opnsense-src/contrib/llvm/tools/lld/ELF/Driver.cpp
Ed Maste 5868914ed4 lld: hack version and help output for compatibility with libtool
GNU libtool checks the output from invoking the linker with --version
and --help, in order to determine the linker "flavour" and the command-
ine arguments to use for various link operations (e.g. generating shared
libraries). To detect GNU ld it looks for the strings "GNU" and
"supported targets:.*elf". Since LLD is compatible with GNU ld we
include those same strings to fool libtool.

Quoting from a comment in the change:
    This is somewhat ugly hack, but in reality, we had no choice other
    than doing this. Considering the very long release cycle of Libtool,
    it is not easy to improve it to recognize LLD as a GNU compatible
    linker in a timely manner. Even if we can make it, there are still a
    lot of "configure" scripts out there that are generated by old
    version of Libtool. We cannot convince every software developer to
    migrate to the latest version and re-generate scripts. So we have
    this hack.

Upstream LLVM revisions r298532, r298568, r298591

Obtained from:	LLVM
MFC after:	1 week
Sponsored by:	The FreeBSD Foundation
2017-03-27 16:01:16 +00:00

845 lines
28 KiB
C++

//===- Driver.cpp ---------------------------------------------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "Driver.h"
#include "Config.h"
#include "Error.h"
#include "ICF.h"
#include "InputFiles.h"
#include "InputSection.h"
#include "LinkerScript.h"
#include "Memory.h"
#include "Strings.h"
#include "SymbolTable.h"
#include "Target.h"
#include "Threads.h"
#include "Writer.h"
#include "lld/Config/Version.h"
#include "lld/Driver/Driver.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/Object/Decompressor.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/TarWriter.h"
#include "llvm/Support/TargetSelect.h"
#include "llvm/Support/raw_ostream.h"
#include <cstdlib>
#include <utility>
using namespace llvm;
using namespace llvm::ELF;
using namespace llvm::object;
using namespace llvm::sys;
using namespace lld;
using namespace lld::elf;
Configuration *elf::Config;
LinkerDriver *elf::Driver;
BumpPtrAllocator elf::BAlloc;
StringSaver elf::Saver{BAlloc};
std::vector<SpecificAllocBase *> elf::SpecificAllocBase::Instances;
bool elf::link(ArrayRef<const char *> Args, bool CanExitEarly,
raw_ostream &Error) {
ErrorCount = 0;
ErrorOS = &Error;
Argv0 = Args[0];
Tar = nullptr;
Config = make<Configuration>();
Driver = make<LinkerDriver>();
ScriptConfig = make<ScriptConfiguration>();
Driver->main(Args, CanExitEarly);
freeArena();
return !ErrorCount;
}
// Parses a linker -m option.
static std::tuple<ELFKind, uint16_t, uint8_t> parseEmulation(StringRef Emul) {
uint8_t OSABI = 0;
StringRef S = Emul;
if (S.endswith("_fbsd")) {
S = S.drop_back(5);
OSABI = ELFOSABI_FREEBSD;
}
std::pair<ELFKind, uint16_t> Ret =
StringSwitch<std::pair<ELFKind, uint16_t>>(S)
.Cases("aarch64elf", "aarch64linux", {ELF64LEKind, EM_AARCH64})
.Case("armelf_linux_eabi", {ELF32LEKind, EM_ARM})
.Case("elf32_x86_64", {ELF32LEKind, EM_X86_64})
.Case("elf32btsmip", {ELF32BEKind, EM_MIPS})
.Case("elf32ltsmip", {ELF32LEKind, EM_MIPS})
.Case("elf32btsmipn32", {ELF32BEKind, EM_MIPS})
.Case("elf32ltsmipn32", {ELF32LEKind, EM_MIPS})
.Case("elf32ppc", {ELF32BEKind, EM_PPC})
.Case("elf64btsmip", {ELF64BEKind, EM_MIPS})
.Case("elf64ltsmip", {ELF64LEKind, EM_MIPS})
.Case("elf64ppc", {ELF64BEKind, EM_PPC64})
.Cases("elf_amd64", "elf_x86_64", {ELF64LEKind, EM_X86_64})
.Case("elf_i386", {ELF32LEKind, EM_386})
.Case("elf_iamcu", {ELF32LEKind, EM_IAMCU})
.Default({ELFNoneKind, EM_NONE});
if (Ret.first == ELFNoneKind) {
if (S == "i386pe" || S == "i386pep" || S == "thumb2pe")
error("Windows targets are not supported on the ELF frontend: " + Emul);
else
error("unknown emulation: " + Emul);
}
return std::make_tuple(Ret.first, Ret.second, OSABI);
}
// Returns slices of MB by parsing MB as an archive file.
