/* * 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. */ #define LUX_SF_INST_SHIFT4MINOR 6 #define LUX_SF_MINOR2INST(x) (x >> LUX_SF_INST_SHIFT4MINOR) #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* For password */ #include #include #include #include #include #include #include #include #include #include "common.h" extern char *dtype[]; extern char *whoami; extern int Options; extern const int OPTION_A; extern const int OPTION_B; extern const int OPTION_C; extern const int OPTION_D; extern const int OPTION_E; extern const int OPTION_F; extern const int OPTION_L; extern const int OPTION_P; extern const int OPTION_R; extern const int OPTION_T; extern const int OPTION_V; extern const int OPTION_Z; extern const int OPTION_Y; extern const int OPTION_CAPF; extern const int PVERBOSE; extern const int SAVE; extern const int EXPERT; static struct termios termios; static int termio_fd; static void pho_display_config(char *); static void dpm_display_config(char *); static void n_rem_list_entry(uchar_t, struct gfc_map *, WWN_list **); static void n_rem_list_entry_fabric(int, struct gfc_map *, WWN_list **); static void n_rem_wwn_entry(uchar_t *, WWN_list **); static void display_disk_info(L_inquiry, L_disk_state, Path_struct *, struct mode_page *, int, char *, int); static void display_lun_info(L_disk_state, Path_struct *, struct mode_page *, int, WWN_list *, char *); static void display_fc_disk(struct path_struct *, char *, gfc_map_t *, L_inquiry, int); static void adm_display_err(char *, int); static void temperature_messages(struct l_state_struct *, int); static void ctlr_messages(struct l_state_struct *, int, int); static void fan_messages(struct l_state_struct *, int, int); static void ps_messages(struct l_state_struct *, int, int); static void abnormal_condition_display(struct l_state_struct *); static void loop_messages(struct l_state_struct *, int, int); static void revision_msg(struct l_state_struct *, int); static void mb_messages(struct l_state_struct *, int, int); static void back_plane_messages(struct l_state_struct *, int, int); static void dpm_SSC100_messages(struct l_state_struct *, int, int); static void mb_messages(struct l_state_struct *, int, int); static void back_plane_messages(struct l_state_struct *, int, int); static void dpm_SSC100_messages(struct l_state_struct *, int, int); static void trans_decode(Trans_elem_st *trans); static void trans_messages(struct l_state_struct *, int); static void adm_print_pathlist(char *); static void display_path_info(char *, char *, WWN_list *); static void copy_wwn_data_to_str(char *, const uchar_t *); static void adm_mplist_free(struct mplist_struct *); static int lun_display(Path_struct *path_struct, L_inquiry inq_struct, int verbose); static int non_encl_fc_disk_display(Path_struct *path_struct, L_inquiry inq_struct, int verbose); static int get_enclStatus(char *phys_path, char *encl_name, int off_flag); static int get_host_controller_pwwn(char *hba_path, uchar_t *pwwn); static int get_lun_capacity(char *devpath, struct scsi_capacity_16 *cap_data); static int get_path_status(char *devpath, int *status); static int get_FC4_host_controller_pwwn(char *hba_path, uchar_t *pwwn); /* * Gets the device's state from the SENA IB and * checks whether device is offlined, bypassed * or if the slot is empty and prints it to the * stdout. * * RETURNS: * 0 O.K. * non-zero otherwise */ int print_devState(char *devname, char *ppath, int fr_flag, int slot, int verbose_flag) { L_state l_state; int err; int i, elem_index = 0; uchar_t device_off, ib_status_code, bypass_a_en, bypass_b_en; Bp_elem_st bpf, bpr; if ((err = l_get_status(ppath, &l_state, verbose_flag)) != 0) { (void) print_errString(err, ppath); return (err); } for (i = 0; i < (int)l_state.ib_tbl.config.enc_num_elem; i++) { elem_index++; if (l_state.ib_tbl.config.type_hdr[i].type == ELM_TYP_BP) { break; } elem_index += l_state.ib_tbl.config.type_hdr[i].num; } (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index]), (void *)&bpf, sizeof (bpf)); (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index + 1]), (void *)&bpr, sizeof (bpr)); if (fr_flag) { device_off = l_state.drv_front[slot].ib_status.dev_off; bypass_a_en = l_state.drv_front[slot].ib_status.bypass_a_en; bypass_b_en = l_state.drv_front[slot].ib_status.bypass_b_en; ib_status_code = l_state.drv_front[slot].ib_status.code; } else { device_off = l_state.drv_rear[slot].ib_status.dev_off; bypass_a_en = l_state.drv_rear[slot].ib_status.bypass_a_en; bypass_b_en = l_state.drv_rear[slot].ib_status.bypass_b_en; ib_status_code = l_state.drv_rear[slot].ib_status.code; } if (device_off) { (void) fprintf(stdout, MSGSTR(2000, "%s is offlined and bypassed.\n" " Could not get device specific" " information.\n\n"), devname); } else if (bypass_a_en && bypass_b_en) { (void) fprintf(stdout, MSGSTR(2001, "%s is bypassed (Port:AB).\n" " Could not get device specific" " information.\n\n"), devname); } else if (ib_status_code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(2002, "Slot %s is empty.\n\n"), devname); } else if (((bpf.code != S_NOT_INSTALLED) && ((bpf.byp_a_enabled || bpf.en_bypass_a) && (bpf.byp_b_enabled || bpf.en_bypass_b))) || ((bpr.code != S_NOT_INSTALLED) && ((bpr.byp_a_enabled || bpr.en_bypass_a) && (bpr.byp_b_enabled || bpr.en_bypass_b)))) { (void) fprintf(stdout, MSGSTR(2003, "Backplane(Port:AB) is bypassed.\n" " Could not get device specific" " information for" " %s.\n\n"), devname); } else { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), devname); } return (-1); } /* * Given an error number, this functions * calls the get_errString() to print a * corresponding error message to the stderr. * get_errString() always returns an error * message, even in case of undefined error number. * So, there is no need to check for a NULL pointer * while printing the error message to the stdout. * * RETURNS: N/A * */ void print_errString(int errnum, char *devpath) { char *errStr; errStr = g_get_errString(errnum); if (devpath == NULL) { (void) fprintf(stderr, "%s \n\n", errStr); } else { (void) fprintf(stderr, "%s - %s.\n\n", errStr, devpath); } /* free the allocated memory for error string */ if (errStr != NULL) (void) free(errStr); } /* * adm_inquiry() Display the inquiry information for * a SENA enclosure(s) or disk(s). * * RETURNS: * none. */ int adm_inquiry(char **argv) { L_inquiry inq; L_inquiry80 inq80; size_t serial_len; int path_index = 0, retval = 0; int slot, f_r, err = 0, argpwwn, argnwwn; char inq_path[MAXNAMELEN]; char *path_phys = NULL, *ptr; Path_struct *path_struct; WWN_list *wwn_list, *wwn_list_ptr, *list_start; char last_logical_path[MAXPATHLEN]; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) strcpy(inq_path, argv[path_index]); if (((ptr = strstr(inq_path, ",")) != NULL) && ((*(ptr + 1) == 'f') || (*(ptr + 1) == 'r') || (*(ptr +1) == 's'))) { if (err != -1) { (void) print_errString(err, argv[path_index]); path_index++; retval++; continue; } *ptr = '\0'; slot = path_struct->slot; f_r = path_struct->f_flag; path_phys = NULL; if ((err = l_convert_name(inq_path, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } path_index++; retval++; continue; } if ((err = print_devState(argv[path_index], path_struct->p_physical_path, f_r, slot, Options & PVERBOSE)) != 0) { path_index++; retval++; continue; } } else { if (err != -1) { (void) print_errString(err, argv[path_index]); } else { (void) fprintf(stderr, "\n "); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), argv[path_index]); (void) fprintf(stderr, "\n"); } } path_index++; retval++; continue; } if (strstr(argv[path_index], "/") != NULL) { if (err = g_get_inquiry(path_phys, &inq)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); path_index++; retval++; continue; } serial_len = sizeof (inq80.inq_serial); if (err = g_get_serial_number(path_phys, inq80.inq_serial, &serial_len)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); path_index++; retval++; continue; } print_inq_data(argv[path_index], path_phys, inq, inq80.inq_serial, serial_len); path_index++; continue; } if ((err = g_get_wwn_list(&wwn_list, 0)) != 0) { return (err); } g_sort_wwn_list(&wwn_list); list_start = wwn_list; argpwwn = argnwwn = 0; (void) strcpy(last_logical_path, path_phys); for (wwn_list_ptr = wwn_list; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argpwwn = 1; break; } else if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argnwwn = 1; break; } } if (!(argpwwn || argnwwn)) { /* * if the wwn list is null or the arg device not found * from the wwn list, still go ahead to issue inquiry. */ if (err = g_get_inquiry(path_phys, &inq)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); path_index++; retval++; continue; } serial_len = sizeof (inq80.inq_serial); if (err = g_get_serial_number(path_phys, inq80.inq_serial, &serial_len)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); path_index++; retval++; continue; } print_inq_data(argv[path_index], path_phys, inq, inq80.inq_serial, serial_len); (void) g_free_wwn_list(&wwn_list); path_index++; continue; } for (wwn_list_ptr = list_start; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (argpwwn) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) != 0) { continue; } (void) strcpy(path_phys, wwn_list_ptr->physical_path); } else if (argnwwn) { if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) != 0) { continue; } if (strstr(wwn_list_ptr->logical_path, last_logical_path) != NULL) { continue; } (void) strcpy(path_phys, wwn_list_ptr->physical_path); (void) strcpy(last_logical_path, wwn_list_ptr->logical_path); } if (err = g_get_inquiry(path_phys, &inq)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); retval++; break; } serial_len = sizeof (inq80.inq_serial); if (err = g_get_serial_number(path_phys, inq80.inq_serial, &serial_len)) { (void) fprintf(stderr, "\n"); (void) print_errString(err, argv[path_index]); (void) fprintf(stderr, "\n"); retval++; break; } print_inq_data(argv[path_index], path_phys, inq, inq80.inq_serial, serial_len); } (void) g_free_wwn_list(&wwn_list); path_index++; } return (retval); } /* * FORCELIP expert function */ int adm_forcelip(char **argv) { int slot, f_r, path_index = 0, err = 0, retval = 0; Path_struct *path_struct = NULL; char *path_phys = NULL, *ptr; char err_path[MAXNAMELEN]; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) strcpy(err_path, argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); path_index++; retval++; continue; } if (((ptr = strstr(err_path, ", ")) != NULL) && ((*(ptr + 1) == 'f') || (*(ptr + 1) == 'r') || (*(ptr +1) == 's'))) { *ptr = '\0'; slot = path_struct->slot; f_r = path_struct->f_flag; path_phys = NULL; if ((err = l_convert_name(err_path, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } path_index++; retval++; continue; } if ((err = print_devState(argv[path_index], path_struct->p_physical_path, f_r, slot, Options & PVERBOSE)) != 0) { path_index++; retval++; continue; } } else { (void) fprintf(stderr, "\n "); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), argv[path_index]); (void) fprintf(stderr, "\n"); } path_index++; retval++; continue; } if (err = g_force_lip(path_phys, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); path_index++; retval++; continue; } path_index++; if (path_struct != NULL) { (void) free(path_struct); } } return (retval); } /* * DISPLAY function * * RETURNS: * 0 O.K. */ int adm_display_config(char **argv) { L_inquiry inq, ses_inq; int i, slot, f_r, path_index = 0, err = 0, opnerr = 0; int retval = 0; gfc_map_t map; Path_struct *path_struct; char *path_phys = NULL, *ptr; char ses_path[MAXPATHLEN], inq_path[MAXNAMELEN]; while (argv[path_index] != NULL) { VERBPRINT(MSGSTR(2108, " Displaying information for: %s\n"), argv[path_index]); map.dev_addr = (gfc_port_dev_info_t *)NULL; if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { if (strstr(argv[path_index], SCSI_VHCI) == NULL) { (void) strcpy(inq_path, argv[path_index]); if (((ptr = strstr(inq_path, ",")) != NULL) && ((*(ptr + 1) == 'f') || (*(ptr + 1) == 'r') || (*(ptr +1) == 's'))) { if (err != -1) { (void) print_errString(err, argv[path_index]); path_index++; retval++; continue; } *ptr = '\0'; slot = path_struct->slot; f_r = path_struct->f_flag; if ((err = l_convert_name(inq_path, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } path_index++; retval++; continue; } if ((err = print_devState(argv[path_index], path_struct->p_physical_path, f_r, slot, Options & PVERBOSE)) != 0) { path_index++; retval++; continue; } } else { if (err != -1) { (void) print_errString(err, argv[path_index]); } else { (void) fprintf(stderr, "\n "); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), argv[path_index]); (void) fprintf(stderr, "\n"); } } } else { if (err != -1) { (void) print_errString(err, argv[path_index]); } else { (void) fprintf(stderr, "\n "); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), argv[path_index]); (void) fprintf(stderr, "\n"); } } path_index++; retval++; continue; } /* * See what kind of device we are talking to. */ if ((opnerr = g_get_inquiry(path_phys, &inq)) != 0) { if (opnerr == L_OPEN_PATH_FAIL) { /* * We check only for L_OPEN_PATH_FAIL because * that is the only error code returned by * g_get_inquiry() which is not got from the ioctl * call itself. So, we are dependent, in a way, on the * implementation of g_get_inquiry(). * */ (void) print_errString(errno, argv[path_index]); path_index++; retval++; continue; } } else if (!g_enclDiskChk((char *)inq.inq_vid, (char *)inq.inq_pid)) { if ((err = lun_display(path_struct, inq, Options & PVERBOSE)) != 0) { (void) print_errString(err, path_phys); exit(1); } } else if (strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) != NULL) { /* * Display SENA enclosure. */ (void) fprintf(stdout, "\n\t\t\t\t "); print_chars(inq.inq_pid, sizeof (inq.inq_pid), 0); (void) fprintf(stdout, "\n"); if (Options & OPTION_R) { adm_display_err(path_phys, (inq.inq_dtype & DTYPE_MASK)); } else { pho_display_config(path_phys); } } else if ((((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI)) && (l_get_enc_type(inq) == DAK_ENC_TYPE)) { /* * Display for the Daktari/DPM */ (void) fprintf(stdout, "\n\t\t"); for (i = 0; i < sizeof (inq.inq_pid); i++) { (void) fprintf(stdout, "%c", inq.inq_pid[i]); } (void) fprintf(stdout, "\n"); if (Options & OPTION_R) { adm_display_err(path_phys, (inq.inq_dtype & DTYPE_MASK)); } else { dpm_display_config(path_phys); } /* * if device is in SENA enclosure * * if the slot is valid, then I know this is a SENA enclosure * and can continue * otherwise: * I first get the ses_path, if this doesn't fail * I retrieve the inquiry data from the ses node * and check teh PID to make sure this is a SENA */ } else if (((inq.inq_dtype & DTYPE_MASK) == DTYPE_DIRECT) && ((path_struct->slot_valid == 1) || ((g_get_dev_map(path_phys, &map, (Options & PVERBOSE)) == 0) && (l_get_ses_path(path_phys, ses_path, &map, Options & PVERBOSE) == 0) && (g_get_inquiry(ses_path, &ses_inq) == 0) && ((strstr((char *)ses_inq.inq_pid, ENCLOSURE_PROD_ID) != NULL))))) { if (Options & OPTION_R) { adm_display_err(path_phys, (inq.inq_dtype & DTYPE_MASK)); } else { display_fc_disk(path_struct, ses_path, &map, inq, Options & PVERBOSE); } } else if (strstr((char *)inq.inq_pid, "SUN_SEN") != 0) { if (strcmp(argv[path_index], path_phys) != 0) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(5, "Physical Path:")); (void) fprintf(stdout, "\n %s\n", path_phys); } (void) fprintf(stdout, MSGSTR(2109, "DEVICE is a ")); print_chars(inq.inq_vid, sizeof (inq.inq_vid), 1); (void) fprintf(stdout, " "); print_chars(inq.inq_pid, sizeof (inq.inq_pid), 1); (void) fprintf(stdout, MSGSTR(2110, " card.")); if (inq.inq_len > 31) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(26, "Revision:")); (void) fprintf(stdout, " "); print_chars(inq.inq_revision, sizeof (inq.inq_revision), 0); } (void) fprintf(stdout, "\n"); /* if device is not in SENA or SSA enclosures. */ } else if ((inq.inq_dtype & DTYPE_MASK) < 0x10) { switch ((inq.inq_dtype & DTYPE_MASK)) { case DTYPE_DIRECT: case DTYPE_SEQUENTIAL: /* Tape */ if (Options & OPTION_R) { adm_display_err(path_phys, (inq.inq_dtype & DTYPE_MASK)); } else if (non_encl_fc_disk_display(path_struct, inq, Options & PVERBOSE) != 0) { (void) fprintf(stderr, MSGSTR(2111, "Error: getting the device" " information.