src/share/vm/prims/jvmtiThreadState.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 2003, 2012, 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_PRIMS_JVMTITHREADSTATE_HPP
 #define SHARE_VM_PRIMS_JVMTITHREADSTATE_HPP

 #include "jvmtifiles/jvmti.h"
 #include "memory/allocation.hpp"
 #include "memory/allocation.inline.hpp"
 #include "prims/jvmtiEventController.hpp"
 #include "runtime/thread.hpp"
 #include "utilities/growableArray.hpp"

 //
 // Forward Declarations
 //

 class JvmtiEnvBase;
 class JvmtiEnvThreadState;
 class JvmtiDynamicCodeEventCollector;

 enum JvmtiClassLoadKind {
   jvmti_class_load_kind_load = 100,
   jvmti_class_load_kind_retransform,
   jvmti_class_load_kind_redefine
 };

 ///////////////////////////////////////////////////////////////
 //
 // class JvmtiEnvThreadStateIterator
 //
 // The only safe means of iterating through the JvmtiEnvThreadStates
 // in a JvmtiThreadState.
 // Note that this iteratation includes invalid environments pending
 // deallocation -- in fact, some uses depend on this behavior.
 //
 class JvmtiEnvThreadStateIterator : public StackObj {
  private:
   JvmtiThreadState* state;
  public:
   JvmtiEnvThreadStateIterator(JvmtiThreadState* thread_state);
   ~JvmtiEnvThreadStateIterator();
   JvmtiEnvThreadState* first();
   JvmtiEnvThreadState* next(JvmtiEnvThreadState* ets);
 };


 ///////////////////////////////////////////////////////////////
 //
 // class JvmtiThreadState
 //
 // The Jvmti state for each thread (across all JvmtiEnv):
 // 1. Local table of enabled events.
 class JvmtiThreadState : public CHeapObj<mtInternal> {
  private:
   friend class JvmtiEnv;
   JavaThread        *_thread;
   bool              _exception_detected;
   bool              _exception_caught;
   bool              _hide_single_stepping;
   bool              _pending_step_for_popframe;
   bool              _pending_step_for_earlyret;
   int               _hide_level;

   // Used to send class being redefined/retransformed and kind of transform
   // info to the class file load hook event handler.
   KlassHandle           *_class_being_redefined;
   JvmtiClassLoadKind    _class_load_kind;

   // This is only valid when is_interp_only_mode() returns true
   int               _cur_stack_depth;

   JvmtiThreadEventEnable _thread_event_enable;

   // for support of JvmtiEnvThreadState
   JvmtiEnvThreadState*   _head_env_thread_state;

   // doubly-linked linear list of active thread state
   // needed in order to iterate the list without holding Threads_lock
   static JvmtiThreadState *_head;
   JvmtiThreadState *_next;
   JvmtiThreadState *_prev;

   // holds the current dynamic code event collector, NULL if no event collector in use
   JvmtiDynamicCodeEventCollector* _dynamic_code_event_collector;
   // holds the current vm object alloc event collector, NULL if no event collector in use
   JvmtiVMObjectAllocEventCollector* _vm_object_alloc_event_collector;

   // Should only be created by factory methods
   JvmtiThreadState(JavaThread *thread);

   friend class JvmtiEnvThreadStateIterator;
   inline JvmtiEnvThreadState* head_env_thread_state();
   inline void set_head_env_thread_state(JvmtiEnvThreadState* ets);

  public:
   ~JvmtiThreadState();

   // is event_type enabled and usable for this thread in any enviroments?
   bool is_enabled(jvmtiEvent event_type) {
     return _thread_event_enable.is_enabled(event_type);
   }

   JvmtiThreadEventEnable *thread_event_enable() {
     return &_thread_event_enable;
   }

