coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/lm4/system.c

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2024-03-04 11:14:53 +01:00
/* Copyright 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 : LM4 hardware specific implementation */
#include "clock.h"
#include "common.h"
#include "console.h"
#include "cpu.h"
#include "host_command.h"
#include "panic.h"
#include "registers.h"
#include "system.h"
#include "task.h"
#include "timer.h"
#include "util.h"
/* Indices for hibernate data registers */
enum hibdata_index {
HIBDATA_INDEX_SCRATCHPAD, /* General-purpose scratchpad */
HIBDATA_INDEX_WAKE, /* Wake reasons for hibernate */
HIBDATA_INDEX_SAVED_RESET_FLAGS, /* Saved reset flags */
#ifdef CONFIG_SOFTWARE_PANIC
HIBDATA_INDEX_SAVED_PANIC_REASON, /* Saved panic reason */
HIBDATA_INDEX_SAVED_PANIC_INFO, /* Saved panic data */
HIBDATA_INDEX_SAVED_PANIC_EXCEPTION /* Saved panic exception code */
#endif
};
/* Flags for HIBDATA_INDEX_WAKE */
#define HIBDATA_WAKE_RTC BIT(0) /* RTC alarm */
#define HIBDATA_WAKE_HARD_RESET BIT(1) /* Hard reset via short RTC alarm */
#define HIBDATA_WAKE_PIN BIT(2) /* Wake pin */
/*
* Time to hibernate to trigger a power-on reset. 50 ms is sufficient for the
* EC itself, but we need a longer delay to ensure the rest of the components
* on the same power rail are reset and 5VALW has dropped.
*/
#define HIB_RESET_USEC 1000000
/*
* Convert between microseconds and the hibernation module RTC subsecond
* register which has 15-bit resolution. Divide down both numerator and
* denominator to avoid integer overflow while keeping the math accurate.
*/
#define HIB_RTC_USEC_TO_SUBSEC(us) ((us) * (32768/64) / (1000000/64))
#define HIB_RTC_SUBSEC_TO_USEC(ss) ((ss) * (1000000/64) / (32768/64))
/**
* Wait for a write to commit to a hibernate register.
*
* @return EC_SUCCESS if successful, non-zero if error.
*/
static int wait_for_hibctl_wc(void)
{
int i;
/* Wait for write-capable */
for (i = 0; i < 1000000; i++) {
if (LM4_HIBERNATE_HIBCTL & LM4_HIBCTL_WRC)
return EC_SUCCESS;
}
return EC_ERROR_TIMEOUT;
}
/**
* Read hibernate register at specified index.
*
* @return The value of the register or 0 if invalid index.
*/
static uint32_t hibdata_read(enum hibdata_index index)
{
if (index < 0 || index >= LM4_HIBERNATE_HIBDATA_ENTRIES)
return 0;
return LM4_HIBERNATE_HIBDATA[index];
}
/**
* Write hibernate register at specified index.
*
* @return nonzero if error.
*/
static int hibdata_write(enum hibdata_index index, uint32_t value)
{
int rv;
if (index < 0 || index >= LM4_HIBERNATE_HIBDATA_ENTRIES)
return EC_ERROR_INVAL;
/* Wait for ok-to-write */
rv = wait_for_hibctl_wc();
if (rv != EC_SUCCESS)
return rv;
/* Write register */
LM4_HIBERNATE_HIBDATA[index] = value;
/* Wait for write-complete */
return wait_for_hibctl_wc();
}
static void check_reset_cause(void)
{
uint32_t hib_status = LM4_HIBERNATE_HIBRIS;
uint32_t raw_reset_cause = LM4_SYSTEM_RESC;
uint32_t hib_wake_flags = hibdata_read(HIBDATA_INDEX_WAKE);
uint32_t flags = 0;
/* Clear the reset causes now that we've read them */
LM4_SYSTEM_RESC = 0;
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIC = hib_status;
hibdata_write(HIBDATA_INDEX_WAKE, 0);
if (raw_reset_cause & 0x02) {
/*
* Full power-on reset of chip. This resets the flash
* protection registers to their permanently-stored values.
