esp-idf/examples/bluetooth/bluedroid/classic_bt/a2dp_source/main/main.c
2022-06-28 13:05:13 +08:00

764 lines
27 KiB
C

/*
This example code is in the Public Domain (or CC0 licensed, at your option.)
Unless required by applicable law or agreed to in writing, this
software is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
CONDITIONS OF ANY KIND, either express or implied.
*/
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "freertos/timers.h"
#include "nvs.h"
#include "nvs_flash.h"
#include "esp_system.h"
#include "esp_log.h"
#include "esp_bt.h"
#include "bt_app_core.h"
#include "esp_bt_main.h"
#include "esp_bt_device.h"
#include "esp_gap_bt_api.h"
#include "esp_a2dp_api.h"
#include "esp_avrc_api.h"
/* log tags */
#define BT_AV_TAG "BT_AV"
#define BT_RC_CT_TAG "RC_CT"
/* device name */
#define TARGET_DEVICE_NAME "ESP_SPEAKER"
#define LOCAL_DEVICE_NAME "ESP_A2DP_SRC"
/* AVRCP used transaction label */
#define APP_RC_CT_TL_GET_CAPS (0)
#define APP_RC_CT_TL_RN_VOLUME_CHANGE (1)
enum {
BT_APP_STACK_UP_EVT = 0x0000, /* event for stack up */
BT_APP_HEART_BEAT_EVT = 0xff00, /* event for heart beat */
};
/* A2DP global states */
enum {
APP_AV_STATE_IDLE,
APP_AV_STATE_DISCOVERING,
APP_AV_STATE_DISCOVERED,
APP_AV_STATE_UNCONNECTED,
APP_AV_STATE_CONNECTING,
APP_AV_STATE_CONNECTED,
APP_AV_STATE_DISCONNECTING,
};
/* sub states of APP_AV_STATE_CONNECTED */
enum {
APP_AV_MEDIA_STATE_IDLE,
APP_AV_MEDIA_STATE_STARTING,
APP_AV_MEDIA_STATE_STARTED,
APP_AV_MEDIA_STATE_STOPPING,
};
/*********************************
* STATIC FUNCTION DECLARATIONS
********************************/
/* handler for bluetooth stack enabled events */
static void bt_av_hdl_stack_evt(uint16_t event, void *p_param);
/* avrc controller event handler */
static void bt_av_hdl_avrc_ct_evt(uint16_t event, void *p_param);
/* GAP callback function */
static void bt_app_gap_cb(esp_bt_gap_cb_event_t event, esp_bt_gap_cb_param_t *param);
/* callback function for A2DP source */
static void bt_app_a2d_cb(esp_a2d_cb_event_t event, esp_a2d_cb_param_t *param);
/* callback function for A2DP source audio data stream */
static int32_t bt_app_a2d_data_cb(uint8_t *data, int32_t len);
/* callback function for AVRCP controller */
static void bt_app_rc_ct_cb(esp_avrc_ct_cb_event_t event, esp_avrc_ct_cb_param_t *param);
/* handler for heart beat timer */
static void bt_app_a2d_heart_beat(TimerHandle_t arg);
/* A2DP application state machine */
static void bt_app_av_sm_hdlr(uint16_t event, void *param);
/* utils for transfer BLuetooth Deveice Address into string form */
static char *bda2str(esp_bd_addr_t bda, char *str, size_t size);
/* A2DP application state machine handler for each state */
static void bt_app_av_state_unconnected_hdlr(uint16_t event, void *param);
static void bt_app_av_state_connecting_hdlr(uint16_t event, void *param);
static void bt_app_av_state_connected_hdlr(uint16_t event, void *param);
static void bt_app_av_state_disconnecting_hdlr(uint16_t event, void *param);
/*********************************
* STATIC VARIABLE DEFINITIONS
********************************/
static esp_bd_addr_t s_peer_bda = {0}; /* Bluetooth Device Address of peer device*/
static uint8_t s_peer_bdname[ESP_BT_GAP_MAX_BDNAME_LEN + 1]; /* Bluetooth Device Name of peer device*/
static int s_a2d_state = APP_AV_STATE_IDLE; /* A2DP global state */
