/*- * Copyright (c) 2000 - 2007 Søren Schmidt * 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, * without modification, immediately at the beginning of the file. * 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 AUTHOR ``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 AUTHOR 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 __FBSDID("$FreeBSD$"); #include "opt_ata.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* prototypes */ static void ata_raid_done(struct ata_request *request); static void ata_raid_config_changed(struct ar_softc *rdp, int writeback); static int ata_raid_status(struct ata_ioc_raid_status *status); static int ata_raid_create(struct ata_ioc_raid_config *config); static int ata_raid_delete(int array); static int ata_raid_addspare(struct ata_ioc_raid_config *config); static int ata_raid_rebuild(int array); static int ata_raid_read_metadata(device_t subdisk); static int ata_raid_write_metadata(struct ar_softc *rdp); static int ata_raid_wipe_metadata(struct ar_softc *rdp); static int ata_raid_adaptec_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_ddf_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_hptv2_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_hptv2_write_meta(struct ar_softc *rdp); static int ata_raid_hptv3_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_intel_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_intel_write_meta(struct ar_softc *rdp); static int ata_raid_ite_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_jmicron_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_jmicron_write_meta(struct ar_softc *rdp); static int ata_raid_lsiv2_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_lsiv3_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_nvidia_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_promise_read_meta(device_t dev, struct ar_softc **raidp, int native); static int ata_raid_promise_write_meta(struct ar_softc *rdp); static int ata_raid_sii_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_sis_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_sis_write_meta(struct ar_softc *rdp); static int ata_raid_via_read_meta(device_t dev, struct ar_softc **raidp); static int ata_raid_via_write_meta(struct ar_softc *rdp); static struct ata_request *ata_raid_init_request(struct ar_softc *rdp, struct bio *bio); static int ata_raid_send_request(struct ata_request *request); static int ata_raid_rw(device_t dev, u_int64_t lba, void *data, u_int bcount, int flags); static char * ata_raid_format(struct ar_softc *rdp); static char * ata_raid_type(struct ar_softc *rdp); static char * ata_raid_flags(struct ar_softc *rdp); /* debugging only */ static void ata_raid_print_meta(struct ar_softc *meta); static void ata_raid_adaptec_print_meta(struct adaptec_raid_conf *meta); static void ata_raid_ddf_print_meta(uint8_t *meta); static void ata_raid_hptv2_print_meta(struct hptv2_raid_conf *meta); static void ata_raid_hptv3_print_meta(struct hptv3_raid_conf *meta); static void ata_raid_intel_print_meta(struct intel_raid_conf *meta); static void ata_raid_ite_print_meta(struct ite_raid_conf *meta); static void ata_raid_jmicron_print_meta(struct jmicron_raid_conf *meta); static void ata_raid_lsiv2_print_meta(struct lsiv2_raid_conf *meta); static void ata_raid_lsiv3_print_meta(struct lsiv3_raid_conf *meta); static void ata_raid_nvidia_print_meta(struct nvidia_raid_conf *meta); static void ata_raid_promise_print_meta(struct promise_raid_conf *meta); static void ata_raid_sii_print_meta(struct sii_raid_conf *meta); static void ata_raid_sis_print_meta(struct sis_raid_conf *meta); static void ata_raid_via_print_meta(struct via_raid_conf *meta); /* internal vars */ static struct ar_softc *ata_raid_arrays[MAX_ARRAYS]; static MALLOC_DEFINE(M_AR, "ar_driver", "ATA PseudoRAID driver"); static devclass_t ata_raid_sub_devclass; static int testing = 0; /* device structures */ static disk_strategy_t ata_raid_strategy; static dumper_t ata_raid_dump; static void ata_raid_attach(struct ar_softc *rdp, int writeback) { char buffer[32]; int disk; mtx_init(&rdp->lock, "ATA PseudoRAID metadata lock", NULL, MTX_DEF); ata_raid_config_changed(rdp, writeback); /* sanitize arrays total_size % (width * interleave) == 0 */ if (rdp->type == AR_T_RAID0 || rdp->type == AR_T_RAID01 || rdp->type == AR_T_RAID5) { rdp->total_sectors = (rdp->total_sectors/(rdp->interleave*rdp->width))* (rdp->interleave * rdp->width); sprintf(buffer, " (stripe %d KB)", (rdp->interleave * DEV_BSIZE) / 1024); } else buffer[0] = '\0'; rdp->disk = disk_alloc(); rdp->disk->d_strategy = ata_raid_strategy; rdp->disk->d_dump = ata_raid_dump; rdp->disk->d_name = "ar"; rdp->disk->d_sectorsize = DEV_BSIZE; rdp->disk->d_mediasize = (off_t)rdp->total_sectors * DEV_BSIZE; rdp->disk->d_fwsectors = rdp->sectors; rdp->disk->d_fwheads = rdp->heads; rdp->disk->d_maxsize = 128 * DEV_BSIZE; rdp->disk->d_drv1 = rdp; rdp->disk->d_unit = rdp->lun; /* we support flushing cache if all components support it */ /* XXX: not all components can be connected at this point */ rdp->disk->d_flags = DISKFLAG_CANFLUSHCACHE; for (disk = 0; disk < rdp->total_disks; disk++) { struct ata_device *atadev; if (rdp->disks[disk].dev == NULL) continue; if ((atadev = device_get_softc(rdp->disks[disk].dev)) == NULL) continue; if (atadev->param.support.command2 & ATA_SUPPORT_FLUSHCACHE) continue; rdp->disk->d_flags = 0; break; } disk_create(rdp->disk, DISK_VERSION); printf("ar%d: %juMB <%s %s%s> status: %s\n", rdp->lun, rdp->total_sectors / ((1024L * 1024L) / DEV_BSIZE), ata_raid_format(rdp), ata_raid_type(rdp), buffer, ata_raid_flags(rdp)); if (testing || bootverbose) printf("ar%d: %ju sectors [%dC/%dH/%dS] <%s> subdisks defined as:\n", rdp->lun, rdp->total_sectors, rdp->cylinders, rdp->heads, rdp->sectors, rdp->name); for (disk = 0; disk < rdp->total_disks; disk++) { printf("ar%d: disk%d ", rdp->lun, disk); if (rdp->disks[disk].dev) { if (rdp->disks[disk].flags & AR_DF_PRESENT) { /* status of this disk in the array */ if (rdp->disks[disk].flags & AR_DF_ONLINE) printf("READY "); else if (rdp->disks[disk].flags & AR_DF_SPARE) printf("SPARE "); else printf("FREE "); /* what type of disk is this in the array */ switch (rdp->type) { case AR_T_RAID1: case AR_T_RAID01: if (disk < rdp->width) printf("(master) "); else printf("(mirror) "); } /* which physical disk is used */ printf("using %s at ata%d-%s\n", device_get_nameunit(rdp->disks[disk].dev), device_get_unit(device_get_parent(rdp->disks[disk].dev)), (((struct ata_device *) device_get_softc(rdp->disks[disk].dev))->unit == ATA_MASTER) ? "master" : "slave"); } else if (rdp->disks[disk].flags & AR_DF_ASSIGNED) printf("DOWN\n"); else printf("INVALID no RAID config on this subdisk\n"); } else printf("DOWN no device found for this subdisk\n"); } } static int ata_raid_ioctl(u_long cmd, caddr_t data) { struct ata_ioc_raid_status *status = (struct ata_ioc_raid_status *)data; struct ata_ioc_raid_config *config = (struct ata_ioc_raid_config *)data; int *lun = (int *)data; int error = EOPNOTSUPP; switch (cmd) { case IOCATARAIDSTATUS: error = ata_raid_status(status); break; case IOCATARAIDCREATE: error = ata_raid_create(config); break; case IOCATARAIDDELETE: error = ata_raid_delete(*lun); break; case IOCATARAIDADDSPARE: error = ata_raid_addspare(config); break; case IOCATARAIDREBUILD: error = ata_raid_rebuild(*lun); break; } return error; } static int ata_raid_flush(struct bio *bp) { struct ar_softc *rdp = bp->bio_disk->d_drv1; struct ata_request *request; device_t dev; int disk, error; error = 0; bp->bio_pflags = 0; for (disk = 0; disk < rdp->total_disks; disk++) { if ((dev = rdp->disks[disk].dev) != NULL) bp->bio_pflags++; } for (disk = 0; disk < rdp->total_disks; disk++) { if ((dev = rdp->disks[disk].dev) == NULL) continue; if (!(request = ata_raid_init_request(rdp, bp))) return ENOMEM; request->dev = dev; request->u.ata.command = ATA_FLUSHCACHE; request->u.ata.lba = 0; request->u.ata.count = 0; request->u.ata.feature = 0; request->timeout = 1; request->retries = 0; request->flags |= ATA_R_ORDERED | ATA_R_DIRECT; ata_queue_request(request); } return 0; } static void ata_raid_strategy(struct bio *bp) { struct ar_softc *rdp = bp->bio_disk->d_drv1; struct ata_request *request; caddr_t data; u_int64_t blkno, lba, blk = 0; int count, chunk, drv, par = 0, change = 0; if (bp->bio_cmd == BIO_FLUSH) { int error; error = ata_raid_flush(bp); if (error != 0) biofinish(bp, NULL, error); return; } if (!(rdp->status & AR_S_READY) || (bp->bio_cmd != BIO_READ && bp->bio_cmd != BIO_WRITE)) { biofinish(bp, NULL, EIO); return; } bp->bio_resid = bp->bio_bcount; for (count = howmany(bp->bio_bcount, DEV_BSIZE), blkno = bp->bio_pblkno, data = bp->bio_data; count > 0; count -= chunk, blkno += chunk, data += (chunk * DEV_BSIZE)) { switch (rdp->type) { case AR_T_RAID1: drv = 0; lba = blkno; chunk = count; break; case AR_T_JBOD: case AR_T_SPAN: drv = 0; lba = blkno; while (lba >= rdp->disks[drv].sectors) lba -= rdp->disks[drv++].sectors; chunk = min(rdp->disks[drv].sectors - lba, count); break; case AR_T_RAID0: case AR_T_RAID01: chunk = blkno % rdp->interleave; drv = (blkno / rdp->interleave) % rdp->width; lba = (((blkno/rdp->interleave)/rdp->width)*rdp->interleave)+chunk; chunk = min(count, rdp->interleave - chunk); break; case AR_T_RAID5: drv = (blkno / rdp->interleave) % (rdp->width - 1); par = rdp->width - 1 - (blkno / (rdp->interleave * (rdp->width - 1))) % rdp->width; if (drv >= par) drv++; lba = ((blkno/rdp->interleave)/(rdp->width-1))*(rdp->interleave) + ((blkno%(rdp->interleave*(rdp->width-1)))%rdp->interleave); chunk = min(count, rdp->interleave - (lba % rdp->interleave)); break; default: printf("ar%d: unknown array type in ata_raid_strategy\n", rdp->lun); biofinish(bp, NULL, EIO); return; } /* offset on all but "first on HPTv2" */ if (!(drv == 0 && rdp->format == AR_F_HPTV2_RAID)) lba += rdp->offset_sectors; if (!(request = ata_raid_init_request(rdp, bp))) { biofinish(bp, NULL, EIO); return; } request->data = data; request->bytecount = chunk * DEV_BSIZE; request->u.ata.lba = lba; request->u.ata.count = request->bytecount / DEV_BSIZE; switch (rdp->type) { case AR_T_JBOD: case AR_T_SPAN: case AR_T_RAID0: if (((rdp->disks[drv].flags & (AR_DF_PRESENT|AR_DF_ONLINE)) == (AR_DF_PRESENT|AR_DF_ONLINE) && !rdp->disks[drv].dev)) { rdp->disks[drv].flags &= ~AR_DF_ONLINE; ata_raid_config_changed(rdp, 1); ata_free_request(request); biofinish(bp, NULL, EIO); return; } request->this = drv; request->dev = rdp->disks[request->this].dev; ata_raid_send_request(request); break; case AR_T_RAID1: case AR_T_RAID01: if ((rdp->disks[drv].flags & (AR_DF_PRESENT|AR_DF_ONLINE))==(AR_DF_PRESENT|AR_DF_ONLINE) && !rdp->disks[drv].dev) { rdp->disks[drv].flags &= ~AR_DF_ONLINE; change = 1; } if ((rdp->disks[drv + rdp->width].flags & (AR_DF_PRESENT|AR_DF_ONLINE))==(AR_DF_PRESENT|AR_DF_ONLINE) && !rdp->disks[drv + rdp->width].dev) { rdp->disks[drv + rdp->width].flags &= ~AR_DF_ONLINE; change = 1; } if (change) ata_raid_config_changed(rdp, 1); if (!(rdp->status & AR_S_READY)) { ata_free_request(request); biofinish(bp, NULL, EIO); return; } if (rdp->status & AR_S_REBUILDING) blk = ((lba / rdp->interleave) * rdp->width) * rdp->interleave + (rdp->interleave * (drv % rdp->width)) + lba % rdp->interleave;; if (bp->bio_cmd == BIO_READ) { int src_online = (rdp->disks[drv].flags & AR_DF_ONLINE); int mir_online = (rdp->disks[drv+rdp->width].flags & AR_DF_ONLINE); /* if mirror gone or close to last access on source */ if (!mir_online || ((src_online) && bp->bio_pblkno >= (rdp->disks[drv].last_lba - AR_PROXIMITY) && bp->bio_pblkno <= (rdp->disks[drv].last_lba + AR_PROXIMITY))) { rdp->toggle = 0; } /* if source gone or close to last access on mirror */ else if (!src_online || ((mir_online) && bp->bio_pblkno >= (rdp->disks[drv+rdp->width].last_lba-AR_PROXIMITY) && bp->bio_pblkno <= (rdp->disks[drv+rdp->width].last_lba+AR_PROXIMITY))) { drv += rdp->width; rdp->toggle = 1; } /* not close to any previous access, toggle */ else { if (rdp->toggle) rdp->toggle = 0; else { drv += rdp->width; rdp->toggle = 1; } } if ((rdp->status & AR_S_REBUILDING) && (blk <= rdp->rebuild_lba) && ((blk + chunk) > rdp->rebuild_lba)) { struct ata_composite *composite; struct ata_request *rebuild; int this; /* figure out what part to rebuild */ if (drv < rdp->width) this = drv + rdp->width; else this = drv - rdp->width; /* do we have a spare to rebuild on ? */ if (rdp->disks[this].flags & AR_DF_SPARE) { if ((composite = ata_alloc_composite())) { if ((rebuild = ata_alloc_request())) { rdp->rebuild_lba = blk + chunk; bcopy(request, rebuild, sizeof(struct ata_request)); rebuild->this = this; rebuild->dev = rdp->disks[this].dev; rebuild->flags &= ~ATA_R_READ; rebuild->flags |= ATA_R_WRITE; mtx_init(&composite->lock, "ATA PseudoRAID rebuild lock", NULL, MTX_DEF); composite->residual = request->bytecount; composite->rd_needed |= (1 << drv); composite->wr_depend |= (1 << drv); composite->wr_needed |= (1 << this); composite->request[drv] = request; composite->request[this] = rebuild; request->composite = composite; rebuild->composite = composite; ata_raid_send_request(rebuild); } else { ata_free_composite(composite); printf("DOH! ata_alloc_request failed!\n"); } } else { printf("DOH! ata_alloc_composite failed!\n"); } } else if (rdp->disks[this].flags & AR_DF_ONLINE) { /* * if we got here we are a chunk of a RAID01 that * does not need a rebuild, but we need to increment * the rebuild_lba address to get the rebuild to * move to the next chunk correctly */ rdp->rebuild_lba = blk + chunk; } else printf("DOH! we didn't find the rebuild part\n"); } } if (bp->bio_cmd == BIO_WRITE) { if ((rdp->disks[drv+rdp->width].flags & AR_DF_ONLINE) || ((rdp->status & AR_S_REBUILDING) && (rdp->disks[drv+rdp->width].flags & AR_DF_SPARE) && ((blk < rdp->rebuild_lba) || ((blk <= rdp->rebuild_lba) && ((blk + chunk) > rdp->rebuild_lba))))) { if ((rdp->disks[drv].flags & AR_DF_ONLINE) || ((rdp->status & AR_S_REBUILDING) && (rdp->disks[drv].flags & AR_DF_SPARE) && ((blk < rdp->rebuild_lba) || ((blk <= rdp->rebuild_lba) && ((blk + chunk) > rdp->rebuild_lba))))) { struct ata_request *mirror; struct ata_composite *composite; int this = drv + rdp->width; if ((composite = ata_alloc_composite())) { if ((mirror = ata_alloc_request())) { if ((blk <= rdp->rebuild_lba) && ((blk + chunk) > rdp->rebuild_lba)) rdp->rebuild_lba = blk + chunk; bcopy(request, mirror, sizeof(struct ata_request)); mirror->this = this; mirror->dev = rdp->disks[this].dev; mtx_init(&composite->lock, "ATA PseudoRAID mirror lock", NULL, MTX_DEF); composite->residual = request->bytecount; composite->wr_needed |= (1 << drv); composite->wr_needed |= (1 << this); composite->request[drv] = request; composite->request[this] = mirror; request->composite = composite; mirror->composite = composite; ata_raid_send_request(mirror); rdp->disks[this].last_lba = bp->bio_pblkno + chunk; } else { ata_free_composite(composite); printf("DOH! ata_alloc_request failed!\n"); } } else { printf("DOH! ata_alloc_composite failed!\n"); } } else drv += rdp->width; } } request->this = drv; request->dev = rdp->disks[request->this].dev; ata_raid_send_request(request); rdp->disks[request->this].last_lba = bp->bio_pblkno + chunk; break; case AR_T_RAID5: if (((rdp->disks[drv].flags & (AR_DF_PRESENT|AR_DF_ONLINE)) == (AR_DF_PRESENT|AR_DF_ONLINE) && !rdp->disks[drv].dev)) { rdp->disks[drv].flags &= ~AR_DF_ONLINE; change = 1; } if (((rdp->disks[par].flags & (AR_DF_PRESENT|AR_DF_ONLINE)) == (AR_DF_PRESENT|AR_DF_ONLINE) && !rdp->disks[par].dev)) { rdp->disks[par].flags &= ~AR_DF_ONLINE; change = 1; } if (change) ata_raid_config_changed(rdp, 1); if (!