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/*!
\file gd32vf103_rcu.c
\brief RCU driver
\version 2019-06-05, V1.0.0, firmware for GD32VF103
*/
/*
Copyright (c) 2019, GigaDevice Semiconductor Inc.
Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice, this
list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation
and/or other materials provided with the distribution.
3. Neither the name of the copyright holder nor the names of its contributors
may be used to endorse or promote products derived from this software without
specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
OF SUCH DAMAGE.
*/
#include "gd32vf103_rcu.h"
/* define clock source */
#define SEL_IRC8M ((uint16_t)0U)
#define SEL_HXTAL ((uint16_t)1U)
#define SEL_PLL ((uint16_t)2U)
/* define startup timeout count */
#define OSC_STARTUP_TIMEOUT ((uint32_t)0xFFFFFU)
#define LXTAL_STARTUP_TIMEOUT ((uint32_t)0x3FFFFFFU)
/*!
\brief deinitialize the RCU
\param[in] none
\param[out] none
\retval none
*/
void rcu_deinit(void)
{
/* enable IRC8M */
RCU_CTL |= RCU_CTL_IRC8MEN;
rcu_osci_stab_wait(RCU_IRC8M);
/* reset CFG0 register */
RCU_CFG0 &= ~(RCU_CFG0_SCS | RCU_CFG0_AHBPSC | RCU_CFG0_APB1PSC | RCU_CFG0_APB2PSC |
RCU_CFG0_ADCPSC | RCU_CFG0_PLLSEL | RCU_CFG0_PREDV0_LSB | RCU_CFG0_PLLMF |
RCU_CFG0_USBFSPSC | RCU_CFG0_CKOUT0SEL | RCU_CFG0_ADCPSC_2 | RCU_CFG0_PLLMF_4);
/* reset CTL register */
RCU_CTL &= ~(RCU_CTL_HXTALEN | RCU_CTL_CKMEN | RCU_CTL_PLLEN);
RCU_CTL &= ~RCU_CTL_HXTALBPS;
RCU_CTL &= ~(RCU_CTL_PLL1EN | RCU_CTL_PLL2EN);
/* reset INT and CFG1 register */
RCU_INT = 0x00ff0000U;
RCU_CFG1 &= ~(RCU_CFG1_PREDV0 | RCU_CFG1_PREDV1 | RCU_CFG1_PLL1MF | RCU_CFG1_PLL2MF |
RCU_CFG1_PREDV0SEL | RCU_CFG1_I2S1SEL | RCU_CFG1_I2S2SEL);
}
/*!
\brief enable the peripherals clock
\param[in] periph: RCU peripherals, refer to rcu_periph_enum
only one parameter can be selected which is shown as below:
\arg RCU_GPIOx (x=A,B,C,D,E): GPIO ports clock
\arg RCU_AF : alternate function clock
\arg RCU_CRC: CRC clock
\arg RCU_DMAx (x=0,1): DMA clock
\arg RCU_USBFS: USBFS clock
\arg RCU_EXMC: EXMC clock
\arg RCU_TIMERx (x=0,1,2,3,4,5,6): TIMER clock
\arg RCU_WWDGT: WWDGT clock
\arg RCU_SPIx (x=0,1,2): SPI clock
\arg RCU_USARTx (x=0,1,2): USART clock
\arg RCU_UARTx (x=3,4): UART clock
\arg RCU_I2Cx (x=0,1): I2C clock
\arg RCU_CANx (x=0,1): CAN clock
\arg RCU_PMU: PMU clock
\arg RCU_DAC: DAC clock
\arg RCU_RTC: RTC clock
\arg RCU_ADCx (x=0,1): ADC clock
\arg RCU_BKPI: BKP interface clock
\param[out] none
\retval none
*/
void rcu_periph_clock_enable(rcu_periph_enum periph)
{
RCU_REG_VAL(periph) |= BIT(RCU_BIT_POS(periph));
}
/*!
\brief disable the peripherals clock
\param[in] periph: RCU peripherals, refer to rcu_periph_enum
only one parameter can be selected which is shown as below:
\arg RCU_GPIOx (x=A,B,C,D,E): GPIO ports clock
\arg RCU_AF: alternate function clock
\arg RCU_CRC: CRC clock
\arg RCU_DMAx (x=0,1): DMA clock
\arg RCU_USBFS: USBFS clock
\arg RCU_EXMC: EXMC clock
\arg RCU_TIMERx (x=0,1,2,3,4,5,6): TIMER clock
\arg RCU_WWDGT: WWDGT clock
\arg RCU_SPIx (x=0,1,2): SPI clock
\arg RCU_USARTx (x=0,1,2): USART clock
\arg RCU_UARTx (x=3,4): UART clock
\arg RCU_I2Cx (x=0,1): I2C clock
\arg RCU_CANx (x=0,1): CAN clock
\arg RCU_PMU: PMU clock
\arg RCU_DAC: DAC clock
\arg RCU_RTC: RTC clock
\arg RCU_ADCx (x=0,1): ADC clock
\arg RCU_BKPI: BKP interface clock
\param[out] none
\retval none
*/
void rcu_periph_clock_disable(rcu_periph_enum periph)
{
RCU_REG_VAL(periph) &= ~BIT(RCU_BIT_POS(periph));
}
/*!
