lld/wasm/SymbolTable.cpp - external/github.com/llvm/llvm-project - Git at Google

 //===- SymbolTable.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
 //
 //===----------------------------------------------------------------------===//

 #include "SymbolTable.h"
 #include "Config.h"
 #include "InputChunks.h"
 #include "InputEvent.h"
 #include "InputGlobal.h"
 #include "WriterUtils.h"
 #include "lld/Common/ErrorHandler.h"
 #include "lld/Common/Memory.h"
 #include "llvm/ADT/SetVector.h"

 #define DEBUG_TYPE "lld"

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

 SymbolTable *lld::wasm::Symtab;

 void SymbolTable::addFile(InputFile *File) {
   log("Processing: " + toString(File));
   if (Config->Trace)
     message(toString(File));
   File->parse();

   // LLVM bitcode file
   if (auto *F = dyn_cast<BitcodeFile>(File))
     BitcodeFiles.push_back(F);
   else if (auto *F = dyn_cast<ObjFile>(File))
     ObjectFiles.push_back(F);
   else if (auto *F = dyn_cast<SharedFile>(File))
     SharedFiles.push_back(F);
 }

 // This function is where all the optimizations of link-time
 // optimization happens. When LTO is in use, some input files are
 // not in native object file format but in the LLVM bitcode format.
 // This function compiles bitcode files into a few big native files
 // using LLVM functions and replaces bitcode symbols with the results.
 // Because all bitcode files that the program consists of are passed
 // to the compiler at once, it can do whole-program optimization.
 void SymbolTable::addCombinedLTOObject() {
   if (BitcodeFiles.empty())
     return;

   // Compile bitcode files and replace bitcode symbols.
   LTO.reset(new BitcodeCompiler);
   for (BitcodeFile *F : BitcodeFiles)
     LTO->add(*F);

   for (StringRef Filename : LTO->compile()) {
     auto *Obj = make<ObjFile>(MemoryBufferRef(Filename, "lto.tmp"), "");
     Obj->parse(true);
     ObjectFiles.push_back(Obj);
   }
 }

 void SymbolTable::reportRemainingUndefines() {
   for (Symbol *Sym : SymVector) {
     if (!Sym->isUndefined() || Sym->isWeak())
       continue;
     if (Config->AllowUndefinedSymbols.count(Sym->getName()) != 0)
       continue;
     if (!Sym->IsUsedInRegularObj)
       continue;
     error(toString(Sym->getFile()) + ": undefined symbol: " + toString(*Sym));
   }
 }

 Symbol *SymbolTable::find(StringRef Name) {
   auto It = SymMap.find(CachedHashStringRef(Name));
   if (It == SymMap.end() || It->second == -1)
     return nullptr;
   return SymVector[It->second];
 }

 void SymbolTable::replace(StringRef Name, Symbol* Sym) {
   auto It = SymMap.find(CachedHashStringRef(Name));
   SymVector[It->second] = Sym;
 }

 std::pair<Symbol *, bool> SymbolTable::insertName(StringRef Name) {
   bool Trace = false;
   auto P = SymMap.insert({CachedHashStringRef(Name), (int)SymVector.size()});
   int &SymIndex = P.first->second;
   bool IsNew = P.second;
   if (SymIndex == -1) {
     SymIndex = SymVector.size();
     Trace = true;
     IsNew = true;
   }

   if (!IsNew)
     return {SymVector[SymIndex], false};

   Symbol *Sym = reinterpret_cast<Symbol *>(make<SymbolUnion>());
   Sym->IsUsedInRegularObj = false;
   Sym->Traced = Trace;
   SymVector.emplace_back(Sym);
   return {Sym, true};
 }

 std::pair<Symbol *, bool> SymbolTable::insert(StringRef Name,
                                               const InputFile *File) {
   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insertName(Name);

   if (!File || File->kind() == InputFile::ObjectKind)
     S->IsUsedInRegularObj = true;

   return {S, WasInserted};
 }

 static void reportTypeError(const Symbol *Existing, const InputFile *File,
                             llvm::wasm::WasmSymbolType Type) {
   error("symbol type mismatch: " + toString(*Existing) + "\n>>> defined as " +
         toString(Existing->getWasmType()) + " in " +
         toString(Existing->getFile()) + "\n>>> defined as " + toString(Type) +
         " in " + toString(File));
 }

 // Check the type of new symbol matches that of the symbol is replacing.
 // Returns true if the function types match, false is there is a singature
 // mismatch.
 static bool signatureMatches(FunctionSymbol *Existing,
                              const WasmSignature *NewSig) {
   if (!NewSig)
     return true;

   const WasmSignature *OldSig = Existing->Signature;
   if (!OldSig) {
     Existing->Signature = NewSig;
     return true;
   }

   return *NewSig == *OldSig;
 }

 static void checkGlobalType(const Symbol *Existing, const InputFile *File,
                             const WasmGlobalType *NewType) {
   if (!isa<GlobalSymbol>(Existing)) {
     reportTypeError(Existing, File, WASM_SYMBOL_TYPE_GLOBAL);
     return;
   }

   const WasmGlobalType *OldType = cast<GlobalSymbol>(Existing)->getGlobalType();
   if (*NewType != *OldType) {
     error("Global type mismatch: " + Existing->getName() + "\n>>> defined as " +
           toString(*OldType) + " in " + toString(Existing->getFile()) +
           "\n>>> defined as " + toString(*NewType) + " in " + toString(File));
   }
 }