(rdp->status & AR_S_READY)) { ata_free_request(request); biofinish(bp, NULL, EIO); return; } if (rdp->status & AR_S_DEGRADED) { /* do the XOR game if possible */ } else { request->this = drv; request->dev = rdp->disks[request->this].dev; if (bp->bio_cmd == BIO_READ) { ata_raid_send_request(request); } if (bp->bio_cmd == BIO_WRITE) { ata_raid_send_request(request); // sikre at læs-modify-skriv til hver disk er atomarisk. // par kopi af request // læse orgdata fra drv // skriv nydata til drv // læse parorgdata fra par // skriv orgdata xor parorgdata xor nydata til par } } break; default: printf("ar%d: unknown array type in ata_raid_strategy\n", rdp->lun); } } } static void ata_raid_done(struct ata_request *request) { struct ar_softc *rdp = request->driver; struct ata_composite *composite = NULL; struct bio *bp = request->bio; int i, mirror, finished = 0; if (bp->bio_cmd == BIO_FLUSH) { if (bp->bio_error == 0) bp->bio_error = request->result; ata_free_request(request); if (--bp->bio_pflags == 0) biodone(bp); return; } switch (rdp->type) { case AR_T_JBOD: case AR_T_SPAN: case AR_T_RAID0: if (request->result) { rdp->disks[request->this].flags &= ~AR_DF_ONLINE; ata_raid_config_changed(rdp, 1); bp->bio_error = request->result; finished = 1; } else { bp->bio_resid -= request->donecount; if (!bp->bio_resid) finished = 1; } break; case AR_T_RAID1: case AR_T_RAID01: if (request->this < rdp->width) mirror = request->this + rdp->width; else mirror = request->this - rdp->width; if (request->result) { rdp->disks[request->this].flags &= ~AR_DF_ONLINE; ata_raid_config_changed(rdp, 1); } if (rdp->status & AR_S_READY) { u_int64_t blk = 0; if (rdp->status & AR_S_REBUILDING) blk = ((request->u.ata.lba / rdp->interleave) * rdp->width) * rdp->interleave + (rdp->interleave * (request->this % rdp->width)) + request->u.ata.lba % rdp->interleave; if (bp->bio_cmd == BIO_READ) { /* is this a rebuild composite */ if ((composite = request->composite)) { mtx_lock(&composite->lock); /* handle the read part of a rebuild composite */ if (request->flags & ATA_R_READ) { /* if read failed array is now broken */ if (request->result) { rdp->disks[request->this].flags &= ~AR_DF_ONLINE; ata_raid_config_changed(rdp, 1); bp->bio_error = request->result; rdp->rebuild_lba = blk; finished = 1; } /* good data, update how far we've gotten */ else { bp->bio_resid -= request->donecount; composite->residual -= request->donecount; if (!composite->residual) { if (composite->wr_done & (1 << mirror)) finished = 1; } } } /* handle the write part of a rebuild composite */ else if (request->flags & ATA_R_WRITE) { if (composite->rd_done & (1 << mirror)) { if (request->result) { printf("DOH! rebuild failed\n"); /* XXX SOS */ rdp->rebuild_lba = blk; } if (!composite->residual) finished = 1; } } mtx_unlock(&composite->lock); } /* if read failed retry on the mirror */ else if (request->result) { request->dev = rdp->disks[mirror].dev; request->flags &= ~ATA_R_TIMEOUT; ata_raid_send_request(request); return; } /* we have good data */ else { bp->bio_resid -= request->donecount; if (!bp->bio_resid) finished = 1; } } else if (bp->bio_cmd == BIO_WRITE) { /* do we have a mirror or rebuild to deal with ? */ if ((composite = request->composite)) { mtx_lock(&composite->lock); if (composite->wr_done & (1 << mirror)) { if (request->result) { if (composite->request[mirror]->result) { printf("DOH! all disks failed and got here\n"); bp->bio_error = EIO; } if (rdp->status & AR_S_REBUILDING) { rdp->rebuild_lba = blk; printf("DOH! rebuild failed\n"); /* XXX SOS */ } bp->bio_resid -= composite->request[mirror]->donecount; composite->residual -= composite->request[mirror]->donecount; } else { bp->bio_resid -= request->donecount; composite->residual -= request->donecount; } if (!composite->residual) finished = 1; } mtx_unlock(&composite->lock); } /* no mirror we are done */ else { bp->bio_resid -= request->donecount; if (!bp->bio_resid) finished = 1; } } } else biofinish(bp, NULL, request->result); break; case AR_T_RAID5: if (request->result) { rdp->disks[request->this].flags &= ~AR_DF_ONLINE; ata_raid_config_changed(rdp, 1); if (rdp->status & AR_S_READY) { if (bp->bio_cmd == BIO_READ) { /* do the XOR game to recover data */ } if (bp->bio_cmd == BIO_WRITE) { /* if the parity failed we're OK sortof */ /* otherwise wee need to do the XOR long dance */ } finished = 1; } else biofinish(bp, NULL, request->result); } else { // did we have an XOR game going ?? bp->bio_resid -= request->donecount; if (!bp->bio_resid) finished = 1; } break; default: printf("ar%d: unknown array type in ata_raid_done\n", rdp->lun); } if (finished) { if ((rdp->status & AR_S_REBUILDING) && rdp->rebuild_lba >= rdp->total_sectors) { int disk; for (disk = 0; disk < rdp->total_disks; disk++) { if ((rdp->disks[disk].flags & (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_SPARE)) == (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_SPARE)) { rdp->disks[disk].flags &= ~AR_DF_SPARE; rdp->disks[disk].flags |= AR_DF_ONLINE; } } rdp->status &= ~AR_S_REBUILDING; ata_raid_config_changed(rdp, 1); } if (!bp->bio_resid) biodone(bp); } if (composite) { if (finished) { /* we are done with this composite, free all resources */ for (i = 0; i < 32; i++) { if (composite->rd_needed & (1 << i) || composite->wr_needed & (1 << i)) { ata_free_request(composite->request[i]); } } mtx_destroy(&composite->lock); ata_free_composite(composite); } } else ata_free_request(request); } static int ata_raid_dump(void *arg, void *virtual, vm_offset_t physical, off_t offset, size_t length) { struct disk *dp = arg; struct ar_softc *rdp = dp->d_drv1; struct bio bp; /* length zero is special and really means flush buffers to media */ if (!length) { int disk, error; for (disk = 0, error = 0; disk < rdp->total_disks; disk++) if (rdp->disks[disk].dev) error |= ata_controlcmd(rdp->disks[disk].dev, ATA_FLUSHCACHE, 0, 0, 0); return (error ? EIO : 0); } bzero(&bp, sizeof(struct bio)); bp.bio_disk = dp; bp.bio_pblkno = offset / DEV_BSIZE; bp.bio_bcount = length; bp.bio_data = virtual; bp.bio_cmd = BIO_WRITE; ata_raid_strategy(&bp); return bp.bio_error; } static void ata_raid_config_changed(struct ar_softc *rdp, int writeback) { int disk, count, status; mtx_lock(&rdp->lock); /* set default all working mode */ status = rdp->status; rdp->status &= ~AR_S_DEGRADED; rdp->status |= AR_S_READY; /* make sure all lost drives are accounted for */ for (disk = 0; disk < rdp->total_disks; disk++) { if (!(rdp->disks[disk].flags & AR_DF_PRESENT)) rdp->disks[disk].flags &= ~AR_DF_ONLINE; } /* depending on RAID type figure out our health status */ switch (rdp->type) { case AR_T_JBOD: case AR_T_SPAN: case AR_T_RAID0: for (disk = 0; disk < rdp->total_disks; disk++) if (!(rdp->disks[disk].flags & AR_DF_ONLINE)) rdp->status &= ~AR_S_READY; break; case AR_T_RAID1: case AR_T_RAID01: for (disk = 0; disk < rdp->width; disk++) { if (!(rdp->disks[disk].flags & AR_DF_ONLINE) && !(rdp->disks[disk + rdp->width].flags & AR_DF_ONLINE)) { rdp->status &= ~AR_S_READY; } else if (((rdp->disks[disk].flags & AR_DF_ONLINE) && !(rdp->disks[disk + rdp->width].flags & AR_DF_ONLINE)) || (!(rdp->disks[disk].flags & AR_DF_ONLINE) && (rdp->disks [disk + rdp->width].flags & AR_DF_ONLINE))) { rdp->status |= AR_S_DEGRADED; } } break; case AR_T_RAID5: for (count = 0, disk = 0; disk < rdp->total_disks; disk++) { if (!(rdp->disks[disk].flags & AR_DF_ONLINE)) count++; } if (count) { if (count > 1) rdp->status &= ~AR_S_READY; else rdp->status |= AR_S_DEGRADED; } break; default: rdp->status &= ~AR_S_READY; } if (rdp->status != status) { if (!(rdp->status & AR_S_READY)) { printf("ar%d: FAILURE - %s array broken\n", rdp->lun, ata_raid_type(rdp)); } else if (rdp->status & AR_S_DEGRADED) { if (rdp->type & (AR_T_RAID1 | AR_T_RAID01)) printf("ar%d: WARNING - mirror", rdp->lun); else printf("ar%d: WARNING - parity", rdp->lun); printf(" protection lost. %s array in DEGRADED mode\n", ata_raid_type(rdp)); } } mtx_unlock(&rdp->lock); if (writeback) ata_raid_write_metadata(rdp); } static int ata_raid_status(struct ata_ioc_raid_status *status) { struct ar_softc *rdp; int i; if (!(rdp = ata_raid_arrays[status->lun])) return ENXIO; status->type = rdp->type; status->total_disks = rdp->total_disks; for (i = 0; i < rdp->total_disks; i++ ) { status->disks[i].state = 0; if ((rdp->disks[i].flags & AR_DF_PRESENT) && rdp->disks[i].dev) { status->disks[i].lun = device_get_unit(rdp->disks[i].dev); if (rdp->disks[i].flags & AR_DF_PRESENT) status->disks[i].state |= AR_DISK_PRESENT; if (rdp->disks[i].flags & AR_DF_ONLINE) status->disks[i].state |= AR_DISK_ONLINE; if (rdp->disks[i].flags & AR_DF_SPARE) status->disks[i].state |= AR_DISK_SPARE; } else status->disks[i].lun = -1; } status->interleave = rdp->interleave; status->status = rdp->status; status->progress = 100 * rdp->rebuild_lba / rdp->total_sectors; return 0; } static int ata_raid_create(struct ata_ioc_raid_config *config) { struct ar_softc *rdp; device_t subdisk; int array, disk; int ctlr = 0, disk_size = 0, total_disks = 0; for (array = 0; array < MAX_ARRAYS; array++) { if (!ata_raid_arrays[array]) break; } if (array >= MAX_ARRAYS) return ENOSPC; if (!(rdp = (struct ar_softc*)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: no memory for metadata storage\n", array); return ENOMEM; } for (disk = 0; disk < config->total_disks; disk++) { if ((subdisk = devclass_get_device(ata_raid_sub_devclass, config->disks[disk]))) { struct ata_raid_subdisk *ars = device_get_softc(subdisk); /* is device already assigned to another array ? */ if (ars->raid[rdp->volume]) { config->disks[disk] = -1; free(rdp, M_AR); return EBUSY; } rdp->disks[disk].dev = device_get_parent(subdisk); switch (pci_get_vendor(GRANDPARENT(rdp->disks[disk].dev))) { case ATA_HIGHPOINT_ID: /* * we need some way to decide if it should be v2 or v3 * for now just use v2 since the v3 BIOS knows how to * handle that as well. */ ctlr = AR_F_HPTV2_RAID; rdp->disks[disk].sectors = HPTV3_LBA(rdp->disks[disk].dev); break; case ATA_INTEL_ID: ctlr = AR_F_INTEL_RAID; rdp->disks[disk].sectors = INTEL_LBA(rdp->disks[disk].dev); break; case ATA_ITE_ID: ctlr = AR_F_ITE_RAID; rdp->disks[disk].sectors = ITE_LBA(rdp->disks[disk].dev); break; case ATA_JMICRON_ID: ctlr = AR_F_JMICRON_RAID; rdp->disks[disk].sectors = JMICRON_LBA(rdp->disks[disk].dev); break; case 0: /* XXX SOS cover up for bug in our PCI code */ case ATA_PROMISE_ID: ctlr = AR_F_PROMISE_RAID; rdp->disks[disk].sectors = PROMISE_LBA(rdp->disks[disk].dev); break; case ATA_SIS_ID: ctlr = AR_F_SIS_RAID; rdp->disks[disk].sectors = SIS_LBA(rdp->disks[disk].dev); break; case ATA_ATI_ID: case ATA_VIA_ID: ctlr = AR_F_VIA_RAID; rdp->disks[disk].sectors = VIA_LBA(rdp->disks[disk].dev); break; default: /* XXX SOS * right, so here we are, we have an ATA chip and we want * to create a RAID and store the metadata. * we need to find a way to tell what kind of metadata this * hardware's BIOS might be using (good ideas are welcomed) * for now we just use our own native FreeBSD format. * the only way to get support for the BIOS format is to * setup the RAID from there, in that case we pickup the * metadata format from the disks (if we support it). */ printf("WARNING!! - not able to determine metadata format\n" "WARNING!! - Using FreeBSD PseudoRAID metadata\n" "If that is not what you want, use the BIOS to " "create the array\n"); ctlr = AR_F_FREEBSD_RAID; rdp->disks[disk].sectors = PROMISE_LBA(rdp->disks[disk].dev); break; } /* we need all disks to be of the same format */ if ((rdp->format & AR_F_FORMAT_MASK) && (rdp->format & AR_F_FORMAT_MASK) != (ctlr & AR_F_FORMAT_MASK)) { free(rdp, M_AR); return EXDEV; } else rdp->format = ctlr; /* use the smallest disk of the lots size */ /* gigabyte boundry ??? XXX SOS */ if (disk_size) disk_size = min(rdp->disks[disk].sectors, disk_size); else disk_size = rdp->disks[disk].sectors; rdp->disks[disk].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE); total_disks++; } else { config->disks[disk] = -1; free(rdp, M_AR); return ENXIO; } } if (total_disks != config->total_disks) { free(rdp, M_AR); return ENODEV; } switch (config->type) { case AR_T_JBOD: case AR_T_SPAN: case AR_T_RAID0: break; case AR_T_RAID1: if (total_disks != 2) { free(rdp, M_AR); return EPERM; } break; case AR_T_RAID01: if (total_disks % 2 != 0) { free(rdp, M_AR); return EPERM; } break; case AR_T_RAID5: if (total_disks < 3) { free(rdp, M_AR); return EPERM; } break; default: free(rdp, M_AR); return EOPNOTSUPP; } rdp->type = config->type; rdp->lun = array; if (rdp->type == AR_T_RAID0 || rdp->type == AR_T_RAID01 || rdp->type == AR_T_RAID5) { int bit = 0; while (config->interleave >>= 1) bit++; rdp->interleave = 1 << bit; } rdp->offset_sectors = 0; /* values that depend on metadata format */ switch (rdp->format) { case AR_F_ADAPTEC_RAID: rdp->interleave = min(max(32, rdp->interleave), 128); /*+*/ break; case AR_F_HPTV2_RAID: rdp->interleave = min(max(8, rdp->interleave), 128); /*+*/ rdp->offset_sectors = HPTV2_LBA(x) + 1; break; case AR_F_HPTV3_RAID: rdp->interleave = min(max(32, rdp->interleave), 4096); /*+*/ break; case AR_F_INTEL_RAID: rdp->interleave = min(max(8, rdp->interleave), 256); /*+*/ break; case AR_F_ITE_RAID: rdp->interleave = min(max(2, rdp->interleave), 128); /*+*/ break; case AR_F_JMICRON_RAID: rdp->interleave = min(max(8, rdp->interleave), 256); /*+*/ break; case AR_F_LSIV2_RAID: rdp->interleave = min(max(2, rdp->interleave), 4096); break; case AR_F_LSIV3_RAID: rdp->interleave = min(max(2, rdp->interleave), 256); break; case AR_F_PROMISE_RAID: rdp->interleave = min(max(2, rdp->interleave), 2048); /*+*/ break; case AR_F_SII_RAID: rdp->interleave = min(max(8, rdp->interleave), 256); /*+*/ break; case AR_F_SIS_RAID: rdp->interleave = min(max(32, rdp->interleave), 512); /*+*/ break; case AR_F_VIA_RAID: rdp->interleave = min(max(8, rdp->interleave), 128); /*+*/ break; } rdp->total_disks = total_disks; rdp->width = total_disks / (rdp->type & (AR_RAID1 | AR_T_RAID01) ? 2 : 1); rdp->total_sectors = disk_size * (rdp->width - (rdp->type == AR_RAID5)); rdp->heads = 255; rdp->sectors = 63; rdp->cylinders = rdp->total_sectors / (255 * 63); rdp->rebuild_lba = 0; rdp->status |= AR_S_READY; /* we are committed to this array, grap the subdisks */ for (disk = 0; disk < config->total_disks; disk++) { if ((subdisk = devclass_get_device(ata_raid_sub_devclass, config->disks[disk]))) { struct ata_raid_subdisk *ars = device_get_softc(subdisk); ars->raid[rdp->volume] = rdp; ars->disk_number[rdp->volume] = disk; } } ata_raid_attach(rdp, 1); ata_raid_arrays[array] = rdp; config->lun = array; return 0; } static int ata_raid_delete(int array) { struct ar_softc *rdp; device_t subdisk; int disk; if (!(rdp = ata_raid_arrays[array])) return ENXIO; rdp->status &= ~AR_S_READY; if (rdp->disk) disk_destroy(rdp->disk); for (disk = 0; disk < rdp->total_disks; disk++) { if ((rdp->disks[disk].flags & AR_DF_PRESENT) && rdp->disks[disk].dev) { if ((subdisk = devclass_get_device(ata_raid_sub_devclass, device_get_unit(rdp->disks[disk].dev)))) { struct ata_raid_subdisk *ars = device_get_softc(subdisk); if (ars->raid[rdp->volume] != rdp) /* XXX SOS */ device_printf(subdisk, "DOH! this disk doesn't belong\n"); if (ars->disk_number[rdp->volume] != disk) /* XXX SOS */ device_printf(subdisk, "DOH! this disk number is wrong\n"); ars->raid[rdp->volume] = NULL; ars->disk_number[rdp->volume] = -1; } rdp->disks[disk].flags = 0; } } ata_raid_wipe_metadata(rdp); ata_raid_arrays[array] = NULL; free(rdp, M_AR); return 0; } static int ata_raid_addspare(struct ata_ioc_raid_config *config) { struct ar_softc *rdp; device_t subdisk; int disk; if (!(rdp = ata_raid_arrays[config->lun])) return ENXIO; if (!(rdp->status & AR_S_DEGRADED) || !(rdp->status & AR_S_READY)) return ENXIO; if (rdp->status & AR_S_REBUILDING) return EBUSY; switch (rdp->type) { case AR_T_RAID1: case AR_T_RAID01: case AR_T_RAID5: for (disk = 0; disk < rdp->total_disks; disk++ ) { if (((rdp->disks[disk].flags & (AR_DF_PRESENT | AR_DF_ONLINE)) == (AR_DF_PRESENT | AR_DF_ONLINE)) && rdp->disks[disk].dev) continue; if ((subdisk = devclass_get_device(ata_raid_sub_devclass, config->disks[0] ))) { struct ata_raid_subdisk *ars = device_get_softc(subdisk); if (ars->raid[rdp->volume]) return EBUSY; /* XXX SOS validate size etc etc */ ars->raid[rdp->volume] = rdp; ars->disk_number[rdp->volume] = disk; rdp->disks[disk].dev = device_get_parent(subdisk); rdp->disks[disk].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_SPARE); device_printf(rdp->disks[disk].dev, "inserted into ar%d disk%d as spare\n", rdp->lun, disk); ata_raid_config_changed(rdp, 1); return 0; } } return ENXIO; default: return EPERM; } } static int ata_raid_rebuild(int array) { struct ar_softc *rdp; int disk, count; if (!(rdp = ata_raid_arrays[array])) return ENXIO; /* XXX SOS we should lock the rdp softc here */ if (!(rdp->status & AR_S_DEGRADED) || !