lib/Target/X86/X86PLT.cpp - platform/frameworks/compile/mclinker - Git at Google

 //===- X86PLT.cpp ---------------------------------------------------------===//
 //
 //                     The MCLinker Project
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 #include "X86GOTPLT.h"
 #include "X86PLT.h"

 #include <llvm/Support/ELF.h>
 #include <llvm/Support/Casting.h>

 #include <mcld/LD/LDSection.h>
 #include <mcld/LinkerConfig.h>
 #include <mcld/Support/MsgHandling.h>

 using namespace mcld;

 //===----------------------------------------------------------------------===//
 // PLT entry data
 //===----------------------------------------------------------------------===//
 X86_32DynPLT0::X86_32DynPLT0(SectionData& pParent)
   : PLT::Entry<sizeof(x86_32_dyn_plt0)>(pParent)
 {
 }

 X86_32DynPLT1::X86_32DynPLT1(SectionData& pParent)
   : PLT::Entry<sizeof(x86_32_dyn_plt1)>(pParent)
 {
 }

 X86_32ExecPLT0::X86_32ExecPLT0(SectionData& pParent)
   : PLT::Entry<sizeof(x86_32_exec_plt0)>(pParent)
 {
 }

 X86_32ExecPLT1::X86_32ExecPLT1(SectionData& pParent)
   : PLT::Entry<sizeof(x86_32_exec_plt1)>(pParent)
 {
 }

 X86_64PLT0::X86_64PLT0(SectionData& pParent)
   : PLT::Entry<sizeof(x86_64_plt0)>(pParent)
 {
 }

 X86_64PLT1::X86_64PLT1(SectionData& pParent)
   : PLT::Entry<sizeof(x86_64_plt1)>(pParent)
 {
 }

 //===----------------------------------------------------------------------===//
 // X86PLT
 //===----------------------------------------------------------------------===//
 X86PLT::X86PLT(LDSection& pSection,
 	       const LinkerConfig& pConfig,
 	       int got_size)
   : PLT(pSection),
     m_Config(pConfig)
 {
   assert(LinkerConfig::DynObj == m_Config.codeGenType() ||
          LinkerConfig::Exec   == m_Config.codeGenType() ||
          LinkerConfig::Binary == m_Config.codeGenType());

   if (got_size == 32) {
     if (LinkerConfig::DynObj == m_Config.codeGenType()) {
       m_PLT0 = x86_32_dyn_plt0;
       m_PLT1 = x86_32_dyn_plt1;
       m_PLT0Size = sizeof (x86_32_dyn_plt0);
       m_PLT1Size = sizeof (x86_32_dyn_plt1);
       // create PLT0
       new X86_32DynPLT0(*m_SectionData);
     }
     else {
       m_PLT0 = x86_32_exec_plt0;
       m_PLT1 = x86_32_exec_plt1;
       m_PLT0Size = sizeof (x86_32_exec_plt0);
       m_PLT1Size = sizeof (x86_32_exec_plt1);
       // create PLT0
       new X86_32ExecPLT0(*m_SectionData);
     }
   }
   else {
     assert(got_size == 64);
     m_PLT0 = x86_64_plt0;
     m_PLT1 = x86_64_plt1;
     m_PLT0Size = sizeof (x86_64_plt0);
     m_PLT1Size = sizeof (x86_64_plt1);
     // create PLT0
     new X86_64PLT0(*m_SectionData);
     m_Last = m_SectionData->begin();
   }
   m_Last = m_SectionData->begin();
 }

 X86PLT::~X86PLT()
 {
 }

 void X86PLT::finalizeSectionSize()
 {
   uint64_t size = 0;
   // plt0 size
   size = getPLT0()->size();

