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fuchsia / third_party / swift / refs/tags/swift-DEVELOPMENT-SNAPSHOT-2019-04-04-a / . / include / swift / AST / ASTContext.h
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//===--- ASTContext.h - AST Context Object ----------------------*- C++ -*-===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2017 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
//
//===----------------------------------------------------------------------===//
//
// This file defines the ASTContext interface.
//
//===----------------------------------------------------------------------===//
#ifndef SWIFT_AST_ASTCONTEXT_H
#define SWIFT_AST_ASTCONTEXT_H
#include "llvm/Support/DataTypes.h"
#include "swift/AST/ClangModuleLoader.h"
#include "swift/AST/Evaluator.h"
#include "swift/AST/Identifier.h"
#include "swift/AST/SearchPathOptions.h"
#include "swift/AST/Type.h"
#include "swift/AST/TypeAlignments.h"
#include "swift/Basic/LangOptions.h"
#include "swift/Basic/Malloc.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/MapVector.h"
#include "llvm/ADT/IntrusiveRefCntPtr.h"
#include "llvm/ADT/PointerIntPair.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/TinyPtrVector.h"
#include "llvm/Support/Allocator.h"
#include <functional>
#include <memory>
#include <utility>
#include <vector>
namespace clang {
class Decl;
class MacroInfo;
class Module;
class ObjCInterfaceDecl;
}
namespace swift {
class ASTContext;
enum class Associativity : unsigned char;
class BoundGenericType;
class ClangNode;
class ConstructorDecl;
class Decl;
class DeclContext;
class DefaultArgumentInitializer;
class ExtensionDecl;
class ForeignRepresentationInfo;
class FuncDecl;
class GenericContext;
class InFlightDiagnostic;
class IterableDeclContext;
class LazyContextData;
class LazyGenericContextData;
class LazyIterableDeclContextData;
class LazyMemberLoader;
class LazyMemberParser;
class LazyResolver;
class PatternBindingDecl;
class PatternBindingInitializer;
class SourceFile;
class SourceLoc;
class Type;
class TypeVariableType;
class TupleType;
class FunctionType;
class GenericSignatureBuilder;
class ArchetypeType;
class Identifier;
class InheritedNameSet;
class ModuleDecl;
class ModuleLoader;
class NominalTypeDecl;
class NormalProtocolConformance;
class InheritedProtocolConformance;
class SelfProtocolConformance;
class SpecializedProtocolConformance;
enum class ProtocolConformanceState;
class Pattern;
enum PointerTypeKind : unsigned;
class PrecedenceGroupDecl;
class TupleTypeElt;
class EnumElementDecl;
class ProtocolDecl;
class SubstitutableType;
class SourceManager;
class ValueDecl;
class DiagnosticEngine;
class TypeCheckerDebugConsumer;
struct RawComment;
class DocComment;
class SILBoxType;
class TypeAliasDecl;
class VarDecl;
class UnifiedStatsReporter;
enum class KnownProtocolKind : uint8_t;
namespace syntax {
class SyntaxArena;
}
/// The arena in which a particular ASTContext allocation will go.
enum class AllocationArena {
/// The permanent arena, which is tied to the lifetime of
/// the ASTContext.
///
/// All global declarations and types need to be allocated into this arena.
/// At present, everything that is not a type involving a type variable is
/// allocated in this arena.
Permanent,
/// The constraint solver's temporary arena, which is tied to the
/// lifetime of a particular instance of the constraint solver.
///
/// Any type involving a type variable is allocated in this arena.
ConstraintSolver
};
/// Lists the set of "known" Foundation entities that are used in the
/// compiler.
///
/// While the names of Foundation types aren't likely to change in
/// Objective-C, their mapping into Swift can. Therefore, when
/// referring to names of Foundation entities in Swift, use this enum
/// and \c ASTContext::getSwiftName or \c ASTContext::getSwiftId.
enum class KnownFoundationEntity {
#define FOUNDATION_ENTITY(Name) Name,
#include "swift/AST/KnownFoundationEntities.def"
};
/// Retrieve the Foundation entity kind for the given Objective-C
/// entity name.
Optional<KnownFoundationEntity> getKnownFoundationEntity(StringRef name);
/// Introduces a new constraint checker arena, whose lifetime is
/// tied to the lifetime of this RAII object.
class ConstraintCheckerArenaRAII {
ASTContext &Self;
void *Data;
public:
/// Introduces a new constraint checker arena, supplanting any
/// existing constraint checker arena.
