/* * 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 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "libdiskmgt.h" #include "disks_private.h" #define CLUSTER_DEV "did" /* specify which disk links to use in the /dev directory */ #define DEVLINK_REGEX "rdsk/.*" #define DEVLINK_FLOPPY_REGEX "rdiskette[0-9]" #define DEVLINK_DID_REGEX "did/rdsk/.*" #define FLOPPY_NAME "rdiskette" #define MAXPROPLEN 1024 #define DEVICE_ID_PROP "devid" #define PROD_ID_PROP "inquiry-product-id" #define PROD_ID_USB_PROP "usb-product-name" #define REMOVABLE_PROP "removable-media" #define HOTPLUGGABLE_PROP "hotpluggable" #define SCSI_OPTIONS_PROP "scsi-options" #define VENDOR_ID_PROP "inquiry-vendor-id" #define VENDOR_ID_USB_PROP "usb-vendor-name" #define WWN_PROP "node-wwn" /* The list of names of possible disk types used by libdevinfo. */ static char *disktypes[] = { DDI_NT_BLOCK, DDI_NT_BLOCK_CHAN, DDI_NT_BLOCK_WWN, DDI_NT_BLOCK_FABRIC, DDI_NT_CD_CHAN, DDI_NT_CD, DDI_NT_FD, NULL }; /* * Most of the removable media will be lumped under here; CD, DVD, MO, etc. */ static char *cdromtypes[] = { DDI_NT_CD_CHAN, DDI_NT_CD, NULL }; static char *ctrltypes[] = { DDI_NT_SCSI_NEXUS, DDI_NT_SCSI_ATTACHMENT_POINT, DDI_NT_FC_ATTACHMENT_POINT, NULL }; static char *bustypes[] = { "sbus", "pci", "usb", NULL }; static bus_t *add_bus(struct search_args *args, di_node_t node, di_minor_t minor, controller_t *cp); static int add_cluster_devs(di_node_t node, di_minor_t minor, void *arg); static controller_t *add_controller(struct search_args *args, di_node_t node, di_minor_t minor); static int add_devpath(di_devlink_t devlink, void *arg); static int add_devs(di_node_t node, di_minor_t minor, void *arg); static int add_disk2controller(disk_t *diskp, struct search_args *args); static int add_disk2path(disk_t *dp, path_t *pp, di_path_state_t st, char *wwn); static int add_int2array(int p, int **parray); static int add_ptr2array(void *p, void ***parray); static char *bus_type(di_node_t node, di_minor_t minor, di_prom_handle_t ph); static int can_remove_controller(controller_t *cp, controller_t *currp); static void clean_paths(struct search_args *args); static disk_t *create_disk(char *deviceid, char *kernel_name, struct search_args *args); static char *ctype(di_node_t node, di_minor_t minor); static boolean_t disk_is_cdrom(char *type); static alias_t *find_alias(disk_t *diskp, char *kernel_name); static bus_t *find_bus(struct search_args *args, char *name); static controller_t *find_controller(struct search_args *args, char *name); static int fix_cluster_devpath(di_devlink_t devlink, void *arg); static disk_t *get_disk_by_deviceid(disk_t *listp, char *devid); static void get_disk_name_from_path(char *path, char *name, int size); static char *get_byte_prop(char *prop_name, di_node_t node); static di_node_t get_parent_bus(di_node_t node, struct search_args *args); static int get_prom_int(char *prop_name, di_node_t node, di_prom_handle_t ph); static char *get_prom_str(char *prop_name, di_node_t node, di_prom_handle_t ph); static int get_prop(char *prop_name, di_node_t node); static char *get_str_prop(char *prop_name, di_node_t node); static int have_disk(struct search_args *args, char *devid, char *kernel_name, disk_t **diskp); static int is_cluster_disk(di_node_t node, di_minor_t minor); static int is_ctds(char *name); static int is_drive(di_minor_t minor); static int is_zvol(di_node_t node, di_minor_t minor); static int is_HBA(di_node_t node, di_minor_t minor); static int new_alias(disk_t *diskp, char *kernel_path, char *devlink_path, struct search_args *args); static int new_devpath(alias_t *ap, char *devpath); static path_t *new_path(controller_t *cp, disk_t *diskp, di_node_t node, di_path_state_t st, char *wwn); static void remove_invalid_controller(char *name, controller_t *currp, struct search_args *args); static char *str_case_index(register char *s1, register char *s2); /* * The functions in this file do a dev tree walk to build up a model of the * disks, controllers and paths on the system. This model is returned in the * args->disk_listp and args->controller_listp members of the args param. * There is no global data for this file so it is thread safe. It is up to * the caller to merge the resulting model with any existing model that is * cached. The caller must also free the memory for this model when it is * no longer needed. */ void findevs(struct search_args *args) { uint_t flags; di_node_t di_root; args->dev_walk_status = 0; args->disk_listp = NULL; args->controller_listp = NULL; args->bus_listp = NULL; args->handle = di_devlink_init(NULL, 0); /* * Have to make several passes at this with the new devfs caching. * First, we find non-mpxio devices. Then we find