MachOWriterExecutable.hpp [plain text]
/* -*- mode: C++; c-basic-offset: 4; tab-width: 4 -*-
*
* Copyright (c) 2005-2009 Apple Inc. All rights reserved.
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*
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* Version 2.0 (the 'License'). You may not use this file except in
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* http://www.opensource.apple.com/apsl/ and read it before using this
* file.
*
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#ifndef __EXECUTABLE_MACH_O__
#define __EXECUTABLE_MACH_O__
#include <stdint.h>
#include <stddef.h>
#include <fcntl.h>
#include <sys/time.h>
#include <uuid/uuid.h>
#include <mach/i386/thread_status.h>
#include <mach/ppc/thread_status.h>
#include <CommonCrypto/CommonDigest.h>
#include <vector>
#include <algorithm>
#include <map>
#include <set>
#include <ext/hash_map>
#include "ObjectFile.h"
#include "ExecutableFile.h"
#include "Options.h"
#include "MachOFileAbstraction.hpp"
#include "MachOTrie.hpp"
//
//
// To implement architecture xxx, you must write template specializations for the following methods:
// MachHeaderAtom<xxx>::setHeaderInfo()
// ThreadsLoadCommandsAtom<xxx>::getSize()
// ThreadsLoadCommandsAtom<xxx>::copyRawContent()
// Writer<xxx>::addObjectRelocs()
// Writer<xxx>::fixUpReferenceRelocatable()
// Writer<xxx>::fixUpReferenceFinal()
// Writer<xxx>::stubableReference()
// Writer<xxx>::weakImportReferenceKind()
// Writer<xxx>::GOTReferenceKind()
//
namespace mach_o {
namespace executable {
// forward references
template <typename A> class WriterAtom;
template <typename A> class PageZeroAtom;
template <typename A> class CustomStackAtom;
template <typename A> class MachHeaderAtom;
template <typename A> class SegmentLoadCommandsAtom;
template <typename A> class EncryptionLoadCommandsAtom;
template <typename A> class SymbolTableLoadCommandsAtom;
template <typename A> class DyldInfoLoadCommandsAtom;
template <typename A> class ThreadsLoadCommandsAtom;
template <typename A> class DylibIDLoadCommandsAtom;
template <typename A> class RoutinesLoadCommandsAtom;
template <typename A> class DyldLoadCommandsAtom;
template <typename A> class UUIDLoadCommandAtom;
template <typename A> class LinkEditAtom;
template <typename A> class SectionRelocationsLinkEditAtom;
template <typename A> class CompressedRebaseInfoLinkEditAtom;
template <typename A> class CompressedBindingInfoLinkEditAtom;
template <typename A> class CompressedWeakBindingInfoLinkEditAtom;
template <typename A> class CompressedLazyBindingInfoLinkEditAtom;
template <typename A> class CompressedExportInfoLinkEditAtom;
template <typename A> class LocalRelocationsLinkEditAtom;
template <typename A> class ExternalRelocationsLinkEditAtom;
template <typename A> class SymbolTableLinkEditAtom;
template <typename A> class SegmentSplitInfoLoadCommandsAtom;
template <typename A> class SegmentSplitInfoContentAtom;
template <typename A> class IndirectTableLinkEditAtom;
template <typename A> class ModuleInfoLinkEditAtom;
template <typename A> class StringsLinkEditAtom;
template <typename A> class LoadCommandsPaddingAtom;
template <typename A> class UnwindInfoAtom;
template <typename A> class StubAtom;
template <typename A> class StubHelperAtom;
template <typename A> class ClassicStubHelperAtom;
template <typename A> class HybridStubHelperAtom;
template <typename A> class HybridStubHelperHelperAtom;
template <typename A> class FastStubHelperAtom;
template <typename A> class FastStubHelperHelperAtom;
template <typename A> class LazyPointerAtom;
template <typename A> class NonLazyPointerAtom;
template <typename A> class DylibLoadCommandsAtom;
template <typename A> class BranchIslandAtom;
// SectionInfo should be nested inside Writer, but I can't figure out how to make the type accessible to the Atom classes
class SectionInfo : public ObjectFile::Section {
public:
SectionInfo() : fFileOffset(0), fSize(0), fRelocCount(0), fRelocOffset(0),
fIndirectSymbolOffset(0), fAlignment(0), fAllLazyPointers(false),
fAllLazyDylibPointers(false),fAllNonLazyPointers(false), fAllStubs(false),
fAllSelfModifyingStubs(false), fAllStubHelpers(false),
fAllZeroFill(false), fVirtualSection(false),
fHasTextLocalRelocs(false), fHasTextExternalRelocs(false)
{ fSegmentName[0] = '\0'; fSectionName[0] = '\0'; }
void setIndex(unsigned int index) { fIndex=index; }
std::vector<ObjectFile::Atom*> fAtoms;
char fSegmentName[20];
char fSectionName[20];
uint64_t fFileOffset;
uint64_t fSize;
uint32_t fRelocCount;
uint32_t fRelocOffset;
uint32_t fIndirectSymbolOffset;
uint8_t fAlignment;
bool fAllLazyPointers;
bool fAllLazyDylibPointers;
bool fAllNonLazyPointers;
bool fAllStubs;
bool fAllSelfModifyingStubs;
bool fAllStubHelpers;
bool fAllZeroFill;
bool fVirtualSection;
bool fHasTextLocalRelocs;
bool fHasTextExternalRelocs;
};
// SegmentInfo should be nested inside Writer, but I can't figure out how to make the type accessible to the Atom classes
class SegmentInfo
{
public:
SegmentInfo(uint64_t pageSize) : fInitProtection(0), fMaxProtection(0), fFileOffset(0), fFileSize(0),
fBaseAddress(0), fSize(0), fPageSize(pageSize), fFixedAddress(false),
fIndependentAddress(false), fHasLoadCommand(true) { fName[0] = '\0'; }
std::vector<class SectionInfo*> fSections;
char fName[20];
uint32_t fInitProtection;
uint32_t fMaxProtection;
uint64_t fFileOffset;
uint64_t fFileSize;
uint64_t fBaseAddress;
uint64_t fSize;
uint64_t fPageSize;
bool fFixedAddress;
bool fIndependentAddress;
bool fHasLoadCommand;
};
struct RebaseInfo {
RebaseInfo(uint8_t t, uint64_t addr) : fType(t), fAddress(addr) {}
uint8_t fType;
uint64_t fAddress;
// for sorting
int operator<(const RebaseInfo& rhs) const {
// sort by type, then address
if ( this->fType != rhs.fType )
return (this->fType < rhs.fType );
return (this->fAddress < rhs.fAddress );
}
};
struct BindingInfo {
BindingInfo(uint8_t t, int ord, const char* sym, bool weak_import, uint64_t addr, int64_t addend)
: fType(t), fFlags(weak_import ? BIND_SYMBOL_FLAGS_WEAK_IMPORT : 0 ), fLibraryOrdinal(ord),
fSymbolName(sym), fAddress(addr), fAddend(addend) {}
BindingInfo(uint8_t t, const char* sym, bool non_weak_definition, uint64_t addr, int64_t addend)
: fType(t), fFlags(non_weak_definition ? BIND_SYMBOL_FLAGS_NON_WEAK_DEFINITION : 0 ), fLibraryOrdinal(0),
fSymbolName(sym), fAddress(addr), fAddend(addend) {}
uint8_t fType;
uint8_t fFlags;
int fLibraryOrdinal;
const char* fSymbolName;
uint64_t fAddress;
int64_t fAddend;
// for sorting
int operator<(const BindingInfo& rhs) const {
// sort by library, symbol, type, then address
if ( this->fLibraryOrdinal != rhs.fLibraryOrdinal )
return (this->fLibraryOrdinal < rhs.fLibraryOrdinal );
if ( this->fSymbolName != rhs.fSymbolName )
return ( strcmp(this->fSymbolName, rhs.fSymbolName) < 0 );
if ( this->fType != rhs.fType )
return (this->fType < rhs.fType );
return (this->fAddress < rhs.fAddress );
}
};
class ByteStream {
private:
std::vector<uint8_t> fData;
public:
std::vector<uint8_t>& bytes() { return fData; }
unsigned long size() const { return fData.size(); }
void reserve(unsigned long l) { fData.reserve(l); }
const uint8_t* start() const { return &fData[0]; }
void append_uleb128(uint64_t value) {
uint8_t byte;
do {
byte = value & 0x7F;
value &= ~0x7F;
if ( value != 0 )
byte |= 0x80;
fData.push_back(byte);
value = value >> 7;
} while( byte >= 0x80 );
}
void append_sleb128(int64_t value) {
bool isNeg = ( value < 0 );
uint8_t byte;
bool more;
do {
byte = value & 0x7F;
value = value >> 7;
if ( isNeg )
more = ( (value != -1) || ((byte & 0x40) == 0) );
else
more = ( (value != 0) || ((byte & 0x40) != 0) );
if ( more )
byte |= 0x80;
fData.push_back(byte);
}
while( more );
}
void append_string(const char* str) {
for (const char* s = str; *s != '\0'; ++s)
fData.push_back(*s);
fData.push_back('\0');
}
void append_byte(uint8_t byte) {
fData.push_back(byte);
}
static unsigned int uleb128_size(uint64_t value) {
uint32_t result = 0;
do {
value = value >> 7;
++result;
} while ( value != 0 );
return result;
}
void pad_to_size(unsigned int alignment) {
while ( (fData.size() % alignment) != 0 )
fData.push_back(0);
}
};
template <typename A>
class Writer : public ExecutableFile::Writer
{
public:
Writer(const char* path, Options& options, std::vector<ExecutableFile::DyLibUsed>& dynamicLibraries);
virtual ~Writer();
virtual const char* getPath() { return fFilePath; }
virtual time_t getModificationTime() { return 0; }
virtual DebugInfoKind getDebugInfoKind() { return ObjectFile::Reader::kDebugInfoNone; }
virtual std::vector<class ObjectFile::Atom*>& getAtoms() { return fWriterSynthesizedAtoms; }
virtual std::vector<class ObjectFile::Atom*>* getJustInTimeAtomsFor(const char* name) { return NULL; }
virtual std::vector<Stab>* getStabs() { return NULL; }
virtual ObjectFile::Atom& makeObjcInfoAtom(ObjectFile::Reader::ObjcConstraint objcContraint,
bool objcReplacementClasses);
virtual class ObjectFile::Atom* getUndefinedProxyAtom(const char* name);
virtual void addSynthesizedAtoms(const std::vector<class ObjectFile::Atom*>& existingAtoms,
class ObjectFile::Atom* dyldClassicHelperAtom,
class ObjectFile::Atom* dyldCompressedHelperAtom,
class ObjectFile::Atom* dyldLazyDylibHelperAtom,
bool biggerThanTwoGigs,
uint32_t dylibSymbolCount,
std::vector<class ObjectFile::Atom*>& newAtoms);
virtual uint64_t write(std::vector<class ObjectFile::Atom*>& atoms,
std::vector<class ObjectFile::Reader::Stab>& stabs,
class ObjectFile::Atom* entryPointAtom,
bool createUUID, bool canScatter,
ObjectFile::Reader::CpuConstraint cpuConstraint,
std::set<const class ObjectFile::Atom*>& atomsThatOverrideWeak,
bool hasExternalWeakDefinitions);
private:
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
enum RelocKind { kRelocNone, kRelocInternal, kRelocExternal };
void assignFileOffsets();
void synthesizeStubs(const std::vector<class ObjectFile::Atom*>& existingAtoms,
std::vector<class ObjectFile::Atom*>& newAtoms);
void synthesizeKextGOT(const std::vector<class ObjectFile::Atom*>& existingAtoms,
std::vector<class ObjectFile::Atom*>& newAtoms);
void createSplitSegContent();
void synthesizeUnwindInfoTable();
void insertDummyStubs();
void partitionIntoSections();
bool addBranchIslands();
bool createBranchIslands();
bool isBranchThatMightNeedIsland(uint8_t kind);
uint32_t textSizeWhenMightNeedBranchIslands();
uint32_t maxDistanceBetweenIslands();
void adjustLoadCommandsAndPadding();
void createDynamicLinkerCommand();
void createDylibCommands();
void buildLinkEdit();
const char* getArchString();
void writeMap();
uint64_t writeAtoms();
void writeNoOps(int fd, uint32_t from, uint32_t to);
void copyNoOps(uint8_t* from, uint8_t* to);
bool segmentsCanSplitApart(const ObjectFile::Atom& from, const ObjectFile::Atom& to);
void addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref);
void collectExportedAndImportedAndLocalAtoms();
void setNlistRange(std::vector<class ObjectFile::Atom*>& atoms, uint32_t startIndex, uint32_t count);
void addLocalLabel(ObjectFile::Atom& atom, uint32_t offsetInAtom, const char* name);
void addGlobalLabel(ObjectFile::Atom& atom, uint32_t offsetInAtom, const char* name);
void buildSymbolTable();
bool stringsNeedLabelsInObjects();
const char* symbolTableName(const ObjectFile::Atom* atom);
void setExportNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry);
void setImportNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry);
void setLocalNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry);
void copyNlistRange(const std::vector<macho_nlist<P> >& entries, uint32_t startIndex);
uint64_t getAtomLoadAddress(const ObjectFile::Atom* atom);
uint8_t ordinalForLibrary(ObjectFile::Reader* file);
bool targetRequiresWeakBinding(const ObjectFile::Atom& target);
int compressedOrdinalForImortedAtom(ObjectFile::Atom* target);
bool shouldExport(const ObjectFile::Atom& atom) const;
void buildFixups();
void adjustLinkEditSections();
void buildObjectFileFixups();
void buildExecutableFixups();
bool preboundLazyPointerType(uint8_t* type);
uint64_t relocAddressInFinalLinkedImage(uint64_t address, const ObjectFile::Atom* atom) const;
void fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const;
void fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const;
void fixUpReference_powerpc(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom,
uint8_t buffer[], bool finalLinkedImage) const;
uint32_t symbolIndex(ObjectFile::Atom& atom);
bool makesExternalRelocatableReference(ObjectFile::Atom& target) const;
uint32_t addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref);
uint32_t addObjectRelocs_powerpc(ObjectFile::Atom* atom, ObjectFile::Reference* ref);
uint8_t getRelocPointerSize();
uint64_t maxAddress();
bool stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref);
bool GOTReferenceKind(uint8_t kind);
bool optimizableGOTReferenceKind(uint8_t kind);
bool weakImportReferenceKind(uint8_t kind);
unsigned int collectStabs();
uint64_t valueForStab(const ObjectFile::Reader::Stab& stab);
uint32_t stringOffsetForStab(const ObjectFile::Reader::Stab& stab);
uint8_t sectionIndexForStab(const ObjectFile::Reader::Stab& stab);
void addStabs(uint32_t startIndex);
RelocKind relocationNeededInFinalLinkedImage(const ObjectFile::Atom& target) const;
bool illegalRelocInFinalLinkedImage(const ObjectFile::Reference&);
bool generatesLocalTextReloc(const ObjectFile::Reference&, const ObjectFile::Atom& atom, SectionInfo* curSection);
bool generatesExternalTextReloc(const ObjectFile::Reference&, const ObjectFile::Atom& atom, SectionInfo* curSection);
bool mightNeedPadSegment();
void scanForAbsoluteReferences();
bool needsModuleTable();
void optimizeDylibReferences();
bool indirectSymbolInRelocatableIsLocal(const ObjectFile::Reference* ref) const;
struct DirectLibrary {
class ObjectFile::Reader* fLibrary;
bool fWeak;
bool fReExport;
};
friend class WriterAtom<A>;
friend class PageZeroAtom<A>;
friend class CustomStackAtom<A>;
friend class MachHeaderAtom<A>;
friend class SegmentLoadCommandsAtom<A>;
friend class EncryptionLoadCommandsAtom<A>;
friend class SymbolTableLoadCommandsAtom<A>;
friend class DyldInfoLoadCommandsAtom<A>;
friend class ThreadsLoadCommandsAtom<A>;
friend class DylibIDLoadCommandsAtom<A>;
friend class RoutinesLoadCommandsAtom<A>;
friend class DyldLoadCommandsAtom<A>;
friend class UUIDLoadCommandAtom<A>;
friend class LinkEditAtom<A>;
friend class SectionRelocationsLinkEditAtom<A>;
friend class CompressedRebaseInfoLinkEditAtom<A>;
friend class CompressedBindingInfoLinkEditAtom<A>;
friend class CompressedWeakBindingInfoLinkEditAtom<A>;
friend class CompressedLazyBindingInfoLinkEditAtom<A>;
friend class CompressedExportInfoLinkEditAtom<A>;
friend class LocalRelocationsLinkEditAtom<A>;
friend class ExternalRelocationsLinkEditAtom<A>;
friend class SymbolTableLinkEditAtom<A>;
friend class SegmentSplitInfoLoadCommandsAtom<A>;
friend class SegmentSplitInfoContentAtom<A>;
friend class IndirectTableLinkEditAtom<A>;
friend class ModuleInfoLinkEditAtom<A>;
friend class StringsLinkEditAtom<A>;
friend class LoadCommandsPaddingAtom<A>;
friend class UnwindInfoAtom<A>;
friend class StubAtom<A>;
friend class StubHelperAtom<A>;
friend class ClassicStubHelperAtom<A>;
friend class HybridStubHelperAtom<A>;
friend class FastStubHelperAtom<A>;
friend class FastStubHelperHelperAtom<A>;
friend class HybridStubHelperHelperAtom<A>;
friend class LazyPointerAtom<A>;
friend class NonLazyPointerAtom<A>;
friend class DylibLoadCommandsAtom<A>;
friend class BranchIslandAtom<A>;
const char* fFilePath;
Options& fOptions;
std::vector<class ObjectFile::Atom*>* fAllAtoms;
std::vector<class ObjectFile::Reader::Stab>* fStabs;
std::set<const class ObjectFile::Atom*>* fRegularDefAtomsThatOverrideADylibsWeakDef;
class SectionInfo* fLoadCommandsSection;
class SegmentInfo* fLoadCommandsSegment;
class MachHeaderAtom<A>* fMachHeaderAtom;
class EncryptionLoadCommandsAtom<A>* fEncryptionLoadCommand;
class SegmentLoadCommandsAtom<A>* fSegmentCommands;
class SymbolTableLoadCommandsAtom<A>* fSymbolTableCommands;
class LoadCommandsPaddingAtom<A>* fHeaderPadding;
class UnwindInfoAtom<A>* fUnwindInfoAtom;
class UUIDLoadCommandAtom<A>* fUUIDAtom;
std::vector<class ObjectFile::Atom*> fWriterSynthesizedAtoms;
std::vector<SegmentInfo*> fSegmentInfos;
class SegmentInfo* fPadSegmentInfo;
class ObjectFile::Atom* fEntryPoint;
class ObjectFile::Atom* fDyldClassicHelperAtom;
class ObjectFile::Atom* fDyldCompressedHelperAtom;
class ObjectFile::Atom* fDyldLazyDylibHelper;
std::map<class ObjectFile::Reader*, DylibLoadCommandsAtom<A>*> fLibraryToLoadCommand;
std::map<class ObjectFile::Reader*, uint32_t> fLibraryToOrdinal;
std::map<class ObjectFile::Reader*, class ObjectFile::Reader*> fLibraryAliases;
std::set<class ObjectFile::Reader*> fForcedWeakImportReaders;
std::vector<class ObjectFile::Atom*> fExportedAtoms;
std::vector<class ObjectFile::Atom*> fImportedAtoms;
std::vector<class ObjectFile::Atom*> fLocalSymbolAtoms;
std::vector<macho_nlist<P> > fLocalExtraLabels;
std::vector<macho_nlist<P> > fGlobalExtraLabels;
std::map<ObjectFile::Atom*, uint32_t> fAtomToSymbolIndex;
class SectionRelocationsLinkEditAtom<A>* fSectionRelocationsAtom;
class CompressedRebaseInfoLinkEditAtom<A>* fCompressedRebaseInfoAtom;
class CompressedBindingInfoLinkEditAtom<A>* fCompressedBindingInfoAtom;
class CompressedWeakBindingInfoLinkEditAtom<A>* fCompressedWeakBindingInfoAtom;
class CompressedLazyBindingInfoLinkEditAtom<A>* fCompressedLazyBindingInfoAtom;
class CompressedExportInfoLinkEditAtom<A>* fCompressedExportInfoAtom;
class LocalRelocationsLinkEditAtom<A>* fLocalRelocationsAtom;
class ExternalRelocationsLinkEditAtom<A>* fExternalRelocationsAtom;
class SymbolTableLinkEditAtom<A>* fSymbolTableAtom;
class SegmentSplitInfoContentAtom<A>* fSplitCodeToDataContentAtom;
class IndirectTableLinkEditAtom<A>* fIndirectTableAtom;
class ModuleInfoLinkEditAtom<A>* fModuleInfoAtom;
class StringsLinkEditAtom<A>* fStringsAtom;
class PageZeroAtom<A>* fPageZeroAtom;
class NonLazyPointerAtom<A>* fFastStubGOTAtom;
macho_nlist<P>* fSymbolTable;
std::vector<macho_relocation_info<P> > fSectionRelocs;
std::vector<macho_relocation_info<P> > fInternalRelocs;
std::vector<macho_relocation_info<P> > fExternalRelocs;
std::vector<RebaseInfo> fRebaseInfo;
std::vector<BindingInfo> fBindingInfo;
std::vector<BindingInfo> fWeakBindingInfo;
std::map<const ObjectFile::Atom*,ObjectFile::Atom*> fStubsMap;
std::map<ObjectFile::Atom*,ObjectFile::Atom*> fGOTMap;
std::vector<class StubAtom<A>*> fAllSynthesizedStubs;
std::vector<ObjectFile::Atom*> fAllSynthesizedStubHelpers;
std::vector<class LazyPointerAtom<A>*> fAllSynthesizedLazyPointers;
std::vector<class LazyPointerAtom<A>*> fAllSynthesizedLazyDylibPointers;
std::vector<class NonLazyPointerAtom<A>*> fAllSynthesizedNonLazyPointers;
uint32_t fSymbolTableCount;
uint32_t fSymbolTableStabsCount;
uint32_t fSymbolTableStabsStartIndex;
uint32_t fSymbolTableLocalCount;
uint32_t fSymbolTableLocalStartIndex;
uint32_t fSymbolTableExportCount;
uint32_t fSymbolTableExportStartIndex;
uint32_t fSymbolTableImportCount;
uint32_t fSymbolTableImportStartIndex;
uint32_t fLargestAtomSize;
uint32_t fDylibSymbolCountUpperBound;
bool fEmitVirtualSections;
bool fHasWeakExports;
bool fReferencesWeakImports;
bool fCanScatter;
bool fWritableSegmentPastFirst4GB;
bool fNoReExportedDylibs;
bool fBiggerThanTwoGigs;
bool fSlideable;
bool fHasThumbBranches;
std::map<const ObjectFile::Atom*,bool> fWeakImportMap;
std::set<const ObjectFile::Reader*> fDylibReadersWithNonWeakImports;
std::set<const ObjectFile::Reader*> fDylibReadersWithWeakImports;
SegmentInfo* fFirstWritableSegment;
ObjectFile::Reader::CpuConstraint fCpuConstraint;
uint32_t fAnonNameIndex;
};
class Segment : public ObjectFile::Segment
{
public:
Segment(const char* name, bool readable, bool writable, bool executable, bool fixedAddress)
: fName(name), fReadable(readable), fWritable(writable), fExecutable(executable), fFixedAddress(fixedAddress) {}
virtual const char* getName() const { return fName; }
virtual bool isContentReadable() const { return fReadable; }
virtual bool isContentWritable() const { return fWritable; }
virtual bool isContentExecutable() const { return fExecutable; }
virtual bool hasFixedAddress() const { return fFixedAddress; }
static Segment fgTextSegment;
static Segment fgPageZeroSegment;
static Segment fgLinkEditSegment;
static Segment fgStackSegment;
static Segment fgImportSegment;
static Segment fgROImportSegment;
static Segment fgDataSegment;
static Segment fgObjCSegment;
static Segment fgHeaderSegment;
private:
const char* fName;
const bool fReadable;
const bool fWritable;
const bool fExecutable;
const bool fFixedAddress;
};
Segment Segment::fgPageZeroSegment("__PAGEZERO", false, false, false, true);
Segment Segment::fgTextSegment("__TEXT", true, false, true, false);
Segment Segment::fgLinkEditSegment("__LINKEDIT", true, false, false, false);
Segment Segment::fgStackSegment("__UNIXSTACK", true, true, false, true);
Segment Segment::fgImportSegment("__IMPORT", true, true, true, false);
Segment Segment::fgROImportSegment("__IMPORT", true, false, true, false);
Segment Segment::fgDataSegment("__DATA", true, true, false, false);
Segment Segment::fgObjCSegment("__OBJC", true, true, false, false);
Segment Segment::fgHeaderSegment("__HEADER", true, false, true, false);
template <typename A>
class WriterAtom : public ObjectFile::Atom
{
public:
enum Kind { zeropage, machHeaderApp, machHeaderDylib, machHeaderBundle, machHeaderObject, loadCommands, undefinedProxy };
WriterAtom(Writer<A>& writer, Segment& segment) : fWriter(writer), fSegment(segment) { }
virtual ObjectFile::Reader* getFile() const { return &fWriter; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const { return false; }
virtual const char* getName() const { return NULL; }
virtual const char* getDisplayName() const { return this->getName(); }
virtual Scope getScope() const { return ObjectFile::Atom::scopeTranslationUnit; }
virtual DefinitionKind getDefinitionKind() const { return kRegularDefinition; }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableNotIn; }
virtual bool dontDeadStrip() const { return true; }
virtual bool isZeroFill() const { return false; }
virtual bool isThumb() const { return false; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return fgEmptyReferenceList; }
virtual bool mustRemainInSection() const { return true; }
virtual ObjectFile::Segment& getSegment() const { return fSegment; }
virtual ObjectFile::Atom& getFollowOnAtom() const { return *((ObjectFile::Atom*)NULL); }
virtual uint32_t getOrdinal() const { return 0; }
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(2); }
virtual void copyRawContent(uint8_t buffer[]) const { throw "don't use copyRawContent"; }
virtual void setScope(Scope) { }
protected:
virtual ~WriterAtom() {}
typedef typename A::P P;
typedef typename A::P::E E;
static Segment& headerSegment(Writer<A>& writer) { return (writer.fOptions.outputKind()==Options::kPreload)
? Segment::fgHeaderSegment : Segment::fgTextSegment; }
static std::vector<ObjectFile::Reference*> fgEmptyReferenceList;
Writer<A>& fWriter;
Segment& fSegment;
};
template <typename A> std::vector<ObjectFile::Reference*> WriterAtom<A>::fgEmptyReferenceList;
template <typename A>
class PageZeroAtom : public WriterAtom<A>
{
public:
PageZeroAtom(Writer<A>& writer) : WriterAtom<A>(writer, Segment::fgPageZeroSegment),
fSize(fWriter.fOptions.zeroPageSize()) {}
virtual const char* getDisplayName() const { return "page zero content"; }
virtual bool isZeroFill() const { return true; }
virtual uint64_t getSize() const { return fSize; }
virtual const char* getSectionName() const { return "._zeropage"; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(12); }
void setSize(uint64_t size) { fSize = size; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
uint64_t fSize;
};
template <typename A>
class DsoHandleAtom : public WriterAtom<A>
{
public:
DsoHandleAtom(Writer<A>& writer) : WriterAtom<A>(writer, Segment::fgTextSegment) {}
virtual const char* getName() const { return "___dso_handle"; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableNotIn; }
virtual uint64_t getSize() const { return 0; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(12); }
virtual const char* getSectionName() const { return "._mach_header"; }
virtual void copyRawContent(uint8_t buffer[]) const {}
};
template <typename A>
class MachHeaderAtom : public WriterAtom<A>
{
public:
MachHeaderAtom(Writer<A>& writer) : WriterAtom<A>(writer, headerSegment(writer)) {}
virtual const char* getName() const;
virtual const char* getDisplayName() const;
virtual ObjectFile::Atom::Scope getScope() const;
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const;
virtual uint64_t getSize() const { return sizeof(macho_header<typename A::P>); }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(12); }
virtual const char* getSectionName() const { return "._mach_header"; }
virtual uint32_t getOrdinal() const { return 1; }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
void setHeaderInfo(macho_header<typename A::P>& header) const;
};
template <typename A>
class CustomStackAtom : public WriterAtom<A>
{
public:
CustomStackAtom(Writer<A>& writer);
virtual const char* getDisplayName() const { return "custom stack content"; }
virtual bool isZeroFill() const { return true; }
virtual uint64_t getSize() const { return fWriter.fOptions.customStackSize(); }
virtual const char* getSectionName() const { return "._stack"; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(12); }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
static bool stackGrowsDown();
};
template <typename A>
class LoadCommandAtom : public WriterAtom<A>
{
protected:
LoadCommandAtom(Writer<A>& writer) : WriterAtom<A>(writer, headerSegment(writer)), fOrdinal(fgCurrentOrdinal++) {}
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(log2(sizeof(typename A::P::uint_t))); }
virtual const char* getSectionName() const { return "._load_commands"; }
virtual uint32_t getOrdinal() const { return fOrdinal; }
static uint64_t alignedSize(uint64_t size);
protected:
uint32_t fOrdinal;
static uint32_t fgCurrentOrdinal;
};
template <typename A> uint32_t LoadCommandAtom<A>::fgCurrentOrdinal = 0;
template <typename A>
class SegmentLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
SegmentLoadCommandsAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer), fCommandCount(0), fSize(0)
{ writer.fSegmentCommands = this; }
virtual const char* getDisplayName() const { return "segment load commands"; }
virtual uint64_t getSize() const { return fSize; }
virtual void copyRawContent(uint8_t buffer[]) const;
void computeSize();
void setup();
unsigned int commandCount() { return fCommandCount; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
unsigned int fCommandCount;
uint32_t fSize;
};
template <typename A>
class SymbolTableLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
SymbolTableLoadCommandsAtom(Writer<A>&);
virtual const char* getDisplayName() const { return "symbol table load commands"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
unsigned int commandCount();
void needDynamicTable();
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
bool fNeedsDynamicSymbolTable;
macho_symtab_command<typename A::P> fSymbolTable;
macho_dysymtab_command<typename A::P> fDynamicSymbolTable;
};
template <typename A>
class ThreadsLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
ThreadsLoadCommandsAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "thread load commands"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
uint8_t* fBuffer;
uint32_t fBufferSize;
};
template <typename A>
class DyldLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
DyldLoadCommandsAtom(Writer<A>& writer) : LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "dyld load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class SegmentSplitInfoLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
SegmentSplitInfoLoadCommandsAtom(Writer<A>& writer) : LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "segment split info load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class AllowableClientLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
AllowableClientLoadCommandsAtom(Writer<A>& writer, const char* client) :
LoadCommandAtom<A>(writer), clientString(client) {}
virtual const char* getDisplayName() const { return "allowable_client load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
const char* clientString;
};
template <typename A>
class DylibLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
DylibLoadCommandsAtom(Writer<A>& writer, ExecutableFile::DyLibUsed& info)
: LoadCommandAtom<A>(writer), fInfo(info),
fOptimizedAway(false) { if (fInfo.options.fLazyLoad) this->fOrdinal += 256; }
virtual const char* getDisplayName() const { return "dylib load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
virtual void optimizeAway() { fOptimizedAway = true; }
bool linkedWeak() { return fInfo.options.fWeakImport; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
ExecutableFile::DyLibUsed fInfo;
bool fOptimizedAway;
};
template <typename A>
class DylibIDLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
DylibIDLoadCommandsAtom(Writer<A>& writer) : LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "dylib ID load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class RoutinesLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
RoutinesLoadCommandsAtom(Writer<A>& writer) : LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "routines load command"; }
virtual uint64_t getSize() const { return sizeof(macho_routines_command<typename A::P>); }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class SubUmbrellaLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
SubUmbrellaLoadCommandsAtom(Writer<A>& writer, const char* name)
: LoadCommandAtom<A>(writer), fName(name) {}
virtual const char* getDisplayName() const { return "sub-umbrella load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
typedef typename A::P P;
const char* fName;
};
template <typename A>
class SubLibraryLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
SubLibraryLoadCommandsAtom(Writer<A>& writer, const char* nameStart, int nameLen)
: LoadCommandAtom<A>(writer), fNameStart(nameStart), fNameLength(nameLen) {}
virtual const char* getDisplayName() const { return "sub-library load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
const char* fNameStart;
int fNameLength;
};
template <typename A>
class UmbrellaLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
UmbrellaLoadCommandsAtom(Writer<A>& writer, const char* name)
: LoadCommandAtom<A>(writer), fName(name) {}
virtual const char* getDisplayName() const { return "umbrella load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
const char* fName;
};
template <typename A>
class UUIDLoadCommandAtom : public LoadCommandAtom<A>
{
public:
UUIDLoadCommandAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer), fEmit(false) {}
virtual const char* getDisplayName() const { return "uuid load command"; }
virtual uint64_t getSize() const { return fEmit ? sizeof(macho_uuid_command<typename A::P>) : 0; }
virtual void copyRawContent(uint8_t buffer[]) const;
virtual void generate();
void setContent(const uint8_t uuid[16]);
const uint8_t* getUUID() { return fUUID; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
uuid_t fUUID;
bool fEmit;
};
template <typename A>
class RPathLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
RPathLoadCommandsAtom(Writer<A>& writer, const char* path)
: LoadCommandAtom<A>(writer), fPath(path) {}
virtual const char* getDisplayName() const { return "rpath load command"; }
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
const char* fPath;
};
template <typename A>
class EncryptionLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
EncryptionLoadCommandsAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer), fStartOffset(0),
fEndOffset(0) {}
virtual const char* getDisplayName() const { return "encryption info load command"; }
virtual uint64_t getSize() const { return sizeof(macho_encryption_info_command<typename A::P>); }
virtual void copyRawContent(uint8_t buffer[]) const;
void setStartEncryptionOffset(uint32_t off) { fStartOffset = off; }
void setEndEncryptionOffset(uint32_t off) { fEndOffset = off; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
uint32_t fStartOffset;
uint32_t fEndOffset;
};
template <typename A>
class DyldInfoLoadCommandsAtom : public LoadCommandAtom<A>
{
public:
DyldInfoLoadCommandsAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer) {}
virtual const char* getDisplayName() const { return "dyld info load command"; }
virtual uint64_t getSize() const { return sizeof(macho_dyld_info_command<typename A::P>); }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class LoadCommandsPaddingAtom : public WriterAtom<A>
{
public:
LoadCommandsPaddingAtom(Writer<A>& writer)
: WriterAtom<A>(writer, headerSegment(writer)), fSize(0) {}
virtual const char* getDisplayName() const { return "header padding"; }
virtual uint64_t getSize() const { return fSize; }
virtual const char* getSectionName() const { return "._load_cmds_pad"; }
virtual void copyRawContent(uint8_t buffer[]) const;
void setSize(uint64_t newSize);
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
uint64_t fSize;
};
template <typename A>
class UnwindInfoAtom : public WriterAtom<A>
{
public:
UnwindInfoAtom(Writer<A>& writer) : WriterAtom<A>(writer, Segment::fgTextSegment),
fHeaderSize(0), fPagesSize(0), fAlignment(4) {}
virtual const char* getName() const { return "unwind info"; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeTranslationUnit; }
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableNotIn; }
virtual uint64_t getSize() const { return fHeaderSize+fPagesSize; }
virtual ObjectFile::Alignment getAlignment() const { return fAlignment; }
virtual const char* getSectionName() const { return "__unwind_info"; }
virtual uint32_t getOrdinal() const { return 1; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)fReferences; }
virtual void copyRawContent(uint8_t buffer[]) const;
void addUnwindInfo(ObjectFile::Atom* func, uint32_t offset, uint32_t encoding,
ObjectFile::Reference* fdeRef, ObjectFile::Reference* lsda,
ObjectFile::Atom* personalityPointer);
void generate();
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
struct Info { ObjectFile::Atom* func; ObjectFile::Atom* fde; ObjectFile::Atom* lsda; uint32_t lsdaOffset; ObjectFile::Atom* personalityPointer; uint32_t encoding; };
struct LSDAEntry { ObjectFile::Atom* func; ObjectFile::Atom* lsda; uint32_t lsdaOffset; };
struct RegFixUp { uint8_t* contentPointer; ObjectFile::Atom* func; ObjectFile::Atom* fde; };
struct CompressedFixUp { uint8_t* contentPointer; ObjectFile::Atom* func; ObjectFile::Atom* fromFunc; };
struct CompressedEncodingFixUp { uint8_t* contentPointer; ObjectFile::Atom* fde; };
bool encodingMeansUseDwarf(compact_unwind_encoding_t encoding);
void compressDuplicates(std::vector<Info>& uniqueInfos);
void findCommonEncoding(const std::vector<Info>& uniqueInfos, std::map<uint32_t, unsigned int>& commonEncodings);
void makeLsdaIndex(const std::vector<Info>& uniqueInfos, std::map<ObjectFile::Atom*, uint32_t>& lsdaIndexOffsetMap);
unsigned int makeRegularSecondLevelPage(const std::vector<Info>& uniqueInfos, uint32_t pageSize, unsigned int endIndex,
uint8_t*& pageEnd);
unsigned int makeCompressedSecondLevelPage(const std::vector<Info>& uniqueInfos,
const std::map<uint32_t,unsigned int> commonEncodings,
uint32_t pageSize, unsigned int endIndex, uint8_t*& pageEnd);
void makePersonalityIndex(std::vector<Info>& uniqueInfos);
uint32_t fHeaderSize;
uint32_t fPagesSize;
uint8_t* fHeaderContent;
uint8_t* fPagesContent;
uint8_t* fPagesContentForDelete;
ObjectFile::Alignment fAlignment;
std::vector<Info> fInfos;
std::map<ObjectFile::Atom*, uint32_t> fPersonalityIndexMap;
std::vector<LSDAEntry> fLSDAIndex;
std::vector<RegFixUp> fRegFixUps;
std::vector<CompressedFixUp> fCompressedFixUps;
std::vector<CompressedEncodingFixUp> fCompressedEncodingFixUps;
std::vector<ObjectFile::Reference*> fReferences;
};
template <typename A>
class LinkEditAtom : public WriterAtom<A>
{
public:
LinkEditAtom(Writer<A>& writer) : WriterAtom<A>(writer, Segment::fgLinkEditSegment), fOrdinal(fgCurrentOrdinal++) {}
uint64_t getFileOffset() const;
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(log2(sizeof(typename A::P::uint_t))); }
virtual uint32_t getOrdinal() const { return fOrdinal; }
private:
uint32_t fOrdinal;
static uint32_t fgCurrentOrdinal;
private:
typedef typename A::P P;
};
template <typename A> uint32_t LinkEditAtom<A>::fgCurrentOrdinal = 0;
template <typename A>
class SectionRelocationsLinkEditAtom : public LinkEditAtom<A>
{
public:
SectionRelocationsLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "section relocations"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._section_relocs"; }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class CompressedInfoLinkEditAtom : public LinkEditAtom<A>
{
public:
CompressedInfoLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual uint64_t getSize() const { return fEncodedData.size(); }
virtual void copyRawContent(uint8_t buffer[]) const { memcpy(buffer, fEncodedData.start(), fEncodedData.size()); }
protected:
typedef typename A::P::uint_t pint_t;
ByteStream fEncodedData;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class CompressedRebaseInfoLinkEditAtom : public CompressedInfoLinkEditAtom<A>
{
public:
CompressedRebaseInfoLinkEditAtom(Writer<A>& writer) : CompressedInfoLinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "compressed rebase info"; }
virtual const char* getSectionName() const { return "._rebase info"; }
void encode();
private:
using CompressedInfoLinkEditAtom<A>::fEncodedData;
using CompressedInfoLinkEditAtom<A>::fWriter;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
};
template <typename A>
class CompressedBindingInfoLinkEditAtom : public CompressedInfoLinkEditAtom<A>
{
public:
CompressedBindingInfoLinkEditAtom(Writer<A>& writer) : CompressedInfoLinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "compressed binding info"; }
virtual const char* getSectionName() const { return "._binding info"; }
void encode();
private:
using CompressedInfoLinkEditAtom<A>::fWriter;
using CompressedInfoLinkEditAtom<A>::fEncodedData;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
};
template <typename A>
class CompressedWeakBindingInfoLinkEditAtom : public CompressedInfoLinkEditAtom<A>
{
public:
CompressedWeakBindingInfoLinkEditAtom(Writer<A>& writer) : CompressedInfoLinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "compressed weak binding info"; }
virtual const char* getSectionName() const { return "._wkbinding info"; }
void encode();
private:
using CompressedInfoLinkEditAtom<A>::fWriter;
using CompressedInfoLinkEditAtom<A>::fEncodedData;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
};
template <typename A>
class CompressedLazyBindingInfoLinkEditAtom : public CompressedInfoLinkEditAtom<A>
{
public:
CompressedLazyBindingInfoLinkEditAtom(Writer<A>& writer) : CompressedInfoLinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "compressed lazy binding info"; }
virtual const char* getSectionName() const { return "._lzbinding info"; }
void encode();
private:
std::vector<uint32_t> fStarts;
using CompressedInfoLinkEditAtom<A>::fWriter;
using CompressedInfoLinkEditAtom<A>::fEncodedData;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
};
template <typename A>
class CompressedExportInfoLinkEditAtom : public CompressedInfoLinkEditAtom<A>
{
public:
CompressedExportInfoLinkEditAtom(Writer<A>& writer)
: CompressedInfoLinkEditAtom<A>(writer), fStartNode(strdup("")) { }
virtual const char* getDisplayName() const { return "compressed export info"; }
virtual const char* getSectionName() const { return "._export info"; }
void encode();
private:
using WriterAtom<A>::fWriter;
using CompressedInfoLinkEditAtom<A>::fEncodedData;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
struct node;
struct edge
{
edge(const char* s, struct node* n) : fSubString(s), fChild(n) { }
~edge() { }
const char* fSubString;
struct node* fChild;
};
struct node
{
node(const char* s) : fCummulativeString(s), fAddress(0), fFlags(0), fOrdered(false),
fHaveExportInfo(false), fTrieOffset(0) {}
~node() { }
const char* fCummulativeString;
std::vector<edge> fChildren;
uint64_t fAddress;
uint32_t fFlags;
bool fOrdered;
bool fHaveExportInfo;
uint32_t fTrieOffset;
void addSymbol(const char* fullStr, uint64_t address, uint32_t flags) {
const char* partialStr = &fullStr[strlen(fCummulativeString)];
for (typename std::vector<edge>::iterator it = fChildren.begin(); it != fChildren.end(); ++it) {
edge& e = *it;
int subStringLen = strlen(e.fSubString);
if ( strncmp(e.fSubString, partialStr, subStringLen) == 0 ) {
// already have matching edge, go down that path
e.fChild->addSymbol(fullStr, address, flags);
return;
}
else {
for (int i=subStringLen-1; i > 0; --i) {
if ( strncmp(e.fSubString, partialStr, i) == 0 ) {
// found a common substring, splice in new node
// was A -> C, now A -> B -> C
char* bNodeCummStr = strdup(e.fChild->fCummulativeString);
bNodeCummStr[strlen(bNodeCummStr)+i-subStringLen] = '\0';
//node* aNode = this;
node* bNode = new node(bNodeCummStr);
node* cNode = e.fChild;
char* abEdgeStr = strdup(e.fSubString);
abEdgeStr[i] = '\0';
char* bcEdgeStr = strdup(&e.fSubString[i]);
edge& abEdge = e;
abEdge.fSubString = abEdgeStr;
abEdge.fChild = bNode;
edge bcEdge(bcEdgeStr, cNode);
bNode->fChildren.push_back(bcEdge);
bNode->addSymbol(fullStr, address, flags);
return;
}
}
}
}
// no commonality with any existing child, make a new edge that is this whole string
node* newNode = new node(strdup(fullStr));
edge newEdge(strdup(partialStr), newNode);
fChildren.push_back(newEdge);
newNode->fAddress = address;
newNode->fFlags = flags;
newNode->fHaveExportInfo = true;
}
void addOrderedNodes(const char* name, std::vector<node*>& orderedNodes) {
if ( !fOrdered ) {
orderedNodes.push_back(this);
//fprintf(stderr, "ordered %p %s\n", this, fCummulativeString);
fOrdered = true;
}
const char* partialStr = &name[strlen(fCummulativeString)];
for (typename std::vector<edge>::iterator it = fChildren.begin(); it != fChildren.end(); ++it) {
edge& e = *it;
int subStringLen = strlen(e.fSubString);
if ( strncmp(e.fSubString, partialStr, subStringLen) == 0 ) {
// already have matching edge, go down that path
e.fChild->addOrderedNodes(name, orderedNodes);
return;
}
}
}
// byte for terminal node size in bytes, or 0x00 if not terminal node
// teminal node (uleb128 flags, uleb128 addr)
// byte for child node count
// each child: zero terminated substring, uleb128 node offset
bool updateOffset(uint32_t& offset) {
uint32_t nodeSize = 1; // byte for length of export info
if ( fHaveExportInfo )
nodeSize += ByteStream::uleb128_size(fFlags) + ByteStream::uleb128_size(fAddress);
// add children
++nodeSize; // byte for count of chidren
for (typename std::vector<edge>::iterator it = fChildren.begin(); it != fChildren.end(); ++it) {
edge& e = *it;
nodeSize += strlen(e.fSubString) + 1 + ByteStream::uleb128_size(e.fChild->fTrieOffset);
}
bool result = (fTrieOffset != offset);
fTrieOffset = offset;
//fprintf(stderr, "updateOffset %p %05d %s\n", this, fTrieOffset, fCummulativeString);
offset += nodeSize;
// return true if fTrieOffset was changed
return result;
}
void appendToStream(ByteStream& out) {
if ( fHaveExportInfo ) {
// nodes with export info: size, flags, address
out.append_byte(out.uleb128_size(fFlags) + out.uleb128_size(fAddress));
out.append_uleb128(fFlags);
out.append_uleb128(fAddress);
}
else {
// no export info
out.append_byte(0);
}
// write number of children
out.append_byte(fChildren.size());
// write each child
for (typename std::vector<edge>::iterator it = fChildren.begin(); it != fChildren.end(); ++it) {
edge& e = *it;
out.append_string(e.fSubString);
out.append_uleb128(e.fChild->fTrieOffset);
}
}
};
struct node fStartNode;
};
template <typename A>
class LocalRelocationsLinkEditAtom : public LinkEditAtom<A>
{
public:
LocalRelocationsLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "local relocations"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._local_relocs"; }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class SymbolTableLinkEditAtom : public LinkEditAtom<A>
{
public:
SymbolTableLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "symbol table"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._symbol_table"; }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class ExternalRelocationsLinkEditAtom : public LinkEditAtom<A>
{
public:
ExternalRelocationsLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "external relocations"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._extern_relocs"; }
virtual void copyRawContent(uint8_t buffer[]) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
struct IndirectEntry {
uint32_t indirectIndex;
uint32_t symbolIndex;
};
template <typename A>
class SegmentSplitInfoContentAtom : public LinkEditAtom<A>
{
public:
SegmentSplitInfoContentAtom(Writer<A>& writer) : LinkEditAtom<A>(writer), fCantEncode(false) { }
virtual const char* getDisplayName() const { return "split segment info"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._split_info"; }
virtual void copyRawContent(uint8_t buffer[]) const;
bool canEncode() { return !fCantEncode; }
void setCantEncode() { fCantEncode = true; }
void add32bitPointerLocation(const ObjectFile::Atom* atom, uint32_t offset) { fKind1Locations.push_back(AtomAndOffset(atom, offset)); }
void add64bitPointerLocation(const ObjectFile::Atom* atom, uint32_t offset) { fKind2Locations.push_back(AtomAndOffset(atom, offset)); }
void addPPCHi16Location(const ObjectFile::Atom* atom, uint32_t offset) { fKind3Locations.push_back(AtomAndOffset(atom, offset)); }
void add32bitImportLocation(const ObjectFile::Atom* atom, uint32_t offset) { fKind4Locations.push_back(AtomAndOffset(atom, offset)); }
void encode();
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
struct AtomAndOffset {
AtomAndOffset(const ObjectFile::Atom* a, uint32_t off) : atom(a), offset(off) {}
const ObjectFile::Atom* atom;
uint32_t offset;
};
void uleb128EncodeAddresses(const std::vector<AtomAndOffset>& locations);
std::vector<AtomAndOffset> fKind1Locations;
std::vector<AtomAndOffset> fKind2Locations;
std::vector<AtomAndOffset> fKind3Locations;
std::vector<AtomAndOffset> fKind4Locations;
std::vector<uint8_t> fEncodedData;
bool fCantEncode;
};
template <typename A>
class IndirectTableLinkEditAtom : public LinkEditAtom<A>
{
public:
IndirectTableLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer) { }
virtual const char* getDisplayName() const { return "indirect symbol table"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._indirect_syms"; }
virtual void copyRawContent(uint8_t buffer[]) const;
std::vector<IndirectEntry> fTable;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
};
template <typename A>
class ModuleInfoLinkEditAtom : public LinkEditAtom<A>
{
public:
ModuleInfoLinkEditAtom(Writer<A>& writer) : LinkEditAtom<A>(writer), fModuleNameOffset(0) { }
virtual const char* getDisplayName() const { return "module table"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._module_info"; }
virtual void copyRawContent(uint8_t buffer[]) const;
void setName() { fModuleNameOffset = fWriter.fStringsAtom->add("single module"); }
uint32_t getTableOfContentsFileOffset() const;
uint32_t getModuleTableFileOffset() const;
uint32_t getReferencesFileOffset() const;
uint32_t getReferencesCount() const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
uint32_t fModuleNameOffset;
};
class CStringEquals
{
public:
bool operator()(const char* left, const char* right) const { return (strcmp(left, right) == 0); }
};
template <typename A>
class StringsLinkEditAtom : public LinkEditAtom<A>
{
public:
StringsLinkEditAtom(Writer<A>& writer);
virtual const char* getDisplayName() const { return "string pool"; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "._string_pool"; }
virtual void copyRawContent(uint8_t buffer[]) const;
int32_t add(const char* name);
int32_t addUnique(const char* name);
int32_t emptyString() { return 1; }
const char* stringForIndex(int32_t) const;
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
enum { kBufferSize = 0x01000000 };
typedef __gnu_cxx::hash_map<const char*, int32_t, __gnu_cxx::hash<const char*>, CStringEquals> StringToOffset;
std::vector<char*> fFullBuffers;
char* fCurrentBuffer;
uint32_t fCurrentBufferUsed;
StringToOffset fUniqueStrings;
};
template <typename A>
class UndefinedSymbolProxyAtom : public WriterAtom<A>
{
public:
UndefinedSymbolProxyAtom(Writer<A>& writer, const char* name) : WriterAtom<A>(writer, Segment::fgLinkEditSegment), fName(name) {}
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeGlobal; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return ObjectFile::Atom::kExternalDefinition; }
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableIn; }
virtual uint64_t getSize() const { return 0; }
virtual const char* getSectionName() const { return "._imports"; }
private:
using WriterAtom<A>::fWriter;
typedef typename A::P P;
const char* fName;
};
template <typename A>
class BranchIslandAtom : public WriterAtom<A>
{
public:
BranchIslandAtom(Writer<A>& writer, const char* name, int islandRegion, ObjectFile::Atom& target,
ObjectFile::Atom& finalTarget, uint32_t finalTargetOffset);
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual uint64_t getSize() const;
virtual bool isThumb() const { return (fIslandKind == kBranchIslandToThumb2); }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kBranchIsland; }
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableIn; }
virtual const char* getSectionName() const { return "__text"; }
virtual void copyRawContent(uint8_t buffer[]) const;
uint64_t getFinalTargetAdress() const { return fFinalTarget.getAddress() + fFinalTargetOffset; }
private:
using WriterAtom<A>::fWriter;
enum IslandKind { kBranchIslandToARM, kBranchIslandToThumb2, kBranchIslandToThumb1 };
const char* fName;
ObjectFile::Atom& fTarget;
ObjectFile::Atom& fFinalTarget;
uint32_t fFinalTargetOffset;
IslandKind fIslandKind;
};
template <typename A>
class StubAtom : public WriterAtom<A>
{
public:
StubAtom(Writer<A>& writer, ObjectFile::Atom& target, bool forLazyDylib);
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kStub; }
virtual uint64_t getSize() const;
virtual ObjectFile::Alignment getAlignment() const;
virtual const char* getSectionName() const { return "__symbol_stub1"; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual void copyRawContent(uint8_t buffer[]) const;
ObjectFile::Atom* getTarget() { return &fTarget; }
virtual uint32_t getOrdinal() const { return fSortingOrdinal; }
void setSortingOrdinal(uint32_t o) { fSortingOrdinal = o; }
private:
static const char* stubName(const char* importName);
friend class LazyPointerAtom<A>;
using WriterAtom<A>::fWriter;
enum StubKind { kStubPIC, kStubNoPIC, kStubShort, kJumpTable };
const char* fName;
ObjectFile::Atom& fTarget;
std::vector<ObjectFile::Reference*> fReferences;
bool fForLazyDylib;
StubKind fKind;
uint32_t fSortingOrdinal;
};
template <typename A>
class FastStubHelperHelperAtom : public WriterAtom<A>
{
public:
FastStubHelperHelperAtom(Writer<A>& writer);
virtual const char* getName() const { return " stub helpers"; } // name sorts to start of helpers
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableIn; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kStubHelper; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "__stub_helper"; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual void copyRawContent(uint8_t buffer[]) const;
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(0); }
virtual uint32_t getOrdinal() const { return 0; }
protected:
using WriterAtom<A>::fWriter;
std::vector<ObjectFile::Reference*> fReferences;
};
template <typename A>
class HybridStubHelperHelperAtom : public WriterAtom<A>
{
public:
HybridStubHelperHelperAtom(Writer<A>& writer);
virtual const char* getName() const { return " stub helpers"; } // name sorts to start of helpers
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableIn; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kStubHelper; }
virtual uint64_t getSize() const;
virtual const char* getSectionName() const { return "__stub_helper"; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual void copyRawContent(uint8_t buffer[]) const;
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(0); }
virtual uint32_t getOrdinal() const { return 0; }
protected:
using WriterAtom<A>::fWriter;
std::vector<ObjectFile::Reference*> fReferences;
};
template <typename A>
class StubHelperAtom : public WriterAtom<A>
{
public:
StubHelperAtom(Writer<A>& writer, ObjectFile::Atom& target,
LazyPointerAtom<A>& lazyPointer, bool forLazyDylib)
: WriterAtom<A>(writer, Segment::fgTextSegment), fName(stubName(target.getName())),
fTarget(target), fLazyPointerAtom(lazyPointer) {
writer.fAllSynthesizedStubHelpers.push_back(this);
}
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kStubHelper; }
virtual const char* getSectionName() const { return "__stub_helper"; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
ObjectFile::Atom* getTarget() { return &fTarget; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(0); }
virtual uint32_t getOrdinal() const { return 1; }
protected:
static const char* stubName(const char* importName);
using WriterAtom<A>::fWriter;
const char* fName;
ObjectFile::Atom& fTarget;
LazyPointerAtom<A>& fLazyPointerAtom;
std::vector<ObjectFile::Reference*> fReferences;
};
template <typename A>
class ClassicStubHelperAtom : public StubHelperAtom<A>
{
public:
ClassicStubHelperAtom(Writer<A>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<A>& lazyPointer, bool forLazyDylib);
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
};
template <typename A>
class HybridStubHelperAtom : public StubHelperAtom<A>
{
public:
HybridStubHelperAtom(Writer<A>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<A>& lazyPointer, bool forLazyDylib);
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
static class HybridStubHelperHelperAtom<A>* fgHelperHelperAtom;
};
template <typename A> class HybridStubHelperHelperAtom<A>* HybridStubHelperAtom<A>::fgHelperHelperAtom = NULL;
template <typename A>
class FastStubHelperAtom : public StubHelperAtom<A>
{
public:
FastStubHelperAtom(Writer<A>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<A>& lazyPointer, bool forLazyDylib);
virtual uint64_t getSize() const;
virtual void copyRawContent(uint8_t buffer[]) const;
static FastStubHelperHelperAtom<A>* fgHelperHelperAtom;
};
template <typename A> FastStubHelperHelperAtom<A>* FastStubHelperAtom<A>::fgHelperHelperAtom = NULL;
template <typename A>
class LazyPointerAtom : public WriterAtom<A>
{
public:
LazyPointerAtom(Writer<A>& writer, ObjectFile::Atom& target,
StubAtom<A>& stub, bool forLazyDylib);
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeTranslationUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return fForLazyDylib ? ObjectFile::Atom::kLazyDylibPointer : ObjectFile::Atom::kLazyPointer; }
virtual uint64_t getSize() const { return sizeof(typename A::P::uint_t); }
virtual const char* getSectionName() const;
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual void copyRawContent(uint8_t buffer[]) const;
ObjectFile::Atom* getTarget() { return &fExternalTarget; }
void setLazyBindingInfoOffset(uint32_t off) { fLazyBindingOffset = off; }
uint32_t getLazyBindingInfoOffset() { return fLazyBindingOffset; }
virtual uint32_t getOrdinal() const { return fSortingOrdinal; }
void setSortingOrdinal(uint32_t o) { fSortingOrdinal = o; }
private:
using WriterAtom<A>::fWriter;
static const char* lazyPointerName(const char* importName);
const char* fName;
ObjectFile::Atom& fTarget;
ObjectFile::Atom& fExternalTarget;
std::vector<ObjectFile::Reference*> fReferences;
bool fForLazyDylib;
bool fCloseStub;
uint32_t fLazyBindingOffset;
uint32_t fSortingOrdinal;
};
template <typename A>
class NonLazyPointerAtom : public WriterAtom<A>
{
public:
NonLazyPointerAtom(Writer<A>& writer, ObjectFile::Atom& target);
NonLazyPointerAtom(Writer<A>& writer, const char* targetName);
NonLazyPointerAtom(Writer<A>& writer);
virtual const char* getName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::ContentType getContentType() const { return ObjectFile::Atom::kNonLazyPointer; }
virtual uint64_t getSize() const { return sizeof(typename A::P::uint_t); }
virtual const char* getSectionName() const { return (fWriter.fOptions.outputKind() == Options::kKextBundle) ? "__got" : "__nl_symbol_ptr"; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual void copyRawContent(uint8_t buffer[]) const;
ObjectFile::Atom* getTarget() { return fTarget; }
virtual uint32_t getOrdinal() const { return fSortingOrdinal; }
void setSortingOrdinal(uint32_t o) { fSortingOrdinal = o; }
private:
using WriterAtom<A>::fWriter;
static const char* nonlazyPointerName(const char* importName);
const char* fName;
ObjectFile::Atom* fTarget;
std::vector<ObjectFile::Reference*> fReferences;
uint32_t fSortingOrdinal;
};
template <typename A>
class ObjCInfoAtom : public WriterAtom<A>
{
public:
ObjCInfoAtom(Writer<A>& writer, ObjectFile::Reader::ObjcConstraint objcContraint,
bool objcReplacementClasses);
virtual const char* getName() const { return "objc$info"; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual uint64_t getSize() const { return 8; }
virtual const char* getSectionName() const;
virtual void copyRawContent(uint8_t buffer[]) const;
private:
Segment& getInfoSegment() const;
uint32_t fContent[2];
};
template <typename A>
class WriterReference : public ObjectFile::Reference
{
public:
typedef typename A::ReferenceKinds Kinds;
WriterReference(uint32_t offset, Kinds kind, ObjectFile::Atom* target,
uint32_t toOffset=0, ObjectFile::Atom* fromTarget=NULL, uint32_t fromOffset=0)
: fKind(kind), fFixUpOffsetInSrc(offset), fTarget(target), fTargetName(target->getName()),
fTargetOffset(toOffset), fFromTarget(fromTarget), fFromTargetOffset(fromOffset) {}
WriterReference(uint32_t offset, Kinds kind, const char* targetName)
: fKind(kind), fFixUpOffsetInSrc(offset), fTarget(NULL), fTargetName(targetName),
fTargetOffset(0), fFromTarget(NULL), fFromTargetOffset(0) {}
virtual ~WriterReference() {}
virtual ObjectFile::Reference::TargetBinding getTargetBinding() const { return (fTarget != NULL) ? ObjectFile::Reference::kBoundDirectly : ObjectFile::Reference::kUnboundByName; }
virtual ObjectFile::Reference::TargetBinding getFromTargetBinding() const { return (fFromTarget != NULL) ? ObjectFile::Reference::kBoundDirectly : ObjectFile::Reference::kDontBind; }
virtual uint8_t getKind() const { return (uint8_t)fKind; }
virtual uint64_t getFixUpOffset() const { return fFixUpOffsetInSrc; }
virtual const char* getTargetName() const { return fTargetName; }
virtual ObjectFile::Atom& getTarget() const { return *fTarget; }
virtual uint64_t getTargetOffset() const { return fTargetOffset; }
virtual ObjectFile::Atom& getFromTarget() const { return *fFromTarget; }
virtual const char* getFromTargetName() const { return fFromTarget->getName(); }
virtual void setTarget(ObjectFile::Atom& target, uint64_t offset) { fTarget = ⌖ fTargetOffset = offset; }
virtual void setFromTarget(ObjectFile::Atom& target) { fFromTarget = ⌖ }
virtual void setFromTargetName(const char* name) { }
virtual void setFromTargetOffset(uint64_t offset) { fFromTargetOffset = offset; }
virtual const char* getDescription() const { return "writer reference"; }
virtual uint64_t getFromTargetOffset() const { return fFromTargetOffset; }
private:
Kinds fKind;
uint32_t fFixUpOffsetInSrc;
ObjectFile::Atom* fTarget;
const char* fTargetName;
uint32_t fTargetOffset;
ObjectFile::Atom* fFromTarget;
uint32_t fFromTargetOffset;
};
template <typename A>
const char* StubHelperAtom<A>::stubName(const char* name)
{
char* buf;
asprintf(&buf, "%s$stubHelper", name);
return buf;
}
template <>
ClassicStubHelperAtom<x86_64>::ClassicStubHelperAtom(Writer<x86_64>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86_64>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86_64>(writer, target, lazyPointer, forLazyDylib)
{
fReferences.push_back(new WriterReference<x86_64>(3, x86_64::kPCRel32, &fLazyPointerAtom));
if ( forLazyDylib ) {
if ( fWriter.fDyldLazyDylibHelper == NULL )
throw "symbol dyld_lazy_dylib_stub_binding_helper not defined (usually in lazydylib1.o)";
fReferences.push_back(new WriterReference<x86_64>(8, x86_64::kPCRel32, fWriter.fDyldLazyDylibHelper));
}
else {
if ( fWriter.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
fReferences.push_back(new WriterReference<x86_64>(8, x86_64::kPCRel32, fWriter.fDyldClassicHelperAtom));
}
}
template <>
uint64_t ClassicStubHelperAtom<x86_64>::getSize() const
{
return 12;
}
template <>
void ClassicStubHelperAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x4C; // lea foo$lazy_ptr(%rip),%r11
buffer[1] = 0x8D;
buffer[2] = 0x1D;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
buffer[6] = 0x00;
buffer[7] = 0xE9; // jmp dyld_stub_binding_helper
buffer[8] = 0x00;
buffer[9] = 0x00;
buffer[10] = 0x00;
buffer[11] = 0x00;
}
template <>
FastStubHelperHelperAtom<x86_64>::FastStubHelperHelperAtom(Writer<x86_64>& writer)
: WriterAtom<x86_64>(writer, Segment::fgTextSegment)
{
fReferences.push_back(new WriterReference<x86_64>(3, x86_64::kPCRel32, new NonLazyPointerAtom<x86_64>(writer)));
fReferences.push_back(new WriterReference<x86_64>(11, x86_64::kPCRel32, writer.fFastStubGOTAtom));
}
template <>
uint64_t FastStubHelperHelperAtom<x86_64>::getSize() const
{
return 16;
}
template <>
void FastStubHelperHelperAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x4C; // leaq dyld_mageLoaderCache(%rip),%r11
buffer[1] = 0x8D;
buffer[2] = 0x1D;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
buffer[6] = 0x00;
buffer[7] = 0x41; // pushq %r11
buffer[8] = 0x53;
buffer[9] = 0xFF; // jmp *_fast_lazy_bind(%rip)
buffer[10] = 0x25;
buffer[11] = 0x00;
buffer[12] = 0x00;
buffer[13] = 0x00;
buffer[14] = 0x00;
buffer[15] = 0x90; // nop
}
template <>
HybridStubHelperHelperAtom<x86_64>::HybridStubHelperHelperAtom(Writer<x86_64>& writer)
: WriterAtom<x86_64>(writer, Segment::fgTextSegment)
{
if ( writer.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
fReferences.push_back(new WriterReference<x86_64>(3, x86_64::kPCRel32_1, writer.fFastStubGOTAtom));
fReferences.push_back(new WriterReference<x86_64>(13, x86_64::kPCRel32, new NonLazyPointerAtom<x86_64>(writer)));
fReferences.push_back(new WriterReference<x86_64>(21, x86_64::kPCRel32, writer.fFastStubGOTAtom));
fReferences.push_back(new WriterReference<x86_64>(30, x86_64::kPCRel32, writer.fDyldClassicHelperAtom));
}
template <>
uint64_t HybridStubHelperHelperAtom<x86_64>::getSize() const
{
return 34;
}
template <>
void HybridStubHelperHelperAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x48; // cmpl $0x00,_fast_lazy_bind
buffer[1] = 0x83;
buffer[2] = 0x3D;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
buffer[6] = 0x00;
buffer[7] = 0x00;
buffer[8] = 0x74; // je 16
buffer[9] = 0x0F;
buffer[10] = 0x4C; // leaq imageCache(%rip),%r11
buffer[11] = 0x8D;
buffer[12] = 0x1D;
buffer[13] = 0x00;
buffer[14] = 0x00;
buffer[15] = 0x00;
buffer[16] = 0x00;
buffer[17] = 0x41; // pushq %r11
buffer[18] = 0x53;
buffer[19] = 0xFF; // jmp *_fast_lazy_bind(%rip)
buffer[20] = 0x25;
buffer[21] = 0x00;
buffer[22] = 0x00;
buffer[23] = 0x00;
buffer[24] = 0x00;
buffer[25] = 0x48; // addq $8,%rsp
buffer[26] = 0x83;
buffer[27] = 0xC4;
buffer[28] = 0x08;
buffer[29] = 0xE9; // jmp dyld_stub_binding_helper
buffer[30] = 0x00;
buffer[31] = 0x00;
buffer[32] = 0x00;
buffer[33] = 0x00;
}
template <>
HybridStubHelperAtom<x86_64>::HybridStubHelperAtom(Writer<x86_64>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86_64>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86_64>(writer, target, lazyPointer, forLazyDylib)
{
if ( fgHelperHelperAtom == NULL ) {
fgHelperHelperAtom = new HybridStubHelperHelperAtom<x86_64>::HybridStubHelperHelperAtom(fWriter);
fWriter.fAllSynthesizedStubHelpers.push_back(fgHelperHelperAtom);
}
fReferences.push_back(new WriterReference<x86_64>(8, x86_64::kPCRel32, &fLazyPointerAtom));
fReferences.push_back(new WriterReference<x86_64>(13, x86_64::kPCRel32, fgHelperHelperAtom));
}
template <>
uint64_t HybridStubHelperAtom<x86_64>::getSize() const
{
return 18;
}
template <>
void HybridStubHelperAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushq $lazy-info-offset
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x4C; // lea foo$lazy_ptr(%rip),%r11
buffer[6] = 0x8D;
buffer[7] = 0x1D;
buffer[8] = 0x00;
buffer[9] = 0x00;
buffer[10] = 0x00;
buffer[11] = 0x00;
buffer[12] = 0xE9; // jmp helper-helper
buffer[13] = 0x00;
buffer[14] = 0x00;
buffer[15] = 0x00;
buffer[16] = 0x00;
buffer[17] = 0x90; // nop
// the lazy binding info is created later than this helper atom, so there
// is no Reference to update. Instead we blast the offset here.
