// SPDX-License-Identifier: Apache-2.0 /* * Copyright 2013-2018 IBM Corp. * Copyright 2018 Google Corp. */ #include #include #include #include #include #include #include #include #include #define TIMER_USE_DONT_LOG 0x80 #define TIMER_USE_DONT_STOP 0x40 #define TIMER_USE_POST 0x02 /* WDT expiration actions */ #define WDT_PRETIMEOUT_SMI 0x10 #define WDT_RESET_ACTION 0x01 #define WDT_NO_ACTION 0x00 /* IPMI defined custom completion codes for the watchdog */ #define WDT_CC_OK 0x00 #define WDT_CC_NOT_INITIALIZED 0x80 /* Flags used for IPMI callbacks */ #define WDT_SET_DO_RESET 0x01 #define WDT_RESET_NO_REINIT 0x01 /* How long to set the overall watchdog timeout for. In units of * 100ms. If the timer is not reset within this time the watchdog * expiration action will occur. */ #define WDT_TIMEOUT 600 /* How often to reset the timer using schedule_timer(). Too short and we risk accidentally resetting the system due to opal_run_pollers() not being called in time, too short and we waste time resetting the wdt more frequently than necessary. */ #define WDT_MARGIN 300 static struct timer wdt_timer; static bool wdt_stopped; static bool wdt_ticking; /* Saved values from the last watchdog set action */ static uint8_t last_action; static uint16_t last_count; static uint8_t last_pretimeout; static void reset_wdt(struct timer *t, void *data, uint64_t now); static void set_wdt_complete(struct ipmi_msg *msg) { const uintptr_t flags = (uintptr_t)msg->user_data; if (flags & WDT_SET_DO_RESET) { /* Make sure the reset action does not create a loop and * perform a reset in the case where the BMC send an * uninitialized error. */ reset_wdt(NULL, (void *)WDT_RESET_NO_REINIT, 0); } ipmi_free_msg(msg); } static void set_wdt(uint8_t action, uint16_t count, uint8_t pretimeout, bool dont_stop, bool do_reset) { struct ipmi_msg *ipmi_msg; uintptr_t completion_flags = 0; if (do_reset) completion_flags |= WDT_SET_DO_RESET; /* Save the values prior to issuing the set operation so that we can * re-initialize the watchdog in error cases. */ last_action = action; last_count = count; last_pretimeout = pretimeout; ipmi_msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_SET_WDT, set_wdt_complete, NULL, NULL, 6, 0); if (!ipmi_msg) { prerror("Unable to allocate set wdt message\n"); return; } ipmi_msg->error = set_wdt_complete; ipmi_msg->user_data = (void *)completion_flags; ipmi_msg->data[0] = TIMER_USE_POST | TIMER_USE_DONT_LOG | (dont_stop ? TIMER_USE_DONT_STOP : 0); ipmi_msg->data[1] = action; /* Timer Actions */ ipmi_msg->data[2] = pretimeout; /* Pre-timeout Interval */ ipmi_msg->data[3] = 0; /* Timer Use Flags */ ipmi_msg->data[4] = count & 0xff; /* Initial countdown (lsb) */ ipmi_msg->data[5] = (count >> 8) & 0xff; /* Initial countdown (msb) */ ipmi_queue_msg(ipmi_msg); } static void reset_wdt_complete(struct ipmi_msg *msg) { const uintptr_t flags = (uintptr_t)msg->user_data; uint64_t reset_delay_ms = (WDT_TIMEOUT - WDT_MARGIN) * 100; if (msg->cc == WDT_CC_NOT_INITIALIZED && !(flags & WDT_RESET_NO_REINIT)) { /* If our timer was not initialized on the BMC side, we should * perform a single attempt to set it up again. */ set_wdt(last_action, last_count, last_pretimeout, true, true); } else if (msg->cc != WDT_CC_OK) { /* Use a short (10s) timeout before performing the next reset * if we encounter an unknown error. This makes sure that we * are able to reset and re-initialize the timer since it might * expire. */ reset_delay_ms = 10 * 1000; } /* If we are inside of skiboot we need to periodically restart the * timer. Reschedule a reset so it happens before the timeout. */ if (wdt_ticking) schedule_timer(&wdt_timer, msecs_to_tb(reset_delay_ms)); ipmi_free_msg(msg); } static struct ipmi_msg *wdt_reset_mkmsg(void) { struct ipmi_msg *ipmi_msg; ipmi_msg = ipmi_mkmsg(IPMI_DEFAULT_INTERFACE, IPMI_RESET_WDT, reset_wdt_complete, NULL, NULL, 0, 0); if (!ipmi_msg) { prerror("Unable to allocate reset wdt message\n"); return NULL; } ipmi_msg->error = reset_wdt_complete; return ipmi_msg; } static void sync_reset_wdt(void) { struct ipmi_msg *ipmi_msg; if ((ipmi_msg = wdt_reset_mkmsg())) ipmi_queue_msg_sync(ipmi_msg); } static void reset_wdt(struct timer *t __unused, void *data, uint64_t now __unused) { struct ipmi_msg *ipmi_msg; if ((ipmi_msg = wdt_reset_mkmsg())) { ipmi_msg->user_data = data; ipmi_queue_msg_head(ipmi_msg); } } void ipmi_wdt_stop(void) { if (!wdt_stopped) { /* Make sure the background reset timer is disabled before * stopping the watchdog. If we issue a reset after disabling * the timer, it will be re-enabled. */ wdt_ticking = false; cancel_timer(&wdt_timer); /* Configure the watchdog to be disabled and do no action * in case the underlying implementation is buggy and times * out anyway. */ wdt_stopped = true; set_wdt(WDT_NO_ACTION, 100, 0, false, false); } } void ipmi_wdt_final_reset(void) { /* We can safely stop the timer prior to setting up our final * watchdog timeout since we have enough margin before the * timeout. */ wdt_ticking = false; cancel_timer(&wdt_timer); /* * We're going to wait a little while before requiring * BOOTKERNEL to have IPMI watchdog support so that people * can catch up in their development environments. * If you still read this after 2018, send a patch! */ #if 0 /* Configure the watchdog and make sure it is still enabled */ set_wdt(WDT_RESET_ACTION | WDT_PRETIMEOUT_SMI, WDT_TIMEOUT, WDT_MARGIN/10, true, true); sync_reset_wdt(); #else set_wdt(WDT_NO_ACTION, 100, 0, false, false); #endif ipmi_set_boot_count(); } void ipmi_wdt_init(void) { init_timer(&wdt_timer, reset_wdt, NULL); set_wdt(WDT_RESET_ACTION, WDT_TIMEOUT, 0, true, false); /* Start the WDT. We do it synchronously to make sure it has * started before skiboot continues booting. Otherwise we * could crash before the wdt has actually been started. */ wdt_ticking = true; sync_reset_wdt(); return; }