lib/LD/GarbageCollection.cpp - platform/frameworks/compile/mclinker - Gitiles

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

 #include "mcld/Fragment/Fragment.h"
 #include "mcld/Fragment/Relocation.h"
 #include "mcld/LD/LDContext.h"
 #include "mcld/LD/LDFileFormat.h"
 #include "mcld/LD/LDSection.h"
 #include "mcld/LD/LDSymbol.h"
 #include "mcld/LD/SectionData.h"
 #include "mcld/LD/RelocData.h"
 #include "mcld/LinkerConfig.h"
 #include "mcld/LinkerScript.h"
 #include "mcld/Module.h"
 #include "mcld/Support/MsgHandling.h"
 #include "mcld/Target/TargetLDBackend.h"

 #include <llvm/Support/Casting.h>

 #include <queue>
 #if !defined(MCLD_ON_WIN32)
 #include <fnmatch.h>
 #define fnmatch0(pattern, string) (fnmatch(pattern, string, 0) == 0)
 #else
 #include <windows.h>
 #include <shlwapi.h>
 #define fnmatch0(pattern, string) (PathMatchSpec(string, pattern) == true)
 #endif

 namespace mcld {

 //===----------------------------------------------------------------------===//
 // Non-member functions
 //===----------------------------------------------------------------------===//
 // FIXME: these rules should be added into SectionMap, while currently adding to
 // SectionMap will cause the output order change in .text section and leads to
 // the .ARM.exidx order incorrect. We should sort the .ARM.exidx.
 static const char* pattern_to_keep[] = {".text*personality*",
                                         ".data*personality*",
                                         ".gnu.linkonce.d*personality*",
                                         ".sdata*personality*"};

 /// shouldKeep - check the section name for the keep sections
 static bool shouldKeep(const std::string& pName) {
   static const unsigned int pattern_size =
       sizeof(pattern_to_keep) / sizeof(pattern_to_keep[0]);
   for (unsigned int i = 0; i < pattern_size; ++i) {
     if (fnmatch0(pattern_to_keep[i], pName.c_str()))
       return true;
   }
   return false;
 }

 /// shouldProcessGC - check if the section kind is handled in GC
 static bool mayProcessGC(const LDSection& pSection) {
   if (pSection.kind() == LDFileFormat::TEXT ||
       pSection.kind() == LDFileFormat::DATA ||
       pSection.kind() == LDFileFormat::BSS ||
       pSection.kind() == LDFileFormat::GCCExceptTable)
     return true;
   return false;
 }

 //===----------------------------------------------------------------------===//
 // GarbageCollection::SectionReachedListMap
 //===----------------------------------------------------------------------===//
 void GarbageCollection::SectionReachedListMap::addReference(
     const LDSection& pFrom,
     const LDSection& pTo) {
   m_ReachedSections[&pFrom].insert(&pTo);
 }

 GarbageCollection::SectionListTy&
 GarbageCollection::SectionReachedListMap::getReachedList(
     const LDSection& pSection) {
   return m_ReachedSections[&pSection];
 }

 GarbageCollection::SectionListTy*
 GarbageCollection::SectionReachedListMap::findReachedList(
     const LDSection& pSection) {
   ReachedSectionsTy::iterator it = m_ReachedSections.find(&pSection);
   if (it == m_ReachedSections.end())
     return NULL;
   return &it->second;
 }

 //===----------------------------------------------------------------------===//
 // GarbageCollection
 //===----------------------------------------------------------------------===//
 GarbageCollection::GarbageCollection(const LinkerConfig& pConfig,
                                      const TargetLDBackend& pBackend,
                                      Module& pModule)
     : m_Config(pConfig), m_Backend(pBackend), m_Module(pModule) {
 }

 GarbageCollection::~GarbageCollection() {
 }

 bool GarbageCollection::run() {
   // 1. traverse all the relocations to set up the reached sections of each
   // section
   setUpReachedSections();
   m_Backend.setUpReachedSectionsForGC(m_Module, m_SectionReachedListMap);

   // 2. get all sections defined the entry point
   SectionVecTy entry;
   getEntrySections(entry);

   // 3. find all the referenced sections those can be reached by entry
   findReferencedSections(entry);