\brief enable the peripherals clock when sleep mode
\param[in] periph: RCU peripherals, refer to rcu_periph_sleep_enum
only one parameter can be selected which is shown as below:
\arg RCU_FMC_SLP: FMC clock
\arg RCU_SRAM_SLP: SRAM clock
\param[out] none
\retval none
*/
void rcu_periph_clock_sleep_enable(rcu_periph_sleep_enum periph)
{
RCU_REG_VAL(periph) |= BIT(RCU_BIT_POS(periph));
}
/*!
\brief disable the peripherals clock when sleep mode
\param[in] periph: RCU peripherals, refer to rcu_periph_sleep_enum
only one parameter can be selected which is shown as below:
\arg RCU_FMC_SLP: FMC clock
\arg RCU_SRAM_SLP: SRAM clock
\param[out] none
\retval none
*/
void rcu_periph_clock_sleep_disable(rcu_periph_sleep_enum periph)
{
RCU_REG_VAL(periph) &= ~BIT(RCU_BIT_POS(periph));
}
/*!
\brief reset the peripherals
\param[in] periph_reset: RCU peripherals reset, refer to rcu_periph_reset_enum
only one parameter can be selected which is shown as below:
\arg RCU_GPIOxRST (x=A,B,C,D,E): reset GPIO ports
\arg RCU_AFRST : reset alternate function clock
\arg RCU_USBFSRST: reset USBFS
\arg RCU_TIMERxRST (x=0,1,2,3,4,5,6): reset TIMER
\arg RCU_WWDGTRST: reset WWDGT
\arg RCU_SPIxRST (x=0,1,2): reset SPI
\arg RCU_USARTxRST (x=0,1,2): reset USART
\arg RCU_UARTxRST (x=3,4): reset UART
\arg RCU_I2CxRST (x=0,1): reset I2C
\arg RCU_CANxRST (x=0,1): reset CAN
\arg RCU_PMURST: reset PMU
\arg RCU_DACRST: reset DAC
\arg RCU_ADCxRST (x=0,1): reset ADC
\arg RCU_BKPIRST: reset BKPI
\param[out] none
\retval none
*/
void rcu_periph_reset_enable(rcu_periph_reset_enum periph_reset)
{
RCU_REG_VAL(periph_reset) |= BIT(RCU_BIT_POS(periph_reset));
}
/*!
\brief disable reset the peripheral
\param[in] periph_reset: RCU peripherals reset, refer to rcu_periph_reset_enum
only one parameter can be selected which is shown as below:
\arg RCU_GPIOxRST (x=A,B,C,D,E): reset GPIO ports
\arg RCU_AFRST : reset alternate function clock
\arg RCU_USBFSRST: reset USBFS
\arg RCU_TIMERxRST (x=0,1,2,3,4,5,6): reset TIMER
\arg RCU_WWDGTRST: reset WWDGT
\arg RCU_SPIxRST (x=0,1,2): reset SPI
\arg RCU_USARTxRST (x=0,1,2): reset USART
\arg RCU_UARTxRST (x=3,4): reset UART
\arg RCU_I2CxRST (x=0,1): reset I2C
\arg RCU_CANxRST (x=0,1): reset CAN
\arg RCU_PMURST: reset PMU
\arg RCU_DACRST: reset DAC
\arg RCU_ADCxRST (x=0,1): reset ADC
\arg RCU_BKPIRST: reset BKPI
\param[out] none
\retval none
*/
void rcu_periph_reset_disable(rcu_periph_reset_enum periph_reset)
{
RCU_REG_VAL(periph_reset) &= ~BIT(RCU_BIT_POS(periph_reset));
}
/*!
\brief reset the BKP domain
\param[in] none
\param[out] none
\retval none
*/
void rcu_bkp_reset_enable(void)
{
RCU_BDCTL |= RCU_BDCTL_BKPRST;
}
/*!
\brief disable the BKP domain reset
\param[in] none
\param[out] none
\retval none
*/
void rcu_bkp_reset_disable(void)
{
RCU_BDCTL &= ~RCU_BDCTL_BKPRST;
}
/*!
\brief configure the system clock source
\param[in] ck_sys: system clock source select
only one parameter can be selected which is shown as below:
\arg RCU_CKSYSSRC_IRC8M: select CK_IRC8M as the CK_SYS source
\arg RCU_CKSYSSRC_HXTAL: select CK_HXTAL as the CK_SYS source
\arg RCU_CKSYSSRC_PLL: select CK_PLL as the CK_SYS source
\param[out] none
\retval none
*/
void rcu_system_clock_source_config(uint32_t ck_sys)
{
uint32_t reg;
reg = RCU_CFG0;
/* reset the SCS bits and set according to ck_sys */
reg &= ~RCU_CFG0_SCS;
RCU_CFG0 = (reg | ck_sys);
}
/*!
\brief get the system clock source
\param[in] none
\param[out] none
\retval which clock is selected as CK_SYS source
\arg RCU_SCSS_IRC8M: CK_IRC8M is selected as the CK_SYS source
\arg RCU_SCSS_HXTAL: CK_HXTAL is selected as the CK_SYS source
\arg RCU_SCSS_PLL: CK_PLL is selected as the CK_SYS source
*/
uint32_t rcu_system_clock_source_get(void)
{
return (RCU_CFG0 & RCU_CFG0_SCSS);
}
/*!