///
/// \param self The ASTContext into which this constraint checker arena
/// will be installed.
///
/// \param allocator The allocator used for allocating any data that
/// goes into the constraint checker arena.
ConstraintCheckerArenaRAII(ASTContext &self,
llvm::BumpPtrAllocator &allocator);
ConstraintCheckerArenaRAII(const ConstraintCheckerArenaRAII &) = delete;
ConstraintCheckerArenaRAII(ConstraintCheckerArenaRAII &&) = delete;
ConstraintCheckerArenaRAII &
operator=(const ConstraintCheckerArenaRAII &) = delete;
ConstraintCheckerArenaRAII &
operator=(ConstraintCheckerArenaRAII &&) = delete;
~ConstraintCheckerArenaRAII();
};
class SILLayout; // From SIL
/// ASTContext - This object creates and owns the AST objects.
/// However, this class does more than just maintain context within an AST.
/// It is the closest thing to thread-local or compile-local storage in this
/// code base. Why? SourceKit uses this code with multiple threads per Unix
/// process. Each thread processes a different source file. Each thread has its
/// own instance of ASTContext, and that instance persists for the duration of
/// the thread, throughout all phases of the compilation. (The name "ASTContext"
/// is a bit of a misnomer here.) Why not use thread-local storage? This code
/// may use DispatchQueues and pthread-style TLS won't work with code that uses
/// DispatchQueues. Summary: if you think you need a global or static variable,
/// you probably need to put it here instead.
class ASTContext final {
ASTContext(const ASTContext&) = delete;
void operator=(const ASTContext&) = delete;
ASTContext(LangOptions &langOpts, SearchPathOptions &SearchPathOpts,
SourceManager &SourceMgr, DiagnosticEngine &Diags);
public:
// Members that should only be used by ASTContext.cpp.
struct Implementation;
Implementation &getImpl() const;
friend ConstraintCheckerArenaRAII;
void operator delete(void *Data) throw();
static ASTContext *get(LangOptions &langOpts,
SearchPathOptions &SearchPathOpts,
SourceManager &SourceMgr,
DiagnosticEngine &Diags);
~ASTContext();
/// Optional table of counters to report, nullptr when not collecting.
///
/// This must be initialized early so that Allocate() doesn't try to access
/// it before being set to null.
UnifiedStatsReporter *Stats = nullptr;
/// The language options used for translation.
LangOptions &LangOpts;
/// The search path options used by this AST context.
SearchPathOptions &SearchPathOpts;
/// The source manager object.
SourceManager &SourceMgr;
/// Diags - The diagnostics engine.
DiagnosticEngine &Diags;
/// The request-evaluator that is used to process various requests.
Evaluator evaluator;
/// The set of top-level modules we have loaded.
/// This map is used for iteration, therefore it's a MapVector and not a
/// DenseMap.
llvm::MapVector<Identifier, ModuleDecl*> LoadedModules;
/// The builtin module.
ModuleDecl * const TheBuiltinModule;
/// The standard library module.
mutable ModuleDecl *TheStdlibModule = nullptr;
/// The name of the standard library module "Swift".
Identifier StdlibModuleName;
/// The name of the SwiftShims module "SwiftShims".
Identifier SwiftShimsModuleName;
// Define the set of known identifiers.
#define IDENTIFIER_WITH_NAME(Name, IdStr) Identifier Id_##Name;
#include "swift/AST/KnownIdentifiers.def"
/// The list of external definitions imported by this context.
llvm::SetVector<Decl *> ExternalDefinitions;
/// FIXME: HACK HACK HACK
/// This state should be tracked somewhere else.
unsigned LastCheckedExternalDefinition = 0;
/// A consumer of type checker debug output.
std::unique_ptr<TypeCheckerDebugConsumer> TypeCheckerDebug;
/// Cache for names of canonical GenericTypeParamTypes.
mutable llvm::DenseMap<unsigned, Identifier>
CanonicalGenericTypeParamTypeNames;
/// Cache of remapped types (useful for diagnostics).
llvm::StringMap<Type> RemappedTypes;
private:
/// The current generation number, which reflects the number of
/// times that external modules have been loaded.
