lib/IRGen/GenClass.h - third_party/swift - Git at Google

 //===--- GenClass.h - Swift IR generation for classes -----------*- 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 provides the private interface to the class-emission code.
 //
 //===----------------------------------------------------------------------===//

 #ifndef SWIFT_IRGEN_GENCLASS_H
 #define SWIFT_IRGEN_GENCLASS_H

 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/ArrayRef.h"

 namespace llvm {
   class Constant;
   class Value;
   class Function;
 }

 namespace swift {
   class CanType;
   class ClassDecl;
   class ExtensionDecl;
   class ProtocolDecl;
   class SILType;
   class Type;
   class VarDecl;

 namespace irgen {
   class ConstantStructBuilder;
   class HeapLayout;
   class IRGenFunction;
   class IRGenModule;
   class MemberAccessStrategy;
   class OwnedAddress;
   class Address;
   class Size;
   class StructLayout;
   class TypeInfo;

   enum class ReferenceCounting : unsigned char;
   enum class IsaEncoding : unsigned char;
   enum class ClassDeallocationKind : unsigned char;
   enum class FieldAccess : uint8_t;

   OwnedAddress projectPhysicalClassMemberAddress(IRGenFunction &IGF,
                                                  llvm::Value *base,
                                                  SILType baseType,
                                                  SILType fieldType,
                                                  VarDecl *field);

   /// Return a strategy for accessing the given stored class property.
   ///
   /// This API is used by RemoteAST.
   MemberAccessStrategy
   getPhysicalClassMemberAccessStrategy(IRGenModule &IGM,
                                        SILType baseType, VarDecl *field);


   enum ForMetaClass_t : bool {
     ForClass = false,
     ForMetaClass = true
   };

   std::pair<Size,Size>
   emitClassPrivateDataFields(IRGenModule &IGM,
                              ConstantStructBuilder &builder,
                              ClassDecl *cls);

   llvm::Constant *emitClassPrivateData(IRGenModule &IGM, ClassDecl *theClass);
   void emitGenericClassPrivateDataTemplate(IRGenModule &IGM,
                                       ClassDecl *theClass,
                                       llvm::SmallVectorImpl<llvm::Constant*> &fields,
                                       Size &metaclassOffset,
                                       Size &classRODataOffset,
                                       Size &metaclassRODataOffset,
                                       Size &totalSize);
   llvm::Constant *emitCategoryData(IRGenModule &IGM, ExtensionDecl *ext);
   llvm::Constant *emitObjCProtocolData(IRGenModule &IGM, ProtocolDecl *ext);

   /// Emit a projection from a class instance to the first tail allocated
   /// element.
   Address emitTailProjection(IRGenFunction &IGF, llvm::Value *Base,
                                   SILType ClassType, SILType TailType);

   typedef llvm::ArrayRef<std::pair<SILType, llvm::Value *>> TailArraysRef;

   /// Adds the size for tail allocated arrays to \p size and returns the new
   /// size value.
   llvm::Value *appendSizeForTailAllocatedArrays(IRGenFunction &IGF,
                                                 llvm::Value *size,
                                                 TailArraysRef TailArrays);

   /// Emit an allocation of a class.
   /// The \p StackAllocSize is an in- and out-parameter. The passed value
   /// specifies the maximum object size for stack allocation. A negative value
   /// means that no stack allocation is possible.
   /// The returned \p StackAllocSize value is the actual size if the object is
   /// allocated on the stack or -1, if the object is allocated on the heap.
   llvm::Value *emitClassAllocation(IRGenFunction &IGF, SILType selfType,
                   bool objc, int &StackAllocSize, TailArraysRef TailArrays);

   /// Emit an allocation of a class using a metadata value.
   llvm::Value *emitClassAllocationDynamic(IRGenFunction &IGF,
                                           llvm::Value *metadata,
                                           SILType selfType,
                                           bool objc, TailArraysRef TailArrays);

   /// Emit class deallocation.
   void emitClassDeallocation(IRGenFunction &IGF, SILType selfType,
                              llvm::Value *selfValue);

   /// Emit class deallocation.
   void emitPartialClassDeallocation(IRGenFunction &IGF,
                                     SILType selfType,
                                     llvm::Value *selfValue,
                                     llvm::Value *metadataValue);