\brief configure the AHB clock prescaler selection
\param[in] ck_ahb: AHB clock prescaler selection
only one parameter can be selected which is shown as below:
\arg RCU_AHB_CKSYS_DIVx, x=1, 2, 4, 8, 16, 64, 128, 256, 512
\param[out] none
\retval none
*/
void rcu_ahb_clock_config(uint32_t ck_ahb)
{
uint32_t reg;
reg = RCU_CFG0;
/* reset the AHBPSC bits and set according to ck_ahb */
reg &= ~RCU_CFG0_AHBPSC;
RCU_CFG0 = (reg | ck_ahb);
}
/*!
\brief configure the APB1 clock prescaler selection
\param[in] ck_apb1: APB1 clock prescaler selection
only one parameter can be selected which is shown as below:
\arg RCU_APB1_CKAHB_DIV1: select CK_AHB as CK_APB1
\arg RCU_APB1_CKAHB_DIV2: select CK_AHB/2 as CK_APB1
\arg RCU_APB1_CKAHB_DIV4: select CK_AHB/4 as CK_APB1
\arg RCU_APB1_CKAHB_DIV8: select CK_AHB/8 as CK_APB1
\arg RCU_APB1_CKAHB_DIV16: select CK_AHB/16 as CK_APB1
\param[out] none
\retval none
*/
void rcu_apb1_clock_config(uint32_t ck_apb1)
{
uint32_t reg;
reg = RCU_CFG0;
/* reset the APB1PSC and set according to ck_apb1 */
reg &= ~RCU_CFG0_APB1PSC;
RCU_CFG0 = (reg | ck_apb1);
}
/*!
\brief configure the APB2 clock prescaler selection
\param[in] ck_apb2: APB2 clock prescaler selection
only one parameter can be selected which is shown as below:
\arg RCU_APB2_CKAHB_DIV1: select CK_AHB as CK_APB2
\arg RCU_APB2_CKAHB_DIV2: select CK_AHB/2 as CK_APB2
\arg RCU_APB2_CKAHB_DIV4: select CK_AHB/4 as CK_APB2
\arg RCU_APB2_CKAHB_DIV8: select CK_AHB/8 as CK_APB2
\arg RCU_APB2_CKAHB_DIV16: select CK_AHB/16 as CK_APB2
\param[out] none
\retval none
*/
void rcu_apb2_clock_config(uint32_t ck_apb2)
{
uint32_t reg;
reg = RCU_CFG0;
/* reset the APB2PSC and set according to ck_apb2 */
reg &= ~RCU_CFG0_APB2PSC;
RCU_CFG0 = (reg | ck_apb2);
}
/*!
\brief configure the CK_OUT0 clock source
\param[in] ckout0_src: CK_OUT0 clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_CKOUT0SRC_NONE: no clock selected
\arg RCU_CKOUT0SRC_CKSYS: system clock selected
\arg RCU_CKOUT0SRC_IRC8M: high speed 8M internal oscillator clock selected
\arg RCU_CKOUT0SRC_HXTAL: HXTAL selected
\arg RCU_CKOUT0SRC_CKPLL_DIV2: CK_PLL/2 selected
\arg RCU_CKOUT0SRC_CKPLL1: CK_PLL1 selected
\arg RCU_CKOUT0SRC_CKPLL2_DIV2: CK_PLL2/2 selected
\arg RCU_CKOUT0SRC_EXT1: EXT1 selected
\arg RCU_CKOUT0SRC_CKPLL2: PLL2 selected
\param[out] none
\retval none
*/
void rcu_ckout0_config(uint32_t ckout0_src)
{
uint32_t reg;
reg = RCU_CFG0;
/* reset the CKOUT0SRC, set according to ckout0_src */
reg &= ~RCU_CFG0_CKOUT0SEL;
RCU_CFG0 = (reg | ckout0_src);
}
/*!
\brief configure the main PLL clock
\param[in] pll_src: PLL clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_PLLSRC_IRC8M_DIV2: IRC8M/2 clock selected as source clock of PLL
\arg RCU_PLLSRC_HXTAL: HXTAL selected as source clock of PLL
\param[in] pll_mul: PLL clock multiplication factor
only one parameter can be selected which is shown as below:
\arg RCU_PLL_MULx (x = 2..14, 6.5, 16..32)
\param[out] none
\retval none
*/
void rcu_pll_config(uint32_t pll_src, uint32_t pll_mul)
{
uint32_t reg = 0U;
reg = RCU_CFG0;
/* PLL clock source and multiplication factor configuration */
reg &= ~(RCU_CFG0_PLLSEL | RCU_CFG0_PLLMF | RCU_CFG0_PLLMF_4);
reg |= (pll_src | pll_mul);
RCU_CFG0 = reg;
}
/*!
