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

 //===- EhFrame.cpp --------------------------------------------------------===//
 //
 //                     The MCLinker Project
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include <mcld/LD/EhFrame.h>

 #include <llvm/Support/Dwarf.h>
 #include <llvm/Support/Host.h>

 #include <mcld/MC/MCLinker.h>
 #include <mcld/Target/TargetLDBackend.h>
 #include <mcld/Support/MsgHandling.h>

 using namespace mcld;

 //==========================
 // EhFrame
 EhFrame::EhFrame()
  : m_fCanRecognizeAll(true) {
 }

 EhFrame::~EhFrame()
 {
 }

 uint64_t EhFrame::readEhFrame(Layout& pLayout,
                               const TargetLDBackend& pBackend,
                               SectionData& pSD,
                               const Input& pInput,
                               LDSection& pSection,
                               MemoryArea& pArea)
 {
   MemoryRegion* region = pArea.request(
                      pInput.fileOffset() + pSection.offset(), pSection.size());
   // an empty .eh_frame
   if (NULL == region) {
     return 0;
   }

   ConstAddress eh_start = region->start();
   ConstAddress eh_end = region->end();
   ConstAddress p = eh_start;

   // read the Length filed
   uint32_t len = readVal(p, pBackend.isLittleEndian());

   // This CIE is a terminator if the Length field is 0, return 0 to handled it
   // as an ordinary input.
   if (0 == len) {
     pArea.release(region);
     return 0;
   }

   if (0xffffffff == len) {
     debug(diag::debug_eh_unsupport) << pInput.name();
     pArea.release(region);
     m_fCanRecognizeAll = false;
     return 0;
   }

   // record the order of the CIE and FDE fragments
   FragListType frag_list;

   while (p < eh_end) {

     if (eh_end - p < 4) {
       debug(diag::debug_eh_unsupport) << pInput.name();
       m_fCanRecognizeAll = false;
       break;
     }
     // read the Length field
     len = readVal(p, pBackend.isLittleEndian());
     p += 4;

     // the zero length entry should be the end of the section
     if (0 == len) {
       if (p < eh_end) {
         debug(diag::debug_eh_unsupport) << pInput.name();
         m_fCanRecognizeAll = false;
       }
       break;
     }
     if (0xffffffff == len) {
       debug(diag::debug_eh_unsupport) << pInput.name();
       m_fCanRecognizeAll = false;
       break;
     }

     if (eh_end - p < 4) {
       debug(diag::debug_eh_unsupport) << pInput.name();
       m_fCanRecognizeAll = false;
       break;
     }

     // compute the section offset of this entry
     uint32_t ent_offset = static_cast<uint32_t>(p - eh_start - 4);

     // get the MemoryRegion for this entry
     MemoryRegion* ent_region = pArea.request(
                 pInput.fileOffset() + pSection.offset() + ent_offset, len + 4);

     // create and add a CIE or FDE entry
     uint32_t id = readVal(p, pBackend.isLittleEndian());
     // CIE
     if (0 == id) {
       if (!addCIE(*ent_region, pBackend, frag_list)) {
         m_fCanRecognizeAll = false;
         pArea.release(ent_region);
         break;
       }
     }

     // FDE
     else {
       if (!addFDE(*ent_region, pBackend, frag_list)) {
         m_fCanRecognizeAll = false;
         pArea.release(ent_region);
         break;
       }
     }
     p += len;
   }

   if (!m_fCanRecognizeAll) {
     debug(diag::debug_eh_unsupport) << pInput.name();
     pArea.release(region);
     deleteFragments(frag_list, pArea);
     return 0;
   }

   // append all CIE and FDE fragments to Layout after we successfully read
   // this eh_frame
   size_t section_size = 0;
   for (FragListType::iterator it = frag_list.begin();
          it != frag_list.end(); ++it)
     section_size += pLayout.appendFragment(**it, pSD, pSection.align());

   pArea.release(region);
   return section_size;
 }

 bool EhFrame::addCIE(MemoryRegion& pRegion,
                      const TargetLDBackend& pBackend,
                      FragListType& pFragList)
 {
   ConstAddress cie_start = pRegion.start();
   ConstAddress cie_end = pRegion.end();
   ConstAddress p = cie_start;

