include/swift/AST/SubstitutionMap.h - third_party/swift - Git at Google

 //===--- SubstitutionMap.h - Swift Substitution Map ASTs --------*- 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 SubstitutionMap class.
 //
 //===----------------------------------------------------------------------===//

 #ifndef SWIFT_AST_SUBSTITUTION_MAP_H
 #define SWIFT_AST_SUBSTITUTION_MAP_H

 #include "swift/AST/ProtocolConformanceRef.h"
 #include "swift/AST/Type.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/DenseMapInfo.h"
 #include "llvm/ADT/Optional.h"

 namespace llvm {
   class FoldingSetNodeID;
 }

 namespace swift {

 class GenericSignature;
 class GenericEnvironment;
 class SubstitutableType;
 typedef CanTypeWrapper<GenericTypeParamType> CanGenericTypeParamType;

 template<class Type> class CanTypeWrapper;
 typedef CanTypeWrapper<SubstitutableType> CanSubstitutableType;

 enum class CombineSubstitutionMaps {
   AtDepth,
   AtIndex
 };

 /// SubstitutionMap is a data structure type that describes the mapping of
 /// abstract types to replacement types, together with associated conformances
 /// to use for deriving nested types and conformances.
 ///
 /// Substitution maps are primarily used when performing substitutions into
 /// any entity that can reference type parameters, e.g., types (via
 /// Type::subst()) and conformances (via ProtocolConformanceRef::subst()).
 ///
 /// SubstitutionMaps are constructed by calling the getSubstitutionMap() method
 /// on a GenericSignature or (equivalently) by calling one of the static
 /// \c SubstitutionMap::get() methods. However, most substitution maps are
 /// computed using higher-level entry points such as
 /// TypeBase::getMemberSubstitutionMap().
 ///
 /// Substitution maps are ASTContext-allocated and are uniqued on construction,
 /// so they can be used as fields in AST nodes.
 class SubstitutionMap {
 public:
   /// Stored data for a substitution map, which uses tail allocation for the
   /// replacement types and conformances.
   class Storage;

 private:
   /// The storage needed to describe the set of substitutions.
   ///
   /// When null, this substitution map is empty, having neither a generic
   /// signature nor any replacement types/conformances.
   Storage *storage = nullptr;

 public:
   /// Retrieve the array of replacement types, which line up with the
   /// generic parameters.
   ///
   /// Note that the types may be null, for cases where the generic parameter
   /// is concrete but hasn't been queried yet.
   ///
   /// Prefer \c getReplacementTypes, this is public for printing purposes.
   ArrayRef<Type> getReplacementTypesBuffer() const;

 private:
   MutableArrayRef<Type> getReplacementTypesBuffer();

   /// Retrieve a mutable reference to the buffer of conformances.
   MutableArrayRef<ProtocolConformanceRef> getConformancesBuffer();

   /// Form a substitution map for the given generic signature with the
   /// specified replacement types and conformances.
   SubstitutionMap(GenericSignature *genericSig,
                   ArrayRef<Type> replacementTypes,
                   ArrayRef<ProtocolConformanceRef> conformances);

   explicit SubstitutionMap(Storage *storage) : storage(storage) { }

 public:
   /// Build an empty substitution map.
   SubstitutionMap() { }

   /// Build an interface type substitution map for the given generic
   /// signature and a vector of Substitutions that correspond to the
   /// requirements of this generic signature.
   static SubstitutionMap get(GenericSignature *genericSig,
                              ArrayRef<Type> replacementTypes,
                              ArrayRef<ProtocolConformanceRef> conformances) {
     return SubstitutionMap(genericSig, replacementTypes, conformances);
   }

   /// Build an interface type substitution map for the given generic
   /// signature using the mapping in the given substitutions.
   static SubstitutionMap get(GenericSignature *genericSig,
                              SubstitutionMap substitutions);

