wasm/Writer.cpp - lld - Git at Google

 //===- Writer.cpp ---------------------------------------------------------===//
 //
 //                             The LLVM Linker
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "Writer.h"

 #include "Config.h"
 #include "OutputSections.h"
 #include "OutputSegment.h"
 #include "SymbolTable.h"
 #include "WriterUtils.h"
 #include "lld/Common/ErrorHandler.h"
 #include "lld/Common/Memory.h"
 #include "lld/Common/Threads.h"
 #include "llvm/Support/FileOutputBuffer.h"
 #include "llvm/Support/Format.h"
 #include "llvm/Support/FormatVariadic.h"
 #include "llvm/Support/LEB128.h"

 #include <cstdarg>

 #define DEBUG_TYPE "lld"

 using namespace llvm;
 using namespace llvm::wasm;
 using namespace lld;
 using namespace lld::wasm;

 static constexpr int kStackAlignment = 16;

 namespace {

 // Traits for using WasmSignature in a DenseMap.
 struct WasmSignatureDenseMapInfo {
   static WasmSignature getEmptyKey() {
     WasmSignature Sig;
     Sig.ReturnType = 1;
     return Sig;
   }
   static WasmSignature getTombstoneKey() {
     WasmSignature Sig;
     Sig.ReturnType = 2;
     return Sig;
   }
   static unsigned getHashValue(const WasmSignature &Sig) {
     uintptr_t Value = 0;
     Value += DenseMapInfo<int32_t>::getHashValue(Sig.ReturnType);
     for (int32_t Param : Sig.ParamTypes)
       Value += DenseMapInfo<int32_t>::getHashValue(Param);
     return Value;
   }
   static bool isEqual(const WasmSignature &LHS, const WasmSignature &RHS) {
     return LHS == RHS;
   }
 };

 // The writer writes a SymbolTable result to a file.
 class Writer {
 public:
   void run();

 private:
   void openFile();

   uint32_t getTypeIndex(const WasmSignature &Sig);
   void assignSymbolIndexes();
   void calculateImports();
   void calculateOffsets();
   void calculateTypes();
   void createOutputSegments();
   void layoutMemory();
   void createHeader();
   void createSections();
   SyntheticSection *createSyntheticSection(uint32_t Type,
                                            std::string Name = "");

   // Builtin sections
   void createTypeSection();
   void createFunctionSection();
   void createTableSection();
   void createGlobalSection();
   void createExportSection();
   void createImportSection();
   void createMemorySection();
   void createElemSection();
   void createStartSection();
   void createCodeSection();
   void createDataSection();

   // Custom sections
   void createRelocSections();
   void createLinkingSection();
   void createNameSection();

   void writeHeader();
   void writeSections();

   uint64_t FileSize = 0;
   uint32_t DataSize = 0;
   uint32_t NumFunctions = 0;
   uint32_t NumMemoryPages = 0;
   uint32_t InitialTableOffset = 0;

   std::vector<const WasmSignature *> Types;
   DenseMap<WasmSignature, int32_t, WasmSignatureDenseMapInfo> TypeIndices;
   std::vector<const Symbol *> FunctionImports;
   std::vector<const Symbol *> GlobalImports;
   std::vector<const Symbol *> DefinedGlobals;
   std::vector<const Symbol *> IndirectFunctions;

   // Elements that are used to construct the final output
   std::string Header;
   std::vector<OutputSection *> OutputSections;

   std::unique_ptr<FileOutputBuffer> Buffer;

   std::vector<OutputSegment *> Segments;
   llvm::SmallDenseMap<StringRef, OutputSegment *> SegmentMap;
 };

 } // anonymous namespace

 static void debugPrint(const char *fmt, ...) {
   if (!errorHandler().Verbose)
     return;
   fprintf(stderr, "lld: ");
   va_list ap;
   va_start(ap, fmt);
   vfprintf(stderr, fmt, ap);
   va_end(ap);
 }

 void Writer::createImportSection() {
   uint32_t NumImports = FunctionImports.size() + GlobalImports.size();
   if (Config->ImportMemory)
     ++NumImports;

   if (NumImports == 0)
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_IMPORT);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, NumImports, "import count");

   for (const Symbol *Sym : FunctionImports) {
     WasmImport Import;
     Import.Module = "env";
     Import.Field = Sym->getName();
     Import.Kind = WASM_EXTERNAL_FUNCTION;
     assert(TypeIndices.count(Sym->getFunctionType()) > 0);
     Import.SigIndex = TypeIndices.lookup(Sym->getFunctionType());
     writeImport(OS, Import);
   }

   if (Config->ImportMemory) {
     WasmImport Import;
     Import.Module = "env";
     Import.Field = "memory";
     Import.Kind = WASM_EXTERNAL_MEMORY;
     Import.Memory.Flags = 0;
     Import.Memory.Initial = NumMemoryPages;
     writeImport(OS, Import);
   }

   for (const Symbol *Sym : GlobalImports) {
     WasmImport Import;
     Import.Module = "env";
     Import.Field = Sym->getName();
     Import.Kind = WASM_EXTERNAL_GLOBAL;
     Import.Global.Mutable = false;
     Import.Global.Type = WASM_TYPE_I32;
     writeImport(OS, Import);
   }
 }

 void Writer::createTypeSection() {
   SyntheticSection *Section = createSyntheticSection(WASM_SEC_TYPE);
   raw_ostream &OS = Section->getStream();
   writeUleb128(OS, Types.size(), "type count");
   for (const WasmSignature *Sig : Types)
     writeSig(OS, *Sig);
 }

 void Writer::createFunctionSection() {
   if (!NumFunctions)
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_FUNCTION);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, NumFunctions, "function count");
   for (ObjFile *File : Symtab->ObjectFiles)
     for (uint32_t Sig : File->getWasmObj()->functionTypes())
       writeUleb128(OS, File->relocateTypeIndex(Sig), "sig index");
 }

 void Writer::createMemorySection() {
   if (Config->ImportMemory)
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_MEMORY);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, 1, "memory count");
   writeUleb128(OS, 0, "memory limits flags");
   writeUleb128(OS, NumMemoryPages, "initial pages");
 }