// Each slice consists of a member file in the archive.
std::vector<MemoryBufferRef>
LinkerDriver::getArchiveMembers(MemoryBufferRef MB) {
std::unique_ptr<Archive> File =
check(Archive::create(MB),
MB.getBufferIdentifier() + ": failed to parse archive");
std::vector<MemoryBufferRef> V;
Error Err = Error::success();
for (const ErrorOr<Archive::Child> &COrErr : File->children(Err)) {
Archive::Child C =
check(COrErr, MB.getBufferIdentifier() +
": could not get the child of the archive");
MemoryBufferRef MBRef =
check(C.getMemoryBufferRef(),
MB.getBufferIdentifier() +
": could not get the buffer for a child of the archive");
V.push_back(MBRef);
}
if (Err)
fatal(MB.getBufferIdentifier() + ": Archive::children failed: " +
toString(std::move(Err)));
// Take ownership of memory buffers created for members of thin archives.
for (std::unique_ptr<MemoryBuffer> &MB : File->takeThinBuffers())
make<std::unique_ptr<MemoryBuffer>>(std::move(MB));
return V;
}
// Opens and parses a file. Path has to be resolved already.
// Newly created memory buffers are owned by this driver.
void LinkerDriver::addFile(StringRef Path) {
using namespace sys::fs;
Optional<MemoryBufferRef> Buffer = readFile(Path);
if (!Buffer.hasValue())
return;
MemoryBufferRef MBRef = *Buffer;
if (InBinary) {
Files.push_back(make<BinaryFile>(MBRef));
return;
}
switch (identify_magic(MBRef.getBuffer())) {
case file_magic::unknown:
readLinkerScript(MBRef);
return;
case file_magic::archive:
if (InWholeArchive) {
for (MemoryBufferRef MB : getArchiveMembers(MBRef))
Files.push_back(createObjectFile(MB, Path));
return;
}
Files.push_back(make<ArchiveFile>(MBRef));
return;
case file_magic::elf_shared_object:
if (Config->Relocatable) {
error("attempted static link of dynamic object " + Path);
return;
}
Files.push_back(createSharedFile(MBRef));
return;
default:
if (InLib)
Files.push_back(make<LazyObjectFile>(MBRef));
else
Files.push_back(createObjectFile(MBRef));
}
}
// Add a given library by searching it from input search paths.
void LinkerDriver::addLibrary(StringRef Name) {
if (Optional<std::string> Path = searchLibrary(Name))
addFile(*Path);
else
error("unable to find library -l" + Name);
}
// This function is called on startup. We need this for LTO since
// LTO calls LLVM functions to compile bitcode files to native code.
// Technically this can be delayed until we read bitcode files, but
// we don't bother to do lazily because the initialization is fast.
static void initLLVM(opt::InputArgList &Args) {
InitializeAllTargets();
InitializeAllTargetMCs();
InitializeAllAsmPrinters();
InitializeAllAsmParsers();
// Parse and evaluate -mllvm options.
std::vector<const char *> V;
V.push_back("lld (LLVM option parsing)");
for (auto *Arg : Args.filtered(OPT_mllvm))
V.push_back(Arg->getValue());
cl::ParseCommandLineOptions(V.size(), V.data());
}
// Some command line options or some combinations of them are not allowed.
