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comparison src/share/vm/runtime/mutex.hpp @ 0:a61af66fc99e jdk7-b24

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author duke
date Sat, 01 Dec 2007 00:00:00 +0000
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1 /*
2 * Copyright 1998-2006 Sun Microsystems, Inc. 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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
20 * CA 95054 USA or visit www.sun.com if you need additional information or
21 * have any questions.
22 *
23 */
24
25 // The SplitWord construct allows us to colocate the contention queue
26 // (cxq) with the lock-byte. The queue elements are ParkEvents, which are
27 // always aligned on 256-byte addresses - the least significant byte of
28 // a ParkEvent is always 0. Colocating the lock-byte with the queue
29 // allows us to easily avoid what would otherwise be a race in lock()
30 // if we were to use two completely separate fields for the contention queue
31 // and the lock indicator. Specifically, colocation renders us immune
32 // from the race where a thread might enqueue itself in the lock() slow-path
33 // immediately after the lock holder drops the outer lock in the unlock()
34 // fast-path.
35 //
36 // Colocation allows us to use a fast-path unlock() form that uses
37 // A MEMBAR instead of a CAS. MEMBAR has lower local latency than CAS
38 // on many platforms.
39 //
40 // See:
41 // + http://blogs.sun.com/dave/entry/biased_locking_in_hotspot
42 // + http://blogs.sun.com/dave/resource/synchronization-public2.pdf
43 //
44 // Note that we're *not* using word-tearing the classic sense.
45 // The lock() fast-path will CAS the lockword and the unlock()
46 // fast-path will store into the lock-byte colocated within the lockword.
47 // We depend on the fact that all our reference platforms have
48 // coherent and atomic byte accesses. More precisely, byte stores
49 // interoperate in a safe, sane, and expected manner with respect to
50 // CAS, ST and LDs to the full-word containing the byte.
51 // If you're porting HotSpot to a platform where that isn't the case
52 // then you'll want change the unlock() fast path from:
53 // STB;MEMBAR #storeload; LDN
54 // to a full-word CAS of the lockword.
55
56
57 union SplitWord { // full-word with separately addressable LSB
58 volatile intptr_t FullWord ;
59 volatile void * Address ;
60 volatile jbyte Bytes [sizeof(intptr_t)] ;
61 } ;
62
63 // Endian-ness ... index of least-significant byte in SplitWord.Bytes[]
64 #ifdef AMD64 // little
65 #define _LSBINDEX 0
66 #else
67 #if IA32 // little
68 #define _LSBINDEX 0
69 #else
70 #ifdef SPARC // big
71 #define _LSBINDEX (sizeof(intptr_t)-1)
72 #else
73 #error "unknown architecture"
74 #endif
75 #endif
76 #endif
77
78 class ParkEvent ;
79
80 // See orderAccess.hpp. We assume throughout the VM that mutex lock and
81 // try_lock do fence-lock-acquire, and that unlock does a release-unlock,
82 // *in that order*. If their implementations change such that these
83 // assumptions are violated, a whole lot of code will break.
84
85 class Monitor : public CHeapObj {
86
87 public:
88 // A special lock: Is a lock where you are guaranteed not to block while you are
89 // holding it, i.e., no vm operation can happen, taking other locks, etc.
90 // NOTE: It is critical that the rank 'special' be the lowest (earliest)
91 // (except for "event"?) for the deadlock dection to work correctly.
92 // The rank native is only for use in Mutex's created by JVM_RawMonitorCreate,
93 // which being external to the VM are not subject to deadlock detection.
94 // The rank safepoint is used only for synchronization in reaching a
95 // safepoint and leaving a safepoint. It is only used for the Safepoint_lock
96 // currently. While at a safepoint no mutexes of rank safepoint are held
97 // by any thread.
98 // The rank named "leaf" is probably historical (and should
99 // be changed) -- mutexes of this rank aren't really leaf mutexes
100 // at all.
101 enum lock_types {
102 event,
103 special,
104 suspend_resume,
105 leaf = suspend_resume + 2,
106 safepoint = leaf + 10,
107 barrier = safepoint + 1,
108 nonleaf = barrier + 1,
109 max_nonleaf = nonleaf + 900,
110 native = max_nonleaf + 1
111 };
112
113 // The WaitSet and EntryList linked lists are composed of ParkEvents.