* Note that this is also triggered by hibernation, because
* that de-powers the chip.
*/
flags |= EC_RESET_FLAG_POWER_ON;
} else if (!flags && (raw_reset_cause & 0x01)) {
/*
* LM4 signals the reset pin in RESC for all power-on resets,
* even though the external pin wasn't asserted. Make setting
* this flag mutually-exclusive with power on flag, so we can
* use it to indicate a keyboard-triggered reset.
*/
flags |= EC_RESET_FLAG_RESET_PIN;
}
if (raw_reset_cause & 0x04)
flags |= EC_RESET_FLAG_BROWNOUT;
if (raw_reset_cause & 0x10)
flags |= EC_RESET_FLAG_SOFT;
if (raw_reset_cause & 0x28) {
/* Watchdog timer 0 or 1 */
flags |= EC_RESET_FLAG_WATCHDOG;
}
/* Handle other raw reset causes */
if (raw_reset_cause && !flags)
flags |= EC_RESET_FLAG_OTHER;
if ((hib_status & 0x09) &&
(hib_wake_flags & HIBDATA_WAKE_HARD_RESET)) {
/* Hibernation caused by software-triggered hard reset */
flags |= EC_RESET_FLAG_HARD;
/* Consume the hibernate reasons so we don't see them below */
hib_status &= ~0x09;
}
if ((hib_status & 0x01) && (hib_wake_flags & HIBDATA_WAKE_RTC))
flags |= EC_RESET_FLAG_RTC_ALARM;
if ((hib_status & 0x08) && (hib_wake_flags & HIBDATA_WAKE_PIN))
flags |= EC_RESET_FLAG_WAKE_PIN;
if (hib_status & 0x04)
flags |= EC_RESET_FLAG_LOW_BATTERY;
/* Restore then clear saved reset flags */
flags |= hibdata_read(HIBDATA_INDEX_SAVED_RESET_FLAGS);
hibdata_write(HIBDATA_INDEX_SAVED_RESET_FLAGS, 0);
system_set_reset_flags(flags);
}
/*
* A3 and earlier chip stepping has a problem accessing flash during shutdown.
* To work around that, we jump to RAM before hibernating. This function must
* live in RAM. It must be called with interrupts disabled, cannot call other
* functions, and can't be declared static (or else the compiler optimizes it
* into the main hibernate function.
*/
void __attribute__((noinline)) __attribute__((section(".iram.text")))
__enter_hibernate(int hibctl)
{
LM4_HIBERNATE_HIBCTL = hibctl;
while (1)
;
}
/**
* Read the real-time clock.
*
* @param ss_ptr Destination for sub-seconds value, if not null.
*
* @return the real-time clock seconds value.
*/
uint32_t system_get_rtc_sec_subsec(uint32_t *ss_ptr)
{
uint32_t rtc, rtc2;
uint32_t rtcss, rtcss2;
/*
* The hibernate module isn't synchronized, so need to read repeatedly
* to guarantee a valid read.
*/
do {
rtc = LM4_HIBERNATE_HIBRTCC;
rtcss = LM4_HIBERNATE_HIBRTCSS & 0x7fff;
rtcss2 = LM4_HIBERNATE_HIBRTCSS & 0x7fff;
rtc2 = LM4_HIBERNATE_HIBRTCC;
} while (rtc != rtc2 || rtcss != rtcss2);
if (ss_ptr)
*ss_ptr = rtcss;
return rtc;
}
timestamp_t system_get_rtc(void)
{
uint32_t rtc, rtc_ss;
timestamp_t time;
rtc = system_get_rtc_sec_subsec(&rtc_ss);
time.val = ((uint64_t)rtc) * SECOND + HIB_RTC_SUBSEC_TO_USEC(rtc_ss);
return time;
}
/**
* Set the real-time clock.
