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s3-clitar: Fix identation.
[Samba/wip.git] / ctdb / server / ctdb_takeover.c
blobd2b2a9e1e1f666f89a8850693456742de8cbc42c
1 /*
2 ctdb ip takeover code
3
4 Copyright (C) Ronnie Sahlberg 2007
5 Copyright (C) Andrew Tridgell 2007
6 Copyright (C) Martin Schwenke 2011
7
8 This program is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3 of the License, or
11 (at your option) any later version.
12
13 This program is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
17
18 You should have received a copy of the GNU General Public License
19 along with this program; if not, see <http://www.gnu.org/licenses/>.
20 */
21 #include "includes.h"
22 #include "tdb.h"
23 #include "lib/util/dlinklist.h"
24 #include "system/network.h"
25 #include "system/filesys.h"
26 #include "system/wait.h"
27 #include "../include/ctdb_private.h"
28 #include "../common/rb_tree.h"
29
30
31 #define TAKEOVER_TIMEOUT() timeval_current_ofs(ctdb->tunable.takeover_timeout,0)
32
33 #define CTDB_ARP_INTERVAL 1
34 #define CTDB_ARP_REPEAT 3
35
36 /* Flags used in IP allocation algorithms. */
37 struct ctdb_ipflags {
38 bool noiptakeover;
39 bool noiphost;
40 };
41
42 struct ctdb_iface {
43 struct ctdb_iface *prev, *next;
44 const char *name;
45 bool link_up;
46 uint32_t references;
47 };
48
49 static const char *ctdb_vnn_iface_string(const struct ctdb_vnn *vnn)
50 {
51 if (vnn->iface) {
52 return vnn->iface->name;
53 }
54
55 return "__none__";
56 }
57
58 static int ctdb_add_local_iface(struct ctdb_context *ctdb, const char *iface)
59 {
60 struct ctdb_iface *i;
61
62 /* Verify that we dont have an entry for this ip yet */
63 for (i=ctdb->ifaces;i;i=i->next) {
64 if (strcmp(i->name, iface) == 0) {
65 return 0;
66 }
67 }
68
69 /* create a new structure for this interface */
70 i = talloc_zero(ctdb, struct ctdb_iface);
71 CTDB_NO_MEMORY_FATAL(ctdb, i);
72 i->name = talloc_strdup(i, iface);
73 CTDB_NO_MEMORY(ctdb, i->name);
74 /*
75 * If link_up defaults to true then IPs can be allocated to a
76 * node during the first recovery. However, then an interface
77 * could have its link marked down during the startup event,
78 * causing the IP to move almost immediately. If link_up
79 * defaults to false then, during normal operation, IPs added
80 * to a new interface can't be assigned until a monitor cycle
81 * has occurred and marked the new interfaces up. This makes
82 * IP allocation unpredictable. The following is a neat
83 * compromise: early in startup link_up defaults to false, so
84 * IPs can't be assigned, and after startup IPs can be
85 * assigned immediately.
86 */
87 i->link_up = (ctdb->runstate == CTDB_RUNSTATE_RUNNING);
88
89 DLIST_ADD(ctdb->ifaces, i);
90
91 return 0;
92 }
93
94 static bool vnn_has_interface_with_name(struct ctdb_vnn *vnn,
95 const char *name)
96 {
97 int n;
98
99 for (n = 0; vnn->ifaces[n] != NULL; n++) {
100 if (strcmp(name, vnn->ifaces[n]) == 0) {
101 return true;
102 }
103 }
104
105 return false;
106 }
107
108 /* If any interfaces now have no possible IPs then delete them. This
109 * implementation is naive (i.e. simple) rather than clever
110 * (i.e. complex). Given that this is run on delip and that operation
111 * is rare, this doesn't need to be efficient - it needs to be
112 * foolproof. One alternative is reference counting, where the logic
113 * is distributed and can, therefore, be broken in multiple places.
114 * Another alternative is to build a red-black tree of interfaces that
115 * can have addresses (by walking ctdb->vnn and ctdb->single_ip_vnn
116 * once) and then walking ctdb->ifaces once and deleting those not in
117 * the tree. Let's go to one of those if the naive implementation
118 * causes problems... :-)
119 */
120 static void ctdb_remove_orphaned_ifaces(struct ctdb_context *ctdb,
121 struct ctdb_vnn *vnn,
122 TALLOC_CTX *mem_ctx)
123 {
124 struct ctdb_iface *i;
125
126 /* For each interface, check if there's an IP using it. */
127 for(i=ctdb->ifaces; i; i=i->next) {
128 struct ctdb_vnn *tv;
129 bool found;
130
131 /* Only consider interfaces named in the given VNN. */
132 if (!vnn_has_interface_with_name(vnn, i->name)) {
133 continue;
134 }
135
136 /* Is the "single IP" on this interface? */
137 if ((ctdb->single_ip_vnn != NULL) &&
138 (ctdb->single_ip_vnn->ifaces[0] != NULL) &&
139 (strcmp(i->name, ctdb->single_ip_vnn->ifaces[0]) == 0)) {
140 /* Found, next interface please... */
141 continue;
142 }
143 /* Search for a vnn with this interface. */
144 found = false;
145 for (tv=ctdb->vnn; tv; tv=tv->next) {
146 if (vnn_has_interface_with_name(tv, i->name)) {
147 found = true;
148 break;
149 }
150 }
151
152 if (!found) {
153 /* None of the VNNs are using this interface. */
154 DLIST_REMOVE(ctdb->ifaces, i);
155 /* Caller will free mem_ctx when convenient. */
156 talloc_steal(mem_ctx, i);
157 }
158 }
159 }
160
161
162 static struct ctdb_iface *ctdb_find_iface(struct ctdb_context *ctdb,
163 const char *iface)
164 {
165 struct ctdb_iface *i;
166
167 for (i=ctdb->ifaces;i;i=i->next) {
168 if (strcmp(i->name, iface) == 0) {
169 return i;
170 }
171 }
172
173 return NULL;
174 }
175
176 static struct ctdb_iface *ctdb_vnn_best_iface(struct ctdb_context *ctdb,
177 struct ctdb_vnn *vnn)
178 {
179 int i;
180 struct ctdb_iface *cur = NULL;
181 struct ctdb_iface *best = NULL;
182
183 for (i=0; vnn->ifaces[i]; i++) {
184
185 cur = ctdb_find_iface(ctdb, vnn->ifaces[i]);
186 if (cur == NULL) {
187 continue;
188 }
189
190 if (!cur->link_up) {
191 continue;
192 }
193
194 if (best == NULL) {
195 best = cur;
196 continue;
197 }
198
199 if (cur->references < best->references) {
200 best = cur;
201 continue;
202 }
203 }
204
205 return best;
206 }
207
208 static int32_t ctdb_vnn_assign_iface(struct ctdb_context *ctdb,
209 struct ctdb_vnn *vnn)
210 {
211 struct ctdb_iface *best = NULL;
212
213 if (vnn->iface) {
214 DEBUG(DEBUG_INFO, (__location__ " public address '%s' "
215 "still assigned to iface '%s'\n",
216 ctdb_addr_to_str(&vnn->public_address),
217 ctdb_vnn_iface_string(vnn)));
218 return 0;
219 }
220
221 best = ctdb_vnn_best_iface(ctdb, vnn);
222 if (best == NULL) {
223 DEBUG(DEBUG_ERR, (__location__ " public address '%s' "
224 "cannot assign to iface any iface\n",
225 ctdb_addr_to_str(&vnn->public_address)));
226 return -1;
227 }
228
229 vnn->iface = best;
230 best->references++;
231 vnn->pnn = ctdb->pnn;
232
233 DEBUG(DEBUG_INFO, (__location__ " public address '%s' "
234 "now assigned to iface '%s' refs[%d]\n",
235 ctdb_addr_to_str(&vnn->public_address),
236 ctdb_vnn_iface_string(vnn),
237 best->references));
238 return 0;
239 }
240
241 static void ctdb_vnn_unassign_iface(struct ctdb_context *ctdb,
242 struct ctdb_vnn *vnn)
243 {
244 DEBUG(DEBUG_INFO, (__location__ " public address '%s' "
245 "now unassigned (old iface '%s' refs[%d])\n",
246 ctdb_addr_to_str(&vnn->public_address),
247 ctdb_vnn_iface_string(vnn),
248 vnn->iface?vnn->iface->references:0));
249 if (vnn->iface) {
250 vnn->iface->references--;
251 }
252 vnn->iface = NULL;
253 if (vnn->pnn == ctdb->pnn) {
254 vnn->pnn = -1;
255 }
256 }
257
258 static bool ctdb_vnn_available(struct ctdb_context *ctdb,
259 struct ctdb_vnn *vnn)
260 {
261 int i;
262
263 if (vnn->iface && vnn->iface->link_up) {
264 return true;
265 }
266
267 for (i=0; vnn->ifaces[i]; i++) {
268 struct ctdb_iface *cur;
269
270 cur = ctdb_find_iface(ctdb, vnn->ifaces[i]);
271 if (cur == NULL) {
272 continue;
273 }
274
275 if (cur->link_up) {
276 return true;
277 }
278 }
279
280 return false;
281 }
282
283 struct ctdb_takeover_arp {
284 struct ctdb_context *ctdb;
285 uint32_t count;
286 ctdb_sock_addr addr;
287 struct ctdb_tcp_array *tcparray;
288 struct ctdb_vnn *vnn;
289 };
290
291
292 /*
293 lists of tcp endpoints
294 */
295 struct ctdb_tcp_list {
296 struct ctdb_tcp_list *prev, *next;
297 struct ctdb_tcp_connection connection;
298 };
299
300 /*
301 list of clients to kill on IP release
302 */
303 struct ctdb_client_ip {
304 struct ctdb_client_ip *prev, *next;
305 struct ctdb_context *ctdb;
306 ctdb_sock_addr addr;
307 uint32_t client_id;
308 };
309
310
311 /*
312 send a gratuitous arp
313 */
314 static void ctdb_control_send_arp(struct event_context *ev, struct timed_event *te,
315 struct timeval t, void *private_data)
316 {
317 struct ctdb_takeover_arp *arp = talloc_get_type(private_data,
318 struct ctdb_takeover_arp);
319 int i, ret;
320 struct ctdb_tcp_array *tcparray;
321 const char *iface = ctdb_vnn_iface_string(arp->vnn);
322
323 ret = ctdb_sys_send_arp(&arp->addr, iface);
324 if (ret != 0) {
325 DEBUG(DEBUG_CRIT,(__location__ " sending of arp failed on iface '%s' (%s)\n",
326 iface, strerror(errno)));
327 }
328
329 tcparray = arp->tcparray;
330 if (tcparray) {
331 for (i=0;i<tcparray->num;i++) {
332 struct ctdb_tcp_connection *tcon;
333
334 tcon = &tcparray->connections[i];
335 DEBUG(DEBUG_INFO,("sending tcp tickle ack for %u->%s:%u\n",
336 (unsigned)ntohs(tcon->dst_addr.ip.sin_port),
337 ctdb_addr_to_str(&tcon->src_addr),
338 (unsigned)ntohs(tcon->src_addr.ip.sin_port)));
339 ret = ctdb_sys_send_tcp(
340 &tcon->src_addr,
341 &tcon->dst_addr,
342 0, 0, 0);
343 if (ret != 0) {
344 DEBUG(DEBUG_CRIT,(__location__ " Failed to send tcp tickle ack for %s\n",
345 ctdb_addr_to_str(&tcon->src_addr)));
346 }
347 }
348 }
349
350 arp->count++;
351
352 if (arp->count == CTDB_ARP_REPEAT) {
353 talloc_free(arp);
354 return;
355 }
356
357 event_add_timed(arp->ctdb->ev, arp->vnn->takeover_ctx,
358 timeval_current_ofs(CTDB_ARP_INTERVAL, 100000),
359 ctdb_control_send_arp, arp);
360 }
361
362 static int32_t ctdb_announce_vnn_iface(struct ctdb_context *ctdb,
363 struct ctdb_vnn *vnn)
364 {
365 struct ctdb_takeover_arp *arp;
366 struct ctdb_tcp_array *tcparray;
367
368 if (!vnn->takeover_ctx) {
369 vnn->takeover_ctx = talloc_new(vnn);
370 if (!vnn->takeover_ctx) {
371 return -1;
372 }
373 }
374
375 arp = talloc_zero(vnn->takeover_ctx, struct ctdb_takeover_arp);
376 if (!arp) {
377 return -1;
378 }
379
380 arp->ctdb = ctdb;
381 arp->addr = vnn->public_address;
382 arp->vnn = vnn;
383
384 tcparray = vnn->tcp_array;
385 if (tcparray) {
386 /* add all of the known tcp connections for this IP to the
387 list of tcp connections to send tickle acks for */
388 arp->tcparray = talloc_steal(arp, tcparray);
389
390 vnn->tcp_array = NULL;
391 vnn->tcp_update_needed = true;
392 }
393
394 event_add_timed(arp->ctdb->ev, vnn->takeover_ctx,
395 timeval_zero(), ctdb_control_send_arp, arp);
396
397 return 0;
398 }
399
400 struct takeover_callback_state {
401 struct ctdb_req_control *c;
402 ctdb_sock_addr *addr;
403 struct ctdb_vnn *vnn;
404 };
405
406 struct ctdb_do_takeip_state {
407 struct ctdb_req_control *c;
408 struct ctdb_vnn *vnn;
409 };
410
411 /*
412 called when takeip event finishes
413 */
414 static void ctdb_do_takeip_callback(struct ctdb_context *ctdb, int status,
415 void *private_data)
416 {
417 struct ctdb_do_takeip_state *state =
418 talloc_get_type(private_data, struct ctdb_do_takeip_state);
419 int32_t ret;
420 TDB_DATA data;
421
422 if (status != 0) {
423 struct ctdb_node *node = ctdb->nodes[ctdb->pnn];
424
425 if (status == -ETIME) {
426 ctdb_ban_self(ctdb);
427 }
428 DEBUG(DEBUG_ERR,(__location__ " Failed to takeover IP %s on interface %s\n",
429 ctdb_addr_to_str(&state->vnn->public_address),
430 ctdb_vnn_iface_string(state->vnn)));
431 ctdb_request_control_reply(ctdb, state->c, NULL, status, NULL);
432
433 node->flags |= NODE_FLAGS_UNHEALTHY;
434 talloc_free(state);
435 return;
436 }
437
438 if (ctdb->do_checkpublicip) {
439
440 ret = ctdb_announce_vnn_iface(ctdb, state->vnn);
441 if (ret != 0) {
442 ctdb_request_control_reply(ctdb, state->c, NULL, -1, NULL);
443 talloc_free(state);
444 return;
445 }
446
447 }
448
449 data.dptr = (uint8_t *)ctdb_addr_to_str(&state->vnn->public_address);
450 data.dsize = strlen((char *)data.dptr) + 1;
451 DEBUG(DEBUG_INFO,(__location__ " sending TAKE_IP for '%s'\n", data.dptr));
452
453 ctdb_daemon_send_message(ctdb, ctdb->pnn, CTDB_SRVID_TAKE_IP, data);
454
455
456 /* the control succeeded */
457 ctdb_request_control_reply(ctdb, state->c, NULL, 0, NULL);
458 talloc_free(state);
459 return;
460 }
461
462 static int ctdb_takeip_destructor(struct ctdb_do_takeip_state *state)
463 {
464 state->vnn->update_in_flight = false;
465 return 0;
466 }
467
468 /*
469 take over an ip address
470 */
471 static int32_t ctdb_do_takeip(struct ctdb_context *ctdb,
472 struct ctdb_req_control *c,
473 struct ctdb_vnn *vnn)
474 {
475 int ret;
476 struct ctdb_do_takeip_state *state;
477
478 if (vnn->update_in_flight) {
479 DEBUG(DEBUG_NOTICE,("Takeover of IP %s/%u rejected "
480 "update for this IP already in flight\n",
481 ctdb_addr_to_str(&vnn->public_address),
482 vnn->public_netmask_bits));
483 return -1;
484 }
485
486 ret = ctdb_vnn_assign_iface(ctdb, vnn);
487 if (ret != 0) {
488 DEBUG(DEBUG_ERR,("Takeover of IP %s/%u failed to "
489 "assign a usable interface\n",
490 ctdb_addr_to_str(&vnn->public_address),
491 vnn->public_netmask_bits));
492 return -1;
493 }
494
495 state = talloc(vnn, struct ctdb_do_takeip_state);
496 CTDB_NO_MEMORY(ctdb, state);
497
498 state->c = talloc_steal(ctdb, c);
499 state->vnn = vnn;
500
501 vnn->update_in_flight = true;
502 talloc_set_destructor(state, ctdb_takeip_destructor);
503
504 DEBUG(DEBUG_NOTICE,("Takeover of IP %s/%u on interface %s\n",
505 ctdb_addr_to_str(&vnn->public_address),
506 vnn->public_netmask_bits,
507 ctdb_vnn_iface_string(vnn)));
508
509 ret = ctdb_event_script_callback(ctdb,
510 state,
511 ctdb_do_takeip_callback,
512 state,
513 CTDB_EVENT_TAKE_IP,
514 "%s %s %u",
515 ctdb_vnn_iface_string(vnn),
516 ctdb_addr_to_str(&vnn->public_address),
517 vnn->public_netmask_bits);
518
519 if (ret != 0) {
520 DEBUG(DEBUG_ERR,(__location__ " Failed to takeover IP %s on interface %s\n",
521 ctdb_addr_to_str(&vnn->public_address),
522 ctdb_vnn_iface_string(vnn)));
523 talloc_free(state);
524 return -1;
525 }
526
527 return 0;
528 }
529
530 struct ctdb_do_updateip_state {
531 struct ctdb_req_control *c;
532 struct ctdb_iface *old;
533 struct ctdb_vnn *vnn;
534 };
535
536 /*
537 called when updateip event finishes
538 */
539 static void ctdb_do_updateip_callback(struct ctdb_context *ctdb, int status,
540 void *private_data)
541 {
542 struct ctdb_do_updateip_state *state =
543 talloc_get_type(private_data, struct ctdb_do_updateip_state);
544 int32_t ret;
545
546 if (status != 0) {
547 if (status == -ETIME) {
548 ctdb_ban_self(ctdb);
549 }
550 DEBUG(DEBUG_ERR,(__location__ " Failed to move IP %s from interface %s to %s\n",
551 ctdb_addr_to_str(&state->vnn->public_address),
552 state->old->name,
553 ctdb_vnn_iface_string(state->vnn)));
554
555 /*
556 * All we can do is reset the old interface
557 * and let the next run fix it
558 */
559 ctdb_vnn_unassign_iface(ctdb, state->vnn);
560 state->vnn->iface = state->old;
561 state->vnn->iface->references++;
562
563 ctdb_request_control_reply(ctdb, state->c, NULL, status, NULL);
564 talloc_free(state);
565 return;
566 }
567
568 if (ctdb->do_checkpublicip) {
569
570 ret = ctdb_announce_vnn_iface(ctdb, state->vnn);
571 if (ret != 0) {
572 ctdb_request_control_reply(ctdb, state->c, NULL, -1, NULL);
573 talloc_free(state);
574 return;
575 }
576
577 }
578
579 /* the control succeeded */
580 ctdb_request_control_reply(ctdb, state->c, NULL, 0, NULL);
581 talloc_free(state);
582 return;
583 }
584
585 static int ctdb_updateip_destructor(struct ctdb_do_updateip_state *state)
586 {
587 state->vnn->update_in_flight = false;
588 return 0;
589 }
590
591 /*
592 update (move) an ip address
593 */
594 static int32_t ctdb_do_updateip(struct ctdb_context *ctdb,
595 struct ctdb_req_control *c,
596 struct ctdb_vnn *vnn)
597 {
598 int ret;
599 struct ctdb_do_updateip_state *state;
600 struct ctdb_iface *old = vnn->iface;
601 const char *new_name;
602
603 if (vnn->update_in_flight) {
604 DEBUG(DEBUG_NOTICE,("Update of IP %s/%u rejected "
605 "update for this IP already in flight\n",
606 ctdb_addr_to_str(&vnn->public_address),
607 vnn->public_netmask_bits));
608 return -1;
609 }
610
611 ctdb_vnn_unassign_iface(ctdb, vnn);
612 ret = ctdb_vnn_assign_iface(ctdb, vnn);
613 if (ret != 0) {
614 DEBUG(DEBUG_ERR,("update of IP %s/%u failed to "
615 "assin a usable interface (old iface '%s')\n",
616 ctdb_addr_to_str(&vnn->public_address),
617 vnn->public_netmask_bits,
618 old->name));
619 return -1;
620 }
621
622 new_name = ctdb_vnn_iface_string(vnn);
623 if (old->name != NULL && new_name != NULL && !strcmp(old->name, new_name)) {
624 /* A benign update from one interface onto itself.
625 * no need to run the eventscripts in this case, just return
626 * success.
