/* * 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. */ /* * Plugin Library for PCI Hot-Plug Controller */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define CFGA_PLUGIN_LIB #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../../../../common/pci/pci_strings.h" extern const struct pci_class_strings_s class_pci[]; extern int class_pci_items; /* * Set the version number */ int cfga_version = CFGA_HSL_V2; #ifdef DEBUG #define PCIHP_DBG 1 #endif #if !defined(TEXT_DOMAIN) #define TEXT_DOMAIN "SYS_TEST" #endif /* * DEBUGING LEVEL * * External routines: 1 - 2 * Internal routines: 3 - 4 */ #ifdef PCIHP_DBG int pcihp_debug = 1; #define DBG(level, args) \ { if (pcihp_debug >= (level)) printf args; } #define DBG_F(level, args) \ { if (pcihp_debug >= (level)) fprintf args; } #else #define DBG(level, args) /* nothing */ #define DBG_F(level, args) /* nothing */ #endif #define CMD_ACQUIRE 0 #define CMD_GETSTAT 1 #define CMD_LIST 2 #define CMD_SLOT_CONNECT 3 #define CMD_SLOT_DISCONNECT 4 #define CMD_SLOT_CONFIGURE 5 #define CMD_SLOT_UNCONFIGURE 6 #define CMD_SLOT_INSERT 7 #define CMD_SLOT_REMOVE 8 #define CMD_OPEN 9 #define CMD_FSTAT 10 #define ERR_CMD_INVAL 11 #define ERR_AP_INVAL 12 #define ERR_AP_ERR 13 #define ERR_OPT_INVAL 14 static char * cfga_errstrs[] = { /* n */ "acquire ", /* n */ "get-status ", /* n */ "list ", /* n */ "connect ", /* n */ "disconnect ", /* n */ "configure ", /* n */ "unconfigure ", /* n */ "insert ", /* n */ "remove ", /* n */ "open ", /* n */ "fstat ", /* y */ "invalid command ", /* y */ "invalid attachment point ", /* y */ "invalid transition ", /* y */ "invalid option ", NULL }; #define HELP_HEADER 1 #define HELP_CONFIG 2 #define HELP_ENABLE_SLOT 3 #define HELP_DISABLE_SLOT 4 #define HELP_ENABLE_AUTOCONF 5 #define HELP_DISABLE_AUTOCONF 6 #define HELP_LED_CNTRL 7 #define HELP_UNKNOWN 8 #define SUCCESS 9 #define FAILED 10 #define UNKNOWN 11 #define MAXLINE 256 /* for type string assembly in get_type() */ #define TPCT(s) (void) strlcat(buf, (s), CFGA_TYPE_LEN) extern int errno; static void cfga_err(char **errstring, ...); static cfga_err_t fix_ap_name(char *ap_log_id, const char *ap_id, char *slot_name, char **errstring); static void build_control_data(struct hpc_control_data *iocdata, uint_t cmd, void *retdata); static cfga_err_t check_options(const char *options); static void cfga_msg(struct cfga_msg *msgp, const char *str); static char *findlink(char *ap_phys_id); static char * cfga_strs[] = { NULL, "\nPCI hotplug specific commands:", "\t-c [connect|disconnect|configure|unconfigure|insert|remove] " "ap_id [ap_id...]", "\t-x enable_slot ap_id [ap_id...]", "\t-x disable_slot ap_id [ap_id...]", "\t-x enable_autoconfig ap_id [ap_id...]", "\t-x disable_autoconfig ap_id [ap_id...]", "\t-x led[=[fault|power|active|attn],mode=[on|off|blink]] ap_id [ap_id...]", "\tunknown command or option: ", "success ", "failed ", "unknown", NULL }; #define MAX_FORMAT 80 #define ENABLE_SLOT 0 #define DISABLE_SLOT 1 #define ENABLE_AUTOCNF 2 #define DISABLE_AUTOCNF 3 #define LED 4 #define MODE 5 /* * Board Type */ static char * board_strs[] = { /* n */ "???", /* HPC_BOARD_UNKNOWN */ /* n */ "hp", /* HPC_BOARD_PCI_HOTPLUG */ /* n */ "nhs", /* HPC_BOARD_CPCI_NON_HS */ /* n */ "bhs", /* HPC_BOARD_CPCI_BASIC_HS */ /* n */ "fhs", /* HPC_BOARD_CPCI_FULL_HS */ /* n */ "hs", /* HPC_BOARD_CPCI_HS */ /* n */ NULL }; /* * HW functions */ static char * func_strs[] = { /* n */ "enable_slot", /* n */ "disable_slot", /* n */ "enable_autoconfig", /* n */ "disable_autoconfig", /* n */ "led", /* n */ "mode", /* n */ NULL }; /* * LED strings */ static char * led_strs[] = { /* n */ "fault", /* HPC_FAULT_LED */ /* n */ "power", /* HPC_POWER_LED */ /* n */ "attn", /* HPC_ATTN_LED */ /* n */ "active", /* HPC_ACTIVE_LED */ /* n */ NULL }; #define FAULT 0 #define POWER 1 #define ATTN 2 #define ACTIVE 3 static char * mode_strs[] = { /* n */ "off", /* HPC_LED_OFF */ /* n */ "on", /* HPC_LED_ON */ /* n */ "blink", /* HPC_LED_BLINK */ /* n */ NULL }; #define OFF 0 #define ON 1 #define BLINK 2 #define cfga_errstrs(i) cfga_errstrs[(i)] #define cfga_eid(a, b) (((a) << 8) + (b)) #define MAXDEVS 32 typedef enum { SOLARIS_SLT_NAME, PROM_SLT_NAME } slt_name_src_t; struct searcharg { char *devpath; char slotnames[MAXDEVS][MAXNAMELEN]; int minor; di_prom_handle_t promp; slt_name_src_t slt_name_src; }; static void *private_check; static int get_occupants(const char *ap_id, hpc_occupant_info_t *occupant) { int rv; int fd; di_node_t ap_node; char *prop_data; char *tmp; char *ptr; struct stat statbuf; dev_t devt; if ((fd = open(ap_id, O_RDWR)) == -1) { DBG(2, ("open = ap_id%s, fd%d\n", ap_id, fd)); DBG_F(2, (stderr, "open on %s failed\n", ap_id)); return (CFGA_ERROR); } if (fstat(fd, &statbuf) == -1) { DBG(1, ("stat failed: %i\n", errno)); (void) close(fd); return (CFGA_ERROR); } (void) close(fd); devt = statbuf.st_rdev; tmp = (char *)(ap_id + sizeof ("/devices") - 1); if ((ptr = strrchr(tmp, ':')) != NULL) *ptr = '\0'; ap_node = di_init(tmp, DINFOPROP | DINFOMINOR); if (ap_node == DI_NODE_NIL) { DBG(1, ("dead %i\n", errno)); return (CFGA_ERROR); } #ifdef PCIHP_DBG ptr = di_devfs_path(ap_node); DBG(1, ("get_occupants: %s\n", ptr)); di_devfs_path_free(ptr); #endif if ((rv = di_prop_lookup_strings(devt, ap_node, "pci-occupant", &prop_data)) == -1) { DBG(1, ("get_occupants: prop_lookup failed: %i\n", errno)); di_fini(ap_node); return (CFGA_ERROR); } if (prop_data && (strcmp(prop_data, "") == 0)) { di_fini(ap_node); occupant->i = 0; occupant->id[0] = NULL; return (CFGA_OK); } DBG(1, ("get_occupants: %i devices found\n", rv)); for (occupant->i = 0; occupant->i < rv; occupant->i++) { if (occupant->i >= (HPC_MAX_OCCUPANTS - 1)) { occupant->i--; break; } occupant->id[occupant->i] = (char *)malloc( strlen(prop_data) + sizeof ("/devices")); (void) snprintf(occupant->id[occupant->i], strlen(prop_data) + sizeof ("/devices"), "/devices%s", prop_data); DBG(1, ("%s\n", occupant->id[occupant->i])); prop_data += strlen(prop_data) + 1; } di_fini(ap_node); occupant->id[occupant->i] = NULL; return (CFGA_OK); } /* * let rcm know that the device has indeed been removed and clean * up rcm data */ static void confirm_rcm(hpc_occupant_info_t *occupant, rcm_handle_t *rhandle) { DBG(1, ("confirm_rcm\n")); if (occupant->i == 0) /* nothing was found to ask rcm about */ return; (void) rcm_notify_remove_list(rhandle, occupant->id, 0, NULL); (void) rcm_free_handle(rhandle); for (; occupant->i >= 0; occupant->i--) free(occupant->id[occupant->i]); } static void fail_rcm(hpc_occupant_info_t *occupant, rcm_handle_t *rhandle) { DBG(1, ("fail_rcm\n")); if (occupant->i == 0) /* nothing was found to ask rcm about */ return; (void) rcm_notify_online_list(rhandle, occupant->id, 0, NULL); (void) rcm_free_handle(rhandle); for (; occupant->i >= 0; occupant->i--) free(occupant->id[occupant->i]); } /* * copied from scsi_rcm_info_table * * Takes an opaque rcm_info_t pointer and a character pointer, and appends * the rcm_info_t data in the form of a table to the given character pointer. */ static void pci_rcm_info_table(rcm_info_t *rinfo, char **table) { int i; size_t w; size_t width = 0; size_t w_rsrc = 0; size_t w_info = 0; size_t table_size = 0; uint_t tuples = 0; rcm_info_tuple_t *tuple = NULL; char *rsrc; char *info; char *newtable; static char format[MAX_FORMAT]; const char *infostr; /* Protect against invalid arguments */ if (rinfo == NULL || table == NULL) return; /* Set localized table header strings */ rsrc = dgettext(TEXT_DOMAIN, "Resource"); info = dgettext(TEXT_DOMAIN, "Information"); /* A first pass, to size up the RCM information */ while (tuple = rcm_info_next(rinfo, tuple)) { if ((infostr = rcm_info_info(tuple)) != NULL) { tuples++; if ((w = strlen(rcm_info_rsrc(tuple))) > w_rsrc) w_rsrc = w; if ((w = strlen(infostr)) > w_info) w_info = w; } } /* If nothing was sized up above, stop early */ if (tuples == 0) return; /* Adjust column widths for column headings */ if ((w = strlen(rsrc)) > w_rsrc) w_rsrc = w; else if ((w_rsrc - w) % 2) w_rsrc++; if ((w = strlen(info)) > w_info) w_info = w; else if ((w_info - w) % 2) w_info++; /* * Compute the total line width of each line, * accounting for intercolumn spacing. */ width = w_info + w_rsrc + 4; /* Allocate space for the table */ table_size = (2 + tuples) * (width + 1) + 2; if (*table == NULL) { /* zero fill for the strcat() call below */ *table = calloc(table_size, sizeof (char)); if (*table == NULL) return; } else { newtable = realloc(*table, strlen(*table) + table_size); if (newtable == NULL) return; else *table = newtable; } /* Place a table header into the string */ /* The resource header */ (void) strcat(*table, "\n"); w = strlen(rsrc); for (i = 0; i < ((w_rsrc - w) / 2); i++) (void) strcat(*table, " "); (void) strcat(*table, rsrc); for (i = 0; i < ((w_rsrc - w) / 2); i++) (void) strcat(*table, " "); /* The information header */ (void) strcat(*table, " "); w = strlen(info); for (i = 0; i < ((w_info - w) / 2); i++) (void) strcat(*table, " "); (void) strcat(*table, info); for (i = 0; i < ((w_info - w) / 2); i++) (void) strcat(*table, " "); /* Underline the headers */ (void) strcat(*table, "\n"); for (i = 0; i < w_rsrc; i++) (void) strcat(*table, "-"); (void) strcat(*table, " "); for (i = 0; i < w_info; i++) (void) strcat(*table, "-"); /* Construct the format string */ (void) snprintf(format, MAX_FORMAT, "%%-%ds %%-%ds", (int)w_rsrc, (int)w_info); /* Add the tuples to the table string */ tuple = NULL; while ((tuple = rcm_info_next(rinfo, tuple)) != NULL) { if ((infostr = rcm_info_info(tuple)) != NULL) { (void) strcat(*table, "\n"); (void) sprintf(&((*table)[strlen(*table)]), format, rcm_info_rsrc(tuple), infostr); } } } /* * Figure out what device is about to be unconfigured or disconnected * and make sure rcm is ok with it. * hangs on to a list of handles so they can then be confirmed or denied * if either getting the occupant list or talking to rcm fails * return CFGA_ERROR so that things can go on without rcm */ static int check_rcm(const