kern_event.c revision 1.117.4.1
1 1.117.4.1 thorpej /* $NetBSD: kern_event.c,v 1.117.4.1 2021/05/13 00:47:32 thorpej Exp $ */ 2 1.49 ad 3 1.49 ad /*- 4 1.64 ad * Copyright (c) 2008, 2009 The NetBSD Foundation, Inc. 5 1.49 ad * All rights reserved. 6 1.49 ad * 7 1.64 ad * This code is derived from software contributed to The NetBSD Foundation 8 1.64 ad * by Andrew Doran. 9 1.64 ad * 10 1.49 ad * Redistribution and use in source and binary forms, with or without 11 1.49 ad * modification, are permitted provided that the following conditions 12 1.49 ad * are met: 13 1.49 ad * 1. Redistributions of source code must retain the above copyright 14 1.49 ad * notice, this list of conditions and the following disclaimer. 15 1.49 ad * 2. Redistributions in binary form must reproduce the above copyright 16 1.49 ad * notice, this list of conditions and the following disclaimer in the 17 1.49 ad * documentation and/or other materials provided with the distribution. 18 1.49 ad * 19 1.49 ad * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.49 ad * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.49 ad * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.49 ad * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.49 ad * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.49 ad * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.49 ad * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.49 ad * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.49 ad * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.49 ad * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.49 ad * POSSIBILITY OF SUCH DAMAGE. 30 1.49 ad */ 31 1.28 kardel 32 1.1 lukem /*- 33 1.1 lukem * Copyright (c) 1999,2000,2001 Jonathan Lemon <jlemon (at) FreeBSD.org> 34 1.108 christos * Copyright (c) 2009 Apple, Inc 35 1.1 lukem * All rights reserved. 36 1.1 lukem * 37 1.1 lukem * Redistribution and use in source and binary forms, with or without 38 1.1 lukem * modification, are permitted provided that the following conditions 39 1.1 lukem * are met: 40 1.1 lukem * 1. Redistributions of source code must retain the above copyright 41 1.1 lukem * notice, this list of conditions and the following disclaimer. 42 1.1 lukem * 2. Redistributions in binary form must reproduce the above copyright 43 1.1 lukem * notice, this list of conditions and the following disclaimer in the 44 1.1 lukem * documentation and/or other materials provided with the distribution. 45 1.1 lukem * 46 1.1 lukem * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 47 1.1 lukem * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 48 1.1 lukem * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 49 1.1 lukem * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 50 1.1 lukem * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 51 1.1 lukem * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 52 1.1 lukem * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 53 1.1 lukem * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 54 1.1 lukem * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 55 1.1 lukem * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 56 1.1 lukem * SUCH DAMAGE. 57 1.1 lukem * 58 1.49 ad * FreeBSD: src/sys/kern/kern_event.c,v 1.27 2001/07/05 17:10:44 rwatson Exp 59 1.1 lukem */ 60 1.14 jdolecek 61 1.14 jdolecek #include <sys/cdefs.h> 62 1.117.4.1 thorpej __KERNEL_RCSID(0, "$NetBSD: kern_event.c,v 1.117.4.1 2021/05/13 00:47:32 thorpej Exp $"); 63 1.1 lukem 64 1.1 lukem #include <sys/param.h> 65 1.1 lukem #include <sys/systm.h> 66 1.1 lukem #include <sys/kernel.h> 67 1.86 christos #include <sys/wait.h> 68 1.1 lukem #include <sys/proc.h> 69 1.1 lukem #include <sys/file.h> 70 1.3 jdolecek #include <sys/select.h> 71 1.1 lukem #include <sys/queue.h> 72 1.1 lukem #include <sys/event.h> 73 1.1 lukem #include <sys/eventvar.h> 74 1.1 lukem #include <sys/poll.h> 75 1.49 ad #include <sys/kmem.h> 76 1.1 lukem #include <sys/stat.h> 77 1.3 jdolecek #include <sys/filedesc.h> 78 1.3 jdolecek #include <sys/syscallargs.h> 79 1.27 elad #include <sys/kauth.h> 80 1.40 ad #include <sys/conf.h> 81 1.49 ad #include <sys/atomic.h> 82 1.1 lukem 83 1.49 ad static int kqueue_scan(file_t *, size_t, struct kevent *, 84 1.49 ad const struct timespec *, register_t *, 85 1.49 ad const struct kevent_ops *, struct kevent *, 86 1.49 ad size_t); 87 1.49 ad static int kqueue_ioctl(file_t *, u_long, void *); 88 1.49 ad static int kqueue_fcntl(file_t *, u_int, void *); 89 1.49 ad static int kqueue_poll(file_t *, int); 90 1.49 ad static int kqueue_kqfilter(file_t *, struct knote *); 91 1.49 ad static int kqueue_stat(file_t *, struct stat *); 92 1.49 ad static int kqueue_close(file_t *); 93 1.117.4.1 thorpej static void kqueue_restart(file_t *); 94 1.49 ad static int kqueue_register(struct kqueue *, struct kevent *); 95 1.49 ad static void kqueue_doclose(struct kqueue *, struct klist *, int); 96 1.49 ad 97 1.49 ad static void knote_detach(struct knote *, filedesc_t *fdp, bool); 98 1.49 ad static void knote_enqueue(struct knote *); 99 1.49 ad static void knote_activate(struct knote *); 100 1.49 ad 101 1.49 ad static void filt_kqdetach(struct knote *); 102 1.49 ad static int filt_kqueue(struct knote *, long hint); 103 1.49 ad static int filt_procattach(struct knote *); 104 1.49 ad static void filt_procdetach(struct knote *); 105 1.49 ad static int filt_proc(struct knote *, long hint); 106 1.49 ad static int filt_fileattach(struct knote *); 107 1.49 ad static void filt_timerexpire(void *x); 108 1.49 ad static int filt_timerattach(struct knote *); 109 1.49 ad static void filt_timerdetach(struct knote *); 110 1.49 ad static int filt_timer(struct knote *, long hint); 111 1.102 christos static int filt_fsattach(struct knote *kn); 112 1.102 christos static void filt_fsdetach(struct knote *kn); 113 1.102 christos static int filt_fs(struct knote *kn, long hint); 114 1.108 christos static int filt_userattach(struct knote *); 115 1.108 christos static void filt_userdetach(struct knote *); 116 1.108 christos static int filt_user(struct knote *, long hint); 117 1.108 christos static void filt_usertouch(struct knote *, struct kevent *, long type); 118 1.1 lukem 119 1.21 christos static const struct fileops kqueueops = { 120 1.101 christos .fo_name = "kqueue", 121 1.64 ad .fo_read = (void *)enxio, 122 1.64 ad .fo_write = (void *)enxio, 123 1.64 ad .fo_ioctl = kqueue_ioctl, 124 1.64 ad .fo_fcntl = kqueue_fcntl, 125 1.64 ad .fo_poll = kqueue_poll, 126 1.64 ad .fo_stat = kqueue_stat, 127 1.64 ad .fo_close = kqueue_close, 128 1.64 ad .fo_kqfilter = kqueue_kqfilter, 129 1.117.4.1 thorpej .fo_restart = kqueue_restart, 130 1.1 lukem }; 131 1.1 lukem 132 1.96 maya static const struct filterops kqread_filtops = { 133 1.96 maya .f_isfd = 1, 134 1.96 maya .f_attach = NULL, 135 1.96 maya .f_detach = filt_kqdetach, 136 1.96 maya .f_event = filt_kqueue, 137 1.96 maya }; 138 1.96 maya 139 1.96 maya static const struct filterops proc_filtops = { 140 1.96 maya .f_isfd = 0, 141 1.96 maya .f_attach = filt_procattach, 142 1.96 maya .f_detach = filt_procdetach, 143 1.96 maya .f_event = filt_proc, 144 1.96 maya }; 145 1.96 maya 146 1.96 maya static const struct filterops file_filtops = { 147 1.96 maya .f_isfd = 1, 148 1.96 maya .f_attach = filt_fileattach, 149 1.96 maya .f_detach = NULL, 150 1.96 maya .f_event = NULL, 151 1.96 maya }; 152 1.96 maya 153 1.96 maya static const struct filterops timer_filtops = { 154 1.96 maya .f_isfd = 0, 155 1.96 maya .f_attach = filt_timerattach, 156 1.96 maya .f_detach = filt_timerdetach, 157 1.96 maya .f_event = filt_timer, 158 1.96 maya }; 159 1.1 lukem 160 1.102 christos static const struct filterops fs_filtops = { 161 1.102 christos .f_isfd = 0, 162 1.102 christos .f_attach = filt_fsattach, 163 1.102 christos .f_detach = filt_fsdetach, 164 1.102 christos .f_event = filt_fs, 165 1.102 christos }; 166 1.102 christos 167 1.108 christos static const struct filterops user_filtops = { 168 1.108 christos .f_isfd = 0, 169 1.108 christos .f_attach = filt_userattach, 170 1.108 christos .f_detach = filt_userdetach, 171 1.108 christos .f_event = filt_user, 172 1.108 christos .f_touch = filt_usertouch, 173 1.108 christos }; 174 1.108 christos 175 1.49 ad static u_int kq_ncallouts = 0; 176 1.8 jdolecek static int kq_calloutmax = (4 * 1024); 177 1.7 thorpej 178 1.1 lukem #define KN_HASHSIZE 64 /* XXX should be tunable */ 179 1.3 jdolecek #define KN_HASH(val, mask) (((val) ^ (val >> 8)) & (mask)) 180 1.1 lukem 181 1.3 jdolecek extern const struct filterops sig_filtops; 182 1.1 lukem 183 1.111 jdolecek #define KQ_FLUX_WAKEUP(kq) cv_broadcast(&kq->kq_cv) 184 1.111 jdolecek 185 1.1 lukem /* 186 1.1 lukem * Table for for all system-defined filters. 187 1.3 jdolecek * These should be listed in the numeric order of the EVFILT_* defines. 188 1.3 jdolecek * If filtops is NULL, the filter isn't implemented in NetBSD. 189 1.3 jdolecek * End of list is when name is NULL. 190 1.93 riastrad * 191 1.49 ad * Note that 'refcnt' is meaningless for built-in filters. 