*
* @param seconds New clock value.
*/
void system_set_rtc(uint32_t seconds)
{
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBRTCLD = seconds;
wait_for_hibctl_wc();
}
/**
* Set the hibernate RTC match time at a given time from now
*
* @param seconds Number of seconds from now for RTC match
* @param microseconds Number of microseconds from now for RTC match
*/
static void set_hibernate_rtc_match_time(uint32_t seconds,
uint32_t microseconds)
{
uint32_t rtc, rtcss;
/*
* Make sure that the requested delay is not less then the
* amount of time it takes to set the RTC match registers,
* otherwise, the match event could be missed.
*/
if (seconds == 0 && microseconds < HIB_SET_RTC_MATCH_DELAY_USEC)
microseconds = HIB_SET_RTC_MATCH_DELAY_USEC;
/* Calculate the wake match */
rtc = system_get_rtc_sec_subsec(&rtcss) + seconds;
rtcss += HIB_RTC_USEC_TO_SUBSEC(microseconds);
if (rtcss > 0x7fff) {
rtc += rtcss >> 15;
rtcss &= 0x7fff;
}
/* Set RTC alarm match */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBRTCM0 = rtc;
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBRTCSS = rtcss << 16;
wait_for_hibctl_wc();
}
/**
* Use hibernate module to set up an RTC interrupt at a given
* time from now
*
* @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)
{
/* Clear pending interrupt */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIC = LM4_HIBERNATE_HIBRIS;
/* Set match time */
set_hibernate_rtc_match_time(seconds, microseconds);
/* Enable RTC interrupt on match */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIM = 1;
/*
* Wait for the write to commit. This ensures that the RTC interrupt
* actually gets enabled. This is important if we're about to switch
* the system to the 30 kHz oscillator, which might prevent the write
* from committing.
*/
wait_for_hibctl_wc();
}
/**
* Disable and clear the RTC interrupt.
*/
void system_reset_rtc_alarm(void)
{
/* Disable hibernate interrupts */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIM = 0;
/* Clear interrupts */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIC = LM4_HIBERNATE_HIBRIS;
}
/**
* Hibernate module interrupt
*/
void __hibernate_irq(void)
{
system_reset_rtc_alarm();
}
DECLARE_IRQ(LM4_IRQ_HIBERNATE, __hibernate_irq, 1);
/**
* Enable hibernate interrupt
*/
void system_enable_hib_interrupt(void)
{
task_enable_irq(LM4_IRQ_HIBERNATE);
}
/**
* Internal hibernate function.
*
* @param seconds Number of seconds to sleep before RTC alarm
* @param microseconds Number of microseconds to sleep before RTC alarm
* @param flags Additional hibernate wake flags
*/
static void hibernate(uint32_t seconds, uint32_t microseconds, uint32_t flags)
{
uint32_t hibctl;
/* Set up wake reasons and hibernate flags */
hibctl = LM4_HIBERNATE_HIBCTL | LM4_HIBCTL_PINWEN;
if (flags & HIBDATA_WAKE_PIN)
hibctl |= LM4_HIBCTL_PINWEN;
else
hibctl &= ~LM4_HIBCTL_PINWEN;
if (seconds || microseconds) {
hibctl |= LM4_HIBCTL_RTCWEN;
flags |= HIBDATA_WAKE_RTC;
set_hibernate_rtc_match_time(seconds, microseconds);
/* Enable RTC interrupt on match */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIM = 1;
} else {
hibctl &= ~LM4_HIBCTL_RTCWEN;
}
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBCTL = hibctl;
/* Clear pending interrupt */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIC = LM4_HIBERNATE_HIBRIS;
/* Store hibernate flags */
hibdata_write(HIBDATA_INDEX_WAKE, flags);
__enter_hibernate(hibctl | LM4_HIBCTL_HIBREQ);
}
void system_hibernate(uint32_t seconds, uint32_t microseconds)
{
/* Flush console before hibernating */
cflush();
hibernate(seconds, microseconds, HIBDATA_WAKE_PIN);
}
void chip_pre_init(void)
{
/* Enable clocks to GPIO block C in run and sleep modes. */
clock_enable_peripheral(CGC_OFFSET_GPIO, 0x0004, CGC_MODE_ALL);
/*
* Ensure PC0:3 are set to JTAG function. They should be set this way
* on a cold boot, but on a warm reboot a previous misbehaving image
* could have set them differently.