 static void checkEventType(const Symbol *Existing, const InputFile *File,
                            const WasmEventType *NewType,
                            const WasmSignature *NewSig) {
   auto ExistingEvent = dyn_cast<EventSymbol>(Existing);
   if (!isa<EventSymbol>(Existing)) {
     reportTypeError(Existing, File, WASM_SYMBOL_TYPE_EVENT);
     return;
   }

   const WasmEventType *OldType = cast<EventSymbol>(Existing)->getEventType();
   const WasmSignature *OldSig = ExistingEvent->Signature;
   if (NewType->Attribute != OldType->Attribute)
     error("Event type mismatch: " + Existing->getName() + "\n>>> defined as " +
           toString(*OldType) + " in " + toString(Existing->getFile()) +
           "\n>>> defined as " + toString(*NewType) + " in " + toString(File));
   if (*NewSig != *OldSig)
     warn("Event signature mismatch: " + Existing->getName() +
          "\n>>> defined as " + toString(*OldSig) + " in " +
          toString(Existing->getFile()) + "\n>>> defined as " +
          toString(*NewSig) + " in " + toString(File));
 }

 static void checkDataType(const Symbol *Existing, const InputFile *File) {
   if (!isa<DataSymbol>(Existing))
     reportTypeError(Existing, File, WASM_SYMBOL_TYPE_DATA);
 }

 DefinedFunction *SymbolTable::addSyntheticFunction(StringRef Name,
                                                    uint32_t Flags,
                                                    InputFunction *Function) {
   LLVM_DEBUG(dbgs() << "addSyntheticFunction: " << Name << "\n");
   assert(!find(Name));
   SyntheticFunctions.emplace_back(Function);
   return replaceSymbol<DefinedFunction>(insertName(Name).first, Name,
                                         Flags, nullptr, Function);
 }

 DefinedData *SymbolTable::addSyntheticDataSymbol(StringRef Name,
                                                  uint32_t Flags) {
   LLVM_DEBUG(dbgs() << "addSyntheticDataSymbol: " << Name << "\n");
   assert(!find(Name));
   return replaceSymbol<DefinedData>(insertName(Name).first, Name, Flags);
 }

 DefinedGlobal *SymbolTable::addSyntheticGlobal(StringRef Name, uint32_t Flags,
                                                InputGlobal *Global) {
   LLVM_DEBUG(dbgs() << "addSyntheticGlobal: " << Name << " -> " << Global
                     << "\n");
   assert(!find(Name));
   SyntheticGlobals.emplace_back(Global);
   return replaceSymbol<DefinedGlobal>(insertName(Name).first, Name, Flags,
                                       nullptr, Global);
 }

 static bool shouldReplace(const Symbol *Existing, InputFile *NewFile,
                           uint32_t NewFlags) {
   // If existing symbol is undefined, replace it.
   if (!Existing->isDefined()) {
     LLVM_DEBUG(dbgs() << "resolving existing undefined symbol: "
                       << Existing->getName() << "\n");
     return true;
   }

   // Now we have two defined symbols. If the new one is weak, we can ignore it.
   if ((NewFlags & WASM_SYMBOL_BINDING_MASK) == WASM_SYMBOL_BINDING_WEAK) {
     LLVM_DEBUG(dbgs() << "existing symbol takes precedence\n");
     return false;
   }

   // If the existing symbol is weak, we should replace it.
   if (Existing->isWeak()) {
     LLVM_DEBUG(dbgs() << "replacing existing weak symbol\n");
     return true;
   }

   // Neither symbol is week. They conflict.
   error("duplicate symbol: " + toString(*Existing) + "\n>>> defined in " +
         toString(Existing->getFile()) + "\n>>> defined in " +
         toString(NewFile));
   return true;
 }

 Symbol *SymbolTable::addDefinedFunction(StringRef Name, uint32_t Flags,
                                         InputFile *File,
                                         InputFunction *Function) {
   LLVM_DEBUG(dbgs() << "addDefinedFunction: " << Name << " ["
                     << (Function ? toString(Function->Signature) : "none")
                     << "]\n");
   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   auto Replace = [&](Symbol* Sym) {
     // If the new defined function doesn't have signture (i.e. bitcode
     // functions) but the old symbol does, then preserve the old signature
     const WasmSignature *OldSig = S->getSignature();
     auto* NewSym = replaceSymbol<DefinedFunction>(Sym, Name, Flags, File, Function);
     if (!NewSym->Signature)
       NewSym->Signature = OldSig;
   };

   if (WasInserted || S->isLazy()) {
     Replace(S);
     return S;
   }

   auto ExistingFunction = dyn_cast<FunctionSymbol>(S);
   if (!ExistingFunction) {
     reportTypeError(S, File, WASM_SYMBOL_TYPE_FUNCTION);
     return S;
   }

   if (Function && !signatureMatches(ExistingFunction, &Function->Signature)) {
     Symbol* Variant;
     if (getFunctionVariant(S, &Function->Signature, File, &Variant))
       // New variant, always replace
       Replace(Variant);
     else if (shouldReplace(S, File, Flags))
       // Variant already exists, replace it after checking shouldReplace
       Replace(Variant);

     // This variant we found take the place in the symbol table as the primary
     // variant.
     replace(Name, Variant);
     return Variant;
   }

