kern_condvar.c revision 1.14.14.5
1 1.14.14.1 mjf /* $NetBSD: kern_condvar.c,v 1.14.14.5 2009/01/17 13:29:18 mjf Exp $ */ 2 1.2 ad 3 1.2 ad /*- 4 1.14.14.1 mjf * Copyright (c) 2006, 2007, 2008 The NetBSD Foundation, Inc. 5 1.2 ad * All rights reserved. 6 1.2 ad * 7 1.2 ad * This code is derived from software contributed to The NetBSD Foundation 8 1.2 ad * by Andrew Doran. 9 1.2 ad * 10 1.2 ad * Redistribution and use in source and binary forms, with or without 11 1.2 ad * modification, are permitted provided that the following conditions 12 1.2 ad * are met: 13 1.2 ad * 1. Redistributions of source code must retain the above copyright 14 1.2 ad * notice, this list of conditions and the following disclaimer. 15 1.2 ad * 2. Redistributions in binary form must reproduce the above copyright 16 1.2 ad * notice, this list of conditions and the following disclaimer in the 17 1.2 ad * documentation and/or other materials provided with the distribution. 18 1.2 ad * 19 1.2 ad * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.2 ad * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.2 ad * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.2 ad * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.2 ad * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.2 ad * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.2 ad * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.2 ad * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.2 ad * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.2 ad * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.2 ad * POSSIBILITY OF SUCH DAMAGE. 30 1.2 ad */ 31 1.2 ad 32 1.2 ad /* 33 1.14.14.4 mjf * Kernel condition variable implementation. 34 1.2 ad */ 35 1.2 ad 36 1.2 ad #include <sys/cdefs.h> 37 1.14.14.1 mjf __KERNEL_RCSID(0, "$NetBSD: kern_condvar.c,v 1.14.14.5 2009/01/17 13:29:18 mjf Exp $"); 38 1.2 ad 39 1.2 ad #include <sys/param.h> 40 1.2 ad #include <sys/proc.h> 41 1.2 ad #include <sys/sched.h> 42 1.2 ad #include <sys/systm.h> 43 1.2 ad #include <sys/condvar.h> 44 1.2 ad #include <sys/sleepq.h> 45 1.14.14.2 mjf #include <sys/lockdebug.h> 46 1.14.14.4 mjf #include <sys/cpu.h> 47 1.14.14.2 mjf 48 1.14.14.2 mjf #include <uvm/uvm_extern.h> 49 1.14.14.2 mjf 50 1.14.14.5 mjf /* 51 1.14.14.5 mjf * Accessors for the private contents of the kcondvar_t data type. 52 1.14.14.5 mjf * 53 1.14.14.5 mjf * cv_opaque[0] sleepq... 54 1.14.14.5 mjf * cv_opaque[1] ...pointers 55 1.14.14.5 mjf * cv_opaque[2] description for ps(1) 56 1.14.14.5 mjf * 57 1.14.14.5 mjf * cv_opaque[0..1] is protected by the interlock passed to cv_wait() (enqueue 58 1.14.14.5 mjf * only), and the sleep queue lock acquired with sleeptab_lookup() (enqueue 59 1.14.14.5 mjf * and dequeue). 