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src/share/vm/prims/jvmtiTagMap.cpp@fa83ab460c54 (annotated)

src/share/vm/prims/jvmtiTagMap.cpp

Fri, 22 Oct 2010 15:59:34 -0400

author

acorn

date

Fri, 22 Oct 2010 15:59:34 -0400

changeset 2233

fa83ab460c54

parent 1907

c18cbe5936b8

child 2314

f95d63e2154a

permissions

-rw-r--r--

6988353: refactor contended sync subsystem
Summary: reduce complexity by factoring synchronizer.cpp
Reviewed-by: dholmes, never, coleenp

duke@435	1	/*
trims@1907	2	* Copyright (c) 2003, 2009, Oracle and/or its affiliates. All rights reserved.
duke@435	3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@435	4	*
duke@435	5	* This code is free software; you can redistribute it and/or modify it
duke@435	6	* under the terms of the GNU General Public License version 2 only, as
duke@435	7	* published by the Free Software Foundation.
duke@435	8	*
duke@435	9	* This code is distributed in the hope that it will be useful, but WITHOUT
duke@435	10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@435	11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@435	12	* version 2 for more details (a copy is included in the LICENSE file that
duke@435	13	* accompanied this code).
duke@435	14	*
duke@435	15	* You should have received a copy of the GNU General Public License version
duke@435	16	* 2 along with this work; if not, write to the Free Software Foundation,
duke@435	17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@435	18	*
trims@1907	19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
trims@1907	20	* or visit www.oracle.com if you need additional information or have any
trims@1907	21	* questions.
duke@435	22	*
duke@435	23	*/
duke@435	24
duke@435	25	# include "incls/_precompiled.incl"
duke@435	26	# include "incls/_jvmtiTagMap.cpp.incl"
duke@435	27
duke@435	28	// JvmtiTagHashmapEntry
duke@435	29	//
duke@435	30	// Each entry encapsulates a JNI weak reference to the tagged object
duke@435	31	// and the tag value. In addition an entry includes a next pointer which
duke@435	32	// is used to chain entries together.
duke@435	33
duke@435	34	class JvmtiTagHashmapEntry : public CHeapObj {
duke@435	35	private:
duke@435	36	friend class JvmtiTagMap;
duke@435	37
duke@435	38	jweak _object; // JNI weak ref to tagged object
duke@435	39	jlong _tag; // the tag
duke@435	40	JvmtiTagHashmapEntry* _next; // next on the list
duke@435	41
duke@435	42	inline void init(jweak object, jlong tag) {
duke@435	43	_object = object;
duke@435	44	_tag = tag;
duke@435	45	_next = NULL;
duke@435	46	}
duke@435	47
duke@435	48	// constructor
duke@435	49	JvmtiTagHashmapEntry(jweak object, jlong tag) { init(object, tag); }
duke@435	50
duke@435	51	public:
duke@435	52
duke@435	53	// accessor methods
duke@435	54	inline jweak object() const { return _object; }
duke@435	55	inline jlong tag() const { return _tag; }
duke@435	56
duke@435	57	inline void set_tag(jlong tag) {
duke@435	58	assert(tag != 0, "can't be zero");
duke@435	59	_tag = tag;
duke@435	60	}
duke@435	61
duke@435	62	inline JvmtiTagHashmapEntry* next() const { return _next; }
duke@435	63	inline void set_next(JvmtiTagHashmapEntry* next) { _next = next; }
duke@435	64	};
duke@435	65
duke@435	66
duke@435	67	// JvmtiTagHashmap
duke@435	68	//
duke@435	69	// A hashmap is essentially a table of pointers to entries. Entries
duke@435	70	// are hashed to a location, or position in the table, and then
duke@435	71	// chained from that location. The "key" for hashing is address of
duke@435	72	// the object, or oop. The "value" is the JNI weak reference to the
duke@435	73	// object and the tag value. Keys are not stored with the entry.
duke@435	74	// Instead the weak reference is resolved to obtain the key.
duke@435	75	//
duke@435	76	// A hashmap maintains a count of the number entries in the hashmap
duke@435	77	// and resizes if the number of entries exceeds a given threshold.
duke@435	78	// The threshold is specified as a percentage of the size - for
duke@435	79	// example a threshold of 0.75 will trigger the hashmap to resize
duke@435	80	// if the number of entries is >75% of table size.
duke@435	81	//
duke@435	82	// A hashmap provides functions for adding, removing, and finding
duke@435	83	// entries. It also provides a function to iterate over all entries
duke@435	84	// in the hashmap.
duke@435	85
duke@435	86	class JvmtiTagHashmap : public CHeapObj {
duke@435	87	private:
duke@435	88	friend class JvmtiTagMap;
duke@435	89
duke@435	90	enum {
duke@435	91	small_trace_threshold = 10000, // threshold for tracing
duke@435	92	medium_trace_threshold = 100000,
duke@435	93	large_trace_threshold = 1000000,
duke@435	94	initial_trace_threshold = small_trace_threshold
duke@435	95	};
duke@435	96
duke@435	97	static int _sizes[]; // array of possible hashmap sizes
duke@435	98	int _size; // actual size of the table
duke@435	99	int _size_index; // index into size table
duke@435	100
duke@435	101	int _entry_count; // number of entries in the hashmap
duke@435	102
duke@435	103	float _load_factor; // load factor as a % of the size
duke@435	104	int _resize_threshold; // computed threshold to trigger resizing.
duke@435	105	bool _resizing_enabled; // indicates if hashmap can resize
duke@435	106
duke@435	107	int _trace_threshold; // threshold for trace messages
duke@435	108
duke@435	109	JvmtiTagHashmapEntry** _table; // the table of entries.
duke@435	110
duke@435	111	// private accessors
duke@435	112	int resize_threshold() const { return _resize_threshold; }
duke@435	113	int trace_threshold() const { return _trace_threshold; }
duke@435	114
duke@435	115	// initialize the hashmap
duke@435	116	void init(int size_index=0, float load_factor=4.0f) {
duke@435	117	int initial_size = _sizes[size_index];
duke@435	118	_size_index = size_index;
duke@435	119	_size = initial_size;
duke@435	120	_entry_count = 0;
duke@435	121	if (TraceJVMTIObjectTagging) {
duke@435	122	_trace_threshold = initial_trace_threshold;
duke@435	123	} else {
duke@435	124	_trace_threshold = -1;
duke@435	125	}
duke@435	126	_load_factor = load_factor;
duke@435	127	_resize_threshold = (int)(_load_factor * _size);
duke@435	128	_resizing_enabled = true;
duke@435	129	size_t s = initial_size * sizeof(JvmtiTagHashmapEntry*);
duke@435	130	_table = (JvmtiTagHashmapEntry**)os::malloc(s);
duke@435	131	if (_table == NULL) {
duke@435	132	vm_exit_out_of_memory(s, "unable to allocate initial hashtable for jvmti object tags");
duke@435	133	}
duke@435	134	for (int i=0; i<initial_size; i++) {
duke@435	135	_table[i] = NULL;
duke@435	136	}
duke@435	137	}
duke@435	138
duke@435	139	// hash a given key (oop) with the specified size
duke@435	140	static unsigned int hash(oop key, int size) {
duke@435	141	// shift right to get better distribution (as these bits will be zero
duke@435	142	// with aligned addresses)
duke@435	143	unsigned int addr = (unsigned int)((intptr_t)key);
duke@435	144	#ifdef _LP64
duke@435	145	return (addr >> 3) % size;
duke@435	146	#else
duke@435	147	return (addr >> 2) % size;
duke@435	148	#endif
duke@435	149	}
duke@435	150
duke@435	151	// hash a given key (oop)
duke@435	152	unsigned int hash(oop key) {
duke@435	153	return hash(key, _size);
duke@435	154	}
duke@435	155
duke@435	156	// resize the hashmap - allocates a large table and re-hashes
duke@435	157	// all entries into the new table.
duke@435	158	void resize() {
duke@435	159	int new_size_index = _size_index+1;
duke@435	160	int new_size = _sizes[new_size_index];
duke@435	161	if (new_size < 0) {
duke@435	162	// hashmap already at maximum capacity
duke@435	163	return;
duke@435	164	}
duke@435	165
duke@435	166	// allocate new table
duke@435	167	size_t s = new_size * sizeof(JvmtiTagHashmapEntry*);
duke@435	168	JvmtiTagHashmapEntry** new_table = (JvmtiTagHashmapEntry**)os::malloc(s);
duke@435	169	if (new_table == NULL) {
duke@435	170	warning("unable to allocate larger hashtable for jvmti object tags");
duke@435	171	set_resizing_enabled(false);
duke@435	172	return;
duke@435	173	}
duke@435	174
duke@435	175	// initialize new table
duke@435	176	int i;
duke@435	177	for (i=0; i<new_size; i++) {
duke@435	178	new_table[i] = NULL;
duke@435	179	}
duke@435	180
duke@435	181	// rehash all entries into the new table
duke@435	182	for (i=0; i<_size; i++) {
duke@435	183	JvmtiTagHashmapEntry* entry = _table[i];
duke@435	184	while (entry != NULL) {
duke@435	185	JvmtiTagHashmapEntry* next = entry->next();
duke@435	186	oop key = JNIHandles::resolve(entry->object());
duke@435	187	assert(key != NULL, "jni weak reference cleared!!");
duke@435	188	unsigned int h = hash(key, new_size);
duke@435	189	JvmtiTagHashmapEntry* anchor = new_table[h];
duke@435	190	if (anchor == NULL) {
duke@435	191	new_table[h] = entry;
duke@435	192	entry->set_next(NULL);
duke@435	193	} else {
duke@435	194	entry->set_next(anchor);
duke@435	195	new_table[h] = entry;
duke@435	196	}
duke@435	197	entry = next;
duke@435	198	}
duke@435	199	}
duke@435	200
duke@435	201	// free old table and update settings.
duke@435	202	os::free((void*)_table);
duke@435	203	_table = new_table;
duke@435	204	_size_index = new_size_index;
duke@435	205	_size = new_size;
duke@435	206
duke@435	207	// compute new resize threshold
duke@435	208	_resize_threshold = (int)(_load_factor * _size);
duke@435	209	}
duke@435	210
duke@435	211
duke@435	212	// internal remove function - remove an entry at a given position in the
duke@435	213	// table.
duke@435	214	inline void remove(JvmtiTagHashmapEntry* prev, int pos, JvmtiTagHashmapEntry* entry) {
duke@435	215	assert(pos >= 0 && pos < _size, "out of range");
duke@435	216	if (prev == NULL) {
duke@435	217	_table[pos] = entry->next();
duke@435	218	} else {
duke@435	219	prev->set_next(entry->next());
duke@435	220	}
duke@435	221	assert(_entry_count > 0, "checking");
duke@435	222	_entry_count--;
duke@435	223	}
duke@435	224
duke@435	225	// resizing switch
duke@435	226	bool is_resizing_enabled() const { return _resizing_enabled; }
duke@435	227	void set_resizing_enabled(bool enable) { _resizing_enabled = enable; }
duke@435	228
duke@435	229	// debugging
duke@435	230	void print_memory_usage();
duke@435	231	void compute_next_trace_threshold();
duke@435	232
duke@435	233	public:
duke@435	234
duke@435	235	// create a JvmtiTagHashmap of a preferred size and optionally a load factor.
duke@435	236	// The preferred size is rounded down to an actual size.
duke@435	237	JvmtiTagHashmap(int size, float load_factor=0.0f) {
duke@435	238	int i=0;
duke@435	239	while (_sizes[i] < size) {
duke@435	240	if (_sizes[i] < 0) {
duke@435	241	assert(i > 0, "sanity check");
duke@435	242	i--;
duke@435	243	break;
duke@435	244	}
duke@435	245	i++;
duke@435	246	}
duke@435	247
duke@435	248	// if a load factor is specified then use it, otherwise use default
duke@435	249	if (load_factor > 0.01f) {
duke@435	250	init(i, load_factor);
duke@435	251	} else {
duke@435	252	init(i);
duke@435	253	}
duke@435	254	}
duke@435	255
duke@435	256	// create a JvmtiTagHashmap with default settings
duke@435	257	JvmtiTagHashmap() {
duke@435	258	init();
duke@435	259	}
duke@435	260
duke@435	261	// release table when JvmtiTagHashmap destroyed
duke@435	262	~JvmtiTagHashmap() {
duke@435	263	if (_table != NULL) {
duke@435	264	os::free((void*)_table);
duke@435	265	_table = NULL;
duke@435	266	}
duke@435	267	}
duke@435	268
duke@435	269	// accessors
duke@435	270	int size() const { return _size; }
duke@435	271	JvmtiTagHashmapEntry** table() const { return _table; }
duke@435	272	int entry_count() const { return _entry_count; }
duke@435	273
duke@435	274	// find an entry in the hashmap, returns NULL if not found.
duke@435	275	inline JvmtiTagHashmapEntry* find(oop key) {
duke@435	276	unsigned int h = hash(key);
duke@435	277	JvmtiTagHashmapEntry* entry = _table[h];
duke@435	278	while (entry != NULL) {
duke@435	279	oop orig_key = JNIHandles::resolve(entry->object());
duke@435	280	assert(orig_key != NULL, "jni weak reference cleared!!");
duke@435	281	if (key == orig_key) {
duke@435	282	break;
duke@435	283	}
duke@435	284	entry = entry->next();
duke@435	285	}
duke@435	286	return entry;
duke@435	287	}
duke@435	288
duke@435	289
duke@435	290	// add a new entry to hashmap
duke@435	291	inline void add(oop key, JvmtiTagHashmapEntry* entry) {
duke@435	292	assert(key != NULL, "checking");
duke@435	293	assert(find(key) == NULL, "duplicate detected");
duke@435	294	unsigned int h = hash(key);
duke@435	295	JvmtiTagHashmapEntry* anchor = _table[h];
duke@435	296	if (anchor == NULL) {
duke@435	297	_table[h] = entry;
duke@435	298	entry->set_next(NULL);
duke@435	299	} else {
duke@435	300	entry->set_next(anchor);
duke@435	301	_table[h] = entry;
duke@435	302	}
duke@435	303
duke@435	304	_entry_count++;
duke@435	305	if (trace_threshold() > 0 && entry_count() >= trace_threshold()) {
duke@435	306	assert(TraceJVMTIObjectTagging, "should only get here when tracing");
duke@435	307	print_memory_usage();
duke@435	308	compute_next_trace_threshold();
duke@435	309	}
duke@435	310
duke@435	311	// if the number of entries exceed the threshold then resize
duke@435	312	if (entry_count() > resize_threshold() && is_resizing_enabled()) {
duke@435	313	resize();
duke@435	314	}
duke@435	315	}
duke@435	316
duke@435	317	// remove an entry with the given key.
duke@435	318	inline JvmtiTagHashmapEntry* remove(oop key) {
duke@435	319	unsigned int h = hash(key);
duke@435	320	JvmtiTagHashmapEntry* entry = _table[h];
duke@435	321	JvmtiTagHashmapEntry* prev = NULL;
duke@435	322	while (entry != NULL) {
duke@435	323	oop orig_key = JNIHandles::resolve(entry->object());
duke@435	324	assert(orig_key != NULL, "jni weak reference cleared!!");
duke@435	325	if (key == orig_key) {
duke@435	326	break;
duke@435	327	}
duke@435	328	prev = entry;
duke@435	329	entry = entry->next();
duke@435	330	}
duke@435	331	if (entry != NULL) {
duke@435	332	remove(prev, h, entry);
duke@435	333	}
duke@435	334	return entry;
duke@435	335	}
duke@435	336
duke@435	337	// iterate over all entries in the hashmap
duke@435	338	void entry_iterate(JvmtiTagHashmapEntryClosure* closure);
duke@435	339	};
duke@435	340
duke@435	341	// possible hashmap sizes - odd primes that roughly double in size.
duke@435	342	// To avoid excessive resizing the odd primes from 4801-76831 and
duke@435	343	// 76831-307261 have been removed. The list must be terminated by -1.
duke@435	344	int JvmtiTagHashmap::_sizes[] = { 4801, 76831, 307261, 614563, 1228891,
duke@435	345	2457733, 4915219, 9830479, 19660831, 39321619, 78643219, -1 };
duke@435	346
duke@435	347
duke@435	348	// A supporting class for iterating over all entries in Hashmap
duke@435	349	class JvmtiTagHashmapEntryClosure {
duke@435	350	public:
duke@435	351	virtual void do_entry(JvmtiTagHashmapEntry* entry) = 0;
duke@435	352	};
duke@435	353
duke@435	354
duke@435	355	// iterate over all entries in the hashmap
duke@435	356	void JvmtiTagHashmap::entry_iterate(JvmtiTagHashmapEntryClosure* closure) {
duke@435	357	for (int i=0; i<_size; i++) {
duke@435	358	JvmtiTagHashmapEntry* entry = _table[i];
duke@435	359	JvmtiTagHashmapEntry* prev = NULL;
duke@435	360	while (entry != NULL) {
duke@435	361	// obtain the next entry before invoking do_entry - this is
duke@435	362	// necessary because do_entry may remove the entry from the
duke@435	363	// hashmap.
duke@435	364	JvmtiTagHashmapEntry* next = entry->next();
duke@435	365	closure->do_entry(entry);
duke@435	366	entry = next;
duke@435	367	}
duke@435	368	}
duke@435	369	}
duke@435	370
duke@435	371	// debugging
duke@435	372	void JvmtiTagHashmap::print_memory_usage() {
duke@435	373	intptr_t p = (intptr_t)this;
duke@435	374	tty->print("[JvmtiTagHashmap @ " INTPTR_FORMAT, p);
duke@435	375
duke@435	376	// table + entries in KB
duke@435	377	int hashmap_usage = (size()*sizeof(JvmtiTagHashmapEntry*) +
duke@435	378	entry_count()*sizeof(JvmtiTagHashmapEntry))/K;
duke@435	379
duke@435	380	int weak_globals_usage = (int)(JNIHandles::weak_global_handle_memory_usage()/K);
duke@435	381	tty->print_cr(", %d entries (%d KB) <JNI weak globals: %d KB>]",
duke@435	382	entry_count(), hashmap_usage, weak_globals_usage);
duke@435	383	}
duke@435	384
duke@435	385	// compute threshold for the next trace message
duke@435	386	void JvmtiTagHashmap::compute_next_trace_threshold() {
duke@435	387	if (trace_threshold() < medium_trace_threshold) {
duke@435	388	_trace_threshold += small_trace_threshold;
duke@435	389	} else {
duke@435	390	if (trace_threshold() < large_trace_threshold) {
duke@435	391	_trace_threshold += medium_trace_threshold;
duke@435	392	} else {
duke@435	393	_trace_threshold += large_trace_threshold;
duke@435	394	}
duke@435	395	}
duke@435	396	}
duke@435	397
duke@435	398	// memory region for young generation
duke@435	399	MemRegion JvmtiTagMap::_young_gen;
duke@435	400
duke@435	401	// get the memory region used for the young generation
duke@435	402	void JvmtiTagMap::get_young_generation() {
ysr@777	403	CollectedHeap* ch = Universe::heap();
ysr@777	404	switch (ch->kind()) {
ysr@777	405	case (CollectedHeap::GenCollectedHeap): {
ysr@777	406	_young_gen = ((GenCollectedHeap*)ch)->get_gen(0)->reserved();
ysr@777	407	break;
ysr@777	408	}
duke@435	409	#ifndef SERIALGC
ysr@777	410	case (CollectedHeap::ParallelScavengeHeap): {
ysr@777	411	_young_gen = ((ParallelScavengeHeap*)ch)->young_gen()->reserved();
ysr@777	412	break;
ysr@777	413	}
ysr@777	414	case (CollectedHeap::G1CollectedHeap): {
ysr@777	415	// Until a more satisfactory solution is implemented, all
ysr@777	416	// oops in the tag map will require rehash at each gc.
ysr@777	417	// This is a correct, if extremely inefficient solution.
ysr@777	418	// See RFE 6621729 for related commentary.
ysr@777	419	_young_gen = ch->reserved_region();
ysr@777	420	break;
ysr@777	421	}
ysr@777	422	#endif // !SERIALGC
ysr@777	423	default:
ysr@777	424	ShouldNotReachHere();
duke@435	425	}
duke@435	426	}
duke@435	427
duke@435	428	// returns true if oop is in the young generation
duke@435	429	inline bool JvmtiTagMap::is_in_young(oop o) {
duke@435	430	assert(_young_gen.start() != NULL, "checking");
duke@435	431	void* p = (void*)o;
duke@435	432	bool in_young = _young_gen.contains(p);
duke@435	433	return in_young;
duke@435	434	}
duke@435	435
duke@435	436	// returns the appropriate hashmap for a given object
duke@435	437	inline JvmtiTagHashmap* JvmtiTagMap::hashmap_for(oop o) {
duke@435	438	if (is_in_young(o)) {
duke@435	439	return _hashmap[0];
duke@435	440	} else {
duke@435	441	return _hashmap[1];
duke@435	442	}
duke@435	443	}
duke@435	444
duke@435	445
duke@435	446	// create a JvmtiTagMap
duke@435	447	JvmtiTagMap::JvmtiTagMap(JvmtiEnv* env) :
duke@435	448	_env(env),
duke@435	449	_lock(Mutex::nonleaf+2, "JvmtiTagMap._lock", false),
duke@435	450	_free_entries(NULL),
duke@435	451	_free_entries_count(0)
duke@435	452	{
duke@435	453	assert(JvmtiThreadState_lock->is_locked(), "sanity check");
duke@435	454	assert(((JvmtiEnvBase *)env)->tag_map() == NULL, "tag map already exists for environment");
duke@435	455
