sys_sched.c revision 1.18
1 1.18 elad /* $NetBSD: sys_sched.c,v 1.18 2008/02/28 16:09:19 elad Exp $ */ 2 1.1 ad 3 1.5 rmind /* 4 1.5 rmind * Copyright (c) 2008, Mindaugas Rasiukevicius <rmind at NetBSD org> 5 1.1 ad * All rights reserved. 6 1.5 rmind * 7 1.1 ad * Redistribution and use in source and binary forms, with or without 8 1.1 ad * modification, are permitted provided that the following conditions 9 1.1 ad * are met: 10 1.1 ad * 1. Redistributions of source code must retain the above copyright 11 1.1 ad * notice, this list of conditions and the following disclaimer. 12 1.1 ad * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 ad * notice, this list of conditions and the following disclaimer in the 14 1.1 ad * documentation and/or other materials provided with the distribution. 15 1.1 ad * 16 1.16 rmind * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 17 1.16 rmind * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 18 1.16 rmind * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 19 1.16 rmind * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 20 1.16 rmind * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 21 1.16 rmind * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 22 1.16 rmind * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 23 1.16 rmind * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 24 1.16 rmind * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 25 1.16 rmind * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 26 1.16 rmind * SUCH DAMAGE. 27 1.1 ad */ 28 1.1 ad 29 1.5 rmind /* 30 1.17 ad * System calls relating to the scheduler. 31 1.17 ad * 32 1.5 rmind * TODO: 33 1.5 rmind * - Handle pthread_setschedprio() as defined by POSIX; 34 1.5 rmind * - Handle sched_yield() case for SCHED_FIFO as defined by POSIX; 35 1.5 rmind */ 36 1.5 rmind 37 1.1 ad #include <sys/cdefs.h> 38 1.18 elad __KERNEL_RCSID(0, "$NetBSD: sys_sched.c,v 1.18 2008/02/28 16:09:19 elad Exp $"); 39 1.1 ad 40 1.1 ad #include <sys/param.h> 41 1.5 rmind 42 1.5 rmind #include <sys/cpu.h> 43 1.5 rmind #include <sys/kauth.h> 44 1.5 rmind #include <sys/kmem.h> 45 1.5 rmind #include <sys/lwp.h> 46 1.5 rmind #include <sys/mutex.h> 47 1.1 ad #include <sys/proc.h> 48 1.5 rmind #include <sys/pset.h> 49 1.5 rmind #include <sys/sched.h> 50 1.1 ad #include <sys/syscallargs.h> 51 1.5 rmind #include <sys/sysctl.h> 52 1.5 rmind #include <sys/systm.h> 53 1.5 rmind #include <sys/types.h> 54 1.5 rmind #include <sys/unistd.h> 55 1.5 rmind 56 1.5 rmind /* 57 1.7 rmind * Convert user priority or the in-kernel priority or convert the current 58 1.7 rmind * priority to the appropriate range according to the policy change. 