 void Writer::createGlobalSection() {
   if (DefinedGlobals.empty())
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_GLOBAL);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, DefinedGlobals.size(), "global count");
   for (const Symbol *Sym : DefinedGlobals) {
     WasmGlobal Global;
     Global.Type = WASM_TYPE_I32;
     Global.Mutable = Sym == Config->StackPointerSymbol;
     Global.InitExpr.Opcode = WASM_OPCODE_I32_CONST;
     Global.InitExpr.Value.Int32 = Sym->getVirtualAddress();
     writeGlobal(OS, Global);
   }
 }

 void Writer::createTableSection() {
   // Always output a table section, even if there are no indirect calls.
   // There are two reasons for this:
   //  1. For executables it is useful to have an empty table slot at 0
   //     which can be filled with a null function call handler.
   //  2. If we don't do this, any program that contains a call_indirect but
   //     no address-taken function will fail at validation time since it is
   //     a validation error to include a call_indirect instruction if there
   //     is not table.
   uint32_t TableSize = InitialTableOffset + IndirectFunctions.size();

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_TABLE);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, 1, "table count");
   writeSleb128(OS, WASM_TYPE_ANYFUNC, "table type");
   writeUleb128(OS, WASM_LIMITS_FLAG_HAS_MAX, "table flags");
   writeUleb128(OS, TableSize, "table initial size");
   writeUleb128(OS, TableSize, "table max size");
 }

 void Writer::createExportSection() {
   bool ExportMemory = !Config->Relocatable && !Config->ImportMemory;
   Symbol *EntrySym = Symtab->find(Config->Entry);
   bool ExportEntry = !Config->Relocatable && EntrySym && EntrySym->isDefined();
   bool ExportHidden = Config->EmitRelocs;

   uint32_t NumExports = ExportMemory ? 1 : 0;

   std::vector<const Symbol *> SymbolExports;
   if (ExportEntry)
     SymbolExports.emplace_back(EntrySym);

   for (const Symbol *Sym : Symtab->getSymbols()) {
     if (Sym->isUndefined() || Sym->isGlobal())
       continue;
     if (Sym->isHidden() && !ExportHidden)
       continue;
     if (ExportEntry && Sym == EntrySym)
       continue;
     SymbolExports.emplace_back(Sym);
   }

   for (const Symbol *Sym : DefinedGlobals) {
     // Can't export the SP right now because it mutable and mutable globals
     // connot be exported.
     if (Sym == Config->StackPointerSymbol)
       continue;
     SymbolExports.emplace_back(Sym);
   }

   NumExports += SymbolExports.size();
   if (!NumExports)
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_EXPORT);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, NumExports, "export count");

   if (ExportMemory) {
     WasmExport MemoryExport;
     MemoryExport.Name = "memory";
     MemoryExport.Kind = WASM_EXTERNAL_MEMORY;
     MemoryExport.Index = 0;
     writeExport(OS, MemoryExport);
   }

   for (const Symbol *Sym : SymbolExports) {
     log("Export: " + Sym->getName());
     WasmExport Export;
     Export.Name = Sym->getName();
     Export.Index = Sym->getOutputIndex();
     if (Sym->isFunction())
       Export.Kind = WASM_EXTERNAL_FUNCTION;
     else
       Export.Kind = WASM_EXTERNAL_GLOBAL;
     writeExport(OS, Export);
   }
 }

 void Writer::createStartSection() {}

 void Writer::createElemSection() {
   if (IndirectFunctions.empty())
     return;

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_ELEM);
   raw_ostream &OS = Section->getStream();

   writeUleb128(OS, 1, "segment count");
   writeUleb128(OS, 0, "table index");
   WasmInitExpr InitExpr;
   InitExpr.Opcode = WASM_OPCODE_I32_CONST;
   InitExpr.Value.Int32 = InitialTableOffset;
   writeInitExpr(OS, InitExpr);
   writeUleb128(OS, IndirectFunctions.size(), "elem count");

   uint32_t TableIndex = InitialTableOffset;
   for (const Symbol *Sym : IndirectFunctions) {
     assert(Sym->getTableIndex() == TableIndex);
     writeUleb128(OS, Sym->getOutputIndex(), "function index");
     ++TableIndex;
   }
 }

 void Writer::createCodeSection() {
   if (!NumFunctions)
     return;

   log("createCodeSection");

   auto Section = make<CodeSection>(NumFunctions, Symtab->ObjectFiles);
   OutputSections.push_back(Section);
 }

 void Writer::createDataSection() {
   if (!Segments.size())
     return;

   log("createDataSection");
   auto Section = make<DataSection>(Segments);
   OutputSections.push_back(Section);
 }

 // Create relocations sections in the final output.
 // These are only created when relocatable output is requested.
 void Writer::createRelocSections() {
   log("createRelocSections");
   // Don't use iterator here since we are adding to OutputSection
   size_t OrigSize = OutputSections.size();
   for (size_t i = 0; i < OrigSize; i++) {
     OutputSection *S = OutputSections[i];
     const char *name;
     uint32_t Count = S->numRelocations();
     if (!Count)
       continue;

     if (S->Type == WASM_SEC_DATA)
       name = "reloc.DATA";
     else if (S->Type == WASM_SEC_CODE)
       name = "reloc.CODE";
     else
       llvm_unreachable("relocations only supported for code and data");

     SyntheticSection *Section = createSyntheticSection(WASM_SEC_CUSTOM, name);
     raw_ostream &OS = Section->getStream();
     writeUleb128(OS, S->Type, "reloc section");
     writeUleb128(OS, Count, "reloc count");
     S->writeRelocations(OS);
   }
 }

 // Create the custom "linking" section containing linker metadata.
 // This is only created when relocatable output is requested.
 void Writer::createLinkingSection() {
   SyntheticSection *Section =
       createSyntheticSection(WASM_SEC_CUSTOM, "linking");
   raw_ostream &OS = Section->getStream();

