/* Bluetooth CSIP - Coordinated Set Identification Profile */ /* * Copyright (c) 2019 Bose Corporation * Copyright (c) 2020-2022 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 #include #include #include #include #include #include "../host/conn_internal.h" #include "../host/hci_core.h" #include "../host/keys.h" #include "common/bt_str.h" #include "audio_internal.h" #include "csip_internal.h" #include "csip_crypto.h" #define CSIP_SET_LOCK_TIMER_VALUE K_SECONDS(60) #define CSIS_CHAR_ATTR_COUNT 3 /* declaration + value + cccd */ #define CSIS_RANK_CHAR_ATTR_COUNT 2 /* declaration + value */ LOG_MODULE_REGISTER(bt_csip_set_member, CONFIG_BT_CSIP_SET_MEMBER_LOG_LEVEL); enum csip_flag { FLAG_ACTIVE, FLAG_NOTIFY_LOCK, FLAG_NOTIFY_SIRK, FLAG_NUM, }; struct csip_client { bt_addr_le_t addr; /* Pending notification flags */ ATOMIC_DEFINE(flags, FLAG_NUM); }; struct bt_csip_set_member_svc_inst { struct bt_csip_sirk sirk; uint8_t set_size; uint8_t set_lock; uint8_t rank; struct bt_csip_set_member_cb *cb; struct k_work_delayable set_lock_timer; bt_addr_le_t lock_client_addr; struct bt_gatt_service *service_p; struct csip_client clients[CONFIG_BT_MAX_PAIRED]; }; static struct bt_csip_set_member_svc_inst svc_insts[CONFIG_BT_CSIP_SET_MEMBER_MAX_INSTANCE_COUNT]; static bt_addr_le_t server_dummy_addr; /* 0'ed address */ static void deferred_nfy_work_handler(struct k_work *work); static K_WORK_DELAYABLE_DEFINE(deferred_nfy_work, deferred_nfy_work_handler); static bool is_last_client_to_write(const struct bt_csip_set_member_svc_inst *svc_inst, const struct bt_conn *conn) { if (conn != NULL) { return bt_addr_le_eq(bt_conn_get_dst(conn), &svc_inst->lock_client_addr); } else { return bt_addr_le_eq(&server_dummy_addr, &svc_inst->lock_client_addr); } } static void notify_work_reschedule(k_timeout_t delay) { int err; /* If it is already scheduled, don't reschedule */ if (k_work_delayable_remaining_get(&deferred_nfy_work) > 0) { return; } err = k_work_reschedule(&deferred_nfy_work, delay); if (err < 0) { LOG_ERR("Failed to reschedule notification work err %d", err); } } static void notify_clients(struct bt_csip_set_member_svc_inst *svc_inst, struct bt_conn *excluded_client, enum csip_flag flag) { bool submit_work = false; /* Mark all bonded devices (except the excluded one) as pending notifications */ for (size_t i = 0U; i < ARRAY_SIZE(svc_inst->clients); i++) { struct csip_client *client; client = &svc_inst->clients[i]; if (atomic_test_bit(client->flags, FLAG_ACTIVE)) { if (excluded_client != NULL && bt_addr_le_eq(bt_conn_get_dst(excluded_client), &client->addr)) { continue; } atomic_set_bit(client->flags, flag); submit_work = true; } } /* Reschedule work for notifying */ if (submit_work) { notify_work_reschedule(K_NO_WAIT); } } static int sirk_encrypt(struct bt_conn *conn, const struct bt_csip_sirk *sirk, struct bt_csip_sirk *enc_sirk) { int err; uint8_t *k; if (IS_ENABLED(CONFIG_BT_CSIP_SET_MEMBER_TEST_SAMPLE_DATA)) { /* test_k is from the sample data from A.2 in the CSIS spec */ static uint8_t