///
/// Various places in the AST, such as the set of extensions associated with
/// a nominal type, keep track of the generation number they saw and will
/// automatically update when they are out of date.
unsigned CurrentGeneration = 0;
friend class Pattern;
/// Mapping from patterns that store interface types that will be lazily
/// resolved to contextual types, to the declaration context in which the
/// pattern resides.
llvm::DenseMap<const Pattern *, DeclContext *>
DelayedPatternContexts;
/// Cache of module names that fail the 'canImport' test in this context.
llvm::SmallPtrSet<Identifier, 8> FailedModuleImportNames;
/// Retrieve the allocator for the given arena.
llvm::BumpPtrAllocator &
getAllocator(AllocationArena arena = AllocationArena::Permanent) const;
public:
/// Allocate - Allocate memory from the ASTContext bump pointer.
void *Allocate(unsigned long bytes, unsigned alignment,
AllocationArena arena = AllocationArena::Permanent) const {
if (bytes == 0)
return nullptr;
if (LangOpts.UseMalloc)
return AlignedAlloc(bytes, alignment);
if (arena == AllocationArena::Permanent && Stats)
Stats->getFrontendCounters().NumASTBytesAllocated += bytes;
return getAllocator(arena).Allocate(bytes, alignment);
}
template <typename T>
T *Allocate(AllocationArena arena = AllocationArena::Permanent) const {
T *res = (T *) Allocate(sizeof(T), alignof(T), arena);
new (res) T();
return res;
}
template <typename T>
MutableArrayRef<T> AllocateUninitialized(unsigned NumElts,
AllocationArena Arena = AllocationArena::Permanent) const {
T *Data = (T *) Allocate(sizeof(T) * NumElts, alignof(T), Arena);
return { Data, NumElts };
}
template <typename T>
MutableArrayRef<T> Allocate(unsigned numElts,
AllocationArena arena = AllocationArena::Permanent) const {
T *res = (T *) Allocate(sizeof(T) * numElts, alignof(T), arena);
for (unsigned i = 0; i != numElts; ++i)
new (res+i) T();
return {res, numElts};
}
/// Allocate a copy of the specified object.
template <typename T>
typename std::remove_reference<T>::type *AllocateObjectCopy(T &&t,
AllocationArena arena = AllocationArena::Permanent) const {
// This function cannot be named AllocateCopy because it would always win
// overload resolution over the AllocateCopy(ArrayRef<T>).
using TNoRef = typename std::remove_reference<T>::type;
TNoRef *res = (TNoRef *) Allocate(sizeof(TNoRef), alignof(TNoRef), arena);
new (res) TNoRef(std::forward<T>(t));
return res;
}
template <typename T, typename It>
T *AllocateCopy(It start, It end,
AllocationArena arena = AllocationArena::Permanent) const {
T *res = (T*)Allocate(sizeof(T)*(end-start), alignof(T), arena);
for (unsigned i = 0; start != end; ++start, ++i)
new (res+i) T(*start);
return res;
}
template<typename T, size_t N>
MutableArrayRef<T> AllocateCopy(T (&array)[N],
AllocationArena arena = AllocationArena::Permanent) const {
return MutableArrayRef<T>(AllocateCopy<T>(array, array+N, arena), N);
}
template<typename T>
MutableArrayRef<T> AllocateCopy(ArrayRef<T> array,
AllocationArena arena = AllocationArena::Permanent) const {
return MutableArrayRef<T>(AllocateCopy<T>(array.begin(),array.end(), arena),
array.size());
}
template<typename T>
ArrayRef<T> AllocateCopy(const SmallVectorImpl<T> &vec,
AllocationArena arena = AllocationArena::Permanent) const {
return AllocateCopy(ArrayRef<T>(vec), arena);
}
template<typename T>
MutableArrayRef<T>
AllocateCopy(SmallVectorImpl<T> &vec,
AllocationArena arena = AllocationArena::Permanent) const {
return AllocateCopy(MutableArrayRef<T>(vec), arena);
}
StringRef AllocateCopy(StringRef Str,
AllocationArena arena = AllocationArena::Permanent) const {
ArrayRef<char> Result =
AllocateCopy(llvm::makeArrayRef(Str.data(), Str.size()), arena);
return StringRef(Result.data(), Result.size());
}
template<typename T, typename Vector, typename Set>
MutableArrayRef<T>
AllocateCopy(llvm::SetVector<T, Vector, Set> setVector,
AllocationArena arena = AllocationArena::Permanent) const {
return MutableArrayRef<T>(AllocateCopy<T>(setVector.begin(),
setVector.end(),
arena),
setVector.size());
}
/// Retrive the syntax node memory manager for this context.
llvm::IntrusiveRefCntPtr<syntax::SyntaxArena> getSyntaxArena() const;
/// Set a new stats reporter.
void setStatsReporter(UnifiedStatsReporter *stats);
/// Creates a new lazy resolver by passing the ASTContext and the other
/// given arguments to a newly-allocated instance of \c ResolverType.