   // Existing function with matching signature.
   if (shouldReplace(S, File, Flags))
     Replace(S);

   return S;
 }

 Symbol *SymbolTable::addDefinedData(StringRef Name, uint32_t Flags,
                                     InputFile *File, InputSegment *Segment,
                                     uint32_t Address, uint32_t Size) {
   LLVM_DEBUG(dbgs() << "addDefinedData:" << Name << " addr:" << Address
                     << "\n");
   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   auto Replace = [&]() {
     replaceSymbol<DefinedData>(S, Name, Flags, File, Segment, Address, Size);
   };

   if (WasInserted || S->isLazy()) {
     Replace();
     return S;
   }

   checkDataType(S, File);

   if (shouldReplace(S, File, Flags))
     Replace();
   return S;
 }

 Symbol *SymbolTable::addDefinedGlobal(StringRef Name, uint32_t Flags,
                                       InputFile *File, InputGlobal *Global) {
   LLVM_DEBUG(dbgs() << "addDefinedGlobal:" << Name << "\n");

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   auto Replace = [&]() {
     replaceSymbol<DefinedGlobal>(S, Name, Flags, File, Global);
   };

   if (WasInserted || S->isLazy()) {
     Replace();
     return S;
   }

   checkGlobalType(S, File, &Global->getType());

   if (shouldReplace(S, File, Flags))
     Replace();
   return S;
 }

 Symbol *SymbolTable::addDefinedEvent(StringRef Name, uint32_t Flags,
                                      InputFile *File, InputEvent *Event) {
   LLVM_DEBUG(dbgs() << "addDefinedEvent:" << Name << "\n");

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   auto Replace = [&]() {
     replaceSymbol<DefinedEvent>(S, Name, Flags, File, Event);
   };

   if (WasInserted || S->isLazy()) {
     Replace();
     return S;
   }

   checkEventType(S, File, &Event->getType(), &Event->Signature);

   if (shouldReplace(S, File, Flags))
     Replace();
   return S;
 }

 Symbol *SymbolTable::addUndefinedFunction(StringRef Name, StringRef ImportName,
                                           StringRef ImportModule,
                                           uint32_t Flags, InputFile *File,
                                           const WasmSignature *Sig) {
   LLVM_DEBUG(dbgs() << "addUndefinedFunction: " << Name <<
              " [" << (Sig ? toString(*Sig) : "none") << "]\n");

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   auto Replace = [&]() {
     replaceSymbol<UndefinedFunction>(S, Name, ImportName, ImportModule, Flags,
                                      File, Sig);
   };

   if (WasInserted)
     Replace();
   else if (auto *Lazy = dyn_cast<LazySymbol>(S))
     Lazy->fetch();
   else {
     auto ExistingFunction = dyn_cast<FunctionSymbol>(S);
     if (!ExistingFunction) {
       reportTypeError(S, File, WASM_SYMBOL_TYPE_FUNCTION);
       return S;
     }
     if (!signatureMatches(ExistingFunction, Sig))
       if (getFunctionVariant(S, Sig, File, &S))
         Replace();
   }

   return S;
 }

 Symbol *SymbolTable::addUndefinedData(StringRef Name, uint32_t Flags,
                                       InputFile *File) {
   LLVM_DEBUG(dbgs() << "addUndefinedData: " << Name << "\n");

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   if (WasInserted)
     replaceSymbol<UndefinedData>(S, Name, Flags, File);
   else if (auto *Lazy = dyn_cast<LazySymbol>(S))
     Lazy->fetch();
   else if (S->isDefined())
     checkDataType(S, File);
   return S;
 }

 Symbol *SymbolTable::addUndefinedGlobal(StringRef Name, StringRef ImportName,
                                         StringRef ImportModule, uint32_t Flags,
                                         InputFile *File,
                                         const WasmGlobalType *Type) {
   LLVM_DEBUG(dbgs() << "addUndefinedGlobal: " << Name << "\n");

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insert(Name, File);

   if (WasInserted)
     replaceSymbol<UndefinedGlobal>(S, Name, ImportName, ImportModule, Flags,
                                    File, Type);
   else if (auto *Lazy = dyn_cast<LazySymbol>(S))
     Lazy->fetch();
   else if (S->isDefined())
     checkGlobalType(S, File, Type);
   return S;
 }

 void SymbolTable::addLazy(ArchiveFile *File, const Archive::Symbol *Sym) {
   LLVM_DEBUG(dbgs() << "addLazy: " << Sym->getName() << "\n");
   StringRef Name = Sym->getName();

   Symbol *S;
   bool WasInserted;
   std::tie(S, WasInserted) = insertName(Name);

   if (WasInserted) {
     replaceSymbol<LazySymbol>(S, Name, 0, File, *Sym);
     return;
   }

   if (!S->isUndefined())
     return;

   // The existing symbol is undefined, load a new one from the archive,
   // unless the the existing symbol is weak in which case replace the undefined
   // symbols with a LazySymbol.
   if (S->isWeak()) {
     const WasmSignature *OldSig = nullptr;
     // In the case of an UndefinedFunction we need to preserve the expected
     // signature.
     if (auto *F = dyn_cast<UndefinedFunction>(S))
       OldSig = F->Signature;
     LLVM_DEBUG(dbgs() << "replacing existing weak undefined symbol\n");
     auto NewSym = replaceSymbol<LazySymbol>(S, Name, WASM_SYMBOL_BINDING_WEAK,
                                             File, *Sym);
     NewSym->Signature = OldSig;
     return;
   }

   LLVM_DEBUG(dbgs() << "replacing existing undefined\n");
   File->addMember(Sym);
 }

 bool SymbolTable::addComdat(StringRef Name) {
   return ComdatGroups.insert(CachedHashStringRef(Name)).second;
 }

 // The new signature doesn't match.  Create a variant to the symbol with the
 // signature encoded in the name and return that instead.  These symbols are
 // then unified later in handleSymbolVariants.
 bool SymbolTable::getFunctionVariant(Symbol* Sym, const WasmSignature *Sig,
                                      const InputFile *File, Symbol **Out) {
   LLVM_DEBUG(dbgs() << "getFunctionVariant: " << Sym->getName() << " -> "
                     << " " << toString(*Sig) << "\n");
   Symbol *Variant = nullptr;