static int s_media_state = APP_AV_MEDIA_STATE_IDLE; /* sub states of APP_AV_STATE_CONNECTED */
static int s_intv_cnt = 0; /* count of heart beat intervals */
static int s_connecting_intv = 0; /* count of heart beat intervals for connecting */
static uint32_t s_pkt_cnt = 0; /* count of packets */
static esp_avrc_rn_evt_cap_mask_t s_avrc_peer_rn_cap; /* AVRC target notification event capability bit mask */
static TimerHandle_t s_tmr; /* handle of heart beat timer */
/*********************************
* STATIC FUNCTION DEFINITIONS
********************************/
static char *bda2str(esp_bd_addr_t bda, char *str, size_t size)
{
if (bda == NULL || str == NULL || size < 18) {
return NULL;
}
sprintf(str, "%02x:%02x:%02x:%02x:%02x:%02x",
bda[0], bda[1], bda[2], bda[3], bda[4], bda[5]);
return str;
}
static bool get_name_from_eir(uint8_t *eir, uint8_t *bdname, uint8_t *bdname_len)
{
uint8_t *rmt_bdname = NULL;
uint8_t rmt_bdname_len = 0;
if (!eir) {
return false;
}
/* get complete or short local name from eir data */
rmt_bdname = esp_bt_gap_resolve_eir_data(eir, ESP_BT_EIR_TYPE_CMPL_LOCAL_NAME, &rmt_bdname_len);
if (!rmt_bdname) {
rmt_bdname = esp_bt_gap_resolve_eir_data(eir, ESP_BT_EIR_TYPE_SHORT_LOCAL_NAME, &rmt_bdname_len);
}
if (rmt_bdname) {
if (rmt_bdname_len > ESP_BT_GAP_MAX_BDNAME_LEN) {
rmt_bdname_len = ESP_BT_GAP_MAX_BDNAME_LEN;
}
if (bdname) {
memcpy(bdname, rmt_bdname, rmt_bdname_len);
bdname[rmt_bdname_len] = '\0';
}
if (bdname_len) {
*bdname_len = rmt_bdname_len;
}
return true;
}
return false;
}
static void filter_inquiry_scan_result(esp_bt_gap_cb_param_t *param)
{
char bda_str[18];
uint32_t cod = 0; /* class of device */
int32_t rssi = -129; /* invalid value */
uint8_t *eir = NULL;
esp_bt_gap_dev_prop_t *p;
/* handle the discovery results */
ESP_LOGI(BT_AV_TAG, "Scanned device: %s", bda2str(param->disc_res.bda, bda_str, 18));
for (int i = 0; i < param->disc_res.num_prop; i++) {
p = param->disc_res.prop + i;
switch (p->type) {
case ESP_BT_GAP_DEV_PROP_COD:
cod = *(uint32_t *)(p->val);
ESP_LOGI(BT_AV_TAG, "--Class of Device: 0x%x", cod);
break;
case ESP_BT_GAP_DEV_PROP_RSSI:
rssi = *(int8_t *)(p->val);
ESP_LOGI(BT_AV_TAG, "--RSSI: %d", rssi);
break;
case ESP_BT_GAP_DEV_PROP_EIR:
eir = (uint8_t *)(p->val);
break;
case ESP_BT_GAP_DEV_PROP_BDNAME:
default:
break;
}
}
/* search for device with MAJOR service class as "rendering" in COD */
if (!esp_bt_gap_is_valid_cod(cod) ||
!(esp_bt_gap_get_cod_srvc(cod) & ESP_BT_COD_SRVC_RENDERING)) {
return;
}
/* search for target device in its Extended Inqury Response */
if (eir) {
get_name_from_eir(eir, s_peer_bdname, NULL);
if (strcmp((char *)s_peer_bdname, TARGET_DEVICE_NAME) == 0) {
ESP_LOGI(BT_AV_TAG, "Found a target device, address %s, name %s", bda_str, s_peer_bdname);
s_a2d_state = APP_AV_STATE_DISCOVERED;
memcpy(s_peer_bda, param->disc_res.bda, ESP_BD_ADDR_LEN);
ESP_LOGI(BT_AV_TAG, "Cancel device discovery ...");
esp_bt_gap_cancel_discovery();
}
}
}
/* GAP callback function */
static void bt_app_gap_cb(esp_bt_gap_cb_event_t event, esp_bt_gap_cb_param_t *param)
{
switch (event) {
/* when device discovered a result, this event comes */
case ESP_BT_GAP_DISC_RES_EVT: {
if (s_a2d_state == APP_AV_STATE_DISCOVERING) {
filter_inquiry_scan_result(param);
}
break;
}
/* when discovery state changed, this event comes */
case ESP_BT_GAP_DISC_STATE_CHANGED_EVT: {