   // 4. stripSections - set the unreached sections to Ignore
   stripSections();
   return true;
 }

 void GarbageCollection::setUpReachedSections() {
   // traverse all the input relocations to setup the reached sections
   Module::obj_iterator input, inEnd = m_Module.obj_end();
   for (input = m_Module.obj_begin(); input != inEnd; ++input) {
     LDContext::sect_iterator rs, rsEnd = (*input)->context()->relocSectEnd();
     for (rs = (*input)->context()->relocSectBegin(); rs != rsEnd; ++rs) {
       // bypass the discarded relocation section
       // 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)
       LDSection* reloc_sect = *rs;
       LDSection* apply_sect = reloc_sect->getLink();
       if ((LDFileFormat::Ignore == reloc_sect->kind()) ||
           (!reloc_sect->hasRelocData()))
         continue;

       // bypass the apply target sections which are not handled by gc
       if (!mayProcessGC(*apply_sect))
         continue;

       bool add_first = false;
       SectionListTy* reached_sects = NULL;
       RelocData::iterator reloc_it, rEnd = reloc_sect->getRelocData()->end();
       for (reloc_it = reloc_sect->getRelocData()->begin(); reloc_it != rEnd;
            ++reloc_it) {
         Relocation* reloc = llvm::cast<Relocation>(reloc_it);
         ResolveInfo* sym = reloc->symInfo();
         // only the target symbols defined in the input fragments can make the
         // reference
         if (sym == NULL)
           continue;
         if (!sym->isDefine() || !sym->outSymbol()->hasFragRef())
           continue;

         // only the target symbols defined in the concerned sections can make
         // the reference
         const LDSection* target_sect =
             &sym->outSymbol()->fragRef()->frag()->getParent()->getSection();
         if (!mayProcessGC(*target_sect))
           continue;

         // setup the reached list, if we first add the element to reached list
         // of this section, create an entry in ReachedSections map
         if (!add_first) {
           reached_sects = &m_SectionReachedListMap.getReachedList(*apply_sect);
           add_first = true;
         }
         reached_sects->insert(target_sect);
       }
       reached_sects = NULL;
       add_first = false;
     }
   }
 }

 void GarbageCollection::getEntrySections(SectionVecTy& pEntry) {
   // all the KEEP sections defined in ldscript are entries, traverse all the
   // input sections and check the SectionMap to find the KEEP sections
   Module::obj_iterator obj, objEnd = m_Module.obj_end();
   SectionMap& sect_map = m_Module.getScript().sectionMap();
   for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
     const std::string input_name = (*obj)->name();
     LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
     for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
       LDSection* section = *sect;
       if (!mayProcessGC(*section))
         continue;

       SectionMap::Input* sm_input =
           sect_map.find(input_name, section->name()).second;
       if (((sm_input != NULL) && (InputSectDesc::Keep == sm_input->policy())) ||
           shouldKeep(section->name()))
         pEntry.push_back(section);
     }
   }

   // when building shared object or the --export-dynamic has been given, the
   // global define symbols are entries
   if (LinkerConfig::DynObj == m_Config.codeGenType() ||
       m_Config.options().exportDynamic()) {
     NamePool::syminfo_iterator info_it,
         info_end = m_Module.getNamePool().syminfo_end();
     for (info_it = m_Module.getNamePool().syminfo_begin(); info_it != info_end;
          ++info_it) {
       ResolveInfo* info = info_it.getEntry();
       if (!info->isDefine() || info->isLocal() ||
           info->shouldForceLocal(m_Config))
         continue;
       LDSymbol* sym = info->outSymbol();
       if (sym == NULL || !sym->hasFragRef())
         continue;

       // only the target symbols defined in the concerned sections can be
       // entries
       const LDSection* sect =
           &sym->fragRef()->frag()->getParent()->getSection();
       if (!mayProcessGC(*sect))
         continue;
       pEntry.push_back(sect);
     }
   }

   // when building executable or PIE
   if (LinkerConfig::Exec == m_Config.codeGenType() ||
       m_Config.options().isPIE()) {
     // 1. the entry symbol is the entry
     LDSymbol* entry_sym =
         m_Module.getNamePool().findSymbol(m_Backend.getEntry(m_Module));
     assert(entry_sym != NULL);
     pEntry.push_back(&entry_sym->fragRef()->frag()->getParent()->getSection());

