llvm-project/lld/MachO/Writer.cpp

995 lines
33 KiB
C++

//===- Writer.cpp ---------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "Writer.h"
#include "Config.h"
#include "InputFiles.h"
#include "InputSection.h"
#include "MapFile.h"
#include "MergedOutputSection.h"
#include "OutputSection.h"
#include "OutputSegment.h"
#include "SymbolTable.h"
#include "Symbols.h"
#include "SyntheticSections.h"
#include "Target.h"
#include "UnwindInfoSection.h"
#include "lld/Common/Arrays.h"
#include "lld/Common/ErrorHandler.h"
#include "lld/Common/Memory.h"
#include "llvm/BinaryFormat/MachO.h"
#include "llvm/Config/llvm-config.h"
#include "llvm/Support/LEB128.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/Parallel.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/TimeProfiler.h"
#include "llvm/Support/xxhash.h"
#include <algorithm>
using namespace llvm;
using namespace llvm::MachO;
using namespace llvm::sys;
using namespace lld;
using namespace lld::macho;
namespace {
class LCUuid;
class Writer {
public:
Writer() : buffer(errorHandler().outputBuffer) {}
void scanRelocations();
void scanSymbols();
void createOutputSections();
void createLoadCommands();
void finalizeAddressses();
void finalizeLinkEditSegment();
void assignAddresses(OutputSegment *);
void openFile();
void writeSections();
void writeUuid();
void writeCodeSignature();
void writeOutputFile();
void run();
std::unique_ptr<FileOutputBuffer> &buffer;
uint64_t addr = 0;
uint64_t fileOff = 0;
MachHeaderSection *header = nullptr;
StringTableSection *stringTableSection = nullptr;
SymtabSection *symtabSection = nullptr;
IndirectSymtabSection *indirectSymtabSection = nullptr;
CodeSignatureSection *codeSignatureSection = nullptr;
UnwindInfoSection *unwindInfoSection = nullptr;
FunctionStartsSection *functionStartsSection = nullptr;
LCUuid *uuidCommand = nullptr;
OutputSegment *linkEditSegment = nullptr;
};
// LC_DYLD_INFO_ONLY stores the offsets of symbol import/export information.
class LCDyldInfo : public LoadCommand {
public:
LCDyldInfo(RebaseSection *rebaseSection, BindingSection *bindingSection,
WeakBindingSection *weakBindingSection,
LazyBindingSection *lazyBindingSection,
ExportSection *exportSection)
: rebaseSection(rebaseSection), bindingSection(bindingSection),
weakBindingSection(weakBindingSection),
lazyBindingSection(lazyBindingSection), exportSection(exportSection) {}
uint32_t getSize() const override { return sizeof(dyld_info_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<dyld_info_command *>(buf);
c->cmd = LC_DYLD_INFO_ONLY;
c->cmdsize = getSize();
if (rebaseSection->isNeeded()) {
c->rebase_off = rebaseSection->fileOff;
c->rebase_size = rebaseSection->getFileSize();
}
if (bindingSection->isNeeded()) {
c->bind_off = bindingSection->fileOff;
c->bind_size = bindingSection->getFileSize();
}
if (weakBindingSection->isNeeded()) {
c->weak_bind_off = weakBindingSection->fileOff;
c->weak_bind_size = weakBindingSection->getFileSize();
}
if (lazyBindingSection->isNeeded()) {
c->lazy_bind_off = lazyBindingSection->fileOff;
c->lazy_bind_size = lazyBindingSection->getFileSize();
}
if (exportSection->isNeeded()) {
c->export_off = exportSection->fileOff;
c->export_size = exportSection->getFileSize();
}
}
RebaseSection *rebaseSection;
BindingSection *bindingSection;
WeakBindingSection *weakBindingSection;
LazyBindingSection *lazyBindingSection;
ExportSection *exportSection;
};
class LCFunctionStarts : public LoadCommand {
public:
explicit LCFunctionStarts(FunctionStartsSection *functionStartsSection)
: functionStartsSection(functionStartsSection) {}
uint32_t getSize() const override { return sizeof(linkedit_data_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<linkedit_data_command *>(buf);
c->cmd = LC_FUNCTION_STARTS;
