/* * Copyright (C) 2004-2009 Red Hat, Inc. All rights reserved. * * This copyrighted material is made available to anyone wishing to use, * modify, copy, or redistribute it subject to the terms and conditions * of the GNU Lesser General Public License v.2.1. * * You should have received a copy of the GNU Lesser General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "logging.h" #include "functions.h" #include #include #include #include #include #include #include #define BYTE_SHIFT 3 /* * Magic for persistent mirrors: "MiRr" * Following on-disk header information is stolen from * drivers/md/dm-log.c */ #define MIRROR_MAGIC 0x4D695272 #define MIRROR_DISK_VERSION 2 #define LOG_OFFSET 2 #define RESYNC_HISTORY 50 //static char resync_history[RESYNC_HISTORY][128]; //static int idx = 0; #define LOG_SPRINT(_lc, f, arg...) do { \ lc->idx++; \ lc->idx = lc->idx % RESYNC_HISTORY; \ sprintf(lc->resync_history[lc->idx], f, ## arg); \ } while (0) struct log_header { uint32_t magic; uint32_t version; uint64_t nr_regions; }; struct log_c { struct dm_list list; char uuid[DM_UUID_LEN]; uint64_t luid; time_t delay; /* limits how fast a resume can happen after suspend */ int touched; int in_sync; /* An in-sync that stays set until suspend/resume */ uint32_t region_size; uint32_t region_count; uint64_t sync_count; dm_bitset_t clean_bits; dm_bitset_t sync_bits; uint32_t recoverer; uint64_t recovering_region; /* -1 means not recovering */ uint64_t skip_bit_warning; /* used to warn if region skipped */ int sync_search; int resume_override; uint32_t block_on_error; enum sync { DEFAULTSYNC, /* Synchronize if necessary */ NOSYNC, /* Devices known to be already in sync */ FORCESYNC, /* Force a sync to happen */ } sync; uint32_t state; /* current operational state of the log */ struct dm_list mark_list; uint32_t recovery_halted; struct recovery_request *recovery_request_list; int disk_fd; /* -1 means no disk log */ int log_dev_failed; uint64_t disk_nr_regions; size_t disk_size; /* size of disk_buffer in bytes */ void *disk_buffer; /* aligned memory for O_DIRECT */ int idx; char resync_history[RESYNC_HISTORY][128]; }; struct mark_entry { struct dm_list list; uint32_t nodeid; uint64_t region; }; struct recovery_request { uint64_t region; struct recovery_request *next; }; static DM_LIST_INIT(log_list); static DM_LIST_INIT(log_pending_list); static int log_test_bit(dm_bitset_t bs, int bit) { return dm_bit(bs, bit) ? 1 : 0; } static void log_set_bit(struct log_c *lc, dm_bitset_t bs, int bit) { dm_bit_set(bs, bit); lc->touched = 1; } static void log_clear_bit(struct log_c *lc, dm_bitset_t bs, int bit) { dm_bit_clear(bs, bit); lc->touched = 1; } static uint64_t find_next_zero_bit(dm_bitset_t bs, unsigned start) { for (; dm_bit(bs, start); start++) if (start >= *bs) return (uint64_t)-1; return start; } static uint64_t count_bits32(dm_bitset_t bs) { unsigned i, size = bs[0]/(unsigned)DM_BITS_PER_INT + 1; unsigned count = 0; for (i = 1; i <= size; i++) count += hweight32(bs[i]); return (uint64_t)count; } /* * get_log * * Returns: log if found, NULL otherwise */ static struct log_c *get_log(const char *uuid, uint64_t luid) { struct log_c *lc; dm_list_iterate_items(lc, &log_list) if (!strcmp(lc->uuid, uuid) && (!luid || (luid == lc->luid))) return lc; return NULL; } /* * get_pending_log * * Pending logs are logs that have been 'clog_ctr'ed, but * have not joined the CPG (via clog_resume). * * Returns: log if found, NULL otherwise */ static struct log_c *get_pending_log(const char *uuid, uint64_t luid) { struct log_c *lc; dm_list_iterate_items(lc, &log_pending_list) if (!strcmp(lc->uuid, uuid) && (!luid || (luid == lc->luid))) return lc; return NULL; } static void header_to_disk(struct log_header *mem, struct log_header *disk) { memcpy(disk, mem, sizeof(struct log_header)); } static void header_from_disk(struct log_header *mem, struct log_header *disk) { memcpy(mem, disk, sizeof(struct log_header)); } static int rw_log(struct log_c *lc, int do_write) { int r; r = (int)lseek(lc->disk_fd, 0, SEEK_SET); if (r < 0) { LOG_ERROR("[%s] rw_log: lseek failure: %s", SHORT_UUID(lc->uuid), strerror(errno)); return -errno; } if (do_write) { /* FIXME Cope with full set of non-error conditions */ r = write(lc->disk_fd, lc->disk_buffer, lc->disk_size); if (r < 0) { LOG_ERROR("[%s] rw_log: write failure: %s", SHORT_UUID(lc->uuid), strerror(errno)); return -EIO; /* Failed disk write */ } return 0; } /* Read */ /* FIXME Cope with full set of non-error conditions */ r = read(lc->disk_fd, lc->disk_buffer, lc->disk_size); if (r < 0) LOG_ERROR("[%s] rw_log: read failure: %s", SHORT_UUID(lc->uuid), strerror(errno)); if (r != lc->disk_size) return -EIO; /* Failed disk read */ return 0; } /* * read_log * @lc * * Valid return codes: * -EINVAL: Invalid header, bits not copied * -EIO: Unable to read disk log * 0: Valid header, disk bit -> lc->clean_bits * * Returns: 0 on success, -EXXX on failure */ static int read_log(struct log_c *lc) { struct log_header lh = { 0 }; size_t bitset_size; if (rw_log(lc, 0)) return -EIO; /* Failed disk read */ header_from_disk(&lh, lc->disk_buffer); if (lh.magic != MIRROR_MAGIC) return -EINVAL; lc->disk_nr_regions = lh.nr_regions; /* Read disk bits into sync_bits */ bitset_size = lc->region_count / 8; bitset_size += (lc->region_count % 8) ? 