MachOReaderRelocatable.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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* This file contains Original Code and/or Modifications of Original Code
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* Version 2.0 (the 'License'). You may not use this file except in
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#ifndef __OBJECT_FILE_MACH_O__
#define __OBJECT_FILE_MACH_O__
#include <stdint.h>
#include <math.h>
#include <unistd.h>
#include <sys/param.h>
#include <vector>
#include <set>
#include <algorithm>
#include "MachOFileAbstraction.hpp"
#include "Architectures.hpp"
#include "ObjectFile.h"
#include "dwarf2.h"
#include "debugline.h"
#include <libunwind/DwarfInstructions.hpp>
#include <libunwind/AddressSpace.hpp>
#include <libunwind/Registers.hpp>
//
//
// To implement architecture xxx, you must write template specializations for the following six methods:
// Reader<xxx>::validFile()
// Reader<xxx>::validSectionType()
// Reader<xxx>::addRelocReference()
// Reference<xxx>::getDescription()
//
//
extern __attribute__((noreturn)) void throwf(const char* format, ...);
extern void warning(const char* format, ...);
namespace mach_o {
namespace relocatable {
class ReferenceSorter
{
public:
bool operator()(const ObjectFile::Reference* left, const ObjectFile::Reference* right)
{
return ( left->getFixUpOffset() < right->getFixUpOffset() );
}
};
// forward reference
template <typename A> class Reader;
struct AtomAndOffset
{
AtomAndOffset(ObjectFile::Atom* a=NULL) : atom(a), offset(0) {}
AtomAndOffset(ObjectFile::Atom* a, uint32_t off) : atom(a), offset(off) {}
ObjectFile::Atom* atom;
uint32_t offset;
};
template <typename A>
class Reference : public ObjectFile::Reference
{
public:
typedef typename A::P P;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
Reference(Kinds kind, const AtomAndOffset& at, const AtomAndOffset& toTarget);
Reference(Kinds kind, const AtomAndOffset& at, const AtomAndOffset& fromTarget, const AtomAndOffset& toTarget);
Reference(Kinds kind, const AtomAndOffset& at, const char* toName, uint32_t toOffset);
virtual ~Reference() {}
virtual ObjectFile::Reference::TargetBinding getTargetBinding() const;
virtual ObjectFile::Reference::TargetBinding getFromTargetBinding() const;
virtual uint8_t getKind() const { return (uint8_t)fKind; }
virtual uint64_t getFixUpOffset() const { return fFixUpOffsetInSrc; }
virtual const char* getTargetName() const { return (fToTarget.atom != NULL) ? fToTarget.atom->getName() : fToTargetName; }
virtual ObjectFile::Atom& getTarget() const { return *fToTarget.atom; }
virtual uint64_t getTargetOffset() const { return (int64_t)((int32_t)fToTarget.offset); }
virtual ObjectFile::Atom& getFromTarget() const { return *fFromTarget.atom; }
virtual const char* getFromTargetName() const { return (fFromTarget.atom != NULL) ? fFromTarget.atom->getName() : fFromTargetName; }
virtual void setTarget(ObjectFile::Atom& target, uint64_t offset) { fToTarget.atom = ⌖ fToTarget.offset = offset; }
virtual void setToTargetOffset(uint64_t offset) { fToTarget.offset = offset; }
virtual void setFromTarget(ObjectFile::Atom& target) { fFromTarget.atom = ⌖ }
virtual void setFromTargetName(const char* name) { fFromTargetName = name; }
virtual void setFromTargetOffset(uint64_t offset) { fFromTarget.offset = offset; }
virtual const char* getDescription() const;
virtual uint64_t getFromTargetOffset() const { return fFromTarget.offset; }
virtual bool isBranch() const;
virtual const char* getTargetDisplayName() const { return (fToTarget.atom != NULL) ? fToTarget.atom->getDisplayName() : fToTargetName; }
virtual const char* getFromTargetDisplayName() const { return (fFromTarget.atom != NULL) ? fFromTarget.atom->getDisplayName() : fFromTargetName; }
static bool fgForFinalLinkedImage;
private:
pint_t fFixUpOffsetInSrc;
AtomAndOffset fToTarget;
AtomAndOffset fFromTarget;
const char* fToTargetName;
const char* fFromTargetName;
Kinds fKind;
};
template <typename A> bool Reference<A>::fgForFinalLinkedImage = true;
template <typename A>
Reference<A>::Reference(Kinds kind, const AtomAndOffset& at, const AtomAndOffset& toTarget)
: fFixUpOffsetInSrc(at.offset), fToTarget(toTarget), fToTargetName(NULL), fFromTargetName(NULL),
fKind(kind)
{
// make reference a by-name unless:
// - the reference type is only used with direct references
// - the target is translation unit scoped
// - the target kind is not regular (is weak or tentative)
if ( (kind != A::kNoFixUp) && (kind != A::kFollowOn) && (kind != A::kGroupSubordinate)
&& (toTarget.atom->getScope() != ObjectFile::Atom::scopeTranslationUnit)
&& (toTarget.atom->getDefinitionKind() != ObjectFile::Atom::kRegularDefinition)
&& (toTarget.atom != at.atom) ) {
fToTargetName = toTarget.atom->getName();
//fprintf(stderr, "Reference(): changing to by-name %p %s, target scope=%d, target section=%s\n", toTarget.atom, fToTargetName, toTarget.atom->getScope(), toTarget.atom->getSectionName());
fToTarget.atom = NULL;
}
((class BaseAtom*)at.atom)->addReference(this);
//fprintf(stderr, "Reference(): %p fToTarget<%s, %08X>\n", this, (fToTarget.atom != NULL) ? fToTarget.atom->getDisplayName() : fToTargetName , fToTarget.offset);
}
template <typename A>
Reference<A>::Reference(Kinds kind, const AtomAndOffset& at, const AtomAndOffset& fromTarget, const AtomAndOffset& toTarget)
: fFixUpOffsetInSrc(at.offset), fToTarget(toTarget), fFromTarget(fromTarget),
fToTargetName(NULL), fFromTargetName(NULL), fKind(kind)
{
// make reference a by-name where needed
if ( (kind != A::kNoFixUp) && (kind != A::kFollowOn) && (kind != A::kGroupSubordinate)
&& (toTarget.atom->getScope() != ObjectFile::Atom::scopeTranslationUnit)
&& (toTarget.atom->getDefinitionKind() != ObjectFile::Atom::kRegularDefinition)
&& (toTarget.atom != at.atom) ) {
fToTargetName = toTarget.atom->getName();
fToTarget.atom = NULL;
}
((class BaseAtom*)at.atom)->addReference(this);
//fprintf(stderr, "Reference(): %p kind=%d, fToTarget<%s, %08X>, fromTarget<%s, %08X>\n", this, kind,
// this->getTargetName(), fToTarget.offset, this->getFromTargetName(), fromTarget.offset);
}
template <typename A>
Reference<A>::Reference(Kinds kind, const AtomAndOffset& at, const char* toName, uint32_t toOffset)
: fFixUpOffsetInSrc(at.offset),
fToTargetName(toName), fFromTargetName(NULL), fKind(kind)
{
fToTarget.offset = toOffset;
((class BaseAtom*)at.atom)->addReference(this);
}
template <typename A>
ObjectFile::Reference::TargetBinding Reference<A>::getTargetBinding() const
{
if ( fgForFinalLinkedImage ) {
if ( (fKind == A::kDtraceProbe) || (fKind == A::kDtraceProbeSite) || (fKind == A::kDtraceIsEnabledSite) || (fKind == A::kDtraceTypeReference) )
return ObjectFile::Reference::kDontBind;
}
if ( fToTarget.atom == NULL )
return ObjectFile::Reference::kUnboundByName;
if ( fToTargetName == NULL )
return ObjectFile::Reference::kBoundDirectly;
else
return ObjectFile::Reference::kBoundByName;
}
template <typename A>
ObjectFile::Reference::TargetBinding Reference<A>::getFromTargetBinding() const
{
if ( fFromTarget.atom == NULL ) {
if ( fFromTargetName == NULL )
return ObjectFile::Reference::kDontBind;
else
return ObjectFile::Reference::kUnboundByName;
}
else {
if ( fFromTargetName == NULL )
return ObjectFile::Reference::kBoundDirectly;
else
return ObjectFile::Reference::kBoundByName;
}
}
template <typename A>
class Segment : public ObjectFile::Segment
{
public:
Segment(const macho_section<typename A::P>* sect);
virtual const char* getName() const { return fSection->segname(); }
virtual bool isContentReadable() const { return true; }
virtual bool isContentWritable() const { return fWritable; }
virtual bool isContentExecutable() const { return fExecutable; }
private:
const macho_section<typename A::P>* fSection;
bool fWritable;
bool fExecutable;
};
template <typename A>
Segment<A>::Segment(const macho_section<typename A::P>* sect)
: fSection(sect), fWritable(true), fExecutable(false)
{
if ( strcmp(fSection->segname(), "__TEXT") == 0 ) {
fWritable = false;
fExecutable = true;
}
else if ( strcmp(fSection->segname(), "__IMPORT") == 0 ) {
fWritable = true;
fExecutable = true;
}
}
class DataSegment : public ObjectFile::Segment
{
public:
virtual const char* getName() const { return "__DATA"; }
virtual bool isContentReadable() const { return true; }
virtual bool isContentWritable() const { return true; }
virtual bool isContentExecutable() const { return false; }
static DataSegment fgSingleton;
};
DataSegment DataSegment::fgSingleton;
class LinkEditSegment : public ObjectFile::Segment
{
public:
virtual const char* getName() const { return "__LINKEDIT"; }
virtual bool isContentReadable() const { return true; }
virtual bool isContentWritable() const { return false; }
virtual bool isContentExecutable() const { return false; }
static LinkEditSegment fgSingleton;
};
LinkEditSegment LinkEditSegment::fgSingleton;
class BaseAtom : public ObjectFile::Atom
{
public:
BaseAtom() : fStabsStartIndex(0), fStabsCount(0), fHasCompactUnwindInfo(false) {}
virtual void setSize(uint64_t size) = 0;
virtual void addReference(ObjectFile::Reference* ref) = 0;
virtual void sortReferences() = 0;
virtual void addLineInfo(const ObjectFile::LineInfo& info) = 0;
virtual const ObjectFile::ReaderOptions& getOptions() const = 0;
virtual uint64_t getObjectAddress() const = 0;
virtual uint32_t getOrdinal() const { return fOrdinal; }
virtual void setOrdinal(uint32_t value) { fOrdinal = value; }
virtual const void* getSectionRecord() const = 0;
virtual unsigned int getSectionIndex() const = 0;
virtual bool isAlias() const { return false; }
virtual uint8_t getLSDAReferenceKind() const { return 0; }
virtual uint8_t getPersonalityReferenceKind() const { return 0; }
virtual uint32_t getCompactUnwindEncoding(uint64_t ehAtomAddress) { return 0; }
virtual ObjectFile::UnwindInfo::iterator beginUnwind() { return fHasCompactUnwindInfo ? &fSingleUnwindInfo[0] : NULL; }
virtual ObjectFile::UnwindInfo::iterator endUnwind() { return fHasCompactUnwindInfo ? &fSingleUnwindInfo[1] : NULL; }
virtual ObjectFile::Reference* getLSDA();
virtual ObjectFile::Reference* getFDE();
virtual Atom* getPersonalityPointer();
virtual void setCompactUnwindEncoding(uint64_t ehAtomAddress);
uint32_t fStabsStartIndex;
uint32_t fStabsCount;
uint32_t fOrdinal;
ObjectFile::UnwindInfo fSingleUnwindInfo[1];
bool fHasCompactUnwindInfo;
};
ObjectFile::Reference* BaseAtom::getLSDA()
{
const uint8_t groupKind = this->getLSDAReferenceKind();
const std::vector<ObjectFile::Reference*>& refs = this->getReferences();
for (std::vector<ObjectFile::Reference*>::const_iterator it=refs.begin(); it != refs.end(); it++) {
ObjectFile::Reference* ref = *it;
if ( (ref->getKind() == groupKind) && (ref->getTarget().getContentType() == ObjectFile::Atom::kLSDAType) ) {
return ref;
}
}
return NULL;
}
ObjectFile::Reference* BaseAtom::getFDE()
{
const uint8_t groupKind = this->getLSDAReferenceKind();
const std::vector<ObjectFile::Reference*>& refs = this->getReferences();
for (std::vector<ObjectFile::Reference*>::const_iterator it=refs.begin(); it != refs.end(); it++) {
ObjectFile::Reference* ref = *it;
if ( (ref->getKind() == groupKind) && (ref->getTarget().getContentType() == ObjectFile::Atom::kCFIType) ) {
return ref;
}
}
return NULL;
}
ObjectFile::Atom* BaseAtom::getPersonalityPointer()
{
const uint8_t personalityKind = this->getPersonalityReferenceKind();
const std::vector<ObjectFile::Reference*>& refs = this->getReferences();
for (std::vector<ObjectFile::Reference*>::const_iterator it=refs.begin(); it != refs.end(); it++) {
ObjectFile::Reference* ref = *it;
if ( ref->getKind() == personalityKind ) {
if ( strcmp(ref->getTarget().getSectionName(), "__nl_symbol_ptr") == 0 )
return &ref->getTarget();
if ( strcmp(ref->getTarget().getSectionName(), "__pointers") == 0 )
return &ref->getTarget();
}
}
return NULL;
}
void BaseAtom::setCompactUnwindEncoding(uint64_t ehAtomAddress)
{
fSingleUnwindInfo[0].unwindInfo = this->getCompactUnwindEncoding(ehAtomAddress);
fHasCompactUnwindInfo = true;
}
class BaseAtomSorter
{
public:
bool operator()(const class BaseAtom* left, const class BaseAtom* right) {
if ( left == right )
return false;
uint64_t leftAddr = left->getObjectAddress();
uint64_t rightAddr = right->getObjectAddress();
if ( leftAddr < rightAddr ) {
return true;
}
else if ( leftAddr > rightAddr ) {
return false;
}
else {
// if they have same address, one might be the end of a section and the other the start of the next section
const void* leftSection = left->getSectionRecord();
const void* rightSection = right->getSectionRecord();
if ( leftSection != rightSection ) {
return ( leftSection < rightSection );
}
// if they have same address and section, one might be an alias
bool leftAlias = left->isAlias();
bool rightAlias = right->isAlias();
if ( leftAlias && rightAlias ) {
// sort multiple aliases for same address first by scope
ObjectFile::Atom::Scope leftScope = left->getScope();
ObjectFile::Atom::Scope rightScope = right->getScope();
if ( leftScope != rightScope ) {
return ( leftScope < rightScope );
}
// sort multiple aliases for same address then by name
return ( strcmp(left->getName(), right->getName()) < 0 );
}
else if ( leftAlias ) {
return true;
}
else if ( rightAlias ) {
return false;
}
// one might be a section start or end label
switch ( left->getContentType() ) {
case ObjectFile::Atom::kSectionStart:
return true;
case ObjectFile::Atom::kSectionEnd:
return false;
default:
break;
}
switch ( right->getContentType() ) {
case ObjectFile::Atom::kSectionStart:
return false;
case ObjectFile::Atom::kSectionEnd:
return true;
default:
break;
}
// they could be tentative defintions
switch ( left->getDefinitionKind() ) {
case ObjectFile::Atom::kTentativeDefinition:
// sort tentative definitions by name
return ( strcmp(left->getName(), right->getName()) < 0 );
case ObjectFile::Atom::kAbsoluteSymbol:
// sort absolute symbols with same address by name
return ( strcmp(left->getName(), right->getName()) < 0 );
default:
// hack for rdar://problem/5102873
if ( !left->isZeroFill() || !right->isZeroFill() )
warning("atom sorting error for %s and %s in %s", left->getDisplayName(), right->getDisplayName(), left->getFile()->getPath());
break;
}
}
return false;
}
};
//
// A SymbolAtom represents a chunk of a mach-o object file that has a symbol table entry
// pointing to it. A C function or global variable is represented by one of these atoms.
//
//
template <typename A>
class SymbolAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return &fOwner; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const
{ return fOwner.getTranslationUnitSource(dir, name); }
virtual const char* getName() const { return &fOwner.fStrings[fSymbol->n_strx()]; }
virtual const char* getDisplayName() const { return getName(); }
virtual ObjectFile::Atom::Scope getScope() const { return fScope; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return ((fSymbol->n_desc() & N_WEAK_DEF) != 0)
? ObjectFile::Atom::kWeakDefinition : ObjectFile::Atom::kRegularDefinition; }
virtual ObjectFile::Atom::ContentType getContentType() const { return fType; }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return fSymbolTableInclusion; }
virtual bool dontDeadStrip() const;
virtual bool isZeroFill() const;
virtual bool isThumb() const { return ((fSymbol->n_desc() & N_ARM_THUMB_DEF) != 0); }
virtual uint64_t getSize() const { return fSize; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const;
virtual Segment<A>& getSegment() const { return *fSegment; }
virtual ObjectFile::Atom& getFollowOnAtom() const;
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return (std::vector<ObjectFile::LineInfo>*)&fLineInfo; }
virtual ObjectFile::Alignment getAlignment() const { return fAlignment; }
virtual void copyRawContent(uint8_t buffer[]) const;
virtual void setScope(ObjectFile::Atom::Scope newScope) { fScope = newScope; }
virtual void setSize(uint64_t size);
virtual void addReference(ObjectFile::Reference* ref) { fReferences.push_back((Reference<A>*)ref); }
virtual void sortReferences() { std::sort(fReferences.begin(), fReferences.end(), ReferenceSorter()); }
virtual void addLineInfo(const ObjectFile::LineInfo& info) { fLineInfo.push_back(info); }
virtual const ObjectFile::ReaderOptions& getOptions() const { return fOwner.fOptions; }
virtual uint64_t getObjectAddress() const { return fAddress; }
virtual const void* getSectionRecord() const { return (const void*)fSection; }
virtual unsigned int getSectionIndex() const { return 1 + (fSection - fOwner.fSectionsStart); }
virtual uint8_t getLSDAReferenceKind() const;
virtual uint8_t getPersonalityReferenceKind() const;
virtual uint32_t getCompactUnwindEncoding(uint64_t ehAtomAddress);
protected:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
typedef typename std::vector<Reference<A>*> ReferenceVector;
typedef typename ReferenceVector::iterator ReferenceVectorIterator; // seems to help C++ parser
typedef typename ReferenceVector::const_iterator ReferenceVectorConstIterator; // seems to help C++ parser
friend class Reader<A>;
SymbolAtom(Reader<A>&, const macho_nlist<P>*, const macho_section<P>*);
virtual ~SymbolAtom() {}
Reader<A>& fOwner;
const macho_nlist<P>* fSymbol;
pint_t fAddress;
pint_t fSize;
const macho_section<P>* fSection;
Segment<A>* fSegment;
ReferenceVector fReferences;
std::vector<ObjectFile::LineInfo> fLineInfo;
ObjectFile::Atom::Scope fScope;
SymbolTableInclusion fSymbolTableInclusion;
ObjectFile::Atom::ContentType fType;
ObjectFile::Alignment fAlignment;
};
template <typename A>
SymbolAtom<A>::SymbolAtom(Reader<A>& owner, const macho_nlist<P>* symbol, const macho_section<P>* section)
: fOwner(owner), fSymbol(symbol), fAddress(0), fSize(0), fSection(section), fSegment(NULL), fType(ObjectFile::Atom::kUnclassifiedType), fAlignment(0)
{
fSingleUnwindInfo[0].startOffset = 0;
fSingleUnwindInfo[0].unwindInfo = 0;
uint8_t type = symbol->n_type();
if ( (type & N_EXT) == 0 )
fScope = ObjectFile::Atom::scopeTranslationUnit;
else if ( (type & N_PEXT) != 0 )
fScope = ObjectFile::Atom::scopeLinkageUnit;
else
fScope = ObjectFile::Atom::scopeGlobal;
if ( (type & N_TYPE) == N_SECT ) {
// real definition
fSegment = new Segment<A>(fSection);
fAddress = fSymbol->n_value();
pint_t sectionStartAddr = section->addr();
pint_t sectionEndAddr = section->addr()+section->size();
if ( (fAddress < sectionStartAddr) || (fAddress > (sectionEndAddr)) ) {
throwf("malformed .o file, symbol %s with address 0x%0llX is not with section %d (%s,%s) address range of 0x%0llX to 0x%0llX",
this->getName(), (uint64_t)fAddress, fSymbol->n_sect(), section->segname(), section->sectname(),
(uint64_t)sectionStartAddr, (uint64_t)(sectionEndAddr) );
}
}
else {
warning("unknown symbol type: %d", type);
}
//fprintf(stderr, "SymbolAtom(%p) %s fAddress=0x%X\n", this, this->getDisplayName(), (uint32_t)fAddress);
// support for .o files built with old ld64
if ( (fSymbol->n_desc() & N_WEAK_DEF) && (strcmp(fSection->sectname(),"__picsymbolstub1__TEXT") == 0) ) {
const char* name = this->getName();
const int nameLen = strlen(name);
if ( (nameLen > 6) && strcmp(&name[nameLen-5], "$stub") == 0 ) {
// switch symbol to point at name that does not have trailing $stub
char correctName[nameLen];
strncpy(correctName, name, nameLen-5);
correctName[nameLen-5] = '\0';
const macho_nlist<P>* symbolsStart = fOwner.fSymbols;
const macho_nlist<P>* symbolsEnd = &symbolsStart[fOwner.fSymbolCount];
for(const macho_nlist<P>* s = symbolsStart; s < symbolsEnd; ++s) {
if ( strcmp(&fOwner.fStrings[s->n_strx()], correctName) == 0 ) {
fSymbol = s;
break;
}
}
}
}
// support for labeled stubs
switch ( section->flags() & SECTION_TYPE ) {
case S_SYMBOL_STUBS:
setSize(section->reserved2());
break;
case S_LAZY_SYMBOL_POINTERS:
case S_NON_LAZY_SYMBOL_POINTERS:
setSize(sizeof(pint_t));
break;
case S_4BYTE_LITERALS:
setSize(4);
break;
case S_8BYTE_LITERALS:
setSize(8);
break;
case S_16BYTE_LITERALS:
setSize(16);
break;
case S_CSTRING_LITERALS:
setSize(strlen((char*)(fOwner.fHeader) + section->offset() + fAddress - section->addr()) + 1);
fType = ObjectFile::Atom::kCStringType;
break;
case S_REGULAR:
case S_ZEROFILL:
case S_COALESCED:
// size calculate later after next atom is found
break;
}
// compute alignment
fAlignment = ObjectFile::Alignment(fSection->align(), fAddress % (1 << fSection->align()));
// compute whether this atom needs to be in symbol table
if ( (fSymbol->n_desc() & REFERENCED_DYNAMICALLY) != 0) {
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableInAndNeverStrip;
}
else if ( fOwner.fOptions.fForFinalLinkedImage && !fOwner.fOptions.fForStatic && (fOwner.fStrings[fSymbol->n_strx()] == 'l') ) {
// labels beginning with a lowercase ell are automatically removed in final linked images <rdar://problem/4571042>
// xnu code base uses a lot of asesembly labels that start with 'l', don't strip those (static executable)
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableNotIn;
}
else {
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableIn;
}
// work around malformed icc generated .o files <rdar://problem/5349847>
// if section starts with a symbol and that symbol address does not match section alignment, then force it to
if ( (section->addr() == fAddress) && (fAlignment.modulus != 0) )
fAlignment.modulus = 0;
}
template <typename A>
bool SymbolAtom<A>::dontDeadStrip() const
{
// the symbol can have a no-dead-strip bit
if ( (fSymbol->n_desc() & (N_NO_DEAD_STRIP|REFERENCED_DYNAMICALLY)) != 0 )
return true;
// or the section can have a no-dead-strip bit
return ( fSection->flags() & S_ATTR_NO_DEAD_STRIP );
}
template <typename A>
const char* SymbolAtom<A>::getSectionName() const
{
if ( fOwner.fOptions.fForFinalLinkedImage ) {
if ( strcmp(fSection->sectname(), "__textcoal_nt") == 0 )
return "__text";
else if ( strcmp(fSection->sectname(), "__const_coal") == 0 )
return "__const";
else if ( strcmp(fSection->sectname(), "__datacoal_nt") == 0 )
return "__data";
else if ( fOwner.fOptions.fAutoOrderInitializers && (strcmp(fSection->sectname(), "__StaticInit") == 0) )
return "__text";
else {
switch ( fSection->flags() & SECTION_TYPE ) {
case S_4BYTE_LITERALS:
case S_8BYTE_LITERALS:
case S_16BYTE_LITERALS:
return "__const";
}
}
}
if ( strlen(fSection->sectname()) > 15 ) {
static char temp[18];
strncpy(temp, fSection->sectname(), 16);
temp[17] = '\0';
return temp;
}
return fSection->sectname();
}
template <typename A>
ObjectFile::Atom& SymbolAtom<A>::getFollowOnAtom() const
{
for (ReferenceVectorConstIterator it=fReferences.begin(); it != fReferences.end(); it++) {
Reference<A>* ref = *it;
if ( ref->getKind() == A::kFollowOn )
return ref->getTarget();
}
return *((ObjectFile::Atom*)NULL);
}
template <typename A>
bool SymbolAtom<A>::isZeroFill() const
{
return ( ((fSection->flags() & SECTION_TYPE) == S_ZEROFILL) && fOwner.fOptions.fOptimizeZeroFill );
}
class Beyond
{
public:
Beyond(uint64_t offset) : fOffset(offset) {}
bool operator()(ObjectFile::Reference* ref) const {
return ( ref->getFixUpOffset() >= fOffset );
}
private:
uint64_t fOffset;
};
template <typename A>
void SymbolAtom<A>::setSize(uint64_t size)
{
// when resizing, any references beyond the new size are tossed
if ( (fSize != 0) && (fReferences.size() > 0) )
fReferences.erase(std::remove_if(fReferences.begin(), fReferences.end(), Beyond(size)), fReferences.end());
// set new size
fSize = size;
}
template <typename A>
void SymbolAtom<A>::copyRawContent(uint8_t buffer[]) const
{
// copy base bytes
if ( isZeroFill() )
bzero(buffer, fSize);
else {
uint32_t fileOffset = fSection->offset() - fSection->addr() + fAddress;
memcpy(buffer, (char*)(fOwner.fHeader)+fileOffset, fSize);
}
}
//
// A SymbolAliasAtom represents an alternate name for a SymbolAtom
//
//
template <typename A>
class SymbolAliasAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return fAliasOf.getFile(); }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const
{ return fAliasOf.getTranslationUnitSource(dir, name); }
virtual const char* getName() const { return fName; }
virtual const char* getDisplayName() const { return fName; }
virtual ObjectFile::Atom::Scope getScope() const { return fScope; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return fAliasOf.getDefinitionKind(); }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return fAliasOf.getSymbolTableInclusion(); }
virtual bool dontDeadStrip() const { return fDontDeadStrip; }
virtual bool isZeroFill() const { return fAliasOf.isZeroFill(); }
virtual bool isThumb() const { return fAliasOf.isThumb(); }
virtual uint64_t getSize() const { return 0; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const { return fAliasOf.getSectionName(); }
virtual Segment<A>& getSegment() const { return (Segment<A>&)fAliasOf.getSegment(); }
virtual ObjectFile::Atom& getFollowOnAtom() const { return (ObjectFile::Atom&)fAliasOf; }
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const { return fAliasOf.getAlignment(); }
virtual void copyRawContent(uint8_t buffer[]) const {}
virtual void setScope(ObjectFile::Atom::Scope newScope) { fScope = newScope; }
virtual void setSize(uint64_t size) { }
virtual void addReference(ObjectFile::Reference* ref) { fReferences.push_back((Reference<A>*)ref); }
virtual void sortReferences() { std::sort(fReferences.begin(), fReferences.end(), ReferenceSorter()); }
virtual void addLineInfo(const ObjectFile::LineInfo& info) { }
virtual const ObjectFile::ReaderOptions& getOptions() const { return fAliasOf.getOptions(); }
virtual uint64_t getObjectAddress() const { return fAliasOf.getObjectAddress(); }
virtual const void* getSectionRecord() const { return fAliasOf.getSectionRecord(); }
virtual unsigned int getSectionIndex() const { return fAliasOf.getSectionIndex(); }
virtual bool isAlias() const { return true; }
protected:
typedef typename A::P P;
typedef typename std::vector<Reference<A>*> ReferenceVector;
typedef typename ReferenceVector::iterator ReferenceVectorIterator; // seems to help C++ parser
typedef typename ReferenceVector::const_iterator ReferenceVectorConstIterator; // seems to help C++ parser
friend class Reader<A>;
SymbolAliasAtom(const char* name, const macho_nlist<P>*, const BaseAtom& );
virtual ~SymbolAliasAtom() {}
const char* fName;
const BaseAtom& fAliasOf;
ObjectFile::Atom::Scope fScope;
bool fDontDeadStrip;
ReferenceVector fReferences;
};
template <typename A>
SymbolAliasAtom<A>::SymbolAliasAtom(const char* name, const macho_nlist<P>* symbol, const BaseAtom& aliasOf)
: fName(name), fAliasOf(aliasOf)
{
//fprintf(stderr, "SymbolAliasAtom(%p) %s\n", this, name);
if ( symbol != NULL ) {
uint8_t type = symbol->n_type();
if ( (type & N_EXT) == 0 )
fScope = ObjectFile::Atom::scopeTranslationUnit;
else if ( (type & N_PEXT) != 0 )
fScope = ObjectFile::Atom::scopeLinkageUnit;
else
fScope = ObjectFile::Atom::scopeGlobal;
fDontDeadStrip = ((symbol->n_desc() & (N_NO_DEAD_STRIP|REFERENCED_DYNAMICALLY)) != 0);
}
else {
// aliases defined on the command line are initially global scope
fScope = ObjectFile::Atom::scopeGlobal;
fDontDeadStrip = false;
}
// add follow-on reference to real atom
new Reference<A>(A::kFollowOn, AtomAndOffset(this), AtomAndOffset((ObjectFile::Atom*)&aliasOf));
}
//
// A TentativeAtom represents a C "common" or "tentative" defintion of data.
