实现网络收音机和FM收音机的功能
- 可以通过WiFi接收网络上的电台,也可以通过FM模块接收空中的电台,并可以通过案件进行切换、选台
- 在OLED显示屏上显示网络电台的IP地址、节目名称等相关信息或FM信号的频段
- 系统能够自动校时,开机后自动调节到准确的时间(年月日时分秒)
使用四个按键来调整一些标志位,GUI中通过标志位来决定显示什么界面。
WiFi配置部分主要使用了乐鑫提供的例程smartconfig。示例工程在esp-idf\examples\wifi\smart_config下,使用手机APP:EspTouch进行WiFi账号和密码的配置。改动不大,增加了一个全局标志位isConnect,在WiFi连接后置true。
校时部分主要使用了乐鑫在CSDN上的文章,当然乐鑫也提供了例程,在esp-idf\examples\protocols\sntp下。CSDN上的文章中更为简略。同样的,我也添加了一个全局标志位isTimeCorrect。以下是我的代码
bool isTimeCorrect = false;
static const char *TAG = "sntp";
static void esp_initialize_sntp(void) {
ESP_LOGI(TAG, "Initializing SNTP");
sntp_setoperatingmode(SNTP_OPMODE_POLL);
sntp_setservername(0, "ntp.tuna.tsinghua.edu.cn");
sntp_setservername(1, "ntp1.aliyun.com");
sntp_setservername(2, "210.72.145.44");
sntp_init();
}
void esp_wait_sntp_sync(void) {
char strftime_buf[64];
esp_initialize_sntp();
// wait for time to be set
time_t now = 0;
int retry = 0;
struct tm timeinfo = {0};
while (timeinfo.tm_year < (2019 - 1900)) {
ESP_LOGD(TAG, "Waiting for system time to be set... (%d)", ++retry);
vTaskDelay(100 / portTICK_PERIOD_MS);
time(&now);
localtime_r(&now, &timeinfo);
}
// set timezone to China Standard Time
setenv("TZ", "CST-8", 1);
tzset();
strftime(strftime_buf, sizeof(strftime_buf), "%c", &timeinfo);
ESP_LOGI(TAG, "The current date/time in Shanghai is: %s", strftime_buf);
isTimeCorrect = true;
sntp_stop();
}在线音频流使用了蜻蜓FM提供的API。此部分主要参考了乐鑫esp-adf库的示例程序esp-adf\examples\player\pipeline_living_stream和esp-adf\examples\player\pipeline_play_mp3_with_dac_or_pwm。删去了解码芯片初始化、i2s初始化和WiFi初始化等部分,并将pipeline_living_stream中的i2s输出改为了pwm输出。参考示例程序增加了换台的部分。
void MY_AUDIO_Init() {
esp_log_level_set("*", ESP_LOG_INFO);
esp_log_level_set(TAG, ESP_LOG_DEBUG);
// ESP_LOGI(TAG, "[ 1 ] Start audio codec chip");
// audio_board_handle_t board_handle = audio_board_init();
// audio_hal_ctrl_codec(board_handle->audio_hal, AUDIO_HAL_CODEC_MODE_DECODE, AUDIO_HAL_CTRL_START);
ESP_LOGI(TAG, "[2.0] Create audio pipeline for playback");
audio_pipeline_cfg_t pipeline_cfg = DEFAULT_AUDIO_PIPELINE_CONFIG();
pipeline = audio_pipeline_init(&pipeline_cfg);
ESP_LOGI(TAG, "[2.1] Create http stream to read data");
http_stream_cfg_t http_cfg = HTTP_STREAM_CFG_DEFAULT();
http_cfg.event_handle = _http_stream_event_handle;
http_cfg.type = AUDIO_STREAM_READER;
http_cfg.enable_playlist_parser = true;
http_stream_reader = http_stream_init(&http_cfg);
ESP_LOGI(TAG, "[2.2] Create pwm stream to write data to codec chip");