   // Linear search through symbol variants.  Should never be more than two
   // or three entries here.
   auto &Variants = SymVariants[CachedHashStringRef(Sym->getName())];
   if (Variants.empty())
     Variants.push_back(Sym);

   for (Symbol* V : Variants) {
     if (*V->getSignature() == *Sig) {
       Variant = V;
       break;
     }
   }

   bool WasAdded = !Variant;
   if (WasAdded) {
     // Create a new variant;
     LLVM_DEBUG(dbgs() << "added new variant\n");
     Variant = reinterpret_cast<Symbol *>(make<SymbolUnion>());
     Variants.push_back(Variant);
   } else {
     LLVM_DEBUG(dbgs() << "variant already exists: " << toString(*Variant) << "\n");
     assert(*Variant->getSignature() == *Sig);
   }

   *Out = Variant;
   return WasAdded;
 }

 // Set a flag for --trace-symbol so that we can print out a log message
 // if a new symbol with the same name is inserted into the symbol table.
 void SymbolTable::trace(StringRef Name) {
   SymMap.insert({CachedHashStringRef(Name), -1});
 }

 static const uint8_t UnreachableFn[] = {
     0x03 /* ULEB length */, 0x00 /* ULEB num locals */,
     0x00 /* opcode unreachable */, 0x0b /* opcode end */
 };

 // Replace the given symbol body with an unreachable function.
 // This is used by handleWeakUndefines in order to generate a callable
 // equivalent of an undefined function and also handleSymbolVariants for
 // undefined functions that don't match the signature of the definition.
 InputFunction *SymbolTable::replaceWithUnreachable(Symbol *Sym,
                                                    const WasmSignature &Sig,
                                                    StringRef DebugName) {
   auto *Func = make<SyntheticFunction>(Sig, Sym->getName(), DebugName);
   Func->setBody(UnreachableFn);
   SyntheticFunctions.emplace_back(Func);
   replaceSymbol<DefinedFunction>(Sym, Sym->getName(), Sym->getFlags(), nullptr,
                                  Func);
   return Func;
 }

 // For weak undefined functions, there may be "call" instructions that reference
 // the symbol. In this case, we need to synthesise a dummy/stub function that
 // will abort at runtime, so that relocations can still provided an operand to
 // the call instruction that passes Wasm validation.
 void SymbolTable::handleWeakUndefines() {
   for (Symbol *Sym : getSymbols()) {
     if (!Sym->isUndefWeak())
       continue;

     const WasmSignature *Sig = Sym->getSignature();
     if (!Sig) {
       // It is possible for undefined functions not to have a signature (eg. if
       // added via "--undefined"), but weak undefined ones do have a signature.
       // Lazy symbols may not be functions and therefore Sig can still be null
       // in some circumstantce.
       assert(!isa<FunctionSymbol>(Sym));
       continue;
     }

     // Add a synthetic dummy for weak undefined functions.  These dummies will
     // be GC'd if not used as the target of any "call" instructions.
     StringRef DebugName = Saver.save("undefined:" + toString(*Sym));
     InputFunction* Func = replaceWithUnreachable(Sym, *Sig, DebugName);
     // Ensure it compares equal to the null pointer, and so that table relocs
     // don't pull in the stub body (only call-operand relocs should do that).
     Func->setTableIndex(0);
     // Hide our dummy to prevent export.
     Sym->setHidden(true);
   }
 }

 static void reportFunctionSignatureMismatch(StringRef SymName,
                                             FunctionSymbol *A,
                                             FunctionSymbol *B, bool Error) {
   std::string msg = ("function signature mismatch: " + SymName +
                      "\n>>> defined as " + toString(*A->Signature) + " in " +
                      toString(A->getFile()) + "\n>>> defined as " +
                      toString(*B->Signature) + " in " + toString(B->getFile()))
                         .str();
   if (Error)
     error(msg);
   else
     warn(msg);
 }

 // Remove any variant symbols that were created due to function signature
 // mismatches.
 void SymbolTable::handleSymbolVariants() {
   for (auto Pair : SymVariants) {
     // Push the initial symbol onto the list of variants.
     StringRef SymName = Pair.first.val();
     std::vector<Symbol *> &Variants = Pair.second;

 #ifndef NDEBUG
     LLVM_DEBUG(dbgs() << "symbol with (" << Variants.size()
                       << ") variants: " << SymName << "\n");
     for (auto *S: Variants) {
       auto *F = cast<FunctionSymbol>(S);
       LLVM_DEBUG(dbgs() << " variant: " + F->getName() << " "
                         << toString(*F->Signature) << "\n");
     }
 #endif

     // Find the one definition.
     DefinedFunction *Defined = nullptr;
     for (auto *Symbol : Variants) {
       if (auto F = dyn_cast<DefinedFunction>(Symbol)) {
         Defined = F;
         break;
       }
     }

     // If there are no definitions, and the undefined symbols disagree on
     // the signature, there is not we can do since we don't know which one
     // to use as the signature on the import.
     if (!Defined) {
       reportFunctionSignatureMismatch(SymName,
                                       cast<FunctionSymbol>(Variants[0]),
                                       cast<FunctionSymbol>(Variants[1]), true);
       return;
     }

     for (auto *Symbol : Variants) {
       if (Symbol != Defined) {
         auto *F = cast<FunctionSymbol>(Symbol);
         reportFunctionSignatureMismatch(SymName, F, Defined, false);
         StringRef DebugName = Saver.save("unreachable:" + toString(*F));
         replaceWithUnreachable(F, *F->Signature, DebugName);
       }
     }
   }
 }
	//===- SymbolTable.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
	//
	//===----------------------------------------------------------------------===//

