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This commit is contained in:
许晟昊 2024-08-09 10:54:40 +08:00
parent ed839442f5
commit d0189cc1dd
134 changed files with 48512 additions and 2242 deletions
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23
.mxproject
View File

@ -1,26 +1,27 @@
[PreviousLibFiles]
LibFiles=Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_tim.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_tim_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\Legacy\stm32_hal_legacy.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_def.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_rcc_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_bus.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_system.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_utils.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_gpio_ex.h;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio_ex.c;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_dma_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_dma.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_dma.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_flash.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_flash_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_exti.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_exti.h;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim_ex.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc_ex.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_dma.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_cortex.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_pwr.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash_ex.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_exti.c;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_tim.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_tim_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\Legacy\stm32_hal_legacy.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_def.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_rcc_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_bus.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_system.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_utils.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_gpio_ex.h;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio_ex.c;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_dma_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_dma.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_dma.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_flash.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_flash_ex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_hal_exti.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_exti.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\stm32f103xb.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\stm32f1xx.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\system_stm32f1xx.h;Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;Drivers\CMSIS\Include\cmsis_armcc.h;Drivers\CMSIS\Include\cmsis_armclang.h;Drivers\CMSIS\Include\cmsis_compiler.h;Drivers\CMSIS\Include\cmsis_gcc.h;Drivers\CMSIS\Include\cmsis_iccarm.h;Drivers\CMSIS\Include\cmsis_version.h;Drivers\CMSIS\Include\core_armv8mbl.h;Drivers\CMSIS\Include\core_armv8mml.h;Drivers\CMSIS\Include\core_cm0.h;Drivers\CMSIS\Include\core_cm0plus.h;Drivers\CMSIS\Include\core_cm1.h;Drivers\CMSIS\Include\core_cm23.h;Drivers\CMSIS\Include\core_cm3.h;Drivers\CMSIS\Include\core_cm33.h;Drivers\CMSIS\Include\core_cm4.h;Drivers\CMSIS\Include\core_cm7.h;Drivers\CMSIS\Include\core_sc000.h;Drivers\CMSIS\Include\core_sc300.h;Drivers\CMSIS\Include\mpu_armv7.h;Drivers\CMSIS\Include\mpu_armv8.h;Drivers\CMSIS\Include\tz_context.h;
[PreviousUsedKeilFiles]
SourceFiles=..\Core\Src\main.c;..\Core\Src\gpio.c;..\Core\Src\stm32f1xx_it.c;..\Core\Src\stm32f1xx_hal_msp.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_dma.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_cortex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_pwr.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_exti.c;..\Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;..\Core\Src\system_stm32f1xx.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_tim_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_rcc_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_gpio.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_dma.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_cortex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_pwr.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_flash_ex.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_hal_exti.c;..\Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;..\Core\Src\system_stm32f1xx.c;;;
HeaderPath=..\Drivers\STM32F1xx_HAL_Driver\Inc;..\Drivers\STM32F1xx_HAL_Driver\Inc\Legacy;..\Drivers\CMSIS\Device\ST\STM32F1xx\Include;..\Drivers\CMSIS\Include;..\Core\Inc;
CDefines=USE_HAL_DRIVER;STM32F103xB;USE_HAL_DRIVER;USE_HAL_DRIVER;
[PreviousGenFiles]
AdvancedFolderStructure=true
HeaderFileListSize=4
HeaderFiles#0=..\Core\Inc\gpio.h
HeaderFiles#1=..\Core\Inc\stm32f1xx_it.h
HeaderFiles#2=..\Core\Inc\stm32_assert.h
HeaderFiles#2=..\Core\Inc\stm32f1xx_hal_conf.h
HeaderFiles#3=..\Core\Inc\main.h
HeaderFolderListSize=1
HeaderPath#0=..\Core\Inc
HeaderFiles=;
SourceFileListSize=3
SourceFileListSize=4
SourceFiles#0=..\Core\Src\gpio.c
SourceFiles#1=..\Core\Src\stm32f1xx_it.c
SourceFiles#2=..\Core\Src\main.c
SourceFiles#2=..\Core\Src\stm32f1xx_hal_msp.c
SourceFiles#3=..\Core\Src\main.c
SourceFolderListSize=1
SourcePath#0=..\Core\Src
SourceFiles=;
[PreviousLibFiles]
LibFiles=Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_system.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_exti.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_bus.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_utils.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_dma.h;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_gpio.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_pwr.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_exti.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_rcc.c;Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_utils.c;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_gpio.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_pwr.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_system.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_exti.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_bus.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_cortex.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_rcc.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_utils.h;Drivers\STM32F1xx_HAL_Driver\Inc\stm32f1xx_ll_dma.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\stm32f103xb.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\stm32f1xx.h;Drivers\CMSIS\Device\ST\STM32F1xx\Include\system_stm32f1xx.h;Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;Drivers\CMSIS\Include\cmsis_armcc.h;Drivers\CMSIS\Include\cmsis_armclang.h;Drivers\CMSIS\Include\cmsis_compiler.h;Drivers\CMSIS\Include\cmsis_gcc.h;Drivers\CMSIS\Include\cmsis_iccarm.h;Drivers\CMSIS\Include\cmsis_version.h;Drivers\CMSIS\Include\core_armv8mbl.h;Drivers\CMSIS\Include\core_armv8mml.h;Drivers\CMSIS\Include\core_cm0.h;Drivers\CMSIS\Include\core_cm0plus.h;Drivers\CMSIS\Include\core_cm1.h;Drivers\CMSIS\Include\core_cm23.h;Drivers\CMSIS\Include\core_cm3.h;Drivers\CMSIS\Include\core_cm33.h;Drivers\CMSIS\Include\core_cm4.h;Drivers\CMSIS\Include\core_cm7.h;Drivers\CMSIS\Include\core_sc000.h;Drivers\CMSIS\Include\core_sc300.h;Drivers\CMSIS\Include\mpu_armv7.h;Drivers\CMSIS\Include\mpu_armv8.h;Drivers\CMSIS\Include\tz_context.h;
[PreviousUsedKeilFiles]
SourceFiles=..\Core\Src\main.c;..\Core\Src\gpio.c;..\Core\Src\stm32f1xx_it.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_gpio.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_pwr.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_exti.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_rcc.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_utils.c;..\Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;..\Core\Src\system_stm32f1xx.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_gpio.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_pwr.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_exti.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_rcc.c;..\Drivers\STM32F1xx_HAL_Driver\Src\stm32f1xx_ll_utils.c;..\Drivers\CMSIS\Device\ST\STM32F1xx\Source\Templates\system_stm32f1xx.c;..\Core\Src\system_stm32f1xx.c;;;
HeaderPath=..\Drivers\STM32F1xx_HAL_Driver\Inc;..\Drivers\CMSIS\Device\ST\STM32F1xx\Include;..\Drivers\CMSIS\Include;..\Core\Inc;
CDefines=USE_FULL_LL_DRIVER;HSE_VALUE:8000000;HSE_STARTUP_TIMEOUT:100;LSE_STARTUP_TIMEOUT:5000;LSE_VALUE:32768;HSI_VALUE:8000000;LSI_VALUE:40000;VDD_VALUE:3300;PREFETCH_ENABLE:1;STM32F103xB;USE_FULL_LL_DRIVER;HSE_VALUE:8000000;HSE_STARTUP_TIMEOUT:100;LSE_STARTUP_TIMEOUT:5000;LSE_VALUE:32768;HSI_VALUE:8000000;LSI_VALUE:40000;VDD_VALUE:3300;PREFETCH_ENABLE:1;

18
.vscode/c_cpp_properties.json vendored Normal file
View File

@ -0,0 +1,18 @@
{
"configurations": [
{
"name": "windows-gcc-x64",
"includePath": [
"${workspaceFolder}/**"
],
"compilerPath": "C:/TDM-GCC-64/bin/gcc.exe",
"cStandard": "${default}",
"cppStandard": "${default}",
"intelliSenseMode": "windows-gcc-x64",
"compilerArgs": [
""
]
}
],
"version": 4
}

24
.vscode/launch.json vendored Normal file
View File

@ -0,0 +1,24 @@
{
"version": "0.2.0",
"configurations": [
{
"name": "C/C++ Runner: Debug Session",
"type": "cppdbg",
"request": "launch",
"args": [],
"stopAtEntry": false,
"externalConsole": true,
"cwd": "e:/work/stm32/电机学习工程/motor/Core/Src",
"program": "e:/work/stm32/电机学习工程/motor/Core/Src/build/Debug/outDebug",
"MIMode": "gdb",
"miDebuggerPath": "gdb",
"setupCommands": [
{
"description": "Enable pretty-printing for gdb",
"text": "-enable-pretty-printing",
"ignoreFailures": true
}
]
}
]
}

27
Core/Inc/main.h
View File

@ -27,20 +27,7 @@ extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_rcc.h"
#include "stm32f1xx_ll_bus.h"
#include "stm32f1xx_ll_system.h"
#include "stm32f1xx_ll_exti.h"
#include "stm32f1xx_ll_cortex.h"
#include "stm32f1xx_ll_utils.h"
#include "stm32f1xx_ll_pwr.h"
#include "stm32f1xx_ll_dma.h"
#include "stm32f1xx_ll_gpio.h"
#if defined(USE_FULL_ASSERT)
#include "stm32_assert.h"
#endif /* USE_FULL_ASSERT */
#include "stm32f1xx_hal.h"
/* Private includes ----------------------------------------------------------*/
/* USER CODE BEGIN Includes */
@ -70,18 +57,6 @@ void Error_Handler(void);
/* USER CODE END EFP */
/* Private defines -----------------------------------------------------------*/
#ifndef NVIC_PRIORITYGROUP_0
#define NVIC_PRIORITYGROUP_0 ((uint32_t)0x00000007) /*!< 0 bit for pre-emption priority,
4 bits for subpriority */
#define NVIC_PRIORITYGROUP_1 ((uint32_t)0x00000006) /*!< 1 bit for pre-emption priority,
3 bits for subpriority */
#define NVIC_PRIORITYGROUP_2 ((uint32_t)0x00000005) /*!< 2 bits for pre-emption priority,
2 bits for subpriority */
#define NVIC_PRIORITYGROUP_3 ((uint32_t)0x00000004) /*!< 3 bits for pre-emption priority,
1 bit for subpriority */
#define NVIC_PRIORITYGROUP_4 ((uint32_t)0x00000003) /*!< 4 bits for pre-emption priority,
0 bit for subpriority */
#endif
/* USER CODE BEGIN Private defines */

53
Core/Inc/stm32_assert.h
View File

@ -1,53 +0,0 @@
/* USER CODE BEGIN Header */
/**
******************************************************************************
* @file stm32_assert.h
* @brief STM32 assert file.
******************************************************************************
* @attention
*
* Copyright (c) 2018 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* USER CODE END Header */
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32_ASSERT_H
#define __STM32_ASSERT_H
#ifdef __cplusplus
extern "C" {
#endif
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/* Includes ------------------------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
#ifdef USE_FULL_ASSERT
/**
* @brief The assert_param macro is used for function's parameters check.
* @param expr: If expr is false, it calls assert_failed function
* which reports the name of the source file and the source
* line number of the call that failed.
* If expr is true, it returns no value.
* @retval None
*/
#define assert_param(expr) ((expr) ? (void)0U : assert_failed((uint8_t *)__FILE__, __LINE__))
/* Exported functions ------------------------------------------------------- */
void assert_failed(uint8_t* file, uint32_t line);
#else
#define assert_param(expr) ((void)0U)
#endif /* USE_FULL_ASSERT */
#ifdef __cplusplus
}
#endif
#endif /* __STM32_ASSERT_H */

391
Core/Inc/stm32f1xx_hal_conf.h Normal file
View File

@ -0,0 +1,391 @@
/* USER CODE BEGIN Header */
/**
******************************************************************************
* @file stm32f1xx_hal_conf.h
* @brief HAL configuration file.
******************************************************************************
* @attention
*
* Copyright (c) 2017 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* USER CODE END Header */
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_CONF_H
#define __STM32F1xx_HAL_CONF_H
#ifdef __cplusplus
extern "C" {
#endif
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/* ########################## Module Selection ############################## */
/**
* @brief This is the list of modules to be used in the HAL driver
*/
#define HAL_MODULE_ENABLED
/*#define HAL_ADC_MODULE_ENABLED */
/*#define HAL_CRYP_MODULE_ENABLED */
/*#define HAL_CAN_MODULE_ENABLED */
/*#define HAL_CAN_LEGACY_MODULE_ENABLED */
/*#define HAL_CEC_MODULE_ENABLED */
/*#define HAL_CORTEX_MODULE_ENABLED */
/*#define HAL_CRC_MODULE_ENABLED */
/*#define HAL_DAC_MODULE_ENABLED */
/*#define HAL_DMA_MODULE_ENABLED */
/*#define HAL_ETH_MODULE_ENABLED */
/*#define HAL_FLASH_MODULE_ENABLED */
#define HAL_GPIO_MODULE_ENABLED
/*#define HAL_I2C_MODULE_ENABLED */
/*#define HAL_I2S_MODULE_ENABLED */
/*#define HAL_IRDA_MODULE_ENABLED */
/*#define HAL_IWDG_MODULE_ENABLED */
/*#define HAL_NOR_MODULE_ENABLED */
/*#define HAL_NAND_MODULE_ENABLED */
/*#define HAL_PCCARD_MODULE_ENABLED */
/*#define HAL_PCD_MODULE_ENABLED */
/*#define HAL_HCD_MODULE_ENABLED */
/*#define HAL_PWR_MODULE_ENABLED */
/*#define HAL_RCC_MODULE_ENABLED */
/*#define HAL_RTC_MODULE_ENABLED */
/*#define HAL_SD_MODULE_ENABLED */
/*#define HAL_MMC_MODULE_ENABLED */
/*#define HAL_SDRAM_MODULE_ENABLED */
/*#define HAL_SMARTCARD_MODULE_ENABLED */
/*#define HAL_SPI_MODULE_ENABLED */
/*#define HAL_SRAM_MODULE_ENABLED */
/*#define HAL_TIM_MODULE_ENABLED */
/*#define HAL_UART_MODULE_ENABLED */
/*#define HAL_USART_MODULE_ENABLED */
/*#define HAL_WWDG_MODULE_ENABLED */
#define HAL_CORTEX_MODULE_ENABLED
#define HAL_DMA_MODULE_ENABLED
#define HAL_FLASH_MODULE_ENABLED
#define HAL_EXTI_MODULE_ENABLED
#define HAL_GPIO_MODULE_ENABLED
#define HAL_PWR_MODULE_ENABLED
#define HAL_RCC_MODULE_ENABLED
/* ########################## Oscillator Values adaptation ####################*/
/**
* @brief Adjust the value of External High Speed oscillator (HSE) used in your application.
* This value is used by the RCC HAL module to compute the system frequency
* (when HSE is used as system clock source, directly or through the PLL).
*/
#if !defined (HSE_VALUE)
#define HSE_VALUE 8000000U /*!< Value of the External oscillator in Hz */
#endif /* HSE_VALUE */
#if !defined (HSE_STARTUP_TIMEOUT)
#define HSE_STARTUP_TIMEOUT 100U /*!< Time out for HSE start up, in ms */
#endif /* HSE_STARTUP_TIMEOUT */
/**
* @brief Internal High Speed oscillator (HSI) value.
* This value is used by the RCC HAL module to compute the system frequency
* (when HSI is used as system clock source, directly or through the PLL).
*/
#if !defined (HSI_VALUE)
#define HSI_VALUE 8000000U /*!< Value of the Internal oscillator in Hz*/
#endif /* HSI_VALUE */
/**
* @brief Internal Low Speed oscillator (LSI) value.
*/
#if !defined (LSI_VALUE)
#define LSI_VALUE 40000U /*!< LSI Typical Value in Hz */
#endif /* LSI_VALUE */ /*!< Value of the Internal Low Speed oscillator in Hz
The real value may vary depending on the variations
in voltage and temperature. */
/**
* @brief External Low Speed oscillator (LSE) value.
* This value is used by the UART, RTC HAL module to compute the system frequency
*/
#if !defined (LSE_VALUE)
#define LSE_VALUE 32768U /*!< Value of the External oscillator in Hz*/
#endif /* LSE_VALUE */
#if !defined (LSE_STARTUP_TIMEOUT)
#define LSE_STARTUP_TIMEOUT 5000U /*!< Time out for LSE start up, in ms */
#endif /* LSE_STARTUP_TIMEOUT */
/* Tip: To avoid modifying this file each time you need to use different HSE,
=== you can define the HSE value in your toolchain compiler preprocessor. */
/* ########################### System Configuration ######################### */
/**
* @brief This is the HAL system configuration section
*/
#define VDD_VALUE 3300U /*!< Value of VDD in mv */
#define TICK_INT_PRIORITY 15U /*!< tick interrupt priority (lowest by default) */
#define USE_RTOS 0U
#define PREFETCH_ENABLE 1U
#define USE_HAL_ADC_REGISTER_CALLBACKS 0U /* ADC register callback disabled */
#define USE_HAL_CAN_REGISTER_CALLBACKS 0U /* CAN register callback disabled */
#define USE_HAL_CEC_REGISTER_CALLBACKS 0U /* CEC register callback disabled */
#define USE_HAL_DAC_REGISTER_CALLBACKS 0U /* DAC register callback disabled */
#define USE_HAL_ETH_REGISTER_CALLBACKS 0U /* ETH register callback disabled */
#define USE_HAL_HCD_REGISTER_CALLBACKS 0U /* HCD register callback disabled */
#define USE_HAL_I2C_REGISTER_CALLBACKS 0U /* I2C register callback disabled */
#define USE_HAL_I2S_REGISTER_CALLBACKS 0U /* I2S register callback disabled */
#define USE_HAL_MMC_REGISTER_CALLBACKS 0U /* MMC register callback disabled */
#define USE_HAL_NAND_REGISTER_CALLBACKS 0U /* NAND register callback disabled */
#define USE_HAL_NOR_REGISTER_CALLBACKS 0U /* NOR register callback disabled */
#define USE_HAL_PCCARD_REGISTER_CALLBACKS 0U /* PCCARD register callback disabled */
#define USE_HAL_PCD_REGISTER_CALLBACKS 0U /* PCD register callback disabled */
#define USE_HAL_RTC_REGISTER_CALLBACKS 0U /* RTC register callback disabled */
#define USE_HAL_SD_REGISTER_CALLBACKS 0U /* SD register callback disabled */
#define USE_HAL_SMARTCARD_REGISTER_CALLBACKS 0U /* SMARTCARD register callback disabled */
#define USE_HAL_IRDA_REGISTER_CALLBACKS 0U /* IRDA register callback disabled */
#define USE_HAL_SRAM_REGISTER_CALLBACKS 0U /* SRAM register callback disabled */
#define USE_HAL_SPI_REGISTER_CALLBACKS 0U /* SPI register callback disabled */
#define USE_HAL_TIM_REGISTER_CALLBACKS 0U /* TIM register callback disabled */
#define USE_HAL_UART_REGISTER_CALLBACKS 0U /* UART register callback disabled */
#define USE_HAL_USART_REGISTER_CALLBACKS 0U /* USART register callback disabled */
#define USE_HAL_WWDG_REGISTER_CALLBACKS 0U /* WWDG register callback disabled */
/* ########################## Assert Selection ############################## */
/**
* @brief Uncomment the line below to expanse the "assert_param" macro in the
* HAL drivers code
*/
/* #define USE_FULL_ASSERT 1U */
/* ################## Ethernet peripheral configuration ##################### */
/* Section 1 : Ethernet peripheral configuration */
/* MAC ADDRESS: MAC_ADDR0:MAC_ADDR1:MAC_ADDR2:MAC_ADDR3:MAC_ADDR4:MAC_ADDR5 */
#define MAC_ADDR0 2U
#define MAC_ADDR1 0U
#define MAC_ADDR2 0U
#define MAC_ADDR3 0U
#define MAC_ADDR4 0U
#define MAC_ADDR5 0U
/* Definition of the Ethernet driver buffers size and count */
#define ETH_RX_BUF_SIZE ETH_MAX_PACKET_SIZE /* buffer size for receive */
#define ETH_TX_BUF_SIZE ETH_MAX_PACKET_SIZE /* buffer size for transmit */
#define ETH_RXBUFNB 8U /* 4 Rx buffers of size ETH_RX_BUF_SIZE */
#define ETH_TXBUFNB 4U /* 4 Tx buffers of size ETH_TX_BUF_SIZE */
/* Section 2: PHY configuration section */
/* DP83848_PHY_ADDRESS Address*/
#define DP83848_PHY_ADDRESS 0x01U
/* PHY Reset delay these values are based on a 1 ms Systick interrupt*/
#define PHY_RESET_DELAY 0x000000FFU
/* PHY Configuration delay */
#define PHY_CONFIG_DELAY 0x00000FFFU
#define PHY_READ_TO 0x0000FFFFU
#define PHY_WRITE_TO 0x0000FFFFU
/* Section 3: Common PHY Registers */
#define PHY_BCR ((uint16_t)0x00) /*!< Transceiver Basic Control Register */
#define PHY_BSR ((uint16_t)0x01) /*!< Transceiver Basic Status Register */
#define PHY_RESET ((uint16_t)0x8000) /*!< PHY Reset */
#define PHY_LOOPBACK ((uint16_t)0x4000) /*!< Select loop-back mode */
#define PHY_FULLDUPLEX_100M ((uint16_t)0x2100) /*!< Set the full-duplex mode at 100 Mb/s */
#define PHY_HALFDUPLEX_100M ((uint16_t)0x2000) /*!< Set the half-duplex mode at 100 Mb/s */
#define PHY_FULLDUPLEX_10M ((uint16_t)0x0100) /*!< Set the full-duplex mode at 10 Mb/s */
#define PHY_HALFDUPLEX_10M ((uint16_t)0x0000) /*!< Set the half-duplex mode at 10 Mb/s */
#define PHY_AUTONEGOTIATION ((uint16_t)0x1000) /*!< Enable auto-negotiation function */
#define PHY_RESTART_AUTONEGOTIATION ((uint16_t)0x0200) /*!< Restart auto-negotiation function */
#define PHY_POWERDOWN ((uint16_t)0x0800) /*!< Select the power down mode */
#define PHY_ISOLATE ((uint16_t)0x0400) /*!< Isolate PHY from MII */
#define PHY_AUTONEGO_COMPLETE ((uint16_t)0x0020) /*!< Auto-Negotiation process completed */
#define PHY_LINKED_STATUS ((uint16_t)0x0004) /*!< Valid link established */
#define PHY_JABBER_DETECTION ((uint16_t)0x0002) /*!< Jabber condition detected */
/* Section 4: Extended PHY Registers */
#define PHY_SR ((uint16_t)0x10U) /*!< PHY status register Offset */
#define PHY_SPEED_STATUS ((uint16_t)0x0002U) /*!< PHY Speed mask */
#define PHY_DUPLEX_STATUS ((uint16_t)0x0004U) /*!< PHY Duplex mask */
/* ################## SPI peripheral configuration ########################## */
/* CRC FEATURE: Use to activate CRC feature inside HAL SPI Driver
* Activated: CRC code is present inside driver
* Deactivated: CRC code cleaned from driver
*/
#define USE_SPI_CRC 0U
/* Includes ------------------------------------------------------------------*/
/**
* @brief Include module's header file
*/
#ifdef HAL_RCC_MODULE_ENABLED
#include "stm32f1xx_hal_rcc.h"
#endif /* HAL_RCC_MODULE_ENABLED */
#ifdef HAL_GPIO_MODULE_ENABLED
#include "stm32f1xx_hal_gpio.h"
#endif /* HAL_GPIO_MODULE_ENABLED */
#ifdef HAL_EXTI_MODULE_ENABLED
#include "stm32f1xx_hal_exti.h"
#endif /* HAL_EXTI_MODULE_ENABLED */
#ifdef HAL_DMA_MODULE_ENABLED
#include "stm32f1xx_hal_dma.h"
#endif /* HAL_DMA_MODULE_ENABLED */
#ifdef HAL_ETH_MODULE_ENABLED
#include "stm32f1xx_hal_eth.h"
#endif /* HAL_ETH_MODULE_ENABLED */
#ifdef HAL_CAN_MODULE_ENABLED
#include "stm32f1xx_hal_can.h"
#endif /* HAL_CAN_MODULE_ENABLED */
#ifdef HAL_CAN_LEGACY_MODULE_ENABLED
#include "Legacy/stm32f1xx_hal_can_legacy.h"
#endif /* HAL_CAN_LEGACY_MODULE_ENABLED */
#ifdef HAL_CEC_MODULE_ENABLED
#include "stm32f1xx_hal_cec.h"
#endif /* HAL_CEC_MODULE_ENABLED */
#ifdef HAL_CORTEX_MODULE_ENABLED
#include "stm32f1xx_hal_cortex.h"
#endif /* HAL_CORTEX_MODULE_ENABLED */
#ifdef HAL_ADC_MODULE_ENABLED
#include "stm32f1xx_hal_adc.h"
#endif /* HAL_ADC_MODULE_ENABLED */
#ifdef HAL_CRC_MODULE_ENABLED
#include "stm32f1xx_hal_crc.h"
#endif /* HAL_CRC_MODULE_ENABLED */
#ifdef HAL_DAC_MODULE_ENABLED
#include "stm32f1xx_hal_dac.h"
#endif /* HAL_DAC_MODULE_ENABLED */
#ifdef HAL_FLASH_MODULE_ENABLED
#include "stm32f1xx_hal_flash.h"
#endif /* HAL_FLASH_MODULE_ENABLED */
#ifdef HAL_SRAM_MODULE_ENABLED
#include "stm32f1xx_hal_sram.h"
#endif /* HAL_SRAM_MODULE_ENABLED */
#ifdef HAL_NOR_MODULE_ENABLED
#include "stm32f1xx_hal_nor.h"
#endif /* HAL_NOR_MODULE_ENABLED */
#ifdef HAL_I2C_MODULE_ENABLED
#include "stm32f1xx_hal_i2c.h"
#endif /* HAL_I2C_MODULE_ENABLED */
#ifdef HAL_I2S_MODULE_ENABLED
#include "stm32f1xx_hal_i2s.h"
#endif /* HAL_I2S_MODULE_ENABLED */
#ifdef HAL_IWDG_MODULE_ENABLED
#include "stm32f1xx_hal_iwdg.h"
#endif /* HAL_IWDG_MODULE_ENABLED */
#ifdef HAL_PWR_MODULE_ENABLED
#include "stm32f1xx_hal_pwr.h"
#endif /* HAL_PWR_MODULE_ENABLED */
#ifdef HAL_RTC_MODULE_ENABLED
#include "stm32f1xx_hal_rtc.h"
#endif /* HAL_RTC_MODULE_ENABLED */
#ifdef HAL_PCCARD_MODULE_ENABLED
#include "stm32f1xx_hal_pccard.h"
#endif /* HAL_PCCARD_MODULE_ENABLED */
#ifdef HAL_SD_MODULE_ENABLED
#include "stm32f1xx_hal_sd.h"
#endif /* HAL_SD_MODULE_ENABLED */
#ifdef HAL_NAND_MODULE_ENABLED
#include "stm32f1xx_hal_nand.h"
#endif /* HAL_NAND_MODULE_ENABLED */
#ifdef HAL_SPI_MODULE_ENABLED
#include "stm32f1xx_hal_spi.h"
#endif /* HAL_SPI_MODULE_ENABLED */
#ifdef HAL_TIM_MODULE_ENABLED
#include "stm32f1xx_hal_tim.h"
#endif /* HAL_TIM_MODULE_ENABLED */
#ifdef HAL_UART_MODULE_ENABLED
#include "stm32f1xx_hal_uart.h"
#endif /* HAL_UART_MODULE_ENABLED */
#ifdef HAL_USART_MODULE_ENABLED
#include "stm32f1xx_hal_usart.h"
#endif /* HAL_USART_MODULE_ENABLED */
#ifdef HAL_IRDA_MODULE_ENABLED
#include "stm32f1xx_hal_irda.h"
#endif /* HAL_IRDA_MODULE_ENABLED */
#ifdef HAL_SMARTCARD_MODULE_ENABLED
#include "stm32f1xx_hal_smartcard.h"
#endif /* HAL_SMARTCARD_MODULE_ENABLED */
#ifdef HAL_WWDG_MODULE_ENABLED
#include "stm32f1xx_hal_wwdg.h"
#endif /* HAL_WWDG_MODULE_ENABLED */
#ifdef HAL_PCD_MODULE_ENABLED
#include "stm32f1xx_hal_pcd.h"
#endif /* HAL_PCD_MODULE_ENABLED */
#ifdef HAL_HCD_MODULE_ENABLED
#include "stm32f1xx_hal_hcd.h"
#endif /* HAL_HCD_MODULE_ENABLED */
#ifdef HAL_MMC_MODULE_ENABLED
#include "stm32f1xx_hal_mmc.h"
#endif /* HAL_MMC_MODULE_ENABLED */
/* Exported macro ------------------------------------------------------------*/
#ifdef USE_FULL_ASSERT
/**
* @brief The assert_param macro is used for function's parameters check.
* @param expr If expr is false, it calls assert_failed function
* which reports the name of the source file and the source
* line number of the call that failed.
* If expr is true, it returns no value.
* @retval None
*/
#define assert_param(expr) ((expr) ? (void)0U : assert_failed((uint8_t *)__FILE__, __LINE__))
/* Exported functions ------------------------------------------------------- */
void assert_failed(uint8_t* file, uint32_t line);
#else
#define assert_param(expr) ((void)0U)
#endif /* USE_FULL_ASSERT */
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_CONF_H */

60
Core/Src/gpio.c
View File

@ -44,42 +44,40 @@
void MX_GPIO_Init(void)
{
LL_GPIO_InitTypeDef GPIO_InitStruct = {0};
GPIO_InitTypeDef GPIO_InitStruct = {0};
/* GPIO Ports Clock Enable */
LL_APB2_GRP1_EnableClock(LL_APB2_GRP1_PERIPH_GPIOC);
LL_APB2_GRP1_EnableClock(LL_APB2_GRP1_PERIPH_GPIOD);
LL_APB2_GRP1_EnableClock(LL_APB2_GRP1_PERIPH_GPIOA);
LL_APB2_GRP1_EnableClock(LL_APB2_GRP1_PERIPH_GPIOB);
__HAL_RCC_GPIOC_CLK_ENABLE();
__HAL_RCC_GPIOD_CLK_ENABLE();
__HAL_RCC_GPIOA_CLK_ENABLE();
__HAL_RCC_GPIOB_CLK_ENABLE();
/**/
GPIO_InitStruct.Pin = LL_GPIO_PIN_13|LL_GPIO_PIN_14|LL_GPIO_PIN_15;
GPIO_InitStruct.Mode = LL_GPIO_MODE_ANALOG;
LL_GPIO_Init(GPIOC, &GPIO_InitStruct);
/*Configure GPIO pins : PC13 PC14 PC15 */
GPIO_InitStruct.Pin = GPIO_PIN_13|GPIO_PIN_14|GPIO_PIN_15;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
HAL_GPIO_Init(GPIOC, &GPIO_InitStruct);
/**/
GPIO_InitStruct.Pin = LL_GPIO_PIN_0|LL_GPIO_PIN_1;
GPIO_InitStruct.Mode = LL_GPIO_MODE_ANALOG;
LL_GPIO_Init(GPIOD, &GPIO_InitStruct);
/*Configure GPIO pins : PA0 PA1 PA2 PA3
PA4 PA5 PA6 PA7
PA8 PA9 PA10 PA11
PA12 PA15 */
GPIO_InitStruct.Pin = GPIO_PIN_0|GPIO_PIN_1|GPIO_PIN_2|GPIO_PIN_3
|GPIO_PIN_4|GPIO_PIN_5|GPIO_PIN_6|GPIO_PIN_7
|GPIO_PIN_8|GPIO_PIN_9|GPIO_PIN_10|GPIO_PIN_11
|GPIO_PIN_12|GPIO_PIN_15;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
HAL_GPIO_Init(GPIOA, &GPIO_InitStruct);
/**/
GPIO_InitStruct.Pin = LL_GPIO_PIN_0|LL_GPIO_PIN_1|LL_GPIO_PIN_2|LL_GPIO_PIN_3
|LL_GPIO_PIN_4|LL_GPIO_PIN_5|LL_GPIO_PIN_6|LL_GPIO_PIN_7
|LL_GPIO_PIN_8|LL_GPIO_PIN_9|LL_GPIO_PIN_10|LL_GPIO_PIN_11
|LL_GPIO_PIN_12|LL_GPIO_PIN_15;
GPIO_InitStruct.Mode = LL_GPIO_MODE_ANALOG;
LL_GPIO_Init(GPIOA, &GPIO_InitStruct);
/**/
GPIO_InitStruct.Pin = LL_GPIO_PIN_0|LL_GPIO_PIN_1|LL_GPIO_PIN_2|LL_GPIO_PIN_10
|LL_GPIO_PIN_11|LL_GPIO_PIN_12|LL_GPIO_PIN_13|LL_GPIO_PIN_14
|LL_GPIO_PIN_15|LL_GPIO_PIN_3|LL_GPIO_PIN_4|LL_GPIO_PIN_5
|LL_GPIO_PIN_6|LL_GPIO_PIN_7|LL_GPIO_PIN_8|LL_GPIO_PIN_9;
GPIO_InitStruct.Mode = LL_GPIO_MODE_ANALOG;
LL_GPIO_Init(GPIOB, &GPIO_InitStruct);
/**/
LL_GPIO_AF_EnableRemap_PD01();
/*Configure GPIO pins : PB0 PB1 PB2 PB10
PB11 PB12 PB13 PB14
PB15 PB3 PB4 PB5
PB6 PB7 PB8 PB9 */
GPIO_InitStruct.Pin = GPIO_PIN_0|GPIO_PIN_1|GPIO_PIN_2|GPIO_PIN_10
|GPIO_PIN_11|GPIO_PIN_12|GPIO_PIN_13|GPIO_PIN_14
|GPIO_PIN_15|GPIO_PIN_3|GPIO_PIN_4|GPIO_PIN_5
|GPIO_PIN_6|GPIO_PIN_7|GPIO_PIN_8|GPIO_PIN_9;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
}

60
Core/Src/main.c
View File

@ -1,7 +1,7 @@
/* USER CODE BEGIN Header */
/**
******************************************************************************
* @file : main.c
* @file main.c
* @brief : Main program body
******************************************************************************
* @attention
@ -70,18 +70,7 @@ int main(void)
/* MCU Configuration--------------------------------------------------------*/
/* Reset of all peripherals, Initializes the Flash interface and the Systick. */
LL_APB2_GRP1_EnableClock(LL_APB2_GRP1_PERIPH_AFIO);
LL_APB1_GRP1_EnableClock(LL_APB1_GRP1_PERIPH_PWR);
/* System interrupt init*/
NVIC_SetPriorityGrouping(NVIC_PRIORITYGROUP_4);
/* SysTick_IRQn interrupt configuration */
NVIC_SetPriority(SysTick_IRQn, NVIC_EncodePriority(NVIC_GetPriorityGrouping(),15, 0));
/** NOJTAG: JTAG-DP Disabled and SW-DP Enabled
*/
LL_GPIO_AF_Remap_SWJ_NOJTAG();
HAL_Init();
/* USER CODE BEGIN Init */
@ -117,30 +106,37 @@ int main(void)
*/
void SystemClock_Config(void)
{
LL_FLASH_SetLatency(LL_FLASH_LATENCY_0);
while(LL_FLASH_GetLatency()!= LL_FLASH_LATENCY_0)
RCC_OscInitTypeDef RCC_OscInitStruct = {0};
RCC_ClkInitTypeDef RCC_ClkInitStruct = {0};
/** Initializes the RCC Oscillators according to the specified parameters
* in the RCC_OscInitTypeDef structure.
*/
RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_HSE;
RCC_OscInitStruct.HSEState = RCC_HSE_ON;
RCC_OscInitStruct.HSEPredivValue = RCC_HSE_PREDIV_DIV1;
RCC_OscInitStruct.HSIState = RCC_HSI_ON;
RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON;
RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSE;
RCC_OscInitStruct.PLL.PLLMUL = RCC_PLL_MUL9;
if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK)
{
Error_Handler();
}
LL_RCC_HSI_SetCalibTrimming(16);
LL_RCC_HSI_Enable();
/* Wait till HSI is ready */
while(LL_RCC_HSI_IsReady() != 1)
/** Initializes the CPU, AHB and APB buses clocks
*/
RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_HCLK|RCC_CLOCKTYPE_SYSCLK
|RCC_CLOCKTYPE_PCLK1|RCC_CLOCKTYPE_PCLK2;
RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK;
RCC_ClkInitStruct.AHBCLKDivider = RCC_SYSCLK_DIV1;
RCC_ClkInitStruct.APB1CLKDivider = RCC_HCLK_DIV2;
RCC_ClkInitStruct.APB2CLKDivider = RCC_HCLK_DIV1;
if (HAL_RCC_ClockConfig(&RCC_ClkInitStruct, FLASH_LATENCY_2) != HAL_OK)
{
Error_Handler();
}
LL_RCC_SetAHBPrescaler(LL_RCC_SYSCLK_DIV_1);
LL_RCC_SetAPB1Prescaler(LL_RCC_APB1_DIV_1);
LL_RCC_SetAPB2Prescaler(LL_RCC_APB2_DIV_1);
LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_HSI);
/* Wait till System clock is ready */
while(LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_HSI)
{
}
LL_Init1msTick(8000000);
LL_SetSystemCoreClock(8000000);
}
/* USER CODE BEGIN 4 */

86
Core/Src/stm32f1xx_hal_msp.c Normal file
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@ -0,0 +1,86 @@
/* USER CODE BEGIN Header */
/**
******************************************************************************
* @file stm32f1xx_hal_msp.c
* @brief This file provides code for the MSP Initialization
* and de-Initialization codes.
******************************************************************************
* @attention
*
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* USER CODE END Header */
/* Includes ------------------------------------------------------------------*/
#include "main.h"
/* USER CODE BEGIN Includes */
/* USER CODE END Includes */
/* Private typedef -----------------------------------------------------------*/
/* USER CODE BEGIN TD */
/* USER CODE END TD */
/* Private define ------------------------------------------------------------*/
/* USER CODE BEGIN Define */
/* USER CODE END Define */
/* Private macro -------------------------------------------------------------*/
/* USER CODE BEGIN Macro */
/* USER CODE END Macro */
/* Private variables ---------------------------------------------------------*/
/* USER CODE BEGIN PV */
/* USER CODE END PV */
/* Private function prototypes -----------------------------------------------*/
/* USER CODE BEGIN PFP */
/* USER CODE END PFP */
/* External functions --------------------------------------------------------*/
/* USER CODE BEGIN ExternalFunctions */
/* USER CODE END ExternalFunctions */
/* USER CODE BEGIN 0 */
/* USER CODE END 0 */
/**
* Initializes the Global MSP.
*/
void HAL_MspInit(void)
{
/* USER CODE BEGIN MspInit 0 */
/* USER CODE END MspInit 0 */
__HAL_RCC_AFIO_CLK_ENABLE();
__HAL_RCC_PWR_CLK_ENABLE();
/* System interrupt init*/
/** NOJTAG: JTAG-DP Disabled and SW-DP Enabled
*/
__HAL_AFIO_REMAP_SWJ_NOJTAG();
/* USER CODE BEGIN MspInit 1 */
/* USER CODE END MspInit 1 */
}
/* USER CODE BEGIN 1 */
/* USER CODE END 1 */

2
Core/Src/stm32f1xx_it.c
View File

@ -185,7 +185,7 @@ void SysTick_Handler(void)
/* USER CODE BEGIN SysTick_IRQn 0 */
/* USER CODE END SysTick_IRQn 0 */
HAL_IncTick();
/* USER CODE BEGIN SysTick_IRQn 1 */
/* USER CODE END SysTick_IRQn 1 */

4334
Drivers/STM32F1xx_HAL_Driver/Inc/Legacy/stm32_hal_legacy.h Normal file
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File diff suppressed because it is too large Load Diff

357
Drivers/STM32F1xx_HAL_Driver/Inc/stm32f1xx_hal.h Normal file
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@ -0,0 +1,357 @@
/**
******************************************************************************
* @file stm32f1xx_hal.h
* @author MCD Application Team
* @brief This file contains all the functions prototypes for the HAL
* module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2017 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_H
#define __STM32F1xx_HAL_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_conf.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup HAL
* @{
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup HAL_Exported_Constants HAL Exported Constants
* @{
*/
/** @defgroup HAL_TICK_FREQ Tick Frequency
* @{
*/
typedef enum
{
HAL_TICK_FREQ_10HZ = 100U,
HAL_TICK_FREQ_100HZ = 10U,
HAL_TICK_FREQ_1KHZ = 1U,
HAL_TICK_FREQ_DEFAULT = HAL_TICK_FREQ_1KHZ
} HAL_TickFreqTypeDef;
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
extern __IO uint32_t uwTick;
extern uint32_t uwTickPrio;
extern HAL_TickFreqTypeDef uwTickFreq;
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup HAL_Exported_Macros HAL Exported Macros
* @{
*/
/** @defgroup DBGMCU_Freeze_Unfreeze Freeze Unfreeze Peripherals in Debug mode
* @brief Freeze/Unfreeze Peripherals in Debug mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @{
*/
/* Peripherals on APB1 */
/**
* @brief TIM2 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM2() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM2_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM2() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM2_STOP)
/**
* @brief TIM3 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM3() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM3_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM3() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM3_STOP)
#if defined (DBGMCU_CR_DBG_TIM4_STOP)
/**
* @brief TIM4 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM4() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM4_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM4() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM4_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM5_STOP)
/**
* @brief TIM5 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM5() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM5_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM5() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM5_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM6_STOP)
/**
* @brief TIM6 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM6() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM6_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM6() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM6_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM7_STOP)
/**
* @brief TIM7 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM7() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM7_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM7() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM7_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM12_STOP)
/**
* @brief TIM12 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM12() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM12_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM12() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM12_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM13_STOP)
/**
* @brief TIM13 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM13() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM13_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM13() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM13_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM14_STOP)
/**
* @brief TIM14 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM14() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM14_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM14() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM14_STOP)
#endif
/**
* @brief WWDG Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_WWDG() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_WWDG_STOP)
#define __HAL_DBGMCU_UNFREEZE_WWDG() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_WWDG_STOP)
/**
* @brief IWDG Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_IWDG() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_IWDG_STOP)
#define __HAL_DBGMCU_UNFREEZE_IWDG() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_IWDG_STOP)
/**
* @brief I2C1 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_I2C1_TIMEOUT() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_I2C1_SMBUS_TIMEOUT)
#define __HAL_DBGMCU_UNFREEZE_I2C1_TIMEOUT() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_I2C1_SMBUS_TIMEOUT)
#if defined (DBGMCU_CR_DBG_I2C2_SMBUS_TIMEOUT)
/**
* @brief I2C2 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_I2C2_TIMEOUT() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_I2C2_SMBUS_TIMEOUT)
#define __HAL_DBGMCU_UNFREEZE_I2C2_TIMEOUT() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_I2C2_SMBUS_TIMEOUT)
#endif
#if defined (DBGMCU_CR_DBG_CAN1_STOP)
/**
* @brief CAN1 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_CAN1() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_CAN1_STOP)
#define __HAL_DBGMCU_UNFREEZE_CAN1() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_CAN1_STOP)
#endif
#if defined (DBGMCU_CR_DBG_CAN2_STOP)
/**
* @brief CAN2 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_CAN2() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_CAN2_STOP)
#define __HAL_DBGMCU_UNFREEZE_CAN2() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_CAN2_STOP)
#endif
/* Peripherals on APB2 */
#if defined (DBGMCU_CR_DBG_TIM1_STOP)
/**
* @brief TIM1 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM1() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM1_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM1() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM1_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM8_STOP)
/**
* @brief TIM8 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM8() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM8_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM8() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM8_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM9_STOP)
/**
* @brief TIM9 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM9() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM9_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM9() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM9_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM10_STOP)
/**
* @brief TIM10 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM10() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM10_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM10() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM10_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM11_STOP)
/**
* @brief TIM11 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM11() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM11_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM11() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM11_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM15_STOP)
/**
* @brief TIM15 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM15() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM15_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM15() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM15_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM16_STOP)
/**
* @brief TIM16 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM16() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM16_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM16() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM16_STOP)
#endif
#if defined (DBGMCU_CR_DBG_TIM17_STOP)
/**
* @brief TIM17 Peripherals Debug mode
*/
#define __HAL_DBGMCU_FREEZE_TIM17() SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM17_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM17() CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_TIM17_STOP)
#endif
/**
* @}
*/
/** @defgroup HAL_Private_Macros HAL Private Macros
* @{
*/
#define IS_TICKFREQ(FREQ) (((FREQ) == HAL_TICK_FREQ_10HZ) || \
((FREQ) == HAL_TICK_FREQ_100HZ) || \
((FREQ) == HAL_TICK_FREQ_1KHZ))
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup HAL_Exported_Functions
* @{
*/
/** @addtogroup HAL_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions ******************************/
HAL_StatusTypeDef HAL_Init(void);
HAL_StatusTypeDef HAL_DeInit(void);
void HAL_MspInit(void);
void HAL_MspDeInit(void);
HAL_StatusTypeDef HAL_InitTick(uint32_t TickPriority);
/**
* @}
*/
/** @addtogroup HAL_Exported_Functions_Group2
* @{
*/
/* Peripheral Control functions ************************************************/
void HAL_IncTick(void);
void HAL_Delay(uint32_t Delay);
uint32_t HAL_GetTick(void);
uint32_t HAL_GetTickPrio(void);
HAL_StatusTypeDef HAL_SetTickFreq(HAL_TickFreqTypeDef Freq);
HAL_TickFreqTypeDef HAL_GetTickFreq(void);
void HAL_SuspendTick(void);
void HAL_ResumeTick(void);
uint32_t HAL_GetHalVersion(void);
uint32_t HAL_GetREVID(void);
uint32_t HAL_GetDEVID(void);
uint32_t HAL_GetUIDw0(void);
uint32_t HAL_GetUIDw1(void);
uint32_t HAL_GetUIDw2(void);
void HAL_DBGMCU_EnableDBGSleepMode(void);
void HAL_DBGMCU_DisableDBGSleepMode(void);
void HAL_DBGMCU_EnableDBGStopMode(void);
void HAL_DBGMCU_DisableDBGStopMode(void);
void HAL_DBGMCU_EnableDBGStandbyMode(void);
void HAL_DBGMCU_DisableDBGStandbyMode(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup HAL_Private_Variables HAL Private Variables
* @{
*/
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup HAL_Private_Constants HAL Private Constants
* @{
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_H */

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Drivers/STM32F1xx_HAL_Driver/Inc/stm32f1xx_hal_cortex.h Normal file
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@ -0,0 +1,408 @@
/**
******************************************************************************
* @file stm32f1xx_hal_cortex.h
* @author MCD Application Team
* @brief Header file of CORTEX HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2017 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_CORTEX_H
#define __STM32F1xx_HAL_CORTEX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup CORTEX
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Types Cortex Exported Types
* @{
*/
#if (__MPU_PRESENT == 1U)
/** @defgroup CORTEX_MPU_Region_Initialization_Structure_definition MPU Region Initialization Structure Definition
* @brief MPU Region initialization structure
* @{
*/
typedef struct
{
uint8_t Enable; /*!< Specifies the status of the region.
This parameter can be a value of @ref CORTEX_MPU_Region_Enable */
uint8_t Number; /*!< Specifies the number of the region to protect.
This parameter can be a value of @ref CORTEX_MPU_Region_Number */
uint32_t BaseAddress; /*!< Specifies the base address of the region to protect. */
uint8_t Size; /*!< Specifies the size of the region to protect.
This parameter can be a value of @ref CORTEX_MPU_Region_Size */
uint8_t SubRegionDisable; /*!< Specifies the number of the subregion protection to disable.
This parameter must be a number between Min_Data = 0x00 and Max_Data = 0xFF */
uint8_t TypeExtField; /*!< Specifies the TEX field level.
This parameter can be a value of @ref CORTEX_MPU_TEX_Levels */
uint8_t AccessPermission; /*!< Specifies the region access permission type.
This parameter can be a value of @ref CORTEX_MPU_Region_Permission_Attributes */
uint8_t DisableExec; /*!< Specifies the instruction access status.
This parameter can be a value of @ref CORTEX_MPU_Instruction_Access */
uint8_t IsShareable; /*!< Specifies the shareability status of the protected region.
This parameter can be a value of @ref CORTEX_MPU_Access_Shareable */
uint8_t IsCacheable; /*!< Specifies the cacheable status of the region protected.
This parameter can be a value of @ref CORTEX_MPU_Access_Cacheable */
uint8_t IsBufferable; /*!< Specifies the bufferable status of the protected region.
This parameter can be a value of @ref CORTEX_MPU_Access_Bufferable */
}MPU_Region_InitTypeDef;
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Constants CORTEX Exported Constants
* @{
*/
/** @defgroup CORTEX_Preemption_Priority_Group CORTEX Preemption Priority Group
* @{
*/
#define NVIC_PRIORITYGROUP_0 0x00000007U /*!< 0 bits for pre-emption priority
4 bits for subpriority */
#define NVIC_PRIORITYGROUP_1 0x00000006U /*!< 1 bits for pre-emption priority
3 bits for subpriority */
#define NVIC_PRIORITYGROUP_2 0x00000005U /*!< 2 bits for pre-emption priority
2 bits for subpriority */
#define NVIC_PRIORITYGROUP_3 0x00000004U /*!< 3 bits for pre-emption priority
1 bits for subpriority */
#define NVIC_PRIORITYGROUP_4 0x00000003U /*!< 4 bits for pre-emption priority
0 bits for subpriority */
/**
* @}
*/
/** @defgroup CORTEX_SysTick_clock_source CORTEX _SysTick clock source
* @{
*/
#define SYSTICK_CLKSOURCE_HCLK_DIV8 0x00000000U
#define SYSTICK_CLKSOURCE_HCLK 0x00000004U
/**
* @}
*/
#if (__MPU_PRESENT == 1)
/** @defgroup CORTEX_MPU_HFNMI_PRIVDEF_Control MPU HFNMI and PRIVILEGED Access control
* @{
*/
#define MPU_HFNMI_PRIVDEF_NONE 0x00000000U
#define MPU_HARDFAULT_NMI MPU_CTRL_HFNMIENA_Msk
#define MPU_PRIVILEGED_DEFAULT MPU_CTRL_PRIVDEFENA_Msk
#define MPU_HFNMI_PRIVDEF (MPU_CTRL_HFNMIENA_Msk | MPU_CTRL_PRIVDEFENA_Msk)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Enable CORTEX MPU Region Enable
* @{
*/
#define MPU_REGION_ENABLE ((uint8_t)0x01)
#define MPU_REGION_DISABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Instruction_Access CORTEX MPU Instruction Access
* @{
*/
#define MPU_INSTRUCTION_ACCESS_ENABLE ((uint8_t)0x00)
#define MPU_INSTRUCTION_ACCESS_DISABLE ((uint8_t)0x01)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Shareable CORTEX MPU Instruction Access Shareable
* @{
*/
#define MPU_ACCESS_SHAREABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_SHAREABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Cacheable CORTEX MPU Instruction Access Cacheable
* @{
*/
#define MPU_ACCESS_CACHEABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_CACHEABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Bufferable CORTEX MPU Instruction Access Bufferable
* @{
*/
#define MPU_ACCESS_BUFFERABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_BUFFERABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_TEX_Levels MPU TEX Levels
* @{
*/
#define MPU_TEX_LEVEL0 ((uint8_t)0x00)
#define MPU_TEX_LEVEL1 ((uint8_t)0x01)
#define MPU_TEX_LEVEL2 ((uint8_t)0x02)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Size CORTEX MPU Region Size
* @{
*/
#define MPU_REGION_SIZE_32B ((uint8_t)0x04)
#define MPU_REGION_SIZE_64B ((uint8_t)0x05)
#define MPU_REGION_SIZE_128B ((uint8_t)0x06)
#define MPU_REGION_SIZE_256B ((uint8_t)0x07)
#define MPU_REGION_SIZE_512B ((uint8_t)0x08)
#define MPU_REGION_SIZE_1KB ((uint8_t)0x09)
#define MPU_REGION_SIZE_2KB ((uint8_t)0x0A)
#define MPU_REGION_SIZE_4KB ((uint8_t)0x0B)
#define MPU_REGION_SIZE_8KB ((uint8_t)0x0C)
#define MPU_REGION_SIZE_16KB ((uint8_t)0x0D)
#define MPU_REGION_SIZE_32KB ((uint8_t)0x0E)
#define MPU_REGION_SIZE_64KB ((uint8_t)0x0F)
#define MPU_REGION_SIZE_128KB ((uint8_t)0x10)
#define MPU_REGION_SIZE_256KB ((uint8_t)0x11)
#define MPU_REGION_SIZE_512KB ((uint8_t)0x12)
#define MPU_REGION_SIZE_1MB ((uint8_t)0x13)
#define MPU_REGION_SIZE_2MB ((uint8_t)0x14)
#define MPU_REGION_SIZE_4MB ((uint8_t)0x15)
#define MPU_REGION_SIZE_8MB ((uint8_t)0x16)
#define MPU_REGION_SIZE_16MB ((uint8_t)0x17)
#define MPU_REGION_SIZE_32MB ((uint8_t)0x18)
#define MPU_REGION_SIZE_64MB ((uint8_t)0x19)
#define MPU_REGION_SIZE_128MB ((uint8_t)0x1A)
#define MPU_REGION_SIZE_256MB ((uint8_t)0x1B)
#define MPU_REGION_SIZE_512MB ((uint8_t)0x1C)
#define MPU_REGION_SIZE_1GB ((uint8_t)0x1D)
#define MPU_REGION_SIZE_2GB ((uint8_t)0x1E)
#define MPU_REGION_SIZE_4GB ((uint8_t)0x1F)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Permission_Attributes CORTEX MPU Region Permission Attributes
* @{
*/
#define MPU_REGION_NO_ACCESS ((uint8_t)0x00)
#define MPU_REGION_PRIV_RW ((uint8_t)0x01)
#define MPU_REGION_PRIV_RW_URO ((uint8_t)0x02)
#define MPU_REGION_FULL_ACCESS ((uint8_t)0x03)
#define MPU_REGION_PRIV_RO ((uint8_t)0x05)
#define MPU_REGION_PRIV_RO_URO ((uint8_t)0x06)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Number CORTEX MPU Region Number
* @{
*/
#define MPU_REGION_NUMBER0 ((uint8_t)0x00)
#define MPU_REGION_NUMBER1 ((uint8_t)0x01)
#define MPU_REGION_NUMBER2 ((uint8_t)0x02)
#define MPU_REGION_NUMBER3 ((uint8_t)0x03)
#define MPU_REGION_NUMBER4 ((uint8_t)0x04)
#define MPU_REGION_NUMBER5 ((uint8_t)0x05)
#define MPU_REGION_NUMBER6 ((uint8_t)0x06)
#define MPU_REGION_NUMBER7 ((uint8_t)0x07)
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Exported Macros -----------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup CORTEX_Exported_Functions
* @{
*/
/** @addtogroup CORTEX_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions *****************************/
void HAL_NVIC_SetPriorityGrouping(uint32_t PriorityGroup);
void HAL_NVIC_SetPriority(IRQn_Type IRQn, uint32_t PreemptPriority, uint32_t SubPriority);
void HAL_NVIC_EnableIRQ(IRQn_Type IRQn);
void HAL_NVIC_DisableIRQ(IRQn_Type IRQn);
void HAL_NVIC_SystemReset(void);
uint32_t HAL_SYSTICK_Config(uint32_t TicksNumb);
/**
* @}
*/
/** @addtogroup CORTEX_Exported_Functions_Group2
* @{
*/
/* Peripheral Control functions ***********************************************/
uint32_t HAL_NVIC_GetPriorityGrouping(void);
void HAL_NVIC_GetPriority(IRQn_Type IRQn, uint32_t PriorityGroup, uint32_t* pPreemptPriority, uint32_t* pSubPriority);
uint32_t HAL_NVIC_GetPendingIRQ(IRQn_Type IRQn);
void HAL_NVIC_SetPendingIRQ(IRQn_Type IRQn);
void HAL_NVIC_ClearPendingIRQ(IRQn_Type IRQn);
uint32_t HAL_NVIC_GetActive(IRQn_Type IRQn);
void HAL_SYSTICK_CLKSourceConfig(uint32_t CLKSource);
void HAL_SYSTICK_IRQHandler(void);
void HAL_SYSTICK_Callback(void);
#if (__MPU_PRESENT == 1U)
void HAL_MPU_Enable(uint32_t MPU_Control);
void HAL_MPU_Disable(void);
void HAL_MPU_ConfigRegion(MPU_Region_InitTypeDef *MPU_Init);
#endif /* __MPU_PRESENT */
/**
* @}
*/
/**
* @}
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup CORTEX_Private_Macros CORTEX Private Macros
* @{
*/
#define IS_NVIC_PRIORITY_GROUP(GROUP) (((GROUP) == NVIC_PRIORITYGROUP_0) || \
((GROUP) == NVIC_PRIORITYGROUP_1) || \
((GROUP) == NVIC_PRIORITYGROUP_2) || \
((GROUP) == NVIC_PRIORITYGROUP_3) || \
((GROUP) == NVIC_PRIORITYGROUP_4))
#define IS_NVIC_PREEMPTION_PRIORITY(PRIORITY) ((PRIORITY) < 0x10U)
#define IS_NVIC_SUB_PRIORITY(PRIORITY) ((PRIORITY) < 0x10U)
#define IS_NVIC_DEVICE_IRQ(IRQ) ((IRQ) >= (IRQn_Type)0x00U)
#define IS_SYSTICK_CLK_SOURCE(SOURCE) (((SOURCE) == SYSTICK_CLKSOURCE_HCLK) || \
((SOURCE) == SYSTICK_CLKSOURCE_HCLK_DIV8))
#if (__MPU_PRESENT == 1U)
#define IS_MPU_REGION_ENABLE(STATE) (((STATE) == MPU_REGION_ENABLE) || \
((STATE) == MPU_REGION_DISABLE))
#define IS_MPU_INSTRUCTION_ACCESS(STATE) (((STATE) == MPU_INSTRUCTION_ACCESS_ENABLE) || \
((STATE) == MPU_INSTRUCTION_ACCESS_DISABLE))
#define IS_MPU_ACCESS_SHAREABLE(STATE) (((STATE) == MPU_ACCESS_SHAREABLE) || \
((STATE) == MPU_ACCESS_NOT_SHAREABLE))
#define IS_MPU_ACCESS_CACHEABLE(STATE) (((STATE) == MPU_ACCESS_CACHEABLE) || \
((STATE) == MPU_ACCESS_NOT_CACHEABLE))
#define IS_MPU_ACCESS_BUFFERABLE(STATE) (((STATE) == MPU_ACCESS_BUFFERABLE) || \
((STATE) == MPU_ACCESS_NOT_BUFFERABLE))
#define IS_MPU_TEX_LEVEL(TYPE) (((TYPE) == MPU_TEX_LEVEL0) || \
((TYPE) == MPU_TEX_LEVEL1) || \
((TYPE) == MPU_TEX_LEVEL2))
#define IS_MPU_REGION_PERMISSION_ATTRIBUTE(TYPE) (((TYPE) == MPU_REGION_NO_ACCESS) || \
((TYPE) == MPU_REGION_PRIV_RW) || \
((TYPE) == MPU_REGION_PRIV_RW_URO) || \
((TYPE) == MPU_REGION_FULL_ACCESS) || \
((TYPE) == MPU_REGION_PRIV_RO) || \
((TYPE) == MPU_REGION_PRIV_RO_URO))
#define IS_MPU_REGION_NUMBER(NUMBER) (((NUMBER) == MPU_REGION_NUMBER0) || \
((NUMBER) == MPU_REGION_NUMBER1) || \
((NUMBER) == MPU_REGION_NUMBER2) || \
((NUMBER) == MPU_REGION_NUMBER3) || \
((NUMBER) == MPU_REGION_NUMBER4) || \
((NUMBER) == MPU_REGION_NUMBER5) || \
((NUMBER) == MPU_REGION_NUMBER6) || \
((NUMBER) == MPU_REGION_NUMBER7))
#define IS_MPU_REGION_SIZE(SIZE) (((SIZE) == MPU_REGION_SIZE_32B) || \
((SIZE) == MPU_REGION_SIZE_64B) || \
((SIZE) == MPU_REGION_SIZE_128B) || \
((SIZE) == MPU_REGION_SIZE_256B) || \
((SIZE) == MPU_REGION_SIZE_512B) || \
((SIZE) == MPU_REGION_SIZE_1KB) || \
((SIZE) == MPU_REGION_SIZE_2KB) || \
((SIZE) == MPU_REGION_SIZE_4KB) || \
((SIZE) == MPU_REGION_SIZE_8KB) || \
((SIZE) == MPU_REGION_SIZE_16KB) || \
((SIZE) == MPU_REGION_SIZE_32KB) || \
((SIZE) == MPU_REGION_SIZE_64KB) || \
((SIZE) == MPU_REGION_SIZE_128KB) || \
((SIZE) == MPU_REGION_SIZE_256KB) || \
((SIZE) == MPU_REGION_SIZE_512KB) || \
((SIZE) == MPU_REGION_SIZE_1MB) || \
((SIZE) == MPU_REGION_SIZE_2MB) || \
((SIZE) == MPU_REGION_SIZE_4MB) || \
((SIZE) == MPU_REGION_SIZE_8MB) || \
((SIZE) == MPU_REGION_SIZE_16MB) || \
((SIZE) == MPU_REGION_SIZE_32MB) || \
((SIZE) == MPU_REGION_SIZE_64MB) || \
((SIZE) == MPU_REGION_SIZE_128MB) || \
((SIZE) == MPU_REGION_SIZE_256MB) || \
((SIZE) == MPU_REGION_SIZE_512MB) || \
((SIZE) == MPU_REGION_SIZE_1GB) || \
((SIZE) == MPU_REGION_SIZE_2GB) || \
((SIZE) == MPU_REGION_SIZE_4GB))
#define IS_MPU_SUB_REGION_DISABLE(SUBREGION) ((SUBREGION) < (uint16_t)0x00FF)
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_CORTEX_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_def.h
* @author MCD Application Team
* @brief This file contains HAL common defines, enumeration, macros and
* structures definitions.
******************************************************************************
* @attention
*
* Copyright (c) 2017 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_DEF
#define __STM32F1xx_HAL_DEF
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx.h"
#include "Legacy/stm32_hal_legacy.h"
#include <stddef.h>
/* Exported types ------------------------------------------------------------*/
/**
* @brief HAL Status structures definition
*/
typedef enum
{
HAL_OK = 0x00U,
HAL_ERROR = 0x01U,
HAL_BUSY = 0x02U,
HAL_TIMEOUT = 0x03U
} HAL_StatusTypeDef;
/**
* @brief HAL Lock structures definition
*/
typedef enum
{
HAL_UNLOCKED = 0x00U,
HAL_LOCKED = 0x01U
} HAL_LockTypeDef;
/* Exported macro ------------------------------------------------------------*/
#define HAL_MAX_DELAY 0xFFFFFFFFU
#define HAL_IS_BIT_SET(REG, BIT) (((REG) & (BIT)) != 0U)
#define HAL_IS_BIT_CLR(REG, BIT) (((REG) & (BIT)) == 0U)
#define __HAL_LINKDMA(__HANDLE__, __PPP_DMA_FIELD__, __DMA_HANDLE__) \
do{ \
(__HANDLE__)->__PPP_DMA_FIELD__ = &(__DMA_HANDLE__); \
(__DMA_HANDLE__).Parent = (__HANDLE__); \
} while(0U)
#if !defined(UNUSED)
#define UNUSED(X) (void)X /* To avoid gcc/g++ warnings */
#endif /* UNUSED */
/** @brief Reset the Handle's State field.
* @param __HANDLE__ specifies the Peripheral Handle.
* @note This macro can be used for the following purpose:
* - When the Handle is declared as local variable; before passing it as parameter
* to HAL_PPP_Init() for the first time, it is mandatory to use this macro
* to set to 0 the Handle's "State" field.
* Otherwise, "State" field may have any random value and the first time the function
* HAL_PPP_Init() is called, the low level hardware initialization will be missed
* (i.e. HAL_PPP_MspInit() will not be executed).
* - When there is a need to reconfigure the low level hardware: instead of calling
* HAL_PPP_DeInit() then HAL_PPP_Init(), user can make a call to this macro then HAL_PPP_Init().
* In this later function, when the Handle's "State" field is set to 0, it will execute the function
* HAL_PPP_MspInit() which will reconfigure the low level hardware.
* @retval None
*/
#define __HAL_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = 0U)
#if (USE_RTOS == 1U)
/* Reserved for future use */
#error "USE_RTOS should be 0 in the current HAL release"
#else
#define __HAL_LOCK(__HANDLE__) \
do{ \
if((__HANDLE__)->Lock == HAL_LOCKED) \
{ \
return HAL_BUSY; \
} \
else \
{ \
(__HANDLE__)->Lock = HAL_LOCKED; \
} \
}while (0U)
#define __HAL_UNLOCK(__HANDLE__) \
do{ \
(__HANDLE__)->Lock = HAL_UNLOCKED; \
}while (0U)
#endif /* USE_RTOS */
#if defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050) /* ARM Compiler V6 */
#ifndef __weak
#define __weak __attribute__((weak))
#endif
#ifndef __packed
#define __packed __attribute__((packed))
#endif
#elif defined ( __GNUC__ ) && !defined (__CC_ARM) /* GNU Compiler */
#ifndef __weak
#define __weak __attribute__((weak))
#endif /* __weak */
#ifndef __packed
#define __packed __attribute__((__packed__))
#endif /* __packed */
#endif /* __GNUC__ */
/* Macro to get variable aligned on 4-bytes, for __ICCARM__ the directive "#pragma data_alignment=4" must be used instead */
#if defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050) /* ARM Compiler V6 */
#ifndef __ALIGN_BEGIN
#define __ALIGN_BEGIN
#endif
#ifndef __ALIGN_END
#define __ALIGN_END __attribute__ ((aligned (4)))
#endif
#elif defined ( __GNUC__ ) && !defined (__CC_ARM) /* GNU Compiler */
#ifndef __ALIGN_END
#define __ALIGN_END __attribute__ ((aligned (4)))
#endif /* __ALIGN_END */
#ifndef __ALIGN_BEGIN
#define __ALIGN_BEGIN
#endif /* __ALIGN_BEGIN */
#else
#ifndef __ALIGN_END
#define __ALIGN_END
#endif /* __ALIGN_END */
#ifndef __ALIGN_BEGIN
#if defined (__CC_ARM) /* ARM Compiler V5*/
#define __ALIGN_BEGIN __align(4)
#elif defined (__ICCARM__) /* IAR Compiler */
#define __ALIGN_BEGIN
#endif /* __CC_ARM */
#endif /* __ALIGN_BEGIN */
#endif /* __GNUC__ */
/**
* @brief __RAM_FUNC definition
*/
#if defined ( __CC_ARM ) || (defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050))
/* ARM Compiler V4/V5 and V6
--------------------------
RAM functions are defined using the toolchain options.
Functions that are executed in RAM should reside in a separate source module.
Using the 'Options for File' dialog you can simply change the 'Code / Const'
area of a module to a memory space in physical RAM.
Available memory areas are declared in the 'Target' tab of the 'Options for Target'
dialog.
*/
#define __RAM_FUNC
#elif defined ( __ICCARM__ )
/* ICCARM Compiler
---------------
RAM functions are defined using a specific toolchain keyword "__ramfunc".
*/
#define __RAM_FUNC __ramfunc
#elif defined ( __GNUC__ )
/* GNU Compiler
------------
RAM functions are defined using a specific toolchain attribute
"__attribute__((section(".RamFunc")))".
*/
#define __RAM_FUNC __attribute__((section(".RamFunc")))
#endif
/**
* @brief __NOINLINE definition
*/
#if defined ( __CC_ARM ) || (defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)) || defined ( __GNUC__ )
/* ARM V4/V5 and V6 & GNU Compiler
-------------------------------
*/
#define __NOINLINE __attribute__ ( (noinline) )
#elif defined ( __ICCARM__ )
/* ICCARM Compiler
---------------
*/
#define __NOINLINE _Pragma("optimize = no_inline")
#endif
#ifdef __cplusplus
}
#endif
#endif /* ___STM32F1xx_HAL_DEF */