duke@435	456	// create the hashmaps
duke@435	457	for (int i=0; i<n_hashmaps; i++) {
duke@435	458	_hashmap[i] = new JvmtiTagHashmap();
duke@435	459	}
duke@435	460
duke@435	461	// get the memory region used by the young generation
duke@435	462	get_young_generation();
duke@435	463
duke@435	464	// finally add us to the environment
duke@435	465	((JvmtiEnvBase *)env)->set_tag_map(this);
duke@435	466	}
duke@435	467
duke@435	468
duke@435	469	// destroy a JvmtiTagMap
duke@435	470	JvmtiTagMap::~JvmtiTagMap() {
duke@435	471
duke@435	472	// no lock acquired as we assume the enclosing environment is
duke@435	473	// also being destroryed.
duke@435	474	((JvmtiEnvBase *)_env)->set_tag_map(NULL);
duke@435	475
duke@435	476	// iterate over the hashmaps and destroy each of the entries
duke@435	477	for (int i=0; i<n_hashmaps; i++) {
duke@435	478	JvmtiTagHashmap* hashmap = _hashmap[i];
duke@435	479	JvmtiTagHashmapEntry** table = hashmap->table();
duke@435	480	for (int j=0; j<hashmap->size(); j++) {
duke@435	481	JvmtiTagHashmapEntry *entry = table[j];
duke@435	482	while (entry != NULL) {
duke@435	483	JvmtiTagHashmapEntry* next = entry->next();
duke@435	484	jweak ref = entry->object();
duke@435	485	JNIHandles::destroy_weak_global(ref);
duke@435	486	delete entry;
duke@435	487	entry = next;
duke@435	488	}
duke@435	489	}
duke@435	490
duke@435	491	// finally destroy the hashmap
duke@435	492	delete hashmap;
duke@435	493	}
duke@435	494
duke@435	495	// remove any entries on the free list
duke@435	496	JvmtiTagHashmapEntry* entry = _free_entries;
duke@435	497	while (entry != NULL) {
duke@435	498	JvmtiTagHashmapEntry* next = entry->next();
duke@435	499	delete entry;
duke@435	500	entry = next;
duke@435	501	}
duke@435	502	}
duke@435	503
duke@435	504	// create a hashmap entry
duke@435	505	// - if there's an entry on the (per-environment) free list then this
duke@435	506	// is returned. Otherwise an new entry is allocated.
duke@435	507	JvmtiTagHashmapEntry* JvmtiTagMap::create_entry(jweak ref, jlong tag) {
duke@435	508	assert(Thread::current()->is_VM_thread() || is_locked(), "checking");
duke@435	509	JvmtiTagHashmapEntry* entry;
duke@435	510	if (_free_entries == NULL) {
duke@435	511	entry = new JvmtiTagHashmapEntry(ref, tag);
duke@435	512	} else {
duke@435	513	assert(_free_entries_count > 0, "mismatched _free_entries_count");
duke@435	514	_free_entries_count--;
duke@435	515	entry = _free_entries;
duke@435	516	_free_entries = entry->next();
duke@435	517	entry->init(ref, tag);
duke@435	518	}
duke@435	519	return entry;
duke@435	520	}
duke@435	521
duke@435	522	// destroy an entry by returning it to the free list
duke@435	523	void JvmtiTagMap::destroy_entry(JvmtiTagHashmapEntry* entry) {
duke@435	524	assert(SafepointSynchronize::is_at_safepoint() || is_locked(), "checking");
duke@435	525	// limit the size of the free list
duke@435	526	if (_free_entries_count >= max_free_entries) {
duke@435	527	delete entry;
duke@435	528	} else {
duke@435	529	entry->set_next(_free_entries);
duke@435	530	_free_entries = entry;
duke@435	531	_free_entries_count++;
duke@435	532	}
duke@435	533	}
duke@435	534
duke@435	535	// returns the tag map for the given environments. If the tag map
duke@435	536	// doesn't exist then it is created.
duke@435	537	JvmtiTagMap* JvmtiTagMap::tag_map_for(JvmtiEnv* env) {
duke@435	538	JvmtiTagMap* tag_map = ((JvmtiEnvBase *)env)->tag_map();
duke@435	539	if (tag_map == NULL) {
duke@435	540	MutexLocker mu(JvmtiThreadState_lock);
duke@435	541	tag_map = ((JvmtiEnvBase *)env)->tag_map();
duke@435	542	if (tag_map == NULL) {
duke@435	543	tag_map = new JvmtiTagMap(env);
duke@435	544	}
duke@435	545	} else {
duke@435	546	CHECK_UNHANDLED_OOPS_ONLY(Thread::current()->clear_unhandled_oops());
duke@435	547	}
duke@435	548	return tag_map;
duke@435	549	}
duke@435	550
duke@435	551	// iterate over all entries in the tag map.
duke@435	552	void JvmtiTagMap::entry_iterate(JvmtiTagHashmapEntryClosure* closure) {
duke@435	553	for (int i=0; i<n_hashmaps; i++) {
duke@435	554	JvmtiTagHashmap* hashmap = _hashmap[i];
duke@435	555	hashmap->entry_iterate(closure);
duke@435	556	}
duke@435	557	}
duke@435	558
duke@435	559	// returns true if the hashmaps are empty
duke@435	560	bool JvmtiTagMap::is_empty() {
duke@435	561	assert(SafepointSynchronize::is_at_safepoint() || is_locked(), "checking");
duke@435	562	assert(n_hashmaps == 2, "not implemented");
duke@435	563	return ((_hashmap[0]->entry_count() == 0) && (_hashmap[1]->entry_count() == 0));
duke@435	564	}
duke@435	565
duke@435	566
duke@435	567	// Return the tag value for an object, or 0 if the object is
duke@435	568	// not tagged
duke@435	569	//
duke@435	570	static inline jlong tag_for(JvmtiTagMap* tag_map, oop o) {
duke@435	571	JvmtiTagHashmapEntry* entry = tag_map->hashmap_for(o)->find(o);
duke@435	572	if (entry == NULL) {
duke@435	573	return 0;
duke@435	574	} else {
duke@435	575	return entry->tag();
duke@435	576	}
duke@435	577	}
duke@435	578
duke@435	579	// If the object is a java.lang.Class then return the klassOop,
duke@435	580	// otherwise return the original object
duke@435	581	static inline oop klassOop_if_java_lang_Class(oop o) {
never@1577	582	if (o->klass() == SystemDictionary::Class_klass()) {
duke@435	583	if (!java_lang_Class::is_primitive(o)) {
duke@435	584	o = (oop)java_lang_Class::as_klassOop(o);
duke@435	585	assert(o != NULL, "class for non-primitive mirror must exist");
duke@435	586	}
duke@435	587	}
duke@435	588	return o;
duke@435	589	}
duke@435	590
duke@435	591	// A CallbackWrapper is a support class for querying and tagging an object
duke@435	592	// around a callback to a profiler. The constructor does pre-callback
duke@435	593	// work to get the tag value, klass tag value, ... and the destructor
duke@435	594	// does the post-callback work of tagging or untagging the object.
duke@435	595	//
duke@435	596	// {
duke@435	597	// CallbackWrapper wrapper(tag_map, o);
duke@435	598	//
duke@435	599	// (*callback)(wrapper.klass_tag(), wrapper.obj_size(), wrapper.obj_tag_p(), ...)
duke@435	600	//
duke@435	601	// } // wrapper goes out of scope here which results in the destructor
duke@435	602	// checking to see if the object has been tagged, untagged, or the
duke@435	603	// tag value has changed.
duke@435	604	//
duke@435	605	class CallbackWrapper : public StackObj {
duke@435	606	private:
duke@435	607	JvmtiTagMap* _tag_map;
duke@435	608	JvmtiTagHashmap* _hashmap;
duke@435	609	JvmtiTagHashmapEntry* _entry;
duke@435	610	oop _o;
duke@435	611	jlong _obj_size;
duke@435	612	jlong _obj_tag;
duke@435	613	klassOop _klass; // the object's class
duke@435	614	jlong _klass_tag;
duke@435	615
duke@435	616	protected:
duke@435	617	JvmtiTagMap* tag_map() const { return _tag_map; }
duke@435	618
duke@435	619	// invoked post-callback to tag, untag, or update the tag of an object
duke@435	620	void inline post_callback_tag_update(oop o, JvmtiTagHashmap* hashmap,
duke@435	621	JvmtiTagHashmapEntry* entry, jlong obj_tag);
duke@435	622	public:
duke@435	623	CallbackWrapper(JvmtiTagMap* tag_map, oop o) {
duke@435	624	assert(Thread::current()->is_VM_thread() || tag_map->is_locked(),
duke@435	625	"MT unsafe or must be VM thread");
duke@435	626
duke@435	627	// for Classes the klassOop is tagged
duke@435	628	_o = klassOop_if_java_lang_Class(o);
duke@435	629
duke@435	630	// object size
duke@435	631	_obj_size = _o->size() * wordSize;
duke@435	632
duke@435	633	// record the context
duke@435	634	_tag_map = tag_map;
duke@435	635	_hashmap = tag_map->hashmap_for(_o);
duke@435	636	_entry = _hashmap->find(_o);
duke@435	637
duke@435	638	// get object tag
duke@435	639	_obj_tag = (_entry == NULL) ? 0 : _entry->tag();
duke@435	640
duke@435	641	// get the class and the class's tag value
duke@435	642	if (_o == o) {
duke@435	643	_klass = _o->klass();
duke@435	644	} else {
duke@435	645	// if the object represents a runtime class then use the
duke@435	646	// tag for java.lang.Class
never@1577	647	_klass = SystemDictionary::Class_klass();
duke@435	648	}
duke@435	649	_klass_tag = tag_for(tag_map, _klass);
duke@435	650	}
duke@435	651
duke@435	652	~CallbackWrapper() {
duke@435	653	post_callback_tag_update(_o, _hashmap, _entry, _obj_tag);
duke@435	654	}
duke@435	655
duke@435	656	inline jlong* obj_tag_p() { return &_obj_tag; }
duke@435	657	inline jlong obj_size() const { return _obj_size; }
duke@435	658	inline jlong obj_tag() const { return _obj_tag; }
duke@435	659	inline klassOop klass() const { return _klass; }
duke@435	660	inline jlong klass_tag() const { return _klass_tag; }
duke@435	661	};
duke@435	662
duke@435	663
duke@435	664
duke@435	665	// callback post-callback to tag, untag, or update the tag of an object
duke@435	666	void inline CallbackWrapper::post_callback_tag_update(oop o,
duke@435	667	JvmtiTagHashmap* hashmap,
duke@435	668	JvmtiTagHashmapEntry* entry,
duke@435	669	jlong obj_tag) {
duke@435	670	if (entry == NULL) {
duke@435	671	if (obj_tag != 0) {
duke@435	672	// callback has tagged the object
duke@435	673	assert(Thread::current()->is_VM_thread(), "must be VMThread");
duke@435	674	HandleMark hm;
duke@435	675	Handle h(o);
duke@435	676	jweak ref = JNIHandles::make_weak_global(h);
duke@435	677	entry = tag_map()->create_entry(ref, obj_tag);
duke@435	678	hashmap->add(o, entry);
duke@435	679	}
duke@435	680	} else {
duke@435	681	// object was previously tagged - the callback may have untagged
duke@435	682	// the object or changed the tag value
duke@435	683	if (obj_tag == 0) {
duke@435	684	jweak ref = entry->object();
duke@435	685
duke@435	686	JvmtiTagHashmapEntry* entry_removed = hashmap->remove(o);
duke@435	687	assert(entry_removed == entry, "checking");
duke@435	688	tag_map()->destroy_entry(entry);
duke@435	689
duke@435	690	JNIHandles::destroy_weak_global(ref);
duke@435	691	} else {
duke@435	692	if (obj_tag != entry->tag()) {
duke@435	693	entry->set_tag(obj_tag);
duke@435	694	}
duke@435	695	}
duke@435	696	}
duke@435	697	}
duke@435	698
duke@435	699	// An extended CallbackWrapper used when reporting an object reference
duke@435	700	// to the agent.
duke@435	701	//
duke@435	702	// {
duke@435	703	// TwoOopCallbackWrapper wrapper(tag_map, referrer, o);
duke@435	704	//
duke@435	705	// (*callback)(wrapper.klass_tag(),
duke@435	706	// wrapper.obj_size(),
duke@435	707	// wrapper.obj_tag_p()
duke@435	708	// wrapper.referrer_tag_p(), ...)
duke@435	709	//
duke@435	710	// } // wrapper goes out of scope here which results in the destructor
duke@435	711	// checking to see if the referrer object has been tagged, untagged,
duke@435	712	// or the tag value has changed.
duke@435	713	//
duke@435	714	class TwoOopCallbackWrapper : public CallbackWrapper {
duke@435	715	private:
duke@435	716	bool _is_reference_to_self;
duke@435	717	JvmtiTagHashmap* _referrer_hashmap;
duke@435	718	JvmtiTagHashmapEntry* _referrer_entry;
duke@435	719	oop _referrer;
duke@435	720	jlong _referrer_obj_tag;
duke@435	721	jlong _referrer_klass_tag;
duke@435	722	jlong* _referrer_tag_p;
duke@435	723
duke@435	724	bool is_reference_to_self() const { return _is_reference_to_self; }
duke@435	725
duke@435	726	public:
duke@435	727	TwoOopCallbackWrapper(JvmtiTagMap* tag_map, oop referrer, oop o) :
duke@435	728	CallbackWrapper(tag_map, o)
duke@435	729	{
duke@435	730	// self reference needs to be handled in a special way
duke@435	731	_is_reference_to_self = (referrer == o);
duke@435	732
duke@435	733	if (_is_reference_to_self) {
duke@435	734	_referrer_klass_tag = klass_tag();
duke@435	735	_referrer_tag_p = obj_tag_p();
duke@435	736	} else {
duke@435	737	// for Classes the klassOop is tagged
duke@435	738	_referrer = klassOop_if_java_lang_Class(referrer);
duke@435	739	// record the context
duke@435	740	_referrer_hashmap = tag_map->hashmap_for(_referrer);
duke@435	741	_referrer_entry = _referrer_hashmap->find(_referrer);
duke@435	742
duke@435	743	// get object tag
duke@435	744	_referrer_obj_tag = (_referrer_entry == NULL) ? 0 : _referrer_entry->tag();
duke@435	745	_referrer_tag_p = &_referrer_obj_tag;
duke@435	746
duke@435	747	// get referrer class tag.
duke@435	748	klassOop k = (_referrer == referrer) ? // Check if referrer is a class...
duke@435	749	_referrer->klass() // No, just get its class
never@1577	750	: SystemDictionary::Class_klass(); // Yes, its class is Class
duke@435	751	_referrer_klass_tag = tag_for(tag_map, k);
duke@435	752	}
duke@435	753	}
duke@435	754
duke@435	755	~TwoOopCallbackWrapper() {
duke@435	756	if (!is_reference_to_self()){
duke@435	757	post_callback_tag_update(_referrer,
duke@435	758	_referrer_hashmap,
duke@435	759	_referrer_entry,
duke@435	760	_referrer_obj_tag);
duke@435	761	}
duke@435	762	}
duke@435	763
duke@435	764	// address of referrer tag
duke@435	765	// (for a self reference this will return the same thing as obj_tag_p())
duke@435	766	inline jlong* referrer_tag_p() { return _referrer_tag_p; }
duke@435	767
duke@435	768	// referrer's class tag
duke@435	769	inline jlong referrer_klass_tag() { return _referrer_klass_tag; }
duke@435	770	};
duke@435	771
duke@435	772	// tag an object
duke@435	773	//
duke@435	774	// This function is performance critical. If many threads attempt to tag objects
duke@435	775	// around the same time then it's possible that the Mutex associated with the
duke@435	776	// tag map will be a hot lock. Eliminating this lock will not eliminate the issue
duke@435	777	// because creating a JNI weak reference requires acquiring a global lock also.
duke@435	778	void JvmtiTagMap::set_tag(jobject object, jlong tag) {
duke@435	779	MutexLocker ml(lock());
duke@435	780
duke@435	781	// resolve the object
duke@435	782	oop o = JNIHandles::resolve_non_null(object);
duke@435	783
duke@435	784	// for Classes we tag the klassOop
duke@435	785	o = klassOop_if_java_lang_Class(o);
duke@435	786
duke@435	787	// see if the object is already tagged
duke@435	788	JvmtiTagHashmap* hashmap = hashmap_for(o);
duke@435	789	JvmtiTagHashmapEntry* entry = hashmap->find(o);
duke@435	790
duke@435	791	// if the object is not already tagged then we tag it
duke@435	792	if (entry == NULL) {
duke@435	793	if (tag != 0) {
duke@435	794	HandleMark hm;
duke@435	795	Handle h(o);
duke@435	796	jweak ref = JNIHandles::make_weak_global(h);
duke@435	797
duke@435	798	// the object may have moved because make_weak_global may
duke@435	799	// have blocked - thus it is necessary resolve the handle
duke@435	800	// and re-hash the object.
duke@435	801	o = h();
duke@435	802	entry = create_entry(ref, tag);
duke@435	803	hashmap_for(o)->add(o, entry);
duke@435	804	} else {
duke@435	805	// no-op
duke@435	806	}
duke@435	807	} else {
duke@435	808	// if the object is already tagged then we either update
duke@435	809	// the tag (if a new tag value has been provided)
duke@435	810	// or remove the object if the new tag value is 0.
duke@435	811	// Removing the object requires that we also delete the JNI
duke@435	812	// weak ref to the object.
duke@435	813	if (tag == 0) {
duke@435	814	jweak ref = entry->object();
duke@435	815	hashmap->remove(o);
duke@435	816	destroy_entry(entry);
duke@435	817	JNIHandles::destroy_weak_global(ref);
duke@435	818	} else {
duke@435	819	entry->set_tag(tag);
duke@435	820	}
duke@435	821	}
duke@435	822	}
duke@435	823
duke@435	824	// get the tag for an object
duke@435	825	jlong JvmtiTagMap::get_tag(jobject object) {
duke@435	826	MutexLocker ml(lock());
duke@435	827
duke@435	828	// resolve the object
duke@435	829	oop o = JNIHandles::resolve_non_null(object);
duke@435	830
duke@435	831	// for Classes get the tag from the klassOop
duke@435	832	return tag_for(this, klassOop_if_java_lang_Class(o));
duke@435	833	}
duke@435	834
duke@435	835
duke@435	836	// Helper class used to describe the static or instance fields of a class.
duke@435	837	// For each field it holds the field index (as defined by the JVMTI specification),
duke@435	838	// the field type, and the offset.
duke@435	839
duke@435	840	class ClassFieldDescriptor: public CHeapObj {
duke@435	841	private:
duke@435	842	int _field_index;
duke@435	843	int _field_offset;
duke@435	844	char _field_type;
duke@435	845	public:
duke@435	846	ClassFieldDescriptor(int index, char type, int offset) :
duke@435	847	_field_index(index), _field_type(type), _field_offset(offset) {
duke@435	848	}
duke@435	849	int field_index() const { return _field_index; }
duke@435	850	char field_type() const { return _field_type; }
duke@435	851	int field_offset() const { return _field_offset; }
duke@435	852	};
duke@435	853
duke@435	854	class ClassFieldMap: public CHeapObj {
duke@435	855	private:
duke@435	856	enum {
duke@435	857	initial_field_count = 5
duke@435	858	};
duke@435	859
duke@435	860	// list of field descriptors
duke@435	861	GrowableArray<ClassFieldDescriptor*>* _fields;
duke@435	862
duke@435	863	// constructor
duke@435	864	ClassFieldMap();
duke@435	865
duke@435	866	// add a field
duke@435	867	void add(int index, char type, int offset);
duke@435	868
duke@435	869	// returns the field count for the given class
duke@435	870	static int compute_field_count(instanceKlassHandle ikh);
duke@435	871
duke@435	872	public:
duke@435	873	~ClassFieldMap();
duke@435	874
duke@435	875	// access
duke@435	876	int field_count() { return _fields->length(); }
duke@435	877	ClassFieldDescriptor* field_at(int i) { return _fields->at(i); }
duke@435	878
duke@435	879	// functions to create maps of static or instance fields
duke@435	880	static ClassFieldMap* create_map_of_static_fields(klassOop k);
duke@435	881	static ClassFieldMap* create_map_of_instance_fields(oop obj);
duke@435	882	};
duke@435	883
duke@435	884	ClassFieldMap::ClassFieldMap() {
duke@435	885	_fields = new (ResourceObj::C_HEAP) GrowableArray<ClassFieldDescriptor*>(initial_field_count, true);
duke@435	886	}
duke@435	887
duke@435	888	ClassFieldMap::~ClassFieldMap() {
duke@435	889	for (int i=0; i<_fields->length(); i++) {
duke@435	890	delete _fields->at(i);
duke@435	891	}
duke@435	892	delete _fields;
duke@435	893	}
duke@435	894
duke@435	895	void ClassFieldMap::add(int index, char type, int offset) {
duke@435	896	ClassFieldDescriptor* field = new ClassFieldDescriptor(index, type, offset);
duke@435	897	_fields->append(field);
duke@435	898	}
duke@435	899
duke@435	900	// Returns a heap allocated ClassFieldMap to describe the static fields
duke@435	901	// of the given class.
duke@435	902	//
duke@435	903	ClassFieldMap* ClassFieldMap::create_map_of_static_fields(klassOop k) {
duke@435	904	HandleMark hm;
duke@435	905	instanceKlassHandle ikh = instanceKlassHandle(Thread::current(), k);
duke@435	906
duke@435	907	// create the field map
duke@435	908	ClassFieldMap* field_map = new ClassFieldMap();
duke@435	909
duke@435	910	FilteredFieldStream f(ikh, false, false);
duke@435	911	int max_field_index = f.field_count()-1;
duke@435	912
duke@435	913	int index = 0;
duke@435	914	for (FilteredFieldStream fld(ikh, true, true); !fld.eos(); fld.next(), index++) {
duke@435	915	// ignore instance fields
duke@435	916	if (!fld.access_flags().is_static()) {
