Mercurial > hg > graal-compiler
annotate src/share/vm/gc_implementation/parallelScavenge/parallelScavengeHeap.cpp @ 1829:fe08403130db
6979458: VM crashes when -XX:ObjectAlignmentInBytes is too big
Summary: Set upper limit 256 for ObjectAlignmentInBytes value.
Reviewed-by: never, iveresov
author | kvn |
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date | Tue, 05 Oct 2010 08:57:20 -0700 |
parents | c18cbe5936b8 |
children | 1e9a9d2e6509 |
rev | line source |
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0 | 1 /* |
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2 * Copyright (c) 2001, 2010, Oracle and/or its affiliates. All rights reserved. |
0 | 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 * | |
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19 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
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20 * or visit www.oracle.com if you need additional information or have any |
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21 * questions. |
0 | 22 * |
23 */ | |
24 | |
25 # include "incls/_precompiled.incl" | |
26 # include "incls/_parallelScavengeHeap.cpp.incl" | |
27 | |
28 PSYoungGen* ParallelScavengeHeap::_young_gen = NULL; | |
29 PSOldGen* ParallelScavengeHeap::_old_gen = NULL; | |
30 PSPermGen* ParallelScavengeHeap::_perm_gen = NULL; | |
31 PSAdaptiveSizePolicy* ParallelScavengeHeap::_size_policy = NULL; | |
32 PSGCAdaptivePolicyCounters* ParallelScavengeHeap::_gc_policy_counters = NULL; | |
33 ParallelScavengeHeap* ParallelScavengeHeap::_psh = NULL; | |
34 GCTaskManager* ParallelScavengeHeap::_gc_task_manager = NULL; | |
35 | |
36 static void trace_gen_sizes(const char* const str, | |
37 size_t pg_min, size_t pg_max, | |
38 size_t og_min, size_t og_max, | |
39 size_t yg_min, size_t yg_max) | |
40 { | |
41 if (TracePageSizes) { | |
42 tty->print_cr("%s: " SIZE_FORMAT "," SIZE_FORMAT " " | |
43 SIZE_FORMAT "," SIZE_FORMAT " " | |
44 SIZE_FORMAT "," SIZE_FORMAT " " | |
45 SIZE_FORMAT, | |
46 str, pg_min / K, pg_max / K, | |
47 og_min / K, og_max / K, | |
48 yg_min / K, yg_max / K, | |
49 (pg_max + og_max + yg_max) / K); | |
50 } | |
51 } | |
52 | |
53 jint ParallelScavengeHeap::initialize() { | |
1166 | 54 CollectedHeap::pre_initialize(); |
55 | |
0 | 56 // Cannot be initialized until after the flags are parsed |
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57 // GenerationSizer flag_parser; |
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58 _collector_policy = new GenerationSizer(); |
0 | 59 |
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60 size_t yg_min_size = _collector_policy->min_young_gen_size(); |
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61 size_t yg_max_size = _collector_policy->max_young_gen_size(); |
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62 size_t og_min_size = _collector_policy->min_old_gen_size(); |
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63 size_t og_max_size = _collector_policy->max_old_gen_size(); |
0 | 64 // Why isn't there a min_perm_gen_size()? |
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65 size_t pg_min_size = _collector_policy->perm_gen_size(); |
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66 size_t pg_max_size = _collector_policy->max_perm_gen_size(); |
0 | 67 |
68 trace_gen_sizes("ps heap raw", | |
69 pg_min_size, pg_max_size, | |
70 og_min_size, og_max_size, | |
71 yg_min_size, yg_max_size); | |
72 | |
73 // The ReservedSpace ctor used below requires that the page size for the perm | |
74 // gen is <= the page size for the rest of the heap (young + old gens). | |
75 const size_t og_page_sz = os::page_size_for_region(yg_min_size + og_min_size, | |
76 yg_max_size + og_max_size, | |
77 8); | |
78 const size_t pg_page_sz = MIN2(os::page_size_for_region(pg_min_size, | |
79 pg_max_size, 16), | |
80 og_page_sz); | |
81 | |
82 const size_t pg_align = set_alignment(_perm_gen_alignment, pg_page_sz); | |
83 const size_t og_align = set_alignment(_old_gen_alignment, og_page_sz); | |
84 const size_t yg_align = set_alignment(_young_gen_alignment, og_page_sz); | |
85 | |
86 // Update sizes to reflect the selected page size(s). | |
87 // | |
88 // NEEDS_CLEANUP. The default TwoGenerationCollectorPolicy uses NewRatio; it | |
89 // should check UseAdaptiveSizePolicy. Changes from generationSizer could | |
90 // move to the common code. | |
91 yg_min_size = align_size_up(yg_min_size, yg_align); | |
92 yg_max_size = align_size_up(yg_max_size, yg_align); | |
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93 size_t yg_cur_size = |
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94 align_size_up(_collector_policy->young_gen_size(), yg_align); |
0 | 95 yg_cur_size = MAX2(yg_cur_size, yg_min_size); |
96 | |
97 og_min_size = align_size_up(og_min_size, og_align); | |
98 og_max_size = align_size_up(og_max_size, og_align); | |
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99 size_t og_cur_size = |
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100 align_size_up(_collector_policy->old_gen_size(), og_align); |
0 | 101 og_cur_size = MAX2(og_cur_size, og_min_size); |
102 | |
103 pg_min_size = align_size_up(pg_min_size, pg_align); | |
104 pg_max_size = align_size_up(pg_max_size, pg_align); | |
105 size_t pg_cur_size = pg_min_size; | |
106 | |
107 trace_gen_sizes("ps heap rnd", | |
108 pg_min_size, pg_max_size, | |
109 og_min_size, og_max_size, | |
110 yg_min_size, yg_max_size); | |
111 | |
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112 const size_t total_reserved = pg_max_size + og_max_size + yg_max_size; |
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113 char* addr = Universe::preferred_heap_base(total_reserved, Universe::UnscaledNarrowOop); |
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114 |
0 | 115 // The main part of the heap (old gen + young gen) can often use a larger page |
116 // size than is needed or wanted for the perm gen. Use the "compound | |
