llvm-project/lld/ELF/InputFiles.cpp

1646 lines
59 KiB
C++

//===- InputFiles.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 "InputFiles.h"
#include "Driver.h"
#include "InputSection.h"
#include "LinkerScript.h"
#include "SymbolTable.h"
#include "Symbols.h"
#include "SyntheticSections.h"
#include "lld/Common/ErrorHandler.h"
#include "lld/Common/Memory.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/CodeGen/Analysis.h"
#include "llvm/DebugInfo/DWARF/DWARFContext.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/IR/Module.h"
#include "llvm/LTO/LTO.h"
#include "llvm/MC/StringTableBuilder.h"
#include "llvm/Object/ELFObjectFile.h"
#include "llvm/Support/ARMAttributeParser.h"
#include "llvm/Support/ARMBuildAttributes.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/TarWriter.h"
#include "llvm/Support/raw_ostream.h"
using namespace llvm;
using namespace llvm::ELF;
using namespace llvm::object;
using namespace llvm::sys;
using namespace llvm::sys::fs;
using namespace llvm::support::endian;
using namespace lld;
using namespace lld::elf;
bool InputFile::isInGroup;
uint32_t InputFile::nextGroupId;
std::vector<BinaryFile *> elf::binaryFiles;
std::vector<BitcodeFile *> elf::bitcodeFiles;
std::vector<LazyObjFile *> elf::lazyObjFiles;
std::vector<InputFile *> elf::objectFiles;
std::vector<SharedFile *> elf::sharedFiles;
std::unique_ptr<TarWriter> elf::tar;
static ELFKind getELFKind(MemoryBufferRef mb, StringRef archiveName) {
unsigned char size;
unsigned char endian;
std::tie(size, endian) = getElfArchType(mb.getBuffer());
auto report = [&](StringRef msg) {
StringRef filename = mb.getBufferIdentifier();
if (archiveName.empty())
fatal(filename + ": " + msg);
else
fatal(archiveName + "(" + filename + "): " + msg);
};
if (!mb.getBuffer().startswith(ElfMagic))
report("not an ELF file");
if (endian != ELFDATA2LSB && endian != ELFDATA2MSB)
report("corrupted ELF file: invalid data encoding");
if (size != ELFCLASS32 && size != ELFCLASS64)
report("corrupted ELF file: invalid file class");
size_t bufSize = mb.getBuffer().size();
if ((size == ELFCLASS32 && bufSize < sizeof(Elf32_Ehdr)) ||
(size == ELFCLASS64 && bufSize < sizeof(Elf64_Ehdr)))
report("corrupted ELF file: file is too short");
if (size == ELFCLASS32)
return (endian == ELFDATA2LSB) ? ELF32LEKind : ELF32BEKind;
return (endian == ELFDATA2LSB) ? ELF64LEKind : ELF64BEKind;
}
InputFile::InputFile(Kind k, MemoryBufferRef m)
: mb(m), groupId(nextGroupId), fileKind(k) {
// All files within the same --{start,end}-group get the same group ID.
// Otherwise, a new file will get a new group ID.
if (!isInGroup)
++nextGroupId;
}
Optional<MemoryBufferRef> elf::readFile(StringRef path) {
// The --chroot option changes our virtual root directory.
// This is useful when you are dealing with files created by --reproduce.
if (!config->chroot.empty() && path.startswith("/"))
path = saver.save(config->chroot + path);
log(path);
auto mbOrErr = MemoryBuffer::getFile(path, -1, false);
if (auto ec = mbOrErr.getError()) {
error("cannot open " + path + ": " + ec.message());
return None;
}
std::unique_ptr<MemoryBuffer> &mb = *mbOrErr;
MemoryBufferRef mbref = mb->getMemBufferRef();
make<std::unique_ptr<MemoryBuffer>>(std::move(mb)); // take MB ownership
if (tar)
tar->append(relativeToRoot(path), mbref.getBuffer());
return mbref;
}
// All input object files must be for the same architecture
// (e.g. it does not make sense to link x86 object files with
// MIPS object files.) This function checks for that error.
static bool isCompatible(InputFile *file) {
if (!file->isElf() && !isa<BitcodeFile>(file))
return true;
if (file->ekind == config->ekind && file->emachine == config->emachine) {
if (config->emachine != EM_MIPS)
return true;
if (isMipsN32Abi(file) == config->mipsN32Abi)
return true;
}
if (!config->emulation.empty()) {
error(toString(file) + " is incompatible with " + config->emulation);
} else {
InputFile *existing;
if (!objectFiles.empty())
existing = objectFiles[0];
else if (!sharedFiles.empty())
existing = sharedFiles[0];
else
existing = bitcodeFiles[0];
error(toString(file) + " is incompatible with " + toString(existing));
}
return false;
}
template <class ELFT> static void doParseFile(InputFile *file) {
if (!isCompatible(file))
return;
// Binary file
if (auto *f = dyn_cast<BinaryFile>(file)) {
binaryFiles.push_back(f);
f->parse();
return;
}
// .a file
if (auto *f = dyn_cast<ArchiveFile>(file)) {
f->parse();
return;
}
// Lazy object file
if (auto *f = dyn_cast<LazyObjFile>(file)) {
lazyObjFiles.push_back(f);
f->parse<ELFT>();
return;
}
if (config->trace)
message(toString(file));
// .so file
if (auto *f = dyn_cast<SharedFile>(file)) {
f->parse<ELFT>();
return;
}
// LLVM bitcode file
if (auto *f = dyn_cast<BitcodeFile>(file)) {
bitcodeFiles.push_back(f);
f->parse<ELFT>();
return;
}
// Regular object file
objectFiles.push_back(file);
cast<ObjFile<ELFT>>(file)->parse();
}
// Add symbols in File to the symbol table.
void elf::parseFile(InputFile *file) {
switch (config->ekind) {
case ELF32LEKind:
doParseFile<ELF32LE>(file);
return;
case ELF32BEKind:
doParseFile<ELF32BE>(file);
return;
case ELF64LEKind:
doParseFile<ELF64LE>(file);
return;
case ELF64BEKind:
doParseFile<ELF64BE>(file);
return;
default:
llvm_unreachable("unknown ELFT");
}
}
// Concatenates arguments to construct a string representing an error location.
static std::string createFileLineMsg(StringRef path, unsigned line) {
std::string filename = path::filename(path);
std::string lineno = ":" + std::to_string(line);
if (filename == path)
return filename + lineno;
return filename + lineno + " (" + path.str() + lineno + ")";
}
template <class ELFT>
static std::string getSrcMsgAux(ObjFile<ELFT> &file, const Symbol &sym,
InputSectionBase &sec, uint64_t offset) {
// In DWARF, functions and variables are stored to different places.