duke@435	917	continue;
duke@435	918	}
duke@435	919	field_map->add(max_field_index - index, fld.signature()->byte_at(0), fld.offset());
duke@435	920	}
duke@435	921	return field_map;
duke@435	922	}
duke@435	923
duke@435	924	// Returns a heap allocated ClassFieldMap to describe the instance fields
duke@435	925	// of the given class. All instance fields are included (this means public
duke@435	926	// and private fields declared in superclasses and superinterfaces too).
duke@435	927	//
duke@435	928	ClassFieldMap* ClassFieldMap::create_map_of_instance_fields(oop obj) {
duke@435	929	HandleMark hm;
duke@435	930	instanceKlassHandle ikh = instanceKlassHandle(Thread::current(), obj->klass());
duke@435	931
duke@435	932	// create the field map
duke@435	933	ClassFieldMap* field_map = new ClassFieldMap();
duke@435	934
duke@435	935	FilteredFieldStream f(ikh, false, false);
duke@435	936
duke@435	937	int max_field_index = f.field_count()-1;
duke@435	938
duke@435	939	int index = 0;
duke@435	940	for (FilteredFieldStream fld(ikh, false, false); !fld.eos(); fld.next(), index++) {
duke@435	941	// ignore static fields
duke@435	942	if (fld.access_flags().is_static()) {
duke@435	943	continue;
duke@435	944	}
duke@435	945	field_map->add(max_field_index - index, fld.signature()->byte_at(0), fld.offset());
duke@435	946	}
duke@435	947
duke@435	948	return field_map;
duke@435	949	}
duke@435	950
duke@435	951	// Helper class used to cache a ClassFileMap for the instance fields of
duke@435	952	// a cache. A JvmtiCachedClassFieldMap can be cached by an instanceKlass during
duke@435	953	// heap iteration and avoid creating a field map for each object in the heap
duke@435	954	// (only need to create the map when the first instance of a class is encountered).
duke@435	955	//
duke@435	956	class JvmtiCachedClassFieldMap : public CHeapObj {
duke@435	957	private:
duke@435	958	enum {
duke@435	959	initial_class_count = 200
duke@435	960	};
duke@435	961	ClassFieldMap* _field_map;
duke@435	962
duke@435	963	ClassFieldMap* field_map() const { return _field_map; }
duke@435	964
duke@435	965	JvmtiCachedClassFieldMap(ClassFieldMap* field_map);
duke@435	966	~JvmtiCachedClassFieldMap();
duke@435	967
duke@435	968	static GrowableArray<instanceKlass*>* _class_list;
duke@435	969	static void add_to_class_list(instanceKlass* ik);
duke@435	970
duke@435	971	public:
duke@435	972	// returns the field map for a given object (returning map cached
duke@435	973	// by instanceKlass if possible
duke@435	974	static ClassFieldMap* get_map_of_instance_fields(oop obj);
duke@435	975
duke@435	976	// removes the field map from all instanceKlasses - should be
duke@435	977	// called before VM operation completes
duke@435	978	static void clear_cache();
duke@435	979
duke@435	980	// returns the number of ClassFieldMap cached by instanceKlasses
duke@435	981	static int cached_field_map_count();
duke@435	982	};
duke@435	983
duke@435	984	GrowableArray<instanceKlass*>* JvmtiCachedClassFieldMap::_class_list;
duke@435	985
duke@435	986	JvmtiCachedClassFieldMap::JvmtiCachedClassFieldMap(ClassFieldMap* field_map) {
duke@435	987	_field_map = field_map;
duke@435	988	}
duke@435	989
duke@435	990	JvmtiCachedClassFieldMap::~JvmtiCachedClassFieldMap() {
duke@435	991	if (_field_map != NULL) {
duke@435	992	delete _field_map;
duke@435	993	}
duke@435	994	}
duke@435	995
duke@435	996	// Marker class to ensure that the class file map cache is only used in a defined
duke@435	997	// scope.
duke@435	998	class ClassFieldMapCacheMark : public StackObj {
duke@435	999	private:
duke@435	1000	static bool _is_active;
duke@435	1001	public:
duke@435	1002	ClassFieldMapCacheMark() {
duke@435	1003	assert(Thread::current()->is_VM_thread(), "must be VMThread");
duke@435	1004	assert(JvmtiCachedClassFieldMap::cached_field_map_count() == 0, "cache not empty");
duke@435	1005	assert(!_is_active, "ClassFieldMapCacheMark cannot be nested");
duke@435	1006	_is_active = true;
duke@435	1007	}
duke@435	1008	~ClassFieldMapCacheMark() {
duke@435	1009	JvmtiCachedClassFieldMap::clear_cache();
duke@435	1010	_is_active = false;
duke@435	1011	}
duke@435	1012	static bool is_active() { return _is_active; }
duke@435	1013	};
duke@435	1014
duke@435	1015	bool ClassFieldMapCacheMark::_is_active;
duke@435	1016
duke@435	1017
duke@435	1018	// record that the given instanceKlass is caching a field map
duke@435	1019	void JvmtiCachedClassFieldMap::add_to_class_list(instanceKlass* ik) {
duke@435	1020	if (_class_list == NULL) {
duke@435	1021	_class_list = new (ResourceObj::C_HEAP) GrowableArray<instanceKlass*>(initial_class_count, true);
duke@435	1022	}
duke@435	1023	_class_list->push(ik);
duke@435	1024	}
duke@435	1025
duke@435	1026	// returns the instance field map for the given object
duke@435	1027	// (returns field map cached by the instanceKlass if possible)
duke@435	1028	ClassFieldMap* JvmtiCachedClassFieldMap::get_map_of_instance_fields(oop obj) {
duke@435	1029	assert(Thread::current()->is_VM_thread(), "must be VMThread");
duke@435	1030	assert(ClassFieldMapCacheMark::is_active(), "ClassFieldMapCacheMark not active");
duke@435	1031
duke@435	1032	klassOop k = obj->klass();
duke@435	1033	instanceKlass* ik = instanceKlass::cast(k);
duke@435	1034
duke@435	1035	// return cached map if possible
duke@435	1036	JvmtiCachedClassFieldMap* cached_map = ik->jvmti_cached_class_field_map();
duke@435	1037	if (cached_map != NULL) {
duke@435	1038	assert(cached_map->field_map() != NULL, "missing field list");
duke@435	1039	return cached_map->field_map();
duke@435	1040	} else {
duke@435	1041	ClassFieldMap* field_map = ClassFieldMap::create_map_of_instance_fields(obj);
duke@435	1042	cached_map = new JvmtiCachedClassFieldMap(field_map);
duke@435	1043	ik->set_jvmti_cached_class_field_map(cached_map);
duke@435	1044	add_to_class_list(ik);
duke@435	1045	return field_map;
duke@435	1046	}
duke@435	1047	}
duke@435	1048
duke@435	1049	// remove the fields maps cached from all instanceKlasses
duke@435	1050	void JvmtiCachedClassFieldMap::clear_cache() {
duke@435	1051	assert(Thread::current()->is_VM_thread(), "must be VMThread");
duke@435	1052	if (_class_list != NULL) {
duke@435	1053	for (int i = 0; i < _class_list->length(); i++) {
duke@435	1054	instanceKlass* ik = _class_list->at(i);
duke@435	1055	JvmtiCachedClassFieldMap* cached_map = ik->jvmti_cached_class_field_map();
duke@435	1056	assert(cached_map != NULL, "should not be NULL");
duke@435	1057	ik->set_jvmti_cached_class_field_map(NULL);
duke@435	1058	delete cached_map; // deletes the encapsulated field map
duke@435	1059	}
duke@435	1060	delete _class_list;
duke@435	1061	_class_list = NULL;
duke@435	1062	}
duke@435	1063	}
duke@435	1064
duke@435	1065	// returns the number of ClassFieldMap cached by instanceKlasses
duke@435	1066	int JvmtiCachedClassFieldMap::cached_field_map_count() {
duke@435	1067	return (_class_list == NULL) ? 0 : _class_list->length();
duke@435	1068	}
duke@435	1069
duke@435	1070	// helper function to indicate if an object is filtered by its tag or class tag
duke@435	1071	static inline bool is_filtered_by_heap_filter(jlong obj_tag,
duke@435	1072	jlong klass_tag,
duke@435	1073	int heap_filter) {
duke@435	1074	// apply the heap filter
duke@435	1075	if (obj_tag != 0) {
duke@435	1076	// filter out tagged objects
duke@435	1077	if (heap_filter & JVMTI_HEAP_FILTER_TAGGED) return true;
duke@435	1078	} else {
duke@435	1079	// filter out untagged objects
duke@435	1080	if (heap_filter & JVMTI_HEAP_FILTER_UNTAGGED) return true;
duke@435	1081	}
duke@435	1082	if (klass_tag != 0) {
duke@435	1083	// filter out objects with tagged classes
duke@435	1084	if (heap_filter & JVMTI_HEAP_FILTER_CLASS_TAGGED) return true;
duke@435	1085	} else {
duke@435	1086	// filter out objects with untagged classes.
duke@435	1087	if (heap_filter & JVMTI_HEAP_FILTER_CLASS_UNTAGGED) return true;
duke@435	1088	}
duke@435	1089	return false;
duke@435	1090	}
duke@435	1091
duke@435	1092	// helper function to indicate if an object is filtered by a klass filter
duke@435	1093	static inline bool is_filtered_by_klass_filter(oop obj, KlassHandle klass_filter) {
duke@435	1094	if (!klass_filter.is_null()) {
duke@435	1095	if (obj->klass() != klass_filter()) {
duke@435	1096	return true;
duke@435	1097	}
duke@435	1098	}
duke@435	1099	return false;
duke@435	1100	}
duke@435	1101
duke@435	1102	// helper function to tell if a field is a primitive field or not
duke@435	1103	static inline bool is_primitive_field_type(char type) {
duke@435	1104	return (type != 'L' && type != '[');
duke@435	1105	}
duke@435	1106
duke@435	1107	// helper function to copy the value from location addr to jvalue.
duke@435	1108	static inline void copy_to_jvalue(jvalue *v, address addr, jvmtiPrimitiveType value_type) {
duke@435	1109	switch (value_type) {
duke@435	1110	case JVMTI_PRIMITIVE_TYPE_BOOLEAN : { v->z = *(jboolean*)addr; break; }
duke@435	1111	case JVMTI_PRIMITIVE_TYPE_BYTE : { v->b = *(jbyte*)addr; break; }
duke@435	1112	case JVMTI_PRIMITIVE_TYPE_CHAR : { v->c = *(jchar*)addr; break; }
duke@435	1113	case JVMTI_PRIMITIVE_TYPE_SHORT : { v->s = *(jshort*)addr; break; }
duke@435	1114	case JVMTI_PRIMITIVE_TYPE_INT : { v->i = *(jint*)addr; break; }
duke@435	1115	case JVMTI_PRIMITIVE_TYPE_LONG : { v->j = *(jlong*)addr; break; }
duke@435	1116	case JVMTI_PRIMITIVE_TYPE_FLOAT : { v->f = *(jfloat*)addr; break; }
duke@435	1117	case JVMTI_PRIMITIVE_TYPE_DOUBLE : { v->d = *(jdouble*)addr; break; }
duke@435	1118	default: ShouldNotReachHere();
duke@435	1119	}
duke@435	1120	}
duke@435	1121
duke@435	1122	// helper function to invoke string primitive value callback
duke@435	1123	// returns visit control flags
duke@435	1124	static jint invoke_string_value_callback(jvmtiStringPrimitiveValueCallback cb,
duke@435	1125	CallbackWrapper* wrapper,
duke@435	1126	oop str,
duke@435	1127	void* user_data)
duke@435	1128	{
never@1577	1129	assert(str->klass() == SystemDictionary::String_klass(), "not a string");
duke@435	1130
duke@435	1131	// get the string value and length
duke@435	1132	// (string value may be offset from the base)
duke@435	1133	int s_len = java_lang_String::length(str);
duke@435	1134	typeArrayOop s_value = java_lang_String::value(str);
duke@435	1135	int s_offset = java_lang_String::offset(str);
duke@435	1136	jchar* value;
duke@435	1137	if (s_len > 0) {
duke@435	1138	value = s_value->char_at_addr(s_offset);
duke@435	1139	} else {
duke@435	1140	value = (jchar*) s_value->base(T_CHAR);
duke@435	1141	}
duke@435	1142
duke@435	1143	// invoke the callback
duke@435	1144	return (*cb)(wrapper->klass_tag(),
duke@435	1145	wrapper->obj_size(),
duke@435	1146	wrapper->obj_tag_p(),
duke@435	1147	value,
duke@435	1148	(jint)s_len,
duke@435	1149	user_data);
duke@435	1150	}
duke@435	1151
duke@435	1152	// helper function to invoke string primitive value callback
duke@435	1153	// returns visit control flags
duke@435	1154	static jint invoke_array_primitive_value_callback(jvmtiArrayPrimitiveValueCallback cb,
duke@435	1155	CallbackWrapper* wrapper,
duke@435	1156	oop obj,
duke@435	1157	void* user_data)
duke@435	1158	{
duke@435	1159	assert(obj->is_typeArray(), "not a primitive array");
duke@435	1160
duke@435	1161	// get base address of first element
duke@435	1162	typeArrayOop array = typeArrayOop(obj);
duke@435	1163	BasicType type = typeArrayKlass::cast(array->klass())->element_type();
duke@435	1164	void* elements = array->base(type);
duke@435	1165
duke@435	1166	// jvmtiPrimitiveType is defined so this mapping is always correct
duke@435	1167	jvmtiPrimitiveType elem_type = (jvmtiPrimitiveType)type2char(type);
duke@435	1168
duke@435	1169	return (*cb)(wrapper->klass_tag(),
duke@435	1170	wrapper->obj_size(),
duke@435	1171	wrapper->obj_tag_p(),
duke@435	1172	(jint)array->length(),
duke@435	1173	elem_type,
duke@435	1174	elements,
duke@435	1175	user_data);
duke@435	1176	}
duke@435	1177
duke@435	1178	// helper function to invoke the primitive field callback for all static fields
duke@435	1179	// of a given class
duke@435	1180	static jint invoke_primitive_field_callback_for_static_fields
duke@435	1181	(CallbackWrapper* wrapper,
duke@435	1182	oop obj,
duke@435	1183	jvmtiPrimitiveFieldCallback cb,
duke@435	1184	void* user_data)
duke@435	1185	{
duke@435	1186	// for static fields only the index will be set
duke@435	1187	static jvmtiHeapReferenceInfo reference_info = { 0 };
duke@435	1188
never@1577	1189	assert(obj->klass() == SystemDictionary::Class_klass(), "not a class");
duke@435	1190	if (java_lang_Class::is_primitive(obj)) {
duke@435	1191	return 0;
duke@435	1192	}
duke@435	1193	klassOop k = java_lang_Class::as_klassOop(obj);
duke@435	1194	Klass* klass = k->klass_part();
duke@435	1195
duke@435	1196	// ignore classes for object and type arrays
duke@435	1197	if (!klass->oop_is_instance()) {
duke@435	1198	return 0;
duke@435	1199	}
duke@435	1200
duke@435	1201	// ignore classes which aren't linked yet
duke@435	1202	instanceKlass* ik = instanceKlass::cast(k);
duke@435	1203	if (!ik->is_linked()) {
duke@435	1204	return 0;
duke@435	1205	}
duke@435	1206
duke@435	1207	// get the field map
duke@435	1208	ClassFieldMap* field_map = ClassFieldMap::create_map_of_static_fields(k);
duke@435	1209
duke@435	1210	// invoke the callback for each static primitive field
duke@435	1211	for (int i=0; i<field_map->field_count(); i++) {
duke@435	1212	ClassFieldDescriptor* field = field_map->field_at(i);
duke@435	1213
duke@435	1214	// ignore non-primitive fields
duke@435	1215	char type = field->field_type();
duke@435	1216	if (!is_primitive_field_type(type)) {
duke@435	1217	continue;
duke@435	1218	}
duke@435	1219	// one-to-one mapping
duke@435	1220	jvmtiPrimitiveType value_type = (jvmtiPrimitiveType)type;
duke@435	1221
duke@435	1222	// get offset and field value
duke@435	1223	int offset = field->field_offset();
duke@435	1224	address addr = (address)k + offset;
duke@435	1225	jvalue value;
duke@435	1226	copy_to_jvalue(&value, addr, value_type);
duke@435	1227
duke@435	1228	// field index
duke@435	1229	reference_info.field.index = field->field_index();
duke@435	1230
duke@435	1231	// invoke the callback
duke@435	1232	jint res = (*cb)(JVMTI_HEAP_REFERENCE_STATIC_FIELD,
duke@435	1233	&reference_info,
duke@435	1234	wrapper->klass_tag(),
duke@435	1235	wrapper->obj_tag_p(),
duke@435	1236	value,
duke@435	1237	value_type,
duke@435	1238	user_data);
duke@435	1239	if (res & JVMTI_VISIT_ABORT) {
duke@435	1240	delete field_map;
duke@435	1241	return res;
duke@435	1242	}
duke@435	1243	}
duke@435	1244
duke@435	1245	delete field_map;
duke@435	1246	return 0;
duke@435	1247	}
duke@435	1248
duke@435	1249	// helper function to invoke the primitive field callback for all instance fields
duke@435	1250	// of a given object
duke@435	1251	static jint invoke_primitive_field_callback_for_instance_fields(
duke@435	1252	CallbackWrapper* wrapper,
duke@435	1253	oop obj,
duke@435	1254	jvmtiPrimitiveFieldCallback cb,
duke@435	1255	void* user_data)
duke@435	1256	{
duke@435	1257	// for instance fields only the index will be set
duke@435	1258	static jvmtiHeapReferenceInfo reference_info = { 0 };
duke@435	1259
duke@435	1260	// get the map of the instance fields
duke@435	1261	ClassFieldMap* fields = JvmtiCachedClassFieldMap::get_map_of_instance_fields(obj);
duke@435	1262
duke@435	1263	// invoke the callback for each instance primitive field
duke@435	1264	for (int i=0; i<fields->field_count(); i++) {
duke@435	1265	ClassFieldDescriptor* field = fields->field_at(i);
duke@435	1266
duke@435	1267	// ignore non-primitive fields
duke@435	1268	char type = field->field_type();
duke@435	1269	if (!is_primitive_field_type(type)) {
duke@435	1270	continue;
duke@435	1271	}
duke@435	1272	// one-to-one mapping
duke@435	1273	jvmtiPrimitiveType value_type = (jvmtiPrimitiveType)type;
duke@435	1274
duke@435	1275	// get offset and field value
duke@435	1276	int offset = field->field_offset();
duke@435	1277	address addr = (address)obj + offset;
duke@435	1278	jvalue value;
duke@435	1279	copy_to_jvalue(&value, addr, value_type);
duke@435	1280
duke@435	1281	// field index
duke@435	1282	reference_info.field.index = field->field_index();
duke@435	1283
duke@435	1284	// invoke the callback
duke@435	1285	jint res = (*cb)(JVMTI_HEAP_REFERENCE_FIELD,
duke@435	1286	&reference_info,
duke@435	1287	wrapper->klass_tag(),
duke@435	1288	wrapper->obj_tag_p(),
duke@435	1289	value,
duke@435	1290	value_type,
duke@435	1291	user_data);
duke@435	1292	if (res & JVMTI_VISIT_ABORT) {
duke@435	1293	return res;
duke@435	1294	}
duke@435	1295	}
duke@435	1296	return 0;
duke@435	1297	}
duke@435	1298
duke@435	1299
duke@435	1300	// VM operation to iterate over all objects in the heap (both reachable
duke@435	1301	// and unreachable)
duke@435	1302	class VM_HeapIterateOperation: public VM_Operation {
duke@435	1303	private:
duke@435	1304	ObjectClosure* _blk;
duke@435	1305	public:
duke@435	1306	VM_HeapIterateOperation(ObjectClosure* blk) { _blk = blk; }
duke@435	1307
duke@435	1308	VMOp_Type type() const { return VMOp_HeapIterateOperation; }
duke@435	1309	void doit() {
duke@435	1310	// allows class files maps to be cached during iteration
duke@435	1311	ClassFieldMapCacheMark cm;
duke@435	1312
duke@435	1313	// make sure that heap is parsable (fills TLABs with filler objects)
duke@435	1314	Universe::heap()->ensure_parsability(false); // no need to retire TLABs
duke@435	1315
duke@435	1316	// Verify heap before iteration - if the heap gets corrupted then
duke@435	1317	// JVMTI's IterateOverHeap will crash.
duke@435	1318	if (VerifyBeforeIteration) {
duke@435	1319	Universe::verify();
duke@435	1320	}
duke@435	1321
duke@435	1322	// do the iteration
jmasa@952	1323	// If this operation encounters a bad object when using CMS,
jmasa@952	1324	// consider using safe_object_iterate() which avoids perm gen
jmasa@952	1325	// objects that may contain bad references.
duke@435	1326	Universe::heap()->object_iterate(_blk);
duke@435	1327
duke@435	1328	// when sharing is enabled we must iterate over the shared spaces
duke@435	1329	if (UseSharedSpaces) {
duke@435	1330	GenCollectedHeap* gch = GenCollectedHeap::heap();
duke@435	1331	CompactingPermGenGen* gen = (CompactingPermGenGen*)gch->perm_gen();
duke@435	1332	gen->ro_space()->object_iterate(_blk);
duke@435	1333	gen->rw_space()->object_iterate(_blk);
duke@435	1334	}
duke@435	1335	}
duke@435	1336
duke@435	1337	};
duke@435	1338
duke@435	1339
duke@435	1340	// An ObjectClosure used to support the deprecated IterateOverHeap and
duke@435	1341	// IterateOverInstancesOfClass functions
duke@435	1342	class IterateOverHeapObjectClosure: public ObjectClosure {
duke@435	1343	private:
duke@435	1344	JvmtiTagMap* _tag_map;
duke@435	1345	KlassHandle _klass;
duke@435	1346	jvmtiHeapObjectFilter _object_filter;
duke@435	1347	jvmtiHeapObjectCallback _heap_object_callback;
duke@435	1348	const void* _user_data;
duke@435	1349
duke@435	1350	// accessors
duke@435	1351	JvmtiTagMap* tag_map() const { return _tag_map; }
