include/swift/SIL/SILVTable.h - third_party/swift - Git at Google

 //===--- SILVTable.h - Defines the SILVTable class --------------*- 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 SILVTable class, which is used to map dynamically
 // dispatchable class methods and properties to their concrete implementations
 // for a dynamic type. This information is used by IRGen to emit class vtables,
 // by the devirtualization pass to promote class_method instructions to static
 // function_refs.
 //
 // Note that vtable layout itself is implemented in SILVTableLayout.h and is
 // independent of the SILVTable; in general, for a class from another module we
 // might not have a SILVTable to deserialize, and for a class in a different
 // translation in the same module the SILVTable is not available either.
 //
 //===----------------------------------------------------------------------===//

 #ifndef SWIFT_SIL_SILVTABLE_H
 #define SWIFT_SIL_SILVTABLE_H

 #include "swift/SIL/SILAllocated.h"
 #include "swift/SIL/SILDeclRef.h"
 #include "swift/SIL/SILFunction.h"
 #include "llvm/ADT/Optional.h"
 #include <algorithm>

 namespace swift {

 class ClassDecl;
 enum IsSerialized_t : unsigned char;
 class SILFunction;
 class SILModule;

 // TODO: Entry should include substitutions needed to invoke an overridden
 // generic base class method.
 class SILVTableEntry {
   /// The declaration reference to the least-derived method visible through
   /// the class.
   SILDeclRef Method;

   /// The function which implements the method for the class and the entry kind.
   llvm::PointerIntPair<SILFunction *, 2, unsigned> ImplAndKind;

   bool IsNonOverridden;

 public:
   enum Kind : uint8_t {
     /// The vtable entry is for a method defined directly in this class.
     Normal,
     /// The vtable entry is inherited from the superclass.
     Inherited,
     /// The vtable entry is inherited from the superclass, and overridden
     /// in this class.
     Override,

     // Please update the PointerIntPair above if you add/remove enums.
   };

   SILVTableEntry() : ImplAndKind(nullptr, Kind::Normal),
                      IsNonOverridden(false) {}

   SILVTableEntry(SILDeclRef Method, SILFunction *Implementation, Kind TheKind,
                  bool NonOverridden)
       : Method(Method), ImplAndKind(Implementation, TheKind),
         IsNonOverridden(NonOverridden) {}

   SILDeclRef getMethod() const { return Method; }

   Kind getKind() const { return Kind(ImplAndKind.getInt()); }
   void setKind(Kind kind) { ImplAndKind.setInt(kind); }

   bool isNonOverridden() const { return IsNonOverridden; }
   void setNonOverridden(bool value) { IsNonOverridden = value; }

   SILFunction *getImplementation() const { return ImplAndKind.getPointer(); }

   void print(llvm::raw_ostream &os) const;

   bool operator==(const SILVTableEntry &e) const {
     return Method == e.Method
       && getImplementation() == e.getImplementation()
       && getKind() == e.getKind()
       && isNonOverridden() == e.isNonOverridden();
   }

   bool operator!=(const SILVTableEntry &e) const {
     return !(*this == e);
   }
 };

 /// A mapping from each dynamically-dispatchable method of a class to the
 /// SILFunction that implements the method for that class.
 /// Note that dead methods are completely removed from the vtable.
 class SILVTable final : public SILAllocated<SILVTable>,
                         llvm::TrailingObjects<SILVTable, SILVTableEntry> {
   friend TrailingObjects;

 public:
   using Entry = SILVTableEntry;

   // Disallow copying into temporary objects.
   SILVTable(const SILVTable &other) = delete;
   SILVTable &operator=(const SILVTable &) = delete;

 private:
   /// The ClassDecl mapped to this VTable.
   ClassDecl *Class;

   /// Whether or not this vtable is serialized, which allows
   /// devirtualization from another module.
   bool Serialized : 1;

   /// The number of SILVTables entries.
   unsigned NumEntries : 31;

   /// Private constructor. Create SILVTables by calling SILVTable::create.
   SILVTable(ClassDecl *c, IsSerialized_t serialized, ArrayRef<Entry> entries);

 public:
   ~SILVTable();

   /// Create a new SILVTable with the given method-to-implementation mapping.
   /// The SILDeclRef keys should reference the most-overridden members available
   /// through the class.
   static SILVTable *create(SILModule &M, ClassDecl *Class,
                            IsSerialized_t Serialized,
                            ArrayRef<Entry> Entries);

   /// Return the class that the vtable represents.
   ClassDecl *getClass() const { return Class; }

