lib/LD/ELFObjectReader.cpp - platform/frameworks/compile/mclinker - Git at Google

 //===- ELFObjectReader.cpp ------------------------------------------------===//
 //
 //                     The MCLinker Project
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 #include <mcld/LD/ELFObjectReader.h>

 #include <string>
 #include <cassert>

 #include <llvm/Support/ELF.h>
 #include <llvm/ADT/Twine.h>

 #include <mcld/IRBuilder.h>
 #include <mcld/MC/MCLDInput.h>
 #include <mcld/LD/ELFReader.h>
 #include <mcld/LD/EhFrameReader.h>
 #include <mcld/LD/EhFrame.h>
 #include <mcld/Target/GNULDBackend.h>
 #include <mcld/Support/MsgHandling.h>
 #include <mcld/Object/ObjectBuilder.h>

 using namespace mcld;

 //===----------------------------------------------------------------------===//
 // ELFObjectReader
 //===----------------------------------------------------------------------===//
 /// constructor
 ELFObjectReader::ELFObjectReader(GNULDBackend& pBackend,
                                  IRBuilder& pBuilder,
                                  const LinkerConfig& pConfig)
   : ObjectReader(),
     m_pELFReader(NULL),
     m_pEhFrameReader(NULL),
     m_Builder(pBuilder),
     m_ReadFlag(ParseEhFrame),
     m_Backend(pBackend),
     m_Config(pConfig) {
   if (pConfig.targets().is32Bits() && pConfig.targets().isLittleEndian()) {
     m_pELFReader = new ELFReader<32, true>(pBackend);
   }

   m_pEhFrameReader = new EhFrameReader();
 }

 /// destructor
 ELFObjectReader::~ELFObjectReader()
 {
   delete m_pELFReader;
   delete m_pEhFrameReader;
 }

 /// isMyFormat
 bool ELFObjectReader::isMyFormat(Input &pInput) const
 {
   assert(pInput.hasMemArea());

   // Don't warning about the frequently requests.
   // MemoryArea has a list of cache to handle this.
   size_t hdr_size = m_pELFReader->getELFHeaderSize();
   MemoryRegion* region = pInput.memArea()->request(pInput.fileOffset(),
                                                      hdr_size);

   uint8_t* ELF_hdr = region->start();
   bool result = true;
   if (!m_pELFReader->isELF(ELF_hdr))
     result = false;
   else if (!m_pELFReader->isMyEndian(ELF_hdr))
     result = false;
   else if (!m_pELFReader->isMyMachine(ELF_hdr))
     result = false;
   else if (Input::Object != m_pELFReader->fileType(ELF_hdr))
     result = false;
   pInput.memArea()->release(region);
   return result;
 }

 /// readHeader - read section header and create LDSections.
 bool ELFObjectReader::readHeader(Input& pInput)
 {
   assert(pInput.hasMemArea());

   size_t hdr_size = m_pELFReader->getELFHeaderSize();
   MemoryRegion* region = pInput.memArea()->request(pInput.fileOffset(),
                                                      hdr_size);
   uint8_t* ELF_hdr = region->start();
   bool result = m_pELFReader->readSectionHeaders(pInput, ELF_hdr);
   pInput.memArea()->release(region);
   return result;
 }

 /// readSections - read all regular sections.
 bool ELFObjectReader::readSections(Input& pInput)
 {
   // handle sections
   LDContext::sect_iterator section, sectEnd = pInput.context()->sectEnd();
   for (section = pInput.context()->sectBegin(); section != sectEnd; ++section) {
     // ignore the section if the LDSection* in input context is NULL
     if (NULL == *section)
         continue;

     switch((*section)->kind()) {
       /** group sections **/
       case LDFileFormat::Group: {
         assert(NULL != (*section)->getLink());
         ResolveInfo* signature =
               m_pELFReader->readSignature(pInput,
                                           *(*section)->getLink(),
                                           (*section)->getInfo());

         bool exist = false;
         if (0 == signature->nameSize() &&
             ResolveInfo::Section == signature->type()) {
           // if the signature is a section symbol in input object, we use the
           // section name as group signature.
           signatures().insert((*section)->name(), exist);
         } else {
           signatures().insert(signature->name(), exist);
         }

