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

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

 #include "mcld/GeneralOptions.h"
 #include "mcld/Module.h"
 #include "mcld/Fragment/RegionFragment.h"
 #include "mcld/LD/LDContext.h"
 #include "mcld/LD/LDSection.h"
 #include "mcld/LD/RelocData.h"
 #include "mcld/LD/Relocator.h"
 #include "mcld/LD/ResolveInfo.h"
 #include "mcld/LD/SectionData.h"
 #include "mcld/LinkerConfig.h"
 #include "mcld/MC/Input.h"
 #include "mcld/Support/Demangle.h"
 #include "mcld/Support/MsgHandling.h"
 #include "mcld/Target/GNULDBackend.h"

 #include <llvm/ADT/StringRef.h>
 #include <llvm/Support/Casting.h>
 #include <llvm/Support/Format.h>

 #include <cassert>
 #include <map>
 #include <set>

 #include <zlib.h>

 namespace mcld {

 static bool isSymCtorOrDtor(const ResolveInfo& pSym) {
   // We can always fold ctors and dtors since accessing function pointer in C++
   // is forbidden.
   llvm::StringRef name(pSym.name(), pSym.nameSize());
   if (!name.startswith("_ZZ") && !name.startswith("_ZN")) {
     return false;
   }
   return isCtorOrDtor(pSym.name(), pSym.nameSize());
 }

 IdenticalCodeFolding::IdenticalCodeFolding(const LinkerConfig& pConfig,
                                            const TargetLDBackend& pBackend,
                                            Module& pModule)
     : m_Config(pConfig), m_Backend(pBackend), m_Module(pModule) {
 }

 void IdenticalCodeFolding::foldIdenticalCode() {
   // 1. Find folding candidates.
   FoldingCandidates candidate_list;
   findCandidates(candidate_list);

   // 2. Initialize constant section content
   for (size_t i = 0; i < candidate_list.size(); ++i) {
     candidate_list[i].initConstantContent(m_Backend, m_KeptSections);
   }

   // 3. Find identical code until convergence
   bool converged = false;
   size_t iterations = 0;
   while (!converged && (iterations < m_Config.options().getICFIterations())) {
     converged = matchCandidates(candidate_list);
     ++iterations;
   }
   if (m_Config.options().printICFSections()) {
     debug(diag::debug_icf_iterations) << iterations;
   }

   // 4. Fold the identical code
   typedef std::set<Input*> FoldedObjects;
   FoldedObjects folded_objs;
   KeptSections::iterator kept, keptEnd = m_KeptSections.end();
   size_t index = 0;
   for (kept = m_KeptSections.begin(); kept != keptEnd; ++kept, ++index) {
     LDSection* sect = (*kept).first;
     Input* obj = (*kept).second.first;
     size_t kept_index = (*kept).second.second;
     if (index != kept_index) {
       sect->setKind(LDFileFormat::Folded);
       folded_objs.insert(obj);

       if (m_Config.options().printICFSections()) {
         KeptSections::iterator it = m_KeptSections.begin() + kept_index;
         LDSection* kept_sect = (*it).first;
         Input* kept_obj = (*it).second.first;
         debug(diag::debug_icf_folded_section) << sect->name() << obj->name()
                                               << kept_sect->name()
                                               << kept_obj->name();
       }
     }
   }

   // Adjust the fragment reference of the folded symbols.
   FoldedObjects::iterator fobj, fobjEnd = folded_objs.end();
   for (fobj = folded_objs.begin(); fobj != fobjEnd; ++fobj) {
     LDContext::sym_iterator sym, symEnd = (*fobj)->context()->symTabEnd();
     for (sym = (*fobj)->context()->symTabBegin(); sym != symEnd; ++sym) {
       if ((*sym)->hasFragRef() && ((*sym)->type() == ResolveInfo::Function)) {
         LDSymbol* out_sym = (*sym)->resolveInfo()->outSymbol();
         FragmentRef* frag_ref = out_sym->fragRef();
         LDSection* sect = &(frag_ref->frag()->getParent()->getSection());
         if (sect->kind() == LDFileFormat::Folded) {
           size_t kept_index = m_KeptSections[sect].second;
           LDSection* kept_sect = (*(m_KeptSections.begin() + kept_index)).first;
           frag_ref->assign(kept_sect->getSectionData()->front(),
                            frag_ref->offset());
         }
       }
     }  // for each symbol
   }    // for each folded object
 }

 void IdenticalCodeFolding::findCandidates(FoldingCandidates& pCandidateList) {
   Module::obj_iterator obj, objEnd = m_Module.obj_end();
   for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
     std::set<const LDSection*> funcptr_access_set;
     typedef std::map<LDSection*, LDSection*> CandidateMap;
     CandidateMap candidate_map;
     LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
     for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
       switch ((*sect)->kind()) {
         case LDFileFormat::TEXT: {
           candidate_map.insert(
               std::make_pair(*sect, reinterpret_cast<LDSection*>(NULL)));
           break;
         }
         case LDFileFormat::Relocation: {
           LDSection* target = (*sect)->getLink();
           if (target->kind() == LDFileFormat::TEXT) {
             candidate_map[target] = *sect;
           }