\n")); retval++; } break; /* case 0x01: same as default */ default: (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(35, "Device Type:")); (void) fprintf(stdout, "%s\n", dtype[inq.inq_dtype & DTYPE_MASK]); break; } } else if ((inq.inq_dtype & DTYPE_MASK) < 0x1f) { (void) fprintf(stdout, MSGSTR(2112, " Device type: Reserved")); (void) fprintf(stdout, "\n"); } else { (void) fprintf(stdout, MSGSTR(2113, " Device type: Unknown device")); (void) fprintf(stdout, "\n"); } path_index++; if (map.dev_addr != NULL) { free((void *)map.dev_addr); } (void) free(path_struct); } return (retval); } /* * Powers off a list of SENA enclosure(s) * and disk(s) which is provided by the user. * * RETURNS: * none. */ int adm_power_off(char **argv, int off_flag) { int path_index = 0, err = 0, retval = 0; L_inquiry inq; char *path_phys = NULL; Path_struct *path_struct; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { /* * In case we did not find the device * in the /devices directory. * * Only valid for pathnames like box,f1 */ if (path_struct->ib_path_flag) { path_phys = path_struct->p_physical_path; } else { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } path_index++; retval++; continue; } } if (path_struct->ib_path_flag) { /* * We are addressing a disk using a path * format type box,f1. */ if (err = l_dev_pwr_up_down(path_phys, path_struct, off_flag, Options & PVERBOSE, Options & OPTION_CAPF)) { /* * Is it Bypassed... try to give more * informtaion. */ print_devState(argv[path_index], path_struct->p_physical_path, path_struct->f_flag, path_struct->slot, Options & PVERBOSE); retval++; } path_index++; continue; } if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); path_index++; retval++; continue; } if ((strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) != 0) || (strncmp((char *)inq.inq_vid, "SUN ", sizeof (inq.inq_vid)) && ((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI))) { if (get_enclStatus(path_phys, argv[path_index], off_flag) != 0) { path_index++; retval++; continue; } /* power off SENA enclosure. */ if (err = l_pho_pwr_up_down(argv[path_index], path_phys, off_flag, Options & PVERBOSE, Options & OPTION_CAPF)) { (void) print_errString(err, argv[path_index]); retval++; } } else if ((inq.inq_dtype & DTYPE_MASK) == DTYPE_DIRECT) { if (err = l_dev_pwr_up_down(path_phys, path_struct, off_flag, Options & PVERBOSE, Options & OPTION_CAPF)) { (void) print_errString(err, argv[path_index]); retval++; } } else { /* * SSA section: */ (void) print_errString(L_INVALID_PATH, argv[path_index]); } path_index++; } return (retval); } void adm_bypass_enable(char **argv, int bypass_flag) { int path_index = 0, err = 0; L_inquiry inq; char *path_phys = NULL; Path_struct *path_struct; if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { /* * In case we did not find the device * in the /devices directory. * * Only valid for pathnames like box,f1 */ if (path_struct->ib_path_flag) { path_phys = path_struct->p_physical_path; } else { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } } if (path_struct->ib_path_flag) { if (Options & OPTION_F) { E_USEAGE(); exit(-1); } /* * We are addressing a disk using a path * format type box,f1 and no disk * path was found. * So set the Force flag so no reserved/busy * check is performed. */ if (err = l_dev_bypass_enable(path_struct, bypass_flag, OPTION_CAPF, Options & OPTION_A, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); exit(-1); } return; } if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) != 0) || (strncmp((char *)inq.inq_vid, "SUN ", sizeof (inq.inq_vid)) && ((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI))) { if ((!((Options & OPTION_F) || (Options & OPTION_R))) || ((Options & OPTION_R) && (Options & OPTION_F))) { E_USEAGE(); exit(-1); } if (err = l_bp_bypass_enable(path_phys, bypass_flag, Options & OPTION_A, Options & OPTION_F, Options & OPTION_CAPF, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); exit(-1); } } else if ((inq.inq_dtype & DTYPE_MASK) == DTYPE_DIRECT) { if (Options & OPTION_F) { E_USEAGE(); exit(-1); } if (err = l_dev_bypass_enable(path_struct, bypass_flag, Options & OPTION_CAPF, Options & OPTION_A, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); exit(-1); } } } /* * adm_download() Download subsystem microcode. * Path must point to a LUX IB. * * RETURNS: * None. */ void adm_download(char **argv, char *file_name) { int path_index = 0, err = 0; char *path_phys = NULL; L_inquiry inq; Path_struct *path_struct; while (argv[path_index] != NULL) { /* * See what kind of device we are talking to. */ if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) != 0) || (strncmp((char *)inq.inq_vid, "SUN ", sizeof (inq.inq_vid)) && ((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI))) { if (err = l_download(path_phys, file_name, (Options & SAVE), (Options & PVERBOSE))) { (void) print_errString(err, (err == L_OPEN_PATH_FAIL) ? argv[path_index]: file_name); exit(-1); } } else { (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), argv[path_index]); } path_index++; } } /* * display_link_status() Reads and displays the link status. * * RETURNS: * none. */ void display_link_status(char **argv) { AL_rls *rls = NULL, *n; int path_index = 0, err = 0; char *path_phys = NULL; Path_struct *path_struct; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } if (err = g_rdls(path_phys, &rls, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); exit(-1); } n = rls; if (n != NULL) { (void) fprintf(stdout, MSGSTR(2007, "\nLink Error Status " "information for loop:%s\n"), n->driver_path); (void) fprintf(stdout, MSGSTR(2008, "al_pa lnk fail " " sync loss signal loss sequence err" " invalid word CRC\n")); } while (n) { if ((n->payload.rls_linkfail == 0xffffffff) && (n->payload.rls_syncfail == 0xffffffff) && (n->payload.rls_sigfail == 0xffffffff) && (n->payload.rls_primitiverr == 0xffffffff) && (n->payload.rls_invalidword == 0xffffffff) && (n->payload.rls_invalidcrc == 0xffffffff)) { (void) fprintf(stdout, "%x\t%-12d%-12d%-14d%-15d%-15d%-12d\n", n->al_ha, n->payload.rls_linkfail, n->payload.rls_syncfail, n->payload.rls_sigfail, n->payload.rls_primitiverr, n->payload.rls_invalidword, n->payload.rls_invalidcrc); } else { (void) fprintf(stdout, "%x\t%-12u%-12u%-14u%-15u%-15u%-12u\n", n->al_ha, n->payload.rls_linkfail, n->payload.rls_syncfail, n->payload.rls_sigfail, n->payload.rls_primitiverr, n->payload.rls_invalidword, n->payload.rls_invalidcrc); } n = n->next; } path_index++; } (void) fprintf(stdout, MSGSTR(2009, "NOTE: These LESB counts are not" " cleared by a reset, only power cycles.\n" "These counts must be compared" " to previously read counts.\n")); } /* * ib_present_chk() Check to see if IB 0 or 1 is present in the box. * * RETURN: * 1 if ib present * 0 otherwise */ int ib_present_chk(struct l_state_struct *l_state, int which_one) { Ctlr_elem_st ctlr; int i; int elem_index = 0; int result = 1; for (i = 0; i < (int)l_state->ib_tbl.config.enc_num_elem; i++) { elem_index++; /* skip global */ if (l_state->ib_tbl.config.type_hdr[i].type == ELM_TYP_IB) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + which_one], (void *)&ctlr, sizeof (ctlr)); if (ctlr.code == S_NOT_INSTALLED) { result = 0; } break; } elem_index += l_state->ib_tbl.config.type_hdr[i].num; } return (result); } /* * print_individual_state() Print individual disk status. * * RETURNS: * none. */ void print_individual_state(int status, int port) { if (status & L_OPEN_FAIL) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(28, "Open Failed")); (void) fprintf(stdout, ") "); } else if (status & L_NOT_READY) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(20, "Not Ready")); (void) fprintf(stdout, ") "); } else if (status & L_NOT_READABLE) { (void) fprintf(stdout, "("); (void) fprintf(stdout, MSGSTR(88, "Not Readable")); (void) fprintf(stdout, ") "); } else if (status & L_SPUN_DWN_D) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(68, "Spun Down")); (void) fprintf(stdout, ") "); } else if (status & L_SCSI_ERR) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(70, "SCSI Error")); (void) fprintf(stdout, ") "); } else if (status & L_RESERVED) { if (port == PORT_A) { (void) fprintf(stdout, MSGSTR(2010, " (Rsrv cnflt:A) ")); } else if (port == PORT_B) { (void) fprintf(stdout, MSGSTR(2011, " (Rsrv cnflt:B) ")); } else { (void) fprintf(stdout, MSGSTR(2012, " (Reserve cnflt)")); } } else if (status & L_NO_LABEL) { (void) fprintf(stdout, "("); (void) fprintf(stdout, MSGSTR(92, "No UNIX Label")); (void) fprintf(stdout, ") "); } } /* * display_disk_msg() Displays status for * an individual SENA device. * * RETURNS: * none. */ void display_disk_msg(struct l_disk_state_struct *dsk_ptr, struct l_state_struct *l_state, Bp_elem_st *bp, int front_flag) { int loop_flag = 0; int a_and_b = 0; int state_a = 0, state_b = 0; if (dsk_ptr->ib_status.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); (void) fprintf(stdout, " "); if (dsk_ptr->ib_status.fault || dsk_ptr->ib_status.fault_req) { (void) fprintf(stdout, "("); (void) fprintf(stdout, MSGSTR(2013, "Faulted")); (void) fprintf(stdout, ") "); } else if (dsk_ptr->ib_status.ident || dsk_ptr->ib_status.rdy_to_ins || dsk_ptr->ib_status.rmv) { (void) fprintf(stdout, MSGSTR(2014, "(LED Blinking) ")); } else { (void) fprintf(stdout, " "); } } else if (dsk_ptr->ib_status.dev_off) { (void) fprintf(stdout, MSGSTR(2015, "Off")); if (dsk_ptr->ib_status.fault || dsk_ptr->ib_status.fault_req) { (void) fprintf(stdout, "("); (void) fprintf(stdout, MSGSTR(2016, "Faulted")); (void) fprintf(stdout, ") "); } else if (dsk_ptr->ib_status.bypass_a_en && dsk_ptr->ib_status.bypass_b_en) { (void) fprintf(stdout, MSGSTR(2017, "(Bypassed:AB)")); (void) fprintf(stdout, " "); } else if (dsk_ptr->ib_status.bypass_a_en) { (void) fprintf(stdout, MSGSTR(2018, "(Bypassed: A)")); (void) fprintf(stdout, " "); } else if (dsk_ptr->ib_status.bypass_b_en) { (void) fprintf(stdout, MSGSTR(2019, "(Bypassed: B)")); (void) fprintf(stdout, " "); } else { (void) fprintf(stdout, " "); } } else { (void) fprintf(stdout, MSGSTR(2020, "On")); if (dsk_ptr->ib_status.fault || dsk_ptr->ib_status.fault_req) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(2021, "Faulted")); (void) fprintf(stdout, ") "); } else if (dsk_ptr->ib_status.bypass_a_en && dsk_ptr->ib_status.bypass_b_en) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(2022, "(Bypassed:AB)")); (void) fprintf(stdout, " "); } else if (ib_present_chk(l_state, 0) && dsk_ptr->ib_status.bypass_a_en) { /* * Before printing that the port is bypassed * verify that there is an IB for this port. * If not then don't print. */ (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(2023, "(Bypassed: A)")); (void) fprintf(stdout, " "); } else if (ib_present_chk(l_state, 1) && dsk_ptr->ib_status.bypass_b_en) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(2024, "(Bypassed: B)")); (void) fprintf(stdout, " "); } else if ((bp->code != S_NOT_INSTALLED) && ((bp->byp_a_enabled || bp->en_bypass_a) && !(bp->byp_b_enabled || bp->en_bypass_b))) { (void) fprintf(stdout, MSGSTR(2025, " (Bypassed BP: A)")); } else if ((bp->code != S_NOT_INSTALLED) && ((bp->byp_b_enabled || bp->en_bypass_b) && !(bp->byp_a_enabled || bp->en_bypass_a))) { (void) fprintf(stdout, MSGSTR(2026, "(Bypassed BP: B)")); } else if ((bp->code != S_NOT_INSTALLED) && ((bp->byp_a_enabled || bp->en_bypass_a) && (bp->byp_b_enabled || bp->en_bypass_b))) { (void) fprintf(stdout, MSGSTR(2027, "(Bypassed BP:AB)")); } else { state_a = dsk_ptr->g_disk_state.d_state_flags[PORT_A]; state_b = dsk_ptr->g_disk_state.d_state_flags[PORT_B]; a_and_b = state_a & state_b; if (dsk_ptr->l_state_flag & L_NO_LOOP) { (void) fprintf(stdout, MSGSTR(2028, " (Loop not accessible)")); loop_flag = 1; } else if (dsk_ptr->l_state_flag & L_INVALID_WWN) { (void) fprintf(stdout, MSGSTR(2029, " (Invalid WWN) ")); } else if (dsk_ptr->l_state_flag & L_INVALID_MAP) { (void) fprintf(stdout, MSGSTR(2030, " (Login failed) ")); } else if (dsk_ptr->l_state_flag & L_NO_PATH_FOUND) { (void) fprintf(stdout, MSGSTR(2031, " (No path found)")); } else if (a_and_b) { print_individual_state(a_and_b, PORT_A_B); } else if (state_a && (!state_b)) { print_individual_state(state_a, PORT_A); } else if ((!state_a) && state_b) { print_individual_state(state_b, PORT_B); } else if (state_a || state_b) { /* NOTE: Double state - should do 2 lines. */ print_individual_state(state_a | state_b, PORT_A_B); } else { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(29, "O.K.")); (void) fprintf(stdout, ") "); } } if (loop_flag) { (void) fprintf(stdout, " "); } else if (strlen(dsk_ptr->g_disk_state.node_wwn_s)) { (void) fprintf(stdout, "%s", dsk_ptr->g_disk_state.node_wwn_s); } else { (void) fprintf(stdout, " "); } } if (front_flag) { (void) fprintf(stdout, " "); } } /* * pho_display_config() Displays device status * information for a SENA enclosure. * * RETURNS: * none. */ void pho_display_config(char *path_phys) { L_state l_state; Bp_elem_st bpf, bpr; int i, j, elem_index = 0, err = 0; /* Get global status */ if (err = l_get_status(path_phys, &l_state, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } /* * Look for abnormal status. */ if (l_state.ib_tbl.p2_s.ui.ab_cond) { abnormal_condition_display(&l_state); } (void) fprintf(stdout, MSGSTR(2032, " DISK STATUS \n" "SLOT FRONT DISKS (Node WWN) " " REAR DISKS (Node WWN)\n")); /* * Print the status for each disk */ for (j = 0; j < (int)l_state.ib_tbl.config.enc_num_elem; j++) { elem_index++; if (l_state.ib_tbl.config.type_hdr[j].type == ELM_TYP_BP) break; elem_index += l_state.ib_tbl.config.type_hdr[j].num; } (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index]), (void *)&bpf, sizeof (bpf)); (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index + 1]), (void *)&bpr, sizeof (bpr)); for (i = 0; i < (int)l_state.total_num_drv/2; i++) { (void) fprintf(stdout, "%-2d ", i); display_disk_msg(&l_state.drv_front[i], &l_state, &bpf, 1); display_disk_msg(&l_state.drv_rear[i], &l_state, &bpr, 0); (void) fprintf(stdout, "\n"); } /* * Display the subsystem status. */ (void) fprintf(stdout, MSGSTR(2242, " SUBSYSTEM STATUS\nFW Revision:")); print_chars(l_state.ib_tbl.config.prod_revision, sizeof (l_state.ib_tbl.config.prod_revision), 1); (void) fprintf(stdout, MSGSTR(2034, " Box ID:%d"), l_state.ib_tbl.box_id); (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(90, "Node WWN:")); for (i = 0; i < 8; i++) { (void) fprintf(stdout, "%1.2x", l_state.ib_tbl.config.enc_node_wwn[i]); } /* Make sure NULL terminated although it is supposed to be */ if (strlen((const char *)l_state.ib_tbl.enclosure_name) <= sizeof (l_state.ib_tbl.enclosure_name)) { (void) fprintf(stdout, MSGSTR(2035, " Enclosure Name:%s\n"), l_state.ib_tbl.enclosure_name); } /* * */ elem_index = 0; /* Get and print CONTROLLER messages */ for (i = 0; i < (int)l_state.ib_tbl.config.enc_num_elem; i++) { elem_index++; /* skip global */ switch (l_state.ib_tbl.config.type_hdr[i].type) { case ELM_TYP_PS: ps_messages(&l_state, i, elem_index); break; case ELM_TYP_FT: fan_messages(&l_state, i, elem_index); break; case ELM_TYP_BP: back_plane_messages(&l_state, i, elem_index); break; case ELM_TYP_IB: ctlr_messages(&l_state, i, elem_index); break; case ELM_TYP_LN: /* * NOTE: I just use the Photon's message * string here and don't look at the * language code. The string includes * the language name. */ if (l_state.ib_tbl.config.type_hdr[i].text_len != 0) { (void) fprintf(stdout, "%s\t", l_state.ib_tbl.config.text[i]); } break; case ELM_TYP_LO: /* Loop configuration */ loop_messages(&l_state, i, elem_index); break; case ELM_TYP_MB: /* Loop configuration */ mb_messages(&l_state, i, elem_index); break; } /* * Calculate the index to each element. */ elem_index += l_state.ib_tbl.config.type_hdr[i].num; } (void) fprintf(stdout, "\n"); } /* * dpm_display_config() Displays device status * information for a DAKTARI enclosure. * * RETURNS: * none. */ void dpm_display_config(char *path_phys) { L_state l_state; Bp_elem_st bpf, bpr; int i, j, elem_index = 0, err = 0, count; /* Get global status */ if (err = l_get_status(path_phys, &l_state, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } /* * Look for abnormal status. */ if (l_state.ib_tbl.p2_s.ui.ab_cond) { abnormal_condition_display(&l_state); } (void) fprintf(stdout, MSGSTR(2247, " DISK STATUS \n" "SLOT DISKS (Node WWN) \n")); /* * Print the status for each disk */ for (j = 0; j < (int)l_state.ib_tbl.config.enc_num_elem; j++) { elem_index++; if (l_state.ib_tbl.config.type_hdr[j].type == ELM_TYP_BP) break; elem_index += l_state.ib_tbl.config.type_hdr[j].num; } (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index]), (void *)&bpf, sizeof (bpf)); (void) bcopy((const void *) &(l_state.ib_tbl.p2_s.element[elem_index + 1]), (void *)&bpr, sizeof (bpr)); for (i = 0, count = 0; i < (int)l_state.total_num_drv/2; i++, count++) { (void) fprintf(stdout, "%-2d ", count); display_disk_msg(&l_state.drv_front[i], &l_state, &bpf, 1); (void) fprintf(stdout, "\n"); } for (i = 0; i < (int)l_state.total_num_drv/2; i++, count++) { (void) fprintf(stdout, "%-2d ", count); display_disk_msg(&l_state.drv_rear[i], &l_state, &bpf, 1); (void) fprintf(stdout, "\n"); } /* * Display the subsystem status. */ (void) fprintf(stdout, MSGSTR(2033, "\t\tSUBSYSTEM STATUS\nFW Revision:")); for (i = 0; i < sizeof (l_state.ib_tbl.config.prod_revision); i++) { (void) fprintf(stdout, "%c", l_state.ib_tbl.config.prod_revision[i]); } (void) fprintf(stdout, MSGSTR(2034, " Box ID:%d"), l_state.ib_tbl.box_id); (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(90, "Node WWN:")); for (i = 0; i < 8; i++) { (void) fprintf(stdout, "%1.2x", l_state.ib_tbl.config.enc_node_wwn[i]); } /* Make sure NULL terminated although it is supposed to be */ if (strlen((const char *)l_state.ib_tbl.enclosure_name) <= sizeof (l_state.ib_tbl.enclosure_name)) { (void) fprintf(stdout, MSGSTR(2035, " Enclosure Name:%s\n"), l_state.ib_tbl.enclosure_name); } /* * */ elem_index = 0; /* Get and print CONTROLLER messages */ for (i = 0; i < (int)l_state.ib_tbl.config.enc_num_elem; i++) { elem_index++; /* skip global */ switch (l_state.ib_tbl.config.type_hdr[i].type) { case ELM_TYP_PS: ps_messages(&l_state, i, elem_index); break; case ELM_TYP_FT: fan_messages(&l_state, i, elem_index); break; case ELM_TYP_BP: dpm_SSC100_messages(&l_state, i, elem_index); break; case ELM_TYP_IB: ctlr_messages(&l_state, i, elem_index); break; case ELM_TYP_LN: /* * NOTE: I just use the Photon's message * string here and don't look at the * language code. The string includes * the language name. */ if (l_state.ib_tbl.config.type_hdr[i].text_len != 0) { (void) fprintf(stdout, "%s\t", l_state.ib_tbl.config.text[i]); } break; case ELM_TYP_LO: /* Loop configuration */ loop_messages(&l_state, i, elem_index); break; case ELM_TYP_MB: /* Loop configuration */ mb_messages(&l_state, i, elem_index); break; case ELM_TYP_FL: trans_messages(&l_state, 1); break; } /* * Calculate the index to each element. */ elem_index += l_state.ib_tbl.config.type_hdr[i].num; } (void) fprintf(stdout, "\n"); } /* * Change the FPM (Front Panel Module) password of the * subsystem associated with the IB addressed by the * enclosure or pathname to name. * */ void intfix(void) { if (termio_fd) { termios.c_lflag |= ECHO; ioctl(termio_fd, TCSETS, &termios); } exit(SIGINT); } /* * up_password() Changes the password for SENA enclosure. * * RETURNS: * none. */ void up_password(char **argv) { int path_index = 0, err = 0; char password[1024]; char input[1024]; int i, j, matched, equal; L_inquiry inq; void (*sig)(); char *path_phys = NULL; Path_struct *path_struct; if ((termio_fd = open("/dev/tty", O_RDONLY)) == -1) { (void) fprintf(stderr, MSGSTR(2036, "Error: tty open failed.\n")); exit(-1); } ioctl(termio_fd, TCGETS, &termios); sig = sigset(SIGINT, (void (*)())intfix); /* * Make sure path valid and is to a PHO * before bothering operator. */ if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) == 0) && (!