llvm-project/lld/COFF/Driver.cpp

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//===- Driver.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 "Driver.h"
#include "Config.h"
#include "DebugTypes.h"
#include "ICF.h"
#include "InputFiles.h"
#include "MarkLive.h"
#include "MinGW.h"
#include "SymbolTable.h"
#include "Symbols.h"
#include "Writer.h"
#include "lld/Common/Args.h"
#include "lld/Common/Driver.h"
#include "lld/Common/ErrorHandler.h"
#include "lld/Common/Filesystem.h"
#include "lld/Common/Memory.h"
#include "lld/Common/Threads.h"
#include "lld/Common/Timer.h"
#include "lld/Common/Version.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/BinaryFormat/Magic.h"
#include "llvm/Object/ArchiveWriter.h"
#include "llvm/Object/COFFImportFile.h"
#include "llvm/Object/COFFModuleDefinition.h"
#include "llvm/Object/WindowsMachineFlag.h"
#include "llvm/Option/Arg.h"
#include "llvm/Option/ArgList.h"
#include "llvm/Option/Option.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/LEB128.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/Process.h"
#include "llvm/Support/TarWriter.h"
#include "llvm/Support/TargetSelect.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/ToolDrivers/llvm-lib/LibDriver.h"
#include <algorithm>
#include <future>
#include <memory>
using namespace llvm;
using namespace llvm::object;
using namespace llvm::COFF;
using llvm::sys::Process;
namespace lld {
namespace coff {
static Timer inputFileTimer("Input File Reading", Timer::root());
Configuration *config;
LinkerDriver *driver;
bool link(ArrayRef<const char *> args, bool canExitEarly, raw_ostream &diag) {
errorHandler().logName = args::getFilenameWithoutExe(args[0]);
errorHandler().errorOS = &diag;
errorHandler().colorDiagnostics = diag.has_colors();
errorHandler().errorLimitExceededMsg =
"too many errors emitted, stopping now"
" (use /errorlimit:0 to see all errors)";
errorHandler().exitEarly = canExitEarly;
config = make<Configuration>();
symtab = make<SymbolTable>();
driver = make<LinkerDriver>();
driver->link(args);
// Call exit() if we can to avoid calling destructors.
if (canExitEarly)
exitLld(errorCount() ? 1 : 0);
freeArena();
ObjFile::instances.clear();
ImportFile::instances.clear();
BitcodeFile::instances.clear();
memset(MergeChunk::instances, 0, sizeof(MergeChunk::instances));
return !errorCount();
}
// Parse options of the form "old;new".
static std::pair<StringRef, StringRef> getOldNewOptions(opt::InputArgList &args,
unsigned id) {
auto *arg = args.getLastArg(id);
if (!arg)
return {"", ""};
StringRef s = arg->getValue();
std::pair<StringRef, StringRef> ret = s.split(';');
if (ret.second.empty())
error(arg->getSpelling() + " expects 'old;new' format, but got " + s);
return ret;
}
// Drop directory components and replace extension with ".exe" or ".dll".
static std::string getOutputPath(StringRef path) {
auto p = path.find_last_of("\\/");
StringRef s = (p == StringRef::npos) ? path : path.substr(p + 1);
const char* e = config->dll ? ".dll" : ".exe";
return (s.substr(0, s.rfind('.')) + e).str();
}
// Returns true if S matches /crtend.?\.o$/.
static bool isCrtend(StringRef s) {
if (!s.endswith(".o"))
return false;
s = s.drop_back(2);
if (s.endswith("crtend"))
return true;
return !s.empty() && s.drop_back().endswith("crtend");
}
// ErrorOr is not default constructible, so it cannot be used as the type
// parameter of a future.
// FIXME: We could open the file in createFutureForFile and avoid needing to
// return an error here, but for the moment that would cost us a file descriptor
// (a limited resource on Windows) for the duration that the future is pending.
using MBErrPair = std::pair<std::unique_ptr<MemoryBuffer>, std::error_code>;
// Create a std::future that opens and maps a file using the best strategy for
// the host platform.
static std::future<MBErrPair> createFutureForFile(std::string path) {
#if _WIN32
// On Windows, file I/O is relatively slow so it is best to do this
// asynchronously.
auto strategy = std::launch::async;
#else
auto strategy = std::launch::deferred;
#endif
return std::async(strategy, [=]() {
auto mbOrErr = MemoryBuffer::getFile(path,
/*FileSize*/ -1,
/*RequiresNullTerminator*/ false);
if (!mbOrErr)
return MBErrPair{nullptr, mbOrErr.getError()};
return MBErrPair{std::move(*mbOrErr), std::error_code()};
});
}
// Symbol names are mangled by prepending "_" on x86.
static StringRef mangle(StringRef sym) {
assert(config->machine != IMAGE_FILE_MACHINE_UNKNOWN);
if (config->machine == I386)
return saver.save("_" + sym);
return sym;
}
static bool findUnderscoreMangle(StringRef sym) {
Symbol *s = symtab->findMangle(mangle(sym));
return s && !isa<Undefined>(s);
}
MemoryBufferRef LinkerDriver::takeBuffer(std::unique_ptr<MemoryBuffer> mb) {
MemoryBufferRef mbref = *mb;
make<std::unique_ptr<MemoryBuffer>>(std::move(mb)); // take ownership
if (driver->tar)
driver->tar->append(relativeToRoot(mbref.getBufferIdentifier()),
mbref.getBuffer());
return mbref;
}
void LinkerDriver::addBuffer(std::unique_ptr<MemoryBuffer> mb,
bool wholeArchive) {
StringRef filename = mb->getBufferIdentifier();
MemoryBufferRef mbref = takeBuffer(std::move(mb));
filePaths.push_back(filename);
// File type is detected by contents, not by file extension.
switch (identify_magic(mbref.getBuffer())) {
case file_magic::windows_resource:
resources.push_back(mbref);
break;
case file_magic::archive:
if (wholeArchive) {
std::unique_ptr<Archive> file =
CHECK(Archive::create(mbref), filename + ": failed to parse archive");
for (MemoryBufferRef m : getArchiveMembers(file.get()))
addArchiveBuffer(m, "<whole-archive>", filename, 0);
return;
}
symtab->addFile(make<ArchiveFile>(mbref));
break;
case file_magic::bitcode:
symtab->addFile(make<BitcodeFile>(mbref, "", 0));
break;
case file_magic::coff_object:
case file_magic::coff_import_library:
symtab->addFile(make<ObjFile>(mbref));
break;
case file_magic::pdb:
loadTypeServerSource(mbref);
break;
case file_magic::coff_cl_gl_object:
error(filename + ": is not a native COFF file. Recompile without /GL");
break;
case file_magic::pecoff_executable:
if (filename.endswith_lower(".dll")) {
error(filename + ": bad file type. Did you specify a DLL instead of an "
"import library?");
break;
}
LLVM_FALLTHROUGH;
default:
error(mbref.getBufferIdentifier() + ": unknown file type");
break;
}
}
void LinkerDriver::enqueuePath(StringRef path, bool wholeArchive) {
auto future =
std::make_shared<std::future<MBErrPair>>(createFutureForFile(path));
std::string pathStr = path;
enqueueTask([=]() {
auto mbOrErr = future->get();
if (mbOrErr.second) {
std::string msg =
"could not open '" + pathStr + "': " + mbOrErr.second.message();
// Check if the filename is a typo for an option flag. OptTable thinks
// that all args that are not known options and that start with / are
// filenames, but e.g. `/nodefaultlibs` is more likely a typo for
// the option `/nodefaultlib` than a reference to a file in the root
// directory.
std::string nearest;
if (COFFOptTable().findNearest(pathStr, nearest) > 1)
error(msg);
else
error(msg + "; did you mean '" + nearest + "'");
} else
driver->addBuffer(std::move(mbOrErr.first), wholeArchive);
});
}
void LinkerDriver::addArchiveBuffer(MemoryBufferRef mb, StringRef symName,
StringRef parentName,
uint64_t offsetInArchive) {
file_magic magic = identify_magic(mb.getBuffer());
if (magic == file_magic::coff_import_library) {
InputFile *imp = make<ImportFile>(mb);
imp->parentName = parentName;
symtab->addFile(imp);
return;
}
InputFile *obj;
if (magic == file_magic::coff_object) {
obj = make<ObjFile>(mb);
} else if (magic == file_magic::bitcode) {
obj = make<BitcodeFile>(mb, parentName, offsetInArchive);
} else {
error("unknown file type: " + mb.getBufferIdentifier());
return;
}
obj->parentName = parentName;
symtab->addFile(obj);
log("Loaded " + toString(obj) + " for " + symName);
}
void LinkerDriver::enqueueArchiveMember(const Archive::Child &c,
const Archive::Symbol &sym,
StringRef parentName) {
auto reportBufferError = [=](Error &&e, StringRef childName) {
fatal("could not get the buffer for the member defining symbol " +
toCOFFString(sym) + ": " + parentName + "(" + childName + "): " +
toString(std::move(e)));
};
if (!c.getParent()->isThin()) {
uint64_t offsetInArchive = c.getChildOffset();
Expected<MemoryBufferRef> mbOrErr = c.getMemoryBufferRef();
if (!mbOrErr)
reportBufferError(mbOrErr.takeError(), check(c.getFullName()));
MemoryBufferRef mb = mbOrErr.get();
enqueueTask([=]() {
driver->addArchiveBuffer(mb, toCOFFString(sym), parentName,
offsetInArchive);
});
return;
}
std::string childName = CHECK(
c.getFullName(),
"could not get the filename for the member defining symbol " +
toCOFFString(sym));
auto future = std::make_shared<std::future<MBErrPair>>(
createFutureForFile(childName));
enqueueTask([=]() {
auto mbOrErr = future->get();
if (mbOrErr.second)
reportBufferError(errorCodeToError(mbOrErr.second), childName);
driver->addArchiveBuffer(takeBuffer(std::move(mbOrErr.first)),
toCOFFString(sym), parentName,
/*OffsetInArchive=*/0);
});
}
static bool isDecorated(StringRef sym) {
return sym.startswith("@") || sym.contains("@@") || sym.startswith("?") ||
(!config->mingw && sym.contains('@'));
COFF: Improve dllexported name mangling compatibility. The rules for dllexported symbols are overly complicated due to x86 name decoration, fuzzy symbol resolution, and the fact that one symbol can be resolved by so many different names. The rules are probably intended to be "intuitive", so that users don't have to understand the name mangling schemes, but it seems that it can lead to unintended symbol exports. To make it clear what I'm trying to do with this patch, let me write how the export rules are subtle and complicated. - x86 name decoration: If machine type is i386 and export name is given by a command line option, like /export:foo, the real symbol name the linker has to search for is _foo because all symbols are decorated with "_" prefixes. This doesn't happen on non-x86 machines. This automatic name decoration happens only when the name is not C++ mangled. However, the symbol name exported from DLLs are ones without "_" on all platforms. Moreover, if the option is given via .drectve section, no symbol decoration is done (the reason being that the .drectve section is created by a compiler and the compiler should always know the exact name of the symbol, I guess). - Fuzzy symbol resolution: In addition to x86 name decoration, the linker has to look for cdecl or C++ mangled symbols for a given /export. For example, it searches for not only _foo but also _foo@<number> or ??foo@... for /export:foo. Previous implementation didn't get it right. I'm trying to make it as compatible with MSVC linker as possible with this patch however the rules are. The new code looks a bit messy to me, but I don't think it can be simpler due to the ad-hoc-ness of the rules. llvm-svn: 246424
2015-08-31 16:43:21 +08:00
}
// Parses .drectve section contents and returns a list of files
// specified by /defaultlib.
void LinkerDriver::parseDirectives(InputFile *file) {
StringRef s = file->getDirectives();
if (s.empty())
return;
log("Directives: " + toString(file) + ": " + s);
ArgParser parser;
// .drectve is always tokenized using Windows shell rules.
