1 /* -*- mode: c; c-basic-offset: 8; -*-
2 * vim: noexpandtab sw=8 ts=8 sts=0:
4 * Copyright (C) 2004, 2005 Oracle. All rights reserved.
6 * This program is free software; you can redistribute it and/or
7 * modify it under the terms of the GNU General Public
8 * License as published by the Free Software Foundation; either
9 * version 2 of the License, or (at your option) any later version.
11 * This program is distributed in the hope that it will be useful,
12 * but WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 * General Public License for more details.
16 * You should have received a copy of the GNU General Public
17 * License along with this program; if not, write to the
18 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
19 * Boston, MA 021110-1307, USA.
22 #include <linux/kernel.h>
23 #include <linux/sched.h>
24 #include <linux/jiffies.h>
25 #include <linux/module.h>
27 #include <linux/bio.h>
28 #include <linux/blkdev.h>
29 #include <linux/delay.h>
30 #include <linux/file.h>
31 #include <linux/kthread.h>
32 #include <linux/configfs.h>
33 #include <linux/random.h>
34 #include <linux/crc32.h>
35 #include <linux/time.h>
37 #include "heartbeat.h"
39 #include "nodemanager.h"
46 * The first heartbeat pass had one global thread that would serialize all hb
47 * callback calls. This global serializing sem should only be removed once
48 * we've made sure that all callees can deal with being called concurrently
49 * from multiple hb region threads.
51 static DECLARE_RWSEM(o2hb_callback_sem);
54 * multiple hb threads are watching multiple regions. A node is live
55 * whenever any of the threads sees activity from the node in its region.
57 static spinlock_t o2hb_live_lock = SPIN_LOCK_UNLOCKED;
58 static struct list_head o2hb_live_slots[O2NM_MAX_NODES];
59 static unsigned long o2hb_live_node_bitmap[BITS_TO_LONGS(O2NM_MAX_NODES)];
60 static LIST_HEAD(o2hb_node_events);
61 static DECLARE_WAIT_QUEUE_HEAD(o2hb_steady_queue);
63 static LIST_HEAD(o2hb_all_regions);
65 static struct o2hb_callback {
66 struct list_head list;
67 } o2hb_callbacks[O2HB_NUM_CB];
69 static struct o2hb_callback *hbcall_from_type(enum o2hb_callback_type type);
71 #define O2HB_DEFAULT_BLOCK_BITS 9
73 unsigned int o2hb_dead_threshold = O2HB_DEFAULT_DEAD_THRESHOLD;
75 /* Only sets a new threshold if there are no active regions.
77 * No locking or otherwise interesting code is required for reading
78 * o2hb_dead_threshold as it can't change once regions are active and
79 * it's not interesting to anyone until then anyway. */
80 static void o2hb_dead_threshold_set(unsigned int threshold)
82 if (threshold > O2HB_MIN_DEAD_THRESHOLD) {
83 spin_lock(&o2hb_live_lock);
84 if (list_empty(&o2hb_all_regions))
85 o2hb_dead_threshold = threshold;
86 spin_unlock(&o2hb_live_lock);
90 struct o2hb_node_event {
91 struct list_head hn_item;
92 enum o2hb_callback_type hn_event_type;
93 struct o2nm_node *hn_node;
97 struct o2hb_disk_slot {
98 struct o2hb_disk_heartbeat_block *ds_raw_block;
101 u64 ds_last_generation;
102 u16 ds_equal_samples;
103 u16 ds_changed_samples;
104 struct list_head ds_live_item;
107 /* each thread owns a region.. when we're asked to tear down the region
108 * we ask the thread to stop, who cleans up the region */
110 struct config_item hr_item;
112 struct list_head hr_all_item;
113 unsigned hr_unclean_stop:1;
115 /* protected by the hr_callback_sem */
116 struct task_struct *hr_task;
118 unsigned int hr_blocks;
119 unsigned long long hr_start_block;
121 unsigned int hr_block_bits;
122 unsigned int hr_block_bytes;
124 unsigned int hr_slots_per_page;
125 unsigned int hr_num_pages;
127 struct page **hr_slot_data;
128 struct block_device *hr_bdev;
129 struct o2hb_disk_slot *hr_slots;
131 /* let the person setting up hb wait for it to return until it
132 * has reached a 'steady' state. This will be fixed when we have
133 * a more complete api that doesn't lead to this sort of fragility. */
134 atomic_t hr_steady_iterations;
136 char hr_dev_name[BDEVNAME_SIZE];
138 unsigned int hr_timeout_ms;
140 /* randomized as the region goes up and down so that a node
141 * recognizes a node going up and down in one iteration */
144 struct work_struct hr_write_timeout_work;
145 unsigned long hr_last_timeout_start;
147 /* Used during o2hb_check_slot to hold a copy of the block
148 * being checked because we temporarily have to zero out the
150 struct o2hb_disk_heartbeat_block *hr_tmp_block;
153 struct o2hb_bio_wait_ctxt {
154 atomic_t wc_num_reqs;
155 struct completion wc_io_complete;
158 static void o2hb_write_timeout(void *arg)
160 struct o2hb_region *reg = arg;
162 mlog(ML_ERROR, "Heartbeat write timeout to device %s after %u "
163 "milliseconds\n", reg->hr_dev_name,
164 jiffies_to_msecs(jiffies - reg->hr_last_timeout_start));
165 o2quo_disk_timeout();
168 static void o2hb_arm_write_timeout(struct o2hb_region *reg)
170 mlog(0, "Queue write timeout for %u ms\n", O2HB_MAX_WRITE_TIMEOUT_MS);
172 cancel_delayed_work(®->hr_write_timeout_work);
173 reg->hr_last_timeout_start = jiffies;
174 schedule_delayed_work(®->hr_write_timeout_work,
175 msecs_to_jiffies(O2HB_MAX_WRITE_TIMEOUT_MS));
178 static void o2hb_disarm_write_timeout(struct o2hb_region *reg)
180 cancel_delayed_work(®->hr_write_timeout_work);
181 flush_scheduled_work();
184 static inline void o2hb_bio_wait_init(struct o2hb_bio_wait_ctxt *wc,