(strncmp((char *)inq.inq_vid, "SUN ", sizeof (inq.inq_vid)) && ((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI)))) { /* * Again this is like the ssaadm code in that the name * is still not defined before this code must be released. */ (void) fprintf(stderr, MSGSTR(2037, "Error: Enclosure is not a %s\n"), ENCLOSURE_PROD_ID); exit(-1); } (void) fprintf(stdout, MSGSTR(2038, "Changing FPM password for subsystem %s\n"), argv[path_index]); equal = 0; while (!equal) { memset(input, 0, sizeof (input)); memset(password, 0, sizeof (password)); (void) fprintf(stdout, MSGSTR(2039, "New password: ")); termios.c_lflag &= ~ECHO; ioctl(termio_fd, TCSETS, &termios); (void) gets(input); (void) fprintf(stdout, MSGSTR(2040, "\nRe-enter new password: ")); (void) gets(password); termios.c_lflag |= ECHO; ioctl(termio_fd, TCSETS, &termios); for (i = 0; input[i]; i++) { if (!isdigit(input[i])) { (void) fprintf(stderr, MSGSTR(2041, "\nError: Invalid password." " The password" " must be 4 decimal-digit characters.\n")); exit(-1); } } if (i && (i != 4)) { (void) fprintf(stderr, MSGSTR(2042, "\nError: Invalid password." " The password" " must be 4 decimal-digit characters.\n")); exit(-1); } for (j = 0; password[j]; j++) { if (!isdigit(password[j])) { (void) fprintf(stderr, MSGSTR(2043, "\nError: Invalid password." " The password" " must be 4 decimal-digit characters.\n")); exit(-1); } } if (i != j) { matched = -1; } else for (i = matched = 0; password[i]; i++) { if (password[i] == input[i]) { matched++; } } if ((matched != -1) && (matched == i)) { equal = 1; } else { (void) fprintf(stdout, MSGSTR(2044, "\npassword: They don't match;" " try again.\n")); } } (void) fprintf(stdout, "\n"); sscanf(input, "%s", password); (void) signal(SIGINT, sig); /* restore signal handler */ /* Send new password to IB */ if (l_new_password(path_phys, input)) { (void) print_errString(err, path_phys); exit(-1); } } /* * Call g_failover to process failover command */ void adm_failover(char **argv) { int path_index = 0, err = 0; char pathclass[20]; char *path_phys = NULL; (void) memset(pathclass, 0, sizeof (pathclass)); (void) strcpy(pathclass, argv[path_index++]); if ((strcmp(pathclass, "primary") != 0) && (strcmp(pathclass, "secondary") != 0)) { (void) fprintf(stderr, MSGSTR(2300, "Incorrect pathclass\n")); exit(-1); } while (argv[path_index] != NULL) { path_phys = g_get_physical_name(argv[path_index++]); if ((path_phys == NULL) || (strstr(path_phys, SCSI_VHCI) == NULL)) { (void) fprintf(stderr, MSGSTR(2301, "Incorrect pathname\n")); exit(-1); } if (err = g_failover(path_phys, pathclass)) { (void) print_errString(err, NULL); exit(-1); } } } /* * up_encl_name() Update the enclosures logical name. * * RETURNS: * none. */ void up_encl_name(char **argv, int argc) { int i, rval, al_pa, path_index = 0, err = 0; L_inquiry inq; Box_list *b_list = NULL; uchar_t node_wwn[WWN_SIZE], port_wwn[WWN_SIZE]; char wwn1[(WWN_SIZE*2)+1], name[1024], *path_phys = NULL; Path_struct *path_struct; (void) memset(name, 0, sizeof (name)); (void) memset(&inq, 0, sizeof (inq)); (void) sscanf(argv[path_index++], "%s", name); for (i = 0; name[i]; i++) { if ((!isalnum(name[i]) && ((name[i] != '#') && (name[i] != '-') && (name[i] != '_') && (name[i] != '.'))) || i >= 16) { (void) fprintf(stderr, MSGSTR(2045, "Error: Invalid enclosure name.\n")); (void) fprintf(stderr, MSGSTR(2046, "Usage: %s [-v] subcommand {a name consisting of" " 1-16 alphanumeric characters}" " {enclosure... | pathname...}\n"), whoami); exit(-1); } } if (((Options & PVERBOSE) && (argc != 5)) || (!(Options & PVERBOSE) && (argc != 4))) { (void) fprintf(stderr, MSGSTR(114, "Error: Incorrect number of arguments.\n")); (void) fprintf(stderr, MSGSTR(2047, "Usage: %s [-v] subcommand {a name consisting of" " 1-16 alphanumeric characters}" " {enclosure... | pathname...}\n"), whoami); exit(-1); } if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } /* * Make sure we are talking to an IB. */ if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((strstr((char *)inq.inq_pid, ENCLOSURE_PROD_ID) == 0) && (!(strncmp((char *)inq.inq_vid, "SUN ", sizeof (inq.inq_vid)) && ((inq.inq_dtype & DTYPE_MASK) == DTYPE_ESI)))) { /* * Again this is like the ssaadm code in that the name * is still not defined before this code must be released. */ (void) fprintf(stderr, MSGSTR(2048, "Error: Pathname does not point to a %s" " enclosure\n"), ENCLOSURE_PROD_NAME); exit(-1); } if (err = g_get_wwn(path_phys, port_wwn, node_wwn, &al_pa, Options & PVERBOSE)) { (void) print_errString(err, argv[path_index]); exit(-1); } for (i = 0; i < WWN_SIZE; i++) { (void) sprintf(&wwn1[i << 1], "%02x", node_wwn[i]); } if ((err = l_get_box_list(&b_list, Options & PVERBOSE)) != 0) { (void) print_errString(err, argv[path_index]); exit(-1); } if (b_list == NULL) { (void) fprintf(stdout, MSGSTR(93, "No %s enclosures found " "in /dev/es\n"), ENCLOSURE_PROD_NAME); exit(-1); } else if (l_duplicate_names(b_list, wwn1, name, Options & PVERBOSE)) { (void) fprintf(stderr, MSGSTR(2049, "Warning: The name you selected, %s," " is already being used.\n" "Please choose a unique name.\n" "You can use the \"probe\" subcommand to" " see all of the enclosure names.\n"), name); (void) l_free_box_list(&b_list); exit(-1); } (void) l_free_box_list(&b_list); /* Send new name to IB */ if (rval = l_new_name(path_phys, name)) { (void) print_errString(rval, path_phys); exit(-1); } if (Options & PVERBOSE) { (void) fprintf(stdout, MSGSTR(2050, "The enclosure has been renamed to %s\n"), name); } } static int get_enclStatus(char *phys_path, char *encl_name, int off_flag) { int found_pwrOnDrv = 0, slot; int found_pwrOffDrv = 0, err = 0; L_state l_state; if ((err = l_get_status(phys_path, &l_state, Options & PVERBOSE)) != 0) { (void) print_errString(err, encl_name); return (err); } if (off_flag) { for (slot = 0; slot < l_state.total_num_drv/2; slot++) { if (((l_state.drv_front[slot].ib_status.code != S_NOT_INSTALLED) && (!l_state.drv_front[slot].ib_status.dev_off)) || ((l_state.drv_rear[slot].ib_status.code != S_NOT_INSTALLED) && (!l_state.drv_rear[slot].ib_status.dev_off))) { found_pwrOnDrv++; break; } } if (!found_pwrOnDrv) { (void) fprintf(stdout, MSGSTR(2051, "Notice: Drives in enclosure" " \"%s\" have already been" " powered off.\n\n"), encl_name); return (-1); } } else { for (slot = 0; slot < l_state.total_num_drv/2; slot++) { if (((l_state.drv_front[slot].ib_status.code != S_NOT_INSTALLED) && (l_state.drv_front[slot].ib_status.dev_off)) || ((l_state.drv_rear[slot].ib_status.code != S_NOT_INSTALLED) && (l_state.drv_rear[slot].ib_status.dev_off))) { found_pwrOffDrv++; break; } } if (!found_pwrOffDrv) { (void) fprintf(stdout, MSGSTR(2052, "Notice: Drives in enclosure" " \"%s\" have already been" " powered on.\n\n"), encl_name); return (-1); } } return (0); } /* * adm_led() The led_request subcommand requests the subsystem * to display the current state or turn off, on, or blink * the yellow LED associated with the disk specified by the * enclosure or pathname. * * RETURNS: * none. */ void adm_led(char **argv, int led_action) { int path_index = 0, err = 0; gfc_map_t map; L_inquiry inq; Dev_elem_st status; char *path_phys = NULL; Path_struct *path_struct; int enc_t = 0; /* enclosure type */ char ses_path[MAXPATHLEN]; L_inquiry ses_inq; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { /* Make sure we have a device path. */ if (path_struct->ib_path_flag) { path_phys = path_struct->p_physical_path; } else { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } } if (!path_struct->ib_path_flag) { if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((inq.inq_dtype & DTYPE_MASK) != DTYPE_DIRECT) { (void) fprintf(stderr, MSGSTR(2053, "Error: pathname must be to a disk device.\n" " %s\n"), argv[path_index]); exit(-1); } } /* * See if we are in fact talking to a loop or not. */ if (err = g_get_dev_map(path_phys, &map, (Options & PVERBOSE))) { (void) print_errString(err, argv[path_index]); } if (led_action == L_LED_ON) { (void) fprintf(stderr, MSGSTR(2054, "The led_on functionality is not applicable " "to this subsystem.\n")); exit(-1); } if (err = l_led(path_struct, led_action, &status, (Options & PVERBOSE))) { (void) print_errString(err, argv[path_index]); exit(-1); } /* Check to see if we have a daktari */ if (l_get_ses_path(path_phys, ses_path, &map, (Options & PVERBOSE)) == 0) { if (g_get_inquiry(ses_path, &ses_inq) == 0) { enc_t = l_get_enc_type(ses_inq); } } switch (led_action) { case L_LED_STATUS: if (status.fault || status.fault_req) { if (!path_struct->slot_valid) { (void) fprintf(stdout, MSGSTR(2055, "LED state is ON for " "device:\n %s\n"), path_phys); } else { if (enc_t == DAK_ENC_TYPE) { if (path_struct->f_flag) { (void) fprintf(stdout, MSGSTR(2236, "LED state is ON for " "device in location: slot %d\n"), path_struct->slot); } else { (void) fprintf(stdout, MSGSTR(2236, "LED state is ON for " "device in location: slot %d\n"), path_struct->slot + (MAX_DRIVES_DAK/2)); } } else { (void) fprintf(stdout, (path_struct->f_flag) ? MSGSTR(2056, "LED state is ON for " "device in location: front,slot %d\n") : MSGSTR(2057, "LED state is ON for " "device in location: rear,slot %d\n"), path_struct->slot); } } } else if (status.ident || status.rdy_to_ins || status.rmv) { if (!path_struct->slot_valid) { (void) fprintf(stdout, MSGSTR(2058, "LED state is BLINKING for " "device:\n %s\n"), path_phys); } else { if (enc_t == DAK_ENC_TYPE) { if (path_struct->f_flag) { (void) fprintf(stdout, MSGSTR(2237, "LED state is BLINKING for " "device in location: slot %d\n"), path_struct->slot); } else { (void) fprintf(stdout, MSGSTR(2237, "LED state is BLINKING for " "device in location: slot %d\n"), path_struct->slot + (MAX_DRIVES_DAK/2)); } } else { (void) fprintf(stdout, (path_struct->f_flag) ? MSGSTR(2059, "LED state is BLINKING for " "device in location: front,slot %d\n") : MSGSTR(2060, "LED state is BLINKING for " "device in location: rear,slot %d\n"), path_struct->slot); } } } else { if (!path_struct->slot_valid) { (void) fprintf(stdout, MSGSTR(2061, "LED state is OFF for " "device:\n %s\n"), path_phys); } else { if (enc_t == DAK_ENC_TYPE) { if (path_struct->f_flag) { (void) fprintf(stdout, MSGSTR(2238, "LED state is OFF for " "device in location: slot %d\n"), path_struct->slot); } else { (void) fprintf(stdout, MSGSTR(2238, "LED state is OFF for " "device in location: slot %d\n"), path_struct->slot + MAX_DRIVES_DAK/2); } } else { (void) fprintf(stdout, (path_struct->f_flag) ? MSGSTR(2062, "LED state is OFF for " "device in location: front,slot %d\n") : MSGSTR(2063, "LED state is OFF for " "device in location: rear,slot %d\n"), path_struct->slot); } } } break; } free((void *)map.dev_addr); path_index++; } } /* * dump() Dump information * * RETURNS: * none. */ void dump(char **argv) { uchar_t *buf; int path_index = 0, err = 0; L_inquiry inq; char hdr_buf[MAXNAMELEN]; Rec_diag_hdr *hdr, *hdr_ptr; char *path_phys = NULL; Path_struct *path_struct; /* * get big buffer */ if ((hdr = (struct rec_diag_hdr *)calloc(1, MAX_REC_DIAG_LENGTH)) == NULL) { (void) print_errString(L_MALLOC_FAILED, NULL); exit(-1); } buf = (uchar_t *)hdr; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } if (err = g_get_inquiry(path_phys, &inq)) { (void) print_errString(err, argv[path_index]); } else { (void) g_dump(MSGSTR(2065, "INQUIRY data: "), (uchar_t *)&inq, 5 + inq.inq_len, HEX_ASCII); } (void) memset(buf, 0, MAX_REC_DIAG_LENGTH); if (err = l_get_envsen(path_phys, buf, MAX_REC_DIAG_LENGTH, (Options & PVERBOSE))) { (void) print_errString(err, argv[path_index]); exit(-1); } (void) fprintf(stdout, MSGSTR(2066, "\t\tEnvironmental Sense Information\n")); /* * Dump all pages. */ hdr_ptr = hdr; while (hdr_ptr->page_len != 0) { (void) sprintf(hdr_buf, MSGSTR(2067, "Page %d: "), hdr_ptr->page_code); (void) g_dump(hdr_buf, (uchar_t *)hdr_ptr, HEADER_LEN + hdr_ptr->page_len, HEX_ASCII); hdr_ptr += ((HEADER_LEN + hdr_ptr->page_len) / sizeof (struct rec_diag_hdr)); } path_index++; } (void) free(buf); } /* * display_socal_stats() Display socal driver kstat information. * * RETURNS: * none. */ void display_socal_stats(int port, char *socal_path, struct socal_stats *fc_stats) { int i; int header_flag = 0; char status_msg_buf[MAXNAMELEN]; int num_status_entries; (void) fprintf(stdout, MSGSTR(2068, "\tInformation for FC Loop on port %d of" " FC100/S Host Adapter\n\tat path: %s\n"), port, socal_path); if (fc_stats->version > 1) { (void) fprintf(stdout, "\t"); (void) fprintf(stdout, MSGSTR(32, "Information from %s"), fc_stats->drvr_name); (void) fprintf(stdout, "\n"); if ((*fc_stats->node_wwn != '\0') && (*fc_stats->port_wwn[port] != '\0')) { (void) fprintf(stdout, MSGSTR(104, " Host Adapter WWN's: Node:%s" " Port:%s\n"), fc_stats->node_wwn, fc_stats->port_wwn[port]); } if (*fc_stats->fw_revision != '\0') { (void) fprintf(stdout, MSGSTR(105, " Host Adapter Firmware Revision: %s\n"), fc_stats->fw_revision); } if (fc_stats->parity_chk_enabled != 0) { (void) fprintf(stdout, MSGSTR(2069, " This Host Adapter checks S-Bus parity.\n")); } } (void) fprintf(stdout, MSGSTR(2070, " Version Resets Req_Q_Intrpts Qfulls" " Unsol_Resps Lips\n")); (void) fprintf(stdout, " %4d%8d%11d%13d%10d%7d\n", fc_stats->version, fc_stats->resets, fc_stats->reqq_intrs, fc_stats->qfulls, fc_stats->pstats[port].unsol_resps, fc_stats->pstats[port].lips); (void) fprintf(stdout, MSGSTR(2071, " Els_rcvd Abts" " Abts_ok Offlines Loop_onlines Onlines\n")); (void) fprintf(stdout, " %4d%9d%10d%9d%13d%10d\n", fc_stats->pstats[port].els_rcvd, fc_stats->pstats[port].abts, fc_stats->pstats[port].abts_ok, fc_stats->pstats[port].offlines, fc_stats->pstats[port].online_loops, fc_stats->pstats[port].onlines); /* If any status conditions exist then display */ if (fc_stats->version > 1) { num_status_entries = FC_STATUS_ENTRIES; } else { num_status_entries = 64; } for (i = 0; i < num_status_entries; i++) { if (fc_stats->pstats[port].resp_status[i] != 0) { if (header_flag++ == 0) { (void) fprintf(stdout, MSGSTR(2072, " Fibre Channel Transport status:\n " "Status Value" " Count\n")); } (void) l_format_fc_status_msg(status_msg_buf, fc_stats->pstats[port].resp_status[i], i); (void) fprintf(stdout, " %s\n", status_msg_buf); } } } /* * display_sf_stats() Display sf driver kstat information. * * This routine is called by private loop device only * * RETURNS: * none. */ void display_sf_stats(char *path_phys, int dtype, struct sf_stats *sf_stats) { int i, al_pa, err = 0; gfc_map_t map; uchar_t node_wwn[WWN_SIZE]; uchar_t port_wwn[WWN_SIZE]; gfc_port_dev_info_t *dev_addr_list; if (sf_stats->version > 1) { (void) fprintf(stdout, "\n\t"); (void) fprintf(stdout, MSGSTR(32, "Information from %s"), sf_stats->drvr_name); (void) fprintf(stdout, "\n"); } else { (void) fprintf(stdout, MSGSTR(2073, "\n\t\tInformation from sf driver:\n")); } (void) fprintf(stdout, MSGSTR(2074, " Version Lip_count Lip_fail" " Alloc_fail #_cmds " "Throttle_limit Pool_size\n")); (void) fprintf(stdout, " %4d%9d%12d%11d%10d%11d%12d\n", sf_stats->version, sf_stats->lip_count, sf_stats->lip_failures, sf_stats->cralloc_failures, sf_stats->ncmds, sf_stats->throttle_limit, sf_stats->cr_pool_size); (void) fprintf(stdout, MSGSTR(2075, "\n\t\tTARGET ERROR INFORMATION:\n")); (void) fprintf(stdout, MSGSTR(2076, "AL_PA Els_fail Timouts Abts_fail" " Tsk_m_fail " " Data_ro_mis Dl_len_mis Logouts\n")); if (err = g_get_dev_map(path_phys, &map, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } if (dtype == DTYPE_DIRECT) { if (err = g_get_wwn(path_phys, port_wwn, node_wwn, &al_pa, Options & PVERBOSE)) { (void) print_errString(err, path_phys); exit(-1); } /* for san toleration, only need to modify the code */ /* such that the current sf_al_map structure replaced */ /* by the new gfc_map structure for private loop device */ for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { if (dev_addr_list->gfc_port_dev.priv_port.sf_al_pa == al_pa) { (void) fprintf(stdout, "%3x%10d%8d%10d%11d%13d%11d%9d\n", al_pa, sf_stats->tstats[i].els_failures, sf_stats->tstats[i].timeouts, sf_stats->tstats[i].abts_failures, sf_stats->tstats[i].task_mgmt_failures, sf_stats->tstats[i].data_ro_mismatches, sf_stats->tstats[i].dl_len_mismatches, sf_stats->tstats[i].logouts_recvd); break; } } if (i >= map.count) { (void) print_errString(L_INVALID_LOOP_MAP, path_phys); exit(-1); } } else { for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { (void) fprintf(stdout, "%3x%10d%8d%10d%11d%13d%11d%9d\n", dev_addr_list->gfc_port_dev.priv_port.sf_al_pa, sf_stats->tstats[i].els_failures, sf_stats->tstats[i].timeouts, sf_stats->tstats[i].abts_failures, sf_stats->tstats[i].task_mgmt_failures, sf_stats->tstats[i].data_ro_mismatches, sf_stats->tstats[i].dl_len_mismatches, sf_stats->tstats[i].logouts_recvd); } } free((void *)map.dev_addr); } /* * adm_display_err() Displays enclosure specific * error information. * * RETURNS: * none. */ static void adm_display_err(char *path_phys, int dtype) { int i, drvr_inst, sf_inst, socal_inst, port, al_pa, err = 0; char *char_ptr, socal_path[MAXPATHLEN], drvr_path[MAXPATHLEN]; struct stat sbuf; kstat_ctl_t *kc; kstat_t *ifp_ks, *sf_ks, *fc_ks; sf_stats_t sf_stats; socal_stats_t fc_stats; ifp_stats_t ifp_stats; int header_flag = 0, pathcnt = 1; char status_msg_buf[MAXNAMELEN]; gfc_map_t map; uchar_t node_wwn[WWN_SIZE], port_wwn[WWN_SIZE]; uint_t path_type; gfc_port_dev_info_t *dev_addr_list; mp_pathlist_t pathlist; int p_on = 0, p_st = 0; if ((kc = kstat_open()) == (kstat_ctl_t *)NULL) { (void) fprintf(stderr, MSGSTR(2077, " Error: can't open kstat\n")); exit(-1); } if (strstr(path_phys, SCSI_VHCI)) { (void) strcpy(drvr_path, path_phys); if (err = g_get_pathlist(drvr_path, &pathlist)) { (void) print_errString(err, NULL); exit(-1); } pathcnt = pathlist.path_count; p_on = p_st = 0; for (i = 0; i < pathcnt; i++) { if (pathlist.path_info[i].path_state < MAXPATHSTATE) { if (pathlist.path_info[i].path_state == MDI_PATHINFO_STATE_ONLINE) { p_on = i; break; } else if (pathlist.path_info[i].path_state == MDI_PATHINFO_STATE_STANDBY) { p_st = i; } } } if (pathlist.path_info[p_on].path_state == MDI_PATHINFO_STATE_ONLINE) { /* on_line path */ (void) strcpy(drvr_path, pathlist.path_info[p_on].path_hba); } else { /* standby or path0 */ (void) strcpy(drvr_path, pathlist.path_info[p_st].path_hba); } free(pathlist.path_info); } else { (void) strcpy(drvr_path, path_phys); if ((char_ptr = strrchr(drvr_path, '/')) == NULL) { (void) print_errString(L_INVLD_PATH_NO_SLASH_FND, path_phys); exit(-1); } *char_ptr = '\0'; /* Make into nexus or HBA driver path. */ } /* * Each HBA and driver stack has its own structures * for this, so we have to handle each one individually. */ path_type = g_get_path_type(drvr_path); if (path_type) { /* Quick sanity check for valid path */ if ((err = g_get_nexus_path(drvr_path, &char_ptr)) != 0) { (void) print_errString(err, path_phys); exit(-1); } (void) strcpy(socal_path, char_ptr); } /* attach :devctl to get node stat instead of dir stat. */ (void) strcat(drvr_path, FC_CTLR); if (stat(drvr_path, &sbuf) < 0) { (void) print_errString(L_LSTAT_ERROR, path_phys); exit(-1); } drvr_inst = minor(sbuf.st_rdev); /* * first take care of ifp card. */ if (path_type & FC4_PCI_FCA) { if ((ifp_ks = kstat_lookup(kc, "ifp", drvr_inst, "statistics")) != NULL) { if (kstat_read(kc, ifp_ks, &ifp_stats) < 0) { (void) fprintf(stderr, MSGSTR(2082, "Error: could not read ifp%d\n"), drvr_inst); exit(-1); } (void) fprintf(stdout, MSGSTR(2083, "\tInformation for FC Loop of" " FC100/P Host Adapter\n\tat path: %s\n"), drvr_path); if (ifp_stats.version > 1) { (void) fprintf(stdout, "\t"); (void) fprintf(stdout, MSGSTR(32, "Information from %s"), ifp_stats.drvr_name); (void) fprintf(stdout, "\n"); if ((*ifp_stats.node_wwn != '\0') && (*ifp_stats.port_wwn != '\0')) { (void) fprintf(stdout, MSGSTR(104, " Host Adapter WWN's: Node:%s" " Port:%s\n"), ifp_stats.node_wwn, ifp_stats.port_wwn); } if (*ifp_stats.fw_revision != 0) { (void) fprintf(stdout, MSGSTR(105, " Host Adapter Firmware Revision: %s\n"), ifp_stats.fw_revision); } if (ifp_stats.parity_chk_enabled != 0) { (void) fprintf(stdout, MSGSTR(2084, " This Host Adapter checks " "PCI-Bus parity.