void layout() override {
PrettyStackTraceDecl DebugStack("emitting field type metadata", NTD);
auto type = NTD->getDeclaredType()->getCanonicalType();
addTypeRef(NTD->getModuleContext(), type);
if (NTD->hasClangNode() &&
!isa<ClassDecl>(NTD) &&
!isa<ProtocolDecl>(NTD))
return;
switch (NTD->getKind()) {
case DeclKind::Class:
case DeclKind::Struct:
layoutRecord();
break;
case DeclKind::Enum:
layoutEnum();
break;
case DeclKind::Protocol:
layoutProtocol();
break;
default:
llvm_unreachable("Not a nominal type");
break;
}
}
bool IRGenerator::canEmitWitnessTableLazily(SILWitnessTable *wt) {
if (Opts.UseJIT)
return false;
// Regardless of the access level, if the witness table is shared it means
// we can safely not emit it. Every other module which needs it will generate
// its own shared copy of it.
if (wt->getLinkage() == SILLinkage::Shared)
return true;
NominalTypeDecl *ConformingTy =
wt->getConformingType()->getNominalOrBoundGenericNominal();
switch (ConformingTy->getEffectiveAccess()) {
case AccessLevel::Private:
case AccessLevel::FilePrivate:
return true;
case AccessLevel::Internal:
return PrimaryIGM->getSILModule().isWholeModule();
default:
return false;
}
llvm_unreachable("switch does not handle all cases");
}
SmallVector<ProtocolDecl *, 2>
DeclContext::getLocalProtocols(
ConformanceLookupKind lookupKind,
SmallVectorImpl<ConformanceDiagnostic> *diagnostics,
bool sorted) const
{
SmallVector<ProtocolDecl *, 2> result;
// Dig out the nominal type.
NominalTypeDecl *nominal = getAsNominalTypeOrNominalTypeExtensionContext();
if (!nominal)
return result;
// Update to record all potential conformances.
nominal->prepareConformanceTable();
nominal->ConformanceTable->lookupConformances(
nominal,
const_cast<DeclContext *>(this),
getASTContext().getLazyResolver(),
lookupKind,
&result,
nullptr,
diagnostics);
// Sort if required.
if (sorted) {
llvm::array_pod_sort(result.begin(), result.end(),
&ProtocolType::compareProtocols);
}
return result;
}
static Type findBaseTypeForReplacingArchetype(const ValueDecl *VD, const Type Ty) {
if (Ty.isNull())
return Type();
// Find the nominal type decl related to VD.
auto TC = VD->getDeclContext()->getInnermostTypeContext();
NominalTypeDecl *NTD = dyn_cast_or_null<NominalTypeDecl>(TC);
if (!NTD) {
ExtensionDecl *ED = dyn_cast_or_null<ExtensionDecl>(TC);
if (ED) {
if (auto T = ED->getExtendedType())
NTD = T->getAnyNominal();
}
}
if (!NTD)
return Type();
Type Result;
// Walk the type tree to find the a sub-type who's convertible to the
// found nominal.
Ty.visit([&](Type T) {
if (!Result && (T->getAnyNominal() == NTD ||
isConvertibleTo(T, NTD->getDeclaredType(),
VD->getDeclContext()))) {
Result = T;
}
});
return Result;
}
void layoutRecord() {
auto kind = FieldDescriptorKind::Struct;
if (auto CD = dyn_cast<ClassDecl>(NTD)) {
auto type = CD->getDeclaredType()->getCanonicalType();
auto RC = getReferenceCountingForType(IGM, type);
if (RC == ReferenceCounting::ObjC)
kind = FieldDescriptorKind::ObjCClass;
else
kind = FieldDescriptorKind::Class;
}
B.addInt16(uint16_t(kind));
B.addInt16(fieldRecordSize);
// Imported classes don't need field descriptors
if (NTD->hasClangNode() && isa<ClassDecl>(NTD)) {
B.addInt32(0);
return;
}
assert(!NTD->hasClangNode() || isa<StructDecl>(NTD));
auto properties = NTD->getStoredProperties();
B.addInt32(std::distance(properties.begin(), properties.end()));
for (auto property : properties)
addFieldDecl(property,
property->getInterfaceType()
->getCanonicalType());
}
static void lookupDeclsFromProtocolsBeingConformedTo(
Type BaseTy, VisibleDeclConsumer &Consumer, LookupState LS,
const DeclContext *FromContext, DeclVisibilityKind Reason,
LazyResolver *TypeResolver, VisitedSet &Visited) {
NominalTypeDecl *CurrNominal = BaseTy->getAnyNominal();
if (!CurrNominal)
return;
for (auto Conformance : CurrNominal->getAllConformances()) {
auto Proto = Conformance->getProtocol();
if (!Proto->isAccessibleFrom(FromContext))
continue;
DeclVisibilityKind ReasonForThisProtocol;
if (Reason == DeclVisibilityKind::MemberOfCurrentNominal)
ReasonForThisProtocol =
DeclVisibilityKind::MemberOfProtocolImplementedByCurrentNominal;
else
ReasonForThisProtocol = getReasonForSuper(Reason);
auto NormalConformance = Conformance->getRootNormalConformance();
for (auto Member : Proto->getMembers()) {
if (auto *ATD = dyn_cast<AssociatedTypeDecl>(Member)) {
// Skip type decls if they aren't visible, or any type that has a
// witness. This cuts down on duplicates.
