Files
clang-p2996/lld/lib/Core/Resolver.cpp
Nick Kledzik be43d7ef29 [mach-o] Implement -demangle.
The darwin linker has the -demangle option which directs it to demangle C++
(and soon Swift) mangled symbol names. Long term we need some Diagnostics object
for formatting errors and warnings. But for now we have the Core linker just
writing messages to llvm::errs(). So, to enable demangling, I changed the
Resolver to call a LinkingContext method on the symbol name.

To make this more interesting, the demangling code is done via __cxa_demangle()
which is part of the C++ ABI, which is only supported on some platforms, so I
had to conditionalize the code with the config generated HAVE_CXXABI_H.

llvm-svn: 218718
2014-09-30 23:15:39 +00:00

464 lines
16 KiB
C++

//===- Core/Resolver.cpp - Resolves Atom References -----------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "lld/Core/Atom.h"
#include "lld/Core/ArchiveLibraryFile.h"
#include "lld/Core/File.h"
#include "lld/Core/SharedLibraryFile.h"
#include "lld/Core/Instrumentation.h"
#include "lld/Core/LLVM.h"
#include "lld/Core/Resolver.h"
#include "lld/Core/SymbolTable.h"
#include "lld/Core/LinkingContext.h"
#include "lld/Core/UndefinedAtom.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <cassert>
#include <vector>
namespace lld {
void Resolver::handleFile(const File &file) {
bool undefAdded = false;
for (const DefinedAtom *atom : file.defined())
doDefinedAtom(*atom);
for (const UndefinedAtom *atom : file.undefined())
if (doUndefinedAtom(*atom))
undefAdded = true;
for (const SharedLibraryAtom *atom : file.sharedLibrary())
doSharedLibraryAtom(*atom);
for (const AbsoluteAtom *atom : file.absolute())
doAbsoluteAtom(*atom);
// Notify the input file manager of the fact that we have made some progress
// on linking using the current input file. It may want to know the fact for
// --start-group/--end-group.
if (undefAdded) {
_context.getInputGraph().notifyProgress();
}
}
void Resolver::forEachUndefines(bool searchForOverrides,
UndefCallback callback) {
// Handle normal archives
unsigned undefineGenCount = 0;
do {
undefineGenCount = _symbolTable.size();
for (const UndefinedAtom *undefAtom : _symbolTable.undefines()) {
StringRef undefName = undefAtom->name();
// load for previous undefine may also have loaded this undefine
if (!_symbolTable.isDefined(undefName))
callback(undefName, false);
}
// search libraries for overrides of common symbols
if (searchForOverrides) {
for (StringRef tentDefName : _symbolTable.tentativeDefinitions()) {
// Load for previous tentative may also have loaded
// something that overrode this tentative, so always check.
const Atom *curAtom = _symbolTable.findByName(tentDefName);
assert(curAtom != nullptr);
if (const DefinedAtom *curDefAtom = dyn_cast<DefinedAtom>(curAtom)) {
if (curDefAtom->merge() == DefinedAtom::mergeAsTentative)
callback(tentDefName, true);
}
}
}
} while (undefineGenCount != _symbolTable.size());
}
void Resolver::handleArchiveFile(const File &file) {
const ArchiveLibraryFile *archiveFile = cast<ArchiveLibraryFile>(&file);
bool searchForOverrides =
_context.searchArchivesToOverrideTentativeDefinitions();
forEachUndefines(searchForOverrides,
[&](StringRef undefName, bool dataSymbolOnly) {
if (const File *member = archiveFile->find(undefName, dataSymbolOnly)) {
member->setOrdinal(_context.getNextOrdinalAndIncrement());
handleFile(*member);
}
});
}
void Resolver::handleSharedLibrary(const File &file) {
// Add all the atoms from the shared library
const SharedLibraryFile *sharedLibrary = cast<SharedLibraryFile>(&file);
handleFile(*sharedLibrary);
bool searchForOverrides =
_context.searchSharedLibrariesToOverrideTentativeDefinitions();
forEachUndefines(searchForOverrides,
[&](StringRef undefName, bool dataSymbolOnly) {
if (const SharedLibraryAtom *atom =
sharedLibrary->exports(undefName, dataSymbolOnly))
doSharedLibraryAtom(*atom);
});
}
bool Resolver::doUndefinedAtom(const UndefinedAtom &atom) {
DEBUG_WITH_TYPE("resolver", llvm::dbgs()
<< " UndefinedAtom: "
<< llvm::format("0x%09lX", &atom)
<< ", name=" << atom.name() << "\n");
// add to list of known atoms
_atoms.push_back(&atom);
// tell symbol table
bool newUndefAdded = _symbolTable.add(atom);
// If the undefined symbol has an alternative name, try to resolve the
// symbol with the name to give it a second chance. This feature is used
// for COFF "weak external" symbol.