\n")); } } (void) fprintf(stdout, MSGSTR(2085, " Version Lips\n")); (void) fprintf(stdout, " %10d%7d\n", ifp_stats.version, ifp_stats.lip_count); /* If any status conditions exist then display */ for (i = 0; i < FC_STATUS_ENTRIES; i++) { if (ifp_stats.resp_status[i] != 0) { if (header_flag++ == 0) { (void) fprintf(stdout, MSGSTR(2086, " Fibre Channel Transport " "status:\n " "Status " " Value" " Count\n")); } (void) l_format_ifp_status_msg( status_msg_buf, ifp_stats.resp_status[i], i); (void) fprintf(stdout, " %s\n", status_msg_buf); } } (void) fprintf(stdout, MSGSTR(2087, "\n\t\tTARGET ERROR INFORMATION:\n")); (void) fprintf(stdout, MSGSTR(2088, "AL_PA logouts_recvd task_mgmt_failures" " data_ro_mismatches data_len_mismatch\n")); if (err = g_get_dev_map(path_phys, &map, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } if (dtype == DTYPE_DIRECT) { if (err = g_get_wwn(path_phys, port_wwn, node_wwn, &al_pa, Options & PVERBOSE)) { (void) print_errString(err, path_phys); exit(-1); } for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { if (dev_addr_list->gfc_port_dev. priv_port.sf_al_pa == al_pa) { (void) fprintf (stdout, "%3x%14d%18d%20d%20d\n", al_pa, ifp_stats.tstats[i]. logouts_recvd, ifp_stats.tstats[i]. task_mgmt_failures, ifp_stats.tstats[i]. data_ro_mismatches, ifp_stats.tstats[i]. dl_len_mismatches); break; } } if (i >= map.count) { (void) print_errString( L_INVALID_LOOP_MAP, path_phys); exit(-1); } } else { for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { (void) fprintf(stdout, "%3x%14d%18d%20d%20d\n", dev_addr_list->gfc_port_dev. priv_port.sf_al_pa, ifp_stats.tstats[i].logouts_recvd, ifp_stats.tstats[i].task_mgmt_failures, ifp_stats.tstats[i].data_ro_mismatches, ifp_stats.tstats[i].dl_len_mismatches); } } free((void *)map.dev_addr); } } else if (path_type & FC4_SF_XPORT) { /* * process cards with sf xport nodes. */ if (stat(socal_path, &sbuf) < 0) { (void) print_errString(L_LSTAT_ERROR, path_phys); exit(-1); } socal_inst = minor(sbuf.st_rdev)/2; port = socal_inst%2; sf_inst = LUX_SF_MINOR2INST(minor(sbuf.st_rdev)); if (!(sf_ks = kstat_lookup(kc, "sf", sf_inst, "statistics"))) { (void) fprintf(stderr, MSGSTR(2078, " Error: could not lookup driver stats for sf%d\n"), sf_inst); exit(-1); } if (!(fc_ks = kstat_lookup(kc, "socal", socal_inst, "statistics"))) { (void) fprintf(stderr, MSGSTR(2079, " Error: could not lookup driver stats for socal%d\n"), socal_inst); exit(-1); } if (kstat_read(kc, sf_ks, &sf_stats) < 0) { (void) fprintf(stderr, MSGSTR(2080, " Error: could not read driver stats for sf%d\n"), sf_inst); exit(-1); } if (kstat_read(kc, fc_ks, &fc_stats) < 0) { (void) fprintf(stderr, MSGSTR(2081, " Error: could not read driver stats for socal%d\n"), socal_inst); exit(-1); } (void) display_socal_stats(port, socal_path, &fc_stats); (void) display_sf_stats(path_phys, dtype, &sf_stats); } else if ((path_type & FC_FCA_MASK) == FC_PCI_FCA) { fprintf(stderr, MSGSTR(2252, "\n WARNING!! display -r on qlc is" " currently not supported.\n")); } else { fprintf(stderr, MSGSTR(2253, "\n WARNING!! display -r is not supported on path\n" " %s\n"), drvr_path); } (void) kstat_close(kc); } /*ARGSUSED*/ /* * adm_display_verbose_disk() Gets the mode page information * for a SENA disk and prints that information. * * RETURNS: * none. */ void adm_display_verbose_disk(char *path, int verbose) { uchar_t *pg_buf; Mode_header_10 *mode_header_ptr; Mp_01 *pg1_buf; Mp_04 *pg4_buf; struct mode_page *pg_hdr; int offset, hdr_printed = 0, err = 0; if ((err = l_get_mode_pg(path, &pg_buf, verbose)) == 0) { mode_header_ptr = (struct mode_header_10_struct *)(int)pg_buf; pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)sizeof (struct mode_header_10_struct) + (uchar_t *)(uintptr_t)(mode_header_ptr->bdesc_length))); offset = sizeof (struct mode_header_10_struct) + mode_header_ptr->bdesc_length; while (offset < (mode_header_ptr->length + sizeof (mode_header_ptr->length))) { switch (pg_hdr->code) { case 0x01: pg1_buf = (struct mode_page_01_struct *) (int)pg_hdr; P_DPRINTF(" adm_display_verbose_disk:" "Mode Sense page 1 found.\n"); if (hdr_printed++ == 0) { (void) fprintf(stdout, MSGSTR(2089, " Mode Sense data:\n")); } (void) fprintf(stdout, MSGSTR(2090, " AWRE:\t\t\t%d\n" " ARRE:\t\t\t%d\n" " Read Retry Count:\t\t" "%d\n" " Write Retry Count:\t\t" "%d\n"), pg1_buf->awre, pg1_buf->arre, pg1_buf->read_retry_count, pg1_buf->write_retry_count); break; case MODEPAGE_GEOMETRY: pg4_buf = (struct mode_page_04_struct *) (int)pg_hdr; P_DPRINTF(" adm_display_verbose_disk:" "Mode Sense page 4 found.\n"); if (hdr_printed++ == 0) { (void) fprintf(stdout, MSGSTR(2091, " Mode Sense data:\n")); } if (pg4_buf->rpm) { (void) fprintf(stdout, MSGSTR(2092, " Medium rotation rate:\t" "%d RPM\n"), pg4_buf->rpm); } break; } offset += pg_hdr->length + sizeof (struct mode_page); pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)offset)); } } else if (getenv("_LUX_P_DEBUG") != NULL) { (void) print_errString(err, path); } } /* * Print out the port_wwn or node_wwn */ void print_wwn(FILE *fd, uchar_t *pn_wwn) { (void) fprintf(fd, " %1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", pn_wwn[0], pn_wwn[1], pn_wwn[2], pn_wwn[3], pn_wwn[4], pn_wwn[5], pn_wwn[6], pn_wwn[7]); } /* * Print out the fabric dev port_id, hard_addr, port_wwn and node_wwn */ void print_fabric_prop(int pos, uchar_t *port_wwn, uchar_t *node_wwn, int port_addr, int hard_addr) { (void) fprintf(stdout, "%-4d %-6x %-6x ", pos, port_addr, hard_addr); print_wwn(stdout, port_wwn); print_wwn(stdout, node_wwn); } /* * Print out the private loop dev port_id, hard_addr, port_wwn and node_wwn */ void print_private_loop_prop(int pos, uchar_t *port_wwn, uchar_t *node_wwn, int port_addr, int hard_addr) { (void) fprintf(stdout, "%-3d %-2x %-2x %-2x ", pos, port_addr, g_sf_alpa_to_switch[port_addr], hard_addr); print_wwn(stdout, port_wwn); print_wwn(stdout, node_wwn); } /* * Get the device map from * fc nexus driver and prints the map. * * RETURNS: * none. */ void dump_map(char **argv) { int i = 0, path_index = 0, pathcnt = 1; int limited_map_flag = 0, err = 0; char *path_phys = NULL; Path_struct *path_struct; struct lilpmap limited_map; uint_t dev_type; char temp2path[MAXPATHLEN]; mp_pathlist_t pathlist; int p_pw = 0, p_on = 0, p_st = 0; gfc_dev_t map_root, map_dev; int *port_addr, *hard_addr, pos = 0, count; uchar_t *hba_port_wwn, *port_wwn, *node_wwn, *dtype_prop; uint_t map_topo; while (argv[path_index] != NULL) { if ((err = l_convert_name(argv[path_index], &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), argv[path_index]); if (err != -1) { (void) print_errString(err, argv[path_index]); } exit(-1); } if (strstr(path_phys, SCSI_VHCI) != NULL) { /* obtain phci */ (void) strcpy(temp2path, path_phys); if (err = g_get_pathlist(temp2path, &pathlist)) { (void) print_errString(err, NULL); exit(-1); } pathcnt = pathlist.path_count; p_pw = p_on = p_st = 0; for (i = 0; i < pathcnt; i++) { if (pathlist.path_info[i].path_state < MAXPATHSTATE) { if (strstr(pathlist.path_info[i]. path_addr, path_struct->argv) != NULL) { p_pw = i; break; } if (pathlist.path_info[i].path_state == MDI_PATHINFO_STATE_ONLINE) { p_on = i; } if (pathlist.path_info[i].path_state == MDI_PATHINFO_STATE_STANDBY) { p_st = i; } } } if (strstr(pathlist.path_info[p_pw].path_addr, path_struct->argv) != NULL) { /* matching input pwwn */ (void) strcpy(temp2path, pathlist.path_info[p_pw].path_hba); } else if (pathlist.path_info[p_on].path_state == MDI_PATHINFO_STATE_ONLINE) { /* on_line path */ (void) strcpy(temp2path, pathlist.path_info[p_on].path_hba); } else { /* standby or path0 */ (void) strcpy(temp2path, pathlist.path_info[p_st].path_hba); } free(pathlist.path_info); (void) strcat(temp2path, FC_CTLR); } else { (void) strcpy(temp2path, path_phys); } if ((dev_type = g_get_path_type(temp2path)) == 0) { (void) print_errString(L_INVALID_PATH, argv[path_index]); exit(-1); } if ((map_root = g_dev_map_init(temp2path, &err, MAP_FORMAT_LILP)) == NULL) { if (dev_type & FC_FCA_MASK) { (void) print_errString(err, argv[path_index]); exit(-1); } else { /* * This did not work so try the FCIO_GETMAP * type ioctl. */ if (err = g_get_limited_map(path_phys, &limited_map, (Options & PVERBOSE))) { (void) print_errString(err, argv[path_index]); exit(-1); } limited_map_flag++; } } if (limited_map_flag) { (void) fprintf(stdout, MSGSTR(2093, "Host Adapter AL_PA: %x\n"), limited_map.lilp_myalpa); (void) fprintf(stdout, MSGSTR(2094, "Pos AL_PA\n")); for (i = 0; i < (uint_t)limited_map.lilp_length; i++) { (void) fprintf(stdout, "%-3d %-2x\n", i, limited_map.lilp_list[i]); } } else { if ((err = g_dev_prop_lookup_bytes(map_root, PORT_WWN_PROP, &count, &hba_port_wwn)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_get_map_topology( map_root, &map_topo)) != 0) { (void) print_errString(err, argv[path_index]); exit(-1); } if ((map_dev = g_get_first_dev(map_root, &err)) == NULL) { if (err == L_NO_SUCH_DEV_FOUND) { g_dev_map_fini(map_root); (void) fprintf(stderr, MSGSTR(2308, " No devices are found on %s.\n"), argv[path_index]); exit(-1); } else { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } } switch (map_topo) { case FC_TOP_FABRIC: case FC_TOP_PUBLIC_LOOP: case FC_TOP_PT_PT: (void) fprintf(stdout, MSGSTR(2095, "Pos Port_ID Hard_Addr Port WWN" " Node WWN Type\n")); while (map_dev) { if ((err = g_dev_prop_lookup_ints( map_dev, PORT_ADDR_PROP, &port_addr)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_bytes(map_dev, PORT_WWN_PROP, &count, &port_wwn)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_bytes(map_dev, NODE_WWN_PROP, &count, &node_wwn)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_ints( map_dev, HARD_ADDR_PROP, &hard_addr)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } print_fabric_prop(pos++, port_wwn, node_wwn, *port_addr, *hard_addr); if ((err = g_dev_prop_lookup_bytes(map_dev, INQ_DTYPE_PROP, &count, &dtype_prop)) != 0) { (void) fprintf(stdout, MSGSTR(2307, " Failed to get the type.\n")); } else { print_fabric_dtype_prop(hba_port_wwn, port_wwn, *dtype_prop); } if (((map_dev = g_get_next_dev( map_dev, &err)) == NULL) && (err != L_NO_SUCH_DEV_FOUND)) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } } break; case FC_TOP_PRIVATE_LOOP: (void) fprintf(stdout, MSGSTR(2295, "Pos AL_PA ID Hard_Addr " "Port WWN Node WWN Type\n")); while (map_dev) { if ((err = g_dev_prop_lookup_ints( map_dev, PORT_ADDR_PROP, &port_addr)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_bytes(map_dev, PORT_WWN_PROP, &count, &port_wwn)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_bytes(map_dev, NODE_WWN_PROP, &count, &node_wwn)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } if ((err = g_dev_prop_lookup_ints( map_dev, HARD_ADDR_PROP, &hard_addr)) != 0) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } print_private_loop_prop(pos++, port_wwn, node_wwn, *port_addr, *hard_addr); if ((err = g_dev_prop_lookup_bytes(map_dev, INQ_DTYPE_PROP, &count, &dtype_prop)) != 0) { (void) fprintf(stdout, MSGSTR(2307, " Failed to get the type.\n")); } else { print_private_loop_dtype_prop(hba_port_wwn, port_wwn, *dtype_prop); } if (((map_dev = g_get_next_dev( map_dev, &err)) == NULL) && (err != L_NO_SUCH_DEV_FOUND)) { g_dev_map_fini(map_root); (void) print_errString(err, argv[path_index]); exit(-1); } } break; default: (void) print_errString(L_UNEXPECTED_FC_TOPOLOGY, argv[path_index]); exit(-1); } g_dev_map_fini(map_root); } limited_map_flag = 0; path_index++; } } /* * Gets a list of non-SENA fcal devices * found on the system. * * OUTPUT: * wwn_list pointer * NULL: No non-enclosure devices found. * !NULL: Devices found * wwn_list points to a linked list of wwn's. * RETURNS: * 0 O.K. */ int n_get_non_encl_list(WWN_list **wwn_list_ptr, int verbose) { int i, j, k, err, found_ib = 0, pathcnt = 1; WWN_list *wwn_list; Box_list *b_list = NULL; gfc_map_t map; uchar_t box_id; gfc_port_dev_info_t *dev_addr_list; char phci_path[MAXPATHLEN], oldphci_path[MAXPATHLEN]; mp_pathlist_t pathlist; /* * Only interested in devices that are not part of * a Photon enclosure. */ if ((err = l_get_box_list(&b_list, verbose)) != 0) { return (err); /* Failure */ } if (err = g_get_wwn_list(&wwn_list, verbose)) { (void) l_free_box_list(&b_list); return (err); } while (b_list != NULL) { pathcnt = 1; if (strstr(b_list->b_physical_path, SCSI_VHCI) != NULL) { (void) strcpy(phci_path, b_list->b_physical_path); if (err = g_get_pathlist(phci_path, &pathlist)) { (void) print_errString(err, NULL); exit(-1); } pathcnt = pathlist.path_count; } for (k = 0; k < pathcnt; k++) { if ((k > 0) && (strstr(oldphci_path, pathlist.path_info[k].path_hba))) { continue; } if (strstr(b_list->b_physical_path, SCSI_VHCI) == NULL) { if ((err = g_get_dev_map(b_list->b_physical_path, &map, verbose)) != 0) { (void) g_free_wwn_list(&wwn_list); (void) l_free_box_list(&b_list); return (err); } } else { (void) strcpy(phci_path, pathlist.path_info[k].path_hba); (void) strcpy(oldphci_path, phci_path); (void) strcat(phci_path, FC_CTLR); if (g_get_dev_map(phci_path, &map, verbose)) { continue; } if (pathcnt == 1) { free(pathlist.path_info); } } switch (map.hba_addr.port_topology) { case FC_TOP_FABRIC: case FC_TOP_PUBLIC_LOOP: for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { for (found_ib = 1, j = 0; j < WWN_SIZE; j++) { if (b_list->b_node_wwn[j] != dev_addr_list->gfc_port_dev. pub_port.dev_nwwn.raw_wwn[j]) { found_ib = 0; } } if (found_ib) { (void) n_rem_list_entry_fabric( dev_addr_list->gfc_port_dev. pub_port.dev_did.port_id, &map, &wwn_list); } } break; case FC_TOP_PRIVATE_LOOP: for (i = 0, dev_addr_list = map.dev_addr; i < map.count; i++, dev_addr_list++) { for (found_ib = 1, j = 0; j < WWN_SIZE; j++) { if (b_list->b_node_wwn[j] != dev_addr_list->gfc_port_dev. priv_port.sf_node_wwn[j]) { found_ib = 0; } } if (found_ib) { box_id = g_sf_alpa_to_switch [dev_addr_list->gfc_port_dev. priv_port.sf_al_pa] & BOX_ID_MASK; /* This function has been added */ /* here only to keep from having */ /* to tab over farther */ (void) n_rem_list_entry(box_id, &map, &wwn_list); if (wwn_list == NULL) { /* Return the list */ *wwn_list_ptr = NULL; break; } } } break; case FC_TOP_PT_PT: (void) free((void *)map.dev_addr); return (L_PT_PT_FC_TOP_NOT_SUPPORTED); default: (void) free((void *)map.dev_addr); return (L_UNEXPECTED_FC_TOPOLOGY); } free((void *)map.dev_addr); } if (pathcnt > 1) { free(pathlist.path_info); } b_list = b_list->box_next; } /* Return the list */ *wwn_list_ptr = wwn_list; (void) l_free_box_list(&b_list); return (0); } /* * n_rem_list_entry() We found an IB so remove disks that * are in the Photon from the individual device list. * * OUTPUT: * wwn_list - removes the fcal disks that are in SENA enclosure * * RETURNS: * none */ void n_rem_list_entry(uchar_t box_id, struct gfc_map *map, struct wwn_list_struct **wwn_list) { int k; gfc_port_dev_info_t *dev_addr_list; N_DPRINTF(" n_rem_list_entry: Removing devices" " with box_id=0x%x from device list.\n", box_id); for (k = 0, dev_addr_list = map->dev_addr; k < map->count; k++, dev_addr_list++) { if ((g_sf_alpa_to_switch[dev_addr_list->gfc_port_dev. priv_port.sf_hard_address] & BOX_ID_MASK) == box_id) { n_rem_wwn_entry(dev_addr_list->gfc_port_dev. priv_port.sf_node_wwn, wwn_list); } } } /* * n_rem_list_entry_fabric() We found an IB so remove disks that * are in the Photon from the individual device list. * * OUTPUT: * wwn_list - removes the fcal disks that are in SENA enclosure * * RETURNS: * none */ void n_rem_list_entry_fabric(int pa, struct gfc_map *map, struct wwn_list_struct **wwn_list) { int k; gfc_port_dev_info_t *dev_addr_ptr; N_DPRINTF(" n_rem_list_entry: Removing devices" " with the same domain and area ID as" " 0x%x PA from device list.