llvm::Constant *IRGenModule::getOrCreateOutlinedDestroyFunction(
SILType T, const TypeInfo &ti,
const OutliningMetadataCollector &collector) {
IRGenMangler mangler;
auto manglingBits = getTypeAndGenericSignatureForManglingOutlineFunction(T);
auto funcName = mangler.mangleOutlinedDestroyFunction(manglingBits.first,
manglingBits.second);
auto ptrTy = ti.getStorageType()->getPointerTo();
llvm::SmallVector<llvm::Type *, 4> paramTys;
paramTys.push_back(ptrTy);
collector.addMetadataParameterTypes(paramTys);
return getOrCreateHelperFunction(funcName, ptrTy, paramTys,
[&](IRGenFunction &IGF) {
Explosion params = IGF.collectParameters();
Address addr = ti.getAddressForPointer(params.claimNext());
collector.bindMetadataParameters(IGF, params);
ti.destroy(IGF, addr, T, true);
IGF.Builder.CreateRet(addr.getAddress());
},
true /*setIsNoInline*/);
}
/// Add a 32-bit relative offset to a mangled nominal type string
/// in the typeref reflection section.
void addNominalRef(const NominalTypeDecl *nominal) {
if (auto proto = dyn_cast<ProtocolDecl>(nominal)) {
IRGenMangler mangler;
SymbolicMangling mangledStr;
mangledStr.String = mangler.mangleBareProtocol(proto);
auto mangledName = IGM.getAddrOfStringForTypeRef(mangledStr);
B.addRelativeAddress(mangledName);
} else {
CanType type = nominal->getDeclaredType()->getCanonicalType();
B.addRelativeAddress(IGM.getTypeRef(type));
}
}
llvm::Constant *
IRGenModule::getOrCreateReleaseFunction(const TypeInfo &ti,
SILType t,
llvm::Type *llvmType) {
auto *loadableTI = cast<LoadableTypeInfo>(&ti);
IRGenMangler mangler;
auto manglingBits =
getTypeAndGenericSignatureForManglingOutlineFunction(t);
auto funcName = mangler.mangleOutlinedReleaseFunction(manglingBits.first,
manglingBits.second);
llvm::Type *argTys[] = {llvmType};
return getOrCreateHelperFunction(
funcName, llvmType, argTys,
[&](IRGenFunction &IGF) {
auto it = IGF.CurFn->arg_begin();
Address addr(&*it++, loadableTI->getFixedAlignment());
Explosion loaded;
loadableTI->loadAsTake(IGF, addr, loaded);
loadableTI->consume(IGF, loaded, irgen::Atomicity::Atomic);
IGF.Builder.CreateRet(addr.getAddress());
},
true /*setIsNoInline*/);
}
/// Add a 32-bit relative offset to a mangled typeref string
/// in the typeref reflection section.
void addTypeRef(ModuleDecl *ModuleContext, CanType type,
CanGenericSignature Context = {}) {
assert(type);
// Generic parameters should be written in terms of interface types
// for the purposes of reflection metadata
assert(!type->hasArchetype() && "Forgot to map typeref out of context");
// TODO: As a compatibility hack, mangle single-field boxes with the legacy
// mangling in reflection metadata.
bool isSingleFieldOfBox = false;
auto boxTy = dyn_cast<SILBoxType>(type);
if (boxTy && boxTy->getLayout()->getFields().size() == 1) {
GenericContextScope scope(IGM, Context);
type = boxTy->getFieldLoweredType(IGM.getSILModule(), 0);
isSingleFieldOfBox = true;
}
IRGenMangler mangler;
std::string MangledStr = mangler.mangleTypeForReflection(type,
ModuleContext, isSingleFieldOfBox);
auto mangledName = IGM.getAddrOfStringForTypeRef(MangledStr);
addRelativeAddress(mangledName);
}
/// Mangle this entity as a std::string.
