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gerrit-public.fairphone.software / toolchain / llvm-project / 141330aef62f4a753622441d11a756cfc72bde94 / . / lld / lib / ReaderWriter / MachO / MachONormalizedFileFromAtoms.cpp
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//===- lib/ReaderWriter/MachO/MachONormalizedFileFromAtoms.cpp ------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file Converts from in-memory Atoms to in-memory normalized mach-o.
///
/// +------------+
/// | normalized |
/// +------------+
/// ^
/// |
/// |
/// +-------+
/// | Atoms |
/// +-------+
#include "MachONormalizedFile.h"
#include "ArchHandler.h"
#include "MachONormalizedFileBinaryUtils.h"
#include "lld/Core/Error.h"
#include "lld/Core/LLVM.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/MachO.h"
#include <map>
#include <system_error>
using llvm::StringRef;
using llvm::isa;
using namespace llvm::MachO;
using namespace lld::mach_o::normalized;
using namespace lld;
namespace {
struct AtomInfo {
const DefinedAtom *atom;
uint64_t offsetInSection;
};
struct SectionInfo {
SectionInfo(StringRef seg, StringRef sect, SectionType type,
const MachOLinkingContext &ctxt, uint32_t attr=0);
StringRef segmentName;
StringRef sectionName;
SectionType type;
uint32_t attributes;
uint64_t address;
uint64_t size;
uint32_t alignment;
std::vector<AtomInfo> atomsAndOffsets;
uint32_t normalizedSectionIndex;
uint32_t finalSectionIndex;
};
SectionInfo::SectionInfo(StringRef sg, StringRef sct, SectionType t,
const MachOLinkingContext &ctxt, uint32_t attrs)
: segmentName(sg), sectionName(sct), type(t), attributes(attrs),
address(0), size(0), alignment(0),
normalizedSectionIndex(0), finalSectionIndex(0) {
uint8_t align;
if (ctxt.sectionAligned(segmentName, sectionName, align)) {
alignment = align;
}
}
struct SegmentInfo {
SegmentInfo(StringRef name);
StringRef name;
uint64_t address;
uint64_t size;
uint32_t access;
std::vector<SectionInfo*> sections;
uint32_t normalizedSegmentIndex;
};
SegmentInfo::SegmentInfo(StringRef n)
: name(n), address(0), size(0), access(0), normalizedSegmentIndex(0) {
}
class Util {
public:
Util(const MachOLinkingContext &ctxt) : _context(ctxt),
_archHandler(ctxt.archHandler()), _entryAtom(nullptr) {}
void assignAtomsToSections(const lld::File &atomFile);
void organizeSections();
void assignAddressesToSections(const NormalizedFile &file);
uint32_t fileFlags();
void copySegmentInfo(NormalizedFile &file);
void copySectionInfo(NormalizedFile &file);
void updateSectionInfo(NormalizedFile &file);
void buildAtomToAddressMap();
std::error_code addSymbols(const lld::File &atomFile, NormalizedFile &file);
void addIndirectSymbols(const lld::File &atomFile, NormalizedFile &file);
void addRebaseAndBindingInfo(const lld::File &, NormalizedFile &file);
void addExportInfo(const lld::File &, NormalizedFile &file);
void addSectionRelocs(const lld::File &, NormalizedFile &file);
void buildDataInCodeArray(const lld::File &, NormalizedFile &file);
void addDependentDylibs(const lld::File &, NormalizedFile &file);
void copyEntryPointAddress(NormalizedFile &file);
void copySectionContent(NormalizedFile &file);
private:
typedef std::map<DefinedAtom::ContentType, SectionInfo*> TypeToSection;
typedef llvm::DenseMap<const Atom*, uint64_t> AtomToAddress;
struct DylibInfo { int ordinal; bool hasWeak; bool hasNonWeak; };
typedef llvm::StringMap<DylibInfo> DylibPathToInfo;
SectionInfo *sectionForAtom(const DefinedAtom*);
SectionInfo *getRelocatableSection(DefinedAtom::ContentType type);
SectionInfo *getFinalSection(DefinedAtom::ContentType type);
void appendAtom(SectionInfo *sect, const DefinedAtom *atom);
SegmentInfo *segmentForName(StringRef segName);
void layoutSectionsInSegment(SegmentInfo *seg, uint64_t &addr);
void layoutSectionsInTextSegment(size_t, SegmentInfo *, uint64_t &);
void copySectionContent(SectionInfo *si, ContentBytes &content);
uint16_t descBits(const DefinedAtom* atom);
int dylibOrdinal(const SharedLibraryAtom *sa);
void segIndexForSection(const SectionInfo *sect,
uint8_t &segmentIndex, uint64_t &segmentStartAddr);
const Atom *targetOfLazyPointer(const DefinedAtom *lpAtom);
const Atom *targetOfStub(const DefinedAtom *stubAtom);
std::error_code getSymbolTableRegion(const DefinedAtom* atom,
bool &inGlobalsRegion,
SymbolScope &symbolScope);
void appendSection(SectionInfo *si, NormalizedFile &file);
uint32_t sectionIndexForAtom(const Atom *atom);
static uint64_t alignTo(uint64_t value, uint8_t align2);
typedef llvm::DenseMap<const Atom*, uint32_t> AtomToIndex;
struct AtomAndIndex { const Atom *atom; uint32_t index; SymbolScope scope; };
struct AtomSorter {
bool operator()(const AtomAndIndex &left, const AtomAndIndex &right);
};
struct SegmentSorter {
bool operator()(const SegmentInfo *left, const SegmentInfo *right);
static unsigned weight(const SegmentInfo *);
};
struct TextSectionSorter {
bool operator()(const SectionInfo *left, const SectionInfo *right);
static unsigned weight(const SectionInfo *);
};
const MachOLinkingContext &_context;
mach_o::ArchHandler &_archHandler;
llvm::BumpPtrAllocator _allocator;
std::vector<SectionInfo*> _sectionInfos;
std::vector<SegmentInfo*> _segmentInfos;
TypeToSection _sectionMap;
std::vector<SectionInfo*> _customSections;
AtomToAddress _atomToAddress;
DylibPathToInfo _dylibInfo;
const DefinedAtom *_entryAtom;
AtomToIndex _atomToSymbolIndex;
};
SectionInfo *Util::getRelocatableSection(DefinedAtom::ContentType type) {
StringRef segmentName;
StringRef sectionName;
SectionType sectionType;
SectionAttr sectionAttrs;
// Use same table used by when parsing .o files.
