Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucom/@/geom/raid/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/ucom/@/geom/raid/md_promise.c |
/*- * Copyright (c) 2011 Alexander Motin <mav@FreeBSD.org> * Copyright (c) 2000 - 2008 Søren Schmidt <sos@FreeBSD.org> * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/geom/raid/md_promise.c 240558 2012-09-16 11:02:22Z mav $"); #include <sys/param.h> #include <sys/bio.h> #include <sys/endian.h> #include <sys/kernel.h> #include <sys/kobj.h> #include <sys/limits.h> #include <sys/lock.h> #include <sys/malloc.h> #include <sys/mutex.h> #include <sys/systm.h> #include <geom/geom.h> #include "geom/raid/g_raid.h" #include "g_raid_md_if.h" static MALLOC_DEFINE(M_MD_PROMISE, "md_promise_data", "GEOM_RAID Promise metadata"); #define PROMISE_MAX_DISKS 8 #define PROMISE_MAX_SUBDISKS 2 #define PROMISE_META_OFFSET 14 struct promise_raid_disk { uint8_t flags; /* Subdisk status. */ #define PROMISE_F_VALID 0x01 #define PROMISE_F_ONLINE 0x02 #define PROMISE_F_ASSIGNED 0x04 #define PROMISE_F_SPARE 0x08 #define PROMISE_F_DUPLICATE 0x10 #define PROMISE_F_REDIR 0x20 #define PROMISE_F_DOWN 0x40 #define PROMISE_F_READY 0x80 uint8_t number; /* Position in a volume. */ uint8_t channel; /* ATA channel number. */ uint8_t device; /* ATA device number. */ uint64_t id __packed; /* Subdisk ID. */ } __packed; struct promise_raid_conf { char promise_id[24]; #define PROMISE_MAGIC "Promise Technology, Inc." #define FREEBSD_MAGIC "FreeBSD ATA driver RAID " uint32_t dummy_0; uint64_t magic_0; #define PROMISE_MAGIC0(x) (((uint64_t)(x.channel) << 48) | \ ((uint64_t)(x.device != 0) << 56)) uint16_t magic_1; uint32_t magic_2; uint8_t filler1[470]; uint32_t integrity; #define PROMISE_I_VALID 0x00000080 struct promise_raid_disk disk; /* This subdisk info. */ uint32_t disk_offset; /* Subdisk offset. */ uint32_t disk_sectors; /* Subdisk size */ uint32_t rebuild_lba; /* Rebuild position. */ uint16_t generation; /* Generation number. */ uint8_t status; /* Volume status. */ #define PROMISE_S_VALID 0x01 #define PROMISE_S_ONLINE 0x02 #define PROMISE_S_INITED 0x04 #define PROMISE_S_READY 0x08 #define PROMISE_S_DEGRADED 0x10 #define PROMISE_S_MARKED 0x20 #define PROMISE_S_MIGRATING 0x40 #define PROMISE_S_FUNCTIONAL 0x80 uint8_t type; /* Voluem type. */ #define PROMISE_T_RAID0 0x00 #define PROMISE_T_RAID1 0x01 #define PROMISE_T_RAID3 0x02 #define PROMISE_T_RAID5 0x04 #define PROMISE_T_SPAN 0x08 #define PROMISE_T_JBOD 0x10 uint8_t total_disks; /* Disks in this volume. */ uint8_t stripe_shift; /* Strip size. */ uint8_t array_width; /* Number of RAID0 stripes. */ uint8_t array_number; /* Global volume number. */ uint32_t total_sectors; /* Volume size. */ uint16_t cylinders; /* Volume geometry: C. */ uint8_t heads; /* Volume geometry: H. */ uint8_t sectors; /* Volume geometry: S. */ uint64_t volume_id __packed; /* Volume ID, */ struct promise_raid_disk disks[PROMISE_MAX_DISKS]; /* Subdisks in this volume. */ char name[32]; /* Volume label. */ uint32_t filler2[8]; uint32_t magic_3; /* Something related to rebuild. */ uint64_t rebuild_lba64; /* Per-volume rebuild position. */ uint32_t magic_4; uint32_t magic_5; uint32_t total_sectors_high; uint32_t filler3[324]; uint32_t checksum; } __packed; struct g_raid_md_promise_perdisk { int pd_updated; int pd_subdisks; struct promise_raid_conf *pd_meta[PROMISE_MAX_SUBDISKS]; }; struct g_raid_md_promise_pervolume { struct promise_raid_conf *pv_meta; uint64_t pv_id; uint16_t pv_generation; int pv_disks_present; int pv_started; struct callout pv_start_co; /* STARTING state timer. */ }; static g_raid_md_create_t g_raid_md_create_promise; static g_raid_md_taste_t g_raid_md_taste_promise; static g_raid_md_event_t g_raid_md_event_promise; static g_raid_md_volume_event_t g_raid_md_volume_event_promise; static g_raid_md_ctl_t g_raid_md_ctl_promise; static g_raid_md_write_t g_raid_md_write_promise; static g_raid_md_fail_disk_t g_raid_md_fail_disk_promise; static g_raid_md_free_disk_t g_raid_md_free_disk_promise; static g_raid_md_free_volume_t g_raid_md_free_volume_promise; static g_raid_md_free_t g_raid_md_free_promise; static kobj_method_t g_raid_md_promise_methods[] = { KOBJMETHOD(g_raid_md_create, g_raid_md_create_promise), KOBJMETHOD(g_raid_md_taste, g_raid_md_taste_promise), KOBJMETHOD(g_raid_md_event, g_raid_md_event_promise), KOBJMETHOD(g_raid_md_volume_event, g_raid_md_volume_event_promise), KOBJMETHOD(g_raid_md_ctl, g_raid_md_ctl_promise), KOBJMETHOD(g_raid_md_write, g_raid_md_write_promise), KOBJMETHOD(g_raid_md_fail_disk, g_raid_md_fail_disk_promise), KOBJMETHOD(g_raid_md_free_disk, g_raid_md_free_disk_promise), KOBJMETHOD(g_raid_md_free_volume, g_raid_md_free_volume_promise), KOBJMETHOD(g_raid_md_free, g_raid_md_free_promise), { 0, 0 } }; static struct g_raid_md_class g_raid_md_promise_class = { "Promise", g_raid_md_promise_methods, sizeof(struct g_raid_md_object), .mdc_enable = 1, .mdc_priority = 100 }; static void g_raid_md_promise_print(struct promise_raid_conf *meta) { int i; if (g_raid_debug < 1) return; printf("********* ATA Promise Metadata *********\n"); printf("promise_id <%.24s>\n", meta->promise_id); printf("disk %02x %02x %02x %02x %016jx\n", meta->disk.flags, meta->disk.number, meta->disk.channel, meta->disk.device, meta->disk.id); printf("disk_offset %u\n", meta->disk_offset); printf("disk_sectors %u\n", meta->disk_sectors); printf("rebuild_lba %u\n", meta->rebuild_lba); printf("generation %u\n", meta->generation); printf("status 0x%02x\n", meta->status); printf("type %u\n", meta->type); printf("total_disks %u\n", meta->total_disks); printf("stripe_shift %u\n", meta->stripe_shift); printf("array_width %u\n", meta->array_width); printf("array_number %u\n", meta->array_number); printf("total_sectors %u\n", meta->total_sectors); printf("cylinders %u\n", meta->cylinders); printf("heads %u\n", meta->heads); printf("sectors %u\n", meta->sectors); printf("volume_id 0x%016jx\n", meta->volume_id); printf("disks:\n"); for (i = 0; i < PROMISE_MAX_DISKS; i++ ) { printf(" %02x %02x %02x %02x %016jx\n", meta->disks[i].flags, meta->disks[i].number, meta->disks[i].channel, meta->disks[i].device, meta->disks[i].id); } printf("name <%.32s>\n", meta->name); printf("magic_3 