   // Must only be called in situations where the state is for the current thread and
   // the environment can not go away.  To be safe, the returned JvmtiEnvThreadState
   // must be used in such a way as there can be no intervening safepoints.
   inline JvmtiEnvThreadState* env_thread_state(JvmtiEnvBase *env);

   static void periodic_clean_up();

   void add_env(JvmtiEnvBase *env);

   // Used by the interpreter for fullspeed debugging support
   bool is_interp_only_mode()                { return _thread->is_interp_only_mode(); }
   void enter_interp_only_mode();
   void leave_interp_only_mode();

   // access to the linked list of all JVMTI thread states
   static JvmtiThreadState *first() {
     assert(Threads::number_of_threads() == 0 || JvmtiThreadState_lock->is_locked(), "sanity check");
     return _head;
   }

   JvmtiThreadState *next()                  {
     return _next;
   }

   // Current stack depth is only valid when is_interp_only_mode() returns true.
   // These functions should only be called at a safepoint - usually called from same thread.
   // Returns the number of Java activations on the stack.
   int cur_stack_depth();
   void invalidate_cur_stack_depth();
   void incr_cur_stack_depth();
   void decr_cur_stack_depth();

   int count_frames();

   inline JavaThread *get_thread()      { return _thread;              }
   inline bool is_exception_detected()  { return _exception_detected;  }
   inline bool is_exception_caught()    { return _exception_caught;  }
   inline void set_exception_detected() { _exception_detected = true;
                                          _exception_caught = false; }
   inline void clear_exception_detected() {
     _exception_detected = false;
     assert(_exception_caught == false, "_exception_caught is out of phase");
   }
   inline void set_exception_caught()   { _exception_caught = true;
                                          _exception_detected = false; }

   inline void clear_hide_single_stepping() {
     if (_hide_level > 0) {
       _hide_level--;
     } else {
       assert(_hide_single_stepping, "hide_single_stepping is out of phase");
       _hide_single_stepping = false;
     }
   }
   inline bool hide_single_stepping() { return _hide_single_stepping; }
   inline void set_hide_single_stepping() {
     if (_hide_single_stepping) {
       _hide_level++;
     } else {
       assert(_hide_level == 0, "hide_level is out of phase");
       _hide_single_stepping = true;
     }
   }

   // Step pending flag is set when PopFrame is called and it is cleared
   // when step for the Pop Frame is completed.
   // This logic is used to distinguish b/w step for pop frame and repeat step.
   void set_pending_step_for_popframe() { _pending_step_for_popframe = true;  }
   void clr_pending_step_for_popframe() { _pending_step_for_popframe = false; }
   bool is_pending_step_for_popframe()  { return _pending_step_for_popframe;  }
   void process_pending_step_for_popframe();

   // Step pending flag is set when ForceEarlyReturn is called and it is cleared
   // when step for the ForceEarlyReturn is completed.
   // This logic is used to distinguish b/w step for early return and repeat step.
   void set_pending_step_for_earlyret() { _pending_step_for_earlyret = true;  }
   void clr_pending_step_for_earlyret() { _pending_step_for_earlyret = false; }
   bool is_pending_step_for_earlyret()  { return _pending_step_for_earlyret;  }
   void process_pending_step_for_earlyret();

   // Setter and getter method is used to send redefined class info
   // when class file load hook event is posted.
   // It is set while loading redefined class and cleared before the
   // class file load hook event is posted.
   inline void set_class_being_redefined(KlassHandle *h_class, JvmtiClassLoadKind kind) {
     _class_being_redefined = h_class;
     _class_load_kind = kind;
   }

   inline void clear_class_being_redefined() {
     _class_being_redefined = NULL;
     _class_load_kind = jvmti_class_load_kind_load;
   }

   inline KlassHandle *get_class_being_redefined() {
     return _class_being_redefined;
   }

   inline JvmtiClassLoadKind get_class_load_kind() {
     return _class_load_kind;
   }

