lib/MC/XCOFFObjectWriter.cpp - llvm - Git at Google

 //===-- 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/MCAsmLayout.h"
 #include "llvm/MC/MCAssembler.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/Error.h"
 #include "llvm/Support/MathExtras.h"

 #include <deque>

 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;

 // Packs the csect's alignment and type into a byte.
 uint8_t getEncodedType(const MCSectionXCOFF *);

 // Wrapper around an MCSymbolXCOFF.
 struct Symbol {
   const MCSymbolXCOFF *const MCSym;
   uint32_t SymbolTableIndex;

   XCOFF::StorageClass getStorageClass() const {
     return MCSym->getStorageClass();
   }
   StringRef getName() const { return MCSym->getName(); }
   Symbol(const MCSymbolXCOFF *MCSym) : MCSym(MCSym), SymbolTableIndex(-1) {}
 };

 // Wrapper for an MCSectionXCOFF.
 struct ControlSection {
   const MCSectionXCOFF *const MCCsect;
   uint32_t SymbolTableIndex;
   uint32_t Address;
   uint32_t Size;

   SmallVector<Symbol, 1> Syms;
   StringRef getName() const { return MCCsect->getSectionName(); }
   ControlSection(const MCSectionXCOFF *MCSec)
       : MCCsect(MCSec), SymbolTableIndex(-1), Address(-1), Size(0) {}
 };

 // 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 Section {
   char Name[XCOFF::NameSize];
   // The physical/virtual address of the section. For an object file
   // these values are equivalent.
   uint32_t Address;
   uint32_t Size;
   uint32_t FileOffsetToData;
   uint32_t FileOffsetToRelocations;
   uint32_t RelocationCount;
   int32_t Flags;

   int16_t Index;

   // Virtual sections do not need storage allocated in the object file.
   const bool IsVirtual;

   void reset() {
     Address = 0;
     Size = 0;
     FileOffsetToData = 0;
     FileOffsetToRelocations = 0;
     RelocationCount = 0;
     Index = -1;
   }

   Section(const char *N, XCOFF::SectionTypeFlags Flags, bool IsVirtual)
       : Address(0), Size(0), FileOffsetToData(0), FileOffsetToRelocations(0),
         RelocationCount(0), Flags(Flags), Index(-1), IsVirtual(IsVirtual) {
     strncpy(Name, N, XCOFF::NameSize);
   }
 };

 class XCOFFObjectWriter : public MCObjectWriter {
   // 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<ControlSection>;

   support::endian::Writer W;
   std::unique_ptr<MCXCOFFObjectTargetWriter> TargetObjectWriter;
   StringTableBuilder Strings;

   // The non-empty sections, in the order they will appear in the section header
   // table.
   std::vector<Section *> Sections;

   // The Predefined sections.
   Section Text;
   Section BSS;

   // 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 ProgramCodeCsects;
   CsectGroup BSSCsects;

   uint32_t SymbolTableEntryCount = 0;
   uint32_t SymbolTableOffset = 0;

   virtual 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;

   static bool nameShouldBeInStringTable(const StringRef &);
   void writeSymbolName(const StringRef &);
   void writeSymbolTableEntryForCsectMemberLabel(const Symbol &,
                                                 const ControlSection &, int16_t,
                                                 uint64_t);
   void writeSymbolTableEntryForControlSection(const ControlSection &, int16_t,
                                               XCOFF::StorageClass);
   void writeFileHeader();
   void writeSectionHeaderTable();
   void writeSections(const MCAssembler &Asm, const MCAsmLayout &Layout);
   void writeSymbolTable(const MCAsmLayout &Layout);

   // 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 &);

   bool
   needsAuxiliaryHeader() const { /* TODO aux header support not implemented. */
     return false;
   }

   // Returns the size of the auxiliary header to be written to the object file.
   size_t auxiliaryHeaderSize() const {
     assert(!needsAuxiliaryHeader() &&
            "Auxiliary header support not implemented.");
     return 0;
   }

 public:
   XCOFFObjectWriter(std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW,
                     raw_pwrite_stream &OS);
 };

 XCOFFObjectWriter::XCOFFObjectWriter(
     std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW, raw_pwrite_stream &OS)
     : W(OS, support::big), TargetObjectWriter(std::move(MOTW)),
       Strings(StringTableBuilder::XCOFF),
       Text(".text", XCOFF::STYP_TEXT, /* IsVirtual */ false),
       BSS(".bss", XCOFF::STYP_BSS, /* IsVirtual */ true) {}

 void XCOFFObjectWriter::reset() {
   // Reset any sections we have written to, and empty the section header table.
   for (auto *Sec : Sections)
     Sec->reset();
   Sections.clear();

   // Clear any csects we have stored.
   ProgramCodeCsects.clear();
   BSSCsects.clear();

   // Reset the symbol table and string table.
   SymbolTableEntryCount = 0;
   SymbolTableOffset = 0;
   Strings.clear();