192 1.1 lukem */ 193 1.3 jdolecek struct kfilter { 194 1.49 ad const char *name; /* name of filter */ 195 1.49 ad uint32_t filter; /* id of filter */ 196 1.49 ad unsigned refcnt; /* reference count */ 197 1.3 jdolecek const struct filterops *filtops;/* operations for filter */ 198 1.49 ad size_t namelen; /* length of name string */ 199 1.3 jdolecek }; 200 1.3 jdolecek 201 1.49 ad /* System defined filters */ 202 1.49 ad static struct kfilter sys_kfilters[] = { 203 1.49 ad { "EVFILT_READ", EVFILT_READ, 0, &file_filtops, 0 }, 204 1.49 ad { "EVFILT_WRITE", EVFILT_WRITE, 0, &file_filtops, 0, }, 205 1.49 ad { "EVFILT_AIO", EVFILT_AIO, 0, NULL, 0 }, 206 1.49 ad { "EVFILT_VNODE", EVFILT_VNODE, 0, &file_filtops, 0 }, 207 1.49 ad { "EVFILT_PROC", EVFILT_PROC, 0, &proc_filtops, 0 }, 208 1.49 ad { "EVFILT_SIGNAL", EVFILT_SIGNAL, 0, &sig_filtops, 0 }, 209 1.49 ad { "EVFILT_TIMER", EVFILT_TIMER, 0, &timer_filtops, 0 }, 210 1.102 christos { "EVFILT_FS", EVFILT_FS, 0, &fs_filtops, 0 }, 211 1.108 christos { "EVFILT_USER", EVFILT_USER, 0, &user_filtops, 0 }, 212 1.49 ad { NULL, 0, 0, NULL, 0 }, 213 1.1 lukem }; 214 1.1 lukem 215 1.49 ad /* User defined kfilters */ 216 1.3 jdolecek static struct kfilter *user_kfilters; /* array */ 217 1.3 jdolecek static int user_kfilterc; /* current offset */ 218 1.3 jdolecek static int user_kfiltermaxc; /* max size so far */ 219 1.49 ad static size_t user_kfiltersz; /* size of allocated memory */ 220 1.49 ad 221 1.95 riastrad /* 222 1.95 riastrad * Global Locks. 223 1.95 riastrad * 224 1.95 riastrad * Lock order: 225 1.95 riastrad * 226 1.95 riastrad * kqueue_filter_lock 227 1.95 riastrad * -> kn_kq->kq_fdp->fd_lock 228 1.95 riastrad * -> object lock (e.g., device driver lock, kqueue_misc_lock, &c.) 229 1.95 riastrad * -> kn_kq->kq_lock 230 1.95 riastrad * 231 1.95 riastrad * Locking rules: 232 1.95 riastrad * 233 1.95 riastrad * f_attach: fdp->fd_lock, KERNEL_LOCK 234 1.95 riastrad * f_detach: fdp->fd_lock, KERNEL_LOCK 235 1.95 riastrad * f_event(!NOTE_SUBMIT) via kevent: fdp->fd_lock, _no_ object lock 236 1.95 riastrad * f_event via knote: whatever caller guarantees 237 1.95 riastrad * Typically, f_event(NOTE_SUBMIT) via knote: object lock 238 1.95 riastrad * f_event(!NOTE_SUBMIT) via knote: nothing, 239 1.95 riastrad * acquires/releases object lock inside. 240 1.95 riastrad */ 241 1.49 ad static krwlock_t kqueue_filter_lock; /* lock on filter lists */ 242 1.49 ad static kmutex_t kqueue_misc_lock; /* miscellaneous */ 243 1.49 ad 244 1.66 elad static kauth_listener_t kqueue_listener; 245 1.66 elad 246 1.66 elad static int 247 1.66 elad kqueue_listener_cb(kauth_cred_t cred, kauth_action_t action, void *cookie, 248 1.66 elad void *arg0, void *arg1, void *arg2, void *arg3) 249 1.66 elad { 250 1.66 elad struct proc *p; 251 1.66 elad int result; 252 1.66 elad 253 1.66 elad result = KAUTH_RESULT_DEFER; 254 1.66 elad p = arg0; 255 1.66 elad 256 1.66 elad if (action != KAUTH_PROCESS_KEVENT_FILTER) 257 1.66 elad return result; 258 1.66 elad 259 1.66 elad if ((kauth_cred_getuid(p->p_cred) != kauth_cred_getuid(cred) || 260 1.66 elad ISSET(p->p_flag, PK_SUGID))) 261 1.66 elad return result; 262 1.66 elad 263 1.66 elad result = KAUTH_RESULT_ALLOW; 264 1.66 elad 265 1.66 elad return result; 266 1.66 elad } 267 1.66 elad 268 1.49 ad /* 269 1.49 ad * Initialize the kqueue subsystem. 270 1.49 ad */ 271 1.49 ad void 272 1.49 ad kqueue_init(void) 273 1.49 ad { 274 1.49 ad 275 1.49 ad rw_init(&kqueue_filter_lock); 276 1.49 ad mutex_init(&kqueue_misc_lock, MUTEX_DEFAULT, IPL_NONE); 277 1.66 elad 278 1.66 elad kqueue_listener = kauth_listen_scope(KAUTH_SCOPE_PROCESS, 279 1.66 elad kqueue_listener_cb, NULL); 280 1.49 ad } 281 1.3 jdolecek 282 1.3 jdolecek /* 283 1.3 jdolecek * Find kfilter entry by name, or NULL if not found. 284 1.3 jdolecek */ 285 1.49 ad static struct kfilter * 286 1.3 jdolecek kfilter_byname_sys(const char *name) 287 1.3 jdolecek { 288 1.3 jdolecek int i; 289 1.3 jdolecek 290 1.49 ad KASSERT(rw_lock_held(&kqueue_filter_lock)); 291 1.49 ad 292 1.3 jdolecek for (i = 0; sys_kfilters[i].name != NULL; i++) { 293 1.3 jdolecek if (strcmp(name, sys_kfilters[i].name) == 0) 294 1.49 ad return &sys_kfilters[i]; 295 1.3 jdolecek } 296 1.49 ad return NULL; 297 1.3 jdolecek } 298 1.3 jdolecek 299 1.3 jdolecek static struct kfilter * 300 1.3 jdolecek kfilter_byname_user(const char *name) 301 1.3 jdolecek { 302 1.3 jdolecek int i; 303 1.3 jdolecek 304 1.49 ad KASSERT(rw_lock_held(&kqueue_filter_lock)); 305 1.49 ad 306 1.31 seanb /* user filter slots have a NULL name if previously deregistered */ 307 1.31 seanb for (i = 0; i < user_kfilterc ; i++) { 308 1.31 seanb if (user_kfilters[i].name != NULL && 309 1.3 jdolecek strcmp(name, user_kfilters[i].name) == 0) 310 1.49 ad return &user_kfilters[i]; 311 1.3 jdolecek } 312 1.49 ad return NULL; 313 1.3 jdolecek } 314 1.3 jdolecek 315 1.49 ad static struct kfilter * 316 1.3 jdolecek kfilter_byname(const char *name) 317 1.3 jdolecek { 318 1.49 ad struct kfilter *kfilter; 319 1.49 ad 320 1.49 ad KASSERT(rw_lock_held(&kqueue_filter_lock)); 321 1.3 jdolecek 322 1.3 jdolecek if ((kfilter = kfilter_byname_sys(name)) != NULL) 323 1.49 ad return kfilter; 324 1.3 jdolecek 325 1.49 ad return kfilter_byname_user(name); 326 1.3 jdolecek } 327 1.3 jdolecek 328 1.3 jdolecek /* 329 1.3 jdolecek * Find kfilter entry by filter id, or NULL if not found. 330 1.3 jdolecek * Assumes entries are indexed in filter id order, for speed. 331 1.3 jdolecek */ 332 1.49 ad static struct kfilter * 333 1.3 jdolecek kfilter_byfilter(uint32_t filter) 334 1.3 jdolecek { 335 1.49 ad struct kfilter *kfilter; 336 1.49 ad 337 1.49 ad KASSERT(rw_lock_held(&kqueue_filter_lock)); 338 1.3 jdolecek 339 1.3 jdolecek if (filter < EVFILT_SYSCOUNT) /* it's a system filter */ 340 1.3 jdolecek kfilter = &sys_kfilters[filter]; 341 1.3 jdolecek else if (user_kfilters != NULL && 342 1.3 jdolecek filter < EVFILT_SYSCOUNT + user_kfilterc) 343 1.3 jdolecek /* it's a user filter */ 344 1.3 jdolecek kfilter = &user_kfilters[filter - EVFILT_SYSCOUNT]; 345 1.3 jdolecek else 346 1.3 jdolecek return (NULL); /* out of range */ 347 1.3 jdolecek KASSERT(kfilter->filter == filter); /* sanity check! */ 348 1.3 jdolecek return (kfilter); 349 1.3 jdolecek } 350 1.3 jdolecek 351 1.3 jdolecek /* 352 1.3 jdolecek * Register a new kfilter. Stores the entry in user_kfilters. 353 1.3 jdolecek * Returns 0 if operation succeeded, or an appropriate errno(2) otherwise. 354 1.3 jdolecek * If retfilter != NULL, the new filterid is returned in it. 355 1.3 jdolecek */ 356 1.3 jdolecek int 357 1.3 jdolecek kfilter_register(const char *name, const struct filterops *filtops, 358 1.49 ad int *retfilter) 359 1.1 lukem { 360 1.3 jdolecek struct kfilter *kfilter; 361 1.49 ad size_t len; 362 1.31 seanb int i; 363 1.3 jdolecek 364 1.3 jdolecek if (name == NULL || name[0] == '\0' || filtops == NULL) 365 1.3 jdolecek return (EINVAL); /* invalid args */ 366 1.49 ad 367 1.49 ad rw_enter(&kqueue_filter_lock, RW_WRITER); 368 1.49 ad if (kfilter_byname(name) != NULL) { 369 1.49 ad rw_exit(&kqueue_filter_lock); 370 1.3 jdolecek return (EEXIST); /* already exists */ 371 1.49 ad } 372 1.49 ad if (user_kfilterc > 0xffffffff - EVFILT_SYSCOUNT) { 373 1.49 ad rw_exit(&kqueue_filter_lock); 374 1.3 jdolecek return (EINVAL); /* too many */ 375 1.49 ad } 376 1.3 jdolecek 377 1.31 seanb for (i = 0; i < user_kfilterc; i++) { 378 1.31 seanb kfilter = &user_kfilters[i]; 379 1.31 seanb if (kfilter->name == NULL) { 380 1.31 seanb /* Previously deregistered slot. Reuse. */ 381 1.31 seanb goto reuse; 382 1.31 seanb } 383 1.31 seanb } 384 1.31 seanb 385 1.3 jdolecek /* check if need to grow user_kfilters */ 386 1.3 jdolecek if (user_kfilterc + 1 > user_kfiltermaxc) { 387 1.49 ad /* Grow in KFILTER_EXTENT chunks. */ 388 1.3 jdolecek user_kfiltermaxc += KFILTER_EXTENT; 389 1.69 dsl len = user_kfiltermaxc * sizeof(*kfilter); 390 1.49 ad kfilter = kmem_alloc(len, KM_SLEEP); 391 1.49 ad memset((char *)kfilter + user_kfiltersz, 0, len - user_kfiltersz); 392 1.49 ad if (user_kfilters != NULL) { 393 1.49 ad memcpy(kfilter, user_kfilters, user_kfiltersz); 394 1.49 ad kmem_free(user_kfilters, user_kfiltersz); 395 1.49 ad } 396 1.49 ad user_kfiltersz = len; 397 1.3 jdolecek user_kfilters = kfilter; 398 1.3 jdolecek } 399 1.31 seanb /* Adding new slot */ 400 1.31 seanb kfilter = &user_kfilters[user_kfilterc++]; 401 1.31 seanb reuse: 402 1.97 christos kfilter->name = kmem_strdupsize(name, &kfilter->namelen, KM_SLEEP); 403 1.3 jdolecek 404 1.31 seanb kfilter->filter = (kfilter - user_kfilters) + EVFILT_SYSCOUNT; 405 1.3 jdolecek 406 1.49 ad kfilter->filtops = kmem_alloc(sizeof(*filtops), KM_SLEEP); 407 1.49 ad memcpy(__UNCONST(kfilter->filtops), filtops, sizeof(*filtops)); 408 1.3 jdolecek 409 1.3 jdolecek if (retfilter != NULL) 410 1.31 seanb *retfilter = kfilter->filter; 411 1.49 ad rw_exit(&kqueue_filter_lock); 412 1.49 ad 413 1.3 jdolecek return (0); 414 1.1 lukem } 415 1.1 lukem 416 1.3 jdolecek /* 417 1.3 jdolecek * Unregister a kfilter previously registered with kfilter_register. 418 1.3 jdolecek * This retains the filter id, but clears the name and frees filtops (filter 419 1.3 jdolecek * operations), so that the number isn't reused during a boot. 420 1.3 jdolecek * Returns 0 if operation succeeded, or an appropriate errno(2) otherwise. 