OVMS3-idf/examples/bluetooth/a2dp_sink/main/bt_app_av.c
wangmengyang 61bd453c15 component/bt: implement AVRCP Target APIs
1. Add more notification events to the enum according to the event list in AVRCP specification.
2. Add API and callback events for basic AVRCP target functionalities to do init, deinit, callback-registration, connection status indication.
3. Implement API to set/get supported PASSTHROUGH command on local AVRCP TG, implement callback events for remote passthrough command indication.
4. Implement API to set/get supported notification eventIDs on local AVRCP TG, implement API to send event notifications to remote CT. \
   Currently supported event in TG only includes ESP_AVRC_RN_VOLUME_CHANGE(0xd), which can be extended in later commits.
5. Implement callback events for SetAbsoluteVolume command indication on TG.
6. Add limitation of event_ids supported in RegisterNotification command in CT. The supported event_ids include: \
   ESP_AVRC_RN_PLAY_STATUS_CHANGE(0x1), ESP_AVRC_RN_TRACK_CHANGE(0x2), ESP_AVRC_RN_PLAY_POS_CHANGE(0x5), ESP_AVRC_RN_VOLUME_CHANGE(0xd).
7. Add feature bit mask in parameter of callback event ESP_AVRC_CT_REMOTE_FEATURES_EVT for peer feature information got from SDP.
8. Add API and callback event to AVRCP CT to retrieve remote TG's supported notification event capabilities.
9. Modify data type for parameter of callback event ESP_AVRC_CT_CHANGE_NOTIFY_EVT.
10. Change AVRCP version from 1.3 to 1.4 for compatibility cause in using AbsoluteVolume feature.
11. Modify local AVRCP device to be category 1 as CT and category 2 as TG that applies to bluetooth headphones or speakers.
12. Update the use of AVRCP APIs and events in the two examples: a2dp_sink and a2dp_gatts_coex, which include the demo of volume control and notification.
2019-04-10 16:34:13 +08:00

361 lines
13 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 <stdint.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include "esp_log.h"
#include "bt_app_core.h"
#include "bt_app_av.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"
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "driver/i2s.h"
#include "sys/lock.h"
// AVRCP used transaction label
#define APP_RC_CT_TL_GET_CAPS (0)
#define APP_RC_CT_TL_GET_META_DATA (1)
#define APP_RC_CT_TL_RN_TRACK_CHANGE (2)
#define APP_RC_CT_TL_RN_PLAYBACK_CHANGE (3)
#define APP_RC_CT_TL_RN_PLAY_POS_CHANGE (4)
/* a2dp event handler */
static void bt_av_hdl_a2d_evt(uint16_t event, void *p_param);
/* avrc CT event handler */
static void bt_av_hdl_avrc_ct_evt(uint16_t event, void *p_param);
/* avrc TG event handler */
static void bt_av_hdl_avrc_tg_evt(uint16_t event, void *p_param);
static uint32_t s_pkt_cnt = 0;
static esp_a2d_audio_state_t s_audio_state = ESP_A2D_AUDIO_STATE_STOPPED;
