wasm/SyntheticSections.cpp - lld - Git at Google

 //===- SyntheticSections.cpp ----------------------------------------------===//
 //
 // 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 contains linker-synthesized sections.
 //
 //===----------------------------------------------------------------------===//

 #include "SyntheticSections.h"

 #include "InputChunks.h"
 #include "InputEvent.h"
 #include "InputGlobal.h"
 #include "OutputSegment.h"
 #include "SymbolTable.h"
 #include "llvm/Support/Path.h"

 using namespace llvm;
 using namespace llvm::wasm;

 using namespace lld;
 using namespace lld::wasm;

 OutStruct lld::wasm::Out;

 namespace {

 // Some synthetic sections (e.g. "name" and "linking") have subsections.
 // Just like the synthetic sections themselves these need to be created before
 // they can be written out (since they are preceded by their length). This
 // class is used to create subsections and then write them into the stream
 // of the parent section.
 class SubSection {
 public:
   explicit SubSection(uint32_t Type) : Type(Type) {}

   void writeTo(raw_ostream &To) {
     OS.flush();
     writeUleb128(To, Type, "subsection type");
     writeUleb128(To, Body.size(), "subsection size");
     To.write(Body.data(), Body.size());
   }

 private:
   uint32_t Type;
   std::string Body;

 public:
   raw_string_ostream OS{Body};
 };

 } // namespace

 void DylinkSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, MemSize, "MemSize");
   writeUleb128(OS, MemAlign, "MemAlign");
   writeUleb128(OS, Out.ElemSec->numEntries(), "TableSize");
   writeUleb128(OS, 0, "TableAlign");
   writeUleb128(OS, Symtab->SharedFiles.size(), "Needed");
   for (auto *SO : Symtab->SharedFiles)
     writeStr(OS, llvm::sys::path::filename(SO->getName()), "so name");
 }

 uint32_t TypeSection::registerType(const WasmSignature &Sig) {
   auto Pair = TypeIndices.insert(std::make_pair(Sig, Types.size()));
   if (Pair.second) {
     LLVM_DEBUG(llvm::dbgs() << "type " << toString(Sig) << "\n");
     Types.push_back(&Sig);
   }
   return Pair.first->second;
 }

 uint32_t TypeSection::lookupType(const WasmSignature &Sig) {
   auto It = TypeIndices.find(Sig);
   if (It == TypeIndices.end()) {
     error("type not found: " + toString(Sig));
     return 0;
   }
   return It->second;
 }

 void TypeSection::writeBody() {
   writeUleb128(BodyOutputStream, Types.size(), "type count");
   for (const WasmSignature *Sig : Types)
     writeSig(BodyOutputStream, *Sig);
 }

 uint32_t ImportSection::numImports() const {
   assert(IsSealed);
   uint32_t NumImports = ImportedSymbols.size() + GOTSymbols.size();
   if (Config->ImportMemory)
     ++NumImports;
   if (Config->ImportTable)
     ++NumImports;
   return NumImports;
 }

 void ImportSection::addGOTEntry(Symbol *Sym) {
   assert(!IsSealed);
   if (Sym->hasGOTIndex())
     return;
   Sym->setGOTIndex(NumImportedGlobals++);
   GOTSymbols.push_back(Sym);
 }

 void ImportSection::addImport(Symbol *Sym) {
   assert(!IsSealed);
   ImportedSymbols.emplace_back(Sym);
   if (auto *F = dyn_cast<FunctionSymbol>(Sym))
     F->setFunctionIndex(NumImportedFunctions++);
   else if (auto *G = dyn_cast<GlobalSymbol>(Sym))
     G->setGlobalIndex(NumImportedGlobals++);
   else
     cast<EventSymbol>(Sym)->setEventIndex(NumImportedEvents++);
 }

 void ImportSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

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

   if (Config->ImportMemory) {
     WasmImport Import;
     Import.Module = DefaultModule;
     Import.Field = "memory";
     Import.Kind = WASM_EXTERNAL_MEMORY;
     Import.Memory.Flags = 0;
     Import.Memory.Initial = Out.MemorySec->NumMemoryPages;
     if (Out.MemorySec->MaxMemoryPages != 0 || Config->SharedMemory) {
       Import.Memory.Flags |= WASM_LIMITS_FLAG_HAS_MAX;
       Import.Memory.Maximum = Out.MemorySec->MaxMemoryPages;
     }
     if (Config->SharedMemory)
       Import.Memory.Flags |= WASM_LIMITS_FLAG_IS_SHARED;
     writeImport(OS, Import);
   }

   if (Config->ImportTable) {
     uint32_t TableSize = Out.ElemSec->ElemOffset + Out.ElemSec->numEntries();
     WasmImport Import;
     Import.Module = DefaultModule;
     Import.Field = FunctionTableName;
     Import.Kind = WASM_EXTERNAL_TABLE;
     Import.Table.ElemType = WASM_TYPE_FUNCREF;
     Import.Table.Limits = {0, TableSize, 0};
     writeImport(OS, Import);
   }