std::string LinkEntity::mangleAsString() const {
IRGenMangler mangler;
switch (getKind()) {
case Kind::DispatchThunk:
return mangler.mangleEntity(getDecl(), /*isCurried=*/false,
ASTMangler::SymbolKind::SwiftDispatchThunk);
case Kind::DispatchThunkInitializer:
return mangler.mangleConstructorEntity(
cast<ConstructorDecl>(getDecl()),
/*isAllocating=*/false,
/*isCurried=*/false,
ASTMangler::SymbolKind::SwiftDispatchThunk);
case Kind::DispatchThunkAllocator:
return mangler.mangleConstructorEntity(
cast<ConstructorDecl>(getDecl()),
/*isAllocating=*/true,
/*isCurried=*/false,
ASTMangler::SymbolKind::SwiftDispatchThunk);
case Kind::ValueWitness:
return mangler.mangleValueWitness(getType(), getValueWitness());
case Kind::ValueWitnessTable:
return mangler.mangleValueWitnessTable(getType());
case Kind::TypeMetadataAccessFunction:
return mangler.mangleTypeMetadataAccessFunction(getType());
case Kind::TypeMetadataLazyCacheVariable:
return mangler.mangleTypeMetadataLazyCacheVariable(getType());
case Kind::TypeMetadataInstantiationCache:
return mangler.mangleTypeMetadataInstantiationCache(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataInstantiationFunction:
return mangler.mangleTypeMetadataInstantiationFunction(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataInPlaceInitializationCache:
return mangler.mangleTypeMetadataInPlaceInitializationCache(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataCompletionFunction:
return mangler.mangleTypeMetadataCompletionFunction(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadata:
switch (getMetadataAddress()) {
case TypeMetadataAddress::FullMetadata:
return mangler.mangleTypeFullMetadataFull(getType());
case TypeMetadataAddress::AddressPoint:
return mangler.mangleTypeMetadataFull(getType());
}
llvm_unreachable("invalid metadata address");
case Kind::TypeMetadataPattern:
return mangler.mangleTypeMetadataPattern(
cast<NominalTypeDecl>(getDecl()));
case Kind::ForeignTypeMetadataCandidate:
return mangler.mangleTypeMetadataFull(getType());
case Kind::SwiftMetaclassStub:
return mangler.mangleClassMetaClass(cast<ClassDecl>(getDecl()));
case Kind::ClassMetadataBaseOffset: // class metadata base offset
return mangler.mangleClassMetadataBaseOffset(cast<ClassDecl>(getDecl()));
case Kind::NominalTypeDescriptor:
return mangler.mangleNominalTypeDescriptor(
cast<NominalTypeDecl>(getDecl()));
case Kind::PropertyDescriptor:
return mangler.manglePropertyDescriptor(
cast<AbstractStorageDecl>(getDecl()));
case Kind::ModuleDescriptor:
return mangler.mangleModuleDescriptor(cast<ModuleDecl>(getDecl()));
case Kind::ExtensionDescriptor:
return mangler.mangleExtensionDescriptor(getExtension());
case Kind::AnonymousDescriptor:
return mangler.mangleAnonymousDescriptor(getDeclContext());
case Kind::ProtocolDescriptor:
return mangler.mangleProtocolDescriptor(cast<ProtocolDecl>(getDecl()));
case Kind::ProtocolConformanceDescriptor:
return mangler.mangleProtocolConformanceDescriptor(
cast<NormalProtocolConformance>(getProtocolConformance()));
case Kind::EnumCase:
return mangler.mangleEnumCase(getDecl());
case Kind::FieldOffset:
return mangler.mangleFieldOffset(getDecl());
case Kind::DirectProtocolWitnessTable:
return mangler.mangleDirectProtocolWitnessTable(getProtocolConformance());
case Kind::GenericProtocolWitnessTableCache:
return mangler.mangleGenericProtocolWitnessTableCache(
getProtocolConformance());
case Kind::GenericProtocolWitnessTableInstantiationFunction:
return mangler.mangleGenericProtocolWitnessTableInstantiationFunction(
getProtocolConformance());
case Kind::ResilientProtocolWitnessTable:
return mangler.mangleResilientProtocolWitnessTable(getProtocolConformance());
case Kind::ProtocolWitnessTableAccessFunction:
return mangler.mangleProtocolWitnessTableAccessFunction(
getProtocolConformance());
case Kind::ProtocolWitnessTablePattern:
return mangler.mangleProtocolWitnessTablePattern(getProtocolConformance());
case Kind::ProtocolWitnessTableLazyAccessFunction:
return mangler.mangleProtocolWitnessTableLazyAccessFunction(getType(),
getProtocolConformance());
case Kind::ProtocolWitnessTableLazyCacheVariable:
return mangler.mangleProtocolWitnessTableLazyCacheVariable(getType(),
getProtocolConformance());
case Kind::AssociatedTypeMetadataAccessFunction:
return mangler.mangleAssociatedTypeMetadataAccessFunction(
getProtocolConformance(), getAssociatedType()->getNameStr());
case Kind::AssociatedTypeWitnessTableAccessFunction: {
auto assocConf = getAssociatedConformance();
return mangler.mangleAssociatedTypeWitnessTableAccessFunction(
getProtocolConformance(), assocConf.first, assocConf.second);
}
case Kind::CoroutineContinuationPrototype:
return mangler.mangleCoroutineContinuationPrototype(
cast<SILFunctionType>(getType()));
// An Objective-C class reference reference. The symbol is private, so
// the mangling is unimportant; it should just be readable in LLVM IR.