// First, lookup a function for a given offset.
if (Optional<DILineInfo> info = file.getDILineInfo(&sec, offset))
return createFileLineMsg(info->FileName, info->Line);
// If it failed, lookup again as a variable.
if (Optional<std::pair<std::string, unsigned>> fileLine =
file.getVariableLoc(sym.getName()))
return createFileLineMsg(fileLine->first, fileLine->second);
// File.sourceFile contains STT_FILE symbol, and that is a last resort.
return file.sourceFile;
}
std::string InputFile::getSrcMsg(const Symbol &sym, InputSectionBase &sec,
uint64_t offset) {
if (kind() != ObjKind)
return "";
switch (config->ekind) {
default:
llvm_unreachable("Invalid kind");
case ELF32LEKind:
return getSrcMsgAux(cast<ObjFile<ELF32LE>>(*this), sym, sec, offset);
case ELF32BEKind:
return getSrcMsgAux(cast<ObjFile<ELF32BE>>(*this), sym, sec, offset);
case ELF64LEKind:
return getSrcMsgAux(cast<ObjFile<ELF64LE>>(*this), sym, sec, offset);
case ELF64BEKind:
return getSrcMsgAux(cast<ObjFile<ELF64BE>>(*this), sym, sec, offset);
}
}
template <class ELFT> void ObjFile<ELFT>::initializeDwarf() {
dwarf = llvm::make_unique<DWARFContext>(make_unique<LLDDwarfObj<ELFT>>(this));
for (std::unique_ptr<DWARFUnit> &cu : dwarf->compile_units()) {
auto report = [](Error err) {
handleAllErrors(std::move(err),
[](ErrorInfoBase &info) { warn(info.message()); });
};
Expected<const DWARFDebugLine::LineTable *> expectedLT =
dwarf->getLineTableForUnit(cu.get(), report);
const DWARFDebugLine::LineTable *lt = nullptr;
if (expectedLT)
lt = *expectedLT;
else
report(expectedLT.takeError());
if (!lt)
continue;
lineTables.push_back(lt);
// Loop over variable records and insert them to variableLoc.
for (const auto &entry : cu->dies()) {
DWARFDie die(cu.get(), &entry);
// Skip all tags that are not variables.
if (die.getTag() != dwarf::DW_TAG_variable)
continue;
// Skip if a local variable because we don't need them for generating
// error messages. In general, only non-local symbols can fail to be
// linked.
if (!dwarf::toUnsigned(die.find(dwarf::DW_AT_external), 0))
continue;
// Get the source filename index for the variable.
unsigned file = dwarf::toUnsigned(die.find(dwarf::DW_AT_decl_file), 0);
if (!lt->hasFileAtIndex(file))
continue;
// Get the line number on which the variable is declared.
unsigned line = dwarf::toUnsigned(die.find(dwarf::DW_AT_decl_line), 0);
// Here we want to take the variable name to add it into variableLoc.
// Variable can have regular and linkage name associated. At first, we try
// to get linkage name as it can be different, for example when we have
// two variables in different namespaces of the same object. Use common
// name otherwise, but handle the case when it also absent in case if the
// input object file lacks some debug info.
StringRef name =
dwarf::toString(die.find(dwarf::DW_AT_linkage_name),
dwarf::toString(die.find(dwarf::DW_AT_name), ""));
if (!name.empty())
variableLoc.insert({name, {lt, file, line}});
}
}
}
// Returns the pair of file name and line number describing location of data
// object (variable, array, etc) definition.
template <class ELFT>
Optional<std::pair<std::string, unsigned>>
ObjFile<ELFT>::getVariableLoc(StringRef name) {
llvm::call_once(initDwarfLine, [this]() { initializeDwarf(); });
// Return if we have no debug information about data object.
auto it = variableLoc.find(name);
if (it == variableLoc.end())
return None;
// Take file name string from line table.
std::string fileName;
if (!it->second.lt->getFileNameByIndex(
it->second.file, {},
DILineInfoSpecifier::FileLineInfoKind::AbsoluteFilePath, fileName))
return None;
return std::make_pair(fileName, it->second.line);
}
// Returns source line information for a given offset
// using DWARF debug info.
template <class ELFT>
Optional<DILineInfo> ObjFile<ELFT>::getDILineInfo(InputSectionBase *s,
uint64_t offset) {
llvm::call_once(initDwarfLine, [this]() { initializeDwarf(); });
// Detect SectionIndex for specified section.
uint64_t sectionIndex = object::SectionedAddress::UndefSection;
ArrayRef<InputSectionBase *> sections = s->file->getSections();
for (uint64_t curIndex = 0; curIndex < sections.size(); ++curIndex) {
if (s == sections[curIndex]) {
sectionIndex = curIndex;
break;
}
}
// Use fake address calcuated by adding section file offset and offset in
// section. See comments for ObjectInfo class.
DILineInfo info;
for (const llvm::DWARFDebugLine::LineTable *lt : lineTables) {
if (lt->getFileLineInfoForAddress(
{s->getOffsetInFile() + offset, sectionIndex}, nullptr,
DILineInfoSpecifier::FileLineInfoKind::AbsoluteFilePath, info))
return info;
}
return None;
}
// Returns "<internal>", "foo.a(bar.o)" or "baz.o".
std::string lld::toString(const InputFile *f) {
if (!f)
return "<internal>";
if (f->toStringCache.empty()) {
if (f->archiveName.empty())
f->toStringCache = f->getName();
else
f->toStringCache = (f->archiveName + "(" + f->getName() + ")").str();
}
return f->toStringCache;
}
ELFFileBase::ELFFileBase(Kind k, MemoryBufferRef mb) : InputFile(k, mb) {
ekind = getELFKind(mb, "");
switch (ekind) {
case ELF32LEKind:
init<ELF32LE>();
break;
case ELF32BEKind:
init<ELF32BE>();
break;
case ELF64LEKind:
init<ELF64LE>();
break;
case ELF64BEKind:
init<ELF64BE>();
break;
default:
llvm_unreachable("getELFKind");
}
}
template <typename Elf_Shdr>
static const Elf_Shdr *findSection(ArrayRef<Elf_Shdr> sections, uint32_t type) {
for (const Elf_Shdr &sec : sections)
if (sec.sh_type == type)
return &sec;
return nullptr;
}
template <class ELFT> void ELFFileBase::init() {
using Elf_Shdr = typename ELFT::Shdr;
using Elf_Sym = typename ELFT::Sym;
// Initialize trivial attributes.
const ELFFile<ELFT> &obj = getObj<ELFT>();
emachine = obj.getHeader()->e_machine;
osabi = obj.getHeader()->e_ident[llvm::ELF::EI_OSABI];
abiVersion = obj.getHeader()->e_ident[llvm::ELF::EI_ABIVERSION];
ArrayRef<Elf_Shdr> sections = CHECK(obj.sections(), this);
// Find a symbol table.
bool isDSO =
(identify_magic(mb.getBuffer()) == file_magic::elf_shared_object);
const Elf_Shdr *symtabSec =
findSection(sections, isDSO ? SHT_DYNSYM : SHT_SYMTAB);
if (!symtabSec)
return;
// Initialize members corresponding to a symbol table.
firstGlobal = symtabSec->sh_info;
ArrayRef<Elf_Sym> eSyms = CHECK(obj.symbols(symtabSec), this);
if (firstGlobal == 0 || firstGlobal > eSyms.size())
fatal(toString(this) + ": invalid sh_info in symbol table");
elfSyms = reinterpret_cast<const void *>(eSyms.data());
numELFSyms = eSyms.size();
stringTable = CHECK(obj.getStringTableForSymtab(*symtabSec, sections), this);
}
template <class ELFT>
uint32_t ObjFile<ELFT>::getSectionIndex(const Elf_Sym &sym) const {
return CHECK(
this->getObj().getSectionIndex(&sym, getELFSyms<ELFT>(), shndxTable),
this);
}
template <class ELFT> ArrayRef<Symbol *> ObjFile<ELFT>::getLocalSymbols() {
if (this->symbols.empty())
return {};
return makeArrayRef(this->symbols).slice(1, this->firstGlobal - 1);
}
template <class ELFT> ArrayRef<Symbol *> ObjFile<ELFT>::getGlobalSymbols() {
return makeArrayRef(this->symbols).slice(this->firstGlobal);
}
template <class ELFT> void ObjFile<ELFT>::parse(bool ignoreComdats) {
// Read a section table. justSymbols is usually false.
if (this->justSymbols)
initializeJustSymbols();
else
initializeSections(ignoreComdats);
// Read a symbol table.
initializeSymbols();
}
// Sections with SHT_GROUP and comdat bits define comdat section groups.