*/
if (((LM4_GPIO_PCTL(LM4_GPIO_C) & 0x0000ffff) == 0x00001111) &&
((LM4_GPIO_AFSEL(LM4_GPIO_C) & 0x0f) == 0x0f) &&
((LM4_GPIO_DEN(LM4_GPIO_C) & 0x0f) == 0x0f) &&
((LM4_GPIO_PUR(LM4_GPIO_C) & 0x0f) == 0x0f))
return; /* Already properly configured */
/* Unlock commit register for JTAG pins */
LM4_GPIO_LOCK(LM4_GPIO_C) = LM4_GPIO_LOCK_UNLOCK;
LM4_GPIO_CR(LM4_GPIO_C) |= 0x0f;
/* Reset JTAG pins */
LM4_GPIO_PCTL(LM4_GPIO_C) =
(LM4_GPIO_PCTL(LM4_GPIO_C) & 0xffff0000) | 0x00001111;
LM4_GPIO_AFSEL(LM4_GPIO_C) |= 0x0f;
LM4_GPIO_DEN(LM4_GPIO_C) |= 0x0f;
LM4_GPIO_PUR(LM4_GPIO_C) |= 0x0f;
/* Set interrupt on either edge of the JTAG signals */
LM4_GPIO_IS(LM4_GPIO_C) &= ~0x0f;
LM4_GPIO_IBE(LM4_GPIO_C) |= 0x0f;
/* Re-lock commit register */
LM4_GPIO_CR(LM4_GPIO_C) &= ~0x0f;
LM4_GPIO_LOCK(LM4_GPIO_C) = 0;
}
void system_pre_init(void)
{
uint32_t hibctl;
#ifdef CONFIG_SOFTWARE_PANIC
uint32_t reason, info;
uint8_t exception;
#endif
/*
* Enable clocks to the hibernation module in run, sleep,
* and deep sleep modes.
*/
clock_enable_peripheral(CGC_OFFSET_HIB, 0x1, CGC_MODE_ALL);
/*
* Enable the hibernation oscillator, if it's not already enabled.
* This should only need setting if the EC completely lost power (for
* example, the battery was pulled).
*/
if (!(LM4_HIBERNATE_HIBCTL & LM4_HIBCTL_CLK32EN)) {
int i;
/* Enable clock to hibernate module */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBCTL |= LM4_HIBCTL_CLK32EN;
/* Wait for write-complete */
for (i = 0; i < 1000000; i++) {
if (LM4_HIBERNATE_HIBRIS & 0x10)
break;
}
/* Enable and reset RTC */
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBCTL |= LM4_HIBCTL_RTCEN;
system_set_rtc(0);
/* Clear all hibernate data entries */
for (i = 0; i < LM4_HIBERNATE_HIBDATA_ENTRIES; i++)
hibdata_write(i, 0);
}
/*
* Set wake reasons to RTC match and WAKE pin by default.
* Before going in to hibernate, these may change.
*/
hibctl = LM4_HIBERNATE_HIBCTL;
hibctl |= LM4_HIBCTL_RTCWEN;
hibctl |= LM4_HIBCTL_PINWEN;
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBCTL = hibctl;
/*
* Initialize registers after reset to work around LM4 chip errata
* (still present in A3 chip stepping).