// /EXPORT: option can appear too many times, processing in fastpath.
opt::InputArgList args;
std::vector<StringRef> exports;
std::tie(args, exports) = parser.parseDirectives(s);
for (StringRef e : exports) {
// If a common header file contains dllexported function
// declarations, many object files may end up with having the
// same /EXPORT options. In order to save cost of parsing them,
// we dedup them first.
if (!directivesExports.insert(e).second)
continue;
Export exp = parseExport(e);
if (config->machine == I386 && config->mingw) {
if (!isDecorated(exp.name))
exp.name = saver.save("_" + exp.name);
if (!exp.extName.empty() && !isDecorated(exp.extName))
exp.extName = saver.save("_" + exp.extName);
}
exp.directives = true;
config->exports.push_back(exp);
}
for (auto *arg : args) {
switch (arg->getOption().getID()) {
case OPT_aligncomm:
parseAligncomm(arg->getValue());
break;
case OPT_alternatename:
parseAlternateName(arg->getValue());
break;
case OPT_defaultlib:
if (Optional<StringRef> path = findLib(arg->getValue()))
enqueuePath(*path, false);
break;
case OPT_entry:
config->entry = addUndefined(mangle(arg->getValue()));
break;
case OPT_failifmismatch:
checkFailIfMismatch(arg->getValue(), file);
break;
case OPT_incl:
addUndefined(arg->getValue());
break;
case OPT_merge:
parseMerge(arg->getValue());
break;
case OPT_nodefaultlib:
config->noDefaultLibs.insert(doFindLib(arg->getValue()).lower());
break;
case OPT_section:
parseSection(arg->getValue());
break;
case OPT_subsystem:
parseSubsystem(arg->getValue(), &config->subsystem,
&config->majorOSVersion, &config->minorOSVersion);
break;
// Only add flags here that link.exe accepts in
// `#pragma comment(linker, "/flag")`-generated sections.
case OPT_editandcontinue:
case OPT_guardsym:
case OPT_throwingnew:
break;
default:
error(arg->getSpelling() + " is not allowed in .drectve");
}
}
}
// Find file from search paths. You can omit ".obj", this function takes
// care of that. Note that the returned path is not guaranteed to exist.
StringRef LinkerDriver::doFindFile(StringRef filename) {
bool hasPathSep = (filename.find_first_of("/\\") != StringRef::npos);
if (hasPathSep)
return filename;
bool hasExt = filename.contains('.');
for (StringRef dir : searchPaths) {
SmallString<128> path = dir;
sys::path::append(path, filename);
if (sys::fs::exists(path.str()))
return saver.save(path.str());
if (!hasExt) {
path.append(".obj");
if (sys::fs::exists(path.str()))
return saver.save(path.str());
}
}
return filename;
}
static Optional<sys::fs::UniqueID> getUniqueID(StringRef path) {
sys::fs::UniqueID ret;
if (sys::fs::getUniqueID(path, ret))
return None;
return ret;
}
// Resolves a file path. This never returns the same path
// (in that case, it returns None).
Optional<StringRef> LinkerDriver::findFile(StringRef filename) {
StringRef path = doFindFile(filename);
if (Optional<sys::fs::UniqueID> id = getUniqueID(path)) {
bool seen = !visitedFiles.insert(*id).second;
if (seen)
return None;
}
if (path.endswith_lower(".lib"))
visitedLibs.insert(sys::path::filename(path));
return path;
}
// MinGW specific. If an embedded directive specified to link to
// foo.lib, but it isn't found, try libfoo.a instead.
StringRef LinkerDriver::doFindLibMinGW(StringRef filename) {
if (filename.contains('/') || filename.contains('\\'))
return filename;
SmallString<128> s = filename;
sys::path::replace_extension(s, ".a");
StringRef libName = saver.save("lib" + s.str());
return doFindFile(libName);
}
// Find library file from search path.
StringRef LinkerDriver::doFindLib(StringRef filename) {
// Add ".lib" to Filename if that has no file extension.
bool hasExt = filename.contains('.');
if (!hasExt)
filename = saver.save(filename + ".lib");
StringRef ret = doFindFile(filename);
// For MinGW, if the find above didn't turn up anything, try
// looking for a MinGW formatted library name.
if (config->mingw && ret == filename)
return doFindLibMinGW(filename);
return ret;
}
// Resolves a library path. /nodefaultlib options are taken into
// consideration. This never returns the same path (in that case,
// it returns None).
Optional<StringRef> LinkerDriver::findLib(StringRef filename) {
if (config->noDefaultLibAll)
return None;
if (!visitedLibs.insert(filename.lower()).second)
return None;
StringRef path = doFindLib(filename);
if (config->noDefaultLibs.count(path.lower()))
return None;
if (Optional<sys::fs::UniqueID> id = getUniqueID(path))
if (!visitedFiles.insert(*id).second)
return None;
return path;
}
// Parses LIB environment which contains a list of search paths.
void LinkerDriver::addLibSearchPaths() {
Optional<std::string> envOpt = Process::GetEnv("LIB");
if (!envOpt.hasValue())
return;
StringRef env = saver.save(*envOpt);
while (!env.empty()) {
StringRef path;
std::tie(path, env) = env.split(';');
searchPaths.push_back(path);
}
}
Symbol *LinkerDriver::addUndefined(StringRef name) {
Symbol *b = symtab->addUndefined(name);
if (!b->isGCRoot) {
b->isGCRoot = true;
config->gcroot.push_back(b);
}
return b;
}
StringRef LinkerDriver::mangleMaybe(Symbol *s) {
[COFF] Fix /export:foo=bar when bar is a weak alias Summary: When handling exports from the command line or from .def files, the linker does a "fuzzy" string lookup to allow finding mangled symbols. However, when the symbol is re-exported under a new name, the linker has to transfer the decorations from the exported symbol over to the new name. This is implemented by taking the mangled symbol that was found in the object and replacing the original symbol name with the export name. Before this patch, LLD implemented the fuzzy search by adding an undefined symbol with the unmangled name, and then during symbol resolution, checking if similar mangled symbols had been added after the last round of symbol resolution. If so, LLD makes the original symbol a weak alias of the mangled symbol. Later, to get the original symbol name, LLD would look through the weak alias and forward it on to the import library writer, which copies the symbol decorations. This approach doesn't work when bar is itself a weak alias, as is the case in asan. It's especially bad when the aliasee of bar contains the string "bar", consider "bar_default". In this case, we would end up exporting the symbol "foo_default" when we should've exported just "foo". To fix this, don't look through weak aliases to find the mangled name. Save the mangled name earlier during fuzzy symbol lookup. Fixes PR42074 Reviewers: mstorsjo, ruiu Subscribers: thakis, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D62984 llvm-svn: 362849
2019-06-08 06:05:12 +08:00
// If the plain symbol name has already been resolved, do nothing.
Undefined *unmangled = dyn_cast<Undefined>(s);
if (!unmangled)
[COFF] Fix /export:foo=bar when bar is a weak alias Summary: When handling exports from the command line or from .def files, the linker does a "fuzzy" string lookup to allow finding mangled symbols. However, when the symbol is re-exported under a new name, the linker has to transfer the decorations from the exported symbol over to the new name. This is implemented by taking the mangled symbol that was found in the object and replacing the original symbol name with the export name. Before this patch, LLD implemented the fuzzy search by adding an undefined symbol with the unmangled name, and then during symbol resolution, checking if similar mangled symbols had been added after the last round of symbol resolution. If so, LLD makes the original symbol a weak alias of the mangled symbol. Later, to get the original symbol name, LLD would look through the weak alias and forward it on to the import library writer, which copies the symbol decorations. This approach doesn't work when bar is itself a weak alias, as is the case in asan. It's especially bad when the aliasee of bar contains the string "bar", consider "bar_default". In this case, we would end up exporting the symbol "foo_default" when we should've exported just "foo". To fix this, don't look through weak aliases to find the mangled name. Save the mangled name earlier during fuzzy symbol lookup. Fixes PR42074 Reviewers: mstorsjo, ruiu Subscribers: thakis, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D62984 llvm-svn: 362849
2019-06-08 06:05:12 +08:00
return "";
// Otherwise, see if a similar, mangled symbol exists in the symbol table.
