#include <stdio.h>
#include <string.h>
#include <ctype.h>
#include <stdlib.h>
#include "bt_app_core.h"
#include "esp_log.h"
#include "esp_bt.h"
#include "esp_bt_device.h"
#include "esp_bt_main.h"
#include "esp_gap_bt_api.h"
#include "esp_a2dp_api.h"
#include "esp_avrc_api.h"
#include "esp_console.h"
#include "esp_pthread.h"
#include "esp_system.h"
#include "esp_wifi.h"
#include "freertos/timers.h"
#include "argtable3/argtable3.h"
#include "platform_config.h"
#include "trace.h"
#include "messaging.h"
#include "cJSON.h"
static const char * TAG = "bt_app_source";
static const char * BT_RC_CT_TAG="RCCT";
extern int32_t output_bt_data(uint8_t *data, int32_t len);
extern void output_bt_tick(void);
extern char* output_state_str(void);
extern bool output_stopped(void);
static void bt_app_av_state_connecting(uint16_t event, void *param);
static void filter_inquiry_scan_result(esp_bt_gap_cb_param_t *param);
/* event for handler "bt_av_hdl_stack_up */
enum {
BT_APP_EVT_STACK_UP = 0,
};
char * APP_AV_STATE_DESC[] = {
"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"
};
static char * ESP_AVRC_CT_DESC[]={
"ESP_AVRC_CT_CONNECTION_STATE_EVT",
"ESP_AVRC_CT_PASSTHROUGH_RSP_EVT",
"ESP_AVRC_CT_METADATA_RSP_EVT",
"ESP_AVRC_CT_PLAY_STATUS_RSP_EVT",
"ESP_AVRC_CT_CHANGE_NOTIFY_EVT",
"ESP_AVRC_CT_REMOTE_FEATURES_EVT",
"ESP_AVRC_CT_GET_RN_CAPABILITIES_RSP_EVT",
"ESP_AVRC_CT_SET_ABSOLUTE_VOLUME_RSP_EVT"
};
#define BT_APP_HEART_BEAT_EVT (0xff00)
// AVRCP used transaction label
#define APP_RC_CT_TL_GET_CAPS (0)
#define APP_RC_CT_TL_RN_VOLUME_CHANGE (1)
#define PEERS_LIST_MAINTAIN_RESET -129
#define PEERS_LIST_MAINTAIN_PURGE -129
/// handler for bluetooth stack enabled events
static void bt_av_hdl_stack_evt(uint16_t event, void *p_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 AVRCP controller
static void bt_app_rc_ct_cb(esp_avrc_ct_cb_event_t event, esp_avrc_ct_cb_param_t *param);
/// avrc CT event handler
static void bt_av_hdl_avrc_ct_evt(uint16_t event, void *p_param);
/// callback function for A2DP source audio data stream
static void a2d_app_heart_beat(void *arg);
/// A2DP application state machine
static void bt_app_av_sm_hdlr(uint16_t event, void *param);
/* A2DP application state machine handler for each state */
static void bt_app_av_state_unconnected(uint16_t event, void *param);
static void bt_app_av_state_connecting(uint16_t event, void *param);
static void bt_app_av_state_connected(uint16_t event, void *param);
static void bt_app_av_state_disconnecting(uint16_t event, void *param);
static void handle_connect_state_unconnected(uint16_t event, esp_a2d_cb_param_t *param);
static void handle_connect_state_connecting(uint16_t event, esp_a2d_cb_param_t *param);
static void handle_connect_state_connected(uint16_t event, esp_a2d_cb_param_t *param);
static void handle_connect_state_disconnecting(uint16_t event, esp_a2d_cb_param_t *param);
static void bt_av_notify_evt_handler(uint8_t event_id, esp_avrc_rn_param_t *event_parameter);
static esp_bd_addr_t s_peer_bda = {0};
static uint8_t s_peer_bdname[ESP_BT_GAP_MAX_BDNAME_LEN + 1];
int bt_app_source_a2d_state = APP_AV_STATE_IDLE;
int bt_app_source_media_state = APP_AV_MEDIA_STATE_IDLE;
static uint32_t s_pkt_cnt = 0;
static TimerHandle_t s_tmr=NULL;
static int prev_duration=10000;
static esp_avrc_rn_evt_cap_mask_t s_avrc_peer_rn_cap;
static int s_connecting_intv = 0;
cJSON * peers_list=NULL;
static struct {
// int control_delay;
// int connect_timeout_delay;
char * sink_name;
} squeezelite_conf;
static cJSON * peers_list_get_entry(const char * s_peer_bdname){
cJSON * element=NULL;
cJSON_ArrayForEach(element,peers_list){
cJSON * name = cJSON_GetObjectItem(element,"name");
if(name && !strcmp(cJSON_GetStringValue(name),s_peer_bdname)){
ESP_LOGV(TAG,"Entry name %s found in current scan list", s_peer_bdname);
return element;
}
}
ESP_LOGV(TAG,"Entry name %s NOT found in current scan list", s_peer_bdname);
return NULL;
}
static void peers_list_reset(){
cJSON * element=NULL;