\brief configure the PREDV0 division factor and clock source
\param[in] predv0_source: PREDV0 input clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_PREDV0SRC_HXTAL: HXTAL selected as PREDV0 input source clock
\arg RCU_PREDV0SRC_CKPLL1: CK_PLL1 selected as PREDV0 input source clock
\param[in] predv0_div: PREDV0 division factor
only one parameter can be selected which is shown as below:
\arg RCU_PREDV0_DIVx, x = 1..16
\param[out] none
\retval none
*/
void rcu_predv0_config(uint32_t predv0_source, uint32_t predv0_div)
{
uint32_t reg = 0U;
reg = RCU_CFG1;
/* reset PREDV0SEL and PREDV0 bits */
reg &= ~(RCU_CFG1_PREDV0SEL | RCU_CFG1_PREDV0);
/* set the PREDV0SEL and PREDV0 division factor */
reg |= (predv0_source | predv0_div);
RCU_CFG1 = reg;
}
/*!
\brief configure the PREDV1 division factor
\param[in] predv1_div: PREDV1 division factor
only one parameter can be selected which is shown as below:
\arg RCU_PREDV1_DIVx, x = 1..16
\param[out] none
\retval none
*/
void rcu_predv1_config(uint32_t predv1_div)
{
uint32_t reg = 0U;
reg = RCU_CFG1;
/* reset the PREDV1 bits */
reg &= ~RCU_CFG1_PREDV1;
/* set the PREDV1 division factor */
reg |= predv1_div;
RCU_CFG1 = reg;
}
/*!
\brief configure the PLL1 clock
\param[in] pll_mul: PLL clock multiplication factor
only one parameter can be selected which is shown as below:
\arg RCU_PLL1_MULx (x = 8..16, 20)
\param[out] none
\retval none
*/
void rcu_pll1_config(uint32_t pll_mul)
{
RCU_CFG1 &= ~RCU_CFG1_PLL1MF;
RCU_CFG1 |= pll_mul;
}
/*!
\brief configure the PLL2 clock
\param[in] pll_mul: PLL clock multiplication factor
only one parameter can be selected which is shown as below:
\arg RCU_PLL2_MULx (x = 8..16, 20)
\param[out] none
\retval none
*/
void rcu_pll2_config(uint32_t pll_mul)
{
RCU_CFG1 &= ~RCU_CFG1_PLL2MF;
RCU_CFG1 |= pll_mul;
}
/*!
\brief configure the ADC prescaler factor
\param[in] adc_psc: ADC prescaler factor
only one parameter can be selected which is shown as below:
\arg RCU_CKADC_CKAPB2_DIV2: ADC prescaler select CK_APB2/2
\arg RCU_CKADC_CKAPB2_DIV4: ADC prescaler select CK_APB2/4
\arg RCU_CKADC_CKAPB2_DIV6: ADC prescaler select CK_APB2/6
\arg RCU_CKADC_CKAPB2_DIV8: ADC prescaler select CK_APB2/8
\arg RCU_CKADC_CKAPB2_DIV12: ADC prescaler select CK_APB2/12
\arg RCU_CKADC_CKAPB2_DIV16: ADC prescaler select CK_APB2/16
\param[out] none
\retval none
*/
void rcu_adc_clock_config(uint32_t adc_psc)
{
uint32_t reg0;
/* reset the ADCPSC bits */
reg0 = RCU_CFG0;
reg0 &= ~(RCU_CFG0_ADCPSC_2 | RCU_CFG0_ADCPSC);
/* set the ADC prescaler factor */
switch(adc_psc){
case RCU_CKADC_CKAPB2_DIV2:
case RCU_CKADC_CKAPB2_DIV4:
case RCU_CKADC_CKAPB2_DIV6:
case RCU_CKADC_CKAPB2_DIV8:
reg0 |= (adc_psc << 14);
break;
case RCU_CKADC_CKAPB2_DIV12:
case RCU_CKADC_CKAPB2_DIV16:
adc_psc &= ~BIT(2);
reg0 |= (adc_psc << 14 | RCU_CFG0_ADCPSC_2);
break;
default:
break;
}
/* set the register */
RCU_CFG0 = reg0;
}
/*!
\brief configure the USBFS prescaler factor
\param[in] usb_psc: USB prescaler factor
only one parameter can be selected which is shown as below:
\arg RCU_CKUSB_CKPLL_DIV1_5: USBFS prescaler select CK_PLL/1.5
\arg RCU_CKUSB_CKPLL_DIV1: USBFS prescaler select CK_PLL/1
\arg RCU_CKUSB_CKPLL_DIV2_5: USBFS prescaler select CK_PLL/2.5
\arg RCU_CKUSB_CKPLL_DIV2: USBFS prescaler select CK_PLL/2
\param[out] none
\retval none
*/
void rcu_usb_clock_config(uint32_t usb_psc)
{
uint32_t reg;
reg = RCU_CFG0;
/* configure the USBFS prescaler factor */
reg &= ~RCU_CFG0_USBFSPSC;
RCU_CFG0 = (reg | usb_psc);
}
/*!
\brief configure the RTC clock source selection
\param[in] rtc_clock_source: RTC clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_RTCSRC_NONE: no clock selected
\arg RCU_RTCSRC_LXTAL: CK_LXTAL selected as RTC source clock
\arg RCU_RTCSRC_IRC40K: CK_IRC40K selected as RTC source clock
\arg RCU_RTCSRC_HXTAL_DIV_128: CK_HXTAL/128 selected as RTC source clock
\param[out] none
\retval none
*/
void rcu_rtc_clock_config(uint32_t rtc_clock_source)
{
uint32_t reg;
reg = RCU_BDCTL;
/* reset the RTCSRC bits and set according to rtc_clock_source */
reg &= ~RCU_BDCTL_RTCSRC;
RCU_BDCTL = (reg | rtc_clock_source);
}
/*!