   // skip the Length (4 byte) and CIE ID (4 byte) fields
   p += 8;

   // the version should be 1
   if (1 != *p) {
     return false;
   }
   ++p;

   // get the Augumentation String
   ConstAddress aug_str = p;
   ConstAddress aug_str_end = static_cast<ConstAddress>(
                                memchr(p, '\0', cie_end - p));

   // skip the Augumentation String field
   p = aug_str_end + 1;

   // skip the Code Alignment Factor
   if (!skipLEB128(&p, cie_end)) {
     return false;
   }
   // skip the Data Alignment Factor
   if (!skipLEB128(&p, cie_end)) {
     return false;
   }
   // skip the Return Address Register
   if (cie_end - p < 1) {
     return false;
   }
   ++p;

   // the Augmentation String start with 'eh' is a CIE from gcc before 3.0,
   // in LSB Core Spec 3.0RC1. We do not support it.
   if (aug_str[0] == 'e' && aug_str[1] == 'h') {
     return false;
   }

   // parse the Augmentation String to get the FDE encodeing if 'z' existed
   std::string aug_str_data;
   uint8_t fde_encoding = llvm::dwarf::DW_EH_PE_absptr;
   if (*aug_str == 'z') {

     aug_str_data += *aug_str;
     ++aug_str;

     // skip the Augumentation Data Length
     if (!skipLEB128(&p, cie_end)) {
       return false;
     }

     while (aug_str != aug_str_end) {
       switch (*aug_str) {
         default:
           return false;

         // LDSA encoding (1 byte)
         case 'L':
           if (cie_end - p < 1) {
             return false;
           }
           ++p;
           break;

         // Two arguments, the first one represents the encoding of the second
         // argument (1 byte). The second one is the address of personality
         // routine.
         case 'P': {
           // the first argument
           if (cie_end - p < 1) {
             return false;
           }
           uint8_t per_encode = *p;
           ++p;
           // get the length of the second argument
           uint32_t per_length = 0;
           if (0x60 == (per_encode & 0x60)) {
             return false;
           }
           switch (per_encode & 7) {
             default:
               return false;
             case llvm::dwarf::DW_EH_PE_udata2:
               per_length = 2;
               break;
             case llvm::dwarf::DW_EH_PE_udata4:
               per_length = 4;
               break;
             case llvm::dwarf::DW_EH_PE_udata8:
               per_length = 8;
               break;
             case llvm::dwarf::DW_EH_PE_absptr:
               per_length = pBackend.bitclass() / 8;
               break;
           }
           // skip the alignment
           if (llvm::dwarf::DW_EH_PE_aligned == (per_encode & 0xf0)) {
             uint32_t per_align = p - cie_end;
             per_align += per_length - 1;
             per_align &= ~(per_length -1);
             if (static_cast<uint32_t>(cie_end - p) < per_align) {
               return false;
             }
             p += per_align;
           }
           // skip the second argument
           if (static_cast<uint32_t>(cie_end - p) < per_length) {
             return false;
           }
           p += per_length;
         }
         break;

         // FDE encoding (1 byte)
         case 'R':
           if (cie_end - p < 1) {
             return false;
           }
           fde_encoding = *p;
           switch (fde_encoding & 7) {
             case llvm::dwarf::DW_EH_PE_udata2:
             case llvm::dwarf::DW_EH_PE_udata4:
             case llvm::dwarf::DW_EH_PE_udata8:
             case llvm::dwarf::DW_EH_PE_absptr:
               break;
             default:
               return false;
           }
           ++p;
           break;
       } // end switch
       aug_str_data += *aug_str;
       ++aug_str;
     } // end while
   }

   note(diag::note_eh_cie) << pRegion.size()
                           << aug_str_data
                           << (fde_encoding & 7);