if (areTypeDeclsVisibleInLookupMode(LS) &&
!NormalConformance->hasTypeWitness(ATD)) {
Consumer.foundDecl(ATD, ReasonForThisProtocol);
}
continue;
}
if (auto *VD = dyn_cast<ValueDecl>(Member)) {
if (TypeResolver) {
TypeResolver->resolveDeclSignature(VD);
if (!NormalConformance->hasWitness(VD) &&
(Conformance->getDeclContext()->getParentSourceFile() !=
FromContext->getParentSourceFile()))
TypeResolver->resolveWitness(NormalConformance, VD);
}
// Skip value requirements that have corresponding witnesses. This cuts
// down on duplicates.
if (!NormalConformance->hasWitness(VD) ||
!NormalConformance->getWitness(VD, nullptr) ||
NormalConformance->getWitness(VD, nullptr).getDecl()->getFullName()
!= VD->getFullName()) {
Consumer.foundDecl(VD, ReasonForThisProtocol);
}
}
}
// Add members from any extensions.
SmallVector<ValueDecl *, 2> FoundDecls;
doGlobalExtensionLookup(BaseTy, Proto->getDeclaredType(), FoundDecls,
FromContext, LS, ReasonForThisProtocol,
TypeResolver);
for (auto *VD : FoundDecls)
Consumer.foundDecl(VD, ReasonForThisProtocol);
}
}
void layout() {
using swift::reflection::FieldDescriptorKind;
PrettyStackTraceDecl DebugStack("emitting field type metadata", NTD);
auto type = NTD->getDeclaredType()->getCanonicalType();
addTypeRef(NTD->getModuleContext(), type);
switch (NTD->getKind()) {
case DeclKind::Class:
case DeclKind::Struct: {
auto properties = NTD->getStoredProperties();
addConstantInt16(uint16_t(isa<StructDecl>(NTD)
? FieldDescriptorKind::Struct
: FieldDescriptorKind::Class));
addConstantInt16(fieldRecordSize);
addConstantInt32(std::distance(properties.begin(), properties.end()));
for (auto property : properties)
addFieldDecl(property,
property->getInterfaceType()
->getCanonicalType());
break;
}
case DeclKind::Enum: {
auto enumDecl = cast<EnumDecl>(NTD);
auto cases = enumDecl->getAllElements();
addConstantInt16(uint16_t(FieldDescriptorKind::Enum));
addConstantInt16(fieldRecordSize);
addConstantInt32(std::distance(cases.begin(), cases.end()));
for (auto enumCase : cases) {
if (enumCase->hasArgumentType()) {
addFieldDecl(enumCase,
enumCase->getArgumentInterfaceType()
->getCanonicalType());
} else {
addFieldDecl(enumCase, CanType());
}
}
break;
}
case DeclKind::Protocol: {
auto protocolDecl = cast<ProtocolDecl>(NTD);
FieldDescriptorKind Kind;
if (protocolDecl->isObjC())
Kind = FieldDescriptorKind::ObjCProtocol;
else if (protocolDecl->requiresClass())
Kind = FieldDescriptorKind::ClassProtocol;
else
Kind = FieldDescriptorKind::Protocol;
addConstantInt16(uint16_t(Kind));
addConstantInt16(fieldRecordSize);
addConstantInt32(0);
break;
}
default:
llvm_unreachable("Not a nominal type");
break;
}
}
/// Recursively traverse the conformance lists to determine sole conforming
/// class, struct or enum type.