627 */
628 ctdb_request_control_reply(ctdb, c, NULL, 0, NULL);
629 return 0;
630 }
631
632 state = talloc(vnn, struct ctdb_do_updateip_state);
633 CTDB_NO_MEMORY(ctdb, state);
634
635 state->c = talloc_steal(ctdb, c);
636 state->old = old;
637 state->vnn = vnn;
638
639 vnn->update_in_flight = true;
640 talloc_set_destructor(state, ctdb_updateip_destructor);
641
642 DEBUG(DEBUG_NOTICE,("Update of IP %s/%u from "
643 "interface %s to %s\n",
644 ctdb_addr_to_str(&vnn->public_address),
645 vnn->public_netmask_bits,
646 old->name,
647 new_name));
648
649 ret = ctdb_event_script_callback(ctdb,
650 state,
651 ctdb_do_updateip_callback,
652 state,
653 CTDB_EVENT_UPDATE_IP,
654 "%s %s %s %u",
655 state->old->name,
656 new_name,
657 ctdb_addr_to_str(&vnn->public_address),
658 vnn->public_netmask_bits);
659 if (ret != 0) {
660 DEBUG(DEBUG_ERR,(__location__ " Failed update IP %s from interface %s to %s\n",
661 ctdb_addr_to_str(&vnn->public_address),
662 old->name, new_name));
663 talloc_free(state);
664 return -1;
665 }
666
667 return 0;
668 }
669
670 /*
671 Find the vnn of the node that has a public ip address
672 returns -1 if the address is not known as a public address
673 */
674 static struct ctdb_vnn *find_public_ip_vnn(struct ctdb_context *ctdb, ctdb_sock_addr *addr)
675 {
676 struct ctdb_vnn *vnn;
677
678 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
679 if (ctdb_same_ip(&vnn->public_address, addr)) {
680 return vnn;
681 }
682 }
683
684 return NULL;
685 }
686
687 /*
688 take over an ip address
689 */
690 int32_t ctdb_control_takeover_ip(struct ctdb_context *ctdb,
691 struct ctdb_req_control *c,
692 TDB_DATA indata,
693 bool *async_reply)
694 {
695 int ret;
696 struct ctdb_public_ip *pip = (struct ctdb_public_ip *)indata.dptr;
697 struct ctdb_vnn *vnn;
698 bool have_ip = false;
699 bool do_updateip = false;
700 bool do_takeip = false;
701 struct ctdb_iface *best_iface = NULL;
702
703 if (pip->pnn != ctdb->pnn) {
704 DEBUG(DEBUG_ERR,(__location__" takeoverip called for an ip '%s' "
705 "with pnn %d, but we're node %d\n",
706 ctdb_addr_to_str(&pip->addr),
707 pip->pnn, ctdb->pnn));
708 return -1;
709 }
710
711 /* update out vnn list */
712 vnn = find_public_ip_vnn(ctdb, &pip->addr);
713 if (vnn == NULL) {
714 DEBUG(DEBUG_INFO,("takeoverip called for an ip '%s' that is not a public address\n",
715 ctdb_addr_to_str(&pip->addr)));
716 return 0;
717 }
718
719 if (ctdb->do_checkpublicip) {
720 have_ip = ctdb_sys_have_ip(&pip->addr);
721 }
722 best_iface = ctdb_vnn_best_iface(ctdb, vnn);
723 if (best_iface == NULL) {
724 DEBUG(DEBUG_ERR,("takeoverip of IP %s/%u failed to find"
725 "a usable interface (old %s, have_ip %d)\n",
726 ctdb_addr_to_str(&vnn->public_address),
727 vnn->public_netmask_bits,
728 ctdb_vnn_iface_string(vnn),
729 have_ip));
730 return -1;
731 }
732
733 if (vnn->iface == NULL && vnn->pnn == -1 && have_ip && best_iface != NULL) {
734 DEBUG(DEBUG_ERR,("Taking over newly created ip\n"));
735 have_ip = false;
736 }
737
738
739 if (vnn->iface == NULL && have_ip) {
740 DEBUG(DEBUG_CRIT,(__location__ " takeoverip of IP %s is known to the kernel, "
741 "but we have no interface assigned, has someone manually configured it? Ignore for now.\n",
742 ctdb_addr_to_str(&vnn->public_address)));
743 return 0;
744 }
745
746 if (vnn->pnn != ctdb->pnn && have_ip && vnn->pnn != -1) {
747 DEBUG(DEBUG_CRIT,(__location__ " takeoverip of IP %s is known to the kernel, "
748 "and we have it on iface[%s], but it was assigned to node %d"
749 "and we are node %d, banning ourself\n",
750 ctdb_addr_to_str(&vnn->public_address),
751 ctdb_vnn_iface_string(vnn), vnn->pnn, ctdb->pnn));
752 ctdb_ban_self(ctdb);
753 return -1;
754 }
755
756 if (vnn->pnn == -1 && have_ip) {
757 vnn->pnn = ctdb->pnn;
758 DEBUG(DEBUG_CRIT,(__location__ " takeoverip of IP %s is known to the kernel, "
759 "and we already have it on iface[%s], update local daemon\n",
760 ctdb_addr_to_str(&vnn->public_address),
761 ctdb_vnn_iface_string(vnn)));
762 return 0;
763 }
764
765 if (vnn->iface) {
766 if (vnn->iface != best_iface) {
767 if (!vnn->iface->link_up) {
768 do_updateip = true;
769 } else if (vnn->iface->references > (best_iface->references + 1)) {
770 /* only move when the rebalance gains something */
771 do_updateip = true;
772 }
773 }
774 }
775
776 if (!have_ip) {
777 if (do_updateip) {
778 ctdb_vnn_unassign_iface(ctdb, vnn);
779 do_updateip = false;
780 }
781 do_takeip = true;
782 }
783
784 if (do_takeip) {
785 ret = ctdb_do_takeip(ctdb, c, vnn);
786 if (ret != 0) {
787 return -1;
788 }
789 } else if (do_updateip) {
790 ret = ctdb_do_updateip(ctdb, c, vnn);
791 if (ret != 0) {
792 return -1;
793 }
794 } else {
795 /*
796 * The interface is up and the kernel known the ip
797 * => do nothing
798 */
799 DEBUG(DEBUG_INFO,("Redundant takeover of IP %s/%u on interface %s (ip already held)\n",
800 ctdb_addr_to_str(&pip->addr),
801 vnn->public_netmask_bits,
802 ctdb_vnn_iface_string(vnn)));
803 return 0;
804 }
805
806 /* tell ctdb_control.c that we will be replying asynchronously */
807 *async_reply = true;
808
809 return 0;
810 }
811
812 /*
813 takeover an ip address old v4 style
814 */
815 int32_t ctdb_control_takeover_ipv4(struct ctdb_context *ctdb,
816 struct ctdb_req_control *c,
817 TDB_DATA indata,
818 bool *async_reply)
819 {
820 TDB_DATA data;
821
822 data.dsize = sizeof(struct ctdb_public_ip);
823 data.dptr = (uint8_t *)talloc_zero(c, struct ctdb_public_ip);
824 CTDB_NO_MEMORY(ctdb, data.dptr);
825
826 memcpy(data.dptr, indata.dptr, indata.dsize);
827 return ctdb_control_takeover_ip(ctdb, c, data, async_reply);
828 }
829
830 /*
831 kill any clients that are registered with a IP that is being released
832 */
833 static void release_kill_clients(struct ctdb_context *ctdb, ctdb_sock_addr *addr)
834 {
835 struct ctdb_client_ip *ip;
836
837 DEBUG(DEBUG_INFO,("release_kill_clients for ip %s\n",
838 ctdb_addr_to_str(addr)));
839
840 for (ip=ctdb->client_ip_list; ip; ip=ip->next) {
841 ctdb_sock_addr tmp_addr;
842
843 tmp_addr = ip->addr;
844 DEBUG(DEBUG_INFO,("checking for client %u with IP %s\n",
845 ip->client_id,
846 ctdb_addr_to_str(&ip->addr)));
847
848 if (ctdb_same_ip(&tmp_addr, addr)) {
849 struct ctdb_client *client = ctdb_reqid_find(ctdb,
850 ip->client_id,
851 struct ctdb_client);
852 DEBUG(DEBUG_INFO,("matched client %u with IP %s and pid %u\n",
853 ip->client_id,
854 ctdb_addr_to_str(&ip->addr),
855 client->pid));
856
857 if (client->pid != 0) {
858 DEBUG(DEBUG_INFO,(__location__ " Killing client pid %u for IP %s on client_id %u\n",
859 (unsigned)client->pid,
860 ctdb_addr_to_str(addr),
861 ip->client_id));
862 kill(client->pid, SIGKILL);
863 }
864 }
865 }
866 }
867
868 /*
869 called when releaseip event finishes
870 */
871 static void release_ip_callback(struct ctdb_context *ctdb, int status,
872 void *private_data)
873 {
874 struct takeover_callback_state *state =
875 talloc_get_type(private_data, struct takeover_callback_state);
876 TDB_DATA data;
877
878 if (status == -ETIME) {
879 ctdb_ban_self(ctdb);
880 }
881
882 if (ctdb->do_checkpublicip && ctdb_sys_have_ip(state->addr)) {
883 DEBUG(DEBUG_ERR, ("IP %s still hosted during release IP callback, failing\n",
884 ctdb_addr_to_str(state->addr)));
885 ctdb_request_control_reply(ctdb, state->c, NULL, -1, NULL);
886 talloc_free(state);
887 return;
888 }
889
890 /* send a message to all clients of this node telling them
891 that the cluster has been reconfigured and they should
892 release any sockets on this IP */
893 data.dptr = (uint8_t *)talloc_strdup(state, ctdb_addr_to_str(state->addr));
894 CTDB_NO_MEMORY_VOID(ctdb, data.dptr);
895 data.dsize = strlen((char *)data.dptr)+1;
896
897 DEBUG(DEBUG_INFO,(__location__ " sending RELEASE_IP for '%s'\n", data.dptr));
898
899 ctdb_daemon_send_message(ctdb, ctdb->pnn, CTDB_SRVID_RELEASE_IP, data);
900
901 /* kill clients that have registered with this IP */
902 release_kill_clients(ctdb, state->addr);
903
904 ctdb_vnn_unassign_iface(ctdb, state->vnn);
905
906 /* the control succeeded */
907 ctdb_request_control_reply(ctdb, state->c, NULL, 0, NULL);
908 talloc_free(state);
909 }
910
911 static int ctdb_releaseip_destructor(struct takeover_callback_state *state)
912 {
913 state->vnn->update_in_flight = false;
914 return 0;
915 }
916
917 /*
918 release an ip address
919 */
920 int32_t ctdb_control_release_ip(struct ctdb_context *ctdb,
921 struct ctdb_req_control *c,
922 TDB_DATA indata,
923 bool *async_reply)
924 {
925 int ret;
926 struct takeover_callback_state *state;
927 struct ctdb_public_ip *pip = (struct ctdb_public_ip *)indata.dptr;
928 struct ctdb_vnn *vnn;
929 char *iface;
930
931 /* update our vnn list */
932 vnn = find_public_ip_vnn(ctdb, &pip->addr);
933 if (vnn == NULL) {
934 DEBUG(DEBUG_INFO,("releaseip called for an ip '%s' that is not a public address\n",
935 ctdb_addr_to_str(&pip->addr)));
936 return 0;
937 }
938 vnn->pnn = pip->pnn;
939
940 /* stop any previous arps */
941 talloc_free(vnn->takeover_ctx);
942 vnn->takeover_ctx = NULL;
943
944 /* Some ctdb tool commands (e.g. moveip, rebalanceip) send
945 * lazy multicast to drop an IP from any node that isn't the
946 * intended new node. The following causes makes ctdbd ignore
947 * a release for any address it doesn't host.
948 */
949 if (ctdb->do_checkpublicip) {
950 if (!ctdb_sys_have_ip(&pip->addr)) {
951 DEBUG(DEBUG_DEBUG,("Redundant release of IP %s/%u on interface %s (ip not held)\n",
952 ctdb_addr_to_str(&pip->addr),
953 vnn->public_netmask_bits,
954 ctdb_vnn_iface_string(vnn)));
955 ctdb_vnn_unassign_iface(ctdb, vnn);
956 return 0;
957 }
958 } else {
959 if (vnn->iface == NULL) {
960 DEBUG(DEBUG_DEBUG,("Redundant release of IP %s/%u (ip not held)\n",
961 ctdb_addr_to_str(&pip->addr),
962 vnn->public_netmask_bits));
963 return 0;
964 }
965 }
966
967 /* There is a potential race between take_ip and us because we
968 * update the VNN via a callback that run when the
969 * eventscripts have been run. Avoid the race by allowing one
970 * update to be in flight at a time.
971 */
972 if (vnn->update_in_flight) {
973 DEBUG(DEBUG_NOTICE,("Release of IP %s/%u rejected "
974 "update for this IP already in flight\n",
975 ctdb_addr_to_str(&vnn->public_address),
976 vnn->public_netmask_bits));
977 return -1;
978 }
979
980 if (ctdb->do_checkpublicip) {
981 iface = ctdb_sys_find_ifname(&pip->addr);
982 if (iface == NULL) {
983 DEBUG(DEBUG_ERR, ("Could not find which interface the ip address is hosted on. can not release it\n"));
984 return 0;
985 }
986 if (vnn->iface == NULL) {
987 DEBUG(DEBUG_WARNING,
988 ("Public IP %s is hosted on interface %s but we have no VNN\n",
989 ctdb_addr_to_str(&pip->addr),
990 iface));
991 } else if (strcmp(iface, ctdb_vnn_iface_string(vnn)) != 0) {
992 DEBUG(DEBUG_WARNING,
993 ("Public IP %s is hosted on inteterface %s but VNN says %s\n",
994 ctdb_addr_to_str(&pip->addr),
995 iface,
996 ctdb_vnn_iface_string(vnn)));
997 /* Should we fix vnn->iface? If we do, what
998 * happens to reference counts?
999 */
1000 }
1001 } else {
1002 iface = strdup(ctdb_vnn_iface_string(vnn));
1003 }
1004
1005 DEBUG(DEBUG_NOTICE,("Release of IP %s/%u on interface %s node:%d\n",
1006 ctdb_addr_to_str(&pip->addr),
1007 vnn->public_netmask_bits,
1008 iface,
1009 pip->pnn));
1010
1011 state = talloc(ctdb, struct takeover_callback_state);
1012 CTDB_NO_MEMORY(ctdb, state);
1013
1014 state->c = talloc_steal(state, c);
1015 state->addr = talloc(state, ctdb_sock_addr);
1016 CTDB_NO_MEMORY(ctdb, state->addr);
1017 *state->addr = pip->addr;
1018 state->vnn = vnn;
1019
1020 vnn->update_in_flight = true;
1021 talloc_set_destructor(state, ctdb_releaseip_destructor);
1022
1023 ret = ctdb_event_script_callback(ctdb,
1024 state, release_ip_callback, state,
1025 CTDB_EVENT_RELEASE_IP,
1026 "%s %s %u",
1027 iface,
1028 ctdb_addr_to_str(&pip->addr),
1029 vnn->public_netmask_bits);
1030 free(iface);
1031 if (ret != 0) {
1032 DEBUG(DEBUG_ERR,(__location__ " Failed to release IP %s on interface %s\n",
1033 ctdb_addr_to_str(&pip->addr),
1034 ctdb_vnn_iface_string(vnn)));
1035 talloc_free(state);
1036 return -1;
1037 }
1038
1039 /* tell the control that we will be reply asynchronously */
1040 *async_reply = true;
1041 return 0;
1042 }
1043
1044 /*
1045 release an ip address old v4 style
1046 */
1047 int32_t ctdb_control_release_ipv4(struct ctdb_context *ctdb,
1048 struct ctdb_req_control *c,
1049 TDB_DATA indata,
1050 bool *async_reply)
1051 {
1052 TDB_DATA data;
1053
1054 data.dsize = sizeof(struct ctdb_public_ip);
1055 data.dptr = (uint8_t *)talloc_zero(c, struct ctdb_public_ip);
1056 CTDB_NO_MEMORY(ctdb, data.dptr);
1057
1058 memcpy(data.dptr, indata.dptr, indata.dsize);
1059 return ctdb_control_release_ip(ctdb, c, data, async_reply);
1060 }
1061
1062
1063 static int ctdb_add_public_address(struct ctdb_context *ctdb,
1064 ctdb_sock_addr *addr,
1065 unsigned mask, const char *ifaces,
1066 bool check_address)
1067 {
1068 struct ctdb_vnn *vnn;
1069 uint32_t num = 0;
1070 char *tmp;
1071 const char *iface;
1072 int i;
1073 int ret;
1074
1075 tmp = strdup(ifaces);
1076 for (iface = strtok(tmp, ","); iface; iface = strtok(NULL, ",")) {
1077 if (!ctdb_sys_check_iface_exists(iface)) {
1078 DEBUG(DEBUG_CRIT,("Interface %s does not exist. Can not add public-address : %s\n", iface, ctdb_addr_to_str(addr)));
1079 free(tmp);
1080 return -1;
1081 }
1082 }
1083 free(tmp);
1084
1085 /* Verify that we dont have an entry for this ip yet */
1086 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
1087 if (ctdb_same_sockaddr(addr, &vnn->public_address)) {
1088 DEBUG(DEBUG_CRIT,("Same ip '%s' specified multiple times in the public address list \n",
1089 ctdb_addr_to_str(addr)));
1090 return -1;
1091 }
1092 }
1093
1094 /* create a new vnn structure for this ip address */
1095 vnn = talloc_zero(ctdb, struct ctdb_vnn);
1096 CTDB_NO_MEMORY_FATAL(ctdb, vnn);
1097 vnn->ifaces = talloc_array(vnn, const char *, num + 2);
1098 tmp = talloc_strdup(vnn, ifaces);
1099 CTDB_NO_MEMORY_FATAL(ctdb, tmp);
1100 for (iface = strtok(tmp, ","); iface; iface = strtok(NULL, ",")) {
1101 vnn->ifaces = talloc_realloc(vnn, vnn->ifaces, const char *, num + 2);
1102 CTDB_NO_MEMORY_FATAL(ctdb, vnn->ifaces);
1103 vnn->ifaces[num] = talloc_strdup(vnn, iface);
1104 CTDB_NO_MEMORY_FATAL(ctdb, vnn->ifaces[num]);
1105 num++;
1106 }
1107 talloc_free(tmp);
1108 vnn->ifaces[num] = NULL;
1109 vnn->public_address = *addr;
1110 vnn->public_netmask_bits = mask;
1111 vnn->pnn = -1;
1112 if (check_address) {
1113 if (ctdb_sys_have_ip(addr)) {
1114 DEBUG(DEBUG_ERR,("We are already hosting public address '%s'. setting PNN to ourself:%d\n", ctdb_addr_to_str(addr), ctdb->pnn));
1115 vnn->pnn = ctdb->pnn;
1116 }
1117 }
1118
1119 for (i=0; vnn->ifaces[i]; i++) {
1120 ret = ctdb_add_local_iface(ctdb, vnn->ifaces[i]);
1121 if (ret != 0) {
1122 DEBUG(DEBUG_CRIT, (__location__ " failed to add iface[%s] "
1123 "for public_address[%s]\n",
1124 vnn->ifaces[i], ctdb_addr_to_str(addr)));
1125 talloc_free(vnn);
1126 return -1;
1127 }
1128 }
1129
1130 DLIST_ADD(ctdb->vnn, vnn);
1131
1132 return 0;
1133 }
1134
1135 static void ctdb_check_interfaces_event(struct event_context *ev, struct timed_event *te,
1136 struct timeval t, void *private_data)
1137 {
1138 struct ctdb_context *ctdb = talloc_get_type(private_data,
1139 struct ctdb_context);
1140 struct ctdb_vnn *vnn;
1141
1142 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
1143 int i;
1144
1145 for (i=0; vnn->ifaces[i] != NULL; i++) {
1146 if (!ctdb_sys_check_iface_exists(vnn->ifaces[i])) {
1147 DEBUG(DEBUG_CRIT,("Interface %s does not exist but is used by public ip %s\n",
1148 vnn->ifaces[i],
1149 ctdb_addr_to_str(&vnn->public_address)));
1150 }
1151 }
1152 }
1153
1154 event_add_timed(ctdb->ev, ctdb->check_public_ifaces_ctx,
1155 timeval_current_ofs(30, 0),
1156 ctdb_check_interfaces_event, ctdb);
1157 }
1158
1159
1160 int ctdb_start_monitoring_interfaces(struct ctdb_context *ctdb)
1161 {
1162 if (ctdb->check_public_ifaces_ctx != NULL) {
1163 talloc_free(ctdb->check_public_ifaces_ctx);
1164 ctdb->check_public_ifaces_ctx = NULL;
1165 }
1166
1167 ctdb->check_public_ifaces_ctx = talloc_new(ctdb);
1168 if (ctdb->check_public_ifaces_ctx == NULL) {
1169 ctdb_fatal(ctdb, "failed to allocate context for checking interfaces");
1170 }
1171
1172 event_add_timed(ctdb->ev, ctdb->check_public_ifaces_ctx,
1173 timeval_current_ofs(30, 0),
1174 ctdb_check_interfaces_event, ctdb);
1175
1176 return 0;
1177 }
1178
1179
1180 /*
1181 setup the public address lists from a file
1182 */
1183 int ctdb_set_public_addresses(struct ctdb_context *ctdb, bool check_addresses)
1184 {
1185 char **lines;
1186 int nlines;
1187 int i;
1188
1189 lines = file_lines_load(ctdb->public_addresses_file, &nlines, ctdb);
1190 if (lines == NULL) {
1191 ctdb_set_error(ctdb, "Failed to load public address list '%s'\n", ctdb->public_addresses_file);
1192 return -1;
1193 }
1194 while (nlines > 0 && strcmp(lines[nlines-1], "") == 0) {
1195 nlines--;
1196 }
1197
1198 for (i=0;i<nlines;i++) {
1199 unsigned mask;
1200 ctdb_sock_addr addr;
1201 const char *addrstr;
1202 const char *ifaces;
1203 char *tok, *line;
1204
1205 line = lines[i];
1206 while ((*line == ' ') || (*line == '\t')) {
1207 line++;
1208 }
1209 if (*line == '#') {
1210 continue;
1211 }
1212 if (strcmp(line, "") == 0) {
1213 continue;
1214 }
1215 tok = strtok(line, " \t");
1216 addrstr = tok;
1217 tok = strtok(NULL, " \t");
1218 if (tok == NULL) {
1219 if (NULL == ctdb->default_public_interface) {
1220 DEBUG(DEBUG_CRIT,("No default public interface and no interface specified at line %u of public address list\n",
1221 i+1));
1222 talloc_free(lines);
1223 return -1;
1224 }
1225 ifaces = ctdb->default_public_interface;
1226 } else {
1227 ifaces = tok;
1228 }
1229
1230 if (!addrstr || !parse_ip_mask(addrstr, ifaces, &addr, &mask)) {
1231 DEBUG(DEBUG_CRIT,("Badly formed line %u in public address list\n", i+1));
1232 talloc_free(lines);
1233 return -1;
1234 }
1235 if (ctdb_add_public_address(ctdb, &addr, mask, ifaces, check_addresses)) {
1236 DEBUG(DEBUG_CRIT,("Failed to add line %u to the public address list\n", i+1));
1237 talloc_free(lines);
1238 return -1;
1239 }
1240 }
1241
1242
1243 talloc_free(lines);
1244 return 0;
1245 }
1246
1247 int ctdb_set_single_public_ip(struct ctdb_context *ctdb,
1248 const char *iface,
1249 const char *ip)
1250 {
1251 struct ctdb_vnn *svnn;
1252 struct ctdb_iface *cur = NULL;
1253 bool ok;
1254 int ret;
1255
1256 svnn = talloc_zero(ctdb, struct ctdb_vnn);
1257 CTDB_NO_MEMORY(ctdb, svnn);
1258
1259 svnn->ifaces = talloc_array(svnn, const char *, 2);
1260 CTDB_NO_MEMORY(ctdb, svnn->ifaces);
1261 svnn->ifaces[0] = talloc_strdup(svnn->ifaces, iface);
1262 CTDB_NO_MEMORY(ctdb, svnn->ifaces[0]);
1263 svnn->ifaces[1] = NULL;
1264
1265 ok = parse_ip(ip, iface, 0, &svnn->public_address);
1266 if (!ok) {
1267 talloc_free(svnn);
1268 return -1;
1269 }
1270
1271 ret = ctdb_add_local_iface(ctdb, svnn->ifaces[0]);
1272 if (ret != 0) {
1273 DEBUG(DEBUG_CRIT, (__location__ " failed to add iface[%s] "
1274 "for single_ip[%s]\n",
1275 svnn->ifaces[0],
1276 ctdb_addr_to_str(&svnn->public_address)));
1277 talloc_free(svnn);
1278 return -1;
1279 }
1280
1281 /* assume the single public ip interface is initially "good" */
1282 cur = ctdb_find_iface(ctdb, iface);
1283 if (cur == NULL) {
1284 DEBUG(DEBUG_CRIT,("Can not find public interface %s used by --single-public-ip", iface));
1285 return -1;
1286 }
1287 cur->link_up = true;
1288
1289 ret = ctdb_vnn_assign_iface(ctdb, svnn);
1290 if (ret != 0) {
1291 talloc_free(svnn);
1292 return -1;
1293 }
1294
1295 ctdb->single_ip_vnn = svnn;
1296 return 0;
1297 }
1298
1299 struct ctdb_public_ip_list {
1300 struct ctdb_public_ip_list *next;
1301 uint32_t pnn;
1302 ctdb_sock_addr addr;
1303 };
1304
1305 /* Given a physical node, return the number of
1306 public addresses that is currently assigned to this node.