if (!_symbolTable.isDefined(atom.name())) {
if (const UndefinedAtom *fallbackAtom = atom.fallback()) {
doUndefinedAtom(*fallbackAtom);
_symbolTable.addReplacement(&atom, fallbackAtom);
}
}
return newUndefAdded;
}
/// \brief Add the section group and the group-child reference members.
void Resolver::maybeAddSectionGroupOrGnuLinkOnce(const DefinedAtom &atom) {
// First time adding a group?
bool isFirstTime = _symbolTable.addGroup(atom);
if (!isFirstTime) {
// If duplicate symbols are allowed, select the first group.
if (_context.getAllowDuplicates())
return;
auto *prevGroup = dyn_cast<DefinedAtom>(_symbolTable.findGroup(atom.name()));
assert(prevGroup &&
"Internal Error: The group atom could only be a defined atom");
// The atoms should be of the same content type, reject invalid group
// resolution behaviors.
if (atom.contentType() == prevGroup->contentType())
return;
llvm::errs() << "SymbolTable: error while merging " << atom.name()
<< "\n";
llvm::report_fatal_error("duplicate symbol error");
return;
}
for (const Reference *r : atom) {
if (r->kindNamespace() == lld::Reference::KindNamespace::all &&
r->kindValue() == lld::Reference::kindGroupChild) {
const DefinedAtom *target = dyn_cast<DefinedAtom>(r->target());
assert(target && "Internal Error: kindGroupChild references need to "
"be associated with Defined Atoms only");
_atoms.push_back(target);
_symbolTable.add(*target);
}
}
}
// Called on each atom when a file is added. Returns true if a given
// atom is added to the symbol table.
void Resolver::doDefinedAtom(const DefinedAtom &atom) {
DEBUG_WITH_TYPE("resolver", llvm::dbgs()
<< " DefinedAtom: "
<< llvm::format("0x%09lX", &atom)
<< ", file=#"
<< atom.file().ordinal()
<< ", atom=#"
<< atom.ordinal()
<< ", name="
<< atom.name()
<< "\n");
// Verify on zero-size atoms are pinned to start or end of section.
if (atom.sectionPosition() == DefinedAtom::sectionPositionStart ||
atom.sectionPosition() == DefinedAtom::sectionPositionEnd) {
assert(atom.size() == 0);
}
// add to list of known atoms
_atoms.push_back(&atom);
if (atom.isGroupParent()) {
maybeAddSectionGroupOrGnuLinkOnce(atom);
} else {
_symbolTable.add(atom);
}
// An atom that should never be dead-stripped is a dead-strip root.
if (_context.deadStrip() && atom.deadStrip() == DefinedAtom::deadStripNever) {
_deadStripRoots.insert(&atom);
}
}
void Resolver::doSharedLibraryAtom(const SharedLibraryAtom &atom) {
DEBUG_WITH_TYPE("resolver", llvm::dbgs()
<< " SharedLibraryAtom: "
<< llvm::format("0x%09lX", &atom)
<< ", name="
<< atom.name()
<< "\n");
// add to list of known atoms
_atoms.push_back(&atom);
// tell symbol table
_symbolTable.add(atom);
}
void Resolver::doAbsoluteAtom(const AbsoluteAtom &atom) {
DEBUG_WITH_TYPE("resolver", llvm::dbgs()
<< " AbsoluteAtom: "
<< llvm::format("0x%09lX", &atom)
<< ", name="
<< atom.name()
<< "\n");
// add to list of known atoms
_atoms.push_back(&atom);
// tell symbol table
if (atom.scope() != Atom::scopeTranslationUnit)
_symbolTable.add(atom);
}
// utility to add a vector of atoms
void Resolver::addAtoms(const std::vector<const DefinedAtom *> &newAtoms) {
for (const DefinedAtom *newAtom : newAtoms)
doDefinedAtom(*newAtom);
}
// Keep adding atoms until _context.getNextFile() returns an error. This
// function is where undefined atoms are resolved.
