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/**
******************************************************************************
* @file stm32l5xx_hal_rcc.c
* @author MCD Application Team
* @brief RCC HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Reset and Clock Control (RCC) peripheral:
* + Initialization and de-initialization functions
* + Peripheral Control functions
*
@verbatim
==============================================================================
##### RCC specific features #####
==============================================================================
[..]
After reset the device is running from Multiple Speed Internal oscillator
(4 MHz) with Flash 0 wait state. I-Cache is disabled, and all peripherals
are off except internal SRAMs, Flash and JTAG.
(+) There is no prescaler on High speed (AHBs) and Low speed (APBs) busses:
all peripherals mapped on these busses are running at MSI speed.
(+) The clock for all peripherals is switched off, except the SRAM and FLASH.
(+) All GPIOs are in analog mode, except the JTAG pins which
are assigned to be used for debug purpose.
[..]
Once the device is started from reset, the user application has to:
(+) Configure the clock source to be used to drive the System clock
(if the application needs higher frequency/performance)
(+) Configure the System clock frequency and Flash settings
(+) Configure the AHB and APB busses prescalers
(+) Enable the clock for the peripheral(s) to be used
(+) Configure the clock source(s) for peripherals which clocks are not
derived from the System clock (SAIx, RTC, ADC, USB FS/SDMMC1/RNG, FDCAN)
@endverbatim
******************************************************************************
* @attention
*
* <h2><center>&copy; Copyright (c) 2019 STMicroelectronics.
* All rights reserved.</center></h2>
*
* This software component is licensed by ST under BSD 3-Clause license,
* the "License"; You may not use this file except in compliance with the
* License. You may obtain a copy of the License at:
* opensource.org/licenses/BSD-3-Clause
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32l5xx_hal.h"
/** @addtogroup STM32L5xx_HAL_Driver
* @{
*/
/** @defgroup RCC RCC
* @brief RCC HAL module driver
* @{
*/
#ifdef HAL_RCC_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup RCC_Private_Constants RCC Private Constants
* @{
*/
#define LSI_TIMEOUT_VALUE ((uint32_t)7U) /* 7 ms (maximum 6ms + 1) */
#define HSI48_TIMEOUT_VALUE ((uint32_t)2U) /* 2 ms (minimum Tick + 1) */
#define PLL_TIMEOUT_VALUE ((uint32_t)2U) /* 2 ms (minimum Tick + 1) */
#define CLOCKSWITCH_TIMEOUT_VALUE ((uint32_t)5000U) /* 5 s */
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup RCC_Private_Macros RCC Private Macros
* @{
*/
#define __MCO1_CLK_ENABLE() __HAL_RCC_GPIOA_CLK_ENABLE()
#define MCO1_GPIO_PORT GPIOA
#define MCO1_PIN GPIO_PIN_8
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup RCC_Private_Functions RCC Private Functions
* @{
*/
static HAL_StatusTypeDef RCC_SetFlashLatencyFromMSIRange(uint32_t msirange);
static uint32_t RCC_GetSysClockFreqFromPLLSource(void);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup RCC_Exported_Functions RCC Exported Functions
* @{
*/
/** @defgroup RCC_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and Configuration functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
This section provides functions allowing to configure the internal and external oscillators
(HSE, HSI, LSE, MSI, LSI, PLL, CSS and MCO) and the System busses clocks (SYSCLK, AHB, APB1
and APB2).
[..] Internal/external clock and PLL configuration
(+) HSI (high-speed internal): 16 MHz factory-trimmed RC used directly or through
the PLL as System clock source.
(+) MSI (Mutiple Speed Internal): Its frequency is software trimmable from 100KHz to 48MHz.
It can be used to generate the clock for the USB FS (48 MHz).
The number of flash wait states is automatically adjusted when MSI range is updated with
HAL_RCC_OscConfig() and the MSI is used as System clock source.
(+) LSI (low-speed internal): 32 KHz low consumption RC used as IWDG and/or RTC
clock source.
(+) HSE (high-speed external): 4 to 48 MHz crystal oscillator used directly or
through the PLL as System clock source. Can be used also optionally as RTC clock source.
(+) LSE (low-speed external): 32.768 KHz oscillator used optionally as RTC clock source.
(+) PLL (clocked by HSI, HSE or MSI) providing up to three independent output clocks:
(++) The first output is used to generate the high speed system clock (up to 110 MHz).
(++) The second output is used to generate the clock for the USB FS (48 MHz),
the random analog generator (<=48 MHz) and the SDMMC1 (<= 48 MHz).
(++) The third output is used to generate an accurate clock to achieve
high-quality audio performance on SAI interface.
(+) PLLSAI1 (clocked by HSI, HSE or MSI) providing up to three independent output clocks:
(++) The first output is used to generate the ADCs clock.
(++) The second output is used to generate the clock for the USB FS (48 MHz),
the random analog generator (<=48 MHz) and the SDMMC1 (<= 48 MHz).
(++) The third output is used to generate an accurate clock to achieve
high-quality audio performance on SAI interface.
(+) PLLSAI2 (clocked by HSI, HSE or MSI) providing an independent output clock:
(++) The output is used to generate an accurate clock to achieve
high-quality audio performance on SAI interface.
(+) CSS (Clock security system): once enabled, if a HSE clock failure occurs
(HSE used directly or through PLL as System clock source), the System clock
is automatically switched to HSI and an interrupt is generated.
The interrupt is linked to the Cortex-M33 NMI (non-maskable interrupt)
exception vector.
(+) CSS on LSE (Clock security system on LSE): once enabled for RTC, if a LSE clock
failure occurs it is not supplied anymore to the RTC. If the MSI was used in
PLL-mode, this mode is disabled. The CSS on LSE failure is detected by a tamper event.
(+) MCO (microcontroller clock output): used to output LSI, LSE, System clock, HSI, HSI48,
HSE, main PLL clock or MSI (through a configurable prescaler) on PA8 pin.
[..] System, AHB and APB busses clocks configuration
(+) Several clock sources can be used to drive the System clock (SYSCLK): MSI, HSI,
HSE and main PLL.
The AHB clock (HCLK) is derived from System clock through configurable
prescaler and used to clock the CPU, memory and peripherals mapped
on AHB bus (DMA, GPIO...). APB1 (PCLK1) and APB2 (PCLK2) clocks are derived
from AHB clock through configurable prescalers and used to clock
the peripherals mapped on these busses. You can use
"HAL_RCC_GetSysClockFreq()" function to retrieve the frequencies of these clocks.
-@- All the peripheral clocks are derived from the System clock (SYSCLK) except:
(+@) SAI: the SAI clock can be derived either from a specific PLL (PLLSAI1) or (PLLSAI2) or
from an external clock mapped on the SAI_CKIN pin.
You have to use HAL_RCCEx_PeriphCLKConfig() function to configure this clock.
(+@) RTC: the RTC clock can be derived either from the LSI, LSE or HSE clock
divided by 2 to 31.
You have to use __HAL_RCC_RTC_ENABLE() and HAL_RCCEx_PeriphCLKConfig() function
to configure this clock.
(+@) USB FS, SDMMC1 and RNG: USB FS requires a frequency equal to 48 MHz
to work correctly, while the SDMMC1 and RNG peripherals require a frequency
equal or lower than to 48 MHz. This clock is derived of the main PLL or PLLSAI1
through PLLQ divider. You have to enable the peripheral clock and use
HAL_RCCEx_PeriphCLKConfig() function to configure this clock.
(+@) IWDG clock which is always the LSI clock.
(+) The maximum frequency of the SYSCLK, HCLK, PCLK1 and PCLK2 is 110 MHz.
The clock source frequency should be adapted depending on the device voltage range
as listed in the Reference Manual "Clock source frequency versus voltage scaling" chapter.