relocatableSectionInfoForContentType(type, segmentName, sectionName,
sectionType, sectionAttrs);
// If we already have a SectionInfo with this name, re-use it.
// This can happen if two ContentType map to the same mach-o section.
for (auto sect : _sectionMap) {
if (sect.second->sectionName.equals(sectionName) &&
sect.second->segmentName.equals(segmentName)) {
return sect.second;
}
}
// Otherwise allocate new SectionInfo object.
SectionInfo *sect = new (_allocator) SectionInfo(segmentName, sectionName,
sectionType, _context,
sectionAttrs);
_sectionInfos.push_back(sect);
_sectionMap[type] = sect;
return sect;
}
#define ENTRY(seg, sect, type, atomType) \
{seg, sect, type, DefinedAtom::atomType }
struct MachOFinalSectionFromAtomType {
StringRef segmentName;
StringRef sectionName;
SectionType sectionType;
DefinedAtom::ContentType atomType;
};
const MachOFinalSectionFromAtomType sectsToAtomType[] = {
ENTRY("__TEXT", "__text", S_REGULAR, typeCode),
ENTRY("__TEXT", "__cstring", S_CSTRING_LITERALS, typeCString),
ENTRY("__TEXT", "__ustring", S_REGULAR, typeUTF16String),
ENTRY("__TEXT", "__const", S_REGULAR, typeConstant),
ENTRY("__TEXT", "__const", S_4BYTE_LITERALS, typeLiteral4),
ENTRY("__TEXT", "__const", S_8BYTE_LITERALS, typeLiteral8),
ENTRY("__TEXT", "__const", S_16BYTE_LITERALS, typeLiteral16),
ENTRY("__TEXT", "__stubs", S_SYMBOL_STUBS, typeStub),
ENTRY("__TEXT", "__stub_helper", S_REGULAR, typeStubHelper),
ENTRY("__TEXT", "__gcc_except_tab", S_REGULAR, typeLSDA),
ENTRY("__TEXT", "__eh_frame", S_COALESCED, typeCFI),
ENTRY("__DATA", "__data", S_REGULAR, typeData),
ENTRY("__DATA", "__const", S_REGULAR, typeConstData),
ENTRY("__DATA", "__cfstring", S_REGULAR, typeCFString),
ENTRY("__DATA", "__la_symbol_ptr", S_LAZY_SYMBOL_POINTERS,
typeLazyPointer),
ENTRY("__DATA", "__mod_init_func", S_MOD_INIT_FUNC_POINTERS,
typeInitializerPtr),
ENTRY("__DATA", "__mod_term_func", S_MOD_TERM_FUNC_POINTERS,
typeTerminatorPtr),
ENTRY("__DATA", "___got", S_NON_LAZY_SYMBOL_POINTERS,
typeGOT),
ENTRY("__DATA", "___bss", S_ZEROFILL, typeZeroFill),
// FIXME: __compact_unwind actually needs to be processed by a pass and put
// into __TEXT,__unwind_info. For now, forwarding it back to
// __LD,__compact_unwind is harmless (it's ignored by the unwinder, which then
// proceeds to process __TEXT,__eh_frame for its instructions).
ENTRY("__LD", "__compact_unwind", S_REGULAR, typeCompactUnwindInfo),
};
#undef ENTRY
SectionInfo *Util::getFinalSection(DefinedAtom::ContentType atomType) {
for (auto &p : sectsToAtomType) {
if (p.atomType != atomType)
continue;
SectionAttr sectionAttrs = 0;
switch (atomType) {
case DefinedAtom::typeCode:
case DefinedAtom::typeStub:
sectionAttrs = S_ATTR_PURE_INSTRUCTIONS;
break;
default:
break;
}
// If we already have a SectionInfo with this name, re-use it.
// This can happen if two ContentType map to the same mach-o section.
for (auto sect : _sectionMap) {
if (sect.second->sectionName.equals(p.sectionName) &&
sect.second->segmentName.equals(p.segmentName)) {
return sect.second;
}
}
// Otherwise allocate new SectionInfo object.