   // RedefineClasses support
   // The bug 6214132 caused the verification to fail.
   //
   // Below is the detailed description of the fix approach taken:
   // 1. What's done in RedefineClasses() before verification:
   //  a) A reference to the class being redefined (_the_class) and a
   //     reference to new version of the class (_scratch_class) are
   //     saved here for use during the bytecode verification phase of
   //     RedefineClasses. See RedefineVerifyMark for how these fields
   //     are managed.
   //   b) The _java_mirror field from _the_class is copied to the
   //     _java_mirror field in _scratch_class. This means that a jclass
   //     returned for _the_class or _scratch_class will refer to the
   //     same Java mirror. The verifier will see the "one true mirror"
   //     for the class being verified.
   // 2. What is done at verification:
   //   When the verifier makes calls into the VM to ask questions about
   //   the class being verified, it will pass the jclass to JVM_* functions.
   //   The jclass is always pointing to the mirror of _the_class.
   //   ~28 JVM_* functions called by the verifier for the information
   //   about CP entries and klass structure should check the jvmtiThreadState
   //   info about equivalent klass versions and use it to replace a Klass*
   //   of _the_class with a Klass* of _scratch_class. The function
   //   class_to_verify_considering_redefinition() must be called for it.
   //
   //   Note again, that this redirection happens only for the verifier thread.
   //   Other threads have very small overhead by checking the existence
   //   of the jvmtiThreadSate and the information about klasses equivalence.
   //   No JNI functions need to be changed, they don't reference the klass guts.
   //   The JavaThread pointer is already available in all JVM_* functions
   //   used by the verifier, so there is no extra performance issue with it.

  private:
   KlassHandle *_the_class_for_redefinition_verification;
   KlassHandle *_scratch_class_for_redefinition_verification;

  public:
   inline void set_class_versions_map(KlassHandle *the_class,
                                      KlassHandle *scratch_class) {
     _the_class_for_redefinition_verification = the_class;
     _scratch_class_for_redefinition_verification = scratch_class;
   }

   inline void clear_class_versions_map() { set_class_versions_map(NULL, NULL); }

   static inline
   Klass* class_to_verify_considering_redefinition(Klass* klass,
                                                     JavaThread *thread) {
     JvmtiThreadState *state = thread->jvmti_thread_state();
     if (state != NULL && state->_the_class_for_redefinition_verification != NULL) {
       if ((*(state->_the_class_for_redefinition_verification))() == klass) {
         klass = (*(state->_scratch_class_for_redefinition_verification))();
       }
     }
     return klass;
   }

   // Todo: get rid of this!
  private:
   bool _debuggable;
  public:
   // Should the thread be enumerated by jvmtiInternal::GetAllThreads?
   bool is_debuggable()                 { return _debuggable; }
   // If a thread cannot be suspended (has no valid last_java_frame) then it gets marked !debuggable
   void set_debuggable(bool debuggable) { _debuggable = debuggable; }

  public:

   bool may_be_walked();

   // Thread local event collector setter and getter methods.
   JvmtiDynamicCodeEventCollector* get_dynamic_code_event_collector() {
     return _dynamic_code_event_collector;
   }
   JvmtiVMObjectAllocEventCollector* get_vm_object_alloc_event_collector() {
     return _vm_object_alloc_event_collector;
   }
   void set_dynamic_code_event_collector(JvmtiDynamicCodeEventCollector* collector) {
     _dynamic_code_event_collector = collector;
   }
   void set_vm_object_alloc_event_collector(JvmtiVMObjectAllocEventCollector* collector) {
     _vm_object_alloc_event_collector = collector;
   }


   //
   // Frame routines
   //

  public:

   //  true when the thread was suspended with a pointer to the last Java frame.
   bool has_last_frame()                     { return _thread->has_last_Java_frame(); }

   void update_for_pop_top_frame();