   for (const Symbol *Sym : ImportedSymbols) {
     WasmImport Import;
     if (auto *F = dyn_cast<UndefinedFunction>(Sym)) {
       Import.Field = F->ImportName;
       Import.Module = F->ImportModule;
     } else if (auto *G = dyn_cast<UndefinedGlobal>(Sym)) {
       Import.Field = G->ImportName;
       Import.Module = G->ImportModule;
     } else {
       Import.Field = Sym->getName();
       Import.Module = DefaultModule;
     }

     if (auto *FunctionSym = dyn_cast<FunctionSymbol>(Sym)) {
       Import.Kind = WASM_EXTERNAL_FUNCTION;
       Import.SigIndex = Out.TypeSec->lookupType(*FunctionSym->Signature);
     } else if (auto *GlobalSym = dyn_cast<GlobalSymbol>(Sym)) {
       Import.Kind = WASM_EXTERNAL_GLOBAL;
       Import.Global = *GlobalSym->getGlobalType();
     } else {
       auto *EventSym = cast<EventSymbol>(Sym);
       Import.Kind = WASM_EXTERNAL_EVENT;
       Import.Event.Attribute = EventSym->getEventType()->Attribute;
       Import.Event.SigIndex = Out.TypeSec->lookupType(*EventSym->Signature);
     }
     writeImport(OS, Import);
   }

   for (const Symbol *Sym : GOTSymbols) {
     WasmImport Import;
     Import.Kind = WASM_EXTERNAL_GLOBAL;
     Import.Global = {WASM_TYPE_I32, true};
     if (isa<DataSymbol>(Sym))
       Import.Module = "GOT.mem";
     else
       Import.Module = "GOT.func";
     Import.Field = Sym->getName();
     writeImport(OS, Import);
   }
 }

 void FunctionSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, InputFunctions.size(), "function count");
   for (const InputFunction *Func : InputFunctions)
     writeUleb128(OS, Out.TypeSec->lookupType(Func->Signature), "sig index");
 }

 void FunctionSection::addFunction(InputFunction *Func) {
   if (!Func->Live)
     return;
   uint32_t FunctionIndex =
       Out.ImportSec->numImportedFunctions() + InputFunctions.size();
   InputFunctions.emplace_back(Func);
   Func->setFunctionIndex(FunctionIndex);
 }

 void TableSection::writeBody() {
   uint32_t TableSize = Out.ElemSec->ElemOffset + Out.ElemSec->numEntries();

   raw_ostream &OS = BodyOutputStream;
   writeUleb128(OS, 1, "table count");
   WasmLimits Limits = {WASM_LIMITS_FLAG_HAS_MAX, TableSize, TableSize};
   writeTableType(OS, WasmTable{WASM_TYPE_FUNCREF, Limits});
 }

 void MemorySection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   bool HasMax = MaxMemoryPages != 0 || Config->SharedMemory;
   writeUleb128(OS, 1, "memory count");
   unsigned Flags = 0;
   if (HasMax)
     Flags |= WASM_LIMITS_FLAG_HAS_MAX;
   if (Config->SharedMemory)
     Flags |= WASM_LIMITS_FLAG_IS_SHARED;
   writeUleb128(OS, Flags, "memory limits flags");
   writeUleb128(OS, NumMemoryPages, "initial pages");
   if (HasMax)
     writeUleb128(OS, MaxMemoryPages, "max pages");
 }

 void GlobalSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, numGlobals(), "global count");
   for (const InputGlobal *G : InputGlobals)
     writeGlobal(OS, G->Global);
   for (const DefinedData *Sym : DefinedFakeGlobals) {
     WasmGlobal Global;
     Global.Type = {WASM_TYPE_I32, false};
     Global.InitExpr.Opcode = WASM_OPCODE_I32_CONST;
     Global.InitExpr.Value.Int32 = Sym->getVirtualAddress();
     writeGlobal(OS, Global);
   }
 }

 void GlobalSection::addGlobal(InputGlobal *Global) {
   if (!Global->Live)
     return;
   uint32_t GlobalIndex =
       Out.ImportSec->numImportedGlobals() + InputGlobals.size();
   LLVM_DEBUG(dbgs() << "addGlobal: " << GlobalIndex << "\n");
   Global->setGlobalIndex(GlobalIndex);
   Out.GlobalSec->InputGlobals.push_back(Global);
 }

 void EventSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, InputEvents.size(), "event count");
   for (InputEvent *E : InputEvents) {
     E->Event.Type.SigIndex = Out.TypeSec->lookupType(E->Signature);
     writeEvent(OS, E->Event);
   }
 }

 void EventSection::addEvent(InputEvent *Event) {
   if (!Event->Live)
     return;
   uint32_t EventIndex = Out.ImportSec->numImportedEvents() + InputEvents.size();
   LLVM_DEBUG(dbgs() << "addEvent: " << EventIndex << "\n");
   Event->setEventIndex(EventIndex);
   InputEvents.push_back(Event);
 }

 void ExportSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, Exports.size(), "export count");
   for (const WasmExport &Export : Exports)
     writeExport(OS, Export);
 }