1307 */
1308 static int node_ip_coverage(struct ctdb_context *ctdb,
1309 int32_t pnn,
1310 struct ctdb_public_ip_list *ips)
1311 {
1312 int num=0;
1313
1314 for (;ips;ips=ips->next) {
1315 if (ips->pnn == pnn) {
1316 num++;
1317 }
1318 }
1319 return num;
1320 }
1321
1322
1323 /* Can the given node host the given IP: is the public IP known to the
1324 * node and is NOIPHOST unset?
1325 */
1326 static bool can_node_host_ip(struct ctdb_context *ctdb, int32_t pnn,
1327 struct ctdb_ipflags ipflags,
1328 struct ctdb_public_ip_list *ip)
1329 {
1330 struct ctdb_all_public_ips *public_ips;
1331 int i;
1332
1333 if (ipflags.noiphost) {
1334 return false;
1335 }
1336
1337 public_ips = ctdb->nodes[pnn]->available_public_ips;
1338
1339 if (public_ips == NULL) {
1340 return false;
1341 }
1342
1343 for (i=0; i<public_ips->num; i++) {
1344 if (ctdb_same_ip(&ip->addr, &public_ips->ips[i].addr)) {
1345 /* yes, this node can serve this public ip */
1346 return true;
1347 }
1348 }
1349
1350 return false;
1351 }
1352
1353 static bool can_node_takeover_ip(struct ctdb_context *ctdb, int32_t pnn,
1354 struct ctdb_ipflags ipflags,
1355 struct ctdb_public_ip_list *ip)
1356 {
1357 if (ipflags.noiptakeover) {
1358 return false;
1359 }
1360
1361 return can_node_host_ip(ctdb, pnn, ipflags, ip);
1362 }
1363
1364 /* search the node lists list for a node to takeover this ip.
1365 pick the node that currently are serving the least number of ips
1366 so that the ips get spread out evenly.
1367 */
1368 static int find_takeover_node(struct ctdb_context *ctdb,
1369 struct ctdb_ipflags *ipflags,
1370 struct ctdb_public_ip_list *ip,
1371 struct ctdb_public_ip_list *all_ips)
1372 {
1373 int pnn, min=0, num;
1374 int i, numnodes;
1375
1376 numnodes = talloc_array_length(ipflags);
1377 pnn = -1;
1378 for (i=0; i<numnodes; i++) {
1379 /* verify that this node can serve this ip */
1380 if (!can_node_takeover_ip(ctdb, i, ipflags[i], ip)) {
1381 /* no it couldnt so skip to the next node */
1382 continue;
1383 }
1384
1385 num = node_ip_coverage(ctdb, i, all_ips);
1386 /* was this the first node we checked ? */
1387 if (pnn == -1) {
1388 pnn = i;
1389 min = num;
1390 } else {
1391 if (num < min) {
1392 pnn = i;
1393 min = num;
1394 }
1395 }
1396 }
1397 if (pnn == -1) {
1398 DEBUG(DEBUG_WARNING,(__location__ " Could not find node to take over public address '%s'\n",
1399 ctdb_addr_to_str(&ip->addr)));
1400
1401 return -1;
1402 }
1403
1404 ip->pnn = pnn;
1405 return 0;
1406 }
1407
1408 #define IP_KEYLEN 4
1409 static uint32_t *ip_key(ctdb_sock_addr *ip)
1410 {
1411 static uint32_t key[IP_KEYLEN];
1412
1413 bzero(key, sizeof(key));
1414
1415 switch (ip->sa.sa_family) {
1416 case AF_INET:
1417 key[3] = htonl(ip->ip.sin_addr.s_addr);
1418 break;
1419 case AF_INET6: {
1420 uint32_t *s6_a32 = (uint32_t *)&(ip->ip6.sin6_addr.s6_addr);
1421 key[0] = htonl(s6_a32[0]);
1422 key[1] = htonl(s6_a32[1]);
1423 key[2] = htonl(s6_a32[2]);
1424 key[3] = htonl(s6_a32[3]);
1425 break;
1426 }
1427 default:
1428 DEBUG(DEBUG_ERR, (__location__ " ERROR, unknown family passed :%u\n", ip->sa.sa_family));
1429 return key;
1430 }
1431
1432 return key;
1433 }
1434
1435 static void *add_ip_callback(void *parm, void *data)
1436 {
1437 struct ctdb_public_ip_list *this_ip = parm;
1438 struct ctdb_public_ip_list *prev_ip = data;
1439
1440 if (prev_ip == NULL) {
1441 return parm;
1442 }
1443 if (this_ip->pnn == -1) {
1444 this_ip->pnn = prev_ip->pnn;
1445 }
1446
1447 return parm;
1448 }
1449
1450 static int getips_count_callback(void *param, void *data)
1451 {
1452 struct ctdb_public_ip_list **ip_list = (struct ctdb_public_ip_list **)param;
1453 struct ctdb_public_ip_list *new_ip = (struct ctdb_public_ip_list *)data;
1454
1455 new_ip->next = *ip_list;
1456 *ip_list = new_ip;
1457 return 0;
1458 }
1459
1460 static struct ctdb_public_ip_list *
1461 create_merged_ip_list(struct ctdb_context *ctdb)
1462 {
1463 int i, j;
1464 struct ctdb_public_ip_list *ip_list;
1465 struct ctdb_all_public_ips *public_ips;
1466
1467 if (ctdb->ip_tree != NULL) {
1468 talloc_free(ctdb->ip_tree);
1469 ctdb->ip_tree = NULL;
1470 }
1471 ctdb->ip_tree = trbt_create(ctdb, 0);
1472
1473 for (i=0;i<ctdb->num_nodes;i++) {
1474 public_ips = ctdb->nodes[i]->known_public_ips;
1475
1476 if (ctdb->nodes[i]->flags & NODE_FLAGS_DELETED) {
1477 continue;
1478 }
1479
1480 /* there were no public ips for this node */
1481 if (public_ips == NULL) {
1482 continue;
1483 }
1484
1485 for (j=0;j<public_ips->num;j++) {
1486 struct ctdb_public_ip_list *tmp_ip;
1487
1488 tmp_ip = talloc_zero(ctdb->ip_tree, struct ctdb_public_ip_list);
1489 CTDB_NO_MEMORY_NULL(ctdb, tmp_ip);
1490 /* Do not use information about IP addresses hosted
1491 * on other nodes, it may not be accurate */
1492 if (public_ips->ips[j].pnn == ctdb->nodes[i]->pnn) {
1493 tmp_ip->pnn = public_ips->ips[j].pnn;
1494 } else {
1495 tmp_ip->pnn = -1;
1496 }
1497 tmp_ip->addr = public_ips->ips[j].addr;
1498 tmp_ip->next = NULL;
1499
1500 trbt_insertarray32_callback(ctdb->ip_tree,
1501 IP_KEYLEN, ip_key(&public_ips->ips[j].addr),
1502 add_ip_callback,
1503 tmp_ip);
1504 }
1505 }
1506
1507 ip_list = NULL;
1508 trbt_traversearray32(ctdb->ip_tree, IP_KEYLEN, getips_count_callback, &ip_list);
1509
1510 return ip_list;
1511 }
1512
1513 /*
1514 * This is the length of the longtest common prefix between the IPs.
1515 * It is calculated by XOR-ing the 2 IPs together and counting the
1516 * number of leading zeroes. The implementation means that all
1517 * addresses end up being 128 bits long.
1518 *
1519 * FIXME? Should we consider IPv4 and IPv6 separately given that the
1520 * 12 bytes of 0 prefix padding will hurt the algorithm if there are
1521 * lots of nodes and IP addresses?
1522 */
1523 static uint32_t ip_distance(ctdb_sock_addr *ip1, ctdb_sock_addr *ip2)
1524 {
1525 uint32_t ip1_k[IP_KEYLEN];
1526 uint32_t *t;
1527 int i;
1528 uint32_t x;
1529
1530 uint32_t distance = 0;
1531
1532 memcpy(ip1_k, ip_key(ip1), sizeof(ip1_k));
1533 t = ip_key(ip2);
1534 for (i=0; i<IP_KEYLEN; i++) {
1535 x = ip1_k[i] ^ t[i];
1536 if (x == 0) {
1537 distance += 32;
1538 } else {
1539 /* Count number of leading zeroes.
1540 * FIXME? This could be optimised...
1541 */
1542 while ((x & (1 << 31)) == 0) {
1543 x <<= 1;
1544 distance += 1;
1545 }
1546 }
1547 }
1548
1549 return distance;
1550 }
1551
1552 /* Calculate the IP distance for the given IP relative to IPs on the
1553 given node. The ips argument is generally the all_ips variable
1554 used in the main part of the algorithm.
1555 */
1556 static uint32_t ip_distance_2_sum(ctdb_sock_addr *ip,
1557 struct ctdb_public_ip_list *ips,
1558 int pnn)
1559 {
1560 struct ctdb_public_ip_list *t;
1561 uint32_t d;
1562
1563 uint32_t sum = 0;
1564
1565 for (t=ips; t != NULL; t=t->next) {
1566 if (t->pnn != pnn) {
1567 continue;
1568 }
1569
1570 /* Optimisation: We never calculate the distance
1571 * between an address and itself. This allows us to
1572 * calculate the effect of removing an address from a
1573 * node by simply calculating the distance between
1574 * that address and all of the exitsing addresses.
1575 * Moreover, we assume that we're only ever dealing
1576 * with addresses from all_ips so we can identify an
1577 * address via a pointer rather than doing a more
1578 * expensive address comparison. */
1579 if (&(t->addr) == ip) {
1580 continue;
1581 }
1582
1583 d = ip_distance(ip, &(t->addr));
1584 sum += d * d; /* Cheaper than pulling in math.h :-) */
1585 }
1586
1587 return sum;
1588 }
1589
1590 /* Return the LCP2 imbalance metric for addresses currently assigned
1591 to the given node.
1592 */
1593 static uint32_t lcp2_imbalance(struct ctdb_public_ip_list * all_ips, int pnn)
1594 {
1595 struct ctdb_public_ip_list *t;
1596
1597 uint32_t imbalance = 0;
1598
1599 for (t=all_ips; t!=NULL; t=t->next) {
1600 if (t->pnn != pnn) {
1601 continue;
1602 }
1603 /* Pass the rest of the IPs rather than the whole
1604 all_ips input list.
1605 */
1606 imbalance += ip_distance_2_sum(&(t->addr), t->next, pnn);
1607 }
1608
1609 return imbalance;
1610 }
1611
1612 /* Allocate any unassigned IPs just by looping through the IPs and
1613 * finding the best node for each.
1614 */
1615 static void basic_allocate_unassigned(struct ctdb_context *ctdb,
1616 struct ctdb_ipflags *ipflags,
1617 struct ctdb_public_ip_list *all_ips)
1618 {
1619 struct ctdb_public_ip_list *tmp_ip;
1620
1621 /* loop over all ip's and find a physical node to cover for
1622 each unassigned ip.
1623 */
1624 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1625 if (tmp_ip->pnn == -1) {
1626 if (find_takeover_node(ctdb, ipflags, tmp_ip, all_ips)) {
1627 DEBUG(DEBUG_WARNING,("Failed to find node to cover ip %s\n",
1628 ctdb_addr_to_str(&tmp_ip->addr)));
1629 }
1630 }
1631 }
1632 }
1633
1634 /* Basic non-deterministic rebalancing algorithm.
1635 */
1636 static void basic_failback(struct ctdb_context *ctdb,
1637 struct ctdb_ipflags *ipflags,
1638 struct ctdb_public_ip_list *all_ips,
1639 int num_ips)
1640 {
1641 int i, numnodes;
1642 int maxnode, maxnum, minnode, minnum, num, retries;
1643 struct ctdb_public_ip_list *tmp_ip;
1644
1645 numnodes = talloc_array_length(ipflags);
1646 retries = 0;
1647
1648 try_again:
1649 maxnum=0;
1650 minnum=0;
1651
1652 /* for each ip address, loop over all nodes that can serve
1653 this ip and make sure that the difference between the node
1654 serving the most and the node serving the least ip's are
1655 not greater than 1.
1656 */
1657 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1658 if (tmp_ip->pnn == -1) {
1659 continue;
1660 }
1661
1662 /* Get the highest and lowest number of ips's served by any
1663 valid node which can serve this ip.
1664 */
1665 maxnode = -1;
1666 minnode = -1;
1667 for (i=0; i<numnodes; i++) {
1668 /* only check nodes that can actually serve this ip */
1669 if (!can_node_takeover_ip(ctdb, i, ipflags[i], tmp_ip)) {
1670 /* no it couldnt so skip to the next node */
1671 continue;
1672 }
1673
1674 num = node_ip_coverage(ctdb, i, all_ips);
1675 if (maxnode == -1) {
1676 maxnode = i;
1677 maxnum = num;
1678 } else {
1679 if (num > maxnum) {
1680 maxnode = i;
1681 maxnum = num;
1682 }
1683 }
1684 if (minnode == -1) {
1685 minnode = i;
1686 minnum = num;
1687 } else {
1688 if (num < minnum) {
1689 minnode = i;
1690 minnum = num;
1691 }
1692 }
1693 }
1694 if (maxnode == -1) {
1695 DEBUG(DEBUG_WARNING,(__location__ " Could not find maxnode. May not be able to serve ip '%s'\n",
1696 ctdb_addr_to_str(&tmp_ip->addr)));
1697
1698 continue;
1699 }
1700
1701 /* if the spread between the smallest and largest coverage by
1702 a node is >=2 we steal one of the ips from the node with
1703 most coverage to even things out a bit.
1704 try to do this a limited number of times since we dont
1705 want to spend too much time balancing the ip coverage.
1706 */
1707 if ( (maxnum > minnum+1)
1708 && (retries < (num_ips + 5)) ){
1709 struct ctdb_public_ip_list *tmp;
1710
1711 /* Reassign one of maxnode's VNNs */
1712 for (tmp=all_ips;tmp;tmp=tmp->next) {
1713 if (tmp->pnn == maxnode) {
1714 (void)find_takeover_node(ctdb, ipflags, tmp, all_ips);
1715 retries++;
1716 goto try_again;;
1717 }
1718 }
1719 }
1720 }
1721 }
1722
1723 static void lcp2_init(struct ctdb_context *tmp_ctx,
1724 struct ctdb_ipflags *ipflags,
1725 struct ctdb_public_ip_list *all_ips,
1726 uint32_t *force_rebalance_nodes,
1727 uint32_t **lcp2_imbalances,
1728 bool **rebalance_candidates)
1729 {
1730 int i, numnodes;
1731 struct ctdb_public_ip_list *tmp_ip;
1732
1733 numnodes = talloc_array_length(ipflags);
1734
1735 *rebalance_candidates = talloc_array(tmp_ctx, bool, numnodes);
1736 CTDB_NO_MEMORY_FATAL(tmp_ctx, *rebalance_candidates);
1737 *lcp2_imbalances = talloc_array(tmp_ctx, uint32_t, numnodes);
1738 CTDB_NO_MEMORY_FATAL(tmp_ctx, *lcp2_imbalances);
1739
1740 for (i=0; i<numnodes; i++) {
1741 (*lcp2_imbalances)[i] = lcp2_imbalance(all_ips, i);
1742 /* First step: assume all nodes are candidates */
1743 (*rebalance_candidates)[i] = true;
1744 }
1745
1746 /* 2nd step: if a node has IPs assigned then it must have been
1747 * healthy before, so we remove it from consideration. This
1748 * is overkill but is all we have because we don't maintain
1749 * state between takeover runs. An alternative would be to
1750 * keep state and invalidate it every time the recovery master
1751 * changes.
1752 */
1753 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1754 if (tmp_ip->pnn != -1) {
1755 (*rebalance_candidates)[tmp_ip->pnn] = false;
1756 }
1757 }
1758
1759 /* 3rd step: if a node is forced to re-balance then
1760 we allow failback onto the node */
1761 if (force_rebalance_nodes == NULL) {
1762 return;
1763 }
1764 for (i = 0; i < talloc_array_length(force_rebalance_nodes); i++) {
1765 uint32_t pnn = force_rebalance_nodes[i];
1766 if (pnn >= numnodes) {
1767 DEBUG(DEBUG_ERR,
1768 (__location__ "unknown node %u\n", pnn));
1769 continue;
1770 }
1771
1772 DEBUG(DEBUG_NOTICE,
1773 ("Forcing rebalancing of IPs to node %u\n", pnn));
1774 (*rebalance_candidates)[pnn] = true;
1775 }
1776 }
1777
1778 /* Allocate any unassigned addresses using the LCP2 algorithm to find
1779 * the IP/node combination that will cost the least.
1780 */
1781 static void lcp2_allocate_unassigned(struct ctdb_context *ctdb,
1782 struct ctdb_ipflags *ipflags,
1783 struct ctdb_public_ip_list *all_ips,
1784 uint32_t *lcp2_imbalances)
1785 {
1786 struct ctdb_public_ip_list *tmp_ip;
1787 int dstnode, numnodes;
1788
1789 int minnode;
1790 uint32_t mindsum, dstdsum, dstimbl, minimbl;
1791 struct ctdb_public_ip_list *minip;
1792
1793 bool should_loop = true;
1794 bool have_unassigned = true;
1795
1796 numnodes = talloc_array_length(ipflags);
1797
1798 while (have_unassigned && should_loop) {
1799 should_loop = false;
1800
1801 DEBUG(DEBUG_DEBUG,(" ----------------------------------------\n"));
1802 DEBUG(DEBUG_DEBUG,(" CONSIDERING MOVES (UNASSIGNED)\n"));
1803
1804 minnode = -1;
1805 mindsum = 0;
1806 minip = NULL;
1807
1808 /* loop over each unassigned ip. */
1809 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1810 if (tmp_ip->pnn != -1) {
1811 continue;
1812 }
1813
1814 for (dstnode=0; dstnode<numnodes; dstnode++) {
1815 /* only check nodes that can actually takeover this ip */
1816 if (!can_node_takeover_ip(ctdb, dstnode,
1817 ipflags[dstnode],
1818 tmp_ip)) {
1819 /* no it couldnt so skip to the next node */
1820 continue;
1821 }
1822
1823 dstdsum = ip_distance_2_sum(&(tmp_ip->addr), all_ips, dstnode);
1824 dstimbl = lcp2_imbalances[dstnode] + dstdsum;
1825 DEBUG(DEBUG_DEBUG,(" %s -> %d [+%d]\n",
1826 ctdb_addr_to_str(&(tmp_ip->addr)),
1827 dstnode,
1828 dstimbl - lcp2_imbalances[dstnode]));
1829
1830
1831 if ((minnode == -1) || (dstdsum < mindsum)) {
1832 minnode = dstnode;
1833 minimbl = dstimbl;
1834 mindsum = dstdsum;
1835 minip = tmp_ip;
1836 should_loop = true;
1837 }
1838 }
1839 }
1840
1841 DEBUG(DEBUG_DEBUG,(" ----------------------------------------\n"));
1842
1843 /* If we found one then assign it to the given node. */
1844 if (minnode != -1) {
1845 minip->pnn = minnode;
1846 lcp2_imbalances[minnode] = minimbl;
1847 DEBUG(DEBUG_INFO,(" %s -> %d [+%d]\n",
1848 ctdb_addr_to_str(&(minip->addr)),
1849 minnode,
1850 mindsum));
1851 }
1852
1853 /* There might be a better way but at least this is clear. */
1854 have_unassigned = false;
1855 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1856 if (tmp_ip->pnn == -1) {
1857 have_unassigned = true;
1858 }
1859 }
1860 }
1861
1862 /* We know if we have an unassigned addresses so we might as
1863 * well optimise.