if (param->disc_st_chg.state == ESP_BT_GAP_DISCOVERY_STOPPED) {
if (s_a2d_state == APP_AV_STATE_DISCOVERED) {
s_a2d_state = APP_AV_STATE_CONNECTING;
ESP_LOGI(BT_AV_TAG, "Device discovery stopped.");
ESP_LOGI(BT_AV_TAG, "a2dp connecting to peer: %s", s_peer_bdname);
/* connect source to peer device specificed by Bluetooth Device Address */
esp_a2d_source_connect(s_peer_bda);
} else {
/* not discovered, continue to discover */
ESP_LOGI(BT_AV_TAG, "Device discovery failed, continue to discover...");
esp_bt_gap_start_discovery(ESP_BT_INQ_MODE_GENERAL_INQUIRY, 10, 0);
}
} else if (param->disc_st_chg.state == ESP_BT_GAP_DISCOVERY_STARTED) {
ESP_LOGI(BT_AV_TAG, "Discovery started.");
}
break;
}
/* when authentication completed, this event comes */
case ESP_BT_GAP_AUTH_CMPL_EVT: {
if (param->auth_cmpl.stat == ESP_BT_STATUS_SUCCESS) {
ESP_LOGI(BT_AV_TAG, "authentication success: %s", param->auth_cmpl.device_name);
esp_log_buffer_hex(BT_AV_TAG, param->auth_cmpl.bda, ESP_BD_ADDR_LEN);
} else {
ESP_LOGE(BT_AV_TAG, "authentication failed, status: %d", param->auth_cmpl.stat);
}
break;
}
/* when Legacy Pairing pin code requested, this event comes */
case ESP_BT_GAP_PIN_REQ_EVT: {
ESP_LOGI(BT_AV_TAG, "ESP_BT_GAP_PIN_REQ_EVT min_16_digit: %d", param->pin_req.min_16_digit);
if (param->pin_req.min_16_digit) {
ESP_LOGI(BT_AV_TAG, "Input pin code: 0000 0000 0000 0000");
esp_bt_pin_code_t pin_code = {0};
esp_bt_gap_pin_reply(param->pin_req.bda, true, 16, pin_code);
} else {
ESP_LOGI(BT_AV_TAG, "Input pin code: 1234");
esp_bt_pin_code_t pin_code;
pin_code[0] = '1';
pin_code[1] = '2';
pin_code[2] = '3';
pin_code[3] = '4';
esp_bt_gap_pin_reply(param->pin_req.bda, true, 4, pin_code);
}
break;
}
#if (CONFIG_BT_SSP_ENABLED == true)
/* when Security Simple Pairing user confirmation requested, this event comes */
case ESP_BT_GAP_CFM_REQ_EVT:
ESP_LOGI(BT_AV_TAG, "ESP_BT_GAP_CFM_REQ_EVT Please compare the numeric value: %d", param->cfm_req.num_val);
esp_bt_gap_ssp_confirm_reply(param->cfm_req.bda, true);
break;
/* when Security Simple Pairing passkey notified, this event comes */
case ESP_BT_GAP_KEY_NOTIF_EVT:
ESP_LOGI(BT_AV_TAG, "ESP_BT_GAP_KEY_NOTIF_EVT passkey: %d", param->key_notif.passkey);
break;
/* when Security Simple Pairing passkey requested, this event comes */
case ESP_BT_GAP_KEY_REQ_EVT:
ESP_LOGI(BT_AV_TAG, "ESP_BT_GAP_KEY_REQ_EVT Please enter passkey!");
break;
#endif
/* when GAP mode changed, this event comes */
case ESP_BT_GAP_MODE_CHG_EVT:
ESP_LOGI(BT_AV_TAG, "ESP_BT_GAP_MODE_CHG_EVT mode: %d", param->mode_chg.mode);
break;
/* other */
default: {
ESP_LOGI(BT_AV_TAG, "event: %d", event);
break;
}
}
return;
}
static void bt_av_hdl_stack_evt(uint16_t event, void *p_param)
{
ESP_LOGD(BT_AV_TAG, "%s event: %d", __func__, event);
switch (event) {
/* when stack up worked, this event comes */
case BT_APP_STACK_UP_EVT: {
char *dev_name = LOCAL_DEVICE_NAME;
esp_bt_dev_set_device_name(dev_name);
esp_bt_gap_register_callback(bt_app_gap_cb);
esp_avrc_ct_init();
esp_avrc_ct_register_callback(bt_app_rc_ct_cb);
esp_avrc_rn_evt_cap_mask_t evt_set = {0};
esp_avrc_rn_evt_bit_mask_operation(ESP_AVRC_BIT_MASK_OP_SET, &evt_set, ESP_AVRC_RN_VOLUME_CHANGE);
ESP_ERROR_CHECK(esp_avrc_tg_set_rn_evt_cap(&evt_set));
esp_a2d_source_init();
esp_a2d_register_callback(&bt_app_a2d_cb);
esp_a2d_source_register_data_callback(bt_app_a2d_data_cb);