   // already holding JvmtiThreadState_lock - retrieve or create JvmtiThreadState
   // Can return NULL if JavaThread is exiting.
   inline static JvmtiThreadState *state_for_while_locked(JavaThread *thread) {
     assert(JvmtiThreadState_lock->is_locked(), "sanity check");

     JvmtiThreadState *state = thread->jvmti_thread_state();
     if (state == NULL) {
       if (thread->is_exiting()) {
         // don't add a JvmtiThreadState to a thread that is exiting
         return NULL;
       }

       state = new JvmtiThreadState(thread);
     }
     return state;
   }

   // retrieve or create JvmtiThreadState
   // Can return NULL if JavaThread is exiting.
   inline static JvmtiThreadState *state_for(JavaThread *thread) {
     JvmtiThreadState *state = thread->jvmti_thread_state();
     if (state == NULL) {
       MutexLocker mu(JvmtiThreadState_lock);
       // check again with the lock held
       state = state_for_while_locked(thread);
     } else {
       CHECK_UNHANDLED_OOPS_ONLY(Thread::current()->clear_unhandled_oops());
     }
     return state;
   }

   // JVMTI ForceEarlyReturn support

   // This is set to earlyret_pending to signal that top Java frame
   // should be returned immediately
  public:
   int           _earlyret_state;
   TosState      _earlyret_tos;
   jvalue        _earlyret_value;
   oop           _earlyret_oop;         // Used to return an oop result into Java code from
                                        // ForceEarlyReturnObject, GC-preserved

   // Setting and clearing earlyret_state
   // earlyret_pending indicates that a ForceEarlyReturn() has been
   // requested and not yet been completed.
  public:
   enum EarlyretState {
     earlyret_inactive = 0,
     earlyret_pending  = 1
   };

   void set_earlyret_pending(void) { _earlyret_state = earlyret_pending;  }
   void clr_earlyret_pending(void) { _earlyret_state = earlyret_inactive; }
   bool is_earlyret_pending(void)  { return (_earlyret_state == earlyret_pending);  }

   TosState earlyret_tos()                            { return _earlyret_tos; }
   oop  earlyret_oop() const                          { return _earlyret_oop; }
   void set_earlyret_oop (oop x)                      { _earlyret_oop = x;    }
   jvalue earlyret_value()                            { return _earlyret_value; }
   void set_earlyret_value(jvalue val, TosState tos)  { _earlyret_tos = tos;  _earlyret_value = val;  }
   void clr_earlyret_value()                          { _earlyret_tos = ilgl; _earlyret_value.j = 0L; }

   static ByteSize earlyret_state_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_state); }
   static ByteSize earlyret_tos_offset()   { return byte_offset_of(JvmtiThreadState, _earlyret_tos); }
   static ByteSize earlyret_oop_offset()   { return byte_offset_of(JvmtiThreadState, _earlyret_oop); }
   static ByteSize earlyret_value_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_value); }

   void oops_do(OopClosure* f) NOT_JVMTI_RETURN; // GC support

 public:
   void set_should_post_on_exceptions(bool val) { _thread->set_should_post_on_exceptions_flag(val ? JNI_TRUE : JNI_FALSE); }
 };

 class RedefineVerifyMark : public StackObj {
  private:
   JvmtiThreadState *_state;
   KlassHandle       _scratch_class;
   Handle            _scratch_mirror;

  public:
   RedefineVerifyMark(KlassHandle *the_class, KlassHandle *scratch_class,
                      JvmtiThreadState *state) : _state(state), _scratch_class(*scratch_class)
   {
     _state->set_class_versions_map(the_class, scratch_class);
     _scratch_mirror = Handle(_scratch_class->java_mirror());
     (*scratch_class)->set_java_mirror((*the_class)->java_mirror());
   }

   ~RedefineVerifyMark() {
     // Restore the scratch class's mirror, so when scratch_class is removed
     // the correct mirror pointing to it can be cleared.
     _scratch_class->set_java_mirror(_scratch_mirror());
     _state->clear_class_versions_map();
   }
 };

