lld/ELF/SymbolTable.cpp - third_party/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
 //
 //===----------------------------------------------------------------------===//
 //
 // Symbol table is a bag of all known symbols. We put all symbols of
 // all input files to the symbol table. The symbol table is basically
 // a hash table with the logic to resolve symbol name conflicts using
 // the symbol types.
 //
 //===----------------------------------------------------------------------===//

 #include "SymbolTable.h"
 #include "Config.h"
 #include "LinkerScript.h"
 #include "Symbols.h"
 #include "SyntheticSections.h"
 #include "lld/Common/ErrorHandler.h"
 #include "lld/Common/Memory.h"
 #include "lld/Common/Strings.h"
 #include "llvm/ADT/STLExtras.h"

 using namespace llvm;
 using namespace llvm::object;
 using namespace llvm::ELF;

 using namespace lld;
 using namespace lld::elf;

 SymbolTable *elf::symtab;

 void SymbolTable::wrap(Symbol *sym, Symbol *real, Symbol *wrap) {
   // Swap symbols as instructed by -wrap.
   int &idx1 = symMap[CachedHashStringRef(sym->getName())];
   int &idx2 = symMap[CachedHashStringRef(real->getName())];
   int &idx3 = symMap[CachedHashStringRef(wrap->getName())];

   idx2 = idx1;
   idx1 = idx3;

   // Now renaming is complete. No one refers Real symbol. We could leave
   // Real as-is, but if Real is written to the symbol table, that may
   // contain irrelevant values. So, we copy all values from Sym to Real.
   StringRef s = real->getName();
   memcpy(real, sym, sizeof(SymbolUnion));
   real->setName(s);
 }

 // Find an existing symbol or create a new one.
 Symbol *SymbolTable::insert(StringRef name) {
   // <name>@@<version> means the symbol is the default version. In that
   // case <name>@@<version> will be used to resolve references to <name>.
   //
   // Since this is a hot path, the following string search code is
   // optimized for speed. StringRef::find(char) is much faster than
   // StringRef::find(StringRef).
   size_t pos = name.find('@');
   if (pos != StringRef::npos && pos + 1 < name.size() && name[pos + 1] == '@')
     name = name.take_front(pos);

   auto p = symMap.insert({CachedHashStringRef(name), (int)symVector.size()});
   int &symIndex = p.first->second;
   bool isNew = p.second;

   if (!isNew)
     return symVector[symIndex];

   Symbol *sym = reinterpret_cast<Symbol *>(make<SymbolUnion>());
   symVector.push_back(sym);

   sym->setName(name);
   sym->symbolKind = Symbol::PlaceholderKind;
   sym->versionId = config->defaultSymbolVersion;
   sym->visibility = STV_DEFAULT;
   sym->isUsedInRegularObj = false;
   sym->exportDynamic = false;
   sym->canInline = true;
   sym->scriptDefined = false;
   sym->partition = 1;
   return sym;
 }

 Symbol *SymbolTable::addSymbol(const Symbol &New) {
   Symbol *sym = symtab->insert(New.getName());
   sym->resolve(New);
   return sym;
 }

 Symbol *SymbolTable::find(StringRef name) {
   auto it = symMap.find(CachedHashStringRef(name));
   if (it == symMap.end())
     return nullptr;
   Symbol *sym = symVector[it->second];
   if (sym->isPlaceholder())
     return nullptr;
   return sym;
 }