static const char *s_a2d_conn_state_str[] = {"Disconnected", "Connecting", "Connected", "Disconnecting"};
static const char *s_a2d_audio_state_str[] = {"Suspended", "Stopped", "Started"};
static esp_avrc_rn_evt_cap_mask_t s_avrc_peer_rn_cap;
static _lock_t s_volume_lock;
static xTaskHandle s_vcs_task_hdl = NULL;
static uint8_t s_volume = 0;
static bool s_volume_notify;
/* callback for A2DP sink */
void bt_app_a2d_cb(esp_a2d_cb_event_t event, esp_a2d_cb_param_t *param)
{
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT:
case ESP_A2D_AUDIO_STATE_EVT:
case ESP_A2D_AUDIO_CFG_EVT: {
bt_app_work_dispatch(bt_av_hdl_a2d_evt, event, param, sizeof(esp_a2d_cb_param_t), NULL);
break;
}
default:
ESP_LOGE(BT_AV_TAG, "Invalid A2DP event: %d", event);
break;
}
}
void bt_app_a2d_data_cb(const uint8_t *data, uint32_t len)
{
size_t bytes_written;
i2s_write(0, data, len, &bytes_written, portMAX_DELAY);
if (++s_pkt_cnt % 100 == 0) {
ESP_LOGI(BT_AV_TAG, "Audio packet count %u", s_pkt_cnt);
}
}
void bt_app_alloc_meta_buffer(esp_avrc_ct_cb_param_t *param)
{
esp_avrc_ct_cb_param_t *rc = (esp_avrc_ct_cb_param_t *)(param);
uint8_t *attr_text = (uint8_t *) malloc (rc->meta_rsp.attr_length + 1);
memcpy(attr_text, rc->meta_rsp.attr_text, rc->meta_rsp.attr_length);
attr_text[rc->meta_rsp.attr_length] = 0;
rc->meta_rsp.attr_text = attr_text;
}
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:
bt_app_alloc_meta_buffer(param);
/* fall through */
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: {
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;
}
}
void bt_app_rc_tg_cb(esp_avrc_tg_cb_event_t event, esp_avrc_tg_cb_param_t *param)
{
switch (event) {
case ESP_AVRC_TG_CONNECTION_STATE_EVT:
case ESP_AVRC_TG_REMOTE_FEATURES_EVT:
case ESP_AVRC_TG_PASSTHROUGH_CMD_EVT:
case ESP_AVRC_TG_SET_ABSOLUTE_VOLUME_CMD_EVT:
case ESP_AVRC_TG_REGISTER_NOTIFICATION_EVT:
bt_app_work_dispatch(bt_av_hdl_avrc_tg_evt, event, param, sizeof(esp_avrc_tg_cb_param_t), NULL);
break;
default:
ESP_LOGE(BT_RC_TG_TAG, "Invalid AVRC event: %d", event);
break;
}
}
static void bt_av_hdl_a2d_evt(uint16_t event, void *p_param)
{
ESP_LOGD(BT_AV_TAG, "%s evt %d", __func__, event);
esp_a2d_cb_param_t *a2d = NULL;
switch (event) {
case ESP_A2D_CONNECTION_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(p_param);
uint8_t *bda = a2d->conn_stat.remote_bda;
ESP_LOGI(BT_AV_TAG, "A2DP connection state: %s, [%02x:%02x:%02x:%02x:%02x:%02x]",
s_a2d_conn_state_str[a2d->conn_stat.state], bda[0], bda[1], bda[2], bda[3], bda[4], bda[5]);
if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_DISCONNECTED) {
esp_bt_gap_set_scan_mode(ESP_BT_CONNECTABLE, ESP_BT_GENERAL_DISCOVERABLE);
} else if (a2d->conn_stat.state == ESP_A2D_CONNECTION_STATE_CONNECTED){