// This function checks for such errors.
static void checkOptions(opt::InputArgList &Args) {
// The MIPS ABI as of 2016 does not support the GNU-style symbol lookup
// table which is a relatively new feature.
if (Config->EMachine == EM_MIPS && Config->GnuHash)
error("the .gnu.hash section is not compatible with the MIPS target.");
if (Config->Pie && Config->Shared)
error("-shared and -pie may not be used together");
if (Config->Relocatable) {
if (Config->Shared)
error("-r and -shared may not be used together");
if (Config->GcSections)
error("-r and --gc-sections may not be used together");
if (Config->ICF)
error("-r and --icf may not be used together");
if (Config->Pie)
error("-r and -pie may not be used together");
}
}
static StringRef getString(opt::InputArgList &Args, unsigned Key,
StringRef Default = "") {
if (auto *Arg = Args.getLastArg(Key))
return Arg->getValue();
return Default;
}
static int getInteger(opt::InputArgList &Args, unsigned Key, int Default) {
int V = Default;
if (auto *Arg = Args.getLastArg(Key)) {
StringRef S = Arg->getValue();
if (S.getAsInteger(10, V))
error(Arg->getSpelling() + ": number expected, but got " + S);
}
return V;
}
static const char *getReproduceOption(opt::InputArgList &Args) {
if (auto *Arg = Args.getLastArg(OPT_reproduce))
return Arg->getValue();
return getenv("LLD_REPRODUCE");
}
static bool hasZOption(opt::InputArgList &Args, StringRef Key) {
for (auto *Arg : Args.filtered(OPT_z))
if (Key == Arg->getValue())
return true;
return false;
}
static uint64_t getZOptionValue(opt::InputArgList &Args, StringRef Key,
uint64_t Default) {
for (auto *Arg : Args.filtered(OPT_z)) {
StringRef Value = Arg->getValue();
size_t Pos = Value.find("=");
if (Pos != StringRef::npos && Key == Value.substr(0, Pos)) {
Value = Value.substr(Pos + 1);
uint64_t Result;
if (Value.getAsInteger(0, Result))
error("invalid " + Key + ": " + Value);
return Result;
}
}
return Default;
}
void LinkerDriver::main(ArrayRef<const char *> ArgsArr, bool CanExitEarly) {
ELFOptTable Parser;
opt::InputArgList Args = Parser.parse(ArgsArr.slice(1));
// Interpret this flag early because error() depends on them.
Config->ErrorLimit = getInteger(Args, OPT_error_limit, 20);
// Handle -help
if (Args.hasArg(OPT_help)) {
printHelp(ArgsArr[0]);
return;
}
// Handle -v or -version.
//
// A note about "compatible with GNU linkers" message: this is a hack for
// scripts generated by GNU Libtool 2.4.6 (released in February 2014 and
// still the newest version in March 2017) or earlier to recognize LLD as
// a GNU compatible linker. As long as an output for the -v option
// contains "GNU" or "with BFD", they recognize us as GNU-compatible.
//
// This is somewhat ugly hack, but in reality, we had no choice other
// than doing this. Considering the very long release cycle of Libtool,
// it is not easy to improve it to recognize LLD as a GNU compatible
// linker in a timely manner. Even if we can make it, there are still a
// lot of "configure" scripts out there that are generated by old version
// of Libtool. We cannot convince every software developer to migrate to
// the latest version and re-generate scripts. So we have this hack.
if (Args.hasArg(OPT_v) || Args.hasArg(OPT_version))
outs() << getLLDVersion() << " (compatible with GNU linkers)\n";
// ld.bfd always exits after printing out the version string.
// ld.gold proceeds if a given option is -v. Because gold's behavior
// is more permissive than ld.bfd, we chose what gold does here.
if (Args.hasArg(OPT_version))
return;
Config->ExitEarly = CanExitEarly && !Args.hasArg(OPT_full_shutdown);
if (const char *Path = getReproduceOption(Args)) {
// Note that --reproduce is a debug option so you can ignore it
// if you are trying to understand the whole picture of the code.