@endverbatim
@internal
Depending on the device voltage range, the maximum frequency should be
adapted accordingly:
(++) Table 1. HCLK clock frequency for STM32L5 devices
(++) +---------------------------------------------------------------------------+
(++) | Latency | HCLK clock frequency (MHz) |
(++) | |---------------------------------------------------------|
(++) | | voltage range 0 | voltage range 1 | voltage range 2 |
(++) |-----------------|-------------------|------------------|------------------|
(++) |0WS(1 CPU cycles)| 0 < HCLK <= 20 | 0 < HCLK <= 8 | 0 < HCLK <= 8 |
(++) |-----------------|-------------------|------------------|------------------|
(++) |1WS(2 CPU cycles)| 20 < HCLK <= 40 | 20 < HCLK <= 40 | 8 < HCLK <= 16 |
(++) |-----------------|-------------------|------------------|------------------|
(++) |2WS(3 CPU cycles)| 40 < HCLK <= 60 | 40 < HCLK <= 60 | 16 < HCLK <= 26 |
(++) |-----------------|-------------------|------------------|------------------|
(++) |3WS(4 CPU cycles)| 60 < HCLK <= 80 | 60 < HCLK <= 80 | |
(++) |-----------------|-------------------|------------------|------------------|
(++) |4WS(5 CPU cycles)| 80 < HCLK <= 100 | | |
(++) |-----------------|-------------------|------------------|------------------|
(++) |5WS(6 CPU cycles)| 100 < HCLK <= 110 | | |
(++) +---------------------------------------------------------------------------+
@endinternal
* @{
*/
/**
* @brief Reset the RCC clock configuration to the default reset state.
* @note The default reset state of the clock configuration is given below:
* - MSI ON and used as system clock source
* - HSE, HSI, HSI48, LSI, LSE, PLL, PLLSAI1 and PLLISAI2 OFF
* - AHB, APB1 and APB2 prescaler set to 1.
* - CSS, MCO1 OFF
* - All interrupts disabled
* - All interrupt and reset flags cleared
* @note This function doesn't modify the configuration of the
* - Peripheral clocks source selection
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCC_DeInit(void)
{
uint32_t tickstart;
FlagStatus pwrclkchanged = RESET;
/* Set MSION bit */
SET_BIT(RCC->CR, RCC_CR_MSION);
/* Insure MSIRDY bit is set before writing default MSIRANGE value */
/* Get start tick */
tickstart = HAL_GetTick();
/* Wait till MSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_MSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > MSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Set MSIRANGE default value */
MODIFY_REG(RCC->CR, RCC_CR_MSIRANGE, RCC_MSIRANGE_6);
/* Reset CFGR register (MSI is selected as system clock source) */
CLEAR_REG(RCC->CFGR);
/* Insure MSI selected as system clock source */
/* Get start tick */
tickstart = HAL_GetTick();
/* Update the SystemCoreClock global variable for MSI as system clock source */
SystemCoreClock = MSI_VALUE;
/* Configure the source of time base considering new system clock settings */
if (HAL_InitTick(TICK_INT_PRIORITY) != HAL_OK)
{
return HAL_ERROR;
}
/* Wait till system clock source is ready */
while (READ_BIT(RCC->CFGR, RCC_CFGR_SWS) != RCC_CFGR_SWS_MSI)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Reset HSION, HSIKERON, HSIASFS, HSEON, HSECSSON, PLLON, PLLSAIxON bits */
CLEAR_BIT(RCC->CR, RCC_CR_CSSON | RCC_CR_HSEON | RCC_CR_HSION | RCC_CR_HSIKERON | RCC_CR_HSIASFS | RCC_CR_PLLON | RCC_CR_PLLSAI1ON | RCC_CR_PLLSAI2ON);
/* Insure PLLRDY, PLLSAI1RDY and PLLSAI2RDY (if present) are reset */
/* Get start tick */
tickstart = HAL_GetTick();
#if defined(RCC_PLLSAI2_SUPPORT)
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY | RCC_CR_PLLSAI1RDY | RCC_CR_PLLSAI2RDY) != 0U)
#else
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY | RCC_CR_PLLSAI1RDY) != 0U)
#endif
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Reset PLLCFGR register */
CLEAR_REG(RCC->PLLCFGR);
SET_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN_4);
/* Reset PLLSAI1CFGR register */
CLEAR_REG(RCC->PLLSAI1CFGR);
SET_BIT(RCC->PLLSAI1CFGR, RCC_PLLSAI1CFGR_PLLSAI1N_4);
/* Reset PLLSAI2CFGR register */
CLEAR_REG(RCC->PLLSAI2CFGR);
SET_BIT(RCC->PLLSAI2CFGR, RCC_PLLSAI2CFGR_PLLSAI2N_4);
/* Reset LSION bit */
CLEAR_BIT(RCC->CSR, RCC_CSR_LSION);
/* Insure LSIRDY bit is reset before LSIPRE bit reset */
/* Get start tick */
tickstart = HAL_GetTick();
/* Wait till LSI is disabled */
while (READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > LSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Reset LSIPRE bit */
CLEAR_BIT(RCC->CSR, RCC_CSR_LSIPRE);
/* Reset HSI48ON bit */
CLEAR_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON);
/* Reset HSEBYP bit */
CLEAR_BIT(RCC->CR, RCC_CR_HSEBYP);
/* Disable all interrupts */
CLEAR_REG(RCC->CIER);
/* Clear all interrupt flags */
WRITE_REG(RCC->CICR, 0xFFFFFFFFU);
/* Clear all reset flags */
SET_BIT(RCC->CSR, RCC_CSR_RMVF);
/* Reset LSEON/LSESYSON/LSEBYP in Backup domain register */
/* Requires to enable write access to Backup Domain if necessary */
if (HAL_IS_BIT_CLR(RCC->APB1ENR1, RCC_APB1ENR1_PWREN))
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if (HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
/* Enable write access to Backup domain */
SET_BIT(PWR->CR1, PWR_CR1_DBP);
}
/* Reset LSEON/LSEBYP/LSESYSEN bit */
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEON);
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEBYP | RCC_BDCR_LSESYSEN);
/* Restore clock configuration if changed */
if (pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
return HAL_OK;
}
/**
* @brief Initialize the RCC Oscillators according to the specified parameters in the
* RCC_OscInitTypeDef.
* @param RCC_OscInitStruct pointer to an RCC_OscInitTypeDef structure that
* contains the configuration information for the RCC Oscillators.
* @note The PLL is not disabled when used as system clock.
* @note Transitions LSE Bypass to LSE On and LSE On to LSE Bypass are not
* supported by this macro. User should request a transition to LSE Off
* first and then LSE On or LSE Bypass.