1 : 0; /* 'lc->clean_bits + 1' becasue dm_bitset_t leads with a uint32_t */ memcpy(lc->clean_bits + 1, (char *)lc->disk_buffer + 1024, bitset_size); return 0; } /* * write_log * @lc * * Returns: 0 on success, -EIO on failure */ static int write_log(struct log_c *lc) { struct log_header lh; size_t bitset_size; lh.magic = MIRROR_MAGIC; lh.version = MIRROR_DISK_VERSION; lh.nr_regions = lc->region_count; header_to_disk(&lh, lc->disk_buffer); /* Write disk bits from clean_bits */ bitset_size = lc->region_count / 8; bitset_size += (lc->region_count % 8) ? 1 : 0; /* 'lc->clean_bits + 1' becasue dm_bitset_t leads with a uint32_t */ memcpy((char *)lc->disk_buffer + 1024, lc->clean_bits + 1, bitset_size); if (rw_log(lc, 1)) { lc->log_dev_failed = 1; return -EIO; /* Failed disk write */ } return 0; } /* FIXME Rewrite this function taking advantage of the udev changes (where in use) to improve its efficiency! */ static int find_disk_path(char *major_minor_str, char *path_rtn, int *unlink_path __attribute__((unused))) { int r; DIR *dp; struct dirent *dep; struct stat statbuf; int major, minor; if (!strstr(major_minor_str, ":")) { r = stat(major_minor_str, &statbuf); if (r) return -errno; if (!S_ISBLK(statbuf.st_mode)) return -EINVAL; sprintf(path_rtn, "%s", major_minor_str); return 0; } r = sscanf(major_minor_str, "%d:%d", &major, &minor); if (r != 2) return -EINVAL; /* FIXME dm_dir() */ LOG_DBG("Checking /dev/mapper for device %d:%d", major, minor); /* Check /dev/mapper dir */ dp = opendir("/dev/mapper"); if (!dp) return -ENOENT; while ((dep = readdir(dp)) != NULL) { /* * FIXME: This is racy. By the time the path is used, * it may point to something else. 'fstat' will be * required upon opening to ensure we got what we * wanted. */ sprintf(path_rtn, "/dev/mapper/%s", dep->d_name); if (stat(path_rtn, &statbuf) < 0) { LOG_DBG("Unable to stat %s", path_rtn); continue; } if (S_ISBLK(statbuf.st_mode) && (major(statbuf.st_rdev) == major) && (minor(statbuf.st_rdev) == minor)) { LOG_DBG(" %s: YES", dep->d_name); if (closedir(dp)) LOG_DBG("Unable to closedir /dev/mapper %s", strerror(errno)); return 0; } else { LOG_DBG(" %s: NO", dep->d_name); } } if (closedir(dp)) LOG_DBG("Unable to closedir /dev/mapper %s", strerror(errno)); /* FIXME Find out why this was here and deal with underlying problem. */ LOG_DBG("Path not found for %d/%d", major, minor); return -ENOENT; // LOG_DBG("Creating /dev/mapper/%d-%d", major, minor); // sprintf(path_rtn, "/dev/mapper/%d-%d", major, minor); // r = mknod(path_rtn, S_IFBLK | S_IRUSR | S_IWUSR, MKDEV(major, minor)); /* * If we have to make the path, we unlink it after we open it */ // *unlink_path = 1; // return r ? -errno : 0; } static int _clog_ctr(char *uuid, uint64_t luid, int argc, char **argv, uint64_t device_size) { int i; int r = 0; char *p; uint64_t region_size; uint64_t region_count; struct log_c *lc = NULL; enum sync log_sync = DEFAULTSYNC; uint32_t block_on_error = 0; int disk_log; char disk_path[128]; int unlink_path = 0; long page_size; int pages; /* If core log request, then argv[0] will be region_size */ if (!strtoll(argv[0], &p, 0) || *p) { disk_log = 1; if ((argc < 2) || (argc > 4)) { LOG_ERROR("Too %s arguments to clustered-disk log type", (argc < 3) ? "few" : "many"); r = -EINVAL; goto fail; } r = find_disk_path(argv[0], disk_path, &unlink_path); if (r) { LOG_ERROR("Unable to find path to device %s", argv[0]); goto fail; } LOG_DBG("Clustered log disk is %s", disk_path); } else { disk_log = 0; if ((argc < 1) || (argc > 3)) { LOG_ERROR("Too %s arguments to clustered-core log type", (argc < 2) ? "few" : "many"); r = -EINVAL; goto fail; } } if (!(region_size = strtoll(argv[disk_log], &p, 0)) || *p) { LOG_ERROR("Invalid region_size argument to clustered-%s log type", (disk_log) ? "disk" : "core"); r = -EINVAL; goto fail; } region_count = device_size / region_size; if (device_size % region_size) { /* * I can't remember if device_size must be a multiple * of region_size, so check it anyway. */ region_count++; } for (i = 0; i < argc; i++) { if (!strcmp(argv[i], "sync")) log_sync = FORCESYNC; else if (!strcmp(argv[i], "nosync")) log_sync = NOSYNC; else if (!strcmp(argv[i], "block_on_error")) block_on_error = 1; } lc = dm_zalloc(sizeof(*lc)); if (!lc) { LOG_ERROR("Unable to allocate cluster log context"); r = -ENOMEM; goto fail; } lc->region_size = region_size; lc->region_count = region_count; lc->sync = log_sync; lc->block_on_error = block_on_error; lc->sync_search = 0; lc->recovering_region = (uint64_t)-1; lc->skip_bit_warning = region_count; lc->disk_fd = -1; lc->log_dev_failed = 0; strncpy(lc->uuid, uuid, DM_UUID_LEN); lc->luid = luid; if (get_log(lc->uuid, lc->luid) || get_pending_log(lc->uuid, lc->luid)) { LOG_ERROR("[%s/%" PRIu64 "u] Log already exists, unable to create.", SHORT_UUID(lc->uuid), lc->luid); dm_free(lc); return -EINVAL; } dm_list_init(&lc->mark_list); lc->clean_bits = dm_bitset_create(NULL, region_count); if (!lc->clean_bits) { LOG_ERROR("Unable to allocate clean bitset"); r = -ENOMEM; goto fail; } lc->sync_bits = dm_bitset_create(NULL, region_count); if (!lc->sync_bits) { LOG_ERROR("Unable to allocate sync bitset"); r = -ENOMEM; goto fail; } if (log_sync == NOSYNC) dm_bit_set_all(lc->sync_bits); lc->sync_count = (log_sync == NOSYNC) ? region_count : 0; if (disk_log) { if ((page_size = sysconf(_SC_PAGESIZE)) < 0) { LOG_ERROR("Unable to read pagesize: %s", strerror(errno)); r = errno; goto fail; } pages = *(lc->clean_bits) / page_size; pages += *(lc->clean_bits) % page_size ? 