     // 2. the symbols have been seen in dynamic objects are entries. If
     // --export-dynamic is set, then these sections already been added. No need
     // to add them again
     if (!m_Config.options().exportDynamic()) {
       NamePool::syminfo_iterator info_it,
           info_end = m_Module.getNamePool().syminfo_end();
       for (info_it = m_Module.getNamePool().syminfo_begin();
            info_it != info_end; ++info_it) {
         ResolveInfo* info = info_it.getEntry();
         if (!info->isDefine() || info->isLocal())
           continue;

         if (!info->isInDyn())
           continue;

         LDSymbol* sym = info->outSymbol();
         if (sym == NULL || !sym->hasFragRef())
           continue;

         // only the target symbols defined in the concerned sections can be
         // entries
         const LDSection* sect =
             &sym->fragRef()->frag()->getParent()->getSection();
         if (!mayProcessGC(*sect))
           continue;

         pEntry.push_back(sect);
       }
     }
   }

   // symbols set by -u should not be garbage collected. Set them entries.
   GeneralOptions::const_undef_sym_iterator usym;
   GeneralOptions::const_undef_sym_iterator usymEnd =
       m_Config.options().undef_sym_end();
   for (usym = m_Config.options().undef_sym_begin(); usym != usymEnd; ++usym) {
     LDSymbol* sym = m_Module.getNamePool().findSymbol(*usym);
     assert(sym);
     ResolveInfo* info = sym->resolveInfo();
     assert(info);
     if (!info->isDefine() || !sym->hasFragRef())
       continue;
     // only the symbols defined in the concerned sections can be entries
     const LDSection* sect = &sym->fragRef()->frag()->getParent()->getSection();
     if (!mayProcessGC(*sect))
       continue;
     pEntry.push_back(sect);
   }
 }

 void GarbageCollection::findReferencedSections(SectionVecTy& pEntry) {
   // list of sections waiting to be processed
   typedef std::queue<const LDSection*> WorkListTy;
   WorkListTy work_list;
   // start from each entry, resolve the transitive closure
   SectionVecTy::iterator entry_it, entry_end = pEntry.end();
   for (entry_it = pEntry.begin(); entry_it != entry_end; ++entry_it) {
     // add entry point to work list
     work_list.push(*entry_it);

     // add section from the work_list to the referencedSections until every
     // reached sections are added
     while (!work_list.empty()) {
       const LDSection* sect = work_list.front();
       work_list.pop();
       // add section to the ReferencedSections, if the section has been put into
       // referencedSections, skip this section
       if (!m_ReferencedSections.insert(sect).second)
         continue;

       // get the section reached list, if the section do not has one, which
       // means no referenced between it and other sections, then skip it
       SectionListTy* reach_list =
           m_SectionReachedListMap.findReachedList(*sect);
       if (reach_list == NULL)
         continue;

       // put the reached sections to work list, skip the one already be in
       // referencedSections
       SectionListTy::iterator it, end = reach_list->end();
       for (it = reach_list->begin(); it != end; ++it) {
         if (m_ReferencedSections.find(*it) == m_ReferencedSections.end())
           work_list.push(*it);
       }
     }
   }
 }

 void GarbageCollection::stripSections() {
   // Traverse all the input Regular and BSS sections, if a section is not found
   // in the ReferencedSections, then it should be garbage collected
   Module::obj_iterator obj, objEnd = m_Module.obj_end();
   for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
     LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
     for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
       LDSection* section = *sect;
       if (!mayProcessGC(*section))
         continue;

       if (m_ReferencedSections.find(section) == m_ReferencedSections.end()) {
         section->setKind(LDFileFormat::Ignore);
         debug(diag::debug_print_gc_sections) << section->name()
                                              << (*obj)->name();
       }
     }
   }

   // Traverse all the relocation sections, if its target section is set to
   // Ignore, then set the relocation section to Ignore as well
   Module::obj_iterator input, inEnd = m_Module.obj_end();
   for (input = m_Module.obj_begin(); input != inEnd; ++input) {
     LDContext::sect_iterator rs, rsEnd = (*input)->context()->relocSectEnd();
     for (rs = (*input)->context()->relocSectBegin(); rs != rsEnd; ++rs) {
       LDSection* reloc_sect = *rs;
       if (LDFileFormat::Ignore == reloc_sect->getLink()->kind())
         reloc_sect->setKind(LDFileFormat::Ignore);
     }
   }
 }