// For instance, "int foo;" is neither a declaration or a definition and
// is represented by a TentativeAtom.
//
template <typename A>
class TentativeAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return &fOwner; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const
{ return fOwner.getTranslationUnitSource(dir, name); }
virtual const char* getName() const { return &fOwner.fStrings[fSymbol->n_strx()]; }
virtual const char* getDisplayName() const { return getName(); }
virtual ObjectFile::Atom::Scope getScope() const { return fScope; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return ObjectFile::Atom::kTentativeDefinition; }
virtual bool isZeroFill() const { return fOwner.fOptions.fOptimizeZeroFill; }
virtual bool isThumb() const { return false; }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return ((fSymbol->n_desc() & REFERENCED_DYNAMICALLY) != 0)
? ObjectFile::Atom::kSymbolTableInAndNeverStrip : ObjectFile::Atom::kSymbolTableIn; }
virtual bool dontDeadStrip() const { return ((fSymbol->n_desc() & (N_NO_DEAD_STRIP|REFERENCED_DYNAMICALLY)) != 0); }
virtual uint64_t getSize() const { return fSymbol->n_value(); }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return fgNoReferences; }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const;
virtual ObjectFile::Segment& getSegment() const { return DataSegment::fgSingleton; }
virtual ObjectFile::Atom& getFollowOnAtom() const { return *(ObjectFile::Atom*)NULL; }
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const;
virtual void copyRawContent(uint8_t buffer[]) const;
virtual void setScope(ObjectFile::Atom::Scope newScope) { fScope = newScope; }
virtual void setSize(uint64_t size) { }
virtual void addReference(ObjectFile::Reference* ref) { throw "ld: can't add references"; }
virtual void sortReferences() { }
virtual void addLineInfo(const ObjectFile::LineInfo& info) { throw "ld: can't add line info to tentative definition"; }
virtual const ObjectFile::ReaderOptions& getOptions() const { return fOwner.fOptions; }
virtual uint64_t getObjectAddress() const { return ULLONG_MAX; }
virtual const void* getSectionRecord() const { return NULL; }
virtual unsigned int getSectionIndex() const { return 0; }
protected:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
friend class Reader<A>;
TentativeAtom(Reader<A>&, const macho_nlist<P>*);
virtual ~TentativeAtom() {}
Reader<A>& fOwner;
const macho_nlist<P>* fSymbol;
ObjectFile::Atom::Scope fScope;
static std::vector<ObjectFile::Reference*> fgNoReferences;
};
template <typename A>
std::vector<ObjectFile::Reference*> TentativeAtom<A>::fgNoReferences;
template <typename A>
TentativeAtom<A>::TentativeAtom(Reader<A>& owner, const macho_nlist<P>* symbol)
: fOwner(owner), fSymbol(symbol)
{
uint8_t type = symbol->n_type();
if ( (type & N_EXT) == 0 )
fScope = ObjectFile::Atom::scopeTranslationUnit;
else if ( (type & N_PEXT) != 0 )
fScope = ObjectFile::Atom::scopeLinkageUnit;
else
fScope = ObjectFile::Atom::scopeGlobal;
if ( ((type & N_TYPE) == N_UNDF) && (symbol->n_value() != 0) ) {
// tentative definition
}
else {
warning("unknown symbol type: %d", type);
}
//fprintf(stderr, "TentativeAtom(%p) %s\n", this, this->getDisplayName());
}
template <typename A>
ObjectFile::Alignment TentativeAtom<A>::getAlignment() const
{
uint8_t alignment = GET_COMM_ALIGN(fSymbol->n_desc());
if ( alignment == 0 ) {
// common symbols align to their size
// that is, a 4-byte common aligns to 4-bytes
// if this size is not a power of two,
// then round up to the next power of two
uint64_t size = this->getSize();
alignment = 63 - (uint8_t)__builtin_clzll(size);
if ( size != (1ULL << alignment) )
++alignment;
}
// limit alignment of extremely large commons to 2^15 bytes (8-page)
if ( alignment < 12 )
return ObjectFile::Alignment(alignment);
else
return ObjectFile::Alignment(12);
}
template <typename A>
const char* TentativeAtom<A>::getSectionName() const
{
if ( fOwner.fOptions.fForFinalLinkedImage || fOwner.fOptions.fMakeTentativeDefinitionsReal )
return "__common";
else
return "._tentdef";
}
template <typename A>
void TentativeAtom<A>::copyRawContent(uint8_t buffer[]) const
{
bzero(buffer, getSize());
}
//
// An AnonymousAtom represents compiler generated data that has no name.
// For instance, a literal C-string or a 64-bit floating point constant
// is represented by an AnonymousAtom.
//
template <typename A>
class AnonymousAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return &fOwner; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const { return false; }
virtual const char* getName() const { return fSynthesizedName; }
virtual const char* getDisplayName() const;
virtual ObjectFile::Atom::Scope getScope() const;
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return fKind; }
virtual ObjectFile::Atom::ContentType getContentType() const { return fType; }
virtual ObjectFile::Atom::SymbolTableInclusion getSymbolTableInclusion() const { return fSymbolTableInclusion; }
virtual bool dontDeadStrip() const { return fDontDeadStrip; }
virtual bool isZeroFill() const;
virtual bool isThumb() const { return false; }
virtual uint64_t getSize() const { return fSize; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return (std::vector<ObjectFile::Reference*>&)(fReferences); }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const;
virtual Segment<A>& getSegment() const { return *fSegment; }
virtual ObjectFile::Atom& getFollowOnAtom() const;
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const;
virtual void copyRawContent(uint8_t buffer[]) const;
virtual void setScope(ObjectFile::Atom::Scope newScope) { fScope = newScope; }
virtual void setSize(uint64_t size) { fSize = size; }
virtual void addReference(ObjectFile::Reference* ref) { fReferences.push_back((Reference<A>*)ref); }
virtual void sortReferences() { std::sort(fReferences.begin(), fReferences.end(), ReferenceSorter()); }
virtual void addLineInfo(const ObjectFile::LineInfo& info);
virtual const ObjectFile::ReaderOptions& getOptions() const { return fOwner.fOptions; }
virtual uint64_t getObjectAddress() const { return fAddress; }
virtual const void* getSectionRecord() const { return (const void*)fSection; }
virtual unsigned int getSectionIndex() const { return fSectionIndex; }
BaseAtom* redirectTo() { return fRedirect; }
bool isWeakImportStub() { return fWeakImportStub; }
void resolveName();
virtual uint8_t getLSDAReferenceKind() const;
virtual uint8_t getPersonalityReferenceKind() const;
virtual uint32_t getCompactUnwindEncoding(uint64_t ehAtomAddress);
protected:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
typedef typename std::vector<Reference<A>*> ReferenceVector;
typedef typename ReferenceVector::iterator ReferenceVectorIterator; // seems to help C++ parser
typedef typename ReferenceVector::const_iterator ReferenceVectorConstIterator; // seems to help C++ parser
friend class Reader<A>;
AnonymousAtom(Reader<A>&, const macho_section<P>*, pint_t addr, pint_t size);
virtual ~AnonymousAtom() {}
static bool cstringsHaveLabels();
Reader<A>& fOwner;
const char* fSynthesizedName;
const char* fDisplayName;
const macho_section<P>* fSection;
pint_t fAddress;
pint_t fSize;
Segment<A>* fSegment;
ReferenceVector fReferences;
BaseAtom* fRedirect;
bool fDontDeadStrip;
bool fWeakImportStub;
ObjectFile::Atom::SymbolTableInclusion fSymbolTableInclusion;
ObjectFile::Atom::Scope fScope;
ObjectFile::Atom::DefinitionKind fKind;
ObjectFile::Atom::ContentType fType;
unsigned int fSectionIndex;
};
template <typename A>
AnonymousAtom<A>::AnonymousAtom(Reader<A>& owner, const macho_section<P>* section, pint_t addr, pint_t size)
: fOwner(owner), fSynthesizedName(NULL), fDisplayName(NULL), fSection(section), fAddress(addr), fSize(size),
fSegment(NULL), fDontDeadStrip(true), fWeakImportStub(false), fSymbolTableInclusion(ObjectFile::Atom::kSymbolTableNotIn),
fScope(ObjectFile::Atom::scopeTranslationUnit), fKind(ObjectFile::Atom::kRegularDefinition),
fType(ObjectFile::Atom::kUnclassifiedType), fSectionIndex(1 + (section - owner.fSectionsStart))
{
fSegment = new Segment<A>(fSection);
fRedirect = this;
uint8_t type = fSection->flags() & SECTION_TYPE;
//fprintf(stderr, "AnonymousAtom(%p) addr=0x%llX in %s from %s\n", this, (long long)addr, section->sectname(), owner.getPath());
switch ( type ) {
case S_ZEROFILL:
{
asprintf((char**)&fSynthesizedName, "zero-fill-at-0x%08X", addr);
}
break;
case S_COALESCED:
case S_REGULAR:
if ( section == owner.fehFrameSection ) {
if ( fSize == 1 ) {
// is CIE
fSize = 0;
fDontDeadStrip = false;
if ( fOwner.fOptions.fForFinalLinkedImage )
fSynthesizedName = "CIE";
else
fSynthesizedName = "EH_frame1";
}
else {
// is FDE
fSynthesizedName = ".eh_PENDING";
fDontDeadStrip = false;
owner.fAtomsPendingAName.push_back(this);
}
fType = ObjectFile::Atom::kCFIType;
// FDEs and CIEs don't need to be in symbol table of final linked images <rdar://problem/4180168>
if ( !fOwner.fOptions.fNoEHLabels )
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableIn;
}
else if ( (strcmp(section->sectname(), "__class") == 0) && (strcmp(section->segname(), "__OBJC") == 0) && owner.fAppleObjc ) {
// special case ObjC classes to synthesize .objc_class_name_* symbols, for Apple runtime only
fSynthesizedName = ".objc_class_name_PENDING";
owner.fAtomsPendingAName.push_back(this);
owner.fSectionsWithAtomsPendingAName.insert(fSection);
if ( fOwner.fOptions.fForFinalLinkedImage )
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableIn;
else
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableInAsAbsolute;
fScope = ObjectFile::Atom::scopeGlobal;
}
else if ( strcmp(fSection->sectname(), "__cstring") == 0 ) {
// handle .o files created by old ld64 -r that are missing cstring section type
const char* str = (char*)(owner.fHeader) + section->offset() + addr - section->addr();
asprintf((char**)&fSynthesizedName, "cstring=%s", str);
}
else if ((strcmp(section->sectname(), "__cfstring") == 0) && (strcmp(section->segname(), "__DATA") == 0)) {
fSynthesizedName = "cfstring-pointer-name-PENDING";
fScope = ObjectFile::Atom::scopeLinkageUnit;
owner.fAtomsPendingAName.push_back(this);
owner.fSectionsWithAtomsPendingAName.insert(fSection);
fDontDeadStrip = false;
fKind = ObjectFile::Atom::kWeakDefinition;
}
else if ( (fSection->flags() & S_ATTR_SOME_INSTRUCTIONS) != 0 ) {
fDontDeadStrip = false;
asprintf((char**)&fSynthesizedName, "anon-func-0x%X", addr);
}
else if ( strncmp(fSection->sectname(), "__gcc_except_tab",16) == 0 ) {
fType = ObjectFile::Atom::kLSDAType;
fDontDeadStrip = false;
fSynthesizedName = ".lsda_PENDING";
owner.fAtomsPendingAName.push_back(this);
if ( !fOwner.fOptions.fNoEHLabels )
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableIn;
}
else if ( section == owner.fUTF16Section ) {
if ( fOwner.fOptions.fForFinalLinkedImage ) {
fDontDeadStrip = false;
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
char* name = new char[16+5*size];
strcpy(name, "utf16-string=");
char* s = &name[13];
const uint16_t* words = (uint16_t*)((char*)(owner.fHeader) + section->offset() + addr - section->addr());
unsigned int wordCount = size/2;
// note, the compiler sometimes puts trailing zeros on the end of the data
if ( E::get32(words[wordCount-1]) == 0 )
--wordCount;
bool needSeperator = false;
for(unsigned int i=0; i < wordCount; ++i) {
if ( needSeperator )
strcpy(s++, ".");
sprintf(s, "%04X", E::get32(words[i]));
s += 4;
needSeperator = true;
}
fSynthesizedName = name;
}
else {
asprintf((char**)&fSynthesizedName, "lutf16-0x%X", addr);
}
}
break;
case S_CSTRING_LITERALS:
{
const char* str = (char*)(owner.fHeader) + section->offset() + addr - section->addr();
if ( (strcmp(fSection->sectname(), "__cstring") == 0) && (strcmp(section->segname(), "__TEXT") == 0) )
asprintf((char**)&fSynthesizedName, "cstring=%s", str);
else
asprintf((char**)&fSynthesizedName, "cstring%s%s=%s", fSection->segname(), fSection->sectname(), str);
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
fType = ObjectFile::Atom::kCStringType;
fDontDeadStrip = false;
if ( !fOwner.fOptions.fForFinalLinkedImage && cstringsHaveLabels() )
fSymbolTableInclusion = ObjectFile::Atom::kSymbolTableIn;
}
break;
case S_4BYTE_LITERALS:
{
uint32_t value = E::get32(*(uint32_t*)(((uint8_t*)owner.fHeader) + section->offset() + addr - section->addr()));
asprintf((char**)&fSynthesizedName, "4-byte-literal=0x%08X", value);
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
fDontDeadStrip = false;
}
break;
case S_8BYTE_LITERALS:
{
uint64_t value = E::get64(*(uint64_t*)(((uint8_t*)owner.fHeader) + section->offset() + addr - section->addr()));
asprintf((char**)&fSynthesizedName, "8-byte-literal=0x%016llX", value);
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
fDontDeadStrip = false;
}
break;
case S_16BYTE_LITERALS:
{
uint64_t value1 = E::get64(*(uint64_t*)(((uint8_t*)owner.fHeader) + section->offset() + addr - section->addr()));
uint64_t value2 = E::get64(*(uint64_t*)(((uint8_t*)owner.fHeader) + section->offset() + addr + 8 - section->addr()));
asprintf((char**)&fSynthesizedName, "16-byte-literal=0x%016llX,%016llX", value1, value2);
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
fDontDeadStrip = false;
}
break;
case S_LITERAL_POINTERS:
{
//uint32_t literalNameAddr = P::getP(*(pint_t*)(((uint8_t*)owner.fHeader) + section->offset() + addr - section->addr()));
//const char* str = (char*)(owner.fHeader) + section->offset() + literalNameAddr - section->addr();
//asprintf((char**)&fSynthesizedName, "literal-pointer@%s@%s@%s", section->segname(), section->sectname(), str);
fSynthesizedName = "literal-pointer-name-PENDING";
fScope = ObjectFile::Atom::scopeLinkageUnit;
fKind = ObjectFile::Atom::kWeakDefinition;
fDontDeadStrip = false;
owner.fAtomsPendingAName.push_back(this);
owner.fSectionsWithAtomsPendingAName.insert(fSection);
}
break;
case S_MOD_INIT_FUNC_POINTERS:
asprintf((char**)&fSynthesizedName, "initializer$%d", (addr - (uint32_t)fSection->addr())/sizeof(pint_t));
break;
case S_MOD_TERM_FUNC_POINTERS:
asprintf((char**)&fSynthesizedName, "terminator$%d", (addr - (uint32_t)fSection->addr())/sizeof(pint_t));
break;
case S_SYMBOL_STUBS:
{
uint32_t index = (fAddress - fSection->addr()) / fSection->reserved2();
index += fSection->reserved1();
uint32_t symbolIndex = E::get32(fOwner.fIndirectTable[index]);
const macho_nlist<P>* sym = &fOwner.fSymbols[symbolIndex];
uint32_t strOffset = sym->n_strx();
// want name to not have $stub suffix, this is what automatic stub generation expects
fSynthesizedName = &fOwner.fStrings[strOffset];
// check for weak import
fWeakImportStub = fOwner.isWeakImportSymbol(sym);
// sometimes the compiler gets confused and generates a stub to a static function
// if so, we should redirect any call to the stub to be calls to the real static function atom
if ( ((sym->n_type() & N_TYPE) != N_UNDF) && ((sym->n_type() & N_EXT) == 0) ) {
BaseAtom* staticAtom = fOwner.findAtomByName(fSynthesizedName);
if ( staticAtom != NULL )
fRedirect = staticAtom;
}
fKind = ObjectFile::Atom::kWeakDefinition;
// might be a spurious stub for a static function, make stub static too
if ( (sym->n_type() & N_EXT) == 0 )
fScope = ObjectFile::Atom::scopeTranslationUnit;
else
fScope = ObjectFile::Atom::scopeLinkageUnit;
}
break;
case S_LAZY_SYMBOL_POINTERS:
case S_NON_LAZY_SYMBOL_POINTERS:
{
// transform i386 __IMPORT/__pointers to __DATA/__nl_symbol_ptr when
// generating the new compressed LINKEDIT format
if ( (type == S_NON_LAZY_SYMBOL_POINTERS) && fOwner.fOptions.fMakeCompressedDyldInfo && (strcmp(fSection->segname(),"__IMPORT") == 0) ) {
macho_section<P>* dummySection = new macho_section<P>(*fSection);
dummySection->set_segname("__DATA");
dummySection->set_sectname("__nl_symbol_ptr");
fSection = dummySection;
fSegment = new Segment<A>(fSection);
}
fDontDeadStrip = false;
fScope = ObjectFile::Atom::scopeLinkageUnit;
uint32_t index = (fAddress - fSection->addr()) / sizeof(pint_t);
index += fSection->reserved1();
uint32_t symbolIndex = E::get32(fOwner.fIndirectTable[index]);
if ( symbolIndex == INDIRECT_SYMBOL_LOCAL ) {
// Silly codegen with non-lazy pointer to a local symbol
uint32_t fileOffset = fSection->offset() - fSection->addr() + fAddress;
pint_t nonLazyPtrValue = P::getP(*((pint_t*)((char*)(fOwner.fHeader)+fileOffset)));
// All atoms not created yet, so we need to scan symbol table
const macho_nlist<P>* closestSym = NULL;
const macho_nlist<P>* end = &fOwner.fSymbols[fOwner.fSymbolCount];
for (const macho_nlist<P>* sym = fOwner.fSymbols; sym < end; ++sym) {
if ( ((sym->n_type() & N_TYPE) == N_SECT)
&& ((sym->n_type() & N_STAB) == 0) ) {
if ( sym->n_value() == nonLazyPtrValue ) {
const char* name = &fOwner.fStrings[sym->n_strx()];
char* str = new char[strlen(name)+16];
strcpy(str, name);
strcat(str, "$non_lazy_ptr");
fSynthesizedName = str;
// add direct reference to target later, because its atom may not be constructed yet
fOwner.fLocalNonLazys.push_back(this);
fScope = ObjectFile::Atom::scopeTranslationUnit;
fType = ObjectFile::Atom::kNonLazyPointer;
return;
}
else if ( (sym->n_value() < nonLazyPtrValue) && ((closestSym == NULL) || (sym->n_value() > closestSym->n_value())) ) {
closestSym = sym;
}
}
}
// add direct reference to target later, because its atom may not be constructed yet
if ( closestSym != NULL ) {
const char* name = &fOwner.fStrings[closestSym->n_strx()];
char* str;
asprintf(&str, "%s+%u$non_lazy_ptr", name, nonLazyPtrValue - closestSym->n_value());
fSynthesizedName = str;
}
else {
fSynthesizedName = "$interior$non_lazy_ptr";
}
fScope = ObjectFile::Atom::scopeTranslationUnit;
fOwner.fLocalNonLazys.push_back(this);
fType = ObjectFile::Atom::kNonLazyPointer;
return;
}
const macho_nlist<P>* targetSymbol = &fOwner.fSymbols[symbolIndex];
const char* name = &fOwner.fStrings[targetSymbol->n_strx()];
char* str = new char[strlen(name)+16];
strcpy(str, name);
if ( type == S_LAZY_SYMBOL_POINTERS ) {
strcat(str, "$lazy_ptr");
fType = ObjectFile::Atom::kLazyPointer;
}
else {
strcat(str, "$non_lazy_ptr");
fType = ObjectFile::Atom::kNonLazyPointer;
}
fSynthesizedName = str;
if ( type == S_NON_LAZY_SYMBOL_POINTERS )
fKind = ObjectFile::Atom::kWeakDefinition;
if ( (targetSymbol->n_type() & N_EXT) == 0 ) {
// target is translation unit scoped, so add direct reference to target
//fOwner.makeReference(A::kPointer, addr, targetSymbol->n_value());
new Reference<A>(A::kPointer, AtomAndOffset(this), fOwner.findAtomAndOffset(targetSymbol->n_value()));
}
else {
if ( fOwner.isWeakImportSymbol(targetSymbol) )
new Reference<A>(A::kPointerWeakImport, AtomAndOffset(this), name, 0);
else
new Reference<A>(A::kPointer, AtomAndOffset(this), name, 0);
}
}
break;
default:
throwf("section type %d not supported with address=0x%08llX", type, (uint64_t)addr);
}
//fprintf(stderr, "AnonymousAtom(%p) %s \n", this, this->getDisplayName());
}
// x86_64 uses L labels on cstrings to allow relocs with addends
template <> bool AnonymousAtom<x86_64>::cstringsHaveLabels() { return true; }
template <typename A> bool AnonymousAtom<A>::cstringsHaveLabels() { return false; }
template <typename A>
void AnonymousAtom<A>::addLineInfo(const ObjectFile::LineInfo& info)
{
// <rdar://problem/6545406> don't warn if line table has entries for stubs
if ( (fSection->flags() & SECTION_TYPE) != S_SYMBOL_STUBS )
warning("can't add line info to anonymous symbol %s from %s", this->getDisplayName(), this->getFile()->getPath());
}
template <typename A>
void AnonymousAtom<A>::resolveName()
{
if ( (strcmp(fSection->sectname(), "__class") == 0) && (strcmp(fSection->segname(), "__OBJC") == 0) ) {
std::vector<ObjectFile::Reference*>& references = this->getReferences();
// references are not yet sorted, so scan the vector
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
if ( ((*rit)->getFixUpOffset() == sizeof(pint_t)) && ((*rit)->getKind() == A::kPointer) ) {
const char* superStr = (*rit)->getTargetName();
if ( strncmp(superStr, "cstring", 7) == 0 ) {
const char* superClassName;
asprintf((char**)&superClassName, ".objc_class_name_%s", &superStr[8]);
new Reference<A>(A::kNoFixUp, AtomAndOffset(this), superClassName, 0);
}
break;
}
}
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
if ( ((*rit)->getFixUpOffset() == 2*sizeof(pint_t)) && ((*rit)->getKind() == A::kPointer) ) {
const char* classStr = (*rit)->getTargetName();
if ( strncmp(classStr, "cstring", 7) == 0 ) {
asprintf((char**)&fSynthesizedName, ".objc_class_name_%s", &classStr[8]);
}
break;
}
}
}
else if ( (fSection->flags() & SECTION_TYPE) == S_LITERAL_POINTERS) {
std::vector<ObjectFile::Reference*>& references = this->getReferences();
if ( references.size() < 1 )
throwf("S_LITERAL_POINTERS section %s,%s missing relocs", fSection->segname(), fSection->sectname());
ObjectFile::Reference* ref = references[0];
const char* str = ref->getTargetName();
if ( strncmp(str, "cstring", 7) == 0 ) {
asprintf((char**)&fSynthesizedName, "literal-pointer@%s@%s@%s", fSection->segname(), fSection->sectname(), &str[8]);
}
}
else if ( (strcmp(fSection->sectname(), "__cfstring") == 0) && (strcmp(fSection->segname(), "__DATA") == 0) ) {
// references are not yet sorted, so scan the vector
std::vector<ObjectFile::Reference*>& references = this->getReferences();
for (std::vector<ObjectFile::Reference*>::iterator rit=references.begin(); rit != references.end(); rit++) {
if ( ((*rit)->getFixUpOffset() == 2*sizeof(pint_t)) && ((*rit)->getKind() == A::kPointer) ) {
const char* superStr = (*rit)->getTargetName();
if ( (superStr != NULL) && (strncmp(superStr, "cstring=", 8) == 0) ) {
asprintf((char**)&fSynthesizedName, "cfstring=%s", &superStr[8]);
}
else if ( (superStr != NULL) && (strncmp(superStr, "utf16-string=", 13) == 0) ) {
asprintf((char**)&fSynthesizedName, "cfstring-utf16=%s", &superStr[13]);
}
else {
// compiled with -fwritable-strings or a non-ASCII string
fKind = ObjectFile::Atom::kRegularDefinition; // these are not coalescable
fScope = ObjectFile::Atom::scopeTranslationUnit;
fSynthesizedName = "cfstring-not-coalesable";
if ( (*rit)->getTargetOffset() != 0 )
warning("-fwritable-strings not compatible with literal CF/NSString in %s", fOwner.getPath());
}
break;
}
}
}
else if ( fSection == fOwner.fehFrameSection ) {
// give name to FDE
ObjectFile::Atom* funcAtom = fOwner.getFunctionAtomFromFDEAddress(fAddress);
if ( funcAtom != NULL )
asprintf((char**)&fSynthesizedName, "%s.eh", funcAtom->getDisplayName());
}
else if ( fOwner.fLSDAAtoms.count(this) != 0) {
// give name to LSDA
ObjectFile::Atom* funcAtom = fOwner.getFunctionAtomFromLSDAAddress(fAddress);
if ( funcAtom != NULL )
asprintf((char**)&fSynthesizedName, "%s.lsda", funcAtom->getDisplayName());
}
}
template <typename A>
const char* AnonymousAtom<A>::getDisplayName() const
{
if ( fSynthesizedName != NULL )
return fSynthesizedName;
if ( fDisplayName != NULL )
return fDisplayName;
if ( (fSection->flags() & SECTION_TYPE) == S_CSTRING_LITERALS ) {
uint32_t fileOffset = fSection->offset() - fSection->addr() + fAddress;
asprintf((char**)&fDisplayName, "atom string literal: \"%s\"", (char*)(fOwner.fHeader)+fileOffset);
}
else {
asprintf((char**)&fDisplayName, "%s@%d", fSection->sectname(), fAddress - (uint32_t)fSection->addr() );
}
return fDisplayName;
}
template <typename A>
ObjectFile::Atom::Scope AnonymousAtom<A>::getScope() const
{
return fScope;
}
template <typename A>
bool AnonymousAtom<A>::isZeroFill() const
{
return ( ((fSection->flags() & SECTION_TYPE) == S_ZEROFILL) && fOwner.fOptions.fOptimizeZeroFill );
}
template <typename A>
const char* AnonymousAtom<A>::getSectionName() const
{
if ( fOwner.fOptions.fForFinalLinkedImage ) {
switch ( fSection->flags() & SECTION_TYPE ) {
case S_4BYTE_LITERALS:
case S_8BYTE_LITERALS:
case S_16BYTE_LITERALS:
return "__const";
}
}
if ( strlen(fSection->sectname()) > 15 ) {
static char temp[18];
strncpy(temp, fSection->sectname(), 16);
temp[17] = '\0';
return temp;
}
return fSection->sectname();
}
template <typename A>
ObjectFile::Alignment AnonymousAtom<A>::getAlignment() const
{
// FDEs and CIEs are always packed together in a final linked image, so ignore section alignment
if ( fType == ObjectFile::Atom::kCFIType )
return ObjectFile::Alignment(0);
switch ( fSection->flags() & SECTION_TYPE ) {
case S_4BYTE_LITERALS:
return ObjectFile::Alignment(2);
case S_8BYTE_LITERALS:
return ObjectFile::Alignment(3);
case S_16BYTE_LITERALS:
return ObjectFile::Alignment(4);
case S_NON_LAZY_SYMBOL_POINTERS:
return ObjectFile::Alignment((uint8_t)log2(sizeof(pint_t)));
case S_CSTRING_LITERALS:
if ( ! fOwner.fOptions.fForFinalLinkedImage )
return ObjectFile::Alignment(fSection->align());
default:
return ObjectFile::Alignment(fSection->align(), fAddress % (1 << fSection->align()));
}
}
template <typename A>
ObjectFile::Atom& AnonymousAtom<A>::getFollowOnAtom() const
{
for (ReferenceVectorConstIterator it=fReferences.begin(); it != fReferences.end(); it++) {
Reference<A>* ref = *it;
if ( ref->getKind() == A::kFollowOn )
return ref->getTarget();
}
return *((ObjectFile::Atom*)NULL);
}
template <typename A>
void AnonymousAtom<A>::copyRawContent(uint8_t buffer[]) const
{
// copy base bytes
if ( isZeroFill() )
bzero(buffer, fSize);
else {
uint32_t fileOffset = fSection->offset() - fSection->addr() + fAddress;
memcpy(buffer, (char*)(fOwner.fHeader)+fileOffset, fSize);
}
}
//
// An AbsoluteAtom represents an N_ABS symbol which can only be created in
// assembly language and usable by static executables such as the kernel/
//
template <typename A>
class AbsoluteAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return &fOwner; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const
{ return fOwner.getTranslationUnitSource(dir, name); }