cJSON_ArrayForEach(element,peers_list){
cJSON * rssi = cJSON_GetObjectItem(element,"rssi");
if(rssi){
rssi->valuedouble = -129;
rssi->valueint = -129;
}
}
}
static void peers_list_purge(){
cJSON * element=NULL;
cJSON_ArrayForEach(element,peers_list){
cJSON * rssi_val = cJSON_GetObjectItem(element,"rssi");
if(rssi_val && rssi_val->valuedouble == -129){
cJSON * name = cJSON_GetObjectItem(element,"name");
ESP_LOGV(TAG,"Purging %s", cJSON_GetStringValue(name)?cJSON_GetStringValue(name):"Unknown");
cJSON_DetachItemViaPointer(peers_list,element);
cJSON_Delete(element);
}
}
}
static cJSON * peers_list_create_entry(const char * s_peer_bdname, int32_t rssi){
cJSON * entry = cJSON_CreateObject();
cJSON_AddStringToObject(entry,"name",s_peer_bdname);
cJSON_AddNumberToObject(entry,"rssi",rssi);
return entry;
}
static void peers_list_update_add(const char * s_peer_bdname, int32_t rssi){
cJSON * element= peers_list_get_entry(s_peer_bdname);
if(element){
cJSON * rssi_val = cJSON_GetObjectItem(element,"rssi");
if(rssi_val && rssi_val->valuedouble != rssi){
ESP_LOGV(TAG,"Updating BT Sink Device: %s rssi to %i", s_peer_bdname,rssi);
rssi_val->valuedouble = rssi;
rssi_val->valueint = rssi;
}
}
else {
ESP_LOGI(TAG,"Found BT Sink Device: %s rssi is %i", s_peer_bdname,rssi);
element = peers_list_create_entry( s_peer_bdname, rssi);
cJSON_AddItemToArray(peers_list,element);
}
}
static void peers_list_maintain(const char * s_peer_bdname, int32_t rssi){
if(!peers_list){
ESP_LOGV(TAG,"Initializing BT peers list");
peers_list=cJSON_CreateArray();
}
if(rssi==PEERS_LIST_MAINTAIN_RESET){
ESP_LOGV(TAG,"Resetting BT peers list");
peers_list_reset();
}
else if(rssi==PEERS_LIST_MAINTAIN_PURGE){
ESP_LOGV(TAG,"Purging BT peers list");
peers_list_purge();
}
if(s_peer_bdname) {
ESP_LOGV(TAG,"Adding/Updating peer %s rssi %i", s_peer_bdname,rssi);
peers_list_update_add(s_peer_bdname, rssi);
}
char * list_json = cJSON_Print(peers_list);
if(list_json){
messaging_post_message(MESSAGING_INFO, MESSAGING_CLASS_BT, list_json);
ESP_LOGV(TAG,"%s", list_json);
free(list_json);
}
}
int bt_app_source_get_a2d_state(){
ESP_LOGD(TAG,"a2dp status: %u = %s", bt_app_source_a2d_state, APP_AV_STATE_DESC[bt_app_source_a2d_state]);
return bt_app_source_a2d_state;
}
int bt_app_source_get_media_state(){
ESP_LOGD(TAG,"media state : %u ", bt_app_source_media_state);
return bt_app_source_media_state;
}
void set_app_source_state(int new_state){
if(bt_app_source_a2d_state!=new_state){
ESP_LOGD(TAG, "Updating state from %s to %s", APP_AV_STATE_DESC[bt_app_source_a2d_state], APP_AV_STATE_DESC[new_state]);
bt_app_source_a2d_state=new_state;
}
}
void set_a2dp_media_state(int new_state){
if(bt_app_source_media_state!=new_state){
bt_app_source_media_state=new_state;
}
}
void hal_bluetooth_init(const char * options)
{
struct {
struct arg_str *sink_name;
// struct arg_int *control_delay;
// struct arg_int *connect_timeout_delay;
struct arg_end *end;
} squeezelite_args;
ESP_LOGD(TAG,"Initializing Bluetooth HAL");
squeezelite_args.sink_name = arg_str0("n", "name", "<sink name>", "the name of the bluetooth to connect to");
// squeezelite_args.control_delay = arg_int0("d", "delay", "<control delay>", "the delay between each pass at the A2DP control loop");
// squeezelite_args.connect_timeout_delay = arg_int0("t","timeout", "<timeout>", "the timeout duration for connecting to the A2DP sink");
squeezelite_args.end = arg_end(2);
ESP_LOGD(TAG,"Copying parameters");
char * opts = strdup(options);
char **argv = malloc(sizeof(char**)*15);
size_t argv_size=15;
// change parms so ' appear as " for parsing the options
for (char* p = opts; (p = strchr(p, '\'')); ++p) *p = '"';
ESP_LOGD(TAG,"Splitting arg line: %s", opts);
argv_size = esp_console_split_argv(opts, argv, argv_size);
ESP_LOGD(TAG,"Parsing parameters");
int nerrors = arg_parse(argv_size , argv, (void **) &squeezelite_args);
if (nerrors != 0) {
ESP_LOGD(TAG,"Parsing Errors");
arg_print_errors(stdout, squeezelite_args.end, "BT");
arg_print_glossary_gnu(stdout, (void **) &squeezelite_args);
