Mon, 05 Nov 2012 15:30:22 -0500
8001591: NMT: assertion failed: assert(rec->addr() + rec->size() <= cur->base()) failed: Can not overlap in memSnapshot.cpp
Summary: NMT should allow overlapping committed regions as long as they belong to the same reserved region
Reviewed-by: dholmes, coleenp
1 /*
2 * Copyright (c) 2003, 2012, 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 */
25 #ifndef SHARE_VM_SERVICES_MEMORYMANAGER_HPP
26 #define SHARE_VM_SERVICES_MEMORYMANAGER_HPP
28 #include "memory/allocation.hpp"
29 #include "runtime/timer.hpp"
30 #include "services/memoryUsage.hpp"
32 // A memory manager is responsible for managing one or more memory pools.
33 // The garbage collector is one type of memory managers responsible
34 // for reclaiming memory occupied by unreachable objects. A Java virtual
35 // machine may have one or more memory managers. It may
36 // add or remove memory managers during execution.
37 // A memory pool can be managed by more than one memory managers.
39 class MemoryPool;
40 class GCMemoryManager;
41 class OopClosure;
43 class MemoryManager : public CHeapObj<mtInternal> {
44 private:
45 enum {
46 max_num_pools = 10
47 };
49 MemoryPool* _pools[max_num_pools];
50 int _num_pools;
52 protected:
53 volatile instanceOop _memory_mgr_obj;
55 public:
56 enum Name {
57 Abstract,
58 CodeCache,
59 Copy,
60 MarkSweepCompact,
61 ParNew,
62 ConcurrentMarkSweep,
63 PSScavenge,
64 PSMarkSweep,
65 G1YoungGen,
66 G1OldGen
67 };
69 MemoryManager();
71 int num_memory_pools() const { return _num_pools; }
72 MemoryPool* get_memory_pool(int index) {
73 assert(index >= 0 && index < _num_pools, "Invalid index");
74 return _pools[index];
75 }
77 void add_pool(MemoryPool* pool);
79 bool is_manager(instanceHandle mh) { return mh() == _memory_mgr_obj; }
81 virtual instanceOop get_memory_manager_instance(TRAPS);
82 virtual MemoryManager::Name kind() { return MemoryManager::Abstract; }
83 virtual bool is_gc_memory_manager() { return false; }
84 virtual const char* name() = 0;
86 // GC support
87 void oops_do(OopClosure* f);
89 // Static factory methods to get a memory manager of a specific type
90 static MemoryManager* get_code_cache_memory_manager();
91 static GCMemoryManager* get_copy_memory_manager();
92 static GCMemoryManager* get_msc_memory_manager();
93 static GCMemoryManager* get_parnew_memory_manager();
94 static GCMemoryManager* get_cms_memory_manager();
95 static GCMemoryManager* get_psScavenge_memory_manager();
96 static GCMemoryManager* get_psMarkSweep_memory_manager();
97 static GCMemoryManager* get_g1YoungGen_memory_manager();
98 static GCMemoryManager* get_g1OldGen_memory_manager();
100 };
102 class CodeCacheMemoryManager : public MemoryManager {
103 private:
104 public:
105 CodeCacheMemoryManager() : MemoryManager() {}
107 MemoryManager::Name kind() { return MemoryManager::CodeCache; }
108 const char* name() { return "CodeCacheManager"; }
109 };
111 class GCStatInfo : public ResourceObj {
112 private:
113 size_t _index;
114 jlong _start_time;
115 jlong _end_time;
117 // We keep memory usage of all memory pools
118 MemoryUsage* _before_gc_usage_array;
119 MemoryUsage* _after_gc_usage_array;
120 int _usage_array_size;
122 void set_gc_usage(int pool_index, MemoryUsage, bool before_gc);
124 public:
125 GCStatInfo(int num_pools);
126 ~GCStatInfo();
128 size_t gc_index() { return _index; }
129 jlong start_time() { return _start_time; }
130 jlong end_time() { return _end_time; }
131 int usage_array_size() { return _usage_array_size; }
132 MemoryUsage before_gc_usage_for_pool(int pool_index) {
133 assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
134 return _before_gc_usage_array[pool_index];
135 }
136 MemoryUsage after_gc_usage_for_pool(int pool_index) {
137 assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
138 return _after_gc_usage_array[pool_index];
139 }
141 MemoryUsage* before_gc_usage_array() { return _before_gc_usage_array; }
142 MemoryUsage* after_gc_usage_array() { return _after_gc_usage_array; }
144 void set_index(size_t index) { _index = index; }
145 void set_start_time(jlong time) { _start_time = time; }
146 void set_end_time(jlong time) { _end_time = time; }
