//===- ObjectLinker.cpp ---------------------------------------------------===//
//
// The MCLinker Project
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include <mcld/Object/ObjectLinker.h>
#include <mcld/LinkerConfig.h>
#include <mcld/Module.h>
#include <mcld/InputTree.h>
#include <mcld/IRBuilder.h>
#include <mcld/LD/LDSection.h>
#include <mcld/LD/LDContext.h>
#include <mcld/LD/Archive.h>
#include <mcld/LD/ArchiveReader.h>
#include <mcld/LD/ObjectReader.h>
#include <mcld/LD/DynObjReader.h>
#include <mcld/LD/GroupReader.h>
#include <mcld/LD/BinaryReader.h>
#include <mcld/LD/ObjectWriter.h>
#include <mcld/LD/ResolveInfo.h>
#include <mcld/LD/RelocData.h>
#include <mcld/Support/RealPath.h>
#include <mcld/Support/MemoryArea.h>
#include <mcld/Support/MsgHandling.h>
#include <mcld/Target/TargetLDBackend.h>
#include <mcld/Fragment/FragmentLinker.h>
#include <mcld/Object/ObjectBuilder.h>
#include <llvm/Support/Casting.h>
using namespace llvm;
using namespace mcld;
ObjectLinker::ObjectLinker(const LinkerConfig& pConfig,
TargetLDBackend& pLDBackend)
: m_Config(pConfig),
m_pLinker(NULL),
m_pModule(NULL),
m_pBuilder(NULL),
m_LDBackend(pLDBackend),
m_pObjectReader(NULL),
m_pDynObjReader(NULL),
m_pArchiveReader(NULL),
m_pGroupReader(NULL),
m_pBinaryReader(NULL),
m_pWriter(NULL) {
}
ObjectLinker::~ObjectLinker()
{
delete m_pLinker;
delete m_pObjectReader;
delete m_pDynObjReader;
delete m_pArchiveReader;
delete m_pGroupReader;
delete m_pBinaryReader;
delete m_pWriter;
}
void ObjectLinker::setup(Module& pModule, IRBuilder& pBuilder)
{
m_pModule = &pModule;
m_pBuilder = &pBuilder;
// set up soname
if (!m_Config.options().soname().empty()) {
m_pModule->setName(m_Config.options().soname());
}
}
/// initFragmentLinker - initialize FragmentLinker
/// Connect all components with FragmentLinker
bool ObjectLinker::initFragmentLinker()
{
if (NULL == m_pLinker) {
m_pLinker = new FragmentLinker(m_Config,
*m_pModule,
m_LDBackend);
}
// initialize the readers and writers
// Because constructor can not be failed, we initalize all readers and
// writers outside the FragmentLinker constructors.
m_pObjectReader = m_LDBackend.createObjectReader(*m_pBuilder);
m_pArchiveReader = m_LDBackend.createArchiveReader(*m_pModule);
m_pDynObjReader = m_LDBackend.createDynObjReader(*m_pBuilder);
m_pGroupReader = new GroupReader(*m_pModule, *m_pObjectReader,
*m_pDynObjReader, *m_pArchiveReader);
m_pBinaryReader = m_LDBackend.createBinaryReader(*m_pBuilder);
m_pWriter = m_LDBackend.createWriter();
// initialize Relocator
m_LDBackend.initRelocator();
return true;
}
/// initStdSections - initialize standard sections
bool ObjectLinker::initStdSections()
{
ObjectBuilder builder(m_Config, *m_pModule);
// initialize standard sections
if (!m_LDBackend.initStdSections(builder))
return false;
// initialize target-dependent sections
m_LDBackend.initTargetSections(*m_pModule, builder);
return true;
}
void ObjectLinker::normalize()
{
// ----- set up inputs ----- //
Module::input_iterator input, inEnd = m_pModule->input_end();
for (input = m_pModule->input_begin(); input!=inEnd; ++input) {
// is a group node
if (isGroup(input)) {
getGroupReader()->readGroup(input, m_pBuilder->getInputBuilder(), m_Config);
continue;
}
// already got type - for example, bitcode or external OIR (object
// intermediate representation)
if ((*input)->type() == Input::Script ||
(*input)->type() == Input::Archive ||
(*input)->type() == Input::External)
continue;
if (Input::Object == (*input)->type()) {
m_pModule->getObjectList().push_back(*input);
continue;
}
if (Input::DynObj == (*input)->type()) {
m_pModule->getLibraryList().push_back(*input);
continue;
}
// read input as a binary file
if (m_Config.options().isBinaryInput()) {
(*input)->setType(Input::Object);
getBinaryReader()->readBinary(**input);
m_pModule->getObjectList().push_back(*input);
}
// is a relocatable object file
else if (getObjectReader()->isMyFormat(**input)) {
(*input)->setType(Input::Object);
getObjectReader()->readHeader(**input);
getObjectReader()->readSections(**input);
getObjectReader()->readSymbols(**input);
m_pModule->getObjectList().push_back(*input);
}
// is a shared object file
else if (getDynObjReader()->isMyFormat(**input)) {
(*input)->setType(Input::DynObj);
getDynObjReader()->readHeader(**input);
getDynObjReader()->readSymbols(**input);
m_pModule->getLibraryList().push_back(*input);
}
// is an archive
else if (getArchiveReader()->isMyFormat(**input)) {
(*input)->setType(Input::Archive);
Archive archive(**input, m_pBuilder->getInputBuilder());
getArchiveReader()->readArchive(archive);
if(archive.numOfObjectMember() > 0) {
m_pModule->getInputTree().merge<InputTree::Inclusive>(input,
archive.inputs());
}
}
else {
fatal(diag::err_unrecognized_input_file) << (*input)->path()
<< m_Config.targets().triple().str();
}
} // end of for
}
bool ObjectLinker::linkable() const
{
// check we have input and output files
if (m_pModule->getInputTree().empty()) {
error(diag::err_no_inputs);
return false;
}
// can not mix -static with shared objects
Module::const_lib_iterator lib, libEnd = m_pModule->lib_end();
for (lib = m_pModule->lib_begin(); lib != libEnd; ++lib) {
if((*lib)->attribute()->isStatic()) {
error(diag::err_mixed_shared_static_objects)
<< (*lib)->name() << (*lib)->path();
return false;
}
}
// --nmagic and --omagic options lead to static executable program.
