//===-- lib/MC/XCOFFObjectWriter.cpp - XCOFF file writer ------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements XCOFF object file writer information. // //===----------------------------------------------------------------------===// #include "llvm/BinaryFormat/XCOFF.h" #include "llvm/MC/MCAsmBackend.h" #include "llvm/MC/MCAsmLayout.h" #include "llvm/MC/MCAssembler.h" #include "llvm/MC/MCFixup.h" #include "llvm/MC/MCFixupKindInfo.h" #include "llvm/MC/MCObjectWriter.h" #include "llvm/MC/MCSectionXCOFF.h" #include "llvm/MC/MCSymbolXCOFF.h" #include "llvm/MC/MCValue.h" #include "llvm/MC/MCXCOFFObjectWriter.h" #include "llvm/MC/StringTableBuilder.h" #include "llvm/Support/Casting.h" #include "llvm/Support/EndianStream.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/MathExtras.h" #include #include using namespace llvm; // An XCOFF object file has a limited set of predefined sections. The most // important ones for us (right now) are: // .text --> contains program code and read-only data. // .data --> contains initialized data, function descriptors, and the TOC. // .bss --> contains uninitialized data. // Each of these sections is composed of 'Control Sections'. A Control Section // is more commonly referred to as a csect. A csect is an indivisible unit of // code or data, and acts as a container for symbols. A csect is mapped // into a section based on its storage-mapping class, with the exception of // XMC_RW which gets mapped to either .data or .bss based on whether it's // explicitly initialized or not. // // We don't represent the sections in the MC layer as there is nothing // interesting about them at at that level: they carry information that is // only relevant to the ObjectWriter, so we materialize them in this class. namespace { constexpr unsigned DefaultSectionAlign = 4; constexpr int16_t MaxSectionIndex = INT16_MAX; // Packs the csect's alignment and type into a byte. uint8_t getEncodedType(const MCSectionXCOFF *); struct XCOFFRelocation { uint32_t SymbolTableIndex; uint32_t FixupOffsetInCsect; uint8_t SignAndSize; uint8_t Type; }; // Wrapper around an MCSymbolXCOFF. struct Symbol { const MCSymbolXCOFF *const MCSym; uint32_t SymbolTableIndex; XCOFF::VisibilityType getVisibilityType() const { return MCSym->getVisibilityType(); } XCOFF::StorageClass getStorageClass() const { return MCSym->getStorageClass(); } StringRef getSymbolTableName() const { return MCSym->getSymbolTableName(); } Symbol(const MCSymbolXCOFF *MCSym) : MCSym(MCSym), SymbolTableIndex(-1) {} }; // Wrapper for an MCSectionXCOFF. // It can be a Csect or debug section or DWARF section and so on. struct XCOFFSection { const MCSectionXCOFF *const MCSec; uint32_t SymbolTableIndex; uint64_t Address; uint64_t Size; SmallVector Syms; SmallVector Relocations; StringRef getSymbolTableName() const { return MCSec->getSymbolTableName(); } XCOFF::VisibilityType getVisibilityType() const { return MCSec->getVisibilityType(); } XCOFFSection(const MCSectionXCOFF *MCSec) : MCSec(MCSec), SymbolTableIndex(-1), Address(-1), Size(0) {} }; // Type to be used for a container representing a set of csects with // (approximately) the same storage mapping class. For example all the csects // with a storage mapping class of `xmc_pr` will get placed into the same // container. using CsectGroup = std::deque; using CsectGroups = std::deque; // The basic section entry defination. This Section represents a section entry // in XCOFF section header table. struct SectionEntry { char Name[XCOFF::NameSize]; // The physical/virtual address of the section. For an object file these // values are equivalent, except for in the overflow section header, where // the physical address specifies the number of relocation entries and the // virtual address specifies the number of line number entries. // TODO: Divide Address into PhysicalAddress and VirtualAddress when line // number entries are supported. uint64_t Address; uint64_t Size; uint64_t FileOffsetToData; uint64_t FileOffsetToRelocations; uint32_t RelocationCount; int32_t Flags; int16_t Index; virtual uint64_t advanceFileOffset(const uint64_t MaxRawDataSize, const uint64_t RawPointer) { FileOffsetToData = RawPointer; uint64_t NewPointer = RawPointer + Size; if (NewPointer > MaxRawDataSize) report_fatal_error("Section raw data overflowed this object file."); return NewPointer; } // XCOFF has special section numbers for symbols: // -2 Specifies N_DEBUG, a special symbolic debugging symbol. // -1 Specifies N_ABS, an absolute symbol. The symbol has a value but is not // relocatable. // 0 Specifies N_UNDEF, an undefined external symbol. // Therefore, we choose -3 (N_DEBUG - 1) to represent a section index that // hasn't been initialized. static constexpr int16_t UninitializedIndex = XCOFF::ReservedSectionNum::N_DEBUG - 1; SectionEntry(StringRef N, int32_t Flags) : Name(), Address(0), Size(0), FileOffsetToData(0), FileOffsetToRelocations(0), RelocationCount(0), Flags(Flags), Index(UninitializedIndex) { assert(N.size() <= XCOFF::NameSize && "section name too long"); memcpy(Name, N.data(), N.size()); } virtual void reset() { Address = 0; Size = 0; FileOffsetToData = 0; FileOffsetToRelocations = 0; RelocationCount = 0; Index = UninitializedIndex; } virtual ~SectionEntry() = default; }; // Represents the data related to a section excluding the csects that make up // the raw data of the section. The csects are stored separately as not all // sections contain csects, and some sections contain csects which are better // stored separately, e.g. the .data section containing read-write, descriptor, // TOCBase and TOC-entry csects. struct CsectSectionEntry : public SectionEntry { // Virtual sections do not need storage allocated in the object file. const bool IsVirtual; // This is a section containing csect groups. CsectGroups Groups; CsectSectionEntry(StringRef N, XCOFF::SectionTypeFlags Flags, bool IsVirtual, CsectGroups Groups) : SectionEntry(N, Flags), IsVirtual(IsVirtual), Groups(Groups) { assert(N.size() <= XCOFF::NameSize && "section name too long"); memcpy(Name, N.data(), N.size()); } void reset() override { SectionEntry::reset(); // Clear any csects we have stored. for (auto *Group : Groups) Group->clear(); } virtual ~CsectSectionEntry() = default; }; struct DwarfSectionEntry : public SectionEntry { // For DWARF section entry. std::unique_ptr DwarfSect; // For DWARF section, we must use real size in the section header. MemorySize // is for the size the DWARF section occupies including paddings. uint32_t MemorySize; // TODO: Remove this override. Loadable sections (e.g., .text, .data) may need // to be aligned. Other sections generally don't need any alignment, but if // they're aligned, the RawPointer should be adjusted before writing the // section. Then a dwarf-specific function wouldn't be needed. uint64_t advanceFileOffset(const uint64_t MaxRawDataSize, const uint64_t