   // create and push back the CIE entry
   CIE* entry = new CIE(pRegion, fde_encoding);
   m_CIEs.push_back(entry);
   pFragList.push_back(static_cast<Fragment*>(entry));
   return true;
 }

 bool EhFrame::addFDE(MemoryRegion& pRegion,
                      const TargetLDBackend& pBackend,
                      FragListType& pFragList)
 {
   ConstAddress fde_start = pRegion.start();
   ConstAddress fde_end = pRegion.end();
   ConstAddress p = fde_start;

   // skip the Length (4 byte) and CIE Pointer (4 byte) fields
   p += 8;

   // get the entry offset of the PC Begin
   if (fde_end - p < 1) {
     return false;
   }
   FDE::Offset pc_offset = static_cast<FDE::Offset>(p - fde_start);

   note(diag::note_eh_fde) << pRegion.size() << pc_offset;
   // create and push back the FDE entry
   FDE* entry = new FDE(pRegion, **(m_CIEs.end() -1), pc_offset);
   m_FDEs.push_back(entry);
   pFragList.push_back(static_cast<Fragment*>(entry));
   return true;
 }

 uint32_t EhFrame::readVal(ConstAddress pAddr, bool pIsTargetLittleEndian)
 {
   const uint32_t* p = reinterpret_cast<const uint32_t*>(pAddr);
   uint32_t val = *p;

   // byte swapping if the host and target have different endian
   if (llvm::sys::isLittleEndianHost() != pIsTargetLittleEndian)
     val = bswap32(val);
   return val;
 }

 bool EhFrame::skipLEB128(ConstAddress* pp, ConstAddress pend)
 {
   for (ConstAddress p = *pp; p < pend; ++p) {
     if (0 == (*p & 0x80)) {
       *pp = p + 1;
       return true;
     }
   }
   return false;
 }

 void EhFrame::deleteFragments(FragListType& pList, MemoryArea& pArea)
 {
   RegionFragment* frag = NULL;
   for (FragListType::iterator it = pList.begin(); it != pList.end(); ++it) {
     frag = static_cast<RegionFragment*>(*it);
     pArea.release(&(frag->getRegion()));
     delete *it;
   }
   pList.clear();
 }
	//===- EhFrame.cpp --------------------------------------------------------===//
	//
	// The MCLinker Project
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include <mcld/LD/EhFrame.h>

	#include <llvm/Support/Dwarf.h>
	#include <llvm/Support/Host.h>

	#include <mcld/MC/MCLinker.h>
	#include <mcld/Target/TargetLDBackend.h>
	#include <mcld/Support/MsgHandling.h>

	using namespace mcld;

	//==========================
	// EhFrame
	EhFrame::EhFrame()
	: m_fCanRecognizeAll(true) {
	}

	EhFrame::~EhFrame()
	{
	}

	uint64_t EhFrame::readEhFrame(Layout& pLayout,
	const TargetLDBackend& pBackend,
	SectionData& pSD,
	const Input& pInput,
	LDSection& pSection,
	MemoryArea& pArea)
	{
	MemoryRegion* region = pArea.request(
	pInput.fileOffset() + pSection.offset(), pSection.size());
	// an empty .eh_frame
	if (NULL == region) {
	return 0;
	}

	ConstAddress eh_start = region->start();
	ConstAddress eh_end = region->end();
	ConstAddress p = eh_start;

	// read the Length filed
	uint32_t len = readVal(p, pBackend.isLittleEndian());

	// This CIE is a terminator if the Length field is 0, return 0 to handled it
	// as an ordinary input.
	if (0 == len) {
	pArea.release(region);
	return 0;
	}

	if (0xffffffff == len) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	pArea.release(region);
	m_fCanRecognizeAll = false;
	return 0;
	}

	// record the order of the CIE and FDE fragments
	FragListType frag_list;

	while (p < eh_end) {

	if (eh_end - p < 4) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	m_fCanRecognizeAll = false;
	break;
	}
	// read the Length field
	len = readVal(p, pBackend.isLittleEndian());
	p += 4;