NominalTypeDecl *
ProtocolConformanceAnalysis::findSoleConformingType(ProtocolDecl *Protocol) {
/// First check in the SoleConformingTypeCache.
auto SoleConformingTypeIt = SoleConformingTypeCache.find(Protocol);
if (SoleConformingTypeIt != SoleConformingTypeCache.end())
return SoleConformingTypeIt->second;
SmallVector<ProtocolDecl *, 8> PDWorkList;
SmallPtrSet<ProtocolDecl *, 8> VisitedPDs;
NominalTypeDecl *SoleConformingNTD = nullptr;
PDWorkList.push_back(Protocol);
while (!PDWorkList.empty()) {
auto *PD = PDWorkList.pop_back_val();
// Protocols must have internal or lower access.
if (PD->getEffectiveAccess() > AccessLevel::Internal) {
return nullptr;
}
VisitedPDs.insert(PD);
auto NTDList = getConformances(PD);
for (auto *ConformingNTD : NTDList) {
// Recurse on protocol types.
if (auto *Proto = dyn_cast<ProtocolDecl>(ConformingNTD)) {
// Ignore visited protocol decls.
if (!VisitedPDs.count(Proto))
PDWorkList.push_back(Proto);
} else { // Classes, Structs and Enums are added here.
// Bail if more than one conforming types were found.
if (SoleConformingNTD && ConformingNTD != SoleConformingNTD) {
return nullptr;
} else {
SoleConformingNTD = ConformingNTD;
}
}
}
}
// Bail if we did not find a sole conforming type.
if (!SoleConformingNTD)
return nullptr;
// Generic declarations are ignored.
if (SoleConformingNTD->isGenericContext()) {
return nullptr;
}
// Populate SoleConformingTypeCache.
SoleConformingTypeCache.insert(std::pair<ProtocolDecl *, NominalTypeDecl *>(
Protocol, SoleConformingNTD));
// Return SoleConformingNTD.
return SoleConformingNTD;
}
static unsigned getIndexForValueDecl(ValueDecl *Decl) {
NominalTypeDecl *D = cast<NominalTypeDecl>(Decl->getDeclContext());
unsigned i = 0;
for (auto *V : D->getStoredProperties()) {
if (V == Decl)
return i;
++i;
}
llvm_unreachable("Failed to find Decl in its decl context?!");
}
static bool shouldPrintAsFavorable(const Decl *D, PrintOptions &Options) {
if (!Options.TransformContext ||
!D->getDeclContext()->isExtensionContext() ||
!Options.TransformContext->isPrintingSynthesizedExtension())
return true;
NominalTypeDecl *Target = Options.TransformContext->getNominal();
Type BaseTy = Target->getDeclaredTypeInContext();
const auto *FD = dyn_cast<FuncDecl>(D);
if (!FD)
return true;
ResolvedMemberResult Result =
resolveValueMember(*Target->getDeclContext(), BaseTy,
FD->getEffectiveFullName());
return !(Result.hasBestOverload() && Result.getBestOverload() != D);
}
Implementation(NominalTypeDecl *Target,
bool IncludeUnconditional,
PrintOptions Options):
Target(Target),
BaseType(Target->getDeclaredInterfaceType()),
DC(Target),
IncludeUnconditional(IncludeUnconditional),
Options(Options), AllGroups(MergeGroupVector()),
InfoMap(collectSynthesizedExtensionInfo(AllGroups)) {}
bool IRGenerator::canEmitWitnessTableLazily(SILWitnessTable *wt) {
if (Opts.UseJIT)
return false;
NominalTypeDecl *ConformingTy =
wt->getConformance()->getType()->getNominalOrBoundGenericNominal();
switch (ConformingTy->getEffectiveAccess()) {
case AccessLevel::Private:
case AccessLevel::FilePrivate:
return true;
case AccessLevel::Internal:
return PrimaryIGM->getSILModule().isWholeModule();
default:
return false;
}
llvm_unreachable("switch does not handle all cases");
}
/// \brief Enumerate immediate members of the type \c LookupType and its
/// extensions, as seen from the context \c CurrDC.