	#include "SymbolTable.h"
	#include "Config.h"
	#include "InputChunks.h"
	#include "InputEvent.h"
	#include "InputGlobal.h"
	#include "WriterUtils.h"
	#include "lld/Common/ErrorHandler.h"
	#include "lld/Common/Memory.h"
	#include "llvm/ADT/SetVector.h"

	#define DEBUG_TYPE "lld"

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

	SymbolTable *lld::wasm::Symtab;

	void SymbolTable::addFile(InputFile *File) {
	log("Processing: " + toString(File));
	if (Config->Trace)
	message(toString(File));
	File->parse();

	// LLVM bitcode file
	if (auto *F = dyn_cast<BitcodeFile>(File))
	BitcodeFiles.push_back(F);
	else if (auto *F = dyn_cast<ObjFile>(File))
	ObjectFiles.push_back(F);
	else if (auto *F = dyn_cast<SharedFile>(File))
	SharedFiles.push_back(F);
	}

	// This function is where all the optimizations of link-time
	// optimization happens. When LTO is in use, some input files are
	// not in native object file format but in the LLVM bitcode format.
	// This function compiles bitcode files into a few big native files
	// using LLVM functions and replaces bitcode symbols with the results.
	// Because all bitcode files that the program consists of are passed
	// to the compiler at once, it can do whole-program optimization.
	void SymbolTable::addCombinedLTOObject() {
	if (BitcodeFiles.empty())
	return;

	// Compile bitcode files and replace bitcode symbols.
	LTO.reset(new BitcodeCompiler);
	for (BitcodeFile *F : BitcodeFiles)
	LTO->add(*F);

	for (StringRef Filename : LTO->compile()) {
	auto *Obj = make<ObjFile>(MemoryBufferRef(Filename, "lto.tmp"), "");
	Obj->parse(true);
	ObjectFiles.push_back(Obj);
	}
	}

	void SymbolTable::reportRemainingUndefines() {
	for (Symbol *Sym : SymVector) {
	if (!Sym->isUndefined() \|\| Sym->isWeak())
	continue;
	if (Config->AllowUndefinedSymbols.count(Sym->getName()) != 0)
	continue;
	if (!Sym->IsUsedInRegularObj)
	continue;
	error(toString(Sym->getFile()) + ": undefined symbol: " + toString(*Sym));
	}
	}

	Symbol *SymbolTable::find(StringRef Name) {
	auto It = SymMap.find(CachedHashStringRef(Name));
	if (It == SymMap.end() \|\| It->second == -1)
	return nullptr;
	return SymVector[It->second];
	}

	void SymbolTable::replace(StringRef Name, Symbol* Sym) {
	auto It = SymMap.find(CachedHashStringRef(Name));
	SymVector[It->second] = Sym;
	}

	std::pair<Symbol *, bool> SymbolTable::insertName(StringRef Name) {
	bool Trace = false;
	auto P = SymMap.insert({CachedHashStringRef(Name), (int)SymVector.size()});
	int &SymIndex = P.first->second;
	bool IsNew = P.second;
	if (SymIndex == -1) {
	SymIndex = SymVector.size();
	Trace = true;
	IsNew = true;
	}

	if (!IsNew)
	return {SymVector[SymIndex], false};

	Symbol Sym = reinterpret_cast<Symbol >(make<SymbolUnion>());
	Sym->IsUsedInRegularObj = false;
	Sym->Traced = Trace;
	SymVector.emplace_back(Sym);
	return {Sym, true};
	}

	std::pair<Symbol *, bool> SymbolTable::insert(StringRef Name,
	const InputFile *File) {
	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insertName(Name);

	if (!File \|\| File->kind() == InputFile::ObjectKind)
	S->IsUsedInRegularObj = true;

	return {S, WasInserted};
	}

	static void reportTypeError(const Symbol Existing, const InputFile File,
	llvm::wasm::WasmSymbolType Type) {
	error("symbol type mismatch: " + toString(*Existing) + "\n>>> defined as " +
	toString(Existing->getWasmType()) + " in " +
	toString(Existing->getFile()) + "\n>>> defined as " + toString(Type) +
	" in " + toString(File));
	}

	// Check the type of new symbol matches that of the symbol is replacing.
	// Returns true if the function types match, false is there is a singature
	// mismatch.
	static bool signatureMatches(FunctionSymbol *Existing,
	const WasmSignature *NewSig) {
	if (!NewSig)
	return true;

	const WasmSignature *OldSig = Existing->Signature;
	if (!OldSig) {
	Existing->Signature = NewSig;
	return true;
	}

	return NewSig == OldSig;
	}

	static void checkGlobalType(const Symbol Existing, const InputFile File,
	const WasmGlobalType *NewType) {
	if (!isa<GlobalSymbol>(Existing)) {
	reportTypeError(Existing, File, WASM_SYMBOL_TYPE_GLOBAL);
	return;
	}

	const WasmGlobalType *OldType = cast<GlobalSymbol>(Existing)->getGlobalType();
	if (NewType != OldType) {
	error("Global type mismatch: " + Existing->getName() + "\n>>> defined as " +
	toString(*OldType) + " in " + toString(Existing->getFile()) +
	"\n>>> defined as " + toString(*NewType) + " in " + toString(File));
	}
	}