421 1.3 jdolecek */ 422 1.3 jdolecek int 423 1.3 jdolecek kfilter_unregister(const char *name) 424 1.1 lukem { 425 1.3 jdolecek struct kfilter *kfilter; 426 1.3 jdolecek 427 1.3 jdolecek if (name == NULL || name[0] == '\0') 428 1.3 jdolecek return (EINVAL); /* invalid name */ 429 1.3 jdolecek 430 1.49 ad rw_enter(&kqueue_filter_lock, RW_WRITER); 431 1.49 ad if (kfilter_byname_sys(name) != NULL) { 432 1.49 ad rw_exit(&kqueue_filter_lock); 433 1.3 jdolecek return (EINVAL); /* can't detach system filters */ 434 1.49 ad } 435 1.1 lukem 436 1.3 jdolecek kfilter = kfilter_byname_user(name); 437 1.49 ad if (kfilter == NULL) { 438 1.49 ad rw_exit(&kqueue_filter_lock); 439 1.3 jdolecek return (ENOENT); 440 1.49 ad } 441 1.49 ad if (kfilter->refcnt != 0) { 442 1.49 ad rw_exit(&kqueue_filter_lock); 443 1.49 ad return (EBUSY); 444 1.49 ad } 445 1.1 lukem 446 1.49 ad /* Cast away const (but we know it's safe. */ 447 1.49 ad kmem_free(__UNCONST(kfilter->name), kfilter->namelen); 448 1.31 seanb kfilter->name = NULL; /* mark as `not implemented' */ 449 1.31 seanb 450 1.3 jdolecek if (kfilter->filtops != NULL) { 451 1.49 ad /* Cast away const (but we know it's safe. */ 452 1.49 ad kmem_free(__UNCONST(kfilter->filtops), 453 1.49 ad sizeof(*kfilter->filtops)); 454 1.3 jdolecek kfilter->filtops = NULL; /* mark as `not implemented' */ 455 1.3 jdolecek } 456 1.49 ad rw_exit(&kqueue_filter_lock); 457 1.49 ad 458 1.1 lukem return (0); 459 1.1 lukem } 460 1.1 lukem 461 1.3 jdolecek 462 1.3 jdolecek /* 463 1.3 jdolecek * Filter attach method for EVFILT_READ and EVFILT_WRITE on normal file 464 1.49 ad * descriptors. Calls fileops kqfilter method for given file descriptor. 465 1.3 jdolecek */ 466 1.3 jdolecek static int 467 1.3 jdolecek filt_fileattach(struct knote *kn) 468 1.3 jdolecek { 469 1.49 ad file_t *fp; 470 1.49 ad 471 1.49 ad fp = kn->kn_obj; 472 1.3 jdolecek 473 1.49 ad return (*fp->f_ops->fo_kqfilter)(fp, kn); 474 1.3 jdolecek } 475 1.3 jdolecek 476 1.3 jdolecek /* 477 1.3 jdolecek * Filter detach method for EVFILT_READ on kqueue descriptor. 478 1.3 jdolecek */ 479 1.1 lukem static void 480 1.1 lukem filt_kqdetach(struct knote *kn) 481 1.1 lukem { 482 1.3 jdolecek struct kqueue *kq; 483 1.1 lukem 484 1.82 matt kq = ((file_t *)kn->kn_obj)->f_kqueue; 485 1.49 ad 486 1.49 ad mutex_spin_enter(&kq->kq_lock); 487 1.109 thorpej selremove_knote(&kq->kq_sel, kn); 488 1.49 ad mutex_spin_exit(&kq->kq_lock); 489 1.1 lukem } 490 1.1 lukem 491 1.3 jdolecek /* 492 1.3 jdolecek * Filter event method for EVFILT_READ on kqueue descriptor. 493 1.3 jdolecek */ 494 1.1 lukem /*ARGSUSED*/ 495 1.1 lukem static int 496 1.33 yamt filt_kqueue(struct knote *kn, long hint) 497 1.1 lukem { 498 1.3 jdolecek struct kqueue *kq; 499 1.49 ad int rv; 500 1.49 ad 501 1.82 matt kq = ((file_t *)kn->kn_obj)->f_kqueue; 502 1.1 lukem 503 1.49 ad if (hint != NOTE_SUBMIT) 504 1.49 ad mutex_spin_enter(&kq->kq_lock); 505 1.117.4.1 thorpej kn->kn_data = KQ_COUNT(kq); 506 1.49 ad rv = (kn->kn_data > 0); 507 1.49 ad if (hint != NOTE_SUBMIT) 508 1.49 ad mutex_spin_exit(&kq->kq_lock); 509 1.49 ad 510 1.49 ad return rv; 511 1.1 lukem } 512 1.1 lukem 513 1.3 jdolecek /* 514 1.3 jdolecek * Filter attach method for EVFILT_PROC. 515 1.3 jdolecek */ 516 1.1 lukem static int 517 1.1 lukem filt_procattach(struct knote *kn) 518 1.1 lukem { 519 1.78 pooka struct proc *p; 520 1.30 ad struct lwp *curl; 521 1.30 ad 522 1.30 ad curl = curlwp; 523 1.1 lukem 524 1.107 ad mutex_enter(&proc_lock); 525 1.77 joerg if (kn->kn_flags & EV_FLAG1) { 526 1.77 joerg /* 527 1.77 joerg * NOTE_TRACK attaches to the child process too early 528 1.77 joerg * for proc_find, so do a raw look up and check the state 529 1.77 joerg * explicitly. 530 1.77 joerg */ 531 1.77 joerg p = proc_find_raw(kn->kn_id); 532 1.77 joerg if (p != NULL && p->p_stat != SIDL) 533 1.77 joerg p = NULL; 534 1.77 joerg } else { 535 1.77 joerg p = proc_find(kn->kn_id); 536 1.77 joerg } 537 1.77 joerg 538 1.49 ad if (p == NULL) { 539 1.107 ad mutex_exit(&proc_lock); 540 1.49 ad return ESRCH; 541 1.49 ad } 542 1.3 jdolecek 543 1.3 jdolecek /* 544 1.3 jdolecek * Fail if it's not owned by you, or the last exec gave us 545 1.3 jdolecek * setuid/setgid privs (unless you're root). 546 1.3 jdolecek */ 547 1.57 ad mutex_enter(p->p_lock); 548 1.107 ad mutex_exit(&proc_lock); 549 1.46 elad if (kauth_authorize_process(curl->l_cred, KAUTH_PROCESS_KEVENT_FILTER, 550 1.49 ad p, NULL, NULL, NULL) != 0) { 551 1.57 ad mutex_exit(p->p_lock); 552 1.49 ad return EACCES; 553 1.49 ad } 554 1.1 lukem 555 1.49 ad kn->kn_obj = p; 556 1.3 jdolecek kn->kn_flags |= EV_CLEAR; /* automatically set */ 557 1.1 lukem 558 1.1 lukem /* 559 1.1 lukem * internal flag indicating registration done by kernel 560 1.1 lukem */ 561 1.1 lukem if (kn->kn_flags & EV_FLAG1) { 562 1.3 jdolecek kn->kn_data = kn->kn_sdata; /* ppid */ 563 1.1 lukem kn->kn_fflags = NOTE_CHILD; 564 1.1 lukem kn->kn_flags &= ~EV_FLAG1; 565 1.1 lukem } 566 1.1 lukem SLIST_INSERT_HEAD(&p->p_klist, kn, kn_selnext); 567 1.57 ad mutex_exit(p->p_lock); 568 1.1 lukem 569 1.49 ad return 0; 570 1.1 lukem } 571 1.1 lukem 572 1.1 lukem /* 573 1.3 jdolecek * Filter detach method for EVFILT_PROC. 574 1.3 jdolecek * 575 1.1 lukem * The knote may be attached to a different process, which may exit, 576 1.1 lukem * leaving nothing for the knote to be attached to. So when the process 577 1.1 lukem * exits, the knote is marked as DETACHED and also flagged as ONESHOT so 578 1.1 lukem * it will be deleted when read out. However, as part of the knote deletion, 579 1.1 lukem * this routine is called, so a check is needed to avoid actually performing 580 1.3 jdolecek * a detach, because the original process might not exist any more. 581 1.1 lukem */ 582 1.1 lukem static void 583 1.1 lukem filt_procdetach(struct knote *kn) 584 1.1 lukem { 585 1.3 jdolecek struct proc *p; 586 1.1 lukem 587 1.1 lukem if (kn->kn_status & KN_DETACHED) 588 1.1 lukem return; 589 1.1 lukem 590 1.49 ad p = kn->kn_obj; 591 1.3 jdolecek 592 1.57 ad mutex_enter(p->p_lock); 593 1.1 lukem SLIST_REMOVE(&p->p_klist, kn, knote, kn_selnext); 594 1.57 ad mutex_exit(p->p_lock); 595 1.1 lukem } 596 1.1 lukem 597 1.3 jdolecek /* 598 1.3 jdolecek * Filter event method for EVFILT_PROC. 599 1.3 jdolecek */ 600 1.1 lukem static int 601 1.1 lukem filt_proc(struct knote *kn, long hint) 602 1.1 lukem { 603 1.49 ad u_int event, fflag; 604 1.49 ad struct kevent kev; 605 1.49 ad struct kqueue *kq; 606 1.49 ad int error; 607 1.1 lukem 608 1.1 lukem event = (u_int)hint & NOTE_PCTRLMASK; 609 1.49 ad kq = kn->kn_kq; 610 1.49 ad fflag = 0; 611 1.1 lukem 612 1.49 ad /* If the user is interested in this event, record it. */ 613 1.1 lukem if (kn->kn_sfflags & event) 614 1.49 ad fflag |= event; 615 1.1 lukem 616 1.1 lukem if (event == NOTE_EXIT) { 617 1.83 christos struct proc *p = kn->kn_obj; 618 1.83 christos 619 1.83 christos if (p != NULL) 620 1.86 christos kn->kn_data = P_WAITSTATUS(p); 621 1.3 jdolecek /* 622 1.49 ad * Process is gone, so flag the event as finished. 623 1.49 ad * 624 1.3 jdolecek * Detach the knote from watched process and mark 625 1.3 jdolecek * it as such. We can't leave this to kqueue_scan(), 626 1.3 jdolecek * since the process might not exist by then. And we 627 1.3 jdolecek * have to do this now, since psignal KNOTE() is called 628 1.3 jdolecek * also for zombies and we might end up reading freed 629 1.3 jdolecek * memory if the kevent would already be picked up 630 1.22 perry * and knote g/c'ed. 631 1.3 jdolecek */ 632 1.49 ad filt_procdetach(kn); 633 1.49 ad 634 1.49 ad mutex_spin_enter(&kq->kq_lock); 635 1.1 lukem kn->kn_status |= KN_DETACHED; 636 1.3 jdolecek /* Mark as ONESHOT, so that the knote it g/c'ed when read */ 637 1.22 perry kn->kn_flags |= (EV_EOF | EV_ONESHOT); 638 1.49 ad kn->kn_fflags |= fflag; 639 1.49 ad mutex_spin_exit(&kq->kq_lock); 640 1.49 ad 641 1.49 ad return 1; 642 1.1 lukem } 643 1.1 lukem 644 1.49 ad mutex_spin_enter(&kq->kq_lock); 645 1.1 lukem if ((event == NOTE_FORK) && (kn->kn_sfflags & NOTE_TRACK)) { 646 1.1 lukem /* 647 1.49 ad * Process forked, and user wants to track the new process, 648 1.49 ad * so attach a new knote to it, and immediately report an 649 1.49 ad * event with the parent's pid. Register knote with new 650 1.49 ad * process. 651 1.1 lukem */ 652 1.104 maxv memset(&kev, 0, sizeof(kev)); 653 1.1 lukem kev.ident = hint & NOTE_PDATAMASK; /* pid */ 654 1.1 lukem kev.filter = kn->kn_filter; 655 1.1 lukem kev.flags = kn->kn_flags | EV_ADD | EV_ENABLE | EV_FLAG1; 656 1.1 lukem kev.fflags = kn->kn_sfflags; 657 1.1 lukem kev.data = kn->kn_id; /* parent */ 658 1.1 lukem kev.udata = kn->kn_kevent.udata; /* preserve udata */ 659 1.49 ad mutex_spin_exit(&kq->kq_lock); 660 1.49 ad error = kqueue_register(kq, &kev); 661 1.49 ad mutex_spin_enter(&kq->kq_lock); 662 1.49 ad if (error != 0) 663 1.1 lukem kn->kn_fflags |= NOTE_TRACKERR; 664 1.1 lukem } 665 1.49 ad kn->kn_fflags |= fflag; 666 1.49 ad fflag = kn->kn_fflags; 667 1.49 ad mutex_spin_exit(&kq->kq_lock); 668 1.1 lukem 669 1.49 ad return fflag != 0; 670 1.8 jdolecek } 671 1.8 jdolecek 672 1.8 jdolecek static void 673 1.8 jdolecek filt_timerexpire(void *knx) 674 1.8 jdolecek { 675 1.8 jdolecek struct knote *kn = knx; 676 1.8 jdolecek int tticks; 677 1.8 jdolecek 678 1.49 ad mutex_enter(&kqueue_misc_lock); 679 1.8 jdolecek kn->kn_data++; 680 1.49 ad knote_activate(kn); 681 1.8 jdolecek if ((kn->kn_flags & EV_ONESHOT) == 0) { 682 1.8 jdolecek tticks = mstohz(kn->kn_sdata); 683 1.73 christos if (tticks <= 0) 684 1.73 christos tticks = 1; 685 1.39 ad callout_schedule((callout_t *)kn->kn_hook, tticks); 686 1.8 jdolecek } 687 1.49 ad mutex_exit(&kqueue_misc_lock); 688 1.8 jdolecek } 689 1.8 jdolecek 690 1.8 jdolecek /* 691 1.8 jdolecek * data contains amount of time to sleep, in milliseconds 692 1.22 perry */ 693 1.8 jdolecek static int 694 1.8 jdolecek filt_timerattach(struct knote *kn) 695 1.8 jdolecek { 696 1.39 ad callout_t *calloutp; 697 1.49 ad struct kqueue *kq; 698 1.8 jdolecek int tticks; 699 1.8 jdolecek 700 1.8 jdolecek tticks = mstohz(kn->kn_sdata); 701 1.8 jdolecek 702 1.8 jdolecek /* if the supplied value is under our resolution, use 1 tick */ 703 1.8 jdolecek if (tticks == 0) { 704 1.8 jdolecek if (kn->kn_sdata == 0) 705 1.49 ad return EINVAL; 706 1.8 jdolecek tticks = 1; 707 1.8 jdolecek } 708 1.8 jdolecek 709 1.49 ad if (atomic_inc_uint_nv(&kq_ncallouts) >= kq_calloutmax || 710 1.49 ad (calloutp = kmem_alloc(sizeof(*calloutp), KM_NOSLEEP)) == NULL) { 711 1.49 ad atomic_dec_uint(&kq_ncallouts); 712 1.49 ad return ENOMEM; 713 1.49 ad } 714 1.54 ad callout_init(calloutp, CALLOUT_MPSAFE); 715 1.49 ad 716 1.49 ad kq = kn->kn_kq; 717 1.49 ad mutex_spin_enter(&kq->kq_lock); 718 1.8 jdolecek kn->kn_flags |= EV_CLEAR; /* automatically set */ 719 1.49 ad kn->kn_hook = calloutp; 720 1.49 ad mutex_spin_exit(&kq->kq_lock); 721 1.49 ad 722 1.8 jdolecek callout_reset(calloutp, tticks, filt_timerexpire, kn); 723 1.8 jdolecek 724 1.8 jdolecek return (0); 725 1.8 jdolecek } 726 1.8 jdolecek 727 1.8 jdolecek static void 728 1.8 jdolecek filt_timerdetach(struct knote *kn) 729 1.8 jdolecek { 730 1.39 ad callout_t *calloutp; 731 1.103 christos struct kqueue *kq = kn->kn_kq; 732 1.103 christos 733 1.103 christos mutex_spin_enter(&kq->kq_lock); 734 1.103 christos /* prevent rescheduling when we expire */ 735 1.103 christos kn->kn_flags |= EV_ONESHOT; 736 1.103 christos mutex_spin_exit(&kq->kq_lock); 737 1.8 jdolecek 738 1.39 ad calloutp = (callout_t *)kn->kn_hook; 739 1.55 ad callout_halt(calloutp, NULL); 740 1.39 ad callout_destroy(calloutp); 741 1.49 ad kmem_free(calloutp, sizeof(*calloutp)); 742 1.49 ad atomic_dec_uint(&kq_ncallouts); 743 1.8 jdolecek } 744 1.8 jdolecek 745 1.8 jdolecek static int 746 1.33 yamt filt_timer(struct knote *kn, long hint) 747 1.8 jdolecek { 748 1.49 ad int rv; 749 1.49 ad 750 1.49 ad mutex_enter(&kqueue_misc_lock); 751 1.49 ad rv = (kn->kn_data != 0); 752 1.49 ad mutex_exit(&kqueue_misc_lock); 753 1.49 ad 754 1.49 ad return rv; 755 1.1 lukem } 756 1.1 lukem 757 1.3 jdolecek /* 758 1.102 christos * Filter event method for EVFILT_FS. 759 1.102 christos */ 760 1.102 christos struct klist fs_klist = SLIST_HEAD_INITIALIZER(&fs_klist); 761 1.102 christos 762 1.102 christos static int 763 1.102 christos filt_fsattach(struct knote *kn) 764 1.102 christos { 765 1.102 christos 766 1.102 christos mutex_enter(&kqueue_misc_lock); 767 1.102 christos kn->kn_flags |= EV_CLEAR; 768 1.102 christos SLIST_INSERT_HEAD(&fs_klist, kn, kn_selnext); 769 1.102 christos mutex_exit(&kqueue_misc_lock); 770 1.102 christos 771 1.102 christos return 0; 772 1.102 christos } 773 1.102 christos 774 1.102 christos static void 775 1.102 christos filt_fsdetach(struct knote *kn) 776 1.102 christos { 777 1.102 christos 778 1.102 christos mutex_enter(&kqueue_misc_lock); 779 1.102 christos SLIST_REMOVE(&fs_klist, kn, knote, kn_selnext); 780 1.102 christos mutex_exit(&kqueue_misc_lock); 781 1.102 christos } 782 1.102 christos 783 1.102 christos static int 784 1.102 christos filt_fs(struct knote *kn, long hint) 785 1.102 christos { 786 1.102 christos int rv; 787 1.102 christos 788 1.102 christos mutex_enter(&kqueue_misc_lock); 789 1.102 christos kn->kn_fflags |= hint; 790 1.102 christos rv = (kn->kn_fflags != 0); 791 1.102 christos mutex_exit(&kqueue_misc_lock); 792 1.102 christos 793 1.102 christos return rv; 794 1.102 christos } 795 1.102 christos 796 1.108 christos static int 797 1.108 christos filt_userattach(struct knote *kn) 798 1.108 christos { 799 1.108 christos struct kqueue *kq = kn->kn_kq; 800 1.108 christos 801 1.108 christos /* 802 1.108 christos * EVFILT_USER knotes are not attached to anything in the kernel. 803 1.108 christos */ 804 1.108 christos mutex_spin_enter(&kq->kq_lock); 805 1.108 christos kn->kn_hook = NULL; 806 1.108 christos if (kn->kn_fflags & NOTE_TRIGGER) 807 1.108 christos kn->kn_hookid = 1; 808 1.108 christos else 809 1.108 christos kn->kn_hookid = 0; 810 1.108 christos mutex_spin_exit(&kq->kq_lock); 811 1.108 christos return (0); 812 1.108 christos } 813 1.108 christos 814 1.108 christos static void 815 1.108 christos filt_userdetach(struct knote *kn) 816 1.108 christos { 817 1.108 christos 818 1.108 christos /* 819 1.108 christos * EVFILT_USER knotes are not attached to anything in the kernel. 820 1.108 christos */ 821 1.108 christos } 822 1.108 christos 823 1.108 christos static int 824 1.108 christos filt_user(struct knote *kn, long hint) 825 1.108 christos { 826 1.108 christos struct kqueue *kq = kn->kn_kq; 827 1.108 christos int hookid; 828 1.108 christos 829 1.108 christos mutex_spin_enter(&kq->kq_lock); 830 1.108 christos hookid = kn->kn_hookid; 831 1.108 christos mutex_spin_exit(&kq->kq_lock); 832 1.108 christos 833 1.108 christos return hookid; 834 1.108 christos } 835 1.108 christos 836 1.108 christos static void 837 1.108 christos filt_usertouch(struct knote *kn, struct kevent *kev, long type) 838 1.108 christos { 839 1.108 christos int ffctrl; 840 1.108 christos 841 1.117 skrll KASSERT(mutex_owned(&kn->kn_kq->kq_lock)); 842 1.116 jdolecek 843 1.108 christos switch (type) { 844 1.108 christos case EVENT_REGISTER: 845 1.108 christos if (kev->fflags & NOTE_TRIGGER) 846 1.108 christos kn->kn_hookid = 1; 847 1.108 christos 848 1.108 christos ffctrl = kev->fflags & NOTE_FFCTRLMASK; 849 1.108 christos kev->fflags &= NOTE_FFLAGSMASK; 850 1.108 christos switch (ffctrl) { 851 1.108 christos case NOTE_FFNOP: 852 1.108 christos break; 853 1.108 christos 854 1.108 christos case NOTE_FFAND: 855 1.108 christos kn->kn_sfflags &= kev->fflags; 856 1.108 christos break; 857 1.108 christos 858 1.108 christos case NOTE_FFOR: 859 1.108 christos kn->kn_sfflags |= kev->fflags; 860 1.108 christos break; 861 1.108 christos 862 1.108 christos case NOTE_FFCOPY: 863 1.108 christos kn->kn_sfflags = kev->fflags; 864 1.108 christos break; 865 1.108 christos 866 1.108 christos default: 867 1.108 christos /* XXX Return error? */ 868 1.108 christos break; 869 1.108 christos } 870 1.108 christos kn->kn_sdata = kev->data; 871 1.108 christos if (kev->flags & EV_CLEAR) { 872 1.108 christos kn->kn_hookid = 0; 873 1.108 christos kn->kn_data = 0; 874 1.108 christos kn->kn_fflags = 0; 875 1.108 christos } 876 1.108 christos break; 877 1.108 christos 878 1.108 christos case EVENT_PROCESS: 879 1.108 christos *kev = kn->kn_kevent; 880 1.108 christos kev->fflags = kn->kn_sfflags; 881 1.108 christos kev->data = kn->kn_sdata; 882 1.108 christos if (kn->kn_flags & EV_CLEAR) { 883 1.108 christos kn->kn_hookid = 0; 884 1.108 christos kn->kn_data = 0; 885 1.108 christos kn->kn_fflags = 0; 886 1.108 christos } 887 1.108 christos break; 888 1.108 christos 889 1.108 christos default: 890 1.108 christos panic("filt_usertouch() - invalid type (%ld)", type); 891 1.108 christos break; 892 1.108 christos } 893 1.108 christos } 894 1.108 christos 895 1.102 christos /* 896 1.3 jdolecek * filt_seltrue: 897 1.3 jdolecek * 898 1.3 jdolecek * This filter "event" routine simulates seltrue(). 899 1.3 jdolecek */ 900 1.1 lukem int 901 1.33 yamt filt_seltrue(struct knote *kn, long hint) 902 1.1 lukem { 903 1.1 lukem 904 1.3 jdolecek /* 905 1.3 jdolecek * We don't know how much data can be read/written, 906 1.3 jdolecek * but we know that it *can* be. This is about as 907 1.3 jdolecek * good as select/poll does as well. 908 1.3 jdolecek */ 909 1.3 jdolecek kn->kn_data = 0; 910 1.3 jdolecek return (1); 911 1.3 jdolecek } 912 1.3 jdolecek 913 1.3 jdolecek /* 914 1.3 jdolecek * This provides full kqfilter entry for device switch tables, which 915 1.3 jdolecek * has same effect as filter using filt_seltrue() as filter method. 916 1.3 jdolecek */ 917 1.3 jdolecek static void 918 1.33 yamt filt_seltruedetach(struct knote *kn) 919 1.3 jdolecek { 920 1.3 jdolecek /* Nothing to do */ 921 1.3 jdolecek } 922 1.3 jdolecek 923 1.96 maya const struct filterops seltrue_filtops = { 924 1.96 maya .f_isfd = 1, 925 1.96 maya .f_attach = NULL, 926 1.96 maya .f_detach = filt_seltruedetach, 927 1.96 maya .f_event = filt_seltrue, 928 1.96 maya }; 929 1.3 jdolecek 930 1.3 jdolecek int 931 1.33 yamt seltrue_kqfilter(dev_t dev, struct knote *kn) 932 1.3 jdolecek { 933 1.3 jdolecek switch (kn->kn_filter) { 934 1.3 jdolecek case EVFILT_READ: 935 1.3 jdolecek case EVFILT_WRITE: 936 1.3 jdolecek kn->kn_fop = &seltrue_filtops; 937 1.3 jdolecek break; 938 1.3 jdolecek default: 939 1.43 pooka return (EINVAL); 940 1.3 jdolecek } 941 1.3 jdolecek 942 1.3 jdolecek /* Nothing more to do */ 943 1.3 jdolecek return (0); 944 1.3 jdolecek } 945 1.3 jdolecek 946 1.3 jdolecek /* 947 1.3 jdolecek * kqueue(2) system call. 948 1.3 jdolecek */ 949 1.72 christos static int 950 1.72 christos kqueue1(struct lwp *l, int flags, register_t *retval) 951 1.3 jdolecek { 952 1.49 ad struct kqueue *kq; 953 1.49 ad file_t *fp; 954 1.49 ad int fd, error; 955 1.3 jdolecek 956 1.49 ad if ((error = fd_allocfile(&fp, &fd)) != 0) 957 1.49 ad return error; 958 1.75 christos fp->f_flag = FREAD | FWRITE | (flags & (FNONBLOCK|FNOSIGPIPE)); 959 1.1 lukem fp->f_type = DTYPE_KQUEUE; 960 1.1 lukem fp->f_ops = &kqueueops; 961 1.49 ad kq = kmem_zalloc(sizeof(*kq), KM_SLEEP); 962 1.49 ad mutex_init(&kq->kq_lock, MUTEX_DEFAULT, IPL_SCHED); 963 1.49 ad cv_init(&kq->kq_cv, "kqueue"); 964 1.49 ad selinit(&kq->kq_sel); 965 1.1 lukem TAILQ_INIT(&kq->kq_head); 966 1.82 matt fp->f_kqueue = kq; 967 1.3 jdolecek *retval = fd; 968 1.49 ad kq->kq_fdp = curlwp->l_fd; 969 1.72 christos fd_set_exclose(l, fd, (flags & O_CLOEXEC) != 0); 970 1.49 ad fd_affix(curproc, fp, fd); 971 1.49 ad return error; 972 1.1 lukem } 973 1.1 lukem 974 1.3 jdolecek /* 975 1.72 christos * kqueue(2) system call. 976 1.72 christos */ 977 1.72 christos int 978 1.72 christos sys_kqueue(struct lwp *l, const void *v, register_t *retval) 979 1.72 christos { 980 1.72 christos return kqueue1(l, 0, retval); 981 1.72 christos } 982 1.72 christos 983 1.72 christos int 984 1.72 christos sys_kqueue1(struct lwp *l, const struct sys_kqueue1_args *uap, 985 1.72 christos register_t *retval) 986 1.72 christos { 987 1.72 christos /* { 988 1.72 christos syscallarg(int) flags; 989 1.72 christos } */ 990 1.72 christos return kqueue1(l, SCARG(uap, flags), retval); 991 1.72 christos } 992 1.72 christos 993 1.72 christos /* 994 1.3 jdolecek * kevent(2) system call. 995 1.3 jdolecek */ 996 1.61 christos int 997 1.81 matt kevent_fetch_changes(void *ctx, const struct kevent *changelist, 998 1.61 christos struct kevent *changes, size_t index, int n) 999 1.24 cube { 1000 1.49 ad 1001 1.24 cube return copyin(changelist + index, changes, n * sizeof(*changes)); 1002 1.24 cube } 1003 1.24 cube 1004 1.61 christos int 1005 1.81 matt kevent_put_events(void *ctx, struct kevent *events, 1006 1.61 christos struct kevent *eventlist, size_t index, int n) 1007 1.24 cube { 1008 1.49 ad 1009 1.24 cube return copyout(events, eventlist + index, n * sizeof(*events)); 1010 1.24 cube } 1011 1.24 cube 1012 1.24 cube static const struct kevent_ops kevent_native_ops = { 1013 1.60 gmcgarry .keo_private = NULL, 1014 1.60 gmcgarry .keo_fetch_timeout = copyin, 1015 1.60 gmcgarry .keo_fetch_changes = kevent_fetch_changes, 1016 1.60 gmcgarry .keo_put_events = kevent_put_events, 1017 1.24 cube }; 1018 1.24 cube 1019 1.1 lukem int 1020 1.61 christos sys___kevent50(struct lwp *l, const struct sys___kevent50_args *uap, 1021 1.61 christos register_t *retval) 1022 1.1 lukem { 1023 1.44 dsl /* { 1024 1.3 jdolecek syscallarg(int) fd; 1025 1.3 jdolecek syscallarg(const struct kevent *) changelist; 1026 1.3 jdolecek syscallarg(size_t) nchanges; 1027 1.3 jdolecek syscallarg(struct kevent *) eventlist; 1028 1.3 jdolecek syscallarg(size_t) nevents; 1029 1.3 jdolecek syscallarg(const struct timespec *) timeout; 1030 1.44 dsl } */ 1031 1.24 cube 1032 1.49 ad return kevent1(retval, SCARG(uap, fd), SCARG(uap, changelist), 1033 1.24 cube SCARG(uap, nchanges), SCARG(uap, eventlist), SCARG(uap, nevents), 1034 1.24 cube SCARG(uap, timeout), &kevent_native_ops); 1035 1.24 cube } 1036 1.24 cube 1037 1.24 cube int 1038 1.49 ad kevent1(register_t *retval, int fd, 1039 1.49 ad const struct kevent *changelist, size_t nchanges, 1040 1.49 ad struct kevent *eventlist, size_t nevents, 1041 1.49 ad const struct timespec *timeout, 1042 1.49 ad const struct kevent_ops *keops) 1043 1.24 cube { 1044 1.49 ad struct kevent *kevp; 1045 1.49 ad struct kqueue *kq; 1046 1.3 jdolecek struct timespec ts; 1047 1.49 ad size_t i, n, ichange; 1048 1.49 ad int nerrors, error; 1049 1.80 maxv struct kevent kevbuf[KQ_NEVENTS]; /* approx 300 bytes on 64-bit */ 1050 1.49 ad file_t *fp; 1051 1.3 jdolecek 1052 1.3 jdolecek /* check that we're dealing with a kq */ 1053 1.49 ad fp = fd_getfile(fd); 1054 1.10 pk if (fp == NULL) 1055 1.1 lukem return (EBADF); 1056 1.10 pk 1057 1.10 pk if (fp->f_type != DTYPE_KQUEUE) { 1058 1.49 ad fd_putfile(fd); 1059 1.10 pk return (EBADF); 1060 1.10 pk } 1061 1.1 lukem 1062 1.24 cube if (timeout != NULL) { 1063 1.24 cube error = (*keops->keo_fetch_timeout)(timeout, &ts, sizeof(ts)); 1064 1.1 lukem if (error) 1065 1.1 lukem goto done; 1066 1.24 cube timeout = &ts; 1067 1.1 lukem } 1068 1.1 lukem 1069 1.82 matt kq = fp->f_kqueue; 1070 1.1 lukem nerrors = 0; 1071 1.24 cube ichange = 0; 1072 1.1 lukem 1073 1.3 jdolecek /* traverse list of events to register */ 1074 1.24 cube while (nchanges > 0) { 1075 1.49 ad n = MIN(nchanges, __arraycount(kevbuf)); 1076 1.24 cube error = (*keops->keo_fetch_changes)(keops->keo_private, 1077 1.49 ad changelist, kevbuf, ichange, n); 1078 1.1 lukem if (error) 1079 1.1 lukem goto done; 1080 1.1 lukem for (i = 0; i < n; i++) { 1081 1.49 ad kevp = &kevbuf[i]; 1082 1.1 lukem kevp->flags &= ~EV_SYSFLAGS; 1083 1.3 jdolecek /* register each knote */ 1084 1.49 ad error = kqueue_register(kq, kevp); 1085 1.89 abhinav if (!error && !(kevp->flags & EV_RECEIPT)) 1086 1.89 abhinav continue; 1087 1.89 abhinav if (nevents == 0) 1088 1.89 abhinav goto done; 1089 1.89 abhinav kevp->flags = EV_ERROR; 1090 1.89 abhinav kevp->data = error; 1091 1.89 abhinav error = (*keops->keo_put_events) 1092 1.89 abhinav (keops->keo_private, kevp, 1093 1.89 abhinav eventlist, nerrors, 1); 1094 1.89 abhinav if (error) 1095 1.89 abhinav goto done; 1096 1.89 abhinav nevents--; 1097 1.89 abhinav nerrors++; 1098 1.1 lukem } 1099 1.24 cube nchanges -= n; /* update the results */ 1100 1.24 cube ichange += n; 1101 1.1 lukem } 1102 1.1 lukem if (nerrors) { 1103 1.3 jdolecek *retval = nerrors; 1104 1.1 lukem error = 0; 1105 1.1 lukem goto done; 1106 1.1 lukem } 1107 1.1 lukem 1108 1.3 jdolecek /* actually scan through the events */ 1109 1.49 ad error = kqueue_scan(fp, nevents, eventlist, timeout, retval, keops, 1110 1.49 ad kevbuf, __arraycount(kevbuf)); 1111 1.3 jdolecek done: 1112 1.49 ad fd_putfile(fd); 1113 1.1 lukem return (error); 1114 1.1 lukem } 1115 1.1 lukem 1116 1.3 jdolecek /* 1117 1.3 jdolecek * Register a given kevent kev onto the kqueue 1118 1.3 jdolecek */ 1119 1.49 ad static int 1120 1.49 ad kqueue_register(struct kqueue *kq, struct kevent *kev) 1121 1.1 lukem { 1122 1.49 ad struct kfilter *kfilter; 1123 1.49 ad filedesc_t *fdp; 1124 1.49 ad file_t *fp; 1125 1.49 ad fdfile_t *ff; 1126 1.49 ad struct knote *kn, *newkn; 1127 1.49 ad struct klist *list; 1128 1.49 ad int error, fd, rv; 1129 1.3 jdolecek 1130 1.3 jdolecek fdp = kq->kq_fdp; 1131 1.3 jdolecek fp = NULL; 1132 1.3 jdolecek kn = NULL; 1133 1.3 jdolecek error = 0; 1134 1.49 ad fd = 0; 1135 1.49 ad 1136 1.49 ad newkn = kmem_zalloc(sizeof(*newkn), KM_SLEEP); 1137 1.49 ad 1138 1.49 ad rw_enter(&kqueue_filter_lock, RW_READER); 1139 1.3 jdolecek kfilter = kfilter_byfilter(kev->filter); 1140 1.3 jdolecek if (kfilter == NULL || kfilter->filtops == NULL) { 1141 1.3 jdolecek /* filter not found nor implemented */ 1142 1.49 ad rw_exit(&kqueue_filter_lock); 1143 1.49 ad kmem_free(newkn, sizeof(*newkn)); 1144 1.1 lukem return (EINVAL); 1145 1.1 lukem } 1146 1.1 lukem 1147 1.3 jdolecek /* search if knote already exists */ 1148 1.3 jdolecek if (kfilter->filtops->f_isfd) { 1149 1.3 jdolecek /* monitoring a file descriptor */ 1150 1.87 christos /* validate descriptor */ 1151 1.88 christos if (kev->ident > INT_MAX 1152 1.88 christos || (fp = fd_getfile(fd = kev->ident)) == NULL) { 1153 1.49 ad rw_exit(&kqueue_filter_lock); 1154 1.49 ad kmem_free(newkn, sizeof(*newkn)); 1155 1.49 ad return EBADF; 1156 1.49 ad } 1157 1.74 rmind mutex_enter(&fdp->fd_lock); 1158 1.65 ad ff = fdp->fd_dt->dt_ff[fd]; 1159 1.98 christos if (ff->ff_refcnt & FR_CLOSING) { 1160 1.98 christos error = EBADF; 1161 1.98 christos goto doneunlock; 1162 1.98 christos } 1163 1.49 ad if (fd <= fdp->fd_lastkqfile) { 1164 1.49 ad SLIST_FOREACH(kn, &ff->ff_knlist, kn_link) { 1165 1.1 lukem if (kq == kn->kn_kq && 1166 1.1 lukem kev->filter == kn->kn_filter) 1167 1.1 lukem break; 1168 1.49 ad } 1169 1.1 lukem } 1170 1.1 lukem } else { 1171 1.3 jdolecek /* 1172 1.3 jdolecek * not monitoring a file descriptor, so 1173 1.3 jdolecek * lookup knotes in internal hash table 1174 1.3 jdolecek */ 1175 1.74 rmind mutex_enter(&fdp->fd_lock); 1176 1.1 lukem if (fdp->fd_knhashmask != 0) { 1177 1.1 lukem list = &fdp->fd_knhash[ 1178 1.1 lukem KN_HASH((u_long)kev->ident, fdp->fd_knhashmask)]; 1179 1.49 ad SLIST_FOREACH(kn, list, kn_link) { 1180 1.1 lukem if (kev->ident == kn->kn_id && 1181 1.1 lukem kq == kn->kn_kq && 1182 1.1 lukem kev->filter == kn->kn_filter) 1183 1.1 lukem break; 1184 1.49 ad } 1185 1.1 lukem } 1186 1.1 lukem } 1187 1.1 lukem 1188 1.1 lukem /* 1189 1.1 lukem * kn now contains the matching knote, or NULL if no match 1190 1.1 lukem */ 1191 1.108 christos if (kn == NULL) { 1192 1.108 christos if (kev->flags & EV_ADD) { 1193 1.3 jdolecek /* create new knote */ 1194 1.49 ad kn = newkn; 1195 1.49 ad newkn = NULL; 1196 1.49 ad kn->kn_obj = fp; 1197 1.79 christos kn->kn_id = kev->ident; 1198 1.1 lukem kn->kn_kq = kq; 1199 1.3 jdolecek kn->kn_fop = kfilter->filtops; 1200 1.49 ad kn->kn_kfilter = kfilter; 1201 1.49 ad kn->kn_sfflags = kev->fflags; 1202 1.49 ad kn->kn_sdata = kev->data; 1203 1.49 ad kev->fflags = 0; 1204 1.49 ad kev->data = 0; 1205 1.49 ad kn->kn_kevent = *kev; 1206 1.1 lukem 1207 1.85 christos KASSERT(kn->kn_fop != NULL); 1208 1.1 lukem /* 1209 1.1 lukem * apply reference count to knote structure, and 1210 1.1 lukem * do not release it at the end of this routine. 1211 1.1 lukem */ 1212 1.1 lukem fp = NULL; 1213 1.1 lukem 1214 1.49 ad if (!kn->kn_fop->f_isfd) { 1215 1.49 ad /* 1216 1.49 ad * If knote is not on an fd, store on 1217 1.49 ad * internal hash table. 