   SubSection DataSizeSubSection(WASM_DATA_SIZE);
   writeUleb128(DataSizeSubSection.getStream(), DataSize, "data size");
   DataSizeSubSection.finalizeContents();
   DataSizeSubSection.writeToStream(OS);

   if (!Config->Relocatable)
     return;

   if (Segments.size()) {
     SubSection SubSection(WASM_SEGMENT_INFO);
     writeUleb128(SubSection.getStream(), Segments.size(), "num data segments");
     for (const OutputSegment *S : Segments) {
       writeStr(SubSection.getStream(), S->Name, "segment name");
       writeUleb128(SubSection.getStream(), S->Alignment, "alignment");
       writeUleb128(SubSection.getStream(), 0, "flags");
     }
     SubSection.finalizeContents();
     SubSection.writeToStream(OS);
   }

   std::vector<WasmInitFunc> InitFunctions;
   for (ObjFile *File : Symtab->ObjectFiles) {
     const WasmLinkingData &L = File->getWasmObj()->linkingData();
     InitFunctions.reserve(InitFunctions.size() + L.InitFunctions.size());
     for (const WasmInitFunc &F : L.InitFunctions)
       InitFunctions.emplace_back(WasmInitFunc{
           F.Priority, File->relocateFunctionIndex(F.FunctionIndex)});
   }

   if (!InitFunctions.empty()) {
     SubSection SubSection(WASM_INIT_FUNCS);
     writeUleb128(SubSection.getStream(), InitFunctions.size(),
                  "num init functionsw");
     for (const WasmInitFunc &F : InitFunctions) {
       writeUleb128(SubSection.getStream(), F.Priority, "priority");
       writeUleb128(SubSection.getStream(), F.FunctionIndex, "function index");
     }
     SubSection.finalizeContents();
     SubSection.writeToStream(OS);
   }
 }

 // Create the custom "name" section containing debug symbol names.
 void Writer::createNameSection() {
   // Create an array of all function sorted by function index space
   std::vector<const Symbol *> Names;

   for (ObjFile *File : Symtab->ObjectFiles) {
     Names.reserve(Names.size() + File->getSymbols().size());
     for (Symbol *S : File->getSymbols()) {
       if (!S->isFunction() || S->isWeak() || S->WrittenToNameSec)
         continue;
       S->WrittenToNameSec = true;
       Names.emplace_back(S);
     }
   }

   SyntheticSection *Section = createSyntheticSection(WASM_SEC_CUSTOM, "name");

   std::sort(Names.begin(), Names.end(), [](const Symbol *A, const Symbol *B) {
     return A->getOutputIndex() < B->getOutputIndex();
   });

   SubSection FunctionSubsection(WASM_NAMES_FUNCTION);
   raw_ostream &OS = FunctionSubsection.getStream();
   writeUleb128(OS, Names.size(), "name count");

   // We have to iterate through the inputs twice so that all the imports
   // appear first before any of the local function names.
   for (const Symbol *S : Names) {
     writeUleb128(OS, S->getOutputIndex(), "func index");
     writeStr(OS, S->getName(), "symbol name");
   }

   FunctionSubsection.finalizeContents();
   FunctionSubsection.writeToStream(Section->getStream());
 }

 void Writer::writeHeader() {
   memcpy(Buffer->getBufferStart(), Header.data(), Header.size());
 }

 void Writer::writeSections() {
   uint8_t *Buf = Buffer->getBufferStart();
   parallelForEach(OutputSections, [Buf](OutputSection *S) { S->writeTo(Buf); });
 }

 // Fix the memory layout of the output binary.  This assigns memory offsets
 // to each of the input data sections as well as the explicit stack region.
 void Writer::layoutMemory() {
   uint32_t MemoryPtr = 0;
   if (!Config->Relocatable) {
     MemoryPtr = Config->GlobalBase;
     debugPrint("mem: global base = %d\n", Config->GlobalBase);
   }

   createOutputSegments();

   // Static data comes first
   for (OutputSegment *Seg : Segments) {
     MemoryPtr = alignTo(MemoryPtr, Seg->Alignment);
     Seg->StartVA = MemoryPtr;
     debugPrint("mem: %-10s offset=%-8d size=%-4d align=%d\n",
                Seg->Name.str().c_str(), MemoryPtr, Seg->Size, Seg->Alignment);
     MemoryPtr += Seg->Size;
   }

   DataSize = MemoryPtr;
   if (!Config->Relocatable)
     DataSize -= Config->GlobalBase;
   debugPrint("mem: static data = %d\n", DataSize);

   // Stack comes after static data
   if (!Config->Relocatable) {
     MemoryPtr = alignTo(MemoryPtr, kStackAlignment);
     if (Config->ZStackSize != alignTo(Config->ZStackSize, kStackAlignment))
       error("stack size must be " + Twine(kStackAlignment) + "-byte aligned");
     debugPrint("mem: stack size  = %d\n", Config->ZStackSize);
     debugPrint("mem: stack base  = %d\n", MemoryPtr);
     MemoryPtr += Config->ZStackSize;
     Config->StackPointerSymbol->setVirtualAddress(MemoryPtr);
     debugPrint("mem: stack top   = %d\n", MemoryPtr);
   }

   uint32_t MemSize = alignTo(MemoryPtr, WasmPageSize);
   NumMemoryPages = MemSize / WasmPageSize;
   debugPrint("mem: total pages = %d\n", NumMemoryPages);
 }

 SyntheticSection *Writer::createSyntheticSection(uint32_t Type,
                                                  std::string Name) {
   auto Sec = make<SyntheticSection>(Type, Name);
   log("createSection: " + toString(*Sec));
   OutputSections.push_back(Sec);
   return Sec;
 }

 void Writer::createSections() {
   // Known sections
   createTypeSection();
   createImportSection();
   createFunctionSection();
   createTableSection();
   createMemorySection();
   createGlobalSection();
   createExportSection();
   createStartSection();
   createElemSection();
   createCodeSection();
   createDataSection();

   // Custom sections
   if (Config->EmitRelocs)
     createRelocSections();
   createLinkingSection();
   if (!Config->StripDebug && !Config->StripAll)
     createNameSection();

   for (OutputSection *S : OutputSections) {
     S->setOffset(FileSize);
     S->finalizeContents();
     FileSize += S->getSize();
   }
 }

 void Writer::calculateOffsets() {
   for (ObjFile *File : Symtab->ObjectFiles) {
     const WasmObjectFile *WasmFile = File->getWasmObj();