 void ElemSection::addEntry(FunctionSymbol *Sym) {
   if (Sym->hasTableIndex())
     return;
   Sym->setTableIndex(ElemOffset + IndirectFunctions.size());
   IndirectFunctions.emplace_back(Sym);
 }

 void ElemSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, 1, "segment count");
   writeUleb128(OS, 0, "table index");
   WasmInitExpr InitExpr;
   if (Config->Pic) {
     InitExpr.Opcode = WASM_OPCODE_GLOBAL_GET;
     InitExpr.Value.Global = WasmSym::TableBase->getGlobalIndex();
   } else {
     InitExpr.Opcode = WASM_OPCODE_I32_CONST;
     InitExpr.Value.Int32 = ElemOffset;
   }
   writeInitExpr(OS, InitExpr);
   writeUleb128(OS, IndirectFunctions.size(), "elem count");

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

 void DataCountSection::writeBody() {
   writeUleb128(BodyOutputStream, NumSegments, "data count");
 }

 bool DataCountSection::isNeeded() const {
   return NumSegments && Out.TargetFeaturesSec->Features.count("bulk-memory");
 }

 static uint32_t getWasmFlags(const Symbol *Sym) {
   uint32_t Flags = 0;
   if (Sym->isLocal())
     Flags |= WASM_SYMBOL_BINDING_LOCAL;
   if (Sym->isWeak())
     Flags |= WASM_SYMBOL_BINDING_WEAK;
   if (Sym->isHidden())
     Flags |= WASM_SYMBOL_VISIBILITY_HIDDEN;
   if (Sym->isUndefined())
     Flags |= WASM_SYMBOL_UNDEFINED;
   if (auto *F = dyn_cast<UndefinedFunction>(Sym)) {
     if (F->getName() != F->ImportName)
       Flags |= WASM_SYMBOL_EXPLICIT_NAME;
   } else if (auto *G = dyn_cast<UndefinedGlobal>(Sym)) {
     if (G->getName() != G->ImportName)
       Flags |= WASM_SYMBOL_EXPLICIT_NAME;
   }
   return Flags;
 }

 void LinkingSection::writeBody() {
   raw_ostream &OS = BodyOutputStream;

   writeUleb128(OS, WasmMetadataVersion, "Version");

   if (!SymtabEntries.empty()) {
     SubSection Sub(WASM_SYMBOL_TABLE);
     writeUleb128(Sub.OS, SymtabEntries.size(), "num symbols");

     for (const Symbol *Sym : SymtabEntries) {
       assert(Sym->isDefined() || Sym->isUndefined());
       WasmSymbolType Kind = Sym->getWasmType();
       uint32_t Flags = getWasmFlags(Sym);

       writeU8(Sub.OS, Kind, "sym kind");
       writeUleb128(Sub.OS, Flags, "sym flags");

       if (auto *F = dyn_cast<FunctionSymbol>(Sym)) {
         writeUleb128(Sub.OS, F->getFunctionIndex(), "index");
         if (Sym->isDefined() || (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
           writeStr(Sub.OS, Sym->getName(), "sym name");
       } else if (auto *G = dyn_cast<GlobalSymbol>(Sym)) {
         writeUleb128(Sub.OS, G->getGlobalIndex(), "index");
         if (Sym->isDefined() || (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
           writeStr(Sub.OS, Sym->getName(), "sym name");
       } else if (auto *E = dyn_cast<EventSymbol>(Sym)) {
         writeUleb128(Sub.OS, E->getEventIndex(), "index");
         if (Sym->isDefined() || (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
           writeStr(Sub.OS, Sym->getName(), "sym name");
       } else if (isa<DataSymbol>(Sym)) {
         writeStr(Sub.OS, Sym->getName(), "sym name");
         if (auto *DataSym = dyn_cast<DefinedData>(Sym)) {
           writeUleb128(Sub.OS, DataSym->getOutputSegmentIndex(), "index");
           writeUleb128(Sub.OS, DataSym->getOutputSegmentOffset(),
                        "data offset");
           writeUleb128(Sub.OS, DataSym->getSize(), "data size");
         }
       } else {
         auto *S = cast<OutputSectionSymbol>(Sym);
         writeUleb128(Sub.OS, S->Section->SectionIndex, "sym section index");
       }
     }

     Sub.writeTo(OS);
   }

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

   if (!InitFunctions.empty()) {
     SubSection Sub(WASM_INIT_FUNCS);
     writeUleb128(Sub.OS, InitFunctions.size(), "num init functions");
     for (const WasmInitEntry &F : InitFunctions) {
       writeUleb128(Sub.OS, F.Priority, "priority");
       writeUleb128(Sub.OS, F.Sym->getOutputSymbolIndex(), "function index");
     }
     Sub.writeTo(OS);
   }

   struct ComdatEntry {
     unsigned Kind;
     uint32_t Index;
   };
   std::map<StringRef, std::vector<ComdatEntry>> Comdats;