pwm_stream_cfg_t pwm_cfg = PWM_STREAM_CFG_DEFAULT();
pwm_cfg.pwm_config.gpio_num_left = AUDIO_Pin;
pwm_cfg.pwm_config.gpio_num_right = AUDIO_Pin + 1;
output_stream_writer = pwm_stream_init(&pwm_cfg);
ESP_LOGI(TAG, "[2.3] Create aac decoder to decode aac file");
aac_decoder_cfg_t aac_cfg = {
.out_rb_size=(2 * 1024),
.task_stack=(4 * 1024),
.task_core=(0),
.task_prio=(5),
.stack_in_ext=1,
};
aac_decoder = aac_decoder_init(&aac_cfg);
ESP_LOGI(TAG, "[2.4] Register all elements to audio pipeline");
audio_pipeline_register(pipeline, http_stream_reader, "http");
audio_pipeline_register(pipeline, aac_decoder, "aac");
audio_pipeline_register(pipeline, output_stream_writer, "pwm");
ESP_LOGI(TAG, "[2.5] Link it together http_stream-->aac_decoder-->pwm_stream");
const char *link_tag[3] = {"http", "aac", "pwm"};
audio_pipeline_link(pipeline, &link_tag[0], 3);
ESP_LOGI(TAG, "[2.6] Set up uri (http as http_stream, aac as aac decoder, and default output is pwm)");
char url[100];
sprintf(url, "http://open.ls.qingting.fm/live/%d/64k.m3u8?format=aac", stationIDList[stationID]);
audio_element_set_uri(http_stream_reader, url);
// ESP_LOGI(TAG, "[ 3 ] Start and wait for Wi-Fi network");
// esp_periph_config_t periph_cfg = DEFAULT_ESP_PERIPH_SET_CONFIG();
// set = esp_periph_set_init(&periph_cfg);
// periph_wifi_cfg_t wifi_cfg = {
// .ssid = (const char *) wifi_config.sta.ssid,
// .password = (const char *) wifi_config.sta.password,
// };
// esp_periph_handle_t wifi_handle = periph_wifi_init(&wifi_cfg);
// esp_periph_start(set, wifi_handle);
// periph_wifi_wait_for_connected(wifi_handle, portMAX_DELAY);
ESP_LOGI(TAG, "[ 4 ] Set up event listener");
audio_event_iface_cfg_t evt_cfg = AUDIO_EVENT_IFACE_DEFAULT_CFG();
evt = audio_event_iface_init(&evt_cfg);
ESP_LOGI(TAG, "[4.1] Listening event from all elements of pipeline");
audio_pipeline_set_listener(pipeline, evt);
ESP_LOGI(TAG, "[4.2] Listening event from peripherals");
// audio_event_iface_set_listener(esp_periph_set_get_event_iface(set), evt);
ESP_LOGI(TAG, "[ 5 ] Start audio_pipeline");
audio_pipeline_run(pipeline);
}
void Audio_Play() {
while (1) {
audio_event_iface_msg_t msg;
esp_err_t ret = audio_event_iface_listen(evt, &msg, portMAX_DELAY);
if (ret != ESP_OK) {
ESP_LOGE(TAG, "[ * ] Event interface error : %d", ret);
continue;
}
if (msg.source_type == AUDIO_ELEMENT_TYPE_ELEMENT &&
msg.source == (void *) aac_decoder &&