// These options turn off page alignment of sections. Because the
// sections are not aligned to pages, these sections can not contain any
// exported functions. Also, because the two options disable linking
// against shared libraries, the output absolutely does not call outside
// functions.
if (m_Config.options().nmagic() && !m_Config.isCodeStatic()) {
error(diag::err_nmagic_not_static);
return false;
}
if (m_Config.options().omagic() && !m_Config.isCodeStatic()) {
error(diag::err_omagic_not_static);
return false;
}
return true;
}
/// readRelocations - read all relocation entries
///
/// All symbols should be read and resolved before this function.
bool ObjectLinker::readRelocations()
{
// Bitcode is read by the other path. This function reads relocation sections
// in object files.
mcld::InputTree::bfs_iterator input, inEnd = m_pModule->getInputTree().bfs_end();
for (input=m_pModule->getInputTree().bfs_begin(); input!=inEnd; ++input) {
if ((*input)->type() == Input::Object && (*input)->hasMemArea()) {
if (!getObjectReader()->readRelocations(**input))
return false;
}
// ignore the other kinds of files.
}
return true;
}
/// mergeSections - put allinput sections into output sections
bool ObjectLinker::mergeSections()
{
ObjectBuilder builder(m_Config, *m_pModule);
Module::obj_iterator obj, objEnd = m_pModule->obj_end();
for (obj = m_pModule->obj_begin(); obj != objEnd; ++obj) {
LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
switch ((*sect)->kind()) {
// Some *INPUT sections should not be merged.
case LDFileFormat::Ignore:
case LDFileFormat::Null:
case LDFileFormat::Relocation:
case LDFileFormat::NamePool:
case LDFileFormat::Group:
case LDFileFormat::StackNote:
// skip
continue;
case LDFileFormat::Target:
if (!m_LDBackend.mergeSection(*m_pModule, **sect)) {
error(diag::err_cannot_merge_section) << (*sect)->name()
<< (*obj)->name();
return false;
}
break;
case LDFileFormat::EhFrame: {
if (!(*sect)->hasEhFrame())
continue; // skip
if (NULL == builder.MergeSection(**sect)) {
error(diag::err_cannot_merge_section) << (*sect)->name()
<< (*obj)->name();
return false;
}
break;
}
default: {
if (!(*sect)->hasSectionData())
continue; // skip
LDSection* out_sect = builder.MergeSection(**sect);
if (NULL != out_sect) {
if (!m_LDBackend.updateSectionFlags(*out_sect, **sect)) {
error(diag::err_cannot_merge_section) << (*sect)->name()
<< (*obj)->name();
return false;
}
}
else {
error(diag::err_cannot_merge_section) << (*sect)->name()
<< (*obj)->name();
return false;
}
break;
}
} // end of switch
} // for each section
} // for each obj
return true;
}
/// addStandardSymbols - shared object and executable files need some
/// standard symbols
/// @return if there are some input symbols with the same name to the
/// standard symbols, return false
bool ObjectLinker::addStandardSymbols()
{
// create and add section symbols for each output section
Module::iterator iter, iterEnd = m_pModule->end();
for (iter = m_pModule->begin(); iter != iterEnd; ++iter) {
m_pModule->getSectionSymbolSet().add(**iter, m_pModule->getNamePool());
}
return m_LDBackend.initStandardSymbols(*m_pBuilder, *m_pModule);
}
/// addTargetSymbols - some targets, such as MIPS and ARM, need some
/// target-dependent symbols
/// @return if there are some input symbols with the same name to the
/// target symbols, return false
bool ObjectLinker::addTargetSymbols()
{
m_LDBackend.initTargetSymbols(*m_pBuilder, *m_pModule);
return true;
}
/// addScriptSymbols - define symbols from the command line option or linker
/// scripts.