(rdp->status & AR_S_READY)) return ENXIO; if (rdp->status & AR_S_REBUILDING) return EBUSY; switch (rdp->type) { case AR_T_RAID1: case AR_T_RAID01: case AR_T_RAID5: for (count = 0, disk = 0; disk < rdp->total_disks; disk++ ) { if (((rdp->disks[disk].flags & (AR_DF_PRESENT|AR_DF_ASSIGNED|AR_DF_ONLINE|AR_DF_SPARE)) == (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_SPARE)) && rdp->disks[disk].dev) { count++; } } if (count) { rdp->rebuild_lba = 0; rdp->status |= AR_S_REBUILDING; return 0; } return EIO; default: return EPERM; } } static int ata_raid_read_metadata(device_t subdisk) { devclass_t pci_devclass = devclass_find("pci"); devclass_t devclass=device_get_devclass(GRANDPARENT(GRANDPARENT(subdisk))); /* prioritize vendor native metadata layout if possible */ if (devclass == pci_devclass) { switch (pci_get_vendor(GRANDPARENT(device_get_parent(subdisk)))) { case ATA_HIGHPOINT_ID: if (ata_raid_hptv3_read_meta(subdisk, ata_raid_arrays)) return 0; if (ata_raid_hptv2_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_INTEL_ID: if (ata_raid_intel_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_ITE_ID: if (ata_raid_ite_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_JMICRON_ID: if (ata_raid_jmicron_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_NVIDIA_ID: if (ata_raid_nvidia_read_meta(subdisk, ata_raid_arrays)) return 0; break; case 0: /* XXX SOS cover up for bug in our PCI code */ case ATA_PROMISE_ID: if (ata_raid_promise_read_meta(subdisk, ata_raid_arrays, 0)) return 0; break; case ATA_ATI_ID: case ATA_SILICON_IMAGE_ID: if (ata_raid_sii_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_SIS_ID: if (ata_raid_sis_read_meta(subdisk, ata_raid_arrays)) return 0; break; case ATA_VIA_ID: if (ata_raid_via_read_meta(subdisk, ata_raid_arrays)) return 0; break; } } /* handle controllers that have multiple layout possibilities */ /* NOTE: the order of these are not insignificant */ /* Adaptec HostRAID */ if (ata_raid_adaptec_read_meta(subdisk, ata_raid_arrays)) return 0; /* LSILogic v3 and v2 */ if (ata_raid_lsiv3_read_meta(subdisk, ata_raid_arrays)) return 0; if (ata_raid_lsiv2_read_meta(subdisk, ata_raid_arrays)) return 0; /* DDF (used by Adaptec, maybe others) */ if (ata_raid_ddf_read_meta(subdisk, ata_raid_arrays)) return 0; /* if none of the above matched, try FreeBSD native format */ return ata_raid_promise_read_meta(subdisk, ata_raid_arrays, 1); } static int ata_raid_write_metadata(struct ar_softc *rdp) { switch (rdp->format) { case AR_F_FREEBSD_RAID: case AR_F_PROMISE_RAID: return ata_raid_promise_write_meta(rdp); case AR_F_HPTV3_RAID: case AR_F_HPTV2_RAID: /* * always write HPT v2 metadata, the v3 BIOS knows it as well. * this is handy since we cannot know what version BIOS is on there */ return ata_raid_hptv2_write_meta(rdp); case AR_F_INTEL_RAID: return ata_raid_intel_write_meta(rdp); case AR_F_JMICRON_RAID: return ata_raid_jmicron_write_meta(rdp); case AR_F_SIS_RAID: return ata_raid_sis_write_meta(rdp); case AR_F_VIA_RAID: return ata_raid_via_write_meta(rdp); #if 0 case AR_F_HPTV3_RAID: return ata_raid_hptv3_write_meta(rdp); case AR_F_ADAPTEC_RAID: return ata_raid_adaptec_write_meta(rdp); case AR_F_ITE_RAID: return ata_raid_ite_write_meta(rdp); case AR_F_LSIV2_RAID: return ata_raid_lsiv2_write_meta(rdp); case AR_F_LSIV3_RAID: return ata_raid_lsiv3_write_meta(rdp); case AR_F_NVIDIA_RAID: return ata_raid_nvidia_write_meta(rdp); case AR_F_SII_RAID: return ata_raid_sii_write_meta(rdp); #endif default: printf("ar%d: writing of %s metadata is NOT supported yet\n", rdp->lun, ata_raid_format(rdp)); } return -1; } static int ata_raid_wipe_metadata(struct ar_softc *rdp) { int disk, error = 0; u_int64_t lba; u_int32_t size; u_int8_t *meta; for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { switch (rdp->format) { case AR_F_ADAPTEC_RAID: lba = ADP_LBA(rdp->disks[disk].dev); size = sizeof(struct adaptec_raid_conf); break; case AR_F_HPTV2_RAID: lba = HPTV2_LBA(rdp->disks[disk].dev); size = sizeof(struct hptv2_raid_conf); break; case AR_F_HPTV3_RAID: lba = HPTV3_LBA(rdp->disks[disk].dev); size = sizeof(struct hptv3_raid_conf); break; case AR_F_INTEL_RAID: lba = INTEL_LBA(rdp->disks[disk].dev); size = 3 * 512; /* XXX SOS */ break; case AR_F_ITE_RAID: lba = ITE_LBA(rdp->disks[disk].dev); size = sizeof(struct ite_raid_conf); break; case AR_F_JMICRON_RAID: lba = JMICRON_LBA(rdp->disks[disk].dev); size = sizeof(struct jmicron_raid_conf); break; case AR_F_LSIV2_RAID: lba = LSIV2_LBA(rdp->disks[disk].dev); size = sizeof(struct lsiv2_raid_conf); break; case AR_F_LSIV3_RAID: lba = LSIV3_LBA(rdp->disks[disk].dev); size = sizeof(struct lsiv3_raid_conf); break; case AR_F_NVIDIA_RAID: lba = NVIDIA_LBA(rdp->disks[disk].dev); size = sizeof(struct nvidia_raid_conf); break; case AR_F_FREEBSD_RAID: case AR_F_PROMISE_RAID: lba = PROMISE_LBA(rdp->disks[disk].dev); size = sizeof(struct promise_raid_conf); break; case AR_F_SII_RAID: lba = SII_LBA(rdp->disks[disk].dev); size = sizeof(struct sii_raid_conf); break; case AR_F_SIS_RAID: lba = SIS_LBA(rdp->disks[disk].dev); size = sizeof(struct sis_raid_conf); break; case AR_F_VIA_RAID: lba = VIA_LBA(rdp->disks[disk].dev); size = sizeof(struct via_raid_conf); break; default: printf("ar%d: wiping of %s metadata is NOT supported yet\n", rdp->lun, ata_raid_format(rdp)); return ENXIO; } if (!(meta = malloc(size, M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(rdp->disks[disk].dev, lba, meta, size, ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "wipe metadata failed\n"); error = EIO; } free(meta, M_AR); } } return error; } /* Adaptec HostRAID Metadata */ static int ata_raid_adaptec_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct adaptec_raid_conf *meta; struct ar_softc *raid; int array, disk, retval = 0; if (!(meta = (struct adaptec_raid_conf *) malloc(sizeof(struct adaptec_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, ADP_LBA(parent), meta, sizeof(struct adaptec_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "Adaptec read metadata failed\n"); goto adaptec_out; } /* check if this is a Adaptec RAID struct */ if (meta->magic_0 != ADP_MAGIC_0 || meta->magic_3 != ADP_MAGIC_3) { if (testing || bootverbose) device_printf(parent, "Adaptec check1 failed\n"); goto adaptec_out; } if (testing || bootverbose) ata_raid_adaptec_print_meta(meta); /* now convert Adaptec metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto adaptec_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_ADAPTEC_RAID)) continue; if (raid->magic_0 && raid->magic_0 != meta->configs[0].magic_0) continue; if (!meta->generation || be32toh(meta->generation) > raid->generation) { switch (meta->configs[0].type) { case ADP_T_RAID0: raid->magic_0 = meta->configs[0].magic_0; raid->type = AR_T_RAID0; raid->interleave = 1 << (meta->configs[0].stripe_shift >> 1); raid->width = be16toh(meta->configs[0].total_disks); break; case ADP_T_RAID1: raid->magic_0 = meta->configs[0].magic_0; raid->type = AR_T_RAID1; raid->width = be16toh(meta->configs[0].total_disks) / 2; break; default: device_printf(parent, "Adaptec unknown RAID type 0x%02x\n", meta->configs[0].type); free(raidp[array], M_AR); raidp[array] = NULL; goto adaptec_out; } raid->format = AR_F_ADAPTEC_RAID; raid->generation = be32toh(meta->generation); raid->total_disks = be16toh(meta->configs[0].total_disks); raid->total_sectors = be32toh(meta->configs[0].sectors); raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; strncpy(raid->name, meta->configs[0].name, min(sizeof(raid->name), sizeof(meta->configs[0].name))); /* clear out any old info */ if (raid->generation) { for (disk = 0; disk < raid->total_disks; disk++) { raid->disks[disk].dev = NULL; raid->disks[disk].flags = 0; } } } if (be32toh(meta->generation) >= raid->generation) { struct ata_device *atadev = device_get_softc(parent); struct ata_channel *ch = device_get_softc(GRANDPARENT(dev)); int disk_number = (ch->unit << !(ch->flags & ATA_NO_SLAVE)) + ATA_DEV(atadev->unit); raid->disks[disk_number].dev = parent; raid->disks[disk_number].sectors = be32toh(meta->configs[disk_number + 1].sectors); raid->disks[disk_number].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; } break; } adaptec_out: free(meta, M_AR); return retval; } static uint64_t ddfbe64toh(uint64_t val) { return (be64toh(val)); } static uint32_t ddfbe32toh(uint32_t val) { return (be32toh(val)); } static uint16_t ddfbe16toh(uint16_t val) { return (be16toh(val)); } static uint64_t ddfle64toh(uint64_t val) { return (le64toh(val)); } static uint32_t ddfle32toh(uint32_t val) { return (le32toh(val)); } static uint16_t ddfle16toh(uint16_t val) { return (le16toh(val)); } static int ata_raid_ddf_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars; device_t parent = device_get_parent(dev); struct ddf_header *hdr; struct ddf_pd_record *pdr; struct ddf_pd_entry *pde = NULL; struct ddf_vd_record *vdr; struct ddf_pdd_record *pdd; struct ddf_sa_record *sa = NULL; struct ddf_vdc_record *vdcr = NULL; struct ddf_vd_entry *vde = NULL; struct ar_softc *raid; uint64_t pri_lba; uint32_t pd_ref, pd_pos; uint8_t *meta, *cr; int hdr_len, vd_state = 0, pd_state = 0; int i, disk, array, retval = 0; uintptr_t max_cr_addr; uint64_t (*ddf64toh)(uint64_t) = NULL; uint32_t (*ddf32toh)(uint32_t) = NULL; uint16_t (*ddf16toh)(uint16_t) = NULL; ars = device_get_softc(dev); raid = NULL; /* Read in the anchor header */ if (!(meta = malloc(DDF_HEADER_LENGTH, M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, DDF_LBA(parent), meta, DDF_HEADER_LENGTH, ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "DDF read metadata failed\n"); goto ddf_out; } /* * Check if this is a DDF RAID struct. Note the apparent "flexibility" * regarding endianness. */ hdr = (struct ddf_header *)meta; if (be32toh(hdr->Signature) == DDF_HEADER_SIGNATURE) { ddf64toh = ddfbe64toh; ddf32toh = ddfbe32toh; ddf16toh = ddfbe16toh; } else if (le32toh(hdr->Signature) == DDF_HEADER_SIGNATURE) { ddf64toh = ddfle64toh; ddf32toh = ddfle32toh; ddf16toh = ddfle16toh; } else goto ddf_out; if (hdr->Header_Type != DDF_HEADER_ANCHOR) { if (testing || bootverbose) device_printf(parent, "DDF check1 failed\n"); goto ddf_out; } pri_lba = ddf64toh(hdr->Primary_Header_LBA); hdr_len = ddf32toh(hdr->cd_section) + ddf32toh(hdr->cd_length); hdr_len = max(hdr_len,ddf32toh(hdr->pdr_section)+ddf32toh(hdr->pdr_length)); hdr_len = max(hdr_len,ddf32toh(hdr->vdr_section)+ddf32toh(hdr->vdr_length)); hdr_len = max(hdr_len,ddf32toh(hdr->cr_section) +ddf32toh(hdr->cr_length)); hdr_len = max(hdr_len,ddf32toh(hdr->pdd_section)+ddf32toh(hdr->pdd_length)); if (testing || bootverbose) device_printf(parent, "DDF pri_lba= %llu length= %d blocks\n", (unsigned long long)pri_lba, hdr_len); if ((pri_lba + hdr_len) > DDF_LBA(parent)) { device_printf(parent, "DDF exceeds length of disk\n"); goto ddf_out; } /* Don't need the anchor anymore, read the rest of the metadata */ free(meta, M_AR); if (!(meta = malloc(hdr_len * DEV_BSIZE, M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, pri_lba, meta, hdr_len * DEV_BSIZE, ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "DDF read full metadata failed\n"); goto ddf_out; } /* Check that we got a Primary Header */ hdr = (struct ddf_header *)meta; if ((ddf32toh(hdr->Signature) != DDF_HEADER_SIGNATURE) || (hdr->Header_Type != DDF_HEADER_PRIMARY)) { if (testing || bootverbose) device_printf(parent, "DDF check2 failed\n"); goto ddf_out; } if (testing || bootverbose) ata_raid_ddf_print_meta(meta); if ((hdr->Open_Flag >= 0x01) && (hdr->Open_Flag <= 0x0f)) { device_printf(parent, "DDF Header open, possibly corrupt metadata\n"); goto ddf_out; } pdr = (struct ddf_pd_record*)(meta + ddf32toh(hdr->pdr_section)*DEV_BSIZE); vdr = (struct ddf_vd_record*)(meta + ddf32toh(hdr->vdr_section)*DEV_BSIZE); cr = (uint8_t *)(meta + ddf32toh(hdr->cr_section)*DEV_BSIZE); pdd = (struct ddf_pdd_record*)(meta + ddf32toh(hdr->pdd_section)*DEV_BSIZE); /* Verify the Physical Disk Device Record */ if (ddf32toh(pdd->Signature) != DDF_PDD_SIGNATURE) { device_printf(parent, "Invalid PD Signature\n"); goto ddf_out; } pd_ref = ddf32toh(pdd->PD_Reference); pd_pos = -1; /* Verify the Physical Disk Record and make sure the disk is usable */ if (ddf32toh(pdr->Signature) != DDF_PDR_SIGNATURE) { device_printf(parent, "Invalid PDR Signature\n"); goto ddf_out; } for (i = 0; i < ddf16toh(pdr->Populated_PDEs); i++) { if (ddf32toh(pdr->entry[i].PD_Reference) != pd_ref) continue; pde = &pdr->entry[i]; pd_state = ddf16toh(pde->PD_State); } if ((pde == NULL) || ((pd_state & DDF_PDE_ONLINE) == 0) || (pd_state & (DDF_PDE_FAILED|DDF_PDE_MISSING|DDF_PDE_UNRECOVERED))) { device_printf(parent, "Physical disk not usable\n"); goto ddf_out; } /* Parse out the configuration record, look for spare and VD records. * While DDF supports a disk being part of more than one array, and * thus having more than one VDCR record, that feature is not supported * by ATA-RAID. Therefore, the first record found takes precedence. */ max_cr_addr = (uintptr_t)cr + ddf32toh(hdr->cr_length) * DEV_BSIZE - 1; for ( ; (uintptr_t)cr < max_cr_addr; cr += ddf16toh(hdr->Configuration_Record_Length) * DEV_BSIZE) { switch (ddf32toh(((uint32_t *)cr)[0])) { case DDF_VDCR_SIGNATURE: vdcr = (struct ddf_vdc_record *)cr; goto cr_found; break; case DDF_VUCR_SIGNATURE: /* Don't care about this record */ break; case DDF_SA_SIGNATURE: sa = (struct ddf_sa_record *)cr; goto cr_found; break; case DDF_CR_INVALID: /* A record was deliberately invalidated */ break; default: device_printf(parent, "Invalid CR signature found\n"); } } cr_found: if ((vdcr == NULL) /* && (sa == NULL) * Spares not supported yet */) { device_printf(parent, "No usable configuration record found\n"); goto ddf_out; } if (vdcr != NULL) { if (vdcr->Secondary_Element_Count != 1) { device_printf(parent, "Unsupported multi-level Virtual Disk\n"); goto ddf_out; } /* Find the Virtual Disk Entry for this array */ if (ddf32toh(vdr->Signature) != DDF_VD_RECORD_SIGNATURE) { device_printf(parent, "Invalid VDR Signature\n"); goto ddf_out; } for (i = 0; i < ddf16toh(vdr->Populated_VDEs); i++) { if (bcmp(vdr->entry[i].VD_GUID, vdcr->VD_GUID, 24)) continue; vde = &vdr->entry[i]; vd_state = vde->VD_State & DDF_VDE_STATE_MASK; } if ((vde == NULL) || ((vd_state != DDF_VDE_OPTIMAL) && (vd_state != DDF_VDE_DEGRADED))) { device_printf(parent, "Unusable Virtual Disk\n"); goto ddf_out; } for (i = 0; i < ddf16toh(hdr->Max_Primary_Element_Entries); i++) { uint32_t pd_tmp; pd_tmp = ddf32toh(vdcr->Physical_Disk_Sequence[i]); if ((pd_tmp == 0x00000000) || (pd_tmp == 0xffffffff)) continue; if (pd_tmp == pd_ref) { pd_pos = i; break; } } if (pd_pos == -1) { device_printf(parent, "Physical device not part of array\n"); goto ddf_out; } } /* now convert DDF metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raid = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raid) { device_printf(parent, "failed to allocate metadata storage\n"); goto ddf_out; } } else raid = raidp[array]; if (raid->format && (raid->format != AR_F_DDF_RAID)) continue; if (raid->magic_0 && (raid->magic_0 != crc32(vde->VD_GUID, 24))) continue; if (!raidp[array]) { raidp[array] = raid; switch (vdcr->Primary_RAID_Level) { case DDF_VDCR_RAID0: raid->magic_0 = crc32(vde->VD_GUID, 24); raid->magic_1 = ddf16toh(vde->VD_Number); raid->type = AR_T_RAID0; raid->interleave = 1 << vdcr->Stripe_Size; raid->width = ddf16toh(vdcr->Primary_Element_Count); break; case DDF_VDCR_RAID1: raid->magic_0 = crc32(vde->VD_GUID, 24); raid->magic_1 = ddf16toh(vde->VD_Number); raid->type = AR_T_RAID1; raid->width = 1; break; default: device_printf(parent, "DDF unsupported RAID type 0x%02x\n", vdcr->Primary_RAID_Level); free(raidp[array], M_AR); raidp[array] = NULL; goto ddf_out; } raid->format = AR_F_DDF_RAID; raid->generation = ddf32toh(vdcr->Sequence_Number); raid->total_disks = ddf16toh(vdcr->Primary_Element_Count); raid->total_sectors = ddf64toh(vdcr->VD_Size); raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; strncpy(raid->name, vde->VD_Name, min(sizeof(raid->name), sizeof(vde->VD_Name))); /* clear out any old info */ if (raid->generation) { for (disk = 0; disk < raid->total_disks; disk++) { raid->disks[disk].dev = NULL; raid->disks[disk].flags = 0; } } } if (ddf32toh(vdcr->Sequence_Number) >= raid->generation) { int disk_number = pd_pos; raid->disks[disk_number].dev = parent; /* Adaptec appears to not set vdcr->Block_Count, yet again in * gross violation of the spec. */ raid->disks[disk_number].sectors = ddf64toh(vdcr->Block_Count); if (raid->disks[disk_number].sectors == 0) raid->disks[disk_number].sectors=ddf64toh(pde->Configured_Size); raid->disks[disk_number].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; } break; } ddf_out: free(meta, M_AR); return retval; } /* Highpoint V2 RocketRAID Metadata */ static int ata_raid_hptv2_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct hptv2_raid_conf *meta; struct ar_softc *raid = NULL; int array, disk_number = 0, retval = 0; if (!(meta = (struct hptv2_raid_conf *) malloc(sizeof(struct hptv2_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, HPTV2_LBA(parent), meta, sizeof(struct hptv2_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "HighPoint (v2) read metadata failed\n"); goto hptv2_out; } /* check if this is a HighPoint v2 RAID struct */ if (meta->magic != HPTV2_MAGIC_OK && meta->magic != HPTV2_MAGIC_BAD) { if (testing || bootverbose) device_printf(parent, "HighPoint (v2) check1 failed\n"); goto hptv2_out; } /* is this disk defined, or an old leftover/spare ? */ if (!meta->magic_0) { if (testing || bootverbose) device_printf(parent, "HighPoint (v2) check2 failed\n"); goto hptv2_out; } if (testing || bootverbose) ata_raid_hptv2_print_meta(meta); /* now convert HighPoint (v2) metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto hptv2_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_HPTV2_RAID)) continue; switch (meta->type) { case HPTV2_T_RAID0: if ((meta->order & (HPTV2_O_RAID0|HPTV2_O_OK)) == (HPTV2_O_RAID0|HPTV2_O_OK)) goto highpoint_raid1; if (meta->order & (HPTV2_O_RAID0 | HPTV2_O_RAID1)) goto highpoint_raid01; if (raid->magic_0 && raid->magic_0 != meta->magic_0) continue; raid->magic_0 = meta->magic_0; raid->type = AR_T_RAID0; raid->interleave = 1 << meta->stripe_shift; disk_number = meta->disk_number; if (!(meta->order & HPTV2_O_OK)) meta->magic = 0; /* mark bad */ break; case HPTV2_T_RAID1: highpoint_raid1: if (raid->magic_0 && raid->magic_0 != meta->magic_0) continue; raid->magic_0 = meta->magic_0; raid->type = AR_T_RAID1; disk_number = (meta->disk_number > 0); break; case HPTV2_T_RAID01_RAID0: highpoint_raid01: if (meta->order & HPTV2_O_RAID0) { if ((raid->magic_0 && raid->magic_0 != meta->magic_0) || (raid->magic_1 && raid->magic_1 != meta->magic_1)) continue; raid->magic_0 = meta->magic_0; raid->magic_1 = meta->magic_1; raid->type = AR_T_RAID01; raid->interleave = 1 << meta->stripe_shift; disk_number = meta->disk_number; } else { if (raid->magic_1 && raid->magic_1 != meta->magic_1) continue; raid->magic_1 = meta->magic_1; raid->type = AR_T_RAID01; raid->interleave = 1 << meta->stripe_shift; disk_number = meta->disk_number + meta->array_width; if (!