///
/// \returns true if a new lazy resolver was created, false if there was
/// already a lazy resolver registered.
template<typename ResolverType, typename ... Args>
bool createLazyResolverIfMissing(Args && ...args) {
if (getLazyResolver())
return false;
setLazyResolver(new ResolverType(*this, std::forward<Args>(args)...));
return true;
}
/// Remove the lazy resolver, if there is one.
///
/// FIXME: We probably don't ever want to do this.
void removeLazyResolver() {
setLazyResolver(nullptr);
}
/// Retrieve the lazy resolver for this context.
LazyResolver *getLazyResolver() const;
private:
/// Set the lazy resolver for this context.
void setLazyResolver(LazyResolver *resolver);
public:
/// Add a lazy parser for resolving members later.
void addLazyParser(LazyMemberParser *parser);
/// Remove a lazy parser.
void removeLazyParser(LazyMemberParser *parser);
/// getIdentifier - Return the uniqued and AST-Context-owned version of the
/// specified string.
Identifier getIdentifier(StringRef Str) const;
/// Decide how to interpret two precedence groups.
Associativity associateInfixOperators(PrecedenceGroupDecl *left,
PrecedenceGroupDecl *right) const;
/// Retrieve the declaration of Swift.Error.
ProtocolDecl *getErrorDecl() const;
CanType getExceptionType() const;
#define KNOWN_STDLIB_TYPE_DECL(NAME, DECL_CLASS, NUM_GENERIC_PARAMS) \
/** Retrieve the declaration of Swift.NAME. */ \
DECL_CLASS *get##NAME##Decl() const;
#include "swift/AST/KnownStdlibTypes.def"
/// Retrieve the declaration of Swift.Optional<T>.Some.
EnumElementDecl *getOptionalSomeDecl() const;
/// Retrieve the declaration of Swift.Optional<T>.None.
EnumElementDecl *getOptionalNoneDecl() const;
/// Retrieve the declaration of the "pointee" property of a pointer type.
VarDecl *getPointerPointeePropertyDecl(PointerTypeKind ptrKind) const;
/// Retrieve the type Swift.AnyObject.
CanType getAnyObjectType() const;
/// Retrieve the type Swift.Never.
CanType getNeverType() const;
/// Retrieve the declaration of Swift.Void.
TypeAliasDecl *getVoidDecl() const;
/// Retrieve the declaration of ObjectiveC.ObjCBool.
StructDecl *getObjCBoolDecl() const;
/// Retrieve the declaration of Foundation.NSError.
ClassDecl *getNSErrorDecl() const;
/// Retrieve the declaration of Foundation.NSNumber.
ClassDecl *getNSNumberDecl() const;
/// Retrieve the declaration of Foundation.NSValue.
ClassDecl *getNSValueDecl() const;
// Declare accessors for the known declarations.
#define FUNC_DECL(Name, Id) \
FuncDecl *get##Name() const;
#include "swift/AST/KnownDecls.def"
/// Get the '+' function on two RangeReplaceableCollection.
FuncDecl *getPlusFunctionOnRangeReplaceableCollection() const;
/// Get the '+' function on two String.
FuncDecl *getPlusFunctionOnString() const;
/// Check whether the standard library provides all the correct
/// intrinsic support for Optional<T>.
///
/// If this is true, the four methods above all promise to return
/// non-null.
bool hasOptionalIntrinsics() const;
/// Check whether the standard library provides all the correct
/// intrinsic support for UnsafeMutablePointer<T> function arguments.
///
/// If this is true, the methods getConvert*ToPointerArgument
/// all promise to return non-null.
bool hasPointerArgumentIntrinsics() const;
/// Check whether the standard library provides all the correct
/// intrinsic support for array literals.
///
/// If this is true, the method getAllocateUninitializedArray
/// promises to return non-null.
bool hasArrayLiteralIntrinsics() const;
/// Retrieve the declaration of Swift.Bool.init(_builtinBooleanLiteral:)
ConstructorDecl *getBoolBuiltinInitDecl() const;
/// Retrieve the declaration of Swift.==(Int, Int) -> Bool.