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/**
******************************************************************************
* @file stm32f1xx_hal_dma.h
* @author MCD Application Team
* @brief Header file of DMA HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_DMA_H
#define __STM32F1xx_HAL_DMA_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup DMA
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup DMA_Exported_Types DMA Exported Types
* @{
*/
/**
* @brief DMA Configuration Structure definition
*/
typedef struct
{
uint32_t Direction; /*!< Specifies if the data will be transferred from memory to peripheral,
from memory to memory or from peripheral to memory.
This parameter can be a value of @ref DMA_Data_transfer_direction */
uint32_t PeriphInc; /*!< Specifies whether the Peripheral address register should be incremented or not.
This parameter can be a value of @ref DMA_Peripheral_incremented_mode */
uint32_t MemInc; /*!< Specifies whether the memory address register should be incremented or not.
This parameter can be a value of @ref DMA_Memory_incremented_mode */
uint32_t PeriphDataAlignment; /*!< Specifies the Peripheral data width.
This parameter can be a value of @ref DMA_Peripheral_data_size */
uint32_t MemDataAlignment; /*!< Specifies the Memory data width.
This parameter can be a value of @ref DMA_Memory_data_size */
uint32_t Mode; /*!< Specifies the operation mode of the DMAy Channelx.
This parameter can be a value of @ref DMA_mode
@note The circular buffer mode cannot be used if the memory-to-memory
data transfer is configured on the selected Channel */
uint32_t Priority; /*!< Specifies the software priority for the DMAy Channelx.
This parameter can be a value of @ref DMA_Priority_level */
} DMA_InitTypeDef;
/**
* @brief HAL DMA State structures definition
*/
typedef enum
{
HAL_DMA_STATE_RESET = 0x00U, /*!< DMA not yet initialized or disabled */
HAL_DMA_STATE_READY = 0x01U, /*!< DMA initialized and ready for use */
HAL_DMA_STATE_BUSY = 0x02U, /*!< DMA process is ongoing */
HAL_DMA_STATE_TIMEOUT = 0x03U /*!< DMA timeout state */
}HAL_DMA_StateTypeDef;
/**
* @brief HAL DMA Error Code structure definition
*/
typedef enum
{
HAL_DMA_FULL_TRANSFER = 0x00U, /*!< Full transfer */
HAL_DMA_HALF_TRANSFER = 0x01U /*!< Half Transfer */
}HAL_DMA_LevelCompleteTypeDef;
/**
* @brief HAL DMA Callback ID structure definition
*/
typedef enum
{
HAL_DMA_XFER_CPLT_CB_ID = 0x00U, /*!< Full transfer */
HAL_DMA_XFER_HALFCPLT_CB_ID = 0x01U, /*!< Half transfer */
HAL_DMA_XFER_ERROR_CB_ID = 0x02U, /*!< Error */
HAL_DMA_XFER_ABORT_CB_ID = 0x03U, /*!< Abort */
HAL_DMA_XFER_ALL_CB_ID = 0x04U /*!< All */
}HAL_DMA_CallbackIDTypeDef;
/**
* @brief DMA handle Structure definition
*/
typedef struct __DMA_HandleTypeDef
{
DMA_Channel_TypeDef *Instance; /*!< Register base address */
DMA_InitTypeDef Init; /*!< DMA communication parameters */
HAL_LockTypeDef Lock; /*!< DMA locking object */
__IO HAL_DMA_StateTypeDef State; /*!< DMA transfer state */
void *Parent; /*!< Parent object state */
void (* XferCpltCallback)( struct __DMA_HandleTypeDef * hdma); /*!< DMA transfer complete callback */
void (* XferHalfCpltCallback)( struct __DMA_HandleTypeDef * hdma); /*!< DMA Half transfer complete callback */
void (* XferErrorCallback)( struct __DMA_HandleTypeDef * hdma); /*!< DMA transfer error callback */
void (* XferAbortCallback)( struct __DMA_HandleTypeDef * hdma); /*!< DMA transfer abort callback */
__IO uint32_t ErrorCode; /*!< DMA Error code */
DMA_TypeDef *DmaBaseAddress; /*!< DMA Channel Base Address */
uint32_t ChannelIndex; /*!< DMA Channel Index */
} DMA_HandleTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup DMA_Exported_Constants DMA Exported Constants
* @{
*/
/** @defgroup DMA_Error_Code DMA Error Code
* @{
*/
#define HAL_DMA_ERROR_NONE 0x00000000U /*!< No error */
#define HAL_DMA_ERROR_TE 0x00000001U /*!< Transfer error */
#define HAL_DMA_ERROR_NO_XFER 0x00000004U /*!< no ongoing transfer */
#define HAL_DMA_ERROR_TIMEOUT 0x00000020U /*!< Timeout error */
#define HAL_DMA_ERROR_NOT_SUPPORTED 0x00000100U /*!< Not supported mode */
/**
* @}
*/
/** @defgroup DMA_Data_transfer_direction DMA Data transfer direction
* @{
*/
#define DMA_PERIPH_TO_MEMORY 0x00000000U /*!< Peripheral to memory direction */
#define DMA_MEMORY_TO_PERIPH ((uint32_t)DMA_CCR_DIR) /*!< Memory to peripheral direction */
#define DMA_MEMORY_TO_MEMORY ((uint32_t)DMA_CCR_MEM2MEM) /*!< Memory to memory direction */
/**
* @}
*/
/** @defgroup DMA_Peripheral_incremented_mode DMA Peripheral incremented mode
* @{
*/
#define DMA_PINC_ENABLE ((uint32_t)DMA_CCR_PINC) /*!< Peripheral increment mode Enable */
#define DMA_PINC_DISABLE 0x00000000U /*!< Peripheral increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_Memory_incremented_mode DMA Memory incremented mode
* @{
*/
#define DMA_MINC_ENABLE ((uint32_t)DMA_CCR_MINC) /*!< Memory increment mode Enable */
#define DMA_MINC_DISABLE 0x00000000U /*!< Memory increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_Peripheral_data_size DMA Peripheral data size
* @{
*/
#define DMA_PDATAALIGN_BYTE 0x00000000U /*!< Peripheral data alignment: Byte */
#define DMA_PDATAALIGN_HALFWORD ((uint32_t)DMA_CCR_PSIZE_0) /*!< Peripheral data alignment: HalfWord */
#define DMA_PDATAALIGN_WORD ((uint32_t)DMA_CCR_PSIZE_1) /*!< Peripheral data alignment: Word */
/**
* @}
*/
/** @defgroup DMA_Memory_data_size DMA Memory data size
* @{
*/
#define DMA_MDATAALIGN_BYTE 0x00000000U /*!< Memory data alignment: Byte */
#define DMA_MDATAALIGN_HALFWORD ((uint32_t)DMA_CCR_MSIZE_0) /*!< Memory data alignment: HalfWord */
#define DMA_MDATAALIGN_WORD ((uint32_t)DMA_CCR_MSIZE_1) /*!< Memory data alignment: Word */
/**
* @}
*/
/** @defgroup DMA_mode DMA mode
* @{
*/
#define DMA_NORMAL 0x00000000U /*!< Normal mode */
#define DMA_CIRCULAR ((uint32_t)DMA_CCR_CIRC) /*!< Circular mode */
/**
* @}
*/
/** @defgroup DMA_Priority_level DMA Priority level
* @{
*/
#define DMA_PRIORITY_LOW 0x00000000U /*!< Priority level : Low */
#define DMA_PRIORITY_MEDIUM ((uint32_t)DMA_CCR_PL_0) /*!< Priority level : Medium */
#define DMA_PRIORITY_HIGH ((uint32_t)DMA_CCR_PL_1) /*!< Priority level : High */
#define DMA_PRIORITY_VERY_HIGH ((uint32_t)DMA_CCR_PL) /*!< Priority level : Very_High */
/**
* @}
*/
/** @defgroup DMA_interrupt_enable_definitions DMA interrupt enable definitions
* @{
*/
#define DMA_IT_TC ((uint32_t)DMA_CCR_TCIE)
#define DMA_IT_HT ((uint32_t)DMA_CCR_HTIE)
#define DMA_IT_TE ((uint32_t)DMA_CCR_TEIE)
/**
* @}
*/
/** @defgroup DMA_flag_definitions DMA flag definitions
* @{
*/
#define DMA_FLAG_GL1 0x00000001U
#define DMA_FLAG_TC1 0x00000002U
#define DMA_FLAG_HT1 0x00000004U
#define DMA_FLAG_TE1 0x00000008U
#define DMA_FLAG_GL2 0x00000010U
#define DMA_FLAG_TC2 0x00000020U
#define DMA_FLAG_HT2 0x00000040U
#define DMA_FLAG_TE2 0x00000080U
#define DMA_FLAG_GL3 0x00000100U
#define DMA_FLAG_TC3 0x00000200U
#define DMA_FLAG_HT3 0x00000400U
#define DMA_FLAG_TE3 0x00000800U
#define DMA_FLAG_GL4 0x00001000U
#define DMA_FLAG_TC4 0x00002000U
#define DMA_FLAG_HT4 0x00004000U
#define DMA_FLAG_TE4 0x00008000U
#define DMA_FLAG_GL5 0x00010000U
#define DMA_FLAG_TC5 0x00020000U
#define DMA_FLAG_HT5 0x00040000U
#define DMA_FLAG_TE5 0x00080000U
#define DMA_FLAG_GL6 0x00100000U
#define DMA_FLAG_TC6 0x00200000U
#define DMA_FLAG_HT6 0x00400000U
#define DMA_FLAG_TE6 0x00800000U
#define DMA_FLAG_GL7 0x01000000U
#define DMA_FLAG_TC7 0x02000000U
#define DMA_FLAG_HT7 0x04000000U
#define DMA_FLAG_TE7 0x08000000U
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup DMA_Exported_Macros DMA Exported Macros
* @{
*/
/** @brief Reset DMA handle state.
* @param __HANDLE__: DMA handle
* @retval None
*/
#define __HAL_DMA_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = HAL_DMA_STATE_RESET)
/**
* @brief Enable the specified DMA Channel.
* @param __HANDLE__: DMA handle
* @retval None
*/
#define __HAL_DMA_ENABLE(__HANDLE__) (SET_BIT((__HANDLE__)->Instance->CCR, DMA_CCR_EN))
/**
* @brief Disable the specified DMA Channel.
* @param __HANDLE__: DMA handle
* @retval None
*/
#define __HAL_DMA_DISABLE(__HANDLE__) (CLEAR_BIT((__HANDLE__)->Instance->CCR, DMA_CCR_EN))
/* Interrupt & Flag management */
/**
* @brief Enables the specified DMA Channel interrupts.
* @param __HANDLE__: DMA handle
* @param __INTERRUPT__: specifies the DMA interrupt sources to be enabled or disabled.
* This parameter can be any combination of the following values:
* @arg DMA_IT_TC: Transfer complete interrupt mask
* @arg DMA_IT_HT: Half transfer complete interrupt mask
* @arg DMA_IT_TE: Transfer error interrupt mask
* @retval None
*/
#define __HAL_DMA_ENABLE_IT(__HANDLE__, __INTERRUPT__) (SET_BIT((__HANDLE__)->Instance->CCR, (__INTERRUPT__)))
/**
* @brief Disable the specified DMA Channel interrupts.
* @param __HANDLE__: DMA handle
* @param __INTERRUPT__: specifies the DMA interrupt sources to be enabled or disabled.
* This parameter can be any combination of the following values:
* @arg DMA_IT_TC: Transfer complete interrupt mask
* @arg DMA_IT_HT: Half transfer complete interrupt mask
* @arg DMA_IT_TE: Transfer error interrupt mask
* @retval None
*/
#define __HAL_DMA_DISABLE_IT(__HANDLE__, __INTERRUPT__) (CLEAR_BIT((__HANDLE__)->Instance->CCR , (__INTERRUPT__)))
/**
* @brief Check whether the specified DMA Channel interrupt is enabled or not.
* @param __HANDLE__: DMA handle
* @param __INTERRUPT__: specifies the DMA interrupt source to check.
* This parameter can be one of the following values:
* @arg DMA_IT_TC: Transfer complete interrupt mask
* @arg DMA_IT_HT: Half transfer complete interrupt mask
* @arg DMA_IT_TE: Transfer error interrupt mask
* @retval The state of DMA_IT (SET or RESET).
*/
#define __HAL_DMA_GET_IT_SOURCE(__HANDLE__, __INTERRUPT__) ((((__HANDLE__)->Instance->CCR & (__INTERRUPT__)) == (__INTERRUPT__)) ? SET : RESET)
/**
* @brief Return the number of remaining data units in the current DMA Channel transfer.
* @param __HANDLE__: DMA handle
* @retval The number of remaining data units in the current DMA Channel transfer.
*/
#define __HAL_DMA_GET_COUNTER(__HANDLE__) ((__HANDLE__)->Instance->CNDTR)
/**
* @}
*/
/* Include DMA HAL Extension module */
#include "stm32f1xx_hal_dma_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup DMA_Exported_Functions
* @{
*/
/** @addtogroup DMA_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions *****************************/
HAL_StatusTypeDef HAL_DMA_Init(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_DeInit (DMA_HandleTypeDef *hdma);
/**
* @}
*/
/** @addtogroup DMA_Exported_Functions_Group2
* @{
*/
/* IO operation functions *****************************************************/
HAL_StatusTypeDef HAL_DMA_Start (DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength);
HAL_StatusTypeDef HAL_DMA_Start_IT(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength);
HAL_StatusTypeDef HAL_DMA_Abort(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_Abort_IT(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_PollForTransfer(DMA_HandleTypeDef *hdma, uint32_t CompleteLevel, uint32_t Timeout);
void HAL_DMA_IRQHandler(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_RegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID, void (* pCallback)( DMA_HandleTypeDef * _hdma));
HAL_StatusTypeDef HAL_DMA_UnRegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID);
/**
* @}
*/
/** @addtogroup DMA_Exported_Functions_Group3
* @{
*/
/* Peripheral State and Error functions ***************************************/
HAL_DMA_StateTypeDef HAL_DMA_GetState(DMA_HandleTypeDef *hdma);
uint32_t HAL_DMA_GetError(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup DMA_Private_Macros DMA Private Macros
* @{
*/
#define IS_DMA_DIRECTION(DIRECTION) (((DIRECTION) == DMA_PERIPH_TO_MEMORY ) || \
((DIRECTION) == DMA_MEMORY_TO_PERIPH) || \
((DIRECTION) == DMA_MEMORY_TO_MEMORY))
#define IS_DMA_BUFFER_SIZE(SIZE) (((SIZE) >= 0x1U) && ((SIZE) < 0x10000U))
#define IS_DMA_PERIPHERAL_INC_STATE(STATE) (((STATE) == DMA_PINC_ENABLE) || \
((STATE) == DMA_PINC_DISABLE))
#define IS_DMA_MEMORY_INC_STATE(STATE) (((STATE) == DMA_MINC_ENABLE) || \
((STATE) == DMA_MINC_DISABLE))
#define IS_DMA_PERIPHERAL_DATA_SIZE(SIZE) (((SIZE) == DMA_PDATAALIGN_BYTE) || \
((SIZE) == DMA_PDATAALIGN_HALFWORD) || \
((SIZE) == DMA_PDATAALIGN_WORD))
#define IS_DMA_MEMORY_DATA_SIZE(SIZE) (((SIZE) == DMA_MDATAALIGN_BYTE) || \
((SIZE) == DMA_MDATAALIGN_HALFWORD) || \
((SIZE) == DMA_MDATAALIGN_WORD ))
#define IS_DMA_MODE(MODE) (((MODE) == DMA_NORMAL ) || \
((MODE) == DMA_CIRCULAR))
#define IS_DMA_PRIORITY(PRIORITY) (((PRIORITY) == DMA_PRIORITY_LOW ) || \
((PRIORITY) == DMA_PRIORITY_MEDIUM) || \
((PRIORITY) == DMA_PRIORITY_HIGH) || \
((PRIORITY) == DMA_PRIORITY_VERY_HIGH))
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_DMA_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_dma_ex.h
* @author MCD Application Team
* @brief Header file of DMA HAL extension module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_DMA_EX_H
#define __STM32F1xx_HAL_DMA_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup DMAEx DMAEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup DMAEx_Exported_Macros DMA Extended Exported Macros
* @{
*/
/* Interrupt & Flag management */
#if defined (STM32F100xE) || defined (STM32F101xE) || defined (STM32F101xG) || defined (STM32F103xE) || \
defined (STM32F103xG) || defined (STM32F105xC) || defined (STM32F107xC)
/** @defgroup DMAEx_High_density_XL_density_Product_devices DMAEx High density and XL density product devices
* @{
*/
/**
* @brief Returns the current DMA Channel transfer complete flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer complete flag index.
*/
#define __HAL_DMA_GET_TC_FLAG_INDEX(__HANDLE__) \
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TC5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TC6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_TC7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TC4 :\
DMA_FLAG_TC5)
/**
* @brief Returns the current DMA Channel half transfer complete flag.
* @param __HANDLE__: DMA handle
* @retval The specified half transfer complete flag index.
*/
#define __HAL_DMA_GET_HT_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_HT5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_HT6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_HT7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_HT4 :\
DMA_FLAG_HT5)
/**
* @brief Returns the current DMA Channel transfer error flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer error flag index.
*/
#define __HAL_DMA_GET_TE_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TE5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TE6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_TE7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TE4 :\
DMA_FLAG_TE5)
/**
* @brief Return the current DMA Channel Global interrupt flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer error flag index.
*/
#define __HAL_DMA_GET_GI_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_GL1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_GL2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_GL3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_GL4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_GL5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_GL6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_GL7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_GL1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_GL2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_GL3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_GL4 :\
DMA_FLAG_GL5)
/**
* @brief Get the DMA Channel pending flags.
* @param __HANDLE__: DMA handle
* @param __FLAG__: Get the specified flag.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx: Transfer complete flag
* @arg DMA_FLAG_HTx: Half transfer complete flag
* @arg DMA_FLAG_TEx: Transfer error flag
* Where x can be 1_7 or 1_5 (depending on DMA1 or DMA2) to select the DMA Channel flag.
* @retval The state of FLAG (SET or RESET).
*/
#define __HAL_DMA_GET_FLAG(__HANDLE__, __FLAG__)\
(((uint32_t)((__HANDLE__)->Instance) > (uint32_t)DMA1_Channel7)? (DMA2->ISR & (__FLAG__)) :\
(DMA1->ISR & (__FLAG__)))
/**
* @brief Clears the DMA Channel pending flags.
* @param __HANDLE__: DMA handle
* @param __FLAG__: specifies the flag to clear.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx: Transfer complete flag
* @arg DMA_FLAG_HTx: Half transfer complete flag
* @arg DMA_FLAG_TEx: Transfer error flag
* Where x can be 1_7 or 1_5 (depending on DMA1 or DMA2) to select the DMA Channel flag.
* @retval None
*/
#define __HAL_DMA_CLEAR_FLAG(__HANDLE__, __FLAG__) \
(((uint32_t)((__HANDLE__)->Instance) > (uint32_t)DMA1_Channel7)? (DMA2->IFCR = (__FLAG__)) :\
(DMA1->IFCR = (__FLAG__)))
/**
* @}
*/
#else
/** @defgroup DMA_Low_density_Medium_density_Product_devices DMA Low density and Medium density product devices
* @{
*/
/**
* @brief Returns the current DMA Channel transfer complete flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer complete flag index.
*/
#define __HAL_DMA_GET_TC_FLAG_INDEX(__HANDLE__) \
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TC5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TC6 :\
DMA_FLAG_TC7)
/**
* @brief Return the current DMA Channel half transfer complete flag.
* @param __HANDLE__: DMA handle
* @retval The specified half transfer complete flag index.
*/
#define __HAL_DMA_GET_HT_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_HT5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_HT6 :\
DMA_FLAG_HT7)
/**
* @brief Return the current DMA Channel transfer error flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer error flag index.
*/
#define __HAL_DMA_GET_TE_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TE5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TE6 :\
DMA_FLAG_TE7)
/**
* @brief Return the current DMA Channel Global interrupt flag.
* @param __HANDLE__: DMA handle
* @retval The specified transfer error flag index.
*/
#define __HAL_DMA_GET_GI_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_GL1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_GL2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_GL3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_GL4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_GL5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_GL6 :\
DMA_FLAG_GL7)
/**
* @brief Get the DMA Channel pending flags.
* @param __HANDLE__: DMA handle
* @param __FLAG__: Get the specified flag.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx: Transfer complete flag
* @arg DMA_FLAG_HTx: Half transfer complete flag
* @arg DMA_FLAG_TEx: Transfer error flag
* @arg DMA_FLAG_GLx: Global interrupt flag
* Where x can be 1_7 to select the DMA Channel flag.
* @retval The state of FLAG (SET or RESET).
*/
#define __HAL_DMA_GET_FLAG(__HANDLE__, __FLAG__) (DMA1->ISR & (__FLAG__))
/**
* @brief Clear the DMA Channel pending flags.
* @param __HANDLE__: DMA handle
* @param __FLAG__: specifies the flag to clear.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx: Transfer complete flag
* @arg DMA_FLAG_HTx: Half transfer complete flag
* @arg DMA_FLAG_TEx: Transfer error flag
* @arg DMA_FLAG_GLx: Global interrupt flag
* Where x can be 1_7 to select the DMA Channel flag.
* @retval None
*/
#define __HAL_DMA_CLEAR_FLAG(__HANDLE__, __FLAG__) (DMA1->IFCR = (__FLAG__))
/**
* @}
*/
#endif
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif /* STM32F100xE || STM32F101xE || STM32F101xG || STM32F103xE || */
/* STM32F103xG || STM32F105xC || STM32F107xC */
#endif /* __STM32F1xx_HAL_DMA_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_exti.h
* @author MCD Application Team
* @brief Header file of EXTI HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32F1xx_HAL_EXTI_H
#define STM32F1xx_HAL_EXTI_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup EXTI EXTI
* @brief EXTI HAL module driver
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup EXTI_Exported_Types EXTI Exported Types
* @{
*/
/**
* @brief HAL EXTI common Callback ID enumeration definition
*/
typedef enum
{
HAL_EXTI_COMMON_CB_ID = 0x00U
} EXTI_CallbackIDTypeDef;
/**
* @brief EXTI Handle structure definition
*/
typedef struct
{
uint32_t Line; /*!< Exti line number */
void (* PendingCallback)(void); /*!< Exti pending callback */
} EXTI_HandleTypeDef;
/**
* @brief EXTI Configuration structure definition
*/
typedef struct
{
uint32_t Line; /*!< The Exti line to be configured. This parameter
can be a value of @ref EXTI_Line */
uint32_t Mode; /*!< The Exit Mode to be configured for a core.
This parameter can be a combination of @ref EXTI_Mode */
uint32_t Trigger; /*!< The Exti Trigger to be configured. This parameter
can be a value of @ref EXTI_Trigger */
uint32_t GPIOSel; /*!< The Exti GPIO multiplexer selection to be configured.
This parameter is only possible for line 0 to 15. It
can be a value of @ref EXTI_GPIOSel */
} EXTI_ConfigTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup EXTI_Exported_Constants EXTI Exported Constants
* @{
*/
/** @defgroup EXTI_Line EXTI Line
* @{
*/
#define EXTI_LINE_0 (EXTI_GPIO | 0x00u) /*!< External interrupt line 0 */
#define EXTI_LINE_1 (EXTI_GPIO | 0x01u) /*!< External interrupt line 1 */
#define EXTI_LINE_2 (EXTI_GPIO | 0x02u) /*!< External interrupt line 2 */
#define EXTI_LINE_3 (EXTI_GPIO | 0x03u) /*!< External interrupt line 3 */
#define EXTI_LINE_4 (EXTI_GPIO | 0x04u) /*!< External interrupt line 4 */
#define EXTI_LINE_5 (EXTI_GPIO | 0x05u) /*!< External interrupt line 5 */
#define EXTI_LINE_6 (EXTI_GPIO | 0x06u) /*!< External interrupt line 6 */
#define EXTI_LINE_7 (EXTI_GPIO | 0x07u) /*!< External interrupt line 7 */
#define EXTI_LINE_8 (EXTI_GPIO | 0x08u) /*!< External interrupt line 8 */
#define EXTI_LINE_9 (EXTI_GPIO | 0x09u) /*!< External interrupt line 9 */
#define EXTI_LINE_10 (EXTI_GPIO | 0x0Au) /*!< External interrupt line 10 */
#define EXTI_LINE_11 (EXTI_GPIO | 0x0Bu) /*!< External interrupt line 11 */
#define EXTI_LINE_12 (EXTI_GPIO | 0x0Cu) /*!< External interrupt line 12 */
#define EXTI_LINE_13 (EXTI_GPIO | 0x0Du) /*!< External interrupt line 13 */
#define EXTI_LINE_14 (EXTI_GPIO | 0x0Eu) /*!< External interrupt line 14 */
#define EXTI_LINE_15 (EXTI_GPIO | 0x0Fu) /*!< External interrupt line 15 */
#define EXTI_LINE_16 (EXTI_CONFIG | 0x10u) /*!< External interrupt line 16 Connected to the PVD Output */
#define EXTI_LINE_17 (EXTI_CONFIG | 0x11u) /*!< External interrupt line 17 Connected to the RTC Alarm event */
#if defined(EXTI_IMR_IM18)
#define EXTI_LINE_18 (EXTI_CONFIG | 0x12u) /*!< External interrupt line 18 Connected to the USB Wakeup from suspend event */
#endif /* EXTI_IMR_IM18 */
#if defined(EXTI_IMR_IM19)
#define EXTI_LINE_19 (EXTI_CONFIG | 0x13u) /*!< External interrupt line 19 Connected to the Ethernet Wakeup event */
#endif /* EXTI_IMR_IM19 */
/**
* @}
*/
/** @defgroup EXTI_Mode EXTI Mode
* @{
*/
#define EXTI_MODE_NONE 0x00000000u
#define EXTI_MODE_INTERRUPT 0x00000001u
#define EXTI_MODE_EVENT 0x00000002u
/**
* @}
*/
/** @defgroup EXTI_Trigger EXTI Trigger
* @{
*/
#define EXTI_TRIGGER_NONE 0x00000000u
#define EXTI_TRIGGER_RISING 0x00000001u
#define EXTI_TRIGGER_FALLING 0x00000002u
#define EXTI_TRIGGER_RISING_FALLING (EXTI_TRIGGER_RISING | EXTI_TRIGGER_FALLING)
/**
* @}
*/
/** @defgroup EXTI_GPIOSel EXTI GPIOSel
* @brief
* @{
*/
#define EXTI_GPIOA 0x00000000u
#define EXTI_GPIOB 0x00000001u
#define EXTI_GPIOC 0x00000002u
#define EXTI_GPIOD 0x00000003u
#if defined (GPIOE)
#define EXTI_GPIOE 0x00000004u
#endif /* GPIOE */
#if defined (GPIOF)
#define EXTI_GPIOF 0x00000005u
#endif /* GPIOF */
#if defined (GPIOG)
#define EXTI_GPIOG 0x00000006u
#endif /* GPIOG */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup EXTI_Exported_Macros EXTI Exported Macros
* @{
*/
/**
* @}
*/
/* Private constants --------------------------------------------------------*/
/** @defgroup EXTI_Private_Constants EXTI Private Constants
* @{
*/
/**
* @brief EXTI Line property definition
*/
#define EXTI_PROPERTY_SHIFT 24u
#define EXTI_CONFIG (0x02uL << EXTI_PROPERTY_SHIFT)
#define EXTI_GPIO ((0x04uL << EXTI_PROPERTY_SHIFT) | EXTI_CONFIG)
#define EXTI_PROPERTY_MASK (EXTI_CONFIG | EXTI_GPIO)
/**
* @brief EXTI bit usage
*/
#define EXTI_PIN_MASK 0x0000001Fu
/**
* @brief EXTI Mask for interrupt & event mode
*/
#define EXTI_MODE_MASK (EXTI_MODE_EVENT | EXTI_MODE_INTERRUPT)
/**
* @brief EXTI Mask for trigger possibilities
*/
#define EXTI_TRIGGER_MASK (EXTI_TRIGGER_RISING | EXTI_TRIGGER_FALLING)
/**
* @brief EXTI Line number
*/
#if defined(EXTI_IMR_IM19)
#define EXTI_LINE_NB 20UL
#elif defined(EXTI_IMR_IM18)
#define EXTI_LINE_NB 19UL
#else /* EXTI_IMR_IM17 */
#define EXTI_LINE_NB 18UL
#endif /* EXTI_IMR_IM19 */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup EXTI_Private_Macros EXTI Private Macros
* @{
*/
#define IS_EXTI_LINE(__EXTI_LINE__) ((((__EXTI_LINE__) & ~(EXTI_PROPERTY_MASK | EXTI_PIN_MASK)) == 0x00u) && \
((((__EXTI_LINE__) & EXTI_PROPERTY_MASK) == EXTI_CONFIG) || \
(((__EXTI_LINE__) & EXTI_PROPERTY_MASK) == EXTI_GPIO)) && \
(((__EXTI_LINE__) & EXTI_PIN_MASK) < EXTI_LINE_NB))
#define IS_EXTI_MODE(__EXTI_LINE__) ((((__EXTI_LINE__) & EXTI_MODE_MASK) != 0x00u) && \
(((__EXTI_LINE__) & ~EXTI_MODE_MASK) == 0x00u))
#define IS_EXTI_TRIGGER(__EXTI_LINE__) (((__EXTI_LINE__) & ~EXTI_TRIGGER_MASK) == 0x00u)
#define IS_EXTI_PENDING_EDGE(__EXTI_LINE__) ((__EXTI_LINE__) == EXTI_TRIGGER_RISING_FALLING)
#define IS_EXTI_CONFIG_LINE(__EXTI_LINE__) (((__EXTI_LINE__) & EXTI_CONFIG) != 0x00u)
#if defined (GPIOG)
#define IS_EXTI_GPIO_PORT(__PORT__) (((__PORT__) == EXTI_GPIOA) || \
((__PORT__) == EXTI_GPIOB) || \
((__PORT__) == EXTI_GPIOC) || \
((__PORT__) == EXTI_GPIOD) || \
((__PORT__) == EXTI_GPIOE) || \
((__PORT__) == EXTI_GPIOF) || \
((__PORT__) == EXTI_GPIOG))
#elif defined (GPIOF)
#define IS_EXTI_GPIO_PORT(__PORT__) (((__PORT__) == EXTI_GPIOA) || \
((__PORT__) == EXTI_GPIOB) || \
((__PORT__) == EXTI_GPIOC) || \
((__PORT__) == EXTI_GPIOD) || \
((__PORT__) == EXTI_GPIOE) || \
((__PORT__) == EXTI_GPIOF))
#elif defined (GPIOE)
#define IS_EXTI_GPIO_PORT(__PORT__) (((__PORT__) == EXTI_GPIOA) || \
((__PORT__) == EXTI_GPIOB) || \
((__PORT__) == EXTI_GPIOC) || \
((__PORT__) == EXTI_GPIOD) || \
((__PORT__) == EXTI_GPIOE))
#else
#define IS_EXTI_GPIO_PORT(__PORT__) (((__PORT__) == EXTI_GPIOA) || \
((__PORT__) == EXTI_GPIOB) || \
((__PORT__) == EXTI_GPIOC) || \
((__PORT__) == EXTI_GPIOD))
#endif /* GPIOG */
#define IS_EXTI_GPIO_PIN(__PIN__) ((__PIN__) < 16u)
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup EXTI_Exported_Functions EXTI Exported Functions
* @brief EXTI Exported Functions
* @{
*/
/** @defgroup EXTI_Exported_Functions_Group1 Configuration functions
* @brief Configuration functions
* @{
*/
/* Configuration functions ****************************************************/
HAL_StatusTypeDef HAL_EXTI_SetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig);
HAL_StatusTypeDef HAL_EXTI_GetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig);
HAL_StatusTypeDef HAL_EXTI_ClearConfigLine(EXTI_HandleTypeDef *hexti);
HAL_StatusTypeDef HAL_EXTI_RegisterCallback(EXTI_HandleTypeDef *hexti, EXTI_CallbackIDTypeDef CallbackID, void (*pPendingCbfn)(void));
HAL_StatusTypeDef HAL_EXTI_GetHandle(EXTI_HandleTypeDef *hexti, uint32_t ExtiLine);
/**
* @}
*/
/** @defgroup EXTI_Exported_Functions_Group2 IO operation functions
* @brief IO operation functions
* @{
*/
/* IO operation functions *****************************************************/
void HAL_EXTI_IRQHandler(EXTI_HandleTypeDef *hexti);
uint32_t HAL_EXTI_GetPending(EXTI_HandleTypeDef *hexti, uint32_t Edge);
void HAL_EXTI_ClearPending(EXTI_HandleTypeDef *hexti, uint32_t Edge);
void HAL_EXTI_GenerateSWI(EXTI_HandleTypeDef *hexti);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32F1xx_HAL_EXTI_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_flash.h
* @author MCD Application Team
* @brief Header file of Flash HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_FLASH_H
#define __STM32F1xx_HAL_FLASH_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup FLASH
* @{
*/
/** @addtogroup FLASH_Private_Constants
* @{
*/
#define FLASH_TIMEOUT_VALUE 50000U /* 50 s */
/**
* @}
*/
/** @addtogroup FLASH_Private_Macros
* @{
*/
#define IS_FLASH_TYPEPROGRAM(VALUE) (((VALUE) == FLASH_TYPEPROGRAM_HALFWORD) || \
((VALUE) == FLASH_TYPEPROGRAM_WORD) || \
((VALUE) == FLASH_TYPEPROGRAM_DOUBLEWORD))
#if defined(FLASH_ACR_LATENCY)
#define IS_FLASH_LATENCY(__LATENCY__) (((__LATENCY__) == FLASH_LATENCY_0) || \
((__LATENCY__) == FLASH_LATENCY_1) || \
((__LATENCY__) == FLASH_LATENCY_2))
#else
#define IS_FLASH_LATENCY(__LATENCY__) ((__LATENCY__) == FLASH_LATENCY_0)
#endif /* FLASH_ACR_LATENCY */
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup FLASH_Exported_Types FLASH Exported Types
* @{
*/
/**
* @brief FLASH Procedure structure definition
*/
typedef enum
{
FLASH_PROC_NONE = 0U,
FLASH_PROC_PAGEERASE = 1U,
FLASH_PROC_MASSERASE = 2U,
FLASH_PROC_PROGRAMHALFWORD = 3U,
FLASH_PROC_PROGRAMWORD = 4U,
FLASH_PROC_PROGRAMDOUBLEWORD = 5U
} FLASH_ProcedureTypeDef;
/**
* @brief FLASH handle Structure definition
*/
typedef struct
{
__IO FLASH_ProcedureTypeDef ProcedureOnGoing; /*!< Internal variable to indicate which procedure is ongoing or not in IT context */
__IO uint32_t DataRemaining; /*!< Internal variable to save the remaining pages to erase or half-word to program in IT context */
__IO uint32_t Address; /*!< Internal variable to save address selected for program or erase */
__IO uint64_t Data; /*!< Internal variable to save data to be programmed */
HAL_LockTypeDef Lock; /*!< FLASH locking object */
__IO uint32_t ErrorCode; /*!< FLASH error code
This parameter can be a value of @ref FLASH_Error_Codes */
} FLASH_ProcessTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup FLASH_Exported_Constants FLASH Exported Constants
* @{
*/
/** @defgroup FLASH_Error_Codes FLASH Error Codes
* @{
*/
#define HAL_FLASH_ERROR_NONE 0x00U /*!< No error */
#define HAL_FLASH_ERROR_PROG 0x01U /*!< Programming error */
#define HAL_FLASH_ERROR_WRP 0x02U /*!< Write protection error */
#define HAL_FLASH_ERROR_OPTV 0x04U /*!< Option validity error */
/**
* @}
*/
/** @defgroup FLASH_Type_Program FLASH Type Program
* @{
*/
#define FLASH_TYPEPROGRAM_HALFWORD 0x01U /*!<Program a half-word (16-bit) at a specified address.*/
#define FLASH_TYPEPROGRAM_WORD 0x02U /*!<Program a word (32-bit) at a specified address.*/
#define FLASH_TYPEPROGRAM_DOUBLEWORD 0x03U /*!<Program a double word (64-bit) at a specified address*/
/**
* @}
*/
#if defined(FLASH_ACR_LATENCY)
/** @defgroup FLASH_Latency FLASH Latency
* @{
*/
#define FLASH_LATENCY_0 0x00000000U /*!< FLASH Zero Latency cycle */
#define FLASH_LATENCY_1 FLASH_ACR_LATENCY_0 /*!< FLASH One Latency cycle */
#define FLASH_LATENCY_2 FLASH_ACR_LATENCY_1 /*!< FLASH Two Latency cycles */
/**
* @}
*/
#else
/** @defgroup FLASH_Latency FLASH Latency
* @{
*/
#define FLASH_LATENCY_0 0x00000000U /*!< FLASH Zero Latency cycle */
/**
* @}
*/
#endif /* FLASH_ACR_LATENCY */
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup FLASH_Exported_Macros FLASH Exported Macros
* @brief macros to control FLASH features
* @{
*/
/** @defgroup FLASH_Half_Cycle FLASH Half Cycle
* @brief macros to handle FLASH half cycle
* @{
*/
/**
* @brief Enable the FLASH half cycle access.
* @note half cycle access can only be used with a low-frequency clock of less than
8 MHz that can be obtained with the use of HSI or HSE but not of PLL.
* @retval None
*/
#define __HAL_FLASH_HALF_CYCLE_ACCESS_ENABLE() (FLASH->ACR |= FLASH_ACR_HLFCYA)
/**
* @brief Disable the FLASH half cycle access.
* @note half cycle access can only be used with a low-frequency clock of less than
8 MHz that can be obtained with the use of HSI or HSE but not of PLL.
* @retval None
*/
#define __HAL_FLASH_HALF_CYCLE_ACCESS_DISABLE() (FLASH->ACR &= (~FLASH_ACR_HLFCYA))
/**
* @}
*/
#if defined(FLASH_ACR_LATENCY)
/** @defgroup FLASH_EM_Latency FLASH Latency
* @brief macros to handle FLASH Latency
* @{
*/
/**
* @brief Set the FLASH Latency.
* @param __LATENCY__ FLASH Latency
* The value of this parameter depend on device used within the same series
* @retval None
*/
#define __HAL_FLASH_SET_LATENCY(__LATENCY__) (FLASH->ACR = (FLASH->ACR&(~FLASH_ACR_LATENCY)) | (__LATENCY__))
/**
* @brief Get the FLASH Latency.
* @retval FLASH Latency
* The value of this parameter depend on device used within the same series
*/
#define __HAL_FLASH_GET_LATENCY() (READ_BIT((FLASH->ACR), FLASH_ACR_LATENCY))
/**
* @}
*/
#endif /* FLASH_ACR_LATENCY */
/** @defgroup FLASH_Prefetch FLASH Prefetch
* @brief macros to handle FLASH Prefetch buffer
* @{
*/
/**
* @brief Enable the FLASH prefetch buffer.
* @retval None
*/
#define __HAL_FLASH_PREFETCH_BUFFER_ENABLE() (FLASH->ACR |= FLASH_ACR_PRFTBE)
/**
* @brief Disable the FLASH prefetch buffer.
* @retval None
*/
#define __HAL_FLASH_PREFETCH_BUFFER_DISABLE() (FLASH->ACR &= (~FLASH_ACR_PRFTBE))
/**
* @}
*/
/**
* @}
*/
/* Include FLASH HAL Extended module */
#include "stm32f1xx_hal_flash_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup FLASH_Exported_Functions
* @{
*/
/** @addtogroup FLASH_Exported_Functions_Group1
* @{
*/
/* IO operation functions *****************************************************/
HAL_StatusTypeDef HAL_FLASH_Program(uint32_t TypeProgram, uint32_t Address, uint64_t Data);
HAL_StatusTypeDef HAL_FLASH_Program_IT(uint32_t TypeProgram, uint32_t Address, uint64_t Data);
/* FLASH IRQ handler function */
void HAL_FLASH_IRQHandler(void);
/* Callbacks in non blocking modes */
void HAL_FLASH_EndOfOperationCallback(uint32_t ReturnValue);
void HAL_FLASH_OperationErrorCallback(uint32_t ReturnValue);
/**
* @}
*/
/** @addtogroup FLASH_Exported_Functions_Group2
* @{
*/
/* Peripheral Control functions ***********************************************/
HAL_StatusTypeDef HAL_FLASH_Unlock(void);
HAL_StatusTypeDef HAL_FLASH_Lock(void);
HAL_StatusTypeDef HAL_FLASH_OB_Unlock(void);
HAL_StatusTypeDef HAL_FLASH_OB_Lock(void);
void HAL_FLASH_OB_Launch(void);
/**
* @}
*/
/** @addtogroup FLASH_Exported_Functions_Group3
* @{
*/
/* Peripheral State and Error functions ***************************************/
uint32_t HAL_FLASH_GetError(void);
/**
* @}
*/
/**
* @}
*/
/* Private function -------------------------------------------------*/
/** @addtogroup FLASH_Private_Functions
* @{
*/
HAL_StatusTypeDef FLASH_WaitForLastOperation(uint32_t Timeout);
#if defined(FLASH_BANK2_END)
HAL_StatusTypeDef FLASH_WaitForLastOperationBank2(uint32_t Timeout);
#endif /* FLASH_BANK2_END */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_FLASH_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_flash_ex.h
* @author MCD Application Team
* @brief Header file of Flash HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_FLASH_EX_H
#define __STM32F1xx_HAL_FLASH_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup FLASHEx
* @{
*/
/** @addtogroup FLASHEx_Private_Constants
* @{
*/
#define FLASH_SIZE_DATA_REGISTER 0x1FFFF7E0U
#define OBR_REG_INDEX 1U
#define SR_FLAG_MASK ((uint32_t)(FLASH_SR_BSY | FLASH_SR_PGERR | FLASH_SR_WRPRTERR | FLASH_SR_EOP))
/**
* @}
*/
/** @addtogroup FLASHEx_Private_Macros
* @{
*/
#define IS_FLASH_TYPEERASE(VALUE) (((VALUE) == FLASH_TYPEERASE_PAGES) || ((VALUE) == FLASH_TYPEERASE_MASSERASE))
#define IS_OPTIONBYTE(VALUE) (((VALUE) <= (OPTIONBYTE_WRP | OPTIONBYTE_RDP | OPTIONBYTE_USER | OPTIONBYTE_DATA)))
#define IS_WRPSTATE(VALUE) (((VALUE) == OB_WRPSTATE_DISABLE) || ((VALUE) == OB_WRPSTATE_ENABLE))
#define IS_OB_RDP_LEVEL(LEVEL) (((LEVEL) == OB_RDP_LEVEL_0) || ((LEVEL) == OB_RDP_LEVEL_1))
#define IS_OB_DATA_ADDRESS(ADDRESS) (((ADDRESS) == OB_DATA_ADDRESS_DATA0) || ((ADDRESS) == OB_DATA_ADDRESS_DATA1))
#define IS_OB_IWDG_SOURCE(SOURCE) (((SOURCE) == OB_IWDG_SW) || ((SOURCE) == OB_IWDG_HW))
#define IS_OB_STOP_SOURCE(SOURCE) (((SOURCE) == OB_STOP_NO_RST) || ((SOURCE) == OB_STOP_RST))
#define IS_OB_STDBY_SOURCE(SOURCE) (((SOURCE) == OB_STDBY_NO_RST) || ((SOURCE) == OB_STDBY_RST))
#if defined(FLASH_BANK2_END)
#define IS_OB_BOOT1(BOOT1) (((BOOT1) == OB_BOOT1_RESET) || ((BOOT1) == OB_BOOT1_SET))
#endif /* FLASH_BANK2_END */
/* Low Density */
#if (defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F103x6))
#define IS_FLASH_NB_PAGES(ADDRESS,NBPAGES) (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x20U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)- 1 <= 0x08007FFFU) : \
((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)- 1 <= 0x08003FFFU))
#endif /* STM32F101x6 || STM32F102x6 || STM32F103x6 */
/* Medium Density */
#if (defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) || defined(STM32F103xB))
#define IS_FLASH_NB_PAGES(ADDRESS,NBPAGES) (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x80U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0801FFFFU) : \
(((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x40U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0800FFFFU) : \
(((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x20U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x08007FFFU) : \
((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x08003FFFU))))
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB*/
/* High Density */
#if (defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F103xE))
#define IS_FLASH_NB_PAGES(ADDRESS,NBPAGES) (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x200U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0807FFFFU) : \
(((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x180U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0805FFFFU) : \
((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0803FFFFU)))
#endif /* STM32F100xE || STM32F101xE || STM32F103xE */
/* XL Density */
#if defined(FLASH_BANK2_END)
#define IS_FLASH_NB_PAGES(ADDRESS,NBPAGES) (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x400U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x080FFFFFU) : \
((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x080BFFFFU))
#endif /* FLASH_BANK2_END */
/* Connectivity Line */
#if (defined(STM32F105xC) || defined(STM32F107xC))
#define IS_FLASH_NB_PAGES(ADDRESS,NBPAGES) (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x100U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0803FFFFU) : \
(((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x80U) ? ((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0801FFFFU) : \
((ADDRESS)+((NBPAGES)*FLASH_PAGE_SIZE)-1 <= 0x0800FFFFU)))
#endif /* STM32F105xC || STM32F107xC */
#define IS_OB_WRP(PAGE) (((PAGE) != 0x0000000U))
#if defined(FLASH_BANK2_END)
#define IS_FLASH_BANK(BANK) (((BANK) == FLASH_BANK_1) || \
((BANK) == FLASH_BANK_2) || \
((BANK) == FLASH_BANK_BOTH))
#else
#define IS_FLASH_BANK(BANK) (((BANK) == FLASH_BANK_1))
#endif /* FLASH_BANK2_END */
/* Low Density */
#if (defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F103x6))
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x20U) ? \
((ADDRESS) <= FLASH_BANK1_END) : ((ADDRESS) <= 0x08003FFFU)))
#endif /* STM32F101x6 || STM32F102x6 || STM32F103x6 */
/* Medium Density */
#if (defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) || defined(STM32F103xB))
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x80U) ? \
((ADDRESS) <= FLASH_BANK1_END) : (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x40U) ? \
((ADDRESS) <= 0x0800FFFF) : (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x20U) ? \
((ADDRESS) <= 0x08007FFF) : ((ADDRESS) <= 0x08003FFFU)))))
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB*/
/* High Density */
#if (defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F103xE))
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x200U) ? \
((ADDRESS) <= FLASH_BANK1_END) : (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x180U) ? \
((ADDRESS) <= 0x0805FFFFU) : ((ADDRESS) <= 0x0803FFFFU))))
#endif /* STM32F100xE || STM32F101xE || STM32F103xE */
/* XL Density */
#if defined(FLASH_BANK2_END)
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x400U) ? \
((ADDRESS) <= FLASH_BANK2_END) : ((ADDRESS) <= 0x080BFFFFU)))
#endif /* FLASH_BANK2_END */
/* Connectivity Line */
#if (defined(STM32F105xC) || defined(STM32F107xC))
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x100U) ? \
((ADDRESS) <= FLASH_BANK1_END) : (((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0x80U) ? \
((ADDRESS) <= 0x0801FFFFU) : ((ADDRESS) <= 0x0800FFFFU))))
#endif /* STM32F105xC || STM32F107xC */
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup FLASHEx_Exported_Types FLASHEx Exported Types
* @{
*/
/**
* @brief FLASH Erase structure definition
*/
typedef struct
{
uint32_t TypeErase; /*!< TypeErase: Mass erase or page erase.
This parameter can be a value of @ref FLASHEx_Type_Erase */
uint32_t Banks; /*!< Select banks to erase when Mass erase is enabled.
This parameter must be a value of @ref FLASHEx_Banks */
uint32_t PageAddress; /*!< PageAdress: Initial FLASH page address to erase when mass erase is disabled
This parameter must be a number between Min_Data = 0x08000000 and Max_Data = FLASH_BANKx_END
(x = 1 or 2 depending on devices)*/
uint32_t NbPages; /*!< NbPages: Number of pagess to be erased.
This parameter must be a value between Min_Data = 1 and Max_Data = (max number of pages - value of initial page)*/
} FLASH_EraseInitTypeDef;
/**
* @brief FLASH Options bytes program structure definition
*/
typedef struct
{
uint32_t OptionType; /*!< OptionType: Option byte to be configured.
This parameter can be a value of @ref FLASHEx_OB_Type */
uint32_t WRPState; /*!< WRPState: Write protection activation or deactivation.
This parameter can be a value of @ref FLASHEx_OB_WRP_State */
uint32_t WRPPage; /*!< WRPPage: specifies the page(s) to be write protected
This parameter can be a value of @ref FLASHEx_OB_Write_Protection */
uint32_t Banks; /*!< Select banks for WRP activation/deactivation of all sectors.
This parameter must be a value of @ref FLASHEx_Banks */
uint8_t RDPLevel; /*!< RDPLevel: Set the read protection level..
This parameter can be a value of @ref FLASHEx_OB_Read_Protection */
#if defined(FLASH_BANK2_END)
uint8_t USERConfig; /*!< USERConfig: Program the FLASH User Option Byte:
IWDG / STOP / STDBY / BOOT1
This parameter can be a combination of @ref FLASHEx_OB_IWatchdog, @ref FLASHEx_OB_nRST_STOP,
@ref FLASHEx_OB_nRST_STDBY, @ref FLASHEx_OB_BOOT1 */
#else
uint8_t USERConfig; /*!< USERConfig: Program the FLASH User Option Byte:
IWDG / STOP / STDBY
This parameter can be a combination of @ref FLASHEx_OB_IWatchdog, @ref FLASHEx_OB_nRST_STOP,
@ref FLASHEx_OB_nRST_STDBY */
#endif /* FLASH_BANK2_END */
uint32_t DATAAddress; /*!< DATAAddress: Address of the option byte DATA to be programmed
This parameter can be a value of @ref FLASHEx_OB_Data_Address */
uint8_t DATAData; /*!< DATAData: Data to be stored in the option byte DATA
This parameter must be a number between Min_Data = 0x00 and Max_Data = 0xFF */
} FLASH_OBProgramInitTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup FLASHEx_Exported_Constants FLASHEx Exported Constants
* @{
*/
/** @defgroup FLASHEx_Constants FLASH Constants
* @{
*/
/** @defgroup FLASHEx_Page_Size Page Size
* @{
*/
#if (defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F103x6) || defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) || defined(STM32F103xB))
#define FLASH_PAGE_SIZE 0x400U
#endif /* STM32F101x6 || STM32F102x6 || STM32F103x6 */
/* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB */
#if (defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F103xE) || defined(STM32F101xG) || defined(STM32F103xG) || defined(STM32F105xC) || defined(STM32F107xC))
#define FLASH_PAGE_SIZE 0x800U
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB */
/* STM32F101xG || STM32F103xG */
/* STM32F105xC || STM32F107xC */
/**
* @}
*/
/** @defgroup FLASHEx_Type_Erase Type Erase
* @{
*/
#define FLASH_TYPEERASE_PAGES 0x00U /*!<Pages erase only*/
#define FLASH_TYPEERASE_MASSERASE 0x02U /*!<Flash mass erase activation*/
/**
* @}
*/
/** @defgroup FLASHEx_Banks Banks
* @{
*/
#if defined(FLASH_BANK2_END)
#define FLASH_BANK_1 1U /*!< Bank 1 */
#define FLASH_BANK_2 2U /*!< Bank 2 */
#define FLASH_BANK_BOTH ((uint32_t)FLASH_BANK_1 | FLASH_BANK_2) /*!< Bank1 and Bank2 */
#else
#define FLASH_BANK_1 1U /*!< Bank 1 */
#endif
/**
* @}
*/
/**
* @}
*/
/** @defgroup FLASHEx_OptionByte_Constants Option Byte Constants
* @{
*/
/** @defgroup FLASHEx_OB_Type Option Bytes Type
* @{
*/
#define OPTIONBYTE_WRP 0x01U /*!<WRP option byte configuration*/
#define OPTIONBYTE_RDP 0x02U /*!<RDP option byte configuration*/
#define OPTIONBYTE_USER 0x04U /*!<USER option byte configuration*/
#define OPTIONBYTE_DATA 0x08U /*!<DATA option byte configuration*/
/**
* @}
*/
/** @defgroup FLASHEx_OB_WRP_State Option Byte WRP State
* @{
*/
#define OB_WRPSTATE_DISABLE 0x00U /*!<Disable the write protection of the desired pages*/
#define OB_WRPSTATE_ENABLE 0x01U /*!<Enable the write protection of the desired pagess*/
/**
* @}
*/
/** @defgroup FLASHEx_OB_Write_Protection Option Bytes Write Protection
* @{
*/
/* STM32 Low and Medium density devices */
#if defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F103x6) \
|| defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) \
|| defined(STM32F103xB)
#define OB_WRP_PAGES0TO3 0x00000001U /*!< Write protection of page 0 to 3 */
#define OB_WRP_PAGES4TO7 0x00000002U /*!< Write protection of page 4 to 7 */
#define OB_WRP_PAGES8TO11 0x00000004U /*!< Write protection of page 8 to 11 */
#define OB_WRP_PAGES12TO15 0x00000008U /*!< Write protection of page 12 to 15 */
#define OB_WRP_PAGES16TO19 0x00000010U /*!< Write protection of page 16 to 19 */
#define OB_WRP_PAGES20TO23 0x00000020U /*!< Write protection of page 20 to 23 */
#define OB_WRP_PAGES24TO27 0x00000040U /*!< Write protection of page 24 to 27 */
#define OB_WRP_PAGES28TO31 0x00000080U /*!< Write protection of page 28 to 31 */
#endif /* STM32F101x6 || STM32F102x6 || STM32F103x6 */
/* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB */
/* STM32 Medium-density devices */
#if defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) || defined(STM32F103xB)
#define OB_WRP_PAGES32TO35 0x00000100U /*!< Write protection of page 32 to 35 */
#define OB_WRP_PAGES36TO39 0x00000200U /*!< Write protection of page 36 to 39 */
#define OB_WRP_PAGES40TO43 0x00000400U /*!< Write protection of page 40 to 43 */
#define OB_WRP_PAGES44TO47 0x00000800U /*!< Write protection of page 44 to 47 */
#define OB_WRP_PAGES48TO51 0x00001000U /*!< Write protection of page 48 to 51 */
#define OB_WRP_PAGES52TO55 0x00002000U /*!< Write protection of page 52 to 55 */
#define OB_WRP_PAGES56TO59 0x00004000U /*!< Write protection of page 56 to 59 */
#define OB_WRP_PAGES60TO63 0x00008000U /*!< Write protection of page 60 to 63 */
#define OB_WRP_PAGES64TO67 0x00010000U /*!< Write protection of page 64 to 67 */
#define OB_WRP_PAGES68TO71 0x00020000U /*!< Write protection of page 68 to 71 */
#define OB_WRP_PAGES72TO75 0x00040000U /*!< Write protection of page 72 to 75 */
#define OB_WRP_PAGES76TO79 0x00080000U /*!< Write protection of page 76 to 79 */
#define OB_WRP_PAGES80TO83 0x00100000U /*!< Write protection of page 80 to 83 */
#define OB_WRP_PAGES84TO87 0x00200000U /*!< Write protection of page 84 to 87 */
#define OB_WRP_PAGES88TO91 0x00400000U /*!< Write protection of page 88 to 91 */
#define OB_WRP_PAGES92TO95 0x00800000U /*!< Write protection of page 92 to 95 */
#define OB_WRP_PAGES96TO99 0x01000000U /*!< Write protection of page 96 to 99 */
#define OB_WRP_PAGES100TO103 0x02000000U /*!< Write protection of page 100 to 103 */
#define OB_WRP_PAGES104TO107 0x04000000U /*!< Write protection of page 104 to 107 */
#define OB_WRP_PAGES108TO111 0x08000000U /*!< Write protection of page 108 to 111 */
#define OB_WRP_PAGES112TO115 0x10000000U /*!< Write protection of page 112 to 115 */
#define OB_WRP_PAGES116TO119 0x20000000U /*!< Write protection of page 115 to 119 */
#define OB_WRP_PAGES120TO123 0x40000000U /*!< Write protection of page 120 to 123 */
#define OB_WRP_PAGES124TO127 0x80000000U /*!< Write protection of page 124 to 127 */
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB */
/* STM32 High-density, XL-density and Connectivity line devices */
#if defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F103xE) \
|| defined(STM32F101xG) || defined(STM32F103xG) \
|| defined(STM32F105xC) || defined(STM32F107xC)
#define OB_WRP_PAGES0TO1 0x00000001U /*!< Write protection of page 0 TO 1 */
#define OB_WRP_PAGES2TO3 0x00000002U /*!< Write protection of page 2 TO 3 */
#define OB_WRP_PAGES4TO5 0x00000004U /*!< Write protection of page 4 TO 5 */
#define OB_WRP_PAGES6TO7 0x00000008U /*!< Write protection of page 6 TO 7 */
#define OB_WRP_PAGES8TO9 0x00000010U /*!< Write protection of page 8 TO 9 */
#define OB_WRP_PAGES10TO11 0x00000020U /*!< Write protection of page 10 TO 11 */
#define OB_WRP_PAGES12TO13 0x00000040U /*!< Write protection of page 12 TO 13 */
#define OB_WRP_PAGES14TO15 0x00000080U /*!< Write protection of page 14 TO 15 */
#define OB_WRP_PAGES16TO17 0x00000100U /*!< Write protection of page 16 TO 17 */
#define OB_WRP_PAGES18TO19 0x00000200U /*!< Write protection of page 18 TO 19 */
#define OB_WRP_PAGES20TO21 0x00000400U /*!< Write protection of page 20 TO 21 */
#define OB_WRP_PAGES22TO23 0x00000800U /*!< Write protection of page 22 TO 23 */
#define OB_WRP_PAGES24TO25 0x00001000U /*!< Write protection of page 24 TO 25 */
#define OB_WRP_PAGES26TO27 0x00002000U /*!< Write protection of page 26 TO 27 */
#define OB_WRP_PAGES28TO29 0x00004000U /*!< Write protection of page 28 TO 29 */
#define OB_WRP_PAGES30TO31 0x00008000U /*!< Write protection of page 30 TO 31 */
#define OB_WRP_PAGES32TO33 0x00010000U /*!< Write protection of page 32 TO 33 */
#define OB_WRP_PAGES34TO35 0x00020000U /*!< Write protection of page 34 TO 35 */
#define OB_WRP_PAGES36TO37 0x00040000U /*!< Write protection of page 36 TO 37 */
#define OB_WRP_PAGES38TO39 0x00080000U /*!< Write protection of page 38 TO 39 */
#define OB_WRP_PAGES40TO41 0x00100000U /*!< Write protection of page 40 TO 41 */
#define OB_WRP_PAGES42TO43 0x00200000U /*!< Write protection of page 42 TO 43 */
#define OB_WRP_PAGES44TO45 0x00400000U /*!< Write protection of page 44 TO 45 */
#define OB_WRP_PAGES46TO47 0x00800000U /*!< Write protection of page 46 TO 47 */
#define OB_WRP_PAGES48TO49 0x01000000U /*!< Write protection of page 48 TO 49 */
#define OB_WRP_PAGES50TO51 0x02000000U /*!< Write protection of page 50 TO 51 */
#define OB_WRP_PAGES52TO53 0x04000000U /*!< Write protection of page 52 TO 53 */
#define OB_WRP_PAGES54TO55 0x08000000U /*!< Write protection of page 54 TO 55 */
#define OB_WRP_PAGES56TO57 0x10000000U /*!< Write protection of page 56 TO 57 */
#define OB_WRP_PAGES58TO59 0x20000000U /*!< Write protection of page 58 TO 59 */
#define OB_WRP_PAGES60TO61 0x40000000U /*!< Write protection of page 60 TO 61 */
#define OB_WRP_PAGES62TO127 0x80000000U /*!< Write protection of page 62 TO 127 */
#define OB_WRP_PAGES62TO255 0x80000000U /*!< Write protection of page 62 TO 255 */
#define OB_WRP_PAGES62TO511 0x80000000U /*!< Write protection of page 62 TO 511 */
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB */
/* STM32F101xG || STM32F103xG */
/* STM32F105xC || STM32F107xC */
#define OB_WRP_ALLPAGES 0xFFFFFFFFU /*!< Write protection of all Pages */
/* Low Density */
#if defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F103x6)
#define OB_WRP_PAGES0TO31MASK 0x000000FFU
#endif /* STM32F101x6 || STM32F102x6 || STM32F103x6 */
/* Medium Density */
#if defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F102xB) || defined(STM32F103xB)
#define OB_WRP_PAGES0TO31MASK 0x000000FFU
#define OB_WRP_PAGES32TO63MASK 0x0000FF00U
#define OB_WRP_PAGES64TO95MASK 0x00FF0000U
#define OB_WRP_PAGES96TO127MASK 0xFF000000U
#endif /* STM32F100xB || STM32F101xB || STM32F102xB || STM32F103xB*/
/* High Density */
#if defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F103xE)
#define OB_WRP_PAGES0TO15MASK 0x000000FFU
#define OB_WRP_PAGES16TO31MASK 0x0000FF00U
#define OB_WRP_PAGES32TO47MASK 0x00FF0000U
#define OB_WRP_PAGES48TO255MASK 0xFF000000U
#endif /* STM32F100xE || STM32F101xE || STM32F103xE */
/* XL Density */
#if defined(STM32F101xG) || defined(STM32F103xG)
#define OB_WRP_PAGES0TO15MASK 0x000000FFU
#define OB_WRP_PAGES16TO31MASK 0x0000FF00U
#define OB_WRP_PAGES32TO47MASK 0x00FF0000U
#define OB_WRP_PAGES48TO511MASK 0xFF000000U
#endif /* STM32F101xG || STM32F103xG */
/* Connectivity line devices */
#if defined(STM32F105xC) || defined(STM32F107xC)
#define OB_WRP_PAGES0TO15MASK 0x000000FFU
#define OB_WRP_PAGES16TO31MASK 0x0000FF00U
#define OB_WRP_PAGES32TO47MASK 0x00FF0000U
#define OB_WRP_PAGES48TO127MASK 0xFF000000U
#endif /* STM32F105xC || STM32F107xC */
/**
* @}
*/
/** @defgroup FLASHEx_OB_Read_Protection Option Byte Read Protection
* @{
*/
#define OB_RDP_LEVEL_0 ((uint8_t)0xA5)
#define OB_RDP_LEVEL_1 ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup FLASHEx_OB_IWatchdog Option Byte IWatchdog
* @{
*/
#define OB_IWDG_SW ((uint16_t)0x0001) /*!< Software IWDG selected */
#define OB_IWDG_HW ((uint16_t)0x0000) /*!< Hardware IWDG selected */
/**
* @}
*/
/** @defgroup FLASHEx_OB_nRST_STOP Option Byte nRST STOP
* @{
*/
#define OB_STOP_NO_RST ((uint16_t)0x0002) /*!< No reset generated when entering in STOP */
#define OB_STOP_RST ((uint16_t)0x0000) /*!< Reset generated when entering in STOP */
/**
* @}
*/
/** @defgroup FLASHEx_OB_nRST_STDBY Option Byte nRST STDBY
* @{
*/
#define OB_STDBY_NO_RST ((uint16_t)0x0004) /*!< No reset generated when entering in STANDBY */
#define OB_STDBY_RST ((uint16_t)0x0000) /*!< Reset generated when entering in STANDBY */
/**
* @}
*/
#if defined(FLASH_BANK2_END)
/** @defgroup FLASHEx_OB_BOOT1 Option Byte BOOT1
* @{
*/
#define OB_BOOT1_RESET ((uint16_t)0x0000) /*!< BOOT1 Reset */
#define OB_BOOT1_SET ((uint16_t)0x0008) /*!< BOOT1 Set */
/**
* @}
*/
#endif /* FLASH_BANK2_END */
/** @defgroup FLASHEx_OB_Data_Address Option Byte Data Address
* @{
*/
#define OB_DATA_ADDRESS_DATA0 0x1FFFF804U
#define OB_DATA_ADDRESS_DATA1 0x1FFFF806U
/**
* @}
*/
/**
* @}
*/
/** @addtogroup FLASHEx_Constants
* @{
*/
/** @defgroup FLASH_Flag_definition Flag definition
* @brief Flag definition
* @{
*/
#if defined(FLASH_BANK2_END)
#define FLASH_FLAG_BSY FLASH_FLAG_BSY_BANK1 /*!< FLASH Bank1 Busy flag */
#define FLASH_FLAG_PGERR FLASH_FLAG_PGERR_BANK1 /*!< FLASH Bank1 Programming error flag */
#define FLASH_FLAG_WRPERR FLASH_FLAG_WRPERR_BANK1 /*!< FLASH Bank1 Write protected error flag */
#define FLASH_FLAG_EOP FLASH_FLAG_EOP_BANK1 /*!< FLASH Bank1 End of Operation flag */
#define FLASH_FLAG_BSY_BANK1 FLASH_SR_BSY /*!< FLASH Bank1 Busy flag */
#define FLASH_FLAG_PGERR_BANK1 FLASH_SR_PGERR /*!< FLASH Bank1 Programming error flag */
#define FLASH_FLAG_WRPERR_BANK1 FLASH_SR_WRPRTERR /*!< FLASH Bank1 Write protected error flag */
#define FLASH_FLAG_EOP_BANK1 FLASH_SR_EOP /*!< FLASH Bank1 End of Operation flag */
#define FLASH_FLAG_BSY_BANK2 (FLASH_SR2_BSY << 16U) /*!< FLASH Bank2 Busy flag */
#define FLASH_FLAG_PGERR_BANK2 (FLASH_SR2_PGERR << 16U) /*!< FLASH Bank2 Programming error flag */
#define FLASH_FLAG_WRPERR_BANK2 (FLASH_SR2_WRPRTERR << 16U) /*!< FLASH Bank2 Write protected error flag */
#define FLASH_FLAG_EOP_BANK2 (FLASH_SR2_EOP << 16U) /*!< FLASH Bank2 End of Operation flag */
#else
#define FLASH_FLAG_BSY FLASH_SR_BSY /*!< FLASH Busy flag */
#define FLASH_FLAG_PGERR FLASH_SR_PGERR /*!< FLASH Programming error flag */
#define FLASH_FLAG_WRPERR FLASH_SR_WRPRTERR /*!< FLASH Write protected error flag */
#define FLASH_FLAG_EOP FLASH_SR_EOP /*!< FLASH End of Operation flag */
#endif
#define FLASH_FLAG_OPTVERR ((OBR_REG_INDEX << 8U | FLASH_OBR_OPTERR)) /*!< Option Byte Error */
/**
* @}
*/
/** @defgroup FLASH_Interrupt_definition Interrupt definition
* @brief FLASH Interrupt definition
* @{
*/
#if defined(FLASH_BANK2_END)
#define FLASH_IT_EOP FLASH_IT_EOP_BANK1 /*!< End of FLASH Operation Interrupt source Bank1 */
#define FLASH_IT_ERR FLASH_IT_ERR_BANK1 /*!< Error Interrupt source Bank1 */
#define FLASH_IT_EOP_BANK1 FLASH_CR_EOPIE /*!< End of FLASH Operation Interrupt source Bank1 */
#define FLASH_IT_ERR_BANK1 FLASH_CR_ERRIE /*!< Error Interrupt source Bank1 */
#define FLASH_IT_EOP_BANK2 (FLASH_CR2_EOPIE << 16U) /*!< End of FLASH Operation Interrupt source Bank2 */
#define FLASH_IT_ERR_BANK2 (FLASH_CR2_ERRIE << 16U) /*!< Error Interrupt source Bank2 */
#else
#define FLASH_IT_EOP FLASH_CR_EOPIE /*!< End of FLASH Operation Interrupt source */
#define FLASH_IT_ERR FLASH_CR_ERRIE /*!< Error Interrupt source */
#endif
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup FLASHEx_Exported_Macros FLASHEx Exported Macros
* @{
*/
/** @defgroup FLASH_Interrupt Interrupt
* @brief macros to handle FLASH interrupts
* @{
*/
#if defined(FLASH_BANK2_END)
/**
* @brief Enable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg @ref FLASH_IT_EOP_BANK1 End of FLASH Operation Interrupt on bank1
* @arg @ref FLASH_IT_ERR_BANK1 Error Interrupt on bank1
* @arg @ref FLASH_IT_EOP_BANK2 End of FLASH Operation Interrupt on bank2
* @arg @ref FLASH_IT_ERR_BANK2 Error Interrupt on bank2
* @retval none
*/
#define __HAL_FLASH_ENABLE_IT(__INTERRUPT__) do { \
/* Enable Bank1 IT */ \
SET_BIT(FLASH->CR, ((__INTERRUPT__) & 0x0000FFFFU)); \
/* Enable Bank2 IT */ \
SET_BIT(FLASH->CR2, ((__INTERRUPT__) >> 16U)); \
} while(0U)
/**
* @brief Disable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg @ref FLASH_IT_EOP_BANK1 End of FLASH Operation Interrupt on bank1
* @arg @ref FLASH_IT_ERR_BANK1 Error Interrupt on bank1
* @arg @ref FLASH_IT_EOP_BANK2 End of FLASH Operation Interrupt on bank2
* @arg @ref FLASH_IT_ERR_BANK2 Error Interrupt on bank2
* @retval none
*/
#define __HAL_FLASH_DISABLE_IT(__INTERRUPT__) do { \
/* Disable Bank1 IT */ \
CLEAR_BIT(FLASH->CR, ((__INTERRUPT__) & 0x0000FFFFU)); \
/* Disable Bank2 IT */ \
CLEAR_BIT(FLASH->CR2, ((__INTERRUPT__) >> 16U)); \
} while(0U)
/**
* @brief Get the specified FLASH flag status.
* @param __FLAG__ specifies the FLASH flag to check.
* This parameter can be one of the following values:
* @arg @ref FLASH_FLAG_EOP_BANK1 FLASH End of Operation flag on bank1
* @arg @ref FLASH_FLAG_WRPERR_BANK1 FLASH Write protected error flag on bank1
* @arg @ref FLASH_FLAG_PGERR_BANK1 FLASH Programming error flag on bank1
* @arg @ref FLASH_FLAG_BSY_BANK1 FLASH Busy flag on bank1
* @arg @ref FLASH_FLAG_EOP_BANK2 FLASH End of Operation flag on bank2
* @arg @ref FLASH_FLAG_WRPERR_BANK2 FLASH Write protected error flag on bank2
* @arg @ref FLASH_FLAG_PGERR_BANK2 FLASH Programming error flag on bank2
* @arg @ref FLASH_FLAG_BSY_BANK2 FLASH Busy flag on bank2
* @arg @ref FLASH_FLAG_OPTVERR Loaded OB and its complement do not match
* @retval The new state of __FLAG__ (SET or RESET).
*/
#define __HAL_FLASH_GET_FLAG(__FLAG__) (((__FLAG__) == FLASH_FLAG_OPTVERR) ? \
(FLASH->OBR & FLASH_OBR_OPTERR) : \
((((__FLAG__) & SR_FLAG_MASK) != RESET)? \
(FLASH->SR & ((__FLAG__) & SR_FLAG_MASK)) : \
(FLASH->SR2 & ((__FLAG__) >> 16U))))
/**
* @brief Clear the specified FLASH flag.
* @param __FLAG__ specifies the FLASH flags to clear.
* This parameter can be any combination of the following values:
* @arg @ref FLASH_FLAG_EOP_BANK1 FLASH End of Operation flag on bank1
* @arg @ref FLASH_FLAG_WRPERR_BANK1 FLASH Write protected error flag on bank1
* @arg @ref FLASH_FLAG_PGERR_BANK1 FLASH Programming error flag on bank1
* @arg @ref FLASH_FLAG_BSY_BANK1 FLASH Busy flag on bank1
* @arg @ref FLASH_FLAG_EOP_BANK2 FLASH End of Operation flag on bank2
* @arg @ref FLASH_FLAG_WRPERR_BANK2 FLASH Write protected error flag on bank2
* @arg @ref FLASH_FLAG_PGERR_BANK2 FLASH Programming error flag on bank2
* @arg @ref FLASH_FLAG_BSY_BANK2 FLASH Busy flag on bank2
* @arg @ref FLASH_FLAG_OPTVERR Loaded OB and its complement do not match
* @retval none
*/
#define __HAL_FLASH_CLEAR_FLAG(__FLAG__) do { \
/* Clear FLASH_FLAG_OPTVERR flag */ \
if ((__FLAG__) == FLASH_FLAG_OPTVERR) \
{ \
CLEAR_BIT(FLASH->OBR, FLASH_OBR_OPTERR); \
} \
else { \
/* Clear Flag in Bank1 */ \
if (((__FLAG__) & SR_FLAG_MASK) != RESET) \
{ \
FLASH->SR = ((__FLAG__) & SR_FLAG_MASK); \
} \
/* Clear Flag in Bank2 */ \
if (((__FLAG__) >> 16U) != RESET) \
{ \
FLASH->SR2 = ((__FLAG__) >> 16U); \
} \
} \
} while(0U)
#else
/**
* @brief Enable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg @ref FLASH_IT_EOP End of FLASH Operation Interrupt
* @arg @ref FLASH_IT_ERR Error Interrupt
* @retval none
*/
#define __HAL_FLASH_ENABLE_IT(__INTERRUPT__) (FLASH->CR |= (__INTERRUPT__))
/**
* @brief Disable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg @ref FLASH_IT_EOP End of FLASH Operation Interrupt
* @arg @ref FLASH_IT_ERR Error Interrupt
* @retval none
*/
#define __HAL_FLASH_DISABLE_IT(__INTERRUPT__) (FLASH->CR &= ~(__INTERRUPT__))
/**
* @brief Get the specified FLASH flag status.
* @param __FLAG__ specifies the FLASH flag to check.
* This parameter can be one of the following values:
* @arg @ref FLASH_FLAG_EOP FLASH End of Operation flag
* @arg @ref FLASH_FLAG_WRPERR FLASH Write protected error flag
* @arg @ref FLASH_FLAG_PGERR FLASH Programming error flag
* @arg @ref FLASH_FLAG_BSY FLASH Busy flag
* @arg @ref FLASH_FLAG_OPTVERR Loaded OB and its complement do not match
* @retval The new state of __FLAG__ (SET or RESET).
*/
#define __HAL_FLASH_GET_FLAG(__FLAG__) (((__FLAG__) == FLASH_FLAG_OPTVERR) ? \
(FLASH->OBR & FLASH_OBR_OPTERR) : \
(FLASH->SR & (__FLAG__)))
/**
* @brief Clear the specified FLASH flag.
* @param __FLAG__ specifies the FLASH flags to clear.
* This parameter can be any combination of the following values:
* @arg @ref FLASH_FLAG_EOP FLASH End of Operation flag
* @arg @ref FLASH_FLAG_WRPERR FLASH Write protected error flag
* @arg @ref FLASH_FLAG_PGERR FLASH Programming error flag
* @arg @ref FLASH_FLAG_OPTVERR Loaded OB and its complement do not match
* @retval none
*/
#define __HAL_FLASH_CLEAR_FLAG(__FLAG__) do { \
/* Clear FLASH_FLAG_OPTVERR flag */ \
if ((__FLAG__) == FLASH_FLAG_OPTVERR) \
{ \
CLEAR_BIT(FLASH->OBR, FLASH_OBR_OPTERR); \
} \
else { \
/* Clear Flag in Bank1 */ \
FLASH->SR = (__FLAG__); \
} \
} while(0U)
#endif
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup FLASHEx_Exported_Functions
* @{
*/
/** @addtogroup FLASHEx_Exported_Functions_Group1
* @{
*/
/* IO operation functions *****************************************************/
HAL_StatusTypeDef HAL_FLASHEx_Erase(FLASH_EraseInitTypeDef *pEraseInit, uint32_t *PageError);
HAL_StatusTypeDef HAL_FLASHEx_Erase_IT(FLASH_EraseInitTypeDef *pEraseInit);
/**
* @}
*/
/** @addtogroup FLASHEx_Exported_Functions_Group2
* @{
*/
/* Peripheral Control functions ***********************************************/
HAL_StatusTypeDef HAL_FLASHEx_OBErase(void);
HAL_StatusTypeDef HAL_FLASHEx_OBProgram(FLASH_OBProgramInitTypeDef *pOBInit);
void HAL_FLASHEx_OBGetConfig(FLASH_OBProgramInitTypeDef *pOBInit);
uint32_t HAL_FLASHEx_OBGetUserData(uint32_t DATAAdress);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_FLASH_EX_H */