char *ap_id, hpc_occupant_info_t *occupant, rcm_handle_t **rhandlep, char **errstring, cfga_flags_t flags) { int rv; rcm_info_t *rinfo; rcm_handle_t *rhandle; uint_t rcmflags; if (get_occupants(ap_id, occupant) != 0) { DBG(1, ("check_rcm: failed to get occupants\n")); return (CFGA_ERROR); } if (occupant->i == 0) { DBG(1, ("check_rcm: no drivers attaching to occupants\n")); return (CFGA_OK); } if (rcm_alloc_handle(NULL, 0, NULL, &rhandle) != RCM_SUCCESS) { DBG(1, ("check_rcm: blocked by rcm failure\n")); return (CFGA_ERROR); } rcmflags = (flags & CFGA_FLAG_FORCE) ? RCM_FORCE : 0; rv = rcm_request_offline_list(rhandle, occupant->id, rcmflags, &rinfo); if (rv == RCM_FAILURE) { DBG(1, ("check_rcm: blocked by rcm failure 2\n")); pci_rcm_info_table(rinfo, errstring); rcm_free_info(rinfo); fail_rcm(occupant, rhandle); return (CFGA_BUSY); } if (rv == RCM_CONFLICT) { DBG(1, ("check_rcm: blocked by %i\n", rcm_info_pid(rinfo))); pci_rcm_info_table(rinfo, errstring); rcm_free_info(rinfo); (void) rcm_free_handle(rhandle); for (; occupant->i >= 0; occupant->i--) free(occupant->id[occupant->i]); return (CFGA_BUSY); } rcm_free_info(rinfo); *rhandlep = rhandle; /* else */ return (CFGA_OK); } /* * Transitional Diagram: * * empty unconfigure * (remove) ^| (physically insert card) * |V * disconnect configure * "-c DISCONNECT" ^| "-c CONNECT" * |V "-c CONFIGURE" * connect unconfigure -> connect configure * <- * "-c UNCONFIGURE" * */ /*ARGSUSED*/ cfga_err_t cfga_change_state(cfga_cmd_t state_change_cmd, const char *ap_id, const char *options, struct cfga_confirm *confp, struct cfga_msg *msgp, char **errstring, cfga_flags_t flags) { int rv; devctl_hdl_t dcp; devctl_ap_state_t state; ap_rstate_t rs; ap_ostate_t os; hpc_occupant_info_t occupants; rcm_handle_t *rhandle; if ((rv = check_options(options)) != CFGA_OK) { return (rv); } if (errstring != NULL) *errstring = NULL; rv = CFGA_OK; DBG(1, ("cfga_change_state:(%s)\n", ap_id)); if ((dcp = devctl_ap_acquire((char *)ap_id, 0)) == NULL) { if (rv == EBUSY) { cfga_err(errstring, CMD_ACQUIRE, ap_id, 0); DBG(1, ("cfga_change_state: device is busy\n")); rv = CFGA_BUSY; } else rv = CFGA_ERROR; return (rv); } if (devctl_ap_getstate(dcp, NULL, &state) == -1) { DBG(2, ("cfga_change_state: devctl ap getstate failed\n")); cfga_err(errstring, CMD_GETSTAT, ap_id, 0); devctl_release((devctl_hdl_t)dcp); if (rv == EBUSY) rv = CFGA_BUSY; else rv = CFGA_ERROR; return (rv); } rs = state.ap_rstate; os = state.ap_ostate; DBG(1, ("cfga_change_state: rs is %d\n", state.ap_rstate)); DBG(1, ("cfga_change_state: os is %d\n", state.ap_ostate)); switch (state_change_cmd) { case CFGA_CMD_CONNECT: if ((rs == AP_RSTATE_EMPTY) || (rs == AP_RSTATE_CONNECTED) || (os == AP_OSTATE_CONFIGURED)) { cfga_err(errstring, ERR_AP_ERR, 0); rv = CFGA_INVAL; } else { /* Lets connect the slot */ if (devctl_ap_connect(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_CONNECT, 0); } } break; case CFGA_CMD_DISCONNECT: DBG(1, ("disconnect\n")); if (os == AP_OSTATE_CONFIGURED) { if ((rv = check_rcm(ap_id, &occupants, &rhandle, errstring, flags)) == CFGA_BUSY) { break; } else if (rv == CFGA_OK) { if (devctl_ap_unconfigure(dcp, NULL) == -1) { if (errno == EBUSY) rv = CFGA_BUSY; else rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_DISCONNECT, 0); fail_rcm(&occupants, rhandle); break; } else { confirm_rcm(&occupants, rhandle); } } else { /* rv == CFGA_ERROR */ if (devctl_ap_unconfigure(dcp, NULL) == -1) { if (errno == EBUSY) rv = CFGA_BUSY; else rv = CFGA_ERROR; break; } else { rv = CFGA_OK; } } } if (rs == AP_RSTATE_CONNECTED) { if (devctl_ap_disconnect(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_DISCONNECT, 0); break; } } else { cfga_err(errstring, ERR_AP_ERR, 0); rv = CFGA_INVAL; } break; case CFGA_CMD_CONFIGURE: if (rs == AP_RSTATE_DISCONNECTED) { if (devctl_ap_connect(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_CONNECT, 0); break; } } /* * for multi-func device we allow multiple * configure on the same slot because one * func can be configured and other one won't */ if (devctl_ap_configure(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_CONFIGURE, 0); if ((rs == AP_RSTATE_DISCONNECTED) && (devctl_ap_disconnect(dcp, NULL) == -1)) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_CONFIGURE, 0); } break; } break; case CFGA_CMD_UNCONFIGURE: DBG(1, ("unconfigure\n")); if (os == AP_OSTATE_CONFIGURED) { if ((rv = check_rcm(ap_id, &occupants, &rhandle, errstring, flags)) == CFGA_BUSY) { break; } else if (rv == CFGA_OK) { if (devctl_ap_unconfigure(dcp, NULL) == -1) { if (errno == EBUSY) rv = CFGA_BUSY; else { if (errno == ENOTSUP) rv = CFGA_OPNOTSUPP; else rv = CFGA_ERROR; } cfga_err(errstring, CMD_SLOT_UNCONFIGURE, 0); fail_rcm(&occupants, rhandle); } else { confirm_rcm(&occupants, rhandle); } } else { /* rv == CFGA_ERROR */ if (devctl_ap_unconfigure(dcp, NULL) == -1) { if (errno == EBUSY) rv = CFGA_BUSY; else { if (errno == ENOTSUP) rv = CFGA_OPNOTSUPP; else rv = CFGA_ERROR; } cfga_err(errstring, CMD_SLOT_UNCONFIGURE, 