\n", pa); for (k = 0, dev_addr_ptr = map->dev_addr; k < map->count; k++, dev_addr_ptr++) { /* matching the domain and area id with input alpa, */ /* ignoring last 8 bits. */ if ((dev_addr_ptr->gfc_port_dev.pub_port.dev_did.port_id | 0xff) == (pa | 0xff)) { n_rem_wwn_entry(dev_addr_ptr-> gfc_port_dev.pub_port.dev_nwwn.raw_wwn, wwn_list); } } } /* * n_rem_wwn_entry() removes input wwn from wwn_list. * * OUTPUT: * wwn_list - removes the input wwn from wwn_list if found. * * RETURNS: * none */ void n_rem_wwn_entry(uchar_t node_wwn[], struct wwn_list_struct **wwn_list) { int l, found_dev; WWN_list *inner, *l1; inner = *wwn_list; while (inner != NULL) { for (found_dev = 1, l = 0; l < WWN_SIZE; l++) { if (inner->w_node_wwn[l] != node_wwn[l]) { found_dev = 0; } } if (found_dev) { /* Remove this entry from the list */ if (inner->wwn_prev != NULL) { inner->wwn_prev->wwn_next = inner->wwn_next; } else { *wwn_list = inner->wwn_next; } if (inner->wwn_next != NULL) { inner->wwn_next->wwn_prev = inner->wwn_prev; } l1 = inner; N_DPRINTF(" n_rem_wwn_entry: " "Removing Logical=%s " "Current=0x%x, " "Prev=0x%x, Next=0x%x\n", l1->logical_path, l1, l1->wwn_prev, l1->wwn_next); inner = inner->wwn_next; if ((l1->wwn_prev == NULL) && (l1->wwn_next) == NULL) { (void) free(l1->physical_path); (void) free(l1->logical_path); (void) free(l1); *wwn_list = NULL; N_DPRINTF(" n_rem_list_entry: " "No non-Photon " "devices left" " in the list.\n"); return; } (void) free(l1->physical_path); (void) free(l1->logical_path); (void) free(l1); } else { inner = inner->wwn_next; } } } /* * non_encl_probe() Finds and displays a list of * non-SENA fcal devices which is found on the * system. * * RETURNS: * none. */ void non_encl_probe() { WWN_list *wwn_list, *wwn_listh, *inner, *l1; int err = 0; char lun_a[MAXPATHLEN], lun_b[MAXPATHLEN], temppath[MAXPATHLEN]; char *tempptra, *tempptrb, *tempptr; mp_pathlist_t pathlist; int compare_result, retr_outer = 0; ddi_devid_t devid1 = NULL, devid2 = NULL; di_node_t root = DI_NODE_NIL; if (err = n_get_non_encl_list(&wwn_list, (Options & PVERBOSE))) { (void) print_errString(err, NULL); exit(-1); } g_sort_wwn_list(&wwn_list); wwn_listh = wwn_list; if (wwn_list != NULL) { if (wwn_list->wwn_next != NULL) { (void) fprintf(stdout, MSGSTR(2098, "\nFound Fibre Channel device(s):\n")); } else { (void) fprintf(stdout, MSGSTR(2099, "\nFound Fibre Channel device:\n")); } } else { return; } while (wwn_list != NULL) { if (strstr(wwn_list->physical_path, SCSI_VHCI) != NULL) { (void) strcpy(temppath, wwn_list->physical_path); if ((!g_get_pathlist(temppath, &pathlist)) && ((tempptra = strchr(pathlist.path_info[0]. path_addr, ','))) != NULL) { tempptra++; (void) strcpy(lun_a, tempptra); free(pathlist.path_info); } } else { if ((((tempptr = strstr(wwn_list->physical_path, SLSH_DRV_NAME_ST)) != NULL) || ((tempptr = strstr(wwn_list->physical_path, SLSH_DRV_NAME_SSD)) != NULL)) && ((tempptra = strchr(tempptr, ',')) != NULL)) { tempptra++; (void) strcpy(lun_a, tempptra); } } (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(90, "Node WWN:")); (void) fprintf(stdout, "%s ", wwn_list->node_wwn_s); if (wwn_list->device_type < 0x10) { (void) fprintf(stdout, MSGSTR(35, "Device Type:")); (void) fprintf(stdout, "%s", dtype[wwn_list->device_type]); } else if (wwn_list->device_type < 0x1f) { (void) fprintf(stdout, MSGSTR(2100, "Type:Reserved")); } else { (void) fprintf(stdout, MSGSTR(2101, "Type:Unknown")); } (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(31, "Logical Path:%s"), wwn_list->logical_path); (void) fprintf(stdout, "\n"); if (Options & OPTION_P) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(5, "Physical Path:")); (void) fprintf(stdout, "\n %s\n", wwn_list->physical_path); } inner = wwn_list->wwn_next; while (inner != NULL) { if (strcmp(inner->node_wwn_s, wwn_list->node_wwn_s) == 0) { if (tempptra != NULL) { if (strstr(inner->physical_path, SCSI_VHCI) != NULL) { (void) strcpy(temppath, inner->physical_path); if ((!g_get_pathlist(temppath, &pathlist)) && ((tempptrb = strchr( pathlist.path_info[0].path_addr, ','))) != NULL) { tempptrb++; (void) strcpy(lun_b, tempptrb); free(pathlist.path_info); } } else { if ((((tempptr = strstr(inner->physical_path, SLSH_DRV_NAME_ST)) != NULL) || ((tempptr = strstr(inner->physical_path, SLSH_DRV_NAME_SSD)) != NULL)) && ((tempptrb = strchr(tempptr, ',')) != NULL)) { tempptrb++; (void) strcpy(lun_b, tempptrb); } } } if (((tempptra == NULL) || (strcmp(lun_a, lun_b)) == 0)) { /* * Have we retrieved a snapshot yet? */ if (root == DI_NODE_NIL) { if ((root = di_init("/", DINFOCPYALL)) == DI_NODE_NIL) { (void) fprintf(stdout, MSGSTR(2319, "\nFailed to get device tree snapshot:\n")); exit(1); } } /* Apply devid to ssd devices only */ if (!retr_outer && strstr(wwn_list->physical_path, SLSH_DRV_NAME_SSD) != NULL) { if ((err = g_devid_get(wwn_list->physical_path, &devid1, root, SSD_DRVR_NAME)) != 0) { (void) print_errString(err, wwn_list->physical_path); } /* * Try retrieve of devid only once. If it fails * don't try it again but print error, * There should be a devid prop. */ retr_outer = 1; } /* * Apply devid to block devices only. * Get devid of inner path and compare * with outer path's devid. */ if ((strstr(inner->physical_path, SLSH_DRV_NAME_SSD) != NULL) && devid1 != NULL) { if ((err = g_devid_get(inner->physical_path, &devid2, root, SSD_DRVR_NAME)) != 0) { (void) print_errString(err, inner->physical_path); compare_result = 0; } else { compare_result = devid_compare(devid1, devid2); } } else { /* devid isn't applied */ compare_result = 0; } if (compare_result == 0) { if (strcmp(wwn_list->logical_path, inner->logical_path)) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(31, "Logical Path:%s"), inner->logical_path); (void) fprintf(stdout, "\n"); if (Options & OPTION_P) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(5, "Physical Path:")); (void) fprintf(stdout, "\n %s\n", inner->physical_path); } } /* Remove this entry from the list */ if (inner->wwn_prev != NULL) { inner->wwn_prev->wwn_next = inner->wwn_next; } if (inner->wwn_next != NULL) { inner->wwn_next->wwn_prev = inner->wwn_prev; } free(inner->physical_path); free(inner->logical_path); l1 = inner; inner = inner->wwn_next; (void) free(l1); } else { inner = inner->wwn_next; } /* End if (compare_result == 0) */ } else { inner = inner->wwn_next; } } else { inner = inner->wwn_next; } devid2 = NULL; } wwn_list = wwn_list->wwn_next; retr_outer = 0; devid1 = NULL; } /* End while (wwn_list != NULL) */ (void) g_free_wwn_list(&wwn_listh); (void) di_fini(root); } void pho_probe() { Box_list *b_list, *o_list, *c_list; int multi_path_flag, multi_print_flag; int duplicate_names_found = 0, err = 0; b_list = o_list = c_list = NULL; if ((err = l_get_box_list(&b_list, Options & PVERBOSE)) != 0) { (void) print_errString(err, NULL); exit(-1); } if (b_list == NULL) { (void) fprintf(stdout, MSGSTR(93, "No %s enclosures found " "in /dev/es\n"), ENCLOSURE_PROD_NAME); } else { o_list = b_list; if (b_list->box_next != NULL) { (void) fprintf(stdout, MSGSTR(2102, "Found Enclosure(s)")); } else { (void) fprintf(stdout, MSGSTR(2103, "Found Enclosure")); } (void) fprintf(stdout, ":\n"); while (b_list != NULL) { /* Don't re-print multiple paths */ c_list = o_list; multi_print_flag = 0; while (c_list != b_list) { if (strcmp(c_list->b_node_wwn_s, b_list->b_node_wwn_s) == 0) { multi_print_flag = 1; break; } c_list = c_list->box_next; } if (multi_print_flag) { b_list = b_list->box_next; continue; } (void) fprintf(stdout, MSGSTR(2104, "%s Name:%s Node WWN:%s "), b_list->prod_id_s, b_list->b_name, b_list->b_node_wwn_s); /* * Print logical path on same line if not multipathed. */ multi_path_flag = 0; c_list = o_list; while (c_list != NULL) { if ((c_list != b_list) && (strcmp(c_list->b_node_wwn_s, b_list->b_node_wwn_s) == 0)) { multi_path_flag = 1; } c_list = c_list->box_next; } if (multi_path_flag) { (void) fprintf(stdout, "\n "); } (void) fprintf(stdout, MSGSTR(31, "Logical Path:%s"), b_list->logical_path); if (Options & OPTION_P) { (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(5, "Physical Path:")); (void) fprintf(stdout, "%s", b_list->b_physical_path); } c_list = o_list; while (c_list != NULL) { if ((c_list != b_list) && (strcmp(c_list->b_node_wwn_s, b_list->b_node_wwn_s) == 0)) { (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(31, "Logical Path:%s"), c_list->logical_path); if (Options & OPTION_P) { (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(5, "Physical Path:")); (void) fprintf(stdout, "%s", c_list->b_physical_path); } } c_list = c_list->box_next; } (void) fprintf(stdout, "\n"); /* Check for duplicate names */ if (l_duplicate_names(o_list, b_list->b_node_wwn_s, (char *)b_list->b_name, Options & PVERBOSE)) { duplicate_names_found++; } b_list = b_list->box_next; } } if (duplicate_names_found) { (void) fprintf(stdout, MSGSTR(2105, "\nWARNING: There are enclosures with " "the same names.\n" "You can not use the \"enclosure\"" " name to specify these subsystems.\n" "Please use the \"enclosure_name\"" " subcommand to select unique names.\n\n")); } (void) l_free_box_list(&b_list); } /* * display_port_status() Prints the device's * port status. * * RETURNS: * none. */ void display_port_status(int d_state_flag) { if (d_state_flag & L_OPEN_FAIL) { (void) fprintf(stdout, MSGSTR(28, "Open Failed")); } else if (d_state_flag & L_NOT_READY) { (void) fprintf(stdout, MSGSTR(20, "Not Ready")); } else if (d_state_flag & L_NOT_READABLE) { (void) fprintf(stdout, MSGSTR(88, "Not Readable")); } else if (d_state_flag & L_SPUN_DWN_D) { (void) fprintf(stdout, MSGSTR(68, "Spun Down")); } else if (d_state_flag & L_SCSI_ERR) { (void) fprintf(stdout, MSGSTR(70, "SCSI Error")); } else if (d_state_flag & L_RESERVED) { (void) fprintf(stdout, MSGSTR(73, "Reservation conflict")); } else if (d_state_flag & L_NO_LABEL) { (void) fprintf(stdout, MSGSTR(92, "No UNIX Label")); } else { (void) fprintf(stdout, MSGSTR(29, "O.K.")); } (void) fprintf(stdout, "\n"); } /* * Displays individual SENA * FC disk information. * * Caller to this routine should free the storage due to * the use of g_get_dev_map * * RETURNS: * none. */ void display_fc_disk(struct path_struct *path_struct, char *ses_path, gfc_map_t *map, L_inquiry inq, int verbose) { static WWN_list *wwn_list = NULL; static char path_phys[MAXPATHLEN]; static L_disk_state l_disk_state; static L_inquiry local_inq; static uchar_t node_wwn[WWN_SIZE]; char same_path_phys = B_FALSE; /* To chk for repeat args */ uchar_t port_wwn[WWN_SIZE], *pg_buf; char logical_path[MAXPATHLEN]; int al_pa, port_a_flag = 0; int offset, mode_data_avail = 0; int no_path_flag = 0, err = 0; L_state l_state; Mode_header_10 *mode_header_ptr = NULL; struct mode_page *pg_hdr; /* * Do a quick check to see if its the same path as in last call. * path_phys is a static array and so dont worry about its * initialization. */ if (strcmp(path_phys, path_struct->p_physical_path) == 0) same_path_phys = B_TRUE; (void) strcpy(path_phys, path_struct->p_physical_path); (void) memset((char *)logical_path, 0, sizeof (logical_path)); /* * slot_valid is 1 when argument is of the form 'enclosure,[f|r]'. * If slot_valid != 1, g_get_dev_map and l_get_ses_path would * already have been called */ if (path_struct->slot_valid == 1) { /* Get the location information. */ if (err = g_get_dev_map(path_phys, map, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } if (err = l_get_ses_path(path_phys, ses_path, map, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } } /* * Get the WWN for our disk if we already haven't or if there was an * error earlier */ if (same_path_phys == B_FALSE) { if (err = g_get_wwn(path_phys, port_wwn, node_wwn, &al_pa, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } if (err = g_get_inquiry(ses_path, &local_inq)) { (void) print_errString(err, ses_path); exit(-1); } } /* * We are interested only a couple of ib_tbl fields and * those get filled using l_get_ib_status. * Note that NOT ALL of ib_tbl fields get filled here */ if ((err = l_get_ib_status(ses_path, &l_state, Options & PVERBOSE)) != 0) { (void) print_errString(err, ses_path); exit(-1); } /* * Get path to all the FC disk and tape devices. * if we haven't already done so in a previous pass */ if ((wwn_list == NULL) && (err = g_get_wwn_list(&wwn_list, verbose))) { (void) print_errString(err, ses_path); exit(-1); /* Failure */ } /* * Get the disk status if it is a different path_phys from * last time. */ if (same_path_phys == B_FALSE) { (void) memset(&l_disk_state, 0, sizeof (struct l_disk_state_struct)); if (err = l_get_disk_status(path_phys, &l_disk_state, wwn_list, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } } if (l_disk_state.l_state_flag & L_NO_PATH_FOUND) { (void) fprintf(stderr, MSGSTR(2106, "\nWARNING: No path found " "in /dev/rdsk directory\n" " Please check the logical links in /dev/rdsk\n" " (It may be necessary to run the \"disks\" " "program.)\n\n")); /* Just call to get the status directly. */ if (err = l_get_port(ses_path, &port_a_flag, verbose)) { (void) print_errString(err, ses_path); exit(-1); } if (err = l_get_disk_port_status(path_phys, &l_disk_state, port_a_flag, (Options & PVERBOSE))) { (void) print_errString(err, path_phys); exit(-1); } no_path_flag++; } if (strlen(l_disk_state.g_disk_state.node_wwn_s) == 0) { (void) sprintf(l_disk_state.g_disk_state.node_wwn_s, "%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", node_wwn[0], node_wwn[1], node_wwn[2], node_wwn[3], node_wwn[4], node_wwn[5], node_wwn[6], node_wwn[7]); } /* get mode page information for FC device */ if (l_get_mode_pg(path_phys, &pg_buf, Options & PVERBOSE) == 0) { mode_header_ptr = (struct mode_header_10_struct *)(int)pg_buf; pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)sizeof (struct mode_header_10_struct) + (uchar_t *)(uintptr_t)(mode_header_ptr->bdesc_length))); offset = sizeof (struct mode_header_10_struct) + mode_header_ptr->bdesc_length; while (offset < (mode_header_ptr->length + sizeof (mode_header_ptr->length)) && !mode_data_avail) { if (pg_hdr->code == MODEPAGE_CACHING) { mode_data_avail++; break; } offset += pg_hdr->length + sizeof (struct mode_page); pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)offset)); } } switch ((inq.inq_dtype & DTYPE_MASK)) { case DTYPE_DIRECT: fprintf(stdout, MSGSTR(121, "DEVICE PROPERTIES for disk: %s\n"), path_struct->argv); break; case DTYPE_SEQUENTIAL: /* Tape */ fprintf(stdout, MSGSTR(2249, "DEVICE PROPERTIES for tape: %s\n"), path_struct->argv); break; default: fprintf(stdout, MSGSTR(2250, "DEVICE PROPERTIES for: %s\n"), path_struct->argv); break; } if (l_disk_state.g_disk_state.port_a_valid) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(141, "Status(Port A):")); (void) fprintf(stdout, "\t"); display_port_status( l_disk_state.g_disk_state.d_state_flags[PORT_A]); } else { if (path_struct->f_flag) { if ((ib_present_chk(&l_state, 0) == 1) && (l_state.drv_front[path_struct->slot].ib_status.bypass_a_en)) { (void) fprintf(stdout, MSGSTR(66, " Status(Port A):\tBYPASSED\n")); } } else { if ((ib_present_chk(&l_state, 0) == 1) && (l_state.drv_rear[path_struct->slot].ib_status.bypass_a_en)) { (void) fprintf(stdout, MSGSTR(66, " Status(Port A):\tBYPASSED\n")); } } } if (l_disk_state.g_disk_state.port_b_valid) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(142, "Status(Port B):")); (void) fprintf(stdout, "\t"); display_port_status(l_disk_state.g_disk_state.d_state_flags[PORT_B]); } else { if (path_struct->f_flag) { if ((ib_present_chk(&l_state, 1) == 1) && (l_state.drv_front[path_struct->slot].ib_status.bypass_b_en)) { (void) fprintf(stdout, MSGSTR(65, " Status(Port B):\tBYPASSED\n")); } } else { if ((ib_present_chk(&l_state, 1) == 1) && (l_state.drv_rear[path_struct->slot].ib_status.bypass_b_en)) { (void) fprintf(stdout, MSGSTR(65, " Status(Port B):\tBYPASSED\n")); } } } if (no_path_flag) { (void) fprintf(stdout, " "); if (port_a_flag != 0) { (void) fprintf(stdout, MSGSTR(142, "Status(Port B):")); } else { (void) fprintf(stdout, MSGSTR(141, "Status(Port A):")); } (void) fprintf(stdout, "\t"); display_port_status( l_disk_state.g_disk_state.d_state_flags[port_a_flag]); } else if ((!l_disk_state.g_disk_state.port_a_valid) && (!l_disk_state.g_disk_state.port_b_valid)) { (void) fprintf(stdout, MSGSTR(2107, " Status:\t\t" "No state available.\n")); } (void) display_disk_info(inq, l_disk_state, path_struct, pg_hdr, mode_data_avail, (char *)local_inq.inq_box_name, verbose); } /* * non_encl_fc_disk_display() Prints the device specific * information for an individual fcal device. * * RETURNS: * none. */ static int non_encl_fc_disk_display(Path_struct *path_struct, L_inquiry inq_struct, int verbose) { char phys_path[MAXPATHLEN]; uchar_t node_wwn[WWN_SIZE], port_wwn[WWN_SIZE], *pg_buf = NULL; L_disk_state l_disk_state; struct dlist *mlist; int i = 0, al_pa, offset, mode_data_avail = 0, err = 0; int path_a_found = 0, path_b_found = 0, argpwwn = 0, argnwwn = 0, pathcnt = 1; L_inquiry local_inq; Mode_header_10 *mode_header_ptr; struct mode_page *pg_hdr; WWN_list *wwn_list, *wwn_list_ptr, *list_start; char temppath[MAXPATHLEN], last_logical_path[MAXPATHLEN]; mp_pathlist_t pathlist; (void) strcpy(phys_path, path_struct->p_physical_path); /* Get path to all the FC disk and tape devices. */ if (err = g_get_wwn_list(&wwn_list, verbose)) { return (err); } g_sort_wwn_list(&wwn_list); list_start = wwn_list; (void) strcpy(last_logical_path, phys_path); for (wwn_list_ptr = wwn_list; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argpwwn = 1; break; } else if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argnwwn = 1; break; } } for (wwn_list_ptr = list_start; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (argpwwn) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) != 0) { continue; } (void) strcpy(phys_path, wwn_list_ptr->physical_path); path_a_found = 0; path_b_found = 0; mode_data_avail = 0; } else if (argnwwn) { if (strstr(wwn_list_ptr->logical_path, last_logical_path) != NULL) { continue; } if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) != 0) { continue; } (void) strcpy(phys_path, wwn_list_ptr->physical_path); (void) strcpy(last_logical_path, wwn_list_ptr->logical_path); path_a_found = 0; path_b_found = 0; mode_data_avail = 0; } (void) memset(&l_disk_state, 0, sizeof (struct l_disk_state_struct)); if ((err = g_get_multipath(phys_path, &(l_disk_state.g_disk_state.multipath_list), wwn_list, verbose)) != 0) { return (err); } mlist = l_disk_state.g_disk_state.multipath_list; if (mlist == NULL) { l_disk_state.l_state_flag = L_NO_PATH_FOUND; N_DPRINTF(" non_encl_fc_disk_display: Error finding" " multiple paths to the disk.