/// @return if there are some existing symbols with identical name to the
/// script symbols, return false.
bool ObjectLinker::addScriptSymbols()
{
return true;
}
bool ObjectLinker::scanRelocations()
{
// apply all relocations of all inputs
Module::obj_iterator input, inEnd = m_pModule->obj_end();
for (input = m_pModule->obj_begin(); input != inEnd; ++input) {
LDContext::sect_iterator rs, rsEnd = (*input)->context()->relocSectEnd();
for (rs = (*input)->context()->relocSectBegin(); rs != rsEnd; ++rs) {
// bypass the reloc section if
// 1. its section kind is changed to Ignore. (The target section is a
// discarded group section.)
// 2. it has no reloc data. (All symbols in the input relocs are in the
// discarded group sections)
if (LDFileFormat::Ignore == (*rs)->kind() || !(*rs)->hasRelocData())
continue;
RelocData::iterator reloc, rEnd = (*rs)->getRelocData()->end();
for (reloc = (*rs)->getRelocData()->begin(); reloc != rEnd; ++reloc) {
Relocation* relocation = llvm::cast<Relocation>(reloc);
// scan relocation
if (LinkerConfig::Object != m_Config.codeGenType())
m_LDBackend.scanRelocation(*relocation, *m_pBuilder, *m_pModule, **rs);
else
m_LDBackend.partialScanRelocation(*relocation, *m_pModule, **rs);
} // for all relocations
} // for all relocation section
} // for all inputs
return true;
}
/// initStubs - initialize stub-related stuff.
bool ObjectLinker::initStubs()
{
// initialize BranchIslandFactory
m_LDBackend.initBRIslandFactory();
// initialize StubFactory
m_LDBackend.initStubFactory();
// initialize target stubs
m_LDBackend.initTargetStubs();
return true;
}
/// allocateCommonSymobols - allocate fragments for common symbols to the
/// corresponding sections
bool ObjectLinker::allocateCommonSymbols()
{
if (LinkerConfig::Object != m_Config.codeGenType() ||
m_Config.options().isDefineCommon())
return m_LDBackend.allocateCommonSymbols(*m_pModule);
return true;
}
/// prelayout - help backend to do some modification before layout
bool ObjectLinker::prelayout()
{
// finalize the section symbols, set their fragment reference and push them
// into output symbol table
Module::iterator sect, sEnd = m_pModule->end();
for (sect = m_pModule->begin(); sect != sEnd; ++sect) {
m_pModule->getSectionSymbolSet().finalize(**sect, m_pModule->getSymbolTable());
}
m_LDBackend.preLayout(*m_pModule, *m_pBuilder);
/// check program interpreter - computer the name size of the runtime dyld
if (!m_Config.isCodeStatic() &&
(LinkerConfig::Exec == m_Config.codeGenType() ||
m_Config.options().isPIE() ||
m_Config.options().hasDyld()))
m_LDBackend.sizeInterp();
/// measure NamePools - compute the size of name pool sections
/// In ELF, will compute the size of.symtab, .strtab, .dynsym, .dynstr,
/// .hash and .shstrtab sections.
///
/// dump all symbols and strings from FragmentLinker and build the format-dependent
/// hash table.
m_LDBackend.sizeNamePools(*m_pModule, m_Config.isCodeStatic());
return true;
}
/// layout - linearly layout all output sections and reserve some space
/// for GOT/PLT
/// Because we do not support instruction relaxing in this early version,
/// if there is a branch can not jump to its target, we return false
/// directly
bool ObjectLinker::layout()
{
m_LDBackend.layout(*m_pModule);
return true;
}
/// prelayout - help backend to do some modification after layout
bool ObjectLinker::postlayout()
{
m_LDBackend.postLayout(*m_pModule, *m_pBuilder);
return true;
}
/// finalizeSymbolValue - finalize the resolved symbol value.
/// Before relocate(), after layout(), FragmentLinker should correct value of all
/// symbol.
bool ObjectLinker::finalizeSymbolValue()
{
return (m_pLinker->finalizeSymbols() && m_LDBackend.finalizeSymbols());
}
/// relocate - applying relocation entries and create relocation
/// section in the output files
/// Create relocation section, asking TargetLDBackend to
/// read the relocation information into RelocationEntry
/// and push_back into the relocation section
bool ObjectLinker::relocation()
{
return m_pLinker->applyRelocations();
}
/// emitOutput - emit the output file.
bool ObjectLinker::emitOutput(MemoryArea& pOutput)
{
return llvm::errc::success == getWriter()->writeObject(*m_pModule, pOutput);
}
/// postProcessing - do modification after all processes
bool ObjectLinker::postProcessing(MemoryArea& pOutput)
{
m_pLinker->syncRelocationResult(pOutput);
// emit .eh_frame_hdr
// eh_frame_hdr should be emitted after syncRelocation, because eh_frame_hdr
// needs FDE PC value, which will be corrected at syncRelocation
m_LDBackend.postProcessing(pOutput);
return true;
}