/* * 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 2006 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 #include #include #include #include #include "device_info.h" /* * #define's */ /* alias node searching return values */ #define NO_MATCH -1 #define EXACT_MATCH 1 #define INEXACT_MATCH 2 /* for prom io operations */ #define BUFSIZE 4096 #define MAXPROPSIZE 256 #define MAXVALSIZE (BUFSIZE - MAXPROPSIZE - sizeof (uint_t)) /* prom_obp_vers() return values */ #define OBP_OF 0x4 /* versions OBP 3.x */ #define OBP_NO_ALIAS_NODE 0x8 /* No alias node */ /* for nftw call */ #define FT_DEPTH 15 /* default logical and physical device name space */ #define DEV "/dev" #define DEVICES "/devices" /* for boot device identification on x86 */ #define CREATE_DISKMAP "/boot/solaris/bin/create_diskmap" #define GRUBDISK_MAP "/var/run/solaris_grubdisk.map" /* * internal structure declarations */ /* for prom io functions */ typedef union { char buf[BUFSIZE]; struct openpromio opp; } Oppbuf; /* used to manage lists of devices and aliases */ struct name_list { char *name; struct name_list *next; }; /* * internal global data */ /* global since nftw does not let you pass args to be updated */ static struct name_list **dev_list; /* global since nftw does not let you pass args to be updated */ static struct boot_dev **bootdev_list; /* mutex to protect bootdev_list and dev_list */ static mutex_t dev_lists_lk = DEFAULTMUTEX; /* * internal function prototypes */ static int prom_open(int); static void prom_close(int); static int is_openprom(int); static int prom_dev_to_alias(char *dev, uint_t options, char ***ret_buf); static int alias_to_prom_dev(char *alias, char *ret_buf); static int prom_srch_aliases_by_def(char *, struct name_list **, struct name_list **, int); static int prom_find_aliases_node(int fd); static int prom_compare_devs(char *prom_dev1, char *prom_dev2); static int _prom_strcmp(char *s1, char *s2); static int prom_srch_node(int fd, char *prop_name, char *ret_buf); static uint_t prom_next_node(int fd, uint_t node_id); static uint_t prom_child_node(int fd, uint_t node_id); static int prom_obp_vers(void); static void parse_name(char *, char **, char **, char **); static int process_bootdev(const char *, const char *, struct boot_dev ***); static int process_minor_name(char *dev_path, const char *default_root); static void options_override(char *prom_path, char *alias_name); static int devfs_phys_to_logical(struct boot_dev **bootdev_array, const int array_size, const char *default_root); static int check_logical_dev(const char *, const struct stat *, int, struct FTW *); static struct boot_dev *alloc_bootdev(char *); static void free_name_list(struct name_list *list, int free_name); static int insert_alias_list(struct name_list **list, char *alias_name); static int get_boot_dev_var(struct openpromio *opp); static int set_boot_dev_var(struct openpromio *opp, char *bootdev); static int devfs_prom_to_dev_name(char *prom_path, char *dev_path); static int devfs_dev_to_prom_names(char *dev_path, char *prom_path, size_t len); /* * frees a list of paths from devfs_get_prom_name_list */ static void prom_list_free(char **prom_list) { int i = 0; if (!prom_list) return; while (prom_list[i]) { free(prom_list[i]); i++; } free(prom_list); } static int devfs_get_prom_name_list(const char *dev_name, char ***prom_list) { char *prom_path = NULL; int count = 0; /* # of slots we will need in prom_list */ int ret, i, len; char **list; char *ptr; if (dev_name == NULL) return (DEVFS_INVAL); if (*dev_name != '/') return (DEVFS_INVAL); if (prom_list == NULL) return (DEVFS_INVAL); /* * make sure we are on a machine which supports a prom * and we have permission to use /dev/openprom */ if ((ret = prom_obp_vers()) < 0) return (ret); if ((prom_path = (char *)malloc(MAXVALSIZE)) == NULL) return (DEVFS_NOMEM); /* * get the prom path name */ ret = devfs_dev_to_prom_names((char *)dev_name, prom_path, MAXVALSIZE); if (ret < 0) { free(prom_path); return (ret); } /* deal with list of names */ for (i = 0; i < ret; i++) if (prom_path[i] == '\0') count++; if ((list = (char **)calloc(count + 1, sizeof (char *))) == NULL) { free(prom_path); return (DEVFS_NOMEM); } ptr = prom_path; for (i = 0; i < count; i++) { len = strlen(ptr) + 1; if ((list[i] = (char *)malloc(len)) == NULL) { free(prom_path); free(list); return (DEVFS_NOMEM); } (void) snprintf(list[i], len, "%s", ptr); ptr += len; } free(prom_path); *prom_list = list; return (0); } /* * retrieve the list of prom representations for a given device name * the list will be sorted in the following order: exact aliases, * inexact aliases, prom device path name. If multiple matches occur * for exact or inexact aliases, then these are sorted in collating * order. The list is returned in prom_list * * the list may be restricted by specifying the correct flags in options. */ int devfs_get_prom_names(const char *dev_name, uint_t options, char ***prom_list) { char *prom_path = NULL; int count = 0; /* # of slots we will need in prom_list */ char **alias_list = NULL; char **list; int ret; if (dev_name == NULL) { return (DEVFS_INVAL); } if (*dev_name != '/') { return (DEVFS_INVAL); } if (prom_list == NULL) { return (DEVFS_INVAL); } /* * make sure we are on a machine which supports a prom * and we have permission to use /dev/openprom */ if ((ret = prom_obp_vers()) < 0) { return (ret); } if ((prom_path = (char *)malloc(MAXPATHLEN)) == NULL) { return (DEVFS_NOMEM); } /* * get the prom path name */ ret = devfs_dev_to_prom_name((char *)dev_name, prom_path); if (ret < 0) { free(prom_path); return (ret); } /* get the list of aliases (exact and inexact) */ if ((ret = prom_dev_to_alias(prom_path, options, &alias_list)) < 0) { free(prom_path); return (ret); } /* now figure out how big the return array must be */ if (alias_list != NULL) { while (alias_list[count] != NULL) { count++; } } if ((options & BOOTDEV_NO_PROM_PATH) == 0) { count++; /* # of slots we will need in prom_list */ } count++; /* for the null terminator */ /* allocate space for the list */ if ((list = (char **)calloc(count, sizeof (char *))) == NULL) { count = 0; while ((alias_list) && (alias_list[count] != NULL)) { free(alias_list[count]); count++; } free(alias_list); free(prom_path); return (DEVFS_NOMEM); } /* fill in the array and free the name list of aliases. */ count = 0; while ((alias_list) && (alias_list[count] != NULL)) { list[count] = alias_list[count]; count++; } if ((options & BOOTDEV_NO_PROM_PATH) == 0) { list[count] = prom_path; } if (alias_list != NULL) { free(alias_list); } *prom_list = list; return (0); } /* * Get a list prom-path translations for a solaris device. * * Returns the number of and all OBP paths and alias variants that * reference the Solaris device path passed in. */ int devfs_get_all_prom_names(const char *solaris_path, uint_t flags, struct devfs_prom_path **paths) { int ret, len, i, count = 0; char *ptr, *prom_path; struct devfs_prom_path *cur = NULL, *new; if ((ret = prom_obp_vers()) < 0) return (ret); if ((prom_path = (char *)malloc(MAXVALSIZE)) == NULL) return (DEVFS_NOMEM); if ((ret = devfs_dev_to_prom_names((char *)solaris_path, prom_path, MAXVALSIZE)) < 0) { free(prom_path); return (ret); } for (i = 0; i < ret; i++) if (prom_path[i] == '\0') count++; *paths = NULL; ptr = prom_path; for (i = 0; i < count; i++) { if ((new = (struct devfs_prom_path *)calloc( sizeof (struct devfs_prom_path), 1)) == NULL) { free(prom_path); devfs_free_all_prom_names(*paths); return (DEVFS_NOMEM); } if (cur == NULL) *paths = new; else cur->next = new; cur = new; len = strlen(ptr) + 1; if ((cur->obp_path = (char *)calloc(len, 1)) == NULL) { free(prom_path); devfs_free_all_prom_names(*paths); return (DEVFS_NOMEM); } (void) snprintf(cur->obp_path, len, "%s", ptr); ptr += len; if ((ret = prom_dev_to_alias(cur->obp_path, flags, &(cur->alias_list))) < 0) { free(prom_path); devfs_free_all_prom_names(*paths); return (ret); } } free(prom_path); return (count); } void devfs_free_all_prom_names(struct devfs_prom_path *paths) { int i; if (paths == NULL) return; devfs_free_all_prom_names(paths->next); if (paths->obp_path != NULL) free(paths->obp_path); if (paths->alias_list != NULL) { for (i = 0; paths->alias_list[i] != NULL; i++) if (paths->alias_list[i] != NULL) free(paths->alias_list[i]); free(paths->alias_list); } free(paths); } /* * Accepts a device name as an input argument. Uses this to set the * boot-device (or like) variable * * By default, this routine prepends to the list and converts the * logical device name to its most compact prom representation. * Available options include: converting the device name to a prom * path name (but not an alias) or performing no conversion at all; * overwriting the existing contents of boot-device rather than * prepending. */ int devfs_bootdev_set_list(const char *dev_name, const uint_t options) { char *prom_path; char *new_bootdev; char *ptr; char **alias_list = NULL; char **prom_list = NULL; Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int ret, len, i, j; if (devfs_bootdev_modifiable() != 0) { return (DEVFS_NOTSUP); } if (dev_name == NULL) { return (DEVFS_INVAL); } if (strlen(dev_name) >= MAXPATHLEN) return (DEVFS_INVAL); if ((*dev_name != '/') && !(options & BOOTDEV_LITERAL)) { return (DEVFS_INVAL); } if ((options & BOOTDEV_LITERAL) && (options & BOOTDEV_PROMDEV)) { return (DEVFS_INVAL); } /* * if we are prepending, make sure that this obp rev * supports multiple boot device entries. */ ret = prom_obp_vers(); if (ret < 0) { return (ret); } if ((prom_path = (char *)malloc(MAXVALSIZE)) == NULL) { return (DEVFS_NOMEM); } if (options & BOOTDEV_LITERAL) { (void) strcpy(prom_path, dev_name); } else { /* need to convert to prom representation */ ret = devfs_get_prom_name_list(dev_name, &prom_list); if (ret < 0) { free(prom_path); return (ret); } len = MAXVALSIZE; i = 0; ptr = prom_path; while (prom_list && prom_list[i]) { if (!(options & BOOTDEV_PROMDEV)) { ret = prom_dev_to_alias(prom_list[i], 0, &alias_list); if (ret < 0) { free(prom_path); prom_list_free(prom_list); return (ret); } if ((alias_list != NULL) && (alias_list[0] != NULL)) { (void) snprintf(ptr, len, "%s ", alias_list[0]); for (ret = 0; alias_list[ret] != NULL; ret++) free(alias_list[ret]); } else { (void) snprintf(ptr, len, "%s ", prom_list[i]); } if (alias_list != NULL) free(alias_list); } else { (void) snprintf(ptr, len, "%s ", prom_list[i]); } j = strlen(ptr); len -= j; ptr += j; i++; } ptr--; *ptr = NULL; prom_list_free(prom_list); } if (options & BOOTDEV_OVERWRITE) { new_bootdev = prom_path; } else { /* retrieve the current value of boot-device */ ret = get_boot_dev_var(opp); if (ret < 0) { free(prom_path); return (ret); } /* prepend new entry - deal with duplicates */ new_bootdev = (char *)malloc(strlen(opp->oprom_array) + strlen(prom_path) + 2); if (new_bootdev == NULL) { free(prom_path); return (DEVFS_NOMEM); } (void) strcpy(new_bootdev, prom_path); if (opp->oprom_size > 0) { for (ptr = strtok(opp->oprom_array, " "); ptr != NULL; ptr = strtok(NULL, " ")) { /* we strip out duplicates */ if (strcmp(prom_path, ptr) == 0) { continue; } (void) strcat(new_bootdev, " "); (void) strcat(new_bootdev, ptr); } } } /* now set the new value */ ret = set_boot_dev_var(opp, new_bootdev); if (options & BOOTDEV_OVERWRITE) { free(prom_path); } else { free(new_bootdev); free(prom_path); } return (ret); } /* * sets the string bootdev as the new value for boot-device */ static int set_boot_dev_var(struct openpromio *opp, char *bootdev) { int prom_fd; int i; int ret; char *valbuf; char *save_bootdev; char *bootdev_variables[] = { "boot-device", "bootdev", "boot-from", NULL }; int found = 0; int *ip = (int *)((void *)opp->oprom_array); /* query the prom */ prom_fd = prom_open(O_RDWR); if (prom_fd < 0) { return (prom_fd); } /* get the diagnostic-mode? property */ (void) strcpy(opp->oprom_array, "diagnostic-mode?"); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) >= 0) { if ((opp->oprom_size > 0) && (strcmp(opp->oprom_array, "true") == 0)) { prom_close(prom_fd); return (DEVFS_ERR); } } /* get the diag-switch? property */ (void) strcpy(opp->oprom_array, "diag-switch?"); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) >= 0) { if ((opp->oprom_size > 