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fuchsia / third_party / swift / refs/tags/swift-DEVELOPMENT-SNAPSHOT-2019-04-04-a / . / lib / PrintAsObjC / PrintAsObjC.cpp
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//===--- PrintAsObjC.cpp - Emit a header file for a Swift AST -------------===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2018 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
#include "swift/PrintAsObjC/PrintAsObjC.h"
#include "swift/Strings.h"
#include "swift/AST/ASTVisitor.h"
#include "swift/AST/ExistentialLayout.h"
#include "swift/AST/ForeignErrorConvention.h"
#include "swift/AST/GenericEnvironment.h"
#include "swift/AST/NameLookup.h"
#include "swift/AST/PrettyStackTrace.h"
#include "swift/AST/ProtocolConformance.h"
#include "swift/AST/TypeVisitor.h"
#include "swift/AST/SwiftNameTranslation.h"
#include "swift/AST/Comment.h"
#include "swift/Basic/StringExtras.h"
#include "swift/Basic/Version.h"
#include "swift/ClangImporter/ClangImporter.h"
#include "swift/Frontend/Frontend.h"
#include "swift/Frontend/PrintingDiagnosticConsumer.h"
#include "swift/IDE/CommentConversion.h"
#include "swift/Parse/Lexer.h"
#include "clang/AST/ASTContext.h"
#include "clang/AST/Attr.h"
#include "clang/AST/Decl.h"
#include "clang/AST/DeclObjC.h"
#include "clang/Basic/CharInfo.h"
#include "clang/Basic/Module.h"
#include "clang/Lex/Lexer.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/raw_ostream.h"
using namespace swift;
using namespace swift::objc_translation;
static bool isNSObjectOrAnyHashable(ASTContext &ctx, Type type) {
if (auto classDecl = type->getClassOrBoundGenericClass()) {
return classDecl->getName()
== ctx.getSwiftId(KnownFoundationEntity::NSObject) &&
classDecl->getModuleContext()->getName() == ctx.Id_ObjectiveC;
}
if (auto nomDecl = type->getAnyNominal()) {
return nomDecl == ctx.getAnyHashableDecl();
}
return false;
}
static bool isAnyObjectOrAny(Type type) {
return type->isAnyObject() || type->isAny();
}
/// Returns true if \p name matches a keyword in any Clang language mode.
static bool isClangKeyword(Identifier name) {
static const llvm::DenseSet<StringRef> keywords = []{
llvm::DenseSet<StringRef> set;
// FIXME: clang::IdentifierInfo /nearly/ has the API we need to do this
// in a more principled way, but not quite.
#define KEYWORD(SPELLING, FLAGS) \
set.insert(#SPELLING);
#define CXX_KEYWORD_OPERATOR(SPELLING, TOK) \
set.insert(#SPELLING);
#include "clang/Basic/TokenKinds.def"
return set;
}();
if (name.empty())
return false;
return keywords.find(name.str()) != keywords.end();
}
namespace {
/// Whether the type being printed is in function param position.
enum IsFunctionParam_t : bool {
IsFunctionParam = true,
IsNotFunctionParam = false,
};
} // end anonymous namespace
/// Returns true if the given selector might be classified as an init method
/// by Objective-C ARC.
static bool looksLikeInitMethod(ObjCSelector selector) {
ArrayRef<Identifier> selectorPieces = selector.getSelectorPieces();
assert(!selectorPieces.empty());
auto firstPiece = selectorPieces.front().str();
if (!firstPiece.startswith("init")) return false;
return !(firstPiece.size() > 4 && clang::isLowercase(firstPiece[4]));
}
/// Returns the name of an <os/object.h> type minus the leading "OS_",
/// or an empty string if \p decl is not an <os/object.h> type.
static StringRef maybeGetOSObjectBaseName(const clang::NamedDecl *decl) {
StringRef name = decl->getName();
if (!name.consume_front("OS_"))
return StringRef();
clang::SourceLocation loc = decl->getLocation();
if (!loc.isMacroID())
return StringRef();
// Hack: check to see if the name came from a macro in <os/object.h>.
clang::SourceManager &sourceMgr = decl->getASTContext().getSourceManager();
clang::SourceLocation expansionLoc =
sourceMgr.getImmediateExpansionRange(loc).getBegin();
clang::SourceLocation spellingLoc = sourceMgr.getSpellingLoc(expansionLoc);
if (!sourceMgr.getFilename(spellingLoc).endswith("/os/object.h"))
return StringRef();
return name;
}
/// Returns true if \p decl represents an <os/object.h> type.
static bool isOSObjectType(const clang::Decl *decl) {
auto *named = dyn_cast_or_null<clang::NamedDecl>(decl);
if (!named)
return false;
return !maybeGetOSObjectBaseName(named).empty();
}
namespace {
using DelayedMemberSet = llvm::SmallSetVector<const ValueDecl *, 32>;
class ObjCPrinter : private DeclVisitor<ObjCPrinter>,
private TypeVisitor<ObjCPrinter, void,
Optional<OptionalTypeKind>>
{
friend ASTVisitor;
friend TypeVisitor;
using NameAndOptional = std::pair<StringRef, bool>;
llvm::DenseMap<std::pair<Identifier, Identifier>, NameAndOptional>
specialNames;
Identifier ID_CFTypeRef;
ModuleDecl &M;
raw_ostream &os;
SmallVector<const FunctionType *, 4> openFunctionTypes;
const DelayedMemberSet &delayedMembers;
AccessLevel minRequiredAccess;
bool protocolMembersOptional = false;
Optional<Type> NSCopyingType;
friend ASTVisitor<ObjCPrinter>;
friend TypeVisitor<ObjCPrinter>;
public:
explicit ObjCPrinter(ModuleDecl &mod, raw_ostream &out,
DelayedMemberSet &delayed, AccessLevel access)
: M(mod), os(out), delayedMembers(delayed), minRequiredAccess(access) {}
void print(const Decl *D) {
PrettyStackTraceDecl trace("printing", D);
ASTVisitor::visit(const_cast<Decl *>(D));
}
void maybePrintObjCGenericParameters(const ClassDecl *importedClass) {
auto *clangDecl = importedClass->getClangDecl();
auto *objcClass = dyn_cast_or_null<clang::ObjCInterfaceDecl>(clangDecl);
if (!objcClass)
return;
if (!objcClass->getTypeParamList())
return;
assert(objcClass->getTypeParamList()->size() != 0);
os << "<";
interleave(*objcClass->getTypeParamList(),
[this](const clang::ObjCTypeParamDecl *param) {
os << param->getName();
},
[this] { os << ", "; });
os << ">";
}
void printAdHocCategory(iterator_range<const ValueDecl * const *> members) {
assert(members.begin() != members.end());
const DeclContext *origDC = (*members.begin())->getDeclContext();
auto *baseClass = origDC->getSelfClassDecl();
os << "@interface " << getNameForObjC(baseClass);
maybePrintObjCGenericParameters(baseClass);
os << " (SWIFT_EXTENSION(" << origDC->getParentModule()->getName()
<< "))\n";
printMembers</*allowDelayed*/true>(members);
os << "@end\n\n";
}
bool shouldInclude(const ValueDecl *VD) {
return isVisibleToObjC(VD, minRequiredAccess);
}
private:
/// Prints a protocol adoption list: <code>&lt;NSCoding, NSCopying&gt;</code>
///
/// This method filters out non-ObjC protocols.
void printProtocols(ArrayRef<ProtocolDecl *> protos) {
SmallVector<ProtocolDecl *, 4> protosToPrint;
std::copy_if(protos.begin(), protos.end(),
std::back_inserter(protosToPrint),
[this](const ProtocolDecl *PD) -> bool {
return shouldInclude(PD);
});
// Drop protocols from the list that are implied by other protocols.
ProtocolType::canonicalizeProtocols(protosToPrint);
if (protosToPrint.empty())
return;
os << " <";
interleave(protosToPrint,
[this](const ProtocolDecl *PD) { os << getNameForObjC(PD); },
[this] { os << ", "; });
os << ">";
}
/// Prints the members of a class, extension, or protocol.
template <bool AllowDelayed = false, typename R>
void printMembers(R &&members) {
for (const Decl *member : members) {
auto VD = dyn_cast<ValueDecl>(member);
if (!VD || !shouldInclude(VD) || isa<TypeDecl>(VD))
continue;
if (isa<AccessorDecl>(VD))
continue;
if (!AllowDelayed && delayedMembers.count(VD)) {
os << "// '" << VD->getFullName() << "' below\n";
continue;
}
if (VD->getAttrs().hasAttribute<OptionalAttr>() != protocolMembersOptional) {
protocolMembersOptional = VD->getAttrs().hasAttribute<OptionalAttr>();
os << (protocolMembersOptional ? "@optional\n" : "@required\n");
}
ASTVisitor::visit(const_cast<ValueDecl*>(VD));
}
}
void printDocumentationComment(Decl *D) {
swift::markup::MarkupContext MC;
auto DC = getSingleDocComment(MC, D);
if (DC.hasValue())
ide::getDocumentationCommentAsDoxygen(DC.getValue(), os);
}
/// Prints an encoded string, escaped properly for C.
void printEncodedString(StringRef str, bool includeQuotes = true) {
// NB: We don't use raw_ostream::write_escaped() because it does hex escapes
// for non-ASCII chars.
llvm::SmallString<128> Buf;
StringRef decodedStr = Lexer::getEncodedStringSegment(str, Buf);
if (includeQuotes) os << '"';
for (unsigned char c : decodedStr) {
switch (c) {
case '\\':
os << '\\' << '\\';
break;
case '\t':
os << '\\' << 't';
break;
case '\n':
os << '\\' << 'n';
break;
case '"':
os << '\\' << '"';
break;
default:
if (c < 0x20 || c == 0x7F) {
os << '\\' << 'x';
os << llvm::hexdigit((c >> 4) & 0xF);
os << llvm::hexdigit((c >> 0) & 0xF);
} else {
os << c;
}
}
}
if (includeQuotes) os << '"';
}
// For a given Decl and Type, if the type is not an optional return
// the type and OTK_None as the optionality. If the type is
// optional, return the underlying object type, and an optionality
// that is based on the type but overridden by the
// ImplicitlyUnwrappedOptionalAttr on the decl.
static std::pair<Type, OptionalTypeKind>
getObjectTypeAndOptionality(const Decl *D, Type ty) {
OptionalTypeKind kind;
if (auto objTy =
ty->getReferenceStorageReferent()->getOptionalObjectType()) {
kind = OTK_Optional;
if (D->getAttrs().hasAttribute<ImplicitlyUnwrappedOptionalAttr>())
kind = OTK_ImplicitlyUnwrappedOptional;
return {objTy, kind};
}
return {ty, OTK_None};
}
// Ignore other declarations.
void visitDecl(Decl *D) {}
void visitClassDecl(ClassDecl *CD) {
printDocumentationComment(CD);
bool hasResilientAncestry =
CD->checkAncestry().contains(AncestryFlags::ResilientOther);
if (hasResilientAncestry) {
os << "SWIFT_RESILIENT_CLASS";
} else {
os << "SWIFT_CLASS";
}
StringRef customName = getNameForObjC(CD, CustomNamesOnly);
if (customName.empty()) {
llvm::SmallString<32> scratch;
os << "(\"" << CD->getObjCRuntimeName(scratch) << "\")";
printAvailability(CD);
os << "\n@interface " << CD->getName();
} else {
os << "_NAMED(\"" << CD->getName() << "\")";
printAvailability(CD);
os << "\n@interface " << customName;
}
if (auto superDecl = CD->getSuperclassDecl())
os << " : " << getNameForObjC(superDecl);
printProtocols(CD->getLocalProtocols(ConformanceLookupKind::OnlyExplicit));
os << "\n";
printMembers(CD->getMembers());
os << "@end\n";
}
bool isEmptyExtensionDecl(ExtensionDecl *ED) {
auto members = ED->getMembers();
auto hasMembers = std::any_of(members.begin(), members.end(),
[this](const Decl *D) -> bool {
if (auto VD = dyn_cast<ValueDecl>(D))
if (shouldInclude(VD))
return true;
return false;
});
auto protocols = ED->getLocalProtocols(ConformanceLookupKind::OnlyExplicit);
auto hasProtocols = std::any_of(protocols.begin(), protocols.end(),
[this](const ProtocolDecl *PD) -> bool {
return shouldInclude(PD);
});
return (!hasMembers && !hasProtocols);
}
void visitExtensionDecl(ExtensionDecl *ED) {
if (isEmptyExtensionDecl(ED))
return;
auto baseClass = ED->getSelfClassDecl();
if (printAvailability(ED, PrintLeadingSpace::No))
os << "\n";
os << "@interface " << getNameForObjC(baseClass);
maybePrintObjCGenericParameters(baseClass);
os << " (SWIFT_EXTENSION(" << ED->getModuleContext()->getName() << "))";
printProtocols(ED->getLocalProtocols(ConformanceLookupKind::OnlyExplicit));
os << "\n";
printMembers(ED->getMembers());
os << "@end\n";
}
void visitProtocolDecl(ProtocolDecl *PD) {
printDocumentationComment(PD);
StringRef customName = getNameForObjC(PD, CustomNamesOnly);
if (customName.empty()) {
llvm::SmallString<32> scratch;
os << "SWIFT_PROTOCOL(\"" << PD->getObjCRuntimeName(scratch) << "\")";
printAvailability(PD);
os << "\n@protocol " << PD->getName();
} else {
os << "SWIFT_PROTOCOL_NAMED(\"" << PD->getName() << "\")";
printAvailability(PD);
os << "\n@protocol " << customName;
}
printProtocols(PD->getInheritedProtocols());
os << "\n";
assert(!protocolMembersOptional && "protocols start required");
printMembers(PD->getMembers());
protocolMembersOptional = false;
os << "@end\n";
}
void visitEnumDecl(EnumDecl *ED) {
printDocumentationComment(ED);
os << "typedef ";
StringRef customName = getNameForObjC(ED, CustomNamesOnly);
if (customName.empty()) {
os << "SWIFT_ENUM(";
} else {
os << "SWIFT_ENUM_NAMED(";
}
print(ED->getRawType(), OTK_None);
if (customName.empty()) {
os << ", " << ED->getName();
} else {
os << ", " << customName
<< ", \"" << ED->getName() << "\"";
}
os << ", "
<< (ED->isFormallyExhaustive(/*useDC*/nullptr) ? "closed" : "open")
<< ") {\n";
for (auto Elt : ED->getAllElements()) {
printDocumentationComment(Elt);
// Print the cases as the concatenation of the enum name with the case
// name.
