/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (C) 2008-2010 Lawrence Livermore National Security, LLC. * Produced at Lawrence Livermore National Laboratory (cf, DISCLAIMER). * Rewritten for Linux by Brian Behlendorf . * LLNL-CODE-403049. */ #include #include #include #include #include #include #include char *zfs_vdev_scheduler = VDEV_SCHEDULER; static void *zfs_vdev_holder = VDEV_HOLDER; /* * Virtual device vector for disks. */ typedef struct dio_request { struct completion dr_comp; /* Completion for sync IO */ atomic_t dr_ref; /* References */ zio_t *dr_zio; /* Parent ZIO */ int dr_rw; /* Read/Write */ int dr_error; /* Bio error */ int dr_bio_count; /* Count of bio's */ struct bio *dr_bio[0]; /* Attached bio's */ } dio_request_t; #ifdef HAVE_OPEN_BDEV_EXCLUSIVE static fmode_t vdev_bdev_mode(int smode) { fmode_t mode = 0; ASSERT3S(smode & (FREAD | FWRITE), !=, 0); if (smode & FREAD) mode |= FMODE_READ; if (smode & FWRITE) mode |= FMODE_WRITE; return mode; } #else static int vdev_bdev_mode(int smode) { int mode = 0; ASSERT3S(smode & (FREAD | FWRITE), !=, 0); if ((smode & FREAD) && !(smode & FWRITE)) mode = MS_RDONLY; return mode; } #endif /* HAVE_OPEN_BDEV_EXCLUSIVE */ static uint64_t bdev_capacity(struct block_device *bdev) { struct hd_struct *part = bdev->bd_part; /* The partition capacity referenced by the block device */ if (part) return (part->nr_sects << 9); /* Otherwise assume the full device capacity */ return (get_capacity(bdev->bd_disk) << 9); } static void vdev_disk_error(zio_t *zio) { #ifdef ZFS_DEBUG printk("ZFS: zio error=%d type=%d offset=%llu size=%llu " "flags=%x delay=%llu\n", zio->io_error, zio->io_type, (u_longlong_t)zio->io_offset, (u_longlong_t)zio->io_size, zio->io_flags, (u_longlong_t)zio->io_delay); #endif } /* * Use the Linux 'noop' elevator for zfs managed block devices. This * strikes the ideal balance by allowing the zfs elevator to do all * request ordering and prioritization. While allowing the Linux * elevator to do the maximum front/back merging allowed by the * physical device. This yields the largest possible requests for * the device with the lowest total overhead. */ static int vdev_elevator_switch(vdev_t *v, char *elevator) { vdev_disk_t *vd = v->vdev_tsd; struct block_device *bdev = vd->vd_bdev; struct request_queue *q = bdev_get_queue(bdev); char *device = bdev->bd_disk->disk_name; int error; /* * Skip devices which are not whole disks (partitions). * Device-mapper devices are excepted since they may be whole * disks despite the vdev_wholedisk flag, in which case we can * and should switch the elevator. If the device-mapper device * does not have an elevator (i.e. dm-raid, dm-crypt, etc.) the * "Skip devices without schedulers" check below will fail. */ if (!v->vdev_wholedisk && strncmp(device, "dm-", 3) != 0) return (0); /* Skip devices without schedulers (loop, ram, dm, etc) */ if (!q->elevator || !blk_queue_stackable(q)) return (0); /* Leave existing scheduler when set to "none" */ if (!strncmp(elevator, "none", 4) && (strlen(elevator) == 4)) return (0); #ifdef HAVE_ELEVATOR_CHANGE error = elevator_change(q, elevator); #else /* For pre-2.6.36 kernels elevator_change() is not available. * Therefore we fall back to using a usermodehelper to echo the * elevator