\n"); (void) g_free_wwn_list(&wwn_list); return (-1); } /* get mode page information for FC device */ if (l_get_mode_pg(phys_path, &pg_buf, verbose) == 0) { mode_header_ptr = (struct mode_header_10_struct *)(int)pg_buf; pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)sizeof (struct mode_header_10_struct) + (uchar_t *)(uintptr_t)(mode_header_ptr->bdesc_length))); offset = sizeof (struct mode_header_10_struct) + mode_header_ptr->bdesc_length; while (offset < (mode_header_ptr->length + sizeof (mode_header_ptr->length)) && !mode_data_avail) { if (pg_hdr->code == MODEPAGE_CACHING) { mode_data_avail++; break; } offset += pg_hdr->length + sizeof (struct mode_page); pg_hdr = ((struct mode_page *)((int)pg_buf + (uchar_t)offset)); } } switch ((inq_struct.inq_dtype & DTYPE_MASK)) { case DTYPE_DIRECT: fprintf(stdout, MSGSTR(121, "DEVICE PROPERTIES for disk: %s\n"), path_struct->argv); break; case DTYPE_SEQUENTIAL: /* Tape */ fprintf(stdout, MSGSTR(2249, "DEVICE PROPERTIES for tape: %s\n"), path_struct->argv); break; default: fprintf(stdout, MSGSTR(2250, "DEVICE PROPERTIES for: %s\n"), path_struct->argv); break; } while ((mlist != NULL) && (!(path_a_found && path_b_found))) { (void) strcpy(phys_path, mlist->dev_path); if (err = g_get_inquiry(phys_path, &local_inq)) { (void) fprintf(stderr, MSGSTR(2114, "non_encl_fc_disk_display: Inquiry failed\n")); (void) print_errString(err, phys_path); (void) g_free_multipath( l_disk_state.g_disk_state.multipath_list); (void) g_free_wwn_list(&wwn_list); return (-1); } if ((err = g_get_wwn(mlist->dev_path, port_wwn, node_wwn, &al_pa, verbose)) != 0) { (void) print_errString(err, mlist->dev_path); (void) g_free_multipath( l_disk_state.g_disk_state.multipath_list); (void) g_free_wwn_list(&wwn_list); return (-1); } if (strlen(l_disk_state.g_disk_state.node_wwn_s) == 0) { (void) sprintf(l_disk_state.g_disk_state.node_wwn_s, "%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", node_wwn[0], node_wwn[1], node_wwn[2], node_wwn[3], node_wwn[4], node_wwn[5], node_wwn[6], node_wwn[7]); } if ((err = l_get_disk_port_status(phys_path, &l_disk_state, (local_inq.inq_port) ? FC_PORT_B : FC_PORT_A, verbose)) != 0) { (void) print_errString(err, phys_path); (void) g_free_multipath( l_disk_state.g_disk_state.multipath_list); exit(-1); } if ((!local_inq.inq_port) && (!path_a_found)) { (void) sprintf(l_disk_state.g_disk_state.port_a_wwn_s, "%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", port_wwn[0], port_wwn[1], port_wwn[2], port_wwn[3], port_wwn[4], port_wwn[5], port_wwn[6], port_wwn[7]); path_a_found = l_disk_state.g_disk_state.port_a_valid = 1; } if ((local_inq.inq_port) && (!path_b_found)) { path_b_found = l_disk_state.g_disk_state.port_b_valid = 1; (void) sprintf(l_disk_state.g_disk_state.port_b_wwn_s, "%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", port_wwn[0], port_wwn[1], port_wwn[2], port_wwn[3], port_wwn[4], port_wwn[5], port_wwn[6], port_wwn[7]); } if ((strstr(mlist->dev_path, SCSI_VHCI) != NULL) && (!l_get_disk_port_status(phys_path, &l_disk_state, (!local_inq.inq_port) ? FC_PORT_B : FC_PORT_A, verbose))) { (void) strcpy(temppath, mlist->dev_path); if (err = g_get_pathlist(temppath, &pathlist)) { (void) print_errString(err, NULL); exit(-1); } pathcnt = pathlist.path_count; if (pathcnt > 1) { for (i = 0; i < pathcnt; i++) { if ((!path_a_found) && (path_b_found) && (strstr(pathlist.path_info[i]. path_addr, l_disk_state.g_disk_state. port_b_wwn_s) == NULL)) { (void) strncpy(l_disk_state. g_disk_state.port_a_wwn_s, pathlist.path_info[i]. path_addr, 16); path_a_found = l_disk_state. g_disk_state.port_a_valid = 1; } if ((path_a_found) && (!path_b_found) && (strstr(pathlist.path_info[i]. path_addr, l_disk_state.g_disk_state. port_a_wwn_s) == NULL)) { (void) strncpy(l_disk_state. g_disk_state.port_b_wwn_s, pathlist.path_info[i]. path_addr, 16); path_b_found = l_disk_state. g_disk_state.port_b_valid = 1; } if ((path_a_found) && (path_b_found)) { break; } } } free(pathlist.path_info); } mlist = mlist->next; } if (l_disk_state.g_disk_state.port_a_valid) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(141, "Status(Port A):")); (void) fprintf(stdout, "\t"); display_port_status(l_disk_state.g_disk_state.d_state_flags[FC_PORT_A]); } if (l_disk_state.g_disk_state.port_b_valid) { (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(142, "Status(Port B):")); (void) fprintf(stdout, "\t"); display_port_status(l_disk_state.g_disk_state.d_state_flags[FC_PORT_B]); } (void) display_disk_info(local_inq, l_disk_state, path_struct, pg_hdr, mode_data_avail, NULL, verbose); (void) g_free_multipath(l_disk_state.g_disk_state.multipath_list); if (!(argpwwn || argnwwn)) { break; } } (void) g_free_wwn_list(&wwn_list); return (0); } /* * display_disk_info() Prints the device specific information * for any FC_AL disk device. * * RETURNS: * none. */ void display_disk_info(L_inquiry inq, L_disk_state l_disk_state, Path_struct *path_struct, struct mode_page *pg_hdr, int mode_data_avail, char *name_buf, int options) { float num_blks; struct dlist *mlist; int port_a, port_b; struct my_mode_caching *pg8_buf; L_inquiry enc_inq; char *enc_phys_path; Path_struct *enc_path_struct; int enc_type = 0; L_inquiry80 inq80; size_t serial_len; int err; serial_len = sizeof (inq80.inq_serial); err = g_get_serial_number(path_struct->p_physical_path, inq80.inq_serial, &serial_len); if (err) { fprintf(stderr, "\n"); print_errString(err, path_struct->p_physical_path); fprintf(stderr, "\n"); exit(1); } (void) fprintf(stdout, " "); (void) fprintf(stdout, MSGSTR(3, "Vendor:")); (void) fprintf(stdout, "\t\t"); print_chars(inq.inq_vid, sizeof (inq.inq_vid), 0); (void) fprintf(stdout, MSGSTR(2115, "\n Product ID:\t\t")); print_chars(inq.inq_pid, sizeof (inq.inq_pid), 0); (void) fprintf(stdout, MSGSTR(2116, "\n WWN(Node):\t\t%s"), l_disk_state.g_disk_state.node_wwn_s); if (l_disk_state.g_disk_state.port_a_valid) { (void) fprintf(stdout, MSGSTR(2117, "\n WWN(Port A):\t\t%s"), l_disk_state.g_disk_state.port_a_wwn_s); } if (l_disk_state.g_disk_state.port_b_valid) { (void) fprintf(stdout, MSGSTR(2118, "\n WWN(Port B):\t\t%s"), l_disk_state.g_disk_state.port_b_wwn_s); } (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(2119, "Revision:")); (void) fprintf(stdout, "\t\t"); print_chars(inq.inq_revision, sizeof (inq.inq_revision), 0); (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(17, "Serial Num:")); (void) fprintf(stdout, "\t\t"); print_chars(inq80.inq_serial, serial_len, 0); num_blks = l_disk_state.g_disk_state.num_blocks; if (num_blks) { num_blks /= 2048; /* get Mbytes */ (void) fprintf(stdout, "\n "); (void) fprintf(stdout, MSGSTR(60, "Unformatted capacity:\t%6.3f MBytes"), num_blks); } (void) fprintf(stdout, "\n"); if (l_disk_state.g_disk_state.persistent_reserv_flag) { (void) fprintf(stdout, MSGSTR(2120, " Persistent Reserve:\t")); if (l_disk_state.g_disk_state.persistent_active) { (void) fprintf(stdout, MSGSTR(39, "Active")); (void) fprintf(stdout, "\n"); } if (l_disk_state.g_disk_state.persistent_registered) { (void) fprintf(stdout, MSGSTR(2121, "Found Registered Keys")); } else { (void) fprintf(stdout, MSGSTR(87, "Not being used")); } (void) fprintf(stdout, "\n"); } if ((mode_data_avail) && (pg_hdr->code == MODEPAGE_CACHING)) { pg8_buf = (struct my_mode_caching *)(int)pg_hdr; if (pg8_buf->wce) { (void) fprintf(stdout, MSGSTR(2122, " Write Cache:\t\t" "Enabled\n")); } if (pg8_buf->rcd == 0) { (void) fprintf(stdout, MSGSTR(2123, " Read Cache:\t\t" "Enabled\n")); (void) fprintf(stdout, MSGSTR(2320, " Minimum prefetch:" "\t0x%x\n" " Maximum prefetch:" "\t0x%x\n"), pg8_buf->min_prefetch, pg8_buf->max_prefetch); } } /* * When /dev/rdsk/cxtxdxsx form of input is specified * for display command the initial library version didn't * display Location information. The change is made * to display the same Location info as the non-library version. */ if (name_buf != NULL) { fprintf(stdout, MSGSTR(2125, " Location:\t\t")); if (path_struct->slot_valid) { /* * We have to do another inquiry on the enclosure (name_buf) * to determine if this device is within a daktari, or * a two sided device. */ if (!l_convert_name(name_buf, &enc_phys_path, &enc_path_struct, 0)) { if (!g_get_inquiry(enc_phys_path, &enc_inq)) { enc_type = l_get_enc_type(enc_inq); } } /* If either of the above fail, we just assume the default */ free(enc_phys_path); free(enc_path_struct); if (enc_type == DAK_ENC_TYPE) { if (path_struct->f_flag) { (void) fprintf(stdout, MSGSTR(2239, "In slot %d in the enclosure named: %s\n"), path_struct->slot, name_buf); } else { (void) fprintf(stdout, MSGSTR(2239, "In slot %d in the enclosure named: %s\n"), path_struct->slot + (MAX_DRIVES_DAK/2), name_buf); } } else { /* Default enclosure type */ (void) fprintf(stdout, path_struct->f_flag ? MSGSTR(2126, "In slot %d in the Front of the enclosure named: %s\n") : MSGSTR(2127, "In slot %d in the Rear of the enclosure named: %s\n"), path_struct->slot, name_buf); } } else { (void) fprintf(stdout, MSGSTR(2228, "In the enclosure named: %s\n"), name_buf); } } (void) fprintf(stdout, " %s\t\t%s\n", MSGSTR(35, "Device Type:"), dtype[inq.inq_dtype & DTYPE_MASK]); mlist = l_disk_state.g_disk_state.multipath_list; (void) fprintf(stdout, MSGSTR(2128, " Path(s):\n")); if (strstr(mlist->dev_path, SCSI_VHCI) != NULL) { (void) fprintf(stdout, " %s\n %s\n", mlist->logical_path, mlist->dev_path); (void) adm_print_pathlist(mlist->dev_path); } else { while (mlist) { (void) fprintf(stdout, " %s\n %s\n", mlist->logical_path, mlist->dev_path); mlist = mlist->next; } } if (Options & OPTION_V) { if (path_struct->slot_valid) { port_a = PORT_A; port_b = PORT_B; } else { port_a = FC_PORT_A; port_b = FC_PORT_B; } /* Only bother if the state is O.K. */ if ((l_disk_state.g_disk_state.port_a_valid) && (l_disk_state.g_disk_state.d_state_flags[port_a] == 0)) adm_display_verbose_disk(path_struct->p_physical_path, options); else if ((l_disk_state.g_disk_state.port_b_valid) && (l_disk_state.g_disk_state.d_state_flags[port_b] == 0)) adm_display_verbose_disk(path_struct->p_physical_path, options); } (void) fprintf(stdout, "\n"); } /* * temp_decode() Display temperature bytes 1-3 state. * * RETURNS: * none. */ void temp_decode(Temp_elem_st *temp) { if (temp->ot_fail) { (void) fprintf(stdout, MSGSTR(2129, ": FAILURE - Over Temperature")); } if (temp->ut_fail) { (void) fprintf(stdout, MSGSTR(2130, ": FAILURE - Under Temperature")); } if (temp->ot_warn) { (void) fprintf(stdout, MSGSTR(2131, ": WARNING - Over Temperature")); } if (temp->ut_warn) { (void) fprintf(stdout, MSGSTR(2132, ": WARNING - Under Temperature")); } } /* * disp_degree() Display temperature in Degrees Celsius. * * RETURNS: * none. */ void disp_degree(Temp_elem_st *temp) { int t; t = temp->degrees; t -= 20; /* re-adjust */ /* * NL_Comment * The %c is the degree symbol. */ (void) fprintf(stdout, ":%1.2d%cC ", t, 186); } /* * trans_decode() Display tranceivers state. * * RETURNS: * none. */ void trans_decode(Trans_elem_st *trans) { if (trans->disabled) { (void) fprintf(stdout, ": "); (void) fprintf(stdout, MSGSTR(34, "Disabled")); } if (trans->lol) { (void) fprintf(stdout, MSGSTR(2133, ": Not receiving a signal")); } if (trans->lsr_fail) { (void) fprintf(stdout, MSGSTR(2134, ": Laser failed")); } } /* * trans_messages() Display tranceiver status. * * NOTE: The decoding of the status assumes that the elements * are in order with the first two elements are for the * "A" IB. It also assumes the tranceivers are numbered * 0 and 1. * * RETURNS: * none. */ void trans_messages(struct l_state_struct *l_state, int ib_a_flag) { Trans_elem_st trans; int i, j, k; int count = 0; int elem_index = 0; /* Get and print messages */ for (i = 0; i < (int)l_state->ib_tbl.config.enc_num_elem; i++) { elem_index++; if (l_state->ib_tbl.config.type_hdr[i].type == ELM_TYP_FL) { if (l_state->ib_tbl.config.type_hdr[i].text_len != 0) { (void) fprintf(stdout, "\n\t\t%s\n", l_state->ib_tbl.config.text[i]); } count = k = 0; for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[i].num; j++) { /* * Only display the status for the selected IB. */ if ((count < 2 && ib_a_flag) || (count >= 2 && !ib_a_flag)) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&trans, sizeof (trans)); if (k == 0) { (void) fprintf(stdout, "\t\t%d ", k); } else { (void) fprintf(stdout, "\n\t\t%d ", k); } if (trans.code == S_OK) { (void) fprintf(stdout, MSGSTR(29, "O.K.")); revision_msg(l_state, elem_index + j); } else if ((trans.code == S_CRITICAL) || (trans.code == S_NONCRITICAL)) { (void) fprintf(stdout, MSGSTR(2135, "Failed")); revision_msg(l_state, elem_index + j); trans_decode(&trans); } else if (trans.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); } else if (trans.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); revision_msg(l_state, elem_index + j); } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); } k++; } count++; } } /* * Calculate the index to each element. */ elem_index += l_state->ib_tbl.config.type_hdr[i].num; } (void) fprintf(stdout, "\n"); } /* * temperature_messages() Display temperature status. * * RETURNS: * none. */ void temperature_messages(struct l_state_struct *l_state, int rear_flag) { Temp_elem_st temp; int i, j, last_ok = 0; int all_ok = 1; int elem_index = 0; /* Get and print messages */ for (i = 0; i < (int)l_state->ib_tbl.config.enc_num_elem; i++) { elem_index++; /* skip global */ if (l_state->ib_tbl.config.type_hdr[i].type == ELM_TYP_TS) { if (!rear_flag) { rear_flag = 1; /* only do front or rear backplane */ if (l_state->ib_tbl.config.type_hdr[i].text_len != 0) { (void) fprintf(stdout, "\t %s", l_state->ib_tbl.config.text[i]); } /* * Check global status and if not all O.K. * then print individually. */ (void) bcopy((const void *)&l_state->ib_tbl.p2_s.element[i], (void *)&temp, sizeof (temp)); for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[i].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&temp, sizeof (temp)); if ((j == 0) && (temp.code == S_OK) && (!(temp.ot_fail || temp.ot_warn || temp.ut_fail || temp.ut_warn))) { (void) fprintf(stdout, "\n\t %d", j); } else if ((j == 6) && (temp.code == S_OK) && all_ok) { (void) fprintf(stdout, "\n\t %d", j); } else if (last_ok && (temp.code == S_OK)) { (void) fprintf(stdout, "%d", j); } else { (void) fprintf(stdout, "\n\t\t%d", j); } if (temp.code == S_OK) { disp_degree(&temp); if (temp.ot_fail || temp.ot_warn || temp.ut_fail || temp.ut_warn) { temp_decode(&temp); all_ok = 0; last_ok = 0; } else { last_ok++; } } else if (temp.code == S_CRITICAL) { (void) fprintf(stdout, MSGSTR(122, "Critical failure")); last_ok = 0; all_ok = 0; } else if (temp.code == S_NONCRITICAL) { (void) fprintf(stdout, MSGSTR(89, "Non-Critical Failure")); last_ok = 0; all_ok = 0; } else if (temp.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); last_ok = 0; all_ok = 0; } else if (temp.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); last_ok = 0; all_ok = 0; } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); last_ok = 0; all_ok = 0; } } if (all_ok) { (void) fprintf(stdout, MSGSTR(2136, " (All temperatures are " "NORMAL.)")); } all_ok = 1; (void) fprintf(stdout, "\n"); } else { rear_flag = 0; } } elem_index += l_state->ib_tbl.config.type_hdr[i].num; } } /* * ib_decode() Display IB byte 3 state. * * RETURNS: * none. */ void ib_decode(Ctlr_elem_st *ctlr) { if (ctlr->overtemp_alart) { (void) fprintf(stdout, MSGSTR(2137, " - IB Over Temperature Alert ")); } if (ctlr->ib_loop_1_fail) { (void) fprintf(stdout, MSGSTR(2138, " - IB Loop 1 has failed ")); } if (ctlr->ib_loop_0_fail) { (void) fprintf(stdout, MSGSTR(2139, " - IB Loop 0 has failed ")); } } /* * mb_messages() Display motherboard * (interconnect assembly) messages. * * RETURNS: * none. */ void mb_messages(struct l_state_struct *l_state, int index, int elem_index) { int j; Interconnect_st interconnect; if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&interconnect, sizeof (interconnect)); (void) fprintf(stdout, "\t"); if (interconnect.code == S_OK) { (void) fprintf(stdout, MSGSTR(29, "O.K.")); revision_msg(l_state, elem_index + j); } else if (interconnect.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); } else if (interconnect.code == S_CRITICAL) { if (interconnect.eprom_fail != 0) { (void) fprintf(stdout, MSGSTR(2140, "Critical Failure: EEPROM failure")); } else { (void) fprintf(stdout, MSGSTR(2141, "Critical Failure: Unknown failure")); } revision_msg(l_state, elem_index + j); } else if (interconnect.code == S_NONCRITICAL) { if (interconnect.eprom_fail != 0) { (void) fprintf(stdout, MSGSTR(2142, "Non-Critical Failure: EEPROM failure")); } else { (void) fprintf(stdout, MSGSTR(2143, "Non-Critical Failure: Unknown failure")); } revision_msg(l_state, elem_index + j); } else if (interconnect.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); revision_msg(l_state, elem_index + j); } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); } (void) fprintf(stdout, "\n"); } } /* * back_plane_messages() Display back_plane messages * including the temperature's. * * RETURNS: * none. */ void back_plane_messages(struct l_state_struct *l_state, int index, int elem_index) { Bp_elem_st bp; int j; char status_string[MAXPATHLEN]; if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&bp, sizeof (bp)); if (j == 0) { (void) fprintf(stdout, MSGSTR(2144, "\tFront Backplane: ")); } else { (void) fprintf(stdout, MSGSTR(2145, "\tRear Backplane: ")); } (void) l_element_msg_string(bp.code, status_string); (void) fprintf(stdout, "%s", status_string); if (bp.code != S_NOT_INSTALLED) { revision_msg(l_state, elem_index + j); if ((bp.byp_a_enabled || bp.en_bypass_a) && !(bp.byp_b_enabled || bp.en_bypass_b)) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(130, "Bypass A enabled")); (void) fprintf(stdout, ")"); } else if ((bp.byp_b_enabled || bp.en_bypass_b) && !