virtual const char* getName() const { return &fOwner.fStrings[fSymbol->n_strx()]; }
virtual const char* getDisplayName() const { return getName(); }
virtual ObjectFile::Atom::Scope getScope() const { return fScope; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return ObjectFile::Atom::kAbsoluteSymbol; }
virtual bool isZeroFill() const { return false; }
virtual bool isThumb() const { return ((fSymbol->n_desc() & N_ARM_THUMB_DEF) != 0); }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableInAsAbsolute; }
virtual bool dontDeadStrip() const { return false; }
virtual uint64_t getSize() const { return 0; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return fgNoReferences; }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const { return "._absolute"; }
virtual ObjectFile::Segment& getSegment() const { return LinkEditSegment::fgSingleton; }
virtual ObjectFile::Atom& getFollowOnAtom() const { return *(ObjectFile::Atom*)NULL; }
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(0); }
virtual void copyRawContent(uint8_t buffer[]) const { }
virtual void setScope(ObjectFile::Atom::Scope newScope) { fScope = newScope; }
virtual void setSize(uint64_t size) { }
virtual void addReference(ObjectFile::Reference* ref) { throw "ld: can't add references"; }
virtual void sortReferences() { }
virtual void addLineInfo(const ObjectFile::LineInfo& info) { throw "ld: can't add line info to tentative definition"; }
virtual const ObjectFile::ReaderOptions& getOptions() const { return fOwner.fOptions; }
virtual uint64_t getObjectAddress() const { return fSymbol->n_value(); }
virtual void setSectionOffset(uint64_t offset) { /* don't let fSectionOffset be altered*/ }
virtual const void* getSectionRecord() const { return NULL; }
virtual unsigned int getSectionIndex() const { return 0; }
protected:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
friend class Reader<A>;
AbsoluteAtom(Reader<A>&, const macho_nlist<P>*);
virtual ~AbsoluteAtom() {}
Reader<A>& fOwner;
const macho_nlist<P>* fSymbol;
ObjectFile::Atom::Scope fScope;
static std::vector<ObjectFile::Reference*> fgNoReferences;
};
template <typename A>
std::vector<ObjectFile::Reference*> AbsoluteAtom<A>::fgNoReferences;
template <typename A>
AbsoluteAtom<A>::AbsoluteAtom(Reader<A>& owner, const macho_nlist<P>* symbol)
: fOwner(owner), fSymbol(symbol)
{
// store absolute adress in fSectionOffset
fSectionOffset = symbol->n_value();
// compute scope
uint8_t type = symbol->n_type();
if ( (type & N_EXT) == 0 )
fScope = ObjectFile::Atom::scopeTranslationUnit;
else if ( (type & N_PEXT) != 0 )
fScope = ObjectFile::Atom::scopeLinkageUnit;
else
fScope = ObjectFile::Atom::scopeGlobal;
//fprintf(stderr, "AbsoluteAtom(%p) %s\n", this, this->getDisplayName());
}
//
// An SectionBoundaryAtom represent the start or end of a section
//
template <typename A>
class SectionBoundaryAtom : public BaseAtom
{
public:
virtual ObjectFile::Reader* getFile() const { return &fOwner; }
virtual bool getTranslationUnitSource(const char** dir, const char** name) const
{ return fOwner.getTranslationUnitSource(dir, name); }
virtual const char* getName() const { return fSymbolName; }
virtual const char* getDisplayName() const { return fDisplayName; }
virtual ObjectFile::Atom::Scope getScope() const { return ObjectFile::Atom::scopeLinkageUnit; }
virtual ObjectFile::Atom::DefinitionKind getDefinitionKind() const { return ObjectFile::Atom::kWeakDefinition; }
virtual ObjectFile::Atom::ContentType getContentType() const { return fStart ? ObjectFile::Atom::kSectionStart : ObjectFile::Atom::kSectionEnd; }
virtual bool isZeroFill() const { return false; }
virtual bool isThumb() const { return false; }
virtual SymbolTableInclusion getSymbolTableInclusion() const { return ObjectFile::Atom::kSymbolTableNotIn; }
virtual bool dontDeadStrip() const { return false; }
virtual uint64_t getSize() const { return 0; }
virtual std::vector<ObjectFile::Reference*>& getReferences() const { return fgNoReferences; }
virtual bool mustRemainInSection() const { return true; }
virtual const char* getSectionName() const { return fSectionName; }
virtual ObjectFile::Segment& getSegment() const { return *fSegment; }
virtual ObjectFile::Atom& getFollowOnAtom() const { return *(ObjectFile::Atom*)NULL; }
virtual std::vector<ObjectFile::LineInfo>* getLineInfo() const { return NULL; }
virtual ObjectFile::Alignment getAlignment() const { return ObjectFile::Alignment(0); }
virtual void copyRawContent(uint8_t buffer[]) const { }
virtual void setScope(ObjectFile::Atom::Scope newScope) { }
virtual void setSize(uint64_t size) { }
virtual void addReference(ObjectFile::Reference* ref) { throw "ld: can't add references"; }
virtual void sortReferences() { }
virtual void addLineInfo(const ObjectFile::LineInfo& info) { throw "ld: can't add line info to tentative definition"; }
virtual const ObjectFile::ReaderOptions& getOptions() const { return fOwner.fOptions; }
virtual uint64_t getObjectAddress() const { return 0; }
virtual const void* getSectionRecord() const { return NULL; }
virtual unsigned int getSectionIndex() const { return 0; }
protected:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
typedef typename A::ReferenceKinds Kinds;
friend class Reader<A>;
class Segment : public ObjectFile::Segment
{
public:
Segment(const char* name, bool r, bool w, bool x):
fName(name), fReadable(r), fWritable(w), fExecutable(x) {}
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; }
private:
const char* fName;
bool fReadable;
bool fWritable;
bool fExecutable;
};
SectionBoundaryAtom(Reader<A>&, bool start, const char* symbolName, const char* segSectName);
virtual ~SectionBoundaryAtom() {}
Reader<A>& fOwner;
class Segment* fSegment;
const char* fSymbolName;
const char* fSectionName;
const char* fDisplayName;
bool fStart;
static std::vector<ObjectFile::Reference*> fgNoReferences;
};
template <typename A>
std::vector<ObjectFile::Reference*> SectionBoundaryAtom<A>::fgNoReferences;
// examples:
// section$start$__DATA$__my
// section$end$__DATA$__my
template <typename A>
SectionBoundaryAtom<A>::SectionBoundaryAtom(Reader<A>& owner, bool start, const char* symbolName, const char* segSectName)
: fOwner(owner), fSymbolName(symbolName), fSectionName(NULL), fStart(start)
{
const char* segSectDividor = strrchr(segSectName, '$');
if ( segSectDividor == NULL )
throwf("malformed section reference name: %s", symbolName);
fSectionName = segSectDividor + 1;
int segNameLen = segSectDividor - segSectName;
if ( segNameLen > 16 )
throwf("malformed section reference name: %s", symbolName);
char segName[18];
strlcpy(segName, segSectName, segNameLen+1);
if ( strcmp(segName, "__TEXT") == 0 )
fSegment = new Segment("__TEXT", true, false, true);
else if ( strcmp(segName, "__DATA") == 0 )
fSegment = new Segment("__DATA", true, true, false);
else
fSegment = new Segment(strdup(segName), true, true, false);
asprintf((char**)&fDisplayName, "%s of section '%s' in segment '%s'", (start ? "start" : "end"), fSectionName, segName);
}
///
/// ObjectFileAddressSpace is used as a template parameter to UnwindCursor for parsing
/// dwarf CFI information in an object file.
///
template <typename A>
class ObjectFileAddressSpace
{
public:
ObjectFileAddressSpace(Reader<A>& reader);
typedef typename A::P::uint_t pint_t;
typedef typename A::P P;
typedef typename A::P::uint_t sint_t;
uint8_t get8(pint_t addr);
uint16_t get16(pint_t addr);
uint32_t get32(pint_t addr);
uint64_t get64(pint_t addr);
pint_t getP(pint_t addr);
uint64_t getULEB128(pint_t& addr, pint_t end);
int64_t getSLEB128(pint_t& addr, pint_t end);
pint_t getEncodedP(pint_t& addr, pint_t end, uint8_t encoding);
private:
const void* mappedAddress(pint_t addr, pint_t* relocTarget=NULL);
pint_t relocated(uint32_t sectOffset, uint32_t relocsOffset, uint32_t relocsCount);
void buildRelocatedMap(const macho_section<P>* sect, std::map<uint32_t,uint64_t>& map);
Reader<A>& fReader;
const uint8_t* fMappingStart;
const macho_section<P>* fSectionsStart;
const macho_section<P>* fSectionsEnd;
std::map<uint32_t,uint64_t> fEHFrameOffsetToTargetMap;
};
template <typename A>
ObjectFileAddressSpace<A>::ObjectFileAddressSpace(Reader<A>& reader)
: fReader(reader), fMappingStart(NULL), fSectionsStart(NULL), fSectionsEnd(NULL)
{
}
template <typename A>
const void* ObjectFileAddressSpace<A>::mappedAddress(pint_t addr, pint_t* relocTarget)
{
if ( fMappingStart == NULL ) {
// delay initialization until now when fReader.fSegment is set up
fMappingStart = (uint8_t*)fReader.fHeader;
fSectionsStart = (macho_section<P>*)((char*)fReader.fSegment + sizeof(macho_segment_command<P>));
fSectionsEnd = &fSectionsStart[fReader.fSegment->nsects()];
// find __eh_frame section and build map of relocations for performance
buildRelocatedMap(fReader.fehFrameSection, fEHFrameOffsetToTargetMap);
}
// special case lookups in __eh_frame section to be fast
const macho_section<P>* ehSect = fReader.fehFrameSection;
if ( (ehSect->addr() <= addr) && (addr < (ehSect->addr()+ehSect->size())) ) {
pint_t offsetOfAddrInSection = addr - ehSect->addr();
if ( relocTarget != NULL ) {
std::map<uint32_t,uint64_t>::iterator pos = fEHFrameOffsetToTargetMap.find(offsetOfAddrInSection);
if ( pos != fEHFrameOffsetToTargetMap.end() )
*relocTarget = pos->second;
else
*relocTarget = 0;
}
return fMappingStart + ehSect->offset() + offsetOfAddrInSection;
}
else {
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( (sect->addr() <= addr) && (addr < (sect->addr()+sect->size())) ) {
pint_t offsetOfAddrInSection = addr - sect->addr();
if ( (sect->flags() & SECTION_TYPE) == S_NON_LAZY_SYMBOL_POINTERS ) {
const uint32_t indirectTableOffset = sect->reserved1();
const uint32_t sectionIndex = offsetOfAddrInSection/sizeof(pint_t);
const uint32_t symbolIndex = A::P::E::get32(fReader.fIndirectTable[indirectTableOffset+sectionIndex]);
// return pointer to symbol name which this non-lazy-pointer will point to
if ( relocTarget != NULL )
*relocTarget = (uintptr_t)&fReader.fStrings[fReader.fSymbols[symbolIndex].n_strx()];
}
else {
if ( relocTarget != NULL )
*relocTarget = relocated(offsetOfAddrInSection, sect->reloff(), sect->nreloc());
}
return fMappingStart + sect->offset() + offsetOfAddrInSection;
}
}
throwf("ObjectFileAddressSpace::mappedAddress(0x%0lX) not in any section", (long)addr);
}
}
template <typename A>
uint8_t ObjectFileAddressSpace<A>::get8(pint_t logicalAddr)
{
return *((uint8_t*)mappedAddress(logicalAddr));
}
template <typename A>
uint16_t ObjectFileAddressSpace<A>::get16(pint_t logicalAddr)
{
return P::E::get16(*((uint16_t*)mappedAddress(logicalAddr)));
}
template <typename A>
uint32_t ObjectFileAddressSpace<A>::get32(pint_t logicalAddr)
{
pint_t relocTarget;
return P::E::get32(*((uint32_t*)mappedAddress(logicalAddr, &relocTarget))) + relocTarget;
}
template <typename A>
uint64_t ObjectFileAddressSpace<A>::get64(pint_t logicalAddr)
{
pint_t relocTarget;
return P::E::get64(*((uint64_t*)mappedAddress(logicalAddr, &relocTarget))) + relocTarget;
}
template <typename A>
typename A::P::uint_t ObjectFileAddressSpace<A>::getP(pint_t logicalAddr)
{
pint_t relocTarget;
return P::getP(*((pint_t*)mappedAddress(logicalAddr, &relocTarget))) + relocTarget;
}
template <typename A>
uint64_t ObjectFileAddressSpace<A>::getULEB128(pint_t& logicalAddr, pint_t end)
{
uintptr_t size = (end - logicalAddr);
libunwind::LocalAddressSpace::pint_t laddr = (libunwind::LocalAddressSpace::pint_t)mappedAddress(logicalAddr);
libunwind::LocalAddressSpace::pint_t sladdr = laddr;
uint64_t result = libunwind::LocalAddressSpace::getULEB128(laddr, laddr+size);
logicalAddr += (laddr-sladdr);
return result;
}
template <typename A>
int64_t ObjectFileAddressSpace<A>::getSLEB128(pint_t& logicalAddr, pint_t end)
{
uintptr_t size = (end - logicalAddr);
libunwind::LocalAddressSpace::pint_t laddr = (libunwind::LocalAddressSpace::pint_t)mappedAddress(logicalAddr);
libunwind::LocalAddressSpace::pint_t sladdr = laddr;
int64_t result = libunwind::LocalAddressSpace::getSLEB128(laddr, laddr+size);
logicalAddr += (laddr-sladdr);
return result;
}
template <typename A>
class Reader : public ObjectFile::Reader
{
public:
static bool validFile(const uint8_t* fileContent, bool subtypeMustMatch=false, cpu_subtype_t subtype=0);
Reader(const uint8_t* fileContent, const char* path, time_t modTime,
const ObjectFile::ReaderOptions& options, uint32_t ordinalBase);
virtual ~Reader() {}
virtual const char* getPath() { return fPath; }
virtual time_t getModificationTime() { return fModTime; }
virtual ObjectFile::Reader::DebugInfoKind getDebugInfoKind() { return fDebugInfo; }
virtual std::vector<class ObjectFile::Atom*>& getAtoms() { return (std::vector<class ObjectFile::Atom*>&)(fAtoms); }
virtual std::vector<class ObjectFile::Atom*>* getJustInTimeAtomsFor(const char* name) { return NULL; }
virtual std::vector<Stab>* getStabs() { return &fStabs; }
virtual ObjectFile::Reader::ObjcConstraint getObjCConstraint() { return fObjConstraint; }
virtual uint32_t updateCpuConstraint(uint32_t current);
virtual bool canScatterAtoms() { return (fHeader->flags() & MH_SUBSECTIONS_VIA_SYMBOLS); }
virtual bool objcReplacementClasses(){ return fReplacementClasses; }
virtual bool hasLongBranchStubs() { return fHasLongBranchStubs; }
bool getTranslationUnitSource(const char** dir, const char** name) const;
private:
typedef typename A::P P;
typedef typename A::P::E E;
typedef typename A::P::uint_t pint_t;
//typedef typename std::vector<Atom<A>*> AtomVector;
//typedef typename AtomVector::iterator AtomVectorIterator; // seems to help C++ parser
typedef typename A::ReferenceKinds Kinds;
typedef typename libunwind::CFI_Parser<ObjectFileAddressSpace<A> >::FDE_Atom_Info FDE_Atom_Info;
typedef typename libunwind::CFI_Parser<ObjectFileAddressSpace<A> >::CIE_Atom_Info CIE_Atom_Info;
typedef class ObjectFileAddressSpace<A> OAS;
friend class ObjectFileAddressSpace<A>;
friend class AnonymousAtom<A>;
friend class TentativeAtom<A>;
friend class AbsoluteAtom<A>;
friend class SectionBoundaryAtom<A>;
friend class SymbolAtom<A>;
typedef std::map<pint_t, BaseAtom*> AddrToAtomMap;
void addReferencesForSection(const macho_section<P>* sect);
bool addRelocReference(const macho_section<P>* sect, const macho_relocation_info<P>* reloc);
bool addRelocReference_powerpc(const macho_section<P>* sect, const macho_relocation_info<P>* reloc);
const char* getDwarfString(uint64_t form, const uint8_t* p);
bool read_comp_unit(const char ** name, const char ** comp_dir, uint64_t *stmt_list);
static bool isWeakImportSymbol(const macho_nlist<P>* sym);
static bool skip_form(const uint8_t ** offset, const uint8_t * end, uint64_t form, uint8_t addr_size, bool dwarf64);
static const char* assureFullPath(const char* path);
AtomAndOffset findAtomAndOffset(pint_t addr);
AtomAndOffset findAtomAndOffsetForSection(pint_t addr, unsigned int sectionIndex);
AtomAndOffset findAtomAndOffset(pint_t baseAddr, pint_t realAddr);
Reference<A>* makeReference(Kinds kind, pint_t atAddr, pint_t toAddr);
Reference<A>* makeReference(Kinds kind, pint_t atAddr, pint_t fromAddr, pint_t toAddr);
Reference<A>* makeReferenceWithToBase(Kinds kind, pint_t atAddr, pint_t toAddr, pint_t toBaseAddr);
Reference<A>* makeReferenceWithToBase(Kinds kind, pint_t atAddr, pint_t fromAddr, pint_t toAddr, pint_t toBaseAddr);
Reference<A>* makeByNameReference(Kinds kind, pint_t atAddr, const char* toName, uint32_t toOffset);
BaseAtom* makeReferenceToEH(const char* ehName, pint_t ehAtomAddress, const macho_section<P>* ehSect);
Reference<A>* makeReferenceToSymbol(Kinds kind, pint_t atAddr, const macho_nlist<P>* toSymbol, pint_t toOffset);
void validSectionType(uint8_t type);
void addDtraceExtraInfos(uint32_t probeAddr, const char* providerName);
void setCpuConstraint(uint32_t cpusubtype);
const macho_section<P>* getSectionForAddress(pint_t);
ObjectFile::Atom* getFunctionAtomFromFDEAddress(pint_t);
ObjectFile::Atom* getFunctionAtomFromLSDAAddress(pint_t);
void addFdeReference(uint8_t encoding, AtomAndOffset inFDE, AtomAndOffset target);
void addCiePersonalityReference(BaseAtom* cieAtom, uint32_t offsetInCIE, uint8_t encoding);
bool isSectDiffReloc(uint8_t r_type);
BaseAtom* findAtomByName(const char*);
const char* fPath;
time_t fModTime;
uint32_t fOrdinalBase;
const ObjectFile::ReaderOptions& fOptions;
const macho_header<P>* fHeader;
const char* fStrings;
const macho_nlist<P>* fSymbols;
uint32_t fSymbolCount;
const macho_segment_command<P>* fSegment;
const uint32_t* fIndirectTable;
std::vector<BaseAtom*> fAtoms;
AddrToAtomMap fAddrToAtom;
AddrToAtomMap fAddrToAbsoluteAtom;
std::vector<class AnonymousAtom<A>*> fLocalNonLazys;
std::vector<class AnonymousAtom<A>*> fAtomsPendingAName;
std::set<const macho_section<P>*> fSectionsWithAtomsPendingAName;
std::vector<const char*> fDtraceProviderInfo;
ObjectFile::Reader::DebugInfoKind fDebugInfo;
bool fHasUUID;
const macho_section<P>* fehFrameSection;
const macho_section<P>* fUTF16Section;
std::set<BaseAtom*> fLSDAAtoms;
const macho_section<P>* fDwarfDebugInfoSect;
const macho_section<P>* fDwarfDebugAbbrevSect;
const macho_section<P>* fDwarfDebugLineSect;
const macho_section<P>* fDwarfDebugStringSect;
const char* fDwarfTranslationUnitDir;
const char* fDwarfTranslationUnitFile;
std::map<uint32_t,const char*> fDwarfIndexToFile;
std::vector<Stab> fStabs;
std::vector<FDE_Atom_Info> fFDEInfos;
std::vector<CIE_Atom_Info> fCIEInfos;
bool fAppleObjc;
bool fHasDTraceProbes;
bool fHaveIndirectSymbols;
bool fReplacementClasses;
bool fHasLongBranchStubs;
ObjectFile::Reader::ObjcConstraint fObjConstraint;
uint32_t fCpuConstraint;
const macho_section<P>* fSectionsStart;
const macho_section<P>* fSectionsEnd;
OAS fObjectAddressSpace;
};
template <typename A>
Reader<A>::Reader(const uint8_t* fileContent, const char* path, time_t modTime, const ObjectFile::ReaderOptions& options, uint32_t ordinalBase)
: fPath(strdup(path)), fModTime(modTime), fOrdinalBase(ordinalBase), fOptions(options), fHeader((const macho_header<P>*)fileContent),
fStrings(NULL), fSymbols(NULL), fSymbolCount(0), fSegment(NULL), fIndirectTable(NULL),
fDebugInfo(kDebugInfoNone), fHasUUID(false), fehFrameSection(NULL), fUTF16Section(NULL),
fDwarfDebugInfoSect(NULL), fDwarfDebugAbbrevSect(NULL), fDwarfDebugLineSect(NULL),
fDwarfTranslationUnitDir(NULL), fDwarfTranslationUnitFile(NULL), fAppleObjc(false), fHasDTraceProbes(false),
fHaveIndirectSymbols(false), fReplacementClasses(false), fHasLongBranchStubs(false),
fObjConstraint(ObjectFile::Reader::kObjcNone), fCpuConstraint(ObjectFile::Reader::kCpuAny),
fSectionsStart(NULL), fSectionsEnd(NULL), fObjectAddressSpace(*this)
{
// sanity check
if ( ! validFile(fileContent, false, 0) )
throw "not a valid mach-o object file";
Reference<A>::fgForFinalLinkedImage = options.fForFinalLinkedImage;
// write out path for -t or -whatsloaded option
if ( options.fLogObjectFiles || options.fLogAllFiles )
printf("%s\n", path);
// cache intersting pointers
const macho_header<P>* header = (const macho_header<P>*)fileContent;
this->setCpuConstraint(header->cpusubtype());
const uint32_t cmd_count = header->ncmds();
const macho_load_command<P>* const cmds = (macho_load_command<P>*)((char*)header + sizeof(macho_header<P>));
const macho_load_command<P>* const cmdsEnd = (macho_load_command<P>*)((char*)header + sizeof(macho_header<P>) + header->sizeofcmds());
const macho_load_command<P>* cmd = cmds;
uint32_t undefinedStartIndex = 0;
uint32_t undefinedEndIndex = 0;
for (uint32_t i = 0; i < cmd_count; ++i) {
switch (cmd->cmd()) {
case LC_SYMTAB:
{
const macho_symtab_command<P>* symtab = (macho_symtab_command<P>*)cmd;
fSymbolCount = symtab->nsyms();
fSymbols = (const macho_nlist<P>*)((char*)header + symtab->symoff());
fStrings = (char*)header + symtab->stroff();
if ( undefinedEndIndex == 0 ) {
undefinedStartIndex = 0;
undefinedEndIndex = symtab->nsyms();
}
}
break;
case LC_DYSYMTAB:
{
const macho_dysymtab_command<P>* dsymtab = (struct macho_dysymtab_command<P>*)cmd;
fIndirectTable = (uint32_t*)((char*)fHeader + dsymtab->indirectsymoff());
undefinedStartIndex = dsymtab->iundefsym();
undefinedEndIndex = undefinedStartIndex + dsymtab->nundefsym();
}
break;
case LC_UUID:
fHasUUID = true;
break;
default:
if ( cmd->cmd() == macho_segment_command<P>::CMD ) {
fSegment = (macho_segment_command<P>*)cmd;
}
break;
}
cmd = (const macho_load_command<P>*)(((char*)cmd)+cmd->cmdsize());
if ( cmd > cmdsEnd )
throwf("malformed dylb, load command #%d is outside size of load commands in %s", i, path);
}
// if there are no load commands, then this file has no content, so no atoms
if ( header->ncmds() < 1 )
return;
fSectionsStart = (macho_section<P>*)((char*)fSegment + sizeof(macho_segment_command<P>));
fSectionsEnd = &fSectionsStart[fSegment->nsects()];
// inital guess for number of atoms
fAtoms.reserve(fSymbolCount);
// if there is an __eh_frame section, decode it into chunks to get atoms in that
// section as well as division points for functions in __text
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( (strcmp(sect->sectname(), "__eh_frame") == 0) && (strcmp(sect->segname(), "__TEXT") == 0) ) {
fehFrameSection = sect;
const char* msg = libunwind::CFI_Parser<ObjectFileAddressSpace<A> >::getCFIs(fObjectAddressSpace, sect->addr(),
sect->size(), fFDEInfos, fCIEInfos);
if ( msg != NULL ) {
throwf("malformed __eh_frame section: %s", msg);
}
else {
//fprintf(stderr, "%lu CIEs, %lu FDEs\n", fCIEInfos.size(), fFDEInfos.size());
// add anonymous atoms for each CIE
for (typename std::vector<CIE_Atom_Info>::const_iterator it = fCIEInfos.begin(); it != fCIEInfos.end(); ++it) {
AnonymousAtom<A>* cieAtom = new AnonymousAtom<A>(*this, sect, it->cieAddress, 1);
fAtoms.push_back(cieAtom);
fAddrToAtom[it->cieAddress] = cieAtom;
}
// add anonymous atoms for each FDE and LSDA
for (typename std::vector<FDE_Atom_Info>::const_iterator it = fFDEInfos.begin(); it != fFDEInfos.end(); ++it) {
//fprintf(stderr, "fdeAddress=0x%08llX, lsdaAddr=0x%08llX, funcAddr=0x%08llX\n", (uint64_t)it->fdeAddress, (uint64_t)it->lsda.address, (uint64_t)it->function.address);
AnonymousAtom<A>* fdeAtom = new AnonymousAtom<A>(*this, sect, it->fdeAddress, 0);
fAtoms.push_back(fdeAtom);
fAddrToAtom[it->fdeAddress] = fdeAtom;
if ( it->lsda.address != 0 ) {
AnonymousAtom<A>* lsdaAtom = new AnonymousAtom<A>(*this, getSectionForAddress(it->lsda.address), it->lsda.address, 0);
fAtoms.push_back(lsdaAtom);
fAddrToAtom[it->lsda.address] = lsdaAtom;
fLSDAAtoms.insert(lsdaAtom);
}
}
}
}
else if ( (strcmp(sect->sectname(), "__ustring") == 0) && (strcmp(sect->segname(), "__TEXT") == 0) ) {
// if there is a __ustring section parse it into AnonymousAtoms based on labels
fUTF16Section = sect;
std::vector<pint_t> utf16Addreses;
for (int i=fSymbolCount-1; i >= 0 ; --i) {
const macho_nlist<P>& sym = fSymbols[i];
if ( (sym.n_type() & N_STAB) == 0 ) {
uint8_t type = (sym.n_type() & N_TYPE);
if ( type == N_SECT ) {
if ( &fSectionsStart[sym.n_sect()-1] == fUTF16Section ) {
utf16Addreses.push_back(sym.n_value());
}
}
}
}
utf16Addreses.push_back(fUTF16Section->addr()+fUTF16Section->size());
std::sort(utf16Addreses.begin(), utf16Addreses.end());
for(int i=utf16Addreses.size()-2; i >=0 ; --i) {
pint_t size = utf16Addreses[i+1] - utf16Addreses[i];
AnonymousAtom<A>* strAtom = new AnonymousAtom<A>(*this, fUTF16Section, utf16Addreses[i], size);
fAtoms.push_back(strAtom);
fAddrToAtom[utf16Addreses[i]] = strAtom;
}
}
}
// add all atoms that have entries in symbol table
BaseAtom* sectionEndAtoms[fSegment->nsects()];
for (unsigned int i=0; i < fSegment->nsects(); ++i)
sectionEndAtoms[i] = NULL;
for (int i=fSymbolCount-1; i >= 0 ; --i) {
// walk backwards through symbol table so globals are see before locals, otherwise a local alias would beome the real name
const macho_nlist<P>& sym = fSymbols[i];
if ( (sym.n_type() & N_STAB) == 0 ) {
uint8_t type = (sym.n_type() & N_TYPE);
if ( type == N_SECT ) {
const macho_section<P>* section = &fSectionsStart[sym.n_sect()-1];
const pint_t sectionStartAddr = section->addr();
const pint_t sectionEndAddr = sectionStartAddr + section->size();
bool suppress = false;
// ignore atoms in debugger sections
if ( (section->flags() & S_ATTR_DEBUG) == 0 ) {
if ( strncmp(&fStrings[sym.n_strx()], "__dtrace_probe$", 15) == 0 ) {
// ignore dtrace probe labels
fHasDTraceProbes = true;
}
else if ( fStrings[sym.n_strx()] == 'L' ) {
// ignore L labels, <rdar://problem/3962731>
}
else if ( section == fehFrameSection ) {
// ignore labels in __eh_frame section
}
else if ( section == fUTF16Section ) {
// ignore labels in __ustring section
}
else {
// ignore labels for atoms in other sections
switch ( section->flags() & SECTION_TYPE ) {
case S_REGULAR:
if ( (sym.n_desc() & N_WEAK_DEF) && strcmp(section->sectname(), "__picsymbolstub1__TEXT") == 0 )
suppress = true; // ignore stubs in crt1.o built by old ld64 that was missing S_SYMBOL_STUBS
case S_ZEROFILL:
case S_COALESCED:
case S_4BYTE_LITERALS:
case S_8BYTE_LITERALS:
case S_16BYTE_LITERALS:
case S_CSTRING_LITERALS:
{
BaseAtom* newAtom;
typename AddrToAtomMap::iterator pos = fAddrToAtom.find(sym.n_value());
if ( (pos != fAddrToAtom.end()) && (pos->second->getSectionRecord() == section) ) {
if ( fLSDAAtoms.count(pos->second) != 0 ) {
// already have LSDA atom from for this address, ignore compiler's label
suppress = true;
break;
}
else {
// another label to an existing address in the same section, make this an alias
newAtom = new SymbolAliasAtom<A>(&fStrings[sym.n_strx()], &sym, *pos->second);
}
}
else {
if ( sym.n_value() == sectionEndAddr ) {
// Symbol address is at end of section. This can interfere
// with a symbol at the start of the next section, so don't
// add to fAddrToAtom. But do track in sectionEndAtoms so we
// still make aliases if there are duplicates.