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Drivers/STM32F1xx_HAL_Driver/Inc/stm32f1xx_hal_gpio.h Normal file
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@ -0,0 +1,306 @@
/**
******************************************************************************
* @file stm32f1xx_hal_gpio.h
* @author MCD Application Team
* @brief Header file of GPIO HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32F1xx_HAL_GPIO_H
#define STM32F1xx_HAL_GPIO_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup GPIO
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup GPIO_Exported_Types GPIO Exported Types
* @{
*/
/**
* @brief GPIO Init structure definition
*/
typedef struct
{
uint32_t Pin; /*!< Specifies the GPIO pins to be configured.
This parameter can be any value of @ref GPIO_pins_define */
uint32_t Mode; /*!< Specifies the operating mode for the selected pins.
This parameter can be a value of @ref GPIO_mode_define */
uint32_t Pull; /*!< Specifies the Pull-up or Pull-Down activation for the selected pins.
This parameter can be a value of @ref GPIO_pull_define */
uint32_t Speed; /*!< Specifies the speed for the selected pins.
This parameter can be a value of @ref GPIO_speed_define */
} GPIO_InitTypeDef;
/**
* @brief GPIO Bit SET and Bit RESET enumeration
*/
typedef enum
{
GPIO_PIN_RESET = 0u,
GPIO_PIN_SET
} GPIO_PinState;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup GPIO_Exported_Constants GPIO Exported Constants
* @{
*/
/** @defgroup GPIO_pins_define GPIO pins define
* @{
*/
#define GPIO_PIN_0 ((uint16_t)0x0001) /* Pin 0 selected */
#define GPIO_PIN_1 ((uint16_t)0x0002) /* Pin 1 selected */
#define GPIO_PIN_2 ((uint16_t)0x0004) /* Pin 2 selected */
#define GPIO_PIN_3 ((uint16_t)0x0008) /* Pin 3 selected */
#define GPIO_PIN_4 ((uint16_t)0x0010) /* Pin 4 selected */
#define GPIO_PIN_5 ((uint16_t)0x0020) /* Pin 5 selected */
#define GPIO_PIN_6 ((uint16_t)0x0040) /* Pin 6 selected */
#define GPIO_PIN_7 ((uint16_t)0x0080) /* Pin 7 selected */
#define GPIO_PIN_8 ((uint16_t)0x0100) /* Pin 8 selected */
#define GPIO_PIN_9 ((uint16_t)0x0200) /* Pin 9 selected */
#define GPIO_PIN_10 ((uint16_t)0x0400) /* Pin 10 selected */
#define GPIO_PIN_11 ((uint16_t)0x0800) /* Pin 11 selected */
#define GPIO_PIN_12 ((uint16_t)0x1000) /* Pin 12 selected */
#define GPIO_PIN_13 ((uint16_t)0x2000) /* Pin 13 selected */
#define GPIO_PIN_14 ((uint16_t)0x4000) /* Pin 14 selected */
#define GPIO_PIN_15 ((uint16_t)0x8000) /* Pin 15 selected */
#define GPIO_PIN_All ((uint16_t)0xFFFF) /* All pins selected */
#define GPIO_PIN_MASK 0x0000FFFFu /* PIN mask for assert test */
/**
* @}
*/
/** @defgroup GPIO_mode_define GPIO mode define
* @brief GPIO Configuration Mode
* Elements values convention: 0xX0yz00YZ
* - X : GPIO mode or EXTI Mode
* - y : External IT or Event trigger detection
* - z : IO configuration on External IT or Event
* - Y : Output type (Push Pull or Open Drain)
* - Z : IO Direction mode (Input, Output, Alternate or Analog)
* @{
*/
#define GPIO_MODE_INPUT 0x00000000u /*!< Input Floating Mode */
#define GPIO_MODE_OUTPUT_PP 0x00000001u /*!< Output Push Pull Mode */
#define GPIO_MODE_OUTPUT_OD 0x00000011u /*!< Output Open Drain Mode */
#define GPIO_MODE_AF_PP 0x00000002u /*!< Alternate Function Push Pull Mode */
#define GPIO_MODE_AF_OD 0x00000012u /*!< Alternate Function Open Drain Mode */
#define GPIO_MODE_AF_INPUT GPIO_MODE_INPUT /*!< Alternate Function Input Mode */
#define GPIO_MODE_ANALOG 0x00000003u /*!< Analog Mode */
#define GPIO_MODE_IT_RISING 0x10110000u /*!< External Interrupt Mode with Rising edge trigger detection */
#define GPIO_MODE_IT_FALLING 0x10210000u /*!< External Interrupt Mode with Falling edge trigger detection */
#define GPIO_MODE_IT_RISING_FALLING 0x10310000u /*!< External Interrupt Mode with Rising/Falling edge trigger detection */
#define GPIO_MODE_EVT_RISING 0x10120000u /*!< External Event Mode with Rising edge trigger detection */
#define GPIO_MODE_EVT_FALLING 0x10220000u /*!< External Event Mode with Falling edge trigger detection */
#define GPIO_MODE_EVT_RISING_FALLING 0x10320000u /*!< External Event Mode with Rising/Falling edge trigger detection */
/**
* @}
*/
/** @defgroup GPIO_speed_define GPIO speed define
* @brief GPIO Output Maximum frequency
* @{
*/
#define GPIO_SPEED_FREQ_LOW (GPIO_CRL_MODE0_1) /*!< Low speed */
#define GPIO_SPEED_FREQ_MEDIUM (GPIO_CRL_MODE0_0) /*!< Medium speed */
#define GPIO_SPEED_FREQ_HIGH (GPIO_CRL_MODE0) /*!< High speed */
/**
* @}
*/
/** @defgroup GPIO_pull_define GPIO pull define
* @brief GPIO Pull-Up or Pull-Down Activation
* @{
*/
#define GPIO_NOPULL 0x00000000u /*!< No Pull-up or Pull-down activation */
#define GPIO_PULLUP 0x00000001u /*!< Pull-up activation */
#define GPIO_PULLDOWN 0x00000002u /*!< Pull-down activation */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup GPIO_Exported_Macros GPIO Exported Macros
* @{
*/
/**
* @brief Checks whether the specified EXTI line flag is set or not.
* @param __EXTI_LINE__: specifies the EXTI line flag to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval The new state of __EXTI_LINE__ (SET or RESET).
*/
#define __HAL_GPIO_EXTI_GET_FLAG(__EXTI_LINE__) (EXTI->PR & (__EXTI_LINE__))
/**
* @brief Clears the EXTI's line pending flags.
* @param __EXTI_LINE__: specifies the EXTI lines flags to clear.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_CLEAR_FLAG(__EXTI_LINE__) (EXTI->PR = (__EXTI_LINE__))
/**
* @brief Checks whether the specified EXTI line is asserted or not.
* @param __EXTI_LINE__: specifies the EXTI line to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval The new state of __EXTI_LINE__ (SET or RESET).
*/
#define __HAL_GPIO_EXTI_GET_IT(__EXTI_LINE__) (EXTI->PR & (__EXTI_LINE__))
/**
* @brief Clears the EXTI's line pending bits.
* @param __EXTI_LINE__: specifies the EXTI lines to clear.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_CLEAR_IT(__EXTI_LINE__) (EXTI->PR = (__EXTI_LINE__))
/**
* @brief Generates a Software interrupt on selected EXTI line.
* @param __EXTI_LINE__: specifies the EXTI line to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_GENERATE_SWIT(__EXTI_LINE__) (EXTI->SWIER |= (__EXTI_LINE__))
/**
* @}
*/
/* Include GPIO HAL Extension module */
#include "stm32f1xx_hal_gpio_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup GPIO_Exported_Functions
* @{
*/
/** @addtogroup GPIO_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions *****************************/
void HAL_GPIO_Init(GPIO_TypeDef *GPIOx, GPIO_InitTypeDef *GPIO_Init);
void HAL_GPIO_DeInit(GPIO_TypeDef *GPIOx, uint32_t GPIO_Pin);
/**
* @}
*/
/** @addtogroup GPIO_Exported_Functions_Group2
* @{
*/
/* IO operation functions *****************************************************/
GPIO_PinState HAL_GPIO_ReadPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
void HAL_GPIO_WritePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin, GPIO_PinState PinState);
void HAL_GPIO_TogglePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
HAL_StatusTypeDef HAL_GPIO_LockPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
void HAL_GPIO_EXTI_IRQHandler(uint16_t GPIO_Pin);
void HAL_GPIO_EXTI_Callback(uint16_t GPIO_Pin);
/**
* @}
*/
/**
* @}
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup GPIO_Private_Constants GPIO Private Constants
* @{
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup GPIO_Private_Macros GPIO Private Macros
* @{
*/
#define IS_GPIO_PIN_ACTION(ACTION) (((ACTION) == GPIO_PIN_RESET) || ((ACTION) == GPIO_PIN_SET))
#define IS_GPIO_PIN(PIN) (((((uint32_t)PIN) & GPIO_PIN_MASK ) != 0x00u) && ((((uint32_t)PIN) & ~GPIO_PIN_MASK) == 0x00u))
#define IS_GPIO_MODE(MODE) (((MODE) == GPIO_MODE_INPUT) ||\
((MODE) == GPIO_MODE_OUTPUT_PP) ||\
((MODE) == GPIO_MODE_OUTPUT_OD) ||\
((MODE) == GPIO_MODE_AF_PP) ||\
((MODE) == GPIO_MODE_AF_OD) ||\
((MODE) == GPIO_MODE_IT_RISING) ||\
((MODE) == GPIO_MODE_IT_FALLING) ||\
((MODE) == GPIO_MODE_IT_RISING_FALLING) ||\
((MODE) == GPIO_MODE_EVT_RISING) ||\
((MODE) == GPIO_MODE_EVT_FALLING) ||\
((MODE) == GPIO_MODE_EVT_RISING_FALLING) ||\
((MODE) == GPIO_MODE_ANALOG))
#define IS_GPIO_SPEED(SPEED) (((SPEED) == GPIO_SPEED_FREQ_LOW) || \
((SPEED) == GPIO_SPEED_FREQ_MEDIUM) || ((SPEED) == GPIO_SPEED_FREQ_HIGH))
#define IS_GPIO_PULL(PULL) (((PULL) == GPIO_NOPULL) || ((PULL) == GPIO_PULLUP) || \
((PULL) == GPIO_PULLDOWN))
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/** @defgroup GPIO_Private_Functions GPIO Private Functions
* @{
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32F1xx_HAL_GPIO_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_gpio_ex.h
* @author MCD Application Team
* @brief Header file of GPIO HAL Extension module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32F1xx_HAL_GPIO_EX_H
#define STM32F1xx_HAL_GPIO_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup GPIOEx GPIOEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup GPIOEx_Exported_Constants GPIOEx Exported Constants
* @{
*/
/** @defgroup GPIOEx_EVENTOUT EVENTOUT Cortex Configuration
* @brief This section propose definition to use the Cortex EVENTOUT signal.
* @{
*/
/** @defgroup GPIOEx_EVENTOUT_PIN EVENTOUT Pin
* @{
*/
#define AFIO_EVENTOUT_PIN_0 AFIO_EVCR_PIN_PX0 /*!< EVENTOUT on pin 0 */
#define AFIO_EVENTOUT_PIN_1 AFIO_EVCR_PIN_PX1 /*!< EVENTOUT on pin 1 */
#define AFIO_EVENTOUT_PIN_2 AFIO_EVCR_PIN_PX2 /*!< EVENTOUT on pin 2 */
#define AFIO_EVENTOUT_PIN_3 AFIO_EVCR_PIN_PX3 /*!< EVENTOUT on pin 3 */
#define AFIO_EVENTOUT_PIN_4 AFIO_EVCR_PIN_PX4 /*!< EVENTOUT on pin 4 */
#define AFIO_EVENTOUT_PIN_5 AFIO_EVCR_PIN_PX5 /*!< EVENTOUT on pin 5 */
#define AFIO_EVENTOUT_PIN_6 AFIO_EVCR_PIN_PX6 /*!< EVENTOUT on pin 6 */
#define AFIO_EVENTOUT_PIN_7 AFIO_EVCR_PIN_PX7 /*!< EVENTOUT on pin 7 */
#define AFIO_EVENTOUT_PIN_8 AFIO_EVCR_PIN_PX8 /*!< EVENTOUT on pin 8 */
#define AFIO_EVENTOUT_PIN_9 AFIO_EVCR_PIN_PX9 /*!< EVENTOUT on pin 9 */
#define AFIO_EVENTOUT_PIN_10 AFIO_EVCR_PIN_PX10 /*!< EVENTOUT on pin 10 */
#define AFIO_EVENTOUT_PIN_11 AFIO_EVCR_PIN_PX11 /*!< EVENTOUT on pin 11 */
#define AFIO_EVENTOUT_PIN_12 AFIO_EVCR_PIN_PX12 /*!< EVENTOUT on pin 12 */
#define AFIO_EVENTOUT_PIN_13 AFIO_EVCR_PIN_PX13 /*!< EVENTOUT on pin 13 */
#define AFIO_EVENTOUT_PIN_14 AFIO_EVCR_PIN_PX14 /*!< EVENTOUT on pin 14 */
#define AFIO_EVENTOUT_PIN_15 AFIO_EVCR_PIN_PX15 /*!< EVENTOUT on pin 15 */
#define IS_AFIO_EVENTOUT_PIN(__PIN__) (((__PIN__) == AFIO_EVENTOUT_PIN_0) || \
((__PIN__) == AFIO_EVENTOUT_PIN_1) || \
((__PIN__) == AFIO_EVENTOUT_PIN_2) || \
((__PIN__) == AFIO_EVENTOUT_PIN_3) || \
((__PIN__) == AFIO_EVENTOUT_PIN_4) || \
((__PIN__) == AFIO_EVENTOUT_PIN_5) || \
((__PIN__) == AFIO_EVENTOUT_PIN_6) || \
((__PIN__) == AFIO_EVENTOUT_PIN_7) || \
((__PIN__) == AFIO_EVENTOUT_PIN_8) || \
((__PIN__) == AFIO_EVENTOUT_PIN_9) || \
((__PIN__) == AFIO_EVENTOUT_PIN_10) || \
((__PIN__) == AFIO_EVENTOUT_PIN_11) || \
((__PIN__) == AFIO_EVENTOUT_PIN_12) || \
((__PIN__) == AFIO_EVENTOUT_PIN_13) || \
((__PIN__) == AFIO_EVENTOUT_PIN_14) || \
((__PIN__) == AFIO_EVENTOUT_PIN_15))
/**
* @}
*/
/** @defgroup GPIOEx_EVENTOUT_PORT EVENTOUT Port
* @{
*/
#define AFIO_EVENTOUT_PORT_A AFIO_EVCR_PORT_PA /*!< EVENTOUT on port A */
#define AFIO_EVENTOUT_PORT_B AFIO_EVCR_PORT_PB /*!< EVENTOUT on port B */
#define AFIO_EVENTOUT_PORT_C AFIO_EVCR_PORT_PC /*!< EVENTOUT on port C */
#define AFIO_EVENTOUT_PORT_D AFIO_EVCR_PORT_PD /*!< EVENTOUT on port D */
#define AFIO_EVENTOUT_PORT_E AFIO_EVCR_PORT_PE /*!< EVENTOUT on port E */
#define IS_AFIO_EVENTOUT_PORT(__PORT__) (((__PORT__) == AFIO_EVENTOUT_PORT_A) || \
((__PORT__) == AFIO_EVENTOUT_PORT_B) || \
((__PORT__) == AFIO_EVENTOUT_PORT_C) || \
((__PORT__) == AFIO_EVENTOUT_PORT_D) || \
((__PORT__) == AFIO_EVENTOUT_PORT_E))
/**
* @}
*/
/**
* @}
*/
/** @defgroup GPIOEx_AFIO_AF_REMAPPING Alternate Function Remapping
* @brief This section propose definition to remap the alternate function to some other port/pins.
* @{
*/
/**
* @brief Enable the remapping of SPI1 alternate function NSS, SCK, MISO and MOSI.
* @note ENABLE: Remap (NSS/PA15, SCK/PB3, MISO/PB4, MOSI/PB5)
* @retval None
*/
#define __HAL_AFIO_REMAP_SPI1_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_SPI1_REMAP)
/**
* @brief Disable the remapping of SPI1 alternate function NSS, SCK, MISO and MOSI.
* @note DISABLE: No remap (NSS/PA4, SCK/PA5, MISO/PA6, MOSI/PA7)
* @retval None
*/
#define __HAL_AFIO_REMAP_SPI1_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_SPI1_REMAP)
/**
* @brief Enable the remapping of I2C1 alternate function SCL and SDA.
* @note ENABLE: Remap (SCL/PB8, SDA/PB9)
* @retval None
*/
#define __HAL_AFIO_REMAP_I2C1_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_I2C1_REMAP)
/**
* @brief Disable the remapping of I2C1 alternate function SCL and SDA.
* @note DISABLE: No remap (SCL/PB6, SDA/PB7)
* @retval None
*/
#define __HAL_AFIO_REMAP_I2C1_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_I2C1_REMAP)
/**
* @brief Enable the remapping of USART1 alternate function TX and RX.
* @note ENABLE: Remap (TX/PB6, RX/PB7)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART1_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_USART1_REMAP)
/**
* @brief Disable the remapping of USART1 alternate function TX and RX.
* @note DISABLE: No remap (TX/PA9, RX/PA10)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART1_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_USART1_REMAP)
/**
* @brief Enable the remapping of USART2 alternate function CTS, RTS, CK, TX and RX.
* @note ENABLE: Remap (CTS/PD3, RTS/PD4, TX/PD5, RX/PD6, CK/PD7)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART2_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_USART2_REMAP)
/**
* @brief Disable the remapping of USART2 alternate function CTS, RTS, CK, TX and RX.
* @note DISABLE: No remap (CTS/PA0, RTS/PA1, TX/PA2, RX/PA3, CK/PA4)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART2_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_USART2_REMAP)
/**
* @brief Enable the remapping of USART3 alternate function CTS, RTS, CK, TX and RX.
* @note ENABLE: Full remap (TX/PD8, RX/PD9, CK/PD10, CTS/PD11, RTS/PD12)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART3_ENABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_USART3_REMAP_FULLREMAP, AFIO_MAPR_USART3_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of USART3 alternate function CTS, RTS, CK, TX and RX.
* @note PARTIAL: Partial remap (TX/PC10, RX/PC11, CK/PC12, CTS/PB13, RTS/PB14)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART3_PARTIAL() AFIO_REMAP_PARTIAL(AFIO_MAPR_USART3_REMAP_PARTIALREMAP, AFIO_MAPR_USART3_REMAP_FULLREMAP)
/**
* @brief Disable the remapping of USART3 alternate function CTS, RTS, CK, TX and RX.
* @note DISABLE: No remap (TX/PB10, RX/PB11, CK/PB12, CTS/PB13, RTS/PB14)
* @retval None
*/
#define __HAL_AFIO_REMAP_USART3_DISABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_USART3_REMAP_NOREMAP, AFIO_MAPR_USART3_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM1 alternate function channels 1 to 4, 1N to 3N, external trigger (ETR) and Break input (BKIN)
* @note ENABLE: Full remap (ETR/PE7, CH1/PE9, CH2/PE11, CH3/PE13, CH4/PE14, BKIN/PE15, CH1N/PE8, CH2N/PE10, CH3N/PE12)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM1_ENABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM1_REMAP_FULLREMAP, AFIO_MAPR_TIM1_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM1 alternate function channels 1 to 4, 1N to 3N, external trigger (ETR) and Break input (BKIN)
* @note PARTIAL: Partial remap (ETR/PA12, CH1/PA8, CH2/PA9, CH3/PA10, CH4/PA11, BKIN/PA6, CH1N/PA7, CH2N/PB0, CH3N/PB1)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM1_PARTIAL() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM1_REMAP_PARTIALREMAP, AFIO_MAPR_TIM1_REMAP_FULLREMAP)
/**
* @brief Disable the remapping of TIM1 alternate function channels 1 to 4, 1N to 3N, external trigger (ETR) and Break input (BKIN)
* @note DISABLE: No remap (ETR/PA12, CH1/PA8, CH2/PA9, CH3/PA10, CH4/PA11, BKIN/PB12, CH1N/PB13, CH2N/PB14, CH3N/PB15)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM1_DISABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM1_REMAP_NOREMAP, AFIO_MAPR_TIM1_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM2 alternate function channels 1 to 4 and external trigger (ETR)
* @note ENABLE: Full remap (CH1/ETR/PA15, CH2/PB3, CH3/PB10, CH4/PB11)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM2_ENABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM2_REMAP_FULLREMAP, AFIO_MAPR_TIM2_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM2 alternate function channels 1 to 4 and external trigger (ETR)
* @note PARTIAL_2: Partial remap (CH1/ETR/PA0, CH2/PA1, CH3/PB10, CH4/PB11)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM2_PARTIAL_2() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM2_REMAP_PARTIALREMAP2, AFIO_MAPR_TIM2_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM2 alternate function channels 1 to 4 and external trigger (ETR)
* @note PARTIAL_1: Partial remap (CH1/ETR/PA15, CH2/PB3, CH3/PA2, CH4/PA3)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM2_PARTIAL_1() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM2_REMAP_PARTIALREMAP1, AFIO_MAPR_TIM2_REMAP_FULLREMAP)
/**
* @brief Disable the remapping of TIM2 alternate function channels 1 to 4 and external trigger (ETR)
* @note DISABLE: No remap (CH1/ETR/PA0, CH2/PA1, CH3/PA2, CH4/PA3)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM2_DISABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM2_REMAP_NOREMAP, AFIO_MAPR_TIM2_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM3 alternate function channels 1 to 4
* @note ENABLE: Full remap (CH1/PC6, CH2/PC7, CH3/PC8, CH4/PC9)
* @note TIM3_ETR on PE0 is not re-mapped.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM3_ENABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM3_REMAP_FULLREMAP, AFIO_MAPR_TIM3_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM3 alternate function channels 1 to 4
* @note PARTIAL: Partial remap (CH1/PB4, CH2/PB5, CH3/PB0, CH4/PB1)
* @note TIM3_ETR on PE0 is not re-mapped.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM3_PARTIAL() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM3_REMAP_PARTIALREMAP, AFIO_MAPR_TIM3_REMAP_FULLREMAP)
/**
* @brief Disable the remapping of TIM3 alternate function channels 1 to 4
* @note DISABLE: No remap (CH1/PA6, CH2/PA7, CH3/PB0, CH4/PB1)
* @note TIM3_ETR on PE0 is not re-mapped.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM3_DISABLE() AFIO_REMAP_PARTIAL(AFIO_MAPR_TIM3_REMAP_NOREMAP, AFIO_MAPR_TIM3_REMAP_FULLREMAP)
/**
* @brief Enable the remapping of TIM4 alternate function channels 1 to 4.
* @note ENABLE: Full remap (TIM4_CH1/PD12, TIM4_CH2/PD13, TIM4_CH3/PD14, TIM4_CH4/PD15)
* @note TIM4_ETR on PE0 is not re-mapped.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM4_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_TIM4_REMAP)
/**
* @brief Disable the remapping of TIM4 alternate function channels 1 to 4.
* @note DISABLE: No remap (TIM4_CH1/PB6, TIM4_CH2/PB7, TIM4_CH3/PB8, TIM4_CH4/PB9)
* @note TIM4_ETR on PE0 is not re-mapped.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM4_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_TIM4_REMAP)
#if defined(AFIO_MAPR_CAN_REMAP_REMAP1)
/**
* @brief Enable or disable the remapping of CAN alternate function CAN_RX and CAN_TX in devices with a single CAN interface.
* @note CASE 1: CAN_RX mapped to PA11, CAN_TX mapped to PA12
* @retval None
*/
#define __HAL_AFIO_REMAP_CAN1_1() AFIO_REMAP_PARTIAL(AFIO_MAPR_CAN_REMAP_REMAP1, AFIO_MAPR_CAN_REMAP)
/**
* @brief Enable or disable the remapping of CAN alternate function CAN_RX and CAN_TX in devices with a single CAN interface.
* @note CASE 2: CAN_RX mapped to PB8, CAN_TX mapped to PB9 (not available on 36-pin package)
* @retval None
*/
#define __HAL_AFIO_REMAP_CAN1_2() AFIO_REMAP_PARTIAL(AFIO_MAPR_CAN_REMAP_REMAP2, AFIO_MAPR_CAN_REMAP)
/**
* @brief Enable or disable the remapping of CAN alternate function CAN_RX and CAN_TX in devices with a single CAN interface.
* @note CASE 3: CAN_RX mapped to PD0, CAN_TX mapped to PD1
* @retval None
*/
#define __HAL_AFIO_REMAP_CAN1_3() AFIO_REMAP_PARTIAL(AFIO_MAPR_CAN_REMAP_REMAP3, AFIO_MAPR_CAN_REMAP)
#endif
/**
* @brief Enable the remapping of PD0 and PD1. When the HSE oscillator is not used
* (application running on internal 8 MHz RC) PD0 and PD1 can be mapped on OSC_IN and
* OSC_OUT. This is available only on 36, 48 and 64 pins packages (PD0 and PD1 are available
* on 100-pin and 144-pin packages, no need for remapping).
* @note ENABLE: PD0 remapped on OSC_IN, PD1 remapped on OSC_OUT.
* @retval None
*/
#define __HAL_AFIO_REMAP_PD01_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_PD01_REMAP)
/**
* @brief Disable the remapping of PD0 and PD1. When the HSE oscillator is not used
* (application running on internal 8 MHz RC) PD0 and PD1 can be mapped on OSC_IN and
* OSC_OUT. This is available only on 36, 48 and 64 pins packages (PD0 and PD1 are available
* on 100-pin and 144-pin packages, no need for remapping).
* @note DISABLE: No remapping of PD0 and PD1
* @retval None
*/
#define __HAL_AFIO_REMAP_PD01_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_PD01_REMAP)
#if defined(AFIO_MAPR_TIM5CH4_IREMAP)
/**
* @brief Enable the remapping of TIM5CH4.
* @note ENABLE: LSI internal clock is connected to TIM5_CH4 input for calibration purpose.
* @note This function is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM5CH4_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_TIM5CH4_IREMAP)
/**
* @brief Disable the remapping of TIM5CH4.
* @note DISABLE: TIM5_CH4 is connected to PA3
* @note This function is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM5CH4_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_TIM5CH4_IREMAP)
#endif
#if defined(AFIO_MAPR_ETH_REMAP)
/**
* @brief Enable the remapping of Ethernet MAC connections with the PHY.
* @note ENABLE: Remap (RX_DV-CRS_DV/PD8, RXD0/PD9, RXD1/PD10, RXD2/PD11, RXD3/PD12)
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_ETH_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_ETH_REMAP)
/**
* @brief Disable the remapping of Ethernet MAC connections with the PHY.
* @note DISABLE: No remap (RX_DV-CRS_DV/PA7, RXD0/PC4, RXD1/PC5, RXD2/PB0, RXD3/PB1)
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_ETH_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_ETH_REMAP)
#endif
#if defined(AFIO_MAPR_CAN2_REMAP)
/**
* @brief Enable the remapping of CAN2 alternate function CAN2_RX and CAN2_TX.
* @note ENABLE: Remap (CAN2_RX/PB5, CAN2_TX/PB6)
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_CAN2_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_CAN2_REMAP)
/**
* @brief Disable the remapping of CAN2 alternate function CAN2_RX and CAN2_TX.
* @note DISABLE: No remap (CAN2_RX/PB12, CAN2_TX/PB13)
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_CAN2_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_CAN2_REMAP)
#endif
#if defined(AFIO_MAPR_MII_RMII_SEL)
/**
* @brief Configures the Ethernet MAC internally for use with an external MII or RMII PHY.
* @note ETH_RMII: Configure Ethernet MAC for connection with an RMII PHY
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_ETH_RMII() AFIO_REMAP_ENABLE(AFIO_MAPR_MII_RMII_SEL)
/**
* @brief Configures the Ethernet MAC internally for use with an external MII or RMII PHY.
* @note ETH_MII: Configure Ethernet MAC for connection with an MII PHY
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_ETH_MII() AFIO_REMAP_DISABLE(AFIO_MAPR_MII_RMII_SEL)
#endif
/**
* @brief Enable the remapping of ADC1_ETRGINJ (ADC 1 External trigger injected conversion).
* @note ENABLE: ADC1 External Event injected conversion is connected to TIM8 Channel4.
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC1_ETRGINJ_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_ADC1_ETRGINJ_REMAP)
/**
* @brief Disable the remapping of ADC1_ETRGINJ (ADC 1 External trigger injected conversion).
* @note DISABLE: ADC1 External trigger injected conversion is connected to EXTI15
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC1_ETRGINJ_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_ADC1_ETRGINJ_REMAP)
/**
* @brief Enable the remapping of ADC1_ETRGREG (ADC 1 External trigger regular conversion).
* @note ENABLE: ADC1 External Event regular conversion is connected to TIM8 TRG0.
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC1_ETRGREG_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_ADC1_ETRGREG_REMAP)
/**
* @brief Disable the remapping of ADC1_ETRGREG (ADC 1 External trigger regular conversion).
* @note DISABLE: ADC1 External trigger regular conversion is connected to EXTI11
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC1_ETRGREG_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_ADC1_ETRGREG_REMAP)
#if defined(AFIO_MAPR_ADC2_ETRGINJ_REMAP)
/**
* @brief Enable the remapping of ADC2_ETRGREG (ADC 2 External trigger injected conversion).
* @note ENABLE: ADC2 External Event injected conversion is connected to TIM8 Channel4.
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC2_ETRGINJ_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_ADC2_ETRGINJ_REMAP)
/**
* @brief Disable the remapping of ADC2_ETRGREG (ADC 2 External trigger injected conversion).
* @note DISABLE: ADC2 External trigger injected conversion is connected to EXTI15
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC2_ETRGINJ_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_ADC2_ETRGINJ_REMAP)
#endif
#if defined (AFIO_MAPR_ADC2_ETRGREG_REMAP)
/**
* @brief Enable the remapping of ADC2_ETRGREG (ADC 2 External trigger regular conversion).
* @note ENABLE: ADC2 External Event regular conversion is connected to TIM8 TRG0.
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC2_ETRGREG_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_ADC2_ETRGREG_REMAP)
/**
* @brief Disable the remapping of ADC2_ETRGREG (ADC 2 External trigger regular conversion).
* @note DISABLE: ADC2 External trigger regular conversion is connected to EXTI11
* @retval None
*/
#define __HAL_AFIO_REMAP_ADC2_ETRGREG_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_ADC2_ETRGREG_REMAP)
#endif
/**
* @brief Enable the Serial wire JTAG configuration
* @note ENABLE: Full SWJ (JTAG-DP + SW-DP): Reset State
* @retval None
*/
#define __HAL_AFIO_REMAP_SWJ_ENABLE() AFIO_DBGAFR_CONFIG(AFIO_MAPR_SWJ_CFG_RESET)
/**
* @brief Enable the Serial wire JTAG configuration
* @note NONJTRST: Full SWJ (JTAG-DP + SW-DP) but without NJTRST
* @retval None
*/
#define __HAL_AFIO_REMAP_SWJ_NONJTRST() AFIO_DBGAFR_CONFIG(AFIO_MAPR_SWJ_CFG_NOJNTRST)
/**
* @brief Enable the Serial wire JTAG configuration
* @note NOJTAG: JTAG-DP Disabled and SW-DP Enabled
* @retval None
*/
#define __HAL_AFIO_REMAP_SWJ_NOJTAG() AFIO_DBGAFR_CONFIG(AFIO_MAPR_SWJ_CFG_JTAGDISABLE)
/**
* @brief Disable the Serial wire JTAG configuration
* @note DISABLE: JTAG-DP Disabled and SW-DP Disabled
* @retval None
*/
#define __HAL_AFIO_REMAP_SWJ_DISABLE() AFIO_DBGAFR_CONFIG(AFIO_MAPR_SWJ_CFG_DISABLE)
#if defined(AFIO_MAPR_SPI3_REMAP)
/**
* @brief Enable the remapping of SPI3 alternate functions SPI3_NSS/I2S3_WS, SPI3_SCK/I2S3_CK, SPI3_MISO, SPI3_MOSI/I2S3_SD.
* @note ENABLE: Remap (SPI3_NSS-I2S3_WS/PA4, SPI3_SCK-I2S3_CK/PC10, SPI3_MISO/PC11, SPI3_MOSI-I2S3_SD/PC12)
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_SPI3_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_SPI3_REMAP)
/**
* @brief Disable the remapping of SPI3 alternate functions SPI3_NSS/I2S3_WS, SPI3_SCK/I2S3_CK, SPI3_MISO, SPI3_MOSI/I2S3_SD.
* @note DISABLE: No remap (SPI3_NSS-I2S3_WS/PA15, SPI3_SCK-I2S3_CK/PB3, SPI3_MISO/PB4, SPI3_MOSI-I2S3_SD/PB5).
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_REMAP_SPI3_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_SPI3_REMAP)
#endif
#if defined(AFIO_MAPR_TIM2ITR1_IREMAP)
/**
* @brief Control of TIM2_ITR1 internal mapping.
* @note TO_USB: Connect USB OTG SOF (Start of Frame) output to TIM2_ITR1 for calibration purposes.
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_TIM2ITR1_TO_USB() AFIO_REMAP_ENABLE(AFIO_MAPR_TIM2ITR1_IREMAP)
/**
* @brief Control of TIM2_ITR1 internal mapping.
* @note TO_ETH: Connect TIM2_ITR1 internally to the Ethernet PTP output for calibration purposes.
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_TIM2ITR1_TO_ETH() AFIO_REMAP_DISABLE(AFIO_MAPR_TIM2ITR1_IREMAP)
#endif
#if defined(AFIO_MAPR_PTP_PPS_REMAP)
/**
* @brief Enable the remapping of ADC2_ETRGREG (ADC 2 External trigger regular conversion).
* @note ENABLE: PTP_PPS is output on PB5 pin.
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_ETH_PTP_PPS_ENABLE() AFIO_REMAP_ENABLE(AFIO_MAPR_PTP_PPS_REMAP)
/**
* @brief Disable the remapping of ADC2_ETRGREG (ADC 2 External trigger regular conversion).
* @note DISABLE: PTP_PPS not output on PB5 pin.
* @note This bit is available only in connectivity line devices and is reserved otherwise.
* @retval None
*/
#define __HAL_AFIO_ETH_PTP_PPS_DISABLE() AFIO_REMAP_DISABLE(AFIO_MAPR_PTP_PPS_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM9_REMAP)
/**
* @brief Enable the remapping of TIM9_CH1 and TIM9_CH2.
* @note ENABLE: Remap (TIM9_CH1 on PE5 and TIM9_CH2 on PE6).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM9_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM9_REMAP)
/**
* @brief Disable the remapping of TIM9_CH1 and TIM9_CH2.
* @note DISABLE: No remap (TIM9_CH1 on PA2 and TIM9_CH2 on PA3).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM9_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM9_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM10_REMAP)
/**
* @brief Enable the remapping of TIM10_CH1.
* @note ENABLE: Remap (TIM10_CH1 on PF6).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM10_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM10_REMAP)
/**
* @brief Disable the remapping of TIM10_CH1.
* @note DISABLE: No remap (TIM10_CH1 on PB8).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM10_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM10_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM11_REMAP)
/**
* @brief Enable the remapping of TIM11_CH1.
* @note ENABLE: Remap (TIM11_CH1 on PF7).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM11_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM11_REMAP)
/**
* @brief Disable the remapping of TIM11_CH1.
* @note DISABLE: No remap (TIM11_CH1 on PB9).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM11_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM11_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM13_REMAP)
/**
* @brief Enable the remapping of TIM13_CH1.
* @note ENABLE: Remap STM32F100:(TIM13_CH1 on PF8). Others:(TIM13_CH1 on PB0).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM13_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM13_REMAP)
/**
* @brief Disable the remapping of TIM13_CH1.
* @note DISABLE: No remap STM32F100:(TIM13_CH1 on PA6). Others:(TIM13_CH1 on PC8).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM13_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM13_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM14_REMAP)
/**
* @brief Enable the remapping of TIM14_CH1.
* @note ENABLE: Remap STM32F100:(TIM14_CH1 on PB1). Others:(TIM14_CH1 on PF9).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM14_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM14_REMAP)
/**
* @brief Disable the remapping of TIM14_CH1.
* @note DISABLE: No remap STM32F100:(TIM14_CH1 on PC9). Others:(TIM14_CH1 on PA7).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM14_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM14_REMAP)
#endif
#if defined(AFIO_MAPR2_FSMC_NADV_REMAP)
/**
* @brief Controls the use of the optional FSMC_NADV signal.
* @note DISCONNECTED: The NADV signal is not connected. The I/O pin can be used by another peripheral.
* @retval None
*/
#define __HAL_AFIO_FSMCNADV_DISCONNECTED() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_FSMC_NADV_REMAP)
/**
* @brief Controls the use of the optional FSMC_NADV signal.
* @note CONNECTED: The NADV signal is connected to the output (default).
* @retval None
*/
#define __HAL_AFIO_FSMCNADV_CONNECTED() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_FSMC_NADV_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM15_REMAP)
/**
* @brief Enable the remapping of TIM15_CH1 and TIM15_CH2.
* @note ENABLE: Remap (TIM15_CH1 on PB14 and TIM15_CH2 on PB15).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM15_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM15_REMAP)
/**
* @brief Disable the remapping of TIM15_CH1 and TIM15_CH2.
* @note DISABLE: No remap (TIM15_CH1 on PA2 and TIM15_CH2 on PA3).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM15_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM15_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM16_REMAP)
/**
* @brief Enable the remapping of TIM16_CH1.
* @note ENABLE: Remap (TIM16_CH1 on PA6).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM16_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM16_REMAP)
/**
* @brief Disable the remapping of TIM16_CH1.
* @note DISABLE: No remap (TIM16_CH1 on PB8).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM16_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM16_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM17_REMAP)
/**
* @brief Enable the remapping of TIM17_CH1.
* @note ENABLE: Remap (TIM17_CH1 on PA7).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM17_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM17_REMAP)
/**
* @brief Disable the remapping of TIM17_CH1.
* @note DISABLE: No remap (TIM17_CH1 on PB9).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM17_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM17_REMAP)
#endif
#if defined(AFIO_MAPR2_CEC_REMAP)
/**
* @brief Enable the remapping of CEC.
* @note ENABLE: Remap (CEC on PB10).
* @retval None
*/
#define __HAL_AFIO_REMAP_CEC_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_CEC_REMAP)
/**
* @brief Disable the remapping of CEC.
* @note DISABLE: No remap (CEC on PB8).
* @retval None
*/
#define __HAL_AFIO_REMAP_CEC_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_CEC_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM1_DMA_REMAP)
/**
* @brief Controls the mapping of the TIM1_CH1 TIM1_CH2 DMA requests onto the DMA1 channels.
* @note ENABLE: Remap (TIM1_CH1 DMA request/DMA1 Channel6, TIM1_CH2 DMA request/DMA1 Channel6)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM1DMA_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM1_DMA_REMAP)
/**
* @brief Controls the mapping of the TIM1_CH1 TIM1_CH2 DMA requests onto the DMA1 channels.
* @note DISABLE: No remap (TIM1_CH1 DMA request/DMA1 Channel2, TIM1_CH2 DMA request/DMA1 Channel3).
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM1DMA_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM1_DMA_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM67_DAC_DMA_REMAP)
/**
* @brief Controls the mapping of the TIM6_DAC1 and TIM7_DAC2 DMA requests onto the DMA1 channels.
* @note ENABLE: Remap (TIM6_DAC1 DMA request/DMA1 Channel3, TIM7_DAC2 DMA request/DMA1 Channel4)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM67DACDMA_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM67_DAC_DMA_REMAP)
/**
* @brief Controls the mapping of the TIM6_DAC1 and TIM7_DAC2 DMA requests onto the DMA1 channels.
* @note DISABLE: No remap (TIM6_DAC1 DMA request/DMA2 Channel3, TIM7_DAC2 DMA request/DMA2 Channel4)
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM67DACDMA_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM67_DAC_DMA_REMAP)
#endif
#if defined(AFIO_MAPR2_TIM12_REMAP)
/**
* @brief Enable the remapping of TIM12_CH1 and TIM12_CH2.
* @note ENABLE: Remap (TIM12_CH1 on PB12 and TIM12_CH2 on PB13).
* @note This bit is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM12_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM12_REMAP)
/**
* @brief Disable the remapping of TIM12_CH1 and TIM12_CH2.
* @note DISABLE: No remap (TIM12_CH1 on PC4 and TIM12_CH2 on PC5).
* @note This bit is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_TIM12_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_TIM12_REMAP)
#endif
#if defined(AFIO_MAPR2_MISC_REMAP)
/**
* @brief Miscellaneous features remapping.
* This bit is set and cleared by software. It controls miscellaneous features.
* The DMA2 channel 5 interrupt position in the vector table.
* The timer selection for DAC trigger 3 (TSEL[2:0] = 011, for more details refer to the DAC_CR register).
* @note ENABLE: DMA2 channel 5 interrupt is mapped separately at position 60 and TIM15 TRGO event is
* selected as DAC Trigger 3, TIM15 triggers TIM1/3.
* @note This bit is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_MISC_ENABLE() SET_BIT(AFIO->MAPR2, AFIO_MAPR2_MISC_REMAP)
/**
* @brief Miscellaneous features remapping.
* This bit is set and cleared by software. It controls miscellaneous features.
* The DMA2 channel 5 interrupt position in the vector table.
* The timer selection for DAC trigger 3 (TSEL[2:0] = 011, for more details refer to the DAC_CR register).
* @note DISABLE: DMA2 channel 5 interrupt is mapped with DMA2 channel 4 at position 59, TIM5 TRGO
* event is selected as DAC Trigger 3, TIM5 triggers TIM1/3.
* @note This bit is available only in high density value line devices.
* @retval None
*/
#define __HAL_AFIO_REMAP_MISC_DISABLE() CLEAR_BIT(AFIO->MAPR2, AFIO_MAPR2_MISC_REMAP)
#endif
/**
* @}
*/
/**
* @}
*/
/** @defgroup GPIOEx_Private_Macros GPIOEx Private Macros
* @{
*/
#if defined(STM32F101x6) || defined(STM32F102x6) || defined(STM32F102xB) || defined(STM32F103x6)
#define GPIO_GET_INDEX(__GPIOx__) (((__GPIOx__) == (GPIOA))? 0uL :\
((__GPIOx__) == (GPIOB))? 1uL :\
((__GPIOx__) == (GPIOC))? 2uL :3uL)
#elif defined(STM32F100xB) || defined(STM32F101xB) || defined(STM32F103xB) || defined(STM32F105xC) || defined(STM32F107xC)
#define GPIO_GET_INDEX(__GPIOx__) (((__GPIOx__) == (GPIOA))? 0uL :\
((__GPIOx__) == (GPIOB))? 1uL :\
((__GPIOx__) == (GPIOC))? 2uL :\
((__GPIOx__) == (GPIOD))? 3uL :4uL)
#elif defined(STM32F100xE) || defined(STM32F101xE) || defined(STM32F101xG) || defined(STM32F103xE) || defined(STM32F103xG)
#define GPIO_GET_INDEX(__GPIOx__) (((__GPIOx__) == (GPIOA))? 0uL :\
((__GPIOx__) == (GPIOB))? 1uL :\
((__GPIOx__) == (GPIOC))? 2uL :\
((__GPIOx__) == (GPIOD))? 3uL :\
((__GPIOx__) == (GPIOE))? 4uL :\
((__GPIOx__) == (GPIOF))? 5uL :6uL)
#endif
#define AFIO_REMAP_ENABLE(REMAP_PIN) do{ uint32_t tmpreg = AFIO->MAPR; \
tmpreg |= AFIO_MAPR_SWJ_CFG; \
tmpreg |= REMAP_PIN; \
AFIO->MAPR = tmpreg; \
}while(0u)
#define AFIO_REMAP_DISABLE(REMAP_PIN) do{ uint32_t tmpreg = AFIO->MAPR; \
tmpreg |= AFIO_MAPR_SWJ_CFG; \
tmpreg &= ~REMAP_PIN; \
AFIO->MAPR = tmpreg; \
}while(0u)
#define AFIO_REMAP_PARTIAL(REMAP_PIN, REMAP_PIN_MASK) do{ uint32_t tmpreg = AFIO->MAPR; \
tmpreg &= ~REMAP_PIN_MASK; \
tmpreg |= AFIO_MAPR_SWJ_CFG; \
tmpreg |= REMAP_PIN; \
AFIO->MAPR = tmpreg; \
}while(0u)
#define AFIO_DBGAFR_CONFIG(DBGAFR_SWJCFG) do{ uint32_t tmpreg = AFIO->MAPR; \
tmpreg &= ~AFIO_MAPR_SWJ_CFG_Msk; \
tmpreg |= DBGAFR_SWJCFG; \
AFIO->MAPR = tmpreg; \
}while(0u)
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup GPIOEx_Exported_Functions
* @{
*/
/** @addtogroup GPIOEx_Exported_Functions_Group1
* @{
*/
void HAL_GPIOEx_ConfigEventout(uint32_t GPIO_PortSource, uint32_t GPIO_PinSource);
void HAL_GPIOEx_EnableEventout(void);
void HAL_GPIOEx_DisableEventout(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32F1xx_HAL_GPIO_EX_H */

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Drivers/STM32F1xx_HAL_Driver/Inc/stm32f1xx_hal_pwr.h Normal file
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@ -0,0 +1,385 @@
/**
******************************************************************************
* @file stm32f1xx_hal_pwr.h
* @author MCD Application Team
* @brief Header file of PWR HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32F1xx_HAL_PWR_H
#define __STM32F1xx_HAL_PWR_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup PWR
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup PWR_Exported_Types PWR Exported Types
* @{
*/
/**
* @brief PWR PVD configuration structure definition
*/
typedef struct
{
uint32_t PVDLevel; /*!< PVDLevel: Specifies the PVD detection level.
This parameter can be a value of @ref PWR_PVD_detection_level */
uint32_t Mode; /*!< Mode: Specifies the operating mode for the selected pins.
This parameter can be a value of @ref PWR_PVD_Mode */
}PWR_PVDTypeDef;
/**
* @}
*/
/* Internal constants --------------------------------------------------------*/
/** @addtogroup PWR_Private_Constants
* @{
*/
#define PWR_EXTI_LINE_PVD ((uint32_t)0x00010000) /*!< External interrupt line 16 Connected to the PVD EXTI Line */
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup PWR_Exported_Constants PWR Exported Constants
* @{
*/
/** @defgroup PWR_PVD_detection_level PWR PVD detection level
* @{
*/
#define PWR_PVDLEVEL_0 PWR_CR_PLS_2V2
#define PWR_PVDLEVEL_1 PWR_CR_PLS_2V3
#define PWR_PVDLEVEL_2 PWR_CR_PLS_2V4
#define PWR_PVDLEVEL_3 PWR_CR_PLS_2V5
#define PWR_PVDLEVEL_4 PWR_CR_PLS_2V6
#define PWR_PVDLEVEL_5 PWR_CR_PLS_2V7
#define PWR_PVDLEVEL_6 PWR_CR_PLS_2V8
#define PWR_PVDLEVEL_7 PWR_CR_PLS_2V9
/**
* @}
*/
/** @defgroup PWR_PVD_Mode PWR PVD Mode
* @{
*/
#define PWR_PVD_MODE_NORMAL 0x00000000U /*!< basic mode is used */
#define PWR_PVD_MODE_IT_RISING 0x00010001U /*!< External Interrupt Mode with Rising edge trigger detection */
#define PWR_PVD_MODE_IT_FALLING 0x00010002U /*!< External Interrupt Mode with Falling edge trigger detection */
#define PWR_PVD_MODE_IT_RISING_FALLING 0x00010003U /*!< External Interrupt Mode with Rising/Falling edge trigger detection */
#define PWR_PVD_MODE_EVENT_RISING 0x00020001U /*!< Event Mode with Rising edge trigger detection */
#define PWR_PVD_MODE_EVENT_FALLING 0x00020002U /*!< Event Mode with Falling edge trigger detection */
#define PWR_PVD_MODE_EVENT_RISING_FALLING 0x00020003U /*!< Event Mode with Rising/Falling edge trigger detection */
/**
* @}
*/
/** @defgroup PWR_WakeUp_Pins PWR WakeUp Pins
* @{
*/
#define PWR_WAKEUP_PIN1 PWR_CSR_EWUP
/**
* @}
*/
/** @defgroup PWR_Regulator_state_in_SLEEP_STOP_mode PWR Regulator state in SLEEP/STOP mode
* @{
*/
#define PWR_MAINREGULATOR_ON 0x00000000U
#define PWR_LOWPOWERREGULATOR_ON PWR_CR_LPDS
/**
* @}
*/
/** @defgroup PWR_SLEEP_mode_entry PWR SLEEP mode entry
* @{
*/
#define PWR_SLEEPENTRY_WFI ((uint8_t)0x01)
#define PWR_SLEEPENTRY_WFE ((uint8_t)0x02)
/**
* @}
*/
/** @defgroup PWR_STOP_mode_entry PWR STOP mode entry
* @{
*/
#define PWR_STOPENTRY_WFI ((uint8_t)0x01)
#define PWR_STOPENTRY_WFE ((uint8_t)0x02)
/**
* @}
*/
/** @defgroup PWR_Flag PWR Flag
* @{
*/
#define PWR_FLAG_WU PWR_CSR_WUF
#define PWR_FLAG_SB PWR_CSR_SBF
#define PWR_FLAG_PVDO PWR_CSR_PVDO
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup PWR_Exported_Macros PWR Exported Macros
* @{
*/
/** @brief Check PWR flag is set or not.
* @param __FLAG__: specifies the flag to check.
* This parameter can be one of the following values:
* @arg PWR_FLAG_WU: Wake Up flag. This flag indicates that a wakeup event
* was received from the WKUP pin or from the RTC alarm
* An additional wakeup event is detected if the WKUP pin is enabled
* (by setting the EWUP bit) when the WKUP pin level is already high.
* @arg PWR_FLAG_SB: StandBy flag. This flag indicates that the system was
* resumed from StandBy mode.
* @arg PWR_FLAG_PVDO: PVD Output. This flag is valid only if PVD is enabled
* by the HAL_PWR_EnablePVD() function. The PVD is stopped by Standby mode
* For this reason, this bit is equal to 0 after Standby or reset
* until the PVDE bit is set.
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_PWR_GET_FLAG(__FLAG__) ((PWR->CSR & (__FLAG__)) == (__FLAG__))
/** @brief Clear the PWR's pending flags.
* @param __FLAG__: specifies the flag to clear.
* This parameter can be one of the following values:
* @arg PWR_FLAG_WU: Wake Up flag
* @arg PWR_FLAG_SB: StandBy flag
*/
#define __HAL_PWR_CLEAR_FLAG(__FLAG__) SET_BIT(PWR->CR, ((__FLAG__) << 2))
/**
* @brief Enable interrupt on PVD Exti Line 16.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR, PWR_EXTI_LINE_PVD)
/**
* @brief Disable interrupt on PVD Exti Line 16.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR, PWR_EXTI_LINE_PVD)
/**
* @brief Enable event on PVD Exti Line 16.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR, PWR_EXTI_LINE_PVD)
/**
* @brief Disable event on PVD Exti Line 16.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR, PWR_EXTI_LINE_PVD)
/**
* @brief PVD EXTI line configuration: set falling edge trigger.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR, PWR_EXTI_LINE_PVD)
/**
* @brief Disable the PVD Extended Interrupt Falling Trigger.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR, PWR_EXTI_LINE_PVD)
/**
* @brief PVD EXTI line configuration: set rising edge trigger.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR, PWR_EXTI_LINE_PVD)
/**
* @brief Disable the PVD Extended Interrupt Rising Trigger.
* This parameter can be:
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR, PWR_EXTI_LINE_PVD)
/**
* @brief PVD EXTI line configuration: set rising & falling edge trigger.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_RISING_FALLING_EDGE() __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE();__HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE();
/**
* @brief Disable the PVD Extended Interrupt Rising & Falling Trigger.
* This parameter can be:
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_RISING_FALLING_EDGE() __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE();__HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE();
/**
* @brief Check whether the specified PVD EXTI interrupt flag is set or not.
* @retval EXTI PVD Line Status.
*/
#define __HAL_PWR_PVD_EXTI_GET_FLAG() (EXTI->PR & (PWR_EXTI_LINE_PVD))
/**
* @brief Clear the PVD EXTI flag.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_CLEAR_FLAG() (EXTI->PR = (PWR_EXTI_LINE_PVD))
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None.
*/
#define __HAL_PWR_PVD_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER, PWR_EXTI_LINE_PVD)
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup PWR_Private_Macros PWR Private Macros
* @{
*/
#define IS_PWR_PVD_LEVEL(LEVEL) (((LEVEL) == PWR_PVDLEVEL_0) || ((LEVEL) == PWR_PVDLEVEL_1)|| \
((LEVEL) == PWR_PVDLEVEL_2) || ((LEVEL) == PWR_PVDLEVEL_3)|| \
((LEVEL) == PWR_PVDLEVEL_4) || ((LEVEL) == PWR_PVDLEVEL_5)|| \
((LEVEL) == PWR_PVDLEVEL_6) || ((LEVEL) == PWR_PVDLEVEL_7))
#define IS_PWR_PVD_MODE(MODE) (((MODE) == PWR_PVD_MODE_IT_RISING)|| ((MODE) == PWR_PVD_MODE_IT_FALLING) || \
((MODE) == PWR_PVD_MODE_IT_RISING_FALLING) || ((MODE) == PWR_PVD_MODE_EVENT_RISING) || \
((MODE) == PWR_PVD_MODE_EVENT_FALLING) || ((MODE) == PWR_PVD_MODE_EVENT_RISING_FALLING) || \
((MODE) == PWR_PVD_MODE_NORMAL))
#define IS_PWR_WAKEUP_PIN(PIN) (((PIN) == PWR_WAKEUP_PIN1))
#define IS_PWR_REGULATOR(REGULATOR) (((REGULATOR) == PWR_MAINREGULATOR_ON) || \
((REGULATOR) == PWR_LOWPOWERREGULATOR_ON))
#define IS_PWR_SLEEP_ENTRY(ENTRY) (((ENTRY) == PWR_SLEEPENTRY_WFI) || ((ENTRY) == PWR_SLEEPENTRY_WFE))
#define IS_PWR_STOP_ENTRY(ENTRY) (((ENTRY) == PWR_STOPENTRY_WFI) || ((ENTRY) == PWR_STOPENTRY_WFE))
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup PWR_Exported_Functions PWR Exported Functions
* @{
*/
/** @addtogroup PWR_Exported_Functions_Group1 Initialization and de-initialization functions
* @{
*/
/* Initialization and de-initialization functions *******************************/
void HAL_PWR_DeInit(void);
void HAL_PWR_EnableBkUpAccess(void);
void HAL_PWR_DisableBkUpAccess(void);
/**
* @}
*/
/** @addtogroup PWR_Exported_Functions_Group2 Peripheral Control functions
* @{
*/
/* Peripheral Control functions ************************************************/
void HAL_PWR_ConfigPVD(PWR_PVDTypeDef *sConfigPVD);
/* #define HAL_PWR_ConfigPVD 12*/
void HAL_PWR_EnablePVD(void);
void HAL_PWR_DisablePVD(void);
/* WakeUp pins configuration functions ****************************************/
void HAL_PWR_EnableWakeUpPin(uint32_t WakeUpPinx);
void HAL_PWR_DisableWakeUpPin(uint32_t WakeUpPinx);
/* Low Power modes configuration functions ************************************/
void HAL_PWR_EnterSTOPMode(uint32_t Regulator, uint8_t STOPEntry);
void HAL_PWR_EnterSLEEPMode(uint32_t Regulator, uint8_t SLEEPEntry);
void HAL_PWR_EnterSTANDBYMode(void);
void HAL_PWR_EnableSleepOnExit(void);
void HAL_PWR_DisableSleepOnExit(void);
void HAL_PWR_EnableSEVOnPend(void);
void HAL_PWR_DisableSEVOnPend(void);
void HAL_PWR_PVD_IRQHandler(void);
void HAL_PWR_PVDCallback(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32F1xx_HAL_PWR_H */

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/**
******************************************************************************
* @file stm32f1xx_hal_tim_ex.h
* @author MCD Application Team
* @brief Header file of TIM HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32F1xx_HAL_TIM_EX_H
#define STM32F1xx_HAL_TIM_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal_def.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup TIMEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Types TIM Extended Exported Types
* @{
*/
/**
* @brief TIM Hall sensor Configuration Structure definition
*/
typedef struct
{
uint32_t IC1Polarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Input_Capture_Polarity */
uint32_t IC1Prescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_Input_Capture_Prescaler */
uint32_t IC1Filter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
uint32_t Commutation_Delay; /*!< Specifies the pulse value to be loaded into the Capture Compare Register.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF */
} TIM_HallSensor_InitTypeDef;
/**
* @}
*/
/* End of exported types -----------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Constants TIM Extended Exported Constants
* @{
*/
/** @defgroup TIMEx_Remap TIM Extended Remapping
* @{
*/
/**
* @}
*/
/**
* @}
*/
/* End of exported constants -------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Macros TIM Extended Exported Macros
* @{
*/
/**
* @}
*/
/* End of exported macro -----------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup TIMEx_Private_Macros TIM Extended Private Macros
* @{
*/
/**
* @}
*/
/* End of private macro ------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup TIMEx_Exported_Functions TIM Extended Exported Functions
* @{
*/
/** @addtogroup TIMEx_Exported_Functions_Group1 Extended Timer Hall Sensor functions
* @brief Timer Hall Sensor functions
* @{
*/
/* Timer Hall Sensor functions **********************************************/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Init(TIM_HandleTypeDef *htim, const TIM_HallSensor_InitTypeDef *sConfig);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIMEx_HallSensor_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIMEx_HallSensor_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_IT(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_IT(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_DMA(TIM_HandleTypeDef *htim, uint32_t *pData, uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_DMA(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group2 Extended Timer Complementary Output Compare functions
* @brief Timer Complementary Output Compare functions
* @{
*/
/* Timer Complementary Output Compare functions *****************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group3 Extended Timer Complementary PWM functions
* @brief Timer Complementary PWM functions
* @{
*/
/* Timer Complementary PWM functions ****************************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group4 Extended Timer Complementary One Pulse functions
* @brief Timer Complementary One Pulse functions
* @{
*/
/* Timer Complementary One Pulse functions **********************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group5 Extended Peripheral Control functions
* @brief Peripheral Control functions
* @{
*/
/* Extended Control functions ************************************************/
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_IT(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_DMA(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_MasterConfigSynchronization(TIM_HandleTypeDef *htim,
const TIM_MasterConfigTypeDef *sMasterConfig);
HAL_StatusTypeDef HAL_TIMEx_ConfigBreakDeadTime(TIM_HandleTypeDef *htim,
const TIM_BreakDeadTimeConfigTypeDef *sBreakDeadTimeConfig);
HAL_StatusTypeDef HAL_TIMEx_RemapConfig(TIM_HandleTypeDef *htim, uint32_t Remap);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group6 Extended Callbacks functions
* @brief Extended Callbacks functions
* @{
*/
/* Extended Callback **********************************************************/
void HAL_TIMEx_CommutCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_CommutHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_BreakCallback(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group7 Extended Peripheral State functions
* @brief Extended Peripheral State functions
* @{
*/
/* Extended Peripheral State functions ***************************************/
HAL_TIM_StateTypeDef HAL_TIMEx_HallSensor_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_ChannelStateTypeDef HAL_TIMEx_GetChannelNState(const TIM_HandleTypeDef *htim, uint32_t ChannelN);
/**
* @}
*/
/**
* @}
*/
/* End of exported functions -------------------------------------------------*/
/* Private functions----------------------------------------------------------*/
/** @addtogroup TIMEx_Private_Functions TIM Extended Private Functions
* @{
*/
void TIMEx_DMACommutationCplt(DMA_HandleTypeDef *hdma);
void TIMEx_DMACommutationHalfCplt(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/* End of private functions --------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32F1xx_HAL_TIM_EX_H */

