compileBroker.cpp source code [OpenJDK/src/hotspot/share/compiler/compileBroker.cpp]

1	/*
2	* Copyright (c) 1999, 2019, Oracle and/or its affiliates. All rights reserved.
3	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
4	*
5	* This code is free software; you can redistribute it and/or modify it
6	* under the terms of the GNU General Public License version 2 only, as
7	* published by the Free Software Foundation.
8	*
9	* This code is distributed in the hope that it will be useful, but WITHOUT
10	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
11	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
12	* version 2 for more details (a copy is included in the LICENSE file that
13	* accompanied this code).
14	*
15	* You should have received a copy of the GNU General Public License version
16	* 2 along with this work; if not, write to the Free Software Foundation,
17	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
18	*
19	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
20	* or visit www.oracle.com if you need additional information or have any
21	* questions.
22	*
23	*/
24
25	#include "precompiled.hpp"
26	#include "jvm.h"
27	#include "classfile/symbolTable.hpp"
28	#include "classfile/systemDictionary.hpp"
29	#include "classfile/vmSymbols.hpp"
30	#include "code/codeCache.hpp"
31	#include "code/codeHeapState.hpp"
32	#include "code/dependencyContext.hpp"
33	#include "compiler/compileBroker.hpp"
34	#include "compiler/compileLog.hpp"
35	#include "compiler/compilerOracle.hpp"
36	#include "compiler/directivesParser.hpp"
37	#include "interpreter/linkResolver.hpp"
38	#include "jfr/jfrEvents.hpp"
39	#include "logging/log.hpp"
40	#include "logging/logStream.hpp"
41	#include "memory/allocation.inline.hpp"
42	#include "memory/resourceArea.hpp"
43	#include "memory/universe.hpp"
44	#include "oops/methodData.hpp"
45	#include "oops/method.inline.hpp"
46	#include "oops/oop.inline.hpp"
47	#include "prims/nativeLookup.hpp"
48	#include "prims/whitebox.hpp"
49	#include "runtime/arguments.hpp"
50	#include "runtime/atomic.hpp"
51	#include "runtime/compilationPolicy.hpp"
52	#include "runtime/handles.inline.hpp"
53	#include "runtime/init.hpp"
54	#include "runtime/interfaceSupport.inline.hpp"
55	#include "runtime/javaCalls.hpp"
56	#include "runtime/jniHandles.inline.hpp"
57	#include "runtime/os.hpp"
58	#include "runtime/safepointVerifiers.hpp"
59	#include "runtime/sharedRuntime.hpp"
60	#include "runtime/sweeper.hpp"
61	#include "runtime/timerTrace.hpp"
62	#include "runtime/vframe.inline.hpp"
63	#include "utilities/debug.hpp"
64	#include "utilities/dtrace.hpp"
65	#include "utilities/events.hpp"
66	#include "utilities/formatBuffer.hpp"
67	#include "utilities/macros.hpp"
68	#ifdef COMPILER1
69	#include "c1/c1_Compiler.hpp"
70	#endif
71	#if INCLUDE_JVMCI
72	#include "jvmci/jvmciEnv.hpp"
73	#include "jvmci/jvmciRuntime.hpp"
74	#endif
75	#ifdef COMPILER2
76	#include "opto/c2compiler.hpp"
77	#endif
78
79	#ifdef DTRACE_ENABLED
80
81	// Only bother with this argument setup if dtrace is available
82
83	#define DTRACE_METHOD_COMPILE_BEGIN_PROBE(method, comp_name) \
84	{ \
85	Symbol* klass_name = (method)->klass_name(); \
86	Symbol* name = (method)->name(); \
87	Symbol* signature = (method)->signature(); \
88	HOTSPOT_METHOD_COMPILE_BEGIN( \
89	(char *) comp_name, strlen(comp_name), \
90	(char *) klass_name->bytes(), klass_name->utf8_length(), \
91	(char *) name->bytes(), name->utf8_length(), \
92	(char *) signature->bytes(), signature->utf8_length()); \
93	}
94
95	#define DTRACE_METHOD_COMPILE_END_PROBE(method, comp_name, success) \
96	{ \
97	Symbol* klass_name = (method)->klass_name(); \
98	Symbol* name = (method)->name(); \
99	Symbol* signature = (method)->signature(); \
100	HOTSPOT_METHOD_COMPILE_END( \
101	(char *) comp_name, strlen(comp_name), \
102	(char *) klass_name->bytes(), klass_name->utf8_length(), \
103	(char *) name->bytes(), name->utf8_length(), \
104	(char *) signature->bytes(), signature->utf8_length(), (success)); \
105	}
106
107	#else // ndef DTRACE_ENABLED
108
109	#define DTRACE_METHOD_COMPILE_BEGIN_PROBE(method, comp_name)
110	#define DTRACE_METHOD_COMPILE_END_PROBE(method, comp_name, success)
111
112	#endif // ndef DTRACE_ENABLED
113
114	bool CompileBroker::_initialized = false;
115	volatile bool CompileBroker::_should_block = false;
116	volatile int CompileBroker::_print_compilation_warning = `0`;
117	volatile jint CompileBroker::_should_compile_new_jobs = run_compilation;
118
119	// The installed compiler(s)
120	AbstractCompiler* CompileBroker::_compilers[`2`];
121
122	// The maximum numbers of compiler threads to be determined during startup.
123	int CompileBroker::_c1_count = `0`;
124	int CompileBroker::_c2_count = `0`;
125
126	// An array of compiler names as Java String objects
127	jobject* CompileBroker::_compiler1_objects = NULL;
128	jobject* CompileBroker::_compiler2_objects = NULL;
129
130	CompileLog** CompileBroker::_compiler1_logs = NULL;
131	CompileLog** CompileBroker::_compiler2_logs = NULL;
132
133	// These counters are used to assign an unique ID to each compilation.
134	volatile jint CompileBroker::_compilation_id = `0`;
135	volatile jint CompileBroker::_osr_compilation_id = `0`;
136
137	// Performance counters
138	PerfCounter* CompileBroker::_perf_total_compilation = NULL;
139	PerfCounter* CompileBroker::_perf_osr_compilation = NULL;
140	PerfCounter* CompileBroker::_perf_standard_compilation = NULL;
141
142	PerfCounter* CompileBroker::_perf_total_bailout_count = NULL;
143	PerfCounter* CompileBroker::_perf_total_invalidated_count = NULL;
144	PerfCounter* CompileBroker::_perf_total_compile_count = NULL;
145	PerfCounter* CompileBroker::_perf_total_osr_compile_count = NULL;
146	PerfCounter* CompileBroker::_perf_total_standard_compile_count = NULL;
147
148	PerfCounter* CompileBroker::_perf_sum_osr_bytes_compiled = NULL;
149	PerfCounter* CompileBroker::_perf_sum_standard_bytes_compiled = NULL;
150	PerfCounter* CompileBroker::_perf_sum_nmethod_size = NULL;
151	PerfCounter* CompileBroker::_perf_sum_nmethod_code_size = NULL;
152
153	PerfStringVariable* CompileBroker::_perf_last_method = NULL;
154	PerfStringVariable* CompileBroker::_perf_last_failed_method = NULL;
155	PerfStringVariable* CompileBroker::_perf_last_invalidated_method = NULL;
156	PerfVariable* CompileBroker::_perf_last_compile_type = NULL;
157	PerfVariable* CompileBroker::_perf_last_compile_size = NULL;
158	PerfVariable* CompileBroker::_perf_last_failed_type = NULL;
159	PerfVariable* CompileBroker::_perf_last_invalidated_type = NULL;
160
161	// Timers and counters for generating statistics
162	elapsedTimer CompileBroker::_t_total_compilation;
163	elapsedTimer CompileBroker::_t_osr_compilation;
164	elapsedTimer CompileBroker::_t_standard_compilation;
165	elapsedTimer CompileBroker::_t_invalidated_compilation;
166	elapsedTimer CompileBroker::_t_bailedout_compilation;
167
168	int CompileBroker::_total_bailout_count = `0`;
169	int CompileBroker::_total_invalidated_count = `0`;
170	int CompileBroker::_total_compile_count = `0`;
171	int CompileBroker::_total_osr_compile_count = `0`;
172	int CompileBroker::_total_standard_compile_count = `0`;
173	int CompileBroker::_total_compiler_stopped_count = `0`;
174	int CompileBroker::_total_compiler_restarted_count = `0`;
175
176	int CompileBroker::_sum_osr_bytes_compiled = `0`;
177	int CompileBroker::_sum_standard_bytes_compiled = `0`;
178	int CompileBroker::_sum_nmethod_size = `0`;
179	int CompileBroker::_sum_nmethod_code_size = `0`;
180
181	long CompileBroker::_peak_compilation_time = `0`;
182
183	CompileQueue* CompileBroker::_c2_compile_queue = NULL;
184	CompileQueue* CompileBroker::_c1_compile_queue = NULL;
185
186
187
188	class CompilationLog : public StringEventLog {
189	public:
190	CompilationLog() : StringEventLog ("Compilation events", "jit") {
191	}
192
193	void log_compile(JavaThread* thread, CompileTask* task) {
194	StringLogMessage lm;
195	stringStream sstr(lm.buffer(), lm.size());
196	// msg.time_stamp().update_to(tty->time_stamp().ticks());
197	task->print(&sstr, NULL, true, false);
198	log(thread, "%s", (const char*)lm);
199	}
200
201	void log_nmethod(JavaThread* thread, nmethod* nm) {
202	log(thread, "nmethod %d%s " INTPTR_FORMAT " code [" INTPTR_FORMAT ", " INTPTR_FORMAT "]",
203	nm->compile_id(), nm->is_osr_method() ? "%" : "",
204	p2i(nm), p2i(nm->code_begin()), p2i(nm->code_end()));
205	}
206
207	void log_failure(JavaThread* thread, CompileTask* task, const char* reason, const char* retry_message) {
208	StringLogMessage lm;
209	lm.print("%4d COMPILE SKIPPED: %s", task->compile_id(), reason);
210	if (retry_message != NULL) {
211	lm.append(" (%s)", retry_message);
212	}
213	lm.print("\n");
214	log(thread, "%s", (const char*)lm);
215	}
216
217	void log_metaspace_failure(const char* reason) {
218	ResourceMark rm;
219	StringLogMessage lm;
220	lm.print("%4d COMPILE PROFILING SKIPPED: %s", -`1`, reason);
221	lm.print("\n");
222	log(JavaThread::current(), "%s", (const char*)lm);
223	}
224	};
225
226	static CompilationLog* _compilation_log = NULL;
227
228	bool compileBroker_init() {
229	if (LogEvents) {
230	_compilation_log = new CompilationLog ();
231	}
232
233	// init directives stack, adding default directive
234	DirectivesStack::init();
235
236	if (DirectivesParser::has_file()) {
237	return DirectivesParser::parse_from_flag();
238	} else if (CompilerDirectivesPrint) {
239	// Print default directive even when no other was added
240	DirectivesStack::print(tty);
241	}
242
243	return true;
244	}
245
246	CompileTaskWrapper::CompileTaskWrapper(CompileTask* task) {
247	CompilerThread* thread = CompilerThread::current();
248	thread->set_task(task);
249	#if INCLUDE_JVMCI
250	if (task->is_blocking() && CompileBroker::compiler(task->comp_level())->is_jvmci()) {
251	task->set_jvmci_compiler_thread(thread);
252	}
253	#endif
254	CompileLog* log = thread->log();
255	if (log != NULL && !task->is_unloaded()) task->log_task_start(log);
256	}
257
258	CompileTaskWrapper::~CompileTaskWrapper() {
259	CompilerThread* thread = CompilerThread::current();
260	CompileTask* task = thread->task();
261	CompileLog* log = thread->log();
262	if (log != NULL && !task->is_unloaded()) task->log_task_done(log);
263	thread->set_task(NULL);
264	task->set_code_handle(NULL);
265	thread->set_env(NULL);
266	if (task->is_blocking()) {
267	bool free_task = false;
268	{
269	MutexLocker notifier(task->lock(), thread);
270	task->mark_complete();
271	#if INCLUDE_JVMCI
272	if (CompileBroker::compiler(task->comp_level())->is_jvmci()) {
273	if (!task->has_waiter()) {
274	// The waiting thread timed out and thus did not free the task.
275	free_task = true;
276	}
277	task->set_jvmci_compiler_thread(NULL);
278	}
279	#endif
280	if (!free_task) {
281	// Notify the waiting thread that the compilation has completed
282	// so that it can free the task.
283	task->lock()->notify_all();
284	}
285	}
286	if (free_task) {
287	// The task can only be freed once the task lock is released.
288	CompileTask::free(task);
289	}
290	} else {
291	task->mark_complete();
292
293	// By convention, the compiling thread is responsible for
294	// recycling a non-blocking CompileTask.
295	CompileTask::free(task);
296	}
297	}
298
299	/**
300	* Check if a CompilerThread can be removed and update count if requested.
301	*/
302	static bool can_remove(CompilerThread ct, bool* do_it) {
303	assert(UseDynamicNumberOfCompilerThreads, "or shouldn't be here");
304	if (!ReduceNumberOfCompilerThreads) return false;
305
306	AbstractCompiler *compiler = ct->compiler();
307	int compiler_count = compiler->num_compiler_threads();
308	bool c1 = compiler->is_c1();
309
310	// Keep at least 1 compiler thread of each type.
311	if (compiler_count < `2`) return false;
312
313	// Keep thread alive for at least some time.
314	if (ct->idle_time_millis() < (c1 ? `500` : `100`)) return false;
315
316	// We only allow the last compiler thread of each type to get removed.
317	jobject last_compiler = c1 ? CompileBroker::compiler1_object(compiler_count - `1`)
318	: CompileBroker::compiler2_object(compiler_count - `1`);
319	if (oopDesc::equals(ct->threadObj(), JNIHandles::resolve_non_null(last_compiler))) {
320	if (do_it) {
321	assert_locked_or_safepoint(CompileThread_lock); // Update must be consistent.
322	compiler->set_num_compiler_threads(compiler_count - `1`);
323	}
324	return true;
325	}
326	return false;
327	}
328
329	/**
330	* Add a CompileTask to a CompileQueue.