     // Function Index
     File->FunctionIndexOffset =
         FunctionImports.size() - File->NumFunctionImports() + NumFunctions;
     NumFunctions += WasmFile->functions().size();

     // Memory
     if (WasmFile->memories().size() > 1)
       fatal(File->getName() + ": contains more than one memory");
   }
 }

 void Writer::calculateImports() {
   for (Symbol *Sym : Symtab->getSymbols()) {
     if (!Sym->isUndefined() || Sym->isWeak())
       continue;

     if (Sym->isFunction()) {
       Sym->setOutputIndex(FunctionImports.size());
       FunctionImports.push_back(Sym);
     } else {
       Sym->setOutputIndex(GlobalImports.size());
       GlobalImports.push_back(Sym);
     }
   }
 }

 uint32_t Writer::getTypeIndex(const WasmSignature &Sig) {
   auto Pair = TypeIndices.insert(std::make_pair(Sig, Types.size()));
   if (Pair.second)
     Types.push_back(&Sig);
   return Pair.first->second;
 }

 void Writer::calculateTypes() {
   for (ObjFile *File : Symtab->ObjectFiles) {
     File->TypeMap.reserve(File->getWasmObj()->types().size());
     for (const WasmSignature &Sig : File->getWasmObj()->types())
       File->TypeMap.push_back(getTypeIndex(Sig));
   }
 }

 void Writer::assignSymbolIndexes() {
   uint32_t GlobalIndex = GlobalImports.size();

   if (Config->StackPointerSymbol) {
     DefinedGlobals.emplace_back(Config->StackPointerSymbol);
     Config->StackPointerSymbol->setOutputIndex(GlobalIndex++);
   }

   if (Config->EmitRelocs)
     DefinedGlobals.reserve(Symtab->getSymbols().size());

   uint32_t TableIndex = InitialTableOffset;

   for (ObjFile *File : Symtab->ObjectFiles) {
     DEBUG(dbgs() << "assignSymbolIndexes: " << File->getName() << "\n");

     for (Symbol *Sym : File->getSymbols()) {
       // Assign indexes for symbols defined with this file.
       if (!Sym->isDefined() || File != Sym->getFile())
         continue;
       if (Sym->isFunction()) {
         auto *Obj = cast<ObjFile>(Sym->getFile());
         Sym->setOutputIndex(Obj->FunctionIndexOffset +
                             Sym->getFunctionIndex());
       } else if (Config->EmitRelocs) {
         DefinedGlobals.emplace_back(Sym);
         Sym->setOutputIndex(GlobalIndex++);
       }
     }

     for (Symbol *Sym : File->getTableSymbols()) {
       if (!Sym->hasTableIndex()) {
         Sym->setTableIndex(TableIndex++);
         IndirectFunctions.emplace_back(Sym);
       }
     }
   }
 }

 static StringRef getOutputDataSegmentName(StringRef Name) {
   if (Config->Relocatable)
     return Name;

   for (StringRef V :
        {".text.", ".rodata.", ".data.rel.ro.", ".data.", ".bss.rel.ro.",
         ".bss.", ".init_array.", ".fini_array.", ".ctors.", ".dtors.", ".tbss.",
         ".gcc_except_table.", ".tdata.", ".ARM.exidx.", ".ARM.extab."}) {
     StringRef Prefix = V.drop_back();
     if (Name.startswith(V) || Name == Prefix)
       return Prefix;
   }

   return Name;
 }

 void Writer::createOutputSegments() {
   for (ObjFile *File : Symtab->ObjectFiles) {
     for (InputSegment *Segment : File->Segments) {
       StringRef Name = getOutputDataSegmentName(Segment->getName());
       OutputSegment *&S = SegmentMap[Name];
       if (S == nullptr) {
         DEBUG(dbgs() << "new segment: " << Name << "\n");
         S = make<OutputSegment>(Name);
         Segments.push_back(S);
       }
       S->addInputSegment(Segment);
       DEBUG(dbgs() << "added data: " << Name << ": " << S->Size << "\n");
     }
   }
 }

 void Writer::run() {
   if (!Config->Relocatable)
     InitialTableOffset = 1;

   log("-- calculateTypes");
   calculateTypes();
   log("-- calculateImports");
   calculateImports();
   log("-- calculateOffsets");
   calculateOffsets();

   if (errorHandler().Verbose) {
     log("Defined Functions: " + Twine(NumFunctions));
     log("Defined Globals  : " + Twine(DefinedGlobals.size()));
     log("Function Imports : " + Twine(FunctionImports.size()));
     log("Global Imports   : " + Twine(GlobalImports.size()));
     log("Total Imports    : " +
         Twine(FunctionImports.size() + GlobalImports.size()));
     for (ObjFile *File : Symtab->ObjectFiles)
       File->dumpInfo();
   }

   log("-- assignSymbolIndexes");
   assignSymbolIndexes();
   log("-- layoutMemory");
   layoutMemory();

   createHeader();
   log("-- createSections");
   createSections();

   log("-- openFile");
   openFile();
   if (errorCount())
     return;

   writeHeader();

   log("-- writeSections");
   writeSections();
   if (errorCount())
     return;

   if (Error E = Buffer->commit())
     fatal("failed to write the output file: " + toString(std::move(E)));
 }

 // Open a result file.
 void Writer::openFile() {
   log("writing: " + Config->OutputFile);
   ::remove(Config->OutputFile.str().c_str());

   Expected<std::unique_ptr<FileOutputBuffer>> BufferOrErr =
       FileOutputBuffer::create(Config->OutputFile, FileSize,
                                FileOutputBuffer::F_executable);

   if (!BufferOrErr)
     error("failed to open " + Config->OutputFile + ": " +
           toString(BufferOrErr.takeError()));
   else
     Buffer = std::move(*BufferOrErr);
 }

 void Writer::createHeader() {
   raw_string_ostream OS(Header);
   writeBytes(OS, WasmMagic, sizeof(WasmMagic), "wasm magic");
   writeU32(OS, WasmVersion, "wasm version");
   OS.flush();
   FileSize += Header.size();
 }

 void lld::wasm::writeResult() { Writer().run(); }
	//===- Writer.cpp ---------------------------------------------------------===//
	//
	// The LLVM Linker
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "Writer.h"