147 void set_before_gc_usage(int pool_index, MemoryUsage usage) {
148 assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
149 set_gc_usage(pool_index, usage, true /* before gc */);
150 }
151 void set_after_gc_usage(int pool_index, MemoryUsage usage) {
152 assert(pool_index >= 0 && pool_index < _usage_array_size, "Range checking");
153 set_gc_usage(pool_index, usage, false /* after gc */);
154 }
156 void clear();
157 };
159 class GCMemoryManager : public MemoryManager {
160 private:
161 // TODO: We should unify the GCCounter and GCMemoryManager statistic
162 size_t _num_collections;
163 elapsedTimer _accumulated_timer;
164 elapsedTimer _gc_timer; // for measuring every GC duration
165 GCStatInfo* _last_gc_stat;
166 Mutex* _last_gc_lock;
167 GCStatInfo* _current_gc_stat;
168 int _num_gc_threads;
169 volatile bool _notification_enabled;
170 public:
171 GCMemoryManager();
172 ~GCMemoryManager();
174 void initialize_gc_stat_info();
176 bool is_gc_memory_manager() { return true; }
177 jlong gc_time_ms() { return _accumulated_timer.milliseconds(); }
178 size_t gc_count() { return _num_collections; }
179 int num_gc_threads() { return _num_gc_threads; }
180 void set_num_gc_threads(int count) { _num_gc_threads = count; }
182 void gc_begin(bool recordGCBeginTime, bool recordPreGCUsage,
183 bool recordAccumulatedGCTime);
184 void gc_end(bool recordPostGCUsage, bool recordAccumulatedGCTime,
185 bool recordGCEndTime, bool countCollection, GCCause::Cause cause);
187 void reset_gc_stat() { _num_collections = 0; _accumulated_timer.reset(); }
189 // Copy out _last_gc_stat to the given destination, returning
190 // the collection count. Zero signifies no gc has taken place.
191 size_t get_last_gc_stat(GCStatInfo* dest);
193 void set_notification_enabled(bool enabled) { _notification_enabled = enabled; }
194 bool is_notification_enabled() { return _notification_enabled; }
195 virtual MemoryManager::Name kind() = 0;
196 };
198 // These subclasses of GCMemoryManager are defined to include
199 // GC-specific information.
200 // TODO: Add GC-specific information
201 class CopyMemoryManager : public GCMemoryManager {
202 private:
203 public:
204 CopyMemoryManager() : GCMemoryManager() {}
206 MemoryManager::Name kind() { return MemoryManager::Copy; }
207 const char* name() { return "Copy"; }
208 };
210 class MSCMemoryManager : public GCMemoryManager {
211 private:
212 public:
213 MSCMemoryManager() : GCMemoryManager() {}
215 MemoryManager::Name kind() { return MemoryManager::MarkSweepCompact; }
216 const char* name() { return "MarkSweepCompact"; }
218 };
220 class ParNewMemoryManager : public GCMemoryManager {
221 private:
222 public:
223 ParNewMemoryManager() : GCMemoryManager() {}
225 MemoryManager::Name kind() { return MemoryManager::ParNew; }
226 const char* name() { return "ParNew"; }
228 };
230 class CMSMemoryManager : public GCMemoryManager {
231 private:
232 public:
233 CMSMemoryManager() : GCMemoryManager() {}
235 MemoryManager::Name kind() { return MemoryManager::ConcurrentMarkSweep; }
236 const char* name() { return "ConcurrentMarkSweep";}
238 };
240 class PSScavengeMemoryManager : public GCMemoryManager {
241 private:
242 public:
243 PSScavengeMemoryManager() : GCMemoryManager() {}
245 MemoryManager::Name kind() { return MemoryManager::PSScavenge; }
246 const char* name() { return "PS Scavenge"; }
248 };
250 class PSMarkSweepMemoryManager : public GCMemoryManager {
251 private:
252 public:
253 PSMarkSweepMemoryManager() : GCMemoryManager() {}
255 MemoryManager::Name kind() { return MemoryManager::PSMarkSweep; }
256 const char* name() { return "PS MarkSweep"; }
257 };
259 class G1YoungGenMemoryManager : public GCMemoryManager {
260 private:
261 public:
262 G1YoungGenMemoryManager() : GCMemoryManager() {}
264 MemoryManager::Name kind() { return MemoryManager::G1YoungGen; }
265 const char* name() { return "G1 Young Generation"; }
266 };
268 class G1OldGenMemoryManager : public GCMemoryManager {
269 private:
270 public:
271 G1OldGenMemoryManager() : GCMemoryManager() {}
273 MemoryManager::Name kind() { return MemoryManager::G1OldGen; }
274 const char* name() { return "G1 Old Generation"; }
275 };
277 #endif // SHARE_VM_SERVICES_MEMORYMANAGER_HPP