	static void checkEventType(const Symbol Existing, const InputFile File,
	const WasmEventType *NewType,
	const WasmSignature *NewSig) {
	auto ExistingEvent = dyn_cast<EventSymbol>(Existing);
	if (!isa<EventSymbol>(Existing)) {
	reportTypeError(Existing, File, WASM_SYMBOL_TYPE_EVENT);
	return;
	}

	const WasmEventType *OldType = cast<EventSymbol>(Existing)->getEventType();
	const WasmSignature *OldSig = ExistingEvent->Signature;
	if (NewType->Attribute != OldType->Attribute)
	error("Event type mismatch: " + Existing->getName() + "\n>>> defined as " +
	toString(*OldType) + " in " + toString(Existing->getFile()) +
	"\n>>> defined as " + toString(*NewType) + " in " + toString(File));
	if (NewSig != OldSig)
	warn("Event signature mismatch: " + Existing->getName() +
	"\n>>> defined as " + toString(*OldSig) + " in " +
	toString(Existing->getFile()) + "\n>>> defined as " +
	toString(*NewSig) + " in " + toString(File));
	}

	static void checkDataType(const Symbol Existing, const InputFile File) {
	if (!isa<DataSymbol>(Existing))
	reportTypeError(Existing, File, WASM_SYMBOL_TYPE_DATA);
	}

	DefinedFunction *SymbolTable::addSyntheticFunction(StringRef Name,
	uint32_t Flags,
	InputFunction *Function) {
	LLVM_DEBUG(dbgs() << "addSyntheticFunction: " << Name << "\n");
	assert(!find(Name));
	SyntheticFunctions.emplace_back(Function);
	return replaceSymbol<DefinedFunction>(insertName(Name).first, Name,
	Flags, nullptr, Function);
	}

	DefinedData *SymbolTable::addSyntheticDataSymbol(StringRef Name,
	uint32_t Flags) {
	LLVM_DEBUG(dbgs() << "addSyntheticDataSymbol: " << Name << "\n");
	assert(!find(Name));
	return replaceSymbol<DefinedData>(insertName(Name).first, Name, Flags);
	}

	DefinedGlobal *SymbolTable::addSyntheticGlobal(StringRef Name, uint32_t Flags,
	InputGlobal *Global) {
	LLVM_DEBUG(dbgs() << "addSyntheticGlobal: " << Name << " -> " << Global
	<< "\n");
	assert(!find(Name));
	SyntheticGlobals.emplace_back(Global);
	return replaceSymbol<DefinedGlobal>(insertName(Name).first, Name, Flags,
	nullptr, Global);
	}

	static bool shouldReplace(const Symbol Existing, InputFile NewFile,
	uint32_t NewFlags) {
	// If existing symbol is undefined, replace it.
	if (!Existing->isDefined()) {
	LLVM_DEBUG(dbgs() << "resolving existing undefined symbol: "
	<< Existing->getName() << "\n");
	return true;
	}

	// Now we have two defined symbols. If the new one is weak, we can ignore it.
	if ((NewFlags & WASM_SYMBOL_BINDING_MASK) == WASM_SYMBOL_BINDING_WEAK) {
	LLVM_DEBUG(dbgs() << "existing symbol takes precedence\n");
	return false;
	}

	// If the existing symbol is weak, we should replace it.
	if (Existing->isWeak()) {
	LLVM_DEBUG(dbgs() << "replacing existing weak symbol\n");
	return true;
	}

	// Neither symbol is week. They conflict.
	error("duplicate symbol: " + toString(*Existing) + "\n>>> defined in " +
	toString(Existing->getFile()) + "\n>>> defined in " +
	toString(NewFile));
	return true;
	}

	Symbol *SymbolTable::addDefinedFunction(StringRef Name, uint32_t Flags,
	InputFile *File,
	InputFunction *Function) {
	LLVM_DEBUG(dbgs() << "addDefinedFunction: " << Name << " ["
	<< (Function ? toString(Function->Signature) : "none")
	<< "]\n");
	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	auto Replace = [&](Symbol* Sym) {
	// If the new defined function doesn't have signture (i.e. bitcode
	// functions) but the old symbol does, then preserve the old signature
	const WasmSignature *OldSig = S->getSignature();
	auto* NewSym = replaceSymbol<DefinedFunction>(Sym, Name, Flags, File, Function);
	if (!NewSym->Signature)
	NewSym->Signature = OldSig;
	};

	if (WasInserted \|\| S->isLazy()) {
	Replace(S);
	return S;
	}

	auto ExistingFunction = dyn_cast<FunctionSymbol>(S);
	if (!ExistingFunction) {
	reportTypeError(S, File, WASM_SYMBOL_TYPE_FUNCTION);
	return S;
	}

	if (Function && !signatureMatches(ExistingFunction, &Function->Signature)) {
	Symbol* Variant;
	if (getFunctionVariant(S, &Function->Signature, File, &Variant))
	// New variant, always replace
	Replace(Variant);
	else if (shouldReplace(S, File, Flags))
	// Variant already exists, replace it after checking shouldReplace
	Replace(Variant);

	// This variant we found take the place in the symbol table as the primary
	// variant.
	replace(Name, Variant);
	return Variant;
	}