duke@435	1352	jvmtiHeapObjectFilter object_filter() const { return _object_filter; }
duke@435	1353	jvmtiHeapObjectCallback object_callback() const { return _heap_object_callback; }
duke@435	1354	KlassHandle klass() const { return _klass; }
duke@435	1355	const void* user_data() const { return _user_data; }
duke@435	1356
duke@435	1357	// indicates if iteration has been aborted
duke@435	1358	bool _iteration_aborted;
duke@435	1359	bool is_iteration_aborted() const { return _iteration_aborted; }
duke@435	1360	void set_iteration_aborted(bool aborted) { _iteration_aborted = aborted; }
duke@435	1361
duke@435	1362	public:
duke@435	1363	IterateOverHeapObjectClosure(JvmtiTagMap* tag_map,
duke@435	1364	KlassHandle klass,
duke@435	1365	jvmtiHeapObjectFilter object_filter,
duke@435	1366	jvmtiHeapObjectCallback heap_object_callback,
duke@435	1367	const void* user_data) :
duke@435	1368	_tag_map(tag_map),
duke@435	1369	_klass(klass),
duke@435	1370	_object_filter(object_filter),
duke@435	1371	_heap_object_callback(heap_object_callback),
duke@435	1372	_user_data(user_data),
duke@435	1373	_iteration_aborted(false)
duke@435	1374	{
duke@435	1375	}
duke@435	1376
duke@435	1377	void do_object(oop o);
duke@435	1378	};
duke@435	1379
duke@435	1380	// invoked for each object in the heap
duke@435	1381	void IterateOverHeapObjectClosure::do_object(oop o) {
duke@435	1382	// check if iteration has been halted
duke@435	1383	if (is_iteration_aborted()) return;
duke@435	1384
duke@435	1385	// ignore any objects that aren't visible to profiler
duke@435	1386	if (!ServiceUtil::visible_oop(o)) return;
duke@435	1387
duke@435	1388	// instanceof check when filtering by klass
duke@435	1389	if (!klass().is_null() && !o->is_a(klass()())) {
duke@435	1390	return;
duke@435	1391	}
duke@435	1392	// prepare for the calllback
duke@435	1393	CallbackWrapper wrapper(tag_map(), o);
duke@435	1394
duke@435	1395	// if the object is tagged and we're only interested in untagged objects
duke@435	1396	// then don't invoke the callback. Similiarly, if the object is untagged
duke@435	1397	// and we're only interested in tagged objects we skip the callback.
duke@435	1398	if (wrapper.obj_tag() != 0) {
duke@435	1399	if (object_filter() == JVMTI_HEAP_OBJECT_UNTAGGED) return;
duke@435	1400	} else {
duke@435	1401	if (object_filter() == JVMTI_HEAP_OBJECT_TAGGED) return;
duke@435	1402	}
duke@435	1403
duke@435	1404	// invoke the agent's callback
duke@435	1405	jvmtiIterationControl control = (*object_callback())(wrapper.klass_tag(),
duke@435	1406	wrapper.obj_size(),
duke@435	1407	wrapper.obj_tag_p(),
duke@435	1408	(void*)user_data());
duke@435	1409	if (control == JVMTI_ITERATION_ABORT) {
duke@435	1410	set_iteration_aborted(true);
duke@435	1411	}
duke@435	1412	}
duke@435	1413
duke@435	1414	// An ObjectClosure used to support the IterateThroughHeap function
duke@435	1415	class IterateThroughHeapObjectClosure: public ObjectClosure {
duke@435	1416	private:
duke@435	1417	JvmtiTagMap* _tag_map;
duke@435	1418	KlassHandle _klass;
duke@435	1419	int _heap_filter;
duke@435	1420	const jvmtiHeapCallbacks* _callbacks;
duke@435	1421	const void* _user_data;
duke@435	1422
duke@435	1423	// accessor functions
duke@435	1424	JvmtiTagMap* tag_map() const { return _tag_map; }
duke@435	1425	int heap_filter() const { return _heap_filter; }
duke@435	1426	const jvmtiHeapCallbacks* callbacks() const { return _callbacks; }
duke@435	1427	KlassHandle klass() const { return _klass; }
duke@435	1428	const void* user_data() const { return _user_data; }
duke@435	1429
duke@435	1430	// indicates if the iteration has been aborted
duke@435	1431	bool _iteration_aborted;
duke@435	1432	bool is_iteration_aborted() const { return _iteration_aborted; }
duke@435	1433
duke@435	1434	// used to check the visit control flags. If the abort flag is set
duke@435	1435	// then we set the iteration aborted flag so that the iteration completes
duke@435	1436	// without processing any further objects
duke@435	1437	bool check_flags_for_abort(jint flags) {
duke@435	1438	bool is_abort = (flags & JVMTI_VISIT_ABORT) != 0;
duke@435	1439	if (is_abort) {
duke@435	1440	_iteration_aborted = true;
duke@435	1441	}
duke@435	1442	return is_abort;
duke@435	1443	}
duke@435	1444
duke@435	1445	public:
duke@435	1446	IterateThroughHeapObjectClosure(JvmtiTagMap* tag_map,
duke@435	1447	KlassHandle klass,
duke@435	1448	int heap_filter,
duke@435	1449	const jvmtiHeapCallbacks* heap_callbacks,
duke@435	1450	const void* user_data) :
duke@435	1451	_tag_map(tag_map),
duke@435	1452	_klass(klass),
duke@435	1453	_heap_filter(heap_filter),
duke@435	1454	_callbacks(heap_callbacks),
duke@435	1455	_user_data(user_data),
duke@435	1456	_iteration_aborted(false)
duke@435	1457	{
duke@435	1458	}
duke@435	1459
duke@435	1460	void do_object(oop o);
duke@435	1461	};
duke@435	1462
duke@435	1463	// invoked for each object in the heap
duke@435	1464	void IterateThroughHeapObjectClosure::do_object(oop obj) {
duke@435	1465	// check if iteration has been halted
duke@435	1466	if (is_iteration_aborted()) return;
duke@435	1467
duke@435	1468	// ignore any objects that aren't visible to profiler
duke@435	1469	if (!ServiceUtil::visible_oop(obj)) return;
duke@435	1470
duke@435	1471	// apply class filter
duke@435	1472	if (is_filtered_by_klass_filter(obj, klass())) return;
duke@435	1473
duke@435	1474	// prepare for callback
duke@435	1475	CallbackWrapper wrapper(tag_map(), obj);
duke@435	1476
duke@435	1477	// check if filtered by the heap filter
duke@435	1478	if (is_filtered_by_heap_filter(wrapper.obj_tag(), wrapper.klass_tag(), heap_filter())) {
duke@435	1479	return;
duke@435	1480	}
duke@435	1481
duke@435	1482	// for arrays we need the length, otherwise -1
duke@435	1483	bool is_array = obj->is_array();
duke@435	1484	int len = is_array ? arrayOop(obj)->length() : -1;
duke@435	1485
duke@435	1486	// invoke the object callback (if callback is provided)
duke@435	1487	if (callbacks()->heap_iteration_callback != NULL) {
duke@435	1488	jvmtiHeapIterationCallback cb = callbacks()->heap_iteration_callback;
duke@435	1489	jint res = (*cb)(wrapper.klass_tag(),
duke@435	1490	wrapper.obj_size(),
duke@435	1491	wrapper.obj_tag_p(),
duke@435	1492	(jint)len,
duke@435	1493	(void*)user_data());
duke@435	1494	if (check_flags_for_abort(res)) return;
duke@435	1495	}
duke@435	1496
duke@435	1497	// for objects and classes we report primitive fields if callback provided
duke@435	1498	if (callbacks()->primitive_field_callback != NULL && obj->is_instance()) {
duke@435	1499	jint res;
duke@435	1500	jvmtiPrimitiveFieldCallback cb = callbacks()->primitive_field_callback;
never@1577	1501	if (obj->klass() == SystemDictionary::Class_klass()) {
duke@435	1502	res = invoke_primitive_field_callback_for_static_fields(&wrapper,
duke@435	1503	obj,
duke@435	1504	cb,
duke@435	1505	(void*)user_data());
duke@435	1506	} else {
duke@435	1507	res = invoke_primitive_field_callback_for_instance_fields(&wrapper,
duke@435	1508	obj,
duke@435	1509	cb,
duke@435	1510	(void*)user_data());
duke@435	1511	}
duke@435	1512	if (check_flags_for_abort(res)) return;
duke@435	1513	}
duke@435	1514
duke@435	1515	// string callback
duke@435	1516	if (!is_array &&
duke@435	1517	callbacks()->string_primitive_value_callback != NULL &&
never@1577	1518	obj->klass() == SystemDictionary::String_klass()) {
duke@435	1519	jint res = invoke_string_value_callback(
duke@435	1520	callbacks()->string_primitive_value_callback,
duke@435	1521	&wrapper,
duke@435	1522	obj,
duke@435	1523	(void*)user_data() );
duke@435	1524	if (check_flags_for_abort(res)) return;
duke@435	1525	}
duke@435	1526
duke@435	1527	// array callback
duke@435	1528	if (is_array &&
duke@435	1529	callbacks()->array_primitive_value_callback != NULL &&
duke@435	1530	obj->is_typeArray()) {
duke@435	1531	jint res = invoke_array_primitive_value_callback(
duke@435	1532	callbacks()->array_primitive_value_callback,
duke@435	1533	&wrapper,
duke@435	1534	obj,
duke@435	1535	(void*)user_data() );
duke@435	1536	if (check_flags_for_abort(res)) return;
duke@435	1537	}
duke@435	1538	};
duke@435	1539
duke@435	1540
duke@435	1541	// Deprecated function to iterate over all objects in the heap
duke@435	1542	void JvmtiTagMap::iterate_over_heap(jvmtiHeapObjectFilter object_filter,
duke@435	1543	KlassHandle klass,
duke@435	1544	jvmtiHeapObjectCallback heap_object_callback,
duke@435	1545	const void* user_data)
duke@435	1546	{
duke@435	1547	MutexLocker ml(Heap_lock);
duke@435	1548	IterateOverHeapObjectClosure blk(this,
duke@435	1549	klass,
duke@435	1550	object_filter,
duke@435	1551	heap_object_callback,
duke@435	1552	user_data);
duke@435	1553	VM_HeapIterateOperation op(&blk);
duke@435	1554	VMThread::execute(&op);
duke@435	1555	}
duke@435	1556
duke@435	1557
duke@435	1558	// Iterates over all objects in the heap
duke@435	1559	void JvmtiTagMap::iterate_through_heap(jint heap_filter,
duke@435	1560	KlassHandle klass,
duke@435	1561	const jvmtiHeapCallbacks* callbacks,
duke@435	1562	const void* user_data)
duke@435	1563	{
duke@435	1564	MutexLocker ml(Heap_lock);
duke@435	1565	IterateThroughHeapObjectClosure blk(this,
duke@435	1566	klass,
duke@435	1567	heap_filter,
duke@435	1568	callbacks,
duke@435	1569	user_data);
duke@435	1570	VM_HeapIterateOperation op(&blk);
duke@435	1571	VMThread::execute(&op);
duke@435	1572	}
duke@435	1573
duke@435	1574	// support class for get_objects_with_tags
duke@435	1575
duke@435	1576	class TagObjectCollector : public JvmtiTagHashmapEntryClosure {
duke@435	1577	private:
duke@435	1578	JvmtiEnv* _env;
duke@435	1579	jlong* _tags;
duke@435	1580	jint _tag_count;
duke@435	1581
duke@435	1582	GrowableArray<jobject>* _object_results; // collected objects (JNI weak refs)
duke@435	1583	GrowableArray<uint64_t>* _tag_results; // collected tags
duke@435	1584
duke@435	1585	public:
duke@435	1586	TagObjectCollector(JvmtiEnv* env, const jlong* tags, jint tag_count) {
duke@435	1587	_env = env;
duke@435	1588	_tags = (jlong*)tags;
duke@435	1589	_tag_count = tag_count;
duke@435	1590	_object_results = new (ResourceObj::C_HEAP) GrowableArray<jobject>(1,true);
duke@435	1591	_tag_results = new (ResourceObj::C_HEAP) GrowableArray<uint64_t>(1,true);
duke@435	1592	}
duke@435	1593
duke@435	1594	~TagObjectCollector() {
duke@435	1595	delete _object_results;
duke@435	1596	delete _tag_results;
duke@435	1597	}
duke@435	1598
duke@435	1599	// for each tagged object check if the tag value matches
duke@435	1600	// - if it matches then we create a JNI local reference to the object
duke@435	1601	// and record the reference and tag value.
duke@435	1602	//
duke@435	1603	void do_entry(JvmtiTagHashmapEntry* entry) {
duke@435	1604	for (int i=0; i<_tag_count; i++) {
duke@435	1605	if (_tags[i] == entry->tag()) {
duke@435	1606	oop o = JNIHandles::resolve(entry->object());
duke@435	1607	assert(o != NULL && o != JNIHandles::deleted_handle(), "sanity check");
duke@435	1608
duke@435	1609	// the mirror is tagged
duke@435	1610	if (o->is_klass()) {
duke@435	1611	klassOop k = (klassOop)o;
duke@435	1612	o = Klass::cast(k)->java_mirror();
duke@435	1613	}
duke@435	1614
duke@435	1615	jobject ref = JNIHandles::make_local(JavaThread::current(), o);
duke@435	1616	_object_results->append(ref);
duke@435	1617	_tag_results->append((uint64_t)entry->tag());
duke@435	1618	}
duke@435	1619	}
duke@435	1620	}
duke@435	1621
duke@435	1622	// return the results from the collection
duke@435	1623	//
duke@435	1624	jvmtiError result(jint* count_ptr, jobject** object_result_ptr, jlong** tag_result_ptr) {
duke@435	1625	jvmtiError error;
duke@435	1626	int count = _object_results->length();
duke@435	1627	assert(count >= 0, "sanity check");
duke@435	1628
duke@435	1629	// if object_result_ptr is not NULL then allocate the result and copy
duke@435	1630	// in the object references.
duke@435	1631	if (object_result_ptr != NULL) {
duke@435	1632	error = _env->Allocate(count * sizeof(jobject), (unsigned char**)object_result_ptr);
duke@435	1633	if (error != JVMTI_ERROR_NONE) {
duke@435	1634	return error;
duke@435	1635	}
duke@435	1636	for (int i=0; i<count; i++) {
duke@435	1637	(*object_result_ptr)[i] = _object_results->at(i);
duke@435	1638	}
duke@435	1639	}
duke@435	1640
duke@435	1641	// if tag_result_ptr is not NULL then allocate the result and copy
duke@435	1642	// in the tag values.
duke@435	1643	if (tag_result_ptr != NULL) {
duke@435	1644	error = _env->Allocate(count * sizeof(jlong), (unsigned char**)tag_result_ptr);
duke@435	1645	if (error != JVMTI_ERROR_NONE) {
duke@435	1646	if (object_result_ptr != NULL) {
duke@435	1647	_env->Deallocate((unsigned char*)object_result_ptr);
duke@435	1648	}
duke@435	1649	return error;
duke@435	1650	}
duke@435	1651	for (int i=0; i<count; i++) {
duke@435	1652	(*tag_result_ptr)[i] = (jlong)_tag_results->at(i);
duke@435	1653	}
duke@435	1654	}
duke@435	1655
duke@435	1656	*count_ptr = count;
duke@435	1657	return JVMTI_ERROR_NONE;
duke@435	1658	}
duke@435	1659	};
duke@435	1660
duke@435	1661	// return the list of objects with the specified tags
duke@435	1662	jvmtiError JvmtiTagMap::get_objects_with_tags(const jlong* tags,
duke@435	1663	jint count, jint* count_ptr, jobject** object_result_ptr, jlong** tag_result_ptr) {
duke@435	1664
duke@435	1665	TagObjectCollector collector(env(), tags, count);
duke@435	1666	{
duke@435	1667	// iterate over all tagged objects
duke@435	1668	MutexLocker ml(lock());
duke@435	1669	entry_iterate(&collector);
duke@435	1670	}
duke@435	1671	return collector.result(count_ptr, object_result_ptr, tag_result_ptr);
duke@435	1672	}
duke@435	1673
duke@435	1674
duke@435	1675	// ObjectMarker is used to support the marking objects when walking the
duke@435	1676	// heap.
duke@435	1677	//
duke@435	1678	// This implementation uses the existing mark bits in an object for
duke@435	1679	// marking. Objects that are marked must later have their headers restored.
duke@435	1680	// As most objects are unlocked and don't have their identity hash computed
duke@435	1681	// we don't have to save their headers. Instead we save the headers that
duke@435	1682	// are "interesting". Later when the headers are restored this implementation
duke@435	1683	// restores all headers to their initial value and then restores the few
duke@435	1684	// objects that had interesting headers.
duke@435	1685	//
duke@435	1686	// Future work: This implementation currently uses growable arrays to save
duke@435	1687	// the oop and header of interesting objects. As an optimization we could
duke@435	1688	// use the same technique as the GC and make use of the unused area
duke@435	1689	// between top() and end().
duke@435	1690	//
duke@435	1691
duke@435	1692	// An ObjectClosure used to restore the mark bits of an object
duke@435	1693	class RestoreMarksClosure : public ObjectClosure {
duke@435	1694	public:
duke@435	1695	void do_object(oop o) {
duke@435	1696	if (o != NULL) {
duke@435	1697	markOop mark = o->mark();
duke@435	1698	if (mark->is_marked()) {
duke@435	1699	o->init_mark();
duke@435	1700	}
duke@435	1701	}
duke@435	1702	}
duke@435	1703	};
duke@435	1704
duke@435	1705	// ObjectMarker provides the mark and visited functions
duke@435	1706	class ObjectMarker : AllStatic {
duke@435	1707	private:
duke@435	1708	// saved headers
duke@435	1709	static GrowableArray<oop>* _saved_oop_stack;
duke@435	1710	static GrowableArray<markOop>* _saved_mark_stack;
duke@435	1711
duke@435	1712	public:
duke@435	1713	static void init(); // initialize
duke@435	1714	static void done(); // clean-up
duke@435	1715
duke@435	1716	static inline void mark(oop o); // mark an object
duke@435	1717	static inline bool visited(oop o); // check if object has been visited
duke@435	1718	};
duke@435	1719
duke@435	1720	GrowableArray<oop>* ObjectMarker::_saved_oop_stack = NULL;
duke@435	1721	GrowableArray<markOop>* ObjectMarker::_saved_mark_stack = NULL;
duke@435	1722
duke@435	1723	// initialize ObjectMarker - prepares for object marking
duke@435	1724	void ObjectMarker::init() {
duke@435	1725	assert(Thread::current()->is_VM_thread(), "must be VMThread");
duke@435	1726
duke@435	1727	// prepare heap for iteration
duke@435	1728	Universe::heap()->ensure_parsability(false); // no need to retire TLABs
duke@435	1729
duke@435	1730	// create stacks for interesting headers
duke@435	1731	_saved_mark_stack = new (ResourceObj::C_HEAP) GrowableArray<markOop>(4000, true);
duke@435	1732	_saved_oop_stack = new (ResourceObj::C_HEAP) GrowableArray<oop>(4000, true);
duke@435	1733
duke@435	1734	if (UseBiasedLocking) {
duke@435	1735	BiasedLocking::preserve_marks();
duke@435	1736	}
duke@435	1737	}
duke@435	1738
duke@435	1739	// Object marking is done so restore object headers
duke@435	1740	void ObjectMarker::done() {
duke@435	1741	// iterate over all objects and restore the mark bits to
duke@435	1742	// their initial value
duke@435	1743	RestoreMarksClosure blk;
duke@435	1744	Universe::heap()->object_iterate(&blk);
duke@435	1745
duke@435	1746	// When sharing is enabled we need to restore the headers of the objects
duke@435	1747	// in the readwrite space too.
duke@435	1748	if (UseSharedSpaces) {
duke@435	1749	GenCollectedHeap* gch = GenCollectedHeap::heap();
duke@435	1750	CompactingPermGenGen* gen = (CompactingPermGenGen*)gch->perm_gen();
duke@435	1751	gen->rw_space()->object_iterate(&blk);
duke@435	1752	}
duke@435	1753
duke@435	1754	// now restore the interesting headers
duke@435	1755	for (int i = 0; i < _saved_oop_stack->length(); i++) {
duke@435	1756	oop o = _saved_oop_stack->at(i);
duke@435	1757	markOop mark = _saved_mark_stack->at(i);
duke@435	1758	o->set_mark(mark);
duke@435	1759	}
duke@435	1760
duke@435	1761	if (UseBiasedLocking) {
duke@435	1762	BiasedLocking::restore_marks();
duke@435	1763	}
duke@435	1764
duke@435	1765	// free the stacks
duke@435	1766	delete _saved_oop_stack;
duke@435	1767	delete _saved_mark_stack;
duke@435	1768	}
duke@435	1769
duke@435	1770	// mark an object
duke@435	1771	inline void ObjectMarker::mark(oop o) {
duke@435	1772	assert(Universe::heap()->is_in(o), "sanity check");
duke@435	1773	assert(!o->mark()->is_marked(), "should only mark an object once");
duke@435	1774
duke@435	1775	// object's mark word
duke@435	1776	markOop mark = o->mark();
duke@435	1777
duke@435	1778	if (mark->must_be_preserved(o)) {
duke@435	1779	_saved_mark_stack->push(mark);
duke@435	1780	_saved_oop_stack->push(o);
duke@435	1781	}
duke@435	1782
duke@435	1783	// mark the object
duke@435	1784	o->set_mark(markOopDesc::prototype()->set_marked());
duke@435	1785	}
duke@435	1786
duke@435	1787	// return true if object is marked
duke@435	1788	inline bool ObjectMarker::visited(oop o) {
duke@435	1789	return o->mark()->is_marked();
duke@435	1790	}
duke@435	1791
duke@435	1792	// Stack allocated class to help ensure that ObjectMarker is used
duke@435	1793	// correctly. Constructor initializes ObjectMarker, destructor calls
duke@435	1794	// ObjectMarker's done() function to restore object headers.
duke@435	1795	class ObjectMarkerController : public StackObj {
duke@435	1796	public:
duke@435	1797	ObjectMarkerController() {
duke@435	1798	ObjectMarker::init();
duke@435	1799	}
duke@435	1800	~ObjectMarkerController() {
duke@435	1801	ObjectMarker::done();
duke@435	1802	}
duke@435	1803	};
duke@435	1804
duke@435	1805
duke@435	1806	// helper to map a jvmtiHeapReferenceKind to an old style jvmtiHeapRootKind
duke@435	1807	// (not performance critical as only used for roots)
duke@435	1808	static jvmtiHeapRootKind toJvmtiHeapRootKind(jvmtiHeapReferenceKind kind) {
duke@435	1809	switch (kind) {
duke@435	1810	case JVMTI_HEAP_REFERENCE_JNI_GLOBAL: return JVMTI_HEAP_ROOT_JNI_GLOBAL;
duke@435	1811	case JVMTI_HEAP_REFERENCE_SYSTEM_CLASS: return JVMTI_HEAP_ROOT_SYSTEM_CLASS;
duke@435	1812	case JVMTI_HEAP_REFERENCE_MONITOR: return JVMTI_HEAP_ROOT_MONITOR;
duke@435	1813	case JVMTI_HEAP_REFERENCE_STACK_LOCAL: return JVMTI_HEAP_ROOT_STACK_LOCAL;
duke@435	1814	case JVMTI_HEAP_REFERENCE_JNI_LOCAL: return JVMTI_HEAP_ROOT_JNI_LOCAL;
duke@435	1815	case JVMTI_HEAP_REFERENCE_THREAD: return JVMTI_HEAP_ROOT_THREAD;
duke@435	1816	case JVMTI_HEAP_REFERENCE_OTHER: return JVMTI_HEAP_ROOT_OTHER;
duke@435	1817	default: ShouldNotReachHere(); return JVMTI_HEAP_ROOT_OTHER;
duke@435	1818	}
duke@435	1819	}
duke@435	1820
duke@435	1821	// Base class for all heap walk contexts. The base class maintains a flag
duke@435	1822	// to indicate if the context is valid or not.
duke@435	1823	class HeapWalkContext VALUE_OBJ_CLASS_SPEC {
duke@435	1824	private:
duke@435	1825	bool _valid;
duke@435	1826	public:
duke@435	1827	HeapWalkContext(bool valid) { _valid = valid; }
duke@435	1828	void invalidate() { _valid = false; }
duke@435	1829	bool is_valid() const { return _valid; }
duke@435	1830	};
duke@435	1831
duke@435	1832	// A basic heap walk context for the deprecated heap walking functions.
duke@435	1833	// The context for a basic heap walk are the callbacks and fields used by
duke@435	1834	// the referrer caching scheme.
duke@435	1835	class BasicHeapWalkContext: public HeapWalkContext {
duke@435	1836	private:
duke@435	1837	jvmtiHeapRootCallback _heap_root_callback;
duke@435	1838	jvmtiStackReferenceCallback _stack_ref_callback;
duke@435	1839	jvmtiObjectReferenceCallback _object_ref_callback;
duke@435	1840
duke@435	1841	// used for caching
duke@435	1842	oop _last_referrer;
duke@435	1843	jlong _last_referrer_tag;
duke@435	1844
duke@435	1845	public:
duke@435	1846	BasicHeapWalkContext() : HeapWalkContext(false) { }
duke@435	1847
duke@435	1848	BasicHeapWalkContext(jvmtiHeapRootCallback heap_root_callback,
duke@435	1849	jvmtiStackReferenceCallback stack_ref_callback,
duke@435	1850	jvmtiObjectReferenceCallback object_ref_callback) :
duke@435	1851	HeapWalkContext(true),
duke@435	1852	_heap_root_callback(heap_root_callback),
duke@435	1853	_stack_ref_callback(stack_ref_callback),
duke@435	1854	_object_ref_callback(object_ref_callback),
duke@435	1855	_last_referrer(NULL),
duke@435	1856	_last_referrer_tag(0) {
duke@435	1857	}
duke@435	1858
duke@435	1859	// accessors
duke@435	1860	jvmtiHeapRootCallback heap_root_callback() const { return _heap_root_callback; }
duke@435	1861	jvmtiStackReferenceCallback stack_ref_callback() const { return _stack_ref_callback; }
duke@435	1862	jvmtiObjectReferenceCallback object_ref_callback() const { return _object_ref_callback; }
duke@435	1863
duke@435	1864	oop last_referrer() const { return _last_referrer; }
duke@435	1865	void set_last_referrer(oop referrer) { _last_referrer = referrer; }
duke@435	1866	jlong last_referrer_tag() const { return _last_referrer_tag; }
duke@435	1867	void set_last_referrer_tag(jlong value) { _last_referrer_tag = value; }
duke@435	1868	};
duke@435	1869
duke@435	1870	// The advanced heap walk context for the FollowReferences functions.
duke@435	1871	// The context is the callbacks, and the fields used for filtering.
duke@435	1872	class AdvancedHeapWalkContext: public HeapWalkContext {
duke@435	1873	private:
duke@435	1874	jint _heap_filter;
duke@435	1875	KlassHandle _klass_filter;
duke@435	1876	const jvmtiHeapCallbacks* _heap_callbacks;
duke@435	1877
duke@435	1878	public:
duke@435	1879	AdvancedHeapWalkContext() : HeapWalkContext(false) { }
duke@435	1880
duke@435	1881	AdvancedHeapWalkContext(jint heap_filter,
duke@435	1882	KlassHandle klass_filter,
duke@435	1883	const jvmtiHeapCallbacks* heap_callbacks) :
duke@435	1884	HeapWalkContext(true),
duke@435	1885	_heap_filter(heap_filter),
duke@435	1886	_klass_filter(klass_filter),
duke@435	1887	_heap_callbacks(heap_callbacks) {
duke@435	1888	}
duke@435	1889
duke@435	1890	// accessors
duke@435	1891	jint heap_filter() const { return _heap_filter; }
duke@435	1892	KlassHandle klass_filter() const { return _klass_filter; }
duke@435	1893
duke@435	1894	const jvmtiHeapReferenceCallback heap_reference_callback() const {
duke@435	1895	return _heap_callbacks->heap_reference_callback;
duke@435	1896	};
duke@435	1897	const jvmtiPrimitiveFieldCallback primitive_field_callback() const {
duke@435	1898	return _heap_callbacks->primitive_field_callback;
duke@435	1899	}
duke@435	1900	const jvmtiArrayPrimitiveValueCallback array_primitive_value_callback() const {
duke@435	1901	return _heap_callbacks->array_primitive_value_callback;
duke@435	1902	}
duke@435	1903	const jvmtiStringPrimitiveValueCallback string_primitive_value_callback() const {
duke@435	1904	return _heap_callbacks->string_primitive_value_callback;
duke@435	1905	}
duke@435	1906	};
duke@435	1907
duke@435	1908	// The CallbackInvoker is a class with static functions that the heap walk can call
duke@435	1909	// into to invoke callbacks. It works in one of two modes. The "basic" mode is
duke@435	1910	// used for the deprecated IterateOverReachableObjects functions. The "advanced"
duke@435	1911	// mode is for the newer FollowReferences function which supports a lot of
duke@435	1912	// additional callbacks.
duke@435	1913	class CallbackInvoker : AllStatic {
duke@435	1914	private:
duke@435	1915	// heap walk styles
duke@435	1916	enum { basic, advanced };
duke@435	1917	static int _heap_walk_type;
duke@435	1918	static bool is_basic_heap_walk() { return _heap_walk_type == basic; }
duke@435	1919	static bool is_advanced_heap_walk() { return _heap_walk_type == advanced; }
duke@435	1920
duke@435	1921	// context for basic style heap walk
duke@435	1922	static BasicHeapWalkContext _basic_context;
duke@435	1923	static BasicHeapWalkContext* basic_context() {
duke@435	1924	assert(_basic_context.is_valid(), "invalid");
duke@435	1925	return &_basic_context;
duke@435	1926	}
duke@435	1927
duke@435	1928	// context for advanced style heap walk
duke@435	1929	static AdvancedHeapWalkContext _advanced_context;
duke@435	1930	static AdvancedHeapWalkContext* advanced_context() {
duke@435	1931	assert(_advanced_context.is_valid(), "invalid");
duke@435	1932	return &_advanced_context;
duke@435	1933	}
duke@435	1934
duke@435	1935	// context needed for all heap walks
duke@435	1936	static JvmtiTagMap* _tag_map;
duke@435	1937	static const void* _user_data;
duke@435	1938	static GrowableArray<oop>* _visit_stack;
duke@435	1939
duke@435	1940	// accessors
duke@435	1941	static JvmtiTagMap* tag_map() { return _tag_map; }
duke@435	1942	static const void* user_data() { return _user_data; }
duke@435	1943	static GrowableArray<oop>* visit_stack() { return _visit_stack; }
duke@435	1944
duke@435	1945	// if the object hasn't been visited then push it onto the visit stack
duke@435	1946	// so that it will be visited later
duke@435	1947	static inline bool check_for_visit(oop obj) {
duke@435	1948	if (!ObjectMarker::visited(obj)) visit_stack()->push(obj);
duke@435	1949	return true;
duke@435	1950	}
duke@435	1951
duke@435	1952	// invoke basic style callbacks
duke@435	1953	static inline bool invoke_basic_heap_root_callback
duke@435	1954	(jvmtiHeapRootKind root_kind, oop obj);
duke@435	1955	static inline bool invoke_basic_stack_ref_callback
duke@435	1956	(jvmtiHeapRootKind root_kind, jlong thread_tag, jint depth, jmethodID method,
duke@435	1957	int slot, oop obj);
duke@435	1958	static inline bool invoke_basic_object_reference_callback
duke@435	1959	(jvmtiObjectReferenceKind ref_kind, oop referrer, oop referree, jint index);
duke@435	1960
duke@435	1961	// invoke advanced style callbacks
duke@435	1962	static inline bool invoke_advanced_heap_root_callback
duke@435	1963	(jvmtiHeapReferenceKind ref_kind, oop obj);
duke@435	1964	static inline bool invoke_advanced_stack_ref_callback
duke@435	1965	(jvmtiHeapReferenceKind ref_kind, jlong thread_tag, jlong tid, int depth,
duke@435	1966	jmethodID method, jlocation bci, jint slot, oop obj);
duke@435	1967	static inline bool invoke_advanced_object_reference_callback
duke@435	1968	(jvmtiHeapReferenceKind ref_kind, oop referrer, oop referree, jint index);
duke@435	1969
duke@435	1970	// used to report the value of primitive fields
duke@435	1971	static inline bool report_primitive_field
duke@435	1972	(jvmtiHeapReferenceKind ref_kind, oop obj, jint index, address addr, char type);
duke@435	1973
duke@435	1974	public:
duke@435	1975	// initialize for basic mode
duke@435	1976	static void initialize_for_basic_heap_walk(JvmtiTagMap* tag_map,
duke@435	1977	GrowableArray<oop>* visit_stack,
duke@435	1978	const void* user_data,
duke@435	1979	BasicHeapWalkContext context);
duke@435	1980
duke@435	1981	// initialize for advanced mode
duke@435	1982	static void initialize_for_advanced_heap_walk(JvmtiTagMap* tag_map,
duke@435	1983	GrowableArray<oop>* visit_stack,
duke@435	1984	const void* user_data,
duke@435	1985	AdvancedHeapWalkContext context);
duke@435	1986
duke@435	1987	// functions to report roots
duke@435	1988	static inline bool report_simple_root(jvmtiHeapReferenceKind kind, oop o);
duke@435	1989	static inline bool report_jni_local_root(jlong thread_tag, jlong tid, jint depth,
duke@435	1990	jmethodID m, oop o);
duke@435	1991	static inline bool report_stack_ref_root(jlong thread_tag, jlong tid, jint depth,
duke@435	1992	jmethodID method, jlocation bci, jint slot, oop o);
duke@435	1993
duke@435	1994	// functions to report references
duke@435	1995	static inline bool report_array_element_reference(oop referrer, oop referree, jint index);
duke@435	1996	static inline bool report_class_reference(oop referrer, oop referree);
duke@435	1997	static inline bool report_class_loader_reference(oop referrer, oop referree);
duke@435	1998	static inline bool report_signers_reference(oop referrer, oop referree);
duke@435	1999	static inline bool report_protection_domain_reference(oop referrer, oop referree);
duke@435	2000	static inline bool report_superclass_reference(oop referrer, oop referree);
duke@435	2001	static inline bool report_interface_reference(oop referrer, oop referree);
duke@435	2002	static inline bool report_static_field_reference(oop referrer, oop referree, jint slot);
duke@435	2003	static inline bool report_field_reference(oop referrer, oop referree, jint slot);
duke@435	2004	static inline bool report_constant_pool_reference(oop referrer, oop referree, jint index);
duke@435	2005	static inline bool report_primitive_array_values(oop array);
duke@435	2006	static inline bool report_string_value(oop str);
duke@435	2007	static inline bool report_primitive_instance_field(oop o, jint index, address value, char type);
duke@435	2008	static inline bool report_primitive_static_field(oop o, jint index, address value, char type);
duke@435	2009	};
duke@435	2010
duke@435	2011	// statics
duke@435	2012	int CallbackInvoker::_heap_walk_type;
duke@435	2013	BasicHeapWalkContext CallbackInvoker::_basic_context;
duke@435	2014	AdvancedHeapWalkContext CallbackInvoker::_advanced_context;
duke@435	2015	JvmtiTagMap* CallbackInvoker::_tag_map;
duke@435	2016	const void* CallbackInvoker::_user_data;
duke@435	2017	GrowableArray<oop>* CallbackInvoker::_visit_stack;
duke@435	2018
duke@435	2019	// initialize for basic heap walk (IterateOverReachableObjects et al)
duke@435	2020	void CallbackInvoker::initialize_for_basic_heap_walk(JvmtiTagMap* tag_map,
duke@435	2021	GrowableArray<oop>* visit_stack,
duke@435	2022	const void* user_data,
duke@435	2023	BasicHeapWalkContext context) {
duke@435	2024	_tag_map = tag_map;
duke@435	2025	_visit_stack = visit_stack;
duke@435	2026	_user_data = user_data;
duke@435	2027	_basic_context = context;
duke@435	2028	_advanced_context.invalidate(); // will trigger assertion if used
duke@435	2029	_heap_walk_type = basic;
duke@435	2030	}
duke@435	2031
duke@435	2032	// initialize for advanced heap walk (FollowReferences)
duke@435	2033	void CallbackInvoker::initialize_for_advanced_heap_walk(JvmtiTagMap* tag_map,
duke@435	2034	GrowableArray<oop>* visit_stack,
duke@435	2035	const void* user_data,
duke@435	2036	AdvancedHeapWalkContext context) {
duke@435	2037	_tag_map = tag_map;
duke@435	2038	_visit_stack = visit_stack;
duke@435	2039	_user_data = user_data;
duke@435	2040	_advanced_context = context;
duke@435	2041	_basic_context.invalidate(); // will trigger assertion if used
duke@435	2042	_heap_walk_type = advanced;
duke@435	2043	}
duke@435	2044
duke@435	2045
duke@435	2046	// invoke basic style heap root callback
duke@435	2047	inline bool CallbackInvoker::invoke_basic_heap_root_callback(jvmtiHeapRootKind root_kind, oop obj) {
duke@435	2048	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2049
duke@435	2050	// if we heap roots should be reported
duke@435	2051	jvmtiHeapRootCallback cb = basic_context()->heap_root_callback();
duke@435	2052	if (cb == NULL) {
duke@435	2053	return check_for_visit(obj);
duke@435	2054	}
duke@435	2055
duke@435	2056	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2057	jvmtiIterationControl control = (*cb)(root_kind,
duke@435	2058	wrapper.klass_tag(),
duke@435	2059	wrapper.obj_size(),
duke@435	2060	wrapper.obj_tag_p(),
duke@435	2061	(void*)user_data());
duke@435	2062	// push root to visit stack when following references
duke@435	2063	if (control == JVMTI_ITERATION_CONTINUE &&
duke@435	2064	basic_context()->object_ref_callback() != NULL) {
duke@435	2065	visit_stack()->push(obj);
duke@435	2066	}
duke@435	2067	return control != JVMTI_ITERATION_ABORT;
duke@435	2068	}
duke@435	2069
duke@435	2070	// invoke basic style stack ref callback
duke@435	2071	inline bool CallbackInvoker::invoke_basic_stack_ref_callback(jvmtiHeapRootKind root_kind,
duke@435	2072	jlong thread_tag,
duke@435	2073	jint depth,
duke@435	2074	jmethodID method,
duke@435	2075	jint slot,
duke@435	2076	oop obj) {
duke@435	2077	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2078
duke@435	2079	// if we stack refs should be reported
duke@435	2080	jvmtiStackReferenceCallback cb = basic_context()->stack_ref_callback();
duke@435	2081	if (cb == NULL) {
duke@435	2082	return check_for_visit(obj);
duke@435	2083	}
duke@435	2084
duke@435	2085	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2086	jvmtiIterationControl control = (*cb)(root_kind,
duke@435	2087	wrapper.klass_tag(),
duke@435	2088	wrapper.obj_size(),
duke@435	2089	wrapper.obj_tag_p(),
duke@435	2090	thread_tag,
duke@435	2091	depth,
duke@435	2092	method,
duke@435	2093	slot,
duke@435	2094	(void*)user_data());
duke@435	2095	// push root to visit stack when following references
duke@435	2096	if (control == JVMTI_ITERATION_CONTINUE &&
duke@435	2097	basic_context()->object_ref_callback() != NULL) {
duke@435	2098	visit_stack()->push(obj);
duke@435	2099	}
duke@435	2100	return control != JVMTI_ITERATION_ABORT;
duke@435	2101	}
duke@435	2102
duke@435	2103	// invoke basic style object reference callback
duke@435	2104	inline bool CallbackInvoker::invoke_basic_object_reference_callback(jvmtiObjectReferenceKind ref_kind,
duke@435	2105	oop referrer,
duke@435	2106	oop referree,
duke@435	2107	jint index) {
duke@435	2108
duke@435	2109	assert(ServiceUtil::visible_oop(referrer), "checking");
duke@435	2110	assert(ServiceUtil::visible_oop(referree), "checking");
duke@435	2111
duke@435	2112	BasicHeapWalkContext* context = basic_context();
duke@435	2113
duke@435	2114	// callback requires the referrer's tag. If it's the same referrer
duke@435	2115	// as the last call then we use the cached value.
duke@435	2116	jlong referrer_tag;
duke@435	2117	if (referrer == context->last_referrer()) {
duke@435	2118	referrer_tag = context->last_referrer_tag();
duke@435	2119	} else {
duke@435	2120	referrer_tag = tag_for(tag_map(), klassOop_if_java_lang_Class(referrer));
duke@435	2121	}
duke@435	2122
duke@435	2123	// do the callback
duke@435	2124	CallbackWrapper wrapper(tag_map(), referree);
duke@435	2125	jvmtiObjectReferenceCallback cb = context->object_ref_callback();
duke@435	2126	jvmtiIterationControl control = (*cb)(ref_kind,
duke@435	2127	wrapper.klass_tag(),
duke@435	2128	wrapper.obj_size(),
duke@435	2129	wrapper.obj_tag_p(),
duke@435	2130	referrer_tag,
duke@435	2131	index,
duke@435	2132	(void*)user_data());
duke@435	2133
duke@435	2134	// record referrer and referrer tag. For self-references record the
duke@435	2135	// tag value from the callback as this might differ from referrer_tag.
duke@435	2136	context->set_last_referrer(referrer);
duke@435	2137	if (referrer == referree) {
duke@435	2138	context->set_last_referrer_tag(*wrapper.obj_tag_p());
duke@435	2139	} else {
duke@435	2140	context->set_last_referrer_tag(referrer_tag);
duke@435	2141	}
duke@435	2142
duke@435	2143	if (control == JVMTI_ITERATION_CONTINUE) {
duke@435	2144	return check_for_visit(referree);
duke@435	2145	} else {
duke@435	2146	return control != JVMTI_ITERATION_ABORT;
duke@435	2147	}
duke@435	2148	}
duke@435	2149
duke@435	2150	// invoke advanced style heap root callback
duke@435	2151	inline bool CallbackInvoker::invoke_advanced_heap_root_callback(jvmtiHeapReferenceKind ref_kind,
duke@435	2152	oop obj) {
duke@435	2153	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2154
duke@435	2155	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2156
duke@435	2157	// check that callback is provided
duke@435	2158	jvmtiHeapReferenceCallback cb = context->heap_reference_callback();
duke@435	2159	if (cb == NULL) {
duke@435	2160	return check_for_visit(obj);
duke@435	2161	}
duke@435	2162
duke@435	2163	// apply class filter
duke@435	2164	if (is_filtered_by_klass_filter(obj, context->klass_filter())) {
duke@435	2165	return check_for_visit(obj);
duke@435	2166	}
duke@435	2167
duke@435	2168	// setup the callback wrapper
duke@435	2169	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2170
duke@435	2171	// apply tag filter
duke@435	2172	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2173	wrapper.klass_tag(),
duke@435	2174	context->heap_filter())) {
duke@435	2175	return check_for_visit(obj);
duke@435	2176	}
duke@435	2177
duke@435	2178	// for arrays we need the length, otherwise -1
duke@435	2179	jint len = (jint)(obj->is_array() ? arrayOop(obj)->length() : -1);
duke@435	2180
duke@435	2181	// invoke the callback
duke@435	2182	jint res = (*cb)(ref_kind,
duke@435	2183	NULL, // referrer info
duke@435	2184	wrapper.klass_tag(),
duke@435	2185	0, // referrer_class_tag is 0 for heap root