SectionInfo *sect = new (_allocator) SectionInfo(p.segmentName,
p.sectionName,
p.sectionType,
_context,
sectionAttrs);
_sectionInfos.push_back(sect);
_sectionMap[atomType] = sect;
return sect;
}
llvm_unreachable("content type not yet supported");
}
SectionInfo *Util::sectionForAtom(const DefinedAtom *atom) {
if (atom->sectionChoice() == DefinedAtom::sectionBasedOnContent) {
// Section for this atom is derived from content type.
DefinedAtom::ContentType type = atom->contentType();
auto pos = _sectionMap.find(type);
if ( pos != _sectionMap.end() )
return pos->second;
bool rMode = (_context.outputMachOType() == llvm::MachO::MH_OBJECT);
return rMode ? getRelocatableSection(type) : getFinalSection(type);
} else {
// This atom needs to be in a custom section.
StringRef customName = atom->customSectionName();
// Look to see if we have already allocated the needed custom section.
for(SectionInfo *sect : _customSections) {
const DefinedAtom *firstAtom = sect->atomsAndOffsets.front().atom;
if (firstAtom->customSectionName().equals(customName)) {
return sect;
}
}
// Not found, so need to create a new custom section.
size_t seperatorIndex = customName.find('/');
assert(seperatorIndex != StringRef::npos);
StringRef segName = customName.slice(0, seperatorIndex);
StringRef sectName = customName.drop_front(seperatorIndex + 1);
SectionInfo *sect = new (_allocator) SectionInfo(segName, sectName,
S_REGULAR, _context);
_customSections.push_back(sect);
_sectionInfos.push_back(sect);
return sect;
}
}
void Util::appendAtom(SectionInfo *sect, const DefinedAtom *atom) {
// Figure out offset for atom in this section given alignment constraints.
uint64_t offset = sect->size;
DefinedAtom::Alignment atomAlign = atom->alignment();
uint64_t align2 = 1 << atomAlign.powerOf2;
uint64_t requiredModulus = atomAlign.modulus;
uint64_t currentModulus = (offset % align2);
if ( currentModulus != requiredModulus ) {
if ( requiredModulus > currentModulus )
offset += requiredModulus-currentModulus;
else
offset += align2+requiredModulus-currentModulus;
}
// Record max alignment of any atom in this section.
if ( atomAlign.powerOf2 > sect->alignment )
sect->alignment = atomAlign.powerOf2;
// Assign atom to this section with this offset.
AtomInfo ai = {atom, offset};
sect->atomsAndOffsets.push_back(ai);
// Update section size to include this atom.
sect->size = offset + atom->size();
}
void Util::assignAtomsToSections(const lld::File &atomFile) {
for (const DefinedAtom *atom : atomFile.defined()) {
appendAtom(sectionForAtom(atom), atom);
}
}
SegmentInfo *Util::segmentForName(StringRef segName) {
for (SegmentInfo *si : _segmentInfos) {
if ( si->name.equals(segName) )
return si;
}
SegmentInfo *info = new (_allocator) SegmentInfo(segName);
if (segName.equals("__TEXT"))
info->access = VM_PROT_READ | VM_PROT_EXECUTE;
else if (segName.equals("__DATA"))
info->access = VM_PROT_READ | VM_PROT_WRITE;
else if (segName.equals("__PAGEZERO"))
info->access = 0;
_segmentInfos.push_back(info);
return info;
}
unsigned Util::SegmentSorter::weight(const SegmentInfo *seg) {
return llvm::StringSwitch<unsigned>(seg->name)
.Case("__PAGEZERO", 1)
.Case("__TEXT", 2)
.Case("__DATA", 3)
.Default(100);
}
bool Util::SegmentSorter::operator()(const SegmentInfo *left,
const SegmentInfo *right) {
return (weight(left) < weight(right));
}
unsigned Util::TextSectionSorter::weight(const SectionInfo *sect) {
return llvm::StringSwitch<unsigned>(sect->sectionName)
.Case("__text", 1)
.Case("__stubs", 2)
.Case("__stub_helper", 3)
.Case("__const", 4)
.Case("__cstring", 5)
.Case("__unwind_info", 98)
.Case("__eh_frame", 99)
.Default(10);
}
bool Util::TextSectionSorter::operator()(const SectionInfo *left,
const SectionInfo *right) {
return (weight(left) < weight(right));
}
void Util::organizeSections() {
if (_context.outputMachOType() == llvm::MachO::MH_OBJECT) {
// Leave sections ordered as normalized file specified.
uint32_t sectionIndex = 1;
for (SectionInfo *si : _sectionInfos) {
si->finalSectionIndex = sectionIndex++;
}
} else {
// Main executables, need a zero-page segment
if (_context.outputMachOType() == llvm::MachO::MH_EXECUTE)
segmentForName("__PAGEZERO");
// Group sections into segments.
for (SectionInfo *si : _sectionInfos) {
SegmentInfo *seg = segmentForName(si->segmentName);
seg->sections.push_back(si);
}
// Sort segments.
std::sort(_segmentInfos.begin(), _segmentInfos.end(), SegmentSorter());
// Sort sections within segments.
for (SegmentInfo *seg : _segmentInfos) {
if (seg->name.equals("__TEXT")) {
std::sort(seg->sections.begin(), seg->sections.end(),
TextSectionSorter());
}
}
// Record final section indexes.