Expected<std::unique_ptr<TarWriter>> ErrOrWriter =
TarWriter::create(Path, path::stem(Path));
if (ErrOrWriter) {
Tar = ErrOrWriter->get();
Tar->append("response.txt", createResponseFile(Args));
Tar->append("version.txt", getLLDVersion() + "\n");
make<std::unique_ptr<TarWriter>>(std::move(*ErrOrWriter));
} else {
error(Twine("--reproduce: failed to open ") + Path + ": " +
toString(ErrOrWriter.takeError()));
}
}
readConfigs(Args);
initLLVM(Args);
createFiles(Args);
inferMachineType();
checkOptions(Args);
if (ErrorCount)
return;
switch (Config->EKind) {
case ELF32LEKind:
link<ELF32LE>(Args);
return;
case ELF32BEKind:
link<ELF32BE>(Args);
return;
case ELF64LEKind:
link<ELF64LE>(Args);
return;
case ELF64BEKind:
link<ELF64BE>(Args);
return;
default:
llvm_unreachable("unknown Config->EKind");
}
}
static UnresolvedPolicy getUnresolvedSymbolOption(opt::InputArgList &Args) {
if (Args.hasArg(OPT_noinhibit_exec))
return UnresolvedPolicy::Warn;
if (Args.hasArg(OPT_no_undefined) || hasZOption(Args, "defs"))
return UnresolvedPolicy::NoUndef;
if (Config->Relocatable)
return UnresolvedPolicy::Ignore;
if (auto *Arg = Args.getLastArg(OPT_unresolved_symbols)) {
StringRef S = Arg->getValue();
if (S == "ignore-all" || S == "ignore-in-object-files")
return UnresolvedPolicy::Ignore;
if (S == "ignore-in-shared-libs" || S == "report-all")
return UnresolvedPolicy::ReportError;
error("unknown --unresolved-symbols value: " + S);
}
return UnresolvedPolicy::ReportError;
}
static Target2Policy getTarget2Option(opt::InputArgList &Args) {
if (auto *Arg = Args.getLastArg(OPT_target2)) {
StringRef S = Arg->getValue();
if (S == "rel")
return Target2Policy::Rel;
if (S == "abs")
return Target2Policy::Abs;
if (S == "got-rel")
return Target2Policy::GotRel;
error("unknown --target2 option: " + S);
}
return Target2Policy::GotRel;
}
static bool isOutputFormatBinary(opt::InputArgList &Args) {
if (auto *Arg = Args.getLastArg(OPT_oformat)) {
StringRef S = Arg->getValue();
if (S == "binary")
return true;
error("unknown --oformat value: " + S);
}
return false;
}
static bool getArg(opt::InputArgList &Args, unsigned K1, unsigned K2,
bool Default) {
if (auto *Arg = Args.getLastArg(K1, K2))
return Arg->getOption().getID() == K1;
return Default;
}
static DiscardPolicy getDiscardOption(opt::InputArgList &Args) {
if (Config->Relocatable)
return DiscardPolicy::None;
auto *Arg =
Args.getLastArg(OPT_discard_all, OPT_discard_locals, OPT_discard_none);
if (!Arg)
return DiscardPolicy::Default;
if (Arg->getOption().getID() == OPT_discard_all)
return DiscardPolicy::All;
if (Arg->getOption().getID() == OPT_discard_locals)
return DiscardPolicy::Locals;
return DiscardPolicy::None;
}
static StripPolicy getStripOption(opt::InputArgList &Args) {
if (auto *Arg = Args.getLastArg(OPT_strip_all, OPT_strip_debug)) {
if (Arg->getOption().getID() == OPT_strip_all)
return StripPolicy::All;
return StripPolicy::Debug;
}
return StripPolicy::None;
}
static uint64_t parseSectionAddress(StringRef S, opt::Arg *Arg) {
uint64_t VA = 0;
if (S.startswith("0x"))
S = S.drop_front(2);
if (S.getAsInteger(16, VA))
error("invalid argument: " + toString(Arg));
return VA;
}
static StringMap<uint64_t> getSectionStartMap(opt::InputArgList &Args) {
StringMap<uint64_t> Ret;
for (auto *Arg : Args.filtered(OPT_section_start)) {
StringRef Name;
StringRef Addr;
std::tie(Name, Addr) = StringRef(Arg->getValue()).split('=');
Ret[Name] = parseSectionAddress(Addr, Arg);
}
if (auto *Arg = Args.getLastArg(OPT_Ttext))
Ret[".text"] = parseSectionAddress(Arg->getValue(), Arg);
if (auto *Arg = Args.getLastArg(OPT_Tdata))
Ret[".data"] = parseSectionAddress(Arg->getValue(), Arg);
if (auto *Arg = Args.getLastArg(OPT_Tbss))
Ret[".bss"] = parseSectionAddress(Arg->getValue(), Arg);
return Ret;
}
static SortSectionPolicy getSortKind(opt::InputArgList &Args) {
StringRef S = getString(Args, OPT_sort_section);
if (S == "alignment")
return SortSectionPolicy::Alignment;
if (S == "name")
return SortSectionPolicy::Name;
if (!S.empty())
error("unknown --sort-section rule: " + S);
return SortSectionPolicy::Default;
}
static std::vector<StringRef> getLines(MemoryBufferRef MB) {
SmallVector<StringRef, 0> Arr;
MB.getBuffer().split(Arr, '\n');
std::vector<StringRef> Ret;
for (StringRef S : Arr) {
S = S.trim();
if (!S.empty())
Ret.push_back(S);
}
return Ret;
}
// Initializes Config members by the command line options.