///
/// Don't do lookup into superclasses or implemented protocols. Uses
/// \p BaseType as the underlying type when checking any constraints on the
/// extensions.
static void lookupTypeMembers(Type BaseType, Type LookupType,
VisibleDeclConsumer &Consumer,
const DeclContext *CurrDC, LookupState LS,
DeclVisibilityKind Reason,
LazyResolver *TypeResolver) {
NominalTypeDecl *D = LookupType->getAnyNominal();
assert(D && "should have a nominal type");
bool LookupFromChildDeclContext = false;
const DeclContext *TempDC = CurrDC;
while (!TempDC->isModuleContext()) {
if (TempDC == D) {
LookupFromChildDeclContext = true;
break;
}
TempDC = TempDC->getParent();
}
SmallVector<ValueDecl*, 2> FoundDecls;
if (LookupFromChildDeclContext) {
// Current decl context is contained inside 'D', so generic parameters
// are visible.
if (D->getGenericParams())
for (auto Param : *D->getGenericParams())
if (isDeclVisibleInLookupMode(Param, LS, CurrDC, TypeResolver))
FoundDecls.push_back(Param);
}
for (Decl *Member : D->getMembers()) {
if (auto *VD = dyn_cast<ValueDecl>(Member))
if (isDeclVisibleInLookupMode(VD, LS, CurrDC, TypeResolver))
FoundDecls.push_back(VD);
}
doGlobalExtensionLookup(BaseType, LookupType, FoundDecls, CurrDC, LS, Reason,
TypeResolver);
// Report the declarations we found to the consumer.
for (auto *VD : FoundDecls)
Consumer.foundDecl(VD, Reason);
}
void findExtensionsFromConformingProtocols(Decl *D,
llvm::SmallPtrSetImpl<ExtensionDecl*> &Results) {
NominalTypeDecl* NTD = dyn_cast<NominalTypeDecl>(D);
if (!NTD || NTD->getKind() == DeclKind::Protocol)
return;
std::vector<NominalTypeDecl*> Unhandled;
auto addTypeLocNominal = [&](TypeLoc TL){
if (TL.getType()) {
if (auto D = TL.getType()->getAnyNominal()) {
Unhandled.push_back(D);
}
}
};
for (auto TL : NTD->getInherited()) {
addTypeLocNominal(TL);
}
while(!Unhandled.empty()) {
NominalTypeDecl* Back = Unhandled.back();
Unhandled.pop_back();
for (ExtensionDecl *E : Back->getExtensions()) {
if(E->isConstrainedExtension())
Results.insert(E);
for (auto TL : Back->getInherited()) {
addTypeLocNominal(TL);
}
}
}
}
static Type findBaseTypeForReplacingArchetype(const ValueDecl *VD, const Type Ty) {
if (Ty.isNull())
return Type();
// Find the nominal type decl related to VD.
NominalTypeDecl *NTD = VD->getDeclContext()->
getAsNominalTypeOrNominalTypeExtensionContext();
if (!NTD)
return Type();
Type Result;
// Walk the type tree to find the a sub-type who's convertible to the
// found nominal.
Ty.visit([&](Type T) {
if (!Result && (T->getAnyNominal() == NTD ||
isConvertibleTo(T, NTD->getDeclaredType(),
VD->getDeclContext()))) {
Result = T;
}
});
return Result;
}
/// Enumerate immediate members of the type \c LookupType and its
/// extensions, as seen from the context \c CurrDC.