0) && (strcmp(opp->oprom_array, "true") == 0)) { prom_close(prom_fd); return (DEVFS_ERR); } } /* * look for one of the following properties in order: * boot-device * bootdev * boot-from * * Use the first one that we find. */ *ip = 0; opp->oprom_size = MAXPROPSIZE; while ((opp->oprom_size != 0) && (!found)) { opp->oprom_size = MAXPROPSIZE; if (ioctl(prom_fd, OPROMNXTOPT, opp) < 0) { break; } for (i = 0; bootdev_variables[i] != NULL; i++) { if (strcmp(opp->oprom_array, bootdev_variables[i]) == 0) { found = 1; break; } } } if (found) { (void) strcpy(opp->oprom_array, bootdev_variables[i]); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) < 0) { prom_close(prom_fd); return (DEVFS_NOTSUP); } } else { prom_close(prom_fd); return (DEVFS_NOTSUP); } /* save the old copy in case we fail */ if ((save_bootdev = strdup(opp->oprom_array)) == NULL) { prom_close(prom_fd); return (DEVFS_NOMEM); } /* set up the new value of boot-device */ (void) strcpy(opp->oprom_array, bootdev_variables[i]); valbuf = opp->oprom_array + strlen(opp->oprom_array) + 1; (void) strcpy(valbuf, bootdev); opp->oprom_size = strlen(valbuf) + strlen(opp->oprom_array) + 2; if (ioctl(prom_fd, OPROMSETOPT, opp) < 0) { free(save_bootdev); prom_close(prom_fd); return (DEVFS_ERR); } /* * now read it back to make sure it took */ (void) strcpy(opp->oprom_array, bootdev_variables[i]); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) >= 0) { if (_prom_strcmp(opp->oprom_array, bootdev) == 0) { /* success */ free(save_bootdev); prom_close(prom_fd); return (0); } /* deal with setting it to "" */ if ((strlen(bootdev) == 0) && (opp->oprom_size == 0)) { /* success */ free(save_bootdev); prom_close(prom_fd); return (0); } } /* * something did not take - write out the old value and * hope that we can restore things... * * unfortunately, there is no way for us to differentiate * whether we exceeded the maximum number of characters * allowable. The limit varies from prom rev to prom * rev, and on some proms, when the limit is * exceeded, whatever was in the * boot-device variable becomes unreadable. * * so if we fail, we will assume we ran out of room. If we * not able to restore the original setting, then we will * return DEVFS_ERR instead. */ ret = DEVFS_LIMIT; (void) strcpy(opp->oprom_array, bootdev_variables[i]); valbuf = opp->oprom_array + strlen(opp->oprom_array) + 1; (void) strcpy(valbuf, save_bootdev); opp->oprom_size = strlen(valbuf) + strlen(opp->oprom_array) + 2; if (ioctl(prom_fd, OPROMSETOPT, opp) < 0) { ret = DEVFS_ERR; } free(save_bootdev); prom_close(prom_fd); return (ret); } /* * retrieve the current value for boot-device */ static int get_boot_dev_var(struct openpromio *opp) { int prom_fd; int i; char *bootdev_variables[] = { "boot-device", "bootdev", "boot-from", NULL }; int found = 0; int *ip = (int *)((void *)opp->oprom_array); /* query the prom */ prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } /* get the diagnostic-mode? property */ (void) strcpy(opp->oprom_array, "diagnostic-mode?"); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) >= 0) { if ((opp->oprom_size > 0) && (strcmp(opp->oprom_array, "true") == 0)) { prom_close(prom_fd); return (DEVFS_ERR); } } /* get the diag-switch? property */ (void) strcpy(opp->oprom_array, "diag-switch?"); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) >= 0) { if ((opp->oprom_size > 0) && (strcmp(opp->oprom_array, "true") == 0)) { prom_close(prom_fd); return (DEVFS_ERR); } } /* * look for one of the following properties in order: * boot-device * bootdev * boot-from * * Use the first one that we find. */ *ip = 0; opp->oprom_size = MAXPROPSIZE; while ((opp->oprom_size != 0) && (!found)) { opp->oprom_size = MAXPROPSIZE; if (ioctl(prom_fd, OPROMNXTOPT, opp) < 0) { break; } for (i = 0; bootdev_variables[i] != NULL; i++) { if (strcmp(opp->oprom_array, bootdev_variables[i]) == 0) { found = 1; break; } } } if (found) { (void) strcpy(opp->oprom_array, bootdev_variables[i]); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETOPT, opp) < 0) { prom_close(prom_fd); return (DEVFS_ERR); } /* boot-device exists but contains nothing */ if (opp->oprom_size == 0) { *opp->oprom_array = '\0'; } } else { prom_close(prom_fd); return (DEVFS_NOTSUP); } prom_close(prom_fd); return (0); } #ifndef __sparc static FILE * open_diskmap(void) { FILE *fp; char cmd[PATH_MAX]; /* make sure we have a map file */ fp = fopen(GRUBDISK_MAP, "r"); if (fp == NULL) { (void) snprintf(cmd, sizeof (cmd), "%s > /dev/null", CREATE_DISKMAP); (void) system(cmd); fp = fopen(GRUBDISK_MAP, "r"); } return (fp); } static int find_x86_boot_device(struct openpromio *opp) { int ret = DEVFS_ERR; char *cp, line[MAXVALSIZE + 6]; FILE *file; file = open_diskmap(); if (file == NULL) return (DEVFS_ERR); while (fgets(line, MAXVALSIZE + 6, file)) { if (strncmp(line, "0 ", 2) != 0) continue; /* drop new-line */ line[strlen(line) - 1] = '\0'; /* * an x86 BIOS only boots a disk, not a partition * or a slice, so hard-code :q (p0) */ cp = strchr(line + 2, ' '); if (cp == NULL) break; (void) snprintf(opp->oprom_array, MAXVALSIZE, "%s:q", cp + 1); opp->oprom_size = MAXVALSIZE; ret = 0; break; } (void) fclose(file); return (ret); } #endif /* ndef __sparc */ /* * retrieve the list of entries in the boot-device configuration * variable. An array of boot_dev structs will be created, one entry * for each device name in the boot-device variable. Each entry * in the array will contain the logical device representation of the * boot-device entry, if any. * * default_root. if set, is used to locate logical device entries in * directories other than /dev */ int devfs_bootdev_get_list(const char *default_root, struct boot_dev ***bootdev_list) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int i; struct boot_dev **tmp_list; if (default_root == NULL) { default_root = ""; } else if (*default_root != '/') { return (DEVFS_INVAL); } if (bootdev_list == NULL) { return (DEVFS_INVAL); } /* get the boot-device variable */ #if defined(sparc) i = get_boot_dev_var(opp); #else i = find_x86_boot_device(opp); #endif if (i < 0) { return (i); } /* now try to translate each entry to a logical device. */ i = process_bootdev(opp->oprom_array, default_root, &tmp_list); if (i == 0) { *bootdev_list = tmp_list; return (0); } else { return (i); } } /* * loop thru the list of entries in a boot-device configuration * variable. */ static int process_bootdev(const char *bootdevice, const char *default_root, struct boot_dev ***list) { int i; char *entry, *ptr; char prom_path[MAXPATHLEN]; char ret_buf[MAXPATHLEN]; struct boot_dev **bootdev_array; int num_entries = 0; int found = 0; int vers; if ((entry = (char *)malloc(strlen(bootdevice) + 1)) == NULL) { return (DEVFS_NOMEM); } /* count the number of entries */ (void) strcpy(entry, bootdevice); for (ptr = strtok(entry, " "); ptr != NULL; ptr = strtok(NULL, " ")) { num_entries++; } (void) strcpy(entry, bootdevice); bootdev_array = (struct boot_dev **) calloc((size_t)num_entries + 1, sizeof (struct boot_dev *)); if (bootdev_array == NULL) { free(entry); return (DEVFS_NOMEM); } vers = prom_obp_vers(); if (vers < 0) { free(entry); return (vers); } /* for each entry in boot-device, do... */ for (ptr = strtok(entry, " "), i = 0; ptr != NULL; ptr = strtok(NULL, " "), i++) { if ((bootdev_array[i] = alloc_bootdev(ptr)) == NULL) { devfs_bootdev_free_list(bootdev_array); free(entry); return (DEVFS_NOMEM); } /* * prom boot-device may be aliased, so we need to do * the necessary prom alias to dev translation. */ if (*ptr != '/') { if (alias_to_prom_dev(ptr, prom_path) < 0) { continue; } } else { (void) strcpy(prom_path, ptr); } /* now we have a prom device path - convert to a devfs name */ if (devfs_prom_to_dev_name(prom_path, ret_buf) < 0) { continue; } /* append any default minor names necessary */ if (process_minor_name(ret_buf, default_root) < 0) { continue; } found = 1; /* * store the physical device path for now - when * we are all done with the entries, we will convert * these to their logical device name equivalents */ bootdev_array[i]->bootdev_trans[0] = strdup(ret_buf); } /* * Convert all of the boot-device entries that translated to a * physical device path in /devices to a logical device path * in /dev (note that there may be several logical device paths * associated with a single physical device path - return them all */ if (found) { if (devfs_phys_to_logical(bootdev_array, num_entries, default_root) < 0) { devfs_bootdev_free_list(bootdev_array); bootdev_array = NULL; } } free(entry); *list = bootdev_array; return (0); } /* * We may get a device path from the prom that has no minor name * information included in it. Since this device name will not * correspond directly to a physical device in /devices, we do our * best to append what the default minor name should be and try this. * * For sparc: we append slice 0 (:a). * For x86: we append fdisk partition 0 (:q). */ static int process_minor_name(char *dev_path, const char *root) { char *cp; #if defined(sparc) const char *default_minor_name = "a"; #else const char *default_minor_name = "q"; #endif int n; struct stat stat_buf; char path[MAXPATHLEN]; (void) snprintf(path, sizeof (path), "%s%s%s", root, DEVICES, dev_path); /* * if the device file already exists as given to us, there * is nothing to do but return. */ if (stat(path, &stat_buf) == 0) { return (0); } /* * if there is no ':' after the last '/' character, or if there is * a ':' with no specifier, append the default segment specifier * ; if there is a ':' followed by a digit, this indicates * a partition number (which does not map into the /devices name * space), so strip the number and replace it with the letter * that represents the partition index */ if ((cp = strrchr(dev_path, '/')) != NULL) { if ((cp = strchr(cp, ':')) == NULL) { (void) strcat(dev_path, ":"); (void) strcat(dev_path, default_minor_name); } else if (*++cp == '\0') { (void) strcat(dev_path, default_minor_name); } else if (isdigit(*cp)) { n = atoi(cp); /* make sure to squash the digit */ *cp = '\0'; switch (n) { case 0: (void) strcat(dev_path, "q"); break; case 1: (void) strcat(dev_path, "r"); break; case 2: (void) strcat(dev_path, "s"); break; case 3: (void) strcat(dev_path, "t"); break; case 4: (void) strcat(dev_path, "u"); break; default: (void) strcat(dev_path, "a"); break; } } } /* * see if we can find something now. */ (void) snprintf(path, sizeof (path), "%s%s%s", root, DEVICES, dev_path); if (stat(path, &stat_buf) == 0) { return (0); } else { return (-1); } } /* * for each entry in bootdev_array, convert the physical device * representation of the boot-device entry to one or more logical device * entries. We use the hammer method - walk through the logical device * name space looking for matches (/dev). We use nftw to do this. */ static int devfs_phys_to_logical(struct boot_dev **bootdev_array, const int array_size, const char *default_root) { int walk_flags = FTW_PHYS | FTW_MOUNT; char *full_path; struct name_list *list; int count, i; char **dev_name_array; size_t default_root_len; char *dev_dir = DEV; int len; if (array_size < 0) { return (-1); } if (bootdev_array == NULL) { return (-1); } if (default_root == NULL) { return (-1); } default_root_len = strlen(default_root); if ((default_root_len != 0) && (*default_root != '/')) { return (-1); } /* short cut for an empty array */ if (*bootdev_array == NULL) { return (0); } /* tell nftw where to start (default: /dev) */ len = default_root_len + strlen(dev_dir) + 1; if ((full_path = (char *)malloc(len)) == NULL) { return (-1); } /* * if the default root path is terminated with a /, we have to * make sure we don't end up with one too many slashes in the * path we are building. */ if ((default_root_len > (size_t)0) && (default_root[default_root_len - 1] == '/')) { (void) snprintf(full_path, len, "%s%s", default_root, &dev_dir[1]); } else { (void) snprintf(full_path, len, "%s%s", default_root, dev_dir); } /* * we need to muck with global data to make nftw work * so single thread access */ (void) mutex_lock(&dev_lists_lk); /* * set the global vars bootdev_list and dev_list for use by nftw * dev_list is an array of lists - one for each boot-device * entry. The nftw function will create a list of logical device * entries for each boot-device and put all of