/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Useful debugging Stuff */ #ifdef DEBUG int sysc_debug_info = 1; int sysc_debug_print_level = 0; #endif /* * Function prototypes */ static int sysctrl_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result); static int sysctrl_attach(dev_info_t *devi, ddi_attach_cmd_t cmd); static int sysctrl_detach(dev_info_t *devi, ddi_detach_cmd_t cmd); static int sysctrl_open(dev_t *, int, int, cred_t *); static int sysctrl_close(dev_t, int, int, cred_t *); static int sysctrl_ioctl(dev_t, int, intptr_t, int, cred_t *, int *); static uint_t system_high_handler(caddr_t arg); static uint_t spur_delay(caddr_t arg); static void spur_retry(void *); static uint_t spur_reenable(caddr_t arg); static void spur_long_timeout(void *); static uint_t spur_clear_count(caddr_t arg); static uint_t ac_fail_handler(caddr_t arg); static void ac_fail_retry(void *); static uint_t ac_fail_reenable(caddr_t arg); static uint_t ps_fail_int_handler(caddr_t arg); static uint_t ps_fail_poll_handler(caddr_t arg); static uint_t ps_fail_handler(struct sysctrl_soft_state *softsp, int fromint); enum power_state compute_power_state(struct sysctrl_soft_state *softsp, int plus_load); static void ps_log_state_change(struct sysctrl_soft_state *softsp, int index, int present); static void ps_log_pres_change(struct sysctrl_soft_state *softsp, int index, int present); static void ps_fail_retry(void *); static uint_t pps_fanfail_handler(caddr_t arg); static void pps_fanfail_retry(void *); static uint_t pps_fanfail_reenable(caddr_t arg); static void pps_fan_poll(void *); static void pps_fan_state_change(struct sysctrl_soft_state *softsp, int index, int fan_ok); static uint_t bd_insert_handler(caddr_t arg); static void bd_insert_timeout(void *); static void bd_remove_timeout(void *); static uint_t bd_insert_normal(caddr_t arg); static void sysctrl_add_kstats(struct sysctrl_soft_state *softsp); static int sysctrl_kstat_update(kstat_t *ksp, int rw); static int psstat_kstat_update(kstat_t *, int); static void init_remote_console_uart(struct sysctrl_soft_state *); static void blink_led_timeout(void *); static uint_t blink_led_handler(caddr_t arg); static void sysctrl_thread_wakeup(void *type); static void sysctrl_overtemp_poll(void); static void sysctrl_keyswitch_poll(void); static void update_key_state(struct sysctrl_soft_state *); static void sysctrl_abort_seq_handler(char *msg); static void nvram_update_powerfail(struct sysctrl_soft_state *softsp); static void toggle_board_green_leds(int); void bd_remove_poll(struct sysctrl_soft_state *); static void sysc_slot_info(int nslots, int *start, int *limit, int *incr); extern void sysc_board_connect_supported_init(void); static void rcons_reinit(struct sysctrl_soft_state *softsp); /* * Configuration data structures */ static struct cb_ops sysctrl_cb_ops = { sysctrl_open, /* open */ sysctrl_close, /* close */ nulldev, /* strategy */ nulldev, /* print */ nulldev, /* dump */ nulldev, /* read */ nulldev, /* write */ sysctrl_ioctl, /* ioctl */ nodev, /* devmap */ nodev, /* mmap */ nodev, /* segmap */ nochpoll, /* poll */ ddi_prop_op, /* cb_prop_op */ 0, /* streamtab */ D_MP|D_NEW, /* Driver compatibility flag */ CB_REV, /* rev */ nodev, /* cb_aread */ nodev /* cb_awrite */ }; static struct dev_ops sysctrl_ops = { DEVO_REV, /* devo_rev */ 0, /* refcnt */ sysctrl_info, /* getinfo */ nulldev, /* identify */ nulldev, /* probe */ sysctrl_attach, /* attach */ sysctrl_detach, /* detach */ nulldev, /* reset */ &sysctrl_cb_ops, /* cb_ops */ (struct bus_ops *)0, /* bus_ops */ nulldev /* power */ }; void *sysctrlp; /* sysctrl soft state hook */ /* # of ticks to silence spurious interrupts */ static clock_t spur_timeout_hz; /* # of ticks to count spurious interrupts to print message */ static clock_t spur_long_timeout_hz; /* # of ticks between AC failure polling */ static clock_t ac_timeout_hz; /* # of ticks between Power Supply Failure polling */ static clock_t ps_fail_timeout_hz; /* * # of ticks between Peripheral Power Supply failure polling * (used both for interrupt retry timeout and polling function) */ static clock_t pps_fan_timeout_hz; /* # of ticks delay after board insert interrupt */ static clock_t bd_insert_delay_hz; /* # of secs to wait before restarting poll if we cannot clear interrupts */ static clock_t bd_insert_retry_hz; /* # of secs between Board Removal polling */ static clock_t bd_remove_timeout_hz; /* # of secs between toggle of OS LED */ static clock_t blink_led_timeout_hz; /* overtemp polling routine timeout delay */ static clock_t overtemp_timeout_hz; /* key switch polling routine timeout delay */ static clock_t keyswitch_timeout_hz; /* Specify which system interrupt condition to monitor */ int enable_sys_interrupt = SYS_AC_PWR_FAIL_EN | SYS_PPS_FAN_FAIL_EN | SYS_PS_FAIL_EN | SYS_SBRD_PRES_EN; /* Should the overtemp_poll thread be running? */ static int sysctrl_do_overtemp_thread = 1; /* Should the keyswitch_poll thread be running? */ static int sysctrl_do_keyswitch_thread = 1; /* * This timeout ID is for board remove polling routine. It is * protected by the fhc_bdlist mutex. * XXX - This will not work for wildfire. A different scheme must be * used since there will be multiple sysctrl nodes, each with its * own list of hotplugged boards to scan. */ static timeout_id_t bd_remove_to_id = 0; /* * If this is set, the system will not shutdown when insufficient power * condition persists. */ int disable_insufficient_power_reboot = 0; /* * Set this to enable suspend/resume */ int sysctrl_enable_detach_suspend = 0; /* * Set this to reflect the OBP initialized HOTPLUG_DISABLED_PROPERTY and * during dynamic detection */ int sysctrl_hotplug_disabled = FALSE; /* Indicates whether or not the overtemp thread has been started */ static int sysctrl_overtemp_thread_started = 0; /* Indicates whether or not the key switch thread has been started */ static int sysctrl_keyswitch_thread_started = 0; /* *Mutex used to protect the soft state list */ static kmutex_t sslist_mutex; /* The CV is used to wakeup the overtemp thread when needed. */ static kcondvar_t overtemp_cv; /* The CV is used to wakeup the key switch thread when needed. */ static kcondvar_t keyswitch_cv; /* This mutex is used to protect the sysctrl_ddi_branch_init variable */ static kmutex_t sysctrl_branch_mutex; /* * This variable is set after all existing branches in the system have * been discovered and held via e_ddi_branch_hold(). This happens on * first open() of any sysctrl minor node. */ static int sysctrl_ddi_branch_init; /* * Linked list of all syctrl soft state structures. * Used for polling sysctrl state changes, i.e. temperature. */ struct sysctrl_soft_state *sys_list = NULL; extern struct mod_ops mod_driverops; static struct modldrv modldrv = { &mod_driverops, /* Type of module. This one is a driver */ "Clock Board %I%", /* name of module */ &sysctrl_ops, /* driver ops */ }; static struct modlinkage modlinkage = { MODREV_1, /* rev */ (void *)&modldrv, NULL }; #ifndef lint char _depends_on[] = "drv/fhc"; #endif /* lint */ /* * These are the module initialization routines. */ int _init(void) { int error; if ((error = ddi_soft_state_init(&sysctrlp, sizeof (struct sysctrl_soft_state), 1)) != 0) return (error); error = mod_install(&modlinkage); if (error != 0) { ddi_soft_state_fini(&sysctrlp); return (error); } mutex_init(&sysctrl_branch_mutex, NULL, MUTEX_DRIVER, NULL); return (0); } int _fini(void) { int error; if ((error = mod_remove(&modlinkage)) != 0) return (error); ddi_soft_state_fini(&sysctrlp); mutex_destroy(&sysctrl_branch_mutex); return (0); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } /* ARGSUSED */ static int sysctrl_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { dev_t dev; int instance; if (infocmd == DDI_INFO_DEVT2INSTANCE) { dev = (dev_t)arg; instance = GETINSTANCE(dev); *result = (void *)(uintptr_t)instance; return (DDI_SUCCESS); } return (DDI_FAILURE); } static int sysctrl_attach(dev_info_t *devi, ddi_attach_cmd_t cmd) { struct sysctrl_soft_state *softsp; int instance; uchar_t tmp_reg; dev_info_t *dip; char *propval; int proplen; int slot_num; int start; /* start index for scan loop */ int limit; /* board number limit for scan loop */ int incr; /* amount to incr each pass thru loop */ void set_clockbrd_info(void); switch (cmd) { case DDI_ATTACH: break; case DDI_RESUME: /* XXX see sysctrl:DDI_SUSPEND for special h/w treatment */ return (DDI_SUCCESS); default: return (DDI_FAILURE); } instance = ddi_get_instance(devi); if (ddi_soft_state_zalloc(sysctrlp, instance) != DDI_SUCCESS) return (DDI_FAILURE); softsp = GETSOFTC(instance); /* Set the dip in the soft state */ softsp->dip = devi; /* Set up the parent dip */ softsp->pdip = ddi_get_parent(softsp->dip); DPRINTF(SYSCTRL_ATTACH_DEBUG, ("sysctrl: devi= 0x%p\n, softsp=0x%p\n", devi, softsp)); /* First set all of the timeout values */ spur_timeout_hz = drv_usectohz(SPUR_TIMEOUT_USEC); spur_long_timeout_hz = drv_usectohz(SPUR_LONG_TIMEOUT_USEC); ac_timeout_hz = drv_usectohz(AC_TIMEOUT_USEC); ps_fail_timeout_hz = drv_usectohz(PS_FAIL_TIMEOUT_USEC); pps_fan_timeout_hz = drv_usectohz(PPS_FAN_TIMEOUT_USEC); bd_insert_delay_hz = drv_usectohz(BRD_INSERT_DELAY_USEC); bd_insert_retry_hz = drv_usectohz(BRD_INSERT_RETRY_USEC); bd_remove_timeout_hz = drv_usectohz(BRD_REMOVE_TIMEOUT_USEC); blink_led_timeout_hz = drv_usectohz(BLINK_LED_TIMEOUT_USEC); overtemp_timeout_hz = drv_usectohz(OVERTEMP_TIMEOUT_SEC * MICROSEC); keyswitch_timeout_hz = drv_usectohz(KEYSWITCH_TIMEOUT_USEC); /* * Map in