\brief configure the I2S1 clock source selection
\param[in] i2s_clock_source: I2S1 clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_I2S1SRC_CKSYS: System clock selected as I2S1 source clock
\arg RCU_I2S1SRC_CKPLL2_MUL2: CK_PLL2x2 selected as I2S1 source clock
\param[out] none
\retval none
*/
void rcu_i2s1_clock_config(uint32_t i2s_clock_source)
{
uint32_t reg;
reg = RCU_CFG1;
/* reset the I2S1SEL bit and set according to i2s_clock_source */
reg &= ~RCU_CFG1_I2S1SEL;
RCU_CFG1 = (reg | i2s_clock_source);
}
/*!
\brief configure the I2S2 clock source selection
\param[in] i2s_clock_source: I2S2 clock source selection
only one parameter can be selected which is shown as below:
\arg RCU_I2S2SRC_CKSYS: system clock selected as I2S2 source clock
\arg RCU_I2S2SRC_CKPLL2_MUL2: CK_PLL2x2 selected as I2S2 source clock
\param[out] none
\retval none
*/
void rcu_i2s2_clock_config(uint32_t i2s_clock_source)
{
uint32_t reg;
reg = RCU_CFG1;
/* reset the I2S2SEL bit and set according to i2s_clock_source */
reg &= ~RCU_CFG1_I2S2SEL;
RCU_CFG1 = (reg | i2s_clock_source);
}
/*!
\brief get the clock stabilization and periphral reset flags
\param[in] flag: the clock stabilization and periphral reset flags, refer to rcu_flag_enum
only one parameter can be selected which is shown as below:
\arg RCU_FLAG_IRC8MSTB: IRC8M stabilization flag
\arg RCU_FLAG_HXTALSTB: HXTAL stabilization flag
\arg RCU_FLAG_PLLSTB: PLL stabilization flag
\arg RCU_FLAG_PLL1STB: PLL1 stabilization flag
\arg RCU_FLAG_PLL2STB: PLL2 stabilization flag
\arg RCU_FLAG_LXTALSTB: LXTAL stabilization flag
\arg RCU_FLAG_IRC40KSTB: IRC40K stabilization flag
\arg RCU_FLAG_EPRST: external PIN reset flag
\arg RCU_FLAG_PORRST: power reset flag
\arg RCU_FLAG_SWRST: software reset flag
\arg RCU_FLAG_FWDGTRST: free watchdog timer reset flag
\arg RCU_FLAG_WWDGTRST: window watchdog timer reset flag
\arg RCU_FLAG_LPRST: low-power reset flag
\param[out] none
\retval FlagStatus: SET or RESET
*/
FlagStatus rcu_flag_get(rcu_flag_enum flag)
{
/* get the rcu flag */
if(RESET != (RCU_REG_VAL(flag) & BIT(RCU_BIT_POS(flag)))){
return SET;
}else{
return RESET;
}
}
/*!
\brief clear all the reset flag
\param[in] none
\param[out] none
\retval none
*/
void rcu_all_reset_flag_clear(void)
{
RCU_RSTSCK |= RCU_RSTSCK_RSTFC;
}
/*!
\brief get the clock stabilization interrupt and ckm flags
\param[in] int_flag: interrupt and ckm flags, refer to rcu_int_flag_enum
only one parameter can be selected which is shown as below:
\arg RCU_INT_FLAG_IRC40KSTB: IRC40K stabilization interrupt flag
\arg RCU_INT_FLAG_LXTALSTB: LXTAL stabilization interrupt flag
\arg RCU_INT_FLAG_IRC8MSTB: IRC8M stabilization interrupt flag
\arg RCU_INT_FLAG_HXTALSTB: HXTAL stabilization interrupt flag
\arg RCU_INT_FLAG_PLLSTB: PLL stabilization interrupt flag
\arg RCU_INT_FLAG_PLL1STB: PLL1 stabilization interrupt flag
\arg RCU_INT_FLAG_PLL2STB: PLL2 stabilization interrupt flag
\arg RCU_INT_FLAG_CKM: HXTAL clock stuck interrupt flag
\param[out] none
\retval FlagStatus: SET or RESET
*/
FlagStatus rcu_interrupt_flag_get(rcu_int_flag_enum int_flag)
{
/* get the rcu interrupt flag */
if(RESET != (RCU_REG_VAL(int_flag) & BIT(RCU_BIT_POS(int_flag)))){
return SET;
}else{
return RESET;
}
}
/*!