RawPointer) override { FileOffsetToData = RawPointer; uint64_t NewPointer = RawPointer + MemorySize; assert(NewPointer <= MaxRawDataSize && "Section raw data overflowed this object file."); return NewPointer; } DwarfSectionEntry(StringRef N, int32_t Flags, std::unique_ptr Sect) : SectionEntry(N, Flags | XCOFF::STYP_DWARF), DwarfSect(std::move(Sect)), MemorySize(0) { assert(DwarfSect->MCSec->isDwarfSect() && "This should be a DWARF section!"); assert(N.size() <= XCOFF::NameSize && "section name too long"); memcpy(Name, N.data(), N.size()); } DwarfSectionEntry(DwarfSectionEntry &&s) = default; virtual ~DwarfSectionEntry() = default; }; struct ExceptionTableEntry { const MCSymbol *Trap; uint64_t TrapAddress = ~0ul; unsigned Lang; unsigned Reason; ExceptionTableEntry(const MCSymbol *Trap, unsigned Lang, unsigned Reason) : Trap(Trap), Lang(Lang), Reason(Reason) {} }; struct ExceptionInfo { const MCSymbol *FunctionSymbol; unsigned FunctionSize; std::vector Entries; }; struct ExceptionSectionEntry : public SectionEntry { std::map ExceptionTable; bool isDebugEnabled = false; ExceptionSectionEntry(StringRef N, int32_t Flags) : SectionEntry(N, Flags | XCOFF::STYP_EXCEPT) { assert(N.size() <= XCOFF::NameSize && "Section too long."); memcpy(Name, N.data(), N.size()); } virtual ~ExceptionSectionEntry() = default; }; struct CInfoSymInfo { // Name of the C_INFO symbol associated with the section std::string Name; std::string Metadata; // Offset into the start of the metadata in the section uint64_t Offset; CInfoSymInfo(std::string Name, std::string Metadata) : Name(Name), Metadata(Metadata) {} // Metadata needs to be padded out to an even word size. uint32_t paddingSize() const { return alignTo(Metadata.size(), sizeof(uint32_t)) - Metadata.size(); }; // Total size of the entry, including the 4 byte length uint32_t size() const { return Metadata.size() + paddingSize() + sizeof(uint32_t); }; }; struct CInfoSymSectionEntry : public SectionEntry { std::unique_ptr Entry; CInfoSymSectionEntry(StringRef N, int32_t Flags) : SectionEntry(N, Flags) {} virtual ~CInfoSymSectionEntry() = default; void addEntry(std::unique_ptr NewEntry) { Entry = std::move(NewEntry); Entry->Offset = sizeof(uint32_t); Size += Entry->size(); } void reset() override { SectionEntry::reset(); Entry.reset(); } }; class XCOFFObjectWriter : public MCObjectWriter { uint32_t SymbolTableEntryCount = 0; uint64_t SymbolTableOffset = 0; uint16_t SectionCount = 0; uint32_t PaddingsBeforeDwarf = 0; std::vector> FileNames; bool HasVisibility = false; support::endian::Writer W; std::unique_ptr TargetObjectWriter; StringTableBuilder Strings; const uint64_t MaxRawDataSize = TargetObjectWriter->is64Bit() ? UINT64_MAX : UINT32_MAX; // Maps the MCSection representation to its corresponding XCOFFSection // wrapper. Needed for finding the XCOFFSection to insert an MCSymbol into // from its containing MCSectionXCOFF. DenseMap SectionMap; // Maps the MCSymbol representation to its corrresponding symbol table index. // Needed for relocation. DenseMap SymbolIndexMap; // CsectGroups. These store the csects which make up different parts of // the sections. Should have one for each set of csects that get mapped into // the same section and get handled in a 'similar' way. CsectGroup UndefinedCsects; CsectGroup ProgramCodeCsects; CsectGroup ReadOnlyCsects; CsectGroup DataCsects; CsectGroup FuncDSCsects; CsectGroup TOCCsects; CsectGroup BSSCsects; CsectGroup TDataCsects; CsectGroup TBSSCsects; // The Predefined sections. CsectSectionEntry Text; CsectSectionEntry Data; CsectSectionEntry BSS; CsectSectionEntry TData; CsectSectionEntry TBSS; // All the XCOFF sections, in the order they will appear in the section header // table. std::array Sections{ {&Text, &Data, &BSS, &TData, &TBSS}}; std::vector DwarfSections; std::vector OverflowSections; ExceptionSectionEntry ExceptionSection; CInfoSymSectionEntry CInfoSymSection; CsectGroup &getCsectGroup(const MCSectionXCOFF *MCSec); void reset() override; void executePostLayoutBinding(MCAssembler &, const MCAsmLayout &) override; void recordRelocation(MCAssembler &, const MCAsmLayout &, const MCFragment *, const MCFixup &, MCValue, uint64_t &) override; uint64_t writeObject(MCAssembler &, const MCAsmLayout &) override; bool is64Bit() const { return TargetObjectWriter->is64Bit(); } bool nameShouldBeInStringTable(const StringRef &); void writeSymbolName(const StringRef &); void writeSymbolEntryForCsectMemberLabel(const Symbol &SymbolRef, const XCOFFSection &CSectionRef, int16_t SectionIndex, uint64_t SymbolOffset); void writeSymbolEntryForControlSection(const XCOFFSection &CSectionRef, int16_t SectionIndex, XCOFF::StorageClass StorageClass); void writeSymbolEntryForDwarfSection(const XCOFFSection &DwarfSectionRef, int16_t SectionIndex); void writeFileHeader(); void writeAuxFileHeader(); void writeSectionHeader(const SectionEntry *Sec); void writeSectionHeaderTable(); void writeSections(const MCAssembler &Asm, const MCAsmLayout &Layout); void writeSectionForControlSectionEntry(const MCAssembler &Asm, const MCAsmLayout &Layout, const CsectSectionEntry &CsectEntry, uint64_t &CurrentAddressLocation); void writeSectionForDwarfSectionEntry(const MCAssembler &Asm, const MCAsmLayout &Layout, const DwarfSectionEntry &DwarfEntry, uint64_t &CurrentAddressLocation); void writeSectionForExceptionSectionEntry( const MCAssembler &Asm, const MCAsmLayout &Layout, ExceptionSectionEntry &ExceptionEntry, uint64_t &CurrentAddressLocation); void writeSectionForCInfoSymSectionEntry(const MCAssembler &Asm, const MCAsmLayout &Layout, CInfoSymSectionEntry &CInfoSymEntry, uint64_t &CurrentAddressLocation); void writeSymbolTable(const MCAsmLayout &Layout); void writeSymbolAuxDwarfEntry(uint64_t LengthOfSectionPortion, uint64_t NumberOfRelocEnt = 0); void writeSymbolAuxCsectEntry(uint64_t SectionOrLength, uint8_t SymbolAlignmentAndType, uint8_t StorageMappingClass); void writeSymbolAuxFunctionEntry(uint32_t EntryOffset, uint32_t FunctionSize, uint64_t LineNumberPointer, uint32_t EndIndex); void writeSymbolAuxExceptionEntry(uint64_t EntryOffset, uint32_t FunctionSize, uint32_t EndIndex); void writeSymbolEntry(StringRef SymbolName, uint64_t Value, int16_t SectionNumber, uint16_t SymbolType, uint8_t StorageClass, uint8_t NumberOfAuxEntries = 1); void writeRelocations(); void writeRelocation(XCOFFRelocation Reloc, const XCOFFSection &Section); // Called after all the csects and symbols have been processed by // `executePostLayoutBinding`, this function handles building up the majority // of the structures in the object file representation. Namely: // *) Calculates physical/virtual addresses, raw-pointer offsets, and section // sizes. // *) Assigns symbol table indices. // *) Builds up the section header table by adding any non-empty sections to // `Sections`. void assignAddressesAndIndices(const MCAsmLayout &); // Called after relocations