	#include "Config.h"
	#include "OutputSections.h"
	#include "OutputSegment.h"
	#include "SymbolTable.h"
	#include "WriterUtils.h"
	#include "lld/Common/ErrorHandler.h"
	#include "lld/Common/Memory.h"
	#include "lld/Common/Threads.h"
	#include "llvm/Support/FileOutputBuffer.h"
	#include "llvm/Support/Format.h"
	#include "llvm/Support/FormatVariadic.h"
	#include "llvm/Support/LEB128.h"

	#include <cstdarg>

	#define DEBUG_TYPE "lld"

	using namespace llvm;
	using namespace llvm::wasm;
	using namespace lld;
	using namespace lld::wasm;

	static constexpr int kStackAlignment = 16;

	namespace {

	// Traits for using WasmSignature in a DenseMap.
	struct WasmSignatureDenseMapInfo {
	static WasmSignature getEmptyKey() {
	WasmSignature Sig;
	Sig.ReturnType = 1;
	return Sig;
	}
	static WasmSignature getTombstoneKey() {
	WasmSignature Sig;
	Sig.ReturnType = 2;
	return Sig;
	}
	static unsigned getHashValue(const WasmSignature &Sig) {
	uintptr_t Value = 0;
	Value += DenseMapInfo<int32_t>::getHashValue(Sig.ReturnType);
	for (int32_t Param : Sig.ParamTypes)
	Value += DenseMapInfo<int32_t>::getHashValue(Param);
	return Value;
	}
	static bool isEqual(const WasmSignature &LHS, const WasmSignature &RHS) {
	return LHS == RHS;
	}
	};

	// The writer writes a SymbolTable result to a file.
	class Writer {
	public:
	void run();

	private:
	void openFile();

	uint32_t getTypeIndex(const WasmSignature &Sig);
	void assignSymbolIndexes();
	void calculateImports();
	void calculateOffsets();
	void calculateTypes();
	void createOutputSegments();
	void layoutMemory();
	void createHeader();
	void createSections();
	SyntheticSection *createSyntheticSection(uint32_t Type,
	std::string Name = "");

	// Builtin sections
	void createTypeSection();
	void createFunctionSection();
	void createTableSection();
	void createGlobalSection();
	void createExportSection();
	void createImportSection();
	void createMemorySection();
	void createElemSection();
	void createStartSection();
	void createCodeSection();
	void createDataSection();

	// Custom sections
	void createRelocSections();
	void createLinkingSection();
	void createNameSection();

	void writeHeader();
	void writeSections();

	uint64_t FileSize = 0;
	uint32_t DataSize = 0;
	uint32_t NumFunctions = 0;
	uint32_t NumMemoryPages = 0;
	uint32_t InitialTableOffset = 0;

	std::vector<const WasmSignature *> Types;
	DenseMap<WasmSignature, int32_t, WasmSignatureDenseMapInfo> TypeIndices;
	std::vector<const Symbol *> FunctionImports;
	std::vector<const Symbol *> GlobalImports;
	std::vector<const Symbol *> DefinedGlobals;
	std::vector<const Symbol *> IndirectFunctions;

	// Elements that are used to construct the final output
	std::string Header;
	std::vector<OutputSection *> OutputSections;

	std::unique_ptr<FileOutputBuffer> Buffer;

	std::vector<OutputSegment *> Segments;
	llvm::SmallDenseMap<StringRef, OutputSegment *> SegmentMap;
	};

	} // anonymous namespace

	static void debugPrint(const char *fmt, ...) {
	if (!errorHandler().Verbose)
	return;
	fprintf(stderr, "lld: ");
	va_list ap;
	va_start(ap, fmt);
	vfprintf(stderr, fmt, ap);
	va_end(ap);
	}

	void Writer::createImportSection() {
	uint32_t NumImports = FunctionImports.size() + GlobalImports.size();
	if (Config->ImportMemory)
	++NumImports;

	if (NumImports == 0)
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_IMPORT);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, NumImports, "import count");

	for (const Symbol *Sym : FunctionImports) {
	WasmImport Import;
	Import.Module = "env";
	Import.Field = Sym->getName();
	Import.Kind = WASM_EXTERNAL_FUNCTION;
	assert(TypeIndices.count(Sym->getFunctionType()) > 0);
	Import.SigIndex = TypeIndices.lookup(Sym->getFunctionType());
	writeImport(OS, Import);
	}

	if (Config->ImportMemory) {
	WasmImport Import;
	Import.Module = "env";
	Import.Field = "memory";
	Import.Kind = WASM_EXTERNAL_MEMORY;
	Import.Memory.Flags = 0;
	Import.Memory.Initial = NumMemoryPages;
	writeImport(OS, Import);
	}

	for (const Symbol *Sym : GlobalImports) {
	WasmImport Import;
	Import.Module = "env";
	Import.Field = Sym->getName();
	Import.Kind = WASM_EXTERNAL_GLOBAL;
	Import.Global.Mutable = false;
	Import.Global.Type = WASM_TYPE_I32;
	writeImport(OS, Import);
	}
	}

	void Writer::createTypeSection() {
	SyntheticSection *Section = createSyntheticSection(WASM_SEC_TYPE);
	raw_ostream &OS = Section->getStream();
	writeUleb128(OS, Types.size(), "type count");
	for (const WasmSignature *Sig : Types)
	writeSig(OS, *Sig);
	}

	void Writer::createFunctionSection() {
	if (!NumFunctions)
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_FUNCTION);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, NumFunctions, "function count");
	for (ObjFile *File : Symtab->ObjectFiles)
	for (uint32_t Sig : File->getWasmObj()->functionTypes())
	writeUleb128(OS, File->relocateTypeIndex(Sig), "sig index");
	}

	void Writer::createMemorySection() {
	if (Config->ImportMemory)
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_MEMORY);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, 1, "memory count");
	writeUleb128(OS, 0, "memory limits flags");
	writeUleb128(OS, NumMemoryPages, "initial pages");
	}