///
/// Don't do lookup into superclasses or implemented protocols. Uses
/// \p BaseType as the underlying type when checking any constraints on the
/// extensions.
static void lookupTypeMembers(Type BaseType, Type LookupType,
VisibleDeclConsumer &Consumer,
const DeclContext *CurrDC, LookupState LS,
DeclVisibilityKind Reason,
LazyResolver *TypeResolver) {
NominalTypeDecl *D = LookupType->getAnyNominal();
assert(D && "should have a nominal type");
SmallVector<ValueDecl*, 2> FoundDecls;
for (Decl *Member : D->getMembers()) {
if (auto *VD = dyn_cast<ValueDecl>(Member))
if (isDeclVisibleInLookupMode(VD, LS, CurrDC, TypeResolver))
FoundDecls.push_back(VD);
}
doGlobalExtensionLookup(BaseType, LookupType, FoundDecls, CurrDC, LS, Reason,
TypeResolver);
// Report the declarations we found to the consumer.
for (auto *VD : FoundDecls)
Consumer.foundDecl(VD, Reason);
}
SmallVector<ProtocolConformance *, 2>
DeclContext::getLocalConformances(
ConformanceLookupKind lookupKind,
SmallVectorImpl<ConformanceDiagnostic> *diagnostics,
bool sorted) const
{
SmallVector<ProtocolConformance *, 2> result;
// Dig out the nominal type.
NominalTypeDecl *nominal = isNominalTypeOrNominalTypeExtensionContext();
if (!nominal)
return result;
// Protocols don't have conformances.
if (isa<ProtocolDecl>(nominal))
return { };
// Update to record all potential conformances.
nominal->prepareConformanceTable();
nominal->ConformanceTable->lookupConformances(
nominal,
const_cast<DeclContext *>(this),
nominal->getASTContext().getLazyResolver(),
lookupKind,
nullptr,
&result,
diagnostics);
// If requested, sort the results.
if (sorted) {
llvm::array_pod_sort(result.begin(), result.end(),
&ConformanceLookupTable::compareProtocolConformances);
}
return result;
}
void layout() override {
if (NTD->hasClangNode() &&
!isa<ClassDecl>(NTD) &&
!isa<StructDecl>(NTD) &&
!isa<ProtocolDecl>(NTD))
return;
PrettyStackTraceDecl DebugStack("emitting field type metadata", NTD);
addNominalRef(NTD);
auto *CD = dyn_cast<ClassDecl>(NTD);
if (CD && CD->getSuperclass()) {
addTypeRef(CD->getSuperclass()->getCanonicalType());
} else {
B.addInt32(0);
}
switch (NTD->getKind()) {
case DeclKind::Class:
case DeclKind::Struct:
layoutRecord();
break;
case DeclKind::Enum:
layoutEnum();
break;
case DeclKind::Protocol:
layoutProtocol();
break;
default:
llvm_unreachable("Not a nominal type");
break;
}
}
std::unique_ptr<ExtensionInfoMap>
collectSynthesizedExtensionInfoForProtocol(MergeGroupVector &AllGroups) {
std::unique_ptr<ExtensionInfoMap> InfoMap(new ExtensionInfoMap());
ExtensionMergeInfoMap MergeInfoMap;
for (auto *E : Target->getExtensions()) {
if (!Options.shouldPrint(E))
continue;
auto Pair = isApplicable(E, /*Synthesized*/false);
if (Pair.first) {
InfoMap->insert({E, Pair.first});
MergeInfoMap.insert({E, Pair.second});
}
}
populateMergeGroup(*InfoMap, MergeInfoMap, AllGroups,
/*AllowMergeWithDefBody*/false);
std::sort(AllGroups.begin(), AllGroups.end());
for (auto &Group : AllGroups) {
Group.sortMembers();
}
return InfoMap;
}
//===----------------------------------------------------------------------===//
// Qualified name lookup handling
//===----------------------------------------------------------------------===//
bool IterativeTypeChecker::isQualifiedLookupInDeclContextSatisfied(
TypeCheckRequest::DeclContextLookupPayloadType payload) {
auto dc = payload.DC;
NominalTypeDecl *nominal = nullptr;
switch (dc->getContextKind()) {
case DeclContextKind::AbstractClosureExpr:
case DeclContextKind::AbstractFunctionDecl:
case DeclContextKind::Initializer:
case DeclContextKind::TopLevelCodeDecl:
case DeclContextKind::SerializedLocal:
case DeclContextKind::SubscriptDecl:
llvm_unreachable("not a DeclContext that supports name lookup");
case DeclContextKind::Module:
case DeclContextKind::FileUnit:
// Modules and file units can always handle name lookup.
return true;
case DeclContextKind::GenericTypeDecl:
// Get the nominal type.
nominal = dyn_cast<NominalTypeDecl>(cast<GenericTypeDecl>(dc));
if (!nominal) return true;
break;
case DeclContextKind::ExtensionDecl: {
auto ext = cast<ExtensionDecl>(dc);
// FIXME: bind the extension. We currently assume this is done.
nominal = ext->getAsNominalTypeOrNominalTypeExtensionContext();
if (!nominal) return true;
break;
}
}
assert(nominal && "Only nominal types are handled here");
// FIXME: Cache a bit indicating when qualified lookup is possible.
