前一篇分析了前十个基础实验的代码,从这里开始分析后十个~
一、PPI原理:
PPI(Programmable Peripheral Interconnect),中文翻译为可编程外设互连。
在nRF51822 内部设置了PPI 方式,可以通过任务和事件让不同外设之间进行互连,而不需要CPU 进行参与。
PPI 通过通道让任务和事件连接在一起。PPI 通道由两个端点组成:
- 任务端点:Task End-Point (TEP)。
- 事件端点:Event End-Point (EEP)。
所谓的互联就是将任务端点写入需要连接的任务寄存器地址,事件端点写入需要连接事件寄存器地址,之后,使能该PPI 通道,即实现了任务和事件的互联。
可以通过如下两种方式使能和关闭PPI 通道:
- 1) 通过独立设置CHEN,CHENSET 和CHENCLR 寄存器。
- 2) 通过PPI 通道组的使能和关闭任务。使用这种方式,在触发任务之前,需要先配置好哪些PPI 通道属于哪个组。
二、运行逻辑:
实验中,用到了3 个定时器:Timer 0、Timer 1 和Timer 2。
1) Timer 0 配置为计数器,在主循环中每100ms 被触发一次,并通过串口打印出计数值。
2) Timer 1 每个偶数秒(2、4、6、8……)产生一次比较匹配事件,该事件通过PPI通道0 和Timer 0 的STOP Task 互联,互联后通过该事件触发Timer 0 的STOP Task。 3) Timer 2 每个奇数秒(1、3、5、7……)产生一次比较匹配事件,该事件通过PPI通道1 和Timer 0 的START Task 互联,互联后通过该事件触发Timer 0 的START Task。实验原理框图如图1 所示:
三、核心代码分析
系统运行后,在循环中Timer 0 计数器的计数值每100ms 增加一次,在偶数秒时,Timer2 产生比较匹配事件,通过PPI 触发Timer 0 的STOP Task,Timer 0 停止计数。此时,尽管主循环中每隔100ms 触发一次Timer 0 计数,但是由于Timer 0 已经停止,所以,计数值不会增加。每个奇数秒,Timer2 产生比较匹配事件,通过PPI 触发Timer 0 的START Task,Timer 0 恢复计数。
main函数部分:
1 int main(void) 2 { 3 timer0_init(); // Timer used to blink the LEDs. 4 timer1_init(); // Timer to generate events on even number of seconds. 5 timer2_init(); // Timer to generate events on odd number of seconds. 6 ppi_init(); // PPI to redirect the event to timer start/stop tasks. 7 串口初始化(略)28 29 // Enabling constant latency as indicated by PAN 11 "HFCLK: Base current with HFCLK 30 // running is too high" found at Product Anomaly document found at31 // https://www.nordicsemi.com/eng/Products/Bluetooth-R-low-energy/nRF51822/#Downloads32 //33 // @note This example does not go to low power mode therefore constant latency is not needed.34 // However this setting will ensure correct behaviour when routing TIMER events through 35 // PPI (shown in this example) and low power mode simultaneously.36 NRF_POWER->TASKS_CONSTLAT = 1;37 38 // Start clock.39 nrf_drv_timer_enable(&timer0);40 nrf_drv_timer_enable(&timer1);41 nrf_drv_timer_enable(&timer2);42 43 // Loop and increment the timer count value and capture value into LEDs. @note counter is only incremented between TASK_START and TASK_STOP.44 while (true)45 {46 47 printf("Current cout: %d\r\n", (int)nrf_drv_timer_capture(&timer0,NRF_TIMER_CC_CHANNEL0));48 49 /* increment the counter */50 nrf_drv_timer_increment(&timer0);51 52 nrf_delay_ms(100);53 }54 }
定时器初始化部分:
1 // Timer even handler. Not used since timer is used only for PPI. 2 void timer_event_handler(nrf_timer_event_t event_type, void * p_context){} 3 4 /** @brief Function for Timer 0 initialization, which will be started and stopped by timer1 and timer2 using PPI. 5 */ 6 static void timer0_init(void) 7 { 8 ret_code_t err_code = nrf_drv_timer_init(&timer0, NULL, timer_event_handler); 9 APP_ERROR_CHECK(err_code);10 }11 12 /** @brief Function for Timer 1 initialization.13 * @details Initializes Timer 1 peripheral, creates event and interrupt every 2 seconds,14 * by configuring CC[0] to timer overflow value, we create events at even number of seconds15 * for example, events are created at 2,4,6 ... seconds. This event