uint32_t offset;
LittleEndian::set32(offset, fLazyPointerAtom.getLazyBindingInfoOffset());
memcpy(&buffer[1], &offset, 4);
}
template <>
FastStubHelperAtom<x86_64>::FastStubHelperAtom(Writer<x86_64>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86_64>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86_64>(writer, target, lazyPointer, forLazyDylib)
{
if ( fgHelperHelperAtom == NULL ) {
fgHelperHelperAtom = new FastStubHelperHelperAtom<x86_64>::FastStubHelperHelperAtom(fWriter);
fWriter.fAllSynthesizedStubHelpers.push_back(fgHelperHelperAtom);
}
fReferences.push_back(new WriterReference<x86_64>(6, x86_64::kPCRel32, fgHelperHelperAtom));
}
template <>
uint64_t FastStubHelperAtom<x86_64>::getSize() const
{
return 10;
}
template <>
void FastStubHelperAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushq $lazy-info-offset
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0xE9; // jmp helperhelper
buffer[6] = 0x00;
buffer[7] = 0x00;
buffer[8] = 0x00;
buffer[9] = 0x00;
// the lazy binding info is created later than this helper atom, so there
// is no Reference to update. Instead we blast the offset here.
uint32_t offset;
LittleEndian::set32(offset, fLazyPointerAtom.getLazyBindingInfoOffset());
memcpy(&buffer[1], &offset, 4);
}
template <>
FastStubHelperHelperAtom<x86>::FastStubHelperHelperAtom(Writer<x86>& writer)
: WriterAtom<x86>(writer, Segment::fgTextSegment)
{
fReferences.push_back(new WriterReference<x86>(1, x86::kAbsolute32, new NonLazyPointerAtom<x86>(writer)));
fReferences.push_back(new WriterReference<x86>(7, x86::kAbsolute32, writer.fFastStubGOTAtom));
}
template <>
uint64_t FastStubHelperHelperAtom<x86>::getSize() const
{
return 12;
}
template <>
void FastStubHelperHelperAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushl $dyld_ImageLoaderCache
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0xFF; // jmp *_fast_lazy_bind
buffer[6] = 0x25;
buffer[7] = 0x00;
buffer[8] = 0x00;
buffer[9] = 0x00;
buffer[10] = 0x00;
buffer[11] = 0x90; // nop
}
template <>
FastStubHelperHelperAtom<arm>::FastStubHelperHelperAtom(Writer<arm>& writer)
: WriterAtom<arm>(writer, Segment::fgTextSegment)
{
fReferences.push_back(new WriterReference<arm>(28, arm::kPointerDiff, new NonLazyPointerAtom<arm>(writer), 0, this, 16));
fReferences.push_back(new WriterReference<arm>(32, arm::kPointerDiff, writer.fFastStubGOTAtom, 0, this, 28));
}
template <>
uint64_t FastStubHelperHelperAtom<arm>::getSize() const
{
return 36;
}
template <>
void FastStubHelperHelperAtom<arm>::copyRawContent(uint8_t buffer[]) const
{
// push lazy-info-offset
OSWriteLittleInt32(&buffer[ 0], 0, 0xe52dc004); // str ip, [sp, #-4]!
// push address of dyld_mageLoaderCache
OSWriteLittleInt32(&buffer[ 4], 0, 0xe59fc010); // ldr ip, L1
OSWriteLittleInt32(&buffer[ 8], 0, 0xe08fc00c); // add ip, pc, ip
OSWriteLittleInt32(&buffer[12], 0, 0xe52dc004); // str ip, [sp, #-4]!
// jump through _fast_lazy_bind
OSWriteLittleInt32(&buffer[16], 0, 0xe59fc008); // ldr ip, L2
OSWriteLittleInt32(&buffer[20], 0, 0xe08fc00c); // add ip, pc, ip
OSWriteLittleInt32(&buffer[24], 0, 0xe59cf000); // ldr pc, [ip]
OSWriteLittleInt32(&buffer[28], 0, 0x00000000); // L1: .long fFastStubGOTAtom - (helperhelper+16)
OSWriteLittleInt32(&buffer[32], 0, 0x00000000); // L2: .long _fast_lazy_bind - (helperhelper+28)
}
template <>
ObjectFile::Alignment StubHelperAtom<arm>::getAlignment() const { return ObjectFile::Alignment(2); }
template <>
FastStubHelperAtom<arm>::FastStubHelperAtom(Writer<arm>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<arm>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<arm>(writer, target, lazyPointer, forLazyDylib)
{
if ( fgHelperHelperAtom == NULL ) {
fgHelperHelperAtom = new FastStubHelperHelperAtom<arm>::FastStubHelperHelperAtom(fWriter);
fWriter.fAllSynthesizedStubHelpers.push_back(fgHelperHelperAtom);
}
fReferences.push_back(new WriterReference<arm>(4, arm::kBranch24, fgHelperHelperAtom));
}
template <>
uint64_t FastStubHelperAtom<arm>::getSize() const
{
return 12;
}
template <>
void FastStubHelperAtom<arm>::copyRawContent(uint8_t buffer[]) const
{
OSWriteLittleInt32(&buffer[0], 0, 0xe59fc000); // ldr ip, [pc, #0]
OSWriteLittleInt32(&buffer[4], 0, 0xea000000); // b _helperhelper
// the lazy binding info is created later than this helper atom, so there
// is no Reference to update. Instead we blast the offset here.
OSWriteLittleInt32(&buffer[8], 0, fLazyPointerAtom.getLazyBindingInfoOffset());
}
template <>
HybridStubHelperHelperAtom<x86>::HybridStubHelperHelperAtom(Writer<x86>& writer)
: WriterAtom<x86>(writer, Segment::fgTextSegment)
{
if ( writer.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
fReferences.push_back(new WriterReference<x86>(2, x86::kAbsolute32, writer.fFastStubGOTAtom));
fReferences.push_back(new WriterReference<x86>(18, x86::kPCRel32, writer.fDyldClassicHelperAtom));
fReferences.push_back(new WriterReference<x86>(26, x86::kAbsolute32, new NonLazyPointerAtom<x86>(writer)));
fReferences.push_back(new WriterReference<x86>(32, x86::kAbsolute32, writer.fFastStubGOTAtom));
}
template <>
uint64_t HybridStubHelperHelperAtom<x86>::getSize() const
{
return 36;
}
template <>
void HybridStubHelperHelperAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x83; // cmpl $0x00,_fast_lazy_bind
buffer[1] = 0x3D;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
buffer[6] = 0x00;
buffer[7] = 0x75; // jne 22
buffer[8] = 0x0D;
buffer[9] = 0x89; // %eax,4(%esp)
buffer[10] = 0x44;
buffer[11] = 0x24;
buffer[12] = 0x04;
buffer[13] = 0x58; // popl %eax
buffer[14] = 0x87; // xchgl (%esp),%eax
buffer[15] = 0x04;
buffer[16] = 0x24;
buffer[17] = 0xE9; // jmpl dyld_stub_binding_helper
buffer[18] = 0x00;
buffer[19] = 0x00;
buffer[20] = 0x00;
buffer[21] = 0x00;
buffer[22] = 0x83; // addl $0x04,%esp
buffer[23] = 0xC4;
buffer[24] = 0x04;
buffer[25] = 0x68; // pushl imageloadercahce
buffer[26] = 0x00;
buffer[27] = 0x00;
buffer[28] = 0x00;
buffer[29] = 0x00;
buffer[30] = 0xFF; // jmp *_fast_lazy_bind(%rip)
buffer[31] = 0x25;
buffer[32] = 0x00;
buffer[33] = 0x00;
buffer[34] = 0x00;
buffer[35] = 0x00;
}
template <>
ClassicStubHelperAtom<x86>::ClassicStubHelperAtom(Writer<x86>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86>(writer, target, lazyPointer, forLazyDylib)
{
fReferences.push_back(new WriterReference<x86>(1, x86::kAbsolute32, &fLazyPointerAtom));
if ( forLazyDylib ) {
if ( fWriter.fDyldLazyDylibHelper == NULL )
throw "symbol dyld_lazy_dylib_stub_binding_helper not defined (usually in lazydylib1.o)";
fReferences.push_back(new WriterReference<x86>(6, x86::kPCRel32, fWriter.fDyldLazyDylibHelper));
}
else {
if ( fWriter.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
fReferences.push_back(new WriterReference<x86>(6, x86::kPCRel32, fWriter.fDyldClassicHelperAtom));
}
}
template <>
uint64_t ClassicStubHelperAtom<x86>::getSize() const
{
return 10;
}
template <>
void ClassicStubHelperAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushl $foo$lazy_ptr
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0xE9; // jmp helperhelper
buffer[6] = 0x00;
buffer[7] = 0x00;
buffer[8] = 0x00;
buffer[9] = 0x00;
}
template <>
HybridStubHelperAtom<x86>::HybridStubHelperAtom(Writer<x86>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86>(writer, target, lazyPointer, forLazyDylib)
{
if ( fgHelperHelperAtom == NULL ) {
fgHelperHelperAtom = new HybridStubHelperHelperAtom<x86>::HybridStubHelperHelperAtom(fWriter);
fWriter.fAllSynthesizedStubHelpers.push_back(fgHelperHelperAtom);
}
fReferences.push_back(new WriterReference<x86>(6, x86::kAbsolute32, &fLazyPointerAtom));
fReferences.push_back(new WriterReference<x86>(11, x86::kPCRel32, fgHelperHelperAtom));
}
template <>
uint64_t HybridStubHelperAtom<x86>::getSize() const
{
return 16;
}
template <>
void HybridStubHelperAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushl $lazy-info-offset
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x68; // pushl $foo$lazy_ptr
buffer[6] = 0x00;
buffer[7] = 0x00;
buffer[8] = 0x00;
buffer[9] = 0x00;
buffer[10] = 0xE9; // jmp dyld_hybrid_stub_binding_helper
buffer[11] = 0x00;
buffer[12] = 0x00;
buffer[13] = 0x00;
buffer[14] = 0x00;
buffer[15] = 0x90; // nop
// the lazy binding info is created later than this helper atom, so there
// is no Reference to update. Instead we blast the offset here.
uint32_t offset;
LittleEndian::set32(offset, fLazyPointerAtom.getLazyBindingInfoOffset());
memcpy(&buffer[1], &offset, 4);
}
template <>
FastStubHelperAtom<x86>::FastStubHelperAtom(Writer<x86>& writer, ObjectFile::Atom& target,
class LazyPointerAtom<x86>& lazyPointer, bool forLazyDylib)
: StubHelperAtom<x86>(writer, target, lazyPointer, forLazyDylib)
{
if ( fgHelperHelperAtom == NULL ) {
fgHelperHelperAtom = new FastStubHelperHelperAtom<x86>::FastStubHelperHelperAtom(fWriter);
fWriter.fAllSynthesizedStubHelpers.push_back(fgHelperHelperAtom);
}
fReferences.push_back(new WriterReference<x86>(6, x86::kPCRel32, fgHelperHelperAtom));
}
template <>
uint64_t FastStubHelperAtom<x86>::getSize() const
{
return 10;
}
template <>
void FastStubHelperAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0x68; // pushl $lazy-info-offset
buffer[1] = 0x00;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0xE9; // jmp helperhelper
buffer[6] = 0x00;
buffer[7] = 0x00;
buffer[8] = 0x00;
buffer[9] = 0x00;
// the lazy binding info is created later than this helper atom, so there
// is no Reference to update. Instead we blast the offset here.
uint32_t offset;
LittleEndian::set32(offset, fLazyPointerAtom.getLazyBindingInfoOffset());
memcpy(&buffer[1], &offset, 4);
}
template <typename A>
const char* LazyPointerAtom<A>::getSectionName() const
{
if ( fCloseStub )
return "__lazy_symbol";
else if ( fForLazyDylib )
return "__ld_symbol_ptr";
else
return "__la_symbol_ptr";
}
// specialize lazy pointer for x86_64 to initially pointer to stub helper
template <>
LazyPointerAtom<x86_64>::LazyPointerAtom(Writer<x86_64>& writer, ObjectFile::Atom& target, StubAtom<x86_64>& stub, bool forLazyDylib)
: WriterAtom<x86_64>(writer, Segment::fgDataSegment), fName(lazyPointerName(target.getName())), fTarget(target),
fExternalTarget(*stub.getTarget()), fForLazyDylib(forLazyDylib), fCloseStub(false), fLazyBindingOffset(0)
{
if ( forLazyDylib )
writer.fAllSynthesizedLazyDylibPointers.push_back(this);
else
writer.fAllSynthesizedLazyPointers.push_back(this);
ObjectFile::Atom* helper;
if ( writer.fOptions.makeCompressedDyldInfo() && !forLazyDylib ) {
if ( writer.fOptions.makeClassicDyldInfo() )
// hybrid LINKEDIT, no fast bind info for weak symbols so use traditional helper
if ( writer.targetRequiresWeakBinding(target) )
helper = new ClassicStubHelperAtom<x86_64>(writer, target, *this, forLazyDylib);
else
helper = new HybridStubHelperAtom<x86_64>(writer, target, *this, forLazyDylib);
else {
if ( target.getDefinitionKind() == ObjectFile::Atom::kWeakDefinition )
helper = ⌖
else
helper = new FastStubHelperAtom<x86_64>(writer, target, *this, forLazyDylib);
}
}
else {
helper = new ClassicStubHelperAtom<x86_64>(writer, target, *this, forLazyDylib);
}
fReferences.push_back(new WriterReference<x86_64>(0, x86_64::kPointer, helper));
}
// specialize lazy pointer for x86 to initially pointer to stub helper
template <>
LazyPointerAtom<x86>::LazyPointerAtom(Writer<x86>& writer, ObjectFile::Atom& target, StubAtom<x86>& stub, bool forLazyDylib)
: WriterAtom<x86>(writer, Segment::fgDataSegment), fName(lazyPointerName(target.getName())), fTarget(target),
fExternalTarget(*stub.getTarget()), fForLazyDylib(forLazyDylib), fCloseStub(false), fLazyBindingOffset(0)
{
if ( forLazyDylib )
writer.fAllSynthesizedLazyDylibPointers.push_back(this);
else
writer.fAllSynthesizedLazyPointers.push_back(this);
ObjectFile::Atom* helper;
if ( writer.fOptions.makeCompressedDyldInfo() && !forLazyDylib ) {
if ( writer.fOptions.makeClassicDyldInfo() ) {
// hybrid LINKEDIT, no fast bind info for weak symbols so use traditional helper
if ( writer.targetRequiresWeakBinding(target) )
helper = new ClassicStubHelperAtom<x86>(writer, target, *this, forLazyDylib);
else
helper = new HybridStubHelperAtom<x86>(writer, target, *this, forLazyDylib);
}
else {
if ( target.getDefinitionKind() == ObjectFile::Atom::kWeakDefinition )
helper = ⌖
else
helper = new FastStubHelperAtom<x86>(writer, target, *this, forLazyDylib);
}
}
else {
helper = new ClassicStubHelperAtom<x86>(writer, target, *this, forLazyDylib);
}
fReferences.push_back(new WriterReference<x86>(0, x86::kPointer, helper));
}
// specialize lazy pointer for arm to initially pointer to stub helper
template <>
LazyPointerAtom<arm>::LazyPointerAtom(Writer<arm>& writer, ObjectFile::Atom& target, StubAtom<arm>& stub, bool forLazyDylib)
: WriterAtom<arm>(writer, Segment::fgDataSegment), fName(lazyPointerName(target.getName())), fTarget(target),
fExternalTarget(*stub.getTarget()), fForLazyDylib(forLazyDylib), fCloseStub(false), fLazyBindingOffset(0)
{
if ( forLazyDylib )
writer.fAllSynthesizedLazyDylibPointers.push_back(this);
else
writer.fAllSynthesizedLazyPointers.push_back(this);
// The one instruction stubs must be close to the lazy pointers
if ( stub.fKind == StubAtom<arm>::kStubShort )
fCloseStub = true;
ObjectFile::Atom* helper;
if ( forLazyDylib ) {
if ( writer.fDyldLazyDylibHelper == NULL )
throw "symbol dyld_lazy_dylib_stub_binding_helper not defined (usually in lazydylib1.o)";
helper = writer.fDyldLazyDylibHelper;
}
else if ( writer.fOptions.makeCompressedDyldInfo() ) {
if ( target.getDefinitionKind() == ObjectFile::Atom::kWeakDefinition )
helper = ⌖
else
helper = new FastStubHelperAtom<arm>(writer, target, *this, forLazyDylib);
}
else {
if ( writer.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
helper = writer.fDyldClassicHelperAtom;
}
fReferences.push_back(new WriterReference<arm>(0, arm::kPointer, helper));
}
template <typename A>
LazyPointerAtom<A>::LazyPointerAtom(Writer<A>& writer, ObjectFile::Atom& target, StubAtom<A>& stub, bool forLazyDylib)
: WriterAtom<A>(writer, Segment::fgDataSegment), fName(lazyPointerName(target.getName())), fTarget(target),
fExternalTarget(*stub.getTarget()), fForLazyDylib(forLazyDylib), fCloseStub(false), fLazyBindingOffset(0)
{
if ( forLazyDylib )
writer.fAllSynthesizedLazyDylibPointers.push_back(this);
else
writer.fAllSynthesizedLazyPointers.push_back(this);
fReferences.push_back(new WriterReference<A>(0, A::kPointer, &target));
}
template <typename A>
const char* LazyPointerAtom<A>::lazyPointerName(const char* name)
{
char* buf;
asprintf(&buf, "%s$lazy_pointer", name);
return buf;
}
template <typename A>
void LazyPointerAtom<A>::copyRawContent(uint8_t buffer[]) const
{
bzero(buffer, getSize());
}
template <typename A>
NonLazyPointerAtom<A>::NonLazyPointerAtom(Writer<A>& writer, ObjectFile::Atom& target)
: WriterAtom<A>(writer, Segment::fgDataSegment), fName(nonlazyPointerName(target.getName())), fTarget(&target)
{
writer.fAllSynthesizedNonLazyPointers.push_back(this);
fReferences.push_back(new WriterReference<A>(0, A::kPointer, &target));
}
template <typename A>
NonLazyPointerAtom<A>::NonLazyPointerAtom(Writer<A>& writer)
: WriterAtom<A>(writer, Segment::fgDataSegment), fName("none"), fTarget(NULL)
{
writer.fAllSynthesizedNonLazyPointers.push_back(this);
}
template <typename A>
NonLazyPointerAtom<A>::NonLazyPointerAtom(Writer<A>& writer, const char* targetName)
: WriterAtom<A>(writer, Segment::fgDataSegment), fName(nonlazyPointerName(targetName)), fTarget(NULL)
{
writer.fAllSynthesizedNonLazyPointers.push_back(this);
fReferences.push_back(new WriterReference<A>(0, A::kPointer, targetName));
}
template <typename A>
const char* NonLazyPointerAtom<A>::nonlazyPointerName(const char* name)
{
char* buf;
asprintf(&buf, "%s$non_lazy_pointer", name);
return buf;
}
template <typename A>
void NonLazyPointerAtom<A>::copyRawContent(uint8_t buffer[]) const
{
bzero(buffer, getSize());
}
template <>
ObjectFile::Alignment StubAtom<ppc>::getAlignment() const
{
return 2;
}
template <>
ObjectFile::Alignment StubAtom<ppc64>::getAlignment() const
{
return 2;
}
template <>
ObjectFile::Alignment StubAtom<arm>::getAlignment() const
{
return 2;
}
template <>
StubAtom<ppc>::StubAtom(Writer<ppc>& writer, ObjectFile::Atom& target, bool forLazyDylib)
: WriterAtom<ppc>(writer, Segment::fgTextSegment), fName(stubName(target.getName())),
fTarget(target), fForLazyDylib(forLazyDylib)
{
writer.fAllSynthesizedStubs.push_back(this);
LazyPointerAtom<ppc>* lp;
if ( fWriter.fOptions.prebind() ) {
// for prebound ppc, lazy pointer starts out pointing to target symbol's address
// if target is a weak definition within this linkage unit or zero if in some dylib
lp = new LazyPointerAtom<ppc>(writer, target, *this, forLazyDylib);
}
else {
// for non-prebound ppc, lazy pointer starts out pointing to dyld_stub_binding_helper glue code
if ( forLazyDylib ) {
if ( writer.fDyldLazyDylibHelper == NULL )
throw "symbol dyld_lazy_dylib_stub_binding_helper not defined (usually in lazydylib1.o)";
lp = new LazyPointerAtom<ppc>(writer, *writer.fDyldLazyDylibHelper, *this, forLazyDylib);
}
else {
if ( writer.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
lp = new LazyPointerAtom<ppc>(writer, *writer.fDyldClassicHelperAtom, *this, forLazyDylib);
}
}
fKind = ( fWriter.fSlideable ? kStubPIC : kStubNoPIC );
if ( fKind == kStubPIC ) {
// picbase is 8 bytes into atom
fReferences.push_back(new WriterReference<ppc>(12, ppc::kPICBaseHigh16, lp, 0, this, 8));
fReferences.push_back(new WriterReference<ppc>(20, ppc::kPICBaseLow16, lp, 0, this, 8));
}
else {
fReferences.push_back(new WriterReference<ppc>(0, ppc::kAbsHigh16AddLow, lp));
fReferences.push_back(new WriterReference<ppc>(4, ppc::kAbsLow16, lp));
}
}
template <>
StubAtom<ppc64>::StubAtom(Writer<ppc64>& writer, ObjectFile::Atom& target, bool forLazyDylib)
: WriterAtom<ppc64>(writer, Segment::fgTextSegment), fName(stubName(target.getName())),
fTarget(target), fForLazyDylib(forLazyDylib)
{
writer.fAllSynthesizedStubs.push_back(this);
LazyPointerAtom<ppc64>* lp;
if ( forLazyDylib ) {
if ( writer.fDyldLazyDylibHelper == NULL )
throw "symbol dyld_lazy_dylib_stub_binding_helper not defined (usually in lazydylib1.o)";
lp = new LazyPointerAtom<ppc64>(writer, *writer.fDyldLazyDylibHelper, *this, forLazyDylib);
}
else {
if ( writer.fDyldClassicHelperAtom == NULL )
throw "symbol dyld_stub_binding_helper not defined (usually in crt1.o/dylib1.o/bundle1.o)";
lp = new LazyPointerAtom<ppc64>(writer, *writer.fDyldClassicHelperAtom, *this, forLazyDylib);
}
if ( fWriter.fSlideable || ((fWriter.fPageZeroAtom != NULL) && (fWriter.fPageZeroAtom->getSize() > 4096)) )
fKind = kStubPIC;
else
fKind = kStubNoPIC;
if ( fKind == kStubPIC ) {
// picbase is 8 bytes into atom
fReferences.push_back(new WriterReference<ppc64>(12, ppc64::kPICBaseHigh16, lp, 0, this, 8));
fReferences.push_back(new WriterReference<ppc64>(20, ppc64::kPICBaseLow14, lp, 0, this, 8));
}
else {
fReferences.push_back(new WriterReference<ppc64>(0, ppc64::kAbsHigh16AddLow, lp));
fReferences.push_back(new WriterReference<ppc64>(4, ppc64::kAbsLow14, lp));
}
}
template <>
StubAtom<x86>::StubAtom(Writer<x86>& writer, ObjectFile::Atom& target, bool forLazyDylib)
: WriterAtom<x86>(writer, (writer.fOptions.makeCompressedDyldInfo()|| forLazyDylib) ? Segment::fgTextSegment : Segment::fgImportSegment),
fName(NULL), fTarget(target), fForLazyDylib(forLazyDylib)
{
if ( writer.fOptions.makeCompressedDyldInfo() || forLazyDylib ) {
fKind = kStubNoPIC;
fName = stubName(target.getName());
LazyPointerAtom<x86>* lp = new LazyPointerAtom<x86>(writer, target, *this, forLazyDylib);
fReferences.push_back(new WriterReference<x86>(2, x86::kAbsolute32, lp));
writer.fAllSynthesizedStubs.push_back(this);
}
else {
fKind = kJumpTable;
if ( &target == NULL )
asprintf((char**)&fName, "cache-line-crossing-stub %p", this);
else {
fName = stubName(target.getName());
writer.fAllSynthesizedStubs.push_back(this);
}
}
}
template <>
StubAtom<x86_64>::StubAtom(Writer<x86_64>& writer, ObjectFile::Atom& target, bool forLazyDylib)
: WriterAtom<x86_64>(writer, Segment::fgTextSegment), fName(stubName(target.getName())), fTarget(target)
{
writer.fAllSynthesizedStubs.push_back(this);
LazyPointerAtom<x86_64>* lp = new LazyPointerAtom<x86_64>(writer, target, *this, forLazyDylib);
fReferences.push_back(new WriterReference<x86_64>(2, x86_64::kPCRel32, lp));
}
template <>
StubAtom<arm>::StubAtom(Writer<arm>& writer, ObjectFile::Atom& target, bool forLazyDylib)
: WriterAtom<arm>(writer, Segment::fgTextSegment), fName(stubName(target.getName())), fTarget(target)
{
writer.fAllSynthesizedStubs.push_back(this);
if ( (writer.fDylibSymbolCountUpperBound < 900)
&& writer.fOptions.makeCompressedDyldInfo()
&& (writer.fOptions.outputKind() != Options::kDynamicLibrary)
&& !forLazyDylib ) {
// dylibs might have __TEXT and __DATA pulled apart to live in shared region
// if > 1000 stubs, the displacement to the lazy pointer my be > 12 bits.
fKind = kStubShort;
}
else if ( fWriter.fSlideable ) {
fKind = kStubPIC;
}
else {
fKind = kStubNoPIC;
}
LazyPointerAtom<arm>* lp = new LazyPointerAtom<arm>(writer, target, *this, forLazyDylib);
switch ( fKind ) {
case kStubPIC:
fReferences.push_back(new WriterReference<arm>(12, arm::kPointerDiff, lp, 0, this, 12));
break;
case kStubNoPIC:
fReferences.push_back(new WriterReference<arm>(8, arm::kReadOnlyPointer, lp));
break;
case kStubShort:
fReferences.push_back(new WriterReference<arm>(0, arm::kPointerDiff12, lp, 0, this, 8));
break;
default:
throw "internal error";
}
}
template <typename A>
const char* StubAtom<A>::stubName(const char* name)
{
char* buf;
asprintf(&buf, "%s$stub", name);
return buf;
}
template <>
uint64_t StubAtom<ppc>::getSize() const
{
return ( (fKind == kStubPIC) ? 32 : 16 );
}
template <>
uint64_t StubAtom<ppc64>::getSize() const
{
return ( (fKind == kStubPIC) ? 32 : 16 );
}
template <>
uint64_t StubAtom<arm>::getSize() const
{
switch ( fKind ) {
case kStubPIC:
return 16;
case kStubNoPIC:
return 12;
case kStubShort:
return 4;
default:
throw "internal error";
}
}
template <>
uint64_t StubAtom<x86>::getSize() const
{
switch ( fKind ) {
case kStubNoPIC:
return 6;
case kJumpTable:
return 5;
default:
throw "internal error";
}
}
template <>
uint64_t StubAtom<x86_64>::getSize() const
{
return 6;
}
template <>
ObjectFile::Alignment StubAtom<x86>::getAlignment() const
{
switch ( fKind ) {
case kStubNoPIC:
return 1;
case kJumpTable:
return 0; // special case x86 self-modifying stubs to be byte aligned
default:
throw "internal error";
}
}
template <>
void StubAtom<ppc64>::copyRawContent(uint8_t buffer[]) const
{
if ( fKind == kStubPIC ) {
OSWriteBigInt32(&buffer [0], 0, 0x7c0802a6); // mflr r0
OSWriteBigInt32(&buffer[ 4], 0, 0x429f0005); // bcl 20,31,Lpicbase
OSWriteBigInt32(&buffer[ 8], 0, 0x7d6802a6); // Lpicbase: mflr r11
OSWriteBigInt32(&buffer[12], 0, 0x3d6b0000); // addis r11,r11,ha16(L_fwrite$lazy_ptr-Lpicbase)
OSWriteBigInt32(&buffer[16], 0, 0x7c0803a6); // mtlr r0
OSWriteBigInt32(&buffer[20], 0, 0xe98b0001); // ldu r12,lo16(L_fwrite$lazy_ptr-Lpicbase)(r11)
OSWriteBigInt32(&buffer[24], 0, 0x7d8903a6); // mtctr r12
OSWriteBigInt32(&buffer[28], 0, 0x4e800420); // bctr
}
else {
OSWriteBigInt32(&buffer[ 0], 0, 0x3d600000); // lis r11,ha16(L_fwrite$lazy_ptr)
OSWriteBigInt32(&buffer[ 4], 0, 0xe98b0001); // ldu r12,lo16(L_fwrite$lazy_ptr)(r11)
OSWriteBigInt32(&buffer[ 8], 0, 0x7d8903a6); // mtctr r12
OSWriteBigInt32(&buffer[12], 0, 0x4e800420); // bctr
}
}
template <>
void StubAtom<ppc>::copyRawContent(uint8_t buffer[]) const
{
if ( fKind == kStubPIC ) {
OSWriteBigInt32(&buffer[ 0], 0, 0x7c0802a6); // mflr r0
OSWriteBigInt32(&buffer[ 4], 0, 0x429f0005); // bcl 20,31,Lpicbase
OSWriteBigInt32(&buffer[ 8], 0, 0x7d6802a6); // Lpicbase: mflr r11
OSWriteBigInt32(&buffer[12], 0, 0x3d6b0000); // addis r11,r11,ha16(L_fwrite$lazy_ptr-Lpicbase)
OSWriteBigInt32(&buffer[16], 0, 0x7c0803a6); // mtlr r0
OSWriteBigInt32(&buffer[20], 0, 0x858b0000); // lwzu r12,lo16(L_fwrite$lazy_ptr-Lpicbase)(r11)
OSWriteBigInt32(&buffer[24], 0, 0x7d8903a6); // mtctr r12
OSWriteBigInt32(&buffer[28], 0, 0x4e800420); // bctr
}
else {
OSWriteBigInt32(&buffer[ 0], 0, 0x3d600000); // lis r11,ha16(L_fwrite$lazy_ptr)
OSWriteBigInt32(&buffer[ 4], 0, 0x858b0000); // lwzu r12,lo16(L_fwrite$lazy_ptr)(r11)
OSWriteBigInt32(&buffer[ 8], 0, 0x7d8903a6); // mtctr r12
OSWriteBigInt32(&buffer[12], 0, 0x4e800420); // bctr
}
}
template <>
void StubAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
switch ( fKind ) {
case kStubNoPIC:
buffer[0] = 0xFF; // jmp *foo$lazy_pointer
buffer[1] = 0x25;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
break;
case kJumpTable:
if ( fWriter.fOptions.prebind() ) {
uint32_t address = this->getAddress();
int32_t rel32 = 0 - (address+5);
buffer[0] = 0xE9;
buffer[1] = rel32 & 0xFF;
buffer[2] = (rel32 >> 8) & 0xFF;
buffer[3] = (rel32 >> 16) & 0xFF;
buffer[4] = (rel32 >> 24) & 0xFF;
}
else {
buffer[0] = 0xF4;
buffer[1] = 0xF4;
buffer[2] = 0xF4;
buffer[3] = 0xF4;
buffer[4] = 0xF4;
}
break;
default:
throw "internal error";
}
}
template <>
void StubAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
buffer[0] = 0xFF; // jmp *foo$lazy_pointer(%rip)
buffer[1] = 0x25;
buffer[2] = 0x00;
buffer[3] = 0x00;
buffer[4] = 0x00;
buffer[5] = 0x00;
}
template <>
void StubAtom<arm>::copyRawContent(uint8_t buffer[]) const
{
switch ( fKind ) {
case kStubPIC:
OSWriteLittleInt32(&buffer[ 0], 0, 0xe59fc004); // ldr ip, pc + 12
OSWriteLittleInt32(&buffer[ 4], 0, 0xe08fc00c); // add ip, pc, ip
OSWriteLittleInt32(&buffer[ 8], 0, 0xe59cf000); // ldr pc, [ip]
OSWriteLittleInt32(&buffer[12], 0, 0x00000000); // .long L_foo$lazy_ptr - (L1$scv + 8)
break;
case kStubNoPIC:
OSWriteLittleInt32(&buffer[ 0], 0, 0xe59fc000); // ldr ip, [pc, #0]
OSWriteLittleInt32(&buffer[ 4], 0, 0xe59cf000); // ldr pc, [ip]
OSWriteLittleInt32(&buffer[ 8], 0, 0x00000000); // .long L_foo$lazy_ptr
break;
case kStubShort:
OSWriteLittleInt32(&buffer[ 0], 0, 0xE59FF000);// ldr pc, [pc, #foo$lazy_ptr]
break;
default:
throw "internal error";
}
}
// x86_64 stubs are 6 bytes
template <>
ObjectFile::Alignment StubAtom<x86_64>::getAlignment() const
{
return 1;
}
template <>
const char* StubAtom<ppc>::getSectionName() const
{
return ( (fKind == kStubPIC) ? "__picsymbolstub1" : "__symbol_stub1");
}
template <>
const char* StubAtom<ppc64>::getSectionName() const
{
return ( (fKind == kStubPIC) ? "__picsymbolstub1" : "__symbol_stub1");
}
template <>
const char* StubAtom<arm>::getSectionName() const
{
switch ( fKind ) {
case kStubPIC:
return "__picsymbolstub4";
case kStubNoPIC:
return "__symbol_stub4";
case kStubShort:
return "__symbolstub1";
default:
throw "internal error";
}
}
template <>
const char* StubAtom<x86>::getSectionName() const
{
switch ( fKind ) {
case kStubNoPIC:
return "__symbol_stub";
case kJumpTable:
return "__jump_table";
default:
throw "internal error";
}
}
struct AtomByNameSorter
{
bool operator()(ObjectFile::Atom* left, ObjectFile::Atom* right)
{
return (strcmp(left->getName(), right->getName()) < 0);
}
};
template <typename P>
struct ExternalRelocSorter
{
bool operator()(const macho_relocation_info<P>& left, const macho_relocation_info<P>& right)
{
// sort first by symbol number
if ( left.r_symbolnum() != right.r_symbolnum() )
return (left.r_symbolnum() < right.r_symbolnum());
// then sort all uses of the same symbol by address
return (left.r_address() < right.r_address());
}
};
template <typename A>
Writer<A>::Writer(const char* path, Options& options, std::vector<ExecutableFile::DyLibUsed>& dynamicLibraries)
: ExecutableFile::Writer(dynamicLibraries), fFilePath(strdup(path)), fOptions(options),
fAllAtoms(NULL), fStabs(NULL), fRegularDefAtomsThatOverrideADylibsWeakDef(NULL), fLoadCommandsSection(NULL),
fLoadCommandsSegment(NULL), fMachHeaderAtom(NULL), fEncryptionLoadCommand(NULL), fSegmentCommands(NULL),
fSymbolTableCommands(NULL), fHeaderPadding(NULL), fUnwindInfoAtom(NULL),
fUUIDAtom(NULL), fPadSegmentInfo(NULL), fEntryPoint( NULL),
fDyldClassicHelperAtom(NULL), fDyldCompressedHelperAtom(NULL), fDyldLazyDylibHelper(NULL),
fSectionRelocationsAtom(NULL), fCompressedRebaseInfoAtom(NULL), fCompressedBindingInfoAtom(NULL),
fCompressedWeakBindingInfoAtom(NULL), fCompressedLazyBindingInfoAtom(NULL), fCompressedExportInfoAtom(NULL),
fLocalRelocationsAtom(NULL), fExternalRelocationsAtom(NULL),
fSymbolTableAtom(NULL), fSplitCodeToDataContentAtom(NULL), fIndirectTableAtom(NULL), fModuleInfoAtom(NULL),
fStringsAtom(NULL), fPageZeroAtom(NULL), fFastStubGOTAtom(NULL), fSymbolTable(NULL), fSymbolTableCount(0),
fSymbolTableStabsCount(0), fSymbolTableLocalCount(0), fSymbolTableExportCount(0), fSymbolTableImportCount(0),
fLargestAtomSize(1),
fEmitVirtualSections(false), fHasWeakExports(false), fReferencesWeakImports(false),
fCanScatter(false), fWritableSegmentPastFirst4GB(false), fNoReExportedDylibs(false),
fBiggerThanTwoGigs(false), fSlideable(false), fHasThumbBranches(false),
fFirstWritableSegment(NULL), fAnonNameIndex(1000)
{
switch ( fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kStaticExecutable:
if ( fOptions.zeroPageSize() != 0 )
fWriterSynthesizedAtoms.push_back(fPageZeroAtom = new PageZeroAtom<A>(*this));
if ( fOptions.outputKind() == Options::kDynamicExecutable )
fWriterSynthesizedAtoms.push_back(new DsoHandleAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fMachHeaderAtom = new MachHeaderAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SegmentLoadCommandsAtom<A>(*this));
if ( fOptions.makeCompressedDyldInfo() )
fWriterSynthesizedAtoms.push_back(new DyldInfoLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SymbolTableLoadCommandsAtom<A>(*this));
if ( fOptions.outputKind() == Options::kDynamicExecutable )
fWriterSynthesizedAtoms.push_back(new DyldLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fUUIDAtom = new UUIDLoadCommandAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new ThreadsLoadCommandsAtom<A>(*this));
if ( fOptions.hasCustomStack() )
fWriterSynthesizedAtoms.push_back(new CustomStackAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fHeaderPadding = new LoadCommandsPaddingAtom<A>(*this));
if ( fOptions.needsUnwindInfoSection() )
fWriterSynthesizedAtoms.push_back(fUnwindInfoAtom = new UnwindInfoAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSectionRelocationsAtom = new SectionRelocationsLinkEditAtom<A>(*this));
if ( fOptions.makeCompressedDyldInfo() ) {
fWriterSynthesizedAtoms.push_back(fCompressedRebaseInfoAtom = new CompressedRebaseInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedBindingInfoAtom = new CompressedBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedWeakBindingInfoAtom = new CompressedWeakBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedLazyBindingInfoAtom = new CompressedLazyBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedExportInfoAtom = new CompressedExportInfoLinkEditAtom<A>(*this));
}
if ( fOptions.makeClassicDyldInfo() )
fWriterSynthesizedAtoms.push_back(fLocalRelocationsAtom = new LocalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSymbolTableAtom = new SymbolTableLinkEditAtom<A>(*this));
if ( fOptions.makeClassicDyldInfo() )
fWriterSynthesizedAtoms.push_back(fExternalRelocationsAtom = new ExternalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fIndirectTableAtom = new IndirectTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fStringsAtom = new StringsLinkEditAtom<A>(*this));
break;
case Options::kPreload:
fWriterSynthesizedAtoms.push_back(fMachHeaderAtom = new MachHeaderAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SegmentLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SymbolTableLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fUUIDAtom = new UUIDLoadCommandAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new ThreadsLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fHeaderPadding = new LoadCommandsPaddingAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSectionRelocationsAtom = new SectionRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fLocalRelocationsAtom = new LocalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fExternalRelocationsAtom = new ExternalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fIndirectTableAtom = new IndirectTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSymbolTableAtom = new SymbolTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fStringsAtom = new StringsLinkEditAtom<A>(*this));
break;
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
fWriterSynthesizedAtoms.push_back(new DsoHandleAtom<A>(*this));
case Options::kKextBundle:
fWriterSynthesizedAtoms.push_back(fMachHeaderAtom = new MachHeaderAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SegmentLoadCommandsAtom<A>(*this));
if ( fOptions.outputKind() == Options::kDynamicLibrary ) {
fWriterSynthesizedAtoms.push_back(new DylibIDLoadCommandsAtom<A>(*this));
if ( fOptions.initFunctionName() != NULL )
fWriterSynthesizedAtoms.push_back(new RoutinesLoadCommandsAtom<A>(*this));
}
fWriterSynthesizedAtoms.push_back(fUUIDAtom = new UUIDLoadCommandAtom<A>(*this));
if ( fOptions.makeCompressedDyldInfo() )
fWriterSynthesizedAtoms.push_back(new DyldInfoLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SymbolTableLoadCommandsAtom<A>(*this));
if ( fOptions.sharedRegionEligible() )
fWriterSynthesizedAtoms.push_back(new SegmentSplitInfoLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fHeaderPadding = new LoadCommandsPaddingAtom<A>(*this));
if ( fOptions.needsUnwindInfoSection() )
fWriterSynthesizedAtoms.push_back(fUnwindInfoAtom = new UnwindInfoAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSectionRelocationsAtom = new SectionRelocationsLinkEditAtom<A>(*this));
if ( fOptions.makeCompressedDyldInfo() ) {
fWriterSynthesizedAtoms.push_back(fCompressedRebaseInfoAtom = new CompressedRebaseInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedBindingInfoAtom = new CompressedBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedWeakBindingInfoAtom = new CompressedWeakBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedLazyBindingInfoAtom = new CompressedLazyBindingInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fCompressedExportInfoAtom = new CompressedExportInfoLinkEditAtom<A>(*this));
}
if ( fOptions.makeClassicDyldInfo() )
fWriterSynthesizedAtoms.push_back(fLocalRelocationsAtom = new LocalRelocationsLinkEditAtom<A>(*this));
if ( fOptions.sharedRegionEligible() ) {
fWriterSynthesizedAtoms.push_back(fSplitCodeToDataContentAtom = new SegmentSplitInfoContentAtom<A>(*this));
}
fWriterSynthesizedAtoms.push_back(fSymbolTableAtom = new SymbolTableLinkEditAtom<A>(*this));
if ( fOptions.makeClassicDyldInfo() )
fWriterSynthesizedAtoms.push_back(fExternalRelocationsAtom = new ExternalRelocationsLinkEditAtom<A>(*this));
if ( fOptions.outputKind() != Options::kKextBundle )
fWriterSynthesizedAtoms.push_back(fIndirectTableAtom = new IndirectTableLinkEditAtom<A>(*this));
if ( this->needsModuleTable() )
fWriterSynthesizedAtoms.push_back(fModuleInfoAtom = new ModuleInfoLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fStringsAtom = new StringsLinkEditAtom<A>(*this));
break;
case Options::kObjectFile:
fWriterSynthesizedAtoms.push_back(fMachHeaderAtom = new MachHeaderAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SegmentLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fUUIDAtom = new UUIDLoadCommandAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SymbolTableLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fHeaderPadding = new LoadCommandsPaddingAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSectionRelocationsAtom = new SectionRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fLocalRelocationsAtom = new LocalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSymbolTableAtom = new SymbolTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fExternalRelocationsAtom = new ExternalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fIndirectTableAtom = new IndirectTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fStringsAtom = new StringsLinkEditAtom<A>(*this));
break;
case Options::kDyld:
fWriterSynthesizedAtoms.push_back(new DsoHandleAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fMachHeaderAtom = new MachHeaderAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SegmentLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new SymbolTableLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new DyldLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fUUIDAtom = new UUIDLoadCommandAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(new ThreadsLoadCommandsAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fHeaderPadding = new LoadCommandsPaddingAtom<A>(*this));
if ( fOptions.needsUnwindInfoSection() )
fWriterSynthesizedAtoms.push_back(fUnwindInfoAtom = new UnwindInfoAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fLocalRelocationsAtom = new LocalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fSymbolTableAtom = new SymbolTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fExternalRelocationsAtom = new ExternalRelocationsLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fIndirectTableAtom = new IndirectTableLinkEditAtom<A>(*this));
fWriterSynthesizedAtoms.push_back(fStringsAtom = new StringsLinkEditAtom<A>(*this));
break;
}
// add extra commmands
bool hasReExports = false;
uint32_t ordinal = 1;
switch ( fOptions.outputKind() ) {
case Options::kDynamicExecutable:
if ( fOptions.makeEncryptable() ) {
fEncryptionLoadCommand = new EncryptionLoadCommandsAtom<A>(*this);
fWriterSynthesizedAtoms.push_back(fEncryptionLoadCommand);
}
// fall through
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
{
// add dylib load command atoms for all dynamic libraries
const unsigned int libCount = dynamicLibraries.size();
for (unsigned int i=0; i < libCount; ++i) {
ExecutableFile::DyLibUsed& dylibInfo = dynamicLibraries[i];
//fprintf(stderr, "dynamicLibraries[%d]: reader=%p, %s, install=%s\n", i, dylibInfo.reader, dylibInfo.reader->getPath(), dylibInfo.reader->getInstallPath() );
if ( dylibInfo.options.fReExport ) {
hasReExports = true;
}
else {
const char* parentUmbrella = dylibInfo.reader->parentUmbrella();
if ( (parentUmbrella != NULL) && (fOptions.outputKind() == Options::kDynamicLibrary) ) {
const char* thisIDLastSlash = strrchr(fOptions.installPath(), '/');
if ( (thisIDLastSlash != NULL) && (strcmp(&thisIDLastSlash[1], parentUmbrella) == 0) )
hasReExports = true;
}
}
if ( dylibInfo.options.fWeakImport ) {
fForcedWeakImportReaders.insert(dylibInfo.reader);
}
if ( dylibInfo.options.fBundleLoader ) {
fLibraryToOrdinal[dylibInfo.reader] = EXECUTABLE_ORDINAL;
}
else {
// see if a DylibLoadCommandsAtom has already been created for this install path
bool newDylib = true;
const char* dylibInstallPath = dylibInfo.reader->getInstallPath();
for (unsigned int seenLib=0; seenLib < i; ++seenLib) {
ExecutableFile::DyLibUsed& seenDylibInfo = dynamicLibraries[seenLib];
if ( !seenDylibInfo.options.fBundleLoader ) {
const char* seenDylibInstallPath = seenDylibInfo.reader->getInstallPath();
if ( strcmp(seenDylibInstallPath, dylibInstallPath) == 0 ) {
fLibraryToOrdinal[dylibInfo.reader] = fLibraryToOrdinal[seenDylibInfo.reader];
fLibraryToLoadCommand[dylibInfo.reader] = fLibraryToLoadCommand[seenDylibInfo.reader];
fLibraryAliases[dylibInfo.reader] = seenDylibInfo.reader;
newDylib = false;
break;
}
}
}
if ( newDylib ) {
// assign new ordinal and check for other paired load commands
fLibraryToOrdinal[dylibInfo.reader] = ordinal++;
DylibLoadCommandsAtom<A>* dyliblc = new DylibLoadCommandsAtom<A>(*this, dylibInfo);
fLibraryToLoadCommand[dylibInfo.reader] = dyliblc;
fWriterSynthesizedAtoms.push_back(dyliblc);
if ( dylibInfo.options.fReExport
&& !fOptions.useSimplifiedDylibReExports()
&& (fOptions.outputKind() == Options::kDynamicLibrary) ) {
// see if child has sub-framework that is this
bool isSubFramework = false;
const char* childInUmbrella = dylibInfo.reader->parentUmbrella();
if ( childInUmbrella != NULL ) {
const char* myLeaf = strrchr(fOptions.installPath(), '/');
if ( myLeaf != NULL ) {
if ( strcmp(childInUmbrella, &myLeaf[1]) == 0 )
isSubFramework = true;
}
}
// LC_SUB_FRAMEWORK is in child, so do nothing in parent
if ( ! isSubFramework ) {
// this dylib also needs a sub_x load command
bool isFrameworkReExport = false;
const char* lastSlash = strrchr(dylibInstallPath, '/');
if ( lastSlash != NULL ) {
char frameworkName[strlen(lastSlash)+20];
sprintf(frameworkName, "/%s.framework/", &lastSlash[1]);
isFrameworkReExport = (strstr(dylibInstallPath, frameworkName) != NULL);
}
if ( isFrameworkReExport ) {
// needs a LC_SUB_UMBRELLA command
fWriterSynthesizedAtoms.push_back(new SubUmbrellaLoadCommandsAtom<A>(*this, &lastSlash[1]));
}
else {
// needs a LC_SUB_LIBRARY command
const char* nameStart = &lastSlash[1];
if ( lastSlash == NULL )
nameStart = dylibInstallPath;
int len = strlen(nameStart);
const char* dot = strchr(nameStart, '.');
if ( dot != NULL )
len = dot - nameStart;
fWriterSynthesizedAtoms.push_back(new SubLibraryLoadCommandsAtom<A>(*this, nameStart, len));
}
}
}
}
}
}
// add umbrella command if needed
if ( fOptions.umbrellaName() != NULL ) {
fWriterSynthesizedAtoms.push_back(new UmbrellaLoadCommandsAtom<A>(*this, fOptions.umbrellaName()));
}
// add allowable client commands if used
std::vector<const char*>& allowableClients = fOptions.allowableClients();
for (std::vector<const char*>::iterator it=allowableClients.begin(); it != allowableClients.end(); ++it)
fWriterSynthesizedAtoms.push_back(new AllowableClientLoadCommandsAtom<A>(*this, *it));
}
break;
case Options::kStaticExecutable:
case Options::kObjectFile:
case Options::kDyld:
case Options::kPreload:
case Options::kKextBundle:
break;
}
fNoReExportedDylibs = !hasReExports;
// add any rpath load commands
for(std::vector<const char*>::const_iterator it=fOptions.rpaths().begin(); it != fOptions.rpaths().end(); ++it) {
fWriterSynthesizedAtoms.push_back(new RPathLoadCommandsAtom<A>(*this, *it));
}
// set up fSlideable
switch ( fOptions.outputKind() ) {
case Options::kObjectFile:
case Options::kStaticExecutable:
fSlideable = false;
break;
case Options::kDynamicExecutable:
fSlideable = fOptions.positionIndependentExecutable();
break;
case Options::kDyld:
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kPreload:
case Options::kKextBundle:
fSlideable = true;
break;
}
//fprintf(stderr, "ordinals table:\n");
//for (std::map<class ObjectFile::Reader*, uint32_t>::iterator it = fLibraryToOrdinal.begin(); it != fLibraryToOrdinal.end(); ++it) {
// fprintf(stderr, "%d <== %s\n", it->second, it->first->getPath());
//}
}
template <typename A>
Writer<A>::~Writer()
{
if ( fFilePath != NULL )
free((void*)fFilePath);
if ( fSymbolTable != NULL )
delete [] fSymbolTable;
}
// for ppc64, -mdynamic-no-pic only works in low 2GB, so we might need to split the zeropage into two segments
template <>bool Writer<ppc64>::mightNeedPadSegment() { return (fOptions.zeroPageSize() >= 0x80000000ULL); }
template <typename A> bool Writer<A>::mightNeedPadSegment() { return false; }
template <typename A>
ObjectFile::Atom* Writer<A>::getUndefinedProxyAtom(const char* name)
{
if ( fOptions.outputKind() == Options::kKextBundle ) {
return new UndefinedSymbolProxyAtom<A>(*this, name);
}
else if ( fOptions.outputKind() == Options::kObjectFile ) {
// when doing -r -exported_symbols_list, don't create proxy for a symbol
// that is supposed to be exported. We want an error instead
// <rdar://problem/5062685> ld does not report error when -r is used and exported symbols are not defined.