c->cmdsize = getSize();
c->dataoff = functionStartsSection->fileOff;
c->datasize = functionStartsSection->getFileSize();
}
private:
FunctionStartsSection *functionStartsSection;
};
class LCDysymtab : public LoadCommand {
public:
LCDysymtab(SymtabSection *symtabSection,
IndirectSymtabSection *indirectSymtabSection)
: symtabSection(symtabSection),
indirectSymtabSection(indirectSymtabSection) {}
uint32_t getSize() const override { return sizeof(dysymtab_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<dysymtab_command *>(buf);
c->cmd = LC_DYSYMTAB;
c->cmdsize = getSize();
c->ilocalsym = 0;
c->iextdefsym = c->nlocalsym = symtabSection->getNumLocalSymbols();
c->nextdefsym = symtabSection->getNumExternalSymbols();
c->iundefsym = c->iextdefsym + c->nextdefsym;
c->nundefsym = symtabSection->getNumUndefinedSymbols();
c->indirectsymoff = indirectSymtabSection->fileOff;
c->nindirectsyms = indirectSymtabSection->getNumSymbols();
}
SymtabSection *symtabSection;
IndirectSymtabSection *indirectSymtabSection;
};
class LCSegment : public LoadCommand {
public:
LCSegment(StringRef name, OutputSegment *seg) : name(name), seg(seg) {}
uint32_t getSize() const override {
return sizeof(segment_command_64) +
seg->numNonHiddenSections() * sizeof(section_64);
}
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<segment_command_64 *>(buf);
buf += sizeof(segment_command_64);
c->cmd = LC_SEGMENT_64;
c->cmdsize = getSize();
memcpy(c->segname, name.data(), name.size());
c->fileoff = seg->fileOff;
c->maxprot = seg->maxProt;
c->initprot = seg->initProt;
if (seg->getSections().empty())
return;
c->vmaddr = seg->firstSection()->addr;
c->vmsize =
seg->lastSection()->addr + seg->lastSection()->getSize() - c->vmaddr;
c->nsects = seg->numNonHiddenSections();
for (const OutputSection *osec : seg->getSections()) {
if (!isZeroFill(osec->flags)) {
assert(osec->fileOff >= seg->fileOff);
c->filesize = std::max(
c->filesize, osec->fileOff + osec->getFileSize() - seg->fileOff);
}
if (osec->isHidden())
continue;
auto *sectHdr = reinterpret_cast<section_64 *>(buf);
buf += sizeof(section_64);
memcpy(sectHdr->sectname, osec->name.data(), osec->name.size());
memcpy(sectHdr->segname, name.data(), name.size());
sectHdr->addr = osec->addr;
sectHdr->offset = osec->fileOff;
sectHdr->align = Log2_32(osec->align);
sectHdr->flags = osec->flags;
sectHdr->size = osec->getSize();
sectHdr->reserved1 = osec->reserved1;
sectHdr->reserved2 = osec->reserved2;
}
}
private:
StringRef name;
OutputSegment *seg;
};
class LCMain : public LoadCommand {
uint32_t getSize() const override { return sizeof(entry_point_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<entry_point_command *>(buf);
c->cmd = LC_MAIN;
c->cmdsize = getSize();
if (config->entry->isInStubs())
c->entryoff =
in.stubs->fileOff + config->entry->stubsIndex * target->stubSize;
else
c->entryoff = config->entry->getFileOffset();
c->stacksize = 0;
}
};
class LCSymtab : public LoadCommand {
public:
LCSymtab(SymtabSection *symtabSection, StringTableSection *stringTableSection)
: symtabSection(symtabSection), stringTableSection(stringTableSection) {}
uint32_t getSize() const override { return sizeof(symtab_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<symtab_command *>(buf);
c->cmd = LC_SYMTAB;
c->cmdsize = getSize();
c->symoff = symtabSection->fileOff;
c->nsyms = symtabSection->getNumSymbols();
c->stroff = stringTableSection->fileOff;
c->strsize = stringTableSection->getFileSize();
}
SymtabSection *symtabSection = nullptr;
StringTableSection *stringTableSection = nullptr;
};
// There are several dylib load commands that share the same structure:
// * LC_LOAD_DYLIB
// * LC_ID_DYLIB
// * LC_REEXPORT_DYLIB
class LCDylib : public LoadCommand {
public:
LCDylib(LoadCommandType type, StringRef path,
