rt-thread/bsp/nuvoton/libraries/m2354/rtt_port/drv_clk.c

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/**************************************************************************//**
*
* @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2020-07-15 klcheng First version
*
******************************************************************************/
#include <rtconfig.h>
#if defined(BSP_USING_CLK)
#include <rtdevice.h>
#include <rthw.h>
#include <rtdbg.h>
#include <stdint.h>
#include <string.h>
#include "NuMicro.h"
/* Private define ---------------------------------------------------------------*/
/* pm run mode speed mapping */
#define CONFIG_HIGH_SPEED_FREQ (96000000ul)
#define CONFIG_NORMAL_SPEED_FREQ (96000000ul)
#define CONFIG_MEDIMUM_SPEED_FREQ (64000000ul)
#define CONFIG_LOW_SPEED_FREQ (48000000ul)
/* pm sleep mode mapping */
#define CONFIG_MODE_LIGHT (CLK_PMUCTL_PDMSEL_FWPD)
#define CONFIG_MODE_DEEP (CLK_PMUCTL_PDMSEL_PD)
#define CONFIG_MODE_STANDBY (CLK_PMUCTL_PDMSEL_SPD)
#define CONFIG_MODE_SHUTDOWN (CLK_PMUCTL_PDMSEL_DPD)
#if defined (NU_CLK_INVOKE_WKTMR)
/* Wake-up timer clock source is 32K */
#define WKTMR_INTERVAL (CLK_PMUCTL_WKTMRIS_209715)
#endif
/* Timer module assigned for pm device usage. */
/* e.g. If TIMERn is reserved for pm, then define the PM_TIMER_USE_INSTANCE
macro to n value (without parentheses). */
#define PM_TIMER_USE_INSTANCE 5
/* Concatenate */
#define _CONCAT2_(x, y) x##y
#define _CONCAT3_(x, y, z) x##y##z
#define CONCAT2(x, y) _CONCAT2_(x, y)
#define CONCAT3(x, y, z) _CONCAT3_(x,y,z)
/* Concatenate the macros of timer instance for driver usage. */
#define PM_TIMER CONCAT2(TIMER, PM_TIMER_USE_INSTANCE)
#define PM_TMR CONCAT2(TMR, PM_TIMER_USE_INSTANCE)
#define PM_TIMER_MODULE CONCAT2(PM_TMR, _MODULE)
#define PM_TIMER_IRQn CONCAT2(PM_TMR, _IRQn)
#define PM_TIMER_IRQHandler CONCAT2(PM_TMR, _IRQHandler)
#define PM_TIMER_SEL_LXT CONCAT3(CLK_CLKSEL3_, PM_TMR, SEL_LXT)
/* Private typedef --------------------------------------------------------------*/
/* Private functions ------------------------------------------------------------*/
static void pm_sleep(struct rt_pm *pm, rt_uint8_t mode);
static void pm_run(struct rt_pm *pm, rt_uint8_t mode);
static void pm_timer_start(struct rt_pm *pm, rt_uint32_t timeout);
static void pm_timer_stop(struct rt_pm *pm);
static rt_tick_t pm_timer_get_tick(struct rt_pm *pm);
static rt_tick_t pm_tick_from_os_tick(rt_tick_t os_tick);
static rt_tick_t os_tick_from_pm_tick(rt_tick_t pm_tick);
/* Public functions -------------------------------------------------------------*/
int rt_hw_pm_init(void);
/* Private variables ------------------------------------------------------------*/
static struct rt_pm_ops ops =
{
.sleep = pm_sleep,
.run = pm_run,
.timer_start = pm_timer_start,
.timer_stop = pm_timer_stop,
.timer_get_tick = pm_timer_get_tick,
};
struct rt_device pm;
/* Sleep and power-down mapping */
const static uint32_t g_au32SleepingMode[PM_SLEEP_MODE_MAX] =
{
0,
0,
CONFIG_MODE_LIGHT,
CONFIG_MODE_DEEP,
CONFIG_MODE_STANDBY,
CONFIG_MODE_SHUTDOWN
};
/* pm sleep() entry */
static void pm_sleep(struct rt_pm *pm, rt_uint8_t mode)
{
RT_ASSERT(mode < PM_SLEEP_MODE_MAX);
if ((mode == PM_SLEEP_MODE_NONE) || (mode == PM_SLEEP_MODE_IDLE))
return;
/* wake-up source: */
/* PM_SLEEP_MODE_LIGHT : TIMERn */
/* PM_SLEEP_MODE_DEEP : TIMERn */
/* PM_SLEEP_MODE_STANDBY : wake-up timer (optional) */
/* PM_SLEEP_MODE_SHUTDOWN : wake-up timer (optional) */
SYS_UnlockReg();
#if defined (NU_CLK_INVOKE_WKTMR)
if ((mode == PM_SLEEP_MODE_SHUTDOWN) || (mode == PM_SLEEP_MODE_STANDBY))
{
/* Enable wake-up timer with pre-defined interval if it is invoked */
CLK_SET_WKTMR_INTERVAL(WKTMR_INTERVAL);
CLK_ENABLE_WKTMR();
}
#endif
/* Set Power-down Mode */
CLK_SetPowerDownMode(g_au32SleepingMode[mode]);
/* Here, take a break. */
CLK_PowerDown();
SYS_LockReg();
}
/* pm run() entry */
static void pm_run(struct rt_pm *pm, rt_uint8_t mode)
{
static uint8_t prev_mode = RT_PM_DEFAULT_RUN_MODE;
/* ignore it if power mode is the same. */
if (mode == prev_mode)
return;
prev_mode = mode;
SYS_UnlockReg();
/* Switch run mode frequency using PLL + HXT if HXT is enabled.