114 // I use ParkEvent instead of threads as ParkEvents are immortal and
115 // type-stable, meaning we can safely unpark() a possibly stale
116 // list element in the unlock()-path.
117
118 protected: // Monitor-Mutex metadata
119 SplitWord _LockWord ; // Contention queue (cxq) colocated with Lock-byte
120 enum LockWordBits { _LBIT=1 } ;
121 Thread * volatile _owner; // The owner of the lock
122 // Consider sequestering _owner on its own $line
123 // to aid future synchronization mechanisms.
124 ParkEvent * volatile _EntryList ; // List of threads waiting for entry
125 ParkEvent * volatile _OnDeck ; // heir-presumptive
126 volatile intptr_t _WaitLock [1] ; // Protects _WaitSet
127 ParkEvent * volatile _WaitSet ; // LL of ParkEvents
128 volatile bool _snuck; // Used for sneaky locking (evil).
129 const char * _name; // Name of mutex
130 int NotifyCount ; // diagnostic assist
131 double pad [8] ; // avoid false sharing
132
133 // Debugging fields for naming, deadlock detection, etc. (some only used in debug mode)
134 #ifndef PRODUCT
135 bool _allow_vm_block;
136 debug_only(int _rank;) // rank (to avoid/detect potential deadlocks)
137 debug_only(Monitor * _next;) // Used by a Thread to link up owned locks
138 debug_only(Thread* _last_owner;) // the last thread to own the lock
139 debug_only(static bool contains(Monitor * locks, Monitor * lock);)
140 debug_only(static Monitor * get_least_ranked_lock(Monitor * locks);)
141 debug_only(Monitor * get_least_ranked_lock_besides_this(Monitor * locks);)
142 #endif
143
144 void set_owner_implementation(Thread* owner) PRODUCT_RETURN;
145 void check_prelock_state (Thread* thread) PRODUCT_RETURN;
146 void check_block_state (Thread* thread) PRODUCT_RETURN;
147
148 // platform-dependent support code can go here (in os_<os_family>.cpp)
149 public:
150 enum {
151 _no_safepoint_check_flag = true,
152 _allow_vm_block_flag = true,
153 _as_suspend_equivalent_flag = true
154 };
155
156 enum WaitResults {
157 CONDVAR_EVENT, // Wait returned because of condition variable notification
158 INTERRUPT_EVENT, // Wait returned because waiting thread was interrupted
159 NUMBER_WAIT_RESULTS
160 };
161
162 private:
163 int TrySpin (Thread * Self) ;
164 int TryLock () ;
165 int TryFast () ;
166 int AcquireOrPush (ParkEvent * ev) ;
167 void IUnlock (bool RelaxAssert) ;
168 void ILock (Thread * Self) ;
169 int IWait (Thread * Self, jlong timo);
170 int ILocked () ;
171
172 protected:
173 static void ClearMonitor (Monitor * m) ;
174 Monitor() ;
175
176 public:
177 Monitor(int rank, const char *name, bool allow_vm_block=false);
178 ~Monitor();
179
180 // Wait until monitor is notified (or times out).
181 // Defaults are to make safepoint checks, wait time is forever (i.e.,
182 // zero), and not a suspend-equivalent condition. Returns true if wait
183 // times out; otherwise returns false.
184 bool wait(bool no_safepoint_check = !_no_safepoint_check_flag,
185 long timeout = 0,
186 bool as_suspend_equivalent = !_as_suspend_equivalent_flag);
187 bool notify();
188 bool notify_all();
189
190
191 void lock(); // prints out warning if VM thread blocks
192 void lock(Thread *thread); // overloaded with current thread
193 void unlock();
194 bool is_locked() const { return _owner != NULL; }
195
196 bool try_lock(); // Like lock(), but unblocking. It returns false instead
197
198 // Lock without safepoint check. Should ONLY be used by safepoint code and other code
199 // that is guaranteed not to block while running inside the VM.