// They are identified and deduplicated by group name. This function
// returns a group name.
template <class ELFT>
StringRef ObjFile<ELFT>::getShtGroupSignature(ArrayRef<Elf_Shdr> sections,
const Elf_Shdr &sec) {
typename ELFT::SymRange symbols = this->getELFSyms<ELFT>();
if (sec.sh_info >= symbols.size())
fatal(toString(this) + ": invalid symbol index");
const typename ELFT::Sym &sym = symbols[sec.sh_info];
StringRef signature = CHECK(sym.getName(this->stringTable), this);
// As a special case, if a symbol is a section symbol and has no name,
// we use a section name as a signature.
//
// Such SHT_GROUP sections are invalid from the perspective of the ELF
// standard, but GNU gold 1.14 (the newest version as of July 2017) or
// older produce such sections as outputs for the -r option, so we need
// a bug-compatibility.
if (signature.empty() && sym.getType() == STT_SECTION)
return getSectionName(sec);
return signature;
}
template <class ELFT> bool ObjFile<ELFT>::shouldMerge(const Elf_Shdr &sec) {
// On a regular link we don't merge sections if -O0 (default is -O1). This
// sometimes makes the linker significantly faster, although the output will
// be bigger.
//
// Doing the same for -r would create a problem as it would combine sections
// with different sh_entsize. One option would be to just copy every SHF_MERGE
// section as is to the output. While this would produce a valid ELF file with
// usable SHF_MERGE sections, tools like (llvm-)?dwarfdump get confused when
// they see two .debug_str. We could have separate logic for combining
// SHF_MERGE sections based both on their name and sh_entsize, but that seems
// to be more trouble than it is worth. Instead, we just use the regular (-O1)
// logic for -r.
if (config->optimize == 0 && !config->relocatable)
return false;
// A mergeable section with size 0 is useless because they don't have
// any data to merge. A mergeable string section with size 0 can be
// argued as invalid because it doesn't end with a null character.
// We'll avoid a mess by handling them as if they were non-mergeable.
if (sec.sh_size == 0)
return false;
// Check for sh_entsize. The ELF spec is not clear about the zero
// sh_entsize. It says that "the member [sh_entsize] contains 0 if
// the section does not hold a table of fixed-size entries". We know
// that Rust 1.13 produces a string mergeable section with a zero
// sh_entsize. Here we just accept it rather than being picky about it.
uint64_t entSize = sec.sh_entsize;
if (entSize == 0)
return false;
if (sec.sh_size % entSize)
fatal(toString(this) +
": SHF_MERGE section size must be a multiple of sh_entsize");
uint64_t flags = sec.sh_flags;
if (!(flags & SHF_MERGE))
return false;
if (flags & SHF_WRITE)
fatal(toString(this) + ": writable SHF_MERGE section is not supported");
return true;
}
// This is for --just-symbols.
//
// --just-symbols is a very minor feature that allows you to link your
// output against other existing program, so that if you load both your
// program and the other program into memory, your output can refer the
// other program's symbols.
//
// When the option is given, we link "just symbols". The section table is
// initialized with null pointers.
template <class ELFT> void ObjFile<ELFT>::initializeJustSymbols() {
ArrayRef<Elf_Shdr> sections = CHECK(this->getObj().sections(), this);
this->sections.resize(sections.size());
}
// An ELF object file may contain a `.deplibs` section. If it exists, the
// section contains a list of library specifiers such as `m` for libm. This
// function resolves a given name by finding the first matching library checking
// the various ways that a library can be specified to LLD. This ELF extension
// is a form of autolinking and is called `dependent libraries`. It is currently
// unique to LLVM and lld.
static void addDependentLibrary(StringRef specifier, const InputFile *f) {
if (!config->dependentLibraries)
return;
if (fs::exists(specifier))
driver->addFile(specifier, /*withLOption=*/false);
else if (Optional<std::string> s = findFromSearchPaths(specifier))
driver->addFile(*s, /*withLOption=*/true);
else if (Optional<std::string> s = searchLibraryBaseName(specifier))
driver->addFile(*s, /*withLOption=*/true);
else
error(toString(f) +
": unable to find library from dependent library specifier: " +
specifier);
}
template <class ELFT>
void ObjFile<ELFT>::initializeSections(bool ignoreComdats) {
const ELFFile<ELFT> &obj = this->getObj();
ArrayRef<Elf_Shdr> objSections = CHECK(obj.sections(), this);
uint64_t size = objSections.size();
this->sections.resize(size);
this->sectionStringTable =
CHECK(obj.getSectionStringTable(objSections), this);
for (size_t i = 0, e = objSections.size(); i < e; i++) {
if (this->sections[i] == &InputSection::discarded)
continue;
const Elf_Shdr &sec = objSections[i];
if (sec.sh_type == ELF::SHT_LLVM_CALL_GRAPH_PROFILE)
cgProfile =
check(obj.template getSectionContentsAsArray<Elf_CGProfile>(&sec));
// SHF_EXCLUDE'ed sections are discarded by the linker. However,
// if -r is given, we'll let the final link discard such sections.
// This is compatible with GNU.
if ((sec.sh_flags & SHF_EXCLUDE) && !config->relocatable) {
if (sec.sh_type == SHT_LLVM_ADDRSIG) {
// We ignore the address-significance table if we know that the object
// file was created by objcopy or ld -r. This is because these tools
// will reorder the symbols in the symbol table, invalidating the data
// in the address-significance table, which refers to symbols by index.
if (sec.sh_link != 0)
this->addrsigSec = &sec;
else if (config->icf == ICFLevel::Safe)
warn(toString(this) + ": --icf=safe is incompatible with object "
"files created using objcopy or ld -r");
}
this->sections[i] = &InputSection::discarded;
continue;
}
switch (sec.sh_type) {
case SHT_GROUP: {
// De-duplicate section groups by their signatures.
StringRef signature = getShtGroupSignature(objSections, sec);
this->sections[i] = &InputSection::discarded;
ArrayRef<Elf_Word> entries =
CHECK(obj.template getSectionContentsAsArray<Elf_Word>(&sec), this);
if (entries.empty())
fatal(toString(this) + ": empty SHT_GROUP");
// The first word of a SHT_GROUP section contains flags. Currently,
// the standard defines only "GRP_COMDAT" flag for the COMDAT group.
// An group with the empty flag doesn't define anything; such sections
// are just skipped.
if (entries[0] == 0)
continue;
if (entries[0] != GRP_COMDAT)
fatal(toString(this) + ": unsupported SHT_GROUP format");
bool isNew =
ignoreComdats ||
symtab->comdatGroups.try_emplace(CachedHashStringRef(signature), this)
.second;
if (isNew) {
if (config->relocatable)
this->sections[i] = createInputSection(sec);
continue;
}
// Otherwise, discard group members.
for (uint32_t secIndex : entries.slice(1)) {
if (secIndex >= size)
fatal(toString(this) +
": invalid section index in group: " + Twine(secIndex));
this->sections[secIndex] = &InputSection::discarded;
}
break;
}
case SHT_SYMTAB_SHNDX:
shndxTable = CHECK(obj.getSHNDXTable(sec, objSections), this);
break;
case SHT_SYMTAB:
case SHT_STRTAB:
case SHT_NULL:
break;
default:
this->sections[i] = createInputSection(sec);
}
// .ARM.exidx sections have a reverse dependency on the InputSection they
// have a SHF_LINK_ORDER dependency, this is identified by the sh_link.