 // Initialize demangledSyms with a map from demangled symbols to symbol
 // objects. Used to handle "extern C++" directive in version scripts.
 //
 // The map will contain all demangled symbols. That can be very large,
 // and in LLD we generally want to avoid do anything for each symbol.
 // Then, why are we doing this? Here's why.
 //
 // Users can use "extern C++ {}" directive to match against demangled
 // C++ symbols. For example, you can write a pattern such as
 // "llvm::*::foo(int, ?)". Obviously, there's no way to handle this
 // other than trying to match a pattern against all demangled symbols.
 // So, if "extern C++" feature is used, we need to demangle all known
 // symbols.
 StringMap<std::vector<Symbol *>> &SymbolTable::getDemangledSyms() {
   if (!demangledSyms) {
     demangledSyms.emplace();
     for (Symbol *sym : symVector) {
       if (!sym->isDefined() && !sym->isCommon())
         continue;
       if (Optional<std::string> s = demangleItanium(sym->getName()))
         (*demangledSyms)[*s].push_back(sym);
       else
         (*demangledSyms)[sym->getName()].push_back(sym);
     }
   }
   return *demangledSyms;
 }

 std::vector<Symbol *> SymbolTable::findByVersion(SymbolVersion ver) {
   if (ver.isExternCpp)
     return getDemangledSyms().lookup(ver.name);
   if (Symbol *b = find(ver.name))
     if (b->isDefined() || b->isCommon())
       return {b};
   return {};
 }

 std::vector<Symbol *> SymbolTable::findAllByVersion(SymbolVersion ver) {
   std::vector<Symbol *> res;
   StringMatcher m(ver.name);

   if (ver.isExternCpp) {
     for (auto &p : getDemangledSyms())
       if (m.match(p.first()))
         res.insert(res.end(), p.second.begin(), p.second.end());
     return res;
   }

   for (Symbol *sym : symVector)
     if ((sym->isDefined() || sym->isCommon()) && m.match(sym->getName()))
       res.push_back(sym);
   return res;
 }

 // Handles -dynamic-list.
 void SymbolTable::handleDynamicList() {
   for (SymbolVersion &ver : config->dynamicList) {
     std::vector<Symbol *> syms;
     if (ver.hasWildcard)
       syms = findAllByVersion(ver);
     else
       syms = findByVersion(ver);

     for (Symbol *b : syms) {
       if (!config->shared)
         b->exportDynamic = true;
       else if (b->includeInDynsym())
         b->isPreemptible = true;
     }
   }
 }

 // Set symbol versions to symbols. This function handles patterns
 // containing no wildcard characters.
 void SymbolTable::assignExactVersion(SymbolVersion ver, uint16_t versionId,
                                      StringRef versionName) {
   if (ver.hasWildcard)
     return;

   // Get a list of symbols which we need to assign the version to.
   std::vector<Symbol *> syms = findByVersion(ver);
   if (syms.empty()) {
     if (!config->undefinedVersion)
       error("version script assignment of '" + versionName + "' to symbol '" +
             ver.name + "' failed: symbol not defined");
     return;
   }

   auto getName = [](uint16_t ver) -> std::string {
     if (ver == VER_NDX_LOCAL)
       return "VER_NDX_LOCAL";
     if (ver == VER_NDX_GLOBAL)
       return "VER_NDX_GLOBAL";
     return ("version '" + config->versionDefinitions[ver - 2].name + "'").str();
   };

   // Assign the version.
   for (Symbol *sym : syms) {
     // Skip symbols containing version info because symbol versions
     // specified by symbol names take precedence over version scripts.
     // See parseSymbolVersion().
     if (sym->getName().contains('@'))
       continue;

     if (sym->versionId == config->defaultSymbolVersion)
       sym->versionId = versionId;
     if (sym->versionId == versionId)
       continue;

     warn("attempt to reassign symbol '" + ver.name + "' of " +
          getName(sym->versionId) + " to " + getName(versionId));
   }
 }

 void SymbolTable::assignWildcardVersion(SymbolVersion ver, uint16_t versionId) {
   if (!ver.hasWildcard)
     return;

   // Exact matching takes precendence over fuzzy matching,
   // so we set a version to a symbol only if no version has been assigned
   // to the symbol. This behavior is compatible with GNU.
   for (Symbol *b : findAllByVersion(ver))
     if (b->versionId == config->defaultSymbolVersion)
       b->versionId = versionId;
 }

