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/* Copyright 2016 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.
*/
/* Clocks and power management settings */
#include "chipset.h"
#include "clock.h"
#include "clock-f.h"
#include "common.h"
#include "console.h"
#include "cpu.h"
#include "hooks.h"
#include "host_command.h"
#include "hwtimer.h"
#include "registers.h"
#include "rtc.h"
#include "system.h"
#include "task.h"
#include "timer.h"
#include "util.h"
/* Console output macros */
#define CPUTS(outstr) cputs(CC_CLOCK, outstr)
#define CPRINTS(format, args...) cprints(CC_CLOCK, format, ## args)
/* Convert decimal to BCD */
static uint8_t u8_to_bcd(uint8_t val)
{
/* Fast division by 10 (when lacking HW div) */
uint32_t quot = ((uint32_t)val * 0xCCCD) >> 19;
uint32_t rem = val - quot * 10;
return rem | (quot << 4);
}
/* Convert between RTC regs in BCD and seconds */
static uint32_t rtc_tr_to_sec(uint32_t rtc_tr)
{
uint32_t sec;
/* convert the hours field */
sec = (((rtc_tr & 0x300000) >> 20) * 10 +
((rtc_tr & 0xf0000) >> 16)) * 3600;
/* convert the minutes field */
sec += (((rtc_tr & 0x7000) >> 12) * 10 + ((rtc_tr & 0xf00) >> 8)) * 60;
/* convert the seconds field */
sec += ((rtc_tr & 0x70) >> 4) * 10 + (rtc_tr & 0xf);
return sec;
}
static uint32_t sec_to_rtc_tr(uint32_t sec)
{
uint32_t rtc_tr;
uint8_t hour;
uint8_t min;
sec %= SECS_PER_DAY;
/* convert the hours field */
hour = sec / 3600;
rtc_tr = u8_to_bcd(hour) << 16;
/* convert the minutes field */
sec -= hour * 3600;
min = sec / 60;
rtc_tr |= u8_to_bcd(min) << 8;
/* convert the seconds field */
sec -= min * 60;
rtc_tr |= u8_to_bcd(sec);
return rtc_tr;
}
/* Register setup before RTC alarm is allowed for update */
static void pre_work_set_rtc_alarm(void)
{
rtc_unlock_regs();
/* Make sure alarm is disabled */
STM32_RTC_CR &= ~STM32_RTC_CR_ALRAE;
while (!(STM32_RTC_ISR & STM32_RTC_ISR_ALRAWF))
;
STM32_RTC_ISR &= ~STM32_RTC_ISR_ALRAF;
}
/* Register setup after RTC alarm is updated */
static void post_work_set_rtc_alarm(void)
{
STM32_EXTI_PR = EXTI_RTC_ALR_EVENT;
/* Enable alarm and alarm interrupt */
STM32_EXTI_IMR |= EXTI_RTC_ALR_EVENT;
STM32_RTC_CR |= STM32_RTC_CR_ALRAE;
rtc_lock_regs();
}
#ifdef CONFIG_HOSTCMD_RTC
static struct wake_time host_wake_time;
int is_host_wake_alarm_expired(timestamp_t ts)
{
return host_wake_time.ts.val &&
timestamp_expired(host_wake_time.ts, &ts);
}
void restore_host_wake_alarm(void)
{
if (!host_wake_time.ts.val)
return;
pre_work_set_rtc_alarm();
/* Set alarm time */
STM32_RTC_ALRMAR = host_wake_time.rtc_alrmar;
post_work_set_rtc_alarm();
}
static uint32_t rtc_dr_to_sec(uint32_t rtc_dr)
{
struct calendar_date time;
uint32_t sec;
time.year = (((rtc_dr & 0xf00000) >> 20) * 10 +
((rtc_dr & 0xf0000) >> 16));
time.month = (((rtc_dr & 0x1000) >> 12) * 10 +
((rtc_dr & 0xf00) >> 8));
time.day = ((rtc_dr & 0x30) >> 4) * 10 + (rtc_dr & 0xf);
sec = date_to_sec(time);
return sec;
}
static uint32_t sec_to_rtc_dr(uint32_t sec)
{
struct calendar_date time;
uint32_t rtc_dr;
time = sec_to_date(sec);
rtc_dr = u8_to_bcd(time.year) << 16;
rtc_dr |= u8_to_bcd(time.month) << 8;
rtc_dr |= u8_to_bcd(time.day);
return rtc_dr;
}
#endif
uint32_t rtc_to_sec(const struct rtc_time_reg *rtc)
{
uint32_t sec = 0;
#ifdef CONFIG_HOSTCMD_RTC
sec = rtc_dr_to_sec(rtc->rtc_dr);
#endif
return sec + (rtcss_to_us(rtc->rtc_ssr) / SECOND) +
rtc_tr_to_sec(rtc->rtc_tr);
}
void sec_to_rtc(uint32_t sec, struct rtc_time_reg *rtc)
{
rtc->rtc_dr = 0;
#ifdef CONFIG_HOSTCMD_RTC
rtc->rtc_dr = sec_to_rtc_dr(sec);
#endif
rtc->rtc_tr = sec_to_rtc_tr(sec);
rtc->rtc_ssr = 0;
}
/* Return sub-10-sec time diff between two rtc readings
*
* Note: this function assumes rtc0 was sampled before rtc1.