if ( fOptions.hasExportMaskList() && fOptions.shouldExport(name) )
return NULL;
else
return new UndefinedSymbolProxyAtom<A>(*this, name);
}
else if ( (fOptions.undefinedTreatment() != Options::kUndefinedError) || fOptions.allowedUndefined(name) )
return new UndefinedSymbolProxyAtom<A>(*this, name);
else
return NULL;
}
template <typename A>
uint8_t Writer<A>::ordinalForLibrary(ObjectFile::Reader* lib)
{
// flat namespace images use zero for all ordinals
if ( fOptions.nameSpace() != Options::kTwoLevelNameSpace )
return 0;
// is an UndefinedSymbolProxyAtom
if ( lib == this )
if ( fOptions.nameSpace() == Options::kTwoLevelNameSpace )
return DYNAMIC_LOOKUP_ORDINAL;
std::map<class ObjectFile::Reader*, uint32_t>::iterator pos = fLibraryToOrdinal.find(lib);
if ( pos != fLibraryToOrdinal.end() )
return pos->second;
throw "can't find ordinal for imported symbol";
}
template <typename A>
bool Writer<A>::targetRequiresWeakBinding(const ObjectFile::Atom& target)
{
switch ( target.getDefinitionKind() ) {
case ObjectFile::Atom::kExternalWeakDefinition:
case ObjectFile::Atom::kWeakDefinition:
return true;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kTentativeDefinition:
break;
}
return false;
}
template <typename A>
int Writer<A>::compressedOrdinalForImortedAtom(ObjectFile::Atom* target)
{
// flat namespace images use zero for all ordinals
if ( fOptions.nameSpace() != Options::kTwoLevelNameSpace )
return BIND_SPECIAL_DYLIB_FLAT_LOOKUP;
// is an UndefinedSymbolProxyAtom
ObjectFile::Reader* lib = target->getFile();
if ( lib == this )
if ( fOptions.nameSpace() == Options::kTwoLevelNameSpace )
return BIND_SPECIAL_DYLIB_FLAT_LOOKUP;
std::map<class ObjectFile::Reader*, uint32_t>::iterator pos;
switch ( target->getDefinitionKind() ) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
pos = fLibraryToOrdinal.find(lib);
if ( pos != fLibraryToOrdinal.end() ) {
if ( pos->second == EXECUTABLE_ORDINAL )
return BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE;
else
return pos->second;
}
break;
case ObjectFile::Atom::kWeakDefinition:
throw "compressedOrdinalForImortedAtom() should not have been called on a weak definition";
case ObjectFile::Atom::kAbsoluteSymbol:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kTentativeDefinition:
return BIND_SPECIAL_DYLIB_SELF;
}
throw "can't find ordinal for imported symbol";
}
template <typename A>
ObjectFile::Atom& Writer<A>::makeObjcInfoAtom(ObjectFile::Reader::ObjcConstraint objcContraint, bool objcReplacementClasses)
{
return *(new ObjCInfoAtom<A>(*this, objcContraint, objcReplacementClasses));
}
template <typename A>
void Writer<A>::addSynthesizedAtoms(const std::vector<class ObjectFile::Atom*>& existingAtoms,
class ObjectFile::Atom* dyldClassicHelperAtom,
class ObjectFile::Atom* dyldCompressedHelperAtom,
class ObjectFile::Atom* dyldLazyDylibHelperAtom,
bool biggerThanTwoGigs,
uint32_t dylibSymbolCount,
std::vector<class ObjectFile::Atom*>& newAtoms)
{
fDyldClassicHelperAtom = dyldClassicHelperAtom;
fDyldCompressedHelperAtom = dyldCompressedHelperAtom;
fDyldLazyDylibHelper = dyldLazyDylibHelperAtom;
fBiggerThanTwoGigs = biggerThanTwoGigs;
fDylibSymbolCountUpperBound = dylibSymbolCount;
// create inter-library stubs
synthesizeStubs(existingAtoms, newAtoms);
}
template <typename A>
uint64_t Writer<A>::write(std::vector<class ObjectFile::Atom*>& atoms,
std::vector<class ObjectFile::Reader::Stab>& stabs,
class ObjectFile::Atom* entryPointAtom,
bool createUUID, bool canScatter, ObjectFile::Reader::CpuConstraint cpuConstraint,
std::set<const class ObjectFile::Atom*>& atomsThatOverrideWeak,
bool hasExternalWeakDefinitions)
{
fAllAtoms = &atoms;
fStabs = &stabs;
fEntryPoint = entryPointAtom;
fCanScatter = canScatter;
fCpuConstraint = cpuConstraint;
fHasWeakExports = hasExternalWeakDefinitions; // dyld needs to search this image as if it had weak exports
fRegularDefAtomsThatOverrideADylibsWeakDef = &atomsThatOverrideWeak;
try {
// Set for create UUID
if (createUUID)
fUUIDAtom->generate();
// remove uneeded dylib load commands
optimizeDylibReferences();
// check for mdynamic-no-pic codegen
scanForAbsoluteReferences();
// create table of unwind info
synthesizeUnwindInfoTable();
// create SegmentInfo and SectionInfo objects and assign all atoms to a section
partitionIntoSections();
// segment load command can now be sized and padding can be set
adjustLoadCommandsAndPadding();
// assign each section a file offset
assignFileOffsets();
// if need to add branch islands, reassign file offsets
if ( addBranchIslands() )
assignFileOffsets();
// now that addresses are assigned, create unwind info
if ( fUnwindInfoAtom != NULL ) {
fUnwindInfoAtom->generate();
// re-layout
adjustLoadCommandsAndPadding();
assignFileOffsets();
}
// make spit-seg info now that all atoms exist
createSplitSegContent();
// build symbol table and relocations
buildLinkEdit();
// write map file if requested
writeMap();
// write everything
return writeAtoms();
} catch (...) {
// clean up if any errors
(void)unlink(fFilePath);
throw;
}
}
template <typename A>
void Writer<A>::buildLinkEdit()
{
this->collectExportedAndImportedAndLocalAtoms();
this->buildSymbolTable();
this->buildFixups();
this->adjustLinkEditSections();
}
template <typename A>
uint64_t Writer<A>::getAtomLoadAddress(const ObjectFile::Atom* atom)
{
return atom->getAddress();
// SectionInfo* info = (SectionInfo*)atom->getSection();
// return info->getBaseAddress() + atom->getSectionOffset();
}
template <>
bool Writer<x86_64>::stringsNeedLabelsInObjects()
{
return true;
}
template <typename A>
bool Writer<A>::stringsNeedLabelsInObjects()
{
return false;
}
template <typename A>
const char* Writer<A>::symbolTableName(const ObjectFile::Atom* atom)
{
static unsigned int counter = 0;
const char* name;
if ( stringsNeedLabelsInObjects()
&& (atom->getContentType() == ObjectFile::Atom::kCStringType)
&& (atom->getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) )
asprintf((char**)&name, "LC%u", counter++);
else
name = atom->getName();
return name;
return atom->getName();
}
template <typename A>
void Writer<A>::setExportNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry)
{
// set n_strx
entry->set_n_strx(this->fStringsAtom->add(this->symbolTableName(atom)));
// set n_type
if ( atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableInAsAbsolute ) {
entry->set_n_type(N_EXT | N_ABS);
}
else {
entry->set_n_type(N_EXT | N_SECT);
if ( (atom->getScope() == ObjectFile::Atom::scopeLinkageUnit) && (fOptions.outputKind() == Options::kObjectFile) ) {
if ( fOptions.keepPrivateExterns() )
entry->set_n_type(N_EXT | N_SECT | N_PEXT);
}
}
// set n_sect (section number of implementation )
uint8_t sectionIndex = atom->getSection()->getIndex();
entry->set_n_sect(sectionIndex);
// the __mh_execute_header is magic and must be an absolute symbol
if ( (sectionIndex==0)
&& (fOptions.outputKind() == Options::kDynamicExecutable)
&& (atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableInAndNeverStrip ))
entry->set_n_type(N_EXT | N_ABS);
// set n_desc
uint16_t desc = 0;
if ( atom->isThumb() )
desc |= N_ARM_THUMB_DEF;
if ( atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableInAndNeverStrip )
desc |= REFERENCED_DYNAMICALLY;
if ( atom->dontDeadStrip() && (fOptions.outputKind() == Options::kObjectFile) )
desc |= N_NO_DEAD_STRIP;
if ( atom->getDefinitionKind() == ObjectFile::Atom::kWeakDefinition ) {
desc |= N_WEAK_DEF;
fHasWeakExports = true;
}
entry->set_n_desc(desc);
// set n_value ( address this symbol will be at if this executable is loaded at it preferred address )
if ( atom->getDefinitionKind() == ObjectFile::Atom::kAbsoluteSymbol )
entry->set_n_value(atom->getSectionOffset());
else
entry->set_n_value(this->getAtomLoadAddress(atom));
}
template <typename A>
void Writer<A>::setImportNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry)
{
// set n_strx
entry->set_n_strx(this->fStringsAtom->add(atom->getName()));
// set n_type
if ( fOptions.outputKind() == Options::kObjectFile ) {
if ( (atom->getScope() == ObjectFile::Atom::scopeLinkageUnit)
&& (atom->getDefinitionKind() == ObjectFile::Atom::kTentativeDefinition) )
entry->set_n_type(N_UNDF | N_EXT | N_PEXT);
else
entry->set_n_type(N_UNDF | N_EXT);
}
else {
if ( fOptions.prebind() )
entry->set_n_type(N_PBUD | N_EXT);
else
entry->set_n_type(N_UNDF | N_EXT);
}
// set n_sect
entry->set_n_sect(0);
uint16_t desc = 0;
if ( fOptions.outputKind() != Options::kObjectFile ) {
// set n_desc ( high byte is library ordinal, low byte is reference type )
std::map<const ObjectFile::Atom*,ObjectFile::Atom*>::iterator pos = fStubsMap.find(atom);
if ( pos != fStubsMap.end() || ( strncmp(atom->getName(), ".objc_class_name_", 17) == 0) )
desc = REFERENCE_FLAG_UNDEFINED_LAZY;
else
desc = REFERENCE_FLAG_UNDEFINED_NON_LAZY;
try {
uint8_t ordinal = this->ordinalForLibrary(atom->getFile());
//fprintf(stderr, "ordinal=%u from reader=%p for symbol=%s\n", ordinal, atom->getFile(), atom->getName());
SET_LIBRARY_ORDINAL(desc, ordinal);
}
catch (const char* msg) {
throwf("%s %s from %s", msg, atom->getDisplayName(), atom->getFile()->getPath());
}
}
else if ( atom->getDefinitionKind() == ObjectFile::Atom::kTentativeDefinition ) {
uint8_t align = atom->getAlignment().powerOf2;
// always record custom alignment of common symbols to match what compiler does
SET_COMM_ALIGN(desc, align);
}
if ( atom->isThumb() )
desc |= N_ARM_THUMB_DEF;
if ( atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableInAndNeverStrip )
desc |= REFERENCED_DYNAMICALLY;
if ( ( fOptions.outputKind() != Options::kObjectFile) && (atom->getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition) ) {
desc |= N_REF_TO_WEAK;
fReferencesWeakImports = true;
}
// set weak_import attribute
if ( fWeakImportMap[atom] )
desc |= N_WEAK_REF;
entry->set_n_desc(desc);
// set n_value, zero for import proxy and size for tentative definition
entry->set_n_value(atom->getSize());
}
template <typename A>
void Writer<A>::setLocalNlist(const ObjectFile::Atom* atom, macho_nlist<P>* entry)
{
// set n_strx
const char* symbolName = this->symbolTableName(atom);
char anonName[32];
if ( (fOptions.outputKind() == Options::kObjectFile) && !fOptions.keepLocalSymbol(symbolName) ) {
if ( stringsNeedLabelsInObjects() && (atom->getContentType() == ObjectFile::Atom::kCStringType) ) {
// don't use 'l' labels for x86_64 strings
// <rdar://problem/6605499> x86_64 obj-c runtime confused when static lib is stripped
}
else {
sprintf(anonName, "l%u", fAnonNameIndex++);
symbolName = anonName;
}
}
entry->set_n_strx(this->fStringsAtom->add(symbolName));
// set n_type
uint8_t type = N_SECT;
if ( atom->getDefinitionKind() == ObjectFile::Atom::kAbsoluteSymbol )
type = N_ABS;
if ( atom->getScope() == ObjectFile::Atom::scopeLinkageUnit )
type |= N_PEXT;
entry->set_n_type(type);
// set n_sect (section number of implementation )
uint8_t sectIndex = atom->getSection()->getIndex();
if ( sectIndex == 0 ) {
// see <mach-o/ldsyms.h> synthesized lable for mach_header needs special section number...
if ( strcmp(atom->getSectionName(), "._mach_header") == 0 )
sectIndex = 1;
}
entry->set_n_sect(sectIndex);
// set n_desc
uint16_t desc = 0;
if ( atom->dontDeadStrip() && (fOptions.outputKind() == Options::kObjectFile) )
desc |= N_NO_DEAD_STRIP;
if ( atom->getDefinitionKind() == ObjectFile::Atom::kWeakDefinition )
desc |= N_WEAK_DEF;
if ( atom->isThumb() )
desc |= N_ARM_THUMB_DEF;
entry->set_n_desc(desc);
// set n_value ( address this symbol will be at if this executable is loaded at it preferred address )
if ( atom->getDefinitionKind() == ObjectFile::Atom::kAbsoluteSymbol )
entry->set_n_value(atom->getSectionOffset());
else
entry->set_n_value(this->getAtomLoadAddress(atom));
}
template <typename A>
void Writer<A>::addLocalLabel(ObjectFile::Atom& atom, uint32_t offsetInAtom, const char* name)
{
macho_nlist<P> entry;
// set n_strx
entry.set_n_strx(fStringsAtom->add(name));
// set n_type
entry.set_n_type(N_SECT);
// set n_sect (section number of implementation )
entry.set_n_sect(atom.getSection()->getIndex());
// set n_desc
entry.set_n_desc(0);
// set n_value ( address this symbol will be at if this executable is loaded at it preferred address )
entry.set_n_value(this->getAtomLoadAddress(&atom) + offsetInAtom);
// add
fLocalExtraLabels.push_back(entry);
}
template <typename A>
void Writer<A>::addGlobalLabel(ObjectFile::Atom& atom, uint32_t offsetInAtom, const char* name)
{
macho_nlist<P> entry;
// set n_strx
entry.set_n_strx(fStringsAtom->add(name));
// set n_type
entry.set_n_type(N_SECT|N_EXT);
// set n_sect (section number of implementation )
entry.set_n_sect(atom.getSection()->getIndex());
// set n_desc
entry.set_n_desc(0);
// set n_value ( address this symbol will be at if this executable is loaded at it preferred address )
entry.set_n_value(this->getAtomLoadAddress(&atom) + offsetInAtom);
// add
fGlobalExtraLabels.push_back(entry);
}
template <typename A>
void Writer<A>::setNlistRange(std::vector<class ObjectFile::Atom*>& atoms, uint32_t startIndex, uint32_t count)
{
macho_nlist<P>* entry = &fSymbolTable[startIndex];
for (uint32_t i=0; i < count; ++i, ++entry) {
ObjectFile::Atom* atom = atoms[i];
if ( &atoms == &fExportedAtoms ) {
this->setExportNlist(atom, entry);
}
else if ( &atoms == &fImportedAtoms ) {
this->setImportNlist(atom, entry);
}
else {
this->setLocalNlist(atom, entry);
}
}
}
template <typename A>
void Writer<A>::copyNlistRange(const std::vector<macho_nlist<P> >& entries, uint32_t startIndex)
{
for ( typename std::vector<macho_nlist<P> >::const_iterator it = entries.begin(); it != entries.end(); ++it)
fSymbolTable[startIndex++] = *it;
}
template <typename A>
struct NListNameSorter
{
NListNameSorter(StringsLinkEditAtom<A>* pool) : fStringPool(pool) {}
bool operator()(const macho_nlist<typename A::P>& left, const macho_nlist<typename A::P>& right)
{
return (strcmp(fStringPool->stringForIndex(left.n_strx()), fStringPool->stringForIndex(right.n_strx())) < 0);
}
private:
StringsLinkEditAtom<A>* fStringPool;
};
template <typename A>
void Writer<A>::buildSymbolTable()
{
fSymbolTableStabsStartIndex = 0;
fSymbolTableStabsCount = fStabs->size();
fSymbolTableLocalStartIndex = fSymbolTableStabsStartIndex + fSymbolTableStabsCount;
fSymbolTableLocalCount = fLocalSymbolAtoms.size() + fLocalExtraLabels.size();
fSymbolTableExportStartIndex = fSymbolTableLocalStartIndex + fSymbolTableLocalCount;
fSymbolTableExportCount = fExportedAtoms.size() + fGlobalExtraLabels.size();
fSymbolTableImportStartIndex = fSymbolTableExportStartIndex + fSymbolTableExportCount;
fSymbolTableImportCount = fImportedAtoms.size();
// allocate symbol table
fSymbolTableCount = fSymbolTableStabsCount + fSymbolTableLocalCount + fSymbolTableExportCount + fSymbolTableImportCount;
fSymbolTable = new macho_nlist<P>[fSymbolTableCount];
// fill in symbol table and string pool (do stabs last so strings are at end of pool)
setNlistRange(fLocalSymbolAtoms, fSymbolTableLocalStartIndex, fLocalSymbolAtoms.size());
if ( fLocalExtraLabels.size() != 0 )
copyNlistRange(fLocalExtraLabels, fSymbolTableLocalStartIndex+fLocalSymbolAtoms.size());
setNlistRange(fExportedAtoms, fSymbolTableExportStartIndex, fExportedAtoms.size());
if ( fGlobalExtraLabels.size() != 0 ) {
copyNlistRange(fGlobalExtraLabels, fSymbolTableExportStartIndex+fExportedAtoms.size());
// re-sort combined range
std::sort( &fSymbolTable[fSymbolTableExportStartIndex],
&fSymbolTable[fSymbolTableExportStartIndex+fSymbolTableExportCount],
NListNameSorter<A>(fStringsAtom) );
}
setNlistRange(fImportedAtoms, fSymbolTableImportStartIndex, fSymbolTableImportCount);
addStabs(fSymbolTableStabsStartIndex);
// set up module table
if ( fModuleInfoAtom != NULL )
fModuleInfoAtom->setName();
// create atom to symbol index map
// imports
int i = 0;
for(std::vector<ObjectFile::Atom*>::iterator it=fImportedAtoms.begin(); it != fImportedAtoms.end(); ++it) {
fAtomToSymbolIndex[*it] = i + fSymbolTableImportStartIndex;
++i;
}
// locals
i = 0;
for(std::vector<ObjectFile::Atom*>::iterator it=fLocalSymbolAtoms.begin(); it != fLocalSymbolAtoms.end(); ++it) {
fAtomToSymbolIndex[*it] = i + fSymbolTableLocalStartIndex;
++i;
}
// exports
i = 0;
for(std::vector<ObjectFile::Atom*>::iterator it=fExportedAtoms.begin(); it != fExportedAtoms.end(); ++it) {
fAtomToSymbolIndex[*it] = i + fSymbolTableExportStartIndex;
++i;
}
}
template <typename A>
bool Writer<A>::shouldExport(const ObjectFile::Atom& atom) const
{
switch ( atom.getSymbolTableInclusion() ) {
case ObjectFile::Atom::kSymbolTableNotIn:
return false;
case ObjectFile::Atom::kSymbolTableInAndNeverStrip:
return true;
case ObjectFile::Atom::kSymbolTableInAsAbsolute:
case ObjectFile::Atom::kSymbolTableIn:
switch ( atom.getScope() ) {
case ObjectFile::Atom::scopeGlobal:
return true;
case ObjectFile::Atom::scopeLinkageUnit:
return ( (fOptions.outputKind() == Options::kObjectFile) && fOptions.keepPrivateExterns() );
default:
return false;
}
break;
}
return false;
}
template <typename A>
void Writer<A>::collectExportedAndImportedAndLocalAtoms()
{
const int atomCount = fAllAtoms->size();
// guess at sizes of each bucket to minimize re-allocations
fImportedAtoms.reserve(100);
fExportedAtoms.reserve(atomCount/2);
fLocalSymbolAtoms.reserve(atomCount);
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
std::vector<SectionInfo*>& sectionInfos = (*segit)->fSections;
for (std::vector<SectionInfo*>::iterator secit = sectionInfos.begin(); secit != sectionInfos.end(); ++secit) {
std::vector<ObjectFile::Atom*>& sectionAtoms = (*secit)->fAtoms;
for (std::vector<ObjectFile::Atom*>::iterator ait = sectionAtoms.begin(); ait != sectionAtoms.end(); ++ait) {
ObjectFile::Atom* atom = *ait;
// only named atoms go in symbol table
if ( atom->getName() != NULL ) {
// put atom into correct bucket: imports, exports, locals
//fprintf(stderr, "collectExportedAndImportedAndLocalAtoms() name=%s\n", atom->getDisplayName());
switch ( atom->getDefinitionKind() ) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
fImportedAtoms.push_back(atom);
break;
case ObjectFile::Atom::kTentativeDefinition:
if ( (fOptions.outputKind() == Options::kObjectFile) && !fOptions.readerOptions().fMakeTentativeDefinitionsReal ) {
fImportedAtoms.push_back(atom);
break;
}
// else fall into
case ObjectFile::Atom::kWeakDefinition:
if ( stringsNeedLabelsInObjects()
&& (fOptions.outputKind() == Options::kObjectFile)
&& (atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableIn)
&& (atom->getScope() == ObjectFile::Atom::scopeLinkageUnit)
&& (atom->getContentType() == ObjectFile::Atom::kCStringType) ) {
fLocalSymbolAtoms.push_back(atom);
break;
}
// else fall into
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
if ( this->shouldExport(*atom) )
fExportedAtoms.push_back(atom);
else if ( (atom->getSymbolTableInclusion() != ObjectFile::Atom::kSymbolTableNotIn)
&& ((fOptions.outputKind() == Options::kObjectFile) || fOptions.keepLocalSymbol(atom->getName())) )
fLocalSymbolAtoms.push_back(atom);
break;
}
}
// when geneating a .o file, dtrace static probes become local labels
if ( (fOptions.outputKind() == Options::kObjectFile) && !fOptions.readerOptions().fForStatic ) {
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
if ( ref->getKind() == A::kDtraceProbe ) {
// dtrace probe points to be add back into generated .o file
this->addLocalLabel(*atom, ref->getFixUpOffset(), ref->getTargetName());
}
}
}
// when linking kernel, old style dtrace static probes become global labels
else if ( fOptions.readerOptions().fForStatic ) {
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
if ( ref->getKind() == A::kDtraceProbe ) {
// dtrace probe points to be add back into generated .o file
this->addGlobalLabel(*atom, ref->getFixUpOffset(), ref->getTargetName());
}
}
}
}
}
}
// sort exported atoms by name
std::sort(fExportedAtoms.begin(), fExportedAtoms.end(), AtomByNameSorter());
// sort imported atoms by name (not required by runtime, but helps make generated files binary diffable)
std::sort(fImportedAtoms.begin(), fImportedAtoms.end(), AtomByNameSorter());
}
template <typename A>
uint64_t Writer<A>::valueForStab(const ObjectFile::Reader::Stab& stab)
{
switch ( stab.type ) {
case N_FUN:
if ( (stab.string == NULL) || (strlen(stab.string) == 0) ) {
// end of function N_FUN has size
return stab.atom->getSize();
}
else {
// start of function N_FUN has address
return getAtomLoadAddress(stab.atom);
}
case N_LBRAC:
case N_RBRAC:
case N_SLINE:
if ( stab.atom == NULL )
// some weird assembly files have slines not associated with a function
return stab.value;
else
// all these stab types need their value changed from an offset in the atom to an address
return getAtomLoadAddress(stab.atom) + stab.value;
case N_STSYM:
case N_LCSYM:
case N_BNSYM:
// all these need address of atom
return getAtomLoadAddress(stab.atom);;
case N_ENSYM:
return stab.atom->getSize();
case N_SO:
if ( stab.atom == NULL ) {
return 0;
}
else {
if ( (stab.string == NULL) || (strlen(stab.string) == 0) ) {
// end of translation unit N_SO has address of end of last atom
return getAtomLoadAddress(stab.atom) + stab.atom->getSize();
}
else {
// start of translation unit N_SO has address of end of first atom
return getAtomLoadAddress(stab.atom);
}
}
break;
default:
return stab.value;
}
}
template <typename A>
uint32_t Writer<A>::stringOffsetForStab(const ObjectFile::Reader::Stab& stab)
{
switch (stab.type) {
case N_SO:
if ( (stab.string == NULL) || stab.string[0] == '\0' ) {
return this->fStringsAtom->emptyString();
break;
}
// fall into uniquing case
case N_SOL:
case N_BINCL:
case N_EXCL:
return this->fStringsAtom->addUnique(stab.string);
break;
default:
if ( stab.string == NULL )
return 0;
else if ( stab.string[0] == '\0' )
return this->fStringsAtom->emptyString();
else
return this->fStringsAtom->add(stab.string);
}
return 0;
}
template <typename A>
uint8_t Writer<A>::sectionIndexForStab(const ObjectFile::Reader::Stab& stab)
{
// in FUN stabs, n_sect field is 0 for start FUN and 1 for end FUN
if ( stab.type == N_FUN )
return stab.other;
else if ( stab.atom != NULL )
return stab.atom->getSection()->getIndex();
else
return stab.other;
}
template <typename A>
void Writer<A>::addStabs(uint32_t startIndex)
{
macho_nlist<P>* entry = &fSymbolTable[startIndex];
for(std::vector<ObjectFile::Reader::Stab>::iterator it = fStabs->begin(); it != fStabs->end(); ++it, ++entry) {
const ObjectFile::Reader::Stab& stab = *it;
entry->set_n_type(stab.type);
entry->set_n_sect(sectionIndexForStab(stab));
entry->set_n_desc(stab.desc);
entry->set_n_value(valueForStab(stab));
entry->set_n_strx(stringOffsetForStab(stab));
}
}
template <typename A>
uint32_t Writer<A>::symbolIndex(ObjectFile::Atom& atom)
{
std::map<ObjectFile::Atom*, uint32_t>::iterator pos = fAtomToSymbolIndex.find(&atom);
if ( pos != fAtomToSymbolIndex.end() )
return pos->second;
throwf("atom not found in symbolIndex(%s) for %s", atom.getDisplayName(), atom.getFile()->getPath());
}
template <>
bool Writer<x86_64>::makesExternalRelocatableReference(ObjectFile::Atom& target) const
{
switch ( target.getSymbolTableInclusion() ) {
case ObjectFile::Atom::kSymbolTableNotIn:
return false;
case ObjectFile::Atom::kSymbolTableInAsAbsolute:
case ObjectFile::Atom::kSymbolTableIn:
case ObjectFile::Atom::kSymbolTableInAndNeverStrip:
return true;
};
return false;
}
template <typename A>
bool Writer<A>::makesExternalRelocatableReference(ObjectFile::Atom& target) const
{
switch ( target.getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
case ObjectFile::Atom::kTentativeDefinition:
if ( fOptions.readerOptions().fMakeTentativeDefinitionsReal )
return false;
else
return (target.getScope() != ObjectFile::Atom::scopeTranslationUnit);
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
return shouldExport(target);
}
return false;
}
template <typename A>
void Writer<A>::buildFixups()
{
if ( fOptions.outputKind() == Options::kObjectFile ) {
this->buildObjectFileFixups();
}
else {
if ( fOptions.keepRelocations() )
this->buildObjectFileFixups();
this->buildExecutableFixups();
}
}
template <>
uint32_t Writer<x86_64>::addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
ObjectFile::Atom& target = ref->getTarget();
bool external = this->makesExternalRelocatableReference(target);
uint32_t symbolIndex = external ? this->symbolIndex(target) : target.getSection()->getIndex();
uint32_t address = atom->getSectionOffset()+ref->getFixUpOffset();
macho_relocation_info<P> reloc1;
macho_relocation_info<P> reloc2;
x86_64::ReferenceKinds kind = (x86_64::ReferenceKinds)ref->getKind();
switch ( kind ) {
case x86_64::kNoFixUp:
case x86_64::kGOTNoFixUp:
case x86_64::kFollowOn:
case x86_64::kGroupSubordinate:
return 0;
case x86_64::kPointer:
case x86_64::kPointerWeakImport:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(3);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_UNSIGNED);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPointer32:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_UNSIGNED);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPointerDiff32:
case x86_64::kPointerDiff:
{
ObjectFile::Atom& fromTarget = ref->getFromTarget();
bool fromExternal = (fromTarget.getSymbolTableInclusion() != ObjectFile::Atom::kSymbolTableNotIn);
uint32_t fromSymbolIndex = fromExternal ? this->symbolIndex(fromTarget) : fromTarget.getSection()->getIndex();
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(kind==x86_64::kPointerDiff32 ? 2 : 3);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_UNSIGNED);
reloc2.set_r_address(address);
reloc2.set_r_symbolnum(fromSymbolIndex);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(kind==x86_64::kPointerDiff32 ? 2 : 3);
reloc2.set_r_extern(fromExternal);
reloc2.set_r_type(X86_64_RELOC_SUBTRACTOR);
fSectionRelocs.push_back(reloc1);
fSectionRelocs.push_back(reloc2);
return 2;
}
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel32WeakImport:
case x86_64::kDtraceProbeSite:
case x86_64::kDtraceIsEnabledSite:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_BRANCH);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_SIGNED);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32_1:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_SIGNED_1);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32_2:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_SIGNED_2);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32_4:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_SIGNED_4);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kBranchPCRel8:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(0);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_BRANCH);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_GOT);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(symbolIndex);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(external);
reloc1.set_r_type(X86_64_RELOC_GOT_LOAD);
fSectionRelocs.push_back(reloc1);
return 1;
case x86_64::kPointerDiff24:
throw "internal linker error, kPointerDiff24 can't be encoded into object files";
case x86_64::kImageOffset32:
throw "internal linker error, kImageOffset32 can't be encoded into object files";
case x86_64::kSectionOffset24:
throw "internal linker error, kSectionOffset24 can't be encoded into object files";
case x86_64::kDtraceTypeReference:
case x86_64::kDtraceProbe:
// generates no relocs
return 0;
}
return 0;
}
template <>
uint32_t Writer<x86>::addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
ObjectFile::Atom& target = ref->getTarget();
bool isExtern = this->makesExternalRelocatableReference(target);
uint32_t symbolIndex = 0;
if ( isExtern )
symbolIndex = this->symbolIndex(target);
uint32_t sectionNum = target.getSection()->getIndex();
uint32_t address = atom->getSectionOffset()+ref->getFixUpOffset();
macho_relocation_info<P> reloc1;
macho_relocation_info<P> reloc2;
macho_scattered_relocation_info<P>* sreloc1 = (macho_scattered_relocation_info<P>*)&reloc1;
macho_scattered_relocation_info<P>* sreloc2 = (macho_scattered_relocation_info<P>*)&reloc2;
x86::ReferenceKinds kind = (x86::ReferenceKinds)ref->getKind();
if ( !isExtern && (sectionNum == 0) && (target.getDefinitionKind() != ObjectFile::Atom::kAbsoluteSymbol) )
warning("section index == 0 for %s (kind=%d, scope=%d, inclusion=%d) in %s",
target.getDisplayName(), target.getDefinitionKind(), target.getScope(), target.getSymbolTableInclusion(), target.getFile()->getPath());
switch ( kind ) {
case x86::kNoFixUp:
case x86::kFollowOn:
case x86::kGroupSubordinate:
return 0;
case x86::kPointer:
case x86::kPointerWeakImport:
case x86::kAbsolute32:
if ( !isExtern && (ref->getTargetOffset() != 0) ) {
// use scattered reloc is target offset is non-zero
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(GENERIC_RELOC_VANILLA);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(isExtern ? symbolIndex : sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(GENERIC_RELOC_VANILLA);
}
fSectionRelocs.push_back(reloc1);
return 1;
case x86::kPointerDiff16:
case x86::kPointerDiff:
{
//pint_t fromAddr = ref->getFromTarget().getAddress() + ref->getFromTargetOffset();
//fprintf(stderr, "addObjectRelocs(): refFromTarget=%s, refTarget=%s, refFromTargetAddr=0x%llX, refFromTargetOffset=0x%llX\n",
// ref->getFromTarget().getDisplayName(), ref->getTarget().getDisplayName(),
// ref->getFromTarget().getAddress(), ref->getFromTargetOffset());
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length( (kind==x86::kPointerDiff) ? 2 : 1 );
if ( ref->getTarget().getScope() == ObjectFile::Atom::scopeTranslationUnit )
sreloc1->set_r_type(GENERIC_RELOC_LOCAL_SECTDIFF);
else
sreloc1->set_r_type(GENERIC_RELOC_SECTDIFF);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
sreloc2->set_r_scattered(true);
sreloc2->set_r_pcrel(false);
sreloc2->set_r_length( (kind==x86::kPointerDiff) ? 2 : 1 );
sreloc2->set_r_type(GENERIC_RELOC_PAIR);
sreloc2->set_r_address(0);
if ( &ref->getFromTarget() == atom )
sreloc2->set_r_value(ref->getFromTarget().getAddress()+ref->getFromTargetOffset());
else
sreloc2->set_r_value(ref->getFromTarget().getAddress());
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case x86::kPCRel32WeakImport:
case x86::kPCRel32:
case x86::kPCRel16:
case x86::kPCRel8:
case x86::kDtraceProbeSite:
case x86::kDtraceIsEnabledSite:
if ( !isExtern && (ref->getTargetOffset() != 0) ) {
// use scattered reloc is target offset is non-zero
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(true);
sreloc1->set_r_length( (kind==x86::kPCRel8) ? 0 : ((kind==x86::kPCRel16) ? 1 : 2) );
sreloc1->set_r_type(GENERIC_RELOC_VANILLA);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(isExtern ? symbolIndex : sectionNum);
reloc1.set_r_pcrel(true);
reloc1.set_r_length( (kind==x86::kPCRel8) ? 0 : ((kind==x86::kPCRel16) ? 1 : 2) );
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(GENERIC_RELOC_VANILLA);
}
fSectionRelocs.push_back(reloc1);
return 1;
case x86::kPointerDiff24:
throw "internal linker error, kPointerDiff24 can't be encoded into object files";
case x86::kImageOffset32:
throw "internal linker error, kImageOffset32 can't be encoded into object files";
case x86::kSectionOffset24:
throw "internal linker error, kSectionOffset24 can't be encoded into object files";
case x86::kDtraceTypeReference:
case x86::kDtraceProbe:
// generates no relocs
return 0;
}
return 0;
}
template <>
uint32_t Writer<arm>::addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
ObjectFile::Atom& target = ref->getTarget();
bool isExtern = this->makesExternalRelocatableReference(target);
uint32_t symbolIndex = 0;
if ( isExtern )
symbolIndex = this->symbolIndex(target);
uint32_t sectionNum = target.getSection()->getIndex();
uint32_t address = atom->getSectionOffset()+ref->getFixUpOffset();
macho_relocation_info<P> reloc1;
macho_relocation_info<P> reloc2;
macho_scattered_relocation_info<P>* sreloc1 = (macho_scattered_relocation_info<P>*)&reloc1;
macho_scattered_relocation_info<P>* sreloc2 = (macho_scattered_relocation_info<P>*)&reloc2;
arm::ReferenceKinds kind = (arm::ReferenceKinds)ref->getKind();
if ( !isExtern && (sectionNum == 0) && (target.getDefinitionKind() != ObjectFile::Atom::kAbsoluteSymbol) )
warning("section index == 0 for %s (kind=%d, scope=%d, inclusion=%d) in %s",
target.getDisplayName(), target.getDefinitionKind(), target.getScope(), target.getSymbolTableInclusion(), target.getFile()->getPath());
switch ( kind ) {
case arm::kNoFixUp:
case arm::kFollowOn:
case arm::kGroupSubordinate:
return 0;
case arm::kPointer:
case arm::kReadOnlyPointer:
case arm::kPointerWeakImport:
if ( !isExtern && (ref->getTargetOffset() != 0) ) {
// use scattered reloc is target offset is non-zero
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(ARM_RELOC_VANILLA);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(isExtern ? symbolIndex : sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(ARM_RELOC_VANILLA);
}
fSectionRelocs.push_back(reloc1);
return 1;
case arm::kPointerDiff:
{
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
if ( ref->getTarget().getScope() == ObjectFile::Atom::scopeTranslationUnit )
sreloc1->set_r_type(ARM_RELOC_LOCAL_SECTDIFF);
else
sreloc1->set_r_type(ARM_RELOC_SECTDIFF);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
sreloc2->set_r_scattered(true);
sreloc2->set_r_pcrel(false);
sreloc2->set_r_length(2);
sreloc2->set_r_type(ARM_RELOC_PAIR);
sreloc2->set_r_address(0);
if ( &ref->getFromTarget() == atom )
sreloc2->set_r_value(ref->getFromTarget().getAddress()+ref->getFromTargetOffset());
else
sreloc2->set_r_value(ref->getFromTarget().getAddress());
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case arm::kBranch24WeakImport:
case arm::kBranch24:
case arm::kDtraceProbeSite:
case arm::kDtraceIsEnabledSite:
if ( !isExtern && (ref->getTargetOffset() != 0) ) {
// use scattered reloc is target offset is non-zero
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(true);
sreloc1->set_r_length(2);
sreloc1->set_r_type(ARM_RELOC_BR24);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(isExtern ? symbolIndex : sectionNum);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(ARM_RELOC_BR24);
}
fSectionRelocs.push_back(reloc1);
return 1;
case arm::kThumbBranch22WeakImport:
case arm::kThumbBranch22:
if ( !isExtern && (ref->getTargetOffset() != 0) ) {
// use scattered reloc if target offset is non-zero
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(true);
sreloc1->set_r_length(2);
sreloc1->set_r_type(ARM_THUMB_RELOC_BR22);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
reloc1.set_r_symbolnum(isExtern ? symbolIndex : sectionNum);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(ARM_THUMB_RELOC_BR22);
}
fSectionRelocs.push_back(reloc1);
return 1;
case arm::kPointerDiff12:
throw "internal error. no reloc for 12-bit pointer diffs";
case arm::kDtraceTypeReference:
case arm::kDtraceProbe:
// generates no relocs
return 0;
}
return 0;
}
template <> uint64_t Writer<ppc>::maxAddress() { return 0xFFFFFFFFULL; }
template <> uint64_t Writer<ppc64>::maxAddress() { return 0xFFFFFFFFFFFFFFFFULL; }
template <> uint64_t Writer<x86>::maxAddress() { return 0xFFFFFFFFULL; }
template <> uint64_t Writer<x86_64>::maxAddress() { return 0xFFFFFFFFFFFFFFFFULL; }
template <> uint64_t Writer<arm>::maxAddress() { return 0xFFFFFFFFULL; }
template <>
uint8_t Writer<ppc>::getRelocPointerSize()
{
return 2;
}
template <>
uint8_t Writer<ppc64>::getRelocPointerSize()
{
return 3;
}
template <>
uint32_t Writer<ppc>::addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
return addObjectRelocs_powerpc(atom, ref);
}
template <>
uint32_t Writer<ppc64>::addObjectRelocs(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
return addObjectRelocs_powerpc(atom, ref);
}
//
// addObjectRelocs<ppc> and addObjectRelocs<ppc64> are almost exactly the same, so
// they use a common addObjectRelocs_powerpc() method.
//
template <typename A>
uint32_t Writer<A>::addObjectRelocs_powerpc(ObjectFile::Atom* atom, ObjectFile::Reference* ref)
{
ObjectFile::Atom& target = ref->getTarget();
bool isExtern = this->makesExternalRelocatableReference(target);
uint32_t symbolIndex = 0;
if ( isExtern )
symbolIndex = this->symbolIndex(target);
uint32_t sectionNum = target.getSection()->getIndex();
uint32_t address = atom->getSectionOffset()+ref->getFixUpOffset();
macho_relocation_info<P> reloc1;
macho_relocation_info<P> reloc2;
macho_scattered_relocation_info<P>* sreloc1 = (macho_scattered_relocation_info<P>*)&reloc1;
macho_scattered_relocation_info<P>* sreloc2 = (macho_scattered_relocation_info<P>*)&reloc2;
typename A::ReferenceKinds kind = (typename A::ReferenceKinds)ref->getKind();
switch ( kind ) {
case A::kNoFixUp:
case A::kFollowOn:
case A::kGroupSubordinate:
return 0;
case A::kPointer:
case A::kPointerWeakImport:
if ( !isExtern && (ref->getTargetOffset() >= target.getSize()) ) {
// use scattered reloc is target offset is outside target
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(getRelocPointerSize());
sreloc1->set_r_type(GENERIC_RELOC_VANILLA);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
else {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(getRelocPointerSize());
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(GENERIC_RELOC_VANILLA);
}
fSectionRelocs.push_back(reloc1);
return 1;
case A::kPointerDiff16:
case A::kPointerDiff32:
case A::kPointerDiff64:
{
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length( (kind == A::kPointerDiff32) ? 2 : ((kind == A::kPointerDiff64) ? 3 : 1));
if ( ref->getTarget().getScope() == ObjectFile::Atom::scopeTranslationUnit )
sreloc1->set_r_type(PPC_RELOC_LOCAL_SECTDIFF);
else
sreloc1->set_r_type(PPC_RELOC_SECTDIFF);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
sreloc2->set_r_scattered(true);
sreloc2->set_r_pcrel(false);
sreloc2->set_r_length(sreloc1->r_length());
sreloc2->set_r_type(PPC_RELOC_PAIR);
sreloc2->set_r_address(0);
sreloc2->set_r_value(ref->getFromTarget().getAddress()+ref->getFromTargetOffset());
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kBranch24WeakImport:
case A::kBranch24:
case A::kDtraceProbeSite:
case A::kDtraceIsEnabledSite:
if ( (ref->getTargetOffset() == 0) || isExtern ) {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_type(PPC_RELOC_BR24);
reloc1.set_r_extern(isExtern);
}
else {
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(true);
sreloc1->set_r_length(2);
sreloc1->set_r_type(PPC_RELOC_BR24);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
fSectionRelocs.push_back(reloc1);
return 1;
case A::kBranch14:
if ( (ref->getTargetOffset() == 0) || isExtern ) {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(true);
reloc1.set_r_length(2);
reloc1.set_r_type(PPC_RELOC_BR14);
reloc1.set_r_extern(isExtern);
}
else {
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(true);
sreloc1->set_r_length(2);
sreloc1->set_r_type(PPC_RELOC_BR14);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
fSectionRelocs.push_back(reloc1);
return 1;
case A::kPICBaseLow16:
case A::kPICBaseLow14:
{
pint_t fromAddr = atom->getAddress() + ref->getFromTargetOffset();
pint_t toAddr = target.getAddress() + ref->getTargetOffset();
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(kind == A::kPICBaseLow16 ? PPC_RELOC_LO16_SECTDIFF : PPC_RELOC_LO14_SECTDIFF);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
sreloc2->set_r_scattered(true);
sreloc2->set_r_pcrel(false);
sreloc2->set_r_length(2);
sreloc2->set_r_type(PPC_RELOC_PAIR);
sreloc2->set_r_address(((toAddr-fromAddr) >> 16) & 0xFFFF);
sreloc2->set_r_value(fromAddr);
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kPICBaseHigh16:
{
pint_t fromAddr = atom->getAddress() + ref->getFromTargetOffset();
pint_t toAddr = target.getAddress() + ref->getTargetOffset();
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(PPC_RELOC_HA16_SECTDIFF);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
sreloc2->set_r_scattered(true);
sreloc2->set_r_pcrel(false);
sreloc2->set_r_length(2);
sreloc2->set_r_type(PPC_RELOC_PAIR);
sreloc2->set_r_address((toAddr-fromAddr) & 0xFFFF);
sreloc2->set_r_value(fromAddr);
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kAbsLow14:
case A::kAbsLow16:
{
pint_t toAddr = target.getAddress() + ref->getTargetOffset();
if ( (ref->getTargetOffset() == 0) || isExtern ) {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(kind==A::kAbsLow16 ? PPC_RELOC_LO16 : PPC_RELOC_LO14);
}
else {
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(kind==A::kAbsLow16 ? PPC_RELOC_LO16 : PPC_RELOC_LO14);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
if ( isExtern )
reloc2.set_r_address(ref->getTargetOffset() >> 16);
else
reloc2.set_r_address(toAddr >> 16);
reloc2.set_r_symbolnum(0);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(2);
reloc2.set_r_extern(false);
reloc2.set_r_type(PPC_RELOC_PAIR);
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kAbsHigh16:
{
pint_t toAddr = target.getAddress() + ref->getTargetOffset();
if ( (ref->getTargetOffset() == 0) || isExtern ) {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(PPC_RELOC_HI16);
}
else {
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(PPC_RELOC_HI16);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
if ( isExtern )
reloc2.set_r_address(ref->getTargetOffset() & 0xFFFF);
else
reloc2.set_r_address(toAddr & 0xFFFF);
reloc2.set_r_symbolnum(0);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(2);
reloc2.set_r_extern(false);
reloc2.set_r_type(PPC_RELOC_PAIR);
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kAbsHigh16AddLow:
{
pint_t toAddr = target.getAddress() + ref->getTargetOffset();
uint32_t overflow = 0;
if ( (toAddr & 0x00008000) != 0 )
overflow = 0x10000;
if ( (ref->getTargetOffset() == 0) || isExtern ) {
reloc1.set_r_address(address);
if ( isExtern )
reloc1.set_r_symbolnum(symbolIndex);
else
reloc1.set_r_symbolnum(sectionNum);
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(PPC_RELOC_HA16);
}
else {
sreloc1->set_r_scattered(true);
sreloc1->set_r_pcrel(false);
sreloc1->set_r_length(2);
sreloc1->set_r_type(PPC_RELOC_HA16);
sreloc1->set_r_address(address);
sreloc1->set_r_value(target.getAddress());
}
if ( isExtern )
reloc2.set_r_address(ref->getTargetOffset() & 0xFFFF);
else
reloc2.set_r_address(toAddr & 0xFFFF);
reloc2.set_r_symbolnum(0);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(2);
reloc2.set_r_extern(false);
reloc2.set_r_type(PPC_RELOC_PAIR);
fSectionRelocs.push_back(reloc2);
fSectionRelocs.push_back(reloc1);
return 2;
}
case A::kDtraceTypeReference:
case A::kDtraceProbe:
// generates no relocs
return 0;
}
return 0;
}
//
// There are cases when an entry in the indirect symbol table is the magic value
// INDIRECT_SYMBOL_LOCAL instead of being a symbol index. When that happens
// the content of the corresponding part of the __nl_symbol_pointer section
// must also change.