msg.cmd == AEL_MSG_CMD_REPORT_MUSIC_INFO) {
audio_element_info_t music_info = {0};
audio_element_getinfo(aac_decoder, &music_info);
ESP_LOGI(TAG, "[ * ] Receive music info from aac decoder, sample_rates=%d, bits=%d, ch=%d",
music_info.sample_rates, music_info.bits, music_info.channels);
audio_element_setinfo(output_stream_writer, &music_info);
pwm_stream_set_clk(output_stream_writer, music_info.sample_rates, music_info.bits, music_info.channels);
continue;
}
/* restart stream when the first pipeline element (http_stream_reader in this case) receives stop event (caused by reading errors) */
if (msg.source_type == AUDIO_ELEMENT_TYPE_ELEMENT && msg.source == (void *) http_stream_reader
&& msg.cmd == AEL_MSG_CMD_REPORT_STATUS && (int) msg.data == AEL_STATUS_ERROR_OPEN) {
ESP_LOGW(TAG, "[ * ] Restart stream");
audio_pipeline_stop(pipeline);
audio_pipeline_wait_for_stop(pipeline);
audio_element_reset_state(aac_decoder);
audio_element_reset_state(output_stream_writer);
audio_pipeline_reset_ringbuffer(pipeline);
audio_pipeline_reset_items_state(pipeline);
audio_pipeline_run(pipeline);
continue;
}
}
}
void Audio_SelectStation(uint16_t new_stationID) {
char url[100];
sprintf(url, "http://open.ls.qingting.fm/live/%d/64k.m3u8?format=aac", stationIDList[new_stationID]);
audio_pipeline_stop(pipeline);
audio_pipeline_wait_for_stop(pipeline);
audio_element_reset_state(aac_decoder);
audio_element_reset_state(output_stream_writer);
audio_pipeline_reset_ringbuffer(pipeline);
audio_pipeline_reset_items_state(pipeline);
audio_element_set_uri(http_stream_reader, url);
audio_pipeline_run(pipeline);
}OLED底层驱动还是使用了我的祖传代码,虽然是i2c的,但是稍微改改发送接口,从spi发送就可以正常使用了。
void MY_SPI_Init() {
spi_bus_config_t buscfg = {
.miso_io_num=-1,
.mosi_io_num=OLED_MOSI_Pin,
.sclk_io_num=OLED_CLK_Pin,
.quadwp_io_num=-1,
.quadhd_io_num=-1,
.max_transfer_sz=0
};
spi_device_interface_config_t devcfg = {
.clock_speed_hz=1 * 1000 * 1000, //Clock out at 1 MHz
.mode=0, //SPI mode 0
.spics_io_num=-1, //CS pin
.queue_size=7, //We want to be able to queue 7 transactions at a time
};
ESP_ERROR_CHECK(spi_bus_initialize(OLED_SPI_HOST, &buscfg, SPI_DMA_DISABLED));
ESP_ERROR_CHECK(spi_bus_add_device(OLED_SPI_HOST, &devcfg, &oled_spi_handle));
}
spi_device_handle_t oled_spi_handle;
void oled_send(uint8_t dc, uint8_t data) {
spi_transaction_t t = {0};
t.length = 8;
t.tx_buffer = &data;
gpio_set_level(OLED_DC_Pin, dc == 0x40);
spi_device_polling_transmit(oled_spi_handle, &t);