185 unsigned int num_ios)
187 atomic_set(&wc->wc_num_reqs, num_ios);
188 init_completion(&wc->wc_io_complete);
191 /* Used in error paths too */
192 static inline void o2hb_bio_wait_dec(struct o2hb_bio_wait_ctxt *wc,
195 /* sadly atomic_sub_and_test() isn't available on all platforms. The
196 * good news is that the fast path only completes one at a time */
198 if (atomic_dec_and_test(&wc->wc_num_reqs)) {
200 complete(&wc->wc_io_complete);
205 static void o2hb_wait_on_io(struct o2hb_region *reg,
206 struct o2hb_bio_wait_ctxt *wc)
208 struct address_space *mapping = reg->hr_bdev->bd_inode->i_mapping;
210 blk_run_address_space(mapping);
212 wait_for_completion(&wc->wc_io_complete);
215 static int o2hb_bio_end_io(struct bio *bio,
216 unsigned int bytes_done,
219 struct o2hb_bio_wait_ctxt *wc = bio->bi_private;
222 mlog(ML_ERROR, "IO Error %d\n", error);
227 o2hb_bio_wait_dec(wc, 1);
231 /* Setup a Bio to cover I/O against num_slots slots starting at
233 static struct bio *o2hb_setup_one_bio(struct o2hb_region *reg,
234 struct o2hb_bio_wait_ctxt *wc,
235 unsigned int start_slot,
236 unsigned int num_slots)
238 int i, nr_vecs, len, first_page, last_page;
239 unsigned int vec_len, vec_start;
240 unsigned int bits = reg->hr_block_bits;
241 unsigned int spp = reg->hr_slots_per_page;
245 nr_vecs = (num_slots + spp - 1) / spp;
247 /* Testing has shown this allocation to take long enough under
248 * GFP_KERNEL that the local node can get fenced. It would be
249 * nicest if we could pre-allocate these bios and avoid this
251 bio = bio_alloc(GFP_ATOMIC, nr_vecs);
253 mlog(ML_ERROR, "Could not alloc slots BIO!\n");
254 bio = ERR_PTR(-ENOMEM);
258 /* Must put everything in 512 byte sectors for the bio... */
259 bio->bi_sector = (reg->hr_start_block + start_slot) << (bits - 9);
260 bio->bi_bdev = reg->hr_bdev;
261 bio->bi_private = wc;
262 bio->bi_end_io = o2hb_bio_end_io;
264 first_page = start_slot / spp;
265 last_page = first_page + nr_vecs;
266 vec_start = (start_slot << bits) % PAGE_CACHE_SIZE;
267 for(i = first_page; i < last_page; i++) {
268 page = reg->hr_slot_data[i];
270 vec_len = PAGE_CACHE_SIZE;
271 /* last page might be short */
272 if (((i + 1) * spp) > (start_slot + num_slots))
273 vec_len = ((num_slots + start_slot) % spp) << bits;
274 vec_len -= vec_start;
276 mlog(ML_HB_BIO, "page %d, vec_len = %u, vec_start = %u\n",
277 i, vec_len, vec_start);
279 len = bio_add_page(bio, page, vec_len, vec_start);
280 if (len != vec_len) {
284 mlog(ML_ERROR, "Error adding page to bio i = %d, "
285 "vec_len = %u, len = %d\n, start = %u\n",
286 i, vec_len, len, vec_start);
298 * Compute the maximum number of sectors the bdev can handle in one bio,
301 * Stolen from oracleasm, thanks Joel!
303 static int compute_max_sectors(struct block_device *bdev)
305 int max_pages, max_sectors, pow_two_sectors;
307 struct request_queue *q;
309 q = bdev_get_queue(bdev);
310 max_pages = q->max_sectors >> (PAGE_SHIFT - 9);
311 if (max_pages > BIO_MAX_PAGES)
312 max_pages = BIO_MAX_PAGES;
313 if (max_pages > q->max_phys_segments)
314 max_pages = q->max_phys_segments;
315 if (max_pages > q->max_hw_segments)
316 max_pages = q->max_hw_segments;
317 max_pages--; /* Handle I/Os that straddle a page */
319 max_sectors = max_pages << (PAGE_SHIFT - 9);
321 /* Why is fls() 1-based???? */
322 pow_two_sectors = 1 << (fls(max_sectors) - 1);
324 return pow_two_sectors;
327 static inline void o2hb_compute_request_limits(struct o2hb_region *reg,
328 unsigned int num_slots,
329 unsigned int *num_bios,
330 unsigned int *slots_per_bio)
332 unsigned int max_sectors, io_sectors;
334 max_sectors = compute_max_sectors(reg->hr_bdev);
336 io_sectors = num_slots << (reg->hr_block_bits - 9);
338 *num_bios = (io_sectors + max_sectors - 1) / max_sectors;
339 *slots_per_bio = max_sectors >> (reg->hr_block_bits - 9);
341 mlog(ML_HB_BIO, "My io size is %u sectors for %u slots. This "
342 "device can handle %u sectors of I/O\n", io_sectors, num_slots,
344 mlog(ML_HB_BIO, "Will need %u bios holding %u slots each\n",
345 *num_bios, *slots_per_bio);
348 static int o2hb_read_slots(struct o2hb_region *reg,
349 unsigned int max_slots)
351 unsigned int num_bios, slots_per_bio, start_slot, num_slots;
353 struct o2hb_bio_wait_ctxt wc;
357 o2hb_compute_request_limits(reg, max_slots, &num_bios, &slots_per_bio);
359 bios = kcalloc(num_bios, sizeof(struct bio *), GFP_KERNEL);
366 o2hb_bio_wait_init(&wc, num_bios);
368 num_slots = slots_per_bio;
369 for(i = 0; i < num_bios; i++) {
370 start_slot = i * slots_per_bio;
372 /* adjust num_slots at last bio */
373 if (max_slots < (start_slot + num_slots))
374 num_slots = max_slots - start_slot;
376 bio = o2hb_setup_one_bio(reg, &wc, start_slot, num_slots);
378 o2hb_bio_wait_dec(&wc, num_bios - i);
380 status = PTR_ERR(bio);
386 submit_bio(READ, bio);
392 o2hb_wait_on_io(reg, &wc);
395 for(i = 0; i < num_bios; i++)
404 static int o2hb_issue_node_write(struct o2hb_region *reg,
405 struct bio **write_bio,
406 struct o2hb_bio_wait_ctxt *write_wc)
412 o2hb_bio_wait_init(write_wc, 1);
414 slot = o2nm_this_node();
416 bio = o2hb_setup_one_bio(reg, write_wc, slot, 1);
418 status = PTR_ERR(bio);
423 submit_bio(WRITE, bio);
431 static u32 o2hb_compute_block_crc_le(struct o2hb_region *reg,
432 struct o2hb_disk_heartbeat_block *hb_block)