(bp.byp_a_enabled || bp.en_bypass_a)) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(129, "Bypass B enabled")); (void) fprintf(stdout, ")"); /* This case covers where a and b are bypassed */ } else if (bp.byp_b_enabled || bp.en_bypass_b) { (void) fprintf(stdout, MSGSTR(2146, " (Bypass's A & B enabled)")); } (void) fprintf(stdout, "\n"); temperature_messages(l_state, j); } else { (void) fprintf(stdout, "\n"); } } } /* * dpm_SSC100_messages() Display SSC100 messages * including the temperature's. * * RETURNS: * none. */ void dpm_SSC100_messages(struct l_state_struct *l_state, int index, int elem_index) { Bp_elem_st bp; int j; char status_string[MAXPATHLEN]; if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&bp, sizeof (bp)); (void) fprintf(stdout, MSGSTR(2246, " SSC100 #%d: "), j); (void) l_element_msg_string(bp.code, status_string); (void) fprintf(stdout, "%s", status_string); if (bp.code != S_NOT_INSTALLED) { revision_msg(l_state, elem_index + j); if ((bp.byp_a_enabled || bp.en_bypass_a) && !(bp.byp_b_enabled || bp.en_bypass_b)) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(130, "Bypass A enabled")); (void) fprintf(stdout, ")"); } else if ((bp.byp_b_enabled || bp.en_bypass_b) && !(bp.byp_a_enabled || bp.en_bypass_a)) { (void) fprintf(stdout, " ("); (void) fprintf(stdout, MSGSTR(129, "Bypass B enabled")); (void) fprintf(stdout, ")"); /* This case covers where a and b are bypassed */ } else if (bp.byp_b_enabled || bp.en_bypass_b) { (void) fprintf(stdout, MSGSTR(2146, " (Bypass's A & B enabled)")); } (void) fprintf(stdout, "\n"); } else { (void) fprintf(stdout, "\n"); } } temperature_messages(l_state, 0); } /* * loop_messages() Display loop messages. * * RETURNS: * none. */ void loop_messages(struct l_state_struct *l_state, int index, int elem_index) { Loop_elem_st loop; int j; if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&loop, sizeof (loop)); (void) fprintf(stdout, "\t"); if (j == 0) { if (loop.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(2147, "Loop A is not installed")); } else { if (loop.split) { (void) fprintf(stdout, MSGSTR(2148, "Loop A is configured as two separate loops.")); } else { (void) fprintf(stdout, MSGSTR(2149, "Loop A is configured as a single loop.")); } } } else { if (loop.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(2150, "Loop B is not installed")); } else { if (loop.split) { (void) fprintf(stdout, MSGSTR(2151, "Loop B is configured as two separate loops.")); } else { (void) fprintf(stdout, MSGSTR(2152, "Loop B is configured as a single loop.")); } } } (void) fprintf(stdout, "\n"); } } /* * ctlr_messages() Display ESI Controller status. * * RETURNS: * none. */ void ctlr_messages(struct l_state_struct *l_state, int index, int elem_index) { Ctlr_elem_st ctlr; int j; int ib_a_flag = 1; if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&ctlr, sizeof (ctlr)); if (j == 0) { (void) fprintf(stdout, MSGSTR(2153, "\tA: ")); } else { (void) fprintf(stdout, MSGSTR(2154, "\tB: ")); ib_a_flag = 0; } if (ctlr.code == S_OK) { (void) fprintf(stdout, MSGSTR(29, "O.K.")); /* If any byte 3 bits set display */ ib_decode(&ctlr); /* Display Version message */ revision_msg(l_state, elem_index + j); /* * Display the tranciver module state for this * IB. */ trans_messages(l_state, ib_a_flag); } else if (ctlr.code == S_CRITICAL) { (void) fprintf(stdout, MSGSTR(122, "Critical failure")); ib_decode(&ctlr); (void) fprintf(stdout, "\n"); } else if (ctlr.code == S_NONCRITICAL) { (void) fprintf(stdout, MSGSTR(89, "Non-Critical Failure")); ib_decode(&ctlr); (void) fprintf(stdout, "\n"); } else if (ctlr.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); (void) fprintf(stdout, "\n"); } else if (ctlr.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); (void) fprintf(stdout, "\n"); } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); (void) fprintf(stdout, "\n"); } } } /* * fan_decode() Display Fans bytes 1-3 state. * * RETURNS: * none. */ void fan_decode(Fan_elem_st *fan) { if (fan->fail) { (void) fprintf(stdout, MSGSTR(2155, ":Yellow LED is on")); } if (fan->speed == 0) { (void) fprintf(stdout, MSGSTR(2156, ":Fan stopped")); } else if (fan->speed < S_HI_SPEED) { (void) fprintf(stdout, MSGSTR(2157, ":Fan speed Low")); } else { (void) fprintf(stdout, MSGSTR(2158, ":Fan speed Hi")); } } /* * fan_messages() Display Fan status. * * RETURNS: * none. */ void fan_messages(struct l_state_struct *l_state, int hdr_index, int elem_index) { Fan_elem_st fan; int j; /* Get and print messages */ if (l_state->ib_tbl.config.type_hdr[hdr_index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[hdr_index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[hdr_index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&fan, sizeof (fan)); (void) fprintf(stdout, "\t%d ", j); if (fan.code == S_OK) { (void) fprintf(stdout, MSGSTR(29, "O.K.")); revision_msg(l_state, elem_index + j); } else if (fan.code == S_CRITICAL) { (void) fprintf(stdout, MSGSTR(122, "Critical failure")); fan_decode(&fan); revision_msg(l_state, elem_index + j); } else if (fan.code == S_NONCRITICAL) { (void) fprintf(stdout, MSGSTR(89, "Non-Critical Failure")); fan_decode(&fan); revision_msg(l_state, elem_index + j); } else if (fan.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); } else if (fan.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); revision_msg(l_state, elem_index + j); } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); } } (void) fprintf(stdout, "\n"); } /* * ps_decode() Display Power Supply bytes 1-3 state. * * RETURNS: * none. */ void ps_decode(Ps_elem_st *ps) { if (ps->dc_over) { (void) fprintf(stdout, MSGSTR(2159, ": DC Voltage too high")); } if (ps->dc_under) { (void) fprintf(stdout, MSGSTR(2160, ": DC Voltage too low")); } if (ps->dc_over_i) { (void) fprintf(stdout, MSGSTR(2161, ": DC Current too high")); } if (ps->ovrtmp_fail || ps->temp_warn) { (void) fprintf(stdout, MSGSTR(2162, ": Temperature too high")); } if (ps->ac_fail) { (void) fprintf(stdout, MSGSTR(2163, ": AC Failed")); } if (ps->dc_fail) { (void) fprintf(stdout, MSGSTR(2164, ": DC Failed")); } } /* * revision_msg() Print the revision message from page 7. * * RETURNS: * none. */ void revision_msg(struct l_state_struct *l_state, int index) { if (strlen((const char *) l_state->ib_tbl.p7_s.element_desc[index].desc_string)) { (void) fprintf(stdout, "(%s)", l_state->ib_tbl.p7_s.element_desc[index].desc_string); } } /* * ps_messages() Display Power Supply status. * * RETURNS: * none. */ void ps_messages(struct l_state_struct *l_state, int index, int elem_index) { Ps_elem_st ps; int j; /* Get and print Power Supply messages */ if (l_state->ib_tbl.config.type_hdr[index].text_len != 0) { (void) fprintf(stdout, "%s\n", l_state->ib_tbl.config.text[index]); } for (j = 0; j < (int)l_state->ib_tbl.config.type_hdr[index].num; j++) { (void) bcopy((const void *) &l_state->ib_tbl.p2_s.element[elem_index + j], (void *)&ps, sizeof (ps)); (void) fprintf(stdout, "\t%d ", j); if (ps.code == S_OK) { (void) fprintf(stdout, MSGSTR(29, "O.K.")); revision_msg(l_state, elem_index + j); } else if (ps.code == S_CRITICAL) { (void) fprintf(stdout, MSGSTR(122, "Critical failure")); ps_decode(&ps); revision_msg(l_state, elem_index + j); } else if (ps.code == S_NONCRITICAL) { (void) fprintf(stdout, MSGSTR(89, "Non-Critical Failure")); ps_decode(&ps); revision_msg(l_state, elem_index + j); } else if (ps.code == S_NOT_INSTALLED) { (void) fprintf(stdout, MSGSTR(30, "Not Installed")); } else if (ps.code == S_NOT_AVAILABLE) { (void) fprintf(stdout, MSGSTR(34, "Disabled")); revision_msg(l_state, elem_index + j); } else { (void) fprintf(stdout, MSGSTR(4, "Unknown status")); } } (void) fprintf(stdout, "\n"); } /* * abnormal_condition() Display any abnormal condition messages. * * RETURNS: * none. */ void abnormal_condition_display(struct l_state_struct *l_state) { (void) fprintf(stdout, "\n"); if (l_state->ib_tbl.p2_s.ui.crit) { (void) fprintf(stdout, MSGSTR(2165, " " "CRITICAL CONDITION DETECTED\n")); } if (l_state->ib_tbl.p2_s.ui.non_crit) { (void) fprintf(stdout, MSGSTR(2166, " " "WARNING: NON-CRITICAL CONDITION DETECTED\n")); } if (l_state->ib_tbl.p2_s.ui.invop) { (void) fprintf(stdout, MSGSTR(2167, " " "WARNING: Invalid Operation bit set.\n" "\tThis means an Enclosure Control page" " or an Array Control page with an invalid\n" "\tformat has previously been transmitted to the" " Enclosure Services card by a\n\tSend Diagnostic" " SCSI command.\n")); } (void) fprintf(stdout, "\n"); } /* * adm_start() Spin up the given list * of SENA devices. * * RETURNS: * none. */ int adm_start(char **argv) { char *path_phys = NULL; Path_struct *path_struct; int err = 0, retval = 0; while (*argv != NULL) { if ((err = l_convert_name(*argv, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), *argv); if (err != -1) { (void) print_errString(err, *argv); } (argv)++; retval++; continue; } VERBPRINT(MSGSTR(101, "Issuing start to:\n %s\n"), *argv); if (err = g_start(path_phys)) { (void) print_errString(err, *argv); (argv)++; retval++; continue; } (argv)++; } return (retval); } /* * adm_stop() Spin down a * given list of SENA devices. * * RETURNS: * none. */ int adm_stop(char **argv) { char *path_phys = NULL; Path_struct *path_struct; int err = 0, retval = 0; while (*argv != NULL) { if ((err = l_convert_name(*argv, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), *argv); if (err != -1) { (void) print_errString(err, *argv); } (argv)++; retval++; continue; } /* * scsi stop is not supported for tape drives. * The scsi unload op code for tape is the same as a * scsi stop for disk so this command will eject the tape. * If an eject is the desired behavior then remove the * following if block. ('mt offline' will give you * the same eject functionality). */ if (strstr(path_phys, SLSH_DRV_NAME_ST)) { errno = ENOTSUP; (void) print_errString(0, path_phys); (argv)++; continue; } VERBPRINT(MSGSTR(100, "Issuing stop to:\n %s\n"), *argv); if (err = g_stop(path_phys, 1)) { (void) print_errString(err, *argv); (argv)++; retval++; continue; } (argv)++; } return (retval); } /* * On a SOC+ chip, the port is either put into (offline) or pulled out * of (online) a loopback mode since the laser cannot be turned on or off. * As of this writing, this feature is yet to be supported by the ifp * driver on a QLogic card. * * INPUT : * Command line args and flag - LUX_P_ONLINE or LUX_P_OFFLINE * The path that is passed has to be the physical path to the port. * For example : * /devices/sbus@2,0/SUNW,socal@2,0:0 * /devices/io-unit@f,e0200000/sbi@0,0/SUNW,socal@2,0:0 * /devices/pci@1f,4000/SUNW,ifp@2:devctl * RETURNS : * Nothing */ int adm_port_offline_online(char *argv[], int flag) { int err, retval = 0; char *path_phys = NULL; char *nexus_path_ptr = NULL; Path_struct *path_struct = NULL; while (*argv != NULL) { if ((err = l_convert_name(*argv, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), *argv); if (err != -1) { (void) print_errString(err, *argv); } argv++; retval++; continue; } /* Get the nexus path - need this to print messages */ if ((err = g_get_nexus_path(path_phys, &nexus_path_ptr)) != 0) { (void) print_errString(err, *argv); retval++; goto cleanup_and_go; } if (flag == LUX_P_OFFLINE) { if ((err = g_port_offline(nexus_path_ptr))) { (void) print_errString(err, nexus_path_ptr); retval++; goto cleanup_and_go; } fprintf(stdout, MSGSTR(2223, "Port %s has been disabled\n"), nexus_path_ptr); } else if (flag == LUX_P_ONLINE) { if ((err = g_port_online(nexus_path_ptr))) { (void) print_errString(err, nexus_path_ptr); retval++; goto cleanup_and_go; } fprintf(stdout, MSGSTR(2224, "Port %s has been enabled\n"), nexus_path_ptr); } else { (void) fprintf(stderr, MSGSTR(2225, "Unknown action requested " "on port - %d\nIgnoring."), flag); retval++; } cleanup_and_go: free(path_phys); free(path_struct); free(nexus_path_ptr); argv++; } return (retval); } /* * Expert level subcommand 'luxadm -e port' * which displays all FC ports on a host and state information for * connectivity (CONNECTED or NOT CONNECTED) indicating whether there * are devices attached to the port. * * Sample output for ifp: * * /devices/pci@1f,4000/SUNW,ifp@2:devctl CONNECTED * /devices/pci@1f,2000/SUNW,ifp@1:devctl NOT CONNECTED * * Sample output for socal: * * /devices/sbus@2,0/SUNW,socal@d,10000:0 CONNECTED * /devices/sbus@2,0/SUNW,socal@d,10000:1 NOT CONNECTED * /devices/sbus@2,0/SUNW,socal@2,0:0 NOT CONNECTED * /devices/sbus@2,0/SUNW,socal@2,0:1 CONNECTED * * Note: for socal the path returned is not a devctl path as there is no * devctl path for socal. * * Sample output for fp: * * /devices/sbus@2,0/SUNW,qlc@5/fp@0,0:devctl CONNECTED * /devices/sbus@2,0/SUNW,qlc@4/fp@1,0:devctl CONNECTED */ int adm_display_port(int verbose) { /* * If another port driver needs to be searched, add it here */ static char *portdrvr_list[] = {"socal", "fp", "ifp", NULL}; portlist_t portlist; int x = 0, err = 0, retval = 0; int port_state; portlist.hbacnt = 0; /* * Look for all HBA ports as listed in portdrvr_list[] */ while (portdrvr_list[x]) { if (err = g_get_port_path(portdrvr_list[x], &portlist)) { if (err != L_PORT_DRIVER_NOT_FOUND && err != L_PHYS_PATH_NOT_FOUND) { (void) print_errString(err, portdrvr_list[x]); retval++; } } x++; } /* * For each port path found get the connection state. * If there are devices attached the state is considered connected. */ for (x = 0; x < portlist.hbacnt; x++) { if (err = g_get_port_state(portlist.physpath[x], &port_state, verbose)) { (void) print_errString(err, portlist.physpath[x]); retval++; } else { fprintf(stdout, "%-65s ", portlist.physpath[x]); if (port_state == PORT_CONNECTED) { (void) fprintf(stdout, MSGSTR(2233, "CONNECTED\n")); } else { (void) fprintf(stdout, MSGSTR(2234, "NOT CONNECTED\n")); } } } g_free_portlist(&portlist); return (retval); } /* * Expert level subcommand 'luxadm -e external_loopback * internal_loopback * no_loopback * Does just what you would think. Sets port in designated loopback * mode. * INPUT: portpath - path to device on which to set loopback mode * flag - loopback mode to set. Values are: * EXT_LOOPBACK * INT_LOOPBACK * NO_LOOPBACK * * RETURN: 0 on success * non-zero on failure */ int adm_port_loopback(char *portpath, int flag) { int err; char *path_phys = NULL; Path_struct *path_struct = NULL; int cmd; if ((err = l_convert_name(portpath, &path_phys, &path_struct, Options & PVERBOSE)) != 0) { (void) fprintf(stderr, MSGSTR(33, " Error: converting" " %s to physical path.\n" " Invalid pathname.\n"), portpath); if (err != -1) { (void) print_errString(err, portpath); } return (-1); } switch (flag) { case EXT_LOOPBACK: cmd = EXT_LPBACK; break; case INT_LOOPBACK: cmd = INT_LPBACK; break; case NO_LOOPBACK: cmd = NO_LPBACK; break; default: (void) fprintf(stderr, MSGSTR(2225, "Unknown action requested " "on port - %d\nIgnoring."), flag); free(path_phys); free(path_struct); return (-1); } if ((err = g_loopback_mode(path_phys, cmd)) != 0) { (void) print_errString(err, portpath); free(path_phys); free(path_struct); return (-1); } else { switch (flag) { case EXT_LOOPBACK: (void) fprintf(stdout, MSGSTR(2230, "External loopback mode set " "on:\n%s\n"), portpath); break; case INT_LOOPBACK: (void) fprintf(stdout, MSGSTR(2231, "Internal loopback mode set " "on:\n%s\n"), portpath); break; case NO_LOOPBACK: (void) fprintf(stdout, MSGSTR(2232, "Loopback mode unset " "on:\n%s\n"), portpath); break; default: fprintf(stderr, MSGSTR(2248, "Undefined command\n")); break; } } free(path_phys); free(path_struct); return (0); } /* * To print the pathlist and mpxio path attributes */ void adm_print_pathlist(char *dev_path) { int i, pathcnt = 1; mp_pathlist_t pathlist; int retval = 0; char temppath[MAXPATHLEN]; char wwns[(WWN_SIZE *2) +1]; uchar_t wwn_data[WWN_SIZE]; int err; int state, ext_state = 0; char *path_state[5]; path_state[0] = MSGSTR(2400, "INIT"); path_state[1] = MSGSTR(2401, "ONLINE"); path_state[2] = MSGSTR(2402, "STANDBY"); path_state[3] = MSGSTR(2403, "FAULT"); path_state[4] = MSGSTR(2404, "OFFLINE"); (void) strcpy(temppath, dev_path); retval = g_get_pathlist(temppath, &pathlist); if (retval != 0) { (void) print_errString(retval, NULL); exit(-1); } pathcnt = pathlist.path_count; for (i = 0; i < pathcnt; i++) { (void) fprintf(stdout, MSGSTR(2303, " Controller \t%s\n"), pathlist.path_info[i].path_hba); (void) fprintf(stdout, MSGSTR(2304, " Device Address\t\t%s\n"), pathlist.path_info[i].path_addr); if ((err = get_host_controller_pwwn( pathlist.path_info[i].path_hba, (uchar_t *)&wwn_data)) != 0) { if (err != ENOTSUP) { (void) print_errString(err, pathlist.path_info[i].path_hba); exit(1); } } if (!err) { copy_wwn_data_to_str(wwns, wwn_data); (void) fprintf(stdout, MSGSTR(2326, " Host controller port WWN\t%s\n"), wwns); } (void) fprintf(stdout, MSGSTR(2305, " Class\t\t\t%s\n"), pathlist.path_info[i].path_class); if (pathlist.path_info[i].path_state < MAXPATHSTATE) { (void) fprintf(stdout, MSGSTR(2306, " State\t\t\t%s\n"), path_state[pathlist.path_info[i].path_state]); } if ((err = g_stms_get_path_state(dev_path, pathlist.path_info[i].path_hba, &state, &ext_state)) != 0) { (void) print_errString(err, pathlist.path_info[i].path_hba); exit(1); } else { if ((ext_state & MDI_PATHINFO_STATE_USER_DISABLE) == MDI_PATHINFO_STATE_USER_DISABLE) { ext_state = 0; fprintf(stdout, MSGSTR(2327, " I/Os disabled on this %s path\n\n"), path_state[pathlist.path_info[i].path_state]); } } } /* Free memory for per path info properties */ free(pathlist.path_info); } /* * compare_multipath * compares path with all paths in pathlist * If there is a match, 0 is returned, otherwise 1 is returned */ int compare_multipath(char *path, struct mplist_struct *pathlist) { while (pathlist != NULL) { if (strncmp(path, pathlist->devpath, MAXPATHLEN) == 0) { return (0); } pathlist = pathlist->next; } return (1); } /* * lun_display() Prints the * information for an individual lun. * * RETURNS: * none. */ static int lun_display(Path_struct *path_struct, L_inquiry inq_struct, int verbose) { char phys_path[MAXPATHLEN], last_logical_path[MAXPATHLEN]; uchar_t *pg_buf = NULL; L_disk_state l_disk_state; struct dlist *mlist; int offset, mode_data_avail, err = 0; Mode_header_10 *mode_header_ptr; struct mode_page *pg_hdr; WWN_list *wwn_list, *list_start, *wwn_list_ptr; WWN_list *wwn_list_find; int found = 0; int argpwwn = 0, argnwwn = 0; struct mplist_struct *mplistp, *mpl, *mpln; struct dlist *dlist; strcpy(phys_path, path_struct->p_physical_path); strcpy(last_logical_path, phys_path); mplistp = mpl = mpln = (struct mplist_struct *)NULL; /* * Get path to all the FC disk and tape devices. * If there is no slash in the argument in this routine, we assume * it is a wwn argument. */ if (strstr(path_struct->argv, "/") != NULL) { if ((err = g_devices_get_all(&wwn_list)) != 0) { return (err); } } else { if ((err = g_get_wwn_list(&wwn_list, verbose)) != 0) { return (err); } } g_sort_wwn_list(&wwn_list); list_start = wwn_list; for (wwn_list_ptr = wwn_list; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argpwwn = 1; break; } else if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) == 0) { list_start = wwn_list_ptr; argnwwn = 1; break; } } for (wwn_list_ptr = list_start; wwn_list_ptr != NULL; wwn_list_ptr = wwn_list_ptr->wwn_next) { if (argpwwn) { if (strcasecmp(wwn_list_ptr->port_wwn_s, path_struct->argv) != 0) { continue; } (void) strcpy(phys_path, wwn_list_ptr->physical_path); } else if (argnwwn) { if (strstr(wwn_list_ptr->logical_path, last_logical_path) != NULL) { continue; } if (strcasecmp(wwn_list_ptr->node_wwn_s, path_struct->argv) != 0) { continue; } (void) strcpy(phys_path, wwn_list_ptr->physical_path); (void) strcpy(last_logical_path, wwn_list_ptr->logical_path); } if (argnwwn || argpwwn) { if (compare_multipath(wwn_list_ptr->logical_path, mplistp) == 0) { continue; } } mode_data_avail = 0; (void) memset(&l_disk_state, 0, sizeof (struct l_disk_state_struct)); /* * Don't call g_get_multipath if this is a SCSI_VHCI device * dlist gets alloc'ed here to retain the free at the end */ if (strstr(phys_path, SCSI_VHCI) == NULL) { if ((err = g_get_multipath(phys_path, &(l_disk_state.g_disk_state.multipath_list), wwn_list, verbose)) != 0) { return (err); } mlist = l_disk_state.g_disk_state.multipath_list; if (mlist == NULL) { l_disk_state.l_state_flag = L_NO_PATH_FOUND; N_DPRINTF(" lun_display: Error finding" " multiple paths to the disk.