os << " ";
if (printSwiftEnumElemNameInObjC(Elt, os)) {
os << " SWIFT_COMPILE_NAME(\"" << Elt->getName() << "\")";
}
if (auto ILE = cast_or_null<IntegerLiteralExpr>(Elt->getRawValueExpr())) {
os << " = ";
if (ILE->isNegative())
os << "-";
os << ILE->getDigitsText();
}
os << ",\n";
}
os << "};\n";
}
void printSingleMethodParam(StringRef selectorPiece,
const ParamDecl *param,
const clang::ParmVarDecl *clangParam,
bool isNSUIntegerSubscript,
bool isLastPiece) {
os << selectorPiece << ":(";
if ((isNSUIntegerSubscript && isLastPiece) ||
(clangParam && isNSUInteger(clangParam->getType()))) {
os << "NSUInteger";
} else {
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) =
getObjectTypeAndOptionality(param, param->getInterfaceType());
print(objTy, kind, Identifier(), IsFunctionParam);
}
os << ")";
if (!param->hasName()) {
os << "_";
} else {
Identifier name = param->getName();
os << name;
if (isClangKeyword(name))
os << "_";
}
}
template <typename T>
static const T *findClangBase(const T *member) {
while (member) {
if (member->getClangDecl())
return member;
member = member->getOverriddenDecl();
}
return nullptr;
}
/// Returns true if \p clangTy is the typedef for NSUInteger.
bool isNSUInteger(clang::QualType clangTy) {
const auto *typedefTy = dyn_cast<clang::TypedefType>(clangTy);
if (!typedefTy)
return false;
const clang::IdentifierInfo *nameII = typedefTy->getDecl()->getIdentifier();
if (!nameII)
return false;
if (nameII->getName() != "NSUInteger")
return false;
return true;
}
Type getForeignResultType(AbstractFunctionDecl *AFD,
FunctionType *methodTy,
Optional<ForeignErrorConvention> errorConvention) {
// A foreign error convention can affect the result type as seen in
// Objective-C.
if (errorConvention) {
switch (errorConvention->getKind()) {
case ForeignErrorConvention::ZeroResult:
case ForeignErrorConvention::NonZeroResult:
// The error convention provides the result type.
return errorConvention->getResultType();
case ForeignErrorConvention::NilResult:
// Errors are propagated via 'nil' returns.
return OptionalType::get(methodTy->getResult());
case ForeignErrorConvention::NonNilError:
case ForeignErrorConvention::ZeroPreservedResult:
break;
}
}
auto result = methodTy->getResult();
if (result->isUninhabited())
return M.getASTContext().TheEmptyTupleType;
return result;
}
/// Returns true if \p sel is the no-argument selector 'init'.
static bool selectorIsInit(ObjCSelector sel) {
return sel.getNumArgs() == 0 &&
sel.getSelectorPieces().front().str() == "init";
}
void printAbstractFunctionAsMethod(AbstractFunctionDecl *AFD,
bool isClassMethod,
bool isNSUIntegerSubscript = false) {
printDocumentationComment(AFD);
if (isClassMethod)
os << "+ (";
else
os << "- (";
const clang::ObjCMethodDecl *clangMethod = nullptr;
if (!isNSUIntegerSubscript) {
if (const AbstractFunctionDecl *clangBase = findClangBase(AFD)) {
clangMethod =
dyn_cast_or_null<clang::ObjCMethodDecl>(clangBase->getClangDecl());
}
}
Optional<ForeignErrorConvention> errorConvention
= AFD->getForeignErrorConvention();
Type rawMethodTy = AFD->getMethodInterfaceType();
auto methodTy = rawMethodTy->castTo<FunctionType>();
auto resultTy = getForeignResultType(AFD, methodTy, errorConvention);
// Constructors and methods returning DynamicSelf return
// instancetype.
if (isa<ConstructorDecl>(AFD) ||
(isa<FuncDecl>(AFD) && cast<FuncDecl>(AFD)->hasDynamicSelf())) {
if (errorConvention && errorConvention->stripsResultOptionality()) {
printNullability(OTK_Optional, NullabilityPrintKind::ContextSensitive);
} else if (auto ctor = dyn_cast<ConstructorDecl>(AFD)) {
printNullability(ctor->getFailability(),
NullabilityPrintKind::ContextSensitive);
} else {
auto func = cast<FuncDecl>(AFD);
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) =
getObjectTypeAndOptionality(func, func->getResultInterfaceType());
printNullability(kind,
NullabilityPrintKind::ContextSensitive);
}
os << "instancetype";
} else if (resultTy->isVoid() &&
AFD->getAttrs().hasAttribute<IBActionAttr>()) {
os << "IBAction";
} else if (clangMethod && isNSUInteger(clangMethod->getReturnType())) {
os << "NSUInteger";
} else {
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) = getObjectTypeAndOptionality(AFD, resultTy);
print(objTy, kind);
}
os << ")";
auto selector = AFD->getObjCSelector();
ArrayRef<Identifier> selectorPieces = selector.getSelectorPieces();
const auto &params = AFD->getParameters()->getArray();
unsigned paramIndex = 0;
for (unsigned i = 0, n = selectorPieces.size(); i != n; ++i) {
if (i > 0) os << ' ';
// Retrieve the selector piece.
StringRef piece = selectorPieces[i].empty() ? StringRef("")
: selectorPieces[i].str();
// If we have an error convention and this is the error
// parameter, print it.
if (errorConvention && i == errorConvention->getErrorParameterIndex()) {
os << piece << ":(";
print(errorConvention->getErrorParameterType(), None);
os << ")error";
continue;
}
// Zero-parameter initializers with a long selector.
if (isa<ConstructorDecl>(AFD) &&
cast<ConstructorDecl>(AFD)->isObjCZeroParameterWithLongSelector()) {
os << piece;
continue;
}
// Zero-parameter methods.
if (params.empty()) {
assert(paramIndex == 0);
os << piece;
paramIndex = 1;
continue;
}
const clang::ParmVarDecl *clangParam = nullptr;
if (clangMethod)
clangParam = clangMethod->parameters()[paramIndex];
// Single-parameter methods.
printSingleMethodParam(piece, params[paramIndex], clangParam,
isNSUIntegerSubscript, i == n-1);
++paramIndex;
}
bool skipAvailability = false;
bool makeNewUnavailable = false;
bool makeNewExplicitlyAvailable = false;
// Swift designated initializers are Objective-C designated initializers.
if (auto ctor = dyn_cast<ConstructorDecl>(AFD)) {
if (ctor->hasStubImplementation()
|| ctor->getFormalAccess() < minRequiredAccess) {
// This will only be reached if the overridden initializer has the
// required access
os << " SWIFT_UNAVAILABLE";
skipAvailability = true;
// If -init is unavailable, then +new should be, too:
makeNewUnavailable = selectorIsInit(selector);
} else {
if (ctor->isDesignatedInit() &&
!isa<ProtocolDecl>(ctor->getDeclContext())) {
os << " OBJC_DESIGNATED_INITIALIZER";
}
// If -init is newly available, +new should be as well if the class
// inherits from NSObject.
if (selectorIsInit(selector) && !ctor->getOverriddenDecl()) {
auto container = ctor->getDeclContext();
auto *classDecl = container->getSelfClassDecl();
if (!classDecl) {
assert(container->getSelfProtocolDecl());
} else {
while (classDecl->hasSuperclass()) {
classDecl = classDecl->getSuperclassDecl();
assert(classDecl &&
"shouldn't PrintAsObjC with invalid superclasses");
}
if (classDecl->hasClangNode() &&
classDecl->getNameStr() == "NSObject") {
makeNewExplicitlyAvailable = true;
}
}
}
}
if (!looksLikeInitMethod(AFD->getObjCSelector())) {
os << " SWIFT_METHOD_FAMILY(init)";
}
} else {
if (looksLikeInitMethod(AFD->getObjCSelector())) {
os << " SWIFT_METHOD_FAMILY(none)";
}
if (methodTy->getResult()->isUninhabited()) {
os << " SWIFT_NORETURN";
} else if (!methodTy->getResult()->isVoid() &&
!AFD->getAttrs().hasAttribute<DiscardableResultAttr>()) {
os << " SWIFT_WARN_UNUSED_RESULT";
}
}
if (!skipAvailability) {
printAvailability(AFD);
}
if (auto accessor = dyn_cast<AccessorDecl>(AFD)) {
printSwift3ObjCDeprecatedInference(accessor->getStorage());
} else {
printSwift3ObjCDeprecatedInference(AFD);
}
os << ";\n";
if (makeNewUnavailable) {
assert(!makeNewExplicitlyAvailable);
// Downgrade this to a warning in pre-Swift-5 mode. This isn't perfect
// because it's a diagnostic inflicted on /clients/, but it's close
// enough. It really is invalid to call +new when -init is unavailable.
StringRef annotationName = "SWIFT_UNAVAILABLE_MSG";
if (!M.getASTContext().isSwiftVersionAtLeast(5))
annotationName = "SWIFT_DEPRECATED_MSG";
os << "+ (nonnull instancetype)new " << annotationName
<< "(\"-init is unavailable\");\n";
} else if (makeNewExplicitlyAvailable) {
os << "+ (nonnull instancetype)new;\n";
}
}
void printAbstractFunctionAsFunction(FuncDecl *FD) {
printDocumentationComment(FD);
Optional<ForeignErrorConvention> errorConvention
= FD->getForeignErrorConvention();
assert(!FD->getGenericSignature() &&
"top-level generic functions not supported here");
auto funcTy = FD->getInterfaceType()->castTo<FunctionType>();
auto resultTy = getForeignResultType(FD, funcTy, errorConvention);
// The result type may be a partial function type we need to close
// up later.