free(opts);
free(argv);
return;
}
if(squeezelite_args.sink_name->count == 0)
{
squeezelite_conf.sink_name = config_alloc_get_default(NVS_TYPE_STR, "a2dp_sink_name", NULL, 0);
if(!squeezelite_conf.sink_name || strlen(squeezelite_conf.sink_name)==0 ){
ESP_LOGW(TAG,"Unable to retrieve the a2dp sink name from nvs.");
}
} else {
squeezelite_conf.sink_name=strdup(squeezelite_args.sink_name->sval[0]);
// sync with NVS
esp_err_t err=ESP_OK;
if((err= config_set_value(NVS_TYPE_STR, "a2dp_sink_name", squeezelite_args.sink_name->sval[0]))!=ESP_OK){
ESP_LOGE(TAG,"Error setting Bluetooth audio device name %s. %s",squeezelite_args.sink_name->sval[0], esp_err_to_name(err));
}
else {
ESP_LOGI(TAG,"Bluetooth audio device name changed to %s",squeezelite_args.sink_name->sval[0]);
}
}
// if(squeezelite_args.connect_timeout_delay->count == 0)
// {
// ESP_LOGD(TAG,"Using default connect timeout");
// char * p = config_alloc_get_default(NVS_TYPE_STR, "a2dp_ctmt", NULL, 0);
// if(p){
// squeezelite_conf.connect_timeout_delay=atoi(p);
// free(p);
// }
// else {
// squeezelite_conf.connect_timeout_delay=CONFIG_A2DP_CONNECT_TIMEOUT_MS;
// }
// } else {
// squeezelite_conf.connect_timeout_delay=squeezelite_args.connect_timeout_delay->ival[0];
// }
// if(squeezelite_args.control_delay->count == 0)
// {
// ESP_LOGD(TAG,"Using default control delay");
// char * p = config_alloc_get_default(NVS_TYPE_STR, "a2dp_ctrld", NULL, 0);
// if(p){
// squeezelite_conf.control_delay=atoi(p);
// free(p);
// }
// else {
// squeezelite_conf.control_delay=CONFIG_A2DP_CONNECT_TIMEOUT_MS;
// }
// } else {
// squeezelite_conf.control_delay=squeezelite_args.control_delay->ival[0];
// }
ESP_LOGD(TAG,"Freeing options");
free(argv);
free(opts);
/*
* Bluetooth audio source init Start
*/
//running_test = false;
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(TAG,"%s initialize controller failed\n", __func__);
return;
}
if (esp_bt_controller_enable(ESP_BT_MODE_CLASSIC_BT) != ESP_OK) {
ESP_LOGE(TAG,"%s enable controller failed\n", __func__);
return;
}
if (esp_bluedroid_init() != ESP_OK) {
ESP_LOGE(TAG,"%s initialize bluedroid failed\n", __func__);
return;
}
if (esp_bluedroid_enable() != ESP_OK) {
ESP_LOGE(TAG,"%s enable bluedroid failed\n", __func__);
return;
}
/* create application task */
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_EVT_STACK_UP, NULL, 0, NULL);
#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);
}
void hal_bluetooth_stop(void) {
/* this still does not work, can't figure out how to stop properly this BT stack */
bt_app_task_shut_down();
ESP_LOGI(TAG, "bt_app_task shutdown successfully");
if (esp_bluedroid_disable() != ESP_OK) return;
ESP_LOGI(TAG, "esp_bluedroid_disable called successfully");
if (esp_bluedroid_deinit() != ESP_OK) return;
ESP_LOGI(TAG, "esp_bluedroid_deinit called successfully");
if (esp_bt_controller_disable() != ESP_OK) return;
ESP_LOGI(TAG, "esp_bt_controller_disable called successfully");
if (esp_bt_controller_deinit() != ESP_OK) return;
ESP_LOGI(TAG, "bt stopped successfully");
}
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);
}
static void handle_bt_gap_pin_req(esp_bt_gap_cb_event_t event, esp_bt_gap_cb_param_t *param){
char * pin_str = config_alloc_get_default(NVS_TYPE_STR, "a2dp_spin", "0000", 0);
int pinlen=pin_str?strlen(pin_str):0;
if (pin_str && ((!param->pin_req.min_16_digit && pinlen==4) || (param->pin_req.min_16_digit && pinlen==16))) {
ESP_LOGI(TAG,"Input pin code %s: ",pin_str);
esp_bt_pin_code_t pin_code;
for (size_t i = 0; i < pinlen; i++)
{
pin_code[i] = pin_str[i];
}
esp_bt_gap_pin_reply(param->pin_req.bda, true, pinlen, pin_code);
}
else {
if(pinlen>0){
ESP_LOGW(TAG,"Pin length: %u does not match the length expected by the device: %u", pinlen, ((param->pin_req.min_16_digit)?16:4));
}
else {
ESP_LOGW(TAG, "No security Pin provided. Trying with default pins.");
}
if (param->pin_req.min_16_digit) {
ESP_LOGI(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(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);