60 1.14.14.5 mjf * 61 1.14.14.5 mjf * cv_opaque[2] (the wmesg) is static and does not change throughout the life 62 1.14.14.5 mjf * of the CV. 63 1.14.14.5 mjf */ 64 1.14.14.5 mjf #define CV_SLEEPQ(cv) ((sleepq_t *)(cv)->cv_opaque) 65 1.14.14.5 mjf #define CV_WMESG(cv) ((const char *)(cv)->cv_opaque[2]) 66 1.14.14.5 mjf #define CV_SET_WMESG(cv, v) (cv)->cv_opaque[2] = __UNCONST(v) 67 1.14.14.5 mjf 68 1.14.14.5 mjf #define CV_DEBUG_P(cv) (CV_WMESG(cv) != nodebug) 69 1.14.14.2 mjf #define CV_RA ((uintptr_t)__builtin_return_address(0)) 70 1.2 ad 71 1.14.14.1 mjf static u_int cv_unsleep(lwp_t *, bool); 72 1.14.14.2 mjf static void cv_wakeup_one(kcondvar_t *); 73 1.14.14.2 mjf static void cv_wakeup_all(kcondvar_t *); 74 1.2 ad 75 1.10 ad static syncobj_t cv_syncobj = { 76 1.2 ad SOBJ_SLEEPQ_SORTED, 77 1.2 ad cv_unsleep, 78 1.14 ad sleepq_changepri, 79 1.4 yamt sleepq_lendpri, 80 1.4 yamt syncobj_noowner, 81 1.2 ad }; 82 1.2 ad 83 1.14.14.2 mjf lockops_t cv_lockops = { 84 1.14.14.2 mjf "Condition variable", 85 1.14.14.2 mjf LOCKOPS_CV, 86 1.14.14.2 mjf NULL 87 1.14.14.2 mjf }; 88 1.14.14.2 mjf 89 1.10 ad static const char deadcv[] = "deadcv"; 90 1.14.14.2 mjf static const char nodebug[] = "nodebug"; 91 1.10 ad 92 1.2 ad /* 93 1.2 ad * cv_init: 94 1.2 ad * 95 1.2 ad * Initialize a condition variable for use. 96 1.2 ad */ 97 1.2 ad void 98 1.2 ad cv_init(kcondvar_t *cv, const char *wmesg) 99 1.2 ad { 100 1.14.14.2 mjf #ifdef LOCKDEBUG 101 1.14.14.2 mjf bool dodebug; 102 1.2 ad 103 1.14.14.2 mjf dodebug = LOCKDEBUG_ALLOC(cv, &cv_lockops, 104 1.14.14.2 mjf (uintptr_t)__builtin_return_address(0)); 105 1.14.14.2 mjf if (!dodebug) { 106 1.14.14.2 mjf /* XXX This will break vfs_lockf. */ 107 1.14.14.2 mjf wmesg = nodebug; 108 1.14.14.2 mjf } 109 1.14.14.2 mjf #endif 110 1.2 ad KASSERT(wmesg != NULL); 111 1.14.14.5 mjf CV_SET_WMESG(cv, wmesg); 112 1.14.14.2 mjf sleepq_init(CV_SLEEPQ(cv)); 113 1.2 ad } 114 1.2 ad 115 1.2 ad /* 116 1.2 ad * cv_destroy: 117 1.2 ad * 118 1.2 ad * Tear down a condition variable. 119 1.2 ad */ 120 1.2 ad void 121 1.2 ad cv_destroy(kcondvar_t *cv) 122 1.2 ad { 123 1.2 ad 124 1.14.14.2 mjf LOCKDEBUG_FREE(CV_DEBUG_P(cv), cv); 125 1.2 ad #ifdef DIAGNOSTIC 126 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 127 1.14.14.5 mjf CV_SET_WMESG(cv, deadcv); 128 1.2 ad #endif 129 1.2 ad } 130 1.2 ad 131 1.2 ad /* 132 1.2 ad * cv_enter: 133 1.2 ad * 134 1.2 ad * Look up and lock the sleep queue corresponding to the given 135 1.2 ad * condition variable, and increment the number of waiters. 136 1.2 ad */ 137 1.14.14.2 mjf static inline void 138 1.6 ad cv_enter(kcondvar_t *cv, kmutex_t *mtx, lwp_t *l) 139 1.2 ad { 140 1.2 ad sleepq_t *sq; 141 1.14.14.2 mjf kmutex_t *mp; 142 1.2 ad 143 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 144 1.14.14.4 mjf KASSERT(!cpu_intr_p()); 145 1.14 ad KASSERT((l->l_pflag & LP_INTR) == 0 || panicstr != NULL); 146 1.2 ad 147 1.14.14.2 mjf LOCKDEBUG_LOCKED(CV_DEBUG_P(cv), cv, mtx, CV_RA, 0); 148 1.14.14.2 mjf 149 1.14 ad l->l_kpriority = true; 150 1.14.14.4 mjf mp = sleepq_hashlock(cv); 151 1.14.14.2 mjf sq = CV_SLEEPQ(cv); 152 1.14.14.2 mjf sleepq_enter(sq, l, mp); 153 1.14.14.5 mjf sleepq_enqueue(sq, cv, CV_WMESG(cv), &cv_syncobj); 154 1.2 ad mutex_exit(mtx); 155 1.14.14.4 mjf KASSERT(cv_has_waiters(cv)); 