uint32_t segmentIndex = 0;
uint32_t sectionIndex = 1;
for (SegmentInfo *seg : _segmentInfos) {
seg->normalizedSegmentIndex = segmentIndex++;
for (SectionInfo *sect : seg->sections) {
sect->finalSectionIndex = sectionIndex++;
}
}
}
}
uint64_t Util::alignTo(uint64_t value, uint8_t align2) {
return llvm::RoundUpToAlignment(value, 1 << align2);
}
void Util::layoutSectionsInSegment(SegmentInfo *seg, uint64_t &addr) {
seg->address = addr;
for (SectionInfo *sect : seg->sections) {
sect->address = alignTo(addr, sect->alignment);
addr += sect->size;
}
seg->size = llvm::RoundUpToAlignment(addr - seg->address,_context.pageSize());
}
// __TEXT segment lays out backwards so padding is at front after load commands.
void Util::layoutSectionsInTextSegment(size_t hlcSize, SegmentInfo *seg,
uint64_t &addr) {
seg->address = addr;
// Walks sections starting at end to calculate padding for start.
int64_t taddr = 0;
for (auto it = seg->sections.rbegin(); it != seg->sections.rend(); ++it) {
SectionInfo *sect = *it;
taddr -= sect->size;
taddr = taddr & (0 - (1 << sect->alignment));
}
int64_t padding = taddr - hlcSize;
while (padding < 0)
padding += _context.pageSize();
// Start assigning section address starting at padded offset.
addr += (padding + hlcSize);
for (SectionInfo *sect : seg->sections) {
sect->address = alignTo(addr, sect->alignment);
addr = sect->address + sect->size;
}
seg->size = llvm::RoundUpToAlignment(addr - seg->address,_context.pageSize());
}
void Util::assignAddressesToSections(const NormalizedFile &file) {
size_t hlcSize = headerAndLoadCommandsSize(file);
uint64_t address = 0; // FIXME
if (_context.outputMachOType() != llvm::MachO::MH_OBJECT) {
for (SegmentInfo *seg : _segmentInfos) {
if (seg->name.equals("__PAGEZERO")) {
seg->size = _context.pageZeroSize();
address += seg->size;
}
else if (seg->name.equals("__TEXT"))
layoutSectionsInTextSegment(hlcSize, seg, address);
else
layoutSectionsInSegment(seg, address);
address = llvm::RoundUpToAlignment(address, _context.pageSize());
}
DEBUG_WITH_TYPE("WriterMachO-norm",
llvm::dbgs() << "assignAddressesToSections()\n";
for (SegmentInfo *sgi : _segmentInfos) {
llvm::dbgs() << " address=" << llvm::format("0x%08llX", sgi->address)
<< ", size=" << llvm::format("0x%08llX", sgi->size)
<< ", segment-name='" << sgi->name
<< "'\n";
for (SectionInfo *si : sgi->sections) {
llvm::dbgs()<< " addr=" << llvm::format("0x%08llX", si->address)
<< ", size=" << llvm::format("0x%08llX", si->size)
<< ", section-name='" << si->sectionName
<< "\n";
}
}
);
} else {
for (SectionInfo *sect : _sectionInfos) {
sect->address = alignTo(address, sect->alignment);
address = sect->address + sect->size;
}
DEBUG_WITH_TYPE("WriterMachO-norm",
llvm::dbgs() << "assignAddressesToSections()\n";
for (SectionInfo *si : _sectionInfos) {
llvm::dbgs() << " section=" << si->sectionName
<< " address= " << llvm::format("0x%08X", si->address)
<< " size= " << llvm::format("0x%08X", si->size)
<< "\n";
}
);
}
}
void Util::copySegmentInfo(NormalizedFile &file) {
for (SegmentInfo *sgi : _segmentInfos) {
Segment seg;
seg.name = sgi->name;
seg.address = sgi->address;
seg.size = sgi->size;
seg.access = sgi->access;
file.segments.push_back(seg);
}
}
void Util::appendSection(SectionInfo *si, NormalizedFile &file) {
// Add new empty section to end of file.sections.
Section temp;
file.sections.push_back(std::move(temp));
Section* normSect = &file.sections.back();
// Copy fields to normalized section.
normSect->segmentName = si->segmentName;
normSect->sectionName = si->sectionName;
normSect->type = si->type;
normSect->attributes = si->attributes;
normSect->address = si->address;
normSect->alignment = si->alignment;
// Record where normalized section is.
si->normalizedSectionIndex = file.sections.size()-1;
}
void Util::copySectionContent(NormalizedFile &file) {
const bool r = (_context.outputMachOType() == llvm::MachO::MH_OBJECT);
// Utility function for ArchHandler to find address of atom in output file.
auto addrForAtom = [&] (const Atom &atom) -> uint64_t {
auto pos = _atomToAddress.find(&atom);
assert(pos != _atomToAddress.end());
return pos->second;
};
for (SectionInfo *si : _sectionInfos) {
if (si->type == llvm::MachO::S_ZEROFILL)
continue;
// Copy content from atoms to content buffer for section.
uint8_t *sectionContent = file.ownedAllocations.Allocate<uint8_t>(si->size);
Section *normSect = &file.sections[si->normalizedSectionIndex];
normSect->content = llvm::makeArrayRef(sectionContent, si->size);
for (AtomInfo &ai : si->atomsAndOffsets) {
uint8_t *atomContent = reinterpret_cast<uint8_t*>
(&sectionContent[ai.offsetInSection]);
_archHandler.generateAtomContent(*ai.atom, r, addrForAtom, atomContent);
}
}
}
void Util::copySectionInfo(NormalizedFile &file) {
file.sections.reserve(_sectionInfos.size());
// For final linked images, write sections grouped by segment.