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

	#include "mcld/Fragment/Fragment.h"
	#include "mcld/Fragment/Relocation.h"
	#include "mcld/LD/LDContext.h"
	#include "mcld/LD/LDFileFormat.h"
	#include "mcld/LD/LDSection.h"
	#include "mcld/LD/LDSymbol.h"
	#include "mcld/LD/SectionData.h"
	#include "mcld/LD/RelocData.h"
	#include "mcld/LinkerConfig.h"
	#include "mcld/LinkerScript.h"
	#include "mcld/Module.h"
	#include "mcld/Support/MsgHandling.h"
	#include "mcld/Target/TargetLDBackend.h"

	#include <llvm/Support/Casting.h>

	#include <queue>
	#if !defined(MCLD_ON_WIN32)
	#include <fnmatch.h>
	#define fnmatch0(pattern, string) (fnmatch(pattern, string, 0) == 0)
	#else
	#include <windows.h>
	#include <shlwapi.h>
	#define fnmatch0(pattern, string) (PathMatchSpec(string, pattern) == true)
	#endif

	namespace mcld {

	//===----------------------------------------------------------------------===//
	// Non-member functions
	//===----------------------------------------------------------------------===//
	// FIXME: these rules should be added into SectionMap, while currently adding to
	// SectionMap will cause the output order change in .text section and leads to
	// the .ARM.exidx order incorrect. We should sort the .ARM.exidx.
	static const char* pattern_to_keep[] = {".textpersonality",
	".datapersonality",
	".gnu.linkonce.dpersonality",
	".sdatapersonality"};

	/// shouldKeep - check the section name for the keep sections
	static bool shouldKeep(const std::string& pName) {
	static const unsigned int pattern_size =
	sizeof(pattern_to_keep) / sizeof(pattern_to_keep[0]);
	for (unsigned int i = 0; i < pattern_size; ++i) {
	if (fnmatch0(pattern_to_keep[i], pName.c_str()))
	return true;
	}
	return false;
	}

	/// shouldProcessGC - check if the section kind is handled in GC
	static bool mayProcessGC(const LDSection& pSection) {
	if (pSection.kind() == LDFileFormat::TEXT \|\|
	pSection.kind() == LDFileFormat::DATA \|\|
	pSection.kind() == LDFileFormat::BSS \|\|
	pSection.kind() == LDFileFormat::GCCExceptTable)
	return true;
	return false;
	}

	//===----------------------------------------------------------------------===//
	// GarbageCollection::SectionReachedListMap
	//===----------------------------------------------------------------------===//
	void GarbageCollection::SectionReachedListMap::addReference(
	const LDSection& pFrom,
	const LDSection& pTo) {
	m_ReachedSections[&pFrom].insert(&pTo);
	}

	GarbageCollection::SectionListTy&
	GarbageCollection::SectionReachedListMap::getReachedList(
	const LDSection& pSection) {
	return m_ReachedSections[&pSection];
	}

	GarbageCollection::SectionListTy*
	GarbageCollection::SectionReachedListMap::findReachedList(
	const LDSection& pSection) {
	ReachedSectionsTy::iterator it = m_ReachedSections.find(&pSection);
	if (it == m_ReachedSections.end())
	return NULL;
	return &it->second;
	}

	//===----------------------------------------------------------------------===//
	// GarbageCollection
	//===----------------------------------------------------------------------===//
	GarbageCollection::GarbageCollection(const LinkerConfig& pConfig,
	const TargetLDBackend& pBackend,
	Module& pModule)
	: m_Config(pConfig), m_Backend(pBackend), m_Module(pModule) {
	}

	GarbageCollection::~GarbageCollection() {
	}

	bool GarbageCollection::run() {
	// 1. traverse all the relocations to set up the reached sections of each
	// section
	setUpReachedSections();
	m_Backend.setUpReachedSectionsForGC(m_Module, m_SectionReachedListMap);

	// 2. get all sections defined the entry point
	SectionVecTy entry;
	getEntrySections(entry);

	// 3. find all the referenced sections those can be reached by entry
	findReferencedSections(entry);