duke@435	2186	wrapper.obj_size(),
duke@435	2187	wrapper.obj_tag_p(),
duke@435	2188	NULL, // referrer_tag_p
duke@435	2189	len,
duke@435	2190	(void*)user_data());
duke@435	2191	if (res & JVMTI_VISIT_ABORT) {
duke@435	2192	return false;// referrer class tag
duke@435	2193	}
duke@435	2194	if (res & JVMTI_VISIT_OBJECTS) {
duke@435	2195	check_for_visit(obj);
duke@435	2196	}
duke@435	2197	return true;
duke@435	2198	}
duke@435	2199
duke@435	2200	// report a reference from a thread stack to an object
duke@435	2201	inline bool CallbackInvoker::invoke_advanced_stack_ref_callback(jvmtiHeapReferenceKind ref_kind,
duke@435	2202	jlong thread_tag,
duke@435	2203	jlong tid,
duke@435	2204	int depth,
duke@435	2205	jmethodID method,
duke@435	2206	jlocation bci,
duke@435	2207	jint slot,
duke@435	2208	oop obj) {
duke@435	2209	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2210
duke@435	2211	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2212
duke@435	2213	// check that callback is provider
duke@435	2214	jvmtiHeapReferenceCallback cb = context->heap_reference_callback();
duke@435	2215	if (cb == NULL) {
duke@435	2216	return check_for_visit(obj);
duke@435	2217	}
duke@435	2218
duke@435	2219	// apply class filter
duke@435	2220	if (is_filtered_by_klass_filter(obj, context->klass_filter())) {
duke@435	2221	return check_for_visit(obj);
duke@435	2222	}
duke@435	2223
duke@435	2224	// setup the callback wrapper
duke@435	2225	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2226
duke@435	2227	// apply tag filter
duke@435	2228	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2229	wrapper.klass_tag(),
duke@435	2230	context->heap_filter())) {
duke@435	2231	return check_for_visit(obj);
duke@435	2232	}
duke@435	2233
duke@435	2234	// setup the referrer info
duke@435	2235	jvmtiHeapReferenceInfo reference_info;
duke@435	2236	reference_info.stack_local.thread_tag = thread_tag;
duke@435	2237	reference_info.stack_local.thread_id = tid;
duke@435	2238	reference_info.stack_local.depth = depth;
duke@435	2239	reference_info.stack_local.method = method;
duke@435	2240	reference_info.stack_local.location = bci;
duke@435	2241	reference_info.stack_local.slot = slot;
duke@435	2242
duke@435	2243	// for arrays we need the length, otherwise -1
duke@435	2244	jint len = (jint)(obj->is_array() ? arrayOop(obj)->length() : -1);
duke@435	2245
duke@435	2246	// call into the agent
duke@435	2247	int res = (*cb)(ref_kind,
duke@435	2248	&reference_info,
duke@435	2249	wrapper.klass_tag(),
duke@435	2250	0, // referrer_class_tag is 0 for heap root (stack)
duke@435	2251	wrapper.obj_size(),
duke@435	2252	wrapper.obj_tag_p(),
duke@435	2253	NULL, // referrer_tag is 0 for root
duke@435	2254	len,
duke@435	2255	(void*)user_data());
duke@435	2256
duke@435	2257	if (res & JVMTI_VISIT_ABORT) {
duke@435	2258	return false;
duke@435	2259	}
duke@435	2260	if (res & JVMTI_VISIT_OBJECTS) {
duke@435	2261	check_for_visit(obj);
duke@435	2262	}
duke@435	2263	return true;
duke@435	2264	}
duke@435	2265
duke@435	2266	// This mask is used to pass reference_info to a jvmtiHeapReferenceCallback
duke@435	2267	// only for ref_kinds defined by the JVM TI spec. Otherwise, NULL is passed.
duke@435	2268	#define REF_INFO_MASK ((1 << JVMTI_HEAP_REFERENCE_FIELD) \
duke@435	2269	| (1 << JVMTI_HEAP_REFERENCE_STATIC_FIELD) \
duke@435	2270	| (1 << JVMTI_HEAP_REFERENCE_ARRAY_ELEMENT) \
duke@435	2271	| (1 << JVMTI_HEAP_REFERENCE_CONSTANT_POOL) \
duke@435	2272	| (1 << JVMTI_HEAP_REFERENCE_STACK_LOCAL) \
duke@435	2273	| (1 << JVMTI_HEAP_REFERENCE_JNI_LOCAL))
duke@435	2274
duke@435	2275	// invoke the object reference callback to report a reference
duke@435	2276	inline bool CallbackInvoker::invoke_advanced_object_reference_callback(jvmtiHeapReferenceKind ref_kind,
duke@435	2277	oop referrer,
duke@435	2278	oop obj,
duke@435	2279	jint index)
duke@435	2280	{
duke@435	2281	// field index is only valid field in reference_info
duke@435	2282	static jvmtiHeapReferenceInfo reference_info = { 0 };
duke@435	2283
duke@435	2284	assert(ServiceUtil::visible_oop(referrer), "checking");
duke@435	2285	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2286
duke@435	2287	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2288
duke@435	2289	// check that callback is provider
duke@435	2290	jvmtiHeapReferenceCallback cb = context->heap_reference_callback();
duke@435	2291	if (cb == NULL) {
duke@435	2292	return check_for_visit(obj);
duke@435	2293	}
duke@435	2294
duke@435	2295	// apply class filter
duke@435	2296	if (is_filtered_by_klass_filter(obj, context->klass_filter())) {
duke@435	2297	return check_for_visit(obj);
duke@435	2298	}
duke@435	2299
duke@435	2300	// setup the callback wrapper
duke@435	2301	TwoOopCallbackWrapper wrapper(tag_map(), referrer, obj);
duke@435	2302
duke@435	2303	// apply tag filter
duke@435	2304	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2305	wrapper.klass_tag(),
duke@435	2306	context->heap_filter())) {
duke@435	2307	return check_for_visit(obj);
duke@435	2308	}
duke@435	2309
duke@435	2310	// field index is only valid field in reference_info
duke@435	2311	reference_info.field.index = index;
duke@435	2312
duke@435	2313	// for arrays we need the length, otherwise -1
duke@435	2314	jint len = (jint)(obj->is_array() ? arrayOop(obj)->length() : -1);
duke@435	2315
duke@435	2316	// invoke the callback
duke@435	2317	int res = (*cb)(ref_kind,
duke@435	2318	(REF_INFO_MASK & (1 << ref_kind)) ? &reference_info : NULL,
duke@435	2319	wrapper.klass_tag(),
duke@435	2320	wrapper.referrer_klass_tag(),
duke@435	2321	wrapper.obj_size(),
duke@435	2322	wrapper.obj_tag_p(),
duke@435	2323	wrapper.referrer_tag_p(),
duke@435	2324	len,
duke@435	2325	(void*)user_data());
duke@435	2326
duke@435	2327	if (res & JVMTI_VISIT_ABORT) {
duke@435	2328	return false;
duke@435	2329	}
duke@435	2330	if (res & JVMTI_VISIT_OBJECTS) {
duke@435	2331	check_for_visit(obj);
duke@435	2332	}
duke@435	2333	return true;
duke@435	2334	}
duke@435	2335
duke@435	2336	// report a "simple root"
duke@435	2337	inline bool CallbackInvoker::report_simple_root(jvmtiHeapReferenceKind kind, oop obj) {
duke@435	2338	assert(kind != JVMTI_HEAP_REFERENCE_STACK_LOCAL &&
duke@435	2339	kind != JVMTI_HEAP_REFERENCE_JNI_LOCAL, "not a simple root");
duke@435	2340	assert(ServiceUtil::visible_oop(obj), "checking");
duke@435	2341
duke@435	2342	if (is_basic_heap_walk()) {
duke@435	2343	// map to old style root kind
duke@435	2344	jvmtiHeapRootKind root_kind = toJvmtiHeapRootKind(kind);
duke@435	2345	return invoke_basic_heap_root_callback(root_kind, obj);
duke@435	2346	} else {
duke@435	2347	assert(is_advanced_heap_walk(), "wrong heap walk type");
duke@435	2348	return invoke_advanced_heap_root_callback(kind, obj);
duke@435	2349	}
duke@435	2350	}
duke@435	2351
duke@435	2352
duke@435	2353	// invoke the primitive array values
duke@435	2354	inline bool CallbackInvoker::report_primitive_array_values(oop obj) {
duke@435	2355	assert(obj->is_typeArray(), "not a primitive array");
duke@435	2356
duke@435	2357	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2358	assert(context->array_primitive_value_callback() != NULL, "no callback");
duke@435	2359
duke@435	2360	// apply class filter
duke@435	2361	if (is_filtered_by_klass_filter(obj, context->klass_filter())) {
duke@435	2362	return true;
duke@435	2363	}
duke@435	2364
duke@435	2365	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2366
duke@435	2367	// apply tag filter
duke@435	2368	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2369	wrapper.klass_tag(),
duke@435	2370	context->heap_filter())) {
duke@435	2371	return true;
duke@435	2372	}
duke@435	2373
duke@435	2374	// invoke the callback
duke@435	2375	int res = invoke_array_primitive_value_callback(context->array_primitive_value_callback(),
duke@435	2376	&wrapper,
duke@435	2377	obj,
duke@435	2378	(void*)user_data());
duke@435	2379	return (!(res & JVMTI_VISIT_ABORT));
duke@435	2380	}
duke@435	2381
duke@435	2382	// invoke the string value callback
duke@435	2383	inline bool CallbackInvoker::report_string_value(oop str) {
never@1577	2384	assert(str->klass() == SystemDictionary::String_klass(), "not a string");
duke@435	2385
duke@435	2386	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2387	assert(context->string_primitive_value_callback() != NULL, "no callback");
duke@435	2388
duke@435	2389	// apply class filter
duke@435	2390	if (is_filtered_by_klass_filter(str, context->klass_filter())) {
duke@435	2391	return true;
duke@435	2392	}
duke@435	2393
duke@435	2394	CallbackWrapper wrapper(tag_map(), str);
duke@435	2395
duke@435	2396	// apply tag filter
duke@435	2397	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2398	wrapper.klass_tag(),
duke@435	2399	context->heap_filter())) {
duke@435	2400	return true;
duke@435	2401	}
duke@435	2402
duke@435	2403	// invoke the callback
duke@435	2404	int res = invoke_string_value_callback(context->string_primitive_value_callback(),
duke@435	2405	&wrapper,
duke@435	2406	str,
duke@435	2407	(void*)user_data());
duke@435	2408	return (!(res & JVMTI_VISIT_ABORT));
duke@435	2409	}
duke@435	2410
duke@435	2411	// invoke the primitive field callback
duke@435	2412	inline bool CallbackInvoker::report_primitive_field(jvmtiHeapReferenceKind ref_kind,
duke@435	2413	oop obj,
duke@435	2414	jint index,
duke@435	2415	address addr,
duke@435	2416	char type)
duke@435	2417	{
duke@435	2418	// for primitive fields only the index will be set
duke@435	2419	static jvmtiHeapReferenceInfo reference_info = { 0 };
duke@435	2420
duke@435	2421	AdvancedHeapWalkContext* context = advanced_context();
duke@435	2422	assert(context->primitive_field_callback() != NULL, "no callback");
duke@435	2423
duke@435	2424	// apply class filter
duke@435	2425	if (is_filtered_by_klass_filter(obj, context->klass_filter())) {
duke@435	2426	return true;
duke@435	2427	}
duke@435	2428
duke@435	2429	CallbackWrapper wrapper(tag_map(), obj);
duke@435	2430
duke@435	2431	// apply tag filter
duke@435	2432	if (is_filtered_by_heap_filter(wrapper.obj_tag(),
duke@435	2433	wrapper.klass_tag(),
duke@435	2434	context->heap_filter())) {
duke@435	2435	return true;
duke@435	2436	}
duke@435	2437
duke@435	2438	// the field index in the referrer
duke@435	2439	reference_info.field.index = index;
duke@435	2440
duke@435	2441	// map the type
duke@435	2442	jvmtiPrimitiveType value_type = (jvmtiPrimitiveType)type;
duke@435	2443
duke@435	2444	// setup the jvalue
duke@435	2445	jvalue value;
duke@435	2446	copy_to_jvalue(&value, addr, value_type);
duke@435	2447
duke@435	2448	jvmtiPrimitiveFieldCallback cb = context->primitive_field_callback();
duke@435	2449	int res = (*cb)(ref_kind,
duke@435	2450	&reference_info,
duke@435	2451	wrapper.klass_tag(),
duke@435	2452	wrapper.obj_tag_p(),
duke@435	2453	value,
duke@435	2454	value_type,
duke@435	2455	(void*)user_data());
duke@435	2456	return (!(res & JVMTI_VISIT_ABORT));
duke@435	2457	}
duke@435	2458
duke@435	2459
duke@435	2460	// instance field
duke@435	2461	inline bool CallbackInvoker::report_primitive_instance_field(oop obj,
duke@435	2462	jint index,
duke@435	2463	address value,
duke@435	2464	char type) {
duke@435	2465	return report_primitive_field(JVMTI_HEAP_REFERENCE_FIELD,
duke@435	2466	obj,
duke@435	2467	index,
duke@435	2468	value,
duke@435	2469	type);
duke@435	2470	}
duke@435	2471
duke@435	2472	// static field
duke@435	2473	inline bool CallbackInvoker::report_primitive_static_field(oop obj,
duke@435	2474	jint index,
duke@435	2475	address value,
duke@435	2476	char type) {
duke@435	2477	return report_primitive_field(JVMTI_HEAP_REFERENCE_STATIC_FIELD,
duke@435	2478	obj,
duke@435	2479	index,
duke@435	2480	value,
duke@435	2481	type);
duke@435	2482	}
duke@435	2483
duke@435	2484	// report a JNI local (root object) to the profiler
duke@435	2485	inline bool CallbackInvoker::report_jni_local_root(jlong thread_tag, jlong tid, jint depth, jmethodID m, oop obj) {
duke@435	2486	if (is_basic_heap_walk()) {
duke@435	2487	return invoke_basic_stack_ref_callback(JVMTI_HEAP_ROOT_JNI_LOCAL,
duke@435	2488	thread_tag,
duke@435	2489	depth,
duke@435	2490	m,
duke@435	2491	-1,
duke@435	2492	obj);
duke@435	2493	} else {
duke@435	2494	return invoke_advanced_stack_ref_callback(JVMTI_HEAP_REFERENCE_JNI_LOCAL,
duke@435	2495	thread_tag, tid,
duke@435	2496	depth,
duke@435	2497	m,
duke@435	2498	(jlocation)-1,
duke@435	2499	-1,
duke@435	2500	obj);
duke@435	2501	}
duke@435	2502	}
duke@435	2503
duke@435	2504
duke@435	2505	// report a local (stack reference, root object)
duke@435	2506	inline bool CallbackInvoker::report_stack_ref_root(jlong thread_tag,
duke@435	2507	jlong tid,
duke@435	2508	jint depth,
duke@435	2509	jmethodID method,
duke@435	2510	jlocation bci,
duke@435	2511	jint slot,
duke@435	2512	oop obj) {
duke@435	2513	if (is_basic_heap_walk()) {
duke@435	2514	return invoke_basic_stack_ref_callback(JVMTI_HEAP_ROOT_STACK_LOCAL,
duke@435	2515	thread_tag,
duke@435	2516	depth,
duke@435	2517	method,
duke@435	2518	slot,
duke@435	2519	obj);
duke@435	2520	} else {
duke@435	2521	return invoke_advanced_stack_ref_callback(JVMTI_HEAP_REFERENCE_STACK_LOCAL,
duke@435	2522	thread_tag,
duke@435	2523	tid,
duke@435	2524	depth,
duke@435	2525	method,
duke@435	2526	bci,
duke@435	2527	slot,
duke@435	2528	obj);
duke@435	2529	}
duke@435	2530	}
duke@435	2531
duke@435	2532	// report an object referencing a class.
duke@435	2533	inline bool CallbackInvoker::report_class_reference(oop referrer, oop referree) {
duke@435	2534	if (is_basic_heap_walk()) {
duke@435	2535	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_CLASS, referrer, referree, -1);
duke@435	2536	} else {
duke@435	2537	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_CLASS, referrer, referree, -1);
duke@435	2538	}
duke@435	2539	}
duke@435	2540
duke@435	2541	// report a class referencing its class loader.
duke@435	2542	inline bool CallbackInvoker::report_class_loader_reference(oop referrer, oop referree) {
duke@435	2543	if (is_basic_heap_walk()) {
duke@435	2544	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_CLASS_LOADER, referrer, referree, -1);
duke@435	2545	} else {
duke@435	2546	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_CLASS_LOADER, referrer, referree, -1);
duke@435	2547	}
duke@435	2548	}
duke@435	2549
duke@435	2550	// report a class referencing its signers.
duke@435	2551	inline bool CallbackInvoker::report_signers_reference(oop referrer, oop referree) {
duke@435	2552	if (is_basic_heap_walk()) {
duke@435	2553	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_SIGNERS, referrer, referree, -1);
duke@435	2554	} else {
duke@435	2555	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_SIGNERS, referrer, referree, -1);
duke@435	2556	}
duke@435	2557	}
duke@435	2558
duke@435	2559	// report a class referencing its protection domain..
duke@435	2560	inline bool CallbackInvoker::report_protection_domain_reference(oop referrer, oop referree) {
duke@435	2561	if (is_basic_heap_walk()) {
duke@435	2562	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_PROTECTION_DOMAIN, referrer, referree, -1);
duke@435	2563	} else {
duke@435	2564	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_PROTECTION_DOMAIN, referrer, referree, -1);
duke@435	2565	}
duke@435	2566	}
duke@435	2567
duke@435	2568	// report a class referencing its superclass.
duke@435	2569	inline bool CallbackInvoker::report_superclass_reference(oop referrer, oop referree) {
duke@435	2570	if (is_basic_heap_walk()) {
duke@435	2571	// Send this to be consistent with past implementation
duke@435	2572	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_CLASS, referrer, referree, -1);
duke@435	2573	} else {
duke@435	2574	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_SUPERCLASS, referrer, referree, -1);
duke@435	2575	}
duke@435	2576	}
duke@435	2577
duke@435	2578	// report a class referencing one of its interfaces.
duke@435	2579	inline bool CallbackInvoker::report_interface_reference(oop referrer, oop referree) {
duke@435	2580	if (is_basic_heap_walk()) {
duke@435	2581	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_INTERFACE, referrer, referree, -1);
duke@435	2582	} else {
duke@435	2583	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_INTERFACE, referrer, referree, -1);
duke@435	2584	}
duke@435	2585	}
duke@435	2586
duke@435	2587	// report a class referencing one of its static fields.
duke@435	2588	inline bool CallbackInvoker::report_static_field_reference(oop referrer, oop referree, jint slot) {
duke@435	2589	if (is_basic_heap_walk()) {
duke@435	2590	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_STATIC_FIELD, referrer, referree, slot);
duke@435	2591	} else {
duke@435	2592	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_STATIC_FIELD, referrer, referree, slot);
duke@435	2593	}
duke@435	2594	}
duke@435	2595
duke@435	2596	// report an array referencing an element object
duke@435	2597	inline bool CallbackInvoker::report_array_element_reference(oop referrer, oop referree, jint index) {
duke@435	2598	if (is_basic_heap_walk()) {
duke@435	2599	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_ARRAY_ELEMENT, referrer, referree, index);
duke@435	2600	} else {
duke@435	2601	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_ARRAY_ELEMENT, referrer, referree, index);
duke@435	2602	}
duke@435	2603	}
duke@435	2604
duke@435	2605	// report an object referencing an instance field object
duke@435	2606	inline bool CallbackInvoker::report_field_reference(oop referrer, oop referree, jint slot) {
duke@435	2607	if (is_basic_heap_walk()) {
duke@435	2608	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_FIELD, referrer, referree, slot);
duke@435	2609	} else {
duke@435	2610	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_FIELD, referrer, referree, slot);
duke@435	2611	}
duke@435	2612	}
duke@435	2613
duke@435	2614	// report an array referencing an element object
duke@435	2615	inline bool CallbackInvoker::report_constant_pool_reference(oop referrer, oop referree, jint index) {
duke@435	2616	if (is_basic_heap_walk()) {
duke@435	2617	return invoke_basic_object_reference_callback(JVMTI_REFERENCE_CONSTANT_POOL, referrer, referree, index);
duke@435	2618	} else {
duke@435	2619	return invoke_advanced_object_reference_callback(JVMTI_HEAP_REFERENCE_CONSTANT_POOL, referrer, referree, index);
duke@435	2620	}
duke@435	2621	}
duke@435	2622
duke@435	2623	// A supporting closure used to process simple roots
duke@435	2624	class SimpleRootsClosure : public OopClosure {
duke@435	2625	private:
duke@435	2626	jvmtiHeapReferenceKind _kind;
duke@435	2627	bool _continue;
duke@435	2628
duke@435	2629	jvmtiHeapReferenceKind root_kind() { return _kind; }
duke@435	2630
duke@435	2631	public:
duke@435	2632	void set_kind(jvmtiHeapReferenceKind kind) {
duke@435	2633	_kind = kind;
duke@435	2634	_continue = true;
duke@435	2635	}
duke@435	2636
duke@435	2637	inline bool stopped() {
duke@435	2638	return !_continue;
duke@435	2639	}
duke@435	2640
