Current Path : /compat/linux/proc/68247/root/compat/linux/proc/68247/root/compat/linux/proc/68247/root/usr/src/usr.sbin/mfiutil/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //compat/linux/proc/68247/root/compat/linux/proc/68247/root/compat/linux/proc/68247/root/usr/src/usr.sbin/mfiutil/mfi_config.c |
/*- * Copyright (c) 2008, 2009 Yahoo!, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The names of the authors may not be used to endorse or promote * products derived from this software without specific prior written * permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: release/9.1.0/usr.sbin/mfiutil/mfi_config.c 237589 2012-06-26 03:05:17Z eadler $ */ #include <sys/param.h> #ifdef DEBUG #include <sys/sysctl.h> #endif #include <err.h> #include <errno.h> #include <fcntl.h> #include <libutil.h> #ifdef DEBUG #include <stdint.h> #endif #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include "mfiutil.h" #ifdef DEBUG static void dump_config(int fd, struct mfi_config_data *config); #endif static int add_spare(int ac, char **av); static int remove_spare(int ac, char **av); static long dehumanize(const char *value) { char *vtp; long iv; if (value == NULL) return (0); iv = strtoq(value, &vtp, 0); if (vtp == value || (vtp[0] != '\0' && vtp[1] != '\0')) { return (0); } switch (vtp[0]) { case 't': case 'T': iv *= 1024; case 'g': case 'G': iv *= 1024; case 'm': case 'M': iv *= 1024; case 'k': case 'K': iv *= 1024; case '\0': break; default: return (0); } return (iv); } int mfi_config_read(int fd, struct mfi_config_data **configp) { struct mfi_config_data *config; uint32_t config_size; int error; /* * Keep fetching the config in a loop until we have a large enough * buffer to hold the entire configuration. */ config = NULL; config_size = 1024; fetch: config = reallocf(config, config_size); if (config == NULL) return (-1); if (mfi_dcmd_command(fd, MFI_DCMD_CFG_READ, config, config_size, NULL, 0, NULL) < 0) { error = errno; free(config); errno = error; return (-1); } if (config->size > config_size) { config_size = config->size; goto fetch; } *configp = config; return (0); } static struct mfi_array * mfi_config_lookup_array(struct mfi_config_data *config, uint16_t array_ref) { struct mfi_array *ar; char *p; int i; p = (char *)config->array; for (i = 0; i < config->array_count; i++) { ar = (struct mfi_array *)p; if (ar->array_ref == array_ref) return (ar); p += config->array_size; } return (NULL); } static struct mfi_ld_config * mfi_config_lookup_volume(struct mfi_config_data *config, uint8_t target_id) { struct mfi_ld_config *ld; char *p; int i; p = (char *)config->array + config->array_count * config->array_size; for (i = 0; i < config->log_drv_count; i++) { ld = (struct mfi_ld_config *)p; if (ld->properties.ld.v.target_id == target_id) return (ld); p += config->log_drv_size; } return (NULL); } static int clear_config(int ac __unused, char **av __unused) { struct mfi_ld_list list; int ch, error, fd; u_int i; fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } if (!mfi_reconfig_supported()) { warnx("The current mfi(4) driver does not support " "configuration changes."); close(fd); return (EOPNOTSUPP); } if (mfi_ld_get_list(fd, &list, NULL) < 0) { error = errno; warn("Failed to get volume list"); close(fd); return (error); } for (i = 0; i < list.ld_count; i++) { if (mfi_volume_busy(fd, list.ld_list[i].ld.v.target_id)) { warnx("Volume %s is busy and cannot be deleted", mfi_volume_name(fd, list.ld_list[i].ld.v.target_id)); close(fd); return (EBUSY); } } printf( "Are you sure you wish to clear the configuration on mfi%u? [y/N] ", mfi_unit); ch = getchar(); if (ch != 'y' && ch != 'Y') { printf("\nAborting\n"); close(fd); return (0); } if (mfi_dcmd_command(fd, MFI_DCMD_CFG_CLEAR, NULL, 0, NULL, 0, NULL) < 