117 // alignment" ReservedSpace ctor to avoid having to use the same page size for | |
118 // all gens. | |
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119 |
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120 ReservedHeapSpace heap_rs(pg_max_size, pg_align, og_max_size + yg_max_size, |
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121 og_align, addr); |
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122 |
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123 if (UseCompressedOops) { |
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124 if (addr != NULL && !heap_rs.is_reserved()) { |
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125 // Failed to reserve at specified address - the requested memory |
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126 // region is taken already, for example, by 'java' launcher. |
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127 // Try again to reserver heap higher. |
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128 addr = Universe::preferred_heap_base(total_reserved, Universe::ZeroBasedNarrowOop); |
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129 ReservedHeapSpace heap_rs0(pg_max_size, pg_align, og_max_size + yg_max_size, |
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130 og_align, addr); |
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131 if (addr != NULL && !heap_rs0.is_reserved()) { |
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132 // Failed to reserve at specified address again - give up. |
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133 addr = Universe::preferred_heap_base(total_reserved, Universe::HeapBasedNarrowOop); |
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134 assert(addr == NULL, ""); |
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135 ReservedHeapSpace heap_rs1(pg_max_size, pg_align, og_max_size + yg_max_size, |
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136 og_align, addr); |
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137 heap_rs = heap_rs1; |
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138 } else { |
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139 heap_rs = heap_rs0; |
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140 } |
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141 } |
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142 } |
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143 |
0 | 144 os::trace_page_sizes("ps perm", pg_min_size, pg_max_size, pg_page_sz, |
145 heap_rs.base(), pg_max_size); | |
146 os::trace_page_sizes("ps main", og_min_size + yg_min_size, | |
147 og_max_size + yg_max_size, og_page_sz, | |
148 heap_rs.base() + pg_max_size, | |
149 heap_rs.size() - pg_max_size); | |
150 if (!heap_rs.is_reserved()) { | |
151 vm_shutdown_during_initialization( | |
152 "Could not reserve enough space for object heap"); | |
153 return JNI_ENOMEM; | |
154 } | |
155 | |
156 _reserved = MemRegion((HeapWord*)heap_rs.base(), | |
157 (HeapWord*)(heap_rs.base() + heap_rs.size())); | |
158 | |
159 CardTableExtension* const barrier_set = new CardTableExtension(_reserved, 3); | |
160 _barrier_set = barrier_set; | |
161 oopDesc::set_bs(_barrier_set); | |
162 if (_barrier_set == NULL) { | |
163 vm_shutdown_during_initialization( | |
164 "Could not reserve enough space for barrier set"); | |
165 return JNI_ENOMEM; | |
166 } | |
167 | |
168 // Initial young gen size is 4 Mb | |
169 // | |
170 // XXX - what about flag_parser.young_gen_size()? | |
171 const size_t init_young_size = align_size_up(4 * M, yg_align); | |
172 yg_cur_size = MAX2(MIN2(init_young_size, yg_max_size), yg_cur_size); | |
173 | |
174 // Split the reserved space into perm gen and the main heap (everything else). | |
175 // The main heap uses a different alignment. | |
176 ReservedSpace perm_rs = heap_rs.first_part(pg_max_size); | |
177 ReservedSpace main_rs = heap_rs.last_part(pg_max_size, og_align); | |
178 | |
179 // Make up the generations | |
180 // Calculate the maximum size that a generation can grow. This | |
181 // includes growth into the other generation. Note that the | |
182 // parameter _max_gen_size is kept as the maximum | |
183 // size of the generation as the boundaries currently stand. | |
184 // _max_gen_size is still used as that value. | |
185 double max_gc_pause_sec = ((double) MaxGCPauseMillis)/1000.0; | |
186 double max_gc_minor_pause_sec = ((double) MaxGCMinorPauseMillis)/1000.0; | |
187 | |
188 _gens = new AdjoiningGenerations(main_rs, | |
189 og_cur_size, | |
190 og_min_size, | |
191 og_max_size, | |
192 yg_cur_size, | |
193 yg_min_size, | |
194 yg_max_size, | |
195 yg_align); | |
196 | |
197 _old_gen = _gens->old_gen(); | |
198 _young_gen = _gens->young_gen(); | |
199 | |
200 const size_t eden_capacity = _young_gen->eden_space()->capacity_in_bytes(); | |
201 const size_t old_capacity = _old_gen->capacity_in_bytes(); | |
202 const size_t initial_promo_size = MIN2(eden_capacity, old_capacity); | |
203 _size_policy = | |
204 new PSAdaptiveSizePolicy(eden_capacity, | |
205 initial_promo_size, | |
206 young_gen()->to_space()->capacity_in_bytes(), | |
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207 intra_heap_alignment(), |
0 | 208 max_gc_pause_sec, |
209 max_gc_minor_pause_sec, | |
210 GCTimeRatio | |
211 ); | |
212 | |
213 _perm_gen = new PSPermGen(perm_rs, | |
214 pg_align, | |
215 pg_cur_size, | |
216 pg_cur_size, | |
217 pg_max_size, | |
218 "perm", 2); | |
219 | |
220 assert(!UseAdaptiveGCBoundary || | |
221 (old_gen()->virtual_space()->high_boundary() == | |
222 young_gen()->virtual_space()->low_boundary()), | |
223 "Boundaries must meet"); | |
224 // initialize the policy counters - 2 collectors, 3 generations | |
225 _gc_policy_counters = | |
226 new PSGCAdaptivePolicyCounters("ParScav:MSC", 2, 3, _size_policy); | |
227 _psh = this; | |
228 | |
229 // Set up the GCTaskManager | |
230 _gc_task_manager = GCTaskManager::create(ParallelGCThreads); | |