   // get first plt1 entry
   X86PLT::iterator it = begin();
   ++it;
   if (end() != it) {
     // plt1 size
     PLTEntryBase* plt1 = &(llvm::cast<PLTEntryBase>(*it));
     size += (m_SectionData->size() - 1) * plt1->size();
   }
   m_Section.setSize(size);

   uint32_t offset = 0;
   SectionData::iterator frag, fragEnd = m_SectionData->end();
   for (frag = m_SectionData->begin(); frag != fragEnd; ++frag) {
     frag->setOffset(offset);
     offset += frag->size();
   }
 }

 bool X86PLT::hasPLT1() const
 {
   return (m_SectionData->size() > 1);
 }

 void X86PLT::reserveEntry(size_t pNum)
 {
   PLTEntryBase* plt1_entry = NULL;

   for (size_t i = 0; i < pNum; ++i) {

     if (LinkerConfig::DynObj == m_Config.codeGenType())
       plt1_entry = new X86_32DynPLT1(*m_SectionData);
     else
       plt1_entry = new X86_32ExecPLT1(*m_SectionData);

     if (NULL == plt1_entry)
       fatal(diag::fail_allocate_memory_plt);
   }
 }

 PLTEntryBase* X86PLT::consume()
 {
   // This will skip PLT0.
   ++m_Last;
   assert(m_Last != m_SectionData->end() &&
          "The number of PLT Entries and ResolveInfo doesn't match");
   return llvm::cast<PLTEntryBase>(&(*m_Last));
 }

 PLTEntryBase* X86PLT::getPLT0() const
 {
   iterator first = m_SectionData->getFragmentList().begin();

   assert(first != m_SectionData->getFragmentList().end() &&
          "FragmentList is empty, getPLT0 failed!");

   PLTEntryBase* plt0 = &(llvm::cast<PLTEntryBase>(*first));

   return plt0;
 }

 //===----------------------------------------------------------------------===//
 // X86_32PLT
 //===----------------------------------------------------------------------===//
 X86_32PLT::X86_32PLT(LDSection& pSection,
 		     X86_32GOTPLT& pGOTPLT,
 		     const LinkerConfig& pConfig)
   : X86PLT(pSection, pConfig, 32),
     m_GOTPLT(pGOTPLT) {
 }

 // FIXME: It only works on little endian machine.
 void X86_32PLT::applyPLT0()
 {
   PLTEntryBase* plt0 = getPLT0();

   unsigned char* data = 0;
   data = static_cast<unsigned char*>(malloc(plt0->size()));

   if (!data)
     fatal(diag::fail_allocate_memory_plt);

   memcpy(data, m_PLT0, plt0->size());

   if (m_PLT0 == x86_32_exec_plt0) {
     uint32_t *offset = reinterpret_cast<uint32_t*>(data + 2);
     *offset = m_GOTPLT.addr() + 4;
     offset = reinterpret_cast<uint32_t*>(data + 8);
     *offset = m_GOTPLT.addr() + 8;
   }

   plt0->setValue(data);
 }

 // FIXME: It only works on little endian machine.
 void X86_32PLT::applyPLT1()
 {
   assert(m_Section.addr() && ".plt base address is NULL!");

   X86PLT::iterator it = m_SectionData->begin();
   X86PLT::iterator ie = m_SectionData->end();
   assert(it != ie && "FragmentList is empty, applyPLT1 failed!");

   uint64_t GOTEntrySize = X86_32GOTEntry::EntrySize;

   // Skip GOT0
   uint64_t GOTEntryOffset = GOTEntrySize * X86GOTPLT0Num;
   if (LinkerConfig::Exec == m_Config.codeGenType())
     GOTEntryOffset += m_GOTPLT.addr();

   //skip PLT0
   uint64_t PLTEntryOffset = m_PLT0Size;
   ++it;