	// Existing function with matching signature.
	if (shouldReplace(S, File, Flags))
	Replace(S);

	return S;
	}

	Symbol *SymbolTable::addDefinedData(StringRef Name, uint32_t Flags,
	InputFile File, InputSegment Segment,
	uint32_t Address, uint32_t Size) {
	LLVM_DEBUG(dbgs() << "addDefinedData:" << Name << " addr:" << Address
	<< "\n");
	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	auto Replace = [&]() {
	replaceSymbol<DefinedData>(S, Name, Flags, File, Segment, Address, Size);
	};

	if (WasInserted \|\| S->isLazy()) {
	Replace();
	return S;
	}

	checkDataType(S, File);

	if (shouldReplace(S, File, Flags))
	Replace();
	return S;
	}

	Symbol *SymbolTable::addDefinedGlobal(StringRef Name, uint32_t Flags,
	InputFile File, InputGlobal Global) {
	LLVM_DEBUG(dbgs() << "addDefinedGlobal:" << Name << "\n");

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	auto Replace = [&]() {
	replaceSymbol<DefinedGlobal>(S, Name, Flags, File, Global);
	};

	if (WasInserted \|\| S->isLazy()) {
	Replace();
	return S;
	}

	checkGlobalType(S, File, &Global->getType());

	if (shouldReplace(S, File, Flags))
	Replace();
	return S;
	}

	Symbol *SymbolTable::addDefinedEvent(StringRef Name, uint32_t Flags,
	InputFile File, InputEvent Event) {
	LLVM_DEBUG(dbgs() << "addDefinedEvent:" << Name << "\n");

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	auto Replace = [&]() {
	replaceSymbol<DefinedEvent>(S, Name, Flags, File, Event);
	};

	if (WasInserted \|\| S->isLazy()) {
	Replace();
	return S;
	}

	checkEventType(S, File, &Event->getType(), &Event->Signature);

	if (shouldReplace(S, File, Flags))
	Replace();
	return S;
	}

	Symbol *SymbolTable::addUndefinedFunction(StringRef Name, StringRef ImportName,
	StringRef ImportModule,
	uint32_t Flags, InputFile *File,
	const WasmSignature *Sig) {
	LLVM_DEBUG(dbgs() << "addUndefinedFunction: " << Name <<
	" [" << (Sig ? toString(*Sig) : "none") << "]\n");

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	auto Replace = [&]() {
	replaceSymbol<UndefinedFunction>(S, Name, ImportName, ImportModule, Flags,
	File, Sig);
	};

	if (WasInserted)
	Replace();
	else if (auto *Lazy = dyn_cast<LazySymbol>(S))
	Lazy->fetch();
	else {
	auto ExistingFunction = dyn_cast<FunctionSymbol>(S);
	if (!ExistingFunction) {
	reportTypeError(S, File, WASM_SYMBOL_TYPE_FUNCTION);
	return S;
	}
	if (!signatureMatches(ExistingFunction, Sig))
	if (getFunctionVariant(S, Sig, File, &S))
	Replace();
	}

	return S;
	}

	Symbol *SymbolTable::addUndefinedData(StringRef Name, uint32_t Flags,
	InputFile *File) {
	LLVM_DEBUG(dbgs() << "addUndefinedData: " << Name << "\n");

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	if (WasInserted)
	replaceSymbol<UndefinedData>(S, Name, Flags, File);
	else if (auto *Lazy = dyn_cast<LazySymbol>(S))
	Lazy->fetch();
	else if (S->isDefined())
	checkDataType(S, File);
	return S;
	}

	Symbol *SymbolTable::addUndefinedGlobal(StringRef Name, StringRef ImportName,
	StringRef ImportModule, uint32_t Flags,
	InputFile *File,
	const WasmGlobalType *Type) {
	LLVM_DEBUG(dbgs() << "addUndefinedGlobal: " << Name << "\n");

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insert(Name, File);

	if (WasInserted)
	replaceSymbol<UndefinedGlobal>(S, Name, ImportName, ImportModule, Flags,
	File, Type);
	else if (auto *Lazy = dyn_cast<LazySymbol>(S))
	Lazy->fetch();
	else if (S->isDefined())
	checkGlobalType(S, File, Type);
	return S;
	}

	void SymbolTable::addLazy(ArchiveFile File, const Archive::Symbol Sym) {
	LLVM_DEBUG(dbgs() << "addLazy: " << Sym->getName() << "\n");
	StringRef Name = Sym->getName();

	Symbol *S;
	bool WasInserted;
	std::tie(S, WasInserted) = insertName(Name);

	if (WasInserted) {
	replaceSymbol<LazySymbol>(S, Name, 0, File, *Sym);
	return;
	}

	if (!S->isUndefined())
	return;

	// The existing symbol is undefined, load a new one from the archive,
	// unless the the existing symbol is weak in which case replace the undefined
	// symbols with a LazySymbol.
	if (S->isWeak()) {
	const WasmSignature *OldSig = nullptr;
	// In the case of an UndefinedFunction we need to preserve the expected
	// signature.
	if (auto *F = dyn_cast<UndefinedFunction>(S))
	OldSig = F->Signature;
	LLVM_DEBUG(dbgs() << "replacing existing weak undefined symbol\n");
	auto NewSym = replaceSymbol<LazySymbol>(S, Name, WASM_SYMBOL_BINDING_WEAK,
	File, *Sym);
	NewSym->Signature = OldSig;
	return;
	}

	LLVM_DEBUG(dbgs() << "replacing existing undefined\n");
	File->addMember(Sym);
	}

	bool SymbolTable::addComdat(StringRef Name) {
	return ComdatGroups.insert(CachedHashStringRef(Name)).second;
	}

	// The new signature doesn't match. Create a variant to the symbol with the
	// signature encoded in the name and return that instead. These symbols are
	// then unified later in handleSymbolVariants.
	bool SymbolTable::getFunctionVariant(Symbol* Sym, const WasmSignature *Sig,
	const InputFile File, Symbol *Out) {
	LLVM_DEBUG(dbgs() << "getFunctionVariant: " << Sym->getName() << " -> "
	<< " " << toString(*Sig) << "\n");
	Symbol *Variant = nullptr;