the lists in * dev_list. */ dev_list = (struct name_list **) calloc(array_size, sizeof (struct name_list *)); if (dev_list == NULL) { free(full_path); (void) mutex_unlock(&dev_lists_lk); return (-1); } bootdev_list = bootdev_array; if (nftw(full_path, check_logical_dev, FT_DEPTH, walk_flags) == -1) { bootdev_list = NULL; free(full_path); for (i = 0; i < array_size; i++) { free_name_list(dev_list[i], 1); } /* don't free dev_list here because it's been handed off */ dev_list = NULL; (void) mutex_unlock(&dev_lists_lk); return (-1); } /* * now we have a filled in dev_list. So for each logical device * list in dev_list, count the number of entries in the list, * create an array of strings of logical devices, and save in the * corresponding boot_dev structure. */ for (i = 0; i < array_size; i++) { /* get the next list */ list = dev_list[i]; count = 0; /* count the number of entries in the list */ while (list != NULL) { count++; list = list->next; } if ((dev_name_array = (char **)malloc((count + 1) * sizeof (char *))) == NULL) { continue; } list = dev_list[i]; count = 0; /* fill in the array */ while (list != NULL) { dev_name_array[count] = list->name; count++; list = list->next; } /* * null terminate the array */ dev_name_array[count] = NULL; if ((bootdev_array[i] != NULL) && (bootdev_array[i]-> bootdev_trans[0] != NULL)) { free(bootdev_array[i]->bootdev_trans[0]); } if (bootdev_array[i] != NULL) { free(bootdev_array[i]->bootdev_trans); bootdev_array[i]->bootdev_trans = dev_name_array; } } bootdev_list = NULL; free(full_path); for (i = 0; i < array_size; i++) { free_name_list(dev_list[i], 0); } free(dev_list); dev_list = NULL; (void) mutex_unlock(&dev_lists_lk); return (0); } /* * nftw function * for a logical dev entry, it walks the list of boot-devices and * sees if there are any matches. If so, it saves the logical device * name off in the appropriate list in dev_list */ /* ARGSUSED */ static int check_logical_dev(const char *node, const struct stat *node_stat, int flags, struct FTW *ftw_info) { char link_buf[MAXPATHLEN]; int link_buf_len; char *name; struct name_list *dev; char *physdev; int i; if (flags != FTW_SL) { return (0); } if ((link_buf_len = readlink(node, (void *)link_buf, MAXPATHLEN)) == -1) { return (0); } link_buf[link_buf_len] = '\0'; if ((name = strstr(link_buf, DEVICES)) == NULL) { return (0); } name = (char *)(name + strlen(DEVICES)); for (i = 0; bootdev_list[i] != NULL; i++) { if (bootdev_list[i]->bootdev_trans[0] == NULL) { continue; } /* * compare the contents of the link with the physical * device representation of this boot device */ physdev = bootdev_list[i]->bootdev_trans[0]; if ((strcmp(name, physdev) == 0) && (strlen(name) == strlen(physdev))) { if ((dev = (struct name_list *) malloc(sizeof (struct name_list))) == NULL) { return (-1); } if ((dev->name = strdup(node)) == NULL) { free(dev); return (-1); } if (dev_list[i] == NULL) { dev_list[i] = dev; dev_list[i]->next = NULL; } else { dev->next = dev_list[i]; dev_list[i] = dev; } } } return (0); } /* * frees a list of boot_dev struct pointers */ void devfs_bootdev_free_list(struct boot_dev **array) { int i = 0; int j; if (array == NULL) { return; } while (array[i] != NULL) { free(array[i]->bootdev_element); j = 0; while (array[i]->bootdev_trans[j] != NULL) { free(array[i]->bootdev_trans[j++]); } free(array[i]->bootdev_trans); free(array[i]); i++; } free(array); } /* * allocates a boot_dev struct and fills in the bootdev_element portion */ static struct boot_dev * alloc_bootdev(char *entry_name) { struct boot_dev *entry; entry = (struct boot_dev *)calloc(1, sizeof (struct boot_dev)); if (entry == NULL) { return (NULL); } if ((entry->bootdev_element = strdup(entry_name)) == NULL) { free(entry); return (NULL); } /* * Allocate room for 1 name and a null terminator - the caller of * this function will need the first slot right away. */ if ((entry->bootdev_trans = (char **)calloc(2, sizeof (char *))) == NULL) { free(entry->bootdev_element); free(entry); return (NULL); } return (entry); } /* * will come back with a concatenated list of paths */ int devfs_dev_to_prom_names(char *dev_path, char *prom_path, size_t len) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int prom_fd; int ret = DEVFS_INVAL; int i; if (prom_path == NULL) { return (DEVFS_INVAL); } if (dev_path == NULL) { return (DEVFS_INVAL); } if (strlen(dev_path) >= MAXPATHLEN) return (DEVFS_INVAL); if (*dev_path != '/') return (DEVFS_INVAL); prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } /* query the prom */ (void) snprintf(opp->oprom_array, MAXVALSIZE, "%s", dev_path); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMDEV2PROMNAME, opp) == 0) { prom_close(prom_fd); /* return the prom path in prom_path */ i = len - opp->oprom_size; if (i < 0) { bcopy(opp->oprom_array, prom_path, len); prom_path[len - 1] = NULL; return (len); } else { bcopy(opp->oprom_array, prom_path, len); return (opp->oprom_size); } } /* * either the prom does not support this ioctl or the argument * was invalid. */ if (errno == ENXIO) { ret = DEVFS_NOTSUP; } prom_close(prom_fd); return (ret); } /* * Convert a physical or logical device name to a name the prom would * understand. Fail if this platform does not support a prom or if * the device does not correspond to a valid prom device. * dev_path should be the name of a device in the logical or * physical device namespace. * prom_path is the prom version of the device name * prom_path must be large enough to contain the result and is * supplied by the user. * * This routine only supports converting leaf device paths */ int devfs_dev_to_prom_name(char *dev_path, char *prom_path) { int rval; rval = devfs_dev_to_prom_names(dev_path, prom_path, MAXPATHLEN); if (rval < 0) return (rval); else return (0); } /* * Use the openprom driver's OPROMPATH2DRV ioctl to convert a devfs * path to a driver name. * devfs_path - the pathname of interest. This must be the physcical device * path with the mount point prefix (ie. /devices) stripped off. * drv_buf - user supplied buffer - the driver name will be stored here. * * If the prom lookup fails, we return the name of the