case Kind::ObjCClassRef: {
llvm::SmallString<64> tempBuffer;
StringRef name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(tempBuffer);
std::string Result("\01l_OBJC_CLASS_REF_$_");
Result.append(name.data(), name.size());
return Result;
}
// An Objective-C class reference; not a swift mangling.
case Kind::ObjCClass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_CLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
// An Objective-C metaclass reference; not a swift mangling.
case Kind::ObjCMetaclass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_METACLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
case Kind::SILFunction:
return getSILFunction()->getName();
case Kind::SILGlobalVariable:
return getSILGlobalVariable()->getName();
case Kind::ReflectionBuiltinDescriptor:
return mangler.mangleReflectionBuiltinDescriptor(getType());
case Kind::ReflectionFieldDescriptor:
return mangler.mangleReflectionFieldDescriptor(getType());
case Kind::ReflectionAssociatedTypeDescriptor:
return mangler.mangleReflectionAssociatedTypeDescriptor(
getProtocolConformance());
}
llvm_unreachable("bad entity kind!");
}
llvm::Constant *IRGenModule::getTypeRef(CanType type) {
IRGenMangler Mangler;
auto SymbolicName = Mangler.mangleTypeForReflection(*this, type);
return getAddrOfStringForTypeRef(SymbolicName);
}
/// Mangle this entity as a std::string.
std::string LinkEntity::mangleAsString() const {
IRGenMangler mangler;
switch (getKind()) {
case Kind::DispatchThunk: {
auto *func = cast<FuncDecl>(getDecl());
return mangler.mangleDispatchThunk(func);
}
case Kind::DispatchThunkInitializer: {
auto *ctor = cast<ConstructorDecl>(getDecl());
return mangler.mangleConstructorDispatchThunk(ctor,
/*isAllocating=*/false);
}
case Kind::DispatchThunkAllocator: {
auto *ctor = cast<ConstructorDecl>(getDecl());
return mangler.mangleConstructorDispatchThunk(ctor,
/*isAllocating=*/true);
}
case Kind::MethodDescriptor: {
auto *func = cast<FuncDecl>(getDecl());
return mangler.mangleMethodDescriptor(func);
}
case Kind::MethodDescriptorInitializer: {
auto *ctor = cast<ConstructorDecl>(getDecl());
return mangler.mangleConstructorMethodDescriptor(ctor,
/*isAllocating=*/false);
}
case Kind::MethodDescriptorAllocator: {
auto *ctor = cast<ConstructorDecl>(getDecl());
return mangler.mangleConstructorMethodDescriptor(ctor,
/*isAllocating=*/true);
}
case Kind::MethodLookupFunction: {
auto *classDecl = cast<ClassDecl>(getDecl());
return mangler.mangleMethodLookupFunction(classDecl);
}
case Kind::ValueWitness:
return mangler.mangleValueWitness(getType(), getValueWitness());
case Kind::ValueWitnessTable:
return mangler.mangleValueWitnessTable(getType());
case Kind::TypeMetadataAccessFunction:
return mangler.mangleTypeMetadataAccessFunction(getType());
case Kind::TypeMetadataLazyCacheVariable:
return mangler.mangleTypeMetadataLazyCacheVariable(getType());
case Kind::TypeMetadataInstantiationCache:
return mangler.mangleTypeMetadataInstantiationCache(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataInstantiationFunction:
return mangler.mangleTypeMetadataInstantiationFunction(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataSingletonInitializationCache:
return mangler.mangleTypeMetadataSingletonInitializationCache(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadataCompletionFunction:
return mangler.mangleTypeMetadataCompletionFunction(
cast<NominalTypeDecl>(getDecl()));
case Kind::TypeMetadata:
switch (getMetadataAddress()) {
case TypeMetadataAddress::FullMetadata:
return mangler.mangleTypeFullMetadataFull(getType());
case TypeMetadataAddress::AddressPoint:
return mangler.mangleTypeMetadataFull(getType());