\n"); (void) g_free_wwn_list(&wwn_list); return (L_NO_VALID_PATH); } } else { /* Search for match on physical path name */ for (wwn_list_find = list_start; wwn_list_find != NULL; wwn_list_find = wwn_list_find->wwn_next) { if (strncmp(wwn_list_find->physical_path, phys_path, strlen(wwn_list_find->physical_path)) == 0) { found++; break; } } if (!found) { return (L_NO_VALID_PATH); } else { found = 0; } if ((dlist = (struct dlist *) calloc(1, sizeof (struct dlist))) == NULL) { return (L_MALLOC_FAILED); } if ((dlist->logical_path = (char *)calloc(1, strlen(wwn_list_find->logical_path) + 1)) == NULL) { return (L_MALLOC_FAILED); } if ((dlist->dev_path = (char *)calloc(1, strlen(phys_path) + 1)) == NULL) { return (L_MALLOC_FAILED); } strncpy(dlist->logical_path, wwn_list_find->logical_path, strlen(wwn_list_find->logical_path)); strncpy(dlist->dev_path, phys_path, strlen(phys_path)); l_disk_state.g_disk_state.multipath_list = dlist; } if (argnwwn || argpwwn) { for (mlist = l_disk_state.g_disk_state.multipath_list; mlist != NULL; mlist = mlist->next) { /* add the path to the list for compare */ if ((mpl = (struct mplist_struct *) calloc(1, sizeof (struct mplist_struct))) == NULL) { adm_mplist_free(mplistp); return (L_MALLOC_FAILED); } mpl->devpath = (char *)calloc(1, MAXPATHLEN+1); if (mpl->devpath == NULL) { adm_mplist_free(mplistp); return (L_MALLOC_FAILED); } strncpy(mpl->devpath, mlist->logical_path, strlen(mlist->logical_path)); if (mplistp == NULL) { mplistp = mpln = mpl; } else { mpln->next = mpl; mpln = mpl; } } } /* get mode page information for FC device */ if (l_get_mode_pg(phys_path, &pg_buf, verbose) == 0) { mode_header_ptr = (struct mode_header_10_struct *) (void *)pg_buf; offset = sizeof (struct mode_header_10_struct) + mode_header_ptr->bdesc_length; pg_hdr = (struct mode_page *)&pg_buf[offset]; while (offset < (mode_header_ptr->length + sizeof (mode_header_ptr->length)) && !mode_data_avail) { if (pg_hdr->code == MODEPAGE_CACHING) { mode_data_avail++; break; } offset += pg_hdr->length + sizeof (struct mode_page); pg_hdr = (struct mode_page *)&pg_buf[offset]; } } switch ((inq_struct.inq_dtype & DTYPE_MASK)) { case DTYPE_DIRECT: fprintf(stdout, MSGSTR(121, "DEVICE PROPERTIES for disk: %s\n"), path_struct->argv); break; case DTYPE_SEQUENTIAL: /* Tape */ fprintf(stdout, MSGSTR(2249, "DEVICE PROPERTIES for tape: %s\n"), path_struct->argv); break; default: fprintf(stdout, MSGSTR(2250, "DEVICE PROPERTIES for: %s\n"), path_struct->argv); break; } (void) display_lun_info(l_disk_state, path_struct, pg_hdr, mode_data_avail, wwn_list, phys_path); (void) g_free_multipath(l_disk_state.g_disk_state.multipath_list); if (!(argpwwn || argnwwn)) { break; } } /* End for wwn_list_ptr = list_start... */ (void) g_free_wwn_list(&wwn_list); adm_mplist_free(mplistp); return (0); } /* * display_lun_info() Prints the device specific information * for a lun. * * RETURNS: * none. */ void display_lun_info(L_disk_state l_disk_state, Path_struct *path_struct, struct mode_page *pg_hdr, int mode_data_avail, WWN_list *wwn_list, char *phys_path) { float lunMbytes; struct scsi_capacity_16 cap_data; struct dlist *mlist; struct my_mode_caching *pg8_buf; int err; L_inquiry inq; hrtime_t start_time, end_time; char *envdb = NULL; int peripheral_qual; L_inquiry80 inq80; size_t serial_len = sizeof (inq80.inq_serial); if ((envdb = getenv("_LUX_T_DEBUG")) != NULL) { start_time = gethrtime(); } memset(&cap_data, 0, sizeof (cap_data)); if (err = g_get_inquiry(phys_path, &inq)) { fprintf(stderr, "\n"); print_errString(err, phys_path); fprintf(stderr, "\n"); exit(1); } if (err = g_get_serial_number(phys_path, inq80.inq_serial, &serial_len)) { fprintf(stderr, "\n"); print_errString(err, phys_path); fprintf(stderr, "\n"); exit(1); } /* * check to see if the peripheral qualifier is zero * if it is non-zero, we will return with an error. */ peripheral_qual = inq.inq_dtype & ~DTYPE_MASK; if (peripheral_qual != DPQ_POSSIBLE) { fprintf(stderr, MSGSTR(2254, "\n Error: Logical Unit " "(%s) is not available.\n"), phys_path); exit(1); } fprintf(stdout, " "); fprintf(stdout, MSGSTR(3, "Vendor:")); fprintf(stdout, "\t\t"); print_chars(inq.inq_vid, sizeof (inq.inq_vid), 0); fprintf(stdout, MSGSTR(2115, "\n Product ID:\t\t")); print_chars(inq.inq_pid, sizeof (inq.inq_pid), 0); fprintf(stdout, "\n "); fprintf(stdout, MSGSTR(2119, "Revision:")); fprintf(stdout, "\t\t"); print_chars(inq.inq_revision, sizeof (inq.inq_revision), 0); fprintf(stdout, "\n "); fprintf(stdout, MSGSTR(17, "Serial Num:")); fprintf(stdout, "\t\t"); print_chars(inq80.inq_serial, serial_len, 0); if ((inq.inq_dtype & DTYPE_MASK) == DTYPE_DIRECT) { if ((err = get_lun_capacity(phys_path, &cap_data)) != 0) { print_errString(err, phys_path); exit(1); } if (cap_data.sc_capacity > 0 && cap_data.sc_lbasize > 0) { lunMbytes = cap_data.sc_capacity + 1; lunMbytes *= cap_data.sc_lbasize; lunMbytes /= (float)(1024*1024); fprintf(stdout, "\n "); fprintf(stdout, MSGSTR(60, "Unformatted capacity:\t%6.3f MBytes"), lunMbytes); } } fprintf(stdout, "\n"); if ((mode_data_avail) && (pg_hdr->code == MODEPAGE_CACHING)) { pg8_buf = (struct my_mode_caching *)(void *)pg_hdr; if (pg8_buf->wce) { fprintf(stdout, MSGSTR(2122, " Write Cache:\t\t" "Enabled\n")); } if (pg8_buf->rcd == 0) { fprintf(stdout, MSGSTR(2123, " Read Cache:\t\t" "Enabled\n")); fprintf(stdout, MSGSTR(2124, " Minimum prefetch:" "\t0x%x\n Maximum prefetch:\t0x%x\n"), pg8_buf->min_prefetch, pg8_buf->max_prefetch); } } fprintf(stdout, " %s\t\t%s\n", MSGSTR(35, "Device Type:"), dtype[inq.inq_dtype & DTYPE_MASK]); fprintf(stdout, MSGSTR(2128, " Path(s):\n")); fprintf(stdout, "\n"); if ((mlist = l_disk_state.g_disk_state.multipath_list) == NULL) { fprintf(stderr, MSGSTR(2323, "Error: No paths found (%s)"), path_struct->argv); exit(1); } if (strstr(mlist->dev_path, SCSI_VHCI) != NULL) { fprintf(stdout, " %s\n %s\n", mlist->logical_path, mlist->dev_path); adm_print_pathlist(mlist->dev_path); } else { /* * first display user's requested path * This will avoid duplicate inquiries as well */ for (mlist = l_disk_state.g_disk_state.multipath_list; mlist != NULL; mlist = mlist->next) { if ((strcmp(mlist->dev_path, path_struct->p_physical_path)) == 0) { display_path_info(mlist->dev_path, mlist->logical_path, wwn_list); break; } } /* * Now display rest of paths * skipping one already displayed */ for (mlist = l_disk_state.g_disk_state.multipath_list; mlist != NULL; mlist = mlist->next) { if ((strcmp(mlist->dev_path, path_struct->p_physical_path)) == 0) { continue; } if (err = g_get_inquiry(mlist->dev_path, &inq)) { fprintf(stderr, "\n"); print_errString(err, mlist->dev_path); fprintf(stderr, "\n"); exit(1); } display_path_info(mlist->dev_path, mlist->logical_path, wwn_list); } } fprintf(stdout, "\n"); if (envdb != NULL) { end_time = gethrtime(); fprintf(stdout, " display_lun_info: " "\t\tTime = %lld millisec\n", (end_time - start_time)/1000000); } } /* * display_path_info() Prints the path specific information * for a lun. * Note: Only applies to ssd nodes currently * * RETURNS: * none. */ static void display_path_info(char *devpath, char *logicalpath, WWN_list *wwn_list) { WWN_list *wwn_list_walk; int err; uchar_t wwn_data[WWN_SIZE]; char wwns[(WWN_SIZE *2) +1]; char drvr_path[MAXPATHLEN]; char *cptr; int status; fprintf(stdout, " %s\n", logicalpath); fprintf(stdout, " %s\n", devpath); fprintf(stdout, " %s\t\t", MSGSTR(2321, "LUN path port WWN:")); /* * Walk the wwn list passed in and print the * port wwn matching the device path */ for (wwn_list_walk = wwn_list; wwn_list_walk != NULL; wwn_list_walk = wwn_list_walk->wwn_next) { if (strcmp(wwn_list_walk->physical_path, devpath) == 0) { fprintf(stdout, "%s", wwn_list_walk->port_wwn_s); break; } } /* * newline here in case port wwn not found */ fprintf(stdout, "\n"); drvr_path[0] = '\0'; (void) strcat(drvr_path, devpath); if (((cptr = strstr(drvr_path, SLSH_DRV_NAME_SSD)) != NULL) || ((cptr = strstr(drvr_path, SLSH_DRV_NAME_ST)) != NULL)) {; *cptr = '\0'; } else { fprintf(stderr, MSGSTR(2324, "Error: Incorrect path (%s)\n"), drvr_path); exit(1); } *cptr = '\0'; if ((err = get_host_controller_pwwn(drvr_path, (uchar_t *)&wwn_data)) != 0) { print_errString(err, drvr_path); exit(1); } copy_wwn_data_to_str(wwns, wwn_data); fprintf(stdout, " %s\t%s\n", MSGSTR(2322, "Host controller port WWN:"), wwns); /* * Determine path status */ if ((err = get_path_status(devpath, &status)) != 0) { print_errString(err, devpath); exit(1); } else { fprintf(stdout, " %s\t\t", MSGSTR(2329, "Path status:")); display_port_status(status); } } /* * Retrieves the lun capacity */ static int get_lun_capacity(char *devpath, struct scsi_capacity_16 *cap_data) { int fd; if (devpath == NULL || cap_data == NULL) { return (L_INVALID_PATH); } if ((fd = g_object_open(devpath, O_RDONLY | O_NDELAY)) == -1) { return (L_OPEN_PATH_FAIL); } else { (void) g_scsi_read_capacity_1016_cmd(fd, cap_data, sizeof (struct scsi_capacity_16)); close(fd); } return (0); } /* * Retrieves the reservation status */ static int get_path_status(char *devpath, int *status) { int fd, mystatus = 0; if (devpath == NULL || status == NULL) { return (L_INVALID_PATH); } *status = 0; if ((fd = g_object_open(devpath, O_RDONLY | O_NDELAY)) == -1) { return (L_OPEN_PATH_FAIL); } else { if ((mystatus = g_scsi_tur(fd)) != 0) { if ((mystatus & L_SCSI_ERROR) && ((mystatus & ~L_SCSI_ERROR) == STATUS_CHECK)) { *status = L_NOT_READY; } else if ((mystatus & L_SCSI_ERROR) && ((mystatus & ~L_SCSI_ERROR) == STATUS_RESERVATION_CONFLICT)) { *status = L_RESERVED; } else { *status = L_SCSI_ERR; } } } close(fd); return (0); } /* * Description: * Retrieves the port wwn associated with the hba node * * hba_path: /devices/pci@8,600000/SUNW,qlc@4/fp@0,0 * pwwn: ptr to a uchar_t array of size WWN_SIZE */ static int get_host_controller_pwwn(char *hba_path, uchar_t *pwwn) { char *cptr, *portptr; int found = 0, err, devlen; char my_hba_path[MAXPATHLEN]; di_node_t node; di_prom_prop_t promprop; uchar_t *port_wwn_data = NULL; int di_ret; di_prom_handle_t ph; char *promname; uchar_t *promdata; uint_t path_type; fc_port_dev_t hba_port; if (hba_path == NULL || pwwn == NULL) { return (L_INVALID_PATH); } if ((path_type = g_get_path_type(hba_path)) == 0) { return (L_INVALID_PATH); } /* * ifp nodes do not have a port-wwn prom property * so handle them via FC4 device map */ if (path_type & FC4_XPORT_MASK) { if ((err = get_FC4_host_controller_pwwn(hba_path, pwwn)) != 0) { return (err); } else { return (0); } /* For Leadville path get the port wwn through g_get_host param. */ } else if ((path_type & FC_GEN_XPORT) && ((path_type & FC_FCA_MASK) == FC_FCA_MASK)) { /* * For Leadville path, get the port wwn through * g_get_host param. This is a general solution * to support 3rd party vendor Leadville FCA. */ my_hba_path[0] = '\0'; (void) strlcat(my_hba_path, hba_path, sizeof (my_hba_path)); (void) snprintf(my_hba_path, sizeof (my_hba_path), "%s%s", hba_path, FC_CTLR); if ((err = g_get_host_params( my_hba_path, &hba_port, 0)) != 0) { return (err); } else { (void) memcpy(pwwn, &hba_port.dev_pwwn.raw_wwn[0], WWN_SIZE); return (0); } } else if ((path_type & FC_FCA_MASK) == FC_PCI_FCA) { /* * Get port WWN through prom property */ my_hba_path[0] = '\0'; (void) strlcat(my_hba_path, hba_path, sizeof (my_hba_path)); /* * sanity check for /devices mount point */ if (strlen(my_hba_path) > (devlen = strlen("/devices"))) { cptr = &my_hba_path[devlen]; } else { return (L_INVALID_PATH); } /* * Now strip off the trailing "/fp@" */ if ((portptr = strstr(cptr, "/fp@")) != NULL) { *portptr = '\0'; } if ((node = di_init(cptr, DINFOCPYALL)) == DI_NODE_NIL) { return (L_DEV_SNAPSHOT_FAILED); } if (di_nodeid(node) == DI_SID_NODEID) { di_ret = di_prop_lookup_bytes(DDI_DEV_T_ANY, node, "port-wwn", &port_wwn_data); if (di_ret == -1 || port_wwn_data == NULL) { di_fini(node); return (L_NO_WWN_PROP_FOUND); } else { (void) memcpy(pwwn, port_wwn_data, WWN_SIZE); found++; } } else if (di_nodeid(node) == DI_PROM_NODEID) { if ((ph = di_prom_init()) == DI_PROM_HANDLE_NIL) { di_fini(node); return (L_PROM_INIT_FAILED); } for (promprop = di_prom_prop_next(ph, node, DI_PROM_PROP_NIL); promprop != DI_PROM_PROP_NIL; promprop = di_prom_prop_next(ph, node, promprop)) { if (((promname = di_prom_prop_name( promprop)) != NULL) && (strcmp(promname, "port-wwn") == 0) && (di_prom_prop_data(promprop, &promdata) == WWN_SIZE)) { /* Found port-wwn */ (void) memcpy(pwwn, promdata, WWN_SIZE); found++; break; } } di_prom_fini(ph); } di_fini(node); if (found) { return (0); } else { return (L_INVALID_PATH); } } else { return (L_INVALID_PATH_TYPE); } } /* * Description: * Retrieve pwwn via SFIOCGMAP */ static int get_FC4_host_controller_pwwn(char *hba_path, uchar_t *pwwn) { sf_al_map_t sf_map; char my_hba_path[MAXPATHLEN]; int fd; if (hba_path == NULL || pwwn == NULL) { return (L_INVALID_PATH); } (void) snprintf(my_hba_path, sizeof (my_hba_path), "%s%s", hba_path, FC_CTLR); if ((fd = g_object_open(my_hba_path, O_NDELAY | O_RDONLY)) == -1) { return (errno); } memset(&sf_map, 0, sizeof (sf_al_map_t)); if (ioctl(fd, SFIOCGMAP, &sf_map) != 0) { close(fd); return (L_SFIOCGMAP_IOCTL_FAIL); } close(fd); if (sf_map.sf_count == 0) { close(fd); return (L_SFIOCGMAP_IOCTL_FAIL); } (void) memcpy(pwwn, &sf_map.sf_hba_addr.sf_port_wwn[0], WWN_SIZE); return (0); } /* * from_ptr: ptr to uchar_t array of size WWN_SIZE * to_ptr: char ptr to string of size WWN_SIZE*2+1 */ void copy_wwn_data_to_str(char *to_ptr, const uchar_t *from_ptr) { if ((to_ptr == NULL) || (from_ptr == NULL)) return; sprintf(to_ptr, "%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x%1.2x", from_ptr[0], from_ptr[1], from_ptr[2], from_ptr[3], from_ptr[4], from_ptr[5], from_ptr[6], from_ptr[7]); } /* * Frees a previously allocated mplist_struct */ void adm_mplist_free(struct mplist_struct *mplistp) { struct mplist_struct *mplistn; while (mplistp != NULL) { mplistn = mplistp->next; if (mplistp->devpath != NULL) { free(mplistp->devpath); mplistp->devpath = NULL; } free(mplistp); mplistp = mplistn; } } int adm_reserve(char *path) { char *path_phys = NULL; int err; if ((path_phys = g_get_physical_name(path)) == NULL) { (void) fprintf(stderr, "%s: ", whoami); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), path); (void) fprintf(stderr, "\n"); return (1); } if ((err = g_reserve(path_phys)) != 0) { (void) print_errString(err, path); return (1); } return (0); } int adm_release(char *path) { char *path_phys = NULL; int err; if ((path_phys = g_get_physical_name(path)) == NULL) { (void) fprintf(stderr, "%s: ", whoami); (void) fprintf(stderr, MSGSTR(112, "Error: Invalid pathname (%s)"), path); (void) fprintf(stderr, "\n"); return (1); } if ((err = g_release(path_phys)) != 0) { (void) print_errString(err, path); return (1); } return (0); } void i18n_catopen() { (void) g_i18n_catopen(); } int adm_check_file(char **path, int flag) { int err; if (err = l_check_file(*path, flag)) { (void) print_errString(err, *path); return (-1); } (void) fprintf(stdout, MSGSTR(2212, "Download file O.K. \n\n")); return (0); } /* * Print out private loop dev dtype */ void print_private_loop_dtype_prop(uchar_t *hba_port_wwn, uchar_t *port_wwn, uchar_t dtype_prop) { if ((dtype_prop & DTYPE_MASK) < 0x10) { (void) fprintf(stdout, " 0x%-2x (%s", (dtype_prop & DTYPE_MASK), dtype[(dtype_prop & DTYPE_MASK)]); } else if ((dtype_prop & DTYPE_MASK) < 0x1f) { (void) fprintf(stdout, MSGSTR(2243, " 0x%-2x (Reserved"), (dtype_prop & DTYPE_MASK)); } else { (void) fprintf(stdout, MSGSTR(2245, " 0x%-2x (Unknown Type"), (dtype_prop & DTYPE_MASK)); } /* Check to see if this is the HBA */ if (wwnConversion(hba_port_wwn) == wwnConversion(port_wwn)) { /* MATCH */ (void) fprintf(stdout, MSGSTR(2244, ",Host Bus Adapter)\n")); } else { (void) fprintf(stdout, ")\n"); } }