uint32_t compatibilityVersion = 0, uint32_t currentVersion = 0)
: type(type), path(path), compatibilityVersion(compatibilityVersion),
currentVersion(currentVersion) {
instanceCount++;
}
uint32_t getSize() const override {
return alignTo(sizeof(dylib_command) + path.size() + 1, 8);
}
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<dylib_command *>(buf);
buf += sizeof(dylib_command);
c->cmd = type;
c->cmdsize = getSize();
c->dylib.name = sizeof(dylib_command);
c->dylib.timestamp = 0;
c->dylib.compatibility_version = compatibilityVersion;
c->dylib.current_version = currentVersion;
memcpy(buf, path.data(), path.size());
buf[path.size()] = '\0';
}
static uint32_t getInstanceCount() { return instanceCount; }
private:
LoadCommandType type;
StringRef path;
uint32_t compatibilityVersion;
uint32_t currentVersion;
static uint32_t instanceCount;
};
uint32_t LCDylib::instanceCount = 0;
class LCLoadDylinker : public LoadCommand {
public:
uint32_t getSize() const override {
return alignTo(sizeof(dylinker_command) + path.size() + 1, 8);
}
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<dylinker_command *>(buf);
buf += sizeof(dylinker_command);
c->cmd = LC_LOAD_DYLINKER;
c->cmdsize = getSize();
c->name = sizeof(dylinker_command);
memcpy(buf, path.data(), path.size());
buf[path.size()] = '\0';
}
private:
// Recent versions of Darwin won't run any binary that has dyld at a
// different location.
const StringRef path = "/usr/lib/dyld";
};
class LCRPath : public LoadCommand {
public:
LCRPath(StringRef path) : path(path) {}
uint32_t getSize() const override {
return alignTo(sizeof(rpath_command) + path.size() + 1, WordSize);
}
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<rpath_command *>(buf);
buf += sizeof(rpath_command);
c->cmd = LC_RPATH;
c->cmdsize = getSize();
c->path = sizeof(rpath_command);
memcpy(buf, path.data(), path.size());
buf[path.size()] = '\0';
}
private:
StringRef path;
};
class LCBuildVersion : public LoadCommand {
public:
LCBuildVersion(PlatformKind platform, const PlatformInfo &platformInfo)
: platform(platform), platformInfo(platformInfo) {}
const int ntools = 1;
uint32_t getSize() const override {
return sizeof(build_version_command) + ntools * sizeof(build_tool_version);
}
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<build_version_command *>(buf);
c->cmd = LC_BUILD_VERSION;
c->cmdsize = getSize();
c->platform = static_cast<uint32_t>(platform);
c->minos = ((platformInfo.minimum.getMajor() << 020) |
(platformInfo.minimum.getMinor().getValueOr(0) << 010) |
platformInfo.minimum.getSubminor().getValueOr(0));
c->sdk = ((platformInfo.sdk.getMajor() << 020) |
(platformInfo.sdk.getMinor().getValueOr(0) << 010) |
platformInfo.sdk.getSubminor().getValueOr(0));
c->ntools = ntools;
auto *t = reinterpret_cast<build_tool_version *>(&c[1]);
t->tool = TOOL_LD;
t->version = (LLVM_VERSION_MAJOR << 020) | (LLVM_VERSION_MINOR << 010) |
LLVM_VERSION_PATCH;
}
PlatformKind platform;
const PlatformInfo &platformInfo;
};
// Stores a unique identifier for the output file based on an MD5 hash of its
// contents. In order to hash the contents, we must first write them, but
// LC_UUID itself must be part of the written contents in order for all the
// offsets to be calculated correctly. We resolve this circular paradox by
// first writing an LC_UUID with an all-zero UUID, then updating the UUID with
// its real value later.
class LCUuid : public LoadCommand {
public:
uint32_t getSize() const override { return sizeof(uuid_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<uuid_command *>(buf);
c->cmd = LC_UUID;
c->cmdsize = getSize();
uuidBuf = c->uuid;
}
void writeUuid(uint64_t digest) const {
// xxhash only gives us 8 bytes, so put some fixed data in the other half.
