1: /*************************************************************************
2: * (C) 2011 AITNET ltd - Sofia/Bulgaria - <misho@aitbg.com>
3: * by Michael Pounov <misho@openbsd-bg.org>
4: *
5: * $Author: misho $
6: * $Id: hooks.c,v 1.1 2011/08/05 15:52:00 misho Exp $
7: *
8: **************************************************************************
9: The ELWIX and AITNET software is distributed under the following
10: terms:
11:
12: All of the documentation and software included in the ELWIX and AITNET
13: Releases is copyrighted by ELWIX - Sofia/Bulgaria <info@elwix.org>
14:
15: Copyright 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
16: by Michael Pounov <misho@elwix.org>. All rights reserved.
17:
18: Redistribution and use in source and binary forms, with or without
19: modification, are permitted provided that the following conditions
20: are met:
21: 1. Redistributions of source code must retain the above copyright
22: notice, this list of conditions and the following disclaimer.
23: 2. Redistributions in binary form must reproduce the above copyright
24: notice, this list of conditions and the following disclaimer in the
25: documentation and/or other materials provided with the distribution.
26: 3. All advertising materials mentioning features or use of this software
27: must display the following acknowledgement:
28: This product includes software developed by Michael Pounov <misho@elwix.org>
29: ELWIX - Embedded LightWeight unIX and its contributors.
30: 4. Neither the name of AITNET nor the names of its contributors
31: may be used to endorse or promote products derived from this software
32: without specific prior written permission.
33:
34: THIS SOFTWARE IS PROVIDED BY AITNET AND CONTRIBUTORS ``AS IS'' AND
35: ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
36: IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
37: ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
38: FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
39: DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
40: OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
41: HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
42: LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
43: OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
44: SUCH DAMAGE.
45: */
46: #include "global.h"
47: #include "hooks.h"
48:
49:
50: /*
51: * sched_hook_init() - Default INIT hook
52: * @root = root task
53: * @data = optional data if !=NULL
54: * return: <0 errors and 0 ok
55: */
56: void *
57: sched_hook_init(void *root, void *data)
58: {
59: sched_root_task_t *r = root;
60:
61: if (!r || r->root_data.iov_base || r->root_data.iov_len)
62: return (void*) -1;
63:
64: r->root_data.iov_base = malloc(sizeof(struct sched_IO));
65: if (!r->root_data.iov_base) {
66: LOGERR;
67: return (void*) -1;
68: } else {
69: r->root_data.iov_len = sizeof(struct sched_IO);
70: memset(r->root_data.iov_base, 0, r->root_data.iov_len);
71: }
72:
73: r->root_kq = kqueue();
74: if (r->root_kq == -1) {
75: LOGERR;
76: return (void*) -1;
77: }
78:
79: return NULL;
80: }
81:
82: /*
83: * sched_hook_fini() - Default FINI hook
84: * @root = root task
85: * @arg = unused
86: * return: <0 errors and 0 ok
87: */
88: void *
89: sched_hook_fini(void *root, void *arg __unused)
90: {
91: sched_root_task_t *r = root;
92:
93: if (!r)
94: return (void*) -1;
95:
96: if (r->root_kq > 2) {
97: close(r->root_kq);
98: r->root_kq = 0;
99: }
100:
101: if (r->root_data.iov_base && r->root_data.iov_len) {
102: free(r->root_data.iov_base);
103: r->root_data.iov_base = NULL;
104: r->root_data.iov_len = 0;
105: }
106:
107: return NULL;
108: }
109:
110: /*
111: * sched_hook_cancel() - Default CANCEL hook
112: * @task = current task
113: * @arg = unused
114: * return: <0 errors and 0 ok
115: */
116: void *
117: sched_hook_cancel(void *task, void *arg __unused)
118: {
119: struct sched_IO *io;