FuncDecl *getEqualIntDecl() const;
/// Retrieve the declaration of Swift._hashValue<H>(for: H) -> Int.
FuncDecl *getHashValueForDecl() const;
/// Retrieve the declaration of Array.append(element:)
FuncDecl *getArrayAppendElementDecl() const;
/// Retrieve the declaration of
/// Array.reserveCapacityForAppend(newElementsCount: Int)
FuncDecl *getArrayReserveCapacityDecl() const;
/// Retrieve the declaration of Swift._unimplementedInitializer.
FuncDecl *getUnimplementedInitializerDecl() const;
/// Retrieve the declaration of Swift._undefined.
FuncDecl *getUndefinedDecl() const;
// Retrieve the declaration of Swift._stdlib_isOSVersionAtLeast.
FuncDecl *getIsOSVersionAtLeastDecl() const;
/// Look for the declaration with the given name within the
/// Swift module.
void lookupInSwiftModule(StringRef name,
SmallVectorImpl<ValueDecl *> &results) const;
/// Retrieve a specific, known protocol.
ProtocolDecl *getProtocol(KnownProtocolKind kind) const;
/// Determine whether the given nominal type is one of the standard
/// library or Cocoa framework types that is known to be bridged by another
/// module's overlay, for layering or implementation detail reasons.
bool isTypeBridgedInExternalModule(NominalTypeDecl *nominal) const;
/// True if the given type is an Objective-C class that serves as the bridged
/// object type for many Swift value types, meaning that the conversion from
/// an object to a value is a conditional cast.
bool isObjCClassWithMultipleSwiftBridgedTypes(Type t);
/// Get the Objective-C type that a Swift type bridges to, if any.
///
/// \param dc The context in which bridging is occurring.
/// \param type The Swift for which we are querying bridging behavior.
/// \param bridgedValueType The specific value type that is bridged,
/// which will usually by the same as \c type.
Type getBridgedToObjC(const DeclContext *dc, Type type,
Type *bridgedValueType = nullptr) const;
/// Determine whether the given Swift type is representable in a
/// given foreign language.
ForeignRepresentationInfo
getForeignRepresentationInfo(NominalTypeDecl *nominal,
ForeignLanguage language,
const DeclContext *dc);
/// Add a declaration to a list of declarations that need to be emitted
/// as part of the current module or source file, but are otherwise not
/// nested within it.
void addExternalDecl(Decl *decl);
/// Add a declaration that was synthesized to a per-source file list if
/// if is part of a source file, or the external declarations list if
/// it is part of an imported type context.
void addSynthesizedDecl(Decl *decl);
/// Add a cleanup function to be called when the ASTContext is deallocated.
void addCleanup(std::function<void(void)> cleanup);
/// Add a cleanup to run the given object's destructor when the ASTContext is
/// deallocated.
template<typename T>
void addDestructorCleanup(T &object) {
addCleanup([&object]{ object.~T(); });
}
//===--------------------------------------------------------------------===//
// Diagnostics Helper functions
//===--------------------------------------------------------------------===//
bool hadError() const;
//===--------------------------------------------------------------------===//
// Type manipulation routines.
//===--------------------------------------------------------------------===//
// Builtin type and simple types that are used frequently.
const CanType TheErrorType; /// This is the ErrorType singleton.
const CanType TheUnresolvedType; /// This is the UnresolvedType singleton.
const CanType TheEmptyTupleType; /// This is '()', aka Void
const CanType TheAnyType; /// This is 'Any', the empty protocol composition
const CanType TheNativeObjectType; /// Builtin.NativeObject
const CanType TheBridgeObjectType; /// Builtin.BridgeObject
const CanType TheUnknownObjectType; /// Builtin.UnknownObject
const CanType TheRawPointerType; /// Builtin.RawPointer
const CanType TheUnsafeValueBufferType; /// Builtin.UnsafeValueBuffer
const CanType TheSILTokenType; /// Builtin.SILToken
const CanType TheIntegerLiteralType; /// Builtin.IntegerLiteralType
const CanType TheIEEE32Type; /// 32-bit IEEE floating point
const CanType TheIEEE64Type; /// 64-bit IEEE floating point
// Target specific types.
const CanType TheIEEE16Type; /// 16-bit IEEE floating point
const CanType TheIEEE80Type; /// 80-bit IEEE floating point
const CanType TheIEEE128Type; /// 128-bit IEEE floating point
const CanType ThePPC128Type; /// 128-bit PowerPC 2xDouble
/// Adds a search path to SearchPathOpts, unless it is already present.