	// Linear search through symbol variants. Should never be more than two
	// or three entries here.
	auto &Variants = SymVariants[CachedHashStringRef(Sym->getName())];
	if (Variants.empty())
	Variants.push_back(Sym);

	for (Symbol* V : Variants) {
	if (V->getSignature() == Sig) {
	Variant = V;
	break;
	}
	}

	bool WasAdded = !Variant;
	if (WasAdded) {
	// Create a new variant;
	LLVM_DEBUG(dbgs() << "added new variant\n");
	Variant = reinterpret_cast<Symbol *>(make<SymbolUnion>());
	Variants.push_back(Variant);
	} else {
	LLVM_DEBUG(dbgs() << "variant already exists: " << toString(*Variant) << "\n");
	assert(Variant->getSignature() == Sig);
	}

	*Out = Variant;
	return WasAdded;
	}

	// Set a flag for --trace-symbol so that we can print out a log message
	// if a new symbol with the same name is inserted into the symbol table.
	void SymbolTable::trace(StringRef Name) {
	SymMap.insert({CachedHashStringRef(Name), -1});
	}

	static const uint8_t UnreachableFn[] = {
	0x03 /* ULEB length /, 0x00 / ULEB num locals */,
	0x00 /* opcode unreachable /, 0x0b / opcode end */
	};

	// Replace the given symbol body with an unreachable function.
	// This is used by handleWeakUndefines in order to generate a callable
	// equivalent of an undefined function and also handleSymbolVariants for
	// undefined functions that don't match the signature of the definition.
	InputFunction SymbolTable::replaceWithUnreachable(Symbol Sym,
	const WasmSignature &Sig,
	StringRef DebugName) {
	auto *Func = make<SyntheticFunction>(Sig, Sym->getName(), DebugName);
	Func->setBody(UnreachableFn);
	SyntheticFunctions.emplace_back(Func);
	replaceSymbol<DefinedFunction>(Sym, Sym->getName(), Sym->getFlags(), nullptr,
	Func);
	return Func;
	}

	// For weak undefined functions, there may be "call" instructions that reference
	// the symbol. In this case, we need to synthesise a dummy/stub function that
	// will abort at runtime, so that relocations can still provided an operand to
	// the call instruction that passes Wasm validation.
	void SymbolTable::handleWeakUndefines() {
	for (Symbol *Sym : getSymbols()) {
	if (!Sym->isUndefWeak())
	continue;

	const WasmSignature *Sig = Sym->getSignature();
	if (!Sig) {
	// It is possible for undefined functions not to have a signature (eg. if
	// added via "--undefined"), but weak undefined ones do have a signature.
	// Lazy symbols may not be functions and therefore Sig can still be null
	// in some circumstantce.
	assert(!isa<FunctionSymbol>(Sym));
	continue;
	}

	// Add a synthetic dummy for weak undefined functions. These dummies will
	// be GC'd if not used as the target of any "call" instructions.
	StringRef DebugName = Saver.save("undefined:" + toString(*Sym));
	InputFunction* Func = replaceWithUnreachable(Sym, *Sig, DebugName);
	// Ensure it compares equal to the null pointer, and so that table relocs
	// don't pull in the stub body (only call-operand relocs should do that).
	Func->setTableIndex(0);
	// Hide our dummy to prevent export.
	Sym->setHidden(true);
	}
	}

	static void reportFunctionSignatureMismatch(StringRef SymName,
	FunctionSymbol *A,
	FunctionSymbol *B, bool Error) {
	std::string msg = ("function signature mismatch: " + SymName +
	"\n>>> defined as " + toString(*A->Signature) + " in " +
	toString(A->getFile()) + "\n>>> defined as " +
	toString(*B->Signature) + " in " + toString(B->getFile()))
	.str();
	if (Error)
	error(msg);
	else
	warn(msg);
	}

	// Remove any variant symbols that were created due to function signature
	// mismatches.
	void SymbolTable::handleSymbolVariants() {
	for (auto Pair : SymVariants) {
	// Push the initial symbol onto the list of variants.
	StringRef SymName = Pair.first.val();
	std::vector<Symbol *> &Variants = Pair.second;

	#ifndef NDEBUG
	LLVM_DEBUG(dbgs() << "symbol with (" << Variants.size()
	<< ") variants: " << SymName << "\n");
	for (auto *S: Variants) {
	auto *F = cast<FunctionSymbol>(S);
	LLVM_DEBUG(dbgs() << " variant: " + F->getName() << " "
	<< toString(*F->Signature) << "\n");
	}
	#endif

	// Find the one definition.
	DefinedFunction *Defined = nullptr;
	for (auto *Symbol : Variants) {
	if (auto F = dyn_cast<DefinedFunction>(Symbol)) {
	Defined = F;
	break;
	}
	}

	// If there are no definitions, and the undefined symbols disagree on
	// the signature, there is not we can do since we don't know which one
	// to use as the signature on the import.
	if (!Defined) {
	reportFunctionSignatureMismatch(SymName,
	cast<FunctionSymbol>(Variants[0]),
	cast<FunctionSymbol>(Variants[1]), true);
	return;
	}

	for (auto *Symbol : Variants) {
	if (Symbol != Defined) {
	auto *F = cast<FunctionSymbol>(Symbol);
	reportFunctionSignatureMismatch(SymName, F, Defined, false);
	StringRef DebugName = Saver.save("unreachable:" + toString(*F));
	replaceWithUnreachable(F, *F->Signature, DebugName);
	}
	}
	}
	}