           // Safe icf
           if (m_Config.options().getICFMode() == GeneralOptions::ICF::Safe) {
             RelocData::iterator rel, relEnd = (*sect)->getRelocData()->end();
             for (rel = (*sect)->getRelocData()->begin(); rel != relEnd; ++rel) {
               LDSymbol* sym = rel->symInfo()->outSymbol();
               if (sym->hasFragRef() && (sym->type() == ResolveInfo::Function)) {
                 const LDSection* def =
                     &sym->fragRef()->frag()->getParent()->getSection();
                 if (!isSymCtorOrDtor(*rel->symInfo()) &&
                     m_Backend.mayHaveUnsafeFunctionPointerAccess(*target) &&
                     m_Backend.getRelocator()
                         ->mayHaveFunctionPointerAccess(*rel)) {
                   funcptr_access_set.insert(def);
                 }
               }
             }  // for each reloc
           }

           break;
         }
         default: {
           // skip
           break;
         }
       }  // end of switch
     }    // for each section

     CandidateMap::iterator candidate, candidateEnd = candidate_map.end();
     for (candidate = candidate_map.begin(); candidate != candidateEnd;
          ++candidate) {
       if ((m_Config.options().getICFMode() == GeneralOptions::ICF::All) ||
           (funcptr_access_set.count(candidate->first) == 0)) {
         size_t index = m_KeptSections.size();
         m_KeptSections[candidate->first] = ObjectAndId(*obj, index);
         pCandidateList.push_back(
             FoldingCandidate(candidate->first, candidate->second, *obj));
       }
     }  // for each possible candidate
   }  // for each obj
 }

 bool IdenticalCodeFolding::matchCandidates(FoldingCandidates& pCandidateList) {
   typedef std::multimap<uint32_t, size_t> ChecksumMap;
   ChecksumMap checksum_map;
   std::vector<std::string> contents(pCandidateList.size());
   bool converged = true;

   for (size_t index = 0; index < pCandidateList.size(); ++index) {
     contents[index] = pCandidateList[index].getContentWithVariables(
         m_Backend, m_KeptSections);
     uint32_t checksum = ::crc32(0xFFFFFFFF,
                                 (const uint8_t*)contents[index].c_str(),
                                 contents[index].length());

     size_t count = checksum_map.count(checksum);
     if (count == 0) {
       checksum_map.insert(std::make_pair(checksum, index));
     } else {
       std::pair<ChecksumMap::iterator, ChecksumMap::iterator> ret =
           checksum_map.equal_range(checksum);
       for (ChecksumMap::iterator it = ret.first; it != ret.second; ++it) {
         size_t kept_index = (*it).second;
         if (contents[index].compare(contents[kept_index]) == 0) {
           m_KeptSections[pCandidateList[index].sect].second = kept_index;
           converged = false;
           break;
         }
       }
     }
   }

   return converged;
 }

 void IdenticalCodeFolding::FoldingCandidate::initConstantContent(
     const TargetLDBackend& pBackend,
     const IdenticalCodeFolding::KeptSections& pKeptSections) {
   // Get the static content from text.
   assert(sect != NULL && sect->hasSectionData());
   SectionData::const_iterator frag, fragEnd = sect->getSectionData()->end();
   for (frag = sect->getSectionData()->begin(); frag != fragEnd; ++frag) {
     switch (frag->getKind()) {
       case Fragment::Region: {
         const RegionFragment& region = llvm::cast<RegionFragment>(*frag);
         content.append(region.getRegion().begin(), region.size());
         break;
       }
       default: {
         // FIXME: Currently we only take care of RegionFragment.
         break;
       }
     }
   }

   // Get the static content from relocs.
   if (reloc_sect != NULL && reloc_sect->hasRelocData()) {
     for (Relocation& rel : *reloc_sect->getRelocData()) {
       llvm::format_object<Relocation::Type,
                           Relocation::Address,
                           Relocation::Address,
                           Relocation::Address> rel_info("%x%llx%llx%llx",
                                                         rel.type(),
                                                         rel.symValue(),
                                                         rel.addend(),
                                                         rel.place());
       char rel_str[48];
       rel_info.print(rel_str, sizeof(rel_str));
       content.append(rel_str);