   MCObjectWriter::reset();
 }

 void XCOFFObjectWriter::executePostLayoutBinding(MCAssembler &Asm,
                                                  const MCAsmLayout &Layout) {
   if (TargetObjectWriter->is64Bit())
     report_fatal_error("64-bit XCOFF object files are not supported yet.");

   // Maps the MC Section representation to its corresponding ControlSection
   // wrapper. Needed for finding the ControlSection to insert an MCSymbol into
   // from its containing MCSectionXCOFF.
   DenseMap<const MCSectionXCOFF *, ControlSection *> WrapperMap;

   for (const auto &S : Asm) {
     const auto *MCSec = cast<const MCSectionXCOFF>(&S);
     assert(WrapperMap.find(MCSec) == WrapperMap.end() &&
            "Cannot add a csect 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->getSectionName()))
       Strings.add(MCSec->getSectionName());

     switch (MCSec->getMappingClass()) {
     case XCOFF::XMC_PR:
       assert(XCOFF::XTY_SD == MCSec->getCSectType() &&
              "Only an initialized csect can contain program code.");
       ProgramCodeCsects.emplace_back(MCSec);
       WrapperMap[MCSec] = &ProgramCodeCsects.back();
       break;
     case XCOFF::XMC_RW:
       if (XCOFF::XTY_CM == MCSec->getCSectType()) {
         BSSCsects.emplace_back(MCSec);
         WrapperMap[MCSec] = &BSSCsects.back();
         break;
       }
       report_fatal_error("Unhandled mapping of read-write csect to section.");
     case XCOFF::XMC_TC0:
       // TODO FIXME Handle emiting the TOC base.
       break;
     case XCOFF::XMC_BS:
       assert(XCOFF::XTY_CM == MCSec->getCSectType() &&
              "Mapping invalid csect. CSECT with bss storage class must be "
              "common type.");
       BSSCsects.emplace_back(MCSec);
       WrapperMap[MCSec] = &BSSCsects.back();
       break;
     default:
       report_fatal_error("Unhandled mapping of csect to section.");
     }
   }

   for (const MCSymbol &S : Asm.symbols()) {
     // Nothing to do for temporary symbols.
     if (S.isTemporary())
       continue;
     const MCSymbolXCOFF *XSym = cast<MCSymbolXCOFF>(&S);

     // Map the symbol into its containing csect.
     const MCSectionXCOFF *ContainingCsect = XSym->getContainingCsect();
     assert(WrapperMap.find(ContainingCsect) != WrapperMap.end() &&
            "Expected containing csect to exist in map");

     // Lookup the containing csect and add the symbol to it.
     WrapperMap[ContainingCsect]->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->getName()))
       Strings.add(XSym->getName());
     }

   Strings.finalize();
   assignAddressesAndIndices(Layout);
 }

 void XCOFFObjectWriter::recordRelocation(MCAssembler &, const MCAsmLayout &,
                                          const MCFragment *, const MCFixup &,
                                          MCValue, uint64_t &) {
   report_fatal_error("XCOFF relocations not supported.");
 }

 void XCOFFObjectWriter::writeSections(const MCAssembler &Asm,
                                       const MCAsmLayout &Layout) {
   // Write the program code control sections one at a time.
   uint32_t CurrentAddressLocation = Text.Address;
   for (const auto &Csect : ProgramCodeCsects) {
     if (uint32_t PaddingSize = Csect.Address - CurrentAddressLocation)
       W.OS.write_zeros(PaddingSize);
     Asm.writeSectionData(W.OS, Csect.MCCsect, Layout);
     CurrentAddressLocation = Csect.Address + Csect.Size;
   }

   if (Text.Index != -1) {
     // The size of the tail padding in a section is the end virtual address of
     // the current section minus the the end virtual address of the last csect
     // in that section.
     if (uint32_t PaddingSize =
             Text.Address + Text.Size - CurrentAddressLocation)
       W.OS.write_zeros(PaddingSize);
   }
 }

 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.");

   if (TargetObjectWriter->is64Bit())
     report_fatal_error("64-bit XCOFF object files are not supported yet.");

   uint64_t StartOffset = W.OS.tell();

   writeFileHeader();
   writeSectionHeaderTable();
   writeSections(Asm, Layout);
   // TODO 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;
 }

 void XCOFFObjectWriter::writeSymbolName(const StringRef &SymbolName) {
   if (nameShouldBeInStringTable(SymbolName)) {
     W.write<int32_t>(0);
     W.write<uint32_t>(Strings.getOffset(SymbolName));
   } else {
     char Name[XCOFF::NameSize];
     std::strncpy(Name, SymbolName.data(), XCOFF::NameSize);
     ArrayRef<char> NameRef(Name, XCOFF::NameSize);
     W.write(NameRef);
   }
 }