331	*/
332	void CompileQueue::add(CompileTask* task) {
333	assert(MethodCompileQueue_lock->owned_by_self(), "must own lock");
334
335	task->set_next(NULL);
336	task->set_prev(NULL);
337
338	if (_last == NULL) {
339	// The compile queue is empty.
340	assert(_first == NULL, "queue is empty");
341	_first = task;
342	_last = task;
343	} else {
344	// Append the task to the queue.
345	assert(_last->next() == NULL, "not last");
346	_last->set_next(task);
347	task->set_prev(_last);
348	_last = task;
349	}
350	++_size;
351
352	// Mark the method as being in the compile queue.
353	task->method()->set_queued_for_compilation();
354
355	if (CIPrintCompileQueue) {
356	print_tty();
357	}
358
359	if (LogCompilation && xtty != NULL) {
360	task->log_task_queued();
361	}
362
363	// Notify CompilerThreads that a task is available.
364	MethodCompileQueue_lock->notify_all();
365	}
366
367	/**
368	* Empties compilation queue by putting all compilation tasks onto
369	* a freelist. Furthermore, the method wakes up all threads that are
370	* waiting on a compilation task to finish. This can happen if background
371	* compilation is disabled.
372	*/
373	void CompileQueue::free_all() {
374	MutexLocker mu(MethodCompileQueue_lock);
375	CompileTask* next = _first;
376
377	// Iterate over all tasks in the compile queue
378	while (next != NULL) {
379	CompileTask* current = next;
380	next = current->next();
381	{
382	// Wake up thread that blocks on the compile task.
383	MutexLocker ct_lock(current->lock());
384	current->lock()->notify();
385	}
386	// Put the task back on the freelist.
387	CompileTask::free(current);
388	}
389	_first = NULL;
390
391	// Wake up all threads that block on the queue.
392	MethodCompileQueue_lock->notify_all();
393	}
394
395	/**
396	* Get the next CompileTask from a CompileQueue
397	*/
398	CompileTask* CompileQueue::get() {
399	// save methods from RedefineClasses across safepoint
400	// across MethodCompileQueue_lock below.
401	methodHandle save_method;
402	methodHandle save_hot_method;
403
404	MonitorLocker locker(MethodCompileQueue_lock);
405	// If _first is NULL we have no more compile jobs. There are two reasons for
406	// having no compile jobs: First, we compiled everything we wanted. Second,
407	// we ran out of code cache so compilation has been disabled. In the latter
408	// case we perform code cache sweeps to free memory such that we can re-enable
409	// compilation.
410	while (_first == NULL) {
411	// Exit loop if compilation is disabled forever
412	if (CompileBroker::is_compilation_disabled_forever()) {
413	return NULL;
414	}
415
416	// If there are no compilation tasks and we can compile new jobs
417	// (i.e., there is enough free space in the code cache) there is
418	// no need to invoke the sweeper. As a result, the hotness of methods
419	// remains unchanged. This behavior is desired, since we want to keep
420	// the stable state, i.e., we do not want to evict methods from the
421	// code cache if it is unnecessary.
422	// We need a timed wait here, since compiler threads can exit if compilation
423	// is disabled forever. We use 5 seconds wait time; the exiting of compiler threads
424	// is not critical and we do not want idle compiler threads to wake up too often.
425	locker.wait(`5`*`1000`);
426
427	if (UseDynamicNumberOfCompilerThreads && _first == NULL) {
428	// Still nothing to compile. Give caller a chance to stop this thread.
429	if (can_remove(CompilerThread::current(), false)) return NULL;
430	}
431	}
432
433	if (CompileBroker::is_compilation_disabled_forever()) {
434	return NULL;
435	}
436
437	CompileTask* task;
438	{
439	NoSafepointVerifier nsv;
440	task = CompilationPolicy::policy()->select_task(this);
441	if (task != NULL) {
442	task = task->select_for_compilation();
443	}
444	}
445
446	if (task != NULL) {
447	// Save method pointers across unlock safepoint. The task is removed from
448	// the compilation queue, which is walked during RedefineClasses.
449	save_method = methodHandle (task->method());
450	save_hot_method = methodHandle (task->hot_method());
451
452	remove(task);
453	}
454	purge_stale_tasks(); // may temporarily release MCQ lock
455	return task;
456	}
457
458	// Clean & deallocate stale compile tasks.
459	// Temporarily releases MethodCompileQueue lock.
460	void CompileQueue::purge_stale_tasks() {
461	assert(MethodCompileQueue_lock->owned_by_self(), "must own lock");
462	if (_first_stale != NULL) {
463	// Stale tasks are purged when MCQ lock is released,
464	// but _first_stale updates are protected by MCQ lock.
465	// Once task processing starts and MCQ lock is released,
466	// other compiler threads can reuse _first_stale.
467	CompileTask* head = _first_stale;
468	_first_stale = NULL;
469	{
470	MutexUnlocker ul(MethodCompileQueue_lock);
471	for (CompileTask* task = head; task != NULL; ) {
472	CompileTask* next_task = task->next();
473	CompileTaskWrapper ctw(task); // Frees the task
474	task->set_failure_reason("stale task");
475	task = next_task;
476	}
477	}
478	}
479	}
480
481	void CompileQueue::remove(CompileTask* task) {
482	assert(MethodCompileQueue_lock->owned_by_self(), "must own lock");
483	if (task->prev() != NULL) {
484	task->prev()->set_next(task->next());
485	} else {
486	// max is the first element
487	assert(task == _first, "Sanity");
488	_first = task->next();
489	}
490
491	if (task->next() != NULL) {
492	task->next()->set_prev(task->prev());
493	} else {
494	// max is the last element
495	assert(task == _last, "Sanity");
496	_last = task->prev();
497	}
498	--_size;
499	}
500
501	void CompileQueue::remove_and_mark_stale(CompileTask* task) {
502	assert(MethodCompileQueue_lock->owned_by_self(), "must own lock");
503	remove(task);
504
505	// Enqueue the task for reclamation (should be done outside MCQ lock)
506	task->set_next(_first_stale);
507	task->set_prev(NULL);
508	_first_stale = task;
509	}
510
511	// methods in the compile queue need to be marked as used on the stack
512	// so that they don't get reclaimed by Redefine Classes
513	void CompileQueue::mark_on_stack() {
514	CompileTask* task = _first;
515	while (task != NULL) {
516	task->mark_on_stack();
517	task = task->next();
518	}
519	}
520
521
522	CompileQueue* CompileBroker::compile_queue(int comp_level) {
523	if (is_c2_compile(comp_level)) return _c2_compile_queue;
524	if (is_c1_compile(comp_level)) return _c1_compile_queue;
525	return NULL;
526	}
527
528	void CompileBroker::print_compile_queues(outputStream* st) {
529	st->print_cr("Current compiles: ");
530
531	char buf[`2000`];
532	int buflen = sizeof(buf);
533	Threads::print_threads_compiling(st, buf, buflen, / short_form = / true);
534
535	st->cr();
536	if (_c1_compile_queue != NULL) {
537	_c1_compile_queue->print(st);
538	}
539	if (_c2_compile_queue != NULL) {
540	_c2_compile_queue->print(st);
541	}
542	}
543
544	void CompileQueue::print(outputStream* st) {
545	assert_locked_or_safepoint(MethodCompileQueue_lock);
546	st->print_cr("%s:", name());
547	CompileTask* task = _first;
548	if (task == NULL) {
549	st->print_cr("Empty");
550	} else {
551	while (task != NULL) {
552	task->print(st, NULL, true, true);
553	task = task->next();
554	}
555	}
556	st->cr();
557	}
558
559	void CompileQueue::print_tty() {
560	ttyLocker ttyl;
561	print(tty);
562	}
563
564	CompilerCounters::CompilerCounters() {
565	_current_method[`0`] = `'\0'`;
566	_compile_type = CompileBroker::no_compile;
567	}
568
569	// ------------------------------------------------------------------
570	// CompileBroker::compilation_init
571	//
572	// Initialize the Compilation object
573	void CompileBroker::compilation_init_phase1(TRAPS) {
574	// No need to initialize compilation system if we do not use it.
575	if (!UseCompiler) {
576	return;
577	}
578	// Set the interface to the current compiler(s).
579	_c1_count = CompilationPolicy::policy()->compiler_count(CompLevel_simple);
580	_c2_count = CompilationPolicy::policy()->compiler_count(CompLevel_full_optimization);
581
582	#if INCLUDE_JVMCI
583	if (EnableJVMCI) {
584	// This is creating a JVMCICompiler singleton.
585	JVMCICompiler* jvmci = new JVMCICompiler ();
586
587	if (UseJVMCICompiler) {
588	_compilers[`1`] = jvmci;
589	if (FLAG_IS_DEFAULT(JVMCIThreads)) {
590	if (BootstrapJVMCI) {
591	// JVMCI will bootstrap so give it more threads
592	_c2_count = MIN2(`32`, os::active_processor_count());
593	}
594	} else {
595	_c2_count = JVMCIThreads;
596	}
597	if (FLAG_IS_DEFAULT(JVMCIHostThreads)) {
598	} else {
599	_c1_count = JVMCIHostThreads;
600	}
601	}
602	}
603	#endif // INCLUDE_JVMCI
604
605	#ifdef COMPILER1
606	if (_c1_count > `0`) {
607	_compilers[`0`] = new Compiler ();
608	}
609	#endif // COMPILER1
610
611	#ifdef COMPILER2
612	if (true JVMCI_ONLY( && !UseJVMCICompiler)) {
613	if (_c2_count > `0`) {
614	_compilers[`1`] = new C2Compiler ();
615	}
616	}
617	#endif // COMPILER2
618
619	// Start the compiler thread(s) and the sweeper thread
620	init_compiler_sweeper_threads();
621	// totalTime performance counter is always created as it is required
622	// by the implementation of java.lang.management.CompilationMBean.
623	{
624	EXCEPTION_MARK;
625	_perf_total_compilation =
626	PerfDataManager::create_counter(JAVA_CI, "totalTime",
627	PerfData::U_Ticks, CHECK);
628	}
629
630	if (UsePerfData) {
631
632	EXCEPTION_MARK;
633
634	// create the jvmstat performance counters
635	_perf_osr_compilation =
636	PerfDataManager::create_counter(SUN_CI, "osrTime",
637	PerfData::U_Ticks, CHECK);
638
639	_perf_standard_compilation =
640	PerfDataManager::create_counter(SUN_CI, "standardTime",
641	PerfData::U_Ticks, CHECK);
642
643	_perf_total_bailout_count =
644	PerfDataManager::create_counter(SUN_CI, "totalBailouts",
645	PerfData::U_Events, CHECK);
646
647	_perf_total_invalidated_count =
648	PerfDataManager::create_counter(SUN_CI, "totalInvalidates",
649	PerfData::U_Events, CHECK);
650
651	_perf_total_compile_count =
652	PerfDataManager::create_counter(SUN_CI, "totalCompiles",
653	PerfData::U_Events, CHECK);
654	_perf_total_osr_compile_count =
655	PerfDataManager::create_counter(SUN_CI, "osrCompiles",
656	PerfData::U_Events, CHECK);
657
658	_perf_total_standard_compile_count =
659	PerfDataManager::create_counter(SUN_CI, "standardCompiles",
660	PerfData::U_Events, CHECK);
661
662	_perf_sum_osr_bytes_compiled =
663	PerfDataManager::create_counter(SUN_CI, "osrBytes",
664	PerfData::U_Bytes, CHECK);
665
666	_perf_sum_standard_bytes_compiled =
667	PerfDataManager::create_counter(SUN_CI, "standardBytes",
668	PerfData::U_Bytes, CHECK);
669
670	_perf_sum_nmethod_size =
671	PerfDataManager::create_counter(SUN_CI, "nmethodSize",
672	PerfData::U_Bytes, CHECK);
673
674	_perf_sum_nmethod_code_size =
675	PerfDataManager::create_counter(SUN_CI, "nmethodCodeSize",
676	PerfData::U_Bytes, CHECK);
677
678	_perf_last_method =
679	PerfDataManager::create_string_variable(SUN_CI, "lastMethod",
680	CompilerCounters::cmname_buffer_length,
681	"", CHECK);
682
683	_perf_last_failed_method =
684	PerfDataManager::create_string_variable(SUN_CI, "lastFailedMethod",
685	CompilerCounters::cmname_buffer_length,
686	"", CHECK);
687
688	_perf_last_invalidated_method =
689	PerfDataManager::create_string_variable(SUN_CI, "lastInvalidatedMethod",
690	CompilerCounters::cmname_buffer_length,
691	"", CHECK);
692
693	_perf_last_compile_type =
694	PerfDataManager::create_variable(SUN_CI, "lastType",
695	PerfData::U_None,
696	(jlong)CompileBroker::no_compile,
697	CHECK);
698
699	_perf_last_compile_size =
700	PerfDataManager::create_variable(SUN_CI, "lastSize",
701	PerfData::U_Bytes,
702	(jlong)CompileBroker::no_compile,
703	CHECK);
704
705
706	_perf_last_failed_type =
707	PerfDataManager::create_variable(SUN_CI, "lastFailedType",
708	PerfData::U_None,
709	(jlong)CompileBroker::no_compile,
710	CHECK);
711
712	_perf_last_invalidated_type =
713	PerfDataManager::create_variable(SUN_CI, "lastInvalidatedType",
714	PerfData::U_None,
715	(jlong)CompileBroker::no_compile,
716	CHECK);
717	}
718	}
719
720	// Completes compiler initialization. Compilation requests submitted
721	// prior to this will be silently ignored.
722	void CompileBroker::compilation_init_phase2() {
723	_initialized = true;
724	}
725
726	Handle CompileBroker::create_thread_oop(const char* name, TRAPS) {
727	Handle string = java_lang_String::create_from_str(name, CHECK_NH);
728	Handle thread_group(THREAD, Universe::system_thread_group());
729	return JavaCalls::construct_new_instance(
730	SystemDictionary::Thread_klass(),
731	vmSymbols::threadgroup_string_void_signature(),
732	thread_group,
733	string,
734	CHECK_NH);
735	}
736
737
738	JavaThread* CompileBroker::make_thread(jobject thread_handle, CompileQueue* queue, AbstractCompiler* comp, TRAPS) {
739	JavaThread* thread = NULL;
740	{
741	MutexLocker mu(Threads_lock, THREAD);
742	if (comp != NULL) {
743	if (!InjectCompilerCreationFailure \|\| comp->num_compiler_threads() == `0`) {
744	CompilerCounters* counters = new CompilerCounters ();
745	thread = new CompilerThread (queue, counters);
746	}
747	} else {
748	thread = new CodeCacheSweeperThread ();
749	}
750	// At this point the new CompilerThread data-races with this startup
751	// thread (which I believe is the primoridal thread and NOT the VM
752	// thread). This means Java bytecodes being executed at startup can
753	// queue compile jobs which will run at whatever default priority the
754	// newly created CompilerThread runs at.