* @note Transition HSE Bypass to HSE On and HSE On to HSE Bypass are not
* supported by this macro. User should request a transition to HSE Off
* first and then HSE On or HSE Bypass.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCC_OscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct)
{
uint32_t tickstart;
uint32_t sysclk_source, pll_config;
HAL_StatusTypeDef status;
/* Check the parameters */
if (RCC_OscInitStruct == NULL)
{
return HAL_ERROR;
}
assert_param(IS_RCC_OSCILLATORTYPE(RCC_OscInitStruct->OscillatorType));
sysclk_source = __HAL_RCC_GET_SYSCLK_SOURCE();
pll_config = __HAL_RCC_GET_PLL_OSCSOURCE();
/*----------------------------- MSI Configuration --------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_MSI) == RCC_OSCILLATORTYPE_MSI)
{
/* Check the parameters */
assert_param(IS_RCC_MSI(RCC_OscInitStruct->MSIState));
assert_param(IS_RCC_MSICALIBRATION_VALUE(RCC_OscInitStruct->MSICalibrationValue));
assert_param(IS_RCC_MSI_CLOCK_RANGE(RCC_OscInitStruct->MSIClockRange));
/* Check if MSI is used as system clock or as PLL source when PLL is selected as system clock */
if ((sysclk_source == RCC_CFGR_SWS_MSI) ||
((sysclk_source == RCC_CFGR_SWS_PLL) && (pll_config == RCC_PLLSOURCE_MSI)))
{
if ((READ_BIT(RCC->CR, RCC_CR_MSIRDY) != 0U) && (RCC_OscInitStruct->MSIState == RCC_MSI_OFF))
{
return HAL_ERROR;
}
/* Otherwise, just the calibration and MSI range change are allowed */
else
{
/* To correctly read data from FLASH memory, the number of wait states (LATENCY)
must be correctly programmed according to the frequency of the CPU clock
(HCLK) and the supply voltage of the device. */
if (RCC_OscInitStruct->MSIClockRange > __HAL_RCC_GET_MSI_RANGE())
{
/* First increase number of wait states update if necessary */
if (RCC_SetFlashLatencyFromMSIRange(RCC_OscInitStruct->MSIClockRange) != HAL_OK)
{
return HAL_ERROR;
}
/* Selects the Multiple Speed oscillator (MSI) clock range .*/
__HAL_RCC_MSI_RANGE_CONFIG(RCC_OscInitStruct->MSIClockRange);
/* Adjusts the Multiple Speed oscillator (MSI) calibration value.*/
__HAL_RCC_MSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->MSICalibrationValue);
}
else
{
/* Else, keep current flash latency while decreasing applies */
/* Selects the Multiple Speed oscillator (MSI) clock range .*/
__HAL_RCC_MSI_RANGE_CONFIG(RCC_OscInitStruct->MSIClockRange);
/* Adjusts the Multiple Speed oscillator (MSI) calibration value.*/
__HAL_RCC_MSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->MSICalibrationValue);
/* Decrease number of wait states update if necessary */
/* Only possible when MSI is the System clock source */
if (sysclk_source == RCC_CFGR_SWS_MSI)
{
if (RCC_SetFlashLatencyFromMSIRange(RCC_OscInitStruct->MSIClockRange) != HAL_OK)
{
return HAL_ERROR;
}
}
}
/* Update the SystemCoreClock global variable */
SystemCoreClock = HAL_RCC_GetSysClockFreq() >> AHBPrescTable[(RCC->CFGR & RCC_CFGR_HPRE) >> RCC_CFGR_HPRE_Pos];
/* Configure the source of time base considering new system clocks settings*/
status = HAL_InitTick(TICK_INT_PRIORITY);
if (status != HAL_OK)
{
return status;
}
}
}
else
{
/* Check the MSI State */
if (RCC_OscInitStruct->MSIState != RCC_MSI_OFF)
{
/* Enable the Internal High Speed oscillator (MSI). */
__HAL_RCC_MSI_ENABLE();
/* Get timeout */
tickstart = HAL_GetTick();
/* Wait till MSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_MSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > MSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Selects the Multiple Speed oscillator (MSI) clock range .*/
__HAL_RCC_MSI_RANGE_CONFIG(RCC_OscInitStruct->MSIClockRange);
/* Adjusts the Multiple Speed oscillator (MSI) calibration value.*/
__HAL_RCC_MSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->MSICalibrationValue);
}
else
{
/* Disable the Internal High Speed oscillator (MSI). */
__HAL_RCC_MSI_DISABLE();
/* Get timeout */
tickstart = HAL_GetTick();
/* Wait till MSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_MSIRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > MSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*------------------------------- HSE Configuration ------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSE) == RCC_OSCILLATORTYPE_HSE)
{
/* Check the parameters */
assert_param(IS_RCC_HSE(RCC_OscInitStruct->HSEState));
/* When the HSE is used as system clock or clock source for PLL in these cases it is not allowed to be disabled */
if ((sysclk_source == RCC_CFGR_SWS_HSE) ||
((sysclk_source == RCC_CFGR_SWS_PLL) && (pll_config == RCC_PLLSOURCE_HSE)))
{
if ((READ_BIT(RCC->CR, RCC_CR_HSERDY) != 0U) && (RCC_OscInitStruct->HSEState == RCC_HSE_OFF))
{
return HAL_ERROR;
}
}
else
{
/* Set the new HSE configuration ---------------------------------------*/
__HAL_RCC_HSE_CONFIG(RCC_OscInitStruct->HSEState);
/* Check the HSE State */
if (RCC_OscInitStruct->HSEState != RCC_HSE_OFF)
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSE is ready */
while (READ_BIT(RCC->CR, RCC_CR_HSERDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSE is disabled */
while (READ_BIT(RCC->CR, RCC_CR_HSERDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > HSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*----------------------------- HSI Configuration --------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSI) == RCC_OSCILLATORTYPE_HSI)
{
/* Check the parameters */
assert_param(IS_RCC_HSI(RCC_OscInitStruct->HSIState));
assert_param(IS_RCC_HSI_CALIBRATION_VALUE(RCC_OscInitStruct->HSICalibrationValue));
/* Check if HSI is used as system clock or as PLL source when PLL is selected as system clock */
if ((sysclk_source == RCC_CFGR_SWS_HSI) ||
((sysclk_source == RCC_CFGR_SWS_PLL) && (pll_config == RCC_PLLSOURCE_HSI)))
{
/* When HSI is used as system clock it will not be disabled */
if ((READ_BIT(RCC->CR, RCC_CR_HSIRDY) != 0U) && (RCC_OscInitStruct->HSIState == RCC_HSI_OFF))
{
return HAL_ERROR;
}
/* Otherwise, just the calibration is allowed */
else
{
/* Adjusts the Internal High Speed oscillator (HSI) calibration value.*/
__HAL_RCC_HSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->HSICalibrationValue);
}
}
else
{
/* Check the HSI State */
if (RCC_OscInitStruct->HSIState != RCC_HSI_OFF)
{
/* Enable the Internal High Speed oscillator (HSI). */
__HAL_RCC_HSI_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_HSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Adjusts the Internal High Speed oscillator (HSI) calibration value.*/
__HAL_RCC_HSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->HSICalibrationValue);
}
else
{
/* Disable the Internal High Speed oscillator (HSI). */
__HAL_RCC_HSI_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI is disabled */
while (READ_BIT(RCC->CR, RCC_CR_HSIRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > HSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*------------------------------ LSI Configuration -------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_LSI) == RCC_OSCILLATORTYPE_LSI)
{
/* Check the parameters */
assert_param(IS_RCC_LSI(RCC_OscInitStruct->LSIState));
/* Check the LSI State */
if (RCC_OscInitStruct->LSIState != RCC_LSI_OFF)
{
/* Apply prescaler value */
if (RCC_OscInitStruct->LSIDiv == RCC_LSI_DIV1)
{
CLEAR_BIT(RCC->CSR, RCC_CSR_LSIPRE);
}
else
{
SET_BIT(RCC->CSR, RCC_CSR_LSIPRE);
}
/* Enable the Internal Low Speed oscillator (LSI). */
__HAL_RCC_LSI_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSI is ready */
while (READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > LSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the Internal Low Speed oscillator (LSI). */
__HAL_RCC_LSI_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSI is disabled */
while (READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > LSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
/*------------------------------ LSE Configuration -------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_LSE) == RCC_OSCILLATORTYPE_LSE)