 void XCOFFObjectWriter::writeSymbolTableEntryForCsectMemberLabel(
     const Symbol &SymbolRef, const ControlSection &CSectionRef,
     int16_t SectionIndex, uint64_t SymbolOffset) {
   // Name or Zeros and string table offset
   writeSymbolName(SymbolRef.getName());
   assert(SymbolOffset <= UINT32_MAX - CSectionRef.Address &&
          "Symbol address overflows.");
   W.write<uint32_t>(CSectionRef.Address + SymbolOffset);
   W.write<int16_t>(SectionIndex);
   // Basic/Derived type. See the description of the n_type field for symbol
   // table entries for a detailed description. Since we don't yet support
   // visibility, and all other bits are either optionally set or reserved, this
   // is always zero.
   // TODO FIXME How to assert a symbol's visibilty is default?
   // TODO Set the function indicator (bit 10, 0x0020) for functions
   // when debugging is enabled.
   W.write<uint16_t>(0);
   W.write<uint8_t>(SymbolRef.getStorageClass());
   // Always 1 aux entry for now.
   W.write<uint8_t>(1);

   // Now output the auxiliary entry.
   W.write<uint32_t>(CSectionRef.SymbolTableIndex);
   // Parameter typecheck hash. Not supported.
   W.write<uint32_t>(0);
   // Typecheck section number. Not supported.
   W.write<uint16_t>(0);
   // Symbol type: Label
   W.write<uint8_t>(XCOFF::XTY_LD);
   // Storage mapping class.
   W.write<uint8_t>(CSectionRef.MCCsect->getMappingClass());
   // Reserved (x_stab).
   W.write<uint32_t>(0);
   // Reserved (x_snstab).
   W.write<uint16_t>(0);
 }

 void XCOFFObjectWriter::writeSymbolTableEntryForControlSection(
     const ControlSection &CSectionRef, int16_t SectionIndex,
     XCOFF::StorageClass StorageClass) {
   // n_name, n_zeros, n_offset
   writeSymbolName(CSectionRef.getName());
   // n_value
   W.write<uint32_t>(CSectionRef.Address);
   // n_scnum
   W.write<int16_t>(SectionIndex);
   // Basic/Derived type. See the description of the n_type field for symbol
   // table entries for a detailed description. Since we don't yet support
   // visibility, and all other bits are either optionally set or reserved, this
   // is always zero.
   // TODO FIXME How to assert a symbol's visibilty is default?
   // TODO Set the function indicator (bit 10, 0x0020) for functions
   // when debugging is enabled.
   W.write<uint16_t>(0);
   // n_sclass
   W.write<uint8_t>(StorageClass);
   // Always 1 aux entry for now.
   W.write<uint8_t>(1);

   // Now output the auxiliary entry.
   W.write<uint32_t>(CSectionRef.Size);
   // Parameter typecheck hash. Not supported.
   W.write<uint32_t>(0);
   // Typecheck section number. Not supported.
   W.write<uint16_t>(0);
   // Symbol type.
   W.write<uint8_t>(getEncodedType(CSectionRef.MCCsect));
   // Storage mapping class.
   W.write<uint8_t>(CSectionRef.MCCsect->getMappingClass());
   // Reserved (x_stab).
   W.write<uint32_t>(0);
   // Reserved (x_snstab).
   W.write<uint16_t>(0);
 }

 void XCOFFObjectWriter::writeFileHeader() {
   // Magic.
   W.write<uint16_t>(0x01df);
   // Number of sections.
   W.write<uint16_t>(Sections.size());
   // Timestamp field. For reproducible output we write a 0, which represents no
   // timestamp.
   W.write<int32_t>(0);
   // Byte Offset to the start of the symbol table.
   W.write<uint32_t>(SymbolTableOffset);
   // Number of entries in the symbol table.
   W.write<int32_t>(SymbolTableEntryCount);
   // Size of the optional header.
   W.write<uint16_t>(0);
   // Flags.
   W.write<uint16_t>(0);
 }

 void XCOFFObjectWriter::writeSectionHeaderTable() {
   for (const auto *Sec : Sections) {
     // Write Name.
     ArrayRef<char> NameRef(Sec->Name, XCOFF::NameSize);
     W.write(NameRef);

     // Write the Physical Address and Virtual Address. In an object file these
     // are the same.
     W.write<uint32_t>(Sec->Address);
     W.write<uint32_t>(Sec->Address);

     W.write<uint32_t>(Sec->Size);
     W.write<uint32_t>(Sec->FileOffsetToData);

     // Relocation pointer and Lineno pointer. Not supported yet.
     W.write<uint32_t>(0);
     W.write<uint32_t>(0);

     // Relocation and line-number counts. Not supported yet.
     W.write<uint16_t>(0);
     W.write<uint16_t>(0);