755
756
757	// At this point it may be possible that no osthread was created for the
758	// JavaThread due to lack of memory. We would have to throw an exception
759	// in that case. However, since this must work and we do not allow
760	// exceptions anyway, check and abort if this fails. But first release the
761	// lock.
762
763	if (thread != NULL && thread->osthread() != NULL) {
764
765	java_lang_Thread::set_thread(JNIHandles::resolve_non_null(thread_handle), thread);
766
767	// Note that this only sets the JavaThread _priority field, which by
768	// definition is limited to Java priorities and not OS priorities.
769	// The os-priority is set in the CompilerThread startup code itself
770
771	java_lang_Thread::set_priority(JNIHandles::resolve_non_null(thread_handle), NearMaxPriority);
772
773	// Note that we cannot call os::set_priority because it expects Java
774	// priorities and we are explicitly* using OS priorities so that it's*
775	// possible to set the compiler thread priority higher than any Java
776	// thread.
777
778	int native_prio = CompilerThreadPriority;
779	if (native_prio == -`1`) {
780	if (UseCriticalCompilerThreadPriority) {
781	native_prio = os::java_to_os_priority[CriticalPriority];
782	} else {
783	native_prio = os::java_to_os_priority[NearMaxPriority];
784	}
785	}
786	os::set_native_priority(thread, native_prio);
787
788	java_lang_Thread::set_daemon(JNIHandles::resolve_non_null(thread_handle));
789
790	thread->set_threadObj(JNIHandles::resolve_non_null(thread_handle));
791	if (comp != NULL) {
792	thread->as_CompilerThread()->set_compiler(comp);
793	}
794	Threads::add(thread);
795	Thread::start(thread);
796	}
797	}
798
799	// First release lock before aborting VM.
800	if (thread == NULL \|\| thread->osthread() == NULL) {
801	if (UseDynamicNumberOfCompilerThreads && comp != NULL && comp->num_compiler_threads() > `0`) {
802	if (thread != NULL) {
803	thread->smr_delete();
804	}
805	return NULL;
806	}
807	vm_exit_during_initialization("java.lang.OutOfMemoryError",
808	os::native_thread_creation_failed_msg());
809	}
810
811	// Let go of Threads_lock before yielding
812	os::naked_yield(); // make sure that the compiler thread is started early (especially helpful on SOLARIS)
813
814	return thread;
815	}
816
817
818	void CompileBroker::init_compiler_sweeper_threads() {
819	EXCEPTION_MARK;
820	#if !defined(ZERO)
821	assert(_c2_count > `0` \|\| _c1_count > `0`, "No compilers?");
822	#endif // !ZERO
823	// Initialize the compilation queue
824	if (_c2_count > `0`) {
825	const char* name = JVMCI_ONLY(UseJVMCICompiler ? "JVMCI compile queue" :) "C2 compile queue";
826	_c2_compile_queue = new CompileQueue (name);
827	_compiler2_objects = NEW_C_HEAP_ARRAY(jobject, _c2_count, mtCompiler);
828	_compiler2_logs = NEW_C_HEAP_ARRAY(CompileLog*, _c2_count, mtCompiler);
829	}
830	if (_c1_count > `0`) {
831	_c1_compile_queue = new CompileQueue ("C1 compile queue");
832	_compiler1_objects = NEW_C_HEAP_ARRAY(jobject, _c1_count, mtCompiler);
833	_compiler1_logs = NEW_C_HEAP_ARRAY(CompileLog*, _c1_count, mtCompiler);
834	}
835
836	char name_buffer[`256`];
837
838	for (int i = `0`; i < _c2_count; i++) {
839	// Create a name for our thread.
840	sprintf(name_buffer, "%s CompilerThread%d", _compilers[`1`]->name(), i);
841	Handle thread_oop = create_thread_oop(name_buffer, CHECK);
842	jobject thread_handle = JNIHandles::make_global(thread_oop);
843	_compiler2_objects[i] = thread_handle;
844	_compiler2_logs[i] = NULL;
845
846	if (!UseDynamicNumberOfCompilerThreads \|\| i == `0`) {
847	JavaThread *ct = make_thread(thread_handle, _c2_compile_queue, _compilers[`1`], CHECK);
848	assert(ct != NULL, "should have been handled for initial thread");
849	_compilers[`1`]->set_num_compiler_threads(i + `1`);
850	if (TraceCompilerThreads) {
851	ResourceMark rm;
852	MutexLocker mu(Threads_lock);
853	tty->print_cr("Added initial compiler thread %s", ct->get_thread_name());
854	}
855	}
856	}
857
858	for (int i = `0`; i < _c1_count; i++) {
859	// Create a name for our thread.
860	sprintf(name_buffer, "C1 CompilerThread%d", i);
861	Handle thread_oop = create_thread_oop(name_buffer, CHECK);
862	jobject thread_handle = JNIHandles::make_global(thread_oop);
863	_compiler1_objects[i] = thread_handle;
864	_compiler1_logs[i] = NULL;
865
866	if (!UseDynamicNumberOfCompilerThreads \|\| i == `0`) {
867	JavaThread *ct = make_thread(thread_handle, _c1_compile_queue, _compilers[`0`], CHECK);
868	assert(ct != NULL, "should have been handled for initial thread");
869	_compilers[`0`]->set_num_compiler_threads(i + `1`);
870	if (TraceCompilerThreads) {
871	ResourceMark rm;
872	MutexLocker mu(Threads_lock);
873	tty->print_cr("Added initial compiler thread %s", ct->get_thread_name());
874	}
875	}
876	}
877
878	if (UsePerfData) {
879	PerfDataManager::create_constant(SUN_CI, "threads", PerfData::U_Bytes, _c1_count + _c2_count, CHECK);
880	}
881
882	if (MethodFlushing) {
883	// Initialize the sweeper thread
884	Handle thread_oop = create_thread_oop("Sweeper thread", CHECK);
885	jobject thread_handle = JNIHandles::make_local(THREAD, thread_oop ());
886	make_thread(thread_handle, NULL, NULL, CHECK);
887	}
888	}
889
890	void CompileBroker::possibly_add_compiler_threads() {
891	EXCEPTION_MARK;
892
893	julong available_memory = os::available_memory();
894	// If SegmentedCodeCache is off, both values refer to the single heap (with type CodeBlobType::All).
895	size_t available_cc_np = CodeCache::unallocated_capacity(CodeBlobType::MethodNonProfiled),
896	available_cc_p = CodeCache::unallocated_capacity(CodeBlobType::MethodProfiled);
897
898	// Only do attempt to start additional threads if the lock is free.
899	if (!CompileThread_lock->try_lock()) return;
900
901	if (_c2_compile_queue != NULL) {
902	int old_c2_count = _compilers[`1`]->num_compiler_threads();
903	int new_c2_count = MIN4(_c2_count,
904	_c2_compile_queue->size() / `2`,
905	(int)(available_memory / (`200`*M)),
906	(int)(available_cc_np / (`128`*K)));
907
908	for (int i = old_c2_count; i < new_c2_count; i++) {
909	JavaThread *ct = make_thread(compiler2_object(i), _c2_compile_queue, _compilers[`1`], CHECK);
910	if (ct == NULL) break;
911	_compilers[`1`]->set_num_compiler_threads(i + `1`);
912	if (TraceCompilerThreads) {
913	ResourceMark rm;
914	MutexLocker mu(Threads_lock);
915	tty->print_cr("Added compiler thread %s (available memory: %dMB, available non-profiled code cache: %dMB)",
916	ct->get_thread_name(), (int)(available_memory/M), (int)(available_cc_np/M));
917	}
918	}
919	}
920
921	if (_c1_compile_queue != NULL) {
922	int old_c1_count = _compilers[`0`]->num_compiler_threads();
923	int new_c1_count = MIN4(_c1_count,
924	_c1_compile_queue->size() / `4`,
925	(int)(available_memory / (`100`*M)),
926	(int)(available_cc_p / (`128`*K)));
927
928	for (int i = old_c1_count; i < new_c1_count; i++) {
929	JavaThread *ct = make_thread(compiler1_object(i), _c1_compile_queue, _compilers[`0`], CHECK);
930	if (ct == NULL) break;
931	_compilers[`0`]->set_num_compiler_threads(i + `1`);
932	if (TraceCompilerThreads) {
933	ResourceMark rm;
934	MutexLocker mu(Threads_lock);
935	tty->print_cr("Added compiler thread %s (available memory: %dMB, available profiled code cache: %dMB)",
936	ct->get_thread_name(), (int)(available_memory/M), (int)(available_cc_p/M));
937	}
938	}
939	}
940
941	CompileThread_lock->unlock();
942	}
943
944
945	/**
946	* Set the methods on the stack as on_stack so that redefine classes doesn't
947	* reclaim them. This method is executed at a safepoint.
948	*/
949	void CompileBroker::mark_on_stack() {
950	assert(SafepointSynchronize::is_at_safepoint(), "sanity check");
951	// Since we are at a safepoint, we do not need a lock to access
952	// the compile queues.
953	if (_c2_compile_queue != NULL) {
954	_c2_compile_queue->mark_on_stack();
955	}
956	if (_c1_compile_queue != NULL) {
957	_c1_compile_queue->mark_on_stack();
958	}
959	}
960
961	// ------------------------------------------------------------------
962	// CompileBroker::compile_method
963	//
964	// Request compilation of a method.
965	void CompileBroker::compile_method_base(const methodHandle& method,
966	int osr_bci,
967	int comp_level,
968	const methodHandle& hot_method,
969	int hot_count,
970	CompileTask::CompileReason compile_reason,
971	bool blocking,
972	Thread* thread) {
973	guarantee(!method ->is_abstract(), "cannot compile abstract methods");
974	assert(method->method_holder()->is_instance_klass(),
975	"sanity check");
976	assert(!method->method_holder()->is_not_initialized(),
977	"method holder must be initialized");
978	assert(!method->is_method_handle_intrinsic(), "do not enqueue these guys");
979
980	if (CIPrintRequests) {
981	tty->print("request: ");
982	method ->print_short_name(tty);
983	if (osr_bci != InvocationEntryBci) {
984	tty->print(" osr_bci: %d", osr_bci);
985	}
986	tty->print(" level: %d comment: %s count: %d", comp_level, CompileTask::reason_name(compile_reason), hot_count);
987	if (!hot_method.is_null()) {
988	tty->print(" hot: ");
989	if (hot_method () != method ()) {
990	hot_method ->print_short_name(tty);
991	} else {
992	tty->print("yes");
993	}
994	}
995	tty->cr();
996	}
997
998	// A request has been made for compilation. Before we do any
999	// real work, check to see if the method has been compiled
1000	// in the meantime with a definitive result.
1001	if (compilation_is_complete(method, osr_bci, comp_level)) {
1002	return;
1003	}
1004
1005	#ifndef PRODUCT
1006	if (osr_bci != -`1` && !FLAG_IS_DEFAULT(OSROnlyBCI)) {
1007	if ((OSROnlyBCI > `0`) ? (OSROnlyBCI != osr_bci) : (-OSROnlyBCI == osr_bci)) {
1008	// Positive OSROnlyBCI means only compile that bci. Negative means don't compile that BCI.
1009	return;
1010	}
1011	}
1012	#endif
1013
1014	// If this method is already in the compile queue, then
1015	// we do not block the current thread.
1016	if (compilation_is_in_queue(method)) {
1017	// We may want to decay our counter a bit here to prevent
1018	// multiple denied requests for compilation. This is an
1019	// open compilation policy issue. Note: The other possibility,
1020	// in the case that this is a blocking compile request, is to have
1021	// all subsequent blocking requesters wait for completion of
1022	// ongoing compiles. Note that in this case we'll need a protocol
1023	// for freeing the associated compile tasks. [Or we could have
1024	// a single static monitor on which all these waiters sleep.]
1025	return;
1026	}
1027
1028	if (TieredCompilation) {
1029	// Tiered policy requires MethodCounters to exist before adding a method to
1030	// the queue. Create if we don't have them yet.
1031	method ->get_method_counters(thread);
1032	}
1033
1034	// Outputs from the following MutexLocker block:
1035	CompileTask* task = NULL;
1036	CompileQueue* queue = compile_queue(comp_level);
1037
1038	// Acquire our lock.
1039	{
1040	MutexLocker locker(MethodCompileQueue_lock, thread);
1041
1042	// Make sure the method has not slipped into the queues since
1043	// last we checked; note that those checks were "fast bail-outs".
1044	// Here we need to be more careful, see 14012000 below.
1045	if (compilation_is_in_queue(method)) {
1046	return;
1047	}
1048
1049	// We need to check again to see if the compilation has
1050	// completed. A previous compilation may have registered
1051	// some result.
1052	if (compilation_is_complete(method, osr_bci, comp_level)) {
1053	return;
1054	}
1055
1056	// We now know that this compilation is not pending, complete,
1057	// or prohibited. Assign a compile_id to this compilation
1058	// and check to see if it is in our [Start..Stop) range.
1059	int compile_id = assign_compile_id(method, osr_bci);
1060	if (compile_id == `0`) {
1061	// The compilation falls outside the allowed range.
1062	return;
1063	}
1064
1065	#if INCLUDE_JVMCI
1066	if (UseJVMCICompiler && blocking) {
1067	// Don't allow blocking compiles for requests triggered by JVMCI.