231 | |
232 if (UseParallelOldGC && !PSParallelCompact::initialize()) { | |
233 return JNI_ENOMEM; | |
234 } | |
235 | |
236 return JNI_OK; | |
237 } | |
238 | |
239 void ParallelScavengeHeap::post_initialize() { | |
240 // Need to init the tenuring threshold | |
241 PSScavenge::initialize(); | |
242 if (UseParallelOldGC) { | |
243 PSParallelCompact::post_initialize(); | |
244 } else { | |
245 PSMarkSweep::initialize(); | |
246 } | |
247 PSPromotionManager::initialize(); | |
248 } | |
249 | |
250 void ParallelScavengeHeap::update_counters() { | |
251 young_gen()->update_counters(); | |
252 old_gen()->update_counters(); | |
253 perm_gen()->update_counters(); | |
254 } | |
255 | |
256 size_t ParallelScavengeHeap::capacity() const { | |
257 size_t value = young_gen()->capacity_in_bytes() + old_gen()->capacity_in_bytes(); | |
258 return value; | |
259 } | |
260 | |
261 size_t ParallelScavengeHeap::used() const { | |
262 size_t value = young_gen()->used_in_bytes() + old_gen()->used_in_bytes(); | |
263 return value; | |
264 } | |
265 | |
266 bool ParallelScavengeHeap::is_maximal_no_gc() const { | |
267 return old_gen()->is_maximal_no_gc() && young_gen()->is_maximal_no_gc(); | |
268 } | |
269 | |
270 | |
271 size_t ParallelScavengeHeap::permanent_capacity() const { | |
272 return perm_gen()->capacity_in_bytes(); | |
273 } | |
274 | |
275 size_t ParallelScavengeHeap::permanent_used() const { | |
276 return perm_gen()->used_in_bytes(); | |
277 } | |
278 | |
279 size_t ParallelScavengeHeap::max_capacity() const { | |
280 size_t estimated = reserved_region().byte_size(); | |
281 estimated -= perm_gen()->reserved().byte_size(); | |
282 if (UseAdaptiveSizePolicy) { | |
283 estimated -= _size_policy->max_survivor_size(young_gen()->max_size()); | |
284 } else { | |
285 estimated -= young_gen()->to_space()->capacity_in_bytes(); | |
286 } | |
287 return MAX2(estimated, capacity()); | |
288 } | |
289 | |
290 bool ParallelScavengeHeap::is_in(const void* p) const { | |
291 if (young_gen()->is_in(p)) { | |
292 return true; | |
293 } | |
294 | |
295 if (old_gen()->is_in(p)) { | |
296 return true; | |
297 } | |
298 | |
299 if (perm_gen()->is_in(p)) { | |
300 return true; | |
301 } | |
302 | |
303 return false; | |
304 } | |
305 | |
306 bool ParallelScavengeHeap::is_in_reserved(const void* p) const { | |
307 if (young_gen()->is_in_reserved(p)) { | |
308 return true; | |
309 } | |
310 | |
311 if (old_gen()->is_in_reserved(p)) { | |
312 return true; | |
313 } | |
314 | |
315 if (perm_gen()->is_in_reserved(p)) { | |
316 return true; | |
317 } | |
318 | |
319 return false; | |
320 } | |
321 | |
322 // There are two levels of allocation policy here. | |
323 // | |
324 // When an allocation request fails, the requesting thread must invoke a VM | |
325 // operation, transfer control to the VM thread, and await the results of a | |
326 // garbage collection. That is quite expensive, and we should avoid doing it | |
327 // multiple times if possible. | |
328 // | |
329 // To accomplish this, we have a basic allocation policy, and also a | |
330 // failed allocation policy. | |
331 // | |
332 // The basic allocation policy controls how you allocate memory without | |
333 // attempting garbage collection. It is okay to grab locks and | |
334 // expand the heap, if that can be done without coming to a safepoint. | |
335 // It is likely that the basic allocation policy will not be very | |
336 // aggressive. | |
337 // | |
338 // The failed allocation policy is invoked from the VM thread after | |
339 // the basic allocation policy is unable to satisfy a mem_allocate | |
340 // request. This policy needs to cover the entire range of collection, | |
341 // heap expansion, and out-of-memory conditions. It should make every | |
342 // attempt to allocate the requested memory. | |
343 | |
344 // Basic allocation policy. Should never be called at a safepoint, or | |
345 // from the VM thread. | |
346 // | |
347 // This method must handle cases where many mem_allocate requests fail | |
348 // simultaneously. When that happens, only one VM operation will succeed, | |
349 // and the rest will not be executed. For that reason, this method loops | |
350 // during failed allocation attempts. If the java heap becomes exhausted, | |
351 // we rely on the size_policy object to force a bail out. | |
352 HeapWord* ParallelScavengeHeap::mem_allocate( | |
353 size_t size, | |
354 bool is_noref, | |
355 bool is_tlab, | |
356 bool* gc_overhead_limit_was_exceeded) { | |
357 assert(!SafepointSynchronize::is_at_safepoint(), "should not be at safepoint"); | |
358 assert(Thread::current() != (Thread*)VMThread::vm_thread(), "should not be in vm thread"); | |
359 assert(!Heap_lock->owned_by_self(), "this thread should not own the Heap_lock"); | |
360 | |
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361 // In general gc_overhead_limit_was_exceeded should be false so |
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362 // set it so here and reset it to true only if the gc time |
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363 // limit is being exceeded as checked below. |
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364 *gc_overhead_limit_was_exceeded = false; |
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365 |
0 | 366 HeapWord* result = young_gen()->allocate(size, is_tlab); |
367 | |
368 uint loop_count = 0; | |
369 uint gc_count = 0; | |
370 | |
371 while (result == NULL) { | |
372 // We don't want to have multiple collections for a single filled generation. | |
373 // To prevent this, each thread tracks the total_collections() value, and if | |
374 // the count has changed, does not do a new collection. | |
375 // | |
376 // The collection count must be read only while holding the heap lock. VM | |
377 // operations also hold the heap lock during collections. There is a lock | |
378 // contention case where thread A blocks waiting on the Heap_lock, while | |