	// 4. stripSections - set the unreached sections to Ignore
	stripSections();
	return true;
	}

	void GarbageCollection::setUpReachedSections() {
	// traverse all the input relocations to setup the reached sections
	Module::obj_iterator input, inEnd = m_Module.obj_end();
	for (input = m_Module.obj_begin(); input != inEnd; ++input) {
	LDContext::sect_iterator rs, rsEnd = (*input)->context()->relocSectEnd();
	for (rs = (*input)->context()->relocSectBegin(); rs != rsEnd; ++rs) {
	// bypass the discarded relocation section
	// 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)
	LDSection* reloc_sect = *rs;
	LDSection* apply_sect = reloc_sect->getLink();
	if ((LDFileFormat::Ignore == reloc_sect->kind()) \|\|
	(!reloc_sect->hasRelocData()))
	continue;

	// bypass the apply target sections which are not handled by gc
	if (!mayProcessGC(*apply_sect))
	continue;

	bool add_first = false;
	SectionListTy* reached_sects = NULL;
	RelocData::iterator reloc_it, rEnd = reloc_sect->getRelocData()->end();
	for (reloc_it = reloc_sect->getRelocData()->begin(); reloc_it != rEnd;
	++reloc_it) {
	Relocation* reloc = llvm::cast<Relocation>(reloc_it);
	ResolveInfo* sym = reloc->symInfo();
	// only the target symbols defined in the input fragments can make the
	// reference
	if (sym == NULL)
	continue;
	if (!sym->isDefine() \|\| !sym->outSymbol()->hasFragRef())
	continue;

	// only the target symbols defined in the concerned sections can make
	// the reference
	const LDSection* target_sect =
	&sym->outSymbol()->fragRef()->frag()->getParent()->getSection();
	if (!mayProcessGC(*target_sect))
	continue;

	// setup the reached list, if we first add the element to reached list
	// of this section, create an entry in ReachedSections map
	if (!add_first) {
	reached_sects = &m_SectionReachedListMap.getReachedList(*apply_sect);
	add_first = true;
	}
	reached_sects->insert(target_sect);
	}
	reached_sects = NULL;
	add_first = false;
	}
	}
	}

	void GarbageCollection::getEntrySections(SectionVecTy& pEntry) {
	// all the KEEP sections defined in ldscript are entries, traverse all the
	// input sections and check the SectionMap to find the KEEP sections
	Module::obj_iterator obj, objEnd = m_Module.obj_end();
	SectionMap& sect_map = m_Module.getScript().sectionMap();
	for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
	const std::string input_name = (*obj)->name();
	LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
	for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
	LDSection* section = *sect;
	if (!mayProcessGC(*section))
	continue;

	SectionMap::Input* sm_input =
	sect_map.find(input_name, section->name()).second;
	if (((sm_input != NULL) && (InputSectDesc::Keep == sm_input->policy())) \|\|
	shouldKeep(section->name()))
	pEntry.push_back(section);
	}
	}

	// when building shared object or the --export-dynamic has been given, the
	// global define symbols are entries
	if (LinkerConfig::DynObj == m_Config.codeGenType() \|\|
	m_Config.options().exportDynamic()) {
	NamePool::syminfo_iterator info_it,
	info_end = m_Module.getNamePool().syminfo_end();
	for (info_it = m_Module.getNamePool().syminfo_begin(); info_it != info_end;
	++info_it) {
	ResolveInfo* info = info_it.getEntry();
	if (!info->isDefine() \|\| info->isLocal() \|\|
	info->shouldForceLocal(m_Config))
	continue;
	LDSymbol* sym = info->outSymbol();
	if (sym == NULL \|\| !sym->hasFragRef())
	continue;

	// only the target symbols defined in the concerned sections can be
	// entries
	const LDSection* sect =
	&sym->fragRef()->frag()->getParent()->getSection();
	if (!mayProcessGC(*sect))
	continue;
	pEntry.push_back(sect);
	}
	}

	// when building executable or PIE
	if (LinkerConfig::Exec == m_Config.codeGenType() \|\|
	m_Config.options().isPIE()) {
	// 1. the entry symbol is the entry
	LDSymbol* entry_sym =
	m_Module.getNamePool().findSymbol(m_Backend.getEntry(m_Module));
	assert(entry_sym != NULL);
	pEntry.push_back(&entry_sym->fragRef()->frag()->getParent()->getSection());

