src/hotspot/share/memory/metaspaceClosure.hpp - platform/libcore - Git at Google

 /*
  * Copyright (c) 2017, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #ifndef SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP
 #define SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP

 #include "logging/log.hpp"
 #include "memory/allocation.hpp"
 #include "oops/array.hpp"
 #include "utilities/globalDefinitions.hpp"
 #include "utilities/growableArray.hpp"
 #include "utilities/resourceHash.hpp"

 // The metadata hierarchy is separate from the oop hierarchy
   class MetaspaceObj;        // no C++ vtable
 //class   Array;             // no C++ vtable
   class   Annotations;       // no C++ vtable
   class   ConstantPoolCache; // no C++ vtable
   class   ConstMethod;       // no C++ vtable
   class   MethodCounters;    // no C++ vtable
   class   Symbol;            // no C++ vtable
   class   Metadata;          // has C++ vtable (so do all subclasses)
   class     ConstantPool;
   class     MethodData;
   class     Method;
   class     Klass;
   class       InstanceKlass;
   class         InstanceMirrorKlass;
   class         InstanceClassLoaderKlass;
   class         InstanceRefKlass;
   class       ArrayKlass;
   class         ObjArrayKlass;
   class         TypeArrayKlass;

 // class MetaspaceClosure --
 //
 // This class is used for iterating the objects in the HotSpot Metaspaces. It
 // provides an API to walk all the reachable objects starting from a set of
 // root references (such as all Klass'es in the SystemDictionary).
 //
 // Currently it is used for compacting the CDS archive by eliminate temporary
 // objects allocated during archive creation time. See ArchiveCompactor in
 // metaspaceShared.cpp for an example.
 //
 // To support MetaspaceClosure, each subclass of MetaspaceObj must provide
 // a method of the type void metaspace_pointers_do(MetaspaceClosure*). This method
 // should call MetaspaceClosure::push() on every pointer fields of this
 // class that points to a MetaspaceObj. See Annotations::metaspace_pointers_do()
 // for an example.
 class MetaspaceClosure {
 public:
   enum Writability {
     _writable,
     _not_writable,
     _default
   };

   // class MetaspaceClosure::Ref --
   //
   // MetaspaceClosure can be viewed as a very simple type of copying garbage
   // collector. For it to function properly, it requires each subclass of
   // MetaspaceObj to provide two methods:
   //
   //  size_t size();                                 -- to determine how much data to copy
   //  void metaspace_pointers_do(MetaspaceClosure*); -- to locate all the embedded pointers
   //
   // Calling these methods would be trivial if these two were virtual methods.
   // However, to save space, MetaspaceObj has NO vtable. The vtable is introduced
   // only in the Metadata class.
   //
   // To work around the lack of a vtable, we use Ref class with templates
   // (see ObjectRef, PrimitiveArrayRef and PointerArrayRef)
   // so that we can statically discover the type of a object. The use of Ref
   // depends on the fact that:
   //
   // [1] We don't use polymorphic pointers for MetaspaceObj's that are not subclasses
   //     of Metadata. I.e., we don't do this:
   //     class Klass {
   //         MetaspaceObj *_obj;
   //         Array<int>* foo() { return (Array<int>*)_obj; }
   //         Symbol*     bar() { return (Symbol*)    _obj; }
   //
   // [2] All Array<T> dimensions are statically declared.
   class Ref {
   protected:
     virtual void** mpp() const = 0;
   public:
     virtual bool not_null() const = 0;
     virtual int size() const = 0;
     virtual void metaspace_pointers_do(MetaspaceClosure *it) const = 0;
     virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const = 0;
     virtual MetaspaceObj::Type msotype() const = 0;
     virtual bool is_read_only_by_default() const = 0;

     address obj() const {
       // In some rare cases (see CPSlot in constantPool.hpp) we store some flags in the lowest
       // 2 bits of a MetaspaceObj pointer. Unmask these when manipulating the pointer.
       uintx p = (uintx)*mpp();
       return (address)(p & (~FLAG_MASK));
     }

     void update(address new_loc) const;

   private:
     static const uintx FLAG_MASK = 0x03;

     int flag_bits() const {
       uintx p = (uintx)*mpp();
       return (int)(p & FLAG_MASK);
     }
   };

 private:
   // -------------------------------------------------- ObjectRef
   template <class T> class ObjectRef : public Ref {
     T** _mpp;
     T* dereference() const {
       return *_mpp;
     }
   protected:
     virtual void** mpp() const {
       return (void**)_mpp;
     }

   public:
     ObjectRef(T** mpp) : _mpp(mpp) {}

     virtual bool is_read_only_by_default() const { return T::is_read_only_by_default(); }
     virtual bool not_null()                const { return dereference() != NULL; }
     virtual int size()                     const { return dereference()->size(); }
     virtual MetaspaceObj::Type msotype()   const { return dereference()->type(); }

     virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
       dereference()->metaspace_pointers_do(it);
     }
     virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
       ((T*)new_loc)->metaspace_pointers_do(it);
     }
   };