	void Writer::createGlobalSection() {
	if (DefinedGlobals.empty())
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_GLOBAL);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, DefinedGlobals.size(), "global count");
	for (const Symbol *Sym : DefinedGlobals) {
	WasmGlobal Global;
	Global.Type = WASM_TYPE_I32;
	Global.Mutable = Sym == Config->StackPointerSymbol;
	Global.InitExpr.Opcode = WASM_OPCODE_I32_CONST;
	Global.InitExpr.Value.Int32 = Sym->getVirtualAddress();
	writeGlobal(OS, Global);
	}
	}

	void Writer::createTableSection() {
	// Always output a table section, even if there are no indirect calls.
	// There are two reasons for this:
	// 1. For executables it is useful to have an empty table slot at 0
	// which can be filled with a null function call handler.
	// 2. If we don't do this, any program that contains a call_indirect but
	// no address-taken function will fail at validation time since it is
	// a validation error to include a call_indirect instruction if there
	// is not table.
	uint32_t TableSize = InitialTableOffset + IndirectFunctions.size();

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_TABLE);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, 1, "table count");
	writeSleb128(OS, WASM_TYPE_ANYFUNC, "table type");
	writeUleb128(OS, WASM_LIMITS_FLAG_HAS_MAX, "table flags");
	writeUleb128(OS, TableSize, "table initial size");
	writeUleb128(OS, TableSize, "table max size");
	}

	void Writer::createExportSection() {
	bool ExportMemory = !Config->Relocatable && !Config->ImportMemory;
	Symbol *EntrySym = Symtab->find(Config->Entry);
	bool ExportEntry = !Config->Relocatable && EntrySym && EntrySym->isDefined();
	bool ExportHidden = Config->EmitRelocs;

	uint32_t NumExports = ExportMemory ? 1 : 0;

	std::vector<const Symbol *> SymbolExports;
	if (ExportEntry)
	SymbolExports.emplace_back(EntrySym);

	for (const Symbol *Sym : Symtab->getSymbols()) {
	if (Sym->isUndefined() \|\| Sym->isGlobal())
	continue;
	if (Sym->isHidden() && !ExportHidden)
	continue;
	if (ExportEntry && Sym == EntrySym)
	continue;
	SymbolExports.emplace_back(Sym);
	}

	for (const Symbol *Sym : DefinedGlobals) {
	// Can't export the SP right now because it mutable and mutable globals
	// connot be exported.
	if (Sym == Config->StackPointerSymbol)
	continue;
	SymbolExports.emplace_back(Sym);
	}

	NumExports += SymbolExports.size();
	if (!NumExports)
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_EXPORT);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, NumExports, "export count");

	if (ExportMemory) {
	WasmExport MemoryExport;
	MemoryExport.Name = "memory";
	MemoryExport.Kind = WASM_EXTERNAL_MEMORY;
	MemoryExport.Index = 0;
	writeExport(OS, MemoryExport);
	}

	for (const Symbol *Sym : SymbolExports) {
	log("Export: " + Sym->getName());
	WasmExport Export;
	Export.Name = Sym->getName();
	Export.Index = Sym->getOutputIndex();
	if (Sym->isFunction())
	Export.Kind = WASM_EXTERNAL_FUNCTION;
	else
	Export.Kind = WASM_EXTERNAL_GLOBAL;
	writeExport(OS, Export);
	}
	}

	void Writer::createStartSection() {}

	void Writer::createElemSection() {
	if (IndirectFunctions.empty())
	return;

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_ELEM);
	raw_ostream &OS = Section->getStream();

	writeUleb128(OS, 1, "segment count");
	writeUleb128(OS, 0, "table index");
	WasmInitExpr InitExpr;
	InitExpr.Opcode = WASM_OPCODE_I32_CONST;
	InitExpr.Value.Int32 = InitialTableOffset;
	writeInitExpr(OS, InitExpr);
	writeUleb128(OS, IndirectFunctions.size(), "elem count");

	uint32_t TableIndex = InitialTableOffset;
	for (const Symbol *Sym : IndirectFunctions) {
	assert(Sym->getTableIndex() == TableIndex);
	writeUleb128(OS, Sym->getOutputIndex(), "function index");
	++TableIndex;
	}
	}

	void Writer::createCodeSection() {
	if (!NumFunctions)
	return;

	log("createCodeSection");

	auto Section = make<CodeSection>(NumFunctions, Symtab->ObjectFiles);
	OutputSections.push_back(Section);
	}

	void Writer::createDataSection() {
	if (!Segments.size())
	return;

	log("createDataSection");
	auto Section = make<DataSection>(Segments);
	OutputSections.push_back(Section);
	}

	// Create relocations sections in the final output.
	// These are only created when relocatable output is requested.
	void Writer::createRelocSections() {
	log("createRelocSections");
	// Don't use iterator here since we are adding to OutputSection
	size_t OrigSize = OutputSections.size();
	for (size_t i = 0; i < OrigSize; i++) {
	OutputSection *S = OutputSections[i];
	const char *name;
	uint32_t Count = S->numRelocations();
	if (!Count)
	continue;

	if (S->Type == WASM_SEC_DATA)
	name = "reloc.DATA";
	else if (S->Type == WASM_SEC_CODE)
	name = "reloc.CODE";
	else
	llvm_unreachable("relocations only supported for code and data");

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_CUSTOM, name);
	raw_ostream &OS = Section->getStream();
	writeUleb128(OS, S->Type, "reloc section");
	writeUleb128(OS, Count, "reloc count");
	S->writeRelocations(OS);
	}
	}

	// Create the custom "linking" section containing linker metadata.
	// This is only created when relocatable output is requested.
	void Writer::createLinkingSection() {
	SyntheticSection *Section =
	createSyntheticSection(WASM_SEC_CUSTOM, "linking");
	raw_ostream &OS = Section->getStream();