}
}
FREE_AND_NULL(pin_str);
}
static void bt_app_gap_cb(esp_bt_gap_cb_event_t event, esp_bt_gap_cb_param_t *param)
{
switch (event) {
case ESP_BT_GAP_DISC_RES_EVT: {
filter_inquiry_scan_result(param);
break;
}
case ESP_BT_GAP_DISC_STATE_CHANGED_EVT: {
if (param->disc_st_chg.state == ESP_BT_GAP_DISCOVERY_STOPPED)
{
peers_list_maintain(NULL, PEERS_LIST_MAINTAIN_PURGE);
if (bt_app_source_a2d_state == APP_AV_STATE_DISCOVERED)
{
ESP_LOGI(TAG,"Discovery completed. Ready to start connecting to %s. ",s_peer_bdname);
set_app_source_state(APP_AV_STATE_UNCONNECTED);
}
else
{
// not discovered, continue to discover
ESP_LOGI(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(TAG,"Discovery started.");
peers_list_maintain(NULL, PEERS_LIST_MAINTAIN_RESET);
}
else
{
ESP_LOGD(TAG,"This shouldn't happen. Discovery has only 2 states (for now).");
}
break;
}
case ESP_BT_GAP_RMT_SRVCS_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_BT_GAP_RMT_SRVCS_EVT));
break;
case ESP_BT_GAP_RMT_SRVC_REC_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_BT_GAP_RMT_SRVC_REC_EVT));
break;
case ESP_BT_GAP_AUTH_CMPL_EVT: {
if (param->auth_cmpl.stat == ESP_BT_STATUS_SUCCESS) {
ESP_LOGI(TAG,"authentication success: %s", param->auth_cmpl.device_name);
//esp_log_buffer_hex(param->auth_cmpl.bda, ESP_BD_ADDR_LEN);
} else {
ESP_LOGE(TAG,"authentication failed, status:%d", param->auth_cmpl.stat);
}
break;
}
case ESP_BT_GAP_PIN_REQ_EVT:
handle_bt_gap_pin_req(event, param);
break;
#if (CONFIG_BT_SSP_ENABLED == true)
case ESP_BT_GAP_CFM_REQ_EVT:
ESP_LOGI(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;
case ESP_BT_GAP_KEY_NOTIF_EVT:
ESP_LOGI(TAG,"ESP_BT_GAP_KEY_NOTIF_EVT passkey:%d", param->key_notif.passkey);
break;
ESP_LOGI(TAG,"ESP_BT_GAP_KEY_REQ_EVT Please enter passkey!");
break;
#endif
default: {
ESP_LOGI(TAG,"event: %d", event);
break;
}
}
return;
}
int heart_beat_delay[] = {
1000,
1000,
1000,
1000,
10000,
500,
1000
};
static void a2d_app_heart_beat(void *arg)
{
bt_app_work_dispatch(bt_app_av_sm_hdlr, BT_APP_HEART_BEAT_EVT, NULL, 0, NULL);
int tmrduration=heart_beat_delay[bt_app_source_a2d_state];
if(prev_duration!=tmrduration){
xTimerChangePeriod(s_tmr,tmrduration, portMAX_DELAY);
ESP_LOGD(TAG,"New heartbeat is %u",tmrduration);
prev_duration=tmrduration;
}
else {
ESP_LOGD(TAG,"Starting Heart beat timer for %ums",tmrduration);
}
xTimerStart(s_tmr, portMAX_DELAY);
}
static const char * conn_state_str(esp_a2d_connection_state_t state){
char * statestr = "Unknown";
switch (state)
{
case ESP_A2D_CONNECTION_STATE_DISCONNECTED:
statestr=STR(ESP_A2D_CONNECTION_STATE_DISCONNECTED);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTING:
statestr=STR(ESP_A2D_CONNECTION_STATE_CONNECTING);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTED:
statestr=STR(ESP_A2D_CONNECTION_STATE_CONNECTED);
break;
case ESP_A2D_CONNECTION_STATE_DISCONNECTING:
statestr=STR(ESP_A2D_CONNECTION_STATE_DISCONNECTING);
break;
default:
break;
}
return statestr;
}
static void unexpected_connection_state(int from, esp_a2d_connection_state_t to)
{
ESP_LOGW(TAG,"Unexpected connection state change. App State: %s (%u) Connection State %s (%u)", APP_AV_STATE_DESC[from], from,conn_state_str(to), to);
}
static void handle_connect_state_unconnected(uint16_t event, esp_a2d_cb_param_t *param){
ESP_LOGV(TAG, "A2DP Event while unconnected ");
switch (param->conn_stat.state)
{
case ESP_A2D_CONNECTION_STATE_DISCONNECTED:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
set_app_source_state(APP_AV_STATE_UNCONNECTED);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTED:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
ESP_LOGE(TAG,"Connection state event received while status was unconnected. Routing message to connecting state handler. State : %u",param->conn_stat.state);
if (param->conn_stat.state == ESP_A2D_CONNECTION_STATE_CONNECTED){
handle_connect_state_connecting(event, param);
}
break;