esp_bt_gap_set_scan_mode(ESP_BT_NON_CONNECTABLE, ESP_BT_NON_DISCOVERABLE);
}
break;
}
case ESP_A2D_AUDIO_STATE_EVT: {
a2d = (esp_a2d_cb_param_t *)(p_param);
ESP_LOGI(BT_AV_TAG, "A2DP audio state: %s", s_a2d_audio_state_str[a2d->audio_stat.state]);
s_audio_state = a2d->audio_stat.state;
if (ESP_A2D_AUDIO_STATE_STARTED == a2d->audio_stat.state) {
s_pkt_cnt = 0;
}
break;
}
case ESP_A2D_AUDIO_CFG_EVT: {
a2d = (esp_a2d_cb_param_t *)(p_param);
ESP_LOGI(BT_AV_TAG, "A2DP audio stream configuration, codec type %d", a2d->audio_cfg.mcc.type);
// for now only SBC stream is supported
if (a2d->audio_cfg.mcc.type == ESP_A2D_MCT_SBC) {
int sample_rate = 16000;
char oct0 = a2d->audio_cfg.mcc.cie.sbc[0];
if (oct0 & (0x01 << 6)) {
sample_rate = 32000;
} else if (oct0 & (0x01 << 5)) {
sample_rate = 44100;
} else if (oct0 & (0x01 << 4)) {
sample_rate = 48000;
}
i2s_set_clk(0, sample_rate, 16, 2);
ESP_LOGI(BT_AV_TAG, "Configure audio player %x-%x-%x-%x",
a2d->audio_cfg.mcc.cie.sbc[0],
a2d->audio_cfg.mcc.cie.sbc[1],
a2d->audio_cfg.mcc.cie.sbc[2],
a2d->audio_cfg.mcc.cie.sbc[3]);
ESP_LOGI(BT_AV_TAG, "Audio player configured, sample rate=%d", sample_rate);
}
break;
}
default:
ESP_LOGE(BT_AV_TAG, "%s unhandled evt %d", __func__, event);
break;
}
}
static void bt_av_new_track(void)
{
// request metadata
uint8_t attr_mask = ESP_AVRC_MD_ATTR_TITLE | ESP_AVRC_MD_ATTR_ARTIST | ESP_AVRC_MD_ATTR_ALBUM | ESP_AVRC_MD_ATTR_GENRE;
esp_avrc_ct_send_metadata_cmd(APP_RC_CT_TL_GET_META_DATA, attr_mask);
// register notification if peer support the event_id
if (esp_avrc_rn_evt_bit_mask_operation(ESP_AVRC_BIT_MASK_OP_TEST, &s_avrc_peer_rn_cap,
ESP_AVRC_RN_TRACK_CHANGE)) {
esp_avrc_ct_send_register_notification_cmd(APP_RC_CT_TL_RN_TRACK_CHANGE, ESP_AVRC_RN_TRACK_CHANGE, 0);
}
}
static void bt_av_playback_changed(void)
{
if (esp_avrc_rn_evt_bit_mask_operation(ESP_AVRC_BIT_MASK_OP_TEST, &s_avrc_peer_rn_cap,
ESP_AVRC_RN_PLAY_STATUS_CHANGE)) {
esp_avrc_ct_send_register_notification_cmd(APP_RC_CT_TL_RN_PLAYBACK_CHANGE, ESP_AVRC_RN_PLAY_STATUS_CHANGE, 0);
}
}
static void bt_av_play_pos_changed(void)
{
if (esp_avrc_rn_evt_bit_mask_operation(ESP_AVRC_BIT_MASK_OP_TEST, &s_avrc_peer_rn_cap,
ESP_AVRC_RN_PLAY_POS_CHANGED)) {
esp_avrc_ct_send_register_notification_cmd(APP_RC_CT_TL_RN_PLAY_POS_CHANGE, ESP_AVRC_RN_PLAY_POS_CHANGED, 10);
}
}
void bt_av_notify_evt_handler(uint8_t event_id, esp_avrc_rn_param_t *event_parameter)
{
switch (event_id) {
case ESP_AVRC_RN_TRACK_CHANGE:
bt_av_new_track();
break;
case ESP_AVRC_RN_PLAY_STATUS_CHANGE:
ESP_LOGI(BT_AV_TAG, "Playback status changed: 0x%x", event_parameter->playback);
bt_av_playback_changed();
break;
case ESP_AVRC_RN_PLAY_POS_CHANGED:
ESP_LOGI(BT_AV_TAG, "Play position changed: %d-ms", event_parameter->play_pos);
