/* Copyright (c) 2013 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. * * Main routine for Chrome EC */ #include "board_config.h" #include "clock.h" #include "common.h" #include "console.h" #include "cpu.h" #include "eeprom.h" #include "eoption.h" #include "flash.h" #include "gpio.h" #include "hooks.h" #include "jtag.h" #include "keyboard_scan.h" #include "system.h" #include "task.h" #include "timer.h" #include "uart.h" #include "watchdog.h" /* Console output macros */ #define CPUTS(outstr) cputs(CC_SYSTEM, outstr) #define CPRINTF(format, args...) cprintf(CC_SYSTEM, format, ## args) test_mockable int main(void) { /* * Pre-initialization (pre-verified boot) stage. Initialization at * this level should do as little as possible, because verified boot * may need to jump to another image, which will repeat this * initialization. In particular, modules should NOT enable * interrupts. */ #ifdef CONFIG_BOARD_PRE_INIT board_config_pre_init(); #endif /* Configure the pin multiplexers and GPIOs */ jtag_pre_init(); gpio_pre_init(); #ifdef CONFIG_BOARD_POST_GPIO_INIT board_config_post_gpio_init(); #endif /* * Initialize interrupts, but don't enable any of them. Note that * task scheduling is not enabled until task_start() below. */ task_pre_init(); /* * Initialize the system module. This enables the hibernate clock * source we need to calibrate the internal oscillator. */ system_pre_init(); system_common_pre_init(); #ifdef CONFIG_FLASH /* * Initialize flash and apply write protect if necessary. Requires * the reset flags calculated by system initialization. */ flash_pre_init(); #endif /* Set the CPU clocks / PLLs. System is now running at full speed. */ clock_init(); /* * Initialize timer. Everything after this can be benchmarked. * get_time() and udelay() may now be used. usleep() requires task * scheduling, so cannot be used yet. Note that interrupts declared * via DECLARE_IRQ() call timer routines when profiling is enabled, so * timer init() must be before uart_init(). */ timer_init(); /* Main initialization stage. Modules may enable interrupts here. */ cpu_init(); /* Initialize UART. Console output functions may now be used. */ uart_init(); if (system_jumped_to_this_image()) { CPRINTF("[%T UART initialized after sysjump]\n"); } else { CPUTS("\n\n--- UART initialized after reboot ---\n"); CPUTS("[Reset cause: "); system_print_reset_flags(); CPUTS("]\n"); } CPRINTF("[Image: %s, %s]\n", system_get_image_copy_string(), system_get_build_info()); #ifdef CONFIG_WATCHDOG /* * Intialize watchdog timer. All lengthy operations between now and * task_start() must periodically call watchdog_reload() to avoid * triggering a watchdog reboot. (This pretty much applies only to * verified boot, because all *other* lengthy operations should be done * by tasks.) */ watchdog_init(); #endif /* * Verified boot needs to read the initial keyboard state and EEPROM * contents. EEPROM must be up first, so keyboard_scan can toggle * debugging settings via keys held at boot. */ #ifdef CONFIG_EEPROM eeprom_init(); #endif #ifdef CONFIG_EOPTION eoption_init(); #endif #ifdef HAS_TASK_KEYSCAN keyboard_scan_init(); #endif /* Initialize the hook library. This calls HOOK_INIT hooks. */ hook_init(); /* * Print the init time. Not completely accurate because it can't take * into account the time before timer_init(), but it'll at least catch * the majority of the time. */ CPRINTF("[%T Inits done]\n"); /* Launch task scheduling (never returns) */ return task_start(); }