into sysfs; This requires /bin/echo and sysfs to be * mounted which may not be true early in the boot process. */ # define SET_SCHEDULER_CMD \ "exec 0/sys/block/%s/queue/scheduler " \ " 2>/dev/null; " \ "echo %s" { char *argv[] = { "/bin/sh", "-c", NULL, NULL }; char *envp[] = { NULL }; argv[2] = kmem_asprintf(SET_SCHEDULER_CMD, device, elevator); error = call_usermodehelper(argv[0], argv, envp, UMH_WAIT_PROC); strfree(argv[2]); } #endif /* HAVE_ELEVATOR_CHANGE */ if (error) printk("ZFS: Unable to set \"%s\" scheduler for %s (%s): %d\n", elevator, v->vdev_path, device, error); return (error); } /* * Expanding a whole disk vdev involves invoking BLKRRPART on the * whole disk device. This poses a problem, because BLKRRPART will * return EBUSY if one of the disk's partitions is open. That's why * we have to do it here, just before opening the data partition. * Unfortunately, BLKRRPART works by dropping all partitions and * recreating them, which means that for a short time window, all * /dev/sdxN device files disappear (until udev recreates them). * This means two things: * - When we open the data partition just after a BLKRRPART, we * can't do it using the normal device file path because of the * obvious race condition with udev. Instead, we use reliable * kernel APIs to get a handle to the new partition device from * the whole disk device. * - Because vdev_disk_open() initially needs to find the device * using its path, multiple vdev_disk_open() invocations in * short succession on the same disk with BLKRRPARTs in the * middle have a high probability of failure (because of the * race condition with udev). A typical situation where this * might happen is when the zpool userspace tool does a * TRYIMPORT immediately followed by an IMPORT. For this * reason, we only invoke BLKRRPART in the module when strictly * necessary (zpool online -e case), and rely on userspace to * do it when possible. */ static struct block_device * vdev_disk_rrpart(const char *path, int mode, vdev_disk_t *vd) { #if defined(HAVE_3ARG_BLKDEV_GET) && defined(HAVE_GET_GENDISK) struct block_device *bdev, *result = ERR_PTR(-ENXIO); struct gendisk *disk; int error, partno; bdev = vdev_bdev_open(path, vdev_bdev_mode(mode), zfs_vdev_holder); if (IS_ERR(bdev)) return bdev; disk = get_gendisk(bdev->bd_dev, &partno); vdev_bdev_close(bdev, vdev_bdev_mode(mode)); if (disk) { bdev = bdget(disk_devt(disk)); if (bdev) { error = blkdev_get(bdev, vdev_bdev_mode(mode), vd); if (error == 0) error = ioctl_by_bdev(bdev, BLKRRPART, 0); vdev_bdev_close(bdev, vdev_bdev_mode(mode)); } bdev = bdget_disk(disk, partno); if (bdev) { error = blkdev_get(bdev, vdev_bdev_mode(mode) | FMODE_EXCL, vd); if (error == 0) result = bdev; } put_disk(disk); } return result; #else return ERR_PTR(-EOPNOTSUPP); #endif /* defined(HAVE_3ARG_BLKDEV_GET) && defined(HAVE_GET_GENDISK) */ } static int vdev_disk_open(vdev_t *v, uint64_t *psize, uint64_t *max_psize, uint64_t *ashift) { struct block_device *bdev = ERR_PTR(-ENXIO); vdev_disk_t *vd; int mode, block_size; /* Must have a pathname and it must be absolute. */ if (v->vdev_path == NULL || v->vdev_path[0] != '/') { v->vdev_stat.vs_aux = VDEV_AUX_BAD_LABEL; return EINVAL; } /* * Reopen the device if it's not currently open. Otherwise, * just