   for (const InputFunction *F : Out.FunctionSec->InputFunctions) {
     StringRef Comdat = F->getComdatName();
     if (!Comdat.empty())
       Comdats[Comdat].emplace_back(
           ComdatEntry{WASM_COMDAT_FUNCTION, F->getFunctionIndex()});
   }
   for (uint32_t I = 0; I < DataSegments.size(); ++I) {
     const auto &InputSegments = DataSegments[I]->InputSegments;
     if (InputSegments.empty())
       continue;
     StringRef Comdat = InputSegments[0]->getComdatName();
 #ifndef NDEBUG
     for (const InputSegment *IS : InputSegments)
       assert(IS->getComdatName() == Comdat);
 #endif
     if (!Comdat.empty())
       Comdats[Comdat].emplace_back(ComdatEntry{WASM_COMDAT_DATA, I});
   }

   if (!Comdats.empty()) {
     SubSection Sub(WASM_COMDAT_INFO);
     writeUleb128(Sub.OS, Comdats.size(), "num comdats");
     for (const auto &C : Comdats) {
       writeStr(Sub.OS, C.first, "comdat name");
       writeUleb128(Sub.OS, 0, "comdat flags"); // flags for future use
       writeUleb128(Sub.OS, C.second.size(), "num entries");
       for (const ComdatEntry &Entry : C.second) {
         writeU8(Sub.OS, Entry.Kind, "entry kind");
         writeUleb128(Sub.OS, Entry.Index, "entry index");
       }
     }
     Sub.writeTo(OS);
   }
 }

 void LinkingSection::addToSymtab(Symbol *Sym) {
   Sym->setOutputSymbolIndex(SymtabEntries.size());
   SymtabEntries.emplace_back(Sym);
 }

 unsigned NameSection::numNames() const {
   unsigned NumNames = Out.ImportSec->numImportedFunctions();
   for (const InputFunction *F : Out.FunctionSec->InputFunctions)
     if (!F->getName().empty() || !F->getDebugName().empty())
       ++NumNames;

   return NumNames;
 }

 // Create the custom "name" section containing debug symbol names.
 void NameSection::writeBody() {
   SubSection Sub(WASM_NAMES_FUNCTION);
   writeUleb128(Sub.OS, numNames(), "name count");

   // Names must appear in function index order.  As it happens ImportedSymbols
   // and InputFunctions are numbered in order with imported functions coming
   // first.
   for (const Symbol *S : Out.ImportSec->ImportedSymbols) {
     if (auto *F = dyn_cast<FunctionSymbol>(S)) {
       writeUleb128(Sub.OS, F->getFunctionIndex(), "func index");
       writeStr(Sub.OS, toString(*S), "symbol name");
     }
   }
   for (const InputFunction *F : Out.FunctionSec->InputFunctions) {
     if (!F->getName().empty()) {
       writeUleb128(Sub.OS, F->getFunctionIndex(), "func index");
       if (!F->getDebugName().empty()) {
         writeStr(Sub.OS, F->getDebugName(), "symbol name");
       } else {
         writeStr(Sub.OS, maybeDemangleSymbol(F->getName()), "symbol name");
       }
     }
   }

   Sub.writeTo(BodyOutputStream);
 }

 void ProducersSection::addInfo(const WasmProducerInfo &Info) {
   for (auto &Producers :
        {std::make_pair(&Info.Languages, &Languages),
         std::make_pair(&Info.Tools, &Tools), std::make_pair(&Info.SDKs, &SDKs)})
     for (auto &Producer : *Producers.first)
       if (Producers.second->end() ==
           llvm::find_if(*Producers.second,
                         [&](std::pair<std::string, std::string> Seen) {
                           return Seen.first == Producer.first;
                         }))
         Producers.second->push_back(Producer);
 }

 void ProducersSection::writeBody() {
   auto &OS = BodyOutputStream;
   writeUleb128(OS, fieldCount(), "field count");
   for (auto &Field :
        {std::make_pair("language", Languages),
         std::make_pair("processed-by", Tools), std::make_pair("sdk", SDKs)}) {
     if (Field.second.empty())
       continue;
     writeStr(OS, Field.first, "field name");
     writeUleb128(OS, Field.second.size(), "number of entries");
     for (auto &Entry : Field.second) {
       writeStr(OS, Entry.first, "producer name");
       writeStr(OS, Entry.second, "producer version");
     }
   }
 }

 void TargetFeaturesSection::writeBody() {
   SmallVector<std::string, 8> Emitted(Features.begin(), Features.end());
   llvm::sort(Emitted);
   auto &OS = BodyOutputStream;
   writeUleb128(OS, Emitted.size(), "feature count");
   for (auto &Feature : Emitted) {
     writeU8(OS, WASM_FEATURE_PREFIX_USED, "feature used prefix");
     writeStr(OS, Feature, "feature name");
   }
 }

 void RelocSection::writeBody() {
   uint32_t Count = Sec->numRelocations();
   assert(Sec->SectionIndex != UINT32_MAX);
   writeUleb128(BodyOutputStream, Sec->SectionIndex, "reloc section");
   writeUleb128(BodyOutputStream, Count, "reloc count");
   Sec->writeRelocations(BodyOutputStream);
 }
	//===- SyntheticSections.cpp ----------------------------------------------===//
	//
	// 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 contains linker-synthesized sections.
	//
	//===----------------------------------------------------------------------===//