437 /* We want to compute the block crc with a 0 value in the
438 * hb_cksum field. Save it off here and replace after the
440 old_cksum = hb_block->hb_cksum;
441 hb_block->hb_cksum = 0;
443 ret = crc32_le(0, (unsigned char *) hb_block, reg->hr_block_bytes);
445 hb_block->hb_cksum = old_cksum;
450 static void o2hb_dump_slot(struct o2hb_disk_heartbeat_block *hb_block)
452 mlog(ML_ERROR, "Dump slot information: seq = 0x%"MLFx64", node = %u, "
453 "cksum = 0x%x, generation 0x%"MLFx64"\n",
454 le64_to_cpu(hb_block->hb_seq), hb_block->hb_node,
455 le32_to_cpu(hb_block->hb_cksum),
456 le64_to_cpu(hb_block->hb_generation));
459 static int o2hb_verify_crc(struct o2hb_region *reg,
460 struct o2hb_disk_heartbeat_block *hb_block)
464 read = le32_to_cpu(hb_block->hb_cksum);
465 computed = o2hb_compute_block_crc_le(reg, hb_block);
467 return read == computed;
470 /* We want to make sure that nobody is heartbeating on top of us --
471 * this will help detect an invalid configuration. */
472 static int o2hb_check_last_timestamp(struct o2hb_region *reg)
475 struct o2hb_disk_slot *slot;
476 struct o2hb_disk_heartbeat_block *hb_block;
478 node_num = o2nm_this_node();
481 slot = ®->hr_slots[node_num];
482 /* Don't check on our 1st timestamp */
483 if (slot->ds_last_time) {
484 hb_block = slot->ds_raw_block;
486 if (le64_to_cpu(hb_block->hb_seq) != slot->ds_last_time)
493 static inline void o2hb_prepare_block(struct o2hb_region *reg,
498 struct o2hb_disk_slot *slot;
499 struct o2hb_disk_heartbeat_block *hb_block;
501 node_num = o2nm_this_node();
502 slot = ®->hr_slots[node_num];
504 hb_block = (struct o2hb_disk_heartbeat_block *)slot->ds_raw_block;
505 memset(hb_block, 0, reg->hr_block_bytes);
506 /* TODO: time stuff */
507 cputime = CURRENT_TIME.tv_sec;
511 hb_block->hb_seq = cpu_to_le64(cputime);
512 hb_block->hb_node = node_num;
513 hb_block->hb_generation = cpu_to_le64(generation);
515 /* This step must always happen last! */
516 hb_block->hb_cksum = cpu_to_le32(o2hb_compute_block_crc_le(reg,
519 mlog(ML_HB_BIO, "our node generation = 0x%"MLFx64", cksum = 0x%x\n",
520 cpu_to_le64(generation), le32_to_cpu(hb_block->hb_cksum));
523 static void o2hb_fire_callbacks(struct o2hb_callback *hbcall,
524 struct o2nm_node *node,
527 struct list_head *iter;
528 struct o2hb_callback_func *f;
530 list_for_each(iter, &hbcall->list) {
531 f = list_entry(iter, struct o2hb_callback_func, hc_item);
532 mlog(ML_HEARTBEAT, "calling funcs %p\n", f);
533 (f->hc_func)(node, idx, f->hc_data);
537 /* Will run the list in order until we process the passed event */
538 static void o2hb_run_event_list(struct o2hb_node_event *queued_event)
541 struct o2hb_callback *hbcall;
542 struct o2hb_node_event *event;
544 spin_lock(&o2hb_live_lock);
545 empty = list_empty(&queued_event->hn_item);
546 spin_unlock(&o2hb_live_lock);
550 /* Holding callback sem assures we don't alter the callback
551 * lists when doing this, and serializes ourselves with other
552 * processes wanting callbacks. */
553 down_write(&o2hb_callback_sem);
555 spin_lock(&o2hb_live_lock);
556 while (!list_empty(&o2hb_node_events)
557 && !list_empty(&queued_event->hn_item)) {
558 event = list_entry(o2hb_node_events.next,
559 struct o2hb_node_event,
561 list_del_init(&event->hn_item);
562 spin_unlock(&o2hb_live_lock);
564 mlog(ML_HEARTBEAT, "Node %s event for %d\n",
565 event->hn_event_type == O2HB_NODE_UP_CB ? "UP" : "DOWN",
568 hbcall = hbcall_from_type(event->hn_event_type);
570 /* We should *never* have gotten on to the list with a
571 * bad type... This isn't something that we should try
572 * to recover from. */
573 BUG_ON(IS_ERR(hbcall));
575 o2hb_fire_callbacks(hbcall, event->hn_node, event->hn_node_num);
577 spin_lock(&o2hb_live_lock);
579 spin_unlock(&o2hb_live_lock);
581 up_write(&o2hb_callback_sem);
584 static void o2hb_queue_node_event(struct o2hb_node_event *event,
585 enum o2hb_callback_type type,
586 struct o2nm_node *node,
589 assert_spin_locked(&o2hb_live_lock);
591 event->hn_event_type = type;
592 event->hn_node = node;
593 event->hn_node_num = node_num;
595 mlog(ML_HEARTBEAT, "Queue node %s event for node %d\n",
596 type == O2HB_NODE_UP_CB ? "UP" : "DOWN", node_num);
598 list_add_tail(&event->hn_item, &o2hb_node_events);
601 static void o2hb_shutdown_slot(struct o2hb_disk_slot *slot)
603 struct o2hb_node_event event =
604 { .hn_item = LIST_HEAD_INIT(event.hn_item), };
605 struct o2nm_node *node;
607 node = o2nm_get_node_by_num(slot->ds_node_num);
611 spin_lock(&o2hb_live_lock);
612 if (!list_empty(&slot->ds_live_item)) {
613 mlog(ML_HEARTBEAT, "Shutdown, node %d leaves region\n",
616 list_del_init(&slot->ds_live_item);
618 if (list_empty(&o2hb_live_slots[slot->ds_node_num])) {
619 clear_bit(slot->ds_node_num, o2hb_live_node_bitmap);
621 o2hb_queue_node_event(&event, O2HB_NODE_DOWN_CB, node,
625 spin_unlock(&o2hb_live_lock);
627 o2hb_run_event_list(&event);
632 static int o2hb_check_slot(struct o2hb_region *reg,
633 struct o2hb_disk_slot *slot)
635 int changed = 0, gen_changed = 0;
636 struct o2hb_node_event event =
637 { .hn_item = LIST_HEAD_INIT(event.hn_item), };
638 struct o2nm_node *node;
639 struct o2hb_disk_heartbeat_block *hb_block = reg->hr_tmp_block;
642 memcpy(hb_block, slot->ds_raw_block, reg->hr_block_bytes);
644 /* Is this correct? Do we assume that the node doesn't exist