bool Resolver::resolveUndefines() {
ScopedTask task(getDefaultDomain(), "resolveUndefines");
for (;;) {
ErrorOr<File &> file = _context.getInputGraph().getNextFile();
std::error_code ec = file.getError();
if (ec == InputGraphError::no_more_files)
return true;
if (!file) {
llvm::errs() << "Error occurred in getNextFile: " << ec.message() << "\n";
return false;
}
switch (file->kind()) {
case File::kindObject:
assert(!file->hasOrdinal());
file->setOrdinal(_context.getNextOrdinalAndIncrement());
handleFile(*file);
break;
case File::kindArchiveLibrary:
if (!file->hasOrdinal())
file->setOrdinal(_context.getNextOrdinalAndIncrement());
handleArchiveFile(*file);
break;
case File::kindSharedLibrary:
if (!file->hasOrdinal())
file->setOrdinal(_context.getNextOrdinalAndIncrement());
handleSharedLibrary(*file);
break;
}
}
}
// switch all references to undefined or coalesced away atoms
// to the new defined atom
void Resolver::updateReferences() {
ScopedTask task(getDefaultDomain(), "updateReferences");
for (const Atom *atom : _atoms) {
if (const DefinedAtom *defAtom = dyn_cast<DefinedAtom>(atom)) {
for (const Reference *ref : *defAtom) {
// A reference of type kindAssociate should't be updated.
// Instead, an atom having such reference will be removed
// if the target atom is coalesced away, so that they will
// go away as a group.
if (ref->kindNamespace() == lld::Reference::KindNamespace::all &&
ref->kindValue() == lld::Reference::kindAssociate) {
if (_symbolTable.isCoalescedAway(atom))
_deadAtoms.insert(ref->target());
continue;
}
const Atom *newTarget = _symbolTable.replacement(ref->target());
const_cast<Reference *>(ref)->setTarget(newTarget);
}
}
}
}
// For dead code stripping, recursively mark atoms "live"
void Resolver::markLive(const Atom *atom) {
// Mark the atom is live. If it's already marked live, then stop recursion.
auto exists = _liveAtoms.insert(atom);
if (!exists.second)
return;
// Mark all atoms it references as live
if (const DefinedAtom *defAtom = dyn_cast<DefinedAtom>(atom)) {
for (const Reference *ref : *defAtom)
markLive(ref->target());
for (const Atom *target : _reverseRef.lookup(defAtom))
markLive(target);
}
}
static bool isBackref(const Reference *ref) {
if (ref->kindNamespace() != lld::Reference::KindNamespace::all)
return false;
return (ref->kindValue() == lld::Reference::kindLayoutBefore ||
ref->kindValue() == lld::Reference::kindGroupChild);
}
// remove all atoms not actually used
void Resolver::deadStripOptimize() {
ScopedTask task(getDefaultDomain(), "deadStripOptimize");
// only do this optimization with -dead_strip
if (!_context.deadStrip())
return;
// Some type of references prevent referring atoms to be dead-striped.
// Make a reverse map of such references before traversing the graph.
for (const Atom *atom : _atoms)
if (const DefinedAtom *defAtom = dyn_cast<DefinedAtom>(atom))
for (const Reference *ref : *defAtom)
if (isBackref(ref))
_reverseRef[ref->target()].insert(atom);
// By default, shared libraries are built with all globals as dead strip roots
if (_context.globalsAreDeadStripRoots())
for (const Atom *atom : _atoms)
if (const DefinedAtom *defAtom = dyn_cast<DefinedAtom>(atom))
if (defAtom->scope() == DefinedAtom::scopeGlobal)
_deadStripRoots.insert(defAtom);
// Or, use list of names that are dead strip roots.