	#include "SyntheticSections.h"

	#include "InputChunks.h"
	#include "InputEvent.h"
	#include "InputGlobal.h"
	#include "OutputSegment.h"
	#include "SymbolTable.h"
	#include "llvm/Support/Path.h"

	using namespace llvm;
	using namespace llvm::wasm;

	using namespace lld;
	using namespace lld::wasm;

	OutStruct lld::wasm::Out;

	namespace {

	// Some synthetic sections (e.g. "name" and "linking") have subsections.
	// Just like the synthetic sections themselves these need to be created before
	// they can be written out (since they are preceded by their length). This
	// class is used to create subsections and then write them into the stream
	// of the parent section.
	class SubSection {
	public:
	explicit SubSection(uint32_t Type) : Type(Type) {}

	void writeTo(raw_ostream &To) {
	OS.flush();
	writeUleb128(To, Type, "subsection type");
	writeUleb128(To, Body.size(), "subsection size");
	To.write(Body.data(), Body.size());
	}

	private:
	uint32_t Type;
	std::string Body;

	public:
	raw_string_ostream OS{Body};
	};

	} // namespace

	void DylinkSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, MemSize, "MemSize");
	writeUleb128(OS, MemAlign, "MemAlign");
	writeUleb128(OS, Out.ElemSec->numEntries(), "TableSize");
	writeUleb128(OS, 0, "TableAlign");
	writeUleb128(OS, Symtab->SharedFiles.size(), "Needed");
	for (auto *SO : Symtab->SharedFiles)
	writeStr(OS, llvm::sys::path::filename(SO->getName()), "so name");
	}

	uint32_t TypeSection::registerType(const WasmSignature &Sig) {
	auto Pair = TypeIndices.insert(std::make_pair(Sig, Types.size()));
	if (Pair.second) {
	LLVM_DEBUG(llvm::dbgs() << "type " << toString(Sig) << "\n");
	Types.push_back(&Sig);
	}
	return Pair.first->second;
	}

	uint32_t TypeSection::lookupType(const WasmSignature &Sig) {
	auto It = TypeIndices.find(Sig);
	if (It == TypeIndices.end()) {
	error("type not found: " + toString(Sig));
	return 0;
	}
	return It->second;
	}

	void TypeSection::writeBody() {
	writeUleb128(BodyOutputStream, Types.size(), "type count");
	for (const WasmSignature *Sig : Types)
	writeSig(BodyOutputStream, *Sig);
	}

	uint32_t ImportSection::numImports() const {
	assert(IsSealed);
	uint32_t NumImports = ImportedSymbols.size() + GOTSymbols.size();
	if (Config->ImportMemory)
	++NumImports;
	if (Config->ImportTable)
	++NumImports;
	return NumImports;
	}

	void ImportSection::addGOTEntry(Symbol *Sym) {
	assert(!IsSealed);
	if (Sym->hasGOTIndex())
	return;
	Sym->setGOTIndex(NumImportedGlobals++);
	GOTSymbols.push_back(Sym);
	}

	void ImportSection::addImport(Symbol *Sym) {
	assert(!IsSealed);
	ImportedSymbols.emplace_back(Sym);
	if (auto *F = dyn_cast<FunctionSymbol>(Sym))
	F->setFunctionIndex(NumImportedFunctions++);
	else if (auto *G = dyn_cast<GlobalSymbol>(Sym))
	G->setGlobalIndex(NumImportedGlobals++);
	else
	cast<EventSymbol>(Sym)->setEventIndex(NumImportedEvents++);
	}

	void ImportSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

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

	if (Config->ImportMemory) {
	WasmImport Import;
	Import.Module = DefaultModule;
	Import.Field = "memory";
	Import.Kind = WASM_EXTERNAL_MEMORY;
	Import.Memory.Flags = 0;
	Import.Memory.Initial = Out.MemorySec->NumMemoryPages;
	if (Out.MemorySec->MaxMemoryPages != 0 \|\| Config->SharedMemory) {
	Import.Memory.Flags \|= WASM_LIMITS_FLAG_HAS_MAX;
	Import.Memory.Maximum = Out.MemorySec->MaxMemoryPages;
	}
	if (Config->SharedMemory)
	Import.Memory.Flags \|= WASM_LIMITS_FLAG_IS_SHARED;
	writeImport(OS, Import);
	}

	if (Config->ImportTable) {
	uint32_t TableSize = Out.ElemSec->ElemOffset + Out.ElemSec->numEntries();
	WasmImport Import;
	Import.Module = DefaultModule;
	Import.Field = FunctionTableName;
	Import.Kind = WASM_EXTERNAL_TABLE;
	Import.Table.ElemType = WASM_TYPE_FUNCREF;
	Import.Table.Limits = {0, TableSize, 0};
	writeImport(OS, Import);
	}