379 // thread B is holding it doing a collection. When thread A gets the lock, | |
380 // the collection count has already changed. To prevent duplicate collections, | |
381 // The policy MUST attempt allocations during the same period it reads the | |
382 // total_collections() value! | |
383 { | |
384 MutexLocker ml(Heap_lock); | |
385 gc_count = Universe::heap()->total_collections(); | |
386 | |
387 result = young_gen()->allocate(size, is_tlab); | |
388 | |
389 // (1) If the requested object is too large to easily fit in the | |
390 // young_gen, or | |
391 // (2) If GC is locked out via GCLocker, young gen is full and | |
392 // the need for a GC already signalled to GCLocker (done | |
393 // at a safepoint), | |
394 // ... then, rather than force a safepoint and (a potentially futile) | |
395 // collection (attempt) for each allocation, try allocation directly | |
396 // in old_gen. For case (2) above, we may in the future allow | |
397 // TLAB allocation directly in the old gen. | |
398 if (result != NULL) { | |
399 return result; | |
400 } | |
401 if (!is_tlab && | |
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402 size >= (young_gen()->eden_space()->capacity_in_words(Thread::current()) / 2)) { |
0 | 403 result = old_gen()->allocate(size, is_tlab); |
404 if (result != NULL) { | |
405 return result; | |
406 } | |
407 } | |
408 if (GC_locker::is_active_and_needs_gc()) { | |
409 // GC is locked out. If this is a TLAB allocation, | |
410 // return NULL; the requestor will retry allocation | |
411 // of an idividual object at a time. | |
412 if (is_tlab) { | |
413 return NULL; | |
414 } | |
415 | |
416 // If this thread is not in a jni critical section, we stall | |
417 // the requestor until the critical section has cleared and | |
418 // GC allowed. When the critical section clears, a GC is | |
419 // initiated by the last thread exiting the critical section; so | |
420 // we retry the allocation sequence from the beginning of the loop, | |
421 // rather than causing more, now probably unnecessary, GC attempts. | |
422 JavaThread* jthr = JavaThread::current(); | |
423 if (!jthr->in_critical()) { | |
424 MutexUnlocker mul(Heap_lock); | |
425 GC_locker::stall_until_clear(); | |
426 continue; | |
427 } else { | |
428 if (CheckJNICalls) { | |
429 fatal("Possible deadlock due to allocating while" | |
430 " in jni critical section"); | |
431 } | |
432 return NULL; | |
433 } | |
434 } | |
435 } | |
436 | |
437 if (result == NULL) { | |
438 | |
439 // Generate a VM operation | |
440 VM_ParallelGCFailedAllocation op(size, is_tlab, gc_count); | |
441 VMThread::execute(&op); | |
442 | |
443 // Did the VM operation execute? If so, return the result directly. | |
444 // This prevents us from looping until time out on requests that can | |
445 // not be satisfied. | |
446 if (op.prologue_succeeded()) { | |
447 assert(Universe::heap()->is_in_or_null(op.result()), | |
448 "result not in heap"); | |
449 | |
450 // If GC was locked out during VM operation then retry allocation | |
451 // and/or stall as necessary. | |
452 if (op.gc_locked()) { | |
453 assert(op.result() == NULL, "must be NULL if gc_locked() is true"); | |
454 continue; // retry and/or stall as necessary | |
455 } | |
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456 |
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457 // Exit the loop if the gc time limit has been exceeded. |
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458 // The allocation must have failed above ("result" guarding |
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459 // this path is NULL) and the most recent collection has exceeded the |
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460 // gc overhead limit (although enough may have been collected to |
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461 // satisfy the allocation). Exit the loop so that an out-of-memory |
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462 // will be thrown (return a NULL ignoring the contents of |
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463 // op.result()), |
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464 // but clear gc_overhead_limit_exceeded so that the next collection |
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465 // starts with a clean slate (i.e., forgets about previous overhead |
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466 // excesses). Fill op.result() with a filler object so that the |
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467 // heap remains parsable. |
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468 const bool limit_exceeded = size_policy()->gc_overhead_limit_exceeded(); |
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469 const bool softrefs_clear = collector_policy()->all_soft_refs_clear(); |
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470 assert(!limit_exceeded || softrefs_clear, "Should have been cleared"); |
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471 if (limit_exceeded && softrefs_clear) { |
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472 *gc_overhead_limit_was_exceeded = true; |
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473 size_policy()->set_gc_overhead_limit_exceeded(false); |
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474 if (PrintGCDetails && Verbose) { |
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475 gclog_or_tty->print_cr("ParallelScavengeHeap::mem_allocate: " |
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476 "return NULL because gc_overhead_limit_exceeded is set"); |
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477 } |
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478 if (op.result() != NULL) { |
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479 CollectedHeap::fill_with_object(op.result(), size); |
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480 } |
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481 return NULL; |
0 | 482 } |