156 1.2 ad } 157 1.2 ad 158 1.2 ad /* 159 1.6 ad * cv_exit: 160 1.6 ad * 161 1.6 ad * After resuming execution, check to see if we have been restarted 162 1.6 ad * as a result of cv_signal(). If we have, but cannot take the 163 1.6 ad * wakeup (because of eg a pending Unix signal or timeout) then try 164 1.6 ad * to ensure that another LWP sees it. This is necessary because 165 1.6 ad * there may be multiple waiters, and at least one should take the 166 1.6 ad * wakeup if possible. 167 1.6 ad */ 168 1.6 ad static inline int 169 1.6 ad cv_exit(kcondvar_t *cv, kmutex_t *mtx, lwp_t *l, const int error) 170 1.6 ad { 171 1.6 ad 172 1.6 ad mutex_enter(mtx); 173 1.14.14.2 mjf if (__predict_false(error != 0)) 174 1.6 ad cv_signal(cv); 175 1.6 ad 176 1.14.14.2 mjf LOCKDEBUG_UNLOCKED(CV_DEBUG_P(cv), cv, CV_RA, 0); 177 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 178 1.10 ad 179 1.6 ad return error; 180 1.6 ad } 181 1.6 ad 182 1.6 ad /* 183 1.2 ad * cv_unsleep: 184 1.2 ad * 185 1.2 ad * Remove an LWP from the condition variable and sleep queue. This 186 1.2 ad * is called when the LWP has not been awoken normally but instead 187 1.2 ad * interrupted: for example, when a signal is received. Must be 188 1.2 ad * called with the LWP locked, and must return it unlocked. 189 1.2 ad */ 190 1.14.14.1 mjf static u_int 191 1.14.14.1 mjf cv_unsleep(lwp_t *l, bool cleanup) 192 1.2 ad { 193 1.10 ad kcondvar_t *cv; 194 1.2 ad 195 1.14.14.1 mjf cv = (kcondvar_t *)(uintptr_t)l->l_wchan; 196 1.14.14.1 mjf 197 1.14.14.2 mjf KASSERT(l->l_wchan == (wchan_t)cv); 198 1.14.14.2 mjf KASSERT(l->l_sleepq == CV_SLEEPQ(cv)); 199 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 200 1.14.14.4 mjf KASSERT(cv_has_waiters(cv)); 201 1.2 ad 202 1.14.14.1 mjf return sleepq_unsleep(l, cleanup); 203 1.2 ad } 204 1.2 ad 205 1.2 ad /* 206 1.2 ad * cv_wait: 207 1.2 ad * 208 1.2 ad * Wait non-interruptably on a condition variable until awoken. 209 1.2 ad */ 210 1.2 ad void 211 1.2 ad cv_wait(kcondvar_t *cv, kmutex_t *mtx) 212 1.2 ad { 213 1.6 ad lwp_t *l = curlwp; 214 1.2 ad 215 1.8 yamt KASSERT(mutex_owned(mtx)); 216 1.2 ad 217 1.14.14.2 mjf cv_enter(cv, mtx, l); 218 1.8 yamt (void)sleepq_block(0, false); 219 1.6 ad (void)cv_exit(cv, mtx, l, 0); 220 1.2 ad } 221 1.2 ad 222 1.2 ad /* 223 1.2 ad * cv_wait_sig: 224 1.2 ad * 225 1.2 ad * Wait on a condition variable until a awoken or a signal is received. 226 1.2 ad * Will also return early if the process is exiting. Returns zero if 227 1.2 ad * awoken normallly, ERESTART if a signal was received and the system 228 1.2 ad * call is restartable, or EINTR otherwise. 229 1.2 ad */ 230 1.2 ad int 231 1.2 ad cv_wait_sig(kcondvar_t *cv, kmutex_t *mtx) 232 1.2 ad { 233 1.6 ad lwp_t *l = curlwp; 234 1.2 ad int error; 235 1.2 ad 236 1.8 yamt KASSERT(mutex_owned(mtx)); 237 1.2 ad 238 1.14.14.2 mjf cv_enter(cv, mtx, l); 239 1.8 yamt error = sleepq_block(0, true); 240 1.6 ad return cv_exit(cv, mtx, l, error); 241 1.2 ad } 242 1.2 ad 243 1.2 ad /* 244 1.2 ad * cv_timedwait: 245 1.2 ad * 246 1.2 ad * Wait on a condition variable until awoken or the specified timeout 247 1.2 ad * expires. Returns zero if awoken normally or EWOULDBLOCK if the 248 1.2 ad * timeout expired. 