//
template <typename A>
bool Writer<A>::indirectSymbolInRelocatableIsLocal(const ObjectFile::Reference* ref) const
{
// cannot use INDIRECT_SYMBOL_LOCAL to tentative definitions in object files
// because tentative defs don't have addresses
if ( ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kTentativeDefinition )
return false;
// must use INDIRECT_SYMBOL_LOCAL if there is an addend
if ( ref->getTargetOffset() != 0 )
return true;
// don't use INDIRECT_SYMBOL_LOCAL for external symbols
return ! this->shouldExport(ref->getTarget());
}
template <typename A>
void Writer<A>::buildObjectFileFixups()
{
uint32_t relocIndex = 0;
std::vector<SegmentInfo*>& segmentInfos = fSegmentInfos;
const int segCount = segmentInfos.size();
for(int i=0; i < segCount; ++i) {
SegmentInfo* curSegment = segmentInfos[i];
std::vector<SectionInfo*>& sectionInfos = curSegment->fSections;
const int sectionCount = sectionInfos.size();
for(int j=0; j < sectionCount; ++j) {
SectionInfo* curSection = sectionInfos[j];
//fprintf(stderr, "buildObjectFileFixups(): starting section %s\n", curSection->fSectionName);
std::vector<ObjectFile::Atom*>& sectionAtoms = curSection->fAtoms;
if ( ! curSection->fAllZeroFill ) {
if ( curSection->fAllNonLazyPointers || curSection->fAllLazyPointers
|| curSection->fAllLazyDylibPointers || curSection->fAllStubs )
curSection->fIndirectSymbolOffset = fIndirectTableAtom->fTable.size();
curSection->fRelocOffset = relocIndex;
const int atomCount = sectionAtoms.size();
for (int k=0; k < atomCount; ++k) {
ObjectFile::Atom* atom = sectionAtoms[k];
//fprintf(stderr, "buildObjectFileFixups(): atom %s has %lu references\n", atom->getDisplayName(), atom->getReferences().size());
std::vector<ObjectFile::Reference*>& refs = atom->getReferences();
const int refCount = refs.size();
for (int l=0; l < refCount; ++l) {
ObjectFile::Reference* ref = refs[l];
if ( curSection->fAllNonLazyPointers || curSection->fAllLazyPointers
|| curSection->fAllLazyDylibPointers || curSection->fAllStubs ) {
uint32_t offsetInSection = atom->getSectionOffset();
uint32_t indexInSection = offsetInSection / atom->getSize();
uint32_t undefinedSymbolIndex;
if ( curSection->fAllStubs ) {
ObjectFile::Atom& stubTarget =ref->getTarget();
ObjectFile::Atom& stubTargetTarget = stubTarget.getReferences()[0]->getTarget();
undefinedSymbolIndex = this->symbolIndex(stubTargetTarget);
//fprintf(stderr, "stub %s ==> %s ==> %s ==> index:%u\n", atom->getDisplayName(), stubTarget.getDisplayName(), stubTargetTarget.getDisplayName(), undefinedSymbolIndex);
}
else if ( curSection->fAllNonLazyPointers) {
// only use INDIRECT_SYMBOL_LOCAL in non-lazy-pointers for atoms that won't be in symbol table or have an addend
if ( this->indirectSymbolInRelocatableIsLocal(ref) )
undefinedSymbolIndex = INDIRECT_SYMBOL_LOCAL;
else
undefinedSymbolIndex = this->symbolIndex(ref->getTarget());
}
else {
// should never get here, fAllLazyPointers not used in generated .o files
undefinedSymbolIndex = INDIRECT_SYMBOL_LOCAL;
}
uint32_t indirectTableIndex = indexInSection + curSection->fIndirectSymbolOffset;
IndirectEntry entry = { indirectTableIndex, undefinedSymbolIndex };
//printf("fIndirectTableAtom->fTable.add(sectionIndex=%u, indirectTableIndex=%u => %u), size=%lld\n", indexInSection, indirectTableIndex, undefinedSymbolIndex, atom->getSize());
fIndirectTableAtom->fTable.push_back(entry);
if ( curSection->fAllLazyPointers ) {
ObjectFile::Atom& target = ref->getTarget();
ObjectFile::Atom& fromTarget = ref->getFromTarget();
if ( &fromTarget == NULL ) {
warning("lazy pointer %s missing initial binding", atom->getDisplayName());
}
else {
bool isExtern = ( ((target.getDefinitionKind() == ObjectFile::Atom::kExternalDefinition)
|| (target.getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition))
&& (target.getSymbolTableInclusion() != ObjectFile::Atom::kSymbolTableNotIn) );
macho_relocation_info<P> reloc1;
reloc1.set_r_address(atom->getSectionOffset());
reloc1.set_r_symbolnum(isExtern ? this->symbolIndex(target) : target.getSection()->getIndex());
reloc1.set_r_pcrel(false);
reloc1.set_r_length();
reloc1.set_r_extern(isExtern);
reloc1.set_r_type(GENERIC_RELOC_VANILLA);
fSectionRelocs.push_back(reloc1);
++relocIndex;
}
}
else if ( curSection->fAllStubs ) {
relocIndex += this->addObjectRelocs(atom, ref);
}
}
else if ( (ref->getKind() != A::kNoFixUp) && (ref->getTargetBinding() != ObjectFile::Reference::kDontBind) ) {
relocIndex += this->addObjectRelocs(atom, ref);
}
}
}
curSection->fRelocCount = relocIndex - curSection->fRelocOffset;
}
}
}
// reverse the relocs
std::reverse(fSectionRelocs.begin(), fSectionRelocs.end());
// now reverse section reloc offsets
for(int i=0; i < segCount; ++i) {
SegmentInfo* curSegment = segmentInfos[i];
std::vector<SectionInfo*>& sectionInfos = curSegment->fSections;
const int sectionCount = sectionInfos.size();
for(int j=0; j < sectionCount; ++j) {
SectionInfo* curSection = sectionInfos[j];
curSection->fRelocOffset = relocIndex - curSection->fRelocOffset - curSection->fRelocCount;
}
}
}
template <>
uint64_t Writer<x86_64>::relocAddressInFinalLinkedImage(uint64_t address, const ObjectFile::Atom* atom) const
{
uint64_t result;
if ( fOptions.outputKind() == Options::kKextBundle ) {
// for x86_64 kext bundles, the r_address field in relocs
// is the offset from the start address of the first segment
result = address - fSegmentInfos[0]->fBaseAddress;
if ( result > 0xFFFFFFFF ) {
throwf("kext bundle too large: address can't fit in 31-bit r_address field in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
}
else {
// for x86_64, the r_address field in relocs for final linked images
// is the offset from the start address of the first writable segment
result = address - fFirstWritableSegment->fBaseAddress;
if ( result > 0xFFFFFFFF ) {
if ( strcmp(atom->getSegment().getName(), "__TEXT") == 0 )
throwf("text relocs not supported for x86_64 in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
else
throwf("image too large: address can't fit in 32-bit r_address field in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
}
return result;
}
template <>
bool Writer<ppc>::illegalRelocInFinalLinkedImage(const ObjectFile::Reference& ref)
{
switch ( ref.getKind() ) {
case ppc::kAbsLow16:
case ppc::kAbsLow14:
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
if ( fSlideable )
return true;
}
return false;
}
template <>
bool Writer<ppc64>::illegalRelocInFinalLinkedImage(const ObjectFile::Reference& ref)
{
switch ( ref.getKind() ) {
case ppc::kAbsLow16:
case ppc::kAbsLow14:
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
if ( fSlideable )
return true;
}
return false;
}
template <>
bool Writer<x86>::illegalRelocInFinalLinkedImage(const ObjectFile::Reference& ref)
{
if ( ref.getKind() == x86::kAbsolute32 ) {
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// illegal in dylibs/bundles, until we support TEXT relocs
return fSlideable;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// illegal until we support TEXT relocs
return true;
case ObjectFile::Atom::kAbsoluteSymbol:
// absolute symbbols only allowed in static executables
return ( fOptions.outputKind() != Options::kStaticExecutable);
}
}
return false;
}
template <>
bool Writer<x86_64>::illegalRelocInFinalLinkedImage(const ObjectFile::Reference& ref)
{
if ( fOptions.outputKind() == Options::kKextBundle ) {
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// true means we need a TEXT relocs
switch ( ref.getKind() ) {
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel32WeakImport:
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
return true;
}
break;
}
}
return false;
}
template <>
bool Writer<arm>::illegalRelocInFinalLinkedImage(const ObjectFile::Reference& ref)
{
switch ( fOptions.outputKind()) {
case Options::kStaticExecutable:
case Options::kPreload:
// all relocations allowed in static executables
return false;
default:
break;
}
if ( ref.getKind() == arm::kReadOnlyPointer ) {
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// illegal in dylibs/bundles, until we support TEXT relocs
return fSlideable;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// illegal until we support TEXT relocs
return true;
case ObjectFile::Atom::kAbsoluteSymbol:
// absolute symbbols only allowed in static executables
return true;
}
}
return false;
}
template <>
bool Writer<x86>::generatesLocalTextReloc(const ObjectFile::Reference& ref, const ObjectFile::Atom& atom, SectionInfo* atomSection)
{
if ( ref.getKind() == x86::kAbsolute32 ) {
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// a reference to the absolute address of something in this same linkage unit can be
// encoded as a local text reloc in a dylib or bundle
if ( fSlideable ) {
macho_relocation_info<P> reloc;
SectionInfo* sectInfo = (SectionInfo*)(ref.getTarget().getSection());
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(sectInfo->getIndex());
reloc.set_r_pcrel(false);
reloc.set_r_length();
reloc.set_r_extern(false);
reloc.set_r_type(GENERIC_RELOC_VANILLA);
fInternalRelocs.push_back(reloc);
atomSection->fHasTextLocalRelocs = true;
if ( fOptions.makeCompressedDyldInfo() ) {
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_TEXT_ABSOLUTE32, atom.getAddress() + ref.getFixUpOffset()));
}
return true;
}
return false;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
}
}
return false;
}
template <>
bool Writer<ppc>::generatesLocalTextReloc(const ObjectFile::Reference& ref, const ObjectFile::Atom& atom, SectionInfo* atomSection)
{
macho_relocation_info<P> reloc1;
macho_relocation_info<P> reloc2;
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
switch ( ref.getKind() ) {
case ppc::kAbsLow16:
case ppc::kAbsLow14:
// a reference to the absolute address of something in this same linkage unit can be
// encoded as a local text reloc in a dylib or bundle
if ( fSlideable ) {
SectionInfo* sectInfo = (SectionInfo*)(ref.getTarget().getSection());
uint32_t targetAddr = ref.getTarget().getAddress() + ref.getTargetOffset();
reloc1.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc1.set_r_symbolnum(sectInfo->getIndex());
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(false);
reloc1.set_r_type(ref.getKind()==ppc::kAbsLow16 ? PPC_RELOC_LO16 : PPC_RELOC_LO14);
reloc2.set_r_address(targetAddr >> 16);
reloc2.set_r_symbolnum(0);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(2);
reloc2.set_r_extern(false);
reloc2.set_r_type(PPC_RELOC_PAIR);
fInternalRelocs.push_back(reloc1);
fInternalRelocs.push_back(reloc2);
atomSection->fHasTextLocalRelocs = true;
return true;
}
break;
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
if ( fSlideable ) {
SectionInfo* sectInfo = (SectionInfo*)(ref.getTarget().getSection());
uint32_t targetAddr = ref.getTarget().getAddress() + ref.getTargetOffset();
reloc1.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc1.set_r_symbolnum(sectInfo->getIndex());
reloc1.set_r_pcrel(false);
reloc1.set_r_length(2);
reloc1.set_r_extern(false);
reloc1.set_r_type(ref.getKind()==ppc::kAbsHigh16AddLow ? PPC_RELOC_HA16 : PPC_RELOC_HI16);
reloc2.set_r_address(targetAddr & 0xFFFF);
reloc2.set_r_symbolnum(0);
reloc2.set_r_pcrel(false);
reloc2.set_r_length(2);
reloc2.set_r_extern(false);
reloc2.set_r_type(PPC_RELOC_PAIR);
fInternalRelocs.push_back(reloc1);
fInternalRelocs.push_back(reloc2);
atomSection->fHasTextLocalRelocs = true;
return true;
}
}
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
}
return false;
}
template <>
bool Writer<arm>::generatesLocalTextReloc(const ObjectFile::Reference& ref, const ObjectFile::Atom& atom, SectionInfo* atomSection)
{
if ( ref.getKind() == arm::kReadOnlyPointer ) {
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// a reference to the absolute address of something in this same linkage unit can be
// encoded as a local text reloc in a dylib or bundle
if ( fSlideable ) {
macho_relocation_info<P> reloc;
SectionInfo* sectInfo = (SectionInfo*)(ref.getTarget().getSection());
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(sectInfo->getIndex());
reloc.set_r_pcrel(false);
reloc.set_r_length();
reloc.set_r_extern(false);
reloc.set_r_type(GENERIC_RELOC_VANILLA);
fInternalRelocs.push_back(reloc);
atomSection->fHasTextLocalRelocs = true;
if ( fOptions.makeCompressedDyldInfo() ) {
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_TEXT_ABSOLUTE32, atom.getAddress() + ref.getFixUpOffset()));
}
return true;
}
return false;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
}
}
return false;
}
template <>
bool Writer<x86_64>::generatesLocalTextReloc(const ObjectFile::Reference&, const ObjectFile::Atom& atom, SectionInfo* curSection)
{
// text relocs not supported (usually never needed because of RIP addressing)
return false;
}
template <>
bool Writer<ppc64>::generatesLocalTextReloc(const ObjectFile::Reference&, const ObjectFile::Atom& atom, SectionInfo* curSection)
{
// text relocs not supported
return false;
}
template <>
bool Writer<x86>::generatesExternalTextReloc(const ObjectFile::Reference& ref, const ObjectFile::Atom& atom, SectionInfo* atomSection)
{
if ( ref.getKind() == x86::kAbsolute32 ) {
macho_relocation_info<P> reloc;
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
return false;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// a reference to the absolute address of something in another linkage unit can be
// encoded as an external text reloc in a dylib or bundle
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(this->symbolIndex(ref.getTarget()));
reloc.set_r_pcrel(false);
reloc.set_r_length();
reloc.set_r_extern(true);
reloc.set_r_type(GENERIC_RELOC_VANILLA);
fExternalRelocs.push_back(reloc);
atomSection->fHasTextExternalRelocs = true;
return true;
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
}
}
return false;
}
template <>
bool Writer<x86_64>::generatesExternalTextReloc(const ObjectFile::Reference& ref, const ObjectFile::Atom& atom, SectionInfo* atomSection)
{
if ( fOptions.outputKind() == Options::kKextBundle ) {
macho_relocation_info<P> reloc;
switch ( ref.getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
switch ( ref.getKind() ) {
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel32WeakImport:
// a branch to something in another linkage unit is
// encoded as an external text reloc in a kext bundle
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(this->symbolIndex(ref.getTarget()));
reloc.set_r_pcrel(true);
reloc.set_r_length(2);
reloc.set_r_extern(true);
reloc.set_r_type(X86_64_RELOC_BRANCH);
fExternalRelocs.push_back(reloc);
atomSection->fHasTextExternalRelocs = true;
return true;
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
// a load of the GOT entry for a symbol in another linkage unit is
// encoded as an external text reloc in a kext bundle
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(this->symbolIndex(ref.getTarget()));
reloc.set_r_pcrel(true);
reloc.set_r_length(2);
reloc.set_r_extern(true);
reloc.set_r_type(X86_64_RELOC_GOT_LOAD);
fExternalRelocs.push_back(reloc);
atomSection->fHasTextExternalRelocs = true;
return true;
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
// a use of the GOT entry for a symbol in another linkage unit is
// encoded as an external text reloc in a kext bundle
reloc.set_r_address(this->relocAddressInFinalLinkedImage(atom.getAddress() + ref.getFixUpOffset(), &atom));
reloc.set_r_symbolnum(this->symbolIndex(ref.getTarget()));
reloc.set_r_pcrel(true);
reloc.set_r_length(2);
reloc.set_r_extern(true);
reloc.set_r_type(X86_64_RELOC_GOT);
fExternalRelocs.push_back(reloc);
atomSection->fHasTextExternalRelocs = true;
return true;
}
break;
}
}
return false;
}
template <typename A>
bool Writer<A>::generatesExternalTextReloc(const ObjectFile::Reference&, const ObjectFile::Atom& atom, SectionInfo* curSection)
{
return false;
}
template <typename A>
typename Writer<A>::RelocKind Writer<A>::relocationNeededInFinalLinkedImage(const ObjectFile::Atom& target) const
{
switch ( target.getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
// in main executables, the only way regular symbols are indirected is if -interposable is used
if ( fOptions.outputKind() == Options::kDynamicExecutable ) {
if ( this->shouldExport(target) && fOptions.interposable(target.getName()) )
return kRelocExternal;
else if ( fSlideable )
return kRelocInternal;
else
return kRelocNone;
}
// for flat-namespace or interposable two-level-namespace
// all references to exported symbols get indirected
else if ( this->shouldExport(target) &&
((fOptions.nameSpace() == Options::kFlatNameSpace)
|| (fOptions.nameSpace() == Options::kForceFlatNameSpace)
|| fOptions.interposable(target.getName()))
&& (target.getName() != NULL)
&& (strncmp(target.getName(), ".objc_class_", 12) != 0) ) // <rdar://problem/5254468>
return kRelocExternal;
else if ( fSlideable )
return kRelocInternal;
else
return kRelocNone;
case ObjectFile::Atom::kWeakDefinition:
// all calls to global weak definitions get indirected
if ( this->shouldExport(target) )
return kRelocExternal;
else if ( fSlideable )
return kRelocInternal;
else
return kRelocNone;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
return kRelocExternal;
case ObjectFile::Atom::kAbsoluteSymbol:
return kRelocNone;
}
return kRelocNone;
}
template <typename A>
uint64_t Writer<A>::relocAddressInFinalLinkedImage(uint64_t address, const ObjectFile::Atom* atom) const
{
// for 32-bit architectures, the r_address field in relocs
// for final linked images is the offset from the first segment
uint64_t result = address - fSegmentInfos[0]->fBaseAddress;
if ( fOptions.outputKind() == Options::kPreload ) {
// kPreload uses a virtual __HEADER segment to cover the load commands
result = address - fSegmentInfos[1]->fBaseAddress;
}
// or the offset from the first writable segment if built split-seg
if ( fOptions.splitSeg() )
result = address - fFirstWritableSegment->fBaseAddress;
if ( result > 0x7FFFFFFF ) {
throwf("image too large: address can't fit in 31-bit r_address field in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
return result;
}
template <>
uint64_t Writer<ppc64>::relocAddressInFinalLinkedImage(uint64_t address, const ObjectFile::Atom* atom) const
{
// for ppc64, the Mac OS X 10.4 dyld assumes r_address is always the offset from the base address.
// the 10.5 dyld, iterprets the r_address as:
// 1) an offset from the base address, iff there are no writable segments with a address > 4GB from base address, otherwise
// 2) an offset from the base address of the first writable segment
// For dyld, r_address is always the offset from the base address
uint64_t result;
bool badFor10_4 = false;
if ( fWritableSegmentPastFirst4GB ) {
if ( fOptions.macosxVersionMin() < ObjectFile::ReaderOptions::k10_5 )
badFor10_4 = true;
result = address - fFirstWritableSegment->fBaseAddress;
if ( result > 0xFFFFFFFF ) {
throwf("image too large: address can't fit in 32-bit r_address field in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
}
else {
result = address - fSegmentInfos[0]->fBaseAddress;
if ( (fOptions.macosxVersionMin() < ObjectFile::ReaderOptions::k10_5) && (result > 0x7FFFFFFF) )
badFor10_4 = true;
}
if ( badFor10_4 ) {
throwf("image or pagezero_size too large for Mac OS X 10.4: address can't fit in 31-bit r_address field for %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
return result;
}
template <> bool Writer<ppc>::preboundLazyPointerType(uint8_t* type) { *type = PPC_RELOC_PB_LA_PTR; return true; }
template <> bool Writer<ppc64>::preboundLazyPointerType(uint8_t* type) { throw "prebinding not supported"; }
template <> bool Writer<x86>::preboundLazyPointerType(uint8_t* type) { *type = GENERIC_RELOC_PB_LA_PTR; return true; }
template <> bool Writer<x86_64>::preboundLazyPointerType(uint8_t* type) { throw "prebinding not supported"; }
template <> bool Writer<arm>::preboundLazyPointerType(uint8_t* type) { *type = ARM_RELOC_PB_LA_PTR; return true; }
template <typename A>
void Writer<A>::buildExecutableFixups()
{
if ( fIndirectTableAtom != NULL )
fIndirectTableAtom->fTable.reserve(50); // minimize reallocations
std::vector<SegmentInfo*>& segmentInfos = fSegmentInfos;
const int segCount = segmentInfos.size();
for(int i=0; i < segCount; ++i) {
SegmentInfo* curSegment = segmentInfos[i];
std::vector<SectionInfo*>& sectionInfos = curSegment->fSections;
const int sectionCount = sectionInfos.size();
for(int j=0; j < sectionCount; ++j) {
SectionInfo* curSection = sectionInfos[j];
//fprintf(stderr, "starting section %s\n", curSection->fSectionName);
std::vector<ObjectFile::Atom*>& sectionAtoms = curSection->fAtoms;
if ( ! curSection->fAllZeroFill ) {
if ( curSection->fAllNonLazyPointers || curSection->fAllLazyPointers || curSection->fAllLazyDylibPointers
|| curSection->fAllStubs || curSection->fAllSelfModifyingStubs ) {
if ( fIndirectTableAtom != NULL )
curSection->fIndirectSymbolOffset = fIndirectTableAtom->fTable.size();
}
const int atomCount = sectionAtoms.size();
for (int k=0; k < atomCount; ++k) {
ObjectFile::Atom* atom = sectionAtoms[k];
std::vector<ObjectFile::Reference*>& refs = atom->getReferences();
const int refCount = refs.size();
//fprintf(stderr, "atom %s has %d references in section %s, %p\n", atom->getDisplayName(), refCount, curSection->fSectionName, atom->getSection());
if ( curSection->fAllNonLazyPointers && (refCount == 0) ) {
// handle imageloadercache GOT slot
uint32_t offsetInSection = atom->getSectionOffset();
uint32_t indexInSection = offsetInSection / sizeof(pint_t);
uint32_t indirectTableIndex = indexInSection + curSection->fIndirectSymbolOffset;
// use INDIRECT_SYMBOL_ABS so 10.5 dyld will leave value as zero
IndirectEntry entry = { indirectTableIndex, INDIRECT_SYMBOL_ABS };
//fprintf(stderr,"fIndirectTableAtom->fTable.push_back(tableIndex=%d, symIndex=0x%X, section=%s)\n",
// indirectTableIndex, INDIRECT_SYMBOL_LOCAL, curSection->fSectionName);
fIndirectTableAtom->fTable.push_back(entry);
}
for (int l=0; l < refCount; ++l) {
ObjectFile::Reference* ref = refs[l];
if ( (fOptions.outputKind() != Options::kKextBundle) &&
(curSection->fAllNonLazyPointers || curSection->fAllLazyPointers || curSection->fAllLazyDylibPointers) ) {
// if atom is in (non)lazy_pointer section, this is encoded as an indirect symbol
if ( atom->getSize() != sizeof(pint_t) ) {
warning("wrong size pointer atom %s from file %s", atom->getDisplayName(), atom->getFile()->getPath());
}
ObjectFile::Atom* pointerTarget = &(ref->getTarget());
if ( curSection->fAllLazyPointers || curSection->fAllLazyDylibPointers ) {
pointerTarget = ((LazyPointerAtom<A>*)atom)->getTarget();
}
uint32_t offsetInSection = atom->getSectionOffset();
uint32_t indexInSection = offsetInSection / sizeof(pint_t);
uint32_t undefinedSymbolIndex = INDIRECT_SYMBOL_LOCAL;
if (atom == fFastStubGOTAtom)
undefinedSymbolIndex = INDIRECT_SYMBOL_ABS;
else if ( this->relocationNeededInFinalLinkedImage(*pointerTarget) == kRelocExternal )
undefinedSymbolIndex = this->symbolIndex(*pointerTarget);
uint32_t indirectTableIndex = indexInSection + curSection->fIndirectSymbolOffset;
IndirectEntry entry = { indirectTableIndex, undefinedSymbolIndex };
//fprintf(stderr,"fIndirectTableAtom->fTable.push_back(tableIndex=%d, symIndex=0x%X, section=%s)\n",
// indirectTableIndex, undefinedSymbolIndex, curSection->fSectionName);
fIndirectTableAtom->fTable.push_back(entry);
if ( curSection->fAllLazyPointers || curSection->fAllLazyDylibPointers ) {
uint8_t preboundLazyType;
if ( fOptions.prebind() && (fDyldClassicHelperAtom != NULL)
&& curSection->fAllLazyPointers && preboundLazyPointerType(&preboundLazyType) ) {
// this is a prebound image, need special relocs for dyld to reset lazy pointers if prebinding is invalid
macho_scattered_relocation_info<P> pblaReloc;
pblaReloc.set_r_scattered(true);
pblaReloc.set_r_pcrel(false);
pblaReloc.set_r_length();
pblaReloc.set_r_type(preboundLazyType);
pblaReloc.set_r_address(relocAddressInFinalLinkedImage(atom->getAddress(), atom));
pblaReloc.set_r_value(fDyldClassicHelperAtom->getAddress());
fInternalRelocs.push_back(*((macho_relocation_info<P>*)&pblaReloc));
}
else if ( fSlideable ) {
// this is a non-prebound dylib/bundle, need vanilla internal relocation to fix up binding handler if image slides
macho_relocation_info<P> dyldHelperReloc;
uint32_t sectionNum = 1;
if ( fDyldClassicHelperAtom != NULL )
sectionNum = ((SectionInfo*)(fDyldClassicHelperAtom->getSection()))->getIndex();
//fprintf(stderr, "lazy pointer reloc, section index=%u, section name=%s\n", sectionNum, curSection->fSectionName);
dyldHelperReloc.set_r_address(relocAddressInFinalLinkedImage(atom->getAddress(), atom));
dyldHelperReloc.set_r_symbolnum(sectionNum);
dyldHelperReloc.set_r_pcrel(false);
dyldHelperReloc.set_r_length();
dyldHelperReloc.set_r_extern(false);
dyldHelperReloc.set_r_type(GENERIC_RELOC_VANILLA);
fInternalRelocs.push_back(dyldHelperReloc);
if ( fOptions.makeCompressedDyldInfo() ) {
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_POINTER,atom->getAddress()));
}
}
if ( fOptions.makeCompressedDyldInfo() ) {
uint8_t type = BIND_TYPE_POINTER;
uint64_t addresss = atom->getAddress() + ref->getFixUpOffset();
if ( pointerTarget->getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition ) {
// This is a referece to a weak def in some dylib (e.g. operator new)
// need to bind into to directly bind this
// later weak binding info may override
int ordinal = compressedOrdinalForImortedAtom(pointerTarget);
fBindingInfo.push_back(BindingInfo(type, ordinal, pointerTarget->getName(), false, addresss, 0));
}
if ( targetRequiresWeakBinding(*pointerTarget) ) {
// note: lazy pointers to weak symbols are not bound lazily
fWeakBindingInfo.push_back(BindingInfo(type, pointerTarget->getName(), false, addresss, 0));
}
}
}
if ( curSection->fAllNonLazyPointers && fOptions.makeCompressedDyldInfo() ) {
if ( pointerTarget != NULL ) {
switch ( this->relocationNeededInFinalLinkedImage(*pointerTarget) ) {
case kRelocNone:
// no rebase or binding info needed
break;
case kRelocInternal:
// a non-lazy pointer that has been optimized to LOCAL needs rebasing info
// but not the magic fFastStubGOTAtom atom
if (atom != fFastStubGOTAtom)
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_POINTER,atom->getAddress()));
break;
case kRelocExternal:
{
uint8_t type = BIND_TYPE_POINTER;
uint64_t addresss = atom->getAddress();
if ( targetRequiresWeakBinding(ref->getTarget()) ) {
fWeakBindingInfo.push_back(BindingInfo(type, ref->getTarget().getName(), false, addresss, 0));
// if this is a non-lazy pointer to a weak definition within this linkage unit
// the pointer needs to initially point within linkage unit and have
// rebase command to slide it.
if ( ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition ) {
// unless if this is a hybrid format, in which case the non-lazy pointer
// is zero on disk. So use a bind instead of a rebase to set initial value
if ( fOptions.makeClassicDyldInfo() )
fBindingInfo.push_back(BindingInfo(type, BIND_SPECIAL_DYLIB_SELF, ref->getTarget().getName(), false, addresss, 0));
else
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_POINTER,atom->getAddress()));
}
// if this is a non-lazy pointer to a weak definition in a dylib,
// the pointer needs to initially bind to the dylib
else if ( ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition ) {
int ordinal = compressedOrdinalForImortedAtom(pointerTarget);
fBindingInfo.push_back(BindingInfo(BIND_TYPE_POINTER, ordinal, pointerTarget->getName(), false, addresss, 0));
}
}
else {
int ordinal = compressedOrdinalForImortedAtom(pointerTarget);
bool weak_import = fWeakImportMap[pointerTarget];
fBindingInfo.push_back(BindingInfo(type, ordinal, ref->getTarget().getName(), weak_import, addresss, 0));
}
}
}
}
}
}
else if ( (ref->getKind() == A::kPointer) || (ref->getKind() == A::kPointerWeakImport) ) {
if ( fSlideable && ((curSegment->fInitProtection & VM_PROT_WRITE) == 0) ) {
if ( fOptions.allowTextRelocs() ) {
if ( fOptions.warnAboutTextRelocs() )
warning("text reloc in %s to %s", atom->getDisplayName(), ref->getTargetName());
}
else {
throwf("pointer in read-only segment not allowed in slidable image, used in %s from %s",
atom->getDisplayName(), atom->getFile()->getPath());
}
}
switch ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) ) {
case kRelocNone:
// no reloc needed
break;
case kRelocInternal:
{
macho_relocation_info<P> internalReloc;
SectionInfo* sectInfo = (SectionInfo*)ref->getTarget().getSection();
uint32_t sectionNum = sectInfo->getIndex();
// special case _mh_dylib_header and friends which are not in any real section
if ( (sectionNum ==0) && sectInfo->fVirtualSection && (strcmp(sectInfo->fSectionName, "._mach_header") == 0) )
sectionNum = 1;
internalReloc.set_r_address(this->relocAddressInFinalLinkedImage(atom->getAddress() + ref->getFixUpOffset(), atom));
internalReloc.set_r_symbolnum(sectionNum);
internalReloc.set_r_pcrel(false);
internalReloc.set_r_length();
internalReloc.set_r_extern(false);
internalReloc.set_r_type(GENERIC_RELOC_VANILLA);
fInternalRelocs.push_back(internalReloc);
if ( fOptions.makeCompressedDyldInfo() ) {
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_POINTER, atom->getAddress() + ref->getFixUpOffset()));
}
}
break;
case kRelocExternal:
{
macho_relocation_info<P> externalReloc;
externalReloc.set_r_address(this->relocAddressInFinalLinkedImage(atom->getAddress() + ref->getFixUpOffset(), atom));
externalReloc.set_r_symbolnum(this->symbolIndex(ref->getTarget()));
externalReloc.set_r_pcrel(false);
externalReloc.set_r_length();
externalReloc.set_r_extern(true);
externalReloc.set_r_type(GENERIC_RELOC_VANILLA);
fExternalRelocs.push_back(externalReloc);
if ( fOptions.makeCompressedDyldInfo() ) {
int64_t addend = ref->getTargetOffset();
uint64_t addresss = atom->getAddress() + ref->getFixUpOffset();
if ( !fOptions.makeClassicDyldInfo() ) {
if ( ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition ) {
// pointers to internal weak defs need a rebase
fRebaseInfo.push_back(RebaseInfo(REBASE_TYPE_POINTER, addresss));
}
}
uint8_t type = BIND_TYPE_POINTER;
if ( targetRequiresWeakBinding(ref->getTarget()) ) {
fWeakBindingInfo.push_back(BindingInfo(type, ref->getTarget().getName(), false, addresss, addend));
if ( fOptions.makeClassicDyldInfo() && (ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) ) {
// hybrid linkedit puts addend in data, so we need bind phase to reset pointer to local definifion
fBindingInfo.push_back(BindingInfo(type, BIND_SPECIAL_DYLIB_SELF, ref->getTarget().getName(), false, addresss, addend));
}
// if this is a pointer to a weak definition in a dylib,
// the pointer needs to initially bind to the dylib
else if ( ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition ) {
int ordinal = compressedOrdinalForImortedAtom(&ref->getTarget());
fBindingInfo.push_back(BindingInfo(BIND_TYPE_POINTER, ordinal, ref->getTarget().getName(), false, addresss, addend));
}
}
else {
int ordinal = compressedOrdinalForImortedAtom(&ref->getTarget());
bool weak_import = fWeakImportMap[&(ref->getTarget())];
fBindingInfo.push_back(BindingInfo(type, ordinal, ref->getTarget().getName(), weak_import, addresss, addend));
}
}
}
break;
}
}
else if ( this->illegalRelocInFinalLinkedImage(*ref) ) {
// new x86 stubs always require text relocs
if ( curSection->fAllStubs || curSection->fAllStubHelpers ) {
if ( this->generatesLocalTextReloc(*ref, *atom, curSection) ) {
// relocs added to fInternalRelocs
}
}
else if ( fOptions.allowTextRelocs() && !atom->getSegment().isContentWritable() ) {
if ( fOptions.warnAboutTextRelocs() )
warning("text reloc in %s to %s", atom->getDisplayName(), ref->getTargetName());
if ( this->generatesLocalTextReloc(*ref, *atom, curSection) ) {
// relocs added to fInternalRelocs
}
else if ( this->generatesExternalTextReloc(*ref, *atom, curSection) ) {
// relocs added to fExternalRelocs
}
else {
throwf("relocation used in %s from %s not allowed in slidable image", atom->getDisplayName(), atom->getFile()->getPath());
}
}
else {
throwf("absolute addressing (perhaps -mdynamic-no-pic) used in %s from %s not allowed in slidable image. "
"Use '-read_only_relocs suppress' to enable text relocs", atom->getDisplayName(), atom->getFile()->getPath());
}
}
}
if ( curSection->fAllSelfModifyingStubs || curSection->fAllStubs ) {
ObjectFile::Atom* stubTarget = ((StubAtom<A>*)atom)->getTarget();
uint32_t undefinedSymbolIndex = (stubTarget != NULL) ? this->symbolIndex(*stubTarget) : INDIRECT_SYMBOL_ABS;
uint32_t offsetInSection = atom->getSectionOffset();
uint32_t indexInSection = offsetInSection / atom->getSize();
uint32_t indirectTableIndex = indexInSection + curSection->fIndirectSymbolOffset;
IndirectEntry entry = { indirectTableIndex, undefinedSymbolIndex };
//fprintf(stderr,"for stub: fIndirectTableAtom->fTable.add(%d-%d => 0x%X-%s), size=%lld\n", indexInSection, indirectTableIndex, undefinedSymbolIndex, stubTarget->getName(), atom->getSize());
fIndirectTableAtom->fTable.push_back(entry);
}
}
}
}
}
if ( fSplitCodeToDataContentAtom != NULL )
fSplitCodeToDataContentAtom->encode();
if ( fCompressedRebaseInfoAtom != NULL )
fCompressedRebaseInfoAtom->encode();
if ( fCompressedBindingInfoAtom != NULL )
fCompressedBindingInfoAtom->encode();
if ( fCompressedWeakBindingInfoAtom != NULL )
fCompressedWeakBindingInfoAtom->encode();
if ( fCompressedLazyBindingInfoAtom != NULL )
fCompressedLazyBindingInfoAtom->encode();
if ( fCompressedExportInfoAtom != NULL )
fCompressedExportInfoAtom->encode();
}
template <>
void Writer<ppc>::addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref)
{
switch ( (ppc::ReferenceKinds)ref->getKind() ) {
case ppc::kPICBaseHigh16:
fSplitCodeToDataContentAtom->addPPCHi16Location(atom, ref->getFixUpOffset());
break;
case ppc::kPointerDiff32:
fSplitCodeToDataContentAtom->add32bitPointerLocation(atom, ref->getFixUpOffset());
break;
case ppc::kPointerDiff64:
fSplitCodeToDataContentAtom->add64bitPointerLocation(atom, ref->getFixUpOffset());
break;
case ppc::kNoFixUp:
case ppc::kGroupSubordinate:
case ppc::kPointer:
case ppc::kPointerWeakImport:
case ppc::kPICBaseLow16:
case ppc::kPICBaseLow14:
// ignore
break;
default:
warning("codegen with reference kind %d in %s prevents image from loading in dyld shared cache", ref->getKind(), atom->getDisplayName());
fSplitCodeToDataContentAtom->setCantEncode();
}
}
template <>
void Writer<ppc64>::addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref)
{
switch ( (ppc64::ReferenceKinds)ref->getKind() ) {
case ppc64::kPICBaseHigh16:
fSplitCodeToDataContentAtom->addPPCHi16Location(atom, ref->getFixUpOffset());
break;
case ppc64::kPointerDiff32:
fSplitCodeToDataContentAtom->add32bitPointerLocation(atom, ref->getFixUpOffset());
break;
case ppc64::kPointerDiff64:
fSplitCodeToDataContentAtom->add64bitPointerLocation(atom, ref->getFixUpOffset());
break;
case ppc64::kNoFixUp:
case ppc64::kGroupSubordinate:
case ppc64::kPointer:
case ppc64::kPointerWeakImport:
case ppc64::kPICBaseLow16:
case ppc64::kPICBaseLow14:
// ignore
break;
default:
warning("codegen with reference kind %d in %s prevents image from loading in dyld shared cache", ref->getKind(), atom->getDisplayName());
fSplitCodeToDataContentAtom->setCantEncode();
}
}
template <>
void Writer<x86>::addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref)
{
switch ( (x86::ReferenceKinds)ref->getKind() ) {
case x86::kPointerDiff:
case x86::kImageOffset32:
if ( strcmp(ref->getTarget().getSegment().getName(), "__IMPORT") == 0 )
fSplitCodeToDataContentAtom->add32bitImportLocation(atom, ref->getFixUpOffset());
else
fSplitCodeToDataContentAtom->add32bitPointerLocation(atom, ref->getFixUpOffset());
break;
case x86::kNoFixUp:
case x86::kGroupSubordinate:
case x86::kPointer:
case x86::kPointerWeakImport:
// ignore
break;
case x86::kPCRel32:
case x86::kPCRel32WeakImport:
if ( (&(ref->getTarget().getSegment()) == &Segment::fgImportSegment)
|| (&(ref->getTarget().getSegment()) == &Segment::fgROImportSegment) ) {
fSplitCodeToDataContentAtom->add32bitImportLocation(atom, ref->getFixUpOffset());
break;
}
// fall into warning case
default:
if ( fOptions.makeCompressedDyldInfo() && (ref->getKind() == x86::kAbsolute32) ) {
// will be encoded in rebase info
}
else {
warning("codegen in %s (offset 0x%08llX) prevents image from loading in dyld shared cache", atom->getDisplayName(), ref->getFixUpOffset());
fSplitCodeToDataContentAtom->setCantEncode();
}
}
}
template <>
void Writer<x86_64>::addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref)
{
switch ( (x86_64::ReferenceKinds)ref->getKind() ) {
case x86_64::kPCRel32:
case x86_64::kPCRel32_1:
case x86_64::kPCRel32_2:
case x86_64::kPCRel32_4:
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
case x86_64::kPointerDiff32:
case x86_64::kImageOffset32:
fSplitCodeToDataContentAtom->add32bitPointerLocation(atom, ref->getFixUpOffset());
break;
case x86_64::kPointerDiff:
fSplitCodeToDataContentAtom->add64bitPointerLocation(atom, ref->getFixUpOffset());
break;
case x86_64::kNoFixUp:
case x86_64::kGroupSubordinate:
case x86_64::kPointer:
case x86_64::kGOTNoFixUp:
// ignore
break;
default:
warning("codegen in %s with kind %d prevents image from loading in dyld shared cache", atom->getDisplayName(), ref->getKind());
fSplitCodeToDataContentAtom->setCantEncode();
}
}
template <>
void Writer<arm>::addCrossSegmentRef(const ObjectFile::Atom* atom, const ObjectFile::Reference* ref)
{
switch ( (arm::ReferenceKinds)ref->getKind() ) {
case arm::kPointerDiff:
fSplitCodeToDataContentAtom->add32bitPointerLocation(atom, ref->getFixUpOffset());
break;
case arm::kNoFixUp:
case arm::kGroupSubordinate:
case arm::kPointer:
case arm::kPointerWeakImport:
case arm::kReadOnlyPointer:
// ignore
break;
default:
warning("codegen in %s prevents image from loading in dyld shared cache", atom->getDisplayName());
fSplitCodeToDataContentAtom->setCantEncode();
}
}
template <typename A>
bool Writer<A>::segmentsCanSplitApart(const ObjectFile::Atom& from, const ObjectFile::Atom& to)
{
switch ( to.getDefinitionKind() ) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kTentativeDefinition:
// segments with same permissions slide together
return ( (from.getSegment().isContentExecutable() != to.getSegment().isContentExecutable())
|| (from.getSegment().isContentWritable() != to.getSegment().isContentWritable()) );
}
throw "ld64 internal error";
}
template <>
void Writer<ppc>::writeNoOps(int fd, uint32_t from, uint32_t to)
{
uint32_t ppcNop;
OSWriteBigInt32(&ppcNop, 0, 0x60000000);
for (uint32_t p=from; p < to; p += 4)
::pwrite(fd, &ppcNop, 4, p);
}
template <>
void Writer<ppc64>::writeNoOps(int fd, uint32_t from, uint32_t to)
{
uint32_t ppcNop;
OSWriteBigInt32(&ppcNop, 0, 0x60000000);
for (uint32_t p=from; p < to; p += 4)
::pwrite(fd, &ppcNop, 4, p);
}
template <>
void Writer<x86>::writeNoOps(int fd, uint32_t from, uint32_t to)
{
uint8_t x86Nop = 0x90;
for (uint32_t p=from; p < to; ++p)
::pwrite(fd, &x86Nop, 1, p);
}
template <>
void Writer<x86_64>::writeNoOps(int fd, uint32_t from, uint32_t to)
{
uint8_t x86Nop = 0x90;
for (uint32_t p=from; p < to; ++p)
::pwrite(fd, &x86Nop, 1, p);
}
template <>
void Writer<arm>::writeNoOps(int fd, uint32_t from, uint32_t to)
{
// FIXME: need thumb nop?
uint32_t armNop;
OSWriteLittleInt32(&armNop, 0, 0xe1a00000);
for (uint32_t p=from; p < to; p += 4)
::pwrite(fd, &armNop, 4, p);
}
template <>
void Writer<ppc>::copyNoOps(uint8_t* from, uint8_t* to)
{
for (uint8_t* p=from; p < to; p += 4)
OSWriteBigInt32((uint32_t*)p, 0, 0x60000000);
}
template <>
void Writer<ppc64>::copyNoOps(uint8_t* from, uint8_t* to)
{
for (uint8_t* p=from; p < to; p += 4)
OSWriteBigInt32((uint32_t*)p, 0, 0x60000000);
}
template <>
void Writer<x86>::copyNoOps(uint8_t* from, uint8_t* to)
{
for (uint8_t* p=from; p < to; ++p)
*p = 0x90;
}
template <>
void Writer<x86_64>::copyNoOps(uint8_t* from, uint8_t* to)
{
for (uint8_t* p=from; p < to; ++p)
*p = 0x90;
}
template <>
void Writer<arm>::copyNoOps(uint8_t* from, uint8_t* to)
{
// fixme: need thumb nop?
for (uint8_t* p=from; p < to; p += 4)
OSWriteBigInt32((uint32_t*)p, 0, 0xe1a00000);
}
static const char* stringName(const char* str)
{
if ( strncmp(str, "cstring=", 8) == 0) {
static char buffer[1024];
char* t = buffer;
*t++ = '\"';
for(const char*s = &str[8]; *s != '\0'; ++s) {
switch(*s) {
case '\n':
*t++ = '\\';
*t++ = 'n';
break;
case '\t':
*t++ = '\\';
*t++ = 't';
break;
default:
*t++ = *s;
break;
}
if ( t > &buffer[1020] ) {
*t++= '\"';
*t++= '.';
*t++= '.';
*t++= '.';
*t++= '\0';
return buffer;
}
}
*t++= '\"';
*t++= '\0';
return buffer;
}
else {
return str;
}
}
template <> const char* Writer<ppc>::getArchString() { return "ppc"; }
template <> const char* Writer<ppc64>::getArchString() { return "ppc64"; }
template <> const char* Writer<x86>::getArchString() { return "i386"; }
template <> const char* Writer<x86_64>::getArchString() { return "x86_64"; }
template <> const char* Writer<arm>::getArchString() { return "arm"; }
template <typename A>
void Writer<A>::writeMap()
{
if ( fOptions.generatedMapPath() != NULL ) {
FILE* mapFile = fopen(fOptions.generatedMapPath(), "w");
if ( mapFile != NULL ) {
// write output path
fprintf(mapFile, "# Path: %s\n", fFilePath);
// write output architecure
fprintf(mapFile, "# Arch: %s\n", getArchString());
// write UUID
if ( fUUIDAtom != NULL ) {
const uint8_t* uuid = fUUIDAtom->getUUID();
fprintf(mapFile, "# UUID: %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X \n",
uuid[0], uuid[1], uuid[2], uuid[3], uuid[4], uuid[5], uuid[6], uuid[7],
uuid[8], uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14], uuid[15]);
}
// write table of object files
std::map<ObjectFile::Reader*, uint32_t> readerToOrdinal;
std::map<uint32_t, ObjectFile::Reader*> ordinalToReader;
std::map<ObjectFile::Reader*, uint32_t> readerToFileOrdinal;
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
std::vector<SectionInfo*>& sectionInfos = (*segit)->fSections;
for (std::vector<SectionInfo*>::iterator secit = sectionInfos.begin(); secit != sectionInfos.end(); ++secit) {
if ( ! (*secit)->fVirtualSection ) {
std::vector<ObjectFile::Atom*>& sectionAtoms = (*secit)->fAtoms;
for (std::vector<ObjectFile::Atom*>::iterator ait = sectionAtoms.begin(); ait != sectionAtoms.end(); ++ait) {
ObjectFile::Reader* reader = (*ait)->getFile();
uint32_t readerOrdinal = (*ait)->getOrdinal();
std::map<ObjectFile::Reader*, uint32_t>::iterator pos = readerToOrdinal.find(reader);
if ( pos == readerToOrdinal.end() ) {
readerToOrdinal[reader] = readerOrdinal;
ordinalToReader[readerOrdinal] = reader;
}
}
}
}
}
fprintf(mapFile, "# Object files:\n");
fprintf(mapFile, "[%3u] %s\n", 0, "linker synthesized");
uint32_t fileIndex = 0;
readerToFileOrdinal[this] = fileIndex++;
for(std::map<uint32_t, ObjectFile::Reader*>::iterator it = ordinalToReader.begin(); it != ordinalToReader.end(); ++it) {
if ( it->first != 0 ) {
fprintf(mapFile, "[%3u] %s\n", fileIndex, it->second->getPath());
readerToFileOrdinal[it->second] = fileIndex++;
}
}
// write table of sections
fprintf(mapFile, "# Sections:\n");
fprintf(mapFile, "# Address\tSize \tSegment\tSection\n");
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
std::vector<SectionInfo*>& sectionInfos = (*segit)->fSections;
for (std::vector<SectionInfo*>::iterator secit = sectionInfos.begin(); secit != sectionInfos.end(); ++secit) {
if ( ! (*secit)->fVirtualSection ) {
SectionInfo* sect = *secit;
fprintf(mapFile, "0x%08llX\t0x%08llX\t%s\t%s\n", sect->getBaseAddress(), sect->fSize,
(*segit)->fName, sect->fSectionName);
}
}
}
// write table of symbols
fprintf(mapFile, "# Symbols:\n");
fprintf(mapFile, "# Address\tSize \tFile Name\n");
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
std::vector<SectionInfo*>& sectionInfos = (*segit)->fSections;
for (std::vector<SectionInfo*>::iterator secit = sectionInfos.begin(); secit != sectionInfos.end(); ++secit) {
if ( ! (*secit)->fVirtualSection ) {
std::vector<ObjectFile::Atom*>& sectionAtoms = (*secit)->fAtoms;
bool isCstring = (strcmp((*secit)->fSectionName, "__cstring") == 0);
for (std::vector<ObjectFile::Atom*>::iterator ait = sectionAtoms.begin(); ait != sectionAtoms.end(); ++ait) {
ObjectFile::Atom* atom = *ait;
fprintf(mapFile, "0x%08llX\t0x%08llX\t[%3u] %s\n", atom->getAddress(), atom->getSize(),
readerToFileOrdinal[atom->getFile()], isCstring ? stringName(atom->getDisplayName()): atom->getDisplayName());
}
}
}
}
fclose(mapFile);
}
else {
warning("could not write map file: %s\n", fOptions.generatedMapPath());
}
}
}
static const char* sCleanupFile = NULL;
static void cleanup(int sig)
{
::signal(sig, SIG_DFL);
if ( sCleanupFile != NULL ) {
::unlink(sCleanupFile);
}
if ( sig == SIGINT )
::exit(1);
}
template <typename A>
uint64_t Writer<A>::writeAtoms()
{
// for UNIX conformance, error if file exists and is not writable
if ( (access(fFilePath, F_OK) == 0) && (access(fFilePath, W_OK) == -1) )
throwf("can't write output file: %s", fFilePath);
int permissions = 0777;
if ( fOptions.outputKind() == Options::kObjectFile )
permissions = 0666;
// Calling unlink first assures the file is gone so that open creates it with correct permissions
// It also handles the case where fFilePath file is not writable but its directory is
// And it means we don't have to truncate the file when done writing (in case new is smaller than old)
(void)unlink(fFilePath);
// try to allocate buffer for entire output file content
int fd = -1;
SectionInfo* lastSection = fSegmentInfos.back()->fSections.back();
uint64_t fileBufferSize = (lastSection->fFileOffset + lastSection->fSize + 4095) & (-4096);
uint8_t* wholeBuffer = (uint8_t*)calloc(fileBufferSize, 1);
uint8_t* atomBuffer = NULL;
bool streaming = false;
if ( wholeBuffer == NULL ) {
fd = open(fFilePath, O_CREAT | O_WRONLY | O_TRUNC, permissions);
if ( fd == -1 )
throwf("can't open output file for writing: %s, errno=%d", fFilePath, errno);
atomBuffer = new uint8_t[(fLargestAtomSize+4095) & (-4096)];
streaming = true;
// install signal handlers to delete output file if program is killed
sCleanupFile = fFilePath;
::signal(SIGINT, cleanup);
::signal(SIGBUS, cleanup);
::signal(SIGSEGV, cleanup);
}
uint32_t size = 0;
uint32_t end = 0;
try {
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
std::vector<SectionInfo*>& sectionInfos = curSegment->fSections;
for (std::vector<SectionInfo*>::iterator secit = sectionInfos.begin(); secit != sectionInfos.end(); ++secit) {
SectionInfo* curSection = *secit;
std::vector<ObjectFile::Atom*>& sectionAtoms = curSection->fAtoms;
//printf("writing with max atom size 0x%X\n", fLargestAtomSize);
//fprintf(stderr, "writing %lu atoms for section %p %s at file offset 0x%08llX\n", sectionAtoms.size(), curSection, curSection->fSectionName, curSection->fFileOffset);
if ( ! curSection->fAllZeroFill ) {
bool needsNops = ((strcmp(curSection->fSegmentName, "__TEXT") == 0) && (strncmp(curSection->fSectionName, "__text", 6) == 0));
for (std::vector<ObjectFile::Atom*>::iterator ait = sectionAtoms.begin(); ait != sectionAtoms.end(); ++ait) {
ObjectFile::Atom* atom = *ait;
if ( (atom->getDefinitionKind() != ObjectFile::Atom::kExternalDefinition)
&& (atom->getDefinitionKind() != ObjectFile::Atom::kExternalWeakDefinition)
&& (atom->getDefinitionKind() != ObjectFile::Atom::kAbsoluteSymbol) ) {
uint32_t fileOffset = curSection->fFileOffset + atom->getSectionOffset();
if ( fileOffset != end ) {
//fprintf(stderr, "writing %d pad bytes, needsNops=%d\n", fileOffset-end, needsNops);
if ( needsNops ) {
// fill gaps with no-ops
if ( streaming )
writeNoOps(fd, end, fileOffset);
else
copyNoOps(&wholeBuffer[end], &wholeBuffer[fileOffset]);
}
else if ( streaming ) {
// zero fill gaps
if ( (fileOffset-end) == 4 ) {
uint32_t zero = 0;
::pwrite(fd, &zero, 4, end);
}
else {
uint8_t zero = 0x00;
for (uint32_t p=end; p < fileOffset; ++p)
::pwrite(fd, &zero, 1, p);
}
}
}
uint64_t atomSize = atom->getSize();
if ( streaming ) {
if ( atomSize > fLargestAtomSize )
throwf("ld64 internal error: atom \"%s\"is larger than expected 0x%llX > 0x%X",
atom->getDisplayName(), atomSize, fLargestAtomSize);
}
else {
if ( fileOffset > fileBufferSize )
throwf("ld64 internal error: atom \"%s\" has file offset greater thatn expceted 0x%X > 0x%llX",
atom->getDisplayName(), fileOffset, fileBufferSize);
}
uint8_t* buffer = streaming ? atomBuffer : &wholeBuffer[fileOffset];
end = fileOffset+atomSize;
// copy raw bytes
atom->copyRawContent(buffer);
// apply any fix-ups
try {
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator it=references.begin(); it != references.end(); it++) {
ObjectFile::Reference* ref = *it;
if ( fOptions.outputKind() == Options::kObjectFile ) {
// doing ld -r
// skip fix-ups for undefined targets
if ( &(ref->getTarget()) != NULL )
this->fixUpReferenceRelocatable(ref, atom, buffer);
}
else {
// producing final linked image
this->fixUpReferenceFinal(ref, atom, buffer);
}
}
}
catch (const char* msg) {
throwf("%s in %s from %s", msg, atom->getDisplayName(), atom->getFile()->getPath());
}
//fprintf(stderr, "writing 0x%08X -> 0x%08X (addr=0x%llX, size=0x%llX), atom %p %s from %s\n",
// fileOffset, end, atom->getAddress(), atom->getSize(), atom, atom->getDisplayName(), atom->getFile()->getPath());
if ( streaming ) {
// write out
::pwrite(fd, buffer, atomSize, fileOffset);
}
else {
if ( (fileOffset + atomSize) > size )
size = fileOffset + atomSize;
}
}
}
}
}
}
// update content based UUID
if ( fOptions.getUUIDMode() == Options::kUUIDContent ) {
uint8_t digest[CC_MD5_DIGEST_LENGTH];
if ( streaming ) {
// if output file file did not fit in memory, re-read file to generate md5 hash
uint32_t kMD5BufferSize = 16*1024;
uint8_t* md5Buffer = (uint8_t*)::malloc(kMD5BufferSize);
if ( md5Buffer != NULL ) {
CC_MD5_CTX md5State;
CC_MD5_Init(&md5State);
::lseek(fd, 0, SEEK_SET);
ssize_t len;
while ( (len = ::read(fd, md5Buffer, kMD5BufferSize)) > 0 )
CC_MD5_Update(&md5State, md5Buffer, len);
CC_MD5_Final(digest, &md5State);
::free(md5Buffer);
}
else {
// if malloc fails, fall back to random uuid
::uuid_generate_random(digest);
}
fUUIDAtom->setContent(digest);
uint32_t uuidOffset = ((SectionInfo*)fUUIDAtom->getSection())->fFileOffset + fUUIDAtom->getSectionOffset();
fUUIDAtom->copyRawContent(atomBuffer);
::pwrite(fd, atomBuffer, fUUIDAtom->getSize(), uuidOffset);
}
else {
// if output file fit in memory, just genrate an md5 hash in memory
#if 1
// temp hack for building on Tiger
CC_MD5_CTX md5State;
CC_MD5_Init(&md5State);
CC_MD5_Update(&md5State, wholeBuffer, size);
CC_MD5_Final(digest, &md5State);
#else
CC_MD5(wholeBuffer, size, digest);
#endif
fUUIDAtom->setContent(digest);
uint32_t uuidOffset = ((SectionInfo*)fUUIDAtom->getSection())->fFileOffset + fUUIDAtom->getSectionOffset();
fUUIDAtom->copyRawContent(&wholeBuffer[uuidOffset]);
}
}
}
catch (...) {
if ( sCleanupFile != NULL )
::unlink(sCleanupFile);
throw;
}
// finish up
if ( streaming ) {
delete [] atomBuffer;
close(fd);
// restore default signal handlers
sCleanupFile = NULL;
::signal(SIGINT, SIG_DFL);
::signal(SIGBUS, SIG_DFL);
::signal(SIGSEGV, SIG_DFL);
}
else {
// write whole output file in one chunk
fd = open(fFilePath, O_CREAT | O_WRONLY | O_TRUNC, permissions);
if ( fd == -1 )
throwf("can't open output file for writing: %s, errno=%d", fFilePath, errno);
::pwrite(fd, wholeBuffer, size, 0);
close(fd);
delete [] wholeBuffer;
}
return end;
}
template <>
void Writer<arm>::fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
int64_t displacement;
int64_t baseAddr;
uint32_t instruction;
uint32_t newInstruction;
uint64_t targetAddr = 0;
uint32_t firstDisp;
uint32_t nextDisp;
uint32_t opcode = 0;
bool relocateableExternal = false;
bool is_bl;
bool is_blx;
bool targetIsThumb;
if ( ref->getTargetBinding() != ObjectFile::Reference::kDontBind ) {
targetAddr = ref->getTarget().getAddress() + ref->getTargetOffset();
relocateableExternal = (relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal);
}
uint32_t* fixUp = (uint32_t*)&buffer[ref->getFixUpOffset()];
switch ( (arm::ReferenceKinds)(ref->getKind()) ) {
case arm::kNoFixUp:
case arm::kFollowOn:
case arm::kGroupSubordinate:
// do nothing
break;
case arm::kPointerWeakImport:
case arm::kPointer:
// If this is the lazy pointers section, then set all lazy pointers to
// point to the dyld stub binding helper.
if ( ((SectionInfo*)inAtom->getSection())->fAllLazyPointers
|| ((SectionInfo*)inAtom->getSection())->fAllLazyDylibPointers ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound lazy pointer to another dylib ==> pointer contains zero
LittleEndian::set32(*fixUp, 0);
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
// prebound lazy pointer to withing this dylib ==> pointer contains address
if ( ref->getTarget().isThumb() && (ref->getTargetOffset() == 0) )
targetAddr |= 1;
LittleEndian::set32(*fixUp, targetAddr);
break;
}
}
else if ( relocateableExternal ) {
if ( fOptions.prebind() ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// prebound external relocation to internal atom ==> pointer contains target address + addend
if ( ref->getTarget().isThumb() && (ref->getTargetOffset() == 0) )
targetAddr |= 1;
LittleEndian::set32(*fixUp, targetAddr);
break;
case ObjectFile::Atom::kAbsoluteSymbol:
break;
}
}
else if ( !fOptions.makeClassicDyldInfo()
&& (ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) ) {
// when using only compressed dyld info, pointer is initially set to point directly to weak definition
if ( ref->getTarget().isThumb() )
targetAddr |= 1;
LittleEndian::set32(*fixUp, targetAddr);
}
else {
// external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
}
}
else {
// pointer contains target address
if ( ref->getTarget().isThumb() && (ref->getTargetOffset() == 0))
targetAddr |= 1;
LittleEndian::set32(*fixUp, targetAddr);
}
break;
case arm::kPointerDiff:
LittleEndian::set32(*fixUp,
(ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case arm::kReadOnlyPointer:
if ( ref->getTarget().isThumb() && (ref->getTargetOffset() == 0))
targetAddr |= 1;
switch ( ref->getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kTentativeDefinition:
// pointer contains target address
LittleEndian::set32(*fixUp, targetAddr);
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
break;
case ObjectFile::Atom::kAbsoluteSymbol:
// pointer contains target address
LittleEndian::set32(*fixUp, targetAddr);
break;
}
break;
case arm::kBranch24WeakImport:
case arm::kBranch24:
displacement = targetAddr - (inAtom->getAddress() + ref->getFixUpOffset());
// check if this is a branch to a branch island that can be skipped
if ( ref->getTarget().getContentType() == ObjectFile::Atom::kBranchIsland ) {
uint64_t finalTargetAddress = ((BranchIslandAtom<arm>*)(&(ref->getTarget())))->getFinalTargetAdress();
int64_t altDisplacment = finalTargetAddress - (inAtom->getAddress() + ref->getFixUpOffset());
if ( (altDisplacment < 33554428LL) && (altDisplacment > (-33554432LL)) ) {
//fprintf(stderr, "using altDisplacment = %lld\n", altDisplacment);
// yes, we can skip the branch island
displacement = altDisplacment;
}
}
// The pc added will be +8 from the pc
displacement -= 8;
//fprintf(stderr, "bl/blx fixup to %s at 0x%08llX, displacement = 0x%08llX\n", ref->getTarget().getDisplayName(), ref->getTarget().getAddress(), displacement);
// max positive displacement is 0x007FFFFF << 2
// max negative displacement is 0xFF800000 << 2
if ( (displacement > 33554428LL) || (displacement < (-33554432LL)) ) {
throwf("b/bl/blx out of range (%lld max is +/-32M) from 0x%08llX %s in %s to 0x%08llX %s in %s",
displacement, inAtom->getAddress(), inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getAddress(), ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
instruction = LittleEndian::get32(*fixUp);
// Make sure we are calling arm with bl, thumb with blx
is_bl = ((instruction & 0xFF000000) == 0xEB000000);
is_blx = ((instruction & 0xFE000000) == 0xFA000000);
if ( is_bl && ref->getTarget().isThumb() ) {
uint32_t opcode = 0xFA000000;
uint32_t disp = (uint32_t)(displacement >> 2) & 0x00FFFFFF;
uint32_t h_bit = (uint32_t)(displacement << 23) & 0x01000000;
newInstruction = opcode | h_bit | disp;
}
else if ( is_blx && !ref->getTarget().isThumb() ) {
uint32_t opcode = 0xEB000000;
uint32_t disp = (uint32_t)(displacement >> 2) & 0x00FFFFFF;
newInstruction = opcode | disp;
}
else if ( !is_bl && !is_blx && ref->getTarget().isThumb() ) {
throwf("don't know how to convert instruction %x referencing %s to thumb",
instruction, ref->getTarget().getDisplayName());
}
else {
newInstruction = (instruction & 0xFF000000) | ((uint32_t)(displacement >> 2) & 0x00FFFFFF);
}
LittleEndian::set32(*fixUp, newInstruction);
break;
case arm::kThumbBranch22WeakImport:
case arm::kThumbBranch22:
instruction = LittleEndian::get32(*fixUp);
is_bl = ((instruction & 0xD000F800) == 0xD000F000);
is_blx = ((instruction & 0xD000F800) == 0xC000F000);
targetIsThumb = ref->getTarget().isThumb();
// The pc added will be +4 from the pc
baseAddr = inAtom->getAddress() + ref->getFixUpOffset() + 4;
// If the target is not thumb, we will be generating a blx instruction
// Since blx cannot have the low bit set, set bit[1] of the target to
// bit[1] of the base address, so that the difference is a multiple of
// 4 bytes.
if ( !targetIsThumb ) {
targetAddr &= -3ULL;
targetAddr |= (baseAddr & 2LL);
}
displacement = targetAddr - baseAddr;
// max positive displacement is 0x003FFFFE
// max negative displacement is 0xFFC00000
if ( (displacement > 4194302LL) || (displacement < (-4194304LL)) ) {
// armv7 supports a larger displacement
if ( fOptions.preferSubArchitecture() && fOptions.subArchitecture() == CPU_SUBTYPE_ARM_V7 ) {
if ( (displacement > 16777214) || (displacement < (-16777216LL)) ) {
throwf("thumb bl/blx out of range (%lld max is +/-16M) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
else {
// The instruction is really two instructions:
// The lower 16 bits are the first instruction, which contains the high
// 11 bits of the displacement.