	SubSection DataSizeSubSection(WASM_DATA_SIZE);
	writeUleb128(DataSizeSubSection.getStream(), DataSize, "data size");
	DataSizeSubSection.finalizeContents();
	DataSizeSubSection.writeToStream(OS);

	if (!Config->Relocatable)
	return;

	if (Segments.size()) {
	SubSection SubSection(WASM_SEGMENT_INFO);
	writeUleb128(SubSection.getStream(), Segments.size(), "num data segments");
	for (const OutputSegment *S : Segments) {
	writeStr(SubSection.getStream(), S->Name, "segment name");
	writeUleb128(SubSection.getStream(), S->Alignment, "alignment");
	writeUleb128(SubSection.getStream(), 0, "flags");
	}
	SubSection.finalizeContents();
	SubSection.writeToStream(OS);
	}

	std::vector<WasmInitFunc> InitFunctions;
	for (ObjFile *File : Symtab->ObjectFiles) {
	const WasmLinkingData &L = File->getWasmObj()->linkingData();
	InitFunctions.reserve(InitFunctions.size() + L.InitFunctions.size());
	for (const WasmInitFunc &F : L.InitFunctions)
	InitFunctions.emplace_back(WasmInitFunc{
	F.Priority, File->relocateFunctionIndex(F.FunctionIndex)});
	}

	if (!InitFunctions.empty()) {
	SubSection SubSection(WASM_INIT_FUNCS);
	writeUleb128(SubSection.getStream(), InitFunctions.size(),
	"num init functionsw");
	for (const WasmInitFunc &F : InitFunctions) {
	writeUleb128(SubSection.getStream(), F.Priority, "priority");
	writeUleb128(SubSection.getStream(), F.FunctionIndex, "function index");
	}
	SubSection.finalizeContents();
	SubSection.writeToStream(OS);
	}
	}

	// Create the custom "name" section containing debug symbol names.
	void Writer::createNameSection() {
	// Create an array of all function sorted by function index space
	std::vector<const Symbol *> Names;

	for (ObjFile *File : Symtab->ObjectFiles) {
	Names.reserve(Names.size() + File->getSymbols().size());
	for (Symbol *S : File->getSymbols()) {
	if (!S->isFunction() \|\| S->isWeak() \|\| S->WrittenToNameSec)
	continue;
	S->WrittenToNameSec = true;
	Names.emplace_back(S);
	}
	}

	SyntheticSection *Section = createSyntheticSection(WASM_SEC_CUSTOM, "name");

	std::sort(Names.begin(), Names.end(), [](const Symbol A, const Symbol B) {
	return A->getOutputIndex() < B->getOutputIndex();
	});

	SubSection FunctionSubsection(WASM_NAMES_FUNCTION);
	raw_ostream &OS = FunctionSubsection.getStream();
	writeUleb128(OS, Names.size(), "name count");

	// We have to iterate through the inputs twice so that all the imports
	// appear first before any of the local function names.
	for (const Symbol *S : Names) {
	writeUleb128(OS, S->getOutputIndex(), "func index");
	writeStr(OS, S->getName(), "symbol name");
	}

	FunctionSubsection.finalizeContents();
	FunctionSubsection.writeToStream(Section->getStream());
	}

	void Writer::writeHeader() {
	memcpy(Buffer->getBufferStart(), Header.data(), Header.size());
	}

	void Writer::writeSections() {
	uint8_t *Buf = Buffer->getBufferStart();
	parallelForEach(OutputSections, [Buf](OutputSection *S) { S->writeTo(Buf); });
	}

	// Fix the memory layout of the output binary. This assigns memory offsets
	// to each of the input data sections as well as the explicit stack region.
	void Writer::layoutMemory() {
	uint32_t MemoryPtr = 0;
	if (!Config->Relocatable) {
	MemoryPtr = Config->GlobalBase;
	debugPrint("mem: global base = %d\n", Config->GlobalBase);
	}

	createOutputSegments();

	// Static data comes first
	for (OutputSegment *Seg : Segments) {
	MemoryPtr = alignTo(MemoryPtr, Seg->Alignment);
	Seg->StartVA = MemoryPtr;
	debugPrint("mem: %-10s offset=%-8d size=%-4d align=%d\n",
	Seg->Name.str().c_str(), MemoryPtr, Seg->Size, Seg->Alignment);
	MemoryPtr += Seg->Size;
	}

	DataSize = MemoryPtr;
	if (!Config->Relocatable)
	DataSize -= Config->GlobalBase;
	debugPrint("mem: static data = %d\n", DataSize);

	// Stack comes after static data
	if (!Config->Relocatable) {
	MemoryPtr = alignTo(MemoryPtr, kStackAlignment);
	if (Config->ZStackSize != alignTo(Config->ZStackSize, kStackAlignment))
	error("stack size must be " + Twine(kStackAlignment) + "-byte aligned");
	debugPrint("mem: stack size = %d\n", Config->ZStackSize);
	debugPrint("mem: stack base = %d\n", MemoryPtr);
	MemoryPtr += Config->ZStackSize;
	Config->StackPointerSymbol->setVirtualAddress(MemoryPtr);
	debugPrint("mem: stack top = %d\n", MemoryPtr);
	}

	uint32_t MemSize = alignTo(MemoryPtr, WasmPageSize);
	NumMemoryPages = MemSize / WasmPageSize;
	debugPrint("mem: total pages = %d\n", NumMemoryPages);
	}

	SyntheticSection *Writer::createSyntheticSection(uint32_t Type,
	std::string Name) {
	auto Sec = make<SyntheticSection>(Type, Name);
	log("createSection: " + toString(*Sec));
	OutputSections.push_back(Sec);
	return Sec;
	}

	void Writer::createSections() {
	// Known sections
	createTypeSection();
	createImportSection();
	createFunctionSection();
	createTableSection();
	createMemorySection();
	createGlobalSection();
	createExportSection();
	createStartSection();
	createElemSection();
	createCodeSection();
	createDataSection();

	// Custom sections
	if (Config->EmitRelocs)
	createRelocSections();
	createLinkingSection();
	if (!Config->StripDebug && !Config->StripAll)
	createNameSection();

	for (OutputSection *S : OutputSections) {
	S->setOffset(FileSize);
	S->finalizeContents();
	FileSize += S->getSize();
	}
	}

	void Writer::calculateOffsets() {
	for (ObjFile *File : Symtab->ObjectFiles) {
	const WasmObjectFile *WasmFile = File->getWasmObj();