120: sched_task_t *t = task;
121: struct kevent chg[1];
122: struct timespec timeout;
123:
124: if (!t || !t->task_root || !ROOT_DATA(t->task_root) || !ROOT_DATLEN(t->task_root))
125: return (void*) -1;
126: else
127: io = ROOT_DATA(t->task_root);
128:
129: timespecclear(&timeout);
130: switch (t->task_type) {
131: case taskREAD:
132: if (FD_ISSET(TASK_FD(t), &io->wfd))
133: EV_SET(&chg[0], TASK_FD(t), EVFILT_WRITE, EV_ADD, 0, 0, &TASK_FD(t));
134: else
135: EV_SET(&chg[0], TASK_FD(t), EVFILT_WRITE, EV_DELETE, 0, 0, &TASK_FD(t));
136: kevent(t->task_root->root_kq, chg, 1, NULL, 0, &timeout);
137:
138: FD_CLR(TASK_FD(t), &io->rfd);
139: break;
140: case taskWRITE:
141: if (FD_ISSET(TASK_FD(t), &io->rfd))
142: EV_SET(&chg[0], TASK_FD(t), EVFILT_READ, EV_ADD, 0, 0, &TASK_FD(t));
143: else
144: EV_SET(&chg[0], TASK_FD(t), EVFILT_READ, EV_DELETE, 0, 0, &TASK_FD(t));
145: kevent(t->task_root->root_kq, chg, 1, NULL, 0, &timeout);
146:
147: FD_CLR(TASK_FD(t), &io->wfd);
148: break;
149: default:
150: break;
151: }
152:
153: return NULL;
154: }
155:
156: /*
157: * sched_hook_read() - Default READ hook
158: * @task = current task
159: * @arg = unused
160: * return: <0 errors and 0 ok
161: */
162: void *
163: sched_hook_read(void *task, void *arg __unused)
164: {
165: struct sched_IO *io;
166: sched_task_t *t = task;
167: struct kevent chg[1];
168: struct timespec timeout;
169:
170: if (!t || !t->task_root || !ROOT_DATA(t->task_root) || !ROOT_DATLEN(t->task_root))
171: return (void*) -1;
172: else
173: io = ROOT_DATA(t->task_root);
174:
175: if (FD_ISSET(TASK_FD(t), &io->rfd))
176: return NULL;
177: else
178: FD_SET(TASK_FD(t), &io->rfd);
179:
180: timespecclear(&timeout);
181: EV_SET(&chg[0], TASK_FD(t), EVFILT_READ, EV_ADD, 0, 0, &TASK_FD(t));
182: if (kevent(t->task_root->root_kq, chg, 1, NULL, 0, &timeout) == -1) {
183: LOGERR;
184: return (void*) -1;
185: }
186:
187: return NULL;
188: }
189:
190: /*
191: * sched_hook_write() - Default WRITE hook
192: * @task = current task
193: * @arg = unused
194: * return: <0 errors and 0 ok
195: */
196: void *
197: sched_hook_write(void *task, void *arg __unused)
198: {
199: struct sched_IO *io;
200: sched_task_t *t = task;
201: struct kevent chg[1];
202: struct timespec timeout;
203:
204: if (!t || !t->task_root || !ROOT_DATA(t->task_root) || !ROOT_DATLEN(t->task_root))
205: return (void*) -1;
206: else
207: io = ROOT_DATA(t->task_root);
208:
209: if (FD_ISSET(TASK_FD(t), &io->wfd))
210: return NULL;
211: else
212: FD_SET(TASK_FD(t), &io->wfd);
213:
214: timespecclear(&timeout);
215: EV_SET(&chg[0], TASK_FD(t), EVFILT_WRITE, EV_ADD, 0, 0, &TASK_FD(t));
216: if (kevent(t->task_root->root_kq, chg, 1, NULL, 0, &timeout) == -1) {
217: LOGERR;
218: return (void*) -1;
219: }
220:
221: return NULL;
222: }
223:
224: /*
225: * sched_hook_fetch() - Default FETCH hook
226: * @root = root task
227: * @arg = unused
228: * return: NULL error or !=NULL fetched task
229: */
230: void *
231: sched_hook_fetch(void *root, void *arg __unused)
232: {
233: struct sched_IO *io;
234: sched_root_task_t *r = root;
235: sched_task_t *task;
236: struct timeval now, m, mtmp;
237: struct timespec nw, *timeout;
238: struct kevent evt[1], res[KQ_EVENTS];
239: register int i;
240: int en;
241:
242: if (!r || !ROOT_DATA(r) || !ROOT_DATLEN(r))
243: return NULL;
244:
245: /* get new task by queue priority */
246: retry:
247: while ((task = TAILQ_FIRST(&r->root_event))) {
248: TAILQ_REMOVE(&r->root_event, task, task_node);
249: task->task_type = taskUNUSE;
250: TAILQ_INSERT_TAIL(&r->root_unuse, task, task_node);
251: return task;
252: }
253: while ((task = TAILQ_FIRST(&r->root_ready))) {
254: TAILQ_REMOVE(&r->root_ready, task, task_node);
255: task->task_type = taskUNUSE;
256: TAILQ_INSERT_TAIL(&r->root_unuse, task, task_node);
257: return task;
258: }
259:
260: #ifdef TIMER_WITHOUT_SORT
261: clock_gettime(CLOCK_MONOTONIC, &nw);