// The upper 16 bits are the second instruction, which contains the low
// 11 bits of the displacement, as well as differentiating bl and blx.
uint32_t s = (uint32_t)(displacement >> 24) & 0x1;
uint32_t i1 = (uint32_t)(displacement >> 23) & 0x1;
uint32_t i2 = (uint32_t)(displacement >> 22) & 0x1;
uint32_t imm10 = (uint32_t)(displacement >> 12) & 0x3FF;
uint32_t imm11 = (uint32_t)(displacement >> 1) & 0x7FF;
uint32_t j1 = (i1 == s);
uint32_t j2 = (i2 == s);
if ( is_bl ) {
if ( targetIsThumb )
opcode = 0xD000F000; // keep bl
else
opcode = 0xC000F000; // change to blx
}
else if ( is_blx ) {
if ( targetIsThumb )
opcode = 0xD000F000; // change to bl
else
opcode = 0xC000F000; // keep blx
}
else if ( !is_bl && !is_blx && !targetIsThumb ) {
throwf("don't know how to convert instruction %x referencing %s to arm",
instruction, ref->getTarget().getDisplayName());
}
nextDisp = (j1 << 13) | (j2 << 11) | imm11;
firstDisp = (s << 10) | imm10;
newInstruction = opcode | (nextDisp << 16) | firstDisp;
//warning("s=%d, j1=%d, j2=%d, imm10=0x%0X, imm11=0x%0X, opcode=0x%08X, first=0x%04X, next=0x%04X, new=0x%08X, disp=0x%llX for %s to %s\n",
// s, j1, j2, imm10, imm11, opcode, firstDisp, nextDisp, newInstruction, displacement, inAtom->getDisplayName(), ref->getTarget().getDisplayName());
LittleEndian::set32(*fixUp, newInstruction);
}
}
else {
throwf("thumb bl/blx out of range (%lld max is +/-4M) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
}
else {
// The instruction is really two instructions:
// The lower 16 bits are the first instruction, which contains the high
// 11 bits of the displacement.
// The upper 16 bits are the second instruction, which contains the low
// 11 bits of the displacement, as well as differentiating bl and blx.
firstDisp = (uint32_t)(displacement >> 12) & 0x7FF;
nextDisp = (uint32_t)(displacement >> 1) & 0x7FF;
if ( is_bl && !targetIsThumb ) {
opcode = 0xE800F000;
}
else if ( is_blx && targetIsThumb ) {
opcode = 0xF800F000;
}
else if ( !is_bl && !is_blx && !targetIsThumb ) {
throwf("don't know how to convert instruction %x referencing %s to arm",
instruction, ref->getTarget().getDisplayName());
}
else {
opcode = instruction & 0xF800F800;
}
newInstruction = opcode | (nextDisp << 16) | firstDisp;
LittleEndian::set32(*fixUp, newInstruction);
}
break;
case arm::kDtraceProbeSite:
if ( inAtom->isThumb() ) {
// change 32-bit blx call site to two thumb NOPs
LittleEndian::set32(*fixUp, 0x46C046C0);
}
else {
// change call site to a NOP
LittleEndian::set32(*fixUp, 0xE1A00000);
}
break;
case arm::kDtraceIsEnabledSite:
if ( inAtom->isThumb() ) {
// change 32-bit blx call site to 'nop', 'eor r0, r0'
LittleEndian::set32(*fixUp, 0x46C04040);
}
else {
// change call site to 'eor r0, r0, r0'
LittleEndian::set32(*fixUp, 0xE0200000);
}
break;
case arm::kDtraceTypeReference:
case arm::kDtraceProbe:
// nothing to fix up
break;
case arm::kPointerDiff12:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > 4092LL) || (displacement <-4092LL) ) {
throwf("ldr 12-bit displacement out of range (%lld max +/-4096) in %s", displacement, inAtom->getDisplayName());
}
instruction = LittleEndian::get32(*fixUp);
if ( displacement >= 0 ) {
instruction &= 0xFFFFF000;
instruction |= ((uint32_t)displacement & 0xFFF);
}
else {
instruction &= 0xFF7FF000;
instruction |= ((uint32_t)(-displacement) & 0xFFF);
}
LittleEndian::set32(*fixUp, instruction);
break;
}
}
template <>
void Writer<arm>::fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
int64_t displacement;
uint32_t instruction;
uint32_t newInstruction;
uint64_t targetAddr = 0;
int64_t baseAddr;
uint32_t firstDisp;
uint32_t nextDisp;
uint32_t opcode = 0;
bool relocateableExternal = false;
bool is_bl;
bool is_blx;
bool targetIsThumb;
if ( ref->getTargetBinding() != ObjectFile::Reference::kDontBind ) {
targetAddr = ref->getTarget().getAddress() + ref->getTargetOffset();
relocateableExternal = this->makesExternalRelocatableReference(ref->getTarget());
}
uint32_t* fixUp = (uint32_t*)&buffer[ref->getFixUpOffset()];
switch ( (arm::ReferenceKinds)(ref->getKind()) ) {
case arm::kNoFixUp:
case arm::kFollowOn:
case arm::kGroupSubordinate:
// do nothing
break;
case arm::kPointer:
case arm::kReadOnlyPointer:
case arm::kPointerWeakImport:
{
if ( ((SectionInfo*)inAtom->getSection())->fAllNonLazyPointers ) {
// indirect symbol table has INDIRECT_SYMBOL_LOCAL, so we must put address in content
if ( this->indirectSymbolInRelocatableIsLocal(ref) )
LittleEndian::set32(*fixUp, targetAddr);
else
LittleEndian::set32(*fixUp, 0);
}
else if ( relocateableExternal ) {
if ( fOptions.prebind() ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// prebound external relocation to internal atom ==> pointer contains target address + addend
LittleEndian::set32(*fixUp, targetAddr);
break;
case ObjectFile::Atom::kAbsoluteSymbol:
break;
}
}
}
else {
// internal relocation
if ( ref->getTarget().getDefinitionKind() != ObjectFile::Atom::kTentativeDefinition ) {
// pointer contains target address
if ( ref->getTarget().isThumb() && (ref->getTargetOffset() == 0))
targetAddr |= 1;
LittleEndian::set32(*fixUp, targetAddr);
}
else {
// pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
}
}
}
break;
case arm::kPointerDiff:
LittleEndian::set32(*fixUp,
(ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case arm::kDtraceProbeSite:
case arm::kDtraceIsEnabledSite:
case arm::kBranch24WeakImport:
case arm::kBranch24:
displacement = targetAddr - (inAtom->getAddress() + ref->getFixUpOffset());
// The pc added will be +8 from the pc
displacement -= 8;
// fprintf(stderr, "b/bl/blx fixup to %s at 0x%08llX, displacement = 0x%08llX\n", ref->getTarget().getDisplayName(), ref->getTarget().getAddress(), displacement);
if ( relocateableExternal ) {
// doing "ld -r" to an external symbol
// the mach-o way of encoding this is that the bl instruction's target addr is the offset into the target
displacement -= ref->getTarget().getAddress();
}
else {
// max positive displacement is 0x007FFFFF << 2
// max negative displacement is 0xFF800000 << 2
if ( (displacement > 33554428LL) || (displacement < (-33554432LL)) ) {
throwf("arm b/bl/blx out of range (%lld max is +/-32M) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
}
instruction = LittleEndian::get32(*fixUp);
// Make sure we are calling arm with bl, thumb with blx
is_bl = ((instruction & 0xFF000000) == 0xEB000000);
is_blx = ((instruction & 0xFE000000) == 0xFA000000);
if ( is_bl && ref->getTarget().isThumb() ) {
uint32_t opcode = 0xFA000000;
uint32_t disp = (uint32_t)(displacement >> 2) & 0x00FFFFFF;
uint32_t h_bit = (uint32_t)(displacement << 23) & 0x01000000;
newInstruction = opcode | h_bit | disp;
}
else if ( is_blx && !ref->getTarget().isThumb() ) {
uint32_t opcode = 0xEB000000;
uint32_t disp = (uint32_t)(displacement >> 2) & 0x00FFFFFF;
newInstruction = opcode | disp;
}
else if ( !is_bl && !is_blx && ref->getTarget().isThumb() ) {
throwf("don't know how to convert instruction %x referencing %s to thumb",
instruction, ref->getTarget().getDisplayName());
}
else {
newInstruction = (instruction & 0xFF000000) | ((uint32_t)(displacement >> 2) & 0x00FFFFFF);
}
LittleEndian::set32(*fixUp, newInstruction);
break;
case arm::kThumbBranch22WeakImport:
case arm::kThumbBranch22:
instruction = LittleEndian::get32(*fixUp);
is_bl = ((instruction & 0xF8000000) == 0xF8000000);
is_blx = ((instruction & 0xF8000000) == 0xE8000000);
targetIsThumb = ref->getTarget().isThumb();
// The pc added will be +4 from the pc
baseAddr = inAtom->getAddress() + ref->getFixUpOffset() + 4;
// If the target is not thumb, we will be generating a blx instruction
// Since blx cannot have the low bit set, set bit[1] of the target to
// bit[1] of the base address, so that the difference is a multiple of
// 4 bytes.
if (!targetIsThumb) {
targetAddr &= -3ULL;
targetAddr |= (baseAddr & 2LL);
}
displacement = targetAddr - baseAddr;
//fprintf(stderr, "thumb %s fixup to %s at 0x%08llX, baseAddr = 0x%08llX, displacement = 0x%08llX, %d\n", is_blx ? "blx" : "bl", ref->getTarget().getDisplayName(), targetAddr, baseAddr, displacement, targetIsThumb);
if ( relocateableExternal ) {
// doing "ld -r" to an external symbol
// the mach-o way of encoding this is that the bl instruction's target addr is the offset into the target
displacement -= ref->getTarget().getAddress();
}
if ( (displacement > 4194302LL) || (displacement < (-4194304LL)) ) {
// armv7 supports a larger displacement
if ( fOptions.preferSubArchitecture() && fOptions.subArchitecture() == CPU_SUBTYPE_ARM_V7 ) {
if ( (displacement > 16777214) || (displacement < (-16777216LL)) ) {
throwf("thumb bl/blx out of range (%lld max is +/-16M) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
else {
// The instruction is really two instructions:
// The lower 16 bits are the first instruction, which contains the high
// 11 bits of the displacement.
// The upper 16 bits are the second instruction, which contains the low
// 11 bits of the displacement, as well as differentiating bl and blx.
uint32_t s = (uint32_t)(displacement >> 24) & 0x1;
uint32_t i1 = (uint32_t)(displacement >> 23) & 0x1;
uint32_t i2 = (uint32_t)(displacement >> 22) & 0x1;
uint32_t imm10 = (uint32_t)(displacement >> 12) & 0x3FF;
uint32_t imm11 = (uint32_t)(displacement >> 1) & 0x7FF;
uint32_t j1 = (i1 == s);
uint32_t j2 = (i2 == s);
if ( is_bl ) {
if ( targetIsThumb )
opcode = 0xD000F000; // keep bl
else
opcode = 0xC000F000; // change to blx
}
else if ( is_blx ) {
if ( targetIsThumb )
opcode = 0xD000F000; // change to bl
else
opcode = 0xC000F000; // keep blx
}
else if ( !is_bl && !is_blx && !targetIsThumb ) {
throwf("don't know how to convert instruction %x referencing %s to arm",
instruction, ref->getTarget().getDisplayName());
}
nextDisp = (j1 << 13) | (j2 << 11) | imm11;
firstDisp = (s << 10) | imm10;
newInstruction = opcode | (nextDisp << 16) | firstDisp;
//warning("s=%d, j1=%d, j2=%d, imm10=0x%0X, imm11=0x%0X, opcode=0x%08X, first=0x%04X, next=0x%04X, new=0x%08X, disp=0x%llX for %s to %s\n",
// s, j1, j2, imm10, imm11, opcode, firstDisp, nextDisp, newInstruction, displacement, inAtom->getDisplayName(), ref->getTarget().getDisplayName());
LittleEndian::set32(*fixUp, newInstruction);
break;
}
}
else {
throwf("thumb bl/blx out of range (%lld max is +/-4M) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
}
// The instruction is really two instructions:
// The lower 16 bits are the first instruction, which contains the first
// 11 bits of the displacement.
// The upper 16 bits are the second instruction, which contains the next
// 11 bits of the displacement, as well as differentiating bl and blx.
firstDisp = (uint32_t)(displacement >> 12) & 0x7FF;
nextDisp = (uint32_t)(displacement >> 1) & 0x7FF;
if ( is_bl && !targetIsThumb ) {
opcode = 0xE800F000;
}
else if ( is_blx && targetIsThumb ) {
opcode = 0xF800F000;
}
else if ( !is_bl && !is_blx && !targetIsThumb ) {
throwf("don't know how to convert instruction %x referencing %s to arm",
instruction, ref->getTarget().getDisplayName());
}
else {
opcode = instruction & 0xF800F800;
}
newInstruction = opcode | (nextDisp << 16) | firstDisp;
LittleEndian::set32(*fixUp, newInstruction);
break;
case arm::kDtraceProbe:
case arm::kDtraceTypeReference:
// nothing to fix up
break;
case arm::kPointerDiff12:
throw "internal error. no reloc for 12-bit pointer diffs";
}
}
template <>
void Writer<x86>::fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
uint32_t* fixUp = (uint32_t*)&buffer[ref->getFixUpOffset()];
uint8_t* dtraceProbeSite;
const int64_t kTwoGigLimit = 0x7FFFFFFF;
const int64_t kSixteenMegLimit = 0x00FFFFFF;
const int64_t kSixtyFourKiloLimit = 0x7FFF;
const int64_t kOneTwentyEightLimit = 0x7F;
int64_t displacement;
uint32_t temp;
x86::ReferenceKinds kind = (x86::ReferenceKinds)(ref->getKind());
switch ( kind ) {
case x86::kNoFixUp:
case x86::kFollowOn:
case x86::kGroupSubordinate:
// do nothing
break;
case x86::kPointerWeakImport:
case x86::kPointer:
{
if ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal ) {
if ( fOptions.prebind() ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// prebound external relocation to internal atom ==> pointer contains target address + addend
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
break;
case ObjectFile::Atom::kAbsoluteSymbol:
break;
}
}
else if ( !fOptions.makeClassicDyldInfo()
&& (ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) ) {
// when using only compressed dyld info, pointer is initially set to point directly to weak definition
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
else {
// external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
}
}
else {
// pointer contains target address
//printf("Atom::fixUpReferenceFinal() target.name=%s, target.address=0x%08llX\n", target.getDisplayName(), target.getAddress());
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
}
break;
case x86::kPointerDiff:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
LittleEndian::set32(*fixUp, (uint32_t)displacement);
break;
case x86::kPointerDiff16:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > kSixtyFourKiloLimit) || (displacement < -(kSixtyFourKiloLimit)) )
throwf("16-bit pointer diff out of range in %s", inAtom->getDisplayName());
LittleEndian::set16(*((uint16_t*)fixUp), (uint16_t)displacement);
break;
case x86::kPointerDiff24:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > kSixteenMegLimit) || (displacement < 0) )
throwf("24-bit pointer diff out of range in %s", inAtom->getDisplayName());
temp = LittleEndian::get32(*fixUp);
temp &= 0xFF000000;
temp |= (displacement & 0x00FFFFFF);
LittleEndian::set32(*fixUp, temp);
break;
case x86::kSectionOffset24:
displacement = ref->getTarget().getSectionOffset();
if ( (displacement > kSixteenMegLimit) || (displacement < 0) )
throwf("24-bit pointer diff out of range in %s", inAtom->getDisplayName());
temp = LittleEndian::get32(*fixUp);
temp &= 0xFF000000;
temp |= (displacement & 0x00FFFFFF);
LittleEndian::set32(*fixUp, temp);
break;
case x86::kDtraceProbeSite:
// change call site to a NOP
dtraceProbeSite = (uint8_t*)fixUp;
dtraceProbeSite[-1] = 0x90; // 1-byte nop
dtraceProbeSite[0] = 0x0F; // 4-byte nop
dtraceProbeSite[1] = 0x1F;
dtraceProbeSite[2] = 0x40;
dtraceProbeSite[3] = 0x00;
break;
case x86::kDtraceIsEnabledSite:
// change call site to a clear eax
dtraceProbeSite = (uint8_t*)fixUp;
dtraceProbeSite[-1] = 0x33; // xorl eax,eax
dtraceProbeSite[0] = 0xC0;
dtraceProbeSite[1] = 0x90; // 1-byte nop
dtraceProbeSite[2] = 0x90; // 1-byte nop
dtraceProbeSite[3] = 0x90; // 1-byte nop
break;
case x86::kPCRel32WeakImport:
case x86::kPCRel32:
case x86::kPCRel16:
case x86::kPCRel8:
displacement = 0;
switch ( ref->getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
throw "codegen problem, can't use rel32 to external symbol";
case ObjectFile::Atom::kTentativeDefinition:
displacement = 0;
break;
case ObjectFile::Atom::kAbsoluteSymbol:
displacement = (ref->getTarget().getSectionOffset() + ref->getTargetOffset()) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
break;
}
if ( kind == x86::kPCRel8 ) {
displacement += 3;
if ( (displacement > kOneTwentyEightLimit) || (displacement < -(kOneTwentyEightLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("rel8 out of range in %s", inAtom->getDisplayName());
}
*(int8_t*)fixUp = (int8_t)displacement;
}
else if ( kind == x86::kPCRel16 ) {
displacement += 2;
if ( (displacement > kSixtyFourKiloLimit) || (displacement < -(kSixtyFourKiloLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("rel16 out of range in %s", inAtom->getDisplayName());
}
LittleEndian::set16(*((uint16_t*)fixUp), (uint16_t)displacement);
}
else {
if ( (displacement > kTwoGigLimit) || (displacement < (-kTwoGigLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("rel32 out of range in %s", inAtom->getDisplayName());
}
LittleEndian::set32(*fixUp, (int32_t)displacement);
}
break;
case x86::kAbsolute32:
switch ( ref->getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kTentativeDefinition:
// pointer contains target address
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
break;
case ObjectFile::Atom::kAbsoluteSymbol:
// pointer contains target address
LittleEndian::set32(*fixUp, ref->getTarget().getSectionOffset() + ref->getTargetOffset());
break;
}
break;
case x86::kImageOffset32:
// offset of target atom from mach_header
displacement = ref->getTarget().getAddress() + ref->getTargetOffset() - fMachHeaderAtom->getAddress();
LittleEndian::set32(*fixUp, (int32_t)displacement);
break;
case x86::kDtraceTypeReference:
case x86::kDtraceProbe:
// nothing to fix up
break;
}
}
template <>
void Writer<x86>::fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
const int64_t kTwoGigLimit = 0x7FFFFFFF;
const int64_t kSixtyFourKiloLimit = 0x7FFF;
const int64_t kOneTwentyEightLimit = 0x7F;
uint32_t* fixUp = (uint32_t*)&buffer[ref->getFixUpOffset()];
bool isExtern = this->makesExternalRelocatableReference(ref->getTarget());
int64_t displacement;
x86::ReferenceKinds kind = (x86::ReferenceKinds)(ref->getKind());
switch ( kind ) {
case x86::kNoFixUp:
case x86::kFollowOn:
case x86::kGroupSubordinate:
// do nothing
break;
case x86::kPointer:
case x86::kPointerWeakImport:
case x86::kAbsolute32:
{
if ( ((SectionInfo*)inAtom->getSection())->fAllNonLazyPointers ) {
// if INDIRECT_SYMBOL_LOCAL the content is pointer, else it is zero
if ( this->indirectSymbolInRelocatableIsLocal(ref) )
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
else
LittleEndian::set32(*fixUp, 0);
}
else if ( isExtern ) {
// external relocation ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
}
else if ( ref->getTarget().getDefinitionKind() != ObjectFile::Atom::kTentativeDefinition ) {
// internal relocation => pointer contains target address
LittleEndian::set32(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
else {
// internal relocation to tentative ==> pointer contains addend
LittleEndian::set32(*fixUp, ref->getTargetOffset());
}
}
break;
case x86::kPointerDiff:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
LittleEndian::set32(*fixUp, (uint32_t)displacement);
break;
case x86::kPointerDiff16:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > kSixtyFourKiloLimit) || (displacement < -(kSixtyFourKiloLimit)) )
throwf("16-bit pointer diff out of range in %s", inAtom->getDisplayName());
LittleEndian::set16(*((uint16_t*)fixUp), (uint16_t)displacement);
break;
case x86::kPCRel8:
case x86::kPCRel16:
case x86::kPCRel32:
case x86::kPCRel32WeakImport:
case x86::kDtraceProbeSite:
case x86::kDtraceIsEnabledSite:
{
if ( isExtern )
displacement = ref->getTargetOffset() - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
else
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
if ( kind == x86::kPCRel8 ) {
displacement += 3;
if ( (displacement > kOneTwentyEightLimit) || (displacement < -(kOneTwentyEightLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("rel8 out of range (%lld)in %s", displacement, inAtom->getDisplayName());
}
int8_t byte = (int8_t)displacement;
*((int8_t*)fixUp) = byte;
}
else if ( kind == x86::kPCRel16 ) {
displacement += 2;
if ( (displacement > kSixtyFourKiloLimit) || (displacement < -(kSixtyFourKiloLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("rel16 out of range in %s", inAtom->getDisplayName());
}
int16_t word = (int16_t)displacement;
LittleEndian::set16(*((uint16_t*)fixUp), word);
}
else {
if ( (displacement > kTwoGigLimit) || (displacement < (-kTwoGigLimit)) ) {
//fprintf(stderr, "call out of range, displacement=ox%llX, from %s in %s to %s in %s\n", displacement,
// inAtom->getDisplayName(), inAtom->getFile()->getPath(), ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
throwf("rel32 out of range in %s", inAtom->getDisplayName());
}
LittleEndian::set32(*fixUp, (int32_t)displacement);
}
}
break;
case x86::kPointerDiff24:
throw "internal linker error, kPointerDiff24 can't be encoded into object files";
case x86::kImageOffset32:
throw "internal linker error, kImageOffset32 can't be encoded into object files";
case x86::kSectionOffset24:
throw "internal linker error, kSectionOffset24 can't be encoded into object files";
case x86::kDtraceProbe:
case x86::kDtraceTypeReference:
// nothing to fix up
break;
}
}
template <>
void Writer<x86_64>::fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
const int64_t twoGigLimit = 0x7FFFFFFF;
const int64_t kSixteenMegLimit = 0x00FFFFFF;
uint64_t* fixUp = (uint64_t*)&buffer[ref->getFixUpOffset()];
uint8_t* dtraceProbeSite;
int64_t displacement = 0;
uint32_t temp;
switch ( (x86_64::ReferenceKinds)(ref->getKind()) ) {
case x86_64::kNoFixUp:
case x86_64::kGOTNoFixUp:
case x86_64::kFollowOn:
case x86_64::kGroupSubordinate:
// do nothing
break;
case x86_64::kPointerWeakImport:
case x86_64::kPointer:
{
if ( &ref->getTarget() != NULL ) {
//fprintf(stderr, "fixUpReferenceFinal: %s reference to %s\n", this->getDisplayName(), target.getDisplayName());
if ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal) {
if ( !fOptions.makeClassicDyldInfo()
&& (ref->getTarget().getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) ) {
// when using only compressed dyld info, pointer is initially set to point directly to weak definition
LittleEndian::set64(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
else {
// external relocation ==> pointer contains addend
LittleEndian::set64(*fixUp, ref->getTargetOffset());
}
}
else {
// internal relocation
// pointer contains target address
//printf("Atom::fixUpReferenceFinal) target.name=%s, target.address=0x%08llX\n", target.getDisplayName(), target.getAddress());
LittleEndian::set64(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
}
}
break;
case x86_64::kPointer32:
{
//fprintf(stderr, "fixUpReferenceFinal: %s reference to %s\n", this->getDisplayName(), target.getDisplayName());
if ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal ) {
// external relocation
throwf("32-bit pointer to dylib or weak symbol %s not supported for x86_64",ref->getTarget().getDisplayName());
}
else {
// internal relocation
// pointer contains target address
//printf("Atom::fixUpReferenceFinal) target.name=%s, target.address=0x%08llX\n", target.getDisplayName(), target.getAddress());
displacement = ref->getTarget().getAddress() + ref->getTargetOffset();
switch ( fOptions.outputKind() ) {
case Options::kObjectFile:
case Options::kPreload:
case Options::kDyld:
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kKextBundle:
throwf("32-bit pointer to symbol %s not supported for x86_64",ref->getTarget().getDisplayName());
case Options::kDynamicExecutable:
// <rdar://problem/5855588> allow x86_64 main executables to use 32-bit pointers if program loads in load 2GB
if ( (displacement > twoGigLimit) || (displacement < (-twoGigLimit)) )
throw "32-bit pointer out of range";
break;
case Options::kStaticExecutable:
// <rdar://problem/5855588> allow x86_64 mach_kernel to truncate pointers
break;
}
LittleEndian::set32(*((uint32_t*)fixUp), (uint32_t)displacement);
}
}
break;
case x86_64::kPointerDiff32:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > twoGigLimit) || (displacement < (-twoGigLimit)) )
throw "32-bit pointer difference out of range";
LittleEndian::set32(*((uint32_t*)fixUp), (uint32_t)displacement);
break;
case x86_64::kPointerDiff:
LittleEndian::set64(*fixUp,
(ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case x86_64::kPointerDiff24:
displacement = (ref->getTarget().getAddress() + ref->getTargetOffset()) - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset());
if ( (displacement > kSixteenMegLimit) || (displacement < 0) )
throwf("24-bit pointer diff out of range in %s", inAtom->getDisplayName());
temp = LittleEndian::get32(*((uint32_t*)fixUp));
temp &= 0xFF000000;
temp |= (displacement & 0x00FFFFFF);
LittleEndian::set32(*((uint32_t*)fixUp), temp);
break;
case x86_64::kSectionOffset24:
displacement = ref->getTarget().getSectionOffset();
if ( (displacement > kSixteenMegLimit) || (displacement < 0) )
throwf("24-bit pointer diff out of range in %s", inAtom->getDisplayName());
temp = LittleEndian::get32(*((uint32_t*)fixUp));
temp &= 0xFF000000;
temp |= (displacement & 0x00FFFFFF);
LittleEndian::set32(*((uint32_t*)fixUp), temp);
break;
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
// if GOT entry was optimized away, change movq instruction to a leaq
if ( std::find(fAllSynthesizedNonLazyPointers.begin(), fAllSynthesizedNonLazyPointers.end(), &(ref->getTarget())) == fAllSynthesizedNonLazyPointers.end() ) {
//fprintf(stderr, "GOT for %s optimized away\n", ref->getTarget().getDisplayName());
uint8_t* opcodes = (uint8_t*)fixUp;
if ( opcodes[-2] != 0x8B )
throw "GOT load reloc does not point to a movq instruction";
opcodes[-2] = 0x8D;
}
// fall into general rel32 case
case x86_64::kBranchPCRel32WeakImport:
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel8:
case x86_64::kPCRel32:
case x86_64::kPCRel32_1:
case x86_64::kPCRel32_2:
case x86_64::kPCRel32_4:
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
switch ( ref->getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kTentativeDefinition:
displacement = (ref->getTarget().getAddress() + (int32_t)ref->getTargetOffset()) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
break;
case ObjectFile::Atom::kAbsoluteSymbol:
displacement = (ref->getTarget().getSectionOffset() + (int32_t)ref->getTargetOffset()) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
if ( fOptions.outputKind() == Options::kKextBundle )
displacement = 0;
else
throwf("codegen problem, can't use rel32 to external symbol %s", ref->getTarget().getDisplayName());
break;
}
switch ( ref->getKind() ) {
case x86_64::kPCRel32_1:
displacement -= 1;
break;
case x86_64::kPCRel32_2:
displacement -= 2;
break;
case x86_64::kPCRel32_4:
displacement -= 4;
break;
case x86_64::kBranchPCRel8:
displacement += 3;
break;
}
if ( ref->getKind() == x86_64::kBranchPCRel8 ) {
if ( (displacement > 127) || (displacement < (-128)) ) {
fprintf(stderr, "branch out of range from %s (%llX) in %s to %s (%llX) in %s\n",
inAtom->getDisplayName(), inAtom->getAddress(), inAtom->getFile()->getPath(), ref->getTarget().getDisplayName(), ref->getTarget().getAddress(), ref->getTarget().getFile()->getPath());
throw "rel8 out of range";
}
*((int8_t*)fixUp) = (int8_t)displacement;
}
else {
if ( (displacement > twoGigLimit) || (displacement < (-twoGigLimit)) ) {
fprintf(stderr, "reference out of range from %s (%llX) in %s to %s (%llX) in %s\n",
inAtom->getDisplayName(), inAtom->getAddress(), inAtom->getFile()->getPath(), ref->getTarget().getDisplayName(), ref->getTarget().getAddress(), ref->getTarget().getFile()->getPath());
throw "rel32 out of range";
}
LittleEndian::set32(*((uint32_t*)fixUp), (int32_t)displacement);
}
break;
case x86_64::kImageOffset32:
// offset of target atom from mach_header
displacement = ref->getTarget().getAddress() + ref->getTargetOffset() - fMachHeaderAtom->getAddress();
LittleEndian::set32(*((uint32_t*)fixUp), (int32_t)displacement);
break;
case x86_64::kDtraceProbeSite:
// change call site to a NOP
dtraceProbeSite = (uint8_t*)fixUp;
dtraceProbeSite[-1] = 0x90; // 1-byte nop
dtraceProbeSite[0] = 0x0F; // 4-byte nop
dtraceProbeSite[1] = 0x1F;
dtraceProbeSite[2] = 0x40;
dtraceProbeSite[3] = 0x00;
break;
case x86_64::kDtraceIsEnabledSite:
// change call site to a clear eax
dtraceProbeSite = (uint8_t*)fixUp;
dtraceProbeSite[-1] = 0x48; // xorq eax,eax
dtraceProbeSite[0] = 0x33;
dtraceProbeSite[1] = 0xC0;
dtraceProbeSite[2] = 0x90; // 1-byte nop
dtraceProbeSite[3] = 0x90; // 1-byte nop
break;
case x86_64::kDtraceTypeReference:
case x86_64::kDtraceProbe:
// nothing to fix up
break;
}
}
template <>
void Writer<x86_64>::fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
const int64_t twoGigLimit = 0x7FFFFFFF;
bool external = this->makesExternalRelocatableReference(ref->getTarget());
uint64_t* fixUp = (uint64_t*)&buffer[ref->getFixUpOffset()];
int64_t displacement = 0;
int32_t temp32;
switch ( (x86_64::ReferenceKinds)(ref->getKind()) ) {
case x86_64::kNoFixUp:
case x86_64::kGOTNoFixUp:
case x86_64::kFollowOn:
case x86_64::kGroupSubordinate:
// do nothing
break;
case x86_64::kPointer:
case x86_64::kPointerWeakImport:
{
if ( external ) {
// external relocation ==> pointer contains addend
LittleEndian::set64(*fixUp, ref->getTargetOffset());
}
else {
// internal relocation ==> pointer contains target address
LittleEndian::set64(*fixUp, ref->getTarget().getAddress() + ref->getTargetOffset());
}
}
break;
case x86_64::kPointer32:
{
if ( external ) {
// external relocation ==> pointer contains addend
LittleEndian::set32(*((uint32_t*)fixUp), ref->getTargetOffset());
}
else {
// internal relocation ==> pointer contains target address
LittleEndian::set32(*((uint32_t*)fixUp), ref->getTarget().getAddress() + ref->getTargetOffset());
}
}
break;
case x86_64::kPointerDiff32:
displacement = ref->getTargetOffset() - ref->getFromTargetOffset();
if ( ref->getTarget().getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn )
displacement += ref->getTarget().getAddress();
if ( ref->getFromTarget().getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn )
displacement -= ref->getFromTarget().getAddress();
LittleEndian::set32(*((uint32_t*)fixUp), displacement);
break;
case x86_64::kPointerDiff:
displacement = ref->getTargetOffset() - ref->getFromTargetOffset();
if ( ref->getTarget().getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn )
displacement += ref->getTarget().getAddress();
if ( ref->getFromTarget().getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn )
displacement -= ref->getFromTarget().getAddress();
LittleEndian::set64(*fixUp, displacement);
break;
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel32WeakImport:
case x86_64::kDtraceProbeSite:
case x86_64::kDtraceIsEnabledSite:
case x86_64::kPCRel32:
case x86_64::kPCRel32_1:
case x86_64::kPCRel32_2:
case x86_64::kPCRel32_4:
// turn unsigned 64-bit target offset in signed 32-bit offset, since that is what source originally had
temp32 = ref->getTargetOffset();
if ( external ) {
// extern relocation contains addend
displacement = temp32;
}
else {
// internal relocations contain delta to target address
displacement = (ref->getTarget().getAddress() + temp32) - (inAtom->getAddress() + ref->getFixUpOffset() + 4);
}
switch ( ref->getKind() ) {
case x86_64::kPCRel32_1:
displacement -= 1;
break;
case x86_64::kPCRel32_2:
displacement -= 2;
break;
case x86_64::kPCRel32_4:
displacement -= 4;
break;
}
if ( (displacement > twoGigLimit) || (displacement < (-twoGigLimit)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throw "rel32 out of range";
}
LittleEndian::set32(*((uint32_t*)fixUp), (int32_t)displacement);
break;
case x86_64::kBranchPCRel8:
// turn unsigned 64-bit target offset in signed 32-bit offset, since that is what source originally had
temp32 = ref->getTargetOffset();
if ( external ) {
// extern relocation contains addend
displacement = temp32;
}
else {
// internal relocations contain delta to target address
displacement = (ref->getTarget().getAddress() + temp32) - (inAtom->getAddress() + ref->getFixUpOffset() + 1);
}
if ( (displacement > 127) || (displacement < (-128)) ) {
//fprintf(stderr, "call out of range from %s in %s to %s in %s\n", this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throw "rel8 out of range";
}
*((int8_t*)fixUp) = (int8_t)displacement;
break;
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTWeakImport:
case x86_64::kPCRel32GOTLoadWeakImport:
// contains addend (usually zero)
LittleEndian::set32(*((uint32_t*)fixUp), (uint32_t)(ref->getTargetOffset()));
break;
case x86_64::kPointerDiff24:
throw "internal linker error, kPointerDiff24 can't be encoded into object files";
case x86_64::kImageOffset32:
throw "internal linker error, kImageOffset32 can't be encoded into object files";
case x86_64::kSectionOffset24:
throw "internal linker error, kSectionOffset24 can't be encoded into object files";
case x86_64::kDtraceTypeReference:
case x86_64::kDtraceProbe:
// nothing to fix up
break;
}
}
template <>
void Writer<ppc>::fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
fixUpReference_powerpc(ref, inAtom, buffer, true);
}
template <>
void Writer<ppc64>::fixUpReferenceFinal(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
fixUpReference_powerpc(ref, inAtom, buffer, true);
}
template <>
void Writer<ppc>::fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
fixUpReference_powerpc(ref, inAtom, buffer, false);
}
template <>
void Writer<ppc64>::fixUpReferenceRelocatable(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[]) const
{
fixUpReference_powerpc(ref, inAtom, buffer, false);
}
//
// ppc and ppc64 are mostly the same, so they share a template specialzation
//
template <typename A>
void Writer<A>::fixUpReference_powerpc(const ObjectFile::Reference* ref, const ObjectFile::Atom* inAtom, uint8_t buffer[], bool finalLinkedImage) const
{
uint32_t instruction;
uint32_t newInstruction;
int64_t displacement;
uint64_t targetAddr = 0;
uint64_t picBaseAddr;
uint16_t instructionLowHalf;
uint16_t instructionHighHalf;
uint32_t* fixUp = (uint32_t*)&buffer[ref->getFixUpOffset()];
pint_t* fixUpPointer = (pint_t*)&buffer[ref->getFixUpOffset()];
bool relocateableExternal = false;
const int64_t picbase_twoGigLimit = 0x80000000;
if ( ref->getTargetBinding() != ObjectFile::Reference::kDontBind ) {
targetAddr = ref->getTarget().getAddress() + ref->getTargetOffset();
if ( finalLinkedImage )
relocateableExternal = (relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal);
else
relocateableExternal = this->makesExternalRelocatableReference(ref->getTarget());
}
switch ( (typename A::ReferenceKinds)(ref->getKind()) ) {
case A::kNoFixUp:
case A::kFollowOn:
case A::kGroupSubordinate:
// do nothing
break;
case A::kPointerWeakImport:
case A::kPointer:
{
//fprintf(stderr, "fixUpReferenceFinal: %s reference to %s\n", this->getDisplayName(), target.getDisplayName());
if ( finalLinkedImage && (((SectionInfo*)inAtom->getSection())->fAllLazyPointers
|| ((SectionInfo*)inAtom->getSection())->fAllLazyDylibPointers) ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound lazy pointer to another dylib ==> pointer contains zero
P::setP(*fixUpPointer, 0);
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
// prebound lazy pointer to withing this dylib ==> pointer contains address
P::setP(*fixUpPointer, targetAddr);
break;
}
}
else if ( !finalLinkedImage && ((SectionInfo*)inAtom->getSection())->fAllNonLazyPointers ) {
// if INDIRECT_SYMBOL_LOCAL the content is pointer, else it is zero
if ( this->indirectSymbolInRelocatableIsLocal(ref) )
P::setP(*fixUpPointer, targetAddr);
else
P::setP(*fixUpPointer, 0);
}
else if ( relocateableExternal ) {
if ( fOptions.prebind() ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// prebound external relocation ==> pointer contains addend
P::setP(*fixUpPointer, ref->getTargetOffset());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// prebound external relocation to internal atom ==> pointer contains target address + addend
P::setP(*fixUpPointer, targetAddr);
break;
case ObjectFile::Atom::kAbsoluteSymbol:
break;
}
}
else {
// external relocation ==> pointer contains addend
P::setP(*fixUpPointer, ref->getTargetOffset());
}
}
else {
// internal relocation
if ( finalLinkedImage || (ref->getTarget().getDefinitionKind() != ObjectFile::Atom::kTentativeDefinition) ) {
// pointer contains target address
//printf("Atom::fixUpReference_powerpc() target.name=%s, target.address=0x%08llX\n", ref->getTarget().getDisplayName(), targetAddr);
P::setP(*fixUpPointer, targetAddr);
}
else {
// pointer contains addend
P::setP(*fixUpPointer, ref->getTargetOffset());
}
}
}
break;
case A::kPointerDiff64:
P::setP(*fixUpPointer, targetAddr - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case A::kPointerDiff32:
P::E::set32(*fixUp, targetAddr - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case A::kPointerDiff16:
P::E::set16(*((uint16_t*)fixUp), targetAddr - (ref->getFromTarget().getAddress() + ref->getFromTargetOffset()) );
break;
case A::kDtraceProbeSite:
if ( finalLinkedImage ) {
// change call site to a NOP
BigEndian::set32(*fixUp, 0x60000000);
}
else {
// set bl instuction to branch to address zero in .o file
int64_t displacement = ref->getTargetOffset() - (inAtom->getAddress() + ref->getFixUpOffset());
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFC000003) | ((uint32_t)displacement & 0x03FFFFFC);
BigEndian::set32(*fixUp, newInstruction);
}
break;
case A::kDtraceIsEnabledSite:
if ( finalLinkedImage ) {
// change call site to a li r3,0
BigEndian::set32(*fixUp, 0x38600000);
}
else {
// set bl instuction to branch to address zero in .o file
int64_t displacement = ref->getTargetOffset() - (inAtom->getAddress() + ref->getFixUpOffset());
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFC000003) | ((uint32_t)displacement & 0x03FFFFFC);
BigEndian::set32(*fixUp, newInstruction);
}
break;
case A::kBranch24WeakImport:
case A::kBranch24:
{
//fprintf(stderr, "bl fixup to %s at 0x%08llX, ", target.getDisplayName(), target.getAddress());
int64_t displacement = targetAddr - (inAtom->getAddress() + ref->getFixUpOffset());
if ( relocateableExternal ) {
// doing "ld -r" to an external symbol
// the mach-o way of encoding this is that the bl instruction's target addr is the offset into the target
displacement -= ref->getTarget().getAddress();
}
else {
const int64_t bl_eightMegLimit = 0x00FFFFFF;
if ( (displacement > bl_eightMegLimit) || (displacement < (-bl_eightMegLimit)) ) {
//fprintf(stderr, "bl out of range (%lld max is +/-16M) from %s in %s to %s in %s\n", displacement, this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("bl out of range (%lld max is +/-16M) from %s at 0x%08llX in %s of %s to %s at 0x%08llX in %s of %s",
displacement, inAtom->getDisplayName(), inAtom->getAddress(), inAtom->getSectionName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getAddress(), ref->getTarget().getSectionName(), ref->getTarget().getFile()->getPath());
}
}
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFC000003) | ((uint32_t)displacement & 0x03FFFFFC);
//fprintf(stderr, "bl fixup: 0x%08X -> 0x%08X\n", instruction, newInstruction);
BigEndian::set32(*fixUp, newInstruction);
}
break;
case A::kBranch14:
{
int64_t displacement = targetAddr - (inAtom->getAddress() + ref->getFixUpOffset());
if ( relocateableExternal ) {
// doing "ld -r" to an external symbol
// the mach-o way of encoding this is that the bl instruction's target addr is the offset into the target
displacement -= ref->getTarget().getAddress();
}
const int64_t b_sixtyFourKiloLimit = 0x0000FFFF;
if ( (displacement > b_sixtyFourKiloLimit) || (displacement < (-b_sixtyFourKiloLimit)) ) {
//fprintf(stderr, "bl out of range (%lld max is +/-16M) from %s in %s to %s in %s\n", displacement, this->getDisplayName(), this->getFile()->getPath(), target.getDisplayName(), target.getFile()->getPath());
throwf("bcc out of range (%lld max is +/-64K) from %s in %s to %s in %s",
displacement, inAtom->getDisplayName(), inAtom->getFile()->getPath(),
ref->getTarget().getDisplayName(), ref->getTarget().getFile()->getPath());
}
//fprintf(stderr, "bcc fixup displacement=0x%08llX, atom.addr=0x%08llX, atom.offset=0x%08X\n", displacement, inAtom->getAddress(), (uint32_t)ref->getFixUpOffset());
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0003) | ((uint32_t)displacement & 0x0000FFFC);
//fprintf(stderr, "bc fixup: 0x%08X -> 0x%08X\n", instruction, newInstruction);
BigEndian::set32(*fixUp, newInstruction);
}
break;
case A::kPICBaseLow16:
picBaseAddr = ref->getFromTarget().getAddress() + ref->getFromTargetOffset();
displacement = targetAddr - picBaseAddr;
if ( (displacement > picbase_twoGigLimit) || (displacement < (-picbase_twoGigLimit)) )
throw "32-bit pic-base out of range";
instructionLowHalf = (displacement & 0xFFFF);
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0000) | instructionLowHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kPICBaseLow14:
picBaseAddr = ref->getFromTarget().getAddress() + ref->getFromTargetOffset();
displacement = targetAddr - picBaseAddr;
if ( (displacement > picbase_twoGigLimit) || (displacement < (-picbase_twoGigLimit)) )
throw "32-bit pic-base out of range";
if ( (displacement & 0x3) != 0 )
throwf("bad offset (0x%08X) for lo14 instruction pic-base fix-up", (uint32_t)displacement);
instructionLowHalf = (displacement & 0xFFFC);
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0003) | instructionLowHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kPICBaseHigh16:
picBaseAddr = ref->getFromTarget().getAddress() + ref->getFromTargetOffset();
displacement = targetAddr - picBaseAddr;
if ( (displacement > picbase_twoGigLimit) || (displacement < (-picbase_twoGigLimit)) )
throw "32-bit pic-base out of range";
instructionLowHalf = displacement >> 16;
if ( (displacement & 0x00008000) != 0 )
++instructionLowHalf;
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0000) | instructionLowHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kAbsLow16:
if ( relocateableExternal && !finalLinkedImage )
targetAddr -= ref->getTarget().getAddress();
instructionLowHalf = (targetAddr & 0xFFFF);
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0000) | instructionLowHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kAbsLow14:
if ( relocateableExternal && !finalLinkedImage )
targetAddr -= ref->getTarget().getAddress();
if ( (targetAddr & 0x3) != 0 )
throw "bad address for absolute lo14 instruction fix-up";
instructionLowHalf = (targetAddr & 0xFFFF);
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0003) | instructionLowHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kAbsHigh16:
if ( relocateableExternal ) {
if ( finalLinkedImage ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
throwf("absolute address to symbol %s in a different linkage unit not supported", ref->getTargetName());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// use target address
break;
case ObjectFile::Atom::kAbsoluteSymbol:
targetAddr = ref->getTarget().getSectionOffset();
break;
}
}
else {
targetAddr -= ref->getTarget().getAddress();
}
}
instructionHighHalf = (targetAddr >> 16);
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0000) | instructionHighHalf;
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kAbsHigh16AddLow:
if ( relocateableExternal ) {
if ( finalLinkedImage ) {
switch (ref->getTarget().getDefinitionKind()) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
throwf("absolute address to symbol %s in a different linkage unit not supported", ref->getTargetName());
break;
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
// use target address
break;
case ObjectFile::Atom::kAbsoluteSymbol:
targetAddr = ref->getTarget().getSectionOffset();
break;
}
}
else {
targetAddr -= ref->getTarget().getAddress();
}
}
if ( targetAddr & 0x00008000 )
targetAddr += 0x00010000;
instruction = BigEndian::get32(*fixUp);
newInstruction = (instruction & 0xFFFF0000) | (targetAddr >> 16);
BigEndian::set32(*fixUp, newInstruction);
break;
case A::kDtraceTypeReference:
case A::kDtraceProbe:
// nothing to fix up
break;
}
}
template <>
bool Writer<ppc>::stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref)
{
uint8_t kind = ref->getKind();
switch ( (ppc::ReferenceKinds)kind ) {
case ppc::kNoFixUp:
case ppc::kFollowOn:
case ppc::kGroupSubordinate:
case ppc::kPointer:
case ppc::kPointerWeakImport:
case ppc::kPointerDiff16:
case ppc::kPointerDiff32:
case ppc::kPointerDiff64:
case ppc::kDtraceProbe:
case ppc::kDtraceProbeSite:
case ppc::kDtraceIsEnabledSite:
case ppc::kDtraceTypeReference:
// these are never used to call external functions
return false;
case ppc::kBranch24:
case ppc::kBranch24WeakImport:
case ppc::kBranch14:
// these are used to call external functions
return true;
case ppc::kPICBaseLow16:
case ppc::kPICBaseLow14:
case ppc::kPICBaseHigh16:
case ppc::kAbsLow16:
case ppc::kAbsLow14:
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
// these are only used to call external functions
// in -mlong-branch stubs
switch ( ref->getTarget().getDefinitionKind() ) {
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
// if the .o file this atom came from has long-branch stubs,
// then assume these instructions in a stub.
// Otherwise, these are a direct reference to something (maybe a runtime text reloc)
return ( inAtom->getFile()->hasLongBranchStubs() );
case ObjectFile::Atom::kTentativeDefinition:
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
return false;
}
break;
}
return false;
}
template <>
bool Writer<arm>::stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref)
{
uint8_t kind = ref->getKind();
switch ( (arm::ReferenceKinds)kind ) {
case arm::kBranch24:
case arm::kBranch24WeakImport:
return true;
case arm::kThumbBranch22:
case arm::kThumbBranch22WeakImport:
fHasThumbBranches = true;
return true;
case arm::kNoFixUp:
case arm::kFollowOn:
case arm::kGroupSubordinate:
case arm::kPointer:
case arm::kReadOnlyPointer:
case arm::kPointerWeakImport:
case arm::kPointerDiff:
case arm::kDtraceProbe:
case arm::kDtraceProbeSite:
case arm::kDtraceIsEnabledSite:
case arm::kDtraceTypeReference:
case arm::kPointerDiff12:
return false;
}
return false;
}
template <>
bool Writer<ppc64>::stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref)
{
uint8_t kind = ref->getKind();
switch ( (ppc64::ReferenceKinds)kind ) {
case ppc::kNoFixUp:
case ppc::kFollowOn:
case ppc::kGroupSubordinate:
case ppc::kPointer:
case ppc::kPointerWeakImport:
case ppc::kPointerDiff16:
case ppc::kPointerDiff32:
case ppc::kPointerDiff64:
case ppc::kPICBaseLow16:
case ppc::kPICBaseLow14:
case ppc::kPICBaseHigh16:
case ppc::kAbsLow16:
case ppc::kAbsLow14:
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
case ppc::kDtraceProbe:
case ppc::kDtraceProbeSite:
case ppc::kDtraceIsEnabledSite:
case ppc::kDtraceTypeReference:
// these are never used to call external functions
return false;
case ppc::kBranch24:
case ppc::kBranch24WeakImport:
case ppc::kBranch14:
// these are used to call external functions
return true;
}
return false;
}
template <>
bool Writer<x86>::stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref)
{
uint8_t kind = ref->getKind();
return (kind == x86::kPCRel32 || kind == x86::kPCRel32WeakImport);
}
template <>
bool Writer<x86_64>::stubableReference(const ObjectFile::Atom* inAtom, const ObjectFile::Reference* ref)
{
uint8_t kind = ref->getKind();
return (kind == x86_64::kBranchPCRel32 || kind == x86_64::kBranchPCRel32WeakImport);
}
template <>
bool Writer<ppc>::weakImportReferenceKind(uint8_t kind)
{
return (kind == ppc::kBranch24WeakImport || kind == ppc::kPointerWeakImport);
}
template <>
bool Writer<ppc64>::weakImportReferenceKind(uint8_t kind)
{
return (kind == ppc64::kBranch24WeakImport || kind == ppc64::kPointerWeakImport);
}
template <>
bool Writer<x86>::weakImportReferenceKind(uint8_t kind)
{
return (kind == x86::kPCRel32WeakImport || kind == x86::kPointerWeakImport);
}
template <>
bool Writer<x86_64>::weakImportReferenceKind(uint8_t kind)
{
switch ( kind ) {
case x86_64::kPointerWeakImport:
case x86_64::kBranchPCRel32WeakImport:
case x86_64::kPCRel32GOTWeakImport:
case x86_64::kPCRel32GOTLoadWeakImport:
return true;
}
return false;
}
template <>
bool Writer<arm>::weakImportReferenceKind(uint8_t kind)
{
return (kind == arm::kBranch24WeakImport || kind == arm::kThumbBranch22WeakImport ||
kind == arm::kPointerWeakImport);
}
template <>
bool Writer<ppc>::GOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<ppc64>::GOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<x86>::GOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<x86_64>::GOTReferenceKind(uint8_t kind)
{
switch ( kind ) {
case x86_64::kPCRel32GOT:
case x86_64::kPCRel32GOTWeakImport:
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
case x86_64::kGOTNoFixUp:
return true;
}
return false;
}
template <>
bool Writer<arm>::GOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<ppc>::optimizableGOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<ppc64>::optimizableGOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<x86>::optimizableGOTReferenceKind(uint8_t kind)
{
return false;
}
template <>
bool Writer<x86_64>::optimizableGOTReferenceKind(uint8_t kind)
{
switch ( kind ) {
case x86_64::kPCRel32GOTLoad:
case x86_64::kPCRel32GOTLoadWeakImport:
return true;
}
return false;
}
template <>
bool Writer<arm>::optimizableGOTReferenceKind(uint8_t kind)
{
return false;
}
// 64-bit architectures never need module table, 32-bit sometimes do for backwards compatiblity
template <typename A> bool Writer<A>::needsModuleTable() {return fOptions.needsModuleTable(); }
template <> bool Writer<ppc64>::needsModuleTable() { return false; }
template <> bool Writer<x86_64>::needsModuleTable() { return false; }
template <typename A>
void Writer<A>::optimizeDylibReferences()
{
//fprintf(stderr, "original ordinals table:\n");
//for (std::map<class ObjectFile::Reader*, uint32_t>::iterator it = fLibraryToOrdinal.begin(); it != fLibraryToOrdinal.end(); ++it) {
// fprintf(stderr, "%u <== %p/%s\n", it->second, it->first, it->first->getPath());
//}
// find unused dylibs that can be removed
std::map<uint32_t, ObjectFile::Reader*> ordinalToReader;
std::map<ObjectFile::Reader*, ObjectFile::Reader*> readerAliases;
for (std::map<ObjectFile::Reader*, uint32_t>::iterator it = fLibraryToOrdinal.begin(); it != fLibraryToOrdinal.end(); ++it) {
ObjectFile::Reader* reader = it->first;
std::map<ObjectFile::Reader*, ObjectFile::Reader*>::iterator aliasPos = fLibraryAliases.find(reader);
if ( aliasPos != fLibraryAliases.end() ) {
// already noticed that this reader has same install name as another reader
readerAliases[reader] = aliasPos->second;
}
else if ( !reader->providedExportAtom() && (reader->implicitlyLinked() || reader->deadStrippable() || fOptions.deadStripDylibs()) ) {
// this reader can be optimized away
it->second = 0xFFFFFFFF;
typename std::map<class ObjectFile::Reader*, class DylibLoadCommandsAtom<A>* >::iterator pos = fLibraryToLoadCommand.find(reader);
if ( pos != fLibraryToLoadCommand.end() )
pos->second->optimizeAway();
}
else {
// mark this reader as using it ordinal
std::map<uint32_t, ObjectFile::Reader*>::iterator pos = ordinalToReader.find(it->second);
if ( pos == ordinalToReader.end() )
ordinalToReader[it->second] = reader;
else
readerAliases[reader] = pos->second;
}
}
// renumber ordinals (depends on iterator walking in ordinal order)
// all LC_LAZY_LOAD_DYLIB load commands must have highest ordinals
uint32_t newOrdinal = 0;
for (std::map<uint32_t, ObjectFile::Reader*>::iterator it = ordinalToReader.begin(); it != ordinalToReader.end(); ++it) {
if ( it->first <= fLibraryToOrdinal.size() ) {
if ( ! it->second->isLazyLoadedDylib() )
fLibraryToOrdinal[it->second] = ++newOrdinal;
}
}
for (std::map<uint32_t, ObjectFile::Reader*>::iterator it = ordinalToReader.begin(); it != ordinalToReader.end(); ++it) {
if ( it->first <= fLibraryToOrdinal.size() ) {
if ( it->second->isLazyLoadedDylib() ) {
fLibraryToOrdinal[it->second] = ++newOrdinal;
}
}
}
// <rdar://problem/5504954> linker does not error when dylib ordinal exceeds 250
if ( (newOrdinal >= MAX_LIBRARY_ORDINAL) && (fOptions.nameSpace() == Options::kTwoLevelNameSpace) )
throwf("two level namespace mach-o files can link with at most %d dylibs, this link would use %d dylibs", MAX_LIBRARY_ORDINAL, newOrdinal);
// add aliases (e.g. -lm points to libSystem.dylib)
for (std::map<ObjectFile::Reader*, ObjectFile::Reader*>::iterator it = readerAliases.begin(); it != readerAliases.end(); ++it) {
fLibraryToOrdinal[it->first] = fLibraryToOrdinal[it->second];
}
//fprintf(stderr, "new ordinals table:\n");
//for (std::map<class ObjectFile::Reader*, uint32_t>::iterator it = fLibraryToOrdinal.begin(); it != fLibraryToOrdinal.end(); ++it) {
// fprintf(stderr, "%u <== %p/%s\n", it->second, it->first, it->first->getPath());
//}
}
template <>
void Writer<arm>::scanForAbsoluteReferences()
{
// arm codegen never has absolute references. FIXME: Is this correct?