are recorded. void finalizeSectionInfo(); void finalizeRelocationInfo(SectionEntry *Sec, uint64_t RelCount); void calcOffsetToRelocations(SectionEntry *Sec, uint64_t &RawPointer); void addExceptionEntry(const MCSymbol *Symbol, const MCSymbol *Trap, unsigned LanguageCode, unsigned ReasonCode, unsigned FunctionSize, bool hasDebug) override; bool hasExceptionSection() { return !ExceptionSection.ExceptionTable.empty(); } unsigned getExceptionSectionSize(); unsigned getExceptionOffset(const MCSymbol *Symbol); void addCInfoSymEntry(StringRef Name, StringRef Metadata) override; size_t auxiliaryHeaderSize() const { // 64-bit object files have no auxiliary header. return HasVisibility && !is64Bit() ? XCOFF::AuxFileHeaderSizeShort : 0; } public: XCOFFObjectWriter(std::unique_ptr MOTW, raw_pwrite_stream &OS); void writeWord(uint64_t Word) { is64Bit() ? W.write(Word) : W.write(Word); } }; XCOFFObjectWriter::XCOFFObjectWriter( std::unique_ptr MOTW, raw_pwrite_stream &OS) : W(OS, llvm::endianness::big), TargetObjectWriter(std::move(MOTW)), Strings(StringTableBuilder::XCOFF), Text(".text", XCOFF::STYP_TEXT, /* IsVirtual */ false, CsectGroups{&ProgramCodeCsects, &ReadOnlyCsects}), Data(".data", XCOFF::STYP_DATA, /* IsVirtual */ false, CsectGroups{&DataCsects, &FuncDSCsects, &TOCCsects}), BSS(".bss", XCOFF::STYP_BSS, /* IsVirtual */ true, CsectGroups{&BSSCsects}), TData(".tdata", XCOFF::STYP_TDATA, /* IsVirtual */ false, CsectGroups{&TDataCsects}), TBSS(".tbss", XCOFF::STYP_TBSS, /* IsVirtual */ true, CsectGroups{&TBSSCsects}), ExceptionSection(".except", XCOFF::STYP_EXCEPT), CInfoSymSection(".info", XCOFF::STYP_INFO) {} void XCOFFObjectWriter::reset() { // Clear the mappings we created. SymbolIndexMap.clear(); SectionMap.clear(); UndefinedCsects.clear(); // Reset any sections we have written to, and empty the section header table. for (auto *Sec : Sections) Sec->reset(); for (auto &DwarfSec : DwarfSections) DwarfSec.reset(); for (auto &OverflowSec : OverflowSections) OverflowSec.reset(); ExceptionSection.reset(); CInfoSymSection.reset(); // Reset states in XCOFFObjectWriter. SymbolTableEntryCount = 0; SymbolTableOffset = 0; SectionCount = 0; PaddingsBeforeDwarf = 0; Strings.clear(); MCObjectWriter::reset(); } CsectGroup &XCOFFObjectWriter::getCsectGroup(const MCSectionXCOFF *MCSec) { switch (MCSec->getMappingClass()) { case XCOFF::XMC_PR: assert(XCOFF::XTY_SD == MCSec->getCSectType() && "Only an initialized csect can contain program code."); return ProgramCodeCsects; case XCOFF::XMC_RO: assert(XCOFF::XTY_SD == MCSec->getCSectType() && "Only an initialized csect can contain read only data."); return ReadOnlyCsects; case XCOFF::XMC_RW: if (XCOFF::XTY_CM == MCSec->getCSectType()) return BSSCsects; if (XCOFF::XTY_SD == MCSec->getCSectType()) return DataCsects; report_fatal_error("Unhandled mapping of read-write csect to section."); case XCOFF::XMC_DS: return FuncDSCsects; case XCOFF::XMC_BS: assert(XCOFF::XTY_CM == MCSec->getCSectType() && "Mapping invalid csect. CSECT with bss storage class must be " "common type."); return BSSCsects; case XCOFF::XMC_TL: assert(XCOFF::XTY_SD == MCSec->getCSectType() && "Mapping invalid csect. CSECT with tdata storage class must be " "an initialized csect."); return TDataCsects; case XCOFF::XMC_UL: assert(XCOFF::XTY_CM == MCSec->getCSectType() && "Mapping invalid csect. CSECT with tbss storage class must be " "an uninitialized csect."); return TBSSCsects; case XCOFF::XMC_TC0: assert(XCOFF::XTY_SD == MCSec->getCSectType() && "Only an initialized csect can contain TOC-base."); assert(TOCCsects.empty() && "We should have only one TOC-base, and it should be the first csect " "in this CsectGroup."); return TOCCsects; case XCOFF::XMC_TC: case XCOFF::XMC_TE: case XCOFF::XMC_TD: assert(XCOFF::XTY_SD == MCSec->getCSectType() && "Only an initialized csect can contain TC entry."); assert(!TOCCsects.empty() && "We should at least have a TOC-base in this CsectGroup."); return TOCCsects; default: report_fatal_error("Unhandled mapping of csect to section."); } } static MCSectionXCOFF *getContainingCsect(const MCSymbolXCOFF *XSym) { if (XSym->isDefined()) return cast(XSym->getFragment()->getParent()); return XSym->getRepresentedCsect(); } void XCOFFObjectWriter::executePostLayoutBinding(MCAssembler &Asm, const MCAsmLayout &Layout) { for (const auto &S : Asm) { const auto *MCSec = cast(&S); assert(!SectionMap.contains(MCSec) && "Cannot add a section twice."); // If the name does not fit in the storage provided in the symbol table // entry, add it to the string table. if (nameShouldBeInStringTable(MCSec->getSymbolTableName())) Strings.add(MCSec->getSymbolTableName()); if (MCSec->isCsect()) { // A new control section. Its CsectSectionEntry should already be staticly // generated as Text/Data/BSS/TDATA/TBSS. Add this section to the group of // the CsectSectionEntry. assert(XCOFF::XTY_ER != MCSec->getCSectType() && "An undefined csect should not get registered."); CsectGroup &Group = getCsectGroup(MCSec); Group.emplace_back(MCSec); SectionMap[MCSec] = &Group.back(); } else if (MCSec->isDwarfSect()) { // A new DwarfSectionEntry. std::unique_ptr DwarfSec = std::make_unique(MCSec); SectionMap[MCSec] = DwarfSec.get(); DwarfSectionEntry SecEntry(MCSec->getName(), *MCSec->getDwarfSubtypeFlags(), std::move(DwarfSec)); DwarfSections.push_back(std::move(SecEntry)); } else llvm_unreachable("unsupport section type!"); } for (const MCSymbol &S : Asm.symbols()) { // Nothing to do for temporary symbols. if (S.isTemporary()) continue; const MCSymbolXCOFF *XSym = cast(&S); const MCSectionXCOFF *ContainingCsect = getContainingCsect(XSym); if (XSym->getVisibilityType() != XCOFF::SYM_V_UNSPECIFIED) HasVisibility = true; if (ContainingCsect->getCSectType() == XCOFF::XTY_ER) { // Handle undefined symbol. UndefinedCsects.emplace_back(ContainingCsect); SectionMap[ContainingCsect] = &UndefinedCsects.back(); if (nameShouldBeInStringTable(ContainingCsect->getSymbolTableName())) Strings.add(ContainingCsect->getSymbolTableName()); continue; } // If the symbol is the csect itself, we don't need to put the symbol // into csect's Syms. if (XSym == ContainingCsect->getQualNameSymbol()) continue; // Only put a label into the symbol table when it is an external label. if (!XSym->isExternal()) continue; assert(SectionMap.contains(ContainingCsect) && "Expected containing csect to exist in map"); XCOFFSection *Csect = SectionMap[ContainingCsect]; // Lookup the containing csect and add the symbol to it. assert(Csect->MCSec->isCsect() && "only csect is supported now!"); Csect->Syms.emplace_back(XSym); // If the name does not fit in the storage provided in the symbol table // entry, add it to the string table. if (nameShouldBeInStringTable(XSym->getSymbolTableName())) Strings.add(XSym->getSymbolTableName()); } std::unique_ptr &CISI = CInfoSymSection.Entry; if (CISI && nameShouldBeInStringTable(CISI->Name)) Strings.add(CISI->Name); FileNames = Asm.getFileNames(); // Emit ".file" as the source file name when there is no file name. if (FileNames.empty()) FileNames.emplace_back(".file", 0); for (const std::pair &F : FileNames) { if (nameShouldBeInStringTable(F.first)) Strings.add(F.first); } Strings.finalize(); assignAddressesAndIndices(Layout); } void XCOFFObjectWriter::recordRelocation(MCAssembler &Asm, const MCAsmLayout &Layout, const MCFragment *Fragment, const MCFixup &Fixup, MCValue Target, uint64_t &FixedValue) { auto getIndex = [this](const MCSymbol *Sym, const MCSectionXCOFF *ContainingCsect) { // If we could not find the symbol directly in SymbolIndexMap, this symbol // could either be a temporary symbol or an undefined symbol. In this case, // we would need to have the relocation reference its csect instead. return SymbolIndexMap.contains(Sym) ? SymbolIndexMap[Sym] : SymbolIndexMap[ContainingCsect->getQualNameSymbol()]; }; auto getVirtualAddress = [this, &Layout](const MCSymbol *Sym, const MCSectionXCOFF *ContainingSect) -> uint64_t { // A DWARF section. if (ContainingSect->isDwarfSect()) return Layout.getSymbolOffset(*Sym); // A csect. if (!Sym->isDefined()) return SectionMap[ContainingSect]->Address; // A label. assert(Sym->isDefined() && "not a valid object that has address!"); return SectionMap[ContainingSect]->Address + Layout.getSymbolOffset(*Sym); }; const MCSymbol *const SymA = &Target.getSymA()->getSymbol(); MCAsmBackend &Backend = Asm.getBackend(); bool IsPCRel = Backend.getFixupKindInfo(Fixup.getKind()).Flags & MCFixupKindInfo::FKF_IsPCRel; uint8_t Type; uint8_t SignAndSize; std::tie(Type, SignAndSize) = TargetObjectWriter->getRelocTypeAndSignSize(Target, Fixup, IsPCRel); const MCSectionXCOFF *SymASec = getContainingCsect(cast(SymA)); assert(SectionMap.contains(SymASec) && "Expected containing csect to exist in map."); assert((Fixup.getOffset() <= MaxRawDataSize - Layout.getFragmentOffset(Fragment)) && "Fragment offset + fixup offset is overflowed."); uint32_t FixupOffsetInCsect = Layout.getFragmentOffset(Fragment) + Fixup.getOffset(); const uint32_t Index = getIndex(SymA, SymASec); if (Type == XCOFF::RelocationType::R_POS || Type == XCOFF::RelocationType::R_TLS || Type == XCOFF::RelocationType::R_TLS_LE || Type == XCOFF::RelocationType::R_TLS_IE) // The FixedValue should be symbol's virtual address in this object file // plus any constant value that we might get. FixedValue = getVirtualAddress(SymA, SymASec) + Target.getConstant(); else if (Type == XCOFF::RelocationType::R_TLSM) // The FixedValue should always be zero since the region handle is only // known at load time. FixedValue = 0; else if (Type == XCOFF::RelocationType::R_TOC || Type == XCOFF::RelocationType::R_TOCL) { // For non toc-data external symbols, R_TOC type relocation will relocate to // data symbols that have XCOFF::XTY_SD type csect. For toc-data external // symbols, R_TOC type relocation will relocate to data symbols that have // XCOFF_ER type csect. For XCOFF_ER kind symbols, there will be no TOC // entry for them, so the FixedValue should always be 0. if (SymASec->getCSectType() == XCOFF::XTY_ER) { FixedValue = 0; } else { // The FixedValue should be the TOC entry offset from the TOC-base plus // any constant offset value. const int64_t TOCEntryOffset = SectionMap[SymASec]->Address - TOCCsects.front().Address + Target.getConstant(); if (Type == XCOFF::RelocationType::R_TOC && !isInt<16>(TOCEntryOffset)) report_fatal_error("TOCEntryOffset overflows in small code model mode"); FixedValue = TOCEntryOffset; } } else if (Type == XCOFF::RelocationType::R_RBR) { MCSectionXCOFF *ParentSec = cast(Fragment->getParent()); assert((SymASec->getMappingClass() == XCOFF::XMC_PR && ParentSec->getMappingClass() == XCOFF::XMC_PR) && "Only XMC_PR csect may have the R_RBR relocation."); // The address of the branch instruction should be the sum of section // address, fragment offset and Fixup offset. uint64_t BRInstrAddress = SectionMap[ParentSec]->Address + FixupOffsetInCsect; // The FixedValue should be the difference between symbol's virtual address // and BR instr address plus any constant value. FixedValue = getVirtualAddress(SymA, SymASec) - BRInstrAddress + Target.getConstant(); } else if (Type == XCOFF::RelocationType::R_REF) { // The FixedValue and FixupOffsetInCsect should always be 0 since it // specifies a nonrelocating reference. FixedValue = 0; FixupOffsetInCsect = 0; } XCOFFRelocation Reloc = {Index, FixupOffsetInCsect, SignAndSize, Type}; MCSectionXCOFF *RelocationSec = cast(Fragment->getParent()); assert(SectionMap.contains(RelocationSec) && "Expected containing csect to exist in map."); SectionMap[RelocationSec]->Relocations.push_back(Reloc); if (!Target.getSymB()) return; const MCSymbol *const SymB = &Target.getSymB()->getSymbol(); if (SymA == SymB) report_fatal_error("relocation for opposite term is not yet supported"); const MCSectionXCOFF *SymBSec = getContainingCsect(cast(SymB)); assert(SectionMap.contains(SymBSec) && "Expected containing csect to exist in map."); if (SymASec == SymBSec) report_fatal_error( "relocation for paired relocatable term is not yet supported"); assert(Type == XCOFF::RelocationType::R_POS && "SymA must be R_POS here if it's not opposite term or paired " "relocatable term."); const uint32_t IndexB = getIndex(SymB, SymBSec); // SymB must be R_NEG here, given the general form of Target(MCValue) is // "SymbolA - SymbolB + imm64". const uint8_t TypeB = XCOFF::RelocationType::R_NEG; XCOFFRelocation RelocB = {IndexB, FixupOffsetInCsect, SignAndSize, TypeB}; SectionMap[RelocationSec]->Relocations.push_back(RelocB); // We already folded "SymbolA + imm64" above when Type is R_POS for SymbolA, // now we just need to fold "- SymbolB" here. FixedValue -= getVirtualAddress(SymB, SymBSec); } void XCOFFObjectWriter::writeSections(const MCAssembler &Asm, const MCAsmLayout &Layout) { uint64_t CurrentAddressLocation = 0; for (const auto *Section : Sections) writeSectionForControlSectionEntry(Asm, Layout, *Section, CurrentAddressLocation); for (const auto &DwarfSection : DwarfSections) writeSectionForDwarfSectionEntry(Asm, Layout, DwarfSection, CurrentAddressLocation); writeSectionForExceptionSectionEntry(Asm, Layout, ExceptionSection, CurrentAddressLocation); writeSectionForCInfoSymSectionEntry(Asm, Layout, CInfoSymSection, CurrentAddressLocation); } uint64_t XCOFFObjectWriter::writeObject(MCAssembler &Asm, const MCAsmLayout &Layout) { // We always emit a timestamp of 0 for reproducibility, so ensure incremental // linking is not enabled, in case, like with Windows COFF, such a timestamp // is incompatible with incremental linking of XCOFF. if (Asm.isIncrementalLinkerCompatible()) report_fatal_error("Incremental linking not supported for XCOFF."); finalizeSectionInfo(); uint64_t StartOffset = W.OS.tell(); writeFileHeader(); writeAuxFileHeader(); writeSectionHeaderTable(); writeSections(Asm, Layout); writeRelocations(); writeSymbolTable(Layout); // Write the string table. Strings.write(W.OS); return W.OS.tell() - StartOffset; } bool XCOFFObjectWriter::nameShouldBeInStringTable(const StringRef &SymbolName) { return SymbolName.size() > XCOFF::NameSize || is64Bit(); } void XCOFFObjectWriter::writeSymbolName(const StringRef &SymbolName) { // Magic, Offset or SymbolName. if (nameShouldBeInStringTable(SymbolName)) { W.write(0); W.write(Strings.getOffset(SymbolName)); } else { char Name[XCOFF::NameSize + 1]; std::strncpy(Name, SymbolName.data(), XCOFF::NameSize); ArrayRef NameRef(Name, XCOFF::NameSize); W.write(NameRef); } } void XCOFFObjectWriter::writeSymbolEntry(StringRef SymbolName, uint64_t Value, int16_t SectionNumber, uint16_t SymbolType, uint8_t StorageClass, uint8_t NumberOfAuxEntries) { if (is64Bit()) { W.write(Value); W.write(Strings.getOffset(SymbolName)); } else { writeSymbolName(SymbolName); W.write(Value); } W.write(SectionNumber); W.write(SymbolType); W.write(StorageClass); W.write(NumberOfAuxEntries); } void XCOFFObjectWriter::writeSymbolAuxCsectEntry(uint64_t SectionOrLength, uint8_t SymbolAlignmentAndType, uint8_t StorageMappingClass) { W.write(is64Bit() ? Lo_32(SectionOrLength) : SectionOrLength); W.write(0); // ParameterHashIndex W.write(0); // TypeChkSectNum W.write(SymbolAlignmentAndType); W.write(StorageMappingClass); if (is64Bit()) { W.write(Hi_32(SectionOrLength)); W.OS.write_zeros(1); // Reserved W.write(XCOFF::AUX_CSECT); } else { W.write(0); // StabInfoIndex W.write(0); // StabSectNum } } void XCOFFObjectWriter::writeSymbolAuxDwarfEntry( uint64_t LengthOfSectionPortion, uint64_t NumberOfRelocEnt) { writeWord(LengthOfSectionPortion); if (!is64Bit()) W.OS.write_zeros(4); // Reserved writeWord(NumberOfRelocEnt); if (is64Bit()) { W.OS.write_zeros(1); // Reserved W.write(XCOFF::AUX_SECT); } else { W.OS.write_zeros(6); // Reserved } } void XCOFFObjectWriter::writeSymbolEntryForCsectMemberLabel( const Symbol &SymbolRef, const XCOFFSection &CSectionRef, int16_t SectionIndex, uint64_t SymbolOffset) { assert(SymbolOffset <= MaxRawDataSize - CSectionRef.Address && "Symbol address overflowed."); auto Entry = ExceptionSection.ExceptionTable.find(SymbolRef.MCSym->getName()); if (Entry != ExceptionSection.ExceptionTable.end()) { writeSymbolEntry(SymbolRef.getSymbolTableName(), CSectionRef.Address + SymbolOffset, SectionIndex, // In the old version of the 32-bit XCOFF interpretation, // symbols may require bit 10 (0x0020) to be set if the // symbol is a function, otherwise the bit should be 0. is64Bit() ? SymbolRef.getVisibilityType() : SymbolRef.getVisibilityType() | 0x0020, SymbolRef.getStorageClass(), (is64Bit() && ExceptionSection.isDebugEnabled) ? 3 : 2); if (is64Bit() && ExceptionSection.isDebugEnabled) { // On 64 bit with debugging enabled, we have a csect, exception, and // function auxilliary entries, so we must increment symbol index by 4. writeSymbolAuxExceptionEntry( ExceptionSection.FileOffsetToData + getExceptionOffset(Entry->second.FunctionSymbol), Entry->second.FunctionSize, SymbolIndexMap[Entry->second.FunctionSymbol] + 4); } // For exception section entries, csect and function auxilliary entries // must exist. On 64-bit there is also an exception auxilliary entry. writeSymbolAuxFunctionEntry( ExceptionSection.FileOffsetToData + getExceptionOffset(Entry->second.FunctionSymbol), Entry->second.FunctionSize, 0, (is64Bit() && ExceptionSection.isDebugEnabled) ? SymbolIndexMap[Entry->second.FunctionSymbol] + 4 : SymbolIndexMap[Entry->second.FunctionSymbol] + 3); } else { writeSymbolEntry(SymbolRef.getSymbolTableName(), CSectionRef.Address + SymbolOffset, SectionIndex, SymbolRef.getVisibilityType(), SymbolRef.getStorageClass()); } writeSymbolAuxCsectEntry(CSectionRef.SymbolTableIndex, XCOFF::XTY_LD, CSectionRef.MCSec->getMappingClass()); } void XCOFFObjectWriter::writeSymbolEntryForDwarfSection( const XCOFFSection &DwarfSectionRef, int16_t SectionIndex) { assert(DwarfSectionRef.MCSec->isDwarfSect() && "Not a DWARF section!"); writeSymbolEntry(DwarfSectionRef.getSymbolTableName(), /*Value=*/0, SectionIndex, /*SymbolType=*/0, XCOFF::C_DWARF); writeSymbolAuxDwarfEntry(DwarfSectionRef.Size); } void XCOFFObjectWriter::writeSymbolEntryForControlSection( const XCOFFSection &CSectionRef, int16_t SectionIndex, XCOFF::StorageClass StorageClass) { writeSymbolEntry(CSectionRef.getSymbolTableName(), CSectionRef.Address, SectionIndex, CSectionRef.getVisibilityType(), StorageClass); writeSymbolAuxCsectEntry(CSectionRef.Size, getEncodedType(CSectionRef.MCSec), CSectionRef.MCSec->getMappingClass()); } void XCOFFObjectWriter::writeSymbolAuxFunctionEntry(uint32_t EntryOffset, uint32_t FunctionSize, uint64_t LineNumberPointer, uint32_t EndIndex) { if (is64Bit()) writeWord(LineNumberPointer); else W.write(EntryOffset); W.write(FunctionSize); if (!is64Bit()) writeWord(LineNumberPointer); W.write(EndIndex); if (is64Bit()) { W.OS.write_zeros(1); W.write(XCOFF::AUX_FCN); } else { W.OS.write_zeros(2); } } void XCOFFObjectWriter::writeSymbolAuxExceptionEntry(uint64_t EntryOffset, uint32_t FunctionSize, uint32_t EndIndex) { assert(is64Bit() && "Exception auxilliary entries are 64-bit only."); W.write(EntryOffset); W.write(FunctionSize); W.write(EndIndex); W.OS.write_zeros(1); // Pad (unused) W.write(XCOFF::AUX_EXCEPT); } void XCOFFObjectWriter::writeFileHeader() { W.write(is64Bit() ? XCOFF::XCOFF64 : XCOFF::XCOFF32); W.write(SectionCount); W.write(0); // TimeStamp writeWord(SymbolTableOffset); if (is64Bit()) { W.write(auxiliaryHeaderSize()); W.write(0); // Flags W.write(SymbolTableEntryCount); } else { W.write(SymbolTableEntryCount); W.write(auxiliaryHeaderSize()); W.write(0); // Flags } } void XCOFFObjectWriter::writeAuxFileHeader() { if (!auxiliaryHeaderSize()) return; W.write(0); // Magic W.write( XCOFF::NEW_XCOFF_INTERPRET); // Version. The new interpretation of the // n_type field in the symbol table entry is // used in XCOFF32. W.write(Sections[0]->Size); // TextSize W.write(Sections[1]->Size); // InitDataSize W.write(Sections[2]->Size); // BssDataSize W.write(0); // EntryPointAddr W.write(Sections[0]->Address); // TextStartAddr W.write(Sections[1]->Address); // DataStartAddr } void XCOFFObjectWriter::writeSectionHeader(const SectionEntry *Sec) { bool IsDwarf = (Sec->Flags & XCOFF::STYP_DWARF) != 0; bool IsOvrflo = (Sec->Flags & XCOFF::STYP_OVRFLO) != 0; // Nothing to write for this Section. if (Sec->Index == SectionEntry::UninitializedIndex) return; // Write Name. ArrayRef NameRef(Sec->Name, XCOFF::NameSize); W.write(NameRef); // Write the Physical Address and Virtual Address. // We use 0 for DWARF sections' Physical and Virtual Addresses. writeWord(IsDwarf ? 0 : Sec->Address); // Since line number is not supported, we set it to 0 for overflow sections. writeWord((IsDwarf || IsOvrflo) ? 