duke@435	2641	void do_oop(oop* obj_p) {
duke@435	2642	// iteration has terminated
duke@435	2643	if (stopped()) {
duke@435	2644	return;
duke@435	2645	}
duke@435	2646
duke@435	2647	// ignore null or deleted handles
duke@435	2648	oop o = *obj_p;
duke@435	2649	if (o == NULL || o == JNIHandles::deleted_handle()) {
duke@435	2650	return;
duke@435	2651	}
duke@435	2652
duke@435	2653	jvmtiHeapReferenceKind kind = root_kind();
duke@435	2654
duke@435	2655	// many roots are Klasses so we use the java mirror
duke@435	2656	if (o->is_klass()) {
duke@435	2657	klassOop k = (klassOop)o;
duke@435	2658	o = Klass::cast(k)->java_mirror();
duke@435	2659	} else {
duke@435	2660
duke@435	2661	// SystemDictionary::always_strong_oops_do reports the application
duke@435	2662	// class loader as a root. We want this root to be reported as
duke@435	2663	// a root kind of "OTHER" rather than "SYSTEM_CLASS".
duke@435	2664	if (o->is_instance() && root_kind() == JVMTI_HEAP_REFERENCE_SYSTEM_CLASS) {
duke@435	2665	kind = JVMTI_HEAP_REFERENCE_OTHER;
duke@435	2666	}
duke@435	2667	}
duke@435	2668
duke@435	2669	// some objects are ignored - in the case of simple
duke@435	2670	// roots it's mostly symbolOops that we are skipping
duke@435	2671	// here.
duke@435	2672	if (!ServiceUtil::visible_oop(o)) {
duke@435	2673	return;
duke@435	2674	}
duke@435	2675
duke@435	2676	// invoke the callback
duke@435	2677	_continue = CallbackInvoker::report_simple_root(kind, o);
duke@435	2678
duke@435	2679	}
coleenp@548	2680	virtual void do_oop(narrowOop* obj_p) { ShouldNotReachHere(); }
duke@435	2681	};
duke@435	2682
duke@435	2683	// A supporting closure used to process JNI locals
duke@435	2684	class JNILocalRootsClosure : public OopClosure {
duke@435	2685	private:
duke@435	2686	jlong _thread_tag;
duke@435	2687	jlong _tid;
duke@435	2688	jint _depth;
duke@435	2689	jmethodID _method;
duke@435	2690	bool _continue;
duke@435	2691	public:
duke@435	2692	void set_context(jlong thread_tag, jlong tid, jint depth, jmethodID method) {
duke@435	2693	_thread_tag = thread_tag;
duke@435	2694	_tid = tid;
duke@435	2695	_depth = depth;
duke@435	2696	_method = method;
duke@435	2697	_continue = true;
duke@435	2698	}
duke@435	2699
duke@435	2700	inline bool stopped() {
duke@435	2701	return !_continue;
duke@435	2702	}
duke@435	2703
duke@435	2704	void do_oop(oop* obj_p) {
duke@435	2705	// iteration has terminated
duke@435	2706	if (stopped()) {
duke@435	2707	return;
duke@435	2708	}
duke@435	2709
duke@435	2710	// ignore null or deleted handles
duke@435	2711	oop o = *obj_p;
duke@435	2712	if (o == NULL || o == JNIHandles::deleted_handle()) {
duke@435	2713	return;
duke@435	2714	}
duke@435	2715
duke@435	2716	if (!ServiceUtil::visible_oop(o)) {
duke@435	2717	return;
duke@435	2718	}
duke@435	2719
duke@435	2720	// invoke the callback
duke@435	2721	_continue = CallbackInvoker::report_jni_local_root(_thread_tag, _tid, _depth, _method, o);
duke@435	2722	}
coleenp@548	2723	virtual void do_oop(narrowOop* obj_p) { ShouldNotReachHere(); }
duke@435	2724	};
duke@435	2725
duke@435	2726
duke@435	2727	// A VM operation to iterate over objects that are reachable from
duke@435	2728	// a set of roots or an initial object.
duke@435	2729	//
duke@435	2730	// For VM_HeapWalkOperation the set of roots used is :-
duke@435	2731	//
duke@435	2732	// - All JNI global references
duke@435	2733	// - All inflated monitors
duke@435	2734	// - All classes loaded by the boot class loader (or all classes
duke@435	2735	// in the event that class unloading is disabled)
duke@435	2736	// - All java threads
duke@435	2737	// - For each java thread then all locals and JNI local references
duke@435	2738	// on the thread's execution stack
duke@435	2739	// - All visible/explainable objects from Universes::oops_do
duke@435	2740	//
duke@435	2741	class VM_HeapWalkOperation: public VM_Operation {
duke@435	2742	private:
duke@435	2743	enum {
duke@435	2744	initial_visit_stack_size = 4000
duke@435	2745	};
duke@435	2746
duke@435	2747	bool _is_advanced_heap_walk; // indicates FollowReferences
duke@435	2748	JvmtiTagMap* _tag_map;
duke@435	2749	Handle _initial_object;
duke@435	2750	GrowableArray<oop>* _visit_stack; // the visit stack
duke@435	2751
duke@435	2752	bool _collecting_heap_roots; // are we collecting roots
duke@435	2753	bool _following_object_refs; // are we following object references
duke@435	2754
duke@435	2755	bool _reporting_primitive_fields; // optional reporting
duke@435	2756	bool _reporting_primitive_array_values;
duke@435	2757	bool _reporting_string_values;
duke@435	2758
duke@435	2759	GrowableArray<oop>* create_visit_stack() {
duke@435	2760	return new (ResourceObj::C_HEAP) GrowableArray<oop>(initial_visit_stack_size, true);
duke@435	2761	}
duke@435	2762
duke@435	2763	// accessors
duke@435	2764	bool is_advanced_heap_walk() const { return _is_advanced_heap_walk; }
duke@435	2765	JvmtiTagMap* tag_map() const { return _tag_map; }
duke@435	2766	Handle initial_object() const { return _initial_object; }
duke@435	2767
duke@435	2768	bool is_following_references() const { return _following_object_refs; }
duke@435	2769
duke@435	2770	bool is_reporting_primitive_fields() const { return _reporting_primitive_fields; }
duke@435	2771	bool is_reporting_primitive_array_values() const { return _reporting_primitive_array_values; }
duke@435	2772	bool is_reporting_string_values() const { return _reporting_string_values; }
duke@435	2773
duke@435	2774	GrowableArray<oop>* visit_stack() const { return _visit_stack; }
duke@435	2775
duke@435	2776	// iterate over the various object types
duke@435	2777	inline bool iterate_over_array(oop o);
duke@435	2778	inline bool iterate_over_type_array(oop o);
duke@435	2779	inline bool iterate_over_class(klassOop o);
duke@435	2780	inline bool iterate_over_object(oop o);
duke@435	2781
duke@435	2782	// root collection
duke@435	2783	inline bool collect_simple_roots();
duke@435	2784	inline bool collect_stack_roots();
duke@435	2785	inline bool collect_stack_roots(JavaThread* java_thread, JNILocalRootsClosure* blk);
duke@435	2786
duke@435	2787	// visit an object
duke@435	2788	inline bool visit(oop o);
duke@435	2789
duke@435	2790	public:
duke@435	2791	VM_HeapWalkOperation(JvmtiTagMap* tag_map,
duke@435	2792	Handle initial_object,
duke@435	2793	BasicHeapWalkContext callbacks,
duke@435	2794	const void* user_data);
duke@435	2795
duke@435	2796	VM_HeapWalkOperation(JvmtiTagMap* tag_map,
duke@435	2797	Handle initial_object,
duke@435	2798	AdvancedHeapWalkContext callbacks,
duke@435	2799	const void* user_data);
duke@435	2800
duke@435	2801	~VM_HeapWalkOperation();
duke@435	2802
duke@435	2803	VMOp_Type type() const { return VMOp_HeapWalkOperation; }
duke@435	2804	void doit();
duke@435	2805	};
duke@435	2806
duke@435	2807
duke@435	2808	VM_HeapWalkOperation::VM_HeapWalkOperation(JvmtiTagMap* tag_map,
duke@435	2809	Handle initial_object,
duke@435	2810	BasicHeapWalkContext callbacks,
duke@435	2811	const void* user_data) {
duke@435	2812	_is_advanced_heap_walk = false;
duke@435	2813	_tag_map = tag_map;
duke@435	2814	_initial_object = initial_object;
duke@435	2815	_following_object_refs = (callbacks.object_ref_callback() != NULL);
duke@435	2816	_reporting_primitive_fields = false;
duke@435	2817	_reporting_primitive_array_values = false;
duke@435	2818	_reporting_string_values = false;
duke@435	2819	_visit_stack = create_visit_stack();
duke@435	2820
duke@435	2821
duke@435	2822	CallbackInvoker::initialize_for_basic_heap_walk(tag_map, _visit_stack, user_data, callbacks);
duke@435	2823	}
duke@435	2824
duke@435	2825	VM_HeapWalkOperation::VM_HeapWalkOperation(JvmtiTagMap* tag_map,
duke@435	2826	Handle initial_object,
duke@435	2827	AdvancedHeapWalkContext callbacks,
duke@435	2828	const void* user_data) {
duke@435	2829	_is_advanced_heap_walk = true;
duke@435	2830	_tag_map = tag_map;
duke@435	2831	_initial_object = initial_object;
duke@435	2832	_following_object_refs = true;
duke@435	2833	_reporting_primitive_fields = (callbacks.primitive_field_callback() != NULL);;
duke@435	2834	_reporting_primitive_array_values = (callbacks.array_primitive_value_callback() != NULL);;
duke@435	2835	_reporting_string_values = (callbacks.string_primitive_value_callback() != NULL);;
duke@435	2836	_visit_stack = create_visit_stack();
duke@435	2837
duke@435	2838	CallbackInvoker::initialize_for_advanced_heap_walk(tag_map, _visit_stack, user_data, callbacks);
duke@435	2839	}
duke@435	2840
duke@435	2841	VM_HeapWalkOperation::~VM_HeapWalkOperation() {
duke@435	2842	if (_following_object_refs) {
duke@435	2843	assert(_visit_stack != NULL, "checking");
duke@435	2844	delete _visit_stack;
duke@435	2845	_visit_stack = NULL;
duke@435	2846	}
duke@435	2847	}
duke@435	2848
duke@435	2849	// an array references its class and has a reference to
duke@435	2850	// each element in the array
duke@435	2851	inline bool VM_HeapWalkOperation::iterate_over_array(oop o) {
duke@435	2852	objArrayOop array = objArrayOop(o);
duke@435	2853	if (array->klass() == Universe::systemObjArrayKlassObj()) {
duke@435	2854	// filtered out
duke@435	2855	return true;
duke@435	2856	}
duke@435	2857
duke@435	2858	// array reference to its class
duke@435	2859	oop mirror = objArrayKlass::cast(array->klass())->java_mirror();
duke@435	2860	if (!CallbackInvoker::report_class_reference(o, mirror)) {
duke@435	2861	return false;
duke@435	2862	}
duke@435	2863
duke@435	2864	// iterate over the array and report each reference to a
duke@435	2865	// non-null element
duke@435	2866	for (int index=0; index<array->length(); index++) {
duke@435	2867	oop elem = array->obj_at(index);
duke@435	2868	if (elem == NULL) {
duke@435	2869	continue;
duke@435	2870	}
duke@435	2871
duke@435	2872	// report the array reference o[index] = elem
duke@435	2873	if (!CallbackInvoker::report_array_element_reference(o, elem, index)) {
duke@435	2874	return false;
duke@435	2875	}
duke@435	2876	}
duke@435	2877	return true;
duke@435	2878	}
duke@435	2879
duke@435	2880	// a type array references its class
duke@435	2881	inline bool VM_HeapWalkOperation::iterate_over_type_array(oop o) {
duke@435	2882	klassOop k = o->klass();
duke@435	2883	oop mirror = Klass::cast(k)->java_mirror();
duke@435	2884	if (!CallbackInvoker::report_class_reference(o, mirror)) {
duke@435	2885	return false;
duke@435	2886	}
duke@435	2887
duke@435	2888	// report the array contents if required
duke@435	2889	if (is_reporting_primitive_array_values()) {
duke@435	2890	if (!CallbackInvoker::report_primitive_array_values(o)) {
duke@435	2891	return false;
duke@435	2892	}
duke@435	2893	}
duke@435	2894	return true;
duke@435	2895	}
duke@435	2896
duke@435	2897	// verify that a static oop field is in range
coleenp@548	2898	static inline bool verify_static_oop(instanceKlass* ik,
coleenp@548	2899	klassOop k, int offset) {
coleenp@548	2900	address obj_p = (address)k + offset;
coleenp@548	2901	address start = (address)ik->start_of_static_fields();
coleenp@548	2902	address end = start + (ik->static_oop_field_size() * heapOopSize);
duke@435	2903	assert(end >= start, "sanity check");
duke@435	2904
duke@435	2905	if (obj_p >= start && obj_p < end) {
duke@435	2906	return true;
duke@435	2907	} else {
duke@435	2908	return false;
duke@435	2909	}
duke@435	2910	}
duke@435	2911
duke@435	2912	// a class references its super class, interfaces, class loader, ...
duke@435	2913	// and finally its static fields
duke@435	2914	inline bool VM_HeapWalkOperation::iterate_over_class(klassOop k) {
duke@435	2915	int i;
duke@435	2916	Klass* klass = klassOop(k)->klass_part();
duke@435	2917
duke@435	2918	if (klass->oop_is_instance()) {
duke@435	2919	instanceKlass* ik = instanceKlass::cast(k);
duke@435	2920
duke@435	2921	// ignore the class if it's has been initialized yet
duke@435	2922	if (!ik->is_linked()) {
duke@435	2923	return true;
duke@435	2924	}
duke@435	2925
duke@435	2926	// get the java mirror
duke@435	2927	oop mirror = klass->java_mirror();
duke@435	2928
duke@435	2929	// super (only if something more interesting than java.lang.Object)
duke@435	2930	klassOop java_super = ik->java_super();
never@1577	2931	if (java_super != NULL && java_super != SystemDictionary::Object_klass()) {
duke@435	2932	oop super = Klass::cast(java_super)->java_mirror();
duke@435	2933	if (!CallbackInvoker::report_superclass_reference(mirror, super)) {
duke@435	2934	return false;
duke@435	2935	}
duke@435	2936	}
duke@435	2937
duke@435	2938	// class loader
duke@435	2939	oop cl = ik->class_loader();
duke@435	2940	if (cl != NULL) {
duke@435	2941	if (!CallbackInvoker::report_class_loader_reference(mirror, cl)) {
duke@435	2942	return false;
duke@435	2943	}
duke@435	2944	}
duke@435	2945
duke@435	2946	// protection domain
duke@435	2947	oop pd = ik->protection_domain();
duke@435	2948	if (pd != NULL) {
duke@435	2949	if (!CallbackInvoker::report_protection_domain_reference(mirror, pd)) {
duke@435	2950	return false;
duke@435	2951	}
duke@435	2952	}
duke@435	2953
duke@435	2954	// signers
duke@435	2955	oop signers = ik->signers();
duke@435	2956	if (signers != NULL) {
duke@435	2957	if (!CallbackInvoker::report_signers_reference(mirror, signers)) {
duke@435	2958	return false;
duke@435	2959	}
duke@435	2960	}
duke@435	2961
duke@435	2962	// references from the constant pool
duke@435	2963	{
duke@435	2964	const constantPoolOop pool = ik->constants();
duke@435	2965	for (int i = 1; i < pool->length(); i++) {
duke@435	2966	constantTag tag = pool->tag_at(i).value();
duke@435	2967	if (tag.is_string() || tag.is_klass()) {
duke@435	2968	oop entry;
duke@435	2969	if (tag.is_string()) {
duke@435	2970	entry = pool->resolved_string_at(i);
duke@435	2971	assert(java_lang_String::is_instance(entry), "must be string");
duke@435	2972	} else {
duke@435	2973	entry = Klass::cast(pool->resolved_klass_at(i))->java_mirror();
duke@435	2974	}
duke@435	2975	if (!CallbackInvoker::report_constant_pool_reference(mirror, entry, (jint)i)) {
duke@435	2976	return false;
duke@435	2977	}
duke@435	2978	}
duke@435	2979	}
duke@435	2980	}
duke@435	2981
duke@435	2982	// interfaces
duke@435	2983	// (These will already have been reported as references from the constant pool
duke@435	2984	// but are specified by IterateOverReachableObjects and must be reported).
duke@435	2985	objArrayOop interfaces = ik->local_interfaces();
duke@435	2986	for (i = 0; i < interfaces->length(); i++) {
duke@435	2987	oop interf = Klass::cast((klassOop)interfaces->obj_at(i))->java_mirror();
duke@435	2988	if (interf == NULL) {
duke@435	2989	continue;
duke@435	2990	}
duke@435	2991	if (!CallbackInvoker::report_interface_reference(mirror, interf)) {
duke@435	2992	return false;
duke@435	2993	}
duke@435	2994	}
duke@435	2995
duke@435	2996	// iterate over the static fields
duke@435	2997
duke@435	2998	ClassFieldMap* field_map = ClassFieldMap::create_map_of_static_fields(k);
duke@435	2999	for (i=0; i<field_map->field_count(); i++) {
duke@435	3000	ClassFieldDescriptor* field = field_map->field_at(i);
duke@435	3001	char type = field->field_type();
duke@435	3002	if (!is_primitive_field_type(type)) {
coleenp@548	3003	oop fld_o = k->obj_field(field->field_offset());
coleenp@548	3004	assert(verify_static_oop(ik, k, field->field_offset()), "sanity check");
duke@435	3005	if (fld_o != NULL) {
duke@435	3006	int slot = field->field_index();
duke@435	3007	if (!CallbackInvoker::report_static_field_reference(mirror, fld_o, slot)) {
duke@435	3008	delete field_map;
duke@435	3009	return false;
duke@435	3010	}
duke@435	3011	}
duke@435	3012	} else {
duke@435	3013	if (is_reporting_primitive_fields()) {
duke@435	3014	address addr = (address)k + field->field_offset();
duke@435	3015	int slot = field->field_index();
duke@435	3016	if (!CallbackInvoker::report_primitive_static_field(mirror, slot, addr, type)) {
duke@435	3017	delete field_map;
duke@435	3018	return false;
duke@435	3019	}
duke@435	3020	}
duke@435	3021	}
duke@435	3022	}
duke@435	3023	delete field_map;
duke@435	3024
duke@435	3025	return true;
duke@435	3026	}
duke@435	3027
duke@435	3028	return true;
duke@435	3029	}
duke@435	3030
duke@435	3031	// an object references a class and its instance fields
duke@435	3032	// (static fields are ignored here as we report these as
duke@435	3033	// references from the class).
duke@435	3034	inline bool VM_HeapWalkOperation::iterate_over_object(oop o) {
duke@435	3035	// reference to the class
duke@435	3036	if (!CallbackInvoker::report_class_reference(o, Klass::cast(o->klass())->java_mirror())) {
duke@435	3037	return false;
duke@435	3038	}
duke@435	3039
duke@435	3040	// iterate over instance fields
duke@435	3041	ClassFieldMap* field_map = JvmtiCachedClassFieldMap::get_map_of_instance_fields(o);
duke@435	3042	for (int i=0; i<field_map->field_count(); i++) {
duke@435	3043	ClassFieldDescriptor* field = field_map->field_at(i);
duke@435	3044	char type = field->field_type();
duke@435	3045	if (!is_primitive_field_type(type)) {
coleenp@548	3046	oop fld_o = o->obj_field(field->field_offset());
duke@435	3047	if (fld_o != NULL) {
duke@435	3048	// reflection code may have a reference to a klassOop.
duke@435	3049	// - see sun.reflect.UnsafeStaticFieldAccessorImpl and sun.misc.Unsafe
duke@435	3050	if (fld_o->is_klass()) {
duke@435	3051	klassOop k = (klassOop)fld_o;
duke@435	3052	fld_o = Klass::cast(k)->java_mirror();
duke@435	3053	}
duke@435	3054	int slot = field->field_index();
duke@435	3055	if (!CallbackInvoker::report_field_reference(o, fld_o, slot)) {
duke@435	3056	return false;
duke@435	3057	}
duke@435	3058	}
duke@435	3059	} else {
duke@435	3060	if (is_reporting_primitive_fields()) {
duke@435	3061	// primitive instance field
duke@435	3062	address addr = (address)o + field->field_offset();
duke@435	3063	int slot = field->field_index();
duke@435	3064	if (!CallbackInvoker::report_primitive_instance_field(o, slot, addr, type)) {
duke@435	3065	return false;
duke@435	3066	}
duke@435	3067	}
duke@435	3068	}
duke@435	3069	}
duke@435	3070
duke@435	3071	// if the object is a java.lang.String
duke@435	3072	if (is_reporting_string_values() &&
never@1577	3073	o->klass() == SystemDictionary::String_klass()) {
duke@435	3074	if (!CallbackInvoker::report_string_value(o)) {
duke@435	3075	return false;
duke@435	3076	}
duke@435	3077	}
duke@435	3078	return true;
duke@435	3079	}
duke@435	3080
duke@435	3081
duke@435	3082	// collects all simple (non-stack) roots.
duke@435	3083	// if there's a heap root callback provided then the callback is
duke@435	3084	// invoked for each simple root.
duke@435	3085	// if an object reference callback is provided then all simple
duke@435	3086	// roots are pushed onto the marking stack so that they can be
duke@435	3087	// processed later
duke@435	3088	//
duke@435	3089	inline bool VM_HeapWalkOperation::collect_simple_roots() {
duke@435	3090	SimpleRootsClosure blk;
duke@435	3091
duke@435	3092	// JNI globals
duke@435	3093	blk.set_kind(JVMTI_HEAP_REFERENCE_JNI_GLOBAL);
duke@435	3094	JNIHandles::oops_do(&blk);
duke@435	3095	if (blk.stopped()) {
duke@435	3096	return false;
