/* cs.c - Bluetooth Channel Sounding handling */ /* * Copyright (c) 2024 Nordic Semiconductor ASA * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include "conn_internal.h" #define LOG_LEVEL CONFIG_BT_HCI_CORE_LOG_LEVEL #include LOG_MODULE_REGISTER(bt_cs); #if defined(CONFIG_BT_CHANNEL_SOUNDING) #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) static struct bt_le_cs_test_cb cs_test_callbacks; #endif struct reassembly_buf_meta_data { uint16_t conn_handle; }; static void clear_on_disconnect(struct bt_conn *conn, uint8_t reason); NET_BUF_POOL_FIXED_DEFINE(reassembly_buf_pool, CONFIG_BT_CHANNEL_SOUNDING_REASSEMBLY_BUFFER_CNT, CONFIG_BT_CHANNEL_SOUNDING_REASSEMBLY_BUFFER_SIZE, sizeof(struct reassembly_buf_meta_data), NULL); static sys_slist_t reassembly_bufs = SYS_SLIST_STATIC_INIT(&reassembly_bufs); struct bt_conn_le_cs_subevent_result reassembled_result; BT_CONN_CB_DEFINE(cs_conn_callbacks) = { .disconnected = clear_on_disconnect, }; /** @brief Allocates new reassembly buffer identified by the connection handle * * @param conn_handle Connection handle * @return struct net_buf* Reassembly buffer, NULL if allocation fails */ static struct net_buf *alloc_reassembly_buf(uint16_t conn_handle) { struct net_buf *buf = net_buf_alloc(&reassembly_buf_pool, K_NO_WAIT); if (!buf) { LOG_ERR("Failed to allocate new reassembly buffer"); return NULL; } struct reassembly_buf_meta_data *buf_meta_data = (struct reassembly_buf_meta_data *)buf->user_data; buf_meta_data->conn_handle = conn_handle; net_buf_slist_put(&reassembly_bufs, buf); LOG_DBG("Allocated new reassembly buffer for conn handle %d", conn_handle); return buf; } /** @brief Frees a reassembly buffer * * @note Takes the ownership of the pointer and sets it to NULL * * @param buf Double pointer to reassembly buffer */ static void free_reassembly_buf(struct net_buf **buf) { if (!buf) { LOG_ERR("NULL double pointer was passed when attempting to free reassembly buffer"); return; } if (!(*buf)) { LOG_WRN("Attempted double free on reassembly buffer"); return; } struct reassembly_buf_meta_data *buf_meta_data = (struct reassembly_buf_meta_data *)((*buf)->user_data); LOG_DBG("De-allocating reassembly buffer for conn handle %d", buf_meta_data->conn_handle); if (!sys_slist_find_and_remove(&reassembly_bufs, &(*buf)->node)) { LOG_WRN("The buffer was not in the list"); } net_buf_unref(*buf); *buf = NULL; } /** @brief Gets the reassembly buffer identified by the connection handle * * @param conn_handle Connection handle * @param allocate Allocates a new reassembly buffer if it's not allocated already * @return struct net_buf* Reassembly buffer, NULL if it doesn't exist or failed when allocating new */ static struct net_buf *get_reassembly_buf(uint16_t conn_handle, bool allocate) { sys_snode_t *node; SYS_SLIST_FOR_EACH_NODE(&reassembly_bufs, node) { struct net_buf *buf = CONTAINER_OF(node, struct net_buf, node); struct reassembly_buf_meta_data *buf_meta_data = (struct reassembly_buf_meta_data *)(buf->user_data); if (buf_meta_data->conn_handle == conn_handle) { return buf; } } return allocate ? alloc_reassembly_buf(conn_handle) : NULL; } /** @brief Adds step data to a reassembly buffer * * @param reassembly_buf Reassembly buffer * @param data Step data * @param data_len Step data length * @return true if successful, false if there is insufficient space */ static bool add_reassembly_data(struct net_buf *reassembly_buf, const uint8_t *data, uint16_t data_len) { if (data_len > net_buf_tailroom(reassembly_buf)) { LOG_ERR("Not enough reassembly buffer space for subevent result"); return false; } net_buf_add_mem(reassembly_buf, data, data_len); return true; } /** @brief Initializes a reassembly buffer from partial step data * * @note Upon first call, this function also registers the disconnection callback * to ensure any dangling reassembly buffer is freed * * @param conn_handle Connection handle * @param steps Step data * @param step_data_len Step data length * @return struct net_buf* Pointer to reassembly buffer, NULL if fails to allocate or insert data */ static struct net_buf *start_reassembly(uint16_t conn_handle, const uint8_t *steps, uint16_t step_data_len) { struct net_buf *reassembly_buf = get_reassembly_buf(conn_handle, true); if (!reassembly_buf) { LOG_ERR("No buffer allocated for the