   PLTEntryBase* plt1 = 0;

   uint64_t PLTRelOffset = 0;

   while (it != ie) {
     plt1 = &(llvm::cast<PLTEntryBase>(*it));
     unsigned char *data;
     data = static_cast<unsigned char*>(malloc(plt1->size()));

     if (!data)
       fatal(diag::fail_allocate_memory_plt);

     memcpy(data, m_PLT1, plt1->size());

     uint32_t* offset;

     offset = reinterpret_cast<uint32_t*>(data + 2);
     *offset = GOTEntryOffset;
     GOTEntryOffset += GOTEntrySize;

     offset = reinterpret_cast<uint32_t*>(data + 7);
     *offset = PLTRelOffset;
     PLTRelOffset += sizeof (llvm::ELF::Elf32_Rel);

     offset = reinterpret_cast<uint32_t*>(data + 12);
     *offset = -(PLTEntryOffset + 12 + 4);
     PLTEntryOffset += m_PLT1Size;

     plt1->setValue(data);
     ++it;
   }
 }

 //===----------------------------------------------------------------------===//
 // X86_64PLT
 //===----------------------------------------------------------------------===//
 X86_64PLT::X86_64PLT(LDSection& pSection,
 		     X86_64GOTPLT& pGOTPLT,
 		     const LinkerConfig& pConfig)
   : X86PLT(pSection, pConfig, 64),
     m_GOTPLT(pGOTPLT) {
 }

 // FIXME: It only works on little endian machine.
 void X86_64PLT::applyPLT0()
 {
   PLTEntryBase* plt0 = getPLT0();

   unsigned char* data = 0;
   data = static_cast<unsigned char*>(malloc(plt0->size()));

   if (!data)
     fatal(diag::fail_allocate_memory_plt);

   memcpy(data, m_PLT0, plt0->size());

   // pushq GOT + 8(%rip)
   uint32_t *offset = reinterpret_cast<uint32_t*>(data + 2);
   *offset = m_GOTPLT.addr() - addr() + 8 - 6;
   // jmq *GOT + 16(%rip)
   offset = reinterpret_cast<uint32_t*>(data + 8);
   *offset = m_GOTPLT.addr() - addr() + 16 - 12;

   plt0->setValue(data);
 }

 // FIXME: It only works on little endian machine.
 void X86_64PLT::applyPLT1()
 {
   assert(m_Section.addr() && ".plt base address is NULL!");

   X86PLT::iterator it = m_SectionData->begin();
   X86PLT::iterator ie = m_SectionData->end();
   assert(it != ie && "FragmentList is empty, applyPLT1 failed!");

   uint64_t GOTEntrySize = X86_64GOTEntry::EntrySize;

   // compute sym@GOTPCREL of the PLT1 entry.
   uint64_t SymGOTPCREL = m_GOTPLT.addr();

   // Skip GOT0
   SymGOTPCREL += GOTEntrySize * X86GOTPLT0Num;

   // skip PLT0
   uint64_t PLTEntryOffset = m_PLT0Size;
   ++it;

   // PC-relative to entry in PLT section.
   SymGOTPCREL -= addr() + PLTEntryOffset + 6;

   PLTEntryBase* plt1 = 0;

   uint64_t PLTRelIndex = 0;

   while (it != ie) {
     plt1 = &(llvm::cast<PLTEntryBase>(*it));
     unsigned char *data;
     data = static_cast<unsigned char*>(malloc(plt1->size()));

     if (!data)
       fatal(diag::fail_allocate_memory_plt);

     memcpy(data, m_PLT1, plt1->size());

     uint32_t* offset;

     // jmpq *sym@GOTPCREL(%rip)
     offset = reinterpret_cast<uint32_t*>(data + 2);
     *offset = SymGOTPCREL;
     SymGOTPCREL += GOTEntrySize - m_PLT1Size;

     // pushq $index
     offset = reinterpret_cast<uint32_t*>(data + 7);
     *offset = PLTRelIndex;
     PLTRelIndex++;