if (sec.sh_flags & SHF_LINK_ORDER) {
InputSectionBase *linkSec = nullptr;
if (sec.sh_link < this->sections.size())
linkSec = this->sections[sec.sh_link];
if (!linkSec)
fatal(toString(this) +
": invalid sh_link index: " + Twine(sec.sh_link));
InputSection *isec = cast<InputSection>(this->sections[i]);
linkSec->dependentSections.push_back(isec);
if (!isa<InputSection>(linkSec))
error("a section " + isec->name +
" with SHF_LINK_ORDER should not refer a non-regular "
"section: " +
toString(linkSec));
}
}
}
// For ARM only, to set the EF_ARM_ABI_FLOAT_SOFT or EF_ARM_ABI_FLOAT_HARD
// flag in the ELF Header we need to look at Tag_ABI_VFP_args to find out how
// the input objects have been compiled.
static void updateARMVFPArgs(const ARMAttributeParser &attributes,
const InputFile *f) {
if (!attributes.hasAttribute(ARMBuildAttrs::ABI_VFP_args))
// If an ABI tag isn't present then it is implicitly given the value of 0
// which maps to ARMBuildAttrs::BaseAAPCS. However many assembler files,
// including some in glibc that don't use FP args (and should have value 3)
// don't have the attribute so we do not consider an implicit value of 0
// as a clash.
return;
unsigned vfpArgs = attributes.getAttributeValue(ARMBuildAttrs::ABI_VFP_args);
ARMVFPArgKind arg;
switch (vfpArgs) {
case ARMBuildAttrs::BaseAAPCS:
arg = ARMVFPArgKind::Base;
break;
case ARMBuildAttrs::HardFPAAPCS:
arg = ARMVFPArgKind::VFP;
break;
case ARMBuildAttrs::ToolChainFPPCS:
// Tool chain specific convention that conforms to neither AAPCS variant.
arg = ARMVFPArgKind::ToolChain;
break;
case ARMBuildAttrs::CompatibleFPAAPCS:
// Object compatible with all conventions.
return;
default:
error(toString(f) + ": unknown Tag_ABI_VFP_args value: " + Twine(vfpArgs));
return;
}
// Follow ld.bfd and error if there is a mix of calling conventions.
if (config->armVFPArgs != arg && config->armVFPArgs != ARMVFPArgKind::Default)
error(toString(f) + ": incompatible Tag_ABI_VFP_args");
else
config->armVFPArgs = arg;
}
// The ARM support in lld makes some use of instructions that are not available
// on all ARM architectures. Namely:
// - Use of BLX instruction for interworking between ARM and Thumb state.
// - Use of the extended Thumb branch encoding in relocation.
// - Use of the MOVT/MOVW instructions in Thumb Thunks.
// The ARM Attributes section contains information about the architecture chosen
// at compile time. We follow the convention that if at least one input object
// is compiled with an architecture that supports these features then lld is
// permitted to use them.
static void updateSupportedARMFeatures(const ARMAttributeParser &attributes) {
if (!attributes.hasAttribute(ARMBuildAttrs::CPU_arch))
return;
auto arch = attributes.getAttributeValue(ARMBuildAttrs::CPU_arch);
switch (arch) {
case ARMBuildAttrs::Pre_v4:
case ARMBuildAttrs::v4:
case ARMBuildAttrs::v4T:
// Architectures prior to v5 do not support BLX instruction
break;
case ARMBuildAttrs::v5T:
case ARMBuildAttrs::v5TE:
case ARMBuildAttrs::v5TEJ:
case ARMBuildAttrs::v6:
case ARMBuildAttrs::v6KZ:
case ARMBuildAttrs::v6K:
config->armHasBlx = true;
// Architectures used in pre-Cortex processors do not support
// The J1 = 1 J2 = 1 Thumb branch range extension, with the exception
// of Architecture v6T2 (arm1156t2-s and arm1156t2f-s) that do.
break;
default:
// All other Architectures have BLX and extended branch encoding
config->armHasBlx = true;
config->armJ1J2BranchEncoding = true;
if (arch != ARMBuildAttrs::v6_M && arch != ARMBuildAttrs::v6S_M)
// All Architectures used in Cortex processors with the exception
// of v6-M and v6S-M have the MOVT and MOVW instructions.
config->armHasMovtMovw = true;
break;
}
}
// If a source file is compiled with x86 hardware-assisted call flow control
// enabled, the generated object file contains feature flags indicating that
// fact. This function reads the feature flags and returns it.
//
// Essentially we want to read a single 32-bit value in this function, but this
// function is rather complicated because the value is buried deep inside a
// .note.gnu.property section.
//
// The section consists of one or more NOTE records. Each NOTE record consists
// of zero or more type-length-value fields. We want to find a field of a
// certain type. It seems a bit too much to just store a 32-bit value, perhaps
// the ABI is unnecessarily complicated.
template <class ELFT>
static uint32_t readAndFeatures(ObjFile<ELFT> *obj, ArrayRef<uint8_t> data) {
using Elf_Nhdr = typename ELFT::Nhdr;
using Elf_Note = typename ELFT::Note;
uint32_t featuresSet = 0;
while (!data.empty()) {
// Read one NOTE record.
if (data.size() < sizeof(Elf_Nhdr))
fatal(toString(obj) + ": .note.gnu.property: section too short");
auto *nhdr = reinterpret_cast<const Elf_Nhdr *>(data.data());
if (data.size() < nhdr->getSize())
fatal(toString(obj) + ": .note.gnu.property: section too short");
Elf_Note note(*nhdr);
if (nhdr->n_type != NT_GNU_PROPERTY_TYPE_0 || note.getName() != "GNU") {
data = data.slice(nhdr->getSize());
continue;
}
uint32_t featureAndType = config->emachine == EM_AARCH64
? GNU_PROPERTY_AARCH64_FEATURE_1_AND
: GNU_PROPERTY_X86_FEATURE_1_AND;
// Read a body of a NOTE record, which consists of type-length-value fields.
ArrayRef<uint8_t> desc = note.getDesc();
while (!desc.empty()) {
if (desc.size() < 8)
fatal(toString(obj) + ": .note.gnu.property: section too short");
uint32_t type = read32le(desc.data());
uint32_t size = read32le(desc.data() + 4);
if (type == featureAndType) {
// We found a FEATURE_1_AND field. There may be more than one of these
// in a .note.gnu.propery section, for a relocatable object we
// accumulate the bits set.
featuresSet |= read32le(desc.data() + 8);
}
// On 64-bit, a payload may be followed by a 4-byte padding to make its
// size a multiple of 8.
if (ELFT::Is64Bits)
size = alignTo(size, 8);
desc = desc.slice(size + 8); // +8 for Type and Size
}
// Go to next NOTE record to look for more FEATURE_1_AND descriptions.
data = data.slice(nhdr->getSize());
}
return featuresSet;
}
template <class ELFT>
InputSectionBase *ObjFile<ELFT>::getRelocTarget(const Elf_Shdr &sec) {
uint32_t idx = sec.sh_info;
if (idx >= this->sections.size())
fatal(toString(this) + ": invalid relocated section index: " + Twine(idx));
InputSectionBase *target = this->sections[idx];
// Strictly speaking, a relocation section must be included in the
// group of the section it relocates. However, LLVM 3.3 and earlier
// would fail to do so, so we gracefully handle that case.
if (target == &InputSection::discarded)
return nullptr;
if (!target)
fatal(toString(this) + ": unsupported relocation reference");
return target;
}
// Create a regular InputSection class that has the same contents
// as a given section.