1218 1.49 ad */ 1219 1.49 ad if (fdp->fd_knhashmask == 0) { 1220 1.49 ad /* XXXAD can block with fd_lock held */ 1221 1.49 ad fdp->fd_knhash = hashinit(KN_HASHSIZE, 1222 1.59 ad HASH_LIST, true, 1223 1.49 ad &fdp->fd_knhashmask); 1224 1.49 ad } 1225 1.49 ad list = &fdp->fd_knhash[KN_HASH(kn->kn_id, 1226 1.49 ad fdp->fd_knhashmask)]; 1227 1.49 ad } else { 1228 1.49 ad /* Otherwise, knote is on an fd. */ 1229 1.49 ad list = (struct klist *) 1230 1.65 ad &fdp->fd_dt->dt_ff[kn->kn_id]->ff_knlist; 1231 1.49 ad if ((int)kn->kn_id > fdp->fd_lastkqfile) 1232 1.49 ad fdp->fd_lastkqfile = kn->kn_id; 1233 1.49 ad } 1234 1.49 ad SLIST_INSERT_HEAD(list, kn, kn_link); 1235 1.1 lukem 1236 1.49 ad KERNEL_LOCK(1, NULL); /* XXXSMP */ 1237 1.49 ad error = (*kfilter->filtops->f_attach)(kn); 1238 1.49 ad KERNEL_UNLOCK_ONE(NULL); /* XXXSMP */ 1239 1.49 ad if (error != 0) { 1240 1.100 christos #ifdef DEBUG 1241 1.105 christos struct proc *p = curlwp->l_proc; 1242 1.101 christos const file_t *ft = kn->kn_obj; 1243 1.105 christos printf("%s: %s[%d]: event type %d not " 1244 1.105 christos "supported for file type %d/%s " 1245 1.105 christos "(error %d)\n", __func__, 1246 1.105 christos p->p_comm, p->p_pid, 1247 1.101 christos kn->kn_filter, ft ? ft->f_type : -1, 1248 1.101 christos ft ? ft->f_ops->fo_name : "?", error); 1249 1.100 christos #endif 1250 1.100 christos 1251 1.49 ad /* knote_detach() drops fdp->fd_lock */ 1252 1.49 ad knote_detach(kn, fdp, false); 1253 1.1 lukem goto done; 1254 1.1 lukem } 1255 1.49 ad atomic_inc_uint(&kfilter->refcnt); 1256 1.108 christos goto done_ev_add; 1257 1.1 lukem } else { 1258 1.108 christos /* No matching knote and the EV_ADD flag is not set. */ 1259 1.108 christos error = ENOENT; 1260 1.108 christos goto doneunlock; 1261 1.1 lukem } 1262 1.108 christos } 1263 1.108 christos 1264 1.108 christos if (kev->flags & EV_DELETE) { 1265 1.108 christos /* knote_detach() drops fdp->fd_lock */ 1266 1.108 christos knote_detach(kn, fdp, true); 1267 1.108 christos goto done; 1268 1.108 christos } 1269 1.108 christos 1270 1.108 christos /* 1271 1.108 christos * The user may change some filter values after the 1272 1.108 christos * initial EV_ADD, but doing so will not reset any 1273 1.108 christos * filter which have already been triggered. 1274 1.108 christos */ 1275 1.108 christos kn->kn_kevent.udata = kev->udata; 1276 1.108 christos KASSERT(kn->kn_fop != NULL); 1277 1.108 christos if (!kn->kn_fop->f_isfd && kn->kn_fop->f_touch != NULL) { 1278 1.116 jdolecek mutex_spin_enter(&kq->kq_lock); 1279 1.108 christos (*kn->kn_fop->f_touch)(kn, kev, EVENT_REGISTER); 1280 1.116 jdolecek mutex_spin_exit(&kq->kq_lock); 1281 1.49 ad } else { 1282 1.108 christos kn->kn_sfflags = kev->fflags; 1283 1.108 christos kn->kn_sdata = kev->data; 1284 1.1 lukem } 1285 1.1 lukem 1286 1.108 christos /* 1287 1.108 christos * We can get here if we are trying to attach 1288 1.108 christos * an event to a file descriptor that does not 1289 1.108 christos * support events, and the attach routine is 1290 1.108 christos * broken and does not return an error. 1291 1.108 christos */ 1292 1.108 christos done_ev_add: 1293 1.108 christos KASSERT(kn->kn_fop != NULL); 1294 1.108 christos KASSERT(kn->kn_fop->f_event != NULL); 1295 1.108 christos KERNEL_LOCK(1, NULL); /* XXXSMP */ 1296 1.108 christos rv = (*kn->kn_fop->f_event)(kn, 0); 1297 1.108 christos KERNEL_UNLOCK_ONE(NULL); /* XXXSMP */ 1298 1.108 christos if (rv) 1299 1.108 christos knote_activate(kn); 1300 1.108 christos 1301 1.3 jdolecek /* disable knote */ 1302 1.49 ad if ((kev->flags & EV_DISABLE)) { 1303 1.49 ad mutex_spin_enter(&kq->kq_lock); 1304 1.49 ad if ((kn->kn_status & KN_DISABLED) == 0) 1305 1.49 ad kn->kn_status |= KN_DISABLED; 1306 1.49 ad mutex_spin_exit(&kq->kq_lock); 1307 1.1 lukem } 1308 1.1 lukem 1309 1.3 jdolecek /* enable knote */ 1310 1.49 ad if ((kev->flags & EV_ENABLE)) { 1311 1.49 ad knote_enqueue(kn); 1312 1.1 lukem } 1313 1.98 christos doneunlock: 1314 1.49 ad mutex_exit(&fdp->fd_lock); 1315 1.3 jdolecek done: 1316 1.49 ad rw_exit(&kqueue_filter_lock); 1317 1.49 ad if (newkn != NULL) 1318 1.49 ad kmem_free(newkn, sizeof(*newkn)); 1319 1.1 lukem if (fp != NULL) 1320 1.49 ad fd_putfile(fd); 1321 1.1 lukem return (error); 1322 1.1 lukem } 1323 1.1 lukem 1324 1.52 yamt #if defined(DEBUG) 1325 1.94 christos #define KN_FMT(buf, kn) \ 1326 1.94 christos (snprintb((buf), sizeof(buf), __KN_FLAG_BITS, (kn)->kn_status), buf) 1327 1.94 christos 1328 1.52 yamt static void 1329 1.94 christos kqueue_check(const char *func, size_t line, const struct kqueue *kq) 1330 1.52 yamt { 1331 1.52 yamt const struct knote *kn; 1332 1.117.4.1 thorpej u_int count; 1333 1.52 yamt int nmarker; 1334 1.94 christos char buf[128]; 1335 1.52 yamt 1336 1.52 yamt KASSERT(mutex_owned(&kq->kq_lock)); 1337 1.117.4.1 thorpej KASSERT(KQ_COUNT(kq) < UINT_MAX / 2); 1338 1.52 yamt 1339 1.52 yamt count = 0; 1340 1.52 yamt nmarker = 0; 1341 1.52 yamt TAILQ_FOREACH(kn, &kq->kq_head, kn_tqe) { 1342 1.52 yamt if ((kn->kn_status & (KN_MARKER | KN_QUEUED)) == 0) { 1343 1.94 christos panic("%s,%zu: kq=%p kn=%p !(MARKER|QUEUED) %s", 1344 1.94 christos func, line, kq, kn, KN_FMT(buf, kn)); 1345 1.52 yamt } 1346 1.52 yamt if ((kn->kn_status & KN_MARKER) == 0) { 1347 1.52 yamt if (kn->kn_kq != kq) { 1348 1.94 christos panic("%s,%zu: kq=%p kn(%p) != kn->kq(%p): %s", 1349 1.94 christos func, line, kq, kn, kn->kn_kq, 1350 1.94 christos KN_FMT(buf, kn)); 1351 1.52 yamt } 1352 1.52 yamt if ((kn->kn_status & KN_ACTIVE) == 0) { 1353 1.94 christos panic("%s,%zu: kq=%p kn=%p: !ACTIVE %s", 1354 1.94 christos func, line, kq, kn, KN_FMT(buf, kn)); 1355 1.52 yamt } 1356 1.52 yamt count++; 1357 1.117.4.1 thorpej if (count > KQ_COUNT(kq)) { 1358 1.112 jdolecek panic("%s,%zu: kq=%p kq->kq_count(%d) != " 1359 1.112 jdolecek "count(%d), nmarker=%d", 1360 1.117.4.1 thorpej func, line, kq, KQ_COUNT(kq), count, 1361 1.112 jdolecek nmarker); 1362 1.52 yamt } 1363 1.52 yamt } else { 1364 1.52 yamt nmarker++; 1365 1.52 yamt } 1366 1.52 yamt } 1367 1.52 yamt } 1368 1.94 christos #define kq_check(a) kqueue_check(__func__, __LINE__, (a)) 1369 1.52 yamt #else /* defined(DEBUG) */ 1370 1.52 yamt #define kq_check(a) /* nothing */ 1371 1.52 yamt #endif /* defined(DEBUG) */ 1372 1.52 yamt 1373 1.117.4.1 thorpej static void 1374 1.117.4.1 thorpej kqueue_restart(file_t *fp) 1375 1.117.4.1 thorpej { 1376 1.117.4.1 thorpej struct kqueue *kq = fp->f_kqueue; 1377 1.117.4.1 thorpej KASSERT(kq != NULL); 1378 1.117.4.1 thorpej 1379 1.117.4.1 thorpej mutex_spin_enter(&kq->kq_lock); 1380 1.117.4.1 thorpej kq->kq_count |= KQ_RESTART; 1381 1.117.4.1 thorpej cv_broadcast(&kq->kq_cv); 1382 1.117.4.1 thorpej mutex_spin_exit(&kq->kq_lock); 1383 1.117.4.1 thorpej } 1384 1.117.4.1 thorpej 1385 1.3 jdolecek /* 1386 1.3 jdolecek * Scan through the list of events on fp (for a maximum of maxevents), 1387 1.3 jdolecek * returning the results in to ulistp. Timeout is determined by tsp; if 1388 1.3 jdolecek * NULL, wait indefinitely, if 0 valued, perform a poll, otherwise wait 1389 1.3 jdolecek * as appropriate. 1390 1.3 jdolecek */ 1391 1.1 lukem static int 1392 1.49 ad kqueue_scan(file_t *fp, size_t maxevents, struct kevent *ulistp, 1393 1.49 ad const struct timespec *tsp, register_t *retval, 1394 1.49 ad const struct kevent_ops *keops, struct kevent *kevbuf, 1395 1.49 ad size_t kevcnt) 1396 1.1 lukem { 1397 1.3 jdolecek struct kqueue *kq; 1398 1.3 jdolecek struct kevent *kevp; 1399 1.62 christos struct timespec ats, sleepts; 1400 1.85 christos struct knote *kn, *marker, morker; 1401 1.24 cube size_t count, nkev, nevents; 1402 1.111 jdolecek int timeout, error, touch, rv, influx; 1403 1.49 ad filedesc_t *fdp; 1404 1.1 lukem 1405 1.49 ad fdp = curlwp->l_fd; 1406 1.82 matt kq = fp->f_kqueue; 1407 1.1 lukem count = maxevents; 1408 1.24 cube nkev = nevents = error = 0; 1409 1.49 ad if (count == 0) { 1410 1.49 ad *retval = 0; 1411 1.49 ad return 0; 1412 1.49 ad } 1413 1.1 lukem 1414 1.9 jdolecek if (tsp) { /* timeout supplied */ 1415 1.63 christos ats = *tsp; 1416 1.62 christos if (inittimeleft(&ats, &sleepts) == -1) { 1417 1.49 ad *retval = maxevents; 1418 1.49 ad return EINVAL; 1419 1.1 lukem } 1420 1.62 christos timeout = tstohz(&ats); 1421 1.9 jdolecek if (timeout <= 0) 1422 1.29 kardel timeout = -1; /* do poll */ 1423 1.1 lukem } else { 1424 1.9 jdolecek /* no timeout, wait forever */ 1425 1.1 lukem timeout = 0; 1426 1.93 riastrad } 1427 1.1 lukem 1428 1.85 christos memset(&morker, 0, sizeof(morker)); 1429 1.85 christos marker = &morker; 1430 1.49 ad marker->kn_status = KN_MARKER; 1431 1.49 ad mutex_spin_enter(&kq->kq_lock); 1432 1.3 jdolecek retry: 1433 1.49 ad kevp = kevbuf; 1434 1.117.4.1 thorpej if (KQ_COUNT(kq) == 0) { 1435 1.49 ad if (timeout >= 0) { 1436 1.49 ad error = cv_timedwait_sig(&kq->kq_cv, 1437 1.49 ad &kq->kq_lock, timeout); 1438 1.49 ad if (error == 0) { 1439 1.117.4.1 thorpej if (KQ_COUNT(kq) == 0 && 1440 1.117.4.1 thorpej (kq->kq_count & KQ_RESTART)) { 1441 1.117.4.1 thorpej /* return to clear file reference */ 1442 1.117.4.1 thorpej error = ERESTART; 1443 1.117.4.1 thorpej } else if (tsp == NULL || (timeout = 1444 1.117.4.1 thorpej gettimeleft(&ats, &sleepts)) > 0) { 1445 1.49 ad goto retry; 1446 1.117.4.1 thorpej } 1447 1.49 ad } else { 1448 1.49 ad /* don't restart after signals... */ 1449 1.49 ad if (error == ERESTART) 1450 1.49 ad error = EINTR; 1451 1.49 ad if (error == EWOULDBLOCK) 1452 1.49 ad error = 0; 1453 1.49 ad } 1454 1.1 lukem } 1455 1.92 christos mutex_spin_exit(&kq->kq_lock); 1456 1.110 jdolecek goto done; 1457 1.110 jdolecek } 1458 1.110 jdolecek 1459 1.110 jdolecek /* mark end of knote list */ 1460 1.110 jdolecek TAILQ_INSERT_TAIL(&kq->kq_head, marker, kn_tqe); 1461 1.111 jdolecek influx = 0; 1462 1.1 lukem 1463 1.110 jdolecek /* 1464 1.110 jdolecek * Acquire the fdp->fd_lock interlock to avoid races with 1465 1.110 jdolecek * file creation/destruction from other threads. 