{
FlagStatus pwrclkchanged = RESET;
/* Check the parameters */
assert_param(IS_RCC_LSE(RCC_OscInitStruct->LSEState));
/* Update LSE configuration in Backup Domain control register */
/* Requires to enable write access to Backup Domain of necessary */
if (HAL_IS_BIT_CLR(RCC->APB1ENR1, RCC_APB1ENR1_PWREN))
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if (HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
/* Enable write access to Backup domain */
SET_BIT(PWR->CR1, PWR_CR1_DBP);
/* Wait for Backup domain Write protection disable */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
if ((HAL_GetTick() - tickstart) > RCC_DBP_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/* Set the new LSE configuration -----------------------------------------*/
if ((RCC_OscInitStruct->LSEState & RCC_BDCR_LSEON) != 0U)
{
if ((RCC_OscInitStruct->LSEState & RCC_BDCR_LSEBYP) != 0U)
{
/* LSE oscillator bypass enable */
SET_BIT(RCC->BDCR, RCC_BDCR_LSEBYP);
SET_BIT(RCC->BDCR, RCC_BDCR_LSEON);
}
else
{
/* LSE oscillator enable */
SET_BIT(RCC->BDCR, RCC_BDCR_LSEON);
}
}
else
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEON);
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEBYP);
}
/* Check the LSE State */
if (RCC_OscInitStruct->LSEState != RCC_LSE_OFF)
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSE is ready */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Enable LSESYS additionnally if requested */
if ((RCC_OscInitStruct->LSEState & RCC_BDCR_LSESYSEN) != 0U)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSESYSEN);
/* Wait till LSESYS is ready */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSESYSRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Make sure LSESYSEN/LSESYSRDY are reset */
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSESYSEN);
/* Wait till LSESYSRDY is cleared */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSESYSRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
else
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSE is disabled */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
if (READ_BIT(RCC->BDCR, RCC_BDCR_LSESYSEN) != 0U)
{
/* Reset LSESYSEN once LSE is disabled */
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSESYSEN);
/* Wait till LSESYSRDY is cleared */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSESYSRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
/* Restore clock configuration if changed */
if (pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/*------------------------------ HSI48 Configuration -----------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSI48) == RCC_OSCILLATORTYPE_HSI48)
{
/* Check the parameters */
assert_param(IS_RCC_HSI48(RCC_OscInitStruct->HSI48State));
/* Check the LSI State */
if (RCC_OscInitStruct->HSI48State != RCC_HSI48_OFF)
{
/* Enable the Internal Low Speed oscillator (HSI48). */
__HAL_RCC_HSI48_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI48 is ready */
while (READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48RDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSI48_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the Internal Low Speed oscillator (HSI48). */
__HAL_RCC_HSI48_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI48 is disabled */
while (READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48RDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > HSI48_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
/*-------------------------------- PLL Configuration -----------------------*/
/* Check the parameters */
assert_param(IS_RCC_PLL(RCC_OscInitStruct->PLL.PLLState));
if (RCC_OscInitStruct->PLL.PLLState != RCC_PLL_NONE)
{
/* Check if the PLL is used as system clock or not */
if (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_PLL)
{
if (RCC_OscInitStruct->PLL.PLLState == RCC_PLL_ON)
{
/* Check the parameters */
assert_param(IS_RCC_PLLSOURCE(RCC_OscInitStruct->PLL.PLLSource));
assert_param(IS_RCC_PLLM_VALUE(RCC_OscInitStruct->PLL.PLLM));
assert_param(IS_RCC_PLLN_VALUE(RCC_OscInitStruct->PLL.PLLN));
assert_param(IS_RCC_PLLP_VALUE(RCC_OscInitStruct->PLL.PLLP));
assert_param(IS_RCC_PLLQ_VALUE(RCC_OscInitStruct->PLL.PLLQ));
assert_param(IS_RCC_PLLR_VALUE(RCC_OscInitStruct->PLL.PLLR));
/* Disable the main PLL. */
__HAL_RCC_PLL_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is ready */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Configure the main PLL clock source, multiplication and division factors. */
__HAL_RCC_PLL_CONFIG(RCC_OscInitStruct->PLL.PLLSource,
RCC_OscInitStruct->PLL.PLLM,
RCC_OscInitStruct->PLL.PLLN,
RCC_OscInitStruct->PLL.PLLP,
RCC_OscInitStruct->PLL.PLLQ,
RCC_OscInitStruct->PLL.PLLR);
/* Enable the main PLL. */
__HAL_RCC_PLL_ENABLE();
/* Enable PLL System Clock output. */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_SYSCLK);
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is ready */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the main PLL. */
__HAL_RCC_PLL_DISABLE();
/* Disable all PLL outputs to save power if no PLLs on */
if (READ_BIT(RCC->CR, (RCC_CR_PLLSAI1RDY | RCC_CR_PLLSAI2RDY)) == 0U)
{
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC, RCC_PLLSOURCE_NONE);
}
__HAL_RCC_PLLCLKOUT_DISABLE(RCC_PLL_SYSCLK | RCC_PLL_48M1CLK | RCC_PLL_SAI3CLK);
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is disabled */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
else
{
/* Check if there is a request to disable the PLL used as System clock source */
if (RCC_OscInitStruct->PLL.PLLState == RCC_PLL_OFF)
{
return HAL_ERROR;
}
else
{
pll_config = RCC->PLLCFGR;
/* Do not return HAL_ERROR if request repeats the current configuration */
if ((READ_BIT(pll_config, RCC_PLLCFGR_PLLSRC) != RCC_OscInitStruct->PLL.PLLSource) ||
(READ_BIT(pll_config, RCC_PLLCFGR_PLLM) != ((RCC_OscInitStruct->PLL.PLLM - 1U) << RCC_PLLCFGR_PLLM_Pos)) ||
(READ_BIT(pll_config, RCC_PLLCFGR_PLLN) != (RCC_OscInitStruct->PLL.PLLN << RCC_PLLCFGR_PLLN_Pos)) ||
(READ_BIT(pll_config, RCC_PLLCFGR_PLLPDIV) != (RCC_OscInitStruct->PLL.PLLP << RCC_PLLCFGR_PLLPDIV_Pos)) ||
(READ_BIT(pll_config, RCC_PLLCFGR_PLLQ) != ((((RCC_OscInitStruct->PLL.PLLQ) >> 1U) - 1U) << RCC_PLLCFGR_PLLQ_Pos)) ||
(READ_BIT(pll_config, RCC_PLLCFGR_PLLR) != ((((RCC_OscInitStruct->PLL.PLLR) >> 1U) - 1U) << RCC_PLLCFGR_PLLR_Pos)))
{
return HAL_ERROR;
}
}
}
}
return HAL_OK;
}
/**
* @brief Initialize the CPU, AHB and APB busses clocks according to the specified
* parameters in the RCC_ClkInitStruct.
* @param RCC_ClkInitStruct pointer to an RCC_OscInitTypeDef structure that
* contains the configuration information for the RCC peripheral.
* @param FLatency FLASH Latency
* This parameter can be one of the following values:
* @arg FLASH_LATENCY_0 FLASH 0 Latency cycle
* @arg FLASH_LATENCY_1 FLASH 1 Latency cycle
* @arg FLASH_LATENCY_2 FLASH 2 Latency cycles
* @arg FLASH_LATENCY_3 FLASH 3 Latency cycles
* @arg FLASH_LATENCY_4 FLASH 4 Latency cycles
* @arg FLASH_LATENCY_5 FLASH 5 Latency cycles
* @arg FLASH_LATENCY_6 FLASH 6 Latency cycles
* @arg FLASH_LATENCY_7 FLASH 7 Latency cycles
* @arg FLASH_LATENCY_8 FLASH 8 Latency cycles
* @arg FLASH_LATENCY_9 FLASH 9 Latency cycles
* @arg FLASH_LATENCY_10 FLASH 10 Latency cycles
* @arg FLASH_LATENCY_11 FLASH 11 Latency cycles
* @arg FLASH_LATENCY_12 FLASH 12 Latency cycles
* @arg FLASH_LATENCY_13 FLASH 13 Latency cycles
* @arg FLASH_LATENCY_14 FLASH 14 Latency cycles
* @arg FLASH_LATENCY_15 FLASH 15 Latency cycles
*
* @note The SystemCoreClock CMSIS variable is used to store System Clock Frequency
* and updated by HAL_RCC_GetHCLKFreq() function called within this function
*
* @note The MSI is used by default as system clock source after
* startup from Reset, wake-up from STANDBY mode. After restart from Reset,
* the MSI frequency is set to its default value 4 MHz.