1068	if (thread->is_Compiler_thread()) {
1069	blocking = false;
1070	}
1071
1072	if (!UseJVMCINativeLibrary) {
1073	// Don't allow blocking compiles if inside a class initializer or while performing class loading
1074	vframeStream vfst((JavaThread*) thread);
1075	for (; !vfst.at_end(); vfst.next()) {
1076	if (vfst.method()->is_static_initializer() \|\|
1077	(vfst.method()->method_holder()->is_subclass_of(SystemDictionary::ClassLoader_klass()) &&
1078	vfst.method()->name() == vmSymbols::loadClass_name())) {
1079	blocking = false;
1080	break;
1081	}
1082	}
1083	}
1084
1085	// Don't allow blocking compilation requests to JVMCI
1086	// if JVMCI itself is not yet initialized
1087	if (!JVMCI::is_compiler_initialized() && compiler(comp_level)->is_jvmci()) {
1088	blocking = false;
1089	}
1090
1091	// Don't allow blocking compilation requests if we are in JVMCIRuntime::shutdown
1092	// to avoid deadlock between compiler thread(s) and threads run at shutdown
1093	// such as the DestroyJavaVM thread.
1094	if (JVMCI::shutdown_called()) {
1095	blocking = false;
1096	}
1097	}
1098	#endif // INCLUDE_JVMCI
1099
1100	// We will enter the compilation in the queue.
1101	// 14012000: Note that this sets the queued_for_compile bits in
1102	// the target method. We can now reason that a method cannot be
1103	// queued for compilation more than once, as follows:
1104	// Before a thread queues a task for compilation, it first acquires
1105	// the compile queue lock, then checks if the method's queued bits
1106	// are set or it has already been compiled. Thus there can not be two
1107	// instances of a compilation task for the same method on the
1108	// compilation queue. Consider now the case where the compilation
1109	// thread has already removed a task for that method from the queue
1110	// and is in the midst of compiling it. In this case, the
1111	// queued_for_compile bits must be set in the method (and these
1112	// will be visible to the current thread, since the bits were set
1113	// under protection of the compile queue lock, which we hold now.
1114	// When the compilation completes, the compiler thread first sets
1115	// the compilation result and then clears the queued_for_compile
1116	// bits. Neither of these actions are protected by a barrier (or done
1117	// under the protection of a lock), so the only guarantee we have
1118	// (on machines with TSO (Total Store Order)) is that these values
1119	// will update in that order. As a result, the only combinations of
1120	// these bits that the current thread will see are, in temporal order:
1121	// <RESULT, QUEUE> :
1122	// <0, 1> : in compile queue, but not yet compiled
1123	// <1, 1> : compiled but queue bit not cleared
1124	// <1, 0> : compiled and queue bit cleared
1125	// Because we first check the queue bits then check the result bits,
1126	// we are assured that we cannot introduce a duplicate task.
1127	// Note that if we did the tests in the reverse order (i.e. check
1128	// result then check queued bit), we could get the result bit before
1129	// the compilation completed, and the queue bit after the compilation
1130	// completed, and end up introducing a "duplicate" (redundant) task.
1131	// In that case, the compiler thread should first check if a method
1132	// has already been compiled before trying to compile it.
1133	// NOTE: in the event that there are multiple compiler threads and
1134	// there is de-optimization/recompilation, things will get hairy,
1135	// and in that case it's best to protect both the testing (here) of
1136	// these bits, and their updating (here and elsewhere) under a
1137	// common lock.
1138	task = create_compile_task(queue,
1139	compile_id, method,
1140	osr_bci, comp_level,
1141	hot_method, hot_count, compile_reason,
1142	blocking);
1143	}
1144
1145	if (blocking) {
1146	wait_for_completion(task);
1147	}
1148	}
1149
1150	nmethod* CompileBroker::compile_method(const methodHandle& method, int osr_bci,
1151	int comp_level,
1152	const methodHandle& hot_method, int hot_count,
1153	CompileTask::CompileReason compile_reason,
1154	Thread* THREAD) {
1155	// Do nothing if compilebroker is not initalized or compiles are submitted on level none
1156	if (!_initialized \|\| comp_level == CompLevel_none) {
1157	return NULL;
1158	}
1159
1160	AbstractCompiler *comp = CompileBroker::compiler(comp_level);
1161	assert(comp != NULL, "Ensure we have a compiler");
1162
1163	DirectiveSet* directive = DirectivesStack::getMatchingDirective(method, comp);
1164	nmethod* nm = CompileBroker::compile_method(method, osr_bci, comp_level, hot_method, hot_count, compile_reason, directive, THREAD);
1165	DirectivesStack::release(directive);
1166	return nm;
1167	}
1168
1169	nmethod* CompileBroker::compile_method(const methodHandle& method, int osr_bci,
1170	int comp_level,
1171	const methodHandle& hot_method, int hot_count,
1172	CompileTask::CompileReason compile_reason,
1173	DirectiveSet* directive,
1174	Thread* THREAD) {
1175
1176	// make sure arguments make sense
1177	assert(method->method_holder()->is_instance_klass(), "not an instance method");
1178	assert(osr_bci == InvocationEntryBci \|\| (`0` <= osr_bci && osr_bci < method->code_size()), "bci out of range");
1179	assert(!method->is_abstract() && (osr_bci == InvocationEntryBci \|\| !method->is_native()), "cannot compile abstract/native methods");
1180	assert(!method->method_holder()->is_not_initialized(), "method holder must be initialized");
1181	assert(!TieredCompilation \|\| comp_level <= TieredStopAtLevel, "Invalid compilation level");
1182	// allow any levels for WhiteBox
1183	assert(WhiteBoxAPI \|\| TieredCompilation \|\| comp_level == CompLevel_highest_tier, "only CompLevel_highest_tier must be used in non-tiered");
1184	// return quickly if possible
1185
1186	// lock, make sure that the compilation
1187	// isn't prohibited in a straightforward way.
1188	AbstractCompiler* comp = CompileBroker::compiler(comp_level);
1189	if (comp == NULL \|\| !comp->can_compile_method(method) \|\|
1190	compilation_is_prohibited(method, osr_bci, comp_level, directive->ExcludeOption)) {
1191	return NULL;
1192	}
1193
1194	#if INCLUDE_JVMCI
1195	if (comp->is_jvmci() && !JVMCI::can_initialize_JVMCI()) {
1196	return NULL;
1197	}
1198	#endif
1199
1200	if (osr_bci == InvocationEntryBci) {
1201	// standard compilation
1202	CompiledMethod* method_code = method ->code();
1203	if (method_code != NULL && method_code->is_nmethod()) {
1204	if (compilation_is_complete(method, osr_bci, comp_level)) {
1205	return (nmethod*) method_code;
1206	}
1207	}
1208	if (method ->is_not_compilable(comp_level)) {
1209	return NULL;
1210	}
1211	} else {
1212	// osr compilation
1213	#ifndef TIERED
1214	// seems like an assert of dubious value
1215	assert(comp_level == CompLevel_highest_tier,
1216	"all OSR compiles are assumed to be at a single compilation level");
1217	#endif // TIERED
1218	// We accept a higher level osr method
1219	nmethod* nm = method ->lookup_osr_nmethod_for(osr_bci, comp_level, false);
1220	if (nm != NULL) return nm;
1221	if (method ->is_not_osr_compilable(comp_level)) return NULL;
1222	}
1223
1224	assert(!HAS_PENDING_EXCEPTION, "No exception should be present");
1225	// some prerequisites that are compiler specific
1226	if (comp->is_c2()) {
1227	method ->constants()->resolve_string_constants(CHECK_AND_CLEAR_NULL);
1228	// Resolve all classes seen in the signature of the method
1229	// we are compiling.
1230	Method::load_signature_classes(method, CHECK_AND_CLEAR_NULL);
1231	}
1232
1233	// If the method is native, do the lookup in the thread requesting
1234	// the compilation. Native lookups can load code, which is not
1235	// permitted during compilation.
1236	//
1237	// Note: A native method implies non-osr compilation which is
1238	// checked with an assertion at the entry of this method.
1239	if (method ->is_native() && !method ->is_method_handle_intrinsic()) {
1240	bool in_base_library;
1241	address adr = NativeLookup::lookup(method, in_base_library, THREAD);
1242	if (HAS_PENDING_EXCEPTION) {
1243	// In case of an exception looking up the method, we just forget
1244	// about it. The interpreter will kick-in and throw the exception.
1245	method ->set_not_compilable("NativeLookup::lookup failed"); // implies is_not_osr_compilable()
1246	CLEAR_PENDING_EXCEPTION;
1247	return NULL;
1248	}
1249	assert(method->has_native_function(), "must have native code by now");
1250	}
1251
1252	// RedefineClasses() has replaced this method; just return
1253	if (method ->is_old()) {
1254	return NULL;
1255	}
1256
1257	// JVMTI -- post_compile_event requires jmethod_id() that may require
1258	// a lock the compiling thread can not acquire. Prefetch it here.
1259	if (JvmtiExport::should_post_compiled_method_load()) {
1260	method ->jmethod_id();
1261	}
1262
1263	// do the compilation
1264	if (method ->is_native()) {
1265	if (!PreferInterpreterNativeStubs \|\| method ->is_method_handle_intrinsic()) {
1266	// The following native methods:
1267	//
1268	// java.lang.Float.intBitsToFloat
1269	// java.lang.Float.floatToRawIntBits
1270	// java.lang.Double.longBitsToDouble
1271	// java.lang.Double.doubleToRawLongBits
1272	//
1273	// are called through the interpreter even if interpreter native stubs
1274	// are not preferred (i.e., calling through adapter handlers is preferred).
1275	// The reason is that on x86_32 signaling NaNs (sNaNs) are not preserved
1276	// if the version of the methods from the native libraries is called.
1277	// As the interpreter and the C2-intrinsified version of the methods preserves
1278	// sNaNs, that would result in an inconsistent way of handling of sNaNs.
1279	if ((UseSSE >= `1` &&
1280	(method ->intrinsic_id() == vmIntrinsics::_intBitsToFloat \|\|
1281	method ->intrinsic_id() == vmIntrinsics::_floatToRawIntBits)) \|\|
1282	(UseSSE >= `2` &&
1283	(method ->intrinsic_id() == vmIntrinsics::_longBitsToDouble \|\|
1284	method ->intrinsic_id() == vmIntrinsics::_doubleToRawLongBits))) {
1285	return NULL;
1286	}
1287
1288	// To properly handle the appendix argument for out-of-line calls we are using a small trampoline that
1289	// pops off the appendix argument and jumps to the target (see gen_special_dispatch in SharedRuntime).
1290	//
1291	// Since normal compiled-to-compiled calls are not able to handle such a thing we MUST generate an adapter
1292	// in this case. If we can't generate one and use it we can not execute the out-of-line method handle calls.
1293	AdapterHandlerLibrary::create_native_wrapper(method);
1294	} else {
1295	return NULL;
1296	}
1297	} else {
1298	// If the compiler is shut off due to code cache getting full
1299	// fail out now so blocking compiles dont hang the java thread
1300	if (!should_compile_new_jobs()) {
1301	CompilationPolicy::policy()->delay_compilation(method ());
1302	return NULL;
1303	}
1304	bool is_blocking = !directive->BackgroundCompilationOption \|\| ReplayCompiles;
1305	compile_method_base(method, osr_bci, comp_level, hot_method, hot_count, compile_reason, is_blocking, THREAD);
1306	}
1307
1308	// return requested nmethod
1309	// We accept a higher level osr method
1310	if (osr_bci == InvocationEntryBci) {
1311	CompiledMethod* code = method ->code();
1312	if (code == NULL) {
1313	return (nmethod*) code;
1314	} else {
1315	return code->as_nmethod_or_null();
1316	}
1317	}
1318	return method ->lookup_osr_nmethod_for(osr_bci, comp_level, false);
1319	}
1320
1321
1322	// ------------------------------------------------------------------
1323	// CompileBroker::compilation_is_complete
1324	//
1325	// See if compilation of this method is already complete.
1326	bool CompileBroker::compilation_is_complete(const methodHandle& method,
1327	int osr_bci,
1328	int comp_level) {
1329	bool is_osr = (osr_bci != standard_entry_bci);
1330	if (is_osr) {
1331	if (method ->is_not_osr_compilable(comp_level)) {
1332	return true;
1333	} else {
1334	nmethod* result = method ->lookup_osr_nmethod_for(osr_bci, comp_level, true);
1335	return (result != NULL);
1336	}
1337	} else {
1338	if (method ->is_not_compilable(comp_level)) {
1339	return true;
1340	} else {
1341	CompiledMethod* result = method ->code();
1342	if (result == NULL) return false;
1343	return comp_level == result->comp_level();
1344	}
1345	}
1346	}
1347
1348
1349	/**
1350	* See if this compilation is already requested.
1351	*
1352	* Implementation note: there is only a single "is in queue" bit
1353	* for each method. This means that the check below is overly
1354	* conservative in the sense that an osr compilation in the queue
1355	* will block a normal compilation from entering the queue (and vice
1356	* versa). This can be remedied by a full queue search to disambiguate
1357	* cases. If it is deemed profitable, this may be done.
1358	*/
1359	bool CompileBroker::compilation_is_in_queue(const methodHandle& method) {
1360	return method ->queued_for_compilation();
1361	}
1362
1363	// ------------------------------------------------------------------
1364	// CompileBroker::compilation_is_prohibited
1365	//
1366	// See if this compilation is not allowed.
1367	bool CompileBroker::compilation_is_prohibited(const methodHandle& method, int osr_bci, int comp_level, bool excluded) {
1368	bool is_native = method ->is_native();
1369	// Some compilers may not support the compilation of natives.
1370	AbstractCompiler *comp = compiler(comp_level);
1371	if (is_native &&
1372	(!CICompileNatives \|\| comp == NULL \|\| !comp->supports_native())) {
1373	method ->set_not_compilable_quietly("native methods not supported", comp_level);
1374	return true;
1375	}
1376
1377	bool is_osr = (osr_bci != standard_entry_bci);
1378	// Some compilers may not support on stack replacement.
1379	if (is_osr &&
1380	(!CICompileOSR \|\| comp == NULL \|\| !comp->supports_osr())) {
1381	method ->set_not_osr_compilable("OSR not supported", comp_level);
1382	return true;
1383	}
1384
1385	// The method may be explicitly excluded by the user.
