Rev 1118 | Details | Compare with Previous | Last modification | View Log | RSS feed
Rev | Author | Line No. | Line |
---|---|---|---|
1085 | pj | 1 | /* |
2 | * Project: S.Ha.R.K. |
||
3 | * |
||
4 | * Coordinators: |
||
5 | * Giorgio Buttazzo <giorgio@sssup.it> |
||
6 | * Paolo Gai <pj@gandalf.sssup.it> |
||
7 | * |
||
8 | * Authors : |
||
9 | * Paolo Gai <pj@gandalf.sssup.it> |
||
10 | * (see the web pages for full authors list) |
||
11 | * |
||
12 | * ReTiS Lab (Scuola Superiore S.Anna - Pisa - Italy) |
||
13 | * |
||
14 | * http://www.sssup.it |
||
15 | * http://retis.sssup.it |
||
16 | * http://shark.sssup.it |
||
17 | */ |
||
18 | |||
19 | /** |
||
20 | ------------ |
||
1123 | pj | 21 | CVS : $Id: edfact.c,v 1.4 2003-01-07 17:10:15 pj Exp $ |
1085 | pj | 22 | |
23 | File: $File$ |
||
1123 | pj | 24 | Revision: $Revision: 1.4 $ |
25 | Last update: $Date: 2003-01-07 17:10:15 $ |
||
1085 | pj | 26 | ------------ |
27 | **/ |
||
28 | |||
29 | /* |
||
30 | * Copyright (C) 2001 Paolo Gai |
||
31 | * |
||
32 | * This program is free software; you can redistribute it and/or modify |
||
33 | * it under the terms of the GNU General Public License as published by |
||
34 | * the Free Software Foundation; either version 2 of the License, or |
||
35 | * (at your option) any later version. |
||
36 | * |
||
37 | * This program is distributed in the hope that it will be useful, |
||
38 | * but WITHOUT ANY WARRANTY; without even the implied warranty of |
||
39 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
||
40 | * GNU General Public License for more details. |
||
41 | * |
||
42 | * You should have received a copy of the GNU General Public License |
||
43 | * along with this program; if not, write to the Free Software |
||
44 | * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA |
||
45 | * |
||
46 | */ |
||
47 | |||
48 | #include "edfact.h" |
||
49 | #include <ll/stdio.h> |
||
50 | #include <ll/string.h> |
||
51 | #include <kernel/model.h> |
||
52 | #include <kernel/descr.h> |
||
53 | #include <kernel/var.h> |
||
54 | #include <kernel/func.h> |
||
55 | #include <kernel/trace.h> |
||
56 | |||
57 | //#define edfact_printf kern_printf |
||
58 | #define edfact_printf printk |
||
59 | |||
60 | /*+ Status used in the level +*/ |
||
61 | #define EDFACT_READY MODULE_STATUS_BASE /*+ - Ready status +*/ |
||
62 | #define EDFACT_IDLE MODULE_STATUS_BASE+4 /*+ to wait the deadline +*/ |
||
63 | |||
64 | /*+ flags +*/ |
||
65 | #define EDFACT_FLAG_NORAISEEXC 2 |
||
66 | |||
67 | /*+ the level redefinition for the Earliest Deadline First level +*/ |
||
68 | typedef struct { |
||
69 | level_des l; /*+ the standard level descriptor +*/ |
||
70 | |||
71 | TIME period[MAX_PROC]; /*+ The task periods; the deadlines are |
||
72 | stored in the priority field +*/ |
||
73 | int deadline_timer[MAX_PROC]; |
||
74 | /*+ The task deadline timers +*/ |
||
75 | |||
76 | struct timespec deadline_timespec[MAX_PROC]; |
||
77 | |||
78 | int dline_miss[MAX_PROC]; /*+ Deadline miss counter +*/ |
||
79 | int wcet_miss[MAX_PROC]; /*+ Wcet miss counter +*/ |
||
80 | |||
81 | int nact[MAX_PROC]; /*+ Wcet miss counter +*/ |
||
82 | |||
83 | int flag[MAX_PROC]; |
||
84 | /*+ used to manage the JOB_TASK_MODEL and the |
||
85 | periodicity +*/ |
||
86 | |||
1118 | pj | 87 | IQUEUE ready; /*+ the ready queue +*/ |
1085 | pj | 88 | |
89 | int flags; /*+ the init flags... +*/ |
||
90 | |||
91 | bandwidth_t U; /*+ the used bandwidth +*/ |
||
92 | |||
93 | } EDFACT_level_des; |
||
94 | |||
95 | |||
