/* $NetBSD: raidctl.c,v 1.50 2010/12/15 18:37:55 pooka Exp $ */ /*- * Copyright (c) 1996, 1997, 1998 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Greg Oster * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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. */ /* * This program is a re-write of the original rf_ctrl program * distributed by CMU with RAIDframe 1.1. * * This program is the user-land interface to the RAIDframe kernel * driver in NetBSD. */ #include #ifndef lint __RCSID("$NetBSD: raidctl.c,v 1.50 2010/12/15 18:37:55 pooka Exp $"); #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "rf_configure.h" #include "prog_ops.h" void do_ioctl(int, u_long, void *, const char *); static void rf_configure(int, char*, int); static const char *device_status(RF_DiskStatus_t); static void rf_get_device_status(int); static void rf_output_configuration(int, const char *); static void get_component_number(int, char *, int *, int *); static void rf_fail_disk(int, char *, int); static void usage(void); static void get_component_label(int, char *); static void set_component_label(int, char *); static void init_component_labels(int, int); static void set_autoconfig(int, int, char *); static void add_hot_spare(int, char *); static void remove_hot_spare(int, char *); static void rebuild_in_place(int, char *); static void check_status(int,int); static void check_parity(int,int, char *); static void do_meter(int, u_long); static void get_bar(char *, double, int); static void get_time_string(char *, int); static void rf_output_pmstat(int, int); static void rf_pm_configure(int, int, char *, int[]); int verbose; int main(int argc,char *argv[]) { int ch, i; int num_options; unsigned long action; char config_filename[PATH_MAX]; char dev_name[PATH_MAX]; char name[PATH_MAX]; char component[PATH_MAX]; char autoconf[10]; char *parityconf = NULL; int parityparams[3]; int do_output; int do_recon; int do_rewrite; int is_clean; int raidID; int serial_number; struct stat st; int fd; int force; int openmode; num_options = 0; action = 0; do_output = 0; do_recon = 0; do_rewrite = 0; is_clean = 0; serial_number = 0; force = 0; openmode = O_RDWR; /* default to read/write */ while ((ch = getopt(argc, argv, "a:A:Bc:C:f:F:g:GiI:l:mM:r:R:sSpPuv")) != -1) switch(ch) { case 'a': action = RAIDFRAME_ADD_HOT_SPARE; strlcpy(component, optarg, sizeof(component)); num_options++; break; case 'A': action = RAIDFRAME_SET_AUTOCONFIG; strlcpy(autoconf, optarg, sizeof(autoconf)); num_options++; break; case 'B': action = RAIDFRAME_COPYBACK; num_options++; break; case 'c': action = RAIDFRAME_CONFIGURE; strlcpy(config_filename, optarg, sizeof(config_filename)); force = 0; num_options++; break; case 'C': strlcpy(config_filename, optarg, sizeof(config_filename)); action = RAIDFRAME_CONFIGURE; force = 1; num_options++; break; case 'f': action = RAIDFRAME_FAIL_DISK; strlcpy(component, optarg, sizeof(component)); do_recon = 0; num_options++; break; case 'F': action = RAIDFRAME_FAIL_DISK; strlcpy(component, optarg, sizeof(component)); do_recon = 1; num_options++; break; case 'g': action = RAIDFRAME_GET_COMPONENT_LABEL; strlcpy(component, optarg, sizeof(component)); openmode = O_RDONLY; num_options++; break; case 'G': action = RAIDFRAME_GET_INFO; openmode = O_RDONLY; do_output = 1; num_options++; break; case 'i': action = RAIDFRAME_REWRITEPARITY; num_options++; break; case 'I': action = RAIDFRAME_INIT_LABELS; serial_number = atoi(optarg); num_options++; break; case 'm': action = RAIDFRAME_PARITYMAP_STATUS; openmode = O_RDONLY; num_options++; break; case 'M': action = RAIDFRAME_PARITYMAP_SET_DISABLE; parityconf = strdup(optarg); num_options++; /* XXXjld: should rf_pm_configure do the atoi()s? */ i = 0; while (i < 3 && optind < argc && isdigit((int)argv[optind][0])) parityparams[i++] = atoi(argv[optind++]); while (i < 3) parityparams[i++] = 0; break; case 'l': action = RAIDFRAME_SET_COMPONENT_LABEL; strlcpy(component, optarg, sizeof(component)); num_options++; break; case 'r': action = RAIDFRAME_REMOVE_HOT_SPARE; strlcpy(component, optarg, sizeof(component)); num_options++; break; case 'R': strlcpy(component, optarg, sizeof(component)); action = RAIDFRAME_REBUILD_IN_PLACE; num_options++; break; case 's': action = RAIDFRAME_GET_INFO; openmode = O_RDONLY; num_options++; break; case 'S': action = RAIDFRAME_CHECK_RECON_STATUS_EXT; openmode = O_RDONLY; num_options++; break; case 'p': action = RAIDFRAME_CHECK_PARITY; openmode = O_RDONLY; num_options++; break; case 'P': action = RAIDFRAME_CHECK_PARITY; do_rewrite = 1; num_options++; break; case 'u': action = RAIDFRAME_SHUTDOWN; num_options++; break; case 'v': verbose = 1; /* Don't bump num_options, as '-v' is not an option like the others */ /* num_options++; */ break; default: usage(); } argc -= optind; argv += optind; if ((num_options > 1) || (argc == 0)) usage(); if (prog_init && prog_init() == -1) err(1, "init failed"); strlcpy(name, argv[0], sizeof(name)); fd = opendisk1(name, openmode, dev_name, sizeof(dev_name), 0, prog_open); if (fd == -1) err(1, "Unable to open device file: %s", name); if (fstat(fd, &st) == -1) err(1, "stat failure on: %s", dev_name); if (!S_ISBLK(st.st_mode) && !S_ISCHR(st.st_mode)) err(1, "invalid device: %s", dev_name); raidID = DISKUNIT(st.st_rdev); switch(action) { case RAIDFRAME_ADD_HOT_SPARE: add_hot_spare(fd, component); break; case RAIDFRAME_REMOVE_HOT_SPARE: remove_hot_spare(fd, component); break; case RAIDFRAME_CONFIGURE: rf_configure(fd, config_filename, force); break; case RAIDFRAME_SET_AUTOCONFIG: set_autoconfig(fd, raidID, autoconf); break; case RAIDFRAME_COPYBACK: printf("Copyback.\n"); do_ioctl(fd, RAIDFRAME_COPYBACK, NULL, "RAIDFRAME_COPYBACK"); if (verbose) { sleep(3); /* XXX give the copyback a chance to start */ printf("Copyback status:\n"); do_meter(fd,RAIDFRAME_CHECK_COPYBACK_STATUS_EXT); } break; case RAIDFRAME_FAIL_DISK: rf_fail_disk(fd, component, do_recon); break; case RAIDFRAME_SET_COMPONENT_LABEL: set_component_label(fd, component); break; case RAIDFRAME_GET_COMPONENT_LABEL: get_component_label(fd, component); break; case RAIDFRAME_INIT_LABELS: init_component_labels(fd, serial_number); break; case RAIDFRAME_REWRITEPARITY: printf("Initiating re-write of parity\n"); do_ioctl(fd, RAIDFRAME_REWRITEPARITY, NULL, "RAIDFRAME_REWRITEPARITY"); if (verbose) { sleep(3); /* XXX give it time to get started */ printf("Parity Re-write status:\n"); do_meter(fd, RAIDFRAME_CHECK_PARITYREWRITE_STATUS_EXT); } break; case RAIDFRAME_CHECK_RECON_STATUS_EXT: check_status(fd,1); break; case RAIDFRAME_GET_INFO: if (do_output) rf_output_configuration(fd, dev_name); else rf_get_device_status(fd); break; case RAIDFRAME_PARITYMAP_STATUS: rf_output_pmstat(fd, raidID); break; case RAIDFRAME_PARITYMAP_SET_DISABLE: rf_pm_configure(fd, raidID, parityconf, parityparams); break; case RAIDFRAME_REBUILD_IN_PLACE: rebuild_in_place(fd, component); break; case RAIDFRAME_CHECK_PARITY: check_parity(fd, do_rewrite, dev_name); break; case RAIDFRAME_SHUTDOWN: do_ioctl(fd, RAIDFRAME_SHUTDOWN, NULL, "RAIDFRAME_SHUTDOWN"); break; default: break; } prog_close(fd); exit(0); } void do_ioctl(int fd, unsigned long command, void *arg, const char *ioctl_name) { if (prog_ioctl(fd, command, arg) == -1) err(1, "ioctl (%s) failed", ioctl_name); } static void rf_configure(int fd, char *config_file, int force) { void *generic; RF_Config_t cfg; if (rf_MakeConfig( config_file, &cfg ) != 0) err(1, "Unable to create RAIDframe configuration structure"); cfg.force = force; /* * Note the extra level of redirection needed here, since * what we really want to pass in is a pointer to the pointer to * the configuration structure. */ generic = &cfg; do_ioctl(fd, RAIDFRAME_CONFIGURE, &generic, "RAIDFRAME_CONFIGURE"); } static const char * device_status(RF_DiskStatus_t status) { switch (status) { case rf_ds_optimal: return ("optimal"); break; case rf_ds_failed: return ("failed"); break; case rf_ds_reconstructing: return ("reconstructing"); break; case rf_ds_dist_spared: return ("dist_spared"); break; case rf_ds_spared: return ("spared"); break; case rf_ds_spare: return ("spare"); break; case rf_ds_used_spare: return ("used_spare"); break; default: return ("UNKNOWN"); } /* NOTREACHED */ } static void rf_get_device_status(int fd) { RF_DeviceConfig_t device_config; void *cfg_ptr; int is_clean; int i; cfg_ptr = &device_config; do_ioctl(fd, RAIDFRAME_GET_INFO, &cfg_ptr, "RAIDFRAME_GET_INFO"); printf("Components:\n"); for(i=0; i < device_config.ndevs; i++) { printf("%20s: %s\n", device_config.devs[i].devname, device_status(device_config.devs[i].status)); } if (device_config.nspares > 0) { printf("Spares:\n"); for(i=0; i < device_config.nspares; i++) { printf("%20s: %s\n", device_config.spares[i].devname, device_status(device_config.spares[i].status)); } } else { printf("No spares.\n"); } for(i=0; i < device_config.ndevs; i++) { if (device_config.devs[i].status == rf_ds_optimal) { get_component_label(fd, device_config.devs[i].devname); } else { printf("%s status is: %s. Skipping label.\n", device_config.devs[i].devname, device_status(device_config.devs[i].status)); } } if (device_config.nspares > 0) { for(i=0; i < device_config.nspares; i++) { if ((device_config.spares[i].status == rf_ds_optimal) || (device_config.spares[i].status == rf_ds_used_spare)) { get_component_label(fd, device_config.spares[i].devname); } else { printf("%s status is: %s. Skipping label.\n", device_config.spares[i].devname, device_status(device_config.spares[i].status)); } } } do_ioctl(fd, RAIDFRAME_CHECK_PARITY, &is_clean, "RAIDFRAME_CHECK_PARITY"); if (is_clean) { printf("Parity status: clean\n"); } else { printf("Parity status: DIRTY\n"); } check_status(fd,0); } static void rf_output_pmstat(int fd, int raidID) { char srs[7]; unsigned int i, j; int dis, dr; struct rf_pmstat st; if (prog_ioctl(fd, RAIDFRAME_PARITYMAP_STATUS, &st) == -1) { if (errno == EINVAL) { printf("raid%d: has no parity; parity map disabled\n", raidID); return; } err(1, "ioctl (%s) failed", "RAIDFRAME_PARITYMAP_STATUS"); } if (st.enabled) { if (0 > humanize_number(srs, 7, st.region_size * DEV_BSIZE, "B", HN_AUTOSCALE, HN_NOSPACE)) strlcpy(srs, "???", 7); printf("raid%d: parity map enabled with %u regions of %s\n", raidID, st.params.regions, srs); printf("raid%d: regions marked clean after %d intervals of" " %d.