     W.write<int32_t>(Sec->Flags);
   }
 }

 void XCOFFObjectWriter::writeSymbolTable(const MCAsmLayout &Layout) {
   // Print out symbol table for the program code.
   for (const auto &Csect : ProgramCodeCsects) {
     // Write out the control section first and then each symbol in it.
     writeSymbolTableEntryForControlSection(Csect, Text.Index,
                                            Csect.MCCsect->getStorageClass());
     for (const auto &Sym : Csect.Syms)
       writeSymbolTableEntryForCsectMemberLabel(
           Sym, Csect, Text.Index, Layout.getSymbolOffset(*Sym.MCSym));
   }

   // The BSS Section is special in that the csects must contain a single symbol,
   // and the contained symbol cannot be represented in the symbol table as a
   // label definition.
   for (auto &Csect : BSSCsects) {
     assert(Csect.Syms.size() == 1 &&
            "Uninitialized csect cannot contain more then 1 symbol.");
     Symbol &Sym = Csect.Syms.back();
     writeSymbolTableEntryForControlSection(Csect, BSS.Index,
                                            Sym.getStorageClass());
   }
 }

 void XCOFFObjectWriter::assignAddressesAndIndices(const MCAsmLayout &Layout) {
   // 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.
   uint32_t Address = 0;
   // Section indices are 1-based in XCOFF.
   int16_t SectionIndex = 1;
   // The first symbol table entry is for the file name. We are not emitting it
   // yet, so start at index 0.
   uint32_t SymbolTableIndex = 0;

   // Text section comes first.
   if (!ProgramCodeCsects.empty()) {
     Sections.push_back(&Text);
     Text.Index = SectionIndex++;
     for (auto &Csect : ProgramCodeCsects) {
       const MCSectionXCOFF *MCSec = Csect.MCCsect;
       Csect.Address = alignTo(Address, MCSec->getAlignment());
       Csect.Size = Layout.getSectionAddressSize(MCSec);
       Address = Csect.Address + Csect.Size;
       Csect.SymbolTableIndex = SymbolTableIndex;
       // 1 main and 1 auxiliary symbol table entry for the csect.
       SymbolTableIndex += 2;
       for (auto &Sym : Csect.Syms) {
         Sym.SymbolTableIndex = SymbolTableIndex;
         // 1 main and 1 auxiliary symbol table entry for each contained symbol
         SymbolTableIndex += 2;
       }
     }
     Address = alignTo(Address, DefaultSectionAlign);

     // The first csect of a section can be aligned by adjusting the virtual
     // address of its containing section instead of writing zeroes into the
     // object file.
     Text.Address = ProgramCodeCsects.front().Address;

     Text.Size = Address - Text.Address;
   }

   // Data section Second. TODO

   // BSS Section third.
   if (!BSSCsects.empty()) {
     Sections.push_back(&BSS);
     BSS.Index = SectionIndex++;
     for (auto &Csect : BSSCsects) {
       const MCSectionXCOFF *MCSec = Csect.MCCsect;
       Csect.Address = alignTo(Address, MCSec->getAlignment());
       Csect.Size = Layout.getSectionAddressSize(MCSec);
       Address = Csect.Address + Csect.Size;
       Csect.SymbolTableIndex = SymbolTableIndex;
       // 1 main and 1 auxiliary symbol table entry for the csect.
       SymbolTableIndex += 2;

       assert(Csect.Syms.size() == 1 &&
              "csect in the BSS can only contain a single symbol.");
       Csect.Syms[0].SymbolTableIndex = Csect.SymbolTableIndex;
     }
     // Pad out Address to the default alignment. This is to match how the system
     // assembler handles the .bss section. Its size is always a multiple of 4.
     Address = alignTo(Address, DefaultSectionAlign);

     BSS.Address = BSSCsects.front().Address;
     BSS.Size = Address - BSS.Address;
   }

   SymbolTableEntryCount = SymbolTableIndex;

   // Calculate the RawPointer value for each section.
   uint64_t RawPointer = sizeof(XCOFF::FileHeader32) + auxiliaryHeaderSize() +
                         Sections.size() * sizeof(XCOFF::SectionHeader32);
   for (auto *Sec : Sections) {
     if (!Sec->IsVirtual) {
       Sec->FileOffsetToData = RawPointer;
       RawPointer += Sec->Size;
     }
   }

   // TODO Add in Relocation storage to the RawPointer Calculation.
   // TODO What to align the SymbolTable to?
   // TODO Error check that the number of symbol table entries fits in 32-bits
   // signed ...
   if (SymbolTableEntryCount)
     SymbolTableOffset = RawPointer;
 }

 // 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 Align = Sec->getAlignment();
   assert(isPowerOf2_32(Align) && "Alignment must be a power of 2.");
   unsigned Log2Align = Log2_32(Align);
   // 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<MCObjectWriter>
 llvm::createXCOFFObjectWriter(std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW,
                               raw_pwrite_stream &OS) {
   return std::make_unique<XCOFFObjectWriter>(std::move(MOTW), OS);
 }
	//===-- 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/MCAsmLayout.h"
	#include "llvm/MC/MCAssembler.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/Error.h"
	#include "llvm/Support/MathExtras.h"