1864 */
1865 if (have_unassigned) {
1866 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
1867 if (tmp_ip->pnn == -1) {
1868 DEBUG(DEBUG_WARNING,("Failed to find node to cover ip %s\n",
1869 ctdb_addr_to_str(&tmp_ip->addr)));
1870 }
1871 }
1872 }
1873 }
1874
1875 /* LCP2 algorithm for rebalancing the cluster. Given a candidate node
1876 * to move IPs from, determines the best IP/destination node
1877 * combination to move from the source node.
1878 */
1879 static bool lcp2_failback_candidate(struct ctdb_context *ctdb,
1880 struct ctdb_ipflags *ipflags,
1881 struct ctdb_public_ip_list *all_ips,
1882 int srcnode,
1883 uint32_t *lcp2_imbalances,
1884 bool *rebalance_candidates)
1885 {
1886 int dstnode, mindstnode, numnodes;
1887 uint32_t srcimbl, srcdsum, dstimbl, dstdsum;
1888 uint32_t minsrcimbl, mindstimbl;
1889 struct ctdb_public_ip_list *minip;
1890 struct ctdb_public_ip_list *tmp_ip;
1891
1892 /* Find an IP and destination node that best reduces imbalance. */
1893 srcimbl = 0;
1894 minip = NULL;
1895 minsrcimbl = 0;
1896 mindstnode = -1;
1897 mindstimbl = 0;
1898
1899 numnodes = talloc_array_length(ipflags);
1900
1901 DEBUG(DEBUG_DEBUG,(" ----------------------------------------\n"));
1902 DEBUG(DEBUG_DEBUG,(" CONSIDERING MOVES FROM %d [%d]\n",
1903 srcnode, lcp2_imbalances[srcnode]));
1904
1905 for (tmp_ip=all_ips; tmp_ip; tmp_ip=tmp_ip->next) {
1906 /* Only consider addresses on srcnode. */
1907 if (tmp_ip->pnn != srcnode) {
1908 continue;
1909 }
1910
1911 /* What is this IP address costing the source node? */
1912 srcdsum = ip_distance_2_sum(&(tmp_ip->addr), all_ips, srcnode);
1913 srcimbl = lcp2_imbalances[srcnode] - srcdsum;
1914
1915 /* Consider this IP address would cost each potential
1916 * destination node. Destination nodes are limited to
1917 * those that are newly healthy, since we don't want
1918 * to do gratuitous failover of IPs just to make minor
1919 * balance improvements.
1920 */
1921 for (dstnode=0; dstnode<numnodes; dstnode++) {
1922 if (!rebalance_candidates[dstnode]) {
1923 continue;
1924 }
1925
1926 /* only check nodes that can actually takeover this ip */
1927 if (!can_node_takeover_ip(ctdb, dstnode,
1928 ipflags[dstnode], tmp_ip)) {
1929 /* no it couldnt so skip to the next node */
1930 continue;
1931 }
1932
1933 dstdsum = ip_distance_2_sum(&(tmp_ip->addr), all_ips, dstnode);
1934 dstimbl = lcp2_imbalances[dstnode] + dstdsum;
1935 DEBUG(DEBUG_DEBUG,(" %d [%d] -> %s -> %d [+%d]\n",
1936 srcnode, -srcdsum,
1937 ctdb_addr_to_str(&(tmp_ip->addr)),
1938 dstnode, dstdsum));
1939
1940 if ((dstimbl < lcp2_imbalances[srcnode]) &&
1941 (dstdsum < srcdsum) && \
1942 ((mindstnode == -1) || \
1943 ((srcimbl + dstimbl) < (minsrcimbl + mindstimbl)))) {
1944
1945 minip = tmp_ip;
1946 minsrcimbl = srcimbl;
1947 mindstnode = dstnode;
1948 mindstimbl = dstimbl;
1949 }
1950 }
1951 }
1952 DEBUG(DEBUG_DEBUG,(" ----------------------------------------\n"));
1953
1954 if (mindstnode != -1) {
1955 /* We found a move that makes things better... */
1956 DEBUG(DEBUG_INFO,("%d [%d] -> %s -> %d [+%d]\n",
1957 srcnode, minsrcimbl - lcp2_imbalances[srcnode],
1958 ctdb_addr_to_str(&(minip->addr)),
1959 mindstnode, mindstimbl - lcp2_imbalances[mindstnode]));
1960
1961
1962 lcp2_imbalances[srcnode] = minsrcimbl;
1963 lcp2_imbalances[mindstnode] = mindstimbl;
1964 minip->pnn = mindstnode;
1965
1966 return true;
1967 }
1968
1969 return false;
1970
1971 }
1972
1973 struct lcp2_imbalance_pnn {
1974 uint32_t imbalance;
1975 int pnn;
1976 };
1977
1978 static int lcp2_cmp_imbalance_pnn(const void * a, const void * b)
1979 {
1980 const struct lcp2_imbalance_pnn * lipa = (const struct lcp2_imbalance_pnn *) a;
1981 const struct lcp2_imbalance_pnn * lipb = (const struct lcp2_imbalance_pnn *) b;
1982
1983 if (lipa->imbalance > lipb->imbalance) {
1984 return -1;
1985 } else if (lipa->imbalance == lipb->imbalance) {
1986 return 0;
1987 } else {
1988 return 1;
1989 }
1990 }
1991
1992 /* LCP2 algorithm for rebalancing the cluster. This finds the source
1993 * node with the highest LCP2 imbalance, and then determines the best
1994 * IP/destination node combination to move from the source node.
1995 */
1996 static void lcp2_failback(struct ctdb_context *ctdb,
1997 struct ctdb_ipflags *ipflags,
1998 struct ctdb_public_ip_list *all_ips,
1999 uint32_t *lcp2_imbalances,
2000 bool *rebalance_candidates)
2001 {
2002 int i, numnodes;
2003 struct lcp2_imbalance_pnn * lips;
2004 bool again;
2005
2006 numnodes = talloc_array_length(ipflags);
2007
2008 try_again:
2009 /* Put the imbalances and nodes into an array, sort them and
2010 * iterate through candidates. Usually the 1st one will be
2011 * used, so this doesn't cost much...
2012 */
2013 DEBUG(DEBUG_DEBUG,("+++++++++++++++++++++++++++++++++++++++++\n"));
2014 DEBUG(DEBUG_DEBUG,("Selecting most imbalanced node from:\n"));
2015 lips = talloc_array(ctdb, struct lcp2_imbalance_pnn, numnodes);
2016 for (i=0; i<numnodes; i++) {
2017 lips[i].imbalance = lcp2_imbalances[i];
2018 lips[i].pnn = i;
2019 DEBUG(DEBUG_DEBUG,(" %d [%d]\n", i, lcp2_imbalances[i]));
2020 }
2021 qsort(lips, numnodes, sizeof(struct lcp2_imbalance_pnn),
2022 lcp2_cmp_imbalance_pnn);
2023
2024 again = false;
2025 for (i=0; i<numnodes; i++) {
2026 /* This means that all nodes had 0 or 1 addresses, so
2027 * can't be imbalanced.
2028 */
2029 if (lips[i].imbalance == 0) {
2030 break;
2031 }
2032
2033 if (lcp2_failback_candidate(ctdb,
2034 ipflags,
2035 all_ips,
2036 lips[i].pnn,
2037 lcp2_imbalances,
2038 rebalance_candidates)) {
2039 again = true;
2040 break;
2041 }
2042 }
2043
2044 talloc_free(lips);
2045 if (again) {
2046 goto try_again;
2047 }
2048 }
2049
2050 static void unassign_unsuitable_ips(struct ctdb_context *ctdb,
2051 struct ctdb_ipflags *ipflags,
2052 struct ctdb_public_ip_list *all_ips)
2053 {
2054 struct ctdb_public_ip_list *tmp_ip;
2055
2056 /* verify that the assigned nodes can serve that public ip
2057 and set it to -1 if not
2058 */
2059 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
2060 if (tmp_ip->pnn == -1) {
2061 continue;
2062 }
2063 if (!can_node_host_ip(ctdb, tmp_ip->pnn,
2064 ipflags[tmp_ip->pnn], tmp_ip) != 0) {
2065 /* this node can not serve this ip. */
2066 DEBUG(DEBUG_DEBUG,("Unassign IP: %s from %d\n",
2067 ctdb_addr_to_str(&(tmp_ip->addr)),
2068 tmp_ip->pnn));
2069 tmp_ip->pnn = -1;
2070 }
2071 }
2072 }
2073
2074 static void ip_alloc_deterministic_ips(struct ctdb_context *ctdb,
2075 struct ctdb_ipflags *ipflags,
2076 struct ctdb_public_ip_list *all_ips)
2077 {
2078 struct ctdb_public_ip_list *tmp_ip;
2079 int i, numnodes;
2080
2081 numnodes = talloc_array_length(ipflags);
2082
2083 DEBUG(DEBUG_NOTICE,("Deterministic IPs enabled. Resetting all ip allocations\n"));
2084 /* Allocate IPs to nodes in a modulo fashion so that IPs will
2085 * always be allocated the same way for a specific set of
2086 * available/unavailable nodes.
2087 */
2088
2089 for (i=0,tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next,i++) {
2090 tmp_ip->pnn = i % numnodes;
2091 }
2092
2093 /* IP failback doesn't make sense with deterministic
2094 * IPs, since the modulo step above implicitly fails
2095 * back IPs to their "home" node.
2096 */
2097 if (1 == ctdb->tunable.no_ip_failback) {
2098 DEBUG(DEBUG_WARNING, ("WARNING: 'NoIPFailback' set but ignored - incompatible with 'DeterministicIPs\n"));
2099 }
2100
2101 unassign_unsuitable_ips(ctdb, ipflags, all_ips);
2102
2103 basic_allocate_unassigned(ctdb, ipflags, all_ips);
2104
2105 /* No failback here! */
2106 }
2107
2108 static void ip_alloc_nondeterministic_ips(struct ctdb_context *ctdb,
2109 struct ctdb_ipflags *ipflags,
2110 struct ctdb_public_ip_list *all_ips)
2111 {
2112 /* This should be pushed down into basic_failback. */
2113 struct ctdb_public_ip_list *tmp_ip;
2114 int num_ips = 0;
2115 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
2116 num_ips++;
2117 }
2118
2119 unassign_unsuitable_ips(ctdb, ipflags, all_ips);
2120
2121 basic_allocate_unassigned(ctdb, ipflags, all_ips);
2122
2123 /* If we don't want IPs to fail back then don't rebalance IPs. */
2124 if (1 == ctdb->tunable.no_ip_failback) {
2125 return;
2126 }
2127
2128 /* Now, try to make sure the ip adresses are evenly distributed
2129 across the nodes.
2130 */
2131 basic_failback(ctdb, ipflags, all_ips, num_ips);
2132 }
2133
2134 static void ip_alloc_lcp2(struct ctdb_context *ctdb,
2135 struct ctdb_ipflags *ipflags,
2136 struct ctdb_public_ip_list *all_ips,
2137 uint32_t *force_rebalance_nodes)
2138 {
2139 uint32_t *lcp2_imbalances;
2140 bool *rebalance_candidates;
2141 int numnodes, num_rebalance_candidates, i;
2142
2143 TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
2144
2145 unassign_unsuitable_ips(ctdb, ipflags, all_ips);
2146
2147 lcp2_init(tmp_ctx, ipflags, all_ips,force_rebalance_nodes,
2148 &lcp2_imbalances, &rebalance_candidates);
2149
2150 lcp2_allocate_unassigned(ctdb, ipflags, all_ips, lcp2_imbalances);
2151
2152 /* If we don't want IPs to fail back then don't rebalance IPs. */
2153 if (1 == ctdb->tunable.no_ip_failback) {
2154 goto finished;
2155 }
2156
2157 /* It is only worth continuing if we have suitable target
2158 * nodes to transfer IPs to. This check is much cheaper than
2159 * continuing on...
2160 */
2161 numnodes = talloc_array_length(ipflags);
2162 num_rebalance_candidates = 0;
2163 for (i=0; i<numnodes; i++) {
2164 if (rebalance_candidates[i]) {
2165 num_rebalance_candidates++;
2166 }
2167 }
2168 if (num_rebalance_candidates == 0) {
2169 goto finished;
2170 }
2171
2172 /* Now, try to make sure the ip adresses are evenly distributed
2173 across the nodes.
2174 */
2175 lcp2_failback(ctdb, ipflags, all_ips,
2176 lcp2_imbalances, rebalance_candidates);
2177
2178 finished:
2179 talloc_free(tmp_ctx);
2180 }
2181
2182 static bool all_nodes_are_disabled(struct ctdb_node_map *nodemap)
2183 {
2184 int i, num_healthy;
2185
2186 /* Count how many completely healthy nodes we have */
2187 num_healthy = 0;
2188 for (i=0;i<nodemap->num;i++) {
2189 if (!(nodemap->nodes[i].flags & (NODE_FLAGS_INACTIVE|NODE_FLAGS_DISABLED))) {
2190 num_healthy++;
2191 }
2192 }
2193
2194 return num_healthy == 0;
2195 }
2196
2197 /* The calculation part of the IP allocation algorithm. */
2198 static void ctdb_takeover_run_core(struct ctdb_context *ctdb,
2199 struct ctdb_ipflags *ipflags,
2200 struct ctdb_public_ip_list **all_ips_p,
2201 uint32_t *force_rebalance_nodes)
2202 {
2203 /* since nodes only know about those public addresses that
2204 can be served by that particular node, no single node has
2205 a full list of all public addresses that exist in the cluster.
2206 Walk over all node structures and create a merged list of
2207 all public addresses that exist in the cluster.
2208
2209 keep the tree of ips around as ctdb->ip_tree
2210 */
2211 *all_ips_p = create_merged_ip_list(ctdb);
2212
2213 if (1 == ctdb->tunable.lcp2_public_ip_assignment) {
2214 ip_alloc_lcp2(ctdb, ipflags, *all_ips_p, force_rebalance_nodes);
2215 } else if (1 == ctdb->tunable.deterministic_public_ips) {
2216 ip_alloc_deterministic_ips(ctdb, ipflags, *all_ips_p);
2217 } else {
2218 ip_alloc_nondeterministic_ips(ctdb, ipflags, *all_ips_p);
2219 }
2220
2221 /* at this point ->pnn is the node which will own each IP
2222 or -1 if there is no node that can cover this ip
2223 */
2224
2225 return;
2226 }
2227
2228 struct get_tunable_callback_data {
2229 const char *tunable;
2230 uint32_t *out;
2231 bool fatal;
2232 };
2233
2234 static void get_tunable_callback(struct ctdb_context *ctdb, uint32_t pnn,
2235 int32_t res, TDB_DATA outdata,
2236 void *callback)
2237 {
2238 struct get_tunable_callback_data *cd =
2239 (struct get_tunable_callback_data *)callback;
2240 int size;
2241
2242 if (res != 0) {
2243 /* Already handled in fail callback */
2244 return;
2245 }
2246
2247 if (outdata.dsize != sizeof(uint32_t)) {
2248 DEBUG(DEBUG_ERR,("Wrong size of returned data when reading \"%s\" tunable from node %d. Expected %d bytes but received %d bytes\n",
2249 cd->tunable, pnn, (int)sizeof(uint32_t),
2250 (int)outdata.dsize));
2251 cd->fatal = true;
2252 return;
2253 }
2254
2255 size = talloc_array_length(cd->out);
2256 if (pnn >= size) {
2257 DEBUG(DEBUG_ERR,("Got %s reply from node %d but nodemap only has %d entries\n",
2258 cd->tunable, pnn, size));
2259 return;
2260 }
2261
2262
2263 cd->out[pnn] = *(uint32_t *)outdata.dptr;
2264 }
2265
2266 static void get_tunable_fail_callback(struct ctdb_context *ctdb, uint32_t pnn,
2267 int32_t res, TDB_DATA outdata,
2268 void *callback)
2269 {
2270 struct get_tunable_callback_data *cd =
2271 (struct get_tunable_callback_data *)callback;
2272
2273 switch (res) {
2274 case -ETIME:
2275 DEBUG(DEBUG_ERR,
2276 ("Timed out getting tunable \"%s\" from node %d\n",
2277 cd->tunable, pnn));
2278 cd->fatal = true;
2279 break;
2280 case -EINVAL:
2281 case -1:
2282 DEBUG(DEBUG_WARNING,
2283 ("Tunable \"%s\" not implemented on node %d\n",
2284 cd->tunable, pnn));
2285 break;
2286 default:
2287 DEBUG(DEBUG_ERR,
2288 ("Unexpected error getting tunable \"%s\" from node %d\n",
2289 cd->tunable, pnn));
2290 cd->fatal = true;
2291 }
2292 }
2293
2294 static uint32_t *get_tunable_from_nodes(struct ctdb_context *ctdb,
2295 TALLOC_CTX *tmp_ctx,
2296 struct ctdb_node_map *nodemap,
2297 const char *tunable,
2298 uint32_t default_value)
2299 {
2300 TDB_DATA data;
2301 struct ctdb_control_get_tunable *t;
2302 uint32_t *nodes;
2303 uint32_t *tvals;
2304 struct get_tunable_callback_data callback_data;
2305 int i;
2306
2307 tvals = talloc_array(tmp_ctx, uint32_t, nodemap->num);
2308 CTDB_NO_MEMORY_NULL(ctdb, tvals);
2309 for (i=0; i<nodemap->num; i++) {
2310 tvals[i] = default_value;
2311 }
2312
2313 callback_data.out = tvals;
2314 callback_data.tunable = tunable;
2315 callback_data.fatal = false;
2316
2317 data.dsize = offsetof(struct ctdb_control_get_tunable, name) + strlen(tunable) + 1;
2318 data.dptr = talloc_size(tmp_ctx, data.dsize);
2319 t = (struct ctdb_control_get_tunable *)data.dptr;
2320 t->length = strlen(tunable)+1;
2321 memcpy(t->name, tunable, t->length);
2322 nodes = list_of_connected_nodes(ctdb, nodemap, tmp_ctx, true);
2323 if (ctdb_client_async_control(ctdb, CTDB_CONTROL_GET_TUNABLE,
2324 nodes, 0, TAKEOVER_TIMEOUT(),
2325 false, data,
2326 get_tunable_callback,
2327 get_tunable_fail_callback,
2328 &callback_data) != 0) {
2329 if (callback_data.fatal) {
2330 talloc_free(tvals);
2331 tvals = NULL;
2332 }
2333 }
2334 talloc_free(nodes);
2335 talloc_free(data.dptr);
2336
2337 return tvals;
2338 }
2339
2340 struct get_runstate_callback_data {
2341 enum ctdb_runstate *out;
2342 bool fatal;
2343 };
2344
2345 static void get_runstate_callback(struct ctdb_context *ctdb, uint32_t pnn,
2346 int32_t res, TDB_DATA outdata,
2347 void *callback_data)
2348 {
2349 struct get_runstate_callback_data *cd =
2350 (struct get_runstate_callback_data *)callback_data;
2351 int size;
2352
2353 if (res != 0) {
2354 /* Already handled in fail callback */
2355 return;
2356 }
2357
2358 if (outdata.dsize != sizeof(uint32_t)) {
2359 DEBUG(DEBUG_ERR,("Wrong size of returned data when getting runstate from node %d. Expected %d bytes but received %d bytes\n",
2360 pnn, (int)sizeof(uint32_t),
2361 (int)outdata.dsize));
2362 cd->fatal = true;
2363 return;
2364 }
2365
2366 size = talloc_array_length(cd->out);
2367 if (pnn >= size) {
2368 DEBUG(DEBUG_ERR,("Got reply from node %d but nodemap only has %d entries\n",
2369 pnn, size));
2370 return;
2371 }
2372
2373 cd->out[pnn] = (enum ctdb_runstate)*(uint32_t *)outdata.dptr;
2374 }
2375
2376 static void get_runstate_fail_callback(struct ctdb_context *ctdb, uint32_t pnn,
2377 int32_t res, TDB_DATA outdata,
2378 void *callback)
2379 {
2380 struct get_runstate_callback_data *cd =
2381 (struct get_runstate_callback_data *)callback;
2382
2383 switch (res) {
2384 case -ETIME:
2385 DEBUG(DEBUG_ERR,
2386 ("Timed out getting runstate from node %d\n", pnn));
2387 cd->fatal = true;
2388 break;
2389 default:
2390 DEBUG(DEBUG_WARNING,
2391 ("Error getting runstate from node %d - assuming runstates not supported\n",
2392 pnn));
2393 }
2394 }
2395
2396 static enum ctdb_runstate * get_runstate_from_nodes(struct ctdb_context *ctdb,
2397 TALLOC_CTX *tmp_ctx,
2398 struct ctdb_node_map *nodemap,
2399 enum ctdb_runstate default_value)
2400 {
2401 uint32_t *nodes;
2402 enum ctdb_runstate *rs;
2403 struct get_runstate_callback_data callback_data;
2404 int i;
2405
2406 rs = talloc_array(tmp_ctx, enum ctdb_runstate, nodemap->num);
2407 CTDB_NO_MEMORY_NULL(ctdb, rs);
2408 for (i=0; i<nodemap->num; i++) {
2409 rs[i] = default_value;
2410 }
2411
2412 callback_data.out = rs;
2413 callback_data.fatal = false;
2414
2415 nodes = list_of_connected_nodes(ctdb, nodemap, tmp_ctx, true);
2416 if (ctdb_client_async_control(ctdb, CTDB_CONTROL_GET_RUNSTATE,
2417 nodes, 0, TAKEOVER_TIMEOUT(),
2418 true, tdb_null,
2419 get_runstate_callback,
2420 get_runstate_fail_callback,
2421 &callback_data) != 0) {
2422 if (callback_data.fatal) {
2423 free(rs);
2424 rs = NULL;
2425 }
2426 }
2427 talloc_free(nodes);
2428
2429 return rs;
2430 }
2431
2432 /* Set internal flags for IP allocation:
2433 * Clear ip flags
2434 * Set NOIPTAKOVER ip flags from per-node NoIPTakeover tunable
2435 * Set NOIPHOST ip flag for each INACTIVE node
2436 * if all nodes are disabled:
2437 * Set NOIPHOST ip flags from per-node NoIPHostOnAllDisabled tunable
2438 * else
2439 * Set NOIPHOST ip flags for disabled nodes
2440 */
2441 static struct ctdb_ipflags *
2442 set_ipflags_internal(struct ctdb_context *ctdb,
2443 TALLOC_CTX *tmp_ctx,
2444 struct ctdb_node_map *nodemap,
2445 uint32_t *tval_noiptakeover,
2446 uint32_t *tval_noiphostonalldisabled,
2447 enum ctdb_runstate *runstate)
2448 {
2449 int i;
2450 struct ctdb_ipflags *ipflags;
2451
2452 /* Clear IP flags - implicit due to talloc_zero */
2453 ipflags = talloc_zero_array(tmp_ctx, struct ctdb_ipflags, nodemap->num);
2454 CTDB_NO_MEMORY_NULL(ctdb, ipflags);
2455
2456 for (i=0;i<nodemap->num;i++) {
2457 /* Can not take IPs on node with NoIPTakeover set */
2458 if (tval_noiptakeover[i] != 0) {
2459 ipflags[i].noiptakeover = true;
2460 }
2461
2462 /* Can not host IPs on node not in RUNNING state */
2463 if (runstate[i] != CTDB_RUNSTATE_RUNNING) {
2464 ipflags[i].noiphost = true;
2465 continue;
2466 }
2467 /* Can not host IPs on INACTIVE node */
2468 if (nodemap->nodes[i].flags & NODE_FLAGS_INACTIVE) {
2469 ipflags[i].noiphost = true;
2470 }
2471 }
2472
2473 if (all_nodes_are_disabled(nodemap)) {
2474 /* If all nodes are disabled, can not host IPs on node
2475 * with NoIPHostOnAllDisabled set
2476 */
2477 for (i=0;i<nodemap->num;i++) {
2478 if (tval_noiphostonalldisabled[i] != 0) {
2479 ipflags[i].noiphost = true;
2480 }
2481 }
2482 } else {
2483 /* If some nodes are not disabled, then can not host
2484 * IPs on DISABLED node
2485 */
2486 for (i=0;i<nodemap->num;i++) {
2487 if (nodemap->nodes[i].flags & NODE_FLAGS_DISABLED) {
2488 ipflags[i].noiphost = true;
2489 }
2490 }
2491 }
2492
2493 return ipflags;
2494 }
2495
2496 static struct ctdb_ipflags *set_ipflags(struct ctdb_context *ctdb,
2497 TALLOC_CTX *tmp_ctx,
2498 struct ctdb_node_map *nodemap)
2499 {
2500 uint32_t *tval_noiptakeover;
2501 uint32_t *tval_noiphostonalldisabled;
2502 struct ctdb_ipflags *ipflags;
2503 enum ctdb_runstate *runstate;
2504
2505
2506 tval_noiptakeover = get_tunable_from_nodes(ctdb, tmp_ctx, nodemap,
2507 "NoIPTakeover", 0);
2508 if (tval_noiptakeover == NULL) {
2509 return NULL;
2510 }
2511
2512 tval_noiphostonalldisabled =
2513 get_tunable_from_nodes(ctdb, tmp_ctx, nodemap,
2514 "NoIPHostOnAllDisabled", 0);
2515 if (tval_noiphostonalldisabled == NULL) {
2516 /* Caller frees tmp_ctx */
2517 return NULL;
2518 }
2519
2520 /* Any nodes where CTDB_CONTROL_GET_RUNSTATE is not supported
2521 * will default to CTDB_RUNSTATE_RUNNING. This ensures
2522 * reasonable behaviour on a mixed cluster during upgrade.