 // This function processes version scripts by updating the versionId
 // member of symbols.
 // If there's only one anonymous version definition in a version
 // script file, the script does not actually define any symbol version,
 // but just specifies symbols visibilities.
 void SymbolTable::scanVersionScript() {
   // First, we assign versions to exact matching symbols,
   // i.e. version definitions not containing any glob meta-characters.
   for (SymbolVersion &ver : config->versionScriptGlobals)
     assignExactVersion(ver, VER_NDX_GLOBAL, "global");
   for (SymbolVersion &ver : config->versionScriptLocals)
     assignExactVersion(ver, VER_NDX_LOCAL, "local");
   for (VersionDefinition &v : config->versionDefinitions)
     for (SymbolVersion &ver : v.globals)
       assignExactVersion(ver, v.id, v.name);

   // Next, we assign versions to fuzzy matching symbols,
   // i.e. version definitions containing glob meta-characters.
   for (SymbolVersion &ver : config->versionScriptGlobals)
     assignWildcardVersion(ver, VER_NDX_GLOBAL);
   for (SymbolVersion &ver : config->versionScriptLocals)
     assignWildcardVersion(ver, VER_NDX_LOCAL);

   // Note that because the last match takes precedence over previous matches,
   // we iterate over the definitions in the reverse order.
   for (VersionDefinition &v : llvm::reverse(config->versionDefinitions))
     for (SymbolVersion &ver : v.globals)
       assignWildcardVersion(ver, v.id);

   // Symbol themselves might know their versions because symbols
   // can contain versions in the form of <name>@<version>.
   // Let them parse and update their names to exclude version suffix.
   for (Symbol *sym : symVector)
     sym->parseSymbolVersion();

   // isPreemptible is false at this point. To correctly compute the binding of a
   // Defined (which is used by includeInDynsym()), we need to know if it is
   // VER_NDX_LOCAL or not. If defaultSymbolVersion is VER_NDX_LOCAL, we should
   // compute symbol versions before handling --dynamic-list.
   handleDynamicList();
 }
	//===- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Symbol table is a bag of all known symbols. We put all symbols of
	// all input files to the symbol table. The symbol table is basically
	// a hash table with the logic to resolve symbol name conflicts using
	// the symbol types.
	//
	//===----------------------------------------------------------------------===//

	#include "SymbolTable.h"
	#include "Config.h"
	#include "LinkerScript.h"
	#include "Symbols.h"
	#include "SyntheticSections.h"
	#include "lld/Common/ErrorHandler.h"
	#include "lld/Common/Memory.h"
	#include "lld/Common/Strings.h"
	#include "llvm/ADT/STLExtras.h"

	using namespace llvm;
	using namespace llvm::object;
	using namespace llvm::ELF;

	using namespace lld;
	using namespace lld::elf;

	SymbolTable *elf::symtab;

	void SymbolTable::wrap(Symbol sym, Symbol real, Symbol *wrap) {
	// Swap symbols as instructed by -wrap.
	int &idx1 = symMap[CachedHashStringRef(sym->getName())];
	int &idx2 = symMap[CachedHashStringRef(real->getName())];
	int &idx3 = symMap[CachedHashStringRef(wrap->getName())];

	idx2 = idx1;
	idx1 = idx3;

	// Now renaming is complete. No one refers Real symbol. We could leave
	// Real as-is, but if Real is written to the symbol table, that may
	// contain irrelevant values. So, we copy all values from Sym to Real.
	StringRef s = real->getName();
	memcpy(real, sym, sizeof(SymbolUnion));
	real->setName(s);
	}