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483 |
0 | 484 return op.result(); |
485 } | |
486 } | |
487 | |
488 // The policy object will prevent us from looping forever. If the | |
489 // time spent in gc crosses a threshold, we will bail out. | |
490 loop_count++; | |
491 if ((result == NULL) && (QueuedAllocationWarningCount > 0) && | |
492 (loop_count % QueuedAllocationWarningCount == 0)) { | |
493 warning("ParallelScavengeHeap::mem_allocate retries %d times \n\t" | |
494 " size=%d %s", loop_count, size, is_tlab ? "(TLAB)" : ""); | |
495 } | |
496 } | |
497 | |
498 return result; | |
499 } | |
500 | |
501 // Failed allocation policy. Must be called from the VM thread, and | |
502 // only at a safepoint! Note that this method has policy for allocation | |
503 // flow, and NOT collection policy. So we do not check for gc collection | |
504 // time over limit here, that is the responsibility of the heap specific | |
505 // collection methods. This method decides where to attempt allocations, | |
506 // and when to attempt collections, but no collection specific policy. | |
507 HeapWord* ParallelScavengeHeap::failed_mem_allocate(size_t size, bool is_tlab) { | |
508 assert(SafepointSynchronize::is_at_safepoint(), "should be at safepoint"); | |
509 assert(Thread::current() == (Thread*)VMThread::vm_thread(), "should be in vm thread"); | |
510 assert(!Universe::heap()->is_gc_active(), "not reentrant"); | |
511 assert(!Heap_lock->owned_by_self(), "this thread should not own the Heap_lock"); | |
512 | |
513 size_t mark_sweep_invocation_count = total_invocations(); | |
514 | |
515 // We assume (and assert!) that an allocation at this point will fail | |
516 // unless we collect. | |
517 | |
518 // First level allocation failure, scavenge and allocate in young gen. | |
519 GCCauseSetter gccs(this, GCCause::_allocation_failure); | |
520 PSScavenge::invoke(); | |
521 HeapWord* result = young_gen()->allocate(size, is_tlab); | |
522 | |
523 // Second level allocation failure. | |
524 // Mark sweep and allocate in young generation. | |
525 if (result == NULL) { | |
526 // There is some chance the scavenge method decided to invoke mark_sweep. | |
527 // Don't mark sweep twice if so. | |
528 if (mark_sweep_invocation_count == total_invocations()) { | |
529 invoke_full_gc(false); | |
530 result = young_gen()->allocate(size, is_tlab); | |
531 } | |
532 } | |
533 | |
534 // Third level allocation failure. | |
535 // After mark sweep and young generation allocation failure, | |
536 // allocate in old generation. | |
537 if (result == NULL && !is_tlab) { | |
538 result = old_gen()->allocate(size, is_tlab); | |
539 } | |
540 | |
541 // Fourth level allocation failure. We're running out of memory. | |
542 // More complete mark sweep and allocate in young generation. | |
543 if (result == NULL) { | |
544 invoke_full_gc(true); | |
545 result = young_gen()->allocate(size, is_tlab); | |
546 } | |
547 | |
548 // Fifth level allocation failure. | |
549 // After more complete mark sweep, allocate in old generation. | |
550 if (result == NULL && !is_tlab) { | |
551 result = old_gen()->allocate(size, is_tlab); | |
552 } | |
553 | |
554 return result; | |
555 } | |
556 | |
557 // | |
558 // This is the policy loop for allocating in the permanent generation. | |
559 // If the initial allocation fails, we create a vm operation which will | |
560 // cause a collection. | |
561 HeapWord* ParallelScavengeHeap::permanent_mem_allocate(size_t size) { | |
562 assert(!SafepointSynchronize::is_at_safepoint(), "should not be at safepoint"); | |
563 assert(Thread::current() != (Thread*)VMThread::vm_thread(), "should not be in vm thread"); | |
564 assert(!Heap_lock->owned_by_self(), "this thread should not own the Heap_lock"); | |
565 | |
566 HeapWord* result; | |
567 | |
568 uint loop_count = 0; | |
569 uint gc_count = 0; | |
570 uint full_gc_count = 0; | |
571 | |
572 do { | |
573 // We don't want to have multiple collections for a single filled generation. | |
574 // To prevent this, each thread tracks the total_collections() value, and if | |
575 // the count has changed, does not do a new collection. | |
576 // | |
577 // The collection count must be read only while holding the heap lock. VM | |
578 // operations also hold the heap lock during collections. There is a lock | |
579 // contention case where thread A blocks waiting on the Heap_lock, while | |
580 // thread B is holding it doing a collection. When thread A gets the lock, | |
581 // the collection count has already changed. To prevent duplicate collections, | |
582 // The policy MUST attempt allocations during the same period it reads the | |
583 // total_collections() value! | |
584 { | |
585 MutexLocker ml(Heap_lock); | |
586 gc_count = Universe::heap()->total_collections(); | |
587 full_gc_count = Universe::heap()->total_full_collections(); | |
588 | |
589 result = perm_gen()->allocate_permanent(size); | |
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590 |
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591 if (result != NULL) { |
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592 return result; |
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593 } |
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594 |
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595 if (GC_locker::is_active_and_needs_gc()) { |
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596 // If this thread is not in a jni critical section, we stall |
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597 // the requestor until the critical section has cleared and |
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598 // GC allowed. When the critical section clears, a GC is |
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599 // initiated by the last thread exiting the critical section; so |
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600 // we retry the allocation sequence from the beginning of the loop, |