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/**
******************************************************************************
* @file stm32f1xx_hal.c
* @author MCD Application Team
* @brief HAL module driver.
* This is the common part of the HAL initialization
*
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The common HAL driver contains a set of generic and common APIs that can be
used by the PPP peripheral drivers and the user to start using the HAL.
[..]
The HAL contains two APIs' categories:
(+) Common HAL APIs
(+) Services HAL APIs
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup HAL HAL
* @brief HAL module driver.
* @{
*/
#ifdef HAL_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup HAL_Private_Constants HAL Private Constants
* @{
*/
/**
* @brief STM32F1xx HAL Driver version number
*/
#define __STM32F1xx_HAL_VERSION_MAIN (0x01U) /*!< [31:24] main version */
#define __STM32F1xx_HAL_VERSION_SUB1 (0x01U) /*!< [23:16] sub1 version */
#define __STM32F1xx_HAL_VERSION_SUB2 (0x09U) /*!< [15:8] sub2 version */
#define __STM32F1xx_HAL_VERSION_RC (0x00U) /*!< [7:0] release candidate */
#define __STM32F1xx_HAL_VERSION ((__STM32F1xx_HAL_VERSION_MAIN << 24)\
|(__STM32F1xx_HAL_VERSION_SUB1 << 16)\
|(__STM32F1xx_HAL_VERSION_SUB2 << 8 )\
|(__STM32F1xx_HAL_VERSION_RC))
#define IDCODE_DEVID_MASK 0x00000FFFU
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup HAL_Private_Variables HAL Private Variables
* @{
*/
__IO uint32_t uwTick;
uint32_t uwTickPrio = (1UL << __NVIC_PRIO_BITS); /* Invalid PRIO */
HAL_TickFreqTypeDef uwTickFreq = HAL_TICK_FREQ_DEFAULT; /* 1KHz */
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions ---------------------------------------------------------*/
/** @defgroup HAL_Exported_Functions HAL Exported Functions
* @{
*/
/** @defgroup HAL_Exported_Functions_Group1 Initialization and de-initialization Functions
* @brief Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Initializes the Flash interface, the NVIC allocation and initial clock
configuration. It initializes the systick also when timeout is needed
and the backup domain when enabled.
(+) de-Initializes common part of the HAL.
(+) Configure The time base source to have 1ms time base with a dedicated
Tick interrupt priority.
(++) SysTick timer is used by default as source of time base, but user
can eventually implement his proper time base source (a general purpose
timer for example or other time source), keeping in mind that Time base
duration should be kept 1ms since PPP_TIMEOUT_VALUEs are defined and
handled in milliseconds basis.
(++) Time base configuration function (HAL_InitTick ()) is called automatically
at the beginning of the program after reset by HAL_Init() or at any time
when clock is configured, by HAL_RCC_ClockConfig().
(++) Source of time base is configured to generate interrupts at regular
time intervals. Care must be taken if HAL_Delay() is called from a
peripheral ISR process, the Tick interrupt line must have higher priority
(numerically lower) than the peripheral interrupt. Otherwise the caller
ISR process will be blocked.
(++) functions affecting time base configurations are declared as __weak
to make override possible in case of other implementations in user file.
@endverbatim
* @{
*/
/**
* @brief This function is used to initialize the HAL Library; it must be the first
* instruction to be executed in the main program (before to call any other
* HAL function), it performs the following:
* Configure the Flash prefetch.
* Configures the SysTick to generate an interrupt each 1 millisecond,
* which is clocked by the HSI (at this stage, the clock is not yet
* configured and thus the system is running from the internal HSI at 16 MHz).
* Set NVIC Group Priority to 4.
* Calls the HAL_MspInit() callback function defined in user file
* "stm32f1xx_hal_msp.c" to do the global low level hardware initialization
*
* @note SysTick is used as time base for the HAL_Delay() function, the application
* need to ensure that the SysTick time base is always set to 1 millisecond
* to have correct HAL operation.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_Init(void)
{
/* Configure Flash prefetch */
#if (PREFETCH_ENABLE != 0)
#if defined(STM32F101x6) || defined(STM32F101xB) || defined(STM32F101xE) || defined(STM32F101xG) || \
defined(STM32F102x6) || defined(STM32F102xB) || \
defined(STM32F103x6) || defined(STM32F103xB) || defined(STM32F103xE) || defined(STM32F103xG) || \
defined(STM32F105xC) || defined(STM32F107xC)
/* Prefetch buffer is not available on value line devices */
__HAL_FLASH_PREFETCH_BUFFER_ENABLE();
#endif
#endif /* PREFETCH_ENABLE */
/* Set Interrupt Group Priority */
HAL_NVIC_SetPriorityGrouping(NVIC_PRIORITYGROUP_4);
/* Use systick as time base source and configure 1ms tick (default clock after Reset is HSI) */
HAL_InitTick(TICK_INT_PRIORITY);
/* Init the low level hardware */
HAL_MspInit();
/* Return function status */
return HAL_OK;
}
/**
* @brief This function de-Initializes common part of the HAL and stops the systick.
* of time base.
* @note This function is optional.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DeInit(void)
{
/* Reset of all peripherals */
__HAL_RCC_APB1_FORCE_RESET();
__HAL_RCC_APB1_RELEASE_RESET();
__HAL_RCC_APB2_FORCE_RESET();
__HAL_RCC_APB2_RELEASE_RESET();
#if defined(STM32F105xC) || defined(STM32F107xC)
__HAL_RCC_AHB_FORCE_RESET();
__HAL_RCC_AHB_RELEASE_RESET();
#endif
/* De-Init the low level hardware */
HAL_MspDeInit();
/* Return function status */
return HAL_OK;
}
/**
* @brief Initialize the MSP.
* @retval None
*/
__weak void HAL_MspInit(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes the MSP.
* @retval None
*/
__weak void HAL_MspDeInit(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_MspDeInit could be implemented in the user file
*/
}
/**
* @brief This function configures the source of the time base.
* The time source is configured to have 1ms time base with a dedicated
* Tick interrupt priority.
* @note This function is called automatically at the beginning of program after
* reset by HAL_Init() or at any time when clock is reconfigured by HAL_RCC_ClockConfig().
* @note In the default implementation, SysTick timer is the source of time base.
* It is used to generate interrupts at regular time intervals.
* Care must be taken if HAL_Delay() is called from a peripheral ISR process,
* The SysTick interrupt must have higher priority (numerically lower)
* than the peripheral interrupt. Otherwise the caller ISR process will be blocked.
* The function is declared as __weak to be overwritten in case of other
* implementation in user file.
* @param TickPriority Tick interrupt priority.
* @retval HAL status
*/
__weak HAL_StatusTypeDef HAL_InitTick(uint32_t TickPriority)
{
/* Configure the SysTick to have interrupt in 1ms time basis*/
if (HAL_SYSTICK_Config(SystemCoreClock / (1000U / uwTickFreq)) > 0U)
{
return HAL_ERROR;
}
/* Configure the SysTick IRQ priority */
if (TickPriority < (1UL << __NVIC_PRIO_BITS))
{
HAL_NVIC_SetPriority(SysTick_IRQn, TickPriority, 0U);
uwTickPrio = TickPriority;
}
else
{
return HAL_ERROR;
}
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup HAL_Exported_Functions_Group2 HAL Control functions
* @brief HAL Control functions
*
@verbatim
===============================================================================
##### HAL Control functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Provide a tick value in millisecond
(+) Provide a blocking delay in millisecond
(+) Suspend the time base source interrupt
(+) Resume the time base source interrupt
(+) Get the HAL API driver version
(+) Get the device identifier
(+) Get the device revision identifier
(+) Enable/Disable Debug module during SLEEP mode
(+) Enable/Disable Debug module during STOP mode
(+) Enable/Disable Debug module during STANDBY mode
@endverbatim
* @{
*/
/**
* @brief This function is called to increment a global variable "uwTick"
* used as application time base.
* @note In the default implementation, this variable is incremented each 1ms
* in SysTick ISR.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_IncTick(void)
{
uwTick += uwTickFreq;
}
/**
* @brief Provides a tick value in millisecond.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval tick value
*/
__weak uint32_t HAL_GetTick(void)
{
return uwTick;
}
/**
* @brief This function returns a tick priority.
* @retval tick priority
*/
uint32_t HAL_GetTickPrio(void)
{
return uwTickPrio;
}
/**
* @brief Set new tick Freq.
* @retval status
*/
HAL_StatusTypeDef HAL_SetTickFreq(HAL_TickFreqTypeDef Freq)
{
HAL_StatusTypeDef status = HAL_OK;
HAL_TickFreqTypeDef prevTickFreq;
assert_param(IS_TICKFREQ(Freq));
if (uwTickFreq != Freq)
{
/* Back up uwTickFreq frequency */
prevTickFreq = uwTickFreq;
/* Update uwTickFreq global variable used by HAL_InitTick() */
uwTickFreq = Freq;
/* Apply the new tick Freq */
status = HAL_InitTick(uwTickPrio);
if (status != HAL_OK)
{
/* Restore previous tick frequency */
uwTickFreq = prevTickFreq;
}
}
return status;
}
/**
* @brief Return tick frequency.
* @retval Tick frequency.
* Value of @ref HAL_TickFreqTypeDef.
*/
HAL_TickFreqTypeDef HAL_GetTickFreq(void)
{
return uwTickFreq;
}
/**
* @brief This function provides minimum delay (in milliseconds) based
* on variable incremented.
* @note In the default implementation , SysTick timer is the source of time base.
* It is used to generate interrupts at regular time intervals where uwTick
* is incremented.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @param Delay specifies the delay time length, in milliseconds.
* @retval None
*/
__weak void HAL_Delay(uint32_t Delay)
{
uint32_t tickstart = HAL_GetTick();
uint32_t wait = Delay;
/* Add a freq to guarantee minimum wait */
if (wait < HAL_MAX_DELAY)
{
wait += (uint32_t)(uwTickFreq);
}
while ((HAL_GetTick() - tickstart) < wait)
{
}
}
/**
* @brief Suspend Tick increment.
* @note In the default implementation , SysTick timer is the source of time base. It is
* used to generate interrupts at regular time intervals. Once HAL_SuspendTick()
* is called, the SysTick interrupt will be disabled and so Tick increment
* is suspended.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_SuspendTick(void)
{
/* Disable SysTick Interrupt */
CLEAR_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Resume Tick increment.
* @note In the default implementation , SysTick timer is the source of time base. It is
* used to generate interrupts at regular time intervals. Once HAL_ResumeTick()
* is called, the SysTick interrupt will be enabled and so Tick increment
* is resumed.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_ResumeTick(void)
{
/* Enable SysTick Interrupt */
SET_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Returns the HAL revision
* @retval version 0xXYZR (8bits for each decimal, R for RC)
*/
uint32_t HAL_GetHalVersion(void)
{
return __STM32F1xx_HAL_VERSION;
}
/**
* @brief Returns the device revision identifier.
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval Device revision identifier
*/
uint32_t HAL_GetREVID(void)
{
return ((DBGMCU->IDCODE) >> DBGMCU_IDCODE_REV_ID_Pos);
}
/**
* @brief Returns the device identifier.
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval Device identifier
*/
uint32_t HAL_GetDEVID(void)
{
return ((DBGMCU->IDCODE) & IDCODE_DEVID_MASK);
}
/**
* @brief Returns first word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw0(void)
{
return(READ_REG(*((uint32_t *)UID_BASE)));
}
/**
* @brief Returns second word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw1(void)
{
return(READ_REG(*((uint32_t *)(UID_BASE + 4U))));
}
/**
* @brief Returns third word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw2(void)
{
return(READ_REG(*((uint32_t *)(UID_BASE + 8U))));
}
/**
* @brief Enable the Debug Module during SLEEP mode
* @retval None
*/
void HAL_DBGMCU_EnableDBGSleepMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Disable the Debug Module during SLEEP mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval None
*/
void HAL_DBGMCU_DisableDBGSleepMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Enable the Debug Module during STOP mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* Note: On all STM32F1 devices:
* If the system tick timer interrupt is enabled during the Stop mode
* debug (DBG_STOP bit set in the DBGMCU_CR register ), it will wakeup
* the system from Stop mode.
* Workaround: To debug the Stop mode, disable the system tick timer
* interrupt.
* Refer to errata sheet of these devices for more details.
* Note: On all STM32F1 devices:
* If the system tick timer interrupt is enabled during the Stop mode
* debug (DBG_STOP bit set in the DBGMCU_CR register ), it will wakeup
* the system from Stop mode.
* Workaround: To debug the Stop mode, disable the system tick timer
* interrupt.
* Refer to errata sheet of these devices for more details.
* @retval None
*/
void HAL_DBGMCU_EnableDBGStopMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Disable the Debug Module during STOP mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval None
*/
void HAL_DBGMCU_DisableDBGStopMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Enable the Debug Module during STANDBY mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval None
*/
void HAL_DBGMCU_EnableDBGStandbyMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @brief Disable the Debug Module during STANDBY mode
* Note: On devices STM32F10xx8 and STM32F10xxB,
* STM32F101xC/D/E and STM32F103xC/D/E,
* STM32F101xF/G and STM32F103xF/G
* STM32F10xx4 and STM32F10xx6
* Debug registers DBGMCU_IDCODE and DBGMCU_CR are accessible only in
* debug mode (not accessible by the user software in normal mode).
* Refer to errata sheet of these devices for more details.
* @retval None
*/
void HAL_DBGMCU_DisableDBGStandbyMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_cortex.c
* @author MCD Application Team
* @brief CORTEX HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the CORTEX:
* + Initialization and de-initialization functions
* + Peripheral Control functions
*
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
*** How to configure Interrupts using CORTEX HAL driver ***
===========================================================
[..]
This section provides functions allowing to configure the NVIC interrupts (IRQ).
The Cortex-M3 exceptions are managed by CMSIS functions.
(#) Configure the NVIC Priority Grouping using HAL_NVIC_SetPriorityGrouping()
function according to the following table.
(#) Configure the priority of the selected IRQ Channels using HAL_NVIC_SetPriority().
(#) Enable the selected IRQ Channels using HAL_NVIC_EnableIRQ().
(#) please refer to programming manual for details in how to configure priority.
-@- When the NVIC_PRIORITYGROUP_0 is selected, IRQ preemption is no more possible.
The pending IRQ priority will be managed only by the sub priority.
-@- IRQ priority order (sorted by highest to lowest priority):
(+@) Lowest preemption priority
(+@) Lowest sub priority
(+@) Lowest hardware priority (IRQ number)
[..]
*** How to configure Systick using CORTEX HAL driver ***
========================================================
[..]
Setup SysTick Timer for time base.
(+) The HAL_SYSTICK_Config()function calls the SysTick_Config() function which
is a CMSIS function that:
(++) Configures the SysTick Reload register with value passed as function parameter.
(++) Configures the SysTick IRQ priority to the lowest value 0x0F.
(++) Resets the SysTick Counter register.
(++) Configures the SysTick Counter clock source to be Core Clock Source (HCLK).
(++) Enables the SysTick Interrupt.
(++) Starts the SysTick Counter.
(+) You can change the SysTick Clock source to be HCLK_Div8 by calling the macro
__HAL_CORTEX_SYSTICKCLK_CONFIG(SYSTICK_CLKSOURCE_HCLK_DIV8) just after the
HAL_SYSTICK_Config() function call. The __HAL_CORTEX_SYSTICKCLK_CONFIG() macro is defined
inside the stm32f1xx_hal_cortex.h file.
(+) You can change the SysTick IRQ priority by calling the
HAL_NVIC_SetPriority(SysTick_IRQn,...) function just after the HAL_SYSTICK_Config() function
call. The HAL_NVIC_SetPriority() call the NVIC_SetPriority() function which is a CMSIS function.
(+) To adjust the SysTick time base, use the following formula:
Reload Value = SysTick Counter Clock (Hz) x Desired Time base (s)
(++) Reload Value is the parameter to be passed for HAL_SYSTICK_Config() function
(++) Reload Value should not exceed 0xFFFFFF
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2017 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup CORTEX CORTEX
* @brief CORTEX HAL module driver
* @{
*/
#ifdef HAL_CORTEX_MODULE_ENABLED
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Functions CORTEX Exported Functions
* @{
*/
/** @defgroup CORTEX_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and Configuration functions
*
@verbatim
==============================================================================
##### Initialization and de-initialization functions #####
==============================================================================
[..]
This section provides the CORTEX HAL driver functions allowing to configure Interrupts
Systick functionalities
@endverbatim
* @{
*/
/**
* @brief Sets the priority grouping field (preemption priority and subpriority)
* using the required unlock sequence.
* @param PriorityGroup: The priority grouping bits length.
* This parameter can be one of the following values:
* @arg NVIC_PRIORITYGROUP_0: 0 bits for preemption priority
* 4 bits for subpriority
* @arg NVIC_PRIORITYGROUP_1: 1 bits for preemption priority
* 3 bits for subpriority
* @arg NVIC_PRIORITYGROUP_2: 2 bits for preemption priority
* 2 bits for subpriority
* @arg NVIC_PRIORITYGROUP_3: 3 bits for preemption priority
* 1 bits for subpriority
* @arg NVIC_PRIORITYGROUP_4: 4 bits for preemption priority
* 0 bits for subpriority
* @note When the NVIC_PriorityGroup_0 is selected, IRQ preemption is no more possible.
* The pending IRQ priority will be managed only by the subpriority.
* @retval None
*/
void HAL_NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
/* Check the parameters */
assert_param(IS_NVIC_PRIORITY_GROUP(PriorityGroup));
/* Set the PRIGROUP[10:8] bits according to the PriorityGroup parameter value */
NVIC_SetPriorityGrouping(PriorityGroup);
}
/**
* @brief Sets the priority of an interrupt.
* @param IRQn: External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xx.h))
* @param PreemptPriority: The preemption priority for the IRQn channel.
* This parameter can be a value between 0 and 15
* A lower priority value indicates a higher priority
* @param SubPriority: the subpriority level for the IRQ channel.
* This parameter can be a value between 0 and 15
* A lower priority value indicates a higher priority.
* @retval None
*/
void HAL_NVIC_SetPriority(IRQn_Type IRQn, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t prioritygroup = 0x00U;
/* Check the parameters */
assert_param(IS_NVIC_SUB_PRIORITY(SubPriority));
assert_param(IS_NVIC_PREEMPTION_PRIORITY(PreemptPriority));
prioritygroup = NVIC_GetPriorityGrouping();
NVIC_SetPriority(IRQn, NVIC_EncodePriority(prioritygroup, PreemptPriority, SubPriority));
}
/**
* @brief Enables a device specific interrupt in the NVIC interrupt controller.
* @note To configure interrupts priority correctly, the NVIC_PriorityGroupConfig()
* function should be called before.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval None
*/
void HAL_NVIC_EnableIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Enable interrupt */
NVIC_EnableIRQ(IRQn);
}
/**
* @brief Disables a device specific interrupt in the NVIC interrupt controller.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval None
*/
void HAL_NVIC_DisableIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Disable interrupt */
NVIC_DisableIRQ(IRQn);
}
/**
* @brief Initiates a system reset request to reset the MCU.
* @retval None
*/
void HAL_NVIC_SystemReset(void)
{
/* System Reset */
NVIC_SystemReset();
}
/**
* @brief Initializes the System Timer and its interrupt, and starts the System Tick Timer.
* Counter is in free running mode to generate periodic interrupts.
* @param TicksNumb: Specifies the ticks Number of ticks between two interrupts.
* @retval status: - 0 Function succeeded.
* - 1 Function failed.
*/
uint32_t HAL_SYSTICK_Config(uint32_t TicksNumb)
{
return SysTick_Config(TicksNumb);
}
/**
* @}
*/
/** @defgroup CORTEX_Exported_Functions_Group2 Peripheral Control functions
* @brief Cortex control functions
*
@verbatim
==============================================================================
##### Peripheral Control functions #####
==============================================================================
[..]
This subsection provides a set of functions allowing to control the CORTEX
(NVIC, SYSTICK, MPU) functionalities.
@endverbatim
* @{
*/
#if (__MPU_PRESENT == 1U)
/**
* @brief Disables the MPU
* @retval None
*/
void HAL_MPU_Disable(void)
{
/* Make sure outstanding transfers are done */
__DMB();
/* Disable fault exceptions */
SCB->SHCSR &= ~SCB_SHCSR_MEMFAULTENA_Msk;
/* Disable the MPU and clear the control register*/
MPU->CTRL = 0U;
}
/**
* @brief Enable the MPU.
* @param MPU_Control: Specifies the control mode of the MPU during hard fault,
* NMI, FAULTMASK and privileged access to the default memory
* This parameter can be one of the following values:
* @arg MPU_HFNMI_PRIVDEF_NONE
* @arg MPU_HARDFAULT_NMI
* @arg MPU_PRIVILEGED_DEFAULT
* @arg MPU_HFNMI_PRIVDEF
* @retval None
*/
void HAL_MPU_Enable(uint32_t MPU_Control)
{
/* Enable the MPU */
MPU->CTRL = MPU_Control | MPU_CTRL_ENABLE_Msk;
/* Enable fault exceptions */
SCB->SHCSR |= SCB_SHCSR_MEMFAULTENA_Msk;
/* Ensure MPU setting take effects */
__DSB();
__ISB();
}
/**
* @brief Initializes and configures the Region and the memory to be protected.
* @param MPU_Init: Pointer to a MPU_Region_InitTypeDef structure that contains
* the initialization and configuration information.
* @retval None
*/
void HAL_MPU_ConfigRegion(MPU_Region_InitTypeDef *MPU_Init)
{
/* Check the parameters */
assert_param(IS_MPU_REGION_NUMBER(MPU_Init->Number));
assert_param(IS_MPU_REGION_ENABLE(MPU_Init->Enable));
/* Set the Region number */
MPU->RNR = MPU_Init->Number;
if ((MPU_Init->Enable) != RESET)
{
/* Check the parameters */
assert_param(IS_MPU_INSTRUCTION_ACCESS(MPU_Init->DisableExec));
assert_param(IS_MPU_REGION_PERMISSION_ATTRIBUTE(MPU_Init->AccessPermission));
assert_param(IS_MPU_TEX_LEVEL(MPU_Init->TypeExtField));
assert_param(IS_MPU_ACCESS_SHAREABLE(MPU_Init->IsShareable));
assert_param(IS_MPU_ACCESS_CACHEABLE(MPU_Init->IsCacheable));
assert_param(IS_MPU_ACCESS_BUFFERABLE(MPU_Init->IsBufferable));
assert_param(IS_MPU_SUB_REGION_DISABLE(MPU_Init->SubRegionDisable));
assert_param(IS_MPU_REGION_SIZE(MPU_Init->Size));
MPU->RBAR = MPU_Init->BaseAddress;
MPU->RASR = ((uint32_t)MPU_Init->DisableExec << MPU_RASR_XN_Pos) |
((uint32_t)MPU_Init->AccessPermission << MPU_RASR_AP_Pos) |
((uint32_t)MPU_Init->TypeExtField << MPU_RASR_TEX_Pos) |
((uint32_t)MPU_Init->IsShareable << MPU_RASR_S_Pos) |
((uint32_t)MPU_Init->IsCacheable << MPU_RASR_C_Pos) |
((uint32_t)MPU_Init->IsBufferable << MPU_RASR_B_Pos) |
((uint32_t)MPU_Init->SubRegionDisable << MPU_RASR_SRD_Pos) |
((uint32_t)MPU_Init->Size << MPU_RASR_SIZE_Pos) |
((uint32_t)MPU_Init->Enable << MPU_RASR_ENABLE_Pos);
}
else
{
MPU->RBAR = 0x00U;
MPU->RASR = 0x00U;
}
}
#endif /* __MPU_PRESENT */
/**
* @brief Gets the priority grouping field from the NVIC Interrupt Controller.
* @retval Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field)
*/
uint32_t HAL_NVIC_GetPriorityGrouping(void)
{
/* Get the PRIGROUP[10:8] field value */
return NVIC_GetPriorityGrouping();
}
/**
* @brief Gets the priority of an interrupt.
* @param IRQn: External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @param PriorityGroup: the priority grouping bits length.
* This parameter can be one of the following values:
* @arg NVIC_PRIORITYGROUP_0: 0 bits for preemption priority
* 4 bits for subpriority
* @arg NVIC_PRIORITYGROUP_1: 1 bits for preemption priority
* 3 bits for subpriority
* @arg NVIC_PRIORITYGROUP_2: 2 bits for preemption priority
* 2 bits for subpriority
* @arg NVIC_PRIORITYGROUP_3: 3 bits for preemption priority
* 1 bits for subpriority
* @arg NVIC_PRIORITYGROUP_4: 4 bits for preemption priority
* 0 bits for subpriority
* @param pPreemptPriority: Pointer on the Preemptive priority value (starting from 0).
* @param pSubPriority: Pointer on the Subpriority value (starting from 0).
* @retval None
*/
void HAL_NVIC_GetPriority(IRQn_Type IRQn, uint32_t PriorityGroup, uint32_t *pPreemptPriority, uint32_t *pSubPriority)
{
/* Check the parameters */
assert_param(IS_NVIC_PRIORITY_GROUP(PriorityGroup));
/* Get priority for Cortex-M system or device specific interrupts */
NVIC_DecodePriority(NVIC_GetPriority(IRQn), PriorityGroup, pPreemptPriority, pSubPriority);
}
/**
* @brief Sets Pending bit of an external interrupt.
* @param IRQn External interrupt number
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval None
*/
void HAL_NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Set interrupt pending */
NVIC_SetPendingIRQ(IRQn);
}
/**
* @brief Gets Pending Interrupt (reads the pending register in the NVIC
* and returns the pending bit for the specified interrupt).
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval status: - 0 Interrupt status is not pending.
* - 1 Interrupt status is pending.
*/
uint32_t HAL_NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Return 1 if pending else 0 */
return NVIC_GetPendingIRQ(IRQn);
}
/**
* @brief Clears the pending bit of an external interrupt.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval None
*/
void HAL_NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Clear pending interrupt */
NVIC_ClearPendingIRQ(IRQn);
}
/**
* @brief Gets active interrupt ( reads the active register in NVIC and returns the active bit).
* @param IRQn External interrupt number
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32f10xxx.h))
* @retval status: - 0 Interrupt status is not pending.
* - 1 Interrupt status is pending.
*/
uint32_t HAL_NVIC_GetActive(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Return 1 if active else 0 */
return NVIC_GetActive(IRQn);
}
/**
* @brief Configures the SysTick clock source.
* @param CLKSource: specifies the SysTick clock source.
* This parameter can be one of the following values:
* @arg SYSTICK_CLKSOURCE_HCLK_DIV8: AHB clock divided by 8 selected as SysTick clock source.
* @arg SYSTICK_CLKSOURCE_HCLK: AHB clock selected as SysTick clock source.
* @retval None
*/
void HAL_SYSTICK_CLKSourceConfig(uint32_t CLKSource)
{
/* Check the parameters */
assert_param(IS_SYSTICK_CLK_SOURCE(CLKSource));
if (CLKSource == SYSTICK_CLKSOURCE_HCLK)
{
SysTick->CTRL |= SYSTICK_CLKSOURCE_HCLK;
}
else
{
SysTick->CTRL &= ~SYSTICK_CLKSOURCE_HCLK;
}
}
/**
* @brief This function handles SYSTICK interrupt request.
* @retval None
*/
void HAL_SYSTICK_IRQHandler(void)
{
HAL_SYSTICK_Callback();
}
/**
* @brief SYSTICK callback.
* @retval None
*/
__weak void HAL_SYSTICK_Callback(void)
{
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_SYSTICK_Callback could be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_CORTEX_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_dma.c
* @author MCD Application Team
* @brief DMA HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Direct Memory Access (DMA) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
* + Peripheral State and errors functions
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
(#) Enable and configure the peripheral to be connected to the DMA Channel
(except for internal SRAM / FLASH memories: no initialization is
necessary). Please refer to the Reference manual for connection between peripherals
and DMA requests.
(#) For a given Channel, program the required configuration through the following parameters:
Channel request, Transfer Direction, Source and Destination data formats,
Circular or Normal mode, Channel Priority level, Source and Destination Increment mode
using HAL_DMA_Init() function.
(#) Use HAL_DMA_GetState() function to return the DMA state and HAL_DMA_GetError() in case of error
detection.
(#) Use HAL_DMA_Abort() function to abort the current transfer
-@- In Memory-to-Memory transfer mode, Circular mode is not allowed.
*** Polling mode IO operation ***
=================================
[..]
(+) Use HAL_DMA_Start() to start DMA transfer after the configuration of Source
address and destination address and the Length of data to be transferred
(+) Use HAL_DMA_PollForTransfer() to poll for the end of current transfer, in this
case a fixed Timeout can be configured by User depending from his application.
*** Interrupt mode IO operation ***
===================================
[..]
(+) Configure the DMA interrupt priority using HAL_NVIC_SetPriority()
(+) Enable the DMA IRQ handler using HAL_NVIC_EnableIRQ()
(+) Use HAL_DMA_Start_IT() to start DMA transfer after the configuration of
Source address and destination address and the Length of data to be transferred.
In this case the DMA interrupt is configured
(+) Use HAL_DMA_IRQHandler() called under DMA_IRQHandler() Interrupt subroutine
(+) At the end of data transfer HAL_DMA_IRQHandler() function is executed and user can
add his own function by customization of function pointer XferCpltCallback and
XferErrorCallback (i.e. a member of DMA handle structure).
*** DMA HAL driver macros list ***
=============================================
[..]
Below the list of most used macros in DMA HAL driver.
(+) __HAL_DMA_ENABLE: Enable the specified DMA Channel.
(+) __HAL_DMA_DISABLE: Disable the specified DMA Channel.
(+) __HAL_DMA_GET_FLAG: Get the DMA Channel pending flags.
(+) __HAL_DMA_CLEAR_FLAG: Clear the DMA Channel pending flags.
(+) __HAL_DMA_ENABLE_IT: Enable the specified DMA Channel interrupts.
(+) __HAL_DMA_DISABLE_IT: Disable the specified DMA Channel interrupts.
(+) __HAL_DMA_GET_IT_SOURCE: Check whether the specified DMA Channel interrupt has occurred or not.
[..]
(@) You can refer to the DMA HAL driver header file for more useful macros
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup DMA DMA
* @brief DMA HAL module driver
* @{
*/
#ifdef HAL_DMA_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup DMA_Private_Functions DMA Private Functions
* @{
*/
static void DMA_SetConfig(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength);
/**
* @}
*/
/* Exported functions ---------------------------------------------------------*/
/** @defgroup DMA_Exported_Functions DMA Exported Functions
* @{
*/
/** @defgroup DMA_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
This section provides functions allowing to initialize the DMA Channel source
and destination addresses, incrementation and data sizes, transfer direction,
circular/normal mode selection, memory-to-memory mode selection and Channel priority value.
[..]
The HAL_DMA_Init() function follows the DMA configuration procedures as described in
reference manual.
@endverbatim
* @{
*/
/**
* @brief Initialize the DMA according to the specified
* parameters in the DMA_InitTypeDef and initialize the associated handle.
* @param hdma: Pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Init(DMA_HandleTypeDef *hdma)
{
uint32_t tmp = 0U;
/* Check the DMA handle allocation */
if(hdma == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
assert_param(IS_DMA_DIRECTION(hdma->Init.Direction));
assert_param(IS_DMA_PERIPHERAL_INC_STATE(hdma->Init.PeriphInc));
assert_param(IS_DMA_MEMORY_INC_STATE(hdma->Init.MemInc));
assert_param(IS_DMA_PERIPHERAL_DATA_SIZE(hdma->Init.PeriphDataAlignment));
assert_param(IS_DMA_MEMORY_DATA_SIZE(hdma->Init.MemDataAlignment));
assert_param(IS_DMA_MODE(hdma->Init.Mode));
assert_param(IS_DMA_PRIORITY(hdma->Init.Priority));
#if defined (DMA2)
/* calculation of the channel index */
if ((uint32_t)(hdma->Instance) < (uint32_t)(DMA2_Channel1))
{
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
}
else
{
/* DMA2 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA2_Channel1) / ((uint32_t)DMA2_Channel2 - (uint32_t)DMA2_Channel1)) << 2;
hdma->DmaBaseAddress = DMA2;
}
#else
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
#endif /* DMA2 */
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
/* Get the CR register value */
tmp = hdma->Instance->CCR;
/* Clear PL, MSIZE, PSIZE, MINC, PINC, CIRC and DIR bits */
tmp &= ((uint32_t)~(DMA_CCR_PL | DMA_CCR_MSIZE | DMA_CCR_PSIZE | \
DMA_CCR_MINC | DMA_CCR_PINC | DMA_CCR_CIRC | \
DMA_CCR_DIR));
/* Prepare the DMA Channel configuration */
tmp |= hdma->Init.Direction |
hdma->Init.PeriphInc | hdma->Init.MemInc |
hdma->Init.PeriphDataAlignment | hdma->Init.MemDataAlignment |
hdma->Init.Mode | hdma->Init.Priority;
/* Write to DMA Channel CR register */
hdma->Instance->CCR = tmp;
/* Initialise the error code */
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Initialize the DMA state*/
hdma->State = HAL_DMA_STATE_READY;
/* Allocate lock resource and initialize it */
hdma->Lock = HAL_UNLOCKED;
return HAL_OK;
}
/**
* @brief DeInitialize the DMA peripheral.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_DeInit(DMA_HandleTypeDef *hdma)
{
/* Check the DMA handle allocation */
if(hdma == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
/* Disable the selected DMA Channelx */
__HAL_DMA_DISABLE(hdma);
/* Reset DMA Channel control register */
hdma->Instance->CCR = 0U;
/* Reset DMA Channel Number of Data to Transfer register */
hdma->Instance->CNDTR = 0U;
/* Reset DMA Channel peripheral address register */
hdma->Instance->CPAR = 0U;
/* Reset DMA Channel memory address register */
hdma->Instance->CMAR = 0U;
#if defined (DMA2)
/* calculation of the channel index */
if ((uint32_t)(hdma->Instance) < (uint32_t)(DMA2_Channel1))
{
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
}
else
{
/* DMA2 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA2_Channel1) / ((uint32_t)DMA2_Channel2 - (uint32_t)DMA2_Channel1)) << 2;
hdma->DmaBaseAddress = DMA2;
}
#else
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
#endif /* DMA2 */
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << (hdma->ChannelIndex));
/* Clean all callbacks */
hdma->XferCpltCallback = NULL;
hdma->XferHalfCpltCallback = NULL;
hdma->XferErrorCallback = NULL;
hdma->XferAbortCallback = NULL;
/* Reset the error code */
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Reset the DMA state */
hdma->State = HAL_DMA_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
/**
* @}
*/
/** @defgroup DMA_Exported_Functions_Group2 Input and Output operation functions
* @brief Input and Output operation functions
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Configure the source, destination address and data length and Start DMA transfer
(+) Configure the source, destination address and data length and
Start DMA transfer with interrupt
(+) Abort DMA transfer
(+) Poll for transfer complete
(+) Handle DMA interrupt request
@endverbatim
* @{
*/
/**
* @brief Start the DMA Transfer.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress: The source memory Buffer address
* @param DstAddress: The destination memory Buffer address
* @param DataLength: The length of data to be transferred from source to destination
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Start(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_DMA_BUFFER_SIZE(DataLength));
/* Process locked */
__HAL_LOCK(hdma);
if(HAL_DMA_STATE_READY == hdma->State)
{
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Disable the peripheral */
__HAL_DMA_DISABLE(hdma);
/* Configure the source, destination address and the data length & clear flags*/
DMA_SetConfig(hdma, SrcAddress, DstAddress, DataLength);
/* Enable the Peripheral */
__HAL_DMA_ENABLE(hdma);
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hdma);
status = HAL_BUSY;
}
return status;
}
/**
* @brief Start the DMA Transfer with interrupt enabled.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress: The source memory Buffer address
* @param DstAddress: The destination memory Buffer address
* @param DataLength: The length of data to be transferred from source to destination
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Start_IT(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_DMA_BUFFER_SIZE(DataLength));
/* Process locked */
__HAL_LOCK(hdma);
if(HAL_DMA_STATE_READY == hdma->State)
{
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Disable the peripheral */
__HAL_DMA_DISABLE(hdma);
/* Configure the source, destination address and the data length & clear flags*/
DMA_SetConfig(hdma, SrcAddress, DstAddress, DataLength);
/* Enable the transfer complete interrupt */
/* Enable the transfer Error interrupt */
if(NULL != hdma->XferHalfCpltCallback)
{
/* Enable the Half transfer complete interrupt as well */
__HAL_DMA_ENABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
}
else
{
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_HT);
__HAL_DMA_ENABLE_IT(hdma, (DMA_IT_TC | DMA_IT_TE));
}
/* Enable the Peripheral */
__HAL_DMA_ENABLE(hdma);
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hdma);
/* Remain BUSY */
status = HAL_BUSY;
}
return status;
}
/**
* @brief Abort the DMA Transfer.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Abort(DMA_HandleTypeDef *hdma)
{
HAL_StatusTypeDef status = HAL_OK;
if(hdma->State != HAL_DMA_STATE_BUSY)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
else
{
/* Disable DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* Disable the channel */
__HAL_DMA_DISABLE(hdma);
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << hdma->ChannelIndex);
}
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @brief Aborts the DMA Transfer in Interrupt mode.
* @param hdma : pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Abort_IT(DMA_HandleTypeDef *hdma)
{
HAL_StatusTypeDef status = HAL_OK;
if(HAL_DMA_STATE_BUSY != hdma->State)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
status = HAL_ERROR;
}
else
{
/* Disable DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* Disable the channel */
__HAL_DMA_DISABLE(hdma);
/* Clear all flags */
__HAL_DMA_CLEAR_FLAG(hdma, __HAL_DMA_GET_GI_FLAG_INDEX(hdma));
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
/* Call User Abort callback */
if(hdma->XferAbortCallback != NULL)
{
hdma->XferAbortCallback(hdma);
}
}
return status;
}
/**
* @brief Polling for transfer complete.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CompleteLevel: Specifies the DMA level complete.
* @param Timeout: Timeout duration.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_PollForTransfer(DMA_HandleTypeDef *hdma, uint32_t CompleteLevel, uint32_t Timeout)
{
uint32_t temp;
uint32_t tickstart = 0U;
if(HAL_DMA_STATE_BUSY != hdma->State)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
/* Polling mode not supported in circular mode */
if (RESET != (hdma->Instance->CCR & DMA_CCR_CIRC))
{
hdma->ErrorCode = HAL_DMA_ERROR_NOT_SUPPORTED;
return HAL_ERROR;
}
/* Get the level transfer complete flag */
if(CompleteLevel == HAL_DMA_FULL_TRANSFER)
{
/* Transfer Complete flag */
temp = __HAL_DMA_GET_TC_FLAG_INDEX(hdma);
}
else
{
/* Half Transfer Complete flag */
temp = __HAL_DMA_GET_HT_FLAG_INDEX(hdma);
}
/* Get tick */
tickstart = HAL_GetTick();
while(__HAL_DMA_GET_FLAG(hdma, temp) == RESET)
{
if((__HAL_DMA_GET_FLAG(hdma, __HAL_DMA_GET_TE_FLAG_INDEX(hdma)) != RESET))
{
/* When a DMA transfer error occurs */
/* A hardware clear of its EN bits is performed */
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << hdma->ChannelIndex);
/* Update error code */
SET_BIT(hdma->ErrorCode, HAL_DMA_ERROR_TE);
/* Change the DMA state */
hdma->State= HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
/* Check for the Timeout */
if(Timeout != HAL_MAX_DELAY)
{
if((Timeout == 0U) || ((HAL_GetTick() - tickstart) > Timeout))
{
/* Update error code */
SET_BIT(hdma->ErrorCode, HAL_DMA_ERROR_TIMEOUT);
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
}
}
if(CompleteLevel == HAL_DMA_FULL_TRANSFER)
{
/* Clear the transfer complete flag */
__HAL_DMA_CLEAR_FLAG(hdma, __HAL_DMA_GET_TC_FLAG_INDEX(hdma));
/* The selected Channelx EN bit is cleared (DMA is disabled and
all transfers are complete) */
hdma->State = HAL_DMA_STATE_READY;
}
else
{
/* Clear the half transfer complete flag */
__HAL_DMA_CLEAR_FLAG(hdma, __HAL_DMA_GET_HT_FLAG_INDEX(hdma));
}
/* Process unlocked */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
/**
* @brief Handles DMA interrupt request.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval None
*/
void HAL_DMA_IRQHandler(DMA_HandleTypeDef *hdma)
{
uint32_t flag_it = hdma->DmaBaseAddress->ISR;
uint32_t source_it = hdma->Instance->CCR;
/* Half Transfer Complete Interrupt management ******************************/
if (((flag_it & (DMA_FLAG_HT1 << hdma->ChannelIndex)) != RESET) && ((source_it & DMA_IT_HT) != RESET))
{
/* Disable the half transfer interrupt if the DMA mode is not CIRCULAR */
if((hdma->Instance->CCR & DMA_CCR_CIRC) == 0U)
{
/* Disable the half transfer interrupt */
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_HT);
}
/* Clear the half transfer complete flag */
__HAL_DMA_CLEAR_FLAG(hdma, __HAL_DMA_GET_HT_FLAG_INDEX(hdma));
/* DMA peripheral state is not updated in Half Transfer */
/* but in Transfer Complete case */
if(hdma->XferHalfCpltCallback != NULL)
{
/* Half transfer callback */
hdma->XferHalfCpltCallback(hdma);
}
}
/* Transfer Complete Interrupt management ***********************************/
else if (((flag_it & (DMA_FLAG_TC1 << hdma->ChannelIndex)) != RESET) && ((source_it & DMA_IT_TC) != RESET))
{
if((hdma->Instance->CCR & DMA_CCR_CIRC) == 0U)
{
/* Disable the transfer complete and error interrupt */
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_TE | DMA_IT_TC);
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
}
/* Clear the transfer complete flag */
__HAL_DMA_CLEAR_FLAG(hdma, __HAL_DMA_GET_TC_FLAG_INDEX(hdma));
/* Process Unlocked */
__HAL_UNLOCK(hdma);
if(hdma->XferCpltCallback != NULL)
{
/* Transfer complete callback */
hdma->XferCpltCallback(hdma);
}
}
/* Transfer Error Interrupt management **************************************/
else if (( RESET != (flag_it & (DMA_FLAG_TE1 << hdma->ChannelIndex))) && (RESET != (source_it & DMA_IT_TE)))
{
/* When a DMA transfer error occurs */
/* A hardware clear of its EN bits is performed */
/* Disable ALL DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << hdma->ChannelIndex);
/* Update error code */
hdma->ErrorCode = HAL_DMA_ERROR_TE;
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
if (hdma->XferErrorCallback != NULL)
{
/* Transfer error callback */
hdma->XferErrorCallback(hdma);
}
}
return;
}
/**
* @brief Register callbacks
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CallbackID: User Callback identifier
* a HAL_DMA_CallbackIDTypeDef ENUM as parameter.
* @param pCallback: pointer to private callback function which has pointer to
* a DMA_HandleTypeDef structure as parameter.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_RegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID, void (* pCallback)( DMA_HandleTypeDef * _hdma))
{
HAL_StatusTypeDef status = HAL_OK;
/* Process locked */
__HAL_LOCK(hdma);
if(HAL_DMA_STATE_READY == hdma->State)
{
switch (CallbackID)
{
case HAL_DMA_XFER_CPLT_CB_ID:
hdma->XferCpltCallback = pCallback;
break;
case HAL_DMA_XFER_HALFCPLT_CB_ID:
hdma->XferHalfCpltCallback = pCallback;
break;
case HAL_DMA_XFER_ERROR_CB_ID:
hdma->XferErrorCallback = pCallback;
break;
case HAL_DMA_XFER_ABORT_CB_ID:
hdma->XferAbortCallback = pCallback;
break;
default:
status = HAL_ERROR;
break;
}
}
else
{
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @brief UnRegister callbacks
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CallbackID: User Callback identifier
* a HAL_DMA_CallbackIDTypeDef ENUM as parameter.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_UnRegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID)
{
HAL_StatusTypeDef status = HAL_OK;
/* Process locked */
__HAL_LOCK(hdma);
if(HAL_DMA_STATE_READY == hdma->State)
{
switch (CallbackID)
{
case HAL_DMA_XFER_CPLT_CB_ID:
hdma->XferCpltCallback = NULL;
break;
case HAL_DMA_XFER_HALFCPLT_CB_ID:
hdma->XferHalfCpltCallback = NULL;
break;
case HAL_DMA_XFER_ERROR_CB_ID:
hdma->XferErrorCallback = NULL;
break;
case HAL_DMA_XFER_ABORT_CB_ID:
hdma->XferAbortCallback = NULL;
break;
case HAL_DMA_XFER_ALL_CB_ID:
hdma->XferCpltCallback = NULL;
hdma->XferHalfCpltCallback = NULL;
hdma->XferErrorCallback = NULL;
hdma->XferAbortCallback = NULL;
break;
default:
status = HAL_ERROR;
break;
}
}
else
{
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @}
*/
/** @defgroup DMA_Exported_Functions_Group3 Peripheral State and Errors functions
* @brief Peripheral State and Errors functions
*
@verbatim
===============================================================================
##### Peripheral State and Errors functions #####
===============================================================================
[..]
This subsection provides functions allowing to
(+) Check the DMA state
(+) Get error code
@endverbatim
* @{
*/
/**
* @brief Return the DMA handle state.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL state
*/
HAL_DMA_StateTypeDef HAL_DMA_GetState(DMA_HandleTypeDef *hdma)
{
/* Return DMA handle state */
return hdma->State;
}
/**
* @brief Return the DMA error code.
* @param hdma : pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval DMA Error Code
*/
uint32_t HAL_DMA_GetError(DMA_HandleTypeDef *hdma)
{
return hdma->ErrorCode;
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup DMA_Private_Functions
* @{
*/
/**
* @brief Sets the DMA Transfer parameter.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress: The source memory Buffer address
* @param DstAddress: The destination memory Buffer address
* @param DataLength: The length of data to be transferred from source to destination
* @retval HAL status
*/
static void DMA_SetConfig(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength)
{
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << hdma->ChannelIndex);
/* Configure DMA Channel data length */
hdma->Instance->CNDTR = DataLength;
/* Memory to Peripheral */
if((hdma->Init.Direction) == DMA_MEMORY_TO_PERIPH)
{
/* Configure DMA Channel destination address */
hdma->Instance->CPAR = DstAddress;
/* Configure DMA Channel source address */
hdma->Instance->CMAR = SrcAddress;
}
/* Peripheral to Memory */
else
{
/* Configure DMA Channel source address */
hdma->Instance->CPAR = SrcAddress;
/* Configure DMA Channel destination address */
hdma->Instance->CMAR = DstAddress;
}
}
/**
* @}
*/
#endif /* HAL_DMA_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

553
Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_hal_exti.c Normal file
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@ -0,0 +1,553 @@
/**
******************************************************************************
* @file stm32f1xx_hal_exti.c
* @author MCD Application Team
* @brief EXTI HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Extended Interrupts and events controller (EXTI) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### EXTI Peripheral features #####
==============================================================================
[..]
(+) Each Exti line can be configured within this driver.
(+) Exti line can be configured in 3 different modes
(++) Interrupt
(++) Event
(++) Both of them
(+) Configurable Exti lines can be configured with 3 different triggers
(++) Rising
(++) Falling
(++) Both of them
(+) When set in interrupt mode, configurable Exti lines have two different
interrupts pending registers which allow to distinguish which transition
occurs:
(++) Rising edge pending interrupt
(++) Falling
(+) Exti lines 0 to 15 are linked to gpio pin number 0 to 15. Gpio port can
be selected through multiplexer.
##### How to use this driver #####
==============================================================================
[..]
(#) Configure the EXTI line using HAL_EXTI_SetConfigLine().
(++) Choose the interrupt line number by setting "Line" member from
EXTI_ConfigTypeDef structure.
(++) Configure the interrupt and/or event mode using "Mode" member from
EXTI_ConfigTypeDef structure.
(++) For configurable lines, configure rising and/or falling trigger
"Trigger" member from EXTI_ConfigTypeDef structure.
(++) For Exti lines linked to gpio, choose gpio port using "GPIOSel"
member from GPIO_InitTypeDef structure.
(#) Get current Exti configuration of a dedicated line using
HAL_EXTI_GetConfigLine().
(++) Provide exiting handle as parameter.
(++) Provide pointer on EXTI_ConfigTypeDef structure as second parameter.
(#) Clear Exti configuration of a dedicated line using HAL_EXTI_ClearConfigLine().
(++) Provide exiting handle as parameter.
(#) Register callback to treat Exti interrupts using HAL_EXTI_RegisterCallback().
(++) Provide exiting handle as first parameter.
(++) Provide which callback will be registered using one value from
EXTI_CallbackIDTypeDef.
(++) Provide callback function pointer.
(#) Get interrupt pending bit using HAL_EXTI_GetPending().
(#) Clear interrupt pending bit using HAL_EXTI_ClearPending().
(#) Generate software interrupt using HAL_EXTI_GenerateSWI().
@endverbatim
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @addtogroup EXTI
* @{
*/
/** MISRA C:2012 deviation rule has been granted for following rule:
* Rule-18.1_b - Medium: Array `EXTICR' 1st subscript interval [0,7] may be out
* of bounds [0,3] in following API :
* HAL_EXTI_SetConfigLine
* HAL_EXTI_GetConfigLine
* HAL_EXTI_ClearConfigLine
*/
#ifdef HAL_EXTI_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private defines -----------------------------------------------------------*/
/** @defgroup EXTI_Private_Constants EXTI Private Constants
* @{
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup EXTI_Exported_Functions
* @{
*/
/** @addtogroup EXTI_Exported_Functions_Group1
* @brief Configuration functions
*
@verbatim
===============================================================================
##### Configuration functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Set configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @param pExtiConfig Pointer on EXTI configuration to be set.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_SetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig)
{
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
/* Check null pointer */
if ((hexti == NULL) || (pExtiConfig == NULL))
{
return HAL_ERROR;
}
/* Check parameters */
assert_param(IS_EXTI_LINE(pExtiConfig->Line));
assert_param(IS_EXTI_MODE(pExtiConfig->Mode));
/* Assign line number to handle */
hexti->Line = pExtiConfig->Line;
/* Compute line mask */
linepos = (pExtiConfig->Line & EXTI_PIN_MASK);
maskline = (1uL << linepos);
/* Configure triggers for configurable lines */
if ((pExtiConfig->Line & EXTI_CONFIG) != 0x00u)
{
assert_param(IS_EXTI_TRIGGER(pExtiConfig->Trigger));
/* Configure rising trigger */
/* Mask or set line */
if ((pExtiConfig->Trigger & EXTI_TRIGGER_RISING) != 0x00u)
{
EXTI->RTSR |= maskline;
}
else
{
EXTI->RTSR &= ~maskline;
}
/* Configure falling trigger */
/* Mask or set line */
if ((pExtiConfig->Trigger & EXTI_TRIGGER_FALLING) != 0x00u)
{
EXTI->FTSR |= maskline;
}
else
{
EXTI->FTSR &= ~maskline;
}
/* Configure gpio port selection in case of gpio exti line */
if ((pExtiConfig->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PORT(pExtiConfig->GPIOSel));
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = AFIO->EXTICR[linepos >> 2u];
regval &= ~(AFIO_EXTICR1_EXTI0 << (AFIO_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
regval |= (pExtiConfig->GPIOSel << (AFIO_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
AFIO->EXTICR[linepos >> 2u] = regval;
}
}
/* Configure interrupt mode : read current mode */
/* Mask or set line */
if ((pExtiConfig->Mode & EXTI_MODE_INTERRUPT) != 0x00u)
{
EXTI->IMR |= maskline;
}
else
{
EXTI->IMR &= ~maskline;
}
/* Configure event mode : read current mode */
/* Mask or set line */
if ((pExtiConfig->Mode & EXTI_MODE_EVENT) != 0x00u)
{
EXTI->EMR |= maskline;
}
else
{
EXTI->EMR &= ~maskline;
}
return HAL_OK;
}
/**
* @brief Get configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @param pExtiConfig Pointer on structure to store Exti configuration.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_GetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig)
{
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
/* Check null pointer */
if ((hexti == NULL) || (pExtiConfig == NULL))
{
return HAL_ERROR;
}
/* Check the parameter */
assert_param(IS_EXTI_LINE(hexti->Line));
/* Store handle line number to configuration structure */
pExtiConfig->Line = hexti->Line;
/* Compute line mask */
linepos = (pExtiConfig->Line & EXTI_PIN_MASK);
maskline = (1uL << linepos);
/* 1] Get core mode : interrupt */
/* Check if selected line is enable */
if ((EXTI->IMR & maskline) != 0x00u)
{
pExtiConfig->Mode = EXTI_MODE_INTERRUPT;
}
else
{
pExtiConfig->Mode = EXTI_MODE_NONE;
}
/* Get event mode */
/* Check if selected line is enable */
if ((EXTI->EMR & maskline) != 0x00u)
{
pExtiConfig->Mode |= EXTI_MODE_EVENT;
}
/* Get default Trigger and GPIOSel configuration */
pExtiConfig->Trigger = EXTI_TRIGGER_NONE;
pExtiConfig->GPIOSel = 0x00u;
/* 2] Get trigger for configurable lines : rising */
if ((pExtiConfig->Line & EXTI_CONFIG) != 0x00u)
{
/* Check if configuration of selected line is enable */
if ((EXTI->RTSR & maskline) != 0x00u)
{
pExtiConfig->Trigger = EXTI_TRIGGER_RISING;
}
/* Get falling configuration */
/* Check if configuration of selected line is enable */
if ((EXTI->FTSR & maskline) != 0x00u)
{
pExtiConfig->Trigger |= EXTI_TRIGGER_FALLING;
}
/* Get Gpio port selection for gpio lines */
if ((pExtiConfig->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = AFIO->EXTICR[linepos >> 2u];
pExtiConfig->GPIOSel = (regval >> (AFIO_EXTICR1_EXTI1_Pos * (linepos & 0x03u))) & AFIO_EXTICR1_EXTI0;
}
}
return HAL_OK;
}
/**
* @brief Clear whole configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_ClearConfigLine(EXTI_HandleTypeDef *hexti)
{
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
/* Check null pointer */
if (hexti == NULL)
{
return HAL_ERROR;
}
/* Check the parameter */
assert_param(IS_EXTI_LINE(hexti->Line));
/* compute line mask */
linepos = (hexti->Line & EXTI_PIN_MASK);
maskline = (1uL << linepos);
/* 1] Clear interrupt mode */
EXTI->IMR = (EXTI->IMR & ~maskline);
/* 2] Clear event mode */
EXTI->EMR = (EXTI->EMR & ~maskline);
/* 3] Clear triggers in case of configurable lines */
if ((hexti->Line & EXTI_CONFIG) != 0x00u)
{
EXTI->RTSR = (EXTI->RTSR & ~maskline);
EXTI->FTSR = (EXTI->FTSR & ~maskline);
/* Get Gpio port selection for gpio lines */
if ((hexti->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = AFIO->EXTICR[linepos >> 2u];
regval &= ~(AFIO_EXTICR1_EXTI0 << (AFIO_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
AFIO->EXTICR[linepos >> 2u] = regval;
}
}
return HAL_OK;
}
/**
* @brief Register callback for a dedicated Exti line.
* @param hexti Exti handle.
* @param CallbackID User callback identifier.
* This parameter can be one of @arg @ref EXTI_CallbackIDTypeDef values.
* @param pPendingCbfn function pointer to be stored as callback.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_RegisterCallback(EXTI_HandleTypeDef *hexti, EXTI_CallbackIDTypeDef CallbackID, void (*pPendingCbfn)(void))
{
HAL_StatusTypeDef status = HAL_OK;
switch (CallbackID)
{
case HAL_EXTI_COMMON_CB_ID:
hexti->PendingCallback = pPendingCbfn;
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Store line number as handle private field.
* @param hexti Exti handle.
* @param ExtiLine Exti line number.
* This parameter can be from 0 to @ref EXTI_LINE_NB.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_GetHandle(EXTI_HandleTypeDef *hexti, uint32_t ExtiLine)
{
/* Check the parameters */
assert_param(IS_EXTI_LINE(ExtiLine));
/* Check null pointer */
if (hexti == NULL)
{
return HAL_ERROR;
}
else
{
/* Store line number as handle private field */
hexti->Line = ExtiLine;
return HAL_OK;
}
}
/**
* @}
*/
/** @addtogroup EXTI_Exported_Functions_Group2
* @brief EXTI IO functions.
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Handle EXTI interrupt request.
* @param hexti Exti handle.
* @retval none.
*/
void HAL_EXTI_IRQHandler(EXTI_HandleTypeDef *hexti)
{
uint32_t regval;
uint32_t maskline;
/* Compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
/* Get pending bit */
regval = (EXTI->PR & maskline);
if (regval != 0x00u)
{
/* Clear pending bit */
EXTI->PR = maskline;
/* Call callback */
if (hexti->PendingCallback != NULL)
{
hexti->PendingCallback();
}
}
}
/**
* @brief Get interrupt pending bit of a dedicated line.
* @param hexti Exti handle.
* @param Edge Specify which pending edge as to be checked.
* This parameter can be one of the following values:
* @arg @ref EXTI_TRIGGER_RISING_FALLING
* This parameter is kept for compatibility with other series.
* @retval 1 if interrupt is pending else 0.
*/
uint32_t HAL_EXTI_GetPending(EXTI_HandleTypeDef *hexti, uint32_t Edge)
{
uint32_t regval;
uint32_t maskline;
uint32_t linepos;
/* Check parameters */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
assert_param(IS_EXTI_PENDING_EDGE(Edge));
/* Prevent unused argument compilation warning */
UNUSED(Edge);
/* Compute line mask */
linepos = (hexti->Line & EXTI_PIN_MASK);
maskline = (1uL << linepos);
/* return 1 if bit is set else 0 */
regval = ((EXTI->PR & maskline) >> linepos);
return regval;
}
/**
* @brief Clear interrupt pending bit of a dedicated line.
* @param hexti Exti handle.
* @param Edge Specify which pending edge as to be clear.
* This parameter can be one of the following values:
* @arg @ref EXTI_TRIGGER_RISING_FALLING
* This parameter is kept for compatibility with other series.
* @retval None.
*/
void HAL_EXTI_ClearPending(EXTI_HandleTypeDef *hexti, uint32_t Edge)
{
uint32_t maskline;
/* Check parameters */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
assert_param(IS_EXTI_PENDING_EDGE(Edge));
/* Prevent unused argument compilation warning */
UNUSED(Edge);
/* Compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
/* Clear Pending bit */
EXTI->PR = maskline;
}
/**
* @brief Generate a software interrupt for a dedicated line.
* @param hexti Exti handle.
* @retval None.
*/
void HAL_EXTI_GenerateSWI(EXTI_HandleTypeDef *hexti)
{
uint32_t maskline;
/* Check parameters */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
/* Compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
/* Generate Software interrupt */
EXTI->SWIER = maskline;
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_EXTI_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_hal_flash.c Normal file
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@ -0,0 +1,964 @@
/**
******************************************************************************
* @file stm32f1xx_hal_flash.c
* @author MCD Application Team
* @brief FLASH HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the internal FLASH memory:
* + Program operations functions
* + Memory Control functions
* + Peripheral State functions
*
@verbatim
==============================================================================
##### FLASH peripheral features #####
==============================================================================
[..] The Flash memory interface manages CPU AHB I-Code and D-Code accesses
to the Flash memory. It implements the erase and program Flash memory operations
and the read and write protection mechanisms.
[..] The Flash memory interface accelerates code execution with a system of instruction
prefetch.
[..] The FLASH main features are:
(+) Flash memory read operations
(+) Flash memory program/erase operations
(+) Read / write protections
(+) Prefetch on I-Code
(+) Option Bytes programming
##### How to use this driver #####
==============================================================================
[..]
This driver provides functions and macros to configure and program the FLASH
memory of all STM32F1xx devices.
(#) FLASH Memory I/O Programming functions: this group includes all needed
functions to erase and program the main memory:
(++) Lock and Unlock the FLASH interface
(++) Erase function: Erase page, erase all pages
(++) Program functions: half word, word and doubleword
(#) FLASH Option Bytes Programming functions: this group includes all needed
functions to manage the Option Bytes:
(++) Lock and Unlock the Option Bytes
(++) Set/Reset the write protection
(++) Set the Read protection Level
(++) Program the user Option Bytes
(++) Launch the Option Bytes loader
(++) Erase Option Bytes
(++) Program the data Option Bytes
(++) Get the Write protection.
(++) Get the user option bytes.
(#) Interrupts and flags management functions : this group
includes all needed functions to:
(++) Handle FLASH interrupts
(++) Wait for last FLASH operation according to its status
(++) Get error flag status
[..] In addition to these function, this driver includes a set of macros allowing
to handle the following operations:
(+) Set/Get the latency
(+) Enable/Disable the prefetch buffer
(+) Enable/Disable the half cycle access
(+) Enable/Disable the FLASH interrupts
(+) Monitor the FLASH flags status
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
#ifdef HAL_FLASH_MODULE_ENABLED
/** @defgroup FLASH FLASH
* @brief FLASH HAL module driver
* @{
*/
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup FLASH_Private_Constants FLASH Private Constants
* @{
*/
/**
* @}
*/
/* Private macro ---------------------------- ---------------------------------*/
/** @defgroup FLASH_Private_Macros FLASH Private Macros
* @{
*/
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup FLASH_Private_Variables FLASH Private Variables
* @{
*/
/* Variables used for Erase pages under interruption*/
FLASH_ProcessTypeDef pFlash;
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup FLASH_Private_Functions FLASH Private Functions
* @{
*/
static void FLASH_Program_HalfWord(uint32_t Address, uint16_t Data);
static void FLASH_SetErrorCode(void);
extern void FLASH_PageErase(uint32_t PageAddress);
/**
* @}
*/
/* Exported functions ---------------------------------------------------------*/
/** @defgroup FLASH_Exported_Functions FLASH Exported Functions
* @{
*/
/** @defgroup FLASH_Exported_Functions_Group1 Programming operation functions
* @brief Programming operation functions
*
@verbatim
@endverbatim
* @{
*/
/**
* @brief Program halfword, word or double word at a specified address
* @note The function HAL_FLASH_Unlock() should be called before to unlock the FLASH interface
* The function HAL_FLASH_Lock() should be called after to lock the FLASH interface
*
* @note If an erase and a program operations are requested simultaneously,
* the erase operation is performed before the program one.
*
* @note FLASH should be previously erased before new programmation (only exception to this
* is when 0x0000 is programmed)
*
* @param TypeProgram: Indicate the way to program at a specified address.
* This parameter can be a value of @ref FLASH_Type_Program
* @param Address: Specifies the address to be programmed.
* @param Data: Specifies the data to be programmed
*
* @retval HAL_StatusTypeDef HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_Program(uint32_t TypeProgram, uint32_t Address, uint64_t Data)
{
HAL_StatusTypeDef status = HAL_ERROR;
uint8_t index = 0;
uint8_t nbiterations = 0;
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Check the parameters */
assert_param(IS_FLASH_TYPEPROGRAM(TypeProgram));
assert_param(IS_FLASH_PROGRAM_ADDRESS(Address));
#if defined(FLASH_BANK2_END)
if(Address <= FLASH_BANK1_END)
{
#endif /* FLASH_BANK2_END */
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation(FLASH_TIMEOUT_VALUE);
#if defined(FLASH_BANK2_END)
}
else
{
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperationBank2(FLASH_TIMEOUT_VALUE);
}
#endif /* FLASH_BANK2_END */
if(status == HAL_OK)
{
if(TypeProgram == FLASH_TYPEPROGRAM_HALFWORD)
{
/* Program halfword (16-bit) at a specified address. */
nbiterations = 1U;
}
else if(TypeProgram == FLASH_TYPEPROGRAM_WORD)
{
/* Program word (32-bit = 2*16-bit) at a specified address. */
nbiterations = 2U;
}
else
{
/* Program double word (64-bit = 4*16-bit) at a specified address. */
nbiterations = 4U;
}
for (index = 0U; index < nbiterations; index++)
{
FLASH_Program_HalfWord((Address + (2U*index)), (uint16_t)(Data >> (16U*index)));
#if defined(FLASH_BANK2_END)
if(Address <= FLASH_BANK1_END)
{
#endif /* FLASH_BANK2_END */
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation(FLASH_TIMEOUT_VALUE);
/* If the program operation is completed, disable the PG Bit */
CLEAR_BIT(FLASH->CR, FLASH_CR_PG);
#if defined(FLASH_BANK2_END)
}
else
{
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperationBank2(FLASH_TIMEOUT_VALUE);
/* If the program operation is completed, disable the PG Bit */
CLEAR_BIT(FLASH->CR2, FLASH_CR2_PG);
}
#endif /* FLASH_BANK2_END */
/* In case of error, stop programation procedure */
if (status != HAL_OK)
{
break;
}
}
}
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
return status;
}
/**
* @brief Program halfword, word or double word at a specified address with interrupt enabled.
* @note The function HAL_FLASH_Unlock() should be called before to unlock the FLASH interface
* The function HAL_FLASH_Lock() should be called after to lock the FLASH interface
*
* @note If an erase and a program operations are requested simultaneously,
* the erase operation is performed before the program one.
*
* @param TypeProgram: Indicate the way to program at a specified address.
* This parameter can be a value of @ref FLASH_Type_Program
* @param Address: Specifies the address to be programmed.
* @param Data: Specifies the data to be programmed
*
* @retval HAL_StatusTypeDef HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_Program_IT(uint32_t TypeProgram, uint32_t Address, uint64_t Data)
{
HAL_StatusTypeDef status = HAL_OK;
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Check the parameters */
assert_param(IS_FLASH_TYPEPROGRAM(TypeProgram));
assert_param(IS_FLASH_PROGRAM_ADDRESS(Address));
#if defined(FLASH_BANK2_END)
/* If procedure already ongoing, reject the next one */
if (pFlash.ProcedureOnGoing != FLASH_PROC_NONE)
{
return HAL_ERROR;
}
if(Address <= FLASH_BANK1_END)
{
/* Enable End of FLASH Operation and Error source interrupts */
__HAL_FLASH_ENABLE_IT(FLASH_IT_EOP_BANK1 | FLASH_IT_ERR_BANK1);
}else
{
/* Enable End of FLASH Operation and Error source interrupts */
__HAL_FLASH_ENABLE_IT(FLASH_IT_EOP_BANK2 | FLASH_IT_ERR_BANK2);
}
#else
/* Enable End of FLASH Operation and Error source interrupts */
__HAL_FLASH_ENABLE_IT(FLASH_IT_EOP | FLASH_IT_ERR);
#endif /* FLASH_BANK2_END */
pFlash.Address = Address;
pFlash.Data = Data;
if(TypeProgram == FLASH_TYPEPROGRAM_HALFWORD)
{
pFlash.ProcedureOnGoing = FLASH_PROC_PROGRAMHALFWORD;
/* Program halfword (16-bit) at a specified address. */
pFlash.DataRemaining = 1U;
}
else if(TypeProgram == FLASH_TYPEPROGRAM_WORD)
{
pFlash.ProcedureOnGoing = FLASH_PROC_PROGRAMWORD;
/* Program word (32-bit : 2*16-bit) at a specified address. */
pFlash.DataRemaining = 2U;
}
else
{
pFlash.ProcedureOnGoing = FLASH_PROC_PROGRAMDOUBLEWORD;
/* Program double word (64-bit : 4*16-bit) at a specified address. */
pFlash.DataRemaining = 4U;
}
/* Program halfword (16-bit) at a specified address. */
FLASH_Program_HalfWord(Address, (uint16_t)Data);
return status;
}
/**
* @brief This function handles FLASH interrupt request.
* @retval None
*/
void HAL_FLASH_IRQHandler(void)
{
uint32_t addresstmp = 0U;
/* Check FLASH operation error flags */
#if defined(FLASH_BANK2_END)
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR_BANK1) || __HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR_BANK1) || \
(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR_BANK2) || __HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR_BANK2)))
#else
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR) ||__HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR))
#endif /* FLASH_BANK2_END */
{
/* Return the faulty address */
addresstmp = pFlash.Address;
/* Reset address */
pFlash.Address = 0xFFFFFFFFU;
/* Save the Error code */
FLASH_SetErrorCode();
/* FLASH error interrupt user callback */
HAL_FLASH_OperationErrorCallback(addresstmp);
/* Stop the procedure ongoing */
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
/* Check FLASH End of Operation flag */
#if defined(FLASH_BANK2_END)
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP_BANK1))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP_BANK1);
#else
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP);
#endif /* FLASH_BANK2_END */
/* Process can continue only if no error detected */
if(pFlash.ProcedureOnGoing != FLASH_PROC_NONE)
{
if(pFlash.ProcedureOnGoing == FLASH_PROC_PAGEERASE)
{
/* Nb of pages to erased can be decreased */
pFlash.DataRemaining--;
/* Check if there are still pages to erase */
if(pFlash.DataRemaining != 0U)
{
addresstmp = pFlash.Address;
/*Indicate user which sector has been erased */
HAL_FLASH_EndOfOperationCallback(addresstmp);
/*Increment sector number*/
addresstmp = pFlash.Address + FLASH_PAGE_SIZE;
pFlash.Address = addresstmp;
/* If the erase operation is completed, disable the PER Bit */
CLEAR_BIT(FLASH->CR, FLASH_CR_PER);
FLASH_PageErase(addresstmp);
}
else
{
/* No more pages to Erase, user callback can be called. */
/* Reset Sector and stop Erase pages procedure */
pFlash.Address = addresstmp = 0xFFFFFFFFU;
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(addresstmp);
}
}
else if(pFlash.ProcedureOnGoing == FLASH_PROC_MASSERASE)
{
/* Operation is completed, disable the MER Bit */
CLEAR_BIT(FLASH->CR, FLASH_CR_MER);
#if defined(FLASH_BANK2_END)
/* Stop Mass Erase procedure if no pending mass erase on other bank */
if (HAL_IS_BIT_CLR(FLASH->CR2, FLASH_CR2_MER))
{
#endif /* FLASH_BANK2_END */
/* MassErase ended. Return the selected bank */
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(0U);
/* Stop Mass Erase procedure*/
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
#if defined(FLASH_BANK2_END)
}
#endif /* FLASH_BANK2_END */
else
{
/* Nb of 16-bit data to program can be decreased */
pFlash.DataRemaining--;
/* Check if there are still 16-bit data to program */
if(pFlash.DataRemaining != 0U)
{
/* Increment address to 16-bit */
pFlash.Address += 2U;
addresstmp = pFlash.Address;
/* Shift to have next 16-bit data */
pFlash.Data = (pFlash.Data >> 16U);
/* Operation is completed, disable the PG Bit */
CLEAR_BIT(FLASH->CR, FLASH_CR_PG);
/*Program halfword (16-bit) at a specified address.*/
FLASH_Program_HalfWord(addresstmp, (uint16_t)pFlash.Data);
}
else
{
/* Program ended. Return the selected address */
/* FLASH EOP interrupt user callback */
if (pFlash.ProcedureOnGoing == FLASH_PROC_PROGRAMHALFWORD)
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address);
}
else if (pFlash.ProcedureOnGoing == FLASH_PROC_PROGRAMWORD)
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address - 2U);
}
else
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address - 6U);
}
/* Reset Address and stop Program procedure */
pFlash.Address = 0xFFFFFFFFU;
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
}
}
}
#if defined(FLASH_BANK2_END)
/* Check FLASH End of Operation flag */
if(__HAL_FLASH_GET_FLAG( FLASH_FLAG_EOP_BANK2))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP_BANK2);
/* Process can continue only if no error detected */
if(pFlash.ProcedureOnGoing != FLASH_PROC_NONE)
{
if(pFlash.ProcedureOnGoing == FLASH_PROC_PAGEERASE)
{
/* Nb of pages to erased can be decreased */
pFlash.DataRemaining--;
/* Check if there are still pages to erase*/
if(pFlash.DataRemaining != 0U)
{
/* Indicate user which page address has been erased*/
HAL_FLASH_EndOfOperationCallback(pFlash.Address);
/* Increment page address to next page */
pFlash.Address += FLASH_PAGE_SIZE;
addresstmp = pFlash.Address;
/* Operation is completed, disable the PER Bit */
CLEAR_BIT(FLASH->CR2, FLASH_CR2_PER);
FLASH_PageErase(addresstmp);
}
else
{
/*No more pages to Erase*/
/*Reset Address and stop Erase pages procedure*/
pFlash.Address = 0xFFFFFFFFU;
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(pFlash.Address);
}
}
else if(pFlash.ProcedureOnGoing == FLASH_PROC_MASSERASE)
{
/* Operation is completed, disable the MER Bit */
CLEAR_BIT(FLASH->CR2, FLASH_CR2_MER);
if (HAL_IS_BIT_CLR(FLASH->CR, FLASH_CR_MER))
{
/* MassErase ended. Return the selected bank*/
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(0U);
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
}
else
{
/* Nb of 16-bit data to program can be decreased */
pFlash.DataRemaining--;
/* Check if there are still 16-bit data to program */
if(pFlash.DataRemaining != 0U)
{
/* Increment address to 16-bit */
pFlash.Address += 2U;
addresstmp = pFlash.Address;
/* Shift to have next 16-bit data */
pFlash.Data = (pFlash.Data >> 16U);
/* Operation is completed, disable the PG Bit */
CLEAR_BIT(FLASH->CR2, FLASH_CR2_PG);
/*Program halfword (16-bit) at a specified address.*/
FLASH_Program_HalfWord(addresstmp, (uint16_t)pFlash.Data);
}
else
{
/*Program ended. Return the selected address*/
/* FLASH EOP interrupt user callback */
if (pFlash.ProcedureOnGoing == FLASH_PROC_PROGRAMHALFWORD)
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address);
}
else if (pFlash.ProcedureOnGoing == FLASH_PROC_PROGRAMWORD)
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address-2U);
}
else
{
HAL_FLASH_EndOfOperationCallback(pFlash.Address-6U);
}
/* Reset Address and stop Program procedure*/
pFlash.Address = 0xFFFFFFFFU;
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
}
}
}
#endif
if(pFlash.ProcedureOnGoing == FLASH_PROC_NONE)
{
#if defined(FLASH_BANK2_END)
/* Operation is completed, disable the PG, PER and MER Bits for both bank */
CLEAR_BIT(FLASH->CR, (FLASH_CR_PG | FLASH_CR_PER | FLASH_CR_MER));
CLEAR_BIT(FLASH->CR2, (FLASH_CR2_PG | FLASH_CR2_PER | FLASH_CR2_MER));
/* Disable End of FLASH Operation and Error source interrupts for both banks */
__HAL_FLASH_DISABLE_IT(FLASH_IT_EOP_BANK1 | FLASH_IT_ERR_BANK1 | FLASH_IT_EOP_BANK2 | FLASH_IT_ERR_BANK2);
#else
/* Operation is completed, disable the PG, PER and MER Bits */
CLEAR_BIT(FLASH->CR, (FLASH_CR_PG | FLASH_CR_PER | FLASH_CR_MER));
/* Disable End of FLASH Operation and Error source interrupts */
__HAL_FLASH_DISABLE_IT(FLASH_IT_EOP | FLASH_IT_ERR);
#endif /* FLASH_BANK2_END */
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
}
}
/**
* @brief FLASH end of operation interrupt callback
* @param ReturnValue: The value saved in this parameter depends on the ongoing procedure
* - Mass Erase: No return value expected
* - Pages Erase: Address of the page which has been erased
* (if 0xFFFFFFFF, it means that all the selected pages have been erased)
* - Program: Address which was selected for data program
* @retval none
*/
__weak void HAL_FLASH_EndOfOperationCallback(uint32_t ReturnValue)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(ReturnValue);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_FLASH_EndOfOperationCallback could be implemented in the user file
*/
}
/**
* @brief FLASH operation error interrupt callback
* @param ReturnValue: The value saved in this parameter depends on the ongoing procedure
* - Mass Erase: No return value expected
* - Pages Erase: Address of the page which returned an error
* - Program: Address which was selected for data program
* @retval none
*/
__weak void HAL_FLASH_OperationErrorCallback(uint32_t ReturnValue)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(ReturnValue);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_FLASH_OperationErrorCallback could be implemented in the user file
*/
}
/**
* @}
*/
/** @defgroup FLASH_Exported_Functions_Group2 Peripheral Control functions
* @brief management functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the FLASH
memory operations.
@endverbatim
* @{
*/
/**
* @brief Unlock the FLASH control register access
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_Unlock(void)
{
HAL_StatusTypeDef status = HAL_OK;
if(READ_BIT(FLASH->CR, FLASH_CR_LOCK) != RESET)
{
/* Authorize the FLASH Registers access */
WRITE_REG(FLASH->KEYR, FLASH_KEY1);
WRITE_REG(FLASH->KEYR, FLASH_KEY2);
/* Verify Flash is unlocked */
if(READ_BIT(FLASH->CR, FLASH_CR_LOCK) != RESET)
{
status = HAL_ERROR;
}
}
#if defined(FLASH_BANK2_END)
if(READ_BIT(FLASH->CR2, FLASH_CR2_LOCK) != RESET)
{
/* Authorize the FLASH BANK2 Registers access */
WRITE_REG(FLASH->KEYR2, FLASH_KEY1);
WRITE_REG(FLASH->KEYR2, FLASH_KEY2);
/* Verify Flash BANK2 is unlocked */
if(READ_BIT(FLASH->CR2, FLASH_CR2_LOCK) != RESET)
{
status = HAL_ERROR;
}
}
#endif /* FLASH_BANK2_END */
return status;
}
/**
* @brief Locks the FLASH control register access
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_Lock(void)
{
/* Set the LOCK Bit to lock the FLASH Registers access */
SET_BIT(FLASH->CR, FLASH_CR_LOCK);
#if defined(FLASH_BANK2_END)
/* Set the LOCK Bit to lock the FLASH BANK2 Registers access */
SET_BIT(FLASH->CR2, FLASH_CR2_LOCK);
#endif /* FLASH_BANK2_END */
return HAL_OK;
}
/**
* @brief Unlock the FLASH Option Control Registers access.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_OB_Unlock(void)
{
if (HAL_IS_BIT_CLR(FLASH->CR, FLASH_CR_OPTWRE))
{
/* Authorizes the Option Byte register programming */
WRITE_REG(FLASH->OPTKEYR, FLASH_OPTKEY1);
WRITE_REG(FLASH->OPTKEYR, FLASH_OPTKEY2);
}
else
{
return HAL_ERROR;
}
return HAL_OK;
}
/**
* @brief Lock the FLASH Option Control Registers access.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_FLASH_OB_Lock(void)
{
/* Clear the OPTWRE Bit to lock the FLASH Option Byte Registers access */
CLEAR_BIT(FLASH->CR, FLASH_CR_OPTWRE);
return HAL_OK;
}
/**
* @brief Launch the option byte loading.
* @note This function will reset automatically the MCU.
* @retval None
*/
void HAL_FLASH_OB_Launch(void)
{
/* Initiates a system reset request to launch the option byte loading */
HAL_NVIC_SystemReset();
}
/**
* @}
*/
/** @defgroup FLASH_Exported_Functions_Group3 Peripheral errors functions
* @brief Peripheral errors functions
*
@verbatim
===============================================================================
##### Peripheral Errors functions #####
===============================================================================
[..]
This subsection permit to get in run-time errors of the FLASH peripheral.
@endverbatim
* @{
*/
/**
* @brief Get the specific FLASH error flag.
* @retval FLASH_ErrorCode The returned value can be:
* @ref FLASH_Error_Codes
*/
uint32_t HAL_FLASH_GetError(void)
{
return pFlash.ErrorCode;
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup FLASH_Private_Functions
* @{
*/
/**
* @brief Program a half-word (16-bit) at a specified address.
* @param Address specify the address to be programmed.
* @param Data specify the data to be programmed.
* @retval None
*/
static void FLASH_Program_HalfWord(uint32_t Address, uint16_t Data)
{
/* Clean the error context */
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
#if defined(FLASH_BANK2_END)
if(Address <= FLASH_BANK1_END)
{
#endif /* FLASH_BANK2_END */
/* Proceed to program the new data */
SET_BIT(FLASH->CR, FLASH_CR_PG);
#if defined(FLASH_BANK2_END)
}
else
{
/* Proceed to program the new data */
SET_BIT(FLASH->CR2, FLASH_CR2_PG);
}
#endif /* FLASH_BANK2_END */
/* Write data in the address */
*(__IO uint16_t*)Address = Data;
}
/**
* @brief Wait for a FLASH operation to complete.
* @param Timeout maximum flash operation timeout
* @retval HAL Status
*/
HAL_StatusTypeDef FLASH_WaitForLastOperation(uint32_t Timeout)
{
/* Wait for the FLASH operation to complete by polling on BUSY flag to be reset.
Even if the FLASH operation fails, the BUSY flag will be reset and an error
flag will be set */
uint32_t tickstart = HAL_GetTick();
while(__HAL_FLASH_GET_FLAG(FLASH_FLAG_BSY))
{
if (Timeout != HAL_MAX_DELAY)
{
if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout))
{
return HAL_TIMEOUT;
}
}
}
/* Check FLASH End of Operation flag */
if (__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP);
}
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR) ||
__HAL_FLASH_GET_FLAG(FLASH_FLAG_OPTVERR) ||
__HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR))
{
/*Save the error code*/
FLASH_SetErrorCode();
return HAL_ERROR;
}
/* There is no error flag set */
return HAL_OK;
}
#if defined(FLASH_BANK2_END)
/**
* @brief Wait for a FLASH BANK2 operation to complete.
* @param Timeout maximum flash operation timeout
* @retval HAL_StatusTypeDef HAL Status
*/
HAL_StatusTypeDef FLASH_WaitForLastOperationBank2(uint32_t Timeout)
{
/* Wait for the FLASH BANK2 operation to complete by polling on BUSY flag to be reset.
Even if the FLASH BANK2 operation fails, the BUSY flag will be reset and an error
flag will be set */
uint32_t tickstart = HAL_GetTick();
while(__HAL_FLASH_GET_FLAG(FLASH_FLAG_BSY_BANK2))
{
if (Timeout != HAL_MAX_DELAY)
{
if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout))
{
return HAL_TIMEOUT;
}
}
}
/* Check FLASH End of Operation flag */
if (__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP_BANK2))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP_BANK2);
}
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR_BANK2) || __HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR_BANK2))
{
/*Save the error code*/
FLASH_SetErrorCode();
return HAL_ERROR;
}
/* If there is an error flag set */
return HAL_OK;
}
#endif /* FLASH_BANK2_END */
/**
* @brief Set the specific FLASH error flag.
* @retval None
*/
static void FLASH_SetErrorCode(void)
{
uint32_t flags = 0U;
#if defined(FLASH_BANK2_END)
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR) || __HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR_BANK2))
#else
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_WRPERR))
#endif /* FLASH_BANK2_END */
{
pFlash.ErrorCode |= HAL_FLASH_ERROR_WRP;
#if defined(FLASH_BANK2_END)
flags |= FLASH_FLAG_WRPERR | FLASH_FLAG_WRPERR_BANK2;
#else
flags |= FLASH_FLAG_WRPERR;
#endif /* FLASH_BANK2_END */
}
#if defined(FLASH_BANK2_END)
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR) || __HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR_BANK2))
#else
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_PGERR))
#endif /* FLASH_BANK2_END */
{
pFlash.ErrorCode |= HAL_FLASH_ERROR_PROG;
#if defined(FLASH_BANK2_END)
flags |= FLASH_FLAG_PGERR | FLASH_FLAG_PGERR_BANK2;
#else
flags |= FLASH_FLAG_PGERR;
#endif /* FLASH_BANK2_END */
}
if(__HAL_FLASH_GET_FLAG(FLASH_FLAG_OPTVERR))
{
pFlash.ErrorCode |= HAL_FLASH_ERROR_OPTV;
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_OPTVERR);
}
/* Clear FLASH error pending bits */
__HAL_FLASH_CLEAR_FLAG(flags);
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_FLASH_MODULE_ENABLED */
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_gpio.c
* @author MCD Application Team
* @brief GPIO HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the General Purpose Input/Output (GPIO) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### GPIO Peripheral features #####
==============================================================================
[..]
Subject to the specific hardware characteristics of each I/O port listed in the datasheet, each
port bit of the General Purpose IO (GPIO) Ports, can be individually configured by software
in several modes:
(+) Input mode
(+) Analog mode
(+) Output mode
(+) Alternate function mode
(+) External interrupt/event lines
[..]
During and just after reset, the alternate functions and external interrupt
lines are not active and the I/O ports are configured in input floating mode.
[..]
All GPIO pins have weak internal pull-up and pull-down resistors, which can be
activated or not.
[..]
In Output or Alternate mode, each IO can be configured on open-drain or push-pull
type and the IO speed can be selected depending on the VDD value.
[..]
All ports have external interrupt/event capability. To use external interrupt
lines, the port must be configured in input mode. All available GPIO pins are
connected to the 16 external interrupt/event lines from EXTI0 to EXTI15.
[..]
The external interrupt/event controller consists of up to 20 edge detectors in connectivity
line devices, or 19 edge detectors in other devices for generating event/interrupt requests.
Each input line can be independently configured to select the type (event or interrupt) and
the corresponding trigger event (rising or falling or both). Each line can also masked
independently. A pending register maintains the status line of the interrupt requests
##### How to use this driver #####
==============================================================================
[..]
(#) Enable the GPIO APB2 clock using the following function : __HAL_RCC_GPIOx_CLK_ENABLE().
(#) Configure the GPIO pin(s) using HAL_GPIO_Init().
(++) Configure the IO mode using "Mode" member from GPIO_InitTypeDef structure
(++) Activate Pull-up, Pull-down resistor using "Pull" member from GPIO_InitTypeDef
structure.
(++) In case of Output or alternate function mode selection: the speed is
configured through "Speed" member from GPIO_InitTypeDef structure
(++) Analog mode is required when a pin is to be used as ADC channel
or DAC output.
(++) In case of external interrupt/event selection the "Mode" member from
GPIO_InitTypeDef structure select the type (interrupt or event) and
the corresponding trigger event (rising or falling or both).
(#) In case of external interrupt/event mode selection, configure NVIC IRQ priority
mapped to the EXTI line using HAL_NVIC_SetPriority() and enable it using
HAL_NVIC_EnableIRQ().
(#) To get the level of a pin configured in input mode use HAL_GPIO_ReadPin().
(#) To set/reset the level of a pin configured in output mode use
HAL_GPIO_WritePin()/HAL_GPIO_TogglePin().
(#) To lock pin configuration until next reset use HAL_GPIO_LockPin().
(#) During and just after reset, the alternate functions are not
active and the GPIO pins are configured in input floating mode (except JTAG
pins).
(#) The LSE oscillator pins OSC32_IN and OSC32_OUT can be used as general purpose
(PC14 and PC15, respectively) when the LSE oscillator is off. The LSE has
priority over the GPIO function.
(#) The HSE oscillator pins OSC_IN/OSC_OUT can be used as
general purpose PD0 and PD1, respectively, when the HSE oscillator is off.
The HSE has priority over the GPIO function.
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup GPIO GPIO
* @brief GPIO HAL module driver
* @{
*/
#ifdef HAL_GPIO_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @addtogroup GPIO_Private_Constants GPIO Private Constants
* @{
*/
#define GPIO_MODE 0x00000003u
#define EXTI_MODE 0x10000000u
#define GPIO_MODE_IT 0x00010000u
#define GPIO_MODE_EVT 0x00020000u
#define RISING_EDGE 0x00100000u
#define FALLING_EDGE 0x00200000u
#define GPIO_OUTPUT_TYPE 0x00000010u
#define GPIO_NUMBER 16u
/* Definitions for bit manipulation of CRL and CRH register */
#define GPIO_CR_MODE_INPUT 0x00000000u /*!< 00: Input mode (reset state) */
#define GPIO_CR_CNF_ANALOG 0x00000000u /*!< 00: Analog mode */
#define GPIO_CR_CNF_INPUT_FLOATING 0x00000004u /*!< 01: Floating input (reset state) */
#define GPIO_CR_CNF_INPUT_PU_PD 0x00000008u /*!< 10: Input with pull-up / pull-down */
#define GPIO_CR_CNF_GP_OUTPUT_PP 0x00000000u /*!< 00: General purpose output push-pull */
#define GPIO_CR_CNF_GP_OUTPUT_OD 0x00000004u /*!< 01: General purpose output Open-drain */
#define GPIO_CR_CNF_AF_OUTPUT_PP 0x00000008u /*!< 10: Alternate function output Push-pull */
#define GPIO_CR_CNF_AF_OUTPUT_OD 0x0000000Cu /*!< 11: Alternate function output Open-drain */
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup GPIO_Exported_Functions GPIO Exported Functions
* @{
*/
/** @defgroup GPIO_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 initialize and de-initialize the GPIOs
to be ready for use.
@endverbatim
* @{
*/
/**
* @brief Initializes the GPIOx peripheral according to the specified parameters in the GPIO_Init.
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Init: pointer to a GPIO_InitTypeDef structure that contains
* the configuration information for the specified GPIO peripheral.
* @retval None
*/
void HAL_GPIO_Init(GPIO_TypeDef *GPIOx, GPIO_InitTypeDef *GPIO_Init)
{
uint32_t position = 0x00u;
uint32_t ioposition;
uint32_t iocurrent;
uint32_t temp;
uint32_t config = 0x00u;
__IO uint32_t *configregister; /* Store the address of CRL or CRH register based on pin number */
uint32_t registeroffset; /* offset used during computation of CNF and MODE bits placement inside CRL or CRH register */
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Init->Pin));
assert_param(IS_GPIO_MODE(GPIO_Init->Mode));
/* Configure the port pins */
while (((GPIO_Init->Pin) >> position) != 0x00u)
{
/* Get the IO position */
ioposition = (0x01uL << position);
/* Get the current IO position */
iocurrent = (uint32_t)(GPIO_Init->Pin) & ioposition;
if (iocurrent == ioposition)
{
/* Check the Alternate function parameters */
assert_param(IS_GPIO_AF_INSTANCE(GPIOx));
/* Based on the required mode, filling config variable with MODEy[1:0] and CNFy[3:2] corresponding bits */
switch (GPIO_Init->Mode)
{
/* If we are configuring the pin in OUTPUT push-pull mode */
case GPIO_MODE_OUTPUT_PP:
/* Check the GPIO speed parameter */
assert_param(IS_GPIO_SPEED(GPIO_Init->Speed));
config = GPIO_Init->Speed + GPIO_CR_CNF_GP_OUTPUT_PP;
break;
/* If we are configuring the pin in OUTPUT open-drain mode */
case GPIO_MODE_OUTPUT_OD:
/* Check the GPIO speed parameter */
assert_param(IS_GPIO_SPEED(GPIO_Init->Speed));
config = GPIO_Init->Speed + GPIO_CR_CNF_GP_OUTPUT_OD;
break;
/* If we are configuring the pin in ALTERNATE FUNCTION push-pull mode */
case GPIO_MODE_AF_PP:
/* Check the GPIO speed parameter */
assert_param(IS_GPIO_SPEED(GPIO_Init->Speed));
config = GPIO_Init->Speed + GPIO_CR_CNF_AF_OUTPUT_PP;
break;
/* If we are configuring the pin in ALTERNATE FUNCTION open-drain mode */
case GPIO_MODE_AF_OD:
/* Check the GPIO speed parameter */
assert_param(IS_GPIO_SPEED(GPIO_Init->Speed));
config = GPIO_Init->Speed + GPIO_CR_CNF_AF_OUTPUT_OD;
break;
/* If we are configuring the pin in INPUT (also applicable to EVENT and IT mode) */
case GPIO_MODE_INPUT:
case GPIO_MODE_IT_RISING:
case GPIO_MODE_IT_FALLING:
case GPIO_MODE_IT_RISING_FALLING:
case GPIO_MODE_EVT_RISING:
case GPIO_MODE_EVT_FALLING:
case GPIO_MODE_EVT_RISING_FALLING:
/* Check the GPIO pull parameter */
assert_param(IS_GPIO_PULL(GPIO_Init->Pull));
if (GPIO_Init->Pull == GPIO_NOPULL)
{
config = GPIO_CR_MODE_INPUT + GPIO_CR_CNF_INPUT_FLOATING;
}
else if (GPIO_Init->Pull == GPIO_PULLUP)
{
config = GPIO_CR_MODE_INPUT + GPIO_CR_CNF_INPUT_PU_PD;
/* Set the corresponding ODR bit */
GPIOx->BSRR = ioposition;
}
else /* GPIO_PULLDOWN */
{
config = GPIO_CR_MODE_INPUT + GPIO_CR_CNF_INPUT_PU_PD;
/* Reset the corresponding ODR bit */
GPIOx->BRR = ioposition;
}
break;
/* If we are configuring the pin in INPUT analog mode */
case GPIO_MODE_ANALOG:
config = GPIO_CR_MODE_INPUT + GPIO_CR_CNF_ANALOG;
break;
/* Parameters are checked with assert_param */
default:
break;
}
/* Check if the current bit belongs to first half or last half of the pin count number
in order to address CRH or CRL register*/
configregister = (iocurrent < GPIO_PIN_8) ? &GPIOx->CRL : &GPIOx->CRH;
registeroffset = (iocurrent < GPIO_PIN_8) ? (position << 2u) : ((position - 8u) << 2u);
/* Apply the new configuration of the pin to the register */
MODIFY_REG((*configregister), ((GPIO_CRL_MODE0 | GPIO_CRL_CNF0) << registeroffset), (config << registeroffset));
/*--------------------- EXTI Mode Configuration ------------------------*/
/* Configure the External Interrupt or event for the current IO */
if ((GPIO_Init->Mode & EXTI_MODE) == EXTI_MODE)
{
/* Enable AFIO Clock */
__HAL_RCC_AFIO_CLK_ENABLE();
temp = AFIO->EXTICR[position >> 2u];
CLEAR_BIT(temp, (0x0Fu) << (4u * (position & 0x03u)));
SET_BIT(temp, (GPIO_GET_INDEX(GPIOx)) << (4u * (position & 0x03u)));
AFIO->EXTICR[position >> 2u] = temp;
/* Enable or disable the rising trigger */
if ((GPIO_Init->Mode & RISING_EDGE) == RISING_EDGE)
{
SET_BIT(EXTI->RTSR, iocurrent);
}
else
{
CLEAR_BIT(EXTI->RTSR, iocurrent);
}
/* Enable or disable the falling trigger */
if ((GPIO_Init->Mode & FALLING_EDGE) == FALLING_EDGE)
{
SET_BIT(EXTI->FTSR, iocurrent);
}
else
{
CLEAR_BIT(EXTI->FTSR, iocurrent);
}
/* Configure the event mask */
if ((GPIO_Init->Mode & GPIO_MODE_EVT) == GPIO_MODE_EVT)
{
SET_BIT(EXTI->EMR, iocurrent);
}
else
{
CLEAR_BIT(EXTI->EMR, iocurrent);
}
/* Configure the interrupt mask */
if ((GPIO_Init->Mode & GPIO_MODE_IT) == GPIO_MODE_IT)
{
SET_BIT(EXTI->IMR, iocurrent);
}
else
{
CLEAR_BIT(EXTI->IMR, iocurrent);
}
}
}
position++;
}
}
/**
* @brief De-initializes the GPIOx peripheral registers to their default reset values.
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Pin: specifies the port bit to be written.
* This parameter can be one of GPIO_PIN_x where x can be (0..15).
* @retval None
*/
void HAL_GPIO_DeInit(GPIO_TypeDef *GPIOx, uint32_t GPIO_Pin)
{
uint32_t position = 0x00u;
uint32_t iocurrent;
uint32_t tmp;
__IO uint32_t *configregister; /* Store the address of CRL or CRH register based on pin number */
uint32_t registeroffset;
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* Configure the port pins */
while ((GPIO_Pin >> position) != 0u)
{
/* Get current io position */
iocurrent = (GPIO_Pin) & (1uL << position);
if (iocurrent)
{
/*------------------------- EXTI Mode Configuration --------------------*/
/* Clear the External Interrupt or Event for the current IO */
tmp = AFIO->EXTICR[position >> 2u];
tmp &= 0x0FuL << (4u * (position & 0x03u));
if (tmp == (GPIO_GET_INDEX(GPIOx) << (4u * (position & 0x03u))))
{
/* Clear EXTI line configuration */
CLEAR_BIT(EXTI->IMR, (uint32_t)iocurrent);
CLEAR_BIT(EXTI->EMR, (uint32_t)iocurrent);
/* Clear Rising Falling edge configuration */
CLEAR_BIT(EXTI->FTSR, (uint32_t)iocurrent);
CLEAR_BIT(EXTI->RTSR, (uint32_t)iocurrent);
tmp = 0x0FuL << (4u * (position & 0x03u));
CLEAR_BIT(AFIO->EXTICR[position >> 2u], tmp);
}
/*------------------------- GPIO Mode Configuration --------------------*/
/* Check if the current bit belongs to first half or last half of the pin count number
in order to address CRH or CRL register */
configregister = (iocurrent < GPIO_PIN_8) ? &GPIOx->CRL : &GPIOx->CRH;
registeroffset = (iocurrent < GPIO_PIN_8) ? (position << 2u) : ((position - 8u) << 2u);
/* CRL/CRH default value is floating input(0x04) shifted to correct position */
MODIFY_REG(*configregister, ((GPIO_CRL_MODE0 | GPIO_CRL_CNF0) << registeroffset), GPIO_CRL_CNF0_0 << registeroffset);
/* ODR default value is 0 */
CLEAR_BIT(GPIOx->ODR, iocurrent);
}
position++;
}
}
/**
* @}
*/
/** @defgroup GPIO_Exported_Functions_Group2 IO operation functions
* @brief GPIO Read and Write
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to manage the GPIOs.
@endverbatim
* @{
*/
/**
* @brief Reads the specified input port pin.
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Pin: specifies the port bit to read.
* This parameter can be GPIO_PIN_x where x can be (0..15).
* @retval The input port pin value.
*/
GPIO_PinState HAL_GPIO_ReadPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
GPIO_PinState bitstatus;
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
if ((GPIOx->IDR & GPIO_Pin) != (uint32_t)GPIO_PIN_RESET)
{
bitstatus = GPIO_PIN_SET;
}
else
{
bitstatus = GPIO_PIN_RESET;
}
return bitstatus;
}
/**
* @brief Sets or clears the selected data port bit.
*
* @note This function uses GPIOx_BSRR register to allow atomic read/modify
* accesses. In this way, there is no risk of an IRQ occurring between
* the read and the modify access.
*
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Pin: specifies the port bit to be written.
* This parameter can be one of GPIO_PIN_x where x can be (0..15).
* @param PinState: specifies the value to be written to the selected bit.
* This parameter can be one of the GPIO_PinState enum values:
* @arg GPIO_PIN_RESET: to clear the port pin
* @arg GPIO_PIN_SET: to set the port pin
* @retval None
*/
void HAL_GPIO_WritePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin, GPIO_PinState PinState)
{
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
assert_param(IS_GPIO_PIN_ACTION(PinState));
if (PinState != GPIO_PIN_RESET)
{
GPIOx->BSRR = GPIO_Pin;
}
else
{
GPIOx->BSRR = (uint32_t)GPIO_Pin << 16u;
}
}
/**
* @brief Toggles the specified GPIO pin
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Pin: Specifies the pins to be toggled.
* @retval None
*/
void HAL_GPIO_TogglePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
uint32_t odr;
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* get current Output Data Register value */
odr = GPIOx->ODR;
/* Set selected pins that were at low level, and reset ones that were high */
GPIOx->BSRR = ((odr & GPIO_Pin) << GPIO_NUMBER) | (~odr & GPIO_Pin);
}
/**
* @brief Locks GPIO Pins configuration registers.
* @note The locking mechanism allows the IO configuration to be frozen. When the LOCK sequence
* has been applied on a port bit, it is no longer possible to modify the value of the port bit until
* the next reset.
* @param GPIOx: where x can be (A..G depending on device used) to select the GPIO peripheral
* @param GPIO_Pin: specifies the port bit to be locked.
* This parameter can be any combination of GPIO_Pin_x where x can be (0..15).
* @retval None
*/
HAL_StatusTypeDef HAL_GPIO_LockPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
__IO uint32_t tmp = GPIO_LCKR_LCKK;
/* Check the parameters */
assert_param(IS_GPIO_LOCK_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* Apply lock key write sequence */
SET_BIT(tmp, GPIO_Pin);
/* Set LCKx bit(s): LCKK='1' + LCK[15-0] */
GPIOx->LCKR = tmp;
/* Reset LCKx bit(s): LCKK='0' + LCK[15-0] */
GPIOx->LCKR = GPIO_Pin;
/* Set LCKx bit(s): LCKK='1' + LCK[15-0] */
GPIOx->LCKR = tmp;
/* Read LCKK register. This read is mandatory to complete key lock sequence */
tmp = GPIOx->LCKR;
/* read again in order to confirm lock is active */
if ((uint32_t)(GPIOx->LCKR & GPIO_LCKR_LCKK))
{
return HAL_OK;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief This function handles EXTI interrupt request.
* @param GPIO_Pin: Specifies the pins connected EXTI line
* @retval None
*/
void HAL_GPIO_EXTI_IRQHandler(uint16_t GPIO_Pin)
{
/* EXTI line interrupt detected */
if (__HAL_GPIO_EXTI_GET_IT(GPIO_Pin) != 0x00u)
{
__HAL_GPIO_EXTI_CLEAR_IT(GPIO_Pin);
HAL_GPIO_EXTI_Callback(GPIO_Pin);
}
}
/**
* @brief EXTI line detection callbacks.
* @param GPIO_Pin: Specifies the pins connected EXTI line
* @retval None
*/
__weak void HAL_GPIO_EXTI_Callback(uint16_t GPIO_Pin)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(GPIO_Pin);
/* NOTE: This function Should not be modified, when the callback is needed,
the HAL_GPIO_EXTI_Callback could be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_GPIO_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_gpio_ex.c
* @author MCD Application Team
* @brief GPIO Extension HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the General Purpose Input/Output (GPIO) extension peripheral.
* + Extended features functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### GPIO Peripheral extension features #####
==============================================================================
[..] GPIO module on STM32F1 family, manage also the AFIO register:
(+) Possibility to use the EVENTOUT Cortex feature
##### How to use this driver #####
==============================================================================
[..] This driver provides functions to use EVENTOUT Cortex feature
(#) Configure EVENTOUT Cortex feature using the function HAL_GPIOEx_ConfigEventout()
(#) Activate EVENTOUT Cortex feature using the HAL_GPIOEx_EnableEventout()
(#) Deactivate EVENTOUT Cortex feature using the HAL_GPIOEx_DisableEventout()
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup GPIOEx GPIOEx
* @brief GPIO HAL module driver
* @{
*/
#ifdef HAL_GPIO_MODULE_ENABLED
/** @defgroup GPIOEx_Exported_Functions GPIOEx Exported Functions
* @{
*/
/** @defgroup GPIOEx_Exported_Functions_Group1 Extended features functions
* @brief Extended features functions
*
@verbatim
==============================================================================
##### Extended features functions #####
==============================================================================
[..] This section provides functions allowing to:
(+) Configure EVENTOUT Cortex feature using the function HAL_GPIOEx_ConfigEventout()
(+) Activate EVENTOUT Cortex feature using the HAL_GPIOEx_EnableEventout()
(+) Deactivate EVENTOUT Cortex feature using the HAL_GPIOEx_DisableEventout()
@endverbatim
* @{
*/
/**
* @brief Configures the port and pin on which the EVENTOUT Cortex signal will be connected.
* @param GPIO_PortSource Select the port used to output the Cortex EVENTOUT signal.
* This parameter can be a value of @ref GPIOEx_EVENTOUT_PORT.
* @param GPIO_PinSource Select the pin used to output the Cortex EVENTOUT signal.
* This parameter can be a value of @ref GPIOEx_EVENTOUT_PIN.
* @retval None
*/
void HAL_GPIOEx_ConfigEventout(uint32_t GPIO_PortSource, uint32_t GPIO_PinSource)
{
/* Verify the parameters */
assert_param(IS_AFIO_EVENTOUT_PORT(GPIO_PortSource));
assert_param(IS_AFIO_EVENTOUT_PIN(GPIO_PinSource));
/* Apply the new configuration */
MODIFY_REG(AFIO->EVCR, (AFIO_EVCR_PORT) | (AFIO_EVCR_PIN), (GPIO_PortSource) | (GPIO_PinSource));
}
/**
* @brief Enables the Event Output.
* @retval None
*/
void HAL_GPIOEx_EnableEventout(void)
{
SET_BIT(AFIO->EVCR, AFIO_EVCR_EVOE);
}
/**
* @brief Disables the Event Output.
* @retval None
*/
void HAL_GPIOEx_DisableEventout(void)
{
CLEAR_BIT(AFIO->EVCR, AFIO_EVCR_EVOE);
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_GPIO_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_pwr.c
* @author MCD Application Team
* @brief PWR HAL module driver.
*
* This file provides firmware functions to manage the following
* functionalities of the Power Controller (PWR) peripheral:
* + Initialization/de-initialization functions
* + Peripheral Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
/** @defgroup PWR PWR
* @brief PWR HAL module driver
* @{
*/
#ifdef HAL_PWR_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup PWR_Private_Constants PWR Private Constants
* @{
*/
/** @defgroup PWR_PVD_Mode_Mask PWR PVD Mode Mask
* @{
*/
#define PVD_MODE_IT 0x00010000U
#define PVD_MODE_EVT 0x00020000U
#define PVD_RISING_EDGE 0x00000001U
#define PVD_FALLING_EDGE 0x00000002U
/**
* @}
*/
/** @defgroup PWR_register_alias_address PWR Register alias address
* @{
*/
/* ------------- PWR registers bit address in the alias region ---------------*/
#define PWR_OFFSET (PWR_BASE - PERIPH_BASE)
#define PWR_CR_OFFSET 0x00U
#define PWR_CSR_OFFSET 0x04U
#define PWR_CR_OFFSET_BB (PWR_OFFSET + PWR_CR_OFFSET)
#define PWR_CSR_OFFSET_BB (PWR_OFFSET + PWR_CSR_OFFSET)
/**
* @}
*/
/** @defgroup PWR_CR_register_alias PWR CR Register alias address
* @{
*/
/* --- CR Register ---*/
/* Alias word address of LPSDSR bit */
#define LPSDSR_BIT_NUMBER PWR_CR_LPDS_Pos
#define CR_LPSDSR_BB ((uint32_t)(PERIPH_BB_BASE + (PWR_CR_OFFSET_BB * 32U) + (LPSDSR_BIT_NUMBER * 4U)))
/* Alias word address of DBP bit */
#define DBP_BIT_NUMBER PWR_CR_DBP_Pos
#define CR_DBP_BB ((uint32_t)(PERIPH_BB_BASE + (PWR_CR_OFFSET_BB * 32U) + (DBP_BIT_NUMBER * 4U)))
/* Alias word address of PVDE bit */
#define PVDE_BIT_NUMBER PWR_CR_PVDE_Pos
#define CR_PVDE_BB ((uint32_t)(PERIPH_BB_BASE + (PWR_CR_OFFSET_BB * 32U) + (PVDE_BIT_NUMBER * 4U)))
/**
* @}
*/
/** @defgroup PWR_CSR_register_alias PWR CSR Register alias address
* @{
*/
/* --- CSR Register ---*/
/* Alias word address of EWUP1 bit */
#define CSR_EWUP_BB(VAL) ((uint32_t)(PERIPH_BB_BASE + (PWR_CSR_OFFSET_BB * 32U) + (POSITION_VAL(VAL) * 4U)))
/**
* @}
*/
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup PWR_Private_Functions PWR Private Functions
* brief WFE cortex command overloaded for HAL_PWR_EnterSTOPMode usage only (see Workaround section)
* @{
*/
static void PWR_OverloadWfe(void);
/* Private functions ---------------------------------------------------------*/
__NOINLINE
static void PWR_OverloadWfe(void)
{
__asm volatile( "wfe" );
__asm volatile( "nop" );
}
/**
* @}
*/
/** @defgroup PWR_Exported_Functions PWR Exported Functions
* @{
*/
/** @defgroup PWR_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
After reset, the backup domain (RTC registers, RTC backup data
registers) is protected against possible unwanted
write accesses.
To enable access to the RTC Domain and RTC registers, proceed as follows:
(+) Enable the Power Controller (PWR) APB1 interface clock using the
__HAL_RCC_PWR_CLK_ENABLE() macro.
(+) Enable access to RTC domain using the HAL_PWR_EnableBkUpAccess() function.
@endverbatim
* @{
*/
/**
* @brief Deinitializes the PWR peripheral registers to their default reset values.
* @retval None
*/
void HAL_PWR_DeInit(void)
{
__HAL_RCC_PWR_FORCE_RESET();
__HAL_RCC_PWR_RELEASE_RESET();
}
/**
* @brief Enables access to the backup domain (RTC registers, RTC
* backup data registers ).
* @note If the HSE divided by 128 is used as the RTC clock, the
* Backup Domain Access should be kept enabled.
* @retval None
*/
void HAL_PWR_EnableBkUpAccess(void)
{
/* Enable access to RTC and backup registers */
*(__IO uint32_t *) CR_DBP_BB = (uint32_t)ENABLE;
}
/**
* @brief Disables access to the backup domain (RTC registers, RTC
* backup data registers).
* @note If the HSE divided by 128 is used as the RTC clock, the
* Backup Domain Access should be kept enabled.
* @retval None
*/
void HAL_PWR_DisableBkUpAccess(void)
{
/* Disable access to RTC and backup registers */
*(__IO uint32_t *) CR_DBP_BB = (uint32_t)DISABLE;
}
/**
* @}
*/
/** @defgroup PWR_Exported_Functions_Group2 Peripheral Control functions
* @brief Low Power modes configuration functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
*** PVD configuration ***
=========================
[..]
(+) The PVD is used to monitor the VDD power supply by comparing it to a
threshold selected by the PVD Level (PLS[2:0] bits in the PWR_CR).
(+) A PVDO flag is available to indicate if VDD/VDDA is higher or lower
than the PVD threshold. This event is internally connected to the EXTI
line16 and can generate an interrupt if enabled. This is done through
__HAL_PVD_EXTI_ENABLE_IT() macro.
(+) The PVD is stopped in Standby mode.
*** WakeUp pin configuration ***
================================
[..]
(+) WakeUp pin is used to wake up the system from Standby mode. This pin is
forced in input pull-down configuration and is active on rising edges.
(+) There is one WakeUp pin:
WakeUp Pin 1 on PA.00.
[..]
*** Low Power modes configuration ***
=====================================
[..]
The device features 3 low-power modes:
(+) Sleep mode: CPU clock off, all peripherals including Cortex-M3 core peripherals like
NVIC, SysTick, etc. are kept running
(+) Stop mode: All clocks are stopped
(+) Standby mode: 1.8V domain powered off
*** Sleep mode ***
==================
[..]
(+) Entry:
The Sleep mode is entered by using the HAL_PWR_EnterSLEEPMode(PWR_MAINREGULATOR_ON, PWR_SLEEPENTRY_WFx)
functions with
(++) PWR_SLEEPENTRY_WFI: enter SLEEP mode with WFI instruction
(++) PWR_SLEEPENTRY_WFE: enter SLEEP mode with WFE instruction
(+) Exit:
(++) WFI entry mode, Any peripheral interrupt acknowledged by the nested vectored interrupt
controller (NVIC) can wake up the device from Sleep mode.
(++) WFE entry mode, Any wakeup event can wake up the device from Sleep mode.
(+++) Any peripheral interrupt w/o NVIC configuration & SEVONPEND bit set in the Cortex (HAL_PWR_EnableSEVOnPend)
(+++) Any EXTI Line (Internal or External) configured in Event mode
*** Stop mode ***
=================
[..]
The Stop mode is based on the Cortex-M3 deepsleep mode combined with peripheral
clock gating. The voltage regulator can be configured either in normal or low-power mode.
In Stop mode, all clocks in the 1.8 V domain are stopped, the PLL, the HSI and the HSE RC
oscillators are disabled. SRAM and register contents are preserved.
In Stop mode, all I/O pins keep the same state as in Run mode.
(+) Entry:
The Stop mode is entered using the HAL_PWR_EnterSTOPMode(PWR_REGULATOR_VALUE, PWR_SLEEPENTRY_WFx )
function with:
(++) PWR_REGULATOR_VALUE= PWR_MAINREGULATOR_ON: Main regulator ON.
(++) PWR_REGULATOR_VALUE= PWR_LOWPOWERREGULATOR_ON: Low Power regulator ON.
(++) PWR_SLEEPENTRY_WFx= PWR_SLEEPENTRY_WFI: enter STOP mode with WFI instruction
(++) PWR_SLEEPENTRY_WFx= PWR_SLEEPENTRY_WFE: enter STOP mode with WFE instruction
(+) Exit:
(++) WFI entry mode, Any EXTI Line (Internal or External) configured in Interrupt mode with NVIC configured
(++) WFE entry mode, Any EXTI Line (Internal or External) configured in Event mode.
*** Standby mode ***
====================
[..]
The Standby mode allows to achieve the lowest power consumption. It is based on the
Cortex-M3 deepsleep mode, with the voltage regulator disabled. The 1.8 V domain is
consequently powered off. The PLL, the HSI oscillator and the HSE oscillator are also
switched off. SRAM and register contents are lost except for registers in the Backup domain
and Standby circuitry
(+) Entry:
(++) The Standby mode is entered using the HAL_PWR_EnterSTANDBYMode() function.
(+) Exit:
(++) WKUP pin rising edge, RTC alarm event rising edge, external Reset in
NRSTpin, IWDG Reset
*** Auto-wakeup (AWU) from low-power mode ***
=============================================
[..]
(+) The MCU can be woken up from low-power mode by an RTC Alarm event,
without depending on an external interrupt (Auto-wakeup mode).
(+) RTC auto-wakeup (AWU) from the Stop and Standby modes
(++) To wake up from the Stop mode with an RTC alarm event, it is necessary to
configure the RTC to generate the RTC alarm using the HAL_RTC_SetAlarm_IT() function.
*** PWR Workarounds linked to Silicon Limitation ***
====================================================
[..]
Below the list of all silicon limitations known on STM32F1xx prouct.
(#)Workarounds Implemented inside PWR HAL Driver
(##)Debugging Stop mode with WFE entry - overloaded the WFE by an internal function
@endverbatim
* @{
*/
/**
* @brief Configures the voltage threshold detected by the Power Voltage Detector(PVD).
* @param sConfigPVD: pointer to an PWR_PVDTypeDef structure that contains the configuration
* information for the PVD.
* @note Refer to the electrical characteristics of your device datasheet for
* more details about the voltage threshold corresponding to each
* detection level.
* @retval None
*/
void HAL_PWR_ConfigPVD(PWR_PVDTypeDef *sConfigPVD)
{
/* Check the parameters */
assert_param(IS_PWR_PVD_LEVEL(sConfigPVD->PVDLevel));
assert_param(IS_PWR_PVD_MODE(sConfigPVD->Mode));
/* Set PLS[7:5] bits according to PVDLevel value */
MODIFY_REG(PWR->CR, PWR_CR_PLS, sConfigPVD->PVDLevel);
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVD_EXTI_DISABLE_EVENT();
__HAL_PWR_PVD_EXTI_DISABLE_IT();
__HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVD->Mode & PVD_MODE_IT) == PVD_MODE_IT)
{
__HAL_PWR_PVD_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVD->Mode & PVD_MODE_EVT) == PVD_MODE_EVT)
{
__HAL_PWR_PVD_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVD->Mode & PVD_RISING_EDGE) == PVD_RISING_EDGE)
{
__HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVD->Mode & PVD_FALLING_EDGE) == PVD_FALLING_EDGE)
{
__HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE();
}
}
/**
* @brief Enables the Power Voltage Detector(PVD).
* @retval None
*/
void HAL_PWR_EnablePVD(void)
{
/* Enable the power voltage detector */
*(__IO uint32_t *) CR_PVDE_BB = (uint32_t)ENABLE;
}
/**
* @brief Disables the Power Voltage Detector(PVD).
* @retval None
*/
void HAL_PWR_DisablePVD(void)
{
/* Disable the power voltage detector */
*(__IO uint32_t *) CR_PVDE_BB = (uint32_t)DISABLE;
}
/**
* @brief Enables the WakeUp PINx functionality.
* @param WakeUpPinx: Specifies the Power Wake-Up pin to enable.
* This parameter can be one of the following values:
* @arg PWR_WAKEUP_PIN1
* @retval None
*/
void HAL_PWR_EnableWakeUpPin(uint32_t WakeUpPinx)
{
/* Check the parameter */
assert_param(IS_PWR_WAKEUP_PIN(WakeUpPinx));
/* Enable the EWUPx pin */
*(__IO uint32_t *) CSR_EWUP_BB(WakeUpPinx) = (uint32_t)ENABLE;
}
/**
* @brief Disables the WakeUp PINx functionality.
* @param WakeUpPinx: Specifies the Power Wake-Up pin to disable.
* This parameter can be one of the following values:
* @arg PWR_WAKEUP_PIN1
* @retval None
*/
void HAL_PWR_DisableWakeUpPin(uint32_t WakeUpPinx)
{
/* Check the parameter */
assert_param(IS_PWR_WAKEUP_PIN(WakeUpPinx));
/* Disable the EWUPx pin */
*(__IO uint32_t *) CSR_EWUP_BB(WakeUpPinx) = (uint32_t)DISABLE;
}
/**
* @brief Enters Sleep mode.
* @note In Sleep mode, all I/O pins keep the same state as in Run mode.
* @param Regulator: Regulator state as no effect in SLEEP mode - allows to support portability from legacy software
* @param SLEEPEntry: Specifies if SLEEP mode is entered with WFI or WFE instruction.
* When WFI entry is used, tick interrupt have to be disabled if not desired as
* the interrupt wake up source.
* This parameter can be one of the following values:
* @arg PWR_SLEEPENTRY_WFI: enter SLEEP mode with WFI instruction
* @arg PWR_SLEEPENTRY_WFE: enter SLEEP mode with WFE instruction
* @retval None
*/
void HAL_PWR_EnterSLEEPMode(uint32_t Regulator, uint8_t SLEEPEntry)
{
/* Check the parameters */
/* No check on Regulator because parameter not used in SLEEP mode */
/* Prevent unused argument(s) compilation warning */
UNUSED(Regulator);
assert_param(IS_PWR_SLEEP_ENTRY(SLEEPEntry));
/* Clear SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* Select SLEEP mode entry -------------------------------------------------*/
if(SLEEPEntry == PWR_SLEEPENTRY_WFI)
{
/* Request Wait For Interrupt */
__WFI();
}
else
{
/* Request Wait For Event */
__SEV();
__WFE();
__WFE();
}
}
/**
* @brief Enters Stop mode.
* @note In Stop mode, all I/O pins keep the same state as in Run mode.
* @note When exiting Stop mode by using an interrupt or a wakeup event,
* HSI RC oscillator is selected as system clock.
* @note When the voltage regulator operates in low power mode, an additional
* startup delay is incurred when waking up from Stop mode.
* By keeping the internal regulator ON during Stop mode, the consumption
* is higher although the startup time is reduced.
* @param Regulator: Specifies the regulator state in Stop mode.
* This parameter can be one of the following values:
* @arg PWR_MAINREGULATOR_ON: Stop mode with regulator ON
* @arg PWR_LOWPOWERREGULATOR_ON: Stop mode with low power regulator ON
* @param STOPEntry: Specifies if Stop mode in entered with WFI or WFE instruction.
* This parameter can be one of the following values:
* @arg PWR_STOPENTRY_WFI: Enter Stop mode with WFI instruction
* @arg PWR_STOPENTRY_WFE: Enter Stop mode with WFE instruction
* @retval None
*/
void HAL_PWR_EnterSTOPMode(uint32_t Regulator, uint8_t STOPEntry)
{
/* Check the parameters */
assert_param(IS_PWR_REGULATOR(Regulator));
assert_param(IS_PWR_STOP_ENTRY(STOPEntry));
/* Clear PDDS bit in PWR register to specify entering in STOP mode when CPU enter in Deepsleep */
CLEAR_BIT(PWR->CR, PWR_CR_PDDS);
/* Select the voltage regulator mode by setting LPDS bit in PWR register according to Regulator parameter value */
MODIFY_REG(PWR->CR, PWR_CR_LPDS, Regulator);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* Select Stop mode entry --------------------------------------------------*/
if(STOPEntry == PWR_STOPENTRY_WFI)
{
/* Request Wait For Interrupt */
__WFI();
}
else
{
/* Request Wait For Event */
__SEV();
PWR_OverloadWfe(); /* WFE redefine locally */
PWR_OverloadWfe(); /* WFE redefine locally */
}
/* Reset SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
}
/**
* @brief Enters Standby mode.
* @note In Standby mode, all I/O pins are high impedance except for:
* - Reset pad (still available)
* - TAMPER pin if configured for tamper or calibration out.
* - WKUP pin (PA0) if enabled.
* @retval None
*/
void HAL_PWR_EnterSTANDBYMode(void)
{
/* Select Standby mode */
SET_BIT(PWR->CR, PWR_CR_PDDS);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* This option is used to ensure that store operations are completed */
#if defined ( __CC_ARM)
__force_stores();
#endif
/* Request Wait For Interrupt */
__WFI();
}
/**
* @brief Indicates Sleep-On-Exit when returning from Handler mode to Thread mode.
* @note Set SLEEPONEXIT bit of SCR register. When this bit is set, the processor
* re-enters SLEEP mode when an interruption handling is over.
* Setting this bit is useful when the processor is expected to run only on
* interruptions handling.
* @retval None
*/
void HAL_PWR_EnableSleepOnExit(void)
{
/* Set SLEEPONEXIT bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Disables Sleep-On-Exit feature when returning from Handler mode to Thread mode.
* @note Clears SLEEPONEXIT bit of SCR register. When this bit is set, the processor
* re-enters SLEEP mode when an interruption handling is over.
* @retval None
*/
void HAL_PWR_DisableSleepOnExit(void)
{
/* Clear SLEEPONEXIT bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Enables CORTEX M3 SEVONPEND bit.
* @note Sets SEVONPEND bit of SCR register. When this bit is set, this causes
* WFE to wake up when an interrupt moves from inactive to pended.
* @retval None
*/
void HAL_PWR_EnableSEVOnPend(void)
{
/* Set SEVONPEND bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @brief Disables CORTEX M3 SEVONPEND bit.
* @note Clears SEVONPEND bit of SCR register. When this bit is set, this causes
* WFE to wake up when an interrupt moves from inactive to pended.
* @retval None
*/
void HAL_PWR_DisableSEVOnPend(void)
{
/* Clear SEVONPEND bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @brief This function handles the PWR PVD interrupt request.
* @note This API should be called under the PVD_IRQHandler().
* @retval None
*/
void HAL_PWR_PVD_IRQHandler(void)
{
/* Check PWR exti flag */
if(__HAL_PWR_PVD_EXTI_GET_FLAG() != RESET)
{
/* PWR PVD interrupt user callback */
HAL_PWR_PVDCallback();
/* Clear PWR Exti pending bit */
__HAL_PWR_PVD_EXTI_CLEAR_FLAG();
}
}
/**
* @brief PWR PVD interrupt callback
* @retval None
*/
__weak void HAL_PWR_PVDCallback(void)
{
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_PWR_PVDCallback could be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_PWR_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/