update the physical size of the device. */ if (v->vdev_tsd != NULL) { ASSERT(v->vdev_reopening); vd = v->vdev_tsd; goto skip_open; } vd = kmem_zalloc(sizeof(vdev_disk_t), KM_PUSHPAGE); if (vd == NULL) return ENOMEM; /* * Devices are always opened by the path provided at configuration * time. This means that if the provided path is a udev by-id path * then drives may be recabled without an issue. If the provided * path is a udev by-path path, then the physical location information * will be preserved. This can be critical for more complicated * configurations where drives are located in specific physical * locations to maximize the systems tolerence to component failure. * Alternatively, you can provide your own udev rule to flexibly map * the drives as you see fit. It is not advised that you use the * /dev/[hd]d devices which may be reordered due to probing order. * Devices in the wrong locations will be detected by the higher * level vdev validation. */ mode = spa_mode(v->vdev_spa); if (v->vdev_wholedisk && v->vdev_expanding) bdev = vdev_disk_rrpart(v->vdev_path, mode, vd); if (IS_ERR(bdev)) bdev = vdev_bdev_open(v->vdev_path, vdev_bdev_mode(mode), zfs_vdev_holder); if (IS_ERR(bdev)) { kmem_free(vd, sizeof(vdev_disk_t)); return -PTR_ERR(bdev); } v->vdev_tsd = vd; vd->vd_bdev = bdev; skip_open: /* Determine the physical block size */ block_size = vdev_bdev_block_size(vd->vd_bdev); /* Clear the nowritecache bit, causes vdev_reopen() to try again. */ v->vdev_nowritecache = B_FALSE; /* Physical volume size in bytes */ *psize = bdev_capacity(vd->vd_bdev); /* TODO: report possible expansion size */ *max_psize = *psize; /* Based on the minimum sector size set the block size */ *ashift = highbit(MAX(block_size, SPA_MINBLOCKSIZE)) - 1; /* Try to set the io scheduler elevator algorithm */ (void) vdev_elevator_switch(v, zfs_vdev_scheduler); return 0; } static void vdev_disk_close(vdev_t *v) { vdev_disk_t *vd = v->vdev_tsd; if (v->vdev_reopening || vd == NULL) return; if (vd->vd_bdev != NULL) vdev_bdev_close(vd->vd_bdev, vdev_bdev_mode(spa_mode(v->vdev_spa))); kmem_free(vd, sizeof(vdev_disk_t)); v->vdev_tsd = NULL; } static dio_request_t * vdev_disk_dio_alloc(int bio_count) { dio_request_t *dr; int i; dr = kmem_zalloc(sizeof(dio_request_t) + sizeof(struct bio *) * bio_count, KM_PUSHPAGE); if (dr) { init_completion(&dr->dr_comp); atomic_set(&dr->dr_ref, 0); dr->dr_bio_count = bio_count; dr->dr_error = 0; for (i = 0; i < dr->dr_bio_count; i++) dr->dr_bio[i] = NULL; } return dr; } static void vdev_disk_dio_free(dio_request_t *dr) { int i; for (i = 0; i < dr->dr_bio_count; i++) if (dr->dr_bio[i]) bio_put(dr->dr_bio[i]); kmem_free(dr, sizeof(dio_request_t) + sizeof(struct bio *) * dr->dr_bio_count); } static int vdev_disk_dio_is_sync(dio_request_t *dr) { #ifdef HAVE_BIO_RW_SYNC /* BIO_RW_SYNC preferred interface from 2.6.12-2.6.29 */ return (dr->dr_rw & (1 << BIO_RW_SYNC)); #else # ifdef HAVE_BIO_RW_SYNCIO /* BIO_RW_SYNCIO preferred interface from 2.6.30-2.6.35 */ return (dr->dr_rw & (1 << BIO_RW_SYNCIO)); # else # ifdef HAVE_REQ_SYNC /* REQ_SYNC preferred interface from 2.6.36-2.6.xx */ return (dr->dr_rw & REQ_SYNC); # else # error "Unable to determine bio sync flag" # endif /* HAVE_REQ_SYNC */ # endif /* HAVE_BIO_RW_SYNC */ #endif /* HAVE_BIO_RW_SYNCIO */ } static void vdev_disk_dio_get(dio_request_t *dr) { atomic_inc(&dr->dr_ref); } static int vdev_disk_dio_put(dio_request_t *dr) { int rc = atomic_dec_return(&dr->dr_ref); /* * Free the dio_request when the last reference is dropped and * ensure zio_interpret is called only once with the correct zio */ if (rc == 0) { zio_t *zio = dr->dr_zio; int error = dr->dr_error; vdev_disk_dio_free(dr); if (zio) { zio->io_delay = jiffies_64 - zio->io_delay; zio->io_error = error; ASSERT3S(zio->io_error, >=, 0); if (zio->io_error) vdev_disk_error(zio); zio_interrupt(zio); } } return rc; } BIO_END_IO_PROTO(vdev_disk_physio_completion, bio, size, error) { dio_request_t *dr = bio->bi_private; int rc; /* Fatal error but print some useful debugging before asserting */ if (dr == NULL) PANIC("dr == NULL, bio->bi_private == NULL\n" "bi_next: %p, bi_flags: %lx, bi_rw: %lu, bi_vcnt: %d\n" "bi_idx: %d, bi_size: %d, bi_end_io: %p, bi_cnt: %d\n", bio->bi_next, bio->bi_flags, bio->bi_rw, bio->bi_vcnt, bio->bi_idx, bio->bi_size, bio->bi_end_io, atomic_read(&bio->bi_cnt)); #ifndef HAVE_2ARGS_BIO_END_IO_T if (bio->bi_size) return 1; #endif /* HAVE_2ARGS_BIO_END_IO_T */ if (error == 0 && !test_bit(BIO_UPTODATE, &bio->bi_flags)) error = -EIO; if (dr->dr_error == 0) dr->dr_error = -error; /* Drop reference aquired by __vdev_disk_physio */ rc = vdev_disk_dio_put(dr); /* Wake up synchronous waiter this is the last outstanding bio */ if ((rc == 1) && vdev_disk_dio_is_sync(dr)) complete(&dr->dr_comp); BIO_END_IO_RETURN(0); } static inline unsigned long bio_nr_pages(void *bio_ptr, unsigned int bio_size) { return ((((unsigned long)bio_ptr + bio_size + PAGE_SIZE - 1) >> PAGE_SHIFT) - ((unsigned long)bio_ptr >> PAGE_SHIFT)); } static unsigned int bio_map(struct bio *bio, void *bio_ptr, unsigned int bio_size) { unsigned int offset, size, i; struct page *page; offset = offset_in_page(bio_ptr); for (i = 0; i < bio->bi_max_vecs; i++) { size = PAGE_SIZE - offset; if (bio_size <= 0) break; if (size > bio_size) size = bio_size; if (kmem_virt(bio_ptr)) page = vmalloc_to_page(bio_ptr); else page = virt_to_page(bio_ptr); if (bio_add_page(bio, page, size, offset) != size) break; bio_ptr += size; bio_size -= size; offset = 0; } return bio_size; } static int __vdev_disk_physio(struct block_device *bdev, zio_t *zio, caddr_t kbuf_ptr, size_t kbuf_size, uint64_t kbuf_offset, int flags) { dio_request_t *dr; caddr_t bio_ptr; uint64_t bio_offset; int bio_size, bio_count = 16; int i = 0, error = 0; ASSERT3U(kbuf_offset + kbuf_size, <=, bdev->bd_inode->i_size); retry: dr = vdev_disk_dio_alloc(bio_count); if (dr == NULL) return ENOMEM; if (zio && !(zio->io_flags & (ZIO_FLAG_IO_RETRY | ZIO_FLAG_TRYHARD))) bio_set_flags_failfast(bdev, &flags); dr->dr_zio = zio; dr->dr_rw = flags; /* * When the IO size exceeds the maximum bio size for the request * queue we are forced to break the IO in multiple bio's and wait * for them all to complete. Ideally, all pool users will set * their volume block size to match the maximum request size and * the common case will be one bio per vdev IO request. */ bio_ptr = kbuf_ptr; bio_offset = kbuf_offset; bio_size = kbuf_size; for (i = 0; i <= dr->dr_bio_count; i++) { /* Finished constructing