 #endif // SHARE_VM_PRIMS_JVMTITHREADSTATE_HPP
	/*
	* Copyright (c) 2003, 2012, 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_PRIMS_JVMTITHREADSTATE_HPP
	#define SHARE_VM_PRIMS_JVMTITHREADSTATE_HPP

	#include "jvmtifiles/jvmti.h"
	#include "memory/allocation.hpp"
	#include "memory/allocation.inline.hpp"
	#include "prims/jvmtiEventController.hpp"
	#include "runtime/thread.hpp"
	#include "utilities/growableArray.hpp"

	//
	// Forward Declarations
	//

	class JvmtiEnvBase;
	class JvmtiEnvThreadState;
	class JvmtiDynamicCodeEventCollector;

	enum JvmtiClassLoadKind {
	jvmti_class_load_kind_load = 100,
	jvmti_class_load_kind_retransform,
	jvmti_class_load_kind_redefine
	};

	///////////////////////////////////////////////////////////////
	//
	// class JvmtiEnvThreadStateIterator
	//
	// The only safe means of iterating through the JvmtiEnvThreadStates
	// in a JvmtiThreadState.
	// Note that this iteratation includes invalid environments pending
	// deallocation -- in fact, some uses depend on this behavior.
	//
	class JvmtiEnvThreadStateIterator : public StackObj {
	private:
	JvmtiThreadState* state;
	public:
	JvmtiEnvThreadStateIterator(JvmtiThreadState* thread_state);
	~JvmtiEnvThreadStateIterator();
	JvmtiEnvThreadState* first();
	JvmtiEnvThreadState* next(JvmtiEnvThreadState* ets);
	};


	///////////////////////////////////////////////////////////////
	//
	// class JvmtiThreadState
	//
	// The Jvmti state for each thread (across all JvmtiEnv):
	// 1. Local table of enabled events.
	class JvmtiThreadState : public CHeapObj<mtInternal> {
	private:
	friend class JvmtiEnv;
	JavaThread *_thread;
	bool _exception_detected;
	bool _exception_caught;
	bool _hide_single_stepping;
	bool _pending_step_for_popframe;
	bool _pending_step_for_earlyret;
	int _hide_level;

	// Used to send class being redefined/retransformed and kind of transform
	// info to the class file load hook event handler.
	KlassHandle *_class_being_redefined;
	JvmtiClassLoadKind _class_load_kind;

	// This is only valid when is_interp_only_mode() returns true
	int _cur_stack_depth;

	JvmtiThreadEventEnable _thread_event_enable;

	// for support of JvmtiEnvThreadState
	JvmtiEnvThreadState* _head_env_thread_state;

	// doubly-linked linear list of active thread state
	// needed in order to iterate the list without holding Threads_lock
	static JvmtiThreadState *_head;
	JvmtiThreadState *_next;
	JvmtiThreadState *_prev;

	// holds the current dynamic code event collector, NULL if no event collector in use
	JvmtiDynamicCodeEventCollector* _dynamic_code_event_collector;
	// holds the current vm object alloc event collector, NULL if no event collector in use
	JvmtiVMObjectAllocEventCollector* _vm_object_alloc_event_collector;

	// Should only be created by factory methods
	JvmtiThreadState(JavaThread *thread);

	friend class JvmtiEnvThreadStateIterator;
	inline JvmtiEnvThreadState* head_env_thread_state();
	inline void set_head_env_thread_state(JvmtiEnvThreadState* ets);

	public:
	~JvmtiThreadState();

	// is event_type enabled and usable for this thread in any enviroments?
	bool is_enabled(jvmtiEvent event_type) {
	return _thread_event_enable.is_enabled(event_type);
	}

	JvmtiThreadEventEnable *thread_event_enable() {
	return &_thread_event_enable;
	}