}这款FM芯片有个坑,它并非像传统的i2c设备一样,可以通过发送设备地址-发送寄存器地址-读或者写值这种操作方法来操作,而是只能顺序读取或者写入所有寄存器数据,具体可以参考数据手册。
由于没能找到比较好的驱动,我这里参考github上一个适配于arduino的程序自己写了一个较为简陋的驱动
struct RDA_Handler RDA5807;
RADIO_FREQ FMStationList[50] = {0};
uint16_t FMStationNum = 0;
void RDA_ReadAllInfo() {
i2c_cmd_handle_t cmd = i2c_cmd_link_create();
i2c_master_start(cmd);
i2c_master_write_byte(cmd, 0x21, 1);
// from 0x0A high to 0x0C low
uint8_t i2c_data_array[6];
// read 0x0A
i2c_master_read_byte(cmd, i2c_data_array + 0, 0);
i2c_master_read_byte(cmd, i2c_data_array + 1, 0);
// read 0x0B
i2c_master_read_byte(cmd, i2c_data_array + 2, 0);
i2c_master_read_byte(cmd, i2c_data_array + 3, 0);
// read 0x0C
i2c_master_read_byte(cmd, i2c_data_array + 4, 0);
i2c_master_read_byte(cmd, i2c_data_array + 5, 1);
i2c_master_stop(cmd);
i2c_master_cmd_begin(FM_I2C_HOST, cmd, 1000 / portTICK_RATE_MS);
i2c_cmd_link_delete(cmd);
RDA5807.radioInfo.rds = i2c_data_array[0] & 0x80;
uint16_t readChan = ((i2c_data_array[0] & 0x03) << 8) + i2c_data_array[1];
switch (RDA5807.band) {
case RADIO_BAND_US:
RDA5807.freq = RDA5807.channelSpacing * readChan + 87 * 1000;
break;
case RADIO_BAND_JP:
case RADIO_BAND_WW:
RDA5807.freq = RDA5807.channelSpacing * readChan + 76 * 1000;
break;
case RADIO_BAND_EE:
RDA5807.freq = RDA5807.channelSpacing * readChan + 65 * 1000;
}
RDA5807.radioInfo.rssi = i2c_data_array[2] >> 2;
}
void RDA_WriteAllInfo() {
i2c_cmd_handle_t cmd = i2c_cmd_link_create();
i2c_master_start(cmd);
i2c_master_write_byte(cmd, 0x20, 1);
for (uint8_t i = 2; i < 8; i++) {
i2c_master_write_byte(cmd, RDA5807.regList[i] >> 8, 1);
i2c_master_write_byte(cmd, RDA5807.regList[i] & 0xff, 1);
}
i2c_master_stop(cmd);
i2c_master_cmd_begin(FM_I2C_HOST, cmd, 1000 / portTICK_RATE_MS);
i2c_cmd_link_delete(cmd);
}
void RDA_Init() {
RDA5807.channelSpacing = 100;
// Reg 0x00 and 0x01 are not used
RDA5807.regList[0] = 0;
RDA5807.regList[1] = 0;
RDA5807.regList[2] = 0b11000000 << 8 | 0b00000011;
RDA5807.regList[3] = 0b00000000 << 8 | 0b00000000;
RDA5807.regList[4] = 0b00001000 << 8 | 0b00000000;
RDA5807.regList[5] = 0b10000100 << 8 | 0b11010100;
RDA5807.regList[6] = 0b00000000 << 8 | 0b00000000;
RDA5807.regList[7] = 0b00000000 << 8 | 0b00000000;
RDA_WriteAllInfo();
RDA_Reset();
}
void RDA_Reset() {
RDA5807.regList[RADIO_REG_CTRL] |= RADIO_REG_CTRL_RESET;
RDA_WriteAllInfo();
vTaskDelay(100 / portTICK_RATE_MS);
RDA5807.regList[RADIO_REG_CTRL] &= !RADIO_REG_CTRL_RESET;