	// the zero length entry should be the end of the section
	if (0 == len) {
	if (p < eh_end) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	m_fCanRecognizeAll = false;
	}
	break;
	}
	if (0xffffffff == len) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	m_fCanRecognizeAll = false;
	break;
	}

	if (eh_end - p < 4) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	m_fCanRecognizeAll = false;
	break;
	}

	// compute the section offset of this entry
	uint32_t ent_offset = static_cast<uint32_t>(p - eh_start - 4);

	// get the MemoryRegion for this entry
	MemoryRegion* ent_region = pArea.request(
	pInput.fileOffset() + pSection.offset() + ent_offset, len + 4);

	// create and add a CIE or FDE entry
	uint32_t id = readVal(p, pBackend.isLittleEndian());
	// CIE
	if (0 == id) {
	if (!addCIE(*ent_region, pBackend, frag_list)) {
	m_fCanRecognizeAll = false;
	pArea.release(ent_region);
	break;
	}
	}

	// FDE
	else {
	if (!addFDE(*ent_region, pBackend, frag_list)) {
	m_fCanRecognizeAll = false;
	pArea.release(ent_region);
	break;
	}
	}
	p += len;
	}

	if (!m_fCanRecognizeAll) {
	debug(diag::debug_eh_unsupport) << pInput.name();
	pArea.release(region);
	deleteFragments(frag_list, pArea);
	return 0;
	}

	// append all CIE and FDE fragments to Layout after we successfully read
	// this eh_frame
	size_t section_size = 0;
	for (FragListType::iterator it = frag_list.begin();
	it != frag_list.end(); ++it)
	section_size += pLayout.appendFragment(**it, pSD, pSection.align());

	pArea.release(region);
	return section_size;
	}

	bool EhFrame::addCIE(MemoryRegion& pRegion,
	const TargetLDBackend& pBackend,
	FragListType& pFragList)
	{
	ConstAddress cie_start = pRegion.start();
	ConstAddress cie_end = pRegion.end();
	ConstAddress p = cie_start;

	// skip the Length (4 byte) and CIE ID (4 byte) fields
	p += 8;

	// the version should be 1
	if (1 != *p) {
	return false;
	}
	++p;

	// get the Augumentation String
	ConstAddress aug_str = p;
	ConstAddress aug_str_end = static_cast<ConstAddress>(
	memchr(p, '\0', cie_end - p));

	// skip the Augumentation String field
	p = aug_str_end + 1;

	// skip the Code Alignment Factor
	if (!skipLEB128(&p, cie_end)) {
	return false;
	}
	// skip the Data Alignment Factor
	if (!skipLEB128(&p, cie_end)) {
	return false;
	}
	// skip the Return Address Register
	if (cie_end - p < 1) {
	return false;
	}
	++p;

	// the Augmentation String start with 'eh' is a CIE from gcc before 3.0,
	// in LSB Core Spec 3.0RC1. We do not support it.
	if (aug_str[0] == 'e' && aug_str[1] == 'h') {
	return false;
	}

	// parse the Augmentation String to get the FDE encodeing if 'z' existed
	std::string aug_str_data;
	uint8_t fde_encoding = llvm::dwarf::DW_EH_PE_absptr;
	if (*aug_str == 'z') {

	aug_str_data += *aug_str;
	++aug_str;

	// skip the Augumentation Data Length
	if (!skipLEB128(&p, cie_end)) {
	return false;
	}

	while (aug_str != aug_str_end) {
	switch (*aug_str) {
	default:
	return false;

	// LDSA encoding (1 byte)
	case 'L':
	if (cie_end - p < 1) {
	return false;
	}
	++p;
	break;