59 1.7 rmind */ 60 1.7 rmind static pri_t 61 1.7 rmind convert_pri(lwp_t *l, int policy, pri_t pri) 62 1.7 rmind { 63 1.7 rmind int delta = 0; 64 1.7 rmind 65 1.7 rmind switch (policy) { 66 1.7 rmind case SCHED_OTHER: 67 1.7 rmind delta = PRI_USER; 68 1.7 rmind break; 69 1.7 rmind case SCHED_FIFO: 70 1.7 rmind case SCHED_RR: 71 1.7 rmind delta = PRI_USER_RT; 72 1.7 rmind break; 73 1.7 rmind default: 74 1.7 rmind panic("upri_to_kpri"); 75 1.7 rmind } 76 1.7 rmind 77 1.7 rmind if (pri != PRI_NONE) { 78 1.7 rmind /* Convert user priority to the in-kernel */ 79 1.7 rmind KASSERT(pri >= SCHED_PRI_MIN && pri <= SCHED_PRI_MAX); 80 1.7 rmind return pri + delta; 81 1.7 rmind } 82 1.7 rmind if (l->l_class == policy) 83 1.7 rmind return l->l_priority; 84 1.7 rmind 85 1.7 rmind /* Change the current priority to the appropriate range */ 86 1.7 rmind if (l->l_class == SCHED_OTHER) { 87 1.7 rmind KASSERT(policy == SCHED_FIFO || policy == SCHED_RR); 88 1.7 rmind return l->l_priority + delta; 89 1.7 rmind } 90 1.7 rmind if (policy == SCHED_OTHER) { 91 1.7 rmind KASSERT(l->l_class == SCHED_FIFO || l->l_class == SCHED_RR); 92 1.7 rmind return l->l_priority - delta; 93 1.7 rmind } 94 1.7 rmind KASSERT(l->l_class != SCHED_OTHER && policy != SCHED_OTHER); 95 1.7 rmind return l->l_class; 96 1.7 rmind } 97 1.7 rmind 98 1.5 rmind int 99 1.18 elad do_sched_setparam(pid_t pid, lwpid_t lid, int policy, 100 1.18 elad const struct sched_param *params) 101 1.5 rmind { 102 1.5 rmind struct proc *p; 103 1.5 rmind struct lwp *t; 104 1.18 elad pri_t pri; 105 1.5 rmind u_int lcnt; 106 1.5 rmind int error; 107 1.5 rmind 108 1.18 elad error = 0; 109 1.18 elad 110 1.18 elad pri = params->sched_priority; 111 1.7 rmind 112 1.7 rmind /* If no parameters specified, just return (this should not happen) */ 113 1.7 rmind if (pri == PRI_NONE && policy == SCHED_NONE) 114 1.7 rmind return 0; 115 1.5 rmind 116 1.7 rmind /* Validate scheduling class */ 117 1.7 rmind if (policy != SCHED_NONE && (policy < SCHED_OTHER || policy > SCHED_RR)) 118 1.7 rmind return EINVAL; 119 1.5 rmind 120 1.7 rmind /* Validate priority */ 121 1.7 rmind if (pri != PRI_NONE && (pri < SCHED_PRI_MIN || pri > SCHED_PRI_MAX)) 122 1.7 rmind return EINVAL; 123 1.5 rmind 124 1.18 elad if (pid != 0) { 125 1.7 rmind /* Find the process */ 126 1.18 elad p = p_find(pid, PFIND_UNLOCK_FAIL); 127 1.7 rmind if (p == NULL) 128 1.7 rmind return ESRCH; 129 1.7 rmind mutex_enter(&p->p_smutex); 130 1.7 rmind mutex_exit(&proclist_lock); 131 1.7 rmind /* Disallow modification of system processes */ 132 1.17 ad if ((p->p_flag & PK_SYSTEM) != 0) { 133 1.7 rmind mutex_exit(&p->p_smutex); 134 1.7 rmind return EPERM; 135 1.7 rmind } 136 1.7 rmind } else { 137 1.7 rmind /* Use the calling process */ 138 1.18 elad p = curlwp->l_proc; 139 1.7 rmind mutex_enter(&p->p_smutex); 140 1.5 rmind } 141 1.1 ad 142 1.5 rmind /* Find the LWP(s) */ 143 1.5 rmind lcnt = 0; 144 1.5 rmind LIST_FOREACH(t, &p->p_lwps, l_sibling) { 145 1.7 rmind pri_t kpri; 146 1.12 elad int lpolicy; 147 1.5 rmind 148 1.5 rmind if (lid && lid != t->l_lid) 149 1.5 rmind continue; 150 1.15 drochner lcnt++; 151 1.7 rmind KASSERT(pri != PRI_NONE || policy != SCHED_NONE); 152 1.7 rmind lwp_lock(t); 153 1.7 rmind 154 1.12 elad if (policy == SCHED_NONE) 155 1.13 yamt lpolicy = t->l_class; 156 1.12 elad else 157 1.12 elad lpolicy = policy; 158 1.12 elad 159 1.7 rmind /* 160 1.7 rmind * Note that, priority may need to be changed to get into 161 1.7 rmind * the correct priority range of the new scheduling class. 