1386	double scale;
1387	if (excluded \|\| (CompilerOracle::has_option_value(method, "CompileThresholdScaling", scale) && scale == `0`)) {
1388	bool quietly = CompilerOracle::should_exclude_quietly();
1389	if (PrintCompilation && !quietly) {
1390	// This does not happen quietly...
1391	ResourceMark rm;
1392	tty->print("### Excluding %s:%s",
1393	method ->is_native() ? "generation of native wrapper" : "compile",
1394	(method ->is_static() ? " static" : ""));
1395	method ->print_short_name(tty);
1396	tty->cr();
1397	}
1398	method ->set_not_compilable("excluded by CompileCommand", comp_level, !quietly);
1399	}
1400
1401	return false;
1402	}
1403
1404	/**
1405	* Generate serialized IDs for compilation requests. If certain debugging flags are used
1406	* and the ID is not within the specified range, the method is not compiled and 0 is returned.
1407	* The function also allows to generate separate compilation IDs for OSR compilations.
1408	*/
1409	int CompileBroker::assign_compile_id(const methodHandle& method, int osr_bci) {
1410	#ifdef ASSERT
1411	bool is_osr = (osr_bci != standard_entry_bci);
1412	int id;
1413	if (method->is_native()) {
1414	assert(!is_osr, "can't be osr");
1415	// Adapters, native wrappers and method handle intrinsics
1416	// should be generated always.
1417	return Atomic::add(`1`, &_compilation_id);
1418	} else if (CICountOSR && is_osr) {
1419	id = Atomic::add(`1`, &_osr_compilation_id);
1420	if (CIStartOSR <= id && id < CIStopOSR) {
1421	return id;
1422	}
1423	} else {
1424	id = Atomic::add(`1`, &_compilation_id);
1425	if (CIStart <= id && id < CIStop) {
1426	return id;
1427	}
1428	}
1429
1430	// Method was not in the appropriate compilation range.
1431	method->set_not_compilable_quietly("Not in requested compile id range");
1432	return `0`;
1433	#else
1434	// CICountOSR is a develop flag and set to 'false' by default. In a product built,
1435	// only _compilation_id is incremented.
1436	return Atomic::add(`1`, &_compilation_id);
1437	#endif
1438	}
1439
1440	// ------------------------------------------------------------------
1441	// CompileBroker::assign_compile_id_unlocked
1442	//
1443	// Public wrapper for assign_compile_id that acquires the needed locks
1444	uint CompileBroker::assign_compile_id_unlocked(Thread* thread, const methodHandle& method, int osr_bci) {
1445	MutexLocker locker(MethodCompileQueue_lock, thread);
1446	return assign_compile_id(method, osr_bci);
1447	}
1448
1449	// ------------------------------------------------------------------
1450	// CompileBroker::preload_classes
1451	void CompileBroker::preload_classes(const methodHandle& method, TRAPS) {
1452	// Move this code over from c1_Compiler.cpp
1453	ShouldNotReachHere();
1454	}
1455
1456
1457	// ------------------------------------------------------------------
1458	// CompileBroker::create_compile_task
1459	//
1460	// Create a CompileTask object representing the current request for
1461	// compilation. Add this task to the queue.
1462	CompileTask* CompileBroker::create_compile_task(CompileQueue* queue,
1463	int compile_id,
1464	const methodHandle& method,
1465	int osr_bci,
1466	int comp_level,
1467	const methodHandle& hot_method,
1468	int hot_count,
1469	CompileTask::CompileReason compile_reason,
1470	bool blocking) {
1471	CompileTask* new_task = CompileTask::allocate();
1472	new_task->initialize(compile_id, method, osr_bci, comp_level,
1473	hot_method, hot_count, compile_reason,
1474	blocking);
1475	queue->add(new_task);
1476	return new_task;
1477	}
1478
1479	#if INCLUDE_JVMCI
1480	// The number of milliseconds to wait before checking if
1481	// JVMCI compilation has made progress.
1482	static const long JVMCI_COMPILATION_PROGRESS_WAIT_TIMESLICE = `1000`;
1483
1484	// The number of JVMCI compilation progress checks that must fail
1485	// before unblocking a thread waiting for a blocking compilation.
1486	static const int JVMCI_COMPILATION_PROGRESS_WAIT_ATTEMPTS = `10`;
1487
1488	/**
1489	* Waits for a JVMCI compiler to complete a given task. This thread
1490	* waits until either the task completes or it sees no JVMCI compilation
1491	* progress for N consecutive milliseconds where N is
1492	* JVMCI_COMPILATION_PROGRESS_WAIT_TIMESLICE *
1493	* JVMCI_COMPILATION_PROGRESS_WAIT_ATTEMPTS.
1494	*
1495	* @return true if this thread needs to free/recycle the task
1496	*/
1497	bool CompileBroker::wait_for_jvmci_completion(JVMCICompiler* jvmci, CompileTask* task, JavaThread* thread) {
1498	MonitorLocker ml(task->lock(), thread);
1499	int progress_wait_attempts = `0`;
1500	int methods_compiled = jvmci->methods_compiled();
1501	while (!task->is_complete() && !is_compilation_disabled_forever() &&
1502	ml.wait(JVMCI_COMPILATION_PROGRESS_WAIT_TIMESLICE)) {
1503	CompilerThread* jvmci_compiler_thread = task->jvmci_compiler_thread();
1504
1505	bool progress;
1506	if (jvmci_compiler_thread != NULL) {
1507	// If the JVMCI compiler thread is not blocked or suspended, we deem it to be making progress.
1508	progress = jvmci_compiler_thread->thread_state() != _thread_blocked &&
1509	!jvmci_compiler_thread->is_external_suspend();
1510	} else {
1511	// Still waiting on JVMCI compiler queue. This thread may be holding a lock
1512	// that all JVMCI compiler threads are blocked on. We use the counter for
1513	// successful JVMCI compilations to determine whether JVMCI compilation
1514	// is still making progress through the JVMCI compiler queue.
1515	progress = jvmci->methods_compiled() != methods_compiled;
1516	}
1517
1518	if (!progress) {
1519	if (++progress_wait_attempts == JVMCI_COMPILATION_PROGRESS_WAIT_ATTEMPTS) {
1520	if (PrintCompilation) {
1521	task->print(tty, "wait for blocking compilation timed out");
1522	}
1523	break;
1524	}
1525	} else {
1526	progress_wait_attempts = `0`;
1527	if (jvmci_compiler_thread == NULL) {
1528	methods_compiled = jvmci->methods_compiled();
1529	}
1530	}
1531	}
1532	task->clear_waiter();
1533	return task->is_complete();
1534	}
1535	#endif
1536
1537	/**
1538	* Wait for the compilation task to complete.
1539	*/
1540	void CompileBroker::wait_for_completion(CompileTask* task) {
1541	if (CIPrintCompileQueue) {
1542	ttyLocker ttyl;
1543	tty->print_cr("BLOCKING FOR COMPILE");
1544	}
1545
1546	assert(task->is_blocking(), "can only wait on blocking task");
1547
1548	JavaThread* thread = JavaThread::current();
1549	thread->set_blocked_on_compilation(true);
1550
1551	methodHandle method(thread, task->method());
1552	bool free_task;
1553	#if INCLUDE_JVMCI
1554	AbstractCompiler* comp = compiler(task->comp_level());
1555	if (comp->is_jvmci()) {
1556	free_task = wait_for_jvmci_completion((JVMCICompiler*) comp, task, thread);
1557	} else
1558	#endif
1559	{
1560	MonitorLocker ml(task->lock(), thread);
1561	free_task = true;
1562	while (!task->is_complete() && !is_compilation_disabled_forever()) {
1563	ml.wait();
1564	}
1565	}
1566
1567	thread->set_blocked_on_compilation(false);
1568	if (free_task) {
1569	if (is_compilation_disabled_forever()) {
1570	CompileTask::free(task);
1571	return;
1572	}
1573
1574	// It is harmless to check this status without the lock, because
1575	// completion is a stable property (until the task object is recycled).
1576	assert(task->is_complete(), "Compilation should have completed");
1577	assert(task->code_handle() == NULL, "must be reset");
1578
1579	// By convention, the waiter is responsible for recycling a
1580	// blocking CompileTask. Since there is only one waiter ever
1581	// waiting on a CompileTask, we know that no one else will
1582	// be using this CompileTask; we can free it.
1583	CompileTask::free(task);
1584	}
1585	}
1586
1587	/**
1588	* Initialize compiler thread(s) + compiler object(s). The postcondition
1589	* of this function is that the compiler runtimes are initialized and that
1590	* compiler threads can start compiling.
1591	*/
1592	bool CompileBroker::init_compiler_runtime() {
1593	CompilerThread* thread = CompilerThread::current();
1594	AbstractCompiler* comp = thread->compiler();
1595	// Final sanity check - the compiler object must exist
1596	guarantee(comp != NULL, "Compiler object must exist");
1597
1598	int system_dictionary_modification_counter;
1599	{
1600	MutexLocker locker(Compile_lock, thread);
1601	system_dictionary_modification_counter = SystemDictionary::number_of_modifications();
1602	}
1603
1604	{
1605	// Must switch to native to allocate ci_env
1606	ThreadToNativeFromVM ttn(thread);
1607	ciEnv ci_env(NULL, system_dictionary_modification_counter);
1608	// Cache Jvmti state
1609	ci_env.cache_jvmti_state();
1610	// Cache DTrace flags
1611	ci_env.cache_dtrace_flags();
1612
1613	// Switch back to VM state to do compiler initialization
1614	ThreadInVMfromNative tv(thread);
1615	ResetNoHandleMark rnhm;
1616
1617	// Perform per-thread and global initializations
1618	comp->initialize();
1619	}
1620
1621	if (comp->is_failed()) {
1622	disable_compilation_forever();
1623	// If compiler initialization failed, no compiler thread that is specific to a
1624	// particular compiler runtime will ever start to compile methods.
1625	shutdown_compiler_runtime(comp, thread);
1626	return false;
1627	}
1628
1629	// C1 specific check
1630	if (comp->is_c1() && (thread->get_buffer_blob() == NULL)) {
1631	warning("Initialization of %s thread failed (no space to run compilers)", thread->name());
1632	return false;
1633	}
1634
1635	return true;
1636	}
1637
1638	/**
1639	* If C1 and/or C2 initialization failed, we shut down all compilation.
1640	* We do this to keep things simple. This can be changed if it ever turns
1641	* out to be a problem.
1642	*/
1643	void CompileBroker::shutdown_compiler_runtime(AbstractCompiler* comp, CompilerThread* thread) {
1644	// Free buffer blob, if allocated
1645	if (thread->get_buffer_blob() != NULL) {
1646	MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag);
1647	CodeCache::free(thread->get_buffer_blob());
1648	}
1649
1650	if (comp->should_perform_shutdown()) {
1651	// There are two reasons for shutting down the compiler
1652	// 1) compiler runtime initialization failed
1653	// 2) The code cache is full and the following flag is set: -XX:-UseCodeCacheFlushing
1654	warning("%s initialization failed. Shutting down all compilers", comp->name());
1655
1656	// Only one thread per compiler runtime object enters here
1657	// Set state to shut down
1658	comp->set_shut_down();
1659
1660	// Delete all queued compilation tasks to make compiler threads exit faster.
1661	if (_c1_compile_queue != NULL) {
1662	_c1_compile_queue->free_all();
1663	}
1664
1665	if (_c2_compile_queue != NULL) {
1666	_c2_compile_queue->free_all();
1667	}
1668
1669	// Set flags so that we continue execution with using interpreter only.
1670	UseCompiler = false;
1671	UseInterpreter = true;
1672
1673	// We could delete compiler runtimes also. However, there are references to
1674	// the compiler runtime(s) (e.g., nmethod::is_compiled_by_c1()) which then
1675	// fail. This can be done later if necessary.
1676	}
1677	}
1678
1679	/**
1680	* Helper function to create new or reuse old CompileLog.
1681	*/
1682	CompileLog* CompileBroker::get_log(CompilerThread* ct) {
1683	if (!LogCompilation) return NULL;
1684
1685	AbstractCompiler *compiler = ct->compiler();
1686	bool c1 = compiler->is_c1();
1687	jobject* compiler_objects = c1 ? _compiler1_objects : _compiler2_objects;
1688	assert(compiler_objects != NULL, "must be initialized at this point");
1689	CompileLog** logs = c1 ? _compiler1_logs : _compiler2_logs;
1690	assert(logs != NULL, "must be initialized at this point");
1691	int count = c1 ? _c1_count : _c2_count;
1692
1693	// Find Compiler number by its threadObj.
1694	oop compiler_obj = ct->threadObj();
1695	int compiler_number = `0`;
1696	bool found = false;
1697	for (; compiler_number < count; compiler_number++) {
1698	if (oopDesc::equals(JNIHandles::resolve_non_null(compiler_objects[compiler_number]), compiler_obj)) {
1699	found = true;
1700	break;
1701	}
1702	}
1703	assert(found, "Compiler must exist at this point");
1704
1705	// Determine pointer for this thread's log.
1706	CompileLog** log_ptr = &logs[compiler_number];
1707
1708	// Return old one if it exists.
1709	CompileLog* log = *log_ptr;
1710	if (log != NULL) {
1711	ct->init_log(log);
1712	return log;
1713	}
1714
1715	// Create a new one and remember it.
1716	init_compiler_thread_log();
1717	log = ct->log();
1718	*log_ptr = log;
1719	return log;
1720	}
1721
1722	// ------------------------------------------------------------------
1723	// CompileBroker::compiler_thread_loop
1724	//
1725	// The main loop run by a CompilerThread.
1726	void CompileBroker::compiler_thread_loop() {
1727	CompilerThread* thread = CompilerThread::current();
1728	CompileQueue* queue = thread->queue();
1729	// For the thread that initializes the ciObjectFactory
1730	// this resource mark holds all the shared objects
1731	ResourceMark rm;
1732
1733	// First thread to get here will initialize the compiler interface
1734
1735	{
1736	ASSERT_IN_VM;
1737	MutexLocker only_one (CompileThread_lock, thread);
1738	if (!ciObjectFactory::is_initialized()) {
1739	ciObjectFactory::initialize();
1740	}
1741	}
1742
1743	// Open a log.