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601 // rather than causing more, now probably unnecessary, GC attempts. |
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602 JavaThread* jthr = JavaThread::current(); |
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603 if (!jthr->in_critical()) { |
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604 MutexUnlocker mul(Heap_lock); |
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605 GC_locker::stall_until_clear(); |
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606 continue; |
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607 } else { |
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608 if (CheckJNICalls) { |
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609 fatal("Possible deadlock due to allocating while" |
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610 " in jni critical section"); |
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611 } |
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612 return NULL; |
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613 } |
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614 } |
0 | 615 } |
616 | |
617 if (result == NULL) { | |
618 | |
619 // Exit the loop if the gc time limit has been exceeded. | |
620 // The allocation must have failed above (result must be NULL), | |
621 // and the most recent collection must have exceeded the | |
622 // gc time limit. Exit the loop so that an out-of-memory | |
623 // will be thrown (returning a NULL will do that), but | |
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624 // clear gc_overhead_limit_exceeded so that the next collection |
0 | 625 // will succeeded if the applications decides to handle the |
626 // out-of-memory and tries to go on. | |
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627 const bool limit_exceeded = size_policy()->gc_overhead_limit_exceeded(); |
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628 if (limit_exceeded) { |
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629 size_policy()->set_gc_overhead_limit_exceeded(false); |
0 | 630 if (PrintGCDetails && Verbose) { |
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631 gclog_or_tty->print_cr("ParallelScavengeHeap::permanent_mem_allocate:" |
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632 " return NULL because gc_overhead_limit_exceeded is set"); |
0 | 633 } |
634 assert(result == NULL, "Allocation did not fail"); | |
635 return NULL; | |
636 } | |
637 | |
638 // Generate a VM operation | |
639 VM_ParallelGCFailedPermanentAllocation op(size, gc_count, full_gc_count); | |
640 VMThread::execute(&op); | |
641 | |
642 // Did the VM operation execute? If so, return the result directly. | |
643 // This prevents us from looping until time out on requests that can | |
644 // not be satisfied. | |
645 if (op.prologue_succeeded()) { | |
646 assert(Universe::heap()->is_in_permanent_or_null(op.result()), | |
647 "result not in heap"); | |
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648 // If GC was locked out during VM operation then retry allocation |
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649 // and/or stall as necessary. |
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650 if (op.gc_locked()) { |
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651 assert(op.result() == NULL, "must be NULL if gc_locked() is true"); |
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652 continue; // retry and/or stall as necessary |
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653 } |
0 | 654 // If a NULL results is being returned, an out-of-memory |
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655 // will be thrown now. Clear the gc_overhead_limit_exceeded |
0 | 656 // flag to avoid the following situation. |
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657 // gc_overhead_limit_exceeded is set during a collection |
0 | 658 // the collection fails to return enough space and an OOM is thrown |
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659 // a subsequent GC prematurely throws an out-of-memory because |
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660 // the gc_overhead_limit_exceeded counts did not start |
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661 // again from 0. |
0 | 662 if (op.result() == NULL) { |
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663 size_policy()->reset_gc_overhead_limit_count(); |
0 | 664 } |
665 return op.result(); | |
666 } | |
667 } | |
668 | |
669 // The policy object will prevent us from looping forever. If the | |
670 // time spent in gc crosses a threshold, we will bail out. | |
671 loop_count++; | |
672 if ((QueuedAllocationWarningCount > 0) && | |
673 (loop_count % QueuedAllocationWarningCount == 0)) { | |
674 warning("ParallelScavengeHeap::permanent_mem_allocate retries %d times \n\t" | |
675 " size=%d", loop_count, size); | |
676 } | |
677 } while (result == NULL); | |
678 | |
679 return result; | |
680 } | |
681 | |
682 // | |
683 // This is the policy code for permanent allocations which have failed | |
684 // and require a collection. Note that just as in failed_mem_allocate, | |
685 // we do not set collection policy, only where & when to allocate and | |
686 // collect. | |
687 HeapWord* ParallelScavengeHeap::failed_permanent_mem_allocate(size_t size) { | |
688 assert(SafepointSynchronize::is_at_safepoint(), "should be at safepoint"); | |
689 assert(Thread::current() == (Thread*)VMThread::vm_thread(), "should be in vm thread"); | |
690 assert(!Universe::heap()->is_gc_active(), "not reentrant"); | |
691 assert(!Heap_lock->owned_by_self(), "this thread should not own the Heap_lock"); | |
692 assert(size > perm_gen()->free_in_words(), "Allocation should fail"); | |
693 | |
694 // We assume (and assert!) that an allocation at this point will fail | |
695 // unless we collect. | |
696 | |
697 // First level allocation failure. Mark-sweep and allocate in perm gen. | |