	for (const Symbol *Sym : ImportedSymbols) {
	WasmImport Import;
	if (auto *F = dyn_cast<UndefinedFunction>(Sym)) {
	Import.Field = F->ImportName;
	Import.Module = F->ImportModule;
	} else if (auto *G = dyn_cast<UndefinedGlobal>(Sym)) {
	Import.Field = G->ImportName;
	Import.Module = G->ImportModule;
	} else {
	Import.Field = Sym->getName();
	Import.Module = DefaultModule;
	}

	if (auto *FunctionSym = dyn_cast<FunctionSymbol>(Sym)) {
	Import.Kind = WASM_EXTERNAL_FUNCTION;
	Import.SigIndex = Out.TypeSec->lookupType(*FunctionSym->Signature);
	} else if (auto *GlobalSym = dyn_cast<GlobalSymbol>(Sym)) {
	Import.Kind = WASM_EXTERNAL_GLOBAL;
	Import.Global = *GlobalSym->getGlobalType();
	} else {
	auto *EventSym = cast<EventSymbol>(Sym);
	Import.Kind = WASM_EXTERNAL_EVENT;
	Import.Event.Attribute = EventSym->getEventType()->Attribute;
	Import.Event.SigIndex = Out.TypeSec->lookupType(*EventSym->Signature);
	}
	writeImport(OS, Import);
	}

	for (const Symbol *Sym : GOTSymbols) {
	WasmImport Import;
	Import.Kind = WASM_EXTERNAL_GLOBAL;
	Import.Global = {WASM_TYPE_I32, true};
	if (isa<DataSymbol>(Sym))
	Import.Module = "GOT.mem";
	else
	Import.Module = "GOT.func";
	Import.Field = Sym->getName();
	writeImport(OS, Import);
	}
	}

	void FunctionSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, InputFunctions.size(), "function count");
	for (const InputFunction *Func : InputFunctions)
	writeUleb128(OS, Out.TypeSec->lookupType(Func->Signature), "sig index");
	}

	void FunctionSection::addFunction(InputFunction *Func) {
	if (!Func->Live)
	return;
	uint32_t FunctionIndex =
	Out.ImportSec->numImportedFunctions() + InputFunctions.size();
	InputFunctions.emplace_back(Func);
	Func->setFunctionIndex(FunctionIndex);
	}

	void TableSection::writeBody() {
	uint32_t TableSize = Out.ElemSec->ElemOffset + Out.ElemSec->numEntries();

	raw_ostream &OS = BodyOutputStream;
	writeUleb128(OS, 1, "table count");
	WasmLimits Limits = {WASM_LIMITS_FLAG_HAS_MAX, TableSize, TableSize};
	writeTableType(OS, WasmTable{WASM_TYPE_FUNCREF, Limits});
	}

	void MemorySection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	bool HasMax = MaxMemoryPages != 0 \|\| Config->SharedMemory;
	writeUleb128(OS, 1, "memory count");
	unsigned Flags = 0;
	if (HasMax)
	Flags \|= WASM_LIMITS_FLAG_HAS_MAX;
	if (Config->SharedMemory)
	Flags \|= WASM_LIMITS_FLAG_IS_SHARED;
	writeUleb128(OS, Flags, "memory limits flags");
	writeUleb128(OS, NumMemoryPages, "initial pages");
	if (HasMax)
	writeUleb128(OS, MaxMemoryPages, "max pages");
	}

	void GlobalSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, numGlobals(), "global count");
	for (const InputGlobal *G : InputGlobals)
	writeGlobal(OS, G->Global);
	for (const DefinedData *Sym : DefinedFakeGlobals) {
	WasmGlobal Global;
	Global.Type = {WASM_TYPE_I32, false};
	Global.InitExpr.Opcode = WASM_OPCODE_I32_CONST;
	Global.InitExpr.Value.Int32 = Sym->getVirtualAddress();
	writeGlobal(OS, Global);
	}
	}

	void GlobalSection::addGlobal(InputGlobal *Global) {
	if (!Global->Live)
	return;
	uint32_t GlobalIndex =
	Out.ImportSec->numImportedGlobals() + InputGlobals.size();
	LLVM_DEBUG(dbgs() << "addGlobal: " << GlobalIndex << "\n");
	Global->setGlobalIndex(GlobalIndex);
	Out.GlobalSec->InputGlobals.push_back(Global);
	}

	void EventSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, InputEvents.size(), "event count");
	for (InputEvent *E : InputEvents) {
	E->Event.Type.SigIndex = Out.TypeSec->lookupType(E->Signature);
	writeEvent(OS, E->Event);
	}
	}

	void EventSection::addEvent(InputEvent *Event) {
	if (!Event->Live)
	return;
	uint32_t EventIndex = Out.ImportSec->numImportedEvents() + InputEvents.size();
	LLVM_DEBUG(dbgs() << "addEvent: " << EventIndex << "\n");
	Event->setEventIndex(EventIndex);
	InputEvents.push_back(Event);
	}

	void ExportSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, Exports.size(), "export count");
	for (const WasmExport &Export : Exports)
	writeExport(OS, Export);
	}

	void ElemSection::addEntry(FunctionSymbol *Sym) {
	if (Sym->hasTableIndex())
	return;
	Sym->setTableIndex(ElemOffset + IndirectFunctions.size());
	IndirectFunctions.emplace_back(Sym);
	}

	void ElemSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, 1, "segment count");
	writeUleb128(OS, 0, "table index");
	WasmInitExpr InitExpr;
	if (Config->Pic) {
	InitExpr.Opcode = WASM_OPCODE_GLOBAL_GET;
	InitExpr.Value.Global = WasmSym::TableBase->getGlobalIndex();
	} else {
	InitExpr.Opcode = WASM_OPCODE_I32_CONST;
	InitExpr.Value.Int32 = ElemOffset;
	}
	writeInitExpr(OS, InitExpr);
	writeUleb128(OS, IndirectFunctions.size(), "elem count");