case ESP_A2D_CONNECTION_STATE_DISCONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
default:
break;
}
}
static void handle_connect_state_connecting(uint16_t event, esp_a2d_cb_param_t *param){
ESP_LOGV(TAG, "A2DP connection state event : %s ",conn_state_str(param->conn_stat.state));
// 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;
// }
switch (param->conn_stat.state)
{
case ESP_A2D_CONNECTION_STATE_DISCONNECTED:
if(param->conn_stat.disc_rsn!=ESP_A2D_DISC_RSN_NORMAL){
ESP_LOGE(TAG,"A2DP had an abnormal disconnect event");
}
else {
ESP_LOGW(TAG,"A2DP connect unsuccessful");
}
set_app_source_state(APP_AV_STATE_UNCONNECTED);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTING: {
break;
}
case ESP_A2D_CONNECTION_STATE_CONNECTED:
set_app_source_state(APP_AV_STATE_CONNECTED);
set_a2dp_media_state(APP_AV_MEDIA_STATE_IDLE);
ESP_LOGD(TAG,"Setting scan mode to ESP_BT_NON_CONNECTABLE, ESP_BT_NON_DISCOVERABLE");
esp_bt_gap_set_scan_mode(ESP_BT_NON_CONNECTABLE, ESP_BT_NON_DISCOVERABLE);
ESP_LOGD(TAG,"Done setting scan mode. App state is now CONNECTED and media state IDLE.");
break;
case ESP_A2D_CONNECTION_STATE_DISCONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
set_app_source_state(APP_AV_STATE_DISCONNECTING);
break;
default:
break;
}
}
static void handle_connect_state_connected(uint16_t event, esp_a2d_cb_param_t *param){
ESP_LOGV(TAG, "A2DP Event while connected ");
switch (param->conn_stat.state)
{
case ESP_A2D_CONNECTION_STATE_DISCONNECTED:
ESP_LOGW(TAG,"a2dp disconnected");
set_app_source_state(APP_AV_STATE_UNCONNECTED);
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTED:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
case ESP_A2D_CONNECTION_STATE_DISCONNECTING:
set_app_source_state(APP_AV_STATE_DISCONNECTING);
break;
default:
break;
}
}
static void handle_connect_state_disconnecting(uint16_t event, esp_a2d_cb_param_t *param){
ESP_LOGV(TAG, "A2DP Event while disconnecting ");
switch (param->conn_stat.state)
{
case ESP_A2D_CONNECTION_STATE_DISCONNECTED:
ESP_LOGI(TAG,"a2dp disconnected");
set_app_source_state(APP_AV_STATE_UNCONNECTED);
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
case ESP_A2D_CONNECTION_STATE_CONNECTED:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
case ESP_A2D_CONNECTION_STATE_DISCONNECTING:
unexpected_connection_state(bt_app_source_a2d_state, param->conn_stat.state);
break;
default:
break;
}
}
static void bt_app_av_sm_hdlr(uint16_t event, void *param)
{
ESP_LOGV(TAG,"bt_app_av_sm_hdlr.%s a2d state: %s", event==BT_APP_HEART_BEAT_EVT?"Heart Beat.":"",APP_AV_STATE_DESC[bt_app_source_a2d_state]);
switch (bt_app_source_a2d_state) {
case APP_AV_STATE_DISCOVERING:
ESP_LOGV(TAG,"state %s, evt 0x%x, output state: %s", APP_AV_STATE_DESC[bt_app_source_a2d_state], event, output_state_str());
break;
case APP_AV_STATE_DISCOVERED:
ESP_LOGV(TAG,"state %s, evt 0x%x, output state: %s", APP_AV_STATE_DESC[bt_app_source_a2d_state], event, output_state_str());
break;
case APP_AV_STATE_UNCONNECTED:
bt_app_av_state_unconnected(event, param);
break;
case APP_AV_STATE_CONNECTING:
bt_app_av_state_connecting(event, param);
break;
case APP_AV_STATE_CONNECTED:
bt_app_av_state_connected(event, param);
break;
case APP_AV_STATE_DISCONNECTING:
bt_app_av_state_disconnecting(event, param);
break;
default:
ESP_LOGE(TAG,"%s invalid state %d", __func__, bt_app_source_a2d_state);
break;
}
}
static char *bda2str(esp_bd_addr_t bda, char *str, size_t size)
{
if (bda == NULL || str == NULL || size < 18) {
return NULL;
}
uint8_t *p = bda;
sprintf(str, "%02x:%02x:%02x:%02x:%02x:%02x",
p[0], p[1], p[2], p[3], p[4], p[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;
}
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;
int32_t rssi = -129; /* invalid value */
uint8_t *eir = NULL;
uint8_t nameLen = 0;
esp_bt_gap_dev_prop_t *p;
memset(bda_str, 0x00, sizeof(bda_str));
if(bt_app_source_a2d_state != APP_AV_STATE_DISCOVERING)
{
// Ignore messages that might have been queued already
// when we've discovered the target device.