if (_context.outputMachOType() != llvm::MachO::MH_OBJECT) {
for (SegmentInfo *sgi : _segmentInfos) {
for (SectionInfo *si : sgi->sections) {
appendSection(si, file);
}
}
} else {
// Object files write sections in default order.
for (SectionInfo *si : _sectionInfos) {
appendSection(si, file);
}
}
}
void Util::updateSectionInfo(NormalizedFile &file) {
file.sections.reserve(_sectionInfos.size());
if (_context.outputMachOType() != llvm::MachO::MH_OBJECT) {
// For final linked images, sections grouped by segment.
for (SegmentInfo *sgi : _segmentInfos) {
Segment *normSeg = &file.segments[sgi->normalizedSegmentIndex];
normSeg->address = sgi->address;
normSeg->size = sgi->size;
for (SectionInfo *si : sgi->sections) {
Section *normSect = &file.sections[si->normalizedSectionIndex];
normSect->address = si->address;
}
}
} else {
// Object files write sections in default order.
for (SectionInfo *si : _sectionInfos) {
Section *normSect = &file.sections[si->normalizedSectionIndex];
normSect->address = si->address;
}
}
}
void Util::copyEntryPointAddress(NormalizedFile &nFile) {
if (_context.outputTypeHasEntry()) {
if (_archHandler.isThumbFunction(*_entryAtom))
nFile.entryAddress = (_atomToAddress[_entryAtom] | 1);
else
nFile.entryAddress = _atomToAddress[_entryAtom];
}
}
void Util::buildAtomToAddressMap() {
DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
<< "assign atom addresses:\n");
const bool lookForEntry = _context.outputTypeHasEntry();
for (SectionInfo *sect : _sectionInfos) {
for (const AtomInfo &info : sect->atomsAndOffsets) {
_atomToAddress[info.atom] = sect->address + info.offsetInSection;
if (lookForEntry && (info.atom->contentType() == DefinedAtom::typeCode) &&
(info.atom->size() != 0) &&
info.atom->name() == _context.entrySymbolName()) {
_entryAtom = info.atom;
}
DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
<< " address="
<< llvm::format("0x%016X", _atomToAddress[info.atom])
<< " atom=" << info.atom
<< " name=" << info.atom->name() << "\n");
}
}
}
uint16_t Util::descBits(const DefinedAtom* atom) {
uint16_t desc = 0;
switch (atom->merge()) {
case lld::DefinedAtom::mergeNo:
case lld::DefinedAtom::mergeAsTentative:
break;
case lld::DefinedAtom::mergeAsWeak:
case lld::DefinedAtom::mergeAsWeakAndAddressUsed:
desc |= N_WEAK_DEF;
break;
case lld::DefinedAtom::mergeSameNameAndSize:
case lld::DefinedAtom::mergeByLargestSection:
case lld::DefinedAtom::mergeByContent:
llvm_unreachable("Unsupported DefinedAtom::merge()");
break;
}
if (atom->contentType() == lld::DefinedAtom::typeResolver)
desc |= N_SYMBOL_RESOLVER;
if (_archHandler.isThumbFunction(*atom))
desc |= N_ARM_THUMB_DEF;
if (atom->deadStrip() == DefinedAtom::deadStripNever) {
if ((atom->contentType() != DefinedAtom::typeInitializerPtr)
&& (atom->contentType() != DefinedAtom::typeTerminatorPtr))
desc |= N_NO_DEAD_STRIP;
}
return desc;
}
bool Util::AtomSorter::operator()(const AtomAndIndex &left,
const AtomAndIndex &right) {
return (left.atom->name().compare(right.atom->name()) < 0);
}
std::error_code Util::getSymbolTableRegion(const DefinedAtom* atom,
bool &inGlobalsRegion,
SymbolScope &scope) {
bool rMode = (_context.outputMachOType() == llvm::MachO::MH_OBJECT);
switch (atom->scope()) {
case Atom::scopeTranslationUnit:
scope = 0;
inGlobalsRegion = false;
return std::error_code();
case Atom::scopeLinkageUnit:
if ((_context.exportMode() == MachOLinkingContext::ExportMode::whiteList)
&& _context.exportSymbolNamed(atom->name())) {
return make_dynamic_error_code(Twine("cannot export hidden symbol ")
+ atom->name());
}
if (rMode) {
if (_context.keepPrivateExterns()) {
// -keep_private_externs means keep in globals region as N_PEXT.
scope = N_PEXT | N_EXT;
inGlobalsRegion = true;
return std::error_code();
}
}
// scopeLinkageUnit symbols are no longer global once linked.
scope = N_PEXT;
inGlobalsRegion = false;
return std::error_code();
case Atom::scopeGlobal:
if (_context.exportRestrictMode()) {
if (_context.exportSymbolNamed(atom->name())) {
scope = N_EXT;
inGlobalsRegion = true;
return std::error_code();
} else {
scope = N_PEXT;
inGlobalsRegion = false;
return std::error_code();
}
} else {
scope = N_EXT;
inGlobalsRegion = true;
return std::error_code();
}
break;
}
}
std::error_code Util::addSymbols(const lld::File &atomFile,
NormalizedFile &file) {
bool rMode = (_context.outputMachOType() == llvm::MachO::MH_OBJECT);
// Mach-O symbol table has three regions: locals, globals, undefs.