if ( sectionEndAtoms[sym.n_sect()-1] == NULL ) {
newAtom = new SymbolAtom<A>(*this, &sym, section);
sectionEndAtoms[sym.n_sect()-1] = newAtom;
// if this is a zero length section, so add to fAddrToAtom
if ( sym.n_value() == sectionStartAddr )
fAddrToAtom[newAtom->getObjectAddress()] = newAtom;
}
else {
newAtom = new SymbolAliasAtom<A>(&fStrings[sym.n_strx()], &sym, *sectionEndAtoms[sym.n_sect()-1]);
}
}
else {
// make SymbolAtom atom for this address
newAtom = new SymbolAtom<A>(*this, &sym, section);
fAddrToAtom[newAtom->getObjectAddress()] = newAtom;
}
}
if ( ! suppress )
fAtoms.push_back(newAtom);
}
break;
case S_SYMBOL_STUBS:
case S_LAZY_SYMBOL_POINTERS:
case S_NON_LAZY_SYMBOL_POINTERS:
// ignore symboled stubs produces by old ld64
break;
default:
warning("symbol %s found in unsupported section in %s",
&fStrings[sym.n_strx()], this->getPath());
}
}
}
}
else if ( (type == N_UNDF) && (sym.n_value() != 0) ) {
fAtoms.push_back(new TentativeAtom<A>(*this, &sym));
}
else if ( (type == N_UNDF) && (sym.n_value() == 0) ) {
const char* symName = &fStrings[sym.n_strx()];
if ( strncmp(symName, "section$start$", 14) == 0)
fAtoms.push_back(new SectionBoundaryAtom<A>(*this, true, symName, &symName[14]));
else if ( strncmp(symName, "section$end$", 12) == 0)
fAtoms.push_back(new SectionBoundaryAtom<A>(*this, false, symName, &symName[12]));
}
else if ( type == N_ABS ) {
const char* symName = &fStrings[sym.n_strx()];
if ( strncmp(symName, ".objc_class_name_", 17) == 0 ) {
// ignore .objc_class_name_* symbols
fAppleObjc = true;
}
else if ( strcmp(&symName[strlen(symName)-3], ".eh") == 0 ) {
// ignore empty *.eh symbols
}
else {
BaseAtom* abAtom = new AbsoluteAtom<A>(*this, &sym);
fAtoms.push_back(abAtom);
fAddrToAbsoluteAtom[sym.n_value()] = abAtom;
}
}
else if ( type == N_INDR ) {
fHaveIndirectSymbols = true;
}
}
}
// add anonymous atoms for any functions (as determined by dwarf unwind) have no symbol names
if ( fehFrameSection != NULL ) {
for (typename std::vector<FDE_Atom_Info>::const_iterator it = fFDEInfos.begin(); it != fFDEInfos.end(); ++it) {
// add if not already an atom at that address
if ( fAddrToAtom.find(it->function.address) == fAddrToAtom.end() ) {
AnonymousAtom<A>* funcAtom = new AnonymousAtom<A>(*this, getSectionForAddress(it->function.address), it->function.address, 0);
fAtoms.push_back(funcAtom);
fAddrToAtom[it->function.address] = funcAtom;
// even though we've made a new atom, be conservative and make sure they lay out together
if ( canScatterAtoms() ) {
AtomAndOffset prev = findAtomAndOffset(it->function.address-1);
if ( prev.atom != NULL ) {
if ( ((BaseAtom*)(prev.atom))->getSectionRecord() == funcAtom->getSectionRecord() )
new Reference<A>(A::kFollowOn, prev, AtomAndOffset(funcAtom));
}
}
}
}
}
// add all fixed size anonymous atoms from special sections
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
pint_t atomSize = 0;
uint8_t type (sect->flags() & SECTION_TYPE);
validSectionType(type);
bool suppress = false;
switch ( type ) {
case S_SYMBOL_STUBS:
suppress = true;
atomSize = sect->reserved2();
break;
case S_LAZY_SYMBOL_POINTERS:
suppress = true;
atomSize = sizeof(pint_t);
break;
case S_NON_LAZY_SYMBOL_POINTERS:
case S_LITERAL_POINTERS:
case S_MOD_INIT_FUNC_POINTERS:
case S_MOD_TERM_FUNC_POINTERS:
atomSize = sizeof(pint_t);
break;
case S_INTERPOSING:
atomSize = sizeof(pint_t)*2;
break;
case S_4BYTE_LITERALS:
atomSize = 4;
break;
case S_8BYTE_LITERALS:
atomSize = 8;
break;
case S_16BYTE_LITERALS:
atomSize = 16;
break;
case S_REGULAR:
// special case ObjC classes to synthesize .objc_class_name_* symbols
if ( (strcmp(sect->sectname(), "__class") == 0) && (strcmp(sect->segname(), "__OBJC") == 0) && fAppleObjc ) {
// gcc sometimes over aligns class structure
uint32_t align = 1 << sect->align();
atomSize = ((12 * sizeof(pint_t)) + align-1) & (-align);
}
// get objc Garbage Collection info
else if ( ((strcmp(sect->sectname(), "__image_info") == 0) && (strcmp(sect->segname(), "__OBJC") == 0))
|| ((strncmp(sect->sectname(), "__objc_imageinfo", 16) == 0) && (strcmp(sect->segname(), "__DATA") == 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
//
const uint32_t* contents = (uint32_t*)(((char*)fHeader) + sect->offset());
if ( (sect->size() >= 8) && (contents[0] == 0) ) {
uint32_t flags = E::get32(contents[1]);
if ( (flags & 4) == 4 )
fObjConstraint = ObjectFile::Reader::kObjcGC;
else if ( (flags & 2) == 2 )
fObjConstraint = ObjectFile::Reader::kObjcRetainReleaseOrGC;
else
fObjConstraint = ObjectFile::Reader::kObjcRetainRelease;
if ( (flags & 1) == 1 )
fReplacementClasses = true;
// don't make atom for this section
atomSize = sect->size();
suppress = true;
}
else {
warning("can't parse __OBJC/__image_info section in %s", fPath);
}
}
// special case constant NS/CFString literals and make an atom out of each one
else if ((strcmp(sect->sectname(), "__cfstring") == 0) && (strcmp(sect->segname(), "__DATA") == 0)) {
atomSize = 4 * sizeof(pint_t);
}
break;
}
if ( atomSize != 0 ) {
for(pint_t sectOffset=0; sectOffset < sect->size(); sectOffset += atomSize) {
pint_t atomAddr = sect->addr() + sectOffset;
// add if not already an atom at that address
if ( fAddrToAtom.find(atomAddr) == fAddrToAtom.end() ) {
AnonymousAtom<A>* newAtom = new AnonymousAtom<A>(*this, sect, atomAddr, atomSize);
if ( !suppress )
fAtoms.push_back(newAtom);
fAddrToAtom[atomAddr] = newAtom->redirectTo();
}
}
}
}
// add all c-string anonymous atoms
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( ((sect->flags() & SECTION_TYPE) == S_CSTRING_LITERALS) || strcmp(sect->sectname(), "__cstring") == 0 ) {
uint32_t stringLen;
pint_t stringAddr;
BaseAtom* mostAlignedEmptyString = NULL;
uint32_t mostAlignedEmptyStringTrailingZeros = 0;
std::vector<std::pair<pint_t,BaseAtom*> > emptyStrings;
for(pint_t sectOffset=0; sectOffset < sect->size(); sectOffset += stringLen) {
stringAddr = sect->addr() + sectOffset;
stringLen = strlen((char*)(fHeader) + sect->offset() + sectOffset) + 1;
// add if not already a non-zero length atom at that address
typename AddrToAtomMap::iterator pos = fAddrToAtom.find(stringAddr);
if ( (pos == fAddrToAtom.end()) || (pos->second->getSize() == 0) ) {
BaseAtom* newAtom = new AnonymousAtom<A>(*this, sect, stringAddr, stringLen);
if ( stringLen == 1 ) {
// because of padding it may look like there are lots of empty strings, keep track of all
emptyStrings.push_back(std::make_pair<pint_t,BaseAtom*>(stringAddr, newAtom));
// record empty string with greatest alignment requirement
uint32_t stringAddrTrailingZeros = (stringAddr==0) ? sect->align() : __builtin_ctz(stringAddr);
if ( (mostAlignedEmptyString == NULL)
|| ( stringAddrTrailingZeros > mostAlignedEmptyStringTrailingZeros) ) {
mostAlignedEmptyString = newAtom;
mostAlignedEmptyStringTrailingZeros = stringAddrTrailingZeros;
}
}
else {
fAtoms.push_back(newAtom);
fAddrToAtom[stringAddr] = newAtom;
}
}
}
// map all uses of empty strings to the most aligned one
if ( mostAlignedEmptyString != NULL ) {
// make most aligned atom a real atom
fAtoms.push_back(mostAlignedEmptyString);
// map all other empty atoms to this one
for (typename std::vector<std::pair<pint_t,BaseAtom*> >::iterator it=emptyStrings.begin(); it != emptyStrings.end(); it++) {
fAddrToAtom[it->first] = mostAlignedEmptyString;
}
}
}
}
// sort all atoms so far by address and section
std::sort(fAtoms.begin(), fAtoms.end(), BaseAtomSorter());
//fprintf(stderr, "sorted atoms:\n");
//for (std::vector<BaseAtom*>::iterator it=fAtoms.begin(); it != fAtoms.end(); it++)
// fprintf(stderr, "0x%08llX %s\n", (*it)->getObjectAddress(), (*it)->getDisplayName());
// create atoms to cover any non-debug ranges not handled above
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
pint_t sectionStartAddr = sect->addr();
pint_t sectionEndAddr = sect->addr() + sect->size();
// don't set follow-on atoms in __eh_frame section
const bool setFollowOnAtom = !canScatterAtoms() && (sect != fehFrameSection);
if ( sect->size() != 0 ) {
// ignore dwarf sections. If ld every supports processing dwarf, this logic will need to change
if ( (sect->flags() & S_ATTR_DEBUG) != 0 ) {
fDebugInfo = kDebugInfoDwarf;
if ( strcmp(sect->sectname(), "__debug_info") == 0 )
fDwarfDebugInfoSect = sect;
else if ( strcmp(sect->sectname(), "__debug_abbrev") == 0 )
fDwarfDebugAbbrevSect = sect;
else if ( strcmp(sect->sectname(), "__debug_line") == 0 )
fDwarfDebugLineSect = sect;
else if ( strcmp(sect->sectname(), "__debug_str") == 0 )
fDwarfDebugStringSect = sect;
}
else {
if ( strcmp(sect->segname(), "__DWARFA") == 0 ) {
throw "object file contains old DWARF debug info - rebuild with newer compiler";
}
uint8_t type (sect->flags() & SECTION_TYPE);
switch ( type ) {
case S_REGULAR:
case S_ZEROFILL:
case S_COALESCED:
// if there is not an atom already at the start of this section, add an anonymous one
pint_t previousAtomAddr = 0;
BaseAtom* previousAtom = NULL;
if ( fAddrToAtom.find(sectionStartAddr) == fAddrToAtom.end() ) {
BaseAtom* newAtom = new AnonymousAtom<A>(*this, sect, sect->addr(), 0);
fAddrToAtom[sect->addr()] = newAtom;
fAtoms.push_back(newAtom);
previousAtomAddr = sectionStartAddr;
previousAtom = newAtom;
std::sort(fAtoms.begin(), fAtoms.end(), BaseAtomSorter());
}
// calculate size of all atoms in this section and add follow-on references
for (std::vector<BaseAtom*>::iterator it=fAtoms.begin(); it != fAtoms.end(); it++) {
BaseAtom* atom = (BaseAtom*)(*it);
pint_t atomAddr = atom->getObjectAddress();
if ( atom->getSectionRecord() == sect ) {
//fprintf(stderr, "addr=0x%08llX, atom=%s\n", (uint64_t)atomAddr, atom->getDisplayName());
if ( (previousAtom != NULL) && (previousAtomAddr != atomAddr) ) {
previousAtom->setSize(atomAddr - previousAtomAddr);
if ( setFollowOnAtom && (atom != previousAtom) )
new Reference<A>(A::kFollowOn, AtomAndOffset(previousAtom), AtomAndOffset(atom));
}
previousAtomAddr = atomAddr;
previousAtom = atom;
}
}
if ( previousAtom != NULL ) {
// set last atom in section
previousAtom->setSize(sectionEndAddr - previousAtomAddr);
}
break;
}
}
}
}
// check for object file that defines no objc classes, but uses objc classes
// check for dtrace provider info
for (uint32_t i=undefinedStartIndex; i < undefinedEndIndex; ++i) {
const macho_nlist<P>& sym = fSymbols[i];
if ( (sym.n_type() & N_STAB) == 0 ) {
if ( (sym.n_type() & N_TYPE) == N_UNDF ) {
const char* undefinedName = &fStrings[sym.n_strx()];
if ( !fAppleObjc && (strncmp(undefinedName, ".objc_class_name_", 17) == 0) ) {
fAppleObjc = true;
}
else if ( strncmp(undefinedName, "___dtrace_", 10) == 0 ) {
if ( strchr(undefinedName, '$') != NULL ) {
if ( (strncmp(&undefinedName[10], "probe$", 6) != 0) && (strncmp(&undefinedName[10], "isenabled$", 10) != 0) ) {
// any undefined starting with __dtrace_*$ that is not ___dtrace_probe$* or ___dtrace_isenabled$*
// is extra provider info
fDtraceProviderInfo.push_back(undefinedName);
}
}
}
}
}
}
// add relocation based references to sections that have atoms with pending names
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( fSectionsWithAtomsPendingAName.count(sect) != 0 )
addReferencesForSection(sect);
}
// update any anonymous atoms that need references built in order to name themselves
for (typename std::vector<AnonymousAtom<A>*>::iterator it=fAtomsPendingAName.begin(); it != fAtomsPendingAName.end(); it++) {
(*it)->resolveName();
}
// add relocation based references to other sections
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( fSectionsWithAtomsPendingAName.count(sect) == 0 )
addReferencesForSection(sect);
}
// add objective-c references
if ( fAppleObjc ) {
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( (strcmp(sect->sectname(), "__cls_refs") == 0) && (strcmp(sect->segname(), "__OBJC") == 0) ) {
for (uint32_t offset = 0; offset < sect->size(); offset += sizeof(pint_t)) {
AtomAndOffset ao = this->findAtomAndOffset(sect->addr()+offset);
ObjectFile::Reference* classRef = ao.atom->getReferences()[0];
if ( classRef->getFixUpOffset() == 0 ) {
const char* classStr = classRef->getTargetName();
if ( strncmp(classStr, "cstring=", 8) == 0 ) {
const char* className;
asprintf((char**)&className, ".objc_class_name_%s", &classStr[8]);
new Reference<A>(A::kNoFixUp, ao, className, 0);
}
}
}
}
}
}
// add direct references to local non-lazy-pointers, can do this now that all atoms are constructed
for (typename std::vector<AnonymousAtom<A>*>::iterator it=fLocalNonLazys.begin(); it != fLocalNonLazys.end(); it++) {
AnonymousAtom<A>* localNonLazy = *it;
uint32_t fileOffset = localNonLazy->fSection->offset() - localNonLazy->fSection->addr() + localNonLazy->fAddress;
pint_t nonLazyPtrValue = P::getP(*((pint_t*)((char*)(fHeader)+fileOffset)));
makeReference(A::kPointer, localNonLazy->fAddress, nonLazyPtrValue);
}
// add personality references to CIEs
for (typename std::vector<CIE_Atom_Info>::const_iterator it = fCIEInfos.begin(); it != fCIEInfos.end(); ++it) {
if ( it->personality.offsetInFDE != 0 )
addCiePersonalityReference(fAddrToAtom[it->cieAddress], it->personality.offsetInFDE, it->personality.encodingOfAddress);
}
// add all references for FDEs, including implicit group references
for (typename std::vector<FDE_Atom_Info>::const_iterator it = fFDEInfos.begin(); it != fFDEInfos.end(); ++it) {
AtomAndOffset funcAO = this->findAtomAndOffset(it->function.address);
if ( funcAO.offset != 0 )
warning("FDE does not point to start of function %s\n", funcAO.atom->getDisplayName());
AtomAndOffset fdeAO = this->findAtomAndOffset(it->fdeAddress);
if ( fdeAO.offset != 0 )
warning("FDE does start its own atom %s\n", funcAO.atom->getDisplayName());
AtomAndOffset cieAO = this->findAtomAndOffset(it->cie.address);
if ( cieAO.offset != 0 )
warning("CIE does start its own atom %s\n", cieAO.atom->getDisplayName());
AtomAndOffset lsdaAO;
if ( it->lsda.address != 0 ) {
lsdaAO = this->findAtomAndOffset(it->lsda.address);
if ( lsdaAO.offset != 0 )
warning("LSDA does start its own atom %s\n", lsdaAO.atom->getDisplayName());
}
// add reference from FDE to CIE
AtomAndOffset cieInfdeAO = AtomAndOffset(fdeAO.atom, it->cie.offsetInFDE);
new Reference<A>(A::kPointerDiff32, cieInfdeAO, cieAO, cieInfdeAO);
// add reference from FDE to function
addFdeReference(it->function.encodingOfAddress, AtomAndOffset(fdeAO.atom, it->function.offsetInFDE), funcAO);
// add reference from FDE to LSDA
if ( it->lsda.address != 0 ) {
addFdeReference(it->lsda.encodingOfAddress, AtomAndOffset(fdeAO.atom, it->lsda.offsetInFDE), lsdaAO);
}
// FDE is in group lead by function atom
new Reference<A>(A::kGroupSubordinate, funcAO, fdeAO);
// LSDA is in group lead by function atom
if ( it->lsda.address != 0 ) {
new Reference<A>(A::kGroupSubordinate, funcAO, lsdaAO);
// add back reference from LSDA to owning function
new Reference<A>(A::kNoFixUp, lsdaAO, funcAO);
}
// compute compact encoding for this FDE
if ( fOptions.fAddCompactUnwindEncoding ) {
((BaseAtom*)(funcAO.atom))->setCompactUnwindEncoding(it->fdeAddress);
// add reference from function atom to personality function
// the only reference a CIE can have is the reference to the personality function
std::vector<class ObjectFile::Reference*>& cieRefs = cieAO.atom->getReferences();
if ( cieRefs.size() == 1 ) {
new Reference<A>((typename A::ReferenceKinds)((BaseAtom*)(funcAO.atom))->getPersonalityReferenceKind(),
funcAO, cieRefs[0]->getTargetName(), 0);
}
}
}
// add command line aliases
for(std::vector<ObjectFile::ReaderOptions::AliasPair>::const_iterator it = fOptions.fAliases.begin(); it != fOptions.fAliases.end(); ++it) {
BaseAtom* target = this->findAtomByName(it->realName);
if ( (target != NULL) && target->getSymbolTableInclusion() != ObjectFile::Atom::kSymbolTableNotIn )
fAtoms.push_back(new SymbolAliasAtom<A>(it->alias, NULL, *target));
}
// add dtrace probe locations
if ( fHasDTraceProbes ) {
for (uint32_t i=0; i < fSymbolCount; ++i) {
const macho_nlist<P>& sym = fSymbols[i];
if ( (sym.n_type() & N_STAB) == 0 ) {
if ( (sym.n_type() & N_TYPE) == N_SECT ) {
const char* symbolName = &fStrings[sym.n_strx()];
if ( strncmp(symbolName, "__dtrace_probe$", 15) == 0 ) {
//fprintf(stderr, "adding dtrace probe at 0x%08llX %s\n", sym.n_value(), symbolName);
makeByNameReference(A::kDtraceProbe, sym.n_value(), symbolName, 0);
}
}
}
}
}
// turn indirect symbols into SymbolAliasAtom
if ( fHaveIndirectSymbols ) {
for (uint32_t i=0; i < fSymbolCount; ++i) {
const macho_nlist<P>& sym = fSymbols[i];
if ( (sym.n_type() & N_STAB) == 0 ) {
if ( (sym.n_type() & N_TYPE) == N_INDR ) {
const char* aliasName = &fStrings[sym.n_strx()];
const char* targetName = &fStrings[sym.n_value()];
//fprintf(stderr, "found alias %s for %s\n", aliasName, targetName);
BaseAtom* target = this->findAtomByName(targetName);
// only currently support N_INDR based aliases to something in the same .o file
if ( target != NULL ) {
fAtoms.push_back(new SymbolAliasAtom<A>(aliasName, &sym, *target));
//fprintf(stderr, "creating alias %s for %s\n", aliasName, targetName);
}
}
}
}
}
//for (typename AddrToAtomMap::iterator it=fAddrToAtom.begin(); it != fAddrToAtom.end(); it++) {
// fprintf(stderr, "[0x%0X -> 0x%0llX) : %s\n", it->first, it->first+it->second->getSize(), it->second->getDisplayName());
//}
// add translation unit info from dwarf
uint64_t stmtList;
if ( (fDebugInfo == kDebugInfoDwarf) && (fOptions.fDebugInfoStripping != ObjectFile::ReaderOptions::kDebugInfoNone) ) {
// compiler sometimes emits emtpty dwarf sections when there is no debug info, skip those
if ( (fDwarfDebugInfoSect != NULL) && (fDwarfDebugInfoSect->size() != 0) ) {
if ( !read_comp_unit(&fDwarfTranslationUnitFile, &fDwarfTranslationUnitDir, &stmtList) ) {
// if can't parse dwarf, warn and give up
fDwarfTranslationUnitFile = NULL;
fDwarfTranslationUnitDir = NULL;
warning("can't parse dwarf compilation unit info in %s", this->getPath());
fDebugInfo = kDebugInfoNone;
}
}
}
// add line number info to atoms from dwarf
if ( (fDebugInfo == kDebugInfoDwarf) && (fOptions.fDebugInfoStripping != ObjectFile::ReaderOptions::kDebugInfoNone) ) {
// file with just data will have no __debug_line info
if ( (fDwarfDebugLineSect != NULL) && (fDwarfDebugLineSect->size() != 0) && (fAddrToAtom.size() != 0)
&& (fDwarfDebugInfoSect != NULL) && (fDwarfDebugInfoSect->size() != 0) ) {
// validate stmt_list
if ( (stmtList != (uint64_t)-1) && (stmtList < fDwarfDebugLineSect->size()) ) {
const uint8_t* debug_line = (uint8_t*)(fHeader) + fDwarfDebugLineSect->offset();
if ( debug_line != NULL ) {
struct line_reader_data* lines = line_open(&debug_line[stmtList],
fDwarfDebugLineSect->size() - stmtList, E::little_endian);
struct line_info result;
ObjectFile::Atom* curAtom = NULL;
uint32_t curAtomOffset = 0;
uint32_t curAtomAddress = 0;
uint32_t curAtomSize = 0;
if ( lines != NULL ) {
while ( line_next (lines, &result, line_stop_pc) ) {
//fprintf(stderr, "curAtom=%p, result.pc=0x%llX, result.line=%llu, result.end_of_sequence=%d, curAtomAddress=0x%X, curAtomSize=0x%X\n",
// curAtom, result.pc, result.line, result.end_of_sequence, curAtomAddress, curAtomSize);
// work around weird debug line table compiler generates if no functions in __text section
if ( (curAtom == NULL) && (result.pc == 0) && result.end_of_sequence && (result.file == 1))
continue;
// for performance, see if in next pc is in current atom
if ( (curAtom != NULL) && (curAtomAddress <= result.pc) && (result.pc < (curAtomAddress+curAtomSize)) ) {
curAtomOffset = result.pc - curAtomAddress;
}
// or pc at end of current atom
else if ( result.end_of_sequence && (curAtom != NULL) && (result.pc == (curAtomAddress+curAtomSize)) ) {
curAtomOffset = result.pc - curAtomAddress;
}
else {
// do slow look up of atom by address
AtomAndOffset ao = this->findAtomAndOffset(result.pc);
curAtom = ao.atom;
if ( curAtom == NULL )
break; // file has line info but no functions
if ( result.end_of_sequence && (curAtomAddress+curAtomSize < result.pc) ) {
// a one line function can be returned by line_next() as one entry with pc at end of blob
// look for alt atom starting at end of previous atom
uint32_t previousEnd = curAtomAddress+curAtomSize;
AtomAndOffset alt = this->findAtomAndOffset(previousEnd);
if ( result.pc <= previousEnd - alt.offset + alt.atom->getSize() ) {
curAtom = alt.atom;
curAtomOffset = alt.offset;
curAtomAddress = previousEnd - alt.offset;
curAtomSize = curAtom->getSize();
}
else {
curAtomOffset = ao.offset;
curAtomAddress = result.pc - ao.offset;
curAtomSize = curAtom->getSize();
}
}
else {
curAtomOffset = ao.offset;
curAtomAddress = result.pc - ao.offset;
curAtomSize = curAtom->getSize();
}
}
const char* filename;
std::map<uint32_t,const char*>::iterator pos = fDwarfIndexToFile.find(result.file);
if ( pos == fDwarfIndexToFile.end() ) {
filename = line_file(lines, result.file);
fDwarfIndexToFile[result.file] = filename;
}
else {
filename = pos->second;
}
ObjectFile::LineInfo info;
info.atomOffset = curAtomOffset;
info.fileName = filename;
info.lineNumber = result.line;
//fprintf(stderr, "addr=0x%08llX, line=%lld, file=%s, atom=%s, atom.size=0x%X, end=%d\n",
// result.pc, result.line, filename, curAtom->getDisplayName(), curAtomSize, result.end_of_sequence);
((BaseAtom*)curAtom)->addLineInfo(info);
if ( result.end_of_sequence ) {
curAtom = NULL;
}
}
line_free(lines);
}
}
else {
warning("could not parse dwarf line number info in %s", this->getPath());
}
}
}
}
// if no dwarf, try processing stabs debugging info
if ( (fDebugInfo == kDebugInfoNone) && (fOptions.fDebugInfoStripping != ObjectFile::ReaderOptions::kDebugInfoNone) ) {
// scan symbol table for stabs entries
fStabs.reserve(fSymbolCount); // reduce re-allocations
BaseAtom* currentAtom = NULL;
pint_t currentAtomAddress = 0;
enum { start, inBeginEnd, inFun } state = start;
for (uint32_t symbolIndex = 0; symbolIndex < fSymbolCount; ++symbolIndex ) {
const macho_nlist<P>* sym = &fSymbols[symbolIndex];
bool useStab = true;
uint8_t type = sym->n_type();
const char* symString = (sym->n_strx() != 0) ? &fStrings[sym->n_strx()] : NULL;
if ( (type & N_STAB) != 0 ) {
fDebugInfo = (fHasUUID ? kDebugInfoStabsUUID : kDebugInfoStabs);
Stab stab;
stab.atom = NULL;
stab.type = type;
stab.other = sym->n_sect();
stab.desc = sym->n_desc();
stab.value = sym->n_value();
stab.string = NULL;
switch (state) {
case start:
switch (type) {
case N_BNSYM:
// beginning of function block
state = inBeginEnd;
// fall into case to lookup atom by addresss
case N_LCSYM:
case N_STSYM:
currentAtomAddress = sym->n_value();
currentAtom = (BaseAtom*)this->findAtomAndOffset(currentAtomAddress).atom;
if ( currentAtom != NULL ) {
stab.atom = currentAtom;
stab.string = symString;
}
else {
fprintf(stderr, "can't find atom for stabs BNSYM at %08llX in %s",
(uint64_t)sym->n_value(), path);
}
break;
case N_SO:
case N_OSO:
case N_OPT:
case N_LSYM:
case N_RSYM:
case N_PSYM:
// not associated with an atom, just copy
stab.string = symString;
break;
case N_GSYM:
{
// n_value field is NOT atom address ;-(
// need to find atom by name match
const char* colon = strchr(symString, ':');
if ( colon != NULL ) {
// build underscore leading name
int nameLen = colon - symString;
char symName[nameLen+2];
strlcpy(&symName[1], symString, nameLen+1);
symName[0] = '_';
symName[nameLen+1] = '\0';
currentAtom = findAtomByName(symName);
if ( currentAtom != NULL ) {
stab.atom = currentAtom;
stab.string = symString;
}
}
else {
// might be a debug-note without trailing :G()
currentAtom = findAtomByName(symString);
if ( currentAtom != NULL ) {
stab.atom = currentAtom;
stab.string = symString;
}
}
if ( stab.atom == NULL ) {
// ld_classic added bogus GSYM stabs for old style dtrace probes
if ( (strncmp(symString, "__dtrace_probe$", 15) != 0) )
warning("can't find atom for N_GSYM stabs %s in %s", symString, path);
useStab = false;
}
break;
}
case N_FUN:
// old style stabs without BNSYM
state = inFun;
currentAtomAddress = sym->n_value();
currentAtom = (BaseAtom*)this->findAtomAndOffset(currentAtomAddress).atom;
if ( currentAtom != NULL ) {
stab.atom = currentAtom;
stab.string = symString;
}
else {
warning("can't find atom for stabs FUN at %08llX in %s",
(uint64_t)currentAtomAddress, path);
}
break;
case N_SOL:
case N_SLINE:
stab.string = symString;
// old stabs
break;
case N_BINCL:
case N_EINCL:
case N_EXCL:
stab.string = symString;
// -gfull built .o file
break;
default:
warning("unknown stabs type 0x%X in %s", type, path);
}
break;
case inBeginEnd:
stab.atom = currentAtom;
switch (type) {
case N_ENSYM:
state = start;
currentAtom = NULL;
break;
case N_LCSYM:
case N_STSYM:
{
BaseAtom* nestedAtom = (BaseAtom*)this->findAtomAndOffset(sym->n_value()).atom;
if ( nestedAtom != NULL ) {
stab.atom = nestedAtom;
stab.string = symString;
}
else {
warning("can't find atom for stabs 0x%X at %08llX in %s",
type, (uint64_t)sym->n_value(), path);
}
break;
}
case N_LBRAC:
case N_RBRAC:
case N_SLINE:
// adjust value to be offset in atom
stab.value -= currentAtomAddress;
default:
stab.string = symString;
break;
}
break;
case inFun:
switch (type) {
case N_FUN:
if ( sym->n_sect() != 0 ) {
// found another start stab, must be really old stabs...