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/**
******************************************************************************
* @file stm32f1xx_hal_rcc_ex.c
* @author MCD Application Team
* @brief Extended RCC HAL module driver.
* This file provides firmware functions to manage the following
* functionalities RCC extension peripheral:
* + Extended Peripheral Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_hal.h"
/** @addtogroup STM32F1xx_HAL_Driver
* @{
*/
#ifdef HAL_RCC_MODULE_ENABLED
/** @defgroup RCCEx RCCEx
* @brief RCC Extension HAL module driver.
* @{
*/
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup RCCEx_Private_Constants RCCEx Private Constants
* @{
*/
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup RCCEx_Private_Macros RCCEx Private Macros
* @{
*/
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/** @defgroup RCCEx_Exported_Functions RCCEx Exported Functions
* @{
*/
/** @defgroup RCCEx_Exported_Functions_Group1 Peripheral Control functions
* @brief Extended Peripheral Control functions
*
@verbatim
===============================================================================
##### Extended Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the RCC Clocks
frequencies.
[..]
(@) Important note: Care must be taken when HAL_RCCEx_PeriphCLKConfig() is used to
select the RTC clock source; in this case the Backup domain will be reset in
order to modify the RTC Clock source, as consequence RTC registers (including
the backup registers) are set to their reset values.
@endverbatim
* @{
*/
/**
* @brief Initializes the RCC extended peripherals clocks according to the specified parameters in the
* RCC_PeriphCLKInitTypeDef.
* @param PeriphClkInit pointer to an RCC_PeriphCLKInitTypeDef structure that
* contains the configuration information for the Extended Peripherals clocks(RTC clock).
*
* @note Care must be taken when HAL_RCCEx_PeriphCLKConfig() is used to select
* the RTC clock source; in this case the Backup domain will be reset in
* order to modify the RTC Clock source, as consequence RTC registers (including
* the backup registers) are set to their reset values.
*
* @note In case of STM32F105xC or STM32F107xC devices, PLLI2S will be enabled if requested on
* one of 2 I2S interfaces. When PLLI2S is enabled, you need to call HAL_RCCEx_DisablePLLI2S to
* manually disable it.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_PeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit)
{
uint32_t tickstart = 0U, temp_reg = 0U;
#if defined(STM32F105xC) || defined(STM32F107xC)
uint32_t pllactive = 0U;
#endif /* STM32F105xC || STM32F107xC */
/* Check the parameters */
assert_param(IS_RCC_PERIPHCLOCK(PeriphClkInit->PeriphClockSelection));
/*------------------------------- RTC/LCD Configuration ------------------------*/
if ((((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
{
FlagStatus pwrclkchanged = RESET;
/* check for RTC Parameters used to output RTCCLK */
assert_param(IS_RCC_RTCCLKSOURCE(PeriphClkInit->RTCClockSelection));
/* As soon as function is called to change RTC clock source, activation of the
power domain is done. */
/* Requires to enable write access to Backup Domain of necessary */
if (__HAL_RCC_PWR_IS_CLK_DISABLED())
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if (HAL_IS_BIT_CLR(PWR->CR, PWR_CR_DBP))
{
/* Enable write access to Backup domain */
SET_BIT(PWR->CR, PWR_CR_DBP);
/* Wait for Backup domain Write protection disable */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_CLR(PWR->CR, PWR_CR_DBP))
{
if ((HAL_GetTick() - tickstart) > RCC_DBP_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/* Reset the Backup domain only if the RTC Clock source selection is modified from reset value */
temp_reg = (RCC->BDCR & RCC_BDCR_RTCSEL);
if ((temp_reg != 0x00000000U) && (temp_reg != (PeriphClkInit->RTCClockSelection & RCC_BDCR_RTCSEL)))
{
/* Store the content of BDCR register before the reset of Backup Domain */
temp_reg = (RCC->BDCR & ~(RCC_BDCR_RTCSEL));
/* RTC Clock selection can be changed only if the Backup Domain is reset */
__HAL_RCC_BACKUPRESET_FORCE();
__HAL_RCC_BACKUPRESET_RELEASE();
/* Restore the Content of BDCR register */
RCC->BDCR = temp_reg;
/* Wait for LSERDY if LSE was enabled */
if (HAL_IS_BIT_SET(temp_reg, RCC_BDCR_LSEON))
{
/* Get Start Tick */
tickstart = HAL_GetTick();
/* Wait till LSE is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_LSERDY) == RESET)
{
if ((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
__HAL_RCC_RTC_CONFIG(PeriphClkInit->RTCClockSelection);
/* Require to disable power clock if necessary */
if (pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/*------------------------------ ADC clock Configuration ------------------*/
if (((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_ADC) == RCC_PERIPHCLK_ADC)
{
/* Check the parameters */
assert_param(IS_RCC_ADCPLLCLK_DIV(PeriphClkInit->AdcClockSelection));
/* Configure the ADC clock source */
__HAL_RCC_ADC_CONFIG(PeriphClkInit->AdcClockSelection);
}
#if defined(STM32F105xC) || defined(STM32F107xC)
/*------------------------------ I2S2 Configuration ------------------------*/
if (((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2S2) == RCC_PERIPHCLK_I2S2)
{
/* Check the parameters */
assert_param(IS_RCC_I2S2CLKSOURCE(PeriphClkInit->I2s2ClockSelection));
/* Configure the I2S2 clock source */
__HAL_RCC_I2S2_CONFIG(PeriphClkInit->I2s2ClockSelection);
}
/*------------------------------ I2S3 Configuration ------------------------*/
if (((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2S3) == RCC_PERIPHCLK_I2S3)
{
/* Check the parameters */
assert_param(IS_RCC_I2S3CLKSOURCE(PeriphClkInit->I2s3ClockSelection));
/* Configure the I2S3 clock source */
__HAL_RCC_I2S3_CONFIG(PeriphClkInit->I2s3ClockSelection);
}
/*------------------------------ PLL I2S Configuration ----------------------*/
/* Check that PLLI2S need to be enabled */
if (HAL_IS_BIT_SET(RCC->CFGR2, RCC_CFGR2_I2S2SRC) || HAL_IS_BIT_SET(RCC->CFGR2, RCC_CFGR2_I2S3SRC))
{
/* Update flag to indicate that PLL I2S should be active */
pllactive = 1;
}
/* Check if PLL I2S need to be enabled */
if (pllactive == 1)
{
/* Enable PLL I2S only if not active */
if (HAL_IS_BIT_CLR(RCC->CR, RCC_CR_PLL3ON))
{
/* Check the parameters */
assert_param(IS_RCC_PLLI2S_MUL(PeriphClkInit->PLLI2S.PLLI2SMUL));
assert_param(IS_RCC_HSE_PREDIV2(PeriphClkInit->PLLI2S.HSEPrediv2Value));
/* Prediv2 can be written only when the PLL2 is disabled. */
/* Return an error only if new value is different from the programmed value */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLL2ON) && \
(__HAL_RCC_HSE_GET_PREDIV2() != PeriphClkInit->PLLI2S.HSEPrediv2Value))
{
return HAL_ERROR;
}
/* Configure the HSE prediv2 factor --------------------------------*/
__HAL_RCC_HSE_PREDIV2_CONFIG(PeriphClkInit->PLLI2S.HSEPrediv2Value);
/* Configure the main PLLI2S multiplication factors. */
__HAL_RCC_PLLI2S_CONFIG(PeriphClkInit->PLLI2S.PLLI2SMUL);
/* Enable the main PLLI2S. */
__HAL_RCC_PLLI2S_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLLI2S is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLLI2SRDY) == RESET)
{
if ((HAL_GetTick() - tickstart) > PLLI2S_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Return an error only if user wants to change the PLLI2SMUL whereas PLLI2S is active */
if (READ_BIT(RCC->CFGR2, RCC_CFGR2_PLL3MUL) != PeriphClkInit->PLLI2S.PLLI2SMUL)
{
return HAL_ERROR;
}
}
}
#endif /* STM32F105xC || STM32F107xC */
#if defined(STM32F102x6) || defined(STM32F102xB) || defined(STM32F103x6)\
|| defined(STM32F103xB) || defined(STM32F103xE) || defined(STM32F103xG)\
|| defined(STM32F105xC) || defined(STM32F107xC)
/*------------------------------ USB clock Configuration ------------------*/
if (((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB)
{
/* Check the parameters */
assert_param(IS_RCC_USBPLLCLK_DIV(PeriphClkInit->UsbClockSelection));
/* Configure the USB clock source */
__HAL_RCC_USB_CONFIG(PeriphClkInit->UsbClockSelection);
}
#endif /* STM32F102x6 || STM32F102xB || STM32F103x6 || STM32F103xB || STM32F103xE || STM32F103xG || STM32F105xC || STM32F107xC */
return HAL_OK;
}
/**
* @brief Get the PeriphClkInit according to the internal
* RCC configuration registers.
* @param PeriphClkInit pointer to an RCC_PeriphCLKInitTypeDef structure that
* returns the configuration information for the Extended Peripherals clocks(RTC, I2S, ADC clocks).
* @retval None
*/
void HAL_RCCEx_GetPeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit)
{
uint32_t srcclk = 0U;
/* Set all possible values for the extended clock type parameter------------*/
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_RTC;
/* Get the RTC configuration -----------------------------------------------*/
srcclk = __HAL_RCC_GET_RTC_SOURCE();
/* Source clock is LSE or LSI*/
PeriphClkInit->RTCClockSelection = srcclk;
/* Get the ADC clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_ADC;
PeriphClkInit->AdcClockSelection = __HAL_RCC_GET_ADC_SOURCE();
#if defined(STM32F105xC) || defined(STM32F107xC)
/* Get the I2S2 clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_I2S2;
PeriphClkInit->I2s2ClockSelection = __HAL_RCC_GET_I2S2_SOURCE();
/* Get the I2S3 clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_I2S3;
PeriphClkInit->I2s3ClockSelection = __HAL_RCC_GET_I2S3_SOURCE();
#endif /* STM32F105xC || STM32F107xC */
#if defined(STM32F103xE) || defined(STM32F103xG)
/* Get the I2S2 clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_I2S2;
PeriphClkInit->I2s2ClockSelection = RCC_I2S2CLKSOURCE_SYSCLK;
/* Get the I2S3 clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_I2S3;
PeriphClkInit->I2s3ClockSelection = RCC_I2S3CLKSOURCE_SYSCLK;
#endif /* STM32F103xE || STM32F103xG */
#if defined(STM32F102x6) || defined(STM32F102xB) || defined(STM32F103x6)\
|| defined(STM32F103xB) || defined(STM32F103xE) || defined(STM32F103xG)\
|| defined(STM32F105xC) || defined(STM32F107xC)
/* Get the USB clock configuration -----------------------------------------*/
PeriphClkInit->PeriphClockSelection |= RCC_PERIPHCLK_USB;
PeriphClkInit->UsbClockSelection = __HAL_RCC_GET_USB_SOURCE();
#endif /* STM32F102x6 || STM32F102xB || STM32F103x6 || STM32F103xB || STM32F103xE || STM32F103xG || STM32F105xC || STM32F107xC */
}
/**
* @brief Returns the peripheral clock frequency
* @note Returns 0 if peripheral clock is unknown
* @param PeriphClk Peripheral clock identifier
* This parameter can be one of the following values:
* @arg @ref RCC_PERIPHCLK_RTC RTC peripheral clock
* @arg @ref RCC_PERIPHCLK_ADC ADC peripheral clock
@if STM32F103xE
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
@endif
@if STM32F103xG
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
@endif
@if STM32F105xC
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock
@endif
@if STM32F107xC
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S3 I2S3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S2 I2S2 peripheral clock
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock
@endif
@if STM32F102xx
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock
@endif
@if STM32F103xx
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock
@endif
* @retval Frequency in Hz (0: means that no available frequency for the peripheral)
*/
uint32_t HAL_RCCEx_GetPeriphCLKFreq(uint32_t PeriphClk)
{
#if defined(STM32F105xC) || defined(STM32F107xC)
static const uint8_t aPLLMULFactorTable[14U] = {0, 0, 4, 5, 6, 7, 8, 9, 0, 0, 0, 0, 0, 13};
static const uint8_t aPredivFactorTable[16U] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16};
uint32_t prediv1 = 0U, pllclk = 0U, pllmul = 0U;
uint32_t pll2mul = 0U, pll3mul = 0U, prediv2 = 0U;
#endif /* STM32F105xC || STM32F107xC */
#if defined(STM32F102x6) || defined(STM32F102xB) || defined(STM32F103x6) || \
defined(STM32F103xB) || defined(STM32F103xE) || defined(STM32F103xG)
static const uint8_t aPLLMULFactorTable[16U] = {2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 16};
static const uint8_t aPredivFactorTable[2U] = {1, 2};
uint32_t prediv1 = 0U, pllclk = 0U, pllmul = 0U;
#endif /* STM32F102x6 || STM32F102xB || STM32F103x6 || STM32F103xB || STM32F103xE || STM32F103xG */
uint32_t temp_reg = 0U, frequency = 0U;
/* Check the parameters */
assert_param(IS_RCC_PERIPHCLOCK(PeriphClk));
switch (PeriphClk)
{
#if defined(STM32F102x6) || defined(STM32F102xB) || defined(STM32F103x6)\
|| defined(STM32F103xB) || defined(STM32F103xE) || defined(STM32F103xG)\
|| defined(STM32F105xC) || defined(STM32F107xC)
case RCC_PERIPHCLK_USB:
{
/* Get RCC configuration ------------------------------------------------------*/
temp_reg = RCC->CFGR;
/* Check if PLL is enabled */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLLON))
{
pllmul = aPLLMULFactorTable[(uint32_t)(temp_reg & RCC_CFGR_PLLMULL) >> RCC_CFGR_PLLMULL_Pos];
if ((temp_reg & RCC_CFGR_PLLSRC) != RCC_PLLSOURCE_HSI_DIV2)
{
#if defined(STM32F105xC) || defined(STM32F107xC) || defined(STM32F100xB)\
|| defined(STM32F100xE)
prediv1 = aPredivFactorTable[(uint32_t)(RCC->CFGR2 & RCC_CFGR2_PREDIV1) >> RCC_CFGR2_PREDIV1_Pos];
#else
prediv1 = aPredivFactorTable[(uint32_t)(RCC->CFGR & RCC_CFGR_PLLXTPRE) >> RCC_CFGR_PLLXTPRE_Pos];
#endif /* STM32F105xC || STM32F107xC || STM32F100xB || STM32F100xE */
#if defined(STM32F105xC) || defined(STM32F107xC)
if (HAL_IS_BIT_SET(RCC->CFGR2, RCC_CFGR2_PREDIV1SRC))
{
/* PLL2 selected as Prediv1 source */
/* PLLCLK = PLL2CLK / PREDIV1 * PLLMUL with PLL2CLK = HSE/PREDIV2 * PLL2MUL */
prediv2 = ((RCC->CFGR2 & RCC_CFGR2_PREDIV2) >> RCC_CFGR2_PREDIV2_Pos) + 1;
pll2mul = ((RCC->CFGR2 & RCC_CFGR2_PLL2MUL) >> RCC_CFGR2_PLL2MUL_Pos) + 2;
pllclk = (uint32_t)((((HSE_VALUE / prediv2) * pll2mul) / prediv1) * pllmul);
}
else
{
/* HSE used as PLL clock source : PLLCLK = HSE/PREDIV1 * PLLMUL */
pllclk = (uint32_t)((HSE_VALUE / prediv1) * pllmul);
}
/* If PLLMUL was set to 13 means that it was to cover the case PLLMUL 6.5 (avoid using float) */
/* In this case need to divide pllclk by 2 */
if (pllmul == aPLLMULFactorTable[(uint32_t)(RCC_CFGR_PLLMULL6_5) >> RCC_CFGR_PLLMULL_Pos])
{
pllclk = pllclk / 2;
}
#else
if ((temp_reg & RCC_CFGR_PLLSRC) != RCC_PLLSOURCE_HSI_DIV2)
{
/* HSE used as PLL clock source : PLLCLK = HSE/PREDIV1 * PLLMUL */
pllclk = (uint32_t)((HSE_VALUE / prediv1) * pllmul);
}
#endif /* STM32F105xC || STM32F107xC */
}
else
{
/* HSI used as PLL clock source : PLLCLK = HSI/2 * PLLMUL */
pllclk = (uint32_t)((HSI_VALUE >> 1) * pllmul);
}
/* Calcul of the USB frequency*/
#if defined(STM32F105xC) || defined(STM32F107xC)
/* USBCLK = PLLVCO = (2 x PLLCLK) / USB prescaler */
if (__HAL_RCC_GET_USB_SOURCE() == RCC_USBCLKSOURCE_PLL_DIV2)
{
/* Prescaler of 2 selected for USB */
frequency = pllclk;
}
else
{
/* Prescaler of 3 selected for USB */
frequency = (2 * pllclk) / 3;
}
#else
/* USBCLK = PLLCLK / USB prescaler */
if (__HAL_RCC_GET_USB_SOURCE() == RCC_USBCLKSOURCE_PLL)
{
/* No prescaler selected for USB */
frequency = pllclk;
}
else
{
/* Prescaler of 1.5 selected for USB */
frequency = (pllclk * 2) / 3;
}
#endif
}
break;
}
#endif /* STM32F102x6 || STM32F102xB || STM32F103x6 || STM32F103xB || STM32F103xE || STM32F103xG || STM32F105xC || STM32F107xC */
#if defined(STM32F103xE) || defined(STM32F103xG) || defined(STM32F105xC) || defined(STM32F107xC)
case RCC_PERIPHCLK_I2S2:
{
#if defined(STM32F103xE) || defined(STM32F103xG)
/* SYSCLK used as source clock for I2S2 */
frequency = HAL_RCC_GetSysClockFreq();
#else
if (__HAL_RCC_GET_I2S2_SOURCE() == RCC_I2S2CLKSOURCE_SYSCLK)
{
/* SYSCLK used as source clock for I2S2 */
frequency = HAL_RCC_GetSysClockFreq();
}
else
{
/* Check if PLLI2S is enabled */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLL3ON))
{
/* PLLI2SVCO = 2 * PLLI2SCLK = 2 * (HSE/PREDIV2 * PLL3MUL) */
prediv2 = ((RCC->CFGR2 & RCC_CFGR2_PREDIV2) >> RCC_CFGR2_PREDIV2_Pos) + 1;
pll3mul = ((RCC->CFGR2 & RCC_CFGR2_PLL3MUL) >> RCC_CFGR2_PLL3MUL_Pos) + 2;
frequency = (uint32_t)(2 * ((HSE_VALUE / prediv2) * pll3mul));
}
}
#endif /* STM32F103xE || STM32F103xG */
break;
}
case RCC_PERIPHCLK_I2S3:
{
#if defined(STM32F103xE) || defined(STM32F103xG)
/* SYSCLK used as source clock for I2S3 */
frequency = HAL_RCC_GetSysClockFreq();
#else
if (__HAL_RCC_GET_I2S3_SOURCE() == RCC_I2S3CLKSOURCE_SYSCLK)
{
/* SYSCLK used as source clock for I2S3 */
frequency = HAL_RCC_GetSysClockFreq();
}
else
{
/* Check if PLLI2S is enabled */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLL3ON))
{
/* PLLI2SVCO = 2 * PLLI2SCLK = 2 * (HSE/PREDIV2 * PLL3MUL) */
prediv2 = ((RCC->CFGR2 & RCC_CFGR2_PREDIV2) >> RCC_CFGR2_PREDIV2_Pos) + 1;
pll3mul = ((RCC->CFGR2 & RCC_CFGR2_PLL3MUL) >> RCC_CFGR2_PLL3MUL_Pos) + 2;
frequency = (uint32_t)(2 * ((HSE_VALUE / prediv2) * pll3mul));
}
}
#endif /* STM32F103xE || STM32F103xG */
break;
}
#endif /* STM32F103xE || STM32F103xG || STM32F105xC || STM32F107xC */
case RCC_PERIPHCLK_RTC:
{
/* Get RCC BDCR configuration ------------------------------------------------------*/
temp_reg = RCC->BDCR;
/* Check if LSE is ready if RTC clock selection is LSE */
if (((temp_reg & RCC_BDCR_RTCSEL) == RCC_RTCCLKSOURCE_LSE) && (HAL_IS_BIT_SET(temp_reg, RCC_BDCR_LSERDY)))
{
frequency = LSE_VALUE;
}
/* Check if LSI is ready if RTC clock selection is LSI */
else if (((temp_reg & RCC_BDCR_RTCSEL) == RCC_RTCCLKSOURCE_LSI) && (HAL_IS_BIT_SET(RCC->CSR, RCC_CSR_LSIRDY)))
{
frequency = LSI_VALUE;
}
else if (((temp_reg & RCC_BDCR_RTCSEL) == RCC_RTCCLKSOURCE_HSE_DIV128) && (HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSERDY)))
{
frequency = HSE_VALUE / 128U;
}
/* Clock not enabled for RTC*/
else
{
/* nothing to do: frequency already initialized to 0U */
}
break;
}
case RCC_PERIPHCLK_ADC:
{
frequency = HAL_RCC_GetPCLK2Freq() / (((__HAL_RCC_GET_ADC_SOURCE() >> RCC_CFGR_ADCPRE_Pos) + 1) * 2);
break;
}
default:
{
break;
}
}
return (frequency);
}
/**
* @}
*/
#if defined(STM32F105xC) || defined(STM32F107xC)
/** @defgroup RCCEx_Exported_Functions_Group2 PLLI2S Management function
* @brief PLLI2S Management functions
*
@verbatim
===============================================================================
##### Extended PLLI2S Management functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the PLLI2S
activation or deactivation
@endverbatim
* @{
*/
/**
* @brief Enable PLLI2S
* @param PLLI2SInit pointer to an RCC_PLLI2SInitTypeDef structure that
* contains the configuration information for the PLLI2S
* @note The PLLI2S configuration not modified if used by I2S2 or I2S3 Interface.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_EnablePLLI2S(RCC_PLLI2SInitTypeDef *PLLI2SInit)
{
uint32_t tickstart = 0U;
/* Check that PLL I2S has not been already enabled by I2S2 or I2S3*/
if (HAL_IS_BIT_CLR(RCC->CFGR2, RCC_CFGR2_I2S2SRC) && HAL_IS_BIT_CLR(RCC->CFGR2, RCC_CFGR2_I2S3SRC))
{
/* Check the parameters */
assert_param(IS_RCC_PLLI2S_MUL(PLLI2SInit->PLLI2SMUL));
assert_param(IS_RCC_HSE_PREDIV2(PLLI2SInit->HSEPrediv2Value));
/* Prediv2 can be written only when the PLL2 is disabled. */
/* Return an error only if new value is different from the programmed value */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLL2ON) && \
(__HAL_RCC_HSE_GET_PREDIV2() != PLLI2SInit->HSEPrediv2Value))
{
return HAL_ERROR;
}
/* Disable the main PLLI2S. */
__HAL_RCC_PLLI2S_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLLI2S is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLLI2SRDY) != RESET)
{
if ((HAL_GetTick() - tickstart) > PLLI2S_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Configure the HSE prediv2 factor --------------------------------*/
__HAL_RCC_HSE_PREDIV2_CONFIG(PLLI2SInit->HSEPrediv2Value);
/* Configure the main PLLI2S multiplication factors. */
__HAL_RCC_PLLI2S_CONFIG(PLLI2SInit->PLLI2SMUL);
/* Enable the main PLLI2S. */
__HAL_RCC_PLLI2S_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLLI2S is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLLI2SRDY) == RESET)
{
if ((HAL_GetTick() - tickstart) > PLLI2S_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* PLLI2S cannot be modified as already used by I2S2 or I2S3 */
return HAL_ERROR;
}
return HAL_OK;
}
/**
* @brief Disable PLLI2S
* @note PLLI2S is not disabled if used by I2S2 or I2S3 Interface.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_DisablePLLI2S(void)
{
uint32_t tickstart = 0U;
/* Disable PLL I2S as not requested by I2S2 or I2S3*/
if (HAL_IS_BIT_CLR(RCC->CFGR2, RCC_CFGR2_I2S2SRC) && HAL_IS_BIT_CLR(RCC->CFGR2, RCC_CFGR2_I2S3SRC))
{
/* Disable the main PLLI2S. */
__HAL_RCC_PLLI2S_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLLI2S is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLLI2SRDY) != RESET)
{
if ((HAL_GetTick() - tickstart) > PLLI2S_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* PLLI2S is currently used by I2S2 or I2S3. Cannot be disabled.*/
return HAL_ERROR;
}
return HAL_OK;
}
/**
* @}
*/
/** @defgroup RCCEx_Exported_Functions_Group3 PLL2 Management function
* @brief PLL2 Management functions
*
@verbatim
===============================================================================
##### Extended PLL2 Management functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the PLL2
activation or deactivation
@endverbatim
* @{
*/
/**
* @brief Enable PLL2
* @param PLL2Init pointer to an RCC_PLL2InitTypeDef structure that
* contains the configuration information for the PLL2
* @note The PLL2 configuration not modified if used indirectly as system clock.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_EnablePLL2(RCC_PLL2InitTypeDef *PLL2Init)
{
uint32_t tickstart = 0U;
/* This bit can not be cleared if the PLL2 clock is used indirectly as system
clock (i.e. it is used as PLL clock entry that is used as system clock). */
if ((__HAL_RCC_GET_PLL_OSCSOURCE() == RCC_PLLSOURCE_HSE) && \
(__HAL_RCC_GET_SYSCLK_SOURCE() == RCC_SYSCLKSOURCE_STATUS_PLLCLK) && \
((READ_BIT(RCC->CFGR2, RCC_CFGR2_PREDIV1SRC)) == RCC_CFGR2_PREDIV1SRC_PLL2))
{
return HAL_ERROR;
}
else
{
/* Check the parameters */
assert_param(IS_RCC_PLL2_MUL(PLL2Init->PLL2MUL));
assert_param(IS_RCC_HSE_PREDIV2(PLL2Init->HSEPrediv2Value));
/* Prediv2 can be written only when the PLLI2S is disabled. */
/* Return an error only if new value is different from the programmed value */
if (HAL_IS_BIT_SET(RCC->CR, RCC_CR_PLL3ON) && \
(__HAL_RCC_HSE_GET_PREDIV2() != PLL2Init->HSEPrediv2Value))
{
return HAL_ERROR;
}
/* Disable the main PLL2. */
__HAL_RCC_PLL2_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL2 is disabled */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLL2RDY) != RESET)
{
if ((HAL_GetTick() - tickstart) > PLL2_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Configure the HSE prediv2 factor --------------------------------*/
__HAL_RCC_HSE_PREDIV2_CONFIG(PLL2Init->HSEPrediv2Value);
/* Configure the main PLL2 multiplication factors. */
__HAL_RCC_PLL2_CONFIG(PLL2Init->PLL2MUL);
/* Enable the main PLL2. */
__HAL_RCC_PLL2_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL2 is ready */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLL2RDY) == RESET)
{
if ((HAL_GetTick() - tickstart) > PLL2_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
return HAL_OK;
}
/**
* @brief Disable PLL2
* @note PLL2 is not disabled if used indirectly as system clock.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_DisablePLL2(void)
{
uint32_t tickstart = 0U;
/* This bit can not be cleared if the PLL2 clock is used indirectly as system
clock (i.e. it is used as PLL clock entry that is used as system clock). */
if ((__HAL_RCC_GET_PLL_OSCSOURCE() == RCC_PLLSOURCE_HSE) && \
(__HAL_RCC_GET_SYSCLK_SOURCE() == RCC_SYSCLKSOURCE_STATUS_PLLCLK) && \
((READ_BIT(RCC->CFGR2, RCC_CFGR2_PREDIV1SRC)) == RCC_CFGR2_PREDIV1SRC_PLL2))
{
return HAL_ERROR;
}
else
{
/* Disable the main PLL2. */
__HAL_RCC_PLL2_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL2 is disabled */
while (__HAL_RCC_GET_FLAG(RCC_FLAG_PLL2RDY) != RESET)
{
if ((HAL_GetTick() - tickstart) > PLL2_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
return HAL_OK;
}
/**
* @}
*/
#endif /* STM32F105xC || STM32F107xC */
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_RCC_MODULE_ENABLED */
/**
* @}
*/

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Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_hal_tim.c Normal file
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Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_hal_tim_ex.c Normal file
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Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_ll_exti.c
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@ -1,213 +0,0 @@
/**
******************************************************************************
* @file stm32f1xx_ll_exti.c
* @author MCD Application Team
* @brief EXTI LL module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
#if defined(USE_FULL_LL_DRIVER)
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_exti.h"
#ifdef USE_FULL_ASSERT
#include "stm32_assert.h"
#else
#define assert_param(expr) ((void)0U)
#endif
/** @addtogroup STM32F1xx_LL_Driver
* @{
*/
#if defined (EXTI)
/** @defgroup EXTI_LL EXTI
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup EXTI_LL_Private_Macros
* @{
*/
#define IS_LL_EXTI_LINE_0_31(__VALUE__) (((__VALUE__) & ~LL_EXTI_LINE_ALL_0_31) == 0x00000000U)
#define IS_LL_EXTI_MODE(__VALUE__) (((__VALUE__) == LL_EXTI_MODE_IT) \
|| ((__VALUE__) == LL_EXTI_MODE_EVENT) \
|| ((__VALUE__) == LL_EXTI_MODE_IT_EVENT))
#define IS_LL_EXTI_TRIGGER(__VALUE__) (((__VALUE__) == LL_EXTI_TRIGGER_NONE) \
|| ((__VALUE__) == LL_EXTI_TRIGGER_RISING) \
|| ((__VALUE__) == LL_EXTI_TRIGGER_FALLING) \
|| ((__VALUE__) == LL_EXTI_TRIGGER_RISING_FALLING))
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup EXTI_LL_Exported_Functions
* @{
*/
/** @addtogroup EXTI_LL_EF_Init
* @{
*/
/**
* @brief De-initialize the EXTI registers to their default reset values.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: EXTI registers are de-initialized
* - ERROR: not applicable
*/
uint32_t LL_EXTI_DeInit(void)
{
/* Interrupt mask register set to default reset values */
LL_EXTI_WriteReg(IMR, 0x00000000U);
/* Event mask register set to default reset values */
LL_EXTI_WriteReg(EMR, 0x00000000U);
/* Rising Trigger selection register set to default reset values */
LL_EXTI_WriteReg(RTSR, 0x00000000U);
/* Falling Trigger selection register set to default reset values */
LL_EXTI_WriteReg(FTSR, 0x00000000U);
/* Software interrupt event register set to default reset values */
LL_EXTI_WriteReg(SWIER, 0x00000000U);
/* Pending register clear */
LL_EXTI_WriteReg(PR, 0x000FFFFFU);
return SUCCESS;
}
/**
* @brief Initialize the EXTI registers according to the specified parameters in EXTI_InitStruct.
* @param EXTI_InitStruct pointer to a @ref LL_EXTI_InitTypeDef structure.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: EXTI registers are initialized
* - ERROR: not applicable
*/
uint32_t LL_EXTI_Init(LL_EXTI_InitTypeDef *EXTI_InitStruct)
{
ErrorStatus status = SUCCESS;
/* Check the parameters */
assert_param(IS_LL_EXTI_LINE_0_31(EXTI_InitStruct->Line_0_31));
assert_param(IS_FUNCTIONAL_STATE(EXTI_InitStruct->LineCommand));
assert_param(IS_LL_EXTI_MODE(EXTI_InitStruct->Mode));
/* ENABLE LineCommand */
if (EXTI_InitStruct->LineCommand != DISABLE)
{
assert_param(IS_LL_EXTI_TRIGGER(EXTI_InitStruct->Trigger));
/* Configure EXTI Lines in range from 0 to 31 */
if (EXTI_InitStruct->Line_0_31 != LL_EXTI_LINE_NONE)
{
switch (EXTI_InitStruct->Mode)
{
case LL_EXTI_MODE_IT:
/* First Disable Event on provided Lines */
LL_EXTI_DisableEvent_0_31(EXTI_InitStruct->Line_0_31);
/* Then Enable IT on provided Lines */
LL_EXTI_EnableIT_0_31(EXTI_InitStruct->Line_0_31);
break;
case LL_EXTI_MODE_EVENT:
/* First Disable IT on provided Lines */
LL_EXTI_DisableIT_0_31(EXTI_InitStruct->Line_0_31);
/* Then Enable Event on provided Lines */
LL_EXTI_EnableEvent_0_31(EXTI_InitStruct->Line_0_31);
break;
case LL_EXTI_MODE_IT_EVENT:
/* Directly Enable IT & Event on provided Lines */
LL_EXTI_EnableIT_0_31(EXTI_InitStruct->Line_0_31);
LL_EXTI_EnableEvent_0_31(EXTI_InitStruct->Line_0_31);
break;
default:
status = ERROR;
break;
}
if (EXTI_InitStruct->Trigger != LL_EXTI_TRIGGER_NONE)
{
switch (EXTI_InitStruct->Trigger)
{
case LL_EXTI_TRIGGER_RISING:
/* First Disable Falling Trigger on provided Lines */
LL_EXTI_DisableFallingTrig_0_31(EXTI_InitStruct->Line_0_31);
/* Then Enable Rising Trigger on provided Lines */
LL_EXTI_EnableRisingTrig_0_31(EXTI_InitStruct->Line_0_31);
break;
case LL_EXTI_TRIGGER_FALLING:
/* First Disable Rising Trigger on provided Lines */
LL_EXTI_DisableRisingTrig_0_31(EXTI_InitStruct->Line_0_31);
/* Then Enable Falling Trigger on provided Lines */
LL_EXTI_EnableFallingTrig_0_31(EXTI_InitStruct->Line_0_31);
break;
case LL_EXTI_TRIGGER_RISING_FALLING:
LL_EXTI_EnableRisingTrig_0_31(EXTI_InitStruct->Line_0_31);
LL_EXTI_EnableFallingTrig_0_31(EXTI_InitStruct->Line_0_31);
break;
default:
status = ERROR;
break;
}
}
}
}
/* DISABLE LineCommand */
else
{
/* De-configure EXTI Lines in range from 0 to 31 */
LL_EXTI_DisableIT_0_31(EXTI_InitStruct->Line_0_31);
LL_EXTI_DisableEvent_0_31(EXTI_InitStruct->Line_0_31);
}
return status;
}
/**
* @brief Set each @ref LL_EXTI_InitTypeDef field to default value.
* @param EXTI_InitStruct Pointer to a @ref LL_EXTI_InitTypeDef structure.
* @retval None
*/
void LL_EXTI_StructInit(LL_EXTI_InitTypeDef *EXTI_InitStruct)
{
EXTI_InitStruct->Line_0_31 = LL_EXTI_LINE_NONE;
EXTI_InitStruct->LineCommand = DISABLE;
EXTI_InitStruct->Mode = LL_EXTI_MODE_IT;
EXTI_InitStruct->Trigger = LL_EXTI_TRIGGER_FALLING;
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined (EXTI) */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */

256
Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_ll_gpio.c
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@ -1,256 +0,0 @@
/**
******************************************************************************
* @file stm32f1xx_ll_gpio.c
* @author MCD Application Team
* @brief GPIO LL module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
#if defined(USE_FULL_LL_DRIVER)
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_gpio.h"
#include "stm32f1xx_ll_bus.h"
#ifdef USE_FULL_ASSERT
#include "stm32_assert.h"
#else
#define assert_param(expr) ((void)0U)
#endif
/** @addtogroup STM32F1xx_LL_Driver
* @{
*/
#if defined (GPIOA) || defined (GPIOB) || defined (GPIOC) || defined (GPIOD) || defined (GPIOE) || defined (GPIOF) || defined (GPIOG)
/** @addtogroup GPIO_LL
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup GPIO_LL_Private_Macros
* @{
*/
#define IS_LL_GPIO_PIN(__VALUE__) ((((__VALUE__) & LL_GPIO_PIN_ALL)!= 0u) &&\
(((__VALUE__) & (~LL_GPIO_PIN_ALL))== 0u))
#define IS_LL_GPIO_MODE(__VALUE__) (((__VALUE__) == LL_GPIO_MODE_ANALOG) ||\
((__VALUE__) == LL_GPIO_MODE_FLOATING) ||\
((__VALUE__) == LL_GPIO_MODE_INPUT) ||\
((__VALUE__) == LL_GPIO_MODE_OUTPUT) ||\
((__VALUE__) == LL_GPIO_MODE_ALTERNATE))
#define IS_LL_GPIO_SPEED(__VALUE__) (((__VALUE__) == LL_GPIO_SPEED_FREQ_LOW) ||\
((__VALUE__) == LL_GPIO_SPEED_FREQ_MEDIUM) ||\
((__VALUE__) == LL_GPIO_SPEED_FREQ_HIGH))
#define IS_LL_GPIO_OUTPUT_TYPE(__VALUE__) (((__VALUE__) == LL_GPIO_OUTPUT_PUSHPULL) ||\
((__VALUE__) == LL_GPIO_OUTPUT_OPENDRAIN))
#define IS_LL_GPIO_PULL(__VALUE__) (((__VALUE__) == LL_GPIO_PULL_DOWN) ||\
((__VALUE__) == LL_GPIO_PULL_UP))
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup GPIO_LL_Exported_Functions
* @{
*/
/** @addtogroup GPIO_LL_EF_Init
* @{
*/
/**
* @brief De-initialize GPIO registers (Registers restored to their default values).
* @param GPIOx GPIO Port
* @retval An ErrorStatus enumeration value:
* - SUCCESS: GPIO registers are de-initialized
* - ERROR: Wrong GPIO Port
*/
ErrorStatus LL_GPIO_DeInit(GPIO_TypeDef *GPIOx)
{
ErrorStatus status = SUCCESS;
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
/* Force and Release reset on clock of GPIOx Port */
if (GPIOx == GPIOA)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOA);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOA);
}
else if (GPIOx == GPIOB)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOB);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOB);
}
else if (GPIOx == GPIOC)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOC);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOC);
}
else if (GPIOx == GPIOD)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOD);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOD);
}
#if defined(GPIOE)
else if (GPIOx == GPIOE)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOE);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOE);
}
#endif
#if defined(GPIOF)
else if (GPIOx == GPIOF)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOF);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOF);
}
#endif
#if defined(GPIOG)
else if (GPIOx == GPIOG)
{
LL_APB2_GRP1_ForceReset(LL_APB2_GRP1_PERIPH_GPIOG);
LL_APB2_GRP1_ReleaseReset(LL_APB2_GRP1_PERIPH_GPIOG);
}
#endif
else
{
status = ERROR;
}
return (status);
}
/**
* @brief Initialize GPIO registers according to the specified parameters in GPIO_InitStruct.
* @param GPIOx GPIO Port
* @param GPIO_InitStruct: pointer to a @ref LL_GPIO_InitTypeDef structure
* that contains the configuration information for the specified GPIO peripheral.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: GPIO registers are initialized according to GPIO_InitStruct content
* - ERROR: Not applicable
*/
ErrorStatus LL_GPIO_Init(GPIO_TypeDef *GPIOx, LL_GPIO_InitTypeDef *GPIO_InitStruct)
{
uint32_t pinmask;
uint32_t pinpos;
uint32_t currentpin;
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
assert_param(IS_LL_GPIO_PIN(GPIO_InitStruct->Pin));
/* ------------------------- Configure the port pins ---------------- */
/* Initialize pinpos on first pin set */
pinmask = ((GPIO_InitStruct->Pin) << GPIO_PIN_MASK_POS) >> GPIO_PIN_NB;
pinpos = POSITION_VAL(pinmask);
/* Configure the port pins */
while ((pinmask >> pinpos) != 0u)
{
/* skip if bit is not set */
if ((pinmask & (1u << pinpos)) != 0u)
{
/* Get current io position */
if (pinpos < GPIO_PIN_MASK_POS)
{
currentpin = (0x00000101uL << pinpos);
}
else
{
currentpin = ((0x00010001u << (pinpos - GPIO_PIN_MASK_POS)) | 0x04000000u);
}
if (GPIO_InitStruct->Mode == LL_GPIO_MODE_INPUT)
{
/* Check The Pull parameter */
assert_param(IS_LL_GPIO_PULL(GPIO_InitStruct->Pull));
/* Pull-up Pull-down resistor configuration*/
LL_GPIO_SetPinPull(GPIOx, currentpin, GPIO_InitStruct->Pull);
}
/* Check Pin Mode parameters */
assert_param(IS_LL_GPIO_MODE(GPIO_InitStruct->Mode));
/* Pin Mode configuration */
LL_GPIO_SetPinMode(GPIOx, currentpin, GPIO_InitStruct->Mode);
if ((GPIO_InitStruct->Mode == LL_GPIO_MODE_OUTPUT) || (GPIO_InitStruct->Mode == LL_GPIO_MODE_ALTERNATE))
{
/* Check speed and Output mode parameters */
assert_param(IS_LL_GPIO_SPEED(GPIO_InitStruct->Speed));
assert_param(IS_LL_GPIO_OUTPUT_TYPE(GPIO_InitStruct->OutputType));
/* Speed mode configuration */
LL_GPIO_SetPinSpeed(GPIOx, currentpin, GPIO_InitStruct->Speed);
/* Output mode configuration*/
LL_GPIO_SetPinOutputType(GPIOx, currentpin, GPIO_InitStruct->OutputType);
}
}
pinpos++;
}
return (SUCCESS);
}
/**
* @brief Set each @ref LL_GPIO_InitTypeDef field to default value.
* @param GPIO_InitStruct: pointer to a @ref LL_GPIO_InitTypeDef structure
* whose fields will be set to default values.
* @retval None
*/
void LL_GPIO_StructInit(LL_GPIO_InitTypeDef *GPIO_InitStruct)
{
/* Reset GPIO init structure parameters values */
GPIO_InitStruct->Pin = LL_GPIO_PIN_ALL;
GPIO_InitStruct->Mode = LL_GPIO_MODE_FLOATING;
GPIO_InitStruct->Speed = LL_GPIO_SPEED_FREQ_LOW;
GPIO_InitStruct->OutputType = LL_GPIO_OUTPUT_OPENDRAIN;
GPIO_InitStruct->Pull = LL_GPIO_PULL_DOWN;
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined (GPIOA) || defined (GPIOB) || defined (GPIOC) || defined (GPIOD) || defined (GPIOE) || defined (GPIOF) || defined (GPIOG) */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */

83
Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_ll_pwr.c
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/**
******************************************************************************
* @file stm32f1xx_ll_pwr.c
* @author MCD Application Team
* @brief PWR LL module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
#if defined(USE_FULL_LL_DRIVER)
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_pwr.h"
#include "stm32f1xx_ll_bus.h"
/** @addtogroup STM32F1xx_LL_Driver
* @{
*/
#if defined(PWR)
/** @defgroup PWR_LL PWR
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup PWR_LL_Exported_Functions
* @{
*/
/** @addtogroup PWR_LL_EF_Init
* @{
*/
/**
* @brief De-initialize the PWR registers to their default reset values.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: PWR registers are de-initialized
* - ERROR: not applicable
*/
ErrorStatus LL_PWR_DeInit(void)
{
/* Force reset of PWR clock */
LL_APB1_GRP1_ForceReset(LL_APB1_GRP1_PERIPH_PWR);
/* Release reset of PWR clock */
LL_APB1_GRP1_ReleaseReset(LL_APB1_GRP1_PERIPH_PWR);
return SUCCESS;
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined(PWR) */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */

471
Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_ll_rcc.c
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/**
******************************************************************************
* @file stm32f1xx_ll_rcc.c
* @author MCD Application Team
* @brief RCC LL module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
#if defined(USE_FULL_LL_DRIVER)
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_rcc.h"
#ifdef USE_FULL_ASSERT
#include "stm32_assert.h"
#else
#define assert_param(expr) ((void)0U)
#endif /* USE_FULL_ASSERT */
/** @addtogroup STM32F1xx_LL_Driver
* @{
*/
#if defined(RCC)
/** @defgroup RCC_LL RCC
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup RCC_LL_Private_Macros
* @{
*/
#if defined(RCC_PLLI2S_SUPPORT)
#define IS_LL_RCC_I2S_CLKSOURCE(__VALUE__) (((__VALUE__) == LL_RCC_I2S2_CLKSOURCE) \
|| ((__VALUE__) == LL_RCC_I2S3_CLKSOURCE))
#endif /* RCC_PLLI2S_SUPPORT */
#if defined(USB) || defined(USB_OTG_FS)
#define IS_LL_RCC_USB_CLKSOURCE(__VALUE__) (((__VALUE__) == LL_RCC_USB_CLKSOURCE))
#endif /* USB */
#define IS_LL_RCC_ADC_CLKSOURCE(__VALUE__) (((__VALUE__) == LL_RCC_ADC_CLKSOURCE))
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup RCC_LL_Private_Functions RCC Private functions
* @{
*/
uint32_t RCC_GetSystemClockFreq(void);
uint32_t RCC_GetHCLKClockFreq(uint32_t SYSCLK_Frequency);
uint32_t RCC_GetPCLK1ClockFreq(uint32_t HCLK_Frequency);
uint32_t RCC_GetPCLK2ClockFreq(uint32_t HCLK_Frequency);
uint32_t RCC_PLL_GetFreqDomain_SYS(void);
#if defined(RCC_PLLI2S_SUPPORT)
uint32_t RCC_PLLI2S_GetFreqDomain_I2S(void);
#endif /* RCC_PLLI2S_SUPPORT */
#if defined(RCC_PLL2_SUPPORT)
uint32_t RCC_PLL2_GetFreqClockFreq(void);
#endif /* RCC_PLL2_SUPPORT */
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup RCC_LL_Exported_Functions
* @{
*/
/** @addtogroup RCC_LL_EF_Init
* @{
*/
/**
* @brief Reset the RCC clock configuration to the default reset state.
* @note The default reset state of the clock configuration is given below:
* - HSI ON and used as system clock source
* - HSE PLL, PLL2 & PLL3 are OFF
* - AHB, APB1 and APB2 prescaler set to 1.
* - CSS, MCO OFF
* - All interrupts disabled
* @note This function doesn't modify the configuration of the
* - Peripheral clocks
* - LSI, LSE and RTC clocks
* @retval An ErrorStatus enumeration value:
* - SUCCESS: RCC registers are de-initialized
* - ERROR: not applicable
*/
ErrorStatus LL_RCC_DeInit(void)
{
/* Set HSION bit */
LL_RCC_HSI_Enable();
/* Wait for HSI READY bit */
while (LL_RCC_HSI_IsReady() != 1U)
{}
/* Configure HSI as system clock source */
LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_HSI);
/* Wait till clock switch is ready */
while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_HSI)
{}
/* Reset PLLON bit */
CLEAR_BIT(RCC->CR, RCC_CR_PLLON);
/* Wait for PLL READY bit to be reset */
while (LL_RCC_PLL_IsReady() != 0U)
{}
/* Reset CFGR register */
LL_RCC_WriteReg(CFGR, 0x00000000U);
/* Reset HSEON, HSEBYP & CSSON bits */
CLEAR_BIT(RCC->CR, (RCC_CR_CSSON | RCC_CR_HSEON | RCC_CR_HSEBYP));
#if defined(RCC_CR_PLL2ON)
/* Reset PLL2ON bit */
CLEAR_BIT(RCC->CR, RCC_CR_PLL2ON);
#endif /* RCC_CR_PLL2ON */
#if defined(RCC_CR_PLL3ON)
/* Reset PLL3ON bit */
CLEAR_BIT(RCC->CR, RCC_CR_PLL3ON);
#endif /* RCC_CR_PLL3ON */
/* Set HSITRIM bits to the reset value */
LL_RCC_HSI_SetCalibTrimming(0x10U);
#if defined(RCC_CFGR2_PREDIV1)
/* Reset CFGR2 register */
LL_RCC_WriteReg(CFGR2, 0x00000000U);
#endif /* RCC_CFGR2_PREDIV1 */
/* Disable all interrupts */
LL_RCC_WriteReg(CIR, 0x00000000U);
/* Clear reset flags */
LL_RCC_ClearResetFlags();
return SUCCESS;
}
/**
* @}
*/
/** @addtogroup RCC_LL_EF_Get_Freq
* @brief Return the frequencies of different on chip clocks; System, AHB, APB1 and APB2 buses clocks
* and different peripheral clocks available on the device.
* @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
* HSI_VALUE(**) or HSE_VALUE(***) multiplied/divided by the PLL factors.
* @note (**) HSI_VALUE is a defined constant but the real value may vary
* depending on the variations in voltage and temperature.
* @note (***) HSE_VALUE is a defined constant, 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 incorrect when using fractional
* value for HSE crystal.
* @note This function can be used by the user application to compute the
* baud-rate for the communication peripherals or configure other parameters.
* @{
*/
/**
* @brief Return the frequencies of different on chip clocks; System, AHB, APB1 and APB2 buses clocks
* @note Each time SYSCLK, HCLK, PCLK1 and/or PCLK2 clock changes, this function
* must be called to update structure fields. Otherwise, any
* configuration based on this function will be incorrect.
* @param RCC_Clocks pointer to a @ref LL_RCC_ClocksTypeDef structure which will hold the clocks frequencies
* @retval None
*/
void LL_RCC_GetSystemClocksFreq(LL_RCC_ClocksTypeDef *RCC_Clocks)
{
/* Get SYSCLK frequency */
RCC_Clocks->SYSCLK_Frequency = RCC_GetSystemClockFreq();
/* HCLK clock frequency */
RCC_Clocks->HCLK_Frequency = RCC_GetHCLKClockFreq(RCC_Clocks->SYSCLK_Frequency);
/* PCLK1 clock frequency */
RCC_Clocks->PCLK1_Frequency = RCC_GetPCLK1ClockFreq(RCC_Clocks->HCLK_Frequency);
/* PCLK2 clock frequency */
RCC_Clocks->PCLK2_Frequency = RCC_GetPCLK2ClockFreq(RCC_Clocks->HCLK_Frequency);
}
#if defined(RCC_CFGR2_I2S2SRC)
/**
* @brief Return I2Sx clock frequency
* @param I2SxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_I2S2_CLKSOURCE
* @arg @ref LL_RCC_I2S3_CLKSOURCE
* @retval I2S clock frequency (in Hz)
*/
uint32_t LL_RCC_GetI2SClockFreq(uint32_t I2SxSource)
{
uint32_t i2s_frequency = LL_RCC_PERIPH_FREQUENCY_NO;
/* Check parameter */
assert_param(IS_LL_RCC_I2S_CLKSOURCE(I2SxSource));
/* I2S1CLK clock frequency */
switch (LL_RCC_GetI2SClockSource(I2SxSource))
{
case LL_RCC_I2S2_CLKSOURCE_SYSCLK: /*!< System clock selected as I2S clock source */
case LL_RCC_I2S3_CLKSOURCE_SYSCLK:
i2s_frequency = RCC_GetSystemClockFreq();
break;
case LL_RCC_I2S2_CLKSOURCE_PLLI2S_VCO: /*!< PLLI2S oscillator clock selected as I2S clock source */
case LL_RCC_I2S3_CLKSOURCE_PLLI2S_VCO:
default:
i2s_frequency = RCC_PLLI2S_GetFreqDomain_I2S() * 2U;
break;
}
return i2s_frequency;
}
#endif /* RCC_CFGR2_I2S2SRC */
#if defined(USB) || defined(USB_OTG_FS)
/**
* @brief Return USBx clock frequency
* @param USBxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_USB_CLKSOURCE
* @retval USB clock frequency (in Hz)
* @arg @ref LL_RCC_PERIPH_FREQUENCY_NO indicates that oscillator (HSI), HSE or PLL is not ready
*/
uint32_t LL_RCC_GetUSBClockFreq(uint32_t USBxSource)
{
uint32_t usb_frequency = LL_RCC_PERIPH_FREQUENCY_NO;
/* Check parameter */
assert_param(IS_LL_RCC_USB_CLKSOURCE(USBxSource));
/* USBCLK clock frequency */
switch (LL_RCC_GetUSBClockSource(USBxSource))
{
#if defined(RCC_CFGR_USBPRE)
case LL_RCC_USB_CLKSOURCE_PLL: /* PLL clock used as USB clock source */
if (LL_RCC_PLL_IsReady())
{
usb_frequency = RCC_PLL_GetFreqDomain_SYS();
}
break;
case LL_RCC_USB_CLKSOURCE_PLL_DIV_1_5: /* PLL clock divided by 1.5 used as USB clock source */
default:
if (LL_RCC_PLL_IsReady())
{
usb_frequency = (RCC_PLL_GetFreqDomain_SYS() * 3U) / 2U;
}
break;
#endif /* RCC_CFGR_USBPRE */
#if defined(RCC_CFGR_OTGFSPRE)
/* USBCLK = PLLVCO/2
= (2 x PLLCLK) / 2
= PLLCLK */
case LL_RCC_USB_CLKSOURCE_PLL_DIV_2: /* PLL clock used as USB clock source */
if (LL_RCC_PLL_IsReady())
{
usb_frequency = RCC_PLL_GetFreqDomain_SYS();
}
break;
/* USBCLK = PLLVCO/3
= (2 x PLLCLK) / 3 */
case LL_RCC_USB_CLKSOURCE_PLL_DIV_3: /* PLL clock divided by 3 used as USB clock source */
default:
if (LL_RCC_PLL_IsReady())
{
usb_frequency = (RCC_PLL_GetFreqDomain_SYS() * 2U) / 3U;
}
break;
#endif /* RCC_CFGR_OTGFSPRE */
}
return usb_frequency;
}
#endif /* USB */
/**
* @brief Return ADCx clock frequency
* @param ADCxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_ADC_CLKSOURCE
* @retval ADC clock frequency (in Hz)
*/
uint32_t LL_RCC_GetADCClockFreq(uint32_t ADCxSource)
{
uint32_t adc_prescaler = 0U;
uint32_t adc_frequency = 0U;
/* Check parameter */
assert_param(IS_LL_RCC_ADC_CLKSOURCE(ADCxSource));
/* Get ADC prescaler */
adc_prescaler = LL_RCC_GetADCClockSource(ADCxSource);
/* ADC frequency = PCLK2 frequency / ADC prescaler (2, 4, 6 or 8) */
adc_frequency = RCC_GetPCLK2ClockFreq(RCC_GetHCLKClockFreq(RCC_GetSystemClockFreq()))
/ (((adc_prescaler >> POSITION_VAL(ADCxSource)) + 1U) * 2U);
return adc_frequency;
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup RCC_LL_Private_Functions
* @{
*/
/**
* @brief Return SYSTEM clock frequency
* @retval SYSTEM clock frequency (in Hz)
*/
uint32_t RCC_GetSystemClockFreq(void)
{
uint32_t frequency = 0U;
/* Get SYSCLK source -------------------------------------------------------*/
switch (LL_RCC_GetSysClkSource())
{
case LL_RCC_SYS_CLKSOURCE_STATUS_HSI: /* HSI used as system clock source */
frequency = HSI_VALUE;
break;
case LL_RCC_SYS_CLKSOURCE_STATUS_HSE: /* HSE used as system clock source */
frequency = HSE_VALUE;
break;
case LL_RCC_SYS_CLKSOURCE_STATUS_PLL: /* PLL used as system clock source */
frequency = RCC_PLL_GetFreqDomain_SYS();
break;
default:
frequency = HSI_VALUE;
break;
}
return frequency;
}
/**
* @brief Return HCLK clock frequency
* @param SYSCLK_Frequency SYSCLK clock frequency
* @retval HCLK clock frequency (in Hz)
*/
uint32_t RCC_GetHCLKClockFreq(uint32_t SYSCLK_Frequency)
{
/* HCLK clock frequency */
return __LL_RCC_CALC_HCLK_FREQ(SYSCLK_Frequency, LL_RCC_GetAHBPrescaler());
}
/**
* @brief Return PCLK1 clock frequency
* @param HCLK_Frequency HCLK clock frequency
* @retval PCLK1 clock frequency (in Hz)
*/
uint32_t RCC_GetPCLK1ClockFreq(uint32_t HCLK_Frequency)
{
/* PCLK1 clock frequency */
return __LL_RCC_CALC_PCLK1_FREQ(HCLK_Frequency, LL_RCC_GetAPB1Prescaler());
}
/**
* @brief Return PCLK2 clock frequency
* @param HCLK_Frequency HCLK clock frequency
* @retval PCLK2 clock frequency (in Hz)
*/
uint32_t RCC_GetPCLK2ClockFreq(uint32_t HCLK_Frequency)
{
/* PCLK2 clock frequency */
return __LL_RCC_CALC_PCLK2_FREQ(HCLK_Frequency, LL_RCC_GetAPB2Prescaler());
}
/**
* @brief Return PLL clock frequency used for system domain
* @retval PLL clock frequency (in Hz)
*/
uint32_t RCC_PLL_GetFreqDomain_SYS(void)
{
uint32_t pllinputfreq = 0U, pllsource = 0U;
/* PLL_VCO = (HSE_VALUE, HSI_VALUE or PLL2 / PLL Predivider) * PLL Multiplicator */
/* Get PLL source */
pllsource = LL_RCC_PLL_GetMainSource();
switch (pllsource)
{
case LL_RCC_PLLSOURCE_HSI_DIV_2: /* HSI used as PLL clock source */
pllinputfreq = HSI_VALUE / 2U;
break;
case LL_RCC_PLLSOURCE_HSE: /* HSE used as PLL clock source */
pllinputfreq = HSE_VALUE / (LL_RCC_PLL_GetPrediv() + 1U);
break;
#if defined(RCC_PLL2_SUPPORT)
case LL_RCC_PLLSOURCE_PLL2: /* PLL2 used as PLL clock source */
pllinputfreq = RCC_PLL2_GetFreqClockFreq() / (LL_RCC_PLL_GetPrediv() + 1U);
break;
#endif /* RCC_PLL2_SUPPORT */
default:
pllinputfreq = HSI_VALUE / 2U;
break;
}
return __LL_RCC_CALC_PLLCLK_FREQ(pllinputfreq, LL_RCC_PLL_GetMultiplicator());
}
#if defined(RCC_PLL2_SUPPORT)
/**
* @brief Return PLL clock frequency used for system domain
* @retval PLL clock frequency (in Hz)
*/
uint32_t RCC_PLL2_GetFreqClockFreq(void)
{
return __LL_RCC_CALC_PLL2CLK_FREQ(HSE_VALUE, LL_RCC_PLL2_GetMultiplicator(), LL_RCC_HSE_GetPrediv2());
}
#endif /* RCC_PLL2_SUPPORT */
#if defined(RCC_PLLI2S_SUPPORT)
/**
* @brief Return PLL clock frequency used for system domain
* @retval PLL clock frequency (in Hz)
*/
uint32_t RCC_PLLI2S_GetFreqDomain_I2S(void)
{
return __LL_RCC_CALC_PLLI2SCLK_FREQ(HSE_VALUE, LL_RCC_PLLI2S_GetMultiplicator(), LL_RCC_HSE_GetPrediv2());
}
#endif /* RCC_PLLI2S_SUPPORT */
/**
* @}
*/
/**
* @}
*/
#endif /* defined(RCC) */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */

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Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_ll_utils.c
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/**
******************************************************************************
* @file stm32f1xx_ll_utils.c
* @author MCD Application Team
* @brief UTILS LL module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32f1xx_ll_rcc.h"
#include "stm32f1xx_ll_utils.h"
#include "stm32f1xx_ll_system.h"
#ifdef USE_FULL_ASSERT
#include "stm32_assert.h"
#else
#define assert_param(expr) ((void)0U)
#endif
/** @addtogroup STM32F1xx_LL_Driver
* @{
*/
/** @addtogroup UTILS_LL
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @addtogroup UTILS_LL_Private_Constants
* @{
*/
/* Defines used for PLL range */
#define UTILS_PLL_OUTPUT_MAX RCC_MAX_FREQUENCY /*!< Frequency max for PLL output, in Hz */
#define UTILS_PLL2_OUTPUT_MAX RCC_MAX_FREQUENCY /*!< Frequency max for PLL2 output, in Hz */
/* Defines used for HSE range */
#define UTILS_HSE_FREQUENCY_MIN RCC_HSE_MIN /*!< Frequency min for HSE frequency, in Hz */
#define UTILS_HSE_FREQUENCY_MAX RCC_HSE_MAX /*!< Frequency max for HSE frequency, in Hz */
/* Defines used for FLASH latency according to HCLK Frequency */
#if defined(FLASH_ACR_LATENCY)
#define UTILS_LATENCY1_FREQ 24000000U /*!< SYSCLK frequency to set FLASH latency 1 */
#define UTILS_LATENCY2_FREQ 48000000U /*!< SYSCLK frequency to set FLASH latency 2 */
#else
/*!< No Latency Configuration in this device */
#endif
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup UTILS_LL_Private_Macros
* @{
*/
#define IS_LL_UTILS_SYSCLK_DIV(__VALUE__) (((__VALUE__) == LL_RCC_SYSCLK_DIV_1) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_2) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_4) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_8) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_16) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_64) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_128) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_256) \
|| ((__VALUE__) == LL_RCC_SYSCLK_DIV_512))
#define IS_LL_UTILS_APB1_DIV(__VALUE__) (((__VALUE__) == LL_RCC_APB1_DIV_1) \
|| ((__VALUE__) == LL_RCC_APB1_DIV_2) \
|| ((__VALUE__) == LL_RCC_APB1_DIV_4) \
|| ((__VALUE__) == LL_RCC_APB1_DIV_8) \
|| ((__VALUE__) == LL_RCC_APB1_DIV_16))
#define IS_LL_UTILS_APB2_DIV(__VALUE__) (((__VALUE__) == LL_RCC_APB2_DIV_1) \
|| ((__VALUE__) == LL_RCC_APB2_DIV_2) \
|| ((__VALUE__) == LL_RCC_APB2_DIV_4) \
|| ((__VALUE__) == LL_RCC_APB2_DIV_8) \
|| ((__VALUE__) == LL_RCC_APB2_DIV_16))
#if defined(RCC_CFGR_PLLMULL6_5)
#define IS_LL_UTILS_PLLMUL_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_PLL_MUL_4) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_5) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_6) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_7) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_8) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_9) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_6_5))
#else
#define IS_LL_UTILS_PLLMUL_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_PLL_MUL_2) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_3) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_4) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_5) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_6) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_7) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_8) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_9) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_10) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_11) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_12) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_13) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_14) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_15) \
|| ((__VALUE__) == LL_RCC_PLL_MUL_16))
#endif /* RCC_CFGR_PLLMULL6_5 */
#if defined(RCC_CFGR2_PREDIV1)
#define IS_LL_UTILS_PREDIV_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_PREDIV_DIV_1) || ((__VALUE__) == LL_RCC_PREDIV_DIV_2) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_3) || ((__VALUE__) == LL_RCC_PREDIV_DIV_4) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_5) || ((__VALUE__) == LL_RCC_PREDIV_DIV_6) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_7) || ((__VALUE__) == LL_RCC_PREDIV_DIV_8) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_9) || ((__VALUE__) == LL_RCC_PREDIV_DIV_10) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_11) || ((__VALUE__) == LL_RCC_PREDIV_DIV_12) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_13) || ((__VALUE__) == LL_RCC_PREDIV_DIV_14) || \
((__VALUE__) == LL_RCC_PREDIV_DIV_15) || ((__VALUE__) == LL_RCC_PREDIV_DIV_16))
#else
#define IS_LL_UTILS_PREDIV_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_PREDIV_DIV_1) || ((__VALUE__) == LL_RCC_PREDIV_DIV_2))
#endif /*RCC_PREDIV1_DIV_2_16_SUPPORT*/
#define IS_LL_UTILS_PLL_FREQUENCY(__VALUE__) ((__VALUE__) <= UTILS_PLL_OUTPUT_MAX)
#if defined(RCC_PLL2_SUPPORT)
#define IS_LL_UTILS_PLL2MUL_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_PLL2_MUL_8) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_9) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_10) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_11) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_12) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_13) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_14) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_16) \
|| ((__VALUE__) == LL_RCC_PLL2_MUL_20))
#define IS_LL_UTILS_PREDIV2_VALUE(__VALUE__) (((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_1) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_2) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_3) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_4) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_5) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_6) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_7) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_8) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_9) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_10) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_11) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_12) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_13) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_14) || \
((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_15) || ((__VALUE__) == LL_RCC_HSE_PREDIV2_DIV_16))
#define IS_LL_UTILS_PLL2_FREQUENCY(__VALUE__) ((__VALUE__) <= UTILS_PLL2_OUTPUT_MAX)
#endif /* RCC_PLL2_SUPPORT */
#define IS_LL_UTILS_HSE_BYPASS(__STATE__) (((__STATE__) == LL_UTILS_HSEBYPASS_ON) \
|| ((__STATE__) == LL_UTILS_HSEBYPASS_OFF))
#define IS_LL_UTILS_HSE_FREQUENCY(__FREQUENCY__) (((__FREQUENCY__) >= UTILS_HSE_FREQUENCY_MIN) && ((__FREQUENCY__) <= UTILS_HSE_FREQUENCY_MAX))
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup UTILS_LL_Private_Functions UTILS Private functions
* @{
*/
static uint32_t UTILS_GetPLLOutputFrequency(uint32_t PLL_InputFrequency,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct);
static ErrorStatus UTILS_PLL_HSE_ConfigSystemClock(uint32_t PLL_InputFrequency, uint32_t HSEBypass,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct,
LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct);
#if defined(RCC_PLL2_SUPPORT)
static uint32_t UTILS_GetPLL2OutputFrequency(uint32_t PLL2_InputFrequency,
LL_UTILS_PLLInitTypeDef *UTILS_PLL2InitStruct);
#endif /* RCC_PLL2_SUPPORT */
static ErrorStatus UTILS_EnablePLLAndSwitchSystem(uint32_t SYSCLK_Frequency, LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct);
static ErrorStatus UTILS_PLL_IsBusy(void);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup UTILS_LL_Exported_Functions
* @{
*/
/** @addtogroup UTILS_LL_EF_DELAY
* @{
*/
/**
* @brief This function configures the Cortex-M SysTick source to have 1ms time base.
* @note When a RTOS is used, it is recommended to avoid changing the Systick
* configuration by calling this function, for a delay use rather osDelay RTOS service.
* @param HCLKFrequency HCLK frequency in Hz
* @note HCLK frequency can be calculated thanks to RCC helper macro or function @ref LL_RCC_GetSystemClocksFreq
* @retval None
*/
void LL_Init1msTick(uint32_t HCLKFrequency)
{
/* Use frequency provided in argument */
LL_InitTick(HCLKFrequency, 1000U);
}
/**
* @brief This function provides accurate delay (in milliseconds) based
* on SysTick counter flag
* @note When a RTOS is used, it is recommended to avoid using blocking delay
* and use rather osDelay service.
* @note To respect 1ms timebase, user should call @ref LL_Init1msTick function which
* will configure Systick to 1ms
* @param Delay specifies the delay time length, in milliseconds.
* @retval None
*/
void LL_mDelay(uint32_t Delay)
{
__IO uint32_t tmp = SysTick->CTRL; /* Clear the COUNTFLAG first */
/* Add this code to indicate that local variable is not used */
((void)tmp);
/* Add a period to guaranty minimum wait */
if (Delay < LL_MAX_DELAY)
{
Delay++;
}
while (Delay)
{
if ((SysTick->CTRL & SysTick_CTRL_COUNTFLAG_Msk) != 0U)
{
Delay--;
}
}
}
/**
* @}
*/
/** @addtogroup UTILS_EF_SYSTEM
* @brief System Configuration functions
*
@verbatim
===============================================================================
##### System Configuration functions #####
===============================================================================
[..]
System, AHB and APB buses clocks configuration
(+) The maximum frequency of the SYSCLK, HCLK, PCLK1 and PCLK2 is RCC_MAX_FREQUENCY Hz.
@endverbatim
@internal
Depending on the SYSCLK frequency, the flash latency should be adapted accordingly:
(++) +-----------------------------------------------+
(++) | Latency | SYSCLK clock frequency (MHz) |
(++) |---------------|-------------------------------|
(++) |0WS(1CPU cycle)| 0 < SYSCLK <= 24 |
(++) |---------------|-------------------------------|
(++) |1WS(2CPU cycle)| 24 < SYSCLK <= 48 |
(++) |---------------|-------------------------------|
(++) |2WS(3CPU cycle)| 48 < SYSCLK <= 72 |
(++) +-----------------------------------------------+
@endinternal
* @{
*/
/**
* @brief This function sets directly SystemCoreClock CMSIS variable.
* @note Variable can be calculated also through SystemCoreClockUpdate function.
* @param HCLKFrequency HCLK frequency in Hz (can be calculated thanks to RCC helper macro)
* @retval None
*/
void LL_SetSystemCoreClock(uint32_t HCLKFrequency)
{
/* HCLK clock frequency */
SystemCoreClock = HCLKFrequency;
}
/**
* @brief Update number of Flash wait states in line with new frequency and current
voltage range.
* @param Frequency SYSCLK frequency
* @retval An ErrorStatus enumeration value:
* - SUCCESS: Latency has been modified
* - ERROR: Latency cannot be modified
*/
#if defined(FLASH_ACR_LATENCY)
ErrorStatus LL_SetFlashLatency(uint32_t Frequency)
{
uint32_t timeout;
uint32_t getlatency;
uint32_t latency = LL_FLASH_LATENCY_0; /* default value 0WS */
ErrorStatus status = SUCCESS;
/* Frequency cannot be equal to 0 */
if (Frequency == 0U)
{
status = ERROR;
}
else
{
if (Frequency > UTILS_LATENCY2_FREQ)
{
/* 48 < SYSCLK <= 72 => 2WS (3 CPU cycles) */
latency = LL_FLASH_LATENCY_2;
}
else
{
if (Frequency > UTILS_LATENCY1_FREQ)
{
/* 24 < SYSCLK <= 48 => 1WS (2 CPU cycles) */
latency = LL_FLASH_LATENCY_1;
}
else
{
/* else SYSCLK < 24MHz default LL_FLASH_LATENCY_0 0WS */
latency = LL_FLASH_LATENCY_0;
}
}
if (status != ERROR)
{
LL_FLASH_SetLatency(latency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by reading the FLASH_ACR register */
timeout = 2;
do
{
/* Wait for Flash latency to be updated */
getlatency = LL_FLASH_GetLatency();
timeout--;
}
while ((getlatency != latency) && (timeout > 0));
if (getlatency != latency)
{
status = ERROR;
}
else
{
status = SUCCESS;
}
}
}
return status;
}
#endif /* FLASH_ACR_LATENCY */
/**
* @brief This function configures system clock with HSI as clock source of the PLL
* @note The application need to ensure that PLL is disabled.
* @note Function is based on the following formula:
* - PLL output frequency = ((HSI frequency / PREDIV) * PLLMUL)
* - PREDIV: Set to 2 for few devices
* - PLLMUL: The application software must set correctly the PLL multiplication factor to
* not exceed 72MHz
* @note FLASH latency can be modified through this function.
* @param UTILS_PLLInitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @param UTILS_ClkInitStruct pointer to a @ref LL_UTILS_ClkInitTypeDef structure that contains
* the configuration information for the BUS prescalers.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: Max frequency configuration done
* - ERROR: Max frequency configuration not done
*/
ErrorStatus LL_PLL_ConfigSystemClock_HSI(LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct,
LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct)
{
ErrorStatus status = SUCCESS;
uint32_t pllfreq = 0U;
/* Check if one of the PLL is enabled */
if (UTILS_PLL_IsBusy() == SUCCESS)
{
#if defined(RCC_PLLSRC_PREDIV1_SUPPORT)
/* Check PREDIV value */
assert_param(IS_LL_UTILS_PREDIV_VALUE(UTILS_PLLInitStruct->PLLDiv));
#else
/* Force PREDIV value to 2 */
UTILS_PLLInitStruct->Prediv = LL_RCC_PREDIV_DIV_2;
#endif /*RCC_PLLSRC_PREDIV1_SUPPORT*/
/* Calculate the new PLL output frequency */
pllfreq = UTILS_GetPLLOutputFrequency(HSI_VALUE, UTILS_PLLInitStruct);
/* Enable HSI if not enabled */
if (LL_RCC_HSI_IsReady() != 1U)
{
LL_RCC_HSI_Enable();
while (LL_RCC_HSI_IsReady() != 1U)
{
/* Wait for HSI ready */
}
}
/* Configure PLL */
LL_RCC_PLL_ConfigDomain_SYS(LL_RCC_PLLSOURCE_HSI_DIV_2, UTILS_PLLInitStruct->PLLMul);
/* Enable PLL and switch system clock to PLL */
status = UTILS_EnablePLLAndSwitchSystem(pllfreq, UTILS_ClkInitStruct);
}
else
{
/* Current PLL configuration cannot be modified */
status = ERROR;
}
return status;
}
/**
* @brief This function configures system clock with HSE as clock source of the PLL
* @note The application need to ensure that PLL is disabled.
* @note Function is based on the following formula:
* - PLL output frequency = ((HSI frequency / PREDIV) * PLLMUL)
* - PREDIV: Set to 2 for few devices
* - PLLMUL: The application software must set correctly the PLL multiplication factor to
* not exceed @ref UTILS_PLL_OUTPUT_MAX
* @note FLASH latency can be modified through this function.
* @param HSEFrequency Value between Min_Data = RCC_HSE_MIN and Max_Data = RCC_HSE_MAX
* @param HSEBypass This parameter can be one of the following values:
* @arg @ref LL_UTILS_HSEBYPASS_ON
* @arg @ref LL_UTILS_HSEBYPASS_OFF
* @param UTILS_PLLInitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @param UTILS_ClkInitStruct pointer to a @ref LL_UTILS_ClkInitTypeDef structure that contains
* the configuration information for the BUS prescalers.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: Max frequency configuration done
* - ERROR: Max frequency configuration not done
*/
ErrorStatus LL_PLL_ConfigSystemClock_HSE(uint32_t HSEFrequency, uint32_t HSEBypass,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct, LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct)
{
ErrorStatus status = SUCCESS;
uint32_t pllfrequency = 0U;
/* Check the parameters */
assert_param(IS_LL_UTILS_HSE_FREQUENCY(HSEFrequency));
assert_param(IS_LL_UTILS_HSE_BYPASS(HSEBypass));
assert_param(IS_LL_UTILS_PREDIV_VALUE(UTILS_PLLInitStruct->Prediv));
/* Calculate the new PLL output frequency */
pllfrequency = UTILS_GetPLLOutputFrequency(HSEFrequency, UTILS_PLLInitStruct);
/* Enable HSE if not enabled */
status = UTILS_PLL_HSE_ConfigSystemClock(HSEFrequency, HSEBypass, UTILS_PLLInitStruct, UTILS_ClkInitStruct);
/* Check if HSE is not enabled*/
if (status == SUCCESS)
{
/* Configure PLL */
LL_RCC_PLL_ConfigDomain_SYS((LL_RCC_PLLSOURCE_HSE | UTILS_PLLInitStruct->Prediv), UTILS_PLLInitStruct->PLLMul);
/* Enable PLL and switch system clock to PLL */
status = UTILS_EnablePLLAndSwitchSystem(pllfrequency, UTILS_ClkInitStruct);
}
return status;
}
#if defined(RCC_PLL2_SUPPORT)
/**
* @brief This function configures system clock with HSE as clock source of the PLL, via PLL2
* @note The application need to ensure that PLL and PLL2 are disabled.
* @note Function is based on the following formula:
* - PLL output frequency = ((((HSE frequency / PREDIV2) * PLL2MUL) / PREDIV) * PLLMUL)
* - PREDIV, PLLMUL, PREDIV2, PLL2MUL: The application software must set correctly the
* PLL multiplication factor to not exceed @ref UTILS_PLL_OUTPUT_MAX
* @note FLASH latency can be modified through this function.
* @param HSEFrequency Value between Min_Data = RCC_HSE_MIN and Max_Data = RCC_HSE_MAX
* @param HSEBypass This parameter can be one of the following values:
* @arg @ref LL_UTILS_HSEBYPASS_ON
* @arg @ref LL_UTILS_HSEBYPASS_OFF
* @param UTILS_PLLInitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @param UTILS_PLL2InitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL2.
* @param UTILS_ClkInitStruct pointer to a @ref LL_UTILS_ClkInitTypeDef structure that contains
* the configuration information for the BUS prescalers.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: Max frequency configuration done
* - ERROR: Max frequency configuration not done
*/
ErrorStatus LL_PLL_ConfigSystemClock_PLL2(uint32_t HSEFrequency, uint32_t HSEBypass,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct,
LL_UTILS_PLLInitTypeDef *UTILS_PLL2InitStruct,
LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct)
{
ErrorStatus status = SUCCESS;
uint32_t pllfrequency = 0U;
/* Check the parameters */
assert_param(IS_LL_UTILS_HSE_FREQUENCY(HSEFrequency));
assert_param(IS_LL_UTILS_HSE_BYPASS(HSEBypass));
assert_param(IS_LL_UTILS_PREDIV_VALUE(UTILS_PLLInitStruct->Prediv));
assert_param(IS_LL_UTILS_PREDIV2_VALUE(UTILS_PLL2InitStruct->Prediv));
/* Calculate the new PLL output frequency */
pllfrequency = UTILS_GetPLLOutputFrequency(HSEFrequency, UTILS_PLLInitStruct);
/* Enable HSE if not enabled */
status = UTILS_PLL_HSE_ConfigSystemClock(HSEFrequency, HSEBypass, UTILS_PLLInitStruct, UTILS_ClkInitStruct);
/* Check if HSE is not enabled*/
if (status == SUCCESS)
{
/* Configure PLL */
LL_RCC_PLL_ConfigDomain_PLL2(UTILS_PLL2InitStruct->Prediv, UTILS_PLL2InitStruct->PLLMul);
LL_RCC_PLL_ConfigDomain_SYS((LL_RCC_PLLSOURCE_PLL2 | UTILS_PLLInitStruct->Prediv), UTILS_PLLInitStruct->PLLMul);
/* Calculate the new PLL output frequency */
pllfrequency = UTILS_GetPLL2OutputFrequency(pllfrequency, UTILS_PLL2InitStruct);
/* Enable PLL and switch system clock to PLL */
status = UTILS_EnablePLLAndSwitchSystem(pllfrequency, UTILS_ClkInitStruct);
}
return status;
}
#endif /* RCC_PLL2_SUPPORT */
/**
* @}
*/
/**
* @}
*/
/** @addtogroup UTILS_LL_Private_Functions
* @{
*/
/**
* @brief Function to check that PLL can be modified
* @param PLL_InputFrequency PLL input frequency (in Hz)
* @param UTILS_PLLInitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @retval PLL output frequency (in Hz)
*/
static uint32_t UTILS_GetPLLOutputFrequency(uint32_t PLL_InputFrequency, LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct)
{
uint32_t pllfreq = 0U;
/* Check the parameters */
assert_param(IS_LL_UTILS_PLLMUL_VALUE(UTILS_PLLInitStruct->PLLMul));
/* Check different PLL parameters according to RM */
#if defined (RCC_CFGR2_PREDIV1)
pllfreq = __LL_RCC_CALC_PLLCLK_FREQ(PLL_InputFrequency / (UTILS_PLLInitStruct->Prediv + 1U), UTILS_PLLInitStruct->PLLMul);
#else
pllfreq = __LL_RCC_CALC_PLLCLK_FREQ(PLL_InputFrequency / ((UTILS_PLLInitStruct->Prediv >> RCC_CFGR_PLLXTPRE_Pos) + 1U), UTILS_PLLInitStruct->PLLMul);
#endif /*RCC_CFGR2_PREDIV1SRC*/
assert_param(IS_LL_UTILS_PLL_FREQUENCY(pllfreq));
return pllfreq;
}
/**
* @brief This function enable the HSE when it is used by PLL or PLL2
* @note The application need to ensure that PLL is disabled.
* @param HSEFrequency Value between Min_Data = RCC_HSE_MIN and Max_Data = RCC_HSE_MAX
* @param HSEBypass This parameter can be one of the following values:
* @arg @ref LL_UTILS_HSEBYPASS_ON
* @arg @ref LL_UTILS_HSEBYPASS_OFF
* @param UTILS_PLLInitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @param UTILS_ClkInitStruct pointer to a @ref LL_UTILS_ClkInitTypeDef structure that contains
* the configuration information for the BUS prescalers.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: HSE configuration done
* - ERROR: HSE configuration not done
*/
static ErrorStatus UTILS_PLL_HSE_ConfigSystemClock(uint32_t PLL_InputFrequency, uint32_t HSEBypass,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct,
LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct)
{
ErrorStatus status = SUCCESS;
/* Check if one of the PLL is enabled */
if (UTILS_PLL_IsBusy() == SUCCESS)
{
/* Enable HSE if not enabled */
if (LL_RCC_HSE_IsReady() != 1U)
{
/* Check if need to enable HSE bypass feature or not */
if (HSEBypass == LL_UTILS_HSEBYPASS_ON)
{
LL_RCC_HSE_EnableBypass();
}
else
{
LL_RCC_HSE_DisableBypass();
}
/* Enable HSE */
LL_RCC_HSE_Enable();
while (LL_RCC_HSE_IsReady() != 1U)
{
/* Wait for HSE ready */
}
}
}
else
{
/* Current PLL configuration cannot be modified */
status = ERROR;
}
return status;
}
#if defined(RCC_PLL2_SUPPORT)
/**
* @brief Function to check that PLL2 can be modified
* @param PLL2_InputFrequency PLL2 input frequency (in Hz)
* @param UTILS_PLL2InitStruct pointer to a @ref LL_UTILS_PLLInitTypeDef structure that contains
* the configuration information for the PLL.
* @retval PLL2 output frequency (in Hz)
*/
static uint32_t UTILS_GetPLL2OutputFrequency(uint32_t PLL2_InputFrequency, LL_UTILS_PLLInitTypeDef *UTILS_PLL2InitStruct)
{
uint32_t pll2freq = 0U;
/* Check the parameters */
assert_param(IS_LL_UTILS_PLL2MUL_VALUE(UTILS_PLL2InitStruct->PLLMul));
assert_param(IS_LL_UTILS_PREDIV2_VALUE(UTILS_PLL2InitStruct->Prediv));
/* Check different PLL2 parameters according to RM */
pll2freq = __LL_RCC_CALC_PLL2CLK_FREQ(PLL2_InputFrequency, UTILS_PLL2InitStruct->PLLMul, UTILS_PLL2InitStruct->Prediv);
assert_param(IS_LL_UTILS_PLL2_FREQUENCY(pll2freq));
return pll2freq;
}
#endif /* RCC_PLL2_SUPPORT */
/**
* @brief Function to check that PLL can be modified
* @retval An ErrorStatus enumeration value:
* - SUCCESS: PLL modification can be done
* - ERROR: PLL is busy
*/
static ErrorStatus UTILS_PLL_IsBusy(void)
{
ErrorStatus status = SUCCESS;
/* Check if PLL is busy*/
if (LL_RCC_PLL_IsReady() != 0U)
{
/* PLL configuration cannot be modified */
status = ERROR;
}
#if defined(RCC_PLL2_SUPPORT)
/* Check if PLL2 is busy*/
if (LL_RCC_PLL2_IsReady() != 0U)
{
/* PLL2 configuration cannot be modified */
status = ERROR;
}
#endif /* RCC_PLL2_SUPPORT */
#if defined(RCC_PLLI2S_SUPPORT)
/* Check if PLLI2S is busy*/
if (LL_RCC_PLLI2S_IsReady() != 0U)
{
/* PLLI2S configuration cannot be modified */
status = ERROR;
}
#endif /* RCC_PLLI2S_SUPPORT */
return status;
}
/**
* @brief Function to enable PLL and switch system clock to PLL
* @param SYSCLK_Frequency SYSCLK frequency
* @param UTILS_ClkInitStruct pointer to a @ref LL_UTILS_ClkInitTypeDef structure that contains
* the configuration information for the BUS prescalers.
* @retval An ErrorStatus enumeration value:
* - SUCCESS: No problem to switch system to PLL
* - ERROR: Problem to switch system to PLL
*/
static ErrorStatus UTILS_EnablePLLAndSwitchSystem(uint32_t SYSCLK_Frequency, LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct)
{
ErrorStatus status = SUCCESS;
#if defined(FLASH_ACR_LATENCY)
uint32_t sysclk_frequency_current = 0U;
#endif /* FLASH_ACR_LATENCY */
assert_param(IS_LL_UTILS_SYSCLK_DIV(UTILS_ClkInitStruct->AHBCLKDivider));
assert_param(IS_LL_UTILS_APB1_DIV(UTILS_ClkInitStruct->APB1CLKDivider));
assert_param(IS_LL_UTILS_APB2_DIV(UTILS_ClkInitStruct->APB2CLKDivider));
#if defined(FLASH_ACR_LATENCY)
/* Calculate current SYSCLK frequency */
sysclk_frequency_current = (SystemCoreClock << AHBPrescTable[LL_RCC_GetAHBPrescaler() >> RCC_CFGR_HPRE_Pos]);
#endif /* FLASH_ACR_LATENCY */
/* Increasing the number of wait states because of higher CPU frequency */
#if defined (FLASH_ACR_LATENCY)
if (sysclk_frequency_current < SYSCLK_Frequency)
{
/* Set FLASH latency to highest latency */
status = LL_SetFlashLatency(SYSCLK_Frequency);
}
#endif /* FLASH_ACR_LATENCY */
/* Update system clock configuration */
if (status == SUCCESS)
{
#if defined(RCC_PLL2_SUPPORT)
if (LL_RCC_PLL_GetMainSource() != LL_RCC_PLLSOURCE_HSI_DIV_2)
{
/* Enable PLL2 */
LL_RCC_PLL2_Enable();
while (LL_RCC_PLL2_IsReady() != 1U)
{
/* Wait for PLL2 ready */
}
}
#endif /* RCC_PLL2_SUPPORT */
/* Enable PLL */
LL_RCC_PLL_Enable();
while (LL_RCC_PLL_IsReady() != 1U)
{
/* Wait for PLL ready */
}
/* Sysclk activation on the main PLL */
LL_RCC_SetAHBPrescaler(UTILS_ClkInitStruct->AHBCLKDivider);
LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_PLL);
while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_PLL)
{
/* Wait for system clock switch to PLL */
}
/* Set APB1 & APB2 prescaler*/
LL_RCC_SetAPB1Prescaler(UTILS_ClkInitStruct->APB1CLKDivider);
LL_RCC_SetAPB2Prescaler(UTILS_ClkInitStruct->APB2CLKDivider);
}
/* Decreasing the number of wait states because of lower CPU frequency */
#if defined (FLASH_ACR_LATENCY)
if (sysclk_frequency_current > SYSCLK_Frequency)
{
/* Set FLASH latency to lowest latency */
status = LL_SetFlashLatency(SYSCLK_Frequency);
}
#endif /* FLASH_ACR_LATENCY */
/* Update SystemCoreClock variable */
if (status == SUCCESS)
{
LL_SetSystemCoreClock(__LL_RCC_CALC_HCLK_FREQ(SYSCLK_Frequency, UTILS_ClkInitStruct->AHBCLKDivider));
}
return status;
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/

9
MDK-ARM/EventRecorderStub.scvd Normal file
View File

@ -0,0 +1,9 @@
<?xml version="1.0" encoding="utf-8"?>
<component_viewer schemaVersion="0.1" xmlns:xs="http://www.w3.org/2001/XMLSchema-instance" xs:noNamespaceSchemaLocation="Component_Viewer.xsd">
<component name="EventRecorderStub" version="1.0.0"/> <!--name and version of the component-->
<events>
</events>
</component_viewer>

21
MDK-ARM/RTE/_motor/RTE_Components.h Normal file
View File

@ -0,0 +1,21 @@
/*
* Auto generated Run-Time-Environment Configuration File
* *** Do not modify ! ***
*
* Project: 'motor'
* Target: 'motor'
*/
#ifndef RTE_COMPONENTS_H
#define RTE_COMPONENTS_H
/*
* Define the Device Header File:
*/
#define CMSIS_device_header "stm32f10x.h"
#endif /* RTE_COMPONENTS_H */

593
MDK-ARM/motor.uvoptx
View File

@ -1,21 +1,26 @@
<?xml version="1.0" encoding="UTF-8"?>
<?xml version="1.0" encoding="UTF-8" standalone="no" ?>
<ProjectOpt xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="project_optx.xsd">
<SchemaVersion>1.0</SchemaVersion>
<Header>### uVision Project, (C) Keil Software</Header>
<Extensions>
<cExt>*.c</cExt>
<aExt>*.s*; *.src; *.a*</aExt>
<oExt>*.obj; *.o</oExt>
<lExt>*.lib</lExt>
<tExt>*.txt; *.h; *.inc</tExt>
<tExt>*.txt; *.h; *.inc; *.md</tExt>
<pExt>*.plm</pExt>
<CppX>*.cpp</CppX>
<nMigrate>0</nMigrate>
</Extensions>
<DaveTm>
<dwLowDateTime>0</dwLowDateTime>
<dwHighDateTime>0</dwHighDateTime>
</DaveTm>
<Target>
<TargetName>motor</TargetName>
<ToolsetNumber>0x4</ToolsetNumber>
@ -40,7 +45,7 @@
<PageWidth>79</PageWidth>
<PageLength>66</PageLength>
<TabStop>8</TabStop>
<ListingPath />
<ListingPath></ListingPath>
</OPTLEX>
<ListingPage>
<CreateCListing>1</CreateCListing>
@ -99,28 +104,33 @@
<bSchkAxf>0</bSchkAxf>
<bTchkAxf>0</bTchkAxf>
<nTsel>6</nTsel>
<sDll />
<sDllPa />
<sDlgDll />
<sDlgPa />
<sIfile />
<tDll />
<tDllPa />
<tDlgDll />
<tDlgPa />
<tIfile />
<sDll></sDll>
<sDllPa></sDllPa>
<sDlgDll></sDlgDll>
<sDlgPa></sDlgPa>
<sIfile></sIfile>
<tDll></tDll>
<tDllPa></tDllPa>
<tDlgDll></tDlgDll>
<tDlgPa></tDlgPa>
<tIfile></tIfile>
<pMon>STLink\ST-LINKIII-KEIL_SWO.dll</pMon>
</DebugOpt>
<TargetDriverDllRegistry>
<SetRegEntry>
<Number>0</Number>
<Key>ST-LINKIII-KEIL_SWO</Key>
<Name>-U-O142 -O2254 -S0 -C0 -N00("ARM CoreSight SW-DP") -D00(2BA01477) -L00(0) -TO18 -TC10000000 -TP21 -TDS8007 -TDT0 -TDC1F -TIEFFFFFFFF -TIP8 -FO7 -FD20000000 -FC800 -FN1 -FF0STM32F10x_128 -FS08000000 -FL010000 -FP0($$Device:STM32F103C8$Flash\STM32F10x_128.FLM)</Name>
<Key>JL2CM3</Key>
<Name>-U -O78 -S2 -ZTIFSpeedSel5000 -A0 -C0 -JU1 -JI127.0.0.1 -JP0 -RST0 -TO18 -TC10000000 -TP21 -TDS8007 -TDT0 -TDC1F -TIEFFFFFFFF -TIP8 -TB1 -TFE0 -FO7 -FD20000000 -FC1000 -FN1 -FF0STM32F10x_128.FLM -FS08000000 -FL020000 -FP0($$Device:STM32F103C8$Flash\STM32F10x_128.FLM)</Name>
</SetRegEntry>
<SetRegEntry>
<Number>0</Number>
<Key />
<Name />
<Key>UL2CM3</Key>
<Name>UL2CM3(-S0 -C0 -P0 -FD20000000 -FC1000 -FN1 -FF0STM32F10x_128 -FS08000000 -FL020000 -FP0($$Device:STM32F103C8$Flash\STM32F10x_128.FLM))</Name>
</SetRegEntry>
<SetRegEntry>
<Number>0</Number>
<Key>ST-LINKIII-KEIL_SWO</Key>
<Name>-US -O2254 -SF4000 -C0 -A0 -I0 -HNlocalhost -HP7184 -P1 -N00("ARM CoreSight SW-DP") -D00(1BA01477) -L00(0) -TO131090 -TC10000000 -TT10000000 -TP21 -TDS8007 -TDT0 -TDC1F -TIEFFFFFFFF -TIP8 -FO7 -FD20000000 -FC800 -FN1 -FF0STM32F10x_128.FLM -FS08000000 -FL010000 -FP0($$Device:STM32F103C8$Flash\STM32F10x_128.FLM)</Name>
</SetRegEntry>
</TargetDriverDllRegistry>
<Breakpoint/>
@ -153,19 +163,548 @@
<newCpu>0</newCpu>
<uProt>0</uProt>
</DebugFlag>
<LintExecutable />
<LintConfigFile />
<LintExecutable></LintExecutable>
<LintConfigFile></LintConfigFile>
<bLintAuto>0</bLintAuto>
<bAutoGenD>0</bAutoGenD>
<LntExFlags>0</LntExFlags>
<pMisraName />
<pszMrule />
<pSingCmds />
<pMultCmds />
<pMisraNamep />
<pszMrulep />
<pSingCmdsp />
<pMultCmdsp />
<pMisraName></pMisraName>
<pszMrule></pszMrule>
<pSingCmds></pSingCmds>
<pMultCmds></pMultCmds>
<pMisraNamep></pMisraNamep>
<pszMrulep></pszMrulep>
<pSingCmdsp></pSingCmdsp>
<pMultCmdsp></pMultCmdsp>
</TargetOption>
</Target>
<Group>
<GroupName>Application/MDK-ARM</GroupName>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>1</GroupNumber>
<FileNumber>1</FileNumber>
<FileType>2</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>startup_stm32f103xb.s</PathWithFileName>
<FilenameWithoutPath>startup_stm32f103xb.s</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>Application/User/Core</GroupName>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>2</GroupNumber>
<FileNumber>2</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>../Core/Src/main.c</PathWithFileName>
<FilenameWithoutPath>main.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>2</GroupNumber>
<FileNumber>3</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>../Core/Src/gpio.c</PathWithFileName>
<FilenameWithoutPath>gpio.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>2</GroupNumber>
<FileNumber>4</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>../Core/Src/stm32f1xx_it.c</PathWithFileName>
<FilenameWithoutPath>stm32f1xx_it.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>2</GroupNumber>
<FileNumber>5</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>../Core/Src/stm32f1xx_hal_msp.c</PathWithFileName>
<FilenameWithoutPath>stm32f1xx_hal_msp.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>Drivers/CMSIS</GroupName>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>3</GroupNumber>
<FileNumber>6</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>../Core/Src/system_stm32f1xx.c</PathWithFileName>
<FilenameWithoutPath>system_stm32f1xx.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>User/application</GroupName>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>4</GroupNumber>
<FileNumber>7</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>..\User\application\app.c</PathWithFileName>
<FilenameWithoutPath>app.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>User/board</GroupName>
<tvExp>1</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>5</GroupNumber>
<FileNumber>8</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>..\User\board\board.c</PathWithFileName>
<FilenameWithoutPath>board.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>User/system</GroupName>
<tvExp>1</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<cbSel>0</cbSel>
<RteFlg>0</RteFlg>
<File>
<GroupNumber>6</GroupNumber>
<FileNumber>9</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
<tvExpOptDlg>0</tvExpOptDlg>
<bDave2>0</bDave2>
<PathWithFileName>..\User\system\bsp\gpios.c</PathWithFileName>
<FilenameWithoutPath>gpios.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>6</GroupNumber>
<FileNumber>10</FileNumber>
<FileType>1</FileType>
<tvExp>0</tvExp>
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<bDave2>0</bDave2>
<PathWithFileName>..\User\system\src\delay.c</PathWithFileName>
<FilenameWithoutPath>delay.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>6</GroupNumber>
<FileNumber>11</FileNumber>
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<tvExp>0</tvExp>
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<bDave2>0</bDave2>
<PathWithFileName>..\User\system\src\sys.c</PathWithFileName>
<FilenameWithoutPath>sys.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
<GroupNumber>6</GroupNumber>
<FileNumber>12</FileNumber>
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<PathWithFileName>..\User\system\src\btn.c</PathWithFileName>
<FilenameWithoutPath>btn.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
</Group>
<Group>
<GroupName>User/lib</GroupName>
<tvExp>1</tvExp>
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<File>
<GroupNumber>7</GroupNumber>
<FileNumber>13</FileNumber>
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<PathWithFileName>..\User\lib\src\aes.c</PathWithFileName>
<FilenameWithoutPath>aes.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
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<FileNumber>14</FileNumber>
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<PathWithFileName>..\User\lib\src\clist.c</PathWithFileName>
<FilenameWithoutPath>clist.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
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<FileNumber>15</FileNumber>
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<PathWithFileName>..\User\lib\src\cmac.c</PathWithFileName>
<FilenameWithoutPath>cmac.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
<File>
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<FileNumber>16</FileNumber>
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<bDave2>0</bDave2>
<PathWithFileName>..\User\lib\src\cmd.c</PathWithFileName>
<FilenameWithoutPath>cmd.c</FilenameWithoutPath>
<RteFlg>0</RteFlg>
<bShared>0</bShared>
</File>
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<PathWithFileName>..\User\lib\src\data_analysis.c</PathWithFileName>
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</File>
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</File>
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</File>
</Group>
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<bDave2>0</bDave2>
<PathWithFileName>../Drivers/STM32F1xx_HAL_Driver/Src/stm32f1xx_hal_gpio_ex.c</PathWithFileName>
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Public/STM32_PID_电机.pdf Normal file
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/**
* @file app.h
* @author xushenghao
* @date 2024-08-09 09:03:08
* @brief
* @copyright Copyright (c) 2024 by xxx, All Rights Reserved.
*/
#ifndef APP_H
#define APP_H
#endif // APP_H

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User/board/board.c Normal file
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#include "board.h"
/**
* @brief
*
*
*/
void board_init(void)
{
// Initialize the board
}

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User/board/board.h Normal file
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/**
* @file board.h
* @author xushenghao
* @date 2024-08-09 09:02:54
* @brief
* @copyright Copyright (c) 2024 by xxx, All Rights Reserved.
*/
#ifndef BOARD_H
#define BOARD_H
#include "lib.h"
extern void board_init(void);
#endif // BOARD_H

38
User/lib/control/custom/pid_c.c Normal file
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#include "pid_c.h"
/**
* @brief PID控制器参数
* @param {PID_C} *self - PID控制器结构体指针
* @param {float32} kp -
* @param {float32} ki -
* @param {float32} kd -
* @param {float32} out_min -
* @param {float32} out_max -
* @return {*} -
*/
static void _set_ctrl_prm(struct PID_C *self, float32 kp, float32 ki, float32 kd, float32 out_min, float32 out_max)
{
self->pri.kp = kp; /*比例系数*/
self->pri.ki = ki; /*积分系数*/
self->pri.kd = kd; /*微分系数*/
self->pri.deadband = 0.5; /*死区*/
self->pri.maximum = out_max; /*最大输出*/
self->pri.minimum = out_min; /*最小输出*/
self->pri.last_error = 0; /*上一次误差*/
self->pri.prev_error = 0; /*上上次误差*/
}
static float32 _PID(struct PID_C *self, float32 target, float32 feedback)
{
/**
* PID算法
*/
return 0;
}
void pid_c_constructor(struct PID_C *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->PID = _PID;
}

34
User/lib/control/custom/pid_c.h Normal file
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#ifndef __PID_C_H__
#define __PID_C_H__
#include "lib.h"
typedef struct PID_C
{
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_C *self, float32 kp, float32 ki, float32 kd, float32 out_min, float32 out_max);
/* 控制接口 */
float32 (*PID)(struct PID_C *self, float32 target, float32 feedback);
// 自定义参数
/* 实际值与目标值之间的误差 */
float32 err;
/* 输出值 */
float32 out;
/* private */
struct
{
float32 kp; /*比例学习速度*/
float32 ki; /*积分学习速度*/
float32 kd; /*微分学习速度*/
float32 ki_error; /*积分误差*/
float32 last_error; /*前一拍偏差*/
float32 prev_error; /*前两拍偏差*/
float32 deadband; /*死区*/
float32 maximum; /*输出值的上限*/
float32 minimum; /*输出值的下限*/
} pri;
} pid_c_t;
extern void pid_c_constructor(struct PID_C *self);
#endif // __PID_C_H__

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#include "pid_g.h"
#include <math.h>
/**
* @brief PID积分及微分控制数据
* @param {PID_G} *self
* @return {*}
*/
static void _restctrl(struct PID_G *self)
{
self->pri.pre_error = 0;
self->pri.sum_iterm = 0;
}
/**
* @brief
* @param {PID_G} *self
* @param {float32} out_min
* @param {float32} out_max
* @return {*}
* @note
*/
static void _set_range(struct PID_G *self, float32 out_min, float32 out_max)
{
self->pri.out_max = out_max;
self->pri.out_min = out_min;
}
/**
* @brief kp
* @param {PID_G} *self
* @param {float32} kp
* @return {*}
* @note
*/
static void _set_kp(struct PID_G *self, float32 kp)
{
self->pri.kp = kp;
}
/**
* @brief ki
* @param {PID_G} *self
* @param {float32} ki
* @return {*}
* @note
*/
static void _set_ki(struct PID_G *self, float32 ki)
{
self->pri.ki = ki;
}
/**
* @brief kd
* @param {PID_G} *self
* @param {float32} kd
* @return {*}
* @note
*/
static void _set_kd(struct PID_G *self, float32 kd)
{
self->pri.kd = kd;
}
/**
* @brief 使
* @param {PID_G} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
static void _set_ki_enable(struct PID_G *self, BOOL enable)
{
self->pri.ki_enable = enable;
}
/**
* @brief 使
* @param {PID_G} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
static void _set_kd_enable(struct PID_G *self, BOOL enable)
{
self->pri.kd_enable = enable;
}
/**
* @brief
* @return {*}
* @note
*/
static void _set_ctrl_prm(struct PID_G *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 out_min, float32 out_max)
{
g_param_t *pri = &self->pri;
osel_memset((uint8_t *)pri, 0, sizeof(pid_g_t));
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
}
static void _update_ctrl_prm(struct PID_G *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 out_min, float32 out_max)
{
g_param_t *pri = &self->pri;
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
}
/**
* @brief 0+PID,PID
* @param {PID_G} *self
* @param {float32} max_err
* @param {BOOL} mode
* @return {*}
*/
static void _set_cfg(struct PID_G *self, float32 max_err, BOOL mode)
{
self->pri.err_limit = max_err;
self->pri.detach = mode == FALSE ? FALSE : TRUE;
}
/**
* @brief
* @param {PID_G} *self
* @param {float32} max_weight
* @return {*}
* @note
*/
static void _set_weight(struct PID_G *self, float32 max_ratio, BOOL mode)
{
self->pri.ui_ratio = max_ratio;
self->pri.weight = mode == FALSE ? FALSE : TRUE;
}
/**
* @brief PID算法函数
* @param {PID_G} *self
* @param {float32} target
* @param {float32} feedback
* @return {*}
* @note
*/
static float32 _PID(struct PID_G *self, float32 target, float32 feedback)
{
float32 error = 0.0f;
float32 insert = 0.0f; ///< 该值为0时积分不介入计算
float32 temp_iterm = 0.0f;
float32 temp_kd = 0.0f;
g_param_t *pri = &self->pri;
pri->ref = target; ///< 目标位置
pri->feed_back = feedback; ///< 实际位置
pri->error = pri->ref - pri->feed_back; /// 误差
error = pri->error;
if (fabs(pri->error) <= pri->err_dead) ///< 误差小于死区,不计算
{
error = 0;
}
/*根据PID配置的模式,获取积分数据,进行积分累加*/
if (pri->out >= pri->out_max) ///< 到达输出上限
{
if (fabs(error) > pri->err_limit && pri->detach) ///< 误差大于积分介入区间,积分不介入计算
{
insert = 0;
}
else
{
insert = 1;
if (error < 0)
{
temp_iterm = pri->ki * error;
}
}
}
else if (pri->out <= pri->out_min) ///< 到达输出下限
{
if (fabs(error) > pri->err_limit && pri->detach) ///< 误差大于积分介入区间,积分不介入计算
{
insert = 0;
}
else
{
insert = 1;
if (error > 0)
{
temp_iterm = pri->ki * error;
}
}
}
else
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
temp_iterm = pri->ki * error;
}
}
if (pri->ki_enable == FALSE)
{
temp_iterm = 0;
insert = 0;
}
/* integral */
pri->sum_iterm += temp_iterm;
if (pri->weight == TRUE)
{
if (pri->sum_iterm > pri->ui_ratio)
{
pri->sum_iterm = pri->ui_ratio;
}
else if (pri->sum_iterm < -pri->ui_ratio)
{
pri->sum_iterm = -pri->ui_ratio;
}
}
else
{
if (pri->sum_iterm > pri->out_max)
{
pri->sum_iterm = pri->out_max;
}
else if (pri->sum_iterm < pri->out_min)
{
pri->sum_iterm = pri->out_min;
}
}
/* differential */
if (pri->kd_enable == TRUE)
{
temp_kd = pri->kd;
}
else
{
temp_kd = 0;
}
pri->out = pri->kp * pri->error + pri->sum_iterm * insert + (pri->error - pri->pre_error) * temp_kd;
pri->pre_error = pri->error; ///< 记录这次误差,为下次微分计算做准备
pri->pre_feed_back = pri->feed_back;
/*limt pid output*/
pri->out = RANGE(pri->out, pri->out_min, pri->out_max); ///< 限制输出
return pri->out;
}
/**
* @brief PID接口
* @param {PID_G} *self
* @return {*}
* @note
*/
void pid_g_constructor(struct PID_G *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->update_ctrl_prm = _update_ctrl_prm;
self->set_cfg = _set_cfg;
self->set_kp = _set_kp;
self->set_ki_enable = _set_ki_enable;
self->set_ki = _set_ki;
self->set_kd_enable = _set_kd_enable;
self->set_kd = _set_kd;
self->set_range = _set_range;
self->restctrl = _restctrl;
self->PID = _PID;
self->set_weight = _set_weight;
}

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#ifndef __PID_G_H__
#define __PID_G_H__
#include "lib.h"
typedef struct
{
float32 ref; /*目标*/
float32 feed_back; /*实际*/
float32 pre_feed_back; /*上一次实际*/
float32 kp; /*比例学习速度*/
float32 ki; /*积分学习速度*/
float32 kd; /*微分学习速度*/
float32 ki_error; /*积分误差*/
float32 error; /*误差*/
float32 pre_error; /*前一拍偏差*/
float32 prev_error; /*前两拍偏差*/
float32 err_dead; /*死区*/
float32 err_limit; /*积分分离上限*/
float32 maximum; /*输出值的上限*/
float32 minimum; /*输出值的下限*/
float32 out; /*输出值*/
float32 sum_iterm; /*积分累加*/
float32 ui_ratio; /*积分权重*/
BOOL ki_enable; /*积分使能*/
BOOL kd_enable; /*微分使能*/
BOOL detach; /*积分分离标志*/
BOOL weight; /*积分权重标志*/
float32 out_max; /*输出最大值*/
float32 out_min; /*输出最小值*/
} g_param_t;
typedef struct PID_G
{
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_G *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 out_min, float32 out_max);
/* 更新PID参数 */
void (*update_ctrl_prm)(struct PID_G *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 out_min, float32 out_max);
/* 控制接口 */
float32 (*PID)(struct PID_G *self, float32 target, float32 feedback);
/* 更新控制区间 */
void (*set_range)(struct PID_G *self, float32 out_min, float32 out_max);
/* 设置积分分离 */
void (*set_cfg)(struct PID_G *self, float32 max_err, BOOL mode);
/* 设置积分权重 */
void (*set_weight)(struct PID_G *self, float32 max_ratio, BOOL mode);
/* 更新kp */
void (*set_kp)(struct PID_G *self, float32 kp);
/* 使能ki */
void (*set_ki_enable)(struct PID_G *self, BOOL enable);
/* 更新ki */
void (*set_ki)(struct PID_G *self, float32 ki);
/* 使能kd */
void (*set_kd_enable)(struct PID_G *self, BOOL enable);
/* 更新kd */
void (*set_kd)(struct PID_G *self, float32 kd);
/* 复位PID积分及微分控制数据 */
void (*restctrl)(struct PID_G *self);
/* private */
g_param_t pri;
} pid_g_t;
extern void pid_g_constructor(struct PID_G *self);
#endif // __PID_G_H__

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#include "pid_hd.h"
#include <math.h>
#include "sys.h"
#include "app.h"
#if INCOMPLETE_DIFFEREN_HD == 1 // 积分分离
/*计算微分项,使用追随误差微分项*/
static float32 td_derivative(struct PID_HD *self, float32 current_err, float32 pre_err, float32 dt)
{
pid_hd_position_t *pri = &self->pri_u.position;
float32 derivative = (current_err - pre_err) / dt; // 计算积分项
derivative = pri->td_alpha * derivative + (1 - pri->td_alpha) * pri->td_beta * pri->pre_derivative; // 追随误差微分器平滑输出
pri->pre_derivative = derivative; // 更新上一次误差
return derivative;
}
#endif
/*杭电设置位置式PID参数*/
static void _set_ctrl_prm_position(struct PID_HD *self, float32 kp, float32 ki, float32 kd)
{
pid_hd_position_t *pri = &self->pri_u.position;
osel_memset((uint8_t *)pri, 0, sizeof(pid_hd_position_t));
/*观测传进来的Kp、Ki、Kd*/
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->ki_limit = 10; // 积分分离界限
pri->err_dead = 0.5; // 控制死区范围
#if INCOMPLETE_DIFFEREN_HD == 1
/*不完全微分系数*/
pri->td_alpha = 0.5;
pri->td_beta = 0.5;
#endif
}
/*杭电:设置输出限幅参数*/
static void _set_out_prm_position(struct PID_HD *self, float32 maximum, float32 minimum)
{
self->pri_u.position.out_max = maximum;
self->pri_u.position.out_min = minimum;
}
/*杭电位置式PID控制算法*/
static float32 _pid_position(struct PID_HD *self, float32 err)
{
/*计算控制的运行时间*/
// sys_millis_reset();
self->pri_u.position.control_time = sys_millis();
self->pri_u.position.tmp_time = 0;
/*测试4.18*/
if (fabs(err) < 0.1)
{
err = 0;
}
float32 x[3];
self->pri_u.position.err = err;
/*抗积分饱和*/
#if INTEGRAL_SEPARATION == 1 // 积分分离
if (self->pri_u.position.out > self->pri_u.position.out_max)
{
if (self->pri_u.position.err > self->pri_u.position.ki_limit) // 积分分离
{
self->pri_u.position.ki_error += 0;
}
else
{
if (self->pri_u.position.err < 0) // 若偏差为负值,执行负偏差的累加
{
self->pri_u.position.ki_error += self->pri_u.position.err;
}
}
}
else if (self->pri_u.position.out < self->pri_u.position.out_min)
{
if (self->pri_u.position.err > self->pri_u.position.ki_limit) // 若偏差为负值,停止积分
{
self->pri_u.position.ki_error += 0;
}
else
{
if (self->pri_u.position.err > 0) // 若偏差为正值,执行正偏差的累加
{
self->pri_u.position.ki_error += self->pri_u.position.err;
}
}
}
else
{
if (fabs(err) > self->pri_u.position.ki_limit || fabs(err) < 0.5)
{
self->pri_u.position.ki_error += 0;
}
else
{
self->pri_u.position.ki_error += self->pri_u.position.err;
}
}
#else /*无积分分离操作*/
if (fabs(err) < 0.4)
{
self->pri_u.position.ki_error += 0;
}
else
{
self->pri_u.position.ki_error += self->pri_u.position.err;
}
#endif
/*输出*/
if (fabs(err) < self->pri_u.position.err_dead)
{
/*输出上一次的值*/
// self->pri_u.position.out = self->pri_u.position.pre_out;
x[0] = self->pri_u.position.err;
x[1] = self->pri_u.position.ki_error;
self->pri_u.position.out = self->pri_u.position.kp * x[0] + self->pri_u.position.ki * x[1] + self->pri_u.position.kd * x[2];
}
else
{
x[0] = self->pri_u.position.err;
x[1] = self->pri_u.position.ki_error;
#if INCOMPLETE_DIFFEREN_HD == 1
/*不完全微分项为了解决普通PID为微分环节容易振荡的问题*/
self->pri_u.position.tmp_time = sys_millis();
self->pri_u.position.control_time -= self->pri_u.position.tmp_time;
self->pri_u.position.control_time /= 1000.0; // 将单位转换为秒
x[2] = td_derivative(&_pid.pid_u.hd, err, self->pri_u.position.pre_error, self->pri_u.position.control_time);
#else
// 普通的微分环节
x[2] = self->pri_u.position.err - self->pri_u.position.pre_error;
#endif
self->pri_u.position.out = self->pri_u.position.kp * x[0] + self->pri_u.position.ki * x[1] + self->pri_u.position.kd * x[2];
}
/*输出限幅*/
if (self->pri_u.position.out > self->pri_u.position.out_max)
{
self->pri_u.position.out = self->pri_u.position.out_max;
}
if (self->pri_u.position.out < self->pri_u.position.out_min)
{
self->pri_u.position.out = self->pri_u.position.out_min;
}
// 更新误差历史
self->pri_u.position.pre_error = self->pri_u.position.err; /*上一次误差值*/
// 更新输出历史
self->pri_u.position.pre_out = self->pri_u.position.out; /*上一次输出值*/
return self->pri_u.position.out;
}
/*杭电:参数控制器*/
void pid_hd_constructor(struct PID_HD *self)
{
self->set_ctrl_prm_position = _set_ctrl_prm_position;
self->set_out_prm_position = _set_out_prm_position;
self->pid_position = _pid_position;
}