can be used to stop Timer 016 * with Timer1->Event_Compare[0] triggering Timer 0 TASK_STOP through PPI.17 */18 static void timer1_init(void)19 {20 // Configure Timer 1 to overflow every 2 seconds. Check TIMER1 configuration for details21 // The overflow occurs every 0xFFFF/(SysClk/2^PRESCALER).22 // = 65535/31250 = 2.097 sec23 ret_code_t err_code = nrf_drv_timer_init(&timer1, NULL, timer_event_handler);24 APP_ERROR_CHECK(err_code);25 26 nrf_drv_timer_extended_compare(&timer1, NRF_TIMER_CC_CHANNEL0, 0xFFFFUL, NRF_TIMER_SHORT_COMPARE0_CLEAR_MASK, false);//比较模式,Timer 1 每个偶数秒(2、4、6、8……)产生一次比较匹配事件,该事件通过PPI通道0 和Timer 0 的STOP Task 互联,互联后通过该事件触发Timer 0 的STOP Task。27 }28 29 /** @brief Function for Timer 2 initialization.30 * @details Initializes Timer 2 peripheral, creates event and interrupt every 2 seconds31 * by configuring CC[0] to half of timer overflow value. Events are created at odd number of seconds.32 * For example, events are created at 1,3,5,... seconds. This event can be used to start Timer 033 * with Timer2->Event_Compare[0] triggering Timer 0 TASK_START through PPI.34 */35 static void timer2_init(void)36 {37 // Generate interrupt/event when half of time before the timer overflows has past, that is at 1,3,5,7... seconds from start.38 // Check TIMER1 configuration for details39 // now the overflow occurs every 0xFFFF/(SysClk/2^PRESCALER)40 // = 65535/31250 = 2.097 sec */41 ret_code_t err_code = nrf_drv_timer_init(&timer2, NULL, timer_event_handler);42 APP_ERROR_CHECK(err_code);43 44 nrf_drv_timer_extended_compare(&timer2, NRF_TIMER_CC_CHANNEL0, 0x7FFFUL, NRF_TIMER_SHORT_COMPARE0_CLEAR_MASK, false);//Timer 2 每个奇数秒(1、3、5、7……)产生一次比较匹配事件,该事件通过PPI通道1 和Timer 0 的START Task 互联,互联后通过该事件触发Timer 0 的START Task。45 }
PPI连接事件部分:
1 /** @brief Function for initializing the PPI peripheral. 2 */ 3 static void ppi_init(void) 4 { 5 uint32_t err_code = NRF_SUCCESS; 6 7 err_code = nrf_drv_ppi_init(); 8 APP_ERROR_CHECK(err_code); 9 10 // Configure 1st available PPI channel to stop TIMER0 counter on TIMER1 COMPARE[0] match, which is every even number of seconds.11 err_code = nrf_drv_ppi_channel_alloc(&ppi_channel1);12 APP_ERROR_CHECK(err_code);13 err_code = nrf_drv_ppi_channel_assign(ppi_channel1,//PPI连接事件14 nrf_drv_timer_event_address_get(&timer1, NRF_TIMER_EVENT_COMPARE0),15 nrf_drv_timer_task_address_get(&timer0, NRF_TIMER_TASK_STOP));16 APP_ERROR_CHECK(err_code);17 18 // Configure 2nd available PPI channel to start timer0 counter at TIMER2 COMPARE[0] match, which is every odd number of seconds.19 err_code = nrf_drv_ppi_channel_alloc(&ppi_channel2);20 APP_ERROR_CHECK(err_code);21 err_code = nrf_drv_ppi_channel_assign(ppi_channel2,22 nrf_drv_timer_event_address_get(&timer2, NRF_TIMER_EVENT_COMPARE0),23 nrf_drv_timer_task_address_get(&timer0, NRF_TIMER_TASK_START));24 APP_ERROR_CHECK(err_code);25 26 // Enable both configured PPI channels27 err_code = nrf_drv_ppi_channel_enable(ppi_channel1);28 APP_ERROR_CHECK(err_code);29 err_code = nrf_drv_ppi_channel_enable(ppi_channel2);30 APP_ERROR_CHECK(err_code);31 }