test_k[] = {0x67, 0x6e, 0x1b, 0x9b, 0xd4, 0x48, 0x69, 0x6f, 0x06, 0x1e, 0xc6, 0x22, 0x3c, 0xe5, 0xce, 0xd9}; static bool swapped; if (!swapped && IS_ENABLED(CONFIG_LITTLE_ENDIAN)) { /* Swap test_k to little endian */ sys_mem_swap(test_k, 16); swapped = true; } LOG_DBG("Encrypting test SIRK"); k = test_k; } else { if (conn == NULL) { return -EINVAL; } k = conn->le.keys->ltk.val; } err = bt_csip_sef(k, sirk->value, enc_sirk->value); if (err != 0) { return err; } enc_sirk->type = BT_CSIP_SIRK_TYPE_ENCRYPTED; return 0; } static int generate_prand(uint8_t dest[BT_CSIP_CRYPTO_PRAND_SIZE]) { bool valid = false; do { int res; uint32_t prand; *dest = 0; res = bt_rand(dest, BT_CSIP_CRYPTO_PRAND_SIZE); if (res != 0) { return res; } /* Validate Prand: Must contain both a 1 and a 0 */ prand = sys_get_le24(dest); if (prand != 0 && prand != 0x3FFFFF) { valid = true; } } while (!valid); dest[BT_CSIP_CRYPTO_PRAND_SIZE - 1] &= 0x3F; dest[BT_CSIP_CRYPTO_PRAND_SIZE - 1] |= BIT(6); return 0; } int bt_csip_set_member_generate_rsi(const struct bt_csip_set_member_svc_inst *svc_inst, uint8_t rsi[BT_CSIP_RSI_SIZE]) { int res = 0; uint8_t prand[BT_CSIP_CRYPTO_PRAND_SIZE]; uint8_t hash[BT_CSIP_CRYPTO_HASH_SIZE]; if (IS_ENABLED(CONFIG_BT_CSIP_SET_MEMBER_TEST_SAMPLE_DATA)) { /* prand is from the sample data from A.2 in the CSIS spec */ sys_put_le24(0x69f563, prand); } else { res = generate_prand(prand); if (res != 0) { LOG_WRN("Could not generate new prand"); return res; } } res = bt_csip_sih(svc_inst->sirk.value, prand, hash); if (res != 0) { LOG_WRN("Could not generate new RSI"); return res; } (void)memcpy(rsi, hash, BT_CSIP_CRYPTO_HASH_SIZE); (void)memcpy(rsi + BT_CSIP_CRYPTO_HASH_SIZE, prand, BT_CSIP_CRYPTO_PRAND_SIZE); return res; } static ssize_t read_sirk(struct bt_conn *conn, const struct bt_gatt_attr *attr, void *buf, uint16_t len, uint16_t offset) { struct bt_csip_sirk enc_sirk; struct bt_csip_sirk *sirk; struct bt_csip_set_member_svc_inst *svc_inst = BT_AUDIO_CHRC_USER_DATA(attr); if (svc_inst->cb != NULL && svc_inst->cb->sirk_read_req != NULL) { ssize_t gatt_err = BT_GATT_ERR(BT_ATT_ERR_SUCCESS); uint8_t cb_rsp; /* Ask higher layer for what SIRK to return, if any */ cb_rsp = svc_inst->cb->sirk_read_req(conn, &svc_insts[0]); if (cb_rsp == BT_CSIP_READ_SIRK_REQ_RSP_ACCEPT) { sirk = &svc_inst->sirk; } else if (IS_ENABLED(CONFIG_BT_CSIP_SET_MEMBER_ENC_SIRK_SUPPORT) && cb_rsp == BT_CSIP_READ_SIRK_REQ_RSP_ACCEPT_ENC) { int err; err = sirk_encrypt(conn, &svc_inst->sirk, &enc_sirk); if (err != 0) { LOG_ERR("Could not encrypt SIRK: %d", err); gatt_err = BT_GATT_ERR(BT_ATT_ERR_UNLIKELY); } else { sirk = &enc_sirk; LOG_HEXDUMP_DBG(enc_sirk.value, sizeof(enc_sirk.value), "Encrypted SIRK"); } } else if (cb_rsp == BT_CSIP_READ_SIRK_REQ_RSP_REJECT) { gatt_err = BT_GATT_ERR(BT_ATT_ERR_AUTHORIZATION); } else if (cb_rsp == BT_CSIP_READ_SIRK_REQ_RSP_OOB_ONLY) { gatt_err = BT_GATT_ERR(BT_CSIP_ERROR_SIRK_OOB_ONLY); } else { LOG_ERR("Invalid callback response: %u", cb_rsp); gatt_err = BT_GATT_ERR(BT_ATT_ERR_UNLIKELY); } if (gatt_err != BT_GATT_ERR(BT_ATT_ERR_SUCCESS)) { return gatt_err; } } else { sirk = &svc_inst->sirk; } LOG_DBG("SIRK %sencrypted", sirk->type == BT_CSIP_SIRK_TYPE_PLAIN ? "not " : ""); LOG_HEXDUMP_DBG(svc_inst->sirk.value, sizeof(svc_inst->sirk.value), "SIRK"); return bt_gatt_attr_read(conn, attr, buf, len, offset, sirk, sizeof(*sirk)); } #if defined(CONFIG_BT_CSIP_SET_MEMBER_NOTIFIABLE) static void sirk_cfg_changed(const struct bt_gatt_attr *attr, uint16_t value) { LOG_DBG("value 0x%04x", value); } #endif /* CONFIG_BT_CSIP_SET_MEMBER_NOTIFIABLE */ static ssize_t read_set_size(struct bt_conn *conn, const struct bt_gatt_attr *attr, void *buf, uint16_t len, uint16_t offset) { struct bt_csip_set_member_svc_inst *svc_inst = BT_AUDIO_CHRC_USER_DATA(attr); LOG_DBG("%u", svc_inst->set_size); return bt_gatt_attr_read(conn, attr, buf, len, offset, &svc_inst->set_size, sizeof(svc_inst->set_size)); } static void set_size_cfg_changed(const struct bt_gatt_attr *attr, uint16_t value) { LOG_DBG("value 0x%04x", value); } static ssize_t read_set_lock(struct bt_conn *conn, const struct bt_gatt_attr *attr, void *buf, uint16_t len, uint16_t offset) { struct bt_csip_set_member_svc_inst *svc_inst = BT_AUDIO_CHRC_USER_DATA(attr); LOG_DBG("%u", svc_inst->set_lock); return bt_gatt_attr_read(conn, attr, buf, len, offset, &svc_inst->set_lock, sizeof(svc_inst->set_lock)); } /** * @brief Set the lock value of a CSIP instance. * * @param conn The connection locking the instance. * Will be NULL if the server locally sets the lock. * @param svc_inst The CSIP instance to change the lock value of * @param val The lock value (BT_CSIP_LOCK_VALUE or BT_CSIP_RELEASE_VALUE) * * @return BT_CSIP_ERROR_* on failure or 0 if success */ static uint8_t set_lock(struct bt_conn *conn, struct bt_csip_set_member_svc_inst *svc_inst, uint8_t val) { bool notify; if (val != BT_CSIP_RELEASE_VALUE && val != BT_CSIP_LOCK_VALUE) { return BT_CSIP_ERROR_LOCK_INVAL_VALUE; } if (svc_inst->set_lock == BT_CSIP_LOCK_VALUE) { if (val == BT_CSIP_LOCK_VALUE) { if (is_last_client_to_write(svc_inst, conn)) { return BT_CSIP_ERROR_LOCK_ALREADY_GRANTED; } else { return BT_CSIP_ERROR_LOCK_DENIED; } } else if (!is_last_client_to_write(svc_inst, conn)) { return BT_CSIP_ERROR_LOCK_RELEASE_DENIED; } } notify = svc_inst->set_lock != val; svc_inst->set_lock = val; if (svc_inst->set_lock == BT_CSIP_LOCK_VALUE) { if (conn != NULL) { bt_addr_le_copy(&svc_inst->lock_client_addr, bt_conn_get_dst(conn)); } (void)k_work_reschedule(&svc_inst->set_lock_timer, CSIP_SET_LOCK_TIMER_VALUE); } else { (void)memset(&svc_inst->lock_client_addr, 0, sizeof(svc_inst->lock_client_addr)); (void)k_work_cancel_delayable(&svc_inst->set_lock_timer); } LOG_DBG("%u", svc_inst->set_lock); if (notify) { /* * The Spec states that all clients, except for the * client writing the value, shall be notified * (if subscribed) */ notify_clients(svc_inst, conn, FLAG_NOTIFY_LOCK); if (svc_inst->cb != NULL && svc_inst->cb->lock_changed != NULL) { bool locked = svc_inst->set_lock == BT_CSIP_LOCK_VALUE; svc_inst->cb->lock_changed(conn, svc_inst, locked); } } return 0; } static ssize_t write_set_lock(struct bt_conn *conn, const struct bt_gatt_attr *attr, const void *buf, uint16_t len, uint16_t offset, uint8_t flags) { ssize_t res; uint8_t val; struct bt_csip_set_member_svc_inst *svc_inst = BT_AUDIO_CHRC_USER_DATA(attr); if (offset != 0) { return BT_GATT_ERR(BT_ATT_ERR_INVALID_OFFSET); } else if (len != sizeof(val)) { return BT_GATT_ERR(BT_ATT_ERR_INVALID_ATTRIBUTE_LEN); } (void)memcpy(&val, buf, len); res = set_lock(conn, svc_inst, val); if (res != BT_ATT_ERR_SUCCESS) { return BT_GATT_ERR(res); } return len; } static void set_lock_cfg_changed(const struct bt_gatt_attr *attr, uint16_t value) { LOG_DBG("value 0x%04x", value); } static ssize_t read_rank(struct bt_conn *conn, const struct bt_gatt_attr *attr, void *buf, uint16_t len, uint16_t offset) { struct bt_csip_set_member_svc_inst *svc_inst = BT_AUDIO_CHRC_USER_DATA(attr); LOG_DBG("%u", svc_inst->rank); return bt_gatt_attr_read(conn, attr, buf, len, offset, &svc_inst->rank, sizeof(svc_inst->rank)); } static void set_lock_timer_handler(struct k_work *work) { struct k_work_delayable *delayable; struct bt_csip_set_member_svc_inst *svc_inst; delayable = k_work_delayable_from_work(work); svc_inst = CONTAINER_OF(delayable, struct bt_csip_set_member_svc_inst, set_lock_timer); LOG_DBG("Lock timeout, releasing"); svc_inst->set_lock = BT_CSIP_RELEASE_VALUE; notify_clients(svc_inst, NULL, FLAG_NOTIFY_LOCK); if (svc_inst->cb != NULL && svc_inst->cb->lock_changed != NULL) { bool locked = svc_inst->set_lock == BT_CSIP_LOCK_VALUE; svc_inst->cb->lock_changed(NULL, svc_inst, locked); } } static void csip_security_changed(struct bt_conn *conn, bt_security_t level, enum bt_security_err err) { if (err != 0 || conn->encrypt == 0) { return; } if (!bt_addr_le_is_bonded(conn->id, &conn->le.dst)) { return; } for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { struct bt_csip_set_member_svc_inst *svc_inst = &svc_insts[i]; for (size_t j = 0U; j < ARRAY_SIZE(svc_inst->clients); j++) { struct csip_client *client; client = &svc_inst->clients[i]; if (atomic_test_bit(client->flags, FLAG_NOTIFY_LOCK) && bt_addr_le_eq(bt_conn_get_dst(conn), &client->addr)) { notify_work_reschedule(K_NO_WAIT); break; } } } } static void handle_csip_disconnect(struct bt_csip_set_member_svc_inst *svc_inst, struct bt_conn *conn) { LOG_DBG("Non-bonded device"); if (is_last_client_to_write(svc_inst, conn)) { (void)memset(&svc_inst->lock_client_addr, 0, sizeof(svc_inst->lock_client_addr)); svc_inst->set_lock = BT_CSIP_RELEASE_VALUE; notify_clients(svc_inst, NULL, FLAG_NOTIFY_LOCK); if (svc_inst->cb != NULL && svc_inst->cb->lock_changed != NULL) { bool locked = svc_inst->set_lock == BT_CSIP_LOCK_VALUE; svc_inst->cb->lock_changed(conn, svc_inst, locked); } } /* Check if the disconnected device once was bonded and stored * here as a bonded device */ for (size_t i = 0U; i < ARRAY_SIZE(svc_inst->clients); i++) { struct csip_client *client; client = &svc_inst->clients[i]; if (bt_addr_le_eq(bt_conn_get_dst(conn), &client->addr)) { (void)memset(client, 0, sizeof(*client)); break; } } } static void csip_disconnected(struct bt_conn *conn, uint8_t reason) { LOG_DBG("Disconnected: %s (reason %u)", bt_addr_le_str(bt_conn_get_dst(conn)), reason); if (!bt_addr_le_is_bonded(conn->id, &conn->le.dst)) { for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { handle_csip_disconnect(&svc_insts[i], conn); } } } static void handle_csip_auth_complete(struct bt_csip_set_member_svc_inst *svc_inst, struct bt_conn *conn) { /* Check if already in list, and do nothing if it is */ for (size_t i = 0U; i < ARRAY_SIZE(svc_inst->clients); i++) { struct csip_client *client; client = &svc_inst->clients[i]; if (atomic_test_bit(client->flags, FLAG_ACTIVE) && bt_addr_le_eq(bt_conn_get_dst(conn), &client->addr)) { return; } } /* Else add the device */ for (size_t i = 0U; i < ARRAY_SIZE(svc_inst->clients); i++) { struct csip_client *client; client = &svc_inst->clients[i]; if (!atomic_test_bit(client->flags, FLAG_ACTIVE)) { atomic_set_bit(client->flags, FLAG_ACTIVE); memcpy(&client->addr, bt_conn_get_dst(conn), sizeof(bt_addr_le_t)); /* Send out all pending notifications */ notify_work_reschedule(K_NO_WAIT); return; } } LOG_WRN("Could not add device to pending notification list"); } static void auth_pairing_complete(struct bt_conn *conn, bool bonded) { /** * If a pairing is complete for a bonded device, then we * 1) Store the connection pointer to later validate SIRK encryption * 2) Check if the device is already in the `clients`, and if it is * not, then we * 3) Check if there's room for another device in the `clients` * array. If there are no more room for a new device, then * 4) Either we ignore this new device (bad luck), or we overwrite * the oldest entry, following the behavior of the key storage. */ LOG_DBG("%s paired (%sbonded)", bt_addr_le_str(bt_conn_get_dst(conn)), bonded ? "" : "not "); if (!bonded) { return; } for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { handle_csip_auth_complete(&svc_insts[i], conn); } } static void csip_bond_deleted(uint8_t id, const bt_addr_le_t *peer) { for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { struct bt_csip_set_member_svc_inst *svc_inst = &svc_insts[i]; for (size_t j = 0U; j < ARRAY_SIZE(svc_inst->clients); j++) { /* Check if match, and if active, if so, reset */ if (atomic_test_bit(svc_inst->clients[i].flags, FLAG_ACTIVE) && bt_addr_le_eq(peer, &svc_inst->clients[i].addr)) { atomic_clear(svc_inst->clients[i].flags); (void)memset(&svc_inst->clients[i].addr, 0, sizeof(bt_addr_le_t)); break; } } } } static struct bt_conn_cb conn_callbacks = { .disconnected = csip_disconnected, .security_changed = csip_security_changed, }; static struct bt_conn_auth_info_cb auth_callbacks = { .pairing_complete = auth_pairing_complete, .bond_deleted = csip_bond_deleted }; #if defined(CONFIG_BT_CSIP_SET_MEMBER_NOTIFIABLE) #define BT_CSIS_CHR_SIRK(_csip) \ BT_AUDIO_CHRC(BT_UUID_CSIS_SIRK, BT_GATT_CHRC_READ | BT_GATT_CHRC_NOTIFY, \ BT_GATT_PERM_READ_ENCRYPT, read_sirk, NULL, &_csip), \ BT_AUDIO_CCC(sirk_cfg_changed) #else #define BT_CSIS_CHR_SIRK(_csip) \ BT_AUDIO_CHRC(BT_UUID_CSIS_SIRK, BT_GATT_CHRC_READ, BT_GATT_PERM_READ_ENCRYPT, read_sirk, \ NULL, &_csip) #endif /* CONFIG_BT_CSIP_SET_MEMBER_NOTIFIABLE */ #define BT_CSIP_SERVICE_DEFINITION(_csip) {\ BT_GATT_PRIMARY_SERVICE(BT_UUID_CSIS), \ BT_CSIS_CHR_SIRK(_csip), \ BT_AUDIO_CHRC(BT_UUID_CSIS_SET_SIZE, \ BT_GATT_CHRC_READ | BT_GATT_CHRC_NOTIFY, \ BT_GATT_PERM_READ_ENCRYPT, \ read_set_size, NULL, &_csip), \ BT_AUDIO_CCC(set_size_cfg_changed), \ BT_AUDIO_CHRC(BT_UUID_CSIS_SET_LOCK, \ BT_GATT_CHRC_READ | BT_GATT_CHRC_NOTIFY | BT_GATT_CHRC_WRITE, \ BT_GATT_PERM_READ_ENCRYPT | BT_GATT_PERM_WRITE_ENCRYPT, \ read_set_lock, write_set_lock, &_csip), \ BT_AUDIO_CCC(set_lock_cfg_changed), \ BT_AUDIO_CHRC(BT_UUID_CSIS_RANK, \ BT_GATT_CHRC_READ, \ BT_GATT_PERM_READ_ENCRYPT, \ read_rank, NULL, &_csip) \ } BT_GATT_SERVICE_INSTANCE_DEFINE(csip_set_member_service_list, svc_insts, CONFIG_BT_CSIP_SET_MEMBER_MAX_INSTANCE_COUNT, BT_CSIP_SERVICE_DEFINITION); /****************************** Public API ******************************/ void *bt_csip_set_member_svc_decl_get(const struct bt_csip_set_member_svc_inst *svc_inst) { if (svc_inst == NULL || svc_inst->service_p == NULL) { return NULL; } return svc_inst->service_p->attrs; } static bool valid_register_param(const struct bt_csip_set_member_register_param *param) { if (param->lockable && param->rank == 0) { LOG_DBG("Rank cannot be 0 if service is lockable"); return false; } if (param->rank > 0 && param->set_size > 0 && param->rank > param->set_size) { LOG_DBG("Invalid rank: %u (shall be less than or equal to set_size: %u)", param->rank, param->set_size); return false; } #if CONFIG_BT_CSIP_SET_MEMBER_MAX_INSTANCE_COUNT > 1 if (param->parent == NULL) { LOG_DBG("Parent service not provided"); return false; } #endif /* CONFIG_BT_CSIP_SET_MEMBER_MAX_INSTANCE_COUNT > 1 */ return true; } static void remove_csis_char(const struct bt_uuid *uuid, struct bt_gatt_service *svc) { size_t attrs_to_rem; /* Rank does not have any CCCD */ if (bt_uuid_cmp(uuid, BT_UUID_CSIS_RANK) == 0) { attrs_to_rem = CSIS_RANK_CHAR_ATTR_COUNT; } else { attrs_to_rem = CSIS_CHAR_ATTR_COUNT; } /* Start at index 4 as the first 4 attributes are mandatory */ for (size_t i = 4U; i < svc->attr_count; i++) { if (bt_uuid_cmp(svc->attrs[i].uuid, uuid) == 0) { /* Remove the characteristic declaration, the characteristic value and * potentially the CCCD. The value declaration will be a i - 1, the * characteristic value at i and the CCCD is potentially at i + 1 */ /* We use attrs_to_rem to determine whether there is a CCCD after the * characteristic value or not, which then determines if this is the last * characteristic or not */ if (i == (svc->attr_count - (attrs_to_rem - 1))) { /* This is the last characteristic in the service: just decrement * the attr_count by number of attributes to remove * (CSIS_CHAR_ATTR_COUNT) */ } else { /* Move all following attributes attrs_to_rem locations "up" */ for (size_t