/* * Copyright (c) 1997, 2014, 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_RUNTIME_HANDLES_HPP #define SHARE_VM_RUNTIME_HANDLES_HPP #include "oops/klass.hpp" //------------------------------------------------------------------------------------------------------------------------ // In order to preserve oops during garbage collection, they should be // allocated and passed around via Handles within the VM. A handle is // simply an extra indirection allocated in a thread local handle area. // // A handle is a ValueObj, so it can be passed around as a value, can // be used as a parameter w/o using &-passing, and can be returned as a // return value. // // oop parameters and return types should be Handles whenever feasible. // // Handles are declared in a straight-forward manner, e.g. // // oop obj = ...; // Handle h1(obj); // allocate new handle // Handle h2(thread, obj); // faster allocation when current thread is known // Handle h3; // declare handle only, no allocation occurs // ... // h3 = h1; // make h3 refer to same indirection as h1 // oop obj2 = h2(); // get handle value // h1->print(); // invoking operation on oop // // Handles are specialized for different oop types to provide extra type // information and avoid unnecessary casting. For each oop type xxxOop // there is a corresponding handle called xxxHandle, e.g. // // oop Handle // Method* methodHandle // instanceOop instanceHandle //------------------------------------------------------------------------------------------------------------------------ // Base class for all handles. Provides overloading of frequently // used operators for ease of use. class Handle VALUE_OBJ_CLASS_SPEC { private: oop* _handle; protected: oop obj() const { return _handle == NULL ? (oop)NULL : *_handle; } oop non_null_obj() const { assert(_handle != NULL, "resolving NULL handle"); return *_handle; } public: // Constructors Handle() { _handle = NULL; } Handle(oop obj); Handle(Thread* thread, oop obj); // General access oop operator () () const { return obj(); } oop operator -> () const { return non_null_obj(); } bool operator == (oop o) const { return obj() == o; } bool operator == (const Handle& h) const { return obj() == h.obj(); } // Null checks bool is_null() const { return _handle == NULL; } bool not_null() const { return _handle != NULL; } // Debugging void print() { obj()->print(); } // Direct interface, use very sparingly. // Used by JavaCalls to quickly convert handles and to create handles static data structures. // Constructor takes a dummy argument to prevent unintentional type conversion in C++. Handle(oop *handle, bool dummy) { _handle = handle; } // Raw handle access. Allows easy duplication of Handles. This can be very unsafe // since duplicates is only valid as long as original handle is alive. oop* raw_value() { return _handle; } static oop raw_resolve(oop *handle) { return handle == NULL ? (oop)NULL : *handle; } }; // Specific Handles for different oop types #define DEF_HANDLE(type, is_a) \ class type##Handle: public Handle { \ protected: \ type##Oop obj() const { return (type##Oop)Handle::obj(); } \ type##Oop non_null_obj() const { return (type##Oop)Handle::non_null_obj(); } \ \ public: \ /* Constructors */ \ type##Handle () : Handle() {} \ type##Handle (type##Oop obj) : Handle((oop)obj) { \ assert(is_null() || ((oop)obj)->is_a(), \ "illegal type"); \ } \ type##Handle (Thread* thread, type##Oop obj) : Handle(thread, (oop)obj) { \ assert(is_null() || ((oop)obj)->is_a(), "illegal type"); \ } \ \ /* Operators for ease of use */ \ type##Oop operator () () const { return obj(); } \ type##Oop operator -> () const { return non_null_obj(); } \ }; DEF_HANDLE(instance , is_instance ) DEF_HANDLE(array , is_array ) DEF_HANDLE(objArray , is_objArray ) DEF_HANDLE(typeArray , is_typeArray ) //------------------------------------------------------------------------------------------------------------------------ // Metadata Handles. Unlike oop Handles these are needed to prevent metadata // from being reclaimed by RedefineClasses. // Specific Handles for different oop types #define DEF_METADATA_HANDLE(name, type) \ class name##Handle; \ class name##Handle : public StackObj { \ type* _value; \ Thread* _thread; \ protected: \ type* obj() const { return _value; } \ type* non_null_obj() const { assert(_value != NULL, "resolving NULL _value"); return _value; } \ \ public: \ /* Constructors */ \ name##Handle () : _value(NULL), _thread(NULL) {} \ name##Handle (type* obj); \ name##Handle (Thread* thread, type* obj); \ \ name##Handle (const name##Handle &h); \ name##Handle& operator=(const name##Handle &s); \ \ /* Destructor */ \ ~name##Handle (); \ void remove(); \ \ /* Operators for ease of use */ \ type* operator () () const { return obj(); } \ type* operator -> () const { return non_null_obj(); } \ \ bool operator == (type* o) const { return obj() == o; } \ bool operator == (const name##Handle& h) const { return obj() == h.obj(); } \ \ /* Null checks */ \ bool is_null() const { return _value == NULL; } \ bool not_null() const { return _value != NULL; } \ }; DEF_METADATA_HANDLE(method, Method) DEF_METADATA_HANDLE(constantPool, ConstantPool) // Writing this class explicitly, since DEF_METADATA_HANDLE(klass) doesn't // provide the necessary Klass* <-> Klass* conversions. This Klass // could be removed when we don't have the Klass* typedef anymore. class