       // Handle the recursive call.
       LDSymbol* sym = rel.symInfo()->outSymbol();
       if ((sym->type() == ResolveInfo::Function) && sym->hasFragRef()) {
         LDSection* def = &sym->fragRef()->frag()->getParent()->getSection();
         if (def == sect) {
           continue;
         }
       }

       if (!pBackend.isSymbolPreemptible(*rel.symInfo()) && sym->hasFragRef() &&
           (pKeptSections.find(
                &sym->fragRef()->frag()->getParent()->getSection()) !=
            pKeptSections.end())) {
         // Mark this reloc as a variable.
         variable_relocs.push_back(&rel);
       } else {
         // TODO: Support inlining merge sections if possible (target-dependent).
         if ((sym->binding() == ResolveInfo::Local) ||
             (sym->binding() == ResolveInfo::Absolute)) {
           // ABS or Local symbols.
           content.append(sym->name()).append(obj->name()).append(
               obj->path().native());
         } else {
           content.append(sym->name());
         }
       }
     }
   }
 }

 std::string IdenticalCodeFolding::FoldingCandidate::getContentWithVariables(
     const TargetLDBackend& pBackend,
     const IdenticalCodeFolding::KeptSections& pKeptSections) {
   std::string result(content);
   // Compute the variable content from relocs.
   std::vector<Relocation*>::const_iterator rel, relEnd = variable_relocs.end();
   for (rel = variable_relocs.begin(); rel != relEnd; ++rel) {
     LDSymbol* sym = (*rel)->symInfo()->outSymbol();
     LDSection* def = &sym->fragRef()->frag()->getParent()->getSection();
     // Use the kept section index.
     KeptSections::const_iterator it = pKeptSections.find(def);
     llvm::format_object<size_t> kept_info("%x", (*it).second.second);
     char kept_str[8];
     kept_info.print(kept_str, sizeof(kept_str));
     result.append(kept_str);
   }

   return result;
 }

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

	#include "mcld/GeneralOptions.h"
	#include "mcld/Module.h"
	#include "mcld/Fragment/RegionFragment.h"
	#include "mcld/LD/LDContext.h"
	#include "mcld/LD/LDSection.h"
	#include "mcld/LD/RelocData.h"
	#include "mcld/LD/Relocator.h"
	#include "mcld/LD/ResolveInfo.h"
	#include "mcld/LD/SectionData.h"
	#include "mcld/LinkerConfig.h"
	#include "mcld/MC/Input.h"
	#include "mcld/Support/Demangle.h"
	#include "mcld/Support/MsgHandling.h"
	#include "mcld/Target/GNULDBackend.h"

	#include <llvm/ADT/StringRef.h>
	#include <llvm/Support/Casting.h>
	#include <llvm/Support/Format.h>

	#include <cassert>
	#include <map>
	#include <set>

	#include <zlib.h>

	namespace mcld {

	static bool isSymCtorOrDtor(const ResolveInfo& pSym) {
	// We can always fold ctors and dtors since accessing function pointer in C++
	// is forbidden.
	llvm::StringRef name(pSym.name(), pSym.nameSize());
	if (!name.startswith("_ZZ") && !name.startswith("_ZN")) {
	return false;
	}
	return isCtorOrDtor(pSym.name(), pSym.nameSize());
	}

	IdenticalCodeFolding::IdenticalCodeFolding(const LinkerConfig& pConfig,
	const TargetLDBackend& pBackend,
	Module& pModule)
	: m_Config(pConfig), m_Backend(pBackend), m_Module(pModule) {
	}

	void IdenticalCodeFolding::foldIdenticalCode() {
	// 1. Find folding candidates.
	FoldingCandidates candidate_list;
	findCandidates(candidate_list);

	// 2. Initialize constant section content
	for (size_t i = 0; i < candidate_list.size(); ++i) {
	candidate_list[i].initConstantContent(m_Backend, m_KeptSections);
	}

	// 3. Find identical code until convergence
	bool converged = false;
	size_t iterations = 0;
	while (!converged && (iterations < m_Config.options().getICFIterations())) {
	converged = matchCandidates(candidate_list);
	++iterations;
	}
	if (m_Config.options().printICFSections()) {
	debug(diag::debug_icf_iterations) << iterations;
	}