645 * if we're not configured for him? */
646 node = o2nm_get_node_by_num(slot->ds_node_num);
650 if (!o2hb_verify_crc(reg, hb_block)) {
651 /* all paths from here will drop o2hb_live_lock for
653 spin_lock(&o2hb_live_lock);
655 /* Don't print an error on the console in this case -
656 * a freshly formatted heartbeat area will not have a
658 if (list_empty(&slot->ds_live_item))
661 /* The node is live but pushed out a bad crc. We
662 * consider it a transient miss but don't populate any
663 * other values as they may be junk. */
664 mlog(ML_ERROR, "Node %d has written a bad crc to %s\n",
665 slot->ds_node_num, reg->hr_dev_name);
666 o2hb_dump_slot(hb_block);
668 slot->ds_equal_samples++;
672 /* we don't care if these wrap.. the state transitions below
673 * clear at the right places */
674 cputime = le64_to_cpu(hb_block->hb_seq);
675 if (slot->ds_last_time != cputime)
676 slot->ds_changed_samples++;
678 slot->ds_equal_samples++;
679 slot->ds_last_time = cputime;
681 /* The node changed heartbeat generations. We assume this to
682 * mean it dropped off but came back before we timed out. We
683 * want to consider it down for the time being but don't want
684 * to lose any changed_samples state we might build up to
685 * considering it live again. */
686 if (slot->ds_last_generation != le64_to_cpu(hb_block->hb_generation)) {
688 slot->ds_equal_samples = 0;
689 mlog(ML_HEARTBEAT, "Node %d changed generation (0x%"MLFx64" "
690 "to 0x%"MLFx64")\n", slot->ds_node_num,
691 slot->ds_last_generation,
692 le64_to_cpu(hb_block->hb_generation));
695 slot->ds_last_generation = le64_to_cpu(hb_block->hb_generation);
697 mlog(ML_HEARTBEAT, "Slot %d gen 0x%"MLFx64" cksum 0x%x "
698 "seq %"MLFu64" last %"MLFu64" changed %u equal %u\n",
699 slot->ds_node_num, slot->ds_last_generation,
700 le32_to_cpu(hb_block->hb_cksum), le64_to_cpu(hb_block->hb_seq),
701 slot->ds_last_time, slot->ds_changed_samples,
702 slot->ds_equal_samples);
704 spin_lock(&o2hb_live_lock);
707 /* dead nodes only come to life after some number of
708 * changes at any time during their dead time */
709 if (list_empty(&slot->ds_live_item) &&
710 slot->ds_changed_samples >= O2HB_LIVE_THRESHOLD) {
711 mlog(ML_HEARTBEAT, "Node %d (id 0x%"MLFx64") joined my "
712 "region\n", slot->ds_node_num, slot->ds_last_generation);
714 /* first on the list generates a callback */
715 if (list_empty(&o2hb_live_slots[slot->ds_node_num])) {
716 set_bit(slot->ds_node_num, o2hb_live_node_bitmap);
718 o2hb_queue_node_event(&event, O2HB_NODE_UP_CB, node,
724 list_add_tail(&slot->ds_live_item,
725 &o2hb_live_slots[slot->ds_node_num]);
727 slot->ds_equal_samples = 0;
731 /* if the list is dead, we're done.. */
732 if (list_empty(&slot->ds_live_item))
735 /* live nodes only go dead after enough consequtive missed
736 * samples.. reset the missed counter whenever we see
738 if (slot->ds_equal_samples >= o2hb_dead_threshold || gen_changed) {
739 mlog(ML_HEARTBEAT, "Node %d left my region\n",
742 /* last off the live_slot generates a callback */
743 list_del_init(&slot->ds_live_item);
744 if (list_empty(&o2hb_live_slots[slot->ds_node_num])) {
745 clear_bit(slot->ds_node_num, o2hb_live_node_bitmap);
747 o2hb_queue_node_event(&event, O2HB_NODE_DOWN_CB, node,
753 /* We don't clear this because the node is still
754 * actually writing new blocks. */
756 slot->ds_changed_samples = 0;
759 if (slot->ds_changed_samples) {
760 slot->ds_changed_samples = 0;
761 slot->ds_equal_samples = 0;
764 spin_unlock(&o2hb_live_lock);
766 o2hb_run_event_list(&event);
772 /* This could be faster if we just implmented a find_last_bit, but I
773 * don't think the circumstances warrant it. */
774 static int o2hb_highest_node(unsigned long *nodes,
781 while ((node = find_next_bit(nodes, numbits, node + 1)) != -1) {
791 static void o2hb_do_disk_heartbeat(struct o2hb_region *reg)
793 int i, ret, highest_node, change = 0;
794 unsigned long configured_nodes[BITS_TO_LONGS(O2NM_MAX_NODES)];
795 struct bio *write_bio;
796 struct o2hb_bio_wait_ctxt write_wc;
798 if (o2nm_configured_node_map(configured_nodes, sizeof(configured_nodes)))
801 highest_node = o2hb_highest_node(configured_nodes, O2NM_MAX_NODES);
802 if (highest_node >= O2NM_MAX_NODES) {
803 mlog(ML_NOTICE, "ocfs2_heartbeat: no configured nodes found!\n");
807 /* No sense in reading the slots of nodes that don't exist
808 * yet. Of course, if the node definitions have holes in them
809 * then we're reading an empty slot anyway... Consider this
811 ret = o2hb_read_slots(reg, highest_node + 1);
817 /* With an up to date view of the slots, we can check that no
818 * other node has been improperly configured to heartbeat in
820 if (!o2hb_check_last_timestamp(reg))
821 mlog(ML_ERROR, "Device \"%s\": another node is heartbeating "
822 "in our slot!\n", reg->hr_dev_name);
824 /* fill in the proper info for our next heartbeat */
825 o2hb_prepare_block(reg, reg->hr_generation);
827 /* And fire off the write. Note that we don't wait on this I/O
829 ret = o2hb_issue_node_write(reg, &write_bio, &write_wc);
836 while((i = find_next_bit(configured_nodes, O2NM_MAX_NODES, i + 1)) < O2NM_MAX_NODES) {
838 change |= o2hb_check_slot(reg, ®->hr_slots[i]);
842 * We have to be sure we've advertised ourselves on disk
843 * before we can go to steady state. This ensures that
844 * people we find in our steady state have seen us.