162 1.7 rmind */ 163 1.12 elad kpri = convert_pri(t, lpolicy, pri); 164 1.12 elad 165 1.12 elad /* Check the permission */ 166 1.18 elad error = kauth_authorize_process(kauth_cred_get(), 167 1.12 elad KAUTH_PROCESS_SCHEDULER_SETPARAM, p, t, KAUTH_ARG(lpolicy), 168 1.12 elad KAUTH_ARG(kpri)); 169 1.14 yamt if (error) { 170 1.14 yamt lwp_unlock(t); 171 1.12 elad break; 172 1.14 yamt } 173 1.5 rmind 174 1.5 rmind /* Set the scheduling class */ 175 1.7 rmind if (policy != SCHED_NONE) 176 1.7 rmind t->l_class = policy; 177 1.5 rmind 178 1.5 rmind /* Change the priority */ 179 1.7 rmind if (t->l_priority != kpri) 180 1.7 rmind lwp_changepri(t, kpri); 181 1.5 rmind 182 1.5 rmind lwp_unlock(t); 183 1.5 rmind } 184 1.5 rmind mutex_exit(&p->p_smutex); 185 1.7 rmind return (lcnt == 0) ? ESRCH : error; 186 1.5 rmind } 187 1.5 rmind 188 1.5 rmind /* 189 1.18 elad * Set scheduling parameters. 190 1.5 rmind */ 191 1.5 rmind int 192 1.18 elad sys__sched_setparam(struct lwp *l, const struct sys__sched_setparam_args *uap, 193 1.5 rmind register_t *retval) 194 1.5 rmind { 195 1.5 rmind /* { 196 1.5 rmind syscallarg(pid_t) pid; 197 1.5 rmind syscallarg(lwpid_t) lid; 198 1.18 elad syscallarg(int) policy; 199 1.18 elad syscallarg(const struct sched_param *) params; 200 1.5 rmind } */ 201 1.18 elad struct sched_param params; 202 1.18 elad int error; 203 1.18 elad 204 1.18 elad /* Get the parameters from the user-space */ 205 1.18 elad error = copyin(SCARG(uap, params), ¶ms, sizeof(params)); 206 1.18 elad if (error) 207 1.18 elad goto out; 208 1.18 elad 209 1.18 elad error = do_sched_setparam(SCARG(uap, pid), SCARG(uap, lid), 210 1.18 elad SCARG(uap, policy), ¶ms); 211 1.18 elad 212 1.18 elad out: 213 1.18 elad return (error); 214 1.18 elad } 215 1.18 elad 216 1.18 elad int 217 1.18 elad do_sched_getparam(pid_t pid, lwpid_t lid, int *policy, 218 1.18 elad struct sched_param *params) 219 1.18 elad { 220 1.18 elad struct sched_param lparams; 221 1.5 rmind struct lwp *t; 222 1.18 elad int error, lpolicy; 223 1.5 rmind 224 1.16 rmind /* Locks the LWP */ 225 1.18 elad t = lwp_find2(pid, lid); 226 1.18 elad if (t == NULL) { 227 1.18 elad error = ESRCH; 228 1.18 elad goto out; 229 1.18 elad } 230 1.10 yamt 231 1.10 yamt /* Check the permission */ 232 1.18 elad error = kauth_authorize_process(kauth_cred_get(), 233 1.11 elad KAUTH_PROCESS_SCHEDULER_GETPARAM, t->l_proc, NULL, NULL, NULL); 234 1.10 yamt if (error != 0) { 235 1.10 yamt lwp_unlock(t); 236 1.18 elad goto