     // jmpq plt0
     offset = reinterpret_cast<uint32_t*>(data + 12);
     *offset = -(PLTEntryOffset + 12 + 4);
     PLTEntryOffset += m_PLT1Size;

     plt1->setValue(data);
     ++it;
   }
 }
	//===- X86PLT.cpp ---------------------------------------------------------===//
	//
	// The MCLinker Project
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	#include "X86GOTPLT.h"
	#include "X86PLT.h"

	#include <llvm/Support/ELF.h>
	#include <llvm/Support/Casting.h>

	#include <mcld/LD/LDSection.h>
	#include <mcld/LinkerConfig.h>
	#include <mcld/Support/MsgHandling.h>

	using namespace mcld;

	//===----------------------------------------------------------------------===//
	// PLT entry data
	//===----------------------------------------------------------------------===//
	X86_32DynPLT0::X86_32DynPLT0(SectionData& pParent)
	: PLT::Entry<sizeof(x86_32_dyn_plt0)>(pParent)
	{
	}

	X86_32DynPLT1::X86_32DynPLT1(SectionData& pParent)
	: PLT::Entry<sizeof(x86_32_dyn_plt1)>(pParent)
	{
	}

	X86_32ExecPLT0::X86_32ExecPLT0(SectionData& pParent)
	: PLT::Entry<sizeof(x86_32_exec_plt0)>(pParent)
	{
	}

	X86_32ExecPLT1::X86_32ExecPLT1(SectionData& pParent)
	: PLT::Entry<sizeof(x86_32_exec_plt1)>(pParent)
	{
	}

	X86_64PLT0::X86_64PLT0(SectionData& pParent)
	: PLT::Entry<sizeof(x86_64_plt0)>(pParent)
	{
	}

	X86_64PLT1::X86_64PLT1(SectionData& pParent)
	: PLT::Entry<sizeof(x86_64_plt1)>(pParent)
	{
	}

	//===----------------------------------------------------------------------===//
	// X86PLT
	//===----------------------------------------------------------------------===//
	X86PLT::X86PLT(LDSection& pSection,
	const LinkerConfig& pConfig,
	int got_size)
	: PLT(pSection),
	m_Config(pConfig)
	{
	assert(LinkerConfig::DynObj == m_Config.codeGenType() \|\|
	LinkerConfig::Exec == m_Config.codeGenType() \|\|
	LinkerConfig::Binary == m_Config.codeGenType());

	if (got_size == 32) {
	if (LinkerConfig::DynObj == m_Config.codeGenType()) {
	m_PLT0 = x86_32_dyn_plt0;
	m_PLT1 = x86_32_dyn_plt1;
	m_PLT0Size = sizeof (x86_32_dyn_plt0);
	m_PLT1Size = sizeof (x86_32_dyn_plt1);
	// create PLT0
	new X86_32DynPLT0(*m_SectionData);
	}
	else {
	m_PLT0 = x86_32_exec_plt0;
	m_PLT1 = x86_32_exec_plt1;
	m_PLT0Size = sizeof (x86_32_exec_plt0);
	m_PLT1Size = sizeof (x86_32_exec_plt1);
	// create PLT0
	new X86_32ExecPLT0(*m_SectionData);
	}
	}
	else {
	assert(got_size == 64);
	m_PLT0 = x86_64_plt0;
	m_PLT1 = x86_64_plt1;
	m_PLT0Size = sizeof (x86_64_plt0);
	m_PLT1Size = sizeof (x86_64_plt1);
	// create PLT0
	new X86_64PLT0(*m_SectionData);
	m_Last = m_SectionData->begin();
	}
	m_Last = m_SectionData->begin();
	}

	X86PLT::~X86PLT()
	{
	}

	void X86PLT::finalizeSectionSize()
	{
	uint64_t size = 0;
	// plt0 size
	size = getPLT0()->size();