j = i - 1U; j < svc->attr_count - attrs_to_rem; j++) { svc->attrs[j] = svc->attrs[j + attrs_to_rem]; } } svc->attr_count -= attrs_to_rem; return; } } __ASSERT(false, "Failed to remove CSIS char %s", bt_uuid_str(uuid)); } static void notify(struct bt_csip_set_member_svc_inst *svc_inst, struct bt_conn *conn, const struct bt_uuid *uuid, const void *data, uint16_t len) { int err; if (svc_inst->service_p == NULL) { return; } err = bt_gatt_notify_uuid(conn, uuid, svc_inst->service_p->attrs, data, len); if (err) { if (err == -ENOTCONN) { LOG_DBG("Notification error: ENOTCONN (%d)", err); } else { LOG_ERR("Notification error: %d", err); } } } static void notify_cb(struct bt_conn *conn, void *data) { struct bt_conn_info info; int err = 0; err = bt_conn_get_info(conn, &info); if (err != 0) { return; } if (info.state != BT_CONN_STATE_CONNECTED) { /* Not connected */ LOG_DBG("Not connected: %u", info.state); return; } for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { struct bt_csip_set_member_svc_inst *svc_inst = &svc_insts[i]; struct csip_client *client = &svc_inst->clients[bt_conn_index(conn)]; if (atomic_test_and_clear_bit(client->flags, FLAG_NOTIFY_LOCK)) { notify(svc_inst, conn, BT_UUID_CSIS_SET_LOCK, &svc_inst->set_lock, sizeof(svc_inst->set_lock)); } if (IS_ENABLED(CONFIG_BT_CSIP_SET_MEMBER_NOTIFIABLE) && atomic_test_and_clear_bit(client->flags, FLAG_NOTIFY_SIRK)) { notify(svc_inst, conn, BT_UUID_CSIS_SIRK, &svc_inst->sirk, sizeof(svc_inst->sirk)); } } } static void deferred_nfy_work_handler(struct k_work *work) { bt_conn_foreach(BT_CONN_TYPE_LE, notify_cb, NULL); } static void add_bonded_addr_to_client_list(const struct bt_bond_info *info, void *data) { for (size_t i = 0U; i < ARRAY_SIZE(svc_insts); i++) { struct bt_csip_set_member_svc_inst *svc_inst = &svc_insts[i]; for (size_t j = 1U; j < ARRAY_SIZE(svc_inst->clients); i++) { /* Check if device is registered, it not, add it */ if (!atomic_test_bit(svc_inst->clients[j].flags, FLAG_ACTIVE)) { char addr_str[BT_ADDR_LE_STR_LEN]; atomic_set_bit(svc_inst->clients[j].flags, FLAG_ACTIVE); memcpy(&svc_inst->clients[j].addr, &info->addr, sizeof(bt_addr_le_t)); bt_addr_le_to_str(&svc_inst->clients[j].addr, addr_str, sizeof(addr_str)); LOG_DBG("Added %s to bonded list\n", addr_str); return; } } } } int bt_csip_set_member_register(const struct bt_csip_set_member_register_param *param, struct bt_csip_set_member_svc_inst **svc_inst) { static bool first_register; static uint8_t instance_cnt; struct bt_csip_set_member_svc_inst *inst; int err; if (instance_cnt == ARRAY_SIZE(svc_insts)) { LOG_DBG("Too many set member registrations"); return -ENOMEM; } CHECKIF(param == NULL) { LOG_DBG("NULL param"); return -EINVAL; } CHECKIF(!valid_register_param(param)) { LOG_DBG("Invalid parameters"); return -EINVAL; } inst = &svc_insts[instance_cnt]; inst->service_p = &csip_set_member_service_list[instance_cnt]; instance_cnt++; if (!first_register) { bt_conn_cb_register(&conn_callbacks); bt_conn_auth_info_cb_register(&auth_callbacks); /* Restore bonding list */ bt_foreach_bond(BT_ID_DEFAULT, add_bonded_addr_to_client_list, NULL); first_register = true; } /* The removal of the optional characteristics should be done in reverse order of the order * in BT_CSIP_SERVICE_DEFINITION, as that improves the performance of remove_csis_char, * since it's easier to remove the last characteristic */ if (param->rank == 0U) { remove_csis_char(BT_UUID_CSIS_RANK, inst->service_p); } if (param->set_size == 0U) { remove_csis_char(BT_UUID_CSIS_SET_SIZE, inst->service_p); } if (!param->lockable) { remove_csis_char(BT_UUID_CSIS_SET_LOCK, inst->service_p); } err = bt_gatt_service_register(inst->service_p); if (err != 0) { LOG_DBG("CSIS service register failed: %d", err); return err; } k_work_init_delayable(&inst->set_lock_timer, set_lock_timer_handler); inst->rank = param->rank; inst->set_size = param->set_size; inst->set_lock = BT_CSIP_RELEASE_VALUE; inst->sirk.type = BT_CSIP_SIRK_TYPE_PLAIN; inst->cb = param->cb; if (IS_ENABLED(CONFIG_BT_CSIP_SET_MEMBER_TEST_SAMPLE_DATA)) { uint8_t test_sirk[] = { 0xcd, 0xcc, 0x72, 0xdd, 0x86, 0x8c, 0xcd, 0xce, 0x22, 0xfd, 0xa1, 0x21, 0x09, 0x7d, 0x7d, 0x45, }; (void)memcpy(inst->sirk.value, test_sirk, sizeof(test_sirk)); LOG_DBG("CSIP SIRK was overwritten by sample data SIRK"); } else { (void)memcpy(inst->sirk.value, param->sirk, sizeof(inst->sirk.value)); } *svc_inst = inst; return 0; } int bt_csip_set_member_unregister(struct bt_csip_set_member_svc_inst *svc_inst) { int err; CHECKIF(svc_inst == NULL) { LOG_DBG("NULL svc_inst"); return -EINVAL; } err = bt_gatt_service_unregister(svc_inst->service_p); if (err != 0) { LOG_DBG("CSIS service unregister failed: %d", err); return err; } (void)k_work_cancel_delayable(&svc_inst->set_lock_timer); memset(svc_inst, 0, sizeof(*svc_inst)); return 0; } int bt_csip_set_member_sirk(struct bt_csip_set_member_svc_inst *svc_inst, const uint8_t sirk[BT_CSIP_SIRK_SIZE]) { CHECKIF(svc_inst == NULL) { LOG_DBG("NULL svc_inst"); return -EINVAL; } CHECKIF(sirk == NULL) { LOG_DBG("NULL SIRK"); return -EINVAL; } memcpy(svc_inst->sirk.value, sirk, BT_CSIP_SIRK_SIZE); notify_clients(svc_inst, NULL, FLAG_NOTIFY_SIRK); return 0; } int bt_csip_set_member_get_sirk(struct bt_csip_set_member_svc_inst *svc_inst, uint8_t sirk[BT_CSIP_SIRK_SIZE]) { CHECKIF(svc_inst == NULL) { LOG_DBG("NULL svc_inst"); return -EINVAL; } CHECKIF(sirk == NULL) { LOG_DBG("NULL SIRK"); return -EINVAL; } memcpy(sirk, svc_inst->sirk.value, BT_CSIP_SIRK_SIZE); return 0; } int bt_csip_set_member_lock(struct bt_csip_set_member_svc_inst *svc_inst, bool lock, bool force) { uint8_t lock_val; int err = 0; if (lock) { lock_val = BT_CSIP_LOCK_VALUE; } else { lock_val = BT_CSIP_RELEASE_VALUE; } if (!lock && force) { svc_inst->set_lock = BT_CSIP_RELEASE_VALUE; notify_clients(svc_inst, NULL, FLAG_NOTIFY_LOCK); if (svc_inst->cb != NULL && svc_inst->cb->lock_changed != NULL) { svc_inst->cb->lock_changed(NULL, &svc_insts[0], false); } } else { err = set_lock(NULL, svc_inst, lock_val); } if (err < 0) { return BT_GATT_ERR(err); } else { return 0; } }