currentAtomAddress = sym->n_value();
currentAtom = (BaseAtom*)this->findAtomAndOffset(currentAtomAddress).atom;
if ( currentAtom != NULL ) {
stab.atom = currentAtom;
stab.string = symString;
}
else {
warning("can't find atom for stabs FUN at %08llX in %s",
(uint64_t)currentAtomAddress, path);
}
}
else {
// found ending stab, switch back to start state
stab.string = symString;
stab.atom = currentAtom;
state = start;
currentAtom = NULL;
}
break;
case N_LBRAC:
case N_RBRAC:
case N_SLINE:
// adjust value to be offset in atom
stab.value -= currentAtomAddress;
stab.atom = currentAtom;
break;
case N_SO:
stab.string = symString;
state = start;
break;
default:
stab.atom = currentAtom;
stab.string = symString;
break;
}
break;
}
// add to list of stabs for this .o file
if ( useStab )
fStabs.push_back(stab);
}
}
}
#if 0
// special case precompiled header .o file (which has no content) to have one empty atom
if ( fAtoms.size() == 0 ) {
int pathLen = strlen(path);
if ( (pathLen > 6) && (strcmp(&path[pathLen-6], ".gch.o")==0) ) {
ObjectFile::Atom* phony = new AnonymousAtom<A>(*this, (uint32_t)0);
//phony->fSynthesizedName = ".gch.o";
fAtoms.push_back(phony);
}
}
#endif
// sort all atoms by address
std::sort(fAtoms.begin(), fAtoms.end(), BaseAtomSorter());
// set ordinal and sort references in each atom
uint32_t index = fOrdinalBase;
for (std::vector<BaseAtom*>::iterator it=fAtoms.begin(); it != fAtoms.end(); it++) {
BaseAtom* atom = (BaseAtom*)(*it);
atom->setOrdinal(index++);
atom->sortReferences();
}
}
template <typename A>
const macho_section<typename A::P>* Reader<A>::getSectionForAddress(pint_t addr)
{
for (const macho_section<P>* sect=fSectionsStart; sect < fSectionsEnd; ++sect) {
if ( (sect->addr() <= addr) && (addr < (sect->addr()+sect->size())) )
return sect;
}
throwf("section not found for address 0x%08llX", (uint64_t)addr);
}
template <typename A>
ObjectFile::Atom* Reader<A>::getFunctionAtomFromFDEAddress(pint_t addr)
{
for (typename std::vector<FDE_Atom_Info>::const_iterator it = fFDEInfos.begin(); it != fFDEInfos.end(); ++it) {
if ( it->fdeAddress == addr ) {
return findAtomAndOffset(it->function.address).atom;
}
}
// CIEs won't be in fFDEInfos
return NULL;
}
template <typename A>
ObjectFile::Atom* Reader<A>::getFunctionAtomFromLSDAAddress(pint_t addr)
{
for (typename std::vector<FDE_Atom_Info>::const_iterator it = fFDEInfos.begin(); it != fFDEInfos.end(); ++it) {
if ( it->lsda.address == addr ) {
return findAtomAndOffset(it->function.address).atom;
}
}
return NULL;
}
template <>
void ObjectFileAddressSpace<x86_64>::buildRelocatedMap(const macho_section<P>* sect, std::map<uint32_t,uint64_t>& map)
{
// mach-o x86_64 is different, the content of a section with a relocation is the addend
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fReader.fHeader) + sect->reloff());
const macho_relocation_info<P>* relocsEnd = &relocs[sect->nreloc()];
for (const macho_relocation_info<P>* reloc = relocs; reloc < relocsEnd; ++reloc) {
std::map<uint32_t,uint64_t>::iterator pos;
switch ( reloc->r_type() ) {
case X86_64_RELOC_UNSIGNED:
pos = map.find(reloc->r_address());
if ( pos != map.end() )
pos->second += fReader.fSymbols[reloc->r_symbolnum()].n_value();
else
map[reloc->r_address()] = fReader.fSymbols[reloc->r_symbolnum()].n_value();
break;
case X86_64_RELOC_SUBTRACTOR:
map[reloc->r_address()] = -fReader.fSymbols[reloc->r_symbolnum()].n_value();
break;
case X86_64_RELOC_GOT:
// there is no good address to return here.
// GOT slots are synthsized by the linker
// this is used for the reference to the personality function in CIEs
map[reloc->r_address()] = 0;
break;
default:
fprintf(stderr, "ObjectFileAddressSpace::buildRelocatedMap() unexpected relocation at r_address=0x%08X\n", reloc->r_address());
break;
}
}
}
template <typename A>
void ObjectFileAddressSpace<A>::buildRelocatedMap(const macho_section<P>* sect, std::map<uint32_t,uint64_t>& map)
{
// in all architectures except x86_64, the section contents are already fixed up to point
// to content in the same object file.
}
template <>
uint64_t ObjectFileAddressSpace<x86_64>::relocated(uint32_t sectOffset, uint32_t relocsOffset, uint32_t relocsCount)
{
// mach-o x86_64 is different, the content of a section with a relocation is the addend
uint64_t result = 0;
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fReader.fHeader) + relocsOffset);
const macho_relocation_info<P>* relocsEnd = &relocs[relocsCount];
for (const macho_relocation_info<P>* reloc = relocs; reloc < relocsEnd; ++reloc) {
//fprintf(stderr, "ObjectFileAddressSpace::relocated(0x%08X), r_address=0x%08X\n", sectOffset, reloc->r_address());
if ( reloc->r_address() == sectOffset ) {
switch ( reloc->r_type() ) {
case X86_64_RELOC_UNSIGNED:
result += fReader.fSymbols[reloc->r_symbolnum()].n_value();
break;
case X86_64_RELOC_SUBTRACTOR:
result -= fReader.fSymbols[reloc->r_symbolnum()].n_value();
break;
case X86_64_RELOC_GOT:
// there is no good address to return here.
// GOT slots are synthsized by the linker
// this is used for the reference to the personality function in CIEs
result = 0;
break;
default:
fprintf(stderr, "ObjectFileAddressSpace::relocated(0x%08X) => type=%d, value=0x%08X\n", sectOffset, reloc->r_type(), reloc->r_symbolnum());
break;
}
}
}
//fprintf(stderr, "ObjectFileAddressSpace::relocated(0x%08X) => 0x%0llX\n", sectOffset, result);
return result;
}
template <typename A>
typename A::P::uint_t ObjectFileAddressSpace<A>::relocated(uint32_t sectOffset, uint32_t relocsOffset, uint32_t relocsCount)
{
// in all architectures except x86_64, the section contents are already fixed up to point
// to content in the same object file.
return 0;
}
// FSF exception handling Pointer-Encoding constants
// Used in CFI augmentation by gcc compiler
enum {
DW_EH_PE_ptr = 0x00,
DW_EH_PE_uleb128 = 0x01,
DW_EH_PE_udata2 = 0x02,
DW_EH_PE_udata4 = 0x03,
DW_EH_PE_udata8 = 0x04,
DW_EH_PE_signed = 0x08,
DW_EH_PE_sleb128 = 0x09,
DW_EH_PE_sdata2 = 0x0A,
DW_EH_PE_sdata4 = 0x0B,
DW_EH_PE_sdata8 = 0x0C,
DW_EH_PE_absptr = 0x00,
DW_EH_PE_pcrel = 0x10,
DW_EH_PE_textrel = 0x20,
DW_EH_PE_datarel = 0x30,
DW_EH_PE_funcrel = 0x40,
DW_EH_PE_aligned = 0x50,
DW_EH_PE_indirect = 0x80,
DW_EH_PE_omit = 0xFF
};
template <>
void Reader<x86_64>::addCiePersonalityReference(BaseAtom* cieAtom, uint32_t offsetInCIE, uint8_t encoding)
{
if ( encoding != (DW_EH_PE_indirect|DW_EH_PE_pcrel|DW_EH_PE_sdata4) )
throw "unexpected personality encoding in CIE";
// walk relocs looking for reloc in this CIE
uint32_t sectOffset = (cieAtom->getObjectAddress() + offsetInCIE) - fehFrameSection->addr();
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fHeader) + fehFrameSection->reloff());
const macho_relocation_info<P>* relocsEnd = &relocs[fehFrameSection->nreloc()];
for (const macho_relocation_info<P>* reloc = relocs; reloc < relocsEnd; ++reloc) {
if ( reloc->r_address() == sectOffset ) {
switch ( reloc->r_type() ) {
case X86_64_RELOC_GOT:
if ( !reloc->r_extern() )
throw "GOT reloc not extern for personality function";
new Reference<x86_64>(x86_64::kPCRel32GOT, AtomAndOffset(cieAtom, offsetInCIE), &fStrings[fSymbols[reloc->r_symbolnum()].n_strx()], 4);
return;
default:
throw "expected GOT reloc for personality function";
}
}
}
throw "personality function not found for CIE";
}
template <>
bool Reader<ppc>::isSectDiffReloc(uint8_t r_type)
{
switch ( r_type ) {
case PPC_RELOC_LOCAL_SECTDIFF:
case PPC_RELOC_SECTDIFF:
return true;
}
return false;
}
template <>
bool Reader<ppc64>::isSectDiffReloc(uint8_t r_type)
{
switch ( r_type ) {
case PPC_RELOC_LOCAL_SECTDIFF:
case PPC_RELOC_SECTDIFF:
return true;
}
return false;
}
template <>
bool Reader<x86>::isSectDiffReloc(uint8_t r_type)
{
switch ( r_type ) {
case GENERIC_RELOC_LOCAL_SECTDIFF:
case GENERIC_RELOC_SECTDIFF:
return true;
}
return false;
}
template <>
bool Reader<arm>::isSectDiffReloc(uint8_t r_type)
{
switch ( r_type ) {
case ARM_RELOC_LOCAL_SECTDIFF:
case ARM_RELOC_SECTDIFF:
return true;
}
return false;
}
template <typename A>
void Reader<A>::addCiePersonalityReference(BaseAtom* cieAtom, uint32_t offsetInCIE, uint8_t encoding)
{
if ( (encoding != (DW_EH_PE_indirect|DW_EH_PE_pcrel|DW_EH_PE_sdata4)) && (encoding != (DW_EH_PE_indirect|DW_EH_PE_pcrel)) )
throw "unexpected personality encoding in CIE";
// walk relocs looking for personality reloc in this CIE
uint32_t sectOffset = (cieAtom->getObjectAddress() + offsetInCIE) - fehFrameSection->addr();
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fHeader) + fehFrameSection->reloff());
const macho_relocation_info<P>* relocsEnd = &relocs[fehFrameSection->nreloc()];
for (const macho_relocation_info<P>* reloc = relocs; reloc < relocsEnd; ++reloc) {
if ( (reloc->r_address() & R_SCATTERED) == 0 ) {
// ignore
}
else {
const macho_scattered_relocation_info<P>* sreloc = (macho_scattered_relocation_info<P>*)reloc;
if ( sreloc->r_address() == sectOffset ) {
if ( isSectDiffReloc(sreloc->r_type()) ) {
// r_value is address of non-lazy-pointer to personality function
new Reference<A>(A::kPointerDiff32, AtomAndOffset(cieAtom, offsetInCIE), AtomAndOffset(cieAtom, offsetInCIE),
findAtomAndOffset(sreloc->r_value()));
return;
}
}
}
}
throw "can't find relocation for personality in CIE";
}
template <typename A>
void Reader<A>::addFdeReference(uint8_t encoding, AtomAndOffset inFDE, AtomAndOffset target)
{
if ( (encoding & 0xF0) != DW_EH_PE_pcrel )
throw "unsupported encoding in FDE";
Kinds kind = A::kNoFixUp;
switch ( encoding & 0xF ) {
case DW_EH_PE_ptr:
kind = A::kPointerDiff;
break;
case DW_EH_PE_sdata4:
kind = A::kPointerDiff32;
break;
default:
throw "unsupported encoding in FDE";
}
new Reference<A>(kind, inFDE, inFDE, target);
}
template <typename A>
typename A::P::uint_t ObjectFileAddressSpace<A>::getEncodedP(pint_t& addr, pint_t end, uint8_t encoding)
{
pint_t startAddr = addr;
pint_t p = addr;
pint_t result;
// first get value
switch (encoding & 0x0F) {
case DW_EH_PE_ptr:
result = getP(addr);
p += sizeof(pint_t);
addr = (pint_t)p;
break;
case DW_EH_PE_uleb128:
result = getULEB128(addr, end);
break;
case DW_EH_PE_udata2:
result = get16(addr);
p += 2;
addr = (pint_t)p;
break;
case DW_EH_PE_udata4:
result = get32(addr);
p += 4;
addr = (pint_t)p;
break;
case DW_EH_PE_udata8:
result = get64(addr);
p += 8;
addr = (pint_t)p;
break;
case DW_EH_PE_sleb128:
result = getSLEB128(addr, end);
break;
case DW_EH_PE_sdata2:
result = (int16_t)get16(addr);
p += 2;
addr = (pint_t)p;
break;
case DW_EH_PE_sdata4:
result = (int32_t)get32(addr);
p += 4;
addr = (pint_t)p;
break;
case DW_EH_PE_sdata8:
result = get64(addr);
p += 8;
addr = (pint_t)p;
break;
default:
throwf("ObjectFileAddressSpace<A>::getEncodedP() encoding 0x%08X not supported", encoding);
}
// then add relative offset
switch ( encoding & 0x70 ) {
case DW_EH_PE_absptr:
// do nothing
break;
case DW_EH_PE_pcrel:
result += startAddr;
break;
case DW_EH_PE_textrel:
throw "DW_EH_PE_textrel pointer encoding not supported";
break;
case DW_EH_PE_datarel:
throw "DW_EH_PE_datarel pointer encoding not supported";
break;
case DW_EH_PE_funcrel:
throw "DW_EH_PE_funcrel pointer encoding not supported";
break;
case DW_EH_PE_aligned:
throw "DW_EH_PE_aligned pointer encoding not supported";
break;
default:
throwf("ObjectFileAddressSpace<A>::getEncodedP() encoding 0x%08X not supported", encoding);
break;
}
if ( encoding & DW_EH_PE_indirect )
result = getP(result);
return result;
}
template <>
uint32_t SymbolAtom<x86>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
pint_t lsda;
pint_t personality;
char warningBuffer[1024];
uint32_t result = libunwind::DwarfInstructions<class ObjectFileAddressSpace<x86>, libunwind::Registers_x86>::createCompactEncodingFromFDE(
fOwner.fObjectAddressSpace, ehAtomAddress, &lsda, &personality, warningBuffer);
if ( (result & UNWIND_X86_MODE_MASK) == UNWIND_X86_MODE_DWARF ) {
//if ( fOwner.fOptions.fForDyld )
// throwf("can't make compact unwind encoding from dwarf for %s", this->getDisplayName());
//else
if ( fOwner.fOptions.fWarnCompactUnwind )
warning("can't make compact unwind encoding from dwarf for %s in %s because %s", this->getDisplayName(), fOwner.getPath(), warningBuffer);
}
return result;
}
template <>
uint32_t SymbolAtom<x86_64>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
pint_t lsda;
pint_t personality;
char warningBuffer[1024];
uint32_t result = libunwind::DwarfInstructions<class ObjectFileAddressSpace<x86_64>, libunwind::Registers_x86_64>::createCompactEncodingFromFDE(
fOwner.fObjectAddressSpace, ehAtomAddress, &lsda, &personality, warningBuffer);
if ( (result & UNWIND_X86_64_MODE_MASK) == UNWIND_X86_64_MODE_DWARF ) {
//if ( fOwner.fOptions.fForDyld )
// throwf("can't make compact unwind encoding from dwarf for %s", this->getDisplayName());
//else
if ( fOwner.fOptions.fWarnCompactUnwind )
warning("can't make compact unwind encoding from dwarf for %s in %s because %s", this->getDisplayName(), fOwner.getPath(), warningBuffer);
}
return result;
}
template <>
uint32_t SymbolAtom<ppc>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for ppc
return 0;
}
template <>
uint32_t SymbolAtom<ppc64>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for ppc64
return 0;
}
template <>
uint32_t SymbolAtom<arm>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for arm
return 0;
}
template <typename A>
uint8_t SymbolAtom<A>::getLSDAReferenceKind() const
{
return A::kGroupSubordinate;
}
template <>
uint8_t SymbolAtom<x86_64>::getPersonalityReferenceKind() const
{
return x86_64::kGOTNoFixUp;
}
template <>
uint8_t SymbolAtom<x86>::getPersonalityReferenceKind() const
{
return x86::kNoFixUp;
}
template <typename A>
uint8_t SymbolAtom<A>::getPersonalityReferenceKind() const
{
// only used with architectures that support compact unwinding
return 0;
}
template <>
uint32_t AnonymousAtom<x86>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
pint_t lsda;
pint_t personality;
char warningBuffer[1024];
uint32_t result = libunwind::DwarfInstructions<class ObjectFileAddressSpace<x86>, libunwind::Registers_x86>::createCompactEncodingFromFDE(
fOwner.fObjectAddressSpace, ehAtomAddress, &lsda, &personality, warningBuffer);
if ( (result & UNWIND_X86_MODE_MASK) == UNWIND_X86_MODE_DWARF ) {
//if ( fOwner.fOptions.fForDyld )
// throwf("can't make compact unwind encoding from dwarf for %s", this->getDisplayName());
//else
if ( fOwner.fOptions.fWarnCompactUnwind )
warning("can't make compact unwind encoding from dwarf for %s in %s", this->getDisplayName(), fOwner.getPath());
}
return result;
}
template <>
uint32_t AnonymousAtom<x86_64>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
pint_t lsda;
pint_t personality;
char warningBuffer[1024];
uint32_t result = libunwind::DwarfInstructions<class ObjectFileAddressSpace<x86_64>, libunwind::Registers_x86_64>::createCompactEncodingFromFDE(
fOwner.fObjectAddressSpace, ehAtomAddress, &lsda, &personality, warningBuffer);
if ( (result & UNWIND_X86_64_MODE_MASK) == UNWIND_X86_64_MODE_DWARF ) {
//if ( fOwner.fOptions.fForDyld )
// throwf("can't make compact unwind encoding from dwarf for %s", this->getDisplayName());
//else
if ( fOwner.fOptions.fWarnCompactUnwind )
warning("can't make compact unwind encoding from dwarf for %s in %s", this->getDisplayName(), fOwner.getPath());
}
return result;
}
template <>
uint32_t AnonymousAtom<ppc>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for ppc
return 0;
}
template <>
uint32_t AnonymousAtom<ppc64>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for ppc64
return 0;
}
template <>
uint32_t AnonymousAtom<arm>::getCompactUnwindEncoding(uint64_t ehAtomAddress)
{
// compact encoding not supported for arm
return 0;
}
template <typename A>
uint8_t AnonymousAtom<A>::getLSDAReferenceKind() const
{
return A::kGroupSubordinate;
}
template <>
uint8_t AnonymousAtom<x86_64>::getPersonalityReferenceKind() const
{
return x86_64::kGOTNoFixUp;
}
template <>
uint8_t AnonymousAtom<x86>::getPersonalityReferenceKind() const
{
return x86::kNoFixUp;
}
template <typename A>
uint8_t AnonymousAtom<A>::getPersonalityReferenceKind() const
{
// only used with architectures that support compact unwinding
return 0;
}
template <>
void Reader<ppc>::setCpuConstraint(uint32_t cpusubtype)
{
switch (cpusubtype) {
case CPU_SUBTYPE_POWERPC_ALL:
case CPU_SUBTYPE_POWERPC_750:
case CPU_SUBTYPE_POWERPC_7400:
case CPU_SUBTYPE_POWERPC_7450:
case CPU_SUBTYPE_POWERPC_970:
fCpuConstraint = cpusubtype;
break;
default:
warning("unknown ppc subtype 0x%08X in %s, defaulting to ALL", cpusubtype, fPath);
fCpuConstraint = CPU_SUBTYPE_POWERPC_ALL;
break;
}
}
template <>
void Reader<arm>::setCpuConstraint(uint32_t cpusubtype)
{
switch (cpusubtype) {
case CPU_SUBTYPE_ARM_ALL:
case CPU_SUBTYPE_ARM_V4T:
case CPU_SUBTYPE_ARM_V5TEJ:
case CPU_SUBTYPE_ARM_V6:
case CPU_SUBTYPE_ARM_XSCALE:
case CPU_SUBTYPE_ARM_V7:
fCpuConstraint = cpusubtype;
break;
default:
warning("unknown arm subtype 0x%08X in %s, defaulting to ALL", cpusubtype, fPath);
fCpuConstraint = CPU_SUBTYPE_ARM_ALL;
break;
}
}
template <typename A>
void Reader<A>::setCpuConstraint(uint32_t cpusubtype)
{
// no cpu sub types for this architecture
}
template <>
uint32_t Reader<ppc>::updateCpuConstraint(uint32_t previous)
{
switch ( previous ) {
case CPU_SUBTYPE_POWERPC_ALL:
return fCpuConstraint;
break;
case CPU_SUBTYPE_POWERPC_750:
if ( fCpuConstraint == CPU_SUBTYPE_POWERPC_7400 ||
fCpuConstraint == CPU_SUBTYPE_POWERPC_7450 ||
fCpuConstraint == CPU_SUBTYPE_POWERPC_970 )
return fCpuConstraint;
break;
case CPU_SUBTYPE_POWERPC_7400:
case CPU_SUBTYPE_POWERPC_7450:
if ( fCpuConstraint == CPU_SUBTYPE_POWERPC_970 )
return fCpuConstraint;
break;
case CPU_SUBTYPE_POWERPC_970:
// G5 can run everything
break;
default:
throw "Unhandled PPC cpu subtype!";
break;
}
return previous;
}
template <>
uint32_t Reader<arm>::updateCpuConstraint(uint32_t previous)
{
switch (previous) {
case CPU_SUBTYPE_ARM_ALL:
return fCpuConstraint;
break;
case CPU_SUBTYPE_ARM_V5TEJ:
// v6, v7, and xscale are more constrained than previous file (v5), so use it
if ( (fCpuConstraint == CPU_SUBTYPE_ARM_V6)
|| (fCpuConstraint == CPU_SUBTYPE_ARM_V7)
|| (fCpuConstraint == CPU_SUBTYPE_ARM_XSCALE) )
return fCpuConstraint;
break;
case CPU_SUBTYPE_ARM_V4T:
// v5, v6, v7, and xscale are more constrained than previous file (v4t), so use it
if ( (fCpuConstraint == CPU_SUBTYPE_ARM_V7)
|| (fCpuConstraint == CPU_SUBTYPE_ARM_V6)
|| (fCpuConstraint == CPU_SUBTYPE_ARM_V5TEJ)
|| (fCpuConstraint == CPU_SUBTYPE_ARM_XSCALE) )
return fCpuConstraint;
break;
case CPU_SUBTYPE_ARM_V6:
// v6 can run everything except xscale and v7
if ( fCpuConstraint == CPU_SUBTYPE_ARM_XSCALE )
throw "can't mix xscale and v6 code";
if ( fCpuConstraint == CPU_SUBTYPE_ARM_V7 )
return fCpuConstraint;
break;
case CPU_SUBTYPE_ARM_XSCALE:
// xscale can run everything except v6 and v7
if ( fCpuConstraint == CPU_SUBTYPE_ARM_V6 )
throw "can't mix xscale and v6 code";
if ( fCpuConstraint == CPU_SUBTYPE_ARM_V7 )
throw "can't mix xscale and v7 code";
break;
case CPU_SUBTYPE_ARM_V7:
// v7 can run everything except xscale
if ( fCpuConstraint == CPU_SUBTYPE_ARM_XSCALE )
throw "can't mix xscale and v7 code";
break;
default:
throw "Unhandled ARM cpu subtype!";
}
return previous;
}
template <typename A>
uint32_t Reader<A>::updateCpuConstraint(uint32_t current)
{
// no cpu sub types for this architecture
return current;
}
template <typename A>
void Reader<A>::addDtraceExtraInfos(uint32_t probeAddr, const char* providerName)
{
// for every ___dtrace_stability$* and ___dtrace_typedefs$* undefine with
// a matching provider name, add a by-name kDtraceTypeReference at probe site
const char* dollar = strchr(providerName, '$');
if ( dollar != NULL ) {
int providerNameLen = dollar-providerName+1;
for ( std::vector<const char*>::iterator it = fDtraceProviderInfo.begin(); it != fDtraceProviderInfo.end(); ++it) {
const char* typeDollar = strchr(*it, '$');
if ( typeDollar != NULL ) {
if ( strncmp(typeDollar+1, providerName, providerNameLen) == 0 ) {
makeByNameReference(A::kDtraceTypeReference, probeAddr, *it, 0);
}
}
}
}
}
template <>
void Reader<x86_64>::validSectionType(uint8_t type)
{
switch ( type ) {
case S_SYMBOL_STUBS:
throw "symbol_stub sections not valid in x86_64 object files";
case S_LAZY_SYMBOL_POINTERS:
throw "lazy pointer sections not valid in x86_64 object files";
case S_NON_LAZY_SYMBOL_POINTERS:
throw "non lazy pointer sections not valid in x86_64 object files";
}
}
template <typename A>
void Reader<A>::validSectionType(uint8_t type)
{
}
template <typename A>
bool Reader<A>::getTranslationUnitSource(const char** dir, const char** name) const
{
if ( fDebugInfo == kDebugInfoDwarf ) {
*dir = fDwarfTranslationUnitDir;
*name = fDwarfTranslationUnitFile;
return (fDwarfTranslationUnitFile != NULL);
}
return false;
}
template <typename A>
BaseAtom* Reader<A>::findAtomByName(const char* name)
{
// first search the more important atoms
for (typename AddrToAtomMap::iterator it=fAddrToAtom.begin(); it != fAddrToAtom.end(); it++) {
const char* atomName = it->second->getName();
if ( (atomName != NULL) && (strcmp(atomName, name) == 0) ) {
return it->second;
}
}
// try all atoms, because this might have been a tentative definition
for (std::vector<BaseAtom*>::iterator it=fAtoms.begin(); it != fAtoms.end(); it++) {
BaseAtom* atom = (BaseAtom*)(*it);
const char* atomName = atom->getName();
if ( (atomName != NULL) && (strcmp(atomName, name) == 0) ) {
return atom;
}
}
return NULL;
}
template <typename A>
Reference<A>* Reader<A>::makeReference(Kinds kind, pint_t atAddr, pint_t toAddr)
{
return new Reference<A>(kind, findAtomAndOffset(atAddr), findAtomAndOffset(toAddr));
}
template <typename A>
Reference<A>* Reader<A>::makeReference(Kinds kind, pint_t atAddr, pint_t fromAddr, pint_t toAddr)
{
return new Reference<A>(kind, findAtomAndOffset(atAddr), findAtomAndOffset(fromAddr), findAtomAndOffset(toAddr));
}
template <typename A>
Reference<A>* Reader<A>::makeReferenceWithToBase(Kinds kind, pint_t atAddr, pint_t toAddr, pint_t toBaseAddr)
{
return new Reference<A>(kind, findAtomAndOffset(atAddr), findAtomAndOffset(toBaseAddr, toAddr));
}
template <typename A>
Reference<A>* Reader<A>::makeReferenceWithToBase(Kinds kind, pint_t atAddr, pint_t fromAddr, pint_t toAddr, pint_t toBaseAddr)
{
return new Reference<A>(kind, findAtomAndOffset(atAddr), findAtomAndOffset(fromAddr), findAtomAndOffset(toBaseAddr, toAddr));
}
template <typename A>
Reference<A>* Reader<A>::makeByNameReference(Kinds kind, pint_t atAddr, const char* toName, uint32_t toOffset)
{
return new Reference<A>(kind, findAtomAndOffset(atAddr), toName, toOffset);
}
template <typename A>
BaseAtom* Reader<A>::makeReferenceToEH(const char* ehName, pint_t ehAtomAddress, const macho_section<P>* ehSect)
{
// add a group subordinate reference from function atom to its eh frame atom
const uint8_t* ehContent = (const uint8_t*)(fHeader) + ehAtomAddress - ehSect->addr() + ehSect->offset();
int32_t deltaMinus8 = P::getP(*(pint_t*)(&ehContent[8])); // offset 8 in eh info is delta to function
pint_t funcAddr = ehAtomAddress + deltaMinus8 + 8;
ObjectFile::Atom* funcAtom = findAtomAndOffset(funcAddr).atom;
ObjectFile::Atom* ehAtom = findAtomAndOffset(ehAtomAddress).atom;
new Reference<A>(A::kGroupSubordinate, funcAtom, ehAtom);
return (BaseAtom*)funcAtom;
}
template <>
Reference<x86_64>* Reader<x86_64>::makeByNameReference(Kinds kind, pint_t atAddr, const char* toName, uint32_t toOffset)
{
// x86_64 uses external relocations everywhere, so external relocations do not imply by-name references
// instead check scope of target
BaseAtom* target = findAtomByName(toName);
if ( (target != NULL) && (target->getScope() == ObjectFile::Atom::scopeTranslationUnit) )
return new Reference<x86_64>(kind, findAtomAndOffset(atAddr), AtomAndOffset(target, toOffset));
else
return new Reference<x86_64>(kind, findAtomAndOffset(atAddr), toName, toOffset);
}
template <>
Reference<x86_64>* Reader<x86_64>::makeReferenceToSymbol(Kinds kind, pint_t atAddr, const macho_nlist<P>* toSymbol, pint_t toOffset)
{
// x86_64 uses external relocations everywhere, so external relocations do not imply by-name references
// instead check scope of target
const char* symbolName = &fStrings[toSymbol->n_strx()];
if ( ((toSymbol->n_type() & N_TYPE) == N_SECT) && (((toSymbol->n_type() & N_EXT) == 0) || (symbolName[0] == 'L')) ) {
AtomAndOffset targetAO = findAtomAndOffsetForSection(toSymbol->n_value(), toSymbol->n_sect());
targetAO.offset = toOffset;
return new Reference<x86_64>(kind, findAtomAndOffset(atAddr), targetAO);
}
else
return new Reference<x86_64>(kind, findAtomAndOffset(atAddr), symbolName, toOffset);
}
template <>
BaseAtom* Reader<x86_64>::makeReferenceToEH(const char* ehName, pint_t ehAtomAddress, const macho_section<P>* ehSect)
{
// add a group subordinate reference from function atom to its eh frame atom
// for x86_64 the __eh_frame section contains the addends, so need to use relocs to find target
uint32_t ehAtomDeltaSectionOffset = ehAtomAddress + 8 - ehSect->addr(); // offset 8 in eh info is delta to function
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fHeader) + ehSect->reloff());
const macho_relocation_info<P>* relocsEnd = &relocs[ehSect->nreloc()];
for (const macho_relocation_info<P>* reloc = relocs; reloc < relocsEnd; ++reloc) {
if ( (reloc->r_address() == ehAtomDeltaSectionOffset) && (reloc->r_type() == X86_64_RELOC_UNSIGNED) ) {
pint_t funcAddr = fSymbols[reloc->r_symbolnum()].n_value();
ObjectFile::Atom* funcAtom = findAtomAndOffset(funcAddr).atom;
ObjectFile::Atom* ehAtom = findAtomAndOffset(ehAtomAddress).atom;
new Reference<x86_64>(x86_64::kGroupSubordinate, funcAtom, ehAtom);
return (BaseAtom*)funcAtom;
}
}
warning("can't find matching function for eh symbol %s", ehName);
return NULL;
}
template <typename A>
AtomAndOffset Reader<A>::findAtomAndOffsetForSection(pint_t addr, unsigned int expectedSectionIndex)
{
AtomAndOffset ao = findAtomAndOffset(addr);
if ( ao.atom != NULL ) {
if ( ((BaseAtom*)(ao.atom))->getSectionIndex() == expectedSectionIndex )
return ao;
}
// The atom found is not in the section expected.