// Add all local (non-global) symbols in address order
std::vector<AtomAndIndex> globals;
globals.reserve(512);
for (SectionInfo *sect : _sectionInfos) {
for (const AtomInfo &info : sect->atomsAndOffsets) {
const DefinedAtom *atom = info.atom;
if (!atom->name().empty()) {
SymbolScope symbolScope;
bool inGlobalsRegion;
if (auto ec = getSymbolTableRegion(atom, inGlobalsRegion, symbolScope)){
return ec;
}
if (inGlobalsRegion) {
AtomAndIndex ai = { atom, sect->finalSectionIndex, symbolScope };
globals.push_back(ai);
} else {
Symbol sym;
sym.name = atom->name();
sym.type = N_SECT;
sym.scope = symbolScope;
sym.sect = sect->finalSectionIndex;
sym.desc = descBits(atom);
sym.value = _atomToAddress[atom];
_atomToSymbolIndex[atom] = file.localSymbols.size();
file.localSymbols.push_back(sym);
}
} else if (rMode && _archHandler.needsLocalSymbolInRelocatableFile(atom)){
// Create 'Lxxx' labels for anonymous atoms if archHandler says so.
static unsigned tempNum = 1;
char tmpName[16];
sprintf(tmpName, "L%04u", tempNum++);
StringRef tempRef(tmpName);
Symbol sym;
sym.name = tempRef.copy(file.ownedAllocations);
sym.type = N_SECT;
sym.scope = 0;
sym.sect = sect->finalSectionIndex;
sym.desc = 0;
sym.value = _atomToAddress[atom];
_atomToSymbolIndex[atom] = file.localSymbols.size();
file.localSymbols.push_back(sym);
}
}
}
// Sort global symbol alphabetically, then add to symbol table.
std::sort(globals.begin(), globals.end(), AtomSorter());
const uint32_t globalStartIndex = file.localSymbols.size();
for (AtomAndIndex &ai : globals) {
Symbol sym;
sym.name = ai.atom->name();
sym.type = N_SECT;
sym.scope = ai.scope;
sym.sect = ai.index;
sym.desc = descBits(static_cast<const DefinedAtom*>(ai.atom));
sym.value = _atomToAddress[ai.atom];
_atomToSymbolIndex[ai.atom] = globalStartIndex + file.globalSymbols.size();
file.globalSymbols.push_back(sym);
}
// Sort undefined symbol alphabetically, then add to symbol table.
std::vector<AtomAndIndex> undefs;
undefs.reserve(128);
for (const UndefinedAtom *atom : atomFile.undefined()) {
AtomAndIndex ai = { atom, 0, N_EXT };
undefs.push_back(ai);
}
for (const SharedLibraryAtom *atom : atomFile.sharedLibrary()) {
AtomAndIndex ai = { atom, 0, N_EXT };
undefs.push_back(ai);
}
std::sort(undefs.begin(), undefs.end(), AtomSorter());
const uint32_t start = file.globalSymbols.size() + file.localSymbols.size();
for (AtomAndIndex &ai : undefs) {
Symbol sym;
uint16_t desc = 0;
if (!rMode) {
uint8_t ordinal = dylibOrdinal(dyn_cast<SharedLibraryAtom>(ai.atom));
llvm::MachO::SET_LIBRARY_ORDINAL(desc, ordinal);
}
sym.name = ai.atom->name();
sym.type = N_UNDF;
sym.scope = ai.scope;
sym.sect = 0;
sym.desc = desc;
sym.value = 0;
_atomToSymbolIndex[ai.atom] = file.undefinedSymbols.size() + start;
file.undefinedSymbols.push_back(sym);
}
return std::error_code();
}
const Atom *Util::targetOfLazyPointer(const DefinedAtom *lpAtom) {
for (const Reference *ref : *lpAtom) {
if (_archHandler.isLazyPointer(*ref)) {
return ref->target();
}
}
return nullptr;
}
const Atom *Util::targetOfStub(const DefinedAtom *stubAtom) {
for (const Reference *ref : *stubAtom) {
if (const Atom *ta = ref->target()) {
if (const DefinedAtom *lpAtom = dyn_cast<DefinedAtom>(ta)) {
const Atom *target = targetOfLazyPointer(lpAtom);
if (target)
return target;
}
}
}
return nullptr;
}
void Util::addIndirectSymbols(const lld::File &atomFile, NormalizedFile &file) {
for (SectionInfo *si : _sectionInfos) {
Section &normSect = file.sections[si->normalizedSectionIndex];
switch (si->type) {
case llvm::MachO::S_NON_LAZY_SYMBOL_POINTERS:
for (const AtomInfo &info : si->atomsAndOffsets) {
bool foundTarget = false;
for (const Reference *ref : *info.atom) {
const Atom *target = ref->target();
if (target) {
if (isa<const SharedLibraryAtom>(target)) {
uint32_t index = _atomToSymbolIndex[target];
normSect.indirectSymbols.push_back(index);
foundTarget = true;
} else {
normSect.indirectSymbols.push_back(
llvm::MachO::INDIRECT_SYMBOL_LOCAL);
}
}
}
if (!foundTarget) {
normSect.indirectSymbols.push_back(
llvm::MachO::INDIRECT_SYMBOL_ABS);
}
}
break;
case llvm::MachO::S_LAZY_SYMBOL_POINTERS:
for (const AtomInfo &info : si->atomsAndOffsets) {
const Atom *target = targetOfLazyPointer(info.atom);
if (target) {
uint32_t index = _atomToSymbolIndex[target];
normSect.indirectSymbols.push_back(index);
}
}
break;
case llvm::MachO::S_SYMBOL_STUBS:
for (const AtomInfo &info : si->atomsAndOffsets) {
const Atom *target = targetOfStub(info.atom);
if (target) {
uint32_t index = _atomToSymbolIndex[target];
normSect.indirectSymbols.push_back(index);
}
}
break;
default:
break;
}
}
}
void Util::addDependentDylibs(const lld::File &atomFile,NormalizedFile &nFile) {
// Scan all imported symbols and build up list of dylibs they are from.