96 | static void EDFACT_timer_deadline(void *par); |
||
97 | |||
1123 | pj | 98 | static void EDFACT_internal_activate(EDFACT_level_des *lev, PID p, |
99 | struct timespec *t) |
||
1085 | pj | 100 | { |
1118 | pj | 101 | struct timespec *temp; |
102 | |||
103 | temp = iq_query_timespec(p, &lev->ready); |
||
104 | |||
1123 | pj | 105 | TIMESPEC_ASSIGN(temp,t); |
1118 | pj | 106 | ADDUSEC2TIMESPEC(lev->period[p], temp); |
1085 | pj | 107 | |
108 | TIMESPEC_ASSIGN(&lev->deadline_timespec[p], |
||
1118 | pj | 109 | temp); |
1085 | pj | 110 | |
111 | /* Insert task in the correct position */ |
||
112 | proc_table[p].status = EDFACT_READY; |
||
1118 | pj | 113 | iq_timespec_insert(p,&lev->ready); |
1085 | pj | 114 | |
115 | /* needed because when there is a wcet miss I disable CONTROL_CAP */ |
||
116 | proc_table[p].control |= CONTROL_CAP; |
||
117 | } |
||
118 | |||
119 | static void EDFACT_timer_deadline(void *par) |
||
120 | { |
||
121 | PID p = (PID) par; |
||
122 | EDFACT_level_des *lev; |
||
123 | |||
124 | lev = (EDFACT_level_des *)level_table[proc_table[p].task_level]; |
||
125 | |||
126 | switch (proc_table[p].status) { |
||
127 | case EDFACT_IDLE: |
||
128 | edfact_printf("I%d",p); |
||
129 | |||
1123 | pj | 130 | EDFACT_internal_activate(lev,p, &lev->deadline_timespec[p]); |
1118 | pj | 131 | |
1085 | pj | 132 | event_need_reschedule(); |
133 | break; |
||
134 | |||
135 | default: |
||
136 | edfact_printf("D%d",p); |
||
137 | /* else, a deadline miss occurred!!! */ |
||
138 | lev->dline_miss[p]++; |
||
139 | |||
140 | /* the task is into another state */ |
||
141 | lev->nact[p]++; |
||
142 | |||
143 | /* Set the deadline timer */ |
||
144 | ADDUSEC2TIMESPEC(lev->period[p], &lev->deadline_timespec[p]); |
||
145 | } |
||
146 | |||
147 | /* Set the deadline timer */ |
||
148 | lev->deadline_timer[p] = kern_event_post(&lev->deadline_timespec[p], |
||
149 | EDFACT_timer_deadline, |
||
150 | (void *)p); |
||
151 | |||
152 | } |
||
153 | |||
154 | static void EDFACT_timer_guest_deadline(void *par) |
||
155 | { |
||
156 | PID p = (PID) par; |
||
157 | |||
158 | edfact_printf("AAARRRGGGHHH!!!"); |
||
159 | kern_raise(XDEADLINE_MISS,p); |
||
160 | } |
||
161 | |||
162 | |||
163 | /* The scheduler only gets the first task in the queue */ |
||
1123 | pj | 164 | static PID EDFACT_public_scheduler(LEVEL l) |
1085 | pj | 165 | { |
166 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
167 | |||
1118 | pj | 168 | return iq_query_first(&lev->ready); |
1085 | pj | 169 | } |
170 | |||
171 | /* The on-line guarantee is enabled only if the appropriate flag is set... */ |
||
1123 | pj | 172 | static int EDFACT_public_guarantee(LEVEL l, bandwidth_t *freebandwidth) |
1085 | pj | 173 | { |
174 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
175 | |||
176 | if (lev->flags & EDFACT_FAILED_GUARANTEE) { |
||
177 | *freebandwidth = 0; |
||
178 | return 0; |
||
179 | } |
||
180 | else |
||
181 | if (*freebandwidth >= lev->U) { |
||
182 | *freebandwidth -= lev->U; |
||
183 | return 1; |
||
184 | } |
||
185 | else |
||
186 | return 0; |
||
187 | |||
188 | } |
||
189 | |||
1123 | pj | 190 | static int EDFACT_public_create(LEVEL l, PID p, TASK_MODEL *m) |
1085 | pj | 191 | { |
192 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
193 | |||
1123 | pj | 194 | HARD_TASK_MODEL *h; |
1085 | pj | 195 | |
1123 | pj | 196 | if (m->pclass != HARD_PCLASS) return -1; |
197 | if (m->level != 0 && m->level != l) return -1; |
||
198 | h = (HARD_TASK_MODEL *)m; |
||