2523 */
2524 runstate = get_runstate_from_nodes(ctdb, tmp_ctx, nodemap,
2525 CTDB_RUNSTATE_RUNNING);
2526 if (runstate == NULL) {
2527 /* Caller frees tmp_ctx */
2528 return NULL;
2529 }
2530
2531 ipflags = set_ipflags_internal(ctdb, tmp_ctx, nodemap,
2532 tval_noiptakeover,
2533 tval_noiphostonalldisabled,
2534 runstate);
2535
2536 talloc_free(tval_noiptakeover);
2537 talloc_free(tval_noiphostonalldisabled);
2538 talloc_free(runstate);
2539
2540 return ipflags;
2541 }
2542
2543 struct iprealloc_callback_data {
2544 bool *retry_nodes;
2545 int retry_count;
2546 client_async_callback fail_callback;
2547 void *fail_callback_data;
2548 struct ctdb_node_map *nodemap;
2549 };
2550
2551 static void iprealloc_fail_callback(struct ctdb_context *ctdb, uint32_t pnn,
2552 int32_t res, TDB_DATA outdata,
2553 void *callback)
2554 {
2555 int numnodes;
2556 struct iprealloc_callback_data *cd =
2557 (struct iprealloc_callback_data *)callback;
2558
2559 numnodes = talloc_array_length(cd->retry_nodes);
2560 if (pnn > numnodes) {
2561 DEBUG(DEBUG_ERR,
2562 ("ipreallocated failure from node %d, "
2563 "but only %d nodes in nodemap\n",
2564 pnn, numnodes));
2565 return;
2566 }
2567
2568 /* Can't run the "ipreallocated" event on a INACTIVE node */
2569 if (cd->nodemap->nodes[pnn].flags & NODE_FLAGS_INACTIVE) {
2570 DEBUG(DEBUG_WARNING,
2571 ("ipreallocated failed on inactive node %d, ignoring\n",
2572 pnn));
2573 return;
2574 }
2575
2576 switch (res) {
2577 case -ETIME:
2578 /* If the control timed out then that's a real error,
2579 * so call the real fail callback
2580 */
2581 cd->fail_callback(ctdb, pnn, res, outdata,
2582 cd->fail_callback_data);
2583 break;
2584 default:
2585 /* If not a timeout then either the ipreallocated
2586 * eventscript (or some setup) failed. This might
2587 * have failed because the IPREALLOCATED control isn't
2588 * implemented - right now there is no way of knowing
2589 * because the error codes are all folded down to -1.
2590 * Consider retrying using EVENTSCRIPT control...
2591 */
2592 DEBUG(DEBUG_WARNING,
2593 ("ipreallocated failure from node %d, flagging retry\n",
2594 pnn));
2595 cd->retry_nodes[pnn] = true;
2596 cd->retry_count++;
2597 }
2598 }
2599
2600 struct takeover_callback_data {
2601 bool *node_failed;
2602 client_async_callback fail_callback;
2603 void *fail_callback_data;
2604 struct ctdb_node_map *nodemap;
2605 };
2606
2607 static void takeover_run_fail_callback(struct ctdb_context *ctdb,
2608 uint32_t node_pnn, int32_t res,
2609 TDB_DATA outdata, void *callback_data)
2610 {
2611 struct takeover_callback_data *cd =
2612 talloc_get_type_abort(callback_data,
2613 struct takeover_callback_data);
2614 int i;
2615
2616 for (i = 0; i < cd->nodemap->num; i++) {
2617 if (node_pnn == cd->nodemap->nodes[i].pnn) {
2618 break;
2619 }
2620 }
2621
2622 if (i == cd->nodemap->num) {
2623 DEBUG(DEBUG_ERR, (__location__ " invalid PNN %u\n", node_pnn));
2624 return;
2625 }
2626
2627 if (!cd->node_failed[i]) {
2628 cd->node_failed[i] = true;
2629 cd->fail_callback(ctdb, node_pnn, res, outdata,
2630 cd->fail_callback_data);
2631 }
2632 }
2633
2634 /*
2635 make any IP alias changes for public addresses that are necessary
2636 */
2637 int ctdb_takeover_run(struct ctdb_context *ctdb, struct ctdb_node_map *nodemap,
2638 uint32_t *force_rebalance_nodes,
2639 client_async_callback fail_callback, void *callback_data)
2640 {
2641 int i, j, ret;
2642 struct ctdb_public_ip ip;
2643 struct ctdb_public_ipv4 ipv4;
2644 uint32_t *nodes;
2645 struct ctdb_public_ip_list *all_ips, *tmp_ip;
2646 TDB_DATA data;
2647 struct timeval timeout;
2648 struct client_async_data *async_data;
2649 struct ctdb_client_control_state *state;
2650 TALLOC_CTX *tmp_ctx = talloc_new(ctdb);
2651 struct ctdb_ipflags *ipflags;
2652 struct takeover_callback_data *takeover_data;
2653 struct iprealloc_callback_data iprealloc_data;
2654 bool *retry_data;
2655
2656 /*
2657 * ip failover is completely disabled, just send out the
2658 * ipreallocated event.
2659 */
2660 if (ctdb->tunable.disable_ip_failover != 0) {
2661 goto ipreallocated;
2662 }
2663
2664 ipflags = set_ipflags(ctdb, tmp_ctx, nodemap);
2665 if (ipflags == NULL) {
2666 DEBUG(DEBUG_ERR,("Failed to set IP flags - aborting takeover run\n"));
2667 talloc_free(tmp_ctx);
2668 return -1;
2669 }
2670
2671 ZERO_STRUCT(ip);
2672
2673 /* Do the IP reassignment calculations */
2674 ctdb_takeover_run_core(ctdb, ipflags, &all_ips, force_rebalance_nodes);
2675
2676 /* Now tell all nodes to release any public IPs should not
2677 * host. This will be a NOOP on nodes that don't currently
2678 * hold the given IP.
2679 */
2680 takeover_data = talloc_zero(tmp_ctx, struct takeover_callback_data);
2681 CTDB_NO_MEMORY_FATAL(ctdb, takeover_data);
2682
2683 takeover_data->node_failed = talloc_zero_array(tmp_ctx,
2684 bool, nodemap->num);
2685 CTDB_NO_MEMORY_FATAL(ctdb, takeover_data->node_failed);
2686 takeover_data->fail_callback = fail_callback;
2687 takeover_data->fail_callback_data = callback_data;
2688 takeover_data->nodemap = nodemap;
2689
2690 async_data = talloc_zero(tmp_ctx, struct client_async_data);
2691 CTDB_NO_MEMORY_FATAL(ctdb, async_data);
2692
2693 async_data->fail_callback = takeover_run_fail_callback;
2694 async_data->callback_data = takeover_data;
2695
2696 for (i=0;i<nodemap->num;i++) {
2697 /* don't talk to unconnected nodes, but do talk to banned nodes */
2698 if (nodemap->nodes[i].flags & NODE_FLAGS_DISCONNECTED) {
2699 continue;
2700 }
2701
2702 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
2703 if (tmp_ip->pnn == nodemap->nodes[i].pnn) {
2704 /* This node should be serving this
2705 vnn so dont tell it to release the ip
2706 */
2707 continue;
2708 }
2709 if (tmp_ip->addr.sa.sa_family == AF_INET) {
2710 ipv4.pnn = tmp_ip->pnn;
2711 ipv4.sin = tmp_ip->addr.ip;
2712
2713 timeout = TAKEOVER_TIMEOUT();
2714 data.dsize = sizeof(ipv4);
2715 data.dptr = (uint8_t *)&ipv4;
2716 state = ctdb_control_send(ctdb, nodemap->nodes[i].pnn,
2717 0, CTDB_CONTROL_RELEASE_IPv4, 0,
2718 data, async_data,
2719 &timeout, NULL);
2720 } else {
2721 ip.pnn = tmp_ip->pnn;
2722 ip.addr = tmp_ip->addr;
2723
2724 timeout = TAKEOVER_TIMEOUT();
2725 data.dsize = sizeof(ip);
2726 data.dptr = (uint8_t *)&ip;
2727 state = ctdb_control_send(ctdb, nodemap->nodes[i].pnn,
2728 0, CTDB_CONTROL_RELEASE_IP, 0,
2729 data, async_data,
2730 &timeout, NULL);
2731 }
2732
2733 if (state == NULL) {
2734 DEBUG(DEBUG_ERR,(__location__ " Failed to call async control CTDB_CONTROL_RELEASE_IP to node %u\n", nodemap->nodes[i].pnn));
2735 talloc_free(tmp_ctx);
2736 return -1;
2737 }
2738
2739 ctdb_client_async_add(async_data, state);
2740 }
2741 }
2742 if (ctdb_client_async_wait(ctdb, async_data) != 0) {
2743 DEBUG(DEBUG_ERR,(__location__ " Async control CTDB_CONTROL_RELEASE_IP failed\n"));
2744 talloc_free(tmp_ctx);
2745 return -1;
2746 }
2747 talloc_free(async_data);
2748
2749
2750 /* tell all nodes to get their own IPs */
2751 async_data = talloc_zero(tmp_ctx, struct client_async_data);
2752 CTDB_NO_MEMORY_FATAL(ctdb, async_data);
2753
2754 async_data->fail_callback = fail_callback;
2755 async_data->callback_data = callback_data;
2756
2757 for (tmp_ip=all_ips;tmp_ip;tmp_ip=tmp_ip->next) {
2758 if (tmp_ip->pnn == -1) {
2759 /* this IP won't be taken over */
2760 continue;
2761 }
2762
2763 if (tmp_ip->addr.sa.sa_family == AF_INET) {
2764 ipv4.pnn = tmp_ip->pnn;
2765 ipv4.sin = tmp_ip->addr.ip;
2766
2767 timeout = TAKEOVER_TIMEOUT();
2768 data.dsize = sizeof(ipv4);
2769 data.dptr = (uint8_t *)&ipv4;
2770 state = ctdb_control_send(ctdb, tmp_ip->pnn,
2771 0, CTDB_CONTROL_TAKEOVER_IPv4, 0,
2772 data, async_data,
2773 &timeout, NULL);
2774 } else {
2775 ip.pnn = tmp_ip->pnn;
2776 ip.addr = tmp_ip->addr;
2777
2778 timeout = TAKEOVER_TIMEOUT();
2779 data.dsize = sizeof(ip);
2780 data.dptr = (uint8_t *)&ip;
2781 state = ctdb_control_send(ctdb, tmp_ip->pnn,
2782 0, CTDB_CONTROL_TAKEOVER_IP, 0,
2783 data, async_data,
2784 &timeout, NULL);
2785 }
2786 if (state == NULL) {
2787 DEBUG(DEBUG_ERR,(__location__ " Failed to call async control CTDB_CONTROL_TAKEOVER_IP to node %u\n", tmp_ip->pnn));
2788 talloc_free(tmp_ctx);
2789 return -1;
2790 }
2791
2792 ctdb_client_async_add(async_data, state);
2793 }
2794 if (ctdb_client_async_wait(ctdb, async_data) != 0) {
2795 DEBUG(DEBUG_ERR,(__location__ " Async control CTDB_CONTROL_TAKEOVER_IP failed\n"));
2796 talloc_free(tmp_ctx);
2797 return -1;
2798 }
2799
2800 ipreallocated:
2801 /*
2802 * Tell all nodes to run eventscripts to process the
2803 * "ipreallocated" event. This can do a lot of things,
2804 * including restarting services to reconfigure them if public
2805 * IPs have moved. Once upon a time this event only used to
2806 * update natwg.
2807 */
2808 retry_data = talloc_zero_array(tmp_ctx, bool, nodemap->num);
2809 CTDB_NO_MEMORY_FATAL(ctdb, retry_data);
2810 iprealloc_data.retry_nodes = retry_data;
2811 iprealloc_data.retry_count = 0;
2812 iprealloc_data.fail_callback = fail_callback;
2813 iprealloc_data.fail_callback_data = callback_data;
2814 iprealloc_data.nodemap = nodemap;
2815
2816 nodes = list_of_connected_nodes(ctdb, nodemap, tmp_ctx, true);
2817 ret = ctdb_client_async_control(ctdb, CTDB_CONTROL_IPREALLOCATED,
2818 nodes, 0, TAKEOVER_TIMEOUT(),
2819 false, tdb_null,
2820 NULL, iprealloc_fail_callback,
2821 &iprealloc_data);
2822 if (ret != 0) {
2823 /* If the control failed then we should retry to any
2824 * nodes flagged by iprealloc_fail_callback using the
2825 * EVENTSCRIPT control. This is a best-effort at
2826 * backward compatiblity when running a mixed cluster
2827 * where some nodes have not yet been upgraded to
2828 * support the IPREALLOCATED control.
2829 */
2830 DEBUG(DEBUG_WARNING,
2831 ("Retry ipreallocated to some nodes using eventscript control\n"));
2832
2833 nodes = talloc_array(tmp_ctx, uint32_t,
2834 iprealloc_data.retry_count);
2835 CTDB_NO_MEMORY_FATAL(ctdb, nodes);
2836
2837 j = 0;
2838 for (i=0; i<nodemap->num; i++) {
2839 if (iprealloc_data.retry_nodes[i]) {
2840 nodes[j] = i;
2841 j++;
2842 }
2843 }
2844
2845 data.dptr = discard_const("ipreallocated");
2846 data.dsize = strlen((char *)data.dptr) + 1;
2847 ret = ctdb_client_async_control(ctdb,
2848 CTDB_CONTROL_RUN_EVENTSCRIPTS,
2849 nodes, 0, TAKEOVER_TIMEOUT(),
2850 false, data,
2851 NULL, fail_callback,
2852 callback_data);
2853 if (ret != 0) {
2854 DEBUG(DEBUG_ERR, (__location__ " failed to send control to run eventscripts with \"ipreallocated\"\n"));
2855 }
2856 }
2857
2858 talloc_free(tmp_ctx);
2859 return ret;
2860 }
2861
2862
2863 /*
2864 destroy a ctdb_client_ip structure
2865 */
2866 static int ctdb_client_ip_destructor(struct ctdb_client_ip *ip)
2867 {
2868 DEBUG(DEBUG_DEBUG,("destroying client tcp for %s:%u (client_id %u)\n",
2869 ctdb_addr_to_str(&ip->addr),
2870 ntohs(ip->addr.ip.sin_port),
2871 ip->client_id));
2872
2873 DLIST_REMOVE(ip->ctdb->client_ip_list, ip);
2874 return 0;
2875 }
2876
2877 /*
2878 called by a client to inform us of a TCP connection that it is managing
2879 that should tickled with an ACK when IP takeover is done
2880 we handle both the old ipv4 style of packets as well as the new ipv4/6
2881 pdus.