for (const StringRef &name : _context.deadStripRoots()) {
const Atom *symAtom = _symbolTable.findByName(name);
assert(symAtom);
_deadStripRoots.insert(symAtom);
}
// mark all roots as live, and recursively all atoms they reference
for (const Atom *dsrAtom : _deadStripRoots)
markLive(dsrAtom);
// now remove all non-live atoms from _atoms
_atoms.erase(std::remove_if(_atoms.begin(), _atoms.end(), [&](const Atom *a) {
return _liveAtoms.count(a) == 0;
}),
_atoms.end());
}
// error out if some undefines remain
bool Resolver::checkUndefines() {
// build vector of remaining undefined symbols
std::vector<const UndefinedAtom *> undefinedAtoms = _symbolTable.undefines();
if (_context.deadStrip()) {
// When dead code stripping, we don't care if dead atoms are undefined.
undefinedAtoms.erase(
std::remove_if(undefinedAtoms.begin(), undefinedAtoms.end(),
[&](const Atom *a) { return _liveAtoms.count(a) == 0; }),
undefinedAtoms.end());
}
// error message about missing symbols
if (!undefinedAtoms.empty()) {
// FIXME: need diagnostics interface for writing error messages
bool foundUndefines = false;
for (const UndefinedAtom *undefAtom : undefinedAtoms) {
const File &f = undefAtom->file();
// Skip over a weak symbol.
if (undefAtom->canBeNull() != UndefinedAtom::canBeNullNever)
continue;
// If this is a library and undefined symbols are allowed on the
// target platform, skip over it.
if (isa<SharedLibraryFile>(f) && _context.allowShlibUndefines())
continue;
// If the undefine is coalesced away, skip over it.
if (_symbolTable.isCoalescedAway(undefAtom))
continue;
// Seems like this symbol is undefined. Warn that.
foundUndefines = true;
if (_context.printRemainingUndefines()) {
llvm::errs() << "Undefined symbol: " << undefAtom->file().path()
<< ": " << _context.demangle(undefAtom->name())
<< "\n";
}
}
if (foundUndefines) {
if (_context.printRemainingUndefines())
llvm::errs() << "symbol(s) not found\n";
return true;
}
}
return false;
}
// remove from _atoms all coaleseced away atoms
void Resolver::removeCoalescedAwayAtoms() {
ScopedTask task(getDefaultDomain(), "removeCoalescedAwayAtoms");
_atoms.erase(std::remove_if(_atoms.begin(), _atoms.end(), [&](const Atom *a) {
return _symbolTable.isCoalescedAway(a) || _deadAtoms.count(a);
}),
_atoms.end());
}
bool Resolver::resolve() {
if (!resolveUndefines())
return false;
updateReferences();
deadStripOptimize();
if (checkUndefines())
if (!_context.allowRemainingUndefines())
return false;
removeCoalescedAwayAtoms();
_result->addAtoms(_atoms);
return true;
}
void Resolver::MergedFile::addAtom(const Atom &atom) {
if (auto *def = dyn_cast<DefinedAtom>(&atom)) {
_definedAtoms._atoms.push_back(def);
} else if (auto *undef = dyn_cast<UndefinedAtom>(&atom)) {
_undefinedAtoms._atoms.push_back(undef);
} else if (auto *shared = dyn_cast<SharedLibraryAtom>(&atom)) {
_sharedLibraryAtoms._atoms.push_back(shared);
} else if (auto *abs = dyn_cast<AbsoluteAtom>(&atom)) {
_absoluteAtoms._atoms.push_back(abs);
} else {
llvm_unreachable("atom has unknown definition kind");
}
}
MutableFile::DefinedAtomRange Resolver::MergedFile::definedAtoms() {
return range<std::vector<const DefinedAtom *>::iterator>(
_definedAtoms._atoms.begin(), _definedAtoms._atoms.end());
}
void Resolver::MergedFile::addAtoms(std::vector<const Atom *> &all) {
ScopedTask task(getDefaultDomain(), "addAtoms");
DEBUG_WITH_TYPE("resolver", llvm::dbgs() << "Resolver final atom list:\n");
for (const Atom *atom : all) {
DEBUG_WITH_TYPE("resolver", llvm::dbgs()
<< llvm::format(" 0x%09lX", atom)
<< ", name="
<< atom->name()
<< "\n");
addAtom(*atom);
}
}
} // namespace lld