(meta->order & HPTV2_O_RAID1)) meta->magic = 0; /* mark bad */ } break; case HPTV2_T_SPAN: if (raid->magic_0 && raid->magic_0 != meta->magic_0) continue; raid->magic_0 = meta->magic_0; raid->type = AR_T_SPAN; disk_number = meta->disk_number; break; default: device_printf(parent, "Highpoint (v2) unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto hptv2_out; } raid->format |= AR_F_HPTV2_RAID; raid->disks[disk_number].dev = parent; raid->disks[disk_number].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED); raid->lun = array; strncpy(raid->name, meta->name_1, min(sizeof(raid->name), sizeof(meta->name_1))); if (meta->magic == HPTV2_MAGIC_OK) { raid->disks[disk_number].flags |= AR_DF_ONLINE; raid->width = meta->array_width; raid->total_sectors = meta->total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = HPTV2_LBA(parent) + 1; raid->rebuild_lba = meta->rebuild_lba; raid->disks[disk_number].sectors = raid->total_sectors / raid->width; } else raid->disks[disk_number].flags &= ~AR_DF_ONLINE; if ((raid->type & AR_T_RAID0) && (raid->total_disks < raid->width)) raid->total_disks = raid->width; if (disk_number >= raid->total_disks) raid->total_disks = disk_number + 1; ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; break; } hptv2_out: free(meta, M_AR); return retval; } static int ata_raid_hptv2_write_meta(struct ar_softc *rdp) { struct hptv2_raid_conf *meta; struct timeval timestamp; int disk, error = 0; if (!(meta = (struct hptv2_raid_conf *) malloc(sizeof(struct hptv2_raid_conf), M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } microtime(×tamp); rdp->magic_0 = timestamp.tv_sec + 2; rdp->magic_1 = timestamp.tv_sec; for (disk = 0; disk < rdp->total_disks; disk++) { if ((rdp->disks[disk].flags & (AR_DF_PRESENT | AR_DF_ONLINE)) == (AR_DF_PRESENT | AR_DF_ONLINE)) meta->magic = HPTV2_MAGIC_OK; if (rdp->disks[disk].flags & AR_DF_ASSIGNED) { meta->magic_0 = rdp->magic_0; if (strlen(rdp->name)) strncpy(meta->name_1, rdp->name, sizeof(meta->name_1)); else strcpy(meta->name_1, "FreeBSD"); } meta->disk_number = disk; switch (rdp->type) { case AR_T_RAID0: meta->type = HPTV2_T_RAID0; strcpy(meta->name_2, "RAID 0"); if (rdp->disks[disk].flags & AR_DF_ONLINE) meta->order = HPTV2_O_OK; break; case AR_T_RAID1: meta->type = HPTV2_T_RAID0; strcpy(meta->name_2, "RAID 1"); meta->disk_number = (disk < rdp->width) ? disk : disk + 5; meta->order = HPTV2_O_RAID0 | HPTV2_O_OK; break; case AR_T_RAID01: meta->type = HPTV2_T_RAID01_RAID0; strcpy(meta->name_2, "RAID 0+1"); if (rdp->disks[disk].flags & AR_DF_ONLINE) { if (disk < rdp->width) { meta->order = (HPTV2_O_RAID0 | HPTV2_O_RAID1); meta->magic_0 = rdp->magic_0 - 1; } else { meta->order = HPTV2_O_RAID1; meta->disk_number -= rdp->width; } } else meta->magic_0 = rdp->magic_0 - 1; meta->magic_1 = rdp->magic_1; break; case AR_T_SPAN: meta->type = HPTV2_T_SPAN; strcpy(meta->name_2, "SPAN"); break; default: free(meta, M_AR); return ENODEV; } meta->array_width = rdp->width; meta->stripe_shift = (rdp->width > 1) ? (ffs(rdp->interleave)-1) : 0; meta->total_sectors = rdp->total_sectors; meta->rebuild_lba = rdp->rebuild_lba; if (testing || bootverbose) ata_raid_hptv2_print_meta(meta); if (rdp->disks[disk].dev) { if (ata_raid_rw(rdp->disks[disk].dev, HPTV2_LBA(rdp->disks[disk].dev), meta, sizeof(struct promise_raid_conf), ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } free(meta, M_AR); return error; } /* Highpoint V3 RocketRAID Metadata */ static int ata_raid_hptv3_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct hptv3_raid_conf *meta; struct ar_softc *raid = NULL; int array, disk_number, retval = 0; if (!(meta = (struct hptv3_raid_conf *) malloc(sizeof(struct hptv3_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, HPTV3_LBA(parent), meta, sizeof(struct hptv3_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "HighPoint (v3) read metadata failed\n"); goto hptv3_out; } /* check if this is a HighPoint v3 RAID struct */ if (meta->magic != HPTV3_MAGIC) { if (testing || bootverbose) device_printf(parent, "HighPoint (v3) check1 failed\n"); goto hptv3_out; } /* check if there are any config_entries */ if (meta->config_entries < 1) { if (testing || bootverbose) device_printf(parent, "HighPoint (v3) check2 failed\n"); goto hptv3_out; } if (testing || bootverbose) ata_raid_hptv3_print_meta(meta); /* now convert HighPoint (v3) metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto hptv3_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_HPTV3_RAID)) continue; if ((raid->format & AR_F_HPTV3_RAID) && raid->magic_0 != meta->magic_0) continue; switch (meta->configs[0].type) { case HPTV3_T_RAID0: raid->type = AR_T_RAID0; raid->width = meta->configs[0].total_disks; disk_number = meta->configs[0].disk_number; break; case HPTV3_T_RAID1: raid->type = AR_T_RAID1; raid->width = meta->configs[0].total_disks / 2; disk_number = meta->configs[0].disk_number; break; case HPTV3_T_RAID5: raid->type = AR_T_RAID5; raid->width = meta->configs[0].total_disks; disk_number = meta->configs[0].disk_number; break; case HPTV3_T_SPAN: raid->type = AR_T_SPAN; raid->width = meta->configs[0].total_disks; disk_number = meta->configs[0].disk_number; break; default: device_printf(parent, "Highpoint (v3) unknown RAID type 0x%02x\n", meta->configs[0].type); free(raidp[array], M_AR); raidp[array] = NULL; goto hptv3_out; } if (meta->config_entries == 2) { switch (meta->configs[1].type) { case HPTV3_T_RAID1: if (raid->type == AR_T_RAID0) { raid->type = AR_T_RAID01; disk_number = meta->configs[1].disk_number + (meta->configs[0].disk_number << 1); break; } default: device_printf(parent, "Highpoint (v3) unknown level 2 0x%02x\n", meta->configs[1].type); free(raidp[array], M_AR); raidp[array] = NULL; goto hptv3_out; } } raid->magic_0 = meta->magic_0; raid->format = AR_F_HPTV3_RAID; raid->generation = meta->timestamp; raid->interleave = 1 << meta->configs[0].stripe_shift; raid->total_disks = meta->configs[0].total_disks + meta->configs[1].total_disks; raid->total_sectors = meta->configs[0].total_sectors + ((u_int64_t)meta->configs_high[0].total_sectors << 32); raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = meta->configs[0].rebuild_lba + ((u_int64_t)meta->configs_high[0].rebuild_lba << 32); raid->lun = array; strncpy(raid->name, meta->name, min(sizeof(raid->name), sizeof(meta->name))); raid->disks[disk_number].sectors = raid->total_sectors / (raid->type == AR_T_RAID5 ? raid->width - 1 : raid->width); raid->disks[disk_number].dev = parent; raid->disks[disk_number].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; break; } hptv3_out: free(meta, M_AR); return retval; } /* Intel MatrixRAID Metadata */ static int ata_raid_intel_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct intel_raid_conf *meta; struct intel_raid_mapping *map; struct ar_softc *raid = NULL; u_int32_t checksum, *ptr; int array, count, disk, volume = 1, retval = 0; char *tmp; if (!(meta = (struct intel_raid_conf *) malloc(1536, M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, INTEL_LBA(parent), meta, 1024, ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "Intel read metadata failed\n"); goto intel_out; } tmp = (char *)meta; bcopy(tmp, tmp+1024, 512); bcopy(tmp+512, tmp, 1024); bzero(tmp+1024, 512); /* check if this is a Intel RAID struct */ if (strncmp(meta->intel_id, INTEL_MAGIC, strlen(INTEL_MAGIC))) { if (testing || bootverbose) device_printf(parent, "Intel check1 failed\n"); goto intel_out; } for (checksum = 0, ptr = (u_int32_t *)meta, count = 0; count < (meta->config_size / sizeof(u_int32_t)); count++) { checksum += *ptr++; } checksum -= meta->checksum; if (checksum != meta->checksum) { if (testing || bootverbose) device_printf(parent, "Intel check2 failed\n"); goto intel_out; } if (testing || bootverbose) ata_raid_intel_print_meta(meta); map = (struct intel_raid_mapping *)&meta->disk[meta->total_disks]; /* now convert Intel metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto intel_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_INTEL_RAID)) continue; if ((raid->format & AR_F_INTEL_RAID) && (raid->magic_0 != meta->config_id)) continue; /* * update our knowledge about the array config based on generation * NOTE: there can be multiple volumes on a disk set */ if (!meta->generation || meta->generation > raid->generation) { switch (map->type) { case INTEL_T_RAID0: raid->type = AR_T_RAID0; raid->width = map->total_disks; break; case INTEL_T_RAID1: if (map->total_disks == 4) raid->type = AR_T_RAID01; else raid->type = AR_T_RAID1; raid->width = map->total_disks / 2; break; case INTEL_T_RAID5: raid->type = AR_T_RAID5; raid->width = map->total_disks; break; default: device_printf(parent, "Intel unknown RAID type 0x%02x\n", map->type); free(raidp[array], M_AR); raidp[array] = NULL; goto intel_out; } switch (map->status) { case INTEL_S_READY: raid->status = AR_S_READY; break; case INTEL_S_DEGRADED: raid->status |= AR_S_DEGRADED; break; case INTEL_S_DISABLED: case INTEL_S_FAILURE: raid->status = 0; } raid->magic_0 = meta->config_id; raid->format = AR_F_INTEL_RAID; raid->generation = meta->generation; raid->interleave = map->stripe_sectors; raid->total_disks = map->total_disks; raid->total_sectors = map->total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = map->offset; raid->rebuild_lba = 0; raid->lun = array; raid->volume = volume - 1; strncpy(raid->name, map->name, min(sizeof(raid->name), sizeof(map->name))); /* clear out any old info */ for (disk = 0; disk < raid->total_disks; disk++) { raid->disks[disk].dev = NULL; bcopy(meta->disk[map->disk_idx[disk]].serial, raid->disks[disk].serial, sizeof(raid->disks[disk].serial)); raid->disks[disk].sectors = meta->disk[map->disk_idx[disk]].sectors; raid->disks[disk].flags = 0; if (meta->disk[map->disk_idx[disk]].flags & INTEL_F_ONLINE) raid->disks[disk].flags |= AR_DF_ONLINE; if (meta->disk[map->disk_idx[disk]].flags & INTEL_F_ASSIGNED) raid->disks[disk].flags |= AR_DF_ASSIGNED; if (meta->disk[map->disk_idx[disk]].flags & INTEL_F_SPARE) { raid->disks[disk].flags &= ~(AR_DF_ONLINE | AR_DF_ASSIGNED); raid->disks[disk].flags |= AR_DF_SPARE; } if (meta->disk[map->disk_idx[disk]].flags & INTEL_F_DOWN) raid->disks[disk].flags &= ~AR_DF_ONLINE; } } if (meta->generation >= raid->generation) { for (disk = 0; disk < raid->total_disks; disk++) { struct ata_device *atadev = device_get_softc(parent); if (!strncmp(raid->disks[disk].serial, atadev->param.serial, sizeof(raid->disks[disk].serial))) { raid->disks[disk].dev = parent; raid->disks[disk].flags |= (AR_DF_PRESENT | AR_DF_ONLINE); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk; retval = 1; } } } else goto intel_out; if (retval) { if (volume < meta->total_volumes) { map = (struct intel_raid_mapping *) &map->disk_idx[map->total_disks]; volume++; retval = 0; continue; } break; } else { free(raidp[array], M_AR); raidp[array] = NULL; if (volume == 2) retval = 1; } } intel_out: free(meta, M_AR); return retval; } static int ata_raid_intel_write_meta(struct ar_softc *rdp) { struct intel_raid_conf *meta; struct intel_raid_mapping *map; struct timeval timestamp; u_int32_t checksum, *ptr; int count, disk, error = 0; char *tmp; if (!(meta = (struct intel_raid_conf *) malloc(1536, M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } rdp->generation++; microtime(×tamp); bcopy(INTEL_MAGIC, meta->intel_id, sizeof(meta->intel_id)); bcopy(INTEL_VERSION_1100, meta->version, sizeof(meta->version)); meta->config_id = timestamp.tv_sec; meta->generation = rdp->generation; meta->total_disks = rdp->total_disks; meta->total_volumes = 1; /* XXX SOS */ for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { struct ata_channel *ch = device_get_softc(device_get_parent(rdp->disks[disk].dev)); struct ata_device *atadev = device_get_softc(rdp->disks[disk].dev); bcopy(atadev->param.serial, meta->disk[disk].serial, sizeof(rdp->disks[disk].serial)); meta->disk[disk].sectors = rdp->disks[disk].sectors; meta->disk[disk].id = (ch->unit << 16) | ATA_DEV(atadev->unit); } else meta->disk[disk].sectors = rdp->total_sectors / rdp->width; meta->disk[disk].flags = 0; if (rdp->disks[disk].flags & AR_DF_SPARE) meta->disk[disk].flags |= INTEL_F_SPARE; else { if (rdp->disks[disk].flags & AR_DF_ONLINE) meta->disk[disk].flags |= INTEL_F_ONLINE; else meta->disk[disk].flags |= INTEL_F_DOWN; if (rdp->disks[disk].flags & AR_DF_ASSIGNED) meta->disk[disk].flags |= INTEL_F_ASSIGNED; } } map = (struct intel_raid_mapping *)&meta->disk[meta->total_disks]; bcopy(rdp->name, map->name, sizeof(rdp->name)); map->total_sectors = rdp->total_sectors; map->state = 12; /* XXX SOS */ map->offset = rdp->offset_sectors; map->stripe_count = rdp->total_sectors / (rdp->interleave*rdp->total_disks); map->stripe_sectors = rdp->interleave; map->disk_sectors = rdp->total_sectors / rdp->width; map->status = INTEL_S_READY; /* XXX SOS */ switch (rdp->type) { case AR_T_RAID0: map->type = INTEL_T_RAID0; break; case AR_T_RAID1: map->type = INTEL_T_RAID1; break; case AR_T_RAID01: map->type = INTEL_T_RAID1; break; case AR_T_RAID5: map->type = INTEL_T_RAID5; break; default: free(meta, M_AR); return ENODEV; } map->total_disks = rdp->total_disks; map->magic[0] = 0x02; map->magic[1] = 0xff; map->magic[2] = 0x01; for (disk = 0; disk < rdp->total_disks; disk++) map->disk_idx[disk] = disk; meta->config_size = (char *)&map->disk_idx[disk] - (char *)meta; for (checksum = 0, ptr = (u_int32_t *)meta, count = 0; count < (meta->config_size / sizeof(u_int32_t)); count++) { checksum += *ptr++; } meta->checksum = checksum; if (testing || bootverbose) ata_raid_intel_print_meta(meta); tmp = (char *)meta; bcopy(tmp, tmp+1024, 512); bcopy(tmp+512, tmp, 1024); bzero(tmp+1024, 512); for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { if (ata_raid_rw(rdp->disks[disk].dev, INTEL_LBA(rdp->disks[disk].dev), meta, 1024, ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } free(meta, M_AR); return error; } /* Integrated Technology Express Metadata */ static int ata_raid_ite_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct ite_raid_conf *meta; struct ar_softc *raid = NULL; int array, disk_number, count, retval = 0; u_int16_t *ptr; if (!(meta = (struct ite_raid_conf *) malloc(sizeof(struct ite_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, ITE_LBA(parent), meta, sizeof(struct ite_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "ITE read metadata failed\n"); goto ite_out; } /* check if this is a ITE RAID struct */ for (ptr = (u_int16_t *)meta->ite_id, count = 0; count < sizeof(meta->ite_id)/sizeof(uint16_t); count++) ptr[count] = be16toh(ptr[count]); if (strncmp(meta->ite_id, ITE_MAGIC, strlen(ITE_MAGIC))) { if (testing || bootverbose) device_printf(parent, "ITE check1 failed\n"); goto ite_out; } if (testing || bootverbose) ata_raid_ite_print_meta(meta); /* now convert ITE metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if ((raid = raidp[array])) { if (raid->format != AR_F_ITE_RAID) continue; if (raid->magic_0 != *((u_int64_t *)meta->timestamp_0)) continue; } /* if we dont have a disks timestamp the RAID is invalidated */ if (*((u_int64_t *)meta->timestamp_1) == 0) goto ite_out; if (!raid) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!(raid = raidp[array])) { device_printf(parent, "failed to allocate metadata storage\n"); goto ite_out; } } switch (meta->type) { case ITE_T_RAID0: raid->type = AR_T_RAID0; raid->width = meta->array_width; raid->total_disks = meta->array_width; disk_number = meta->disk_number; break; case ITE_T_RAID1: raid->type = AR_T_RAID1; raid->width = 1; raid->total_disks = 2; disk_number = meta->disk_number; break; case ITE_T_RAID01: raid->type = AR_T_RAID01; raid->width = meta->array_width; raid->total_disks = 4; disk_number = ((meta->disk_number & 0x02) >> 1) | ((meta->disk_number & 0x01) << 1); break; case ITE_T_SPAN: raid->type = AR_T_SPAN; raid->width = 1; raid->total_disks = meta->array_width; disk_number = meta->disk_number; break; default: device_printf(parent, "ITE unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto ite_out; } raid->magic_0 = *((u_int64_t *)meta->timestamp_0); raid->format = AR_F_ITE_RAID; raid->generation = 0; raid->interleave = meta->stripe_sectors; raid->total_sectors = meta->total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; raid->disks[disk_number].dev = parent; raid->disks[disk_number].sectors = raid->total_sectors / raid->width; raid->disks[disk_number].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; break; } ite_out: free(meta, M_AR); return retval; } /* JMicron Technology Corp Metadata */ static int ata_raid_jmicron_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct jmicron_raid_conf *meta; struct ar_softc *raid = NULL; u_int16_t checksum, *ptr; u_int64_t disk_size; int count, array, disk, total_disks, retval = 0; if (!