}
llvm_unreachable("invalid metadata address");
case Kind::TypeMetadataPattern:
return mangler.mangleTypeMetadataPattern(
cast<NominalTypeDecl>(getDecl()));
case Kind::SwiftMetaclassStub:
return mangler.mangleClassMetaClass(cast<ClassDecl>(getDecl()));
case Kind::ObjCMetadataUpdateFunction:
return mangler.mangleObjCMetadataUpdateFunction(cast<ClassDecl>(getDecl()));
case Kind::ObjCResilientClassStub:
switch (getMetadataAddress()) {
case TypeMetadataAddress::FullMetadata:
return mangler.mangleFullObjCResilientClassStub(cast<ClassDecl>(getDecl()));
case TypeMetadataAddress::AddressPoint:
return mangler.mangleObjCResilientClassStub(cast<ClassDecl>(getDecl()));
}
llvm_unreachable("invalid metadata address");
case Kind::ClassMetadataBaseOffset: // class metadata base offset
return mangler.mangleClassMetadataBaseOffset(cast<ClassDecl>(getDecl()));
case Kind::NominalTypeDescriptor:
return mangler.mangleNominalTypeDescriptor(
cast<NominalTypeDecl>(getDecl()));
case Kind::OpaqueTypeDescriptor:
return mangler.mangleOpaqueTypeDescriptor(cast<OpaqueTypeDecl>(getDecl()));
case Kind::OpaqueTypeDescriptorAccessor:
return mangler.mangleOpaqueTypeDescriptorAccessor(
cast<OpaqueTypeDecl>(getDecl()));
case Kind::OpaqueTypeDescriptorAccessorImpl:
return mangler.mangleOpaqueTypeDescriptorAccessorImpl(
cast<OpaqueTypeDecl>(getDecl()));
case Kind::OpaqueTypeDescriptorAccessorKey:
return mangler.mangleOpaqueTypeDescriptorAccessorKey(
cast<OpaqueTypeDecl>(getDecl()));
case Kind::OpaqueTypeDescriptorAccessorVar:
return mangler.mangleOpaqueTypeDescriptorAccessorVar(
cast<OpaqueTypeDecl>(getDecl()));
case Kind::PropertyDescriptor:
return mangler.manglePropertyDescriptor(
cast<AbstractStorageDecl>(getDecl()));
case Kind::ModuleDescriptor:
return mangler.mangleModuleDescriptor(cast<ModuleDecl>(getDecl()));
case Kind::ExtensionDescriptor:
return mangler.mangleExtensionDescriptor(getExtension());
case Kind::AnonymousDescriptor:
return mangler.mangleAnonymousDescriptor(getAnonymousDeclContext());
case Kind::ProtocolDescriptor:
return mangler.mangleProtocolDescriptor(cast<ProtocolDecl>(getDecl()));
case Kind::ProtocolRequirementsBaseDescriptor:
return mangler.mangleProtocolRequirementsBaseDescriptor(
cast<ProtocolDecl>(getDecl()));
case Kind::AssociatedTypeDescriptor:
return mangler.mangleAssociatedTypeDescriptor(
cast<AssociatedTypeDecl>(getDecl()));
case Kind::AssociatedConformanceDescriptor: {
auto assocConformance = getAssociatedConformance();
return mangler.mangleAssociatedConformanceDescriptor(
cast<ProtocolDecl>(getDecl()),
assocConformance.first,
assocConformance.second);
}
case Kind::BaseConformanceDescriptor: {
auto assocConformance = getAssociatedConformance();
return mangler.mangleBaseConformanceDescriptor(
cast<ProtocolDecl>(getDecl()),
assocConformance.second);
}
case Kind::DefaultAssociatedConformanceAccessor: {
auto assocConformance = getAssociatedConformance();
return mangler.mangleDefaultAssociatedConformanceAccessor(
cast<ProtocolDecl>(getDecl()),
assocConformance.first,
assocConformance.second);
}
case Kind::ProtocolConformanceDescriptor:
return mangler.mangleProtocolConformanceDescriptor(
getRootProtocolConformance());
case Kind::EnumCase:
return mangler.mangleEnumCase(getDecl());
case Kind::FieldOffset:
return mangler.mangleFieldOffset(getDecl());
case Kind::ProtocolWitnessTable:
return mangler.mangleWitnessTable(getRootProtocolConformance());
case Kind::GenericProtocolWitnessTableInstantiationFunction:
return mangler.mangleGenericProtocolWitnessTableInstantiationFunction(
getProtocolConformance());
case Kind::ProtocolWitnessTablePattern:
return mangler.mangleProtocolWitnessTablePattern(getProtocolConformance());