Symbol *mangled = symtab->findMangle(unmangled->getName());
if (!mangled)
[COFF] Fix /export:foo=bar when bar is a weak alias Summary: When handling exports from the command line or from .def files, the linker does a "fuzzy" string lookup to allow finding mangled symbols. However, when the symbol is re-exported under a new name, the linker has to transfer the decorations from the exported symbol over to the new name. This is implemented by taking the mangled symbol that was found in the object and replacing the original symbol name with the export name. Before this patch, LLD implemented the fuzzy search by adding an undefined symbol with the unmangled name, and then during symbol resolution, checking if similar mangled symbols had been added after the last round of symbol resolution. If so, LLD makes the original symbol a weak alias of the mangled symbol. Later, to get the original symbol name, LLD would look through the weak alias and forward it on to the import library writer, which copies the symbol decorations. This approach doesn't work when bar is itself a weak alias, as is the case in asan. It's especially bad when the aliasee of bar contains the string "bar", consider "bar_default". In this case, we would end up exporting the symbol "foo_default" when we should've exported just "foo". To fix this, don't look through weak aliases to find the mangled name. Save the mangled name earlier during fuzzy symbol lookup. Fixes PR42074 Reviewers: mstorsjo, ruiu Subscribers: thakis, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D62984 llvm-svn: 362849
2019-06-08 06:05:12 +08:00
return "";
// If we find a similar mangled symbol, make this an alias to it and return
// its name.
log(unmangled->getName() + " aliased to " + mangled->getName());
unmangled->weakAlias = symtab->addUndefined(mangled->getName());
return mangled->getName();
[COFF] Fix /export:foo=bar when bar is a weak alias Summary: When handling exports from the command line or from .def files, the linker does a "fuzzy" string lookup to allow finding mangled symbols. However, when the symbol is re-exported under a new name, the linker has to transfer the decorations from the exported symbol over to the new name. This is implemented by taking the mangled symbol that was found in the object and replacing the original symbol name with the export name. Before this patch, LLD implemented the fuzzy search by adding an undefined symbol with the unmangled name, and then during symbol resolution, checking if similar mangled symbols had been added after the last round of symbol resolution. If so, LLD makes the original symbol a weak alias of the mangled symbol. Later, to get the original symbol name, LLD would look through the weak alias and forward it on to the import library writer, which copies the symbol decorations. This approach doesn't work when bar is itself a weak alias, as is the case in asan. It's especially bad when the aliasee of bar contains the string "bar", consider "bar_default". In this case, we would end up exporting the symbol "foo_default" when we should've exported just "foo". To fix this, don't look through weak aliases to find the mangled name. Save the mangled name earlier during fuzzy symbol lookup. Fixes PR42074 Reviewers: mstorsjo, ruiu Subscribers: thakis, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D62984 llvm-svn: 362849
2019-06-08 06:05:12 +08:00
}
// Windows specific -- find default entry point name.
//
// There are four different entry point functions for Windows executables,
// each of which corresponds to a user-defined "main" function. This function
// infers an entry point from a user-defined "main" function.
StringRef LinkerDriver::findDefaultEntry() {
assert(config->subsystem != IMAGE_SUBSYSTEM_UNKNOWN &&
"must handle /subsystem before calling this");
if (config->mingw)
return mangle(config->subsystem == IMAGE_SUBSYSTEM_WINDOWS_GUI
? "WinMainCRTStartup"
: "mainCRTStartup");
if (config->subsystem == IMAGE_SUBSYSTEM_WINDOWS_GUI) {
if (findUnderscoreMangle("wWinMain")) {
if (!findUnderscoreMangle("WinMain"))
return mangle("wWinMainCRTStartup");
warn("found both wWinMain and WinMain; using latter");
}
return mangle("WinMainCRTStartup");
}
if (findUnderscoreMangle("wmain")) {
if (!findUnderscoreMangle("main"))
return mangle("wmainCRTStartup");
warn("found both wmain and main; using latter");
}
return mangle("mainCRTStartup");
}
WindowsSubsystem LinkerDriver::inferSubsystem() {
if (config->dll)
return IMAGE_SUBSYSTEM_WINDOWS_GUI;
if (config->mingw)
return IMAGE_SUBSYSTEM_WINDOWS_CUI;
// Note that link.exe infers the subsystem from the presence of these
// functions even if /entry: or /nodefaultlib are passed which causes them
// to not be called.
bool haveMain = findUnderscoreMangle("main");
bool haveWMain = findUnderscoreMangle("wmain");
bool haveWinMain = findUnderscoreMangle("WinMain");
bool haveWWinMain = findUnderscoreMangle("wWinMain");
if (haveMain || haveWMain) {
if (haveWinMain || haveWWinMain) {
warn(std::string("found ") + (haveMain ? "main" : "wmain") + " and " +
(haveWinMain ? "WinMain" : "wWinMain") +
"; defaulting to /subsystem:console");
}
return IMAGE_SUBSYSTEM_WINDOWS_CUI;
}
if (haveWinMain || haveWWinMain)
return IMAGE_SUBSYSTEM_WINDOWS_GUI;
return IMAGE_SUBSYSTEM_UNKNOWN;
}
static uint64_t getDefaultImageBase() {
if (config->is64())
return config->dll ? 0x180000000 : 0x140000000;
return config->dll ? 0x10000000 : 0x400000;
}
static std::string createResponseFile(const opt::InputArgList &args,
ArrayRef<StringRef> filePaths,
ArrayRef<StringRef> searchPaths) {
SmallString<0> data;
raw_svector_ostream os(data);
for (auto *arg : args) {
switch (arg->getOption().getID()) {
case OPT_linkrepro:
case OPT_INPUT:
case OPT_defaultlib:
case OPT_libpath:
case OPT_manifest:
case OPT_manifest_colon:
case OPT_manifestdependency:
case OPT_manifestfile:
case OPT_manifestinput:
case OPT_manifestuac:
break;
case OPT_implib:
case OPT_pdb:
case OPT_out:
os << arg->getSpelling() << sys::path::filename(arg->getValue()) << "\n";
break;
default:
os << toString(*arg) << "\n";
}
}
for (StringRef path : searchPaths) {
std::string relPath = relativeToRoot(path);
os << "/libpath:" << quote(relPath) << "\n";
}
for (StringRef path : filePaths)
os << quote(relativeToRoot(path)) << "\n";
return data.str();
}
enum class DebugKind { Unknown, None, Full, FastLink, GHash, Dwarf, Symtab };
static DebugKind parseDebugKind(const opt::InputArgList &args) {
auto *a = args.getLastArg(OPT_debug, OPT_debug_opt);
if (!a)
return DebugKind::None;
if (a->getNumValues() == 0)
return DebugKind::Full;
DebugKind debug = StringSwitch<DebugKind>(a->getValue())
.CaseLower("none", DebugKind::None)
.CaseLower("full", DebugKind::Full)
.CaseLower("fastlink", DebugKind::FastLink)
// LLD extensions
.CaseLower("ghash", DebugKind::GHash)
.CaseLower("dwarf", DebugKind::Dwarf)
.CaseLower("symtab", DebugKind::Symtab)
.Default(DebugKind::Unknown);
if (debug == DebugKind::FastLink) {
warn("/debug:fastlink unsupported; using /debug:full");
return DebugKind::Full;
}
if (debug == DebugKind::Unknown) {
error("/debug: unknown option: " + Twine(a->getValue()));
return DebugKind::None;
}
return debug;
}
static unsigned parseDebugTypes(const opt::InputArgList &args) {
unsigned debugTypes = static_cast<unsigned>(DebugType::None);
if (auto *a = args.getLastArg(OPT_debugtype)) {
SmallVector<StringRef, 3> types;
StringRef(a->getValue())
.split(types, ',', /*MaxSplit=*/-1, /*KeepEmpty=*/false);
for (StringRef type : types) {
unsigned v = StringSwitch<unsigned>(type.lower())
.Case("cv", static_cast<unsigned>(DebugType::CV))
.Case("pdata", static_cast<unsigned>(DebugType::PData))
.Case("fixup", static_cast<unsigned>(DebugType::Fixup))
.Default(0);
if (v == 0) {
warn("/debugtype: unknown option '" + type + "'");
continue;
}
debugTypes |= v;
}
return debugTypes;
}
// Default debug types
debugTypes = static_cast<unsigned>(DebugType::CV);
if (args.hasArg(OPT_driver))
debugTypes |= static_cast<unsigned>(DebugType::PData);
if (args.hasArg(OPT_profile))
debugTypes |= static_cast<unsigned>(DebugType::Fixup);
return debugTypes;
}
static std::string getMapFile(const opt::InputArgList &args) {
auto *arg = args.getLastArg(OPT_lldmap, OPT_lldmap_file);
if (!arg)
return "";
if (arg->getOption().getID() == OPT_lldmap_file)
return arg->getValue();
assert(arg->getOption().getID() == OPT_lldmap);
StringRef outFile = config->outputFile;
return (outFile.substr(0, outFile.rfind('.')) + ".map").str();
}
static std::string getImplibPath() {
if (!config->implib.empty())
return config->implib;
SmallString<128> out = StringRef(config->outputFile);
sys::path::replace_extension(out, ".lib");
return out.str();
}
//
// The import name is caculated as the following:
//
// | LIBRARY w/ ext | LIBRARY w/o ext | no LIBRARY
// -----+----------------+---------------------+------------------
// LINK | {value} | {value}.{.dll/.exe} | {output name}
// LIB | {value} | {value}.dll | {output name}.dll
//
static std::string getImportName(bool asLib) {
SmallString<128> out;
if (config->importName.empty()) {
out.assign(sys::path::filename(config->outputFile));
if (asLib)
sys::path::replace_extension(out, ".dll");
} else {
out.assign(config->importName);
if (!sys::path::has_extension(out))
sys::path::replace_extension(out,
(config->dll || asLib) ? ".dll" : ".exe");
}
return out.str();
}
static void createImportLibrary(bool asLib) {
std::vector<COFFShortExport> exports;
for (Export &e1 : config->exports) {
COFFShortExport e2;
e2.Name = e1.name;
e2.SymbolName = e1.symbolName;
e2.ExtName = e1.extName;
e2.Ordinal = e1.ordinal;
e2.Noname = e1.noname;
e2.Data = e1.data;
e2.Private = e1.isPrivate;
e2.Constant = e1.constant;
exports.push_back(e2);
}
auto handleError = [](Error &&e) {
handleAllErrors(std::move(e),
[](ErrorInfoBase &eib) { error(eib.message()); });
};
std::string libName = getImportName(asLib);
std::string path = getImplibPath();
if (!config->incremental) {
handleError(writeImportLibrary(libName, path, exports, config->machine,
config->mingw));
return;
}
// If the import library already exists, replace it only if the contents
// have changed.