(meta = (struct jmicron_raid_conf *) malloc(sizeof(struct jmicron_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, JMICRON_LBA(parent), meta, sizeof(struct jmicron_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "JMicron read metadata failed\n"); } /* check for JMicron signature */ if (strncmp(meta->signature, JMICRON_MAGIC, 2)) { if (testing || bootverbose) device_printf(parent, "JMicron check1 failed\n"); goto jmicron_out; } /* calculate checksum and compare for valid */ for (checksum = 0, ptr = (u_int16_t *)meta, count = 0; count < 64; count++) checksum += *ptr++; if (checksum) { if (testing || bootverbose) device_printf(parent, "JMicron check2 failed\n"); goto jmicron_out; } if (testing || bootverbose) ata_raid_jmicron_print_meta(meta); /* now convert JMicron meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { jmicron_next: if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto jmicron_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_JMICRON_RAID)) continue; for (total_disks = 0, disk = 0; disk < JM_MAX_DISKS; disk++) { if (meta->disks[disk]) { if (raid->format == AR_F_JMICRON_RAID) { if (bcmp(&meta->disks[disk], raid->disks[disk].serial, sizeof(u_int32_t))) { array++; goto jmicron_next; } } else bcopy(&meta->disks[disk], raid->disks[disk].serial, sizeof(u_int32_t)); total_disks++; } } /* handle spares XXX SOS */ switch (meta->type) { case JM_T_RAID0: raid->type = AR_T_RAID0; raid->width = total_disks; break; case JM_T_RAID1: raid->type = AR_T_RAID1; raid->width = 1; break; case JM_T_RAID01: raid->type = AR_T_RAID01; raid->width = total_disks / 2; break; case JM_T_RAID5: raid->type = AR_T_RAID5; raid->width = total_disks; break; case JM_T_JBOD: raid->type = AR_T_SPAN; raid->width = 1; break; default: device_printf(parent, "JMicron unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto jmicron_out; } disk_size = (meta->disk_sectors_high << 16) + meta->disk_sectors_low; raid->format = AR_F_JMICRON_RAID; strncpy(raid->name, meta->name, sizeof(meta->name)); raid->generation = 0; raid->interleave = 2 << meta->stripe_shift; raid->total_disks = total_disks; raid->total_sectors = disk_size * (raid->width-(raid->type==AR_RAID5)); raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = meta->offset * 16; raid->rebuild_lba = 0; raid->lun = array; for (disk = 0; disk < raid->total_disks; disk++) { if (meta->disks[disk] == meta->disk_id) { raid->disks[disk].dev = parent; raid->disks[disk].sectors = disk_size; raid->disks[disk].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk; retval = 1; break; } } break; } jmicron_out: free(meta, M_AR); return retval; } static int ata_raid_jmicron_write_meta(struct ar_softc *rdp) { struct jmicron_raid_conf *meta; u_int64_t disk_sectors; int disk, error = 0; if (!(meta = (struct jmicron_raid_conf *) malloc(sizeof(struct jmicron_raid_conf), M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } rdp->generation++; switch (rdp->type) { case AR_T_JBOD: meta->type = JM_T_JBOD; break; case AR_T_RAID0: meta->type = JM_T_RAID0; break; case AR_T_RAID1: meta->type = JM_T_RAID1; break; case AR_T_RAID5: meta->type = JM_T_RAID5; break; case AR_T_RAID01: meta->type = JM_T_RAID01; break; default: free(meta, M_AR); return ENODEV; } bcopy(JMICRON_MAGIC, meta->signature, sizeof(JMICRON_MAGIC)); meta->version = JMICRON_VERSION; meta->offset = rdp->offset_sectors / 16; disk_sectors = rdp->total_sectors / (rdp->width - (rdp->type == AR_RAID5)); meta->disk_sectors_low = disk_sectors & 0xffff; meta->disk_sectors_high = disk_sectors >> 16; strncpy(meta->name, rdp->name, sizeof(meta->name)); meta->stripe_shift = ffs(rdp->interleave) - 2; for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].serial[0]) bcopy(rdp->disks[disk].serial,&meta->disks[disk],sizeof(u_int32_t)); else meta->disks[disk] = (u_int32_t)(uintptr_t)rdp->disks[disk].dev; } for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { u_int16_t checksum = 0, *ptr; int count; meta->disk_id = meta->disks[disk]; meta->checksum = 0; for (ptr = (u_int16_t *)meta, count = 0; count < 64; count++) checksum += *ptr++; meta->checksum -= checksum; if (testing || bootverbose) ata_raid_jmicron_print_meta(meta); if (ata_raid_rw(rdp->disks[disk].dev, JMICRON_LBA(rdp->disks[disk].dev), meta, sizeof(struct jmicron_raid_conf), ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } /* handle spares XXX SOS */ free(meta, M_AR); return error; } /* LSILogic V2 MegaRAID Metadata */ static int ata_raid_lsiv2_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct lsiv2_raid_conf *meta; struct ar_softc *raid = NULL; int array, retval = 0; if (!(meta = (struct lsiv2_raid_conf *) malloc(sizeof(struct lsiv2_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, LSIV2_LBA(parent), meta, sizeof(struct lsiv2_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "LSI (v2) read metadata failed\n"); goto lsiv2_out; } /* check if this is a LSI RAID struct */ if (strncmp(meta->lsi_id, LSIV2_MAGIC, strlen(LSIV2_MAGIC))) { if (testing || bootverbose) device_printf(parent, "LSI (v2) check1 failed\n"); goto lsiv2_out; } if (testing || bootverbose) ata_raid_lsiv2_print_meta(meta); /* now convert LSI (v2) config meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { int raid_entry, conf_entry; if (!raidp[array + meta->raid_number]) { raidp[array + meta->raid_number] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array + meta->raid_number]) { device_printf(parent, "failed to allocate metadata storage\n"); goto lsiv2_out; } } raid = raidp[array + meta->raid_number]; if (raid->format && (raid->format != AR_F_LSIV2_RAID)) continue; if (raid->magic_0 && ((raid->magic_0 != meta->timestamp) || (raid->magic_1 != meta->raid_number))) continue; array += meta->raid_number; raid_entry = meta->raid_number; conf_entry = (meta->configs[raid_entry].raid.config_offset >> 4) + meta->disk_number - 1; switch (meta->configs[raid_entry].raid.type) { case LSIV2_T_RAID0: raid->magic_0 = meta->timestamp; raid->magic_1 = meta->raid_number; raid->type = AR_T_RAID0; raid->interleave = meta->configs[raid_entry].raid.stripe_sectors; raid->width = meta->configs[raid_entry].raid.array_width; break; case LSIV2_T_RAID1: raid->magic_0 = meta->timestamp; raid->magic_1 = meta->raid_number; raid->type = AR_T_RAID1; raid->width = meta->configs[raid_entry].raid.array_width; break; case LSIV2_T_RAID0 | LSIV2_T_RAID1: raid->magic_0 = meta->timestamp; raid->magic_1 = meta->raid_number; raid->type = AR_T_RAID01; raid->interleave = meta->configs[raid_entry].raid.stripe_sectors; raid->width = meta->configs[raid_entry].raid.array_width; break; default: device_printf(parent, "LSI v2 unknown RAID type 0x%02x\n", meta->configs[raid_entry].raid.type); free(raidp[array], M_AR); raidp[array] = NULL; goto lsiv2_out; } raid->format = AR_F_LSIV2_RAID; raid->generation = 0; raid->total_disks = meta->configs[raid_entry].raid.disk_count; raid->total_sectors = meta->configs[raid_entry].raid.total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; if (meta->configs[conf_entry].disk.device != LSIV2_D_NONE) { raid->disks[meta->disk_number].dev = parent; raid->disks[meta->disk_number].sectors = meta->configs[conf_entry].disk.disk_sectors; raid->disks[meta->disk_number].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = meta->disk_number; retval = 1; } else raid->disks[meta->disk_number].flags &= ~AR_DF_ONLINE; break; } lsiv2_out: free(meta, M_AR); return retval; } /* LSILogic V3 MegaRAID Metadata */ static int ata_raid_lsiv3_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct lsiv3_raid_conf *meta; struct ar_softc *raid = NULL; u_int8_t checksum, *ptr; int array, entry, count, disk_number, retval = 0; if (!(meta = (struct lsiv3_raid_conf *) malloc(sizeof(struct lsiv3_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, LSIV3_LBA(parent), meta, sizeof(struct lsiv3_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "LSI (v3) read metadata failed\n"); goto lsiv3_out; } /* check if this is a LSI RAID struct */ if (strncmp(meta->lsi_id, LSIV3_MAGIC, strlen(LSIV3_MAGIC))) { if (testing || bootverbose) device_printf(parent, "LSI (v3) check1 failed\n"); goto lsiv3_out; } /* check if the checksum is OK */ for (checksum = 0, ptr = meta->lsi_id, count = 0; count < 512; count++) checksum += *ptr++; if (checksum) { if (testing || bootverbose) device_printf(parent, "LSI (v3) check2 failed\n"); goto lsiv3_out; } if (testing || bootverbose) ata_raid_lsiv3_print_meta(meta); /* now convert LSI (v3) config meta into our generic form */ for (array = 0, entry = 0; array < MAX_ARRAYS && entry < 8;) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto lsiv3_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_LSIV3_RAID)) { array++; continue; } if ((raid->format == AR_F_LSIV3_RAID) && (raid->magic_0 != meta->timestamp)) { array++; continue; } switch (meta->raid[entry].total_disks) { case 0: entry++; continue; case 1: if (meta->raid[entry].device == meta->device) { disk_number = 0; break; } if (raid->format) array++; entry++; continue; case 2: disk_number = (meta->device & (LSIV3_D_DEVICE|LSIV3_D_CHANNEL))?1:0; break; default: device_printf(parent, "lsiv3 > 2 disk support untested!!\n"); disk_number = (meta->device & LSIV3_D_DEVICE ? 1 : 0) + (meta->device & LSIV3_D_CHANNEL ? 2 : 0); break; } switch (meta->raid[entry].type) { case LSIV3_T_RAID0: raid->type = AR_T_RAID0; raid->width = meta->raid[entry].total_disks; break; case LSIV3_T_RAID1: raid->type = AR_T_RAID1; raid->width = meta->raid[entry].array_width; break; default: device_printf(parent, "LSI v3 unknown RAID type 0x%02x\n", meta->raid[entry].type); free(raidp[array], M_AR); raidp[array] = NULL; entry++; continue; } raid->magic_0 = meta->timestamp; raid->format = AR_F_LSIV3_RAID; raid->generation = 0; raid->interleave = meta->raid[entry].stripe_pages * 8; raid->total_disks = meta->raid[entry].total_disks; raid->total_sectors = raid->width * meta->raid[entry].sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = meta->raid[entry].offset; raid->rebuild_lba = 0; raid->lun = array; raid->disks[disk_number].dev = parent; raid->disks[disk_number].sectors = raid->total_sectors / raid->width; raid->disks[disk_number].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; entry++; array++; } lsiv3_out: free(meta, M_AR); return retval; } /* nVidia MediaShield Metadata */ static int ata_raid_nvidia_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct nvidia_raid_conf *meta; struct ar_softc *raid = NULL; u_int32_t checksum, *ptr; int array, count, retval = 0; if (!(meta = (struct nvidia_raid_conf *) malloc(sizeof(struct nvidia_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, NVIDIA_LBA(parent), meta, sizeof(struct nvidia_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "nVidia read metadata failed\n"); goto nvidia_out; } /* check if this is a nVidia RAID struct */ if (strncmp(meta->nvidia_id, NV_MAGIC, strlen(NV_MAGIC))) { if (testing || bootverbose) device_printf(parent, "nVidia check1 failed\n"); goto nvidia_out; } /* check if the checksum is OK */ for (checksum = 0, ptr = (u_int32_t*)meta, count = 0; count < meta->config_size; count++) checksum += *ptr++; if (checksum) { if (testing || bootverbose) device_printf(parent, "nVidia check2 failed\n"); goto nvidia_out; } if (testing || bootverbose) ata_raid_nvidia_print_meta(meta); /* now convert nVidia meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto nvidia_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_NVIDIA_RAID)) continue; if (raid->format == AR_F_NVIDIA_RAID && ((raid->magic_0 != meta->magic_1) || (raid->magic_1 != meta->magic_2))) { continue; } switch (meta->type) { case NV_T_SPAN: raid->type = AR_T_SPAN; break; case NV_T_RAID0: raid->type = AR_T_RAID0; break; case NV_T_RAID1: raid->type = AR_T_RAID1; break; case NV_T_RAID5: raid->type = AR_T_RAID5; break; case NV_T_RAID01: raid->type = AR_T_RAID01; break; default: device_printf(parent, "nVidia unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto nvidia_out; } raid->magic_0 = meta->magic_1; raid->magic_1 = meta->magic_2; raid->format = AR_F_NVIDIA_RAID; raid->generation = 0; raid->interleave = meta->stripe_sectors; raid->width = meta->array_width; raid->total_disks = meta->total_disks; raid->total_sectors = meta->total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = meta->rebuild_lba; raid->lun = array; raid->status = AR_S_READY; if (meta->status & NV_S_DEGRADED) raid->status |= AR_S_DEGRADED; raid->disks[meta->disk_number].dev = parent; raid->disks[meta->disk_number].sectors = raid->total_sectors / raid->width; raid->disks[meta->disk_number].flags = (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = meta->disk_number; retval = 1; break; } nvidia_out: free(meta, M_AR); return retval; } /* Promise FastTrak Metadata */ static int ata_raid_promise_read_meta(device_t dev, struct ar_softc **raidp, int native) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct promise_raid_conf *meta; struct ar_softc *raid; u_int32_t checksum, *ptr; int array, count, disk, disksum = 0, retval = 0; if (!(meta = (struct promise_raid_conf *) malloc(sizeof(struct promise_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, PROMISE_LBA(parent), meta, sizeof(struct promise_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "%s read metadata failed\n", native ? "FreeBSD" : "Promise"); goto promise_out; } /* check the signature */ if (native) { if (strncmp(meta->promise_id, ATA_MAGIC, strlen(ATA_MAGIC))) { if (testing || bootverbose) device_printf(parent, "FreeBSD check1 failed\n"); goto promise_out; } } else { if (strncmp(meta->promise_id, PR_MAGIC, strlen(PR_MAGIC))) { if (testing || bootverbose) device_printf(parent, "Promise check1 failed\n"); goto promise_out; } } /* check if the checksum is OK */ for (checksum = 0, ptr = (u_int32_t *)meta, count = 0; count < 511; count++) checksum += *ptr++; if (checksum != *ptr) { if (testing || bootverbose) device_printf(parent, "%s check2 failed\n", native ? "FreeBSD" : "Promise"); goto promise_out; } /* check on disk integrity status */ if (meta->raid.integrity != PR_I_VALID) { if (testing || bootverbose) device_printf(parent, "%s check3 failed\n", native ? "FreeBSD" : "Promise"); goto promise_out; } if (testing || bootverbose) ata_raid_promise_print_meta(meta); /* now convert Promise metadata into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto promise_out; } } raid = raidp[array]; if (raid->format && (raid->format != (native ? AR_F_FREEBSD_RAID : AR_F_PROMISE_RAID))) continue; if ((raid->format == (native ? AR_F_FREEBSD_RAID : AR_F_PROMISE_RAID))&& !(meta->raid.magic_1 == (raid->magic_1))) continue; /* update our knowledge about the array config based on generation */ if (!meta->raid.generation || meta->raid.generation > raid->generation){ switch (meta->raid.type) { case PR_T_SPAN: raid->type = AR_T_SPAN; break; case PR_T_JBOD: raid->type = AR_T_JBOD; break; case PR_T_RAID0: raid->type = AR_T_RAID0; break; case PR_T_RAID1: raid->type = AR_T_RAID1; if (meta->raid.array_width > 1) raid->type = AR_T_RAID01; break; case PR_T_RAID5: raid->type = AR_T_RAID5; break; default: device_printf(parent, "%s unknown RAID type 0x%02x\n", native ? "FreeBSD" : "Promise", meta->raid.type); free(raidp[array], M_AR); raidp[array] = NULL; goto promise_out; } raid->magic_1 = meta->raid.magic_1; raid->format = (native ? AR_F_FREEBSD_RAID : AR_F_PROMISE_RAID); raid->generation = meta->raid.generation; raid->interleave = 1 << meta->raid.stripe_shift; raid->width = meta->raid.array_width; raid->total_disks = meta->raid.total_disks; raid->heads = meta->raid.heads + 1; raid->sectors = meta->raid.sectors; raid->cylinders = meta->raid.cylinders + 1; raid->total_sectors = meta->raid.total_sectors; raid->offset_sectors = 0; raid->rebuild_lba = meta->raid.rebuild_lba; raid->lun = array; if ((meta->raid.status & (PR_S_VALID | PR_S_ONLINE | PR_S_INITED | PR_S_READY)) == (PR_S_VALID | PR_S_ONLINE | PR_S_INITED | PR_S_READY)) { raid->status |= AR_S_READY; if (meta->raid.status & PR_S_DEGRADED) raid->status |= AR_S_DEGRADED; } else raid->status &= ~AR_S_READY; /* convert disk flags to our internal types */ for (disk = 0; disk < meta->raid.total_disks; disk++) { raid->disks[disk].dev = NULL; raid->disks[disk].flags = 0; *((u_int64_t *)(raid->disks[disk].serial)) = meta->raid.disk[disk].magic_0; disksum += meta->raid.disk[disk].flags; if (meta->raid.disk[disk].flags & PR_F_ONLINE) raid->disks[disk].flags |= AR_DF_ONLINE; if (meta->raid.disk[disk].flags & PR_F_ASSIGNED) raid->disks[disk].flags |= AR_DF_ASSIGNED; if (meta->raid.disk[disk].flags & PR_F_SPARE) { raid->disks[disk].flags &= ~(AR_DF_ONLINE | AR_DF_ASSIGNED); raid->disks[disk].flags |= AR_DF_SPARE; } if (meta->raid.disk[disk].flags & (PR_F_REDIR | PR_F_DOWN)) raid->disks[disk].flags &= ~AR_DF_ONLINE; } if (!disksum) { device_printf(parent, "%s subdisks has no flags\n", native ? "FreeBSD" : "Promise"); free(raidp[array], M_AR); raidp[array] = NULL; goto promise_out; } } if (meta->raid.generation >= raid->generation) { int disk_number = meta->raid.disk_number; if (raid->disks[disk_number].flags && (meta->magic_0 == *((u_int64_t *)(raid->disks[disk_number].serial)))) { raid->disks[disk_number].dev = parent; raid->disks[disk_number].flags |= AR_DF_PRESENT; raid->disks[disk_number].sectors = meta->raid.disk_sectors; if ((raid->disks[disk_number].flags & (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE)) == (AR_DF_PRESENT | AR_DF_ASSIGNED | AR_DF_ONLINE)) { ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; } } } break; } promise_out: free(meta, M_AR); return retval; } static int ata_raid_promise_write_meta(struct ar_softc *rdp) { struct promise_raid_conf *meta; struct timeval timestamp; u_int32_t *ckptr; int count, disk, drive, error = 0; if (!