1 : 0; pages += 1; /* for header */ r = open(disk_path, O_RDWR | O_DIRECT); if (r < 0) { LOG_ERROR("Unable to open log device, %s: %s", disk_path, strerror(errno)); r = errno; goto fail; } if (unlink_path) if (unlink(disk_path) < 0) { LOG_DBG("Warning: Unable to unlink log device, %s: %s", disk_path, strerror(errno)); } lc->disk_fd = r; lc->disk_size = pages * page_size; r = posix_memalign(&(lc->disk_buffer), page_size, lc->disk_size); if (r) { LOG_ERROR("Unable to allocate memory for disk_buffer"); goto fail; } memset(lc->disk_buffer, 0, lc->disk_size); LOG_DBG("Disk log ready"); } dm_list_add(&log_pending_list, &lc->list); return 0; fail: if (lc) { if (lc->disk_fd >= 0 && close(lc->disk_fd)) LOG_ERROR("Close device error, %s: %s", disk_path, strerror(errno)); free(lc->disk_buffer); dm_free(lc->sync_bits); dm_free(lc->clean_bits); dm_free(lc); } return r; } /* * clog_ctr * @rq * * rq->data should contain constructor string as follows: * [disk] [[no]sync] * The kernel is responsible for adding the argument * to the end; otherwise, we cannot compute the region_count. * * FIXME: Currently relies on caller to fill in rq->error */ static int clog_dtr(struct dm_ulog_request *rq); static int clog_ctr(struct dm_ulog_request *rq) { int argc, i, r = 0; char *p, **argv = NULL; char *dev_size_str; uint64_t device_size; /* Sanity checks */ if (!rq->data_size) { LOG_ERROR("Received constructor request with no data"); return -EINVAL; } if (strlen(rq->data) > rq->data_size) { LOG_ERROR("Received constructor request with bad data"); LOG_ERROR("strlen(rq->data)[%d] != rq->data_size[%llu]", (int)strlen(rq->data), (unsigned long long)rq->data_size); LOG_ERROR("rq->data = '%s' [%d]", rq->data, (int)strlen(rq->data)); return -EINVAL; } /* Split up args */ for (argc = 0, p = rq->data; (p = strstr(p, " ")); p++, argc++) *p = '\0'; argv = malloc(argc * sizeof(char *)); if (!argv) return -ENOMEM; p = dev_size_str = rq->data; p += strlen(p) + 1; for (i = 0; i < argc; i++, p = p + strlen(p) + 1) argv[i] = p; if (strcmp(argv[0], "clustered-disk") && strcmp(argv[0], "clustered-core")) { LOG_ERROR("Unsupported userspace log type, \"%s\"", argv[0]); free(argv); return -EINVAL; } if (!(device_size = strtoll(dev_size_str, &p, 0)) || *p) { LOG_ERROR("Invalid device size argument: %s", dev_size_str); free(argv); return -EINVAL; } r = _clog_ctr(rq->uuid, rq->luid, argc - 1, argv + 1, device_size); /* We join the CPG when we resume */ /* No returning data */ if ((rq->version > 1) && !strcmp(argv[0], "clustered-disk")) rq->data_size = sprintf(rq->data, "%s", argv[1]) + 1; else rq->data_size = 0; if (r) { LOG_ERROR("Failed to create cluster log (%s)", rq->uuid); for (i = 0; i < argc; i++) LOG_ERROR("argv[%d] = %s", i, argv[i]); } else LOG_DBG("[%s] Cluster log created", SHORT_UUID(rq->uuid)); free(argv); return r; } /* * clog_dtr * @rq * */ static int clog_dtr(struct dm_ulog_request *rq) { struct log_c *lc = get_log(rq->uuid, rq->luid); if (lc) { /* * The log should not be on the official list. There * should have been a suspend first. */ LOG_ERROR("[%s] DTR before SUS: leaving CPG", SHORT_UUID(rq->uuid)); destroy_cluster_cpg(rq->uuid); } else if (!(lc = get_pending_log(rq->uuid, rq->luid))) { LOG_ERROR("clog_dtr called on log that is not official or pending"); return -EINVAL; } LOG_DBG("[%s] Cluster log removed", SHORT_UUID(lc->uuid)); dm_list_del(&lc->list); if (lc->disk_fd != -1 && close(lc->disk_fd)) LOG_ERROR("Failed to close disk log: %s", strerror(errno)); if (lc->disk_buffer) free(lc->disk_buffer); dm_free(lc->clean_bits); dm_free(lc->sync_bits); dm_free(lc); return 0; } /* * clog_presuspend * @rq * */ static int clog_presuspend(struct dm_ulog_request *rq) { struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (lc->touched) LOG_DBG("WARNING: log still marked as 'touched' during suspend"); lc->recovery_halted = 1; return 0; } /* * clog_postsuspend * @rq * */ static int clog_postsuspend(struct dm_ulog_request *rq) { struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; LOG_DBG("[%s] clog_postsuspend: leaving CPG", SHORT_UUID(lc->uuid)); destroy_cluster_cpg(rq->uuid); lc->state = LOG_SUSPENDED; lc->recovering_region = (uint64_t)-1; lc->recoverer = (uint32_t)-1; lc->delay = time(NULL); return 0; } /* * cluster_postsuspend * @rq * */ int cluster_postsuspend(char *uuid, uint64_t luid) { struct log_c *lc = get_log(uuid, luid); if (!lc) return -EINVAL; LOG_DBG("[%s] clog_postsuspend: finalizing", SHORT_UUID(lc->uuid)); lc->resume_override = 0; /* move log to pending list */ dm_list_del(&lc->list); dm_list_add(&log_pending_list, &lc->list); return 0; } /* * clog_resume * @rq * * Does the main work of resuming. */ static int clog_resume(struct dm_ulog_request *rq) { uint32_t i; int commit_log = 0; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; lc->in_sync = 0; switch (lc->resume_override) { case 1000: LOG_ERROR("[%s] Additional resume issued before suspend", SHORT_UUID(rq->uuid)); #ifdef DEBUG kill(getpid(), SIGUSR1); #endif return 0; case 0: lc->resume_override = 1000; if (lc->disk_fd == -1) { LOG_DBG("[%s] Master resume.", SHORT_UUID(lc->uuid)); goto no_disk; } LOG_DBG("[%s] Master resume: reading disk log", SHORT_UUID(lc->uuid)); commit_log = 1; break; case 1: LOG_ERROR("Error:: partial bit loading (just sync_bits)"); return -EINVAL; case 2: LOG_ERROR("Error:: partial bit loading (just clean_bits)"); return -EINVAL; case 3: LOG_DBG("[%s] Non-master resume: bits pre-loaded", SHORT_UUID(lc->uuid)); lc->resume_override = 1000; goto out; default: LOG_ERROR("Error:: multiple loading of bits (%d)", lc->resume_override); return -EINVAL; } if (lc->log_dev_failed) { LOG_ERROR("Log device has failed, unable to read bits"); rq->error = 0; /* We can handle this so far */ lc->disk_nr_regions = 0; } else rq->error = read_log(lc); switch (rq->error) { case 0: if (lc->disk_nr_regions < lc->region_count) LOG_DBG("[%s] Mirror has grown, updating log bits", SHORT_UUID(lc->uuid)); else if (lc->disk_nr_regions > lc->region_count) LOG_DBG("[%s] Mirror has shrunk, updating log bits", SHORT_UUID(lc->uuid)); break; case -EINVAL: LOG_DBG("[%s] (Re)initializing mirror log - resync issued.", SHORT_UUID(lc->uuid)); lc->disk_nr_regions = 0; break; default: LOG_ERROR("Failed to read disk log"); lc->disk_nr_regions = 0; break; } no_disk: /* If mirror has grown, set bits appropriately */ if (lc->sync == NOSYNC) for (i = lc->disk_nr_regions; i < lc->region_count; i++) log_set_bit(lc, lc->clean_bits, i); else for (i = lc->disk_nr_regions; i < lc->region_count; i++) log_clear_bit(lc, lc->clean_bits, i); /* Clear any old bits if device has shrunk */ for (i = lc->region_count; i % 32; i++) log_clear_bit(lc, lc->clean_bits, i); /* copy clean across to sync */ dm_bit_copy(lc->sync_bits, lc->clean_bits); if (commit_log && (lc->disk_fd >= 0)) { rq->error = write_log(lc); if (rq->error) LOG_ERROR("Failed initial disk log write"); else LOG_DBG("Disk log initialized"); lc->touched = 0; } out: /* * Clear any old bits if device has shrunk - necessary * for non-master resume */ for (i = lc->region_count; i % 32; i++) { log_clear_bit(lc, lc->clean_bits, i); log_clear_bit(lc, lc->sync_bits, i); } lc->sync_count = count_bits32(lc->sync_bits); LOG_SPRINT(lc, "[%s] Initial sync_count = %llu", SHORT_UUID(lc->uuid), (unsigned long long)lc->sync_count); lc->sync_search = 0; lc->state = LOG_RESUMED; lc->recovery_halted = 0; return rq->error; } /* * local_resume * @rq * * If the log is pending, we must first join the cpg and * put the log in the official list. * */ int local_resume(struct dm_ulog_request *rq) { int r; time_t t; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) { /* Is the log in the pending list? */ lc = get_pending_log(rq->uuid, rq->luid); if (!lc) { LOG_ERROR("clog_resume called on log that is not official or pending"); return -EINVAL; } t = time(NULL); t -= lc->delay; /* * This should be considered a temporary fix. It addresses * a problem that exists when nodes suspend/resume in rapid * succession. While the problem is very rare, it has been * seen to happen in real-world-like testing. * * The problem: * - Node A joins cluster * - Node B joins cluster * - Node A prepares checkpoint * - Node A gets ready to write checkpoint * - Node B leaves * - Node B joins * - Node A finishes write of checkpoint * - Node B receives checkpoint meant for previous session * -- Node B can now be non-coherent * * This timer will solve the problem for now, but could be * replaced by a generation number sent with the resume * command from the kernel. The generation number would * be included in the name of the checkpoint to prevent * reading stale data. */ if ((t < 3) && (t >= 0)) sleep(3 - t); /* Join the CPG */ r = create_cluster_cpg(rq->uuid, rq->luid); if (r) { LOG_ERROR("clog_resume: Failed to create cluster CPG"); return r; } /* move log to official list */ dm_list_del(&lc->list); dm_list_add(&log_list, &lc->list); } return 0; } /* * clog_get_region_size * @rq * * Since this value doesn't change, the kernel * should not need to talk to server to get this * The function is here for completness * * Returns: 0 on success, -EXXX on failure */ static int clog_get_region_size(struct dm_ulog_request *rq) { uint64_t *rtn = (uint64_t *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc && !(lc = get_pending_log(rq->uuid, rq->luid))) return -EINVAL; *rtn = lc->region_size; rq->data_size = sizeof(*rtn); return 0; } /* * clog_is_clean * @rq * * Returns: 1 if clean, 0 otherwise */ static int clog_is_clean(struct dm_ulog_request *rq) { int64_t *rtn = (int64_t *)rq->data; uint64_t *region = (uint64_t *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; *rtn = log_test_bit(lc->clean_bits, *region); rq->data_size = sizeof(*rtn); return 0; } /* * clog_in_sync * @rq * * We ignore any request for non-block. That * should be handled elsewhere. (If the request * has come this far, it has already blocked.) * * Returns: 1 if in-sync, 0 otherwise */ static int clog_in_sync(struct dm_ulog_request *rq) { int64_t *rtn = (int64_t *)rq->data; uint64_t *region_p = (uint64_t *)rq->data; uint64_t region = *region_p; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (region > lc->region_count) return -EINVAL; *rtn = log_test_bit(lc->sync_bits, region); /* * If the mirror was successfully recovered, we want to always * force every machine to write to all devices - otherwise, * corruption will occur. Here's how: * Node1 suffers a failure and marks a region out-of-sync * Node2 attempts a