///
/// Does any proper bookkeeping to keep all module loaders up to date as well.
void addSearchPath(StringRef searchPath, bool isFramework, bool isSystem);
/// Adds a module loader to this AST context.
///
/// \param loader The new module loader, which will be added after any
/// existing module loaders.
/// \param isClang \c true if this module loader is responsible for loading
/// Clang modules, which are special-cased in some parts of the
/// compiler.
void addModuleLoader(std::unique_ptr<ModuleLoader> loader,
bool isClang = false);
/// Load extensions to the given nominal type from the external
/// module loaders.
///
/// \param nominal The nominal type whose extensions should be loaded.
///
/// \param previousGeneration The previous generation number. The AST already
/// contains extensions loaded from any generation up to and including this
/// one.
void loadExtensions(NominalTypeDecl *nominal, unsigned previousGeneration);
/// Load the methods within the given class that produce
/// Objective-C class or instance methods with the given selector.
///
/// \param classDecl The class in which we are searching for @objc methods.
/// The search only considers this class and its extensions; not any
/// superclasses.
///
/// \param selector The selector to search for.
///
/// \param isInstanceMethod Whether we are looking for an instance method
/// (vs. a class method).
///
/// \param previousGeneration The previous generation with which this
/// callback was invoked. The list of methods will already contain all of
/// the results from generations up and including \c previousGeneration.
///
/// \param methods The list of @objc methods in this class that have this
/// selector and are instance/class methods as requested. This list will be
/// extended with any methods found in subsequent generations.
void loadObjCMethods(ClassDecl *classDecl,
ObjCSelector selector,
bool isInstanceMethod,
unsigned previousGeneration,
llvm::TinyPtrVector<AbstractFunctionDecl *> &methods);
/// Retrieve the Clang module loader for this ASTContext.
///
/// If there is no Clang module loader, returns a null pointer.
/// The loader is owned by the AST context.
ClangModuleLoader *getClangModuleLoader() const;
/// Asks every module loader to verify the ASTs it has loaded.
///
/// Does nothing in non-asserts (NDEBUG) builds.
void verifyAllLoadedModules() const;
/// Check whether the module with a given name can be imported without
/// importing it.
///
/// Note that even if this check succeeds, errors may still occur if the
/// module is loaded in full.
bool canImportModule(std::pair<Identifier, SourceLoc> ModulePath);
/// \returns a module with a given name that was already loaded. If the
/// module was not loaded, returns nullptr.
ModuleDecl *getLoadedModule(
ArrayRef<std::pair<Identifier, SourceLoc>> ModulePath) const;
ModuleDecl *getLoadedModule(Identifier ModuleName) const;
/// Attempts to load a module into this ASTContext.
///
/// If a module by this name has already been loaded, the existing module will
/// be returned.
///
/// \returns The requested module, or NULL if the module cannot be found.
ModuleDecl *getModule(ArrayRef<std::pair<Identifier, SourceLoc>> ModulePath);
ModuleDecl *getModuleByName(StringRef ModuleName);
/// Returns the standard library module, or null if the library isn't present.
///
/// If \p loadIfAbsent is true, the ASTContext will attempt to load the module
/// if it hasn't been set yet.
ModuleDecl *getStdlibModule(bool loadIfAbsent = false);
ModuleDecl *getStdlibModule() const {
return const_cast<ASTContext *>(this)->getStdlibModule(false);
}
/// Retrieve the current generation number, which reflects the
/// number of times a module import has caused mass invalidation of
/// lookup tables.
///
/// Various places in the AST keep track of the generation numbers at which
/// their own information is valid, such as the list of extensions associated
/// with a nominal type.
unsigned getCurrentGeneration() const { return CurrentGeneration; }
/// Increase the generation number, implying that various lookup
/// tables have been significantly altered by the introduction of a new
/// module import.
///
/// \returns the previous generation number.
unsigned bumpGeneration() { return CurrentGeneration++; }
/// Produce a "normal" conformance for a nominal type.
NormalProtocolConformance *
getConformance(Type conformingType,
ProtocolDecl *protocol,
SourceLoc loc,
DeclContext *dc,
ProtocolConformanceState state);
/// Produce a self-conformance for the given protocol.
