/* * Copyright 2023 NXP * Copyright (c) 2024 Nordic Semiconductor ASA * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bap_stream_rx.h" #include "bstests.h" #include "common.h" #if defined(CONFIG_BT_PBP) #define SEM_TIMEOUT K_SECONDS(30) extern enum bst_result_t bst_result; static bool pbs_found; static K_SEM_DEFINE(sem_pa_synced, 0U, 1U); static K_SEM_DEFINE(sem_base_received, 0U, 1U); static K_SEM_DEFINE(sem_syncable, 0U, 1U); static K_SEM_DEFINE(sem_pa_sync_lost, 0U, 1U); static struct bt_bap_broadcast_sink *broadcast_sink; static struct bt_le_per_adv_sync *bcast_pa_sync; static struct audio_test_stream test_streams[CONFIG_BT_BAP_BROADCAST_SNK_STREAM_COUNT]; static struct bt_bap_stream *streams_p[ARRAY_SIZE(test_streams)]; static const struct bt_audio_codec_cap codec = BT_AUDIO_CODEC_CAP_LC3( BT_AUDIO_CODEC_CAP_FREQ_16KHZ | BT_AUDIO_CODEC_CAP_FREQ_24KHZ | BT_AUDIO_CODEC_CAP_FREQ_48KHZ, BT_AUDIO_CODEC_CAP_DURATION_10, BT_AUDIO_CODEC_CAP_CHAN_COUNT_SUPPORT(1), 40u, 155u, 1u, BT_AUDIO_CONTEXT_TYPE_MEDIA); /* Create a mask for the maximum BIS we can sync to using the number of streams * we have. We add an additional 1 since the bis indexes start from 1 and not * 0. */ static const uint32_t bis_index_mask = BIT_MASK(ARRAY_SIZE(test_streams) + 1U); static uint32_t bis_index_bitfield; static uint32_t broadcast_id; static struct bt_pacs_cap cap = { .codec_cap = &codec, }; static void broadcast_scan_recv(const struct bt_le_scan_recv_info *info, struct net_buf_simple *ad); static struct bt_le_scan_cb broadcast_scan_cb = { .recv = broadcast_scan_recv }; static void base_recv_cb(struct bt_bap_broadcast_sink *sink, const struct bt_bap_base *base, size_t base_size) { k_sem_give(&sem_base_received); } static void syncable_cb(struct bt_bap_broadcast_sink *sink, const struct bt_iso_biginfo *biginfo) { printk("Broadcast sink %p is now syncable\n", sink); k_sem_give(&sem_syncable); } static struct bt_bap_broadcast_sink_cb broadcast_sink_cbs = { .base_recv = base_recv_cb, .syncable = syncable_cb, }; static void started_cb(struct bt_bap_stream *stream) { struct audio_test_stream *test_stream = audio_test_stream_from_bap_stream(stream); memset(&test_stream->last_info, 0, sizeof(test_stream->last_info)); test_stream->rx_cnt = 0U; printk("Stream %p started\n", stream); } static void stopped_cb(struct bt_bap_stream *stream, uint8_t reason) { printk("Stream %p stopped with reason 0x%02X\n", stream, reason); } static bool pa_decode_base(struct bt_data *data, void *user_data) { const struct bt_bap_base *base = bt_bap_base_get_base_from_ad(data); uint32_t base_bis_index_bitfield = 0U; int err; /* Base is NULL if the data does not contain a valid BASE */ if (base == NULL) { return true; } err = bt_bap_base_get_bis_indexes(base, &base_bis_index_bitfield); if (err != 0) { return false; } bis_index_bitfield = base_bis_index_bitfield & bis_index_mask; k_sem_give(&sem_base_received); return false; } static void broadcast_pa_recv(struct bt_le_per_adv_sync *sync, const struct bt_le_per_adv_sync_recv_info *info, struct net_buf_simple *buf) { bt_data_parse(buf, pa_decode_base, NULL); } static void broadcast_pa_synced(struct