(meta = (struct promise_raid_conf *) malloc(sizeof(struct promise_raid_conf), M_AR, M_NOWAIT))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } rdp->generation++; microtime(×tamp); for (disk = 0; disk < rdp->total_disks; disk++) { for (count = 0; count < sizeof(struct promise_raid_conf); count++) *(((u_int8_t *)meta) + count) = 255 - (count % 256); meta->dummy_0 = 0x00020000; meta->raid.disk_number = disk; if (rdp->disks[disk].dev) { struct ata_device *atadev = device_get_softc(rdp->disks[disk].dev); struct ata_channel *ch = device_get_softc(device_get_parent(rdp->disks[disk].dev)); meta->raid.channel = ch->unit; meta->raid.device = ATA_DEV(atadev->unit); meta->raid.disk_sectors = rdp->disks[disk].sectors; meta->raid.disk_offset = rdp->offset_sectors; } else { meta->raid.channel = 0; meta->raid.device = 0; meta->raid.disk_sectors = 0; meta->raid.disk_offset = 0; } meta->magic_0 = PR_MAGIC0(meta->raid) | timestamp.tv_sec; meta->magic_1 = timestamp.tv_sec >> 16; meta->magic_2 = timestamp.tv_sec; meta->raid.integrity = PR_I_VALID; meta->raid.magic_0 = meta->magic_0; meta->raid.rebuild_lba = rdp->rebuild_lba; meta->raid.generation = rdp->generation; if (rdp->status & AR_S_READY) { meta->raid.flags = (PR_F_VALID | PR_F_ASSIGNED | PR_F_ONLINE); meta->raid.status = (PR_S_VALID | PR_S_ONLINE | PR_S_INITED | PR_S_READY); if (rdp->status & AR_S_DEGRADED) meta->raid.status |= PR_S_DEGRADED; else meta->raid.status |= PR_S_FUNCTIONAL; } else { meta->raid.flags = PR_F_DOWN; meta->raid.status = 0; } switch (rdp->type) { case AR_T_RAID0: meta->raid.type = PR_T_RAID0; break; case AR_T_RAID1: meta->raid.type = PR_T_RAID1; break; case AR_T_RAID01: meta->raid.type = PR_T_RAID1; break; case AR_T_RAID5: meta->raid.type = PR_T_RAID5; break; case AR_T_SPAN: meta->raid.type = PR_T_SPAN; break; case AR_T_JBOD: meta->raid.type = PR_T_JBOD; break; default: free(meta, M_AR); return ENODEV; } meta->raid.total_disks = rdp->total_disks; meta->raid.stripe_shift = ffs(rdp->interleave) - 1; meta->raid.array_width = rdp->width; meta->raid.array_number = rdp->lun; meta->raid.total_sectors = rdp->total_sectors; meta->raid.cylinders = rdp->cylinders - 1; meta->raid.heads = rdp->heads - 1; meta->raid.sectors = rdp->sectors; meta->raid.magic_1 = (u_int64_t)meta->magic_2<<16 | meta->magic_1; bzero(&meta->raid.disk, 8 * 12); for (drive = 0; drive < rdp->total_disks; drive++) { meta->raid.disk[drive].flags = 0; if (rdp->disks[drive].flags & AR_DF_PRESENT) meta->raid.disk[drive].flags |= PR_F_VALID; if (rdp->disks[drive].flags & AR_DF_ASSIGNED) meta->raid.disk[drive].flags |= PR_F_ASSIGNED; if (rdp->disks[drive].flags & AR_DF_ONLINE) meta->raid.disk[drive].flags |= PR_F_ONLINE; else if (rdp->disks[drive].flags & AR_DF_PRESENT) meta->raid.disk[drive].flags = (PR_F_REDIR | PR_F_DOWN); if (rdp->disks[drive].flags & AR_DF_SPARE) meta->raid.disk[drive].flags |= PR_F_SPARE; meta->raid.disk[drive].dummy_0 = 0x0; if (rdp->disks[drive].dev) { struct ata_channel *ch = device_get_softc(device_get_parent(rdp->disks[drive].dev)); struct ata_device *atadev = device_get_softc(rdp->disks[drive].dev); meta->raid.disk[drive].channel = ch->unit; meta->raid.disk[drive].device = ATA_DEV(atadev->unit); } meta->raid.disk[drive].magic_0 = PR_MAGIC0(meta->raid.disk[drive]) | timestamp.tv_sec; } if (rdp->disks[disk].dev) { if ((rdp->disks[disk].flags & (AR_DF_PRESENT | AR_DF_ONLINE)) == (AR_DF_PRESENT | AR_DF_ONLINE)) { if (rdp->format == AR_F_FREEBSD_RAID) bcopy(ATA_MAGIC, meta->promise_id, sizeof(ATA_MAGIC)); else bcopy(PR_MAGIC, meta->promise_id, sizeof(PR_MAGIC)); } else bzero(meta->promise_id, sizeof(meta->promise_id)); meta->checksum = 0; for (ckptr = (int32_t *)meta, count = 0; count < 511; count++) meta->checksum += *ckptr++; if (testing || bootverbose) ata_raid_promise_print_meta(meta); if (ata_raid_rw(rdp->disks[disk].dev, PROMISE_LBA(rdp->disks[disk].dev), meta, sizeof(struct promise_raid_conf), ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } free(meta, M_AR); return error; } /* Silicon Image Medley Metadata */ static int ata_raid_sii_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct sii_raid_conf *meta; struct ar_softc *raid = NULL; u_int16_t checksum, *ptr; int array, count, disk, retval = 0; if (!(meta = (struct sii_raid_conf *) malloc(sizeof(struct sii_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, SII_LBA(parent), meta, sizeof(struct sii_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "Silicon Image read metadata failed\n"); goto sii_out; } /* check if this is a Silicon Image (Medley) RAID struct */ for (checksum = 0, ptr = (u_int16_t *)meta, count = 0; count < 160; count++) checksum += *ptr++; if (checksum) { if (testing || bootverbose) device_printf(parent, "Silicon Image check1 failed\n"); goto sii_out; } for (checksum = 0, ptr = (u_int16_t *)meta, count = 0; count < 256; count++) checksum += *ptr++; if (checksum != meta->checksum_1) { if (testing || bootverbose) device_printf(parent, "Silicon Image check2 failed\n"); goto sii_out; } /* check verison */ if (meta->version_major != 0x0002 || (meta->version_minor != 0x0000 && meta->version_minor != 0x0001)) { if (testing || bootverbose) device_printf(parent, "Silicon Image check3 failed\n"); goto sii_out; } if (testing || bootverbose) ata_raid_sii_print_meta(meta); /* now convert Silicon Image meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto sii_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_SII_RAID)) continue; if (raid->format == AR_F_SII_RAID && (raid->magic_0 != *((u_int64_t *)meta->timestamp))) { continue; } /* update our knowledge about the array config based on generation */ if (!meta->generation || meta->generation > raid->generation) { switch (meta->type) { case SII_T_RAID0: raid->type = AR_T_RAID0; break; case SII_T_RAID1: raid->type = AR_T_RAID1; break; case SII_T_RAID01: raid->type = AR_T_RAID01; break; case SII_T_SPARE: device_printf(parent, "Silicon Image SPARE disk\n"); free(raidp[array], M_AR); raidp[array] = NULL; goto sii_out; default: device_printf(parent,"Silicon Image unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto sii_out; } raid->magic_0 = *((u_int64_t *)meta->timestamp); raid->format = AR_F_SII_RAID; raid->generation = meta->generation; raid->interleave = meta->stripe_sectors; raid->width = (meta->raid0_disks != 0xff) ? meta->raid0_disks : 1; raid->total_disks = ((meta->raid0_disks != 0xff) ? meta->raid0_disks : 0) + ((meta->raid1_disks != 0xff) ? meta->raid1_disks : 0); raid->total_sectors = meta->total_sectors; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = meta->rebuild_lba; raid->lun = array; strncpy(raid->name, meta->name, min(sizeof(raid->name), sizeof(meta->name))); /* clear out any old info */ if (raid->generation) { for (disk = 0; disk < raid->total_disks; disk++) { raid->disks[disk].dev = NULL; raid->disks[disk].flags = 0; } } } if (meta->generation >= raid->generation) { /* XXX SOS add check for the right physical disk by serial# */ if (meta->status & SII_S_READY) { int disk_number = (raid->type == AR_T_RAID01) ? meta->raid1_ident + (meta->raid0_ident << 1) : meta->disk_number; raid->disks[disk_number].dev = parent; raid->disks[disk_number].sectors = raid->total_sectors / raid->width; raid->disks[disk_number].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; retval = 1; } } break; } sii_out: free(meta, M_AR); return retval; } /* Silicon Integrated Systems Metadata */ static int ata_raid_sis_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct sis_raid_conf *meta; struct ar_softc *raid = NULL; int array, disk_number, drive, retval = 0; if (!(meta = (struct sis_raid_conf *) malloc(sizeof(struct sis_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, SIS_LBA(parent), meta, sizeof(struct sis_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "Silicon Integrated Systems read metadata failed\n"); } /* check for SiS magic */ if (meta->magic != SIS_MAGIC) { if (testing || bootverbose) device_printf(parent, "Silicon Integrated Systems check1 failed\n"); goto sis_out; } if (testing || bootverbose) ata_raid_sis_print_meta(meta); /* now convert SiS meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto sis_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_SIS_RAID)) continue; if ((raid->format == AR_F_SIS_RAID) && ((raid->magic_0 != meta->controller_pci_id) || (raid->magic_1 != meta->timestamp))) { continue; } switch (meta->type_total_disks & SIS_T_MASK) { case SIS_T_JBOD: raid->type = AR_T_JBOD; raid->width = (meta->type_total_disks & SIS_D_MASK); raid->total_sectors += SIS_LBA(parent); break; case SIS_T_RAID0: raid->type = AR_T_RAID0; raid->width = (meta->type_total_disks & SIS_D_MASK); if (!raid->total_sectors || (raid->total_sectors > (raid->width * SIS_LBA(parent)))) raid->total_sectors = raid->width * SIS_LBA(parent); break; case SIS_T_RAID1: raid->type = AR_T_RAID1; raid->width = 1; if (!raid->total_sectors || (raid->total_sectors > SIS_LBA(parent))) raid->total_sectors = SIS_LBA(parent); break; default: device_printf(parent, "Silicon Integrated Systems " "unknown RAID type 0x%08x\n", meta->magic); free(raidp[array], M_AR); raidp[array] = NULL; goto sis_out; } raid->magic_0 = meta->controller_pci_id; raid->magic_1 = meta->timestamp; raid->format = AR_F_SIS_RAID; raid->generation = 0; raid->interleave = meta->stripe_sectors; raid->total_disks = (meta->type_total_disks & SIS_D_MASK); raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; /* XXX SOS if total_disks > 2 this doesn't float */ if (((meta->disks & SIS_D_MASTER) >> 4) == meta->disk_number) disk_number = 0; else disk_number = 1; for (drive = 0; drive < raid->total_disks; drive++) { raid->disks[drive].sectors = raid->total_sectors/raid->width; if (drive == disk_number) { raid->disks[disk_number].dev = parent; raid->disks[disk_number].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk_number; } } retval = 1; break; } sis_out: free(meta, M_AR); return retval; } static int ata_raid_sis_write_meta(struct ar_softc *rdp) { struct sis_raid_conf *meta; struct timeval timestamp; int disk, error = 0; if (!(meta = (struct sis_raid_conf *) malloc(sizeof(struct sis_raid_conf), M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } rdp->generation++; microtime(×tamp); meta->magic = SIS_MAGIC; /* XXX SOS if total_disks > 2 this doesn't float */ for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { struct ata_channel *ch = device_get_softc(device_get_parent(rdp->disks[disk].dev)); struct ata_device *atadev = device_get_softc(rdp->disks[disk].dev); int disk_number = 1 + ATA_DEV(atadev->unit) + (ch->unit << 1); meta->disks |= disk_number << ((1 - disk) << 2); } } switch (rdp->type) { case AR_T_JBOD: meta->type_total_disks = SIS_T_JBOD; break; case AR_T_RAID0: meta->type_total_disks = SIS_T_RAID0; break; case AR_T_RAID1: meta->type_total_disks = SIS_T_RAID1; break; default: free(meta, M_AR); return ENODEV; } meta->type_total_disks |= (rdp->total_disks & SIS_D_MASK); meta->stripe_sectors = rdp->interleave; meta->timestamp = timestamp.tv_sec; for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { struct ata_channel *ch = device_get_softc(device_get_parent(rdp->disks[disk].dev)); struct ata_device *atadev = device_get_softc(rdp->disks[disk].dev); meta->controller_pci_id = (pci_get_vendor(GRANDPARENT(rdp->disks[disk].dev)) << 16) | pci_get_device(GRANDPARENT(rdp->disks[disk].dev)); bcopy(atadev->param.model, meta->model, sizeof(meta->model)); /* XXX SOS if total_disks > 2 this may not float */ meta->disk_number = 1 + ATA_DEV(atadev->unit) + (ch->unit << 1); if (testing || bootverbose) ata_raid_sis_print_meta(meta); if (ata_raid_rw(rdp->disks[disk].dev, SIS_LBA(rdp->disks[disk].dev), meta, sizeof(struct sis_raid_conf), ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } free(meta, M_AR); return error; } /* VIA Tech V-RAID Metadata */ static int ata_raid_via_read_meta(device_t dev, struct ar_softc **raidp) { struct ata_raid_subdisk *ars = device_get_softc(dev); device_t parent = device_get_parent(dev); struct via_raid_conf *meta; struct ar_softc *raid = NULL; u_int8_t checksum, *ptr; int array, count, disk, retval = 0; if (!(meta = (struct via_raid_conf *) malloc(sizeof(struct via_raid_conf), M_AR, M_NOWAIT | M_ZERO))) return ENOMEM; if (ata_raid_rw(parent, VIA_LBA(parent), meta, sizeof(struct via_raid_conf), ATA_R_READ)) { if (testing || bootverbose) device_printf(parent, "VIA read metadata failed\n"); goto via_out; } /* check if this is a VIA RAID struct */ if (meta->magic != VIA_MAGIC) { if (testing || bootverbose) device_printf(parent, "VIA check1 failed\n"); goto via_out; } /* calculate checksum and compare for valid */ for (checksum = 0, ptr = (u_int8_t *)meta, count = 0; count < 50; count++) checksum += *ptr++; if (checksum != meta->checksum) { if (testing || bootverbose) device_printf(parent, "VIA check2 failed\n"); goto via_out; } if (testing || bootverbose) ata_raid_via_print_meta(meta); /* now convert VIA meta into our generic form */ for (array = 0; array < MAX_ARRAYS; array++) { if (!raidp[array]) { raidp[array] = (struct ar_softc *)malloc(sizeof(struct ar_softc), M_AR, M_NOWAIT | M_ZERO); if (!raidp[array]) { device_printf(parent, "failed to allocate metadata storage\n"); goto via_out; } } raid = raidp[array]; if (raid->format && (raid->format != AR_F_VIA_RAID)) continue; if (raid->format == AR_F_VIA_RAID && (raid->magic_0 != meta->disks[0])) continue; switch (meta->type & VIA_T_MASK) { case VIA_T_RAID0: raid->type = AR_T_RAID0; raid->width = meta->stripe_layout & VIA_L_DISKS; if (!raid->total_sectors || (raid->total_sectors > (raid->width * meta->disk_sectors))) raid->total_sectors = raid->width * meta->disk_sectors; break; case VIA_T_RAID1: raid->type = AR_T_RAID1; raid->width = 1; raid->total_sectors = meta->disk_sectors; break; case VIA_T_RAID01: raid->type = AR_T_RAID01; raid->width = meta->stripe_layout & VIA_L_DISKS; if (!raid->total_sectors || (raid->total_sectors > (raid->width * meta->disk_sectors))) raid->total_sectors = raid->width * meta->disk_sectors; break; case VIA_T_RAID5: raid->type = AR_T_RAID5; raid->width = meta->stripe_layout & VIA_L_DISKS; if (!raid->total_sectors || (raid->total_sectors > ((raid->width - 1)*meta->disk_sectors))) raid->total_sectors = (raid->width - 1) * meta->disk_sectors; break; case VIA_T_SPAN: raid->type = AR_T_SPAN; raid->width = 1; raid->total_sectors += meta->disk_sectors; break; default: device_printf(parent,"VIA unknown RAID type 0x%02x\n", meta->type); free(raidp[array], M_AR); raidp[array] = NULL; goto via_out; } raid->magic_0 = meta->disks[0]; raid->format = AR_F_VIA_RAID; raid->generation = 0; raid->interleave = 0x08 << ((meta->stripe_layout & VIA_L_MASK) >> VIA_L_SHIFT); for (count = 0, disk = 0; disk < 8; disk++) if (meta->disks[disk]) count++; raid->total_disks = count; raid->heads = 255; raid->sectors = 63; raid->cylinders = raid->total_sectors / (63 * 255); raid->offset_sectors = 0; raid->rebuild_lba = 0; raid->lun = array; for (disk = 0; disk < raid->total_disks; disk++) { if (meta->disks[disk] == meta->disk_id) { raid->disks[disk].dev = parent; bcopy(&meta->disk_id, raid->disks[disk].serial, sizeof(u_int32_t)); raid->disks[disk].sectors = meta->disk_sectors; raid->disks[disk].flags = (AR_DF_ONLINE | AR_DF_PRESENT | AR_DF_ASSIGNED); ars->raid[raid->volume] = raid; ars->disk_number[raid->volume] = disk; retval = 1; break; } } break; } via_out: free(meta, M_AR); return retval; } static int ata_raid_via_write_meta(struct ar_softc *rdp) { struct via_raid_conf *meta; int disk, error = 0; if (!(meta = (struct via_raid_conf *) malloc(sizeof(struct via_raid_conf), M_AR, M_NOWAIT | M_ZERO))) { printf("ar%d: failed to allocate metadata storage\n", rdp->lun); return ENOMEM; } rdp->generation++; meta->magic = VIA_MAGIC; meta->dummy_0 = 0x02; switch (rdp->type) { case AR_T_SPAN: meta->type = VIA_T_SPAN; meta->stripe_layout = (rdp->total_disks & VIA_L_DISKS); break; case AR_T_RAID0: meta->type = VIA_T_RAID0; meta->stripe_layout = ((rdp->interleave >> 1) & VIA_L_MASK); meta->stripe_layout |= (rdp->total_disks & VIA_L_DISKS); break; case AR_T_RAID1: meta->type = VIA_T_RAID1; meta->stripe_layout = (rdp->total_disks & VIA_L_DISKS); break; case AR_T_RAID5: meta->type = VIA_T_RAID5; meta->stripe_layout = ((rdp->interleave >> 1) & VIA_L_MASK); meta->stripe_layout |= (rdp->total_disks & VIA_L_DISKS); break; case AR_T_RAID01: meta->type = VIA_T_RAID01; meta->stripe_layout = ((rdp->interleave >> 1) & VIA_L_MASK); meta->stripe_layout |= (rdp->width & VIA_L_DISKS); break; default: free(meta, M_AR); return ENODEV; } meta->type |= VIA_T_BOOTABLE; /* XXX SOS */ meta->disk_sectors = rdp->total_sectors / (rdp->width - (rdp->type == AR_RAID5)); for (disk = 0; disk < rdp->total_disks; disk++) meta->disks[disk] = (u_int32_t)(uintptr_t)rdp->disks[disk].dev; for (disk = 0; disk < rdp->total_disks; disk++) { if (rdp->disks[disk].dev) { u_int8_t *ptr; int count; meta->disk_index = disk * sizeof(u_int32_t); if (rdp->type == AR_T_RAID01) meta->disk_index = ((meta->disk_index & 0x08) << 2) | (meta->disk_index & ~0x08); meta->disk_id = meta->disks[disk]; meta->checksum = 0; for (ptr = (u_int8_t *)meta, count = 0; count < 50; count++) meta->checksum += *ptr++; if (testing || bootverbose) ata_raid_via_print_meta(meta); if (ata_raid_rw(rdp->disks[disk].dev, VIA_LBA(rdp->disks[disk].dev), meta, sizeof(struct via_raid_conf), ATA_R_WRITE | ATA_R_DIRECT)) { device_printf(rdp->disks[disk].dev, "write metadata failed\n"); error = EIO; } } } free(meta, M_AR); return error; } static struct ata_request * ata_raid_init_request(struct ar_softc *rdp, struct bio *bio) { struct ata_request *request; if (!