PrintMultiPartType multiPart(*this);
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) = getObjectTypeAndOptionality(FD, resultTy);
visitPart(objTy, kind);
assert(FD->getAttrs().hasAttribute<CDeclAttr>()
&& "not a cdecl function");
os << ' ' << FD->getAttrs().getAttribute<CDeclAttr>()->Name << '(';
auto params = FD->getParameters();
if (params->size()) {
interleave(*params,
[&](const ParamDecl *param) {
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) = getObjectTypeAndOptionality(
param, param->getInterfaceType());
print(objTy, kind, param->getName(), IsFunctionParam);
},
[&] { os << ", "; });
} else {
os << "void";
}
os << ')';
// Finish the result type.
multiPart.finish();
if (funcTy->getResult()->isUninhabited()) {
os << " SWIFT_NORETURN";
} else if (!funcTy->getResult()->isVoid() &&
!FD->getAttrs().hasAttribute<DiscardableResultAttr>()) {
os << " SWIFT_WARN_UNUSED_RESULT";
}
printAvailability(FD);
os << ';';
}
enum class PrintLeadingSpace : bool {
No = false,
Yes = true
};
/// Returns \c true if anything was printed.
bool printAvailability(const Decl *D, PrintLeadingSpace printLeadingSpace =
PrintLeadingSpace::Yes) {
bool hasPrintedAnything = false;
auto maybePrintLeadingSpace = [&] {
if (printLeadingSpace == PrintLeadingSpace::Yes || hasPrintedAnything)
os << " ";
hasPrintedAnything = true;
};
for (auto AvAttr : D->getAttrs().getAttributes<AvailableAttr>()) {
if (AvAttr->Platform == PlatformKind::none) {
if (AvAttr->PlatformAgnostic ==
PlatformAgnosticAvailabilityKind::Unavailable) {
// Availability for *
if (!AvAttr->Rename.empty() && isa<ValueDecl>(D)) {
// rename
maybePrintLeadingSpace();
os << "SWIFT_UNAVAILABLE_MSG(\"'"
<< cast<ValueDecl>(D)->getBaseName()
<< "' has been renamed to '";
printRenameForDecl(AvAttr, cast<ValueDecl>(D), false);
os << '\'';
if (!AvAttr->Message.empty()) {
os << ": ";
printEncodedString(AvAttr->Message, false);
}
os << "\")";
} else if (!AvAttr->Message.empty()) {
maybePrintLeadingSpace();
os << "SWIFT_UNAVAILABLE_MSG(";
printEncodedString(AvAttr->Message);
os << ")";
} else {
maybePrintLeadingSpace();
os << "SWIFT_UNAVAILABLE";
}
break;
}
if (AvAttr->isUnconditionallyDeprecated()) {
if (!AvAttr->Rename.empty() || !AvAttr->Message.empty()) {
maybePrintLeadingSpace();
os << "SWIFT_DEPRECATED_MSG(";
printEncodedString(AvAttr->Message);
if (!AvAttr->Rename.empty()) {
os << ", ";
printRenameForDecl(AvAttr, cast<ValueDecl>(D), true);
}
os << ")";
} else {
maybePrintLeadingSpace();
os << "SWIFT_DEPRECATED";
}
}
continue;
}
// Availability for a specific platform
if (!AvAttr->Introduced.hasValue() && !AvAttr->Deprecated.hasValue() &&
!AvAttr->Obsoleted.hasValue() &&
!AvAttr->isUnconditionallyDeprecated() &&
!AvAttr->isUnconditionallyUnavailable()) {
continue;
}
const char *plat;
switch (AvAttr->Platform) {
case PlatformKind::OSX:
plat = "macos";
break;
case PlatformKind::iOS:
plat = "ios";
break;
case PlatformKind::tvOS:
plat = "tvos";
break;
case PlatformKind::watchOS:
plat = "watchos";
break;
case PlatformKind::OSXApplicationExtension:
plat = "macos_app_extension";
break;
case PlatformKind::iOSApplicationExtension:
plat = "ios_app_extension";
break;
case PlatformKind::tvOSApplicationExtension:
plat = "tvos_app_extension";
break;
case PlatformKind::watchOSApplicationExtension:
plat = "watchos_app_extension";
break;
case PlatformKind::none:
llvm_unreachable("handled above");
}
maybePrintLeadingSpace();
os << "SWIFT_AVAILABILITY(" << plat;
if (AvAttr->isUnconditionallyUnavailable()) {
os << ",unavailable";
} else {
if (AvAttr->Introduced.hasValue()) {
os << ",introduced=" << AvAttr->Introduced.getValue().getAsString();
}
if (AvAttr->Deprecated.hasValue()) {
os << ",deprecated=" << AvAttr->Deprecated.getValue().getAsString();
} else if (AvAttr->isUnconditionallyDeprecated()) {
// We need to specify some version, we can't just say deprecated.
// We also can't deprecate it before it's introduced.
if (AvAttr->Introduced.hasValue()) {
os << ",deprecated=" << AvAttr->Introduced.getValue().getAsString();
} else {
os << ",deprecated=0.0.1";
}
}
if (AvAttr->Obsoleted.hasValue()) {
os << ",obsoleted=" << AvAttr->Obsoleted.getValue().getAsString();
}
}
if (!AvAttr->Rename.empty() && isa<ValueDecl>(D)) {
os << ",message=\"'" << cast<ValueDecl>(D)->getBaseName()
<< "' has been renamed to '";
printRenameForDecl(AvAttr, cast<ValueDecl>(D), false);
os << '\'';
if (!AvAttr->Message.empty()) {
os << ": ";
printEncodedString(AvAttr->Message, false);
}
os << "\"";
} else if (!AvAttr->Message.empty()) {
os << ",message=";
printEncodedString(AvAttr->Message);
}
os << ")";
}
return hasPrintedAnything;
}
const ValueDecl *getRenameDecl(const ValueDecl *D,
const ParsedDeclName renamedParsedDeclName) {
auto declContext = D->getDeclContext();
ASTContext &astContext = D->getASTContext();
auto renamedDeclName = renamedParsedDeclName.formDeclName(astContext);
if (isa<ClassDecl>(D) || isa<ProtocolDecl>(D)) {
if (!renamedParsedDeclName.ContextName.empty()) {
return nullptr;
}
UnqualifiedLookup lookup(renamedDeclName.getBaseIdentifier(),
declContext->getModuleScopeContext(), nullptr,
SourceLoc(),
UnqualifiedLookup::Flags::TypeLookup);
return lookup.getSingleTypeResult();
}
TypeDecl *typeDecl = declContext->getSelfNominalTypeDecl();
const ValueDecl *renamedDecl = nullptr;
SmallVector<ValueDecl *, 4> lookupResults;
declContext->lookupQualified(typeDecl->getDeclaredInterfaceType(),
renamedDeclName, NL_QualifiedDefault, nullptr,
lookupResults);
if (lookupResults.size() == 1) {
auto candidate = lookupResults[0];
if (!shouldInclude(candidate))
return nullptr;
if (candidate->getKind() != D->getKind() ||
(candidate->isInstanceMember() !=
cast<ValueDecl>(D)->isInstanceMember()))
return nullptr;
renamedDecl = candidate;
} else {
for (auto candidate : lookupResults) {
if (!shouldInclude(candidate))
continue;
if (candidate->getKind() != D->getKind() ||
(candidate->isInstanceMember() !=
cast<ValueDecl>(D)->isInstanceMember()))
continue;
if (isa<AbstractFunctionDecl>(candidate)) {
auto cParams = cast<AbstractFunctionDecl>(candidate)->getParameters();
auto dParams = cast<AbstractFunctionDecl>(D)->getParameters();
if (cParams->size() != dParams->size())
continue;
bool hasSameParameterTypes = true;
for (auto index : indices(*cParams)) {
auto cParamsType = cParams->get(index)->getType();
auto dParamsType = dParams->get(index)->getType();
if (!cParamsType->matchesParameter(dParamsType,
TypeMatchOptions())) {
hasSameParameterTypes = false;
break;
}
}
if (!hasSameParameterTypes) {
continue;
}
}
if (renamedDecl) {
// If we found a duplicated candidate then we would silently fail.
renamedDecl = nullptr;
break;
}
renamedDecl = candidate;
}
}
return renamedDecl;
}
void printRenameForDecl(const AvailableAttr *AvAttr, const ValueDecl *D,
bool includeQuotes) {
assert(!AvAttr->Rename.empty());
const ValueDecl *renamedDecl =
getRenameDecl(D, parseDeclName(AvAttr->Rename));
if (renamedDecl) {
SmallString<128> scratch;
auto renamedObjCRuntimeName =
renamedDecl->getObjCRuntimeName()->getString(scratch);
printEncodedString(renamedObjCRuntimeName, includeQuotes);
} else {
printEncodedString(AvAttr->Rename, includeQuotes);
}
}
void printSwift3ObjCDeprecatedInference(ValueDecl *VD) {
const LangOptions &langOpts = M.getASTContext().LangOpts;
if (!langOpts.EnableSwift3ObjCInference ||
langOpts.WarnSwift3ObjCInference == Swift3ObjCInferenceWarnings::None) {
return;
}
auto attr = VD->getAttrs().getAttribute<ObjCAttr>();
if (!attr || !attr->isSwift3Inferred())
return;
os << " SWIFT_DEPRECATED_OBJC(\"Swift ";
if (isa<VarDecl>(VD))
os << "property";
else if (isa<SubscriptDecl>(VD))
os << "subscript";
else if (isa<ConstructorDecl>(VD))
os << "initializer";
else
os << "method";
os << " '";
auto nominal = VD->getDeclContext()->getSelfNominalTypeDecl();
printEncodedString(nominal->getName().str(), /*includeQuotes=*/false);
os << ".";
SmallString<32> scratch;
printEncodedString(VD->getFullName().getString(scratch),
/*includeQuotes=*/false);
os << "' uses '@objc' inference deprecated in Swift 4; add '@objc' to "
<< "provide an Objective-C entrypoint\")";
}
void visitFuncDecl(FuncDecl *FD) {
if (FD->getDeclContext()->isTypeContext())
printAbstractFunctionAsMethod(FD, FD->isStatic());
else
printAbstractFunctionAsFunction(FD);
}
void visitConstructorDecl(ConstructorDecl *CD) {
printAbstractFunctionAsMethod(CD, false);
}
bool maybePrintIBOutletCollection(Type ty) {
if (auto unwrapped = ty->getOptionalObjectType())
ty = unwrapped;
auto genericTy = ty->getAs<BoundGenericStructType>();
if (!genericTy || genericTy->getDecl() != M.getASTContext().getArrayDecl())
return false;
assert(genericTy->getGenericArgs().size() == 1);
auto argTy = genericTy->getGenericArgs().front();
if (auto classDecl = argTy->getClassOrBoundGenericClass())
os << "IBOutletCollection(" << getNameForObjC(classDecl) << ") ";
else
os << "IBOutletCollection(id) ";
return true;
}
/// Returns whether \p ty is the C type \c CFTypeRef, or some typealias
/// thereof.
bool isCFTypeRef(Type ty) {
const TypeAliasDecl *TAD = nullptr;
while (auto aliasTy = dyn_cast<TypeAliasType>(ty.getPointer())) {
TAD = aliasTy->getDecl();
ty = aliasTy->getSinglyDesugaredType();
}
if (!TAD || !TAD->hasClangNode())
return false;
if (ID_CFTypeRef.empty())
ID_CFTypeRef = M.getASTContext().getIdentifier("CFTypeRef");
return TAD->getName() == ID_CFTypeRef;
}
/// Returns true if \p ty can be used with Objective-C reference-counting
/// annotations like \c strong and \c weak.
bool isObjCReferenceCountableObjectType(Type ty) {
if (auto classDecl = ty->getClassOrBoundGenericClass()) {
switch (classDecl->getForeignClassKind()) {
case ClassDecl::ForeignKind::Normal:
case ClassDecl::ForeignKind::RuntimeOnly:
return true;
case ClassDecl::ForeignKind::CFType:
return false;
}
}
if (ty->isObjCExistentialType() && !isCFTypeRef(ty))
return true;
return false;
}
void visitVarDecl(VarDecl *VD) {
assert(VD->getDeclContext()->isTypeContext() &&
"cannot handle global variables right now");
printDocumentationComment(VD);
if (VD->isStatic()) {
// Older Clangs don't support class properties.
os << "SWIFT_CLASS_PROPERTY(";
}
// For now, never promise atomicity.
os << "@property (nonatomic";
if (VD->isStatic())
os << ", class";
ASTContext &ctx = M.getASTContext();
bool isSettable = VD->isSettable(nullptr);
if (isSettable && !ctx.isAccessControlDisabled())
isSettable = (VD->getSetterFormalAccess() >= minRequiredAccess);
if (!isSettable)
os << ", readonly";
// Print the ownership semantics, if relevant.