         if (exist) {
           // if this is not the first time we see this group signature, then
           // ignore all the members in this group (set Ignore)
           MemoryRegion* region = pInput.memArea()->request(
                pInput.fileOffset() + (*section)->offset(), (*section)->size());
           llvm::ELF::Elf32_Word* value =
                      reinterpret_cast<llvm::ELF::Elf32_Word*>(region->start());

           size_t size = region->size() / sizeof(llvm::ELF::Elf32_Word);
           if (llvm::ELF::GRP_COMDAT == *value) {
             for (size_t index = 1; index < size; ++index) {
               pInput.context()->getSection(value[index])->setKind(LDFileFormat::Ignore);
             }
           }
           pInput.memArea()->release(region);
         }
         ResolveInfo::Destroy(signature);
         break;
       }
       /** relocation sections **/
       case LDFileFormat::Relocation: {
         assert(NULL != (*section)->getLink());
         size_t link_index = (*section)->getLink()->index();
         LDSection* link_sect = pInput.context()->getSection(link_index);
         if (NULL == link_sect || LDFileFormat::Ignore == link_sect->kind()) {
           // Relocation sections of group members should also be part of the
           // group. Thus, if the associated member sections are ignored, the
           // related relocations should be also ignored.
           (*section)->setKind(LDFileFormat::Ignore);
         }
         break;
       }
       /** normal sections **/
       // FIXME: support Version Kind
       case LDFileFormat::Version:
       // FIXME: support GCCExceptTable Kind
       case LDFileFormat::GCCExceptTable:
       /** Fall through **/
       case LDFileFormat::Regular:
       case LDFileFormat::Note:
       case LDFileFormat::MetaData: {
         SectionData* sd = IRBuilder::CreateSectionData(**section);
         if (!m_pELFReader->readRegularSection(pInput, *sd))
           fatal(diag::err_cannot_read_section) << (*section)->name();
         break;
       }
       case LDFileFormat::Debug: {
         if (m_Config.options().stripDebug()) {
           (*section)->setKind(LDFileFormat::Ignore);
         }
         else {
           SectionData* sd = IRBuilder::CreateSectionData(**section);
           if (!m_pELFReader->readRegularSection(pInput, *sd)) {
             fatal(diag::err_cannot_read_section) << (*section)->name();
           }
         }
         break;
       }
       case LDFileFormat::EhFrame: {
         EhFrame* eh_frame = IRBuilder::CreateEhFrame(**section);

         if (m_Config.options().hasEhFrameHdr() &&
             (m_ReadFlag & ParseEhFrame)) {

           // if --eh-frame-hdr option is given, parse .eh_frame.
           if (!m_pEhFrameReader->read<32, true>(pInput, *eh_frame)) {
             // if we failed to parse a .eh_frame, we should not parse the rest
             // .eh_frame.
             m_ReadFlag ^= ParseEhFrame;
           }
         }
         else {
           if (!m_pELFReader->readRegularSection(pInput,
                                                 eh_frame->getSectionData())) {
             fatal(diag::err_cannot_read_section) << (*section)->name();
           }
         }
         break;
       }
       /** target dependent sections **/
       case LDFileFormat::Target: {
         SectionData* sd = IRBuilder::CreateSectionData(**section);
         if (!m_Backend.readSection(pInput, *sd)) {
           fatal(diag::err_cannot_read_target_section) << (*section)->name();
         }
         break;
       }
       /** BSS sections **/
       case LDFileFormat::BSS: {
         IRBuilder::CreateBSS(**section);
         break;
       }
       // ignore
       case LDFileFormat::Null:
       case LDFileFormat::NamePool:
       case LDFileFormat::Ignore:
       case LDFileFormat::StackNote:
         continue;
       // warning
       case LDFileFormat::EhFrameHdr:
       default: {
         warning(diag::warn_illegal_input_section) << (*section)->name()
                                                   << pInput.name()
                                                   << pInput.path();
         break;
       }
     }
   } // end of for all sections

   return true;
 }

 /// readSymbols - read symbols from the input relocatable object.
 bool ELFObjectReader::readSymbols(Input& pInput)
 {
   assert(pInput.hasMemArea());

   LDSection* symtab_shdr = pInput.context()->getSection(".symtab");
   if (NULL == symtab_shdr) {
     note(diag::note_has_no_symtab) << pInput.name()
                                    << pInput.path()
                                    << ".symtab";
     return true;
   }