2882 */
2883 int32_t ctdb_control_tcp_client(struct ctdb_context *ctdb, uint32_t client_id,
2884 TDB_DATA indata)
2885 {
2886 struct ctdb_client *client = ctdb_reqid_find(ctdb, client_id, struct ctdb_client);
2887 struct ctdb_control_tcp *old_addr = NULL;
2888 struct ctdb_control_tcp_addr new_addr;
2889 struct ctdb_control_tcp_addr *tcp_sock = NULL;
2890 struct ctdb_tcp_list *tcp;
2891 struct ctdb_tcp_connection t;
2892 int ret;
2893 TDB_DATA data;
2894 struct ctdb_client_ip *ip;
2895 struct ctdb_vnn *vnn;
2896 ctdb_sock_addr addr;
2897
2898 switch (indata.dsize) {
2899 case sizeof(struct ctdb_control_tcp):
2900 old_addr = (struct ctdb_control_tcp *)indata.dptr;
2901 ZERO_STRUCT(new_addr);
2902 tcp_sock = &new_addr;
2903 tcp_sock->src.ip = old_addr->src;
2904 tcp_sock->dest.ip = old_addr->dest;
2905 break;
2906 case sizeof(struct ctdb_control_tcp_addr):
2907 tcp_sock = (struct ctdb_control_tcp_addr *)indata.dptr;
2908 break;
2909 default:
2910 DEBUG(DEBUG_ERR,(__location__ " Invalid data structure passed "
2911 "to ctdb_control_tcp_client. size was %d but "
2912 "only allowed sizes are %lu and %lu\n",
2913 (int)indata.dsize,
2914 (long unsigned)sizeof(struct ctdb_control_tcp),
2915 (long unsigned)sizeof(struct ctdb_control_tcp_addr)));
2916 return -1;
2917 }
2918
2919 addr = tcp_sock->src;
2920 ctdb_canonicalize_ip(&addr, &tcp_sock->src);
2921 addr = tcp_sock->dest;
2922 ctdb_canonicalize_ip(&addr, &tcp_sock->dest);
2923
2924 ZERO_STRUCT(addr);
2925 memcpy(&addr, &tcp_sock->dest, sizeof(addr));
2926 vnn = find_public_ip_vnn(ctdb, &addr);
2927 if (vnn == NULL) {
2928 switch (addr.sa.sa_family) {
2929 case AF_INET:
2930 if (ntohl(addr.ip.sin_addr.s_addr) != INADDR_LOOPBACK) {
2931 DEBUG(DEBUG_ERR,("Could not add client IP %s. This is not a public address.\n",
2932 ctdb_addr_to_str(&addr)));
2933 }
2934 break;
2935 case AF_INET6:
2936 DEBUG(DEBUG_ERR,("Could not add client IP %s. This is not a public ipv6 address.\n",
2937 ctdb_addr_to_str(&addr)));
2938 break;
2939 default:
2940 DEBUG(DEBUG_ERR,(__location__ " Unknown family type %d\n", addr.sa.sa_family));
2941 }
2942
2943 return 0;
2944 }
2945
2946 if (vnn->pnn != ctdb->pnn) {
2947 DEBUG(DEBUG_ERR,("Attempt to register tcp client for IP %s we don't hold - failing (client_id %u pid %u)\n",
2948 ctdb_addr_to_str(&addr),
2949 client_id, client->pid));
2950 /* failing this call will tell smbd to die */
2951 return -1;
2952 }
2953
2954 ip = talloc(client, struct ctdb_client_ip);
2955 CTDB_NO_MEMORY(ctdb, ip);
2956
2957 ip->ctdb = ctdb;
2958 ip->addr = addr;
2959 ip->client_id = client_id;
2960 talloc_set_destructor(ip, ctdb_client_ip_destructor);
2961 DLIST_ADD(ctdb->client_ip_list, ip);
2962
2963 tcp = talloc(client, struct ctdb_tcp_list);
2964 CTDB_NO_MEMORY(ctdb, tcp);
2965
2966 tcp->connection.src_addr = tcp_sock->src;
2967 tcp->connection.dst_addr = tcp_sock->dest;
2968
2969 DLIST_ADD(client->tcp_list, tcp);
2970
2971 t.src_addr = tcp_sock->src;
2972 t.dst_addr = tcp_sock->dest;
2973
2974 data.dptr = (uint8_t *)&t;
2975 data.dsize = sizeof(t);
2976
2977 switch (addr.sa.sa_family) {
2978 case AF_INET:
2979 DEBUG(DEBUG_INFO,("registered tcp client for %u->%s:%u (client_id %u pid %u)\n",
2980 (unsigned)ntohs(tcp_sock->dest.ip.sin_port),
2981 ctdb_addr_to_str(&tcp_sock->src),
2982 (unsigned)ntohs(tcp_sock->src.ip.sin_port), client_id, client->pid));
2983 break;
2984 case AF_INET6:
2985 DEBUG(DEBUG_INFO,("registered tcp client for %u->%s:%u (client_id %u pid %u)\n",
2986 (unsigned)ntohs(tcp_sock->dest.ip6.sin6_port),
2987 ctdb_addr_to_str(&tcp_sock->src),
2988 (unsigned)ntohs(tcp_sock->src.ip6.sin6_port), client_id, client->pid));
2989 break;
2990 default:
2991 DEBUG(DEBUG_ERR,(__location__ " Unknown family %d\n", addr.sa.sa_family));
2992 }
2993
2994
2995 /* tell all nodes about this tcp connection */
2996 ret = ctdb_daemon_send_control(ctdb, CTDB_BROADCAST_CONNECTED, 0,
2997 CTDB_CONTROL_TCP_ADD,
2998 0, CTDB_CTRL_FLAG_NOREPLY, data, NULL, NULL);
2999 if (ret != 0) {
3000 DEBUG(DEBUG_ERR,(__location__ " Failed to send CTDB_CONTROL_TCP_ADD\n"));
3001 return -1;
3002 }
3003
3004 return 0;
3005 }
3006
3007 /*
3008 find a tcp address on a list
3009 */
3010 static struct ctdb_tcp_connection *ctdb_tcp_find(struct ctdb_tcp_array *array,
3011 struct ctdb_tcp_connection *tcp)
3012 {
3013 int i;
3014
3015 if (array == NULL) {
3016 return NULL;
3017 }
3018
3019 for (i=0;i<array->num;i++) {
3020 if (ctdb_same_sockaddr(&array->connections[i].src_addr, &tcp->src_addr) &&
3021 ctdb_same_sockaddr(&array->connections[i].dst_addr, &tcp->dst_addr)) {
3022 return &array->connections[i];
3023 }
3024 }
3025 return NULL;
3026 }
3027
3028
3029
3030 /*
3031 called by a daemon to inform us of a TCP connection that one of its
3032 clients managing that should tickled with an ACK when IP takeover is
3033 done
3034 */
3035 int32_t ctdb_control_tcp_add(struct ctdb_context *ctdb, TDB_DATA indata, bool tcp_update_needed)
3036 {
3037 struct ctdb_tcp_connection *p = (struct ctdb_tcp_connection *)indata.dptr;
3038 struct ctdb_tcp_array *tcparray;
3039 struct ctdb_tcp_connection tcp;
3040 struct ctdb_vnn *vnn;
3041
3042 vnn = find_public_ip_vnn(ctdb, &p->dst_addr);
3043 if (vnn == NULL) {
3044 DEBUG(DEBUG_INFO,(__location__ " got TCP_ADD control for an address which is not a public address '%s'\n",
3045 ctdb_addr_to_str(&p->dst_addr)));
3046
3047 return -1;
3048 }
3049
3050
3051 tcparray = vnn->tcp_array;
3052
3053 /* If this is the first tickle */
3054 if (tcparray == NULL) {
3055 tcparray = talloc_size(ctdb->nodes,
3056 offsetof(struct ctdb_tcp_array, connections) +
3057 sizeof(struct ctdb_tcp_connection) * 1);
3058 CTDB_NO_MEMORY(ctdb, tcparray);
3059 vnn->tcp_array = tcparray;
3060
3061 tcparray->num = 0;
3062 tcparray->connections = talloc_size(tcparray, sizeof(struct ctdb_tcp_connection));
3063 CTDB_NO_MEMORY(ctdb, tcparray->connections);
3064
3065 tcparray->connections[tcparray->num].src_addr = p->src_addr;
3066 tcparray->connections[tcparray->num].dst_addr = p->dst_addr;
3067 tcparray->num++;
3068
3069 if (tcp_update_needed) {
3070 vnn->tcp_update_needed = true;
3071 }
3072 return 0;
3073 }
3074
3075
3076 /* Do we already have this tickle ?*/
3077 tcp.src_addr = p->src_addr;
3078 tcp.dst_addr = p->dst_addr;
3079 if (ctdb_tcp_find(vnn->tcp_array, &tcp) != NULL) {
3080 DEBUG(DEBUG_DEBUG,("Already had tickle info for %s:%u for vnn:%u\n",
3081 ctdb_addr_to_str(&tcp.dst_addr),
3082 ntohs(tcp.dst_addr.ip.sin_port),
3083 vnn->pnn));
3084 return 0;
3085 }
3086
3087 /* A new tickle, we must add it to the array */
3088 tcparray->connections = talloc_realloc(tcparray, tcparray->connections,
3089 struct ctdb_tcp_connection,
3090 tcparray->num+1);
3091 CTDB_NO_MEMORY(ctdb, tcparray->connections);
3092
3093 vnn->tcp_array = tcparray;
3094 tcparray->connections[tcparray->num].src_addr = p->src_addr;
3095 tcparray->connections[tcparray->num].dst_addr = p->dst_addr;
3096 tcparray->num++;
3097
3098 DEBUG(DEBUG_INFO,("Added tickle info for %s:%u from vnn %u\n",
3099 ctdb_addr_to_str(&tcp.dst_addr),
3100 ntohs(tcp.dst_addr.ip.sin_port),
3101 vnn->pnn));
3102
3103 if (tcp_update_needed) {
3104 vnn->tcp_update_needed = true;
3105 }
3106
3107 return 0;
3108 }
3109
3110
3111 /*
3112 called by a daemon to inform us of a TCP connection that one of its
3113 clients managing that should tickled with an ACK when IP takeover is
3114 done
3115 */
3116 static void ctdb_remove_tcp_connection(struct ctdb_context *ctdb, struct ctdb_tcp_connection *conn)
3117 {
3118 struct ctdb_tcp_connection *tcpp;
3119 struct ctdb_vnn *vnn = find_public_ip_vnn(ctdb, &conn->dst_addr);
3120
3121 if (vnn == NULL) {
3122 DEBUG(DEBUG_ERR,(__location__ " unable to find public address %s\n",
3123 ctdb_addr_to_str(&conn->dst_addr)));
3124 return;
3125 }
3126
3127 /* if the array is empty we cant remove it
3128 and we dont need to do anything
3129 */
3130 if (vnn->tcp_array == NULL) {
3131 DEBUG(DEBUG_INFO,("Trying to remove tickle that doesnt exist (array is empty) %s:%u\n",
3132 ctdb_addr_to_str(&conn->dst_addr),
3133 ntohs(conn->dst_addr.ip.sin_port)));
3134 return;
3135 }
3136
3137
3138 /* See if we know this connection
3139 if we dont know this connection then we dont need to do anything
3140 */
3141 tcpp = ctdb_tcp_find(vnn->tcp_array, conn);
3142 if (tcpp == NULL) {
3143 DEBUG(DEBUG_INFO,("Trying to remove tickle that doesnt exist %s:%u\n",
3144 ctdb_addr_to_str(&conn->dst_addr),
3145 ntohs(conn->dst_addr.ip.sin_port)));
3146 return;
3147 }
3148
3149
3150 /* We need to remove this entry from the array.
3151 Instead of allocating a new array and copying data to it
3152 we cheat and just copy the last entry in the existing array
3153 to the entry that is to be removed and just shring the
3154 ->num field
3155 */
3156 *tcpp = vnn->tcp_array->connections[vnn->tcp_array->num - 1];
3157 vnn->tcp_array->num--;
3158
3159 /* If we deleted the last entry we also need to remove the entire array
3160 */
3161 if (vnn->tcp_array->num == 0) {
3162 talloc_free(vnn->tcp_array);
3163 vnn->tcp_array = NULL;
3164 }
3165
3166 vnn->tcp_update_needed = true;
3167
3168 DEBUG(DEBUG_INFO,("Removed tickle info for %s:%u\n",
3169 ctdb_addr_to_str(&conn->src_addr),
3170 ntohs(conn->src_addr.ip.sin_port)));
3171 }
3172
3173
3174 /*
3175 called by a daemon to inform us of a TCP connection that one of its
3176 clients used are no longer needed in the tickle database
3177 */
3178 int32_t ctdb_control_tcp_remove(struct ctdb_context *ctdb, TDB_DATA indata)
3179 {
3180 struct ctdb_tcp_connection *conn = (struct ctdb_tcp_connection *)indata.dptr;
3181
3182 ctdb_remove_tcp_connection(ctdb, conn);
3183
3184 return 0;
3185 }
3186
3187
3188 /*
3189 called when a daemon restarts - send all tickes for all public addresses
3190 we are serving immediately to the new node.
3191 */
3192 int32_t ctdb_control_startup(struct ctdb_context *ctdb, uint32_t vnn)
3193 {
3194 /*XXX here we should send all tickes we are serving to the new node */
3195 return 0;
3196 }
3197
3198
3199 /*
3200 called when a client structure goes away - hook to remove
3201 elements from the tcp_list in all daemons
3202 */
3203 void ctdb_takeover_client_destructor_hook(struct ctdb_client *client)
3204 {
3205 while (client->tcp_list) {
3206 struct ctdb_tcp_list *tcp = client->tcp_list;
3207 DLIST_REMOVE(client->tcp_list, tcp);
3208 ctdb_remove_tcp_connection(client->ctdb, &tcp->connection);
3209 }
3210 }
3211
3212
3213 /*
3214 release all IPs on shutdown
3215 */
3216 void ctdb_release_all_ips(struct ctdb_context *ctdb)
3217 {
3218 struct ctdb_vnn *vnn;
3219 int count = 0;
3220
3221 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3222 if (!ctdb_sys_have_ip(&vnn->public_address)) {
3223 ctdb_vnn_unassign_iface(ctdb, vnn);
3224 continue;
3225 }
3226 if (!vnn->iface) {
3227 continue;
3228 }
3229
3230 DEBUG(DEBUG_INFO,("Release of IP %s/%u on interface %s node:-1\n",
3231 ctdb_addr_to_str(&vnn->public_address),
3232 vnn->public_netmask_bits,
3233 ctdb_vnn_iface_string(vnn)));
3234
3235 ctdb_event_script_args(ctdb, CTDB_EVENT_RELEASE_IP, "%s %s %u",
3236 ctdb_vnn_iface_string(vnn),
3237 ctdb_addr_to_str(&vnn->public_address),
3238 vnn->public_netmask_bits);
3239 release_kill_clients(ctdb, &vnn->public_address);
3240 ctdb_vnn_unassign_iface(ctdb, vnn);
3241 count++;
3242 }
3243
3244 DEBUG(DEBUG_NOTICE,(__location__ " Released %d public IPs\n", count));
3245 }
3246
3247
3248 /*
3249 get list of public IPs
3250 */
3251 int32_t ctdb_control_get_public_ips(struct ctdb_context *ctdb,
3252 struct ctdb_req_control *c, TDB_DATA *outdata)
3253 {
3254 int i, num, len;
3255 struct ctdb_all_public_ips *ips;
3256 struct ctdb_vnn *vnn;
3257 bool only_available = false;
3258
3259 if (c->flags & CTDB_PUBLIC_IP_FLAGS_ONLY_AVAILABLE) {
3260 only_available = true;
3261 }
3262
3263 /* count how many public ip structures we have */
3264 num = 0;
3265 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3266 num++;
3267 }
3268
3269 len = offsetof(struct ctdb_all_public_ips, ips) +
3270 num*sizeof(struct ctdb_public_ip);
3271 ips = talloc_zero_size(outdata, len);
3272 CTDB_NO_MEMORY(ctdb, ips);
3273
3274 i = 0;
3275 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3276 if (only_available && !ctdb_vnn_available(ctdb, vnn)) {
3277 continue;
3278 }
3279 ips->ips[i].pnn = vnn->pnn;
3280 ips->ips[i].addr = vnn->public_address;
3281 i++;
3282 }
3283 ips->num = i;
3284 len = offsetof(struct ctdb_all_public_ips, ips) +
3285 i*sizeof(struct ctdb_public_ip);
3286
3287 outdata->dsize = len;
3288 outdata->dptr = (uint8_t *)ips;
3289
3290 return 0;
3291 }
3292
3293
3294 /*
3295 get list of public IPs, old ipv4 style. only returns ipv4 addresses
3296 */
3297 int32_t ctdb_control_get_public_ipsv4(struct ctdb_context *ctdb,
3298 struct ctdb_req_control *c, TDB_DATA *outdata)
3299 {
3300 int i, num, len;
3301 struct ctdb_all_public_ipsv4 *ips;
3302 struct ctdb_vnn *vnn;
3303
3304 /* count how many public ip structures we have */
3305 num = 0;
3306 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3307 if (vnn->public_address.sa.sa_family != AF_INET) {
3308 continue;
3309 }
3310 num++;
3311 }
3312
3313 len = offsetof(struct ctdb_all_public_ipsv4, ips) +
3314 num*sizeof(struct ctdb_public_ipv4);
3315 ips = talloc_zero_size(outdata, len);
3316 CTDB_NO_MEMORY(ctdb, ips);
3317
3318 outdata->dsize = len;
3319 outdata->dptr = (uint8_t *)ips;
3320
3321 ips->num = num;
3322 i = 0;
3323 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3324 if (vnn->public_address.sa.sa_family != AF_INET) {
3325 continue;
3326 }
3327 ips->ips[i].pnn = vnn->pnn;
3328 ips->ips[i].sin = vnn->public_address.ip;
3329 i++;
3330 }
3331
3332 return 0;
3333 }
3334
3335 int32_t ctdb_control_get_public_ip_info(struct ctdb_context *ctdb,
3336 struct ctdb_req_control *c,
3337 TDB_DATA indata,
3338 TDB_DATA *outdata)
3339 {
3340 int i, num, len;
3341 ctdb_sock_addr *addr;
3342 struct ctdb_control_public_ip_info *info;
3343 struct ctdb_vnn *vnn;
3344
3345 addr = (ctdb_sock_addr *)indata.dptr;
3346
3347 vnn = find_public_ip_vnn(ctdb, addr);
3348 if (vnn == NULL) {
3349 /* if it is not a public ip it could be our 'single ip' */
3350 if (ctdb->single_ip_vnn) {
3351 if (ctdb_same_ip(&ctdb->single_ip_vnn->public_address, addr)) {
3352 vnn = ctdb->single_ip_vnn;
3353 }
3354 }
3355 }
3356 if (vnn == NULL) {
3357 DEBUG(DEBUG_ERR,(__location__ " Could not get public ip info, "
3358 "'%s'not a public address\n",
3359 ctdb_addr_to_str(addr)));
3360 return -1;
3361 }
3362
3363 /* count how many public ip structures we have */
3364 num = 0;
3365 for (;vnn->ifaces[num];) {
3366 num++;
3367 }
3368
3369 len = offsetof(struct ctdb_control_public_ip_info, ifaces) +
3370 num*sizeof(struct ctdb_control_iface_info);
3371 info = talloc_zero_size(outdata, len);
3372 CTDB_NO_MEMORY(ctdb, info);
3373
3374 info->ip.addr = vnn->public_address;
3375 info->ip.pnn = vnn->pnn;
3376 info->active_idx = 0xFFFFFFFF;
3377
3378 for (i=0; vnn->ifaces[i]; i++) {
3379 struct ctdb_iface *cur;
3380
3381 cur = ctdb_find_iface(ctdb, vnn->ifaces[i]);
3382 if (cur == NULL) {
3383 DEBUG(DEBUG_CRIT, (__location__ " internal error iface[%s] unknown\n",
3384 vnn->ifaces[i]));
3385 return -1;
3386 }
3387 if (vnn->iface == cur) {
3388 info->active_idx = i;
3389 }
3390 strncpy(info->ifaces[i].name, cur->name, sizeof(info->ifaces[i].name)-1);
3391 info->ifaces[i].link_state = cur->link_up;
3392 info->ifaces[i].references = cur->references;
3393 }
3394 info->num = i;
3395 len = offsetof(struct ctdb_control_public_ip_info, ifaces) +
3396 i*sizeof(struct ctdb_control_iface_info);
3397
3398 outdata->dsize = len;
3399 outdata->dptr = (uint8_t *)info;
3400
3401 return 0;
3402 }
3403
3404 int32_t ctdb_control_get_ifaces(struct ctdb_context *ctdb,
3405 struct ctdb_req_control *c,
3406 TDB_DATA *outdata)
3407 {
3408 int i, num, len;
3409 struct ctdb_control_get_ifaces *ifaces;
3410 struct ctdb_iface *cur;
3411
3412 /* count how many public ip structures we have */
3413 num = 0;
3414 for (cur=ctdb->ifaces;cur;cur=cur->next) {
3415 num++;
3416 }
3417
3418 len = offsetof(struct ctdb_control_get_ifaces, ifaces) +
3419 num*sizeof(struct ctdb_control_iface_info);
3420 ifaces = talloc_zero_size(outdata, len);
3421 CTDB_NO_MEMORY(ctdb, ifaces);
3422
3423 i = 0;
3424 for (cur=ctdb->ifaces;cur;cur=cur->next) {
3425 strcpy(ifaces->ifaces[i].name, cur->name);
3426 ifaces->ifaces[i].link_state = cur->link_up;
3427 ifaces->ifaces[i].references = cur->references;
3428 i++;
3429 }
3430 ifaces->num = i;
3431 len = offsetof(struct ctdb_control_get_ifaces, ifaces) +
3432 i*sizeof(struct ctdb_control_iface_info);
3433
3434 outdata->dsize = len;
3435 outdata->dptr = (uint8_t *)ifaces;
3436
3437 return 0;
3438 }
3439
3440 int32_t ctdb_control_set_iface_link(struct ctdb_context *ctdb,
3441 struct ctdb_req_control *c,
3442 TDB_DATA indata)
3443 {
3444 struct ctdb_control_iface_info *info;
3445 struct ctdb_iface *iface;
3446 bool link_up = false;
3447
3448 info = (struct ctdb_control_iface_info *)indata.dptr;
3449
3450 if (info->name[CTDB_IFACE_SIZE] != '\0') {
3451 int len = strnlen(info->name, CTDB_IFACE_SIZE);
3452 DEBUG(DEBUG_ERR, (__location__ " name[%*.*s] not terminated\n",
3453 len, len, info->name));
3454 return -1;
3455 }
3456
3457 switch (info->link_state) {
3458 case 0:
3459 link_up = false;
3460 break;
3461 case 1:
3462 link_up = true;
3463 break;
3464 default:
3465 DEBUG(DEBUG_ERR, (__location__ " link_state[%u] invalid\n",
3466 (unsigned int)info->link_state));
3467 return -1;
3468 }
3469
3470 if (info->references != 0) {
3471 DEBUG(DEBUG_ERR, (__location__ " references[%u] should be 0\n",
3472 (unsigned int)info->references));
3473 return -1;
3474 }
3475
3476 iface = ctdb_find_iface(ctdb, info->name);
3477 if (iface == NULL) {
3478 return -1;
3479 }
3480
3481 if (link_up == iface->link_up) {
3482 return 0;
3483 }
3484
3485 DEBUG(iface->link_up?DEBUG_ERR:DEBUG_NOTICE,
3486 ("iface[%s] has changed it's link status %s => %s\n",
3487 iface->name,
3488 iface->link_up?"up":"down",
3489 link_up?"up":"down"));
3490
3491 iface->link_up = link_up;
3492 return 0;
3493 }
3494
3495
3496 /*
3497 structure containing the listening socket and the list of tcp connections
3498 that the ctdb daemon is to kill
3499 */
3500 struct ctdb_kill_tcp {
3501 struct ctdb_vnn *vnn;
3502 struct ctdb_context *ctdb;
3503 int capture_fd;
3504 struct fd_event *fde;
3505 trbt_tree_t *connections;
3506 void *private_data;
3507 };
3508
3509 /*
3510 a tcp connection that is to be killed
3511 */
3512 struct ctdb_killtcp_con {
3513 ctdb_sock_addr src_addr;
3514 ctdb_sock_addr dst_addr;
3515 int count;
3516 struct ctdb_kill_tcp *killtcp;
3517 };
3518
3519 /* this function is used to create a key to represent this socketpair
3520 in the killtcp tree.