// This probably means there was a label at the end of the section.
// Do a slow sequential lookup
for (std::vector<BaseAtom*>::iterator it=fAtoms.begin(); it != fAtoms.end(); ++it) {
BaseAtom* atom = *it;
if ( atom->getSectionIndex() == expectedSectionIndex ) {
pint_t objAddr = atom->getObjectAddress();
if ( (objAddr == addr) || ((objAddr < addr) && (objAddr+atom->getSize() > addr)) ) {
return AtomAndOffset(atom, addr-atom->getObjectAddress());
}
}
}
// no atom found that matched section, fall back to one orginally found
return ao;
}
template <typename A>
AtomAndOffset Reader<A>::findAtomAndOffset(pint_t addr)
{
// STL has no built-in for "find largest key that is same or less than"
typename AddrToAtomMap::iterator it = fAddrToAtom.upper_bound(addr);
// if no atoms up to this address return none found
if ( it == fAddrToAtom.begin() )
return AtomAndOffset(NULL);
// otherwise upper_bound gets us next key, so we back up one
--it;
AtomAndOffset result;
result.atom = it->second;
result.offset = addr - it->first;
//fprintf(stderr, "findAtomAndOffset(0x%0llX) ==> %s (0x%0llX -> 0x%0llX)\n",
// (uint64_t)addr, result.atom->getDisplayName(), (uint64_t)it->first, it->first+result.atom->getSize());
return result;
}
// "scattered" relocations enable you to offset into an atom past the end of it
// baseAddr is the address of the target atom,
// realAddr is the points into it
template <typename A>
AtomAndOffset Reader<A>::findAtomAndOffset(pint_t baseAddr, pint_t realAddr)
{
typename AddrToAtomMap::iterator it = fAddrToAtom.find(baseAddr);
if ( it != fAddrToAtom.end() ) {
AtomAndOffset result;
result.atom = it->second;
result.offset = realAddr - it->first;
if ( result.atom->isThumb() )
result.offset &= -2;
//fprintf(stderr, "findAtomAndOffset(0x%08X, 0x%08X) => %s + 0x%08X\n", baseAddr, realAddr, result.atom->getDisplayName(), result.offset);
return result;
}
// getting here means we have a scattered relocation to an address without a label
// so, find the atom that contains the baseAddr, and offset from that to the readAddr
AtomAndOffset result = findAtomAndOffset(baseAddr);
result.offset += (realAddr-baseAddr);
return result;
}
/* Skip over a LEB128 value (signed or unsigned). */
static void
skip_leb128 (const uint8_t ** offset, const uint8_t * end)
{
while (*offset != end && **offset >= 0x80)
(*offset)++;
if (*offset != end)
(*offset)++;
}
/* Read a ULEB128 into a 64-bit word. Return (uint64_t)-1 on overflow
or error. On overflow, skip past the rest of the uleb128. */
static uint64_t
read_uleb128 (const uint8_t ** offset, const uint8_t * end)
{
uint64_t result = 0;
int bit = 0;
do {
uint64_t b;
if (*offset == end)
return (uint64_t) -1;
b = **offset & 0x7f;
if (bit >= 64 || b << bit >> bit != b)
result = (uint64_t) -1;
else
result |= b << bit, bit += 7;
} while (*(*offset)++ >= 0x80);
return result;
}
/* Skip over a DWARF attribute of form FORM. */
template <typename A>
bool Reader<A>::skip_form(const uint8_t ** offset, const uint8_t * end, uint64_t form,
uint8_t addr_size, bool dwarf64)
{
int64_t sz=0;
switch (form)
{
case DW_FORM_addr:
sz = addr_size;
break;
case DW_FORM_block2:
if (end - *offset < 2)
return false;
sz = 2 + A::P::E::get16(*(uint16_t*)offset);
break;
case DW_FORM_block4:
if (end - *offset < 4)
return false;
sz = 2 + A::P::E::get32(*(uint32_t*)offset);
break;
case DW_FORM_data2:
case DW_FORM_ref2:
sz = 2;
break;
case DW_FORM_data4:
case DW_FORM_ref4:
sz = 4;
break;
case DW_FORM_data8:
case DW_FORM_ref8:
sz = 8;
break;
case DW_FORM_string:
while (*offset != end && **offset)
++*offset;
case DW_FORM_data1:
case DW_FORM_flag:
case DW_FORM_ref1:
sz = 1;
break;
case DW_FORM_block:
sz = read_uleb128 (offset, end);
break;
case DW_FORM_block1:
if (*offset == end)
return false;
sz = 1 + **offset;
break;
case DW_FORM_sdata:
case DW_FORM_udata:
case DW_FORM_ref_udata:
skip_leb128 (offset, end);
return true;
case DW_FORM_strp:
case DW_FORM_ref_addr:
sz = 4;
break;
default:
return false;
}
if (end - *offset < sz)
return false;
*offset += sz;
return true;
}
template <typename A>
const char* Reader<A>::getDwarfString(uint64_t form, const uint8_t* p)
{
if ( form == DW_FORM_string )
return (const char*)p;
else if ( form == DW_FORM_strp ) {
uint32_t offset = E::get32(*((uint32_t*)p));
const char* dwarfStrings = (char*)(fHeader) + fDwarfDebugStringSect->offset();
if ( offset > fDwarfDebugStringSect->size() ) {
warning("unknown dwarf DW_FORM_strp (offset=0x%08X) is too big in %s\n", offset, this->getPath());
return NULL;
}
return &dwarfStrings[offset];
}
warning("unknown dwarf string encoding (form=%lld) in %s\n", form, this->getPath());
return NULL;
}
// Look at the compilation unit DIE and determine
// its NAME, compilation directory (in COMP_DIR) and its
// line number information offset (in STMT_LIST). NAME and COMP_DIR
// may be NULL (especially COMP_DIR) if they are not in the .o file;
// STMT_LIST will be (uint64_t) -1.
//
// At present this assumes that there's only one compilation unit DIE.
//
template <typename A>
bool Reader<A>::read_comp_unit(const char ** name, const char ** comp_dir,
uint64_t *stmt_list)
{
const uint8_t * debug_info;
const uint8_t * debug_abbrev;
const uint8_t * di;
const uint8_t * da;
const uint8_t * end;
const uint8_t * enda;
uint64_t sz;
uint16_t vers;
uint64_t abbrev_base;
uint64_t abbrev;
uint8_t address_size;
bool dwarf64;
*name = NULL;
*comp_dir = NULL;
*stmt_list = (uint64_t) -1;
if ( (fDwarfDebugInfoSect == NULL) || (fDwarfDebugAbbrevSect == NULL) )
return false;
debug_info = (uint8_t*)(fHeader) + fDwarfDebugInfoSect->offset();
debug_abbrev = (uint8_t*)(fHeader) + fDwarfDebugAbbrevSect->offset();
di = debug_info;
if (fDwarfDebugInfoSect->size() < 12)
/* Too small to be a real debug_info section. */
return false;
sz = A::P::E::get32(*(uint32_t*)di);
di += 4;
dwarf64 = sz == 0xffffffff;
if (dwarf64)
sz = A::P::E::get64(*(uint64_t*)di), di += 8;
else if (sz > 0xffffff00)
/* Unknown dwarf format. */
return false;
/* Verify claimed size. */
if (sz + (di - debug_info) > fDwarfDebugInfoSect->size() || sz <= (dwarf64 ? 23 : 11))
return false;
vers = A::P::E::get16(*(uint16_t*)di);
if (vers < 2 || vers > 3)
/* DWARF version wrong for this code.
Chances are we could continue anyway, but we don't know for sure. */
return false;
di += 2;
/* Find the debug_abbrev section. */
abbrev_base = dwarf64 ? A::P::E::get64(*(uint64_t*)di) : A::P::E::get32(*(uint32_t*)di);
di += dwarf64 ? 8 : 4;
if (abbrev_base > fDwarfDebugAbbrevSect->size())
return false;
da = debug_abbrev + abbrev_base;
enda = debug_abbrev + fDwarfDebugAbbrevSect->size();
address_size = *di++;
/* Find the abbrev number we're looking for. */
end = di + sz;
abbrev = read_uleb128 (&di, end);
if (abbrev == (uint64_t) -1)
return false;
/* Skip through the debug_abbrev section looking for that abbrev. */
for (;;)
{
uint64_t this_abbrev = read_uleb128 (&da, enda);
uint64_t attr;
if (this_abbrev == abbrev)
/* This is almost always taken. */
break;
skip_leb128 (&da, enda); /* Skip the tag. */
if (da == enda)
return false;
da++; /* Skip the DW_CHILDREN_* value. */
do {
attr = read_uleb128 (&da, enda);
skip_leb128 (&da, enda);
} while (attr != 0 && attr != (uint64_t) -1);
if (attr != 0)
return false;
}
/* Check that the abbrev is one for a DW_TAG_compile_unit. */
if (read_uleb128 (&da, enda) != DW_TAG_compile_unit)
return false;
if (da == enda)
return false;
da++; /* Skip the DW_CHILDREN_* value. */
/* Now, go through the DIE looking for DW_AT_name,
DW_AT_comp_dir, and DW_AT_stmt_list. */
for (;;)
{
uint64_t attr = read_uleb128 (&da, enda);
uint64_t form = read_uleb128 (&da, enda);
if (attr == (uint64_t) -1)
return false;
else if (attr == 0)
return true;
if (form == DW_FORM_indirect)
form = read_uleb128 (&di, end);
if (attr == DW_AT_name)
*name = getDwarfString(form, di);
else if (attr == DW_AT_comp_dir)
*comp_dir = getDwarfString(form, di);
else if (attr == DW_AT_stmt_list && form == DW_FORM_data4)
*stmt_list = A::P::E::get32(*(uint32_t*)di);
else if (attr == DW_AT_stmt_list && form == DW_FORM_data8)
*stmt_list = A::P::E::get64(*(uint64_t*)di);
if (! skip_form (&di, end, form, address_size, dwarf64))
return false;
}
}
template <typename A>
const char* Reader<A>::assureFullPath(const char* path)
{
if ( path[0] == '/' )
return path;
char cwdbuff[MAXPATHLEN];
if ( getcwd(cwdbuff, MAXPATHLEN) != NULL ) {
char* result;
asprintf(&result, "%s/%s", cwdbuff, path);
if ( result != NULL )
return result;
}
return path;
}
//
//
// To implement architecture xxx, you must write template specializations for the following six methods:
// Reader<xxx>::validFile()
// Reader<xxx>::addRelocReference()
// Reference<xxx>::getDescription()
//
//
template <>
bool Reader<ppc>::validFile(const uint8_t* fileContent, bool, cpu_subtype_t)
{
const macho_header<P>* header = (const macho_header<P>*)fileContent;
if ( header->magic() != MH_MAGIC )
return false;
if ( header->cputype() != CPU_TYPE_POWERPC )
return false;
if ( header->filetype() != MH_OBJECT )
return false;
return true;
}
template <>
bool Reader<ppc64>::validFile(const uint8_t* fileContent, bool, cpu_subtype_t)
{
const macho_header<P>* header = (const macho_header<P>*)fileContent;
if ( header->magic() != MH_MAGIC_64 )
return false;
if ( header->cputype() != CPU_TYPE_POWERPC64 )
return false;
if ( header->filetype() != MH_OBJECT )
return false;
return true;
}
template <>
bool Reader<x86>::validFile(const uint8_t* fileContent, bool, cpu_subtype_t)
{
const macho_header<P>* header = (const macho_header<P>*)fileContent;
if ( header->magic() != MH_MAGIC )
return false;
if ( header->cputype() != CPU_TYPE_I386 )
return false;
if ( header->filetype() != MH_OBJECT )
return false;
return true;
}
template <>
bool Reader<x86_64>::validFile(const uint8_t* fileContent, bool, cpu_subtype_t)
{
const macho_header<P>* header = (const macho_header<P>*)fileContent;
if ( header->magic() != MH_MAGIC_64 )
return false;
if ( header->cputype() != CPU_TYPE_X86_64 )
return false;
if ( header->filetype() != MH_OBJECT )
return false;
return true;
}
template <>
bool Reader<arm>::validFile(const uint8_t* fileContent, bool subtypeMustMatch, cpu_subtype_t subtype)
{
const macho_header<P>* header = (const macho_header<P>*)fileContent;
if ( header->magic() != MH_MAGIC )
return false;
if ( header->cputype() != CPU_TYPE_ARM )
return false;
if ( header->filetype() != MH_OBJECT )
return false;
if ( subtypeMustMatch && ((cpu_subtype_t)header->cpusubtype() != subtype) )
return false;
return true;
}
template <typename A>
bool Reader<A>::isWeakImportSymbol(const macho_nlist<P>* sym)
{
return ( ((sym->n_type() & N_TYPE) == N_UNDF) && ((sym->n_desc() & N_WEAK_REF) != 0) );
}
template <>
bool Reader<ppc64>::addRelocReference(const macho_section<ppc64::P>* sect, const macho_relocation_info<ppc64::P>* reloc)
{
return addRelocReference_powerpc(sect, reloc);
}
template <>
bool Reader<ppc>::addRelocReference(const macho_section<ppc::P>* sect, const macho_relocation_info<ppc::P>* reloc)
{
return addRelocReference_powerpc(sect, reloc);
}
//
// ppc and ppc64 both use the same relocations, so process them in one common routine
//
template <typename A>
bool Reader<A>::addRelocReference_powerpc(const macho_section<typename A::P>* sect,
const macho_relocation_info<typename A::P>* reloc)
{
uint32_t srcAddr;
uint32_t dstAddr;
uint32_t* fixUpPtr;
int32_t displacement = 0;
uint32_t instruction = 0;
uint32_t offsetInTarget;
int16_t lowBits;
bool result = false;
if ( (reloc->r_address() & R_SCATTERED) == 0 ) {
const macho_relocation_info<P>* nextReloc = &reloc[1];
const char* targetName = NULL;
bool weakImport = false;
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + reloc->r_address());
if ( reloc->r_type() != PPC_RELOC_PAIR )
instruction = BigEndian::get32(*fixUpPtr);
srcAddr = sect->addr() + reloc->r_address();
if ( reloc->r_extern() ) {
const macho_nlist<P>* targetSymbol = &fSymbols[reloc->r_symbolnum()];
targetName = &fStrings[targetSymbol->n_strx()];
weakImport = this->isWeakImportSymbol(targetSymbol);
}
switch ( reloc->r_type() ) {
case PPC_RELOC_BR24:
{
if ( (instruction & 0x4C000000) == 0x48000000 ) {
displacement = (instruction & 0x03FFFFFC);
if ( (displacement & 0x02000000) != 0 )
displacement |= 0xFC000000;
}
else {
printf("bad instruction for BR24 reloc");
}
if ( reloc->r_extern() ) {
offsetInTarget = srcAddr + displacement;
if ( strncmp(targetName, "___dtrace_probe$", 16) == 0 ) {
makeByNameReference(A::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( strncmp(targetName, "___dtrace_isenabled$", 20) == 0 ) {
makeByNameReference(A::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( weakImport )
makeByNameReference(A::kBranch24WeakImport, srcAddr, targetName, offsetInTarget);
else
makeByNameReference(A::kBranch24, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = srcAddr + displacement;
// if this is a branch to a stub, we need to see if the stub is for a weak imported symbol
ObjectFile::Atom* atom = findAtomAndOffset(dstAddr).atom;
targetName = atom->getName();
if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_probe$", 16) == 0) ) {
makeByNameReference(A::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_isenabled$", 20) == 0) ) {
makeByNameReference(A::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( (atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn)
&& ((AnonymousAtom<A>*)atom)->isWeakImportStub() )
makeReference(A::kBranch24WeakImport, srcAddr, dstAddr);
else
makeReference(A::kBranch24, srcAddr, dstAddr);
}
}
break;
case PPC_RELOC_BR14:
{
displacement = (instruction & 0x0000FFFC);
if ( (displacement & 0x00008000) != 0 )
displacement |= 0xFFFF0000;
if ( reloc->r_extern() ) {
offsetInTarget = srcAddr + displacement;
makeByNameReference(A::kBranch14, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = srcAddr + displacement;
makeReference(A::kBranch14, srcAddr, dstAddr);
}
}
break;
case PPC_RELOC_PAIR:
// skip, processed by a previous look ahead
break;
case PPC_RELOC_LO16:
{
if ( nextReloc->r_type() != PPC_RELOC_PAIR ) {
throw "PPC_RELOC_LO16 missing following pair";
}
result = true;
lowBits = (instruction & 0xFFFF);
if ( reloc->r_extern() ) {
offsetInTarget = (nextReloc->r_address() << 16) | ((uint32_t)lowBits & 0x0000FFFF);
makeByNameReference(A::kAbsLow16, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = (nextReloc->r_address() << 16) + ((uint32_t)lowBits & 0x0000FFFF);
if ( reloc->r_symbolnum() == R_ABS ) {
// find absolute symbol that corresponds to pointerValue
typename AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(A::kAbsLow16, srcAddr, pos->second->getName(), 0);
else
makeReference(A::kAbsLow16, srcAddr, dstAddr);
}
else {
makeReference(A::kAbsLow16, srcAddr, dstAddr);
}
}
}
break;
case PPC_RELOC_LO14:
{
if ( nextReloc->r_type() != PPC_RELOC_PAIR ) {
throw "PPC_RELOC_LO14 missing following pair";
}
result = true;
lowBits = (instruction & 0xFFFC);
if ( reloc->r_extern() ) {
offsetInTarget = (nextReloc->r_address() << 16) | ((uint32_t)lowBits & 0x0000FFFF);
makeByNameReference(A::kAbsLow14, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = (nextReloc->r_address() << 16) | ((uint32_t)lowBits & 0x0000FFFF);
if ( reloc->r_symbolnum() == R_ABS ) {
// find absolute symbol that corresponds to pointerValue
typename AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(A::kAbsLow14, srcAddr, pos->second->getName(), 0);
else
makeReference(A::kAbsLow14, srcAddr, dstAddr);
}
else {
makeReference(A::kAbsLow14, srcAddr, dstAddr);
}
}
}
break;
case PPC_RELOC_HI16:
{
if ( nextReloc->r_type() != PPC_RELOC_PAIR ) {
throw "PPC_RELOC_HI16 missing following pair";
}
result = true;
if ( reloc->r_extern() ) {
offsetInTarget = ((instruction & 0x0000FFFF) << 16) | (nextReloc->r_address() & 0x0000FFFF);
makeByNameReference(A::kAbsHigh16, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = ((instruction & 0x0000FFFF) << 16) | (nextReloc->r_address() & 0x0000FFFF);
if ( reloc->r_symbolnum() == R_ABS ) {
// find absolute symbol that corresponds to pointerValue
typename AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(A::kAbsHigh16, srcAddr, pos->second->getName(), 0);
else
makeReference(A::kAbsHigh16, srcAddr, dstAddr);
}
else {
makeReference(A::kAbsHigh16, srcAddr, dstAddr);
}
}
}
break;
case PPC_RELOC_HA16:
{
if ( nextReloc->r_type() != PPC_RELOC_PAIR ) {
throw "PPC_RELOC_HA16 missing following pair";
}
result = true;
lowBits = (nextReloc->r_address() & 0x0000FFFF);
if ( reloc->r_extern() ) {
offsetInTarget = ((instruction & 0x0000FFFF) << 16) + (int32_t)lowBits;
makeByNameReference(A::kAbsHigh16AddLow, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = ((instruction & 0x0000FFFF) << 16) + (int32_t)lowBits;
if ( reloc->r_symbolnum() == R_ABS ) {
// find absolute symbol that corresponds to pointerValue
typename AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(A::kAbsHigh16AddLow, srcAddr, pos->second->getName(), 0);
else
makeReference(A::kAbsHigh16AddLow, srcAddr, dstAddr);
}
else {
makeReference(A::kAbsHigh16AddLow, srcAddr, dstAddr);
}
}
}
break;
case PPC_RELOC_VANILLA:
{
pint_t pointerValue = P::getP(*((pint_t*)fixUpPtr));
if ( reloc->r_extern() ) {
if ( weakImport )
makeByNameReference(A::kPointerWeakImport, srcAddr, targetName, pointerValue);
else
makeByNameReference(A::kPointer, srcAddr, targetName, pointerValue);
}
else {
new Reference<A>(A::kPointer, findAtomAndOffset(srcAddr), findAtomAndOffsetForSection(pointerValue, reloc->r_symbolnum()));
}
}
break;
case PPC_RELOC_JBSR:
// this is from -mlong-branch codegen. We ignore the jump island and make reference to the real target
if ( nextReloc->r_type() != PPC_RELOC_PAIR ) {
throw "PPC_RELOC_JBSR missing following pair";
}
if ( !fHasLongBranchStubs )
warning("object file compiled with -mlong-branch which is no longer needed. To remove this warning, recompile without -mlong-branch: %s", fPath);
fHasLongBranchStubs = true;
result = true;
if ( reloc->r_extern() ) {
throw "PPC_RELOC_JBSR should not be using an external relocation";
}
makeReference(A::kBranch24, srcAddr, nextReloc->r_address());
if ( (instruction & 0x4C000000) == 0x48000000 ) {
displacement = (instruction & 0x03FFFFFC);
if ( (displacement & 0x02000000) != 0 )
displacement |= 0xFC000000;
}
else {
fprintf(stderr, "bad instruction for BR24 reloc");
}
break;
default:
warning("unknown relocation type %d", reloc->r_type());
}
}
else {
const macho_scattered_relocation_info<P>* sreloc = (macho_scattered_relocation_info<P>*)reloc;
srcAddr = sect->addr() + sreloc->r_address();
dstAddr = sreloc->r_value();
uint32_t betterDstAddr;
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + sreloc->r_address());
const macho_scattered_relocation_info<P>* nextSReloc = &sreloc[1];
const macho_relocation_info<P>* nextReloc = &reloc[1];
// file format allows pair to be scattered or not
bool nextRelocIsPair = false;
uint32_t nextRelocAddress = 0;
uint32_t nextRelocValue = 0;
if ( (nextReloc->r_address() & R_SCATTERED) == 0 ) {
if ( nextReloc->r_type() == PPC_RELOC_PAIR ) {
nextRelocIsPair = true;
nextRelocAddress = nextReloc->r_address();
result = true;
}
}
else {
if ( nextSReloc->r_type() == PPC_RELOC_PAIR ) {
nextRelocIsPair = true;
nextRelocAddress = nextSReloc->r_address();
nextRelocValue = nextSReloc->r_value();
result = true;
}
}
switch (sreloc->r_type()) {
case PPC_RELOC_VANILLA:
{
betterDstAddr = P::getP(*(pint_t*)fixUpPtr);
//fprintf(stderr, "scattered pointer reloc: srcAddr=0x%08X, dstAddr=0x%08X, pointer=0x%08X\n", srcAddr, dstAddr, betterDstAddr);
// with a scattered relocation we get both the target (sreloc->r_value()) and the target+offset (*fixUpPtr)
makeReferenceWithToBase(A::kPointer, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_BR14:
{
instruction = BigEndian::get32(*fixUpPtr);
displacement = (instruction & 0x0000FFFC);
if ( (displacement & 0x00008000) != 0 )
displacement |= 0xFFFF0000;
betterDstAddr = srcAddr+displacement;
//fprintf(stderr, "betterDstAddr=0x%08X, srcAddr=0x%08X, displacement=0x%08X\n", betterDstAddr, srcAddr, displacement);
makeReferenceWithToBase(A::kBranch14, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_BR24:
{
instruction = BigEndian::get32(*fixUpPtr);
if ( (instruction & 0x4C000000) == 0x48000000 ) {
displacement = (instruction & 0x03FFFFFC);