   // -------------------------------------------------- PrimitiveArrayRef
   template <class T> class PrimitiveArrayRef : public Ref {
     Array<T>** _mpp;
     Array<T>* dereference() const {
       return *_mpp;
     }
   protected:
     virtual void** mpp() const {
       return (void**)_mpp;
     }

   public:
     PrimitiveArrayRef(Array<T>** mpp) : _mpp(mpp) {}

     // all Arrays are read-only by default
     virtual bool is_read_only_by_default() const { return true; }
     virtual bool not_null()                const { return dereference() != NULL;  }
     virtual int size()                     const { return dereference()->size(); }
     virtual MetaspaceObj::Type msotype()   const { return MetaspaceObj::array_type(sizeof(T)); }

     virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
       Array<T>* array = dereference();
       log_trace(cds)("Iter(PrimitiveArray): %p [%d]", array, array->length());
     }
     virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
       Array<T>* array = (Array<T>*)new_loc;
       log_trace(cds)("Iter(PrimitiveArray): %p [%d]", array, array->length());
     }
   };

   // -------------------------------------------------- PointerArrayRef
   template <class T> class PointerArrayRef : public Ref {
     Array<T*>** _mpp;
     Array<T*>* dereference() const {
       return *_mpp;
     }
   protected:
     virtual void** mpp() const {
       return (void**)_mpp;
     }

   public:
     PointerArrayRef(Array<T*>** mpp) : _mpp(mpp) {}

     // all Arrays are read-only by default
     virtual bool is_read_only_by_default() const { return true; }
     virtual bool not_null()                const { return dereference() != NULL; }
     virtual int size()                     const { return dereference()->size(); }
     virtual MetaspaceObj::Type msotype()   const { return MetaspaceObj::array_type(sizeof(T*)); }

     virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
       metaspace_pointers_do_at_impl(it, dereference());
     }
     virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
       metaspace_pointers_do_at_impl(it, (Array<T*>*)new_loc);
     }
   private:
     void metaspace_pointers_do_at_impl(MetaspaceClosure *it, Array<T*>* array) const {
       log_trace(cds)("Iter(ObjectArray): %p [%d]", array, array->length());
       for (int i = 0; i < array->length(); i++) {
         T** mpp = array->adr_at(i);
         it->push(mpp);
       }
     }
   };

   void push_impl(Ref* ref, Writability w);

 public:
   // returns true if we want to keep iterating the pointers embedded inside <ref>
   virtual bool do_ref(Ref* ref, bool read_only) = 0;

   // When you do:
   //     void MyType::metaspace_pointers_do(MetaspaceClosure* it) {
   //       it->push(_my_field)
   //
   // C++ will try to match the "most specific" template function. This one will
   // will be matched if possible (if mpp is an Array<> of any pointer type).
   template <typename T> void push(Array<T*>** mpp, Writability w = _default) {
     PointerArrayRef<T> ref(mpp);
     push_impl(&ref, w);
   }

   // If the above function doesn't match (mpp is an Array<>, but T is not a pointer type), then
   // this is the second choice.
   template <typename T> void push(Array<T>** mpp, Writability w = _default) {
     PrimitiveArrayRef<T> ref(mpp);
     push_impl(&ref, w);
   }

   // If the above function doesn't match (mpp is not an Array<> type), then
   // this will be matched by default.
   template <class T> void push(T** mpp, Writability w = _default) {
     ObjectRef<T> ref(mpp);
     push_impl(&ref, w);
   }
 };

 // This is a special MetaspaceClosure that visits each unique MetaspaceObj once.
 class UniqueMetaspaceClosure : public MetaspaceClosure {
   // Do not override. Returns true if we are discovering ref->obj() for the first time.
   virtual bool do_ref(Ref* ref, bool read_only);

 public:
   // Gets called the first time we discover an object.
   virtual void do_unique_ref(Ref* ref, bool read_only) = 0;
 private:
   static unsigned my_hash(const address& a) {
     return primitive_hash<address>(a);
   }
   static bool my_equals(const address& a0, const address& a1) {
     return primitive_equals<address>(a0, a1);
   }
   ResourceHashtable<
       address, bool,
       UniqueMetaspaceClosure::my_hash,   // solaris compiler doesn't like: primitive_hash<address>
       UniqueMetaspaceClosure::my_equals, // solaris compiler doesn't like: primitive_equals<address>
       15889,                             // prime number
       ResourceObj::C_HEAP> _has_been_visited;
 };