3521 this key is used to insert and lookup matching socketpairs that are
3522 to be tickled and RST
3523 */
3524 #define KILLTCP_KEYLEN 10
3525 static uint32_t *killtcp_key(ctdb_sock_addr *src, ctdb_sock_addr *dst)
3526 {
3527 static uint32_t key[KILLTCP_KEYLEN];
3528
3529 bzero(key, sizeof(key));
3530
3531 if (src->sa.sa_family != dst->sa.sa_family) {
3532 DEBUG(DEBUG_ERR, (__location__ " ERROR, different families passed :%u vs %u\n", src->sa.sa_family, dst->sa.sa_family));
3533 return key;
3534 }
3535
3536 switch (src->sa.sa_family) {
3537 case AF_INET:
3538 key[0] = dst->ip.sin_addr.s_addr;
3539 key[1] = src->ip.sin_addr.s_addr;
3540 key[2] = dst->ip.sin_port;
3541 key[3] = src->ip.sin_port;
3542 break;
3543 case AF_INET6: {
3544 uint32_t *dst6_addr32 =
3545 (uint32_t *)&(dst->ip6.sin6_addr.s6_addr);
3546 uint32_t *src6_addr32 =
3547 (uint32_t *)&(src->ip6.sin6_addr.s6_addr);
3548 key[0] = dst6_addr32[3];
3549 key[1] = src6_addr32[3];
3550 key[2] = dst6_addr32[2];
3551 key[3] = src6_addr32[2];
3552 key[4] = dst6_addr32[1];
3553 key[5] = src6_addr32[1];
3554 key[6] = dst6_addr32[0];
3555 key[7] = src6_addr32[0];
3556 key[8] = dst->ip6.sin6_port;
3557 key[9] = src->ip6.sin6_port;
3558 break;
3559 }
3560 default:
3561 DEBUG(DEBUG_ERR, (__location__ " ERROR, unknown family passed :%u\n", src->sa.sa_family));
3562 return key;
3563 }
3564
3565 return key;
3566 }
3567
3568 /*
3569 called when we get a read event on the raw socket
3570 */
3571 static void capture_tcp_handler(struct event_context *ev, struct fd_event *fde,
3572 uint16_t flags, void *private_data)
3573 {
3574 struct ctdb_kill_tcp *killtcp = talloc_get_type(private_data, struct ctdb_kill_tcp);
3575 struct ctdb_killtcp_con *con;
3576 ctdb_sock_addr src, dst;
3577 uint32_t ack_seq, seq;
3578
3579 if (!(flags & EVENT_FD_READ)) {
3580 return;
3581 }
3582
3583 if (ctdb_sys_read_tcp_packet(killtcp->capture_fd,
3584 killtcp->private_data,
3585 &src, &dst,
3586 &ack_seq, &seq) != 0) {
3587 /* probably a non-tcp ACK packet */
3588 return;
3589 }
3590
3591 /* check if we have this guy in our list of connections
3592 to kill
3593 */
3594 con = trbt_lookuparray32(killtcp->connections,
3595 KILLTCP_KEYLEN, killtcp_key(&src, &dst));
3596 if (con == NULL) {
3597 /* no this was some other packet we can just ignore */
3598 return;
3599 }
3600
3601 /* This one has been tickled !
3602 now reset him and remove him from the list.
3603 */
3604 DEBUG(DEBUG_INFO, ("sending a tcp reset to kill connection :%d -> %s:%d\n",
3605 ntohs(con->dst_addr.ip.sin_port),
3606 ctdb_addr_to_str(&con->src_addr),
3607 ntohs(con->src_addr.ip.sin_port)));
3608
3609 ctdb_sys_send_tcp(&con->dst_addr, &con->src_addr, ack_seq, seq, 1);
3610 talloc_free(con);
3611 }
3612
3613
3614 /* when traversing the list of all tcp connections to send tickle acks to
3615 (so that we can capture the ack coming back and kill the connection
3616 by a RST)
3617 this callback is called for each connection we are currently trying to kill
3618 */
3619 static int tickle_connection_traverse(void *param, void *data)
3620 {
3621 struct ctdb_killtcp_con *con = talloc_get_type(data, struct ctdb_killtcp_con);
3622
3623 /* have tried too many times, just give up */
3624 if (con->count >= 5) {
3625 /* can't delete in traverse: reparent to delete_cons */
3626 talloc_steal(param, con);
3627 return 0;
3628 }
3629
3630 /* othervise, try tickling it again */
3631 con->count++;
3632 ctdb_sys_send_tcp(
3633 (ctdb_sock_addr *)&con->dst_addr,
3634 (ctdb_sock_addr *)&con->src_addr,
3635 0, 0, 0);
3636 return 0;
3637 }
3638
3639
3640 /*
3641 called every second until all sentenced connections have been reset
3642 */
3643 static void ctdb_tickle_sentenced_connections(struct event_context *ev, struct timed_event *te,
3644 struct timeval t, void *private_data)
3645 {
3646 struct ctdb_kill_tcp *killtcp = talloc_get_type(private_data, struct ctdb_kill_tcp);
3647 void *delete_cons = talloc_new(NULL);
3648
3649 /* loop over all connections sending tickle ACKs */
3650 trbt_traversearray32(killtcp->connections, KILLTCP_KEYLEN, tickle_connection_traverse, delete_cons);
3651
3652 /* now we've finished traverse, it's safe to do deletion. */
3653 talloc_free(delete_cons);
3654
3655 /* If there are no more connections to kill we can remove the
3656 entire killtcp structure
3657 */
3658 if ( (killtcp->connections == NULL) ||
3659 (killtcp->connections->root == NULL) ) {
3660 talloc_free(killtcp);
3661 return;
3662 }
3663
3664 /* try tickling them again in a seconds time
3665 */
3666 event_add_timed(killtcp->ctdb->ev, killtcp, timeval_current_ofs(1, 0),
3667 ctdb_tickle_sentenced_connections, killtcp);
3668 }
3669
3670 /*
3671 destroy the killtcp structure
3672 */
3673 static int ctdb_killtcp_destructor(struct ctdb_kill_tcp *killtcp)
3674 {
3675 struct ctdb_vnn *tmpvnn;
3676
3677 /* verify that this vnn is still active */
3678 for (tmpvnn = killtcp->ctdb->vnn; tmpvnn; tmpvnn = tmpvnn->next) {
3679 if (tmpvnn == killtcp->vnn) {
3680 break;
3681 }
3682 }
3683
3684 if (tmpvnn == NULL) {
3685 return 0;
3686 }
3687
3688 if (killtcp->vnn->killtcp != killtcp) {
3689 return 0;
3690 }
3691
3692 killtcp->vnn->killtcp = NULL;
3693
3694 return 0;
3695 }
3696
3697
3698 /* nothing fancy here, just unconditionally replace any existing
3699 connection structure with the new one.
3700
3701 dont even free the old one if it did exist, that one is talloc_stolen
3702 by the same node in the tree anyway and will be deleted when the new data
3703 is deleted
3704 */
3705 static void *add_killtcp_callback(void *parm, void *data)
3706 {
3707 return parm;
3708 }
3709
3710 /*
3711 add a tcp socket to the list of connections we want to RST
3712 */
3713 static int ctdb_killtcp_add_connection(struct ctdb_context *ctdb,
3714 ctdb_sock_addr *s,
3715 ctdb_sock_addr *d)
3716 {
3717 ctdb_sock_addr src, dst;
3718 struct ctdb_kill_tcp *killtcp;
3719 struct ctdb_killtcp_con *con;
3720 struct ctdb_vnn *vnn;
3721
3722 ctdb_canonicalize_ip(s, &src);
3723 ctdb_canonicalize_ip(d, &dst);
3724
3725 vnn = find_public_ip_vnn(ctdb, &dst);
3726 if (vnn == NULL) {
3727 vnn = find_public_ip_vnn(ctdb, &src);
3728 }
3729 if (vnn == NULL) {
3730 /* if it is not a public ip it could be our 'single ip' */
3731 if (ctdb->single_ip_vnn) {
3732 if (ctdb_same_ip(&ctdb->single_ip_vnn->public_address, &dst)) {
3733 vnn = ctdb->single_ip_vnn;
3734 }
3735 }
3736 }
3737 if (vnn == NULL) {
3738 DEBUG(DEBUG_ERR,(__location__ " Could not killtcp, not a public address\n"));
3739 return -1;
3740 }
3741
3742 killtcp = vnn->killtcp;
3743
3744 /* If this is the first connection to kill we must allocate
3745 a new structure
3746 */
3747 if (killtcp == NULL) {
3748 killtcp = talloc_zero(vnn, struct ctdb_kill_tcp);
3749 CTDB_NO_MEMORY(ctdb, killtcp);
3750
3751 killtcp->vnn = vnn;
3752 killtcp->ctdb = ctdb;
3753 killtcp->capture_fd = -1;
3754 killtcp->connections = trbt_create(killtcp, 0);
3755
3756 vnn->killtcp = killtcp;
3757 talloc_set_destructor(killtcp, ctdb_killtcp_destructor);
3758 }
3759
3760
3761
3762 /* create a structure that describes this connection we want to
3763 RST and store it in killtcp->connections
3764 */
3765 con = talloc(killtcp, struct ctdb_killtcp_con);
3766 CTDB_NO_MEMORY(ctdb, con);
3767 con->src_addr = src;
3768 con->dst_addr = dst;
3769 con->count = 0;
3770 con->killtcp = killtcp;
3771
3772
3773 trbt_insertarray32_callback(killtcp->connections,
3774 KILLTCP_KEYLEN, killtcp_key(&con->dst_addr, &con->src_addr),
3775 add_killtcp_callback, con);
3776
3777 /*
3778 If we dont have a socket to listen on yet we must create it
3779 */
3780 if (killtcp->capture_fd == -1) {
3781 const char *iface = ctdb_vnn_iface_string(vnn);
3782 killtcp->capture_fd = ctdb_sys_open_capture_socket(iface, &killtcp->private_data);
3783 if (killtcp->capture_fd == -1) {
3784 DEBUG(DEBUG_CRIT,(__location__ " Failed to open capturing "
3785 "socket on iface '%s' for killtcp (%s)\n",
3786 iface, strerror(errno)));
3787 goto failed;
3788 }
3789 }
3790
3791
3792 if (killtcp->fde == NULL) {
3793 killtcp->fde = event_add_fd(ctdb->ev, killtcp, killtcp->capture_fd,
3794 EVENT_FD_READ,
3795 capture_tcp_handler, killtcp);
3796 tevent_fd_set_auto_close(killtcp->fde);
3797
3798 /* We also need to set up some events to tickle all these connections
3799 until they are all reset
3800 */
3801 event_add_timed(ctdb->ev, killtcp, timeval_current_ofs(1, 0),
3802 ctdb_tickle_sentenced_connections, killtcp);
3803 }
3804
3805 /* tickle him once now */
3806 ctdb_sys_send_tcp(
3807 &con->dst_addr,
3808 &con->src_addr,
3809 0, 0, 0);
3810
3811 return 0;
3812
3813 failed:
3814 talloc_free(vnn->killtcp);
3815 vnn->killtcp = NULL;
3816 return -1;
3817 }
3818
3819 /*
3820 kill a TCP connection.
3821 */
3822 int32_t ctdb_control_kill_tcp(struct ctdb_context *ctdb, TDB_DATA indata)
3823 {
3824 struct ctdb_control_killtcp *killtcp = (struct ctdb_control_killtcp *)indata.dptr;
3825
3826 return ctdb_killtcp_add_connection(ctdb, &killtcp->src_addr, &killtcp->dst_addr);
3827 }
3828
3829 /*
3830 called by a daemon to inform us of the entire list of TCP tickles for
3831 a particular public address.
3832 this control should only be sent by the node that is currently serving
3833 that public address.
3834 */
3835 int32_t ctdb_control_set_tcp_tickle_list(struct ctdb_context *ctdb, TDB_DATA indata)
3836 {
3837 struct ctdb_control_tcp_tickle_list *list = (struct ctdb_control_tcp_tickle_list *)indata.dptr;
3838 struct ctdb_tcp_array *tcparray;
3839 struct ctdb_vnn *vnn;
3840
3841 /* We must at least have tickles.num or else we cant verify the size
3842 of the received data blob
3843 */
3844 if (indata.dsize < offsetof(struct ctdb_control_tcp_tickle_list,
3845 tickles.connections)) {
3846 DEBUG(DEBUG_ERR,("Bad indata in ctdb_control_set_tcp_tickle_list. Not enough data for the tickle.num field\n"));
3847 return -1;
3848 }
3849
3850 /* verify that the size of data matches what we expect */
3851 if (indata.dsize < offsetof(struct ctdb_control_tcp_tickle_list,
3852 tickles.connections)
3853 + sizeof(struct ctdb_tcp_connection)
3854 * list->tickles.num) {
3855 DEBUG(DEBUG_ERR,("Bad indata in ctdb_control_set_tcp_tickle_list\n"));
3856 return -1;
3857 }
3858
3859 vnn = find_public_ip_vnn(ctdb, &list->addr);
3860 if (vnn == NULL) {
3861 DEBUG(DEBUG_INFO,(__location__ " Could not set tcp tickle list, '%s' is not a public address\n",
3862 ctdb_addr_to_str(&list->addr)));
3863
3864 return 1;
3865 }
3866
3867 /* remove any old ticklelist we might have */
3868 talloc_free(vnn->tcp_array);
3869 vnn->tcp_array = NULL;
3870
3871 tcparray = talloc(ctdb->nodes, struct ctdb_tcp_array);
3872 CTDB_NO_MEMORY(ctdb, tcparray);
3873
3874 tcparray->num = list->tickles.num;
3875
3876 tcparray->connections = talloc_array(tcparray, struct ctdb_tcp_connection, tcparray->num);
3877 CTDB_NO_MEMORY(ctdb, tcparray->connections);
3878
3879 memcpy(tcparray->connections, &list->tickles.connections[0],
3880 sizeof(struct ctdb_tcp_connection)*tcparray->num);
3881
3882 /* We now have a new fresh tickle list array for this vnn */
3883 vnn->tcp_array = talloc_steal(vnn, tcparray);
3884
3885 return 0;
3886 }
3887
3888 /*
3889 called to return the full list of tickles for the puclic address associated
3890 with the provided vnn
3891 */
3892 int32_t ctdb_control_get_tcp_tickle_list(struct ctdb_context *ctdb, TDB_DATA indata, TDB_DATA *outdata)
3893 {
3894 ctdb_sock_addr *addr = (ctdb_sock_addr *)indata.dptr;
3895 struct ctdb_control_tcp_tickle_list *list;
3896 struct ctdb_tcp_array *tcparray;
3897 int num;
3898 struct ctdb_vnn *vnn;
3899
3900 vnn = find_public_ip_vnn(ctdb, addr);
3901 if (vnn == NULL) {
3902 DEBUG(DEBUG_ERR,(__location__ " Could not get tcp tickle list, '%s' is not a public address\n",
3903 ctdb_addr_to_str(addr)));
3904
3905 return 1;
3906 }
3907
3908 tcparray = vnn->tcp_array;
3909 if (tcparray) {
3910 num = tcparray->num;
3911 } else {
3912 num = 0;
3913 }
3914
3915 outdata->dsize = offsetof(struct ctdb_control_tcp_tickle_list,
3916 tickles.connections)
3917 + sizeof(struct ctdb_tcp_connection) * num;
3918
3919 outdata->dptr = talloc_size(outdata, outdata->dsize);
3920 CTDB_NO_MEMORY(ctdb, outdata->dptr);
3921 list = (struct ctdb_control_tcp_tickle_list *)outdata->dptr;
3922
3923 list->addr = *addr;
3924 list->tickles.num = num;
3925 if (num) {
3926 memcpy(&list->tickles.connections[0], tcparray->connections,
3927 sizeof(struct ctdb_tcp_connection) * num);
3928 }
3929
3930 return 0;
3931 }
3932
3933
3934 /*
3935 set the list of all tcp tickles for a public address
3936 */
3937 static int ctdb_ctrl_set_tcp_tickles(struct ctdb_context *ctdb,
3938 struct timeval timeout, uint32_t destnode,
3939 ctdb_sock_addr *addr,
3940 struct ctdb_tcp_array *tcparray)
3941 {
3942 int ret, num;
3943 TDB_DATA data;
3944 struct ctdb_control_tcp_tickle_list *list;
3945
3946 if (tcparray) {
3947 num = tcparray->num;
3948 } else {
3949 num = 0;
3950 }
3951
3952 data.dsize = offsetof(struct ctdb_control_tcp_tickle_list,
3953 tickles.connections) +
3954 sizeof(struct ctdb_tcp_connection) * num;
3955 data.dptr = talloc_size(ctdb, data.dsize);
3956 CTDB_NO_MEMORY(ctdb, data.dptr);
3957
3958 list = (struct ctdb_control_tcp_tickle_list *)data.dptr;
3959 list->addr = *addr;
3960 list->tickles.num = num;
3961 if (tcparray) {
3962 memcpy(&list->tickles.connections[0], tcparray->connections, sizeof(struct ctdb_tcp_connection) * num);
3963 }
3964
3965 ret = ctdb_daemon_send_control(ctdb, CTDB_BROADCAST_CONNECTED, 0,
3966 CTDB_CONTROL_SET_TCP_TICKLE_LIST,
3967 0, CTDB_CTRL_FLAG_NOREPLY, data, NULL, NULL);
3968 if (ret != 0) {
3969 DEBUG(DEBUG_ERR,(__location__ " ctdb_control for set tcp tickles failed\n"));
3970 return -1;
3971 }
3972
3973 talloc_free(data.dptr);
3974
3975 return ret;
3976 }
3977
3978
3979 /*
3980 perform tickle updates if required
3981 */
3982 static void ctdb_update_tcp_tickles(struct event_context *ev,
3983 struct timed_event *te,
3984 struct timeval t, void *private_data)
3985 {
3986 struct ctdb_context *ctdb = talloc_get_type(private_data, struct ctdb_context);
3987 int ret;
3988 struct ctdb_vnn *vnn;
3989
3990 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
3991 /* we only send out updates for public addresses that
3992 we have taken over
3993 */
3994 if (ctdb->pnn != vnn->pnn) {
3995 continue;
3996 }
3997 /* We only send out the updates if we need to */
3998 if (!vnn->tcp_update_needed) {
3999 continue;
4000 }
4001 ret = ctdb_ctrl_set_tcp_tickles(ctdb,
4002 TAKEOVER_TIMEOUT(),
4003 CTDB_BROADCAST_CONNECTED,
4004 &vnn->public_address,
4005 vnn->tcp_array);
4006 if (ret != 0) {
4007 DEBUG(DEBUG_ERR,("Failed to send the tickle update for public address %s\n",
4008 ctdb_addr_to_str(&vnn->public_address)));
4009 }
4010 }
4011
4012 event_add_timed(ctdb->ev, ctdb->tickle_update_context,
4013 timeval_current_ofs(ctdb->tunable.tickle_update_interval, 0),
4014 ctdb_update_tcp_tickles, ctdb);
4015 }
4016
4017
4018 /*
4019 start periodic update of tcp tickles
4020 */
4021 void ctdb_start_tcp_tickle_update(struct ctdb_context *ctdb)
4022 {
4023 ctdb->tickle_update_context = talloc_new(ctdb);
4024
4025 event_add_timed(ctdb->ev, ctdb->tickle_update_context,
4026 timeval_current_ofs(ctdb->tunable.tickle_update_interval, 0),
4027 ctdb_update_tcp_tickles, ctdb);
4028 }
4029
4030
4031
4032
4033 struct control_gratious_arp {
4034 struct ctdb_context *ctdb;
4035 ctdb_sock_addr addr;
4036 const char *iface;
4037 int count;
4038 };
4039
4040 /*
4041 send a control_gratuitous arp
4042 */
4043 static void send_gratious_arp(struct event_context *ev, struct timed_event *te,
4044 struct timeval t, void *private_data)
4045 {
4046 int ret;
4047 struct control_gratious_arp *arp = talloc_get_type(private_data,
4048 struct control_gratious_arp);
4049
4050 ret = ctdb_sys_send_arp(&arp->addr, arp->iface);
4051 if (ret != 0) {
4052 DEBUG(DEBUG_ERR,(__location__ " sending of gratious arp on iface '%s' failed (%s)\n",
4053 arp->iface, strerror(errno)));
4054 }
4055
4056
4057 arp->count++;
4058 if (arp->count == CTDB_ARP_REPEAT) {
4059 talloc_free(arp);
4060 return;
4061 }
4062
4063 event_add_timed(arp->ctdb->ev, arp,
4064 timeval_current_ofs(CTDB_ARP_INTERVAL, 0),
4065 send_gratious_arp, arp);
4066 }
4067
4068
4069 /*
4070 send a gratious arp
4071 */
4072 int32_t ctdb_control_send_gratious_arp(struct ctdb_context *ctdb, TDB_DATA indata)