   /// Emit the constant fragile instance size of the class, or null if the class
   /// does not have fixed layout. For resilient classes this does not
   /// correspond to the runtime alignment of instances of the class.
   llvm::Constant *tryEmitClassConstantFragileInstanceSize(IRGenModule &IGM,
                                                    ClassDecl *theClass);
   /// Emit the constant fragile instance alignment mask of the class, or null if
   /// the class does not have fixed layout. For resilient classes this does not
   /// correspond to the runtime alignment of instances of the class.
   llvm::Constant *tryEmitClassConstantFragileInstanceAlignMask(IRGenModule &IGM,
                                                         ClassDecl *theClass);
   /// Emit the constant fragile offset of the given property inside an instance
   /// of the class.
   llvm::Constant *
   tryEmitConstantClassFragilePhysicalMemberOffset(IRGenModule &IGM,
                                                   SILType baseType,
                                                   VarDecl *field);

   unsigned getClassFieldIndex(IRGenModule &IGM,
                               SILType baseType,
                               VarDecl *field);

   FieldAccess getClassFieldAccess(IRGenModule &IGM,
                                   SILType baseType,
                                   VarDecl *field);

   /// Creates a layout for the class \p classType with allocated tail elements
   /// \p tailTypes.
   ///
   /// The caller is responsible for deleting the returned StructLayout.
   StructLayout *getClassLayoutWithTailElems(IRGenModule &IGM, SILType classType,
                                             llvm::ArrayRef<SILType> tailTypes);

   /// What reference counting mechanism does a class-like type use?
   ReferenceCounting getReferenceCountingForType(IRGenModule &IGM,
                                                 CanType type);

   /// What isa-encoding mechanism does a type use?
   IsaEncoding getIsaEncodingForType(IRGenModule &IGM, CanType type);

   ClassDecl *getRootClassForMetaclass(IRGenModule &IGM, ClassDecl *theClass);

   /// Does the class metadata for the given class require dynamic
   /// initialization beyond what can be achieved automatically by
   /// the runtime?
   bool doesClassMetadataRequireDynamicInitialization(IRGenModule &IGM,
                                                      ClassDecl *theClass);

   /// Returns true if a conformance of the \p conformingType references the
   /// nominal type descriptor of the type.
   ///
   /// Otherwise the conformance references the foreign metadata of the
   /// \p conformingType.
   bool doesConformanceReferenceNominalTypeDescriptor(IRGenModule &IGM,
                                                      CanType conformingType);

   /// If the superclass came from another module, we may have dropped
   /// stored properties due to the Swift language version availability of
   /// their types. In these cases we can't precisely lay out the ivars in
   /// the class object at compile time so we need to do runtime layout.
   bool classHasIncompleteLayout(IRGenModule &IGM,
                                 ClassDecl *theClass);
 } // end namespace irgen
 } // end namespace swift

 #endif
	//===--- GenClass.h - Swift IR generation for classes ------------ 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 provides the private interface to the class-emission code.
	//
	//===----------------------------------------------------------------------===//

	#ifndef SWIFT_IRGEN_GENCLASS_H
	#define SWIFT_IRGEN_GENCLASS_H

	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/ArrayRef.h"

	namespace llvm {
	class Constant;
	class Value;
	class Function;
	}

	namespace swift {
	class CanType;
	class ClassDecl;
	class ExtensionDecl;
	class ProtocolDecl;
	class SILType;
	class Type;
	class VarDecl;

	namespace irgen {
	class ConstantStructBuilder;
	class HeapLayout;
	class IRGenFunction;
	class IRGenModule;
	class MemberAccessStrategy;
	class OwnedAddress;
	class Address;
	class Size;
	class StructLayout;
	class TypeInfo;

	enum class ReferenceCounting : unsigned char;
	enum class IsaEncoding : unsigned char;
	enum class ClassDeallocationKind : unsigned char;
	enum class FieldAccess : uint8_t;

	OwnedAddress projectPhysicalClassMemberAddress(IRGenFunction &IGF,
	llvm::Value *base,
	SILType baseType,
	SILType fieldType,
	VarDecl *field);

	/// Return a strategy for accessing the given stored class property.
	///
	/// This API is used by RemoteAST.
	MemberAccessStrategy
	getPhysicalClassMemberAccessStrategy(IRGenModule &IGM,
	SILType baseType, VarDecl *field);


	enum ForMetaClass_t : bool {
	ForClass = false,
	ForMetaClass = true
	};

	std::pair<Size,Size>
	emitClassPrivateDataFields(IRGenModule &IGM,
	ConstantStructBuilder &builder,
	ClassDecl *cls);

	llvm::Constant emitClassPrivateData(IRGenModule &IGM, ClassDecl theClass);
	void emitGenericClassPrivateDataTemplate(IRGenModule &IGM,
	ClassDecl *theClass,
	llvm::SmallVectorImpl<llvm::Constant*> &fields,
	Size &metaclassOffset,
	Size &classRODataOffset,
	Size &metaclassRODataOffset,
	Size &totalSize);
	llvm::Constant emitCategoryData(IRGenModule &IGM, ExtensionDecl ext);
	llvm::Constant emitObjCProtocolData(IRGenModule &IGM, ProtocolDecl ext);