Type ty = VD->getInterfaceType();
if (auto referenceStorageTy = ty->getAs<ReferenceStorageType>()) {
switch (referenceStorageTy->getOwnership()) {
case ReferenceOwnership::Strong:
llvm_unreachable("not represented with a ReferenceStorageType");
case ReferenceOwnership::Weak: {
auto innerTy =
referenceStorageTy->getReferentType()->getOptionalObjectType();
if (isObjCReferenceCountableObjectType(innerTy))
os << ", weak";
break;
}
case ReferenceOwnership::Unowned:
case ReferenceOwnership::Unmanaged:
// We treat "unowned" as "unsafe_unretained" (even though it's more
// like "safe_unretained") because we want people to think twice about
// allowing that object to disappear. "unowned(unsafe)" (and
// Swift.Unmanaged, handled below) really are "unsafe_unretained".
os << ", unsafe_unretained";
break;
}
} else {
Type copyTy = ty;
bool isOptional = false;
if (auto unwrappedTy = copyTy->getOptionalObjectType()) {
isOptional = true;
copyTy = unwrappedTy;
}
auto nominal = copyTy->getNominalOrBoundGenericNominal();
if (nominal && isa<StructDecl>(nominal)) {
if (nominal == ctx.getArrayDecl() ||
nominal == ctx.getDictionaryDecl() ||
nominal == ctx.getSetDecl() ||
nominal == ctx.getStringDecl() ||
(!getKnownTypeInfo(nominal) && getObjCBridgedClass(nominal))) {
// We fast-path the most common cases in the condition above.
os << ", copy";
} else if (nominal == ctx.getUnmanagedDecl()) {
os << ", unsafe_unretained";
// Don't print unsafe_unretained twice.
if (auto boundTy = copyTy->getAs<BoundGenericType>()) {
ty = boundTy->getGenericArgs().front();
if (isOptional)
ty = OptionalType::get(ty);
}
}
} else if (auto fnTy = copyTy->getAs<FunctionType>()) {
switch (fnTy->getRepresentation()) {
case FunctionTypeRepresentation::Block:
case FunctionTypeRepresentation::Swift:
os << ", copy";
break;
case FunctionTypeRepresentation::Thin:
case FunctionTypeRepresentation::CFunctionPointer:
break;
}
} else if (isObjCReferenceCountableObjectType(copyTy)) {
os << ", strong";
}
}
Identifier objCName = VD->getObjCPropertyName();
bool hasReservedName = isClangKeyword(objCName);
// Handle custom accessor names.
llvm::SmallString<64> buffer;
if (hasReservedName ||
VD->getObjCGetterSelector() !=
VarDecl::getDefaultObjCGetterSelector(ctx, objCName)) {
os << ", getter=" << VD->getObjCGetterSelector().getString(buffer);
}
if (isSettable) {
if (hasReservedName ||
VD->getObjCSetterSelector() !=
VarDecl::getDefaultObjCSetterSelector(ctx, objCName)) {
buffer.clear();
os << ", setter=" << VD->getObjCSetterSelector().getString(buffer);
}
}
os << ") ";
if (VD->getAttrs().hasAttribute<IBOutletAttr>()) {
if (!maybePrintIBOutletCollection(ty))
os << "IBOutlet ";
}
clang::QualType clangTy;
if (const VarDecl *base = findClangBase(VD))
if (auto prop = dyn_cast<clang::ObjCPropertyDecl>(base->getClangDecl()))
clangTy = prop->getType();
if (!clangTy.isNull() && isNSUInteger(clangTy)) {
os << "NSUInteger " << objCName;
if (hasReservedName)
os << "_";
} else {
OptionalTypeKind kind;
Type objTy;
std::tie(objTy, kind) = getObjectTypeAndOptionality(VD, ty);
print(objTy, kind, objCName);
}
printSwift3ObjCDeprecatedInference(VD);
printAvailability(VD);
os << ";";
if (VD->isStatic()) {
os << ")\n";
// Older Clangs don't support class properties, so print the accessors as
// well. This is harmless.
printAbstractFunctionAsMethod(VD->getGetter(), true);
if (isSettable) {
assert(VD->getSetter() && "settable ObjC property missing setter decl");
printAbstractFunctionAsMethod(VD->getSetter(), true);
}
} else {
os << "\n";
if (looksLikeInitMethod(VD->getObjCGetterSelector()))
printAbstractFunctionAsMethod(VD->getGetter(), false);
if (isSettable && looksLikeInitMethod(VD->getObjCSetterSelector()))
printAbstractFunctionAsMethod(VD->getSetter(), false);
}
}
void visitSubscriptDecl(SubscriptDecl *SD) {
assert(SD->isInstanceMember() && "static subscripts not supported");
bool isNSUIntegerSubscript = false;
if (auto clangBase = findClangBase(SD)) {
const auto *clangGetter =
cast<clang::ObjCMethodDecl>(clangBase->getClangDecl());
const auto *indexParam = clangGetter->parameters().front();
isNSUIntegerSubscript = isNSUInteger(indexParam->getType());
}
printAbstractFunctionAsMethod(SD->getGetter(), false, isNSUIntegerSubscript);
if (auto setter = SD->getSetter())
printAbstractFunctionAsMethod(setter, false, isNSUIntegerSubscript);
}
/// Visit part of a type, such as the base of a pointer type.
///
/// If a full type is being printed, use print() instead.
void visitPart(Type ty, Optional<OptionalTypeKind> optionalKind) {
TypeVisitor::visit(ty, optionalKind);
}
/// Where nullability information should be printed.
enum class NullabilityPrintKind {
Before,
After,
ContextSensitive,
};
void printNullability(Optional<OptionalTypeKind> kind,
NullabilityPrintKind printKind
= NullabilityPrintKind::After) {
if (!kind)
return;
switch (printKind) {
case NullabilityPrintKind::ContextSensitive:
switch (*kind) {
case OTK_None:
os << "nonnull";
break;
case OTK_Optional:
os << "nullable";
break;
case OTK_ImplicitlyUnwrappedOptional:
os << "null_unspecified";
break;
}
break;
case NullabilityPrintKind::After:
os << ' ';
LLVM_FALLTHROUGH;
case NullabilityPrintKind::Before:
switch (*kind) {
case OTK_None:
os << "_Nonnull";
break;
case OTK_Optional:
os << "_Nullable";
break;
case OTK_ImplicitlyUnwrappedOptional:
os << "_Null_unspecified";
break;
}
break;
}
if (printKind != NullabilityPrintKind::After)
os << ' ';
}
/// Determine whether this generic Swift nominal type maps to a
/// generic Objective-C class.
static bool hasGenericObjCType(const NominalTypeDecl *nominal) {
auto clangDecl = nominal->getClangDecl();
if (!clangDecl) return false;
auto objcClass = dyn_cast<clang::ObjCInterfaceDecl>(clangDecl);
if (!objcClass) return false;
if (objcClass->getTypeParamList() == nullptr) return false;
return true;
}
/// If \p nominal is bridged to an Objective-C class (via a conformance to
/// _ObjectiveCBridgeable), return that class.
///
/// Otherwise returns null.
const ClassDecl *getObjCBridgedClass(const NominalTypeDecl *nominal) {
// Print imported bridgeable decls as their unbridged type.
if (nominal->hasClangNode())
return nullptr;
auto &ctx = nominal->getASTContext();
// Dig out the ObjectiveCBridgeable protocol.
auto proto = ctx.getProtocol(KnownProtocolKind::ObjectiveCBridgeable);
if (!proto) return nullptr;
// Determine whether this nominal type is _ObjectiveCBridgeable.
SmallVector<ProtocolConformance *, 2> conformances;
if (!nominal->lookupConformance(&M, proto, conformances))
return nullptr;
// Dig out the Objective-C type.
auto conformance = conformances.front();
Type objcType = ProtocolConformanceRef::getTypeWitnessByName(
nominal->getDeclaredType(),
ProtocolConformanceRef(conformance),
ctx.Id_ObjectiveCType,
nullptr);
if (!objcType) return nullptr;
// Dig out the Objective-C class.
return objcType->getClassOrBoundGenericClass();
}
/// If the nominal type is bridged to Objective-C (via a conformance
/// to _ObjectiveCBridgeable), print the bridged type.
void printObjCBridgeableType(const NominalTypeDecl *swiftNominal,
const ClassDecl *objcClass,
ArrayRef<Type> typeArgs,
Optional<OptionalTypeKind> optionalKind) {
auto &ctx = swiftNominal->getASTContext();
assert(objcClass);
Type rewrittenArgsBuf[2];
// Detect when the type arguments correspond to the unspecialized
// type, and clear them out. There is some type-specific hackery
// here for:
//
// NSArray<id> --> NSArray
// NSDictionary<NSObject *, id> --> NSDictionary
// NSSet<id> --> NSSet
if (!typeArgs.empty() &&
(!hasGenericObjCType(objcClass)
|| (swiftNominal == ctx.getArrayDecl() &&
isAnyObjectOrAny(typeArgs[0]))
|| (swiftNominal == ctx.getDictionaryDecl() &&
isNSObjectOrAnyHashable(ctx, typeArgs[0]) &&
isAnyObjectOrAny(typeArgs[1]))
|| (swiftNominal == ctx.getSetDecl() &&
isNSObjectOrAnyHashable(ctx, typeArgs[0])))) {
typeArgs = {};
}
// Use the proper upper id<NSCopying> bound for Dictionaries with
// upper-bounded keys.
else if (swiftNominal == ctx.getDictionaryDecl() &&
isNSObjectOrAnyHashable(ctx, typeArgs[0])) {
if (ModuleDecl *M = ctx.getLoadedModule(ctx.Id_Foundation)) {
if (!NSCopyingType) {
UnqualifiedLookup lookup(ctx.getIdentifier("NSCopying"), M, nullptr);
auto type = lookup.getSingleTypeResult();
if (type && isa<ProtocolDecl>(type)) {
NSCopyingType = type->getDeclaredInterfaceType();
} else {
NSCopyingType = Type();
}
}
if (*NSCopyingType) {
rewrittenArgsBuf[0] = *NSCopyingType;
rewrittenArgsBuf[1] = typeArgs[1];
typeArgs = rewrittenArgsBuf;
}
}
}
// Print the class type.
SmallString<32> objcNameScratch;
os << objcClass->getObjCRuntimeName(objcNameScratch);
// Print the type arguments, if present.
if (!typeArgs.empty()) {
os << "<";
interleave(typeArgs,
[this](Type type) {
printCollectionElement(type);
},
[this] { os << ", "; });
os << ">";
}
os << " *";
printNullability(optionalKind);
}
/// If the nominal type is bridged to Objective-C (via a conformance to
/// _ObjectiveCBridgeable), print the bridged type. Otherwise, nothing is
/// printed.
///
/// \returns true iff printed something.
bool printIfObjCBridgeable(const NominalTypeDecl *nominal,
ArrayRef<Type> typeArgs,
Optional<OptionalTypeKind> optionalKind) {
if (const ClassDecl *objcClass = getObjCBridgedClass(nominal)) {
printObjCBridgeableType(nominal, objcClass, typeArgs, optionalKind);
return true;
}
return false;
}
/// If \p typeDecl is one of the standard library types used to map in Clang
/// primitives and basic types, return the address of the info in
/// \c specialNames containing the Clang name and whether it can be optional.
///
/// Returns null if the name is not one of these known types.
const NameAndOptional *getKnownTypeInfo(const TypeDecl *typeDecl) {
if (specialNames.empty()) {
ASTContext &ctx = M.getASTContext();
#define MAP(SWIFT_NAME, CLANG_REPR, NEEDS_NULLABILITY) \
specialNames[{ctx.StdlibModuleName, ctx.getIdentifier(#SWIFT_NAME)}] = \
{ CLANG_REPR, NEEDS_NULLABILITY}
MAP(CBool, "bool", false);
MAP(CChar, "char", false);
MAP(CWideChar, "wchar_t", false);
MAP(CChar16, "char16_t", false);
MAP(CChar32, "char32_t", false);
MAP(CSignedChar, "signed char", false);
MAP(CShort, "short", false);
MAP(CInt, "int", false);
MAP(CLong, "long", false);
MAP(CLongLong, "long long", false);
MAP(CUnsignedChar, "unsigned char", false);
MAP(CUnsignedShort, "unsigned short", false);
MAP(CUnsignedInt, "unsigned int", false);
MAP(CUnsignedLong, "unsigned long", false);
MAP(CUnsignedLongLong, "unsigned long long", false);
MAP(CFloat, "float", false);
MAP(CDouble, "double", false);
MAP(Int8, "int8_t", false);
MAP(Int16, "int16_t", false);
MAP(Int32, "int32_t", false);
MAP(Int64, "int64_t", false);
MAP(UInt8, "uint8_t", false);
MAP(UInt16, "uint16_t", false);
MAP(UInt32, "uint32_t", false);
MAP(UInt64, "uint64_t", false);
MAP(Float, "float", false);
MAP(Double, "double", false);
MAP(Float32, "float", false);
MAP(Float64, "double", false);
MAP(Int, "NSInteger", false);
MAP(UInt, "NSUInteger", false);
MAP(Bool, "BOOL", false);
MAP(OpaquePointer, "void *", true);
MAP(UnsafeRawPointer, "void const *", true);
MAP(UnsafeMutableRawPointer, "void *", true);
Identifier ID_ObjectiveC = ctx.Id_ObjectiveC;
specialNames[{ID_ObjectiveC, ctx.getIdentifier("ObjCBool")}]
= { "BOOL", false};
specialNames[{ID_ObjectiveC, ctx.getIdentifier("Selector")}]
= { "SEL", true };
specialNames[{ID_ObjectiveC,
ctx.getIdentifier(
ctx.getSwiftName(KnownFoundationEntity::NSZone))}]
= { "struct _NSZone *", true };
specialNames[{ctx.Id_Darwin, ctx.getIdentifier("DarwinBoolean")}]
= { "Boolean", false};
Identifier ID_CoreGraphics = ctx.getIdentifier("CoreGraphics");
specialNames[{ID_CoreGraphics, ctx.getIdentifier("CGFloat")}]
= { "CGFloat", false };
// Use typedefs we set up for SIMD vector types.