int ordinal = 1;
for (const SharedLibraryAtom *slAtom : atomFile.sharedLibrary()) {
StringRef loadPath = slAtom->loadName();
DylibPathToInfo::iterator pos = _dylibInfo.find(loadPath);
if (pos == _dylibInfo.end()) {
DylibInfo info;
info.ordinal = ordinal++;
info.hasWeak = slAtom->canBeNullAtRuntime();
info.hasNonWeak = !info.hasWeak;
_dylibInfo[loadPath] = info;
DependentDylib depInfo;
depInfo.path = loadPath;
depInfo.kind = llvm::MachO::LC_LOAD_DYLIB;
nFile.dependentDylibs.push_back(depInfo);
} else {
if ( slAtom->canBeNullAtRuntime() )
pos->second.hasWeak = true;
else
pos->second.hasNonWeak = true;
}
}
// Automatically weak link dylib in which all symbols are weak (canBeNull).
for (DependentDylib &dep : nFile.dependentDylibs) {
DylibInfo &info = _dylibInfo[dep.path];
if (info.hasWeak && !info.hasNonWeak)
dep.kind = llvm::MachO::LC_LOAD_WEAK_DYLIB;
}
}
int Util::dylibOrdinal(const SharedLibraryAtom *sa) {
return _dylibInfo[sa->loadName()].ordinal;
}
void Util::segIndexForSection(const SectionInfo *sect, uint8_t &segmentIndex,
uint64_t &segmentStartAddr) {
segmentIndex = 0;
for (const SegmentInfo *seg : _segmentInfos) {
if ((seg->address <= sect->address)
&& (seg->address+seg->size >= sect->address+sect->size)) {
segmentStartAddr = seg->address;
return;
}
++segmentIndex;
}
llvm_unreachable("section not in any segment");
}
uint32_t Util::sectionIndexForAtom(const Atom *atom) {
uint64_t address = _atomToAddress[atom];
uint32_t index = 1;
for (const SectionInfo *si : _sectionInfos) {
if ((si->address <= address) && (address < si->address+si->size))
return index;
++index;
}
llvm_unreachable("atom not in any section");
}
void Util::addSectionRelocs(const lld::File &, NormalizedFile &file) {
if (_context.outputMachOType() != llvm::MachO::MH_OBJECT)
return;
// Utility function for ArchHandler to find symbol index for an atom.
auto symIndexForAtom = [&] (const Atom &atom) -> uint32_t {
auto pos = _atomToSymbolIndex.find(&atom);
assert(pos != _atomToSymbolIndex.end());
return pos->second;
};
// Utility function for ArchHandler to find section index for an atom.
auto sectIndexForAtom = [&] (const Atom &atom) -> uint32_t {
return sectionIndexForAtom(&atom);
};
// Utility function for ArchHandler to find address of atom in output file.
auto addressForAtom = [&] (const Atom &atom) -> uint64_t {
auto pos = _atomToAddress.find(&atom);
assert(pos != _atomToAddress.end());
return pos->second;
};
for (SectionInfo *si : _sectionInfos) {
Section &normSect = file.sections[si->normalizedSectionIndex];
for (const AtomInfo &info : si->atomsAndOffsets) {
const DefinedAtom *atom = info.atom;
for (const Reference *ref : *atom) {
_archHandler.appendSectionRelocations(*atom, info.offsetInSection, *ref,
symIndexForAtom,
sectIndexForAtom,
addressForAtom,
normSect.relocations);
}
}
}
}
void Util::buildDataInCodeArray(const lld::File &, NormalizedFile &file) {
for (SectionInfo *si : _sectionInfos) {
for (const AtomInfo &info : si->atomsAndOffsets) {
// Atoms that contain data-in-code have "transition" references
// which mark a point where the embedded data starts of ends.
// This needs to be converted to the mach-o format which is an array
// of data-in-code ranges.
uint32_t startOffset = 0;
DataRegionType mode = DataRegionType(0);
for (const Reference *ref : *info.atom) {
if (ref->kindNamespace() != Reference::KindNamespace::mach_o)
continue;
if (_archHandler.isDataInCodeTransition(ref->kindValue())) {
DataRegionType nextMode = (DataRegionType)ref->addend();
if (mode != nextMode) {
if (mode != 0) {
// Found end data range, so make range entry.
DataInCode entry;
entry.offset = si->address + info.offsetInSection + startOffset;
entry.length = ref->offsetInAtom() - startOffset;
entry.kind = mode;
file.dataInCode.push_back(entry);
}
}
mode = nextMode;
startOffset = ref->offsetInAtom();
}
}
if (mode != 0) {
// Function ends with data (no end transition).