\brief clear the interrupt flags
\param[in] int_flag_clear: clock stabilization and stuck interrupt flags clear, refer to rcu_int_flag_clear_enum
only one parameter can be selected which is shown as below:
\arg RCU_INT_FLAG_IRC40KSTB_CLR: IRC40K stabilization interrupt flag clear
\arg RCU_INT_FLAG_LXTALSTB_CLR: LXTAL stabilization interrupt flag clear
\arg RCU_INT_FLAG_IRC8MSTB_CLR: IRC8M stabilization interrupt flag clear
\arg RCU_INT_FLAG_HXTALSTB_CLR: HXTAL stabilization interrupt flag clear
\arg RCU_INT_FLAG_PLLSTB_CLR: PLL stabilization interrupt flag clear
\arg RCU_INT_FLAG_PLL1STB_CLR: PLL1 stabilization interrupt flag clear
\arg RCU_INT_FLAG_PLL2STB_CLR: PLL2 stabilization interrupt flag clear
\arg RCU_INT_FLAG_CKM_CLR: clock stuck interrupt flag clear
\param[out] none
\retval none
*/
void rcu_interrupt_flag_clear(rcu_int_flag_clear_enum int_flag_clear)
{
RCU_REG_VAL(int_flag_clear) |= BIT(RCU_BIT_POS(int_flag_clear));
}
/*!
\brief enable the stabilization interrupt
\param[in] stab_int: clock stabilization interrupt, refer to rcu_int_enum
Only one parameter can be selected which is shown as below:
\arg RCU_INT_IRC40KSTB: IRC40K stabilization interrupt enable
\arg RCU_INT_LXTALSTB: LXTAL stabilization interrupt enable
\arg RCU_INT_IRC8MSTB: IRC8M stabilization interrupt enable
\arg RCU_INT_HXTALSTB: HXTAL stabilization interrupt enable
\arg RCU_INT_PLLSTB: PLL stabilization interrupt enable
\arg RCU_INT_PLL1STB: PLL1 stabilization interrupt enable
\arg RCU_INT_PLL2STB: PLL2 stabilization interrupt enable
\param[out] none
\retval none
*/
void rcu_interrupt_enable(rcu_int_enum stab_int)
{
RCU_REG_VAL(stab_int) |= BIT(RCU_BIT_POS(stab_int));
}
/*!
\brief disable the stabilization interrupt
\param[in] stab_int: clock stabilization interrupt, refer to rcu_int_enum
only one parameter can be selected which is shown as below:
\arg RCU_INT_IRC40KSTB: IRC40K stabilization interrupt enable
\arg RCU_INT_LXTALSTB: LXTAL stabilization interrupt enable
\arg RCU_INT_IRC8MSTB: IRC8M stabilization interrupt enable
\arg RCU_INT_HXTALSTB: HXTAL stabilization interrupt enable
\arg RCU_INT_PLLSTB: PLL stabilization interrupt enable
\arg RCU_INT_PLL1STB: PLL1 stabilization interrupt enable
\arg RCU_INT_PLL2STB: PLL2 stabilization interrupt enable
\param[out] none
\retval none
*/
void rcu_interrupt_disable(rcu_int_enum stab_int)
{
RCU_REG_VAL(stab_int) &= ~BIT(RCU_BIT_POS(stab_int));
}
/*!
\brief wait for oscillator stabilization flags is SET or oscillator startup is timeout
\param[in] osci: oscillator types, refer to rcu_osci_type_enum
only one parameter can be selected which is shown as below:
\arg RCU_HXTAL: high speed crystal oscillator(HXTAL)
\arg RCU_LXTAL: low speed crystal oscillator(LXTAL)
\arg RCU_IRC8M: internal 8M RC oscillators(IRC8M)
\arg RCU_IRC40K: internal 40K RC oscillator(IRC40K)
\arg RCU_PLL_CK: phase locked loop(PLL)
\arg RCU_PLL1_CK: phase locked loop 1
\arg RCU_PLL2_CK: phase locked loop 2
\param[out] none
\retval ErrStatus: SUCCESS or ERROR
*/
ErrStatus rcu_osci_stab_wait(rcu_osci_type_enum osci)
{
uint32_t stb_cnt = 0U;
ErrStatus reval = ERROR;
FlagStatus osci_stat = RESET;
switch(osci){
/* wait HXTAL stable */
case RCU_HXTAL:
while((RESET == osci_stat) && (HXTAL_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_HXTALSTB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_HXTALSTB)){
reval = SUCCESS;
}
break;
/* wait LXTAL stable */
case RCU_LXTAL:
while((RESET == osci_stat) && (LXTAL_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_LXTALSTB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_LXTALSTB)){
reval = SUCCESS;
}
break;
/* wait IRC8M stable */
case RCU_IRC8M:
while((RESET == osci_stat) && (IRC8M_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_IRC8MSTB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_IRC8MSTB)){
reval = SUCCESS;
}
break;
/* wait IRC40K stable */
case RCU_IRC40K:
while((RESET == osci_stat) && (OSC_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_IRC40KSTB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_IRC40KSTB)){
reval = SUCCESS;
}
break;
/* wait PLL stable */
case RCU_PLL_CK:
while((RESET == osci_stat) && (OSC_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_PLLSTB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_PLLSTB)){
reval = SUCCESS;
}
break;
/* wait PLL1 stable */
case RCU_PLL1_CK:
while((RESET == osci_stat) && (OSC_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_PLL1STB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_PLL1STB)){
reval = SUCCESS;
}
break;
/* wait PLL2 stable */
case RCU_PLL2_CK:
while((RESET == osci_stat) && (OSC_STARTUP_TIMEOUT != stb_cnt)){
osci_stat = rcu_flag_get(RCU_FLAG_PLL2STB);
stb_cnt++;
}
/* check whether flag is set or not */
if(RESET != rcu_flag_get(RCU_FLAG_PLL2STB)){
reval = SUCCESS;
}
break;
default:
break;
}
/* return value */
return reval;
}
/*!