   LDSection* strtab_shdr = symtab_shdr->getLink();
   if (NULL == strtab_shdr) {
     fatal(diag::fatal_cannot_read_strtab) << pInput.name()
                                           << pInput.path()
                                           << ".symtab";
     return false;
   }

   MemoryRegion* symtab_region = pInput.memArea()->request(
              pInput.fileOffset() + symtab_shdr->offset(), symtab_shdr->size());
   MemoryRegion* strtab_region = pInput.memArea()->request(
              pInput.fileOffset() + strtab_shdr->offset(), strtab_shdr->size());
   char* strtab = reinterpret_cast<char*>(strtab_region->start());
   bool result = m_pELFReader->readSymbols(pInput,
                                           m_Builder,
                                           *symtab_region,
                                           strtab);
   pInput.memArea()->release(symtab_region);
   pInput.memArea()->release(strtab_region);
   return result;
 }

 bool ELFObjectReader::readRelocations(Input& pInput)
 {
   assert(pInput.hasMemArea());

   MemoryArea* mem = pInput.memArea();
   LDContext::sect_iterator rs, rsEnd = pInput.context()->relocSectEnd();
   for (rs = pInput.context()->relocSectBegin(); rs != rsEnd; ++rs) {
     if (LDFileFormat::Ignore == (*rs)->kind())
       continue;

     uint32_t offset = pInput.fileOffset() + (*rs)->offset();
     uint32_t size = (*rs)->size();
     MemoryRegion* region = mem->request(offset, size);
     IRBuilder::CreateRelocData(**rs); ///< create relocation data for the header
     switch ((*rs)->type()) {
       case llvm::ELF::SHT_RELA: {
         if (!m_pELFReader->readRela(pInput, **rs, *region)) {
           mem->release(region);
           return false;
         }
         break;
       }
       case llvm::ELF::SHT_REL: {
         if (!m_pELFReader->readRel(pInput, **rs, *region)) {
           mem->release(region);
           return false;
         }
         break;
       }
       default: { ///< should not enter
         mem->release(region);
         return false;
       }
     } // end of switch

     mem->release(region);
   } // end of for all relocation data

   return true;
 }
	//===- ELFObjectReader.cpp ------------------------------------------------===//
	//
	// The MCLinker Project
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	#include <mcld/LD/ELFObjectReader.h>

	#include <string>
	#include <cassert>

	#include <llvm/Support/ELF.h>
	#include <llvm/ADT/Twine.h>

	#include <mcld/IRBuilder.h>
	#include <mcld/MC/MCLDInput.h>
	#include <mcld/LD/ELFReader.h>
	#include <mcld/LD/EhFrameReader.h>
	#include <mcld/LD/EhFrame.h>
	#include <mcld/Target/GNULDBackend.h>
	#include <mcld/Support/MsgHandling.h>
	#include <mcld/Object/ObjectBuilder.h>

	using namespace mcld;

	//===----------------------------------------------------------------------===//
	// ELFObjectReader
	//===----------------------------------------------------------------------===//
	/// constructor
	ELFObjectReader::ELFObjectReader(GNULDBackend& pBackend,
	IRBuilder& pBuilder,
	const LinkerConfig& pConfig)
	: ObjectReader(),
	m_pELFReader(NULL),
	m_pEhFrameReader(NULL),
	m_Builder(pBuilder),
	m_ReadFlag(ParseEhFrame),
	m_Backend(pBackend),
	m_Config(pConfig) {
	if (pConfig.targets().is32Bits() && pConfig.targets().isLittleEndian()) {
	m_pELFReader = new ELFReader<32, true>(pBackend);
	}

	m_pEhFrameReader = new EhFrameReader();
	}

	/// destructor
	ELFObjectReader::~ELFObjectReader()
	{
	delete m_pELFReader;
	delete m_pEhFrameReader;
	}

	/// isMyFormat
	bool ELFObjectReader::isMyFormat(Input &pInput) const
	{
	assert(pInput.hasMemArea());