*/
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBRTCT = 0x7fff;
wait_for_hibctl_wc();
LM4_HIBERNATE_HIBIM = 0;
check_reset_cause();
#ifdef CONFIG_SOFTWARE_PANIC
/* Restore then clear saved panic reason */
reason = hibdata_read(HIBDATA_INDEX_SAVED_PANIC_REASON);
info = hibdata_read(HIBDATA_INDEX_SAVED_PANIC_INFO);
exception = hibdata_read(HIBDATA_INDEX_SAVED_PANIC_EXCEPTION);
if (reason || info || exception) {
panic_set_reason(reason, info, exception);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_REASON, 0);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_INFO, 0);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_EXCEPTION, 0);
}
#endif
/* Initialize bootcfg if needed */
if (LM4_SYSTEM_BOOTCFG != CONFIG_BOOTCFG_VALUE) {
/* read-modify-write */
LM4_FLASH_FMD = (LM4_SYSTEM_BOOTCFG_MASK & LM4_SYSTEM_BOOTCFG)
| (~LM4_SYSTEM_BOOTCFG_MASK & CONFIG_BOOTCFG_VALUE);
LM4_FLASH_FMA = 0x75100000;
LM4_FLASH_FMC = 0xa4420008; /* WRKEY | COMT */
while (LM4_FLASH_FMC & 0x08)
;
}
/* Brown-outs should trigger a reset */
LM4_SYSTEM_PBORCTL |= 0x02;
}
void system_reset(int flags)
{
uint32_t save_flags = 0;
/* Disable interrupts to avoid task swaps during reboot */
interrupt_disable();
/* Save current reset reasons if necessary */
if (flags & SYSTEM_RESET_PRESERVE_FLAGS)
save_flags = system_get_reset_flags() | EC_RESET_FLAG_PRESERVED;
if (flags & SYSTEM_RESET_LEAVE_AP_OFF)
save_flags |= EC_RESET_FLAG_AP_OFF;
hibdata_write(HIBDATA_INDEX_SAVED_RESET_FLAGS, save_flags);
if (flags & SYSTEM_RESET_HARD) {
#ifdef CONFIG_SOFTWARE_PANIC
uint32_t reason, info;
uint8_t exception;
/* Panic data will be wiped by hard reset, so save it */
panic_get_reason(&reason, &info, &exception);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_REASON, reason);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_INFO, info);
hibdata_write(HIBDATA_INDEX_SAVED_PANIC_EXCEPTION, exception);
#endif
/*
* Bounce through hibernate to trigger a hard reboot. Do
* not wake on wake pin, since we need the full duration.
*/
hibernate(0, HIB_RESET_USEC, HIBDATA_WAKE_HARD_RESET);
} else
CPU_NVIC_APINT = 0x05fa0004;
/* Spin and wait for reboot; should never return */
while (1)
;
}
int system_set_scratchpad(uint32_t value)
{
return hibdata_write(HIBDATA_INDEX_SCRATCHPAD, value);
}
uint32_t system_get_scratchpad(void)
{
return hibdata_read(HIBDATA_INDEX_SCRATCHPAD);
}
const char *system_get_chip_vendor(void)
{
return "ti";
}
static char to_hex(int x)
{
if (x >= 0 && x <= 9)
return '0' + x;
return 'a' + x - 10;
}
const char *system_get_chip_id_string(void)
{
static char str[15] = "Unknown-";
char *p = str + 8;
uint32_t did = LM4_SYSTEM_DID1 >> 16;
if (*p)
return (const char *)str;
*p = to_hex(did >> 12);
*(p + 1) = to_hex((did >> 8) & 0xf);
*(p + 2) = to_hex((did >> 4) & 0xf);
*(p + 3) = to_hex(did & 0xf);
*(p + 4) = '\0';
return (const char *)str;
}
const char *system_get_raw_chip_name(void)
{
switch ((LM4_SYSTEM_DID1 & 0xffff0000) >> 16) {
case 0x10de:
return "tm4e1g31h6zrb";
case 0x10e2:
return "lm4fsxhh5bb";
case 0x10e3:
return "lm4fs232h5bb";
case 0x10e4:
return "lm4fs99h5bb";
case 0x10e6:
return "lm4fs1ah5bb";
case 0x10ea:
return "lm4fs1gh5bb";
default:
return system_get_chip_id_string();
}
}
const char *system_get_chip_name(void)
{
const char *postfix = "-tm"; /* test mode */
static char str[20];
const char *raw_chip_name = system_get_raw_chip_name();
char *p = str;
if (LM4_TEST_MODE_ENABLED) {
/* Debug mode is enabled. Postfix chip name. */
while (*raw_chip_name)
*(p++) = *(raw_chip_name++);
while (*postfix)
*(p++) = *(postfix++);
*p = '\0';
return (const char *)str;
} else {
return raw_chip_name;
}
}
int system_get_bbram(enum system_bbram_idx idx, uint8_t *value)
{
return EC_ERROR_UNIMPLEMENTED;
}
int system_set_bbram(enum system_bbram_idx idx, uint8_t value)
{
return EC_ERROR_UNIMPLEMENTED;
}
const char *system_get_chip_revision(void)
{
static char rev[3];
/* Extract the major[15:8] and minor[7:0] revisions. */
rev[0] = 'A' + ((LM4_SYSTEM_DID0 >> 8) & 0xff);
rev[1] = '0' + (LM4_SYSTEM_DID0 & 0xff);
rev[2] = 0;
return rev;
}
/*****************************************************************************/
/* Console commands */
void print_system_rtc(enum console_channel ch)
{
uint32_t rtc;
uint32_t rtcss;
rtc = system_get_rtc_sec_subsec(&rtcss);
cprintf(ch, "RTC: 0x%08x.%04x (%d.%06d s)\n",
rtc, rtcss, rtc, HIB_RTC_SUBSEC_TO_USEC(rtcss));
}
#ifdef CONFIG_CMD_RTC
static int command_system_rtc(int argc, char **argv)
{
if (argc == 3 && !strcasecmp(argv[1], "set")) {
char *e;
uint32_t t = strtoi(argv[2], &e, 0);
if (*e)
return EC_ERROR_PARAM2;
system_set_rtc(t);
} else if (argc > 1) {
return EC_ERROR_INVAL;
}
print_system_rtc(CC_COMMAND);
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(rtc, command_system_rtc,
"[set <seconds>]",
"Get/set real-time clock");
#ifdef CONFIG_CMD_RTC_ALARM
/**
* Test the RTC alarm by setting an interrupt on RTC match.
*/
static int command_rtc_alarm_test(int argc, char **argv)
{
int s = 1, us = 0;
char *e;
ccprintf("Setting RTC alarm\n");
system_enable_hib_interrupt();
if (argc > 1) {
s = strtoi(argv[1], &e, 10);
if (*e)
return EC_ERROR_PARAM1;
}
if (argc > 2) {
us = strtoi(argv[2], &e, 10);
if (*e)
return EC_ERROR_PARAM2;
}
system_set_rtc_alarm(s, us);
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(rtc_alarm, command_rtc_alarm_test,
"[seconds [microseconds]]",
"Test alarm");
#endif /* CONFIG_CMD_RTC_ALARM */
#endif /* CONFIG_CMD_RTC */
/*****************************************************************************/
/* Host commands */
#ifdef CONFIG_HOSTCMD_RTC
static enum ec_status system_rtc_get_value(struct host_cmd_handler_args *args)
{
struct ec_response_rtc *r = args->response;
r->time = system_get_rtc_sec_subsec(NULL);
args->response_size = sizeof(*r);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_RTC_GET_VALUE,
system_rtc_get_value,
EC_VER_MASK(0));
static enum ec_status system_rtc_set_value(struct host_cmd_handler_args *args)
{
const struct ec_params_rtc *p = args->params;
system_set_rtc(p->time);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_RTC_SET_VALUE,
system_rtc_set_value,
EC_VER_MASK(0));
#endif /* CONFIG_HOSTCMD_RTC */