	// Find an existing symbol or create a new one.
	Symbol *SymbolTable::insert(StringRef name) {
	// <name>@@<version> means the symbol is the default version. In that
	// case <name>@@<version> will be used to resolve references to <name>.
	//
	// Since this is a hot path, the following string search code is
	// optimized for speed. StringRef::find(char) is much faster than
	// StringRef::find(StringRef).
	size_t pos = name.find('@');
	if (pos != StringRef::npos && pos + 1 < name.size() && name[pos + 1] == '@')
	name = name.take_front(pos);

	auto p = symMap.insert({CachedHashStringRef(name), (int)symVector.size()});
	int &symIndex = p.first->second;
	bool isNew = p.second;

	if (!isNew)
	return symVector[symIndex];

	Symbol sym = reinterpret_cast<Symbol >(make<SymbolUnion>());
	symVector.push_back(sym);

	sym->setName(name);
	sym->symbolKind = Symbol::PlaceholderKind;
	sym->versionId = config->defaultSymbolVersion;
	sym->visibility = STV_DEFAULT;
	sym->isUsedInRegularObj = false;
	sym->exportDynamic = false;
	sym->canInline = true;
	sym->scriptDefined = false;
	sym->partition = 1;
	return sym;
	}

	Symbol *SymbolTable::addSymbol(const Symbol &New) {
	Symbol *sym = symtab->insert(New.getName());
	sym->resolve(New);
	return sym;
	}

	Symbol *SymbolTable::find(StringRef name) {
	auto it = symMap.find(CachedHashStringRef(name));
	if (it == symMap.end())
	return nullptr;
	Symbol *sym = symVector[it->second];
	if (sym->isPlaceholder())
	return nullptr;
	return sym;
	}

	// Initialize demangledSyms with a map from demangled symbols to symbol
	// objects. Used to handle "extern C++" directive in version scripts.
	//
	// The map will contain all demangled symbols. That can be very large,
	// and in LLD we generally want to avoid do anything for each symbol.
	// Then, why are we doing this? Here's why.
	//
	// Users can use "extern C++ {}" directive to match against demangled
	// C++ symbols. For example, you can write a pattern such as
	// "llvm::*::foo(int, ?)". Obviously, there's no way to handle this
	// other than trying to match a pattern against all demangled symbols.
	// So, if "extern C++" feature is used, we need to demangle all known
	// symbols.
	StringMap<std::vector<Symbol *>> &SymbolTable::getDemangledSyms() {
	if (!demangledSyms) {
	demangledSyms.emplace();
	for (Symbol *sym : symVector) {
	if (!sym->isDefined() && !sym->isCommon())
	continue;
	if (Optional<std::string> s = demangleItanium(sym->getName()))
	(demangledSyms)[s].push_back(sym);
	else
	(*demangledSyms)[sym->getName()].push_back(sym);
	}
	}
	return *demangledSyms;
	}

	std::vector<Symbol *> SymbolTable::findByVersion(SymbolVersion ver) {
	if (ver.isExternCpp)
	return getDemangledSyms().lookup(ver.name);
	if (Symbol *b = find(ver.name))
	if (b->isDefined() \|\| b->isCommon())
	return {b};
	return {};
	}

	std::vector<Symbol *> SymbolTable::findAllByVersion(SymbolVersion ver) {
	std::vector<Symbol *> res;
	StringMatcher m(ver.name);

	if (ver.isExternCpp) {
	for (auto &p : getDemangledSyms())
	if (m.match(p.first()))
	res.insert(res.end(), p.second.begin(), p.second.end());
	return res;
	}

	for (Symbol *sym : symVector)
	if ((sym->isDefined() \|\| sym->isCommon()) && m.match(sym->getName()))
	res.push_back(sym);
	return res;
	}

	// Handles -dynamic-list.
	void SymbolTable::handleDynamicList() {
	for (SymbolVersion &ver : config->dynamicList) {
	std::vector<Symbol *> syms;
	if (ver.hasWildcard)
	syms = findAllByVersion(ver);
	else
	syms = findByVersion(ver);

	for (Symbol *b : syms) {
	if (!config->shared)
	b->exportDynamic = true;
	else if (b->includeInDynsym())
	b->isPreemptible = true;
	}
	}
	}