4073 {
4074 struct ctdb_control_gratious_arp *gratious_arp = (struct ctdb_control_gratious_arp *)indata.dptr;
4075 struct control_gratious_arp *arp;
4076
4077 /* verify the size of indata */
4078 if (indata.dsize < offsetof(struct ctdb_control_gratious_arp, iface)) {
4079 DEBUG(DEBUG_ERR,(__location__ " Too small indata to hold a ctdb_control_gratious_arp structure. Got %u require %u bytes\n",
4080 (unsigned)indata.dsize,
4081 (unsigned)offsetof(struct ctdb_control_gratious_arp, iface)));
4082 return -1;
4083 }
4084 if (indata.dsize !=
4085 ( offsetof(struct ctdb_control_gratious_arp, iface)
4086 + gratious_arp->len ) ){
4087
4088 DEBUG(DEBUG_ERR,(__location__ " Wrong size of indata. Was %u bytes "
4089 "but should be %u bytes\n",
4090 (unsigned)indata.dsize,
4091 (unsigned)(offsetof(struct ctdb_control_gratious_arp, iface)+gratious_arp->len)));
4092 return -1;
4093 }
4094
4095
4096 arp = talloc(ctdb, struct control_gratious_arp);
4097 CTDB_NO_MEMORY(ctdb, arp);
4098
4099 arp->ctdb = ctdb;
4100 arp->addr = gratious_arp->addr;
4101 arp->iface = talloc_strdup(arp, gratious_arp->iface);
4102 CTDB_NO_MEMORY(ctdb, arp->iface);
4103 arp->count = 0;
4104
4105 event_add_timed(arp->ctdb->ev, arp,
4106 timeval_zero(), send_gratious_arp, arp);
4107
4108 return 0;
4109 }
4110
4111 int32_t ctdb_control_add_public_address(struct ctdb_context *ctdb, TDB_DATA indata)
4112 {
4113 struct ctdb_control_ip_iface *pub = (struct ctdb_control_ip_iface *)indata.dptr;
4114 int ret;
4115
4116 /* verify the size of indata */
4117 if (indata.dsize < offsetof(struct ctdb_control_ip_iface, iface)) {
4118 DEBUG(DEBUG_ERR,(__location__ " Too small indata to hold a ctdb_control_ip_iface structure\n"));
4119 return -1;
4120 }
4121 if (indata.dsize !=
4122 ( offsetof(struct ctdb_control_ip_iface, iface)
4123 + pub->len ) ){
4124
4125 DEBUG(DEBUG_ERR,(__location__ " Wrong size of indata. Was %u bytes "
4126 "but should be %u bytes\n",
4127 (unsigned)indata.dsize,
4128 (unsigned)(offsetof(struct ctdb_control_ip_iface, iface)+pub->len)));
4129 return -1;
4130 }
4131
4132 DEBUG(DEBUG_NOTICE,("Add IP %s\n", ctdb_addr_to_str(&pub->addr)));
4133
4134 ret = ctdb_add_public_address(ctdb, &pub->addr, pub->mask, &pub->iface[0], true);
4135
4136 if (ret != 0) {
4137 DEBUG(DEBUG_ERR,(__location__ " Failed to add public address\n"));
4138 return -1;
4139 }
4140
4141 return 0;
4142 }
4143
4144 /*
4145 called when releaseip event finishes for del_public_address
4146 */
4147 static void delete_ip_callback(struct ctdb_context *ctdb, int status,
4148 void *private_data)
4149 {
4150 talloc_free(private_data);
4151 }
4152
4153 int32_t ctdb_control_del_public_address(struct ctdb_context *ctdb, TDB_DATA indata)
4154 {
4155 struct ctdb_control_ip_iface *pub = (struct ctdb_control_ip_iface *)indata.dptr;
4156 struct ctdb_vnn *vnn;
4157 int ret;
4158
4159 /* verify the size of indata */
4160 if (indata.dsize < offsetof(struct ctdb_control_ip_iface, iface)) {
4161 DEBUG(DEBUG_ERR,(__location__ " Too small indata to hold a ctdb_control_ip_iface structure\n"));
4162 return -1;
4163 }
4164 if (indata.dsize !=
4165 ( offsetof(struct ctdb_control_ip_iface, iface)
4166 + pub->len ) ){
4167
4168 DEBUG(DEBUG_ERR,(__location__ " Wrong size of indata. Was %u bytes "
4169 "but should be %u bytes\n",
4170 (unsigned)indata.dsize,
4171 (unsigned)(offsetof(struct ctdb_control_ip_iface, iface)+pub->len)));
4172 return -1;
4173 }
4174
4175 DEBUG(DEBUG_NOTICE,("Delete IP %s\n", ctdb_addr_to_str(&pub->addr)));
4176
4177 /* walk over all public addresses until we find a match */
4178 for (vnn=ctdb->vnn;vnn;vnn=vnn->next) {
4179 if (ctdb_same_ip(&vnn->public_address, &pub->addr)) {
4180 TALLOC_CTX *mem_ctx = talloc_new(ctdb);
4181
4182 DLIST_REMOVE(ctdb->vnn, vnn);
4183 talloc_steal(mem_ctx, vnn);
4184 ctdb_remove_orphaned_ifaces(ctdb, vnn, mem_ctx);
4185 if (vnn->pnn != ctdb->pnn) {
4186 if (vnn->iface != NULL) {
4187 ctdb_vnn_unassign_iface(ctdb, vnn);
4188 }
4189 talloc_free(mem_ctx);
4190 return 0;
4191 }
4192 vnn->pnn = -1;
4193
4194 ret = ctdb_event_script_callback(ctdb,
4195 mem_ctx, delete_ip_callback, mem_ctx,
4196 CTDB_EVENT_RELEASE_IP,
4197 "%s %s %u",
4198 ctdb_vnn_iface_string(vnn),
4199 ctdb_addr_to_str(&vnn->public_address),
4200 vnn->public_netmask_bits);
4201 if (vnn->iface != NULL) {
4202 ctdb_vnn_unassign_iface(ctdb, vnn);
4203 }
4204 if (ret != 0) {
4205 return -1;
4206 }
4207 return 0;
4208 }
4209 }
4210
4211 return -1;
4212 }
4213
4214
4215 struct ipreallocated_callback_state {
4216 struct ctdb_req_control *c;
4217 };
4218
4219 static void ctdb_ipreallocated_callback(struct ctdb_context *ctdb,
4220 int status, void *p)
4221 {
4222 struct ipreallocated_callback_state *state =
4223 talloc_get_type(p, struct ipreallocated_callback_state);
4224
4225 if (status != 0) {
4226 DEBUG(DEBUG_ERR,
4227 (" \"ipreallocated\" event script failed (status %d)\n",
4228 status));
4229 if (status == -ETIME) {
4230 ctdb_ban_self(ctdb);
4231 }
4232 }
4233
4234 ctdb_request_control_reply(ctdb, state->c, NULL, status, NULL);
4235 talloc_free(state);
4236 }
4237
4238 /* A control to run the ipreallocated event */
4239 int32_t ctdb_control_ipreallocated(struct ctdb_context *ctdb,
4240 struct ctdb_req_control *c,
4241 bool *async_reply)
4242 {
4243 int ret;
4244 struct ipreallocated_callback_state *state;
4245
4246 state = talloc(ctdb, struct ipreallocated_callback_state);
4247 CTDB_NO_MEMORY(ctdb, state);
4248
4249 DEBUG(DEBUG_INFO,(__location__ " Running \"ipreallocated\" event\n"));
4250
4251 ret = ctdb_event_script_callback(ctdb, state,
4252 ctdb_ipreallocated_callback, state,
4253 CTDB_EVENT_IPREALLOCATED,
4254 "%s", "");
4255
4256 if (ret != 0) {
4257 DEBUG(DEBUG_ERR,("Failed to run \"ipreallocated\" event \n"));
4258 talloc_free(state);
4259 return -1;
4260 }
4261
4262 /* tell the control that we will be reply asynchronously */
4263 state->c = talloc_steal(state, c);
4264 *async_reply = true;
4265
4266 return 0;
4267 }
4268
4269
4270 /* This function is called from the recovery daemon to verify that a remote
4271 node has the expected ip allocation.
4272 This is verified against ctdb->ip_tree
4273 */
4274 int verify_remote_ip_allocation(struct ctdb_context *ctdb,
4275 struct ctdb_all_public_ips *ips,
4276 uint32_t pnn)
4277 {
4278 struct ctdb_public_ip_list *tmp_ip;
4279 int i;
4280
4281 if (ctdb->ip_tree == NULL) {
4282 /* dont know the expected allocation yet, assume remote node
4283 is correct. */
4284 return 0;
4285 }
4286
4287 if (ips == NULL) {
4288 return 0;
4289 }
4290
4291 for (i=0; i<ips->num; i++) {
4292 tmp_ip = trbt_lookuparray32(ctdb->ip_tree, IP_KEYLEN, ip_key(&ips->ips[i].addr));
4293 if (tmp_ip == NULL) {
4294 DEBUG(DEBUG_ERR,("Node %u has new or unknown public IP %s\n", pnn, ctdb_addr_to_str(&ips->ips[i].addr)));
4295 return -1;
4296 }
4297
4298 if (tmp_ip->pnn == -1 || ips->ips[i].pnn == -1) {
4299 continue;
4300 }
4301
4302 if (tmp_ip->pnn != ips->ips[i].pnn) {
4303 DEBUG(DEBUG_ERR,
4304 ("Inconsistent IP allocation - node %u thinks %s is held by node %u while it is assigned to node %u\n",
4305 pnn,
4306 ctdb_addr_to_str(&ips->ips[i].addr),
4307 ips->ips[i].pnn, tmp_ip->pnn));
4308 return -1;
4309 }
4310 }
4311
4312 return 0;
4313 }
4314
4315 int update_ip_assignment_tree(struct ctdb_context *ctdb, struct ctdb_public_ip *ip)
4316 {
4317 struct ctdb_public_ip_list *tmp_ip;
4318
4319 if (ctdb->ip_tree == NULL) {
4320 DEBUG(DEBUG_ERR,("No ctdb->ip_tree yet. Failed to update ip assignment\n"));
4321 return -1;
4322 }
4323
4324 tmp_ip = trbt_lookuparray32(ctdb->ip_tree, IP_KEYLEN, ip_key(&ip->addr));
4325 if (tmp_ip == NULL) {
4326 DEBUG(DEBUG_ERR,(__location__ " Could not find record for address %s, update ip\n", ctdb_addr_to_str(&ip->addr)));
4327 return -1;
4328 }
4329
4330 DEBUG(DEBUG_NOTICE,("Updated ip assignment tree for ip : %s from node %u to node %u\n", ctdb_addr_to_str(&ip->addr), tmp_ip->pnn, ip->pnn));
4331 tmp_ip->pnn = ip->pnn;
4332
4333 return 0;
4334 }
4335
4336
4337 struct ctdb_reloadips_handle {
4338 struct ctdb_context *ctdb;
4339 struct ctdb_req_control *c;
4340 int status;
4341 int fd[2];
4342 pid_t child;
4343 struct fd_event *fde;
4344 };
4345
4346 static int ctdb_reloadips_destructor(struct ctdb_reloadips_handle *h)
4347 {
4348 if (h == h->ctdb->reload_ips) {
4349 h->ctdb->reload_ips = NULL;
4350 }
4351 if (h->c != NULL) {
4352 ctdb_request_control_reply(h->ctdb, h->c, NULL, h->status, NULL);
4353 h->c = NULL;
4354 }
4355 ctdb_kill(h->ctdb, h->child, SIGKILL);
4356 return 0;
4357 }
4358
4359 static void ctdb_reloadips_timeout_event(struct event_context *ev,
4360 struct timed_event *te,
4361 struct timeval t, void *private_data)
4362 {
4363 struct ctdb_reloadips_handle *h = talloc_get_type(private_data, struct ctdb_reloadips_handle);
4364
4365 talloc_free(h);
4366 }
4367
4368 static void ctdb_reloadips_child_handler(struct event_context *ev, struct fd_event *fde,
4369 uint16_t flags, void *private_data)
4370 {
4371 struct ctdb_reloadips_handle *h = talloc_get_type(private_data, struct ctdb_reloadips_handle);
4372
4373 char res;
4374 int ret;
4375
4376 ret = read(h->fd[0], &res, 1);
4377 if (ret < 1 || res != 0) {
4378 DEBUG(DEBUG_ERR, (__location__ " Reloadips child process returned error\n"));
4379 res = 1;
4380 }
4381 h->status = res;
4382
4383 talloc_free(h);
4384 }
4385
4386 static int ctdb_reloadips_child(struct ctdb_context *ctdb)
4387 {
4388 TALLOC_CTX *mem_ctx = talloc_new(NULL);
4389 struct ctdb_all_public_ips *ips;
4390 struct ctdb_vnn *vnn;
4391 struct client_async_data *async_data;
4392 struct timeval timeout;
4393 TDB_DATA data;
4394 struct ctdb_client_control_state *state;
4395 bool first_add;
4396 int i, ret;
4397
4398 CTDB_NO_MEMORY(ctdb, mem_ctx);
4399
4400 /* Read IPs from local node */
4401 ret = ctdb_ctrl_get_public_ips(ctdb, TAKEOVER_TIMEOUT(),
4402 CTDB_CURRENT_NODE, mem_ctx, &ips);
4403 if (ret != 0) {
4404 DEBUG(DEBUG_ERR,
4405 ("Unable to fetch public IPs from local node\n"));
4406 talloc_free(mem_ctx);
4407 return -1;
4408 }
4409
4410 /* Read IPs file - this is safe since this is a child process */
4411 ctdb->vnn = NULL;
4412 if (ctdb_set_public_addresses(ctdb, false) != 0) {
4413 DEBUG(DEBUG_ERR,("Failed to re-read public addresses file\n"));
4414 talloc_free(mem_ctx);
4415 return -1;
4416 }
4417
4418 async_data = talloc_zero(mem_ctx, struct client_async_data);
4419 CTDB_NO_MEMORY(ctdb, async_data);
4420
4421 /* Compare IPs between node and file for IPs to be deleted */
4422 for (i = 0; i < ips->num; i++) {
4423 /* */
4424 for (vnn = ctdb->vnn; vnn; vnn = vnn->next) {
4425 if (ctdb_same_ip(&vnn->public_address,
4426 &ips->ips[i].addr)) {
4427 /* IP is still in file */
4428 break;
4429 }
4430 }
4431
4432 if (vnn == NULL) {
4433 /* Delete IP ips->ips[i] */
4434 struct ctdb_control_ip_iface *pub;
4435
4436 DEBUG(DEBUG_NOTICE,
4437 ("IP %s no longer configured, deleting it\n",
4438 ctdb_addr_to_str(&ips->ips[i].addr)));
4439
4440 pub = talloc_zero(mem_ctx,
4441 struct ctdb_control_ip_iface);
4442 CTDB_NO_MEMORY(ctdb, pub);
4443
4444 pub->addr = ips->ips[i].addr;
4445 pub->mask = 0;
4446 pub->len = 0;
4447
4448 timeout = TAKEOVER_TIMEOUT();
4449
4450 data.dsize = offsetof(struct ctdb_control_ip_iface,
4451 iface) + pub->len;
4452 data.dptr = (uint8_t *)pub;
4453
4454 state = ctdb_control_send(ctdb, CTDB_CURRENT_NODE, 0,
4455 CTDB_CONTROL_DEL_PUBLIC_IP,
4456 0, data, async_data,
4457 &timeout, NULL);
4458 if (state == NULL) {
4459 DEBUG(DEBUG_ERR,
4460 (__location__
4461 " failed sending CTDB_CONTROL_DEL_PUBLIC_IP\n"));
4462 goto failed;
4463 }
4464
4465 ctdb_client_async_add(async_data, state);
4466 }
4467 }
4468
4469 /* Compare IPs between node and file for IPs to be added */
4470 first_add = true;
4471 for (vnn = ctdb->vnn; vnn; vnn = vnn->next) {
4472 for (i = 0; i < ips->num; i++) {
4473 if (ctdb_same_ip(&vnn->public_address,
4474 &ips->ips[i].addr)) {
4475 /* IP already on node */
4476 break;
4477 }
4478 }
4479 if (i == ips->num) {
4480 /* Add IP ips->ips[i] */
4481 struct ctdb_control_ip_iface *pub;
4482 const char *ifaces = NULL;
4483 uint32_t len;
4484 int iface = 0;
4485
4486 DEBUG(DEBUG_NOTICE,
4487 ("New IP %s configured, adding it\n",
4488 ctdb_addr_to_str(&vnn->public_address)));
4489 if (first_add) {
4490 uint32_t pnn = ctdb_get_pnn(ctdb);
4491
4492 data.dsize = sizeof(pnn);
4493 data.dptr = (uint8_t *)&pnn;
4494
4495 ret = ctdb_client_send_message(
4496 ctdb,
4497 CTDB_BROADCAST_CONNECTED,
4498 CTDB_SRVID_REBALANCE_NODE,
4499 data);
4500 if (ret != 0) {
4501 DEBUG(DEBUG_WARNING,
4502 ("Failed to send message to force node reallocation - IPs may be unbalanced\n"));
4503 }
4504
4505 first_add = false;
4506 }
4507
4508 ifaces = vnn->ifaces[0];
4509 iface = 1;
4510 while (vnn->ifaces[iface] != NULL) {
4511 ifaces = talloc_asprintf(vnn, "%s,%s", ifaces,
4512 vnn->ifaces[iface]);
4513 iface++;
4514 }
4515
4516 len = strlen(ifaces) + 1;
4517 pub = talloc_zero_size(mem_ctx,
4518 offsetof(struct ctdb_control_ip_iface, iface) + len);
4519 CTDB_NO_MEMORY(ctdb, pub);
4520
4521 pub->addr = vnn->public_address;
4522 pub->mask = vnn->public_netmask_bits;
4523 pub->len = len;
4524 memcpy(&pub->iface[0], ifaces, pub->len);
4525
4526 timeout = TAKEOVER_TIMEOUT();
4527
4528 data.dsize = offsetof(struct ctdb_control_ip_iface,
4529 iface) + pub->len;
4530 data.dptr = (uint8_t *)pub;
4531
4532 state = ctdb_control_send(ctdb, CTDB_CURRENT_NODE, 0,
4533 CTDB_CONTROL_ADD_PUBLIC_IP,
4534 0, data, async_data,
4535 &timeout, NULL);
4536 if (state == NULL) {
4537 DEBUG(DEBUG_ERR,
4538 (__location__
4539 " failed sending CTDB_CONTROL_ADD_PUBLIC_IP\n"));
4540 goto failed;
4541 }
4542
4543 ctdb_client_async_add(async_data, state);
4544 }
4545 }
4546
4547 if (ctdb_client_async_wait(ctdb, async_data) != 0) {
4548 DEBUG(DEBUG_ERR,(__location__ " Add/delete IPs failed\n"));
4549 goto failed;
4550 }
4551
4552 talloc_free(mem_ctx);
4553 return 0;
4554
4555 failed:
4556 talloc_free(mem_ctx);
4557 return -1;
4558 }
4559
4560 /* This control is sent to force the node to re-read the public addresses file
4561 and drop any addresses we should nnot longer host, and add new addresses
4562 that we are now able to host
4563 */
4564 int32_t ctdb_control_reload_public_ips(struct ctdb_context *ctdb, struct ctdb_req_control *c, bool *async_reply)
4565 {
4566 struct ctdb_reloadips_handle *h;
4567 pid_t parent = getpid();
4568
4569 if (ctdb->reload_ips != NULL) {
4570 talloc_free(ctdb->reload_ips);
4571 ctdb->reload_ips = NULL;
4572 }
4573
4574 h = talloc(ctdb, struct ctdb_reloadips_handle);
4575 CTDB_NO_MEMORY(ctdb, h);
4576 h->ctdb = ctdb;
4577 h->c = NULL;
4578 h->status = -1;
4579
4580 if (pipe(h->fd) == -1) {
4581 DEBUG(DEBUG_ERR,("Failed to create pipe for ctdb_freeze_lock\n"));
4582 talloc_free(h);
4583 return -1;
4584 }
4585
4586 h->child = ctdb_fork(ctdb);
4587 if (h->child == (pid_t)-1) {
4588 DEBUG(DEBUG_ERR, ("Failed to fork a child for reloadips\n"));
4589 close(h->fd[0]);
4590 close(h->fd[1]);
4591 talloc_free(h);
4592 return -1;
4593 }
4594
4595 /* child process */
4596 if (h->child == 0) {
4597 signed char res = 0;
4598
4599 close(h->fd[0]);
4600 debug_extra = talloc_asprintf(NULL, "reloadips:");
4601
4602 ctdb_set_process_name("ctdb_reloadips");
4603 if (switch_from_server_to_client(ctdb, "reloadips-child") != 0) {
4604 DEBUG(DEBUG_CRIT,("ERROR: Failed to switch reloadips child into client mode\n"));
4605 res = -1;
4606 } else {
4607 res = ctdb_reloadips_child(ctdb);
4608 if (res != 0) {
4609 DEBUG(DEBUG_ERR,("Failed to reload ips on local node\n"));
4610 }
4611 }
4612
4613 write(h->fd[1], &res, 1);
4614 /* make sure we die when our parent dies */
4615 while (ctdb_kill(ctdb, parent, 0) == 0 || errno != ESRCH) {
4616 sleep(5);
4617 }
4618 _exit(0);
4619 }
4620
4621 h->c = talloc_steal(h, c);
4622
4623 close(h->fd[1]);
4624 set_close_on_exec(h->fd[0]);
4625
4626 talloc_set_destructor(h, ctdb_reloadips_destructor);
4627
4628
4629 h->fde = event_add_fd(ctdb->ev, h, h->fd[0],
4630 EVENT_FD_READ, ctdb_reloadips_child_handler,
4631 (void *)h);
4632 tevent_fd_set_auto_close(h->fde);
4633
4634 event_add_timed(ctdb->ev, h,
4635 timeval_current_ofs(120, 0),
4636 ctdb_reloadips_timeout_event, h);
4637
4638 /* we reply later */
4639 *async_reply = true;
4640 return 0;
4641 }
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