	// 2. the symbols have been seen in dynamic objects are entries. If
	// --export-dynamic is set, then these sections already been added. No need
	// to add them again
	if (!m_Config.options().exportDynamic()) {
	NamePool::syminfo_iterator info_it,
	info_end = m_Module.getNamePool().syminfo_end();
	for (info_it = m_Module.getNamePool().syminfo_begin();
	info_it != info_end; ++info_it) {
	ResolveInfo* info = info_it.getEntry();
	if (!info->isDefine() \|\| info->isLocal())
	continue;

	if (!info->isInDyn())
	continue;

	LDSymbol* sym = info->outSymbol();
	if (sym == NULL \|\| !sym->hasFragRef())
	continue;

	// only the target symbols defined in the concerned sections can be
	// entries
	const LDSection* sect =
	&sym->fragRef()->frag()->getParent()->getSection();
	if (!mayProcessGC(*sect))
	continue;

	pEntry.push_back(sect);
	}
	}
	}

	// symbols set by -u should not be garbage collected. Set them entries.
	GeneralOptions::const_undef_sym_iterator usym;
	GeneralOptions::const_undef_sym_iterator usymEnd =
	m_Config.options().undef_sym_end();
	for (usym = m_Config.options().undef_sym_begin(); usym != usymEnd; ++usym) {
	LDSymbol* sym = m_Module.getNamePool().findSymbol(*usym);
	assert(sym);
	ResolveInfo* info = sym->resolveInfo();
	assert(info);
	if (!info->isDefine() \|\| !sym->hasFragRef())
	continue;
	// only the symbols defined in the concerned sections can be entries
	const LDSection* sect = &sym->fragRef()->frag()->getParent()->getSection();
	if (!mayProcessGC(*sect))
	continue;
	pEntry.push_back(sect);
	}
	}

	void GarbageCollection::findReferencedSections(SectionVecTy& pEntry) {
	// list of sections waiting to be processed
	typedef std::queue<const LDSection*> WorkListTy;
	WorkListTy work_list;
	// start from each entry, resolve the transitive closure
	SectionVecTy::iterator entry_it, entry_end = pEntry.end();
	for (entry_it = pEntry.begin(); entry_it != entry_end; ++entry_it) {
	// add entry point to work list
	work_list.push(*entry_it);

	// add section from the work_list to the referencedSections until every
	// reached sections are added
	while (!work_list.empty()) {
	const LDSection* sect = work_list.front();
	work_list.pop();
	// add section to the ReferencedSections, if the section has been put into
	// referencedSections, skip this section
	if (!m_ReferencedSections.insert(sect).second)
	continue;

	// get the section reached list, if the section do not has one, which
	// means no referenced between it and other sections, then skip it
	SectionListTy* reach_list =
	m_SectionReachedListMap.findReachedList(*sect);
	if (reach_list == NULL)
	continue;

	// put the reached sections to work list, skip the one already be in
	// referencedSections
	SectionListTy::iterator it, end = reach_list->end();
	for (it = reach_list->begin(); it != end; ++it) {
	if (m_ReferencedSections.find(*it) == m_ReferencedSections.end())
	work_list.push(*it);
	}
	}
	}
	}

	void GarbageCollection::stripSections() {
	// Traverse all the input Regular and BSS sections, if a section is not found
	// in the ReferencedSections, then it should be garbage collected
	Module::obj_iterator obj, objEnd = m_Module.obj_end();
	for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
	LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
	for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
	LDSection* section = *sect;
	if (!mayProcessGC(*section))
	continue;

	if (m_ReferencedSections.find(section) == m_ReferencedSections.end()) {
	section->setKind(LDFileFormat::Ignore);
	debug(diag::debug_print_gc_sections) << section->name()
	<< (*obj)->name();
	}
	}
	}

	// Traverse all the relocation sections, if its target section is set to
	// Ignore, then set the relocation section to Ignore as well
	Module::obj_iterator input, inEnd = m_Module.obj_end();
	for (input = m_Module.obj_begin(); input != inEnd; ++input) {
	LDContext::sect_iterator rs, rsEnd = (*input)->context()->relocSectEnd();
	for (rs = (*input)->context()->relocSectBegin(); rs != rsEnd; ++rs) {
	LDSection* reloc_sect = *rs;
	if (LDFileFormat::Ignore == reloc_sect->getLink()->kind())
	reloc_sect->setKind(LDFileFormat::Ignore);
	}
	}
	}

	} // namespace mcld