   /// Returns true if this vtable is going to be (or was) serialized.
   IsSerialized_t isSerialized() const {
     return Serialized ? IsSerialized : IsNotSerialized;
   }

   /// Sets the serialized flag.
   void setSerialized(IsSerialized_t serialized) {
     assert(serialized != IsSerializable);
     Serialized = (serialized ? 1 : 0);
   }

   /// Return all of the method entries.
   ArrayRef<Entry> getEntries() const {
     return {getTrailingObjects<SILVTableEntry>(), NumEntries};
   }

   /// Return all of the method entries mutably.
   /// If you do modify entries, make sure to invoke `updateVTableCache` to update the
   /// SILModule's cache entry.
   MutableArrayRef<Entry> getMutableEntries() {
     return {getTrailingObjects<SILVTableEntry>(), NumEntries};
   }

   void updateVTableCache(const Entry &entry);

   /// Look up the implementation function for the given method.
   Optional<Entry> getEntry(SILModule &M, SILDeclRef method) const;

   /// Removes entries from the vtable.
   /// \p predicate Returns true if the passed entry should be removed.
   template <typename Predicate> void removeEntries_if(Predicate predicate) {
     auto Entries = getMutableEntries();
     Entry *end = std::remove_if(
         Entries.begin(), Entries.end(), [&](Entry &entry) -> bool {
           if (predicate(entry)) {
             entry.getImplementation()->decrementRefCount();
             removeFromVTableCache(entry);
             return true;
           }
           return false;
         });
     NumEntries = std::distance(Entries.begin(), end);
   }

   /// Verify that the vtable is well-formed for the given class.
   void verify(const SILModule &M) const;

   /// Print the vtable.
   void print(llvm::raw_ostream &OS, bool Verbose = false) const;
   void dump() const;

 private:
   void removeFromVTableCache(Entry &entry);
 };

 } // end swift namespace

 //===----------------------------------------------------------------------===//
 // ilist_traits for SILVTable
 //===----------------------------------------------------------------------===//

 namespace llvm {

 template <>
 struct ilist_traits<::swift::SILVTable> :
 public ilist_node_traits<::swift::SILVTable> {
   using SILVTable = ::swift::SILVTable;

   static void deleteNode(SILVTable *VT) { VT->~SILVTable(); }

 private:
   void createNode(const SILVTable &);
 };

 } // end llvm namespace

 #endif
	//===--- SILVTable.h - Defines the SILVTable class --------------- 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 SILVTable class, which is used to map dynamically
	// dispatchable class methods and properties to their concrete implementations
	// for a dynamic type. This information is used by IRGen to emit class vtables,
	// by the devirtualization pass to promote class_method instructions to static
	// function_refs.
	//
	// Note that vtable layout itself is implemented in SILVTableLayout.h and is
	// independent of the SILVTable; in general, for a class from another module we
	// might not have a SILVTable to deserialize, and for a class in a different
	// translation in the same module the SILVTable is not available either.
	//
	//===----------------------------------------------------------------------===//

	#ifndef SWIFT_SIL_SILVTABLE_H
	#define SWIFT_SIL_SILVTABLE_H

	#include "swift/SIL/SILAllocated.h"
	#include "swift/SIL/SILDeclRef.h"
	#include "swift/SIL/SILFunction.h"
	#include "llvm/ADT/Optional.h"
	#include <algorithm>

	namespace swift {

	class ClassDecl;
	enum IsSerialized_t : unsigned char;
	class SILFunction;
	class SILModule;

	// TODO: Entry should include substitutions needed to invoke an overridden
	// generic base class method.
	class SILVTableEntry {
	/// The declaration reference to the least-derived method visible through
	/// the class.
	SILDeclRef Method;

	/// The function which implements the method for the class and the entry kind.
	llvm::PointerIntPair<SILFunction *, 2, unsigned> ImplAndKind;

	bool IsNonOverridden;

	public:
	enum Kind : uint8_t {
	/// The vtable entry is for a method defined directly in this class.
	Normal,
	/// The vtable entry is inherited from the superclass.
	Inherited,
	/// The vtable entry is inherited from the superclass, and overridden
	/// in this class.
	Override,

	// Please update the PointerIntPair above if you add/remove enums.
	};

	SILVTableEntry() : ImplAndKind(nullptr, Kind::Normal),
	IsNonOverridden(false) {}

	SILVTableEntry(SILDeclRef Method, SILFunction *Implementation, Kind TheKind,
	bool NonOverridden)
	: Method(Method), ImplAndKind(Implementation, TheKind),
	IsNonOverridden(NonOverridden) {}

