//===- subzero/src/IceELFSection.cpp - Representation of ELF sections -----===// // // The Subzero Code Generator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief Defines how ELF sections are represented. /// //===----------------------------------------------------------------------===// #include "IceELFSection.h" #include "IceDefs.h" #include "IceELFStreamer.h" #include "llvm/Support/MathExtras.h" using namespace llvm::ELF; namespace Ice { // Text sections. void ELFTextSection::appendData(ELFStreamer &Str, const llvm::StringRef MoreData) { Str.writeBytes(MoreData); Header.sh_size += MoreData.size(); } // Data sections. void ELFDataSection::appendData(ELFStreamer &Str, const llvm::StringRef MoreData) { Str.writeBytes(MoreData); Header.sh_size += MoreData.size(); } void ELFDataSection::appendZeros(ELFStreamer &Str, SizeT NumBytes) { Str.writeZeroPadding(NumBytes); Header.sh_size += NumBytes; } void ELFDataSection::appendRelocationOffset(ELFStreamer &Str, bool IsRela, RelocOffsetT RelocOffset) { const SizeT RelocAddrSize = typeWidthInBytes(getPointerType()); if (IsRela) { appendZeros(Str, RelocAddrSize); return; } assert(RelocAddrSize == 4 && " writeLE32 assumes RelocAddrSize is 4"); Str.writeLE32(RelocOffset); Header.sh_size += RelocAddrSize; } void ELFDataSection::padToAlignment(ELFStreamer &Str, Elf64_Xword Align) { assert(llvm::isPowerOf2_32(Align)); Elf64_Xword AlignDiff = Utils::OffsetToAlignment(Header.sh_size, Align); if (AlignDiff == 0) return; if (Header.sh_type != llvm::ELF::SHT_NOBITS) Str.writeZeroPadding(AlignDiff); Header.sh_size += AlignDiff; } // Relocation sections. void ELFRelocationSection::addRelocations(RelocOffsetT BaseOff, const FixupRefList &FixupRefs, ELFSymbolTableSection *SymTab) { for (const AssemblerFixup *FR : FixupRefs) { Fixups.push_back(*FR); AssemblerFixup &F = Fixups.back(); F.set_position(BaseOff + F.position()); assert(!F.valueIsSymbol()); if (!F.isNullSymbol()) { // Do an early lookup in the symbol table. If the symbol is found, // replace the Constant in the symbol with the ELFSym, and calculate the // final value of the addend. As such, a local label allocated from the // Assembler arena will be converted to a symbol before the Assembler // arena goes away. if (const ELFSym *Sym = SymTab->findSymbol(F.symbol())) { F.set_addend(F.offset()); F.set_value(Sym); } } } } size_t ELFRelocationSection::getSectionDataSize() const { return Fixups.size() * Header.sh_entsize; } // Symbol tables. void ELFSymbolTableSection::createNullSymbol(ELFSection *NullSection, GlobalContext *Ctx) { // The first entry in the symbol table should be a NULL entry, so make sure // the map is still empty. assert(LocalSymbols.empty()); // Explicitly set the null symbol name to the empty string, so that // GlobalString::operator<() orders the null string first. NullSymbolName = GlobalString::createWithString(Ctx, ""); createDefinedSym(NullSymbolName, STT_NOTYPE, STB_LOCAL, NullSection, 0, 0); NullSymbol = findSymbol(NullSymbolName); } void ELFSymbolTableSection::createDefinedSym(GlobalString Name, uint8_t Type, uint8_t Binding, ELFSection *Section, RelocOffsetT Offset, SizeT Size) { ELFSym NewSymbol = ELFSym(); NewSymbol.Sym.setBindingAndType(Binding, Type); NewSymbol.Sym.st_value = Offset; NewSymbol.Sym.st_size = Size; NewSymbol.Section = Section; NewSymbol.Number = ELFSym::UnknownNumber; bool Unique; if (Binding == STB_LOCAL) Unique = LocalSymbols.insert(std::make_pair(Name, NewSymbol)).second; else Unique = GlobalSymbols.insert(std::make_pair(Name, NewSymbol)).second; assert(Unique); (void)Unique; } void ELFSymbolTableSection::noteUndefinedSym(GlobalString Name, ELFSection *NullSection) { ELFSym NewSymbol = ELFSym(); NewSymbol.Sym.setBindingAndType(STB_GLOBAL, STT_NOTYPE); NewSymbol.Section = NullSection; NewSymbol.Number = ELFSym::UnknownNumber; bool Unique = GlobalSymbols.insert(std::make_pair(Name, NewSymbol)).second; if (!Unique) { std::string Buffer; llvm::raw_string_ostream StrBuf(Buffer); StrBuf << "Symbol external and defined: " << Name; llvm::report_fatal_error(StrBuf.str()); } (void)Unique; } const ELFSym *ELFSymbolTableSection::findSymbol(GlobalString Name) const { auto I = LocalSymbols.find(Name); if (I != LocalSymbols.end()) return &I->second; I = GlobalSymbols.find(Name); if (I != GlobalSymbols.end()) return &I->second; return nullptr; } void ELFSymbolTableSection::updateIndices(const ELFStringTableSection *StrTab) { SizeT SymNumber = 0; for (auto &KeyValue : LocalSymbols) { GlobalString Name = KeyValue.first; ELFSection *Section = KeyValue.second.Section; Elf64_Sym &SymInfo = KeyValue.second.Sym; if (Name != NullSymbolName && Name.hasStdString()) SymInfo.st_name = StrTab->getIndex(Name.toString()); SymInfo.st_shndx = Section->getNumber(); KeyValue.second.setNumber(SymNumber++); } for (auto &KeyValue : GlobalSymbols) { const std::string &Name = KeyValue.first.toString(); ELFSection *Section = KeyValue.second.Section; Elf64_Sym &SymInfo = KeyValue.second.Sym; if (!Name.empty()) SymInfo.st_name = StrTab->getIndex(Name); SymInfo.st_shndx = Section->getNumber(); KeyValue.second.setNumber(SymNumber++); } } void ELFSymbolTableSection::writeData(ELFStreamer &Str, bool IsELF64) { if (IsELF64) { writeSymbolMap(Str, LocalSymbols); writeSymbolMap(Str, GlobalSymbols); } else { writeSymbolMap(Str, LocalSymbols); writeSymbolMap(Str, GlobalSymbols); } } // String tables. void ELFStringTableSection::add(const std::string &Str) { assert(!isLaidOut()); assert(!Str.empty()); StringToIndexMap.insert(std::make_pair(Str, UnknownIndex)); } size_t ELFStringTableSection::getIndex(const std::string &Str) const { assert(isLaidOut()); StringToIndexType::const_iterator It = StringToIndexMap.find(Str); if (It == StringToIndexMap.end()) { llvm::report_fatal_error("String index not found: " + Str); return UnknownIndex; } return It->second; } bool ELFStringTableSection::SuffixComparator:: operator()(const std::string &StrA, const std::string &StrB) const { size_t LenA = StrA.size(); size_t LenB = StrB.size(); size_t CommonLen = std::min(LenA, LenB); // If there is a difference in the common suffix, use that diff to sort. for (size_t i = 0; i < CommonLen; ++i) { char a = StrA[LenA - i - 1]; char b = StrB[LenB - i - 1]; if (a != b) return a > b; } // If the common suffixes are completely equal, let the longer one come // first, so that it can be laid out first and its characters shared. return LenA > LenB; } void ELFStringTableSection::doLayout() { assert(!isLaidOut()); llvm::StringRef Prev; // String table starts with 0 byte. StringData.push_back(0); for (auto &StringIndex : StringToIndexMap) { assert(StringIndex.second == UnknownIndex); llvm::StringRef Cur = llvm::StringRef(StringIndex.first); if (Prev.endswith(Cur)) { // Prev is already in the StringData, and Cur is shorter than Prev based // on the sort. StringIndex.second = StringData.size() - Cur.size() - 1; continue; } StringIndex.second = StringData.size(); std::copy(Cur.begin(), Cur.end(), back_inserter(StringData)); StringData.push_back(0); Prev = Cur; } } } // end of namespace Ice