s3: signals are processed twice in child.
[Samba/gbeck.git] / lib / tevent / tevent_signal.c
blob45f65cf6dddf9e3f45cb1554c8e80c75474302ab
1 /*
2 Unix SMB/CIFS implementation.
4 common events code for signal events
6 Copyright (C) Andrew Tridgell 2007
8 ** NOTE! The following LGPL license applies to the tevent
9 ** library. This does NOT imply that all of Samba is released
10 ** under the LGPL
12 This library is free software; you can redistribute it and/or
13 modify it under the terms of the GNU Lesser General Public
14 License as published by the Free Software Foundation; either
15 version 3 of the License, or (at your option) any later version.
17 This library is distributed in the hope that it will be useful,
18 but WITHOUT ANY WARRANTY; without even the implied warranty of
19 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
20 Lesser General Public License for more details.
22 You should have received a copy of the GNU Lesser General Public
23 License along with this library; if not, see <http://www.gnu.org/licenses/>.
26 #include "replace.h"
27 #include "system/filesys.h"
28 #include "system/wait.h"
29 #include "tevent.h"
30 #include "tevent_internal.h"
31 #include "tevent_util.h"
33 #define TEVENT_NUM_SIGNALS 64
35 /* maximum number of SA_SIGINFO signals to hold in the queue.
36 NB. This *MUST* be a power of 2, in order for the ring buffer
37 wrap to work correctly. Thanks to Petr Vandrovec <petr@vandrovec.name>
38 for this. */
40 #define TEVENT_SA_INFO_QUEUE_COUNT 64
42 struct tevent_sigcounter {
43 uint32_t count;
44 uint32_t seen;
47 #define TEVENT_SIG_INCREMENT(s) (s).count++
48 #define TEVENT_SIG_SEEN(s, n) (s).seen += (n)
49 #define TEVENT_SIG_PENDING(s) ((s).seen != (s).count)
51 struct tevent_common_signal_list {
52 struct tevent_common_signal_list *prev, *next;
53 struct tevent_signal *se;
57 the poor design of signals means that this table must be static global
59 static struct tevent_sig_state {
60 struct tevent_common_signal_list *sig_handlers[TEVENT_NUM_SIGNALS+1];
61 struct sigaction *oldact[TEVENT_NUM_SIGNALS+1];
62 struct tevent_sigcounter signal_count[TEVENT_NUM_SIGNALS+1];
63 struct tevent_sigcounter got_signal;
64 #ifdef SA_SIGINFO
65 /* with SA_SIGINFO we get quite a lot of info per signal */
66 siginfo_t *sig_info[TEVENT_NUM_SIGNALS+1];
67 struct tevent_sigcounter sig_blocked[TEVENT_NUM_SIGNALS+1];
68 #endif
69 } *sig_state;
72 return number of sigcounter events not processed yet
74 static uint32_t tevent_sig_count(struct tevent_sigcounter s)
76 return s.count - s.seen;
80 signal handler - redirects to registered signals
82 static void tevent_common_signal_handler(int signum)
84 char c = 0;
85 ssize_t res;
86 struct tevent_common_signal_list *sl;
87 struct tevent_context *ev = NULL;
88 int saved_errno = errno;
90 TEVENT_SIG_INCREMENT(sig_state->signal_count[signum]);
91 TEVENT_SIG_INCREMENT(sig_state->got_signal);
93 /* Write to each unique event context. */
94 for (sl = sig_state->sig_handlers[signum]; sl; sl = sl->next) {
95 if (sl->se->event_ctx && sl->se->event_ctx != ev) {
96 ev = sl->se->event_ctx;
97 /* doesn't matter if this pipe overflows */
98 res = write(ev->pipe_fds[1], &c, 1);
102 errno = saved_errno;
105 #ifdef SA_SIGINFO
107 signal handler with SA_SIGINFO - redirects to registered signals
109 static void tevent_common_signal_handler_info(int signum, siginfo_t *info,
110 void *uctx)
112 uint32_t count = tevent_sig_count(sig_state->signal_count[signum]);
113 /* sig_state->signal_count[signum].seen % TEVENT_SA_INFO_QUEUE_COUNT
114 * is the base of the unprocessed signals in the ringbuffer. */
115 uint32_t ofs = (sig_state->signal_count[signum].seen + count) %
116 TEVENT_SA_INFO_QUEUE_COUNT;
117 sig_state->sig_info[signum][ofs] = *info;
119 tevent_common_signal_handler(signum);
121 /* handle SA_SIGINFO */
122 if (count+1 == TEVENT_SA_INFO_QUEUE_COUNT) {