	// Must only be called in situations where the state is for the current thread and
	// the environment can not go away. To be safe, the returned JvmtiEnvThreadState
	// must be used in such a way as there can be no intervening safepoints.
	inline JvmtiEnvThreadState* env_thread_state(JvmtiEnvBase *env);

	static void periodic_clean_up();

	void add_env(JvmtiEnvBase *env);

	// Used by the interpreter for fullspeed debugging support
	bool is_interp_only_mode() { return _thread->is_interp_only_mode(); }
	void enter_interp_only_mode();
	void leave_interp_only_mode();

	// access to the linked list of all JVMTI thread states
	static JvmtiThreadState *first() {
	assert(Threads::number_of_threads() == 0 \|\| JvmtiThreadState_lock->is_locked(), "sanity check");
	return _head;
	}

	JvmtiThreadState *next() {
	return _next;
	}

	// Current stack depth is only valid when is_interp_only_mode() returns true.
	// These functions should only be called at a safepoint - usually called from same thread.
	// Returns the number of Java activations on the stack.
	int cur_stack_depth();
	void invalidate_cur_stack_depth();
	void incr_cur_stack_depth();
	void decr_cur_stack_depth();

	int count_frames();

	inline JavaThread *get_thread() { return _thread; }
	inline bool is_exception_detected() { return _exception_detected; }
	inline bool is_exception_caught() { return _exception_caught; }
	inline void set_exception_detected() { _exception_detected = true;
	_exception_caught = false; }
	inline void clear_exception_detected() {
	_exception_detected = false;
	assert(_exception_caught == false, "_exception_caught is out of phase");
	}
	inline void set_exception_caught() { _exception_caught = true;
	_exception_detected = false; }

	inline void clear_hide_single_stepping() {
	if (_hide_level > 0) {
	_hide_level--;
	} else {
	assert(_hide_single_stepping, "hide_single_stepping is out of phase");
	_hide_single_stepping = false;
	}
	}
	inline bool hide_single_stepping() { return _hide_single_stepping; }
	inline void set_hide_single_stepping() {
	if (_hide_single_stepping) {
	_hide_level++;
	} else {
	assert(_hide_level == 0, "hide_level is out of phase");
	_hide_single_stepping = true;
	}
	}

	// Step pending flag is set when PopFrame is called and it is cleared
	// when step for the Pop Frame is completed.
	// This logic is used to distinguish b/w step for pop frame and repeat step.
	void set_pending_step_for_popframe() { _pending_step_for_popframe = true; }
	void clr_pending_step_for_popframe() { _pending_step_for_popframe = false; }
	bool is_pending_step_for_popframe() { return _pending_step_for_popframe; }
	void process_pending_step_for_popframe();

	// Step pending flag is set when ForceEarlyReturn is called and it is cleared
	// when step for the ForceEarlyReturn is completed.
	// This logic is used to distinguish b/w step for early return and repeat step.
	void set_pending_step_for_earlyret() { _pending_step_for_earlyret = true; }
	void clr_pending_step_for_earlyret() { _pending_step_for_earlyret = false; }
	bool is_pending_step_for_earlyret() { return _pending_step_for_earlyret; }
	void process_pending_step_for_earlyret();

	// Setter and getter method is used to send redefined class info
	// when class file load hook event is posted.
	// It is set while loading redefined class and cleared before the
	// class file load hook event is posted.
	inline void set_class_being_redefined(KlassHandle *h_class, JvmtiClassLoadKind kind) {
	_class_being_redefined = h_class;
	_class_load_kind = kind;
	}

	inline void clear_class_being_redefined() {
	_class_being_redefined = NULL;
	_class_load_kind = jvmti_class_load_kind_load;
	}

	inline KlassHandle *get_class_being_redefined() {
	return _class_being_redefined;
	}