last component in * the pathname. This routine is useful for looking up driver names * associated with generically named devices. * * This routine returns driver names that have aliases resolved. */ int devfs_path_to_drv(char *devfs_path, char *drv_buf) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); char *slash, *colon, *dev_addr; char driver_path[MAXPATHLEN]; int prom_fd; if (drv_buf == NULL) { return (-1); } if (devfs_path == NULL) { return (-1); } if (strlen(devfs_path) >= MAXPATHLEN) return (-1); if (*devfs_path != '/') return (-1); /* strip off any minor node info at the end of the path */ (void) strcpy(driver_path, devfs_path); slash = strrchr(driver_path, '/'); if (slash == NULL) return (-1); colon = strrchr(slash, ':'); if (colon != NULL) *colon = '\0'; /* query the prom */ if ((prom_fd = prom_open(O_RDONLY)) >= 0) { (void) strcpy(opp->oprom_array, driver_path); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMPATH2DRV, opp) == 0) { prom_close(prom_fd); /* return the driver name in drv_buf */ (void) strcpy(drv_buf, opp->oprom_array); return (0); } prom_close(prom_fd); } else if (prom_fd != DEVFS_NOTSUP) return (-1); /* * If we get here, then either: * 1. this platform does not support an openprom driver * 2. we were asked to look up a device the prom does * not know about (e.g. a pseudo device) * In this case, we use the last component of the devfs path * name and try to derive the driver name */ /* use the last component of devfs_path as the driver name */ if ((dev_addr = strrchr(slash, '@')) != NULL) *dev_addr = '\0'; slash++; /* use opp->oprom_array as a buffer */ (void) strcpy(opp->oprom_array, slash); if (devfs_resolve_aliases(opp->oprom_array) == NULL) return (-1); (void) strcpy(drv_buf, opp->oprom_array); return (0); } /* * These modctl calls do the equivalent of: * ddi_name_to_major() * ddi_major_to_name() * This results in two things: * - the driver name must be a valid one * - any driver aliases are resolved. * drv is overwritten with the resulting name. */ char * devfs_resolve_aliases(char *drv) { major_t maj; char driver_name[MAXNAMELEN + 1]; if (drv == NULL) { return (NULL); } if (modctl(MODGETMAJBIND, drv, strlen(drv) + 1, &maj) < 0) return (NULL); else if (modctl(MODGETNAME, driver_name, sizeof (driver_name), &maj) < 0) { return (NULL); } else { (void) strcpy(drv, driver_name); return (drv); } } /* * open the openprom device. and verify that we are on an * OBP/1275 OF machine. If the prom does not exist, then we * return an error */ static int prom_open(int oflag) { int prom_fd = -1; char *promdev = "/dev/openprom"; while (prom_fd < 0) { if ((prom_fd = open(promdev, oflag)) < 0) { if (errno == EAGAIN) { (void) sleep(5); continue; } if ((errno == ENXIO) || (errno == ENOENT)) { return (DEVFS_NOTSUP); } if ((errno == EPERM) || (errno == EACCES)) { return (DEVFS_PERM); } return (DEVFS_ERR); } else break; } if (is_openprom(prom_fd)) return (prom_fd); else { prom_close(prom_fd); return (DEVFS_ERR); } } static void prom_close(int prom_fd) { (void) close(prom_fd); } /* * is this an OBP/1275 OF machine? */ static int is_openprom(int prom_fd) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); unsigned int i; opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMGETCONS, opp) < 0) return (0); i = (unsigned int)((unsigned char)opp->oprom_array[0]); return ((i & OPROMCONS_OPENPROM) == OPROMCONS_OPENPROM); } /* * convert a prom device path name to an equivalent physical device * path in the kernel. */ static int devfs_prom_to_dev_name(char *prom_path, char *dev_path) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int prom_fd; int ret = DEVFS_INVAL; if (dev_path == NULL) { return (DEVFS_INVAL); } if (prom_path == NULL) { return (DEVFS_INVAL); } if (strlen(prom_path) >= MAXPATHLEN) return (DEVFS_INVAL); if (*prom_path != '/') { return (DEVFS_INVAL); } /* query the prom */ prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } (void) strcpy(opp->oprom_array, prom_path); opp->oprom_size = MAXVALSIZE; if (ioctl(prom_fd, OPROMPROM2DEVNAME, opp) == 0) { prom_close(prom_fd); /* * success * return the prom path in prom_path */ (void) strcpy(dev_path, opp->oprom_array); return (0); } /* * either the argument was not a valid name or the openprom * driver does not support this ioctl. */ if (errno == ENXIO) { ret = DEVFS_NOTSUP; } prom_close(prom_fd); return (ret); } /* * convert a prom device path to a list of equivalent alias names * If there is no alias node, or there are no aliases that correspond * to dev, we return empty lists. */ static int prom_dev_to_alias(char *dev, uint_t options, char ***ret_buf) { struct name_list *exact_list; struct name_list *inexact_list; struct name_list *list; char *ptr; char **array; int prom_fd; int count; int vers; vers = prom_obp_vers(); if (vers < 0) { return (vers); } if (dev == NULL) { return (DEVFS_INVAL); } if (*dev != '/') return (DEVFS_INVAL); if (strlen(dev) >= MAXPATHLEN) return (DEVFS_INVAL); if ((ptr = strchr(dev, ':')) != NULL) { if (strchr(ptr, '/') != NULL) return (DEVFS_INVAL); } if (ret_buf == NULL) { return (DEVFS_INVAL); } prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } (void) prom_srch_aliases_by_def(dev, &exact_list, &inexact_list, prom_fd); prom_close(prom_fd); if ((options & BOOTDEV_NO_EXACT_ALIAS) != 0) { free_name_list(exact_list, 1); exact_list = NULL; } if ((options & BOOTDEV_NO_INEXACT_ALIAS) != 0) { free_name_list(inexact_list, 1); inexact_list = NULL; } count = 0; list = exact_list; while (list != NULL) { list = list->next; count++; } list = inexact_list; while (list != NULL) { list = list->next; count++; } if ((*ret_buf = (char **)malloc((count + 1) * sizeof (char *))) == NULL) { free_name_list(inexact_list, 1); free_name_list(exact_list, 1); return (DEVFS_NOMEM); } array = *ret_buf; count = 0; list = exact_list; while (list != NULL) { array[count] = list->name; list = list->next; count++; } list = inexact_list; while (list != NULL) { array[count] = list->name; list = list->next; count++; } array[count] = NULL; free_name_list(inexact_list, 0); free_name_list(exact_list, 0); return (0); } /* * determine the version