 #endif // SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP
	/*
	* Copyright (c) 2017, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#ifndef SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP
	#define SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP

	#include "logging/log.hpp"
	#include "memory/allocation.hpp"
	#include "oops/array.hpp"
	#include "utilities/globalDefinitions.hpp"
	#include "utilities/growableArray.hpp"
	#include "utilities/resourceHash.hpp"

	// The metadata hierarchy is separate from the oop hierarchy
	class MetaspaceObj; // no C++ vtable
	//class Array; // no C++ vtable
	class Annotations; // no C++ vtable
	class ConstantPoolCache; // no C++ vtable
	class ConstMethod; // no C++ vtable
	class MethodCounters; // no C++ vtable
	class Symbol; // no C++ vtable
	class Metadata; // has C++ vtable (so do all subclasses)
	class ConstantPool;
	class MethodData;
	class Method;
	class Klass;
	class InstanceKlass;
	class InstanceMirrorKlass;
	class InstanceClassLoaderKlass;
	class InstanceRefKlass;
	class ArrayKlass;
	class ObjArrayKlass;
	class TypeArrayKlass;

	// class MetaspaceClosure --
	//
	// This class is used for iterating the objects in the HotSpot Metaspaces. It
	// provides an API to walk all the reachable objects starting from a set of
	// root references (such as all Klass'es in the SystemDictionary).
	//
	// Currently it is used for compacting the CDS archive by eliminate temporary
	// objects allocated during archive creation time. See ArchiveCompactor in
	// metaspaceShared.cpp for an example.
	//
	// To support MetaspaceClosure, each subclass of MetaspaceObj must provide
	// a method of the type void metaspace_pointers_do(MetaspaceClosure*). This method
	// should call MetaspaceClosure::push() on every pointer fields of this
	// class that points to a MetaspaceObj. See Annotations::metaspace_pointers_do()
	// for an example.
	class MetaspaceClosure {
	public:
	enum Writability {
	_writable,
	_not_writable,
	_default
	};

	// class MetaspaceClosure::Ref --
	//
	// MetaspaceClosure can be viewed as a very simple type of copying garbage
	// collector. For it to function properly, it requires each subclass of
	// MetaspaceObj to provide two methods:
	//
	// size_t size(); -- to determine how much data to copy
	// void metaspace_pointers_do(MetaspaceClosure*); -- to locate all the embedded pointers
	//
	// Calling these methods would be trivial if these two were virtual methods.
	// However, to save space, MetaspaceObj has NO vtable. The vtable is introduced
	// only in the Metadata class.
	//
	// To work around the lack of a vtable, we use Ref class with templates
	// (see ObjectRef, PrimitiveArrayRef and PointerArrayRef)
	// so that we can statically discover the type of a object. The use of Ref
	// depends on the fact that:
	//
	// [1] We don't use polymorphic pointers for MetaspaceObj's that are not subclasses
	// of Metadata. I.e., we don't do this:
	// class Klass {
	// MetaspaceObj *_obj;
	// Array<int>* foo() { return (Array<int>*)_obj; }
	// Symbol* bar() { return (Symbol*) _obj; }
	//
	// [2] All Array<T> dimensions are statically declared.
	class Ref {
	protected:
	virtual void** mpp() const = 0;
	public:
	virtual bool not_null() const = 0;
	virtual int size() const = 0;
	virtual void metaspace_pointers_do(MetaspaceClosure *it) const = 0;
	virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const = 0;
	virtual MetaspaceObj::Type msotype() const = 0;
	virtual bool is_read_only_by_default() const = 0;

	address obj() const {
	// In some rare cases (see CPSlot in constantPool.hpp) we store some flags in the lowest
	// 2 bits of a MetaspaceObj pointer. Unmask these when manipulating the pointer.
	uintx p = (uintx)*mpp();
	return (address)(p & (~FLAG_MASK));
	}

	void update(address new_loc) const;

	private:
	static const uintx FLAG_MASK = 0x03;

	int flag_bits() const {
	uintx p = (uintx)*mpp();
	return (int)(p & FLAG_MASK);
	}
	};

	private:
	// -------------------------------------------------- ObjectRef
	template <class T> class ObjectRef : public Ref {
	T** _mpp;
	T* dereference() const {
	return *_mpp;
	}
	protected:
	virtual void** mpp() const {
	return (void**)_mpp;
	}

	public:
	ObjectRef(T** mpp) : _mpp(mpp) {}

	virtual bool is_read_only_by_default() const { return T::is_read_only_by_default(); }
	virtual bool not_null() const { return dereference() != NULL; }
	virtual int size() const { return dereference()->size(); }
	virtual MetaspaceObj::Type msotype() const { return dereference()->type(); }

	virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
	dereference()->metaspace_pointers_do(it);
	}
	virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
	((T*)new_loc)->metaspace_pointers_do(it);
	}
	};