	// 4. Fold the identical code
	typedef std::set<Input*> FoldedObjects;
	FoldedObjects folded_objs;
	KeptSections::iterator kept, keptEnd = m_KeptSections.end();
	size_t index = 0;
	for (kept = m_KeptSections.begin(); kept != keptEnd; ++kept, ++index) {
	LDSection* sect = (*kept).first;
	Input* obj = (*kept).second.first;
	size_t kept_index = (*kept).second.second;
	if (index != kept_index) {
	sect->setKind(LDFileFormat::Folded);
	folded_objs.insert(obj);

	if (m_Config.options().printICFSections()) {
	KeptSections::iterator it = m_KeptSections.begin() + kept_index;
	LDSection* kept_sect = (*it).first;
	Input* kept_obj = (*it).second.first;
	debug(diag::debug_icf_folded_section) << sect->name() << obj->name()
	<< kept_sect->name()
	<< kept_obj->name();
	}
	}
	}

	// Adjust the fragment reference of the folded symbols.
	FoldedObjects::iterator fobj, fobjEnd = folded_objs.end();
	for (fobj = folded_objs.begin(); fobj != fobjEnd; ++fobj) {
	LDContext::sym_iterator sym, symEnd = (*fobj)->context()->symTabEnd();
	for (sym = (*fobj)->context()->symTabBegin(); sym != symEnd; ++sym) {
	if ((sym)->hasFragRef() && ((sym)->type() == ResolveInfo::Function)) {
	LDSymbol* out_sym = (*sym)->resolveInfo()->outSymbol();
	FragmentRef* frag_ref = out_sym->fragRef();
	LDSection* sect = &(frag_ref->frag()->getParent()->getSection());
	if (sect->kind() == LDFileFormat::Folded) {
	size_t kept_index = m_KeptSections[sect].second;
	LDSection* kept_sect = (*(m_KeptSections.begin() + kept_index)).first;
	frag_ref->assign(kept_sect->getSectionData()->front(),
	frag_ref->offset());
	}
	}
	} // for each symbol
	} // for each folded object
	}

	void IdenticalCodeFolding::findCandidates(FoldingCandidates& pCandidateList) {
	Module::obj_iterator obj, objEnd = m_Module.obj_end();
	for (obj = m_Module.obj_begin(); obj != objEnd; ++obj) {
	std::set<const LDSection*> funcptr_access_set;
	typedef std::map<LDSection, LDSection> CandidateMap;
	CandidateMap candidate_map;
	LDContext::sect_iterator sect, sectEnd = (*obj)->context()->sectEnd();
	for (sect = (*obj)->context()->sectBegin(); sect != sectEnd; ++sect) {
	switch ((*sect)->kind()) {
	case LDFileFormat::TEXT: {
	candidate_map.insert(
	std::make_pair(sect, reinterpret_cast<LDSection>(NULL)));
	break;
	}
	case LDFileFormat::Relocation: {
	LDSection* target = (*sect)->getLink();
	if (target->kind() == LDFileFormat::TEXT) {
	candidate_map[target] = *sect;
	}

	// Safe icf
	if (m_Config.options().getICFMode() == GeneralOptions::ICF::Safe) {
	RelocData::iterator rel, relEnd = (*sect)->getRelocData()->end();
	for (rel = (*sect)->getRelocData()->begin(); rel != relEnd; ++rel) {
	LDSymbol* sym = rel->symInfo()->outSymbol();
	if (sym->hasFragRef() && (sym->type() == ResolveInfo::Function)) {
	const LDSection* def =
	&sym->fragRef()->frag()->getParent()->getSection();
	if (!isSymCtorOrDtor(*rel->symInfo()) &&
	m_Backend.mayHaveUnsafeFunctionPointerAccess(*target) &&
	m_Backend.getRelocator()
	->mayHaveFunctionPointerAccess(*rel)) {
	funcptr_access_set.insert(def);
	}
	}
	} // for each reloc
	}

	break;
	}
	default: {
	// skip
	break;
	}
	} // end of switch
	} // for each section