case Kind::ProtocolWitnessTableLazyAccessFunction:
return mangler.mangleProtocolWitnessTableLazyAccessFunction(getType(),
getProtocolConformance());
case Kind::ProtocolWitnessTableLazyCacheVariable:
return mangler.mangleProtocolWitnessTableLazyCacheVariable(getType(),
getProtocolConformance());
case Kind::AssociatedTypeWitnessTableAccessFunction: {
auto assocConf = getAssociatedConformance();
if (isa<GenericTypeParamType>(assocConf.first)) {
return mangler.mangleBaseWitnessTableAccessFunction(
getProtocolConformance(), assocConf.second);
}
return mangler.mangleAssociatedTypeWitnessTableAccessFunction(
getProtocolConformance(), assocConf.first, assocConf.second);
}
case Kind::CoroutineContinuationPrototype:
return mangler.mangleCoroutineContinuationPrototype(
cast<SILFunctionType>(getType()));
// An Objective-C class reference reference. The symbol is private, so
// the mangling is unimportant; it should just be readable in LLVM IR.
case Kind::ObjCClassRef: {
llvm::SmallString<64> tempBuffer;
StringRef name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(tempBuffer);
std::string Result("OBJC_CLASS_REF_$_");
Result.append(name.data(), name.size());
return Result;
}
// An Objective-C class reference; not a swift mangling.
case Kind::ObjCClass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_CLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
// An Objective-C metaclass reference; not a swift mangling.
case Kind::ObjCMetaclass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_METACLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
case Kind::SILFunction: {
std::string Result(getSILFunction()->getName());
if (isDynamicallyReplaceable()) {
Result.append("TI");
}
return Result;
}
case Kind::DynamicallyReplaceableFunctionImpl: {
assert(isa<AbstractFunctionDecl>(getDecl()));
std::string Result;
if (auto *Constructor = dyn_cast<ConstructorDecl>(getDecl())) {
Result = mangler.mangleConstructorEntity(Constructor, isAllocator(),
/*isCurried=*/false);
} else {
Result = mangler.mangleEntity(getDecl(), /*isCurried=*/false);
}
Result.append("TI");
return Result;
}
case Kind::DynamicallyReplaceableFunctionVariable: {
std::string Result(getSILFunction()->getName());
Result.append("TX");
return Result;
}
case Kind::DynamicallyReplaceableFunctionKey: {
std::string Result(getSILFunction()->getName());
Result.append("Tx");
return Result;
}
case Kind::DynamicallyReplaceableFunctionVariableAST: {
assert(isa<AbstractFunctionDecl>(getDecl()));
std::string Result;
if (auto *Constructor = dyn_cast<ConstructorDecl>(getDecl())) {
Result =
mangler.mangleConstructorEntity(Constructor, isAllocator(),
/*isCurried=*/false);
} else {
Result = mangler.mangleEntity(getDecl(), /*isCurried=*/false);
}
Result.append("TX");
return Result;
}
case Kind::DynamicallyReplaceableFunctionKeyAST: {
assert(isa<AbstractFunctionDecl>(getDecl()));
std::string Result;
if (auto *Constructor = dyn_cast<ConstructorDecl>(getDecl())) {
Result =
mangler.mangleConstructorEntity(Constructor, isAllocator(),
/*isCurried=*/false);
} else {
Result = mangler.mangleEntity(getDecl(), /*isCurried=*/false);
}
Result.append("Tx");
return Result;
}
case Kind::SILGlobalVariable:
return getSILGlobalVariable()->getName();
case Kind::ReflectionBuiltinDescriptor:
return mangler.mangleReflectionBuiltinDescriptor(getType());
case Kind::ReflectionFieldDescriptor:
return mangler.mangleReflectionFieldDescriptor(getType());
case Kind::ReflectionAssociatedTypeDescriptor:
return mangler.mangleReflectionAssociatedTypeDescriptor(
getProtocolConformance());
}
llvm_unreachable("bad entity kind!");
}
/// Mangle this entity into the given stream.