/* set discoverable and connectable mode */
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
ESP_LOGI(BT_AV_TAG, "Starting device discovery...");
s_a2d_state = APP_AV_STATE_DISCOVERING;
esp_bt_gap_start_discovery(ESP_BT_INQ_MODE_GENERAL_INQUIRY, 10, 0);
/* create and start heart beat timer */
do {
int tmr_id = 0;
s_tmr = xTimerCreate("connTmr", (10000 / portTICK_RATE_MS),
pdTRUE, (void *) &tmr_id, bt_app_a2d_heart_beat);
xTimerStart(s_tmr, portMAX_DELAY);
} while (0);
break;
}
/* other */
default: {
ESP_LOGE(BT_AV_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
}
static void bt_app_a2d_cb(esp_a2d_cb_event_t event, esp_a2d_cb_param_t *param)
{
bt_app_work_dispatch(bt_app_av_sm_hdlr, event, param, sizeof(esp_a2d_cb_param_t), NULL);
}
/* generate some random noise to simulate source audio */
static int32_t bt_app_a2d_data_cb(uint8_t *data, int32_t len)
{
if (data == NULL || len < 0) {
return 0;
}
int *p_buf = (int *)data;
for (int i = 0; i < (len >> 1); i++) {
p_buf[i] = rand() % (1 << 16);
}
return len;
}
static void bt_app_a2d_heart_beat(TimerHandle_t arg)
{
bt_app_work_dispatch(bt_app_av_sm_hdlr, BT_APP_HEART_BEAT_EVT, NULL, 0, NULL);
}
static void bt_app_av_sm_hdlr(uint16_t event, void *param)
{
ESP_LOGI(BT_AV_TAG, "%s state: %d, event: 0x%x", __func__, s_a2d_state, event);
/* select handler according to different states. */
switch (s_a2d_state) {
case APP_AV_STATE_DISCOVERING:
case APP_AV_STATE_DISCOVERED:
break;
case APP_AV_STATE_UNCONNECTED:
bt_app_av_state_unconnected_hdlr(event, param);
break;
case APP_AV_STATE_CONNECTING:
bt_app_av_state_connecting_hdlr(event, param);
break;
case APP_AV_STATE_CONNECTED:
bt_app_av_state_connected_hdlr(event, param);
break;
case APP_AV_STATE_DISCONNECTING:
bt_app_av_state_disconnecting_hdlr(event, param);
break;
default:
ESP_LOGE(BT_AV_TAG, "%s invalid state: %d", __func__, s_a2d_state);
break;
}
}
static void bt_app_av_state_unconnected_hdlr(uint16_t event, void *param)
{
/* handle the events of intrest in unconnected state */
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT:
case ESP_A2D_AUDIO_STATE_EVT:
case ESP_A2D_AUDIO_CFG_EVT:
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
break;
case BT_APP_HEART_BEAT_EVT: {
uint8_t *bda = s_peer_bda;
ESP_LOGI(BT_AV_TAG, "a2dp connecting to peer: %02x:%02x:%02x:%02x:%02x:%02x",
bda[0], bda[1], bda[2], bda[3], bda[4], bda[5]);
esp_a2d_source_connect(s_peer_bda);
s_a2d_state = APP_AV_STATE_CONNECTING;
s_connecting_intv = 0;
break;
}
default: {
ESP_LOGE(BT_AV_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
}
static void bt_app_av_state_connecting_hdlr(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
/* handle the events of intrest in connecting state */
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_CONNECTED) {
ESP_LOGI(BT_AV_TAG, "a2dp connected");
s_a2d_state = APP_AV_STATE_CONNECTED;
s_media_state = APP_AV_MEDIA_STATE_IDLE;
esp_bt_gap_set_scan_mode(ESP_BT_NON_CONNECTABLE, ESP_BT_NON_DISCOVERABLE);
} else if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_DISCONNECTED) {
s_a2d_state = APP_AV_STATE_UNCONNECTED;
}
break;
}
case ESP_A2D_AUDIO_STATE_EVT:
case ESP_A2D_AUDIO_CFG_EVT:
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
break;
case BT_APP_HEART_BEAT_EVT:
/**
* Switch state to APP_AV_STATE_UNCONNECTED
* when connecting lasts more than 2 heart beat intervals.