the registers sets that OBP hands us. According * to the sun4u device tree spec., the register sets are as * follows: * * 0 Clock Frequency Registers (contains the bit * for enabling the remote console reset) * 1 Misc (has all the registers that we need * 2 Clock Version Register */ if (ddi_map_regs(softsp->dip, 0, (caddr_t *)&softsp->clk_freq1, 0, 0)) { cmn_err(CE_WARN, "sysctrl%d: unable to map clock frequency " "registers", instance); goto bad0; } if (ddi_map_regs(softsp->dip, 1, (caddr_t *)&softsp->csr, 0, 0)) { cmn_err(CE_WARN, "sysctrl%d: unable to map internal" "registers", instance); goto bad1; } /* * There is a new register for newer vintage clock board nodes, * OBP register set 2 in the clock board node. * */ (void) ddi_map_regs(softsp->dip, 2, (caddr_t *)&softsp->clk_ver, 0, 0); /* * Fill in the virtual addresses of the registers in the * sysctrl_soft_state structure. We do not want to calculate * them on the fly. This way we waste a little memory, but * avoid bugs down the road. */ softsp->clk_freq2 = (uchar_t *)((caddr_t)softsp->clk_freq1 + SYS_OFF_CLK_FREQ2); softsp->status1 = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_STAT1); softsp->status2 = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_STAT2); softsp->ps_stat = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_PSSTAT); softsp->ps_pres = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_PSPRES); softsp->pppsr = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_PPPSR); softsp->temp_reg = (uchar_t *)((caddr_t)softsp->csr + SYS_OFF_TEMP); set_clockbrd_info(); /* * Enable the hardware watchdog gate on the clock board if * map_wellknown has detected that watchdog timer is available * and user wants it to be enabled. */ if (watchdog_available && watchdog_enable) *(softsp->clk_freq2) |= TOD_RESET_EN; else *(softsp->clk_freq2) &= ~TOD_RESET_EN; /* Check for inherited faults from the PROM. */ if (*softsp->csr & SYS_LED_MID) { reg_fault(0, FT_PROM, FT_SYSTEM); } /* * calculate and cache the number of slots on this system */ switch (SYS_TYPE(*softsp->status1)) { case SYS_16_SLOT: softsp->nslots = 16; break; case SYS_8_SLOT: softsp->nslots = 8; break; case SYS_4_SLOT: /* check the clk_version register - if the ptr is valid */ if ((softsp->clk_ver != NULL) && (SYS_TYPE2(*softsp->clk_ver) == SYS_PLUS_SYSTEM)) { softsp->nslots = 5; } else { softsp->nslots = 4; } break; case SYS_TESTBED: default: softsp->nslots = 0; break; } /* create the fault list kstat */ create_ft_kstats(instance); /* * Do a priming read on the ADC, and throw away the first value * read. This is a feature of the ADC hardware. After a power cycle * it does not contains valid data until a read occurs. */ tmp_reg = *(softsp->temp_reg); /* Wait 30 usec for ADC hardware to stabilize. */ DELAY(30); /* shut off all interrupt sources */ *(softsp->csr) &= ~(SYS_PPS_FAN_FAIL_EN | SYS_PS_FAIL_EN | SYS_AC_PWR_FAIL_EN | SYS_SBRD_PRES_EN); tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif /* * Now register our high interrupt with the system. */ if (ddi_add_intr(devi, 0, &softsp->iblock, &softsp->idevice, (uint_t (*)(caddr_t))nulldev, NULL) != DDI_SUCCESS) goto bad2; mutex_init(&softsp->csr_mutex, NULL, MUTEX_DRIVER, (void *)softsp->iblock); ddi_remove_intr(devi, 0, softsp->iblock); if (ddi_add_intr(devi, 0, &softsp->iblock, &softsp->idevice, system_high_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad3; if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->spur_id, &softsp->spur_int_c, NULL, spur_delay, (caddr_t)softsp) != DDI_SUCCESS) goto bad4; mutex_init(&softsp->spur_int_lock, NULL, MUTEX_DRIVER, (void *)softsp->spur_int_c); if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->spur_high_id, NULL, NULL, spur_reenable, (caddr_t)softsp) != DDI_SUCCESS) goto bad5; if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->spur_long_to_id, NULL, NULL, spur_clear_count, (caddr_t)softsp) != DDI_SUCCESS) goto bad6; /* * Now register low-level ac fail handler */ if (ddi_add_softintr(devi, DDI_SOFTINT_HIGH, &softsp->ac_fail_id, NULL, NULL, ac_fail_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad7; if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->ac_fail_high_id, NULL, NULL, ac_fail_reenable, (caddr_t)softsp) != DDI_SUCCESS) goto bad8; /* * Now register low-level ps fail handler */ if (ddi_add_softintr(devi, DDI_SOFTINT_HIGH, &softsp->ps_fail_int_id, &softsp->ps_fail_c, NULL, ps_fail_int_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad9; mutex_init(&softsp->ps_fail_lock, NULL, MUTEX_DRIVER, (void *)softsp->ps_fail_c); if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->ps_fail_poll_id, NULL, NULL, ps_fail_poll_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad10; /* * Now register low-level pps fan fail handler */ if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->pps_fan_id, NULL, NULL, pps_fanfail_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad11; if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->pps_fan_high_id, NULL, NULL, pps_fanfail_reenable, (caddr_t)softsp) != DDI_SUCCESS) goto bad12; /* * Based upon a check for a current share backplane, advise * that system does not support hot plug * */ if ((*(softsp->pppsr) & SYS_NOT_CURRENT_S) != 0) { cmn_err(CE_NOTE, "Hot Plug not supported in this system"); sysctrl_hotplug_disabled = TRUE; } /* * If the trigger circuit is busted or the NOT_BRD_PRES line * is stuck then OBP will publish this property stating that * hot plug is not available. If this happens we will complain * to the console and register a system fault. We will also * not enable the board insert interrupt for this session. */ if (ddi_prop_op(DDI_DEV_T_ANY, softsp->dip, PROP_LEN_AND_VAL_ALLOC, DDI_PROP_DONTPASS, HOTPLUG_DISABLED_PROPERTY, (caddr_t)&propval, &proplen) == DDI_PROP_SUCCESS) { cmn_err(CE_WARN, "Hot Plug Unavailable [%s]", propval); reg_fault(0, FT_HOT_PLUG, FT_SYSTEM); sysctrl_hotplug_disabled = TRUE; enable_sys_interrupt &= ~SYS_SBRD_PRES_EN; kmem_free(propval, proplen); } sysc_board_connect_supported_init(); fhc_bd_sc_register(sysc_policy_update, softsp); sysc_slot_info(softsp->nslots, &start, &limit, &incr); /* Prime the board list. */ fhc_bdlist_prime(start, limit, incr); /* * Set up a board remove timeout call. */ (void) fhc_bdlist_lock(-1); DPRINTF(SYSCTRL_ATTACH_DEBUG, ("attach: start bd_remove_poll()...")); bd_remove_poll(softsp); fhc_bdlist_unlock(); /* * Now register low-level board insert handler */ if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->sbrd_pres_id, NULL, NULL, bd_insert_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad13; if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->sbrd_gone_id, NULL, NULL, bd_insert_normal, (caddr_t)softsp) != DDI_SUCCESS) goto bad14; /* * Now register led blink handler (interrupt level) */ if (ddi_add_softintr(devi, DDI_SOFTINT_LOW, &softsp->blink_led_id, &softsp->sys_led_c, NULL, blink_led_handler, (caddr_t)softsp) != DDI_SUCCESS) goto bad15; mutex_init(&softsp->sys_led_lock, NULL, MUTEX_DRIVER, (void *)softsp->sys_led_c); /* initialize the bit field for all pps fans to assumed good */ softsp->pps_fan_saved = softsp->pps_fan_external_state = SYS_AC_FAN_OK | SYS_KEYSW_FAN_OK; /* prime the power supply state machines */ if (enable_sys_interrupt & SYS_PS_FAIL_EN) ddi_trigger_softintr(softsp->ps_fail_poll_id); /* kick off the OS led blinker */ softsp->sys_led = FALSE; ddi_trigger_softintr(softsp->blink_led_id); /* Now enable selected interrupt sources */ mutex_enter(&softsp->csr_mutex); *(softsp->csr) |= enable_sys_interrupt & (SYS_AC_PWR_FAIL_EN | SYS_PS_FAIL_EN | SYS_PPS_FAN_FAIL_EN | SYS_SBRD_PRES_EN); tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); /* Initialize the temperature */ init_temp_arrays(&softsp->tempstat); /* * initialize key switch shadow state */ softsp->key_shadow = KEY_BOOT; /* * Now add this soft state structure to the front of the linked list * of soft state structures. */ if (sys_list == (struct sysctrl_soft_state *)NULL) { mutex_init(&sslist_mutex, NULL, MUTEX_DEFAULT, NULL); } mutex_enter(&sslist_mutex); softsp->next = sys_list; sys_list = softsp; mutex_exit(&sslist_mutex); /* Setup the kstats for this device */ sysctrl_add_kstats(softsp); /* kick off the PPS fan poll routine */ pps_fan_poll(softsp); if (sysctrl_overtemp_thread_started == 0) { /* * set up the overtemp condition variable before * starting the thread. */ cv_init(&overtemp_cv, NULL, CV_DRIVER, NULL); /* * start up the overtemp polling thread */ (void) thread_create(NULL, 0, (void (*)())sysctrl_overtemp_poll, NULL, 0, &p0, TS_RUN, minclsyspri); sysctrl_overtemp_thread_started++; } if (sysctrl_keyswitch_thread_started == 0) { extern void (*abort_seq_handler)(); /* * interpose sysctrl's abort sequence handler */ abort_seq_handler = sysctrl_abort_seq_handler; /* * set up the key switch condition variable before * starting the thread */ cv_init(&keyswitch_cv, NULL, CV_DRIVER, NULL); /* * start up the key switch polling thread */ (void) thread_create(NULL, 0, (void (*)())sysctrl_keyswitch_poll, NULL, 0, &p0, TS_RUN, minclsyspri); sysctrl_keyswitch_thread_started++; } /* * perform initialization to allow setting of powerfail-time */ if ((dip = ddi_find_devinfo("options", -1, 0)) == NULL) softsp->options_nodeid = (pnode_t)NULL; else softsp->options_nodeid = (pnode_t)ddi_get_nodeid(dip); DPRINTF(SYSCTRL_ATTACH_DEBUG, ("sysctrl: Creating devices start:%d, limit:%d, incr:%d\n", start, limit, incr)); /* * Create minor node for each system attachment points */ for (slot_num = start; slot_num < limit; slot_num = slot_num + incr) { char name[30]; (void) sprintf(name, "slot%d", slot_num); if (ddi_create_minor_node(devi, name, S_IFCHR, (PUTINSTANCE(instance) | slot_num), DDI_NT_ATTACHMENT_POINT, 0) == DDI_FAILURE) { cmn_err(CE_WARN, "sysctrl%d: \"%s\" " "ddi_create_minor_node failed", instance, name); goto bad16; } } ddi_report_dev(devi); /* * Remote console is inherited from POST */ if ((*(softsp->clk_freq2) & RCONS_UART_EN) == 0) { softsp->enable_rcons_atboot = FALSE; cmn_err(CE_WARN, "Remote console not active"); } else softsp->enable_rcons_atboot = TRUE; return (DDI_SUCCESS); bad16: cv_destroy(&keyswitch_cv); cv_destroy(&overtemp_cv); mutex_destroy(&sslist_mutex); mutex_destroy(&softsp->sys_led_lock); ddi_remove_softintr(softsp->blink_led_id); bad15: ddi_remove_softintr(softsp->sbrd_gone_id); bad14: ddi_remove_softintr(softsp->sbrd_pres_id); bad13: ddi_remove_softintr(softsp->pps_fan_high_id); bad12: ddi_remove_softintr(softsp->pps_fan_id); bad11: ddi_remove_softintr(softsp->ps_fail_poll_id); bad10: mutex_destroy(&softsp->ps_fail_lock); ddi_remove_softintr(softsp->ps_fail_int_id); bad9: ddi_remove_softintr(softsp->ac_fail_high_id); bad8: ddi_remove_softintr(softsp->ac_fail_id); bad7: ddi_remove_softintr(softsp->spur_long_to_id); bad6: ddi_remove_softintr(softsp->spur_high_id); bad5: mutex_destroy(&softsp->spur_int_lock); ddi_remove_softintr(softsp->spur_id); bad4: ddi_remove_intr(devi, 0, softsp->iblock); bad3: mutex_destroy(&softsp->csr_mutex); bad2: ddi_unmap_regs(softsp->dip, 1, (caddr_t *)&softsp->csr, 0, 0); if (softsp->clk_ver != NULL) ddi_unmap_regs(softsp->dip, 2, (caddr_t *)&softsp->clk_ver, 0, 0); bad1: ddi_unmap_regs(softsp->dip, 0, (caddr_t *)&softsp->clk_freq1, 0, 0); bad0: ddi_soft_state_free(sysctrlp, instance); ddi_remove_minor_node(dip, NULL); cmn_err(CE_WARN, "sysctrl%d: Initialization failure. Some system level events," " {AC Fail, Fan Failure, PS Failure} not detected", instance); return (DDI_FAILURE); } struct sysc_hold { int start; int limit; int incr; int hold; }; static int sysctrl_hold_rele_branches(dev_info_t *dip, void *arg) { int *rp, len, slot, i; struct sysc_hold *ap = (struct sysc_hold *)arg; /* * For Sunfire, top nodes on board are always children of root dip */ ASSERT(ddi_get_parent(dip) == ddi_root_node()); /* * Skip non-PROM and "central" nodes */ if (!ndi_dev_is_prom_node(dip) || strcmp(ddi_node_name(dip), "central") == 0) return (DDI_WALK_PRUNECHILD); /* * Extract board # from reg property. */ if (ddi_getlongprop(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS | DDI_PROP_CANSLEEP, "reg", (caddr_t)&rp, &len) != DDI_SUCCESS) { DPRINTF(SYSC_DEBUG, ("devinfo node %s(%p) has no reg" " property\n", ddi_node_name(dip), (void *)dip)); return (DDI_WALK_PRUNECHILD); } slot = (*rp - 0x1c0) >> 2; kmem_free(rp, len); ASSERT(ap->start >= 0 && ap->start < ap->limit); for (i = ap->start; i < ap->limit; i = i + ap->incr) { if (i == slot) break; } if (i >= ap->limit) { DPRINTF(SYSC_DEBUG, ("sysctrl_hold_rele: Invalid board # (%d)" " for node %s(%p)\n", slot, ddi_node_name(dip), (void *)dip)); return (DDI_WALK_PRUNECHILD); } if (ap->hold) { ASSERT(!e_ddi_branch_held(dip)); e_ddi_branch_hold(dip); } else { ASSERT(e_ddi_branch_held(dip)); e_ddi_branch_rele(dip); } return (DDI_WALK_PRUNECHILD); } /* ARGSUSED */ static int sysctrl_detach(dev_info_t *devi, ddi_detach_cmd_t cmd) { #ifdef SYSCTRL_SUPPORTS_DETACH dev_info_t *rdip; struct sysc_hold arg = {0}; struct sysctrl_soft_state *softsp; #endif /* SYSCTRL_SUPPORTS_DETACH */ if (sysctrl_enable_detach_suspend == FALSE) return (DDI_FAILURE); switch (cmd) { case DDI_SUSPEND: /* * XXX we don't presently save the state of the remote * console because it is a constant function of POST. * XXX we don't deal with the hardware watchdog here * either. It should be handled in hardclk. */ return (DDI_SUCCESS); case DDI_DETACH: break; default: return (DDI_FAILURE); } #ifdef SYSCTRL_SUPPORTS_DETACH /* * XXX If sysctrl ever supports detach, this code should be enabled * This is only the portion of the detach code dealing with * the DDI branch routines. Other parts of detach will need * to be added. */ /* * Walk immediate children of root devinfo node, releasing holds * on branches acquired in first sysctrl_open(). */ instance = ddi_get_instance(dip); softsp = GETSOFTC(instance); if (softsp == NULL) { cmn_err(CE_WARN, "sysctrl%d device not attached", instance); return (DDI_FAILURE); } sysc_slot_info(softsp->nslots, &arg.start, &arg.limit, &arg.incr); arg.hold = 0; rdip = ddi_root_node(); ndi_devi_enter(rdip, &circ); ddi_walk_devs(ddi_get_child(rdip), sysctrl_hold_rele_branches, &arg); ndi_devi_exit(rdip, circ); sysctrl_ddi_branch_init = 0; return (DDI_SUCCESS); #endif /* SYSCTRL_SUPPORTS_DETACH */ return (DDI_FAILURE); } /* ARGSUSED */ static int sysctrl_open(dev_t *devp, int flag, int otyp, cred_t *credp) { int instance; int slot; dev_t dev; int circ; dev_info_t *rdip; struct sysc_hold arg = {0}; struct sysctrl_soft_state *softsp; dev = *devp; /* * We checked against the instance softstate structure since there * will only be one instance of sysctrl (clock board) in UEXX00 * * Since we only create minor devices for existing slots on a * particular system, we don't need to worry about non-exist slot. */ instance = GETINSTANCE(dev); slot = GETSLOT(dev); /* Is the instance attached? */ if ((softsp = GETSOFTC(instance)) == NULL) { cmn_err(CE_WARN, "sysctrl%d device not attached", instance); return (ENXIO); } /* verify that otyp is appropriate */ if (otyp != OTYP_CHR) { return (EINVAL); } if (!fhc_bd_valid(slot)) return (ENXIO); /* * On first open of a sysctrl minor walk immediate children of the * devinfo root node and hold all branches of interest. */ mutex_enter(&sysctrl_branch_mutex); if (!sysctrl_ddi_branch_init) { sysctrl_ddi_branch_init = 1; sysc_slot_info(softsp->nslots, &arg.start, &arg.limit, &arg.incr); arg.hold = 1; rdip = ddi_root_node(); ndi_devi_enter(rdip, &circ); ddi_walk_devs(ddi_get_child(rdip), sysctrl_hold_rele_branches, &arg); ndi_devi_exit(rdip, circ); } mutex_exit(&sysctrl_branch_mutex); return (DDI_SUCCESS); } /* ARGSUSED */ static int sysctrl_close(dev_t devp, int flag, int otyp, cred_t *credp) { return (DDI_SUCCESS); } /* * This function will acquire the lock and set the in_transition * bit for the specified slot. If the slot is being used, * we return FALSE; else set in_transition and return TRUE. */ static int sysc_enter_transition(int slot) { fhc_bd_t *list; sysc_cfga_stat_t *sysc_stat_lk; fhc_bd_t *glist; sysc_cfga_stat_t *sysc_stat_gk; /* mutex lock the structure */ list = fhc_bdlist_lock(slot); if ((slot != -1) && (list == NULL)) { fhc_bdlist_unlock(); return (FALSE); } glist = fhc_bd_clock(); if (slot == -1) list = glist; /* change the in_transition bit */ sysc_stat_lk = &list->sc; sysc_stat_gk = &glist->sc; if ((sysc_stat_lk->in_transition == TRUE) || (sysc_stat_gk->in_transition == TRUE)) { fhc_bdlist_unlock(); return (FALSE); } else { sysc_stat_lk->in_transition = TRUE; return (TRUE); } } /* * This function will release the lock and clear the in_transition * bit for the specified slot. */ static void sysc_exit_transition(int slot) { fhc_bd_t *list; sysc_cfga_stat_t *sysc_stat_lk; ASSERT(fhc_bdlist_locked()); if (slot == -1) list = fhc_bd_clock(); else list = fhc_bd(slot); sysc_stat_lk = &list->sc; ASSERT(sysc_stat_lk->in_transition == TRUE); sysc_stat_lk->in_transition = FALSE; fhc_bdlist_unlock(); } static int sysc_pkt_init(sysc_cfga_pkt_t *pkt, intptr_t arg, int flag) { #ifdef _MULTI_DATAMODEL if (ddi_model_convert_from(flag & FMODELS) == DDI_MODEL_ILP32) { sysc_cfga_cmd32_t sysc_cmd32; if (ddi_copyin((void *)arg, &sysc_cmd32, sizeof (sysc_cfga_cmd32_t), flag) != 0) { return (EFAULT); } pkt->cmd_cfga.force = sysc_cmd32.force; pkt->cmd_cfga.test = sysc_cmd32.test; pkt->cmd_cfga.arg = sysc_cmd32.arg; pkt->cmd_cfga.errtype = sysc_cmd32.errtype; pkt->cmd_cfga.outputstr = (char *)(uintptr_t)sysc_cmd32.outputstr; } else #endif /* _MULTI_DATAMODEL */ if (ddi_copyin((void *)arg, &(pkt->cmd_cfga), sizeof (sysc_cfga_cmd_t), flag) != 0) { return (EFAULT); } pkt->errbuf = kmem_zalloc(SYSC_OUTPUT_LEN, KM_SLEEP); return (0); } static int sysc_pkt_fini(sysc_cfga_pkt_t *pkt, intptr_t arg, int flag) { int ret = TRUE; #ifdef _MULTI_DATAMODEL if (ddi_model_convert_from(flag & FMODELS) == DDI_MODEL_ILP32) { if (ddi_copyout(&(pkt->cmd_cfga.errtype), (void *)&(((sysc_cfga_cmd32_t *)arg)->errtype), sizeof (sysc_err_t), flag) != 0) { ret = FALSE; } } else #endif if (ddi_copyout(&(pkt->cmd_cfga.errtype), (void *)&(((sysc_cfga_cmd_t *)arg)->errtype), sizeof (sysc_err_t), flag) != 0) { ret = FALSE; } if ((ret != FALSE) && ((pkt->cmd_cfga.outputstr != NULL) && (ddi_copyout(pkt->errbuf, pkt->cmd_cfga.outputstr, SYSC_OUTPUT_LEN, flag) != 0))) { ret = FALSE; } kmem_free(pkt->errbuf, SYSC_OUTPUT_LEN); return (ret); } /* ARGSUSED */ static int sysctrl_ioctl(dev_t devt, int cmd, intptr_t arg, int flag, cred_t *cred_p, int *rval_p) { struct sysctrl_soft_state *softsp; sysc_cfga_pkt_t sysc_pkt; fhc_bd_t *fhc_list = NULL; sysc_cfga_stat_t *sc_list = NULL; fhc_bd_t *bdp; sysc_cfga_stat_t *sc = NULL; int instance; int slot; int retval = 0; int i; instance = GETINSTANCE(devt); softsp = GETSOFTC(instance); if (softsp == NULL) { cmn_err(CE_CONT, "sysctrl_ioctl(%d): NULL softstate ptr!