std::string LinkEntity::mangleNew() const {
// Almost everything below gets the common prefix:
// mangled-name ::= '_T' global
IRGenMangler mangler;
switch (getKind()) {
// global ::= 'w' value-witness-kind // value witness
case Kind::ValueWitness:
return mangler.mangleValueWitness(getType(), getValueWitness());
// global ::= 'WV' type // value witness
case Kind::ValueWitnessTable:
return mangler.mangleValueWitnessTable(getType());
// global ::= 'Ma' type // type metadata access function
case Kind::TypeMetadataAccessFunction:
return mangler.mangleTypeMetadataAccessFunction(getType());
// global ::= 'ML' type // type metadata lazy cache variable
case Kind::TypeMetadataLazyCacheVariable:
return mangler.mangleTypeMetadataLazyCacheVariable(getType());
// global ::= 'Mf' type // 'full' type metadata
// global ::= 'M' directness type // type metadata
// global ::= 'MP' directness type // type metadata pattern
case Kind::TypeMetadata:
switch (getMetadataAddress()) {
case TypeMetadataAddress::FullMetadata:
return mangler.mangleTypeFullMetadataFull(getType());
case TypeMetadataAddress::AddressPoint:
return mangler.mangleTypeMetadataFull(getType(), isMetadataPattern());
}
llvm_unreachable("invalid metadata address");
// global ::= 'M' directness type // type metadata
case Kind::ForeignTypeMetadataCandidate:
return mangler.mangleTypeMetadataFull(getType(), /*isPattern=*/false);
// global ::= 'Mm' type // class metaclass
case Kind::SwiftMetaclassStub:
return mangler.mangleClassMetaClass(cast<ClassDecl>(getDecl()));
// global ::= 'Mn' type // nominal type descriptor
case Kind::NominalTypeDescriptor:
return mangler.mangleNominalTypeDescriptor(
cast<NominalTypeDecl>(getDecl()));
// global ::= 'Mp' type // protocol descriptor
case Kind::ProtocolDescriptor:
return mangler.mangleProtocolDescriptor(cast<ProtocolDecl>(getDecl()));
// global ::= 'Wo' entity
case Kind::WitnessTableOffset:
return mangler.mangleWitnessTableOffset(getDecl());
// global ::= 'Wv' directness entity
case Kind::FieldOffset:
return mangler.mangleFieldOffsetFull(getDecl(), isOffsetIndirect());
// global ::= 'WP' protocol-conformance
case Kind::DirectProtocolWitnessTable:
return mangler.mangleDirectProtocolWitnessTable(getProtocolConformance());
// global ::= 'WG' protocol-conformance
case Kind::GenericProtocolWitnessTableCache:
return mangler.mangleGenericProtocolWitnessTableCache(
getProtocolConformance());
// global ::= 'WI' protocol-conformance
case Kind::GenericProtocolWitnessTableInstantiationFunction:
return mangler.mangleGenericProtocolWitnessTableInstantiationFunction(
getProtocolConformance());
// global ::= 'Wa' protocol-conformance
case Kind::ProtocolWitnessTableAccessFunction:
return mangler.mangleProtocolWitnessTableAccessFunction(
getProtocolConformance());
// global ::= 'Wl' type protocol-conformance
case Kind::ProtocolWitnessTableLazyAccessFunction:
return mangler.mangleProtocolWitnessTableLazyAccessFunction(getType(),
getProtocolConformance());
// global ::= 'WL' type protocol-conformance
case Kind::ProtocolWitnessTableLazyCacheVariable:
return mangler.mangleProtocolWitnessTableLazyCacheVariable(getType(),
getProtocolConformance());
// global ::= 'Wt' protocol-conformance identifier
case Kind::AssociatedTypeMetadataAccessFunction:
return mangler.mangleAssociatedTypeMetadataAccessFunction(
getProtocolConformance(), getAssociatedType()->getNameStr());
// global ::= 'WT' protocol-conformance identifier nominal-type
case Kind::AssociatedTypeWitnessTableAccessFunction:
return mangler.mangleAssociatedTypeWitnessTableAccessFunction(
getProtocolConformance(), getAssociatedType()->getNameStr(),
getAssociatedProtocol());
// For all the following, this rule was imposed above:
// global ::= local-marker? entity // some identifiable thing
// entity ::= declaration // other declaration
case Kind::Function:
// As a special case, functions can have manually mangled names.
