/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (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 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Daktari platform platform specific environment monitoring policies */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /*LINTLIBRARY*/ /* resides in libcfgadm */ extern cfga_err_t config_change_state(cfga_cmd_t, int, char *const *, const char *, struct cfga_confirm *, struct cfga_msg *, char **, cfga_flags_t); /* Local Routine */ static int32_t update_gen_fault_led(psvc_opaque_t, char *); static void shutdown_routine(void); static int32_t update_thresholds(psvc_opaque_t hdlp, char *id, int offset); #ifdef DEBUG static int dak_policy_debug = 0; #define D1SYS_ERR(ARGS) if (dak_policy_debug & 0x1) syslog ARGS; #define D2SYS_ERR(ARGS) if (dak_policy_debug & 0x2) syslog ARGS; #else #define D1SYS_ERR(ARGS) #define D2SYS_ERR(ARGS) #endif #define I2C_PATH "/devices/pci@9,700000/ebus@1/i2c@1,30" #define I2C_NODE I2C_PATH ":devctl" #define PCF8574 I2C_PATH "/ioexp@0,%x:pcf8574" #define PCF8591 I2C_PATH "/adio@0,%x:port_0" #define FRU I2C_PATH "/fru@0,%x:fru" #define HPC3130_DEV I2C_PATH "/hotplug-controller@0,%2x:port_%1x" #define GEN_FAULT_LED "FSP_GEN_FAULT_LED" #define EMPTY_STRING "EMPTY" #define DEVICE_FAILURE_MSG gettext("WARNING: Device %s failure detected") #define DEVICE_INSERTED_MSG gettext("Device %s inserted") #define DEVICE_REMOVED_MSG gettext("Device %s removed") #define PS_UNPLUGGED_MSG gettext("Device %s unplugged") #define PS_PLUGGED_MSG gettext("Device %s Plugged in") #define DEVICE_OK_MSG gettext("Device %s OK") #define SET_LED_FAILED_MSG \ gettext("Failed to set LED state, id = %s, errno = %d\n") #define GET_PRESENCE_FAILED_MSG \ gettext("Failed to get presence attribute, id = %s, errno = %d\n") #define GET_SENSOR_FAILED_MSG \ gettext("Failed to get sensor value, id = %s, errno = %d\n") #define ADD_PS_MSG \ gettext("WARNING: Only 1 Power Supply in system. ADD a 2nd Power Supply.\n") #define REMOVE_LOAD_MSG \ gettext("WARNING: Power Supply at 95%% current. Remove some load.\n") #define PS_OVER_CURRENT_MSG \ gettext("WARNING: Power Supply overcurrent detected\n") #define DEVICE_UNKNOWN_MSG gettext("Unknown device %s instance %d\n") #define DEVICE_HANDLE_FAIL_MSG \ gettext("Failed to get device handle for %s, errno = %d\n") #define DEVTREE_NODE_CREATE_FAILED \ gettext("psvc PICL plugin: Failed to create node for %s, errno = %d") #define DEVTREE_NODE_DELETE_FAILED \ gettext("psvc PICL plugin: Failed to delete node for %s, errno = %d") #define DISK_FAULT_MSG gettext("%s: Error Reported\n") #define DISK_OK_MSG gettext("%s: Error Cleared\n") #define SET_FANSPEED_FAILED_MSG \ gettext("Failed to set fan speed, id = %s, errno = %d\n") #define GET_ATTR_FRU_FAILED_MSG gettext("Failed psvc_get_attr for FRU info\n") #define NO_FRU_INFO_MSG \ gettext("No FRU Information for %s using default module card\n") #define DAKTARI_MAX_PS 3 #define DAK_MAX_PS_I_SENSORS 4 #define DAK_MAX_DISKS 12 #define DAK_MAX_CPU_MOD 4 #define DAK_MAX_FAULT_SENSORS 3 #define DAK_MAX_FANS 10 static int co_ps = 0; static char *shutdown_string = "shutdown -y -g 60 -i 5 \"OVERTEMP condition\""; typedef struct i2c_hp { int32_t addr[2]; char name[256]; char compatible[256]; } i2c_hp_t; typedef struct seg_desc { int32_t segdesc; int16_t segoffset; int16_t seglength; } seg_desc_t; static int32_t threshold_names[] = { PSVC_HW_LO_SHUT_ATTR, PSVC_LO_SHUT_ATTR, PSVC_LO_WARN_ATTR, PSVC_NOT_USED, /* LOW MODE which is not used */ PSVC_OPTIMAL_TEMP_ATTR, PSVC_HI_WARN_ATTR, PSVC_HI_SHUT_ATTR, PSVC_HW_HI_SHUT_ATTR }; int32_t psvc_MB_update_thresholds_0(psvc_opaque_t hdlp, char *id, int offset) { int IO_offset = 0xd; int32_t err; err = update_thresholds(hdlp, id, IO_offset); return (err); } int32_t psvc_IO_update_thresholds_0(psvc_opaque_t hdlp, char *id, int offset) { int IO_offset = 0x8; int32_t err; err = update_thresholds(hdlp, id, IO_offset); return (err); } int32_t psvc_DBP_update_thresholds_0(psvc_opaque_t hdlp, char *id, int offset) { int IO_offset = 0x7; int32_t err; err = update_thresholds(hdlp, id, IO_offset); return (err); } /* * used to determine if a change of state occured. valid when states * are strings. */ static int8_t change_of_state_str(char *state1, char *check1, char *state2, char *check2) { int change = 0; if ((strcmp(state1, check1) == 0) && (strcmp(state2, check2) != 0)) change = 1; if ((strcmp(state1, check1) != 0) && (strcmp(state2, check2) == 0)) change = 1; return (change); } /* * Update thresholds tries to read the temperature thresholds from the FRU * SEEproms and then updates the thresholds in the object by overriding the * hardcoded thresholds. For Daktari it is an Error if the FRU does not * contain the segment that had the temperature thresholds. */ static int32_t update_thresholds(psvc_opaque_t hdlp, char *id, int offset) { int32_t status = PSVC_SUCCESS; fru_info_t fru_data; char *fru, seg_name[2]; int8_t seg_count, temp_array[8]; int32_t match_count, i, j, seg_desc_start = 0x1806, temp_address; int32_t seg_found, temp; boolean_t present; seg_desc_t segment; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &present); if ((status != PSVC_SUCCESS) || (present != PSVC_PRESENT)) return (status); status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &match_count, PSVC_FRU); if (status == PSVC_FAILURE) return (status); for (i = 0; i < match_count; i++) { seg_found = 0; status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &fru, PSVC_FRU, i); if (status != PSVC_SUCCESS) return (status); fru_data.buf_start = 0x1805; fru_data.buf = (char *)&seg_count; fru_data.read_size = 1; status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { return (status); } for (j = 0; (j < seg_count) && (!seg_found); j++) { fru_data.buf_start = seg_desc_start; fru_data.buf = seg_name; fru_data.read_size = 2; status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); seg_desc_start = seg_desc_start + 2; fru_data.buf_start = seg_desc_start; fru_data.buf = (char *)&segment; fru_data.read_size = sizeof (seg_desc_t); status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, "Failed psvc_get_attr for FRU info\n"); return (status); } seg_desc_start = seg_desc_start + sizeof (seg_desc_t); if (memcmp(seg_name, "SC", 2) == 0) seg_found = 1; } if (seg_found) { temp_address = segment.segoffset + offset; fru_data.buf_start = temp_address; fru_data.buf = (char *)&temp_array; fru_data.read_size = sizeof (temp_array); status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, "Failed psvc_get_attr for FRU info\n"); return (status); } else { for (j = 0; j < sizeof (temp_array); j++) { if (threshold_names[j] == PSVC_NOT_USED) continue; temp = temp_array[j]; status = psvc_set_attr(hdlp, id, threshold_names[j], &temp); if (status != PSVC_SUCCESS) { return (status); } } } } else { syslog(LOG_ERR, "No FRU Information for %s" " using default temperatures\n", id); } } return (status); } int32_t psvc_fan_init_speed_0(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; boolean_t present; char *control_id; int32_t init_speed = 0; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &present); if ((status != PSVC_SUCCESS) || (present != PSVC_PRESENT)) return (status); status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &control_id, PSVC_FAN_DRIVE_CONTROL, 0); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, control_id, PSVC_CONTROL_VALUE_ATTR, &init_speed); if (status == PSVC_FAILURE) { syslog(LOG_ERR, SET_FANSPEED_FAILED_MSG, control_id, errno); return (status); } return (status); } int32_t psvc_update_setpoint_0(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; char *temp_sensor; int32_t match_count, i, temp; int16_t lowest_temp = 500; boolean_t present; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &present); if ((status != PSVC_SUCCESS) || (present != PSVC_PRESENT)) return (status); status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &match_count, PSVC_DEV_TEMP_SENSOR); if (status == PSVC_FAILURE) return (status); for (i = 0; i < match_count; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &temp_sensor, PSVC_DEV_TEMP_SENSOR, i); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, temp_sensor, PSVC_OPTIMAL_TEMP_ATTR, &temp); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, "Failed to get Optimal temp for %s\n", temp_sensor); return (status); } if (temp < lowest_temp) lowest_temp = temp; } status = psvc_set_attr(hdlp, id, PSVC_SETPOINT_ATTR, &lowest_temp); if (status == PSVC_FAILURE) { syslog(LOG_ERR, "Failed to change setpoint for %s\n", id); return (status); } return (status); } int32_t psvc_remove_missing_nodes_0(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; char state[32]; char *physical_dev; int32_t i, device_count; char parent_path[256]; picl_nodehdl_t child_node; boolean_t present; status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &device_count, PSVC_PHYSICAL_DEVICE); if (status == PSVC_FAILURE) return (status); for (i = 0; i < device_count; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &physical_dev, PSVC_PHYSICAL_DEVICE, i); if (status != PSVC_SUCCESS) return (status); if (strncmp(physical_dev, "LTC1427", 7) == 0) continue; status = psvc_get_attr(hdlp, physical_dev, PSVC_PROBE_RESULT_ATTR, state); if (status != PSVC_SUCCESS) continue; status = psvc_get_attr(hdlp, physical_dev, PSVC_PRESENCE_ATTR, &present); if (status == PSVC_FAILURE) { syslog(LOG_ERR, GET_PRESENCE_FAILED_MSG, physical_dev, errno); return (status); } if ((strcmp(state, PSVC_ERROR) == 0) && (present == PSVC_PRESENT)) { /* convert name to node, and parent path */ psvcplugin_lookup(physical_dev, parent_path, &child_node); /* Device removed */ ptree_delete_node(child_node); } } return (status); } int32_t psvc_check_ps_hotplug_status_0(psvc_opaque_t hdlp, char *id) { char fail_valid_switch_id[PICL_PROPNAMELEN_MAX]; int32_t status = PSVC_SUCCESS; char valid_switch_state[32]; char state[32], fault[32]; int32_t led_count, j; char *led_id; char led_state[32]; boolean_t present; static int8_t hotplug_failed_count = 0; int8_t retry; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &present); if (status == PSVC_FAILURE) { syslog(LOG_ERR, GET_PRESENCE_FAILED_MSG, id, errno); return (status); } if (present == PSVC_ABSENT) { errno = ENODEV; return (PSVC_FAILURE); } snprintf(fail_valid_switch_id, sizeof (fail_valid_switch_id), "%s%s", id, "_SENSOR_VALID_SWITCH"); retry = 0; do { if (retry) sleep(1); status = psvc_get_attr(hdlp, fail_valid_switch_id, PSVC_STATE_ATTR, valid_switch_state); if (status == PSVC_FAILURE) { if (hotplug_failed_count == 0) { /* * First time the get_attr call failed * set count so that if we fail again * we will know */ hotplug_failed_count = 1; /* * We probably failed because the power * supply was just insterted or removed * before the get_attr call. We then * return from this policy successfully * knowing it will be run again shortly * with the right PS state. */ return (PSVC_SUCCESS); } else { /* * We have failed before and so this * we will consider a hardware problem * and it should be reported */ syslog(LOG_ERR, "Failed getting %s State: ", "ps_hotplug_status_0\n", fail_valid_switch_id); return (status); } } /* * Because we have successfully gotten a value from * the i2c device on the PS we will set the * failed_count to 0 */ hotplug_failed_count = 0; status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) return (status); retry++; /* * check to see if we need to retry. the conditions are: * * valid_switch_state state retry * -------------------------------------------------- * PSVC_OFF !PSVC_HOTPLUGGED yes * PSVC_ON PSVC_HOTPLUGGED yes * PSVC_OFF PSVC_HOTPLUGGED no * PSVC_ON !PSVC_HOTPLUGGED no */ } while ((retry < PSVC_NUM_OF_RETRIES) && change_of_state_str(valid_switch_state, PSVC_OFF, state, PSVC_HOTPLUGGED)); if ((strcmp(valid_switch_state, PSVC_OFF) == 0) && (strcmp(state, PSVC_HOTPLUGGED) != 0)) { strcpy(state, PSVC_HOTPLUGGED); strcpy(fault, PSVC_NO_FAULT); strcpy(led_state, PSVC_LED_OFF); status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) return (status); status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &led_count, PSVC_DEV_FAULT_LED); if (status == PSVC_FAILURE) return (status); for (j = 0; j < led_count; j++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &led_id, PSVC_DEV_FAULT_LED, j); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, led_id, PSVC_LED_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, SET_LED_FAILED_MSG, led_id, errno); return (status); } } syslog(LOG_ERR, PS_UNPLUGGED_MSG, id); return (status); } if ((strcmp(valid_switch_state, PSVC_ON) == 0) && (strcmp(state, PSVC_HOTPLUGGED) == 0)) { strcpy(state, PSVC_OK); strcpy(fault, PSVC_NO_FAULT); status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) return (status); syslog(LOG_ERR, PS_PLUGGED_MSG, id); } return (status); } int32_t psvc_ps_overcurrent_check_policy_0(psvc_opaque_t hdlp, char *system) { int32_t status = PSVC_SUCCESS; boolean_t present; static char *sensor_id[DAKTARI_MAX_PS][DAK_MAX_PS_I_SENSORS]; static char *power_supply_id[DAKTARI_MAX_PS] = {{NULL}}; int32_t i, j; int32_t amps, oc_flag = 0, ps_present = 0; static int32_t hi_warn[DAKTARI_MAX_PS][DAK_MAX_PS_I_SENSORS]; char state[32]; static int8_t overcurrent_failed_check = 0; static int8_t threshold_counter = 0; if (power_supply_id[0] == NULL) { for (i = 0; i < DAKTARI_MAX_PS; i++) { status = psvc_get_attr(hdlp, system, PSVC_ASSOC_ID_ATTR, &(power_supply_id[i]), PSVC_PS, i); if (status != PSVC_SUCCESS) return (status); for (j = 0; j < DAK_MAX_PS_I_SENSORS; ++j) { status = psvc_get_attr(hdlp, power_supply_id[i], PSVC_ASSOC_ID_ATTR, &(sensor_id[i][j]), PSVC_PS_I_SENSOR, j); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, sensor_id[i][j], PSVC_HI_WARN_ATTR, &(hi_warn[i][j])); if (status != PSVC_SUCCESS) return (status); } } } for (i = 0; i < DAKTARI_MAX_PS; i++) { status = psvc_get_attr(hdlp, power_supply_id[i], PSVC_PRESENCE_ATTR, &present); if (status == PSVC_FAILURE) { syslog(LOG_ERR, GET_PRESENCE_FAILED_MSG, power_supply_id[i], errno); return (status); } if (present == PSVC_ABSENT) { continue; } status = psvc_check_ps_hotplug_status_0(hdlp, power_supply_id[i]); if (status == PSVC_FAILURE) return (status); status = psvc_get_attr(hdlp, power_supply_id[i], PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) return (status); if (strcmp(state, PSVC_HOTPLUGGED) == 0) { continue; } else { ps_present++; } for (j = 0; j < DAK_MAX_PS_I_SENSORS; ++j) { status = psvc_get_attr(hdlp, sensor_id[i][j], PSVC_SENSOR_VALUE_ATTR, &s); if (status != PSVC_SUCCESS) { if (overcurrent_failed_check == 0) { /* * First time the get_attr call * failed set count so that if we * fail again we will know */ overcurrent_failed_check = 1; /* * We probably failed because the power * supply was just insterted or removed * before the get_attr call. We then * return from this policy successfully * knowing it will be run again shortly * with the right PS state. */ return (PSVC_SUCCESS); } else { /* * We have failed before and so this we * will consider a hardware problem and * it should be reported. */ syslog(LOG_ERR, "Failed getting %s sensor value", sensor_id[i][j]); return (status); } } /* * Because we have successfully gotten a value from the * i2c device on the PS we will set the failed_count * to 0. */ overcurrent_failed_check = 0; if (amps >= hi_warn[i][j]) { oc_flag = 1; } } } if (oc_flag) { /* * Because we observed an overcurrent * condition, we increment threshold_counter. * Once threshold_counter reaches the value * of PSVC_THRESHOLD_COUNTER we log the event. */ threshold_counter++; if (threshold_counter == PSVC_THRESHOLD_COUNTER) { threshold_counter = 0; if (ps_present == 1) { syslog(LOG_ERR, PS_OVER_CURRENT_MSG); syslog(LOG_ERR, ADD_PS_MSG); } else { syslog(LOG_ERR, PS_OVER_CURRENT_MSG); syslog(LOG_ERR, REMOVE_LOAD_MSG); } } } else { threshold_counter = 0; } return (PSVC_SUCCESS); } int32_t psvc_ps_device_fail_notifier_policy_0(psvc_opaque_t hdlp, char *system) { static char *ps_id[DAKTARI_MAX_PS] = {{NULL}}; static char *sensor_id[DAKTARI_MAX_PS][DAK_MAX_FAULT_SENSORS]; char *led_id = "FSP_POWER_FAULT_LED"; int i, j; char state[32], fault[32], previous_state[32], past_state[32]; char led_state[32]; char bad_sensors[DAK_MAX_FAULT_SENSORS][256]; int32_t status = PSVC_SUCCESS; boolean_t present; int fail_state; static int8_t device_fail_failed_check = 0; int8_t retry, should_retry; if (ps_id[0] == NULL) { for (i = 0; i < DAKTARI_MAX_PS; i++) { status = psvc_get_attr(hdlp, system, PSVC_ASSOC_ID_ATTR, &(ps_id[i]), PSVC_PS, i); if (status != PSVC_SUCCESS) return (status); for (j = 0; j < DAK_MAX_FAULT_SENSORS; j++) { status = psvc_get_attr(hdlp, ps_id[i], PSVC_ASSOC_ID_ATTR, &(sensor_id[i][j]), PSVC_DEV_FAULT_SENSOR, j); if (status != PSVC_SUCCESS) return (status); } } } for (i = 0; i < DAKTARI_MAX_PS; i++) { fail_state = 0; status = psvc_get_attr(hdlp, ps_id[i], PSVC_PRESENCE_ATTR, &present); if (status == PSVC_FAILURE) return (status); if (present == PSVC_ABSENT) { errno = ENODEV; return (PSVC_FAILURE); } status = psvc_check_ps_hotplug_status_0(hdlp, ps_id[i]); if (status == PSVC_FAILURE) return (status); status = psvc_get_attr(hdlp, ps_id[i], PSVC_STATE_ATTR, past_state); if (status == PSVC_FAILURE) return (status); if (strcmp(past_state, PSVC_HOTPLUGGED) == 0) { return (PICL_SUCCESS); } retry = 0; do { if (retry) sleep(1); fail_state = 0; should_retry = 0; for (j = 0; j < DAK_MAX_FAULT_SENSORS; ++j) { status = psvc_get_attr(hdlp, sensor_id[i][j], PSVC_SWITCH_STATE_ATTR, state); if (status != PSVC_SUCCESS) { if (device_fail_failed_check == 0) { /* * First time the get_attr call * failed set count so that * if we fail again we will know */ device_fail_failed_check = 1; /* * We probably failed because * the power supply was just * insterted or removed before * the get_attr call. We then * return from this policy * successfully knowing it will * be run again shortly * with the right PS state. */ return (PSVC_SUCCESS); } else { /* * We