846 o2hb_wait_on_io(reg, &write_wc);
848 o2hb_arm_write_timeout(reg);
850 /* let the person who launched us know when things are steady */
851 if (!change && (atomic_read(®->hr_steady_iterations) != 0)) {
852 if (atomic_dec_and_test(®->hr_steady_iterations))
853 wake_up(&o2hb_steady_queue);
857 /* Subtract b from a, storing the result in a. a *must* have a larger
859 static void o2hb_tv_subtract(struct timeval *a,
862 /* just return 0 when a is after b */
863 if (a->tv_sec < b->tv_sec ||
864 (a->tv_sec == b->tv_sec && a->tv_usec < b->tv_usec)) {
870 a->tv_sec -= b->tv_sec;
871 a->tv_usec -= b->tv_usec;
872 while ( a->tv_usec < 0 ) {
874 a->tv_usec += 1000000;
878 static unsigned int o2hb_elapsed_msecs(struct timeval *start,
881 struct timeval res = *end;
883 o2hb_tv_subtract(&res, start);
885 return res.tv_sec * 1000 + res.tv_usec / 1000;
889 * we ride the region ref that the region dir holds. before the region
890 * dir is removed and drops it ref it will wait to tear down this
893 static int o2hb_thread(void *data)
896 struct o2hb_region *reg = data;
897 struct bio *write_bio;
898 struct o2hb_bio_wait_ctxt write_wc;
899 struct timeval before_hb, after_hb;
900 unsigned int elapsed_msec;
902 mlog(ML_HEARTBEAT|ML_KTHREAD, "hb thread running\n");
904 set_user_nice(current, -20);
906 while (!kthread_should_stop() && !reg->hr_unclean_stop) {
907 /* We track the time spent inside
908 * o2hb_do_disk_heartbeat so that we avoid more then
909 * hr_timeout_ms between disk writes. On busy systems
910 * this should result in a heartbeat which is less
911 * likely to time itself out. */
912 do_gettimeofday(&before_hb);
914 o2hb_do_disk_heartbeat(reg);
916 do_gettimeofday(&after_hb);
917 elapsed_msec = o2hb_elapsed_msecs(&before_hb, &after_hb);
919 mlog(0, "start = %lu.%lu, end = %lu.%lu, msec = %u\n",
920 before_hb.tv_sec, (unsigned long) before_hb.tv_usec,
921 after_hb.tv_sec, (unsigned long) after_hb.tv_usec,
924 if (elapsed_msec < reg->hr_timeout_ms) {
925 /* the kthread api has blocked signals for us so no
926 * need to record the return value. */
927 msleep_interruptible(reg->hr_timeout_ms - elapsed_msec);
931 o2hb_disarm_write_timeout(reg);
933 /* unclean stop is only used in very bad situation */
934 for(i = 0; !reg->hr_unclean_stop && i < reg->hr_blocks; i++)
935 o2hb_shutdown_slot(®->hr_slots[i]);
937 /* Explicit down notification - avoid forcing the other nodes
938 * to timeout on this region when we could just as easily
939 * write a clear generation - thus indicating to them that
940 * this node has left this region.
942 * XXX: Should we skip this on unclean_stop? */
943 o2hb_prepare_block(reg, 0);
944 ret = o2hb_issue_node_write(reg, &write_bio, &write_wc);
946 o2hb_wait_on_io(reg, &write_wc);
952 mlog(ML_HEARTBEAT|ML_KTHREAD, "hb thread exiting\n");
961 for (i = 0; i < ARRAY_SIZE(o2hb_callbacks); i++)
962 INIT_LIST_HEAD(&o2hb_callbacks[i].list);
964 for (i = 0; i < ARRAY_SIZE(o2hb_live_slots); i++)
965 INIT_LIST_HEAD(&o2hb_live_slots[i]);
967 INIT_LIST_HEAD(&o2hb_node_events);
969 memset(o2hb_live_node_bitmap, 0, sizeof(o2hb_live_node_bitmap));
972 /* if we're already in a callback then we're already serialized by the sem */
973 static void o2hb_fill_node_map_from_callback(unsigned long *map,
976 BUG_ON(bytes < (BITS_TO_LONGS(O2NM_MAX_NODES) * sizeof(unsigned long)));
978 memcpy(map, &o2hb_live_node_bitmap, bytes);
982 * get a map of all nodes that are heartbeating in any regions
984 void o2hb_fill_node_map(unsigned long *map, unsigned bytes)
986 /* callers want to serialize this map and callbacks so that they
987 * can trust that they don't miss nodes coming to the party */
988 down_read(&o2hb_callback_sem);
989 spin_lock(&o2hb_live_lock);
990 o2hb_fill_node_map_from_callback(map, bytes);
991 spin_unlock(&o2hb_live_lock);
992 up_read(&o2hb_callback_sem);
994 EXPORT_SYMBOL_GPL(o2hb_fill_node_map);
997 * heartbeat configfs bits. The heartbeat set is a default set under
998 * the cluster set in nodemanager.c.
1001 static struct o2hb_region *to_o2hb_region(struct config_item *item)
1003 return item ? container_of(item, struct o2hb_region, hr_item) : NULL;
1006 /* drop_item only drops its ref after killing the thread, nothing should
1007 * be using the region anymore. this has to clean up any state that
1008 * attributes might have built up. */
1009 static void o2hb_region_release(struct config_item *item)
1013 struct o2hb_region *reg = to_o2hb_region(item);
1015 if (reg->hr_tmp_block)
1016 kfree(reg->hr_tmp_block);
1018 if (reg->hr_slot_data) {
1019 for (i = 0; i < reg->hr_num_pages; i++) {
1020 page = reg->hr_slot_data[i];
1024 kfree(reg->hr_slot_data);
1028 blkdev_put(reg->hr_bdev);
1031 kfree(reg->hr_slots);
1033 spin_lock(&o2hb_live_lock);
1034 list_del(®->hr_all_item);
1035 spin_unlock(&o2hb_live_lock);
1040 static int o2hb_read_block_input(struct o2hb_region *reg,
1043 unsigned long *ret_bytes,
1044 unsigned int *ret_bits)
1046 unsigned long bytes;
1047 char *p = (char *)page;
1049 bytes = simple_strtoul(p, &p, 0);
1050 if (!p || (*p && (*p != '\n')))
1053 /* Heartbeat and fs min / max block sizes are the same. */
1054 if (bytes > 4096 || bytes < 512)
1056 if (hweight16(bytes) != 1)
1062 *ret_bits = ffs(bytes) - 1;
1067 static ssize_t o2hb_region_block_bytes_read(struct o2hb_region *reg,
1070 return sprintf(page, "%u\n", reg->hr_block_bytes);
1073 static ssize_t o2hb_region_block_bytes_write(struct o2hb_region *reg,
1078 unsigned long block_bytes;
1079 unsigned int block_bits;