*/
if (++s_connecting_intv >= 2) {
s_a2d_state = APP_AV_STATE_UNCONNECTED;
s_connecting_intv = 0;
}
break;
default:
ESP_LOGE(BT_AV_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
static void bt_app_av_media_proc(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
switch (s_media_state) {
case APP_AV_MEDIA_STATE_IDLE: {
if (event == BT_APP_HEART_BEAT_EVT) {
ESP_LOGI(BT_AV_TAG, "a2dp media ready checking ...");
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_CHECK_SRC_RDY);
} else if (event == ESP_A2D_MEDIA_CTRL_ACK_EVT) {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->media_ctrl_stat.cmd == ESP_A2D_MEDIA_CTRL_CHECK_SRC_RDY &&
a2d->media_ctrl_stat.status == ESP_A2D_MEDIA_CTRL_ACK_SUCCESS) {
ESP_LOGI(BT_AV_TAG, "a2dp media ready, starting ...");
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_START);
s_media_state = APP_AV_MEDIA_STATE_STARTING;
}
}
break;
}
case APP_AV_MEDIA_STATE_STARTING: {
if (event == ESP_A2D_MEDIA_CTRL_ACK_EVT) {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->media_ctrl_stat.cmd == ESP_A2D_MEDIA_CTRL_START &&
a2d->media_ctrl_stat.status == ESP_A2D_MEDIA_CTRL_ACK_SUCCESS) {
ESP_LOGI(BT_AV_TAG, "a2dp media start successfully.");
s_intv_cnt = 0;
s_media_state = APP_AV_MEDIA_STATE_STARTED;
} else {
/* not started succesfully, transfer to idle state */
ESP_LOGI(BT_AV_TAG, "a2dp media start failed.");
s_media_state = APP_AV_MEDIA_STATE_IDLE;
}
}
break;
}
case APP_AV_MEDIA_STATE_STARTED: {
if (event == BT_APP_HEART_BEAT_EVT) {
/* stop media after 10 heart beat intervals */
if (++s_intv_cnt >= 10) {
ESP_LOGI(BT_AV_TAG, "a2dp media stopping...");
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_STOP);
s_media_state = APP_AV_MEDIA_STATE_STOPPING;
s_intv_cnt = 0;
}
}
break;
}
case APP_AV_MEDIA_STATE_STOPPING: {
if (event == ESP_A2D_MEDIA_CTRL_ACK_EVT) {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->media_ctrl_stat.cmd == ESP_A2D_MEDIA_CTRL_STOP &&
a2d->media_ctrl_stat.status == ESP_A2D_MEDIA_CTRL_ACK_SUCCESS) {
ESP_LOGI(BT_AV_TAG, "a2dp media stopped successfully, disconnecting...");
s_media_state = APP_AV_MEDIA_STATE_IDLE;
esp_a2d_source_disconnect(s_peer_bda);
s_a2d_state = APP_AV_STATE_DISCONNECTING;
} else {
ESP_LOGI(BT_AV_TAG, "a2dp media stopping...");
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_STOP);
}
}
break;
}
default: {
break;
}
}
}
static void bt_app_av_state_connected_hdlr(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
/* handle the events of intrest in connected state */
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_DISCONNECTED) {
ESP_LOGI(BT_AV_TAG, "a2dp disconnected");
s_a2d_state = APP_AV_STATE_UNCONNECTED;
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
}
break;
}
case ESP_A2D_AUDIO_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(param);
if (ESP_A2D_AUDIO_STATE_STARTED == a2d->audio_stat.state) {
s_pkt_cnt = 0;
}
break;
}
case ESP_A2D_AUDIO_CFG_EVT:
/* not suppposed to occur for A2DP source */
break;
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
case BT_APP_HEART_BEAT_EVT: {
bt_app_av_media_proc(event, param);
break;
}
default: {
ESP_LOGE(BT_AV_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