}
template <>
void Writer<x86_64>::scanForAbsoluteReferences()
{
// x86_64 codegen never has absolute references
}
template <>
void Writer<x86>::scanForAbsoluteReferences()
{
// when linking -pie verify there are no absolute addressing, unless -read_only_relocs is also used
if ( fOptions.positionIndependentExecutable() && !fOptions.allowTextRelocs() ) {
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
if ( atom->getContentType() == ObjectFile::Atom::kStub )
continue;
if ( atom->getContentType() == ObjectFile::Atom::kStubHelper )
continue;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch (ref->getKind()) {
case x86::kAbsolute32:
throwf("cannot link -pie: -mdynamic-no-pic codegen found in %s from %s", atom->getDisplayName(), atom->getFile()->getPath());
return;
}
}
}
}
}
template <>
void Writer<ppc>::scanForAbsoluteReferences()
{
// when linking -pie verify there are no absolute addressing, unless -read_only_relocs is also used
if ( fOptions.positionIndependentExecutable() && !fOptions.allowTextRelocs() ) {
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch (ref->getKind()) {
case ppc::kAbsLow16:
case ppc::kAbsLow14:
case ppc::kAbsHigh16:
case ppc::kAbsHigh16AddLow:
throwf("cannot link -pie: -mdynamic-no-pic codegen found in %s from %s", atom->getDisplayName(), atom->getFile()->getPath());
return;
}
}
}
}
}
// for ppc64 look for any -mdynamic-no-pic codegen
template <>
void Writer<ppc64>::scanForAbsoluteReferences()
{
// only do this for main executable
if ( mightNeedPadSegment() && (fPageZeroAtom != NULL) ) {
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch (ref->getKind()) {
case ppc64::kAbsLow16:
case ppc64::kAbsLow14:
case ppc64::kAbsHigh16:
case ppc64::kAbsHigh16AddLow:
//fprintf(stderr, "found -mdynamic-no-pic codegen in %s in %s\n", atom->getDisplayName(), atom->getFile()->getPath());
// shrink page-zero and add pad segment to compensate
fPadSegmentInfo = new SegmentInfo(4096);
strcpy(fPadSegmentInfo->fName, "__4GBFILL");
fPageZeroAtom->setSize(0x1000);
return;
}
}
}
}
}
template <typename A>
void Writer<A>::insertDummyStubs()
{
// only needed for x86
}
template <>
void Writer<x86>::insertDummyStubs()
{
// any 5-byte stubs that cross a 32-byte cache line may update incorrectly
std::vector<class StubAtom<x86>*> betterStubs;
for (std::vector<class StubAtom<x86>*>::iterator it=fAllSynthesizedStubs.begin(); it != fAllSynthesizedStubs.end(); it++) {
switch (betterStubs.size() % 64 ) {
case 12:// stub would occupy 0x3C->0x41
case 25:// stub would occupy 0x7D->0x82
case 38:// stub would occupy 0xBE->0xC3
case 51:// stub would occupy 0xFF->0x04
betterStubs.push_back(new StubAtom<x86>(*this, *((ObjectFile::Atom*)NULL), false)); //pad with dummy stub
break;
}
betterStubs.push_back(*it);
}
// replace
fAllSynthesizedStubs.clear();
fAllSynthesizedStubs.insert(fAllSynthesizedStubs.begin(), betterStubs.begin(), betterStubs.end());
}
template <typename A>
void Writer<A>::synthesizeKextGOT(const std::vector<class ObjectFile::Atom*>& existingAtoms,
std::vector<class ObjectFile::Atom*>& newAtoms)
{
// walk every atom and reference
for (std::vector<ObjectFile::Atom*>::const_iterator it=existingAtoms.begin(); it != existingAtoms.end(); it++) {
const ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch ( ref->getTargetBinding()) {
case ObjectFile::Reference::kUnboundByName:
case ObjectFile::Reference::kDontBind:
break;
case ObjectFile::Reference::kBoundByName:
case ObjectFile::Reference::kBoundDirectly:
ObjectFile::Atom& target = ref->getTarget();
// create GOT slots (non-lazy pointers) as needed
if ( this->GOTReferenceKind(ref->getKind()) ) {
bool useGOT = ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal );
// if this GOT usage cannot be optimized away then make a GOT enry
if ( ! this->optimizableGOTReferenceKind(ref->getKind()) )
useGOT = true;
if ( useGOT ) {
ObjectFile::Atom* nlp = NULL;
std::map<ObjectFile::Atom*,ObjectFile::Atom*>::iterator pos = fGOTMap.find(&target);
if ( pos == fGOTMap.end() ) {
nlp = new NonLazyPointerAtom<A>(*this, target);
fGOTMap[&target] = nlp;
newAtoms.push_back(nlp);
}
else {
nlp = pos->second;
}
// alter reference to use non lazy pointer instead
ref->setTarget(*nlp, ref->getTargetOffset());
}
}
// build map of which symbols need weak importing
if ( (target.getDefinitionKind() == ObjectFile::Atom::kExternalDefinition)
|| (target.getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition) ) {
if ( this->weakImportReferenceKind(ref->getKind()) ) {
fWeakImportMap[&target] = true;
}
}
break;
}
}
}
}
template <typename A>
void Writer<A>::synthesizeStubs(const std::vector<class ObjectFile::Atom*>& existingAtoms,
std::vector<class ObjectFile::Atom*>& newAtoms)
{
switch ( fOptions.outputKind() ) {
case Options::kObjectFile:
case Options::kPreload:
// these output kinds never have stubs
return;
case Options::kKextBundle:
// new kext need a synthesized GOT only
synthesizeKextGOT(existingAtoms, newAtoms);
return;
case Options::kStaticExecutable:
case Options::kDyld:
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kDynamicExecutable:
// try to synthesize stubs for these
break;
}
// walk every atom and reference
for (std::vector<ObjectFile::Atom*>::const_iterator it=existingAtoms.begin(); it != existingAtoms.end(); it++) {
ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch ( ref->getTargetBinding()) {
case ObjectFile::Reference::kUnboundByName:
case ObjectFile::Reference::kDontBind:
break;
case ObjectFile::Reference::kBoundByName:
case ObjectFile::Reference::kBoundDirectly:
ObjectFile::Atom& target = ref->getTarget();
// build map of which symbols need weak importing
if ( (target.getDefinitionKind() == ObjectFile::Atom::kExternalDefinition)
|| (target.getDefinitionKind() == ObjectFile::Atom::kExternalWeakDefinition) ) {
bool weakImport = this->weakImportReferenceKind(ref->getKind());
// <rdar://problem/5633081> Obj-C Symbols in Leopard Can't Be Weak Linked
// dyld in Mac OS X 10.3 and earlier need N_WEAK_REF bit set on undefines to objc symbols
// in dylibs that are weakly linked.
if ( (ref->getKind() == A::kNoFixUp) && (strncmp(target.getName(), ".objc_class_name_", 17) == 0) ) {
typename std::map<class ObjectFile::Reader*, class DylibLoadCommandsAtom<A>* >::iterator pos;
pos = fLibraryToLoadCommand.find(target.getFile());
if ( pos != fLibraryToLoadCommand.end() ) {
if ( pos->second->linkedWeak() )
weakImport = true;
}
}
// <rdar://problem/6186838> -weak_library no longer forces uses to be weak_import
if ( fForcedWeakImportReaders.count(target.getFile()) != 0 ) {
fWeakImportMap[&target] = true;
weakImport = true;
}
std::map<const ObjectFile::Atom*,bool>::iterator pos = fWeakImportMap.find(&target);
if ( pos == fWeakImportMap.end() ) {
// target not in fWeakImportMap, so add
fWeakImportMap[&target] = weakImport;
}
else {
// target in fWeakImportMap, check for weakness mismatch
if ( pos->second != weakImport ) {
// found mismatch
switch ( fOptions.weakReferenceMismatchTreatment() ) {
case Options::kWeakReferenceMismatchError:
throwf("mismatching weak references for symbol: %s", target.getName());
case Options::kWeakReferenceMismatchWeak:
pos->second = true;
break;
case Options::kWeakReferenceMismatchNonWeak:
pos->second = false;
break;
}
}
}
// update if we use a weak_import or a strong import from this dylib
if ( fWeakImportMap[&target] )
fDylibReadersWithWeakImports.insert(target.getFile());
else
fDylibReadersWithNonWeakImports.insert(target.getFile());
}
// create stubs as needed
if ( this->stubableReference(atom, ref)
&& (ref->getTargetOffset() == 0)
&& this->relocationNeededInFinalLinkedImage(target) == kRelocExternal ) {
ObjectFile::Atom* stub = NULL;
std::map<const ObjectFile::Atom*,ObjectFile::Atom*>::iterator pos = fStubsMap.find(&target);
if ( pos == fStubsMap.end() ) {
bool forLazyDylib = false;
switch ( target.getDefinitionKind() ) {
case ObjectFile::Atom::kRegularDefinition:
case ObjectFile::Atom::kWeakDefinition:
case ObjectFile::Atom::kAbsoluteSymbol:
case ObjectFile::Atom::kTentativeDefinition:
break;
case ObjectFile::Atom::kExternalDefinition:
case ObjectFile::Atom::kExternalWeakDefinition:
if ( target.getFile()->isLazyLoadedDylib() )
forLazyDylib = true;
break;
}
// just-in-time, create GOT slot to dyld_stub_binder
if ( fOptions.makeCompressedDyldInfo() && (fFastStubGOTAtom == NULL) ) {
if ( fDyldCompressedHelperAtom == NULL )
throw "missing symbol dyld_stub_binder";
fFastStubGOTAtom = new NonLazyPointerAtom<A>(*this, *fDyldCompressedHelperAtom);
}
stub = new StubAtom<A>(*this, target, forLazyDylib);
fStubsMap[&target] = stub;
}
else {
stub = pos->second;
}
// alter reference to use stub instead
ref->setTarget(*stub, 0);
}
else if ( fOptions.usingLazyDylibLinking() && target.getFile()->isLazyLoadedDylib() ) {
throwf("illegal reference to %s in lazy loaded dylib from %s in %s",
target.getDisplayName(), atom->getDisplayName(),
atom->getFile()->getPath());
}
// create GOT slots (non-lazy pointers) as needed
else if ( this->GOTReferenceKind(ref->getKind()) ) {
//
bool mustUseGOT = ( this->relocationNeededInFinalLinkedImage(ref->getTarget()) == kRelocExternal );
bool useGOT;
if ( fBiggerThanTwoGigs ) {
// in big images use GOT for all zero fill atoms
// this is just a heuristic and may need to be re-examined
useGOT = mustUseGOT || ref->getTarget().isZeroFill();
}
else {
// < 2GB image so remove all GOT entries that we can
useGOT = mustUseGOT;
}
// if this GOT usage cannot be optimized away then make a GOT enry
if ( ! this->optimizableGOTReferenceKind(ref->getKind()) )
useGOT = true;
if ( useGOT ) {
ObjectFile::Atom* nlp = NULL;
std::map<ObjectFile::Atom*,ObjectFile::Atom*>::iterator pos = fGOTMap.find(&target);
if ( pos == fGOTMap.end() ) {
nlp = new NonLazyPointerAtom<A>(*this, target);
fGOTMap[&target] = nlp;
}
else {
nlp = pos->second;
}
// alter reference to use non lazy pointer instead
ref->setTarget(*nlp, ref->getTargetOffset());
}
}
}
}
}
// sort stubs
std::sort(fAllSynthesizedStubs.begin(), fAllSynthesizedStubs.end(), AtomByNameSorter());
// add dummy self-modifying stubs (x86 only)
if ( ! fOptions.makeCompressedDyldInfo() )
this->insertDummyStubs();
// set ordinals so sorting is preserved
uint32_t sortOrder = 0;
for (typename std::vector<StubAtom<A>*>::iterator it=fAllSynthesizedStubs.begin(); it != fAllSynthesizedStubs.end(); it++)
(*it)->setSortingOrdinal(sortOrder++);
std::sort(fAllSynthesizedStubHelpers.begin(), fAllSynthesizedStubHelpers.end(), AtomByNameSorter());
// sort lazy pointers
std::sort(fAllSynthesizedLazyPointers.begin(), fAllSynthesizedLazyPointers.end(), AtomByNameSorter());
sortOrder = 0;
for (typename std::vector<LazyPointerAtom<A>*>::iterator it=fAllSynthesizedLazyPointers.begin(); it != fAllSynthesizedLazyPointers.end(); it++)
(*it)->setSortingOrdinal(sortOrder++);
std::sort(fAllSynthesizedLazyDylibPointers.begin(), fAllSynthesizedLazyDylibPointers.end(), AtomByNameSorter());
// sort non-lazy pointers
std::sort(fAllSynthesizedNonLazyPointers.begin(), fAllSynthesizedNonLazyPointers.end(), AtomByNameSorter());
sortOrder = 0;
for (typename std::vector<NonLazyPointerAtom<A>*>::iterator it=fAllSynthesizedNonLazyPointers.begin(); it != fAllSynthesizedNonLazyPointers.end(); it++)
(*it)->setSortingOrdinal(sortOrder++);
std::sort(fAllSynthesizedNonLazyPointers.begin(), fAllSynthesizedNonLazyPointers.end(), AtomByNameSorter());
// tell linker about all synthesized atoms
newAtoms.insert(newAtoms.end(), fAllSynthesizedStubs.begin(), fAllSynthesizedStubs.end());
newAtoms.insert(newAtoms.end(), fAllSynthesizedStubHelpers.begin(), fAllSynthesizedStubHelpers.end());
newAtoms.insert(newAtoms.end(), fAllSynthesizedLazyPointers.begin(), fAllSynthesizedLazyPointers.end());
newAtoms.insert(newAtoms.end(), fAllSynthesizedLazyDylibPointers.begin(), fAllSynthesizedLazyDylibPointers.end());
newAtoms.insert(newAtoms.end(), fAllSynthesizedNonLazyPointers.begin(), fAllSynthesizedNonLazyPointers.end());
}
template <typename A>
void Writer<A>::createSplitSegContent()
{
// build LC_SEGMENT_SPLIT_INFO once all atoms exist
if ( fSplitCodeToDataContentAtom != NULL ) {
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
switch ( ref->getTargetBinding()) {
case ObjectFile::Reference::kUnboundByName:
case ObjectFile::Reference::kDontBind:
break;
case ObjectFile::Reference::kBoundByName:
case ObjectFile::Reference::kBoundDirectly:
if ( this->segmentsCanSplitApart(*atom, ref->getTarget()) ) {
this->addCrossSegmentRef(atom, ref);
}
break;
}
}
}
// bad codegen may cause LC_SEGMENT_SPLIT_INFO to be removed
adjustLoadCommandsAndPadding();
}
}
template <typename A>
void Writer<A>::synthesizeUnwindInfoTable()
{
if ( fUnwindInfoAtom != NULL ) {
// walk every atom and gets its unwind info
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
if ( atom->beginUnwind() == atom->endUnwind() ) {
// be sure to mark that we have no unwind info for stuff in the TEXT segment without unwind info
if ( strcmp(atom->getSegment().getName(), "__TEXT") == 0 )
fUnwindInfoAtom->addUnwindInfo(atom, 0, 0, NULL, NULL, NULL);
}
else {
// atom has unwind
for ( ObjectFile::UnwindInfo::iterator uit = atom->beginUnwind(); uit != atom->endUnwind(); ++uit ) {
fUnwindInfoAtom->addUnwindInfo(atom, uit->startOffset, uit->unwindInfo, atom->getFDE(), atom->getLSDA(), atom->getPersonalityPointer());
}
}
}
}
}
template <typename A>
void Writer<A>::partitionIntoSections()
{
const bool oneSegmentCommand = (fOptions.outputKind() == Options::kObjectFile);
// for every atom, set its sectionInfo object and section offset
// build up fSegmentInfos along the way
ObjectFile::Section* curSection = (ObjectFile::Section*)(-1);
SectionInfo* currentSectionInfo = NULL;
SegmentInfo* currentSegmentInfo = NULL;
SectionInfo* cstringSectionInfo = NULL;
unsigned int sectionIndex = 1;
fSegmentInfos.reserve(8);
for (unsigned int i=0; i < fAllAtoms->size(); ++i) {
ObjectFile::Atom* atom = (*fAllAtoms)[i];
if ( ((atom->getSection() != curSection) || (curSection==NULL))
&& ((currentSectionInfo == NULL)
|| (strcmp(atom->getSectionName(),currentSectionInfo->fSectionName) != 0)
|| (strcmp(atom->getSegment().getName(),currentSectionInfo->fSegmentName) != 0)) ) {
if ( oneSegmentCommand ) {
if ( currentSegmentInfo == NULL ) {
currentSegmentInfo = new SegmentInfo(fOptions.segmentAlignment());
currentSegmentInfo->fInitProtection = VM_PROT_READ | VM_PROT_WRITE | VM_PROT_EXECUTE;
currentSegmentInfo->fMaxProtection = VM_PROT_READ | VM_PROT_WRITE | VM_PROT_EXECUTE;
this->fSegmentInfos.push_back(currentSegmentInfo);
}
currentSectionInfo = new SectionInfo();
strcpy(currentSectionInfo->fSectionName, atom->getSectionName());
strcpy(currentSectionInfo->fSegmentName, atom->getSegment().getName());
currentSectionInfo->fAlignment = atom->getAlignment().powerOf2;
currentSectionInfo->fAllZeroFill = atom->isZeroFill();
currentSectionInfo->fVirtualSection = (currentSectionInfo->fSectionName[0] == '.');
if ( !currentSectionInfo->fVirtualSection || fEmitVirtualSections )
currentSectionInfo->setIndex(sectionIndex++);
currentSegmentInfo->fSections.push_back(currentSectionInfo);
if ( (strcmp(currentSectionInfo->fSegmentName, "__TEXT") == 0) && (strcmp(currentSectionInfo->fSectionName, "__cstring") == 0) )
cstringSectionInfo = currentSectionInfo;
}
else {
if ( (currentSegmentInfo == NULL) || (strcmp(currentSegmentInfo->fName, atom->getSegment().getName()) != 0) ) {
currentSegmentInfo = new SegmentInfo(fOptions.segmentAlignment());
strcpy(currentSegmentInfo->fName, atom->getSegment().getName());
uint32_t initprot = 0;
if ( atom->getSegment().isContentReadable() )
initprot |= VM_PROT_READ;
if ( atom->getSegment().isContentWritable() )
initprot |= VM_PROT_WRITE;
if ( atom->getSegment().isContentExecutable() )
initprot |= VM_PROT_EXECUTE;
if ( fOptions.readOnlyx86Stubs() && (strcmp(atom->getSegment().getName(), "__IMPORT") == 0) )
initprot &= ~VM_PROT_WRITE; // hack until i386 __pointers section is synthesized by linker
currentSegmentInfo->fInitProtection = initprot;
if ( initprot == 0 )
currentSegmentInfo->fMaxProtection = 0; // pagezero should have maxprot==initprot==0
else if ( fOptions.architecture() == CPU_TYPE_ARM )
currentSegmentInfo->fMaxProtection = currentSegmentInfo->fInitProtection; // iPhoneOS wants max==init
else
currentSegmentInfo->fMaxProtection = VM_PROT_READ | VM_PROT_WRITE | VM_PROT_EXECUTE;
std::vector<Options::SegmentProtect>& customSegProtections = fOptions.customSegmentProtections();
for(std::vector<Options::SegmentProtect>::iterator it = customSegProtections.begin(); it != customSegProtections.end(); ++it) {
if ( strcmp(it->name, currentSegmentInfo->fName) == 0 ) {
currentSegmentInfo->fInitProtection = it->init;
currentSegmentInfo->fMaxProtection = it->max;
}
}
currentSegmentInfo->fBaseAddress = atom->getSegment().getBaseAddress();
currentSegmentInfo->fFixedAddress = atom->getSegment().hasFixedAddress();
if ( currentSegmentInfo->fFixedAddress && (&(atom->getSegment()) == &Segment::fgStackSegment) )
currentSegmentInfo->fIndependentAddress = true;
if ( (fOptions.outputKind() == Options::kPreload) && (strcmp(currentSegmentInfo->fName, "__LINKEDIT")==0) )
currentSegmentInfo->fHasLoadCommand = false;
if ( strcmp(currentSegmentInfo->fName, "__HEADER")==0 )
currentSegmentInfo->fHasLoadCommand = false;
this->fSegmentInfos.push_back(currentSegmentInfo);
}
currentSectionInfo = new SectionInfo();
currentSectionInfo->fAtoms.reserve(fAllAtoms->size()/4); // reduce reallocations by starting large
strcpy(currentSectionInfo->fSectionName, atom->getSectionName());
strcpy(currentSectionInfo->fSegmentName, atom->getSegment().getName());
currentSectionInfo->fAlignment = atom->getAlignment().powerOf2;
// check for -sectalign override
std::vector<Options::SectionAlignment>& alignmentOverrides = fOptions.sectionAlignments();
for(std::vector<Options::SectionAlignment>::iterator it=alignmentOverrides.begin(); it != alignmentOverrides.end(); ++it) {
if ( (strcmp(it->segmentName, currentSectionInfo->fSegmentName) == 0) && (strcmp(it->sectionName, currentSectionInfo->fSectionName) == 0) )
currentSectionInfo->fAlignment = it->alignment;
}
currentSectionInfo->fAllZeroFill = atom->isZeroFill();
currentSectionInfo->fVirtualSection = ( currentSectionInfo->fSectionName[0] == '.');
if ( !currentSectionInfo->fVirtualSection || fEmitVirtualSections )
currentSectionInfo->setIndex(sectionIndex++);
currentSegmentInfo->fSections.push_back(currentSectionInfo);
}
//fprintf(stderr, "new section %s for atom %s\n", atom->getSectionName(), atom->getDisplayName());
if ( strcmp(currentSectionInfo->fSectionName, "._load_commands") == 0 ) {
fLoadCommandsSection = currentSectionInfo;
fLoadCommandsSegment = currentSegmentInfo;
}
switch ( atom->getContentType() ) {
case ObjectFile::Atom::kLazyPointer:
currentSectionInfo->fAllLazyPointers = true;
fSymbolTableCommands->needDynamicTable();
break;
case ObjectFile::Atom::kNonLazyPointer:
currentSectionInfo->fAllNonLazyPointers = true;
fSymbolTableCommands->needDynamicTable();
break;
case ObjectFile::Atom::kLazyDylibPointer:
currentSectionInfo->fAllLazyDylibPointers = true;
break;
case ObjectFile::Atom::kStubHelper:
currentSectionInfo->fAllStubHelpers = true;
break;
case ObjectFile::Atom::kCFIType:
currentSectionInfo->fAlignment = __builtin_ctz(sizeof(pint_t)); // always start CFI info pointer aligned
break;
case ObjectFile::Atom::kStub:
if ( (strcmp(currentSectionInfo->fSegmentName, "__IMPORT") == 0) && (strcmp(currentSectionInfo->fSectionName, "__jump_table") == 0) ) {
currentSectionInfo->fAllSelfModifyingStubs = true;
currentSectionInfo->fAlignment = 6; // force x86 fast stubs to start on 64-byte boundary
}
else {
currentSectionInfo->fAllStubs = true;
}
fSymbolTableCommands->needDynamicTable();
break;
default:
break;
}
curSection = atom->getSection();
}
// any non-zero fill atoms make whole section marked not-zero-fill
if ( currentSectionInfo->fAllZeroFill && ! atom->isZeroFill() )
currentSectionInfo->fAllZeroFill = false;
// change section object to be Writer's SectionInfo object
atom->setSection(currentSectionInfo);
// section alignment is that of a contained atom with the greatest alignment
uint8_t atomAlign = atom->getAlignment().powerOf2;
if ( currentSectionInfo->fAlignment < atomAlign )
currentSectionInfo->fAlignment = atomAlign;
// calculate section offset for this atom
uint64_t offset = currentSectionInfo->fSize;
uint64_t alignment = 1 << atomAlign;
uint64_t currentModulus = (offset % alignment);
uint64_t requiredModulus = atom->getAlignment().modulus;
if ( currentModulus != requiredModulus ) {
if ( requiredModulus > currentModulus )
offset += requiredModulus-currentModulus;
else
offset += requiredModulus+alignment-currentModulus;
}
atom->setSectionOffset(offset);
uint64_t curAtomSize = atom->getSize();
currentSectionInfo->fSize = offset + curAtomSize;
// add atom to section vector
currentSectionInfo->fAtoms.push_back(atom);
//fprintf(stderr, " adding atom %p %s size=0x%0llX to section %p %s from %s\n", atom, atom->getDisplayName(), atom->getSize(),
// currentSectionInfo, currentSectionInfo->fSectionName, atom->getFile()->getPath());
// update largest size
if ( !currentSectionInfo->fAllZeroFill && (curAtomSize > fLargestAtomSize) )
fLargestAtomSize = curAtomSize;
}
if ( (cstringSectionInfo != NULL) && (cstringSectionInfo->fAlignment > 0) ) {
// when merging cstring sections in .o files, all strings need to use the max alignment
uint64_t offset = 0;
uint64_t cstringAlignment = 1 << cstringSectionInfo->fAlignment;
for (std::vector<ObjectFile::Atom*>::iterator it=cstringSectionInfo->fAtoms.begin(); it != cstringSectionInfo->fAtoms.end(); it++) {
offset = (offset + (cstringAlignment-1)) & (-cstringAlignment);
ObjectFile::Atom* atom = *it;
atom->setSectionOffset(offset);
offset += atom->getSize();
}
cstringSectionInfo->fSize = offset;
}
}
struct TargetAndOffset { ObjectFile::Atom* atom; uint32_t offset; };
class TargetAndOffsetComparor
{
public:
bool operator()(const TargetAndOffset& left, const TargetAndOffset& right) const
{
if ( left.atom != right.atom )
return ( left.atom < right.atom );
return ( left.offset < right.offset );
}
};
template <>
bool Writer<ppc>::addBranchIslands()
{
return this->createBranchIslands();
}
template <>
bool Writer<ppc64>::addBranchIslands()
{
return this->createBranchIslands();
}
template <>
bool Writer<x86>::addBranchIslands()
{
// x86 branches can reach entire 4G address space, so no need for branch islands
return false;
}
template <>
bool Writer<x86_64>::addBranchIslands()
{
// x86 branches can reach entire 4G size of largest image
return false;
}
template <>
bool Writer<arm>::addBranchIslands()
{
return this->createBranchIslands();
}
template <>
bool Writer<ppc>::isBranchThatMightNeedIsland(uint8_t kind)
{
switch (kind) {
case ppc::kBranch24:
case ppc::kBranch24WeakImport:
return true;
}
return false;
}
template <>
bool Writer<ppc64>::isBranchThatMightNeedIsland(uint8_t kind)
{
switch (kind) {
case ppc64::kBranch24:
case ppc64::kBranch24WeakImport:
return true;
}
return false;
}
template <>
bool Writer<arm>::isBranchThatMightNeedIsland(uint8_t kind)
{
switch (kind) {
case arm::kBranch24:
case arm::kBranch24WeakImport:
case arm::kThumbBranch22:
case arm::kThumbBranch22WeakImport:
return true;
}
return false;
}
template <>
uint32_t Writer<ppc>::textSizeWhenMightNeedBranchIslands()
{
return 16000000;
}
template <>
uint32_t Writer<ppc64>::textSizeWhenMightNeedBranchIslands()
{
return 16000000;
}
template <>
uint32_t Writer<arm>::textSizeWhenMightNeedBranchIslands()
{
if ( fHasThumbBranches == false )
return 32000000; // ARM can branch +/- 32MB
else if ( fOptions.preferSubArchitecture() && fOptions.subArchitecture() == CPU_SUBTYPE_ARM_V7 )
return 16000000; // thumb2 can branch +/- 16MB
else
return 4000000; // thumb1 can branch +/- 4MB
}
template <>
uint32_t Writer<ppc>::maxDistanceBetweenIslands()
{
return 14*1024*1024;
}
template <>
uint32_t Writer<ppc64>::maxDistanceBetweenIslands()
{
return 14*1024*1024;
}
template <>
uint32_t Writer<arm>::maxDistanceBetweenIslands()
{
if ( fHasThumbBranches == false )
return 30*1024*1024;
else if ( fOptions.preferSubArchitecture() && fOptions.subArchitecture() == CPU_SUBTYPE_ARM_V7 )
return 14*1024*1024;
else
return 3500000;
}
//
// PowerPC can do PC relative branches as far as +/-16MB.
// If a branch target is >16MB then we insert one or more
// "branch islands" between the branch and its target that
// allows island hopping to the target.
//
// Branch Island Algorithm
//
// If the __TEXT segment < 16MB, then no branch islands needed
// Otherwise, every 14MB into the __TEXT segment a region is
// added which can contain branch islands. Every out-of-range
// bl instruction is checked. If it crosses a region, an island
// is added to that region with the same target and the bl is
// adjusted to target the island instead.
//
// In theory, if too many islands are added to one region, it
// could grow the __TEXT enough that other previously in-range
// bl branches could be pushed out of range. We reduce the
// probability this could happen by placing the ranges every
// 14MB which means the region would have to be 2MB (512,000 islands)
// before any branches could be pushed out of range.
//
template <typename A>
bool Writer<A>::createBranchIslands()
{
bool log = false;
bool result = false;
// Can only possibly need branch islands if __TEXT segment > 16M
if ( fLoadCommandsSegment->fSize > textSizeWhenMightNeedBranchIslands() ) {
if ( log) fprintf(stderr, "ld: checking for branch islands, __TEXT segment size=%llu\n", fLoadCommandsSegment->fSize);
const uint32_t kBetweenRegions = maxDistanceBetweenIslands(); // place regions of islands every 14MB in __text section
SectionInfo* textSection = NULL;
for (std::vector<SectionInfo*>::iterator it=fLoadCommandsSegment->fSections.begin(); it != fLoadCommandsSegment->fSections.end(); it++) {
if ( strcmp((*it)->fSectionName, "__text") == 0 ) {
textSection = *it;
if ( log) fprintf(stderr, "ld: checking for branch islands, __text section size=%llu\n", textSection->fSize);
break;
}
}
const int kIslandRegionsCount = fLoadCommandsSegment->fSize / kBetweenRegions;
typedef std::map<TargetAndOffset,ObjectFile::Atom*, TargetAndOffsetComparor> AtomToIsland;
AtomToIsland regionsMap[kIslandRegionsCount];
std::vector<ObjectFile::Atom*> regionsIslands[kIslandRegionsCount];
unsigned int islandCount = 0;
if (log) fprintf(stderr, "ld: will use %u branch island regions\n", kIslandRegionsCount);
// create islands for branch references that are out of range
for (std::vector<ObjectFile::Atom*>::iterator it=fAllAtoms->begin(); it != fAllAtoms->end(); it++) {
ObjectFile::Atom* atom = *it;
std::vector<ObjectFile::Reference*>& references = atom->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
ObjectFile::Reference* ref = *rit;
if ( this->isBranchThatMightNeedIsland(ref->getKind()) ) {
ObjectFile::Atom& target = ref->getTarget();
int64_t srcAddr = atom->getAddress() + ref->getFixUpOffset();
int64_t dstAddr = target.getAddress() + ref->getTargetOffset();
int64_t displacement = dstAddr - srcAddr;
TargetAndOffset finalTargetAndOffset = { &target, ref->getTargetOffset() };
const int64_t kBranchLimit = kBetweenRegions;
if ( displacement > kBranchLimit ) {
// create forward branch chain
ObjectFile::Atom* nextTarget = ⌖
for (int i=kIslandRegionsCount-1; i >=0 ; --i) {
AtomToIsland* region = ®ionsMap[i];
int64_t islandRegionAddr = kBetweenRegions * (i+1) + textSection->getBaseAddress();
if ( (srcAddr < islandRegionAddr) && (islandRegionAddr <= dstAddr) ) {
AtomToIsland::iterator pos = region->find(finalTargetAndOffset);
if ( pos == region->end() ) {
BranchIslandAtom<A>* island = new BranchIslandAtom<A>(*this, target.getDisplayName(), i, *nextTarget, *finalTargetAndOffset.atom, finalTargetAndOffset.offset);
island->setSection(textSection);
(*region)[finalTargetAndOffset] = island;
if (log) fprintf(stderr, "added island %s to region %d for %s\n", island->getDisplayName(), i, atom->getDisplayName());
regionsIslands[i].push_back(island);
++islandCount;
nextTarget = island;
}
else {
nextTarget = pos->second;
}
}
}
if (log) fprintf(stderr, "using island %s for branch to %s from %s\n", nextTarget->getDisplayName(), target.getDisplayName(), atom->getDisplayName());
ref->setTarget(*nextTarget, 0);
}
else if ( displacement < (-kBranchLimit) ) {
// create back branching chain
ObjectFile::Atom* prevTarget = ⌖
for (int i=0; i < kIslandRegionsCount ; ++i) {
AtomToIsland* region = ®ionsMap[i];
int64_t islandRegionAddr = kBetweenRegions * (i+1);
if ( (dstAddr <= islandRegionAddr) && (islandRegionAddr < srcAddr) ) {
AtomToIsland::iterator pos = region->find(finalTargetAndOffset);
if ( pos == region->end() ) {
BranchIslandAtom<A>* island = new BranchIslandAtom<A>(*this, target.getDisplayName(), i, *prevTarget, *finalTargetAndOffset.atom, finalTargetAndOffset.offset);
island->setSection(textSection);
(*region)[finalTargetAndOffset] = island;
if (log) fprintf(stderr, "added back island %s to region %d for %s\n", island->getDisplayName(), i, atom->getDisplayName());
regionsIslands[i].push_back(island);
++islandCount;
prevTarget = island;
}
else {
prevTarget = pos->second;
}
}
}
if (log) fprintf(stderr, "using back island %s for %s\n", prevTarget->getDisplayName(), atom->getDisplayName());
ref->setTarget(*prevTarget, 0);
}
}
}
}
// insert islands into __text section and adjust section offsets
if ( islandCount > 0 ) {
if ( log ) fprintf(stderr, "ld: %u branch islands required in %u regions\n", islandCount, kIslandRegionsCount);
std::vector<ObjectFile::Atom*> newAtomList;
newAtomList.reserve(textSection->fAtoms.size()+islandCount);
uint64_t islandRegionAddr = kBetweenRegions + textSection->getBaseAddress();
uint64_t textSectionAlignment = (1 << textSection->fAlignment);
int regionIndex = 0;
uint64_t atomSlide = 0;
uint64_t sectionOffset = 0;
for (std::vector<ObjectFile::Atom*>::iterator it=textSection->fAtoms.begin(); it != textSection->fAtoms.end(); it++) {
ObjectFile::Atom* atom = *it;
if ( (atom->getAddress()+atom->getSize()) > islandRegionAddr ) {
uint64_t islandStartOffset = atom->getSectionOffset() + atomSlide;
sectionOffset = islandStartOffset;
std::vector<ObjectFile::Atom*>* regionIslands = ®ionsIslands[regionIndex];
for (std::vector<ObjectFile::Atom*>::iterator rit=regionIslands->begin(); rit != regionIslands->end(); rit++) {
ObjectFile::Atom* islandAtom = *rit;
newAtomList.push_back(islandAtom);
uint64_t alignment = 1 << (islandAtom->getAlignment().powerOf2);
sectionOffset = ( (sectionOffset+alignment-1) & (-alignment) );
islandAtom->setSectionOffset(sectionOffset);
if ( log ) fprintf(stderr, "assigning __text offset 0x%08llx to %s\n", sectionOffset, islandAtom->getDisplayName());
sectionOffset += islandAtom->getSize();
}
++regionIndex;
islandRegionAddr += kBetweenRegions;
uint64_t islandRegionAlignmentBlocks = (sectionOffset - islandStartOffset + textSectionAlignment - 1) / textSectionAlignment;
atomSlide += (islandRegionAlignmentBlocks * textSectionAlignment);
}
newAtomList.push_back(atom);
if ( atomSlide != 0 )
atom->setSectionOffset(atom->getSectionOffset()+atomSlide);
}
sectionOffset = textSection->fSize+atomSlide;
// put any remaining islands at end of __text section
if ( regionIndex < kIslandRegionsCount ) {
std::vector<ObjectFile::Atom*>* regionIslands = ®ionsIslands[regionIndex];
for (std::vector<ObjectFile::Atom*>::iterator rit=regionIslands->begin(); rit != regionIslands->end(); rit++) {
ObjectFile::Atom* islandAtom = *rit;
newAtomList.push_back(islandAtom);
uint64_t alignment = 1 << (islandAtom->getAlignment().powerOf2);
sectionOffset = ( (sectionOffset+alignment-1) & (-alignment) );
islandAtom->setSectionOffset(sectionOffset);
if ( log ) fprintf(stderr, "assigning __text offset 0x%08llx to %s\n", sectionOffset, islandAtom->getDisplayName());
sectionOffset += islandAtom->getSize();
}
}
textSection->fAtoms = newAtomList;
textSection->fSize = sectionOffset;
result = true;
}
}
return result;
}
template <typename A>
void Writer<A>::adjustLoadCommandsAndPadding()
{
fSegmentCommands->computeSize();
// recompute load command section offsets
uint64_t offset = 0;
std::vector<class ObjectFile::Atom*>& loadCommandAtoms = fLoadCommandsSection->fAtoms;
const unsigned int atomCount = loadCommandAtoms.size();
for (unsigned int i=0; i < atomCount; ++i) {
ObjectFile::Atom* atom = loadCommandAtoms[i];
uint64_t alignment = 1 << atom->getAlignment().powerOf2;
offset = ( (offset+alignment-1) & (-alignment) );
atom->setSectionOffset(offset);
uint32_t atomSize = atom->getSize();
if ( atomSize > fLargestAtomSize )
fLargestAtomSize = atomSize;
offset += atomSize;
fLoadCommandsSection->fSize = offset;
}
const uint32_t sizeOfLoadCommandsPlusHeader = offset + sizeof(macho_header<typename A::P>);
std::vector<SectionInfo*>& sectionInfos = fLoadCommandsSegment->fSections;
const int sectionCount = sectionInfos.size();
uint32_t totalSizeOfTEXTLessHeaderAndLoadCommands = 0;
for(int j=0; j < sectionCount; ++j) {
SectionInfo* curSection = sectionInfos[j];
if ( strcmp(curSection->fSectionName, fHeaderPadding->getSectionName()) == 0 )
break;
totalSizeOfTEXTLessHeaderAndLoadCommands += curSection->fSize;
}
uint64_t paddingSize = 0;
if ( fOptions.outputKind() == Options::kDyld ) {
// dyld itself has special padding requirements. We want the beginning __text section to start at a stable address
paddingSize = 4096 - (totalSizeOfTEXTLessHeaderAndLoadCommands % 4096);
}
else if ( fOptions.outputKind() == Options::kObjectFile ) {
// mach-o .o files need no padding between load commands and first section
// but leave enough room that the object file could be signed
paddingSize = 32;
}
else if ( fOptions.outputKind() == Options::kPreload ) {
// mach-o MH_PRELOAD files need no padding between load commands and first section
paddingSize = 0;
}
else {
// work backwards from end of segment and lay out sections so that extra room goes to padding atom
uint64_t addr = 0;
for(int j=sectionCount-1; j >=0; --j) {
SectionInfo* curSection = sectionInfos[j];
if ( strcmp(curSection->fSectionName, fHeaderPadding->getSectionName()) == 0 ) {
addr -= (fLoadCommandsSection->fSize+fMachHeaderAtom->getSize());
paddingSize = addr % fOptions.segmentAlignment();
break;
}
addr -= curSection->fSize;
addr = addr & (0 - (1 << curSection->fAlignment));
}
// if command line requires more padding than this
uint32_t minPad = fOptions.minimumHeaderPad();
if ( fOptions.maxMminimumHeaderPad() ) {
// -headerpad_max_install_names means there should be room for every path load command to grow to 1204 bytes
uint32_t altMin = fLibraryToOrdinal.size() * MAXPATHLEN;
if ( fOptions.outputKind() == Options::kDynamicLibrary )
altMin += MAXPATHLEN;
if ( altMin > minPad )
minPad = altMin;
}
if ( paddingSize < minPad ) {
int extraPages = (minPad - paddingSize + fOptions.segmentAlignment() - 1)/fOptions.segmentAlignment();
paddingSize += extraPages * fOptions.segmentAlignment();
}
if ( fOptions.makeEncryptable() ) {
// load commands must be on a separate non-encrypted page
int loadCommandsPage = (sizeOfLoadCommandsPlusHeader + minPad)/fOptions.segmentAlignment();
int textPage = (sizeOfLoadCommandsPlusHeader + paddingSize)/fOptions.segmentAlignment();
if ( loadCommandsPage == textPage ) {
paddingSize += fOptions.segmentAlignment();
textPage += 1;
}
//paddingSize = 4096 - ((totalSizeOfTEXTLessHeaderAndLoadCommands+fOptions.minimumHeaderPad()) % 4096) + fOptions.minimumHeaderPad();
fEncryptionLoadCommand->setStartEncryptionOffset(textPage*fOptions.segmentAlignment());
}
}
// adjust atom size and update section size
fHeaderPadding->setSize(paddingSize);
for(int j=0; j < sectionCount; ++j) {
SectionInfo* curSection = sectionInfos[j];
if ( strcmp(curSection->fSectionName, fHeaderPadding->getSectionName()) == 0 )
curSection->fSize = paddingSize;
}
}
static uint64_t segmentAlign(uint64_t addr, uint64_t alignment)
{
return ((addr+alignment-1) & (-alignment));
}
// assign file offsets and logical address to all segments
template <typename A>
void Writer<A>::assignFileOffsets()
{
const bool virtualSectionOccupyAddressSpace = ((fOptions.outputKind() != Options::kObjectFile)
&& (fOptions.outputKind() != Options::kPreload));
bool haveFixedSegments = false;
uint64_t fileOffset = 0;
uint64_t nextContiguousAddress = fOptions.baseAddress();
uint64_t nextReadOnlyAddress = fOptions.baseAddress();
uint64_t nextWritableAddress = fOptions.baseWritableAddress();
// process segments with fixed addresses (-segaddr)
for (std::vector<Options::SegmentStart>::iterator it = fOptions.customSegmentAddresses().begin(); it != fOptions.customSegmentAddresses().end(); ++it) {
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
if ( strcmp(curSegment->fName, it->name) == 0 ) {
curSegment->fBaseAddress = it->address;
curSegment->fFixedAddress = true;
break;
}
}
}
// process segments with fixed addresses (-seg_page_size)
for (std::vector<Options::SegmentSize>::iterator it = fOptions.customSegmentSizes().begin(); it != fOptions.customSegmentSizes().end(); ++it) {
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
if ( strcmp(curSegment->fName, it->name) == 0 ) {
curSegment->fPageSize = it->size;
break;
}
}
}
// Run through the segments and each segment's sections to assign addresses
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
if ( fOptions.splitSeg() ) {
if ( curSegment->fInitProtection & VM_PROT_WRITE )
nextContiguousAddress = nextWritableAddress;
else
nextContiguousAddress = nextReadOnlyAddress;
}
if ( fOptions.outputKind() == Options::kPreload ) {
if ( strcmp(curSegment->fName, "__HEADER") == 0 )
nextContiguousAddress = 0;
else if ( strcmp(curSegment->fName, "__TEXT") == 0 )
nextContiguousAddress = fOptions.baseAddress();
}
fileOffset = segmentAlign(fileOffset, curSegment->fPageSize);
curSegment->fFileOffset = fileOffset;
// Set the segment base address
if ( curSegment->fFixedAddress )
haveFixedSegments = true;
else
curSegment->fBaseAddress = segmentAlign(nextContiguousAddress, curSegment->fPageSize);
// We've set the segment address, now run through each section.