#define MAP_SIMD_TYPE(BASENAME, _, __) \
specialNames[{ctx.Id_simd, ctx.getIdentifier(#BASENAME "2")}] \
= { "swift_" #BASENAME "2", false }; \
specialNames[{ctx.Id_simd, ctx.getIdentifier(#BASENAME "3")}] \
= { "swift_" #BASENAME "3", false }; \
specialNames[{ctx.Id_simd, ctx.getIdentifier(#BASENAME "4")}] \
= { "swift_" #BASENAME "4", false };
#include "swift/ClangImporter/SIMDMappedTypes.def"
static_assert(SWIFT_MAX_IMPORTED_SIMD_ELEMENTS == 4,
"must add or remove special name mappings if max number of "
"SIMD elements is changed");
}
Identifier moduleName = typeDecl->getModuleContext()->getName();
Identifier name = typeDecl->getName();
auto iter = specialNames.find({moduleName, name});
if (iter == specialNames.end())
return nullptr;
return &iter->second;
}
/// If \p typeDecl is one of the standard library types used to map in Clang
/// primitives and basic types, print out the appropriate spelling and
/// return true.
///
/// This handles typealiases and structs provided by the standard library
/// for interfacing with C and Objective-C.
bool printIfKnownSimpleType(const TypeDecl *typeDecl,
Optional<OptionalTypeKind> optionalKind) {
auto *knownTypeInfo = getKnownTypeInfo(typeDecl);
if (!knownTypeInfo)
return false;
os << knownTypeInfo->first;
if (knownTypeInfo->second)
printNullability(optionalKind);
return true;
}
void visitType(TypeBase *Ty, Optional<OptionalTypeKind> optionalKind) {
assert(Ty->getDesugaredType() == Ty && "unhandled sugared type");
os << "/* ";
Ty->print(os);
os << " */";
}
bool isClangPointerType(const clang::TypeDecl *clangTypeDecl) const {
ASTContext &ctx = M.getASTContext();
auto &clangASTContext = ctx.getClangModuleLoader()->getClangASTContext();
clang::QualType clangTy = clangASTContext.getTypeDeclType(clangTypeDecl);
return clangTy->isPointerType() || clangTy->isBlockPointerType() ||
clangTy->isObjCObjectPointerType();
}
bool printImportedAlias(const TypeAliasDecl *alias,
Optional<OptionalTypeKind> optionalKind) {
if (!alias->hasClangNode())
return false;
if (auto *clangTypeDecl =
dyn_cast<clang::TypeDecl>(alias->getClangDecl())) {
maybePrintTagKeyword(alias);
os << getNameForObjC(alias);
if (isClangPointerType(clangTypeDecl))
printNullability(optionalKind);
} else if (auto *clangObjCClass
= dyn_cast<clang::ObjCInterfaceDecl>(alias->getClangDecl())){
os << clangObjCClass->getName() << " *";
printNullability(optionalKind);
} else {
auto *clangCompatAlias =
cast<clang::ObjCCompatibleAliasDecl>(alias->getClangDecl());
os << clangCompatAlias->getName() << " *";
printNullability(optionalKind);
}
return true;
}
void visitTypeAliasType(TypeAliasType *aliasTy,
Optional<OptionalTypeKind> optionalKind) {
const TypeAliasDecl *alias = aliasTy->getDecl();
if (printIfKnownSimpleType(alias, optionalKind))
return;
if (printImportedAlias(alias, optionalKind))
return;
visitPart(aliasTy->getSinglyDesugaredType(), optionalKind);
}
void maybePrintTagKeyword(const TypeDecl *NTD) {
if (isa<EnumDecl>(NTD) && !NTD->hasClangNode()) {
os << "enum ";
return;
}
auto clangDecl = dyn_cast_or_null<clang::TagDecl>(NTD->getClangDecl());
if (!clangDecl)
return;
if (clangDecl->getTypedefNameForAnonDecl())
return;
ASTContext &ctx = M.getASTContext();
auto importer = static_cast<ClangImporter *>(ctx.getClangModuleLoader());
if (importer->hasTypedef(clangDecl))
return;
os << clangDecl->getKindName() << " ";
}
void visitStructType(StructType *ST,
Optional<OptionalTypeKind> optionalKind) {
const StructDecl *SD = ST->getStructOrBoundGenericStruct();
// Handle known type names.
if (printIfKnownSimpleType(SD, optionalKind))
return;
// Handle bridged types.
if (printIfObjCBridgeable(SD, { }, optionalKind))
return;
maybePrintTagKeyword(SD);
os << getNameForObjC(SD);
// Handle swift_newtype applied to a pointer type.
if (auto *clangDecl = cast_or_null<clang::TypeDecl>(SD->getClangDecl()))
if (isClangPointerType(clangDecl))
printNullability(optionalKind);
}
/// Print a collection element type using Objective-C generics syntax.
///
/// This will print the type as bridged to Objective-C.
void printCollectionElement(Type ty) {
ASTContext &ctx = M.getASTContext();
auto isSwiftNewtype = [](const StructDecl *SD) -> bool {
if (!SD)
return false;
auto *clangDecl = SD->getClangDecl();
if (!clangDecl)
return false;
return clangDecl->hasAttr<clang::SwiftNewtypeAttr>();
};
// Use the type as bridged to Objective-C unless the element type is itself
// an imported type or a collection.
const StructDecl *SD = ty->getStructOrBoundGenericStruct();
if (ty->isAny()) {
ty = ctx.getAnyObjectType();
} else if (SD != ctx.getArrayDecl() &&
SD != ctx.getDictionaryDecl() &&
SD != ctx.getSetDecl() &&
!isSwiftNewtype(SD)) {
ty = ctx.getBridgedToObjC(&M, ty);
}
assert(ty && "unknown bridged type");
print(ty, None);
}
/// If \p BGT represents a generic struct used to import Clang types, print
/// it out.
bool printIfKnownGenericStruct(const BoundGenericStructType *BGT,
Optional<OptionalTypeKind> optionalKind) {
StructDecl *SD = BGT->getDecl();
if (!SD->getModuleContext()->isStdlibModule())
return false;
ASTContext &ctx = M.getASTContext();
if (SD == ctx.getUnmanagedDecl()) {
auto args = BGT->getGenericArgs();
assert(args.size() == 1);
visitPart(args.front(), optionalKind);
os << " __unsafe_unretained";
return true;
}
// Everything from here on is some kind of pointer type.
bool isConst;
if (SD == ctx.getUnsafePointerDecl()) {
isConst = true;
} else if (SD == ctx.getAutoreleasingUnsafeMutablePointerDecl() ||
SD == ctx.getUnsafeMutablePointerDecl()) {
isConst = false;
} else {
// Not a pointer.
return false;
}
auto args = BGT->getGenericArgs();
assert(args.size() == 1);
visitPart(args.front(), OTK_None);
if (isConst)
os << " const";
os << " *";
printNullability(optionalKind);
return true;
}
void visitBoundGenericStructType(BoundGenericStructType *BGT,
Optional<OptionalTypeKind> optionalKind) {
// Handle bridged types.
if (printIfObjCBridgeable(BGT->getDecl(), BGT->getGenericArgs(),
optionalKind))
return;
if (printIfKnownGenericStruct(BGT, optionalKind))
return;
visitBoundGenericType(BGT, optionalKind);
}
void printGenericArgs(BoundGenericType *BGT) {
os << '<';
interleave(BGT->getGenericArgs(),
[this](Type t) { print(t, None); },
[this] { os << ", "; });
os << '>';
}
void visitBoundGenericClassType(BoundGenericClassType *BGT,
Optional<OptionalTypeKind> optionalKind) {
// Only handle imported ObjC generics.
auto CD = BGT->getClassOrBoundGenericClass();
if (!CD->isObjC())
return visitType(BGT, optionalKind);
assert(CD->getClangDecl() && "objc generic class w/o clang node?!");
auto clangDecl = cast<clang::NamedDecl>(CD->getClangDecl());
if (isa<clang::ObjCInterfaceDecl>(clangDecl)) {
os << clangDecl->getName();
} else {
maybePrintTagKeyword(CD);
os << clangDecl->getName();
}
printGenericArgs(BGT);
if (isa<clang::ObjCInterfaceDecl>(clangDecl)) {
os << " *";
}
printNullability(optionalKind);
}
void visitBoundGenericType(BoundGenericType *BGT,
Optional<OptionalTypeKind> optionalKind) {
// Handle bridged types.
if (!isa<StructDecl>(BGT->getDecl()) &&
printIfObjCBridgeable(BGT->getDecl(), BGT->getGenericArgs(),
optionalKind))
return;
if (auto underlying = BGT->getOptionalObjectType()) {
visitPart(underlying, OTK_Optional);
} else
visitType(BGT, optionalKind);
}
void visitEnumType(EnumType *ET, Optional<OptionalTypeKind> optionalKind) {
const EnumDecl *ED = ET->getDecl();
// Handle bridged types.
if (printIfObjCBridgeable(ED, { }, optionalKind))
return;
maybePrintTagKeyword(ED);
os << getNameForObjC(ED);
}
void visitClassType(ClassType *CT, Optional<OptionalTypeKind> optionalKind) {
const ClassDecl *CD = CT->getClassOrBoundGenericClass();
assert(CD->isObjC());
auto clangDecl = dyn_cast_or_null<clang::NamedDecl>(CD->getClangDecl());
if (clangDecl) {
// Hack for <os/object.h> types, which use classes in Swift but
// protocols in Objective-C, and a typedef to hide the difference.
StringRef osObjectName = maybeGetOSObjectBaseName(clangDecl);
if (!osObjectName.empty()) {
os << osObjectName << "_t";
} else if (isa<clang::ObjCInterfaceDecl>(clangDecl)) {
os << clangDecl->getName() << " *";
} else {
maybePrintTagKeyword(CD);
os << clangDecl->getName();
}
} else {
os << getNameForObjC(CD) << " *";
}
printNullability(optionalKind);
}
void visitExistentialType(Type T,
Optional<OptionalTypeKind> optionalKind,
bool isMetatype = false) {
auto layout = T->getExistentialLayout();
if (layout.isErrorExistential()) {
if (isMetatype) os << "Class";
else os << "NSError *";
printNullability(optionalKind);
return;
}
if (auto superclass = layout.explicitSuperclass) {
auto *CD = superclass->getClassOrBoundGenericClass();
assert(CD->isObjC());
if (isMetatype) {
os << "SWIFT_METATYPE(" << getNameForObjC(CD) << ")";
} else {
os << getNameForObjC(CD);
if (auto *BGT = superclass->getAs<BoundGenericClassType>())
printGenericArgs(BGT);
}
} else {
os << (isMetatype ? "Class" : "id");
}
SmallVector<ProtocolDecl *, 2> protos;
for (auto proto : layout.getProtocols())
protos.push_back(proto->getDecl());
printProtocols(protos);
if (layout.explicitSuperclass && !isMetatype)
os << " *";
printNullability(optionalKind);
}
void visitProtocolType(ProtocolType *PT,
Optional<OptionalTypeKind> optionalKind) {
visitExistentialType(PT, optionalKind, /*isMetatype=*/false);
}
void visitProtocolCompositionType(ProtocolCompositionType *PCT,
Optional<OptionalTypeKind> optionalKind) {
visitExistentialType(PCT, optionalKind, /*isMetatype=*/false);
}
void visitExistentialMetatypeType(ExistentialMetatypeType *MT,
Optional<OptionalTypeKind> optionalKind) {
Type instanceTy = MT->getInstanceType();
visitExistentialType(instanceTy, optionalKind, /*isMetatype=*/true);
}
void visitMetatypeType(MetatypeType *MT,
Optional<OptionalTypeKind> optionalKind) {
Type instanceTy = MT->getInstanceType();
if (auto classTy = instanceTy->getAs<ClassType>()) {
const ClassDecl *CD = classTy->getDecl();
assert(CD->isObjC());
os << "SWIFT_METATYPE(" << getNameForObjC(CD) << ")";
printNullability(optionalKind);
} else {
visitType(MT, optionalKind);
}
}
void visitGenericTypeParamType(GenericTypeParamType *type,
Optional<OptionalTypeKind> optionalKind) {
const GenericTypeParamDecl *decl = type->getDecl();
assert(decl && "can't print canonicalized GenericTypeParamType");
if (auto *extension = dyn_cast<ExtensionDecl>(decl->getDeclContext())) {
const ClassDecl *extendedClass = extension->getSelfClassDecl();
assert(extendedClass->isGeneric());
assert(extension->getGenericParams()->size() ==
extendedClass->getGenericParams()->size() &&
"extensions with custom generic parameters?");
assert(extension->getGenericSignature()->getCanonicalSignature() ==
extendedClass->getGenericSignature()->getCanonicalSignature() &&
"constrained extensions or custom generic parameters?");
type = extendedClass->getGenericEnvironment()->getSugaredType(type);
decl = type->getDecl();
}
assert(decl->getClangDecl() && "can only handle imported ObjC generics");
os << cast<clang::ObjCTypeParamDecl>(decl->getClangDecl())->getName();
printNullability(optionalKind);
}
void printFunctionType(FunctionType *FT, char pointerSigil,
Optional<OptionalTypeKind> optionalKind) {
visitPart(FT->getResult(), OTK_None);
os << " (" << pointerSigil;
printNullability(optionalKind);
openFunctionTypes.push_back(FT);
}
void visitFunctionType(FunctionType *FT,
Optional<OptionalTypeKind> optionalKind) {
switch (FT->getRepresentation()) {
case AnyFunctionType::Representation::Thin:
llvm_unreachable("can't represent thin functions in ObjC");
// Native Swift function types bridge to block types.
case AnyFunctionType::Representation::Swift:
case AnyFunctionType::Representation::Block:
printFunctionType(FT, '^', optionalKind);
break;
case AnyFunctionType::Representation::CFunctionPointer:
printFunctionType(FT, '*', optionalKind);
}
}
/// Print the part of a function type that appears after where the variable
/// name would go.