0) { error = errno; warn("Failed to clear configuration"); close(fd); return (error); } printf("mfi%d: Configuration cleared\n", mfi_unit); close(fd); return (0); } MFI_COMMAND(top, clear, clear_config); #define MAX_DRIVES_PER_ARRAY MFI_MAX_ROW_SIZE #define MFI_ARRAY_SIZE sizeof(struct mfi_array) #define RT_RAID0 0 #define RT_RAID1 1 #define RT_RAID5 2 #define RT_RAID6 3 #define RT_JBOD 4 #define RT_CONCAT 5 #define RT_RAID10 6 #define RT_RAID50 7 #define RT_RAID60 8 static int compare_int(const void *one, const void *two) { int first, second; first = *(const int *)one; second = *(const int *)two; return (first - second); } static struct raid_type_entry { const char *name; int raid_type; } raid_type_table[] = { { "raid0", RT_RAID0 }, { "raid-0", RT_RAID0 }, { "raid1", RT_RAID1 }, { "raid-1", RT_RAID1 }, { "mirror", RT_RAID1 }, { "raid5", RT_RAID5 }, { "raid-5", RT_RAID5 }, { "raid6", RT_RAID6 }, { "raid-6", RT_RAID6 }, { "jbod", RT_JBOD }, { "concat", RT_CONCAT }, { "raid10", RT_RAID10 }, { "raid1+0", RT_RAID10 }, { "raid-10", RT_RAID10 }, { "raid-1+0", RT_RAID10 }, { "raid50", RT_RAID50 }, { "raid5+0", RT_RAID50 }, { "raid-50", RT_RAID50 }, { "raid-5+0", RT_RAID50 }, { "raid60", RT_RAID60 }, { "raid6+0", RT_RAID60 }, { "raid-60", RT_RAID60 }, { "raid-6+0", RT_RAID60 }, { NULL, 0 }, }; struct config_id_state { int array_count; int log_drv_count; int *arrays; int *volumes; uint16_t array_ref; uint8_t target_id; }; struct array_info { int drive_count; struct mfi_pd_info *drives; struct mfi_array *array; }; /* Parse a comma-separated list of drives for an array. */ static int parse_array(int fd, int raid_type, char *array_str, struct array_info *info) { struct mfi_pd_info *pinfo; uint16_t device_id; char *cp; u_int count; int error; cp = array_str; for (count = 0; cp != NULL; count++) { cp = strchr(cp, ','); if (cp != NULL) { cp++; if (*cp == ',') { warnx("Invalid drive list '%s'", array_str); return (EINVAL); } } } /* Validate the number of drives for this array. */ if (count >= MAX_DRIVES_PER_ARRAY) { warnx("Too many drives for a single array: max is %d", MAX_DRIVES_PER_ARRAY); return (EINVAL); } switch (raid_type) { case RT_RAID1: case RT_RAID10: if (count % 2 != 0) { warnx("RAID1 and RAID10 require an even number of " "drives in each array"); return (EINVAL); } break; case RT_RAID5: case RT_RAID50: if (count < 3) { warnx("RAID5 and RAID50 require at least 3 drives in " "each array"); return (EINVAL); } break; case RT_RAID6: case RT_RAID60: if (count < 4) { warnx("RAID6 and RAID60 require at least 4 drives in " "each array"); return (EINVAL); } break; } /* Validate each drive. */ info->drives = calloc(count, sizeof(struct mfi_pd_info)); if (info->drives == NULL) { warnx("malloc failed"); return (ENOMEM); } info->drive_count = count; for (pinfo = info->drives; (cp = strsep(&array_str, ",")) != NULL; pinfo++) { error = mfi_lookup_drive(fd, cp, &device_id); if (error) { free(info->drives); info->drives = NULL; return (error); } if (mfi_pd_get_info(fd, device_id, pinfo, NULL) < 0) { error = errno; warn("Failed to fetch drive info for drive %s", cp); free(info->drives); info->drives = NULL; return (error); } if (pinfo->fw_state != MFI_PD_STATE_UNCONFIGURED_GOOD) { warnx("Drive %u is not available", device_id); free(info->drives); info->drives = NULL; return (EINVAL); } } return (0); } /* * Find the next free array ref assuming that 'array_ref' is the last * one used. 'array_ref' should be 0xffff for the initial test. */ static uint16_t find_next_array(struct config_id_state *state) { int i; /* Assume the current one is used. */ state->array_ref++; /* Find the next free one. */ for (i = 0; i < state->array_count; i++) if (state->arrays[i] == state->array_ref) state->array_ref++; return (state->array_ref); } /* * Find the next free volume ID assuming that 'target_id' is the last * one used. 