//===--- DerivedConformances.h - Derived protocol conformance ---*- C++ -*-===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2014 - 2020 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 entry points to synthesize compiler-derived conformances // to certain known protocols. // //===----------------------------------------------------------------------===// #ifndef SWIFT_SEMA_DERIVEDCONFORMANCES_H #define SWIFT_SEMA_DERIVEDCONFORMANCES_H #include namespace swift { class Decl; class DeclRefExpr; class AccessorDecl; class NominalTypeDecl; class PatternBindingDecl; class Type; class ValueDecl; class VarDecl; class DerivedConformance { public: ASTContext &Context; Decl *ConformanceDecl; NominalTypeDecl *Nominal; ProtocolDecl *Protocol; DerivedConformance(ASTContext &ctx, Decl *conformanceDecl, NominalTypeDecl *nominal, ProtocolDecl *protocol); /// Retrieve the context in which the conformance is declared (either the /// nominal type, or an extension of it) as a \c DeclContext. DeclContext *getConformanceContext() const; /// Add \c children as members of the context that declares the conformance. void addMembersToConformanceContext(ArrayRef children); /// Get the declared type of the protocol that this is conformance is for. Type getProtocolType() const; /// True if the type can implicitly derive a conformance for the given /// protocol. /// /// If true, explicit conformance checking will synthesize implicit /// declarations for requirements of the protocol that are not satisfied by /// the type's explicit members. /// /// \param nominal The nominal type for which we are determining whether to /// derive a witness. /// /// \param protocol The protocol whose requirements are being derived. /// /// \return True if the type can implicitly derive a conformance for the /// given protocol. static bool derivesProtocolConformance(DeclContext *DC, NominalTypeDecl *nominal, ProtocolDecl *protocol); /// Diagnose problems, if any, preventing automatic derivation of protocol /// requirements /// /// \param nominal The nominal type for which we would like to diagnose /// derivation failures /// /// \param protocol The protocol with requirements we would like to diagnose /// derivation failures for static void tryDiagnoseFailedDerivation(DeclContext *DC, NominalTypeDecl *nominal, ProtocolDecl *protocol); /// Determine the derivable requirement that would satisfy the given /// requirement, if there is one. /// /// \param nominal The nominal type for which we are determining whether to /// derive a witness. /// /// \param requirement The requirement for which we are checking for a /// derivation. This requirement need not be within a derivable protocol, /// because derivable requirements can get restated in inherited unrelated /// or unrelated protocols. /// /// \returns The requirement whose witness could be derived to potentially /// satisfy this given requirement, or NULL if there is no such requirement. static ValueDecl *getDerivableRequirement(NominalTypeDecl *nominal, ValueDecl *requirement); /// Determine if an AdditiveArithmetic requirement can be derived for a type. /// /// \returns True if the requirement can be derived. static bool canDeriveAdditiveArithmetic(NominalTypeDecl *type, DeclContext *DC); /// Derive an AdditiveArithmetic requirement for a nominal type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveAdditiveArithmetic(ValueDecl *requirement); /// Determine if a Differentiable requirement can be derived for a type. /// /// \returns True if the requirement can be derived. static bool canDeriveDifferentiable(NominalTypeDecl *type, DeclContext *DC); /// Derive a Differentiable requirement for a nominal type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveDifferentiable(ValueDecl *requirement); /// Derive a Differentiable type witness for a nominal type. /// /// \returns the derived member, which will also be added to the type. Type deriveDifferentiable(AssociatedTypeDecl *assocType); /// Derive a CaseIterable requirement for an enum if it has no associated /// values for any of its cases. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveCaseIterable(ValueDecl *requirement); /// Derive a CaseIterable type witness for an enum if it has no associated /// values for any of its cases. /// /// \returns the derived member, which will also be added to the type. Type deriveCaseIterable(AssociatedTypeDecl *assocType); /// Determine if a RawRepresentable requirement can be derived for a type. /// /// This is implemented for non-empty enums without associated values, /// that declare a raw type in the inheritance clause. static bool canDeriveRawRepresentable(DeclContext *DC, NominalTypeDecl *type); /// Derive a RawRepresentable requirement for an enum, if it has a valid /// raw type and raw values for all of its cases. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveRawRepresentable(ValueDecl *requirement); /// Derive a RawRepresentable type witness for an enum, if it has a valid /// raw type and raw values for all of its cases. /// /// \returns the derived member, which will also be added to the type. Type deriveRawRepresentable(AssociatedTypeDecl *assocType); /// Determine if a Comparable requirement can be derived for a type. /// /// This is implemented for enums without associated or raw values. /// /// \returns True if the requirement can be derived. static bool canDeriveComparable(DeclContext *DC, EnumDecl *enumeration); /// Derive an Equatable requirement for a type. /// /// This is implemented for enums without associated or raw values. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveComparable(ValueDecl *requirement); /// Determine if an Equatable requirement can be derived for a type. /// /// This is implemented for enums without associated values or all-Equatable /// associated values, and for structs with all-Equatable stored properties. /// /// \returns True if the requirement can be derived. static bool canDeriveEquatable(DeclContext *DC, NominalTypeDecl *type); /// Derive an Equatable requirement for a type. /// /// This is implemented for enums without associated values or all-Equatable /// associated values, and for structs with all-Equatable stored properties. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveEquatable(ValueDecl *requirement); /// Diagnose problems, if any, preventing automatic derivation of Equatable /// requirements /// /// \param nominal The nominal type for which we would like to diagnose /// derivation failures static void tryDiagnoseFailedEquatableDerivation(DeclContext *DC, NominalTypeDecl *nominal); /// Determine if a Hashable requirement can be derived for a type. /// /// This is implemented for enums without associated values or all-Hashable /// associated values, and for structs with all-Hashable stored properties. /// /// \returns True if the requirement can be derived. static bool canDeriveHashable(NominalTypeDecl *type); /// Derive a Hashable requirement for a type. /// /// This is implemented for enums without associated values or all-Hashable /// associated values, and for structs with all-Hashable stored properties. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveHashable(ValueDecl *requirement); /// Diagnose problems, if any, preventing automatic derivation of Hashable /// requirements /// /// \param nominal The nominal type for which we would like to diagnose /// derivation failures static void tryDiagnoseFailedHashableDerivation(DeclContext *DC, NominalTypeDecl *nominal); /// Derive a _BridgedNSError requirement for an @objc enum type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveBridgedNSError(ValueDecl *requirement); /// Derive a CodingKey requirement for an enum type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveCodingKey(ValueDecl *requirement); /// Derive an Encodable requirement for a struct type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveEncodable(ValueDecl *requirement); /// Derive a Decodable requirement for a struct type. /// /// \returns the derived member, which will also be added to the type. ValueDecl *deriveDecodable(ValueDecl *requirement); /// Declare a read-only property. std::pair declareDerivedProperty(Identifier name, Type propertyInterfaceType, Type propertyContextType, bool isStatic, bool isFinal); /// Add a getter to a derived property. The property becomes read-only. static AccessorDecl * addGetterToReadOnlyDerivedProperty(VarDecl *property, Type propertyContextType); /// Declare a getter for a derived property. /// The getter will not be added to the property yet. static AccessorDecl *declareDerivedPropertyGetter(VarDecl *property, Type propertyContextType); /// Build a reference to the 'self' decl of a derived function. static DeclRefExpr *createSelfDeclRef(AbstractFunctionDecl *fn); /// Returns true if this derivation is trying to use a context that isn't /// appropriate for deriving. /// /// \param synthesizing The decl that is being synthesized. bool checkAndDiagnoseDisallowedContext(ValueDecl *synthesizing) const; /// Returns a generated guard statement that checks whether the given lhs and /// rhs expressions are equal. If not equal, the else block for the guard /// returns `guardReturnValue`. /// \p C The AST context. /// \p lhsExpr The first expression to compare for equality. /// \p rhsExpr The second expression to compare for equality. /// \p guardReturnValue The expression to return if the two sides are not /// equal static GuardStmt *returnIfNotEqualGuard(ASTContext &C, Expr *lhsExpr, Expr *rhsExpr, Expr *guardReturnValue); // return false static GuardStmt *returnFalseIfNotEqualGuard(ASTContext &C, Expr *lhsExpr, Expr *rhsExpr); // return lhs < rhs static GuardStmt * returnComparisonIfNotEqualGuard(ASTContext &C, Expr *lhsExpr, Expr *rhsExpr); /// Returns the ParamDecl for each associated value of the given enum whose /// type does not conform to a protocol \p theEnum The enum whose elements and /// associated values should be checked. \p protocol The protocol being /// requested. \return The ParamDecl of each associated value whose type does /// not conform. static SmallVector associatedValuesNotConformingToProtocol(DeclContext *DC, EnumDecl *theEnum, ProtocolDecl *protocol); /// Returns true if, for every element of the given enum, it either has no /// associated values or all of them conform to a protocol. /// \p theEnum The enum whose elements and associated values should be /// checked. \p protocol The protocol being requested. \return True if all /// associated values of all elements of the enum conform. static bool allAssociatedValuesConformToProtocol(DeclContext *DC, EnumDecl *theEnum, ProtocolDecl *protocol); /// Create AST statements which convert from an enum to an Int with a switch. /// \p stmts The generated statements are appended to this vector. /// \p parentDC Either an extension or the enum itself. /// \p enumDecl The enum declaration. /// \p enumVarDecl The enum input variable. /// \p funcDecl The parent function. /// \p indexName The name of the output variable. /// \return A DeclRefExpr of the output variable (of type Int). static DeclRefExpr * convertEnumToIndex(SmallVectorImpl &stmts, DeclContext *parentDC, EnumDecl *enumDecl, VarDecl *enumVarDecl, AbstractFunctionDecl *funcDecl, const char *indexName); static Pattern * enumElementPayloadSubpattern(EnumElementDecl *enumElementDecl, char varPrefix, DeclContext *varContext, SmallVectorImpl &boundVars); static VarDecl *indexedVarDecl(char prefixChar, int index, Type type, DeclContext *varContext); }; } // namespace swift #endif