///
/// This is necessary to handle C's awful declarator syntax.
/// "(A) -> ((B) -> C)" becomes "C (^ (^)(A))(B)".
void finishFunctionType(const FunctionType *FT) {
os << ")(";
if (!FT->getParams().empty()) {
interleave(FT->getParams(),
[this](const AnyFunctionType::Param &param) {
print(param.getOldType(), OTK_None, param.getLabel(),
IsFunctionParam);
},
[this] { os << ", "; });
} else {
os << "void";
}
os << ")";
}
void visitTupleType(TupleType *TT, Optional<OptionalTypeKind> optionalKind) {
assert(TT->getNumElements() == 0);
os << "void";
}
void visitParenType(ParenType *PT, Optional<OptionalTypeKind> optionalKind) {
visitPart(PT->getSinglyDesugaredType(), optionalKind);
}
void visitSyntaxSugarType(SyntaxSugarType *SST,
Optional<OptionalTypeKind> optionalKind) {
visitPart(SST->getSinglyDesugaredType(), optionalKind);
}
void visitDynamicSelfType(DynamicSelfType *DST,
Optional<OptionalTypeKind> optionalKind) {
printNullability(optionalKind, NullabilityPrintKind::ContextSensitive);
os << "instancetype";
}
void visitReferenceStorageType(ReferenceStorageType *RST,
Optional<OptionalTypeKind> optionalKind) {
visitPart(RST->getReferentType(), optionalKind);
}
/// RAII class for printing multi-part C types, such as functions and arrays.
class PrintMultiPartType {
ObjCPrinter &Printer;
decltype(ObjCPrinter::openFunctionTypes) savedFunctionTypes;
PrintMultiPartType(const PrintMultiPartType &) = delete;
public:
PrintMultiPartType(ObjCPrinter &Printer)
: Printer(Printer) {
savedFunctionTypes.swap(Printer.openFunctionTypes);
}
void finish() {
auto &openFunctionTypes = Printer.openFunctionTypes;
while (!openFunctionTypes.empty()) {
const FunctionType *openFunctionTy = openFunctionTypes.pop_back_val();
Printer.finishFunctionType(openFunctionTy);
}
openFunctionTypes = std::move(savedFunctionTypes);
savedFunctionTypes.clear();
}
~PrintMultiPartType() {
finish();
}
};
/// Print a full type, optionally declaring the given \p name.
///
/// This will properly handle nested function types (see
/// finishFunctionType()). If only a part of a type is being printed, use
/// visitPart().
public:
void print(Type ty, Optional<OptionalTypeKind> optionalKind,
Identifier name = Identifier(),
IsFunctionParam_t isFuncParam = IsNotFunctionParam) {
PrettyStackTraceType trace(M.getASTContext(), "printing", ty);
if (isFuncParam)
if (auto fnTy = ty->lookThroughAllOptionalTypes()
->getAs<AnyFunctionType>())
if (fnTy->isNoEscape())
os << "SWIFT_NOESCAPE ";
PrintMultiPartType multiPart(*this);
visitPart(ty, optionalKind);
if (!name.empty()) {
os << ' ' << name;
if (isClangKeyword(name)) {
os << '_';
}
}
}
};
class ReferencedTypeFinder : public TypeVisitor<ReferencedTypeFinder> {
friend TypeVisitor;
ModuleDecl &M;
llvm::function_ref<void(ReferencedTypeFinder &, const TypeDecl *)> Callback;
bool NeedsDefinition = false;
ReferencedTypeFinder(ModuleDecl &mod, decltype(Callback) callback)
: M(mod), Callback(callback) {}
void visitType(TypeBase *base) {
llvm_unreachable("unhandled type");
}
void visitTypeAliasType(TypeAliasType *aliasTy) {
if (aliasTy->getDecl()->hasClangNode() &&
!aliasTy->getDecl()->isCompatibilityAlias()) {
Callback(*this, aliasTy->getDecl());
} else {
visit(aliasTy->getSinglyDesugaredType());
}
}
void visitParenType(ParenType *parenTy) {
visit(parenTy->getSinglyDesugaredType());
}
void visitTupleType(TupleType *tupleTy) {
for (auto elemTy : tupleTy->getElementTypes())
visit(elemTy);
}
void visitReferenceStorageType(ReferenceStorageType *ty) {
visit(ty->getReferentType());
}
void visitNominalType(NominalType *nominal) {
Callback(*this, nominal->getDecl());
}
void visitAnyMetatypeType(AnyMetatypeType *metatype) {
visit(metatype->getInstanceType());
}
void visitDynamicSelfType(DynamicSelfType *module) {
return;
}
void visitArchetypeType(ArchetypeType *archetype) {
llvm_unreachable("Should not see archetypes in interface types");
}
void visitGenericTypeParamType(GenericTypeParamType *param) {
// Appears in protocols and in generic ObjC classes.
return;
}
void visitDependentMemberType(DependentMemberType *member) {
// Appears in protocols and in generic ObjC classes.
return;
}
void visitAnyFunctionType(AnyFunctionType *fnTy) {
for (auto &param : fnTy->getParams())
visit(param.getOldType());
visit(fnTy->getResult());
}
void visitSyntaxSugarType(SyntaxSugarType *sugar) {
visit(sugar->getSinglyDesugaredType());
}
void visitProtocolCompositionType(ProtocolCompositionType *composition) {
auto layout = composition->getExistentialLayout();
if (auto superclass = layout.explicitSuperclass)
visit(superclass);
for (auto proto : layout.getProtocols())
visit(proto);
}
void visitLValueType(LValueType *lvalue) {
llvm_unreachable("LValue types should not appear in interface types");
}
void visitInOutType(InOutType *inout) {
visit(inout->getObjectType());
}
/// Returns true if \p paramTy has any constraints other than being
/// class-bound ("conforms to" AnyObject).
static bool isConstrained(GenericSignature *sig,
GenericTypeParamType *paramTy) {
if (sig->getSuperclassBound(paramTy))
return true;
auto conformsTo = sig->getConformsTo(paramTy);
return !conformsTo.empty();
}
void visitBoundGenericType(BoundGenericType *boundGeneric) {
auto *decl = boundGeneric->getDecl();
NeedsDefinition = true;
Callback(*this, decl);
NeedsDefinition = false;
bool isObjCGeneric = decl->hasClangNode();
auto *sig = decl->getGenericSignature();
for_each(boundGeneric->getGenericArgs(),
sig->getInnermostGenericParams(),
[&](Type argTy, GenericTypeParamType *paramTy) {
if (isObjCGeneric && isConstrained(sig, paramTy))
NeedsDefinition = true;
visit(argTy);
NeedsDefinition = false;
});
}
public:
using TypeVisitor::visit;
bool needsDefinition() const {
return NeedsDefinition;
}
static void walk(ModuleDecl &mod, Type ty, decltype(Callback) callback) {
ReferencedTypeFinder(mod, callback).visit(ty);
}
};
class ModuleWriter {
enum class EmissionState {
NotYetDefined = 0,
DefinitionRequested,
Defined
};
llvm::DenseMap<const TypeDecl *, std::pair<EmissionState, bool>> seenTypes;
std::vector<const Decl *> declsToWrite;
DelayedMemberSet delayedMembers;
using ImportModuleTy = PointerUnion<ModuleDecl*, const clang::Module*>;
SmallPtrSet<ImportModuleTy, 8> imports;
std::string bodyBuffer;
llvm::raw_string_ostream os{bodyBuffer};
ModuleDecl &M;
StringRef bridgingHeader;
ObjCPrinter printer;
public:
ModuleWriter(ModuleDecl &mod, StringRef header, AccessLevel access)
: M(mod), bridgingHeader(header), printer(M, os, delayedMembers, access) {}
/// Returns true if we added the decl's module to the import set, false if
/// the decl is a local decl.
///
/// The standard library is special-cased: we assume that any types from it
/// will be handled explicitly rather than needing an explicit @import.
bool addImport(const Decl *D) {
ModuleDecl *otherModule = D->getModuleContext();
if (otherModule == &M)
return false;
if (otherModule->isStdlibModule() ||
otherModule->isBuiltinModule())
return true;
// Don't need a module for SIMD types in C.
if (otherModule->getName() == M.getASTContext().Id_simd)
return true;
// If there's a Clang node, see if it comes from an explicit submodule.
// Import that instead, looking through any implicit submodules.
if (auto clangNode = D->getClangNode()) {
auto importer =
static_cast<ClangImporter *>(M.getASTContext().getClangModuleLoader());
if (const auto *clangModule = importer->getClangOwningModule(clangNode)) {
while (clangModule && !clangModule->IsExplicit)
clangModule = clangModule->Parent;
if (clangModule) {
imports.insert(clangModule);
return true;
}
}
}
imports.insert(otherModule);
return true;
}
bool hasBeenRequested(const TypeDecl *D) const {
return seenTypes.lookup(D).first >= EmissionState::DefinitionRequested;
}
bool tryRequire(const TypeDecl *D) {
if (addImport(D)) {
seenTypes[D] = { EmissionState::Defined, true };
return true;
}
auto &state = seenTypes[D];
return state.first == EmissionState::Defined;
}
bool require(const TypeDecl *D) {
if (addImport(D)) {
seenTypes[D] = { EmissionState::Defined, true };
return true;
}
auto &state = seenTypes[D];
switch (state.first) {
case EmissionState::NotYetDefined:
case EmissionState::DefinitionRequested:
state.first = EmissionState::DefinitionRequested;
declsToWrite.push_back(D);
return false;
case EmissionState::Defined:
return true;
}
llvm_unreachable("Unhandled EmissionState in switch.");
}
void forwardDeclare(const NominalTypeDecl *NTD,
llvm::function_ref<void(void)> Printer) {
if (NTD->getModuleContext()->isStdlibModule())
return;
auto &state = seenTypes[NTD];
if (state.second)
return;
Printer();
state.second = true;
}
bool forwardDeclare(const ClassDecl *CD) {
if (!CD->isObjC() ||
CD->getForeignClassKind() == ClassDecl::ForeignKind::CFType ||
isOSObjectType(CD->getClangDecl())) {
return false;
}
forwardDeclare(CD, [&]{ os << "@class " << getNameForObjC(CD) << ";\n"; });
return true;
}
void forwardDeclare(const ProtocolDecl *PD) {
assert(PD->isObjC() ||
*PD->getKnownProtocolKind() == KnownProtocolKind::Error);
forwardDeclare(PD, [&]{
os << "@protocol " << getNameForObjC(PD) << ";\n";
});
}
void forwardDeclare(const EnumDecl *ED) {
assert(ED->isObjC() || ED->hasClangNode());
forwardDeclare(ED, [&]{
os << "enum " << getNameForObjC(ED) << " : ";
printer.print(ED->getRawType(), OTK_None);
os << ";\n";
});
}
bool forwardDeclareMemberTypes(DeclRange members, const Decl *container) {
switch (container->getKind()) {
case DeclKind::Class:
case DeclKind::Protocol:
case DeclKind::Extension:
break;
default:
llvm_unreachable("unexpected container kind");
}
bool hadAnyDelayedMembers = false;
SmallVector<ValueDecl *, 4> nestedTypes;
for (auto member : members) {
auto VD = dyn_cast<ValueDecl>(member);
if (!VD || !printer.shouldInclude(VD))
continue;
// Catch nested types and emit their definitions /after/ this class.
if (isa<TypeDecl>(VD)) {
// Don't emit nested types that are just implicitly @objc.