1084 status = o2hb_read_block_input(reg, page, count,
1085 &block_bytes, &block_bits);
1089 reg->hr_block_bytes = (unsigned int)block_bytes;
1090 reg->hr_block_bits = block_bits;
1095 static ssize_t o2hb_region_start_block_read(struct o2hb_region *reg,
1098 return sprintf(page, "%llu\n", reg->hr_start_block);
1101 static ssize_t o2hb_region_start_block_write(struct o2hb_region *reg,
1105 unsigned long long tmp;
1106 char *p = (char *)page;
1111 tmp = simple_strtoull(p, &p, 0);
1112 if (!p || (*p && (*p != '\n')))
1115 reg->hr_start_block = tmp;
1120 static ssize_t o2hb_region_blocks_read(struct o2hb_region *reg,
1123 return sprintf(page, "%d\n", reg->hr_blocks);
1126 static ssize_t o2hb_region_blocks_write(struct o2hb_region *reg,
1131 char *p = (char *)page;
1136 tmp = simple_strtoul(p, &p, 0);
1137 if (!p || (*p && (*p != '\n')))
1140 if (tmp > O2NM_MAX_NODES || tmp == 0)
1143 reg->hr_blocks = (unsigned int)tmp;
1148 static ssize_t o2hb_region_dev_read(struct o2hb_region *reg,
1151 unsigned int ret = 0;
1154 ret = sprintf(page, "%s\n", reg->hr_dev_name);
1159 static void o2hb_init_region_params(struct o2hb_region *reg)
1161 reg->hr_slots_per_page = PAGE_CACHE_SIZE >> reg->hr_block_bits;
1162 reg->hr_timeout_ms = O2HB_REGION_TIMEOUT_MS;
1164 mlog(ML_HEARTBEAT, "hr_start_block = %llu, hr_blocks = %u\n",
1165 reg->hr_start_block, reg->hr_blocks);
1166 mlog(ML_HEARTBEAT, "hr_block_bytes = %u, hr_block_bits = %u\n",
1167 reg->hr_block_bytes, reg->hr_block_bits);
1168 mlog(ML_HEARTBEAT, "hr_timeout_ms = %u\n", reg->hr_timeout_ms);
1169 mlog(ML_HEARTBEAT, "dead threshold = %u\n", o2hb_dead_threshold);
1172 static int o2hb_map_slot_data(struct o2hb_region *reg)
1175 unsigned int last_slot;
1176 unsigned int spp = reg->hr_slots_per_page;
1179 struct o2hb_disk_slot *slot;
1181 reg->hr_tmp_block = kmalloc(reg->hr_block_bytes, GFP_KERNEL);
1182 if (reg->hr_tmp_block == NULL) {
1183 mlog_errno(-ENOMEM);
1187 reg->hr_slots = kcalloc(reg->hr_blocks,
1188 sizeof(struct o2hb_disk_slot), GFP_KERNEL);
1189 if (reg->hr_slots == NULL) {
1190 mlog_errno(-ENOMEM);
1194 for(i = 0; i < reg->hr_blocks; i++) {
1195 slot = ®->hr_slots[i];
1196 slot->ds_node_num = i;
1197 INIT_LIST_HEAD(&slot->ds_live_item);
1198 slot->ds_raw_block = NULL;
1201 reg->hr_num_pages = (reg->hr_blocks + spp - 1) / spp;
1202 mlog(ML_HEARTBEAT, "Going to require %u pages to cover %u blocks "
1203 "at %u blocks per page\n",
1204 reg->hr_num_pages, reg->hr_blocks, spp);
1206 reg->hr_slot_data = kcalloc(reg->hr_num_pages, sizeof(struct page *),
1208 if (!reg->hr_slot_data) {
1209 mlog_errno(-ENOMEM);
1213 for(i = 0; i < reg->hr_num_pages; i++) {
1214 page = alloc_page(GFP_KERNEL);
1216 mlog_errno(-ENOMEM);
1220 reg->hr_slot_data[i] = page;
1222 last_slot = i * spp;
1223 raw = page_address(page);
1225 (j < spp) && ((j + last_slot) < reg->hr_blocks);
1227 BUG_ON((j + last_slot) >= reg->hr_blocks);
1229 slot = ®->hr_slots[j + last_slot];
1230 slot->ds_raw_block =
1231 (struct o2hb_disk_heartbeat_block *) raw;
1233 raw += reg->hr_block_bytes;
1240 /* Read in all the slots available and populate the tracking
1241 * structures so that we can start with a baseline idea of what's
1243 static int o2hb_populate_slot_data(struct o2hb_region *reg)
1246 struct o2hb_disk_slot *slot;
1247 struct o2hb_disk_heartbeat_block *hb_block;
1251 ret = o2hb_read_slots(reg, reg->hr_blocks);
1257 /* We only want to get an idea of the values initially in each
1258 * slot, so we do no verification - o2hb_check_slot will
1259 * actually determine if each configured slot is valid and
1260 * whether any values have changed. */
1261 for(i = 0; i < reg->hr_blocks; i++) {
1262 slot = ®->hr_slots[i];
1263 hb_block = (struct o2hb_disk_heartbeat_block *) slot->ds_raw_block;
1265 /* Only fill the values that o2hb_check_slot uses to
1266 * determine changing slots */
1267 slot->ds_last_time = le64_to_cpu(hb_block->hb_seq);
1268 slot->ds_last_generation = le64_to_cpu(hb_block->hb_generation);
1276 /* this is acting as commit; we set up all of hr_bdev and hr_task or nothing */
1277 static ssize_t o2hb_region_dev_write(struct o2hb_region *reg,
1283 char *p = (char *)page;
1284 struct file *filp = NULL;
1285 struct inode *inode = NULL;
1286 ssize_t ret = -EINVAL;
1291 /* We can't heartbeat without having had our node number
1292 * configured yet. */
1293 if (o2nm_this_node() == O2NM_MAX_NODES)
1296 fd = simple_strtol(p, &p, 0);
1297 if (!p || (*p && (*p != '\n')))
1300 if (fd < 0 || fd >= INT_MAX)
1307 if (reg->hr_blocks == 0 || reg->hr_start_block == 0 ||
1308 reg->hr_block_bytes == 0)
1311 inode = igrab(filp->f_mapping->host);
1315 if (!S_ISBLK(inode->i_mode))
1318 reg->hr_bdev = I_BDEV(filp->f_mapping->host);
1319 ret = blkdev_get(reg->hr_bdev, FMODE_WRITE | FMODE_READ, 0);
1321 reg->hr_bdev = NULL;
1326 bdevname(reg->hr_bdev, reg->hr_dev_name);
1328 sectsize = bdev_hardsect_size(reg->hr_bdev);
1329 if (sectsize != reg->hr_block_bytes) {
1331 "blocksize %u incorrect for device, expected %d",
1332 reg->hr_block_bytes, sectsize);
1337 o2hb_init_region_params(reg);
1339 /* Generation of zero is invalid */
1341 get_random_bytes(®->hr_generation,
1342 sizeof(reg->hr_generation));
1343 } while (reg->hr_generation == 0);
1345 ret = o2hb_map_slot_data(reg);
1351 ret = o2hb_populate_slot_data(reg);
1357 INIT_WORK(®->hr_write_timeout_work, o2hb_write_timeout, reg);
1360 * A node is considered live after it has beat LIVE_THRESHOLD
1361 * times. We're not steady until we've given them a chance
1362 * _after_ our first read.