0 : Sec->Address); writeWord(Sec->Size); writeWord(Sec->FileOffsetToData); writeWord(Sec->FileOffsetToRelocations); writeWord(0); // FileOffsetToLineNumberInfo. Not supported yet. if (is64Bit()) { W.write(Sec->RelocationCount); W.write(0); // NumberOfLineNumbers. Not supported yet. W.write(Sec->Flags); W.OS.write_zeros(4); } else { // For the overflow section header, s_nreloc provides a reference to the // primary section header and s_nlnno must have the same value. // For common section headers, if either of s_nreloc or s_nlnno are set to // 65535, the other one must also be set to 65535. W.write(Sec->RelocationCount); W.write((IsOvrflo || Sec->RelocationCount == XCOFF::RelocOverflow) ? Sec->RelocationCount : 0); // NumberOfLineNumbers. Not supported yet. W.write(Sec->Flags); } } void XCOFFObjectWriter::writeSectionHeaderTable() { for (const auto *CsectSec : Sections) writeSectionHeader(CsectSec); for (const auto &DwarfSec : DwarfSections) writeSectionHeader(&DwarfSec); for (const auto &OverflowSec : OverflowSections) writeSectionHeader(&OverflowSec); if (hasExceptionSection()) writeSectionHeader(&ExceptionSection); if (CInfoSymSection.Entry) writeSectionHeader(&CInfoSymSection); } void XCOFFObjectWriter::writeRelocation(XCOFFRelocation Reloc, const XCOFFSection &Section) { if (Section.MCSec->isCsect()) writeWord(Section.Address + Reloc.FixupOffsetInCsect); else { // DWARF sections' address is set to 0. assert(Section.MCSec->isDwarfSect() && "unsupport section type!"); writeWord(Reloc.FixupOffsetInCsect); } W.write(Reloc.SymbolTableIndex); W.write(Reloc.SignAndSize); W.write(Reloc.Type); } void XCOFFObjectWriter::writeRelocations() { for (const auto *Section : Sections) { if (Section->Index == SectionEntry::UninitializedIndex) // Nothing to write for this Section. continue; for (const auto *Group : Section->Groups) { if (Group->empty()) continue; for (const auto &Csect : *Group) { for (const auto Reloc : Csect.Relocations) writeRelocation(Reloc, Csect); } } } for (const auto &DwarfSection : DwarfSections) for (const auto &Reloc : DwarfSection.DwarfSect->Relocations) writeRelocation(Reloc, *DwarfSection.DwarfSect); } void XCOFFObjectWriter::writeSymbolTable(const MCAsmLayout &Layout) { // Write C_FILE symbols. for (const std::pair &F : FileNames) { // The n_name of a C_FILE symbol is the source file's name when no auxiliary // entries are present. StringRef FileName = F.first; // For C_FILE symbols, the Source Language ID overlays the high-order byte // of the SymbolType field, and the CPU Version ID is defined as the // low-order byte. // AIX's system assembler determines the source language ID based on the // source file's name suffix, and the behavior here is consistent with it. uint8_t LangID; if (FileName.ends_with(".c")) LangID = XCOFF::TB_C; else if (FileName.ends_with_insensitive(".f") || FileName.ends_with_insensitive(".f77") || FileName.ends_with_insensitive(".f90") || FileName.ends_with_insensitive(".f95") || FileName.ends_with_insensitive(".f03") || FileName.ends_with_insensitive(".f08")) LangID = XCOFF::TB_Fortran; else LangID = XCOFF::TB_CPLUSPLUS; uint8_t CpuID; if (is64Bit()) CpuID = XCOFF::TCPU_PPC64; else CpuID = XCOFF::TCPU_COM; writeSymbolEntry(FileName, /*Value=*/0, XCOFF::ReservedSectionNum::N_DEBUG, /*SymbolType=*/(LangID << 8) | CpuID, XCOFF::C_FILE, /*NumberOfAuxEntries=*/0); } if (CInfoSymSection.Entry) writeSymbolEntry(CInfoSymSection.Entry->Name, CInfoSymSection.Entry->Offset, CInfoSymSection.Index, /*SymbolType=*/0, XCOFF::C_INFO, /*NumberOfAuxEntries=*/0); for (const auto &Csect : UndefinedCsects) { writeSymbolEntryForControlSection(Csect, XCOFF::ReservedSectionNum::N_UNDEF, Csect.MCSec->getStorageClass()); } for (const auto *Section : Sections) { if (Section->Index == SectionEntry::UninitializedIndex) // Nothing to write for this Section. continue; for (const auto *Group : Section->Groups) { if (Group->empty()) continue; const int16_t SectionIndex = Section->Index; for (const auto &Csect : *Group) { // Write out the control section first and then each symbol in it. writeSymbolEntryForControlSection(Csect, SectionIndex, Csect.MCSec->getStorageClass()); for (const auto &Sym : Csect.Syms) writeSymbolEntryForCsectMemberLabel( Sym, Csect, SectionIndex, Layout.getSymbolOffset(*(Sym.MCSym))); } } } for (const auto &DwarfSection : DwarfSections) writeSymbolEntryForDwarfSection(*DwarfSection.DwarfSect, DwarfSection.Index); } void XCOFFObjectWriter::finalizeRelocationInfo(SectionEntry *Sec, uint64_t RelCount) { // Handles relocation field overflows in an XCOFF32 file. An XCOFF64 file // may not contain an overflow section header. if (!is64Bit() && (RelCount >= static_cast(XCOFF::RelocOverflow))) { // Generate an overflow section header. SectionEntry SecEntry(".ovrflo", XCOFF::STYP_OVRFLO); // This field specifies the file section number of the section header that // overflowed. SecEntry.RelocationCount = Sec->Index; // This field specifies the number of relocation entries actually // required. SecEntry.Address = RelCount; SecEntry.Index = ++SectionCount; OverflowSections.push_back(std::move(SecEntry)); // The field in the primary section header is always 65535 // (XCOFF::RelocOverflow). Sec->RelocationCount = XCOFF::RelocOverflow; } else { Sec->RelocationCount = RelCount; } } void XCOFFObjectWriter::calcOffsetToRelocations(SectionEntry *Sec, uint64_t &RawPointer) { if (!Sec->RelocationCount) return; Sec->FileOffsetToRelocations = RawPointer; uint64_t RelocationSizeInSec = 0; if (!is64Bit() && Sec->RelocationCount == static_cast(XCOFF::RelocOverflow)) { // Find its corresponding overflow section. for (auto &OverflowSec : OverflowSections) { if (OverflowSec.RelocationCount == static_cast(Sec->Index)) { RelocationSizeInSec = OverflowSec.Address * XCOFF::RelocationSerializationSize32; // This field must have the same values as in the corresponding // primary section header. OverflowSec.FileOffsetToRelocations = Sec->FileOffsetToRelocations; } } assert(RelocationSizeInSec && "Overflow section header doesn't exist."); } else { RelocationSizeInSec = Sec->RelocationCount * (is64Bit() ? XCOFF::RelocationSerializationSize64 : XCOFF::RelocationSerializationSize32); } RawPointer += RelocationSizeInSec; if (RawPointer > MaxRawDataSize) report_fatal_error("Relocation data overflowed this object file."); } void XCOFFObjectWriter::finalizeSectionInfo() { for (auto *Section : Sections) { if (Section->Index == SectionEntry::UninitializedIndex) // Nothing to record for this Section. continue; uint64_t RelCount = 0; for (const auto *Group : Section->Groups) { if (Group->empty()) continue; for (auto &Csect : *Group) RelCount += Csect.Relocations.size(); } finalizeRelocationInfo(Section, RelCount); } for (auto &DwarfSection : DwarfSections) finalizeRelocationInfo(&DwarfSection, DwarfSection.DwarfSect->Relocations.size()); // Calculate the RawPointer value for all headers. uint64_t RawPointer = (is64Bit() ? (XCOFF::FileHeaderSize64 + SectionCount * XCOFF::SectionHeaderSize64) : (XCOFF::FileHeaderSize32 + SectionCount * XCOFF::SectionHeaderSize32)) + auxiliaryHeaderSize(); // Calculate the file offset to the section data. for (auto *Sec : Sections) { if (Sec->Index == SectionEntry::UninitializedIndex || Sec->IsVirtual) continue; RawPointer = Sec->advanceFileOffset(MaxRawDataSize, RawPointer); } if (!DwarfSections.empty()) { RawPointer += PaddingsBeforeDwarf; for (auto &DwarfSection : DwarfSections) { RawPointer = DwarfSection.advanceFileOffset(MaxRawDataSize, RawPointer); } } if (hasExceptionSection()) RawPointer = ExceptionSection.advanceFileOffset(MaxRawDataSize, RawPointer); if (CInfoSymSection.Entry) RawPointer = CInfoSymSection.advanceFileOffset(MaxRawDataSize, RawPointer); for (auto *Sec : Sections) { if (Sec->Index != SectionEntry::UninitializedIndex) calcOffsetToRelocations(Sec, RawPointer); } for (auto &DwarfSec : DwarfSections) calcOffsetToRelocations(&DwarfSec, RawPointer); // TODO Error check that the number of symbol table entries fits in 32-bits // signed ... if (SymbolTableEntryCount) SymbolTableOffset = RawPointer; } void XCOFFObjectWriter::addExceptionEntry( const MCSymbol *Symbol, const MCSymbol *Trap, unsigned LanguageCode, unsigned ReasonCode, unsigned FunctionSize, bool hasDebug) { // If a module had debug info, debugging is enabled and XCOFF emits the // exception auxilliary entry. if (hasDebug) ExceptionSection.isDebugEnabled = true; auto Entry = ExceptionSection.ExceptionTable.find(Symbol->getName()); if (Entry != ExceptionSection.ExceptionTable.end()) { Entry->second.Entries.push_back( ExceptionTableEntry(Trap, LanguageCode, ReasonCode)); return; } ExceptionInfo NewEntry; NewEntry.FunctionSymbol = Symbol; NewEntry.FunctionSize = FunctionSize; NewEntry.Entries.push_back( ExceptionTableEntry(Trap, LanguageCode, ReasonCode)); ExceptionSection.ExceptionTable.insert( std::pair(Symbol->getName(), NewEntry)); } unsigned XCOFFObjectWriter::getExceptionSectionSize() { unsigned EntryNum = 0; for (auto it = ExceptionSection.ExceptionTable.begin(); it != ExceptionSection.ExceptionTable.end(); ++it) // The size() gets +1 to account for the initial entry containing the // symbol table index. EntryNum += it->second.Entries.size() + 1; return EntryNum * (is64Bit() ? XCOFF::ExceptionSectionEntrySize64 : XCOFF::ExceptionSectionEntrySize32); } unsigned XCOFFObjectWriter::getExceptionOffset(const MCSymbol *Symbol) { unsigned EntryNum = 0; for (auto it = ExceptionSection.ExceptionTable.begin(); it != ExceptionSection.ExceptionTable.end(); ++it) { if (Symbol == it->second.FunctionSymbol) break; EntryNum += it->second.Entries.size() + 1; } return EntryNum * (is64Bit() ? XCOFF::ExceptionSectionEntrySize64 : XCOFF::ExceptionSectionEntrySize32); } void XCOFFObjectWriter::addCInfoSymEntry(StringRef Name, StringRef Metadata) { assert(!CInfoSymSection.Entry && "Multiple entries are not supported"); CInfoSymSection.addEntry( std::make_unique(Name.str(), Metadata.str())); } void XCOFFObjectWriter::assignAddressesAndIndices(const MCAsmLayout &Layout) { // The symbol table starts with all the C_FILE symbols. uint32_t SymbolTableIndex = FileNames.size(); if (CInfoSymSection.Entry) SymbolTableIndex++; // Calculate indices for undefined symbols. for (auto &Csect : UndefinedCsects) { Csect.Size = 0; Csect.Address = 0; Csect.SymbolTableIndex = SymbolTableIndex; SymbolIndexMap[Csect.MCSec->getQualNameSymbol()] = Csect.SymbolTableIndex; // 1 main and 1 auxiliary symbol table entry for each contained symbol. SymbolTableIndex += 2; } // The address corrresponds to the address of sections and symbols in the // object file. We place the shared address 0 immediately after the // section header table. uint64_t Address = 0; // Section indices are 1-based in XCOFF. int32_t SectionIndex = 1; bool HasTDataSection = false; for (auto *Section : Sections) { const bool IsEmpty = llvm::all_of(Section->Groups, [](const CsectGroup *Group) { return Group->empty(); }); if (IsEmpty) continue; if (SectionIndex > MaxSectionIndex) report_fatal_error("Section index overflow!"); Section->Index = SectionIndex++; SectionCount++; bool SectionAddressSet = false; // Reset the starting address to 0 for TData section. if (Section->Flags == XCOFF::STYP_TDATA) { Address = 0; HasTDataSection = true; } // Reset the starting address to 0 for TBSS section if the object file does // not contain TData Section. if ((Section->Flags == XCOFF::STYP_TBSS) && !HasTDataSection) Address = 0; for (auto *Group : Section->Groups) { if (Group->empty()) continue; for (auto &Csect : *Group) { const MCSectionXCOFF *MCSec = Csect.MCSec; Csect.Address = alignTo(Address, MCSec->getAlign()); Csect.Size = Layout.getSectionAddressSize(MCSec); Address = Csect.Address + Csect.Size; Csect.SymbolTableIndex = SymbolTableIndex; SymbolIndexMap[MCSec->getQualNameSymbol()] = Csect.SymbolTableIndex; // 1 main and 1 auxiliary symbol table entry for the csect. SymbolTableIndex += 2; for (auto &Sym : Csect.Syms) { bool hasExceptEntry = false; auto Entry = ExceptionSection.ExceptionTable.find(Sym.MCSym->getName()); if (Entry != ExceptionSection.ExceptionTable.end()) { hasExceptEntry = true; for (auto &TrapEntry : Entry->second.Entries) { TrapEntry.TrapAddress = Layout.getSymbolOffset(*(Sym.MCSym)) + TrapEntry.Trap->getOffset(); } } Sym.SymbolTableIndex = SymbolTableIndex; SymbolIndexMap[Sym.MCSym] = Sym.SymbolTableIndex; // 1 main and 1 auxiliary symbol table entry for each contained // symbol. For symbols with exception section entries, a function // auxilliary entry is needed, and on 64-bit XCOFF with debugging // enabled, an additional exception auxilliary entry is needed. SymbolTableIndex += 2; if (hasExceptionSection() && hasExceptEntry) { if (is64Bit() && ExceptionSection.isDebugEnabled) SymbolTableIndex += 2; else SymbolTableIndex += 1; } } } if (!SectionAddressSet) { Section->Address = Group->front().Address; SectionAddressSet = true; } } // Make sure the address of the next section aligned to // DefaultSectionAlign. Address = alignTo(Address, DefaultSectionAlign); Section->Size = Address - Section->Address; } // Start to generate DWARF sections. Sections other than DWARF section use // DefaultSectionAlign as the default alignment, while DWARF sections have // their own alignments. If these two alignments are not the same, we need // some paddings here and record the paddings bytes for FileOffsetToData // calculation. if (!DwarfSections.empty()) PaddingsBeforeDwarf = alignTo(Address, (*DwarfSections.begin()).DwarfSect->MCSec->getAlign()) - Address; DwarfSectionEntry *LastDwarfSection = nullptr; for (auto &DwarfSection : DwarfSections) { assert((SectionIndex <= MaxSectionIndex) && "Section index overflow!"); XCOFFSection &DwarfSect = *DwarfSection.DwarfSect; const MCSectionXCOFF *MCSec = DwarfSect.MCSec; // Section