*
* @note The HSI can be selected as system clock source after
* from STOP modes or in case of failure of the HSE used directly or indirectly
* as system clock (if the Clock Security System CSS is enabled).
*
* @note A switch from one clock source to another occurs only if the target
* clock source is ready (clock stable after startup delay or PLL locked).
* If a clock source which is not yet ready is selected, the switch will
* occur when the clock source is ready.
*
* @note HAL_RCC_ClockConfig() function takes care of clock switching transition state
* with AHB prescaler when switching from HSE or HSI or MSI to PLL with AHB
* frequency (HCLK) higher than 80 MHz and when switching from PLL with HCLK
* higher than 80 MHz to HSE or HSI or MSI currently used as system clock source.
*
* @note You can use HAL_RCC_GetClockConfig() function to know which clock is
* currently used as system clock source.
*
* @note Depending on the device voltage range, the software has to set correctly
* HPRE[3:0] bits to ensure that HCLK not exceed the maximum allowed frequency
* (for more details refer to section above "Initialization/de-initialization functions")
* @retval None
*/
HAL_StatusTypeDef HAL_RCC_ClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t FLatency)
{
uint32_t tickstart;
uint32_t pllfreq;
uint32_t hpre = RCC_SYSCLK_DIV1;
HAL_StatusTypeDef status;
/* Check Null pointer */
if (RCC_ClkInitStruct == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_RCC_CLOCKTYPE(RCC_ClkInitStruct->ClockType));
assert_param(IS_FLASH_LATENCY(FLatency));
/* To correctly read data from FLASH memory, the number of wait states (LATENCY)
must be correctly programmed according to the frequency of the CPU clock
(HCLK) and the supply voltage of the device. */
/* Increasing the number of wait states because of higher CPU frequency */
if (FLatency > (FLASH->ACR & FLASH_ACR_LATENCY))
{
/* Program the new number of wait states to the LATENCY bits in the FLASH_ACR register */
__HAL_FLASH_SET_LATENCY(FLatency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by reading the FLASH_ACR register */
if ((FLASH->ACR & FLASH_ACR_LATENCY) != FLatency)
{
return HAL_ERROR;
}
}
/*------------------------- SYSCLK Configuration ---------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_SYSCLK) == RCC_CLOCKTYPE_SYSCLK)
{
assert_param(IS_RCC_SYSCLKSOURCE(RCC_ClkInitStruct->SYSCLKSource));
/* PLL is selected as System Clock Source */
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_PLLCLK)
{
/* Check the PLL ready flag */
if (READ_BIT(RCC->CR, RCC_CR_PLLRDY) == 0U)
{
return HAL_ERROR;
}
/* Transition state management when selecting PLL as SYSCLK source and */
/* target frequency above 80Mhz */
/* Compute target PLL output frequency */
pllfreq = RCC_GetSysClockFreqFromPLLSource();
/* Intermediate step with HCLK prescaler 2 necessary before to go over 80Mhz */
if (pllfreq > 80000000U)
{
if (READ_BIT(RCC->CFGR, RCC_CFGR_HPRE) == RCC_SYSCLK_DIV1)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV2);
hpre = RCC_SYSCLK_DIV2;
}
else if ((((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_HCLK) == RCC_CLOCKTYPE_HCLK) &&
(RCC_ClkInitStruct->AHBCLKDivider == RCC_SYSCLK_DIV1))
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV2);
hpre = RCC_SYSCLK_DIV2;
}
else
{
/* nothing to do */
}
}
}
else
{
/* HSE is selected as System Clock Source */
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_HSE)
{
/* Check the HSE ready flag */
if (READ_BIT(RCC->CR, RCC_CR_HSERDY) == 0U)
{
return HAL_ERROR;
}
}
/* MSI is selected as System Clock Source */
else if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_MSI)
{
/* Check the MSI ready flag */
if (READ_BIT(RCC->CR, RCC_CR_MSIRDY) == 0U)
{
return HAL_ERROR;
}
}
/* HSI is selected as System Clock Source */
else
{
/* Check the HSI ready flag */
if (READ_BIT(RCC->CR, RCC_CR_HSIRDY) == 0U)
{
return HAL_ERROR;
}
}
/* Transition state management when when going down from PLL used as */
/* SYSCLK source and frequency above 80Mhz */
pllfreq = HAL_RCC_GetSysClockFreq();
/* Intermediate step with HCLK prescaler 2 necessary before to go under 80Mhz */
if (pllfreq > 80000000U)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV2);
hpre = RCC_SYSCLK_DIV2;
}
}
MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, RCC_ClkInitStruct->SYSCLKSource);
/* Get Start Tick*/
tickstart = HAL_GetTick();
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_PLLCLK)
{
while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_PLL)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_HSE)
{
while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_HSE)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_MSI)
{
while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_MSI)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_HSI)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*-------------------------- HCLK Configuration --------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_HCLK) == RCC_CLOCKTYPE_HCLK)
{
assert_param(IS_RCC_HCLK(RCC_ClkInitStruct->AHBCLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_ClkInitStruct->AHBCLKDivider);
}
else
{
/* Is intermediate HCLK prescaler 2 applied internally, complete with HCLK prescaler 1 */
if (hpre == RCC_SYSCLK_DIV2)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV1);
}
}
/* Decreasing the number of wait states because of lower CPU frequency */
if (FLatency < (FLASH->ACR & FLASH_ACR_LATENCY))
{
/* Program the new number of wait states to the LATENCY bits in the FLASH_ACR register */
__HAL_FLASH_SET_LATENCY(FLatency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by reading the FLASH_ACR register */
if ((FLASH->ACR & FLASH_ACR_LATENCY) != FLatency)
{
return HAL_ERROR;
}
}
/*-------------------------- PCLK1 Configuration ---------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK1) == RCC_CLOCKTYPE_PCLK1)
{
assert_param(IS_RCC_PCLK(RCC_ClkInitStruct->APB1CLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE1, RCC_ClkInitStruct->APB1CLKDivider);
}
/*-------------------------- PCLK2 Configuration ---------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK2) == RCC_CLOCKTYPE_PCLK2)
{
assert_param(IS_RCC_PCLK(RCC_ClkInitStruct->APB2CLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE2, ((RCC_ClkInitStruct->APB2CLKDivider) << 3U));
}
/* Update the SystemCoreClock global variable */
SystemCoreClock = HAL_RCC_GetSysClockFreq() >> AHBPrescTable[(RCC->CFGR & RCC_CFGR_HPRE) >> RCC_CFGR_HPRE_Pos];
/* Configure the source of time base considering new system clocks settings*/
status = HAL_InitTick(TICK_INT_PRIORITY);
return status;
}
/**
* @}
*/
/** @defgroup RCC_Exported_Functions_Group2 Peripheral Control functions
* @brief RCC clocks control functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to:
(+) Ouput clock to MCO pin.
(+) Retrieve current clock frequencies.
(+) Enable the Clock Security System.
@endverbatim
* @{
*/
/**
* @brief Select the clock source to output on MCO pin(PA8).
* @note PA8 should be configured in alternate function mode.
* @param RCC_MCOx specifies the output direction for the clock source.
* For STM32L5xx family this parameter can have only one value:
* @arg @ref RCC_MCO1 Clock source to output on MCO1 pin(PA8).
* @param RCC_MCOSource specifies the clock source to output.
* This parameter can be one of the following values:
* @arg @ref RCC_MCO1SOURCE_NOCLOCK MCO output disabled, no clock on MCO
* @arg @ref RCC_MCO1SOURCE_SYSCLK system clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_MSI MSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI HSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSE HSE clock selected as MCO sourcee
* @arg @ref RCC_MCO1SOURCE_PLLCLK main PLL clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSI LSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSE LSE clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI48 HSI48 clock selected as MCO source
* @param RCC_MCODiv specifies the MCO prescaler.