'target_id' should be 0xff for the initial test. */ static uint8_t find_next_volume(struct config_id_state *state) { int i; /* Assume the current one is used. */ state->target_id++; /* Find the next free one. */ for (i = 0; i < state->log_drv_count; i++) if (state->volumes[i] == state->target_id) state->target_id++; return (state->target_id); } /* Populate an array with drives. */ static void build_array(int fd __unused, char *arrayp, struct array_info *array_info, struct config_id_state *state, int verbose) { struct mfi_array *ar = (struct mfi_array *)arrayp; int i; ar->size = array_info->drives[0].coerced_size; ar->num_drives = array_info->drive_count; ar->array_ref = find_next_array(state); for (i = 0; i < array_info->drive_count; i++) { if (verbose) printf("Adding drive %s to array %u\n", mfi_drive_name(NULL, array_info->drives[i].ref.v.device_id, MFI_DNAME_DEVICE_ID|MFI_DNAME_HONOR_OPTS), ar->array_ref); if (ar->size > array_info->drives[i].coerced_size) ar->size = array_info->drives[i].coerced_size; ar->pd[i].ref = array_info->drives[i].ref; ar->pd[i].fw_state = MFI_PD_STATE_ONLINE; } array_info->array = ar; } /* * Create a volume that spans one or more arrays. */ static void build_volume(char *volumep, int narrays, struct array_info *arrays, int raid_type, long stripe_size, struct config_id_state *state, int verbose) { struct mfi_ld_config *ld = (struct mfi_ld_config *)volumep; struct mfi_array *ar; int i; /* properties */ ld->properties.ld.v.target_id = find_next_volume(state); ld->properties.ld.v.seq = 0; ld->properties.default_cache_policy = MR_LD_CACHE_ALLOW_WRITE_CACHE | MR_LD_CACHE_WRITE_BACK; ld->properties.access_policy = MFI_LD_ACCESS_RW; ld->properties.disk_cache_policy = MR_PD_CACHE_UNCHANGED; ld->properties.current_cache_policy = MR_LD_CACHE_ALLOW_WRITE_CACHE | MR_LD_CACHE_WRITE_BACK; ld->properties.no_bgi = 0; /* params */ switch (raid_type) { case RT_RAID0: case RT_JBOD: ld->params.primary_raid_level = DDF_RAID0; ld->params.raid_level_qualifier = 0; ld->params.secondary_raid_level = 0; break; case RT_RAID1: ld->params.primary_raid_level = DDF_RAID1; ld->params.raid_level_qualifier = 0; ld->params.secondary_raid_level = 0; break; case RT_RAID5: ld->params.primary_raid_level = DDF_RAID5; ld->params.raid_level_qualifier = 3; ld->params.secondary_raid_level = 0; break; case RT_RAID6: ld->params.primary_raid_level = DDF_RAID6; ld->params.raid_level_qualifier = 3; ld->params.secondary_raid_level = 0; break; case RT_CONCAT: ld->params.primary_raid_level = DDF_CONCAT; ld->params.raid_level_qualifier = 0; ld->params.secondary_raid_level = 0; break; case RT_RAID10: ld->params.primary_raid_level = DDF_RAID1; ld->params.raid_level_qualifier = 0; ld->params.secondary_raid_level = 3; /* XXX? */ break; case RT_RAID50: /* * XXX: This appears to work though the card's BIOS * complains that the configuration is foreign. The * BIOS setup does not allow for creation of RAID-50 * or RAID-60 arrays. The only nested array * configuration it allows for is RAID-10. */ ld->params.primary_raid_level = DDF_RAID5; ld->params.raid_level_qualifier = 3; ld->params.secondary_raid_level = 3; /* XXX? */ break; case RT_RAID60: ld->params.primary_raid_level = DDF_RAID6; ld->params.raid_level_qualifier = 3; ld->params.secondary_raid_level = 3; /* XXX? */ break; } /* * Stripe size is encoded as (2 ^ N) * 512 = stripe_size. Use * ffs() to simulate log2(stripe_size). */ ld->params.stripe_size = ffs(stripe_size) - 1 - 9; ld->params.num_drives = arrays[0].array->num_drives; ld->params.span_depth = narrays; ld->params.state = MFI_LD_STATE_OPTIMAL; ld->params.init_state = MFI_LD_PARAMS_INIT_NO; ld->params.is_consistent = 0; /* spans */ for (i = 0; i < narrays; i++) { ar = arrays[i].array; if (verbose) printf("Adding array %u to volume %u\n", ar->array_ref, ld->properties.ld.v.target_id); ld->span[i].start_block = 0; ld->span[i].num_blocks = ar->size; ld->span[i].array_ref = ar->array_ref; } } static int create_volume(int ac, char **av) { struct mfi_config_data *config; struct mfi_array *ar; struct mfi_ld_config *ld; struct config_id_state state; size_t config_size; char *p, *cfg_arrays, *cfg_volumes; int error, fd, i, raid_type; int narrays, nvolumes, arrays_per_volume; struct array_info *arrays; long stripe_size; #ifdef DEBUG int dump; #endif int ch, verbose; /* * Backwards compat. Map 'create volume' to 'create' and * 'create spare' to 'add'. */ if (ac > 1) { if (strcmp(av[1], "volume") == 0) { av++; ac--; } else if (strcmp(av[1], "spare") == 0) { av++; ac--; return (add_spare(ac, av)); } } if (ac < 2) { warnx("create volume: volume type required"); return (EINVAL); } bzero(&state, sizeof(state)); config = NULL; arrays = NULL; narrays = 0; error = 0; fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } if (!mfi_reconfig_supported()) { warnx("The current mfi(4) driver does not support " "configuration changes."); error = EOPNOTSUPP; goto error; } /* Lookup the RAID type first. */ raid_type = -1; for (i = 0; raid_type_table[i].name != NULL; i++) if (strcasecmp(raid_type_table[i].name, av[1]) == 0) { raid_type = raid_type_table[i].raid_type; break; } if (raid_type == -1) { warnx("Unknown or unsupported volume type %s", av[1]); error = EINVAL; goto error; } /* Parse any options. */ optind = 2; #ifdef DEBUG dump = 0; #endif verbose = 0; stripe_size = 64 * 1024; while ((ch = getopt(ac, av, "ds:v")) != -1) { switch (ch) { #ifdef DEBUG case 'd': dump = 1; break; #endif case 's': stripe_size = dehumanize(optarg); if ((stripe_size < 512) || (!powerof2(stripe_size))) stripe_size = 64 * 1024; break; case 'v': verbose = 1; break; case '?': default: error = EINVAL; goto error; } } ac -= optind; av += optind; /* Parse all the arrays. */ narrays = ac; if (narrays == 0) { warnx("At least one drive list is required"); error = EINVAL; goto error; } switch (raid_type) { case RT_RAID0: case RT_RAID1: case RT_RAID5: case RT_RAID6: case RT_CONCAT: if (narrays != 1) { warnx("Only one drive list can be specified"); error = EINVAL; goto error; } break; case RT_RAID10: case RT_RAID50: case RT_RAID60: if (narrays < 1) { warnx("RAID10, RAID50, and RAID60 require at least " "two drive lists"); error = EINVAL; goto error; } if (narrays > MFI_MAX_SPAN_DEPTH) { warnx("Volume spans more than %d arrays", MFI_MAX_SPAN_DEPTH); error = EINVAL; goto error; } break; } arrays = calloc(narrays, sizeof(*arrays)); if (arrays == NULL) { warnx("malloc failed"); error = ENOMEM; goto error; } for (i = 0; i < narrays; i++) { error = parse_array(fd, raid_type, av[i], &arrays[i]); if (error) goto error; } switch (raid_type) { case RT_RAID10: case RT_RAID50: case RT_RAID60: for (i = 1; i < narrays; i++) { if (arrays[i].drive_count != arrays[0].drive_count) { warnx("All arrays must contain the same " "number of drives"); error = EINVAL; goto error; } } break; } /* * Fetch the current config and build sorted lists of existing * array and volume identifiers. */ if (mfi_config_read(fd, &config) < 0) { error = errno; warn("Failed to read configuration"); goto error; } p = (char *)config->array; state.array_ref = 0xffff; state.target_id = 0xff; state.array_count = config->array_count; if (config->array_count > 0) { state.arrays = calloc(config->array_count, sizeof(int)); if (state.arrays == NULL) { warnx("malloc failed"); error = ENOMEM; goto error; } for (i = 0; i < config->array_count; i++) { ar = (struct mfi_array *)p; state.arrays[i] = ar->array_ref; p += config->array_size; } qsort(state.arrays, config->array_count, sizeof(int), compare_int); } else