249 1.2 ad */ 250 1.2 ad int 251 1.2 ad cv_timedwait(kcondvar_t *cv, kmutex_t *mtx, int timo) 252 1.2 ad { 253 1.6 ad lwp_t *l = curlwp; 254 1.2 ad int error; 255 1.2 ad 256 1.8 yamt KASSERT(mutex_owned(mtx)); 257 1.2 ad 258 1.14.14.2 mjf cv_enter(cv, mtx, l); 259 1.8 yamt error = sleepq_block(timo, false); 260 1.6 ad return cv_exit(cv, mtx, l, error); 261 1.2 ad } 262 1.2 ad 263 1.2 ad /* 264 1.2 ad * cv_timedwait_sig: 265 1.2 ad * 266 1.2 ad * Wait on a condition variable until a timeout expires, awoken or a 267 1.2 ad * signal is received. Will also return early if the process is 268 1.2 ad * exiting. Returns zero if awoken normallly, EWOULDBLOCK if the 269 1.2 ad * timeout expires, ERESTART if a signal was received and the system 270 1.2 ad * call is restartable, or EINTR otherwise. 271 1.2 ad */ 272 1.2 ad int 273 1.2 ad cv_timedwait_sig(kcondvar_t *cv, kmutex_t *mtx, int timo) 274 1.2 ad { 275 1.6 ad lwp_t *l = curlwp; 276 1.2 ad int error; 277 1.2 ad 278 1.8 yamt KASSERT(mutex_owned(mtx)); 279 1.2 ad 280 1.14.14.2 mjf cv_enter(cv, mtx, l); 281 1.8 yamt error = sleepq_block(timo, true); 282 1.6 ad return cv_exit(cv, mtx, l, error); 283 1.2 ad } 284 1.2 ad 285 1.2 ad /* 286 1.2 ad * cv_signal: 287 1.2 ad * 288 1.2 ad * Wake the highest priority LWP waiting on a condition variable. 289 1.2 ad * Must be called with the interlocking mutex held. 290 1.2 ad */ 291 1.2 ad void 292 1.2 ad cv_signal(kcondvar_t *cv) 293 1.2 ad { 294 1.14.14.2 mjf 295 1.14.14.3 mjf /* LOCKDEBUG_WAKEUP(CV_DEBUG_P(cv), cv, CV_RA); */ 296 1.14.14.2 mjf KASSERT(cv_is_valid(cv)); 297 1.14.14.2 mjf 298 1.14.14.4 mjf if (__predict_false(!TAILQ_EMPTY(CV_SLEEPQ(cv)))) 299 1.14.14.2 mjf cv_wakeup_one(cv); 300 1.14.14.2 mjf } 301 1.14.14.2 mjf 302 1.14.14.2 mjf static void __noinline 303 1.14.14.2 mjf cv_wakeup_one(kcondvar_t *cv) 304 1.14.14.2 mjf { 305 1.2 ad sleepq_t *sq; 306 1.14.14.2 mjf kmutex_t *mp; 307 1.14.14.2 mjf int swapin; 308 1.14.14.2 mjf lwp_t *l; 309 1.2 ad 310 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 311 1.14.14.1 mjf 312 1.14.14.4 mjf mp = sleepq_hashlock(cv); 313 1.14.14.2 mjf sq = CV_SLEEPQ(cv); 314 1.14.14.2 mjf l = TAILQ_FIRST(sq); 315 1.14.14.2 mjf if (l == NULL) { 316 1.14.14.2 mjf mutex_spin_exit(mp); 317 1.2 ad return; 318 1.14.14.2 mjf } 319 1.14.14.2 mjf KASSERT(l->l_sleepq == sq); 320 1.14.14.2 mjf KASSERT(l->l_mutex == mp); 321 1.14.14.2 mjf KASSERT(l->l_wchan == cv); 322 1.14.14.2 mjf swapin = sleepq_remove(sq, l); 323 1.14.14.2 mjf mutex_spin_exit(mp); 324 1.2 ad 325 1.2 ad /* 326 1.14.14.2 mjf * If there are newly awakend threads that need to be swapped in, 327 1.14.14.2 mjf * then kick the swapper into action. 