result reassembly"); return NULL; } if (reassembly_buf->len) { LOG_WRN("Over-written incomplete CS subevent results"); } net_buf_reset(reassembly_buf); bool success = add_reassembly_data(reassembly_buf, steps, step_data_len); return success ? reassembly_buf : NULL; } /** @brief Adds more step data to reassembly buffer identified by the connection handle * * @param conn_handle Connection handle * @param steps Step data * @param step_data_len Step data length * @return struct net_buf* Pointer to reassembly buffer, NULL if fails to insert data */ static struct net_buf *continue_reassembly(uint16_t conn_handle, const uint8_t *steps, uint16_t step_data_len) { struct net_buf *reassembly_buf = get_reassembly_buf(conn_handle, false); if (!reassembly_buf) { LOG_ERR("No reassembly buffer was allocated for this CS procedure, possibly due to " "an out-of-order subevent result continue event"); return NULL; } if (!reassembly_buf->len) { LOG_WRN("Discarded out-of-order partial CS subevent results"); return NULL; } if (!step_data_len) { return reassembly_buf; } bool success = add_reassembly_data(reassembly_buf, steps, step_data_len); return success ? reassembly_buf : NULL; } /** * @brief Disconnect callback to clear any dangling reassembly buffer * * @param conn Connection * @param reason Reason */ static void clear_on_disconnect(struct bt_conn *conn, uint8_t reason) { struct net_buf *buf = get_reassembly_buf(conn->handle, false); if (buf) { free_reassembly_buf(&buf); } } /** @brief Invokes user callback for new subevent results * * @param conn Connection context, NULL for CS Test subevent results * @param p_result Pointer to subevent results */ static void invoke_subevent_result_callback(struct bt_conn *conn, struct bt_conn_le_cs_subevent_result *p_result) { #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) if (!conn) { cs_test_callbacks.le_cs_test_subevent_data_available(p_result); } else #endif /* CONFIG_BT_CHANNEL_SOUNDING_TEST */ { notify_cs_subevent_result(conn, p_result); } } /** @brief Resets reassembly results * */ static void reset_reassembly_results(void) { memset(&reassembled_result, 0, sizeof(struct bt_conn_le_cs_subevent_result)); } /** @brief Converts PCT to a pair of int16_t * */ struct bt_le_cs_iq_sample bt_le_cs_parse_pct(const uint8_t pct[3]) { uint32_t pct_u32 = sys_get_le24(pct); /* Extract I and Q. */ uint16_t i_u16 = pct_u32 & BT_HCI_LE_CS_PCT_I_MASK; uint16_t q_u16 = (pct_u32 & BT_HCI_LE_CS_PCT_Q_MASK) >> 12; /* Convert from 12-bit 2's complement to int16_t */ int16_t i = (i_u16 ^ BIT(11)) - BIT(11); int16_t q = (q_u16 ^ BIT(11)) - BIT(11); return (struct bt_le_cs_iq_sample){.i = i, .q = q}; } void bt_le_cs_set_valid_chmap_bits(uint8_t channel_map[10]) { memset(channel_map, 0xFF, 10); /** Channels n = 0, 1, 23, 24, 25, 77, and 78 are not allowed and shall be set to zero. * Channel 79 is reserved for future use and shall be set to zero. */ BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 0, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 1, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 23, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 24, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 25, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 77, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 78, 0); BT_LE_CS_CHANNEL_BIT_SET_VAL(channel_map, 79, 0); } int bt_le_cs_read_remote_supported_capabilities(struct bt_conn *conn) { struct bt_hci_cp_le_read_remote_supported_capabilities *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_READ_REMOTE_SUPPORTED_CAPABILITIES, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_READ_REMOTE_SUPPORTED_CAPABILITIES, buf, NULL); } void bt_hci_le_cs_read_remote_supported_capabilities_complete(struct net_buf *buf) { struct bt_conn *conn; struct bt_conn_le_cs_capabilities remote_cs_capabilities; struct bt_hci_evt_le_cs_read_remote_supported_capabilities_complete *evt; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("Read Remote Supported Capabilities failed (status 0x%02X)", evt->status); return; } conn = bt_conn_lookup_handle(sys_le16_to_cpu(evt->conn_handle), BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Could not lookup connection handle when reading remote CS capabilities"); return; } remote_cs_capabilities.num_config_supported = evt->num_config_supported; remote_cs_capabilities.max_consecutive_procedures_supported = sys_le16_to_cpu(evt->max_consecutive_procedures_supported); remote_cs_capabilities.num_antennas_supported = evt->num_antennas_supported; remote_cs_capabilities.max_antenna_paths_supported = evt->max_antenna_paths_supported; remote_cs_capabilities.initiator_supported = evt->roles_supported & BT_HCI_LE_CS_INITIATOR_ROLE_MASK; remote_cs_capabilities.reflector_supported = evt->roles_supported & BT_HCI_LE_CS_REFLECTOR_ROLE_MASK; remote_cs_capabilities.mode_3_supported = evt->modes_supported & BT_HCI_LE_CS_MODES_SUPPORTED_MODE_3_MASK; remote_cs_capabilities.rtt_aa_only_n = evt->rtt_aa_only_n; remote_cs_capabilities.rtt_sounding_n = evt->rtt_sounding_n; remote_cs_capabilities.rtt_random_payload_n = evt->rtt_random_payload_n; if (evt->rtt_aa_only_n) { if (evt->rtt_capability & BT_HCI_LE_CS_RTT_AA_ONLY_N_10NS_MASK) { remote_cs_capabilities.rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_10NS; } else { remote_cs_capabilities.rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_150NS; } } else { remote_cs_capabilities.rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_NOT_SUPP; } if (evt->rtt_sounding_n) { if (evt->rtt_capability & BT_HCI_LE_CS_RTT_SOUNDING_N_10NS_MASK) { remote_cs_capabilities.rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_10NS; } else { remote_cs_capabilities.rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_150NS; } } else { remote_cs_capabilities.rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_NOT_SUPP; } if (evt->rtt_random_payload_n) { if (evt->rtt_capability & BT_HCI_LE_CS_RTT_RANDOM_PAYLOAD_N_10NS_MASK) { remote_cs_capabilities.rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_10NS; } else { remote_cs_capabilities.rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_150NS; } } else { remote_cs_capabilities.rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_NOT_SUPP; } remote_cs_capabilities.phase_based_nadm_sounding_supported = sys_le16_to_cpu(evt->nadm_sounding_capability) & BT_HCI_LE_CS_NADM_SOUNDING_CAPABILITY_PHASE_BASED_MASK; remote_cs_capabilities.phase_based_nadm_random_supported = sys_le16_to_cpu(evt->nadm_random_capability) & BT_HCI_LE_CS_NADM_RANDOM_CAPABILITY_PHASE_BASED_MASK; remote_cs_capabilities.cs_sync_2m_phy_supported = evt->cs_sync_phys_supported & BT_HCI_LE_CS_SYNC_PHYS_2M_MASK; remote_cs_capabilities.cs_sync_2m_2bt_phy_supported = evt->cs_sync_phys_supported & BT_HCI_LE_CS_SYNC_PHYS_2M_2BT_MASK; remote_cs_capabilities.cs_without_fae_supported = sys_le16_to_cpu(evt->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_NO_TX_FAE_MASK; remote_cs_capabilities.chsel_alg_3c_supported = sys_le16_to_cpu(evt->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_CHSEL_ALG_3C_MASK; remote_cs_capabilities.pbr_from_rtt_sounding_seq_supported = sys_le16_to_cpu(evt->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_PBR_FROM_RTT_SOUNDING_SEQ_MASK; remote_cs_capabilities.t_ip1_times_supported = sys_le16_to_cpu(evt->t_ip1_times_supported); remote_cs_capabilities.t_ip2_times_supported = sys_le16_to_cpu(evt->t_ip2_times_supported); remote_cs_capabilities.t_fcs_times_supported = sys_le16_to_cpu(evt->t_fcs_times_supported); remote_cs_capabilities.t_pm_times_supported = sys_le16_to_cpu(evt->t_pm_times_supported); remote_cs_capabilities.t_sw_time = evt->t_sw_time_supported; remote_cs_capabilities.tx_snr_capability = evt->tx_snr_capability; notify_remote_cs_capabilities(conn, remote_cs_capabilities); bt_conn_unref(conn); } int bt_le_cs_set_default_settings(struct bt_conn *conn, const struct bt_le_cs_set_default_settings_param *params) { struct bt_hci_cp_le_cs_set_default_settings *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_SET_DEFAULT_SETTINGS, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->max_tx_power = params->max_tx_power; cp->cs_sync_antenna_selection = params->cs_sync_antenna_selection; cp->role_enable = 0; if (params->enable_initiator_role) { cp->role_enable |= BT_HCI_OP_LE_CS_INITIATOR_ROLE_MASK; } if (params->enable_reflector_role) { cp->role_enable |= BT_HCI_OP_LE_CS_REFLECTOR_ROLE_MASK; } return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_SET_DEFAULT_SETTINGS, buf, NULL); } int bt_le_cs_read_remote_fae_table(struct bt_conn *conn) { struct