}
static void bt_app_av_state_disconnecting_hdlr(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
/* handle the events of intrest in disconnecing state */
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(param);
if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_DISCONNECTED) {
ESP_LOGI(BT_AV_TAG, "a2dp disconnected");
s_a2d_state = APP_AV_STATE_UNCONNECTED;
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
}
break;
}
case ESP_A2D_AUDIO_STATE_EVT:
case ESP_A2D_AUDIO_CFG_EVT:
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
case BT_APP_HEART_BEAT_EVT:
break;
default: {
ESP_LOGE(BT_AV_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
}
/* callback function for AVRCP controller */
static void bt_app_rc_ct_cb(esp_avrc_ct_cb_event_t event, esp_avrc_ct_cb_param_t *param)
{
switch (event) {
case ESP_AVRC_CT_CONNECTION_STATE_EVT:
case ESP_AVRC_CT_PASSTHROUGH_RSP_EVT:
case ESP_AVRC_CT_METADATA_RSP_EVT:
case ESP_AVRC_CT_CHANGE_NOTIFY_EVT:
case ESP_AVRC_CT_REMOTE_FEATURES_EVT:
case ESP_AVRC_CT_GET_RN_CAPABILITIES_RSP_EVT:
case ESP_AVRC_CT_SET_ABSOLUTE_VOLUME_RSP_EVT: {
bt_app_work_dispatch(bt_av_hdl_avrc_ct_evt, event, param, sizeof(esp_avrc_ct_cb_param_t), NULL);
break;
}
default: {
ESP_LOGE(BT_RC_CT_TAG, "Invalid AVRC event: %d", event);
break;
}
}
}
static void bt_av_volume_changed(void)
{
if (esp_avrc_rn_evt_bit_mask_operation(ESP_AVRC_BIT_MASK_OP_TEST, &s_avrc_peer_rn_cap,
ESP_AVRC_RN_VOLUME_CHANGE)) {
esp_avrc_ct_send_register_notification_cmd(APP_RC_CT_TL_RN_VOLUME_CHANGE, ESP_AVRC_RN_VOLUME_CHANGE, 0);
}
}
void bt_av_notify_evt_handler(uint8_t event_id, esp_avrc_rn_param_t *event_parameter)
{
switch (event_id) {
/* when volume changed locally on target, this event comes */
case ESP_AVRC_RN_VOLUME_CHANGE: {
ESP_LOGI(BT_RC_CT_TAG, "Volume changed: %d", event_parameter->volume);
ESP_LOGI(BT_RC_CT_TAG, "Set absolute volume: volume %d", event_parameter->volume + 5);
esp_avrc_ct_send_set_absolute_volume_cmd(APP_RC_CT_TL_RN_VOLUME_CHANGE, event_parameter->volume + 5);
bt_av_volume_changed();
break;
}
/* other */
default:
break;
}
}
/* AVRC controller event handler */
static void bt_av_hdl_avrc_ct_evt(uint16_t event, void *p_param)
{
ESP_LOGD(BT_RC_CT_TAG, "%s evt %d", __func__, event);
esp_avrc_ct_cb_param_t *rc = (esp_avrc_ct_cb_param_t *)(p_param);
switch (event) {
/* when connection state changed, this event comes */
case ESP_AVRC_CT_CONNECTION_STATE_EVT: {
uint8_t *bda = rc->conn_stat.remote_bda;
ESP_LOGI(BT_RC_CT_TAG, "AVRC conn_state event: state %d, [%02x:%02x:%02x:%02x:%02x:%02x]",
rc->conn_stat.connected, bda[0], bda[1], bda[2], bda[3], bda[4], bda[5]);
if (rc->conn_stat.connected) {
esp_avrc_ct_send_get_rn_capabilities_cmd(APP_RC_CT_TL_GET_CAPS);
} else {
s_avrc_peer_rn_cap.bits = 0;
}
break;
}
/* when passthrough responsed, this event comes */
case ESP_AVRC_CT_PASSTHROUGH_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC passthrough response: key_code 0x%x, key_state %d", rc->psth_rsp.key_code, rc->psth_rsp.key_state);
break;
}
/* when metadata responsed, this event comes */
