/* Copyright (c) 2012 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* Watchdog driver */ #include "clock.h" #include "common.h" #include "registers.h" #include "gpio.h" #include "hooks.h" #include "task.h" #include "util.h" #include "watchdog.h" /* * We use watchdog 0 which is clocked on the system clock * to avoid the penalty cycles on each write access */ /* magic value to unlock the watchdog registers */ #define LM4_WATCHDOG_MAGIC_WORD 0x1ACCE551 static uint32_t watchdog_period; /* Watchdog counter initial value */ void IRQ_HANDLER(LM4_IRQ_WATCHDOG)(void) __attribute__((naked)); void IRQ_HANDLER(LM4_IRQ_WATCHDOG)(void) { /* Naked call so we can extract raw LR and SP */ asm volatile("mov r0, lr\n" "mov r1, sp\n" /* Must push registers in pairs to keep 64-bit aligned * stack for ARM EABI. This also conveniently saves * R0=LR so we can pass it to task_resched_if_needed. */ "push {r0, lr}\n" "bl watchdog_trace\n" /* Do NOT reset the watchdog interrupt here; it will * be done in watchdog_reload(), or reset will be * triggered if we don't call that by the next watchdog * period. Instead, de-activate the interrupt in the * NVIC, so the watchdog trace will only be printed * once. */ "mov r0, %[irq]\n" "bl task_disable_irq\n" "pop {r0, lr}\n" "b task_resched_if_needed\n" : : [irq] "i" (LM4_IRQ_WATCHDOG)); } const struct irq_priority __keep IRQ_PRIORITY(LM4_IRQ_WATCHDOG) __attribute__((section(".rodata.irqprio"))) = {LM4_IRQ_WATCHDOG, 0}; /* put the watchdog at the highest priority */ void watchdog_reload(void) { uint32_t status = LM4_WATCHDOG_RIS(0); /* Unlock watchdog registers */ LM4_WATCHDOG_LOCK(0) = LM4_WATCHDOG_MAGIC_WORD; /* As we reboot only on the second timeout, if we have already reached * the first timeout we need to reset the interrupt bit. */ if (status) { LM4_WATCHDOG_ICR(0) = status; /* That doesn't seem to unpend the watchdog interrupt (even if * we do dummy writes to force the write to be committed), so * explicitly unpend the interrupt before re-enabling it. */ task_clear_pending_irq(LM4_IRQ_WATCHDOG); task_enable_irq(LM4_IRQ_WATCHDOG); } /* Reload the watchdog counter */ LM4_WATCHDOG_LOAD(0) = watchdog_period; /* Re-lock watchdog registers */ LM4_WATCHDOG_LOCK(0) = 0xdeaddead; } DECLARE_HOOK(HOOK_TICK, watchdog_reload, HOOK_PRIO_DEFAULT); static void watchdog_freq_changed(void) { /* Set the timeout period */ watchdog_period = CONFIG_WATCHDOG_PERIOD_MS * (clock_get_freq() / 1000); /* Reload the watchdog timer now */ watchdog_reload(); } DECLARE_HOOK(HOOK_FREQ_CHANGE, watchdog_freq_changed, HOOK_PRIO_DEFAULT); int watchdog_init(void) { /* Enable watchdog 0 clock in run, sleep, and deep sleep modes */ clock_enable_peripheral(CGC_OFFSET_WD, 0x1, CGC_MODE_ALL); /* Set initial timeout period */ watchdog_freq_changed(); /* Unlock watchdog registers */ LM4_WATCHDOG_LOCK(0) = LM4_WATCHDOG_MAGIC_WORD; /* De-activate the watchdog when the JTAG stops the CPU */ LM4_WATCHDOG_TEST(0) |= 1 << 8; /* Reset after 2 time-out, activate the watchdog and lock the control * register. */ LM4_WATCHDOG_CTL(0) = 0x3; /* Reset watchdog interrupt bits */ LM4_WATCHDOG_ICR(0) = LM4_WATCHDOG_RIS(0); /* Lock watchdog registers against unintended accesses */ LM4_WATCHDOG_LOCK(0) = 0xdeaddead; /* Enable watchdog interrupt */ task_enable_irq(LM4_IRQ_WATCHDOG); return EC_SUCCESS; }