698 GCCauseSetter gccs(this, GCCause::_allocation_failure); | |
699 invoke_full_gc(false); | |
700 HeapWord* result = perm_gen()->allocate_permanent(size); | |
701 | |
702 // Second level allocation failure. We're running out of memory. | |
703 if (result == NULL) { | |
704 invoke_full_gc(true); | |
705 result = perm_gen()->allocate_permanent(size); | |
706 } | |
707 | |
708 return result; | |
709 } | |
710 | |
711 void ParallelScavengeHeap::ensure_parsability(bool retire_tlabs) { | |
712 CollectedHeap::ensure_parsability(retire_tlabs); | |
713 young_gen()->eden_space()->ensure_parsability(); | |
714 } | |
715 | |
716 size_t ParallelScavengeHeap::unsafe_max_alloc() { | |
717 return young_gen()->eden_space()->free_in_bytes(); | |
718 } | |
719 | |
720 size_t ParallelScavengeHeap::tlab_capacity(Thread* thr) const { | |
721 return young_gen()->eden_space()->tlab_capacity(thr); | |
722 } | |
723 | |
724 size_t ParallelScavengeHeap::unsafe_max_tlab_alloc(Thread* thr) const { | |
725 return young_gen()->eden_space()->unsafe_max_tlab_alloc(thr); | |
726 } | |
727 | |
728 HeapWord* ParallelScavengeHeap::allocate_new_tlab(size_t size) { | |
729 return young_gen()->allocate(size, true); | |
730 } | |
731 | |
732 void ParallelScavengeHeap::accumulate_statistics_all_tlabs() { | |
733 CollectedHeap::accumulate_statistics_all_tlabs(); | |
734 } | |
735 | |
736 void ParallelScavengeHeap::resize_all_tlabs() { | |
737 CollectedHeap::resize_all_tlabs(); | |
738 } | |
739 | |
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740 bool ParallelScavengeHeap::can_elide_initializing_store_barrier(oop new_obj) { |
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741 // We don't need barriers for stores to objects in the |
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742 // young gen and, a fortiori, for initializing stores to |
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743 // objects therein. |
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744 return is_in_young(new_obj); |
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745 } |
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746 |
0 | 747 // This method is used by System.gc() and JVMTI. |
748 void ParallelScavengeHeap::collect(GCCause::Cause cause) { | |
749 assert(!Heap_lock->owned_by_self(), | |
750 "this thread should not own the Heap_lock"); | |
751 | |
752 unsigned int gc_count = 0; | |
753 unsigned int full_gc_count = 0; | |
754 { | |
755 MutexLocker ml(Heap_lock); | |
756 // This value is guarded by the Heap_lock | |
757 gc_count = Universe::heap()->total_collections(); | |
758 full_gc_count = Universe::heap()->total_full_collections(); | |
759 } | |
760 | |
761 VM_ParallelGCSystemGC op(gc_count, full_gc_count, cause); | |
762 VMThread::execute(&op); | |
763 } | |
764 | |
765 // This interface assumes that it's being called by the | |
766 // vm thread. It collects the heap assuming that the | |
767 // heap lock is already held and that we are executing in | |
768 // the context of the vm thread. | |
769 void ParallelScavengeHeap::collect_as_vm_thread(GCCause::Cause cause) { | |
770 assert(Thread::current()->is_VM_thread(), "Precondition#1"); | |
771 assert(Heap_lock->is_locked(), "Precondition#2"); | |
772 GCCauseSetter gcs(this, cause); | |
773 switch (cause) { | |
774 case GCCause::_heap_inspection: | |
775 case GCCause::_heap_dump: { | |
776 HandleMark hm; | |
777 invoke_full_gc(false); | |
778 break; | |
779 } | |
780 default: // XXX FIX ME | |
781 ShouldNotReachHere(); | |
782 } | |
783 } | |
784 | |
785 | |
786 void ParallelScavengeHeap::oop_iterate(OopClosure* cl) { | |
787 Unimplemented(); | |
788 } | |
789 | |
790 void ParallelScavengeHeap::object_iterate(ObjectClosure* cl) { | |
791 young_gen()->object_iterate(cl); | |
792 old_gen()->object_iterate(cl); | |
793 perm_gen()->object_iterate(cl); | |
794 } | |
795 | |
796 void ParallelScavengeHeap::permanent_oop_iterate(OopClosure* cl) { | |
797 Unimplemented(); | |
798 } | |
799 | |
800 void ParallelScavengeHeap::permanent_object_iterate(ObjectClosure* cl) { | |
801 perm_gen()->object_iterate(cl); | |
802 } | |
803 | |
804 HeapWord* ParallelScavengeHeap::block_start(const void* addr) const { | |
805 if (young_gen()->is_in_reserved(addr)) { | |
806 assert(young_gen()->is_in(addr), | |
807 "addr should be in allocated part of young gen"); | |
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808 if (Debugging) return NULL; // called from find() in debug.cpp |
0 | 809 Unimplemented(); |
810 } else if (old_gen()->is_in_reserved(addr)) { | |
811 assert(old_gen()->is_in(addr), | |
812 "addr should be in allocated part of old gen"); | |
813 return old_gen()->start_array()->object_start((HeapWord*)addr); | |
814 } else if (perm_gen()->is_in_reserved(addr)) { | |
815 assert(perm_gen()->is_in(addr), | |
816 "addr should be in allocated part of perm gen"); | |
817 return perm_gen()->start_array()->object_start((HeapWord*)addr); | |
818 } | |
819 return 0; | |
820 } | |
821 | |
822 size_t ParallelScavengeHeap::block_size(const HeapWord* addr) const { | |
823 return oop(addr)->size(); | |
824 } | |
825 | |
826 bool ParallelScavengeHeap::block_is_obj(const HeapWord* addr) const { | |
827 return block_start(addr) == addr; | |
828 } | |
829 | |
830 jlong ParallelScavengeHeap::millis_since_last_gc() { | |
831 return UseParallelOldGC ? | |
832 PSParallelCompact::millis_since_last_gc() : | |
833 PSMarkSweep::millis_since_last_gc(); | |
834 } | |
835 | |
836 void ParallelScavengeHeap::prepare_for_verify() { | |
837 ensure_parsability(false); // no need to retire TLABs for verification | |
838 } | |
839 | |
840 void ParallelScavengeHeap::print() const { print_on(tty); } | |
841 | |
842 void ParallelScavengeHeap::print_on(outputStream* st) const { | |
843 young_gen()->print_on(st); | |
844 old_gen()->print_on(st); | |
845 perm_gen()->print_on(st); | |
846 } | |
847 | |
848 void ParallelScavengeHeap::gc_threads_do(ThreadClosure* tc) const { | |