if ( (displacement & 0x02000000) != 0 )
displacement |= 0xFC000000;
betterDstAddr = srcAddr+displacement;
makeReferenceWithToBase(A::kBranch24, srcAddr, betterDstAddr, dstAddr);
}
}
break;
case PPC_RELOC_LO16_SECTDIFF:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_LO16_SECTDIFF missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (instruction & 0xFFFF);
displacement = (nextRelocAddress << 16) | ((uint32_t)lowBits & 0x0000FFFF);
makeReferenceWithToBase(A::kPICBaseLow16, srcAddr, nextRelocValue, nextRelocValue + displacement, dstAddr);
}
break;
case PPC_RELOC_LO14_SECTDIFF:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_LO14_SECTDIFF missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (instruction & 0xFFFC);
displacement = (nextRelocAddress << 16) | ((uint32_t)lowBits & 0x0000FFFF);
makeReferenceWithToBase(A::kPICBaseLow14, srcAddr, nextRelocValue, nextRelocValue + displacement, dstAddr);
}
break;
case PPC_RELOC_HA16_SECTDIFF:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_HA16_SECTDIFF missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (nextRelocAddress & 0x0000FFFF);
displacement = ((instruction & 0x0000FFFF) << 16) + (int32_t)lowBits;
makeReferenceWithToBase(A::kPICBaseHigh16, srcAddr, nextRelocValue, nextRelocValue + displacement, dstAddr);
}
break;
case PPC_RELOC_LO14:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_LO14 missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (instruction & 0xFFFC);
betterDstAddr = (nextRelocAddress << 16) + ((uint32_t)lowBits & 0x0000FFFF);
makeReferenceWithToBase(A::kAbsLow14, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_LO16:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_LO16 missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (instruction & 0xFFFF);
betterDstAddr = (nextRelocAddress << 16) + ((uint32_t)lowBits & 0x0000FFFF);
makeReferenceWithToBase(A::kAbsLow16, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_HA16:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_HA16 missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (nextRelocAddress & 0xFFFF);
betterDstAddr = ((instruction & 0xFFFF) << 16) + (int32_t)lowBits;
makeReferenceWithToBase(A::kAbsHigh16AddLow, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_HI16:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_HI16 missing following pair";
}
instruction = BigEndian::get32(*fixUpPtr);
lowBits = (nextRelocAddress & 0xFFFF);
betterDstAddr = ((instruction & 0xFFFF) << 16) | (lowBits & 0x0000FFFF);
makeReferenceWithToBase(A::kAbsHigh16, srcAddr, betterDstAddr, dstAddr);
}
break;
case PPC_RELOC_SECTDIFF:
case PPC_RELOC_LOCAL_SECTDIFF:
{
if ( ! nextRelocIsPair ) {
throw "PPC_RELOC_SECTDIFF missing following pair";
}
Kinds kind = A::kPointerDiff32;;
uint32_t contentAddr = 0;
switch ( sreloc->r_length() ) {
case 0:
throw "bad diff relocations r_length (0) for ppc architecture";
case 1:
kind = A::kPointerDiff16;
contentAddr = BigEndian::get16(*((uint16_t*)fixUpPtr));
break;
case 2:
kind = A::kPointerDiff32;
contentAddr = BigEndian::get32(*fixUpPtr);
break;
case 3:
kind = A::kPointerDiff64;
contentAddr = BigEndian::get64(*((uint64_t*)fixUpPtr));
break;
}
AtomAndOffset srcao = findAtomAndOffset(srcAddr);
AtomAndOffset fromao = findAtomAndOffset(nextRelocValue);
AtomAndOffset toao = findAtomAndOffset(dstAddr);
// check for addend encoded in the section content
//fprintf(stderr, "addRef: dstAddr=0x%X, nextRelocValue=0x%X, contentAddr=0x%X\n",
// dstAddr, nextRelocValue, contentAddr);
if ( (dstAddr - nextRelocValue) != contentAddr ) {
if ( toao.atom == srcao.atom )
toao.offset += (contentAddr + nextRelocValue) - dstAddr;
else if ( fromao.atom == srcao.atom )
toao.offset += (contentAddr + nextRelocValue) - dstAddr;
else
fromao.offset += (dstAddr - contentAddr) - nextRelocValue;
}
//fprintf(stderr, "addRef: src=%s+0x%X, from=%s+0x%X, to=%s+0x%X\n",
// srcao.atom->getDisplayName(), srcao.offset,
// fromao.atom->getDisplayName(), fromao.offset,
// toao.atom->getDisplayName(), toao.offset);
new Reference<A>(kind, srcao, fromao, toao);
}
break;
case PPC_RELOC_PAIR:
break;
case PPC_RELOC_HI16_SECTDIFF:
warning("unexpected scattered relocation type PPC_RELOC_HI16_SECTDIFF");
break;
default:
warning("unknown scattered relocation type %d", sreloc->r_type());
}
}
return result;
}
template <>
bool Reader<x86>::addRelocReference(const macho_section<x86::P>* sect, const macho_relocation_info<x86::P>* reloc)
{
uint32_t srcAddr;
uint32_t dstAddr;
uint32_t* fixUpPtr;
bool result = false;
if ( (reloc->r_address() & R_SCATTERED) == 0 ) {
srcAddr = sect->addr() + reloc->r_address();
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + reloc->r_address());
switch ( reloc->r_type() ) {
case GENERIC_RELOC_VANILLA:
{
x86::ReferenceKinds kind = x86::kPointer;
uint32_t pointerValue = E::get32(*fixUpPtr);
if ( reloc->r_pcrel() ) {
switch( reloc->r_length() ) {
case 0:
kind = x86::kPCRel8;
pointerValue = srcAddr + *((int8_t*)fixUpPtr) + sizeof(int8_t);
break;
case 1:
kind = x86::kPCRel16;
pointerValue = srcAddr + (int16_t)E::get16(*((uint16_t*)fixUpPtr)) + sizeof(uint16_t);
break;
case 2:
kind = x86::kPCRel32;
pointerValue += srcAddr + sizeof(uint32_t);
break;
case 3:
throw "bad pc-rel vanilla relocation length";
}
}
else if ( strcmp(sect->segname(), "__TEXT") == 0 ) {
kind = x86::kAbsolute32;
if ( reloc->r_length() != 2 )
throw "bad vanilla relocation length";
}
else {
kind = x86::kPointer;
if ( reloc->r_length() != 2 )
throw "bad vanilla relocation length";
}
if ( reloc->r_extern() ) {
const macho_nlist<P>* targetSymbol = &fSymbols[reloc->r_symbolnum()];
if ( this->isWeakImportSymbol(targetSymbol) ) {
if ( reloc->r_pcrel() )
kind = x86::kPCRel32WeakImport;
else
kind = x86::kPointerWeakImport;
}
const char* targetName = &fStrings[targetSymbol->n_strx()];
if ( strncmp(targetName, "___dtrace_probe$", 16) == 0 ) {
makeByNameReference(x86::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( strncmp(targetName, "___dtrace_isenabled$", 20) == 0 ) {
makeByNameReference(x86::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else
makeByNameReference(kind, srcAddr, targetName, pointerValue);
}
else {
AtomAndOffset targetAO = findAtomAndOffsetForSection(pointerValue, reloc->r_symbolnum());
const char* targetName = targetAO.atom->getName();
if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_probe$", 16) == 0) ) {
makeByNameReference(x86::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_isenabled$", 20) == 0) ) {
makeByNameReference(x86::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
// if this is a reference to a stub, we need to see if the stub is for a weak imported symbol
else if ( reloc->r_pcrel() && (targetAO.atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn)
&& ((AnonymousAtom<x86>*)targetAO.atom)->isWeakImportStub() )
new Reference<x86>(x86::kPCRel32WeakImport, findAtomAndOffset(srcAddr), targetAO);
else if ( reloc->r_symbolnum() != R_ABS )
new Reference<x86>(kind, findAtomAndOffset(srcAddr), targetAO);
else {
// find absolute symbol that corresponds to pointerValue
AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(pointerValue);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(kind, srcAddr, pos->second->getName(), 0);
else
throwf("R_ABS reloc but no absolute symbol at target address");
}
}
}
break;
default:
warning("unknown relocation type %d", reloc->r_type());
}
}
else {
const macho_scattered_relocation_info<P>* sreloc = (macho_scattered_relocation_info<P>*)reloc;
srcAddr = sect->addr() + sreloc->r_address();
dstAddr = sreloc->r_value();
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + sreloc->r_address());
const macho_scattered_relocation_info<P>* nextSReloc = &sreloc[1];
const macho_relocation_info<P>* nextReloc = &reloc[1];
pint_t betterDstAddr;
// file format allows pair to be scattered or not
bool nextRelocIsPair = false;
uint32_t nextRelocAddress = 0;
uint32_t nextRelocValue = 0;
if ( (nextReloc->r_address() & R_SCATTERED) == 0 ) {
if ( nextReloc->r_type() == GENERIC_RELOC_PAIR ) {
nextRelocIsPair = true;
nextRelocAddress = nextReloc->r_address();
result = true;
}
}
else {
if ( nextSReloc->r_type() == GENERIC_RELOC_PAIR ) {
nextRelocIsPair = true;
nextRelocAddress = nextSReloc->r_address();
nextRelocValue = nextSReloc->r_value();
}
}
switch (sreloc->r_type()) {
case GENERIC_RELOC_VANILLA:
betterDstAddr = LittleEndian::get32(*fixUpPtr);
//fprintf(stderr, "pointer reloc: srcAddr=0x%08X, dstAddr=0x%08X, pointer=0x%08lX\n", srcAddr, dstAddr, betterDstAddr);
// with a scattered relocation we get both the target (sreloc->r_value()) and the target+offset (*fixUpPtr)
if ( sreloc->r_pcrel() ) {
switch ( sreloc->r_length() ) {
case 2:
betterDstAddr += srcAddr + 4;
makeReferenceWithToBase(x86::kPCRel32, srcAddr, betterDstAddr, dstAddr);
break;
case 1:
betterDstAddr = LittleEndian::get16(*((uint16_t*)fixUpPtr)) + srcAddr + 2;
makeReferenceWithToBase(x86::kPCRel16, srcAddr, betterDstAddr, dstAddr);
break;
case 0:
betterDstAddr = *((uint8_t*)fixUpPtr) + srcAddr + 1;
makeReferenceWithToBase(x86::kPCRel8, srcAddr, betterDstAddr, dstAddr);
break;
case 3:
throwf("unsupported r_length=3 for scattered pc-rel vanilla reloc");
break;
}
}
else {
if ( sreloc->r_length() != 2 )
throwf("unsupported r_length=%d for scattered vanilla reloc", sreloc->r_length());
if ( strcmp(sect->segname(), "__TEXT") == 0 )
makeReferenceWithToBase(x86::kAbsolute32, srcAddr, betterDstAddr, dstAddr);
else
makeReferenceWithToBase(x86::kPointer, srcAddr, betterDstAddr, dstAddr);
}
break;
case GENERIC_RELOC_SECTDIFF:
case GENERIC_RELOC_LOCAL_SECTDIFF:
{
if ( !nextRelocIsPair ) {
throw "GENERIC_RELOC_SECTDIFF missing following pair";
}
x86::ReferenceKinds kind = x86::kPointerDiff;
uint32_t contentAddr = 0;
switch ( sreloc->r_length() ) {
case 0:
case 3:
throw "bad length for GENERIC_RELOC_SECTDIFF";
case 1:
kind = x86::kPointerDiff16;
contentAddr = LittleEndian::get16(*((uint16_t*)fixUpPtr));
break;
case 2:
kind = x86::kPointerDiff;
contentAddr = LittleEndian::get32(*fixUpPtr);
break;
}
AtomAndOffset srcao = findAtomAndOffset(srcAddr);
AtomAndOffset fromao = findAtomAndOffset(nextRelocValue);
AtomAndOffset toao = findAtomAndOffset(dstAddr);
// check for addend encoded in the section content
//fprintf(stderr, "addRef: dstAddr=0x%X, nextRelocValue=0x%X, contentAddr=0x%X\n",
// dstAddr, nextRelocValue, contentAddr);
if ( (dstAddr - nextRelocValue) != contentAddr ) {
if ( toao.atom == srcao.atom )
toao.offset += (contentAddr + nextRelocValue) - dstAddr;
else if ( fromao.atom == srcao.atom )
toao.offset += (contentAddr + nextRelocValue) - dstAddr;
else
fromao.offset += (dstAddr - contentAddr) - nextRelocValue;
}
//fprintf(stderr, "addRef: src=%s+0x%X, from=%s+0x%X, to=%s+0x%X\n",
// srcao.atom->getDisplayName(), srcao.offset,
// fromao.atom->getDisplayName(), fromao.offset,
// toao.atom->getDisplayName(), toao.offset);
new Reference<x86>(kind, srcao, fromao, toao);
}
break;
case GENERIC_RELOC_PAIR:
// do nothing, already used via a look ahead
break;
default:
warning("unknown scattered relocation type %d", sreloc->r_type());
}
}
return result;
}
template <>
bool Reader<x86_64>::addRelocReference(const macho_section<x86_64::P>* sect, const macho_relocation_info<x86_64::P>* reloc)
{
uint64_t srcAddr;
uint64_t dstAddr = 0;
uint64_t addend;
uint32_t* fixUpPtr;
x86_64::ReferenceKinds kind = x86_64::kNoFixUp;
bool result = false;
const macho_nlist<P>* targetSymbol = NULL;
const char* targetName = NULL;
srcAddr = sect->addr() + reloc->r_address();
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + reloc->r_address());
//fprintf(stderr, "addReloc type=%d, len=%d, address=0x%X\n", reloc->r_type(), reloc->r_length(), reloc->r_address());
if ( reloc->r_extern() ) {
targetSymbol = &fSymbols[reloc->r_symbolnum()];
targetName = &fStrings[targetSymbol->n_strx()];
}
switch ( reloc->r_type() ) {
case X86_64_RELOC_UNSIGNED:
if ( reloc->r_pcrel() )
throw "pcrel and X86_64_RELOC_UNSIGNED not supported";
switch ( reloc->r_length() ) {
case 0:
case 1:
throw "length < 2 and X86_64_RELOC_UNSIGNED not supported";
case 2:
kind = x86_64::kPointer32;
break;
case 3:
if ( reloc->r_extern() && isWeakImportSymbol(targetSymbol) )
kind = x86_64::kPointerWeakImport;
else
kind = x86_64::kPointer;
break;
}
dstAddr = E::get64(*((uint64_t*)fixUpPtr));
if ( reloc->r_extern() ) {
makeReferenceToSymbol(kind, srcAddr, targetSymbol, dstAddr);
}
else {
makeReference(kind, srcAddr, dstAddr);
// verify that dstAddr is in the section being targeted
int sectNum = reloc->r_symbolnum();
const macho_section<P>* const sectionsStart = (macho_section<P>*)((char*)fSegment + sizeof(macho_segment_command<P>));
const macho_section<P>* const targetSection = §ionsStart[sectNum-1];
if ( (dstAddr < targetSection->addr()) || (dstAddr > (targetSection->addr()+targetSection->size())) ) {
throwf("local relocation for address 0x%08llX in section %s does not target section %s",
srcAddr, sect->sectname(), targetSection->sectname());
}
}
break;
case X86_64_RELOC_SIGNED:
case X86_64_RELOC_SIGNED_1:
case X86_64_RELOC_SIGNED_2:
case X86_64_RELOC_SIGNED_4:
if ( ! reloc->r_pcrel() )
throw "not pcrel and X86_64_RELOC_SIGNED* not supported";
if ( reloc->r_length() != 2 )
throw "length != 2 and X86_64_RELOC_SIGNED* not supported";
addend = (int64_t)((int32_t)(E::get32(*fixUpPtr)));
if ( reloc->r_extern() ) {
switch ( reloc->r_type() ) {
case X86_64_RELOC_SIGNED:
kind = x86_64::kPCRel32;
// begin support for old .o files before X86_64_RELOC_SIGNED_1 was created
if ( addend == (uint64_t)(-1) ) {
addend = 0;
kind = x86_64::kPCRel32_1;
}
else if ( addend == (uint64_t)(-2) ) {
addend = 0;
kind = x86_64::kPCRel32_2;
}
else if ( addend == (uint64_t)(-4) ) {
addend = 0;
kind = x86_64::kPCRel32_4;
}
break;
// end support for old .o files before X86_64_RELOC_SIGNED_1 was created
case X86_64_RELOC_SIGNED_1:
kind = x86_64::kPCRel32_1;
addend += 1;
break;
case X86_64_RELOC_SIGNED_2:
kind = x86_64::kPCRel32_2;
addend += 2;
break;
case X86_64_RELOC_SIGNED_4:
kind = x86_64::kPCRel32_4;
addend += 4;
break;
}
makeReferenceToSymbol(kind, srcAddr, targetSymbol, addend);
}
else {
uint64_t ripRelativeOffset = addend;
switch ( reloc->r_type() ) {
case X86_64_RELOC_SIGNED:
dstAddr = srcAddr + 4 + ripRelativeOffset;
kind = x86_64::kPCRel32;
break;
case X86_64_RELOC_SIGNED_1:
dstAddr = srcAddr + 5 + ripRelativeOffset;
kind = x86_64::kPCRel32_1;
break;
case X86_64_RELOC_SIGNED_2:
dstAddr = srcAddr + 6 + ripRelativeOffset;
kind = x86_64::kPCRel32_2;
break;
case X86_64_RELOC_SIGNED_4:
dstAddr = srcAddr + 8 + ripRelativeOffset;
kind = x86_64::kPCRel32_4;
break;
}
makeReference(kind, srcAddr, dstAddr);
// verify that dstAddr is in the section being targeted
int sectNum = reloc->r_symbolnum();
const macho_section<P>* const sectionsStart = (macho_section<P>*)((char*)fSegment + sizeof(macho_segment_command<P>));
const macho_section<P>* const targetSection = §ionsStart[sectNum-1];
if ( (dstAddr < targetSection->addr()) || (dstAddr > (targetSection->addr()+targetSection->size())) ) {
throwf("local relocation for address 0x%08llX in section %s does not target section %s",
srcAddr, sect->sectname(), targetSection->sectname());
}
}
break;
case X86_64_RELOC_BRANCH:
if ( ! reloc->r_pcrel() )
throw "not pcrel and X86_64_RELOC_BRANCH not supported";
if ( reloc->r_length() == 2 ) {
dstAddr = (int64_t)((int32_t)(E::get32(*fixUpPtr)));
if ( reloc->r_extern() ) {
if ( strncmp(targetName, "___dtrace_probe$", 16) == 0 ) {
makeByNameReference(x86_64::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( strncmp(targetName, "___dtrace_isenabled$", 20) == 0 ) {
makeByNameReference(x86_64::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( isWeakImportSymbol(targetSymbol) )
makeReferenceToSymbol(x86_64::kBranchPCRel32WeakImport, srcAddr, targetSymbol, dstAddr);
else
makeReferenceToSymbol(x86_64::kBranchPCRel32, srcAddr, targetSymbol, dstAddr);
}
else {
makeReference(x86_64::kBranchPCRel32, srcAddr, srcAddr+4+dstAddr);
}
}
else if ( reloc->r_length() == 0 ) {
dstAddr = *((int8_t*)fixUpPtr);
if ( reloc->r_extern() ) {
makeReferenceToSymbol(x86_64::kBranchPCRel8, srcAddr, targetSymbol, dstAddr);
}
else {
makeReference(x86_64::kBranchPCRel8, srcAddr, srcAddr+1+dstAddr);
}
}
else {
throwf("length=%d and X86_64_RELOC_BRANCH not supported", reloc->r_length());;
}
break;
case X86_64_RELOC_GOT:
if ( ! reloc->r_extern() )
throw "not extern and X86_64_RELOC_GOT not supported";
if ( ! reloc->r_pcrel() )
throw "not pcrel and X86_64_RELOC_GOT not supported";
if ( reloc->r_length() != 2 )
throw "length != 2 and X86_64_RELOC_GOT not supported";
addend = (int64_t)((int32_t)(E::get32(*fixUpPtr)));
if ( isWeakImportSymbol(targetSymbol) )
makeReferenceToSymbol(x86_64::kPCRel32GOTWeakImport, srcAddr, targetSymbol, addend);
else
makeReferenceToSymbol(x86_64::kPCRel32GOT, srcAddr, targetSymbol, addend);
break;
case X86_64_RELOC_GOT_LOAD:
if ( ! reloc->r_extern() )
throw "not extern and X86_64_RELOC_GOT_LOAD not supported";
if ( ! reloc->r_pcrel() )
throw "not pcrel and X86_64_RELOC_GOT_LOAD not supported";
if ( reloc->r_length() != 2 )
throw "length != 2 and X86_64_RELOC_GOT_LOAD not supported";
addend = (int64_t)((int32_t)(E::get32(*fixUpPtr)));
if ( isWeakImportSymbol(targetSymbol) )
makeReferenceToSymbol(x86_64::kPCRel32GOTLoadWeakImport, srcAddr, targetSymbol, addend);
else
makeReferenceToSymbol(x86_64::kPCRel32GOTLoad, srcAddr, targetSymbol, addend);
break;
case X86_64_RELOC_SUBTRACTOR:
{
if ( reloc->r_pcrel() )
throw "X86_64_RELOC_SUBTRACTOR cannot be pc-relative";
if ( reloc->r_length() < 2 )
throw "X86_64_RELOC_SUBTRACTOR must have r_length of 2 or 3";
if ( !reloc->r_extern() )
throw "X86_64_RELOC_SUBTRACTOR must have r_extern=1";
const macho_relocation_info<x86_64::P>* nextReloc = &reloc[1];
if ( nextReloc->r_type() != X86_64_RELOC_UNSIGNED )
throw "X86_64_RELOC_SUBTRACTOR must be followed by X86_64_RELOC_UNSIGNED";
result = true;
if ( nextReloc->r_pcrel() )
throw "X86_64_RELOC_UNSIGNED following a X86_64_RELOC_SUBTRACTOR cannot be pc-relative";
if ( nextReloc->r_length() != reloc->r_length() )
throw "X86_64_RELOC_UNSIGNED following a X86_64_RELOC_SUBTRACTOR must have same r_length";
Reference<x86_64>* ref;
bool negativeAddend;
if ( reloc->r_length() == 2 ) {
kind = x86_64::kPointerDiff32;
dstAddr = E::get32(*fixUpPtr); // addend is in content
negativeAddend = ((dstAddr & 0x80000000) != 0);
}
else {
kind = x86_64::kPointerDiff;
dstAddr = E::get64(*((uint64_t*)fixUpPtr)); // addend is in content
negativeAddend = ((dstAddr & 0x8000000000000000ULL) != 0);
}
AtomAndOffset inAtomAndOffset = this->findAtomAndOffset(srcAddr);
ObjectFile::Atom* inAtom = inAtomAndOffset.atom;
// create reference with "to" target
if ( nextReloc->r_extern() ) {
const macho_nlist<P>* targetSymbol = &fSymbols[nextReloc->r_symbolnum()];
const char* targetName = &fStrings[targetSymbol->n_strx()];
ref = makeReferenceToSymbol(kind, srcAddr, targetSymbol, 0);
// if "to" is in this atom, change by-name to a direct reference
if ( strcmp(targetName, inAtom->getName()) == 0 )
ref->setTarget(*inAtom, 0);
}
else {
ref = makeReference(kind, srcAddr, dstAddr);
}
// add in "from" target
if ( reloc->r_extern() ) {
const macho_nlist<P>* targetFromSymbol = &fSymbols[reloc->r_symbolnum()];
const char* fromTargetName = &fStrings[targetFromSymbol->n_strx()];
if ( (targetFromSymbol->n_type() & N_EXT) == 0 ) {
// from target is translation unit scoped, so use a direct reference
ref->setFromTarget(*(findAtomAndOffset(targetSymbol->n_value()).atom));
}
else if ( strcmp(fromTargetName, inAtom->getName()) == 0 ) {
// if "from" is in this atom, change by-name to a direct reference
ref->setFromTarget(*inAtom);
}
else {
// some non-static other atom
ref->setFromTargetName(fromTargetName);
}
}
else {
throw "X86_64_RELOC_SUBTRACTOR not supported with r_extern=0";
}
// addend goes in from side iff negative
if ( negativeAddend )
ref->setFromTargetOffset(-dstAddr);
else
ref->setToTargetOffset(dstAddr);
break;
}
default:
warning("unknown relocation type %d", reloc->r_type());
}
return result;
}
/// Reader<arm>::addRelocReference -
/// turns arm relocation entries into references. Returns true if the next
/// relocation should be skipped, false otherwise.