	#include <deque>

	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;

	// Packs the csect's alignment and type into a byte.
	uint8_t getEncodedType(const MCSectionXCOFF *);

	// Wrapper around an MCSymbolXCOFF.
	struct Symbol {
	const MCSymbolXCOFF *const MCSym;
	uint32_t SymbolTableIndex;

	XCOFF::StorageClass getStorageClass() const {
	return MCSym->getStorageClass();
	}
	StringRef getName() const { return MCSym->getName(); }
	Symbol(const MCSymbolXCOFF *MCSym) : MCSym(MCSym), SymbolTableIndex(-1) {}
	};

	// Wrapper for an MCSectionXCOFF.
	struct ControlSection {
	const MCSectionXCOFF *const MCCsect;
	uint32_t SymbolTableIndex;
	uint32_t Address;
	uint32_t Size;

	SmallVector<Symbol, 1> Syms;
	StringRef getName() const { return MCCsect->getSectionName(); }
	ControlSection(const MCSectionXCOFF *MCSec)
	: MCCsect(MCSec), SymbolTableIndex(-1), Address(-1), Size(0) {}
	};

	// 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 Section {
	char Name[XCOFF::NameSize];
	// The physical/virtual address of the section. For an object file
	// these values are equivalent.
	uint32_t Address;
	uint32_t Size;
	uint32_t FileOffsetToData;
	uint32_t FileOffsetToRelocations;
	uint32_t RelocationCount;
	int32_t Flags;

	int16_t Index;

	// Virtual sections do not need storage allocated in the object file.
	const bool IsVirtual;

	void reset() {
	Address = 0;
	Size = 0;
	FileOffsetToData = 0;
	FileOffsetToRelocations = 0;
	RelocationCount = 0;
	Index = -1;
	}

	Section(const char *N, XCOFF::SectionTypeFlags Flags, bool IsVirtual)
	: Address(0), Size(0), FileOffsetToData(0), FileOffsetToRelocations(0),
	RelocationCount(0), Flags(Flags), Index(-1), IsVirtual(IsVirtual) {
	strncpy(Name, N, XCOFF::NameSize);
	}
	};

	class XCOFFObjectWriter : public MCObjectWriter {
	// 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<ControlSection>;

	support::endian::Writer W;
	std::unique_ptr<MCXCOFFObjectTargetWriter> TargetObjectWriter;
	StringTableBuilder Strings;

	// The non-empty sections, in the order they will appear in the section header
	// table.
	std::vector<Section *> Sections;

	// The Predefined sections.
	Section Text;
	Section BSS;

	// 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 ProgramCodeCsects;
	CsectGroup BSSCsects;

	uint32_t SymbolTableEntryCount = 0;
	uint32_t SymbolTableOffset = 0;

	virtual 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;

	static bool nameShouldBeInStringTable(const StringRef &);
	void writeSymbolName(const StringRef &);
	void writeSymbolTableEntryForCsectMemberLabel(const Symbol &,
	const ControlSection &, int16_t,
	uint64_t);
	void writeSymbolTableEntryForControlSection(const ControlSection &, int16_t,
	XCOFF::StorageClass);
	void writeFileHeader();
	void writeSectionHeaderTable();
	void writeSections(const MCAssembler &Asm, const MCAsmLayout &Layout);
	void writeSymbolTable(const MCAsmLayout &Layout);

	// 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 &);

	bool
	needsAuxiliaryHeader() const { /* TODO aux header support not implemented. */
	return false;
	}

	// Returns the size of the auxiliary header to be written to the object file.
	size_t auxiliaryHeaderSize() const {
	assert(!needsAuxiliaryHeader() &&
	"Auxiliary header support not implemented.");
	return 0;
	}

	public:
	XCOFFObjectWriter(std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW,
	raw_pwrite_stream &OS);
	};

	XCOFFObjectWriter::XCOFFObjectWriter(
	std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW, raw_pwrite_stream &OS)
	: W(OS, support::big), TargetObjectWriter(std::move(MOTW)),
	Strings(StringTableBuilder::XCOFF),
	Text(".text", XCOFF::STYP_TEXT, /* IsVirtual */ false),
	BSS(".bss", XCOFF::STYP_BSS, /* IsVirtual */ true) {}

	void XCOFFObjectWriter::reset() {
	// Reset any sections we have written to, and empty the section header table.
	for (auto *Sec : Sections)
	Sec->reset();
	Sections.clear();

	// Clear any csects we have stored.
	ProgramCodeCsects.clear();
	BSSCsects.clear();

	// Reset the symbol table and string table.
	SymbolTableEntryCount = 0;
	SymbolTableOffset = 0;
	Strings.clear();