out; 237 1.5 rmind } 238 1.10 yamt 239 1.18 elad lparams.sched_priority = t->l_priority; 240 1.18 elad lpolicy = t->l_class; 241 1.5 rmind lwp_unlock(t); 242 1.5 rmind 243 1.18 elad switch (lpolicy) { 244 1.5 rmind case SCHED_OTHER: 245 1.18 elad lparams.sched_priority -= PRI_USER; 246 1.5 rmind break; 247 1.5 rmind case SCHED_RR: 248 1.5 rmind case SCHED_FIFO: 249 1.18 elad lparams.sched_priority -= PRI_USER_RT; 250 1.5 rmind break; 251 1.5 rmind } 252 1.18 elad 253 1.18 elad if (policy != NULL) 254 1.18 elad *policy = lpolicy; 255 1.18 elad 256 1.18 elad if (params != NULL) 257 1.18 elad *params = lparams; 258 1.18 elad 259 1.18 elad out: 260 1.18 elad return error; 261 1.18 elad } 262 1.18 elad 263 1.18 elad /* 264 1.18 elad * Get scheduling parameters. 265 1.18 elad */ 266 1.18 elad int 267 1.18 elad sys__sched_getparam(struct lwp *l, const struct sys__sched_getparam_args *uap, 268 1.18 elad register_t *retval) 269 1.18 elad { 270 1.18 elad /* { 271 1.18 elad syscallarg(pid_t) pid; 272 1.18 elad syscallarg(lwpid_t) lid; 273 1.18 elad syscallarg(int *) policy; 274 1.18 elad syscallarg(struct sched_param *) params; 275 1.18 elad } */ 276 1.18 elad struct sched_param params; 277 1.18 elad int error, policy; 278 1.18 elad 279 1.18 elad error = do_sched_getparam(SCARG(uap, pid), SCARG(uap, lid), &policy, 280 1.18 elad ¶ms); 281 1.18 elad if (error) 282 1.18 elad goto out; 283 1.18 elad 284 1.18 elad error = copyout(¶ms, SCARG(uap, params), sizeof(params)); 285 1.10 yamt if (error == 0 && SCARG(uap, policy) != NULL) 286 1.10 yamt error = copyout(&policy, SCARG(uap, policy), sizeof(int)); 287 1.18 elad 288 1.18 elad out: 289 1.18 elad return (error); 290 1.5 rmind } 291 1.5 rmind 292 1.5 rmind /* 293 1.5 rmind * Set affinity. 294 1.5 rmind */ 295 1.5 rmind int 296 1.5 rmind sys__sched_setaffinity(struct lwp *l, 297 1.5 rmind const struct sys__sched_setaffinity_args *uap, register_t *retval) 298 1.5 rmind { 299 1.5 rmind /* { 300 1.5 rmind syscallarg(pid_t) pid; 301 1.5 rmind syscallarg(lwpid_t) lid; 302 1.5 rmind syscallarg(size_t) size; 303 1.5 rmind syscallarg(void *) cpuset; 304 1.5 rmind } */ 305 1.5 rmind cpuset_t *cpuset; 306 1.5 rmind struct cpu_info *ci = NULL; 307 1.5 rmind struct proc *p; 308 1.5 rmind struct lwp *t; 309 1.5 rmind CPU_INFO_ITERATOR cii; 310 1.5 rmind lwpid_t lid; 311 1.5 rmind u_int lcnt; 312 1.5 rmind int error; 313 1.5 rmind 314 1.5 rmind /* Allocate the CPU set, and get it from userspace */ 315 1.5 rmind cpuset = kmem_zalloc(sizeof(cpuset_t), KM_SLEEP); 316 1.5 rmind error = copyin(SCARG(uap, cpuset), cpuset, 317 1.5 rmind min(SCARG(uap, size), sizeof(cpuset_t))); 318 1.5 rmind if (error) 319 1.5 rmind goto error; 320 1.5 rmind 321 1.5 rmind /* Look for a CPU in the set */ 322 1.5 rmind for (CPU_INFO_FOREACH(cii, ci)) 323 1.5 rmind if (CPU_ISSET(cpu_index(ci), cpuset)) 324 1.5 rmind break; 325 1.5 rmind if (ci == NULL) { 326 1.5 rmind /* Empty set */ 327 1.5 rmind kmem_free(cpuset, sizeof(cpuset_t)); 328 1.5 rmind cpuset = NULL; 329 1.5 rmind } 330 1.5 rmind 331 1.7 rmind if (SCARG(uap, pid) != 0) { 332 1.7 rmind /* Find the process */ 333 1.7 rmind p = p_find(SCARG(uap, pid), PFIND_UNLOCK_FAIL); 334 1.7 rmind if (p == NULL) { 335 1.7 rmind error = ESRCH; 336 1.7 rmind goto error; 337 1.7 rmind } 338 1.7 rmind mutex_enter(&p->p_smutex); 339 1.7 rmind mutex_exit(&proclist_lock); 340 1.17 ad /* Disallow modification of system processes. */ 341 1.17 ad if ((p->p_flag & PK_SYSTEM) != 0) { 342 1.17 ad mutex_exit(&p->p_smutex); 343 1.17 ad error = EPERM; 344 1.17 ad goto error; 345 1.17 ad } 346 1.7 rmind } else { 347 1.7 rmind /* Use the calling process */ 348 1.7 rmind p = l->l_proc; 349 1.7 rmind mutex_enter(&p->p_smutex); 350 1.5 rmind } 351 1.5 rmind 352 1.10 yamt /* 353 1.10 yamt * Check the permission. 354 1.10 yamt */ 355 1.11 elad error = kauth_authorize_process(l->l_cred, 356 1.11 elad KAUTH_PROCESS_SCHEDULER_SETAFFINITY, p, NULL, NULL, NULL); 357 1.10 yamt if (error != 0) { 358 1.10 yamt mutex_exit(&p->p_smutex); 359 1.10 yamt goto error; 360 1.10 yamt } 361 1.5 rmind 362 1.5 rmind /* Find the LWP(s) */ 363 1.5 rmind lcnt = 0; 364 1.5 rmind lid = SCARG(uap, lid); 365 1.5 rmind LIST_FOREACH(t, &p->p_lwps, l_sibling) { 366 1.5 rmind if (lid && lid != t->l_lid) 367 1.5 rmind continue; 368 1.5 rmind lwp_lock(t); 369 1.5 rmind if (cpuset) { 370 1.5 rmind /* Set the affinity flag and new CPU set */ 371 1.5 rmind t->l_flag |= LW_AFFINITY; 372 1.5 rmind memcpy(&t->l_affinity, cpuset, sizeof(cpuset_t)); 373 1.5 rmind /* Migrate to another CPU, unlocks LWP */ 374 1.5 rmind lwp_migrate(t, ci); 375 1.5 rmind } else { 376 1.5 rmind /* Unset the affinity flag */ 377 1.5 rmind t->l_flag &= ~LW_AFFINITY; 378 1.5 rmind lwp_unlock(t); 379 1.5 rmind } 380 1.5 rmind lcnt++; 381 1.5 rmind } 382 1.5 rmind mutex_exit(&p->p_smutex); 383 1.5 rmind if (lcnt == 0) 384 1.5 rmind error = ESRCH; 385 1.5 rmind error: 386 1.5 rmind if (cpuset != NULL) 387 1.5 rmind kmem_free(cpuset, sizeof(cpuset_t)); 388 1.5 rmind return error; 389 1.5 rmind } 390 1.5 rmind 391 1.5 rmind /* 392 1.5 rmind * Get affinity. 393 1.5 rmind */ 394 1.5 rmind int 395 1.5 rmind sys__sched_getaffinity(struct lwp *l, 396 1.5 rmind const struct sys__sched_getaffinity_args *uap, register_t *retval) 397 1.5 rmind { 398 1.5 rmind /* { 399 1.5 rmind syscallarg(pid_t) pid; 400 1.5 rmind syscallarg(lwpid_t) lid; 401 1.5 rmind syscallarg(size_t) size; 402 1.5 rmind syscallarg(void *) cpuset; 403 1.5 rmind } */ 404 1.5 rmind struct lwp *t; 405 1.5 rmind void *cpuset; 406 1.5 rmind int error; 407 1.5 rmind 408 1.5 rmind if (SCARG(uap, size) <= 0) 409 1.5 rmind return EINVAL; 410 1.5 rmind cpuset = kmem_zalloc(sizeof(cpuset_t), KM_SLEEP); 411 1.5 rmind 412 1.16 rmind /* Locks the LWP */ 413 1.16 rmind t = lwp_find2(SCARG(uap, pid), SCARG(uap, lid)); 414 1.5 rmind if (t == NULL) { 415 1.5 rmind kmem_free(cpuset, sizeof(cpuset_t)); 416 1.5 rmind return ESRCH; 417 1.5 rmind } 418 1.10 yamt /* Check the permission */ 419 1.11 elad if (kauth_authorize_process(l->l_cred, 420 1.11 elad KAUTH_PROCESS_SCHEDULER_GETAFFINITY, t->l_proc, NULL, NULL, NULL)) { 421 1.10 yamt lwp_unlock(t); 422 1.10 yamt kmem_free(cpuset, sizeof(cpuset_t)); 423 1.10 yamt return EPERM; 424 1.10 yamt } 425 1.5 rmind if (t->l_flag & LW_AFFINITY) 426 1.5 rmind memcpy(cpuset, &t->l_affinity, sizeof(cpuset_t)); 427 1.5 rmind lwp_unlock(t); 428 1.5 rmind 429 1.5 rmind error = copyout(cpuset, SCARG(uap, cpuset), 430 1.5 rmind min(SCARG(uap, size), sizeof(cpuset_t))); 431 1.5 rmind 432 1.5 rmind kmem_free(cpuset, sizeof(cpuset_t)); 433 1.5 rmind return error; 434 1.5 rmind } 435 1.5 rmind 436 1.5 rmind /* 437 1.5 rmind * Yield. 438 1.5 rmind */ 439 1.1 ad int 440 1.4 dsl sys_sched_yield(struct lwp *l, const void *v, register_t *retval) 441 1.1 ad { 442 1.1 ad 443 1.1 ad yield(); 444 1.1 ad return 0; 445 1.1 ad } 446 1.5 rmind 447 1.5 rmind /* 448 1.5 rmind * Sysctl nodes and initialization. 449 1.5 rmind */ 450 1.5 rmind SYSCTL_SETUP(sysctl_sched_setup, "sysctl sched setup") 451 1.5 rmind { 452 1.5 rmind const struct sysctlnode *node = NULL; 453 1.5 rmind 454 1.5 rmind sysctl_createv(clog, 0, NULL, NULL, 455 1.5 rmind CTLFLAG_PERMANENT, 456 1.5 rmind CTLTYPE_NODE, "kern", NULL, 457 1.5 rmind NULL, 0, NULL, 0, 458 1.5 rmind CTL_KERN, CTL_EOL); 459 1.5 rmind sysctl_createv(clog, 0, NULL, NULL, 460 1.5 rmind CTLFLAG_PERMANENT|CTLFLAG_IMMEDIATE, 461 1.5 rmind CTLTYPE_INT, "posix_sched", 462 1.5 rmind SYSCTL_DESCR("Version of IEEE Std 1003.1 and its " 463 1.5 rmind "Process Scheduling option to which the " 464 1.5 rmind "system attempts to conform"), 465 1.5 rmind NULL, _POSIX_PRIORITY_SCHEDULING, NULL, 0, 466 1.5 rmind CTL_KERN, CTL_CREATE, CTL_EOL); 467 1.5 rmind sysctl_createv(clog, 0, NULL, &node, 468 1.5 rmind CTLFLAG_PERMANENT, 469 1.5 rmind CTLTYPE_NODE, "sched", 470 1.5 rmind SYSCTL_DESCR("Scheduler options"), 471 1.5 rmind NULL, 0, NULL, 0, 472 1.5 rmind CTL_KERN, CTL_CREATE, CTL_EOL); 473 1.5 rmind 474 1.5 rmind if (node == NULL) 475 1.5 rmind return; 476 1.5 rmind 477 1.5 rmind sysctl_createv(clog, 0, &node, NULL, 478 1.5 rmind CTLFLAG_PERMANENT | CTLFLAG_IMMEDIATE, 479 1.5 rmind CTLTYPE_INT, "pri_min", 480 1.5 rmind SYSCTL_DESCR("Minimal POSIX real-time priority"), 481 1.5 rmind NULL, SCHED_PRI_MIN, NULL, 0, 482 1.5 rmind CTL_CREATE, CTL_EOL); 483 1.5 rmind sysctl_createv(clog, 0, &node, NULL, 484 1.5 rmind CTLFLAG_PERMANENT | CTLFLAG_IMMEDIATE, 485 1.5 rmind CTLTYPE_INT, "pri_max", 486 1.5 rmind SYSCTL_DESCR("Minimal POSIX real-time priority"), 487 1.5 rmind NULL, SCHED_PRI_MAX, NULL, 0, 488 1.5 rmind CTL_CREATE, CTL_EOL); 489 1.5 rmind } 490
Indexes created Sun Sep 21 15:09:59 GMT 2025