	// Two arguments, the first one represents the encoding of the second
	// argument (1 byte). The second one is the address of personality
	// routine.
	case 'P': {
	// the first argument
	if (cie_end - p < 1) {
	return false;
	}
	uint8_t per_encode = *p;
	++p;
	// get the length of the second argument
	uint32_t per_length = 0;
	if (0x60 == (per_encode & 0x60)) {
	return false;
	}
	switch (per_encode & 7) {
	default:
	return false;
	case llvm::dwarf::DW_EH_PE_udata2:
	per_length = 2;
	break;
	case llvm::dwarf::DW_EH_PE_udata4:
	per_length = 4;
	break;
	case llvm::dwarf::DW_EH_PE_udata8:
	per_length = 8;
	break;
	case llvm::dwarf::DW_EH_PE_absptr:
	per_length = pBackend.bitclass() / 8;
	break;
	}
	// skip the alignment
	if (llvm::dwarf::DW_EH_PE_aligned == (per_encode & 0xf0)) {
	uint32_t per_align = p - cie_end;
	per_align += per_length - 1;
	per_align &= ~(per_length -1);
	if (static_cast<uint32_t>(cie_end - p) < per_align) {
	return false;
	}
	p += per_align;
	}
	// skip the second argument
	if (static_cast<uint32_t>(cie_end - p) < per_length) {
	return false;
	}
	p += per_length;
	}
	break;

	// FDE encoding (1 byte)
	case 'R':
	if (cie_end - p < 1) {
	return false;
	}
	fde_encoding = *p;
	switch (fde_encoding & 7) {
	case llvm::dwarf::DW_EH_PE_udata2:
	case llvm::dwarf::DW_EH_PE_udata4:
	case llvm::dwarf::DW_EH_PE_udata8:
	case llvm::dwarf::DW_EH_PE_absptr:
	break;
	default:
	return false;
	}
	++p;
	break;
	} // end switch
	aug_str_data += *aug_str;
	++aug_str;
	} // end while
	}

	note(diag::note_eh_cie) << pRegion.size()
	<< aug_str_data
	<< (fde_encoding & 7);

	// create and push back the CIE entry
	CIE* entry = new CIE(pRegion, fde_encoding);
	m_CIEs.push_back(entry);
	pFragList.push_back(static_cast<Fragment*>(entry));
	return true;
	}

	bool EhFrame::addFDE(MemoryRegion& pRegion,
	const TargetLDBackend& pBackend,
	FragListType& pFragList)
	{
	ConstAddress fde_start = pRegion.start();
	ConstAddress fde_end = pRegion.end();
	ConstAddress p = fde_start;

	// skip the Length (4 byte) and CIE Pointer (4 byte) fields
	p += 8;

	// get the entry offset of the PC Begin
	if (fde_end - p < 1) {
	return false;
	}
	FDE::Offset pc_offset = static_cast<FDE::Offset>(p - fde_start);

	note(diag::note_eh_fde) << pRegion.size() << pc_offset;
	// create and push back the FDE entry
	FDE* entry = new FDE(pRegion, **(m_CIEs.end() -1), pc_offset);
	m_FDEs.push_back(entry);
	pFragList.push_back(static_cast<Fragment*>(entry));
	return true;
	}

	uint32_t EhFrame::readVal(ConstAddress pAddr, bool pIsTargetLittleEndian)
	{
	const uint32_t* p = reinterpret_cast<const uint32_t*>(pAddr);
	uint32_t val = *p;

	// byte swapping if the host and target have different endian
	if (llvm::sys::isLittleEndianHost() != pIsTargetLittleEndian)
	val = bswap32(val);
	return val;
	}

	bool EhFrame::skipLEB128(ConstAddress* pp, ConstAddress pend)
	{
	for (ConstAddress p = *pp; p < pend; ++p) {
	if (0 == (*p & 0x80)) {
	*pp = p + 1;
	return true;
	}
	}
	return false;
	}

	void EhFrame::deleteFragments(FragListType& pList, MemoryArea& pArea)
	{
	RegionFragment* frag = NULL;
	for (FragListType::iterator it = pList.begin(); it != pList.end(); ++it) {
	frag = static_cast<RegionFragment>(it);
	pArea.release(&(frag->getRegion()));
	delete *it;
	}
	pList.clear();
	}