ErrorOr<std::unique_ptr<MemoryBuffer>> oldBuf = MemoryBuffer::getFile(
path, /*FileSize*/ -1, /*RequiresNullTerminator*/ false);
if (!oldBuf) {
handleError(writeImportLibrary(libName, path, exports, config->machine,
config->mingw));
return;
}
SmallString<128> tmpName;
if (std::error_code ec =
sys::fs::createUniqueFile(path + ".tmp-%%%%%%%%.lib", tmpName))
fatal("cannot create temporary file for import library " + path + ": " +
ec.message());
if (Error e = writeImportLibrary(libName, tmpName, exports, config->machine,
config->mingw)) {
handleError(std::move(e));
return;
}
std::unique_ptr<MemoryBuffer> newBuf = check(MemoryBuffer::getFile(
tmpName, /*FileSize*/ -1, /*RequiresNullTerminator*/ false));
if ((*oldBuf)->getBuffer() != newBuf->getBuffer()) {
oldBuf->reset();
handleError(errorCodeToError(sys::fs::rename(tmpName, path)));
} else {
sys::fs::remove(tmpName);
}
}
static void parseModuleDefs(StringRef path) {
std::unique_ptr<MemoryBuffer> mb = CHECK(
MemoryBuffer::getFile(path, -1, false, true), "could not open " + path);
COFFModuleDefinition m = check(parseCOFFModuleDefinition(
mb->getMemBufferRef(), config->machine, config->mingw));
if (config->outputFile.empty())
config->outputFile = saver.save(m.OutputFile);
config->importName = saver.save(m.ImportName);
if (m.ImageBase)
config->imageBase = m.ImageBase;
if (m.StackReserve)
config->stackReserve = m.StackReserve;
if (m.StackCommit)
config->stackCommit = m.StackCommit;
if (m.HeapReserve)
config->heapReserve = m.HeapReserve;
if (m.HeapCommit)
config->heapCommit = m.HeapCommit;
if (m.MajorImageVersion)
config->majorImageVersion = m.MajorImageVersion;
if (m.MinorImageVersion)
config->minorImageVersion = m.MinorImageVersion;
if (m.MajorOSVersion)
config->majorOSVersion = m.MajorOSVersion;
if (m.MinorOSVersion)
config->minorOSVersion = m.MinorOSVersion;
for (COFFShortExport e1 : m.Exports) {
Export e2;
// In simple cases, only Name is set. Renamed exports are parsed
// and set as "ExtName = Name". If Name has the form "OtherDll.Func",
// it shouldn't be a normal exported function but a forward to another
// DLL instead. This is supported by both MS and GNU linkers.
if (e1.ExtName != e1.Name && StringRef(e1.Name).contains('.')) {
e2.name = saver.save(e1.ExtName);
e2.forwardTo = saver.save(e1.Name);
config->exports.push_back(e2);
continue;
}
e2.name = saver.save(e1.Name);
e2.extName = saver.save(e1.ExtName);
e2.ordinal = e1.Ordinal;
e2.noname = e1.Noname;
e2.data = e1.Data;
e2.isPrivate = e1.Private;
e2.constant = e1.Constant;
config->exports.push_back(e2);
}
}
void LinkerDriver::enqueueTask(std::function<void()> task) {
taskQueue.push_back(std::move(task));
}
bool LinkerDriver::run() {
ScopedTimer t(inputFileTimer);
bool didWork = !taskQueue.empty();
while (!taskQueue.empty()) {
taskQueue.front()();
taskQueue.pop_front();
}
return didWork;
}
// Parse an /order file. If an option is given, the linker places
// COMDAT sections in the same order as their names appear in the
// given file.
static void parseOrderFile(StringRef arg) {
// For some reason, the MSVC linker requires a filename to be
// preceded by "@".
if (!arg.startswith("@")) {
error("malformed /order option: '@' missing");
return;
}
// Get a list of all comdat sections for error checking.
DenseSet<StringRef> set;
for (Chunk *c : symtab->getChunks())
if (auto *sec = dyn_cast<SectionChunk>(c))
if (sec->sym)
set.insert(sec->sym->getName());
// Open a file.
StringRef path = arg.substr(1);
std::unique_ptr<MemoryBuffer> mb = CHECK(
MemoryBuffer::getFile(path, -1, false, true), "could not open " + path);
// Parse a file. An order file contains one symbol per line.
// All symbols that were not present in a given order file are
// considered to have the lowest priority 0 and are placed at
// end of an output section.
for (std::string s : args::getLines(mb->getMemBufferRef())) {
if (config->machine == I386 && !isDecorated(s))
s = "_" + s;
if (set.count(s) == 0) {
if (config->warnMissingOrderSymbol)
warn("/order:" + arg + ": missing symbol: " + s + " [LNK4037]");
}
else
config->order[s] = INT_MIN + config->order.size();
}
}
static void markAddrsig(Symbol *s) {
if (auto *d = dyn_cast_or_null<Defined>(s))
if (SectionChunk *c = dyn_cast_or_null<SectionChunk>(d->getChunk()))
c->keepUnique = true;
}
static void findKeepUniqueSections() {
// Exported symbols could be address-significant in other executables or DSOs,
// so we conservatively mark them as address-significant.
for (Export &r : config->exports)
markAddrsig(r.sym);
// Visit the address-significance table in each object file and mark each
// referenced symbol as address-significant.
for (ObjFile *obj : ObjFile::instances) {
ArrayRef<Symbol *> syms = obj->getSymbols();
if (obj->addrsigSec) {
ArrayRef<uint8_t> contents;
cantFail(
obj->getCOFFObj()->getSectionContents(obj->addrsigSec, contents));
const uint8_t *cur = contents.begin();
while (cur != contents.end()) {
unsigned size;
const char *err;
uint64_t symIndex = decodeULEB128(cur, &size, contents.end(), &err);
if (err)
fatal(toString(obj) + ": could not decode addrsig section: " + err);
if (symIndex >= syms.size())
fatal(toString(obj) + ": invalid symbol index in addrsig section");
markAddrsig(syms[symIndex]);
cur += size;
}
} else {
// If an object file does not have an address-significance table,
// conservatively mark all of its symbols as address-significant.
for (Symbol *s : syms)
markAddrsig(s);
}
}
}
// link.exe replaces each %foo% in altPath with the contents of environment
// variable foo, and adds the two magic env vars _PDB (expands to the basename
// of pdb's output path) and _EXT (expands to the extension of the output
// binary).
// lld only supports %_PDB% and %_EXT% and warns on references to all other env
// vars.
static void parsePDBAltPath(StringRef altPath) {
SmallString<128> buf;
StringRef pdbBasename =
sys::path::filename(config->pdbPath, sys::path::Style::windows);
StringRef binaryExtension =
sys::path::extension(config->outputFile, sys::path::Style::windows);
if (!binaryExtension.empty())
binaryExtension = binaryExtension.substr(1); // %_EXT% does not include '.'.
// Invariant:
// +--------- cursor ('a...' might be the empty string).
// | +----- firstMark
// | | +- secondMark
// v v v
// a...%...%...
size_t cursor = 0;
while (cursor < altPath.size()) {
size_t firstMark, secondMark;
if ((firstMark = altPath.find('%', cursor)) == StringRef::npos ||
(secondMark = altPath.find('%', firstMark + 1)) == StringRef::npos) {
// Didn't find another full fragment, treat rest of string as literal.
buf.append(altPath.substr(cursor));
break;
}
// Found a full fragment. Append text in front of first %, and interpret
// text between first and second % as variable name.
buf.append(altPath.substr(cursor, firstMark - cursor));
StringRef var = altPath.substr(firstMark, secondMark - firstMark + 1);
if (var.equals_lower("%_pdb%"))
buf.append(pdbBasename);
else if (var.equals_lower("%_ext%"))
buf.append(binaryExtension);
else {
warn("only %_PDB% and %_EXT% supported in /pdbaltpath:, keeping " +
var + " as literal");
buf.append(var);
}
cursor = secondMark + 1;
}
config->pdbAltPath = buf;
}
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
/// Check that at most one resource obj file was used.
/// Call after ObjFile::Instances is complete.
static void diagnoseMultipleResourceObjFiles() {
// The .rsrc$01 section in a resource obj file contains a tree description
// of resources. Merging multiple resource obj files would require merging
// the trees instead of using usual linker section merging semantics.
// Since link.exe disallows linking more than one resource obj file with
// LNK4078, mirror that. The normal use of resource files is to give the
// linker many .res files, which are then converted to a single resource obj
// file internally, so this is not a big restriction in practice.
ObjFile *resourceObjFile = nullptr;
for (ObjFile *f : ObjFile::instances) {
if (!f->isResourceObjFile)
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
continue;
if (!resourceObjFile) {
resourceObjFile = f;
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
continue;
}
error(toString(f) +
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
": more than one resource obj file not allowed, already got " +
toString(resourceObjFile));
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
}
}
// In MinGW, if no symbols are chosen to be exported, then all symbols are
// automatically exported by default. This behavior can be forced by the
// -export-all-symbols option, so that it happens even when exports are
// explicitly specified. The automatic behavior can be disabled using the
// -exclude-all-symbols option, so that lld-link behaves like link.exe rather
// than MinGW in the case that nothing is explicitly exported.
void LinkerDriver::maybeExportMinGWSymbols(const opt::InputArgList &args) {
if (!config->dll)
return;
if (!args.hasArg(OPT_export_all_symbols)) {
if (!config->exports.empty())
return;
if (args.hasArg(OPT_exclude_all_symbols))
return;
}
AutoExporter exporter;
for (auto *arg : args.filtered(OPT_wholearchive_file))
if (Optional<StringRef> path = doFindFile(arg->getValue()))
exporter.addWholeArchive(*path);
symtab->forEachSymbol([&](Symbol *s) {
auto *def = dyn_cast<Defined>(s);
if (!exporter.shouldExport(def))
return;
Export e;
e.name = def->getName();
e.sym = def;
if (Chunk *c = def->getChunk())
if (!(c->getOutputCharacteristics() & IMAGE_SCN_MEM_EXECUTE))
e.data = true;
config->exports.push_back(e);
});
}
void LinkerDriver::link(ArrayRef<const char *> argsArr) {
// Needed for LTO.
InitializeAllTargetInfos();
InitializeAllTargets();
InitializeAllTargetMCs();
InitializeAllAsmParsers();
InitializeAllAsmPrinters();
// If the first command line argument is "/lib", link.exe acts like lib.exe.
// We call our own implementation of lib.exe that understands bitcode files.
if (argsArr.size() > 1 && StringRef(argsArr[1]).equals_lower("/lib")) {
if (llvm::libDriverMain(argsArr.slice(1)) != 0)
fatal("lib failed");
return;
}
// Parse command line options.