* This parameter can be one of the following values:
* @arg @ref RCC_MCODIV_1 no division applied to MCO clock
* @arg @ref RCC_MCODIV_2 division by 2 applied to MCO clock
* @arg @ref RCC_MCODIV_4 division by 4 applied to MCO clock
* @arg @ref RCC_MCODIV_8 division by 8 applied to MCO clock
* @arg @ref RCC_MCODIV_16 division by 16 applied to MCO clock
* @retval None
*/
void HAL_RCC_MCOConfig(uint32_t RCC_MCOx, uint32_t RCC_MCOSource, uint32_t RCC_MCODiv)
{
GPIO_InitTypeDef GPIO_InitStruct;
/* Check the parameters */
assert_param(IS_RCC_MCO(RCC_MCOx));
assert_param(IS_RCC_MCODIV(RCC_MCODiv));
assert_param(IS_RCC_MCO1SOURCE(RCC_MCOSource));
/* MCO Clock Enable */
__MCO1_CLK_ENABLE();
/* Configue the MCO1 pin in alternate function mode */
GPIO_InitStruct.Pin = MCO1_PIN;
GPIO_InitStruct.Mode = GPIO_MODE_AF_PP;
GPIO_InitStruct.Speed = GPIO_SPEED_FREQ_HIGH;
GPIO_InitStruct.Pull = GPIO_NOPULL;
GPIO_InitStruct.Alternate = GPIO_AF0_MCO;
HAL_GPIO_Init(MCO1_GPIO_PORT, &GPIO_InitStruct);
/* Mask MCOSEL[] and MCOPRE[] bits then set MCO1 clock source and prescaler */
MODIFY_REG(RCC->CFGR, (RCC_CFGR_MCOSEL | RCC_CFGR_MCOPRE), (RCC_MCOSource | RCC_MCODiv));
}
/**
* @brief Return the SYSCLK frequency.
*
* @note The system frequency computed by this function is not the real
* frequency in the chip. It is calculated based on the predefined
* constant and the selected clock source:
* @note If SYSCLK source is MSI, function returns values based on MSI
* Value as defined by the MSI range.
* @note If SYSCLK source is HSI, function returns values based on HSI_VALUE(*)
* @note If SYSCLK source is HSE, function returns values based on HSE_VALUE(**)
* @note If SYSCLK source is PLL, function returns values based on HSE_VALUE(**),
* HSI_VALUE(*) or MSI Value multiplied/divided by the PLL factors.
* @note (*) HSI_VALUE is a constant defined in stm32l5xx_hal_conf.h file (default value
* 16 MHz) but the real value may vary depending on the variations
* in voltage and temperature.
* @note (**) HSE_VALUE is a constant defined in stm32l5xx_hal_conf.h file (default value
* 8 MHz), user has to ensure that HSE_VALUE is same as the real
* frequency of the crystal used. Otherwise, this function may
* have wrong result.
*
* @note The result of this function could be not correct when using fractional
* value for HSE crystal.
*
* @note This function can be used by the user application to compute the
* baudrate for the communication peripherals or configure other parameters.
*
* @note Each time SYSCLK changes, this function must be called to update the
* right SYSCLK value. Otherwise, any configuration based on this function will be incorrect.
*
*
* @retval SYSCLK frequency
*/
uint32_t HAL_RCC_GetSysClockFreq(void)
{
uint32_t msirange = 0U, sysclockfreq = 0U;
uint32_t pllvco, pllsource, pllr, pllm; /* no init needed */
uint32_t sysclk_source, pll_oscsource;
sysclk_source = __HAL_RCC_GET_SYSCLK_SOURCE();
pll_oscsource = __HAL_RCC_GET_PLL_OSCSOURCE();
if ((sysclk_source == RCC_CFGR_SWS_MSI) ||
((sysclk_source == RCC_CFGR_SWS_PLL) && (pll_oscsource == RCC_PLLSOURCE_MSI)))
{
/* MSI or PLL with MSI source used as system clock source */
/* Get SYSCLK source */
if (READ_BIT(RCC->CR, RCC_CR_MSIRGSEL) == 0U)
{
/* MSISRANGE from RCC_CSR applies */
msirange = READ_BIT(RCC->CSR, RCC_CSR_MSISRANGE) >> RCC_CSR_MSISRANGE_Pos;
}
else
{
/* MSIRANGE from RCC_CR applies */
msirange = READ_BIT(RCC->CR, RCC_CR_MSIRANGE) >> RCC_CR_MSIRANGE_Pos;
}
/*MSI frequency range in Hz*/
msirange = MSIRangeTable[msirange];
if (sysclk_source == RCC_CFGR_SWS_MSI)
{
/* MSI used as system clock source */
sysclockfreq = msirange;
}
}
else if (sysclk_source == RCC_CFGR_SWS_HSI)
{
/* HSI used as system clock source */
sysclockfreq = HSI_VALUE;
}
else if (sysclk_source == RCC_CFGR_SWS_HSE)
{
/* HSE used as system clock source */
sysclockfreq = HSE_VALUE;
}
else
{
/* unexpected case: sysclockfreq at 0 */
}
if (sysclk_source == RCC_CFGR_SWS_PLL)
{
/* PLL used as system clock source */
/* PLL_VCO = (HSE_VALUE or HSI_VALUE or MSI_VALUE/ PLLM) * PLLN
SYSCLK = PLL_VCO / PLLR
*/
pllsource = (RCC->PLLCFGR & RCC_PLLCFGR_PLLSRC);
pllm = ((RCC->PLLCFGR & RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U ;
switch (pllsource)
{
case RCC_PLLSOURCE_HSI: /* HSI used as PLL clock source */
pllvco = (HSI_VALUE / pllm) * ((RCC->PLLCFGR & RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_HSE: /* HSE used as PLL clock source */
pllvco = (HSE_VALUE / pllm) * ((RCC->PLLCFGR & RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_MSI: /* MSI used as PLL clock source */
default:
pllvco = (msirange / pllm) * ((RCC->PLLCFGR & RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
}
pllr = (((RCC->PLLCFGR & RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U) * 2U;
sysclockfreq = pllvco / pllr;
}
return sysclockfreq;
}
/**
* @brief Return the HCLK frequency.
* @note Each time HCLK changes, this function must be called to update the
* right HCLK value. Otherwise, any configuration based on this function will be incorrect.
*
* @note The SystemCoreClock CMSIS variable is used to store System Clock Frequency.
* @retval HCLK frequency in Hz
*/
uint32_t HAL_RCC_GetHCLKFreq(void)
{
SystemCoreClockUpdate();
return SystemCoreClock;
}
/**
* @brief Return the PCLK1 frequency.
* @note Each time PCLK1 changes, this function must be called to update the
* right PCLK1 value. Otherwise, any configuration based on this function will be incorrect.
* @retval PCLK1 frequency in Hz
*/
uint32_t HAL_RCC_GetPCLK1Freq(void)
{
/* Get HCLK source and Compute PCLK1 frequency ---------------------------*/
return (HAL_RCC_GetHCLKFreq() >> APBPrescTable[(RCC->CFGR & RCC_CFGR_PPRE1) >> RCC_CFGR_PPRE1_Pos]);
}
/**
* @brief Return the PCLK2 frequency.
* @note Each time PCLK2 changes, this function must be called to update the
* right PCLK2 value. Otherwise, any configuration based on this function will be incorrect.
* @retval PCLK2 frequency in Hz
*/
uint32_t HAL_RCC_GetPCLK2Freq(void)
{
/* Get HCLK source and Compute PCLK2 frequency ---------------------------*/
return (HAL_RCC_GetHCLKFreq() >> APBPrescTable[(RCC->CFGR & RCC_CFGR_PPRE2) >> RCC_CFGR_PPRE2_Pos]);
}
/**
* @brief Configure the RCC_OscInitStruct according to the internal
* RCC configuration registers.