	CandidateMap::iterator candidate, candidateEnd = candidate_map.end();
	for (candidate = candidate_map.begin(); candidate != candidateEnd;
	++candidate) {
	if ((m_Config.options().getICFMode() == GeneralOptions::ICF::All) \|\|
	(funcptr_access_set.count(candidate->first) == 0)) {
	size_t index = m_KeptSections.size();
	m_KeptSections[candidate->first] = ObjectAndId(*obj, index);
	pCandidateList.push_back(
	FoldingCandidate(candidate->first, candidate->second, *obj));
	}
	} // for each possible candidate
	} // for each obj
	}

	bool IdenticalCodeFolding::matchCandidates(FoldingCandidates& pCandidateList) {
	typedef std::multimap<uint32_t, size_t> ChecksumMap;
	ChecksumMap checksum_map;
	std::vector<std::string> contents(pCandidateList.size());
	bool converged = true;

	for (size_t index = 0; index < pCandidateList.size(); ++index) {
	contents[index] = pCandidateList[index].getContentWithVariables(
	m_Backend, m_KeptSections);
	uint32_t checksum = ::crc32(0xFFFFFFFF,
	(const uint8_t*)contents[index].c_str(),
	contents[index].length());

	size_t count = checksum_map.count(checksum);
	if (count == 0) {
	checksum_map.insert(std::make_pair(checksum, index));
	} else {
	std::pair<ChecksumMap::iterator, ChecksumMap::iterator> ret =
	checksum_map.equal_range(checksum);
	for (ChecksumMap::iterator it = ret.first; it != ret.second; ++it) {
	size_t kept_index = (*it).second;
	if (contents[index].compare(contents[kept_index]) == 0) {
	m_KeptSections[pCandidateList[index].sect].second = kept_index;
	converged = false;
	break;
	}
	}
	}
	}

	return converged;
	}

	void IdenticalCodeFolding::FoldingCandidate::initConstantContent(
	const TargetLDBackend& pBackend,
	const IdenticalCodeFolding::KeptSections& pKeptSections) {
	// Get the static content from text.
	assert(sect != NULL && sect->hasSectionData());
	SectionData::const_iterator frag, fragEnd = sect->getSectionData()->end();
	for (frag = sect->getSectionData()->begin(); frag != fragEnd; ++frag) {
	switch (frag->getKind()) {
	case Fragment::Region: {
	const RegionFragment& region = llvm::cast<RegionFragment>(*frag);
	content.append(region.getRegion().begin(), region.size());
	break;
	}
	default: {
	// FIXME: Currently we only take care of RegionFragment.
	break;
	}
	}
	}

	// Get the static content from relocs.
	if (reloc_sect != NULL && reloc_sect->hasRelocData()) {
	for (Relocation& rel : *reloc_sect->getRelocData()) {
	llvm::format_object<Relocation::Type,
	Relocation::Address,
	Relocation::Address,
	Relocation::Address> rel_info("%x%llx%llx%llx",
	rel.type(),
	rel.symValue(),
	rel.addend(),
	rel.place());
	char rel_str[48];
	rel_info.print(rel_str, sizeof(rel_str));
	content.append(rel_str);

	// Handle the recursive call.
	LDSymbol* sym = rel.symInfo()->outSymbol();
	if ((sym->type() == ResolveInfo::Function) && sym->hasFragRef()) {
	LDSection* def = &sym->fragRef()->frag()->getParent()->getSection();
	if (def == sect) {
	continue;
	}
	}

	if (!pBackend.isSymbolPreemptible(*rel.symInfo()) && sym->hasFragRef() &&
	(pKeptSections.find(
	&sym->fragRef()->frag()->getParent()->getSection()) !=
	pKeptSections.end())) {
	// Mark this reloc as a variable.
	variable_relocs.push_back(&rel);
	} else {
	// TODO: Support inlining merge sections if possible (target-dependent).
	if ((sym->binding() == ResolveInfo::Local) \|\|
	(sym->binding() == ResolveInfo::Absolute)) {
	// ABS or Local symbols.
	content.append(sym->name()).append(obj->name()).append(
	obj->path().native());
	} else {
	content.append(sym->name());
	}
	}
	}
	}
	}

	std::string IdenticalCodeFolding::FoldingCandidate::getContentWithVariables(
	const TargetLDBackend& pBackend,
	const IdenticalCodeFolding::KeptSections& pKeptSections) {
	std::string result(content);
	// Compute the variable content from relocs.
	std::vector<Relocation*>::const_iterator rel, relEnd = variable_relocs.end();
	for (rel = variable_relocs.begin(); rel != relEnd; ++rel) {
	LDSymbol* sym = (*rel)->symInfo()->outSymbol();
	LDSection* def = &sym->fragRef()->frag()->getParent()->getSection();
	// Use the kept section index.
	KeptSections::const_iterator it = pKeptSections.find(def);
	llvm::format_object<size_t> kept_info("%x", (*it).second.second);
	char kept_str[8];
	kept_info.print(kept_str, sizeof(kept_str));
	result.append(kept_str);
	}

	return result;
	}

	} // namespace mcld