void LinkerDriver::readConfigs(opt::InputArgList &Args) {
for (auto *Arg : Args.filtered(OPT_L))
Config->SearchPaths.push_back(Arg->getValue());
std::vector<StringRef> RPaths;
for (auto *Arg : Args.filtered(OPT_rpath))
RPaths.push_back(Arg->getValue());
if (!RPaths.empty())
Config->RPath = llvm::join(RPaths.begin(), RPaths.end(), ":");
if (auto *Arg = Args.getLastArg(OPT_m)) {
// Parse ELF{32,64}{LE,BE} and CPU type.
StringRef S = Arg->getValue();
std::tie(Config->EKind, Config->EMachine, Config->OSABI) =
parseEmulation(S);
Config->MipsN32Abi = (S == "elf32btsmipn32" || S == "elf32ltsmipn32");
Config->Emulation = S;
}
Config->AllowMultipleDefinition = Args.hasArg(OPT_allow_multiple_definition);
Config->Bsymbolic = Args.hasArg(OPT_Bsymbolic);
Config->BsymbolicFunctions = Args.hasArg(OPT_Bsymbolic_functions);
Config->Demangle = getArg(Args, OPT_demangle, OPT_no_demangle, true);
Config->DisableVerify = Args.hasArg(OPT_disable_verify);
Config->EhFrameHdr = Args.hasArg(OPT_eh_frame_hdr);
Config->EnableNewDtags = !Args.hasArg(OPT_disable_new_dtags);
Config->ExportDynamic = Args.hasArg(OPT_export_dynamic);
Config->FatalWarnings = Args.hasArg(OPT_fatal_warnings);
Config->GcSections = getArg(Args, OPT_gc_sections, OPT_no_gc_sections, false);
Config->GdbIndex = Args.hasArg(OPT_gdb_index);
Config->ICF = Args.hasArg(OPT_icf);
Config->NoGnuUnique = Args.hasArg(OPT_no_gnu_unique);
Config->NoUndefinedVersion = Args.hasArg(OPT_no_undefined_version);
Config->Nostdlib = Args.hasArg(OPT_nostdlib);
Config->OMagic = Args.hasArg(OPT_omagic);
Config->Pie = getArg(Args, OPT_pie, OPT_nopie, false);
Config->PrintGcSections = Args.hasArg(OPT_print_gc_sections);
Config->Relocatable = Args.hasArg(OPT_relocatable);
Config->DefineCommon = getArg(Args, OPT_define_common, OPT_no_define_common,
!Config->Relocatable);
Config->Discard = getDiscardOption(Args);
Config->SaveTemps = Args.hasArg(OPT_save_temps);
Config->SingleRoRx = Args.hasArg(OPT_no_rosegment);
Config->Shared = Args.hasArg(OPT_shared);
Config->Target1Rel = getArg(Args, OPT_target1_rel, OPT_target1_abs, false);
Config->Threads = getArg(Args, OPT_threads, OPT_no_threads, true);
Config->Trace = Args.hasArg(OPT_trace);
Config->Verbose = Args.hasArg(OPT_verbose);
Config->WarnCommon = Args.hasArg(OPT_warn_common);
Config->DynamicLinker = getString(Args, OPT_dynamic_linker);
Config->Entry = getString(Args, OPT_entry);
Config->Fini = getString(Args, OPT_fini, "_fini");
Config->Init = getString(Args, OPT_init, "_init");
Config->LTOAAPipeline = getString(Args, OPT_lto_aa_pipeline);
Config->LTONewPmPasses = getString(Args, OPT_lto_newpm_passes);
Config->OutputFile = getString(Args, OPT_o);
Config->SoName = getString(Args, OPT_soname);
Config->Sysroot = getString(Args, OPT_sysroot);
Config->Optimize = getInteger(Args, OPT_O, 1);
Config->LTOO = getInteger(Args, OPT_lto_O, 2);
if (Config->LTOO > 3)
error("invalid optimization level for LTO: " + getString(Args, OPT_lto_O));
Config->LTOPartitions = getInteger(Args, OPT_lto_partitions, 1);