\n", (int)GETSLOT(devt)); return (ENXIO); } slot = GETSLOT(devt); /* * First switch is to do correct locking and do ddi_copyin() */ switch (cmd) { case SYSC_CFGA_CMD_GETSTATUS: /* mutex lock the whole list */ if (sysc_enter_transition(-1) != TRUE) { retval = EBUSY; goto cleanup_exit; } /* allocate the memory before acquiring mutex */ fhc_list = kmem_zalloc(sizeof (fhc_bd_t) * fhc_max_boards(), KM_SLEEP); sc_list = kmem_zalloc(sizeof (sysc_cfga_stat_t) * fhc_max_boards(), KM_SLEEP); break; case SYSC_CFGA_CMD_EJECT: case SYSC_CFGA_CMD_INSERT: retval = ENOTSUP; goto cleanup_exit; case SYSC_CFGA_CMD_CONNECT: case SYSC_CFGA_CMD_DISCONNECT: case SYSC_CFGA_CMD_UNCONFIGURE: case SYSC_CFGA_CMD_CONFIGURE: case SYSC_CFGA_CMD_TEST: case SYSC_CFGA_CMD_TEST_SET_COND: case SYSC_CFGA_CMD_QUIESCE_TEST: /* ioctls allowed if caller has write permission */ if (!(flag & FWRITE)) { retval = EPERM; goto cleanup_exit; } retval = sysc_pkt_init(&sysc_pkt, arg, flag); if (retval != 0) goto cleanup_exit; /* grasp lock and set in_transition bit */ if (sysc_enter_transition(cmd == SYSC_CFGA_CMD_QUIESCE_TEST ? -1 : slot) != TRUE) { retval = EBUSY; SYSC_ERR_SET(&sysc_pkt, SYSC_ERR_INTRANS); goto cleanup_copyout; } /* get the status structure for the slot */ bdp = fhc_bd(slot); sc = &bdp->sc; break; /* POSIX definition: return ENOTTY if unsupported command */ default: retval = ENOTTY; goto cleanup_exit; } /* * Second switch is to call the underlayer workhorse. */ switch (cmd) { case SYSC_CFGA_CMD_GETSTATUS: for (i = 0; i < fhc_max_boards(); i++) { if (fhc_bd_valid(i)) { bdp = fhc_bd(i); if (fhc_bd_is_jtag_master(i)) bdp->sc.no_detach = 1; else bdp->sc.no_detach = 0; bcopy((caddr_t)&bdp->sc, &sc_list[i], sizeof (sysc_cfga_stat_t)); } else { sc_list[i].board = -1; sc_list[i].rstate = SYSC_CFGA_RSTATE_EMPTY; } } sysc_exit_transition(-1); break; case SYSC_CFGA_CMD_EJECT: case SYSC_CFGA_CMD_INSERT: retval = ENOTSUP; goto cleanup_exit; case SYSC_CFGA_CMD_CONNECT: retval = sysc_policy_connect(softsp, &sysc_pkt, sc); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_DISCONNECT: retval = sysc_policy_disconnect(softsp, &sysc_pkt, sc); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_UNCONFIGURE: retval = sysc_policy_unconfigure(softsp, &sysc_pkt, sc); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_CONFIGURE: retval = sysc_policy_configure(softsp, &sysc_pkt, sc); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_TEST: retval = fhc_bd_test(slot, &sysc_pkt); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_TEST_SET_COND: retval = fhc_bd_test_set_cond(slot, &sysc_pkt); sysc_exit_transition(slot); break; case SYSC_CFGA_CMD_QUIESCE_TEST: sysctrl_suspend_prepare(); fhc_bdlist_unlock(); if (sysctrl_suspend(&sysc_pkt) == DDI_SUCCESS) { sysctrl_resume(&sysc_pkt); } else { retval = EBUSY; } (void) fhc_bdlist_lock(-1); sysc_exit_transition(-1); break; default: retval = ENOTTY; goto cleanup_exit; } cleanup_copyout: /* * 3rd switch is to do appropriate copyout and reset locks */ switch (cmd) { case SYSC_CFGA_CMD_GETSTATUS: if (ddi_copyout(sc_list, (void *)arg, sizeof (sysc_cfga_stat_t) * fhc_max_boards(), flag) != 0) { retval = EFAULT; } /* cleanup memory */ kmem_free(fhc_list, sizeof (fhc_bd_t) * fhc_max_boards()); kmem_free(sc_list, sizeof (sysc_cfga_stat_t) * fhc_max_boards()); break; case SYSC_CFGA_CMD_EJECT: case SYSC_CFGA_CMD_INSERT: retval = ENOTSUP; break; case SYSC_CFGA_CMD_CONNECT: case SYSC_CFGA_CMD_DISCONNECT: case SYSC_CFGA_CMD_UNCONFIGURE: case SYSC_CFGA_CMD_CONFIGURE: case SYSC_CFGA_CMD_TEST: case SYSC_CFGA_CMD_TEST_SET_COND: case SYSC_CFGA_CMD_QUIESCE_TEST: if (sysc_pkt_fini(&sysc_pkt, arg, flag) != TRUE) return (EFAULT); break; default: retval = ENOTTY; break; } cleanup_exit: return (retval); } /* * system_high_handler() * This routine handles system interrupts. * * This routine goes through all the interrupt sources and masks * off the enable bit if interrupting. Because of the special * nature of the pps fan source bits, we also cache the state * of the fan bits for that special case. * * The rest of the work is done in the low level handlers */ static uint_t system_high_handler(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t csr; uchar_t status2; uchar_t tmp_reg; int serviced = 0; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); /* read in the hardware registers */ csr = *(softsp->csr); status2 = *(softsp->status2); if (csr & SYS_AC_PWR_FAIL_EN) { if (status2 & SYS_AC_FAIL) { /* save the powerfail state in nvram */ nvram_update_powerfail(softsp); /* disable this interrupt source */ csr &= ~SYS_AC_PWR_FAIL_EN; ddi_trigger_softintr(softsp->ac_fail_id); serviced++; } } if (csr & SYS_PS_FAIL_EN) { if ((*(softsp->ps_stat) != 0xff) || ((~status2) & (SYS_PPS0_OK | SYS_CLK_33_OK | SYS_CLK_50_OK)) || (~(*(softsp->pppsr)) & SYS_PPPSR_BITS)) { /* disable this interrupt source */ csr &= ~SYS_PS_FAIL_EN; ddi_trigger_softintr(softsp->ps_fail_int_id); serviced++; } } if (csr & SYS_PPS_FAN_FAIL_EN) { if (status2 & SYS_RACK_FANFAIL || !(status2 & SYS_AC_FAN_OK) || !(status2 & SYS_KEYSW_FAN_OK)) { /* * we must cache the fan status because it goes * away when we disable interrupts !?!?! */ softsp->pps_fan_saved = status2; /* disable this interrupt source */ csr &= ~SYS_PPS_FAN_FAIL_EN; ddi_trigger_softintr(softsp->pps_fan_id); serviced++; } } if (csr & SYS_SBRD_PRES_EN) { if (!(*(softsp->status1) & SYS_NOT_BRD_PRES)) { /* disable this interrupt source */ csr &= ~SYS_SBRD_PRES_EN; ddi_trigger_softintr(softsp->sbrd_pres_id); serviced++; } } if (!serviced) { /* * if we get here than it is likely that contact bounce * is messing with us. so, we need to shut this interrupt * up for a while to let the contacts settle down. * Then we will re-enable the interrupts that are enabled * right now. The trick is to disable the appropriate * interrupts and then to re-enable them correctly, even * though intervening handlers might have been working. */ /* remember all interrupts that could have caused it */ softsp->saved_en_state |= csr & (SYS_AC_PWR_FAIL_EN | SYS_PS_FAIL_EN | SYS_PPS_FAN_FAIL_EN | SYS_SBRD_PRES_EN); /* and then turn them off */ csr &= ~(SYS_AC_PWR_FAIL_EN | SYS_PS_FAIL_EN | SYS_PPS_FAN_FAIL_EN | SYS_SBRD_PRES_EN); /* and then bump the counter */ softsp->spur_count++; /* and kick off the timeout */ ddi_trigger_softintr(softsp->spur_id); } /* update the real csr */ *(softsp->csr) = csr; tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); return (DDI_INTR_CLAIMED); } /* * we've detected a spurious interrupt. * determine if we should log a message and if we need another timeout */ static uint_t spur_delay(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; ASSERT(softsp); /* do we need to complain? */ mutex_enter(&softsp->csr_mutex); /* NOTE: this is == because we want one message per long timeout */ if (softsp->spur_count == MAX_SPUR_COUNT) { char buf[128]; /* print out the candidates known at this time */ /* XXX not perfect because of re-entrant nature but close */ buf[0] = '\0'; if (softsp->saved_en_state & SYS_AC_PWR_FAIL_EN) (void) strcat(buf, "AC FAIL"); if (softsp->saved_en_state & SYS_PPS_FAN_FAIL_EN) (void) strcat(buf, buf[0] ? "|PPS FANS" : "PPS FANS"); if (softsp->saved_en_state & SYS_PS_FAIL_EN) (void) strcat(buf, buf[0] ? "|PS FAIL" : "PS FAIL"); if (softsp->saved_en_state & SYS_SBRD_PRES_EN) (void) strcat(buf, buf[0] ? "|BOARD INSERT" : "BOARD INSERT"); /* * This is a high level mutex, therefore it needs to be * dropped before calling cmn_err. */ mutex_exit(&softsp->csr_mutex); cmn_err(CE_WARN, "sysctrl%d: unserviced interrupt." " possible sources [%s].", ddi_get_instance(softsp->dip), buf); } else mutex_exit(&softsp->csr_mutex); mutex_enter(&softsp->spur_int_lock); /* do we need to start the short timeout? */ if (softsp->spur_timeout_id == 0) { softsp->spur_timeout_id = timeout(spur_retry, softsp, spur_timeout_hz); } /* do we need to start the long timeout? */ if (softsp->spur_long_timeout_id == 0) { softsp->spur_long_timeout_id = timeout(spur_long_timeout, softsp, spur_long_timeout_hz); } mutex_exit(&softsp->spur_int_lock); return (DDI_INTR_CLAIMED); } /* * spur_retry * * this routine simply triggers the interrupt which will re-enable * the interrupts disabled by the spurious int detection. */ static void spur_retry(void *arg) { struct sysctrl_soft_state *softsp = arg; ASSERT(softsp); ddi_trigger_softintr(softsp->spur_high_id); mutex_enter(&softsp->spur_int_lock); softsp->spur_timeout_id = 0; mutex_exit(&softsp->spur_int_lock); } /* * spur_reenable * * OK, we've been slient for a while. Go ahead and re-enable the * interrupts that were enabled at the time of the spurious detection. */ static uint_t spur_reenable(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t tmp_reg; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); /* reenable those who were spurious candidates */ *(softsp->csr) |= softsp->saved_en_state & (SYS_AC_PWR_FAIL_EN | SYS_PS_FAIL_EN | SYS_PPS_FAN_FAIL_EN | SYS_SBRD_PRES_EN); tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif /* clear out the saved state */ softsp->saved_en_state = 0; mutex_exit(&softsp->csr_mutex); return (DDI_INTR_CLAIMED); } /* * spur_long_timeout * * this routine merely resets the spurious interrupt counter thus ending * the interval of interest. of course this is done by triggering a * softint because the counter is protected by an interrupt mutex. */ static void spur_long_timeout(void *arg) { struct sysctrl_soft_state *softsp = arg; ASSERT(softsp); ddi_trigger_softintr(softsp->spur_long_to_id); mutex_enter(&softsp->spur_int_lock); softsp->spur_long_timeout_id = 0; mutex_exit(&softsp->spur_int_lock); } /* * spur_clear_count * * simply clear out the spurious interrupt counter. * * softint level only */ static uint_t