KlassHandle : public StackObj { Klass* _value; protected: Klass* obj() const { return _value; } Klass* non_null_obj() const { assert(_value != NULL, "resolving NULL _value"); return _value; } public: KlassHandle() : _value(NULL) {} KlassHandle(const Klass* obj) : _value(const_cast(obj)) {}; KlassHandle(Thread* thread, const Klass* obj) : _value(const_cast(obj)) {}; Klass* operator () () const { return obj(); } Klass* operator -> () const { return non_null_obj(); } bool operator == (Klass* o) const { return obj() == o; } bool operator == (const KlassHandle& h) const { return obj() == h.obj(); } bool is_null() const { return _value == NULL; } bool not_null() const { return _value != NULL; } }; class instanceKlassHandle : public KlassHandle { public: /* Constructors */ instanceKlassHandle () : KlassHandle() {} instanceKlassHandle (const Klass* k) : KlassHandle(k) { assert(k == NULL || k->oop_is_instance(), "illegal type"); } instanceKlassHandle (Thread* thread, const Klass* k) : KlassHandle(thread, k) { assert(k == NULL || k->oop_is_instance(), "illegal type"); } /* Access to klass part */ InstanceKlass* operator () () const { return (InstanceKlass*)obj(); } InstanceKlass* operator -> () const { return (InstanceKlass*)obj(); } }; //------------------------------------------------------------------------------------------------------------------------ // Thread local handle area class HandleArea: public Arena { friend class HandleMark; friend class NoHandleMark; friend class ResetNoHandleMark; #ifdef ASSERT int _handle_mark_nesting; int _no_handle_mark_nesting; #endif HandleArea* _prev; // link to outer (older) area public: // Constructor HandleArea(HandleArea* prev) : Arena(mtThread, Chunk::tiny_size) { debug_only(_handle_mark_nesting = 0); debug_only(_no_handle_mark_nesting = 0); _prev = prev; } // Only coroutine uses this constructor HandleArea(HandleArea* prev, size_t init_size) : Arena(mtThread, init_size) { assert(EnableCoroutine, "EnableCoroutine is off"); debug_only(_handle_mark_nesting = 0); debug_only(_no_handle_mark_nesting = 0); _prev = prev; } // Handle allocation private: oop* real_allocate_handle(oop obj) { #ifdef ASSERT oop* handle = (oop*) (UseMallocOnly ? internal_malloc_4(oopSize) : Amalloc_4(oopSize)); #else oop* handle = (oop*) Amalloc_4(oopSize); #endif *handle = obj; return handle; } public: #ifdef ASSERT oop* allocate_handle(oop obj); #else oop* allocate_handle(oop obj) { return real_allocate_handle(obj); } #endif // Garbage collection support void oops_do(OopClosure* f); // Number of handles in use size_t used() const { return Arena::used() / oopSize; } debug_only(bool no_handle_mark_active() { return _no_handle_mark_nesting > 0; }) }; //------------------------------------------------------------------------------------------------------------------------ // Handles are allocated in a (growable) thread local handle area. Deallocation // is managed using a HandleMark. It should normally not be necessary to use // HandleMarks manually. // // A HandleMark constructor will record the current handle area top, and the // desctructor will reset the top, destroying all handles allocated in between. // The following code will therefore NOT work: // // Handle h; // { // HandleMark hm; // h = Handle(obj); // } // h()->print(); // WRONG, h destroyed by HandleMark destructor. // // If h has to be preserved, it can be converted to an oop or a local JNI handle // across the HandleMark boundary. // The base class of HandleMark should have been StackObj but we also heap allocate // a HandleMark when a thread is created. The operator new is for this special case. class HandleMark { private: Thread *_thread; // thread that owns this mark HandleArea *_area; // saved handle area Chunk *_chunk; // saved arena chunk char *_hwm, *_max; // saved arena info size_t _size_in_bytes; // size of handle area // Link to previous active HandleMark in thread HandleMark* _previous_handle_mark; void initialize(Thread* thread); // common code for constructors void set_previous_handle_mark(HandleMark* mark) { _previous_handle_mark = mark; } HandleMark* previous_handle_mark() const { return _previous_handle_mark; } size_t size_in_bytes() const { return _size_in_bytes; } public: HandleMark(); // see handles_inline.hpp HandleMark(Thread* thread) { initialize(thread); } HandleMark(Thread* thread, HandleArea* area, HandleMark* last_handle_mark); ~HandleMark(); // Functions used by HandleMarkCleaner // called in the constructor of HandleMarkCleaner void push(); // called in the destructor of HandleMarkCleaner void pop_and_restore(); // overloaded operators void* operator new(size_t size) throw(); void* operator new [](size_t size) throw(); void operator delete(void* p); void operator delete[](void* p); }; //------------------------------------------------------------------------------------------------------------------------ // A NoHandleMark stack object will verify that no handles are allocated // in its scope. Enabled in debug mode only. class NoHandleMark: public StackObj { public: #ifdef ASSERT NoHandleMark(); ~NoHandleMark(); #else NoHandleMark() {} ~NoHandleMark() {} #endif }; class ResetNoHandleMark: public StackObj { int _no_handle_mark_nesting; public: #ifdef ASSERT ResetNoHandleMark(); ~ResetNoHandleMark(); #else ResetNoHandleMark() {} ~ResetNoHandleMark() {} #endif }; #endif // SHARE_VM_RUNTIME_HANDLES_HPP