(request = ata_alloc_request())) { printf("FAILURE - out of memory in ata_raid_init_request\n"); return NULL; } request->timeout = 5; request->retries = 2; request->callback = ata_raid_done; request->driver = rdp; request->bio = bio; switch (request->bio->bio_cmd) { case BIO_READ: request->flags = ATA_R_READ; break; case BIO_WRITE: request->flags = ATA_R_WRITE; break; case BIO_FLUSH: request->flags = ATA_R_CONTROL; break; } return request; } static int ata_raid_send_request(struct ata_request *request) { struct ata_device *atadev = device_get_softc(request->dev); request->transfersize = min(request->bytecount, atadev->max_iosize); if (request->flags & ATA_R_READ) { if (atadev->mode >= ATA_DMA) { request->flags |= ATA_R_DMA; request->u.ata.command = ATA_READ_DMA; } else if (atadev->max_iosize > DEV_BSIZE) request->u.ata.command = ATA_READ_MUL; else request->u.ata.command = ATA_READ; } else if (request->flags & ATA_R_WRITE) { if (atadev->mode >= ATA_DMA) { request->flags |= ATA_R_DMA; request->u.ata.command = ATA_WRITE_DMA; } else if (atadev->max_iosize > DEV_BSIZE) request->u.ata.command = ATA_WRITE_MUL; else request->u.ata.command = ATA_WRITE; } else { device_printf(request->dev, "FAILURE - unknown IO operation\n"); ata_free_request(request); return EIO; } request->flags |= (ATA_R_ORDERED | ATA_R_THREAD); ata_queue_request(request); return 0; } static int ata_raid_rw(device_t dev, u_int64_t lba, void *data, u_int bcount, int flags) { struct ata_device *atadev = device_get_softc(dev); struct ata_request *request; int error; if (bcount % DEV_BSIZE) { device_printf(dev, "FAILURE - transfers must be modulo sectorsize\n"); return ENOMEM; } if (!(request = ata_alloc_request())) { device_printf(dev, "FAILURE - out of memory in ata_raid_rw\n"); return ENOMEM; } /* setup request */ request->dev = dev; request->timeout = 10; request->retries = 0; request->data = data; request->bytecount = bcount; request->transfersize = DEV_BSIZE; request->u.ata.lba = lba; request->u.ata.count = request->bytecount / DEV_BSIZE; request->flags = flags; if (flags & ATA_R_READ) { if (atadev->mode >= ATA_DMA) { request->u.ata.command = ATA_READ_DMA; request->flags |= ATA_R_DMA; } else request->u.ata.command = ATA_READ; ata_queue_request(request); } else if (flags & ATA_R_WRITE) { if (atadev->mode >= ATA_DMA) { request->u.ata.command = ATA_WRITE_DMA; request->flags |= ATA_R_DMA; } else request->u.ata.command = ATA_WRITE; ata_queue_request(request); } else { device_printf(dev, "FAILURE - unknown IO operation\n"); request->result = EIO; } error = request->result; ata_free_request(request); return error; } /* * module handeling */ static int ata_raid_subdisk_probe(device_t dev) { device_quiet(dev); return 0; } static int ata_raid_subdisk_attach(device_t dev) { struct ata_raid_subdisk *ars = device_get_softc(dev); int volume; for (volume = 0; volume < MAX_VOLUMES; volume++) { ars->raid[volume] = NULL; ars->disk_number[volume] = -1; } ata_raid_read_metadata(dev); return 0; } static int ata_raid_subdisk_detach(device_t dev) { struct ata_raid_subdisk *ars = device_get_softc(dev); int volume; for (volume = 0; volume < MAX_VOLUMES; volume++) { if (ars->raid[volume]) { ars->raid[volume]->disks[ars->disk_number[volume]].flags &= ~(AR_DF_PRESENT | AR_DF_ONLINE); ars->raid[volume]->disks[ars->disk_number[volume]].dev = NULL; if (mtx_initialized(&ars->raid[volume]->lock)) ata_raid_config_changed(ars->raid[volume], 1); ars->raid[volume] = NULL; ars->disk_number[volume] = -1; } } return 0; } static device_method_t ata_raid_sub_methods[] = { /* device interface */ DEVMETHOD(device_probe, ata_raid_subdisk_probe), DEVMETHOD(device_attach, ata_raid_subdisk_attach), DEVMETHOD(device_detach, ata_raid_subdisk_detach), { 0, 0 } }; static driver_t ata_raid_sub_driver = { "subdisk", ata_raid_sub_methods, sizeof(struct ata_raid_subdisk) }; DRIVER_MODULE(subdisk, ad, ata_raid_sub_driver, ata_raid_sub_devclass, NULL, NULL); static int ata_raid_module_event_handler(module_t mod, int what, void *arg) { int i; switch (what) { case MOD_LOAD: if (testing || bootverbose) printf("ATA PseudoRAID loaded\n"); #if 0 /* setup table to hold metadata for all ATA PseudoRAID arrays */ ata_raid_arrays = malloc(sizeof(struct ar_soft *) * MAX_ARRAYS, M_AR, M_NOWAIT | M_ZERO); if (!ata_raid_arrays) { printf("ataraid: no memory for metadata storage\n"); return ENOMEM; } #endif /* attach found PseudoRAID arrays */ for (i = 0; i < MAX_ARRAYS; i++) { struct ar_softc *rdp = ata_raid_arrays[i]; if (!rdp || !rdp->format) continue; if (testing || bootverbose) ata_raid_print_meta(rdp); ata_raid_attach(rdp, 0); } ata_raid_ioctl_func = ata_raid_ioctl; return 0; case MOD_UNLOAD: /* detach found PseudoRAID arrays */ for (i = 0; i < MAX_ARRAYS; i++) { struct ar_softc *rdp = ata_raid_arrays[i]; if (!rdp || !rdp->status) continue; if (mtx_initialized(&rdp->lock)) mtx_destroy(&rdp->lock); if (rdp->disk) disk_destroy(rdp->disk); } if (testing || bootverbose) printf("ATA PseudoRAID unloaded\n"); #if 0 free(ata_raid_arrays, M_AR); #endif ata_raid_ioctl_func = NULL; return 0; default: return EOPNOTSUPP; } } static moduledata_t ata_raid_moduledata = { "ataraid", ata_raid_module_event_handler, NULL }; DECLARE_MODULE(ata, ata_raid_moduledata, SI_SUB_RAID, SI_ORDER_FIRST); MODULE_VERSION(ataraid, 1); MODULE_DEPEND(ataraid, ata, 1, 1, 1); MODULE_DEPEND(ataraid, ad, 1, 1, 1); static char * ata_raid_format(struct ar_softc *rdp) { switch (rdp->format) { case AR_F_FREEBSD_RAID: return "FreeBSD PseudoRAID"; case AR_F_ADAPTEC_RAID: return "Adaptec HostRAID"; case AR_F_DDF_RAID: return "DDF"; case AR_F_HPTV2_RAID: return "HighPoint v2 RocketRAID"; case AR_F_HPTV3_RAID: return "HighPoint v3 RocketRAID"; case AR_F_INTEL_RAID: return "Intel MatrixRAID"; case AR_F_ITE_RAID: return "Integrated Technology Express"; case AR_F_JMICRON_RAID: return "JMicron Technology Corp"; case AR_F_LSIV2_RAID: return "LSILogic v2 MegaRAID"; case AR_F_LSIV3_RAID: return "LSILogic v3 MegaRAID"; case AR_F_NVIDIA_RAID: return "nVidia MediaShield"; case AR_F_PROMISE_RAID: return "Promise Fasttrak"; case AR_F_SII_RAID: return "Silicon Image Medley"; case AR_F_SIS_RAID: return "Silicon Integrated Systems"; case AR_F_VIA_RAID: return "VIA Tech V-RAID"; default: return "UNKNOWN"; } } static char * ata_raid_type(struct ar_softc *rdp) { switch (rdp->type) { case AR_T_JBOD: return "JBOD"; case AR_T_SPAN: return "SPAN"; case AR_T_RAID0: return "RAID0"; case AR_T_RAID1: return "RAID1"; case AR_T_RAID3: return "RAID3"; case AR_T_RAID4: return "RAID4"; case AR_T_RAID5: return "RAID5"; case AR_T_RAID01: return "RAID0+1"; default: return "UNKNOWN"; } } static char * ata_raid_flags(struct ar_softc *rdp) { switch (rdp->status & (AR_S_READY | AR_S_DEGRADED | AR_S_REBUILDING)) { case AR_S_READY: return "READY"; case AR_S_READY | AR_S_DEGRADED: return "DEGRADED"; case AR_S_READY | AR_S_REBUILDING: case AR_S_READY | AR_S_DEGRADED | AR_S_REBUILDING: return "REBUILDING"; default: return "BROKEN"; } } /* debugging gunk */ static void ata_raid_print_meta(struct ar_softc *raid) { int i; printf("********** ATA PseudoRAID ar%d Metadata **********\n", raid->lun); printf("=================================================\n"); printf("format %s\n", ata_raid_format(raid)); printf("type %s\n", ata_raid_type(raid)); printf("flags 0x%02x %b\n", raid->status, raid->status, "\20\3REBUILDING\2DEGRADED\1READY\n"); printf("magic_0 0x%016jx\n", raid->magic_0); printf("magic_1 0x%016jx\n",raid->magic_1); printf("generation %u\n", raid->generation); printf("total_sectors %ju\n", raid->total_sectors); printf("offset_sectors %ju\n", raid->offset_sectors); printf("heads %u\n", raid->heads); printf("sectors %u\n", raid->sectors); printf("cylinders %u\n", raid->cylinders); printf("width %u\n", raid->width); printf("interleave %u\n", raid->interleave); printf("total_disks %u\n", raid->total_disks); for (i = 0; i < raid->total_disks; i++) { printf(" disk %d: flags = 0x%02x %b\n", i, raid->disks[i].flags, raid->disks[i].flags, "\20\4ONLINE\3SPARE\2ASSIGNED\1PRESENT\n"); if (raid->disks[i].dev) { printf(" "); device_printf(raid->disks[i].dev, " sectors %jd\n", raid->disks[i].sectors); } } printf("=================================================\n"); } static char * ata_raid_adaptec_type(int type) { static char buffer[16]; switch (type) { case ADP_T_RAID0: return "RAID0"; case ADP_T_RAID1: return "RAID1"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_adaptec_print_meta(struct adaptec_raid_conf *meta) { int i; printf("********* ATA Adaptec HostRAID Metadata *********\n"); printf("magic_0 <0x%08x>\n", be32toh(meta->magic_0)); printf("generation 0x%08x\n", be32toh(meta->generation)); printf("dummy_0 0x%04x\n", be16toh(meta->dummy_0)); printf("total_configs %u\n", be16toh(meta->total_configs)); printf("dummy_1 0x%04x\n", be16toh(meta->dummy_1)); printf("checksum 0x%04x\n", be16toh(meta->checksum)); printf("dummy_2 0x%08x\n", be32toh(meta->dummy_2)); printf("dummy_3 0x%08x\n", be32toh(meta->dummy_3)); printf("flags 0x%08x\n", be32toh(meta->flags)); printf("timestamp 0x%08x\n", be32toh(meta->timestamp)); printf("dummy_4 0x%08x 0x%08x 0x%08x 0x%08x\n", be32toh(meta->dummy_4[0]), be32toh(meta->dummy_4[1]), be32toh(meta->dummy_4[2]), be32toh(meta->dummy_4[3])); printf("dummy_5 0x%08x 0x%08x 0x%08x 0x%08x\n", be32toh(meta->dummy_5[0]), be32toh(meta->dummy_5[1]), be32toh(meta->dummy_5[2]), be32toh(meta->dummy_5[3])); for (i = 0; i < be16toh(meta->total_configs); i++) { printf(" %d total_disks %u\n", i, be16toh(meta->configs[i].disk_number)); printf(" %d generation %u\n", i, be16toh(meta->configs[i].generation)); printf(" %d magic_0 0x%08x\n", i, be32toh(meta->configs[i].magic_0)); printf(" %d dummy_0 0x%02x\n", i, meta->configs[i].dummy_0); printf(" %d type %s\n", i, ata_raid_adaptec_type(meta->configs[i].type)); printf(" %d dummy_1 0x%02x\n", i, meta->configs[i].dummy_1); printf(" %d flags %d\n", i, be32toh(meta->configs[i].flags)); printf(" %d dummy_2 0x%02x\n", i, meta->configs[i].dummy_2); printf(" %d dummy_3 0x%02x\n", i, meta->configs[i].dummy_3); printf(" %d dummy_4 0x%02x\n", i, meta->configs[i].dummy_4); printf(" %d dummy_5 0x%02x\n", i, meta->configs[i].dummy_5); printf(" %d disk_number %u\n", i, be32toh(meta->configs[i].disk_number)); printf(" %d dummy_6 0x%08x\n", i, be32toh(meta->configs[i].dummy_6)); printf(" %d sectors %u\n", i, be32toh(meta->configs[i].sectors)); printf(" %d stripe_shift %u\n", i, be16toh(meta->configs[i].stripe_shift)); printf(" %d dummy_7 0x%08x\n", i, be32toh(meta->configs[i].dummy_7)); printf(" %d dummy_8 0x%08x 0x%08x 0x%08x 0x%08x\n", i, be32toh(meta->configs[i].dummy_8[0]), be32toh(meta->configs[i].dummy_8[1]), be32toh(meta->configs[i].dummy_8[2]), be32toh(meta->configs[i].dummy_8[3])); printf(" %d name <%s>\n", i, meta->configs[i].name); } printf("magic_1 <0x%08x>\n", be32toh(meta->magic_1)); printf("magic_2 <0x%08x>\n", be32toh(meta->magic_2)); printf("magic_3 <0x%08x>\n", be32toh(meta->magic_3)); printf("magic_4 <0x%08x>\n", be32toh(meta->magic_4)); printf("=================================================\n"); } static void ata_raid_ddf_print_meta(uint8_t *meta) { struct ddf_header *hdr; struct ddf_cd_record *cd; struct ddf_pd_record *pdr; struct ddf_pd_entry *pde; struct ddf_vd_record *vdr; struct ddf_vd_entry *vde; struct ddf_pdd_record *pdd; uint64_t (*ddf64toh)(uint64_t) = NULL; uint32_t (*ddf32toh)(uint32_t) = NULL; uint16_t (*ddf16toh)(uint16_t) = NULL; uint8_t *cr; char *r; /* Check if this is a DDF RAID struct */ hdr = (struct ddf_header *)meta; if (be32toh(hdr->Signature) == DDF_HEADER_SIGNATURE) { ddf64toh = ddfbe64toh; ddf32toh = ddfbe32toh; ddf16toh = ddfbe16toh; } else { ddf64toh = ddfle64toh; ddf32toh = ddfle32toh; ddf16toh = ddfle16toh; } hdr = (struct ddf_header*)meta; cd = (struct ddf_cd_record*)(meta + ddf32toh(hdr->cd_section) *DEV_BSIZE); pdr = (struct ddf_pd_record*)(meta + ddf32toh(hdr->pdr_section)*DEV_BSIZE); vdr = (struct ddf_vd_record*)(meta + ddf32toh(hdr->vdr_section)*DEV_BSIZE); cr = (uint8_t *)(meta + ddf32toh(hdr->cr_section) * DEV_BSIZE); pdd = (struct ddf_pdd_record*)(meta + ddf32toh(hdr->pdd_section)*DEV_BSIZE); pde = NULL; vde = NULL; printf("********* ATA DDF Metadata *********\n"); printf("**** Header ****\n"); r = (char *)&hdr->DDF_rev[0]; printf("DDF_rev= %8.8s Sequence_Number= 0x%x Open_Flag= 0x%x\n", r, ddf32toh(hdr->Sequence_Number), hdr->Open_Flag); printf("Primary Header LBA= %llu Header_Type = 0x%x\n", (unsigned long long)ddf64toh(hdr->Primary_Header_LBA), hdr->Header_Type); printf("Max_PD_Entries= %d Max_VD_Entries= %d Max_Partitions= %d " "CR_Length= %d\n", ddf16toh(hdr->Max_PD_Entries), ddf16toh(hdr->Max_VD_Entries), ddf16toh(hdr->Max_Partitions), ddf16toh(hdr->Configuration_Record_Length)); printf("CD= %d:%d PDR= %d:%d VDR= %d:%d CR= %d:%d PDD= %d%d\n", ddf32toh(hdr->cd_section), ddf32toh(hdr->cd_length), ddf32toh(hdr->pdr_section), ddf32toh(hdr->pdr_length), ddf32toh(hdr->vdr_section), ddf32toh(hdr->vdr_length), ddf32toh(hdr->cr_section), ddf32toh(hdr->cr_length), ddf32toh(hdr->pdd_section), ddf32toh(hdr->pdd_length)); printf("**** Controler Data ****\n"); r = (char *)&cd->Product_ID[0]; printf("Product_ID: %16.16s\n", r); printf("Vendor 0x%x, Device 0x%x, SubVendor 0x%x, Sub_Device 0x%x\n", ddf16toh(cd->Controller_Type.Vendor_ID), ddf16toh(cd->Controller_Type.Device_ID), ddf16toh(cd->Controller_Type.SubVendor_ID), ddf16toh(cd->Controller_Type.SubDevice_ID)); } static char * ata_raid_hptv2_type(int type) { static char buffer[16]; switch (type) { case HPTV2_T_RAID0: return "RAID0"; case HPTV2_T_RAID1: return "RAID1"; case HPTV2_T_RAID01_RAID0: return "RAID01_RAID0"; case HPTV2_T_SPAN: return "SPAN"; case HPTV2_T_RAID_3: return "RAID3"; case HPTV2_T_RAID_5: return "RAID5"; case HPTV2_T_JBOD: return "JBOD"; case HPTV2_T_RAID01_RAID1: return "RAID01_RAID1"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_hptv2_print_meta(struct hptv2_raid_conf *meta) { int i; printf("****** ATA Highpoint V2 RocketRAID Metadata *****\n"); printf("magic 0x%08x\n", meta->magic); printf("magic_0 0x%08x\n", meta->magic_0); printf("magic_1 0x%08x\n", meta->magic_1); printf("order 0x%08x\n", meta->order); printf("array_width %u\n", meta->array_width); printf("stripe_shift %u\n", meta->stripe_shift); printf("type %s\n", ata_raid_hptv2_type(meta->type)); printf("disk_number %u\n", meta->disk_number); printf("total_sectors %u\n", meta->total_sectors); printf("disk_mode 0x%08x\n", meta->disk_mode); printf("boot_mode 0x%08x\n", meta->boot_mode); printf("boot_disk 0x%02x\n", meta->boot_disk); printf("boot_protect 0x%02x\n", meta->boot_protect); printf("log_entries 0x%02x\n", meta->error_log_entries); printf("log_index 0x%02x\n", meta->error_log_index); if (meta->error_log_entries) { printf(" timestamp reason disk status sectors lba\n"); for (i = meta->error_log_index; i < meta->error_log_index + meta->error_log_entries; i++) printf(" 0x%08x 0x%02x 0x%02x 0x%02x 0x%02x 0x%08x\n", meta->errorlog[i%32].timestamp, meta->errorlog[i%32].reason, meta->errorlog[i%32].disk, meta->errorlog[i%32].status, meta->errorlog[i%32].sectors, meta->errorlog[i%32].lba); } printf("rebuild_lba 0x%08x\n", meta->rebuild_lba); printf("dummy_1 0x%02x\n", meta->dummy_1); printf("name_1 <%.15s>\n", meta->name_1); printf("dummy_2 0x%02x\n", meta->dummy_2); printf("name_2 <%.15s>\n", meta->name_2); printf("=================================================\n"); } static char * ata_raid_hptv3_type(int type) { static char buffer[16]; switch (type) { case HPTV3_T_SPARE: return "SPARE"; case HPTV3_T_JBOD: return "JBOD"; case HPTV3_T_SPAN: return "SPAN"; case HPTV3_T_RAID0: return "RAID0"; case HPTV3_T_RAID1: return "RAID1"; case HPTV3_T_RAID3: return "RAID3"; case HPTV3_T_RAID5: return "RAID5"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_hptv3_print_meta(struct hptv3_raid_conf *meta) { int i; printf("****** ATA Highpoint V3 RocketRAID Metadata *****\n"); printf("magic 0x%08x\n", meta->magic); printf("magic_0 0x%08x\n", meta->magic_0); printf("checksum_0 0x%02x\n", meta->checksum_0); printf("mode 0x%02x\n", meta->mode); printf("user_mode 0x%02x\n", meta->user_mode); printf("config_entries 0x%02x\n", meta->config_entries); for (i = 0; i < meta->config_entries; i++) { printf("config %d:\n", i); printf(" total_sectors %ju\n", meta->configs[0].total_sectors + ((u_int64_t)meta->configs_high[0].total_sectors << 32)); printf(" type %s\n", ata_raid_hptv3_type(meta->configs[i].type)); printf(" total_disks %u\n", meta->configs[i].total_disks); printf(" disk_number %u\n", meta->configs[i].disk_number); printf(" stripe_shift %u\n", meta->configs[i].stripe_shift); printf(" status %b\n", meta->configs[i].status, "\20\2RAID5\1NEED_REBUILD\n"); printf(" critical_disks %u\n", meta->configs[i].critical_disks); printf(" rebuild_lba %ju\n", meta->configs_high[0].rebuild_lba + ((u_int64_t)meta->configs_high[0].rebuild_lba << 32)); } printf("name <%.16s>\n", meta->name); printf("timestamp 0x%08x\n", meta->timestamp); printf("description <%.16s>\n", meta->description); printf("creator <%.16s>\n", meta->creator); printf("checksum_1 0x%02x\n", meta->checksum_1); printf("dummy_0 0x%02x\n", meta->dummy_0); printf("dummy_1 0x%02x\n", meta->dummy_1); printf("flags %b\n", meta->flags, "\20\4RCACHE\3WCACHE\2NCQ\1TCQ\n"); printf("=================================================\n"); } static char * ata_raid_intel_type(int type) { static char buffer[16]; switch (type) { case INTEL_T_RAID0: return "RAID0"; case INTEL_T_RAID1: return "RAID1"; case INTEL_T_RAID5: return "RAID5"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_intel_print_meta(struct intel_raid_conf *meta) { struct intel_raid_mapping *map; int i, j; printf("********* ATA Intel MatrixRAID Metadata *********\n"); printf("intel_id <%.24s>\n", meta->intel_id); printf("version <%.6s>\n", meta->version); printf("checksum 0x%08x\n", meta->checksum); printf("config_size 0x%08x\n", meta->config_size); printf("config_id 0x%08x\n", meta->config_id); printf("generation 0x%08x\n", meta->generation); printf("total_disks %u\n", meta->total_disks); printf("total_volumes %u\n", meta->total_volumes); printf("DISK# serial disk_sectors disk_id flags\n"); for (i = 0; i < meta->total_disks; i++ ) { printf(" %d <%.16s> %u 0x%08x 0x%08x\n", i, meta->disk[i].serial, meta->disk[i].sectors, meta->disk[i].id, meta->disk[i].flags); } map = (struct intel_raid_mapping *)&meta->disk[meta->total_disks]; for (j = 0; j < meta->total_volumes; j++) { printf("name %.16s\n", map->name); printf("total_sectors %ju\n", map->total_sectors); printf("state %u\n", map->state); printf("reserved %u\n", map->reserved); printf("offset %u\n", map->offset); printf("disk_sectors %u\n", map->disk_sectors); printf("stripe_count %u\n", map->stripe_count); printf("stripe_sectors %u\n", map->stripe_sectors); printf("status %u\n", map->status); printf("type %s\n", ata_raid_intel_type(map->type)); printf("total_disks %u\n", map->total_disks); printf("magic[0] 0x%02x\n", map->magic[0]); printf("magic[1] 0x%02x\n", map->magic[1]); printf("magic[2] 0x%02x\n", map->magic[2]); for (i = 0; i < map->total_disks; i++ ) { printf(" disk %d at disk_idx 0x%08x\n", i, map->disk_idx[i]); } map = (struct intel_raid_mapping *)&map->disk_idx[map->total_disks]; } printf("=================================================\n"); } static char * ata_raid_ite_type(int type) { static char buffer[16]; switch (type) { case ITE_T_RAID0: return "RAID0"; case ITE_T_RAID1: return "RAID1"; case ITE_T_RAID01: return "RAID0+1"; case ITE_T_SPAN: return "SPAN"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_ite_print_meta(struct ite_raid_conf *meta) { printf("*** ATA Integrated Technology Express Metadata **\n"); printf("ite_id <%.40s>\n", meta->ite_id); printf("timestamp_0 %04x/%02x/%02x %02x:%02x:%02x.%02x\n", *((u_int16_t *)meta->timestamp_0), meta->timestamp_0[2], meta->timestamp_0[3], meta->timestamp_0[5], meta->timestamp_0[4], meta->timestamp_0[7], meta->timestamp_0[6]); printf("total_sectors %jd\n", meta->total_sectors); printf("type %s\n", ata_raid_ite_type(meta->type)); printf("stripe_1kblocks %u\n", meta->stripe_1kblocks); printf("timestamp_1 %04x/%02x/%02x %02x:%02x:%02x.%02x\n", *((u_int16_t *)meta->timestamp_1), meta->timestamp_1[2], meta->timestamp_1[3], meta->timestamp_1[5], meta->timestamp_1[4], meta->timestamp_1[7], meta->timestamp_1[6]); printf("stripe_sectors %u\n", meta->stripe_sectors); printf("array_width %u\n", meta->array_width); printf("disk_number %u\n", meta->disk_number); printf("disk_sectors %u\n", meta->disk_sectors); printf("=================================================\n"); } static char * ata_raid_jmicron_type(int type) { static char buffer[16]; switch (type) { case JM_T_RAID0: return "RAID0"; case JM_T_RAID1: return "RAID1"; case JM_T_RAID01: return "RAID0+1"; case JM_T_JBOD: return "JBOD"; case JM_T_RAID5: return "RAID5"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_jmicron_print_meta(struct jmicron_raid_conf *meta) { int i; printf("***** ATA JMicron Technology Corp Metadata ******\n"); printf("signature %.2s\n", meta->signature); printf("version 0x%04x\n", meta->version); printf("checksum 0x%04x\n", meta->checksum); printf("disk_id 0x%08x\n", meta->disk_id); printf("offset 0x%08x\n", meta->offset); printf("disk_sectors_low 0x%08x\n", meta->disk_sectors_low); printf("disk_sectors_high 0x%08x\n", meta->disk_sectors_high); printf("name %.16s\n", meta->name); printf("type %s\n", ata_raid_jmicron_type(meta->type)); printf("stripe_shift %d\n", meta->stripe_shift); printf("flags 0x%04x\n", meta->flags); printf("spare:\n"); for (i=0; i < 2 && meta->spare[i]; i++) printf(" %d 0x%08x\n", i, meta->spare[i]); printf("disks:\n"); for (i=0; i < 8 && meta->disks[i]; i++) printf(" %d 0x%08x\n", i, meta->disks[i]); printf("=================================================\n"); } static char * ata_raid_lsiv2_type(int type) { static char buffer[16]; switch (type) { case LSIV2_T_RAID0: return "RAID0"; case LSIV2_T_RAID1: return "RAID1"; case LSIV2_T_SPARE: return "SPARE"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_lsiv2_print_meta(struct lsiv2_raid_conf *meta) { int i; printf("******* ATA LSILogic V2 MegaRAID Metadata *******\n"); printf("lsi_id <%s>\n", meta->lsi_id); printf("dummy_0 0x%02x\n", meta->dummy_0); printf("flags 0x%02x\n", meta->flags); printf("version 0x%04x\n", meta->version); printf("config_entries 0x%02x\n", meta->config_entries); printf("raid_count 0x%02x\n", meta->raid_count); printf("total_disks 0x%02x\n", meta->total_disks); printf("dummy_1 0x%02x\n", meta->dummy_1); printf("dummy_2 0x%04x\n", meta->dummy_2); for (i = 0; i < meta->config_entries; i++) { printf(" type %s\n", ata_raid_lsiv2_type(meta->configs[i].raid.type)); printf(" dummy_0 %02x\n", meta->configs[i].raid.dummy_0); printf(" stripe_sectors %u\n", meta->configs[i].raid.stripe_sectors); printf(" array_width %u\n", meta->configs[i].raid.array_width); printf(" disk_count %u\n", meta->configs[i].raid.disk_count); printf(" config_offset %u\n", meta->configs[i].raid.config_offset); printf(" dummy_1 %u\n", meta->configs[i].raid.dummy_1); printf(" flags %02x\n", meta->configs[i].raid.flags); printf(" total_sectors %u\n", meta->configs[i].raid.total_sectors); } printf("disk_number 0x%02x\n", meta->disk_number); printf("raid_number 0x%02x\n", meta->raid_number); printf("timestamp 0x%08x\n", meta->timestamp); printf("=================================================\n"); } static char * ata_raid_lsiv3_type(int type) { static char buffer[16]; switch (type) { case LSIV3_T_RAID0: return "RAID0"; case LSIV3_T_RAID1: return "RAID1"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_lsiv3_print_meta(struct lsiv3_raid_conf *meta) { int i; printf("******* ATA LSILogic V3 MegaRAID Metadata *******\n"); printf("lsi_id <%.6s>\n", meta->lsi_id); printf("dummy_0 0x%04x\n", meta->dummy_0); printf("version 0x%04x\n", meta->version); printf("dummy_0 0x%04x\n", meta->dummy_1); printf("RAID configs:\n"); for (i = 0; i < 8; i++) { if (meta->raid[i].total_disks) { printf("%02d stripe_pages %u\n", i, meta->raid[i].stripe_pages); printf("%02d type %s\n", i, ata_raid_lsiv3_type(meta->raid[i].type)); printf("%02d total_disks %u\n", i, meta->raid[i].total_disks); printf("%02d array_width %u\n", i, meta->raid[i].array_width); printf("%02d sectors %u\n", i, meta->raid[i].sectors); printf("%02d offset %u\n", i, meta->raid[i].offset); printf("%02d device 0x%02x\n", i, meta->raid[i].device); } } printf("DISK configs:\n"); for (i = 0; i < 6; i++) { if (meta->disk[i].disk_sectors) { printf("%02d disk_sectors %u\n", i, meta->disk[i].disk_sectors); printf("%02d flags 0x%02x\n", i, meta->disk[i].flags); } } printf("device 0x%02x\n", meta->device); printf("timestamp 0x%08x\n", meta->timestamp); printf("checksum_1 0x%02x\n", meta->checksum_1); printf("=================================================\n"); } static char * ata_raid_nvidia_type(int type) { static char buffer[16]; switch (type) { case NV_T_SPAN: return "SPAN"; case NV_T_RAID0: return "RAID0"; case NV_T_RAID1: return "RAID1"; case NV_T_RAID3: return "RAID3"; case NV_T_RAID5: return "RAID5"; case NV_T_RAID01: return "RAID0+1"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_nvidia_print_meta(struct nvidia_raid_conf *meta) { printf("******** ATA nVidia MediaShield Metadata ********\n"); printf("nvidia_id <%.8s>\n", meta->nvidia_id); printf("config_size %d\n", meta->config_size); printf("checksum 0x%08x\n", meta->checksum); printf("version 0x%04x\n", meta->version); printf("disk_number %d\n", meta->disk_number); printf("dummy_0 0x%02x\n", meta->dummy_0); printf("total_sectors %d\n", meta->total_sectors); printf("sectors_size %d\n", meta->sector_size); printf("serial %.16s\n", meta->serial); printf("revision %.4s\n", meta->revision); printf("dummy_1 0x%08x\n", meta->dummy_1); printf("magic_0 0x%08x\n", meta->magic_0); printf("magic_1 0x%016jx\n", meta->magic_1); printf("magic_2 0x%016jx\n", meta->magic_2); printf("flags 0x%02x\n", meta->flags); printf("array_width %d\n", meta->array_width); printf("total_disks %d\n", meta->total_disks); printf("dummy_2 0x%02x\n", meta->dummy_2); printf("type %s\n", ata_raid_nvidia_type(meta->type)); printf("dummy_3 0x%04x\n", meta->dummy_3); printf("stripe_sectors %d\n", meta->stripe_sectors); printf("stripe_bytes %d\n", meta->stripe_bytes); printf("stripe_shift %d\n", meta->stripe_shift); printf("stripe_mask 0x%08x\n", meta->stripe_mask); printf("stripe_sizesectors %d\n", meta->stripe_sizesectors); printf("stripe_sizebytes %d\n", meta->stripe_sizebytes); printf("rebuild_lba %d\n", meta->rebuild_lba); printf("dummy_4 0x%08x\n", meta->dummy_4); printf("dummy_5 0x%08x\n", meta->dummy_5); printf("status 0x%08x\n", meta->status); printf("=================================================\n"); } static char * ata_raid_promise_type(int type) { static char buffer[16]; switch (type) { case PR_T_RAID0: return "RAID0"; case PR_T_RAID1: return "RAID1"; case PR_T_RAID3: return "RAID3"; case PR_T_RAID5: return "RAID5"; case PR_T_SPAN: return "SPAN"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_promise_print_meta(struct promise_raid_conf *meta) { int i; printf("********* ATA Promise FastTrak Metadata *********\n"); printf("promise_id <%s>\n", meta->promise_id); printf("dummy_0 0x%08x\n", meta->dummy_0); printf("magic_0 0x%016jx\n", meta->magic_0); printf("magic_1 0x%04x\n", meta->magic_1); printf("magic_2 0x%08x\n", meta->magic_2); printf("integrity 0x%08x %b\n", meta->raid.integrity, meta->raid.integrity, "\20\10VALID\n" ); printf("flags 0x%02x %b\n", meta->raid.flags, meta->raid.flags, "\20\10READY\7DOWN\6REDIR\5DUPLICATE\4SPARE" "\3ASSIGNED\2ONLINE\1VALID\n"); printf("disk_number %d\n", meta->raid.disk_number); printf("channel 0x%02x\n", meta->raid.channel); printf("device 0x%02x\n", meta->raid.device); printf("magic_0 0x%016jx\n", meta->raid.magic_0); printf("disk_offset %u\n", meta->raid.disk_offset); printf("disk_sectors %u\n", meta->raid.disk_sectors); printf("rebuild_lba 0x%08x\n", meta->raid.rebuild_lba); printf("generation 0x%04x\n", meta->raid.generation); printf("status 0x%02x %b\n", meta->raid.status, meta->raid.status, "\20\6MARKED\5DEGRADED\4READY\3INITED\2ONLINE\1VALID\n"); printf("type %s\n", ata_raid_promise_type(meta->raid.type)); printf("total_disks %u\n", meta->raid.total_disks); printf("stripe_shift %u\n", meta->raid.stripe_shift); printf("array_width %u\n", meta->raid.array_width); printf("array_number %u\n", meta->raid.array_number); printf("total_sectors %u\n", meta->raid.total_sectors); printf("cylinders %u\n", meta->raid.cylinders); printf("heads %u\n", meta->raid.heads); printf("sectors %u\n", meta->raid.sectors); printf("magic_1 0x%016jx\n", meta->raid.magic_1); printf("DISK# flags dummy_0 channel device magic_0\n"); for (i = 0; i < 8; i++) { printf(" %d %b 0x%02x 0x%02x 0x%02x ", i, meta->raid.disk[i].flags, "\20\10READY\7DOWN\6REDIR\5DUPLICATE\4SPARE" "\3ASSIGNED\2ONLINE\1VALID\n", meta->raid.disk[i].dummy_0, meta->raid.disk[i].channel, meta->raid.disk[i].device); printf("0x%016jx\n", meta->raid.disk[i].magic_0); } printf("checksum 0x%08x\n", meta->checksum); printf("=================================================\n"); } static char * ata_raid_sii_type(int type) { static char buffer[16]; switch (type) { case SII_T_RAID0: return "RAID0"; case SII_T_RAID1: return "RAID1"; case SII_T_RAID01: return "RAID0+1"; case SII_T_SPARE: return "SPARE"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_sii_print_meta(struct sii_raid_conf *meta) { printf("******* ATA Silicon Image Medley Metadata *******\n"); printf("total_sectors %ju\n", meta->total_sectors); printf("dummy_0 0x%04x\n", meta->dummy_0); printf("dummy_1 0x%04x\n", meta->dummy_1); printf("controller_pci_id 0x%08x\n", meta->controller_pci_id); printf("version_minor 0x%04x\n", meta->version_minor); printf("version_major 0x%04x\n", meta->version_major); printf("timestamp 20%02x/%02x/%02x %02x:%02x:%02x\n", meta->timestamp[5], meta->timestamp[4], meta->timestamp[3], meta->timestamp[2], meta->timestamp[1], meta->timestamp[0]); printf("stripe_sectors %u\n", meta->stripe_sectors); printf("dummy_2 0x%04x\n", meta->dummy_2); printf("disk_number %u\n", meta->disk_number); printf("type %s\n", ata_raid_sii_type(meta->type)); printf("raid0_disks %u\n", meta->raid0_disks); printf("raid0_ident %u\n", meta->raid0_ident); printf("raid1_disks %u\n", meta->raid1_disks); printf("raid1_ident %u\n", meta->raid1_ident); printf("rebuild_lba %ju\n", meta->rebuild_lba); printf("generation 0x%08x\n", meta->generation); printf("status 0x%02x %b\n", meta->status, meta->status, "\20\1READY\n"); printf("base_raid1_position %02x\n", meta->base_raid1_position); printf("base_raid0_position %02x\n", meta->base_raid0_position); printf("position %02x\n", meta->position); printf("dummy_3 %04x\n", meta->dummy_3); printf("name <%.16s>\n", meta->name); printf("checksum_0 0x%04x\n", meta->checksum_0); printf("checksum_1 0x%04x\n", meta->checksum_1); printf("=================================================\n"); } static char * ata_raid_sis_type(int type) { static char buffer[16]; switch (type) { case SIS_T_JBOD: return "JBOD"; case SIS_T_RAID0: return "RAID0"; case SIS_T_RAID1: return "RAID1"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_sis_print_meta(struct sis_raid_conf *meta) { printf("**** ATA Silicon Integrated Systems Metadata ****\n"); printf("magic 0x%04x\n", meta->magic); printf("disks 0x%02x\n", meta->disks); printf("type %s\n", ata_raid_sis_type(meta->type_total_disks & SIS_T_MASK)); printf("total_disks %u\n", meta->type_total_disks & SIS_D_MASK); printf("dummy_0 0x%08x\n", meta->dummy_0); printf("controller_pci_id 0x%08x\n", meta->controller_pci_id); printf("stripe_sectors %u\n", meta->stripe_sectors); printf("dummy_1 0x%04x\n", meta->dummy_1); printf("timestamp 0x%08x\n", meta->timestamp); printf("model %.40s\n", meta->model); printf("disk_number %u\n", meta->disk_number); printf("dummy_2 0x%02x 0x%02x 0x%02x\n", meta->dummy_2[0], meta->dummy_2[1], meta->dummy_2[2]); printf("=================================================\n"); } static char * ata_raid_via_type(int type) { static char buffer[16]; switch (type) { case VIA_T_RAID0: return "RAID0"; case VIA_T_RAID1: return "RAID1"; case VIA_T_RAID5: return "RAID5"; case VIA_T_RAID01: return "RAID0+1"; case VIA_T_SPAN: return "SPAN"; default: sprintf(buffer, "UNKNOWN 0x%02x", type); return buffer; } } static void ata_raid_via_print_meta(struct via_raid_conf *meta) { int i; printf("*************** ATA VIA Metadata ****************\n"); printf("magic 0x%02x\n", meta->magic); printf("dummy_0 0x%02x\n", meta->dummy_0); printf("type %s\n", ata_raid_via_type(meta->type & VIA_T_MASK)); printf("bootable %d\n", meta->type & VIA_T_BOOTABLE); printf("unknown %d\n", meta->type & VIA_T_UNKNOWN); printf("disk_index 0x%02x\n", meta->disk_index); printf("stripe_layout 0x%02x\n", meta->stripe_layout); printf(" stripe_disks %d\n", meta->stripe_layout & VIA_L_DISKS); printf(" stripe_sectors %d\n", 0x08 << ((meta->stripe_layout & VIA_L_MASK) >> VIA_L_SHIFT)); printf("disk_sectors %ju\n", meta->disk_sectors); printf("disk_id 0x%08x\n", meta->disk_id); printf("DISK# disk_id\n"); for (i = 0; i < 8; i++) { if (meta->disks[i]) printf(" %d 0x%08x\n", i, meta->disks[i]); } printf("checksum 0x%02x\n", meta->checksum); printf("=================================================\n"); }