* Additionally, this function only looks at the difference mod 10
* seconds.
*/
uint32_t get_rtc_diff(const struct rtc_time_reg *rtc0,
const struct rtc_time_reg *rtc1)
{
uint32_t rtc0_val, rtc1_val, diff;
rtc0_val = (rtc0->rtc_tr & 0xF) * SECOND + rtcss_to_us(rtc0->rtc_ssr);
rtc1_val = (rtc1->rtc_tr & 0xF) * SECOND + rtcss_to_us(rtc1->rtc_ssr);
diff = rtc1_val;
if (rtc1_val < rtc0_val) {
/* rtc_ssr has wrapped, since we assume rtc0 < rtc1, add
* 10 seconds to get the correct value
*/
diff += 10 * SECOND;
}
diff -= rtc0_val;
return diff;
}
void rtc_read(struct rtc_time_reg *rtc)
{
/*
* Read current time synchronously. Each register must be read
* twice with identical values because glitches may occur for reads
* close to the RTCCLK edge.
*/
do {
rtc->rtc_dr = STM32_RTC_DR;
do {
rtc->rtc_tr = STM32_RTC_TR;
do {
rtc->rtc_ssr = STM32_RTC_SSR;
} while (rtc->rtc_ssr != STM32_RTC_SSR);
} while (rtc->rtc_tr != STM32_RTC_TR);
} while (rtc->rtc_dr != STM32_RTC_DR);
}
void set_rtc_alarm(uint32_t delay_s, uint32_t delay_us,
struct rtc_time_reg *rtc, uint8_t save_alarm)
{
uint32_t alarm_sec = 0;
uint32_t alarm_us = 0;
if (delay_s == EC_RTC_ALARM_CLEAR && !delay_us) {
reset_rtc_alarm(rtc);
return;
}
/* Alarm timeout must be within 1 day (86400 seconds) */
ASSERT((delay_s + delay_us / SECOND) < SECS_PER_DAY);
pre_work_set_rtc_alarm();
rtc_read(rtc);
/* Calculate alarm time */
alarm_sec = rtc_tr_to_sec(rtc->rtc_tr) + delay_s;
if (delay_us) {
alarm_us = rtcss_to_us(rtc->rtc_ssr) + delay_us;
alarm_sec = alarm_sec + alarm_us / SECOND;
alarm_us = alarm_us % SECOND;
}
/*
* If seconds is greater than 1 day, subtract by 1 day to deal with
* 24-hour rollover.
*/
if (alarm_sec >= SECS_PER_DAY)
alarm_sec -= SECS_PER_DAY;
/*
* Set alarm time in seconds and check for match on
* hours, minutes, and seconds.
*/
STM32_RTC_ALRMAR = sec_to_rtc_tr(alarm_sec) | 0xc0000000;
/*
* Set alarm time in subseconds and check for match on subseconds.
* If the caller doesn't specify subsecond delay (e.g. host command),
* just align the alarm time to second.
*/
STM32_RTC_ALRMASSR = delay_us ?
(us_to_rtcss(alarm_us) | 0x0f000000) : 0;
#ifdef CONFIG_HOSTCMD_RTC
/*
* If alarm is set by the host, preserve the wake time timestamp
* and alarm registers.