   /// Build an interface type substitution map for the given generic signature
   /// from a type substitution function and conformance lookup function.
   static SubstitutionMap get(GenericSignature *genericSig,
                              TypeSubstitutionFn subs,
                              LookupConformanceFn lookupConformance);

   /// Retrieve the generic signature describing the environment in which
   /// substitutions occur.
   GenericSignature *getGenericSignature() const;

   /// Retrieve the array of protocol conformances, which line up with the
   /// requirements of the generic signature.
   ArrayRef<ProtocolConformanceRef> getConformances() const;

   /// Look up a conformance for the given type to the given protocol.
   Optional<ProtocolConformanceRef>
   lookupConformance(CanType type, ProtocolDecl *proto) const;

   /// Whether the substitution map is empty.
   bool empty() const;

   /// Whether the substitution has any substitutable parameters, i.e.,
   /// it is non-empty and at least one of the type parameters can be
   /// substituted (i.e., is not mapped to a concrete type).
   bool hasAnySubstitutableParams() const;

   /// Whether the substitution map is non-empty.
   explicit operator bool() const { return !empty(); }

   /// Retrieve the array of replacement types, which line up with the
   /// generic parameters.
   ArrayRef<Type> getReplacementTypes() const;

   /// Query whether any replacement types in the map contain archetypes.
   bool hasArchetypes() const;

   /// Query whether any replacement types in the map contain an opened
   /// existential.
   bool hasOpenedExistential() const;

   /// Query whether any replacement types in the map contain dynamic Self.
   bool hasDynamicSelf() const;

   /// Whether the replacement types are all canonical.
   bool isCanonical() const;

   /// Return the canonical form of this substitution map.
   SubstitutionMap getCanonical() const;

   /// Apply a substitution to all replacement types in the map. Does not
   /// change keys.
   SubstitutionMap subst(SubstitutionMap subMap) const;

   /// Apply a substitution to all replacement types in the map. Does not
   /// change keys.
   SubstitutionMap subst(TypeSubstitutionFn subs,
                         LookupConformanceFn conformances) const;

   /// Create a substitution map for a protocol conformance.
   static SubstitutionMap
   getProtocolSubstitutions(ProtocolDecl *protocol,
                            Type selfType,
                            ProtocolConformanceRef conformance);

   /// Given that 'derivedDecl' is an override of 'baseDecl' in a subclass,
   /// and 'derivedSubs' is a set of substitutions written in terms of the
   /// generic signature of 'derivedDecl', produce a set of substitutions
   /// written in terms of the generic signature of 'baseDecl'.
   static SubstitutionMap
   getOverrideSubstitutions(const ValueDecl *baseDecl,
                            const ValueDecl *derivedDecl,
                            Optional<SubstitutionMap> derivedSubs);

   /// Variant of the above for when we have the generic signatures but not
   /// the decls for 'derived' and 'base'.
   static SubstitutionMap
   getOverrideSubstitutions(const ClassDecl *baseClass,
                            const ClassDecl *derivedClass,
                            GenericSignature *baseSig,
                            GenericSignature *derivedSig,
                            Optional<SubstitutionMap> derivedSubs);

   /// Combine two substitution maps as follows.
   ///
   /// The result is written in terms of the generic parameters of 'genericSig'.
   ///
   /// Generic parameters with a depth or index less than 'firstDepthOrIndex'
   /// come from 'firstSubMap'.
   ///
   /// Generic parameters with a depth greater than 'firstDepthOrIndex' come
   /// from 'secondSubMap', but are looked up starting with a depth or index of
   /// 'secondDepthOrIndex'.
   ///
   /// The 'how' parameter determines if we're looking at the depth or index.
   static SubstitutionMap
   combineSubstitutionMaps(SubstitutionMap firstSubMap,
                           SubstitutionMap secondSubMap,
                           CombineSubstitutionMaps how,
                           unsigned baseDepthOrIndex,
                           unsigned origDepthOrIndex,
                           GenericSignature *genericSig);

   /// Swap archetypes in the substitution map's replacement types with their
   /// interface types.
   SubstitutionMap mapReplacementTypesOutOfContext() const;