	// Set symbol versions to symbols. This function handles patterns
	// containing no wildcard characters.
	void SymbolTable::assignExactVersion(SymbolVersion ver, uint16_t versionId,
	StringRef versionName) {
	if (ver.hasWildcard)
	return;

	// Get a list of symbols which we need to assign the version to.
	std::vector<Symbol *> syms = findByVersion(ver);
	if (syms.empty()) {
	if (!config->undefinedVersion)
	error("version script assignment of '" + versionName + "' to symbol '" +
	ver.name + "' failed: symbol not defined");
	return;
	}

	auto getName = [](uint16_t ver) -> std::string {
	if (ver == VER_NDX_LOCAL)
	return "VER_NDX_LOCAL";
	if (ver == VER_NDX_GLOBAL)
	return "VER_NDX_GLOBAL";
	return ("version '" + config->versionDefinitions[ver - 2].name + "'").str();
	};

	// Assign the version.
	for (Symbol *sym : syms) {
	// Skip symbols containing version info because symbol versions
	// specified by symbol names take precedence over version scripts.
	// See parseSymbolVersion().
	if (sym->getName().contains('@'))
	continue;

	if (sym->versionId == config->defaultSymbolVersion)
	sym->versionId = versionId;
	if (sym->versionId == versionId)
	continue;

	warn("attempt to reassign symbol '" + ver.name + "' of " +
	getName(sym->versionId) + " to " + getName(versionId));
	}
	}

	void SymbolTable::assignWildcardVersion(SymbolVersion ver, uint16_t versionId) {
	if (!ver.hasWildcard)
	return;

	// Exact matching takes precendence over fuzzy matching,
	// so we set a version to a symbol only if no version has been assigned
	// to the symbol. This behavior is compatible with GNU.
	for (Symbol *b : findAllByVersion(ver))
	if (b->versionId == config->defaultSymbolVersion)
	b->versionId = versionId;
	}

	// This function processes version scripts by updating the versionId
	// member of symbols.
	// If there's only one anonymous version definition in a version
	// script file, the script does not actually define any symbol version,
	// but just specifies symbols visibilities.
	void SymbolTable::scanVersionScript() {
	// First, we assign versions to exact matching symbols,
	// i.e. version definitions not containing any glob meta-characters.
	for (SymbolVersion &ver : config->versionScriptGlobals)
	assignExactVersion(ver, VER_NDX_GLOBAL, "global");
	for (SymbolVersion &ver : config->versionScriptLocals)
	assignExactVersion(ver, VER_NDX_LOCAL, "local");
	for (VersionDefinition &v : config->versionDefinitions)
	for (SymbolVersion &ver : v.globals)
	assignExactVersion(ver, v.id, v.name);

	// Next, we assign versions to fuzzy matching symbols,
	// i.e. version definitions containing glob meta-characters.
	for (SymbolVersion &ver : config->versionScriptGlobals)
	assignWildcardVersion(ver, VER_NDX_GLOBAL);
	for (SymbolVersion &ver : config->versionScriptLocals)
	assignWildcardVersion(ver, VER_NDX_LOCAL);

	// Note that because the last match takes precedence over previous matches,
	// we iterate over the definitions in the reverse order.
	for (VersionDefinition &v : llvm::reverse(config->versionDefinitions))
	for (SymbolVersion &ver : v.globals)
	assignWildcardVersion(ver, v.id);

	// Symbol themselves might know their versions because symbols
	// can contain versions in the form of <name>@<version>.
	// Let them parse and update their names to exclude version suffix.
	for (Symbol *sym : symVector)
	sym->parseSymbolVersion();

	// isPreemptible is false at this point. To correctly compute the binding of a
	// Defined (which is used by includeInDynsym()), we need to know if it is
	// VER_NDX_LOCAL or not. If defaultSymbolVersion is VER_NDX_LOCAL, we should
	// compute symbol versions before handling --dynamic-list.
	handleDynamicList();
	}