static_assert(sizeof(uuid_command::uuid) == 16, "unexpected uuid size");
memcpy(uuidBuf, "LLD\xa1UU1D", 8);
memcpy(uuidBuf + 8, &digest, 8);
// RFC 4122 conformance. We need to fix 4 bits in byte 6 and 2 bits in
// byte 8. Byte 6 is already fine due to the fixed data we put in. We don't
// want to lose bits of the digest in byte 8, so swap that with a byte of
// fixed data that happens to have the right bits set.
std::swap(uuidBuf[3], uuidBuf[8]);
// Claim that this is an MD5-based hash. It isn't, but this signals that
// this is not a time-based and not a random hash. MD5 seems like the least
// bad lie we can put here.
assert((uuidBuf[6] & 0xf0) == 0x30 && "See RFC 4122 Sections 4.2.2, 4.1.3");
assert((uuidBuf[8] & 0xc0) == 0x80 && "See RFC 4122 Section 4.2.2");
}
mutable uint8_t *uuidBuf;
};
class LCCodeSignature : public LoadCommand {
public:
LCCodeSignature(CodeSignatureSection *section) : section(section) {}
uint32_t getSize() const override { return sizeof(linkedit_data_command); }
void writeTo(uint8_t *buf) const override {
auto *c = reinterpret_cast<linkedit_data_command *>(buf);
c->cmd = LC_CODE_SIGNATURE;
c->cmdsize = getSize();
c->dataoff = static_cast<uint32_t>(section->fileOff);
c->datasize = section->getSize();
}
CodeSignatureSection *section;
};
} // namespace
// Adds stubs and bindings where necessary (e.g. if the symbol is a
// DylibSymbol.)
static void prepareBranchTarget(Symbol *sym) {
if (auto *dysym = dyn_cast<DylibSymbol>(sym)) {
if (in.stubs->addEntry(dysym)) {
if (sym->isWeakDef()) {
in.binding->addEntry(dysym, in.lazyPointers->isec,
sym->stubsIndex * WordSize);
in.weakBinding->addEntry(sym, in.lazyPointers->isec,
sym->stubsIndex * WordSize);
} else {
in.lazyBinding->addEntry(dysym);
}
}
} else if (auto *defined = dyn_cast<Defined>(sym)) {
if (defined->isExternalWeakDef()) {
if (in.stubs->addEntry(sym)) {
in.rebase->addEntry(in.lazyPointers->isec, sym->stubsIndex * WordSize);
in.weakBinding->addEntry(sym, in.lazyPointers->isec,
sym->stubsIndex * WordSize);
}
}
}
}
// Can a symbol's address can only be resolved at runtime?
static bool needsBinding(const Symbol *sym) {
if (isa<DylibSymbol>(sym))
return true;
if (const auto *defined = dyn_cast<Defined>(sym))
return defined->isExternalWeakDef();
return false;
}
static void prepareSymbolRelocation(Symbol *sym, const InputSection *isec,
const Reloc &r) {
const RelocAttrs &relocAttrs = target->getRelocAttrs(r.type);
if (relocAttrs.hasAttr(RelocAttrBits::BRANCH)) {
prepareBranchTarget(sym);
} else if (relocAttrs.hasAttr(RelocAttrBits::GOT)) {
if (relocAttrs.hasAttr(RelocAttrBits::POINTER) || needsBinding(sym))
in.got->addEntry(sym);
} else if (relocAttrs.hasAttr(RelocAttrBits::TLV)) {
if (needsBinding(sym))
in.tlvPointers->addEntry(sym);
} else if (relocAttrs.hasAttr(RelocAttrBits::UNSIGNED)) {
// References from thread-local variable sections are treated as offsets
// relative to the start of the referent section, and therefore have no
// need of rebase opcodes.
if (!(isThreadLocalVariables(isec->flags) && isa<Defined>(sym)))
addNonLazyBindingEntries(sym, isec, r.offset, r.addend);
}
}
void Writer::scanRelocations() {
TimeTraceScope timeScope("Scan relocations");
for (InputSection *isec : inputSections) {
if (isec->segname == segment_names::ld) {
prepareCompactUnwind(isec);
continue;
}
for (auto it = isec->relocs.begin(); it != isec->relocs.end(); ++it) {
Reloc &r = *it;
if (target->hasAttr(r.type, RelocAttrBits::SUBTRAHEND)) {
// Skip over the following UNSIGNED relocation -- it's just there as the
// minuend, and doesn't have the usual UNSIGNED semantics. We don't want
// to emit rebase opcodes for it.