0x%08x\n", meta->magic_3); printf("rebuild_lba64 %ju\n", meta->rebuild_lba64); printf("magic_4 0x%08x\n", meta->magic_4); printf("magic_5 0x%08x\n", meta->magic_5); printf("total_sectors_high 0x%08x\n", meta->total_sectors_high); printf("=================================================\n"); } static struct promise_raid_conf * promise_meta_copy(struct promise_raid_conf *meta) { struct promise_raid_conf *nmeta; nmeta = malloc(sizeof(*nmeta), M_MD_PROMISE, M_WAITOK); memcpy(nmeta, meta, sizeof(*nmeta)); return (nmeta); } static int promise_meta_find_disk(struct promise_raid_conf *meta, uint64_t id) { int pos; for (pos = 0; pos < meta->total_disks; pos++) { if (meta->disks[pos].id == id) return (pos); } return (-1); } static int promise_meta_unused_range(struct promise_raid_conf **metaarr, int nsd, uint32_t sectors, uint32_t *off, uint32_t *size) { uint32_t coff, csize; int i, j; sectors -= 131072; *off = 0; *size = 0; coff = 0; csize = sectors; i = 0; while (1) { for (j = 0; j < nsd; j++) { if (metaarr[j]->disk_offset >= coff) { csize = MIN(csize, metaarr[j]->disk_offset - coff); } } if (csize > *size) { *off = coff; *size = csize; } if (i >= nsd) break; coff = metaarr[i]->disk_offset + metaarr[i]->disk_sectors; csize = sectors - coff; i++; }; return ((*size > 0) ? 1 : 0); } static int promise_meta_translate_disk(struct g_raid_volume *vol, int md_disk_pos) { int disk_pos, width; if (md_disk_pos >= 0 && vol->v_raid_level == G_RAID_VOLUME_RL_RAID1E) { width = vol->v_disks_count / 2; disk_pos = (md_disk_pos / width) + (md_disk_pos % width) * width; } else disk_pos = md_disk_pos; return (disk_pos); } static void promise_meta_get_name(struct promise_raid_conf *meta, char *buf) { int i; strncpy(buf, meta->name, 32); buf[32] = 0; for (i = 31; i >= 0; i--) { if (buf[i] > 0x20) break; buf[i] = 0; } } static void promise_meta_put_name(struct promise_raid_conf *meta, char *buf) { memset(meta->name, 0x20, 32); memcpy(meta->name, buf, MIN(strlen(buf), 32)); } static int promise_meta_read(struct g_consumer *cp, struct promise_raid_conf **metaarr) { struct g_provider *pp; struct promise_raid_conf *meta; char *buf; int error, i, subdisks; uint32_t checksum, *ptr; pp = cp->provider; subdisks = 0; next: /* Read metadata block. */ buf = g_read_data(cp, pp->mediasize - pp->sectorsize * (63 - subdisks * PROMISE_META_OFFSET), pp->sectorsize * 4, &error); if (buf == NULL) { G_RAID_DEBUG(1, "Cannot read metadata from %s (error=%d).", pp->name, error); return (subdisks); } meta = (struct promise_raid_conf *)buf; /* Check if this is an Promise RAID struct */ if (strncmp(meta->promise_id, PROMISE_MAGIC, strlen(PROMISE_MAGIC)) && strncmp(meta->promise_id, FREEBSD_MAGIC, strlen(FREEBSD_MAGIC))) { if (subdisks == 0) G_RAID_DEBUG(1, "Promise signature check failed on %s", pp->name); g_free(buf); return (subdisks); } meta = malloc(sizeof(*meta), M_MD_PROMISE, M_WAITOK); memcpy(meta, buf, MIN(sizeof(*meta), pp->sectorsize * 4)); g_free(buf); /* Check metadata checksum. */ for (checksum = 0, ptr = (uint32_t *)meta, i = 0; i < 511; i++) checksum += *ptr++; if (checksum != meta->checksum) { G_RAID_DEBUG(1, "Promise checksum check failed on %s", pp->name); free(meta, M_MD_PROMISE); return (subdisks); } if ((meta->integrity & PROMISE_I_VALID) == 0) { G_RAID_DEBUG(1, "Promise metadata is invalid on %s", pp->name); free(meta, M_MD_PROMISE); return (subdisks); } if (meta->total_disks > PROMISE_MAX_DISKS) { G_RAID_DEBUG(1, "Wrong number of disks on %s (%d)", pp->name, meta->total_disks); free(meta, M_MD_PROMISE); return (subdisks); } /* Save this part and look for next. */ *metaarr = meta; metaarr++; subdisks++; if (subdisks < PROMISE_MAX_SUBDISKS) goto next; return (subdisks); } static int promise_meta_write(struct g_consumer *cp, struct promise_raid_conf **metaarr, int nsd) { struct g_provider *pp; struct promise_raid_conf *meta; char *buf; int error, i, subdisk, fake; uint32_t checksum, *ptr, off, size; pp = cp->provider; subdisk = 0; fake = 0; next: buf = malloc(pp->sectorsize * 4, M_MD_PROMISE, M_WAITOK | M_ZERO); meta = NULL; if (subdisk < nsd) { meta = metaarr[subdisk]; } else if (!fake && promise_meta_unused_range(metaarr, nsd, cp->provider->mediasize / cp->provider->sectorsize, &off, &size)) { /* Optionally add record for unused space. */ meta = (struct promise_raid_conf *)buf; memcpy(&meta->promise_id[0], PROMISE_MAGIC, sizeof(PROMISE_MAGIC) - 1); meta->dummy_0 = 0x00020000; meta->integrity = PROMISE_I_VALID; meta->disk.flags = PROMISE_F_ONLINE | PROMISE_F_VALID; meta->disk.number = 0xff; arc4rand(&meta->disk.id, sizeof(meta->disk.id), 0); meta->disk_offset = off; meta->disk_sectors = size; meta->rebuild_lba = UINT32_MAX; fake = 1; } if (meta != NULL) { /* Recalculate checksum for case if metadata were changed. */ meta->checksum = 0; for (checksum = 0, ptr = (uint32_t *)meta, i = 0; i < 511; i++) checksum += *ptr++; meta->checksum = checksum; memcpy(buf, meta, MIN(pp->sectorsize * 4, sizeof(*meta))); } error = g_write_data(cp, pp->mediasize - pp->sectorsize * (63 - subdisk * PROMISE_META_OFFSET), buf, pp->sectorsize * 4); if (error != 0) { G_RAID_DEBUG(1, "Cannot write metadata to %s (error=%d).", pp->name, error); } free(buf, M_MD_PROMISE); subdisk++; if (subdisk < PROMISE_MAX_SUBDISKS) goto next; return (error); } static int promise_meta_erase(struct g_consumer *cp) { struct g_provider *pp; char *buf; int error, subdisk; pp = cp->provider; buf = malloc(4 * pp->sectorsize, M_MD_PROMISE, M_WAITOK | M_ZERO); for (subdisk = 0; subdisk < PROMISE_MAX_SUBDISKS; subdisk++) { error = g_write_data(cp, pp->mediasize - pp->sectorsize * (63 - subdisk * PROMISE_META_OFFSET), buf, 4 * pp->sectorsize); if (error != 0) { G_RAID_DEBUG(1, "Cannot erase metadata on %s (error=%d).", pp->name, error); } } free(buf, M_MD_PROMISE); return (error); } static int promise_meta_write_spare(struct g_consumer *cp) { struct promise_raid_conf *meta; int error; meta = malloc(sizeof(*meta), M_MD_PROMISE, M_WAITOK | M_ZERO); memcpy(&meta->promise_id[0], PROMISE_MAGIC, sizeof(PROMISE_MAGIC) - 1); meta->dummy_0 = 0x00020000; meta->integrity = PROMISE_I_VALID; meta->disk.flags = PROMISE_F_SPARE | PROMISE_F_ONLINE | PROMISE_F_VALID; meta->disk.number = 0xff; arc4rand(&meta->disk.id, sizeof(meta->disk.id), 