	SILDeclRef getMethod() const { return Method; }

	Kind getKind() const { return Kind(ImplAndKind.getInt()); }
	void setKind(Kind kind) { ImplAndKind.setInt(kind); }

	bool isNonOverridden() const { return IsNonOverridden; }
	void setNonOverridden(bool value) { IsNonOverridden = value; }

	SILFunction *getImplementation() const { return ImplAndKind.getPointer(); }

	void print(llvm::raw_ostream &os) const;

	bool operator==(const SILVTableEntry &e) const {
	return Method == e.Method
	&& getImplementation() == e.getImplementation()
	&& getKind() == e.getKind()
	&& isNonOverridden() == e.isNonOverridden();
	}

	bool operator!=(const SILVTableEntry &e) const {
	return !(*this == e);
	}
	};

	/// A mapping from each dynamically-dispatchable method of a class to the
	/// SILFunction that implements the method for that class.
	/// Note that dead methods are completely removed from the vtable.
	class SILVTable final : public SILAllocated<SILVTable>,
	llvm::TrailingObjects<SILVTable, SILVTableEntry> {
	friend TrailingObjects;

	public:
	using Entry = SILVTableEntry;

	// Disallow copying into temporary objects.
	SILVTable(const SILVTable &other) = delete;
	SILVTable &operator=(const SILVTable &) = delete;

	private:
	/// The ClassDecl mapped to this VTable.
	ClassDecl *Class;

	/// Whether or not this vtable is serialized, which allows
	/// devirtualization from another module.
	bool Serialized : 1;

	/// The number of SILVTables entries.
	unsigned NumEntries : 31;

	/// Private constructor. Create SILVTables by calling SILVTable::create.
	SILVTable(ClassDecl *c, IsSerialized_t serialized, ArrayRef<Entry> entries);

	public:
	~SILVTable();

	/// Create a new SILVTable with the given method-to-implementation mapping.
	/// The SILDeclRef keys should reference the most-overridden members available
	/// through the class.
	static SILVTable create(SILModule &M, ClassDecl Class,
	IsSerialized_t Serialized,
	ArrayRef<Entry> Entries);

	/// Return the class that the vtable represents.
	ClassDecl *getClass() const { return Class; }

	/// Returns true if this vtable is going to be (or was) serialized.
	IsSerialized_t isSerialized() const {
	return Serialized ? IsSerialized : IsNotSerialized;
	}

	/// Sets the serialized flag.
	void setSerialized(IsSerialized_t serialized) {
	assert(serialized != IsSerializable);
	Serialized = (serialized ? 1 : 0);
	}

	/// Return all of the method entries.
	ArrayRef<Entry> getEntries() const {
	return {getTrailingObjects<SILVTableEntry>(), NumEntries};
	}

	/// Return all of the method entries mutably.
	/// If you do modify entries, make sure to invoke `updateVTableCache` to update the
	/// SILModule's cache entry.
	MutableArrayRef<Entry> getMutableEntries() {
	return {getTrailingObjects<SILVTableEntry>(), NumEntries};
	}

	void updateVTableCache(const Entry &entry);

	/// Look up the implementation function for the given method.
	Optional<Entry> getEntry(SILModule &M, SILDeclRef method) const;

	/// Removes entries from the vtable.
	/// \p predicate Returns true if the passed entry should be removed.
	template <typename Predicate> void removeEntries_if(Predicate predicate) {
	auto Entries = getMutableEntries();
	Entry *end = std::remove_if(
	Entries.begin(), Entries.end(), [&](Entry &entry) -> bool {
	if (predicate(entry)) {
	entry.getImplementation()->decrementRefCount();
	removeFromVTableCache(entry);
	return true;
	}
	return false;
	});
	NumEntries = std::distance(Entries.begin(), end);
	}

	/// Verify that the vtable is well-formed for the given class.
	void verify(const SILModule &M) const;

	/// Print the vtable.
	void print(llvm::raw_ostream &OS, bool Verbose = false) const;
	void dump() const;

	private:
	void removeFromVTableCache(Entry &entry);
	};

	} // end swift namespace

	//===----------------------------------------------------------------------===//
	// ilist_traits for SILVTable
	//===----------------------------------------------------------------------===//

	namespace llvm {

	template <>
	struct ilist_traits<::swift::SILVTable> :
	public ilist_node_traits<::swift::SILVTable> {
	using SILVTable = ::swift::SILVTable;

	static void deleteNode(SILVTable *VT) { VT->~SILVTable(); }

	private:
	void createNode(const SILVTable &);
	};

	} // end llvm namespace

	#endif