// If we needed them for this query, did we already add implicit
// initializers?
auto name = payload.Name;
if ((!name || name.matchesRef(getASTContext().Id_init)) &&
!nominal->addedImplicitInitializers())
return false;
// For classes, check the superclass.
if (auto classDecl = dyn_cast<ClassDecl>(nominal)) {
if (!isSatisfied(requestTypeCheckSuperclass(classDecl)))
return false;
if (auto superclass = classDecl->getSuperclass()) {
if (auto superclassDecl = superclass->getAnyNominal()) {
if (!isSatisfied(requestQualifiedLookupInDeclContext({ superclassDecl,
payload.Name,
payload.Loc })))
return false;
}
}
}
return true;
}
std::unique_ptr<ExtensionInfoMap>
collectSynthesizedExtensionInfo(MergeGroupVector &AllGroups) {
if (isa<ProtocolDecl>(Target)) {
return collectSynthesizedExtensionInfoForProtocol(AllGroups);
}
std::unique_ptr<ExtensionInfoMap> InfoMap(new ExtensionInfoMap());
ExtensionMergeInfoMap MergeInfoMap;
std::vector<NominalTypeDecl*> Unhandled;
auto handleExtension = [&](ExtensionDecl *E, bool Synthesized,
ExtensionDecl *EnablingE,
NormalProtocolConformance *Conf) {
if (Options.shouldPrint(E)) {
auto Pair = isApplicable(E, Synthesized, EnablingE, Conf);
if (Pair.first) {
InfoMap->insert({E, Pair.first});
MergeInfoMap.insert({E, Pair.second});
}
}
};
for (auto *Conf : Target->getLocalConformances()) {
Unhandled.push_back(Conf->getProtocol());
}
if (auto *CD = dyn_cast<ClassDecl>(Target)) {
if (auto Super = CD->getSuperclassDecl())
Unhandled.push_back(Super);
}
while (!Unhandled.empty()) {
NominalTypeDecl* Back = Unhandled.back();
Unhandled.pop_back();
for (ExtensionDecl *E : Back->getExtensions()) {
handleExtension(E, true, nullptr, nullptr);
}
for (auto *Conf : Back->getLocalConformances()) {
Unhandled.push_back(Conf->getProtocol());
}
if (auto *CD = dyn_cast<ClassDecl>(Back)) {
if (auto Super = CD->getSuperclass())
Unhandled.push_back(Super->getAnyNominal());
}
}
// Merge with actual extensions.
for (auto *EnablingE : Target->getExtensions()) {
handleExtension(EnablingE, false, nullptr, nullptr);
for (auto *Conf : EnablingE->getLocalConformances()) {
for (auto E : Conf->getProtocol()->getExtensions())
handleExtension(E, true, EnablingE, Conf->getRootNormalConformance());
}
}
populateMergeGroup(*InfoMap, MergeInfoMap, AllGroups,
/*AllowMergeWithDefBody*/true);
std::sort(AllGroups.begin(), AllGroups.end());
for (auto &Group : AllGroups) {
Group.removeUnfavored(Target);
Group.sortMembers();
}
AllGroups.erase(std::remove_if(AllGroups.begin(), AllGroups.end(),
[](ExtensionMergeGroup &Group) { return Group.Members.empty(); }),
AllGroups.end());
return InfoMap;
}
void layout() {
using swift::reflection::FieldDescriptorKind;
PrettyStackTraceDecl DebugStack("emitting field type metadata", NTD);
auto type = NTD->getDeclaredType()->getCanonicalType();
addTypeRef(NTD->getModuleContext(), type);
if (NTD->hasClangNode() &&
!isa<ClassDecl>(NTD) &&
!isa<ProtocolDecl>(NTD))
return;
switch (NTD->getKind()) {
case DeclKind::Class:
case DeclKind::Struct: {
auto kind = FieldDescriptorKind::Struct;
if (auto CD = dyn_cast<ClassDecl>(NTD)) {
auto RC = getReferenceCountingForClass(IGM, const_cast<ClassDecl *>(CD));
if (RC == ReferenceCounting::ObjC)