0); meta->disk_sectors = cp->provider->mediasize / cp->provider->sectorsize; meta->disk_sectors -= 131072; meta->rebuild_lba = UINT32_MAX; error = promise_meta_write(cp, &meta, 1); free(meta, M_MD_PROMISE); return (error); } static struct g_raid_volume * g_raid_md_promise_get_volume(struct g_raid_softc *sc, uint64_t id) { struct g_raid_volume *vol; struct g_raid_md_promise_pervolume *pv; TAILQ_FOREACH(vol, &sc->sc_volumes, v_next) { pv = vol->v_md_data; if (pv->pv_id == id) break; } return (vol); } static int g_raid_md_promise_purge_volumes(struct g_raid_softc *sc) { struct g_raid_volume *vol, *tvol; struct g_raid_md_promise_pervolume *pv; int i, res; res = 0; TAILQ_FOREACH_SAFE(vol, &sc->sc_volumes, v_next, tvol) { pv = vol->v_md_data; if (!pv->pv_started || vol->v_stopping) continue; for (i = 0; i < vol->v_disks_count; i++) { if (vol->v_subdisks[i].sd_state != G_RAID_SUBDISK_S_NONE) break; } if (i >= vol->v_disks_count) { g_raid_destroy_volume(vol); res = 1; } } return (res); } static int g_raid_md_promise_purge_disks(struct g_raid_softc *sc) { struct g_raid_disk *disk, *tdisk; struct g_raid_volume *vol; struct g_raid_md_promise_perdisk *pd; int i, j, res; res = 0; TAILQ_FOREACH_SAFE(disk, &sc->sc_disks, d_next, tdisk) { if (disk->d_state == G_RAID_DISK_S_SPARE) continue; pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; /* Scan for deleted volumes. */ for (i = 0; i < pd->pd_subdisks; ) { vol = g_raid_md_promise_get_volume(sc, pd->pd_meta[i]->volume_id); if (vol != NULL && !vol->v_stopping) { i++; continue; } free(pd->pd_meta[i], M_MD_PROMISE); for (j = i; j < pd->pd_subdisks - 1; j++) pd->pd_meta[j] = pd->pd_meta[j + 1]; pd->pd_meta[PROMISE_MAX_SUBDISKS - 1] = NULL; pd->pd_subdisks--; pd->pd_updated = 1; } /* If there is no metadata left - erase and delete disk. */ if (pd->pd_subdisks == 0) { promise_meta_erase(disk->d_consumer); g_raid_destroy_disk(disk); res = 1; } } return (res); } static int g_raid_md_promise_supported(int level, int qual, int disks, int force) { if (disks > PROMISE_MAX_DISKS) return (0); switch (level) { case G_RAID_VOLUME_RL_RAID0: if (disks < 1) return (0); if (!force && disks < 2) return (0); break; case G_RAID_VOLUME_RL_RAID1: if (disks < 1) return (0); if (!force && (disks != 2)) return (0); break; case G_RAID_VOLUME_RL_RAID1E: if (disks < 2) return (0); if (disks % 2 != 0) return (0); if (!force && (disks != 4)) return (0); break; case G_RAID_VOLUME_RL_SINGLE: if (disks != 1) return (0); break; case G_RAID_VOLUME_RL_CONCAT: if (disks < 2) return (0); break; case G_RAID_VOLUME_RL_RAID5: if (disks < 3) return (0); if (qual != G_RAID_VOLUME_RLQ_R5LA) return (0); break; default: return (0); } if (level != G_RAID_VOLUME_RL_RAID5 && qual != G_RAID_VOLUME_RLQ_NONE) return (0); return (1); } static int g_raid_md_promise_start_disk(struct g_raid_disk *disk, int sdn, struct g_raid_volume *vol) { struct g_raid_softc *sc; struct g_raid_subdisk *sd; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; struct promise_raid_conf *meta; off_t size; int disk_pos, md_disk_pos, i, resurrection = 0; uint32_t eoff, esize; sc = disk->d_softc; pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; pv = vol->v_md_data; meta = pv->pv_meta; if (sdn >= 0) { /* Find disk position in metadata by it's serial. */ md_disk_pos = promise_meta_find_disk(meta, pd->pd_meta[sdn]->disk.id); /* For RAID0+1 we need to translate order. */ disk_pos = promise_meta_translate_disk(vol, md_disk_pos); } else { md_disk_pos = -1; disk_pos = -1; } if (disk_pos < 0) { G_RAID_DEBUG1(1, sc, "Disk %s is not part of the volume %s", g_raid_get_diskname(disk), vol->v_name); /* Failed stale disk is useless for us. */ if (sdn >= 0 && pd->pd_meta[sdn]->disk.flags & PROMISE_F_DOWN) { g_raid_change_disk_state(disk, G_RAID_DISK_S_STALE_FAILED); return (0); } /* If we were given specific metadata subdisk - erase it. */ if (sdn >= 0) { free(pd->pd_meta[sdn], M_MD_PROMISE); for (i = sdn; i < pd->pd_subdisks - 1; i++) pd->pd_meta[i] = pd->pd_meta[i + 1]; pd->pd_meta[PROMISE_MAX_SUBDISKS - 1] = NULL; pd->pd_subdisks--; } /* If we are in the start process, that's all for now. */ if (!pv->pv_started) goto nofit; /* * If we have already started - try to get use of the disk. * Try to replace OFFLINE disks first, then FAILED. */ promise_meta_unused_range(pd->pd_meta, pd->pd_subdisks, disk->d_consumer->provider->mediasize / disk->d_consumer->provider->sectorsize, &eoff, &esize); if (esize == 0) { G_RAID_DEBUG1(1, sc, "No free space on disk %s", g_raid_get_diskname(disk)); goto nofit; } size = INT64_MAX; for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; if (sd->sd_state != G_RAID_SUBDISK_S_NONE) size = sd->sd_size; if (sd->sd_state <= G_RAID_SUBDISK_S_FAILED && (disk_pos < 0 || vol->v_subdisks[i].sd_state < sd->sd_state)) disk_pos = i; } if (disk_pos >= 0 && vol->v_raid_level != G_RAID_VOLUME_RL_CONCAT && (off_t)esize * 512 < size) { G_RAID_DEBUG1(1, sc, "Disk %s free space " "is too small (%ju < %ju)", g_raid_get_diskname(disk), (off_t)esize * 512, size); disk_pos = -1; } if (disk_pos >= 0) { if (vol->v_raid_level != G_RAID_VOLUME_RL_CONCAT) esize = size / 512; /* For RAID0+1 we need to translate order. */ md_disk_pos = promise_meta_translate_disk(vol, disk_pos); } else { nofit: if (pd->pd_subdisks == 0) { g_raid_change_disk_state(disk, G_RAID_DISK_S_SPARE); } return (0); } G_RAID_DEBUG1(1, sc, "Disk %s takes pos %d in the volume %s", g_raid_get_diskname(disk), disk_pos, vol->v_name); resurrection = 1; } sd = &vol->v_subdisks[disk_pos]; if (resurrection && sd->sd_disk != NULL) { g_raid_change_disk_state(sd->sd_disk, G_RAID_DISK_S_STALE_FAILED); TAILQ_REMOVE(&sd->sd_disk->d_subdisks, sd, sd_next); } vol->v_subdisks[disk_pos].sd_disk = disk; TAILQ_INSERT_TAIL(&disk->d_subdisks, sd, sd_next); /* Welcome the new disk. */ if (resurrection) g_raid_change_disk_state(disk, G_RAID_DISK_S_ACTIVE); else if (meta->disks[md_disk_pos].flags & PROMISE_F_DOWN) g_raid_change_disk_state(disk, G_RAID_DISK_S_FAILED); else g_raid_change_disk_state(disk, G_RAID_DISK_S_ACTIVE); if (resurrection) { sd->sd_offset = (off_t)eoff * 512; sd->sd_size = (off_t)esize * 512; } else { sd->sd_offset = (off_t)pd->pd_meta[sdn]->disk_offset * 512; sd->sd_size = (off_t)pd->pd_meta[sdn]->disk_sectors * 512; } if (resurrection) { /* Stale disk, almost same as new. */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_NEW); } else if (meta->disks[md_disk_pos].flags & PROMISE_F_DOWN) { /* Failed disk. */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_FAILED); } else if (meta->disks[md_disk_pos].flags & PROMISE_F_REDIR) { /* Rebuilding disk. */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_REBUILD); if (pd->pd_meta[sdn]->generation != meta->generation) sd->sd_rebuild_pos = 0; else { sd->sd_rebuild_pos = (off_t)pd->pd_meta[sdn]->rebuild_lba * 512; } } else if (!