1744	CompileLog* log = get_log(thread);
1745	if (log != NULL) {
1746	log->begin_elem("start_compile_thread name='%s' thread='" UINTX_FORMAT "' process='%d'",
1747	thread->name(),
1748	os::current_thread_id(),
1749	os::current_process_id());
1750	log->stamp();
1751	log->end_elem();
1752	}
1753
1754	// If compiler thread/runtime initialization fails, exit the compiler thread
1755	if (!init_compiler_runtime()) {
1756	return;
1757	}
1758
1759	thread->start_idle_timer();
1760
1761	// Poll for new compilation tasks as long as the JVM runs. Compilation
1762	// should only be disabled if something went wrong while initializing the
1763	// compiler runtimes. This, in turn, should not happen. The only known case
1764	// when compiler runtime initialization fails is if there is not enough free
1765	// space in the code cache to generate the necessary stubs, etc.
1766	while (!is_compilation_disabled_forever()) {
1767	// We need this HandleMark to avoid leaking VM handles.
1768	HandleMark hm(thread);
1769
1770	CompileTask* task = queue->get();
1771	if (task == NULL) {
1772	if (UseDynamicNumberOfCompilerThreads) {
1773	// Access compiler_count under lock to enforce consistency.
1774	MutexLocker only_one(CompileThread_lock);
1775	if (can_remove(thread, true)) {
1776	if (TraceCompilerThreads) {
1777	tty->print_cr("Removing compiler thread %s after " JLONG_FORMAT " ms idle time",
1778	thread->name(), thread->idle_time_millis());
1779	}
1780	// Free buffer blob, if allocated
1781	if (thread->get_buffer_blob() != NULL) {
1782	MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag);
1783	CodeCache::free(thread->get_buffer_blob());
1784	}
1785	return; // Stop this thread.
1786	}
1787	}
1788	} else {
1789	// Assign the task to the current thread. Mark this compilation
1790	// thread as active for the profiler.
1791	// CompileTaskWrapper also keeps the Method from being deallocated if redefinition*
1792	// occurs after fetching the compile task off the queue.
1793	CompileTaskWrapper ctw(task);
1794	nmethodLocker result_handle; // (handle for the nmethod produced by this task)
1795	task->set_code_handle(&result_handle);
1796	methodHandle method(thread, task->method());
1797
1798	// Never compile a method if breakpoints are present in it
1799	if (method ()->number_of_breakpoints() == `0`) {
1800	// Compile the method.
1801	if ((UseCompiler \|\| AlwaysCompileLoopMethods) && CompileBroker::should_compile_new_jobs()) {
1802	invoke_compiler_on_method(task);
1803	thread->start_idle_timer();
1804	} else {
1805	// After compilation is disabled, remove remaining methods from queue
1806	method ->clear_queued_for_compilation();
1807	task->set_failure_reason("compilation is disabled");
1808	}
1809	}
1810
1811	if (UseDynamicNumberOfCompilerThreads) {
1812	possibly_add_compiler_threads();
1813	}
1814	}
1815	}
1816
1817	// Shut down compiler runtime
1818	shutdown_compiler_runtime(thread->compiler(), thread);
1819	}
1820
1821	// ------------------------------------------------------------------
1822	// CompileBroker::init_compiler_thread_log
1823	//
1824	// Set up state required by +LogCompilation.
1825	void CompileBroker::init_compiler_thread_log() {
1826	CompilerThread* thread = CompilerThread::current();
1827	char file_name[`4`*K];
1828	FILE* fp = NULL;
1829	intx thread_id = os::current_thread_id();
1830	for (int try_temp_dir = `1`; try_temp_dir >= `0`; try_temp_dir--) {
1831	const char* dir = (try_temp_dir ? os::get_temp_directory() : NULL);
1832	if (dir == NULL) {
1833	jio_snprintf(file_name, sizeof(file_name), "hs_c" UINTX_FORMAT "_pid%u.log",
1834	thread_id, os::current_process_id());
1835	} else {
1836	jio_snprintf(file_name, sizeof(file_name),
1837	"%s%shs_c" UINTX_FORMAT "_pid%u.log", dir,
1838	os::file_separator(), thread_id, os::current_process_id());
1839	}
1840
1841	fp = fopen(file_name, "wt");
1842	if (fp != NULL) {
1843	if (LogCompilation && Verbose) {
1844	tty->print_cr("Opening compilation log %s", file_name);
1845	}
1846	CompileLog* log = new(ResourceObj::C_HEAP, mtCompiler) CompileLog (file_name, fp, thread_id);
1847	if (log == NULL) {
1848	fclose(fp);
1849	return;
1850	}
1851	thread->init_log(log);
1852
1853	if (xtty != NULL) {
1854	ttyLocker ttyl;
1855	// Record any per thread log files
1856	xtty->elem("thread_logfile thread='" INTX_FORMAT "' filename='%s'", thread_id, file_name);
1857	}
1858	return;
1859	}
1860	}
1861	warning("Cannot open log file: %s", file_name);
1862	}
1863
1864	void CompileBroker::log_metaspace_failure() {
1865	const char* message = "some methods may not be compiled because metaspace "
1866	"is out of memory";
1867	if (_compilation_log != NULL) {
1868	_compilation_log->log_metaspace_failure(message);
1869	}
1870	if (PrintCompilation) {
1871	tty->print_cr("COMPILE PROFILING SKIPPED: %s", message);
1872	}
1873	}
1874
1875
1876	// ------------------------------------------------------------------
1877	// CompileBroker::set_should_block
1878	//
1879	// Set _should_block.
1880	// Call this from the VM, with Threads_lock held and a safepoint requested.
1881	void CompileBroker::set_should_block() {
1882	assert(Threads_lock->owner() == Thread::current(), "must have threads lock");
1883	assert(SafepointSynchronize::is_at_safepoint(), "must be at a safepoint already");
1884	#ifndef PRODUCT
1885	if (PrintCompilation && (Verbose \|\| WizardMode))
1886	tty->print_cr("notifying compiler thread pool to block");
1887	#endif
1888	_should_block = true;
1889	}
1890
1891	// ------------------------------------------------------------------
1892	// CompileBroker::maybe_block
1893	//
1894	// Call this from the compiler at convenient points, to poll for _should_block.
1895	void CompileBroker::maybe_block() {
1896	if (_should_block) {
1897	#ifndef PRODUCT
1898	if (PrintCompilation && (Verbose \|\| WizardMode))
1899	tty->print_cr("compiler thread " INTPTR_FORMAT " poll detects block request", p2i(Thread::current()));
1900	#endif
1901	ThreadInVMfromNative tivfn(JavaThread::current());
1902	}
1903	}
1904
1905	// wrapper for CodeCache::print_summary()
1906	static void codecache_print(bool detailed)
1907	{
1908	ResourceMark rm;
1909	stringStream s;
1910	// Dump code cache into a buffer before locking the tty,
1911	{
1912	MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag);
1913	CodeCache::print_summary(&s, detailed);
1914	}
1915	ttyLocker ttyl;
1916	tty->print("%s", s.as_string());
1917	}
1918
1919	// wrapper for CodeCache::print_summary() using outputStream
1920	static void codecache_print(outputStream* out, bool detailed) {
1921	ResourceMark rm;
1922	stringStream s;
1923
1924	// Dump code cache into a buffer
1925	{
1926	MutexLocker mu(CodeCache_lock, Mutex::_no_safepoint_check_flag);
1927	CodeCache::print_summary(&s, detailed);
1928	}
1929
1930	char* remaining_log = s.as_string();
1931	while (*remaining_log != `'\0'`) {
1932	char* eol = strchr(remaining_log, `'\n'`);
1933	if (eol == NULL) {
1934	out->print_cr("%s", remaining_log);
1935	remaining_log = remaining_log + strlen(remaining_log);
1936	} else {
1937	*eol = `'\0'`;
1938	out->print_cr("%s", remaining_log);
1939	remaining_log = eol + `1`;
1940	}
1941	}
1942	}
1943
1944	void CompileBroker::post_compile(CompilerThread* thread, CompileTask* task, bool success, ciEnv* ci_env,
1945	int compilable, const char* failure_reason) {
1946	if (success) {
1947	task->mark_success();
1948	if (ci_env != NULL) {
1949	task->set_num_inlined_bytecodes(ci_env->num_inlined_bytecodes());
1950	}
1951	if (_compilation_log != NULL) {
1952	nmethod* code = task->code();
1953	if (code != NULL) {
1954	_compilation_log->log_nmethod(thread, code);
1955	}
1956	}
1957	} else if (AbortVMOnCompilationFailure) {
1958	if (compilable == ciEnv::MethodCompilable_not_at_tier) {
1959	fatal("Not compilable at tier %d: %s", task->comp_level(), failure_reason);
1960	}
1961	if (compilable == ciEnv::MethodCompilable_never) {
1962	fatal("Never compilable: %s", failure_reason);
1963	}
1964	}
1965	// simulate crash during compilation
1966	assert(task->compile_id() != CICrashAt, "just as planned");
1967	}
1968
1969	static void post_compilation_event(EventCompilation* event, CompileTask* task) {
1970	assert(event != NULL, "invariant");
1971	assert(event->should_commit(), "invariant");
1972	event->set_method(task->method());
1973	event->set_compileId(task->compile_id());
1974	event->set_compileLevel(task->comp_level());
1975	event->set_succeded(task->is_success());
1976	event->set_isOsr(task->osr_bci() != CompileBroker::standard_entry_bci);
1977	event->set_codeSize((task->code() == NULL) ? `0` : task->code()->total_size());
1978	event->set_inlinedBytes(task->num_inlined_bytecodes());
1979	event->commit();
1980	}
1981
1982	int DirectivesStack::_depth = `0`;
1983	CompilerDirectives* DirectivesStack::_top = NULL;
1984	CompilerDirectives* DirectivesStack::_bottom = NULL;
1985
1986	// ------------------------------------------------------------------
1987	// CompileBroker::invoke_compiler_on_method
1988	//
1989	// Compile a method.
1990	//
1991	void CompileBroker::invoke_compiler_on_method(CompileTask* task) {
1992	task->print_ul();
1993	if (PrintCompilation) {
1994	ResourceMark rm;
1995	task->print_tty();
1996	}
1997	elapsedTimer time;
1998
1999	CompilerThread* thread = CompilerThread::current();
2000	ResourceMark rm(thread);
2001
2002	if (LogEvents) {
2003	_compilation_log->log_compile(thread, task);
2004	}
2005
2006	// Common flags.
2007	uint compile_id = task->compile_id();
2008	int osr_bci = task->osr_bci();
2009	bool is_osr = (osr_bci != standard_entry_bci);
2010	bool should_log = (thread->log() != NULL);
2011	bool should_break = false;
2012	const int task_level = task->comp_level();
2013	AbstractCompiler* comp = task->compiler();
2014
2015	DirectiveSet* directive;
2016	{
2017	// create the handle inside it's own block so it can't
2018	// accidentally be referenced once the thread transitions to
2019	// native. The NoHandleMark before the transition should catch
2020	// any cases where this occurs in the future.
2021	methodHandle method(thread, task->method());
2022	assert(!method->is_native(), "no longer compile natives");
2023
2024	// Look up matching directives
2025	directive = DirectivesStack::getMatchingDirective(method, comp);
2026
2027	// Update compile information when using perfdata.
2028	if (UsePerfData) {
2029	update_compile_perf_data(thread, method, is_osr);
2030	}
2031
2032	DTRACE_METHOD_COMPILE_BEGIN_PROBE(method, compiler_name(task_level));
2033	}
2034
2035	should_break = directive->BreakAtExecuteOption \|\| task->check_break_at_flags();
2036	if (should_log && !directive->LogOption) {
2037	should_log = false;
2038	}
2039
2040	// Allocate a new set of JNI handles.
2041	push_jni_handle_block();
2042	Method* target_handle = task->method();
2043	int compilable = ciEnv::MethodCompilable;
2044	const char* failure_reason = NULL;
2045	bool failure_reason_on_C_heap = false;
2046	const char* retry_message = NULL;
2047
2048	int system_dictionary_modification_counter;
2049	{
2050	MutexLocker locker(Compile_lock, thread);
2051	system_dictionary_modification_counter = SystemDictionary::number_of_modifications();
2052	}
2053
2054	#if INCLUDE_JVMCI
2055	if (UseJVMCICompiler && comp != NULL && comp->is_jvmci()) {
2056	JVMCICompiler* jvmci = (JVMCICompiler*) comp;
2057
2058	TraceTime t1("compilation", &time);
2059	EventCompilation event;
2060
2061	// Skip redefined methods
2062	if (target_handle->is_old()) {
2063	failure_reason = "redefined method";
2064	retry_message = "not retryable";
2065	compilable = ciEnv::MethodCompilable_never;
2066	} else {
2067	JVMCICompileState compile_state(task, system_dictionary_modification_counter);
2068	JVMCIEnv env(thread, &compile_state, __FILE__, __LINE__);
2069	methodHandle method(thread, target_handle);
2070	env.runtime()->compile_method(&env, jvmci, method, osr_bci);
2071
2072	failure_reason = compile_state.failure_reason();
2073	failure_reason_on_C_heap = compile_state.failure_reason_on_C_heap();
2074	if (!compile_state.retryable()) {
2075	retry_message = "not retryable";
2076	compilable = ciEnv::MethodCompilable_not_at_tier;
2077	}
2078	if (task->code() == NULL) {
2079	assert(failure_reason != NULL, "must specify failure_reason");
2080	}
2081	}
2082	post_compile(thread, task, task->code() != NULL, NULL, compilable, failure_reason);
2083	if (event.should_commit()) {
2084	post_compilation_event(&event, task);
2085	}
2086
2087	} else
2088	#endif // INCLUDE_JVMCI
2089	{
2090	NoHandleMark nhm;
2091	ThreadToNativeFromVM ttn(thread);
2092
2093	ciEnv ci_env(task, system_dictionary_modification_counter);
2094	if (should_break) {
2095	ci_env.set_break_at_compile(true);
2096	}
2097	if (should_log) {
2098	ci_env.set_log(thread->log());
2099	}
2100	assert(thread->env() == &ci_env, "set by ci_env");
2101	// The thread-env() field is cleared in ~CompileTaskWrapper.