1364 atomic_set(®->hr_steady_iterations, O2HB_LIVE_THRESHOLD + 1);
1366 reg->hr_task = kthread_run(o2hb_thread, reg, "o2hb-%s",
1367 reg->hr_item.ci_name);
1368 if (IS_ERR(reg->hr_task)) {
1369 ret = PTR_ERR(reg->hr_task);
1371 reg->hr_task = NULL;
1375 ret = wait_event_interruptible(o2hb_steady_queue,
1376 atomic_read(®->hr_steady_iterations) == 0);
1378 kthread_stop(reg->hr_task);
1379 reg->hr_task = NULL;
1391 blkdev_put(reg->hr_bdev);
1392 reg->hr_bdev = NULL;
1398 struct o2hb_region_attribute {
1399 struct configfs_attribute attr;
1400 ssize_t (*show)(struct o2hb_region *, char *);
1401 ssize_t (*store)(struct o2hb_region *, const char *, size_t);
1404 static struct o2hb_region_attribute o2hb_region_attr_block_bytes = {
1405 .attr = { .ca_owner = THIS_MODULE,
1406 .ca_name = "block_bytes",
1407 .ca_mode = S_IRUGO | S_IWUSR },
1408 .show = o2hb_region_block_bytes_read,
1409 .store = o2hb_region_block_bytes_write,
1412 static struct o2hb_region_attribute o2hb_region_attr_start_block = {
1413 .attr = { .ca_owner = THIS_MODULE,
1414 .ca_name = "start_block",
1415 .ca_mode = S_IRUGO | S_IWUSR },
1416 .show = o2hb_region_start_block_read,
1417 .store = o2hb_region_start_block_write,
1420 static struct o2hb_region_attribute o2hb_region_attr_blocks = {
1421 .attr = { .ca_owner = THIS_MODULE,
1422 .ca_name = "blocks",
1423 .ca_mode = S_IRUGO | S_IWUSR },
1424 .show = o2hb_region_blocks_read,
1425 .store = o2hb_region_blocks_write,
1428 static struct o2hb_region_attribute o2hb_region_attr_dev = {
1429 .attr = { .ca_owner = THIS_MODULE,
1431 .ca_mode = S_IRUGO | S_IWUSR },
1432 .show = o2hb_region_dev_read,
1433 .store = o2hb_region_dev_write,
1436 static struct configfs_attribute *o2hb_region_attrs[] = {
1437 &o2hb_region_attr_block_bytes.attr,
1438 &o2hb_region_attr_start_block.attr,
1439 &o2hb_region_attr_blocks.attr,
1440 &o2hb_region_attr_dev.attr,
1444 static ssize_t o2hb_region_show(struct config_item *item,
1445 struct configfs_attribute *attr,
1448 struct o2hb_region *reg = to_o2hb_region(item);
1449 struct o2hb_region_attribute *o2hb_region_attr =
1450 container_of(attr, struct o2hb_region_attribute, attr);
1453 if (o2hb_region_attr->show)
1454 ret = o2hb_region_attr->show(reg, page);
1458 static ssize_t o2hb_region_store(struct config_item *item,
1459 struct configfs_attribute *attr,
1460 const char *page, size_t count)
1462 struct o2hb_region *reg = to_o2hb_region(item);
1463 struct o2hb_region_attribute *o2hb_region_attr =
1464 container_of(attr, struct o2hb_region_attribute, attr);
1465 ssize_t ret = -EINVAL;
1467 if (o2hb_region_attr->store)
1468 ret = o2hb_region_attr->store(reg, page, count);
1472 static struct configfs_item_operations o2hb_region_item_ops = {
1473 .release = o2hb_region_release,
1474 .show_attribute = o2hb_region_show,
1475 .store_attribute = o2hb_region_store,
1478 static struct config_item_type o2hb_region_type = {
1479 .ct_item_ops = &o2hb_region_item_ops,
1480 .ct_attrs = o2hb_region_attrs,
1481 .ct_owner = THIS_MODULE,
1486 struct o2hb_heartbeat_group {
1487 struct config_group hs_group;
1491 static struct o2hb_heartbeat_group *to_o2hb_heartbeat_group(struct config_group *group)
1494 container_of(group, struct o2hb_heartbeat_group, hs_group)
1498 static struct config_item *o2hb_heartbeat_group_make_item(struct config_group *group,
1501 struct o2hb_region *reg = NULL;
1502 struct config_item *ret = NULL;
1504 reg = kcalloc(1, sizeof(struct o2hb_region), GFP_KERNEL);
1506 goto out; /* ENOMEM */
1508 config_item_init_type_name(®->hr_item, name, &o2hb_region_type);
1510 ret = ®->hr_item;
1512 spin_lock(&o2hb_live_lock);
1513 list_add_tail(®->hr_all_item, &o2hb_all_regions);
1514 spin_unlock(&o2hb_live_lock);
1522 static void o2hb_heartbeat_group_drop_item(struct config_group *group,
1523 struct config_item *item)
1525 struct o2hb_region *reg = to_o2hb_region(item);
1527 /* stop the thread when the user removes the region dir */
1529 kthread_stop(reg->hr_task);
1530 reg->hr_task = NULL;
1533 config_item_put(item);
1536 struct o2hb_heartbeat_group_attribute {
1537 struct configfs_attribute attr;
1538 ssize_t (*show)(struct o2hb_heartbeat_group *, char *);
1539 ssize_t (*store)(struct o2hb_heartbeat_group *, const char *, size_t);
1542 static ssize_t o2hb_heartbeat_group_show(struct config_item *item,
1543 struct configfs_attribute *attr,
1546 struct o2hb_heartbeat_group *reg = to_o2hb_heartbeat_group(to_config_group(item));
1547 struct o2hb_heartbeat_group_attribute *o2hb_heartbeat_group_attr =
1548 container_of(attr, struct o2hb_heartbeat_group_attribute, attr);
1551 if (o2hb_heartbeat_group_attr->show)
1552 ret = o2hb_heartbeat_group_attr->show(reg, page);
1556 static ssize_t o2hb_heartbeat_group_store(struct config_item *item,
1557 struct configfs_attribute *attr,
1558 const char *page, size_t count)
1560 struct o2hb_heartbeat_group *reg = to_o2hb_heartbeat_group(to_config_group(item));
1561 struct o2hb_heartbeat_group_attribute *o2hb_heartbeat_group_attr =
1562 container_of(attr, struct o2hb_heartbeat_group_attribute, attr);
1563 ssize_t ret = -EINVAL;
1565 if (o2hb_heartbeat_group_attr->store)
1566 ret = o2hb_heartbeat_group_attr->store(reg, page, count);
1570 static ssize_t o2hb_heartbeat_group_threshold_show(struct o2hb_heartbeat_group *group,