return;
}
memset(s_peer_bdname, 0x00,sizeof(s_peer_bdname));
bda2str(param->disc_res.bda, bda_str, 18);
ESP_LOGV(TAG,"\n=======================\nScanned device: %s",bda_str );
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_LOGV(TAG,"-- Class of Device: 0x%x", cod);
break;
case ESP_BT_GAP_DEV_PROP_RSSI:
rssi = *(int8_t *)(p->val);
ESP_LOGV(TAG,"-- RSSI: %d", rssi);
break;
case ESP_BT_GAP_DEV_PROP_EIR:
eir = (uint8_t *)(p->val);
ESP_LOGV(TAG,"-- EIR: %u", *eir);
break;
case ESP_BT_GAP_DEV_PROP_BDNAME:
nameLen = (p->len > ESP_BT_GAP_MAX_BDNAME_LEN) ? ESP_BT_GAP_MAX_BDNAME_LEN : (uint8_t)p->len;
memcpy(s_peer_bdname, (uint8_t *)(p->val), nameLen);
s_peer_bdname[nameLen] = '\0';
ESP_LOGV(TAG,"-- Name: %s", s_peer_bdname);
break;
default:
break;
}
}
if (!esp_bt_gap_is_valid_cod(cod)){
/* search for device with MAJOR service class as "rendering" in COD */
ESP_LOGV(TAG,"--Invalid class of device. Skipping.\n");
return;
}
else if (!(esp_bt_gap_get_cod_srvc(cod) & ESP_BT_COD_SRVC_RENDERING))
{
ESP_LOGV(TAG,"--Not a rendering device. Skipping.\n");
return;
}
/* search for device named "ESP_SPEAKER" in its extended inqury response */
if (eir) {
ESP_LOGV(TAG,"--Getting details from eir.\n");
get_name_from_eir(eir, s_peer_bdname, NULL);
ESP_LOGV(TAG,"--Device name is %s\n",s_peer_bdname);
}
if(strlen((char *)s_peer_bdname)>0) {
peers_list_maintain((const char *)s_peer_bdname, rssi);
}
if (squeezelite_conf.sink_name && strlen(squeezelite_conf.sink_name) >0 && strcmp((char *)s_peer_bdname, squeezelite_conf.sink_name) == 0) {
ESP_LOGI(TAG,"Found our target device. address %s, name %s", bda_str, s_peer_bdname);
ESP_LOGV(TAG,"=======================\n");
if(esp_bt_gap_cancel_discovery()!=ESP_ERR_INVALID_STATE)
{
ESP_LOGD(TAG,"Cancel device discovery ...");
memcpy(s_peer_bda, param->disc_res.bda, ESP_BD_ADDR_LEN);
set_app_source_state(APP_AV_STATE_DISCOVERED);
}
else
{
ESP_LOGE(TAG,"Cancel device discovery failed...");
}
}
else
{
ESP_LOGV(TAG,"Not the device we are looking for (%s). Continuing scan", squeezelite_conf.sink_name?squeezelite_conf.sink_name:"N/A");
}
}
static void bt_av_hdl_stack_evt(uint16_t event, void *p_param)
{
switch (event) {
case BT_APP_EVT_STACK_UP: {
ESP_LOGI(TAG,"BT Stack going up.");
/* set up device name */
char * a2dp_dev_name = config_alloc_get_default(NVS_TYPE_STR, "a2dp_dev_name", CONFIG_A2DP_DEV_NAME, 0);
if(a2dp_dev_name == NULL){
ESP_LOGW(TAG,"Unable to retrieve the a2dp device name from nvs");
esp_bt_dev_set_device_name(CONFIG_A2DP_DEV_NAME);
}
else {
esp_bt_dev_set_device_name(a2dp_dev_name);
free(a2dp_dev_name);
}
ESP_LOGI(TAG,"Preparing to connect");
/* register GAP callback function */
esp_bt_gap_register_callback(bt_app_gap_cb);
/* initialize AVRCP controller */
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);
assert(esp_avrc_tg_set_rn_evt_cap(&evt_set) == ESP_OK);
/* initialize A2DP source */
esp_a2d_register_callback(&bt_app_a2d_cb);
esp_a2d_source_register_data_callback(&output_bt_data);
esp_a2d_source_init();
/* set discoverable and connectable mode */
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
/* start device discovery */
ESP_LOGI(TAG,"Starting device discovery...");
set_app_source_state(APP_AV_STATE_DISCOVERING);
esp_bt_gap_start_discovery(ESP_BT_INQ_MODE_GENERAL_INQUIRY, 10, 0);
/* create and start heart beat timer */
int tmr_id = 0;
s_tmr = xTimerCreate("connTmr", ( prev_duration/ portTICK_RATE_MS),pdFALSE, (void *)tmr_id, a2d_app_heart_beat);
xTimerStart(s_tmr, portMAX_DELAY);
break;
}
default:
ESP_LOGE(TAG,"%s unhandled evt %d", __func__, event);
break;
}
}
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_METADATA_RSP_EVT:
case ESP_AVRC_CT_CONNECTION_STATE_EVT:
case ESP_AVRC_CT_PASSTHROUGH_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: {
ESP_LOGD(TAG,"Received %s message", ESP_AVRC_CT_DESC[event]);
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_app_av_media_proc(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
switch (bt_app_source_media_state) {
case APP_AV_MEDIA_STATE_IDLE: {
if (event == BT_APP_HEART_BEAT_EVT) {
if(!output_stopped())
{
ESP_LOGI(TAG,"Output state is %s, Checking if A2DP is ready.", output_state_str());
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(TAG,"a2dp media ready, starting playback!");
set_a2dp_media_state(APP_AV_MEDIA_STATE_STARTING);
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_START);
}
}
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(TAG,"a2dp media started successfully.");
set_a2dp_media_state(APP_AV_MEDIA_STATE_STARTED);
} else {
// not started succesfully, transfer to idle state
ESP_LOGI(TAG,"a2dp media start failed.");
set_a2dp_media_state(APP_AV_MEDIA_STATE_IDLE);
}
}
break;
}
case APP_AV_MEDIA_STATE_STARTED: {
if (event == BT_APP_HEART_BEAT_EVT) {
if(output_stopped()) {
ESP_LOGI(TAG,"Output state is %s. Stopping a2dp media ...", output_state_str());
set_a2dp_media_state(APP_AV_MEDIA_STATE_STOPPING);
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_STOP);
} else {
output_bt_tick();
}
}
break;
}
case APP_AV_MEDIA_STATE_STOPPING: {
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(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(TAG,"a2dp media stopped successfully...");
set_a2dp_media_state(APP_AV_MEDIA_STATE_IDLE);
} else {
ESP_LOGI(TAG,"a2dp media stopping...");
esp_a2d_media_ctrl(ESP_A2D_MEDIA_CTRL_STOP);
}
}
break;
}
case APP_AV_MEDIA_STATE_WAIT_DISCONNECT:{
esp_a2d_source_disconnect(s_peer_bda);
set_app_source_state(APP_AV_STATE_DISCONNECTING);
ESP_LOGI(TAG,"a2dp disconnecting...");
}
}
}
static void bt_app_av_state_unconnected(uint16_t event, void *param)
{
ESP_LOGV(TAG, "Handling state unconnected A2DP event");
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT:
handle_connect_state_unconnected(event, (esp_a2d_cb_param_t *)param);
break;
case ESP_A2D_AUDIO_STATE_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_STATE_EVT));
break;
case ESP_A2D_AUDIO_CFG_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_CFG_EVT));
break;
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_MEDIA_CTRL_ACK_EVT));
break;
case BT_APP_HEART_BEAT_EVT: {
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(BT_APP_HEART_BEAT_EVT));
switch (esp_bluedroid_get_status()) {
case ESP_BLUEDROID_STATUS_UNINITIALIZED:
ESP_LOGV(TAG,"BlueDroid Status is ESP_BLUEDROID_STATUS_UNINITIALIZED.");
break;
case ESP_BLUEDROID_STATUS_INITIALIZED:
ESP_LOGV(TAG,"BlueDroid Status is ESP_BLUEDROID_STATUS_INITIALIZED.");
break;
case ESP_BLUEDROID_STATUS_ENABLED:
ESP_LOGV(TAG,"BlueDroid Status is ESP_BLUEDROID_STATUS_ENABLED.");
break;
default:
break;
}
uint8_t *p = s_peer_bda;
ESP_LOGI(TAG, "a2dp connecting to %s, BT peer: %02x:%02x:%02x:%02x:%02x:%02x",s_peer_bdname,p[0], p[1], p[2], p[3], p[4], p[5]);
if(esp_a2d_source_connect(s_peer_bda)==ESP_OK) {
set_app_source_state(APP_AV_STATE_CONNECTING);
s_connecting_intv = 0;
}
else {
set_app_source_state(APP_AV_STATE_UNCONNECTED);
// there was an issue connecting... continue to discover
ESP_LOGE(TAG,"Attempt at connecting failed, restart at discover...");
esp_bt_gap_start_discovery(ESP_BT_INQ_MODE_GENERAL_INQUIRY, 10, 0);
}
break;
}
default:
ESP_LOGE(TAG,"%s unhandled evt %d", __func__, event);
break;
}
}
static void bt_app_av_state_connecting(uint16_t event, void *param)
{