write, gets by is_remote_recovering, * and queries the sync status of the region - finding * it out-of-sync. * Node2 thinks the write should be a nosync write, but it * hasn't suffered the drive failure that Node1 has yet. * It then issues a generic_make_request directly to * the primary image only - which is exactly the device * that has suffered the failure. * Node2 suffers a lost write - which completely bypasses the * mirror layer because it had gone through generic_m_r. * The file system will likely explode at this point due to * I/O errors. If it wasn't the primary that failed, it is * easily possible in this case to issue writes to just one * of the remaining images - also leaving the mirror inconsistent. * * We let in_sync() return 1 in a cluster regardless of what is * in the bitmap once recovery has successfully completed on a * mirror. This ensures the mirroring code will continue to * attempt to write to all mirror images. The worst that can * happen for reads is that additional read attempts may be * taken. * * Futher investigation may be required to determine if there are * similar possible outcomes when the mirror is in the process of * recovering. In that case, lc->in_sync would not have been set * yet. */ if (!*rtn && lc->in_sync) *rtn = 1; if (*rtn) LOG_DBG("[%s] Region is in-sync: %llu", SHORT_UUID(lc->uuid), (unsigned long long)region); else LOG_DBG("[%s] Region is not in-sync: %llu", SHORT_UUID(lc->uuid), (unsigned long long)region); rq->data_size = sizeof(*rtn); return 0; } /* * clog_flush * @rq * */ static int clog_flush(struct dm_ulog_request *rq, int server) { int r = 0; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (!lc->touched) return 0; /* * Do the actual flushing of the log only * if we are the server. */ if (server && (lc->disk_fd >= 0)) { r = rq->error = write_log(lc); if (r) LOG_ERROR("[%s] Error writing to disk log", SHORT_UUID(lc->uuid)); else LOG_DBG("[%s] Disk log written", SHORT_UUID(lc->uuid)); } lc->touched = 0; return r; } /* * mark_region * @lc * @region * @who * * Put a mark region request in the tree for tracking. * * Returns: 0 on success, -EXXX on error */ static int mark_region(struct log_c *lc, uint64_t region, uint32_t who) { int found = 0; struct mark_entry *m; dm_list_iterate_items(m, &lc->mark_list) if (m->region == region) { found = 1; if (m->nodeid == who) return 0; } if (!found) log_clear_bit(lc, lc->clean_bits, region); /* * Save allocation until here - if there is a failure, * at least we have cleared the bit. */ m = malloc(sizeof(*m)); if (!m) { LOG_ERROR("Unable to allocate space for mark_entry: %llu/%u", (unsigned long long)region, who); return -ENOMEM; } m->nodeid = who; m->region = region; dm_list_add(&lc->mark_list, &m->list); return 0; } /* * clog_mark_region * @rq * * rq may contain more than one mark request. We * can determine the number from the 'data_size' field. * * Returns: 0 on success, -EXXX on failure */ static int clog_mark_region(struct dm_ulog_request *rq, uint32_t originator) { int r; int count; uint64_t *region; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (rq->data_size % sizeof(uint64_t)) { LOG_ERROR("Bad data size given for mark_region request"); return -EINVAL; } count = rq->data_size / sizeof(uint64_t); region = (uint64_t *)&rq->data; for (; count > 0; count--, region++) { r = mark_region(lc, *region, originator); if (r) return r; } rq->data_size = 0; return 0; } static int clear_region(struct log_c *lc, uint64_t region, uint32_t who) { int other_matches = 0; struct mark_entry *m, *n; dm_list_iterate_items_safe(m, n, &lc->mark_list) if (m->region == region) { if (m->nodeid == who) { dm_list_del(&m->list); free(m); } else other_matches = 1; } /* * Clear region if: * 1) It is in-sync * 2) There are no other machines that have it marked */ if (!other_matches && log_test_bit(lc->sync_bits, region)) log_set_bit(lc, lc->clean_bits, region); return 0; } /* * clog_clear_region * @rq * * rq may contain more than one clear request. We * can determine the number from the 'data_size' field. * * Returns: 0 on success, -EXXX on failure */ static int clog_clear_region(struct dm_ulog_request *rq, uint32_t originator) { int r; int count; uint64_t *region; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (rq->data_size % sizeof(uint64_t)) { LOG_ERROR("Bad data size given for clear_region request"); return -EINVAL; } count = rq->data_size / sizeof(uint64_t); region = (uint64_t *)&rq->data; for (; count > 0; count--, region++) { r = clear_region(lc, *region, originator); if (r) return r; } rq->data_size = 0; return 0; } /* * clog_get_resync_work * @rq * */ static int clog_get_resync_work(struct dm_ulog_request *rq, uint32_t originator) { struct { int64_t i; uint64_t r; } *pkg = (void *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; rq->data_size = sizeof(*pkg); pkg->i = 0; if (lc->sync_search >= lc->region_count) { /* * FIXME: handle intermittent errors during recovery * by resetting sync_search... but not to many times. */ LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Recovery finished", rq->seq, SHORT_UUID(lc->uuid), originator); return 0; } if (lc->recovering_region != (uint64_t)-1) { if (lc->recoverer == originator) { LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Re-requesting work (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)lc->recovering_region); pkg->r = lc->recovering_region; pkg->i = 1; LOG_COND(log_resend_requests, "***** RE-REQUEST *****"); } else { LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Someone already recovering (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)lc->recovering_region); } return 0; } while (lc->recovery_request_list) { struct recovery_request *del; del = lc->recovery_request_list; lc->recovery_request_list = del->next; pkg->r = del->region; free(del); if (!log_test_bit(lc->sync_bits, pkg->r)) { LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Assigning priority resync work (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)pkg->r); pkg->i = 1; lc->recovering_region = pkg->r; lc->recoverer = originator; return 0; } } pkg->r = find_next_zero_bit(lc->sync_bits, lc->sync_search); if (pkg->r >= lc->region_count) { LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Resync work complete.", rq->seq, SHORT_UUID(lc->uuid), originator); lc->sync_search = lc->region_count + 1; return 0; } lc->sync_search = pkg->r + 1; LOG_SPRINT(lc, "GET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Assigning resync work (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)pkg->r); pkg->i = 1; lc->recovering_region = pkg->r; lc->recoverer = originator; return 0; } /* * clog_set_region_sync * @rq */ static int clog_set_region_sync(struct dm_ulog_request *rq, uint32_t originator) { struct { uint64_t region; int64_t in_sync; } *pkg = (void *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; lc->recovering_region = (uint64_t)-1; if (pkg->in_sync) { if (log_test_bit(lc->sync_bits, pkg->region)) { LOG_SPRINT(lc, "SET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Region already set (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)pkg->region); } else { log_set_bit(lc, lc->sync_bits, pkg->region); lc->sync_count++; /* The rest of this section is all for debugging */ LOG_SPRINT(lc, "SET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Setting region (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)pkg->region); if (pkg->region == lc->skip_bit_warning) lc->skip_bit_warning = lc->region_count; if (pkg->region > (lc->skip_bit_warning + 5)) { LOG_SPRINT(lc, "*** Region #%llu skipped during recovery ***", (unsigned long long)lc->skip_bit_warning); lc->skip_bit_warning = lc->region_count; #ifdef DEBUG kill(getpid(), SIGUSR1); #endif } if (!log_test_bit(lc->sync_bits, (pkg->region) ? pkg->region - 1 : 0)) { LOG_SPRINT(lc, "*** Previous bit not set ***"); lc->skip_bit_warning = (pkg->region) ? pkg->region - 1 : 0; } } } else if (log_test_bit(lc->sync_bits, pkg->region)) { lc->sync_count--; log_clear_bit(lc, lc->sync_bits, pkg->region); LOG_SPRINT(lc, "SET - SEQ#=%u, UUID=%s, nodeid = %u:: " "Unsetting region (%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)pkg->region); } if (lc->sync_count != count_bits32(lc->sync_bits)) { unsigned long long reset = count_bits32(lc->sync_bits); LOG_SPRINT(lc, "SET - SEQ#=%u, UUID=%s, nodeid = %u:: " "sync_count(%llu) != bitmap count(%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)lc->sync_count, reset); #ifdef DEBUG kill(getpid(), SIGUSR1); #endif lc->sync_count = reset; } if (lc->sync_count > lc->region_count) LOG_SPRINT(lc, "SET - SEQ#=%u, UUID=%s, nodeid = %u:: " "(lc->sync_count > lc->region_count) - this is bad", rq->seq, SHORT_UUID(lc->uuid), originator); if (lc->sync_count == lc->region_count) lc->in_sync = 1; rq->data_size = 0; return 0; } /* * clog_get_sync_count * @rq */ static int clog_get_sync_count(struct dm_ulog_request *rq, uint32_t originator) { uint64_t *sync_count = (uint64_t *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); /* * FIXME: Mirror requires us to be able to ask for * the sync count while pending... but I don't like * it because other machines may not be suspended and * the stored value may not be accurate. */ if (!lc) lc = get_pending_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; *sync_count = lc->sync_count; rq->data_size = sizeof(*sync_count); if (lc->sync_count != count_bits32(lc->sync_bits)) { unsigned long long reset = count_bits32(lc->sync_bits); LOG_SPRINT(lc, "get_sync_count - SEQ#=%u, UUID=%s, nodeid = %u:: " "sync_count(%llu) != bitmap count(%llu)", rq->seq, SHORT_UUID(lc->uuid), originator, (unsigned long long)lc->sync_count, reset); #ifdef DEBUG kill(getpid(), SIGUSR1); #endif lc->sync_count = reset; } return 0; } static int core_status_info(struct log_c *lc __attribute__((unused)), struct dm_ulog_request *rq) { int r; char *data = (char *)rq->data; r = sprintf(data, "1 clustered-core"); if (r < 0) return r; rq->data_size = r; return 0; } static int disk_status_info(struct log_c *lc, struct dm_ulog_request *rq) { int r; char *data = (char *)rq->data; struct stat statbuf; if(fstat(lc->disk_fd, &statbuf)) { rq->error = -errno; return -errno; } r = sprintf(data, "3 clustered-disk %d:%d %c", major(statbuf.st_rdev), minor(statbuf.st_rdev), (lc->log_dev_failed) ? 