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/* 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.
*/
/* System module for Chrome EC */
#ifndef __CROS_EC_SYSTEM_H
#define __CROS_EC_SYSTEM_H
#include "atomic.h"
#include "common.h"
#include "timer.h"
/* Reset causes */
#define RESET_FLAG_OTHER (1 << 0) /* Other known reason */
#define RESET_FLAG_RESET_PIN (1 << 1) /* Reset pin asserted */
#define RESET_FLAG_BROWNOUT (1 << 2) /* Brownout */
#define RESET_FLAG_POWER_ON (1 << 3) /* Power-on reset */
#define RESET_FLAG_WATCHDOG (1 << 4) /* Watchdog timer reset */
#define RESET_FLAG_SOFT (1 << 5) /* Soft reset trigger by core */
#define RESET_FLAG_HIBERNATE (1 << 6) /* Wake from hibernate */
#define RESET_FLAG_RTC_ALARM (1 << 7) /* RTC alarm wake */
#define RESET_FLAG_WAKE_PIN (1 << 8) /* Wake pin triggered wake */
#define RESET_FLAG_LOW_BATTERY (1 << 9) /* Low battery triggered wake */
#define RESET_FLAG_SYSJUMP (1 << 10) /* Jumped directly to this image */
#define RESET_FLAG_HARD (1 << 11) /* Hard reset from software */
#define RESET_FLAG_AP_OFF (1 << 12) /* Do not power on AP */
#define RESET_FLAG_PRESERVED (1 << 13) /* Some reset flags preserved from
* previous boot */
#define RESET_FLAG_USB_RESUME (1 << 14) /* USB resume triggered wake */
/* Per chip implementation to save raw RESET_FLAG_ flags. */
void chip_save_reset_flags(int flags);
/* System images */
enum system_image_copy_t {
SYSTEM_IMAGE_UNKNOWN = 0,
SYSTEM_IMAGE_RO,
SYSTEM_IMAGE_RW,
#ifdef CONFIG_RW_B
SYSTEM_IMAGE_RW_B,
#endif
};
/**
* Pre-initializes the module. This occurs before clocks or tasks are
* set up.
*/
void system_pre_init(void);
/**
* System common pre-initialization; called after chip-specific
* system_pre_init().
*/
void system_common_pre_init(void);
/**
* Get the reset flags.
*
* @return Reset flags (RESET_FLAG_*), or 0 if the cause is unknown.
*/
uint32_t system_get_reset_flags(void);
/**
* Set reset flags.
*
* @param flags Flags to set in reset flags
*/
void system_set_reset_flags(uint32_t flags);
/**
* Clear reset flags.
*
* @param flags Flags to clear in reset flags
*/
void system_clear_reset_flags(uint32_t flags);
/**
* Print a description of the reset flags to the console.
*/
void system_print_reset_flags(void);
/**
* Check if system is locked down for normal consumer use.
*
* @return non-zero if the system is locked down for normal consumer use.
* Potentially-dangerous developer and/or factory commands must be disabled
* unless this command returns 0.
*
* This should be controlled by the same mechanism which write-protects the
* read-only image (so that the only way to unlock the system is to unprotect
* the read-only image).
*/
int system_is_locked(void);
/**
* Disable jumping between images for the rest of this boot.
*/
void system_disable_jump(void);
/**
* Return the image copy which is currently running.
*/
enum system_image_copy_t system_get_image_copy(void);
/**
* Return non-zero if the system has switched between image copies at least
* once since the last real boot.
*/
int system_jumped_to_this_image(void);
/**
* Preserve data across a jump between images.
*
* This may ONLY be called from within a HOOK_SYSJUMP handler.
*
* @param tag Data type
* @param size Size of data; must be less than 255 bytes.
* @param version Data version, so that tag data can evolve as firmware
* is updated.
* @param data Pointer to data to save
* @return EC_SUCCESS, or non-zero if error.
*/
int system_add_jump_tag(uint16_t tag, int version, int size, const void *data);
/**
* Retrieve previously stored jump data
*
* This retrieves data stored by a previous image's call to
* system_add_jump_tag().
*
* @param tag Data type to retrieve
* @param version Set to data version if successful
* @param size Set to data size if successful
* @return A pointer to the data, or NULL if no matching tag is
* found. This pointer will be 32-bit aligned.
*/
const uint8_t *system_get_jump_tag(uint16_t tag, int *version, int *size);
/**
* Return the address just past the last usable byte in RAM.
*/
uintptr_t system_usable_ram_end(void);
/**
* Return non-zero if the given range is overlapped with the active image.