static InputSection *toRegularSection(MergeInputSection *sec) {
return make<InputSection>(sec->file, sec->flags, sec->type, sec->alignment,
sec->data(), sec->name);
}
template <class ELFT>
InputSectionBase *ObjFile<ELFT>::createInputSection(const Elf_Shdr &sec) {
StringRef name = getSectionName(sec);
switch (sec.sh_type) {
case SHT_ARM_ATTRIBUTES: {
if (config->emachine != EM_ARM)
break;
ARMAttributeParser attributes;
ArrayRef<uint8_t> contents = check(this->getObj().getSectionContents(&sec));
attributes.Parse(contents, /*isLittle*/ config->ekind == ELF32LEKind);
updateSupportedARMFeatures(attributes);
updateARMVFPArgs(attributes, this);
// FIXME: Retain the first attribute section we see. The eglibc ARM
// dynamic loaders require the presence of an attribute section for dlopen
// to work. In a full implementation we would merge all attribute sections.
if (in.armAttributes == nullptr) {
in.armAttributes = make<InputSection>(*this, sec, name);
return in.armAttributes;
}
return &InputSection::discarded;
}
case SHT_LLVM_DEPENDENT_LIBRARIES: {
if (config->relocatable)
break;
ArrayRef<char> data =
CHECK(this->getObj().template getSectionContentsAsArray<char>(&sec), this);
if (!data.empty() && data.back() != '\0') {
error(toString(this) +
": corrupted dependent libraries section (unterminated string): " +
name);
return &InputSection::discarded;
}
for (const char *d = data.begin(), *e = data.end(); d < e;) {
StringRef s(d);
addDependentLibrary(s, this);
d += s.size() + 1;
}
return &InputSection::discarded;
}
case SHT_RELA:
case SHT_REL: {
// Find a relocation target section and associate this section with that.
// Target may have been discarded if it is in a different section group
// and the group is discarded, even though it's a violation of the
// spec. We handle that situation gracefully by discarding dangling
// relocation sections.
InputSectionBase *target = getRelocTarget(sec);
if (!target)
return nullptr;
// This section contains relocation information.
// If -r is given, we do not interpret or apply relocation
// but just copy relocation sections to output.
if (config->relocatable) {
InputSection *relocSec = make<InputSection>(*this, sec, name);
// We want to add a dependency to target, similar like we do for
// -emit-relocs below. This is useful for the case when linker script
// contains the "/DISCARD/". It is perhaps uncommon to use a script with
// -r, but we faced it in the Linux kernel and have to handle such case
// and not to crash.
target->dependentSections.push_back(relocSec);
return relocSec;
}
if (target->firstRelocation)
fatal(toString(this) +
": multiple relocation sections to one section are not supported");
// ELF spec allows mergeable sections with relocations, but they are
// rare, and it is in practice hard to merge such sections by contents,
// because applying relocations at end of linking changes section
// contents. So, we simply handle such sections as non-mergeable ones.
// Degrading like this is acceptable because section merging is optional.
if (auto *ms = dyn_cast<MergeInputSection>(target)) {
target = toRegularSection(ms);
this->sections[sec.sh_info] = target;
}
if (sec.sh_type == SHT_RELA) {
ArrayRef<Elf_Rela> rels = CHECK(getObj().relas(&sec), this);
target->firstRelocation = rels.begin();
target->numRelocations = rels.size();
target->areRelocsRela = true;
} else {
ArrayRef<Elf_Rel> rels = CHECK(getObj().rels(&sec), this);
target->firstRelocation = rels.begin();
target->numRelocations = rels.size();
target->areRelocsRela = false;
}
assert(isUInt<31>(target->numRelocations));
// Relocation sections processed by the linker are usually removed
// from the output, so returning `nullptr` for the normal case.
// However, if -emit-relocs is given, we need to leave them in the output.
// (Some post link analysis tools need this information.)
if (config->emitRelocs) {
InputSection *relocSec = make<InputSection>(*this, sec, name);
// We will not emit relocation section if target was discarded.
target->dependentSections.push_back(relocSec);
return relocSec;
}
return nullptr;
}
}
// The GNU linker uses .note.GNU-stack section as a marker indicating
// that the code in the object file does not expect that the stack is
// executable (in terms of NX bit). If all input files have the marker,
// the GNU linker adds a PT_GNU_STACK segment to tells the loader to
// make the stack non-executable. Most object files have this section as
// of 2017.
//
// But making the stack non-executable is a norm today for security
// reasons. Failure to do so may result in a serious security issue.
// Therefore, we make LLD always add PT_GNU_STACK unless it is
// explicitly told to do otherwise (by -z execstack). Because the stack
// executable-ness is controlled solely by command line options,
// .note.GNU-stack sections are simply ignored.
if (name == ".note.GNU-stack")
return &InputSection::discarded;
// Object files that use processor features such as Intel Control-Flow
// Enforcement (CET) or AArch64 Branch Target Identification BTI, use a
// .note.gnu.property section containing a bitfield of feature bits like the
// GNU_PROPERTY_X86_FEATURE_1_IBT flag. Read a bitmap containing the flag.
//
// Since we merge bitmaps from multiple object files to create a new
// .note.gnu.property containing a single AND'ed bitmap, we discard an input
// file's .note.gnu.property section.
if (name == ".note.gnu.property") {
ArrayRef<uint8_t> contents = check(this->getObj().getSectionContents(&sec));
this->andFeatures = readAndFeatures(this, contents);
return &InputSection::discarded;
}
// Split stacks is a feature to support a discontiguous stack,
// commonly used in the programming language Go. For the details,
// see https://gcc.gnu.org/wiki/SplitStacks. An object file compiled
// for split stack will include a .note.GNU-split-stack section.
if (name == ".note.GNU-split-stack") {
if (config->relocatable) {
error("cannot mix split-stack and non-split-stack in a relocatable link");
return &InputSection::discarded;
}
this->splitStack = true;
return &InputSection::discarded;
}
// An object file cmpiled for split stack, but where some of the
// functions were compiled with the no_split_stack_attribute will
// include a .note.GNU-no-split-stack section.
if (name == ".note.GNU-no-split-stack") {
this->someNoSplitStack = true;
return &InputSection::discarded;
}
// The linkonce feature is a sort of proto-comdat. Some glibc i386 object
// files contain definitions of symbol "__x86.get_pc_thunk.bx" in linkonce
// sections. Drop those sections to avoid duplicate symbol errors.
// FIXME: This is glibc PR20543, we should remove this hack once that has been
// fixed for a while.
if (name == ".gnu.linkonce.t.__x86.get_pc_thunk.bx" ||
name == ".gnu.linkonce.t.__i686.get_pc_thunk.bx")
return &InputSection::discarded;
// If we are creating a new .build-id section, strip existing .build-id
// sections so that the output won't have more than one .build-id.