bt_le_per_adv_sync *sync, struct bt_le_per_adv_sync_synced_info *info) { printk("PA synced\n"); k_sem_give(&sem_pa_synced); } static void broadcast_pa_terminated(struct bt_le_per_adv_sync *sync, const struct bt_le_per_adv_sync_term_info *info) { if (sync == bcast_pa_sync) { printk("PA sync %p lost with reason %u\n", sync, info->reason); bcast_pa_sync = NULL; k_sem_give(&sem_pa_sync_lost); } } static struct bt_bap_stream_ops stream_ops = { .started = started_cb, .stopped = stopped_cb, .recv = bap_stream_rx_recv_cb, }; static struct bt_le_per_adv_sync_cb broadcast_sync_cb = { .synced = broadcast_pa_synced, .recv = broadcast_pa_recv, .term = broadcast_pa_terminated, }; static int reset(void) { int err; k_sem_reset(&sem_pa_synced); k_sem_reset(&sem_base_received); k_sem_reset(&sem_syncable); k_sem_reset(&sem_pa_sync_lost); UNSET_FLAG(flag_audio_received); broadcast_id = BT_BAP_INVALID_BROADCAST_ID; bis_index_bitfield = 0U; pbs_found = false; if (broadcast_sink != NULL) { err = bt_bap_broadcast_sink_delete(broadcast_sink); if (err) { printk("Deleting broadcast sink failed (err %d)\n", err); return err; } broadcast_sink = NULL; } return 0; } static int init(void) { int err; err = bt_enable(NULL); if (err) { FAIL("Bluetooth enable failed (err %d)\n", err); return err; } printk("Bluetooth initialized\n"); bt_bap_broadcast_sink_register_cb(&broadcast_sink_cbs); bt_le_per_adv_sync_cb_register(&broadcast_sync_cb); err = bt_pacs_cap_register(BT_AUDIO_DIR_SINK, &cap); if (err) { printk("Capability register failed (err %d)\n", err); return err; } for (size_t i = 0U; i < ARRAY_SIZE(test_streams); i++) { streams_p[i] = bap_stream_from_audio_test_stream(&test_streams[i]); bt_bap_stream_cb_register(streams_p[i], &stream_ops); } return 0; } static void sync_broadcast_pa(const struct bt_le_scan_recv_info *info) { struct bt_le_per_adv_sync_param param; int err; /* Unregister the callbacks to prevent broadcast_scan_recv to be called again */ bt_le_scan_cb_unregister(&broadcast_scan_cb); err = bt_le_scan_stop(); if (err != 0) { printk("Could not stop scan: %d\n", err); } bt_addr_le_copy(¶m.addr, info->addr); param.options = 0; param.sid = info->sid; param.skip = PA_SYNC_SKIP; param.timeout = interval_to_sync_timeout(info->interval); err = bt_le_per_adv_sync_create(¶m, &bcast_pa_sync); if (err != 0) { printk("Could not sync to PA: %d\n", err); } } static bool scan_check_and_sync_broadcast(struct bt_data *data, void *user_data) { enum bt_pbp_announcement_feature source_features; struct bt_uuid_16 adv_uuid; uint8_t *tmp_meta; int ret; if (data->type != BT_DATA_SVC_DATA16) { return true; } if (!bt_uuid_create(&adv_uuid.uuid, data->data, BT_UUID_SIZE_16)) { return true; } if (!bt_uuid_cmp(&adv_uuid.uuid, BT_UUID_BROADCAST_AUDIO)) { /* Save broadcast_id */ if (broadcast_id == BT_BAP_INVALID_BROADCAST_ID) { broadcast_id = sys_get_le24(data->data + BT_UUID_SIZE_16); } /* Found Broadcast Audio and Public Broadcast Announcement Services */ if (pbs_found) { return false; } } ret = bt_pbp_parse_announcement(data, &source_features, &tmp_meta); if (ret >= 0) { printk("Found Suitable Public Broadcast Announcement with %d