RDA_WriteAllInfo();
}
void RDA_SetBandFrequency(enum RADIO_BAND newBand, RADIO_FREQ newFreq) {
RDA_SetBand(newBand);
RDA_SetFrequency(newFreq);
}
void RDA_SetFrequency(RADIO_FREQ newFreq) {
RADIO_FREQ freqHigh, freqLow;
switch (RDA5807.band) {
case RADIO_BAND_US:
freqLow = 87000;
freqHigh = 108000;
break;
case RADIO_BAND_JP:
freqLow = 76000;
freqHigh = 91000;
break;
case RADIO_BAND_WW:
freqLow = 76000;
freqHigh = 108000;
break;
case RADIO_BAND_EE:
freqLow = 65000;
freqHigh = 76000;
break;
default:
freqLow = 65000;
freqHigh = 108000;
break;
}
if (newFreq < freqLow) newFreq = freqLow;
if (newFreq > freqHigh) newFreq = freqHigh;
uint16_t regChannel = RDA5807.regList[RADIO_REG_CHAN] &
(RADIO_REG_CHAN_SPACE | RADIO_REG_CHAN_BAND);
uint16_t newChannel = (newFreq - freqLow) / RDA5807.channelSpacing;
regChannel += RADIO_REG_CHAN_TUNE; // enable tuning
regChannel |= newChannel << 6;
RDA5807.regList[RADIO_REG_CTRL] |=
RADIO_REG_CTRL_OUTPUT | RADIO_REG_CTRL_UNMUTE |
RADIO_REG_CTRL_RDS | RADIO_REG_CTRL_ENABLE; // | RADIO_REG_CTRL_NEW
RDA5807.regList[RADIO_REG_CHAN] = regChannel;
RDA_WriteAllInfo();
}
void RDA_SetBand(enum RADIO_BAND newBand) {
RDA5807.band = newBand;
switch (newBand) {
case RADIO_BAND_US:
RDA5807.regList[RADIO_REG_CHAN] &= !RADIO_REG_CHAN_BAND;
RDA5807.regList[RADIO_REG_CHAN] |= RADIO_REG_CHAN_BAND_US;
break;
case RADIO_BAND_JP:
RDA5807.regList[RADIO_REG_CHAN] &= !RADIO_REG_CHAN_BAND;
RDA5807.regList[RADIO_REG_CHAN] |= RADIO_REG_CHAN_BAND_JP;
break;
case RADIO_BAND_WW:
RDA5807.regList[RADIO_REG_CHAN] &= !RADIO_REG_CHAN_BAND;
RDA5807.regList[RADIO_REG_CHAN] |= RADIO_REG_CHAN_BAND_WW;
break;
case RADIO_BAND_EE:
RDA5807.regList[RADIO_REG_CHAN] &= !RADIO_REG_CHAN_BAND;
RDA5807.regList[RADIO_REG_CHAN] |= RADIO_REG_CHAN_BAND_EE;
break;
default:
break;
}
RDA5807.regList[RADIO_REG_CHAN] |= RADIO_REG_CHAN_SPACE_100;
RDA_WriteAllInfo();
}GUI部分我新建了一个线程,根据各个标志位来判断模式,显示各类信息
void GUI_Init() {
xTaskCreate(GUI_Task, "GUI_Task", 4096, NULL, 3, NULL);
}
void GUI_Task() {
while (1) {
if (!isConnect) {
OLED_ShowNotConnect();
lastState = 0;
} else {
if (!isTimeCorrect) {
OLED_ShowTimeCalibrating();
lastState = 1;
} else {
OLED_ShowTime();
if (isFM) {
OLED_ShowFM();
lastState = 2;
} else {
OLED_ShowInternetFM();
lastState = 3;
}
}
}
vTaskDelay(100 / portTICK_RATE_MS);
}
}WiFi未连接时和连接后的校时时,显示一串字符串,表明状态
void OLED_ShowNotConnect() {
if (lastState != 0) {
OLED_Clear();