200 void lock_without_safepoint_check();
201 void lock_without_safepoint_check (Thread * Self) ;
202
203 // Current owner - not not MT-safe. Can only be used to guarantee that
204 // the current running thread owns the lock
205 Thread* owner() const { return _owner; }
206 bool owned_by_self() const;
207
208 // Support for JVM_RawMonitorEnter & JVM_RawMonitorExit. These can be called by
209 // non-Java thread. (We should really have a RawMonitor abstraction)
210 void jvm_raw_lock();
211 void jvm_raw_unlock();
212 const char *name() const { return _name; }
213
214 void print_on_error(outputStream* st) const;
215
216 #ifndef PRODUCT
217 void print_on(outputStream* st) const;
218 void print() const { print_on(tty); }
219 debug_only(int rank() const { return _rank; })
220 bool allow_vm_block() { return _allow_vm_block; }
221
222 debug_only(Monitor *next() const { return _next; })
223 debug_only(void set_next(Monitor *next) { _next = next; })
224 #endif
225
226 void set_owner(Thread* owner) {
227 #ifndef PRODUCT
228 set_owner_implementation(owner);
229 debug_only(void verify_Monitor(Thread* thr));
230 #else
231 _owner = owner;
232 #endif
233 }
234
235 };
236
237 // Normally we'd expect Monitor to extend Mutex in the sense that a monitor
238 // constructed from pthreads primitives might extend a mutex by adding
239 // a condvar and some extra metadata. In fact this was the case until J2SE7.
240 //
241 // Currently, however, the base object is a monitor. Monitor contains all the
242 // logic for wait(), notify(), etc. Mutex extends monitor and restricts the
243 // visiblity of wait(), notify(), and notify_all().
244 //
245 // Another viable alternative would have been to have Monitor extend Mutex and
246 // implement all the normal mutex and wait()-notify() logic in Mutex base class.
247 // The wait()-notify() facility would be exposed via special protected member functions
248 // (e.g., _Wait() and _Notify()) in Mutex. Monitor would extend Mutex and expose wait()
249 // as a call to _Wait(). That is, the public wait() would be a wrapper for the protected
250 // _Wait().
251 //
252 // An even better alternative is to simply eliminate Mutex:: and use Monitor:: instead.
253 // After all, monitors are sufficient for Java-level synchronization. At one point in time
254 // there may have been some benefit to having distinct mutexes and monitors, but that time
255 // has past.
256 //
257 // The Mutex/Monitor design parallels that of Java-monitors, being based on
258 // thread-specific park-unpark platform-specific primitives.
259
260
261 class Mutex : public Monitor { // degenerate Monitor
262 public:
263 Mutex (int rank, const char *name, bool allow_vm_block=false);
264 ~Mutex () ;
265 private:
266 bool notify () { ShouldNotReachHere(); return false; }
267 bool notify_all() { ShouldNotReachHere(); return false; }
268 bool wait (bool no_safepoint_check, long timeout, bool as_suspend_equivalent) {
269 ShouldNotReachHere() ;
270 return false ;
271 }
272 };
273
274 /*
275 * Per-thread blocking support for JSR166. See the Java-level
276 * Documentation for rationale. Basically, park acts like wait, unpark
277 * like notify.
278 *
279 * 6271289 --
280 * To avoid errors where an os thread expires but the JavaThread still
281 * exists, Parkers are immortal (type-stable) and are recycled across
282 * new threads. This parallels the ParkEvent implementation.
283 * Because park-unpark allow spurious wakeups it is harmless if an
284 * unpark call unparks a new thread using the old Parker reference.
285 *
286 * In the future we'll want to think about eliminating Parker and using
287 * ParkEvent instead. There's considerable duplication between the two
288 * services.
289 *
290 */
291
292 class Parker : public os::PlatformParker {
293 private:
294 volatile int _counter ;
295 Parker * FreeNext ;
296 JavaThread * AssociatedWith ; // Current association
297
298 public:
299 Parker() : PlatformParker() {
300 _counter = 0 ;
301 FreeNext = NULL ;
302 AssociatedWith = NULL ;
303 }
304 protected:
305 ~Parker() { ShouldNotReachHere(); }
306 public:
307 // For simplicity of interface with Java, all forms of park (indefinite,
308 // relative, and absolute) are multiplexed into one call.
309 void park(bool isAbsolute, jlong time);
310 void unpark();
311
312 // Lifecycle operators
313 static Parker * Allocate (JavaThread * t) ;
314 static void Release (Parker * e) ;
315 private:
316 static Parker * volatile FreeList ;
317 static volatile int ListLock ;
318 };