123 /* we've filled the info array - block this signal until
124 these ones are delivered */
125 sigset_t set;
126 sigemptyset(&set);
127 sigaddset(&set, signum);
128 sigprocmask(SIG_BLOCK, &set, NULL);
129 TEVENT_SIG_INCREMENT(sig_state->sig_blocked[signum]);
132 #endif
134 static int tevent_common_signal_list_destructor(struct tevent_common_signal_list *sl)
136 if (sig_state->sig_handlers[sl->se->signum]) {
137 DLIST_REMOVE(sig_state->sig_handlers[sl->se->signum], sl);
139 return 0;
143 destroy a signal event
145 static int tevent_signal_destructor(struct tevent_signal *se)
147 struct tevent_common_signal_list *sl;
148 sl = talloc_get_type(se->additional_data,
149 struct tevent_common_signal_list);
151 if (se->event_ctx) {
152 DLIST_REMOVE(se->event_ctx->signal_events, se);
155 talloc_free(sl);
157 if (sig_state->sig_handlers[se->signum] == NULL) {
158 /* restore old handler, if any */
159 if (sig_state->oldact[se->signum]) {
160 sigaction(se->signum, sig_state->oldact[se->signum], NULL);
161 sig_state->oldact[se->signum] = NULL;
163 #ifdef SA_SIGINFO
164 if (se->sa_flags & SA_SIGINFO) {
165 if (sig_state->sig_info[se->signum]) {
166 talloc_free(sig_state->sig_info[se->signum]);
167 sig_state->sig_info[se->signum] = NULL;
170 #endif
173 return 0;
177 this is part of the pipe hack needed to avoid the signal race condition
179 static void signal_pipe_handler(struct tevent_context *ev, struct tevent_fd *fde,
180 uint16_t flags, void *_private)
182 char c[16];
183 ssize_t res;
184 /* its non-blocking, doesn't matter if we read too much */
185 res = read(fde->fd, c, sizeof(c));
189 add a signal event
190 return NULL on failure (memory allocation error)
192 struct tevent_signal *tevent_common_add_signal(struct tevent_context *ev,
193 TALLOC_CTX *mem_ctx,
194 int signum,
195 int sa_flags,
196 tevent_signal_handler_t handler,
197 void *private_data,
198 const char *handler_name,
199 const char *location)
201 struct tevent_signal *se;
202 struct tevent_common_signal_list *sl;
203 sigset_t set, oldset;
205 if (signum >= TEVENT_NUM_SIGNALS) {
206 errno = EINVAL;
207 return NULL;
210 /* the sig_state needs to be on a global context as it can last across
211 multiple event contexts */
212 if (sig_state == NULL) {
213 sig_state = talloc_zero(talloc_autofree_context(), struct tevent_sig_state);
214 if (sig_state == NULL) {
215 return NULL;
219 se = talloc(mem_ctx?mem_ctx:ev, struct tevent_signal);
220 if (se == NULL) return NULL;
222 se->event_ctx = ev;
223 se->signum = signum;
224 se->sa_flags = sa_flags;
225 se->handler = handler;
226 se->private_data = private_data;
227 se->handler_name = handler_name;
228 se->location = location;
229 se->additional_data = NULL;
231 sl = talloc(se, struct tevent_common_signal_list);
232 if (!sl) {
233 talloc_free(se);
234 return NULL;
236 sl->se = se;
237 se->additional_data = sl;
239 /* Ensure, no matter the destruction order, that we always have a handle on the global sig_state */
240 if (!talloc_reference(se, sig_state)) {
241 talloc_free(se);
242 return NULL;
245 /* we need to setup the pipe hack handler if not already
246 setup */
247 if (ev->pipe_fde == NULL) {
248 if (pipe(ev->pipe_fds) == -1) {
249 talloc_free(se);
250 return NULL;
252 ev_set_blocking(ev->pipe_fds[0], false);
253 ev_set_blocking(ev->pipe_fds[1], false);
254 ev->pipe_fde = tevent_add_fd(ev, ev, ev->pipe_fds[0],
255 TEVENT_FD_READ,
256 signal_pipe_handler, NULL);
257 if (!ev->pipe_fde) {
258 close(ev->pipe_fds[0]);
259 close(ev->pipe_fds[1]);
260 talloc_free(se);
261 return NULL;
265 /* only install a signal handler if not already installed */
266 if (sig_state->sig_handlers[signum] == NULL) {
267 struct sigaction act;
268 ZERO_STRUCT(act);
269 act.sa_handler = tevent_common_signal_handler;
270 act.sa_flags = sa_flags;
271 #ifdef SA_SIGINFO
272 if (sa_flags & SA_SIGINFO) {
273 act.sa_handler = NULL;