(meta->disks[md_disk_pos].flags & PROMISE_F_ONLINE)) { /* Rebuilding disk. */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_NEW); } else if (pd->pd_meta[sdn]->generation != meta->generation || (meta->status & PROMISE_S_MARKED)) { /* Stale disk or dirty volume (unclean shutdown). */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_STALE); } else { /* Up to date disk. */ g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_ACTIVE); } g_raid_event_send(sd, G_RAID_SUBDISK_E_NEW, G_RAID_EVENT_SUBDISK); return (resurrection); } static void g_raid_md_promise_refill(struct g_raid_softc *sc) { struct g_raid_volume *vol; struct g_raid_subdisk *sd; struct g_raid_disk *disk; struct g_raid_md_object *md; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; int update, updated, i, bad; md = sc->sc_md; restart: updated = 0; TAILQ_FOREACH(vol, &sc->sc_volumes, v_next) { pv = vol->v_md_data; if (!pv->pv_started || vol->v_stopping) continue; /* Search for subdisk that needs replacement. */ bad = 0; for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; if (sd->sd_state == G_RAID_SUBDISK_S_NONE || sd->sd_state == G_RAID_SUBDISK_S_FAILED) bad = 1; } if (!bad) continue; G_RAID_DEBUG1(1, sc, "Volume %s is not complete, " "trying to refill.", vol->v_name); TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { /* Skip failed. */ if (disk->d_state < G_RAID_DISK_S_SPARE) continue; /* Skip already used by this volume. */ for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; if (sd->sd_disk == disk) break; } if (i < vol->v_disks_count) continue; /* Try to use disk if it has empty extents. */ pd = disk->d_md_data; if (pd->pd_subdisks < PROMISE_MAX_SUBDISKS) { update = g_raid_md_promise_start_disk(disk, -1, vol); } else update = 0; if (update) { updated = 1; g_raid_md_write_promise(md, vol, NULL, disk); break; } } } if (updated) goto restart; } static void g_raid_md_promise_start(struct g_raid_volume *vol) { struct g_raid_softc *sc; struct g_raid_subdisk *sd; struct g_raid_disk *disk; struct g_raid_md_object *md; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; struct promise_raid_conf *meta; int i; sc = vol->v_softc; md = sc->sc_md; pv = vol->v_md_data; meta = pv->pv_meta; vol->v_raid_level_qualifier = G_RAID_VOLUME_RLQ_NONE; if (meta->type == PROMISE_T_RAID0) vol->v_raid_level = G_RAID_VOLUME_RL_RAID0; else if (meta->type == PROMISE_T_RAID1) { if (meta->array_width == 1) vol->v_raid_level = G_RAID_VOLUME_RL_RAID1; else vol->v_raid_level = G_RAID_VOLUME_RL_RAID1E; } else if (meta->type == PROMISE_T_RAID3) vol->v_raid_level = G_RAID_VOLUME_RL_RAID3; else if (meta->type == PROMISE_T_RAID5) { vol->v_raid_level = G_RAID_VOLUME_RL_RAID5; vol->v_raid_level_qualifier = G_RAID_VOLUME_RLQ_R5LA; } else if (meta->type == PROMISE_T_SPAN) vol->v_raid_level = G_RAID_VOLUME_RL_CONCAT; else if (meta->type == PROMISE_T_JBOD) vol->v_raid_level = G_RAID_VOLUME_RL_SINGLE; else vol->v_raid_level = G_RAID_VOLUME_RL_UNKNOWN; vol->v_strip_size = 512 << meta->stripe_shift; //ZZZ vol->v_disks_count = meta->total_disks; vol->v_mediasize = (off_t)meta->total_sectors * 512; //ZZZ if (meta->total_sectors_high < 256) /* If value looks sane. */ vol->v_mediasize |= ((off_t)meta->total_sectors_high << 32) * 512; //ZZZ vol->v_sectorsize = 512; //ZZZ for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; sd->sd_offset = (off_t)meta->disk_offset * 512; //ZZZ sd->sd_size = (off_t)meta->disk_sectors * 512; //ZZZ } g_raid_start_volume(vol); /* Make all disks found till the moment take their places. */ TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { pd = disk->d_md_data; for (i = 0; i < pd->pd_subdisks; i++) { if (pd->pd_meta[i]->volume_id == meta->volume_id) g_raid_md_promise_start_disk(disk, i, vol); } } pv->pv_started = 1; callout_stop(&pv->pv_start_co); G_RAID_DEBUG1(0, sc, "Volume started."); g_raid_md_write_promise(md, vol, NULL, NULL); /* Pickup any STALE/SPARE disks to refill array if needed. */ g_raid_md_promise_refill(sc); g_raid_event_send(vol, G_RAID_VOLUME_E_START, G_RAID_EVENT_VOLUME); } static void g_raid_promise_go(void *arg) { struct g_raid_volume *vol; struct g_raid_softc *sc; struct g_raid_md_promise_pervolume *pv; vol = arg; pv = vol->v_md_data; sc = vol->v_softc; if (!pv->pv_started) { G_RAID_DEBUG1(0, sc, "Force volume start due to timeout."); g_raid_event_send(vol, G_RAID_VOLUME_E_STARTMD, G_RAID_EVENT_VOLUME); } } static void g_raid_md_promise_new_disk(struct g_raid_disk *disk) { struct g_raid_softc *sc; struct g_raid_md_object *md; struct promise_raid_conf *pdmeta; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; struct g_raid_volume *vol; int i; char buf[33]; sc = disk->d_softc; md = sc->sc_md; pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; if (pd->pd_subdisks == 0) { g_raid_change_disk_state(disk, G_RAID_DISK_S_SPARE); g_raid_md_promise_refill(sc); return; } for (i = 0; i < pd->pd_subdisks; i++) { pdmeta = pd->pd_meta[i]; /* Look for volume with matching ID. */ vol = g_raid_md_promise_get_volume(sc, pdmeta->volume_id); if (vol == NULL) { promise_meta_get_name(pdmeta, buf); vol = g_raid_create_volume(sc, buf, pdmeta->array_number); pv = malloc(sizeof(*pv), M_MD_PROMISE, M_WAITOK | M_ZERO); pv->pv_id = pdmeta->volume_id; vol->v_md_data = pv; callout_init(&pv->pv_start_co, 1); callout_reset(&pv->pv_start_co, g_raid_start_timeout * hz, g_raid_promise_go, vol); } else pv = vol->v_md_data; /* If we haven't started yet - check metadata freshness. */ if (pv->pv_meta == NULL || !pv->pv_started) { if (pv->pv_meta == NULL || ((int16_t)(pdmeta->generation - pv->pv_generation)) > 0) { G_RAID_DEBUG1(1, sc, "Newer disk"); if (pv->pv_meta != NULL) free(pv->pv_meta, M_MD_PROMISE); pv->pv_meta = promise_meta_copy(pdmeta); pv->pv_generation = pv->pv_meta->generation; pv->pv_disks_present = 1; } else if (pdmeta->generation == pv->pv_generation) { pv->pv_disks_present++; G_RAID_DEBUG1(1, sc, "Matching disk (%d of %d up)", pv->pv_disks_present, pv->pv_meta->total_disks); } else { G_RAID_DEBUG1(1, sc, "Older disk"); } } } for (i = 0; i < pd->pd_subdisks; i++) { pdmeta = pd->pd_meta[i]; /* Look for volume with matching ID. */ vol = g_raid_md_promise_get_volume(sc, pdmeta->volume_id); if (vol == NULL) continue; pv = vol->v_md_data; if (pv->pv_started) { if (g_raid_md_promise_start_disk(disk, i, vol)) g_raid_md_write_promise(md, vol, NULL, NULL); } else { /* If we collected all needed disks - start array. */ if (pv->pv_disks_present == pv->pv_meta->total_disks) g_raid_md_promise_start(vol); } } } static int g_raid_md_create_promise(struct g_raid_md_object *md, struct g_class *mp, struct g_geom **gp) { struct g_geom *geom; struct g_raid_softc *sc; /* Search for existing node. */ LIST_FOREACH(geom, &mp->geom, geom) { sc = geom->softc; if (sc == NULL) continue; if (sc->sc_stopping != 0) continue; if (sc->sc_md->mdo_class != md->mdo_class) continue; break; } if (geom != NULL) { *gp = geom; return (G_RAID_MD_TASTE_EXISTING); } /* Create new one if not found. */ sc = g_raid_create_node(mp, "Promise", md); if (sc == NULL) return (G_RAID_MD_TASTE_FAIL); md->mdo_softc = sc; *gp = sc->sc_geom; return (G_RAID_MD_TASTE_NEW); } static int g_raid_md_taste_promise(struct g_raid_md_object *md, struct g_class *mp, struct g_consumer *cp, struct g_geom **gp) { struct g_consumer *rcp; struct g_provider *pp; struct g_raid_softc *sc; struct g_raid_disk *disk; struct promise_raid_conf *meta, *metaarr[4]; struct g_raid_md_promise_perdisk *pd; struct g_geom *geom; int error, i, j, result, len, subdisks; char name[16]; uint16_t vendor; G_RAID_DEBUG(1, "Tasting Promise on %s", cp->provider->name); pp = cp->provider; /* Read metadata from device. */ meta = NULL; vendor = 0xffff; if (g_access(cp, 1, 0, 0) != 0) return (G_RAID_MD_TASTE_FAIL); g_topology_unlock(); len = 2; if (pp->geom->rank == 1) g_io_getattr("GEOM::hba_vendor", cp, &len, &vendor); subdisks = promise_meta_read(cp, metaarr); g_topology_lock(); g_access(cp, -1, 0, 0); if (subdisks == 0) { if (g_raid_aggressive_spare) { if (vendor == 0x105a || vendor == 0x1002) { G_RAID_DEBUG(1, "No Promise metadata, forcing spare."); goto search; } else { G_RAID_DEBUG(1, "Promise/ATI vendor mismatch " "0x%04x != 0x105a/0x1002", vendor); } } return (G_RAID_MD_TASTE_FAIL); } /* Metadata valid. Print it. */ for (i = 0; i < subdisks; i++) g_raid_md_promise_print(metaarr[i]); /* Purge meaningless (empty/spare) records. */ for (i = 0; i < subdisks; ) { if (metaarr[i]->disk.flags & PROMISE_F_ASSIGNED) { i++; continue; } free(metaarr[i], M_MD_PROMISE); for (j = i; j < subdisks - 1; j++) metaarr[i] = metaarr[j + 1]; metaarr[PROMISE_MAX_SUBDISKS - 1] = NULL; subdisks--; } search: /* Search for matching node. */ sc = NULL; LIST_FOREACH(geom, &mp->geom, geom) { sc = geom->softc; if (sc == NULL) continue; if (sc->sc_stopping != 0) continue; if (sc->sc_md->mdo_class != md->mdo_class) continue; break; } /* Found matching node. */ if (geom != NULL) { G_RAID_DEBUG(1, "Found matching array %s", sc->sc_name); result = G_RAID_MD_TASTE_EXISTING; } else { /* Not found matching node -- create one. */ result = G_RAID_MD_TASTE_NEW; snprintf(name, sizeof(name), "Promise"); sc = g_raid_create_node(mp, name, md); md->mdo_softc = sc; geom = sc->sc_geom; } rcp = g_new_consumer(geom); g_attach(rcp, pp); if (g_access(rcp, 1, 1, 1) != 0) ; //goto fail1; g_topology_unlock(); sx_xlock(&sc->sc_lock); pd = malloc(sizeof(*pd), M_MD_PROMISE, M_WAITOK | M_ZERO); pd->pd_subdisks = subdisks; for (i = 0; i < subdisks; i++) pd->pd_meta[i] = metaarr[i]; disk = g_raid_create_disk(sc); disk->d_md_data = (void *)pd; disk->d_consumer = rcp; rcp->private = disk; /* Read kernel dumping information. */ disk->d_kd.offset = 0; disk->d_kd.length = OFF_MAX; len = sizeof(disk->d_kd); error = g_io_getattr("GEOM::kerneldump", rcp, &len, &disk->d_kd); if (disk->d_kd.di.dumper == NULL) G_RAID_DEBUG1(2, sc, "Dumping not supported by %s: %d.", rcp->provider->name, error); g_raid_md_promise_new_disk(disk); sx_xunlock(&sc->sc_lock); g_topology_lock(); *gp = geom; return (result); } static int g_raid_md_event_promise(struct g_raid_md_object *md, struct g_raid_disk *disk, u_int event) { struct g_raid_softc *sc; sc = md->mdo_softc; if (disk == NULL) return (-1); switch (event) { case G_RAID_DISK_E_DISCONNECTED: /* Delete disk. */ g_raid_change_disk_state(disk, G_RAID_DISK_S_NONE); g_raid_destroy_disk(disk); g_raid_md_promise_purge_volumes(sc); /* Write updated metadata to all disks. */ g_raid_md_write_promise(md, NULL, NULL, NULL); /* Check if anything left. */ if (g_raid_ndisks(sc, -1) == 0) g_raid_destroy_node(sc, 0); else g_raid_md_promise_refill(sc); return (0); } return (-2); } static int g_raid_md_volume_event_promise(struct g_raid_md_object *md, struct g_raid_volume *vol, u_int event) { struct g_raid_md_promise_pervolume *pv; pv = (struct g_raid_md_promise_pervolume *)vol->v_md_data; switch (event) { case G_RAID_VOLUME_E_STARTMD: if (!pv->pv_started) g_raid_md_promise_start(vol); return (0); } return (-2); } static int g_raid_md_ctl_promise(struct g_raid_md_object *md, struct gctl_req *req) { struct g_raid_softc *sc; struct g_raid_volume *vol, *vol1; struct g_raid_subdisk *sd; struct g_raid_disk *disk, *disks[PROMISE_MAX_DISKS]; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; struct g_consumer *cp; struct g_provider *pp; char arg[16]; const char *verb, *volname, *levelname, *diskname; char *tmp; int *nargs, *force; off_t size, sectorsize, strip; intmax_t *sizearg, *striparg; uint32_t offs[PROMISE_MAX_DISKS], esize; int numdisks, i, len, level, qual; int error; sc = md->mdo_softc; verb = gctl_get_param(req, "verb", NULL); nargs = gctl_get_paraml(req, "nargs", sizeof(*nargs)); error = 0; if (strcmp(verb, "label") == 0) { if (*nargs < 4) { gctl_error(req, "Invalid number of arguments."); return (-1); } volname = gctl_get_asciiparam(req, "arg1"); if (volname == NULL) { gctl_error(req, "No volume name."); return (-2); } levelname = gctl_get_asciiparam(req, "arg2"); if (levelname == NULL) { gctl_error(req, "No RAID level."); return (-3); } if (strcasecmp(levelname, "RAID5") == 0) levelname = "RAID5-LA"; if (g_raid_volume_str2level(levelname, &level, &qual)) { gctl_error(req, "Unknown RAID level '%s'.", levelname); return (-4); } numdisks = *nargs - 3; force = gctl_get_paraml(req, "force", sizeof(*force)); if (!g_raid_md_promise_supported(level, qual, numdisks, force ? *force : 0)) { gctl_error(req, "Unsupported RAID level " "(0x%02x/0x%02x), or number of disks (%d).", level, qual, numdisks); return (-5); } /* Search for disks, connect them and probe. */ size = INT64_MAX; sectorsize = 0; bzero(disks, sizeof(disks)); bzero(offs, sizeof(offs)); for (i = 0; i < numdisks; i++) { snprintf(arg, sizeof(arg), "arg%d", i + 3); diskname = gctl_get_asciiparam(req, arg); if (diskname == NULL) { gctl_error(req, "No disk name (%s).", arg); error = -6; break; } if (strcmp(diskname, "NONE") == 0) continue; TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { if (disk->d_consumer != NULL && disk->d_consumer->provider != NULL && strcmp(disk->d_consumer->provider->name, diskname) == 0) break; } if (disk != NULL) { if (disk->d_state != G_RAID_DISK_S_ACTIVE) { gctl_error(req, "Disk '%s' is in a " "wrong state (%s).", diskname, g_raid_disk_state2str(disk->d_state)); error = -7; break; } pd = disk->d_md_data; if (pd->pd_subdisks >= PROMISE_MAX_SUBDISKS) { gctl_error(req, "Disk '%s' already " "used by %d volumes.", diskname, pd->pd_subdisks); error = -7; break; } pp = disk->d_consumer->provider; disks[i] = disk; promise_meta_unused_range(pd->pd_meta, pd->pd_subdisks, pp->mediasize / pp->sectorsize, &offs[i], &esize); size = MIN(size, (off_t)esize * pp->sectorsize); sectorsize = MAX(sectorsize, pp->sectorsize); continue; } g_topology_lock(); cp = g_raid_open_consumer(sc, diskname); if (cp == NULL) { gctl_error(req, "Can't open disk '%s'.", diskname); g_topology_unlock(); error = -8; break; } pp = cp->provider; pd = malloc(sizeof(*pd), M_MD_PROMISE, M_WAITOK | M_ZERO); disk = g_raid_create_disk(sc); disk->d_md_data = (void *)pd; disk->d_consumer = cp; disks[i] = disk; cp->private = disk; g_topology_unlock(); if (pp->mediasize / pp->sectorsize > UINT32_MAX) { gctl_error(req, "Disk '%s' is too big.", diskname); error = -8; break; } /* Read kernel dumping information. */ disk->d_kd.offset = 0; disk->d_kd.length = OFF_MAX; len = sizeof(disk->d_kd); g_io_getattr("GEOM::kerneldump", cp, &len, &disk->d_kd); if (disk->d_kd.di.dumper == NULL) G_RAID_DEBUG1(2, sc, "Dumping not supported by %s.", cp->provider->name); /* Reserve some space for metadata. */ size = MIN(size, pp->mediasize - 131072llu * pp->sectorsize); sectorsize = MAX(sectorsize, pp->sectorsize); } if (error != 0) { for (i = 0; i < numdisks; i++) { if (disks[i] != NULL && disks[i]->d_state == G_RAID_DISK_S_NONE) g_raid_destroy_disk(disks[i]); } return (error); } if (sectorsize <= 0) { gctl_error(req, "Can't get sector size."); return (-8); } /* Handle size argument. */ len = sizeof(*sizearg); sizearg = gctl_get_param(req, "size", &len); if (sizearg != NULL && len == sizeof(*sizearg) && *sizearg > 0) { if (*sizearg > size) { gctl_error(req, "Size too big %lld > %lld.", (long long)*sizearg, (long long)size); return (-9); } size = *sizearg; } /* Handle strip argument. */ strip = 131072; len = sizeof(*striparg); striparg = gctl_get_param(req, "strip", &len); if (striparg != NULL && len == sizeof(*striparg) && *striparg > 0) { if (*striparg < sectorsize) { gctl_error(req, "Strip size too small."); return (-10); } if (*striparg % sectorsize != 0) { gctl_error(req, "Incorrect strip size."); return (-11); } strip = *striparg; } /* Round size down to strip or sector. */ if (level == G_RAID_VOLUME_RL_RAID1 || level == G_RAID_VOLUME_RL_SINGLE || level == G_RAID_VOLUME_RL_CONCAT) size -= (size % sectorsize); else if (level == G_RAID_VOLUME_RL_RAID1E && (numdisks & 1) != 0) size -= (size % (2 * strip)); else size -= (size % strip); if (size <= 0) { gctl_error(req, "Size too small."); return (-13); } if (size > 0xffffffffllu * sectorsize) { gctl_error(req, "Size too big."); return (-14); } /* We have all we need, create things: volume, ... */ pv = malloc(sizeof(*pv), M_MD_PROMISE, M_WAITOK | M_ZERO); arc4rand(&pv->pv_id, sizeof(pv->pv_id), 0); pv->pv_generation = 0; pv->pv_started = 1; vol = g_raid_create_volume(sc, volname, -1); vol->v_md_data = pv; vol->v_raid_level = level; vol->v_raid_level_qualifier = qual; vol->v_strip_size = strip; vol->v_disks_count = numdisks; if (level == G_RAID_VOLUME_RL_RAID0 || level == G_RAID_VOLUME_RL_CONCAT || level == G_RAID_VOLUME_RL_SINGLE) vol->v_mediasize = size * numdisks; else if (level == G_RAID_VOLUME_RL_RAID1) vol->v_mediasize = size; else if (level == G_RAID_VOLUME_RL_RAID3 || level == G_RAID_VOLUME_RL_RAID5) vol->v_mediasize = size * (numdisks - 1); else { /* RAID1E */ vol->v_mediasize = ((size * numdisks) / strip / 2) * strip; } vol->v_sectorsize = sectorsize; g_raid_start_volume(vol); /* , and subdisks. */ for (i = 0; i < numdisks; i++) { disk = disks[i]; sd = &vol->v_subdisks[i]; sd->sd_disk = disk; sd->sd_offset = (off_t)offs[i] * 512; sd->sd_size = size; if (disk == NULL) continue; TAILQ_INSERT_TAIL(&disk->d_subdisks, sd, sd_next); g_raid_change_disk_state(disk, G_RAID_DISK_S_ACTIVE); g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_ACTIVE); g_raid_event_send(sd, G_RAID_SUBDISK_E_NEW, G_RAID_EVENT_SUBDISK); } /* Write metadata based on created entities. */ G_RAID_DEBUG1(0, sc, "Array started."); g_raid_md_write_promise(md, vol, NULL, NULL); /* Pickup any STALE/SPARE disks to refill array if needed. */ g_raid_md_promise_refill(sc); g_raid_event_send(vol, G_RAID_VOLUME_E_START, G_RAID_EVENT_VOLUME); return (0); } if (strcmp(verb, "add") == 0) { gctl_error(req, "`add` command is not applicable, " "use `label` instead."); return (-99); } if (strcmp(verb, "delete") == 0) { /* Full node destruction. */ if (*nargs == 1) { /* Check if some volume is still open. */ force = gctl_get_paraml(req, "force", sizeof(*force)); if (force != NULL && *force == 0 && g_raid_nopens(sc) != 0) { gctl_error(req, "Some volume is still open."); return (-4); } TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { if (disk->d_consumer) promise_meta_erase(disk->d_consumer); } g_raid_destroy_node(sc, 0); return (0); } /* Destroy specified volume. If it was last - all node. */ if (*nargs != 2) { gctl_error(req, "Invalid number of arguments."); return (-1); } volname = gctl_get_asciiparam(req, "arg1"); if (volname == NULL) { gctl_error(req, "No volume name."); return (-2); } /* Search for volume. */ TAILQ_FOREACH(vol, &sc->sc_volumes, v_next) { if (strcmp(vol->v_name, volname) == 0) break; } if (vol == NULL) { i = strtol(volname, &tmp, 10); if (verb != volname && tmp[0] == 0) { TAILQ_FOREACH(vol, &sc->sc_volumes, v_next) { if (vol->v_global_id == i) break; } } } if (vol == NULL) { gctl_error(req, "Volume '%s' not found.", volname); return (-3); } /* Check if volume is still open. */ force = gctl_get_paraml(req, "force", sizeof(*force)); if (force != NULL && *force == 0 && vol->v_provider_open != 0) { gctl_error(req, "Volume is still open."); return (-4); } /* Destroy volume and potentially node. */ i = 0; TAILQ_FOREACH(vol1, &sc->sc_volumes, v_next) i++; if (i >= 2) { g_raid_destroy_volume(vol); g_raid_md_promise_purge_disks(sc); g_raid_md_write_promise(md, NULL, NULL, NULL); } else { TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { if (disk->d_consumer) promise_meta_erase(disk->d_consumer); } g_raid_destroy_node(sc, 0); } return (0); } if (strcmp(verb, "remove") == 0 || strcmp(verb, "fail") == 0) { if (*nargs < 2) { gctl_error(req, "Invalid number of arguments."); return (-1); } for (i = 1; i < *nargs; i++) { snprintf(arg, sizeof(arg), "arg%d", i); diskname = gctl_get_asciiparam(req, arg); if (diskname == NULL) { gctl_error(req, "No disk name (%s).", arg); error = -2; break; } if (strncmp(diskname, "/dev/", 5) == 0) diskname += 5; TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { if (disk->d_consumer != NULL && disk->d_consumer->provider != NULL && strcmp(disk->d_consumer->provider->name, diskname) == 0) break; } if (disk == NULL) { gctl_error(req, "Disk '%s' not found.", diskname); error = -3; break; } if (strcmp(verb, "fail") == 0) { g_raid_md_fail_disk_promise(md, NULL, disk); continue; } /* Erase metadata on deleting disk and destroy it. */ promise_meta_erase(disk->d_consumer); g_raid_destroy_disk(disk); } g_raid_md_promise_purge_volumes(sc); /* Write updated metadata to remaining disks. */ g_raid_md_write_promise(md, NULL, NULL, NULL); /* Check if anything left. */ if (g_raid_ndisks(sc, -1) == 0) g_raid_destroy_node(sc, 0); else g_raid_md_promise_refill(sc); return (error); } if (strcmp(verb, "insert") == 0) { if (*nargs < 2) { gctl_error(req, "Invalid number of arguments."); return (-1); } for (i = 1; i < *nargs; i++) { /* Get disk name. */ snprintf(arg, sizeof(arg), "arg%d", i); diskname = gctl_get_asciiparam(req, arg); if (diskname == NULL) { gctl_error(req, "No disk name (%s).", arg); error = -3; break; } /* Try to find provider with specified name. */ g_topology_lock(); cp = g_raid_open_consumer(sc, diskname); if (cp == NULL) { gctl_error(req, "Can't open disk '%s'.", diskname); g_topology_unlock(); error = -4; break; } pp = cp->provider; g_topology_unlock(); if (pp->mediasize / pp->sectorsize > UINT32_MAX) { gctl_error(req, "Disk '%s' is too big.", diskname); g_raid_kill_consumer(sc, cp); error = -8; break; } pd = malloc(sizeof(*pd), M_MD_PROMISE, M_WAITOK | M_ZERO); disk = g_raid_create_disk(sc); disk->d_consumer = cp; disk->d_md_data = (void *)pd; cp->private = disk; /* Read kernel dumping information. */ disk->d_kd.offset = 0; disk->d_kd.length = OFF_MAX; len = sizeof(disk->d_kd); g_io_getattr("GEOM::kerneldump", cp, &len, &disk->d_kd); if (disk->d_kd.di.dumper == NULL) G_RAID_DEBUG1(2, sc, "Dumping not supported by %s.", cp->provider->name); /* Welcome the "new" disk. */ g_raid_change_disk_state(disk, G_RAID_DISK_S_SPARE); promise_meta_write_spare(cp); g_raid_md_promise_refill(sc); } return (error); } return (-100); } static int g_raid_md_write_promise(struct g_raid_md_object *md, struct g_raid_volume *tvol, struct g_raid_subdisk *tsd, struct g_raid_disk *tdisk) { struct g_raid_softc *sc; struct g_raid_volume *vol; struct g_raid_subdisk *sd; struct g_raid_disk *disk; struct g_raid_md_promise_perdisk *pd; struct g_raid_md_promise_pervolume *pv; struct promise_raid_conf *meta; off_t rebuild_lba64; int i, j, pos, rebuild; sc = md->mdo_softc; if (sc->sc_stopping == G_RAID_DESTROY_HARD) return (0); /* Generate new per-volume metadata for affected volumes. */ TAILQ_FOREACH(vol, &sc->sc_volumes, v_next) { if (vol->v_stopping) continue; /* Skip volumes not related to specified targets. */ if (tvol != NULL && vol != tvol) continue; if (tsd != NULL && vol != tsd->sd_volume) continue; if (tdisk != NULL) { for (i = 0; i < vol->v_disks_count; i++) { if (vol->v_subdisks[i].sd_disk == tdisk) break; } if (i >= vol->v_disks_count) continue; } pv = (struct g_raid_md_promise_pervolume *)vol->v_md_data; pv->pv_generation++; meta = malloc(sizeof(*meta), M_MD_PROMISE, M_WAITOK | M_ZERO); if (pv->pv_meta != NULL) memcpy(meta, pv->pv_meta, sizeof(*meta)); memcpy(meta->promise_id, PROMISE_MAGIC, sizeof(PROMISE_MAGIC) - 1); meta->dummy_0 = 0x00020000; meta->integrity = PROMISE_I_VALID; meta->generation = pv->pv_generation; meta->status = PROMISE_S_VALID | PROMISE_S_ONLINE | PROMISE_S_INITED | PROMISE_S_READY; if (vol->v_state <= G_RAID_VOLUME_S_DEGRADED) meta->status |= PROMISE_S_DEGRADED; if (vol->v_dirty) meta->status |= PROMISE_S_MARKED; /* XXX: INVENTED! */ if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID0 || vol->v_raid_level == G_RAID_VOLUME_RL_SINGLE) meta->type = PROMISE_T_RAID0; else if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID1 || vol->v_raid_level == G_RAID_VOLUME_RL_RAID1E) meta->type = PROMISE_T_RAID1; else if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID3) meta->type = PROMISE_T_RAID3; else if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID5) meta->type = PROMISE_T_RAID5; else if (vol->v_raid_level == G_RAID_VOLUME_RL_CONCAT) meta->type = PROMISE_T_SPAN; else meta->type = PROMISE_T_JBOD; meta->total_disks = vol->v_disks_count; meta->stripe_shift = ffs(vol->v_strip_size / 1024); meta->array_width = vol->v_disks_count; if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID1 || vol->v_raid_level == G_RAID_VOLUME_RL_RAID1E) meta->array_width /= 2; meta->array_number = vol->v_global_id; meta->total_sectors = vol->v_mediasize / vol->v_sectorsize; meta->total_sectors_high = (vol->v_mediasize / vol->v_sectorsize) >> 32; meta->cylinders = meta->total_sectors / (255 * 63) - 1; meta->heads = 254; meta->sectors = 63; meta->volume_id = pv->pv_id; rebuild_lba64 = UINT64_MAX; rebuild = 0; for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; /* For RAID0+1 we need to translate order. */ pos = promise_meta_translate_disk(vol, i); meta->disks[pos].flags = PROMISE_F_VALID | PROMISE_F_ASSIGNED; if (sd->sd_state == G_RAID_SUBDISK_S_NONE) { meta->disks[pos].flags |= 0; } else if (sd->sd_state == G_RAID_SUBDISK_S_FAILED) { meta->disks[pos].flags |= PROMISE_F_DOWN | PROMISE_F_REDIR; } else if (sd->sd_state <= G_RAID_SUBDISK_S_REBUILD) { meta->disks[pos].flags |= PROMISE_F_ONLINE | PROMISE_F_REDIR; if (sd->sd_state == G_RAID_SUBDISK_S_REBUILD) { rebuild_lba64 = MIN(rebuild_lba64, sd->sd_rebuild_pos / 512); } else rebuild_lba64 = 0; rebuild = 1; } else { meta->disks[pos].flags |= PROMISE_F_ONLINE; if (sd->sd_state < G_RAID_SUBDISK_S_ACTIVE) { meta->status |= PROMISE_S_MARKED; if (sd->sd_state == G_RAID_SUBDISK_S_RESYNC) { rebuild_lba64 = MIN(rebuild_lba64, sd->sd_rebuild_pos / 512); } else rebuild_lba64 = 0; } } if (pv->pv_meta != NULL) { meta->disks[pos].id = pv->pv_meta->disks[pos].id; } else { meta->disks[pos].number = i * 2; arc4rand(&meta->disks[pos].id, sizeof(meta->disks[pos].id), 0); } } promise_meta_put_name(meta, vol->v_name); /* Try to mimic AMD BIOS rebuild/resync behavior. */ if (rebuild_lba64 != UINT64_MAX) { if (rebuild) meta->magic_3 = 0x03040010UL; /* Rebuild? */ else meta->magic_3 = 0x03040008UL; /* Resync? */ /* Translate from per-disk to per-volume LBA. */ if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID1 || vol->v_raid_level == G_RAID_VOLUME_RL_RAID1E) { rebuild_lba64 *= meta->array_width; } else if (vol->v_raid_level == G_RAID_VOLUME_RL_RAID3 || vol->v_raid_level == G_RAID_VOLUME_RL_RAID5) { rebuild_lba64 *= meta->array_width - 1; } else rebuild_lba64 = 0; } else meta->magic_3 = 0x03000000UL; meta->rebuild_lba64 = rebuild_lba64; meta->magic_4 = 0x04010101UL; /* Replace per-volume metadata with new. */ if (pv->pv_meta != NULL) free(pv->pv_meta, M_MD_PROMISE); pv->pv_meta = meta; /* Copy new metadata to the disks, adding or replacing old. */ for (i = 0; i < vol->v_disks_count; i++) { sd = &vol->v_subdisks[i]; disk = sd->sd_disk; if (disk == NULL) continue; /* For RAID0+1 we need to translate order. */ pos = promise_meta_translate_disk(vol, i); pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; for (j = 0; j < pd->pd_subdisks; j++) { if (pd->pd_meta[j]->volume_id == meta->volume_id) break; } if (j == pd->pd_subdisks) pd->pd_subdisks++; if (pd->pd_meta[j] != NULL) free(pd->pd_meta[j], M_MD_PROMISE); pd->pd_meta[j] = promise_meta_copy(meta); pd->pd_meta[j]->disk = meta->disks[pos]; pd->pd_meta[j]->disk.number = pos; pd->pd_meta[j]->disk_offset = sd->sd_offset / 512; pd->pd_meta[j]->disk_sectors = sd->sd_size / 512; if (sd->sd_state == G_RAID_SUBDISK_S_REBUILD) { pd->pd_meta[j]->rebuild_lba = sd->sd_rebuild_pos / 512; } else if (sd->sd_state < G_RAID_SUBDISK_S_REBUILD) pd->pd_meta[j]->rebuild_lba = 0; else pd->pd_meta[j]->rebuild_lba = UINT32_MAX; pd->pd_updated = 1; } } TAILQ_FOREACH(disk, &sc->sc_disks, d_next) { pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; if (disk->d_state != G_RAID_DISK_S_ACTIVE) continue; if (!pd->pd_updated) continue; G_RAID_DEBUG(1, "Writing Promise metadata to %s", g_raid_get_diskname(disk)); for (i = 0; i < pd->pd_subdisks; i++) g_raid_md_promise_print(pd->pd_meta[i]); promise_meta_write(disk->d_consumer, pd->pd_meta, pd->pd_subdisks); pd->pd_updated = 0; } return (0); } static int g_raid_md_fail_disk_promise(struct g_raid_md_object *md, struct g_raid_subdisk *tsd, struct g_raid_disk *tdisk) { struct g_raid_softc *sc; struct g_raid_md_promise_perdisk *pd; struct g_raid_subdisk *sd; int i, pos; sc = md->mdo_softc; pd = (struct g_raid_md_promise_perdisk *)tdisk->d_md_data; /* We can't fail disk that is not a part of array now. */ if (tdisk->d_state != G_RAID_DISK_S_ACTIVE) return (-1); /* * Mark disk as failed in metadata and try to write that metadata * to the disk itself to prevent it's later resurrection as STALE. */ if (pd->pd_subdisks > 0 && tdisk->d_consumer != NULL) G_RAID_DEBUG(1, "Writing Promise metadata to %s", g_raid_get_diskname(tdisk)); for (i = 0; i < pd->pd_subdisks; i++) { pd->pd_meta[i]->disk.flags |= PROMISE_F_DOWN | PROMISE_F_REDIR; pos = pd->pd_meta[i]->disk.number; if (pos >= 0 && pos < PROMISE_MAX_DISKS) { pd->pd_meta[i]->disks[pos].flags |= PROMISE_F_DOWN | PROMISE_F_REDIR; } g_raid_md_promise_print(pd->pd_meta[i]); } if (tdisk->d_consumer != NULL) promise_meta_write(tdisk->d_consumer, pd->pd_meta, pd->pd_subdisks); /* Change states. */ g_raid_change_disk_state(tdisk, G_RAID_DISK_S_FAILED); TAILQ_FOREACH(sd, &tdisk->d_subdisks, sd_next) { g_raid_change_subdisk_state(sd, G_RAID_SUBDISK_S_FAILED); g_raid_event_send(sd, G_RAID_SUBDISK_E_FAILED, G_RAID_EVENT_SUBDISK); } /* Write updated metadata to remaining disks. */ g_raid_md_write_promise(md, NULL, NULL, tdisk); g_raid_md_promise_refill(sc); return (0); } static int g_raid_md_free_disk_promise(struct g_raid_md_object *md, struct g_raid_disk *disk) { struct g_raid_md_promise_perdisk *pd; int i; pd = (struct g_raid_md_promise_perdisk *)disk->d_md_data; for (i = 0; i < pd->pd_subdisks; i++) { if (pd->pd_meta[i] != NULL) { free(pd->pd_meta[i], M_MD_PROMISE); pd->pd_meta[i] = NULL; } } free(pd, M_MD_PROMISE); disk->d_md_data = NULL; return (0); } static int g_raid_md_free_volume_promise(struct g_raid_md_object *md, struct g_raid_volume *vol) { struct g_raid_md_promise_pervolume *pv; pv = (struct g_raid_md_promise_pervolume *)vol->v_md_data; if (pv && pv->pv_meta != NULL) { free(pv->pv_meta, M_MD_PROMISE); pv->pv_meta = NULL; } if (pv && !pv->pv_started) { pv->pv_started = 1; callout_stop(&pv->pv_start_co); } free(pv, M_MD_PROMISE); vol->v_md_data = NULL; return (0); } static int g_raid_md_free_promise(struct g_raid_md_object *md) { return (0); } G_RAID_MD_DECLARE(promise, "Promise");