0); } else { rv = CFGA_OK; } } } else { cfga_err(errstring, ERR_AP_ERR, 0); rv = CFGA_INVAL; } DBG(1, ("uncofigure rv:(%i)\n", rv)); break; case CFGA_CMD_LOAD: if ((os == AP_OSTATE_UNCONFIGURED) && (rs == AP_RSTATE_DISCONNECTED)) { if (devctl_ap_insert(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_INSERT, 0); } } else { cfga_err(errstring, ERR_AP_ERR, 0); rv = CFGA_INVAL; } break; case CFGA_CMD_UNLOAD: if ((os == AP_OSTATE_UNCONFIGURED) && (rs == AP_RSTATE_DISCONNECTED)) { if (devctl_ap_remove(dcp, NULL) == -1) { rv = CFGA_ERROR; cfga_err(errstring, CMD_SLOT_REMOVE, 0); } } else { cfga_err(errstring, ERR_AP_ERR, 0); rv = CFGA_INVAL; } break; default: rv = CFGA_OPNOTSUPP; break; } devctl_release((devctl_hdl_t)dcp); return (rv); } /* * Building iocdatat to pass it to nexus * * iocdata->cmd == HPC_CTRL_ENABLE_SLOT/HPC_CTRL_DISABLE_SLOT * HPC_CTRL_ENABLE_AUTOCFG/HPC_CTRL_DISABLE_AUTOCFG * HPC_CTRL_GET_LED_STATE/HPC_CTRL_SET_LED_STATE * HPC_CTRL_GET_SLOT_STATE/HPC_CTRL_GET_SLOT_INFO * HPC_CTRL_DEV_CONFIGURE/HPC_CTRL_DEV_UNCONFIGURE * HPC_CTRL_GET_BOARD_TYPE * */ static void build_control_data(struct hpc_control_data *iocdata, uint_t cmd, void *retdata) { iocdata->cmd = cmd; iocdata->data = retdata; } /* * building logical name from ap_id */ /*ARGSUSED2*/ static void get_logical_name(const char *ap_id, char *buf, dev_t rdev) { char *bufptr, *bufptr2, *pci, *apid; DBG(1, ("get_logical_name: %s\n", ap_id)); if ((apid = malloc(MAXPATHLEN)) == NULL) { DBG(1, ("malloc failed\n")); return; } (void) memset(apid, 0, MAXPATHLEN); (void) strncpy(apid, ap_id, strlen(ap_id)); /* needs to look for last /, not first */ bufptr = strrchr(apid, '/'); bufptr2 = strrchr(apid, ':'); pci = ++bufptr; bufptr = strchr(pci, ','); if (bufptr != NULL) { *bufptr = '\0'; } bufptr = strchr(pci, '@'); if (bufptr != NULL) { *bufptr = '\0'; bufptr++; } DBG(1, ("%s\n%s\n%s\n", pci, bufptr, bufptr2)); (void) strcat(buf, pci); (void) strcat(buf, bufptr); (void) strcat(buf, bufptr2); free(apid); } static cfga_err_t prt_led_mode(const char *ap_id, int repeat, char **errstring, struct cfga_msg *msgp) { hpc_led_info_t power_led_info = {HPC_POWER_LED, 0}; hpc_led_info_t fault_led_info = {HPC_FAULT_LED, 0}; hpc_led_info_t attn_led_info = {HPC_ATTN_LED, 0}; hpc_led_info_t active_led_info = {HPC_ACTIVE_LED, 0}; struct hpc_control_data iocdata; struct stat statbuf; char *buff; int fd; hpc_slot_info_t slot_info; char *cp, line[MAXLINE]; int len = MAXLINE; DBG(1, ("prt_led_mod function\n")); if (!repeat) cfga_msg(msgp, "Ap_Id\t\t\tLed"); if ((fd = open(ap_id, O_RDWR)) == -1) { DBG(2, ("open = ap_id%s, fd%d\n", ap_id, fd)); DBG_F(2, (stderr, "open on %s failed\n", ap_id)); cfga_err(errstring, CMD_OPEN, ap_id, 0); return (CFGA_ERROR); } if (fstat(fd, &statbuf) == -1) { DBG(2, ("fstat = ap_id%s, fd%d\n", ap_id, fd)); DBG_F(2, (stderr, "fstat on %s failed\n", ap_id)); cfga_err(errstring, CMD_FSTAT, ap_id, 0); return (CFGA_ERROR); } if ((buff = malloc(MAXPATHLEN)) == NULL) { cfga_err(errstring, "malloc ", 0); return (CFGA_ERROR); } (void) memset(buff, 0, MAXPATHLEN); DBG(1, ("ioctl boardtype\n")); build_control_data(&iocdata, HPC_CTRL_GET_SLOT_INFO, (void *)&slot_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { get_logical_name(ap_id, slot_info.pci_slot_name, 0); DBG(1, ("ioctl failed slotinfo: %s\n", slot_info.pci_slot_name)); } else { /* * the driver will report back things like hpc0_slot0 * this needs to be changed to things like pci1:hpc0_slot0 */ if (fix_ap_name(buff, ap_id, slot_info.pci_slot_name, errstring) != CFGA_OK) { free(buff); (void) close(fd); return (CFGA_ERROR); } DBG(1, ("ioctl slotinfo: %s\n", buff)); } cp = line; (void) snprintf(cp, len, "%s\t\t", buff); len -= strlen(cp); cp += strlen(cp); free(buff); build_control_data(&iocdata, HPC_CTRL_GET_LED_STATE, &power_led_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { (void) snprintf(cp, len, "%s=%s,", led_strs[power_led_info.led], cfga_strs[UNKNOWN]); len -= strlen(cp); cp += strlen(cp); } else { (void) snprintf(cp, len, "%s=%s,", led_strs[power_led_info.led], mode_strs[power_led_info.state]); len -= strlen(cp); cp += strlen(cp); } DBG(1, ("%s:%d\n", led_strs[power_led_info.led], power_led_info.state)); build_control_data(&iocdata, HPC_CTRL_GET_LED_STATE, &fault_led_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { (void) snprintf(cp, len, "%s=%s,", led_strs[fault_led_info.led], cfga_strs[UNKNOWN]); len -= strlen(cp); cp += strlen(cp); } else { (void) snprintf(cp, len, "%s=%s,", led_strs[fault_led_info.led], mode_strs[fault_led_info.state]); len -= strlen(cp); cp += strlen(cp); } DBG(1, ("%s:%d\n", led_strs[fault_led_info.led], fault_led_info.state)); build_control_data(&iocdata, HPC_CTRL_GET_LED_STATE, &attn_led_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { (void) snprintf(cp, len, "%s=%s,", led_strs[attn_led_info.led], cfga_strs[UNKNOWN]); len -= strlen(cp); cp += strlen(cp); } else { (void) snprintf(cp, len, "%s=%s,", led_strs[attn_led_info.led], mode_strs[attn_led_info.state]); len -= strlen(cp); cp += strlen(cp); } DBG(1, ("%s:%d\n", led_strs[attn_led_info.led], attn_led_info.state)); build_control_data(&iocdata, HPC_CTRL_GET_LED_STATE, &active_led_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { (void) snprintf(cp, len, "%s=%s", led_strs[active_led_info.led], cfga_strs[UNKNOWN]); } else { (void) snprintf(cp, len, "%s=%s", led_strs[active_led_info.led], mode_strs[active_led_info.state]); } cfga_msg(msgp, line); /* print the message */ DBG(1, ("%s:%d\n", led_strs[active_led_info.led], active_led_info.state)); (void) close(fd); return (CFGA_OK); } /*ARGSUSED*/ cfga_err_t cfga_private_func(const char *function, const char *ap_id, const char *options, struct cfga_confirm *confp, struct cfga_msg *msgp, char **errstring, cfga_flags_t flags) { char *str; int len, fd, i = 0, repeat = 0; char buf[MAXNAMELEN]; char ptr; hpc_led_info_t led_info; struct hpc_control_data iocdata; cfga_err_t rv; DBG(1, ("cfgadm_private_func: ap_id:%s\n", ap_id)); DBG(2, (" options: %s\n", (options == NULL)?"null":options)); DBG(2, (" confp: %x\n", confp)); DBG(2, (" cfga_msg: %x\n", cfga_msg)); DBG(2, (" flag: %d\n", flags)); if ((rv = check_options(options)) != CFGA_OK) { return (rv); } if (private_check == confp) repeat = 1; else private_check = (void*)confp; /* XXX change const 6 to func_str[i] != NULL */ for (i = 0, str = func_strs[i], len = strlen(str); i < 6; i++) { str = func_strs[i]; len = strlen(str); if (strncmp(function, str, len) == 0) break; } switch (i) { case ENABLE_SLOT: build_control_data(&iocdata, HPC_CTRL_ENABLE_SLOT, 0); break; case DISABLE_SLOT: build_control_data(&iocdata, HPC_CTRL_DISABLE_SLOT, 0); break; case ENABLE_AUTOCNF: build_control_data(&iocdata, HPC_CTRL_ENABLE_AUTOCFG, 0); break; case DISABLE_AUTOCNF: build_control_data(&iocdata, HPC_CTRL_DISABLE_AUTOCFG, 0); break; case LED: /* set mode */ ptr = function[len++]; if (ptr == '=') { str = (char *)function; for (str = (str+len++), i = 0; *str != ','; i++, str++) { if (i == (MAXNAMELEN - 1)) break; buf[i] = *str; DBG_F(2, (stdout, "%c\n", buf[i])); } buf[i] = '\0'; str++; DBG(2, ("buf = %s\n", buf)); /* ACTIVE=3,ATTN=2,POWER=1,FAULT=0 */ if (strcmp(buf, led_strs[POWER]) == 0) led_info.led = HPC_POWER_LED; else if (strcmp(buf, led_strs[FAULT]) == 0) led_info.led = HPC_FAULT_LED; else if (strcmp(buf, led_strs[ATTN]) == 0) led_info.led = HPC_ATTN_LED; else if (strcmp(buf, led_strs[ACTIVE]) == 0) led_info.led = HPC_ACTIVE_LED; else return (CFGA_INVAL); len = strlen(func_strs[MODE]); if ((strncmp(str, func_strs[MODE], len) == 0) && (*(str+(len)) == '=')) { for (str = (str+(++len)), i = 0; *str != NULL; i++, str++) { buf[i] = *str; } } buf[i] = '\0'; DBG(2, ("buf_mode= %s\n", buf)); /* ON = 1, OFF = 0 */ if (strcmp(buf, mode_strs[ON]) == 0) led_info.state = HPC_LED_ON; else if (strcmp(buf, mode_strs[OFF]) == 0) led_info.state = HPC_LED_OFF; else if (strcmp(buf, mode_strs[BLINK]) == 0) led_info.state = HPC_LED_BLINK; else return (CFGA_INVAL); /* sendin */ build_control_data(&iocdata, HPC_CTRL_SET_LED_STATE, (void *)&led_info); break; } else if (ptr == '\0') { /* print mode */ DBG(1, ("Print mode\n")); return (prt_led_mode(ap_id, repeat, errstring, msgp)); } /* FALLTHROUGH */ default: DBG(1, ("default\n")); errno = EINVAL; return (CFGA_INVAL); } if ((fd = open(ap_id, O_RDWR)) == -1) { DBG(1, ("open failed\n")); return (CFGA_ERROR); } DBG(1, ("open = ap_id=%s, fd=%d\n", ap_id, fd)); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { DBG(1, ("ioctl failed\n")); (void) close(fd); return (CFGA_ERROR); } (void) close(fd); return (CFGA_OK); } /*ARGSUSED*/ cfga_err_t cfga_test(const char *ap_id, const char *options, struct cfga_msg *msgp, char **errstring, cfga_flags_t flags) { cfga_err_t rv; if (errstring != NULL) *errstring = NULL; if ((rv = check_options(options)) != CFGA_OK) { return (rv); } DBG(1, ("cfga_test:(%s)\n", ap_id)); /* will need to implement pci CTRL command */ return (CFGA_NOTSUPP); } static int fixup_slotname(int rval, int *intp, struct searcharg *slotarg) { /* * The slot-names property describes the external labeling of add-in slots. * This property is an encoded array, an integer followed by a list of * strings. The return value from di_prop_lookup_ints for slot-names is -1. * The expected return value should be the number of elements. * Di_prop_decode_common does not decode encoded data from software, * such as the solaris device tree, unlike from the prom. * Di_prop_decode_common takes the size of the encoded data and mods * it with the size of int. The size of the encoded data for slot-names is 9 * and the size of int is 4, yielding a non zero result. A value of -1 is used * to indicate that the number of elements can not be determined. * Di_prop_decode_common can be modified to decode encoded data from the solaris * device tree. */ if ((slotarg->slt_name_src == PROM_SLT_NAME) && (rval == -1)) { return (DI_WALK_TERMINATE); } else { int i; char *tmptr = (char *)(intp+1); DBG(1, ("slot-bitmask: %x \n", *intp)); rval = (rval -1) * 4; for (i = 0; i <= slotarg->minor; i++) { DBG(2, ("curr slot-name: %s \n", tmptr)); if (i >= MAXDEVS) return (DI_WALK_TERMINATE); if ((*intp >> i) & 1) { /* assign tmptr */ DBG(2, ("slot-name: %s \n", tmptr)); if (i == slotarg->minor) (void) strcpy(slotarg->slotnames[i], tmptr); /* wind tmptr to next \0 */ while (*tmptr != '\0') { tmptr++; } tmptr++; } else { /* point at unknown string */ if (i == slotarg->minor) (void) strcpy(slotarg->slotnames[i], "unknown"); } } } return (DI_WALK_TERMINATE); } static int find_slotname(di_node_t din, di_minor_t dim, void *arg) { struct searcharg *slotarg = (struct searcharg *)arg; di_prom_handle_t ph = (di_prom_handle_t)slotarg->promp; di_prom_prop_t prom_prop; di_prop_t solaris_prop; int *intp, rval; char *devname; char fulldevname[MAXNAMELEN]; slotarg->minor = dim->dev_minor % 256; DBG(2, ("minor number:(%i)\n", slotarg->minor)); DBG(2, ("hot plug slots found so far:(%i)\n", 0)); if ((devname = di_devfs_path(din)) != NULL) { (void) snprintf(fulldevname, MAXNAMELEN, "/devices%s:%s", devname, di_minor_name(dim)); di_devfs_path_free(devname); } if (strcmp(fulldevname, slotarg->devpath) == 0) { /* * Check the Solaris device tree first * in the case of a DR operation */ solaris_prop = di_prop_hw_next(din, DI_PROP_NIL); while (solaris_prop != DI_PROP_NIL) { if (strcmp("slot-names", di_prop_name(solaris_prop)) == 0) { rval = di_prop_lookup_ints(DDI_DEV_T_ANY, din, di_prop_name(solaris_prop), &intp); slotarg->slt_name_src = SOLARIS_SLT_NAME; return (fixup_slotname(rval, intp, slotarg)); } solaris_prop = di_prop_hw_next(din, solaris_prop); } /* * Check the prom device tree which is populated at boot. * If this fails, give up and set the slot name to null. */ prom_prop = di_prom_prop_next(ph, din, DI_PROM_PROP_NIL); while (prom_prop != DI_PROM_PROP_NIL) { if (strcmp("slot-names", di_prom_prop_name(prom_prop)) == 0) { rval = di_prom_prop_lookup_ints(ph, din, di_prom_prop_name(prom_prop), &intp); slotarg->slt_name_src = PROM_SLT_NAME; return (fixup_slotname(rval, intp, slotarg)); } prom_prop = di_prom_prop_next(ph, din, prom_prop); } *slotarg->slotnames[slotarg->minor] = '\0'; return (DI_WALK_TERMINATE); } else return (DI_WALK_CONTINUE); } static int find_physical_slot_names(const char *devcomp, struct searcharg *slotarg) { di_node_t root_node; DBG(1, ("find_physical_slot_names\n")); if ((root_node = di_init("/", DINFOCPYALL|DINFOPATH)) == DI_NODE_NIL) { DBG(1, ("di_init() failed\n")); return (NULL); } slotarg->devpath = (char *)devcomp; if ((slotarg->promp = di_prom_init()) == DI_PROM_HANDLE_NIL) { DBG(1, ("di_prom_init() failed\n")); di_fini(root_node); return (NULL); } (void) di_walk_minor(root_node, "ddi_ctl:attachment_point:pci", 0, (void *)slotarg, find_slotname); di_prom_fini(slotarg->promp); di_fini(root_node); if (slotarg->slotnames[0] != NULL) return (0); else return (-1); } static void get_type(hpc_board_type_t boardtype, hpc_card_info_t cardinfo, char *buf) { int i; DBG(1, ("class: %i\n", cardinfo.base_class)); DBG(1, ("subclass: %i\n", cardinfo.sub_class)); if (cardinfo.base_class == PCI_CLASS_NONE) { TPCT("unknown"); return; } for (i = 0; i < class_pci_items; i++) { if ((cardinfo.base_class == class_pci[i].base_class) && (cardinfo.sub_class == class_pci[i].sub_class) && (cardinfo.prog_class == class_pci[i].prog_class)) { TPCT(class_pci[i].short_desc); break; } } if (i == class_pci_items) TPCT("unknown"); TPCT("/"); switch (boardtype) { case HPC_BOARD_PCI_HOTPLUG: case HPC_BOARD_CPCI_NON_HS: case HPC_BOARD_CPCI_BASIC_HS: case HPC_BOARD_CPCI_FULL_HS: case HPC_BOARD_CPCI_HS: TPCT(board_strs[boardtype]); break; case HPC_BOARD_UNKNOWN: default: TPCT(board_strs[HPC_BOARD_UNKNOWN]); } } /* * call-back function for di_devlink_walk * if the link lives in /dev/cfg copy its name */ static int found_devlink(di_devlink_t link, void *ap_log_id) { if (strncmp("/dev/cfg/", di_devlink_path(link), 9) == 0) { /* copy everything but /dev/cfg/ */ (void) strcpy((char *)ap_log_id, di_devlink_path(link) + 9); DBG(1, ("found_devlink: %s\n", (char *)ap_log_id)); return (DI_WALK_TERMINATE); } return (DI_WALK_CONTINUE); } /* * Walk throught the cached /dev link tree looking for links to the ap * if none are found return an error */ static cfga_err_t check_devlinks(char *ap_log_id, const char *ap_id) { di_devlink_handle_t hdl; DBG(1, ("check_devlinks: %s\n", ap_id)); hdl = di_devlink_init(NULL, 0); if (strncmp("/devices/", ap_id, 9) == 0) { /* ap_id is a valid minor_path with /devices prepended */ (void) di_devlink_walk(hdl, NULL, ap_id + 8, DI_PRIMARY_LINK, (void *)ap_log_id, found_devlink); } else { DBG(1, ("check_devlinks: invalid ap_id: %s\n", ap_id)); return (CFGA_ERROR); } (void) di_devlink_fini(&hdl); if (ap_log_id[0] != '\0') return (CFGA_OK); else return (CFGA_ERROR); } /* * most of this is needed to compensate for * differences between various platforms */ static cfga_err_t fix_ap_name(char *ap_log_id, const char *ap_id, char *slot_name, char **errstring) { char *buf; char *tmp; char *ptr; di_node_t ap_node; ap_log_id[0] = '\0'; if (check_devlinks(ap_log_id, ap_id) == CFGA_OK) return (CFGA_OK); DBG(1, ("fix_ap_name: %s\n", ap_id)); if ((buf = malloc(strlen(ap_id) + 1)) == NULL) { DBG(1, ("malloc failed\n")); return (CFGA_ERROR); } (void) strcpy(buf, ap_id); tmp = buf + sizeof ("/devices") - 1; ptr = strchr(tmp, ':'); ptr[0] = '\0'; DBG(1, ("fix_ap_name: %s\n", tmp)); ap_node = di_init(tmp, DINFOMINOR); if (ap_node == DI_NODE_NIL) { cfga_err(errstring, "di_init ", 0); DBG(1, ("fix_ap_name: failed to snapshot node\n")); return (CFGA_ERROR); } (void) snprintf(ap_log_id, strlen(ap_id) + 1, "%s%i:%s", di_driver_name(ap_node), di_instance(ap_node), slot_name); DBG(1, ("fix_ap_name: %s\n", ap_log_id)); di_fini(ap_node); free(buf); return (CFGA_OK); } static int findlink_cb(di_devlink_t devlink, void *arg) { (*(char **)arg) = strdup(di_devlink_path(devlink)); return (DI_WALK_TERMINATE); } /* * returns an allocated string containing the full path to the devlink for * in the devlink database; we expect only one devlink per * so we return the first encountered */ static char * findlink(char *ap_phys_id) { di_devlink_handle_t hdl; char *path = NULL; hdl = di_devlink_init(NULL, 0); if (strncmp("/devices/", ap_phys_id, 9) == 0) ap_phys_id += 8; (void) di_devlink_walk(hdl, "^cfg/.+$", ap_phys_id, DI_PRIMARY_LINK, (void *)&path, findlink_cb); (void) di_devlink_fini(&hdl); return (path); } /* * returns CFGA_OK if it can succesfully retrieve the devlink info associated * with devlink for which will be returned through */ cfga_err_t get_dli(char *dlpath, char *ap_info, int ap_info_sz) { int fd; fd = di_dli_openr(dlpath); if (fd < 0) return (CFGA_ERROR); (void) read(fd, ap_info, ap_info_sz); ap_info[ap_info_sz - 1] = '\0'; di_dli_close(fd); return (CFGA_OK); } /*ARGSUSED*/ cfga_err_t cfga_list_ext(const char *ap_id, cfga_list_data_t **cs, int *nlist, const char *options, const char *listopts, char **errstring, cfga_flags_t flags) { devctl_hdl_t dcp; struct hpc_control_data iocdata; devctl_ap_state_t state; hpc_board_type_t boardtype; hpc_card_info_t cardinfo; hpc_slot_info_t slot_info; struct searcharg slotname_arg; int fd; int rv = CFGA_OK; char *dlpath = NULL; if ((rv = check_options(options)) != CFGA_OK) { return (rv); } if (errstring != NULL) *errstring = NULL; (void) memset(&slot_info, 0, sizeof (hpc_slot_info_t)); DBG(1, ("cfga_list_ext:(%s)\n", ap_id)); if (cs == NULL || nlist == NULL) { rv = CFGA_ERROR; return (rv); } *nlist = 1; if ((*cs = malloc(sizeof (cfga_list_data_t))) == NULL) { cfga_err(errstring, "malloc ", 0); DBG(1, ("malloc failed\n")); rv = CFGA_ERROR; return (rv); } (void) memset(*cs, 0, sizeof (cfga_list_data_t)); if ((dcp = devctl_ap_acquire((char *)ap_id, 0)) == NULL) { cfga_err(errstring, CMD_GETSTAT, 0); DBG(2, ("cfga_list_ext::(devctl_ap_acquire())\n")); rv = CFGA_ERROR; return (rv); } if (devctl_ap_getstate(dcp, NULL, &state) == -1) { cfga_err(errstring, ERR_AP_ERR, ap_id, 0); devctl_release((devctl_hdl_t)dcp); DBG(2, ("cfga_list_ext::(devctl_ap_getstate())\n")); rv = CFGA_ERROR; return (rv); } switch (state.ap_rstate) { case AP_RSTATE_EMPTY: (*cs)->ap_r_state = CFGA_STAT_EMPTY; DBG(2, ("ap_rstate = CFGA_STAT_EMPTY\n")); break; case AP_RSTATE_DISCONNECTED: (*cs)->ap_r_state = CFGA_STAT_DISCONNECTED; DBG(2, ("ap_rstate = CFGA_STAT_DISCONNECTED\n")); break; case AP_RSTATE_CONNECTED: (*cs)->ap_r_state = CFGA_STAT_CONNECTED; DBG(2, ("ap_rstate = CFGA_STAT_CONNECTED\n")); break; default: cfga_err(errstring, CMD_GETSTAT, ap_id, 0); rv = CFGA_ERROR; devctl_release((devctl_hdl_t)dcp); return (rv); } switch (state.ap_ostate) { case AP_OSTATE_CONFIGURED: (*cs)->ap_o_state = CFGA_STAT_CONFIGURED; DBG(2, ("ap_ostate = CFGA_STAT_CONFIGURED\n")); break; case AP_OSTATE_UNCONFIGURED: (*cs)->ap_o_state = CFGA_STAT_UNCONFIGURED; DBG(2, ("ap_ostate = CFGA_STAT_UNCONFIGURED\n")); break; default: cfga_err(errstring, CMD_GETSTAT, ap_id, 0); rv = CFGA_ERROR; devctl_release((devctl_hdl_t)dcp); return (rv); } switch (state.ap_condition) { case AP_COND_OK: (*cs)->ap_cond = CFGA_COND_OK; DBG(2, ("ap_cond = CFGA_COND_OK\n")); break; case AP_COND_FAILING: (*cs)->ap_cond = CFGA_COND_FAILING; DBG(2, ("ap_cond = CFGA_COND_FAILING\n")); break; case AP_COND_FAILED: (*cs)->ap_cond = CFGA_COND_FAILED; DBG(2, ("ap_cond = CFGA_COND_FAILED\n")); break; case AP_COND_UNUSABLE: (*cs)->ap_cond = CFGA_COND_UNUSABLE; DBG(2, ("ap_cond = CFGA_COND_UNUSABLE\n")); break; case AP_COND_UNKNOWN: (*cs)->ap_cond = CFGA_COND_UNKNOWN; DBG(2, ("ap_cond = CFGA_COND_UNKNOW\n")); break; default: cfga_err(errstring, CMD_GETSTAT, ap_id, 0); rv = CFGA_ERROR; devctl_release((devctl_hdl_t)dcp); return (rv); } (*cs)->ap_busy = (int)state.ap_in_transition; devctl_release((devctl_hdl_t)dcp); if ((fd = open(ap_id, O_RDWR)) == -1) { cfga_err(errstring, ERR_AP_ERR, ap_id, 0); (*cs)->ap_status_time = 0; boardtype = HPC_BOARD_UNKNOWN; cardinfo.base_class = PCI_CLASS_NONE; get_logical_name(ap_id, slot_info.pci_slot_name, 0); DBG(2, ("open