*/
int system_unsafe_to_overwrite(uint32_t offset, uint32_t size);
/**
* Return a text description of the image copy which is currently running.
*/
const char *system_get_image_copy_string(void);
/**
* Return a text description of the passed image copy parameter.
*/
const char *system_image_copy_t_to_string(enum system_image_copy_t copy);
/**
* Return the number of bytes used in the specified image.
*
* This is the actual size of code+data in the image, as opposed to the
* amount of space reserved in flash for that image.
*
* @return actual image size in bytes, 0 if the image contains no content or
* error.
*/
int system_get_image_used(enum system_image_copy_t copy);
/**
* Jump to the specified image copy.
*/
int system_run_image_copy(enum system_image_copy_t copy);
/**
* Get the version string for an image
*
* @param copy Image copy to get version from, or SYSTEM_IMAGE_UNKNOWN
* to get the version for the currently running image.
* @return The version string for the image copy, or an empty string if
* error.
*/
const char *system_get_version(enum system_image_copy_t copy);
/**
* Return the board version number. The meaning of this number is
* board-dependent; boards where the code actually cares about this should
* declare enum board_version in board.h.
*/
int system_get_board_version(void);
/**
* Return information about the build including the version, build date and
* user/machine which performed the build.
*/
const char *system_get_build_info(void);
/* Flags for system_reset() */
/*
* Hard reset. Cuts power to the entire system. If not present, does a soft
* reset which just resets the core and on-chip peripherals.
*/
#define SYSTEM_RESET_HARD (1 << 0)
/*
* Preserve existing reset flags. Used by flash pre-init when it discovers it
* needs to do a hard reset to clear write protect registers.
*/
#define SYSTEM_RESET_PRESERVE_FLAGS (1 << 1)
/*
* Leave AP off on next reboot, instead of powering it on to do EC software
* sync.
*/
#define SYSTEM_RESET_LEAVE_AP_OFF (1 << 2)
/**
* Reset the system.
*
* @param flags Reset flags; see SYSTEM_RESET_* above.
*/
void system_reset(int flags);
/**
* Set a scratchpad register to the specified value.
*
* The scratchpad register must maintain its contents across a
* software-requested warm reset.
*
* @param value Value to store.
* @return EC_SUCCESS, or non-zero if error.
*/
int system_set_scratchpad(uint32_t value);
/**
* Return the current scratchpad register value.
*/
uint32_t system_get_scratchpad(void);
/**
* Return the chip vendor/name/revision string.
*/
const char *system_get_chip_vendor(void);
const char *system_get_chip_name(void);
const char *system_get_chip_revision(void);
/**
* Get/Set VbNvContext in non-volatile storage. The block should be 16 bytes
* long, which is the current size of VbNvContext block.
*
* @param block Pointer to a buffer holding VbNvContext.
* @return 0 on success, !0 on error.
*/
int system_get_vbnvcontext(uint8_t *block);
int system_set_vbnvcontext(const uint8_t *block);
/**
* Put the EC in hibernate (lowest EC power state).
*
* @param seconds Number of seconds to hibernate.
* @param microseconds Number of microseconds to hibernate.
*
* The EC will hibernate until the wake pin is asserted. If seconds and/or
* microseconds is non-zero, the EC will also automatically wake after that
* period. If both are zero, the EC will only wake on a wake pin assert. Very
* short hibernation delays do not work well; if non-zero, the delays must be
* at least SYSTEM_HIB_MINIMUM_DURATION.
*
* Note although the name is similar, EC hibernate is NOT the same as chipset
* S4/hibernate.
*/
void system_hibernate(uint32_t seconds, uint32_t microseconds);
/**
* Optional board-level callback functions called before and after initiating
* chip-level hibernate sequence. These function may or may not return,
* depending if the board implements an alternate hibernate method. The _late
* version is called after interrupts are disabled.
*/
void board_hibernate(void) __attribute__((weak));
void board_hibernate_late(void) __attribute__((weak));
/* Minimum duration to get proper hibernation */
#define SYSTEM_HIB_MINIMUM_DURATION 0, 150000
/**
* Get/Set console force enable status. This is only supported/used on platform
* with CONFIG_CONSOLE_RESTRICTED_INPUT defined.
*/
int system_get_console_force_enabled(void);
int system_set_console_force_enabled(int enabled);
/**
* Read the real-time clock.
*
* @return The real-time clock value as a timestamp.
*/
timestamp_t system_get_rtc(void);
/**
* Enable hibernate interrupt
*/
void system_enable_hib_interrupt(void);
/* Low power modes for idle API */
enum {
/*
* Sleep masks to prevent going in to deep sleep.