* @param RCC_OscInitStruct pointer to an RCC_OscInitTypeDef structure that
* will be configured.
* @retval None
*/
void HAL_RCC_GetOscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct)
{
/* Check the parameters */
assert_param(RCC_OscInitStruct != (void *)NULL);
/* Set all possible values for the Oscillator type parameter ---------------*/
RCC_OscInitStruct->OscillatorType = RCC_OSCILLATORTYPE_HSE | RCC_OSCILLATORTYPE_HSI | RCC_OSCILLATORTYPE_MSI | \
RCC_OSCILLATORTYPE_LSE | RCC_OSCILLATORTYPE_LSI | RCC_OSCILLATORTYPE_HSI48;
/* Get the HSE configuration -----------------------------------------------*/
if ((RCC->CR & RCC_CR_HSEBYP) == RCC_CR_HSEBYP)
{
RCC_OscInitStruct->HSEState = RCC_HSE_BYPASS;
}
else if ((RCC->CR & RCC_CR_HSEON) == RCC_CR_HSEON)
{
RCC_OscInitStruct->HSEState = RCC_HSE_ON;
}
else
{
RCC_OscInitStruct->HSEState = RCC_HSE_OFF;
}
/* Get the MSI configuration -----------------------------------------------*/
if ((RCC->CR & RCC_CR_MSION) == RCC_CR_MSION)
{
RCC_OscInitStruct->MSIState = RCC_MSI_ON;
}
else
{
RCC_OscInitStruct->MSIState = RCC_MSI_OFF;
}
RCC_OscInitStruct->MSICalibrationValue = (uint32_t)((RCC->ICSCR & RCC_ICSCR_MSITRIM) >> RCC_ICSCR_MSITRIM_Pos);
RCC_OscInitStruct->MSIClockRange = (uint32_t)((RCC->CR & RCC_CR_MSIRANGE));
/* Get the HSI configuration -----------------------------------------------*/
if ((RCC->CR & RCC_CR_HSION) == RCC_CR_HSION)
{
RCC_OscInitStruct->HSIState = RCC_HSI_ON;
}
else
{
RCC_OscInitStruct->HSIState = RCC_HSI_OFF;
}
RCC_OscInitStruct->HSICalibrationValue = (uint32_t)((RCC->ICSCR & RCC_ICSCR_HSITRIM) >> RCC_ICSCR_HSITRIM_Pos);
/* Get the LSE configuration -----------------------------------------------*/
if ((RCC->BDCR & RCC_BDCR_LSEBYP) == RCC_BDCR_LSEBYP)
{
if ((RCC->BDCR & RCC_BDCR_LSESYSEN) == RCC_BDCR_LSESYSEN)
{
RCC_OscInitStruct->LSEState = RCC_LSE_BYPASS;
}
else
{
RCC_OscInitStruct->LSEState = RCC_LSE_BYPASS_RTC_ONLY;
}
}
else if ((RCC->BDCR & RCC_BDCR_LSEON) == RCC_BDCR_LSEON)
{
if ((RCC->BDCR & RCC_BDCR_LSESYSEN) == RCC_BDCR_LSESYSEN)
{
RCC_OscInitStruct->LSEState = RCC_LSE_ON;
}
else
{
RCC_OscInitStruct->LSEState = RCC_LSE_ON_RTC_ONLY;
}
}
else
{
RCC_OscInitStruct->LSEState = RCC_LSE_OFF;
}
/* Get the LSI configuration -----------------------------------------------*/
if ((RCC->CSR & RCC_CSR_LSION) == RCC_CSR_LSION)
{
RCC_OscInitStruct->LSIState = RCC_LSI_ON;
}
else
{
RCC_OscInitStruct->LSIState = RCC_LSI_OFF;
}
if ((RCC->CSR & RCC_CSR_LSIPRE) == RCC_CSR_LSIPRE)
{
RCC_OscInitStruct->LSIDiv = RCC_LSI_DIV128;
}
else
{
RCC_OscInitStruct->LSIDiv = RCC_LSI_DIV1;
}
/* Get the HSI48 configuration ---------------------------------------------*/
if ((RCC->CRRCR & RCC_CRRCR_HSI48ON) == RCC_CRRCR_HSI48ON)
{
RCC_OscInitStruct->HSI48State = RCC_HSI48_ON;
}
else
{
RCC_OscInitStruct->HSI48State = RCC_HSI48_OFF;
}
/* Get the PLL configuration -----------------------------------------------*/
if ((RCC->CR & RCC_CR_PLLON) == RCC_CR_PLLON)
{
RCC_OscInitStruct->PLL.PLLState = RCC_PLL_ON;
}
else
{
RCC_OscInitStruct->PLL.PLLState = RCC_PLL_OFF;
}
RCC_OscInitStruct->PLL.PLLSource = (uint32_t)(RCC->PLLCFGR & RCC_PLLCFGR_PLLSRC);
RCC_OscInitStruct->PLL.PLLM = (uint32_t)(((RCC->PLLCFGR & RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U);
RCC_OscInitStruct->PLL.PLLN = (uint32_t)((RCC->PLLCFGR & RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
RCC_OscInitStruct->PLL.PLLQ = (uint32_t)((((RCC->PLLCFGR & RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
RCC_OscInitStruct->PLL.PLLR = (uint32_t)((((RCC->PLLCFGR & RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U) << 1U);
RCC_OscInitStruct->PLL.PLLP = (uint32_t)((RCC->PLLCFGR & RCC_PLLCFGR_PLLPDIV) >> RCC_PLLCFGR_PLLPDIV_Pos);
}
/**
* @brief Configure the RCC_ClkInitStruct according to the internal
* RCC configuration registers.
* @param RCC_ClkInitStruct pointer to an RCC_ClkInitTypeDef structure that
* will be configured.
* @param pFLatency Pointer on the Flash Latency.
* @retval None
*/
void HAL_RCC_GetClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t *pFLatency)
{
/* Check the parameters */
assert_param(RCC_ClkInitStruct != (void *)NULL);
assert_param(pFLatency != (void *)NULL);
/* Set all possible values for the Clock type parameter --------------------*/
RCC_ClkInitStruct->ClockType = RCC_CLOCKTYPE_SYSCLK | RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2;
/* Get the SYSCLK configuration --------------------------------------------*/
RCC_ClkInitStruct->SYSCLKSource = (uint32_t)(RCC->CFGR & RCC_CFGR_SW);
/* Get the HCLK configuration ----------------------------------------------*/
RCC_ClkInitStruct->AHBCLKDivider = (uint32_t)(RCC->CFGR & RCC_CFGR_HPRE);
/* Get the APB1 configuration ----------------------------------------------*/
RCC_ClkInitStruct->APB1CLKDivider = (uint32_t)(RCC->CFGR & RCC_CFGR_PPRE1);
/* Get the APB2 configuration ----------------------------------------------*/
RCC_ClkInitStruct->APB2CLKDivider = (uint32_t)((RCC->CFGR & RCC_CFGR_PPRE2) >> 3U);
/* Get the Flash Wait State (Latency) configuration ------------------------*/
*pFLatency = (uint32_t)(FLASH->ACR & FLASH_ACR_LATENCY);
}
/**
* @brief Enable the Clock Security System.
* @note If a failure is detected on the HSE oscillator clock, this oscillator
* is automatically disabled and an interrupt is generated to inform the
* software about the failure (Clock Security System Interrupt, CSSI),
* allowing the MCU to perform rescue operations. The CSSI is linked to
* the Cortex-M33 NMI (Non-Maskable Interrupt) exception vector.
* @note The Clock Security System can only be cleared by reset.
* @retval None
*/
void HAL_RCC_EnableCSS(void)
{
SET_BIT(RCC->CR, RCC_CR_CSSON) ;
}
/**
* @brief Handle the RCC Clock Security System interrupt request.