	inline JvmtiClassLoadKind get_class_load_kind() {
	return _class_load_kind;
	}

	// RedefineClasses support
	// The bug 6214132 caused the verification to fail.
	//
	// Below is the detailed description of the fix approach taken:
	// 1. What's done in RedefineClasses() before verification:
	// a) A reference to the class being redefined (_the_class) and a
	// reference to new version of the class (_scratch_class) are
	// saved here for use during the bytecode verification phase of
	// RedefineClasses. See RedefineVerifyMark for how these fields
	// are managed.
	// b) The _java_mirror field from _the_class is copied to the
	// _java_mirror field in _scratch_class. This means that a jclass
	// returned for _the_class or _scratch_class will refer to the
	// same Java mirror. The verifier will see the "one true mirror"
	// for the class being verified.
	// 2. What is done at verification:
	// When the verifier makes calls into the VM to ask questions about
	// the class being verified, it will pass the jclass to JVM_* functions.
	// The jclass is always pointing to the mirror of _the_class.
	// ~28 JVM_* functions called by the verifier for the information
	// about CP entries and klass structure should check the jvmtiThreadState
	// info about equivalent klass versions and use it to replace a Klass*
	// of _the_class with a Klass* of _scratch_class. The function
	// class_to_verify_considering_redefinition() must be called for it.
	//
	// Note again, that this redirection happens only for the verifier thread.
	// Other threads have very small overhead by checking the existence
	// of the jvmtiThreadSate and the information about klasses equivalence.
	// No JNI functions need to be changed, they don't reference the klass guts.
	// The JavaThread pointer is already available in all JVM_* functions
	// used by the verifier, so there is no extra performance issue with it.

	private:
	KlassHandle *_the_class_for_redefinition_verification;
	KlassHandle *_scratch_class_for_redefinition_verification;

	public:
	inline void set_class_versions_map(KlassHandle *the_class,
	KlassHandle *scratch_class) {
	_the_class_for_redefinition_verification = the_class;
	_scratch_class_for_redefinition_verification = scratch_class;
	}

	inline void clear_class_versions_map() { set_class_versions_map(NULL, NULL); }

	static inline
	Klass* class_to_verify_considering_redefinition(Klass* klass,
	JavaThread *thread) {
	JvmtiThreadState *state = thread->jvmti_thread_state();
	if (state != NULL && state->_the_class_for_redefinition_verification != NULL) {
	if ((*(state->_the_class_for_redefinition_verification))() == klass) {
	klass = (*(state->_scratch_class_for_redefinition_verification))();
	}
	}
	return klass;
	}

	// Todo: get rid of this!
	private:
	bool _debuggable;
	public:
	// Should the thread be enumerated by jvmtiInternal::GetAllThreads?
	bool is_debuggable() { return _debuggable; }
	// If a thread cannot be suspended (has no valid last_java_frame) then it gets marked !debuggable
	void set_debuggable(bool debuggable) { _debuggable = debuggable; }

	public:

	bool may_be_walked();

	// Thread local event collector setter and getter methods.
	JvmtiDynamicCodeEventCollector* get_dynamic_code_event_collector() {
	return _dynamic_code_event_collector;
	}
	JvmtiVMObjectAllocEventCollector* get_vm_object_alloc_event_collector() {
	return _vm_object_alloc_event_collector;
	}
	void set_dynamic_code_event_collector(JvmtiDynamicCodeEventCollector* collector) {
	_dynamic_code_event_collector = collector;
	}
	void set_vm_object_alloc_event_collector(JvmtiVMObjectAllocEventCollector* collector) {
	_vm_object_alloc_event_collector = collector;
	}


	//
	// Frame routines
	//

	public:

	// true when the thread was suspended with a pointer to the last Java frame.
	bool has_last_frame() { return _thread->has_last_Java_frame(); }

	void update_for_pop_top_frame();