mpxio/multipath * devices. Finally, we get cluster devices. */ flags = DINFOCACHE; di_root = di_init("/", flags); args->ph = di_prom_init(); (void) di_walk_minor(di_root, NULL, 0, args, add_devs); di_fini(di_root); flags = DINFOCPYALL | DINFOPATH; di_root = di_init("/", flags); (void) di_walk_minor(di_root, NULL, 0, args, add_devs); di_fini(di_root); /* do another pass to clean up cluster devpaths */ flags = DINFOCACHE; di_root = di_init("/", flags); (void) di_walk_minor(di_root, DDI_PSEUDO, 0, args, add_cluster_devs); if (args->ph != DI_PROM_HANDLE_NIL) { (void) di_prom_fini(args->ph); } di_fini(di_root); (void) di_devlink_fini(&(args->handle)); clean_paths(args); } /* * Definitions of private functions */ static bus_t * add_bus(struct search_args *args, di_node_t node, di_minor_t minor, controller_t *cp) { char *btype; char *devpath; bus_t *bp; char kstat_name[MAXPATHLEN]; di_node_t pnode; if (node == DI_NODE_NIL) { return (NULL); } if ((btype = bus_type(node, minor, args->ph)) == NULL) { return (add_bus(args, di_parent_node(node), di_minor_next(di_parent_node(node), NULL), cp)); } devpath = di_devfs_path(node); if ((bp = find_bus(args, devpath)) != NULL) { di_devfs_path_free((void *) devpath); if (cp != NULL) { if (add_ptr2array(cp, (void ***)&bp->controllers) != 0) { args->dev_walk_status = ENOMEM; return (NULL); } } return (bp); } /* Special handling for root node. */ if (strcmp(devpath, "/") == 0) { di_devfs_path_free((void *) devpath); return (NULL); } if (dm_debug) { (void) fprintf(stderr, "INFO: add_bus %s\n", devpath); } bp = (bus_t *)calloc(1, sizeof (bus_t)); if (bp == NULL) { return (NULL); } bp->name = strdup(devpath); di_devfs_path_free((void *) devpath); if (bp->name == NULL) { args->dev_walk_status = ENOMEM; cache_free_bus(bp); return (NULL); } bp->btype = strdup(btype); if (bp->btype == NULL) { args->dev_walk_status = ENOMEM; cache_free_bus(bp); return (NULL); } (void) snprintf(kstat_name, sizeof (kstat_name), "%s%d", di_node_name(node), di_instance(node)); if ((bp->kstat_name = strdup(kstat_name)) == NULL) { args->dev_walk_status = ENOMEM; cache_free_bus(bp); return (NULL); } /* if parent node is a bus, get its name */ if ((pnode = get_parent_bus(node, args)) != NULL) { devpath = di_devfs_path(pnode); bp->pname = strdup(devpath); di_devfs_path_free((void *) devpath); if (bp->pname == NULL) { args->dev_walk_status = ENOMEM; cache_free_bus(bp); return (NULL); } } else { bp->pname = NULL; } bp->freq = get_prom_int("clock-frequency", node, args->ph); bp->controllers = (controller_t **)calloc(1, sizeof (controller_t *)); if (bp->controllers == NULL) { args->dev_walk_status = ENOMEM; cache_free_bus(bp); return (NULL); } bp->controllers[0] = NULL; if (cp != NULL) { if (add_ptr2array(cp, (void ***)&bp->controllers) != 0) { args->dev_walk_status = ENOMEM; return (NULL); } } bp->next = args->bus_listp; args->bus_listp = bp; return (bp); } static int add_cluster_devs(di_node_t node, di_minor_t minor, void *arg) { struct search_args *args; char *devpath; char slice_path[MAXPATHLEN]; int result = DI_WALK_CONTINUE; if (!is_cluster_disk(node, minor)) { return (DI_WALK_CONTINUE); } args = (struct search_args *)arg; if (dm_debug > 1) { /* This is all just debugging code */ char *devpath; char dev_name[MAXPATHLEN]; devpath = di_devfs_path(node); (void) snprintf(dev_name, sizeof (dev_name), "%s:%s", devpath, di_minor_name(minor)); di_devfs_path_free((void *) devpath); (void) fprintf(stderr, "INFO: cluster dev: %s\n", dev_name); } args->node = node; args->minor = minor; args->dev_walk_status = 0; /* * Fix the devpaths for the cluster drive. * * We will come through here once for each raw slice device name. */ devpath = di_devfs_path(node); (void) snprintf(slice_path, sizeof (slice_path), "%s:%s", devpath, di_minor_name(minor)); di_devfs_path_free((void *) devpath); /* Walk the /dev tree to get the cluster devlinks. */ (void) di_devlink_walk(args->handle, DEVLINK_DID_REGEX, slice_path, DI_PRIMARY_LINK, arg, fix_cluster_devpath); if (args->dev_walk_status != 0) { result = DI_WALK_TERMINATE; } return (result); } static controller_t * add_controller(struct search_args *args, di_node_t node, di_minor_t minor) { char *devpath; controller_t *cp; char kstat_name[MAXPATHLEN]; char *c_type = DM_CTYPE_UNKNOWN; devpath = di_devfs_path(node); if ((cp = find_controller(args, devpath)) != NULL) { di_devfs_path_free((void *) devpath); return (cp); } /* Special handling for fp attachment node. */ if (strcmp(di_node_name(node), "fp") == 0) { di_node_t pnode; pnode = di_parent_node(node); if (pnode != DI_NODE_NIL) { di_devfs_path_free((void *) devpath); devpath = di_devfs_path(pnode); if ((cp = find_controller(args, devpath)) != NULL) { di_devfs_path_free((void *) devpath); return (cp); } /* not in the list, create it */ node = pnode; c_type = DM_CTYPE_FIBRE; } } if (dm_debug) { (void) fprintf(stderr, "INFO: add_controller %s\n", devpath); } cp = (controller_t *)calloc(1, sizeof (controller_t)); if (cp == NULL) { return (NULL); } cp->name = strdup(devpath); di_devfs_path_free((void *) devpath); if (cp->name == NULL) { cache_free_controller(cp); return (NULL); } if (strcmp(c_type, DM_CTYPE_UNKNOWN) == 0) { c_type = ctype(node, minor); } cp->ctype = c_type; (void) snprintf(kstat_name, sizeof (kstat_name), "%s%d", di_node_name(node), di_instance(node)); if ((cp->kstat_name = strdup(kstat_name)) == NULL) { cache_free_controller(cp); return (NULL); } if (libdiskmgt_str_eq(cp->ctype, "scsi")) { cp->scsi_options = get_prop(SCSI_OPTIONS_PROP, node); } if (libdiskmgt_str_eq(di_node_name(node), "scsi_vhci")) { cp->multiplex = 1; } else { cp->multiplex = 0; } cp->freq = get_prom_int("clock-frequency", node, args->ph); cp->disks = (disk_t **)calloc(1, sizeof (disk_t *)); if (cp->disks == NULL) { cache_free_controller(cp); return (NULL); } cp->disks[0] = NULL; cp->next = args->controller_listp; args->controller_listp = cp; cp->bus = add_bus(args, di_parent_node(node), di_minor_next(di_parent_node(node), NULL), cp); return (cp); } static int add_devpath(di_devlink_t devlink, void *arg) { struct search_args *args; char *devidstr; disk_t *diskp; char kernel_name[MAXPATHLEN]; args = (struct search_args *)arg; /* * Get the diskp value from calling have_disk. Can either be found * by kernel name or devid. */ diskp = NULL; devidstr = get_str_prop(DEVICE_ID_PROP, args->node); (void) snprintf(kernel_name, sizeof (kernel_name), "%s%d", di_node_name(args->node), di_instance(args->node)); (void) have_disk(args, devidstr, kernel_name, &diskp); /* * The devlink_path is usually of the form /dev/rdsk/c0t0d0s0. * For diskettes it is /dev/rdiskette*. * On Intel we would also get each fdisk partition as well * (e.g. /dev/rdsk/c0t0d0p0). */ if (diskp != NULL) { alias_t *ap; char *devlink_path; if (diskp->drv_type != DM_DT_FLOPPY) { /* * Add other controllers for multipath disks. This will have * no effect if the controller relationship is already set up. */ if (add_disk2controller(diskp, args) != 0) { args->dev_walk_status = ENOMEM; } } (void) snprintf(kernel_name, sizeof (kernel_name), "%s%d", di_node_name(args->node), di_instance(args->node)); devlink_path = (char *)di_devlink_path(devlink); if (dm_debug > 1) { (void) fprintf(stderr, "INFO: devpath %s\n", devlink_path); } if ((ap = find_alias(diskp, kernel_name)) == NULL) { if (new_alias(diskp, kernel_name, devlink_path, args) != 0) { args->dev_walk_status = ENOMEM; } } else { /* * It is possible that we have already added this devpath. * Do not add it again. new_devpath will return a 0 if * found, and not add the path. */ if (new_devpath(ap, devlink_path) != 0) { args->dev_walk_status = ENOMEM; } } } return (DI_WALK_CONTINUE); } static int add_devs(di_node_t node, di_minor_t minor, void *arg) { struct search_args *args; int result = DI_WALK_CONTINUE; args = (struct search_args *)arg; if (dm_debug > 1) { /* This is all just debugging code */ char *devpath; char dev_name[MAXPATHLEN]; devpath = di_devfs_path(node); (void) snprintf(dev_name, sizeof (dev_name), "%s:%s", devpath, di_minor_name(minor)); di_devfs_path_free((void *) devpath); (void) fprintf(stderr, "INFO: dev: %s, node: %s%d, minor: 0x%x, type: %s\n", dev_name, di_node_name(node), di_instance(node), di_minor_spectype(minor), (di_minor_nodetype(minor) != NULL ? di_minor_nodetype(minor) : "NULL")); } if (bus_type(node, minor, args->ph) != NULL) { if (add_bus(args, node, minor, NULL) == NULL) { args->dev_walk_status = ENOMEM; result = DI_WALK_TERMINATE; } } else if (is_HBA(node, minor)) { if (add_controller(args, node, minor) == NULL) { args->dev_walk_status = ENOMEM; result = DI_WALK_TERMINATE; } } else if (di_minor_spectype(minor) == S_IFCHR && (is_drive(minor) || is_zvol(node, minor))) { char *devidstr; char kernel_name[MAXPATHLEN]; disk_t *diskp; (void) snprintf(kernel_name, sizeof (kernel_name), "%s%d", di_node_name(node), di_instance(node)); devidstr = get_str_prop(DEVICE_ID_PROP, node); args->node = node; args->minor = minor; /* Check if we already got this disk and this is another slice */ if (!have_disk(args, devidstr, kernel_name, &diskp)) { args->dev_walk_status = 0; /* This is a newly found disk, create the disk structure. */ diskp = create_disk(devidstr, kernel_name, args); if (diskp == NULL) { args->dev_walk_status = ENOMEM; } if (diskp->drv_type != DM_DT_FLOPPY) { /* add the controller relationship */ if (args->dev_walk_status == 0) { if (add_disk2controller(diskp, args) != 0) { args->dev_walk_status = ENOMEM; } } } } /* Add the devpaths for the drive. */ if (args->dev_walk_status == 0) { char *devpath; char slice_path[MAXPATHLEN]; char *pattern; /* * We will come through here once for each of the raw slice * device names. */ devpath = di_devfs_path(node); (void) snprintf(slice_path, sizeof (slice_path), "%s:%s", devpath, di_minor_name(minor)); di_devfs_path_free((void *) devpath); if (libdiskmgt_str_eq(di_minor_nodetype(minor), DDI_NT_FD)) { pattern = DEVLINK_FLOPPY_REGEX; } else { pattern = DEVLINK_REGEX; } /* Walk the /dev tree to get the devlinks. */ (void) di_devlink_walk(args->handle, pattern, slice_path, DI_PRIMARY_LINK, arg, add_devpath); } if (args->dev_walk_status != 0) { result = DI_WALK_TERMINATE; } } return (result); } static int add_disk2controller(disk_t *diskp, struct search_args *args) { di_node_t pnode; controller_t *cp; di_minor_t minor; di_node_t node; int i; node = args->node; pnode = di_parent_node(node); if (pnode == DI_NODE_NIL) { return (0); } minor = di_minor_next(pnode, NULL); if (minor == NULL) { return (0); } if ((cp = add_controller(args, pnode, minor)) == NULL) { return (ENOMEM); } /* check if the disk <-> ctrl assoc is already there */ for (i = 0; diskp->controllers[i]; i++) { if (cp == diskp->controllers[i]) { return (0); } } /* this is a new controller for this disk */ /* add the disk to the controlller */ if (add_ptr2array(diskp, (void ***)&cp->disks) != 0) { return (ENOMEM); } /* add the controlller to the disk */ if (add_ptr2array(cp, (void ***)&diskp->controllers) != 0) { return (ENOMEM); } /* * Set up paths for mpxio controlled drives. */ if (libdiskmgt_str_eq(di_node_name(pnode), "scsi_vhci")) { /* note: mpxio di_path stuff is all consolidation private */ di_path_t pi = DI_PATH_NIL; while ((pi = di_path_client_next_path(node, pi)) != DI_PATH_NIL) { int cnt; uchar_t *bytes; char str[MAXPATHLEN]; char *wwn; di_node_t phci_node = di_path_phci_node(pi); /* get the node wwn */ cnt = di_path_prop_lookup_bytes(pi, WWN_PROP, &bytes); wwn = NULL; if (cnt > 0) { int i; str[0] = 0; for (i = 0; i < cnt; i++) { char bstr[8]; /* a byte is only 2 hex chars + null */ (void) snprintf(bstr, sizeof (bstr), "%.2x", bytes[i]); (void) strlcat(str, bstr, sizeof (str)); } wwn = str; } if (new_path(cp, diskp, phci_node, di_path_state(pi), wwn) == NULL) { return (ENOMEM); } } } return (0); } static int add_disk2path(disk_t *dp, path_t *pp, di_path_state_t st, char *wwn) { /* add the disk to the path */ if (add_ptr2array(dp, (void ***)&pp->disks) != 0) { cache_free_path(pp); return (0); } /* add the path to the disk */ if (add_ptr2array(pp, (void ***)&dp->paths) != 0) { cache_free_path(pp); return (0); } /* add the path state for this disk */ if (add_int2array(st, &pp->states) != 0) { cache_free_path(pp); return (0); } /* add the path state for this disk */ if (wwn != NULL) { char *wp; if ((wp = strdup(wwn)) != NULL) { if (add_ptr2array(wp, (void ***)(&pp->wwns)) != 0) { cache_free_path(pp); return (0); } } } return (1); } static int add_int2array(int p, int **parray) { int i; int cnt; int *pa; int *new_array; pa = *parray; cnt = 0; if (pa != NULL) { for (; pa[cnt] != -1; cnt++) ; } new_array = (int *)calloc(cnt + 2, sizeof (int *)); if (new_array == NULL) { return (ENOMEM); } /* copy the existing array */ for (i = 0; i < cnt; i++) { new_array[i] = pa[i]; } new_array[i] = p; new_array[i + 1] = -1; free(pa); *parray = new_array; return (0); } static int add_ptr2array(void *p, void ***parray) { int i; int cnt; void **pa; void **new_array; pa = *parray; cnt = 0; if (pa != NULL) { for (; pa[cnt]; cnt++) ; } new_array = (void **)calloc(cnt + 2, sizeof (void *)); if (new_array == NULL) { return (ENOMEM); } /* copy the existing array */ for (i = 0; i < cnt; i++) { new_array[i] = pa[i]; } new_array[i] = p; new_array[i + 1] = NULL; free(pa); *parray = new_array; return (0); } /* * This double checks that we aren't going to get into a bad situation. * This function should never fail, but I just want to double check things. */ static int can_remove_controller(controller_t *cp, controller_t *currp) { if (dm_debug) { if (cp == currp) { (void) fprintf(stderr, "ERROR: remove current controller\n"); } if (cp->disks != NULL && cp->disks[0] != NULL) { (void) fprintf(stderr, "ERROR: remove controller with disk ptrs\n"); } if (cp->paths != NULL && cp->paths[0] != NULL) { (void) fprintf(stderr, "ERROR: remove controller with path ptrs\n"); } } return (1); } /* * If we have a controller in the list that is really a path then we need to * take that controller out of the list since nodes that are paths are not * considered to be controllers. */ static void clean_paths(struct search_args *args) { controller_t *cp; cp = args->controller_listp; while (cp != NULL) { path_t **pp; pp = cp->paths; if (pp != NULL) { int i; for (i = 0; pp[i]; i++) { remove_invalid_controller(pp[i]->name, cp, args); } } cp = cp->next; } } static disk_t * create_disk(char *deviceid, char *kernel_name, struct search_args *args) { disk_t *diskp; char *type; char *prod_id; char *vendor_id; if (dm_debug) { (void) fprintf(stderr, "INFO: create_disk %s\n", kernel_name); } diskp = calloc(1, sizeof (disk_t)); if (diskp == NULL) { return (NULL); } diskp->controllers = (controller_t **) calloc(1, sizeof (controller_t *)); if (diskp->controllers == NULL) { cache_free_disk(diskp); return (NULL); } diskp->controllers[0] = NULL; diskp->devid = NULL; if (deviceid != NULL) { if ((diskp->device_id = strdup(deviceid)) == NULL) { cache_free_disk(diskp); return (NULL); } (void) devid_str_decode(deviceid, &(diskp->devid), NULL); } if (kernel_name != NULL) { diskp->kernel_name = strdup(kernel_name); if (diskp->kernel_name == NULL) { cache_free_disk(diskp); return (NULL); } } diskp->paths = NULL; diskp->aliases = NULL; diskp->cd_rom = 0; diskp->rpm = 0; type = di_minor_nodetype(args->minor); prod_id = get_str_prop(PROD_ID_PROP, args->node); if (prod_id != NULL) { if ((diskp->product_id = strdup(prod_id)) == NULL) { cache_free_disk(diskp); return (NULL); } } else { prod_id = get_str_prop(PROD_ID_USB_PROP, args->node); if (prod_id != NULL) { if ((diskp->product_id = strdup(prod_id)) == NULL) { cache_free_disk(diskp); return (NULL); } } } vendor_id = get_str_prop(VENDOR_ID_PROP, args->node); if (vendor_id != NULL) { if ((diskp->vendor_id = strdup(vendor_id)) == NULL) { cache_free_disk(diskp); return (NULL); } } else { vendor_id = get_str_prop(VENDOR_ID_PROP, args->node); if (vendor_id != NULL) { if ((diskp->vendor_id = strdup(vendor_id)) == NULL) { cache_free_disk(diskp); return (NULL); } } } /* * DVD, CD-ROM, CD-RW, MO, etc. are all reported as CD-ROMS. * We try to use uscsi later to determine the real type. * The cd_rom flag tells us that the kernel categorized the drive * as a CD-ROM. We leave the drv_type as UKNOWN for now. * The combination of the cd_rom flag being set with the drv_type of * unknown is what triggers the uscsi probe in drive.c. */ if (disk_is_cdrom(type)) { diskp->drv_type = DM_DT_UNKNOWN; diskp->cd_rom = 1; diskp->removable = 1; } else if (libdiskmgt_str_eq(type, DDI_NT_FD)) { diskp->drv_type = DM_DT_FLOPPY; diskp->removable = 1; } else { /* not a "CD-ROM" or Floppy */ diskp->removable = get_prop(REMOVABLE_PROP, args->node); if (diskp->removable == -1) { diskp->removable = 0; #if defined(i386) || defined(__amd64) /* * x86 does not have removable property. Check for common * removable drives, zip & jaz, and mark those correctly. */ if (vendor_id != NULL && prod_id != NULL) { if (str_case_index(vendor_id, "iomega") != NULL) { if (str_case_index(prod_id, "jaz") != NULL) { diskp->removable = 1; } else if (str_case_index(prod_id, "zip") != NULL) { diskp->removable = 1; } } } #endif } if (diskp->removable) { /* * For removable jaz or zip drives there is no way * to get the drive type unless media is inserted, so we * look at the product-id for a hint. */ diskp->drv_type = DM_DT_UNKNOWN; if (prod_id != NULL) { if (str_case_index(prod_id, "jaz") != NULL) { diskp->drv_type = DM_DT_JAZ; } else if (str_case_index(prod_id, "zip") != NULL) { diskp->drv_type = DM_DT_ZIP; } } } else { diskp->drv_type = DM_DT_FIXED; } } diskp->next = args->disk_listp; args->disk_listp = diskp; return (diskp); } static char * ctype(di_node_t node, di_minor_t minor) { char *type; char *name; type = di_minor_nodetype(minor); name = di_node_name(node); /* IDE disks use SCSI nexus as the type, so handle this special case */ if (libdiskmgt_str_eq(name, "ide")) { return (DM_CTYPE_ATA); } if (libdiskmgt_str_eq(di_minor_name(minor), "scsa2usb")) { return (DM_CTYPE_USB); } if (libdiskmgt_str_eq(type, DDI_NT_SCSI_NEXUS) || libdiskmgt_str_eq(type, DDI_NT_SCSI_ATTACHMENT_POINT)) { return (DM_CTYPE_SCSI); } if (libdiskmgt_str_eq(type, DDI_NT_FC_ATTACHMENT_POINT)) { return (DM_CTYPE_FIBRE); } if (libdiskmgt_str_eq(type, DDI_NT_NEXUS) && libdiskmgt_str_eq(name, "fp")) { return (DM_CTYPE_FIBRE); } if (libdiskmgt_str_eq(type, DDI_PSEUDO) && libdiskmgt_str_eq(name, "ide")) { return (DM_CTYPE_ATA); } return (DM_CTYPE_UNKNOWN); } static boolean_t disk_is_cdrom(char *type) { int type_index; for (type_index = 0; cdromtypes[type_index] != NULL; type_index++) { if (libdiskmgt_str_eq(type, cdromtypes[type_index])) { return (B_TRUE); } } return (B_FALSE); } static alias_t * find_alias(disk_t *diskp, char *kernel_name) { alias_t *ap; ap = diskp->aliases; while (ap != NULL) { if (libdiskmgt_str_eq(ap->kstat_name, kernel_name)) { return (ap); } ap = ap->next; } return (NULL); } static bus_t * find_bus(struct search_args *args, char *name) { bus_t *listp; listp = args->bus_listp; while (listp != NULL) { if (libdiskmgt_str_eq(listp->name, name)) { return (listp); } listp = listp->next; } return (NULL); } static controller_t * find_controller(struct search_args *args, char *name) { controller_t *listp; listp = args->controller_listp; while (listp != NULL) { if (libdiskmgt_str_eq(listp->name, name)) { return (listp); } listp = listp->next; } return (NULL); } static int fix_cluster_devpath(di_devlink_t devlink, void *arg) { int fd; struct search_args *args; char *devlink_path; disk_t *diskp = NULL; alias_t *ap = NULL; /* * The devlink_path is of the form /dev/did/rdsk/d1s0. */ args = (struct search_args *)arg; /* Find the disk by the deviceid we read from the cluster disk. */ devlink_path = (char *)di_devlink_path(devlink); if (devlink_path == NULL) { return (DI_WALK_CONTINUE); } if ((fd = open(devlink_path, O_RDONLY|O_NDELAY)) >= 0) { ddi_devid_t devid; if (dm_debug > 1) { (void) fprintf(stderr, "INFO: cluster devpath %s\n", devlink_path); } if (devid_get(fd, &devid) == 0) { char *minor; char *devidstr; minor = di_minor_name(args->minor); if ((devidstr = devid_str_encode(devid, minor)) != NULL) { diskp = get_disk_by_deviceid(args->disk_listp, devidstr); /* * This really shouldn't happen, since we should have * found all of the disks during our first pass through * the dev tree, but just in case... */ if (diskp == NULL) { if (dm_debug > 1) { (void) fprintf(stderr, "INFO: cluster create disk\n"); } diskp = create_disk(devidstr, NULL, args); if (diskp == NULL) { args->dev_walk_status = ENOMEM; } /* add the controller relationship */ if (args->dev_walk_status == 0) { if (add_disk2controller(diskp, args) != 0) { args->dev_walk_status = ENOMEM; } } if (new_alias(diskp, NULL, devlink_path, args) != 0) { args->dev_walk_status = ENOMEM; } } devid_str_free(devidstr); } devid_free(devid); } (void) close(fd); } if (diskp != NULL) { if (dm_debug > 1) { (void) fprintf(stderr, "INFO: cluster found disk\n"); } ap = diskp->aliases; } if (ap != NULL) { /* NOTE: if ap->next != NULL have cluster disks w/ multiple paths */ if (!ap->cluster) { char *basep; char *namep; int cnt = 0; int size; char alias[MAXPATHLEN]; /* * First time; save the /dev/rdsk devpaths and update the * alias info with the new alias name. */ ap->orig_paths = ap->devpaths; ap->devpaths = NULL; free(ap->alias); /* get the new cluster alias name */ basep = strrchr(devlink_path, '/'); if (basep == NULL) { basep = devlink_path; } else { basep++; } size = sizeof (alias) - 1; namep = alias; while (*basep != 0 && *basep != 's' && cnt < size) { *namep++ = *basep++; cnt++; } *namep = 0; if ((ap->alias = strdup(alias)) == NULL) { args->dev_walk_status = ENOMEM; } ap->cluster = 1; } if (new_devpath(ap, devlink_path) != 0) { args->dev_walk_status = ENOMEM; } } return (DI_WALK_CONTINUE); } /* * Check if we have the drive in our list, based upon the device id. * We got the device id from the dev tree walk. This is encoded * using devid_str_encode(3DEVID). In order to check the device ids we need * to use the devid_compare(3DEVID) function, so we need to decode the * string representation of the device id. */ static disk_t * get_disk_by_deviceid(disk_t *listp, char *devidstr) { ddi_devid_t devid; if (devidstr == NULL || devid_str_decode(devidstr, &devid, NULL) != 0) { return (NULL); } while (listp != NULL) { if (listp->devid != NULL && devid_compare(listp->devid, devid) == 0) { break; } listp = listp->next; } devid_free(devid); return (listp); } /* * Get the base disk name with no path prefix and no slice (if there is one). * The name parameter should be big enough to hold the name. * This handles diskette names ok (/dev/rdiskette0) since there is no slice, * and converts the raw diskette name. * But, we don't know how to strip off the slice from third party drive * names. That just means that their drive name will include a slice on * it. */ static void get_disk_name_from_path(char *path, char *name, int size) { char *basep; int cnt = 0; basep = strrchr(path, '/'); if (basep == NULL) { basep = path; } else { basep++; } size = size - 1; /* leave room for terminating 0 */ if (is_ctds(basep)) { while (*basep != 0 && *basep != 's' && cnt < size) { *name++ = *basep++; cnt++; } *name = 0; } else { if (strncmp(basep, FLOPPY_NAME, sizeof (FLOPPY_NAME) - 1) == 0) { /* * a floppy, convert rdiskette name to diskette name, * by skipping over the 'r' for raw diskette */ basep++; } /* not a ctds name, just copy it */ (void) strlcpy(name, basep, size); } } static char * get_byte_prop(char *prop_name, di_node_t node) { int cnt; uchar_t *bytes; int i; char str[MAXPATHLEN]; cnt = di_prop_lookup_bytes(DDI_DEV_T_ANY, node, prop_name, &bytes); if (cnt < 1) { return (NULL); } str[0] = 0; for (i = 0; i < cnt; i++) { char bstr[8]; /* a byte is only 2 hex chars + null */ (void) snprintf(bstr, sizeof (bstr), "%.2x", bytes[i]); (void) strlcat(str, bstr, sizeof (str)); } return (strdup(str)); } static di_node_t get_parent_bus(di_node_t node, struct search_args *args) { di_node_t pnode; pnode = di_parent_node(node); if (pnode == DI_NODE_NIL) { return (NULL); } if (bus_type(pnode, di_minor_next(pnode, NULL), args->ph) != NULL) { return (pnode); } return (get_parent_bus(pnode, args)); } static int get_prom_int(char *prop_name, di_node_t node, di_prom_handle_t ph) { int *n; if (di_prom_prop_lookup_ints(ph, node, prop_name, &n) == 1) { return (*n); } return (0); } static char * get_prom_str(char *prop_name, di_node_t node, di_prom_handle_t ph) { char *str; if (di_prom_prop_lookup_strings(ph, node, prop_name, &str) == 1) { return (str); } return (NULL); } /* * Get one of the positive int or boolean properties. */ static int get_prop(char *prop_name, di_node_t node) { int num; int *ip; if ((num = di_prop_lookup_ints(DDI_DEV_T_ANY, node, prop_name, &ip)) >= 0) { if (num == 0) { /* boolean */ return (1); } else if (num == 1) { /* single int */ return (*ip); } } return (-1); } static char * get_str_prop(char *prop_name, di_node_t node) { char *str; if (di_prop_lookup_strings(DDI_DEV_T_ANY, node, prop_name, &str) == 1) { return (str); } return (NULL); } /* * Check if we have the drive in our list, based upon the device id, if the * drive has a device id, or the kernel name, if it doesn't have a device id. */ static int have_disk(struct search_args *args, char *devidstr, char *kernel_name, disk_t **diskp) { disk_t *listp; *diskp = NULL; listp = args->disk_listp; if (devidstr != NULL) { if ((*diskp = get_disk_by_deviceid(listp, devidstr)) != NULL) { return (1); } } else { /* no devid, try matching the kernel names on the drives */ while (listp != NULL) { if (libdiskmgt_str_eq(kernel_name, listp->kernel_name)) { *diskp = listp; return (1); } listp = listp->next; } } return (0); } static char * bus_type(di_node_t node, di_minor_t minor, di_prom_handle_t ph) { char *type; int i; type = get_prom_str("device_type", node, ph); if (type == NULL) { type = di_node_name(node); } for (i = 0; bustypes[i]; i++) { if (libdiskmgt_str_eq(type, bustypes[i])) { return (type); } } if (minor != NULL && strcmp(di_minor_nodetype(minor), DDI_NT_USB_ATTACHMENT_POINT) == 0) { return ("usb"); } return (NULL); } static int is_cluster_disk(di_node_t node, di_minor_t minor) { if (di_minor_spectype(minor) == S_IFCHR && libdiskmgt_str_eq(di_minor_nodetype(minor), DDI_PSEUDO) && libdiskmgt_str_eq(di_node_name(node), CLUSTER_DEV)) { return (1); } return (0); } /* * If the input name is in c[t]ds format then return 1, otherwise return 0. */ static int is_ctds(char *name) { char *p; p = name; if (*p++ != 'c') { return (0); } /* skip controller digits */ while (isdigit(*p)) { p++; } /* handle optional target */ if (*p == 't') { p++; /* skip over target */ while (isdigit(*p) || isupper(*p)) { p++; } } if (*p++ != 'd') { return (0); } while (isdigit(*p)) { p++; } if (*p++ != 's') { return (0); } /* check the slice number */ while (isdigit(*p)) { p++; } if (*p != 0) { return (0); } return (1); } static int is_drive(di_minor_t minor) { char *type; int type_index; type = di_minor_nodetype(minor); type_index = 0; while (disktypes[type_index] != NULL) { if (libdiskmgt_str_eq(type, disktypes[type_index])) { return (1); } type_index++; } return (0); } static int is_zvol(di_node_t node, di_minor_t minor) { if ((strncmp(di_node_name(node), ZFS_DRIVER, 3) == 0) && di_minor_devt(minor)) return (1); return (0); } static int is_HBA(di_node_t node, di_minor_t minor) { char *type; char *name; int type_index; type = di_minor_nodetype(minor); type_index = 0; while (ctrltypes[type_index] != NULL) { if (libdiskmgt_str_eq(type, ctrltypes[type_index])) { return (1); } type_index++; } name = di_node_name(node); if (libdiskmgt_str_eq(type, DDI_PSEUDO) && libdiskmgt_str_eq(name, "ide")) { return (1); } return (0); } static int new_alias(disk_t *diskp, char *kernel_name, char *devlink_path, struct search_args *args) { alias_t *aliasp; char alias[MAXPATHLEN]; di_node_t pnode; aliasp = malloc(sizeof (alias_t)); if (aliasp == NULL) { return (ENOMEM); } aliasp->alias = NULL; aliasp->kstat_name = NULL; aliasp->wwn = NULL; aliasp->devpaths = NULL; aliasp->orig_paths = NULL; get_disk_name_from_path(devlink_path, alias, sizeof (alias)); aliasp->alias = strdup(alias); if (aliasp->alias == NULL) { cache_free_alias(aliasp); return (ENOMEM); } if (kernel_name != NULL) { aliasp->kstat_name = strdup(kernel_name); if (aliasp->kstat_name == NULL) { cache_free_alias(aliasp); return (ENOMEM); } } else { aliasp->kstat_name = NULL; } aliasp->cluster = 0; aliasp->lun = get_prop(DM_LUN, args->node); aliasp->target = get_prop(DM_TARGET, args->node); aliasp->wwn = get_byte_prop(WWN_PROP, args->node); pnode = di_parent_node(args->node); if (pnode != DI_NODE_NIL) { char prop_name[MAXPROPLEN]; (void) snprintf(prop_name, sizeof (prop_name), "target%d-sync-speed", aliasp->target); diskp->sync_speed = get_prop(prop_name, pnode); (void) snprintf(prop_name, sizeof (prop_name), "target%d-wide", aliasp->target); diskp->wide = get_prop(prop_name, pnode); } if (new_devpath(aliasp, devlink_path) != 0) { cache_free_alias(aliasp); return (ENOMEM); } aliasp->next = diskp->aliases; diskp->aliases = aliasp; return (0); } /* * Append the new devpath to the end of the devpath list. This is important * since we may want to use the order of the devpaths to match up the vtoc * entries. */ static int new_devpath(alias_t *ap, char *devpath) { slice_t *newdp; slice_t *alistp; /* * First, search the alias list to be sure that this devpath is * not already there. */ for (alistp = ap->devpaths; alistp != NULL; alistp = alistp->next) { if (libdiskmgt_str_eq(alistp->devpath, devpath)) { return (0); } } /* * Otherwise, not found so add this new devpath to the list. */ newdp = malloc(sizeof (slice_t)); if (newdp == NULL) { return (ENOMEM); } newdp->devpath = strdup(devpath); if (newdp->devpath == NULL) { free(newdp); return (ENOMEM); } newdp->slice_num = -1; newdp->next = NULL; if (ap->devpaths == NULL) { ap->devpaths = newdp; } else { /* append the devpath to the end of the list */ slice_t *dp; dp = ap->devpaths; while (dp->next != NULL) { dp = dp->next; } dp->next = newdp; } return (0); } static path_t * new_path(controller_t *cp, disk_t *dp, di_node_t node, di_path_state_t st, char *wwn) { char *devpath; path_t *pp; di_minor_t minor; /* Special handling for fp attachment node. */ if (strcmp(di_node_name(node), "fp") == 0) { di_node_t pnode; pnode = di_parent_node(node); if (pnode != DI_NODE_NIL) { node = pnode; } } devpath = di_devfs_path(node); /* check if the path is already there */ pp = NULL; if (cp->paths != NULL) { int i; for (i = 0; cp->paths[i]; i++) { if (libdiskmgt_str_eq(devpath, cp->paths[i]->name)) { pp = cp->paths[i]; break; } } } if (pp != NULL) { /* the path exists, add this disk to it */ di_devfs_path_free((void *) devpath); if (!add_disk2path(dp, pp, st, wwn)) { return (NULL); } return (pp); } /* create a new path */ pp = calloc(1, sizeof (path_t)); if (pp == NULL) { di_devfs_path_free((void *) devpath); return (NULL); } pp->name = strdup(devpath); di_devfs_path_free((void *) devpath); if (pp->name == NULL) { cache_free_path(pp); return (NULL); } /* add the disk to the path */ if (!add_disk2path(dp, pp, st, wwn)) { return (NULL); } /* add the path to the controller */ if (add_ptr2array(pp, (void ***)&cp->paths) != 0) { cache_free_path(pp); return (NULL); } /* add the controller to the path */ pp->controller = cp; minor = di_minor_next(node, NULL); if (minor != NULL) { pp->ctype = ctype(node, minor); } else { pp->ctype = DM_CTYPE_UNKNOWN; } return (pp); } /* * We pass in the current controller pointer (currp) so we can double check * that we aren't corrupting the list by removing the element we are on. This * should never happen, but it doesn't hurt to double check. */ static void remove_invalid_controller(char *name, controller_t *currp, struct search_args *args) { controller_t *cp; bus_t *bp; controller_t *prevp; bp = args->bus_listp; while (bp != NULL) { int i; for (i = 0; bp->controllers[i]; i++) { if (libdiskmgt_str_eq(bp->controllers[i]->name, name)) { int j; /* remove pointer to invalid controller (it is a path) */ for (j = i; bp->controllers[j]; j++) { bp->controllers[j] = bp->controllers[j + 1]; } } } bp = bp->next; } if (args->controller_listp == NULL) { return; } cp = args->controller_listp; if (libdiskmgt_str_eq(cp->name, name)) { if (can_remove_controller(cp, currp)) { args->controller_listp = cp->next; cache_free_controller(cp); } return; } prevp = cp; cp = cp->next; while (cp != NULL) { if (libdiskmgt_str_eq(cp->name, name)) { if (can_remove_controller(cp, currp)) { prevp->next = cp->next; cache_free_controller(cp); } return; } prevp = cp; cp = cp->next; } } /* * This is the standard strstr code modified for case independence. */ static char * str_case_index(register char *s1, register char *s2) { uint_t s2len = strlen(s2); /* length of the second string */ /* If the length of the second string is 0, return the first arg. */ if (s2len == 0) { return (s1); } while (strlen(s1) >= s2len) { if (strncasecmp(s1, s2, s2len) == 0) { return (s1); } s1++; } return (NULL); }