3-Key_Scan.zip_STM8函数库_key_scan代码资源-CSDN文库

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c：29个

o：7个

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166 浏览量 2022-09-14 21:50:30 上传评论收藏 263KB ZIP 举报

STM8是一款8位微控制器，由STMicroelectronics（意法半导体）生产，广泛应用于各种嵌入式系统设计中。在给定的“3-Key_Scan.zip”压缩包中，我们聚焦于STM8的键盘扫描功能，这是一个关键的输入处理机制，尤其在需要用户交互的设备上，如家用电器、工业控制面板或消费电子产品。 STM8的函数库是为开发者提供的一系列预先编写的代码模块，简化了在STM8平台上进行软件开发的工作。这些库通常包括中断服务例程、定时器配置、I/O口管理、通信协议等功能。在“3-Key_Scan.zip”中，我们特别关注的是与键盘扫描相关的函数库，这将帮助我们理解如何在STM8上检测和处理按键输入。键扫描代码是用于检测多按键阵列状态的程序逻辑。在STM8应用中，它可能涉及到初始化GPIO端口以读取按键状态，设置中断处理程序，以及执行周期性的扫描循环，通过逐行或逐列检测低电平来识别哪些按键被按下。这个过程可以是简单的轮询，也可以是中断驱动，取决于应用的需求和资源优化。我们需要对STM8的GPIO（通用输入/输出）进行配置。STM8的每个GPIO引脚都可以独立配置为输入或输出，并且有多种工作模式，如模拟输入、推挽输出、开漏输出等。在键盘扫描中，通常将按键连接到输入引脚，并启用内部上拉电阻，以便在没有按键按下时检测高电平。接下来，我们会设置一个循环或中断服务例程，定期检查按键状态。这可以通过逐个扫描行线并检测列线上的电压变化来实现。当一个按键被按下时，它会将对应的行和列短路，导致读取到低电平。通过记录所有低电平的位置，我们可以确定哪个按键被按下。在实际应用中，为了提高鲁棒性和防止按键抖动，可能需要添加去抖动算法。这通常通过在检测到按键变化后等待一小段时间，然后再确认状态是否稳定来实现。此外，按键的中断处理可能需要优先级管理和事件队列，以确保在处理按键事件的同时不影响其他系统任务。总结起来，“3-Key_Scan.zip”包含的资源和代码是关于如何在STM8微控制器上实现键盘扫描功能的实例。它涉及STM8的GPIO配置、中断服务、扫描算法和可能的去抖动处理，这些都是嵌入式系统开发中的重要知识点。通过学习和理解这个代码库，开发者可以更好地掌握STM8平台上的用户输入处理，从而构建更高效、可靠的系统。