	// already holding JvmtiThreadState_lock - retrieve or create JvmtiThreadState
	// Can return NULL if JavaThread is exiting.
	inline static JvmtiThreadState state_for_while_locked(JavaThread thread) {
	assert(JvmtiThreadState_lock->is_locked(), "sanity check");

	JvmtiThreadState *state = thread->jvmti_thread_state();
	if (state == NULL) {
	if (thread->is_exiting()) {
	// don't add a JvmtiThreadState to a thread that is exiting
	return NULL;
	}

	state = new JvmtiThreadState(thread);
	}
	return state;
	}

	// retrieve or create JvmtiThreadState
	// Can return NULL if JavaThread is exiting.
	inline static JvmtiThreadState state_for(JavaThread thread) {
	JvmtiThreadState *state = thread->jvmti_thread_state();
	if (state == NULL) {
	MutexLocker mu(JvmtiThreadState_lock);
	// check again with the lock held
	state = state_for_while_locked(thread);
	} else {
	CHECK_UNHANDLED_OOPS_ONLY(Thread::current()->clear_unhandled_oops());
	}
	return state;
	}

	// JVMTI ForceEarlyReturn support

	// This is set to earlyret_pending to signal that top Java frame
	// should be returned immediately
	public:
	int _earlyret_state;
	TosState _earlyret_tos;
	jvalue _earlyret_value;
	oop _earlyret_oop; // Used to return an oop result into Java code from
	// ForceEarlyReturnObject, GC-preserved

	// Setting and clearing earlyret_state
	// earlyret_pending indicates that a ForceEarlyReturn() has been
	// requested and not yet been completed.
	public:
	enum EarlyretState {
	earlyret_inactive = 0,
	earlyret_pending = 1
	};

	void set_earlyret_pending(void) { _earlyret_state = earlyret_pending; }
	void clr_earlyret_pending(void) { _earlyret_state = earlyret_inactive; }
	bool is_earlyret_pending(void) { return (_earlyret_state == earlyret_pending); }

	TosState earlyret_tos() { return _earlyret_tos; }
	oop earlyret_oop() const { return _earlyret_oop; }
	void set_earlyret_oop (oop x) { _earlyret_oop = x; }
	jvalue earlyret_value() { return _earlyret_value; }
	void set_earlyret_value(jvalue val, TosState tos) { _earlyret_tos = tos; _earlyret_value = val; }
	void clr_earlyret_value() { _earlyret_tos = ilgl; _earlyret_value.j = 0L; }

	static ByteSize earlyret_state_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_state); }
	static ByteSize earlyret_tos_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_tos); }
	static ByteSize earlyret_oop_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_oop); }
	static ByteSize earlyret_value_offset() { return byte_offset_of(JvmtiThreadState, _earlyret_value); }

	void oops_do(OopClosure* f) NOT_JVMTI_RETURN; // GC support

	public:
	void set_should_post_on_exceptions(bool val) { _thread->set_should_post_on_exceptions_flag(val ? JNI_TRUE : JNI_FALSE); }
	};

	class RedefineVerifyMark : public StackObj {
	private:
	JvmtiThreadState *_state;
	KlassHandle _scratch_class;
	Handle _scratch_mirror;

	public:
	RedefineVerifyMark(KlassHandle the_class, KlassHandle scratch_class,
	JvmtiThreadState state) : _state(state), _scratch_class(scratch_class)
	{
	_state->set_class_versions_map(the_class, scratch_class);
	_scratch_mirror = Handle(_scratch_class->java_mirror());
	(scratch_class)->set_java_mirror((the_class)->java_mirror());
	}

	~RedefineVerifyMark() {
	// Restore the scratch class's mirror, so when scratch_class is removed
	// the correct mirror pointing to it can be cleared.
	_scratch_class->set_java_mirror(_scratch_mirror());
	_state->clear_class_versions_map();
	}
	};

	#endif // SHARE_VM_PRIMS_JVMTITHREADSTATE_HPP