Otherwise, the system clock will use PLL + HIRC. */
switch (mode)
{
case PM_RUN_MODE_HIGH_SPEED:
CLK_SetCoreClock(CONFIG_HIGH_SPEED_FREQ);
break;
case PM_RUN_MODE_NORMAL_SPEED:
CLK_SetCoreClock(CONFIG_NORMAL_SPEED_FREQ);
break;
case PM_RUN_MODE_MEDIUM_SPEED:
CLK_SetCoreClock(CONFIG_MEDIMUM_SPEED_FREQ);
break;
case PM_RUN_MODE_LOW_SPEED:
CLK_SetCoreClock(CONFIG_LOW_SPEED_FREQ);
break;
default:
RT_ASSERT(0);
break;
}
SystemCoreClockUpdate();
SysTick_Config(SystemCoreClock / RT_TICK_PER_SECOND);
SYS_LockReg();
}
static void hw_timer_init(void)
{
/* Assign a hardware timer for pm usage. */
SYS_UnlockReg();
CLK_SetModuleClock(PM_TIMER_MODULE, PM_TIMER_SEL_LXT, MODULE_NoMsk);
CLK_EnableModuleClock(PM_TIMER_MODULE);
SYS_LockReg();
/* Initialize timer and enable wakeup function. */
TIMER_Open(PM_TIMER, TIMER_CONTINUOUS_MODE, 1);
TIMER_SET_PRESCALE_VALUE(PM_TIMER, 0);
TIMER_EnableInt(PM_TIMER);
TIMER_EnableWakeup(PM_TIMER);
NVIC_EnableIRQ(PM_TIMER_IRQn);
}
/* convert os tick to pm timer tick */
static rt_tick_t pm_tick_from_os_tick(rt_tick_t os_tick)
{
rt_uint32_t hz = TIMER_GetModuleClock(PM_TIMER);
return (rt_tick_t)(hz * os_tick / RT_TICK_PER_SECOND);
}
/* convert pm timer tick to os tick */
static rt_tick_t os_tick_from_pm_tick(rt_tick_t pm_tick)
{
static rt_uint32_t os_tick_remain = 0;
rt_uint32_t ret, hz;
hz = TIMER_GetModuleClock(PM_TIMER);
ret = (pm_tick * RT_TICK_PER_SECOND + os_tick_remain) / hz;
os_tick_remain += (pm_tick * RT_TICK_PER_SECOND);
os_tick_remain %= hz;
return ret;
}
/* pm_ops timer_get_tick() entry */
static rt_tick_t pm_timer_get_tick(struct rt_pm *pm)
{
rt_tick_t tick;
tick = TIMER_GetCounter(PM_TIMER);
return os_tick_from_pm_tick(tick);
}
/* pm timer_start() entry */
static void pm_timer_start(struct rt_pm *pm, rt_uint32_t timeout)
{
int tick;
if (timeout == RT_TICK_MAX)
return;
/* start pm timer to compensate the os tick in power down mode */
tick = pm_tick_from_os_tick(timeout);
TIMER_SET_CMP_VALUE(PM_TIMER, tick);
TIMER_Start(PM_TIMER);
}
/* pm timer_stop() entry */
static void pm_timer_stop(struct rt_pm *pm)
{
TIMER_Stop(PM_TIMER);
TIMER_ResetCounter(PM_TIMER);
}
/* pm device driver initialize. */
int rt_hw_pm_init(void)
{
rt_uint8_t timer_mask;
if (CLK_GetPMUWKSrc())
{
/* Release I/O hold status after wake-up from Standby Power-down Mode (SPD) */
CLK->IOPDCTL = 1;
/* Clear Power Manager Status register */
CLK->PMUSTS = CLK_PMUSTS_CLRWK_Msk;
}
hw_timer_init();
/* initialize timer mask */
timer_mask = (1UL << PM_SLEEP_MODE_LIGHT) |
(1UL << PM_SLEEP_MODE_DEEP);
/* initialize system pm module */
rt_system_pm_init(&ops, timer_mask, RT_NULL);
return RT_EOK;
}
INIT_BOARD_EXPORT(rt_hw_pm_init);
extern void rt_pm_exit_critical(rt_uint32_t ctx, rt_uint8_t sleep_mode);
void rt_pm_exit_critical(rt_uint32_t ctx, rt_uint8_t sleep_mode)
{
if ( (sleep_mode==PM_SLEEP_MODE_LIGHT) || (sleep_mode==PM_SLEEP_MODE_DEEP) )
{
if (TIMER_GetIntFlag(PM_TIMER))
{
TIMER_ClearIntFlag(PM_TIMER);
}
if (TIMER_GetWakeupFlag(PM_TIMER))
{
TIMER_ClearWakeupFlag(PM_TIMER);
}
NVIC_ClearPendingIRQ(PM_TIMER_IRQn);
}
rt_hw_interrupt_enable(ctx);
}
#endif /* BSP_USING_CLK */