index. DwarfSection.Index = SectionIndex++; SectionCount++; // Symbol index. DwarfSect.SymbolTableIndex = SymbolTableIndex; SymbolIndexMap[MCSec->getQualNameSymbol()] = DwarfSect.SymbolTableIndex; // 1 main and 1 auxiliary symbol table entry for the csect. SymbolTableIndex += 2; // Section address. Make it align to section alignment. // We use address 0 for DWARF sections' Physical and Virtual Addresses. // This address is used to tell where is the section in the final object. // See writeSectionForDwarfSectionEntry(). DwarfSection.Address = DwarfSect.Address = alignTo(Address, MCSec->getAlign()); // Section size. // For DWARF section, we must use the real size which may be not aligned. DwarfSection.Size = DwarfSect.Size = Layout.getSectionAddressSize(MCSec); Address = DwarfSection.Address + DwarfSection.Size; if (LastDwarfSection) LastDwarfSection->MemorySize = DwarfSection.Address - LastDwarfSection->Address; LastDwarfSection = &DwarfSection; } if (LastDwarfSection) { // Make the final DWARF section address align to the default section // alignment for follow contents. Address = alignTo(LastDwarfSection->Address + LastDwarfSection->Size, DefaultSectionAlign); LastDwarfSection->MemorySize = Address - LastDwarfSection->Address; } if (hasExceptionSection()) { ExceptionSection.Index = SectionIndex++; SectionCount++; ExceptionSection.Address = 0; ExceptionSection.Size = getExceptionSectionSize(); Address += ExceptionSection.Size; Address = alignTo(Address, DefaultSectionAlign); } if (CInfoSymSection.Entry) { CInfoSymSection.Index = SectionIndex++; SectionCount++; CInfoSymSection.Address = 0; Address += CInfoSymSection.Size; Address = alignTo(Address, DefaultSectionAlign); } SymbolTableEntryCount = SymbolTableIndex; } void XCOFFObjectWriter::writeSectionForControlSectionEntry( const MCAssembler &Asm, const MCAsmLayout &Layout, const CsectSectionEntry &CsectEntry, uint64_t &CurrentAddressLocation) { // Nothing to write for this Section. if (CsectEntry.Index == SectionEntry::UninitializedIndex) return; // There could be a gap (without corresponding zero padding) between // sections. // There could be a gap (without corresponding zero padding) between // sections. assert(((CurrentAddressLocation <= CsectEntry.Address) || (CsectEntry.Flags == XCOFF::STYP_TDATA) || (CsectEntry.Flags == XCOFF::STYP_TBSS)) && "CurrentAddressLocation should be less than or equal to section " "address if the section is not TData or TBSS."); CurrentAddressLocation = CsectEntry.Address; // For virtual sections, nothing to write. But need to increase // CurrentAddressLocation for later sections like DWARF section has a correct // writing location. if (CsectEntry.IsVirtual) { CurrentAddressLocation += CsectEntry.Size; return; } for (const auto &Group : CsectEntry.Groups) { for (const auto &Csect : *Group) { if (uint32_t PaddingSize = Csect.Address - CurrentAddressLocation) W.OS.write_zeros(PaddingSize); if (Csect.Size) Asm.writeSectionData(W.OS, Csect.MCSec, Layout); CurrentAddressLocation = Csect.Address + Csect.Size; } } // The size of the tail padding in a section is the end virtual address of // the current section minus the end virtual address of the last csect // in that section. if (uint64_t PaddingSize = CsectEntry.Address + CsectEntry.Size - CurrentAddressLocation) { W.OS.write_zeros(PaddingSize); CurrentAddressLocation += PaddingSize; } } void XCOFFObjectWriter::writeSectionForDwarfSectionEntry( const MCAssembler &Asm, const MCAsmLayout &Layout, const DwarfSectionEntry &DwarfEntry, uint64_t &CurrentAddressLocation) { // There could be a gap (without corresponding zero padding) between // sections. For example DWARF section alignment is bigger than // DefaultSectionAlign. assert(CurrentAddressLocation <= DwarfEntry.Address && "CurrentAddressLocation should be less than or equal to section " "address."); if (uint64_t PaddingSize = DwarfEntry.Address - CurrentAddressLocation) W.OS.write_zeros(PaddingSize); if (DwarfEntry.Size) Asm.writeSectionData(W.OS, DwarfEntry.DwarfSect->MCSec, Layout); CurrentAddressLocation = DwarfEntry.Address + DwarfEntry.Size; // DWARF section size is not aligned to DefaultSectionAlign. // Make sure CurrentAddressLocation is aligned to DefaultSectionAlign. uint32_t Mod = CurrentAddressLocation % DefaultSectionAlign; uint32_t TailPaddingSize = Mod ? DefaultSectionAlign - Mod : 0; if (TailPaddingSize) W.OS.write_zeros(TailPaddingSize); CurrentAddressLocation += TailPaddingSize; } void XCOFFObjectWriter::writeSectionForExceptionSectionEntry( const MCAssembler &Asm, const MCAsmLayout &Layout, ExceptionSectionEntry &ExceptionEntry, uint64_t &CurrentAddressLocation) { for (auto it = ExceptionEntry.ExceptionTable.begin(); it != ExceptionEntry.ExceptionTable.end(); it++) { // For every symbol that has exception entries, you must start the entries // with an initial symbol table index entry W.write(SymbolIndexMap[it->second.FunctionSymbol]); if (is64Bit()) { // 4-byte padding on 64-bit. W.OS.write_zeros(4); } W.OS.write_zeros(2); for (auto &TrapEntry : it->second.Entries) { writeWord(TrapEntry.TrapAddress); W.write(TrapEntry.Lang); W.write(TrapEntry.Reason); } } CurrentAddressLocation += getExceptionSectionSize(); } void XCOFFObjectWriter::writeSectionForCInfoSymSectionEntry( const MCAssembler &Asm, const MCAsmLayout &Layout, CInfoSymSectionEntry &CInfoSymEntry, uint64_t &CurrentAddressLocation) { if (!CInfoSymSection.Entry) return; constexpr int WordSize = sizeof(uint32_t); std::unique_ptr &CISI = CInfoSymEntry.Entry; const std::string &Metadata = CISI->Metadata; // Emit the 4-byte length of the metadata. W.write(Metadata.size()); if (Metadata.size() == 0) return; // Write out the payload one word at a time. size_t Index = 0; while (Index + WordSize <= Metadata.size()) { uint32_t NextWord = llvm::support::endian::read32be(Metadata.data() + Index); W.write(NextWord); Index += WordSize; } // If there is padding, we have at least one byte of payload left to emit. if (CISI->paddingSize()) { std::array LastWord = {0}; ::memcpy(LastWord.data(), Metadata.data() + Index, Metadata.size() - Index); W.write(llvm::support::endian::read32be(LastWord.data())); } CurrentAddressLocation += CISI->size(); } // Takes the log base 2 of the alignment and shifts the result into the 5 most // significant bits of a byte, then or's in the csect type into the least // significant 3 bits. uint8_t getEncodedType(const MCSectionXCOFF *Sec) { unsigned Log2Align = Log2(Sec->getAlign()); // Result is a number in the range [0, 31] which fits in the 5 least // significant bits. Shift this value into the 5 most significant bits, and // bitwise-or in the csect type. uint8_t EncodedAlign = Log2Align << 3; return EncodedAlign | Sec->getCSectType(); } } // end anonymous namespace std::unique_ptr llvm::createXCOFFObjectWriter(std::unique_ptr MOTW, raw_pwrite_stream &OS) { return std::make_unique(std::move(MOTW), OS); }