// This is not usually a problem because input object files normally don't
// have .build-id sections, but you can create such files by
// "ld.{bfd,gold,lld} -r --build-id", and we want to guard against it.
if (name == ".note.gnu.build-id" && config->buildId != BuildIdKind::None)
return &InputSection::discarded;
// The linker merges EH (exception handling) frames and creates a
// .eh_frame_hdr section for runtime. So we handle them with a special
// class. For relocatable outputs, they are just passed through.
if (name == ".eh_frame" && !config->relocatable)
return make<EhInputSection>(*this, sec, name);
if (shouldMerge(sec))
return make<MergeInputSection>(*this, sec, name);
return make<InputSection>(*this, sec, name);
}
template <class ELFT>
StringRef ObjFile<ELFT>::getSectionName(const Elf_Shdr &sec) {
return CHECK(getObj().getSectionName(&sec, sectionStringTable), this);
}
// Initialize this->Symbols. this->Symbols is a parallel array as
// its corresponding ELF symbol table.
template <class ELFT> void ObjFile<ELFT>::initializeSymbols() {
ArrayRef<Elf_Sym> eSyms = this->getELFSyms<ELFT>();
this->symbols.resize(eSyms.size());
// Our symbol table may have already been partially initialized
// because of LazyObjFile.
for (size_t i = 0, end = eSyms.size(); i != end; ++i)
if (!this->symbols[i] && eSyms[i].getBinding() != STB_LOCAL)
this->symbols[i] =
symtab->insert(CHECK(eSyms[i].getName(this->stringTable), this));
// Fill this->Symbols. A symbol is either local or global.
for (size_t i = 0, end = eSyms.size(); i != end; ++i) {
const Elf_Sym &eSym = eSyms[i];
// Read symbol attributes.
uint32_t secIdx = getSectionIndex(eSym);
if (secIdx >= this->sections.size())
fatal(toString(this) + ": invalid section index: " + Twine(secIdx));
InputSectionBase *sec = this->sections[secIdx];
uint8_t binding = eSym.getBinding();
uint8_t stOther = eSym.st_other;
uint8_t type = eSym.getType();
uint64_t value = eSym.st_value;
uint64_t size = eSym.st_size;
StringRefZ name = this->stringTable.data() + eSym.st_name;
// Handle local symbols. Local symbols are not added to the symbol
// table because they are not visible from other object files. We
// allocate symbol instances and add their pointers to Symbols.
if (binding == STB_LOCAL) {
if (eSym.getType() == STT_FILE)
sourceFile = CHECK(eSym.getName(this->stringTable), this);
if (this->stringTable.size() <= eSym.st_name)
fatal(toString(this) + ": invalid symbol name offset");
if (eSym.st_shndx == SHN_UNDEF)
this->symbols[i] = make<Undefined>(this, name, binding, stOther, type);
else if (sec == &InputSection::discarded)
this->symbols[i] = make<Undefined>(this, name, binding, stOther, type,
/*DiscardedSecIdx=*/secIdx);
else
this->symbols[i] =
make<Defined>(this, name, binding, stOther, type, value, size, sec);
continue;
}
// Handle global undefined symbols.
if (eSym.st_shndx == SHN_UNDEF) {
this->symbols[i]->resolve(Undefined{this, name, binding, stOther, type});
continue;
}
// Handle global common symbols.
if (eSym.st_shndx == SHN_COMMON) {
if (value == 0 || value >= UINT32_MAX)
fatal(toString(this) + ": common symbol '" + StringRef(name.data) +
"' has invalid alignment: " + Twine(value));
this->symbols[i]->resolve(
CommonSymbol{this, name, binding, stOther, type, value, size});
continue;
}
// If a defined symbol is in a discarded section, handle it as if it
// were an undefined symbol. Such symbol doesn't comply with the
// standard, but in practice, a .eh_frame often directly refer
// COMDAT member sections, and if a comdat group is discarded, some
// defined symbol in a .eh_frame becomes dangling symbols.
if (sec == &InputSection::discarded) {
this->symbols[i]->resolve(
Undefined{this, name, binding, stOther, type, secIdx});
continue;
}
// Handle global defined symbols.
if (binding == STB_GLOBAL || binding == STB_WEAK ||
binding == STB_GNU_UNIQUE) {
this->symbols[i]->resolve(
Defined{this, name, binding, stOther, type, value, size, sec});
continue;
}
fatal(toString(this) + ": unexpected binding: " + Twine((int)binding));
}
}
ArchiveFile::ArchiveFile(std::unique_ptr<Archive> &&file)
: InputFile(ArchiveKind, file->getMemoryBufferRef()),
file(std::move(file)) {}
void ArchiveFile::parse() {
for (const Archive::Symbol &sym : file->symbols())
symtab->addSymbol(LazyArchive{*this, sym});
}
// Returns a buffer pointing to a member file containing a given symbol.
void ArchiveFile::fetch(const Archive::Symbol &sym) {
Archive::Child c =
CHECK(sym.getMember(), toString(this) +
": could not get the member for symbol " +
sym.getName());
if (!seen.insert(c.getChildOffset()).second)
return;
MemoryBufferRef mb =
CHECK(c.getMemoryBufferRef(),
toString(this) +
": could not get the buffer for the member defining symbol " +
sym.getName());
if (tar && c.getParent()->isThin())
tar->append(relativeToRoot(CHECK(c.getFullName(), this)), mb.getBuffer());
InputFile *file = createObjectFile(
mb, getName(), c.getParent()->isThin() ? 0 : c.getChildOffset());
file->groupId = groupId;
parseFile(file);
}
unsigned SharedFile::vernauxNum;
// Parse the version definitions in the object file if present, and return a
// vector whose nth element contains a pointer to the Elf_Verdef for version
// identifier n. Version identifiers that are not definitions map to nullptr.
template <typename ELFT>
static std::vector<const void *> parseVerdefs(const uint8_t *base,
const typename ELFT::Shdr *sec) {
if (!sec)
return {};
// We cannot determine the largest verdef identifier without inspecting
// every Elf_Verdef, but both bfd and gold assign verdef identifiers
// sequentially starting from 1, so we predict that the largest identifier
// will be verdefCount.
unsigned verdefCount = sec->sh_info;
std::vector<const void *> verdefs(verdefCount + 1);
// Build the Verdefs array by following the chain of Elf_Verdef objects
// from the start of the .gnu.version_d section.
const uint8_t *verdef = base + sec->sh_offset;
for (unsigned i = 0; i != verdefCount; ++i) {
auto *curVerdef = reinterpret_cast<const typename ELFT::Verdef *>(verdef);
verdef += curVerdef->vd_next;
unsigned verdefIndex = curVerdef->vd_ndx;
verdefs.resize(verdefIndex + 1);
verdefs[verdefIndex] = curVerdef;
}
return verdefs;
}
// We do not usually care about alignments of data in shared object
// files because the loader takes care of it. However, if we promote a
// DSO symbol to point to .bss due to copy relocation, we need to keep
// the original alignment requirements. We infer it in this function.
template <typename ELFT>
static uint64_t getAlignment(ArrayRef<typename ELFT::Shdr> sections,
const typename ELFT::Sym &sym) {
uint64_t ret = UINT64_MAX;
if (sym.st_value)
ret = 1ULL << countTrailingZeros((uint64_t)sym.st_value);
if (0 < sym.st_shndx && sym.st_shndx < sections.size())
ret = std::min<uint64_t>(ret, sections[sym.st_shndx].sh_addralign);
return (ret > UINT32_MAX) ? 0 : ret;
}
// Fully parse the shared object file.
//
// This function parses symbol versions. If a DSO has version information,
// the file has a ".gnu.version_d" section which contains symbol version
// definitions. Each symbol is associated to one version through a table in
// ".gnu.version" section. That table is a parallel array for the symbol
// table, and each table entry contains an index in ".gnu.version_d".
//
// The special index 0 is reserved for VERF_NDX_LOCAL and 1 is for
// VER_NDX_GLOBAL. There's no table entry for these special versions in
// ".gnu.version_d".