kind = FieldDescriptorKind::ObjCClass;
else
kind = FieldDescriptorKind::Class;
}
addConstantInt16(uint16_t(kind));
addConstantInt16(fieldRecordSize);
// Imported classes don't need field descriptors
if (NTD->hasClangNode()) {
assert(isa<ClassDecl>(NTD));
addConstantInt32(0);
break;
}
auto properties = NTD->getStoredProperties();
addConstantInt32(std::distance(properties.begin(), properties.end()));
for (auto property : properties)
addFieldDecl(property,
property->getInterfaceType()
->getCanonicalType());
break;
}
case DeclKind::Enum: {
auto enumDecl = cast<EnumDecl>(NTD);
auto cases = enumDecl->getAllElements();
addConstantInt16(uint16_t(FieldDescriptorKind::Enum));
addConstantInt16(fieldRecordSize);
addConstantInt32(std::distance(cases.begin(), cases.end()));
for (auto enumCase : cases) {
if (enumCase->hasArgumentType()) {
addFieldDecl(enumCase,
enumCase->getArgumentInterfaceType()
->getCanonicalType());
} else {
addFieldDecl(enumCase, CanType());
}
}
break;
}
case DeclKind::Protocol: {
auto protocolDecl = cast<ProtocolDecl>(NTD);
FieldDescriptorKind Kind;
if (protocolDecl->isObjC())
Kind = FieldDescriptorKind::ObjCProtocol;
else if (protocolDecl->requiresClass())
Kind = FieldDescriptorKind::ClassProtocol;
else
Kind = FieldDescriptorKind::Protocol;
addConstantInt16(uint16_t(Kind));
addConstantInt16(fieldRecordSize);
addConstantInt32(0);
break;
}
default:
llvm_unreachable("Not a nominal type");
break;
}
}
static void bindExtensionDecl(ExtensionDecl *ED, TypeChecker &TC) {
if (ED->getExtendedType())
return;
// If we didn't parse a type, fill in an error type and bail out.
if (!ED->getExtendedTypeLoc().getTypeRepr()) {
ED->setInvalid();
ED->getExtendedTypeLoc().setInvalidType(TC.Context);
return;
}
auto dc = ED->getDeclContext();
// Validate the representation.
// FIXME: Perform some kind of "shallow" validation here?
TypeResolutionOptions options;
options |= TR_AllowUnboundGenerics;
options |= TR_ExtensionBinding;
if (TC.validateType(ED->getExtendedTypeLoc(), dc, options)) {
ED->setInvalid();
return;
}
// Dig out the extended type.
auto extendedType = ED->getExtendedType();
// Hack to allow extending a generic typealias.
if (auto *unboundGeneric = extendedType->getAs<UnboundGenericType>()) {
if (auto *aliasDecl = dyn_cast<TypeAliasDecl>(unboundGeneric->getDecl())) {
auto extendedNominal = aliasDecl->getDeclaredInterfaceType()->getAnyNominal();
if (extendedNominal) {
extendedType = extendedNominal->getDeclaredType();
ED->getExtendedTypeLoc().setType(extendedType);
}
}
}
// Handle easy cases.
// Cannot extend a metatype.
if (extendedType->is<AnyMetatypeType>()) {
TC.diagnose(ED->getLoc(), diag::extension_metatype, extendedType)
.highlight(ED->getExtendedTypeLoc().getSourceRange());
ED->setInvalid();
ED->getExtendedTypeLoc().setInvalidType(TC.Context);
return;
}
// Cannot extend a bound generic type.
if (extendedType->isSpecialized()) {
TC.diagnose(ED->getLoc(), diag::extension_specialization,
extendedType->getAnyNominal()->getName())
.highlight(ED->getExtendedTypeLoc().getSourceRange());
ED->setInvalid();
ED->getExtendedTypeLoc().setInvalidType(TC.Context);
return;
}
// Dig out the nominal type being extended.