328 1.2 ad */ 329 1.14.14.2 mjf if (swapin) 330 1.14.14.2 mjf uvm_kick_scheduler(); 331 1.14.14.1 mjf 332 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 333 1.2 ad } 334 1.2 ad 335 1.2 ad /* 336 1.2 ad * cv_broadcast: 337 1.2 ad * 338 1.2 ad * Wake all LWPs waiting on a condition variable. Must be called 339 1.2 ad * with the interlocking mutex held. 340 1.2 ad */ 341 1.2 ad void 342 1.2 ad cv_broadcast(kcondvar_t *cv) 343 1.2 ad { 344 1.14.14.2 mjf 345 1.14.14.3 mjf /* LOCKDEBUG_WAKEUP(CV_DEBUG_P(cv), cv, CV_RA); */ 346 1.14.14.2 mjf KASSERT(cv_is_valid(cv)); 347 1.14.14.2 mjf 348 1.14.14.4 mjf if (__predict_false(!TAILQ_EMPTY(CV_SLEEPQ(cv)))) 349 1.14.14.2 mjf cv_wakeup_all(cv); 350 1.14.14.2 mjf } 351 1.14.14.2 mjf 352 1.14.14.2 mjf static void __noinline 353 1.14.14.2 mjf cv_wakeup_all(kcondvar_t *cv) 354 1.14.14.2 mjf { 355 1.2 ad sleepq_t *sq; 356 1.14.14.2 mjf kmutex_t *mp; 357 1.14.14.2 mjf int swapin; 358 1.14.14.2 mjf lwp_t *l, *next; 359 1.2 ad 360 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 361 1.14.14.1 mjf 362 1.14.14.4 mjf mp = sleepq_hashlock(cv); 363 1.14.14.2 mjf swapin = 0; 364 1.14.14.4 mjf sq = CV_SLEEPQ(cv); 365 1.14.14.2 mjf for (l = TAILQ_FIRST(sq); l != NULL; l = next) { 366 1.14.14.2 mjf KASSERT(l->l_sleepq == sq); 367 1.14.14.2 mjf KASSERT(l->l_mutex == mp); 368 1.14.14.2 mjf KASSERT(l->l_wchan == cv); 369 1.14.14.2 mjf next = TAILQ_NEXT(l, l_sleepchain); 370 1.14.14.2 mjf swapin |= sleepq_remove(sq, l); 371 1.14.14.2 mjf } 372 1.14.14.2 mjf mutex_spin_exit(mp); 373 1.2 ad 374 1.14.14.2 mjf /* 375 1.14.14.2 mjf * If there are newly awakend threads that need to be swapped in, 376 1.14.14.2 mjf * then kick the swapper into action. 377 1.14.14.2 mjf */ 378 1.14.14.2 mjf if (swapin) 379 1.14.14.2 mjf uvm_kick_scheduler(); 380 1.14.14.1 mjf 381 1.14.14.1 mjf KASSERT(cv_is_valid(cv)); 382 1.2 ad } 383 1.2 ad 384 1.2 ad /* 385 1.11 ad * cv_wakeup: 386 1.11 ad * 387 1.11 ad * Wake all LWPs waiting on a condition variable. For cases 388 1.11 ad * where the address may be waited on by mtsleep()/tsleep(). 389 1.11 ad * Not a documented call. 390 1.11 ad */ 391 1.11 ad void 392 1.11 ad cv_wakeup(kcondvar_t *cv) 393 1.11 ad { 394 1.11 ad 395 1.14.14.2 mjf cv_wakeup_all(cv); 396 1.14.14.2 mjf wakeup(cv); 397 1.11 ad } 398 1.11 ad 399 1.11 ad /* 400 1.2 ad * cv_has_waiters: 401 1.2 ad * 402 1.2 ad * For diagnostic assertions: return non-zero if a condition 403 1.2 ad * variable has waiters. 404 1.2 ad */ 405 1.7 ad bool 406 1.2 ad cv_has_waiters(kcondvar_t *cv) 407 1.2 ad { 408 1.2 ad 409 1.14.14.2 mjf return !TAILQ_EMPTY(CV_SLEEPQ(cv)); 410 1.2 ad } 411 1.14.14.1 mjf 412 1.14.14.1 mjf /* 413 1.14.14.1 mjf * cv_is_valid: 414 1.14.14.1 mjf * 415 1.14.14.1 mjf * For diagnostic assertions: return non-zero if a condition 416 1.14.14.1 mjf * variable appears to be valid. No locks need be held. 417 1.14.14.1 mjf */ 418 1.14.14.1 mjf bool 419 1.14.14.1 mjf cv_is_valid(kcondvar_t *cv) 420 1.14.14.1 mjf { 421 1.14.14.1 mjf 422 1.14.14.5 mjf return CV_WMESG(cv) != deadcv && CV_WMESG(cv) != NULL; 423 1.14.14.1 mjf } 424
Indexes created Mon Sep 29 21:09:56 GMT 2025