// You should have to opt into this, since they are even less
// namespaced than usual.
if (std::any_of(VD->getAttrs().begin(), VD->getAttrs().end(),
[](const DeclAttribute *attr) {
return isa<ObjCAttr>(attr) && !attr->isImplicit();
})) {
nestedTypes.push_back(VD);
}
continue;
}
bool needsToBeIndividuallyDelayed = false;
ReferencedTypeFinder::walk(M, VD->getInterfaceType(),
[&](ReferencedTypeFinder &finder,
const TypeDecl *TD) {
if (TD == container)
return;
if (finder.needsDefinition() && isa<NominalTypeDecl>(TD)) {
// We can delay individual members of classes; do so if necessary.
if (isa<ClassDecl>(container)) {
if (!tryRequire(TD)) {
needsToBeIndividuallyDelayed = true;
hadAnyDelayedMembers = true;
}
return;
}
// Extensions can always be delayed wholesale.
if (isa<ExtensionDecl>(container)) {
if (!require(TD))
hadAnyDelayedMembers = true;
return;
}
// Protocols should be delayed wholesale unless we might have a cycle.
auto *proto = cast<ProtocolDecl>(container);
if (!hasBeenRequested(proto) || !hasBeenRequested(TD)) {
if (!require(TD))
hadAnyDelayedMembers = true;
return;
}
// Otherwise, we have a cyclic dependency. Give up and continue with
// regular forward-declarations even though this will lead to an
// error; there's nothing we can do here.
// FIXME: It would be nice to diagnose this.
}
if (auto CD = dyn_cast<ClassDecl>(TD)) {
if (!forwardDeclare(CD)) {
(void)addImport(CD);
}
} else if (auto PD = dyn_cast<ProtocolDecl>(TD)) {
forwardDeclare(PD);
} else if (auto TAD = dyn_cast<TypeAliasDecl>(TD)) {
if (TAD->hasClangNode())
(void)addImport(TD);
} else if (addImport(TD)) {
return;
} else if (auto ED = dyn_cast<EnumDecl>(TD)) {
forwardDeclare(ED);
} else if (isa<AbstractTypeParamDecl>(TD)) {
llvm_unreachable("should not see type params here");
} else {
assert(false && "unknown local type decl");
}
});
if (needsToBeIndividuallyDelayed) {
assert(isa<ClassDecl>(container));
delayedMembers.insert(VD);
}
}
declsToWrite.insert(declsToWrite.end()-1, nestedTypes.rbegin(),
nestedTypes.rend());
// Separate forward declarations from the class itself.
return !hadAnyDelayedMembers;
}
bool writeClass(const ClassDecl *CD) {
if (addImport(CD))
return true;
if (seenTypes[CD].first == EmissionState::Defined)
return true;
bool allRequirementsSatisfied = true;
const ClassDecl *superclass = nullptr;
if ((superclass = CD->getSuperclassDecl())) {
allRequirementsSatisfied &= require(superclass);
}
for (auto proto : CD->getLocalProtocols(
ConformanceLookupKind::OnlyExplicit))
if (printer.shouldInclude(proto))
allRequirementsSatisfied &= require(proto);
if (!allRequirementsSatisfied)
return false;
(void)forwardDeclareMemberTypes(CD->getMembers(), CD);
seenTypes[CD] = { EmissionState::Defined, true };
os << '\n';
printer.print(CD);
return true;
}
bool writeFunc(const FuncDecl *FD) {
if (addImport(FD))
return true;
printer.print(FD);
return true;
}
bool writeProtocol(const ProtocolDecl *PD) {
if (addImport(PD))
return true;
if (seenTypes[PD].first == EmissionState::Defined)
return true;
bool allRequirementsSatisfied = true;
for (auto proto : PD->getInheritedProtocols()) {
assert(proto->isObjC());
allRequirementsSatisfied &= require(proto);
}
if (!allRequirementsSatisfied)
return false;
if (!forwardDeclareMemberTypes(PD->getMembers(), PD))
return false;
seenTypes[PD] = { EmissionState::Defined, true };
os << '\n';
printer.print(PD);
return true;
}
bool writeExtension(const ExtensionDecl *ED) {
bool allRequirementsSatisfied = true;
const ClassDecl *CD = ED->getSelfClassDecl();
allRequirementsSatisfied &= require(CD);
for (auto proto : ED->getLocalProtocols())
if (printer.shouldInclude(proto))
allRequirementsSatisfied &= require(proto);
if (!allRequirementsSatisfied)
return false;
// This isn't rolled up into the previous set of requirements because
// it /also/ prints forward declarations, and the header is a little
// prettier if those are as close as possible to the necessary extension.
if (!forwardDeclareMemberTypes(ED->getMembers(), ED))
return false;
os << '\n';
printer.print(ED);
return true;
}
bool writeEnum(const EnumDecl *ED) {
if (addImport(ED))
return true;
if (seenTypes[ED].first == EmissionState::Defined)
return true;
seenTypes[ED] = {EmissionState::Defined, true};
printer.print(ED);
ASTContext &ctx = M.getASTContext();
SmallVector<ProtocolConformance *, 1> conformances;
auto errorTypeProto = ctx.getProtocol(KnownProtocolKind::Error);
if (ED->lookupConformance(&M, errorTypeProto, conformances)) {
bool hasDomainCase = std::any_of(ED->getAllElements().begin(),
ED->getAllElements().end(),
[](const EnumElementDecl *elem) {
return elem->getName().str() == "Domain";
});
if (!hasDomainCase) {
os << "static NSString * _Nonnull const " << getNameForObjC(ED)
<< "Domain = @\"" << getErrorDomainStringForObjC(ED) << "\";\n";
}
}
return true;
}
void writePrologue(raw_ostream &out) {
out << "// Generated by " << version::getSwiftFullVersion(
M.getASTContext().LangOpts.EffectiveLanguageVersion) << "\n"
"#pragma clang diagnostic push\n"
"#pragma clang diagnostic ignored \"-Wgcc-compat\"\n"
"\n"
"#if !defined(__has_include)\n"
"# define __has_include(x) 0\n"
"#endif\n"
"#if !defined(__has_attribute)\n"
"# define __has_attribute(x) 0\n"
"#endif\n"
"#if !defined(__has_feature)\n"
"# define __has_feature(x) 0\n"
"#endif\n"
"#if !defined(__has_warning)\n"
"# define __has_warning(x) 0\n"
"#endif\n"
"\n"
"#if __has_include(<swift/objc-prologue.h>)\n"
"# include <swift/objc-prologue.h>\n"
"#endif\n"
"\n"
"#pragma clang diagnostic ignored \"-Wauto-import\"\n"
"#include <Foundation/Foundation.h>\n"
"#include <stdint.h>\n"
"#include <stddef.h>\n"
"#include <stdbool.h>\n"
"\n"
"#if !defined(SWIFT_TYPEDEFS)\n"
"# define SWIFT_TYPEDEFS 1\n"
"# if __has_include(<uchar.h>)\n"
"# include <uchar.h>\n"
"# elif !defined(__cplusplus)\n"
"typedef uint_least16_t char16_t;\n"
"typedef uint_least32_t char32_t;\n"
"# endif\n"
#define MAP_SIMD_TYPE(C_TYPE, SCALAR_TYPE, _) \
"typedef " #SCALAR_TYPE " swift_" #C_TYPE "2" \
" __attribute__((__ext_vector_type__(2)));\n" \
"typedef " #SCALAR_TYPE " swift_" #C_TYPE "3" \
" __attribute__((__ext_vector_type__(3)));\n" \
"typedef " #SCALAR_TYPE " swift_" #C_TYPE "4" \
" __attribute__((__ext_vector_type__(4)));\n"
#include "swift/ClangImporter/SIMDMappedTypes.def"
"#endif\n"
"\n"
"#if !defined(SWIFT_PASTE)\n"
"# define SWIFT_PASTE_HELPER(x, y) x##y\n"
"# define SWIFT_PASTE(x, y) SWIFT_PASTE_HELPER(x, y)\n"
"#endif"
"\n"
"#if !defined(SWIFT_METATYPE)\n"
"# define SWIFT_METATYPE(X) Class\n"
"#endif\n"
"#if !defined(SWIFT_CLASS_PROPERTY)\n"
"# if __has_feature(objc_class_property)\n"
"# define SWIFT_CLASS_PROPERTY(...) __VA_ARGS__\n"
"# else\n"
"# define SWIFT_CLASS_PROPERTY(...)\n"
"# endif\n"
"#endif\n"
"\n"
"#if __has_attribute(objc_runtime_name)\n"
"# define SWIFT_RUNTIME_NAME(X) "
"__attribute__((objc_runtime_name(X)))\n"
"#else\n"
"# define SWIFT_RUNTIME_NAME(X)\n"
"#endif\n"
"#if __has_attribute(swift_name)\n"
"# define SWIFT_COMPILE_NAME(X) "
"__attribute__((swift_name(X)))\n"
"#else\n"
"# define SWIFT_COMPILE_NAME(X)\n"
"#endif\n"
"#if __has_attribute(objc_method_family)\n"
"# define SWIFT_METHOD_FAMILY(X) "
"__attribute__((objc_method_family(X)))\n"
"#else\n"
"# define SWIFT_METHOD_FAMILY(X)\n"
"#endif\n"
"#if __has_attribute(noescape)\n"
"# define SWIFT_NOESCAPE __attribute__((noescape))\n"
"#else\n"
"# define SWIFT_NOESCAPE\n"
"#endif\n"
"#if __has_attribute(warn_unused_result)\n"
"# define SWIFT_WARN_UNUSED_RESULT __attribute__((warn_unused_result))\n"
"#else\n"
"# define SWIFT_WARN_UNUSED_RESULT\n"
"#endif\n"
"#if __has_attribute(noreturn)\n"
"# define SWIFT_NORETURN __attribute__((noreturn))\n"
"#else\n"
"# define SWIFT_NORETURN\n"
"#endif\n"
"#if !defined(SWIFT_CLASS_EXTRA)\n"
"# define SWIFT_CLASS_EXTRA\n"
"#endif\n"
"#if !defined(SWIFT_PROTOCOL_EXTRA)\n"
"# define SWIFT_PROTOCOL_EXTRA\n"
"#endif\n"
"#if !defined(SWIFT_ENUM_EXTRA)\n"
"# define SWIFT_ENUM_EXTRA\n"
"#endif\n"
"#if !defined(SWIFT_CLASS)\n"
"# if __has_attribute(objc_subclassing_restricted)\n"
"# define SWIFT_CLASS(SWIFT_NAME) SWIFT_RUNTIME_NAME(SWIFT_NAME) "
"__attribute__((objc_subclassing_restricted)) "
"SWIFT_CLASS_EXTRA\n"
"# define SWIFT_CLASS_NAMED(SWIFT_NAME) "
"__attribute__((objc_subclassing_restricted)) "
"SWIFT_COMPILE_NAME(SWIFT_NAME) "
"SWIFT_CLASS_EXTRA\n"
"# else\n"
"# define SWIFT_CLASS(SWIFT_NAME) SWIFT_RUNTIME_NAME(SWIFT_NAME) "
"SWIFT_CLASS_EXTRA\n"
"# define SWIFT_CLASS_NAMED(SWIFT_NAME) "
"SWIFT_COMPILE_NAME(SWIFT_NAME) "
"SWIFT_CLASS_EXTRA\n"
"# endif\n"
"#endif\n"
"#if !defined(SWIFT_RESILIENT_CLASS)\n"
"# if __has_attribute(objc_class_stub)\n"
"# define SWIFT_RESILIENT_CLASS(SWIFT_NAME) SWIFT_CLASS(SWIFT_NAME) "
"__attribute__((objc_class_stub))\n"
"# define SWIFT_RESILIENT_CLASS_NAMED(SWIFT_NAME) "
"__attribute__((objc_class_stub)) "
"SWIFT_CLASS_NAMED(SWIFT_NAME)\n"
"# else\n"
"# define SWIFT_RESILIENT_CLASS(SWIFT_NAME) "
"SWIFT_CLASS(SWIFT_NAME)\n"
"# define SWIFT_RESILIENT_CLASS_NAMED(SWIFT_NAME) "
"SWIFT_CLASS_NAMED(SWIFT_NAME)\n"
"# endif\n"
"#endif\n"
"\n"
"#if !defined(SWIFT_PROTOCOL)\n"
"# define SWIFT_PROTOCOL(SWIFT_NAME) SWIFT_RUNTIME_NAME(SWIFT_NAME) "
"SWIFT_PROTOCOL_EXTRA\n"
"# define SWIFT_PROTOCOL_NAMED(SWIFT_NAME) "
"SWIFT_COMPILE_NAME(SWIFT_NAME) "
"SWIFT_PROTOCOL_EXTRA\n"
"#endif\n"
"\n"
"#if !defined(SWIFT_EXTENSION)\n"
"# define SWIFT_EXTENSION(M) SWIFT_PASTE(M##_Swift_, __LINE__)\n"
"#endif\n"
"\n"
"#if !defined(OBJC_DESIGNATED_INITIALIZER)\n"
"# if __has_attribute(objc_designated_initializer)\n"
"# define OBJC_DESIGNATED_INITIALIZER "
"__attribute__((objc_designated_initializer))\n"
"# else\n"
"# define OBJC_DESIGNATED_INITIALIZER\n"
"# endif\n"
"#endif\n"
"#if !defined(SWIFT_ENUM_ATTR)\n"
"# if defined(__has_attribute) && "
"__has_attribute(enum_extensibility)\n"
"# define SWIFT_ENUM_ATTR(_extensibility) "
"__attribute__((enum_extensibility(_extensibility)))\n"
"# else\n"
"# define SWIFT_ENUM_ATTR(_extensibility)\n"