	// Don't warning about the frequently requests.
	// MemoryArea has a list of cache to handle this.
	size_t hdr_size = m_pELFReader->getELFHeaderSize();
	MemoryRegion* region = pInput.memArea()->request(pInput.fileOffset(),
	hdr_size);

	uint8_t* ELF_hdr = region->start();
	bool result = true;
	if (!m_pELFReader->isELF(ELF_hdr))
	result = false;
	else if (!m_pELFReader->isMyEndian(ELF_hdr))
	result = false;
	else if (!m_pELFReader->isMyMachine(ELF_hdr))
	result = false;
	else if (Input::Object != m_pELFReader->fileType(ELF_hdr))
	result = false;
	pInput.memArea()->release(region);
	return result;
	}

	/// readHeader - read section header and create LDSections.
	bool ELFObjectReader::readHeader(Input& pInput)
	{
	assert(pInput.hasMemArea());

	size_t hdr_size = m_pELFReader->getELFHeaderSize();
	MemoryRegion* region = pInput.memArea()->request(pInput.fileOffset(),
	hdr_size);
	uint8_t* ELF_hdr = region->start();
	bool result = m_pELFReader->readSectionHeaders(pInput, ELF_hdr);
	pInput.memArea()->release(region);
	return result;
	}

	/// readSections - read all regular sections.
	bool ELFObjectReader::readSections(Input& pInput)
	{
	// handle sections
	LDContext::sect_iterator section, sectEnd = pInput.context()->sectEnd();
	for (section = pInput.context()->sectBegin(); section != sectEnd; ++section) {
	// ignore the section if the LDSection* in input context is NULL
	if (NULL == *section)
	continue;

	switch((*section)->kind()) {
	/ group sections /
	case LDFileFormat::Group: {
	assert(NULL != (*section)->getLink());
	ResolveInfo* signature =
	m_pELFReader->readSignature(pInput,
	(section)->getLink(),
	(*section)->getInfo());

	bool exist = false;
	if (0 == signature->nameSize() &&
	ResolveInfo::Section == signature->type()) {
	// if the signature is a section symbol in input object, we use the
	// section name as group signature.
	signatures().insert((*section)->name(), exist);
	} else {
	signatures().insert(signature->name(), exist);
	}

	if (exist) {
	// if this is not the first time we see this group signature, then
	// ignore all the members in this group (set Ignore)
	MemoryRegion* region = pInput.memArea()->request(
	pInput.fileOffset() + (section)->offset(), (section)->size());
	llvm::ELF::Elf32_Word* value =
	reinterpret_cast<llvm::ELF::Elf32_Word*>(region->start());

	size_t size = region->size() / sizeof(llvm::ELF::Elf32_Word);
	if (llvm::ELF::GRP_COMDAT == *value) {
	for (size_t index = 1; index < size; ++index) {
	pInput.context()->getSection(value[index])->setKind(LDFileFormat::Ignore);
	}
	}
	pInput.memArea()->release(region);
	}
	ResolveInfo::Destroy(signature);
	break;
	}
	/ relocation sections /
	case LDFileFormat::Relocation: {
	assert(NULL != (*section)->getLink());
	size_t link_index = (*section)->getLink()->index();
	LDSection* link_sect = pInput.context()->getSection(link_index);
	if (NULL == link_sect \|\| LDFileFormat::Ignore == link_sect->kind()) {
	// Relocation sections of group members should also be part of the
	// group. Thus, if the associated member sections are ignored, the
	// related relocations should be also ignored.
	(*section)->setKind(LDFileFormat::Ignore);
	}
	break;
	}
	/ normal sections /
	// FIXME: support Version Kind
	case LDFileFormat::Version:
	// FIXME: support GCCExceptTable Kind
	case LDFileFormat::GCCExceptTable:
	/ Fall through /
	case LDFileFormat::Regular:
	case LDFileFormat::Note:
	case LDFileFormat::MetaData: {
	SectionData* sd = IRBuilder::CreateSectionData(**section);
	if (!m_pELFReader->readRegularSection(pInput, *sd))
	fatal(diag::err_cannot_read_section) << (*section)->name();
	break;
	}
	case LDFileFormat::Debug: {
	if (m_Config.options().stripDebug()) {
	(*section)->setKind(LDFileFormat::Ignore);
	}
	else {
	SectionData* sd = IRBuilder::CreateSectionData(**section);
	if (!m_pELFReader->readRegularSection(pInput, *sd)) {
	fatal(diag::err_cannot_read_section) << (*section)->name();
	}
	}
	break;
	}
	case LDFileFormat::EhFrame: {
	EhFrame* eh_frame = IRBuilder::CreateEhFrame(**section);