\brief turn on the oscillator
\param[in] osci: oscillator types, refer to rcu_osci_type_enum
only one parameter can be selected which is shown as below:
\arg RCU_HXTAL: high speed crystal oscillator(HXTAL)
\arg RCU_LXTAL: low speed crystal oscillator(LXTAL)
\arg RCU_IRC8M: internal 8M RC oscillators(IRC8M)
\arg RCU_IRC40K: internal 40K RC oscillator(IRC40K)
\arg RCU_PLL_CK: phase locked loop(PLL)
\arg RCU_PLL1_CK: phase locked loop 1
\arg RCU_PLL2_CK: phase locked loop 2
\param[out] none
\retval none
*/
void rcu_osci_on(rcu_osci_type_enum osci)
{
RCU_REG_VAL(osci) |= BIT(RCU_BIT_POS(osci));
}
/*!
\brief turn off the oscillator
\param[in] osci: oscillator types, refer to rcu_osci_type_enum
only one parameter can be selected which is shown as below:
\arg RCU_HXTAL: high speed crystal oscillator(HXTAL)
\arg RCU_LXTAL: low speed crystal oscillator(LXTAL)
\arg RCU_IRC8M: internal 8M RC oscillators(IRC8M)
\arg RCU_IRC40K: internal 40K RC oscillator(IRC40K)
\arg RCU_PLL_CK: phase locked loop(PLL)
\arg RCU_PLL1_CK: phase locked loop 1
\arg RCU_PLL2_CK: phase locked loop 2
\param[out] none
\retval none
*/
void rcu_osci_off(rcu_osci_type_enum osci)
{
RCU_REG_VAL(osci) &= ~BIT(RCU_BIT_POS(osci));
}
/*!
\brief enable the oscillator bypass mode, HXTALEN or LXTALEN must be reset before it
\param[in] osci: oscillator types, refer to rcu_osci_type_enum
only one parameter can be selected which is shown as below:
\arg RCU_HXTAL: high speed crystal oscillator(HXTAL)
\arg RCU_LXTAL: low speed crystal oscillator(LXTAL)
\param[out] none
\retval none
*/
void rcu_osci_bypass_mode_enable(rcu_osci_type_enum osci)
{
uint32_t reg;
switch(osci){
/* enable HXTAL to bypass mode */
case RCU_HXTAL:
reg = RCU_CTL;
RCU_CTL &= ~RCU_CTL_HXTALEN;
RCU_CTL = (reg | RCU_CTL_HXTALBPS);
break;
/* enable LXTAL to bypass mode */
case RCU_LXTAL:
reg = RCU_BDCTL;
RCU_BDCTL &= ~RCU_BDCTL_LXTALEN;
RCU_BDCTL = (reg | RCU_BDCTL_LXTALBPS);
break;
case RCU_IRC8M:
case RCU_IRC40K:
case RCU_PLL_CK:
case RCU_PLL1_CK:
case RCU_PLL2_CK:
break;
default:
break;
}
}
/*!
\brief disable the oscillator bypass mode, HXTALEN or LXTALEN must be reset before it
\param[in] osci: oscillator types, refer to rcu_osci_type_enum
only one parameter can be selected which is shown as below:
\arg RCU_HXTAL: high speed crystal oscillator(HXTAL)
\arg RCU_LXTAL: low speed crystal oscillator(LXTAL)
\param[out] none
\retval none
*/
void rcu_osci_bypass_mode_disable(rcu_osci_type_enum osci)
{
uint32_t reg;
switch(osci){
/* disable HXTAL to bypass mode */
case RCU_HXTAL:
reg = RCU_CTL;
RCU_CTL &= ~RCU_CTL_HXTALEN;
RCU_CTL = (reg & ~RCU_CTL_HXTALBPS);
break;
/* disable LXTAL to bypass mode */
case RCU_LXTAL:
reg = RCU_BDCTL;
RCU_BDCTL &= ~RCU_BDCTL_LXTALEN;
RCU_BDCTL = (reg & ~RCU_BDCTL_LXTALBPS);
break;
case RCU_IRC8M:
case RCU_IRC40K:
case RCU_PLL_CK:
case RCU_PLL1_CK:
case RCU_PLL2_CK:
break;
default:
break;
}
}
/*!
\brief enable the HXTAL clock monitor
\param[in] none
\param[out] none
\retval none
*/
void rcu_hxtal_clock_monitor_enable(void)
{
RCU_CTL |= RCU_CTL_CKMEN;
}
/*!
\brief disable the HXTAL clock monitor
\param[in] none
\param[out] none
\retval none
*/
void rcu_hxtal_clock_monitor_disable(void)
{
RCU_CTL &= ~RCU_CTL_CKMEN;
}
/*!
\brief set the IRC8M adjust value
\param[in] irc8m_adjval: IRC8M adjust value, must be between 0 and 0x1F
\param[out] none
\retval none
*/
void rcu_irc8m_adjust_value_set(uint32_t irc8m_adjval)
{
uint32_t reg;
reg = RCU_CTL;
/* reset the IRC8MADJ bits and set according to irc8m_adjval */
reg &= ~RCU_CTL_IRC8MADJ;
RCU_CTL = (reg | ((irc8m_adjval & 0x1FU) << 3));
}
/*!