state.arrays = NULL; state.log_drv_count = config->log_drv_count; if (config->log_drv_count) { state.volumes = calloc(config->log_drv_count, sizeof(int)); if (state.volumes == NULL) { warnx("malloc failed"); error = ENOMEM; goto error; } for (i = 0; i < config->log_drv_count; i++) { ld = (struct mfi_ld_config *)p; state.volumes[i] = ld->properties.ld.v.target_id; p += config->log_drv_size; } qsort(state.volumes, config->log_drv_count, sizeof(int), compare_int); } else state.volumes = NULL; free(config); /* Determine the size of the configuration we will build. */ switch (raid_type) { case RT_RAID0: case RT_RAID1: case RT_RAID5: case RT_RAID6: case RT_CONCAT: case RT_JBOD: /* Each volume spans a single array. */ nvolumes = narrays; break; case RT_RAID10: case RT_RAID50: case RT_RAID60: /* A single volume spans multiple arrays. */ nvolumes = 1; break; default: /* Pacify gcc. */ abort(); } config_size = sizeof(struct mfi_config_data) + sizeof(struct mfi_ld_config) * nvolumes + MFI_ARRAY_SIZE * narrays; config = calloc(1, config_size); if (config == NULL) { warnx("malloc failed"); error = ENOMEM; goto error; } config->size = config_size; config->array_count = narrays; config->array_size = MFI_ARRAY_SIZE; /* XXX: Firmware hardcode */ config->log_drv_count = nvolumes; config->log_drv_size = sizeof(struct mfi_ld_config); config->spares_count = 0; config->spares_size = 40; /* XXX: Firmware hardcode */ cfg_arrays = (char *)config->array; cfg_volumes = cfg_arrays + config->array_size * narrays; /* Build the arrays. */ for (i = 0; i < narrays; i++) { build_array(fd, cfg_arrays, &arrays[i], &state, verbose); cfg_arrays += config->array_size; } /* Now build the volume(s). */ arrays_per_volume = narrays / nvolumes; for (i = 0; i < nvolumes; i++) { build_volume(cfg_volumes, arrays_per_volume, &arrays[i * arrays_per_volume], raid_type, stripe_size, &state, verbose); cfg_volumes += config->log_drv_size; } #ifdef DEBUG if (dump) dump_config(fd, config); #endif /* Send the new config to the controller. */ if (mfi_dcmd_command(fd, MFI_DCMD_CFG_ADD, config, config_size, NULL, 0, NULL) < 0) { error = errno; warn("Failed to add volume"); /* FALLTHROUGH */ } error: /* Clean up. */ free(config); free(state.volumes); free(state.arrays); if (arrays != NULL) { for (i = 0; i < narrays; i++) free(arrays[i].drives); free(arrays); } close(fd); return (error); } MFI_COMMAND(top, create, create_volume); static int delete_volume(int ac, char **av) { struct mfi_ld_info info; int error, fd; uint8_t target_id, mbox[4]; /* * Backwards compat. Map 'delete volume' to 'delete' and * 'delete spare' to 'remove'. */ if (ac > 1) { if (strcmp(av[1], "volume") == 0) { av++; ac--; } else if (strcmp(av[1], "spare") == 0) { av++; ac--; return (remove_spare(ac, av)); } } if (ac != 2) { warnx("delete volume: volume required"); return (EINVAL); } fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } if (!mfi_reconfig_supported()) { warnx("The current mfi(4) driver does not support " "configuration changes."); close(fd); return (EOPNOTSUPP); } if (mfi_lookup_volume(fd, av[1], &target_id) < 0) { error = errno; warn("Invalid volume %s", av[1]); close(fd); return (error); } if (mfi_ld_get_info(fd, target_id, &info, NULL) < 0) { error = errno; warn("Failed to get info for volume %d", target_id); close(fd); return (error); } if (mfi_volume_busy(fd, target_id)) { warnx("Volume %s is busy and cannot be deleted", mfi_volume_name(fd, target_id)); close(fd); return (EBUSY); } mbox_store_ldref(mbox, &info.ld_config.properties.ld); if (mfi_dcmd_command(fd, MFI_DCMD_LD_DELETE, NULL, 0, mbox, sizeof(mbox), NULL) < 0) { error = errno; warn("Failed to delete volume"); close(fd); return (error); } close(fd); return (0); } MFI_COMMAND(top, delete, delete_volume); static