//
// The file format for symbol versioning is perhaps a bit more complicated
// than necessary, but you can easily understand the code if you wrap your
// head around the data structure described above.
template <class ELFT> void SharedFile::parse() {
using Elf_Dyn = typename ELFT::Dyn;
using Elf_Shdr = typename ELFT::Shdr;
using Elf_Sym = typename ELFT::Sym;
using Elf_Verdef = typename ELFT::Verdef;
using Elf_Versym = typename ELFT::Versym;
ArrayRef<Elf_Dyn> dynamicTags;
const ELFFile<ELFT> obj = this->getObj<ELFT>();
ArrayRef<Elf_Shdr> sections = CHECK(obj.sections(), this);
const Elf_Shdr *versymSec = nullptr;
const Elf_Shdr *verdefSec = nullptr;
// Search for .dynsym, .dynamic, .symtab, .gnu.version and .gnu.version_d.
for (const Elf_Shdr &sec : sections) {
switch (sec.sh_type) {
default:
continue;
case SHT_DYNAMIC:
dynamicTags =
CHECK(obj.template getSectionContentsAsArray<Elf_Dyn>(&sec), this);
break;
case SHT_GNU_versym:
versymSec = &sec;
break;
case SHT_GNU_verdef:
verdefSec = &sec;
break;
}
}
if (versymSec && numELFSyms == 0) {
error("SHT_GNU_versym should be associated with symbol table");
return;
}
// Search for a DT_SONAME tag to initialize this->soName.
for (const Elf_Dyn &dyn : dynamicTags) {
if (dyn.d_tag == DT_NEEDED) {
uint64_t val = dyn.getVal();
if (val >= this->stringTable.size())
fatal(toString(this) + ": invalid DT_NEEDED entry");
dtNeeded.push_back(this->stringTable.data() + val);
} else if (dyn.d_tag == DT_SONAME) {
uint64_t val = dyn.getVal();
if (val >= this->stringTable.size())
fatal(toString(this) + ": invalid DT_SONAME entry");
soName = this->stringTable.data() + val;
}
}
// DSOs are uniquified not by filename but by soname.
DenseMap<StringRef, SharedFile *>::iterator it;
bool wasInserted;
std::tie(it, wasInserted) = symtab->soNames.try_emplace(soName, this);
// If a DSO appears more than once on the command line with and without
// --as-needed, --no-as-needed takes precedence over --as-needed because a
// user can add an extra DSO with --no-as-needed to force it to be added to
// the dependency list.
it->second->isNeeded |= isNeeded;
if (!wasInserted)
return;
sharedFiles.push_back(this);
verdefs = parseVerdefs<ELFT>(obj.base(), verdefSec);
// Parse ".gnu.version" section which is a parallel array for the symbol
// table. If a given file doesn't have a ".gnu.version" section, we use
// VER_NDX_GLOBAL.
size_t size = numELFSyms - firstGlobal;
std::vector<uint32_t> versyms(size, VER_NDX_GLOBAL);
if (versymSec) {
ArrayRef<Elf_Versym> versym =
CHECK(obj.template getSectionContentsAsArray<Elf_Versym>(versymSec),
this)
.slice(firstGlobal);
for (size_t i = 0; i < size; ++i)
versyms[i] = versym[i].vs_index;
}
// System libraries can have a lot of symbols with versions. Using a
// fixed buffer for computing the versions name (foo@ver) can save a
// lot of allocations.
SmallString<0> versionedNameBuffer;
// Add symbols to the symbol table.
ArrayRef<Elf_Sym> syms = this->getGlobalELFSyms<ELFT>();
for (size_t i = 0; i < syms.size(); ++i) {
const Elf_Sym &sym = syms[i];
// ELF spec requires that all local symbols precede weak or global
// symbols in each symbol table, and the index of first non-local symbol
// is stored to sh_info. If a local symbol appears after some non-local
// symbol, that's a violation of the spec.
StringRef name = CHECK(sym.getName(this->stringTable), this);
if (sym.getBinding() == STB_LOCAL) {
warn("found local symbol '" + name +
"' in global part of symbol table in file " + toString(this));
continue;
}
if (sym.isUndefined()) {
Symbol *s = symtab->addSymbol(
Undefined{this, name, sym.getBinding(), sym.st_other, sym.getType()});
s->exportDynamic = true;
continue;
}
// MIPS BFD linker puts _gp_disp symbol into DSO files and incorrectly
// assigns VER_NDX_LOCAL to this section global symbol. Here is a
// workaround for this bug.
uint32_t idx = versyms[i] & ~VERSYM_HIDDEN;
if (config->emachine == EM_MIPS && idx == VER_NDX_LOCAL &&
name == "_gp_disp")
continue;
uint32_t alignment = getAlignment<ELFT>(sections, sym);
if (!(versyms[i] & VERSYM_HIDDEN)) {
symtab->addSymbol(SharedSymbol{*this, name, sym.getBinding(),
sym.st_other, sym.getType(), sym.st_value,
sym.st_size, alignment, idx});
}
// Also add the symbol with the versioned name to handle undefined symbols
// with explicit versions.
if (idx == VER_NDX_GLOBAL)
continue;
if (idx >= verdefs.size() || idx == VER_NDX_LOCAL) {
error("corrupt input file: version definition index " + Twine(idx) +
" for symbol " + name + " is out of bounds\n>>> defined in " +
toString(this));
continue;
}
StringRef verName =
this->stringTable.data() +
reinterpret_cast<const Elf_Verdef *>(verdefs[idx])->getAux()->vda_name;
versionedNameBuffer.clear();
name = (name + "@" + verName).toStringRef(versionedNameBuffer);
symtab->addSymbol(SharedSymbol{*this, saver.save(name), sym.getBinding(),
sym.st_other, sym.getType(), sym.st_value,
sym.st_size, alignment, idx});
}
}
static ELFKind getBitcodeELFKind(const Triple &t) {
if (t.isLittleEndian())
return t.isArch64Bit() ? ELF64LEKind : ELF32LEKind;
return t.isArch64Bit() ? ELF64BEKind : ELF32BEKind;
}
static uint8_t getBitcodeMachineKind(StringRef path, const Triple &t) {
switch (t.getArch()) {
case Triple::aarch64:
return EM_AARCH64;
case Triple::amdgcn:
case Triple::r600:
return EM_AMDGPU;
case Triple::arm:
case Triple::thumb:
return EM_ARM;
case Triple::avr:
return EM_AVR;
case Triple::mips:
case Triple::mipsel:
case Triple::mips64:
case Triple::mips64el:
return EM_MIPS;
case Triple::msp430:
return EM_MSP430;
case Triple::ppc:
return EM_PPC;
case Triple::ppc64:
case Triple::ppc64le:
return EM_PPC64;
case Triple::riscv32:
case Triple::riscv64:
return EM_RISCV;
case Triple::x86:
return t.isOSIAMCU() ? EM_IAMCU : EM_386;
case Triple::x86_64:
return EM_X86_64;
default:
error(path + ": could not infer e_machine from bitcode target triple " +
t.str());
return EM_NONE;
}
}
BitcodeFile::BitcodeFile(MemoryBufferRef mb, StringRef archiveName,
uint64_t offsetInArchive)
: InputFile(BitcodeKind, mb) {
this->archiveName = archiveName;
std::string path = mb.getBufferIdentifier().str();
if (config->thinLTOIndexOnly)
path = replaceThinLTOSuffix(mb.getBufferIdentifier());
// ThinLTO assumes that all MemoryBufferRefs given to it have a unique
// name. If two archives define two members with the same name, this
// causes a collision which result in only one of the objects being taken
// into consideration at LTO time (which very likely causes undefined
// symbols later in the link stage). So we append file offset to make
// filename unique.