2102
2103	// Cache Jvmti state
2104	ci_env.cache_jvmti_state();
2105
2106	// Cache DTrace flags
2107	ci_env.cache_dtrace_flags();
2108
2109	ciMethod* target = ci_env.get_method_from_handle(target_handle);
2110
2111	TraceTime t1("compilation", &time);
2112	EventCompilation event;
2113
2114	if (comp == NULL) {
2115	ci_env.record_method_not_compilable("no compiler", !TieredCompilation);
2116	} else {
2117	if (WhiteBoxAPI && WhiteBox::compilation_locked) {
2118	MonitorLocker locker(Compilation_lock, Mutex::_no_safepoint_check_flag);
2119	while (WhiteBox::compilation_locked) {
2120	locker.wait();
2121	}
2122	}
2123	comp->compile_method(&ci_env, target, osr_bci, directive);
2124	}
2125
2126	if (!ci_env.failing() && task->code() == NULL) {
2127	//assert(false, "compiler should always document failure");
2128	// The compiler elected, without comment, not to register a result.
2129	// Do not attempt further compilations of this method.
2130	ci_env.record_method_not_compilable("compile failed", !TieredCompilation);
2131	}
2132
2133	// Copy this bit to the enclosing block:
2134	compilable = ci_env.compilable();
2135
2136	if (ci_env.failing()) {
2137	failure_reason = ci_env.failure_reason();
2138	retry_message = ci_env.retry_message();
2139	ci_env.report_failure(failure_reason);
2140	}
2141
2142	post_compile(thread, task, !ci_env.failing(), &ci_env, compilable, failure_reason);
2143	if (event.should_commit()) {
2144	post_compilation_event(&event, task);
2145	}
2146	}
2147	// Remove the JNI handle block after the ciEnv destructor has run in
2148	// the previous block.
2149	pop_jni_handle_block();
2150
2151	if (failure_reason != NULL) {
2152	task->set_failure_reason(failure_reason, failure_reason_on_C_heap);
2153	if (_compilation_log != NULL) {
2154	_compilation_log->log_failure(thread, task, failure_reason, retry_message);
2155	}
2156	if (PrintCompilation) {
2157	FormatBufferResource msg = retry_message != NULL ?
2158	FormatBufferResource ("COMPILE SKIPPED: %s (%s)", failure_reason, retry_message) :
2159	FormatBufferResource ("COMPILE SKIPPED: %s", failure_reason);
2160	task->print(tty, msg);
2161	}
2162	}
2163
2164	methodHandle method(thread, task->method());
2165
2166	DTRACE_METHOD_COMPILE_END_PROBE(method, compiler_name(task_level), task->is_success());
2167
2168	collect_statistics(thread, time, task);
2169
2170	nmethod* nm = task->code();
2171	if (nm != NULL) {
2172	nm->maybe_print_nmethod(directive);
2173	}
2174	DirectivesStack::release(directive);
2175
2176	if (PrintCompilation && PrintCompilation2) {
2177	tty->print("%7d ", (int) tty->time_stamp().milliseconds()); // print timestamp
2178	tty->print("%4d ", compile_id); // print compilation number
2179	tty->print("%s ", (is_osr ? "%" : " "));
2180	if (task->code() != NULL) {
2181	tty->print("size: %d(%d) ", task->code()->total_size(), task->code()->insts_size());
2182	}
2183	tty->print_cr("time: %d inlined: %d bytes", (int)time.milliseconds(), task->num_inlined_bytecodes());
2184	}
2185
2186	Log(compilation, codecache) log;
2187	if (log.is_debug()) {
2188	LogStream ls(log.debug());
2189	codecache_print(&ls, / detailed= / false);
2190	}
2191	if (PrintCodeCacheOnCompilation) {
2192	codecache_print(/ detailed= / false);
2193	}
2194	// Disable compilation, if required.
2195	switch (compilable) {
2196	case ciEnv::MethodCompilable_never:
2197	if (is_osr)
2198	method ->set_not_osr_compilable_quietly("MethodCompilable_never");
2199	else
2200	method ->set_not_compilable_quietly("MethodCompilable_never");
2201	break;
2202	case ciEnv::MethodCompilable_not_at_tier:
2203	if (is_osr)
2204	method ->set_not_osr_compilable_quietly("MethodCompilable_not_at_tier", task_level);
2205	else
2206	method ->set_not_compilable_quietly("MethodCompilable_not_at_tier", task_level);
2207	break;
2208	}
2209
2210	// Note that the queued_for_compilation bits are cleared without
2211	// protection of a mutex. [They were set by the requester thread,
2212	// when adding the task to the compile queue -- at which time the
2213	// compile queue lock was held. Subsequently, we acquired the compile
2214	// queue lock to get this task off the compile queue; thus (to belabour
2215	// the point somewhat) our clearing of the bits must be occurring
2216	// only after the setting of the bits. See also 14012000 above.
2217	method ->clear_queued_for_compilation();
2218	}
2219
2220	/**
2221	* The CodeCache is full. Print warning and disable compilation.
2222	* Schedule code cache cleaning so compilation can continue later.
2223	* This function needs to be called only from CodeCache::allocate(),
2224	* since we currently handle a full code cache uniformly.
2225	*/
2226	void CompileBroker::handle_full_code_cache(int code_blob_type) {
2227	UseInterpreter = true;
2228	if (UseCompiler \|\| AlwaysCompileLoopMethods ) {
2229	if (xtty != NULL) {
2230	ResourceMark rm;
2231	stringStream s;
2232	// Dump code cache state into a buffer before locking the tty,
2233	// because log_state() will use locks causing lock conflicts.
2234	CodeCache::log_state(&s);
2235	// Lock to prevent tearing
2236	ttyLocker ttyl;
2237	xtty->begin_elem("code_cache_full");
2238	xtty->print("%s", s.as_string());
2239	xtty->stamp();
2240	xtty->end_elem();
2241	}
2242
2243	#ifndef PRODUCT
2244	if (ExitOnFullCodeCache) {
2245	codecache_print(/ detailed= / true);
2246	before_exit(JavaThread::current());
2247	exit_globals(); // will delete tty
2248	vm_direct_exit(`1`);
2249	}
2250	#endif
2251	if (UseCodeCacheFlushing) {
2252	// Since code cache is full, immediately stop new compiles
2253	if (CompileBroker::set_should_compile_new_jobs(CompileBroker::stop_compilation)) {
2254	NMethodSweeper::log_sweep("disable_compiler");
2255	}
2256	} else {
2257	disable_compilation_forever();
2258	}
2259
2260	CodeCache::report_codemem_full(code_blob_type, should_print_compiler_warning());
2261	}
2262	}
2263
2264	// ------------------------------------------------------------------
2265	// CompileBroker::update_compile_perf_data
2266	//
2267	// Record this compilation for debugging purposes.
2268	void CompileBroker::update_compile_perf_data(CompilerThread* thread, const methodHandle& method, bool is_osr) {
2269	ResourceMark rm;
2270	char* method_name = method ->name()->as_C_string();
2271	char current_method[CompilerCounters::cmname_buffer_length];
2272	size_t maxLen = CompilerCounters::cmname_buffer_length;
2273
2274	const char* class_name = method ->method_holder()->name()->as_C_string();
2275
2276	size_t s1len = strlen(class_name);
2277	size_t s2len = strlen(method_name);
2278
2279	// check if we need to truncate the string
2280	if (s1len + s2len + `2` > maxLen) {
2281
2282	// the strategy is to lop off the leading characters of the
2283	// class name and the trailing characters of the method name.
2284
2285	if (s2len + `2` > maxLen) {
2286	// lop of the entire class name string, let snprintf handle
2287	// truncation of the method name.
2288	class_name += s1len; // null string
2289	}
2290	else {
2291	// lop off the extra characters from the front of the class name
2292	class_name += ((s1len + s2len + `2`) - maxLen);
2293	}
2294	}
2295
2296	jio_snprintf(current_method, maxLen, "%s %s", class_name, method_name);
2297
2298	int last_compile_type = normal_compile;
2299	if (CICountOSR && is_osr) {
2300	last_compile_type = osr_compile;
2301	}
2302
2303	CompilerCounters* counters = thread->counters();
2304	counters->set_current_method(current_method);
2305	counters->set_compile_type((jlong) last_compile_type);
2306	}
2307
2308	// ------------------------------------------------------------------
2309	// CompileBroker::push_jni_handle_block
2310	//
2311	// Push on a new block of JNI handles.
2312	void CompileBroker::push_jni_handle_block() {
2313	JavaThread* thread = JavaThread::current();
2314
2315	// Allocate a new block for JNI handles.
2316	// Inlined code from jni_PushLocalFrame()
2317	JNIHandleBlock* java_handles = thread->active_handles();
2318	JNIHandleBlock* compile_handles = JNIHandleBlock::allocate_block(thread);
2319	assert(compile_handles != NULL && java_handles != NULL, "should not be NULL");
2320	compile_handles->set_pop_frame_link(java_handles); // make sure java handles get gc'd.
2321	thread->set_active_handles(compile_handles);
2322	}
2323
2324
2325	// ------------------------------------------------------------------
2326	// CompileBroker::pop_jni_handle_block
2327	//
2328	// Pop off the current block of JNI handles.
2329	void CompileBroker::pop_jni_handle_block() {
2330	JavaThread* thread = JavaThread::current();
2331
2332	// Release our JNI handle block
2333	JNIHandleBlock* compile_handles = thread->active_handles();
2334	JNIHandleBlock* java_handles = compile_handles->pop_frame_link();
2335	thread->set_active_handles(java_handles);
2336	compile_handles->set_pop_frame_link(NULL);
2337	JNIHandleBlock::release_block(compile_handles, thread); // may block
2338	}
2339
2340	// ------------------------------------------------------------------
2341	// CompileBroker::collect_statistics
2342	//
2343	// Collect statistics about the compilation.
2344
2345	void CompileBroker::collect_statistics(CompilerThread* thread, elapsedTimer time, CompileTask* task) {
2346	bool success = task->is_success();
2347	methodHandle method (thread, task->method());
2348	uint compile_id = task->compile_id();
2349	bool is_osr = (task->osr_bci() != standard_entry_bci);
2350	nmethod* code = task->code();
2351	CompilerCounters* counters = thread->counters();
2352
2353	assert(code == NULL \|\| code->is_locked_by_vm(), "will survive the MutexLocker");
2354	MutexLocker locker(CompileStatistics_lock);
2355
2356	// _perf variables are production performance counters which are
2357	// updated regardless of the setting of the CITime and CITimeEach flags
2358	//
2359
2360	// account all time, including bailouts and failures in this counter;
2361	// C1 and C2 counters are counting both successful and unsuccessful compiles
2362	_t_total_compilation.add(time);
2363
2364	if (!success) {
2365	_total_bailout_count++;
2366	if (UsePerfData) {
2367	_perf_last_failed_method->set_value(counters->current_method());
2368	_perf_last_failed_type->set_value(counters->compile_type());
2369	_perf_total_bailout_count->inc();
2370	}
2371	_t_bailedout_compilation.add(time);
2372	} else if (code == NULL) {
2373	if (UsePerfData) {
2374	_perf_last_invalidated_method->set_value(counters->current_method());
2375	_perf_last_invalidated_type->set_value(counters->compile_type());
2376	_perf_total_invalidated_count->inc();
2377	}
2378	_total_invalidated_count++;
2379	_t_invalidated_compilation.add(time);
2380	} else {
2381	// Compilation succeeded
2382
2383	// update compilation ticks - used by the implementation of
2384	// java.lang.management.CompilationMBean
2385	_perf_total_compilation->inc(time.ticks());
2386	_peak_compilation_time = time.milliseconds() > _peak_compilation_time ? time.milliseconds() : _peak_compilation_time;
2387
2388	if (CITime) {
2389	int bytes_compiled = method ->code_size() + task->num_inlined_bytecodes();
2390	if (is_osr) {
2391	_t_osr_compilation.add(time);
2392	_sum_osr_bytes_compiled += bytes_compiled;
2393	} else {
2394	_t_standard_compilation.add(time);
2395	_sum_standard_bytes_compiled += method ->code_size() + task->num_inlined_bytecodes();
2396	}
2397
2398	#if INCLUDE_JVMCI
2399	AbstractCompiler* comp = compiler(task->comp_level());
2400	if (comp) {
2401	CompilerStatistics* stats = comp->stats();
2402	if (stats) {
2403	if (is_osr) {
2404	stats->_osr.update(time, bytes_compiled);
2405	} else {
2406	stats->_standard.update(time, bytes_compiled);
2407	}
2408	stats->_nmethods_size += code->total_size();
2409	stats->_nmethods_code_size += code->insts_size();
2410	} else { // if (!stats)
2411	assert(false, "Compiler statistics object must exist");
2412	}
2413	} else { // if (!comp)
2414	assert(false, "Compiler object must exist");
2415	}
2416	#endif // INCLUDE_JVMCI
2417	}
2418
2419	if (UsePerfData) {
2420	// save the name of the last method compiled
2421	_perf_last_method->set_value(counters->current_method());
2422	_perf_last_compile_type->set_value(counters->compile_type());
2423	_perf_last_compile_size->set_value(method ->code_size() +
2424	task->num_inlined_bytecodes());
2425	if (is_osr) {
2426	_perf_osr_compilation->inc(time.ticks());
2427	_perf_sum_osr_bytes_compiled->inc(method ->code_size() + task->num_inlined_bytecodes());
2428	} else {
2429	_perf_standard_compilation->inc(time.ticks());
2430	_perf_sum_standard_bytes_compiled->inc(method ->code_size() + task->num_inlined_bytecodes());
2431	}
2432	}
2433
2434	if (CITimeEach) {
2435	float bytes_per_sec = `1.0` * (method ->code_size() + task->num_inlined_bytecodes()) / time.seconds();
2436	tty->print_cr("%3d seconds: %f bytes/sec : %f (bytes %d + %d inlined)",
2437	compile_id, time.seconds(), bytes_per_sec, method ->code_size(), task->num_inlined_bytecodes());
2438	}
2439
2440	// Collect counts of successful compilations
2441	_sum_nmethod_size += code->total_size();
2442	_sum_nmethod_code_size += code->insts_size();
2443	_total_compile_count++;
2444
2445	if (UsePerfData) {
2446	_perf_sum_nmethod_size->inc( code->total_size());
2447	_perf_sum_nmethod_code_size->inc(code->insts_size());
2448	_perf_total_compile_count->inc();
2449	}
2450
2451	if (is_osr) {
2452	if (UsePerfData) _perf_total_osr_compile_count->inc();
2453	_total_osr_compile_count++;
2454	} else {
2455	if (UsePerfData) _perf_total_standard_compile_count->inc();
2456	_total_standard_compile_count++;
2457	}
2458	}
2459	// set the current method for the thread to null
2460	if (UsePerfData) counters->set_current_method("");
2461	}
2462
2463	const char* CompileBroker::compiler_name(int comp_level) {
2464	AbstractCompiler *comp = CompileBroker::compiler(comp_level);
2465	if (comp == NULL) {
2466	return "no compiler";
2467	} else {
2468	return (comp->name());
2469	}
2470	}
2471
2472	#if INCLUDE_JVMCI
2473	void CompileBroker::print_times(AbstractCompiler* comp) {
2474	CompilerStatistics* stats = comp->stats();
2475	if (stats) {
2476	tty->print_cr(" %s {speed: %d bytes/s; standard: %6.3f s, %d bytes, %d methods; osr: %6.3f s, %d bytes, %d methods; nmethods_size: %d bytes; nmethods_code_size: %d bytes}",
2477	comp->name(), stats->bytes_per_second(),
2478	stats->_standard._time.seconds(), stats->_standard._bytes, stats->_standard._count,
2479	stats->_osr._time.seconds(), stats->_osr._bytes, stats->_osr._count,
2480	stats->_nmethods_size, stats->_nmethods_code_size);
2481	} else { // if (!stats)
2482	assert(false, "Compiler statistics object must exist");
2483	}
2484	comp->print_timers();
2485	}
2486	#endif // INCLUDE_JVMCI
2487
2488	void CompileBroker::print_times(bool per_compiler, bool aggregate) {
2489	#if INCLUDE_JVMCI
2490	elapsedTimer standard_compilation;
2491	elapsedTimer total_compilation;
2492	elapsedTimer osr_compilation;
2493
2494	int standard_bytes_compiled = `0`;
2495	int osr_bytes_compiled = `0`;
2496
2497	int standard_compile_count = `0`;
2498	int osr_compile_count = `0`;
2499	int total_compile_count = `0`;
2500
2501	int nmethods_size = `0`;
2502	int nmethods_code_size = `0`;
2503	bool printedHeader = false;
2504
2505	for (unsigned int i = `0`; i < sizeof(_compilers) / sizeof(AbstractCompiler*); i++) {
2506	AbstractCompiler* comp = _compilers[i];
2507	if (comp != NULL) {
2508	if (per_compiler && aggregate && !printedHeader) {
2509	printedHeader = true;
2510	tty->cr();
2511	tty->print_cr("Individual compiler times (for compiled methods only)");
2512	tty->print_cr("------------------------------------------------");
2513	tty->cr();
2514	}
2515	CompilerStatistics* stats = comp->stats();
2516
2517	if (stats) {
2518	standard_compilation.add(stats->_standard._time);
2519	osr_compilation.add(stats->_osr._time);
2520
2521	standard_bytes_compiled += stats->_standard._bytes;
2522	osr_bytes_compiled += stats->_osr._bytes;
2523
2524	standard_compile_count += stats->_standard._count;
2525	osr_compile_count += stats->_osr._count;
2526
2527	nmethods_size += stats->_nmethods_size;
2528	nmethods_code_size += stats->_nmethods_code_size;
2529	} else { // if (!stats)
2530	assert(false, "Compiler statistics object must exist");
2531	}
2532
2533	if (per_compiler) {
2534	print_times(comp);
2535	}
2536	}
2537	}
2538	total_compile_count = osr_compile_count + standard_compile_count;
2539	total_compilation.add(osr_compilation);
2540	total_compilation.add(standard_compilation);
2541
2542	// In hosted mode, print the JVMCI compiler specific counters manually.