uint64_t address = curSegment->fBaseAddress;
SectionInfo* firstZeroFillSection = NULL;
SectionInfo* prevSection = NULL;
std::vector<SectionInfo*>& sectionInfos = curSegment->fSections;
for (std::vector<SectionInfo*>::iterator it = sectionInfos.begin(); it != sectionInfos.end(); ++it) {
SectionInfo* curSection = *it;
// adjust section address based on alignment
uint64_t alignment = 1 << curSection->fAlignment;
if ( curSection->fAtoms.size() == 1 ) {
// if there is only one atom in section, use modulus for even better layout
ObjectFile::Alignment atomAlign = curSection->fAtoms[0]->getAlignment();
uint64_t atomAlignP2 = (1 << atomAlign.powerOf2);
uint64_t currentModulus = (address % atomAlignP2);
if ( currentModulus != atomAlign.modulus ) {
if ( atomAlign.modulus > currentModulus )
address += atomAlign.modulus-currentModulus;
else
address += atomAlign.modulus+atomAlignP2-currentModulus;
}
}
else {
address = ( (address+alignment-1) & (-alignment) );
}
// adjust file offset to match address
if ( prevSection != NULL ) {
if ( virtualSectionOccupyAddressSpace || !prevSection->fVirtualSection )
fileOffset = (address - prevSection->getBaseAddress()) + prevSection->fFileOffset;
else
fileOffset = ( (fileOffset+alignment-1) & (-alignment) );
}
// update section info
curSection->fFileOffset = fileOffset;
curSection->setBaseAddress(address);
//fprintf(stderr, "%s %s addr=0x%llX, fileoffset=0x%llX, size=0x%llX\n", curSegment->fName, curSection->fSectionName, address, fileOffset, curSection->fSize);
// keep track of trailing zero fill sections
if ( curSection->fAllZeroFill && (firstZeroFillSection == NULL) )
firstZeroFillSection = curSection;
if ( !curSection->fAllZeroFill && (firstZeroFillSection != NULL) && (fOptions.outputKind() != Options::kObjectFile) )
throwf("zero-fill section %s not at end of segment", curSection->fSectionName);
// update running pointers
if ( virtualSectionOccupyAddressSpace || !curSection->fVirtualSection )
address += curSection->fSize;
fileOffset += curSection->fSize;
// sanity check size of 32-bit binaries
if ( address > maxAddress() )
throwf("section %s exceeds 4GB limit", curSection->fSectionName);
// update segment info
curSegment->fFileSize = fileOffset - curSegment->fFileOffset;
curSegment->fSize = curSegment->fFileSize;
prevSection = curSection;
}
if ( fOptions.outputKind() == Options::kObjectFile ) {
// don't page align .o files
}
else {
// optimize trailing zero-fill sections to not occupy disk space
if ( firstZeroFillSection != NULL ) {
curSegment->fFileSize = firstZeroFillSection->fFileOffset - curSegment->fFileOffset;
fileOffset = firstZeroFillSection->fFileOffset;
}
// page align segment size
curSegment->fFileSize = segmentAlign(curSegment->fFileSize, curSegment->fPageSize);
curSegment->fSize = segmentAlign(curSegment->fSize, curSegment->fPageSize);
if ( !curSegment->fIndependentAddress && (curSegment->fBaseAddress >= nextContiguousAddress) ) {
nextContiguousAddress = segmentAlign(curSegment->fBaseAddress+curSegment->fSize, curSegment->fPageSize);
fileOffset = segmentAlign(fileOffset, curSegment->fPageSize);
if ( curSegment->fInitProtection & VM_PROT_WRITE )
nextWritableAddress = nextContiguousAddress;
else
nextReadOnlyAddress = nextContiguousAddress;
}
}
//fprintf(stderr, "end of seg %s, fileoffset=0x%llX, nextContiguousAddress=0x%llX\n", curSegment->fName, fileOffset, nextContiguousAddress);
}
// check for segment overlaps caused by user specified fixed segments (e.g. __PAGEZERO, __UNIXSTACK)
if ( haveFixedSegments ) {
int segCount = fSegmentInfos.size();
for(int i=0; i < segCount; ++i) {
SegmentInfo* segment1 = fSegmentInfos[i];
for(int j=0; j < segCount; ++j) {
if ( i != j ) {
SegmentInfo* segment2 = fSegmentInfos[j];
if ( segment1->fBaseAddress < segment2->fBaseAddress ) {
if ( (segment1->fBaseAddress+segment1->fSize) > segment2->fBaseAddress )
throwf("segments overlap: %s (0x%08llX + 0x%08llX) and %s (0x%08llX + 0x%08llX)",
segment1->fName, segment1->fBaseAddress, segment1->fSize, segment2->fName, segment2->fBaseAddress, segment2->fSize);
}
else if ( segment1->fBaseAddress > segment2->fBaseAddress ) {
if ( (segment2->fBaseAddress+segment2->fSize) > segment1->fBaseAddress )
throwf("segments overlap: %s (0x%08llX + 0x%08llX) and %s (0x%08llX + 0x%08llX)",
segment1->fName, segment1->fBaseAddress, segment1->fSize, segment2->fName, segment2->fBaseAddress, segment2->fSize);
}
else if ( (segment1->fSize != 0) && (segment2->fSize != 0) ) {
throwf("segments overlap: %s (0x%08llX + 0x%08llX) and %s (0x%08llX + 0x%08llX)",
segment1->fName, segment1->fBaseAddress, segment1->fSize, segment2->fName, segment2->fBaseAddress, segment2->fSize);
}
}
}
}
}
// set up fFirstWritableSegment and fWritableSegmentPastFirst4GB
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
if ( (curSegment->fInitProtection & VM_PROT_WRITE) != 0 ) {
if ( fFirstWritableSegment == NULL )
fFirstWritableSegment = curSegment;
if ( (curSegment->fBaseAddress + curSegment->fSize - fOptions.baseAddress()) >= 0x100000000LL )
fWritableSegmentPastFirst4GB = true;
}
}
// record size of encrypted part of __TEXT segment
if ( fOptions.makeEncryptable() ) {
for (std::vector<SegmentInfo*>::iterator segit = fSegmentInfos.begin(); segit != fSegmentInfos.end(); ++segit) {
SegmentInfo* curSegment = *segit;
if ( strcmp(curSegment->fName, "__TEXT") == 0 ) {
fEncryptionLoadCommand->setEndEncryptionOffset(curSegment->fFileSize);
break;
}
}
}
}
template <typename A>
void Writer<A>::adjustLinkEditSections()
{
// link edit content is always in last segment
SegmentInfo* lastSeg = fSegmentInfos[fSegmentInfos.size()-1];
unsigned int firstLinkEditSectionIndex = 0;
while ( strcmp(lastSeg->fSections[firstLinkEditSectionIndex]->fSegmentName, "__LINKEDIT") != 0 )
++firstLinkEditSectionIndex;
const unsigned int linkEditSectionCount = lastSeg->fSections.size();
uint64_t fileOffset = lastSeg->fSections[firstLinkEditSectionIndex]->fFileOffset;
uint64_t address = lastSeg->fSections[firstLinkEditSectionIndex]->getBaseAddress();
if ( fPadSegmentInfo != NULL ) {
// insert __4GBFILL segment into segments vector before LINKEDIT
for(std::vector<SegmentInfo*>::iterator it = fSegmentInfos.begin(); it != fSegmentInfos.end(); ++it) {
if ( *it == lastSeg ) {
fSegmentInfos.insert(it, fPadSegmentInfo);
break;
}
}
// adjust __4GBFILL segment to span from end of last segment to zeroPageSize
fPadSegmentInfo->fSize = fOptions.zeroPageSize() - address;
fPadSegmentInfo->fBaseAddress = address;
// adjust LINKEDIT to start at zeroPageSize
address = fOptions.zeroPageSize();
lastSeg->fBaseAddress = fOptions.zeroPageSize();
}
for (unsigned int i=firstLinkEditSectionIndex; i < linkEditSectionCount; ++i) {
std::vector<class ObjectFile::Atom*>& atoms = lastSeg->fSections[i]->fAtoms;
// adjust section address based on alignment
uint64_t sectionAlignment = 1 << lastSeg->fSections[i]->fAlignment;
uint64_t pad = ((address+sectionAlignment-1) & (-sectionAlignment)) - address;
address += pad;
fileOffset += pad; // adjust file offset to match address
lastSeg->fSections[i]->setBaseAddress(address);
if ( strcmp(lastSeg->fSections[i]->fSectionName, "._absolute") == 0 )
lastSeg->fSections[i]->setBaseAddress(0);
lastSeg->fSections[i]->fFileOffset = fileOffset;
uint64_t sectionOffset = 0;
for (unsigned int j=0; j < atoms.size(); ++j) {
ObjectFile::Atom* atom = atoms[j];
uint64_t alignment = 1 << atom->getAlignment().powerOf2;
sectionOffset = ( (sectionOffset+alignment-1) & (-alignment) );
atom->setSectionOffset(sectionOffset);
uint64_t size = atom->getSize();
sectionOffset += size;
if ( size > fLargestAtomSize )
fLargestAtomSize = size;
}
//fprintf(stderr, "setting: lastSeg->fSections[%d]->fSize = 0x%08llX\n", i, sectionOffset);
lastSeg->fSections[i]->fSize = sectionOffset;
fileOffset += sectionOffset;
address += sectionOffset;
}
if ( fOptions.outputKind() == Options::kObjectFile ) {
//lastSeg->fBaseAddress = 0;
//lastSeg->fSize = lastSeg->fSections[firstLinkEditSectionIndex]->
//lastSeg->fFileOffset = 0;
//lastSeg->fFileSize =
}
else {
lastSeg->fFileSize = fileOffset - lastSeg->fFileOffset;
lastSeg->fSize = (address - lastSeg->fBaseAddress+4095) & (-4096);
}
}
template <typename A>
ObjectFile::Atom::Scope MachHeaderAtom<A>::getScope() const
{
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kStaticExecutable:
return ObjectFile::Atom::scopeGlobal;
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kDyld:
case Options::kObjectFile:
case Options::kPreload:
case Options::kKextBundle:
return ObjectFile::Atom::scopeLinkageUnit;
}
throw "unknown header type";
}
template <typename A>
ObjectFile::Atom::SymbolTableInclusion MachHeaderAtom<A>::getSymbolTableInclusion() const
{
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
return ObjectFile::Atom::kSymbolTableInAndNeverStrip;
case Options::kStaticExecutable:
return ObjectFile::Atom::kSymbolTableInAsAbsolute;
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kDyld:
return ObjectFile::Atom::kSymbolTableIn;
case Options::kObjectFile:
case Options::kPreload:
case Options::kKextBundle:
return ObjectFile::Atom::kSymbolTableNotIn;
}
throw "unknown header type";
}
template <typename A>
const char* MachHeaderAtom<A>::getName() const
{
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kStaticExecutable:
return "__mh_execute_header";
case Options::kDynamicLibrary:
return "__mh_dylib_header";
case Options::kDynamicBundle:
return "__mh_bundle_header";
case Options::kObjectFile:
case Options::kPreload:
case Options::kKextBundle:
return NULL;
case Options::kDyld:
return "__mh_dylinker_header";
}
throw "unknown header type";
}
template <typename A>
const char* MachHeaderAtom<A>::getDisplayName() const
{
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kStaticExecutable:
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kDyld:
return this->getName();
case Options::kObjectFile:
case Options::kPreload:
case Options::kKextBundle:
return "mach header";
}
throw "unknown header type";
}
template <typename A>
void MachHeaderAtom<A>::copyRawContent(uint8_t buffer[]) const
{
// get file type
uint32_t fileType = 0;
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kStaticExecutable:
fileType = MH_EXECUTE;
break;
case Options::kDynamicLibrary:
fileType = MH_DYLIB;
break;
case Options::kDynamicBundle:
fileType = MH_BUNDLE;
break;
case Options::kObjectFile:
fileType = MH_OBJECT;
break;
case Options::kDyld:
fileType = MH_DYLINKER;
break;
case Options::kPreload:
fileType = MH_PRELOAD;
break;
case Options::kKextBundle:
fileType = MH_KEXT_BUNDLE;
break;
}
// get flags
uint32_t flags = 0;
if ( fWriter.fOptions.outputKind() == Options::kObjectFile ) {
if ( fWriter.fCanScatter )
flags = MH_SUBSECTIONS_VIA_SYMBOLS;
}
else {
if ( fWriter.fOptions.outputKind() == Options::kStaticExecutable ) {
flags |= MH_NOUNDEFS;
}
else if ( fWriter.fOptions.outputKind() == Options::kPreload ) {
flags |= MH_NOUNDEFS;
if ( fWriter.fOptions.positionIndependentExecutable() )
flags |= MH_PIE;
}
else {
flags = MH_DYLDLINK;
if ( fWriter.fOptions.bindAtLoad() )
flags |= MH_BINDATLOAD;
switch ( fWriter.fOptions.nameSpace() ) {
case Options::kTwoLevelNameSpace:
flags |= MH_TWOLEVEL | MH_NOUNDEFS;
break;
case Options::kFlatNameSpace:
break;
case Options::kForceFlatNameSpace:
flags |= MH_FORCE_FLAT;
break;
}
bool hasWeakDefines = fWriter.fHasWeakExports;
if ( fWriter.fRegularDefAtomsThatOverrideADylibsWeakDef->size() != 0 ) {
for(std::set<const ObjectFile::Atom*>::iterator it = fWriter.fRegularDefAtomsThatOverrideADylibsWeakDef->begin();
it != fWriter.fRegularDefAtomsThatOverrideADylibsWeakDef->end(); ++it) {
if ( fWriter.shouldExport(**it) ) {
hasWeakDefines = true;
break;
}
}
}
if ( hasWeakDefines )
flags |= MH_WEAK_DEFINES;
if ( fWriter.fReferencesWeakImports || fWriter.fHasWeakExports )
flags |= MH_BINDS_TO_WEAK;
if ( fWriter.fOptions.prebind() )
flags |= MH_PREBOUND;
if ( fWriter.fOptions.splitSeg() )
flags |= MH_SPLIT_SEGS;
if ( (fWriter.fOptions.outputKind() == Options::kDynamicLibrary) && fWriter.fNoReExportedDylibs )
flags |= MH_NO_REEXPORTED_DYLIBS;
if ( fWriter.fOptions.positionIndependentExecutable() )
flags |= MH_PIE;
if ( fWriter.fOptions.markAutoDeadStripDylib() )
flags |= MH_DEAD_STRIPPABLE_DYLIB;
}
if ( fWriter.fOptions.hasExecutableStack() )
flags |= MH_ALLOW_STACK_EXECUTION;
if ( fWriter.fOptions.readerOptions().fRootSafe )
flags |= MH_ROOT_SAFE;
if ( fWriter.fOptions.readerOptions().fSetuidSafe )
flags |= MH_SETUID_SAFE;
}
// get commands info
uint32_t commandsSize = 0;
uint32_t commandsCount = 0;
std::vector<class ObjectFile::Atom*>& loadCommandAtoms = fWriter.fLoadCommandsSection->fAtoms;
for (std::vector<ObjectFile::Atom*>::iterator it=loadCommandAtoms.begin(); it != loadCommandAtoms.end(); it++) {
ObjectFile::Atom* atom = *it;
commandsSize += atom->getSize();
// segment and symbol table atoms can contain more than one load command
if ( atom == fWriter.fSegmentCommands )
commandsCount += fWriter.fSegmentCommands->commandCount();
else if ( atom == fWriter.fSymbolTableCommands )
commandsCount += fWriter.fSymbolTableCommands->commandCount();
else if ( atom->getSize() != 0 )
++commandsCount;
}
// fill out mach_header
macho_header<typename A::P>* mh = (macho_header<typename A::P>*)buffer;
setHeaderInfo(*mh);
mh->set_filetype(fileType);
mh->set_ncmds(commandsCount);
mh->set_sizeofcmds(commandsSize);
mh->set_flags(flags);
}
template <>
void MachHeaderAtom<ppc>::setHeaderInfo(macho_header<ppc::P>& header) const
{
header.set_magic(MH_MAGIC);
header.set_cputype(CPU_TYPE_POWERPC);
header.set_cpusubtype(fWriter.fCpuConstraint);
}
template <>
void MachHeaderAtom<ppc64>::setHeaderInfo(macho_header<ppc64::P>& header) const
{
header.set_magic(MH_MAGIC_64);
header.set_cputype(CPU_TYPE_POWERPC64);
if ( (fWriter.fOptions.outputKind() == Options::kDynamicExecutable) && (fWriter.fOptions.macosxVersionMin() >= ObjectFile::ReaderOptions::k10_5) )
header.set_cpusubtype(CPU_SUBTYPE_POWERPC_ALL | 0x80000000);
else
header.set_cpusubtype(CPU_SUBTYPE_POWERPC_ALL);
header.set_reserved(0);
}
template <>
void MachHeaderAtom<x86>::setHeaderInfo(macho_header<x86::P>& header) const
{
header.set_magic(MH_MAGIC);
header.set_cputype(CPU_TYPE_I386);
header.set_cpusubtype(CPU_SUBTYPE_I386_ALL);
}
template <>
void MachHeaderAtom<x86_64>::setHeaderInfo(macho_header<x86_64::P>& header) const
{
header.set_magic(MH_MAGIC_64);
header.set_cputype(CPU_TYPE_X86_64);
if ( (fWriter.fOptions.outputKind() == Options::kDynamicExecutable) && (fWriter.fOptions.macosxVersionMin() >= ObjectFile::ReaderOptions::k10_5) )
header.set_cpusubtype(CPU_SUBTYPE_X86_64_ALL | 0x80000000);
else
header.set_cpusubtype(CPU_SUBTYPE_X86_64_ALL);
header.set_reserved(0);
}
template <>
void MachHeaderAtom<arm>::setHeaderInfo(macho_header<arm::P>& header) const
{
header.set_magic(MH_MAGIC);
header.set_cputype(CPU_TYPE_ARM);
header.set_cpusubtype(fWriter.fCpuConstraint);
}
template <typename A>
CustomStackAtom<A>::CustomStackAtom(Writer<A>& writer)
: WriterAtom<A>(writer, Segment::fgStackSegment)
{
if ( stackGrowsDown() )
Segment::fgStackSegment.setBaseAddress(writer.fOptions.customStackAddr() - writer.fOptions.customStackSize());
else
Segment::fgStackSegment.setBaseAddress(writer.fOptions.customStackAddr());
}
template <> bool CustomStackAtom<ppc>::stackGrowsDown() { return true; }
template <> bool CustomStackAtom<ppc64>::stackGrowsDown() { return true; }
template <> bool CustomStackAtom<x86>::stackGrowsDown() { return true; }
template <> bool CustomStackAtom<x86_64>::stackGrowsDown() { return true; }
template <> bool CustomStackAtom<arm>::stackGrowsDown() { return true; }
template <typename A>
void SegmentLoadCommandsAtom<A>::computeSize()
{
uint64_t size = 0;
std::vector<SegmentInfo*>& segmentInfos = fWriter.fSegmentInfos;
int segCount = 0;
for(std::vector<SegmentInfo*>::iterator it = segmentInfos.begin(); it != segmentInfos.end(); ++it) {
SegmentInfo* seg = *it;
if ( seg->fHasLoadCommand ) {
++segCount;
size += sizeof(macho_segment_command<P>);
std::vector<SectionInfo*>& sectionInfos = seg->fSections;
const int sectionCount = sectionInfos.size();
for(int j=0; j < sectionCount; ++j) {
if ( fWriter.fEmitVirtualSections || ! sectionInfos[j]->fVirtualSection )
size += sizeof(macho_section<P>);
}
}
}
fSize = size;
fCommandCount = segCount;
if ( fWriter.fPadSegmentInfo != NULL ) {
++fCommandCount;
fSize += sizeof(macho_segment_command<P>);
}
}
template <>
uint64_t LoadCommandAtom<ppc>::alignedSize(uint64_t size)
{
return ((size+3) & (-4)); // 4-byte align all load commands for 32-bit mach-o
}
template <>
uint64_t LoadCommandAtom<ppc64>::alignedSize(uint64_t size)
{
return ((size+7) & (-8)); // 8-byte align all load commands for 64-bit mach-o
}
template <>
uint64_t LoadCommandAtom<x86>::alignedSize(uint64_t size)
{
return ((size+3) & (-4)); // 4-byte align all load commands for 32-bit mach-o
}
template <>
uint64_t LoadCommandAtom<x86_64>::alignedSize(uint64_t size)
{
return ((size+7) & (-8)); // 8-byte align all load commands for 64-bit mach-o
}
template <>
uint64_t LoadCommandAtom<arm>::alignedSize(uint64_t size)
{
return ((size+3) & (-4)); // 4-byte align all load commands for 32-bit mach-o
}
template <typename A>
void SegmentLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
const bool oneSegment =( fWriter.fOptions.outputKind() == Options::kObjectFile );
bzero(buffer, size);
uint8_t* p = buffer;
typename std::vector<SegmentInfo*>& segmentInfos = fWriter.fSegmentInfos;
for(std::vector<SegmentInfo*>::iterator it = segmentInfos.begin(); it != segmentInfos.end(); ++it) {
SegmentInfo* segInfo = *it;
if ( ! segInfo->fHasLoadCommand )
continue;
const int sectionCount = segInfo->fSections.size();
macho_segment_command<P>* cmd = (macho_segment_command<P>*)p;
cmd->set_cmd(macho_segment_command<P>::CMD);
cmd->set_segname(segInfo->fName);
cmd->set_vmaddr(segInfo->fBaseAddress);
cmd->set_vmsize(oneSegment ? 0 : segInfo->fSize);
cmd->set_fileoff(segInfo->fFileOffset);
cmd->set_filesize(oneSegment ? 0 : segInfo->fFileSize);
cmd->set_maxprot(segInfo->fMaxProtection);
cmd->set_initprot(segInfo->fInitProtection);
// add sections array
macho_section<P>* const sections = (macho_section<P>*)&p[sizeof(macho_segment_command<P>)];
unsigned int sectionsEmitted = 0;
for (int j=0; j < sectionCount; ++j) {
SectionInfo* sectInfo = segInfo->fSections[j];
if ( fWriter.fEmitVirtualSections || !sectInfo->fVirtualSection ) {
macho_section<P>* sect = §ions[sectionsEmitted++];
if ( oneSegment ) {
// .o file segment does not cover load commands, so recalc at first real section
if ( sectionsEmitted == 1 ) {
cmd->set_vmaddr(sectInfo->getBaseAddress());
cmd->set_fileoff(sectInfo->fFileOffset);
}
cmd->set_filesize((sectInfo->fFileOffset+sectInfo->fSize)-cmd->fileoff());
cmd->set_vmsize(sectInfo->getBaseAddress() + sectInfo->fSize);
}
sect->set_sectname(sectInfo->fSectionName);
sect->set_segname(sectInfo->fSegmentName);
sect->set_addr(sectInfo->getBaseAddress());
sect->set_size(sectInfo->fSize);
sect->set_offset(sectInfo->fFileOffset);
sect->set_align(sectInfo->fAlignment);
if ( sectInfo->fRelocCount != 0 ) {
sect->set_reloff(sectInfo->fRelocOffset * sizeof(macho_relocation_info<P>) + fWriter.fSectionRelocationsAtom->getFileOffset());
sect->set_nreloc(sectInfo->fRelocCount);
}
if ( sectInfo->fAllZeroFill ) {
sect->set_flags(S_ZEROFILL);
sect->set_offset(0);
}
else if ( sectInfo->fAllLazyPointers ) {
sect->set_flags(S_LAZY_SYMBOL_POINTERS);
sect->set_reserved1(sectInfo->fIndirectSymbolOffset);
}
else if ( sectInfo->fAllLazyDylibPointers ) {
sect->set_flags(S_LAZY_DYLIB_SYMBOL_POINTERS);
sect->set_reserved1(sectInfo->fIndirectSymbolOffset);
}
else if ( sectInfo->fAllNonLazyPointers ) {
sect->set_flags(S_NON_LAZY_SYMBOL_POINTERS);
sect->set_reserved1(sectInfo->fIndirectSymbolOffset);
}
else if ( sectInfo->fAllStubs ) {
sect->set_flags(S_SYMBOL_STUBS | S_ATTR_SOME_INSTRUCTIONS | S_ATTR_PURE_INSTRUCTIONS);
sect->set_reserved1(sectInfo->fIndirectSymbolOffset);
sect->set_reserved2(sectInfo->fSize / sectInfo->fAtoms.size());
if ( sectInfo->fHasTextLocalRelocs )
sect->set_flags(sect->flags() | S_ATTR_LOC_RELOC);
}
else if ( sectInfo->fAllSelfModifyingStubs ) {
sect->set_flags(S_SYMBOL_STUBS | S_ATTR_SELF_MODIFYING_CODE);
sect->set_reserved1(sectInfo->fIndirectSymbolOffset);
sect->set_reserved2(sectInfo->fSize / sectInfo->fAtoms.size());
}
else if ( sectInfo->fAllStubHelpers ) {
sect->set_flags(S_ATTR_SOME_INSTRUCTIONS | S_ATTR_PURE_INSTRUCTIONS);
if ( sectInfo->fHasTextLocalRelocs )
sect->set_flags(sect->flags() | S_ATTR_LOC_RELOC);
}
else if ( sectInfo->fAtoms.at(0)->getContentType() == ObjectFile::Atom::kCStringType ) {
sect->set_flags(S_CSTRING_LITERALS);
}
else if ( sectInfo->fAtoms.at(0)->getContentType() == ObjectFile::Atom::kCFIType ) {
sect->set_flags(S_COALESCED | S_ATTR_NO_TOC | S_ATTR_STRIP_STATIC_SYMS);
}
else if ( (strcmp(sectInfo->fSectionName, "__mod_init_func") == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_MOD_INIT_FUNC_POINTERS);
}
else if ( (strcmp(sectInfo->fSectionName, "__mod_term_func") == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_MOD_TERM_FUNC_POINTERS);
}
else if ( (strcmp(sectInfo->fSectionName, "__textcoal_nt") == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_COALESCED);
}
else if ( (strcmp(sectInfo->fSectionName, "__const_coal") == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_COALESCED);
}
else if ( (strcmp(sectInfo->fSectionName, "__interpose") == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_INTERPOSING);
}
else if ( (strcmp(sectInfo->fSectionName, "__literal4") == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_4BYTE_LITERALS);
}
else if ( (strcmp(sectInfo->fSectionName, "__literal8") == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_8BYTE_LITERALS);
}
else if ( (strcmp(sectInfo->fSectionName, "__literal16") == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_16BYTE_LITERALS);
}
else if ( (strcmp(sectInfo->fSectionName, "__message_refs") == 0) && (strcmp(sectInfo->fSegmentName, "__OBJC") == 0) ) {
sect->set_flags(S_LITERAL_POINTERS);
}
else if ( (strcmp(sectInfo->fSectionName, "__objc_selrefs") == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_LITERAL_POINTERS);
}
else if ( (strcmp(sectInfo->fSectionName, "__cls_refs") == 0) && (strcmp(sectInfo->fSegmentName, "__OBJC") == 0) ) {
sect->set_flags(S_LITERAL_POINTERS);
}
else if ( (strncmp(sectInfo->fSectionName, "__dof_", 6) == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_DTRACE_DOF);
}
else if ( (strncmp(sectInfo->fSectionName, "__dof_", 6) == 0) && (strcmp(sectInfo->fSegmentName, "__DATA") == 0) ) {
sect->set_flags(S_DTRACE_DOF);
}
else if ( (strncmp(sectInfo->fSectionName, "__text", 6) == 0) && (strcmp(sectInfo->fSegmentName, "__TEXT") == 0) ) {
sect->set_flags(S_REGULAR | S_ATTR_SOME_INSTRUCTIONS | S_ATTR_PURE_INSTRUCTIONS);
if ( sectInfo->fHasTextLocalRelocs )
sect->set_flags(sect->flags() | S_ATTR_LOC_RELOC);
if ( sectInfo->fHasTextExternalRelocs )
sect->set_flags(sect->flags() | S_ATTR_EXT_RELOC);
}
//fprintf(stderr, "section %s flags=0x%08X\n", sectInfo->fSectionName, sect->flags());
}
}
p = &p[sizeof(macho_segment_command<P>) + sectionsEmitted*sizeof(macho_section<P>)];
cmd->set_cmdsize(sizeof(macho_segment_command<P>) + sectionsEmitted*sizeof(macho_section<P>));
cmd->set_nsects(sectionsEmitted);
}
}
template <typename A>
SymbolTableLoadCommandsAtom<A>::SymbolTableLoadCommandsAtom(Writer<A>& writer)
: LoadCommandAtom<A>(writer), fNeedsDynamicSymbolTable(false)
{
bzero(&fSymbolTable, sizeof(macho_symtab_command<P>));
bzero(&fDynamicSymbolTable, sizeof(macho_dysymtab_command<P>));
switch ( fWriter.fOptions.outputKind() ) {
case Options::kDynamicExecutable:
case Options::kDynamicLibrary:
case Options::kDynamicBundle:
case Options::kDyld:
case Options::kKextBundle:
fNeedsDynamicSymbolTable = true;
break;
case Options::kObjectFile:
case Options::kStaticExecutable:
fNeedsDynamicSymbolTable = false;
case Options::kPreload:
fNeedsDynamicSymbolTable = fWriter.fOptions.positionIndependentExecutable();
break;
}
writer.fSymbolTableCommands = this;
}
template <typename A>
void SymbolTableLoadCommandsAtom<A>::needDynamicTable()
{
fNeedsDynamicSymbolTable = true;
}
template <typename A>
uint64_t SymbolTableLoadCommandsAtom<A>::getSize() const
{
if ( fNeedsDynamicSymbolTable )
return this->alignedSize(sizeof(macho_symtab_command<P>) + sizeof(macho_dysymtab_command<P>));
else
return this->alignedSize(sizeof(macho_symtab_command<P>));
}
template <typename A>
void SymbolTableLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
// build LC_SYMTAB command
macho_symtab_command<P>* symbolTableCmd = (macho_symtab_command<P>*)buffer;
bzero(symbolTableCmd, sizeof(macho_symtab_command<P>));
symbolTableCmd->set_cmd(LC_SYMTAB);
symbolTableCmd->set_cmdsize(sizeof(macho_symtab_command<P>));
symbolTableCmd->set_nsyms(fWriter.fSymbolTableCount);
symbolTableCmd->set_symoff(fWriter.fSymbolTableCount == 0 ? 0 : fWriter.fSymbolTableAtom->getFileOffset());
symbolTableCmd->set_stroff(fWriter.fStringsAtom->getSize() == 0 ? 0 : fWriter.fStringsAtom->getFileOffset());
symbolTableCmd->set_strsize(fWriter.fStringsAtom->getSize());
// build LC_DYSYMTAB command
if ( fNeedsDynamicSymbolTable ) {
macho_dysymtab_command<P>* dynamicSymbolTableCmd = (macho_dysymtab_command<P>*)&buffer[sizeof(macho_symtab_command<P>)];
bzero(dynamicSymbolTableCmd, sizeof(macho_dysymtab_command<P>));
dynamicSymbolTableCmd->set_cmd(LC_DYSYMTAB);
dynamicSymbolTableCmd->set_cmdsize(sizeof(macho_dysymtab_command<P>));
dynamicSymbolTableCmd->set_ilocalsym(fWriter.fSymbolTableStabsStartIndex);
dynamicSymbolTableCmd->set_nlocalsym(fWriter.fSymbolTableStabsCount + fWriter.fSymbolTableLocalCount);
dynamicSymbolTableCmd->set_iextdefsym(fWriter.fSymbolTableExportStartIndex);
dynamicSymbolTableCmd->set_nextdefsym(fWriter.fSymbolTableExportCount);
dynamicSymbolTableCmd->set_iundefsym(fWriter.fSymbolTableImportStartIndex);
dynamicSymbolTableCmd->set_nundefsym(fWriter.fSymbolTableImportCount);
if ( fWriter.fModuleInfoAtom != NULL ) {
dynamicSymbolTableCmd->set_tocoff(fWriter.fModuleInfoAtom->getTableOfContentsFileOffset());
dynamicSymbolTableCmd->set_ntoc(fWriter.fSymbolTableExportCount);
dynamicSymbolTableCmd->set_modtaboff(fWriter.fModuleInfoAtom->getModuleTableFileOffset());
dynamicSymbolTableCmd->set_nmodtab(1);
dynamicSymbolTableCmd->set_extrefsymoff(fWriter.fModuleInfoAtom->getReferencesFileOffset());
dynamicSymbolTableCmd->set_nextrefsyms(fWriter.fModuleInfoAtom->getReferencesCount());
}
dynamicSymbolTableCmd->set_indirectsymoff((fWriter.fIndirectTableAtom == NULL) ? 0 : fWriter.fIndirectTableAtom->getFileOffset());
dynamicSymbolTableCmd->set_nindirectsyms((fWriter.fIndirectTableAtom == NULL) ? 0 : fWriter.fIndirectTableAtom->fTable.size());
if ( fWriter.fOptions.outputKind() != Options::kObjectFile ) {
if ( fWriter.fExternalRelocationsAtom != 0 ) {
dynamicSymbolTableCmd->set_extreloff((fWriter.fExternalRelocs.size()==0) ? 0 : fWriter.fExternalRelocationsAtom->getFileOffset());
dynamicSymbolTableCmd->set_nextrel(fWriter.fExternalRelocs.size());
}
if ( fWriter.fLocalRelocationsAtom != 0 ) {
dynamicSymbolTableCmd->set_locreloff((fWriter.fInternalRelocs.size()==0) ? 0 : fWriter.fLocalRelocationsAtom->getFileOffset());
dynamicSymbolTableCmd->set_nlocrel(fWriter.fInternalRelocs.size());
}
}
}
}
template <typename A>
unsigned int SymbolTableLoadCommandsAtom<A>::commandCount()
{
return fNeedsDynamicSymbolTable ? 2 : 1;
}
template <typename A>
uint64_t DyldLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_dylinker_command<P>) + strlen("/usr/lib/dyld") + 1);
}
template <typename A>
void DyldLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_dylinker_command<P>* cmd = (macho_dylinker_command<P>*)buffer;
if ( fWriter.fOptions.outputKind() == Options::kDyld )
cmd->set_cmd(LC_ID_DYLINKER);
else
cmd->set_cmd(LC_LOAD_DYLINKER);
cmd->set_cmdsize(this->getSize());
cmd->set_name_offset();
strcpy((char*)&buffer[sizeof(macho_dylinker_command<P>)], "/usr/lib/dyld");
}
template <typename A>
uint64_t AllowableClientLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_sub_client_command<P>) + strlen(this->clientString) + 1);
}
template <typename A>
void AllowableClientLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_sub_client_command<P>* cmd = (macho_sub_client_command<P>*)buffer;
cmd->set_cmd(LC_SUB_CLIENT);
cmd->set_cmdsize(size);
cmd->set_client_offset();
strcpy((char*)&buffer[sizeof(macho_sub_client_command<P>)], this->clientString);
}
template <typename A>
uint64_t DylibLoadCommandsAtom<A>::getSize() const
{
if ( fOptimizedAway ) {
return 0;
}
else {
const char* path = fInfo.reader->getInstallPath();
return this->alignedSize(sizeof(macho_dylib_command<P>) + strlen(path) + 1);
}
}
template <typename A>
void DylibLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
if ( fOptimizedAway )
return;
uint64_t size = this->getSize();
bzero(buffer, size);
const char* path = fInfo.reader->getInstallPath();
macho_dylib_command<P>* cmd = (macho_dylib_command<P>*)buffer;
// <rdar://problem/5529626> If only weak_import symbols are used, linker should use LD_LOAD_WEAK_DYLIB
bool autoWeakLoadDylib = ( (fWriter.fDylibReadersWithWeakImports.count(fInfo.reader) > 0)
&& (fWriter.fDylibReadersWithNonWeakImports.count(fInfo.reader) == 0) );
if ( fInfo.options.fLazyLoad )
cmd->set_cmd(LC_LAZY_LOAD_DYLIB);
else if ( fInfo.options.fWeakImport || autoWeakLoadDylib )
cmd->set_cmd(LC_LOAD_WEAK_DYLIB);
else if ( fInfo.options.fReExport && fWriter.fOptions.useSimplifiedDylibReExports() )
cmd->set_cmd(LC_REEXPORT_DYLIB);
else
cmd->set_cmd(LC_LOAD_DYLIB);
cmd->set_cmdsize(this->getSize());
cmd->set_timestamp(2); // needs to be some constant value that is different than DylibIDLoadCommandsAtom uses
cmd->set_current_version(fInfo.reader->getCurrentVersion());
cmd->set_compatibility_version(fInfo.reader->getCompatibilityVersion());
cmd->set_name_offset();
strcpy((char*)&buffer[sizeof(macho_dylib_command<P>)], path);
}
template <typename A>
uint64_t DylibIDLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_dylib_command<P>) + strlen(fWriter.fOptions.installPath()) + 1);
}
template <typename A>
void DylibIDLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_dylib_command<P>* cmd = (macho_dylib_command<P>*)buffer;
cmd->set_cmd(LC_ID_DYLIB);
cmd->set_cmdsize(this->getSize());
cmd->set_name_offset();
cmd->set_timestamp(1); // needs to be some constant value that is different than DylibLoadCommandsAtom uses
cmd->set_current_version(fWriter.fOptions.currentVersion());
cmd->set_compatibility_version(fWriter.fOptions.compatibilityVersion());
strcpy((char*)&buffer[sizeof(macho_dylib_command<P>)], fWriter.fOptions.installPath());
}
template <typename A>
void RoutinesLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t initAddr = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
if (fWriter.fEntryPoint->isThumb())
initAddr |= 1ULL;
bzero(buffer, sizeof(macho_routines_command<P>));
macho_routines_command<P>* cmd = (macho_routines_command<P>*)buffer;
cmd->set_cmd(macho_routines_command<P>::CMD);
cmd->set_cmdsize(this->getSize());
cmd->set_init_address(initAddr);
}
template <typename A>
uint64_t SubUmbrellaLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_sub_umbrella_command<P>) + strlen(fName) + 1);
}
template <typename A>
void SubUmbrellaLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_sub_umbrella_command<P>* cmd = (macho_sub_umbrella_command<P>*)buffer;
cmd->set_cmd(LC_SUB_UMBRELLA);
cmd->set_cmdsize(this->getSize());
cmd->set_sub_umbrella_offset();
strcpy((char*)&buffer[sizeof(macho_sub_umbrella_command<P>)], fName);
}
template <typename A>
void UUIDLoadCommandAtom<A>::generate()
{
switch ( fWriter.fOptions.getUUIDMode() ) {
case Options::kUUIDNone:
fEmit = false;
break;
case Options::kUUIDRandom:
::uuid_generate_random(fUUID);
fEmit = true;
break;
case Options::kUUIDContent:
bzero(fUUID, 16);
fEmit = true;
break;
}
}
template <typename A>
void UUIDLoadCommandAtom<A>::setContent(const uint8_t uuid[16])
{
memcpy(fUUID, uuid, 16);
}
template <typename A>
void UUIDLoadCommandAtom<A>::copyRawContent(uint8_t buffer[]) const
{
if (fEmit) {
uint64_t size = this->getSize();
bzero(buffer, size);
macho_uuid_command<P>* cmd = (macho_uuid_command<P>*)buffer;
cmd->set_cmd(LC_UUID);
cmd->set_cmdsize(this->getSize());
cmd->set_uuid((uint8_t*)fUUID);
}
}
template <typename A>
uint64_t SubLibraryLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_sub_library_command<P>) + fNameLength + 1);
}
template <typename A>
void SubLibraryLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_sub_library_command<P>* cmd = (macho_sub_library_command<P>*)buffer;
cmd->set_cmd(LC_SUB_LIBRARY);
cmd->set_cmdsize(this->getSize());
cmd->set_sub_library_offset();
strncpy((char*)&buffer[sizeof(macho_sub_library_command<P>)], fNameStart, fNameLength);
buffer[sizeof(macho_sub_library_command<P>)+fNameLength] = '\0';
}
template <typename A>
uint64_t UmbrellaLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_sub_framework_command<P>) + strlen(fName) + 1);
}
template <typename A>
void UmbrellaLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_sub_framework_command<P>* cmd = (macho_sub_framework_command<P>*)buffer;
cmd->set_cmd(LC_SUB_FRAMEWORK);
cmd->set_cmdsize(this->getSize());
cmd->set_umbrella_offset();
strcpy((char*)&buffer[sizeof(macho_sub_framework_command<P>)], fName);
}
template <>
uint64_t ThreadsLoadCommandsAtom<ppc>::getSize() const
{
return this->alignedSize(16 + 40*4); // base size + PPC_THREAD_STATE_COUNT * 4
}
template <>
uint64_t ThreadsLoadCommandsAtom<ppc64>::getSize() const
{
return this->alignedSize(16 + 76*4); // base size + PPC_THREAD_STATE64_COUNT * 4
}
template <>
uint64_t ThreadsLoadCommandsAtom<x86>::getSize() const
{
return this->alignedSize(16 + 16*4); // base size + i386_THREAD_STATE_COUNT * 4
}
template <>
uint64_t ThreadsLoadCommandsAtom<x86_64>::getSize() const
{
return this->alignedSize(16 + x86_THREAD_STATE64_COUNT * 4);
}
// We should be picking it up from a header
template <>
uint64_t ThreadsLoadCommandsAtom<arm>::getSize() const
{
return this->alignedSize(16 + 17 * 4); // base size + ARM_THREAD_STATE_COUNT * 4
}
template <>
void ThreadsLoadCommandsAtom<ppc>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
uint64_t start = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
bzero(buffer, size);
macho_thread_command<ppc::P>* cmd = (macho_thread_command<ppc::P>*)buffer;
cmd->set_cmd(LC_UNIXTHREAD);
cmd->set_cmdsize(size);
cmd->set_flavor(1); // PPC_THREAD_STATE
cmd->set_count(40); // PPC_THREAD_STATE_COUNT;
cmd->set_thread_register(0, start);
if ( fWriter.fOptions.hasCustomStack() )
cmd->set_thread_register(3, fWriter.fOptions.customStackAddr()); // r1
}
template <>
void ThreadsLoadCommandsAtom<ppc64>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
uint64_t start = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
bzero(buffer, size);
macho_thread_command<ppc64::P>* cmd = (macho_thread_command<ppc64::P>*)buffer;
cmd->set_cmd(LC_UNIXTHREAD);
cmd->set_cmdsize(size);
cmd->set_flavor(5); // PPC_THREAD_STATE64
cmd->set_count(76); // PPC_THREAD_STATE64_COUNT;
cmd->set_thread_register(0, start);
if ( fWriter.fOptions.hasCustomStack() )
cmd->set_thread_register(3, fWriter.fOptions.customStackAddr()); // r1
}
template <>
void ThreadsLoadCommandsAtom<x86>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
uint64_t start = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
bzero(buffer, size);
macho_thread_command<x86::P>* cmd = (macho_thread_command<x86::P>*)buffer;
cmd->set_cmd(LC_UNIXTHREAD);
cmd->set_cmdsize(size);
cmd->set_flavor(1); // i386_THREAD_STATE
cmd->set_count(16); // i386_THREAD_STATE_COUNT;
cmd->set_thread_register(10, start);
if ( fWriter.fOptions.hasCustomStack() )
cmd->set_thread_register(7, fWriter.fOptions.customStackAddr()); // esp
}
template <>
void ThreadsLoadCommandsAtom<x86_64>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
uint64_t start = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
bzero(buffer, size);
macho_thread_command<x86_64::P>* cmd = (macho_thread_command<x86_64::P>*)buffer;
cmd->set_cmd(LC_UNIXTHREAD);
cmd->set_cmdsize(size);
cmd->set_flavor(x86_THREAD_STATE64);
cmd->set_count(x86_THREAD_STATE64_COUNT);
cmd->set_thread_register(16, start); // rip
if ( fWriter.fOptions.hasCustomStack() )
cmd->set_thread_register(7, fWriter.fOptions.customStackAddr()); // uesp
}
template <>
void ThreadsLoadCommandsAtom<arm>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
uint64_t start = fWriter.getAtomLoadAddress(fWriter.fEntryPoint);
if ( fWriter.fEntryPoint->isThumb() )
start |= 1ULL;
bzero(buffer, size);
macho_thread_command<arm::P>* cmd = (macho_thread_command<arm::P>*)buffer;
cmd->set_cmd(LC_UNIXTHREAD);
cmd->set_cmdsize(size);
cmd->set_flavor(1);
cmd->set_count(17);
cmd->set_thread_register(15, start); // pc
if ( fWriter.fOptions.hasCustomStack() )
cmd->set_thread_register(13, fWriter.fOptions.customStackAddr()); // FIXME: sp?
}
template <typename A>
uint64_t RPathLoadCommandsAtom<A>::getSize() const
{
return this->alignedSize(sizeof(macho_rpath_command<P>) + strlen(fPath) + 1);
}
template <typename A>
void RPathLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_rpath_command<P>* cmd = (macho_rpath_command<P>*)buffer;
cmd->set_cmd(LC_RPATH);
cmd->set_cmdsize(this->getSize());
cmd->set_path_offset();
strcpy((char*)&buffer[sizeof(macho_rpath_command<P>)], fPath);
}
template <typename A>
void EncryptionLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
macho_encryption_info_command<P>* cmd = (macho_encryption_info_command<P>*)buffer;
cmd->set_cmd(LC_ENCRYPTION_INFO);
cmd->set_cmdsize(this->getSize());
cmd->set_cryptoff(fStartOffset);
cmd->set_cryptsize(fEndOffset-fStartOffset);
cmd->set_cryptid(0);
}
template <typename A>
void LoadCommandsPaddingAtom<A>::copyRawContent(uint8_t buffer[]) const
{
bzero(buffer, fSize);
}
template <typename A>
void LoadCommandsPaddingAtom<A>::setSize(uint64_t newSize)
{
fSize = newSize;
// this resizing by-passes the way fLargestAtomSize is set, so re-check here
if ( fWriter.fLargestAtomSize < newSize )
fWriter.fLargestAtomSize = newSize;
}
template <typename A>
void UnwindInfoAtom<A>::addUnwindInfo(ObjectFile::Atom* func, uint32_t offset, uint32_t encoding,
ObjectFile::Reference* fdeRef, ObjectFile::Reference* lsdaRef,
ObjectFile::Atom* personalityPointer)
{
Info info;
info.func = func;
if ( fdeRef != NULL )
info.fde = &fdeRef->getTarget();
else
info.fde = NULL;
if ( lsdaRef != NULL ) {
info.lsda = &lsdaRef->getTarget();
info.lsdaOffset = lsdaRef->getTargetOffset();
}
else {
info.lsda = NULL;
info.lsdaOffset = 0;
}
info.personalityPointer = personalityPointer;
info.encoding = encoding;
fInfos.push_back(info);
//fprintf(stderr, "addUnwindInfo() encoding=0x%08X, lsda=%p, lsdaOffset=%d, person=%p, func=%s\n",
// encoding, info.lsda, info.lsdaOffset, personalityPointer, func->getDisplayName());
}
template <>
bool UnwindInfoAtom<x86>::encodingMeansUseDwarf(compact_unwind_encoding_t encoding)
{
return ( (encoding & UNWIND_X86_MODE_MASK) == UNWIND_X86_MODE_DWARF);
}
template <>
bool UnwindInfoAtom<x86_64>::encodingMeansUseDwarf(compact_unwind_encoding_t encoding)
{
return ( (encoding & UNWIND_X86_64_MODE_MASK) == UNWIND_X86_64_MODE_DWARF);
}
template <typename A>
bool UnwindInfoAtom<A>::encodingMeansUseDwarf(compact_unwind_encoding_t encoding)
{
return false;
}
template <typename A>
void UnwindInfoAtom<A>::compressDuplicates(std::vector<Info>& uniqueInfos)
{
// build new list removing entries where next function has same encoding
uniqueInfos.reserve(fInfos.size());
Info last;
last.func = NULL;
last.lsda = NULL;
last.lsdaOffset = 0;
last.personalityPointer = NULL;
last.encoding = 0xFFFFFFFF;
for(typename std::vector<Info>::iterator it=fInfos.begin(); it != fInfos.end(); ++it) {
Info& newInfo = *it;
bool newNeedsDwarf = encodingMeansUseDwarf(newInfo.encoding);
// remove infos which have same encoding and personalityPointer as last one
if ( newNeedsDwarf || (newInfo.encoding != last.encoding) || (newInfo.personalityPointer != last.personalityPointer)
|| (newInfo.lsda != NULL) || (last.lsda != NULL) ) {
uniqueInfos.push_back(newInfo);
}
last = newInfo;
}
//fprintf(stderr, "compressDuplicates() fInfos.size()=%lu, uniqueInfos.size()=%lu\n", fInfos.size(), uniqueInfos.size());
}
template <typename A>
void UnwindInfoAtom<A>::findCommonEncoding(const std::vector<Info>& uniqueInfos, std::map<uint32_t, unsigned int>& commonEncodings)
{
// scan infos to get frequency counts for each encoding
std::map<uint32_t, unsigned int> encodingsUsed;
unsigned int mostCommonEncodingUsageCount = 0;
for(typename std::vector<Info>::const_iterator it=uniqueInfos.begin(); it != uniqueInfos.end(); ++it) {
// never put dwarf into common table
if ( encodingMeansUseDwarf(it->encoding) )
continue;
std::map<uint32_t, unsigned int>::iterator pos = encodingsUsed.find(it->encoding);
if ( pos == encodingsUsed.end() ) {
encodingsUsed[it->encoding] = 1;
}
else {
encodingsUsed[it->encoding] += 1;
if ( mostCommonEncodingUsageCount < encodingsUsed[it->encoding] )
mostCommonEncodingUsageCount = encodingsUsed[it->encoding];
}
}
// put the most common encodings into the common table, but at most 127 of them
for(unsigned int usages=mostCommonEncodingUsageCount; usages > 1; --usages) {
for (std::map<uint32_t, unsigned int>::iterator euit=encodingsUsed.begin(); euit != encodingsUsed.end(); ++euit) {
if ( euit->second == usages ) {
unsigned int size = commonEncodings.size();
if ( size < 127 ) {
commonEncodings[euit->first] = size;
}
}
}
}
}
template <typename A>
void UnwindInfoAtom<A>::makeLsdaIndex(const std::vector<Info>& uniqueInfos, std::map<ObjectFile::Atom*, uint32_t>& lsdaIndexOffsetMap)
{
for(typename std::vector<Info>::const_iterator it=uniqueInfos.begin(); it != uniqueInfos.end(); ++it) {
lsdaIndexOffsetMap[it->func] = fLSDAIndex.size() * sizeof(macho_unwind_info_section_header_lsda_index_entry<P>);
if ( it->lsda != NULL ) {
LSDAEntry entry;
entry.func = it->func;
entry.lsda = it->lsda;
entry.lsdaOffset = it->lsdaOffset;
fLSDAIndex.push_back(entry);
}
}
}
template <typename A>
void UnwindInfoAtom<A>::makePersonalityIndex(std::vector<Info>& uniqueInfos)
{
for(typename std::vector<Info>::iterator it=uniqueInfos.begin(); it != uniqueInfos.end(); ++it) {
if ( it->personalityPointer != NULL ) {
std::map<ObjectFile::Atom*, uint32_t>::iterator pos = fPersonalityIndexMap.find(it->personalityPointer);
if ( pos == fPersonalityIndexMap.end() ) {
const uint32_t nextIndex = fPersonalityIndexMap.size() + 1;
fPersonalityIndexMap[it->personalityPointer] = nextIndex;
}
uint32_t personalityIndex = fPersonalityIndexMap[it->personalityPointer];
it->encoding |= (personalityIndex << (__builtin_ctz(UNWIND_PERSONALITY_MASK)) );
}
}
}
template <typename A>
unsigned int UnwindInfoAtom<A>::makeRegularSecondLevelPage(const std::vector<Info>& uniqueInfos, uint32_t pageSize,
unsigned int endIndex, uint8_t*& pageEnd)
{
const unsigned int maxEntriesPerPage = (pageSize - sizeof(unwind_info_regular_second_level_page_header))/sizeof(unwind_info_regular_second_level_entry);
const unsigned int entriesToAdd = ((endIndex > maxEntriesPerPage) ? maxEntriesPerPage : endIndex);
uint8_t* pageStart = pageEnd
- entriesToAdd*sizeof(unwind_info_regular_second_level_entry)
- sizeof(unwind_info_regular_second_level_page_header);
macho_unwind_info_regular_second_level_page_header<P>* page = (macho_unwind_info_regular_second_level_page_header<P>*)pageStart;
page->set_kind(UNWIND_SECOND_LEVEL_REGULAR);
page->set_entryPageOffset(sizeof(macho_unwind_info_regular_second_level_page_header<P>));
page->set_entryCount(entriesToAdd);
macho_unwind_info_regular_second_level_entry<P>* entryTable = (macho_unwind_info_regular_second_level_entry<P>*)(pageStart + page->entryPageOffset());
for (unsigned int i=0; i < entriesToAdd; ++i) {
const Info& info = uniqueInfos[endIndex-entriesToAdd+i];
entryTable[i].set_functionOffset(0);
entryTable[i].set_encoding(info.encoding);
RegFixUp fixup;
fixup.contentPointer = (uint8_t*)(&entryTable[i]);
fixup.func = info.func;
fixup.fde = ( encodingMeansUseDwarf(info.encoding) ? info.fde : NULL );
fRegFixUps.push_back(fixup);
}
//fprintf(stderr, "regular page with %u entries\n", entriesToAdd);
pageEnd = pageStart;
return endIndex - entriesToAdd;
}
template <typename A>
unsigned int UnwindInfoAtom<A>::makeCompressedSecondLevelPage(const std::vector<Info>& uniqueInfos,
const std::map<uint32_t,unsigned int> commonEncodings,
uint32_t pageSize, unsigned int endIndex, uint8_t*& pageEnd)
{
const bool log = false;
if (log) fprintf(stderr, "makeCompressedSecondLevelPage(pageSize=%u, endIndex=%u)\n", pageSize, endIndex);
// first pass calculates how many compressed entries we could fit in this sized page
// keep adding entries to page until:
// 1) encoding table plus entry table plus header exceed page size
// 2) the file offset delta from the first to last function > 24 bits
// 3) custom encoding index reachs 255
// 4) run out of uniqueInfos to encode
std::map<uint32_t, unsigned int> pageSpecificEncodings;
uint32_t space4 = (pageSize - sizeof(unwind_info_compressed_second_level_page_header))/sizeof(uint32_t);
std::vector<uint8_t> encodingIndexes;
int index = endIndex-1;
int entryCount = 0;
uint64_t lastEntryAddress = uniqueInfos[index].func->getAddress();
bool canDo = true;
while ( canDo && (index >= 0) ) {
const Info& info = uniqueInfos[index--];
// compute encoding index
unsigned int encodingIndex;
std::map<uint32_t, unsigned int>::const_iterator pos = commonEncodings.find(info.encoding);
if ( pos != commonEncodings.end() ) {
encodingIndex = pos->second;
}
else {
// no commmon entry, so add one on this page
uint32_t encoding = info.encoding;
if ( encodingMeansUseDwarf(encoding) ) {
// make unique pseudo encoding so this dwarf will gets is own encoding entry slot
encoding += (index+1);
}
std::map<uint32_t, unsigned int>::iterator ppos = pageSpecificEncodings.find(encoding);
if ( ppos != pageSpecificEncodings.end() ) {
encodingIndex = pos->second;
}
else {
encodingIndex = commonEncodings.size() + pageSpecificEncodings.size();
if ( encodingIndex <= 255 ) {
pageSpecificEncodings[encoding] = encodingIndex;
}
else {
canDo = false; // case 3)
if (log) fprintf(stderr, "end of compressed page with %u entries, %lu custom encodings because too many custom encodings\n",
entryCount, pageSpecificEncodings.size());
}
}
}
if ( canDo )
encodingIndexes.push_back(encodingIndex);
// compute function offset
uint32_t funcOffsetWithInPage = lastEntryAddress - info.func->getAddress();
if ( funcOffsetWithInPage > 0x00FFFF00 ) {
// don't use 0x00FFFFFF because addresses may vary after atoms are laid out again
canDo = false; // case 2)
if (log) fprintf(stderr, "can't use compressed page with %u entries because function offset too big\n", entryCount);
}
else {
++entryCount;
}
// check room for entry
if ( (pageSpecificEncodings.size()+entryCount) >= space4 ) {
canDo = false; // case 1)
--entryCount;
if (log) fprintf(stderr, "end of compressed page with %u entries because full\n", entryCount);
}
//if (log) fprintf(stderr, "space4=%d, pageSpecificEncodings.size()=%ld, entryCount=%d\n", space4, pageSpecificEncodings.size(), entryCount);
}
// check for cases where it would be better to use a regular (non-compressed) page
const unsigned int compressPageUsed = sizeof(unwind_info_compressed_second_level_page_header)
+ pageSpecificEncodings.size()*sizeof(uint32_t)
+ entryCount*sizeof(uint32_t);
if ( (compressPageUsed < (pageSize-4) && (index >= 0) ) ) {
const int regularEntriesPerPage = (pageSize - sizeof(unwind_info_regular_second_level_page_header))/sizeof(unwind_info_regular_second_level_entry);
if ( entryCount < regularEntriesPerPage ) {
return makeRegularSecondLevelPage(uniqueInfos, pageSize, endIndex, pageEnd);
}
}
// check if we need any padding because adding another entry would take 8 bytes but only have room for 4
uint32_t pad = 0;
if ( compressPageUsed == (pageSize-4) )
pad = 4;
// second pass fills in page
uint8_t* pageStart = pageEnd - compressPageUsed - pad;
macho_unwind_info_compressed_second_level_page_header<P>* page = (macho_unwind_info_compressed_second_level_page_header<P>*)pageStart;
page->set_kind(UNWIND_SECOND_LEVEL_COMPRESSED);
page->set_entryPageOffset(sizeof(macho_unwind_info_compressed_second_level_page_header<P>));
page->set_entryCount(entryCount);
page->set_encodingsPageOffset(page->entryPageOffset()+entryCount*sizeof(uint32_t));
page->set_encodingsCount(pageSpecificEncodings.size());
uint32_t* const encodingsArray = (uint32_t*)&pageStart[page->encodingsPageOffset()];
// fill in entry table
uint32_t* const entiresArray = (uint32_t*)&pageStart[page->entryPageOffset()];
ObjectFile::Atom* firstFunc = uniqueInfos[endIndex-entryCount].func;
for(unsigned int i=endIndex-entryCount; i < endIndex; ++i) {
const Info& info = uniqueInfos[i];
uint8_t encodingIndex;
if ( encodingMeansUseDwarf(info.encoding) ) {
// dwarf entries are always in page specific encodings
encodingIndex = pageSpecificEncodings[info.encoding+i];
}
else {
std::map<uint32_t, unsigned int>::const_iterator pos = commonEncodings.find(info.encoding);
if ( pos != commonEncodings.end() )
encodingIndex = pos->second;
else
encodingIndex = pageSpecificEncodings[info.encoding];
}
uint32_t entryIndex = i - endIndex + entryCount;
A::P::E::set32(entiresArray[entryIndex], encodingIndex << 24);
CompressedFixUp funcStartFixUp;
funcStartFixUp.contentPointer = (uint8_t*)(&entiresArray[entryIndex]);
funcStartFixUp.func = info.func;
funcStartFixUp.fromFunc = firstFunc;
fCompressedFixUps.push_back(funcStartFixUp);
if ( encodingMeansUseDwarf(info.encoding) ) {
CompressedEncodingFixUp dwarfStartFixup;
dwarfStartFixup.contentPointer = (uint8_t*)(&encodingsArray[encodingIndex-commonEncodings.size()]);
dwarfStartFixup.fde = info.fde;
fCompressedEncodingFixUps.push_back(dwarfStartFixup);
}
}
// fill in encodings table
for(std::map<uint32_t, unsigned int>::const_iterator it = pageSpecificEncodings.begin(); it != pageSpecificEncodings.end(); ++it) {
A::P::E::set32(encodingsArray[it->second-commonEncodings.size()], it->first);
}
if (log) fprintf(stderr, "compressed page with %u entries, %lu custom encodings\n", entryCount, pageSpecificEncodings.size());
// update pageEnd;
pageEnd = pageStart;
return endIndex-entryCount; // endIndex for next page
}
template <> void UnwindInfoAtom<ppc>::generate() { }
template <> void UnwindInfoAtom<ppc64>::generate() { }
template <> void UnwindInfoAtom<arm>::generate() { }
template <typename A>
void UnwindInfoAtom<A>::generate()
{
// only generate table if there are functions with unwind info
if ( fInfos.size() > 0 ) {
// find offset of end of __unwind_info section
SectionInfo* unwindSectionInfo = (SectionInfo*)this->getSection();
// build new list that has proper offsetInImage and remove entries where next function has same encoding
std::vector<Info> uniqueInfos;
this->compressDuplicates(uniqueInfos);
// build personality index, update encodings with personality index
this->makePersonalityIndex(uniqueInfos);
if ( fPersonalityIndexMap.size() > 3 )
throw "too many personality routines for compact unwind to encode";
// put the most common encodings into the common table, but at most 127 of them
std::map<uint32_t, unsigned int> commonEncodings;
this->findCommonEncoding(uniqueInfos, commonEncodings);
// build lsda index
std::map<ObjectFile::Atom*, uint32_t> lsdaIndexOffsetMap;
this->makeLsdaIndex(uniqueInfos, lsdaIndexOffsetMap);
// calculate worst case size for all unwind info pages when allocating buffer
const unsigned int entriesPerRegularPage = (4096-sizeof(unwind_info_regular_second_level_page_header))/sizeof(unwind_info_regular_second_level_entry);
const unsigned int pageCount = ((uniqueInfos.size() - 1)/entriesPerRegularPage) + 1;
fPagesContentForDelete = (uint8_t*)calloc(pageCount,4096);
fPagesSize = 0;
if ( fPagesContentForDelete == NULL )
throw "could not allocate space for compact unwind info";
ObjectFile::Atom* secondLevelFirstFuncs[pageCount*3];
uint8_t* secondLevelPagesStarts[pageCount*3];
// make last second level page smaller so that all other second level pages can be page aligned
uint32_t maxLastPageSize = unwindSectionInfo->fFileOffset % 4096;
uint32_t tailPad = 0;
if ( maxLastPageSize < 128 ) {
tailPad = maxLastPageSize;
maxLastPageSize = 4096;
}
// fill in pages in reverse order
unsigned int endIndex = uniqueInfos.size();
unsigned int secondLevelPageCount = 0;
uint8_t* pageEnd = &fPagesContentForDelete[pageCount*4096];
uint32_t pageSize = maxLastPageSize;
while ( endIndex > 0 ) {
endIndex = makeCompressedSecondLevelPage(uniqueInfos, commonEncodings, pageSize, endIndex, pageEnd);
secondLevelPagesStarts[secondLevelPageCount] = pageEnd;
secondLevelFirstFuncs[secondLevelPageCount] = uniqueInfos[endIndex].func;
++secondLevelPageCount;
pageSize = 4096; // last page can be odd size, make rest up to 4096 bytes in size
}
fPagesContent = pageEnd;
fPagesSize = &fPagesContentForDelete[pageCount*4096] - pageEnd;
// calculate section layout
const uint32_t commonEncodingsArraySectionOffset = sizeof(macho_unwind_info_section_header<P>);
const uint32_t commonEncodingsArrayCount = commonEncodings.size();
const uint32_t commonEncodingsArraySize = commonEncodingsArrayCount * sizeof(compact_unwind_encoding_t);
const uint32_t personalityArraySectionOffset = commonEncodingsArraySectionOffset + commonEncodingsArraySize;