1466 1.110 jdolecek */ 1467 1.111 jdolecek relock: 1468 1.110 jdolecek mutex_spin_exit(&kq->kq_lock); 1469 1.110 jdolecek mutex_enter(&fdp->fd_lock); 1470 1.110 jdolecek mutex_spin_enter(&kq->kq_lock); 1471 1.92 christos 1472 1.110 jdolecek while (count != 0) { 1473 1.110 jdolecek kn = TAILQ_FIRST(&kq->kq_head); /* get next knote */ 1474 1.111 jdolecek 1475 1.111 jdolecek if ((kn->kn_status & KN_MARKER) != 0 && kn != marker) { 1476 1.111 jdolecek if (influx) { 1477 1.111 jdolecek influx = 0; 1478 1.111 jdolecek KQ_FLUX_WAKEUP(kq); 1479 1.111 jdolecek } 1480 1.111 jdolecek mutex_exit(&fdp->fd_lock); 1481 1.114 jdolecek (void)cv_wait(&kq->kq_cv, &kq->kq_lock); 1482 1.111 jdolecek goto relock; 1483 1.111 jdolecek } 1484 1.111 jdolecek 1485 1.111 jdolecek TAILQ_REMOVE(&kq->kq_head, kn, kn_tqe); 1486 1.111 jdolecek if (kn == marker) { 1487 1.111 jdolecek /* it's our marker, stop */ 1488 1.111 jdolecek KQ_FLUX_WAKEUP(kq); 1489 1.111 jdolecek if (count == maxevents) { 1490 1.110 jdolecek mutex_exit(&fdp->fd_lock); 1491 1.110 jdolecek goto retry; 1492 1.49 ad } 1493 1.111 jdolecek break; 1494 1.110 jdolecek } 1495 1.111 jdolecek KASSERT((kn->kn_status & KN_BUSY) == 0); 1496 1.111 jdolecek 1497 1.110 jdolecek kq_check(kq); 1498 1.115 jdolecek kn->kn_status &= ~KN_QUEUED; 1499 1.110 jdolecek kn->kn_status |= KN_BUSY; 1500 1.110 jdolecek kq_check(kq); 1501 1.110 jdolecek if (kn->kn_status & KN_DISABLED) { 1502 1.115 jdolecek kn->kn_status &= ~KN_BUSY; 1503 1.111 jdolecek kq->kq_count--; 1504 1.110 jdolecek /* don't want disabled events */ 1505 1.110 jdolecek continue; 1506 1.110 jdolecek } 1507 1.110 jdolecek if ((kn->kn_flags & EV_ONESHOT) == 0) { 1508 1.110 jdolecek mutex_spin_exit(&kq->kq_lock); 1509 1.110 jdolecek KASSERT(kn->kn_fop != NULL); 1510 1.110 jdolecek KASSERT(kn->kn_fop->f_event != NULL); 1511 1.110 jdolecek KERNEL_LOCK(1, NULL); /* XXXSMP */ 1512 1.110 jdolecek KASSERT(mutex_owned(&fdp->fd_lock)); 1513 1.110 jdolecek rv = (*kn->kn_fop->f_event)(kn, 0); 1514 1.110 jdolecek KERNEL_UNLOCK_ONE(NULL); /* XXXSMP */ 1515 1.110 jdolecek mutex_spin_enter(&kq->kq_lock); 1516 1.115 jdolecek /* Re-poll if note was re-enqueued. */ 1517 1.115 jdolecek if ((kn->kn_status & KN_QUEUED) != 0) { 1518 1.115 jdolecek kn->kn_status &= ~KN_BUSY; 1519 1.115 jdolecek /* Re-enqueue raised kq_count, lower it again */ 1520 1.115 jdolecek kq->kq_count--; 1521 1.115 jdolecek influx = 1; 1522 1.115 jdolecek continue; 1523 1.115 jdolecek } 1524 1.110 jdolecek if (rv == 0) { 1525 1.110 jdolecek /* 1526 1.110 jdolecek * non-ONESHOT event that hasn't 1527 1.110 jdolecek * triggered again, so de-queue. 1528 1.110 jdolecek */ 1529 1.115 jdolecek kn->kn_status &= ~(KN_ACTIVE|KN_BUSY); 1530 1.111 jdolecek kq->kq_count--; 1531 1.111 jdolecek influx = 1; 1532 1.110 jdolecek continue; 1533 1.49 ad } 1534 1.110 jdolecek } 1535 1.110 jdolecek KASSERT(kn->kn_fop != NULL); 1536 1.110 jdolecek touch = (!kn->kn_fop->f_isfd && 1537 1.110 jdolecek kn->kn_fop->f_touch != NULL); 1538 1.110 jdolecek /* XXXAD should be got from f_event if !oneshot. */ 1539 1.110 jdolecek if (touch) { 1540 1.110 jdolecek (*kn->kn_fop->f_touch)(kn, kevp, EVENT_PROCESS); 1541 1.110 jdolecek } else { 1542 1.110 jdolecek *kevp = kn->kn_kevent; 1543 1.110 jdolecek } 1544 1.110 jdolecek kevp++; 1545 1.110 jdolecek nkev++; 1546 1.111 jdolecek influx = 1; 1547 1.110 jdolecek if (kn->kn_flags & EV_ONESHOT) { 1548 1.110 jdolecek /* delete ONESHOT events after retrieval */ 1549 1.115 jdolecek kn->kn_status &= ~KN_BUSY; 1550 1.111 jdolecek kq->kq_count--; 1551 1.110 jdolecek mutex_spin_exit(&kq->kq_lock); 1552 1.110 jdolecek knote_detach(kn, fdp, true); 1553 1.110 jdolecek mutex_enter(&fdp->fd_lock); 1554 1.110 jdolecek mutex_spin_enter(&kq->kq_lock); 1555 1.110 jdolecek } else if (kn->kn_flags & EV_CLEAR) { 1556 1.110 jdolecek /* clear state after retrieval */ 1557 1.110 jdolecek kn->kn_data = 0; 1558 1.110 jdolecek kn->kn_fflags = 0; 1559 1.110 jdolecek /* 1560 1.110 jdolecek * Manually clear knotes who weren't 1561 1.110 jdolecek * 'touch'ed. 1562 1.110 jdolecek */ 1563 1.110 jdolecek if (touch == 0) { 1564 1.49 ad kn->kn_data = 0; 1565 1.49 ad kn->kn_fflags = 0; 1566 1.49 ad } 1567 1.115 jdolecek kn->kn_status &= ~(KN_ACTIVE|KN_BUSY); 1568 1.111 jdolecek kq->kq_count--; 1569 1.110 jdolecek } else if (kn->kn_flags & EV_DISPATCH) { 1570 1.110 jdolecek kn->kn_status |= KN_DISABLED; 1571 1.115 jdolecek kn->kn_status &= ~(KN_ACTIVE|KN_BUSY); 1572 1.111 jdolecek kq->kq_count--; 1573 1.110 jdolecek } else { 1574 1.110 jdolecek /* add event back on list */ 1575 1.110 jdolecek kq_check(kq); 1576 1.115 jdolecek kn->kn_status |= KN_QUEUED; 1577 1.110 jdolecek kn->kn_status &= ~KN_BUSY; 1578 1.110 jdolecek TAILQ_INSERT_TAIL(&kq->kq_head, kn, kn_tqe); 1579 1.110 jdolecek kq_check(kq); 1580 1.110 jdolecek } 1581 1.111 jdolecek 1582 1.110 jdolecek if (nkev == kevcnt) { 1583 1.110 jdolecek /* do copyouts in kevcnt chunks */ 1584 1.111 jdolecek influx = 0; 1585 1.111 jdolecek KQ_FLUX_WAKEUP(kq); 1586 1.110 jdolecek mutex_spin_exit(&kq->kq_lock); 1587 1.110 jdolecek mutex_exit(&fdp->fd_lock); 1588 1.110 jdolecek error = (*keops->keo_put_events) 1589 1.110 jdolecek (keops->keo_private, 1590 1.110 jdolecek kevbuf, ulistp, nevents, nkev); 1591 1.110 jdolecek mutex_enter(&fdp->fd_lock); 1592 1.110 jdolecek mutex_spin_enter(&kq->kq_lock); 1593 1.110 jdolecek nevents += nkev; 1594 1.110 jdolecek nkev = 0; 1595 1.110 jdolecek kevp = kevbuf; 1596 1.110 jdolecek } 1597 1.110 jdolecek count--; 1598 1.110 jdolecek if (error != 0 || count == 0) { 1599 1.110 jdolecek /* remove marker */ 1600 1.110 jdolecek TAILQ_REMOVE(&kq->kq_head, marker, kn_tqe); 1601 1.110 jdolecek break; 1602 1.1 lukem } 1603 1.1 lukem } 1604 1.111 jdolecek KQ_FLUX_WAKEUP(kq); 1605 1.110 jdolecek mutex_spin_exit(&kq->kq_lock); 1606 1.110 jdolecek mutex_exit(&fdp->fd_lock); 1607 1.110 jdolecek 1608 1.110 jdolecek done: 1609 1.49 ad if (nkev != 0) { 1610 1.3 jdolecek /* copyout remaining events */ 1611 1.24 cube error = (*keops->keo_put_events)(keops->keo_private, 1612 1.49 ad kevbuf, ulistp, nevents, nkev); 1613 1.49 ad } 1614 1.3 jdolecek *retval = maxevents - count; 1615 1.3 jdolecek 1616 1.49 ad return error; 1617 1.1 lukem } 1618 1.1 lukem 1619 1.1 lukem /* 1620 1.49 ad * fileops ioctl method for a kqueue descriptor. 1621 1.3 jdolecek * 1622 1.3 jdolecek * Two ioctls are currently supported. They both use struct kfilter_mapping: 1623 1.3 jdolecek * KFILTER_BYNAME find name for filter, and return result in 1624 1.3 jdolecek * name, which is of size len. 1625 1.3 jdolecek * KFILTER_BYFILTER find filter for name. len is ignored. 1626 1.3 jdolecek */ 1627 1.1 lukem /*ARGSUSED*/ 1628 1.1 lukem static int 1629 1.49 ad kqueue_ioctl(file_t *fp, u_long com, void *data) 1630 1.1 lukem { 1631 1.3 jdolecek struct kfilter_mapping *km; 1632 1.3 jdolecek const struct kfilter *kfilter; 1633 1.3 jdolecek char *name; 1634 1.3 jdolecek int error; 1635 1.3 jdolecek 1636 1.49 ad km = data; 1637 1.3 jdolecek error = 0; 1638 1.49 ad name = kmem_alloc(KFILTER_MAXNAME, KM_SLEEP); 1639 1.3 jdolecek 1640 1.3 jdolecek switch (com) { 1641 1.3 jdolecek case KFILTER_BYFILTER: /* convert filter -> name */ 1642 1.49 ad rw_enter(&kqueue_filter_lock, RW_READER); 1643 1.3 jdolecek kfilter = kfilter_byfilter(km->filter); 1644 1.49 ad if (kfilter != NULL) { 1645 1.49 ad strlcpy(name, kfilter->name, KFILTER_MAXNAME); 1646 1.49 ad rw_exit(&kqueue_filter_lock); 1647 1.49 ad error = copyoutstr(name, km->name, km->len, NULL); 1648 1.49 ad } else { 1649 1.49 ad rw_exit(&kqueue_filter_lock); 1650 1.3 jdolecek error = ENOENT; 1651 1.49 ad } 1652 1.3 jdolecek break; 1653 1.3 jdolecek 1654 1.3 jdolecek case KFILTER_BYNAME: /* convert name -> filter */ 1655 1.3 jdolecek error = copyinstr(km->name, name, KFILTER_MAXNAME, NULL); 1656 1.3 jdolecek if (error) { 1657 1.3 jdolecek break; 1658 1.3 jdolecek } 1659 1.49 ad rw_enter(&kqueue_filter_lock, RW_READER); 1660 1.3 jdolecek kfilter = kfilter_byname(name); 1661 1.3 jdolecek if (kfilter != NULL) 1662 1.3 jdolecek km->filter = kfilter->filter; 1663 1.3 jdolecek else 1664 1.3 jdolecek error = ENOENT; 1665 1.49 ad rw_exit(&kqueue_filter_lock); 1666 1.3 jdolecek break; 1667 1.3 jdolecek 1668 1.3 jdolecek default: 1669 1.3 jdolecek error = ENOTTY; 1670 1.49 ad break; 1671 1.3 jdolecek 1672 1.3 jdolecek } 1673 1.49 ad kmem_free(name, KFILTER_MAXNAME); 1674 1.3 jdolecek return (error); 1675 1.3 jdolecek } 1676 1.3 jdolecek 1677 1.3 jdolecek /* 1678 1.49 ad * fileops fcntl method for a kqueue descriptor. 1679 1.3 jdolecek */ 1680 1.3 jdolecek static int 1681 1.49 ad kqueue_fcntl(file_t *fp, u_int com, void *data) 1682 1.3 jdolecek { 1683 1.3 jdolecek 1684 1.1 lukem return (ENOTTY); 1685 1.1 lukem } 1686 1.1 lukem 1687 1.3 jdolecek /* 1688 1.49 ad * fileops poll method for a kqueue descriptor. 