\brief deep-sleep mode voltage select
\param[in] dsvol: deep sleep mode voltage
only one parameter can be selected which is shown as below:
\arg RCU_DEEPSLEEP_V_1_2: the core voltage is 1.2V
\arg RCU_DEEPSLEEP_V_1_1: the core voltage is 1.1V
\arg RCU_DEEPSLEEP_V_1_0: the core voltage is 1.0V
\arg RCU_DEEPSLEEP_V_0_9: the core voltage is 0.9V
\param[out] none
\retval none
*/
void rcu_deepsleep_voltage_set(uint32_t dsvol)
{
dsvol &= RCU_DSV_DSLPVS;
RCU_DSV = dsvol;
}
/*!
\brief get the system clock, bus and peripheral clock frequency
\param[in] clock: the clock frequency which to get
only one parameter can be selected which is shown as below:
\arg CK_SYS: system clock frequency
\arg CK_AHB: AHB clock frequency
\arg CK_APB1: APB1 clock frequency
\arg CK_APB2: APB2 clock frequency
\param[out] none
\retval clock frequency of system, AHB, APB1, APB2
*/
uint32_t rcu_clock_freq_get(rcu_clock_freq_enum clock)
{
uint32_t sws, ck_freq = 0U;
uint32_t cksys_freq, ahb_freq, apb1_freq, apb2_freq;
uint32_t pllsel, predv0sel, pllmf,ck_src, idx, clk_exp;
uint32_t predv0, predv1, pll1mf;
/* exponent of AHB, APB1 and APB2 clock divider */
uint8_t ahb_exp[16] = {0, 0, 0, 0, 0, 0, 0, 0, 1, 2, 3, 4, 6, 7, 8, 9};
uint8_t apb1_exp[8] = {0, 0, 0, 0, 1, 2, 3, 4};
uint8_t apb2_exp[8] = {0, 0, 0, 0, 1, 2, 3, 4};
sws = GET_BITS(RCU_CFG0, 2, 3);
switch(sws){
/* IRC8M is selected as CK_SYS */
case SEL_IRC8M:
cksys_freq = IRC8M_VALUE;
break;
/* HXTAL is selected as CK_SYS */
case SEL_HXTAL:
cksys_freq = HXTAL_VALUE;
break;
/* PLL is selected as CK_SYS */
case SEL_PLL:
/* PLL clock source selection, HXTAL or IRC8M/2 */
pllsel = (RCU_CFG0 & RCU_CFG0_PLLSEL);
if(RCU_PLLSRC_HXTAL == pllsel) {
/* PLL clock source is HXTAL */
ck_src = HXTAL_VALUE;
predv0sel = (RCU_CFG1 & RCU_CFG1_PREDV0SEL);
/* source clock use PLL1 */
if(RCU_PREDV0SRC_CKPLL1 == predv0sel){
predv1 = (uint32_t)((RCU_CFG1 & RCU_CFG1_PREDV1) >> 4) + 1U;
pll1mf = (uint32_t)((RCU_CFG1 & RCU_CFG1_PLL1MF) >> 8) + 2U;
if(17U == pll1mf){
pll1mf = 20U;
}
ck_src = (ck_src / predv1) * pll1mf;
}
predv0 = (RCU_CFG1 & RCU_CFG1_PREDV0) + 1U;
ck_src /= predv0;
}else{
/* PLL clock source is IRC8M/2 */
ck_src = IRC8M_VALUE/2U;
}
/* PLL multiplication factor */
pllmf = GET_BITS(RCU_CFG0, 18, 21);
if((RCU_CFG0 & RCU_CFG0_PLLMF_4)){
pllmf |= 0x10U;
}
if(pllmf < 15U){
pllmf += 2U;
}else{
pllmf += 1U;
}
cksys_freq = ck_src * pllmf;
if(15U == pllmf){
/* PLL source clock multiply by 6.5 */
cksys_freq = ck_src * 6U + ck_src / 2U;
}
break;
/* IRC8M is selected as CK_SYS */
default:
cksys_freq = IRC8M_VALUE;
break;
}
/* calculate AHB clock frequency */
idx = GET_BITS(RCU_CFG0, 4, 7);
clk_exp = ahb_exp[idx];
ahb_freq = cksys_freq >> clk_exp;
/* calculate APB1 clock frequency */
idx = GET_BITS(RCU_CFG0, 8, 10);
clk_exp = apb1_exp[idx];
apb1_freq = ahb_freq >> clk_exp;
/* calculate APB2 clock frequency */
idx = GET_BITS(RCU_CFG0, 11, 13);
clk_exp = apb2_exp[idx];
apb2_freq = ahb_freq >> clk_exp;
/* return the clocks frequency */
switch(clock){
case CK_SYS:
ck_freq = cksys_freq;
break;
case CK_AHB:
ck_freq = ahb_freq;
break;
case CK_APB1:
ck_freq = apb1_freq;
break;
case CK_APB2:
ck_freq = apb2_freq;
break;
default:
break;
}
return ck_freq;
}