it = std::next(it);
assert(isa<Defined>(it->referent.dyn_cast<Symbol *>()));
continue;
}
if (auto *sym = r.referent.dyn_cast<Symbol *>()) {
if (auto *undefined = dyn_cast<Undefined>(sym))
treatUndefinedSymbol(*undefined);
// treatUndefinedSymbol() can replace sym with a DylibSymbol; re-check.
if (!isa<Undefined>(sym) && validateSymbolRelocation(sym, isec, r))
prepareSymbolRelocation(sym, isec, r);
} else {
assert(r.referent.is<InputSection *>());
if (!r.pcrel)
in.rebase->addEntry(isec, r.offset);
}
}
}
}
void Writer::scanSymbols() {
TimeTraceScope timeScope("Scan symbols");
for (const Symbol *sym : symtab->getSymbols()) {
if (const auto *defined = dyn_cast<Defined>(sym)) {
if (defined->overridesWeakDef)
in.weakBinding->addNonWeakDefinition(defined);
} else if (const auto *dysym = dyn_cast<DylibSymbol>(sym)) {
if (dysym->isDynamicLookup())
continue;
dysym->getFile()->refState =
std::max(dysym->getFile()->refState, dysym->refState);
}
}
}
void Writer::createLoadCommands() {
uint8_t segIndex = 0;
for (OutputSegment *seg : outputSegments) {
in.header->addLoadCommand(make<LCSegment>(seg->name, seg));
seg->index = segIndex++;
}
in.header->addLoadCommand(make<LCDyldInfo>(
in.rebase, in.binding, in.weakBinding, in.lazyBinding, in.exports));
in.header->addLoadCommand(make<LCSymtab>(symtabSection, stringTableSection));
in.header->addLoadCommand(
make<LCDysymtab>(symtabSection, indirectSymtabSection));
if (functionStartsSection)
in.header->addLoadCommand(make<LCFunctionStarts>(functionStartsSection));
for (StringRef path : config->runtimePaths)
in.header->addLoadCommand(make<LCRPath>(path));
switch (config->outputType) {
case MH_EXECUTE:
in.header->addLoadCommand(make<LCLoadDylinker>());
in.header->addLoadCommand(make<LCMain>());
break;
case MH_DYLIB:
in.header->addLoadCommand(make<LCDylib>(LC_ID_DYLIB, config->installName,
config->dylibCompatibilityVersion,
config->dylibCurrentVersion));
break;
case MH_BUNDLE:
break;
default:
llvm_unreachable("unhandled output file type");
}
uuidCommand = make<LCUuid>();
in.header->addLoadCommand(uuidCommand);
in.header->addLoadCommand(
make<LCBuildVersion>(config->target.Platform, config->platformInfo));
int64_t dylibOrdinal = 1;
for (InputFile *file : inputFiles) {
if (auto *dylibFile = dyn_cast<DylibFile>(file)) {
if (dylibFile->isBundleLoader) {
dylibFile->ordinal = BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE;
// Shortcut since bundle-loader does not re-export the symbols.
dylibFile->reexport = false;
continue;
}
dylibFile->ordinal = dylibOrdinal++;
LoadCommandType lcType =
dylibFile->forceWeakImport || dylibFile->refState == RefState::Weak
? LC_LOAD_WEAK_DYLIB
: LC_LOAD_DYLIB;
in.header->addLoadCommand(make<LCDylib>(lcType, dylibFile->dylibName,
dylibFile->compatibilityVersion,
dylibFile->currentVersion));
if (dylibFile->reexport)
in.header->addLoadCommand(
make<LCDylib>(LC_REEXPORT_DYLIB, dylibFile->dylibName));
}
}
if (codeSignatureSection)
in.header->addLoadCommand(make<LCCodeSignature>(codeSignatureSection));
const uint32_t MACOS_MAXPATHLEN = 1024;
config->headerPad = std::max(
config->headerPad, (config->headerPadMaxInstallNames
? LCDylib::getInstanceCount() * MACOS_MAXPATHLEN
: 0));
}
static size_t getSymbolPriority(const SymbolPriorityEntry &entry,
const InputFile *f) {
// We don't use toString(InputFile *) here because it returns the full path
// for object files, and we only want the basename.