case ESP_AVRC_CT_METADATA_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC metadata response: attribute id 0x%x, %s", rc->meta_rsp.attr_id, rc->meta_rsp.attr_text);
free(rc->meta_rsp.attr_text);
break;
}
/* when notification changed, this event comes */
case ESP_AVRC_CT_CHANGE_NOTIFY_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC event notification: %d", rc->change_ntf.event_id);
bt_av_notify_evt_handler(rc->change_ntf.event_id, &rc->change_ntf.event_parameter);
break;
}
/* when indicate feature of remote device, this event comes */
case ESP_AVRC_CT_REMOTE_FEATURES_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC remote features %x, TG features %x", rc->rmt_feats.feat_mask, rc->rmt_feats.tg_feat_flag);
break;
}
/* when get supported notification events capability of peer device, this event comes */
case ESP_AVRC_CT_GET_RN_CAPABILITIES_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "remote rn_cap: count %d, bitmask 0x%x", rc->get_rn_caps_rsp.cap_count,
rc->get_rn_caps_rsp.evt_set.bits);
s_avrc_peer_rn_cap.bits = rc->get_rn_caps_rsp.evt_set.bits;
bt_av_volume_changed();
break;
}
/* when set absolute volume responsed, this event comes */
case ESP_AVRC_CT_SET_ABSOLUTE_VOLUME_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "Set absolute volume response: volume %d", rc->set_volume_rsp.volume);
break;
}
/* other */
default: {
ESP_LOGE(BT_RC_CT_TAG, "%s unhandled event: %d", __func__, event);
break;
}
}
}
/*********************************
* MAIN ENTRY POINT
********************************/
void app_main(void)
{
/* initialize NVS — it is used to store PHY calibration data */
esp_err_t ret = nvs_flash_init();
if (ret == ESP_ERR_NVS_NO_FREE_PAGES || ret == ESP_ERR_NVS_NEW_VERSION_FOUND) {
ESP_ERROR_CHECK(nvs_flash_erase());
ret = nvs_flash_init();
}
ESP_ERROR_CHECK(ret);
/*
* This example only uses the functions of Classical Bluetooth.
* So release the controller memory for Bluetooth Low Energy.
*/
ESP_ERROR_CHECK(esp_bt_controller_mem_release(ESP_BT_MODE_BLE));
esp_bt_controller_config_t bt_cfg = BT_CONTROLLER_INIT_CONFIG_DEFAULT();
if (esp_bt_controller_init(&bt_cfg) != ESP_OK) {
ESP_LOGE(BT_AV_TAG, "%s initialize controller failed\n", __func__);
return;
}
if (esp_bt_controller_enable(ESP_BT_MODE_CLASSIC_BT) != ESP_OK) {
ESP_LOGE(BT_AV_TAG, "%s enable controller failed\n", __func__);
return;
}
if (esp_bluedroid_init() != ESP_OK) {
ESP_LOGE(BT_AV_TAG, "%s initialize bluedroid failed\n", __func__);
return;
}
if (esp_bluedroid_enable() != ESP_OK) {
ESP_LOGE(BT_AV_TAG, "%s enable bluedroid failed\n", __func__);
return;
}
#if (CONFIG_BT_SSP_ENABLED == true)
/* set default parameters for Secure Simple Pairing */
esp_bt_sp_param_t param_type = ESP_BT_SP_IOCAP_MODE;
esp_bt_io_cap_t iocap = ESP_BT_IO_CAP_IO;
esp_bt_gap_set_security_param(param_type, &iocap, sizeof(uint8_t));
#endif
/*
* Set default parameters for Legacy Pairing
* Use variable pin, input pin code when pairing
*/
esp_bt_pin_type_t pin_type = ESP_BT_PIN_TYPE_VARIABLE;
esp_bt_pin_code_t pin_code;
esp_bt_gap_set_pin(pin_type, 0, pin_code);
bt_app_task_start_up();
/* Bluetooth device name, connection mode and profile set up */
bt_app_work_dispatch(bt_av_hdl_stack_evt, BT_APP_STACK_UP_EVT, NULL, 0, NULL);
}