1689 1.3 jdolecek * Determine if kqueue has events pending. 1690 1.3 jdolecek */ 1691 1.1 lukem static int 1692 1.49 ad kqueue_poll(file_t *fp, int events) 1693 1.1 lukem { 1694 1.3 jdolecek struct kqueue *kq; 1695 1.3 jdolecek int revents; 1696 1.3 jdolecek 1697 1.82 matt kq = fp->f_kqueue; 1698 1.49 ad 1699 1.3 jdolecek revents = 0; 1700 1.3 jdolecek if (events & (POLLIN | POLLRDNORM)) { 1701 1.49 ad mutex_spin_enter(&kq->kq_lock); 1702 1.117.4.1 thorpej if (KQ_COUNT(kq) != 0) { 1703 1.3 jdolecek revents |= events & (POLLIN | POLLRDNORM); 1704 1.1 lukem } else { 1705 1.49 ad selrecord(curlwp, &kq->kq_sel); 1706 1.1 lukem } 1707 1.52 yamt kq_check(kq); 1708 1.49 ad mutex_spin_exit(&kq->kq_lock); 1709 1.1 lukem } 1710 1.49 ad 1711 1.49 ad return revents; 1712 1.1 lukem } 1713 1.1 lukem 1714 1.3 jdolecek /* 1715 1.49 ad * fileops stat method for a kqueue descriptor. 1716 1.3 jdolecek * Returns dummy info, with st_size being number of events pending. 1717 1.3 jdolecek */ 1718 1.1 lukem static int 1719 1.49 ad kqueue_stat(file_t *fp, struct stat *st) 1720 1.1 lukem { 1721 1.49 ad struct kqueue *kq; 1722 1.49 ad 1723 1.82 matt kq = fp->f_kqueue; 1724 1.1 lukem 1725 1.49 ad memset(st, 0, sizeof(*st)); 1726 1.117.4.1 thorpej st->st_size = KQ_COUNT(kq); 1727 1.1 lukem st->st_blksize = sizeof(struct kevent); 1728 1.1 lukem st->st_mode = S_IFIFO; 1729 1.49 ad 1730 1.49 ad return 0; 1731 1.49 ad } 1732 1.49 ad 1733 1.49 ad static void 1734 1.49 ad kqueue_doclose(struct kqueue *kq, struct klist *list, int fd) 1735 1.49 ad { 1736 1.49 ad struct knote *kn; 1737 1.49 ad filedesc_t *fdp; 1738 1.49 ad 1739 1.49 ad fdp = kq->kq_fdp; 1740 1.49 ad 1741 1.49 ad KASSERT(mutex_owned(&fdp->fd_lock)); 1742 1.49 ad 1743 1.49 ad for (kn = SLIST_FIRST(list); kn != NULL;) { 1744 1.49 ad if (kq != kn->kn_kq) { 1745 1.49 ad kn = SLIST_NEXT(kn, kn_link); 1746 1.49 ad continue; 1747 1.49 ad } 1748 1.49 ad knote_detach(kn, fdp, true); 1749 1.49 ad mutex_enter(&fdp->fd_lock); 1750 1.49 ad kn = SLIST_FIRST(list); 1751 1.49 ad } 1752 1.1 lukem } 1753 1.1 lukem 1754 1.49 ad 1755 1.3 jdolecek /* 1756 1.49 ad * fileops close method for a kqueue descriptor. 1757 1.3 jdolecek */ 1758 1.1 lukem static int 1759 1.49 ad kqueue_close(file_t *fp) 1760 1.1 lukem { 1761 1.49 ad struct kqueue *kq; 1762 1.49 ad filedesc_t *fdp; 1763 1.49 ad fdfile_t *ff; 1764 1.49 ad int i; 1765 1.49 ad 1766 1.82 matt kq = fp->f_kqueue; 1767 1.82 matt fp->f_kqueue = NULL; 1768 1.79 christos fp->f_type = 0; 1769 1.49 ad fdp = curlwp->l_fd; 1770 1.1 lukem 1771 1.49 ad mutex_enter(&fdp->fd_lock); 1772 1.49 ad for (i = 0; i <= fdp->fd_lastkqfile; i++) { 1773 1.65 ad if ((ff = fdp->fd_dt->dt_ff[i]) == NULL) 1774 1.49 ad continue; 1775 1.49 ad kqueue_doclose(kq, (struct klist *)&ff->ff_knlist, i); 1776 1.1 lukem } 1777 1.1 lukem if (fdp->fd_knhashmask != 0) { 1778 1.1 lukem for (i = 0; i < fdp->fd_knhashmask + 1; i++) { 1779 1.49 ad kqueue_doclose(kq, &fdp->fd_knhash[i], -1); 1780 1.1 lukem } 1781 1.1 lukem } 1782 1.49 ad mutex_exit(&fdp->fd_lock); 1783 1.49 ad 1784 1.117.4.1 thorpej KASSERT(KQ_COUNT(kq) == 0); 1785 1.49 ad mutex_destroy(&kq->kq_lock); 1786 1.49 ad cv_destroy(&kq->kq_cv); 1787 1.48 rmind seldestroy(&kq->kq_sel); 1788 1.49 ad kmem_free(kq, sizeof(*kq)); 1789 1.1 lukem 1790 1.1 lukem return (0); 1791 1.1 lukem } 1792 1.1 lukem 1793 1.3 jdolecek /* 1794 1.3 jdolecek * struct fileops kqfilter method for a kqueue descriptor. 1795 1.3 jdolecek * Event triggered when monitored kqueue changes. 1796 1.3 jdolecek */ 1797 1.3 jdolecek static int 1798 1.49 ad kqueue_kqfilter(file_t *fp, struct knote *kn) 1799 1.3 jdolecek { 1800 1.3 jdolecek struct kqueue *kq; 1801 1.49 ad 1802 1.82 matt kq = ((file_t *)kn->kn_obj)->f_kqueue; 1803 1.49 ad 1804 1.49 ad KASSERT(fp == kn->kn_obj); 1805 1.3 jdolecek 1806 1.3 jdolecek if (kn->kn_filter != EVFILT_READ) 1807 1.49 ad return 1; 1808 1.49 ad 1809 1.3 jdolecek kn->kn_fop = &kqread_filtops; 1810 1.49 ad mutex_enter(&kq->kq_lock); 1811 1.109 thorpej selrecord_knote(&kq->kq_sel, kn); 1812 1.49 ad mutex_exit(&kq->kq_lock); 1813 1.49 ad 1814 1.49 ad return 0; 1815 1.3 jdolecek } 1816 1.3 jdolecek 1817 1.3 jdolecek 1818 1.3 jdolecek /* 1819 1.49 ad * Walk down a list of knotes, activating them if their event has 1820 1.49 ad * triggered. The caller's object lock (e.g. device driver lock) 1821 1.49 ad * must be held. 1822 1.1 lukem */ 1823 1.1 lukem void 1824 1.1 lukem knote(struct klist *list, long hint) 1825 1.1 lukem { 1826 1.71 drochner struct knote *kn, *tmpkn; 1827 1.1 lukem 1828 1.71 drochner SLIST_FOREACH_SAFE(kn, list, kn_selnext, tmpkn) { 1829 1.85 christos KASSERT(kn->kn_fop != NULL); 1830 1.84 christos KASSERT(kn->kn_fop->f_event != NULL); 1831 1.49 ad if ((*kn->kn_fop->f_event)(kn, hint)) 1832 1.49 ad knote_activate(kn); 1833 1.49 ad } 1834 1.1 lukem } 1835 1.1 lukem 1836 1.1 lukem /* 1837 1.49 ad * Remove all knotes referencing a specified fd 1838 1.1 lukem */ 1839 1.1 lukem void 1840 1.49 ad knote_fdclose(int fd) 1841 1.1 lukem { 1842 1.49 ad struct klist *list; 1843 1.1 lukem struct knote *kn; 1844 1.49 ad filedesc_t *fdp; 1845 1.1 lukem 1846 1.49 ad fdp = curlwp->l_fd; 1847 1.106 riastrad mutex_enter(&fdp->fd_lock); 1848 1.65 ad list = (struct klist *)&fdp->fd_dt->dt_ff[fd]->ff_knlist; 1849 1.1 lukem while ((kn = SLIST_FIRST(list)) != NULL) { 1850 1.49 ad knote_detach(kn, fdp, true); 1851 1.49 ad mutex_enter(&fdp->fd_lock); 1852 1.1 lukem } 1853 1.49 ad mutex_exit(&fdp->fd_lock); 1854 1.1 lukem } 1855 1.1 lukem 1856 1.1 lukem /* 1857 1.49 ad * Drop knote. Called with fdp->fd_lock held, and will drop before 1858 1.49 ad * returning. 1859 1.3 jdolecek */ 1860 1.1 lukem static void 1861 1.49 ad knote_detach(struct knote *kn, filedesc_t *fdp, bool dofop) 1862 1.1 lukem { 1863 1.49 ad struct klist *list; 1864 1.53 ad struct kqueue *kq; 1865 1.53 ad 1866 1.53 ad kq = kn->kn_kq; 1867 1.1 lukem 1868 1.49 ad KASSERT((kn->kn_status & KN_MARKER) == 0); 1869 1.49 ad KASSERT(mutex_owned(&fdp->fd_lock)); 1870 1.3 jdolecek 1871 1.85 christos KASSERT(kn->kn_fop != NULL); 1872 1.53 ad /* Remove from monitored object. */ 1873 1.49 ad if (dofop) { 1874 1.85 christos KASSERT(kn->kn_fop->f_detach != NULL); 1875 1.49 ad KERNEL_LOCK(1, NULL); /* XXXSMP */ 1876 1.49 ad (*kn->kn_fop->f_detach)(kn); 1877 1.49 ad KERNEL_UNLOCK_ONE(NULL); /* XXXSMP */ 1878 1.1 lukem } 1879 1.3 jdolecek 1880 1.53 ad /* Remove from descriptor table. */ 1881 1.1 lukem if (kn->kn_fop->f_isfd) 1882 1.65 ad list = (struct klist *)&fdp->fd_dt->dt_ff[kn->kn_id]->ff_knlist; 1883 1.1 lukem else 1884 1.1 lukem list = &fdp->fd_knhash[KN_HASH(kn->kn_id, fdp->fd_knhashmask)]; 1885 1.1 lukem 1886 1.1 lukem SLIST_REMOVE(list, kn, knote, kn_link); 1887 1.53 ad 1888 1.53 ad /* Remove from kqueue. */ 1889 1.85 christos again: 1890 1.53 ad mutex_spin_enter(&kq->kq_lock); 1891 1.53 ad if ((kn->kn_status & KN_QUEUED) != 0) { 1892 1.53 ad kq_check(kq); 1893 1.85 christos kq->kq_count--; 1894 1.53 ad TAILQ_REMOVE(&kq->kq_head, kn, kn_tqe); 1895 1.53 ad kn->kn_status &= ~KN_QUEUED; 1896 1.53 ad kq_check(kq); 1897 1.85 christos } else if (kn->kn_status & KN_BUSY) { 1898 1.85 christos mutex_spin_exit(&kq->kq_lock); 1899 1.85 christos goto again; 1900 1.53 ad } 1901 1.53 ad mutex_spin_exit(&kq->kq_lock); 1902 1.53 ad 1903 1.49 ad mutex_exit(&fdp->fd_lock); 1904 1.93 riastrad if (kn->kn_fop->f_isfd) 1905 1.49 ad fd_putfile(kn->kn_id); 1906 1.49 ad atomic_dec_uint(&kn->kn_kfilter->refcnt); 1907 1.49 ad kmem_free(kn, sizeof(*kn)); 1908 1.1 lukem } 1909 1.1 lukem 1910 1.3 jdolecek /* 1911 1.3 jdolecek * Queue new event for knote. 1912 1.3 jdolecek */ 1913 1.1 lukem static void 1914 1.1 lukem knote_enqueue(struct knote *kn) 1915 1.1 lukem { 1916 1.49 ad struct kqueue *kq; 1917 1.49 ad 1918 1.49 ad KASSERT((kn->kn_status & KN_MARKER) == 0); 1919 1.1 lukem 1920 1.3 jdolecek kq = kn->kn_kq; 1921 1.1 lukem 1922 1.49 ad mutex_spin_enter(&kq->kq_lock); 1923 1.49 ad if ((kn->kn_status & KN_DISABLED) != 0) { 1924 1.49 ad kn->kn_status &= ~KN_DISABLED; 1925 1.49 ad } 1926 1.49 ad if ((kn->kn_status & (KN_ACTIVE | KN_QUEUED)) == KN_ACTIVE) { 1927 1.52 yamt kq_check(kq); 1928 1.85 christos kn->kn_status |= KN_QUEUED; 1929 1.49 ad TAILQ_INSERT_TAIL(&kq->kq_head, kn, kn_tqe); 1930 1.49 ad kq->kq_count++; 1931 1.52 yamt kq_check(kq); 1932 1.49 ad cv_broadcast(&kq->kq_cv); 1933 1.49 ad selnotify(&kq->kq_sel, 0, NOTE_SUBMIT); 1934 1.49 ad } 1935 1.49 ad mutex_spin_exit(&kq->kq_lock); 1936 1.1 lukem } 1937 1.49 ad /* 1938 1.49 ad * Queue new event for knote. 1939 1.49 ad */ 1940 1.49 ad static void 1941 1.49 ad knote_activate(struct knote *kn) 1942 1.49 ad { 1943 1.49 ad struct kqueue *kq; 1944 1.49 ad 1945 1.49 ad KASSERT((kn->kn_status & KN_MARKER) == 0); 1946 1.1 lukem 1947 1.3 jdolecek kq = kn->kn_kq; 1948 1.12 pk 1949 1.49 ad mutex_spin_enter(&kq->kq_lock); 1950 1.49 ad kn->kn_status |= KN_ACTIVE; 1951 1.49 ad if ((kn->kn_status & (KN_QUEUED | KN_DISABLED)) == 0) { 1952 1.52 yamt kq_check(kq); 1953 1.85 christos kn->kn_status |= KN_QUEUED; 1954 1.49 ad TAILQ_INSERT_TAIL(&kq->kq_head, kn, kn_tqe); 1955 1.49 ad kq->kq_count++; 1956 1.52 yamt kq_check(kq); 1957 1.49 ad cv_broadcast(&kq->kq_cv); 1958 1.49 ad selnotify(&kq->kq_sel, 0, NOTE_SUBMIT); 1959 1.49 ad } 1960 1.49 ad mutex_spin_exit(&kq->kq_lock); 1961 1.1 lukem } 1962
Indexes created Mon Sep 29 21:09:56 GMT 2025