octets of metadata\n", ret); pbs_found = true; /* Continue parsing if Broadcast Audio Announcement Service was not found */ if (broadcast_id == BT_BAP_INVALID_BROADCAST_ID) { return true; } return false; } /* Continue parsing */ return true; } static void broadcast_scan_recv(const struct bt_le_scan_recv_info *info, struct net_buf_simple *ad) { pbs_found = false; /* We are only interested in non-connectable periodic advertisers */ if ((info->adv_props & BT_GAP_ADV_PROP_CONNECTABLE) || info->interval == 0) { return; } bt_data_parse(ad, scan_check_and_sync_broadcast, (void *)&broadcast_id); if ((broadcast_id != BT_BAP_INVALID_BROADCAST_ID) && pbs_found) { sync_broadcast_pa(info); } } static void test_main(void) { int count = 0; int err; init(); while (count < PBP_STREAMS_TO_SEND) { printk("Resetting for iteration %d\n", count); err = reset(); if (err != 0) { printk("Resetting failed: %d\n", err); break; } /* Register callbacks */ bt_le_scan_cb_register(&broadcast_scan_cb); /* Start scanning */ printk("Starting scan\n"); err = bt_le_scan_start(BT_LE_SCAN_PASSIVE, NULL); if (err) { printk("Scan start failed (err %d)\n", err); break; } /* Wait for PA sync */ printk("Waiting for PA Sync\n"); err = k_sem_take(&sem_pa_synced, SEM_TIMEOUT); if (err != 0) { printk("sem_pa_synced timed out\n"); break; } /* Wait for BASE decode */ printk("Waiting for BASE\n"); err = k_sem_take(&sem_base_received, SEM_TIMEOUT); if (err != 0) { printk("sem_base_received timed out\n"); break; } /* Create broadcast sink */ printk("Creating broadcast sink\n"); err = bt_bap_broadcast_sink_create(bcast_pa_sync, broadcast_id, &broadcast_sink); if (err != 0) { printk("Sink not created!\n"); break; } printk("Waiting for syncable\n"); err = k_sem_take(&sem_syncable, SEM_TIMEOUT); if (err != 0) { printk("sem_syncable timed out\n"); break; } /* Sync to broadcast source */ printk("Syncing broadcast sink\n"); err = bt_bap_broadcast_sink_sync(broadcast_sink, bis_index_bitfield, streams_p, NULL); if (err != 0) { printk("Unable to sync to broadcast source: %d\n", err); break; } /* Wait for data */ printk("Waiting for data\n"); WAIT_FOR_FLAG(flag_audio_received); printk("Sending signal to broadcaster to stop\n"); backchannel_sync_send_all(); /* let the broadcast source know it can stop */ /* Wait for the stream to end */ printk("Waiting for sync lost\n"); k_sem_take(&sem_pa_sync_lost, SEM_TIMEOUT); count++; } if (count == PBP_STREAMS_TO_SEND) { /* Pass if we synced only with the high quality broadcast */ PASS("Public Broadcast sink passed\n"); } else { FAIL("Public Broadcast sink failed (%d/%d)\n", count, PBP_STREAMS_TO_SEND); } } static const struct bst_test_instance test_public_broadcast_sink[] = { { .test_id = "public_broadcast_sink", .test_pre_init_f = test_init, .test_tick_f = test_tick, .test_main_f = test_main }, BSTEST_END_MARKER }; struct bst_test_list *test_public_broadcast_sink_install(struct bst_test_list *tests) { return bst_add_tests(tests, test_public_broadcast_sink); } #else /* !CONFIG_BT_PBP */ struct bst_test_list *test_public_broadcast_sink_install(struct bst_test_list *tests) { return tests; } #endif /* CONFIG_BT_PBP */