on %s failed\n", ap_id)); goto cont; } DBG(1, ("open = ap_id=%s, fd=%d\n", ap_id, fd)); (*cs)->ap_status_time = state.ap_last_change; /* need board type and a way to get to hpc_slot_info */ build_control_data(&iocdata, HPC_CTRL_GET_BOARD_TYPE, (void *)&boardtype); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { boardtype = HPC_BOARD_UNKNOWN; } DBG(1, ("ioctl boardtype\n")); build_control_data(&iocdata, HPC_CTRL_GET_SLOT_INFO, (void *)&slot_info); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { get_logical_name(ap_id, slot_info.pci_slot_name, 0); DBG(1, ("ioctl failed slotinfo: %s\n", slot_info.pci_slot_name)); } else { /* * the driver will report back things like hpc0_slot0 * this needs to be changed to things like pci1:hpc0_slot0 */ rv = fix_ap_name((*cs)->ap_log_id, ap_id, slot_info.pci_slot_name, errstring); DBG(1, ("ioctl slotinfo: %s\n", (*cs)->ap_log_id)); } build_control_data(&iocdata, HPC_CTRL_GET_CARD_INFO, (void *)&cardinfo); if (ioctl(fd, DEVCTL_AP_CONTROL, &iocdata) == -1) { DBG(1, ("ioctl failed\n")); cardinfo.base_class = PCI_CLASS_NONE; } DBG(1, ("ioctl cardinfo: %d\n", cardinfo.base_class)); DBG(1, ("ioctl subclass: %d\n", cardinfo.sub_class)); DBG(1, ("ioctl headertype: %d\n", cardinfo.header_type)); (void) close(fd); cont: (void) strcpy((*cs)->ap_phys_id, ap_id); /* physical path of AP */ dlpath = findlink((*cs)->ap_phys_id); if (dlpath != NULL) { if (get_dli(dlpath, (*cs)->ap_info, sizeof ((*cs)->ap_info)) != CFGA_OK) (*cs)->ap_info[0] = '\0'; free(dlpath); } if ((*cs)->ap_log_id[0] == '\0') (void) strcpy((*cs)->ap_log_id, slot_info.pci_slot_name); if ((*cs)->ap_info[0] == '\0') { /* slot_names of bus node */ if (find_physical_slot_names(ap_id, &slotname_arg) != -1) (void) strcpy((*cs)->ap_info, slotname_arg.slotnames[slotname_arg.minor]); } /* class_code/subclass/boardtype */ get_type(boardtype, cardinfo, (*cs)->ap_type); DBG(1, ("cfga_list_ext return success\n")); rv = CFGA_OK; return (rv); } /* * This routine prints a single line of help message */ static void cfga_msg(struct cfga_msg *msgp, const char *str) { DBG(2, ("<%s>", str)); if (msgp == NULL || msgp->message_routine == NULL) return; (*msgp->message_routine)(msgp->appdata_ptr, str); (*msgp->message_routine)(msgp->appdata_ptr, "\n"); } static cfga_err_t check_options(const char *options) { struct cfga_msg *msgp = NULL; if (options) { cfga_msg(msgp, dgettext(TEXT_DOMAIN, cfga_strs[HELP_UNKNOWN])); cfga_msg(msgp, options); return (CFGA_INVAL); } return (CFGA_OK); } /*ARGSUSED*/ cfga_err_t cfga_help(struct cfga_msg *msgp, const char *options, cfga_flags_t flags) { if (options) { cfga_msg(msgp, dgettext(TEXT_DOMAIN, cfga_strs[HELP_UNKNOWN])); cfga_msg(msgp, options); } DBG(1, ("cfga_help\n")); cfga_msg(msgp, dgettext(TEXT_DOMAIN, cfga_strs[HELP_HEADER])); cfga_msg(msgp, cfga_strs[HELP_CONFIG]); cfga_msg(msgp, cfga_strs[HELP_ENABLE_SLOT]); cfga_msg(msgp, cfga_strs[HELP_DISABLE_SLOT]); cfga_msg(msgp, cfga_strs[HELP_ENABLE_AUTOCONF]); cfga_msg(msgp, cfga_strs[HELP_DISABLE_AUTOCONF]); cfga_msg(msgp, cfga_strs[HELP_LED_CNTRL]); return (CFGA_OK); } /* * cfga_err() accepts a variable number of message IDs and constructs * a corresponding error string which is returned via the errstring argument. * cfga_err() calls gettext() to internationalize proper messages. */ static void cfga_err(char **errstring, ...) { int a; int i; int n; int len; int flen; char *p; char *q; char *s[32]; char *failed; va_list ap; /* * If errstring is null it means user in not interested in getting * error status. So we don't do all the work */ if (errstring == NULL) { return; } va_start(ap, errstring); failed = dgettext(TEXT_DOMAIN, cfga_strs[FAILED]); flen = strlen(failed); for (n = len = 0; (a = va_arg(ap, int)) != 0; n++) { switch (a) { case CMD_GETSTAT: case CMD_LIST: case CMD_SLOT_CONNECT: case CMD_SLOT_DISCONNECT: case CMD_SLOT_CONFIGURE: case CMD_SLOT_UNCONFIGURE: p = cfga_errstrs(a); len += (strlen(p) + flen); s[n] = p; s[++n] = cfga_strs[FAILED]; DBG(2, ("<%s>", p)); DBG(2, (cfga_strs[FAILED])); break; case ERR_CMD_INVAL: case ERR_AP_INVAL: case ERR_OPT_INVAL: case ERR_AP_ERR: switch (a) { case ERR_CMD_INVAL: p = dgettext(TEXT_DOMAIN, cfga_errstrs[ERR_CMD_INVAL]); break; case ERR_AP_INVAL: p = dgettext(TEXT_DOMAIN, cfga_errstrs[ERR_AP_INVAL]); break; case ERR_OPT_INVAL: p = dgettext(TEXT_DOMAIN, cfga_errstrs[ERR_OPT_INVAL]); break; case ERR_AP_ERR: p = dgettext(TEXT_DOMAIN, cfga_errstrs[ERR_AP_ERR]); break; } if ((q = va_arg(ap, char *)) != NULL) { len += (strlen(p) + strlen(q)); s[n] = p; s[++n] = q; DBG(2, ("<%s>", p)); DBG(2, ("<%s>", q)); break; } else { len += strlen(p); s[n] = p; } DBG(2, ("<%s>", p)); break; default: n--; break; } } DBG(2, ("\n")); va_end(ap); if ((p = calloc(len + 1, 1)) == NULL) return; for (i = 0; i < n; i++) { (void) strlcat(p, s[i], len + 1); DBG(2, ("i:%d, %s\n", i, s[i])); } *errstring = p; #ifdef DEBUG printf("%s\n", *errstring); free(*errstring); #endif } /* * cfga_ap_id_cmp -- use default_ap_id_cmp() in libcfgadm */