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT:
handle_connect_state_connecting(event, (esp_a2d_cb_param_t *)param);
break;
case ESP_A2D_AUDIO_STATE_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_STATE_EVT));
break;
case ESP_A2D_AUDIO_CFG_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_CFG_EVT));
break;
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_MEDIA_CTRL_ACK_EVT));
break;
case BT_APP_HEART_BEAT_EVT:
if (++s_connecting_intv >= 2) {
set_app_source_state(APP_AV_STATE_UNCONNECTED);
ESP_LOGW(TAG,"A2DP Connect time out! Setting state to Unconnected. ");
s_connecting_intv = 0;
}
break;
default:
ESP_LOGE(TAG,"%s unhandled evt %d", __func__, event);
break;
}
}
static void bt_app_av_state_connected(uint16_t event, void *param)
{
esp_a2d_cb_param_t *a2d = NULL;
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT: {
handle_connect_state_connected(event, (esp_a2d_cb_param_t *)param);
break;
}
case ESP_A2D_AUDIO_STATE_EVT: {
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(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
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_CFG_EVT));
break;
case ESP_A2D_MEDIA_CTRL_ACK_EVT:{
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_MEDIA_CTRL_ACK_EVT));
bt_app_av_media_proc(event, param);
break;
}
case BT_APP_HEART_BEAT_EVT: {
ESP_LOGV(TAG,QUOTE(BT_APP_HEART_BEAT_EVT));
bt_app_av_media_proc(event, param);
break;
}
default:
ESP_LOGE(TAG,"%s unhandled evt %d", __func__, event);
break;
}
}
static void bt_app_av_state_disconnecting(uint16_t event, void *param)
{
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT:
handle_connect_state_disconnecting( event, (esp_a2d_cb_param_t *)param);
break;
case ESP_A2D_AUDIO_STATE_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_STATE_EVT));
break;
case ESP_A2D_AUDIO_CFG_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_AUDIO_CFG_EVT));
break;
case ESP_A2D_MEDIA_CTRL_ACK_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(ESP_A2D_MEDIA_CTRL_ACK_EVT));
break;
case BT_APP_HEART_BEAT_EVT:
ESP_LOG_DEBUG_EVENT(TAG,QUOTE(BT_APP_HEART_BEAT_EVT));
break;
default:
ESP_LOGE(TAG,"%s unhandled evt %d", __func__, 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);
}
}
static void bt_av_notify_evt_handler(uint8_t event_id, esp_avrc_rn_param_t *event_parameter)
{
switch (event_id) {
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;
}
}
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) {
case ESP_AVRC_CT_CONNECTION_STATE_EVT: {
uint8_t *bda = rc->conn_stat.remote_bda;
ESP_LOGI(BT_RC_CT_TAG, "AVRC conn_state evt: 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) {
// get remote supported event_ids of peer AVRCP Target
esp_avrc_ct_send_get_rn_capabilities_cmd(APP_RC_CT_TL_GET_CAPS);
} else {
// clear peer notification capability record
s_avrc_peer_rn_cap.bits = 0;
}
break;
}
case ESP_AVRC_CT_PASSTHROUGH_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC passthrough rsp: key_code 0x%x, key_state %d", rc->psth_rsp.key_code, rc->psth_rsp.key_state);
break;
}
case ESP_AVRC_CT_METADATA_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "AVRC metadata rsp: attribute id 0x%x, %s", rc->meta_rsp.attr_id, rc->meta_rsp.attr_text);
free(rc->meta_rsp.attr_text);
break;
}
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;
}
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;
}
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;
}
case ESP_AVRC_CT_SET_ABSOLUTE_VOLUME_RSP_EVT: {
ESP_LOGI(BT_RC_CT_TAG, "Set absolute volume rsp: volume %d", rc->set_volume_rsp.volume);
break;
}
default:
ESP_LOGE(BT_RC_CT_TAG, "%s unhandled evt %d", __func__, event);
break;
}
}