duke@435	3097	}
duke@435	3098
duke@435	3099	// Preloaded classes and loader from the system dictionary
duke@435	3100	blk.set_kind(JVMTI_HEAP_REFERENCE_SYSTEM_CLASS);
duke@435	3101	SystemDictionary::always_strong_oops_do(&blk);
duke@435	3102	if (blk.stopped()) {
duke@435	3103	return false;
duke@435	3104	}
duke@435	3105
duke@435	3106	// Inflated monitors
duke@435	3107	blk.set_kind(JVMTI_HEAP_REFERENCE_MONITOR);
duke@435	3108	ObjectSynchronizer::oops_do(&blk);
duke@435	3109	if (blk.stopped()) {
duke@435	3110	return false;
duke@435	3111	}
duke@435	3112
duke@435	3113	// Threads
duke@435	3114	for (JavaThread* thread = Threads::first(); thread != NULL ; thread = thread->next()) {
duke@435	3115	oop threadObj = thread->threadObj();
duke@435	3116	if (threadObj != NULL && !thread->is_exiting() && !thread->is_hidden_from_external_view()) {
duke@435	3117	bool cont = CallbackInvoker::report_simple_root(JVMTI_HEAP_REFERENCE_THREAD, threadObj);
duke@435	3118	if (!cont) {
duke@435	3119	return false;
duke@435	3120	}
duke@435	3121	}
duke@435	3122	}
duke@435	3123
duke@435	3124	// Other kinds of roots maintained by HotSpot
duke@435	3125	// Many of these won't be visible but others (such as instances of important
duke@435	3126	// exceptions) will be visible.
duke@435	3127	blk.set_kind(JVMTI_HEAP_REFERENCE_OTHER);
duke@435	3128	Universe::oops_do(&blk);
jrose@1424	3129
jrose@1424	3130	// If there are any non-perm roots in the code cache, visit them.
jrose@1424	3131	blk.set_kind(JVMTI_HEAP_REFERENCE_OTHER);
jrose@1424	3132	CodeBlobToOopClosure look_in_blobs(&blk, false);
jrose@1424	3133	CodeCache::scavenge_root_nmethods_do(&look_in_blobs);
jrose@1424	3134
duke@435	3135	return true;
duke@435	3136	}
duke@435	3137
duke@435	3138	// Walk the stack of a given thread and find all references (locals
duke@435	3139	// and JNI calls) and report these as stack references
duke@435	3140	inline bool VM_HeapWalkOperation::collect_stack_roots(JavaThread* java_thread,
duke@435	3141	JNILocalRootsClosure* blk)
duke@435	3142	{
duke@435	3143	oop threadObj = java_thread->threadObj();
duke@435	3144	assert(threadObj != NULL, "sanity check");
duke@435	3145
duke@435	3146	// only need to get the thread's tag once per thread
duke@435	3147	jlong thread_tag = tag_for(_tag_map, threadObj);
duke@435	3148
duke@435	3149	// also need the thread id
duke@435	3150	jlong tid = java_lang_Thread::thread_id(threadObj);
duke@435	3151
duke@435	3152
duke@435	3153	if (java_thread->has_last_Java_frame()) {
duke@435	3154
duke@435	3155	// vframes are resource allocated
duke@435	3156	Thread* current_thread = Thread::current();
duke@435	3157	ResourceMark rm(current_thread);
duke@435	3158	HandleMark hm(current_thread);
duke@435	3159
duke@435	3160	RegisterMap reg_map(java_thread);
duke@435	3161	frame f = java_thread->last_frame();
duke@435	3162	vframe* vf = vframe::new_vframe(&f, &reg_map, java_thread);
duke@435	3163
duke@435	3164	bool is_top_frame = true;
duke@435	3165	int depth = 0;
duke@435	3166	frame* last_entry_frame = NULL;
duke@435	3167
duke@435	3168	while (vf != NULL) {
duke@435	3169	if (vf->is_java_frame()) {
duke@435	3170
duke@435	3171	// java frame (interpreted, compiled, ...)
duke@435	3172	javaVFrame *jvf = javaVFrame::cast(vf);
duke@435	3173
duke@435	3174	// the jmethodID
duke@435	3175	jmethodID method = jvf->method()->jmethod_id();
duke@435	3176
duke@435	3177	if (!(jvf->method()->is_native())) {
duke@435	3178	jlocation bci = (jlocation)jvf->bci();
duke@435	3179	StackValueCollection* locals = jvf->locals();
duke@435	3180	for (int slot=0; slot<locals->size(); slot++) {
duke@435	3181	if (locals->at(slot)->type() == T_OBJECT) {
duke@435	3182	oop o = locals->obj_at(slot)();
duke@435	3183	if (o == NULL) {
duke@435	3184	continue;
duke@435	3185	}
duke@435	3186
duke@435	3187	// stack reference
duke@435	3188	if (!CallbackInvoker::report_stack_ref_root(thread_tag, tid, depth, method,
duke@435	3189	bci, slot, o)) {
duke@435	3190	return false;
duke@435	3191	}
duke@435	3192	}
duke@435	3193	}
duke@435	3194	} else {
duke@435	3195	blk->set_context(thread_tag, tid, depth, method);
duke@435	3196	if (is_top_frame) {
duke@435	3197	// JNI locals for the top frame.
duke@435	3198	java_thread->active_handles()->oops_do(blk);
duke@435	3199	} else {
duke@435	3200	if (last_entry_frame != NULL) {
duke@435	3201	// JNI locals for the entry frame
duke@435	3202	assert(last_entry_frame->is_entry_frame(), "checking");
duke@435	3203	last_entry_frame->entry_frame_call_wrapper()->handles()->oops_do(blk);
duke@435	3204	}
duke@435	3205	}
duke@435	3206	}
duke@435	3207	last_entry_frame = NULL;
duke@435	3208	depth++;
duke@435	3209	} else {
duke@435	3210	// externalVFrame - for an entry frame then we report the JNI locals
duke@435	3211	// when we find the corresponding javaVFrame
duke@435	3212	frame* fr = vf->frame_pointer();
duke@435	3213	assert(fr != NULL, "sanity check");
duke@435	3214	if (fr->is_entry_frame()) {
duke@435	3215	last_entry_frame = fr;
duke@435	3216	}
duke@435	3217	}
duke@435	3218
duke@435	3219	vf = vf->sender();
duke@435	3220	is_top_frame = false;
duke@435	3221	}
duke@435	3222	} else {
duke@435	3223	// no last java frame but there may be JNI locals
duke@435	3224	blk->set_context(thread_tag, tid, 0, (jmethodID)NULL);
duke@435	3225	java_thread->active_handles()->oops_do(blk);
duke@435	3226	}
duke@435	3227	return true;
duke@435	3228	}
duke@435	3229
duke@435	3230
duke@435	3231	// collects all stack roots - for each thread it walks the execution
duke@435	3232	// stack to find all references and local JNI refs.
duke@435	3233	inline bool VM_HeapWalkOperation::collect_stack_roots() {
duke@435	3234	JNILocalRootsClosure blk;
duke@435	3235	for (JavaThread* thread = Threads::first(); thread != NULL ; thread = thread->next()) {
duke@435	3236	oop threadObj = thread->threadObj();
duke@435	3237	if (threadObj != NULL && !thread->is_exiting() && !thread->is_hidden_from_external_view()) {
duke@435	3238	if (!collect_stack_roots(thread, &blk)) {
duke@435	3239	return false;
duke@435	3240	}
duke@435	3241	}
duke@435	3242	}
duke@435	3243	return true;
duke@435	3244	}
duke@435	3245
duke@435	3246	// visit an object
duke@435	3247	// first mark the object as visited
duke@435	3248	// second get all the outbound references from this object (in other words, all
duke@435	3249	// the objects referenced by this object).
duke@435	3250	//
duke@435	3251	bool VM_HeapWalkOperation::visit(oop o) {
duke@435	3252	// mark object as visited
duke@435	3253	assert(!ObjectMarker::visited(o), "can't visit same object more than once");
duke@435	3254	ObjectMarker::mark(o);
duke@435	3255
duke@435	3256	// instance
duke@435	3257	if (o->is_instance()) {
never@1577	3258	if (o->klass() == SystemDictionary::Class_klass()) {
duke@435	3259	o = klassOop_if_java_lang_Class(o);
duke@435	3260	if (o->is_klass()) {
duke@435	3261	// a java.lang.Class
duke@435	3262	return iterate_over_class(klassOop(o));
duke@435	3263	}
duke@435	3264	} else {
duke@435	3265	return iterate_over_object(o);
duke@435	3266	}
duke@435	3267	}
duke@435	3268
duke@435	3269	// object array
duke@435	3270	if (o->is_objArray()) {
duke@435	3271	return iterate_over_array(o);
duke@435	3272	}
duke@435	3273
duke@435	3274	// type array
duke@435	3275	if (o->is_typeArray()) {
duke@435	3276	return iterate_over_type_array(o);
duke@435	3277	}
duke@435	3278
duke@435	3279	return true;
duke@435	3280	}
duke@435	3281
duke@435	3282	void VM_HeapWalkOperation::doit() {
duke@435	3283	ResourceMark rm;
duke@435	3284	ObjectMarkerController marker;
duke@435	3285	ClassFieldMapCacheMark cm;
duke@435	3286
duke@435	3287	assert(visit_stack()->is_empty(), "visit stack must be empty");
duke@435	3288
duke@435	3289	// the heap walk starts with an initial object or the heap roots
duke@435	3290	if (initial_object().is_null()) {
duke@435	3291	if (!collect_simple_roots()) return;
duke@435	3292	if (!collect_stack_roots()) return;
duke@435	3293	} else {
duke@435	3294	visit_stack()->push(initial_object()());
duke@435	3295	}
duke@435	3296
duke@435	3297	// object references required
duke@435	3298	if (is_following_references()) {
duke@435	3299
duke@435	3300	// visit each object until all reachable objects have been
duke@435	3301	// visited or the callback asked to terminate the iteration.
duke@435	3302	while (!visit_stack()->is_empty()) {
duke@435	3303	oop o = visit_stack()->pop();
duke@435	3304	if (!ObjectMarker::visited(o)) {
duke@435	3305	if (!visit(o)) {
duke@435	3306	break;
duke@435	3307	}
duke@435	3308	}
duke@435	3309	}
duke@435	3310	}
duke@435	3311	}
duke@435	3312
duke@435	3313	// iterate over all objects that are reachable from a set of roots
duke@435	3314	void JvmtiTagMap::iterate_over_reachable_objects(jvmtiHeapRootCallback heap_root_callback,
duke@435	3315	jvmtiStackReferenceCallback stack_ref_callback,
duke@435	3316	jvmtiObjectReferenceCallback object_ref_callback,
duke@435	3317	const void* user_data) {
duke@435	3318	MutexLocker ml(Heap_lock);
duke@435	3319	BasicHeapWalkContext context(heap_root_callback, stack_ref_callback, object_ref_callback);
duke@435	3320	VM_HeapWalkOperation op(this, Handle(), context, user_data);
duke@435	3321	VMThread::execute(&op);
duke@435	3322	}
duke@435	3323
duke@435	3324	// iterate over all objects that are reachable from a given object
duke@435	3325	void JvmtiTagMap::iterate_over_objects_reachable_from_object(jobject object,
duke@435	3326	jvmtiObjectReferenceCallback object_ref_callback,
duke@435	3327	const void* user_data) {
duke@435	3328	oop obj = JNIHandles::resolve(object);
duke@435	3329	Handle initial_object(Thread::current(), obj);
duke@435	3330
duke@435	3331	MutexLocker ml(Heap_lock);
duke@435	3332	BasicHeapWalkContext context(NULL, NULL, object_ref_callback);
duke@435	3333	VM_HeapWalkOperation op(this, initial_object, context, user_data);
duke@435	3334	VMThread::execute(&op);
duke@435	3335	}
duke@435	3336
duke@435	3337	// follow references from an initial object or the GC roots
duke@435	3338	void JvmtiTagMap::follow_references(jint heap_filter,
duke@435	3339	KlassHandle klass,
duke@435	3340	jobject object,
duke@435	3341	const jvmtiHeapCallbacks* callbacks,
duke@435	3342	const void* user_data)
duke@435	3343	{
duke@435	3344	oop obj = JNIHandles::resolve(object);
duke@435	3345	Handle initial_object(Thread::current(), obj);
duke@435	3346
duke@435	3347	MutexLocker ml(Heap_lock);
duke@435	3348	AdvancedHeapWalkContext context(heap_filter, klass, callbacks);
duke@435	3349	VM_HeapWalkOperation op(this, initial_object, context, user_data);
duke@435	3350	VMThread::execute(&op);
duke@435	3351	}
duke@435	3352
duke@435	3353
duke@435	3354	// called post-GC
duke@435	3355	// - for each JVMTI environment with an object tag map, call its rehash
duke@435	3356	// function to re-sync with the new object locations.
duke@435	3357	void JvmtiTagMap::gc_epilogue(bool full) {
duke@435	3358	assert(SafepointSynchronize::is_at_safepoint(), "must be executed at a safepoint");
duke@435	3359	if (JvmtiEnv::environments_might_exist()) {
duke@435	3360	// re-obtain the memory region for the young generation (might
duke@435	3361	// changed due to adaptive resizing policy)
duke@435	3362	get_young_generation();
duke@435	3363
duke@435	3364	JvmtiEnvIterator it;
duke@435	3365	for (JvmtiEnvBase* env = it.first(); env != NULL; env = it.next(env)) {
duke@435	3366	JvmtiTagMap* tag_map = env->tag_map();
duke@435	3367	if (tag_map != NULL && !tag_map->is_empty()) {
duke@435	3368	TraceTime t(full ? "JVMTI Full Rehash " : "JVMTI Rehash ", TraceJVMTIObjectTagging);
duke@435	3369	if (full) {
duke@435	3370	tag_map->rehash(0, n_hashmaps);
duke@435	3371	} else {
duke@435	3372	tag_map->rehash(0, 0); // tag map for young gen only
duke@435	3373	}
duke@435	3374	}
duke@435	3375	}
duke@435	3376	}
duke@435	3377	}
duke@435	3378
duke@435	3379	// CMS has completed referencing processing so we may have JNI weak refs
duke@435	3380	// to objects in the CMS generation that have been GC'ed.
duke@435	3381	void JvmtiTagMap::cms_ref_processing_epilogue() {
duke@435	3382	assert(SafepointSynchronize::is_at_safepoint(), "must be executed at a safepoint");
duke@435	3383	assert(UseConcMarkSweepGC, "should only be used with CMS");
duke@435	3384	if (JvmtiEnv::environments_might_exist()) {
duke@435	3385	JvmtiEnvIterator it;
duke@435	3386	for (JvmtiEnvBase* env = it.first(); env != NULL; env = it.next(env)) {
duke@435	3387	JvmtiTagMap* tag_map = ((JvmtiEnvBase *)env)->tag_map();
duke@435	3388	if (tag_map != NULL && !tag_map->is_empty()) {
duke@435	3389	TraceTime t("JVMTI Rehash (CMS) ", TraceJVMTIObjectTagging);
duke@435	3390	tag_map->rehash(1, n_hashmaps); // assume CMS not used in young gen
duke@435	3391	}
duke@435	3392	}
duke@435	3393	}
duke@435	3394	}
duke@435	3395
duke@435	3396
duke@435	3397	// For each entry in the hashmaps 'start' to 'end' :
duke@435	3398	//
duke@435	3399	// 1. resolve the JNI weak reference
duke@435	3400	//
duke@435	3401	// 2. If it resolves to NULL it means the object has been freed so the entry
duke@435	3402	// is removed, the weak reference destroyed, and the object free event is
duke@435	3403	// posted (if enabled).
duke@435	3404	//
duke@435	3405	// 3. If the weak reference resolves to an object then we re-hash the object
duke@435	3406	// to see if it has moved or has been promoted (from the young to the old
duke@435	3407	// generation for example).
duke@435	3408	//
duke@435	3409	void JvmtiTagMap::rehash(int start, int end) {
duke@435	3410
duke@435	3411	// does this environment have the OBJECT_FREE event enabled
duke@435	3412	bool post_object_free = env()->is_enabled(JVMTI_EVENT_OBJECT_FREE);
duke@435	3413
duke@435	3414	// counters used for trace message
duke@435	3415	int freed = 0;
duke@435	3416	int moved = 0;
duke@435	3417	int promoted = 0;
duke@435	3418
duke@435	3419	// we assume there are two hashmaps - one for the young generation
duke@435	3420	// and the other for all other spaces.
duke@435	3421	assert(n_hashmaps == 2, "not implemented");
duke@435	3422	JvmtiTagHashmap* young_hashmap = _hashmap[0];
duke@435	3423	JvmtiTagHashmap* other_hashmap = _hashmap[1];
duke@435	3424
duke@435	3425	// reenable sizing (if disabled)
duke@435	3426	young_hashmap->set_resizing_enabled(true);
duke@435	3427	other_hashmap->set_resizing_enabled(true);
duke@435	3428
duke@435	3429	// when re-hashing the hashmap corresponding to the young generation we
duke@435	3430	// collect the entries corresponding to objects that have been promoted.
duke@435	3431	JvmtiTagHashmapEntry* promoted_entries = NULL;
duke@435	3432
duke@435	3433	if (end >= n_hashmaps) {
duke@435	3434	end = n_hashmaps - 1;
duke@435	3435	}
duke@435	3436
duke@435	3437	for (int i=start; i <= end; i++) {
duke@435	3438	JvmtiTagHashmap* hashmap = _hashmap[i];
duke@435	3439
duke@435	3440	// if the hashmap is empty then we can skip it
duke@435	3441	if (hashmap->_entry_count == 0) {
duke@435	3442	continue;
duke@435	3443	}
duke@435	3444
duke@435	3445	// now iterate through each entry in the table
duke@435	3446
duke@435	3447	JvmtiTagHashmapEntry** table = hashmap->table();
duke@435	3448	int size = hashmap->size();
duke@435	3449
duke@435	3450	for (int pos=0; pos<size; pos++) {
duke@435	3451	JvmtiTagHashmapEntry* entry = table[pos];
duke@435	3452	JvmtiTagHashmapEntry* prev = NULL;
duke@435	3453
duke@435	3454	while (entry != NULL) {
duke@435	3455	JvmtiTagHashmapEntry* next = entry->next();
duke@435	3456
duke@435	3457	jweak ref = entry->object();
duke@435	3458	oop oop = JNIHandles::resolve(ref);
duke@435	3459
duke@435	3460	// has object been GC'ed
duke@435	3461	if (oop == NULL) {
duke@435	3462	// grab the tag
duke@435	3463	jlong tag = entry->tag();
duke@435	3464	guarantee(tag != 0, "checking");
duke@435	3465
duke@435	3466	// remove GC'ed entry from hashmap and return the
duke@435	3467	// entry to the free list
duke@435	3468	hashmap->remove(prev, pos, entry);
duke@435	3469	destroy_entry(entry);
duke@435	3470
duke@435	3471	// destroy the weak ref
duke@435	3472	JNIHandles::destroy_weak_global(ref);
duke@435	3473
duke@435	3474	// post the event to the profiler
duke@435	3475	if (post_object_free) {
duke@435	3476	JvmtiExport::post_object_free(env(), tag);
duke@435	3477	}
duke@435	3478
duke@435	3479	freed++;
duke@435	3480	entry = next;
duke@435	3481	continue;
duke@435	3482	}
duke@435	3483
duke@435	3484	// if this is the young hashmap then the object is either promoted
duke@435	3485	// or moved.
duke@435	3486	// if this is the other hashmap then the object is moved.
duke@435	3487
duke@435	3488	bool same_gen;
duke@435	3489	if (i == 0) {
duke@435	3490	assert(hashmap == young_hashmap, "checking");
duke@435	3491	same_gen = is_in_young(oop);
duke@435	3492	} else {
duke@435	3493	same_gen = true;
duke@435	3494	}
duke@435	3495
duke@435	3496
duke@435	3497	if (same_gen) {
duke@435	3498	// if the object has moved then re-hash it and move its
duke@435	3499	// entry to its new location.
duke@435	3500	unsigned int new_pos = JvmtiTagHashmap::hash(oop, size);
duke@435	3501	if (new_pos != (unsigned int)pos) {
duke@435	3502	if (prev == NULL) {
duke@435	3503	table[pos] = next;
duke@435	3504	} else {
duke@435	3505	prev->set_next(next);
duke@435	3506	}
duke@435	3507	entry->set_next(table[new_pos]);
duke@435	3508	table[new_pos] = entry;
duke@435	3509	moved++;
duke@435	3510	} else {
duke@435	3511	// object didn't move
duke@435	3512	prev = entry;
duke@435	3513	}
duke@435	3514	} else {
duke@435	3515	// object has been promoted so remove the entry from the
duke@435	3516	// young hashmap
duke@435	3517	assert(hashmap == young_hashmap, "checking");
duke@435	3518	hashmap->remove(prev, pos, entry);
duke@435	3519
duke@435	3520	// move the entry to the promoted list
duke@435	3521	entry->set_next(promoted_entries);
duke@435	3522	promoted_entries = entry;
duke@435	3523	}
duke@435	3524
duke@435	3525	entry = next;
duke@435	3526	}
duke@435	3527	}
duke@435	3528	}
duke@435	3529
duke@435	3530
duke@435	3531	// add the entries, corresponding to the promoted objects, to the
duke@435	3532	// other hashmap.
duke@435	3533	JvmtiTagHashmapEntry* entry = promoted_entries;
duke@435	3534	while (entry != NULL) {
duke@435	3535	oop o = JNIHandles::resolve(entry->object());
duke@435	3536	assert(hashmap_for(o) == other_hashmap, "checking");
duke@435	3537	JvmtiTagHashmapEntry* next = entry->next();
duke@435	3538	other_hashmap->add(o, entry);
duke@435	3539	entry = next;
duke@435	3540	promoted++;
duke@435	3541	}
duke@435	3542
duke@435	3543	// stats
duke@435	3544	if (TraceJVMTIObjectTagging) {
duke@435	3545	int total_moves = promoted + moved;
duke@435	3546
duke@435	3547	int post_total = 0;
duke@435	3548	for (int i=0; i<n_hashmaps; i++) {
duke@435	3549	post_total += _hashmap[i]->_entry_count;
duke@435	3550	}
duke@435	3551	int pre_total = post_total + freed;
duke@435	3552
duke@435	3553	tty->print("(%d->%d, %d freed, %d promoted, %d total moves)",
duke@435	3554	pre_total, post_total, freed, promoted, total_moves);
duke@435	3555	}
duke@435	3556	}