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

	void DataCountSection::writeBody() {
	writeUleb128(BodyOutputStream, NumSegments, "data count");
	}

	bool DataCountSection::isNeeded() const {
	return NumSegments && Out.TargetFeaturesSec->Features.count("bulk-memory");
	}

	static uint32_t getWasmFlags(const Symbol *Sym) {
	uint32_t Flags = 0;
	if (Sym->isLocal())
	Flags \|= WASM_SYMBOL_BINDING_LOCAL;
	if (Sym->isWeak())
	Flags \|= WASM_SYMBOL_BINDING_WEAK;
	if (Sym->isHidden())
	Flags \|= WASM_SYMBOL_VISIBILITY_HIDDEN;
	if (Sym->isUndefined())
	Flags \|= WASM_SYMBOL_UNDEFINED;
	if (auto *F = dyn_cast<UndefinedFunction>(Sym)) {
	if (F->getName() != F->ImportName)
	Flags \|= WASM_SYMBOL_EXPLICIT_NAME;
	} else if (auto *G = dyn_cast<UndefinedGlobal>(Sym)) {
	if (G->getName() != G->ImportName)
	Flags \|= WASM_SYMBOL_EXPLICIT_NAME;
	}
	return Flags;
	}

	void LinkingSection::writeBody() {
	raw_ostream &OS = BodyOutputStream;

	writeUleb128(OS, WasmMetadataVersion, "Version");

	if (!SymtabEntries.empty()) {
	SubSection Sub(WASM_SYMBOL_TABLE);
	writeUleb128(Sub.OS, SymtabEntries.size(), "num symbols");

	for (const Symbol *Sym : SymtabEntries) {
	assert(Sym->isDefined() \|\| Sym->isUndefined());
	WasmSymbolType Kind = Sym->getWasmType();
	uint32_t Flags = getWasmFlags(Sym);

	writeU8(Sub.OS, Kind, "sym kind");
	writeUleb128(Sub.OS, Flags, "sym flags");

	if (auto *F = dyn_cast<FunctionSymbol>(Sym)) {
	writeUleb128(Sub.OS, F->getFunctionIndex(), "index");
	if (Sym->isDefined() \|\| (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
	writeStr(Sub.OS, Sym->getName(), "sym name");
	} else if (auto *G = dyn_cast<GlobalSymbol>(Sym)) {
	writeUleb128(Sub.OS, G->getGlobalIndex(), "index");
	if (Sym->isDefined() \|\| (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
	writeStr(Sub.OS, Sym->getName(), "sym name");
	} else if (auto *E = dyn_cast<EventSymbol>(Sym)) {
	writeUleb128(Sub.OS, E->getEventIndex(), "index");
	if (Sym->isDefined() \|\| (Flags & WASM_SYMBOL_EXPLICIT_NAME) != 0)
	writeStr(Sub.OS, Sym->getName(), "sym name");
	} else if (isa<DataSymbol>(Sym)) {
	writeStr(Sub.OS, Sym->getName(), "sym name");
	if (auto *DataSym = dyn_cast<DefinedData>(Sym)) {
	writeUleb128(Sub.OS, DataSym->getOutputSegmentIndex(), "index");
	writeUleb128(Sub.OS, DataSym->getOutputSegmentOffset(),
	"data offset");
	writeUleb128(Sub.OS, DataSym->getSize(), "data size");
	}
	} else {
	auto *S = cast<OutputSectionSymbol>(Sym);
	writeUleb128(Sub.OS, S->Section->SectionIndex, "sym section index");
	}
	}

	Sub.writeTo(OS);
	}

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

	if (!InitFunctions.empty()) {
	SubSection Sub(WASM_INIT_FUNCS);
	writeUleb128(Sub.OS, InitFunctions.size(), "num init functions");
	for (const WasmInitEntry &F : InitFunctions) {
	writeUleb128(Sub.OS, F.Priority, "priority");
	writeUleb128(Sub.OS, F.Sym->getOutputSymbolIndex(), "function index");
	}
	Sub.writeTo(OS);
	}

	struct ComdatEntry {
	unsigned Kind;
	uint32_t Index;
	};
	std::map<StringRef, std::vector<ComdatEntry>> Comdats;