of prom we are running on. * Also include any prom revision specific information. */ static int prom_obp_vers(void) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int prom_fd; static int version = 0; /* cache version */ if (version > 0) { return (version); } prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } opp->oprom_size = MAXVALSIZE; if ((ioctl(prom_fd, OPROMGETVERSION, opp)) < 0) { prom_close(prom_fd); return (DEVFS_ERR); } prom_close(prom_fd); version |= OBP_OF; return (version); } /* * search the aliases node by definition - compile a list of * alias names that are both exact and inexact matches. */ static int prom_srch_aliases_by_def(char *promdev_def, struct name_list **exact_list, struct name_list **inexact_list, int prom_fd) { Oppbuf oppbuf; Oppbuf propdef_oppbuf; struct openpromio *opp = &(oppbuf.opp); struct openpromio *propdef_opp = &(propdef_oppbuf.opp); int *ip = (int *)((void *)opp->oprom_array); int ret; struct name_list *inexact_match = *inexact_list = NULL; struct name_list *exact_match = *exact_list = NULL; char alias_buf[MAXNAMELEN]; int found = 0; (void) memset(oppbuf.buf, 0, BUFSIZE); opp->oprom_size = MAXPROPSIZE; *ip = 0; if ((ret = ioctl(prom_fd, OPROMNXTPROP, opp)) < 0) return (0); if (opp->oprom_size == 0) return (0); while ((ret >= 0) && (opp->oprom_size > 0)) { (void) strcpy(propdef_opp->oprom_array, opp->oprom_array); opp->oprom_size = MAXPROPSIZE; propdef_opp->oprom_size = MAXVALSIZE; if ((ioctl(prom_fd, OPROMGETPROP, propdef_opp) < 0) || (propdef_opp->oprom_size == 0)) { ret = ioctl(prom_fd, OPROMNXTPROP, opp); continue; } ret = prom_compare_devs(promdev_def, propdef_opp->oprom_array); if (ret == EXACT_MATCH) { found++; if (insert_alias_list(exact_list, opp->oprom_array) != 0) { free_name_list(exact_match, 1); free_name_list(inexact_match, 1); return (-1); } } if (ret == INEXACT_MATCH) { found++; (void) strcpy(alias_buf, opp->oprom_array); options_override(promdev_def, alias_buf); if (insert_alias_list(inexact_list, alias_buf) != 0) { free_name_list(exact_match, 1); free_name_list(inexact_match, 1); return (-1); } } ret = ioctl(prom_fd, OPROMNXTPROP, opp); } if (found) { return (0); } else { return (-1); } } /* * free a list of name_list structs and optionally * free the strings they contain. */ static void free_name_list(struct name_list *list, int free_name) { struct name_list *next = list; while (next != NULL) { list = list->next; if (free_name) free(next->name); free(next); next = list; } } /* * insert a new alias in a list of aliases - the list is sorted * in collating order (ignoring anything that comes after the * ':' in the name). */ static int insert_alias_list(struct name_list **list, char *alias_name) { struct name_list *entry = *list; struct name_list *new_entry, *prev_entry; int ret; char *colon1, *colon2; if ((new_entry = (struct name_list *)malloc(sizeof (struct name_list))) == NULL) { return (-1); } if ((new_entry->name = strdup(alias_name)) == NULL) { free(new_entry); return (-1); } new_entry->next = NULL; if (entry == NULL) { *list = new_entry; return (0); } if ((colon1 = strchr(alias_name, ':')) != NULL) { *colon1 = '\0'; } prev_entry = NULL; while (entry != NULL) { if ((colon2 = strchr(entry->name, ':')) != NULL) { *colon2 = '\0'; } ret = strcmp(alias_name, entry->name); if (colon2 != NULL) { *colon2 = ':'; } /* duplicate */ if (ret == 0) { free(new_entry->name); free(new_entry); if (colon1 != NULL) { *colon1 = ':'; } return (0); } if (ret < 0) { new_entry->next = entry; if (prev_entry == NULL) { /* in beginning of list */ *list = new_entry; } else { /* in middle of list */ prev_entry->next = new_entry; } if (colon1 != NULL) { *colon1 = ':'; } return (0); } prev_entry = entry; entry = entry->next; } /* at end of list */ prev_entry->next = new_entry; new_entry->next = NULL; if (colon1 != NULL) { *colon1 = ':'; } return (0); } /* * append :x to alias_name to override any default minor name options */ static void options_override(char *prom_path, char *alias_name) { char *colon; if ((colon = strrchr(alias_name, ':')) != NULL) { /* * XXX - should alias names in /aliases ever have a * : embedded in them? * If so we ignore it. */ *colon = '\0'; } if ((colon = strrchr(prom_path, ':')) != NULL) { (void) strcat(alias_name, colon); } } /* * compare to prom device names. * if the device names are not fully qualified. we convert them - * we only do this as a last resort though since it requires * jumping into the kernel. */ static int prom_compare_devs(char *prom_dev1, char *prom_dev2) { char *dev1, *dev2; char *ptr1, *ptr2; char *drvname1, *addrname1, *minorname1; char *drvname2, *addrname2, *minorname2; char component1[MAXNAMELEN], component2[MAXNAMELEN]; char devname1[MAXPATHLEN], devname2[MAXPATHLEN]; int unqualified_name = 0; int error = EXACT_MATCH; int len1, len2; char *wildcard = ",0"; ptr1 = prom_dev1; ptr2 = prom_dev2; if ((ptr1 == NULL) || (*ptr1 != '/')) { return (NO_MATCH); } if ((ptr2 == NULL) || (*ptr2 != '/')) { return (NO_MATCH); } /* * compare device names one component at a time. */ while ((ptr1 != NULL) && (ptr2 != NULL)) { *ptr1 = *ptr2 = '/'; dev1 = ptr1 + 1; dev2 = ptr2 + 1; if ((ptr1 = strchr(dev1, '/')) != NULL) *ptr1 = '\0'; if ((ptr2 = strchr(dev2, '/')) != NULL) *ptr2 = '\0'; (void) strcpy(component1, dev1); (void) strcpy(component2, dev2); parse_name(component1, &drvname1, &addrname1, &minorname1); parse_name(component2, &drvname2, &addrname2, &minorname2); if ((drvname1 == NULL) && (addrname1 == NULL)) { error = NO_MATCH; break; } if ((drvname2 == NULL) && (addrname2 == NULL)) { error = NO_MATCH; break; } if (_prom_strcmp(drvname1, drvname2) != 0) { error = NO_MATCH; break; } /* * a possible name is driver_name@address. The address * portion is optional (i.e. the name is not fully * qualified.). We have to deal with the case where * the component name is either driver_name or * driver_name@address */ if ((addrname1 == NULL) ^ (addrname2 == NULL)) { unqualified_name = 1; } else if (addrname1 && (_prom_strcmp(addrname1, addrname2) != 0)) { /* * check to see if appending a ",0" to the * shorter address causes a match to occur. * If so