SelfProtocolConformance *
getSelfConformance(ProtocolDecl *protocol);
/// A callback used to produce a diagnostic for an ill-formed protocol
/// conformance that was type-checked before we're actually walking the
/// conformance itself, along with a bit indicating whether this diagnostic
/// produces an error.
struct DelayedConformanceDiag {
ValueDecl *Requirement;
std::function<void()> Callback;
bool IsError;
};
/// Check whether current context has any errors associated with
/// ill-formed protocol conformances which haven't been produced yet.
bool hasDelayedConformanceErrors() const;
/// Add a delayed diagnostic produced while type-checking a
/// particular protocol conformance.
void addDelayedConformanceDiag(NormalProtocolConformance *conformance,
DelayedConformanceDiag fn);
/// Retrieve the delayed-conformance diagnostic callbacks for the
/// given normal protocol conformance.
std::vector<DelayedConformanceDiag>
takeDelayedConformanceDiags(NormalProtocolConformance *conformance);
/// Add delayed missing witnesses for the given normal protocol conformance.
void addDelayedMissingWitnesses(NormalProtocolConformance *conformance,
ArrayRef<ValueDecl*> witnesses);
/// Retrieve the delayed missing witnesses for the given normal protocol
/// conformance.
std::vector<ValueDecl*>
takeDelayedMissingWitnesses(NormalProtocolConformance *conformance);
/// Produce a specialized conformance, which takes a generic
/// conformance and substitutions written in terms of the generic
/// conformance's signature.
///
/// \param type The type for which we are retrieving the conformance.
///
/// \param generic The generic conformance.
///
/// \param substitutions The set of substitutions required to produce the
/// specialized conformance from the generic conformance.
ProtocolConformance *
getSpecializedConformance(Type type,
ProtocolConformance *generic,
SubstitutionMap substitutions);
/// Produce an inherited conformance, for subclasses of a type
/// that already conforms to a protocol.
///
/// \param type The type for which we are retrieving the conformance.
///
/// \param inherited The inherited conformance.
InheritedProtocolConformance *
getInheritedConformance(Type type, ProtocolConformance *inherited);
/// Get the lazy data for the given declaration.
///
/// \param lazyLoader If non-null, the lazy loader to use when creating the
/// lazy data. The pointer must either be null or be consistent
/// across all calls for the same \p func.
LazyContextData *getOrCreateLazyContextData(const DeclContext *decl,
LazyMemberLoader *lazyLoader);
/// Use the lazy parsers associated with the context to populate the members
/// of the given decl context.
///
/// \param IDC The context whose member decls should be lazily parsed.
void parseMembers(IterableDeclContext *IDC);
/// Use the lazy parsers associated with the context to check whether the decl
/// context has been parsed.
bool hasUnparsedMembers(const IterableDeclContext *IDC) const;
/// Get the lazy function data for the given generic context.
///
/// \param lazyLoader If non-null, the lazy loader to use when creating the
/// function data. The pointer must either be null or be consistent
/// across all calls for the same \p func.
LazyGenericContextData *getOrCreateLazyGenericContextData(
const GenericContext *dc,
LazyMemberLoader *lazyLoader);
/// Get the lazy iterable context for the given iterable declaration context.
///
/// \param lazyLoader If non-null, the lazy loader to use when creating the
/// iterable context data. The pointer must either be null or be consistent
/// across all calls for the same \p idc.
LazyIterableDeclContextData *getOrCreateLazyIterableContextData(
const IterableDeclContext *idc,
LazyMemberLoader *lazyLoader);
/// Returns memory usage of this ASTContext.
size_t getTotalMemory() const;
/// Returns memory used exclusively by constraint solver.
size_t getSolverMemory() const;
/// Complain if @objc or dynamic is used without importing Foundation.
void diagnoseAttrsRequiringFoundation(SourceFile &SF);
/// Note that the given method produces an Objective-C method.
void recordObjCMethod(AbstractFunctionDecl *method);
/// Diagnose any Objective-C method overrides that aren't reflected
/// as overrides in Swift.
bool diagnoseUnintendedObjCMethodOverrides(SourceFile &sf);
/// Note that there is a conflict between different definitions that
/// produce the same Objective-C method.
void recordObjCMethodConflict(ClassDecl *classDecl, ObjCSelector selector,
bool isInstance);
/// Diagnose all conflicts between members that have the same
/// Objective-C selector in the same class.
///
/// \param sf The source file for which we are diagnosing conflicts.