199 | if (!h->wcet || !h->mit || h->periodicity != PERIODIC) return -1; |
||
200 | /* now we know that m is a valid model */ |
||
1085 | pj | 201 | |
202 | lev->period[p] = h->mit; |
||
203 | |||
204 | lev->flag[p] = 0; |
||
205 | lev->deadline_timer[p] = -1; |
||
206 | lev->dline_miss[p] = 0; |
||
207 | lev->wcet_miss[p] = 0; |
||
208 | lev->nact[p] = 0; |
||
209 | |||
210 | /* Enable wcet check */ |
||
211 | proc_table[p].avail_time = h->wcet; |
||
212 | proc_table[p].wcet = h->wcet; |
||
213 | proc_table[p].control |= CONTROL_CAP; |
||
214 | |||
215 | /* update the bandwidth... */ |
||
216 | if (lev->flags & EDFACT_ENABLE_GUARANTEE) { |
||
217 | bandwidth_t b; |
||
218 | b = (MAX_BANDWIDTH / h->mit) * h->wcet; |
||
219 | |||
220 | /* really update lev->U, checking an overflow... */ |
||
221 | if (MAX_BANDWIDTH - lev->U > b) |
||
222 | lev->U += b; |
||
223 | else |
||
224 | /* The task can NOT be guaranteed (U>MAX_BANDWIDTH)... |
||
225 | in this case, we don't raise an exception... in fact, after the |
||
226 | EDFACT_task_create the task_create will call level_guarantee that return |
||
227 | -1... return -1 in EDFACT_task_create isn't correct, because: |
||
228 | . generally, the guarantee must be done when also the resources |
||
229 | are registered |
||
230 | . returning -1 will cause the task_create to return with an errno |
||
231 | ETASK_CREATE instead of ENO_GUARANTEE!!! |
||
232 | |||
233 | Why I use the flag??? because if the lev->U overflows, if i.e. I set |
||
234 | it to MAX_BANDWIDTH, I lose the correct allocated bandwidth... |
||
235 | */ |
||
236 | lev->flags |= EDFACT_FAILED_GUARANTEE; |
||
237 | } |
||
238 | |||
239 | return 0; /* OK, also if the task cannot be guaranteed... */ |
||
240 | } |
||
241 | |||
1123 | pj | 242 | static void EDFACT_public_detach(LEVEL l, PID p) |
1085 | pj | 243 | { |
244 | /* the EDFACT level doesn't introduce any dinamic allocated new field. |
||
245 | we have only to reset the NO_GUARANTEE FIELD and decrement the allocated |
||
246 | bandwidth */ |
||
247 | |||
248 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
249 | |||
250 | if (lev->flags & EDFACT_FAILED_GUARANTEE) |
||
251 | lev->flags &= ~EDFACT_FAILED_GUARANTEE; |
||
252 | else |
||
253 | lev->U -= (MAX_BANDWIDTH / lev->period[p]) * proc_table[p].wcet; |
||
254 | } |
||
255 | |||
1123 | pj | 256 | static void EDFACT_public_dispatch(LEVEL l, PID p, int nostop) |
1085 | pj | 257 | { |
258 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
259 | |||
260 | /* the task state is set EXE by the scheduler() |
||
261 | we extract the task from the ready queue |
||
262 | NB: we can't assume that p is the first task in the queue!!! */ |
||
1118 | pj | 263 | iq_extract(p, &lev->ready); |
1085 | pj | 264 | } |
265 | |||
1123 | pj | 266 | static void EDFACT_public_epilogue(LEVEL l, PID p) |
1085 | pj | 267 | { |
268 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
269 | |||
270 | /* check if the wcet is finished... */ |
||
271 | if (proc_table[p].avail_time <= 0 && proc_table[p].control&CONTROL_CAP) { |
||
272 | /* wcet finished: disable wcet event and count wcet miss */ |
||
273 | edfact_printf("W%d",p); |
||
274 | proc_table[p].control &= ~CONTROL_CAP; |
||
275 | lev->wcet_miss[p]++; |
||
276 | } |
||
277 | |||
278 | /* the task it returns into the ready queue... */ |
||
1118 | pj | 279 | iq_timespec_insert(p,&lev->ready); |
1085 | pj | 280 | proc_table[p].status = EDFACT_READY; |
281 | } |
||
282 | |||
1123 | pj | 283 | static void EDFACT_public_activate(LEVEL l, PID p) |