849 PSScavenge::gc_task_manager()->threads_do(tc); | |
850 } | |
851 | |
852 void ParallelScavengeHeap::print_gc_threads_on(outputStream* st) const { | |
853 PSScavenge::gc_task_manager()->print_threads_on(st); | |
854 } | |
855 | |
856 void ParallelScavengeHeap::print_tracing_info() const { | |
857 if (TraceGen0Time) { | |
858 double time = PSScavenge::accumulated_time()->seconds(); | |
859 tty->print_cr("[Accumulated GC generation 0 time %3.7f secs]", time); | |
860 } | |
861 if (TraceGen1Time) { | |
862 double time = PSMarkSweep::accumulated_time()->seconds(); | |
863 tty->print_cr("[Accumulated GC generation 1 time %3.7f secs]", time); | |
864 } | |
865 } | |
866 | |
867 | |
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868 void ParallelScavengeHeap::verify(bool allow_dirty, bool silent, bool option /* ignored */) { |
0 | 869 // Why do we need the total_collections()-filter below? |
870 if (total_collections() > 0) { | |
871 if (!silent) { | |
872 gclog_or_tty->print("permanent "); | |
873 } | |
874 perm_gen()->verify(allow_dirty); | |
875 | |
876 if (!silent) { | |
877 gclog_or_tty->print("tenured "); | |
878 } | |
879 old_gen()->verify(allow_dirty); | |
880 | |
881 if (!silent) { | |
882 gclog_or_tty->print("eden "); | |
883 } | |
884 young_gen()->verify(allow_dirty); | |
885 } | |
886 if (!silent) { | |
887 gclog_or_tty->print("ref_proc "); | |
888 } | |
889 ReferenceProcessor::verify(); | |
890 } | |
891 | |
892 void ParallelScavengeHeap::print_heap_change(size_t prev_used) { | |
893 if (PrintGCDetails && Verbose) { | |
894 gclog_or_tty->print(" " SIZE_FORMAT | |
895 "->" SIZE_FORMAT | |
896 "(" SIZE_FORMAT ")", | |
897 prev_used, used(), capacity()); | |
898 } else { | |
899 gclog_or_tty->print(" " SIZE_FORMAT "K" | |
900 "->" SIZE_FORMAT "K" | |
901 "(" SIZE_FORMAT "K)", | |
902 prev_used / K, used() / K, capacity() / K); | |
903 } | |
904 } | |
905 | |
906 ParallelScavengeHeap* ParallelScavengeHeap::heap() { | |
907 assert(_psh != NULL, "Uninitialized access to ParallelScavengeHeap::heap()"); | |
908 assert(_psh->kind() == CollectedHeap::ParallelScavengeHeap, "not a parallel scavenge heap"); | |
909 return _psh; | |
910 } | |
911 | |
912 // Before delegating the resize to the young generation, | |
913 // the reserved space for the young and old generations | |
914 // may be changed to accomodate the desired resize. | |
915 void ParallelScavengeHeap::resize_young_gen(size_t eden_size, | |
916 size_t survivor_size) { | |
917 if (UseAdaptiveGCBoundary) { | |
918 if (size_policy()->bytes_absorbed_from_eden() != 0) { | |
919 size_policy()->reset_bytes_absorbed_from_eden(); | |
920 return; // The generation changed size already. | |
921 } | |
922 gens()->adjust_boundary_for_young_gen_needs(eden_size, survivor_size); | |
923 } | |
924 | |
925 // Delegate the resize to the generation. | |
926 _young_gen->resize(eden_size, survivor_size); | |
927 } | |
928 | |
929 // Before delegating the resize to the old generation, | |
930 // the reserved space for the young and old generations | |
931 // may be changed to accomodate the desired resize. | |
932 void ParallelScavengeHeap::resize_old_gen(size_t desired_free_space) { | |
933 if (UseAdaptiveGCBoundary) { | |
934 if (size_policy()->bytes_absorbed_from_eden() != 0) { | |
935 size_policy()->reset_bytes_absorbed_from_eden(); | |
936 return; // The generation changed size already. | |
937 } | |
938 gens()->adjust_boundary_for_old_gen_needs(desired_free_space); | |
939 } | |
940 | |
941 // Delegate the resize to the generation. | |
942 _old_gen->resize(desired_free_space); | |
943 } | |
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944 |
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945 ParallelScavengeHeap::ParStrongRootsScope::ParStrongRootsScope() { |
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946 // nothing particular |
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947 } |
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948 |
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949 ParallelScavengeHeap::ParStrongRootsScope::~ParStrongRootsScope() { |
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950 // nothing particular |
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951 } |
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952 |
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953 #ifndef PRODUCT |
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954 void ParallelScavengeHeap::record_gen_tops_before_GC() { |
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955 if (ZapUnusedHeapArea) { |
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956 young_gen()->record_spaces_top(); |
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957 old_gen()->record_spaces_top(); |
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958 perm_gen()->record_spaces_top(); |
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959 } |
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960 } |
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961 |
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962 void ParallelScavengeHeap::gen_mangle_unused_area() { |
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963 if (ZapUnusedHeapArea) { |
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964 young_gen()->eden_space()->mangle_unused_area(); |
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965 young_gen()->to_space()->mangle_unused_area(); |
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966 young_gen()->from_space()->mangle_unused_area(); |
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967 old_gen()->object_space()->mangle_unused_area(); |
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968 perm_gen()->object_space()->mangle_unused_area(); |
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969 } |
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970 } |
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971 #endif |