   /// Verify that this substitution map is valid.
   void verify() const;

   /// Whether to dump the full substitution map, or just a minimal useful subset
   /// (on a single line).
   enum class DumpStyle { Minimal, Full };
   /// Dump the contents of this substitution map for debugging purposes.
   void dump(llvm::raw_ostream &out, DumpStyle style = DumpStyle::Full,
             unsigned indent = 0) const;

   LLVM_ATTRIBUTE_DEPRECATED(void dump() const, "only for use in the debugger");

   /// Profile the substitution map, for use with LLVM's FoldingSet.
   void profile(llvm::FoldingSetNodeID &id) const;

   const void *getOpaqueValue() const { return storage; }

   static SubstitutionMap getFromOpaqueValue(const void *ptr) {
     return SubstitutionMap(const_cast<Storage *>((const Storage *)ptr));
   }

   static SubstitutionMap getEmptyKey() {
     return SubstitutionMap(
              (Storage *)llvm::DenseMapInfo<void*>::getEmptyKey());
   }

   static SubstitutionMap getTombstoneKey() {
     return SubstitutionMap(
                (Storage *)llvm::DenseMapInfo<void*>::getTombstoneKey());
   }

   friend bool operator ==(SubstitutionMap lhs, SubstitutionMap rhs) {
     return lhs.storage == rhs.storage;
   }

   friend bool operator !=(SubstitutionMap lhs, SubstitutionMap rhs) {
     return lhs.storage != rhs.storage;
   }

 private:
   friend class GenericSignature;
   friend class GenericEnvironment;
   friend struct QuerySubstitutionMap;

   /// Look up the replacement for the given type parameter or interface type.
   /// Note that this only finds replacements for maps that are directly
   /// stored inside the map. In most cases, you should call Type::subst()
   /// instead, since that will resolve member types also.
   Type lookupSubstitution(CanSubstitutableType type) const;
 };

 /// A function object suitable for use as a \c TypeSubstitutionFn that
 /// queries an underlying \c SubstitutionMap.
 struct QuerySubstitutionMap {
   SubstitutionMap subMap;

   Type operator()(SubstitutableType *type) const;
 };

 /// Functor class suitable for use as a \c LookupConformanceFn to look up a
 /// conformance in a \c SubstitutionMap.
 class LookUpConformanceInSubstitutionMap {
   SubstitutionMap Subs;
 public:
   explicit LookUpConformanceInSubstitutionMap(SubstitutionMap Subs)
     : Subs(Subs) {}

   Optional<ProtocolConformanceRef>
   operator()(CanType dependentType,
              Type conformingReplacementType,
              ProtocolDecl *conformedProtocol) const;
 };

 } // end namespace swift

 namespace llvm {
   template <>
   struct PointerLikeTypeTraits<swift::SubstitutionMap> {
     static void *getAsVoidPointer(swift::SubstitutionMap map) {
       return const_cast<void *>(map.getOpaqueValue());
     }
     static swift::SubstitutionMap getFromVoidPointer(const void *ptr) {
       return swift::SubstitutionMap::getFromOpaqueValue(ptr);
     }

     /// Note: Assuming storage is at leaste 4-byte aligned.
     enum { NumLowBitsAvailable = 2 };
   };

   // Substitution maps hash just like pointers.
   template<> struct DenseMapInfo<swift::SubstitutionMap> {
     static swift::SubstitutionMap getEmptyKey() {
       return swift::SubstitutionMap::getEmptyKey();
     }
     static swift::SubstitutionMap getTombstoneKey() {
       return swift::SubstitutionMap::getTombstoneKey();
     }
     static unsigned getHashValue(swift::SubstitutionMap map) {
       return DenseMapInfo<void*>::getHashValue(map.getOpaqueValue());
     }
     static bool isEqual(swift::SubstitutionMap lhs,
                         swift::SubstitutionMap rhs) {
       return lhs.getOpaqueValue() == rhs.getOpaqueValue();
     }
   };