1085 | pj | 284 | { |
285 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 286 | struct timespec t; |
1085 | pj | 287 | |
288 | /* Test if we are trying to activate a non sleeping task */ |
||
289 | /* save activation (only if needed... */ |
||
290 | if (proc_table[p].status != SLEEP) { |
||
291 | /* a periodic task cannot be activated when it is already active */ |
||
292 | kern_raise(XACTIVATION,p); |
||
293 | return; |
||
294 | } |
||
295 | |||
1123 | pj | 296 | kern_gettime(&t); |
297 | EDFACT_internal_activate(lev,p, &t); |
||
1085 | pj | 298 | |
299 | /* Set the deadline timer */ |
||
300 | lev->deadline_timer[p] = kern_event_post(&lev->deadline_timespec[p], |
||
301 | EDFACT_timer_deadline, |
||
302 | (void *)p); |
||
303 | |||
304 | } |
||
305 | |||
1123 | pj | 306 | static void EDFACT_public_unblock(LEVEL l, PID p) |
1085 | pj | 307 | { |
308 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
309 | |||
310 | /* Insert task in the coEDFect position */ |
||
311 | proc_table[p].status = EDFACT_READY; |
||
1118 | pj | 312 | iq_timespec_insert(p,&lev->ready); |
1085 | pj | 313 | } |
314 | |||
1123 | pj | 315 | static void EDFACT_public_block(LEVEL l, PID p) |
1085 | pj | 316 | { |
317 | } |
||
318 | |||
1123 | pj | 319 | static int EDFACT_public_message(LEVEL l, PID p, void *m) |
1085 | pj | 320 | { |
321 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 322 | struct timespec t; |
1085 | pj | 323 | |
324 | /* we reset the capacity counters... */ |
||
325 | proc_table[p].avail_time = proc_table[p].wcet; |
||
326 | |||
327 | if (lev->nact[p] > 0) { |
||
328 | edfact_printf("E%d",p); |
||
329 | |||
330 | /* Pending activation: reactivate the thread!!! */ |
||
331 | lev->nact[p]--; |
||
332 | |||
333 | /* see also EDFACT_timer_deadline */ |
||
1123 | pj | 334 | kern_gettime(&t); |
335 | EDFACT_internal_activate(lev,p, &t); |
||
1085 | pj | 336 | |
337 | /* check if the deadline has already expired */ |
||
1118 | pj | 338 | if (TIMESPEC_A_LT_B(iq_query_timespec(p, &lev->ready), &schedule_time)) { |
1085 | pj | 339 | /* count the deadline miss */ |
340 | lev->dline_miss[p]++; |
||
1123 | pj | 341 | kern_event_delete(lev->deadline_timer[p]); |
1085 | pj | 342 | } |
343 | |||
344 | } |
||
345 | else { |
||
346 | edfact_printf("e%d",p); |
||
347 | |||
348 | /* the task has terminated his job before it consume the wcet. All OK! */ |
||
349 | proc_table[p].status = EDFACT_IDLE; |
||
350 | |||
351 | /* when the deadline timer fire, it recognize the situation and set |
||
1123 | pj | 352 | correctly all the stuffs (like reactivation, etc... ) */ |
1085 | pj | 353 | } |
1123 | pj | 354 | |
355 | jet_update_endcycle(); /* Update the Jet data... */ |
||
356 | trc_logevent(TRC_ENDCYCLE,&exec_shadow); /* tracer stuff */ |
||
357 | |||
358 | return 0; |
||
1085 | pj | 359 | } |
360 | |||
1123 | pj | 361 | static void EDFACT_public_end(LEVEL l, PID p) |
1085 | pj | 362 | { |
363 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
364 | |||
365 | edfact_printf("Û%d",p); |
||
366 | |||
367 | /* we finally put the task in the ready queue */ |
||
368 | proc_table[p].status = FREE; |
||
1118 | pj | 369 | iq_insertfirst(p,&freedesc); |
1085 | pj | 370 | /* and free the allocated bandwidth */ |
371 | lev->U -= (MAX_BANDWIDTH/lev->period[p]) * proc_table[p].wcet; |
||
372 | |||
373 | if (lev->deadline_timer[p] != -1) { |
||
374 | edfact_printf("²%d",p); |
||
1123 | pj | 375 | kern_event_delete(lev->deadline_timer[p]); |
1085 | pj | 376 | } |
377 | } |
||