have failed before and * so this we will consider a * hardware problem and * it should be reported. */ syslog(LOG_ERR, "Failed in " "getting sensor state for " "%s\n", sensor_id[i][j]); return (status); } } /* * Because we have successfully gotten * a value from the i2c device on the * PS we will set the failed_count to 0. */ device_fail_failed_check = 0; /* * If we find that the sensor is on we * fill in the name of the sensor in * the bad_sensor array. If the sensor * is off we use EMPTY_STRING as a check * later on as to when NOT to print out * what is in bad_sensor[]. */ if (strcmp(state, PSVC_SWITCH_ON) == 0) { fail_state++; strlcpy(bad_sensors[j], sensor_id[i][j], sizeof (bad_sensors[j])); } else { strcpy(bad_sensors[j], EMPTY_STRING); } } retry++; /* * check to see if we need to retry. the conditions are: * * fail_state past_state retry * -------------------------------------------------- * + PSVC_OK yes * 0 PSVC_ERROR yes * + PSVC_ERROR no * 0 PSVC_OK no */ if ((fail_state > 0) && (strcmp(past_state, PSVC_OK) == 0)) { should_retry = 1; } else if ((fail_state == 0) && (strcmp(past_state, PSVC_ERROR) == 0)) { should_retry = 1; } } while ((retry < PSVC_NUM_OF_RETRIES) && should_retry); if (fail_state != 0) { strcpy(state, PSVC_ERROR); strcpy(fault, PSVC_GEN_FAULT); } else { strcpy(state, PSVC_OK); strcpy(fault, PSVC_NO_FAULT); } status = psvc_set_attr(hdlp, ps_id[i], PSVC_STATE_ATTR, state); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, ps_id[i], PSVC_FAULTID_ATTR, fault); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, ps_id[i], PSVC_PREV_STATE_ATTR, previous_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(state, previous_state) != 0) { char dev_label[32]; psvc_get_attr(hdlp, ps_id[i], PSVC_LABEL_ATTR, dev_label); if (strcmp(state, PSVC_ERROR) == 0) { syslog(LOG_ERR, DEVICE_FAILURE_MSG, dev_label); for (j = 0; j < DAK_MAX_FAULT_SENSORS; ++j) { if (strcmp(bad_sensors[j], EMPTY_STRING) != 0) syslog(LOG_ERR, "%s\n", bad_sensors[j]); } strcpy(led_state, PSVC_LED_ON); } else { syslog(LOG_ERR, DEVICE_OK_MSG, dev_label); strcpy(led_state, PSVC_LED_OFF); } status = psvc_set_attr(hdlp, led_id, PSVC_LED_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, SET_LED_FAILED_MSG, led_id, errno); return (status); } } } return (PSVC_SUCCESS); } int32_t psvc_ps_check_and_disable_dr_policy_0(psvc_opaque_t hdlp, char *id) { char state[32]; static char *name[DAKTARI_MAX_PS] = {{NULL}}; int ps_cnt = 0; int i, j; int dr_conf; int fd, rv; boolean_t present; char dev_path[sizeof (HPC3130_DEV)+8]; unsigned char controller_names[HPC3130_CONTROLLERS] = { 0xe2, 0xe6, 0xe8, 0xec }; if (name[0] == NULL) { for (i = 0; i < DAKTARI_MAX_PS; i++) { rv = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &(name[i]), PSVC_PS, i); if (rv != PSVC_SUCCESS) return (rv); } } /* * Go through the power supplies to make sure they're present * and OK. */ ps_cnt = DAKTARI_MAX_PS; for (i = 0; i < DAKTARI_MAX_PS; i++) { rv = psvc_get_attr(hdlp, name[i], PSVC_PRESENCE_ATTR, &present); if (rv != PSVC_SUCCESS) return (rv); if (present != PSVC_PRESENT) { ps_cnt--; continue; } else { rv = psvc_get_attr(hdlp, name[i], PSVC_STATE_ATTR, state); if (rv != PSVC_SUCCESS) return (rv); if (strcmp(state, PSVC_OK)) ps_cnt--; } } /* * No change in DR configuration is needed if the new power supply * count equals the current count. */ if (ps_cnt == co_ps) return (PSVC_SUCCESS); /* * Disable DR when hotplugged down to 1 power supply; enable DR when * hotplugged up from 1 supply. */ assert(ps_cnt); if ((co_ps == 0 || co_ps > 1) && ps_cnt != 1) { co_ps = ps_cnt; return (PSVC_SUCCESS); } dr_conf = (ps_cnt == 1 ? HPC3130_DR_DISABLE : HPC3130_DR_ENABLE); co_ps = ps_cnt; for (i = 0; i < HPC3130_CONTROLLERS; i++) { for (j = 0; j < HPC3130_SLOTS; j++) { (void) snprintf(dev_path, sizeof (dev_path), HPC3130_DEV, controller_names[i], j); fd = open(dev_path, O_RDWR); if (fd == -1) return (PSVC_FAILURE); rv = ioctl(fd, HPC3130_CONF_DR, &dr_conf); close(fd); if (rv == -1) return (PSVC_FAILURE); } } return (PSVC_SUCCESS); } int32_t psvc_fan_blast_shutoff_policy_0(psvc_opaque_t hdlp, char *id) { char switch_status[32]; int32_t status = PSVC_SUCCESS; status = psvc_get_attr(hdlp, id, PSVC_SWITCH_STATE_ATTR, switch_status); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, id, PSVC_SWITCH_STATE_ATTR, PSVC_SWITCH_OFF); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, id, PSVC_SWITCH_STATE_ATTR, PSVC_SWITCH_ON); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, id, PSVC_SWITCH_STATE_ATTR, PSVC_SWITCH_OFF); return (status); } int32_t psvc_fan_fault_check_policy_0(psvc_opaque_t hdlp, char *system) { static char *fan_id[DAK_MAX_FANS] = {{NULL}}; boolean_t enabled; int32_t speed; int32_t status = PSVC_SUCCESS; int r; static int8_t threshold_counter = 0; if (fan_id[0] == NULL) { for (r = 0; r < DAK_MAX_FANS; r++) { status = psvc_get_attr(hdlp, system, PSVC_ASSOC_ID_ATTR, &(fan_id[r]), PSVC_FAN, r); if (status != PSVC_SUCCESS) return (status); } } for (r = 0; r < DAK_MAX_FANS; r++) { status = psvc_get_attr(hdlp, fan_id[r], PSVC_ENABLE_ATTR, &enabled); if (status != PSVC_SUCCESS) return (status); if (enabled == PSVC_ENABLED) { uint64_t features; char *switch_id; char switch_state[32], fan_state[32]; int fan_count, fans; char *other_fan_id; char fstate[32], ffault[32]; /* * If any other fan on the fan tray has an ERROR state, * mark this fan bad and return */ psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_MATCHES_ATTR, &fan_count, PSVC_FAN_TRAY_FANS); for (fans = 0; fans < fan_count; ++fans) { status = psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_ID_ATTR, &other_fan_id, PSVC_FAN_TRAY_FANS, fans); if (status == PSVC_FAILURE) return (status); status = psvc_get_attr(hdlp, other_fan_id, PSVC_STATE_ATTR, fan_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(fan_state, PSVC_ERROR) == 0) { strlcpy(ffault, PSVC_GEN_FAULT, sizeof (ffault)); status = psvc_set_attr(hdlp, fan_id[r], PSVC_FAULTID_ATTR, ffault); if (status != PSVC_SUCCESS) return (status); strlcpy(fstate, PSVC_ERROR, sizeof (fstate)); status = psvc_set_attr(hdlp, fan_id[r], PSVC_STATE_ATTR, fstate); return (status); } } /* * Select tachometer for IO or CPU primary/secondary * fans. */ pthread_mutex_lock(&fan_mutex); status = psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_ID_ATTR, &switch_id, PSVC_FAN_PRIM_SEC_SELECTOR, 0); if (status != PSVC_FAILURE) { status = psvc_get_attr(hdlp, fan_id[r], PSVC_FEATURES_ATTR, &features); if (status == PSVC_FAILURE) { pthread_mutex_unlock(&fan_mutex); return (status); } if (features & PSVC_DEV_PRIMARY) strlcpy(switch_state, PSVC_SWITCH_ON, sizeof (switch_state)); else strlcpy(switch_state, PSVC_SWITCH_OFF, sizeof (switch_state)); status = psvc_set_attr(hdlp, switch_id, PSVC_SWITCH_STATE_ATTR, switch_state); if (status == PSVC_FAILURE) { pthread_mutex_unlock(&fan_mutex); return (status); } /* allow time for speed to be determined */ (void) poll(NULL, 0, 250); } status = psvc_get_attr(hdlp, fan_id[r], PSVC_SENSOR_VALUE_ATTR, &speed); if (status != PSVC_SUCCESS) { pthread_mutex_unlock(&fan_mutex); return (status); } pthread_mutex_unlock(&fan_mutex); if (speed == 0) { threshold_counter++; if (threshold_counter == PSVC_THRESHOLD_COUNTER) { int32_t i; int32_t led_count; char led_state[32]; char *led_id; char *slot_id; char label[32]; char state[32], fault[32]; threshold_counter = 0; strlcpy(fault, PSVC_GEN_FAULT, sizeof (fault)); status = psvc_set_attr(hdlp, fan_id[r], PSVC_FAULTID_ATTR, fault); if (status != PSVC_SUCCESS) return (status); strlcpy(state, PSVC_ERROR, sizeof (state)); status = psvc_set_attr(hdlp, fan_id[r], PSVC_STATE_ATTR, state); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, fan_id[r], PSVC_LABEL_ATTR, label); if (status != PSVC_SUCCESS) return (status); syslog(LOG_ERR, DEVICE_FAILURE_MSG, label); /* turn on fault LEDs */ psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_MATCHES_ATTR, &led_count, PSVC_DEV_FAULT_LED); strlcpy(led_state, PSVC_LED_ON, sizeof (led_state)); for (i = 0; i < led_count; ++i) { status = psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_ID_ATTR, &led_id, PSVC_DEV_FAULT_LED, i); if (status == PSVC_FAILURE) return (status); status = psvc_set_attr(hdlp, led_id, PSVC_LED_STATE_ATTR, led_state); if (status == PSVC_FAILURE) return (status); } /* turn on OK to remove LEDs */ status = psvc_get_attr(hdlp, fan_id[r], PSVC_ASSOC_ID_ATTR, &slot_id, PSVC_PARENT, 0); if (status != PSVC_SUCCESS) return (status); psvc_get_attr(hdlp, slot_id, PSVC_ASSOC_MATCHES_ATTR, &led_count, PSVC_SLOT_REMOVE_LED); strlcpy(led_state, PSVC_LED_ON, sizeof (led_state)); for (i = 0; i < led_count; ++i) { status = psvc_get_attr(hdlp, slot_id, PSVC_ASSOC_ID_ATTR, &led_id, PSVC_SLOT_REMOVE_LED, i); if (status == PSVC_FAILURE) return (status); status = psvc_set_attr(hdlp, led_id, PSVC_LED_STATE_ATTR, led_state); if (status == PSVC_FAILURE) return (status); } } } } } return (PSVC_SUCCESS); } /* * This routine takes in the PSVC handle pointer, the PS name, and the * instance number (0, 1, or 2). It simply make a psvc_get call to get the * presence of each of the children under the PS. This call will set the * presence state of the child device if it was not there when the system * was booted. */ static int handle_ps_hotplug_children_presence(psvc_opaque_t hdlp, char *id) { char *sensor_id; char fail_valid_switch_id[PICL_PROPNAMELEN_MAX]; int32_t status = PSVC_SUCCESS; boolean_t presence; int j; /* Get the Sensor Valid Switch presence */ snprintf(fail_valid_switch_id, sizeof (fail_valid_switch_id), "%s%s", id, "_SENSOR_VALID_SWITCH"); status = psvc_get_attr(hdlp, fail_valid_switch_id, PSVC_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); /* Go through each PS's fault sensors */ for (j = 0; j < DAK_MAX_FAULT_SENSORS; j++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &(sensor_id), PSVC_DEV_FAULT_SENSOR, j); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, sensor_id, PSVC_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); } /* Go through each PS's current sensors */ for (j = 0; j < DAK_MAX_PS_I_SENSORS; ++j) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &(sensor_id), PSVC_PS_I_SENSOR, j); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, sensor_id, PSVC_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); } /* Go through each PS's onboard i2c hardware */ for (j = 0; j < 3; j++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &(sensor_id), PSVC_PHYSICAL_DEVICE, j); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, sensor_id, PSVC_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); } return (status); } static i2c_hp_t devices[3][3] = { {{{0, 0x90}, "adio", "i2c-pcf8591"}, {{0, 0x70}, "ioexp", "i2c-pcf8574"}, {{0, 0xa0}, "fru", "i2c-at24c64"}}, {{{0, 0x92}, "adio", "i2c-pcf8591"}, {{0, 0x72}, "ioexp", "i2c-pcf8574"}, {{0, 0xa2}, "fru", "i2c-at24c64"}}, {{{0, 0x94}, "adio", "i2c-pcf8591"}, {{0, 0x74}, "ioexp", "i2c-pcf8574"}, {{0, 0xa4}, "fru", "i2c-at24c64"}}, }; int32_t psvc_ps_hotplug_policy_0(psvc_opaque_t hdlp, char *id) { boolean_t presence, previous_presence; int32_t status = PSVC_SUCCESS; char label[32], state[32], fault[32]; int32_t ps_instance, led_count; char *switch_id, *led_id; int i; picl_nodehdl_t parent_node; char parent_path[256], ps_path[256]; picl_nodehdl_t child_node; devctl_hdl_t bus_handle, dev_handle; devctl_ddef_t ddef_hdl; char pcf8574_devpath[256], pcf8591_devpath[256], fru_devpath[256]; int8_t retry; status = psvc_get_attr(hdlp, id, PSVC_PREV_PRESENCE_ATTR, &previous_presence); if (status != PSVC_SUCCESS) return (status); retry = 0; do { if (retry) sleep(1); status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); retry++; } while ((retry < PSVC_NUM_OF_RETRIES) && (presence != previous_presence)); if (presence == previous_presence) { /* No change */ return (status); } status = psvc_get_attr(hdlp, id, PSVC_LABEL_ATTR, label); if (status != PSVC_SUCCESS) return (status); /* convert name to node, and parent path */ psvcplugin_lookup(id, parent_path, &child_node); if (presence == PSVC_PRESENT) { /* * Run this code if Power Supply was just added into the * System. This code toggles hotplug switch and adds the * PS and it's children to the picl tree. We then goto adding * device drivers at bottom of the routine. */ int32_t switch_count; char state[32], fault[32]; char switch_state[32]; /* may detect presence before all connections are made */ (void) poll(NULL, 0, 500); /* Device added */ syslog(LOG_ERR, DEVICE_INSERTED_MSG, label); strcpy(state, PSVC_OK); status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status != PSVC_SUCCESS) return (status); strcpy(fault, PSVC_NO_FAULT); status = psvc_set_attr(hdlp, id, PSVC_FAULTID_ATTR, fault); if (status != PSVC_SUCCESS) return (status); /* Enable i2c bus */ psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &switch_count, PSVC_HOTPLUG_ENABLE_SWITCH); for (i = 0; i < switch_count; ++i) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &switch_id, PSVC_HOTPLUG_ENABLE_SWITCH, i); if (status == PSVC_FAILURE) return (status); strcpy(switch_state, PSVC_SWITCH_OFF); status = psvc_set_attr(hdlp, switch_id, PSVC_SWITCH_STATE_ATTR, switch_state); if (status == PSVC_FAILURE) return (status); strcpy(switch_state, PSVC_SWITCH_ON); status = psvc_set_attr(hdlp, switch_id, PSVC_SWITCH_STATE_ATTR, switch_state); if (status == PSVC_FAILURE) return (status); } ptree_get_node_by_path(parent_path, &parent_node); ptree_add_node(parent_node, child_node); snprintf(ps_path, sizeof (ps_path), "%s/%s", parent_path, id); psvcplugin_add_children(ps_path); } else { /* * Run this code if PS was just removed from the system. We * delete the device from the picl tree and then shut off * all fault lights associated with the PS. We also set the * device state to PSVC_REMOVED so that if we hit overcurrent * or fault checking code we can do a psvc call to see that * the device has not offically been added into the system. * We then will drop to code lower in the routine to remove * the device drivers for this PS. */ /* Device removed */ syslog(LOG_ERR, DEVICE_REMOVED_MSG, label); ptree_delete_node(child_node); psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &led_count, PSVC_DEV_FAULT_LED); for (i = 0; i < led_count; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &led_id, PSVC_DEV_FAULT_LED, i); if (status != PSVC_SUCCESS) { return (status); } status = psvc_set_attr(hdlp, led_id, PSVC_LED_STATE_ATTR, PSVC_OFF); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, SET_LED_FAILED_MSG, led_id, errno); return (status); } } strcpy(state, PSVC_OK); strcpy(fault, PSVC_NO_FAULT); status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, id, PSVC_FAULTID_ATTR, fault); if (status != PSVC_SUCCESS) return (status); } status = psvc_set_attr(hdlp, id, PSVC_PREV_PRESENCE_ATTR, &presence); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, id, PSVC_INSTANCE_ATTR, &ps_instance); if (status != PSVC_SUCCESS) return (status); if (presence != PSVC_PRESENT) { /* * This is the additional code needed to remove the PS from * the system. It removes the device drivers from the * device tree. */ snprintf(pcf8574_devpath, sizeof (pcf8574_devpath), PCF8574, devices[ps_instance][1].addr[1]); snprintf(pcf8591_devpath, sizeof (pcf8591_devpath), PCF8591, devices[ps_instance][0].addr[1]); snprintf(fru_devpath, sizeof (fru_devpath), FRU, devices[ps_instance][2].addr[1]); dev_handle = devctl_device_acquire(pcf8591_devpath, 0); if (dev_handle == NULL) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, pcf8591_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else if ((devctl_device_remove(dev_handle)) && (errno != ENXIO)) { syslog(LOG_ERR, DEVTREE_NODE_DELETE_FAILED, pcf8591_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else { devctl_release(dev_handle); status = PSVC_SUCCESS; } dev_handle = devctl_device_acquire(pcf8574_devpath, 0); if (dev_handle == NULL) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, pcf8574_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else if ((devctl_device_remove(dev_handle)) && (errno != ENXIO)) { syslog(LOG_ERR, DEVTREE_NODE_DELETE_FAILED, pcf8574_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else { devctl_release(dev_handle); status = PSVC_SUCCESS; } dev_handle = devctl_device_acquire(fru_devpath, 0); if (dev_handle == NULL) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, fru_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else if ((devctl_device_remove(dev_handle)) && (errno != ENXIO)) { syslog(LOG_ERR, DEVTREE_NODE_DELETE_FAILED, fru_devpath, errno); devctl_release(dev_handle); return (PSVC_FAILURE); } else { devctl_release(dev_handle); status = PSVC_SUCCESS; } return (status); } /* * This code is to update the presences of power supply child * devices in the event that picld was started without a power * supply present. This call makes the devices available * after that initial insertion. */ status = handle_ps_hotplug_children_presence(hdlp, id); if (status == PSVC_FAILURE) { return (status); } /* * We fall through to here if the device has been inserted. * Add the devinfo tree node entry for the seeprom and attach * the i2c seeprom driver */ bus_handle = devctl_bus_acquire(I2C_NODE, 0); if (bus_handle == NULL) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, I2C_NODE, errno); return (PSVC_FAILURE); } /* Create the deivce nodes for all 3 i2c parts on the PS */ for (i = 0; i < 3; i++) { ddef_hdl = devctl_ddef_alloc(devices[ps_instance][i].name, 0); if (ddef_hdl == NULL) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, devices[ps_instance][i].name, errno); return (PSVC_FAILURE); } status = devctl_ddef_string(ddef_hdl, "compatible", devices[ps_instance][i].compatible); if (status == -1) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, devices[ps_instance][i].name, errno); return (PSVC_FAILURE); } status = devctl_ddef_int_array(ddef_hdl, "reg", 2, devices[ps_instance][i].addr); if (status == -1) { syslog(LOG_ERR, DEVICE_HANDLE_FAIL_MSG, devices[ps_instance][i].name, errno); return (PSVC_FAILURE); } if (devctl_bus_dev_create(bus_handle, ddef_hdl, 0, &dev_handle)) { syslog(LOG_ERR, DEVTREE_NODE_CREATE_FAILED, devices[ps_instance][i].name, errno); return (PSVC_FAILURE); } else devctl_release(dev_handle); devctl_ddef_free(ddef_hdl); } devctl_release(bus_handle); return (status); } static void shutdown_routine() { static boolean_t shutdown_flag = 0; if (!