	/// Emit a projection from a class instance to the first tail allocated
	/// element.
	Address emitTailProjection(IRGenFunction &IGF, llvm::Value *Base,
	SILType ClassType, SILType TailType);

	typedef llvm::ArrayRef<std::pair<SILType, llvm::Value *>> TailArraysRef;

	/// Adds the size for tail allocated arrays to \p size and returns the new
	/// size value.
	llvm::Value *appendSizeForTailAllocatedArrays(IRGenFunction &IGF,
	llvm::Value *size,
	TailArraysRef TailArrays);

	/// Emit an allocation of a class.
	/// The \p StackAllocSize is an in- and out-parameter. The passed value
	/// specifies the maximum object size for stack allocation. A negative value
	/// means that no stack allocation is possible.
	/// The returned \p StackAllocSize value is the actual size if the object is
	/// allocated on the stack or -1, if the object is allocated on the heap.
	llvm::Value *emitClassAllocation(IRGenFunction &IGF, SILType selfType,
	bool objc, int &StackAllocSize, TailArraysRef TailArrays);

	/// Emit an allocation of a class using a metadata value.
	llvm::Value *emitClassAllocationDynamic(IRGenFunction &IGF,
	llvm::Value *metadata,
	SILType selfType,
	bool objc, TailArraysRef TailArrays);

	/// Emit class deallocation.
	void emitClassDeallocation(IRGenFunction &IGF, SILType selfType,
	llvm::Value *selfValue);

	/// Emit class deallocation.
	void emitPartialClassDeallocation(IRGenFunction &IGF,
	SILType selfType,
	llvm::Value *selfValue,
	llvm::Value *metadataValue);

	/// Emit the constant fragile instance size of the class, or null if the class
	/// does not have fixed layout. For resilient classes this does not
	/// correspond to the runtime alignment of instances of the class.
	llvm::Constant *tryEmitClassConstantFragileInstanceSize(IRGenModule &IGM,
	ClassDecl *theClass);
	/// Emit the constant fragile instance alignment mask of the class, or null if
	/// the class does not have fixed layout. For resilient classes this does not
	/// correspond to the runtime alignment of instances of the class.
	llvm::Constant *tryEmitClassConstantFragileInstanceAlignMask(IRGenModule &IGM,
	ClassDecl *theClass);
	/// Emit the constant fragile offset of the given property inside an instance
	/// of the class.
	llvm::Constant *
	tryEmitConstantClassFragilePhysicalMemberOffset(IRGenModule &IGM,
	SILType baseType,
	VarDecl *field);

	unsigned getClassFieldIndex(IRGenModule &IGM,
	SILType baseType,
	VarDecl *field);

	FieldAccess getClassFieldAccess(IRGenModule &IGM,
	SILType baseType,
	VarDecl *field);

	/// Creates a layout for the class \p classType with allocated tail elements
	/// \p tailTypes.
	///
	/// The caller is responsible for deleting the returned StructLayout.
	StructLayout *getClassLayoutWithTailElems(IRGenModule &IGM, SILType classType,
	llvm::ArrayRef<SILType> tailTypes);

	/// What reference counting mechanism does a class-like type use?
	ReferenceCounting getReferenceCountingForType(IRGenModule &IGM,
	CanType type);

	/// What isa-encoding mechanism does a type use?
	IsaEncoding getIsaEncodingForType(IRGenModule &IGM, CanType type);

	ClassDecl getRootClassForMetaclass(IRGenModule &IGM, ClassDecl theClass);

	/// Does the class metadata for the given class require dynamic
	/// initialization beyond what can be achieved automatically by
	/// the runtime?
	bool doesClassMetadataRequireDynamicInitialization(IRGenModule &IGM,
	ClassDecl *theClass);

	/// Returns true if a conformance of the \p conformingType references the
	/// nominal type descriptor of the type.
	///
	/// Otherwise the conformance references the foreign metadata of the
	/// \p conformingType.
	bool doesConformanceReferenceNominalTypeDescriptor(IRGenModule &IGM,
	CanType conformingType);

	/// If the superclass came from another module, we may have dropped
	/// stored properties due to the Swift language version availability of
	/// their types. In these cases we can't precisely lay out the ivars in
	/// the class object at compile time so we need to do runtime layout.
	bool classHasIncompleteLayout(IRGenModule &IGM,
	ClassDecl *theClass);
	} // end namespace irgen
	} // end namespace swift

	#endif