	// -------------------------------------------------- PrimitiveArrayRef
	template <class T> class PrimitiveArrayRef : public Ref {
	Array<T>** _mpp;
	Array<T>* dereference() const {
	return *_mpp;
	}
	protected:
	virtual void** mpp() const {
	return (void**)_mpp;
	}

	public:
	PrimitiveArrayRef(Array<T>** mpp) : _mpp(mpp) {}

	// all Arrays are read-only by default
	virtual bool is_read_only_by_default() const { return true; }
	virtual bool not_null() const { return dereference() != NULL; }
	virtual int size() const { return dereference()->size(); }
	virtual MetaspaceObj::Type msotype() const { return MetaspaceObj::array_type(sizeof(T)); }

	virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
	Array<T>* array = dereference();
	log_trace(cds)("Iter(PrimitiveArray): %p [%d]", array, array->length());
	}
	virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
	Array<T>* array = (Array<T>*)new_loc;
	log_trace(cds)("Iter(PrimitiveArray): %p [%d]", array, array->length());
	}
	};

	// -------------------------------------------------- PointerArrayRef
	template <class T> class PointerArrayRef : public Ref {
	Array<T>* _mpp;
	Array<T> dereference() const {
	return *_mpp;
	}
	protected:
	virtual void** mpp() const {
	return (void**)_mpp;
	}

	public:
	PointerArrayRef(Array<T>* mpp) : _mpp(mpp) {}

	// all Arrays are read-only by default
	virtual bool is_read_only_by_default() const { return true; }
	virtual bool not_null() const { return dereference() != NULL; }
	virtual int size() const { return dereference()->size(); }
	virtual MetaspaceObj::Type msotype() const { return MetaspaceObj::array_type(sizeof(T*)); }

	virtual void metaspace_pointers_do(MetaspaceClosure *it) const {
	metaspace_pointers_do_at_impl(it, dereference());
	}
	virtual void metaspace_pointers_do_at(MetaspaceClosure *it, address new_loc) const {
	metaspace_pointers_do_at_impl(it, (Array<T>)new_loc);
	}
	private:
	void metaspace_pointers_do_at_impl(MetaspaceClosure it, Array<T>* array) const {
	log_trace(cds)("Iter(ObjectArray): %p [%d]", array, array->length());
	for (int i = 0; i < array->length(); i++) {
	T** mpp = array->adr_at(i);
	it->push(mpp);
	}
	}
	};

	void push_impl(Ref* ref, Writability w);

	public:
	// returns true if we want to keep iterating the pointers embedded inside <ref>
	virtual bool do_ref(Ref* ref, bool read_only) = 0;

	// When you do:
	// void MyType::metaspace_pointers_do(MetaspaceClosure* it) {
	// it->push(_my_field)
	//
	// C++ will try to match the "most specific" template function. This one will
	// will be matched if possible (if mpp is an Array<> of any pointer type).
	template <typename T> void push(Array<T>* mpp, Writability w = _default) {
	PointerArrayRef<T> ref(mpp);
	push_impl(&ref, w);
	}

	// If the above function doesn't match (mpp is an Array<>, but T is not a pointer type), then
	// this is the second choice.
	template <typename T> void push(Array<T>** mpp, Writability w = _default) {
	PrimitiveArrayRef<T> ref(mpp);
	push_impl(&ref, w);
	}

	// If the above function doesn't match (mpp is not an Array<> type), then
	// this will be matched by default.
	template <class T> void push(T** mpp, Writability w = _default) {
	ObjectRef<T> ref(mpp);
	push_impl(&ref, w);
	}
	};

	// This is a special MetaspaceClosure that visits each unique MetaspaceObj once.
	class UniqueMetaspaceClosure : public MetaspaceClosure {
	// Do not override. Returns true if we are discovering ref->obj() for the first time.
	virtual bool do_ref(Ref* ref, bool read_only);

	public:
	// Gets called the first time we discover an object.
	virtual void do_unique_ref(Ref* ref, bool read_only) = 0;
	private:
	static unsigned my_hash(const address& a) {
	return primitive_hash<address>(a);
	}
	static bool my_equals(const address& a0, const address& a1) {
	return primitive_equals<address>(a0, a1);
	}
	ResourceHashtable<
	address, bool,
	UniqueMetaspaceClosure::my_hash, // solaris compiler doesn't like: primitive_hash<address>
	UniqueMetaspaceClosure::my_equals, // solaris compiler doesn't like: primitive_equals<address>
	15889, // prime number
	ResourceObj::C_HEAP> _has_been_visited;
	};

	#endif // SHARE_VM_MEMORY_METASPACE_ITERATOR_HPP