	if (m_Config.options().hasEhFrameHdr() &&
	(m_ReadFlag & ParseEhFrame)) {

	// if --eh-frame-hdr option is given, parse .eh_frame.
	if (!m_pEhFrameReader->read<32, true>(pInput, *eh_frame)) {
	// if we failed to parse a .eh_frame, we should not parse the rest
	// .eh_frame.
	m_ReadFlag ^= ParseEhFrame;
	}
	}
	else {
	if (!m_pELFReader->readRegularSection(pInput,
	eh_frame->getSectionData())) {
	fatal(diag::err_cannot_read_section) << (*section)->name();
	}
	}
	break;
	}
	/ target dependent sections /
	case LDFileFormat::Target: {
	SectionData* sd = IRBuilder::CreateSectionData(**section);
	if (!m_Backend.readSection(pInput, *sd)) {
	fatal(diag::err_cannot_read_target_section) << (*section)->name();
	}
	break;
	}
	/ BSS sections /
	case LDFileFormat::BSS: {
	IRBuilder::CreateBSS(**section);
	break;
	}
	// ignore
	case LDFileFormat::Null:
	case LDFileFormat::NamePool:
	case LDFileFormat::Ignore:
	case LDFileFormat::StackNote:
	continue;
	// warning
	case LDFileFormat::EhFrameHdr:
	default: {
	warning(diag::warn_illegal_input_section) << (*section)->name()
	<< pInput.name()
	<< pInput.path();
	break;
	}
	}
	} // end of for all sections

	return true;
	}

	/// readSymbols - read symbols from the input relocatable object.
	bool ELFObjectReader::readSymbols(Input& pInput)
	{
	assert(pInput.hasMemArea());

	LDSection* symtab_shdr = pInput.context()->getSection(".symtab");
	if (NULL == symtab_shdr) {
	note(diag::note_has_no_symtab) << pInput.name()
	<< pInput.path()
	<< ".symtab";
	return true;
	}

	LDSection* strtab_shdr = symtab_shdr->getLink();
	if (NULL == strtab_shdr) {
	fatal(diag::fatal_cannot_read_strtab) << pInput.name()
	<< pInput.path()
	<< ".symtab";
	return false;
	}

	MemoryRegion* symtab_region = pInput.memArea()->request(
	pInput.fileOffset() + symtab_shdr->offset(), symtab_shdr->size());
	MemoryRegion* strtab_region = pInput.memArea()->request(
	pInput.fileOffset() + strtab_shdr->offset(), strtab_shdr->size());
	char* strtab = reinterpret_cast<char*>(strtab_region->start());
	bool result = m_pELFReader->readSymbols(pInput,
	m_Builder,
	*symtab_region,
	strtab);
	pInput.memArea()->release(symtab_region);
	pInput.memArea()->release(strtab_region);
	return result;
	}

	bool ELFObjectReader::readRelocations(Input& pInput)
	{
	assert(pInput.hasMemArea());

	MemoryArea* mem = pInput.memArea();
	LDContext::sect_iterator rs, rsEnd = pInput.context()->relocSectEnd();
	for (rs = pInput.context()->relocSectBegin(); rs != rsEnd; ++rs) {
	if (LDFileFormat::Ignore == (*rs)->kind())
	continue;

	uint32_t offset = pInput.fileOffset() + (*rs)->offset();
	uint32_t size = (*rs)->size();
	MemoryRegion* region = mem->request(offset, size);
	IRBuilder::CreateRelocData(**rs); ///< create relocation data for the header
	switch ((*rs)->type()) {
	case llvm::ELF::SHT_RELA: {
	if (!m_pELFReader->readRela(pInput, *rs, region)) {
	mem->release(region);
	return false;
	}
	break;
	}
	case llvm::ELF::SHT_REL: {
	if (!m_pELFReader->readRel(pInput, *rs, region)) {
	mem->release(region);
	return false;
	}
	break;
	}
	default: { ///< should not enter
	mem->release(region);
	return false;
	}
	} // end of switch

	mem->release(region);
	} // end of for all relocation data

	return true;
	}