	MCObjectWriter::reset();
	}

	void XCOFFObjectWriter::executePostLayoutBinding(MCAssembler &Asm,
	const MCAsmLayout &Layout) {
	if (TargetObjectWriter->is64Bit())
	report_fatal_error("64-bit XCOFF object files are not supported yet.");

	// Maps the MC Section representation to its corresponding ControlSection
	// wrapper. Needed for finding the ControlSection to insert an MCSymbol into
	// from its containing MCSectionXCOFF.
	DenseMap<const MCSectionXCOFF , ControlSection > WrapperMap;

	for (const auto &S : Asm) {
	const auto *MCSec = cast<const MCSectionXCOFF>(&S);
	assert(WrapperMap.find(MCSec) == WrapperMap.end() &&
	"Cannot add a csect 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->getSectionName()))
	Strings.add(MCSec->getSectionName());

	switch (MCSec->getMappingClass()) {
	case XCOFF::XMC_PR:
	assert(XCOFF::XTY_SD == MCSec->getCSectType() &&
	"Only an initialized csect can contain program code.");
	ProgramCodeCsects.emplace_back(MCSec);
	WrapperMap[MCSec] = &ProgramCodeCsects.back();
	break;
	case XCOFF::XMC_RW:
	if (XCOFF::XTY_CM == MCSec->getCSectType()) {
	BSSCsects.emplace_back(MCSec);
	WrapperMap[MCSec] = &BSSCsects.back();
	break;
	}
	report_fatal_error("Unhandled mapping of read-write csect to section.");
	case XCOFF::XMC_TC0:
	// TODO FIXME Handle emiting the TOC base.
	break;
	case XCOFF::XMC_BS:
	assert(XCOFF::XTY_CM == MCSec->getCSectType() &&
	"Mapping invalid csect. CSECT with bss storage class must be "
	"common type.");
	BSSCsects.emplace_back(MCSec);
	WrapperMap[MCSec] = &BSSCsects.back();
	break;
	default:
	report_fatal_error("Unhandled mapping of csect to section.");
	}
	}

	for (const MCSymbol &S : Asm.symbols()) {
	// Nothing to do for temporary symbols.
	if (S.isTemporary())
	continue;
	const MCSymbolXCOFF *XSym = cast<MCSymbolXCOFF>(&S);

	// Map the symbol into its containing csect.
	const MCSectionXCOFF *ContainingCsect = XSym->getContainingCsect();
	assert(WrapperMap.find(ContainingCsect) != WrapperMap.end() &&
	"Expected containing csect to exist in map");

	// Lookup the containing csect and add the symbol to it.
	WrapperMap[ContainingCsect]->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->getName()))
	Strings.add(XSym->getName());
	}

	Strings.finalize();
	assignAddressesAndIndices(Layout);
	}

	void XCOFFObjectWriter::recordRelocation(MCAssembler &, const MCAsmLayout &,
	const MCFragment *, const MCFixup &,
	MCValue, uint64_t &) {
	report_fatal_error("XCOFF relocations not supported.");
	}

	void XCOFFObjectWriter::writeSections(const MCAssembler &Asm,
	const MCAsmLayout &Layout) {
	// Write the program code control sections one at a time.
	uint32_t CurrentAddressLocation = Text.Address;
	for (const auto &Csect : ProgramCodeCsects) {
	if (uint32_t PaddingSize = Csect.Address - CurrentAddressLocation)
	W.OS.write_zeros(PaddingSize);
	Asm.writeSectionData(W.OS, Csect.MCCsect, Layout);
	CurrentAddressLocation = Csect.Address + Csect.Size;
	}

	if (Text.Index != -1) {
	// The size of the tail padding in a section is the end virtual address of
	// the current section minus the the end virtual address of the last csect
	// in that section.
	if (uint32_t PaddingSize =
	Text.Address + Text.Size - CurrentAddressLocation)
	W.OS.write_zeros(PaddingSize);
	}
	}

	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.");

	if (TargetObjectWriter->is64Bit())
	report_fatal_error("64-bit XCOFF object files are not supported yet.");

	uint64_t StartOffset = W.OS.tell();

	writeFileHeader();
	writeSectionHeaderTable();
	writeSections(Asm, Layout);
	// TODO 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;
	}

	void XCOFFObjectWriter::writeSymbolName(const StringRef &SymbolName) {
	if (nameShouldBeInStringTable(SymbolName)) {
	W.write<int32_t>(0);
	W.write<uint32_t>(Strings.getOffset(SymbolName));
	} else {
	char Name[XCOFF::NameSize];
	std::strncpy(Name, SymbolName.data(), XCOFF::NameSize);
	ArrayRef<char> NameRef(Name, XCOFF::NameSize);
	W.write(NameRef);
	}
	}