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#ifndef __PID_HD__
#define __PID_HD__
#include "lib.h"
#define INTEGRAL_SEPARATION 1 // 积分分离
#define INCOMPLETE_DIFFEREN_HD 1 // 不完全微分
typedef struct
{
float32 ref;
float32 feed_back;
float32 pre_feed_back;
float32 pre_error;
float32 ki_error; /*积分误差*/
float32 ki_limit; /*积分分离界限*/
float32 ki_alpha; /*变积分的系数*/
float32 err;
float32 sum_iterm;
float32 kp;
float32 kp_small; /*在接近稳态时的Kp*/
float32 kp_big; /*在大范围时的Kp*/
float32 ki;
float32 kd;
float32 err_limit;
BOOL detach;
float32 err_dead;
#if INCOMPLETE_DIFFEREN_HD == 1
float32 td_alpha; /*不完全微分系数*/
float32 td_beta; /*不完全微分系数beta*/
float32 pre_derivative; /*上一次微分值*/
#endif
float32 out;
float32 pre_out;
float32 out_max;
float32 out_min;
BOOL sm;
float32 sv_range;
uint32_t control_time; /*控制算法运行一次花费的时间*/
uint32_t tmp_time; /*临时用来记录控制的运行时间*/
} pid_hd_position_t; // 位置式PID
typedef struct PID_HD
{
/* 设置PID三个参数 */
void (*set_ctrl_prm_position)(struct PID_HD *self, float32 kp, float32 ki, float32 kd);
/* 设置输出范围 */
void (*set_out_prm_position)(struct PID_HD *self, float32 maximum, float32 minimum);
/* 控制接口 */
float32 (*pid_position)(struct PID_HD *self, float32 err);
// 自定义参数
/* 实际值与目标值之间的误差 */
float32 err;
/* 输出值 */
float32 out;
/* private */
struct
{
pid_hd_position_t position;
} pri_u;
} pid_hd_t;
extern void pid_hd_constructor(struct PID_HD *self);
#endif // __PID_HD__

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#include "pid_x.h"
#include "math.h"
#define LAG_PHASE (6) // 迟滞相位,单位:拍
#ifndef PI
#define PI 3.14159265358979f
#endif
// 注1自适应模糊pid最重要的就是论域的选择要和你应该控制的对象相切合
// 注2以下各阀值、限幅值、输出值均需要根据具体的使用情况进行更改
// 注3因为我的控制对象惯性比较大所以以下各部分取值较小
// 论域e:[-5,5] ec:[-0.5,0.5]
// 误差的阀值小于这个数值的时候不做PID调整避免误差较小时频繁调节引起震荡
#define Emin 0.3f
#define Emid 1.0f
#define Emax 5.0f
// 调整值限幅,防止积分饱和
#define Umax 1
#define Umin -1
#define NB 0
#define NM 1
#define NS 2
#define ZO 3
#define PS 4
#define PM 5
#define PB 6
int32_t kp[7][7] = {{PB, PB, PM, PM, PS, ZO, ZO},
{PB, PB, PM, PS, PS, ZO, ZO},
{PM, PM, PM, PS, ZO, NS, NS},
{PM, PM, PS, ZO, NS, NM, NM},
{PS, PS, ZO, NS, NS, NM, NM},
{PS, ZO, NS, NM, NM, NM, NB},
{ZO, ZO, NM, NM, NM, NB, NB}};
int32_t kd[7][7] = {{PS, NS, NB, NB, NB, NM, PS},
{PS, NS, NB, NM, NM, NS, ZO},
{ZO, NS, NM, NM, NS, NS, ZO},
{ZO, NS, NS, NS, NS, NS, ZO},
{ZO, ZO, ZO, ZO, ZO, ZO, ZO},
{PB, NS, PS, PS, PS, PS, PB},
{PB, PM, PM, PM, PS, PS, PB}};
int32_t ki[7][7] = {{NB, NB, NM, NM, NS, ZO, ZO},
{NB, NB, NM, NS, NS, ZO, ZO},
{NB, NM, NS, NS, ZO, PS, PS},
{NM, NM, NS, ZO, PS, PM, PM},
{NM, NS, ZO, PS, PS, PM, PB},
{ZO, ZO, PS, PS, PM, PB, PB},
{ZO, ZO, PS, PM, PM, PB, PB}};
static float32 ec; // 误差变化率
/**************求隶属度(三角形)***************/
float32 FTri(float32 x, float32 a, float32 b, float32 c) // FuzzyTriangle
{
if (x <= a)
return 0;
else if ((a < x) && (x <= b))
return (x - a) / (b - a);
else if ((b < x) && (x <= c))
return (c - x) / (c - b);
else if (x > c)
return 0;
else
return 0;
}
/*****************求隶属度(梯形左)*******************/
float32 FTraL(float32 x, float32 a, float32 b) // FuzzyTrapezoidLeft
{
if (x <= a)
return 1;
else if ((a < x) && (x <= b))
return (b - x) / (b - a);
else if (x > b)
return 0;
else
return 0;
}
/*****************求隶属度(梯形右)*******************/
float32 FTraR(float32 x, float32 a, float32 b) // FuzzyTrapezoidRight
{
if (x <= a)
return 0;
if ((a < x) && (x < b))
return (x - a) / (b - a);
if (x >= b)
return 1;
else
return 1;
}
/****************三角形反模糊化处理**********************/
float32 uFTri(float32 x, float32 a, float32 b, float32 c)
{
float32 y, z;
z = (b - a) * x + a;
y = c - (c - b) * x;
return (y + z) / 2;
}
/*******************梯形(左)反模糊化***********************/
float32 uFTraL(float32 x, float32 a, float32 b)
{
return b - (b - a) * x;
}
/*******************梯形(右)反模糊化***********************/
float32 uFTraR(float32 x, float32 a, float32 b)
{
return (b - a) * x + a;
}
/**************************求交集****************************/
float32 fand(float32 a, float32 b)
{
return (a < b) ? a : b;
}
/**************************求并集****************************/
float32 forr(float32 a, float32 b)
{
return (a < b) ? b : a;
}
static float32 _PID(struct PID_X *self, float32 target, float32 feedback)
{
float32 pwm_var; // pwm调整量
float32 iError; // 当前误差
float32 set, input;
CLASSICPID *pri = &self->pri;
// 计算隶属度表
float32 es[7], ecs[7], e;
float32 form[7][7];
int i = 0, j = 0;
int MaxX = 0, MaxY = 0;
// 记录隶属度最大项及相应推理表的p、i、d值
float32 lsd;
int temp_p, temp_d, temp_i;
float32 detkp, detkd, detki; // 推理后的结果
// 输入格式的转化及偏差计算
set = target;
input = feedback;
iError = set - input; // 偏差
e = iError;
ec = iError - pri->lasterror;
// 当温度差的绝对值小于Emax时对pid的参数进行调整
if (fabs(iError) <= Emax)
{
// 计算iError在es与ecs中各项的隶属度
es[NB] = FTraL(e * 5, -3, -1); // e
es[NM] = FTri(e * 5, -3, -2, 0);
es[NS] = FTri(e * 5, -3, -1, 1);
es[ZO] = FTri(e * 5, -2, 0, 2);
es[PS] = FTri(e * 5, -1, 1, 3);
es[PM] = FTri(e * 5, 0, 2, 3);
es[PB] = FTraR(e * 5, 1, 3);
ecs[NB] = FTraL(ec * 30, -3, -1); // ec
ecs[NM] = FTri(ec * 30, -3, -2, 0);
ecs[NS] = FTri(ec * 30, -3, -1, 1);
ecs[ZO] = FTri(ec * 30, -2, 0, 2);
ecs[PS] = FTri(ec * 30, -1, 1, 3);
ecs[PM] = FTri(ec * 30, 0, 2, 3);
ecs[PB] = FTraR(ec * 30, 1, 3);
// 计算隶属度表确定e和ec相关联后表格各项隶属度的值
for (i = 0; i < 7; i++)
{
for (j = 0; j < 7; j++)
{
form[i][j] = fand(es[i], ecs[j]);
}
}
// 取出具有最大隶属度的那一项
for (i = 0; i < 7; i++)
{
for (j = 0; j < 7; j++)
{
if (form[MaxX][MaxY] < form[i][j])
{
MaxX = i;
MaxY = j;
}
}
}
// 进行模糊推理,并去模糊
lsd = form[MaxX][MaxY];
temp_p = kp[MaxX][MaxY];
temp_d = kd[MaxX][MaxY];
temp_i = ki[MaxX][MaxY];
if (temp_p == NB)
detkp = uFTraL(lsd, -0.3, -0.1);
else if (temp_p == NM)
detkp = uFTri(lsd, -0.3, -0.2, 0);
else if (temp_p == NS)
detkp = uFTri(lsd, -0.3, -0.1, 0.1);
else if (temp_p == ZO)
detkp = uFTri(lsd, -0.2, 0, 0.2);
else if (temp_p == PS)
detkp = uFTri(lsd, -0.1, 0.1, 0.3);
else if (temp_p == PM)
detkp = uFTri(lsd, 0, 0.2, 0.3);
else if (temp_p == PB)
detkp = uFTraR(lsd, 0.1, 0.3);
if (temp_d == NB)
detkd = uFTraL(lsd, -3, -1);
else if (temp_d == NM)
detkd = uFTri(lsd, -3, -2, 0);
else if (temp_d == NS)
detkd = uFTri(lsd, -3, 1, 1);
else if (temp_d == ZO)
detkd = uFTri(lsd, -2, 0, 2);
else if (temp_d == PS)
detkd = uFTri(lsd, -1, 1, 3);
else if (temp_d == PM)
detkd = uFTri(lsd, 0, 2, 3);
else if (temp_d == PB)
detkd = uFTraR(lsd, 1, 3);
if (temp_i == NB)
detki = uFTraL(lsd, -0.06, -0.02);
else if (temp_i == NM)
detki = uFTri(lsd, -0.06, -0.04, 0);
else if (temp_i == NS)
detki = uFTri(lsd, -0.06, -0.02, 0.02);
else if (temp_i == ZO)
detki = uFTri(lsd, -0.04, 0, 0.04);
else if (temp_i == PS)
detki = uFTri(lsd, -0.02, 0.02, 0.06);
else if (temp_i == PM)
detki = uFTri(lsd, 0, 0.04, 0.06);
else if (temp_i == PB)
detki = uFTraR(lsd, 0.02, 0.06);
// pid三项系数的修改
pri->pKp += detkp;
pri->pKi += detki;
if (pri->kd_e)
{
pri->pKd += detkd;
}
else
{
pri->pKd = 0; // 取消微分作用
}
// 对Kp,Ki进行限幅
if (pri->pKp < 0)
{
pri->pKp = 0;
}
if (pri->pKi < 0)
{
pri->pKi = 0;
}
// 计算新的K1,nKi,nKd
pri->nKp = pri->pKp + pri->pKi + pri->pKd;
pri->nKi = -(pri->pKp + 2 * pri->pKd);
pri->nKd = pri->pKd;
}
if (iError > Emax)
{
pri->out = pri->max;
pwm_var = 0;
pri->flag = 1; // 设定标志位,如果误差超过了门限值,则认为当控制量第一次到达给定值时,应该采取下面的 抑制超调 的措施
}
else if (iError < -Emax)
{
pri->out = pri->min;
pwm_var = 0;
}
else if (fabsf(iError) <= Emin)
{
pwm_var = 0;
}
else
{
if (iError < Emid && pri->flag == 1) // 第一次超过(设定值-Emid(-0.08)摄氏度),是输出为零,防止超调,也可以输出其他值,不至于太小而引起震荡
{
pri->out = 0;
pri->flag = 0;
}
else if (-iError > Emid) // 超过(设定+Emid(+0.08)摄氏度)
{
pwm_var = -1;
}
else
{
// 增量计算
pwm_var = (pri->nKp * iError // e[k]
+ pri->nKi * pri->lasterror // e[k-1]
+ pri->nKd * pri->preverror); // e[k-2]
}
if (pwm_var >= Umax)
pwm_var = Umax; // 调整值限幅,防止积分饱和
if (pwm_var <= Umin)
pwm_var = Umin; // 调整值限幅,防止积分饱和
}
pri->preverror = pri->lasterror;
pri->lasterror = iError;
pri->out += pwm_var; // 调整PWM输出
if (pri->out > pri->max)
pri->out = pri->max; // 输出值限幅
if (pri->out < pri->min)
pri->out = pri->min; // 输出值限幅
return pri->out;
}
/*整定开始前的预处理,判断状态及初始化变量*/
static void tune_pretreatment(struct PID_X *self)
{
CLASSIC_AUTOTUNE *tune = &self->tune;
CLASSICPID *vPID = &self->pri;
tune->tuneTimer = 0;
tune->startTime = 0;
tune->endTime = 0;
tune->outputStep = 100;
if (*vPID->pSV >= *vPID->pPV)
{
tune->initialStatus = 1;
tune->outputStatus = 0;
}
else
{
tune->initialStatus = 0;
tune->outputStatus = 1;
}
tune->tuneEnable = 1;
tune->preEnable = 0;
tune->zeroAcrossCounter = 0;
tune->riseLagCounter = 0;
tune->fallLagCounter = 0;
}
/*计算PID参数值*/
static void calculation_parameters(struct PID_X *self)
{
CLASSIC_AUTOTUNE *tune = &self->tune;
CLASSICPID *vPID = &self->pri;
float32 kc = 0.0f;
float32 tc = 0.0f;
float32 zn[3][3] = {{0.5f, 100000.0f, 0.0f}, {0.45f, 0.8f, 0.0f}, {0.6f, 0.5f, 0.125f}};
tc = (tune->endTime - tune->startTime) * tune->tunePeriod / 1000.0;
kc = (8.0f * tune->outputStep) / (PI * (tune->maxPV - tune->minPV));
vPID->pKp = zn[tune->controllerType][0] * kc; // 比例系数
vPID->pKi = vPID->pKp * tune->tunePeriod / (zn[tune->controllerType][1] * tc); // 积分系数
vPID->pKd = vPID->pKp * zn[tune->controllerType][2] * tc / tune->tunePeriod; // 微分系数
}
/**
* @brief
* @param {PID_X} *self
* @return {*}
* @note tuneEnablepreEnable和controllerType需要提前赋值tuneEnable变量值为0时是使用PID控制器tuneEnable变量值为1时是开启整定过程tuneEnable变量值为2时是指示整定失败preEnable变量在整定前赋值为1controllerType则根据所整定的控制器的类型来定
*/
static uint8_t _auto_tune(struct PID_X *self)
{
CLASSIC_AUTOTUNE *tune = &self->tune;
CLASSICPID *vPID = &self->pri;
/*整定开始前的预处理,只执行一次*/
if (tune->preEnable == 1)
{
tune_pretreatment(self);
}
uint32_t tuneDuration = 0;
tune->tuneTimer++;
tuneDuration = (tune->tuneTimer * tune->tunePeriod) / 1000;
if (tuneDuration > (10 * 60)) // 整定过程持续超过10分钟未能形成有效振荡整定失败
{
tune->tuneEnable = 2;
tune->preEnable = 1;
return tune->tuneEnable;
}
if (*vPID->pSV >= *vPID->pPV) // 设定值大于测量值,则开执行单元
{
tune->riseLagCounter++;
tune->fallLagCounter = 0;
if (tune->riseLagCounter > LAG_PHASE)
{
*vPID->pMV = vPID->max;
if (tune->outputStatus == 0)
{
tune->outputStatus = 1;
tune->zeroAcrossCounter++;
if (tune->zeroAcrossCounter == 3)
{
tune->startTime = tune->tuneTimer;
}
}
}
}
else
{
tune->riseLagCounter = 0;
tune->fallLagCounter++;
if (tune->fallLagCounter > LAG_PHASE)
{
*vPID->pMV = vPID->min;
if (tune->outputStatus == 1)
{
tune->outputStatus = 0;
tune->zeroAcrossCounter++;
if (tune->zeroAcrossCounter == 3)
{
tune->startTime = tune->tuneTimer;
}
}
}
}
if (tune->zeroAcrossCounter == 3) // 已经两次过零,可以记录波形数据
{
if (tune->initialStatus == 1) // 初始设定值大于测量值则区域3出现最小值
{
if (*vPID->pPV < tune->minPV)
{
tune->minPV = *vPID->pPV;
}
}
else if (tune->initialStatus == 0) // 初始设定值小于测量值则区域3出现最大值
{
if (*vPID->pPV > tune->maxPV)
{
tune->maxPV = *vPID->pPV;
}
}
}
else if (tune->zeroAcrossCounter == 4) // 已经三次过零,记录另半波的数据
{
if (tune->initialStatus == 1) // 初始设定值大于测量值则区域4出现最大值
{
if (*vPID->pPV > tune->maxPV)
{
tune->maxPV = *vPID->pPV;
}
}
else if (tune->initialStatus == 0) // 初始设定值小于测量值则区域4出现最小值
{
if (*vPID->pPV < tune->minPV)
{
tune->minPV = *vPID->pPV;
}
}
}
else if (tune->zeroAcrossCounter == 5) // 已经四次过零,振荡已形成可以整定参数
{
calculation_parameters(self);
tune->tuneEnable = 0;
tune->preEnable = 1;
}
return tune->tuneEnable;
}
void pid_x_constructor(struct PID_X *self)
{
self->PID = _PID;
self->AUTO_TUNE = _auto_tune;
self->pri.flag = 0;
self->pri.out = 0;
self->tune.preEnable = 1;
}

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#ifndef __PID_X_H__
#define __PID_X_H__
#include "lib.h"
/*定义PID对象类型*/
typedef struct CLASSIC
{
float32 *pPV; // 测量值指针
float32 *pSV; // 设定值指针
float32 *pMV; // 输出值指针
BOOL *pMA; // 手自动操作指针
float32 out; // 输出值
float32 setpoint; // 设定值
float32 lasterror; // 前一拍偏差
float32 preverror; // 前两拍偏差
float32 max; // 输出值上限
float32 min; // 输出值下限
uint16_t flag; // 状态标志位
float32 pKp; // 比例系数
float32 pKi; // 积分系数
float32 pKd; // 微分系数
float32 nKp; // 比例系数
float32 nKi; // 积分系数
float32 nKd; // 微分系数
BOOL direct; // 正反作用
BOOL sm; // 设定值平滑
BOOL cas; // 串级设定
BOOL pac; // 输出防陡变
BOOL kd_e; // 微分使能
} CLASSICPID;
// 定义整定参数
typedef struct
{
uint8_t tuneEnable : 2; // 整定与PID控制开关0PID控制1参数整定2整定失败
uint8_t preEnable : 2; // 预处理使能,在开始整定前置位
uint8_t initialStatus : 1; // 记录开始整定前偏差的初始状态
uint8_t outputStatus : 1; // 记录输出的初始状态0允许上升过零计数1允许下降过零计数
uint8_t controllerType : 2; // 控制器类型0P控制器1PI控制器2PID控制器
uint8_t zeroAcrossCounter; // 过零点计数器每次输出改变加1比实际过零次数多1
uint8_t riseLagCounter; // 上升迟滞时间计数器
uint8_t fallLagCounter; // 下降迟滞时间计数器
uint16_t tunePeriod; // 整定采样周期
uint32_t tuneTimer; // 整定计时器
uint32_t startTime; // 记录波形周期起始时间
uint32_t endTime; // 记录波形周期结束时间
float32 outputStep; // 输出阶跃d
float32 maxPV; // 振荡波形中测量值的最大值
float32 minPV; // 振荡波形中测量值的最小值
} CLASSIC_AUTOTUNE;
typedef struct PID_X
{
/* 控制接口 */
float32 (*PID)(struct PID_X *self, float32 target, float32 feedback);
uint8_t (*AUTO_TUNE)(struct PID_X *self);
/* private */
CLASSICPID pri;
CLASSIC_AUTOTUNE tune;
} pid_x_t;
extern void pid_x_constructor(struct PID_X *self);
#endif // __PID_X_H__

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#include "pid_zh.h"
#include "sys.h"
#include <math.h>
// 定义输出量比例因子
#ifdef GPS3000
#define KUP 0.0f // #define KUP 3.0f
#define KUI 0.00f
#define KUD 0.0f // #define KUP 3.0f
#else
#define KUP 3.0f
#define KUI 0.0f
#define KUD 0.0f
#endif
// 模糊集合
#define NL -3
#define NM -2
#define NS -1
#define ZE 0
#define PS 1
#define PM 2
#define PL 3
// 定义偏差E的范围因为设置了非线性区间误差在10时才开始进行PID调节这里E的范围为10
#define MAXE (10)
#define MINE (-MAXE)
// 定义EC的范围因为变化非常缓慢每次的EC都非常小这里可以根据实际需求来调整
#define MAXEC (10)
#define MINEC (-MAXEC)
// 定义e,ec的量化因子
#define KE 3 / MAXE
#define KEC 3 / MAXEC
static const float32 fuzzyRuleKp[7][7] = {
PL, PL, PM, PL, PS, PM, PL,
PL, PM, PM, PM, PS, PM, PL,
PM, PS, PS, PS, PS, PS, PM,
PM, PS, ZE, ZE, ZE, PS, PM,
PS, PS, PS, PS, PS, PM, PM,
PM, PM, PM, PM, PL, PL, PL,
PM, PL, PL, PL, PL, PL, PL};
static const float32 fuzzyRuleKi[7][7] = {
PL, PL, PL, PL, PM, PL, PL,
PL, PL, PM, PM, PM, PL, PL,
PM, PM, PS, PS, PS, PM, PM,
PM, PS, ZE, ZE, ZE, PS, PM,
PM, PS, PS, PS, PS, PM, PM,
PM, PM, PS, PM, PM, PL, PL,
PM, PL, PM, PL, PL, PL, PL};
/*
static const float32 fuzzyRuleKi[7][7] = {
NL, NL, NL, NL, NM, NL, NL,
NL, NL, NM, NM, NM, NL, NL,
NM, NM, NS, NS, NS, NM, NM,
NM, NS, ZE, ZE, ZE, NS, NM,
NM, NS, NS, NS, NS, NM, NM,
NM, NM, NS, NM, NM, NL, NL,
NM, NL, NM, NL, NL, NL, NL};
*/
static const float32 fuzzyRuleKd[7][7] = {
PS, PS, ZE, ZE, ZE, PL, PL,
PS, PS, PS, PS, ZE, PS, PM,
PL, PL, PM, PS, ZE, PS, PM,
PL, PM, PM, PS, ZE, PS, PM,
PL, PM, PS, PS, ZE, PS, PS,
PM, PS, PS, PS, ZE, PS, PS,
PS, ZE, ZE, ZE, ZE, PL, PL};
/*
static const float32 fuzzyRuleKp[7][7] = {
PL, PL, PM, PM, PS, ZE, ZE,
PL, PL, PM, PS, PS, ZE, NS,
PM, PM, PM, PS, ZE, NS, NS,
PM, PM, PS, ZE, NS, NM, NM,
PS, PS, ZE, NS, NS, NM, NM,
PS, ZE, NS, NM, NM, NM, NL,
ZE, ZE, NM, NM, NM, NL, NL};
static const float32 fuzzyRuleKi[7][7] = {
NL, NL, NM, NM, NS, ZE, ZE,
NL, NL, NM, NS, NS, ZE, ZE,
NL, NM, NS, NS, ZE, PS, PS,
NM, NM, NS, ZE, PS, PM, PM,
NM, NS, ZE, PS, PS, NM, PL,
ZE, ZE, PS, PS, PM, PL, PL,
ZE, ZE, PS, PM, PM, PL, PL};
static const float32 fuzzyRuleKd[7][7] = {
PS, NS, NL, NL, NL, NM, PS,
PS, NS, NL, NM, NM, NS, ZE,
ZE, NS, NM, NM, NS, NS, ZE,
ZE, NS, NS, NS, NS, NS, ZE,
ZE, ZE, ZE, ZE, ZE, ZE, ZE,
PL, NS, PS, PS, PS, PS, PL,
PL, PM, PM, PM, PS, PS, PL};
*/
static void fuzzy(float32 e, float32 ec, FUZZY_PID_ZH_t *fuzzy_pid)
{
float32 etemp, ectemp;
float32 eLefttemp, ecLefttemp; // ec,e左隶属度
float32 eRighttemp, ecRighttemp;
int eLeftIndex, ecLeftIndex; // 模糊位置标号
int eRightIndex, ecRightIndex;
e = RANGE(e, MINE, MAXE);
ec = RANGE(ec, MINEC, MAXEC);
e = e * KE;
ec = ec * KEC;
etemp = e > 3.0f ? 0.0f : (e < -3.0f ? 0.0f : (e >= 0.0f ? (e >= 2.0f ? 2.5f : (e >= 1.0f ? 1.5f : 0.5f)) : (e >= -1.0f ? -0.5f : (e >= -2.0f ? -1.5f : (e >= -3.0f ? -2.5f : 0.0f)))));
eLeftIndex = (int)((etemp - 0.5f) + 3); //[-3,2] -> [0,5]
eRightIndex = (int)((etemp + 0.5f) + 3);
eLefttemp = etemp == 0.0f ? 0.0f : ((etemp + 0.5f) - e);
eRighttemp = etemp == 0.0f ? 0.0f : (e - (etemp - 0.5f));
ectemp = ec > 3.0f ? 0.0f : (ec < -3.0f ? 0.0f : (ec >= 0.0f ? (ec >= 2.0f ? 2.5f : (ec >= 1.0f ? 1.5f : 0.5f)) : (ec >= -1.0f ? -0.5f : (ec >= -2.0f ? -1.5f : (ec >= -3.0f ? -2.5f : 0.0f)))));
ecLeftIndex = (int)((ectemp - 0.5f) + 3); //[-3,2] -> [0,5]
ecRightIndex = (int)((ectemp + 0.5f) + 3);
ecLefttemp = ectemp == 0.0f ? 0.0f : ((ectemp + 0.5f) - ec);
ecRighttemp = ectemp == 0.0f ? 0.0f : (ec - (ectemp - 0.5f));
/*************************************反模糊*************************************/
fuzzy_pid->kp = (eLefttemp * ecLefttemp * fuzzyRuleKp[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKp[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKp[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKp[eRightIndex][ecRightIndex]);
fuzzy_pid->ki = (eLefttemp * ecLefttemp * fuzzyRuleKi[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKi[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKi[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKi[eRightIndex][ecRightIndex]);
fuzzy_pid->kd = (eLefttemp * ecLefttemp * fuzzyRuleKd[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKd[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKd[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKd[eRightIndex][ecRightIndex]);
// 对解算出的KP,KI,KD进行量化映射
fuzzy_pid->kp = fuzzy_pid->kp * fuzzy_pid->kup;
fuzzy_pid->ki = fuzzy_pid->ki * fuzzy_pid->kui;
fuzzy_pid->kd = fuzzy_pid->kd * fuzzy_pid->kud;
}
static void smoothSetpoint(struct PID_FUZZY_ZH *self, float32 target_sv)
{
#if FUZZY_SUB_TYPE == PID_SUB_TYPE_POSITION
pid_zh_position_t *pri = &self->pri;
#else
pid_common_increment_t *pri = &self->pri;
#endif
float32 stepIn = (pri->sv_range) * 0.1f;
float32 kFactor = 0.0f;
if (fabs(pri->ref - target_sv) <= stepIn)
{
pri->ref = target_sv;
}
else
{
if (pri->ref - target_sv > 0)
{
kFactor = -1.0f;
}
else if (pri->ref - target_sv < 0)
{
kFactor = 1.0f;
}
else
{
kFactor = 0.0f;
}
pri->ref = pri->ref + kFactor * stepIn;
}
}
/*封装模糊接口*/
static void compensate(float32 e, float32 ec, FUZZY_PID_ZH_t *fuzzy_d)
{
fuzzy(e, ec, fuzzy_d);
}
/**
* @brief PID积分及微分控制数据
* @param {PID_FUZZY_ZH} *self
* @return {*}
*/
static void _restctrl(struct PID_FUZZY_ZH *self)
{
self->pri.pre_error = 0;
self->pri.sum_iterm = 0;
#if INCOMPLETE_DIFFEREN == 1
self->pri.lastdev = 0;
#endif
}
/**
* @brief
* @param {PID_FUZZY_ZH} *self
* @param {float32} out_min
* @param {float32} out_max
* @return {*}
* @note
*/
static void _set_range(struct PID_FUZZY_ZH *self, float32 out_min, float32 out_max)
{
self->pri.out_max = out_max;
self->pri.out_min = out_min;
}
/**
* @brief 使
* @param {PID_FUZZY_ZH} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
// static void _set_ki_enable(struct PID_FUZZY_ZH *self, BOOL enable)
// {
// self->pri.ki_enable = enable;
// }
/**
* @brief 使
* @param {PID_FUZZY_ZH} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
static void _set_kd_enable(struct PID_FUZZY_ZH *self, BOOL enable)
{
self->pri.kd_enable = enable;
}
/*
* Function:使
* parameter:*pid需要配PID参数结构指针sv_range控制范围sv的范围
* return:
*/
static void _set_smooth_enable(struct PID_FUZZY_ZH *self, BOOL enable, float32 sv_range)
{
#if FUZZY_SUB_TYPE == PID_SUB_TYPE_POSITION
pid_zh_position_t *pri = &self->pri;
#else
pid_common_increment_t *pri = &self->pri;
#endif
pri->sm = enable;
pri->sv_range = sv_range;
}
// 设置控制参数
static void _set_ctrl_prm(struct PID_FUZZY_ZH *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max)
{
self->open = TRUE;
self->fuzzy.kup = KUP;
self->fuzzy.kui = KUI;
self->fuzzy.kud = KUD;
#if FUZZY_SUB_TYPE == PID_SUB_TYPE_POSITION
pid_zh_position_t *pri = &self->pri;
osel_memset((uint8_t *)pri, 0, sizeof(pid_zh_position_t));
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
pri->sm = FALSE;
#else
pid_common_increment_t *pri = &self->pri;
osel_memset((uint8_t *)pri, 0, sizeof(pid_common_increment_t));
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
#endif
if (kd > 0)
{
pri->kd_enable = TRUE;
}
else
{
pri->kd_enable = FALSE;
}
}
static void _update_ctrl_prm(struct PID_FUZZY_ZH *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max)
{
#if FUZZY_SUB_TYPE == PID_SUB_TYPE_POSITION
pid_zh_position_t *pri = &self->pri;
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
pri->sm = FALSE;
#else
pid_common_increment_t *pri = &self->pri;
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
#endif
if (kd > 0)
{
pri->kd_enable = TRUE;
}
else
{
pri->kd_enable = FALSE;
}
}
/**
* @brief 0+PID,PID
* @param {PID_FUZZY_ZH} *self
* @param {float32} max_err
* @param {BOOL} mode
* @return {*}
*/
static void _set_cfg(struct PID_FUZZY_ZH *self, float32 max_err, BOOL mode)
{
self->pri.err_limit = max_err;
self->pri.detach = mode == FALSE ? FALSE : TRUE;
}
#if FUZZY_SUB_TYPE == PID_SUB_TYPE_POSITION
static float32 _PID(struct PID_FUZZY_ZH *self, float32 target, float32 feedback)
{
float32 error = 0;
float32 insert = 0;
float32 ec = 0;
float32 kd = 0;
#if INCOMPLETE_DIFFEREN == 1
float32 thisdev = 0;
#else
// float32 dinput = 0.0f;
#endif
float32 temp_iterm = 0.0f;
pid_zh_position_t *pri = &self->pri;
/*获取期望值与实际值,进行偏差计算*/
if (pri->sm == 1)
{
smoothSetpoint(self, target);
}
else
{
pri->ref = target;
}
pri->feed_back = feedback;
error = pri->ref - pri->feed_back;
if (fabs(error) <= pri->err_dead)
error = 0;
/* fuzzy control caculate */
ec = error - pri->pre_error;
if (self->open == TRUE)
{
compensate(error, ec, &self->fuzzy);
}
/*根据PID配置的模式,获取积分数据,进行积分累加*/
if (pri->out >= pri->out_max)
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
if (error < 0)
{
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
}
else if (pri->out <= pri->out_min)
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
if (error > 0)
{
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
}
else
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
pri->sum_iterm += temp_iterm;
/* limt integral */
pri->sum_iterm = RANGE(pri->sum_iterm, pri->out_min, pri->out_max);
/*
if (pri->sum_ref)
pri->sum_iterm = RANGE(pri->sum_iterm, pri->sum_ref - 1.0f, pri->sum_ref + 1.0f);
else
pri->sum_iterm = RANGE(pri->sum_iterm, pri->out_min, pri->out_max);
*/
#if INCOMPLETE_DIFFEREN == 1
/*不完全微分*/
thisdev = (pri->kd + self->fuzzy.kd) * (1.0 - pri->alpha) * (error - pri->pre_error) + pri->alpha * pri->lastdev;
/*caculate pid out*/
pri->out = (pri->kp + self->fuzzy.kp) * error + pri->sum_iterm * insert + thisdev;
/*record last dev result*/
pri->lastdev = thisdev;
#else
if (pri->kd_enable == TRUE)
{
kd = pri->kd + self->fuzzy.kd;
}
else
{
kd = 0;
}
pri->out = (pri->kp + self->fuzzy.kp) * error + pri->sum_iterm * insert + (error - pri->pre_error) * (kd);
// pri->out += pri->sum_ref;
#endif
pri->pre_error = error;
/*record last feedback sensor result*/
pri->pre_feed_back = pri->feed_back;
/*limt pid output*/
pri->out = RANGE(pri->out, pri->out_min, pri->out_max);
return pri->out;
}
#else
#endif
void pid_zh_constructor(struct PID_FUZZY_ZH *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->update_ctrl_prm = _update_ctrl_prm;
self->set_cfg = _set_cfg;
self->set_smooth_enable = _set_smooth_enable;
// self->set_ki_enable = _set_ki_enable;
self->set_kd_enable = _set_kd_enable;
self->set_range = _set_range;
self->restctrl = _restctrl;
self->PID = _PID;
}

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#ifndef __PID_ZH_H__
#define __PID_ZH_H__
#include "lib.h"
#include "pid_auto_tune.h"
#define GPS2000
typedef struct
{
float32 ref;
float32 feed_back;
float32 pre_feed_back;
float32 pre_error;
float32 sum_ref;
float32 sum_iterm;
float32 kp;
float32 ki;
float32 kd;
float32 err_limit;
BOOL detach;
float32 err_dead;
#if INCOMPLETE_DIFFEREN == 1
float32 alpha;
float32 lastdev;
#endif
float32 out;
float32 out_max;
float32 out_min;
float32 sv_range;
BOOL sm;
BOOL ki_enable;
BOOL kd_enable;
} pid_zh_position_t; // 位置式PID
typedef struct
{
float32 kp;
float32 ki;
float32 kd;
float32 kup;
float32 kui;
float32 kud;
} FUZZY_PID_ZH_t;
// 模糊PID
typedef struct PID_FUZZY_ZH
{
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_FUZZY_ZH *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max); // 设置PID参数
void (*update_ctrl_prm)(struct PID_FUZZY_ZH *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max); // 更新PID参数
void (*set_range)(struct PID_FUZZY_ZH *self, float32 out_min, float32 out_max); // 更新最大最小值
void (*set_cfg)(struct PID_FUZZY_ZH *self, float32 max_err, BOOL mode); // 配置PID模式,默认不使用积分分离
void (*set_smooth_enable)(struct PID_FUZZY_ZH *self, BOOL enable, float32 sv_range); // 设置平滑范围
// void (*set_ki_enable)(struct PID_FUZZY *self, BOOL enable);
// 微分开启使能
void (*set_kd_enable)(struct PID_FUZZY_ZH *self, BOOL enable);
void (*restctrl)(struct PID_FUZZY_ZH *self); // 复位PID积分及微分控制数据
/* 控制接口 */
float32 (*PID)(struct PID_FUZZY_ZH *self, float32 target, float32 feedback);
pid_zh_position_t pri;
BOOL open; // 是否使用模糊PID控制
FUZZY_PID_ZH_t fuzzy;
} pid_zh_t; // 模糊PID
extern void pid_zh_constructor(struct PID_FUZZY_ZH *self);
#endif

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# 架构
|文件|路径| <div style="width:300px">说明</div>|
|:--|:--|:--|
|pid|User\lib\control\src|PID算法模块|
|execute|User\application\src|执行器|
|app_flow|User|任务流程控制|
## APP_FLOW任务流程控制
> adjust_inspection 中在没有检测到调试信号时执行<b style="color:blue">execute_dac,EXECUTE_PLAN</b>定义了需要执行的算法任务计划
## PID算法模块
文件内容:
|文件| <div style="width:300px">说明</div>|
|:--|:--|
|pid.c|构造算法的入口|
|pid_common.c|普通算法|
|pid_neural.c|神经网络算法|
|pid_fuzzy.c|模糊算法|
<b style="color:blue">custom 目录下为各自算法实现</b>
## EXECUTE执行器
> execute_pid_init中定义了初始化参数
> execute_dac中定义了执行器

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#ifndef __PID_H__
#define __PID_H__
#include "lib.h"
#include "pid_auto_tune.h"
#include "pid_c.h"
#include "pid_g.h"
#include "pid_x.h"
#include "pid_zh.h"
#include "pid_hd.h"
#define INCOMPLETE_DIFFEREN 0 // 不完全微分
typedef enum
{
PID_SUB_TYPE_POSITION, // 位置式
PID_SUB_TYPE_INCREMENT, // 增量式
} pid_sub_type_e;
typedef enum
{
// PID自整定
PID_TYPE_AUTO_TUNE,
// 通用PID
PID_TYPE_COMMON,
// 神经PID
PID_TYPE_NEURAL,
// 模糊PID
PID_TYPE_FUZZY,
// 以下是自定义PID
// cj PID
PID_TYPE_CUSTOM_CAO,
// gp jPID
PID_TYPE_CUSTOM_GAO,
// xsh PID
PID_TYPE_CUSTOM_XU,
// zxm PID
PID_TYPE_CUSTOM_ZHANG,
// hangdian PID
PID_TYPE_CUSTOM_HANGDIAN,
} pid_type_e;
#pragma pack(1)
typedef struct
{
float32 ref;
float32 feedback;
float32 pre_feedback;
float32 e_0; // 当前误差
float32 e_1; // 上一次误差
float32 kp;
float32 ki;
float32 kd;
float32 err_limit;
BOOL detach;
float32 err_dead;
float32 alpha;
float32 lastdev;
float32 out;
float32 out_max;
float32 out_min;
float32 sv_range;
float32 iout; // 积分输出
BOOL sm;
BOOL ki_enable;
BOOL kd_enable;
float32 deviation; // 纠正系统误差造成的影响作用于死区大于0需要补偿小于0需要反向补偿
} pid_common_position_t; // 位置式PID
typedef struct
{
float32 ref; // 目标设定值
float32 feedback; // 传感器采集值
float32 out; // PID计算结果
float32 kp;
float32 ki;
float32 kd;
float32 e_0; // 当前误差
float32 e_1; // 上一次误差
float32 e_2; // 上上次误差
float32 err_dead;
float32 deviation; // 纠正系统误差造成的影响,作用于死区
float32 out_max; // 输出限幅
float32 out_min; // 输出限幅
float32 sum_iterm;
float32 iout; // 积分输出
float32 alpha; // 不完全微分参数
float32 lastdev; // 不完全微分参数
BOOL sm;
BOOL ki_enable;
BOOL kd_enable;
float32 sv_range;
// 没有用的
float32 err_limit;
BOOL detach;
} pid_common_increment_t; // 增量式PID
#pragma pack()
typedef struct PID_COMMON
{
uint8_t type;
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_COMMON *self, float32 kp, float32 ki, float32 kd);
/* 设置积分范围 */
void (*set_integral_prm)(struct PID_COMMON *self, float32 integral_up, float32 integral_low);
/* 控制接口 */
float32 (*PID)(struct PID_COMMON *self, float32 err);
/* in value */
float32 err;
/* out value */
float32 out;
union
{
pid_common_position_t position;
pid_common_increment_t increment;
} pri_u;
} pid_common_t; // 通用PID
typedef struct PID_NEURAL
{
uint8_t type;
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_NEURAL *self, float32 minimum, float32 maximum);
/* 设置输出范围 */
void (*set_out_prm)(struct PID_NEURAL *self, float32 minimum, float32 maximum);
/* 控制接口 */
float32 (*PID)(struct PID_NEURAL *self, float32 target, float32 feedback);
struct
{
float32 setpoint; /*设定值*/
float32 kcoef; /*神经元输出比例*/
float32 kp; /*比例学习速度*/
float32 ki; /*积分学习速度*/
float32 kd; /*微分学习速度*/
float32 lasterror; /*前一拍偏差*/
float32 preerror; /*前两拍偏差*/
float32 deadband; /*死区*/
float32 result; /*输出值*/
float32 output; /*百分比输出值*/
float32 maximum; /*输出值的上限*/
float32 minimum; /*输出值的下限*/
float32 wp; /*比例加权系数*/
float32 wi; /*积分加权系数*/
float32 wd; /*微分加权系数*/
} pri;
} pid_neural_t; // 神经PID
typedef struct
{
float32 kp;
float32 ki;
float32 kd;
float32 kup;
float32 kui;
float32 kud;
float32 maxe; // 非线性区间最大值
float32 mine; // 非线性区间最小值
} FUZZY_PID_t;
// 模糊PID
typedef struct PID_FUZZY
{
/* 设置PID三个参数 */
void (*set_ctrl_prm)(struct PID_FUZZY *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 deviation,
float32 out_min, float32 out_max); // 设置PID参数
void (*set_error_max_min)(struct PID_FUZZY *self, float32 mine, float32 maxe); // 设置非线性区间值
void (*update_ctrl_prm)(struct PID_FUZZY *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max); // 更新PID参数
void (*set_range)(struct PID_FUZZY *self, float32 out_min, float32 out_max); // 更新最大最小值
void (*set_cfg)(struct PID_FUZZY *self, float32 max_err, BOOL mode); // 配置PID模式,默认不使用积分分离
void (*set_smooth_enable)(struct PID_FUZZY *self, BOOL enable, float32 sv_range); // 设置平滑范围
void (*set_iout)(struct PID_FUZZY *self, float32 iout); // 设置积分输出
void (*set_err_dead)(struct PID_FUZZY *self, float32 err_dead); // 设置死区
void (*set_kp)(struct PID_FUZZY *self, float32 kp);
void (*set_ki_enable)(struct PID_FUZZY *self, BOOL enable);
void (*set_ki)(struct PID_FUZZY *self, float32 ki);
// 微分开启使能
void (*set_kd_enable)(struct PID_FUZZY *self, BOOL enable);
void (*set_kd)(struct PID_FUZZY *self, float32 kd);
void (*set_kd_dev)(struct PID_FUZZY *self, float32 alpha);
void (*restctrl)(struct PID_FUZZY *self, float32 out); // 复位PID积分及微分控制数据
/* 控制接口 */
float32 (*execute)(struct PID_FUZZY *self, float32 target, float32 feedback);
BOOL(*in_dead_zone)
(struct PID_FUZZY *self);
union
{
pid_common_position_t position;
pid_common_increment_t increment;
} pri_u;
pid_sub_type_e sub_type; // 位置式PID增量式PID
BOOL open; // 是否使用模糊PID控制
BOOL speed_integral_enable; // 变速积分,暂时没有验证成功
FUZZY_PID_t fuzzy;
} pid_fuzzy_t; // 模糊PID
// PID
typedef struct
{
pid_type_e type; // 不同的算法类型模糊PID神经PID通用PID
pid_sub_type_e sub_type; // 位置式PID增量式PID
union
{
pid_common_t common;
pid_neural_t neural;
pid_fuzzy_t fuzzy;
// 自定义PID
pid_c_t cao;
pid_g_t gao;
pid_x_t xu;
pid_zh_t zhang;
pid_hd_t hd;
} pid_u;
pid_auto_tune_t auto_tune;
} pid_t;
// PID控制
extern void pid_constructor(pid_t *self);
// private
// 神经元PID
extern void pid_neural_constructor(struct PID_NEURAL *self);
// 模糊PID
extern void pid_fuzzy_constructor(struct PID_FUZZY *self);
#endif

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/***
* @Author:
* @Date: 2023-07-24 11:17:55
* @LastEditors: xxx
* @LastEditTime: 2023-07-24 11:19:06
* @Description:pid自动调参 KP和震荡周期
* @email:
* @Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __PID_AUTO_TUNE_H__
#define __PID_AUTO_TUNE_H__
#include "lib.h"
typedef struct PID_AUTO_TUNE
{
// public:
void (*set_ctrl_prm)(struct PID_AUTO_TUNE *self, float32 *input, float32 *output);
int32_t (*runtime)(struct PID_AUTO_TUNE *self);
void (*set_output_step)(struct PID_AUTO_TUNE *self, int32_t step);
void (*set_control_type)(struct PID_AUTO_TUNE *self, int32_t type);
void (*set_noise_band)(struct PID_AUTO_TUNE *self, int32_t band);
void (*set_look_back)(struct PID_AUTO_TUNE *self, int32_t n);
float32 (*get_kp)(struct PID_AUTO_TUNE *self);
float32 (*get_ki)(struct PID_AUTO_TUNE *self);
float32 (*get_kd)(struct PID_AUTO_TUNE *self);
// private:
struct
{
BOOL isMax, isMin; // 运算中出现最大、最小值标志
float32 *input, *output;
float32 setpoint; // 反向控制判断值,这个值需要根据对象的实际工作值确定!是通过第一次启动时对应的输入值带入的。
int32_t noiseBand; // 判断回差,类似于施密特触发器,实际控制反向的比较值是 setpoint + noiseBand 或 setpoint - noiseBand
int32_t controlType; // 计算 PID 参数时,选择 PI 或 PID 模式,输出 Kp Ki或 Kp、Ki、Kd
BOOL running;
uint32_t peak1, peak2, lastTime; // 峰值对应的时间
int32_t sampleTime;
int32_t nLookBack;
int32_t peakType;
int32_t lastInputs[51]; // 保存的历史输入值, 改为 50 次。 by shenghao.xu
int32_t peaks[13]; // 保存的历史峰值,最多存前 12 次,对应 6个最大、6个最小。20221124 by Embedream
int32_t peakCount; // 峰值计数
int32_t peakPeriod[7]; // 保存前 6 次的最大值间隔时间 by shenghao.xu
int32_t peakMaxCount; // 最大峰值计数 by shenghao.xu
BOOL justchanged;
int32_t oStep; // 这个值是用于计算控制高低值的,以 outputStart 为中值,输出高值用 outputStart + oStep 输出低值用 outputStart - oStep
float32 outputStart; // 输出控制的基础值,这个需要结合对象特征确定,此值也是通过第一次启动时对应的输出值带入的。
float32 Ku, Pu;
} pri;
} pid_auto_tune_t;
extern void pid_auto_tune_constructor(struct PID_AUTO_TUNE *self);
#endif // __PID_AUTO_TUNE_H__

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User/lib/control/src/pid.c Normal file
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#include "pid.h"
#include <math.h>
// 构造函数将接口绑定
void pid_constructor(pid_t *self)
{
switch (self->type)
{
case PID_TYPE_COMMON:
/* code */
break;
case PID_TYPE_NEURAL:
pid_neural_constructor(&self->pid_u.neural);
break;
case PID_TYPE_FUZZY:
self->pid_u.fuzzy.sub_type = self->sub_type;
pid_fuzzy_constructor(&self->pid_u.fuzzy);
break;
case PID_TYPE_AUTO_TUNE:
pid_auto_tune_constructor(&self->auto_tune);
break;
case PID_TYPE_CUSTOM_CAO:
pid_c_constructor(&self->pid_u.cao);
break;
case PID_TYPE_CUSTOM_GAO:
pid_g_constructor(&self->pid_u.gao);
break;
case PID_TYPE_CUSTOM_XU:
pid_x_constructor(&self->pid_u.xu);
break;
case PID_TYPE_CUSTOM_ZHANG:
pid_zh_constructor(&self->pid_u.zhang);
break;
case PID_TYPE_CUSTOM_HANGDIAN:
pid_hd_constructor(&self->pid_u.hd);
break;
default:
break;
}
}

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User/lib/control/src/pid_auto_tune.c Normal file
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#include "pid_auto_tune.h"
#include "sys.h"
/*
, 0.1 0.2 4
*/
static void set_look_backsec(pid_auto_tune_t *self, int32_t value)
{
if (value < 2)
value = 2;
if (value > 40)
value = 40;
if (value < 40)
{
self->pri.nLookBack = 12; // 按目前实际周期约300ms、采样周期 10ms 考虑,一个周期只有 30 点,回溯 12 点即可。
self->pri.sampleTime = value * 10; // 改为 Value*10 ms 20、30、40 ~ 200ms
}
else
{
self->pri.nLookBack = 50 + value;
self->pri.sampleTime = 4000;
}
}
static void _set_ctrl_prm(struct PID_AUTO_TUNE *self, float32 *input, float32 *output)
{
self->pri.input = input;
self->pri.output = output;
self->pri.controlType = 0; // 默认为 PI 模式
self->pri.noiseBand = 1;
self->pri.running = FALSE;
self->pri.oStep = 1;
set_look_backsec(self, 8);
self->pri.lastTime = sys_millis();
}
static void _set_noise_band(struct PID_AUTO_TUNE *self, int32_t value)
{
self->pri.noiseBand = value;
}
static void _set_output_step(struct PID_AUTO_TUNE *self, int32_t value)
{
self->pri.oStep = value;
}
// * Determies if the tuning parameters returned will be PI (D=0)
// or PID. (0=PI, 1=PID)
static void _set_control_type(struct PID_AUTO_TUNE *self, int32_t value)
{
self->pri.controlType = value;
}
static void _set_look_back(struct PID_AUTO_TUNE *self, int32_t value)
{
set_look_backsec(self, value);
}
static float32 _get_kp(struct PID_AUTO_TUNE *self)
{
float32 kp = self->pri.controlType == 1 ? 0.6f * self->pri.Ku : 0.4f * self->pri.Ku;
return kp;
}
static float32 _get_ki(struct PID_AUTO_TUNE *self)
{
float32 ki = self->pri.controlType == 1 ? 1.2f * self->pri.Ku / self->pri.Pu : 0.48f * self->pri.Ku / self->pri.Pu;
return ki;
}
static float32 _get_kd(struct PID_AUTO_TUNE *self)
{
return self->pri.controlType == 1 ? 0.075f * self->pri.Ku * self->pri.Pu : 0;
}
/**
* @brief 0 - 1 - 2 -
* @return {*}
*/
static int32_t _runtime(struct PID_AUTO_TUNE *self)
{
int32_t i, iSum;
uint32_t now = sys_millis();
if ((now - self->pri.lastTime) < ((uint32_t)self->pri.sampleTime))
{
return 2; // 原来返回值为 FALSE 不符合函数定义,也无法区分,改为 2by shenghao.xu
}
// 开始整定计算
self->pri.lastTime = now;
float32 refVal = *(self->pri.input);
if (FALSE == self->pri.running) // 首次进入,初始化参数
{
self->pri.peakType = 0;
self->pri.peakCount = 0;
self->pri.peakMaxCount = 0;
self->pri.peak1 = 0;
self->pri.peak2 = 0;
self->pri.justchanged = FALSE;
self->pri.setpoint = refVal; // 不变
self->pri.running = TRUE;
self->pri.outputStart = *self->pri.output;
*self->pri.output = self->pri.outputStart + self->pri.oStep;
}
// 根据输入与设定点的关系振荡输出
if (refVal > (self->pri.setpoint + self->pri.noiseBand))
*self->pri.output = self->pri.outputStart - self->pri.oStep;
else if (refVal < (self->pri.setpoint - self->pri.noiseBand))
*self->pri.output = self->pri.outputStart + self->pri.oStep;
// bool isMax=TRUE, isMin=TRUE;
self->pri.isMax = TRUE;
self->pri.isMin = TRUE;
// id peaks
/*
isMaxisMin
*/
for (i = self->pri.nLookBack - 1; i >= 0; i--)
{
int32_t val = self->pri.lastInputs[i];
if (self->pri.isMax)
self->pri.isMax = (refVal > val); // 第一次是新输入和缓存最后一个值比较,如果大于,则前面的值均判是否大于
if (self->pri.isMin)
self->pri.isMin = (refVal < val); // 第一次是新输入和缓存最后一个值比较,如果小于,则前面的值均判是否小于
self->pri.lastInputs[i + 1] = self->pri.lastInputs[i]; // 每采样一次,将输入缓存的数据向后挪一次
}
self->pri.lastInputs[0] = refVal; // 新采样的数据放置缓存第一个单元。
/*
nLookBack
nLookBack
1peaks[] peakCount +1
2
3 Ku
1121266
2 6 Pu
*/
if (self->pri.isMax)
{
if (self->pri.peakType == 0)
self->pri.peakType = 1; // 首次最大值,初始化
if (self->pri.peakType == -1) // 如果前一次为最小值,则标识目前进入最大值判断
{
self->pri.peakType = 1; // 开始最大值判断
self->pri.peakCount++; // 峰值计数 by shenghao.xu
self->pri.justchanged = TRUE; // 标识峰值转换
if (self->pri.peak2 != 0) // 已经纪录一次最大峰值对应时间后,开始记录峰值周期 by shenghao.xu
{
self->pri.peakPeriod[self->pri.peakMaxCount] = (int32_t)(self->pri.peak1 - self->pri.peak2); // 最大峰值间隔时间(即峰值周期)
self->pri.peakMaxCount++; // 最大峰值计数
}
self->pri.peak2 = self->pri.peak1; // 刷新上次最大值对应时间
}
self->pri.peak1 = now; // 保存最大值对应时间 peak1
self->pri.peaks[self->pri.peakCount] = refVal; // 保存最大值
} // 此段代码可以保证得到的是真正的最大值因为peakType不变则会不断刷新最大值
else if (self->pri.isMin)
{
if (self->pri.peakType == 0)
self->pri.peakType = -1; // 首次最小值,初始化
if (self->pri.peakType == 1) // 如果前一次是最大值判断,则转入最小值判断
{
self->pri.peakType = -1; // 开始最小值判断
self->pri.peakCount++; // 峰值计数
self->pri.justchanged = TRUE;
}
if (self->pri.peakCount < 10)
self->pri.peaks[self->pri.peakCount] = refVal; // 只要类型不变,就不断刷新最小值
}
/* by shenghao.xu
2
1 12 ( 13 )
2
35
4 10 9 Ku A
5 5 Pu
*/
if (self->pri.justchanged && self->pri.peakCount == 12)
{
// we've transitioned. check if we can autotune based on the last peaks
iSum = 0;
for (i = 2; i <= 10; i++)
iSum += ABS(self->pri.peaks[i] - self->pri.peaks[i + 1]);
iSum /= 9; // 取 9 次峰峰值平均值
self->pri.Ku = (float32)(4 * (2 * self->pri.oStep)) / (iSum * 3.14159); // 用峰峰平均值计算 Ku
iSum = 0;
for (i = 1; i <= 5; i++)
iSum += self->pri.peakPeriod[i];
iSum /= 5; // 计算峰值的所有周期平均值
self->pri.Pu = (float32)(iSum) / 1000; // 用周期平均值作为 Pu单位
*self->pri.output = 0;
self->pri.running = FALSE;
return 1;
}
self->pri.justchanged = FALSE;
return 0;
}
void pid_auto_tune_constructor(struct PID_AUTO_TUNE *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->runtime = _runtime;
self->set_output_step = _set_output_step;
self->set_control_type = _set_control_type;
self->set_noise_band = _set_noise_band;
self->set_look_back = _set_look_back;
self->get_kp = _get_kp;
self->get_ki = _get_ki;
self->get_kd = _get_kd;
}

0
User/lib/control/src/pid_common.c Normal file
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User/lib/control/src/pid_fuzzy.c Normal file
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#include "pid.h"
#include <math.h>
// 模糊集合
#define NL -3
#define NM -2
#define NS -1
#define ZE 0
#define PS 1
#define PM 2
#define PL 3
// 定义偏差E的范围因为设置了非线性区间误差在10时才开始进行PID调节这里E的范围为10
#define MAXE (10)
#define MINE (-MAXE)
// 定义EC的范围因为变化非常缓慢每次的EC都非常小这里可以根据实际需求来调整
#define MAXEC (10)
#define MINEC (-MAXEC)
// 定义e,ec的量化因子
#define KE 3 / MAXE
#define KEC 3 / MAXEC
// 定义输出量比例因子
#define KUP 3.0f // 这里只使用了模糊PID的比例增益
#define KUI 0.0f
#define KUD 0.0f
static const float32 fuzzyRuleKp[7][7] = {
PL, PL, PM, PL, PS, PM, PL,
PL, PM, PM, PM, PS, PM, PL,
PM, PS, PS, PS, PS, PS, PM,
PM, PS, ZE, ZE, ZE, PS, PM,
PS, PS, PS, PS, PS, PM, PM,
PM, PM, PM, PM, PL, PL, PL,
PM, PL, PL, PL, PL, PL, PL};
static const float32 fuzzyRuleKi[7][7] = {
NL, NL, NL, NL, NM, NL, NL,
NL, NL, NM, NM, NM, NL, NL,
NM, NM, NS, NS, NS, NM, NM,
NM, NS, ZE, ZE, ZE, NS, NM,
NM, NS, NS, NS, NS, NM, NM,
NM, NM, NS, NM, NM, NL, NL,
NM, NL, NM, NL, NL, NL, NL};
static const float32 fuzzyRuleKd[7][7] = {
PS, PS, ZE, ZE, ZE, PL, PL,
NS, NS, NS, NS, ZE, NS, PM,
NL, NL, NM, NS, ZE, PS, PM,
NL, NM, NM, NS, ZE, PS, PM,
NL, NM, NS, NS, ZE, PS, PS,
NM, NS, NS, NS, ZE, PS, PS,
PS, ZE, ZE, ZE, ZE, PL, PL};
static void fuzzy(float32 e, float32 ec, FUZZY_PID_t *fuzzy_pid)
{
float32 etemp, ectemp;
float32 eLefttemp, ecLefttemp; // ec,e左隶属度
float32 eRighttemp, ecRighttemp;
int eLeftIndex, ecLeftIndex; // 模糊位置标号
int eRightIndex, ecRightIndex;
e = RANGE(e, fuzzy_pid->mine, fuzzy_pid->maxe);
ec = RANGE(ec, MINEC, MAXEC);
e = e * KE;
ec = ec * KEC;
etemp = e > 3.0f ? 0.0f : (e < -3.0f ? 0.0f : (e >= 0.0f ? (e >= 2.0f ? 2.5f : (e >= 1.0f ? 1.5f : 0.5f)) : (e >= -1.0f ? -0.5f : (e >= -2.0f ? -1.5f : (e >= -3.0f ? -2.5f : 0.0f)))));
eLeftIndex = (int)((etemp - 0.5f) + 3); //[-3,3] -> [0,6]
eRightIndex = (int)((etemp + 0.5f) + 3);
eLefttemp = etemp == 0.0f ? 0.0f : ((etemp + 0.5f) - e); //
eRighttemp = etemp == 0.0f ? 0.0f : (e - (etemp - 0.5f));
ectemp = ec > 3.0f ? 0.0f : (ec < -3.0f ? 0.0f : (ec >= 0.0f ? (ec >= 2.0f ? 2.5f : (ec >= 1.0f ? 1.5f : 0.5f)) : (ec >= -1.0f ? -0.5f : (ec >= -2.0f ? -1.5f : (ec >= -3.0f ? -2.5f : 0.0f)))));
ecLeftIndex = (int)((ectemp - 0.5f) + 3); //[-3,3] -> [0,6]
ecRightIndex = (int)((ectemp + 0.5f) + 3);
ecLefttemp = ectemp == 0.0f ? 0.0f : ((ectemp + 0.5f) - ec);
ecRighttemp = ectemp == 0.0f ? 0.0f : (ec - (ectemp - 0.5f));
/*************************************反模糊*************************************/
fuzzy_pid->kp = (eLefttemp * ecLefttemp * fuzzyRuleKp[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKp[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKp[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKp[eRightIndex][ecRightIndex]);
fuzzy_pid->ki = (eLefttemp * ecLefttemp * fuzzyRuleKi[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKi[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKi[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKi[eRightIndex][ecRightIndex]);
fuzzy_pid->kd = (eLefttemp * ecLefttemp * fuzzyRuleKd[eLeftIndex][ecLeftIndex] + eLefttemp * ecRighttemp * fuzzyRuleKd[eLeftIndex][ecRightIndex] + eRighttemp * ecLefttemp * fuzzyRuleKd[eRightIndex][ecLeftIndex] + eRighttemp * ecRighttemp * fuzzyRuleKd[eRightIndex][ecRightIndex]);
// 对解算出的KP,KI,KD进行量化映射
fuzzy_pid->kp = fuzzy_pid->kp * fuzzy_pid->kup;
fuzzy_pid->ki = fuzzy_pid->ki * fuzzy_pid->kui;
fuzzy_pid->kd = fuzzy_pid->kd * fuzzy_pid->kud;
}
/**
* @brief SV平滑给定,0.10-1
* @param {PID_FUZZY} *self
* @param {float32} target_sv
* @return {*}
* @note
*/
static void smooth_setpoint(struct PID_FUZZY *self, float32 target_sv)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
float32 stepIn = (pri->sv_range) * 0.1f;
float32 kFactor = 0.0f;
if (fabs(pri->ref - target_sv) <= stepIn)
{
pri->ref = target_sv;
}
else
{
if (pri->ref - target_sv > 0)
{
kFactor = -1.0f;
}
else if (pri->ref - target_sv < 0)
{
kFactor = 1.0f;
}
else
{
kFactor = 0.0f;
}
pri->ref = pri->ref + kFactor * stepIn;
}
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
float32 stepIn = (pri->sv_range) * 0.1f;
float32 kFactor = 0.0f;
if (fabs(pri->ref - target_sv) <= stepIn)
{
pri->ref = target_sv;
}
else
{
if (pri->ref - target_sv > 0)
{
kFactor = -1.0f;
}
else if (pri->ref - target_sv < 0)
{
kFactor = 1.0f;
}
else
{
kFactor = 0.0f;
}
pri->ref = pri->ref + kFactor * stepIn;
}
}
}
// 变速积分
static float32 changing_integral_rate(struct PID_FUZZY *self)
{
float32 err = 0, iout = 0;
float32 err_1 = 1, // 误差下限
err_2 = 10; // 误差上限
float32 index = 0;
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
err = pri->e_0;
iout = pri->iout;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
err = pri->e_0;
iout = pri->iout;
}
if (err * iout > 0) // 判断积分是否为积累趋势
{
if (ABS(err) <= err_1)
{
index = 1; // 完整积分
}
else if (ABS(err) <= (err_1 + err_2))
{
// 使用线性函数过渡
index = (float)(err_2 - ABS(err) + err_1) / err_2;
}
else
{
index = 0;
}
}
return index;
}
/*封装模糊接口*/
static void compensate(float32 e, float32 ec, FUZZY_PID_t *fuzzy_d)
{
fuzzy(e, ec, fuzzy_d);
}
/**
* @brief
* @param {PID_FUZZY} *self
* @param {float32} out_min
* @param {float32} out_max
* @return {*}
* @note
*/
static void _set_range(struct PID_FUZZY *self, float32 out_min, float32 out_max)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->out_max = out_max;
pri->out_min = out_min;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->out_max = out_max;
pri->out_min = out_min;
}
}
/**
* @brief
* @param {PID_FUZZY} *self
* @param {float32} err_dead
* @return {*}
* @note
*/
static void _set_err_dead(struct PID_FUZZY *self, float32 err_dead)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->err_dead = err_dead;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->err_dead = err_dead;
}
}
static void _set_iout(struct PID_FUZZY *self, float32 iout)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->iout = iout;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->iout = iout;
}
}
static void _set_kp(struct PID_FUZZY *self, float32 kp)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->kp = kp;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->kp = kp;
}
}
/**
* @brief 使
* @param {PID_FUZZY} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
// static void _set_ki_enable(struct PID_FUZZY *self, BOOL enable)
// {
// pri->ki_enable = enable;
// }
/**
* @brief 使
* @param {PID_FUZZY} *self
* @param {BOOL} enable
* @return {*}
* @note
*/
static void _set_kd_enable(struct PID_FUZZY *self, BOOL enable)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->kd_enable = enable;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->kd_enable = enable;
}
}
static void _set_kd(struct PID_FUZZY *self, float32 kd)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->kd = kd;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->kd = kd;
}
}
/**
* @brief
* @param {PID_FUZZY} *self
* @param {float32} alpha
* @return {*}
* @note alpha范围0-1,
*/
static void _set_kd_dev(struct PID_FUZZY *self, float32 alpha)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->alpha = alpha;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->alpha = alpha;
}
}
static void _set_ki_enable(struct PID_FUZZY *self, BOOL enable)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->ki_enable = enable;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->ki_enable = enable;
}
}
static void _set_ki(struct PID_FUZZY *self, float32 ki)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->ki = ki;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->ki = ki;
}
}
/*
* Function:使
* parameter:*pid需要配PID参数结构指针sv_range控制范围sv的范围
* return:
*/
static void _set_smooth_enable(struct PID_FUZZY *self, BOOL enable, float32 sv_range)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->sm = enable;
pri->sv_range = sv_range;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->sm = enable;
pri->sv_range = sv_range;
}
}
// 设置控制参数
static void _set_ctrl_prm(struct PID_FUZZY *self, float32 kp, float32 ki, float32 kd, float32 err_dead, float32 deviation,
float32 out_min, float32 out_max)
{
self->open = TRUE;
self->fuzzy.kup = KUP;
self->fuzzy.kui = KUI;
self->fuzzy.kud = KUD;
self->fuzzy.mine = MINE;
self->fuzzy.maxe = MAXE;
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
osel_memset((uint8_t *)pri, 0, sizeof(pid_common_position_t));
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->deviation = deviation;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
pri->sm = FALSE;
pri->ki_enable = TRUE;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
osel_memset((uint8_t *)pri, 0, sizeof(pid_common_increment_t));
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->deviation = deviation;
pri->out_max = out_max;
pri->out_min = out_min;
pri->ki_enable = TRUE;
}
}
static void _set_error_max_min(struct PID_FUZZY *self, float32 mine, float32 maxe)
{
self->fuzzy.mine = mine;
self->fuzzy.maxe = maxe;
}
static void _update_ctrl_prm(struct PID_FUZZY *self, float32 kp, float32 ki, float32 kd, float32 err_dead,
float32 out_min, float32 out_max)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
pri->detach = FALSE;
pri->sm = FALSE;
if (kd > 0)
{
pri->kd_enable = TRUE;
}
else
{
pri->kd_enable = FALSE;
}
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->kp = kp;
pri->ki = ki;
pri->kd = kd;
pri->err_dead = err_dead;
pri->out_max = out_max;
pri->out_min = out_min;
if (kd > 0)
{
pri->kd_enable = TRUE;
}
else
{
pri->kd_enable = FALSE;
}
}
}
/**
* @brief 0+PID,PID
* @param {PID_FUZZY} *self
* @param {float32} max_err
* @param {BOOL} mode
* @return {*}
*/
static void _set_cfg(struct PID_FUZZY *self, float32 max_err, BOOL mode)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->err_limit = max_err;
pri->detach = mode == FALSE ? FALSE : TRUE;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->err_limit = max_err;
pri->detach = mode == FALSE ? FALSE : TRUE;
}
}
/**
* @brief
*
* PID_FUZZY
*
* @param self PID_FUZZY
*
* @return TRUE FALSE
*/
static BOOL _in_dead_zone(struct PID_FUZZY *self)
{
float32 deviation = 0.0f;
float32 err_dead = 0.0f;
float32 err = 0.0f;
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
deviation = pri->deviation;
err_dead = pri->err_dead;
err = pri->feedback - pri->ref;
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
deviation = pri->deviation;
err_dead = pri->err_dead;
err = pri->feedback - pri->ref;
}
if (ABS(err + deviation) <= err_dead)
{
return TRUE;
}
else
{
return FALSE;
}
}
static float32 position_pid(struct PID_FUZZY *self, float32 target, float32 feedback)
{
float32 error = 0;
float32 ec = 0;
float32 kd = 0;
float32 thisdev = 0;
pid_common_position_t *pri = &self->pri_u.position;
/*获取期望值与实际值,进行偏差计算*/
if (pri->sm == 1)
{
smooth_setpoint(self, target);
}
else
{
pri->ref = target;
}
pri->feedback = feedback;
error = pri->ref - pri->feedback;
if (self->in_dead_zone(self) == TRUE)
{
error = 0;
}
pri->e_0 = error;
/* fuzzy control caculate */
ec = error - pri->e_1;
if (self->open == TRUE)
{
compensate(error, ec, &self->fuzzy);
}
/*根据PID配置的模式,获取积分数据,进行积分累加*/
if (self->speed_integral_enable == TRUE)
{
pri->iout = (pri->ki + self->fuzzy.ki) * error * changing_integral_rate(self);
}
else
{
float32 temp_iterm = 0.0f;
float32 insert = 0;
if (pri->out >= pri->out_max)
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
if (error < 0)
{
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
}
else if (pri->out <= pri->out_min)
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
if (error > 0)
{
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
}
else
{
if (fabs(error) > pri->err_limit && pri->detach)
{
insert = 0;
}
else
{
insert = 1;
temp_iterm = (pri->ki + self->fuzzy.ki) * error;
}
}
pri->iout += temp_iterm;
/* limt integral */
if (pri->iout > pri->out_max)
{
pri->iout = pri->out_max;
}
else if (pri->iout < pri->out_min)
{
pri->iout = pri->out_min;
}
pri->iout = pri->iout * insert;
}
#if INCOMPLETE_DIFFEREN == 1
/*不完全微分*/
thisdev = kd * (1.0 - pri->alpha) * (error - pri->e_1) + pri->alpha * pri->lastdev;
/*record last dev result*/
pri->lastdev = thisdev;
#else
thisdev = (error - pri->e_1) * (kd);
#endif
if (pri->kd_enable == TRUE)
{
thisdev = 0;
}
if (pri->ki_enable == FALSE)
{
pri->iout = 0;
}
pri->out = (pri->kp + self->fuzzy.kp) * error + pri->iout + thisdev;
pri->e_1 = error;
/*record last feedback sensor result*/
pri->pre_feedback = pri->feedback;
/*limt pid output*/
pri->out = RANGE(pri->out, pri->out_min, pri->out_max);
return pri->out;
}
static float32 increment_pid(struct PID_FUZZY *self, float32 target, float32 feedback)
{
float32 ep, ei, ed;
float32 inc_out;
float32 thisdev = 0;
pid_common_increment_t *pri = &self->pri_u.increment;
pri->feedback = feedback;
pri->e_0 = pri->ref - pri->feedback;
if (pri->e_0 >= MAXE)
{
return pri->out_max;
}
else if (pri->e_0 <= MINE)
{
return pri->out_min;
}
if (pri->sm == 1)
{
smooth_setpoint(self, target);
}
else
{
pri->ref = target;
}
if (fabs(pri->e_0) <= pri->err_dead)
{
pri->e_0 = 0;
}
ep = pri->e_0 - pri->e_1;
ei = pri->e_0;
ed = pri->e_0 - 2 * pri->e_1 + pri->e_2;
if (self->open == TRUE)
{
compensate(pri->e_0, ep, &self->fuzzy);
}
#if INCOMPLETE_DIFFEREN == 1
/*不完全微分*/
thisdev = (1.0 - pri->alpha) * (pri->kd + self->fuzzy.kd) * ed + pri->alpha * pri->lastdev;
#else
ed = ed;
#endif
if (self->speed_integral_enable == TRUE)
{
if (ABS(pri->e_0) > MAXE)
{
pri->iout = (pri->ki + self->fuzzy.ki) * ei;
}
else
{
// 变速积分
pri->iout = (pri->ki + self->fuzzy.ki) * ei * changing_integral_rate(self);
}
}
else
{
pri->iout = (pri->ki + self->fuzzy.ki) * ei;
}
if (pri->kd_enable == FALSE)
{
thisdev = 0;
}
if (pri->ki_enable == FALSE)
{
pri->iout = 0;
}
inc_out = (pri->kp + self->fuzzy.kp) * ep + pri->iout + thisdev;
pri->e_2 = pri->e_1;
pri->e_1 = pri->e_0;
pri->lastdev = thisdev;
pri->out = pri->out + inc_out;
pri->out = RANGE(pri->out, pri->out_min, pri->out_max);
return pri->out;
}
static float32 _pid(struct PID_FUZZY *self, float32 target, float32 feedback)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
return position_pid(self, target, feedback);
}
else
{
return increment_pid(self, target, feedback);
}
}
/**
* @brief PID积分及微分控制数据
* @param {PID_FUZZY} *self
* @return {*}
*/
static void _restctrl(struct PID_FUZZY *self, float32 out)
{
if (self->sub_type == PID_SUB_TYPE_POSITION)
{
pid_common_position_t *pri = NULL;
pri = &self->pri_u.position;
pri->e_1 = 0;
pri->iout = 0;
pri->out = out;
pri->iout = out;
#if INCOMPLETE_DIFFEREN == 1
pri->lastdev = 0;
#endif
}
else
{
pid_common_increment_t *pri = NULL;
pri = &self->pri_u.increment;
pri->e_0 = 0;
pri->e_1 = 0;
pri->e_2 = 0;
pri->lastdev = 0;
pri->out = out;
pri->iout = out;
}
}
void pid_fuzzy_constructor(struct PID_FUZZY *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->set_error_max_min = _set_error_max_min;
self->update_ctrl_prm = _update_ctrl_prm;
self->set_cfg = _set_cfg;
self->set_smooth_enable = _set_smooth_enable;
self->set_err_dead = _set_err_dead;
self->set_kp = _set_kp;
self->set_ki_enable = _set_ki_enable;
self->set_ki = _set_ki;
self->set_kd_enable = _set_kd_enable;
self->set_kd = _set_kd;
self->set_kd_dev = _set_kd_dev;
self->set_range = _set_range;
self->restctrl = _restctrl;
self->set_iout = _set_iout;
self->in_dead_zone = _in_dead_zone;
self->execute = _pid;
}