succeed. */ len1 = strlen(addrname1); len2 = strlen(addrname2); if ((len1 < len2) && (strncmp(addrname1, addrname2, len1) == 0) && (strcmp(wildcard, &addrname2[len1]) == 0)) { continue; } else if ((len2 < len1) && (strncmp(addrname1, addrname2, len2) == 0) && (strcmp(wildcard, &addrname1[len2]) == 0)) { continue; } error = NO_MATCH; break; } } /* * if either of the two device paths still has more components, * then we do not have a match. */ if (ptr1 != NULL) { *ptr1 = '/'; error = NO_MATCH; } if (ptr2 != NULL) { *ptr2 = '/'; error = NO_MATCH; } if (error == NO_MATCH) { return (error); } /* * OK - we found a possible match but one or more of the * path components was not fully qualified (did not have any * address information. So we need to convert it to a form * that is fully qualified and then compare the resulting * strings. */ if (unqualified_name != 0) { if ((devfs_prom_to_dev_name(prom_dev1, devname1) < 0) || (devfs_prom_to_dev_name(prom_dev2, devname2) < 0)) { return (NO_MATCH); } if ((dev1 = strrchr(devname1, ':')) != NULL) { *dev1 = '\0'; } if ((dev2 = strrchr(devname2, ':')) != NULL) { *dev2 = '\0'; } if (strcmp(devname1, devname2) != 0) { return (NO_MATCH); } } /* * the resulting strings matched. If the minorname information * matches, then we have an exact match, otherwise an inexact match */ if (_prom_strcmp(minorname1, minorname2) == 0) { return (EXACT_MATCH); } else { return (INEXACT_MATCH); } } /* * wrapper or strcmp - deals with null strings. */ static int _prom_strcmp(char *s1, char *s2) { if ((s1 == NULL) && (s2 == NULL)) return (0); if ((s1 == NULL) && (s2 != NULL)) { return (-1); } if ((s1 != NULL) && (s2 == NULL)) { return (1); } return (strcmp(s1, s2)); } /* * break device@a,b:minor into components */ static void parse_name(char *name, char **drvname, char **addrname, char **minorname) { char *cp, ch; cp = *drvname = name; *addrname = *minorname = NULL; if (*name == '@') *drvname = NULL; while ((ch = *cp) != '\0') { if (ch == '@') *addrname = ++cp; else if (ch == ':') *minorname = ++cp; ++cp; } if (*addrname) { *((*addrname)-1) = '\0'; } if (*minorname) { *((*minorname)-1) = '\0'; } } /* * converts a prom alias to a prom device name. * if we find no matching device, then we fail since if were * given a valid alias, then by definition, there must be a * device pathname associated with it in the /aliases node. */ static int alias_to_prom_dev(char *alias, char *ret_buf) { char *options_ptr; char alias_buf[MAXNAMELEN]; char alias_def[MAXPATHLEN]; char options[16] = ""; int prom_fd = -1; int ret; int i; if (strchr(alias, '/') != NULL) return (DEVFS_INVAL); if (strlen(alias) > (MAXNAMELEN - 1)) return (DEVFS_INVAL); if (ret_buf == NULL) { return (DEVFS_INVAL); } prom_fd = prom_open(O_RDONLY); if (prom_fd < 0) { return (prom_fd); } (void) strlcpy(alias_buf, alias, sizeof (alias_buf)); /* * save off any options (minor name info) that is * explicitly called out in the alias name */ if ((options_ptr = strchr(alias_buf, ':')) != NULL) { *options_ptr = '\0'; (void) strlcpy(options, ++options_ptr, sizeof (options)); } *alias_def = '\0'; ret = prom_find_aliases_node(prom_fd); if (ret == 0) { /* * we loop because one alias may define another... we have * to work our way down to an actual device definition. */ for (i = 0; i <= 10; i++) { ret = prom_srch_node(prom_fd, alias_buf, alias_def); if (ret == -1) { break; } (void) strlcpy(alias_buf, alias_def, sizeof (alias_buf)); if (*alias_def == '/') { break; } /* * save off any explicit options (minor name info) * if none has been encountered yet */ if (options_ptr == NULL) { options_ptr = strchr(alias_buf, ':'); if (options_ptr != NULL) { *options_ptr = '\0'; (void) strlcpy(options, ++options_ptr, sizeof (options)); } } } } prom_close(prom_fd); /* error */ if (ret == -1) { return (ret); } (void) strlcpy(ret_buf, alias_def, strlen(ret_buf) + 1); /* override minor name information */ if (options_ptr != NULL) { if ((options_ptr = strrchr(ret_buf, ':')) == NULL) { (void) strcat(ret_buf, ":"); } else { *(++options_ptr) = '\0'; } (void) strcat(ret_buf, options); } return (0); } /* * search a prom node for a property name */ static int prom_srch_node(int fd, char *prop_name, char *ret_buf) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); int *ip = (int *)((void *)opp->oprom_array); (void) memset(oppbuf.buf, 0, BUFSIZE); opp->oprom_size = MAXPROPSIZE; *ip = 0; if (ioctl(fd, OPROMNXTPROP, opp) < 0) return (-1); if (opp->oprom_size == 0) return (-1); while (strcmp(prop_name, opp->oprom_array) != 0) { opp->oprom_size = MAXPROPSIZE; if (ioctl(fd, OPROMNXTPROP, opp) < 0) return (-1); if (opp->oprom_size == 0) return (-1); } opp->oprom_size = MAXVALSIZE; if (ioctl(fd, OPROMGETPROP, opp) < 0) return (-1); if (opp->oprom_size == 0) return (-1); (void) strlcpy(ret_buf, opp->oprom_array, strlen(ret_buf) + 1); return (0); } /* * return the aliases node. */ static int prom_find_aliases_node(int fd) { uint_t child_id; char buf[MAXNAMELEN]; if ((child_id = prom_next_node(fd, 0)) == 0) return (-1); if ((child_id = prom_child_node(fd, child_id)) == 0) return (-1); while (child_id != 0) { if (prom_srch_node(fd, "name", buf) == 0) { if (strcmp(buf, "aliases") == 0) { return (0); } } child_id = prom_next_node(fd, child_id); } return (-1); } /* * get sibling */ static uint_t prom_next_node(int fd, uint_t node_id) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); uint_t *ip = (uint_t *)((void *)opp->oprom_array); (void) memset(oppbuf.buf, 0, BUFSIZE); opp->oprom_size = MAXVALSIZE; *ip = node_id; if (ioctl(fd, OPROMNEXT, opp) < 0) return (0); return (*(uint_t *)((void *)opp->oprom_array)); } /* * get child */ static uint_t prom_child_node(int fd, uint_t node_id) { Oppbuf oppbuf; struct openpromio *opp = &(oppbuf.opp); uint_t *ip = (uint_t *)((void *)opp->oprom_array); (void) memset(oppbuf.buf, 0, BUFSIZE); opp->oprom_size = MAXVALSIZE; *ip = node_id; if (ioctl(fd, OPROMCHILD, opp) < 0) return (0); return (*(uint_t *)((void *)opp->oprom_array)); } /* * only on sparc for now */ int devfs_bootdev_modifiable(void) { #if defined(sparc) return (0); #else return (DEVFS_NOTSUP); #endif }