	void XCOFFObjectWriter::writeSymbolTableEntryForCsectMemberLabel(
	const Symbol &SymbolRef, const ControlSection &CSectionRef,
	int16_t SectionIndex, uint64_t SymbolOffset) {
	// Name or Zeros and string table offset
	writeSymbolName(SymbolRef.getName());
	assert(SymbolOffset <= UINT32_MAX - CSectionRef.Address &&
	"Symbol address overflows.");
	W.write<uint32_t>(CSectionRef.Address + SymbolOffset);
	W.write<int16_t>(SectionIndex);
	// Basic/Derived type. See the description of the n_type field for symbol
	// table entries for a detailed description. Since we don't yet support
	// visibility, and all other bits are either optionally set or reserved, this
	// is always zero.
	// TODO FIXME How to assert a symbol's visibilty is default?
	// TODO Set the function indicator (bit 10, 0x0020) for functions
	// when debugging is enabled.
	W.write<uint16_t>(0);
	W.write<uint8_t>(SymbolRef.getStorageClass());
	// Always 1 aux entry for now.
	W.write<uint8_t>(1);

	// Now output the auxiliary entry.
	W.write<uint32_t>(CSectionRef.SymbolTableIndex);
	// Parameter typecheck hash. Not supported.
	W.write<uint32_t>(0);
	// Typecheck section number. Not supported.
	W.write<uint16_t>(0);
	// Symbol type: Label
	W.write<uint8_t>(XCOFF::XTY_LD);
	// Storage mapping class.
	W.write<uint8_t>(CSectionRef.MCCsect->getMappingClass());
	// Reserved (x_stab).
	W.write<uint32_t>(0);
	// Reserved (x_snstab).
	W.write<uint16_t>(0);
	}

	void XCOFFObjectWriter::writeSymbolTableEntryForControlSection(
	const ControlSection &CSectionRef, int16_t SectionIndex,
	XCOFF::StorageClass StorageClass) {
	// n_name, n_zeros, n_offset
	writeSymbolName(CSectionRef.getName());
	// n_value
	W.write<uint32_t>(CSectionRef.Address);
	// n_scnum
	W.write<int16_t>(SectionIndex);
	// Basic/Derived type. See the description of the n_type field for symbol
	// table entries for a detailed description. Since we don't yet support
	// visibility, and all other bits are either optionally set or reserved, this
	// is always zero.
	// TODO FIXME How to assert a symbol's visibilty is default?
	// TODO Set the function indicator (bit 10, 0x0020) for functions
	// when debugging is enabled.
	W.write<uint16_t>(0);
	// n_sclass
	W.write<uint8_t>(StorageClass);
	// Always 1 aux entry for now.
	W.write<uint8_t>(1);

	// Now output the auxiliary entry.
	W.write<uint32_t>(CSectionRef.Size);
	// Parameter typecheck hash. Not supported.
	W.write<uint32_t>(0);
	// Typecheck section number. Not supported.
	W.write<uint16_t>(0);
	// Symbol type.
	W.write<uint8_t>(getEncodedType(CSectionRef.MCCsect));
	// Storage mapping class.
	W.write<uint8_t>(CSectionRef.MCCsect->getMappingClass());
	// Reserved (x_stab).
	W.write<uint32_t>(0);
	// Reserved (x_snstab).
	W.write<uint16_t>(0);
	}

	void XCOFFObjectWriter::writeFileHeader() {
	// Magic.
	W.write<uint16_t>(0x01df);
	// Number of sections.
	W.write<uint16_t>(Sections.size());
	// Timestamp field. For reproducible output we write a 0, which represents no
	// timestamp.
	W.write<int32_t>(0);
	// Byte Offset to the start of the symbol table.
	W.write<uint32_t>(SymbolTableOffset);
	// Number of entries in the symbol table.
	W.write<int32_t>(SymbolTableEntryCount);
	// Size of the optional header.
	W.write<uint16_t>(0);
	// Flags.
	W.write<uint16_t>(0);
	}

	void XCOFFObjectWriter::writeSectionHeaderTable() {
	for (const auto *Sec : Sections) {
	// Write Name.
	ArrayRef<char> NameRef(Sec->Name, XCOFF::NameSize);
	W.write(NameRef);

	// Write the Physical Address and Virtual Address. In an object file these
	// are the same.
	W.write<uint32_t>(Sec->Address);
	W.write<uint32_t>(Sec->Address);

	W.write<uint32_t>(Sec->Size);
	W.write<uint32_t>(Sec->FileOffsetToData);

	// Relocation pointer and Lineno pointer. Not supported yet.
	W.write<uint32_t>(0);
	W.write<uint32_t>(0);

	// Relocation and line-number counts. Not supported yet.
	W.write<uint16_t>(0);
	W.write<uint16_t>(0);