ArgParser parser;
opt::InputArgList args = parser.parseLINK(argsArr);
// Parse and evaluate -mllvm options.
std::vector<const char *> v;
v.push_back("lld-link (LLVM option parsing)");
for (auto *arg : args.filtered(OPT_mllvm))
v.push_back(arg->getValue());
cl::ParseCommandLineOptions(v.size(), v.data());
// Handle /errorlimit early, because error() depends on it.
if (auto *arg = args.getLastArg(OPT_errorlimit)) {
int n = 20;
StringRef s = arg->getValue();
if (s.getAsInteger(10, n))
error(arg->getSpelling() + " number expected, but got " + s);
errorHandler().errorLimit = n;
}
// Handle /help
if (args.hasArg(OPT_help)) {
printHelp(argsArr[0]);
return;
}
lld::threadsEnabled = args.hasFlag(OPT_threads, OPT_threads_no, true);
if (args.hasArg(OPT_show_timing))
config->showTiming = true;
config->showSummary = args.hasArg(OPT_summary);
ScopedTimer t(Timer::root());
// Handle --version, which is an lld extension. This option is a bit odd
// because it doesn't start with "/", but we deliberately chose "--" to
// avoid conflict with /version and for compatibility with clang-cl.
if (args.hasArg(OPT_dash_dash_version)) {
outs() << getLLDVersion() << "\n";
return;
}
// Handle /lldmingw early, since it can potentially affect how other
// options are handled.
config->mingw = args.hasArg(OPT_lldmingw);
if (auto *arg = args.getLastArg(OPT_linkrepro)) {
SmallString<64> path = StringRef(arg->getValue());
sys::path::append(path, "repro.tar");
Expected<std::unique_ptr<TarWriter>> errOrWriter =
TarWriter::create(path, "repro");
if (errOrWriter) {
tar = std::move(*errOrWriter);
} else {
error("/linkrepro: failed to open " + path + ": " +
toString(errOrWriter.takeError()));
}
}
if (!args.hasArg(OPT_INPUT)) {
if (args.hasArg(OPT_deffile))
config->noEntry = true;
else
fatal("no input files");
}
// Construct search path list.
searchPaths.push_back("");
for (auto *arg : args.filtered(OPT_libpath))
searchPaths.push_back(arg->getValue());
addLibSearchPaths();
// Handle /ignore
for (auto *arg : args.filtered(OPT_ignore)) {
SmallVector<StringRef, 8> vec;
StringRef(arg->getValue()).split(vec, ',');
for (StringRef s : vec) {
if (s == "4037")
config->warnMissingOrderSymbol = false;
else if (s == "4099")
config->warnDebugInfoUnusable = false;
else if (s == "4217")
config->warnLocallyDefinedImported = false;
// Other warning numbers are ignored.
}
}
// Handle /out
if (auto *arg = args.getLastArg(OPT_out))
config->outputFile = arg->getValue();
// Handle /verbose
if (args.hasArg(OPT_verbose))
config->verbose = true;
errorHandler().verbose = config->verbose;
// Handle /force or /force:unresolved
if (args.hasArg(OPT_force, OPT_force_unresolved))
config->forceUnresolved = true;
// Handle /force or /force:multiple
if (args.hasArg(OPT_force, OPT_force_multiple))
config->forceMultiple = true;
// Handle /force or /force:multipleres
if (args.hasArg(OPT_force, OPT_force_multipleres))
config->forceMultipleRes = true;
// Handle /debug
DebugKind debug = parseDebugKind(args);
if (debug == DebugKind::Full || debug == DebugKind::Dwarf ||
debug == DebugKind::GHash) {
config->debug = true;
config->incremental = true;
}
// Handle /demangle
config->demangle = args.hasFlag(OPT_demangle, OPT_demangle_no);
// Handle /debugtype
config->debugTypes = parseDebugTypes(args);
// Handle /pdb
bool shouldCreatePDB =
(debug == DebugKind::Full || debug == DebugKind::GHash);
if (shouldCreatePDB) {
if (auto *arg = args.getLastArg(OPT_pdb))
config->pdbPath = arg->getValue();
if (auto *arg = args.getLastArg(OPT_pdbaltpath))
config->pdbAltPath = arg->getValue();
if (args.hasArg(OPT_natvis))
config->natvisFiles = args.getAllArgValues(OPT_natvis);
if (auto *arg = args.getLastArg(OPT_pdb_source_path))
config->pdbSourcePath = arg->getValue();
}
// Handle /noentry
if (args.hasArg(OPT_noentry)) {
if (args.hasArg(OPT_dll))
config->noEntry = true;
else
error("/noentry must be specified with /dll");
}
// Handle /dll
if (args.hasArg(OPT_dll)) {
config->dll = true;
config->manifestID = 2;
}
// Handle /dynamicbase and /fixed. We can't use hasFlag for /dynamicbase
// because we need to explicitly check whether that option or its inverse was
// present in the argument list in order to handle /fixed.
auto *dynamicBaseArg = args.getLastArg(OPT_dynamicbase, OPT_dynamicbase_no);
if (dynamicBaseArg &&
dynamicBaseArg->getOption().getID() == OPT_dynamicbase_no)
config->dynamicBase = false;
// MSDN claims "/FIXED:NO is the default setting for a DLL, and /FIXED is the
// default setting for any other project type.", but link.exe defaults to
// /FIXED:NO for exe outputs as well. Match behavior, not docs.
bool fixed = args.hasFlag(OPT_fixed, OPT_fixed_no, false);
if (fixed) {
if (dynamicBaseArg &&
dynamicBaseArg->getOption().getID() == OPT_dynamicbase) {
error("/fixed must not be specified with /dynamicbase");
} else {
config->relocatable = false;
config->dynamicBase = false;
}
}
// Handle /appcontainer
config->appContainer =
args.hasFlag(OPT_appcontainer, OPT_appcontainer_no, false);
// Handle /machine
if (auto *arg = args.getLastArg(OPT_machine)) {
config->machine = getMachineType(arg->getValue());
if (config->machine == IMAGE_FILE_MACHINE_UNKNOWN)
fatal(Twine("unknown /machine argument: ") + arg->getValue());
}
// Handle /nodefaultlib:<filename>
for (auto *arg : args.filtered(OPT_nodefaultlib))
config->noDefaultLibs.insert(doFindLib(arg->getValue()).lower());
// Handle /nodefaultlib
if (args.hasArg(OPT_nodefaultlib_all))
config->noDefaultLibAll = true;
// Handle /base
if (auto *arg = args.getLastArg(OPT_base))
parseNumbers(arg->getValue(), &config->imageBase);
2015-05-30 00:21:11 +08:00
// Handle /filealign
if (auto *arg = args.getLastArg(OPT_filealign)) {
parseNumbers(arg->getValue(), &config->fileAlign);
if (!isPowerOf2_64(config->fileAlign))
error("/filealign: not a power of two: " + Twine(config->fileAlign));
}
2015-05-30 00:21:11 +08:00
// Handle /stack
if (auto *arg = args.getLastArg(OPT_stack))
parseNumbers(arg->getValue(), &config->stackReserve, &config->stackCommit);
// Handle /guard:cf
if (auto *arg = args.getLastArg(OPT_guard))
parseGuard(arg->getValue());
// Handle /heap
if (auto *arg = args.getLastArg(OPT_heap))
parseNumbers(arg->getValue(), &config->heapReserve, &config->heapCommit);
// Handle /version
if (auto *arg = args.getLastArg(OPT_version))
parseVersion(arg->getValue(), &config->majorImageVersion,
&config->minorImageVersion);
// Handle /subsystem
if (auto *arg = args.getLastArg(OPT_subsystem))
parseSubsystem(arg->getValue(), &config->subsystem, &config->majorOSVersion,
&config->minorOSVersion);
// Handle /timestamp
if (llvm::opt::Arg *arg = args.getLastArg(OPT_timestamp, OPT_repro)) {
if (arg->getOption().getID() == OPT_repro) {
config->timestamp = 0;
config->repro = true;
} else {
config->repro = false;
StringRef value(arg->getValue());
if (value.getAsInteger(0, config->timestamp))
fatal(Twine("invalid timestamp: ") + value +
". Expected 32-bit integer");
}
} else {
config->repro = false;
config->timestamp = time(nullptr);
}
// Handle /alternatename
for (auto *arg : args.filtered(OPT_alternatename))
parseAlternateName(arg->getValue());
// Handle /include
for (auto *arg : args.filtered(OPT_incl))
addUndefined(arg->getValue());
// Handle /implib
if (auto *arg = args.getLastArg(OPT_implib))
config->implib = arg->getValue();
// Handle /opt.
bool doGC = debug == DebugKind::None || args.hasArg(OPT_profile);
unsigned icfLevel =
args.hasArg(OPT_profile) ? 0 : 1; // 0: off, 1: limited, 2: on
unsigned tailMerge = 1;
for (auto *arg : args.filtered(OPT_opt)) {
std::string str = StringRef(arg->getValue()).lower();
SmallVector<StringRef, 1> vec;
StringRef(str).split(vec, ',');
for (StringRef s : vec) {
if (s == "ref") {
doGC = true;
} else if (s == "noref") {
doGC = false;
} else if (s == "icf" || s.startswith("icf=")) {
icfLevel = 2;
} else if (s == "noicf") {
icfLevel = 0;
} else if (s == "lldtailmerge") {
tailMerge = 2;
} else if (s == "nolldtailmerge") {
tailMerge = 0;
} else if (s.startswith("lldlto=")) {
StringRef optLevel = s.substr(7);
if (optLevel.getAsInteger(10, config->ltoo) || config->ltoo > 3)
error("/opt:lldlto: invalid optimization level: " + optLevel);
} else if (s.startswith("lldltojobs=")) {
StringRef jobs = s.substr(11);
if (jobs.getAsInteger(10, config->thinLTOJobs) ||
config->thinLTOJobs == 0)
error("/opt:lldltojobs: invalid job count: " + jobs);
} else if (s.startswith("lldltopartitions=")) {
StringRef n = s.substr(17);
if (n.getAsInteger(10, config->ltoPartitions) ||
config->ltoPartitions == 0)
error("/opt:lldltopartitions: invalid partition count: " + n);
} else if (s != "lbr" && s != "nolbr")
error("/opt: unknown option: " + s);
}
}
// Limited ICF is enabled if GC is enabled and ICF was never mentioned
// explicitly.