*/
if (save_alarm) {
host_wake_time.ts.val = delay_s * SECOND + get_time().val;
host_wake_time.rtc_alrmar = STM32_RTC_ALRMAR;
}
#endif
post_work_set_rtc_alarm();
}
uint32_t get_rtc_alarm(void)
{
struct rtc_time_reg now;
uint32_t now_sec;
uint32_t alarm_sec;
if (!(STM32_RTC_CR & STM32_RTC_CR_ALRAE))
return 0;
rtc_read(&now);
now_sec = rtc_tr_to_sec(now.rtc_tr);
alarm_sec = rtc_tr_to_sec(STM32_RTC_ALRMAR & 0x3fffff);
return ((alarm_sec < now_sec) ? SECS_PER_DAY : 0) +
(alarm_sec - now_sec);
}
void reset_rtc_alarm(struct rtc_time_reg *rtc)
{
rtc_unlock_regs();
/* Disable alarm */
STM32_RTC_CR &= ~STM32_RTC_CR_ALRAE;
STM32_RTC_ISR &= ~STM32_RTC_ISR_ALRAF;
/* Disable RTC alarm interrupt */
STM32_EXTI_IMR &= ~EXTI_RTC_ALR_EVENT;
STM32_EXTI_PR = EXTI_RTC_ALR_EVENT;
/* Clear the pending RTC alarm IRQ in NVIC */
task_clear_pending_irq(STM32_IRQ_RTC_ALARM);
/* Read current time */
rtc_read(rtc);
rtc_lock_regs();
}
test_mockable_static
void __rtc_alarm_irq(void)
{
struct rtc_time_reg rtc;
reset_rtc_alarm(&rtc);
#ifdef CONFIG_HOSTCMD_RTC
/* Wake up the host if there is a saved rtc wake alarm. */
if (host_wake_time.ts.val) {
host_wake_time.ts.val = 0;
host_set_single_event(EC_HOST_EVENT_RTC);
}
#endif
}
DECLARE_IRQ(STM32_IRQ_RTC_ALARM, __rtc_alarm_irq, 1);
__attribute__((weak))
int clock_get_timer_freq(void)
{
return clock_get_freq();
}
void clock_init(void)
{
/*
* The initial state :
* SYSCLK from HSI (=8MHz), no divider on AHB, APB1, APB2
* PLL unlocked, RTC enabled on LSE
*/
/*
* put 1 Wait-State for flash access to ensure proper reads at 48Mhz
* and enable prefetch buffer.
*/
STM32_FLASH_ACR = STM32_FLASH_ACR_LATENCY | STM32_FLASH_ACR_PRFTEN;
#ifdef CHIP_FAMILY_STM32F4
/* Enable data and instruction cache. */
STM32_FLASH_ACR |= STM32_FLASH_ACR_DCEN | STM32_FLASH_ACR_ICEN;
#endif
config_hispeed_clock();
rtc_init();
}
#ifdef CHIP_FAMILY_STM32F4
void reset_flash_cache(void)
{
/* Disable data and instruction cache. */
STM32_FLASH_ACR &= ~(STM32_FLASH_ACR_DCEN | STM32_FLASH_ACR_ICEN);
/* Reset data and instruction cache */
STM32_FLASH_ACR |= STM32_FLASH_ACR_DCRST | STM32_FLASH_ACR_ICRST;
}
DECLARE_HOOK(HOOK_SYSJUMP, reset_flash_cache, HOOK_PRIO_DEFAULT);
#endif
/*****************************************************************************/
/* Console commands */
void print_system_rtc(enum console_channel ch)
{
uint32_t sec;
struct rtc_time_reg rtc;
rtc_read(&rtc);
sec = rtc_to_sec(&rtc);
cprintf(ch, "RTC: 0x%08x (%d.00 s)\n", sec, sec);
}
#ifdef CONFIG_CMD_RTC
static int command_system_rtc(int argc, char **argv)
{
char *e;
uint32_t t;
if (argc == 3 && !strcasecmp(argv[1], "set")) {
t = strtoi(argv[2], &e, 0);
if (*e)
return EC_ERROR_PARAM2;
rtc_set(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
static int command_rtc_alarm_test(int argc, char **argv)
{
int s = 1, us = 0;
struct rtc_time_reg rtc;
char *e;
ccprintf("Setting RTC alarm\n");
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;
}
set_rtc_alarm(s, us, &rtc, 0);
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;
struct rtc_time_reg rtc;
rtc_read(&rtc);
r->time = rtc_to_sec(&rtc);
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;
rtc_set(p->time);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_RTC_SET_VALUE,
system_rtc_set_value,
EC_VER_MASK(0));
static enum ec_status system_rtc_set_alarm(struct host_cmd_handler_args *args)
{
struct rtc_time_reg rtc;
const struct ec_params_rtc *p = args->params;
/* Alarm timeout must be within 1 day (86400 seconds) */
if (p->time >= SECS_PER_DAY)
return EC_RES_INVALID_PARAM;
set_rtc_alarm(p->time, 0, &rtc, 1);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_RTC_SET_ALARM,
system_rtc_set_alarm,
EC_VER_MASK(0));
static enum ec_status system_rtc_get_alarm(struct host_cmd_handler_args *args)
{
struct ec_response_rtc *r = args->response;
r->time = get_rtc_alarm();
args->response_size = sizeof(*r);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_RTC_GET_ALARM,
system_rtc_get_alarm,
EC_VER_MASK(0));
#endif /* CONFIG_HOSTCMD_RTC */
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