	W.write<int32_t>(Sec->Flags);
	}
	}

	void XCOFFObjectWriter::writeSymbolTable(const MCAsmLayout &Layout) {
	// Print out symbol table for the program code.
	for (const auto &Csect : ProgramCodeCsects) {
	// Write out the control section first and then each symbol in it.
	writeSymbolTableEntryForControlSection(Csect, Text.Index,
	Csect.MCCsect->getStorageClass());
	for (const auto &Sym : Csect.Syms)
	writeSymbolTableEntryForCsectMemberLabel(
	Sym, Csect, Text.Index, Layout.getSymbolOffset(*Sym.MCSym));
	}

	// The BSS Section is special in that the csects must contain a single symbol,
	// and the contained symbol cannot be represented in the symbol table as a
	// label definition.
	for (auto &Csect : BSSCsects) {
	assert(Csect.Syms.size() == 1 &&
	"Uninitialized csect cannot contain more then 1 symbol.");
	Symbol &Sym = Csect.Syms.back();
	writeSymbolTableEntryForControlSection(Csect, BSS.Index,
	Sym.getStorageClass());
	}
	}

	void XCOFFObjectWriter::assignAddressesAndIndices(const MCAsmLayout &Layout) {
	// 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.
	uint32_t Address = 0;
	// Section indices are 1-based in XCOFF.
	int16_t SectionIndex = 1;
	// The first symbol table entry is for the file name. We are not emitting it
	// yet, so start at index 0.
	uint32_t SymbolTableIndex = 0;

	// Text section comes first.
	if (!ProgramCodeCsects.empty()) {
	Sections.push_back(&Text);
	Text.Index = SectionIndex++;
	for (auto &Csect : ProgramCodeCsects) {
	const MCSectionXCOFF *MCSec = Csect.MCCsect;
	Csect.Address = alignTo(Address, MCSec->getAlignment());
	Csect.Size = Layout.getSectionAddressSize(MCSec);
	Address = Csect.Address + Csect.Size;
	Csect.SymbolTableIndex = SymbolTableIndex;
	// 1 main and 1 auxiliary symbol table entry for the csect.
	SymbolTableIndex += 2;
	for (auto &Sym : Csect.Syms) {
	Sym.SymbolTableIndex = SymbolTableIndex;
	// 1 main and 1 auxiliary symbol table entry for each contained symbol
	SymbolTableIndex += 2;
	}
	}
	Address = alignTo(Address, DefaultSectionAlign);

	// The first csect of a section can be aligned by adjusting the virtual
	// address of its containing section instead of writing zeroes into the
	// object file.
	Text.Address = ProgramCodeCsects.front().Address;

	Text.Size = Address - Text.Address;
	}

	// Data section Second. TODO

	// BSS Section third.
	if (!BSSCsects.empty()) {
	Sections.push_back(&BSS);
	BSS.Index = SectionIndex++;
	for (auto &Csect : BSSCsects) {
	const MCSectionXCOFF *MCSec = Csect.MCCsect;
	Csect.Address = alignTo(Address, MCSec->getAlignment());
	Csect.Size = Layout.getSectionAddressSize(MCSec);
	Address = Csect.Address + Csect.Size;
	Csect.SymbolTableIndex = SymbolTableIndex;
	// 1 main and 1 auxiliary symbol table entry for the csect.
	SymbolTableIndex += 2;

	assert(Csect.Syms.size() == 1 &&
	"csect in the BSS can only contain a single symbol.");
	Csect.Syms[0].SymbolTableIndex = Csect.SymbolTableIndex;
	}
	// Pad out Address to the default alignment. This is to match how the system
	// assembler handles the .bss section. Its size is always a multiple of 4.
	Address = alignTo(Address, DefaultSectionAlign);

	BSS.Address = BSSCsects.front().Address;
	BSS.Size = Address - BSS.Address;
	}

	SymbolTableEntryCount = SymbolTableIndex;

	// Calculate the RawPointer value for each section.
	uint64_t RawPointer = sizeof(XCOFF::FileHeader32) + auxiliaryHeaderSize() +
	Sections.size() * sizeof(XCOFF::SectionHeader32);
	for (auto *Sec : Sections) {
	if (!Sec->IsVirtual) {
	Sec->FileOffsetToData = RawPointer;
	RawPointer += Sec->Size;
	}
	}

	// TODO Add in Relocation storage to the RawPointer Calculation.
	// TODO What to align the SymbolTable to?
	// TODO Error check that the number of symbol table entries fits in 32-bits
	// signed ...
	if (SymbolTableEntryCount)
	SymbolTableOffset = RawPointer;
	}

	// 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 Align = Sec->getAlignment();
	assert(isPowerOf2_32(Align) && "Alignment must be a power of 2.");
	unsigned Log2Align = Log2_32(Align);
	// 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<MCObjectWriter>
	llvm::createXCOFFObjectWriter(std::unique_ptr<MCXCOFFObjectTargetWriter> MOTW,
	raw_pwrite_stream &OS) {
	return std::make_unique<XCOFFObjectWriter>(std::move(MOTW), OS);
	}