bio's for given buffer */ if (bio_size <= 0) break; /* * By default only 'bio_count' bio's per dio are allowed. * However, if we find ourselves in a situation where more * are needed we allocate a larger dio and warn the user. */ if (dr->dr_bio_count == i) { vdev_disk_dio_free(dr); bio_count *= 2; goto retry; } dr->dr_bio[i] = bio_alloc(GFP_NOIO, bio_nr_pages(bio_ptr, bio_size)); if (dr->dr_bio[i] == NULL) { vdev_disk_dio_free(dr); return ENOMEM; } /* Matching put called by vdev_disk_physio_completion */ vdev_disk_dio_get(dr); dr->dr_bio[i]->bi_bdev = bdev; dr->dr_bio[i]->bi_sector = bio_offset >> 9; dr->dr_bio[i]->bi_rw = dr->dr_rw; dr->dr_bio[i]->bi_end_io = vdev_disk_physio_completion; dr->dr_bio[i]->bi_private = dr; /* Remaining size is returned to become the new size */ bio_size = bio_map(dr->dr_bio[i], bio_ptr, bio_size); /* Advance in buffer and construct another bio if needed */ bio_ptr += dr->dr_bio[i]->bi_size; bio_offset += dr->dr_bio[i]->bi_size; } /* Extra reference to protect dio_request during submit_bio */ vdev_disk_dio_get(dr); if (zio) zio->io_delay = jiffies_64; /* Submit all bio's associated with this dio */ for (i = 0; i < dr->dr_bio_count; i++) if (dr->dr_bio[i]) submit_bio(dr->dr_rw, dr->dr_bio[i]); /* * On synchronous blocking requests we wait for all bio the completion * callbacks to run. We will be woken when the last callback runs * for this dio. We are responsible for putting the last dio_request * reference will in turn put back the last bio references. The * only synchronous consumer is vdev_disk_read_rootlabel() all other * IO originating from vdev_disk_io_start() is asynchronous. */ if (vdev_disk_dio_is_sync(dr)) { wait_for_completion(&dr->dr_comp); error = dr->dr_error; ASSERT3S(atomic_read(&dr->dr_ref), ==, 1); } (void)vdev_disk_dio_put(dr); return error; } int vdev_disk_physio(struct block_device *bdev, caddr_t kbuf, size_t size, uint64_t offset, int flags) { bio_set_flags_failfast(bdev, &flags); return __vdev_disk_physio(bdev, NULL, kbuf, size, offset, flags); } BIO_END_IO_PROTO(vdev_disk_io_flush_completion, bio, size, rc) { zio_t *zio = bio->bi_private; zio->io_delay = jiffies_64 - zio->io_delay; zio->io_error = -rc; if (rc && (rc == -EOPNOTSUPP)) zio->io_vd->vdev_nowritecache = B_TRUE; bio_put(bio); ASSERT3S(zio->io_error, >=, 0); if (zio->io_error) vdev_disk_error(zio); zio_interrupt(zio); BIO_END_IO_RETURN(0); } static int vdev_disk_io_flush(struct block_device *bdev, zio_t *zio) { struct request_queue *q; struct bio *bio; q = bdev_get_queue(bdev); if (!q) return ENXIO; bio = bio_alloc(GFP_KERNEL, 0); if (!bio) return ENOMEM; bio->bi_end_io = vdev_disk_io_flush_completion; bio->bi_private = zio; bio->bi_bdev = bdev; zio->io_delay = jiffies_64; submit_bio(VDEV_WRITE_FLUSH_FUA, bio); return 0; } static int vdev_disk_io_start(zio_t *zio) { vdev_t *v = zio->io_vd; vdev_disk_t *vd = v->vdev_tsd; int flags, error; switch (zio->io_type) { case ZIO_TYPE_IOCTL: if (!vdev_readable(v)) { zio->io_error = ENXIO; return ZIO_PIPELINE_CONTINUE; } switch (zio->io_cmd) { case DKIOCFLUSHWRITECACHE: if (zfs_nocacheflush) break; if (v->vdev_nowritecache) { zio->io_error = ENOTSUP; break; } error = vdev_disk_io_flush(vd->vd_bdev, zio); if (error == 0) return ZIO_PIPELINE_STOP; zio->io_error = error; if (error == ENOTSUP) v->vdev_nowritecache = B_TRUE; break; default: zio->io_error = ENOTSUP; } return ZIO_PIPELINE_CONTINUE; case ZIO_TYPE_WRITE: flags = WRITE; break; case ZIO_TYPE_READ: flags = READ; break; default: zio->io_error = ENOTSUP; return ZIO_PIPELINE_CONTINUE; } error = __vdev_disk_physio(vd->vd_bdev, zio, zio->io_data, zio->io_size, zio->io_offset, flags); if (error) { zio->io_error = error; return ZIO_PIPELINE_CONTINUE; } return ZIO_PIPELINE_STOP; } static void vdev_disk_io_done(zio_t *zio) { /* * If the device returned EIO, we revalidate the media. If it is * determined the media has changed this triggers the asynchronous * removal of the device from the configuration. */ if (zio->io_error == EIO) { vdev_t *v = zio->io_vd; vdev_disk_t *vd = v->vdev_tsd; if (check_disk_change(vd->vd_bdev)) { vdev_bdev_invalidate(vd->vd_bdev); v->vdev_remove_wanted = B_TRUE; spa_async_request(zio->io_spa, SPA_ASYNC_REMOVE); } } } static void vdev_disk_hold(vdev_t *vd) { ASSERT(spa_config_held(vd->vdev_spa, SCL_STATE, RW_WRITER)); /* We must have a pathname, and it must be absolute. */ if (vd->vdev_path == NULL || vd->vdev_path[0] != '/') return; /* * Only prefetch path and devid info if the device has * never been opened. */ if (vd->vdev_tsd != NULL) return; /* XXX: Implement me as a vnode lookup for the device */ vd->vdev_name_vp = NULL; vd->vdev_devid_vp = NULL; } static void vdev_disk_rele(vdev_t *vd) { ASSERT(spa_config_held(vd->vdev_spa, SCL_STATE, RW_WRITER)); /* XXX: Implement me as a vnode rele for the device */ } vdev_ops_t vdev_disk_ops = { vdev_disk_open, vdev_disk_close, vdev_default_asize, vdev_disk_io_start, vdev_disk_io_done, NULL, vdev_disk_hold, vdev_disk_rele, VDEV_TYPE_DISK, /* name of this vdev type */ B_TRUE /* leaf vdev */ }; /* * Given the root disk device devid or pathname, read the label from * the device, and construct a configuration nvlist. */ int vdev_disk_read_rootlabel(char *devpath, char *devid, nvlist_t **config) { struct block_device *bdev; vdev_label_t *label; uint64_t s, size; int i; bdev = vdev_bdev_open(devpath, vdev_bdev_mode(FREAD), zfs_vdev_holder); if (IS_ERR(bdev)) return -PTR_ERR(bdev); s = bdev_capacity(bdev); if (s == 0) { vdev_bdev_close(bdev, vdev_bdev_mode(FREAD)); return EIO; } size = P2ALIGN_TYPED(s, sizeof(vdev_label_t), uint64_t); label = vmem_alloc(sizeof(vdev_label_t), KM_PUSHPAGE); for (i = 0; i < VDEV_LABELS; i++) { uint64_t offset, state, txg = 0; /* read vdev label */ offset = vdev_label_offset(size, i, 0); if (vdev_disk_physio(bdev, (caddr_t)label, VDEV_SKIP_SIZE + VDEV_PHYS_SIZE, offset, READ_SYNC) != 0) continue; if (nvlist_unpack(label->vl_vdev_phys.vp_nvlist, sizeof (label->vl_vdev_phys.vp_nvlist), config, 0) != 0) { *config = NULL; continue; } if (nvlist_lookup_uint64(*config, ZPOOL_CONFIG_POOL_STATE, &state) != 0 || state >= POOL_STATE_DESTROYED) { nvlist_free(*config); *config = NULL; continue; } if (nvlist_lookup_uint64(*config, ZPOOL_CONFIG_POOL_TXG, &txg) != 0 || txg == 0) { nvlist_free(*config); *config = NULL; continue; } break; } vmem_free(label, sizeof(vdev_label_t)); vdev_bdev_close(bdev, vdev_bdev_mode(FREAD)); return 0; } module_param(zfs_vdev_scheduler, charp, 0644); MODULE_PARM_DESC(zfs_vdev_scheduler, "I/O scheduler");