262: now.tv_sec = nw.tv_sec;
263: now.tv_usec = nw.tv_nsec / 1000;
264:
265: timerclear(&r->root_wait);
266: TAILQ_FOREACH(task, &r->root_timer, task_node) {
267: if (!timerisset(&r->root_wait))
268: r->root_wait = TASK_TV(task);
269: else if (timercmp(&TASK_TV(task), &r->root_wait, -) < 0)
270: r->root_wait = TASK_TV(task);
271: }
272:
273: if (TAILQ_FIRST(&r->root_timer)) {
274: m = r->root_wait;
275: timersub(&m, &now, &mtmp);
276: r->root_wait = mtmp;
277: } else {
278: /* set wait INFTIM */
279: r->root_wait.tv_sec = r->root_wait.tv_usec = -1;
280: }
281: #else
282: if (!TAILQ_FIRST(&r->root_eventlo) && (task = TAILQ_FIRST(&r->root_timer))) {
283: clock_gettime(CLOCK_MONOTONIC, &nw);
284: now.tv_sec = nw.tv_sec;
285: now.tv_usec = nw.tv_nsec / 1000;
286:
287: m = TASK_TV(task);
288: timersub(&m, &now, &mtmp);
289: r->root_wait = mtmp;
290: } else {
291: /* set wait INFTIM */
292: r->root_wait.tv_sec = r->root_wait.tv_usec = -1;
293: }
294: #endif
295: /* if present member of eventLo, set NOWAIT */
296: if (TAILQ_FIRST(&r->root_eventlo))
297: timerclear(&r->root_wait);
298:
299: if (r->root_wait.tv_sec != -1 && r->root_wait.tv_usec != -1) {
300: nw.tv_sec = r->root_wait.tv_sec;
301: nw.tv_nsec = r->root_wait.tv_usec * 1000;
302: timeout = &nw;
303: } else /* wait INFTIM */
304: timeout = NULL;
305: if ((en = kevent(r->root_kq, NULL, 0, res, KQ_EVENTS, timeout)) == -1) {
306: LOGERR;
307: goto retry;
308: }
309:
310: timespecclear(&nw);
311: /* Go and catch the cat into pipes ... */
312: for (i = 0; i < en; i++) {
313: memcpy(evt, &res[i], sizeof evt);
314: evt->flags = EV_DELETE;
315: /* Put read/write task to ready queue */
316: switch (res[i].filter) {
317: case EVFILT_READ:
318: TAILQ_FOREACH(task, &r->root_read, task_node) {
319: if (TASK_FD(task) != *((int*) res[i].udata))
320: continue;
321: /* remove read handle */
322: io = ROOT_DATA(task->task_root);
323: FD_CLR(TASK_FD(task), &io->rfd);
324:
325: TAILQ_REMOVE(&r->root_read, task, task_node);
326: task->task_type = taskREADY;
327: TAILQ_INSERT_TAIL(&r->root_ready, task, task_node);
328: break;
329: }
330: break;
331: case EVFILT_WRITE:
332: TAILQ_FOREACH(task, &r->root_write, task_node) {
333: if (TASK_FD(task) != *((int*) res[i].udata))
334: continue;
335: /* remove write handle */
336: io = ROOT_DATA(task->task_root);
337: FD_CLR(TASK_FD(task), &io->wfd);
338:
339: TAILQ_REMOVE(&r->root_write, task, task_node);
340: task->task_type = taskREADY;
341: TAILQ_INSERT_TAIL(&r->root_ready, task, task_node);
342: break;
343: }
344: break;
345: }
346:
347: if (kevent(r->root_kq, evt, 1, NULL, 0, &nw) == -1)
348: LOGERR;
349: }
350:
351: /* timer update */
352: clock_gettime(CLOCK_MONOTONIC, &nw);
353: now.tv_sec = nw.tv_sec;
354: now.tv_usec = nw.tv_nsec / 1000;
355:
356: TAILQ_FOREACH(task, &r->root_timer, task_node)
357: if (timercmp(&now, &TASK_TV(task), -) >= 0) {
358: TAILQ_REMOVE(&r->root_timer, task, task_node);
359: task->task_type = taskREADY;
360: TAILQ_INSERT_TAIL(&r->root_ready, task, task_node);
361: }
362:
363: /* put eventlo priority task to ready queue, if there is no ready task or
364: reach max missed fetch-rotate */
365: if ((task = TAILQ_FIRST(&r->root_eventlo))) {
366: if (!TAILQ_FIRST(&r->root_ready) || r->root_eventlo_miss > MAX_EVENTLO_MISS) {
367: r->root_eventlo_miss = 0;
368:
369: TAILQ_REMOVE(&r->root_eventlo, task, task_node);
370: task->task_type = taskREADY;
371: TAILQ_INSERT_TAIL(&r->root_ready, task, task_node);
372: } else
373: r->root_eventlo_miss++;
374: } else
375: r->root_eventlo_miss = 0;
376:
377: /* OK, lets get ready task !!! */
378: if (!(task = TAILQ_FIRST(&r->root_ready)))
379: goto retry;
380: TAILQ_REMOVE(&r->root_ready, task, task_node);
381: task->task_type = taskUNUSE;
382: TAILQ_INSERT_TAIL(&r->root_unuse, task, task_node);
383: return task;
384: }
385:
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