*/
SLEEP_MASK_AP_RUN = (1 << 0), /* the main CPU is running */
SLEEP_MASK_UART = (1 << 1), /* UART communication ongoing */
SLEEP_MASK_I2C_MASTER = (1 << 2), /* I2C master communication ongoing */
SLEEP_MASK_CHARGING = (1 << 3), /* Charging loop ongoing */
SLEEP_MASK_USB_PWR = (1 << 4), /* USB power loop ongoing */
SLEEP_MASK_USB_PD = (1 << 5), /* USB PD device connected */
SLEEP_MASK_SPI = (1 << 6), /* SPI communications ongoing */
SLEEP_MASK_I2C_SLAVE = (1 << 7), /* I2C slave communication ongoing */
SLEEP_MASK_FAN = (1 << 8), /* Fan control loop ongoing */
SLEEP_MASK_USB_DEVICE = (1 << 9), /* Generic USB device in use */
SLEEP_MASK_FORCE_NO_DSLEEP = (1 << 15), /* Force disable. */
/*
* Sleep masks to prevent using slow speed clock in deep sleep.
*/
SLEEP_MASK_JTAG = (1 << 16), /* JTAG is in use. */
SLEEP_MASK_CONSOLE = (1 << 17), /* Console is in use. */
SLEEP_MASK_FORCE_NO_LOW_SPEED = (1 << 31) /* Force disable. */
};
/*
* Current sleep mask. You may read from this variable, but must NOT
* modify it; use enable_sleep() or disable_sleep() to do that.
*/
extern uint32_t sleep_mask;
/*
* Macros to use to get whether deep sleep is allowed or whether
* low speed deep sleep is allowed.
*/
#ifndef CONFIG_LOW_POWER_S0
#define DEEP_SLEEP_ALLOWED (!(sleep_mask & 0x0000ffff))
#else
#define DEEP_SLEEP_ALLOWED (!(sleep_mask & 0x0000ffff & \
(~SLEEP_MASK_AP_RUN)))
#endif
#define LOW_SPEED_DEEP_SLEEP_ALLOWED (!(sleep_mask & 0xffff0000))
/**
* Enable low power sleep mask. For low power sleep to take affect, all masks
* in the sleep mask enum above must be enabled.
*
* @param Sleep mask to enable.
*/
static inline void enable_sleep(uint32_t mask)
{
atomic_clear(&sleep_mask, mask);
}
/**
* Disable low power sleep mask. For low power sleep to take affect, all masks
* in the sleep mask enum above must be enabled.
*
* @param Sleep mask to enable.
*/
static inline void disable_sleep(uint32_t mask)
{
atomic_or(&sleep_mask, mask);
}
/**
* Postpone sleeping for at least this long, regardless of sleep_mask.
*
* @param Amount of time to postpone sleeping
*/
void delay_sleep_by(uint32_t us);
/**
* Use hibernate module to set up an RTC interrupt at a given
* time from now
*
* Note: If time given is less than HIB_SET_RTC_MATCH_DELAY_USEC, then it will
* set the interrupt at exactly HIB_SET_RTC_MATCH_DELAY_USEC.
*
* @param seconds Number of seconds before RTC interrupt
* @param microseconds Number of microseconds before RTC interrupt
*/
void system_set_rtc_alarm(uint32_t seconds, uint32_t microseconds);
/**
* Disable and clear the RTC interrupt.
*/
void system_reset_rtc_alarm(void);
#ifdef CONFIG_EXTERNAL_STORAGE
/**
* Return address of little FW to prepare for sysjump
*
* Note: This feature is used for code ram arch
*
*/
uint32_t system_get_lfw_address(void);
/**
* Setup the destination image for a sysjump
*
* Note: This is called for devices with code ram arc by system code
* just before the jump to the little firmware. It should store the
* destination image so that it will be available to the little
* firmware after the jump.
*
* @param copy Region - (RO/RW) to use in code ram
*/
void system_set_image_copy(enum system_image_copy_t copy);
/**
* Return which region is used in Code RAM
*
* Note: This feature is used for code ram arch
*
*/
enum system_image_copy_t system_get_shrspi_image_copy(void);
#endif
#ifdef CONFIG_FW_RESET_VECTOR
/**
* Determine reset vector will be jumped to the assigned address.
*
* @return The address of the reset vector for RO/RW firmware image jump.
*/
uintptr_t system_get_fw_reset_vector(uintptr_t base);
#endif
/**
* Check if the EC is warm booting.
*
* @return true if the EC is warm booting.
*/
int system_is_reboot_warm(void);
#endif /* __CROS_EC_SYSTEM_H */
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