bt_av_play_pos_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_new_track();
bt_av_playback_changed();
bt_av_play_pos_changed();
break;
}
default:
ESP_LOGE(BT_RC_CT_TAG, "%s unhandled evt %d", __func__, event);
break;
}
}
static void volume_set_by_controller(uint8_t volume)
{
ESP_LOGI(BT_RC_TG_TAG, "Volume is set by remote controller %d%%\n", (uint32_t)volume * 100 / 0x7f);
_lock_acquire(&s_volume_lock);
s_volume = volume;
_lock_release(&s_volume_lock);
}
static void volume_set_by_local_host(uint8_t volume)
{
ESP_LOGI(BT_RC_TG_TAG, "Volume is set locally to: %d%%", (uint32_t)volume * 100 / 0x7f);
_lock_acquire(&s_volume_lock);
s_volume = volume;
_lock_release(&s_volume_lock);
if (s_volume_notify) {
esp_avrc_rn_param_t rn_param;
rn_param.volume = s_volume;
esp_avrc_tg_send_rn_rsp(ESP_AVRC_RN_VOLUME_CHANGE, ESP_AVRC_RN_RSP_CHANGED, &rn_param);
s_volume_notify = false;
}
}
static void volume_change_simulation(void *arg)
{
ESP_LOGI(BT_RC_TG_TAG, "start volume change simulation");
for (;;) {
vTaskDelay(10000 / portTICK_RATE_MS);
uint8_t volume = (s_volume + 5) & 0x7f;
volume_set_by_local_host(volume);
}
}
static void bt_av_hdl_avrc_tg_evt(uint16_t event, void *p_param)
{
ESP_LOGD(BT_RC_TG_TAG, "%s evt %d", __func__, event);
esp_avrc_tg_cb_param_t *rc = (esp_avrc_tg_cb_param_t *)(p_param);
switch (event) {
case ESP_AVRC_TG_CONNECTION_STATE_EVT: {
uint8_t *bda = rc->conn_stat.remote_bda;
ESP_LOGI(BT_RC_TG_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) {
// create task to simulate volume change
xTaskCreate(volume_change_simulation, "vcsT", 2048, NULL, 5, &s_vcs_task_hdl);
} else {
vTaskDelete(s_vcs_task_hdl);
ESP_LOGI(BT_RC_TG_TAG, "Stop volume change simulation");
}
break;
}
case ESP_AVRC_TG_PASSTHROUGH_CMD_EVT: {
ESP_LOGI(BT_RC_TG_TAG, "AVRC passthrough cmd: key_code 0x%x, key_state %d", rc->psth_cmd.key_code, rc->psth_cmd.key_state);
break;
}
case ESP_AVRC_TG_SET_ABSOLUTE_VOLUME_CMD_EVT: {
ESP_LOGI(BT_RC_TG_TAG, "AVRC set absolute volume: %d%%", (int)rc->set_abs_vol.volume * 100/ 0x7f);
volume_set_by_controller(rc->set_abs_vol.volume);
break;
}
case ESP_AVRC_TG_REGISTER_NOTIFICATION_EVT: {
ESP_LOGI(BT_RC_TG_TAG, "AVRC register event notification: %d, param: 0x%x", rc->reg_ntf.event_id, rc->reg_ntf.event_parameter);
if (rc->reg_ntf.event_id == ESP_AVRC_RN_VOLUME_CHANGE) {
s_volume_notify = true;
esp_avrc_rn_param_t rn_param;
rn_param.volume = s_volume;
esp_avrc_tg_send_rn_rsp(ESP_AVRC_RN_VOLUME_CHANGE, ESP_AVRC_RN_RSP_INTERIM, &rn_param);
}
break;
}
case ESP_AVRC_TG_REMOTE_FEATURES_EVT: {
ESP_LOGI(BT_RC_TG_TAG, "AVRC remote features %x, CT features %x", rc->rmt_feats.feat_mask, rc->rmt_feats.ct_feat_flag);
break;
}
default:
ESP_LOGE(BT_RC_TG_TAG, "%s unhandled evt %d", __func__, event);
break;
}
}