StringRef filename;
if (f->archiveName.empty())
filename = path::filename(f->getName());
else
filename = saver.save(path::filename(f->archiveName) + "(" +
path::filename(f->getName()) + ")");
return std::max(entry.objectFiles.lookup(filename), entry.anyObjectFile);
}
// Each section gets assigned the priority of the highest-priority symbol it
// contains.
static DenseMap<const InputSection *, size_t> buildInputSectionPriorities() {
DenseMap<const InputSection *, size_t> sectionPriorities;
if (config->priorities.empty())
return sectionPriorities;
auto addSym = [&](Defined &sym) {
auto it = config->priorities.find(sym.getName());
if (it == config->priorities.end())
return;
SymbolPriorityEntry &entry = it->second;
size_t &priority = sectionPriorities[sym.isec];
priority = std::max(priority, getSymbolPriority(entry, sym.isec->file));
};
// TODO: Make sure this handles weak symbols correctly.
for (const InputFile *file : inputFiles) {
if (isa<ObjFile>(file))
for (Symbol *sym : file->symbols)
if (auto *d = dyn_cast<Defined>(sym))
addSym(*d);
}
return sectionPriorities;
}
static int segmentOrder(OutputSegment *seg) {
return StringSwitch<int>(seg->name)
.Case(segment_names::pageZero, -4)
.Case(segment_names::text, -3)
.Case(segment_names::dataConst, -2)
.Case(segment_names::data, -1)
// Make sure __LINKEDIT is the last segment (i.e. all its hidden
// sections must be ordered after other sections).
.Case(segment_names::linkEdit, std::numeric_limits<int>::max())
.Default(0);
}
static int sectionOrder(OutputSection *osec) {
StringRef segname = osec->parent->name;
// Sections are uniquely identified by their segment + section name.
if (segname == segment_names::text) {
return StringSwitch<int>(osec->name)
.Case(section_names::header, -4)
.Case(section_names::text, -3)
.Case(section_names::stubs, -2)
.Case(section_names::stubHelper, -1)
.Case(section_names::unwindInfo, std::numeric_limits<int>::max() - 1)
.Case(section_names::ehFrame, std::numeric_limits<int>::max())
.Default(0);
} else if (segname == segment_names::data) {
// For each thread spawned, dyld will initialize its TLVs by copying the
// address range from the start of the first thread-local data section to
// the end of the last one. We therefore arrange these sections contiguously
// to minimize the amount of memory used. Additionally, since zerofill
// sections must be at the end of their segments, and since TLV data
// sections can be zerofills, we end up putting all TLV data sections at the
// end of the segment.
switch (sectionType(osec->flags)) {
case S_THREAD_LOCAL_REGULAR:
return std::numeric_limits<int>::max() - 2;
case S_THREAD_LOCAL_ZEROFILL:
return std::numeric_limits<int>::max() - 1;
case S_ZEROFILL:
return std::numeric_limits<int>::max();
default:
return StringSwitch<int>(osec->name)
.Case(section_names::laSymbolPtr, -2)
.Case(section_names::data, -1)
.Default(0);
}
} else if (segname == segment_names::linkEdit) {
return StringSwitch<int>(osec->name)
.Case(section_names::rebase, -9)
.Case(section_names::binding, -8)
.Case(section_names::weakBinding, -7)
.Case(section_names::lazyBinding, -6)
.Case(section_names::export_, -5)
.Case(section_names::functionStarts, -4)
.Case(section_names::symbolTable, -3)
.Case(section_names::indirectSymbolTable, -2)
.Case(section_names::stringTable, -1)
.Case(section_names::codeSignature, std::numeric_limits<int>::max())
.Default(0);
}
// ZeroFill sections must always be the at the end of their segments,
// otherwise subsequent sections may get overwritten with zeroes at runtime.
if (sectionType(osec->flags) == S_ZEROFILL)
return std::numeric_limits<int>::max();
return 0;
}
template <typename T, typename F>
static std::function<bool(T, T)> compareByOrder(F ord) {
return [=](T a, T b) { return ord(a) < ord(b); };
}
// Sorting only can happen once all outputs have been collected. Here we sort
// segments, output sections within each segment, and input sections within each
// output segment.