// FIXME: LLD only implements "limited" ICF, i.e. it only merges identical
// code. If the user passes /OPT:ICF explicitly, LLD should merge identical
// comdat readonly data.
if (icfLevel == 1 && !doGC)
icfLevel = 0;
config->doGC = doGC;
config->doICF = icfLevel > 0;
config->tailMerge = (tailMerge == 1 && config->doICF) || tailMerge == 2;
// Handle /lldsavetemps
if (args.hasArg(OPT_lldsavetemps))
config->saveTemps = true;
// Handle /kill-at
if (args.hasArg(OPT_kill_at))
config->killAt = true;
// Handle /lldltocache
if (auto *arg = args.getLastArg(OPT_lldltocache))
config->ltoCache = arg->getValue();
// Handle /lldsavecachepolicy
if (auto *arg = args.getLastArg(OPT_lldltocachepolicy))
config->ltoCachePolicy = CHECK(
parseCachePruningPolicy(arg->getValue()),
Twine("/lldltocachepolicy: invalid cache policy: ") + arg->getValue());
// Handle /failifmismatch
for (auto *arg : args.filtered(OPT_failifmismatch))
checkFailIfMismatch(arg->getValue(), nullptr);
// Handle /merge
for (auto *arg : args.filtered(OPT_merge))
parseMerge(arg->getValue());
// Add default section merging rules after user rules. User rules take
// precedence, but we will emit a warning if there is a conflict.
parseMerge(".idata=.rdata");
parseMerge(".didat=.rdata");
parseMerge(".edata=.rdata");
parseMerge(".xdata=.rdata");
parseMerge(".bss=.data");
if (config->mingw) {
parseMerge(".ctors=.rdata");
parseMerge(".dtors=.rdata");
parseMerge(".CRT=.rdata");
}
// Handle /section
for (auto *arg : args.filtered(OPT_section))
parseSection(arg->getValue());
// Handle /aligncomm
for (auto *arg : args.filtered(OPT_aligncomm))
parseAligncomm(arg->getValue());
// Handle /manifestdependency. This enables /manifest unless /manifest:no is
// also passed.
if (auto *arg = args.getLastArg(OPT_manifestdependency)) {
config->manifestDependency = arg->getValue();
config->manifest = Configuration::SideBySide;
}
// Handle /manifest and /manifest:
if (auto *arg = args.getLastArg(OPT_manifest, OPT_manifest_colon)) {
if (arg->getOption().getID() == OPT_manifest)
config->manifest = Configuration::SideBySide;
else
parseManifest(arg->getValue());
}
// Handle /manifestuac
if (auto *arg = args.getLastArg(OPT_manifestuac))
parseManifestUAC(arg->getValue());
// Handle /manifestfile
if (auto *arg = args.getLastArg(OPT_manifestfile))
config->manifestFile = arg->getValue();
// Handle /manifestinput
for (auto *arg : args.filtered(OPT_manifestinput))
config->manifestInput.push_back(arg->getValue());
if (!config->manifestInput.empty() &&
config->manifest != Configuration::Embed) {
fatal("/manifestinput: requires /manifest:embed");
}
config->thinLTOEmitImportsFiles = args.hasArg(OPT_thinlto_emit_imports_files);
config->thinLTOIndexOnly = args.hasArg(OPT_thinlto_index_only) ||
args.hasArg(OPT_thinlto_index_only_arg);
config->thinLTOIndexOnlyArg =
args.getLastArgValue(OPT_thinlto_index_only_arg);
config->thinLTOPrefixReplace =
getOldNewOptions(args, OPT_thinlto_prefix_replace);
config->thinLTOObjectSuffixReplace =
getOldNewOptions(args, OPT_thinlto_object_suffix_replace);
// Handle miscellaneous boolean flags.
config->allowBind = args.hasFlag(OPT_allowbind, OPT_allowbind_no, true);
config->allowIsolation =
args.hasFlag(OPT_allowisolation, OPT_allowisolation_no, true);
config->incremental =
args.hasFlag(OPT_incremental, OPT_incremental_no,
!config->doGC && !config->doICF && !args.hasArg(OPT_order) &&
!args.hasArg(OPT_profile));
config->integrityCheck =
args.hasFlag(OPT_integritycheck, OPT_integritycheck_no, false);
config->nxCompat = args.hasFlag(OPT_nxcompat, OPT_nxcompat_no, true);
for (auto *arg : args.filtered(OPT_swaprun))
parseSwaprun(arg->getValue());
config->terminalServerAware =
!config->dll && args.hasFlag(OPT_tsaware, OPT_tsaware_no, true);
config->debugDwarf = debug == DebugKind::Dwarf;
config->debugGHashes = debug == DebugKind::GHash;
config->debugSymtab = debug == DebugKind::Symtab;
config->mapFile = getMapFile(args);
if (config->incremental && args.hasArg(OPT_profile)) {
warn("ignoring '/incremental' due to '/profile' specification");
config->incremental = false;
}
if (config->incremental && args.hasArg(OPT_order)) {
warn("ignoring '/incremental' due to '/order' specification");
config->incremental = false;
}
if (config->incremental && config->doGC) {
warn("ignoring '/incremental' because REF is enabled; use '/opt:noref' to "
"disable");
config->incremental = false;
}
if (config->incremental && config->doICF) {
warn("ignoring '/incremental' because ICF is enabled; use '/opt:noicf' to "
"disable");
config->incremental = false;
}
if (errorCount())
return;
std::set<sys::fs::UniqueID> wholeArchives;
for (auto *arg : args.filtered(OPT_wholearchive_file))
if (Optional<StringRef> path = doFindFile(arg->getValue()))
if (Optional<sys::fs::UniqueID> id = getUniqueID(*path))
wholeArchives.insert(*id);
// A predicate returning true if a given path is an argument for
// /wholearchive:, or /wholearchive is enabled globally.
// This function is a bit tricky because "foo.obj /wholearchive:././foo.obj"
// needs to be handled as "/wholearchive:foo.obj foo.obj".
auto isWholeArchive = [&](StringRef path) -> bool {
if (args.hasArg(OPT_wholearchive_flag))
return true;
if (Optional<sys::fs::UniqueID> id = getUniqueID(path))
return wholeArchives.count(*id);
return false;
};
// Create a list of input files. Files can be given as arguments
// for /defaultlib option.
for (auto *arg : args.filtered(OPT_INPUT, OPT_wholearchive_file))
if (Optional<StringRef> path = findFile(arg->getValue()))
enqueuePath(*path, isWholeArchive(*path));
for (auto *arg : args.filtered(OPT_defaultlib))
if (Optional<StringRef> path = findLib(arg->getValue()))
enqueuePath(*path, false);
// Windows specific -- Create a resource file containing a manifest file.
if (config->manifest == Configuration::Embed)
addBuffer(createManifestRes(), false);
// Read all input files given via the command line.
run();
if (errorCount())
return;
// We should have inferred a machine type by now from the input files, but if
// not we assume x64.
if (config->machine == IMAGE_FILE_MACHINE_UNKNOWN) {
warn("/machine is not specified. x64 is assumed");
config->machine = AMD64;
}
config->wordsize = config->is64() ? 8 : 4;
// Handle /safeseh, x86 only, on by default, except for mingw.
if (config->machine == I386 &&
args.hasFlag(OPT_safeseh, OPT_safeseh_no, !config->mingw))
config->safeSEH = true;
// Handle /functionpadmin
for (auto *arg : args.filtered(OPT_functionpadmin, OPT_functionpadmin_opt))
parseFunctionPadMin(arg, config->machine);
// Input files can be Windows resource files (.res files). We use
// WindowsResource to convert resource files to a regular COFF file,
// then link the resulting file normally.
if (!resources.empty())
symtab->addFile(make<ObjFile>(convertResToCOFF(resources)));
if (tar)
tar->append("response.txt",
createResponseFile(args, filePaths,
ArrayRef<StringRef>(searchPaths).slice(1)));
// Handle /largeaddressaware
config->largeAddressAware = args.hasFlag(
OPT_largeaddressaware, OPT_largeaddressaware_no, config->is64());
// Handle /highentropyva
config->highEntropyVA =
config->is64() &&
args.hasFlag(OPT_highentropyva, OPT_highentropyva_no, true);
if (!config->dynamicBase &&
(config->machine == ARMNT || config->machine == ARM64))
error("/dynamicbase:no is not compatible with " +
machineToStr(config->machine));
// Handle /export
for (auto *arg : args.filtered(OPT_export)) {
Export e = parseExport(arg->getValue());
if (config->machine == I386) {
if (!isDecorated(e.name))
e.name = saver.save("_" + e.name);
if (!e.extName.empty() && !isDecorated(e.extName))
e.extName = saver.save("_" + e.extName);
COFF: Improve dllexported name mangling compatibility. The rules for dllexported symbols are overly complicated due to x86 name decoration, fuzzy symbol resolution, and the fact that one symbol can be resolved by so many different names. The rules are probably intended to be "intuitive", so that users don't have to understand the name mangling schemes, but it seems that it can lead to unintended symbol exports. To make it clear what I'm trying to do with this patch, let me write how the export rules are subtle and complicated. - x86 name decoration: If machine type is i386 and export name is given by a command line option, like /export:foo, the real symbol name the linker has to search for is _foo because all symbols are decorated with "_" prefixes. This doesn't happen on non-x86 machines. This automatic name decoration happens only when the name is not C++ mangled. However, the symbol name exported from DLLs are ones without "_" on all platforms. Moreover, if the option is given via .drectve section, no symbol decoration is done (the reason being that the .drectve section is created by a compiler and the compiler should always know the exact name of the symbol, I guess). - Fuzzy symbol resolution: In addition to x86 name decoration, the linker has to look for cdecl or C++ mangled symbols for a given /export. For example, it searches for not only _foo but also _foo@<number> or ??foo@... for /export:foo. Previous implementation didn't get it right. I'm trying to make it as compatible with MSVC linker as possible with this patch however the rules are. The new code looks a bit messy to me, but I don't think it can be simpler due to the ad-hoc-ness of the rules. llvm-svn: 246424
2015-08-31 16:43:21 +08:00
}
config->exports.push_back(e);
}
// Handle /def
if (auto *arg = args.getLastArg(OPT_deffile)) {
// parseModuleDefs mutates Config object.
parseModuleDefs(arg->getValue());
}
// Handle generation of import library from a def file.
if (!args.hasArg(OPT_INPUT)) {
fixupExports();
createImportLibrary(/*asLib=*/true);
return;
}
// Windows specific -- if no /subsystem is given, we need to infer
// that from entry point name. Must happen before /entry handling,
// and after the early return when just writing an import library.
if (config->subsystem == IMAGE_SUBSYSTEM_UNKNOWN) {
config->subsystem = inferSubsystem();
if (config->subsystem == IMAGE_SUBSYSTEM_UNKNOWN)
fatal("subsystem must be defined");
}
// Handle /entry and /dll
if (auto *arg = args.getLastArg(OPT_entry)) {
config->entry = addUndefined(mangle(arg->getValue()));
} else if (!config->entry && !config->noEntry) {
if (args.hasArg(OPT_dll)) {
StringRef s = (config->machine == I386) ? "__DllMainCRTStartup@12"
: "_DllMainCRTStartup";
config->entry = addUndefined(s);
} else {
// Windows specific -- If entry point name is not given, we need to
// infer that from user-defined entry name.