template <>
bool Reader<arm>::addRelocReference(const macho_section<arm::P>* sect,
const macho_relocation_info<arm::P>* reloc)
{
uint32_t * fixUpPtr;
int32_t displacement;
uint32_t instruction = 0;
bool result = false;
uint32_t srcAddr;
uint32_t dstAddr;
uint32_t pointerValue;
arm::ReferenceKinds kind = arm::kNoFixUp;
if ( (reloc->r_address() & R_SCATTERED) == 0 ) {
// non-scattered relocation
const char* targetName = NULL;
bool weakImport = false;
srcAddr = sect->addr() + reloc->r_address();
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + reloc->r_address());
if ( reloc->r_type() != ARM_RELOC_PAIR )
instruction = LittleEndian::get32(*fixUpPtr);
if ( reloc->r_extern() ) {
const macho_nlist<P>* targetSymbol = &fSymbols[reloc->r_symbolnum()];
targetName = &fStrings[targetSymbol->n_strx()];
weakImport = this->isWeakImportSymbol(targetSymbol);
}
switch ( reloc->r_type() ) {
case ARM_RELOC_BR24:
// Sign-extend displacement
displacement = (instruction & 0x00FFFFFF) << 2;
if ( (displacement & 0x02000000) != 0 )
displacement |= 0xFC000000;
// The pc added will be +8 from the pc
displacement += 8;
// If this is BLX add H << 1
if ((instruction & 0xFE000000) == 0xFA000000)
displacement += ((instruction & 0x01000000) >> 23);
if ( reloc->r_extern() ) {
uint32_t offsetInTarget = srcAddr + displacement;
if ( strncmp(targetName, "___dtrace_probe$", 16) == 0 ) {
makeByNameReference(arm::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( strncmp(targetName, "___dtrace_isenabled$", 20) == 0 ) {
makeByNameReference(arm::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( weakImport )
makeByNameReference(arm::kBranch24WeakImport, srcAddr, targetName, offsetInTarget);
else
makeByNameReference(arm::kBranch24, srcAddr, targetName, offsetInTarget);
}
else {
dstAddr = srcAddr + displacement;
ObjectFile::Atom* atom = findAtomAndOffset(dstAddr).atom;
// check for dtrace probes and weak_import stubs
const char* targetName = atom->getName();
if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_probe$", 16) == 0) ) {
makeByNameReference(arm::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_isenabled$", 20) == 0) ) {
makeByNameReference(arm::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( (atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn)
&& ((AnonymousAtom<x86>*)atom)->isWeakImportStub() )
makeReference(arm::kBranch24WeakImport, srcAddr, dstAddr);
else if ( reloc->r_symbolnum() != R_ABS )
makeReference(arm::kBranch24, srcAddr, dstAddr);
else {
// find absolute symbol that corresponds to pointerValue
AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(arm::kBranch24, srcAddr, pos->second->getName(), 0);
else
throwf("R_ABS reloc but no absolute symbol at target address");
}
}
break;
case ARM_THUMB_RELOC_BR22:
// thumb2 added two more bits to displacement, complicating the displacement decoding
{
uint32_t s = (instruction >> 10) & 0x1;
uint32_t j1 = (instruction >> 29) & 0x1;
uint32_t j2 = (instruction >> 27) & 0x1;
uint32_t imm10 = instruction & 0x3FF;
uint32_t imm11 = (instruction >> 16) & 0x7FF;
uint32_t i1 = (j1 == s);
uint32_t i2 = (j2 == s);
uint32_t dis = (s << 24) | (i1 << 23) | (i2 << 22) | (imm10 << 12) | (imm11 << 1);
int32_t sdis = dis;
if ( s )
sdis |= 0xFE000000;
displacement = sdis;
}
// The pc added will be +4 from the pc
displacement += 4;
// If the instruction was blx, force the low 2 bits to be clear
dstAddr = srcAddr + displacement;
if ((instruction & 0xF8000000) == 0xE8000000)
dstAddr &= 0xFFFFFFFC;
if ( reloc->r_extern() ) {
uint32_t offsetInTarget = dstAddr;
if ( strncmp(targetName, "___dtrace_probe$", 16) == 0 ) {
makeByNameReference(arm::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( strncmp(targetName, "___dtrace_isenabled$", 20) == 0 ) {
makeByNameReference(arm::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( weakImport )
makeByNameReference(arm::kThumbBranch22WeakImport, srcAddr, targetName, offsetInTarget);
else
makeByNameReference(arm::kThumbBranch22, srcAddr, targetName, offsetInTarget);
}
else {
ObjectFile::Atom* atom = findAtomAndOffset(dstAddr).atom;
// check for dtrace probes and weak_import stubs
const char* targetName = atom->getName();
if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_probe$", 16) == 0) ) {
makeByNameReference(arm::kDtraceProbeSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[16]);
}
else if ( (targetName != NULL) && (strncmp(targetName, "___dtrace_isenabled$", 20) == 0) ) {
makeByNameReference(arm::kDtraceIsEnabledSite, srcAddr, targetName, 0);
addDtraceExtraInfos(srcAddr, &targetName[20]);
}
else if ( (atom->getSymbolTableInclusion() == ObjectFile::Atom::kSymbolTableNotIn)
&& ((AnonymousAtom<x86>*)atom)->isWeakImportStub() )
makeReference(arm::kThumbBranch22WeakImport, srcAddr, dstAddr);
else if ( reloc->r_symbolnum() != R_ABS )
makeReference(arm::kThumbBranch22, srcAddr, dstAddr);
else {
// find absolute symbol that corresponds to pointerValue
AddrToAtomMap::iterator pos = fAddrToAbsoluteAtom.find(dstAddr);
if ( pos != fAddrToAbsoluteAtom.end() )
makeByNameReference(arm::kThumbBranch22, srcAddr, pos->second->getName(), 0);
else
throwf("R_ABS reloc but no absolute symbol at target address");
}
}
break;
case ARM_RELOC_VANILLA:
if ( reloc->r_length() != 2 )
throw "bad length for ARM_RELOC_VANILLA";
pointerValue = instruction;
kind = arm::kPointer;
if ( strcmp(sect->segname(), "__TEXT") == 0 )
kind = arm::kReadOnlyPointer;
if ( weakImport )
kind = arm::kPointerWeakImport;
if ( reloc->r_extern() ) {
makeByNameReference(kind, srcAddr, targetName, pointerValue);
}
else {
AtomAndOffset at = findAtomAndOffset(srcAddr);
AtomAndOffset to = findAtomAndOffsetForSection(pointerValue, reloc->r_symbolnum());
if ( to.atom->isThumb() )
to.offset &= -2;
new Reference<arm>(kind, at, to);
}
break;
case ARM_THUMB_32BIT_BRANCH:
// ignore old unnecessary relocs
break;
default:
warning("unexpected relocation type %u", reloc->r_type());
break;
}
}
else {
const macho_scattered_relocation_info<P>* sreloc = (macho_scattered_relocation_info<P>*)reloc;
const macho_scattered_relocation_info<P>* nextSReloc = &sreloc[1];
srcAddr = sect->addr() + sreloc->r_address();
dstAddr = sreloc->r_value();
uint32_t betterDstAddr;
fixUpPtr = (uint32_t*)((char*)(fHeader) + sect->offset() + sreloc->r_address());
instruction = LittleEndian::get32(*fixUpPtr);
// A ARM_RELOC_PAIR only follows ARM_RELOC_{SECTDIFF,LOCAL_SECTDIFF}
// relocation types, and it is an error to see one otherwise.
bool nextRelocIsPair = false;
uint32_t nextRelocAddress = 0;
uint32_t nextRelocValue = 0;
if ( nextSReloc->r_type() == ARM_RELOC_PAIR ) {
nextRelocIsPair = true;
nextRelocAddress = nextSReloc->r_address();
nextRelocValue = nextSReloc->r_value();
result = true;
}
switch (sreloc->r_type()) {
case ARM_RELOC_VANILLA:
if ( sreloc->r_length() != 2 )
throw "bad length for ARM_RELOC_VANILLA";
//fprintf(stderr, "scattered pointer reloc: srcAddr=0x%08X, dstAddr=0x%08X, pointer=0x%08X\n", srcAddr, dstAddr, betterDstAddr);
betterDstAddr = LittleEndian::get32(*fixUpPtr);
kind = arm::kPointer;
if ( strcmp(sect->segname(), "__TEXT") == 0 )
kind = arm::kReadOnlyPointer;
// with a scattered relocation we get both the target (sreloc->r_value()) and the target+offset (*fixUpPtr)
makeReferenceWithToBase(kind, srcAddr, betterDstAddr, dstAddr);
break;
case ARM_RELOC_BR24:
// Sign-extend displacement
displacement = (instruction & 0x00FFFFFF) << 2;
if ( (displacement & 0x02000000) != 0 )
displacement |= 0xFC000000;
// The pc added will be +8 from the pc
displacement += 8;
// If this is BLX add H << 1
if ((instruction & 0xFE000000) == 0xFA000000)
displacement += ((instruction & 0x01000000) >> 23);
betterDstAddr = srcAddr+displacement;
makeReferenceWithToBase(arm::kBranch24, srcAddr, betterDstAddr, dstAddr);
break;
case ARM_THUMB_RELOC_BR22:
// thumb2 added two more bits to displacement, complicating the displacement decoding
{
uint32_t s = (instruction >> 10) & 0x1;
uint32_t j1 = (instruction >> 29) & 0x1;
uint32_t j2 = (instruction >> 27) & 0x1;
uint32_t imm10 = instruction & 0x3FF;
uint32_t imm11 = (instruction >> 16) & 0x7FF;
uint32_t i1 = (j1 == s);
uint32_t i2 = (j2 == s);
uint32_t dis = (s << 24) | (i1 << 23) | (i2 << 22) | (imm10 << 12) | (imm11 << 1);
int32_t sdis = dis;
if ( s )
sdis |= 0xFE000000;
displacement = sdis;
}
// The pc added will be +4 from the pc
displacement += 4;
betterDstAddr = srcAddr+displacement;
// If the instruction was blx, force the low 2 bits to be clear
if ((instruction & 0xF8000000) == 0xE8000000)
betterDstAddr &= 0xFFFFFFFC;
makeReferenceWithToBase(arm::kThumbBranch22, srcAddr, betterDstAddr, dstAddr);
break;
case ARM_RELOC_SECTDIFF:
case ARM_RELOC_LOCAL_SECTDIFF:
if ( !nextRelocIsPair ) {
throw "ARM_RELOC_SECTDIFF missing following pair";
}
if ( sreloc->r_length() != 2 )
throw "bad length for ARM_RELOC_SECTDIFF";
{
AtomAndOffset srcao = findAtomAndOffset(srcAddr);
AtomAndOffset fromao = findAtomAndOffset(nextRelocValue);
AtomAndOffset toao = findAtomAndOffset(dstAddr);
// check for addend encoded in the section content
pointerValue = LittleEndian::get32(*fixUpPtr);
if ( (dstAddr - nextRelocValue) != pointerValue ) {
if ( toao.atom == srcao.atom )
toao.offset += (pointerValue + nextRelocValue) - dstAddr;
else if ( fromao.atom == srcao.atom )
toao.offset += (pointerValue + nextRelocValue) - dstAddr;
else
fromao.offset += (dstAddr - pointerValue) - nextRelocValue;
}
new Reference<arm>(arm::kPointerDiff, srcao, fromao, toao);
}
break;
default:
warning("unexpected srelocation type %u", sreloc->r_type());
break;
}
}
return result;
}
template <typename A>
void Reader<A>::addReferencesForSection(const macho_section<P>* sect)
{
// ignore dwarf sections. If ld ever supports processing dwarf, this logic will need to change
if ( (sect->flags() & S_ATTR_DEBUG) == 0 ) {
switch ( sect->flags() & SECTION_TYPE ) {
case S_SYMBOL_STUBS:
case S_LAZY_SYMBOL_POINTERS:
// we ignore compiler generated stubs, so ignore those relocs too
break;
default:
// ignore all relocations in __eh_frame section
if ( sect == fehFrameSection )
return;
const macho_relocation_info<P>* relocs = (macho_relocation_info<P>*)((char*)(fHeader) + sect->reloff());
const uint32_t relocCount = sect->nreloc();
//fprintf(stderr, "relocCount = %d in section %s\n", relocCount, sect->sectname());
for (uint32_t r = 0; r < relocCount; ++r) {
try {
if ( addRelocReference(sect, &relocs[r]) )
++r; // skip next
}
catch (const char* msg) {
throwf("in section %s,%s reloc %u: %s", sect->segname(), sect->sectname(), r, msg);
}
}
}
}
}
template <>
const char* Reference<x86>::getDescription() const
{
static char temp[2048];
switch( fKind ) {
case x86::kNoFixUp:
sprintf(temp, "reference to ");
break;
case x86::kFollowOn:
sprintf(temp, "followed by ");
break;
case x86::kGroupSubordinate:
sprintf(temp, "group subordinate ");
break;
case x86::kPointerWeakImport:
sprintf(temp, "offset 0x%04X, weak import pointer to ", fFixUpOffsetInSrc);
break;
case x86::kPointer:
sprintf(temp, "offset 0x%04X, pointer to ", fFixUpOffsetInSrc);
break;
case x86::kPointerDiff:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 32-bit pointer difference: (&%s%s%s + 0x%08X) - (&%s%s%s + 0x%08X)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
break;
case x86::kPointerDiff16:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 16-bit pointer difference: (&%s%s%s + 0x%08X) - (&%s%s%s + 0x%08X)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
break;
case x86::kPCRel32WeakImport:
sprintf(temp, "offset 0x%04X, rel32 reference to weak imported ", fFixUpOffsetInSrc);
break;
case x86::kPCRel32:
sprintf(temp, "offset 0x%04X, rel32 reference to ", fFixUpOffsetInSrc);
break;
case x86::kPCRel16:
sprintf(temp, "offset 0x%04X, rel16 reference to ", fFixUpOffsetInSrc);
break;
case x86::kPCRel8:
sprintf(temp, "offset 0x%04X, rel8 reference to ", fFixUpOffsetInSrc);
break;
case x86::kAbsolute32:
sprintf(temp, "offset 0x%04X, absolute32 reference to ", fFixUpOffsetInSrc);
break;
case x86::kImageOffset32:
sprintf(temp, "offset 0x%04X, 32-bit offset of ", fFixUpOffsetInSrc);
break;
case x86::kPointerDiff24:
sprintf(temp, "offset 0x%04X, 24-bit pointer difference: (&%s + 0x%08X) - (&%s + 0x%08X)",
fFixUpOffsetInSrc, this->getTargetDisplayName(), fToTarget.offset,
this->getFromTargetDisplayName(), fFromTarget.offset );
return temp;
break;
case x86::kSectionOffset24:
sprintf(temp, "offset 0x%04X, 24-bit section offset of ", fFixUpOffsetInSrc);
break;
case x86::kDtraceProbe:
sprintf(temp, "offset 0x%04X, dtrace static probe ", fFixUpOffsetInSrc);
break;
case x86::kDtraceProbeSite:
sprintf(temp, "offset 0x%04X, dtrace static probe site", fFixUpOffsetInSrc);
break;
case x86::kDtraceIsEnabledSite:
sprintf(temp, "offset 0x%04X, dtrace static probe is-enabled site", fFixUpOffsetInSrc);
break;
case x86::kDtraceTypeReference:
sprintf(temp, "offset 0x%04X, dtrace type/stability reference", fFixUpOffsetInSrc);
break;
}
// always quote by-name references
if ( fToTargetName != NULL ) {
strcat(temp, "\"");
strcat(temp, fToTargetName);
strcat(temp, "\"");
}
else if ( fToTarget.atom != NULL ) {
strcat(temp, fToTarget.atom->getDisplayName());
}
else {
strcat(temp, "NULL target");
}
if ( fToTarget.offset != 0 )
sprintf(&temp[strlen(temp)], " plus 0x%08X", fToTarget.offset);
return temp;
}
template <>
const char* Reference<ppc>::getDescription() const
{
static char temp[2048];
switch( fKind ) {
case ppc::kNoFixUp:
sprintf(temp, "reference to ");
break;
case ppc::kFollowOn:
sprintf(temp, "followed by ");
break;
case ppc::kGroupSubordinate:
sprintf(temp, "group subordinate ");
break;
case ppc::kPointerWeakImport:
sprintf(temp, "offset 0x%04X, weak import pointer to ", fFixUpOffsetInSrc);
break;
case ppc::kPointer:
sprintf(temp, "offset 0x%04X, pointer to ", fFixUpOffsetInSrc);
break;
case ppc::kPointerDiff16:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 16-bit pointer difference: (&%s%s%s + %d) - (&%s%s%s + %d)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case ppc::kPointerDiff32:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 32-bit pointer difference: (&%s%s%s + %d) - (&%s%s%s + %d)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case ppc::kPointerDiff64:
throw "unsupported refrence kind";
break;
case ppc::kBranch24WeakImport:
sprintf(temp, "offset 0x%04X, pc-rel branch fixup to weak imported ", fFixUpOffsetInSrc);
break;
case ppc::kBranch24:
case ppc::kBranch14:
sprintf(temp, "offset 0x%04X, pc-rel branch fixup to ", fFixUpOffsetInSrc);
break;
case ppc::kPICBaseLow16:
sprintf(temp, "offset 0x%04X, low 16 fixup from pic-base of %s plus 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.atom->getDisplayName(), fFromTarget.offset);
break;
case ppc::kPICBaseLow14:
sprintf(temp, "offset 0x%04X, low 14 fixup from pic-base of %s plus 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.atom->getDisplayName(), fFromTarget.offset);
break;
case ppc::kPICBaseHigh16:
sprintf(temp, "offset 0x%04X, high 16 fixup from pic-base of %s plus 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.atom->getDisplayName(), fFromTarget.offset);
break;
case ppc::kAbsLow16:
sprintf(temp, "offset 0x%04X, low 16 fixup to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc::kAbsLow14:
sprintf(temp, "offset 0x%04X, low 14 fixup to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc::kAbsHigh16:
sprintf(temp, "offset 0x%04X, high 16 fixup or to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc::kAbsHigh16AddLow:
sprintf(temp, "offset 0x%04X, high 16 fixup add to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc::kDtraceProbe:
sprintf(temp, "offset 0x%04X, dtrace static probe ", fFixUpOffsetInSrc);
break;
case ppc::kDtraceProbeSite:
sprintf(temp, "offset 0x%04X, dtrace static probe site", fFixUpOffsetInSrc);
break;
case ppc::kDtraceIsEnabledSite:
sprintf(temp, "offset 0x%04X, dtrace static probe is-enabled site", fFixUpOffsetInSrc);
break;
case ppc::kDtraceTypeReference:
sprintf(temp, "offset 0x%04X, dtrace type/stability reference", fFixUpOffsetInSrc);
break;
}
// always quote by-name references
if ( fToTargetName != NULL ) {
strcat(temp, "\"");
strcat(temp, fToTargetName);
strcat(temp, "\"");
}
else if ( fToTarget.atom != NULL ) {
strcat(temp, fToTarget.atom->getDisplayName());
}
else {
strcat(temp, "NULL target");
}
if ( fToTarget.offset != 0 )
sprintf(&temp[strlen(temp)], " plus 0x%08X", fToTarget.offset);
return temp;
}
template <>
const char* Reference<ppc64>::getDescription() const
{
static char temp[2048];
switch( fKind ) {
case ppc64::kNoFixUp:
sprintf(temp, "reference to ");
break;
case ppc64::kFollowOn:
sprintf(temp, "followed by ");
break;
case ppc64::kGroupSubordinate:
sprintf(temp, "group subordinate ");
break;
case ppc64::kPointerWeakImport:
sprintf(temp, "offset 0x%04llX, weak import pointer to ", fFixUpOffsetInSrc);
break;
case ppc64::kPointer:
sprintf(temp, "offset 0x%04llX, pointer to ", fFixUpOffsetInSrc);
break;
case ppc64::kPointerDiff64:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04llX, 64-bit pointer difference: (&%s%s%s + %u) - (&%s%s%s + %u)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case ppc64::kPointerDiff32:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04llX, 32-bit pointer difference: (&%s%s%s + %u) - (&%s%s%s + %u)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case ppc64::kPointerDiff16:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04llX, 16-bit pointer difference: (&%s%s%s + %u) - (&%s%s%s + %u)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case ppc64::kBranch24WeakImport:
sprintf(temp, "offset 0x%04llX, pc-rel branch fixup to weak imported ", fFixUpOffsetInSrc);
break;
case ppc64::kBranch24:
case ppc64::kBranch14:
sprintf(temp, "offset 0x%04llX, pc-rel branch fixup to ", fFixUpOffsetInSrc);
break;
case ppc64::kPICBaseLow16:
sprintf(temp, "offset 0x%04llX, low 16 fixup from pic-base offset 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.offset);
break;
case ppc64::kPICBaseLow14:
sprintf(temp, "offset 0x%04llX, low 14 fixup from pic-base offset 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.offset);
break;
case ppc64::kPICBaseHigh16:
sprintf(temp, "offset 0x%04llX, high 16 fixup from pic-base offset 0x%04X to ", fFixUpOffsetInSrc, fFromTarget.offset);
break;
case ppc64::kAbsLow16:
sprintf(temp, "offset 0x%04llX, low 16 fixup to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc64::kAbsLow14:
sprintf(temp, "offset 0x%04llX, low 14 fixup to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc64::kAbsHigh16:
sprintf(temp, "offset 0x%04llX, high 16 fixup or to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc64::kAbsHigh16AddLow:
sprintf(temp, "offset 0x%04llX, high 16 fixup add to absolute address of ", fFixUpOffsetInSrc);
break;
case ppc64::kDtraceProbe:
sprintf(temp, "offset 0x%04llX, dtrace static probe ", fFixUpOffsetInSrc);
break;
case ppc64::kDtraceProbeSite:
sprintf(temp, "offset 0x%04llX, dtrace static probe site", fFixUpOffsetInSrc);
break;
case ppc64::kDtraceIsEnabledSite:
sprintf(temp, "offset 0x%04llX, dtrace static probe is-enabled site", fFixUpOffsetInSrc);
break;
case ppc64::kDtraceTypeReference:
sprintf(temp, "offset 0x%04llX, dtrace type/stability reference", fFixUpOffsetInSrc);
break;
}
// always quote by-name references
if ( fToTargetName != NULL ) {
strcat(temp, "\"");
strcat(temp, fToTargetName);
strcat(temp, "\"");
}
else if ( fToTarget.atom != NULL ) {
strcat(temp, fToTarget.atom->getDisplayName());
}
else {
strcat(temp, "NULL target");
}
if ( fToTarget.offset != 0 )
sprintf(&temp[strlen(temp)], " plus 0x%llX", this->getTargetOffset());
return temp;
}
template <>
const char* Reference<x86_64>::getDescription() const
{
static char temp[2048];
switch( fKind ) {
case x86_64::kNoFixUp:
sprintf(temp, "reference to ");
break;
case x86_64::kFollowOn:
sprintf(temp, "followed by ");
break;
case x86_64::kGroupSubordinate:
sprintf(temp, "group subordinate ");
break;
case x86_64::kPointerWeakImport:
sprintf(temp, "offset 0x%04llX, weak import pointer to ", fFixUpOffsetInSrc);
break;
case x86_64::kPointer:
sprintf(temp, "offset 0x%04llX, pointer to ", fFixUpOffsetInSrc);
break;
case x86_64::kPointer32:
sprintf(temp, "offset 0x%04llX, 32-bit pointer to ", fFixUpOffsetInSrc);
break;
case x86_64::kPointerDiff32:
case x86_64::kPointerDiff:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
const char* size = (fKind == x86_64::kPointerDiff32) ? "32-bit" : "64-bit";
sprintf(temp, "offset 0x%04llX, %s pointer difference: (&%s%s%s + 0x%08X) - (&%s%s%s + 0x%08X)",
fFixUpOffsetInSrc, size, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
break;
case x86_64::kPCRel32:
sprintf(temp, "offset 0x%04llX, rel32 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32_1:
sprintf(temp, "offset 0x%04llX, rel32-1 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32_2:
sprintf(temp, "offset 0x%04llX, rel32-2 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32_4:
sprintf(temp, "offset 0x%04llX, rel32-4 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kBranchPCRel32:
sprintf(temp, "offset 0x%04llX, branch rel32 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kBranchPCRel32WeakImport:
sprintf(temp, "offset 0x%04llX, branch rel32 reference to weak imported ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32GOT:
sprintf(temp, "offset 0x%04llX, rel32 reference to GOT entry for ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32GOTWeakImport:
sprintf(temp, "offset 0x%04llX, rel32 reference to GOT entry for weak imported ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32GOTLoad:
sprintf(temp, "offset 0x%04llX, rel32 reference to GOT entry for ", fFixUpOffsetInSrc);
break;
case x86_64::kPCRel32GOTLoadWeakImport:
sprintf(temp, "offset 0x%04llX, rel32 reference to GOT entry for weak imported ", fFixUpOffsetInSrc);
break;
case x86_64::kGOTNoFixUp:
sprintf(temp, "reference to GOT entry for ");
break;
case x86_64::kBranchPCRel8:
sprintf(temp, "offset 0x%04llX, branch rel8 reference to ", fFixUpOffsetInSrc);
break;
case x86_64::kPointerDiff24:
sprintf(temp, "offset 0x%04llX, 24-bit pointer difference: (&%s + 0x%08X) - (&%s + 0x%08X)",
fFixUpOffsetInSrc, this->getTargetDisplayName(), fToTarget.offset,
this->getFromTargetDisplayName(), fFromTarget.offset );
return temp;
case x86_64::kImageOffset32:
sprintf(temp, "offset 0x%04llX, 32bit offset of ", fFixUpOffsetInSrc);
break;
case x86_64::kSectionOffset24:
sprintf(temp, "offset 0x%04llX, 24-bit section offset of ", fFixUpOffsetInSrc);
break;
case x86_64::kDtraceProbe:
sprintf(temp, "offset 0x%04llX, dtrace static probe ", fFixUpOffsetInSrc);
break;
case x86_64::kDtraceProbeSite:
sprintf(temp, "offset 0x%04llX, dtrace static probe site", fFixUpOffsetInSrc);
break;
case x86_64::kDtraceIsEnabledSite:
sprintf(temp, "offset 0x%04llX, dtrace static probe is-enabled site", fFixUpOffsetInSrc);
break;
case x86_64::kDtraceTypeReference:
sprintf(temp, "offset 0x%04llX, dtrace type/stability reference", fFixUpOffsetInSrc);
break;
}
// always quote by-name references
if ( fToTargetName != NULL ) {
strcat(temp, "\"");
strcat(temp, fToTargetName);
strcat(temp, "\"");
}
else if ( fToTarget.atom != NULL ) {
strcat(temp, fToTarget.atom->getDisplayName());
}
else {
strcat(temp, "NULL target");
}
if ( fToTarget.offset != 0 )
sprintf(&temp[strlen(temp)], " plus 0x%llX", this->getTargetOffset());
return temp;
}
template <>
const char* Reference<arm>::getDescription() const
{
static char temp[2048];
switch( fKind ) {
case arm::kNoFixUp:
sprintf(temp, "reference to ");
break;
case arm::kFollowOn:
sprintf(temp, "followed by ");
break;
case arm::kGroupSubordinate:
sprintf(temp, "group subordinate ");
break;
case arm::kPointer:
sprintf(temp, "offset 0x%04X, pointer to ", fFixUpOffsetInSrc);
break;
case arm::kPointerWeakImport:
sprintf(temp, "offset 0x%04X, weak import pointer to ", fFixUpOffsetInSrc);
break;
case arm::kPointerDiff:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 32-bit pointer difference: (&%s%s%s + %d) - (&%s%s%s + %d)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case arm::kPointerDiff12:
{
// by-name references have quoted names
const char* targetQuotes = (&(this->getTarget()) == NULL) ? "\"" : "";
const char* fromQuotes = (&(this->getFromTarget()) == NULL) ? "\"" : "";
sprintf(temp, "offset 0x%04X, 12-bit pointer difference: (&%s%s%s + %d) - (&%s%s%s + %d)",
fFixUpOffsetInSrc, targetQuotes, this->getTargetDisplayName(), targetQuotes, fToTarget.offset,
fromQuotes, this->getFromTargetDisplayName(), fromQuotes, fFromTarget.offset );
return temp;
}
case arm::kReadOnlyPointer:
sprintf(temp, "offset 0x%04X, read-only pointer to ", fFixUpOffsetInSrc);
break;
case arm::kBranch24:
case arm::kThumbBranch22:
sprintf(temp, "offset 0x%04X, pc-rel branch fixup to ", fFixUpOffsetInSrc);
break;
case arm::kBranch24WeakImport:
case arm::kThumbBranch22WeakImport:
sprintf(temp, "offset 0x%04X, pc-rel branch fixup to weak imported ", fFixUpOffsetInSrc);
break;
case arm::kDtraceProbe:
sprintf(temp, "offset 0x%04X, dtrace static probe ", fFixUpOffsetInSrc);
break;
case arm::kDtraceProbeSite:
sprintf(temp, "offset 0x%04X, dtrace static probe site", fFixUpOffsetInSrc);
break;
case arm::kDtraceIsEnabledSite:
sprintf(temp, "offset 0x%04X, dtrace static probe is-enabled site", fFixUpOffsetInSrc);
break;
case arm::kDtraceTypeReference:
sprintf(temp, "offset 0x%04X, dtrace type/stability reference", fFixUpOffsetInSrc);
break;
}
// always quote by-name references
if ( fToTargetName != NULL ) {
strcat(temp, "\"");
strcat(temp, fToTargetName);
strcat(temp, "\"");
}
else if ( fToTarget.atom != NULL ) {
strcat(temp, fToTarget.atom->getDisplayName());
}
else {
strcat(temp, "NULL target");
}
if ( fToTarget.offset != 0 )
sprintf(&temp[strlen(temp)], " plus 0x%08X", fToTarget.offset);
return temp;
}
template <>
bool Reference<x86>::isBranch() const
{
switch ( fKind ) {
case x86::kPCRel32:
case x86::kPCRel32WeakImport:
return true;
default:
return false;
}
}
template <>
bool Reference<x86_64>::isBranch() const
{
switch ( fKind ) {
case x86_64::kBranchPCRel32:
case x86_64::kBranchPCRel32WeakImport:
return true;
default:
return false;
}
}
template <>
bool Reference<ppc>::isBranch() const
{
switch ( fKind ) {
case ppc::kBranch24:
case ppc::kBranch24WeakImport:
return true;
default:
return false;
}
}
template <>
bool Reference<ppc64>::isBranch() const
{
switch ( fKind ) {
case ppc64::kBranch24:
case ppc64::kBranch24WeakImport:
return true;
default:
return false;
}
}
template <>
bool Reference<arm>::isBranch() const
{
switch ( fKind ) {
case arm::kBranch24:
case arm::kBranch24WeakImport:
case arm::kThumbBranch22:
case arm::kThumbBranch22WeakImport:
return true;
default:
return false;
}
}
}; // namespace relocatable
}; // namespace mach_o
#endif // __OBJECT_FILE_MACH_O__