OLED_ShowString(0, 0, (uint8_t *) "Wifi is not connected. Please Connect Wifi with EspTouch.", 16);
}
}
void OLED_ShowTimeCalibrating() {
if (lastState != 1) {
OLED_Clear();
OLED_ShowString(0, 0, (uint8_t *) "Wifi is connected. Trying to calibrate time...", 16);
}
}显示FM的频段和信号强度(rssi)
uint32_t freq_temp = -1;
void OLED_ShowFM() {
static uint8_t rssi_temp = -1;
char ch[30];
RDA_ReadAllInfo();
if (lastState != 2) {
OLED_Clear();
SetMuxFM();
OLED_ShowString(0, 0, (uint8_t *) "FM", 16);
sprintf(ch, "freq:%6d", RDA5807.freq);
OLED_ShowString(0, 2, (uint8_t *) ch, 16);
freq_temp = RDA5807.freq;
sprintf(ch, "rssi: %2d/64", RDA5807.radioInfo.rssi + 1);
OLED_ShowString(0, 4, (uint8_t *) ch, 16);
rssi_temp = RDA5807.radioInfo.rssi;
OLED_ShowString(0, 6, (uint8_t *) "SW Pre Nex Mute", 16);
} else {
if (freq_temp != RDA5807.freq) {
sprintf(ch, "freq:%6d", freq_temp);
OLED_ShowString(0, 2, (uint8_t *) ch, 16);
RDA_SetFrequency(freq_temp);
}
if (rssi_temp != RDA5807.radioInfo.rssi) {
sprintf(ch, "rssi: %2d/64", RDA5807.radioInfo.rssi + 1);
OLED_ShowString(0, 4, (uint8_t *) ch, 16);
rssi_temp = RDA5807.radioInfo.rssi;
}
}
}显示本次使用的电台蜻蜓FM的IP和当前节目名称。根据蜻蜓FM的开放平台的品牌露出规范,添加相应的字符
void OLED_ShowInternetFM() {
static uint8_t stationID_temp = -1;
char ch[30];
if (lastState != 3) {
OLED_Clear();
SetMuxESP();
OLED_ShowString(0, 0, (uint8_t *) "OL", 16);
OLED_ShowString(0, 2, (uint8_t *) "IP:115.231.142.5", 16);
sprintf(ch, "FM%4d", ConvStaIDToName(stationIDList[stationID]));
OLED_ShowString(0, 4, (uint8_t *) ch, 16);
stationID_temp = stationID;
OLED_ShowQingtingLogo(6 * 8, 4);
OLED_ShowString(0, 6, (uint8_t *) "SW Pre Nex Mute", 16);
} else {
if (stationID_temp != stationID) {
Audio_SelectStation(stationID);
sprintf(ch, "FM%4d", ConvStaIDToName(stationIDList[stationID]));
OLED_ShowString(0, 4, (uint8_t *) ch, 16);
stationID_temp = stationID;
}
}
}
uint16_t ConvStaIDToName(uint16_t _stationID) {
switch (_stationID) {
case 4522: return 930; //FM93交通之声
case 4518: return 880; //浙江之声
case 1133: return 918; //杭州交通91.8电台
case 1163: return 1054; //西湖之声
case 4521: return 996; //浙江FM99.6
case 1135: return 922; //嘉兴交通广播
case 4866: return 968; //浙江音乐调频
case 4523: return 1070; //浙江城市之声
default: return -1;
}
}
void OLED_ShowQingtingLogo(uint8_t x, uint8_t y) {
const uint8_t logo[][16] = {
{0x00, 0x08, 0x08, 0x28, 0xC8, 0x08, 0x08, 0xFF, 0x08, 0x08, 0x88, 0x68, 0x08, 0x08, 0x00, 0x00},
{0x21, 0x21, 0x11, 0x11, 0x09, 0x05, 0x03, 0xFF, 0x03, 0x05, 0x09, 0x11, 0x11, 0x21, 0x21, 0x00},/*"来",0*/