int add_spare(int ac, char **av) { struct mfi_pd_info info; struct mfi_config_data *config; struct mfi_array *ar; struct mfi_ld_config *ld; struct mfi_spare *spare; uint16_t device_id; uint8_t target_id; char *p; int error, fd, i; if (ac < 2) { warnx("add spare: drive required"); return (EINVAL); } fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } config = NULL; spare = NULL; error = mfi_lookup_drive(fd, av[1], &device_id); if (error) goto error; if (mfi_pd_get_info(fd, device_id, &info, NULL) < 0) { error = errno; warn("Failed to fetch drive info"); goto error; } if (info.fw_state != MFI_PD_STATE_UNCONFIGURED_GOOD) { warnx("Drive %u is not available", device_id); error = EINVAL; goto error; } if (ac > 2) { if (mfi_lookup_volume(fd, av[2], &target_id) < 0) { error = errno; warn("Invalid volume %s", av[2]); goto error; } } if (mfi_config_read(fd, &config) < 0) { error = errno; warn("Failed to read configuration"); goto error; } spare = malloc(sizeof(struct mfi_spare) + sizeof(uint16_t) * config->array_count); if (spare == NULL) { warnx("malloc failed"); error = ENOMEM; goto error; } bzero(spare, sizeof(struct mfi_spare)); spare->ref = info.ref; if (ac == 2) { /* Global spare backs all arrays. */ p = (char *)config->array; for (i = 0; i < config->array_count; i++) { ar = (struct mfi_array *)p; if (ar->size > info.coerced_size) { warnx("Spare isn't large enough for array %u", ar->array_ref); error = EINVAL; goto error; } p += config->array_size; } spare->array_count = 0; } else { /* * Dedicated spares only back the arrays for a * specific volume. */ ld = mfi_config_lookup_volume(config, target_id); if (ld == NULL) { warnx("Did not find volume %d", target_id); error = EINVAL; goto error; } spare->spare_type |= MFI_SPARE_DEDICATED; spare->array_count = ld->params.span_depth; for (i = 0; i < ld->params.span_depth; i++) { ar = mfi_config_lookup_array(config, ld->span[i].array_ref); if (ar == NULL) { warnx("Missing array; inconsistent config?"); error = ENXIO; goto error; } if (ar->size > info.coerced_size) { warnx("Spare isn't large enough for array %u", ar->array_ref); error = EINVAL; goto error; } spare->array_ref[i] = ar->array_ref; } } if (mfi_dcmd_command(fd, MFI_DCMD_CFG_MAKE_SPARE, spare, sizeof(struct mfi_spare) + sizeof(uint16_t) * spare->array_count, NULL, 0, NULL) < 0) { error = errno; warn("Failed to assign spare"); /* FALLTHROUGH. */ } error: free(spare); free(config); close(fd); return (error); } MFI_COMMAND(top, add, add_spare); static int remove_spare(int ac, char **av) { struct mfi_pd_info info; int error, fd; uint16_t device_id; uint8_t mbox[4]; if (ac != 2) { warnx("remove spare: drive required"); return (EINVAL); } fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } error = mfi_lookup_drive(fd, av[1], &device_id); if (error) { close(fd); return (error); } /* Get the info for this drive. */ if (mfi_pd_get_info(fd, device_id, &info, NULL) < 0) { error = errno; warn("Failed to fetch info for drive %u", device_id); close(fd); return (error); } if (info.fw_state != MFI_PD_STATE_HOT_SPARE) { warnx("Drive %u is not a hot spare", device_id); close(fd); return (EINVAL); } mbox_store_pdref(mbox, &info.ref); if (mfi_dcmd_command(fd, MFI_DCMD_CFG_REMOVE_SPARE, NULL, 0, mbox, sizeof(mbox), NULL) < 0) { error = errno; warn("Failed to delete spare"); close(fd); return (error); } close(fd); return (0); } MFI_COMMAND(top, remove, remove_spare); #ifdef DEBUG /* Display raw data about a config. */ static void dump_config(int fd, struct mfi_config_data *config) { struct mfi_array *ar; struct mfi_ld_config *ld; struct mfi_spare *sp; struct mfi_pd_info pinfo; uint16_t device_id; char *p; int i, j; printf( "mfi%d Configuration (Debug): %d arrays, %d volumes, %d