 }

 #endif
	//===--- SubstitutionMap.h - Swift Substitution Map ASTs --------- 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 SubstitutionMap class.
	//
	//===----------------------------------------------------------------------===//

	#ifndef SWIFT_AST_SUBSTITUTION_MAP_H
	#define SWIFT_AST_SUBSTITUTION_MAP_H

	#include "swift/AST/ProtocolConformanceRef.h"
	#include "swift/AST/Type.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/DenseMapInfo.h"
	#include "llvm/ADT/Optional.h"

	namespace llvm {
	class FoldingSetNodeID;
	}

	namespace swift {

	class GenericSignature;
	class GenericEnvironment;
	class SubstitutableType;
	typedef CanTypeWrapper<GenericTypeParamType> CanGenericTypeParamType;

	template<class Type> class CanTypeWrapper;
	typedef CanTypeWrapper<SubstitutableType> CanSubstitutableType;

	enum class CombineSubstitutionMaps {
	AtDepth,
	AtIndex
	};

	/// SubstitutionMap is a data structure type that describes the mapping of
	/// abstract types to replacement types, together with associated conformances
	/// to use for deriving nested types and conformances.
	///
	/// Substitution maps are primarily used when performing substitutions into
	/// any entity that can reference type parameters, e.g., types (via
	/// Type::subst()) and conformances (via ProtocolConformanceRef::subst()).
	///
	/// SubstitutionMaps are constructed by calling the getSubstitutionMap() method
	/// on a GenericSignature or (equivalently) by calling one of the static
	/// \c SubstitutionMap::get() methods. However, most substitution maps are
	/// computed using higher-level entry points such as
	/// TypeBase::getMemberSubstitutionMap().
	///
	/// Substitution maps are ASTContext-allocated and are uniqued on construction,
	/// so they can be used as fields in AST nodes.
	class SubstitutionMap {
	public:
	/// Stored data for a substitution map, which uses tail allocation for the
	/// replacement types and conformances.
	class Storage;

	private:
	/// The storage needed to describe the set of substitutions.
	///
	/// When null, this substitution map is empty, having neither a generic
	/// signature nor any replacement types/conformances.
	Storage *storage = nullptr;

	public:
	/// Retrieve the array of replacement types, which line up with the
	/// generic parameters.
	///
	/// Note that the types may be null, for cases where the generic parameter
	/// is concrete but hasn't been queried yet.
	///
	/// Prefer \c getReplacementTypes, this is public for printing purposes.
	ArrayRef<Type> getReplacementTypesBuffer() const;

	private:
	MutableArrayRef<Type> getReplacementTypesBuffer();

	/// Retrieve a mutable reference to the buffer of conformances.
	MutableArrayRef<ProtocolConformanceRef> getConformancesBuffer();

	/// Form a substitution map for the given generic signature with the
	/// specified replacement types and conformances.
	SubstitutionMap(GenericSignature *genericSig,
	ArrayRef<Type> replacementTypes,
	ArrayRef<ProtocolConformanceRef> conformances);

	explicit SubstitutionMap(Storage *storage) : storage(storage) { }

	public:
	/// Build an empty substitution map.
	SubstitutionMap() { }

	/// Build an interface type substitution map for the given generic
	/// signature and a vector of Substitutions that correspond to the
	/// requirements of this generic signature.
	static SubstitutionMap get(GenericSignature *genericSig,
	ArrayRef<Type> replacementTypes,
	ArrayRef<ProtocolConformanceRef> conformances) {
	return SubstitutionMap(genericSig, replacementTypes, conformances);
	}

	/// Build an interface type substitution map for the given generic
	/// signature using the mapping in the given substitutions.
	static SubstitutionMap get(GenericSignature *genericSig,
	SubstitutionMap substitutions);

	/// Build an interface type substitution map for the given generic signature
	/// from a type substitution function and conformance lookup function.
	static SubstitutionMap get(GenericSignature *genericSig,
	TypeSubstitutionFn subs,
	LookupConformanceFn lookupConformance);