	// get first plt1 entry
	X86PLT::iterator it = begin();
	++it;
	if (end() != it) {
	// plt1 size
	PLTEntryBase* plt1 = &(llvm::cast<PLTEntryBase>(*it));
	size += (m_SectionData->size() - 1) * plt1->size();
	}
	m_Section.setSize(size);

	uint32_t offset = 0;
	SectionData::iterator frag, fragEnd = m_SectionData->end();
	for (frag = m_SectionData->begin(); frag != fragEnd; ++frag) {
	frag->setOffset(offset);
	offset += frag->size();
	}
	}

	bool X86PLT::hasPLT1() const
	{
	return (m_SectionData->size() > 1);
	}

	void X86PLT::reserveEntry(size_t pNum)
	{
	PLTEntryBase* plt1_entry = NULL;

	for (size_t i = 0; i < pNum; ++i) {

	if (LinkerConfig::DynObj == m_Config.codeGenType())
	plt1_entry = new X86_32DynPLT1(*m_SectionData);
	else
	plt1_entry = new X86_32ExecPLT1(*m_SectionData);

	if (NULL == plt1_entry)
	fatal(diag::fail_allocate_memory_plt);
	}
	}

	PLTEntryBase* X86PLT::consume()
	{
	// This will skip PLT0.
	++m_Last;
	assert(m_Last != m_SectionData->end() &&
	"The number of PLT Entries and ResolveInfo doesn't match");
	return llvm::cast<PLTEntryBase>(&(*m_Last));
	}

	PLTEntryBase* X86PLT::getPLT0() const
	{
	iterator first = m_SectionData->getFragmentList().begin();

	assert(first != m_SectionData->getFragmentList().end() &&
	"FragmentList is empty, getPLT0 failed!");

	PLTEntryBase* plt0 = &(llvm::cast<PLTEntryBase>(*first));

	return plt0;
	}

	//===----------------------------------------------------------------------===//
	// X86_32PLT
	//===----------------------------------------------------------------------===//
	X86_32PLT::X86_32PLT(LDSection& pSection,
	X86_32GOTPLT& pGOTPLT,
	const LinkerConfig& pConfig)
	: X86PLT(pSection, pConfig, 32),
	m_GOTPLT(pGOTPLT) {
	}

	// FIXME: It only works on little endian machine.
	void X86_32PLT::applyPLT0()
	{
	PLTEntryBase* plt0 = getPLT0();

	unsigned char* data = 0;
	data = static_cast<unsigned char*>(malloc(plt0->size()));

	if (!data)
	fatal(diag::fail_allocate_memory_plt);

	memcpy(data, m_PLT0, plt0->size());

	if (m_PLT0 == x86_32_exec_plt0) {
	uint32_t offset = reinterpret_cast<uint32_t>(data + 2);
	*offset = m_GOTPLT.addr() + 4;
	offset = reinterpret_cast<uint32_t*>(data + 8);
	*offset = m_GOTPLT.addr() + 8;
	}

	plt0->setValue(data);
	}

	// FIXME: It only works on little endian machine.
	void X86_32PLT::applyPLT1()
	{
	assert(m_Section.addr() && ".plt base address is NULL!");

	X86PLT::iterator it = m_SectionData->begin();
	X86PLT::iterator ie = m_SectionData->end();
	assert(it != ie && "FragmentList is empty, applyPLT1 failed!");

	uint64_t GOTEntrySize = X86_32GOTEntry::EntrySize;

	// Skip GOT0
	uint64_t GOTEntryOffset = GOTEntrySize * X86GOTPLT0Num;
	if (LinkerConfig::Exec == m_Config.codeGenType())
	GOTEntryOffset += m_GOTPLT.addr();

	//skip PLT0
	uint64_t PLTEntryOffset = m_PLT0Size;
	++it;