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#include "pid.h"
#include <math.h>
// 设置控制参数
static void _set_ctrl_prm(struct PID_NEURAL *self, float32 minimum, float32 maximum)
{
self->pri.setpoint = minimum; /*设定值*/
self->pri.kcoef = 0.12; /*神经元输出比例*/
self->pri.kp = 0.45; /*比例学习速度*/
self->pri.ki = 0.05; /*积分学习速度*/
self->pri.kd = 0; /*微分学习速度*/
self->pri.lasterror = 0.0; /*前一拍偏差*/
self->pri.preerror = 0.0; /*前两拍偏差*/
self->pri.result = minimum; /*PID控制器结果*/
self->pri.output = 0.0; /*输出值,百分比*/
self->pri.maximum = maximum; /*输出值上限*/
self->pri.minimum = minimum; /*输出值下限*/
self->pri.deadband = (maximum - minimum) * 0.0005f; /*死区*/
self->pri.wp = 0.10; /*比例加权系数*/
self->pri.wi = 0.10; /*积分加权系数*/
self->pri.wd = 0.10; /*微分加权系数*/
}
// 设置输出参数
static void _set_out_prm(struct PID_NEURAL *self, float32 minimum, float32 maximum)
{
self->pri.maximum = maximum;
self->pri.minimum = minimum;
}
/*单神经元学习规则函数*/
static void NeureLearningRules(struct PID_NEURAL *self, float32 zk, float32 uk, float32 *xi)
{
self->pri.wi = self->pri.wi + self->pri.ki * zk * uk * xi[0];
self->pri.wp = self->pri.wp + self->pri.kp * zk * uk * xi[1];
self->pri.wd = self->pri.wd + self->pri.kd * zk * uk * xi[2];
}
static float32 _PID(struct PID_NEURAL *self, float32 target, float32 feedback)
{
float32 x[3];
float32 w[3];
float32 sabs;
float32 error;
float32 result;
float32 deltaResult;
self->pri.setpoint = target;
error = self->pri.setpoint - feedback;
result = self->pri.result;
if (fabs(error) > self->pri.deadband)
{
x[0] = error;
x[1] = error - self->pri.lasterror;
x[2] = error - self->pri.lasterror * 2 + self->pri.preerror;
sabs = fabs(self->pri.wi) + fabs(self->pri.wp) + fabs(self->pri.wd);
w[0] = self->pri.wi / sabs;
w[1] = self->pri.wp / sabs;
w[2] = self->pri.wd / sabs;
deltaResult = (w[0] * x[0] + w[1] * x[1] + w[2] * x[2]) * self->pri.kcoef;
}
else
{
deltaResult = 0;
}
result = result + deltaResult;
if (result > self->pri.maximum)
{
result = self->pri.maximum;
}
if (result < self->pri.minimum)
{
result = self->pri.minimum;
}
self->pri.result = result;
self->pri.output = self->pri.result;
// 单神经元学习
NeureLearningRules(self, error, result, x);
self->pri.preerror = self->pri.lasterror;
self->pri.lasterror = error;
return self->pri.output;
}
void pid_neural_constructor(struct PID_NEURAL *self)
{
self->set_ctrl_prm = _set_ctrl_prm;
self->set_out_prm = _set_out_prm;
self->PID = _PID;
}

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# 模糊PID控制器设计文档
# 模糊PID控制器详细设计文档
## 1. 引言
### 1.1 目的
本文档旨在详细介绍模糊PID控制器的设计理念、实现方法和使用指南为开发者提供一套完整的模糊PID控制解决方案。
### 1.2 背景
PID控制器因其结构简单、稳定性好、易于实现等优点在工业控制系统中得到了广泛应用。然而传统PID控制器在面对复杂或非线性系统时性能表现不佳。模糊PID控制器通过引入模糊逻辑动态调整PID参数以适应系统在不同工作状态下的控制需求从而提高控制性能。
## 2. 设计概述
### 2.1 设计目标
- **适应性**:能够适应不同类型和不同工作状态的控制系统。
- **稳定性**:保证控制系统在各种工作条件下的稳定运行。
- **易用性**:提供简单易懂的接口,便于开发者快速实现和调试。
### 2.2 功能模块
模糊PID控制器主要包括以下几个功能模块
1. **模糊控制模块**负责根据输入的误差和误差变化率通过模糊逻辑计算出PID参数。
2. **SV平滑给定模块**:负责平滑控制目标值,减少控制过程中的突变。
3. **变速积分模块**:根据误差的大小调整积分速率,提高控制效率。
4. **参数设置模块**提供接口函数用于设置和调整PID参数。
## 3. 功能模块详细设计
### 3.1 模糊控制模块
#### 3.1.1 输入处理
- **误差处理**:将实时误差 `e`限制在预定的范围内,并进行模糊化处理。
- **误差变化率处理**:将误差变化率 `ec`进行相同的处理。
#### 3.1.2 模糊规则库
- **规则定义**根据系统的具体需求定义一套模糊规则用于计算PID参数。
- **规则应用**:根据输入的误差和误差变化率的模糊化值,通过模糊规则库计算出 `kp`、`ki`、`kd`。
### 3.2 SV平滑给定模块
- **平滑策略**:根据当前目标值与新目标值之间的差值,动态调整目标值变化的步长,实现平滑过渡。
### 3.3 变速积分模块
- **积分策略**:根据误差的大小,调整积分速率。误差较小时,使用完整积分;误差较大时,减小或停止积分。
### 3.4 参数设置模块
- **接口设计**提供一系列接口函数用于设置PID控制器的参数如输出限制、死区误差等。
## 4. 使用说明
### 4.1 初始化
- **控制器初始化**根据控制对象的特性初始化模糊PID控制器的相关参数和模糊规则库。
### 4.2 实时控制
- **参数调整**在控制循环中根据实时误差和误差变化率动态调整PID参数。
- **控制执行**根据调整后的PID参数执行PID控制算法输出控制信号。
### 4.3 参数调整
- **动态调整**根据系统运行情况通过参数设置模块调整PID参数优化控制效果。
## 5. 结论
模糊PID控制器通过动态调整PID参数提高了控制系统的适应性和稳定性特别适用于复杂或非线性系统的控制。本文档提供了模糊PID控制器的详细设计方案旨在帮助开发者更好地理解和应用模糊PID控制技术
## 概述
本文档旨在详细介绍模糊PID控制器的设计与实现。模糊PID控制器结合了传统PID控制和模糊逻辑控制的优点通过模糊逻辑对PID参数进行动态调整以适应控制系统在不同工作状态下的需求。
## 功能模块
### 1. 模糊控制模块
- **功能描述**:根据误差 `e`和误差变化率 `ec`的模糊化值通过模糊规则库计算出模糊PID控制器的三个参数比例系数 `kp`、积分系数 `ki`、微分系数 `kd`
- **实现方法**:首先将输入的误差 `e`和误差变化率 `ec`限制在预定范围内,然后通过模糊化处理得到其隶属度和模糊位置标号,最后根据模糊规则库计算出 `kp`、`ki`、`kd`的值。
### 2. SV平滑给定模块
- **功能描述**平滑控制目标值Setpoint Value, SV以减少控制过程中的突变提高系统的稳定性。
- **实现方法**:根据当前目标值与新目标值之间的差值,动态调整目标值的变化步长,以实现平滑过渡。
### 3. 变速积分模块
- **功能描述**:根据误差的大小调整积分速率,以提高控制系统的快速性和稳定性。
- **实现方法**:当误差较小时,使用完整积分;当误差在一定范围内变化时,通过线性函数调整积分速率;当误差较大时,减小或停止积分,以避免积分饱和。
### 4. 参数设置模块
- **功能描述**提供接口函数用于设置PID控制器的各项参数包括输出限制范围、死区误差、积分输出值、PID参数等。
- **实现方法**:根据控制器的子类型(位置型或增量型),分别设置相应参数的值。
## 使用说明
1. **初始化**根据控制对象的具体情况初始化模糊PID控制器的结构体包括最大误差、最小误差、PID参数的模糊规则库等。
2. **实时控制**:在控制循环中,根据当前的误差 `e`和误差变化率 `ec`调用模糊控制模块计算出动态调整的PID参数然后根据这些参数进行PID控制。
3. **参数调整**根据系统运行情况通过参数设置模块调整PID控制器的参数以优化控制效果。
## 结论
模糊PID控制器通过引入模糊逻辑使得PID参数能够根据控制系统的实时状态动态调整从而提高了控制系统的适应性和稳定性。通过本文档的设计与实现开发者可以更好地理解和应用模糊PID控制器。

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https://www.cnblogs.com/foxclever/p/16299063.html

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# 变量BIN: 给定的是我们想要生成的可执行文件的名称
BIN = run.exe
SO = lib.dll
# 变量SRC中给的是所有的想要编译的.c源文件与makefile在同一目录下可直接写如这里的main.c否则需要写明相对路径如这里的其余源文件都在目录src下
# 多文件时,选择用"\"进行分行处理
SRC = \
../src/malloc.c \
../src/sqqueue.c \
../src/mlist.c \
../src/debug.c \
../src/data_analysis.c \
../src/filter.c \
../src/clist.c \
../src/aes.c \
../src/cmac.c \
../src/lib.c
EXAMPLE = \
./simple_clist.c \
./simple_data_analysis.c \
./simple_sqqueue.c \
./simple_aes.c \
./simple_cmac.c
CPLUS_INCLUDE_PATH= -I ../inc
# 变量CC给定编译器名gcc
# 变量CFLAGS传给编译器的某些编译参数看需求添加
CC = gcc
CFLAGS = -m32 -std=c99
# 变量GDB给定debugger名gdb
# 变量RM给定删除文件方式用于后面删除所有编译所得的.o文件,linux下使用rm -rf
GDB = gdb
RM = rm -rf
# 变量OBJS将变量SRC中所有的.c文件替换成以.o结尾即将.c源文件编译成.o文件
OBJS = $(SRC:%.c=%.o)
EXAPMLES = $(EXAMPLE:%.c=%.o)
$(SO): $(OBJS) $(EXAPMLES)
# pull in dependencies for .o files
-include $(OBJS:.o=.d)
%.o: %.c
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) -c $< -o $@
.PHONY: all clean clist data_analysis
all: $(SO)
rm:
$(RM) $(OBJS)
#简单链表
clist: $(SO)
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) $(OBJS) ./simple_clist.o -o $(BIN)
$(RM) $(OBJS) $(EXAPMLES)
#数据分析器
data_analysis: $(SO)
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) $(OBJS) ./simple_data_analysis.o -o $(BIN)
$(RM) $(OBJS) $(EXAPMLES)
#队列
sqqueue: $(SO)
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) $(OBJS) ./simple_sqqueue.o -o $(BIN)
$(RM) $(OBJS) $(EXAPMLES)
#aes加密
aes: $(SO)
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) $(OBJS) ./simple_aes.o -o $(BIN)
$(RM) $(OBJS) $(EXAPMLES)
#cmac类CRC
cmac: $(SO)
$(CC) $(CPLUS_INCLUDE_PATH) $(CFLAGS) $(OBJS) ./simple_cmac.o -o $(BIN)
$(RM) $(OBJS) $(EXAPMLES)
#运行程序
run:
./run.exe
clean:
$(RM) $(OBJS) $(EXAPMLES) $(BIN)

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#include "../inc/data_type_def.h"
#include "../inc/log.h"
#include "../inc/osel_arch.h"
#include "../inc/aes.h"
// 全局变量
static aes_context AesContext; // 密钥表
static uint8_t aBlock[] = {0x00, 0x00, 0x00, 0xcc, 0xff, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; // 数据块
static uint8_t sBlock[] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; // 存放输出结果
int32_t main(void)
{
uint8_t buf[16] = {0x00};
uint8_t size = ARRAY_LEN(buf);
uint8_t key[] = {
0x2B, 0x7E, 0x15, 0x16, 0x28, 0xAE, 0xD2, 0xA6,
0xAB, 0xF7, 0x15, 0x88, 0x09, 0xCF, 0x4F, 0x3C}; // 密钥
// 初始化密文
for (int i = 0; i < size; i++)
{
buf[i] = i;
}
// 设置预密钥
osel_memset(AesContext.ksch, 0, ARRAY_LEN(AesContext.ksch));
aes_set_key(key, 16, &AesContext);
// 加密
osel_memcpy(aBlock, buf, size);
aes_encrypt(aBlock, sBlock, &AesContext);
LOG_HEX(sBlock, ARRAY_LEN(sBlock)); // 打印加密结果:50 fe 67 cc 99 6d 32 b6 da 09 37 e9 9b af ec 60
// 解密
osel_memcpy(aBlock, sBlock, size);
aes_decrypt(aBlock, sBlock, &AesContext);
LOG_HEX(sBlock, ARRAY_LEN(sBlock)); // 打印解密结果:00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
}

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#include "../inc/data_type_def.h"
#include "../inc/clist.h"
int32_t main(void)
{
clist_node_t *head = NULL; // 创建头指针初始化为NULL
clist_init(&head); // 初始化指针(可有可无)
// 1添加数据
for (int32_t i = 0; i < 30; i++)
{
if (i > 10)
clist_push_front(&head, (cnode)i); // 头部插入
else
clist_push_back(&head, (cnode)i); // 尾部插入
}
LOG_PRINT("\n 1: count:%d \n", clist_node_count(head)); // 获取链表节点数,打印
clist_print(head); // 打印链表
// 2删除数据
for (int32_t i = 0; i < 10; i++)
{
if (i > 5)
clist_pop_back(&head); // 删除尾部
else
clist_pop_front(&head); // 头部删除
}
LOG_PRINT("\n 2: count:%d \n", clist_node_count(head));
clist_print(head);
// 3插入数据
clist_insert(&head, 5, (cnode)1111);
clist_insert_for_node(&head, head->Next->Next->Next->Next->Next, (cnode)10000);
clist_insert(&head, 1000, (cnode)2222); // 无效插入
LOG_PRINT("\n 3: count:%d \n", clist_node_count(head));
clist_print(head);
// 4删除指定节点
clist_remove(&head, (cnode)5);
clist_erase_for_node(&head, head->Next->Next);
clist_remove(&head, (cnode)1000); // 无效删除
clist_print(head);
LOG_PRINT("\n 4: count:%d \n", clist_node_count(head));
clist_print(head);
// 5删除所有节点
clist_destroy(&head);
LOG_PRINT("\n 5: count:%d ", clist_node_count(head));
clist_print(head);
return 0;
}

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#include "../inc/data_type_def.h"
#include "../inc/log.h"
#include "../inc/osel_arch.h"
#include "../inc/cmac.h"
static uint8_t key[] = {
0x2B, 0x7E, 0x15, 0x16, 0x28, 0xAE, 0xD2, 0xA6,
0xAB, 0xF7, 0x15, 0x88, 0x09, 0xCF, 0x4F, 0x3C}; // 密钥
int32_t main(void)
{
uint8_t *p;
uint8_t buffer[16] = {0x00};
uint32_t size = ARRAY_LEN(buffer);
// 初始化需要校验的数据
for (int i = 0; i < size; i++)
{
buffer[i] = i;
}
uint8_t mic[16]; // 存放生成校验数据的数组
AES_CMAC_CTX AesCmacCtx[1]; // 密钥扩展表
AES_CMAC_Init(AesCmacCtx); // 完成密钥扩展表的初始化
AES_CMAC_SetKey(AesCmacCtx, key); // 完成密钥扩展表数据
AES_CMAC_Update(AesCmacCtx, buffer, size & 0xFF); // 完成数据的奇偶校验
AES_CMAC_Final(mic, AesCmacCtx); // 生成16个字节的校验表
uint32_t xor_vol = (uint32_t)((uint32_t)mic[3] << 24 | (uint32_t)mic[2] << 16 | (uint32_t)mic[1] << 8 | (uint32_t)mic[0]); // 取表4个字节作为校验码
p = (uint8_t *)&xor_vol;
LOG_HEX(p, 4); // 打印结果5c 7e fb 43
}

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#include "../inc/data_type_def.h"
#include "../inc/log.h"
#include "../inc/cmd.h"
void at_name_req(void)
{
LOG_PRINT("name:cmd\n");
}
void at_version_req(void)
{
LOG_PRINT("version:1.0\n");
}
REGISTER_CMD(NAME, at_name_req, at name);
REGISTER_CMD(VERSION, at_version_req, at version);
int32_t main(void)
{
cmd_init();
cmd_parsing("TEST");
cmd_parsing("NAME");
cmd_parsing("VERSION");
return 0;
}

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#include "../inc/data_type_def.h"
#include "../inc/log.h"
#include "../inc/osel_arch.h"
#include "../inc/data_analysis.h"
#define UART_RXSIZE (254U)
#define UART_DATA_ANALYSIS_PORT_1 DATA_1
#define UART_DATA_ANALYSIS_PORT_2 DATA_2
static data_interupt_cb_t uart_data_analysis_cb = NULL; // 数据源中断回调函数
static void data_analysis_event1(void)
{
uint8_t frame[UART_RXSIZE];
uint8_t data_head[3];
uint8_t crc[2];
uint16_t frame_len, out_frame_len;
data_read(UART_DATA_ANALYSIS_PORT_1, &data_head[0], 3);
osel_memcpy((uint8_t *)&frame_len, &data_head[1], 2);
frame_len = B2S_UINT16(frame_len) - 2; // 报文长度包含帧长这里需要减2
if (frame_len > UART_RXSIZE)
{
lock_data(UART_DATA_ANALYSIS_PORT_1);
unlock_data(UART_DATA_ANALYSIS_PORT_1);
return;
}
out_frame_len = data_read(UART_DATA_ANALYSIS_PORT_1, frame, (uint16_t)frame_len);
if (out_frame_len != frame_len)
{
return;
}
out_frame_len = out_frame_len - 1; // 报文中包含帧尾这里需要减1
// 校验CRC_16
uint16_t crc_16 = 0;
uint16_t crc16 = crc16_compute(&frame[0], out_frame_len - 2);
osel_memcpy(&crc[0], &frame[out_frame_len - 2], 2);
crc_16 = BUILD_UINT16(crc[1], crc[0]);
if (crc16 != crc_16)
{
return;
}
// CRC校验通过后将数据长度-2
out_frame_len -= 2;
LOG_PRINT("data_analysis_event1 ok:");
LOG_HEX(frame, out_frame_len);
}
static void data_analysis_event2(void)
{
uint8_t frame[UART_RXSIZE];
uint8_t data_head[4];
uint8_t crc[2];
uint16_t frame_len, out_frame_len;
data_read(UART_DATA_ANALYSIS_PORT_2, &data_head[0], 4);
osel_memcpy((uint8_t *)&frame_len, &data_head[2], 2);
frame_len = B2S_UINT16(frame_len);
if (frame_len > UART_RXSIZE)
{
lock_data(UART_DATA_ANALYSIS_PORT_2);
unlock_data(UART_DATA_ANALYSIS_PORT_2);
return;
}
out_frame_len = data_read(UART_DATA_ANALYSIS_PORT_2, frame, (uint16_t)frame_len);
if (out_frame_len != frame_len)
{
return;
}
// 校验CRC_16
uint16_t crc_16 = 0;
uint16_t crc16 = crc16_compute(&frame[0], out_frame_len - 2);
osel_memcpy(&crc[0], &frame[out_frame_len - 2], 2);
crc_16 = BUILD_UINT16(crc[1], crc[0]);
if (crc16 != crc_16)
{
LOG_PRINT("crc error crc16:%x, crc_16:%x\n");
return;
}
out_frame_len -= 2; // 去掉CRC_16
LOG_PRINT("data_analysis_event2 ok:");
LOG_HEX(frame, out_frame_len);
}
/**
* @brief
* @return {*}
* @note
*/
static void data_register1(void)
{
/**
*
1 2 2 2 1 n 2 1
*/
#define FRAME_HEAD 0x05 // 帧头
#define FRAME_TAIL 0x1b // 帧尾
// 注册数据解析
data_reg_t reg;
reg.sd.valid = true; // 数据头部验证有效标志位
reg.sd.len = 1; // 数据头部长度
reg.sd.pos = 0; // 数据头部偏移量
reg.sd.data[0] = FRAME_HEAD; // 数据头部数据
reg.ld.len = 2; // 数据长度
reg.ld.pos = 2; // 报文长度包含帧长这里需要设置偏移2
reg.ld.valid = true; // 数据长度有效标志位
reg.ld.little_endian = false; // 数据长度是否小端模式
reg.argu.len_max = UART_RXSIZE; // 数据最大长度
reg.argu.len_min = 2; // 数据最小长度
reg.ed.valid = true; // 数据尾部有效标志位
reg.ed.len = 1; // 数据尾部长度
reg.ed.data[0] = FRAME_TAIL; // 数据尾部数据
reg.echo_en = false; // 是否回显
reg.func_ptr = data_analysis_event1; // 数据解析回调函数 data_analysis模块处理完数据后会调用这个函数继续数据协议的处理
uart_data_analysis_cb = data_fsm_init(UART_DATA_ANALYSIS_PORT_1); // 注册数据处理函数 data_analysis模块会调用这个函数将数据写入到data_analysis模块
data_reg(UART_DATA_ANALYSIS_PORT_1, reg); // 注册数据解析
}
/**
* @brief
* @return {*}
* @note
*/
static void data_register2(void)
{
/**
*
2 2 2 2 1 n 2
*/
#define FRAME_HEAD1 0xD5 // 帧头
#define FRAME_HEAD2 0xC8 // 帧尾
// 注册数据解析
data_reg_t reg;
reg.sd.valid = true; // 数据头部验证有效标志位
reg.sd.len = 2; // 数据头部长度
reg.sd.pos = 0; // 数据头部偏移量
reg.sd.data[0] = FRAME_HEAD1; // 数据头部数据
reg.sd.data[1] = FRAME_HEAD2; // 数据头部数据
reg.ld.len = 2; // 数据长度
reg.ld.pos = 2; // 报文长度包含帧长这里需要设置偏移2
reg.ld.valid = true; // 数据长度有效标志位
reg.ld.little_endian = false; // 数据长度是否小端模式
reg.argu.len_max = UART_RXSIZE; // 数据最大长度
reg.argu.len_min = 2; // 数据最小长度
reg.ed.valid = false; // 数据尾部有效标志位
reg.echo_en = false; // 是否回显
reg.func_ptr = data_analysis_event2; // 数据解析回调函数 data_analysis模块处理完数据后会调用这个函数继续数据协议的处理
uart_data_analysis_cb = data_fsm_init(UART_DATA_ANALYSIS_PORT_2); // 注册数据处理函数 data_analysis模块会调用这个函数将数据写入到data_analysis模块
data_reg(UART_DATA_ANALYSIS_PORT_2, reg); // 注册数据解析
}
int32_t main(void)
{
data_register1();
data_register2();
// 模拟串口数据
uint8_t data1[] = {0x05, 0x00, 0x0a, 0xff, 0xff, 0x00, 0x01, 0x00, 0x55, 0x40, 0x1b};
for (uint16_t i = 0; i < ARRAY_LEN(data1); i++)
{
uart_data_analysis_cb(UART_DATA_ANALYSIS_PORT_1, *(data1 + i));
}
// 模拟串口数据
uint8_t data2[] = {0xD5, 0xC8, 0x00, 0x07, 0xff, 0xff, 0x00, 0x01, 0x00, 0x55, 0x40};
for (uint16_t i = 0; i < ARRAY_LEN(data2); i++)
{
uart_data_analysis_cb(UART_DATA_ANALYSIS_PORT_2, *(data2 + i));
}
return 0;
}

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#include "../inc/data_type_def.h"
#include "../inc/log.h"
#include "../inc/osel_arch.h"
#include "../inc/sqqueue.h"
typedef struct
{
uint8_t x;
uint8_t y;
} element_t;
sqqueue_ctrl_t queue; // 创建队列对象
void traverse_cb(const void *e)
{
element_t *p = (element_t *)e;
LOG_PRINT("x = %d, y = %d", p->x, p->y);
}
int32_t main(void)
{
int size = 10;
// 初始化队列
if (FALSE == sqqueue_ctrl_init(&queue, sizeof(element_t), size))
{
LOG_ERR("queue init failed!");
return -1; // 创建失败
}
// 添加测试元素
for (int i = 1; i <= 10; i++)
{
element_t element;
element.x = i * 10;
element.y = i * 10;
queue.enter(&queue, &element); // 将成员插入到队列中
}
LOG_PRINT("add queue len = %d", queue.get_len(&queue)); // 获取队列长度
queue.del(&queue); // 移除首元素
LOG_PRINT("del queue len = %d", queue.get_len(&queue)); // 获取队列长度
queue.revoke(&queue); // 移除尾元素
LOG_PRINT("revoke queue len = %d", queue.get_len(&queue)); // 获取队列长度
queue.remove(&queue, 3); // 删除相对队头指定偏移位置的元素
LOG_PRINT("remove queue len = %d", queue.get_len(&queue)); // 获取队列长度
LOG_PRINT("queue traverse:");
queue.traverse(&queue, traverse_cb); // 遍历队列
queue.clear_sqq(&queue); // 清空队列
LOG_PRINT("clear queue len = %d", queue.get_len(&queue)); // 获取队列长度
return 0;
}

18
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{
"configurations": [
{
"name": "windows-gcc-x64",
"includePath": [
"${workspaceFolder}/**"
],
"compilerPath": "C:/TDM-GCC-64/bin/gcc.exe",
"cStandard": "${default}",
"cppStandard": "${default}",
"intelliSenseMode": "windows-gcc-x64",
"compilerArgs": [
""
]
}
],
"version": 4
}

24
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{
"version": "0.2.0",
"configurations": [
{
"name": "C/C++ Runner: Debug Session",
"type": "cppdbg",
"request": "launch",
"args": [],
"stopAtEntry": false,
"externalConsole": true,
"cwd": "e:/work/stm32/epm/User/lib/flow",
"program": "e:/work/stm32/epm/User/lib/flow/build/Debug/outDebug",
"MIMode": "gdb",
"miDebuggerPath": "gdb",
"setupCommands": [
{
"description": "Enable pretty-printing for gdb",
"text": "-enable-pretty-printing",
"ignoreFailures": true
}
]
}
]
}

58
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{
"C_Cpp_Runner.cCompilerPath": "gcc",
"C_Cpp_Runner.cppCompilerPath": "g++",
"C_Cpp_Runner.debuggerPath": "gdb",
"C_Cpp_Runner.cStandard": "",
"C_Cpp_Runner.cppStandard": "",
"C_Cpp_Runner.msvcBatchPath": "C:/Program Files/Microsoft Visual Studio/2022/Community/VC/Auxiliary/Build/vcvarsall.bat",
"C_Cpp_Runner.useMsvc": false,
"C_Cpp_Runner.warnings": [
"-Wall",
"-Wextra",
"-Wpedantic",
"-Wshadow",
"-Wformat=2",
"-Wcast-align",
"-Wconversion",
"-Wsign-conversion",
"-Wnull-dereference"
],
"C_Cpp_Runner.msvcWarnings": [
"/W4",
"/permissive-",
"/w14242",
"/w14287",
"/w14296",
"/w14311",
"/w14826",
"/w44062",
"/w44242",
"/w14905",
"/w14906",
"/w14263",
"/w44265",
"/w14928"
],
"C_Cpp_Runner.enableWarnings": true,
"C_Cpp_Runner.warningsAsError": false,
"C_Cpp_Runner.compilerArgs": [],
"C_Cpp_Runner.linkerArgs": [],
"C_Cpp_Runner.includePaths": [],
"C_Cpp_Runner.includeSearch": [
"*",
"**/*"
],
"C_Cpp_Runner.excludeSearch": [
"**/build",
"**/build/**",
"**/.*",
"**/.*/**",
"**/.vscode",
"**/.vscode/**"
],
"C_Cpp_Runner.useAddressSanitizer": false,
"C_Cpp_Runner.useUndefinedSanitizer": false,
"C_Cpp_Runner.useLeakSanitizer": false,
"C_Cpp_Runner.showCompilationTime": false,
"C_Cpp_Runner.useLinkTimeOptimization": false
}

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# flow_lib
#### 介绍
适用于嵌入式单片机的裸机程序微库只占用你的rom 6个字节是的6个字节。颠覆式的设计思维让你写代码的时候像flow(流水)一样丝滑让你永远不用在为delay时cpu空转而烦恼附加的超轻便的软件定时器让你轻松实现各种定时需求另还有信号量的配方让你任务间的同步像诗一样写意并且能让你裸机程序效率提升百倍以上。
#### 移植说明
移植特别简单flow_def.h有一个全局变量
```
extern unsigned long flow_tick;
```
把这个变量放在你的某个硬件中断里去这个硬件中断一定要是一直运行的推荐RTC半秒中断或者systick中断都可以。
然后在flow.h里的第一行有个宏
```
#define FL_HARD_TICK (500) /* 系统硬件中断一次所需要的时间单位ms */
```
把这里的值改成你的硬件中断一次所需的时间单位是毫秒比如你的flow_tick放在了一个500ms中断一次的rtc里那么这里的宏FL_HARD_TICK的值就是500具体中断设为多少取决于你的系统最短一次的延时的时间。
假如我的最短延时需求是100ms那么我就得给个100ms中断一次的硬件中断源宏FL_HARD_TICK的值就是100我就可以这样使用
```
FL_LOCK_DELAY(fl, FL_CLOCK_SEC /10);
```
来延时100ms。
#### 使用说明
核心文件时flow.h看这里的注释基本就会使用大部分功能。
```
#ifndef __FLOW_
#define __FLOW_
#include <flow_def.h>
#include <flow_core.h>
#include <flow_sem.h>
#define FL_HARD_TICK (500) /* 系统硬件中断一次所需要的时间单位ms */
#define FL_CLOCK_SEC (1000/FL_HARD_TICK) /* 一秒钟需要的tick可以除也可以自行添加其它宏 */
/**
* 初始化一个flow进程
*/
#define FL_INIT(fl) FLOW_INIT(fl)
/**
* flow头必须放在函数内的最前面
*/
#define FL_HEAD(fl) FLOW_HEAD(fl)
/**
* flow尾必须放在函数内的最后面
*/
#define FL_TAIL(fl) FLOW_TAIL(fl)
/**
* 给进程加锁直到judge为真加锁期间一直放开cpu给其他进程使用
*/
#define FL_LOCK_WAIT(fl, judge) FLOW_LOCK_WAIT(fl, judge)
/**
* 如果judge为真就一直给进程加锁加锁期间一直放开cpu给其他进程使用
*/
#define FL_LOCK_WHILE(fl, judge) FLOW_LOCK_WHILE(fl, judge)
/**
* 退出该进程
*/
#define FL_EXIT(fl) FLOW_EXIT(fl)
/**
* 无条件锁住进程一次,下次进来再接着往下运行
*/
#define FL_LOCK_ONCE(fl) FLOW_LOCK_ONCE(fl)
/**
* 等待一个flow进程结束
*/
#define FL_WAIT_PROCESS_END(fl, process) FLOW_WAIT_PROCESS_END(fl, process)
/**
* 等待一个flow子进程结束
*/
#define FL_WAIT_CHILD(fl, cfl, process) FLOW_WAIT_CHILD_PROCESS_END(fl, cfl, process)
/**
* 给进程加锁时长为time加锁期间一直放开cpu给其他进程使用time如果用FL_CLOCK_SEC来乘那么time的单位就是s
* 此处time必须是常数
*/
#define FL_LOCK_DELAY(fl,time) FLOW_LOCK_DELAY(fl,time)
/**
* 给进程加锁时长为time延时期间如果judge为真就直接解锁进程
* 此处time必须是常数
*/
#define FL_LOCK_DELAY_OR_WAIT(fl,judge,time) FLOW_LOCK_DELAY_OR_WAIT(fl,judge,time)
/**
* 初始化一个信号量
*/
#define FL_SEM_INIT(sem, count) FLOW_SEM_INIT(sem, count)
/**
* 给进程加锁,直到有信号释放
*/
#define FL_LOCK_WAIT_SEM(f, sem) FLOW_LOCK_WAIT_SEM(f, sem)
/**
* 给进程加锁直到有信号或者超时此处time可以为变量其他的接口处time必须是常数
*/
#define FL_LOCK_WAIT_SEM_OR_TIMEOUT(fl, sem, time) FLOW_LOCK_WAIT_SEM_OR_TIMEOUT(fl, sem, time)
/**
* 释放一个信号量
*/
#define FL_SEM_RELEASE(sem) FLOW_SEM_RELEASE(sem)
/**
* 初始化一个软件定时器
*/
void fl_timer_set(struct flow_timer *t, unsigned long interval);
/**
* 复位一个软件定时器
*/
void fl_timer_reset(struct flow_timer *t);
/**
* 重启一个软件定时器
*/
void fl_timer_restart(struct flow_timer *t);
/**
* 检测一个软件定时器是否超时0为不超时1为超时
*/
char fl_timer_timeout(struct flow_timer *t);
/**
* 检测一个软件定时器还剩多少时间超时单位为硬件tick比如硬件tick 500ms中断一次那么
* 返回的时间单位就是500ms
*/
unsigned long fl_hour_much_time(struct flow_timer *t);
#endif /* __FLOW_ */
```
简单举个例子先从需求说起假如说你现在需要一个函数这个函数的功能是每隔1s让你的led亮一次正常设计的要么起个软件定时器或者硬件定时器甚至状态机可以实现需求但是都太low了让我们看一下如何用flow库来实现这个函数。
该函数格式如下:
```
char led_flash(struct flow *fl)
{}
```
其中char、struct flow *fl是必备的。
再来看看函数里面的内容格式:
```
char led_flash(struct flow *fl)
{
FL_HEAD(fl);
FL_TAIL(fl);
}
```
函数里面的FL_HEAD和FL_TAIL是使用flow库的所必须的宏FL_HEAD(fl)放到函数的最前面如果你的函数内部有变量定义的话放在变量定义的后面。而FL_TAIL(fl)是放在函数最后面一行的。
基本格式有了再来看下如何实现延时一秒呢其实只用一个语句就OK。
```
char led_flash(struct flow *fl)
{
FL_HEAD(fl);
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_open();
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_close();
FL_TAIL(fl);
}
```
是的你没看错仅仅只需要FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1)这一个语句就OK当执行到这个语句的时候该函数就会让出CPU权限当延时时间到了之后就会回来接着执行FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1)下面的语句。一直到FL_TAIL(fl),该函数就会结束任务,再也不会执行了,那么如果我们想让它一直循环执行呢?看下面:
```
char led_flash(struct flow *fl)
{
FL_HEAD(fl);
while(1)
{
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_open();
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_close();
}
FL_TAIL(fl);
}
```
看起来像不像个进程?其实也有点操作系统的样子了。。。
光有这个函数也不行,还得进行一些额外的操作
比如:
```
static struct flow fl_led; /* 1定义一个struct flow变量给这个函数使用 */
static char led_flash(struct flow *fl)
{
FL_HEAD(fl);
led_init(); /* 这里还能解决你的初始化问题,这里的函数只会在开机时或者说进程第一次进来时运行一次,以后将永远不会运行。注意:如果放在
FL_HEAD(fl)前面,那么就是每次轮到这个进程运行的时侯就会运行一次,总之很灵活 */
while(1)
{
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_open();
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
led_close();
}
FL_TAIL(fl);
}
int main(void)
{
FL_INIT(&fl_led); /* 2初始化struct flow变量 */
while(1)
{
led_flash(&fl_led); /* 3把led_flash进程放在main函数的while循环里 */
...
}
return 0;
}
```
经过以上3步就可以实现进程之间的切换啦。然后想根据某个条件来锁住线程释放CPU的话可以把里面的
```
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1);
```
换成
```
FL_LOCK_WAIT(fl, judge);
```
当里面的judge为假时线程就一直锁住在这一行语句当judge为真时就可以往下执行啦。同理可以完成很多其他的神奇功能让你的cpu再也不空转啦具体请看flow.h文件。。。。
这个版本暂时先写这么多先看看example.c。

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#include "flow.h"
/* 1初始化一个struct flow变量 */
static struct flow fl_led;
static char led_flash(struct flow *fl)
{
FL_HEAD(fl);
for (;;)
{
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1U); /* 延时一秒 */
led_open();
FL_LOCK_DELAY(fl, FL_CLOCK_SEC * 1U); /* 延时一秒 */
led_close();
}
FL_TAIL(fl);
}
int main(void)
{
FL_INIT(&fl_led);
for (;;)
{
led_flash(&fl_led);
// other_process();
}
return 0;
}

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/**
* @file flow.h
* @author: xxx
* @date: 2023-07-21 17:00:15
* @brief
* @copyright: Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __FLOW_
#define __FLOW_
#include "flow_def.h"
#include "flow_core.h"
#include "flow_sem.h"
#define FL_HARD_TICK (10U) /* 系统硬件中断一次所需要的时间单位ms */
#define FL_CLOCK_SEC (1000U / FL_HARD_TICK) /* 一秒钟需要的tick可以根据需求添加其他时间更短的宏 */
#define FL_CLOCK_100MSEC (100U / FL_HARD_TICK)
#define FL_CLOCK_10MSEC (FL_CLOCK_100MSEC / 10U)
/**
* flow进程
*/
#define FL_INIT(fl) FLOW_INIT((fl))
/**
* flow头
*/
#define FL_HEAD(fl) FLOW_HEAD((fl))
/**
* flow尾
*/
#define FL_TAIL(fl) FLOW_TAIL((fl))
/**
* judge为真cpu给其他进程使用
*/
#define FL_LOCK_WAIT(fl, judge) FLOW_LOCK_WAIT((fl), (judge))
/**
* judge为真cpu给其他进程使用
*/
#define FL_LOCK_WHILE(fl, judge) FLOW_LOCK_WHILE((fl), (judge))
/**
* 退
*/
#define FL_EXIT(fl) FLOW_EXIT((fl))
/**
*
*/
#define FL_LOCK_ONCE(fl) FLOW_LOCK_ONCE((fl))
/**
* flow进程结束
*/
#define FL_WAIT_PROCESS_END(fl, process) FLOW_WAIT_PROCESS_END((fl), (process))
/**
* flow子进程结束
*/
#define FL_WAIT_CHILD(fl, cfl, process) FLOW_WAIT_CHILD_PROCESS_END((fl), (cfl), (process))
/**
* timecpu给其他进程使用time如果用FL_CLOCK_SEC来乘time的单位就是s
* time必须是常数
*/
#define FL_LOCK_DELAY(fl, time) FLOW_LOCK_DELAY((fl), (time))
/**
* timejudge为真
* time必须是常数
*/
#define FL_LOCK_DELAY_OR_WAIT(fl, judge, time) FLOW_LOCK_DELAY_OR_WAIT((fl), (judge), (time))
/**
*
*/
#define FL_SEM_INIT(sem, count) FLOW_SEM_INIT((sem), (count))
/**
*
*/
#define FL_LOCK_WAIT_SEM(fl, sem) FLOW_LOCK_WAIT_SEM((fl), (sem))
/**
* time可以为常数或者变量time必须是常数
*/
#define FL_LOCK_WAIT_SEM_OR_TIMEOUT(fl, sem, time) FLOW_LOCK_WAIT_SEM_OR_TIMEOUT((fl), (sem), (time))
/**
*
*/
#define FL_SEM_RELEASE(sem) FLOW_SEM_RELEASE((sem))
/**
*
*/
#define FL_SEM_IS_RELEASE(fl, sem) FLOW_SEM_IS_RELEASE((fl), (sem))
/**
*
*/
void fl_timer_set(struct flow_timer *t, unsigned long interval);
/**
*
*/
void fl_timer_reset(struct flow_timer *t);
/**
*
*/
void fl_timer_restart(struct flow_timer *t);
/**
* 01
*/
unsigned char fl_timer_timeout(struct flow_timer *t);
/**
* ticktick 500ms中断一次
* 500ms*n
*/
unsigned long fl_hour_much_time(struct flow_timer *t);
#endif /* __FLOW_ */

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/**
* @file
* @author xxx
* @date 2023-07-21 17:00:15
* @brief
* @copyright Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#include "flow.h"
unsigned long flow_tick;
/**
* @brief
* @param t
* @param interval
* @return NULL
* @note occurs时开始
*/
void fl_timer_set(struct flow_timer *t, unsigned long interval)
{
if (interval == 0)
{
// 如果间隔时间为零,返回错误
return;
}
t->interval = interval;
t->start = flow_tick;
}
/**
* @brief
* @param t
* @return NULL
* @note occurs时开始
*/
void fl_timer_reset(struct flow_timer *t)
{
t->start += t->interval;
}
/**
* @brief
* @param t
* @return NULL
* @note flow_tick
*/
void fl_timer_restart(struct flow_timer *t)
{
t->start = flow_tick;
}
/**
* @brief flow_timer结构体的超时状态
* @param {flow_timer} *t flow_timer结构体的指针
* @return {unsigned char} 10
* @note flow_timer结构体中的start时间之差是否大于或等于interval
*/
unsigned char fl_timer_timeout(struct flow_timer *t)
{
return ((flow_tick - t->start) >= t->interval) ? 1U : 0U;
}
/**
* @brief flow_timer结构体中的时间长度
* @param {flow_timer} *t flow_timer结构体的指针
* @return {unsigned long}
* @note start时间加上interval与当前时间flow_tick之差flow_ticktime_len - flow_tick0
*/
unsigned long fl_hour_much_time(struct flow_timer *t)
{
unsigned long time_len = t->start + t->interval;
if (time_len >= flow_tick)
{
return (time_len - flow_tick);
}
else
{
return 0U;
}
}

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/**
* @file flow_core.h
* @author: xxx
* @date: 2023-07-21 17:00:15
* @brief
* @copyright: Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __FLOW_CORE_
#define __FLOW_CORE_
#include "flow_def.h"
// 在定时器中断中调用
#define FLOW_TICK_UPDATE() \
do \
{ \
flow_tick++; \
} while (0);
// 初始化一个flow进程
#define FLOW_INIT(f) ((f)->line = 0)
// flow头必须放在函数内的最前面
#define FLOW_HEAD(f) \
{ \
volatile char lock_once_flag = 0; \
switch ((f)->line) \
{ \
case 0:
// flow尾必须放在函数内的最后面
#define FLOW_TAIL(f) \
} \
; \
lock_once_flag = (f)->line = 0; \
return FLOW_END; \
} \
;
// 给进程加锁直到judge为真加锁期间一直放开cpu给其他进程使用
#define FLOW_LOCK_WAIT(f, judge) \
do \
{ \
(f)->line = __LINE__; \
case __LINE__:; \
if (!(judge)) \
return FLOW_WAIT; \
} while (0)
// 如果judge为真就一直给进程加锁加锁期间一直放开cpu给其他进程使用
#define FLOW_LOCK_WHILE(f, judge) \
do \
{ \
(f)->line = __LINE__; \
case __LINE__:; \
if (judge) \
return FLOW_WAIT; \
} while (0)
// 退出该进程
#define FLOW_EXIT(f) \
do \
{ \
(f)->line = 0; \
return FLOW_FINISH; \
} while (0)
// 无条件锁住进程一次,下次进来再接着往下运行
#define FLOW_LOCK_ONCE(f) \
do \
{ \
lock_once_flag = 1; \
(f)->line = __LINE__; \
case __LINE__:; \
if (lock_once_flag) \
return FLOW_LOCK; \
} while (0)
// 等待一个flow进程结束
#define FLOW_WAIT_PROCESS_END(f, process) FLOW_LOCK_WHILE(f, (process) < FLOW_FINISH)
// 等待一个flow子进程结束
#define FLOW_WAIT_CHILD_PROCESS_END(f, cf, process) \
do \
{ \
FLOW_INIT((cf)); \
FLOW_WAIT_PROCESS_END((f), (process)); \
} while (0)
// 给进程加锁时长为time加锁期间一直放开cpu给其他进程使用time如果用FL_CLOCK_SEC来乘那么time的单位就是s
#define FLOW_LOCK_DELAY(f, t) \
do \
{ \
(f)->time = flow_tick; \
FLOW_LOCK_WAIT((f), ((flow_tick - (f)->time) >= (t))); \
} while (0)
// 给进程加锁时长为time延时期间如果judge为真就直接解锁进程
#define FLOW_LOCK_DELAY_OR_WAIT(f, judge, t) \
do \
{ \
(f)->time = flow_tick; \
FLOW_LOCK_WAIT((f), ((judge) || ((flow_tick - (f)->time) >= (t)))); \
} while (0)
#endif /* __FLOW_CORE_ */

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/**
* @file flow_def.h
* @author: xxx
* @date: 2023-07-21 17:00:15
* @brief
* @copyright: Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __FLOW_DEF_
#define __FLOW_DEF_
#define FLOW_WAIT (0)
#define FLOW_LOCK (1)
#define FLOW_FINISH (2)
#define FLOW_END (3)
struct flow
{
unsigned long line;
unsigned long time;
};
struct flow_timer
{
unsigned long start;
unsigned long interval;
};
struct flow_sem
{
unsigned long count;
unsigned long time;
};
extern unsigned long flow_tick;
#endif /* __FLOW_DEF_ */

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/***
* @file:
* @author: xxx
* @date: 2023-07-21 17:00:15
* @brief
* @copyright: Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __FLOW_SEM_H__
#define __FLOW_SEM_H__
#include "flow_def.h"
#include "flow_core.h"
#define FLOW_SEM_INIT(s, c) ((s)->count = c) // 初始化信号量s的计数值为c
// 等待信号量s的计数值大于0
#define FLOW_LOCK_WAIT_SEM(f, s) \
do \
{ \
FLOW_LOCK_WAIT(f, (s)->count > 0); \
--(s)->count; \
} while (0)
// 等待信号量s的计数值大于0或者当前时间与锁f的时间之差大于等于t
#define FLOW_LOCK_WAIT_SEM_OR_TIMEOUT(f, s, t) \
do \
{ \
(f)->time = flow_tick; \
(s)->time = (t); \
FLOW_LOCK_WAIT(f, (((s)->count > 0) || ((flow_tick - (f)->time) >= ((s)->time)))); \
if (((s)->count > 0) && ((flow_tick - (f)->time) < ((s)->time))) \
--(s)->count; \
} while (0)
#define FLOW_SEM_RELEASE(s) (++(s)->count)
#define FLOW_SEM_IS_RELEASE(f, s) (flow_tick - (f)->time) < ((s)->time)
#endif /* __FLOW_SEM_H__ */

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/*
---------------------------------------------------------------------------
Copyright (c) 1998-2008, Brian Gladman, Worcester, UK. All rights reserved.
LICENSE TERMS
The redistribution and use of this software (with or without changes)
is allowed without the payment of fees or royalties provided that:
1. source code distributions include the above copyright notice, this
list of conditions and the following disclaimer;
2. binary distributions include the above copyright notice, this list
of conditions and the following disclaimer in their documentation;
3. the name of the copyright holder is not used to endorse products
built using this software without specific written permission.
DISCLAIMER
This software is provided 'as is' with no explicit or implied warranties
in respect of its properties, including, but not limited to, correctness
and/or fitness for purpose.
---------------------------------------------------------------------------
Issue 09/09/2006
This is an AES implementation that uses only 8-bit byte operations on the
cipher state.
*/
#ifndef AES_H
#define AES_H
#if 1
#define AES_ENC_PREKEYED /* AES encryption with a precomputed key schedule */
#endif
#if 1
#define AES_DEC_PREKEYED /* AES decryption with a precomputed key schedule */
#endif
#if 0
#define AES_ENC_128_OTFK /* AES encryption with 'on the fly' 128 bit keying */
#endif
#if 0
#define AES_DEC_128_OTFK /* AES decryption with 'on the fly' 128 bit keying */
#endif
#if 0
#define AES_ENC_256_OTFK /* AES encryption with 'on the fly' 256 bit keying */
#endif
#if 0
#define AES_DEC_256_OTFK /* AES decryption with 'on the fly' 256 bit keying */
#endif
#define N_ROW 4
#define N_COL 4
#define N_BLOCK (N_ROW * N_COL)
#define N_MAX_ROUNDS 14
typedef uint8_t return_type;
/* Warning: The key length for 256 bit keys overflows a byte
(see comment below)
*/
typedef uint8_t length_type;
typedef struct
{
uint8_t ksch[(N_MAX_ROUNDS + 1) * N_BLOCK];
uint8_t rnd;
} aes_context;
/* The following calls are for a precomputed key schedule
NOTE: If the length_type used for the key length is an
unsigned 8-bit character, a key length of 256 bits must
be entered as a length in bytes (valid inputs are hence
128, 192, 16, 24 and 32).
*/
#if defined(AES_ENC_PREKEYED) || defined(AES_DEC_PREKEYED)
return_type aes_set_key(const uint8_t key[],
length_type keylen,
aes_context ctx[1]);
#endif
#if defined(AES_ENC_PREKEYED)
return_type aes_encrypt(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const aes_context ctx[1]);
return_type aes_cbc_encrypt(const uint8_t *in,
uint8_t *out,
int32_t n_block,
uint8_t iv[N_BLOCK],
const aes_context ctx[1]);
#endif
#if defined(AES_DEC_PREKEYED)
return_type aes_decrypt(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const aes_context ctx[1]);
return_type aes_cbc_decrypt(const uint8_t *in,
uint8_t *out,
int32_t n_block,
uint8_t iv[N_BLOCK],
const aes_context ctx[1]);
#endif
/* The following calls are for 'on the fly' keying. In this case the
encryption and decryption keys are different.
The encryption subroutines take a key in an array of bytes in
key[L] where L is 16, 24 or 32 bytes for key lengths of 128,
192, and 256 bits respectively. They then encrypts the input
data, in[] with this key and put the reult in the output array
out[]. In addition, the second key array, o_key[L], is used
to output the key that is needed by the decryption subroutine
to reverse the encryption operation. The two key arrays can
be the same array but in this case the original key will be
overwritten.
In the same way, the decryption subroutines output keys that
can be used to reverse their effect when used for encryption.
Only 128 and 256 bit keys are supported in these 'on the fly'
modes.
*/
#if defined(AES_ENC_128_OTFK)
void aes_encrypt_128(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const uint8_t key[N_BLOCK],
uint8_t o_key[N_BLOCK]);
#endif
#if defined(AES_DEC_128_OTFK)
void aes_decrypt_128(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const uint8_t key[N_BLOCK],
uint8_t o_key[N_BLOCK]);
#endif
#if defined(AES_ENC_256_OTFK)
void aes_encrypt_256(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const uint8_t key[2 * N_BLOCK],
uint8_t o_key[2 * N_BLOCK]);
#endif
#if defined(AES_DEC_256_OTFK)
void aes_decrypt_256(const uint8_t in[N_BLOCK],
uint8_t out[N_BLOCK],
const uint8_t key[2 * N_BLOCK],
uint8_t o_key[2 * N_BLOCK]);
#endif
#endif

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/**
* @file clist.h
* @author xxx
* @date 2023-08-08 23:18:15
* @brief 使 lib\examples\simple_clist.c
* @copyright Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __CLIST_H
#define __CLIST_H
#include "lib.h"
typedef void *cnode;
/// 链表中一个节点的结构体
typedef struct CLIST_NODE
{
cnode data; /// 值
struct CLIST_NODE *Next; /// 指向下一个结点
} clist_node_t;
void clist_init(clist_node_t **ppFirst); ///< 初始化 ,构造一条空的链表
void clist_print(clist_node_t *First); ///< 打印链表
uint32_t clist_node_count(clist_node_t *First); ///< 获取链表节点数
void clist_push_back(clist_node_t **ppFirst, cnode data); ///< 尾部插入
void clist_push_front(clist_node_t **ppFirst, cnode data); ///< 头部插入
void clist_pop_back(clist_node_t **ppFirst); ///< 尾部删除
void clist_pop_front(clist_node_t **ppFirst); ///< 头部删除
void clist_insert_for_node(clist_node_t **ppFirst, clist_node_t *pPos, cnode data); ///< 给定结点插入,插入到结点前
int32_t clist_insert(clist_node_t **ppFirst, int32_t Pos, cnode data); ///< 按位置插入
void clist_erase_for_node(clist_node_t **ppFirst, clist_node_t *pPos); ///< 给定结点删除
void clist_remove(clist_node_t **ppFirst, cnode data); ///< 按值删除,只删遇到的第一个
void clist_remove_all(clist_node_t **ppFirst, cnode data); ///< 按值删除,删除所有的
void clist_destroy(clist_node_t **ppFirst); ///< 销毁 ,需要销毁每一个节点
clist_node_t *clist_find(clist_node_t *pFirst, cnode data); ///< 按值查找,返回第一个找到的结点指针,如果没找到,返回 NULL
#endif //__CLIST_H

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/**************************************************************************
Copyright (C) 2009 Lander Casado, Philippas Tsigas
All rights reserved.
Permission is hereby granted, free of charge, to any person obtaining
a copy of this software and associated documentation files
(the "Software"), to deal with the Software without restriction, including
without limitation the rights to use, copy, modify, merge, publish,
distribute, sublicense, and/or sell copies of the Software, and to
permit persons to whom the Software is furnished to do so, subject to
the following conditions:
Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimers. Redistributions in
binary form must reproduce the above copyright notice, this list of
conditions and the following disclaimers in the documentation and/or
other materials provided with the distribution.
In no event shall the authors or copyright holders be liable for any special,
incidental, indirect or consequential damages of any kind, or any damages
whatsoever resulting from loss of use, data or profits, whether or not
advised of the possibility of damage, and on any theory of liability,
arising out of or in connection with the use or performance of this software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS WITH THE SOFTWARE
*****************************************************************************/
#ifndef _CMAC_H_
#define _CMAC_H_
#include "aes.h"
#define AES_CMAC_KEY_LENGTH 16
#define AES_CMAC_DIGEST_LENGTH 16
typedef struct _AES_CMAC_CTX
{
aes_context rijndael;
uint8_t X[16];
uint8_t M_last[16];
uint32_t M_n;
} AES_CMAC_CTX;
// #include <sys/cdefs.h>
//__BEGIN_DECLS
void AES_CMAC_Init(AES_CMAC_CTX *ctx);
void AES_CMAC_SetKey(AES_CMAC_CTX *ctx, const uint8_t key[AES_CMAC_KEY_LENGTH]);
void AES_CMAC_Update(AES_CMAC_CTX *ctx, const uint8_t *data, uint32_t len);
// __attribute__((__bounded__(__string__,2,3)));
void AES_CMAC_Final(uint8_t digest[AES_CMAC_DIGEST_LENGTH], AES_CMAC_CTX *ctx);
// __attribute__((__bounded__(__minbytes__,1,AES_CMAC_DIGEST_LENGTH)));
//__END_DECLS
#endif /* _CMAC_H_ */

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/**
* @file cmd.h
* @author xxx
* @date 2023-06-25 13:07:02
* @brief
* @copyright Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef _CMD_H_
#define _CMD_H_
#define CMD_HASH 0xb433e5c6
#if defined(__CC_ARM) || defined(__CLANG_ARM) /* ARM Compiler */
#define SECTION(x) __attribute__((section(x)))
#define CMD_USED __attribute__((used))
#elif defined(__IAR_SYSTEMS_ICC__) /* IAR Compiler */
#define SECTION(x) @x
#define CMD_USED __root
#else
#error "not supported tool chain..."
#endif
typedef void (*cmd_handler)(void);
typedef struct cmd
{
const char *cmd;
const char *cmd_mess;
unsigned int hash;
cmd_handler handler;
} cmd_t;
/// 注册命令
#define REGISTER_CMD(cmd, handler, desc) \
const char _register_##cmd##_cmd[] = #cmd; \
const char _register_##cmd##_desc[] = #desc; \
CMD_USED cmd_t _register_##cmd SECTION("CMDS") = \
{ \
_register_##cmd##_cmd, \
_register_##cmd##_desc, \
(unsigned int)CMD_HASH, \
(cmd_handler)&handler};
void cmd_init(void); ///< 初始化命令
void cmd_parsing(char *str); ///< 命令解析
#endif

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/**
* @file data_analysis.h
* @author xxx
* @date 2023-06-25 13:07:02
* @brief
* @copyright Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef COMPONENTS_COMMON_INCLUDE_DATA_ANALYSIS_H_
#define COMPONENTS_COMMON_INCLUDE_DATA_ANALYSIS_H_
#include "data_type_def.h"
typedef enum
{
DATA_1,
DATA_2,
DATA_MAX,
} DataId_t; // 处理数据模块的个数,请根据实际情况修改
#define DATA_NUM (DATA_MAX)
#define DATA_BUF_RECV_SQQ_LEN 650u
#define DATA_BUF_SEND_SQQ_LEN 0u
#define DATA_SD_LEN_MAX 2
#define DATA_LD_LEN_MAX 2
#define DATA_ED_LEN_MAX 1
typedef struct _data_reg_t_
{
struct
{
uint8_t len;
uint8_t pos;
uint8_t data[DATA_SD_LEN_MAX];
BOOL valid; // 是否有效
} sd; // start delimiter
struct
{
uint8_t len;
uint8_t pos; // 偏移量在wait_end_state中根据帧长去掉固定长度来判断是否是结束符
uint8_t little_endian;
BOOL valid; // 是否有效
} ld; // length describe
struct
{
uint16_t len_max;
uint16_t len_min;
} argu;
struct
{
uint8_t len;
uint8_t data[DATA_ED_LEN_MAX];
BOOL valid;
} ed;
BOOL echo_en;
void (*func_ptr)(void);
} data_reg_t;
typedef void (*data_interupt_cb_t)(uint8_t id, uint8_t ch); ///< 中断回调函数,数据从这里写入
extern uint8_t data_read(uint8_t id, void *buffer, uint16_t len); ///< 读取数据
extern void data_write(uint8_t id, uint8_t *const string, uint16_t len); ///< TODO 写入数据
extern void lock_data(uint8_t data_id); ///< 锁定数据,防止中断写入数据
extern void unlock_data(uint8_t data_id); ///< 解锁数据
extern data_interupt_cb_t data_fsm_init(uint8_t data_id); ///< 初始化数据状态机
extern BOOL data_reg(uint8_t id, data_reg_t reg); ///< 注册数据
extern void data_unreg(uint8_t id); ///< 注销数据
#endif /* COMPONENTS_COMMON_INCLUDE_DATA_ANALYSIS_H_ */

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/***
* @Author:
* @Date: 2023-03-29 13:16:28
* @LastEditors: xxx
* @LastEditTime: 2023-03-30 00:34:11
* @Description:
* @email:
* @Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __DATA_TYPE_DEF_H_
#define __DATA_TYPE_DEF_H_
#include <stdint.h>
#ifndef PI
#define PI (3.14159265358979323846f)
#endif
#ifndef TRUE
#define TRUE 1
#define FALSE 0
#endif
#ifndef OK
typedef enum
{
OK = 0,
FAIL = !OK,
} state_e;
#endif
#ifndef __IO
#define __IO volatile
#endif
typedef unsigned char BOOL; /* boolean data */
typedef unsigned char bool_t; /* boolean data */
#if !defined(__stdint_h) && !defined(_GCC_WRAP_STDINT_H)
typedef unsigned char uint8_t;
typedef unsigned short int uint16_t;
typedef unsigned long int uint32_t;
typedef unsigned long long uint64_t;
typedef signed char int8_t;
typedef signed short int int16_t;
typedef signed long int int32_t;
typedef long long int64_t;
#endif
typedef float float32;
typedef double float64;
#ifndef float32_t
typedef float float32_t;
#endif
#ifndef float64_t
typedef double float64_t;
#endif
#pragma pack(1)
typedef struct
{
uint8_t bs[3];
} uint24_t;
typedef struct
{
uint8_t bs[5];
} uint40_t;
typedef union
{
float32 f;
int32_t c;
} float32_u;
#pragma pack()
typedef enum
{
DATA_TYPE_INT8 = 0, // 8-bit signed integer
DATA_TYPE_UINT8, // 8-bit unsigned integer
DATA_TYPE_INT16, // 16-bit signed integer
DATA_TYPE_UINT16, // 16-bit unsigned integer
DATA_TYPE_INT32, // 32-bit signed integer
DATA_TYPE_UINT32, // 32-bit unsigned integer
DATA_TYPE_INT64, // 64-bit signed integer
DATA_TYPE_UINT64, // 64-bit unsigned integer
DATA_TYPE_FLOAT, // 32-bit floating point number
DATA_TYPE_DOUBLE, // 64-bit floating point number
DATA_TYPE_STRING, // string
DATA_TYPE_ARRAY, // array
DATA_TYPE_STRUCT, // structure
DATA_TYPE_UNION, // union
DATA_TYPE_ENUM, // enumeration
DATA_TYPE_POINTER, // pointer
DATA_TYPE_FUNCTION, // function
DATA_TYPE_VOID, // void
DATA_TYPE_MAX,
} data_type_e;
typedef uint16_t nwk_id_t;
/**
* STANDARD BITS
*/
#ifndef BIT0
#define BIT0 (0x01u)
#define BIT1 (0x02u)
#define BIT2 (0x04u)
#define BIT3 (0x08u)
#define BIT4 (0x10u)
#define BIT5 (0x20u)
#define BIT6 (0x40u)
#define BIT7 (0x80u)
#define BIT8 (0x0100u)
#define BIT9 (0x0200u)
#define BIT10 (0x0400u)
#define BIT11 (0x0800u)
#define BIT12 (0x1000u)
#define BIT13 (0x2000u)
#define BIT14 (0x4000u)
#define BIT15 (0x8000u)
#define BIT16 (0x00010000u)
#define BIT17 (0x00020000u)
#define BIT18 (0x00040000u)
#define BIT19 (0x00080000u)
#define BIT20 (0x00100000u)
#define BIT21 (0x00200000u)
#define BIT22 (0x00400000u)
#define BIT_SET(x, b) x |= b // 置位
#define BIT_CLR(x, b) x &= ~b // 清零
#define BIT_IS_SET(x, b) ((x) & (b)) // 判断某一位是否为1
#define BIT_IS_CLR(x, b) (!((x) & (b))) // 判断某一位是否为0
#endif
#ifndef BF
/**
* @brief
* @return {*}
* @note
*> uint8_t num = 0x12; 00010010 <p>
*> uint8_t bit = 2; 20 <p>
*> uint8_t width = 1; 1 <p>
*> uint8_t result = BF(num, bit, width); 1 <p>
*/
#define BF(x, b, s) (((x) & (b)) >> (s))
#endif
#ifndef MIN
/**
* @brief
* @return {*}
* @note
*> int num1 = 10; <p>
*> int num2 = 20; <p>
*> int result = MIN(num1, num2); // 结果为10 <p>
*/
#define MIN(n, m) (((n) < (m)) ? (n) : (m))
#endif
#ifndef MAX
/**
* @brief
* @return {*}
* @note
*> int num1 = 10; <p>
*> int num2 = 20; <p>
*> int result = MAX(num1, num2); // 结果为20 <p>
*/
#define MAX(n, m) (((n) < (m)) ? (m) : (n))
#endif
#ifndef ABS
/**
* @brief
* @return {*}
* @note
*> int num = -10;
*> int result = ABS(num); // 结果为10
*/
#define ABS(n) (((n) < 0) ? -(n) : (n))
#endif
#ifndef RANGE
#define RANGE(x, a, b) (MIN(MAX(x, a), b))
#endif
/**
* @brief Macro to check if a value is between a minimum and maximum value (inclusive).
* @param x The value to check.
* @param min The minimum value.
* @param max The maximum value.
* @return Returns 1 if the value is between the minimum and maximum values (inclusive), 0 otherwise.
*/
#define IS_BETWEEN(x, min, max) ((x) >= min && (x) <= max)
#define ARRAY_LEN(arr) (sizeof(arr)) / (sizeof(arr[0]))
#define HI_UINT16(a) (((uint16_t)(a) >> 8) & 0xFF)
#define LO_UINT16(a) ((uint16_t)(a) & 0xFF)
#define HI_1_UINT32(a) (((uint32_t)(a) >> 24) & 0xFF)
#define HI_2_UINT32(a) (((uint32_t)(a) >> 16) & 0xFF)
#define HI_3_UINT32(a) (((uint32_t)(a) >> 8) & 0xFF)
#define HI_4_UINT32(a) ((uint32_t)(a) & 0xFF)
#define LO_1_UINT8(a) (uint8_t)((a) & 0xFF)
#define LO_2_UINT8(a) (uint8_t)(((a) & 0xFF00) >> 8)
#define LO_3_UINT8(a) (uint8_t)(((a) & 0xFF0000) >> 16)
#define LO_4_UINT8(a) (uint8_t)(((a) & 0xFF000000) >> 24)
// uint32小端转大端
#define S2B_UINT32(a) \
(((uint32_t)(a) & 0xFF000000) >> 24) + (((uint32_t)(a) & 0x00FF0000) >> 8) + (((uint32_t)(a) & 0x0000FF00) << 8) + (((uint32_t)(a) & 0x000000FF) << 24)
// uint32大端转小端
#define B2S_UINT32(a) S2B_UINT32(a)
// uint16小端转大端
#define S2B_UINT16(a) ((((uint16_t)(a) & 0xFF00) >> 8) + (((uint16_t)(a) & 0x00FF) << 8))
// uint16大端转小端
#define B2S_UINT16(a) S2B_UINT16(a)
#define BUILD_UINT16(loByte, hiByte) \
((uint16_t)(((loByte) & 0x00FF) + (((hiByte) & 0x00FF) << 8)))
// float32小端转大端
static inline float32 S2B_FLOAT32(float fv)
{
float32_u _f;
_f.f = fv;
_f.c = S2B_UINT32(_f.c);
return _f.f;
}
// float32大端转小端
#define B2S_FLOAT32(a) S2B_FLOAT32(a)
// 反序数组
#define REVERSE_ARRAY(arr, len) \
do \
{ \
uint8_t _tmp; \
uint16_t _i; \
for (_i = 0; _i < len / 2; _i++) \
{ \
_tmp = arr[_i]; \
arr[_i] = arr[len - _i - 1]; \
arr[len - _i - 1] = _tmp; \
} \
} while (0);
// 比较2个数组是否相等
#define IsEqual(arr1, arr2, n) ({ \
int _equal = 1; \
for (int _i = 0; _i < n; _i++) \
{ \
if (arr1[_i] != arr2[_i]) \
{ \
_equal = 0; \
break; \
} \
} \
_equal; \
})
// ASSIC码转换为数字
#define ASCII_TO_NUM(c) ((c) >= '0' && (c) <= '9' ? (c) - '0' : (c) - 'A' + 10)
// 数字转换为ASSIC码
#define NUM_TO_ASCII(x) ((x) < 10 ? (x) + '0' : (x) - 10 + 'A')
#define FLOAT_TO_UINT16(x) (x * 8192 / 100 + 2048) ///> 浮点压缩uint16_t
#define UINT16_TO_FLOAT(x) (100 * (x - 2048) / 8192) ///> uint16转浮点
#endif /* __DATA_TYPE_DEF_H_ */

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/***
* @Author:
* @Date: 2023-04-04 08:13:11
* @LastEditors: xxx
* @LastEditTime: 2023-04-04 13:21:46
* @Description:
* @email:
* @Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __DEBUG_H
#define __DEBUG_H
#include "lib.h"
/*形参*/
#define _DBG_LINE_ , uint16_t line
/*实参*/
#define __DBG_LINE , __LINE__
extern BOOL DBG_ASSERT(uint8_t cond _DBG_LINE_);
#endif //__DEBUG_H

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/**
* @file filter.h
* @author xxx
* @date 2023-08-08 22:59:46
* @brief
* @copyright Copyright (c) 2023 by xxx, All Rights Reserved.
*/
#ifndef __FILTER_H__
#define __FILTER_H__
#include "lib.h"
typedef struct
{
float32 x; // 卡尔曼滤波器的估计值
float32 a; // 状态转移矩阵1表示没有动态变化
float32 h; // 观测矩阵1表示直接观测
float32 q; // 过程噪声协方差
float32 r; // 观测噪声协方差
float32 p; // 估计误差协方差
float32 gain; // 卡尔曼增益
float32 change_max; // 允许的最大变化量,用于判断观测值是否异常
} kalman_t; // 卡尔曼滤波器结构
typedef struct
{
BOOL fisrt_flag; // 第一次标志位
float32 alpha; // 滤波系数 0~1
float32 last_value; // 上次滤波结果
} lpf_t; // 一阶低通滤波器
typedef struct
{
uint16_t size; // 滑动窗口大小
float32 *window; // 滑动窗口
volatile float32 sum; // 滑动窗口和
volatile float32 out; // 滤波结果
uint16_t index; // 滑动窗口索引
} lpf_window_t; // 滑动窗口滤波器
void kalman_init(kalman_t *cfg, float32 change_max);
float32 kalman_update(kalman_t *cfg, float32 input);
void lpf_init(lpf_t *cfg);
float32 lpf_update(lpf_t *cfg, float32 input);
void lpf_reset(lpf_t *cfg);
void lpf_window_init(lpf_window_t *cfg, uint16_t size);
void lpf_window_dinit(lpf_window_t *cfg);
float32 lpf_window_update(lpf_window_t *cfg, float32 input);
void lpf_window_reset(lpf_window_t *cfg);
#endif // __FILTER_H__

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#ifndef __FSM_H__
#define __FSM_H__
#include <stdint.h>
/* ----------------------- Defines ------------------------------------------*/
// 用于快速识别出 STATE与STEP
#define FSM_STATE(name) state_##name
#define FSM_FUNCT(name) funct_##name
// 数据类型定义区
typedef signed char state;
typedef long long step_ret;
typedef void *AS_STEP_RETVAL;
/*!
* @brief
*
*
* @param[in] void*
*
* @return
*/
typedef void *(*Procedure)(void *);
typedef struct
{
state ds; // 默认状态
state cs; // 当前状态
state ns; // 下个状态
} SM_STATE;
// 状态机 属性 定义
typedef struct
{
// 状态管理
SM_STATE st;
// 状态机跳转表
Procedure *procedures;
// 状态机数据区域
void *data;
// 错误处理(用于存放 状态 执行 的结果)
step_ret ret_ptr; // 状态 执行结果
void *err_ptr;
state err_flag;
} FSM;
/* ----------------------- Start function declaration -----------------------------*/
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] err_var
*
* @return /
*/
static inline void set_err_var(FSM *fsm, void *err_var)
{
if (!fsm)
return;
fsm->err_ptr = err_var;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return /
*/
static inline void *get_err_var(FSM *fsm)
{
return fsm->err_ptr;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return /
*/
static inline state is_fsm_error(FSM *fsm)
{
return fsm->err_flag;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return /
*/
static inline state set_fsm_error_flag(FSM *fsm)
{
if (!fsm)
return -1;
fsm->err_flag = 1;
return 0;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return /
*/
static inline state clr_fsm_error_flag(FSM *fsm)
{
if (!fsm)
return -1;
fsm->err_flag = 0;
return 0;
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] procedures
*
*/
static inline void set_procedures(FSM *fsm, Procedure *procedures)
{
if (fsm)
{
fsm->procedures = procedures;
fsm->st.cs = -1; // 执行run之前当前状态是未定的
}
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] data
*
*/
static inline void set_data_entry(FSM *fsm, void *data)
{
if (fsm)
fsm->data = data;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return
*
*/
static inline void *get_data_entry(FSM *fsm)
{
return fsm->data;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return
* -1 :
*/
static inline state run_state_machine_once(FSM *fsm)
{
if (!fsm)
return -1;
// 切换到新状态
fsm->st.cs = fsm->st.ns;
// 跳转到下一个状态(状态 执行 结果 保存在 ret_ptr 中
fsm->ret_ptr = (step_ret)fsm->procedures[fsm->st.cs](fsm);
return fsm->st.cs;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return /
*/
static inline step_ret *get_step_retval(FSM *fsm)
{
return &fsm->ret_ptr;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return
*/
static inline state get_curr_state(FSM *fsm)
{
return fsm->st.cs;
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] st
*
*/
static inline void set_default_state(FSM *fsm, state st)
{
if (!fsm)
return;
fsm->st.ds = st;
fsm->st.ns = st;
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] st
*
*/
static inline void set_next_state(FSM *fsm, state st)
{
if (fsm)
fsm->st.ns = st;
}
/*!
* @brief
*
* @param[in] fsm
*
* @return
*/
static inline state get_next_state(FSM *fsm)
{
return fsm->st.ns;
}
/*!
* @brief
*
* @param[in] fsm
*
*/
static inline void init_state_machine(FSM *p)
{
set_next_state(p, p->st.ds);
p->st.cs = -1; // 执行run之前当前状态是未定的
}
/*!
* @brief
*
* @param[in] fsm
*
*/
static inline void reset_state_machine(FSM *p)
{
if (!p)
return;
clr_fsm_error_flag(p);
init_state_machine(p);
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] st
*
* @return /
*/
static inline state is_curr_state(FSM *fsm, state st)
{
return fsm->st.cs == st;
}
/*!
* @brief
*
* @param[in] fsm
*
* @param[in] st
*
* @return /
*/
static inline state is_next_state(FSM *fsm, state st)
{
return fsm->st.ns == st;
}
#endif // __FSM_H__

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