if (Config->LTOPartitions == 0)
error("--lto-partitions: number of threads must be > 0");
Config->ThinLTOJobs = getInteger(Args, OPT_thinlto_jobs, -1u);
if (Config->ThinLTOJobs == 0)
error("--thinlto-jobs: number of threads must be > 0");
Config->ZCombreloc = !hasZOption(Args, "nocombreloc");
Config->ZExecstack = hasZOption(Args, "execstack");
Config->ZNodelete = hasZOption(Args, "nodelete");
Config->ZNow = hasZOption(Args, "now");
Config->ZOrigin = hasZOption(Args, "origin");
Config->ZRelro = !hasZOption(Args, "norelro");
Config->ZStackSize = getZOptionValue(Args, "stack-size", -1);
Config->ZWxneeded = hasZOption(Args, "wxneeded");
Config->OFormatBinary = isOutputFormatBinary(Args);
Config->SectionStartMap = getSectionStartMap(Args);
Config->SortSection = getSortKind(Args);
Config->Target2 = getTarget2Option(Args);
Config->UnresolvedSymbols = getUnresolvedSymbolOption(Args);
// --omagic is an option to create old-fashioned executables in which
// .text segments are writable. Today, the option is still in use to
// create special-purpose programs such as boot loaders. It doesn't
// make sense to create PT_GNU_RELRO for such executables.
if (Config->OMagic)
Config->ZRelro = false;
if (!Config->Relocatable)
Config->Strip = getStripOption(Args);
// Config->Pic is true if we are generating position-independent code.
Config->Pic = Config->Pie || Config->Shared;
if (auto *Arg = Args.getLastArg(OPT_hash_style)) {
StringRef S = Arg->getValue();
if (S == "gnu") {
Config->GnuHash = true;
Config->SysvHash = false;
} else if (S == "both") {
Config->GnuHash = true;
} else if (S != "sysv")
error("unknown hash style: " + S);
}
// Parse --build-id or --build-id=<style>.
if (Args.hasArg(OPT_build_id))
Config->BuildId = BuildIdKind::Fast;
if (auto *Arg = Args.getLastArg(OPT_build_id_eq)) {
StringRef S = Arg->getValue();
if (S == "md5") {
Config->BuildId = BuildIdKind::Md5;
} else if (S == "sha1" || S == "tree") {
Config->BuildId = BuildIdKind::Sha1;
} else if (S == "uuid") {
Config->BuildId = BuildIdKind::Uuid;
} else if (S == "none") {
Config->BuildId = BuildIdKind::None;
} else if (S.startswith("0x")) {
Config->BuildId = BuildIdKind::Hexstring;
Config->BuildIdVector = parseHex(S.substr(2));
} else {
error("unknown --build-id style: " + S);
}
}
for (auto *Arg : Args.filtered(OPT_auxiliary))
Config->AuxiliaryList.push_back(Arg->getValue());
if (!Config->Shared && !Config->AuxiliaryList.empty())
error("-f may not be used without -shared");
for (auto *Arg : Args.filtered(OPT_undefined))
Config->Undefined.push_back(Arg->getValue());
if (auto *Arg = Args.getLastArg(OPT_dynamic_list))
if (Optional<MemoryBufferRef> Buffer = readFile(Arg->getValue()))
readDynamicList(*Buffer);
if (auto *Arg = Args.getLastArg(OPT_symbol_ordering_file))
if (Optional<MemoryBufferRef> Buffer = readFile(Arg->getValue()))
Config->SymbolOrderingFile = getLines(*Buffer);
// If --retain-symbol-file is used, we'll retail only the symbols listed in
// the file and discard all others.