2543	if (!UseJVMCICompiler) {
2544	JVMCICompiler::print_compilation_timers();
2545	}
2546	#else // INCLUDE_JVMCI
2547	elapsedTimer standard_compilation = CompileBroker::_t_standard_compilation;
2548	elapsedTimer osr_compilation = CompileBroker::_t_osr_compilation;
2549	elapsedTimer total_compilation = CompileBroker::_t_total_compilation;
2550
2551	int standard_bytes_compiled = CompileBroker::_sum_standard_bytes_compiled;
2552	int osr_bytes_compiled = CompileBroker::_sum_osr_bytes_compiled;
2553
2554	int standard_compile_count = CompileBroker::_total_standard_compile_count;
2555	int osr_compile_count = CompileBroker::_total_osr_compile_count;
2556	int total_compile_count = CompileBroker::_total_compile_count;
2557
2558	int nmethods_size = CompileBroker::_sum_nmethod_code_size;
2559	int nmethods_code_size = CompileBroker::_sum_nmethod_size;
2560	#endif // INCLUDE_JVMCI
2561
2562	if (!aggregate) {
2563	return;
2564	}
2565	tty->cr();
2566	tty->print_cr("Accumulated compiler times");
2567	tty->print_cr("----------------------------------------------------------");
2568	//0000000000111111111122222222223333333333444444444455555555556666666666
2569	//0123456789012345678901234567890123456789012345678901234567890123456789
2570	tty->print_cr(" Total compilation time : %7.3f s", total_compilation.seconds());
2571	tty->print_cr(" Standard compilation : %7.3f s, Average : %2.3f s",
2572	standard_compilation.seconds(),
2573	standard_compilation.seconds() / standard_compile_count);
2574	tty->print_cr(" Bailed out compilation : %7.3f s, Average : %2.3f s",
2575	CompileBroker::_t_bailedout_compilation.seconds(),
2576	CompileBroker::_t_bailedout_compilation.seconds() / CompileBroker::_total_bailout_count);
2577	tty->print_cr(" On stack replacement : %7.3f s, Average : %2.3f s",
2578	osr_compilation.seconds(),
2579	osr_compilation.seconds() / osr_compile_count);
2580	tty->print_cr(" Invalidated : %7.3f s, Average : %2.3f s",
2581	CompileBroker::_t_invalidated_compilation.seconds(),
2582	CompileBroker::_t_invalidated_compilation.seconds() / CompileBroker::_total_invalidated_count);
2583
2584	AbstractCompiler *comp = compiler(CompLevel_simple);
2585	if (comp != NULL) {
2586	tty->cr();
2587	comp->print_timers();
2588	}
2589	comp = compiler(CompLevel_full_optimization);
2590	if (comp != NULL) {
2591	tty->cr();
2592	comp->print_timers();
2593	}
2594	tty->cr();
2595	tty->print_cr(" Total compiled methods : %8d methods", total_compile_count);
2596	tty->print_cr(" Standard compilation : %8d methods", standard_compile_count);
2597	tty->print_cr(" On stack replacement : %8d methods", osr_compile_count);
2598	int tcb = osr_bytes_compiled + standard_bytes_compiled;
2599	tty->print_cr(" Total compiled bytecodes : %8d bytes", tcb);
2600	tty->print_cr(" Standard compilation : %8d bytes", standard_bytes_compiled);
2601	tty->print_cr(" On stack replacement : %8d bytes", osr_bytes_compiled);
2602	double tcs = total_compilation.seconds();
2603	int bps = tcs == `0.0` ? `0` : (int)(tcb / tcs);
2604	tty->print_cr(" Average compilation speed : %8d bytes/s", bps);
2605	tty->cr();
2606	tty->print_cr(" nmethod code size : %8d bytes", nmethods_code_size);
2607	tty->print_cr(" nmethod total size : %8d bytes", nmethods_size);
2608	}
2609
2610	// Print general/accumulated JIT information.
2611	void CompileBroker::print_info(outputStream *out) {
2612	if (out == NULL) out = tty;
2613	out->cr();
2614	out->print_cr("======================");
2615	out->print_cr(" General JIT info ");
2616	out->print_cr("======================");
2617	out->cr();
2618	out->print_cr(" JIT is : %7s", should_compile_new_jobs() ? "on" : "off");
2619	out->print_cr(" Compiler threads : %7d", (int)CICompilerCount);
2620	out->cr();
2621	out->print_cr("CodeCache overview");
2622	out->print_cr("--------------------------------------------------------");
2623	out->cr();
2624	out->print_cr(" Reserved size : " SIZE_FORMAT_W(`7`) " KB", CodeCache::max_capacity() / K);
2625	out->print_cr(" Committed size : " SIZE_FORMAT_W(`7`) " KB", CodeCache::capacity() / K);
2626	out->print_cr(" Unallocated capacity : " SIZE_FORMAT_W(`7`) " KB", CodeCache::unallocated_capacity() / K);
2627	out->cr();
2628
2629	out->cr();
2630	out->print_cr("CodeCache cleaning overview");
2631	out->print_cr("--------------------------------------------------------");
2632	out->cr();
2633	NMethodSweeper::print(out);
2634	out->print_cr("--------------------------------------------------------");
2635	out->cr();
2636	}
2637
2638	// Note: tty_lock must not be held upon entry to this function.
2639	// Print functions called from herein do "micro-locking" on tty_lock.
2640	// That's a tradeoff which keeps together important blocks of output.
2641	// At the same time, continuous tty_lock hold time is kept in check,
2642	// preventing concurrently printing threads from stalling a long time.
2643	void CompileBroker::print_heapinfo(outputStream* out, const char* function, size_t granularity) {
2644	TimeStamp ts_total;
2645	TimeStamp ts_global;
2646	TimeStamp ts;
2647
2648	bool allFun = !strcmp(function, "all");
2649	bool aggregate = !strcmp(function, "aggregate") \|\| !strcmp(function, "analyze") \|\| allFun;
2650	bool usedSpace = !strcmp(function, "UsedSpace") \|\| allFun;
2651	bool freeSpace = !strcmp(function, "FreeSpace") \|\| allFun;
2652	bool methodCount = !strcmp(function, "MethodCount") \|\| allFun;
2653	bool methodSpace = !strcmp(function, "MethodSpace") \|\| allFun;
2654	bool methodAge = !strcmp(function, "MethodAge") \|\| allFun;
2655	bool methodNames = !strcmp(function, "MethodNames") \|\| allFun;
2656	bool discard = !strcmp(function, "discard") \|\| allFun;
2657
2658	if (out == NULL) {
2659	out = tty;
2660	}
2661
2662	if (!(aggregate \|\| usedSpace \|\| freeSpace \|\| methodCount \|\| methodSpace \|\| methodAge \|\| methodNames \|\| discard)) {
2663	out->print_cr("\n__ CodeHeapStateAnalytics: Function %s is not supported", function);
2664	out->cr();
2665	return;
2666	}
2667
2668	ts_total.update(); // record starting point
2669
2670	if (aggregate) {
2671	print_info(out);
2672	}
2673
2674	// We hold the CodeHeapStateAnalytics_lock all the time, from here until we leave this function.
2675	// That prevents another thread from destroying our view on the CodeHeap.
2676	// When we request individual parts of the analysis via the jcmd interface, it is possible
2677	// that in between another thread (another jcmd user or the vm running into CodeCache OOM)
2678	// updated the aggregated data. That's a tolerable tradeoff because we can't hold a lock
2679	// across user interaction.
2680	// Acquire this lock before acquiring the CodeCache_lock.
2681	// CodeHeapStateAnalytics_lock could be held by a concurrent thread for a long time,
2682	// leading to an unnecessarily long hold time of the CodeCache_lock.
2683	ts.update(); // record starting point
2684	MutexLocker mu1(CodeHeapStateAnalytics_lock, Mutex::_no_safepoint_check_flag);
2685	out->print_cr("\n__ CodeHeapStateAnalytics lock wait took %10.3f seconds _________\n", ts.seconds());
2686
2687	// If we serve an "allFun" call, it is beneficial to hold the CodeCache_lock
2688	// for the entire duration of aggregation and printing. That makes sure
2689	// we see a consistent picture and do not run into issues caused by
2690	// the CodeHeap being altered concurrently.
2691	Monitor* global_lock = allFun ? CodeCache_lock : NULL;
2692	Monitor* function_lock = allFun ? NULL : CodeCache_lock;
2693	ts_global.update(); // record starting point
2694	MutexLocker mu2(global_lock, Mutex::_no_safepoint_check_flag);
2695	if (global_lock != NULL) {
2696	out->print_cr("\n__ CodeCache (global) lock wait took %10.3f seconds _________\n", ts_global.seconds());
2697	ts_global.update(); // record starting point
2698	}
2699
2700	if (aggregate) {
2701	ts.update(); // record starting point
2702	MutexLocker mu3(function_lock, Mutex::_no_safepoint_check_flag);
2703	if (function_lock != NULL) {
2704	out->print_cr("\n__ CodeCache (function) lock wait took %10.3f seconds _________\n", ts.seconds());
2705	}
2706
2707	ts.update(); // record starting point
2708	CodeCache::aggregate(out, granularity);
2709	if (function_lock != NULL) {
2710	out->print_cr("\n__ CodeCache (function) lock hold took %10.3f seconds _________\n", ts.seconds());
2711	}
2712	}
2713
2714	if (usedSpace) CodeCache::print_usedSpace(out);
2715	if (freeSpace) CodeCache::print_freeSpace(out);
2716	if (methodCount) CodeCache::print_count(out);
2717	if (methodSpace) CodeCache::print_space(out);
2718	if (methodAge) CodeCache::print_age(out);
2719	if (methodNames) {
2720	// print_names() has shown to be sensitive to concurrent CodeHeap modifications.
2721	// Therefore, request the CodeCache_lock before calling...
2722	MutexLocker mu3(function_lock, Mutex::_no_safepoint_check_flag);
2723	CodeCache::print_names(out);
2724	}
2725	if (discard) CodeCache::discard(out);
2726
2727	if (global_lock != NULL) {
2728	out->print_cr("\n__ CodeCache (global) lock hold took %10.3f seconds _________\n", ts_global.seconds());
2729	}
2730	out->print_cr("\n__ CodeHeapStateAnalytics total duration %10.3f seconds _________\n", ts_total.seconds());
2731	}
2732

Browse the source code of OpenJDK/src/hotspot/share/compiler/compileBroker.cpp