	PLTEntryBase* plt1 = 0;

	uint64_t PLTRelOffset = 0;

	while (it != ie) {
	plt1 = &(llvm::cast<PLTEntryBase>(*it));
	unsigned char *data;
	data = static_cast<unsigned char*>(malloc(plt1->size()));

	if (!data)
	fatal(diag::fail_allocate_memory_plt);

	memcpy(data, m_PLT1, plt1->size());

	uint32_t* offset;

	offset = reinterpret_cast<uint32_t*>(data + 2);
	*offset = GOTEntryOffset;
	GOTEntryOffset += GOTEntrySize;

	offset = reinterpret_cast<uint32_t*>(data + 7);
	*offset = PLTRelOffset;
	PLTRelOffset += sizeof (llvm::ELF::Elf32_Rel);

	offset = reinterpret_cast<uint32_t*>(data + 12);
	*offset = -(PLTEntryOffset + 12 + 4);
	PLTEntryOffset += m_PLT1Size;

	plt1->setValue(data);
	++it;
	}
	}

	//===----------------------------------------------------------------------===//
	// X86_64PLT
	//===----------------------------------------------------------------------===//
	X86_64PLT::X86_64PLT(LDSection& pSection,
	X86_64GOTPLT& pGOTPLT,
	const LinkerConfig& pConfig)
	: X86PLT(pSection, pConfig, 64),
	m_GOTPLT(pGOTPLT) {
	}

	// FIXME: It only works on little endian machine.
	void X86_64PLT::applyPLT0()
	{
	PLTEntryBase* plt0 = getPLT0();

	unsigned char* data = 0;
	data = static_cast<unsigned char*>(malloc(plt0->size()));

	if (!data)
	fatal(diag::fail_allocate_memory_plt);

	memcpy(data, m_PLT0, plt0->size());

	// pushq GOT + 8(%rip)
	uint32_t offset = reinterpret_cast<uint32_t>(data + 2);
	*offset = m_GOTPLT.addr() - addr() + 8 - 6;
	// jmq *GOT + 16(%rip)
	offset = reinterpret_cast<uint32_t*>(data + 8);
	*offset = m_GOTPLT.addr() - addr() + 16 - 12;

	plt0->setValue(data);
	}

	// FIXME: It only works on little endian machine.
	void X86_64PLT::applyPLT1()
	{
	assert(m_Section.addr() && ".plt base address is NULL!");

	X86PLT::iterator it = m_SectionData->begin();
	X86PLT::iterator ie = m_SectionData->end();
	assert(it != ie && "FragmentList is empty, applyPLT1 failed!");

	uint64_t GOTEntrySize = X86_64GOTEntry::EntrySize;

	// compute sym@GOTPCREL of the PLT1 entry.
	uint64_t SymGOTPCREL = m_GOTPLT.addr();

	// Skip GOT0
	SymGOTPCREL += GOTEntrySize * X86GOTPLT0Num;

	// skip PLT0
	uint64_t PLTEntryOffset = m_PLT0Size;
	++it;

	// PC-relative to entry in PLT section.
	SymGOTPCREL -= addr() + PLTEntryOffset + 6;

	PLTEntryBase* plt1 = 0;

	uint64_t PLTRelIndex = 0;

	while (it != ie) {
	plt1 = &(llvm::cast<PLTEntryBase>(*it));
	unsigned char *data;
	data = static_cast<unsigned char*>(malloc(plt1->size()));

	if (!data)
	fatal(diag::fail_allocate_memory_plt);

	memcpy(data, m_PLT1, plt1->size());

	uint32_t* offset;

	// jmpq *sym@GOTPCREL(%rip)
	offset = reinterpret_cast<uint32_t*>(data + 2);
	*offset = SymGOTPCREL;
	SymGOTPCREL += GOTEntrySize - m_PLT1Size;

	// pushq $index
	offset = reinterpret_cast<uint32_t*>(data + 7);
	*offset = PLTRelIndex;
	PLTRelIndex++;

	// jmpq plt0
	offset = reinterpret_cast<uint32_t*>(data + 12);
	*offset = -(PLTEntryOffset + 12 + 4);
	PLTEntryOffset += m_PLT1Size;

	plt1->setValue(data);
	++it;
	}
	}