	for (const InputFunction *F : Out.FunctionSec->InputFunctions) {
	StringRef Comdat = F->getComdatName();
	if (!Comdat.empty())
	Comdats[Comdat].emplace_back(
	ComdatEntry{WASM_COMDAT_FUNCTION, F->getFunctionIndex()});
	}
	for (uint32_t I = 0; I < DataSegments.size(); ++I) {
	const auto &InputSegments = DataSegments[I]->InputSegments;
	if (InputSegments.empty())
	continue;
	StringRef Comdat = InputSegments[0]->getComdatName();
	#ifndef NDEBUG
	for (const InputSegment *IS : InputSegments)
	assert(IS->getComdatName() == Comdat);
	#endif
	if (!Comdat.empty())
	Comdats[Comdat].emplace_back(ComdatEntry{WASM_COMDAT_DATA, I});
	}

	if (!Comdats.empty()) {
	SubSection Sub(WASM_COMDAT_INFO);
	writeUleb128(Sub.OS, Comdats.size(), "num comdats");
	for (const auto &C : Comdats) {
	writeStr(Sub.OS, C.first, "comdat name");
	writeUleb128(Sub.OS, 0, "comdat flags"); // flags for future use
	writeUleb128(Sub.OS, C.second.size(), "num entries");
	for (const ComdatEntry &Entry : C.second) {
	writeU8(Sub.OS, Entry.Kind, "entry kind");
	writeUleb128(Sub.OS, Entry.Index, "entry index");
	}
	}
	Sub.writeTo(OS);
	}
	}

	void LinkingSection::addToSymtab(Symbol *Sym) {
	Sym->setOutputSymbolIndex(SymtabEntries.size());
	SymtabEntries.emplace_back(Sym);
	}

	unsigned NameSection::numNames() const {
	unsigned NumNames = Out.ImportSec->numImportedFunctions();
	for (const InputFunction *F : Out.FunctionSec->InputFunctions)
	if (!F->getName().empty() \|\| !F->getDebugName().empty())
	++NumNames;

	return NumNames;
	}

	// Create the custom "name" section containing debug symbol names.
	void NameSection::writeBody() {
	SubSection Sub(WASM_NAMES_FUNCTION);
	writeUleb128(Sub.OS, numNames(), "name count");

	// Names must appear in function index order. As it happens ImportedSymbols
	// and InputFunctions are numbered in order with imported functions coming
	// first.
	for (const Symbol *S : Out.ImportSec->ImportedSymbols) {
	if (auto *F = dyn_cast<FunctionSymbol>(S)) {
	writeUleb128(Sub.OS, F->getFunctionIndex(), "func index");
	writeStr(Sub.OS, toString(*S), "symbol name");
	}
	}
	for (const InputFunction *F : Out.FunctionSec->InputFunctions) {
	if (!F->getName().empty()) {
	writeUleb128(Sub.OS, F->getFunctionIndex(), "func index");
	if (!F->getDebugName().empty()) {
	writeStr(Sub.OS, F->getDebugName(), "symbol name");
	} else {
	writeStr(Sub.OS, maybeDemangleSymbol(F->getName()), "symbol name");
	}
	}
	}

	Sub.writeTo(BodyOutputStream);
	}

	void ProducersSection::addInfo(const WasmProducerInfo &Info) {
	for (auto &Producers :
	{std::make_pair(&Info.Languages, &Languages),
	std::make_pair(&Info.Tools, &Tools), std::make_pair(&Info.SDKs, &SDKs)})
	for (auto &Producer : *Producers.first)
	if (Producers.second->end() ==
	llvm::find_if(*Producers.second,
	[&](std::pair<std::string, std::string> Seen) {
	return Seen.first == Producer.first;
	}))
	Producers.second->push_back(Producer);
	}

	void ProducersSection::writeBody() {
	auto &OS = BodyOutputStream;
	writeUleb128(OS, fieldCount(), "field count");
	for (auto &Field :
	{std::make_pair("language", Languages),
	std::make_pair("processed-by", Tools), std::make_pair("sdk", SDKs)}) {
	if (Field.second.empty())
	continue;
	writeStr(OS, Field.first, "field name");
	writeUleb128(OS, Field.second.size(), "number of entries");
	for (auto &Entry : Field.second) {
	writeStr(OS, Entry.first, "producer name");
	writeStr(OS, Entry.second, "producer version");
	}
	}
	}

	void TargetFeaturesSection::writeBody() {
	SmallVector<std::string, 8> Emitted(Features.begin(), Features.end());
	llvm::sort(Emitted);
	auto &OS = BodyOutputStream;
	writeUleb128(OS, Emitted.size(), "feature count");
	for (auto &Feature : Emitted) {
	writeU8(OS, WASM_FEATURE_PREFIX_USED, "feature used prefix");
	writeStr(OS, Feature, "feature name");
	}
	}

	void RelocSection::writeBody() {
	uint32_t Count = Sec->numRelocations();
	assert(Sec->SectionIndex != UINT32_MAX);
	writeUleb128(BodyOutputStream, Sec->SectionIndex, "reloc section");
	writeUleb128(BodyOutputStream, Count, "reloc count");
	Sec->writeRelocations(BodyOutputStream);
	}