NominalTypeDecl *extendedNominal = extendedType->getAnyNominal();
if (!extendedNominal) {
TC.diagnose(ED->getLoc(), diag::non_nominal_extension, extendedType)
.highlight(ED->getExtendedTypeLoc().getSourceRange());
ED->setInvalid();
ED->getExtendedTypeLoc().setInvalidType(TC.Context);
return;
}
assert(extendedNominal && "Should have the nominal type being extended");
// If the extended type is generic or is a protocol. Clone or create
// the generic parameters.
if (extendedNominal->isGenericContext()) {
if (auto proto = dyn_cast<ProtocolDecl>(extendedNominal)) {
// For a protocol extension, build the generic parameter list.
ED->setGenericParams(proto->createGenericParams(ED));
} else {
// Clone the existing generic parameter list.
ED->setGenericParams(
cloneGenericParams(TC.Context, ED,
extendedNominal->getGenericParamsOfContext()));
}
}
// If we have a trailing where clause, deal with it now.
// For now, trailing where clauses are only permitted on protocol extensions.
if (auto trailingWhereClause = ED->getTrailingWhereClause()) {
if (!extendedNominal->isGenericContext()) {
// Only generic and protocol types are permitted to have
// trailing where clauses.
TC.diagnose(ED, diag::extension_nongeneric_trailing_where, extendedType)
.highlight(trailingWhereClause->getSourceRange());
ED->setTrailingWhereClause(nullptr);
} else {
// Merge the trailing where clause into the generic parameter list.
// FIXME: Long-term, we'd like clients to deal with the trailing where
// clause explicitly, but for now it's far more direct to represent
// the trailing where clause as part of the requirements.
ED->getGenericParams()->addTrailingWhereClause(
TC.Context,
trailingWhereClause->getWhereLoc(),
trailingWhereClause->getRequirements());
}
}
extendedNominal->addExtension(ED);
}
ProtocolConformance *ConformanceLookupTable::getConformance(
NominalTypeDecl *nominal,
LazyResolver *resolver,
ConformanceEntry *entry) {
// If we already have a conformance, we're done.
if (auto conformance = entry->getConformance())
return conformance;
ProtocolDecl *protocol = entry->getProtocol();
// Determine where the explicit conformance actually lives.
// FIXME: This is a hack to ensure that inherited conformances are
// always "single step", which is bad for resilience but is assumed
// elsewhere in the compiler.
DeclContext *conformingDC = getConformingContext(nominal, resolver, entry);
if (!conformingDC)
return nullptr;
NominalTypeDecl *conformingNominal
= conformingDC->isNominalTypeOrNominalTypeExtensionContext();
// Form the conformance.
Type type = entry->getDeclContext()->getDeclaredTypeInContext();
ProtocolConformance *conformance;
ASTContext &ctx = nominal->getASTContext();
if (entry->getKind() == ConformanceEntryKind::Inherited) {
// For an inherited conformance, the conforming nominal type will
// be different from the nominal type.
assert(conformingNominal != nominal && "Broken inherited conformance");
// Find the superclass type that matches where the conformance was
// declared.
Type superclassTy = type->getSuperclass(resolver);
while (superclassTy->getAnyNominal() != conformingNominal)
superclassTy = superclassTy->getSuperclass(resolver);
// Look up the inherited conformance.
Module *module = entry->getDeclContext()->getParentModule();
auto inheritedConformance = module->lookupConformance(superclassTy,
protocol,
resolver)
.getPointer();
// Form the inherited conformance.
conformance = ctx.getInheritedConformance(type, inheritedConformance);
} else {
// Create or find the normal conformance.
Type conformingType = conformingDC->getDeclaredTypeInContext();
SourceLoc conformanceLoc
= conformingNominal == conformingDC
? conformingNominal->getLoc()
: cast<ExtensionDecl>(conformingDC)->getLoc();
conformance = ctx.getConformance(conformingType, protocol, conformanceLoc,
conformingDC,
ProtocolConformanceState::Incomplete);
}
// Record the conformance.
entry->Conformance = conformance;
return conformance;
}
llvm::GlobalVariable *emit() {
auto entity = LinkEntity::forReflectionFieldDescriptor(
NTD->getDeclaredType()->getCanonicalType());
auto section = IGM.getFieldTypeMetadataSectionName();
return ReflectionMetadataBuilder::emit(entity, section);
}