(shutdown_flag)) { system(shutdown_string); shutdown_flag = 1; } } /* * This policy checks temperature sensors to see if the fault attribute * is set to either High or Low Shutdown. If so then it shuts the system * down with a 1 minute warning period */ int32_t psvc_shutdown_policy(psvc_opaque_t hdlp, char *id) { int32_t status; char fault[32] = {0}; boolean_t pr; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &pr); if ((status != PSVC_SUCCESS) || (pr != PSVC_PRESENT)) { return (status); } status = psvc_get_attr(hdlp, id, PSVC_FAULTID_ATTR, fault); if (status != PSVC_SUCCESS) return (status); if ((strcmp(fault, PSVC_TEMP_LO_SHUT) == 0) || (strcmp(fault, PSVC_TEMP_HI_SHUT) == 0)) { shutdown_routine(); } return (PSVC_SUCCESS); } int32_t psvc_check_disk_fault_policy_0(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; int32_t i; char curr_state[32], prev_state[32], led_state[32]; char disk_fault[32], disk_state[32]; static char *disk_id[DAK_MAX_DISKS] = {{NULL}}; static char *led_id[DAK_MAX_DISKS] = {{NULL}}; static char *parent_id[DAK_MAX_DISKS] = {{NULL}}; boolean_t present; int8_t retry; /* * Check which disk faulted, now get the disks. * We are now going to get disk, disk parent, * parent's leds, and check to see if parent's leds are on */ if (disk_id[0] == NULL) { for (i = 0; i < DAK_MAX_DISKS; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &(disk_id[i]), PSVC_DISK, i); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, disk_id[i], PSVC_ASSOC_ID_ATTR, &(parent_id[i]), PSVC_PARENT, 0); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, parent_id[i], PSVC_ASSOC_ID_ATTR, &(led_id[i]), PSVC_SLOT_FAULT_LED, 0); if (status != PSVC_SUCCESS) return (status); } } for (i = 0; i < DAK_MAX_DISKS; i++) { curr_state[0] = 0; prev_state[0] = 0; status = psvc_get_attr(hdlp, disk_id[i], PSVC_PRESENCE_ATTR, &present); if (status != PSVC_SUCCESS) return (status); if (present == PSVC_ABSENT) continue; /* * Check if whether or not the led is on. * If so, then this disk has a problem and * set its fault and error states to bad. * If not, then set fault and error states to good. * If the disk underwent a change in state, then * print out what state it's now in. */ status = psvc_get_attr(hdlp, disk_id[i], PSVC_STATE_ATTR, prev_state); if (status != PSVC_SUCCESS) return (status); retry = 0; do { if (retry) sleep(1); status = psvc_get_attr(hdlp, led_id[i], PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); retry++; /* * check to see if we need to retry. the conditions are: * * prev_state led_state retry * -------------------------------------------------- * PSVC_ERROR PSVC_LED_ON yes * PSVC_OK PSVC_LED_OFF yes * PSVC_ERROR PSVC_LED_OFF no * PSVC_OK PSVC_LED_ON no */ } while ((retry < PSVC_NUM_OF_RETRIES) && change_of_state_str(prev_state, PSVC_OK, led_state, PSVC_LED_ON)); /* * Set the disk's state and fault id according to * what we found the disk fault sensor (disk_slot_fault_led) * to be. */ if (strcmp(led_state, PSVC_LED_ON) == 0) { strcpy(disk_fault, PSVC_GEN_FAULT); strcpy(disk_state, PSVC_ERROR); } else { strcpy(disk_fault, PSVC_NO_FAULT); strcpy(disk_state, PSVC_OK); } status = psvc_set_attr(hdlp, disk_id[i], PSVC_STATE_ATTR, disk_state); if (status != PSVC_SUCCESS) return (status); status = psvc_set_attr(hdlp, disk_id[i], PSVC_FAULTID_ATTR, disk_fault); if (status != PSVC_SUCCESS) return (status); /* * Check disk states. If they differ, then print out * the current state of the disk */ status = psvc_get_attr(hdlp, disk_id[i], PSVC_PREV_STATE_ATTR, prev_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(disk_state, prev_state) != 0) { if (strcmp(disk_state, PSVC_ERROR) == 0) { syslog(LOG_ERR, DISK_FAULT_MSG, disk_id[i]); } else { syslog(LOG_ERR, DISK_OK_MSG, disk_id[i]); } } } return (PSVC_SUCCESS); } int32_t psvc_update_FSP_fault_led_policy_0(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; int32_t i; int32_t dev_count, fault_state = 0; char *dev_id; char dev_state[32], led_state[32]; boolean_t present; status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &dev_count, PSVC_DEV_FAULT_SENSOR); if (status != PSVC_SUCCESS) return (status); fault_state = 0; for (i = 0; i < dev_count; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &dev_id, PSVC_DEV_FAULT_SENSOR, i); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, dev_id, PSVC_PRESENCE_ATTR, &present); if (status != PSVC_SUCCESS) return (status); if (present == PSVC_ABSENT) continue; status = psvc_get_attr(hdlp, dev_id, PSVC_STATE_ATTR, dev_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(dev_state, PSVC_ERROR) == 0) { fault_state = 1; } } if (fault_state == 1) { status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(led_state, PSVC_OFF) == 0) { status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, PSVC_ON); if (status != PSVC_SUCCESS) return (status); } } else { status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(led_state, PSVC_ON) == 0) { status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, PSVC_OFF); if (status != PSVC_SUCCESS) return (status); } } status = update_gen_fault_led(hdlp, GEN_FAULT_LED); return (status); } int32_t update_gen_fault_led(psvc_opaque_t hdlp, char *id) { int32_t status = PSVC_SUCCESS; int32_t i; int32_t led_count, fault_state; char *led_id; char led_state[32]; status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &led_count, PSVC_DEV_FAULT_SENSOR); if (status != PSVC_SUCCESS) return (status); fault_state = 0; for (i = 0; i < led_count; i++) { status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &led_id, PSVC_DEV_FAULT_SENSOR, i); if (status != PSVC_SUCCESS) return (status); status = psvc_get_attr(hdlp, led_id, PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(led_state, PSVC_ON) == 0) { fault_state = 1; } } if (fault_state == 1) { status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(led_state, PSVC_OFF) == 0) { status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, PSVC_ON); if (status != PSVC_SUCCESS) return (status); } } else { status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, led_state); if (status != PSVC_SUCCESS) return (status); if (strcmp(led_state, PSVC_ON) == 0) { status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, PSVC_OFF); if (status != PSVC_SUCCESS) return (status); } } return (status); } /* * This function detects whether the module present in the dakatari's * CPU slot is a CPU module or a Zulu (XVR-4000). * Based on this detection it also sets the appropriate temperature sensors * to HOTPLUGGED, so that it works properly with check_temp() function */ #define MAX_MODULE_SIZE 20 #define MAX_TEMP_SENSOR_SIZE 30 int32_t psvc_update_cpu_module_card_node_0(psvc_opaque_t hdlp, char *id) { int32_t set_temp_sensor_properties(psvc_opaque_t, char *); int32_t remove_module_node(psvc_opaque_t, char *); int32_t status = PSVC_SUCCESS; fru_info_t fru_data; char *fru, seg_name[2]; int8_t seg_count, module_card; int32_t match_count, i, j, seg_desc_start = 0x1806, module_address; int32_t seg_found; boolean_t present; seg_desc_t segment; char other_module_id[MAX_MODULE_SIZE]; char cpu_temp_sensor1[MAX_TEMP_SENSOR_SIZE]; char cpu_temp_sensor2[MAX_TEMP_SENSOR_SIZE]; char zulu_temp_sensor1[MAX_TEMP_SENSOR_SIZE]; char zulu_temp_sensor2[MAX_TEMP_SENSOR_SIZE]; int offset = 0x7; status = psvc_get_attr(hdlp, id, PSVC_PRESENCE_ATTR, &present); if ((status != PSVC_SUCCESS) || (present != PSVC_PRESENT)) { return (status); } status = psvc_get_attr(hdlp, id, PSVC_ASSOC_MATCHES_ATTR, &match_count, PSVC_FRU); if (status == PSVC_FAILURE) { return (status); } for (i = 0; i < match_count; i++) { seg_found = 0; status = psvc_get_attr(hdlp, id, PSVC_ASSOC_ID_ATTR, &fru, PSVC_FRU, i); if (status != PSVC_SUCCESS) return (status); fru_data.buf_start = 0x1805; fru_data.buf = (char *)&seg_count; fru_data.read_size = 1; status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { return (status); } for (j = 0; (j < seg_count) && (!seg_found); j++) { fru_data.buf_start = seg_desc_start; fru_data.buf = seg_name; fru_data.read_size = 2; status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, GET_ATTR_FRU_FAILED_MSG); return (status); } seg_desc_start = seg_desc_start + 2; fru_data.buf_start = seg_desc_start; fru_data.buf = (char *)&segment; fru_data.read_size = sizeof (seg_desc_t); status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, GET_ATTR_FRU_FAILED_MSG); return (status); } seg_desc_start = seg_desc_start + sizeof (seg_desc_t); if (memcmp(seg_name, "SC", 2) == 0) seg_found = 1; } if (seg_found) { module_address = segment.segoffset + offset; fru_data.buf_start = module_address; fru_data.buf = (char *)&module_card; fru_data.read_size = 1; status = psvc_get_attr(hdlp, fru, PSVC_FRU_INFO_ATTR, &fru_data); if (status != PSVC_SUCCESS) { syslog(LOG_ERR, GET_ATTR_FRU_FAILED_MSG); return (status); } } else { syslog(LOG_ERR, NO_FRU_INFO_MSG, id); } } if (strcmp(id, "ZULU_1_3_MOD_CARD") == 0) { strlcpy(other_module_id, "CPU_1_3_MOD_CARD", MAX_MODULE_SIZE); strlcpy(cpu_temp_sensor1, "CPU1_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(cpu_temp_sensor2, "CPU3_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(zulu_temp_sensor1, "ZULU1_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(zulu_temp_sensor2, "ZULU3_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); } if (strcmp(id, "ZULU_4_6_MOD_CARD") == 0) { strlcpy(other_module_id, "CPU_4_6_MOD_CARD", MAX_MODULE_SIZE); strlcpy(cpu_temp_sensor1, "CPU4_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(cpu_temp_sensor2, "CPU6_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(zulu_temp_sensor1, "ZULU4_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); strlcpy(zulu_temp_sensor2, "ZULU6_DIE_TEMPERATURE_SENSOR", MAX_TEMP_SENSOR_SIZE); } /* * If the module in the CPU slot is a Zulu (XVR-4000), then * location 0x1EB0 in its FRUid prom has a value 0xFB. * If Zulu (XVR-4000) is detected, delete the CPU node, otherwise * delete the Zulu node. Also set the temperature sensor value to * HOTPLUGGED for absent temperature sensors. */ if ((module_card & 0xff) == 0xfb) { status = set_temp_sensor_properties(hdlp, cpu_temp_sensor1); if (status == PSVC_FAILURE) { return (status); } status = set_temp_sensor_properties(hdlp, cpu_temp_sensor2); if (status == PSVC_FAILURE) { return (status); } /* * Remove CPU node */ status = remove_module_node(hdlp, other_module_id); if (status == PSVC_FAILURE) { return (status); } } else { status = set_temp_sensor_properties(hdlp, zulu_temp_sensor1); if (status == PSVC_FAILURE) { return (status); } status = set_temp_sensor_properties(hdlp, zulu_temp_sensor2); if (status == PSVC_FAILURE) { return (status); } /* * Remove Zulu (XVR-4000) node */ status = remove_module_node(hdlp, id); if (status == PSVC_FAILURE) { return (status); } } return (PSVC_SUCCESS); } /* * Remove the CPU slot's module node */ int32_t remove_module_node(psvc_opaque_t hdlp, char *id) { char parent_path[256]; picl_nodehdl_t child_node; /* convert name to node, and parent path */ psvcplugin_lookup(id, parent_path, &child_node); /* Device removed */ ptree_delete_node(child_node); return (PSVC_SUCCESS); } /* * Set absent temperature sensor values to HOTPLUGGED */ int32_t set_temp_sensor_properties(psvc_opaque_t hdlp, char *id) { char state[32]; int32_t status = PSVC_SUCCESS; status = psvc_get_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) { return (status); } if (strcmp(state, PSVC_HOTPLUGGED) != 0) { strcpy(state, PSVC_HOTPLUGGED); status = psvc_set_attr(hdlp, id, PSVC_STATE_ATTR, state); if (status == PSVC_FAILURE) { return (status); } } return (PSVC_SUCCESS); }