	// Function Index
	File->FunctionIndexOffset =
	FunctionImports.size() - File->NumFunctionImports() + NumFunctions;
	NumFunctions += WasmFile->functions().size();

	// Memory
	if (WasmFile->memories().size() > 1)
	fatal(File->getName() + ": contains more than one memory");
	}
	}

	void Writer::calculateImports() {
	for (Symbol *Sym : Symtab->getSymbols()) {
	if (!Sym->isUndefined() \|\| Sym->isWeak())
	continue;

	if (Sym->isFunction()) {
	Sym->setOutputIndex(FunctionImports.size());
	FunctionImports.push_back(Sym);
	} else {
	Sym->setOutputIndex(GlobalImports.size());
	GlobalImports.push_back(Sym);
	}
	}
	}

	uint32_t Writer::getTypeIndex(const WasmSignature &Sig) {
	auto Pair = TypeIndices.insert(std::make_pair(Sig, Types.size()));
	if (Pair.second)
	Types.push_back(&Sig);
	return Pair.first->second;
	}

	void Writer::calculateTypes() {
	for (ObjFile *File : Symtab->ObjectFiles) {
	File->TypeMap.reserve(File->getWasmObj()->types().size());
	for (const WasmSignature &Sig : File->getWasmObj()->types())
	File->TypeMap.push_back(getTypeIndex(Sig));
	}
	}

	void Writer::assignSymbolIndexes() {
	uint32_t GlobalIndex = GlobalImports.size();

	if (Config->StackPointerSymbol) {
	DefinedGlobals.emplace_back(Config->StackPointerSymbol);
	Config->StackPointerSymbol->setOutputIndex(GlobalIndex++);
	}

	if (Config->EmitRelocs)
	DefinedGlobals.reserve(Symtab->getSymbols().size());

	uint32_t TableIndex = InitialTableOffset;

	for (ObjFile *File : Symtab->ObjectFiles) {
	DEBUG(dbgs() << "assignSymbolIndexes: " << File->getName() << "\n");

	for (Symbol *Sym : File->getSymbols()) {
	// Assign indexes for symbols defined with this file.
	if (!Sym->isDefined() \|\| File != Sym->getFile())
	continue;
	if (Sym->isFunction()) {
	auto *Obj = cast<ObjFile>(Sym->getFile());
	Sym->setOutputIndex(Obj->FunctionIndexOffset +
	Sym->getFunctionIndex());
	} else if (Config->EmitRelocs) {
	DefinedGlobals.emplace_back(Sym);
	Sym->setOutputIndex(GlobalIndex++);
	}
	}

	for (Symbol *Sym : File->getTableSymbols()) {
	if (!Sym->hasTableIndex()) {
	Sym->setTableIndex(TableIndex++);
	IndirectFunctions.emplace_back(Sym);
	}
	}
	}
	}

	static StringRef getOutputDataSegmentName(StringRef Name) {
	if (Config->Relocatable)
	return Name;

	for (StringRef V :
	{".text.", ".rodata.", ".data.rel.ro.", ".data.", ".bss.rel.ro.",
	".bss.", ".init_array.", ".fini_array.", ".ctors.", ".dtors.", ".tbss.",
	".gcc_except_table.", ".tdata.", ".ARM.exidx.", ".ARM.extab."}) {
	StringRef Prefix = V.drop_back();
	if (Name.startswith(V) \|\| Name == Prefix)
	return Prefix;
	}

	return Name;
	}

	void Writer::createOutputSegments() {
	for (ObjFile *File : Symtab->ObjectFiles) {
	for (InputSegment *Segment : File->Segments) {
	StringRef Name = getOutputDataSegmentName(Segment->getName());
	OutputSegment *&S = SegmentMap[Name];
	if (S == nullptr) {
	DEBUG(dbgs() << "new segment: " << Name << "\n");
	S = make<OutputSegment>(Name);
	Segments.push_back(S);
	}
	S->addInputSegment(Segment);
	DEBUG(dbgs() << "added data: " << Name << ": " << S->Size << "\n");
	}
	}
	}

	void Writer::run() {
	if (!Config->Relocatable)
	InitialTableOffset = 1;

	log("-- calculateTypes");
	calculateTypes();
	log("-- calculateImports");
	calculateImports();
	log("-- calculateOffsets");
	calculateOffsets();

	if (errorHandler().Verbose) {
	log("Defined Functions: " + Twine(NumFunctions));
	log("Defined Globals : " + Twine(DefinedGlobals.size()));
	log("Function Imports : " + Twine(FunctionImports.size()));
	log("Global Imports : " + Twine(GlobalImports.size()));
	log("Total Imports : " +
	Twine(FunctionImports.size() + GlobalImports.size()));
	for (ObjFile *File : Symtab->ObjectFiles)
	File->dumpInfo();
	}

	log("-- assignSymbolIndexes");
	assignSymbolIndexes();
	log("-- layoutMemory");
	layoutMemory();

	createHeader();
	log("-- createSections");
	createSections();

	log("-- openFile");
	openFile();
	if (errorCount())
	return;

	writeHeader();

	log("-- writeSections");
	writeSections();
	if (errorCount())
	return;

	if (Error E = Buffer->commit())
	fatal("failed to write the output file: " + toString(std::move(E)));
	}

	// Open a result file.
	void Writer::openFile() {
	log("writing: " + Config->OutputFile);
	::remove(Config->OutputFile.str().c_str());

	Expected<std::unique_ptr<FileOutputBuffer>> BufferOrErr =
	FileOutputBuffer::create(Config->OutputFile, FileSize,
	FileOutputBuffer::F_executable);

	if (!BufferOrErr)
	error("failed to open " + Config->OutputFile + ": " +
	toString(BufferOrErr.takeError()));
	else
	Buffer = std::move(*BufferOrErr);
	}

	void Writer::createHeader() {
	raw_string_ostream OS(Header);
	writeBytes(OS, WasmMagic, sizeof(WasmMagic), "wasm magic");
	writeU32(OS, WasmVersion, "wasm version");
	OS.flush();
	FileSize += Header.size();
	}

	void lld::wasm::writeResult() { Writer().run(); }