'D' : 'A'); if (r < 0) return r; rq->data_size = r; return 0; } /* * clog_status_info * @rq * */ static int clog_status_info(struct dm_ulog_request *rq) { int r; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) lc = get_pending_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (lc->disk_fd == -1) r = core_status_info(lc, rq); else r = disk_status_info(lc, rq); return r; } static int core_status_table(struct log_c *lc, struct dm_ulog_request *rq) { int r; char *data = (char *)rq->data; r = sprintf(data, "clustered-core %u %s%s ", lc->region_size, (lc->sync == DEFAULTSYNC) ? "" : (lc->sync == NOSYNC) ? "nosync " : "sync ", (lc->block_on_error) ? "block_on_error" : ""); if (r < 0) return r; rq->data_size = r; return 0; } static int disk_status_table(struct log_c *lc, struct dm_ulog_request *rq) { int r; char *data = (char *)rq->data; struct stat statbuf; if(fstat(lc->disk_fd, &statbuf)) { rq->error = -errno; return -errno; } r = sprintf(data, "clustered-disk %d:%d %u %s%s ", major(statbuf.st_rdev), minor(statbuf.st_rdev), lc->region_size, (lc->sync == DEFAULTSYNC) ? "" : (lc->sync == NOSYNC) ? "nosync " : "sync ", (lc->block_on_error) ? "block_on_error" : ""); if (r < 0) return r; rq->data_size = r; return 0; } /* * clog_status_table * @rq * */ static int clog_status_table(struct dm_ulog_request *rq) { int r; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) lc = get_pending_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (lc->disk_fd == -1) r = core_status_table(lc, rq); else r = disk_status_table(lc, rq); return r; } /* * clog_is_remote_recovering * @rq * */ static int clog_is_remote_recovering(struct dm_ulog_request *rq) { uint64_t *region_p = (uint64_t *)rq->data; uint64_t region = *region_p; struct { int64_t is_recovering; uint64_t in_sync_hint; } *pkg = (void *)rq->data; struct log_c *lc = get_log(rq->uuid, rq->luid); if (!lc) return -EINVAL; if (region > lc->region_count) return -EINVAL; if (lc->recovery_halted) { LOG_DBG("[%s] Recovery halted... [not remote recovering]: %llu", SHORT_UUID(lc->uuid), (unsigned long long)region); pkg->is_recovering = 0; pkg->in_sync_hint = lc->region_count; /* none are recovering */ } else { pkg->is_recovering = !log_test_bit(lc->sync_bits, region); /* * Remember, 'lc->sync_search' is 1 plus the region * currently being recovered. So, we must take off 1 * to account for that; but only if 'sync_search > 1'. */ pkg->in_sync_hint = lc->sync_search ? (lc->sync_search - 1) : 0; LOG_DBG("[%s] Region is %s: %llu", SHORT_UUID(lc->uuid), (region == lc->recovering_region) ? "currently remote recovering" : (pkg->is_recovering) ? "pending remote recovery" : "not remote recovering", (unsigned long long)region); } if (pkg->is_recovering && (region != lc->recovering_region)) { struct recovery_request *rr; /* Already in the list? */ for (rr = lc->recovery_request_list; rr; rr = rr->next) if (rr->region == region) goto out; /* Failure to allocated simply means we can't prioritize it */ rr = malloc(sizeof(*rr)); if (!rr) goto out; LOG_DBG("[%s] Adding region to priority list: %llu", SHORT_UUID(lc->uuid), (unsigned long long)region); rr->region = region; rr->next = lc->recovery_request_list; lc->recovery_request_list = rr; } out: rq->data_size = sizeof(*pkg); return 0; } /* * do_request * @rq: the request * @server: is this request performed by the server * * An inability to perform this function will return an error * from this function. However, an inability to successfully * perform the request will fill in the 'rq->error' field. * * 'rq' (or more correctly, rq->u_rq.data) should be of sufficient * size to hold any returning data. Currently, local.c uses 2kiB * to hold 'rq' - leaving ~1.5kiB for return data... more than * enough for all the implemented functions here. * * Returns: 0 on success, -EXXX on error */ int do_request(struct clog_request *rq, int server) { int r; if (!rq) return 0; if (rq->u_rq.error) LOG_DBG("Programmer error: rq struct has error set"); switch (rq->u_rq.request_type) { case DM_ULOG_CTR: r = clog_ctr(&rq->u_rq); break; case DM_ULOG_DTR: r = clog_dtr(&rq->u_rq); break; case DM_ULOG_PRESUSPEND: r = clog_presuspend(&rq->u_rq); break; case DM_ULOG_POSTSUSPEND: r = clog_postsuspend(&rq->u_rq); break; case DM_ULOG_RESUME: r = clog_resume(&rq->u_rq); break; case DM_ULOG_GET_REGION_SIZE: r = clog_get_region_size(&rq->u_rq); break; case DM_ULOG_IS_CLEAN: r = clog_is_clean(&rq->u_rq); break; case DM_ULOG_IN_SYNC: r = clog_in_sync(&rq->u_rq); break; case DM_ULOG_FLUSH: r = clog_flush(&rq->u_rq, server); break; case DM_ULOG_MARK_REGION: r = clog_mark_region(&rq->u_rq, rq->originator); break; case DM_ULOG_CLEAR_REGION: r = clog_clear_region(&rq->u_rq, rq->originator); break; case DM_ULOG_GET_RESYNC_WORK: r = clog_get_resync_work(&rq->u_rq, rq->originator); break; case DM_ULOG_SET_REGION_SYNC: r = clog_set_region_sync(&rq->u_rq, rq->originator); break; case DM_ULOG_GET_SYNC_COUNT: r = clog_get_sync_count(&rq->u_rq, rq->originator); break; case DM_ULOG_STATUS_INFO: r = clog_status_info(&rq->u_rq); break; case DM_ULOG_STATUS_TABLE: r = clog_status_table(&rq->u_rq); break; case DM_ULOG_IS_REMOTE_RECOVERING: r = clog_is_remote_recovering(&rq->u_rq); break; default: LOG_ERROR("Unknown request"); r = rq->u_rq.error = -EINVAL; break; } if (r && !rq->u_rq.error) rq->u_rq.error = r; else if (r != rq->u_rq.error) LOG_DBG("Warning: error from function != rq->u_rq.error"); if (rq->u_rq.error && rq->u_rq.data_size) { /* Make sure I'm handling errors correctly above */ LOG_DBG("Programmer error: rq->u_rq.error && rq->u_rq.data_size"); rq->u_rq.data_size = 0; } return 0; } static void print_bits(dm_bitset_t bs, int print) { int i, size; char outbuf[128] = { 0 }; unsigned char *buf = (unsigned char *)(bs + 1); size = (*bs % 8) ? 