const uint32_t personalityArrayCount = fPersonalityIndexMap.size();
const uint32_t personalityArraySize = personalityArrayCount * sizeof(uint32_t);
const uint32_t indexSectionOffset = personalityArraySectionOffset + personalityArraySize;
const uint32_t indexCount = secondLevelPageCount+1;
const uint32_t indexSize = indexCount * sizeof(macho_unwind_info_section_header_index_entry<P>);
const uint32_t lsdaIndexArraySectionOffset = indexSectionOffset + indexSize;
const uint32_t lsdaIndexArrayCount = fLSDAIndex.size();
const uint32_t lsdaIndexArraySize = lsdaIndexArrayCount * sizeof(macho_unwind_info_section_header_lsda_index_entry<P>);
const uint32_t headerEndSectionOffset = lsdaIndexArraySectionOffset + lsdaIndexArraySize;
// allocate and fill in section header
fHeaderSize = headerEndSectionOffset;
fHeaderContent = new uint8_t[fHeaderSize];
bzero(fHeaderContent, fHeaderSize);
macho_unwind_info_section_header<P>* sectionHeader = (macho_unwind_info_section_header<P>*)fHeaderContent;
sectionHeader->set_version(UNWIND_SECTION_VERSION);
sectionHeader->set_commonEncodingsArraySectionOffset(commonEncodingsArraySectionOffset);
sectionHeader->set_commonEncodingsArrayCount(commonEncodingsArrayCount);
sectionHeader->set_personalityArraySectionOffset(personalityArraySectionOffset);
sectionHeader->set_personalityArrayCount(personalityArrayCount);
sectionHeader->set_indexSectionOffset(indexSectionOffset);
sectionHeader->set_indexCount(indexCount);
// copy common encodings
uint32_t* commonEncodingsTable = (uint32_t*)&fHeaderContent[commonEncodingsArraySectionOffset];
for (std::map<uint32_t, unsigned int>::iterator it=commonEncodings.begin(); it != commonEncodings.end(); ++it)
A::P::E::set32(commonEncodingsTable[it->second], it->first);
// make references for personality entries
uint32_t* personalityArray = (uint32_t*)&fHeaderContent[sectionHeader->personalityArraySectionOffset()];
for (std::map<ObjectFile::Atom*, unsigned int>::iterator it=fPersonalityIndexMap.begin(); it != fPersonalityIndexMap.end(); ++it) {
uint32_t offset = (uint8_t*)&personalityArray[it->second-1] - fHeaderContent;
fReferences.push_back(new WriterReference<A>(offset, A::kImageOffset32, it->first));
}
// build first level index and references
macho_unwind_info_section_header_index_entry<P>* indexTable = (macho_unwind_info_section_header_index_entry<P>*)&fHeaderContent[indexSectionOffset];
for (unsigned int i=0; i < secondLevelPageCount; ++i) {
unsigned int reverseIndex = secondLevelPageCount - 1 - i;
indexTable[i].set_functionOffset(0);
indexTable[i].set_secondLevelPagesSectionOffset(secondLevelPagesStarts[reverseIndex]-fPagesContent+headerEndSectionOffset);
indexTable[i].set_lsdaIndexArraySectionOffset(lsdaIndexOffsetMap[secondLevelFirstFuncs[reverseIndex]]+lsdaIndexArraySectionOffset);
uint32_t refOffset = (uint8_t*)&indexTable[i] - fHeaderContent;
fReferences.push_back(new WriterReference<A>(refOffset, A::kImageOffset32, secondLevelFirstFuncs[reverseIndex]));
}
indexTable[secondLevelPageCount].set_functionOffset(0);
indexTable[secondLevelPageCount].set_secondLevelPagesSectionOffset(0);
indexTable[secondLevelPageCount].set_lsdaIndexArraySectionOffset(lsdaIndexArraySectionOffset+lsdaIndexArraySize);
fReferences.push_back(new WriterReference<A>((uint8_t*)&indexTable[secondLevelPageCount] - fHeaderContent, A::kImageOffset32,
fInfos.back().func, fInfos.back().func->getSize()+1));
// build lsda references
uint32_t lsdaEntrySectionOffset = lsdaIndexArraySectionOffset;
for (typename std::vector<LSDAEntry>::iterator it = fLSDAIndex.begin(); it != fLSDAIndex.end(); ++it) {
fReferences.push_back(new WriterReference<A>(lsdaEntrySectionOffset, A::kImageOffset32, it->func));
fReferences.push_back(new WriterReference<A>(lsdaEntrySectionOffset+4, A::kImageOffset32, it->lsda, it->lsdaOffset));
lsdaEntrySectionOffset += sizeof(unwind_info_section_header_lsda_index_entry);
}
// make references for regular second level entries
for (typename std::vector<RegFixUp>::iterator it = fRegFixUps.begin(); it != fRegFixUps.end(); ++it) {
uint32_t offset = (it->contentPointer - fPagesContent) + fHeaderSize;
fReferences.push_back(new WriterReference<A>(offset, A::kImageOffset32, it->func));
if ( it->fde != NULL )
fReferences.push_back(new WriterReference<A>(offset+4, A::kSectionOffset24, it->fde));
}
// make references for compressed second level entries
for (typename std::vector<CompressedFixUp>::iterator it = fCompressedFixUps.begin(); it != fCompressedFixUps.end(); ++it) {
uint32_t offset = (it->contentPointer - fPagesContent) + fHeaderSize;
fReferences.push_back(new WriterReference<A>(offset, A::kPointerDiff24, it->func, 0, it->fromFunc, 0));
}
for (typename std::vector<CompressedEncodingFixUp>::iterator it = fCompressedEncodingFixUps.begin(); it != fCompressedEncodingFixUps.end(); ++it) {
uint32_t offset = (it->contentPointer - fPagesContent) + fHeaderSize;
fReferences.push_back(new WriterReference<A>(offset, A::kSectionOffset24, it->fde));
}
// update section record with new size
unwindSectionInfo->fSize = this->getSize();
// alter alignment so this section lays out so second level tables are page aligned
if ( secondLevelPageCount > 2 )
fAlignment = ObjectFile::Alignment(12, (unwindSectionInfo->fFileOffset - this->getSize()) % 4096);
}
}
template <typename A>
void UnwindInfoAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, fHeaderContent, fHeaderSize);
memcpy(&buffer[fHeaderSize], fPagesContent, fPagesSize);
}
template <typename A>
uint64_t LinkEditAtom<A>::getFileOffset() const
{
return ((SectionInfo*)this->getSection())->fFileOffset + this->getSectionOffset();
}
template <typename A>
uint64_t SectionRelocationsLinkEditAtom<A>::getSize() const
{
return fWriter.fSectionRelocs.size() * sizeof(macho_relocation_info<P>);
}
template <typename A>
void SectionRelocationsLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, &fWriter.fSectionRelocs[0], this->getSize());
}
template <typename A>
uint64_t LocalRelocationsLinkEditAtom<A>::getSize() const
{
return fWriter.fInternalRelocs.size() * sizeof(macho_relocation_info<P>);
}
template <typename A>
void LocalRelocationsLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, &fWriter.fInternalRelocs[0], this->getSize());
}
template <typename A>
uint64_t SymbolTableLinkEditAtom<A>::getSize() const
{
return fWriter.fSymbolTableCount * sizeof(macho_nlist<P>);
}
template <typename A>
void SymbolTableLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, fWriter.fSymbolTable, this->getSize());
}
template <typename A>
uint64_t ExternalRelocationsLinkEditAtom<A>::getSize() const
{
return fWriter.fExternalRelocs.size() * sizeof(macho_relocation_info<P>);
}
template <typename A>
void ExternalRelocationsLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
std::sort(fWriter.fExternalRelocs.begin(), fWriter.fExternalRelocs.end(), ExternalRelocSorter<P>());
memcpy(buffer, &fWriter.fExternalRelocs[0], this->getSize());
}
template <typename A>
uint64_t IndirectTableLinkEditAtom<A>::getSize() const
{
return fTable.size() * sizeof(uint32_t);
}
template <typename A>
void IndirectTableLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
const uint32_t indirectTableSize = fTable.size();
uint32_t* indirectTable = (uint32_t*)buffer;
for(std::vector<IndirectEntry>::const_iterator it = fTable.begin(); it != fTable.end(); ++it) {
if ( it->indirectIndex < indirectTableSize )
A::P::E::set32(indirectTable[it->indirectIndex], it->symbolIndex);
else
throwf("malformed indirect table. size=%d, index=%d", indirectTableSize, it->indirectIndex);
}
}
template <typename A>
uint64_t ModuleInfoLinkEditAtom<A>::getSize() const
{
return fWriter.fSymbolTableExportCount*sizeof(macho_dylib_table_of_contents<P>)
+ sizeof(macho_dylib_module<P>)
+ this->getReferencesCount()*sizeof(uint32_t);
}
template <typename A>
uint32_t ModuleInfoLinkEditAtom<A>::getTableOfContentsFileOffset() const
{
return this->getFileOffset();
}
template <typename A>
uint32_t ModuleInfoLinkEditAtom<A>::getModuleTableFileOffset() const
{
return this->getFileOffset() + fWriter.fSymbolTableExportCount*sizeof(macho_dylib_table_of_contents<P>);
}
template <typename A>
uint32_t ModuleInfoLinkEditAtom<A>::getReferencesFileOffset() const
{
return this->getModuleTableFileOffset() + sizeof(macho_dylib_module<P>);
}
template <typename A>
uint32_t ModuleInfoLinkEditAtom<A>::getReferencesCount() const
{
return fWriter.fSymbolTableExportCount + fWriter.fSymbolTableImportCount;
}
template <typename A>
void ModuleInfoLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
bzero(buffer, size);
// create toc. The symbols are already sorted, they are all in the smae module
macho_dylib_table_of_contents<P>* p = (macho_dylib_table_of_contents<P>*)buffer;
for(uint32_t i=0; i < fWriter.fSymbolTableExportCount; ++i, ++p) {
p->set_symbol_index(fWriter.fSymbolTableExportStartIndex+i);
p->set_module_index(0);
}
// create module table (one entry)
pint_t objcModuleSectionStart = 0;
pint_t objcModuleSectionSize = 0;
uint16_t numInits = 0;
uint16_t numTerms = 0;
std::vector<SegmentInfo*>& segmentInfos = fWriter.fSegmentInfos;
for (std::vector<SegmentInfo*>::iterator segit = segmentInfos.begin(); segit != segmentInfos.end(); ++segit) {
std::vector<SectionInfo*>& sectionInfos = (*segit)->fSections;
if ( strcmp((*segit)->fName, "__DATA") == 0 ) {
for (std::vector<SectionInfo*>::iterator sectit = sectionInfos.begin(); sectit != sectionInfos.end(); ++sectit) {
if ( strcmp((*sectit)->fSectionName, "__mod_init_func") == 0 )
numInits = (*sectit)->fSize / sizeof(typename A::P::uint_t);
else if ( strcmp((*sectit)->fSectionName, "__mod_term_func") == 0 )
numTerms = (*sectit)->fSize / sizeof(typename A::P::uint_t);
}
}
else if ( strcmp((*segit)->fName, "__OBJC") == 0 ) {
for (std::vector<SectionInfo*>::iterator sectit = sectionInfos.begin(); sectit != sectionInfos.end(); ++sectit) {
SectionInfo* sectInfo = (*sectit);
if ( strcmp(sectInfo->fSectionName, "__module_info") == 0 ) {
objcModuleSectionStart = sectInfo->getBaseAddress();
objcModuleSectionSize = sectInfo->fSize;
}
}
}
}
macho_dylib_module<P>* module = (macho_dylib_module<P>*)&buffer[fWriter.fSymbolTableExportCount*sizeof(macho_dylib_table_of_contents<P>)];
module->set_module_name(fModuleNameOffset);
module->set_iextdefsym(fWriter.fSymbolTableExportStartIndex);
module->set_nextdefsym(fWriter.fSymbolTableExportCount);
module->set_irefsym(0);
module->set_nrefsym(this->getReferencesCount());
module->set_ilocalsym(fWriter.fSymbolTableStabsStartIndex);
module->set_nlocalsym(fWriter.fSymbolTableStabsCount+fWriter.fSymbolTableLocalCount);
module->set_iextrel(0);
module->set_nextrel(fWriter.fExternalRelocs.size());
module->set_iinit_iterm(0,0);
module->set_ninit_nterm(numInits,numTerms);
module->set_objc_module_info_addr(objcModuleSectionStart);
module->set_objc_module_info_size(objcModuleSectionSize);
// create reference table
macho_dylib_reference<P>* ref = (macho_dylib_reference<P>*)((uint8_t*)module + sizeof(macho_dylib_module<P>));
for(uint32_t i=0; i < fWriter.fSymbolTableExportCount; ++i, ++ref) {
ref->set_isym(fWriter.fSymbolTableExportStartIndex+i);
ref->set_flags(REFERENCE_FLAG_DEFINED);
}
for(uint32_t i=0; i < fWriter.fSymbolTableImportCount; ++i, ++ref) {
ref->set_isym(fWriter.fSymbolTableImportStartIndex+i);
std::map<const ObjectFile::Atom*,ObjectFile::Atom*>::iterator pos = fWriter.fStubsMap.find(fWriter.fImportedAtoms[i]);
if ( pos != fWriter.fStubsMap.end() )
ref->set_flags(REFERENCE_FLAG_UNDEFINED_LAZY);
else
ref->set_flags(REFERENCE_FLAG_UNDEFINED_NON_LAZY);
}
}
template <typename A>
StringsLinkEditAtom<A>::StringsLinkEditAtom(Writer<A>& writer)
: LinkEditAtom<A>(writer), fCurrentBuffer(NULL), fCurrentBufferUsed(0)
{
fCurrentBuffer = new char[kBufferSize];
// burn first byte of string pool (so zero is never a valid string offset)
fCurrentBuffer[fCurrentBufferUsed++] = ' ';
// make offset 1 always point to an empty string
fCurrentBuffer[fCurrentBufferUsed++] = '\0';
}
template <typename A>
uint64_t StringsLinkEditAtom<A>::getSize() const
{
// align size
return (kBufferSize * fFullBuffers.size() + fCurrentBufferUsed + sizeof(typename A::P::uint_t) - 1) & (-sizeof(typename A::P::uint_t));
}
template <typename A>
void StringsLinkEditAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t offset = 0;
for (unsigned int i=0; i < fFullBuffers.size(); ++i) {
memcpy(&buffer[offset], fFullBuffers[i], kBufferSize);
offset += kBufferSize;
}
memcpy(&buffer[offset], fCurrentBuffer, fCurrentBufferUsed);
// zero fill end to align
offset += fCurrentBufferUsed;
while ( (offset % sizeof(typename A::P::uint_t)) != 0 )
buffer[offset++] = 0;
}
template <typename A>
int32_t StringsLinkEditAtom<A>::add(const char* name)
{
int32_t offset = kBufferSize * fFullBuffers.size() + fCurrentBufferUsed;
int lenNeeded = strlcpy(&fCurrentBuffer[fCurrentBufferUsed], name, kBufferSize-fCurrentBufferUsed)+1;
if ( (fCurrentBufferUsed+lenNeeded) < kBufferSize ) {
fCurrentBufferUsed += lenNeeded;
}
else {
int copied = kBufferSize-fCurrentBufferUsed-1;
// change trailing '\0' that strlcpy added to real char
fCurrentBuffer[kBufferSize-1] = name[copied];
// alloc next buffer
fFullBuffers.push_back(fCurrentBuffer);
fCurrentBuffer = new char[kBufferSize];
fCurrentBufferUsed = 0;
// append rest of string
this->add(&name[copied+1]);
}
return offset;
}
template <typename A>
int32_t StringsLinkEditAtom<A>::addUnique(const char* name)
{
StringToOffset::iterator pos = fUniqueStrings.find(name);
if ( pos != fUniqueStrings.end() ) {
return pos->second;
}
else {
int32_t offset = this->add(name);
fUniqueStrings[name] = offset;
return offset;
}
}
template <typename A>
const char* StringsLinkEditAtom<A>::stringForIndex(int32_t index) const
{
int32_t currentBufferStartIndex = kBufferSize * fFullBuffers.size();
int32_t maxIndex = currentBufferStartIndex + fCurrentBufferUsed;
// check for out of bounds
if ( index > maxIndex )
return "";
// check for index in fCurrentBuffer
if ( index > currentBufferStartIndex )
return &fCurrentBuffer[index-currentBufferStartIndex];
// otherwise index is in a full buffer
uint32_t fullBufferIndex = index/kBufferSize;
return &fFullBuffers[fullBufferIndex][index-(kBufferSize*fullBufferIndex)];
}
template <typename A>
BranchIslandAtom<A>::BranchIslandAtom(Writer<A>& writer, const char* name, int islandRegion, ObjectFile::Atom& target,
ObjectFile::Atom& finalTarget, uint32_t finalTargetOffset)
: WriterAtom<A>(writer, Segment::fgTextSegment), fTarget(target), fFinalTarget(finalTarget), fFinalTargetOffset(finalTargetOffset)
{
if ( finalTargetOffset == 0 ) {
if ( islandRegion == 0 )
asprintf((char**)&fName, "%s$island", name);
else
asprintf((char**)&fName, "%s$island$%d", name, islandRegion+1);
}
else {
asprintf((char**)&fName, "%s_plus_%d$island$%d", name, finalTargetOffset, islandRegion);
}
if ( finalTarget.isThumb() ) {
if ( writer.fOptions.preferSubArchitecture() && writer.fOptions.subArchitecture() == CPU_SUBTYPE_ARM_V7 ) {
fIslandKind = kBranchIslandToThumb2;
}
else {
fIslandKind = kBranchIslandToThumb1;
}
}
else {
fIslandKind = kBranchIslandToARM;
}
}
template <>
void BranchIslandAtom<ppc>::copyRawContent(uint8_t buffer[]) const
{
int64_t displacement;
const int64_t bl_sixteenMegLimit = 0x00FFFFFF;
if ( fTarget.getContentType() == ObjectFile::Atom::kBranchIsland ) {
displacement = getFinalTargetAdress() - this->getAddress();
if ( (displacement > bl_sixteenMegLimit) && (displacement < (-bl_sixteenMegLimit)) ) {
displacement = fTarget.getAddress() - this->getAddress();
}
}
else {
displacement = fTarget.getAddress() + fFinalTargetOffset - this->getAddress();
}
int32_t branchInstruction = 0x48000000 | ((uint32_t)displacement & 0x03FFFFFC);
OSWriteBigInt32(buffer, 0, branchInstruction);
}
template <>
void BranchIslandAtom<ppc64>::copyRawContent(uint8_t buffer[]) const
{
int64_t displacement;
const int64_t bl_sixteenMegLimit = 0x00FFFFFF;
if ( fTarget.getContentType() == ObjectFile::Atom::kBranchIsland ) {
displacement = getFinalTargetAdress() - this->getAddress();
if ( (displacement > bl_sixteenMegLimit) && (displacement < (-bl_sixteenMegLimit)) ) {
displacement = fTarget.getAddress() - this->getAddress();
}
}
else {
displacement = fTarget.getAddress() + fFinalTargetOffset - this->getAddress();
}
int32_t branchInstruction = 0x48000000 | ((uint32_t)displacement & 0x03FFFFFC);
OSWriteBigInt32(buffer, 0, branchInstruction);
}
template <>
void BranchIslandAtom<arm>::copyRawContent(uint8_t buffer[]) const
{
const bool log = false;
switch ( fIslandKind ) {
case kBranchIslandToARM:
{
int64_t displacement;
// an ARM branch can branch farther than a thumb branch. The branch
// island generation was conservative and put islands every thumb
// branch distance apart. Check to see if this is a an island
// hopping branch that could be optimized to go directly to target.
if ( fTarget.getContentType() == ObjectFile::Atom::kBranchIsland ) {
displacement = getFinalTargetAdress() - this->getAddress() - 8;
if ( (displacement < 33554428LL) && (displacement > (-33554432LL)) ) {
// can skip branch island and jump straight to target
if (log) fprintf(stderr, "%s: optimized jump to final target at 0x%08llX, thisAddr=0x%08llX\n", fName, getFinalTargetAdress(), this->getAddress());
}
else {
// ultimate target is too far, jump to island
displacement = fTarget.getAddress() - this->getAddress() - 8;
if (log) fprintf(stderr, "%s: jump to branch island at 0x%08llX\n", fName, fTarget.getAddress());
}
}
else {
// target of island is ultimate target
displacement = fTarget.getAddress() + fFinalTargetOffset - this->getAddress() - 8;
if (log) fprintf(stderr, "%s: jump to target at 0x%08llX\n", fName, fTarget.getAddress());
}
uint32_t imm24 = (displacement >> 2) & 0x00FFFFFF;
int32_t branchInstruction = 0xEA000000 | imm24;
OSWriteLittleInt32(buffer, 0, branchInstruction);
}
break;
case kBranchIslandToThumb2:
{
int64_t displacement;
// an ARM branch can branch farther than a thumb branch. The branch
// island generation was conservative and put islands every thumb
// branch distance apart. Check to see if this is a an island
// hopping branch that could be optimized to go directly to target.
if ( fTarget.getContentType() == ObjectFile::Atom::kBranchIsland ) {
displacement = getFinalTargetAdress() - this->getAddress() - 4;
if ( (displacement < 16777214) && (displacement > (-16777216LL)) ) {
// can skip branch island and jump straight to target
if (log) fprintf(stderr, "%s: optimized jump to final target at 0x%08llX, thisAddr=0x%08llX\n", fName, getFinalTargetAdress(), this->getAddress());
}
else {
// ultimate target is too far, jump to island
displacement = fTarget.getAddress() - this->getAddress() - 4;
if (log) fprintf(stderr, "%s: jump to branch island at 0x%08llX\n", fName, fTarget.getAddress());
}
}
else {
// target of island is ultimate target
displacement = fTarget.getAddress() + fFinalTargetOffset - this->getAddress() - 4;
if (log) fprintf(stderr, "%s: jump to target at 0x%08llX\n", fName, fTarget.getAddress());
}
if ( (displacement > 16777214) || (displacement < (-16777216LL)) ) {
throwf("internal branch island error: thumb2 b/bx out of range (%lld max is +/-16M) from %s to %s in %s",
displacement, this->getDisplayName(),
fTarget.getDisplayName(), fTarget.getFile()->getPath());
}
// The instruction is really two instructions:
// The lower 16 bits are the first instruction, which contains the high
// 11 bits of the displacement.
// The upper 16 bits are the second instruction, which contains the low
// 11 bits of the displacement, as well as differentiating bl and blx.
uint32_t s = (uint32_t)(displacement >> 24) & 0x1;
uint32_t i1 = (uint32_t)(displacement >> 23) & 0x1;
uint32_t i2 = (uint32_t)(displacement >> 22) & 0x1;
uint32_t imm10 = (uint32_t)(displacement >> 12) & 0x3FF;
uint32_t imm11 = (uint32_t)(displacement >> 1) & 0x7FF;
uint32_t j1 = (i1 == s);
uint32_t j2 = (i2 == s);
uint32_t opcode = 0x9000F000;
uint32_t nextDisp = (j1 << 13) | (j2 << 11) | imm11;
uint32_t firstDisp = (s << 10) | imm10;
uint32_t newInstruction = opcode | (nextDisp << 16) | firstDisp;
//warning("s=%d, j1=%d, j2=%d, imm10=0x%0X, imm11=0x%0X, opcode=0x%08X, first=0x%04X, next=0x%04X, new=0x%08X, disp=0x%llX for %s to %s\n",
// s, j1, j2, imm10, imm11, opcode, firstDisp, nextDisp, newInstruction, displacement, inAtom->getDisplayName(), ref->getTarget().getDisplayName());
OSWriteLittleInt32(buffer, 0, newInstruction);
}
break;
case kBranchIslandToThumb1:
{
// There is no large displacement thumb1 branch instruction.
// Instead use ARM instructions that can jump to thumb.
// we use a 32-bit displacement, so we can directly jump to target which means no island hopping
int64_t displacement = getFinalTargetAdress() - (this->getAddress() + 12);
if ( fFinalTarget.isThumb() )
displacement |= 1;
if (log) fprintf(stderr, "%s: 4 ARM instruction jump to final target at 0x%08llX\n", fName, getFinalTargetAdress());
OSWriteLittleInt32(&buffer[ 0], 0, 0xe59fc004); // ldr ip, pc + 4
OSWriteLittleInt32(&buffer[ 4], 0, 0xe08fc00c); // add ip, pc, ip
OSWriteLittleInt32(&buffer[ 8], 0, 0xe12fff1c); // bx ip
OSWriteLittleInt32(&buffer[12], 0, displacement); // .long target-this
}
break;
};
}
template <>
uint64_t BranchIslandAtom<ppc>::getSize() const
{
return 4;
}
template <>
uint64_t BranchIslandAtom<ppc64>::getSize() const
{
return 4;
}
template <>
uint64_t BranchIslandAtom<arm>::getSize() const
{
switch ( fIslandKind ) {
case kBranchIslandToARM:
return 4;
case kBranchIslandToThumb1:
return 16;
case kBranchIslandToThumb2:
return 4;
};
throw "internal error: no ARM branch island kind";
}
template <typename A>
uint64_t SegmentSplitInfoLoadCommandsAtom<A>::getSize() const
{
if ( fWriter.fSplitCodeToDataContentAtom->canEncode() )
return this->alignedSize(sizeof(macho_linkedit_data_command<P>));
else
return 0; // a zero size causes the load command to be suppressed
}
template <typename A>
void SegmentSplitInfoLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
uint64_t size = this->getSize();
if ( size > 0 ) {
bzero(buffer, size);
macho_linkedit_data_command<P>* cmd = (macho_linkedit_data_command<P>*)buffer;
cmd->set_cmd(LC_SEGMENT_SPLIT_INFO);
cmd->set_cmdsize(size);
cmd->set_dataoff(fWriter.fSplitCodeToDataContentAtom->getFileOffset());
cmd->set_datasize(fWriter.fSplitCodeToDataContentAtom->getSize());
}
}
template <typename A>
uint64_t SegmentSplitInfoContentAtom<A>::getSize() const
{
return fEncodedData.size();
}
template <typename A>
void SegmentSplitInfoContentAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, &fEncodedData[0], fEncodedData.size());
}
template <typename A>
void SegmentSplitInfoContentAtom<A>::uleb128EncodeAddresses(const std::vector<SegmentSplitInfoContentAtom<A>::AtomAndOffset>& locations)
{
pint_t addr = fWriter.fOptions.baseAddress();
for(typename std::vector<AtomAndOffset>::const_iterator it = locations.begin(); it != locations.end(); ++it) {
pint_t nextAddr = it->atom->getAddress() + it->offset;
//fprintf(stderr, "\t0x%0llX\n", (uint64_t)nextAddr);
uint64_t delta = nextAddr - addr;
if ( delta == 0 )
throw "double split seg info for same address";
// uleb128 encode
uint8_t byte;
do {
byte = delta & 0x7F;
delta &= ~0x7F;
if ( delta != 0 )
byte |= 0x80;
fEncodedData.push_back(byte);
delta = delta >> 7;
}
while( byte >= 0x80 );
addr = nextAddr;
}
}
template <typename A>
void SegmentSplitInfoContentAtom<A>::encode()
{
if ( ! fCantEncode ) {
fEncodedData.reserve(8192);
if ( fKind1Locations.size() != 0 ) {
fEncodedData.push_back(1);
//fprintf(stderr, "type 1:\n");
this->uleb128EncodeAddresses(fKind1Locations);
fEncodedData.push_back(0);
}
if ( fKind2Locations.size() != 0 ) {
fEncodedData.push_back(2);
//fprintf(stderr, "type 2:\n");
this->uleb128EncodeAddresses(fKind2Locations);
fEncodedData.push_back(0);
}
if ( fKind3Locations.size() != 0 ) {
fEncodedData.push_back(3);
//fprintf(stderr, "type 3:\n");
this->uleb128EncodeAddresses(fKind3Locations);
fEncodedData.push_back(0);
}
if ( fKind4Locations.size() != 0 ) {
fEncodedData.push_back(4);
//fprintf(stderr, "type 4:\n");
this->uleb128EncodeAddresses(fKind4Locations);
fEncodedData.push_back(0);
}
// always add zero byte to mark end
fEncodedData.push_back(0);
// add zeros to end to align size
while ( (fEncodedData.size() % sizeof(pint_t)) != 0 )
fEncodedData.push_back(0);
}
}
template <typename A>
ObjCInfoAtom<A>::ObjCInfoAtom(Writer<A>& writer, ObjectFile::Reader::ObjcConstraint objcConstraint, bool objcReplacementClasses)
: WriterAtom<A>(writer, getInfoSegment())
{
fContent[0] = 0;
uint32_t value = 0;
// struct objc_image_info {
// uint32_t version; // initially 0
// uint32_t flags;
// };
// #define OBJC_IMAGE_SUPPORTS_GC 2
// #define OBJC_IMAGE_GC_ONLY 4
//
if ( objcReplacementClasses )
value = 1;
switch ( objcConstraint ) {
case ObjectFile::Reader::kObjcNone:
case ObjectFile::Reader::kObjcRetainRelease:
break;
case ObjectFile::Reader::kObjcRetainReleaseOrGC:
value |= 2;
break;
case ObjectFile::Reader::kObjcGC:
value |= 6;
break;
}
A::P::E::set32(fContent[1], value);
}
template <typename A>
void ObjCInfoAtom<A>::copyRawContent(uint8_t buffer[]) const
{
memcpy(buffer, &fContent[0], 8);
}
// objc info section is in a different segment and section for 32 vs 64 bit runtimes
template <> const char* ObjCInfoAtom<ppc>::getSectionName() const { return "__image_info"; }
template <> const char* ObjCInfoAtom<x86>::getSectionName() const { return "__image_info"; }
template <> const char* ObjCInfoAtom<arm>::getSectionName() const { return "__objc_imageinfo"; }
template <> const char* ObjCInfoAtom<ppc64>::getSectionName() const { return "__objc_imageinfo"; }
template <> const char* ObjCInfoAtom<x86_64>::getSectionName() const { return "__objc_imageinfo"; }
template <> Segment& ObjCInfoAtom<ppc>::getInfoSegment() const { return Segment::fgObjCSegment; }
template <> Segment& ObjCInfoAtom<x86>::getInfoSegment() const { return Segment::fgObjCSegment; }
template <> Segment& ObjCInfoAtom<ppc64>::getInfoSegment() const { return Segment::fgDataSegment; }
template <> Segment& ObjCInfoAtom<x86_64>::getInfoSegment() const { return Segment::fgDataSegment; }
template <> Segment& ObjCInfoAtom<arm>::getInfoSegment() const { return Segment::fgDataSegment; }
template <typename A>
void DyldInfoLoadCommandsAtom<A>::copyRawContent(uint8_t buffer[]) const
{
// build LC_DYLD_INFO command
macho_dyld_info_command<P>* cmd = (macho_dyld_info_command<P>*)buffer;
bzero(cmd, sizeof(macho_dyld_info_command<P>));
cmd->set_cmd( fWriter.fOptions.makeClassicDyldInfo() ? LC_DYLD_INFO : LC_DYLD_INFO_ONLY);
cmd->set_cmdsize(sizeof(macho_dyld_info_command<P>));
if ( (fWriter.fCompressedRebaseInfoAtom != NULL) && (fWriter.fCompressedRebaseInfoAtom->getSize() != 0) ) {
cmd->set_rebase_off(fWriter.fCompressedRebaseInfoAtom->getFileOffset());
cmd->set_rebase_size(fWriter.fCompressedRebaseInfoAtom->getSize());
}
if ( (fWriter.fCompressedBindingInfoAtom != NULL) && (fWriter.fCompressedBindingInfoAtom->getSize() != 0) ) {
cmd->set_bind_off(fWriter.fCompressedBindingInfoAtom->getFileOffset());
cmd->set_bind_size(fWriter.fCompressedBindingInfoAtom->getSize());
}
if ( (fWriter.fCompressedWeakBindingInfoAtom != NULL) && (fWriter.fCompressedWeakBindingInfoAtom->getSize() != 0) ) {
cmd->set_weak_bind_off(fWriter.fCompressedWeakBindingInfoAtom->getFileOffset());
cmd->set_weak_bind_size(fWriter.fCompressedWeakBindingInfoAtom->getSize());
}
if ( (fWriter.fCompressedLazyBindingInfoAtom != NULL) && (fWriter.fCompressedLazyBindingInfoAtom->getSize() != 0) ) {
cmd->set_lazy_bind_off(fWriter.fCompressedLazyBindingInfoAtom->getFileOffset());
cmd->set_lazy_bind_size(fWriter.fCompressedLazyBindingInfoAtom->getSize());
}
if ( (fWriter.fCompressedExportInfoAtom != NULL) && (fWriter.fCompressedExportInfoAtom->getSize() != 0) ) {
cmd->set_export_off(fWriter.fCompressedExportInfoAtom->getFileOffset());
cmd->set_export_size(fWriter.fCompressedExportInfoAtom->getSize());
}
}
struct rebase_tmp
{
rebase_tmp(uint8_t op, uint64_t p1, uint64_t p2=0) : opcode(op), operand1(p1), operand2(p2) {}
uint8_t opcode;
uint64_t operand1;
uint64_t operand2;
};
template <typename A>
void CompressedRebaseInfoLinkEditAtom<A>::encode()
{
// sort rebase info by type, then address
const std::vector<SegmentInfo*>& segments = fWriter.fSegmentInfos;
std::vector<RebaseInfo>& info = fWriter.fRebaseInfo;
std::sort(info.begin(), info.end());
// convert to temp encoding that can be more easily optimized
std::vector<rebase_tmp> mid;
const SegmentInfo* currentSegment = NULL;
unsigned int segIndex = 0;
uint8_t type = 0;
uint64_t address = (uint64_t)(-1);
for (std::vector<RebaseInfo>::iterator it = info.begin(); it != info.end(); ++it) {
if ( type != it->fType ) {
mid.push_back(rebase_tmp(REBASE_OPCODE_SET_TYPE_IMM, it->fType));
type = it->fType;
}
if ( address != it->fAddress ) {
if ( (currentSegment == NULL) || (it->fAddress < currentSegment->fBaseAddress)
|| ((currentSegment->fBaseAddress+currentSegment->fSize) <= it->fAddress) ) {
segIndex = 0;
for (std::vector<SegmentInfo*>::const_iterator segit = segments.begin(); segit != segments.end(); ++segit) {
if ( ((*segit)->fBaseAddress <= it->fAddress) && (it->fAddress < ((*segit)->fBaseAddress+(*segit)->fSize)) ) {
currentSegment = *segit;
break;
}
++segIndex;
}
mid.push_back(rebase_tmp(REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB, segIndex, it->fAddress - currentSegment->fBaseAddress));
}
else {
mid.push_back(rebase_tmp(REBASE_OPCODE_ADD_ADDR_ULEB, it->fAddress-address));
}
address = it->fAddress;
}
mid.push_back(rebase_tmp(REBASE_OPCODE_DO_REBASE_ULEB_TIMES, 1));
address += sizeof(pint_t);
}
mid.push_back(rebase_tmp(REBASE_OPCODE_DONE, 0));
// optimize phase 1, compress packed runs of pointers
rebase_tmp* dst = &mid[0];
for (const rebase_tmp* src = &mid[0]; src->opcode != REBASE_OPCODE_DONE; ++src) {
if ( (src->opcode == REBASE_OPCODE_DO_REBASE_ULEB_TIMES) && (src->operand1 == 1) ) {
*dst = *src++;
while (src->opcode == REBASE_OPCODE_DO_REBASE_ULEB_TIMES ) {
dst->operand1 += src->operand1;
++src;
}
--src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = REBASE_OPCODE_DONE;
// optimize phase 2, combine rebase/add pairs
dst = &mid[0];
for (const rebase_tmp* src = &mid[0]; src->opcode != REBASE_OPCODE_DONE; ++src) {
if ( (src->opcode == REBASE_OPCODE_DO_REBASE_ULEB_TIMES)
&& (src->operand1 == 1)
&& (src[1].opcode == REBASE_OPCODE_ADD_ADDR_ULEB)) {
dst->opcode = REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB;
dst->operand1 = src[1].operand1;
++src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = REBASE_OPCODE_DONE;
// optimize phase 3, compress packed runs of REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB with
// same addr delta into one REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB
dst = &mid[0];
for (const rebase_tmp* src = &mid[0]; src->opcode != REBASE_OPCODE_DONE; ++src) {
uint64_t delta = src->operand1;
if ( (src->opcode == REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB)
&& (src[1].opcode == REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB)
&& (src[2].opcode == REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB)
&& (src[1].operand1 == delta)
&& (src[2].operand1 == delta) ) {
// found at least three in a row, this is worth compressing
dst->opcode = REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB;
dst->operand1 = 1;
dst->operand2 = delta;
++src;
while ( (src->opcode == REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB)
&& (src->operand1 == delta) ) {
dst->operand1++;
++src;
}
--src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = REBASE_OPCODE_DONE;
// optimize phase 4, use immediate encodings
for (rebase_tmp* p = &mid[0]; p->opcode != REBASE_OPCODE_DONE; ++p) {
if ( (p->opcode == REBASE_OPCODE_ADD_ADDR_ULEB)
&& (p->operand1 < (15*sizeof(pint_t)))
&& ((p->operand1 % sizeof(pint_t)) == 0) ) {
p->opcode = REBASE_OPCODE_ADD_ADDR_IMM_SCALED;
p->operand1 = p->operand1/sizeof(pint_t);
}
else if ( (p->opcode == REBASE_OPCODE_DO_REBASE_ULEB_TIMES) && (p->operand1 < 15) ) {
p->opcode = REBASE_OPCODE_DO_REBASE_IMM_TIMES;
}
}
// convert to compressed encoding
const static bool log = false;
fEncodedData.reserve(info.size()*2);
bool done = false;
for (std::vector<rebase_tmp>::iterator it = mid.begin(); !done && it != mid.end() ; ++it) {
switch ( it->opcode ) {
case REBASE_OPCODE_DONE:
if ( log ) fprintf(stderr, "REBASE_OPCODE_DONE()\n");
done = true;
break;
case REBASE_OPCODE_SET_TYPE_IMM:
if ( log ) fprintf(stderr, "REBASE_OPCODE_SET_TYPE_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(REBASE_OPCODE_SET_TYPE_IMM | it->operand1);
break;
case REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB:
if ( log ) fprintf(stderr, "REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB(%lld, 0x%llX)\n", it->operand1, it->operand2);
fEncodedData.append_byte(REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB | it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
case REBASE_OPCODE_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "REBASE_OPCODE_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(REBASE_OPCODE_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case REBASE_OPCODE_ADD_ADDR_IMM_SCALED:
if ( log ) fprintf(stderr, "REBASE_OPCODE_ADD_ADDR_IMM_SCALED(%lld=0x%llX)\n", it->operand1, it->operand1*sizeof(pint_t));
fEncodedData.append_byte(REBASE_OPCODE_ADD_ADDR_IMM_SCALED | it->operand1 );
break;
case REBASE_OPCODE_DO_REBASE_IMM_TIMES:
if ( log ) fprintf(stderr, "REBASE_OPCODE_DO_REBASE_IMM_TIMES(%lld)\n", it->operand1);
fEncodedData.append_byte(REBASE_OPCODE_DO_REBASE_IMM_TIMES | it->operand1);
break;
case REBASE_OPCODE_DO_REBASE_ULEB_TIMES:
if ( log ) fprintf(stderr, "REBASE_OPCODE_DO_REBASE_ULEB_TIMES(%lld)\n", it->operand1);
fEncodedData.append_byte(REBASE_OPCODE_DO_REBASE_ULEB_TIMES);
fEncodedData.append_uleb128(it->operand1);
break;
case REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB:
if ( log ) fprintf(stderr, "REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB(%lld, %lld)\n", it->operand1, it->operand2);
fEncodedData.append_byte(REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB);
fEncodedData.append_uleb128(it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
}
}
// align to pointer size
fEncodedData.pad_to_size(sizeof(pint_t));
if (log) fprintf(stderr, "total rebase info size = %ld\n", fEncodedData.size());
}
struct binding_tmp
{
binding_tmp(uint8_t op, uint64_t p1, uint64_t p2=0, const char* s=NULL)
: opcode(op), operand1(p1), operand2(p2), name(s) {}
uint8_t opcode;
uint64_t operand1;
uint64_t operand2;
const char* name;
};
template <typename A>
void CompressedBindingInfoLinkEditAtom<A>::encode()
{
// sort by library, symbol, type, then address
const std::vector<SegmentInfo*>& segments = fWriter.fSegmentInfos;
std::vector<BindingInfo>& info = fWriter.fBindingInfo;
std::sort(info.begin(), info.end());
// convert to temp encoding that can be more easily optimized
std::vector<binding_tmp> mid;
const SegmentInfo* currentSegment = NULL;
unsigned int segIndex = 0;
int ordinal = 0x80000000;
const char* symbolName = NULL;
uint8_t type = 0;
uint64_t address = (uint64_t)(-1);
int64_t addend = 0;
for (std::vector<BindingInfo>::iterator it = info.begin(); it != info.end(); ++it) {
if ( ordinal != it->fLibraryOrdinal ) {
if ( it->fLibraryOrdinal <= 0 ) {
// special lookups are encoded as negative numbers in BindingInfo
mid.push_back(binding_tmp(BIND_OPCODE_SET_DYLIB_SPECIAL_IMM, it->fLibraryOrdinal));
}
else {
mid.push_back(binding_tmp(BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB, it->fLibraryOrdinal));
}
ordinal = it->fLibraryOrdinal;
}
if ( symbolName != it->fSymbolName ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM, it->fFlags, 0, it->fSymbolName));
symbolName = it->fSymbolName;
}
if ( type != it->fType ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_TYPE_IMM, it->fType));
type = it->fType;
}
if ( address != it->fAddress ) {
if ( (currentSegment == NULL) || (it->fAddress < currentSegment->fBaseAddress)
|| ((currentSegment->fBaseAddress+currentSegment->fSize) <=it->fAddress)
|| (it->fAddress < address) ) {
segIndex = 0;
for (std::vector<SegmentInfo*>::const_iterator segit = segments.begin(); segit != segments.end(); ++segit) {
if ( ((*segit)->fBaseAddress <= it->fAddress) && (it->fAddress < ((*segit)->fBaseAddress+(*segit)->fSize)) ) {
currentSegment = *segit;
break;
}
++segIndex;
}
mid.push_back(binding_tmp(BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB, segIndex, it->fAddress - currentSegment->fBaseAddress));
}
else {
mid.push_back(binding_tmp(BIND_OPCODE_ADD_ADDR_ULEB, it->fAddress-address));
}
address = it->fAddress;
}
if ( addend != it->fAddend ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_ADDEND_SLEB, it->fAddend));
addend = it->fAddend;
}
mid.push_back(binding_tmp(BIND_OPCODE_DO_BIND, 0));
address += sizeof(pint_t);
}
mid.push_back(binding_tmp(BIND_OPCODE_DONE, 0));
// optimize phase 1, combine bind/add pairs
binding_tmp* dst = &mid[0];
for (const binding_tmp* src = &mid[0]; src->opcode != BIND_OPCODE_DONE; ++src) {
if ( (src->opcode == BIND_OPCODE_DO_BIND)
&& (src[1].opcode == BIND_OPCODE_ADD_ADDR_ULEB) ) {
dst->opcode = BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB;
dst->operand1 = src[1].operand1;
++src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = BIND_OPCODE_DONE;
// optimize phase 2, compress packed runs of BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB with
// same addr delta into one BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB
dst = &mid[0];
for (const binding_tmp* src = &mid[0]; src->opcode != BIND_OPCODE_DONE; ++src) {
uint64_t delta = src->operand1;
if ( (src->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src[1].opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src[1].operand1 == delta) ) {
// found at least two in a row, this is worth compressing
dst->opcode = BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB;
dst->operand1 = 1;
dst->operand2 = delta;
++src;
while ( (src->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src->operand1 == delta) ) {
dst->operand1++;
++src;
}
--src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = BIND_OPCODE_DONE;
// optimize phase 3, use immediate encodings
for (binding_tmp* p = &mid[0]; p->opcode != REBASE_OPCODE_DONE; ++p) {
if ( (p->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (p->operand1 < (15*sizeof(pint_t)))
&& ((p->operand1 % sizeof(pint_t)) == 0) ) {
p->opcode = BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED;
p->operand1 = p->operand1/sizeof(pint_t);
}
else if ( (p->opcode == BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB) && (p->operand1 <= 15) ) {
p->opcode = BIND_OPCODE_SET_DYLIB_ORDINAL_IMM;
}
}
dst->opcode = BIND_OPCODE_DONE;
// convert to compressed encoding
const static bool log = false;
fEncodedData.reserve(info.size()*2);
bool done = false;
for (std::vector<binding_tmp>::iterator it = mid.begin(); !done && it != mid.end() ; ++it) {
switch ( it->opcode ) {
case BIND_OPCODE_DONE:
if ( log ) fprintf(stderr, "BIND_OPCODE_DONE()\n");
done = true;
break;
case BIND_OPCODE_SET_DYLIB_ORDINAL_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_ORDINAL_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_IMM | it->operand1);
break;
case BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_SET_DYLIB_SPECIAL_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_SPECIAL_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_SPECIAL_IMM | (it->operand1 & BIND_IMMEDIATE_MASK));
break;
case BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM(0x%0llX, %s)\n", it->operand1, it->name);
fEncodedData.append_byte(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM | it->operand1);
fEncodedData.append_string(it->name);
break;
case BIND_OPCODE_SET_TYPE_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_TYPE_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_TYPE_IMM | it->operand1);
break;
case BIND_OPCODE_SET_ADDEND_SLEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_ADDEND_SLEB(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_ADDEND_SLEB);
fEncodedData.append_sleb128(it->operand1);
break;
case BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB(%lld, 0x%llX)\n", it->operand1, it->operand2);
fEncodedData.append_byte(BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB | it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
case BIND_OPCODE_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_DO_BIND:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND()\n");
fEncodedData.append_byte(BIND_OPCODE_DO_BIND);
break;
case BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED(%lld=0x%llX)\n", it->operand1, it->operand1*sizeof(pint_t));
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED | it->operand1 );
break;
case BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB(%lld, %lld)\n", it->operand1, it->operand2);
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB);
fEncodedData.append_uleb128(it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
}
}
// align to pointer size
fEncodedData.pad_to_size(sizeof(pint_t));
if (log) fprintf(stderr, "total binding info size = %ld\n", fEncodedData.size());
}
struct WeakBindingSorter
{
bool operator()(const BindingInfo& left, const BindingInfo& right)
{
// sort by symbol, type, address
if ( left.fSymbolName != right.fSymbolName )
return ( strcmp(left.fSymbolName, right.fSymbolName) < 0 );
if ( left.fType != right.fType )
return (left.fType < right.fType);
return (left.fAddress < right.fAddress);
}
};
template <typename A>
void CompressedWeakBindingInfoLinkEditAtom<A>::encode()
{
// add regular atoms that override a dylib's weak definitions
for(std::set<const class ObjectFile::Atom*>::iterator it = fWriter.fRegularDefAtomsThatOverrideADylibsWeakDef->begin();
it != fWriter.fRegularDefAtomsThatOverrideADylibsWeakDef->end(); ++it) {
if ( fWriter.shouldExport(**it) )
fWriter.fWeakBindingInfo.push_back(BindingInfo(0, (*it)->getName(), true, 0, 0));
}
// add all exported weak definitions
for(std::vector<class ObjectFile::Atom*>::iterator it = fWriter.fAllAtoms->begin(); it != fWriter.fAllAtoms->end(); ++it) {
ObjectFile::Atom* atom = *it;
if ( (atom->getDefinitionKind() == ObjectFile::Atom::kWeakDefinition) && fWriter.shouldExport(*atom) ) {
fWriter.fWeakBindingInfo.push_back(BindingInfo(0, atom->getName(), false, 0, 0));
}
}
// sort by symbol, type, address
const std::vector<SegmentInfo*>& segments = fWriter.fSegmentInfos;
std::vector<BindingInfo>& info = fWriter.fWeakBindingInfo;
if ( info.size() == 0 )
return;
std::sort(info.begin(), info.end(), WeakBindingSorter());
// convert to temp encoding that can be more easily optimized
std::vector<binding_tmp> mid;
mid.reserve(info.size());
const SegmentInfo* currentSegment = NULL;
unsigned int segIndex = 0;
const char* symbolName = NULL;
uint8_t type = 0;
uint64_t address = (uint64_t)(-1);
int64_t addend = 0;
for (std::vector<BindingInfo>::iterator it = info.begin(); it != info.end(); ++it) {
if ( symbolName != it->fSymbolName ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM, it->fFlags, 0, it->fSymbolName));
symbolName = it->fSymbolName;
}
if ( it->fType != 0 ) {
if ( type != it->fType ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_TYPE_IMM, it->fType));
type = it->fType;
}
if ( address != it->fAddress ) {
// non weak symbols just have BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM
// weak symbols have SET_SEG, ADD_ADDR, SET_ADDED, DO_BIND
if ( (currentSegment == NULL) || (it->fAddress < currentSegment->fBaseAddress)
|| ((currentSegment->fBaseAddress+currentSegment->fSize) <=it->fAddress) ) {
segIndex = 0;
for (std::vector<SegmentInfo*>::const_iterator segit = segments.begin(); segit != segments.end(); ++segit) {
if ( ((*segit)->fBaseAddress <= it->fAddress) && (it->fAddress < ((*segit)->fBaseAddress+(*segit)->fSize)) ) {
currentSegment = *segit;
break;
}
++segIndex;
}
mid.push_back(binding_tmp(BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB, segIndex, it->fAddress - currentSegment->fBaseAddress));
}
else {
mid.push_back(binding_tmp(BIND_OPCODE_ADD_ADDR_ULEB, it->fAddress-address));
}
address = it->fAddress;
}
if ( addend != it->fAddend ) {
mid.push_back(binding_tmp(BIND_OPCODE_SET_ADDEND_SLEB, it->fAddend));
addend = it->fAddend;
}
mid.push_back(binding_tmp(BIND_OPCODE_DO_BIND, 0));
address += sizeof(pint_t);
}
}
mid.push_back(binding_tmp(BIND_OPCODE_DONE, 0));
// optimize phase 1, combine bind/add pairs
binding_tmp* dst = &mid[0];
for (const binding_tmp* src = &mid[0]; src->opcode != BIND_OPCODE_DONE; ++src) {
if ( (src->opcode == BIND_OPCODE_DO_BIND)
&& (src[1].opcode == BIND_OPCODE_ADD_ADDR_ULEB) ) {
dst->opcode = BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB;
dst->operand1 = src[1].operand1;
++src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = BIND_OPCODE_DONE;
// optimize phase 2, compress packed runs of BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB with
// same addr delta into one BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB
dst = &mid[0];
for (const binding_tmp* src = &mid[0]; src->opcode != BIND_OPCODE_DONE; ++src) {
uint64_t delta = src->operand1;
if ( (src->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src[1].opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src[1].operand1 == delta) ) {
// found at least two in a row, this is worth compressing
dst->opcode = BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB;
dst->operand1 = 1;
dst->operand2 = delta;
++src;
while ( (src->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (src->operand1 == delta) ) {
dst->operand1++;
++src;
}
--src;
++dst;
}
else {
*dst++ = *src;
}
}
dst->opcode = BIND_OPCODE_DONE;
// optimize phase 3, use immediate encodings
for (binding_tmp* p = &mid[0]; p->opcode != REBASE_OPCODE_DONE; ++p) {
if ( (p->opcode == BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB)
&& (p->operand1 < (15*sizeof(pint_t)))
&& ((p->operand1 % sizeof(pint_t)) == 0) ) {
p->opcode = BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED;
p->operand1 = p->operand1/sizeof(pint_t);
}
}
dst->opcode = BIND_OPCODE_DONE;
// convert to compressed encoding
const static bool log = false;
fEncodedData.reserve(info.size()*2);
bool done = false;
for (std::vector<binding_tmp>::iterator it = mid.begin(); !done && it != mid.end() ; ++it) {
switch ( it->opcode ) {
case BIND_OPCODE_DONE:
if ( log ) fprintf(stderr, "BIND_OPCODE_DONE()\n");
fEncodedData.append_byte(BIND_OPCODE_DONE);
done = true;
break;
case BIND_OPCODE_SET_DYLIB_ORDINAL_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_ORDINAL_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_IMM | it->operand1);
break;
case BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_SET_DYLIB_SPECIAL_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_DYLIB_SPECIAL_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_SPECIAL_IMM | (it->operand1 & BIND_IMMEDIATE_MASK));
break;
case BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM(0x%0llX, %s)\n", it->operand1, it->name);
fEncodedData.append_byte(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM | it->operand1);
fEncodedData.append_string(it->name);
break;
case BIND_OPCODE_SET_TYPE_IMM:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_TYPE_IMM(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_TYPE_IMM | it->operand1);
break;
case BIND_OPCODE_SET_ADDEND_SLEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_ADDEND_SLEB(%lld)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_SET_ADDEND_SLEB);
fEncodedData.append_sleb128(it->operand1);
break;
case BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB(%lld, 0x%llX)\n", it->operand1, it->operand2);
fEncodedData.append_byte(BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB | it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
case BIND_OPCODE_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_DO_BIND:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND()\n");
fEncodedData.append_byte(BIND_OPCODE_DO_BIND);
break;
case BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB(0x%llX)\n", it->operand1);
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB);
fEncodedData.append_uleb128(it->operand1);
break;
case BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED(%lld=0x%llX)\n", it->operand1, it->operand1*sizeof(pint_t));
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED | it->operand1 );
break;
case BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB:
if ( log ) fprintf(stderr, "BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB(%lld, %lld)\n", it->operand1, it->operand2);
fEncodedData.append_byte(BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB);
fEncodedData.append_uleb128(it->operand1);
fEncodedData.append_uleb128(it->operand2);
break;
}
}
// align to pointer size
fEncodedData.pad_to_size(sizeof(pint_t));
if (log) fprintf(stderr, "total weak binding info size = %ld\n", fEncodedData.size());
}
template <typename A>
void CompressedLazyBindingInfoLinkEditAtom<A>::encode()
{
// stream all lazy bindings and record start offsets
const SegmentInfo* currentSegment = NULL;
uint8_t segIndex = 0;
const std::vector<SegmentInfo*>& segments = fWriter.fSegmentInfos;
std::vector<class LazyPointerAtom<A>*>& allLazys = fWriter.fAllSynthesizedLazyPointers;
for (typename std::vector<class LazyPointerAtom<A>*>::iterator it = allLazys.begin(); it != allLazys.end(); ++it) {
LazyPointerAtom<A>* lazyPointerAtom = *it;
ObjectFile::Atom* lazyPointerTargetAtom = lazyPointerAtom->getTarget();
// skip lazy pointers that are bound non-lazily because they are coalesced
if ( ! fWriter.targetRequiresWeakBinding(*lazyPointerTargetAtom) ) {
// record start offset for use by stub helper
lazyPointerAtom->setLazyBindingInfoOffset(fEncodedData.size());
// write address to bind
pint_t address = lazyPointerAtom->getAddress();
if ( (currentSegment == NULL) || (address < currentSegment->fBaseAddress)
|| ((currentSegment->fBaseAddress+currentSegment->fSize) <= address) ) {
segIndex = 0;
for (std::vector<SegmentInfo*>::const_iterator segit = segments.begin(); segit != segments.end(); ++segit) {
if ( ((*segit)->fBaseAddress <= address) && (address < ((*segit)->fBaseAddress+(*segit)->fSize)) ) {
currentSegment = *segit;
break;
}
++segIndex;
}
}
fEncodedData.append_byte(BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB | segIndex);
fEncodedData.append_uleb128(lazyPointerAtom->getAddress() - currentSegment->fBaseAddress);
// write ordinal
int ordinal = fWriter.compressedOrdinalForImortedAtom(lazyPointerTargetAtom);
if ( ordinal <= 0 ) {
// special lookups are encoded as negative numbers in BindingInfo
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_SPECIAL_IMM | (ordinal & BIND_IMMEDIATE_MASK) );
}
else if ( ordinal <= 15 ) {
// small ordinals are encoded in opcode
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_IMM | ordinal);
}
else {
fEncodedData.append_byte(BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB);
fEncodedData.append_uleb128(ordinal);
}
// write symbol name
bool weak_import = fWriter.fWeakImportMap[lazyPointerTargetAtom];
if ( weak_import )
fEncodedData.append_byte(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM | BIND_SYMBOL_FLAGS_WEAK_IMPORT);
else
fEncodedData.append_byte(BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM);
fEncodedData.append_string(lazyPointerTargetAtom->getName());
// write do bind
fEncodedData.append_byte(BIND_OPCODE_DO_BIND);
fEncodedData.append_byte(BIND_OPCODE_DONE);
}
}
// align to pointer size
fEncodedData.pad_to_size(sizeof(pint_t));
//fprintf(stderr, "lazy binding info size = %ld, for %ld entries\n", fEncodedData.size(), allLazys.size());
}
struct TrieEntriesSorter
{
TrieEntriesSorter(Options& o) : fOptions(o) {}
bool operator()(const mach_o::trie::Entry& left, const mach_o::trie::Entry& right)
{
unsigned int leftOrder;
unsigned int rightOrder;
fOptions.exportedSymbolOrder(left.name, &leftOrder);
fOptions.exportedSymbolOrder(right.name, &rightOrder);
if ( leftOrder != rightOrder )
return (leftOrder < rightOrder);
else
return (left.address < right.address);
}
private:
Options& fOptions;
};
template <typename A>
void CompressedExportInfoLinkEditAtom<A>::encode()
{
// make vector of mach_o::trie::Entry for all exported symbols
std::vector<class ObjectFile::Atom*>& exports = fWriter.fExportedAtoms;
uint64_t imageBaseAddress = fWriter.fMachHeaderAtom->getAddress();
std::vector<mach_o::trie::Entry> entries;
entries.reserve(exports.size());
for (std::vector<ObjectFile::Atom*>::iterator it = exports.begin(); it != exports.end(); ++it) {
ObjectFile::Atom* atom = *it;
uint64_t flags = 0;
if ( atom->getDefinitionKind() == ObjectFile::Atom::kWeakDefinition )
flags |= EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION;
uint64_t address = atom->getAddress() - imageBaseAddress;
if ( atom->isThumb() )
address |= 1;
mach_o::trie::Entry entry;
entry.name = atom->getName();
entry.flags = flags;
entry.address = address;
entries.push_back(entry);
}
// sort vector by -exported_symbols_order, and any others by address
std::sort(entries.begin(), entries.end(), TrieEntriesSorter(fWriter.fOptions));
// create trie
mach_o::trie::makeTrie(entries, fEncodedData.bytes());
// align to pointer size
fEncodedData.pad_to_size(sizeof(pint_t));
}
}; // namespace executable
}; // namespace mach_o
#endif // __EXECUTABLE_MACH_O__