378 | |||
379 | |||
380 | /* Guest Functions |
||
381 | These functions manages a JOB_TASK_MODEL, that is used to put |
||
382 | a guest task in the EDFACT ready queue. */ |
||
383 | |||
1123 | pj | 384 | static void EDFACT_private_insert(LEVEL l, PID p, TASK_MODEL *m) |
1085 | pj | 385 | { |
386 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
387 | |||
1123 | pj | 388 | JOB_TASK_MODEL *job; |
1085 | pj | 389 | |
1123 | pj | 390 | if (m->pclass != JOB_PCLASS || (m->level != 0 && m->level != l) ) { |
391 | kern_raise(XINVALID_TASK, p); |
||
392 | return; |
||
393 | } |
||
394 | |||
395 | job = (JOB_TASK_MODEL *)m; |
||
396 | |||
1118 | pj | 397 | TIMESPEC_ASSIGN(iq_query_timespec(p, &lev->ready), &job->deadline); |
1085 | pj | 398 | |
399 | lev->deadline_timer[p] = -1; |
||
400 | lev->dline_miss[p] = 0; |
||
401 | lev->wcet_miss[p] = 0; |
||
402 | lev->nact[p] = 0; |
||
403 | |||
404 | if (job->noraiseexc) |
||
405 | lev->flag[p] = EDFACT_FLAG_NORAISEEXC; |
||
1123 | pj | 406 | else { |
1085 | pj | 407 | lev->flag[p] = 0; |
1123 | pj | 408 | lev->deadline_timer[p] = kern_event_post(iq_query_timespec(p, &lev->ready), |
409 | EDFACT_timer_guest_deadline, |
||
410 | (void *)p); |
||
411 | } |
||
1085 | pj | 412 | |
413 | lev->period[p] = job->period; |
||
414 | |||
1123 | pj | 415 | /* Insert task in the correct position */ |
416 | iq_timespec_insert(p,&lev->ready); |
||
417 | proc_table[p].status = EDFACT_READY; |
||
418 | |||
1085 | pj | 419 | /* there is no bandwidth guarantee at this level, it is performed |
420 | by the level that inserts guest tasks... */ |
||
421 | } |
||
422 | |||
1123 | pj | 423 | static void EDFACT_private_dispatch(LEVEL l, PID p, int nostop) |
1085 | pj | 424 | { |
425 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
426 | |||
427 | /* the task state is set to EXE by the scheduler() |
||
428 | we extract the task from the ready queue |
||
429 | NB: we can't assume that p is the first task in the queue!!! */ |
||
1118 | pj | 430 | iq_extract(p, &lev->ready); |
1085 | pj | 431 | } |
432 | |||
1123 | pj | 433 | static void EDFACT_private_epilogue(LEVEL l, PID p) |
1085 | pj | 434 | { |
435 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
436 | |||
437 | /* the task has been preempted. it returns into the ready queue... */ |
||
1118 | pj | 438 | iq_timespec_insert(p,&lev->ready); |
1085 | pj | 439 | proc_table[p].status = EDFACT_READY; |
440 | } |
||
441 | |||
1123 | pj | 442 | static void EDFACT_private_extract(LEVEL l, PID p) |
1085 | pj | 443 | { |
444 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
445 | |||
446 | //kern_printf("EDFACT_guest_end: dline timer %d\n",lev->deadline_timer[p]); |
||
447 | if (proc_table[p].status == EDFACT_READY) |
||
448 | { |
||
1118 | pj | 449 | iq_extract(p, &lev->ready); |
1085 | pj | 450 | //kern_printf("(g_end rdy extr)"); |
451 | } |
||
452 | |||
453 | /* we remove the deadline timer, because the slice is finished */ |
||
454 | if (lev->deadline_timer[p] != NIL) { |
||
455 | // kern_printf("EDFACT_guest_end: dline timer %d\n",lev->deadline_timer[p]); |
||
1123 | pj | 456 | kern_event_delete(lev->deadline_timer[p]); |
1085 | pj | 457 | lev->deadline_timer[p] = NIL; |
458 | } |
||
459 | |||
460 | } |
||
461 | |||
462 | /* Registration functions */ |
||
463 | |||
464 | /*+ Registration function: |
||
465 | int flags the init flags ... see EDFACT.h +*/ |
||
1123 | pj | 466 | LEVEL EDFACT_register_level(int flags) |
1085 | pj | 467 | { |
468 | LEVEL l; /* the level that we register */ |