DataInCode entry;
entry.offset = si->address + info.offsetInSection + startOffset;
entry.length = info.atom->size() - startOffset;
entry.kind = mode;
file.dataInCode.push_back(entry);
}
}
}
}
void Util::addRebaseAndBindingInfo(const lld::File &atomFile,
NormalizedFile &nFile) {
if (_context.outputMachOType() == llvm::MachO::MH_OBJECT)
return;
uint8_t segmentIndex;
uint64_t segmentStartAddr;
for (SectionInfo *sect : _sectionInfos) {
segIndexForSection(sect, segmentIndex, segmentStartAddr);
for (const AtomInfo &info : sect->atomsAndOffsets) {
const DefinedAtom *atom = info.atom;
for (const Reference *ref : *atom) {
uint64_t segmentOffset = _atomToAddress[atom] + ref->offsetInAtom()
- segmentStartAddr;
const Atom* targ = ref->target();
if (_archHandler.isPointer(*ref)) {
// A pointer to a DefinedAtom requires rebasing.
if (dyn_cast<DefinedAtom>(targ)) {
RebaseLocation rebase;
rebase.segIndex = segmentIndex;
rebase.segOffset = segmentOffset;
rebase.kind = llvm::MachO::REBASE_TYPE_POINTER;
nFile.rebasingInfo.push_back(rebase);
}
// A pointer to an SharedLibraryAtom requires binding.
if (const SharedLibraryAtom *sa = dyn_cast<SharedLibraryAtom>(targ)) {
BindLocation bind;
bind.segIndex = segmentIndex;
bind.segOffset = segmentOffset;
bind.kind = llvm::MachO::BIND_TYPE_POINTER;
bind.canBeNull = sa->canBeNullAtRuntime();
bind.ordinal = dylibOrdinal(sa);
bind.symbolName = targ->name();
bind.addend = ref->addend();
nFile.bindingInfo.push_back(bind);
}
}
if (_archHandler.isLazyPointer(*ref)) {
BindLocation bind;
bind.segIndex = segmentIndex;
bind.segOffset = segmentOffset;
bind.kind = llvm::MachO::BIND_TYPE_POINTER;
bind.canBeNull = false; //sa->canBeNullAtRuntime();
bind.ordinal = 1; // FIXME
bind.symbolName = targ->name();
bind.addend = ref->addend();
nFile.lazyBindingInfo.push_back(bind);
}
}
}
}
}
void Util::addExportInfo(const lld::File &atomFile, NormalizedFile &nFile) {
if (_context.outputMachOType() == llvm::MachO::MH_OBJECT)
return;
for (SectionInfo *sect : _sectionInfos) {
for (const AtomInfo &info : sect->atomsAndOffsets) {
const DefinedAtom *atom = info.atom;
if (atom->scope() != Atom::scopeGlobal)
continue;
if (_context.exportRestrictMode()) {
if (!_context.exportSymbolNamed(atom->name()))
continue;
}
Export exprt;
exprt.name = atom->name();
exprt.offset = _atomToAddress[atom]; // FIXME: subtract base address
exprt.kind = EXPORT_SYMBOL_FLAGS_KIND_REGULAR;
if (atom->merge() == DefinedAtom::mergeAsWeak)
exprt.flags = EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION;
else
exprt.flags = 0;
exprt.otherOffset = 0;
exprt.otherName = StringRef();
nFile.exportInfo.push_back(exprt);
}
}
}
uint32_t Util::fileFlags() {
// FIXME: these need to determined at runtime.
if (_context.outputMachOType() == MH_OBJECT) {
return MH_SUBSECTIONS_VIA_SYMBOLS;
} else {
return MH_DYLDLINK | MH_NOUNDEFS | MH_TWOLEVEL;
}
}
} // end anonymous namespace
namespace lld {
namespace mach_o {
namespace normalized {
/// Convert a set of Atoms into a normalized mach-o file.
ErrorOr<std::unique_ptr<NormalizedFile>>
normalizedFromAtoms(const lld::File &atomFile,
const MachOLinkingContext &context) {
// The util object buffers info until the normalized file can be made.
Util util(context);
util.assignAtomsToSections(atomFile);
util.organizeSections();
std::unique_ptr<NormalizedFile> f(new NormalizedFile());
NormalizedFile &normFile = *f.get();
normFile.arch = context.arch();
normFile.fileType = context.outputMachOType();
normFile.flags = util.fileFlags();
normFile.installName = context.installName();
util.addDependentDylibs(atomFile, normFile);
util.copySegmentInfo(normFile);
util.copySectionInfo(normFile);
util.assignAddressesToSections(normFile);
util.buildAtomToAddressMap();
util.updateSectionInfo(normFile);
util.copySectionContent(normFile);
if (auto ec = util.addSymbols(atomFile, normFile)) {
return ec;
}
util.addIndirectSymbols(atomFile, normFile);
util.addRebaseAndBindingInfo(atomFile, normFile);
util.addExportInfo(atomFile, normFile);
util.addSectionRelocs(atomFile, normFile);
util.buildDataInCodeArray(atomFile, normFile);
util.copyEntryPointAddress(normFile);
return std::move(f);
}
} // namespace normalized
} // namespace mach_o
} // namespace lld