	/// Retrieve the generic signature describing the environment in which
	/// substitutions occur.
	GenericSignature *getGenericSignature() const;

	/// Retrieve the array of protocol conformances, which line up with the
	/// requirements of the generic signature.
	ArrayRef<ProtocolConformanceRef> getConformances() const;

	/// Look up a conformance for the given type to the given protocol.
	Optional<ProtocolConformanceRef>
	lookupConformance(CanType type, ProtocolDecl *proto) const;

	/// Whether the substitution map is empty.
	bool empty() const;

	/// Whether the substitution has any substitutable parameters, i.e.,
	/// it is non-empty and at least one of the type parameters can be
	/// substituted (i.e., is not mapped to a concrete type).
	bool hasAnySubstitutableParams() const;

	/// Whether the substitution map is non-empty.
	explicit operator bool() const { return !empty(); }

	/// Retrieve the array of replacement types, which line up with the
	/// generic parameters.
	ArrayRef<Type> getReplacementTypes() const;

	/// Query whether any replacement types in the map contain archetypes.
	bool hasArchetypes() const;

	/// Query whether any replacement types in the map contain an opened
	/// existential.
	bool hasOpenedExistential() const;

	/// Query whether any replacement types in the map contain dynamic Self.
	bool hasDynamicSelf() const;

	/// Whether the replacement types are all canonical.
	bool isCanonical() const;

	/// Return the canonical form of this substitution map.
	SubstitutionMap getCanonical() const;

	/// Apply a substitution to all replacement types in the map. Does not
	/// change keys.
	SubstitutionMap subst(SubstitutionMap subMap) const;

	/// Apply a substitution to all replacement types in the map. Does not
	/// change keys.
	SubstitutionMap subst(TypeSubstitutionFn subs,
	LookupConformanceFn conformances) const;

	/// Create a substitution map for a protocol conformance.
	static SubstitutionMap
	getProtocolSubstitutions(ProtocolDecl *protocol,
	Type selfType,
	ProtocolConformanceRef conformance);

	/// Given that 'derivedDecl' is an override of 'baseDecl' in a subclass,
	/// and 'derivedSubs' is a set of substitutions written in terms of the
	/// generic signature of 'derivedDecl', produce a set of substitutions
	/// written in terms of the generic signature of 'baseDecl'.
	static SubstitutionMap
	getOverrideSubstitutions(const ValueDecl *baseDecl,
	const ValueDecl *derivedDecl,
	Optional<SubstitutionMap> derivedSubs);

	/// Variant of the above for when we have the generic signatures but not
	/// the decls for 'derived' and 'base'.
	static SubstitutionMap
	getOverrideSubstitutions(const ClassDecl *baseClass,
	const ClassDecl *derivedClass,
	GenericSignature *baseSig,
	GenericSignature *derivedSig,
	Optional<SubstitutionMap> derivedSubs);

	/// Combine two substitution maps as follows.
	///
	/// The result is written in terms of the generic parameters of 'genericSig'.
	///
	/// Generic parameters with a depth or index less than 'firstDepthOrIndex'
	/// come from 'firstSubMap'.
	///
	/// Generic parameters with a depth greater than 'firstDepthOrIndex' come
	/// from 'secondSubMap', but are looked up starting with a depth or index of
	/// 'secondDepthOrIndex'.
	///
	/// The 'how' parameter determines if we're looking at the depth or index.
	static SubstitutionMap
	combineSubstitutionMaps(SubstitutionMap firstSubMap,
	SubstitutionMap secondSubMap,
	CombineSubstitutionMaps how,
	unsigned baseDepthOrIndex,
	unsigned origDepthOrIndex,
	GenericSignature *genericSig);

	/// Swap archetypes in the substitution map's replacement types with their
	/// interface types.
	SubstitutionMap mapReplacementTypesOutOfContext() const;