"# endif\n"
"#endif\n"
"#if !defined(SWIFT_ENUM)\n"
"# define SWIFT_ENUM(_type, _name, _extensibility) "
"enum _name : _type _name; "
"enum SWIFT_ENUM_ATTR(_extensibility) SWIFT_ENUM_EXTRA "
"_name : _type\n"
"# if __has_feature(generalized_swift_name)\n"
"# define SWIFT_ENUM_NAMED(_type, _name, SWIFT_NAME, "
"_extensibility) "
"enum _name : _type _name SWIFT_COMPILE_NAME(SWIFT_NAME); "
"enum SWIFT_COMPILE_NAME(SWIFT_NAME) "
"SWIFT_ENUM_ATTR(_extensibility) SWIFT_ENUM_EXTRA _name : _type\n"
"# else\n"
"# define SWIFT_ENUM_NAMED(_type, _name, SWIFT_NAME, "
"_extensibility) SWIFT_ENUM(_type, _name, _extensibility)\n"
"# endif\n"
"#endif\n"
"#if !defined(SWIFT_UNAVAILABLE)\n"
"# define SWIFT_UNAVAILABLE __attribute__((unavailable))\n"
"#endif\n"
"#if !defined(SWIFT_UNAVAILABLE_MSG)\n"
"# define SWIFT_UNAVAILABLE_MSG(msg) __attribute__((unavailable(msg)))\n"
"#endif\n"
"#if !defined(SWIFT_AVAILABILITY)\n"
"# define SWIFT_AVAILABILITY(plat, ...) __attribute__((availability(plat, __VA_ARGS__)))\n"
"#endif\n"
"#if !defined(SWIFT_DEPRECATED)\n"
"# define SWIFT_DEPRECATED __attribute__((deprecated))\n"
"#endif\n"
"#if !defined(SWIFT_DEPRECATED_MSG)\n"
"# define SWIFT_DEPRECATED_MSG(...) __attribute__((deprecated(__VA_ARGS__)))\n"
"#endif\n"
"#if __has_feature(attribute_diagnose_if_objc)\n"
"# define SWIFT_DEPRECATED_OBJC(Msg) __attribute__((diagnose_if(1, Msg, \"warning\")))\n"
"#else\n"
"# define SWIFT_DEPRECATED_OBJC(Msg) SWIFT_DEPRECATED_MSG(Msg)\n"
"#endif\n"
;
static_assert(SWIFT_MAX_IMPORTED_SIMD_ELEMENTS == 4,
"need to add SIMD typedefs here if max elements is increased");
}
bool isUnderlyingModule(ModuleDecl *import) {
if (bridgingHeader.empty())
return import != &M && import->getName() == M.getName();
auto importer =
static_cast<ClangImporter *>(import->getASTContext()
.getClangModuleLoader());
return import == importer->getImportedHeaderModule();
}
static int compareImportModulesByName(const ImportModuleTy *left,
const ImportModuleTy *right) {
auto *leftSwiftModule = left->dyn_cast<ModuleDecl *>();
auto *rightSwiftModule = right->dyn_cast<ModuleDecl *>();
if (leftSwiftModule && !rightSwiftModule)
return -compareImportModulesByName(right, left);
if (leftSwiftModule && rightSwiftModule)
return leftSwiftModule->getName().compare(rightSwiftModule->getName());
auto *leftClangModule = left->get<const clang::Module *>();
assert(leftClangModule->isSubModule() &&
"top-level modules should use a normal swift::ModuleDecl");
if (rightSwiftModule) {
// Because the Clang module is a submodule, its full name will never be
// equal to a Swift module's name, even if the top-level name is the same;
// it will always come before or after.
if (leftClangModule->getTopLevelModuleName() <
rightSwiftModule->getName().str()) {
return -1;
}
return 1;
}
auto *rightClangModule = right->get<const clang::Module *>();
assert(rightClangModule->isSubModule() &&
"top-level modules should use a normal swift::ModuleDecl");
SmallVector<StringRef, 8> leftReversePath(
ModuleDecl::ReverseFullNameIterator(leftClangModule), {});
SmallVector<StringRef, 8> rightReversePath(
ModuleDecl::ReverseFullNameIterator(rightClangModule), {});
assert(leftReversePath != rightReversePath &&
"distinct Clang modules should not have the same full name");
if (std::lexicographical_compare(leftReversePath.rbegin(),
leftReversePath.rend(),
rightReversePath.rbegin(),
rightReversePath.rend())) {
return -1;
}
return 1;
}
void writeImports(raw_ostream &out) {
out << "#if __has_feature(modules)\n";
out << "#if __has_warning(\"-Watimport-in-framework-header\")\n"
<< "#pragma clang diagnostic ignored \"-Watimport-in-framework-header\"\n"
<< "#endif\n";
// Sort alphabetically for determinism and consistency.
SmallVector<ImportModuleTy, 8> sortedImports{imports.begin(),
imports.end()};
llvm::array_pod_sort(sortedImports.begin(), sortedImports.end(),
&compareImportModulesByName);
// Track printed names to handle overlay modules.
llvm::SmallPtrSet<Identifier, 8> seenImports;
bool includeUnderlying = false;
for (auto import : sortedImports) {
if (auto *swiftModule = import.dyn_cast<ModuleDecl *>()) {
auto Name = swiftModule->getName();
if (isUnderlyingModule(swiftModule)) {
includeUnderlying = true;
continue;
}
if (seenImports.insert(Name).second)
out << "@import " << Name.str() << ";\n";
} else {
const auto *clangModule = import.get<const clang::Module *>();
assert(clangModule->isSubModule() &&
"top-level modules should use a normal swift::ModuleDecl");
out << "@import ";
ModuleDecl::ReverseFullNameIterator(clangModule).printForward(out);
out << ";\n";
}
}
out << "#endif\n\n";
if (includeUnderlying) {
if (bridgingHeader.empty())
out << "#import <" << M.getName().str() << '/' << M.getName().str()
<< ".h>\n\n";
else
out << "#import \"" << bridgingHeader << "\"\n\n";
}
}
bool writeToStream(raw_ostream &out) {
SmallVector<Decl *, 64> decls;
M.getTopLevelDecls(decls);
auto newEnd = std::remove_if(decls.begin(), decls.end(),
[this](const Decl *D) -> bool {
if (auto VD = dyn_cast<ValueDecl>(D))
return !printer.shouldInclude(VD);
if (auto ED = dyn_cast<ExtensionDecl>(D)) {
auto baseClass = ED->getSelfClassDecl();
return !baseClass || !printer.shouldInclude(baseClass) ||
baseClass->isForeign();
}
return true;
});
decls.erase(newEnd, decls.end());
// REVERSE sort the decls, since we are going to copy them onto a stack.
llvm::array_pod_sort(decls.begin(), decls.end(),
[](Decl * const *lhs, Decl * const *rhs) -> int {
enum : int {
Ascending = -1,
Equivalent = 0,
Descending = 1,
};
assert(*lhs != *rhs && "duplicate top-level decl");
auto getSortName = [](const Decl *D) -> StringRef {
if (auto VD = dyn_cast<ValueDecl>(D))
return VD->getBaseName().userFacingName();
if (auto ED = dyn_cast<ExtensionDecl>(D)) {
auto baseClass = ED->getSelfClassDecl();
return baseClass->getName().str();
}
llvm_unreachable("unknown top-level ObjC decl");
};
// Sort by names.
int result = getSortName(*rhs).compare(getSortName(*lhs));
if (result != 0)
return result;
// Prefer value decls to extensions.
assert(!(isa<ValueDecl>(*lhs) && isa<ValueDecl>(*rhs)));
if (isa<ValueDecl>(*lhs) && !isa<ValueDecl>(*rhs))
return Descending;
if (!isa<ValueDecl>(*lhs) && isa<ValueDecl>(*rhs))
return Ascending;
// Break ties in extensions by putting smaller extensions last (in reverse
// order).
// FIXME: This will end up taking linear time.
auto lhsMembers = cast<ExtensionDecl>(*lhs)->getMembers();
auto rhsMembers = cast<ExtensionDecl>(*rhs)->getMembers();
unsigned numLHSMembers = std::distance(lhsMembers.begin(),
lhsMembers.end());
unsigned numRHSMembers = std::distance(rhsMembers.begin(),
rhsMembers.end());
if (numLHSMembers != numRHSMembers)
return numLHSMembers < numRHSMembers ? Descending : Ascending;
// Or the extension with fewer protocols.
auto lhsProtos = cast<ExtensionDecl>(*lhs)->getLocalProtocols();
auto rhsProtos = cast<ExtensionDecl>(*rhs)->getLocalProtocols();
if (lhsProtos.size() != rhsProtos.size())
return lhsProtos.size() < rhsProtos.size() ? Descending : Ascending;
// If that fails, arbitrarily pick the extension whose protocols are
// alphabetically first.
auto mismatch =
std::mismatch(lhsProtos.begin(), lhsProtos.end(), rhsProtos.begin(),
[] (const ProtocolDecl *nextLHSProto,
const ProtocolDecl *nextRHSProto) {
return nextLHSProto->getName() != nextRHSProto->getName();
});
if (mismatch.first == lhsProtos.end())
return Equivalent;
StringRef lhsProtoName = (*mismatch.first)->getName().str();
return lhsProtoName.compare((*mismatch.second)->getName().str());
});
assert(declsToWrite.empty());
declsToWrite.assign(decls.begin(), decls.end());
while (!declsToWrite.empty()) {
const Decl *D = declsToWrite.back();
bool success = true;
if (isa<ValueDecl>(D)) {
if (auto CD = dyn_cast<ClassDecl>(D))
success = writeClass(CD);
else if (auto PD = dyn_cast<ProtocolDecl>(D))
success = writeProtocol(PD);
else if (auto ED = dyn_cast<EnumDecl>(D))
success = writeEnum(ED);
else if (auto ED = dyn_cast<FuncDecl>(D))
success = writeFunc(ED);
else
llvm_unreachable("unknown top-level ObjC value decl");
} else if (auto ED = dyn_cast<ExtensionDecl>(D)) {
success = writeExtension(ED);
} else {
llvm_unreachable("unknown top-level ObjC decl");
}
if (success) {
assert(declsToWrite.back() == D);
os << "\n";
declsToWrite.pop_back();
}
}
if (!delayedMembers.empty()) {
auto groupBegin = delayedMembers.begin();
for (auto i = groupBegin, e = delayedMembers.end(); i != e; ++i) {
if ((*i)->getDeclContext() != (*groupBegin)->getDeclContext()) {
printer.printAdHocCategory(make_range(groupBegin, i));
groupBegin = i;
}
}
printer.printAdHocCategory(make_range(groupBegin, delayedMembers.end()));
}
writePrologue(out);
writeImports(out);
out <<
"#pragma clang diagnostic ignored \"-Wproperty-attribute-mismatch\"\n"
"#pragma clang diagnostic ignored \"-Wduplicate-method-arg\"\n"
"#if __has_warning(\"-Wpragma-clang-attribute\")\n"
"# pragma clang diagnostic ignored \"-Wpragma-clang-attribute\"\n"
"#endif\n"
"#pragma clang diagnostic ignored \"-Wunknown-pragmas\"\n"
"#pragma clang diagnostic ignored \"-Wnullability\"\n"
"\n"
"#if __has_attribute(external_source_symbol)\n"
"# pragma push_macro(\"any\")\n"
"# undef any\n"
"# pragma clang attribute push("
"__attribute__((external_source_symbol(language=\"Swift\", "
"defined_in=\"" << M.getNameStr() << "\",generated_declaration))), "
"apply_to=any(function,enum,objc_interface,objc_category,"
"objc_protocol))\n"
"# pragma pop_macro(\"any\")\n"
"#endif\n\n"
<< os.str()
<< "#if __has_attribute(external_source_symbol)\n"
"# pragma clang attribute pop\n"
"#endif\n"
"#pragma clang diagnostic pop\n";
return false;
}
};
} // end anonymous namespace
bool swift::printAsObjC(llvm::raw_ostream &os, ModuleDecl *M,
StringRef bridgingHeader,
AccessLevel minRequiredAccess) {
llvm::PrettyStackTraceString trace("While generating Objective-C header");
return ModuleWriter(*M, bridgingHeader, minRequiredAccess).writeToStream(os);
}