static void sortSegmentsAndSections() {
TimeTraceScope timeScope("Sort segments and sections");
llvm::stable_sort(outputSegments,
compareByOrder<OutputSegment *>(segmentOrder));
DenseMap<const InputSection *, size_t> isecPriorities =
buildInputSectionPriorities();
uint32_t sectionIndex = 0;
for (OutputSegment *seg : outputSegments) {
seg->sortOutputSections(compareByOrder<OutputSection *>(sectionOrder));
for (OutputSection *osec : seg->getSections()) {
// Now that the output sections are sorted, assign the final
// output section indices.
if (!osec->isHidden())
osec->index = ++sectionIndex;
if (!firstTLVDataSection && isThreadLocalData(osec->flags))
firstTLVDataSection = osec;
if (!isecPriorities.empty()) {
if (auto *merged = dyn_cast<MergedOutputSection>(osec)) {
llvm::stable_sort(merged->inputs,
[&](InputSection *a, InputSection *b) {
return isecPriorities[a] > isecPriorities[b];
});
}
}
}
}
}
static NamePair maybeRenameSection(NamePair key) {
auto newNames = config->sectionRenameMap.find(key);
if (newNames != config->sectionRenameMap.end())
return newNames->second;
auto newName = config->segmentRenameMap.find(key.first);
if (newName != config->segmentRenameMap.end())
return std::make_pair(newName->second, key.second);
return key;
}
void Writer::createOutputSections() {
TimeTraceScope timeScope("Create output sections");
// First, create hidden sections
stringTableSection = make<StringTableSection>();
unwindInfoSection = make<UnwindInfoSection>(); // TODO(gkm): only when no -r
symtabSection = make<SymtabSection>(*stringTableSection);
indirectSymtabSection = make<IndirectSymtabSection>();
if (config->adhocCodesign)
codeSignatureSection = make<CodeSignatureSection>();
if (config->emitFunctionStarts)
functionStartsSection = make<FunctionStartsSection>();
switch (config->outputType) {
case MH_EXECUTE:
make<PageZeroSection>();
break;
case MH_DYLIB:
case MH_BUNDLE:
break;
default:
llvm_unreachable("unhandled output file type");
}
// Then merge input sections into output sections.
MapVector<NamePair, MergedOutputSection *> mergedOutputSections;
for (InputSection *isec : inputSections) {
NamePair names = maybeRenameSection({isec->segname, isec->name});
MergedOutputSection *&osec = mergedOutputSections[names];
if (osec == nullptr)
osec = make<MergedOutputSection>(names.second);
osec->mergeInput(isec);
}
for (const auto &it : mergedOutputSections) {
StringRef segname = it.first.first;
MergedOutputSection *osec = it.second;
if (unwindInfoSection && segname == segment_names::ld) {
assert(osec->name == section_names::compactUnwind);
unwindInfoSection->setCompactUnwindSection(osec);
} else {
getOrCreateOutputSegment(segname)->addOutputSection(osec);
}
}
for (SyntheticSection *ssec : syntheticSections) {
auto it = mergedOutputSections.find({ssec->segname, ssec->name});
if (it == mergedOutputSections.end()) {
if (ssec->isNeeded())
getOrCreateOutputSegment(ssec->segname)->addOutputSection(ssec);
} else {
error("section from " + toString(it->second->firstSection()->file) +
" conflicts with synthetic section " + ssec->segname + "," +
ssec->name);
}
}
// dyld requires __LINKEDIT segment to always exist (even if empty).
linkEditSegment = getOrCreateOutputSegment(segment_names::linkEdit);
}
void Writer::finalizeAddressses() {
TimeTraceScope timeScope("Finalize addresses");
// Ensure that segments (and the sections they contain) are allocated
// addresses in ascending order, which dyld requires.