///
/// \returns true if there were any conflicts diagnosed.
bool diagnoseObjCMethodConflicts(SourceFile &sf);
/// Note that an optional @objc requirement has gone unsatisfied by
/// a conformance to its protocol.
///
/// \param dc The declaration context in which the conformance occurs.
/// \param req The optional requirement.
void recordObjCUnsatisfiedOptReq(DeclContext *dc, AbstractFunctionDecl *req);
/// Diagnose any unsatisfied @objc optional requirements of
/// protocols that conflict with methods.
bool diagnoseObjCUnsatisfiedOptReqConflicts(SourceFile &sf);
/// Retrieve the Swift name for the given Foundation entity, where
/// "NS" prefix stripping will apply under omit-needless-words.
StringRef getSwiftName(KnownFoundationEntity kind);
/// Retrieve the Swift identifier for the given Foundation entity, where
/// "NS" prefix stripping will apply under omit-needless-words.
Identifier getSwiftId(KnownFoundationEntity kind) {
return getIdentifier(getSwiftName(kind));
}
/// Collect visible clang modules from the ClangModuleLoader. These modules are
/// not necessarily loaded.
void getVisibleTopLevelClangModules(SmallVectorImpl<clang::Module*> &Modules) const;
private:
/// Register the given generic signature builder to be used as the canonical
/// generic signature builder for the given signature, if we don't already
/// have one.
void registerGenericSignatureBuilder(GenericSignature *sig,
GenericSignatureBuilder &&builder);
friend class GenericSignatureBuilder;
public:
/// Retrieve or create the stored generic signature builder for the given
/// canonical generic signature and module.
GenericSignatureBuilder *getOrCreateGenericSignatureBuilder(
CanGenericSignature sig);
/// Retrieve or create the canonical generic environment of a canonical
/// generic signature builder.
GenericEnvironment *getOrCreateCanonicalGenericEnvironment(
GenericSignatureBuilder *builder,
GenericSignature *sig);
/// Retrieve a generic signature with a single unconstrained type parameter,
/// like `<T>`.
CanGenericSignature getSingleGenericParameterSignature() const;
/// Retrieve a generic signature with a single type parameter conforming
/// to the given existential type.
CanGenericSignature getExistentialSignature(CanType existential,
ModuleDecl *mod);
/// Whether our effective Swift version is at least 'major'.
///
/// This is usually the check you want; for example, when introducing
/// a new language feature which is only visible in Swift 5, you would
/// check for isSwiftVersionAtLeast(5).
bool isSwiftVersionAtLeast(unsigned major, unsigned minor = 0) const {
return LangOpts.isSwiftVersionAtLeast(major, minor);
}
/// Check whether it's important to respect access control restrictions
/// in current context.
bool isAccessControlDisabled() const {
return !LangOpts.EnableAccessControl;
}
/// Each kind and SourceFile has its own cache for a Type.
Type &getDefaultTypeRequestCache(SourceFile *, KnownProtocolKind);
private:
friend Decl;
Optional<RawComment> getRawComment(const Decl *D);
void setRawComment(const Decl *D, RawComment RC);
Optional<StringRef> getBriefComment(const Decl *D);
void setBriefComment(const Decl *D, StringRef Comment);
friend TypeBase;
friend ArchetypeType;
/// Provide context-level uniquing for SIL lowered type layouts and boxes.
friend SILLayout;
friend SILBoxType;
};
/// Retrieve information about the given Objective-C method for
/// diagnostic purposes, to be used with OBJC_DIAG_SELECT in
/// DiagnosticsSema.def.
std::pair<unsigned, DeclName> getObjCMethodDiagInfo(
AbstractFunctionDecl *method);
/// Attach Fix-Its to the given diagnostic that updates the name of the
/// given declaration to the desired target name.
///
/// \returns false if the name could not be fixed.
bool fixDeclarationName(InFlightDiagnostic &diag, ValueDecl *decl,
DeclName targetName);
/// Fix the Objective-C name of the given declaration to match the provided
/// Objective-C selector.
///
/// \param ignoreImpliedName When true, ignore the implied name of the
/// given declaration, because it no longer applies.
///
/// For properties, the selector should be a zero-parameter selector of the
/// given property's name.
bool fixDeclarationObjCName(InFlightDiagnostic &diag, ValueDecl *decl,
Optional<ObjCSelector> targetNameOpt,
bool ignoreImpliedName = false);
} // end namespace swift
#endif