%03ds\n", raidID, st.params.cooldown, st.params.tickms / 1000, st.params.tickms % 1000); printf("raid%d: write/sync/clean counters " "%"PRIu64"/%"PRIu64"/%"PRIu64"\n", raidID, st.ctrs.nwrite, st.ctrs.ncachesync, st.ctrs.nclearing); dr = 0; for (i = 0; i < st.params.regions; i++) if (isset(st.dirty, i)) dr++; printf("raid%d: %d dirty region%s\n", raidID, dr, dr == 1 ? "" : "s"); if (verbose > 0) { for (i = 0; i < RF_PARITYMAP_NBYTE; i += 32) { printf(" "); for (j = i; j < RF_PARITYMAP_NBYTE && j < i + 32; j++) printf("%x%x", st.dirty[j] & 15, (st.dirty[j] >> 4) & 15); printf("\n"); } } } else { printf("raid%d: parity map disabled\n", raidID); } do_ioctl(fd, RAIDFRAME_PARITYMAP_GET_DISABLE, &dis, "RAIDFRAME_PARITYMAP_GET_DISABLE"); printf("raid%d: parity map will %s %sabled on next configure\n", raidID, dis == st.enabled ? "be" : "remain", dis ? "dis" : "en"); } static void rf_pm_configure(int fd, int raidID, char *parityconf, int parityparams[]) { int dis; struct rf_pmparams params; if (strcasecmp(parityconf, "yes") == 0) dis = 0; else if (strcasecmp(parityconf, "no") == 0) dis = 1; else if (strcasecmp(parityconf, "set") == 0) { params.cooldown = parityparams[0]; params.tickms = parityparams[1]; params.regions = parityparams[2]; do_ioctl(fd, RAIDFRAME_PARITYMAP_SET_PARAMS, ¶ms, "RAIDFRAME_PARITYMAP_SET_PARAMS"); if (params.cooldown != 0 || params.tickms != 0) { printf("raid%d: parity cleaned after", raidID); if (params.cooldown != 0) printf(" %d", params.cooldown); printf(" intervals"); if (params.tickms != 0) { printf(" of %d.%03ds", params.tickms / 1000, params.tickms % 1000); } printf("\n"); } if (params.regions != 0) printf("raid%d: will use %d regions on next" " configuration\n", raidID, params.regions); return; /* XXX the control flow here could be prettier. */ } else err(1, "`%s' is not a valid parity map command", parityconf); do_ioctl(fd, RAIDFRAME_PARITYMAP_SET_DISABLE, &dis, "RAIDFRAME_PARITYMAP_SET_DISABLE"); printf("raid%d: parity map will be %sabled on next configure\n", raidID, dis ? "dis" : "en"); } static void rf_output_configuration(int fd, const char *name) { RF_DeviceConfig_t device_config; void *cfg_ptr; int i; RF_ComponentLabel_t component_label; void *label_ptr; int component_num; int num_cols; cfg_ptr = &device_config; printf("# raidctl config file for %s\n", name); printf("\n"); do_ioctl(fd, RAIDFRAME_GET_INFO, &cfg_ptr, "RAIDFRAME_GET_INFO"); printf("START array\n"); printf("# numRow numCol numSpare\n"); printf("%d %d %d\n", device_config.rows, device_config.cols, device_config.nspares); printf("\n"); printf("START disks\n"); for(i=0; i < device_config.ndevs; i++) printf("%s\n", device_config.devs[i].devname); printf("\n"); if (device_config.nspares > 0) { printf("START spare\n"); for(i=0; i < device_config.nspares; i++) printf("%s\n", device_config.spares[i].devname); printf("\n"); } for(i=0; i < device_config.ndevs; i++) { if (device_config.devs[i].status == rf_ds_optimal) break; } if (i == device_config.ndevs) { printf("# WARNING: no optimal components; using %s\n", device_config.devs[0].devname); i = 0; } get_component_number(fd, device_config.devs[i].devname, &component_num, &num_cols); memset(&component_label, 0, sizeof(RF_ComponentLabel_t)); component_label.row = component_num / num_cols; component_label.column = component_num % num_cols; label_ptr = &component_label; do_ioctl(fd, RAIDFRAME_GET_COMPONENT_LABEL, &label_ptr, "RAIDFRAME_GET_COMPONENT_LABEL"); printf("START layout\n"); printf( "# sectPerSU SUsPerParityUnit SUsPerReconUnit RAID_level_%c\n", (char) component_label.parityConfig); printf("%d %d %d %c\n", component_label.sectPerSU, component_label.SUsPerPU, component_label.SUsPerRU, (char) component_label.parityConfig); printf("\n"); printf("START queue\n"); printf("fifo %d\n", device_config.maxqdepth); } static void get_component_number(int fd, char *component_name, int *component_number, int *num_columns) { RF_DeviceConfig_t device_config; void *cfg_ptr; int i; int found; *component_number = -1; /* Assuming a full path spec... */ cfg_ptr = &device_config; do_ioctl(fd, RAIDFRAME_GET_INFO, &cfg_ptr, "RAIDFRAME_GET_INFO"); *num_columns = device_config.cols; found = 0; for(i=0; i < device_config.ndevs; i++) { if (strncmp(component_name, device_config.devs[i].devname, PATH_MAX)==0) { found = 1; *component_number = i; } } if (!found) { /* maybe it's a spare? */ for(i=0; i < device_config.nspares; i++) { if (strncmp(component_name, device_config.spares[i].devname, PATH_MAX)==0) { found = 1; *component_number = i + device_config.ndevs; /* the way spares are done should really change... */ *num_columns = device_config.cols + device_config.nspares; } } } if (!found) err(1,"%s is not a component of this device", component_name); } static void rf_fail_disk(int fd, char *component_to_fail, int do_recon) { struct rf_recon_req recon_request; int component_num; int num_cols; get_component_number(fd, component_to_fail, &component_num, &num_cols); recon_request.row = component_num / num_cols; recon_request.col = component_num % num_cols; if (do_recon) { recon_request.flags = RF_FDFLAGS_RECON; } else { recon_request.flags = RF_FDFLAGS_NONE; } do_ioctl(fd, RAIDFRAME_FAIL_DISK, &recon_request, "RAIDFRAME_FAIL_DISK"); if (do_recon && verbose) { printf("Reconstruction status:\n"); sleep(3); /* XXX give reconstruction a chance to start */ do_meter(fd,RAIDFRAME_CHECK_RECON_STATUS_EXT); } } static void get_component_label(int fd, char *component) { RF_ComponentLabel_t component_label; void *label_ptr; int component_num; int num_cols; get_component_number(fd, component, &component_num, &num_cols); memset( &component_label, 0, sizeof(RF_ComponentLabel_t)); component_label.row = component_num / num_cols; component_label.column = component_num % num_cols; label_ptr = &component_label; do_ioctl( fd, RAIDFRAME_GET_COMPONENT_LABEL, &label_ptr, "RAIDFRAME_GET_COMPONENT_LABEL"); printf("Component label for %s:\n",component); printf(" Row: %d, Column: %d, Num Rows: %d, Num Columns: %d\n", component_label.row, component_label.column, component_label.num_rows, component_label.num_columns); printf(" Version: %d, Serial Number: %d, Mod Counter: %d\n", component_label.version, component_label.serial_number, component_label.mod_counter); printf(" Clean: %s, Status: %d\n", component_label.clean ? "Yes" : "No", component_label.status ); printf(" sectPerSU: %d, SUsPerPU: %d, SUsPerRU: %d\n", component_label.sectPerSU, component_label.SUsPerPU, component_label.SUsPerRU); printf(" Queue size: %d, blocksize: %d, numBlocks: %u\n", component_label.maxOutstanding, component_label.blockSize, component_label.numBlocks); printf(" RAID Level: %c\n", (char) component_label.parityConfig); printf(" Autoconfig: %s\n", component_label.autoconfigure ? "Yes" : "No" ); printf(" Root partition: %s\n", component_label.root_partition ? "Yes" : "No" ); printf(" Last configured as: raid%d\n", component_label.last_unit ); } static void set_component_label(int fd, char *component) { RF_ComponentLabel_t component_label; int component_num; int num_cols; get_component_number(fd, component, &component_num, &num_cols); /* XXX This is currently here for testing, and future expandability */ component_label.version = 1; component_label.serial_number = 123456; component_label.mod_counter = 0; component_label.row = component_num / num_cols; component_label.column = component_num % num_cols; component_label.num_rows = 0; component_label.num_columns = 5; component_label.clean = 0; component_label.status = 1; do_ioctl( fd, RAIDFRAME_SET_COMPONENT_LABEL, &component_label, "RAIDFRAME_SET_COMPONENT_LABEL"); } static void init_component_labels(int fd, int serial_number) { RF_ComponentLabel_t component_label; component_label.version = 0; component_label.serial_number = serial_number; component_label.mod_counter = 0; component_label.row = 0; component_label.column = 0; component_label.num_rows = 0; component_label.num_columns = 0; component_label.clean = 0; component_label.status = 0; do_ioctl( fd, RAIDFRAME_INIT_LABELS, &component_label, "RAIDFRAME_SET_COMPONENT_LABEL"); } static void set_autoconfig(int fd, int raidID, char *autoconf) { int auto_config; int root_config; auto_config = 0; root_config = 0; if (strncasecmp(autoconf,"root", 4) == 0) { root_config = 1; } if ((strncasecmp(autoconf,"yes", 3) == 0) || root_config == 1) { auto_config = 1; } do_ioctl(fd, RAIDFRAME_SET_AUTOCONFIG, &auto_config, "RAIDFRAME_SET_AUTOCONFIG"); do_ioctl(fd, RAIDFRAME_SET_ROOT, &root_config, "RAIDFRAME_SET_ROOT"); printf("raid%d: Autoconfigure: %s\n", raidID, auto_config ? "Yes" : "No"); if (root_config == 1) { printf("raid%d: Root: %s\n", raidID, auto_config ? "Yes" : "No"); } } static void add_hot_spare(int fd, char *component) { RF_SingleComponent_t hot_spare; hot_spare.row = 0; hot_spare.column = 0; strncpy(hot_spare.component_name, component, sizeof(hot_spare.component_name)); do_ioctl( fd, RAIDFRAME_ADD_HOT_SPARE, &hot_spare, "RAIDFRAME_ADD_HOT_SPARE"); } static void remove_hot_spare(int fd, char *component) { RF_SingleComponent_t hot_spare; int component_num; int num_cols; get_component_number(fd, component, &component_num, &num_cols); hot_spare.row = component_num / num_cols; hot_spare.column = component_num % num_cols; strncpy(hot_spare.component_name, component, sizeof(hot_spare.component_name)); do_ioctl( fd, RAIDFRAME_REMOVE_HOT_SPARE, &hot_spare, "RAIDFRAME_REMOVE_HOT_SPARE"); } static void rebuild_in_place(int fd, char *component) { RF_SingleComponent_t comp; int component_num; int num_cols; get_component_number(fd, component, &component_num, &num_cols); comp.row = 0; comp.column = component_num; strncpy(comp.component_name, component, sizeof(comp.component_name)); do_ioctl( fd, RAIDFRAME_REBUILD_IN_PLACE, &comp, "RAIDFRAME_REBUILD_IN_PLACE"); if (verbose) { printf("Reconstruction status:\n"); sleep(3); /* XXX give reconstruction a chance to start */ do_meter(fd,RAIDFRAME_CHECK_RECON_STATUS_EXT); } } static void check_parity(int fd, int do_rewrite, char *dev_name) { int is_clean; int percent_done; is_clean = 0; percent_done = 0; do_ioctl(fd, RAIDFRAME_CHECK_PARITY, &is_clean, "RAIDFRAME_CHECK_PARITY"); if (is_clean) { printf("%s: Parity status: clean\n",dev_name); } else { printf("%s: Parity status: DIRTY\n",dev_name); if (do_rewrite) { printf("%s: Initiating re-write of parity\n", dev_name); do_ioctl(fd, RAIDFRAME_REWRITEPARITY, NULL, "RAIDFRAME_REWRITEPARITY"); sleep(3); /* XXX give it time to get started. */ if (verbose) { printf("Parity Re-write status:\n"); do_meter(fd, RAIDFRAME_CHECK_PARITYREWRITE_STATUS_EXT); } else { do_ioctl(fd, RAIDFRAME_CHECK_PARITYREWRITE_STATUS, &percent_done, "RAIDFRAME_CHECK_PARITYREWRITE_STATUS" ); while( percent_done < 100 ) { sleep(3); /* wait a bit... */ do_ioctl(fd, RAIDFRAME_CHECK_PARITYREWRITE_STATUS, &percent_done, "RAIDFRAME_CHECK_PARITYREWRITE_STATUS"); } } printf("%s: Parity Re-write complete\n", dev_name); } else { /* parity is wrong, and is not being fixed. Exit w/ an error. */ exit(1); } } } static void check_status(int fd, int meter) { int recon_percent_done = 0; int parity_percent_done = 0; int copyback_percent_done = 0; do_ioctl(fd, RAIDFRAME_CHECK_RECON_STATUS, &recon_percent_done, "RAIDFRAME_CHECK_RECON_STATUS"); printf("Reconstruction is %d%% complete.\n", recon_percent_done); do_ioctl(fd, RAIDFRAME_CHECK_PARITYREWRITE_STATUS, &parity_percent_done, "RAIDFRAME_CHECK_PARITYREWRITE_STATUS"); printf("Parity Re-write is %d%% complete.\n", parity_percent_done); do_ioctl(fd, RAIDFRAME_CHECK_COPYBACK_STATUS, ©back_percent_done, "RAIDFRAME_CHECK_COPYBACK_STATUS"); printf("Copyback is %d%% complete.\n", copyback_percent_done); if (meter) { /* These 3 should be mutually exclusive at this point */ if (recon_percent_done < 100) { printf("Reconstruction status:\n"); do_meter(fd,RAIDFRAME_CHECK_RECON_STATUS_EXT); } else if (parity_percent_done < 100) { printf("Parity Re-write status:\n"); do_meter(fd,RAIDFRAME_CHECK_PARITYREWRITE_STATUS_EXT); } else if (copyback_percent_done < 100) { printf("Copyback status:\n"); do_meter(fd,RAIDFRAME_CHECK_COPYBACK_STATUS_EXT); } } } const char *tbits = "|/-\\"; static void do_meter(int fd, u_long option) { int percent_done; RF_uint64 start_value; RF_ProgressInfo_t progressInfo; void *pInfoPtr; struct timeval start_time; struct timeval current_time; double elapsed; int elapsed_sec; int elapsed_usec; int simple_eta,last_eta; double rate; RF_uint64 amount; int tbit_value; char buffer[1024]; char bar_buffer[1024]; char eta_buffer[1024]; if (gettimeofday(&start_time,NULL) == -1) err(1, "gettimeofday failed!?!?"); memset(&progressInfo, 0, sizeof(RF_ProgressInfo_t)); pInfoPtr=&progressInfo; percent_done = 0; do_ioctl(fd, option, &pInfoPtr, ""); start_value = progressInfo.completed; current_time = start_time; simple_eta = 0; last_eta = 0; tbit_value = 0; while(progressInfo.completed < progressInfo.total) { percent_done = (progressInfo.completed * 100) / progressInfo.total; get_bar(bar_buffer, percent_done, 40); elapsed_sec = current_time.tv_sec - start_time.tv_sec; elapsed_usec = current_time.tv_usec - start_time.tv_usec; if (elapsed_usec < 0) { elapsed_usec-=1000000; elapsed_sec++; } elapsed = (double) elapsed_sec + (double) elapsed_usec / 1000000.0; amount = progressInfo.completed - start_value; if (amount <= 0) { /* we don't do negatives (yet?) */ amount = 0; } if (elapsed == 0) rate = 0.0; else rate = amount / elapsed; if (rate > 0.0) { simple_eta = (int) (((double)progressInfo.total - (double) progressInfo.completed) / rate); } else { simple_eta = -1; } if (simple_eta <=0) { simple_eta = last_eta; } else { last_eta = simple_eta; } get_time_string(eta_buffer, simple_eta); snprintf(buffer,1024,"\r%3d%% |%s| ETA: %s %c", percent_done,bar_buffer,eta_buffer,tbits[tbit_value]); write(fileno(stdout),buffer,strlen(buffer)); fflush(stdout); if (++tbit_value>3) tbit_value = 0; sleep(2); if (gettimeofday(¤t_time,NULL) == -1) err(1, "gettimeofday failed!?!?"); do_ioctl( fd, option, &pInfoPtr, ""); } printf("\n"); } /* 40 '*''s per line, then 40 ' ''s line. */ /* If you've got a screen wider than 160 characters, "tough" */ #define STAR_MIDPOINT 4*40 const char stars[] = "****************************************" "****************************************" "****************************************" "****************************************" " " " " " " " " " "; static void get_bar(char *string, double percent, int max_strlen) { int offset; if (max_strlen > STAR_MIDPOINT) { max_strlen = STAR_MIDPOINT; } offset = STAR_MIDPOINT - (int)((percent * max_strlen)/ 100); if (offset < 0) offset = 0; snprintf(string,max_strlen,"%s",&stars[offset]); } static void get_time_string(char *string, int simple_time) { int minutes, seconds, hours; char hours_buffer[5]; char minutes_buffer[5]; char seconds_buffer[5]; if (simple_time >= 0) { minutes = (int) simple_time / 60; seconds = ((int)simple_time - 60*minutes); hours = minutes / 60; minutes = minutes - 60*hours; if (hours > 0) { snprintf(hours_buffer,5,"%02d:",hours); } else { snprintf(hours_buffer,5," "); } snprintf(minutes_buffer,5,"%02d:",minutes); snprintf(seconds_buffer,5,"%02d",seconds); snprintf(string,1024,"%s%s%s", hours_buffer, minutes_buffer, seconds_buffer); } else { snprintf(string,1024," --:--"); } } static void usage(void) { const char *progname = getprogname(); fprintf(stderr, "usage: %s [-v] -a component dev\n", progname); fprintf(stderr, " %s [-v] -A [yes | no | root] dev\n", progname); fprintf(stderr, " %s [-v] -B dev\n", progname); fprintf(stderr, " %s [-v] -c config_file dev\n", progname); fprintf(stderr, " %s [-v] -C config_file dev\n", progname); fprintf(stderr, " %s [-v] -f component dev\n", progname); fprintf(stderr, " %s [-v] -F component dev\n", progname); fprintf(stderr, " %s [-v] -g component dev\n", progname); fprintf(stderr, " %s [-v] -G dev\n", progname); fprintf(stderr, " %s [-v] -i dev\n", progname); fprintf(stderr, " %s [-v] -I serial_number dev\n", progname); fprintf(stderr, " %s [-v] -m dev\n", progname); fprintf(stderr, " %s [-v] -M [yes | no | set params] dev\n", progname); fprintf(stderr, " %s [-v] -p dev\n", progname); fprintf(stderr, " %s [-v] -P dev\n", progname); fprintf(stderr, " %s [-v] -r component dev\n", progname); fprintf(stderr, " %s [-v] -R component dev\n", progname); fprintf(stderr, " %s [-v] -s dev\n", progname); fprintf(stderr, " %s [-v] -S dev\n", progname); fprintf(stderr, " %s [-v] -u dev\n", progname); exit(1); /* NOTREACHED */ }