spur_clear_count(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); softsp->spur_count = 0; mutex_exit(&softsp->csr_mutex); return (DDI_INTR_CLAIMED); } /* * ac_fail_handler * * This routine polls the AC power failure bit in the system status2 * register. If we get to this routine, then we sensed an ac fail * condition. Note the fact and check again in a few. * * Called as softint from high interrupt. */ static uint_t ac_fail_handler(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; ASSERT(softsp); cmn_err(CE_WARN, "%s failure detected", ft_str_table[FT_AC_PWR]); reg_fault(0, FT_AC_PWR, FT_SYSTEM); (void) timeout(ac_fail_retry, softsp, ac_timeout_hz); return (DDI_INTR_CLAIMED); } /* * The timeout from ac_fail_handler() that checks to see if the * condition persists. */ static void ac_fail_retry(void *arg) { struct sysctrl_soft_state *softsp = arg; ASSERT(softsp); if (*softsp->status2 & SYS_AC_FAIL) { /* still bad? */ (void) timeout(ac_fail_retry, softsp, ac_timeout_hz); } else { cmn_err(CE_NOTE, "%s failure no longer detected", ft_str_table[FT_AC_PWR]); clear_fault(0, FT_AC_PWR, FT_SYSTEM); ddi_trigger_softintr(softsp->ac_fail_high_id); } } /* * The interrupt routine that we use to re-enable the interrupt. * Called from ddi_trigger_softint() in the ac_fail_retry() when * the AC is better. */ static uint_t ac_fail_reenable(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t tmp_reg; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); *(softsp->csr) |= SYS_AC_PWR_FAIL_EN; tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); return (DDI_INTR_CLAIMED); } /* * ps_fail_int_handler * * Handle power supply failure interrupt. * * This wrapper is called as softint from hardware interrupt routine. */ static uint_t ps_fail_int_handler(caddr_t arg) { return (ps_fail_handler((struct sysctrl_soft_state *)arg, 1)); } /* * ps_fail_poll_handler * * Handle power supply failure interrupt. * * This wrapper is called as softint from power supply poll routine. */ static uint_t ps_fail_poll_handler(caddr_t arg) { return (ps_fail_handler((struct sysctrl_soft_state *)arg, 0)); } /* * ps_fail_handler * * This routine checks all eight of the board power supplies that are * installed plus the Peripheral power supply and the two DC OK. Since the * hardware bits are not enough to indicate Power Supply failure * vs. being turned off via software, the driver must maintain a * shadow state for the Power Supply status and monitor all changes. * * Called as a softint only. */ static uint_t ps_fail_handler(struct sysctrl_soft_state *softsp, int fromint) { int i; struct ps_state *pstatp; int poll_needed = 0; uchar_t ps_stat, ps_pres, status1, status2, pppsr; uchar_t tmp_reg; enum power_state current_power_state; ASSERT(softsp); /* pre-read the hardware state */ ps_stat = *softsp->ps_stat; ps_pres = *softsp->ps_pres; status1 = *softsp->status1; status2 = *softsp->status2; pppsr = *softsp->pppsr; (void) fhc_bdlist_lock(-1); mutex_enter(&softsp->ps_fail_lock); for (i = 0, pstatp = &softsp->ps_stats[0]; i < SYS_PS_COUNT; i++, pstatp++) { int temp_psok; int temp_pres; int is_precharge = FALSE; int is_fan_assy = FALSE; /* * pre-compute the presence and ok bits for this * power supply from the hardware registers. * NOTE: 4-slot pps1 is the same as core ps 7... */ switch (i) { /* the core power supplies */ case 0: case 1: case 2: case 3: case 4: case 5: case 6: case 7: temp_pres = !((ps_pres >> i) & 0x1); temp_psok = (ps_stat >> i) & 0x1; break; /* the first peripheral power supply */ case SYS_PPS0_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = status2 & SYS_PPS0_OK; break; /* shared 3.3v clock power */ case SYS_CLK_33_INDEX: temp_pres = TRUE; temp_psok = status2 & SYS_CLK_33_OK; break; /* shared 5.0v clock power */ case SYS_CLK_50_INDEX: temp_pres = TRUE; temp_psok = status2 & SYS_CLK_50_OK; break; /* peripheral 5v */ case SYS_V5_P_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES) || ((IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) && !(ps_pres & SYS_NOT_PPS1_PRES)); temp_psok = pppsr & SYS_V5_P_OK; break; /* peripheral 12v */ case SYS_V12_P_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES) || ((IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) && !(ps_pres & SYS_NOT_PPS1_PRES)); temp_psok = pppsr & SYS_V12_P_OK; break; /* aux 5v */ case SYS_V5_AUX_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = pppsr & SYS_V5_AUX_OK; break; /* peripheral 5v precharge */ case SYS_V5_P_PCH_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = pppsr & SYS_V5_P_PCH_OK; is_precharge = TRUE; break; /* peripheral 12v precharge */ case SYS_V12_P_PCH_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = pppsr & SYS_V12_P_PCH_OK; is_precharge = TRUE; break; /* 3.3v precharge */ case SYS_V3_PCH_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = pppsr & SYS_V3_PCH_OK; is_precharge = TRUE; break; /* 5v precharge */ case SYS_V5_PCH_INDEX: temp_pres = !(status1 & SYS_NOT_PPS0_PRES); temp_psok = pppsr & SYS_V5_PCH_OK; is_precharge = TRUE; break; /* peripheral fan assy */ case SYS_P_FAN_INDEX: temp_pres = (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) && !(status1 & SYS_NOT_P_FAN_PRES); temp_psok = softsp->pps_fan_saved & SYS_AC_FAN_OK; is_fan_assy = TRUE; break; } /* *** Phase 1 -- power supply presence tests *** */ /* do we know the presence status for this power supply? */ if (pstatp->pshadow == PRES_UNKNOWN) { pstatp->pshadow = temp_pres ? PRES_IN : PRES_OUT; pstatp->dcshadow = temp_pres ? PS_BOOT : PS_OUT; } else { /* has the ps presence state changed? */ if (!temp_pres ^ (pstatp->pshadow == PRES_IN)) { pstatp->pctr = 0; } else { /* a change! are we counting? */ if (pstatp->pctr == 0) { pstatp->pctr = PS_PRES_CHANGE_TICKS; } else if (--pstatp->pctr == 0) { pstatp->pshadow = temp_pres ? PRES_IN : PRES_OUT; pstatp->dcshadow = temp_pres ? PS_UNKNOWN : PS_OUT; /* * Now we know the state has * changed, so we should log it. */ ps_log_pres_change(softsp, i, temp_pres); } } } /* *** Phase 2 -- power supply status tests *** */ /* check if the Power Supply is removed or same as before */ if ((pstatp->dcshadow == PS_OUT) || ((pstatp->dcshadow == PS_OK) && temp_psok) || ((pstatp->dcshadow == PS_FAIL) && !temp_psok)) { pstatp->dcctr = 0; } else { /* OK, a change, do we start the timer? */ if (pstatp->dcctr == 0) { switch (pstatp->dcshadow) { case PS_BOOT: pstatp->dcctr = PS_FROM_BOOT_TICKS; break; case PS_UNKNOWN: pstatp->dcctr = is_fan_assy ? PS_P_FAN_FROM_UNKNOWN_TICKS : PS_FROM_UNKNOWN_TICKS; break; case PS_OK: pstatp->dcctr = is_precharge ? PS_PCH_FROM_OK_TICKS : PS_FROM_OK_TICKS; break; case PS_FAIL: pstatp->dcctr = PS_FROM_FAIL_TICKS; break; default: panic("sysctrl%d: Unknown Power " "Supply State %d", pstatp->dcshadow, ddi_get_instance(softsp->dip)); } } /* has the ticker expired? */ if (--pstatp->dcctr == 0) { /* we'll skip OK messages during boot */ if (!((pstatp->dcshadow == PS_BOOT) && temp_psok)) { ps_log_state_change(softsp, i, temp_psok); } /* * remote console interface has to be * reinitialized on the rising edge V5_AUX * when it is NOT boot. At the boot time an * an error condition exists if it was not * enabled before. */ if ((i == SYS_V5_AUX_INDEX) && (pstatp->dcshadow != PS_BOOT) && (softsp->enable_rcons_atboot)) { if (temp_psok) rcons_reinit(softsp); else /* disable rconsole */ *(softsp->clk_freq2) &= ~RCONS_UART_EN; tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif } /* regardless, update the shadow state */ pstatp->dcshadow = temp_psok ? PS_OK : PS_FAIL; /* always update board condition */ sysc_policy_update(softsp, NULL, SYSC_EVT_BD_PS_CHANGE); } } /* * We will need to continue polling for three reasons: * - a failing power supply is detected and we haven't yet * determined the power supplies existence. * - the power supply is just installed and we're waiting * to give it a change to power up, * - a failed power supply state is recognized * * NOTE: PS_FAIL shadow state is not the same as !temp_psok * because of the persistence of PS_FAIL->PS_OK. */ if (!temp_psok || (pstatp->dcshadow == PS_UNKNOWN) || (pstatp->dcshadow == PS_FAIL)) { poll_needed++; } } /* * Now, get the current power state for this instance. * If the current state is different than what was known, complain. */ current_power_state = compute_power_state(softsp, 0); if (softsp->power_state != current_power_state) { switch (current_power_state) { case BELOW_MINIMUM: cmn_err(CE_WARN, "Insufficient power available to system"); if (!disable_insufficient_power_reboot) { cmn_err(CE_WARN, "System reboot in %d seconds", PS_INSUFFICIENT_COUNTDOWN_SEC); } reg_fault(1, FT_INSUFFICIENT_POWER, FT_SYSTEM); softsp->power_countdown = PS_POWER_COUNTDOWN_TICKS; break; case MINIMUM: /* If we came from REDUNDANT, complain */ if (softsp->power_state == REDUNDANT) { cmn_err(CE_WARN, "Redundant power lost"); /* If we came from BELOW_MINIMUM, hurrah! */ } else if (softsp->power_state == BELOW_MINIMUM) { cmn_err(CE_NOTE, "Minimum power available"); clear_fault(1, FT_INSUFFICIENT_POWER, FT_SYSTEM); } break; case REDUNDANT: /* If we aren't from boot, spread the good news */ if (softsp->power_state != BOOT) { cmn_err(CE_NOTE, "Redundant power available"); clear_fault(1, FT_INSUFFICIENT_POWER, FT_SYSTEM); } break; default: break; } softsp->power_state = current_power_state; sysc_policy_update(softsp, NULL, SYSC_EVT_BD_PS_CHANGE); } mutex_exit(&softsp->ps_fail_lock); fhc_bdlist_unlock(); /* * Are we in insufficient powerstate? * If so, is it time to take action? */ if (softsp->power_state == BELOW_MINIMUM && softsp->power_countdown > 0 && --(softsp->power_countdown) == 0 && !disable_insufficient_power_reboot) { cmn_err(CE_WARN, "Insufficient power. System Reboot Started..."); fhc_reboot(); } /* * If we don't have ps problems that need to be polled for, then * enable interrupts. */ if (!poll_needed) { mutex_enter(&softsp->csr_mutex); *(softsp->csr) |= SYS_PS_FAIL_EN; tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); } /* * Only the polling loop re-triggers the polling loop timeout */ if (!fromint) { (void) timeout(ps_fail_retry, softsp, ps_fail_timeout_hz); } return (DDI_INTR_CLAIMED); } /* * Compute the current power configuration for this system. * Disk boards and Clock boards are not counted. * * This function must be called with the ps_fail_lock held. */ enum power_state compute_power_state(struct sysctrl_soft_state *softsp, int plus_load) { int i; int ok_supply_count = 0; int load_count = 0; int minimum_power_count; int pps_ok; fhc_bd_t *list; ASSERT(mutex_owned(&softsp->ps_fail_lock)); /* * Walk down the interesting power supplies and * count the operational power units */ for (i = 0; i < 8; i++) { /* * power supply id 7 on a 4 or 5 slot system is PPS1. * don't include it in the redundant core power calculation. */ if (i == 7 && (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots))) continue; if (softsp->ps_stats[i].dcshadow == PS_OK) ok_supply_count++; } /* Note the state of the PPS... */ pps_ok = (softsp->ps_stats[SYS_PPS0_INDEX].dcshadow == PS_OK); /* * Dynamically compute the load count in the system. * Don't count disk boards or boards in low power state. */ for (list = fhc_bd_first(); list; list = fhc_bd_next(list)) { ASSERT(list->sc.type != CLOCK_BOARD); if (list->sc.rstate == SYSC_CFGA_RSTATE_CONNECTED) { load_count++; } } load_count += plus_load; /* * If we are 8 slot and we have 7 or 8 boards, then the PPS * can count as a power supply... */ if (IS8SLOT(softsp->nslots) && load_count >= 7 && pps_ok) ok_supply_count++; /* * This is to cover the corner case of a UE3500 having 5 * boards installed and still giving it N+1 power status. */ if (IS5SLOT(softsp->nslots) && (load_count >= 5)) ok_supply_count++; /* * Determine our power situation. This is a simple step * function right now: * * minimum power count = min(7, floor((board count + 1) / 2)) */ minimum_power_count = (load_count + 1) / 2; if (minimum_power_count > 7) minimum_power_count = 7; if (ok_supply_count > minimum_power_count) return (REDUNDANT); else if (ok_supply_count == minimum_power_count) return (MINIMUM); else return (BELOW_MINIMUM); } /* * log the change of power supply presence */ static void ps_log_pres_change(struct sysctrl_soft_state *softsp, int index, int present) { char *trans = present ? "Installed" : "Removed"; switch (index) { /* the core power supplies (except for 7) */ case 0: case 1: case 2: case 3: case 4: case 5: case 6: cmn_err(CE_NOTE, "%s %d %s", ft_str_table[FT_CORE_PS], index, trans); if (!present) { clear_fault(index, FT_CORE_PS, FT_SYSTEM); sysc_policy_update(softsp, NULL, SYSC_EVT_BD_PS_CHANGE); } break; /* power supply 7 / pps 1 */ case 7: if (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) { cmn_err(CE_NOTE, "%s 1 %s", ft_str_table[FT_PPS], trans); if (!present) { clear_fault(1, FT_PPS, FT_SYSTEM); } } else { cmn_err(CE_NOTE, "%s %d %s", ft_str_table[FT_CORE_PS], index, trans); if (!present) { clear_fault(7, FT_CORE_PS, FT_SYSTEM); sysc_policy_update(softsp, NULL, SYSC_EVT_BD_PS_CHANGE); } } break; /* the peripheral power supply 0 */ case SYS_PPS0_INDEX: cmn_err(CE_NOTE, "%s 0 %s", ft_str_table[FT_PPS], trans); if (!present) { clear_fault(0, FT_PPS, FT_SYSTEM); sysc_policy_update(softsp, NULL, SYSC_EVT_BD_PS_CHANGE); } break; /* the peripheral rack fan assy */ case SYS_P_FAN_INDEX: cmn_err(CE_NOTE, "%s %s", ft_str_table[FT_PPS_FAN], trans); if (!present) { clear_fault(0, FT_PPS_FAN, FT_SYSTEM); } break; /* we don't mention a change of presence state for any other power */ } } /* * log the change of power supply status */ static void ps_log_state_change(struct sysctrl_soft_state *softsp, int index, int ps_ok) { int level = ps_ok ? CE_NOTE : CE_WARN; char *s = ps_ok ? "OK" : "Failing"; switch (index) { /* the core power supplies (except 7) */ case 0: case 1: case 2: case 3: case 4: case 5: case 6: cmn_err(level, "%s %d %s", ft_str_table[FT_CORE_PS], index, s); if (ps_ok) { clear_fault(index, FT_CORE_PS, FT_SYSTEM); } else { reg_fault(index, FT_CORE_PS, FT_SYSTEM); } break; /* power supply 7 / pps 1 */ case 7: if (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) { cmn_err(level, "%s 1 %s", ft_str_table[FT_PPS], s); if (ps_ok) { clear_fault(1, FT_PPS, FT_SYSTEM); } else { reg_fault(1, FT_PPS, FT_SYSTEM); } } else { cmn_err(level, "%s %d %s", ft_str_table[FT_CORE_PS], index, s); if (ps_ok) { clear_fault(index, FT_CORE_PS, FT_SYSTEM); } else { reg_fault(index, FT_CORE_PS, FT_SYSTEM); } } break; /* the peripheral power supply */ case SYS_PPS0_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_PPS], s); if (ps_ok) { clear_fault(0, FT_PPS, FT_SYSTEM); } else { reg_fault(0, FT_PPS, FT_SYSTEM); } break; /* shared 3.3v clock power */ case SYS_CLK_33_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_CLK_33], s); if (ps_ok) { clear_fault(0, FT_CLK_33, FT_SYSTEM); } else { reg_fault(0, FT_CLK_33, FT_SYSTEM); } break; /* shared 5.0v clock power */ case SYS_CLK_50_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_CLK_50], s); if (ps_ok) { clear_fault(0, FT_CLK_50, FT_SYSTEM); } else { reg_fault(0, FT_CLK_50, FT_SYSTEM); } break; /* peripheral 5v */ case SYS_V5_P_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V5_P], s); if (ps_ok) { clear_fault(0, FT_V5_P, FT_SYSTEM); } else { reg_fault(0, FT_V5_P, FT_SYSTEM); } break; /* peripheral 12v */ case SYS_V12_P_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V12_P], s); if (ps_ok) { clear_fault(0, FT_V12_P, FT_SYSTEM); } else { reg_fault(0, FT_V12_P, FT_SYSTEM); } break; /* aux 5v */ case SYS_V5_AUX_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V5_AUX], s); if (ps_ok) { clear_fault(0, FT_V5_AUX, FT_SYSTEM); } else { reg_fault(0, FT_V5_AUX, FT_SYSTEM); } break; /* peripheral 5v precharge */ case SYS_V5_P_PCH_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V5_P_PCH], s); if (ps_ok) { clear_fault(0, FT_V5_P_PCH, FT_SYSTEM); } else { reg_fault(0, FT_V5_P_PCH, FT_SYSTEM); } break; /* peripheral 12v precharge */ case SYS_V12_P_PCH_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V12_P_PCH], s); if (ps_ok) { clear_fault(0, FT_V12_P_PCH, FT_SYSTEM); } else { reg_fault(0, FT_V12_P_PCH, FT_SYSTEM); } break; /* 3.3v precharge */ case SYS_V3_PCH_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V3_PCH], s); if (ps_ok) { clear_fault(0, FT_V3_PCH, FT_SYSTEM); } else { reg_fault(0, FT_V3_PCH, FT_SYSTEM); } break; /* 5v precharge */ case SYS_V5_PCH_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_V5_PCH], s); if (ps_ok) { clear_fault(0, FT_V5_PCH, FT_SYSTEM); } else { reg_fault(0, FT_V5_PCH, FT_SYSTEM); } break; /* peripheral power supply fans */ case SYS_P_FAN_INDEX: cmn_err(level, "%s %s", ft_str_table[FT_PPS_FAN], s); if (ps_ok) { clear_fault(0, FT_PPS_FAN, FT_SYSTEM); } else { reg_fault(0, FT_PPS_FAN, FT_SYSTEM); } break; } } /* * The timeout from ps_fail_handler() that simply re-triggers a check * of the ps condition. */ static void ps_fail_retry(void *arg) { struct sysctrl_soft_state *softsp = arg; ASSERT(softsp); ddi_trigger_softintr(softsp->ps_fail_poll_id); } /* * pps_fanfail_handler * * This routine is called from the high level handler. */ static uint_t pps_fanfail_handler(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; ASSERT(softsp); /* always check again in a bit by re-enabling the fan interrupt */ (void) timeout(pps_fanfail_retry, softsp, pps_fan_timeout_hz); return (DDI_INTR_CLAIMED); } /* * After a bit of waiting, we simply re-enable the interrupt to * see if we get another one. The softintr triggered routine does * the dirty work for us since it runs in the interrupt context. */ static void pps_fanfail_retry(void *arg) { struct sysctrl_soft_state *softsp = arg; ASSERT(softsp); ddi_trigger_softintr(softsp->pps_fan_high_id); } /* * The other half of the retry handler run from the interrupt context */ static uint_t pps_fanfail_reenable(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t tmp_reg; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); /* * re-initialize the bit field for all pps fans to assumed good. * If the fans are still bad, we're going to get an immediate system * interrupt which will put the correct state back anyway. * * NOTE: the polling routines that use this state understand the * pulse resulting from above... */ softsp->pps_fan_saved = SYS_AC_FAN_OK | SYS_KEYSW_FAN_OK; *(softsp->csr) |= SYS_PPS_FAN_FAIL_EN; tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); return (DDI_INTR_CLAIMED); } /* * * Poll the hardware shadow state to determine the pps fan status. * The shadow state is maintained by the system_high handler and its * associated pps_* functions (above). * * There is a short time interval where the shadow state is pulsed to * the OK state even when the fans are bad. However, this polling * routine has some built in hysteresis to filter out those _normal_ * events. */ static void pps_fan_poll(void *arg) { struct sysctrl_soft_state *softsp = arg; int i; ASSERT(softsp); for (i = 0; i < SYS_PPS_FAN_COUNT; i++) { int fanfail = FALSE; /* determine fan status */ switch (i) { case RACK: fanfail = softsp->pps_fan_saved & SYS_RACK_FANFAIL; break; case AC: /* * Don't bother polling the AC fan on 4 and 5 slot * systems. * Rather, it is handled by the power supply loop. */ fanfail = !(IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) && !(softsp->pps_fan_saved & SYS_AC_FAN_OK); break; case KEYSW: /* * This signal is not usable if aux5v is missing * so we will synthesize a failed fan when aux5v * fails or when pps0 is out. * The 4 and 5 slot systems behave the same. */ fanfail = (!(IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) && (softsp->ps_stats[SYS_V5_AUX_INDEX].dcshadow != PS_OK)) || !(softsp->pps_fan_saved & SYS_KEYSW_FAN_OK); break; } /* is the fan bad? */ if (fanfail) { /* is this condition different than we know? */ if (softsp->pps_fan_state_count[i] == 0) { /* log the change to failed */ pps_fan_state_change(softsp, i, FALSE); } /* always restart the fan OK counter */ softsp->pps_fan_state_count[i] = PPS_FROM_FAIL_TICKS; } else { /* do we currently know the fan is bad? */ if (softsp->pps_fan_state_count[i]) { /* yes, but has it been stable? */ if (--softsp->pps_fan_state_count[i] == 0) { /* log the change to OK */ pps_fan_state_change(softsp, i, TRUE); } } } } /* always check again in a bit by re-enabling the fan interrupt */ (void) timeout(pps_fan_poll, softsp, pps_fan_timeout_hz); } /* * pps_fan_state_change() * * Log the changed fan condition and update the external status. */ static void pps_fan_state_change(struct sysctrl_soft_state *softsp, int index, int fan_ok) { char *fan_type; char *state = fan_ok ? "fans OK" : "fan failure detected"; switch (index) { case RACK: /* 4 and 5 slot systems behave the same */ fan_type = (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) ? "Disk Drive" : "Rack Exhaust"; if (fan_ok) { softsp->pps_fan_external_state &= ~SYS_RACK_FANFAIL; clear_fault(0, (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) ? FT_DSK_FAN : FT_RACK_EXH, FT_SYSTEM); } else { softsp->pps_fan_external_state |= SYS_RACK_FANFAIL; reg_fault(0, (IS4SLOT(softsp->nslots) || IS5SLOT(softsp->nslots)) ? FT_DSK_FAN : FT_RACK_EXH, FT_SYSTEM); } break; case AC: fan_type = "AC Box"; if (fan_ok) { softsp->pps_fan_external_state |= SYS_AC_FAN_OK; clear_fault(0, FT_AC_FAN, FT_SYSTEM); } else { softsp->pps_fan_external_state &= ~SYS_AC_FAN_OK; reg_fault(0, FT_AC_FAN, FT_SYSTEM); } break; case KEYSW: fan_type = "Keyswitch"; if (fan_ok) { softsp->pps_fan_external_state |= SYS_KEYSW_FAN_OK; clear_fault(0, FT_KEYSW_FAN, FT_SYSTEM); } else { softsp->pps_fan_external_state &= ~SYS_KEYSW_FAN_OK; reg_fault(0, FT_KEYSW_FAN, FT_SYSTEM); } break; default: fan_type = "[invalid fan id]"; break; } /* now log the state change */ cmn_err(fan_ok ? CE_NOTE : CE_WARN, "%s %s", fan_type, state); } static uint_t bd_insert_handler(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; ASSERT(softsp); DPRINTF(SYSCTRL_ATTACH_DEBUG, ("bd_insert_handler()")); (void) timeout(bd_insert_timeout, softsp, bd_insert_delay_hz); return (DDI_INTR_CLAIMED); } void bd_remove_poll(struct sysctrl_soft_state *softsp) { ASSERT(fhc_bdlist_locked()); if (!bd_remove_to_id) { bd_remove_to_id = timeout(bd_remove_timeout, softsp, bd_remove_timeout_hz); } else { DPRINTF(SYSCTRL_ATTACH_DEBUG, ("bd_remove_poll ignoring start request")); } } /* * bd_insert_timeout() * * This routine handles the board insert interrupt. It is called from a * timeout so that it does not run at interrupt level. The main job * of this routine is to find hotplugged boards and de-assert the * board insert interrupt coming from the board. For hotplug phase I, * the routine also powers down the board. * JTAG scan is used to find boards which have been inserted. * All other control of the boards is also done by JTAG scan. */ static void bd_insert_timeout(void *arg) { struct sysctrl_soft_state *softsp = arg; int found; ASSERT(softsp); if (sysctrl_hotplug_disabled) { sysc_policy_update(softsp, NULL, SYSC_EVT_BD_HP_DISABLED); } else { /* * Lock the board list mutex. Keep it locked until all work * is done. */ (void) fhc_bdlist_lock(-1); found = fhc_bd_insert_scan(); if (found) { DPRINTF(SYSCTRL_ATTACH_DEBUG, ("bd_insert_timeout starting bd_remove_poll()")); bd_remove_poll(softsp); } fhc_bdlist_unlock(); } /* * Enable interrupts. */ ddi_trigger_softintr(softsp->sbrd_gone_id); } static void bd_remove_timeout(void *arg) { struct sysctrl_soft_state *softsp = arg; int keep_polling; ASSERT(softsp); /* * Lock the board list mutex. Keep it locked until all work * is done. */ (void) fhc_bdlist_lock(-1); bd_remove_to_id = 0; /* delete our timeout ID */ keep_polling = fhc_bd_remove_scan(); if (keep_polling) { bd_remove_poll(softsp); } else { DPRINTF(SYSCTRL_ATTACH_DEBUG, ("exiting bd_remove_poll.")); } fhc_bdlist_unlock(); } static uint_t bd_insert_normal(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t tmp_reg; ASSERT(softsp); /* has the condition been removed? */ /* XXX add deglitch state machine here */ if (!(*(softsp->status1) & SYS_NOT_BRD_PRES)) { /* check again in a few */ (void) timeout(bd_insert_timeout, softsp, bd_insert_retry_hz); } else { /* Turn on the enable bit for this interrupt */ mutex_enter(&softsp->csr_mutex); *(softsp->csr) |= SYS_SBRD_PRES_EN; /* flush the hardware store buffer */ tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); } return (DDI_INTR_CLAIMED); } /* * blink LED handler. * * The actual bit manipulation needs to occur at interrupt level * because we need access to the CSR with its CSR mutex */ static uint_t blink_led_handler(caddr_t arg) { struct sysctrl_soft_state *softsp = (struct sysctrl_soft_state *)arg; uchar_t tmp_reg; ASSERT(softsp); mutex_enter(&softsp->csr_mutex); /* * XXX - The lock for the sys_led is not held here. If more * complicated tasks are done with the System LED, then * locking should be done here. */ /* read the hardware register. */ tmp_reg = *(softsp->csr); /* Only turn on the OS System LED bit if the softsp state is on. */ if (softsp->sys_led) { tmp_reg |= SYS_LED_RIGHT; } else { tmp_reg &= ~SYS_LED_RIGHT; } /* Turn on the yellow LED if system fault status is set. */ if (softsp->sys_fault) { tmp_reg |= SYS_LED_MID; } else { tmp_reg &= ~SYS_LED_MID; } /* write to the hardware register */ *(softsp->csr) = tmp_reg; /* flush the hardware store buffer */ tmp_reg = *(softsp->csr); #ifdef lint tmp_reg = tmp_reg; #endif mutex_exit(&softsp->csr_mutex); (void) timeout(blink_led_timeout, softsp, blink_led_timeout_hz); return (DDI_INTR_CLAIMED); } /* * simply re-trigger the interrupt handler on led timeout */ static void blink_led_timeout(void *arg) { struct sysctrl_soft_state *softsp = arg; int led_state; ASSERT(softsp); /* * Process the system fault list here. This is where the driver * must decide what yellow LEDs to turn on if any. The fault * list is walked and each fhc_list entry is updated with it's * yellow LED status. This info is used later by the routine * toggle_board_green_leds(). * * The variable system_fault is non-zero if any non- * suppressed faults are found in the system. */ softsp->sys_fault = process_fault_list(); /* blink the system board OS LED */ mutex_enter(&softsp->sys_led_lock); softsp->sys_led = !softsp->sys_led; led_state = softsp->sys_led; mutex_exit(&softsp->sys_led_lock); toggle_board_green_leds(led_state); ddi_trigger_softintr(softsp->blink_led_id); } void toggle_board_green_leds(int led_state) { fhc_bd_t *list; (void) fhc_bdlist_lock(-1); for (list = fhc_bd_first(); list; list = fhc_bd_next(list)) { uint_t value = 0; if (list->sc.in_transition || (list->sc.rstate != SYSC_CFGA_RSTATE_CONNECTED)) continue; ASSERT(list->sc.type != CLOCK_BOARD); ASSERT(list->sc.type != DISK_BOARD); ASSERT(list->softsp); if ((list->sc.ostate == SYSC_CFGA_OSTATE_CONFIGURED) && led_state) value |= FHC_LED_RIGHT; if (list->fault) value |= FHC_LED_MID; else value &= ~FHC_LED_MID; update_board_leds(list, FHC_LED_RIGHT|FHC_LED_MID, value); } fhc_bdlist_unlock(); } /* * timestamp an AC power failure in nvram */ static void nvram_update_powerfail(struct sysctrl_soft_state *softsp) { char buf[80]; int len = 0; numtos(gethrestime_sec(), buf); if (softsp->options_nodeid) { len = prom_setprop(softsp->options_nodeid, "powerfail-time", buf, strlen(buf)+1); } if (len <= 0) { cmn_err(CE_WARN, "sysctrl%d: failed to set powerfail-time " "to %s\n", ddi_get_instance(softsp->dip), buf); } } void sysctrl_add_kstats(struct sysctrl_soft_state *softsp) { struct kstat *ksp; /* Generic sysctrl kstats */ struct kstat *pksp; /* Power Supply kstat */ struct kstat *tksp; /* Sysctrl temperatrure kstat */ struct kstat *ttsp; /* Sysctrl temperature test kstat */ if ((ksp = kstat_create("unix", ddi_get_instance(softsp->dip), SYSCTRL_KSTAT_NAME, "misc", KSTAT_TYPE_NAMED, sizeof (struct sysctrl_kstat) / sizeof (kstat_named_t), KSTAT_FLAG_PERSISTENT)) == NULL) { cmn_err(CE_WARN, "sysctrl%d: kstat_create failed", ddi_get_instance(softsp->dip)); } else { struct sysctrl_kstat *sysksp; sysksp = (struct sysctrl_kstat *)(ksp->ks_data); /* now init the named kstats */ kstat_named_init(&sysksp->csr, CSR_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->status1, STAT1_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->status2, STAT2_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->clk_freq2, CLK_FREQ2_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->fan_status, FAN_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->key_status, KEY_KSTAT_NAMED, KSTAT_DATA_CHAR); kstat_named_init(&sysksp->power_state, POWER_KSTAT_NAMED, KSTAT_DATA_INT32); kstat_named_init(&sysksp->clk_ver, CLK_VER_KSTAT_NAME, KSTAT_DATA_CHAR); ksp->ks_update = sysctrl_kstat_update; ksp->ks_private = (void *)softsp; kstat_install(ksp); } if ((tksp = kstat_create("unix", CLOCK_BOARD_INDEX, OVERTEMP_KSTAT_NAME, "misc", KSTAT_TYPE_RAW, sizeof (struct temp_stats), KSTAT_FLAG_PERSISTENT)) == NULL) { cmn_err(CE_WARN, "sysctrl%d: kstat_create failed", ddi_get_instance(softsp->dip)); } else { tksp->ks_update = overtemp_kstat_update; tksp->ks_private = (void *)&softsp->tempstat; kstat_install(tksp); } if ((ttsp = kstat_create("unix", CLOCK_BOARD_INDEX, TEMP_OVERRIDE_KSTAT_NAME, "misc", KSTAT_TYPE_RAW, sizeof (short), KSTAT_FLAG_PERSISTENT | KSTAT_FLAG_WRITABLE)) == NULL) { cmn_err(CE_WARN, "sysctrl%d: kstat_create failed", ddi_get_instance(softsp->dip)); } else { ttsp->ks_update = temp_override_kstat_update; ttsp->ks_private = (void *)&softsp->tempstat.override; kstat_install(ttsp); } if ((pksp = kstat_create("unix", ddi_get_instance(softsp->dip), PSSHAD_KSTAT_NAME, "misc", KSTAT_TYPE_RAW, SYS_PS_COUNT, KSTAT_FLAG_PERSISTENT)) == NULL) { cmn_err(CE_WARN, "sysctrl%d: kstat_create failed", ddi_get_instance(softsp->dip)); } else { pksp->ks_update = psstat_kstat_update; pksp->ks_private = (void *)softsp; kstat_install(pksp); } } static int sysctrl_kstat_update(kstat_t *ksp, int rw) { struct sysctrl_kstat *sysksp; struct sysctrl_soft_state *softsp; sysksp = (struct sysctrl_kstat *)(ksp->ks_data); softsp = (struct sysctrl_soft_state *)(ksp->ks_private); /* this is a read-only kstat. Exit on a write */ if (rw == KSTAT_WRITE) { return (EACCES); } else { /* * copy the current state of the hardware into the * kstat structure. */ sysksp->csr.value.c[0] = *(softsp->csr); sysksp->status1.value.c[0] = *(softsp->status1); sysksp->status2.value.c[0] = *(softsp->status2); sysksp->clk_freq2.value.c[0] = *(softsp->clk_freq2); sysksp->fan_status.value.c[0] = softsp->pps_fan_external_state; sysksp->key_status.value.c[0] = softsp->key_shadow; sysksp->power_state.value.i32 = softsp->power_state; /* * non-existence of the clock version register returns the * value 0xff when the hardware register location is read */ if (softsp->clk_ver != NULL) sysksp->clk_ver.value.c[0] = *(softsp->clk_ver); else sysksp->clk_ver.value.c[0] = (char)0xff; } return (0); } static int psstat_kstat_update(kstat_t *ksp, int rw) { struct sysctrl_soft_state *softsp; uchar_t *ptr = (uchar_t *)(ksp->ks_data); int ps; softsp = (struct sysctrl_soft_state *)(ksp->ks_private); if (rw == KSTAT_WRITE) { return (EACCES); } else { for (ps = 0; ps < SYS_PS_COUNT; ps++) { *ptr++ = softsp->ps_stats[ps].dcshadow; } } return (0); } static void sysctrl_thread_wakeup(void *arg) { int type = (int)(uintptr_t)arg; /* * grab mutex to guarantee that our wakeup call * arrives after we go to sleep -- so we can't sleep forever. */ mutex_enter(&sslist_mutex); switch (type) { case OVERTEMP_POLL: cv_signal(&overtemp_cv); break; case KEYSWITCH_POLL: cv_signal(&keyswitch_cv); break; default: cmn_err(CE_WARN, "sysctrl: invalid type %d to wakeup\n", type); break; } mutex_exit(&sslist_mutex); } static void sysctrl_overtemp_poll(void) { struct sysctrl_soft_state *list; callb_cpr_t cprinfo; CALLB_CPR_INIT(&cprinfo, &sslist_mutex, callb_generic_cpr, "overtemp"); /* The overtemp data structures are protected by a mutex. */ mutex_enter(&sslist_mutex); while (sysctrl_do_overtemp_thread) { for (list = sys_list; list != NULL; list = list->next) { if (list->temp_reg != NULL) { update_temp(list->pdip, &list->tempstat, *(list->temp_reg)); } } CALLB_CPR_SAFE_BEGIN(&cprinfo); /* now have this thread sleep for a while */ (void) timeout(sysctrl_thread_wakeup, (void *)OVERTEMP_POLL, overtemp_timeout_hz); cv_wait(&overtemp_cv, &sslist_mutex); CALLB_CPR_SAFE_END(&cprinfo, &sslist_mutex); } CALLB_CPR_EXIT(&cprinfo); thread_exit(); /* NOTREACHED */ } static void sysctrl_keyswitch_poll(void) { struct sysctrl_soft_state *list; callb_cpr_t cprinfo; CALLB_CPR_INIT(&cprinfo, &sslist_mutex, callb_generic_cpr, "keyswitch"); /* The keyswitch data strcutures are protected by a mutex. */ mutex_enter(&sslist_mutex); while (sysctrl_do_keyswitch_thread) { for (list = sys_list; list != NULL; list = list->next) { if (list->status1 != NULL) update_key_state(list); } CALLB_CPR_SAFE_BEGIN(&cprinfo); /* now have this thread sleep for a while */ (void) timeout(sysctrl_thread_wakeup, (void *)KEYSWITCH_POLL, keyswitch_timeout_hz); cv_wait(&keyswitch_cv, &sslist_mutex); CALLB_CPR_SAFE_END(&cprinfo, &sslist_mutex); } CALLB_CPR_EXIT(&cprinfo); thread_exit(); /* NOTREACHED */ } /* * check the key switch position for state changes */ static void update_key_state(struct sysctrl_soft_state *list) { enum keyswitch_state key; /* * snapshot current hardware key position */ if (*(list->status1) & SYS_NOT_SECURE) key = KEY_NOT_SECURE; else key = KEY_SECURE; /* * check for state transition */ if (key != list->key_shadow) { /* * handle state transition */ switch (list->key_shadow) { case KEY_BOOT: cmn_err(CE_CONT, "?sysctrl%d: Key switch is%sin the " "secure position\n", ddi_get_instance(list->dip), (key == KEY_SECURE) ? " " : " not "); list->key_shadow = key; break; case KEY_SECURE: case KEY_NOT_SECURE: cmn_err(CE_NOTE, "sysctrl%d: Key switch has changed" " to the %s position", ddi_get_instance(list->dip), (key == KEY_SECURE) ? "secure" : "not-secure"); list->key_shadow = key; break; default: cmn_err(CE_CONT, "?sysctrl%d: Key switch is in an unknown position," "treated as being in the %s position\n", ddi_get_instance(list->dip), (list->key_shadow == KEY_SECURE) ? "secure" : "not-secure"); break; } } } /* * consider key switch position when handling an abort sequence */ static void sysctrl_abort_seq_handler(char *msg) { struct sysctrl_soft_state *list; uint_t secure = 0; char buf[64], inst[4]; /* * if any of the key switch positions are secure, * then disallow entry to the prom/debugger */ mutex_enter(&sslist_mutex); buf[0] = (char)0; for (list = sys_list; list != NULL; list = list->next) { if (!(*(list->status1) & SYS_NOT_SECURE)) { if (secure++) (void) strcat(buf, ","); /* * XXX: later, replace instance number with nodeid */ (void) sprintf(inst, "%d", ddi_get_instance(list->dip)); (void) strcat(buf, inst); } } mutex_exit(&sslist_mutex); if (secure) { cmn_err(CE_CONT, "!sysctrl(%s): ignoring debug enter sequence\n", buf); } else { cmn_err(CE_CONT, "!sysctrl: allowing debug enter\n"); debug_enter(msg); } } #define TABLE_END 0xFF struct uart_cmd { uchar_t reg; uchar_t data; }; /* * Time constant defined by this formula: * ((4915200/32)/(baud) -2) */ struct uart_cmd uart_table[] = { { 0x09, 0xc0 }, /* Force hardware reset */ { 0x04, 0x46 }, /* X16 clock mode, 1 stop bit/char, no parity */ { 0x03, 0xc0 }, /* Rx is 8 bits/char */ { 0x05, 0xe2 }, /* DTR, Tx is 8 bits/char, RTS */ { 0x09, 0x02 }, /* No vector returned on interrupt */ { 0x0b, 0x55 }, /* Rx Clock = Tx Clock = BR generator = ~TRxC OUT */ { 0x0c, 0x0e }, /* Time Constant = 0x000e for 9600 baud */ { 0x0d, 0x00 }, /* High byte of time constant */ { 0x0e, 0x02 }, /* BR generator comes from Z-SCC's PCLK input */ { 0x03, 0xc1 }, /* Rx is 8 bits/char, Rx is enabled */ { 0x05, 0xea }, /* DTR, Tx is 8 bits/char, Tx is enabled, RTS */ { 0x0e, 0x03 }, /* BR comes from PCLK, BR generator is enabled */ { 0x00, 0x30 }, /* Error reset */ { 0x00, 0x30 }, /* Error reset */ { 0x00, 0x10 }, /* external status reset */ { 0x03, 0xc1 }, /* Rx is 8 bits/char, Rx is enabled */ { TABLE_END, 0x0 } }; static void init_remote_console_uart(struct sysctrl_soft_state *softsp) { int i = 0; /* * Serial chip expects software to write to the control * register first with the desired register number. Then * write to the control register with the desired data. * So walk thru table writing the register/data pairs to * the serial port chip. */ while (uart_table[i].reg != TABLE_END) { *(softsp->rcons_ctl) = uart_table[i].reg; *(softsp->rcons_ctl) = uart_table[i].data; i++; } } /* * return the slot information of the system * * function take a sysctrl_soft_state, so it's ready for sunfire+ * change which requires 2 registers to decide the system type. */ static void sysc_slot_info(int nslots, int *start, int *limit, int *incr) { switch (nslots) { case 8: *start = 0; *limit = 8; *incr = 1; break; case 5: *start = 1; *limit = 10; *incr = 2; break; case 4: *start = 1; *limit = 8; *incr = 2; break; case 0: case 16: default: *start = 0; *limit = 16; *incr = 1; break; } } /* * reinitialize the Remote Console on the clock board * * with V5_AUX power outage the Remote Console ends up in * unknown state and has to be reinitilized if it was enabled * initially. */ static void rcons_reinit(struct sysctrl_soft_state *softsp) { uchar_t tmp_reg; if (!(softsp->rcons_ctl)) /* * There is no OBP register set for the remote console UART, * so offset from the last register set, the misc register * set, in order to map in the remote console UART. */ if (ddi_map_regs(softsp->dip, 1, (caddr_t *)&softsp->rcons_ctl, RMT_CONS_OFFSET, RMT_CONS_LEN)) { cmn_err(CE_WARN, "Unable to reinitialize " "remote console."); return; } /* Disable the remote console reset control bits. */ *(softsp->clk_freq2) &= ~RCONS_UART_EN; /* flush the hardware buffers */ tmp_reg = *(softsp->csr); /* * Program the UART to watch ttya console. */ init_remote_console_uart(softsp); /* Now enable the remote console reset control bits. */ *(softsp->clk_freq2) |= RCONS_UART_EN; /* flush the hardware buffers */ tmp_reg = *(softsp->csr); /* print some info for user to watch */ cmn_err(CE_NOTE, "Remote console reinitialized"); #ifdef lint tmp_reg = tmp_reg; #endif }