1 : 0; size += (*bs / 8); for (i = 0; i < size; i++) { if (!(i % 16)) { if (outbuf[0] != '\0') { if (print) LOG_PRINT("%s", outbuf); else LOG_DBG("%s", outbuf); } memset(outbuf, 0, sizeof(outbuf)); sprintf(outbuf, "[%3d - %3d]", i, i+15); } sprintf(outbuf + strlen(outbuf), " %.2X", (unsigned char)buf[i]); } if (outbuf[0] != '\0') { if (print) LOG_PRINT("%s", outbuf); else LOG_DBG("%s", outbuf); } } /* int store_bits(const char *uuid, const char *which, char **buf)*/ int push_state(const char *uuid, uint64_t luid, const char *which, char **buf, uint32_t debug_who) { int bitset_size; struct log_c *lc; if (*buf) LOG_ERROR("store_bits: *buf != NULL"); lc = get_log(uuid, luid); if (!lc) { LOG_ERROR("store_bits: No log found for %s", uuid); return -EINVAL; } if (!strcmp(which, "recovering_region")) { *buf = malloc(64); /* easily handles the 2 written numbers */ if (!*buf) return -ENOMEM; sprintf(*buf, "%llu %u", (unsigned long long)lc->recovering_region, lc->recoverer); LOG_SPRINT(lc, "CKPT SEND - SEQ#=X, UUID=%s, nodeid = %u:: " "recovering_region=%llu, recoverer=%u, sync_count=%llu", SHORT_UUID(lc->uuid), debug_who, (unsigned long long)lc->recovering_region, lc->recoverer, (unsigned long long)count_bits32(lc->sync_bits)); return 64; } /* Size in 'int's */ bitset_size = (*(lc->clean_bits) / DM_BITS_PER_INT) + 1; /* Size in bytes */ bitset_size *= 4; *buf = malloc(bitset_size); if (!*buf) { LOG_ERROR("store_bits: Unable to allocate memory"); return -ENOMEM; } if (!strncmp(which, "sync_bits", 9)) { memcpy(*buf, lc->sync_bits + 1, bitset_size); LOG_DBG("[%s] storing sync_bits (sync_count = %llu):", SHORT_UUID(uuid), (unsigned long long) count_bits32(lc->sync_bits)); print_bits(lc->sync_bits, 0); } else if (!strncmp(which, "clean_bits", 9)) { memcpy(*buf, lc->clean_bits + 1, bitset_size); LOG_DBG("[%s] storing clean_bits:", SHORT_UUID(lc->uuid)); print_bits(lc->clean_bits, 0); } return bitset_size; } /*int load_bits(const char *uuid, const char *which, char *buf, int size)*/ int pull_state(const char *uuid, uint64_t luid, const char *which, char *buf, int size) { int bitset_size; struct log_c *lc; if (!buf) { LOG_ERROR("pull_state: buf == NULL"); return -EINVAL; } lc = get_log(uuid, luid); if (!lc) { LOG_ERROR("pull_state: No log found for %s", uuid); return -EINVAL; } if (!strncmp(which, "recovering_region", 17)) { if (sscanf(buf, "%llu %u", (unsigned long long *)&lc->recovering_region, &lc->recoverer) != 2) { LOG_ERROR("cannot parse recovering region from: %s", buf); return -EINVAL; } LOG_SPRINT(lc, "CKPT INIT - SEQ#=X, UUID=%s, nodeid = X:: " "recovering_region=%llu, recoverer=%u", SHORT_UUID(lc->uuid), (unsigned long long)lc->recovering_region, lc->recoverer); return 0; } /* Size in 'int's */ bitset_size = (*(lc->clean_bits) /DM_BITS_PER_INT) + 1; /* Size in bytes */ bitset_size *= 4; if (bitset_size != size) { LOG_ERROR("pull_state(%s): bad bitset_size (%d vs %d)", which, size, bitset_size); return -EINVAL; } if (!strncmp(which, "sync_bits", 9)) { lc->resume_override += 1; memcpy(lc->sync_bits + 1, buf, bitset_size); LOG_DBG("[%s] loading sync_bits (sync_count = %llu):", SHORT_UUID(lc->uuid),(unsigned long long) count_bits32(lc->sync_bits)); print_bits(lc->sync_bits, 0); } else if (!strncmp(which, "clean_bits", 9)) { lc->resume_override += 2; memcpy(lc->clean_bits + 1, buf, bitset_size); LOG_DBG("[%s] loading clean_bits:", SHORT_UUID(lc->uuid)); print_bits(lc->clean_bits, 0); } return 0; } int log_get_state(struct dm_ulog_request *rq) { struct log_c *lc; lc = get_log(rq->uuid, rq->luid); if (!lc) /* FIXME Callers are ignoring this */ return -EINVAL; return (int)lc->state; } /* * log_status * * Returns: 1 if logs are still present, 0 otherwise */ int log_status(void) { if (!dm_list_empty(&log_list) || !dm_list_empty(&log_pending_list)) return 1; return 0; } void log_debug(void) { struct log_c *lc; uint64_t r; int i; LOG_ERROR(""); LOG_ERROR("LOG COMPONENT DEBUGGING::"); LOG_ERROR("Official log list:"); LOG_ERROR("Pending log list:"); dm_list_iterate_items(lc, &log_pending_list) { LOG_ERROR("%s", lc->uuid); LOG_ERROR("sync_bits:"); print_bits(lc->sync_bits, 1); LOG_ERROR("clean_bits:"); print_bits(lc->clean_bits, 1); } dm_list_iterate_items(lc, &log_list) { LOG_ERROR("%s", lc->uuid); LOG_ERROR(" recoverer : %" PRIu32, lc->recoverer); LOG_ERROR(" recovering_region: %" PRIu64, lc->recovering_region); LOG_ERROR(" recovery_halted : %s", (lc->recovery_halted) ? "YES" : "NO"); LOG_ERROR("sync_bits:"); print_bits(lc->sync_bits, 1); LOG_ERROR("clean_bits:"); print_bits(lc->clean_bits, 1); LOG_ERROR("Validating %s::", SHORT_UUID(lc->uuid)); r = find_next_zero_bit(lc->sync_bits, 0); LOG_ERROR(" lc->region_count = %" PRIu32, lc->region_count); LOG_ERROR(" lc->sync_count = %" PRIu64, lc->sync_count); LOG_ERROR(" next zero bit = %" PRIu64, r); if ((r > lc->region_count) || ((r == lc->region_count) && (lc->sync_count > lc->region_count))) { LOG_ERROR("ADJUSTING SYNC_COUNT"); lc->sync_count = lc->region_count; } LOG_ERROR("Resync request history:"); for (i = 0; i < RESYNC_HISTORY; i++) { lc->idx++; lc->idx = lc->idx % RESYNC_HISTORY; if (lc->resync_history[lc->idx][0] == '\0') continue; LOG_ERROR("%d:%d) %s", i, lc->idx, lc->resync_history[lc->idx]); } } }