//
// Note that at this point, __LINKEDIT sections are empty, but we need to
// determine addresses of other segments/sections before generating its
// contents.
for (OutputSegment *seg : outputSegments)
if (seg != linkEditSegment)
assignAddresses(seg);
// FIXME(gkm): create branch-extension thunks here, then adjust addresses
}
void Writer::finalizeLinkEditSegment() {
TimeTraceScope timeScope("Finalize __LINKEDIT segment");
// Fill __LINKEDIT contents.
in.rebase->finalizeContents();
in.binding->finalizeContents();
in.weakBinding->finalizeContents();
in.lazyBinding->finalizeContents();
in.exports->finalizeContents();
symtabSection->finalizeContents();
indirectSymtabSection->finalizeContents();
if (functionStartsSection)
functionStartsSection->finalizeContents();
// Now that __LINKEDIT is filled out, do a proper calculation of its
// addresses and offsets.
assignAddresses(linkEditSegment);
}
void Writer::assignAddresses(OutputSegment *seg) {
uint64_t pageSize = target->getPageSize();
addr = alignTo(addr, pageSize);
fileOff = alignTo(fileOff, pageSize);
seg->fileOff = fileOff;
for (OutputSection *osec : seg->getSections()) {
if (!osec->isNeeded())
continue;
addr = alignTo(addr, osec->align);
fileOff = alignTo(fileOff, osec->align);
osec->addr = addr;
osec->fileOff = isZeroFill(osec->flags) ? 0 : fileOff;
osec->finalize();
addr += osec->getSize();
fileOff += osec->getFileSize();
}
seg->fileSize = fileOff - seg->fileOff;
}
void Writer::openFile() {
Expected<std::unique_ptr<FileOutputBuffer>> bufferOrErr =
FileOutputBuffer::create(config->outputFile, fileOff,
FileOutputBuffer::F_executable);
if (!bufferOrErr)
error("failed to open " + config->outputFile + ": " +
llvm::toString(bufferOrErr.takeError()));
else
buffer = std::move(*bufferOrErr);
}
void Writer::writeSections() {
uint8_t *buf = buffer->getBufferStart();
for (const OutputSegment *seg : outputSegments)
for (const OutputSection *osec : seg->getSections())
osec->writeTo(buf + osec->fileOff);
}
// In order to utilize multiple cores, we first split the buffer into chunks,
// compute a hash for each chunk, and then compute a hash value of the hash
// values.
void Writer::writeUuid() {
TimeTraceScope timeScope("Computing UUID");
ArrayRef<uint8_t> data{buffer->getBufferStart(), buffer->getBufferEnd()};
unsigned chunkCount = parallel::strategy.compute_thread_count() * 10;
// Round-up integer division
size_t chunkSize = (data.size() + chunkCount - 1) / chunkCount;
std::vector<ArrayRef<uint8_t>> chunks = split(data, chunkSize);
std::vector<uint64_t> hashes(chunks.size());
parallelForEachN(0, chunks.size(),
[&](size_t i) { hashes[i] = xxHash64(chunks[i]); });
uint64_t digest = xxHash64({reinterpret_cast<uint8_t *>(hashes.data()),
hashes.size() * sizeof(uint64_t)});
uuidCommand->writeUuid(digest);
}
void Writer::writeCodeSignature() {
if (codeSignatureSection)
codeSignatureSection->writeHashes(buffer->getBufferStart());
}
void Writer::writeOutputFile() {
TimeTraceScope timeScope("Write output file");
openFile();
if (errorCount())
return;
writeSections();
writeUuid();
writeCodeSignature();
if (auto e = buffer->commit())
error("failed to write to the output file: " + toString(std::move(e)));
}
void Writer::run() {
prepareBranchTarget(config->entry);
scanRelocations();
if (in.stubHelper->isNeeded())
in.stubHelper->setup();
scanSymbols();
createOutputSections();
// No more sections nor segments are created beyond this point.
sortSegmentsAndSections();
createLoadCommands();
finalizeAddressses();
finalizeLinkEditSegment();
writeMapFile();
writeOutputFile();
}
void macho::writeResult() { Writer().run(); }
void macho::createSyntheticSections() {
in.header = make<MachHeaderSection>();
in.rebase = make<RebaseSection>();
in.binding = make<BindingSection>();
in.weakBinding = make<WeakBindingSection>();
in.lazyBinding = make<LazyBindingSection>();
in.exports = make<ExportSection>();
in.got = make<GotSection>();
in.tlvPointers = make<TlvPointerSection>();
in.lazyPointers = make<LazyPointerSection>();
in.stubs = make<StubsSection>();
in.stubHelper = make<StubHelperSection>();
in.imageLoaderCache = make<ImageLoaderCacheSection>();
}
OutputSection *macho::firstTLVDataSection = nullptr;