if (auto *Arg = Args.getLastArg(OPT_retain_symbols_file)) {
Config->Discard = DiscardPolicy::RetainFile;
if (Optional<MemoryBufferRef> Buffer = readFile(Arg->getValue()))
for (StringRef S : getLines(*Buffer))
Config->RetainSymbolsFile.insert(S);
}
for (auto *Arg : Args.filtered(OPT_export_dynamic_symbol))
Config->VersionScriptGlobals.push_back(
{Arg->getValue(), /*IsExternCpp*/ false, /*HasWildcard*/ false});
// Dynamic lists are a simplified linker script that doesn't need the
// "global:" and implicitly ends with a "local:*". Set the variables needed to
// simulate that.
if (Args.hasArg(OPT_dynamic_list) || Args.hasArg(OPT_export_dynamic_symbol)) {
Config->ExportDynamic = true;
if (!Config->Shared)
Config->DefaultSymbolVersion = VER_NDX_LOCAL;
}
if (auto *Arg = Args.getLastArg(OPT_version_script))
if (Optional<MemoryBufferRef> Buffer = readFile(Arg->getValue()))
readVersionScript(*Buffer);
}
// Returns a value of "-format" option.
static bool getBinaryOption(StringRef S) {
if (S == "binary")
return true;
if (S == "elf" || S == "default")
return false;
error("unknown -format value: " + S +
" (supported formats: elf, default, binary)");
return false;
}
void LinkerDriver::createFiles(opt::InputArgList &Args) {
for (auto *Arg : Args) {
switch (Arg->getOption().getID()) {
case OPT_l:
addLibrary(Arg->getValue());
break;
case OPT_INPUT:
addFile(Arg->getValue());
break;
case OPT_alias_script_T:
case OPT_script:
if (Optional<MemoryBufferRef> MB = readFile(Arg->getValue()))
readLinkerScript(*MB);
break;
case OPT_as_needed:
Config->AsNeeded = true;
break;
case OPT_format:
InBinary = getBinaryOption(Arg->getValue());
break;
case OPT_no_as_needed:
Config->AsNeeded = false;
break;
case OPT_Bstatic:
Config->Static = true;
break;
case OPT_Bdynamic:
Config->Static = false;
break;
case OPT_whole_archive:
InWholeArchive = true;
break;
case OPT_no_whole_archive:
InWholeArchive = false;
break;
case OPT_start_lib:
InLib = true;
break;
case OPT_end_lib:
InLib = false;
break;
}
}
if (Files.empty() && ErrorCount == 0)
error("no input files");
}
// If -m <machine_type> was not given, infer it from object files.
void LinkerDriver::inferMachineType() {
if (Config->EKind != ELFNoneKind)
return;
for (InputFile *F : Files) {
if (F->EKind == ELFNoneKind)
continue;
Config->EKind = F->EKind;
Config->EMachine = F->EMachine;
Config->OSABI = F->OSABI;
Config->MipsN32Abi = Config->EMachine == EM_MIPS && isMipsN32Abi(F);
return;
}
error("target emulation unknown: -m or at least one .o file required");
}
// Parse -z max-page-size=<value>. The default value is defined by
// each target.
static uint64_t getMaxPageSize(opt::InputArgList &Args) {
uint64_t Val =
getZOptionValue(Args, "max-page-size", Target->DefaultMaxPageSize);
if (!isPowerOf2_64(Val))
error("max-page-size: value isn't a power of 2");
return Val;
}
// Parses -image-base option.
static uint64_t getImageBase(opt::InputArgList &Args) {
// Use default if no -image-base option is given.