{0x00, 0x00, 0x00, 0xF8, 0x88, 0x8C, 0x8A, 0x89, 0x88, 0x88, 0x88, 0xF8, 0x00, 0x00, 0x00, 0x00},
{0x00, 0x00, 0x00, 0xFF, 0x44, 0x44, 0x44, 0x44, 0x44, 0x44, 0x44, 0xFF, 0x00, 0x00, 0x00, 0x00},/*"自",1*/
{0x00, 0xF8, 0x08, 0xFF, 0x08, 0xF8, 0x44, 0x54, 0x54, 0x54, 0x7F, 0x54, 0x54, 0x54, 0x44, 0x00},
{0x20, 0x63, 0x21, 0x1F, 0x11, 0x39, 0x00, 0xFF, 0x15, 0x15, 0x15, 0x55, 0x95, 0x7F, 0x00, 0x00},/*"蜻",2*/
{0xF8, 0x08, 0xFF, 0x08, 0xF8, 0x00, 0x84, 0xE4, 0x9C, 0x00, 0x44, 0x44, 0xFC, 0x42, 0x42, 0x00},
{0x23, 0x61, 0x3F, 0x11, 0xB9, 0x40, 0x26, 0x18, 0x27, 0x40, 0x48, 0x48, 0x4F, 0x48, 0x48, 0x00},/*"蜓",3*/
};
for (uint8_t j = 0; j < 2; j++) {
OLED_Set_Pos(x + j * 16, y);
for (uint8_t i = 0; i < 16; i++) {
OLED_WR_DATA(logo[2 * j][i]);
}
OLED_Set_Pos(x + j * 16, y + 1);
for (uint8_t i = 0; i < 16; i++) {
OLED_WR_DATA(logo[2 * j + 1][i]);
}
}
// OLED_ShowChar(x + 2 * 16, y, ' ', 16);
for (uint8_t j = 2; j < 4; j++) {
OLED_Set_Pos(x + j * 16, y);
for (uint8_t i = 0; i < 16; i++) {
OLED_WR_DATA(logo[2 * j][i]);
}
OLED_Set_Pos(x + j * 16, y + 1);
for (uint8_t i = 0; i < 16; i++) {
OLED_WR_DATA(logo[2 * j + 1][i]);
}
}
OLED_ShowChar(x + 4 * 16, y, 'F', 16);
OLED_ShowChar(x + 4 * 16 + 8, y, 'M', 16);
}由于空间限制,在这里实现循环显示约5秒的时间2秒的日期。
void OLED_ShowTime() {
static uint8_t i = 0;
char ch[30];
time_t now = 0;
struct tm timeinfo = {0};
i++;
time(&now);
localtime_r(&now, &timeinfo);
if (i > 50) {
sprintf(ch, "%2dy%2dm%2dd",
timeinfo.tm_year % 100, timeinfo.tm_mon + 1, timeinfo.tm_mday);
if (i == 70) {
i = 0;
}
} else {
sprintf(ch, "%2d:%2d:%2d ",
timeinfo.tm_hour, timeinfo.tm_min, timeinfo.tm_sec);
}
OLED_ShowString(56, 0, (uint8_t *) ch, 16);
}按键初始化为输入并附加外部中断回调
static void gpio_isr_handler(void *arg) {
uint32_t gpio_num = (uint32_t) arg;
switch (gpio_num) {
case Key1_Pin:
isFM = !isFM;
break;
case Key2_Pin:
if (isFM) {
freq_temp -= RDA5807.channelSpacing;
} else {
if (stationID == 0) {
stationID = 7;
} else {
stationID--;
}
}
break;
case Key3_Pin:
if (isFM) {
freq_temp += RDA5807.channelSpacing;
} else {
if (stationID == 7) {
stationID = 0;
} else {
stationID++;
}
}
break;
case Key4_Pin:
ToggleSpeaker();
break;
default:
break;
}
}初次上手乐鑫,我感觉乐鑫的例程还是十分丰富的。由于在使用STM32时,我已经对cmake有一个初步的掌握了,转到乐鑫的esp-idf时就显得不那么费力了,也能继续用我熟悉的CLion了。但是似乎对于那些只熟悉MDK-ARM或者IAR的嵌入式开发者,转而使用乐鑫idf就似乎显得要学的东西有点多了。
再对比下当下STM32和ESP32的价格和性能,ESP32还真是便宜大碗啊,还有着WiFi功能。尽管ESP的库比ST的Hal库庞大亿点,深入调试略微麻烦,有些库甚至封装成了lib,但还是在群友的帮助下解决了问题。