* @note This API should be called under the NMI_Handler().
* @retval None
*/
void HAL_RCC_NMI_IRQHandler(void)
{
/* Check RCC CSSF interrupt flag */
if (__HAL_RCC_GET_IT(RCC_IT_CSS))
{
/* RCC Clock Security System interrupt user callback */
HAL_RCC_CSSCallback();
/* Clear RCC CSS pending bit */
__HAL_RCC_CLEAR_IT(RCC_IT_CSS);
}
}
/**
* @brief RCC Clock Security System interrupt callback.
* @retval none
*/
__weak void HAL_RCC_CSSCallback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_RCC_CSSCallback should be implemented in the user file
*/
}
/**
* @}
*/
/** @defgroup RCC_Exported_Functions_Group3 Attributes management functions
* @brief Attributes management functions.
*
@verbatim
===============================================================================
##### RCC attributes functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Configure the RCC item attribute(s).
* @note Available attributes are to secure items and set RCC as privileged.
* Default state is not secure and unprivileged access allowed.
* @note Secure and non-secure attributes can only be set from the secure
* state when the system implements the security (TZEN=1).
* @note Security and privilege attributes can be set independently.
* @param Item Item(s) to set attributes on.
* This parameter can be a one or a combination of @ref RCC_items
* @param Attributes can be one or a combination of the following values:
* @arg @ref RCC_PRIV Privileged-only access
* @arg @ref RCC_NPRIV Privileged/Non-privileged access
* @arg @ref RCC_SEC Secure-only access
* @arg @ref RCC_NSEC Secure/Non-secure access
* @retval None
*/
void HAL_RCC_ConfigAttributes(uint32_t Item, uint32_t Attributes)
{
/* Check the parameters */
assert_param(IS_RCC_ITEMS_ATTRIBUTES(Item));
assert_param(IS_RCC_ATTRIBUTES(Attributes));
/* Privilege/non-privilege attribute */
if ((Attributes & RCC_PRIV) == RCC_PRIV)
{
SET_BIT(RCC->CR, RCC_CR_PRIV);
}
else if ((Attributes & RCC_NPRIV) == RCC_NPRIV)
{
CLEAR_BIT(RCC->CR, RCC_CR_PRIV);
}
else
{
/* do nothing */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/* Secure/non-secure attribute */
if ((Attributes & RCC_SEC) == RCC_SEC)
{
SET_BIT(RCC_S->SECCFGR, Item);
}
else if ((Attributes & RCC_NSEC) == RCC_NSEC)
{
CLEAR_BIT(RCC_S->SECCFGR, Item);
}
else
{
/* do nothing */
}
#endif /* __ARM_FEATURE_CMSE */
}
/**
* @brief Get the attribute of a RCC item.
* @note Secure and non-secure attributes are only available from secure state
* when the system implements the security (TZEN=1)
* @param Item Single item to get secure/non-secure and privilege/non-privilege attribute from.
* @param pAttributes pointer to return the attributes value.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_RCC_GetConfigAttributes(uint32_t Item, uint32_t *pAttributes)
{
uint32_t attributes;
/* Check null pointer */
if (pAttributes == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_RCC_ITEMS_ATTRIBUTES(Item));
/* Get privilege or non-privilege attribute */
if (READ_BIT(RCC->CR, RCC_CR_PRIV) != 0U)
{
attributes = RCC_PRIV;
}
else
{
attributes = RCC_NPRIV;
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/* Get the secure or non-secure attribute state */
if ((RCC_S->SECCFGR & Item) == Item)
{
attributes |= RCC_SEC;
}
else
{
attributes |= RCC_NSEC;
}
#endif /* __ARM_FEATURE_CMSE */
/* return value */
*pAttributes = attributes;
return HAL_OK;
}
/**
* @}
*/
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @addtogroup RCC_Private_Functions
* @{
*/
/**
* @brief Update number of Flash wait states in line with MSI range and current
voltage range.
* @param msirange MSI range value from RCC_MSIRANGE_0 to RCC_MSIRANGE_11
* @retval HAL status
*/
static HAL_StatusTypeDef RCC_SetFlashLatencyFromMSIRange(uint32_t msirange)
{
uint32_t latency = FLASH_LATENCY_0; /* default value 0WS */
uint32_t vos;
if (__HAL_RCC_PWR_IS_CLK_ENABLED())
{
vos = HAL_PWREx_GetVoltageRange();
}
else
{
__HAL_RCC_PWR_CLK_ENABLE();
vos = HAL_PWREx_GetVoltageRange();
__HAL_RCC_PWR_CLK_DISABLE();
}
if ((vos == PWR_REGULATOR_VOLTAGE_SCALE0) || (vos == PWR_REGULATOR_VOLTAGE_SCALE1))
{
if (msirange > RCC_MSIRANGE_8)
{
/* MSI > 16Mhz */
if (msirange > RCC_MSIRANGE_10)
{
/* MSI 48Mhz */
latency = FLASH_LATENCY_2; /* 2WS */
}
else
{
/* MSI 24Mhz or 32Mhz */
latency = FLASH_LATENCY_1; /* 1WS */
}
}
/* else MSI <= 16Mhz default FLASH_LATENCY_0 0WS */
}
else
{
if (msirange > RCC_MSIRANGE_8)
{
/* MSI > 16Mhz */
latency = FLASH_LATENCY_3; /* 3WS */
}
else
{
if (msirange == RCC_MSIRANGE_8)
{
/* MSI 16Mhz */
latency = FLASH_LATENCY_2; /* 2WS */
}
else if (msirange == RCC_MSIRANGE_7)
{
/* MSI 8Mhz */
latency = FLASH_LATENCY_1; /* 1WS */
}
else
{
/* MSI < 8Mhz default FLASH_LATENCY_0 0WS */
}
}
}
__HAL_FLASH_SET_LATENCY(latency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by reading the FLASH_ACR register */
if ((FLASH->ACR & FLASH_ACR_LATENCY) != latency)
{
return HAL_ERROR;
}
return HAL_OK;
}
/**
* @brief Compute SYSCLK frequency based on PLL SYSCLK source.
* @retval SYSCLK frequency
*/
static uint32_t RCC_GetSysClockFreqFromPLLSource(void)
{
uint32_t msirange = 0U;
uint32_t pllvco, pllsource, pllr, pllm, sysclockfreq; /* no init needed */
if (__HAL_RCC_GET_PLL_OSCSOURCE() == RCC_PLLSOURCE_MSI)
{
/* Get MSI range source */
if (READ_BIT(RCC->CR, RCC_CR_MSIRGSEL) == 0U)
{
/* MSISRANGE from RCC_CSR applies */
msirange = READ_BIT(RCC->CSR, RCC_CSR_MSISRANGE) >> RCC_CSR_MSISRANGE_Pos;
}
else
{
/* MSIRANGE from RCC_CR applies */
msirange = READ_BIT(RCC->CR, RCC_CR_MSIRANGE) >> RCC_CR_MSIRANGE_Pos;
}
/*MSI frequency range in Hz*/
msirange = MSIRangeTable[msirange];
}
/* PLL_VCO = (HSE_VALUE or HSI_VALUE or MSI_VALUE/ PLLM) * PLLN
SYSCLK = PLL_VCO / PLLR
*/
pllsource = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC);
pllm = (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U ;
switch (pllsource)
{
case RCC_PLLSOURCE_HSI: /* HSI used as PLL clock source */
pllvco = (HSI_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_HSE: /* HSE used as PLL clock source */
pllvco = (HSE_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_MSI: /* MSI used as PLL clock source */
default:
pllvco = (msirange / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
}
pllr = ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U) * 2U;
sysclockfreq = pllvco / pllr;
return sysclockfreq;
}
/**
* @}
*/
#endif /* HAL_RCC_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
/************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/