StringRef name = archiveName.empty()
? saver.save(path)
: saver.save(archiveName + "(" + path + " at " +
utostr(offsetInArchive) + ")");
MemoryBufferRef mbref(mb.getBuffer(), name);
obj = CHECK(lto::InputFile::create(mbref), this);
Triple t(obj->getTargetTriple());
ekind = getBitcodeELFKind(t);
emachine = getBitcodeMachineKind(mb.getBufferIdentifier(), t);
}
static uint8_t mapVisibility(GlobalValue::VisibilityTypes gvVisibility) {
switch (gvVisibility) {
case GlobalValue::DefaultVisibility:
return STV_DEFAULT;
case GlobalValue::HiddenVisibility:
return STV_HIDDEN;
case GlobalValue::ProtectedVisibility:
return STV_PROTECTED;
}
llvm_unreachable("unknown visibility");
}
template <class ELFT>
static Symbol *createBitcodeSymbol(const std::vector<bool> &keptComdats,
const lto::InputFile::Symbol &objSym,
BitcodeFile &f) {
StringRef name = saver.save(objSym.getName());
uint8_t binding = objSym.isWeak() ? STB_WEAK : STB_GLOBAL;
uint8_t type = objSym.isTLS() ? STT_TLS : STT_NOTYPE;
uint8_t visibility = mapVisibility(objSym.getVisibility());
bool canOmitFromDynSym = objSym.canBeOmittedFromSymbolTable();
int c = objSym.getComdatIndex();
if (objSym.isUndefined() || (c != -1 && !keptComdats[c])) {
Undefined New(&f, name, binding, visibility, type);
if (canOmitFromDynSym)
New.exportDynamic = false;
return symtab->addSymbol(New);
}
if (objSym.isCommon())
return symtab->addSymbol(
CommonSymbol{&f, name, binding, visibility, STT_OBJECT,
objSym.getCommonAlignment(), objSym.getCommonSize()});
Defined New(&f, name, binding, visibility, type, 0, 0, nullptr);
if (canOmitFromDynSym)
New.exportDynamic = false;
return symtab->addSymbol(New);
}
template <class ELFT> void BitcodeFile::parse() {
std::vector<bool> keptComdats;
for (StringRef s : obj->getComdatTable())
keptComdats.push_back(
symtab->comdatGroups.try_emplace(CachedHashStringRef(s), this).second);
for (const lto::InputFile::Symbol &objSym : obj->symbols())
symbols.push_back(createBitcodeSymbol<ELFT>(keptComdats, objSym, *this));
for (auto l : obj->getDependentLibraries())
addDependentLibrary(l, this);
}
void BinaryFile::parse() {
ArrayRef<uint8_t> data = arrayRefFromStringRef(mb.getBuffer());
auto *section = make<InputSection>(this, SHF_ALLOC | SHF_WRITE, SHT_PROGBITS,
8, data, ".data");
sections.push_back(section);
// For each input file foo that is embedded to a result as a binary
// blob, we define _binary_foo_{start,end,size} symbols, so that
// user programs can access blobs by name. Non-alphanumeric
// characters in a filename are replaced with underscore.
std::string s = "_binary_" + mb.getBufferIdentifier().str();
for (size_t i = 0; i < s.size(); ++i)
if (!isAlnum(s[i]))
s[i] = '_';
symtab->addSymbol(Defined{nullptr, saver.save(s + "_start"), STB_GLOBAL,
STV_DEFAULT, STT_OBJECT, 0, 0, section});
symtab->addSymbol(Defined{nullptr, saver.save(s + "_end"), STB_GLOBAL,
STV_DEFAULT, STT_OBJECT, data.size(), 0, section});
symtab->addSymbol(Defined{nullptr, saver.save(s + "_size"), STB_GLOBAL,
STV_DEFAULT, STT_OBJECT, data.size(), 0, nullptr});
}
InputFile *elf::createObjectFile(MemoryBufferRef mb, StringRef archiveName,
uint64_t offsetInArchive) {
if (isBitcode(mb))
return make<BitcodeFile>(mb, archiveName, offsetInArchive);
switch (getELFKind(mb, archiveName)) {
case ELF32LEKind:
return make<ObjFile<ELF32LE>>(mb, archiveName);
case ELF32BEKind:
return make<ObjFile<ELF32BE>>(mb, archiveName);
case ELF64LEKind:
return make<ObjFile<ELF64LE>>(mb, archiveName);
case ELF64BEKind:
return make<ObjFile<ELF64BE>>(mb, archiveName);
default:
llvm_unreachable("getELFKind");
}
}
void LazyObjFile::fetch() {
if (mb.getBuffer().empty())
return;
InputFile *file = createObjectFile(mb, archiveName, offsetInArchive);
file->groupId = groupId;
mb = {};
// Copy symbol vector so that the new InputFile doesn't have to
// insert the same defined symbols to the symbol table again.
file->symbols = std::move(symbols);
parseFile(file);
}
template <class ELFT> void LazyObjFile::parse() {
using Elf_Sym = typename ELFT::Sym;
// A lazy object file wraps either a bitcode file or an ELF file.
if (isBitcode(this->mb)) {
std::unique_ptr<lto::InputFile> obj =
CHECK(lto::InputFile::create(this->mb), this);
for (const lto::InputFile::Symbol &sym : obj->symbols()) {
if (sym.isUndefined())
continue;
symtab->addSymbol(LazyObject{*this, saver.save(sym.getName())});
}
return;
}
if (getELFKind(this->mb, archiveName) != config->ekind) {
error("incompatible file: " + this->mb.getBufferIdentifier());
return;
}
// Find a symbol table.
ELFFile<ELFT> obj = check(ELFFile<ELFT>::create(mb.getBuffer()));
ArrayRef<typename ELFT::Shdr> sections = CHECK(obj.sections(), this);
for (const typename ELFT::Shdr &sec : sections) {
if (sec.sh_type != SHT_SYMTAB)
continue;
// A symbol table is found.
ArrayRef<Elf_Sym> eSyms = CHECK(obj.symbols(&sec), this);
uint32_t firstGlobal = sec.sh_info;
StringRef strtab = CHECK(obj.getStringTableForSymtab(sec, sections), this);
this->symbols.resize(eSyms.size());
// Get existing symbols or insert placeholder symbols.
for (size_t i = firstGlobal, end = eSyms.size(); i != end; ++i)
if (eSyms[i].st_shndx != SHN_UNDEF)
this->symbols[i] = symtab->insert(CHECK(eSyms[i].getName(strtab), this));
// Replace existing symbols with LazyObject symbols.
//
// resolve() may trigger this->fetch() if an existing symbol is an
// undefined symbol. If that happens, this LazyObjFile has served
// its purpose, and we can exit from the loop early.
for (Symbol *sym : this->symbols) {
if (!sym)
continue;
sym->resolve(LazyObject{*this, sym->getName()});
// MemoryBuffer is emptied if this file is instantiated as ObjFile.
if (mb.getBuffer().empty())
return;
}
return;
}
}
std::string elf::replaceThinLTOSuffix(StringRef path) {
StringRef suffix = config->thinLTOObjectSuffixReplace.first;
StringRef repl = config->thinLTOObjectSuffixReplace.second;
if (path.consume_back(suffix))
return (path + repl).str();
return path;
}
template void BitcodeFile::parse<ELF32LE>();
template void BitcodeFile::parse<ELF32BE>();
template void BitcodeFile::parse<ELF64LE>();
template void BitcodeFile::parse<ELF64BE>();
template void LazyObjFile::parse<ELF32LE>();
template void LazyObjFile::parse<ELF32BE>();
template void LazyObjFile::parse<ELF64LE>();
template void LazyObjFile::parse<ELF64BE>();
template class elf::ObjFile<ELF32LE>;
template class elf::ObjFile<ELF32BE>;
template class elf::ObjFile<ELF64LE>;
template class elf::ObjFile<ELF64BE>;
template void SharedFile::parse<ELF32LE>();
template void SharedFile::parse<ELF32BE>();
template void SharedFile::parse<ELF64LE>();
template void SharedFile::parse<ELF64BE>();