274 act.sa_sigaction = tevent_common_signal_handler_info;
275 if (sig_state->sig_info[signum] == NULL) {
276 sig_state->sig_info[signum] =
277 talloc_zero_array(sig_state, siginfo_t,
278 TEVENT_SA_INFO_QUEUE_COUNT);
279 if (sig_state->sig_info[signum] == NULL) {
280 talloc_free(se);
281 return NULL;
285 #endif
286 sig_state->oldact[signum] = talloc(sig_state, struct sigaction);
287 if (sig_state->oldact[signum] == NULL) {
288 talloc_free(se);
289 return NULL;
291 if (sigaction(signum, &act, sig_state->oldact[signum]) == -1) {
292 talloc_free(se);
293 return NULL;
297 DLIST_ADD(se->event_ctx->signal_events, se);
299 /* Make sure the signal doesn't come in while we're mangling list. */
300 sigemptyset(&set);
301 sigaddset(&set, signum);
302 sigprocmask(SIG_BLOCK, &set, &oldset);
303 DLIST_ADD(sig_state->sig_handlers[signum], sl);
304 sigprocmask(SIG_SETMASK, &oldset, NULL);
306 talloc_set_destructor(se, tevent_signal_destructor);
307 talloc_set_destructor(sl, tevent_common_signal_list_destructor);
309 return se;
314 check if a signal is pending
315 return != 0 if a signal was pending
317 int tevent_common_check_signal(struct tevent_context *ev)
319 int i;
321 if (!sig_state || !TEVENT_SIG_PENDING(sig_state->got_signal)) {
322 return 0;
325 for (i=0;i<TEVENT_NUM_SIGNALS+1;i++) {
326 struct tevent_common_signal_list *sl, *next;
327 struct tevent_sigcounter counter = sig_state->signal_count[i];
328 uint32_t count = tevent_sig_count(counter);
329 #ifdef SA_SIGINFO
330 /* Ensure we null out any stored siginfo_t entries
331 * after processing for debugging purposes. */
332 bool clear_processed_siginfo = false;
333 #endif
335 if (count == 0) {
336 continue;
338 for (sl=sig_state->sig_handlers[i];sl;sl=next) {
339 struct tevent_signal *se = sl->se;
340 next = sl->next;
341 #ifdef SA_SIGINFO
342 if (se->sa_flags & SA_SIGINFO) {
343 uint32_t j;
345 clear_processed_siginfo = true;
347 for (j=0;j<count;j++) {
348 /* sig_state->signal_count[i].seen
349 * % TEVENT_SA_INFO_QUEUE_COUNT is
350 * the base position of the unprocessed
351 * signals in the ringbuffer. */
352 uint32_t ofs = (counter.seen + j)
353 % TEVENT_SA_INFO_QUEUE_COUNT;
354 se->handler(ev, se, i, 1,
355 (void*)&sig_state->sig_info[i][ofs],
356 se->private_data);
358 if (se->sa_flags & SA_RESETHAND) {
359 talloc_free(se);
361 continue;
363 #endif
364 se->handler(ev, se, i, count, NULL, se->private_data);
365 if (se->sa_flags & SA_RESETHAND) {
366 talloc_free(se);
370 #ifdef SA_SIGINFO
371 if (clear_processed_siginfo) {
372 uint32_t j;
373 for (j=0;j<count;j++) {
374 uint32_t ofs = (counter.seen + j)
375 % TEVENT_SA_INFO_QUEUE_COUNT;
376 memset((void*)&sig_state->sig_info[i][ofs],
377 '\0',
378 sizeof(siginfo_t));
381 #endif
383 TEVENT_SIG_SEEN(sig_state->signal_count[i], count);
384 TEVENT_SIG_SEEN(sig_state->got_signal, count);
386 #ifdef SA_SIGINFO
387 if (TEVENT_SIG_PENDING(sig_state->sig_blocked[i])) {
388 /* We'd filled the queue, unblock the
389 signal now the queue is empty again.
390 Note we MUST do this after the
391 TEVENT_SIG_SEEN(sig_state->signal_count[i], count)
392 call to prevent a new signal running
393 out of room in the sig_state->sig_info[i][]
394 ring buffer. */
395 sigset_t set;
396 sigemptyset(&set);
397 sigaddset(&set, i);
398 TEVENT_SIG_SEEN(sig_state->sig_blocked[i],
399 tevent_sig_count(sig_state->sig_blocked[i]));
400 sigprocmask(SIG_UNBLOCK, &set, NULL);
402 #endif
405 return 1;
408 void tevent_cleanup_pending_signal_handlers(struct tevent_signal *se)
410 struct tevent_common_signal_list *sl;
411 sl = talloc_get_type(se->additional_data,
412 struct tevent_common_signal_list);
414 tevent_common_signal_list_destructor(sl);
416 if (sig_state->sig_handlers[se->signum] == NULL) {
417 if (sig_state->oldact[se->signum]) {
418 sigaction(se->signum, sig_state->oldact[se->signum], NULL);
419 sig_state->oldact[se->signum] = NULL;
422 return;