spares\n", mfi_unit, config->array_count, config->log_drv_count, config->spares_count); printf(" array size: %u\n", config->array_size); printf(" volume size: %u\n", config->log_drv_size); printf(" spare size: %u\n", config->spares_size); p = (char *)config->array; for (i = 0; i < config->array_count; i++) { ar = (struct mfi_array *)p; printf(" array %u of %u drives:\n", ar->array_ref, ar->num_drives); printf(" size = %ju\n", (uintmax_t)ar->size); for (j = 0; j < ar->num_drives; j++) { device_id = ar->pd[j].ref.v.device_id; if (device_id == 0xffff) printf(" drive MISSING\n"); else { printf(" drive %u %s\n", device_id, mfi_pdstate(ar->pd[j].fw_state)); if (mfi_pd_get_info(fd, device_id, &pinfo, NULL) >= 0) { printf(" raw size: %ju\n", (uintmax_t)pinfo.raw_size); printf(" non-coerced size: %ju\n", (uintmax_t)pinfo.non_coerced_size); printf(" coerced size: %ju\n", (uintmax_t)pinfo.coerced_size); } } } p += config->array_size; } for (i = 0; i < config->log_drv_count; i++) { ld = (struct mfi_ld_config *)p; printf(" volume %s ", mfi_volume_name(fd, ld->properties.ld.v.target_id)); printf("%s %s", mfi_raid_level(ld->params.primary_raid_level, ld->params.secondary_raid_level), mfi_ldstate(ld->params.state)); if (ld->properties.name[0] != '\0') printf(" <%s>", ld->properties.name); printf("\n"); printf(" primary raid level: %u\n", ld->params.primary_raid_level); printf(" raid level qualifier: %u\n", ld->params.raid_level_qualifier); printf(" secondary raid level: %u\n", ld->params.secondary_raid_level); printf(" stripe size: %u\n", ld->params.stripe_size); printf(" num drives: %u\n", ld->params.num_drives); printf(" init state: %u\n", ld->params.init_state); printf(" consistent: %u\n", ld->params.is_consistent); printf(" no bgi: %u\n", ld->properties.no_bgi); printf(" spans:\n"); for (j = 0; j < ld->params.span_depth; j++) { printf(" array %u @ ", ld->span[j].array_ref); printf("%ju : %ju\n", (uintmax_t)ld->span[j].start_block, (uintmax_t)ld->span[j].num_blocks); } p += config->log_drv_size; } for (i = 0; i < config->spares_count; i++) { sp = (struct mfi_spare *)p; printf(" %s spare %u ", sp->spare_type & MFI_SPARE_DEDICATED ? "dedicated" : "global", sp->ref.v.device_id); printf("%s", mfi_pdstate(MFI_PD_STATE_HOT_SPARE)); printf(" backs:\n"); for (j = 0; j < sp->array_count; j++) printf(" array %u\n", sp->array_ref[j]); p += config->spares_size; } } static int debug_config(int ac, char **av) { struct mfi_config_data *config; int error, fd; if (ac != 1) { warnx("debug: extra arguments"); return (EINVAL); } fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } /* Get the config from the controller. */ if (mfi_config_read(fd, &config) < 0) { error = errno; warn("Failed to get config"); close(fd); return (error); } /* Dump out the configuration. */ dump_config(fd, config); free(config); close(fd); return (0); } MFI_COMMAND(top, debug, debug_config); static int dump(int ac, char **av) { struct mfi_config_data *config; char buf[64]; size_t len; int error, fd; if (ac != 1) { warnx("dump: extra arguments"); return (EINVAL); } fd = mfi_open(mfi_unit, O_RDWR); if (fd < 0) { error = errno; warn("mfi_open"); return (error); } /* Get the stashed copy of the last dcmd from the driver. */ snprintf(buf, sizeof(buf), "dev.mfi.%d.debug_command", mfi_unit); if (sysctlbyname(buf, NULL, &len, NULL, 0) < 0) { error = errno; warn("Failed to read debug command"); if (error == ENOENT) error = EOPNOTSUPP; close(fd); return (error); } config = malloc(len); if (config == NULL) { warnx("malloc failed"); close(fd); return (ENOMEM); } if (sysctlbyname(buf, config, &len, NULL, 0) < 0) { error = errno; warn("Failed to read debug command"); free(config); close(fd); return (error); } dump_config(fd, config); free(config); close(fd); return (0); } MFI_COMMAND(top, dump, dump); #endif