StringRef s = findDefaultEntry();
if (s.empty())
fatal("entry point must be defined");
config->entry = addUndefined(s);
log("Entry name inferred: " + s);
}
}
// Handle /delayload
for (auto *arg : args.filtered(OPT_delayload)) {
config->delayLoads.insert(StringRef(arg->getValue()).lower());
if (config->machine == I386) {
config->delayLoadHelper = addUndefined("___delayLoadHelper2@8");
} else {
config->delayLoadHelper = addUndefined("__delayLoadHelper2");
}
}
// Set default image name if neither /out or /def set it.
if (config->outputFile.empty()) {
config->outputFile =
getOutputPath((*args.filtered(OPT_INPUT).begin())->getValue());
}
// Fail early if an output file is not writable.
if (auto e = tryCreateFile(config->outputFile)) {
error("cannot open output file " + config->outputFile + ": " + e.message());
return;
}
if (shouldCreatePDB) {
// Put the PDB next to the image if no /pdb flag was passed.
if (config->pdbPath.empty()) {
config->pdbPath = config->outputFile;
sys::path::replace_extension(config->pdbPath, ".pdb");
}
// The embedded PDB path should be the absolute path to the PDB if no
// /pdbaltpath flag was passed.
if (config->pdbAltPath.empty()) {
config->pdbAltPath = config->pdbPath;
// It's important to make the path absolute and remove dots. This path
// will eventually be written into the PE header, and certain Microsoft
// tools won't work correctly if these assumptions are not held.
sys::fs::make_absolute(config->pdbAltPath);
sys::path::remove_dots(config->pdbAltPath);
} else {
// Don't do this earlier, so that Config->OutputFile is ready.
parsePDBAltPath(config->pdbAltPath);
}
}
// Set default image base if /base is not given.
if (config->imageBase == uint64_t(-1))
config->imageBase = getDefaultImageBase();
symtab->addSynthetic(mangle("__ImageBase"), nullptr);
if (config->machine == I386) {
symtab->addAbsolute("___safe_se_handler_table", 0);
symtab->addAbsolute("___safe_se_handler_count", 0);
}
symtab->addAbsolute(mangle("__guard_fids_count"), 0);
symtab->addAbsolute(mangle("__guard_fids_table"), 0);
symtab->addAbsolute(mangle("__guard_flags"), 0);
symtab->addAbsolute(mangle("__guard_iat_count"), 0);
symtab->addAbsolute(mangle("__guard_iat_table"), 0);
symtab->addAbsolute(mangle("__guard_longjmp_count"), 0);
symtab->addAbsolute(mangle("__guard_longjmp_table"), 0);
// Needed for MSVC 2017 15.5 CRT.
symtab->addAbsolute(mangle("__enclave_config"), 0);
if (config->mingw) {
symtab->addAbsolute(mangle("__RUNTIME_PSEUDO_RELOC_LIST__"), 0);
symtab->addAbsolute(mangle("__RUNTIME_PSEUDO_RELOC_LIST_END__"), 0);
symtab->addAbsolute(mangle("__CTOR_LIST__"), 0);
symtab->addAbsolute(mangle("__DTOR_LIST__"), 0);
[COFF] Support MinGW automatic dllimport of data Normally, in order to reference exported data symbols from a different DLL, the declarations need to have the dllimport attribute, in order to use the __imp_<var> symbol (which contains an address to the actual variable) instead of the variable itself directly. This isn't an issue in the same way for functions, since any reference to the function without the dllimport attribute will end up as a reference to a thunk which loads the actual target function from the import address table (IAT). GNU ld, in MinGW environments, supports automatically importing data symbols from DLLs, even if the references didn't have the appropriate dllimport attribute. Since the PE/COFF format doesn't support the kind of relocations that this would require, the MinGW's CRT startup code has an custom framework of their own for manually fixing the missing relocations once module is loaded and the target addresses in the IAT are known. For this to work, the linker (originall in GNU ld) creates a list of remaining references needing fixup, which the runtime processes on startup before handing over control to user code. While this feature is rather controversial, it's one of the main features allowing unix style libraries to be used on windows without any extra porting effort. Some sort of automatic fixing of data imports is also necessary for the itanium C++ ABI on windows (as clang implements it right now) for importing vtable pointers in certain cases, see D43184 for some discussion on that. The runtime pseudo relocation handler supports 8/16/32/64 bit addresses, either PC relative references (like IMAGE_REL_*_REL32*) or absolute references (IMAGE_REL_AMD64_ADDR32, IMAGE_REL_AMD64_ADDR32, IMAGE_REL_I386_DIR32). On linking, the relocation is handled as a relocation against the corresponding IAT slot. For the absolute references, a normal base relocation is created, to update the embedded address in case the image is loaded at a different address. The list of runtime pseudo relocations contains the RVA of the imported symbol (the IAT slot), the RVA of the location the relocation should be applied to, and a size of the memory location. When the relocations are fixed at runtime, the difference between the actual IAT slot value and the IAT slot address is added to the reference, doing the right thing for both absolute and relative references. With this patch alone, things work fine for i386 binaries, and mostly for x86_64 binaries, with feature parity with GNU ld. Despite this, there are a few gotchas: - References to data from within code works fine on both x86 architectures, since their relocations consist of plain 32 or 64 bit absolute/relative references. On ARM and AArch64, references to data doesn't consist of a plain 32 or 64 bit embedded address or offset in the code. On ARMNT, it's usually a MOVW+MOVT instruction pair represented by a IMAGE_REL_ARM_MOV32T relocation, each instruction containing 16 bit of the target address), on AArch64, it's usually an ADRP+ADD/LDR/STR instruction pair with an even more complex encoding, storing a PC relative address (with a range of +/- 4 GB). This could theoretically be remedied by extending the runtime pseudo relocation handler with new relocation types, to support these instruction encodings. This isn't an issue for GCC/GNU ld since they don't support windows on ARMNT/AArch64. - For x86_64, if references in code are encoded as 32 bit PC relative offsets, the runtime relocation will fail if the target turns out to be out of range for a 32 bit offset. - Fixing up the relocations at runtime requires making sections writable if necessary, with the VirtualProtect function. In Windows Store/UWP apps, this function is forbidden. These limitations are addressed by a few later patches in lld and llvm. Differential Revision: https://reviews.llvm.org/D50917 llvm-svn: 340726
2018-08-27 16:43:31 +08:00
}
// This code may add new undefined symbols to the link, which may enqueue more
// symbol resolution tasks, so we need to continue executing tasks until we
// converge.
do {
// Windows specific -- if entry point is not found,
// search for its mangled names.
if (config->entry)
mangleMaybe(config->entry);
// Windows specific -- Make sure we resolve all dllexported symbols.
for (Export &e : config->exports) {
if (!e.forwardTo.empty())
continue;
e.sym = addUndefined(e.name);
if (!e.directives)
e.symbolName = mangleMaybe(e.sym);
}
// Add weak aliases. Weak aliases is a mechanism to give remaining
// undefined symbols final chance to be resolved successfully.
for (auto pair : config->alternateNames) {
StringRef from = pair.first;
StringRef to = pair.second;
Symbol *sym = symtab->find(from);
if (!sym)
continue;
if (auto *u = dyn_cast<Undefined>(sym))
if (!u->weakAlias)
u->weakAlias = symtab->addUndefined(to);
}
// Windows specific -- if __load_config_used can be resolved, resolve it.
if (symtab->findUnderscore("_load_config_used"))
addUndefined(mangle("_load_config_used"));
} while (run());
if (args.hasArg(OPT_include_optional)) {
// Handle /includeoptional
for (auto *arg : args.filtered(OPT_include_optional))
if (dyn_cast_or_null<Lazy>(symtab->find(arg->getValue())))
addUndefined(arg->getValue());
while (run());
}
if (config->mingw) {
[COFF] Support MinGW automatic dllimport of data Normally, in order to reference exported data symbols from a different DLL, the declarations need to have the dllimport attribute, in order to use the __imp_<var> symbol (which contains an address to the actual variable) instead of the variable itself directly. This isn't an issue in the same way for functions, since any reference to the function without the dllimport attribute will end up as a reference to a thunk which loads the actual target function from the import address table (IAT). GNU ld, in MinGW environments, supports automatically importing data symbols from DLLs, even if the references didn't have the appropriate dllimport attribute. Since the PE/COFF format doesn't support the kind of relocations that this would require, the MinGW's CRT startup code has an custom framework of their own for manually fixing the missing relocations once module is loaded and the target addresses in the IAT are known. For this to work, the linker (originall in GNU ld) creates a list of remaining references needing fixup, which the runtime processes on startup before handing over control to user code. While this feature is rather controversial, it's one of the main features allowing unix style libraries to be used on windows without any extra porting effort. Some sort of automatic fixing of data imports is also necessary for the itanium C++ ABI on windows (as clang implements it right now) for importing vtable pointers in certain cases, see D43184 for some discussion on that. The runtime pseudo relocation handler supports 8/16/32/64 bit addresses, either PC relative references (like IMAGE_REL_*_REL32*) or absolute references (IMAGE_REL_AMD64_ADDR32, IMAGE_REL_AMD64_ADDR32, IMAGE_REL_I386_DIR32). On linking, the relocation is handled as a relocation against the corresponding IAT slot. For the absolute references, a normal base relocation is created, to update the embedded address in case the image is loaded at a different address. The list of runtime pseudo relocations contains the RVA of the imported symbol (the IAT slot), the RVA of the location the relocation should be applied to, and a size of the memory location. When the relocations are fixed at runtime, the difference between the actual IAT slot value and the IAT slot address is added to the reference, doing the right thing for both absolute and relative references. With this patch alone, things work fine for i386 binaries, and mostly for x86_64 binaries, with feature parity with GNU ld. Despite this, there are a few gotchas: - References to data from within code works fine on both x86 architectures, since their relocations consist of plain 32 or 64 bit absolute/relative references. On ARM and AArch64, references to data doesn't consist of a plain 32 or 64 bit embedded address or offset in the code. On ARMNT, it's usually a MOVW+MOVT instruction pair represented by a IMAGE_REL_ARM_MOV32T relocation, each instruction containing 16 bit of the target address), on AArch64, it's usually an ADRP+ADD/LDR/STR instruction pair with an even more complex encoding, storing a PC relative address (with a range of +/- 4 GB). This could theoretically be remedied by extending the runtime pseudo relocation handler with new relocation types, to support these instruction encodings. This isn't an issue for GCC/GNU ld since they don't support windows on ARMNT/AArch64. - For x86_64, if references in code are encoded as 32 bit PC relative offsets, the runtime relocation will fail if the target turns out to be out of range for a 32 bit offset. - Fixing up the relocations at runtime requires making sections writable if necessary, with the VirtualProtect function. In Windows Store/UWP apps, this function is forbidden. These limitations are addressed by a few later patches in lld and llvm. Differential Revision: https://reviews.llvm.org/D50917 llvm-svn: 340726
2018-08-27 16:43:31 +08:00
// Load any further object files that might be needed for doing automatic
// imports.