if (auto AsmA = getDecl()->getAttrs().getAttribute<SILGenNameAttr>()) {
return AsmA->Name;
}
// Otherwise, fall through into the 'other decl' case.
LLVM_FALLTHROUGH;
case Kind::Other:
// As a special case, Clang functions and globals don't get mangled at all.
if (auto clangDecl = getDecl()->getClangDecl()) {
if (auto namedClangDecl = dyn_cast<clang::DeclaratorDecl>(clangDecl)) {
if (auto asmLabel = namedClangDecl->getAttr<clang::AsmLabelAttr>()) {
std::string Name(1, '\01');
Name.append(asmLabel->getLabel());
return Name;
}
if (namedClangDecl->hasAttr<clang::OverloadableAttr>()) {
// FIXME: When we can import C++, use Clang's mangler all the time.
std::string storage;
llvm::raw_string_ostream SS(storage);
mangleClangDecl(SS, namedClangDecl, getDecl()->getASTContext());
return SS.str();
}
return namedClangDecl->getName();
}
}
if (auto type = dyn_cast<NominalTypeDecl>(getDecl())) {
return mangler.mangleNominalType(type);
}
if (auto ctor = dyn_cast<ConstructorDecl>(getDecl())) {
// FIXME: Hack. LinkInfo should be able to refer to the allocating
// constructor rather than inferring it here.
return mangler.mangleConstructorEntity(ctor, /*isAllocating=*/true,
/*isCurried=*/false);
}
return mangler.mangleEntity(getDecl(), /*isCurried=*/false);
// An Objective-C class reference reference. The symbol is private, so
// the mangling is unimportant; it should just be readable in LLVM IR.
case Kind::ObjCClassRef: {
llvm::SmallString<64> tempBuffer;
StringRef name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(tempBuffer);
std::string Result("OBJC_CLASS_REF_$_");
Result.append(name.data(), name.size());
return Result;
}
// An Objective-C class reference; not a swift mangling.
case Kind::ObjCClass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_CLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
// An Objective-C metaclass reference; not a swift mangling.
case Kind::ObjCMetaclass: {
llvm::SmallString<64> TempBuffer;
StringRef Name = cast<ClassDecl>(getDecl())->getObjCRuntimeName(TempBuffer);
std::string Result("OBJC_METACLASS_$_");
Result.append(Name.data(), Name.size());
return Result;
}
case Kind::SILFunction:
return getSILFunction()->getName();
case Kind::SILGlobalVariable:
return getSILGlobalVariable()->getName();
case Kind::ReflectionBuiltinDescriptor:
return mangler.mangleReflectionBuiltinDescriptor(getType());
case Kind::ReflectionFieldDescriptor:
return mangler.mangleReflectionFieldDescriptor(getType());
case Kind::ReflectionAssociatedTypeDescriptor:
return mangler.mangleReflectionAssociatedTypeDescriptor(
getProtocolConformance());
case Kind::ReflectionSuperclassDescriptor:
return mangler.mangleReflectionSuperclassDescriptor(
cast<ClassDecl>(getDecl()));
}
llvm_unreachable("bad entity kind!");
}