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3-Key_Scan.zip （77个子文件）

3-Key_Scan

FWlib

inc

stm8s_tim2.h 14KB

stm8s_tim5.h 19KB

stm8s_clk.h 17KB

stm8s_tim3.h 13KB

stm8s_i2c.h 27KB

stm8s_adc2.h 11KB

stm8s_rst.h 3KB

stm8s_awu.h 5KB

stm8s.h 113KB

stm8s_spi.h 13KB

stm8s_uart3.h 15KB

stm8s_tim1.h 26KB

stm8s_itc.h 7KB

stm8s_tim4.h 5KB

stm8s_gpio.h 6KB

stm8s_exti.h 5KB

stm8s_flash.h 13KB

stm8s_beep.h 3KB

stm8s_uart2.h 19KB

stm8s_uart1.h 16KB

stm8s_adc1.h 15KB

stm8s_wwdg.h 2KB

stm8s_can.h 25KB

stm8s_tim6.h 9KB

stm8s_iwdg.h 4KB

src

stm8s_tim4.c 12KB

stm8s_uart2.c 29KB

stm8s_tim5.c 50KB

stm8s_can.c 48KB

stm8s_tim3.c 37KB

stm8s_spi.c 14KB

stm8s_tim6.c 15KB

stm8s_iwdg.c 3KB

stm8s_wwdg.c 4KB

stm8s_i2c.c 32KB

stm8s_clk.c 22KB

stm8s_flash.c 25KB

stm8s_adc2.c 13KB

stm8s_adc1.c 23KB

stm8s_tim1.c 84KB

stm8s_uart1.c 26KB

stm8s_exti.c 6KB

stm8s_tim2.c 46KB

stm8s_uart3.c 24KB

stm8s_gpio.c 8KB

stm8s_awu.c 6KB

stm8s_itc.c 10KB

stm8s_rst.c 3KB

stm8s_beep.c 5KB

Project

Key_Scan.eww 162B

Key_Scan.ewd 11KB

Key_Scan.ewp 42KB

settings

Key_Scan.dni 1KB

Key_Scan.cspy.bat 1KB

Key_Scan.wsdt 4KB

Key_Scan.dbgdt 3KB

Key_Scan.dep 7KB

Debug

List

Exe

Key_Scan.hex 6KB

Key_Scan.out 62KB

Obj

key_scan.o 9KB

Key_Scan.pbd 1KB

sysclock.o 9KB

stm8s_flash.o 46KB

led.o 14KB

stm8s_clk.o 55KB

stm8s_gpio.o 22KB

main.o 6KB

USER

sysclock.c 3KB

stm8s_it.c 13KB

main.c 2KB

led.h 3KB

stm8s_conf.h 4KB

led.c 4KB

sysclock.h 1KB

key_scan.c 2KB

stm8s_it.h 5KB

key_scan.h 2KB

/** ****************************************************************************** * @file stm8s_tim1.c * @author MCD Application Team * @version V2.1.0 * @date 18-November-2011 * @brief This file contains all the functions for the TIM1 peripheral. ****************************************************************************** * @attention * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * * <h2><center>© COPYRIGHT 2011 STMicroelectronics</center></h2> ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm8s_tim1.h" /** @addtogroup STM8S_StdPeriph_Driver * @{ */ /* Private typedef -----------------------------------------------------------*/ /* Private define ------------------------------------------------------------*/ /* Private macro -------------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ /* Private function prototypes -----------------------------------------------*/ static void TI1_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI2_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI3_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); static void TI4_Config(uint8_t TIM1_ICPolarity, uint8_t TIM1_ICSelection, uint8_t TIM1_ICFilter); /** * @addtogroup TIM1_Public_Functions * @{ */ /** * @brief Deinitializes the TIM1 peripheral registers to their default reset values. * @param None * @retval None */ void TIM1_DeInit(void) { TIM1->CR1 = TIM1_CR1_RESET_VALUE; TIM1->CR2 = TIM1_CR2_RESET_VALUE; TIM1->SMCR = TIM1_SMCR_RESET_VALUE; TIM1->ETR = TIM1_ETR_RESET_VALUE; TIM1->IER = TIM1_IER_RESET_VALUE; TIM1->SR2 = TIM1_SR2_RESET_VALUE; /* Disable channels */ TIM1->CCER1 = TIM1_CCER1_RESET_VALUE; TIM1->CCER2 = TIM1_CCER2_RESET_VALUE; /* Configure channels as inputs: it is necessary if lock level is equal to 2 or 3 */ TIM1->CCMR1 = 0x01; TIM1->CCMR2 = 0x01; TIM1->CCMR3 = 0x01; TIM1->CCMR4 = 0x01; /* Then reset channel registers: it also works if lock level is equal to 2 or 3 */ TIM1->CCER1 = TIM1_CCER1_RESET_VALUE; TIM1->CCER2 = TIM1_CCER2_RESET_VALUE; TIM1->CCMR1 = TIM1_CCMR1_RESET_VALUE; TIM1->CCMR2 = TIM1_CCMR2_RESET_VALUE; TIM1->CCMR3 = TIM1_CCMR3_RESET_VALUE; TIM1->CCMR4 = TIM1_CCMR4_RESET_VALUE; TIM1->CNTRH = TIM1_CNTRH_RESET_VALUE; TIM1->CNTRL = TIM1_CNTRL_RESET_VALUE; TIM1->PSCRH = TIM1_PSCRH_RESET_VALUE; TIM1->PSCRL = TIM1_PSCRL_RESET_VALUE; TIM1->ARRH = TIM1_ARRH_RESET_VALUE; TIM1->ARRL = TIM1_ARRL_RESET_VALUE; TIM1->CCR1H = TIM1_CCR1H_RESET_VALUE; TIM1->CCR1L = TIM1_CCR1L_RESET_VALUE; TIM1->CCR2H = TIM1_CCR2H_RESET_VALUE; TIM1->CCR2L = TIM1_CCR2L_RESET_VALUE; TIM1->CCR3H = TIM1_CCR3H_RESET_VALUE; TIM1->CCR3L = TIM1_CCR3L_RESET_VALUE; TIM1->CCR4H = TIM1_CCR4H_RESET_VALUE; TIM1->CCR4L = TIM1_CCR4L_RESET_VALUE; TIM1->OISR = TIM1_OISR_RESET_VALUE; TIM1->EGR = 0x01; /* TIM1_EGR_UG */ TIM1->DTR = TIM1_DTR_RESET_VALUE; TIM1->BKR = TIM1_BKR_RESET_VALUE; TIM1->RCR = TIM1_RCR_RESET_VALUE; TIM1->SR1 = TIM1_SR1_RESET_VALUE; } /** * @brief Initializes the TIM1 Time Base Unit according to the specified parameters. * @param TIM1_Prescaler specifies the Prescaler value. * @param TIM1_CounterMode specifies the counter mode from @ref TIM1_CounterMode_TypeDef . * @param TIM1_Period specifies the Period value. * @param TIM1_RepetitionCounter specifies the Repetition counter value * @retval None */ void TIM1_TimeBaseInit(uint16_t TIM1_Prescaler, TIM1_CounterMode_TypeDef TIM1_CounterMode, uint16_t TIM1_Period, uint8_t TIM1_RepetitionCounter) { /* Check parameters */ assert_param(IS_TIM1_COUNTER_MODE_OK(TIM1_CounterMode)); /* Set the Autoreload value */ TIM1->ARRH = (uint8_t)(TIM1_Period >> 8); TIM1->ARRL = (uint8_t)(TIM1_Period); /* Set the Prescaler value */ TIM1->PSCRH = (uint8_t)(TIM1_Prescaler >> 8); TIM1->PSCRL = (uint8_t)(TIM1_Prescaler); /* Select the Counter Mode */ TIM1->CR1 = (uint8_t)((uint8_t)(TIM1->CR1 & (uint8_t)(~(TIM1_CR1_CMS | TIM1_CR1_DIR))) | (uint8_t)(TIM1_CounterMode)); /* Set the Repetition Counter value */ TIM1->RCR = TIM1_RepetitionCounter; } /** * @brief Initializes the TIM1 Channel1 according to the specified parameters. * @param TIM1_OCMode specifies the Output Compare mode from * @ref TIM1_OCMode_TypeDef. * @param TIM1_OutputState specifies the Output State from * @ref TIM1_OutputState_TypeDef. * @param TIM1_OutputNState specifies the Complementary Output State * from @ref TIM1_OutputNState_TypeDef. * @param TIM1_Pulse specifies the Pulse width value. * @param TIM1_OCPolarity specifies the Output Compare Polarity from * @ref TIM1_OCPolarity_TypeDef. * @param TIM1_OCNPolarity specifies the Complementary Output Compare Polarity * from @ref TIM1_OCNPolarity_TypeDef. * @param TIM1_OCIdleState specifies the Output Compare Idle State from * @ref TIM1_OCIdleState_TypeDef. * @param TIM1_OCNIdleState specifies the Complementary Output Compare Idle * State from @ref TIM1_OCIdleState_TypeDef. * @retval None */ void TIM1_OC1Init(TIM1_OCMode_TypeDef TIM1_OCMode, TIM1_OutputState_TypeDef TIM1_OutputState, TIM1_OutputNState_TypeDef TIM1_OutputNState, uint16_t TIM1_Pulse, TIM1_OCPolarity_TypeDef TIM1_OCPolarity, TIM1_OCNPolarity_TypeDef TIM1_OCNPolarity, TIM1_OCIdleState_TypeDef TIM1_OCIdleState, TIM1_OCNIdleState_TypeDef TIM1_OCNIdleState) { /* Check the parameters */ assert_param(IS_TIM1_OC_MODE_OK(TIM1_OCMode)); assert_param(IS_TIM1_OUTPUT_STATE_OK(TIM1_OutputState)); assert_param(IS_TIM1_OUTPUTN_STATE_OK(TIM1_OutputNState)); assert_param(IS_TIM1_OC_POLARITY_OK(TIM1_OCPolarity)); assert_param(IS_TIM1_OCN_POLARITY_OK(TIM1_OCNPolarity)); assert_param(IS_TIM1_OCIDLE_STATE_OK(TIM1_OCIdleState)); assert_param(IS_TIM1_OCNIDLE_STATE_OK(TIM1_OCNIdleState)); /* Disable the Channel 1: Reset the CCE Bit, Set the Output State , the Output N State, the Output Polarity & the Output N Polarity*/ TIM1->CCER1 &= (uint8_t)(~( TIM1_CCER1_CC1E | TIM1_CCER1_CC1NE | TIM1_CCER1_CC1P | TIM1_CCER1_CC1NP)); /* Set the Output State & Set the Output N State & Set the Output Polarity & Set the Output N Polarity */ TIM1->CCER1 |= (uint8_t)((uint8_t)((uint8_t)(TIM1_OutputState & TIM1_CCER1_CC1E) | (uint8_t)(TIM1_OutputNState & TIM1_CCER1_CC1NE)) | (uint8_t)( (uint8_t)(TIM1_OCPolarity & TIM1_CCER1_CC1P) | (uint8_t)(TIM1_OCNPolarity & TIM1_CCER1_CC1NP))