1573 return sprintf(page, "%u\n", o2hb_dead_threshold);
1576 static ssize_t o2hb_heartbeat_group_threshold_store(struct o2hb_heartbeat_group *group,
1581 char *p = (char *)page;
1583 tmp = simple_strtoul(p, &p, 10);
1584 if (!p || (*p && (*p != '\n')))
1587 /* this will validate ranges for us. */
1588 o2hb_dead_threshold_set((unsigned int) tmp);
1593 static struct o2hb_heartbeat_group_attribute o2hb_heartbeat_group_attr_threshold = {
1594 .attr = { .ca_owner = THIS_MODULE,
1595 .ca_name = "dead_threshold",
1596 .ca_mode = S_IRUGO | S_IWUSR },
1597 .show = o2hb_heartbeat_group_threshold_show,
1598 .store = o2hb_heartbeat_group_threshold_store,
1601 static struct configfs_attribute *o2hb_heartbeat_group_attrs[] = {
1602 &o2hb_heartbeat_group_attr_threshold.attr,
1606 static struct configfs_item_operations o2hb_hearbeat_group_item_ops = {
1607 .show_attribute = o2hb_heartbeat_group_show,
1608 .store_attribute = o2hb_heartbeat_group_store,
1611 static struct configfs_group_operations o2hb_heartbeat_group_group_ops = {
1612 .make_item = o2hb_heartbeat_group_make_item,
1613 .drop_item = o2hb_heartbeat_group_drop_item,
1616 static struct config_item_type o2hb_heartbeat_group_type = {
1617 .ct_group_ops = &o2hb_heartbeat_group_group_ops,
1618 .ct_item_ops = &o2hb_hearbeat_group_item_ops,
1619 .ct_attrs = o2hb_heartbeat_group_attrs,
1620 .ct_owner = THIS_MODULE,
1623 /* this is just here to avoid touching group in heartbeat.h which the
1624 * entire damn world #includes */
1625 struct config_group *o2hb_alloc_hb_set(void)
1627 struct o2hb_heartbeat_group *hs = NULL;
1628 struct config_group *ret = NULL;
1630 hs = kcalloc(1, sizeof(struct o2hb_heartbeat_group), GFP_KERNEL);
1634 config_group_init_type_name(&hs->hs_group, "heartbeat",
1635 &o2hb_heartbeat_group_type);
1637 ret = &hs->hs_group;
1644 void o2hb_free_hb_set(struct config_group *group)
1646 struct o2hb_heartbeat_group *hs = to_o2hb_heartbeat_group(group);
1650 /* hb callback registration and issueing */
1652 static struct o2hb_callback *hbcall_from_type(enum o2hb_callback_type type)
1654 if (type == O2HB_NUM_CB)
1655 return ERR_PTR(-EINVAL);
1657 return &o2hb_callbacks[type];
1660 void o2hb_setup_callback(struct o2hb_callback_func *hc,
1661 enum o2hb_callback_type type,
1666 INIT_LIST_HEAD(&hc->hc_item);
1669 hc->hc_priority = priority;
1671 hc->hc_magic = O2HB_CB_MAGIC;
1673 EXPORT_SYMBOL_GPL(o2hb_setup_callback);
1675 int o2hb_register_callback(struct o2hb_callback_func *hc)
1677 struct o2hb_callback_func *tmp;
1678 struct list_head *iter;
1679 struct o2hb_callback *hbcall;
1682 BUG_ON(hc->hc_magic != O2HB_CB_MAGIC);
1683 BUG_ON(!list_empty(&hc->hc_item));
1685 hbcall = hbcall_from_type(hc->hc_type);
1686 if (IS_ERR(hbcall)) {
1687 ret = PTR_ERR(hbcall);
1691 down_write(&o2hb_callback_sem);
1693 list_for_each(iter, &hbcall->list) {
1694 tmp = list_entry(iter, struct o2hb_callback_func, hc_item);
1695 if (hc->hc_priority < tmp->hc_priority) {
1696 list_add_tail(&hc->hc_item, iter);
1700 if (list_empty(&hc->hc_item))
1701 list_add_tail(&hc->hc_item, &hbcall->list);
1703 up_write(&o2hb_callback_sem);
1706 mlog(ML_HEARTBEAT, "returning %d on behalf of %p for funcs %p\n",
1707 ret, __builtin_return_address(0), hc);
1710 EXPORT_SYMBOL_GPL(o2hb_register_callback);
1712 int o2hb_unregister_callback(struct o2hb_callback_func *hc)
1714 BUG_ON(hc->hc_magic != O2HB_CB_MAGIC);
1716 mlog(ML_HEARTBEAT, "on behalf of %p for funcs %p\n",
1717 __builtin_return_address(0), hc);
1719 if (list_empty(&hc->hc_item))
1722 down_write(&o2hb_callback_sem);
1724 list_del_init(&hc->hc_item);
1726 up_write(&o2hb_callback_sem);
1730 EXPORT_SYMBOL_GPL(o2hb_unregister_callback);
1732 int o2hb_check_node_heartbeating(u8 node_num)
1734 unsigned long testing_map[BITS_TO_LONGS(O2NM_MAX_NODES)];
1736 o2hb_fill_node_map(testing_map, sizeof(testing_map));
1737 if (!test_bit(node_num, testing_map)) {
1739 "node (%u) does not have heartbeating enabled.\n",
1746 EXPORT_SYMBOL_GPL(o2hb_check_node_heartbeating);
1748 int o2hb_check_node_heartbeating_from_callback(u8 node_num)
1750 unsigned long testing_map[BITS_TO_LONGS(O2NM_MAX_NODES)];
1752 o2hb_fill_node_map_from_callback(testing_map, sizeof(testing_map));
1753 if (!test_bit(node_num, testing_map)) {
1755 "node (%u) does not have heartbeating enabled.\n",
1762 EXPORT_SYMBOL_GPL(o2hb_check_node_heartbeating_from_callback);
1764 /* Makes sure our local node is configured with a node number, and is
1766 int o2hb_check_local_node_heartbeating(void)
1770 /* if this node was set then we have networking */
1771 node_num = o2nm_this_node();
1772 if (node_num == O2NM_MAX_NODES) {
1773 mlog(ML_HEARTBEAT, "this node has not been configured.\n");
1777 return o2hb_check_node_heartbeating(node_num);
1779 EXPORT_SYMBOL_GPL(o2hb_check_local_node_heartbeating);
1782 * this is just a hack until we get the plumbing which flips file systems
1783 * read only and drops the hb ref instead of killing the node dead.
1785 void o2hb_stop_all_regions(void)
1787 struct o2hb_region *reg;
1789 mlog(ML_ERROR, "stopping heartbeat on all active regions.\n");
1791 spin_lock(&o2hb_live_lock);
1793 list_for_each_entry(reg, &o2hb_all_regions, hr_all_item)
1794 reg->hr_unclean_stop = 1;
1796 spin_unlock(&o2hb_live_lock);
1798 EXPORT_SYMBOL_GPL(o2hb_stop_all_regions);