	/// Verify that this substitution map is valid.
	void verify() const;

	/// Whether to dump the full substitution map, or just a minimal useful subset
	/// (on a single line).
	enum class DumpStyle { Minimal, Full };
	/// Dump the contents of this substitution map for debugging purposes.
	void dump(llvm::raw_ostream &out, DumpStyle style = DumpStyle::Full,
	unsigned indent = 0) const;

	LLVM_ATTRIBUTE_DEPRECATED(void dump() const, "only for use in the debugger");

	/// Profile the substitution map, for use with LLVM's FoldingSet.
	void profile(llvm::FoldingSetNodeID &id) const;

	const void *getOpaqueValue() const { return storage; }

	static SubstitutionMap getFromOpaqueValue(const void *ptr) {
	return SubstitutionMap(const_cast<Storage >((const Storage )ptr));
	}

	static SubstitutionMap getEmptyKey() {
	return SubstitutionMap(
	(Storage )llvm::DenseMapInfo<void>::getEmptyKey());
	}

	static SubstitutionMap getTombstoneKey() {
	return SubstitutionMap(
	(Storage )llvm::DenseMapInfo<void>::getTombstoneKey());
	}

	friend bool operator ==(SubstitutionMap lhs, SubstitutionMap rhs) {
	return lhs.storage == rhs.storage;
	}

	friend bool operator !=(SubstitutionMap lhs, SubstitutionMap rhs) {
	return lhs.storage != rhs.storage;
	}

	private:
	friend class GenericSignature;
	friend class GenericEnvironment;
	friend struct QuerySubstitutionMap;

	/// Look up the replacement for the given type parameter or interface type.
	/// Note that this only finds replacements for maps that are directly
	/// stored inside the map. In most cases, you should call Type::subst()
	/// instead, since that will resolve member types also.
	Type lookupSubstitution(CanSubstitutableType type) const;
	};

	/// A function object suitable for use as a \c TypeSubstitutionFn that
	/// queries an underlying \c SubstitutionMap.
	struct QuerySubstitutionMap {
	SubstitutionMap subMap;

	Type operator()(SubstitutableType *type) const;
	};

	/// Functor class suitable for use as a \c LookupConformanceFn to look up a
	/// conformance in a \c SubstitutionMap.
	class LookUpConformanceInSubstitutionMap {
	SubstitutionMap Subs;
	public:
	explicit LookUpConformanceInSubstitutionMap(SubstitutionMap Subs)
	: Subs(Subs) {}

	Optional<ProtocolConformanceRef>
	operator()(CanType dependentType,
	Type conformingReplacementType,
	ProtocolDecl *conformedProtocol) const;
	};

	} // end namespace swift

	namespace llvm {
	template <>
	struct PointerLikeTypeTraits<swift::SubstitutionMap> {
	static void *getAsVoidPointer(swift::SubstitutionMap map) {
	return const_cast<void *>(map.getOpaqueValue());
	}
	static swift::SubstitutionMap getFromVoidPointer(const void *ptr) {
	return swift::SubstitutionMap::getFromOpaqueValue(ptr);
	}

	/// Note: Assuming storage is at leaste 4-byte aligned.
	enum { NumLowBitsAvailable = 2 };
	};

	// Substitution maps hash just like pointers.
	template<> struct DenseMapInfo<swift::SubstitutionMap> {
	static swift::SubstitutionMap getEmptyKey() {
	return swift::SubstitutionMap::getEmptyKey();
	}
	static swift::SubstitutionMap getTombstoneKey() {
	return swift::SubstitutionMap::getTombstoneKey();
	}
	static unsigned getHashValue(swift::SubstitutionMap map) {
	return DenseMapInfo<void*>::getHashValue(map.getOpaqueValue());
	}
	static bool isEqual(swift::SubstitutionMap lhs,
	swift::SubstitutionMap rhs) {
	return lhs.getOpaqueValue() == rhs.getOpaqueValue();
	}
	};

	}

	#endif