// Because we are using "Target" here, this function
// has to be called after the variable is initialized.
auto *Arg = Args.getLastArg(OPT_image_base);
if (!Arg)
return Config->Pic ? 0 : Target->DefaultImageBase;
StringRef S = Arg->getValue();
uint64_t V;
if (S.getAsInteger(0, V)) {
error("-image-base: number expected, but got " + S);
return 0;
}
if ((V % Config->MaxPageSize) != 0)
warn("-image-base: address isn't multiple of page size: " + S);
return V;
}
// Do actual linking. Note that when this function is called,
// all linker scripts have already been parsed.
template <class ELFT> void LinkerDriver::link(opt::InputArgList &Args) {
SymbolTable<ELFT> Symtab;
elf::Symtab<ELFT>::X = &Symtab;
Target = createTarget();
ScriptBase = Script<ELFT>::X = make<LinkerScript<ELFT>>();
Config->Rela =
ELFT::Is64Bits || Config->EMachine == EM_X86_64 || Config->MipsN32Abi;
Config->Mips64EL =
(Config->EMachine == EM_MIPS && Config->EKind == ELF64LEKind);
Config->MaxPageSize = getMaxPageSize(Args);
Config->ImageBase = getImageBase(Args);
// Default output filename is "a.out" by the Unix tradition.
if (Config->OutputFile.empty())
Config->OutputFile = "a.out";
// Use default entry point name if no name was given via the command
// line nor linker scripts. For some reason, MIPS entry point name is
// different from others.
Config->WarnMissingEntry =
(!Config->Entry.empty() || (!Config->Shared && !Config->Relocatable));
if (Config->Entry.empty() && !Config->Relocatable)
Config->Entry = (Config->EMachine == EM_MIPS) ? "__start" : "_start";
// Handle --trace-symbol.
for (auto *Arg : Args.filtered(OPT_trace_symbol))
Symtab.trace(Arg->getValue());
// Add all files to the symbol table. This will add almost all
// symbols that we need to the symbol table.
for (InputFile *F : Files)
Symtab.addFile(F);
// If an entry symbol is in a static archive, pull out that file now
// to complete the symbol table. After this, no new names except a
// few linker-synthesized ones will be added to the symbol table.
if (Symtab.find(Config->Entry))
Symtab.addUndefined(Config->Entry);
// Return if there were name resolution errors.
if (ErrorCount)
return;
Symtab.scanUndefinedFlags();
Symtab.scanShlibUndefined();
Symtab.scanVersionScript();
Symtab.addCombinedLTOObject();
if (ErrorCount)
return;
for (auto *Arg : Args.filtered(OPT_wrap))
Symtab.wrap(Arg->getValue());
// Now that we have a complete list of input files.
// Beyond this point, no new files are added.
// Aggregate all input sections into one place.
for (elf::ObjectFile<ELFT> *F : Symtab.getObjectFiles())
for (InputSectionBase<ELFT> *S : F->getSections())
if (S && S != &InputSection<ELFT>::Discarded)
Symtab.Sections.push_back(S);
for (BinaryFile *F : Symtab.getBinaryFiles())
for (InputSectionData *S : F->getSections())
Symtab.Sections.push_back(cast<InputSection<ELFT>>(S));
// Do size optimizations: garbage collection and identical code folding.
if (Config->GcSections)
markLive<ELFT>();
if (Config->ICF)
doIcf<ELFT>();
// MergeInputSection::splitIntoPieces needs to be called before
// any call of MergeInputSection::getOffset. Do that.
forEach(Symtab.Sections.begin(), Symtab.Sections.end(),
[](InputSectionBase<ELFT> *S) {
if (!S->Live)
return;
if (Decompressor::isCompressedELFSection(S->Flags, S->Name))
S->uncompress();
if (auto *MS = dyn_cast<MergeInputSection<ELFT>>(S))
MS->splitIntoPieces();
});
// Write the result to the file.
writeResult<ELFT>();
}