//
// For cases with no automatically imported symbols, this iterates once
// over the symbol table and doesn't do anything.
//
// For the normal case with a few automatically imported symbols, this
// should only need to be run once, since each new object file imported
// is an import library and wouldn't add any new undefined references,
// but there's nothing stopping the __imp_ symbols from coming from a
// normal object file as well (although that won't be used for the
// actual autoimport later on). If this pass adds new undefined references,
// we won't iterate further to resolve them.
symtab->loadMinGWAutomaticImports();
[COFF] Support MinGW automatic dllimport of data Normally, in order to reference exported data symbols from a different DLL, the declarations need to have the dllimport attribute, in order to use the __imp_<var> symbol (which contains an address to the actual variable) instead of the variable itself directly. This isn't an issue in the same way for functions, since any reference to the function without the dllimport attribute will end up as a reference to a thunk which loads the actual target function from the import address table (IAT). GNU ld, in MinGW environments, supports automatically importing data symbols from DLLs, even if the references didn't have the appropriate dllimport attribute. Since the PE/COFF format doesn't support the kind of relocations that this would require, the MinGW's CRT startup code has an custom framework of their own for manually fixing the missing relocations once module is loaded and the target addresses in the IAT are known. For this to work, the linker (originall in GNU ld) creates a list of remaining references needing fixup, which the runtime processes on startup before handing over control to user code. While this feature is rather controversial, it's one of the main features allowing unix style libraries to be used on windows without any extra porting effort. Some sort of automatic fixing of data imports is also necessary for the itanium C++ ABI on windows (as clang implements it right now) for importing vtable pointers in certain cases, see D43184 for some discussion on that. The runtime pseudo relocation handler supports 8/16/32/64 bit addresses, either PC relative references (like IMAGE_REL_*_REL32*) or absolute references (IMAGE_REL_AMD64_ADDR32, IMAGE_REL_AMD64_ADDR32, IMAGE_REL_I386_DIR32). On linking, the relocation is handled as a relocation against the corresponding IAT slot. For the absolute references, a normal base relocation is created, to update the embedded address in case the image is loaded at a different address. The list of runtime pseudo relocations contains the RVA of the imported symbol (the IAT slot), the RVA of the location the relocation should be applied to, and a size of the memory location. When the relocations are fixed at runtime, the difference between the actual IAT slot value and the IAT slot address is added to the reference, doing the right thing for both absolute and relative references. With this patch alone, things work fine for i386 binaries, and mostly for x86_64 binaries, with feature parity with GNU ld. Despite this, there are a few gotchas: - References to data from within code works fine on both x86 architectures, since their relocations consist of plain 32 or 64 bit absolute/relative references. On ARM and AArch64, references to data doesn't consist of a plain 32 or 64 bit embedded address or offset in the code. On ARMNT, it's usually a MOVW+MOVT instruction pair represented by a IMAGE_REL_ARM_MOV32T relocation, each instruction containing 16 bit of the target address), on AArch64, it's usually an ADRP+ADD/LDR/STR instruction pair with an even more complex encoding, storing a PC relative address (with a range of +/- 4 GB). This could theoretically be remedied by extending the runtime pseudo relocation handler with new relocation types, to support these instruction encodings. This isn't an issue for GCC/GNU ld since they don't support windows on ARMNT/AArch64. - For x86_64, if references in code are encoded as 32 bit PC relative offsets, the runtime relocation will fail if the target turns out to be out of range for a 32 bit offset. - Fixing up the relocations at runtime requires making sections writable if necessary, with the VirtualProtect function. In Windows Store/UWP apps, this function is forbidden. These limitations are addressed by a few later patches in lld and llvm. Differential Revision: https://reviews.llvm.org/D50917 llvm-svn: 340726
2018-08-27 16:43:31 +08:00
run();
}
// At this point, we should not have any symbols that cannot be resolved.
// If we are going to do codegen for link-time optimization, check for
// unresolvable symbols first, so we don't spend time generating code that
// will fail to link anyway.
if (!BitcodeFile::instances.empty() && !config->forceUnresolved)
symtab->reportUnresolvable();
if (errorCount())
return;
// Do LTO by compiling bitcode input files to a set of native COFF files then
// link those files (unless -thinlto-index-only was given, in which case we
// resolve symbols and write indices, but don't generate native code or link).
symtab->addCombinedLTOObjects();
// If -thinlto-index-only is given, we should create only "index
// files" and not object files. Index file creation is already done
// in addCombinedLTOObject, so we are done if that's the case.
if (config->thinLTOIndexOnly)
return;
// If we generated native object files from bitcode files, this resolves
// references to the symbols we use from them.
run();
// Resolve remaining undefined symbols and warn about imported locals.
symtab->resolveRemainingUndefines();
if (errorCount())
return;
if (config->mingw) {
// In MinGW, all symbols are automatically exported if no symbols
// are chosen to be exported.
maybeExportMinGWSymbols(args);
// Make sure the crtend.o object is the last object file. This object
// file can contain terminating section chunks that need to be placed
// last. GNU ld processes files and static libraries explicitly in the
// order provided on the command line, while lld will pull in needed
// files from static libraries only after the last object file on the
// command line.
for (auto i = ObjFile::instances.begin(), e = ObjFile::instances.end();
i != e; i++) {
ObjFile *file = *i;
if (isCrtend(file->getName())) {
ObjFile::instances.erase(i);
ObjFile::instances.push_back(file);
break;
}
}
}
// Windows specific -- when we are creating a .dll file, we also
// need to create a .lib file.
if (!config->exports.empty() || config->dll) {
fixupExports();
createImportLibrary(/*asLib=*/false);
assignExportOrdinals();
}
// Handle /output-def (MinGW specific).
if (auto *arg = args.getLastArg(OPT_output_def))
writeDefFile(arg->getValue());
// Set extra alignment for .comm symbols
for (auto pair : config->alignComm) {
StringRef name = pair.first;
uint32_t alignment = pair.second;
Symbol *sym = symtab->find(name);
if (!sym) {
warn("/aligncomm symbol " + name + " not found");
continue;
}
// If the symbol isn't common, it must have been replaced with a regular
// symbol, which will carry its own alignment.
auto *dc = dyn_cast<DefinedCommon>(sym);
if (!dc)
continue;
CommonChunk *c = dc->getChunk();
c->setAlignment(std::max(c->getAlignment(), alignment));
}
// Windows specific -- Create a side-by-side manifest file.
if (config->manifest == Configuration::SideBySide)
createSideBySideManifest();
// Handle /order. We want to do this at this moment because we
// need a complete list of comdat sections to warn on nonexistent
// functions.
if (auto *arg = args.getLastArg(OPT_order))
parseOrderFile(arg->getValue());
// Identify unreferenced COMDAT sections.
if (config->doGC)
markLive(symtab->getChunks());
lld-link: Reject more than one resource .obj file Users are exepcted to pass all .res files to the linker, which then merges all the resource in all .res files into a tree structure and then converts the final tree structure to a .obj file with .rsrc$01 and .rsrc$02 sections and then links that. If the user instead passes several .obj files containing such resources, the correct thing to do would be to have custom code to merge the trees in the resource sections instead of doing normal section merging -- but link.exe rejects if multiple resource obj files are passed in with LNK4078, so let lld-link do that too instead of silently writing broken .rsrc sections in that case. The only real way to run into this is if users manually convert .res files to .obj files by running cvtres and then handing the resulting .obj files to lld-link instead, which in practice likely never happens. (lld-link is slightly stricter than link.exe now: If link.exe is passed one .obj file created by cvtres, and a .res file, for some reason it just emits a warning instead of an error and outputs strange looking data. lld-link now errors out on mixed input like this.) One way users could accidentally run into this is the following scenario: If a .res file is passed to lib.exe, then lib.exe calls cvtres.exe on the .res file before putting it in the output .lib. (llvm-lib currently doesn't do this.) link.exe's /wholearchive seems to only add obj files referenced from the static library index, but lld-link current really adds all files in the archive. So if lld-link /wholearchive is used with .lib files produced by lib.exe and .res files were among the files handed to lib.exe, we previously silently produced invalid output, but now we error out. link.exe's /wholearchive semantics on the other hand mean that it wouldn't load the resource object files from the .lib file at all. Since this scenario is probably still an unlikely corner case, the difference in behavior here seems fine -- and lld-link might have to change to use link.exe's /wholearchive semantics in the future anyways. Vaguely related to PR42180. Differential Revision: https://reviews.llvm.org/D63109 llvm-svn: 363078
2019-06-11 23:22:28 +08:00
// Needs to happen after the last call to addFile().
diagnoseMultipleResourceObjFiles();
// Identify identical COMDAT sections to merge them.
if (config->doICF) {
findKeepUniqueSections();
doICF(symtab->getChunks());
}
// Write the result.
writeResult();
// Stop early so we can print the results.
Timer::root().stop();
if (config->showTiming)
Timer::root().print();
}
} // namespace coff
} // namespace lld