||
469 | EDFACT_level_des *lev; /* for readableness only */ |
||
470 | PID i; /* a counter */ |
||
471 | |||
472 | printk("EDFACT_register_level\n"); |
||
473 | |||
474 | /* request an entry in the level_table */ |
||
1123 | pj | 475 | l = level_alloc_descriptor(sizeof(EDFACT_level_des)); |
1085 | pj | 476 | |
1123 | pj | 477 | lev = (EDFACT_level_des *)level_table[l]; |
1085 | pj | 478 | |
479 | printk(" lev=%d\n",(int)lev); |
||
480 | |||
481 | /* fill the standard descriptor */ |
||
1123 | pj | 482 | lev->l.private_insert = EDFACT_private_insert; |
483 | lev->l.private_extract = EDFACT_private_extract; |
||
484 | lev->l.private_dispatch = EDFACT_private_dispatch; |
||
485 | lev->l.private_epilogue = EDFACT_private_epilogue; |
||
1085 | pj | 486 | |
1123 | pj | 487 | lev->l.public_scheduler = EDFACT_public_scheduler; |
1085 | pj | 488 | if (flags & EDFACT_ENABLE_GUARANTEE) |
1123 | pj | 489 | lev->l.public_guarantee = EDFACT_public_guarantee; |
1085 | pj | 490 | else |
1123 | pj | 491 | lev->l.public_guarantee = NULL; |
492 | lev->l.public_create = EDFACT_public_create; |
||
493 | lev->l.public_detach = EDFACT_public_detach; |
||
494 | lev->l.public_end = EDFACT_public_end; |
||
495 | lev->l.public_dispatch = EDFACT_public_dispatch; |
||
496 | lev->l.public_epilogue = EDFACT_public_epilogue; |
||
497 | lev->l.public_activate = EDFACT_public_activate; |
||
498 | lev->l.public_unblock = EDFACT_public_unblock; |
||
499 | lev->l.public_block = EDFACT_public_block; |
||
500 | lev->l.public_message = EDFACT_public_message; |
||
1085 | pj | 501 | |
502 | /* fill the EDFACT descriptor part */ |
||
503 | for(i=0; i<MAX_PROC; i++) { |
||
504 | lev->period[i] = 0; |
||
505 | lev->deadline_timer[i] = -1; |
||
506 | lev->flag[i] = 0; |
||
507 | lev->dline_miss[i] = 0; |
||
508 | lev->wcet_miss[i] = 0; |
||
509 | lev->nact[i] = 0; |
||
510 | } |
||
511 | |||
1118 | pj | 512 | iq_init(&lev->ready,&freedesc, 0); |
1085 | pj | 513 | lev->flags = flags & 0x07; |
514 | lev->U = 0; |
||
1123 | pj | 515 | |
516 | return l; |
||
1085 | pj | 517 | } |
518 | |||
519 | bandwidth_t EDFACT_usedbandwidth(LEVEL l) |
||
520 | { |
||
521 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 522 | |
523 | return lev->U; |
||
1085 | pj | 524 | } |
525 | |||
526 | int EDFACT_get_dline_miss(PID p) |
||
527 | { |
||
528 | LEVEL l = proc_table[p].task_level; |
||
529 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 530 | |
531 | return lev->dline_miss[p]; |
||
1085 | pj | 532 | } |
533 | |||
534 | int EDFACT_get_wcet_miss(PID p) |
||
535 | { |
||
536 | LEVEL l = proc_table[p].task_level; |
||
537 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 538 | |
539 | return lev->wcet_miss[p]; |
||
1085 | pj | 540 | } |
541 | |||
542 | int EDFACT_get_nact(PID p) |
||
543 | { |
||
544 | LEVEL l = proc_table[p].task_level; |
||
545 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 546 | |
547 | return lev->nact[p]; |
||
1085 | pj | 548 | } |
549 | |||
550 | int EDFACT_reset_dline_miss(PID p) |
||
551 | { |
||
552 | LEVEL l = proc_table[p].task_level; |
||
553 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 554 | |
555 | lev->dline_miss[p] = 0; |
||
556 | return 0; |
||
1085 | pj | 557 | } |
558 | |||
559 | int EDFACT_reset_wcet_miss(PID p) |
||
560 | { |
||
561 | LEVEL l = proc_table[p].task_level; |
||
562 | EDFACT_level_des *lev = (EDFACT_level_des *)(level_table[l]); |
||
1123 | pj | 563 | |
564 | lev->wcet_miss[p] = 0; |
||
565 | return 0; |
||
1085 | pj | 566 | } |
567 |