bt_hci_cp_le_read_remote_fae_table *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_READ_REMOTE_FAE_TABLE, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_READ_REMOTE_FAE_TABLE, buf, NULL); } void bt_hci_le_cs_read_remote_fae_table_complete(struct net_buf *buf) { struct bt_conn *conn; struct bt_conn_le_cs_fae_table fae_table; struct bt_hci_evt_le_cs_read_remote_fae_table_complete *evt; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("Read Remote FAE Table failed with status 0x%02X", evt->status); return; } conn = bt_conn_lookup_handle(sys_le16_to_cpu(evt->conn_handle), BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Could not lookup connection handle when reading remote FAE Table"); return; } fae_table.remote_fae_table = evt->remote_fae_table; notify_remote_cs_fae_table(conn, fae_table); bt_conn_unref(conn); } #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) int bt_le_cs_test_cb_register(struct bt_le_cs_test_cb cb) { cs_test_callbacks = cb; return 0; } int bt_le_cs_start_test(const struct bt_le_cs_test_param *params) { struct bt_hci_op_le_cs_test *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_TEST, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->main_mode_type = params->main_mode; cp->sub_mode_type = params->sub_mode; cp->main_mode_repetition = params->main_mode_repetition; cp->mode_0_steps = params->mode_0_steps; cp->role = params->role; cp->rtt_type = params->rtt_type; cp->cs_sync_phy = params->cs_sync_phy; cp->cs_sync_antenna_selection = params->cs_sync_antenna_selection; sys_put_le24(params->subevent_len, cp->subevent_len); cp->subevent_interval = sys_cpu_to_le16(params->subevent_interval); cp->max_num_subevents = params->max_num_subevents; cp->transmit_power_level = params->transmit_power_level; cp->t_ip1_time = params->t_ip1_time; cp->t_ip2_time = params->t_ip2_time; cp->t_fcs_time = params->t_fcs_time; cp->t_pm_time = params->t_pm_time; cp->t_sw_time = params->t_sw_time; cp->tone_antenna_config_selection = params->tone_antenna_config_selection; cp->reserved = 0; cp->snr_control_initiator = params->initiator_snr_control; cp->snr_control_reflector = params->reflector_snr_control; cp->drbg_nonce = sys_cpu_to_le16(params->drbg_nonce); cp->channel_map_repetition = params->override_config_0.channel_map_repetition; cp->override_config = sys_cpu_to_le16(params->override_config); uint8_t override_parameters_length = 0; if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_0_MASK) { const uint8_t num_channels = params->override_config_0.set.num_channels; net_buf_add_u8(buf, num_channels); override_parameters_length++; net_buf_add_mem(buf, params->override_config_0.set.channels, num_channels); override_parameters_length += num_channels; } else { net_buf_add_mem(buf, params->override_config_0.not_set.channel_map, sizeof(params->override_config_0.not_set.channel_map)); net_buf_add_u8(buf, params->override_config_0.not_set.channel_selection_type); net_buf_add_u8(buf, params->override_config_0.not_set.ch3c_shape); net_buf_add_u8(buf, params->override_config_0.not_set.ch3c_jump); override_parameters_length += (sizeof(params->override_config_0.not_set.channel_map) + sizeof(params->override_config_0.not_set.channel_selection_type) + sizeof(params->override_config_0.not_set.ch3c_shape) + sizeof(params->override_config_0.not_set.ch3c_jump)); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_2_MASK) { net_buf_add_mem(buf, ¶ms->override_config_2, sizeof(params->override_config_2)); override_parameters_length += sizeof(params->override_config_2); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_3_MASK) { net_buf_add_mem(buf, ¶ms->override_config_3, sizeof(params->override_config_3)); override_parameters_length += sizeof(params->override_config_3); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_4_MASK) { net_buf_add_mem(buf, ¶ms->override_config_4, sizeof(params->override_config_4)); override_parameters_length += sizeof(params->override_config_4); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_5_MASK) { net_buf_add_le32(buf, params->override_config_5.cs_sync_aa_initiator); net_buf_add_le32(buf, params->override_config_5.cs_sync_aa_reflector); override_parameters_length += sizeof(params->override_config_5); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_6_MASK) { net_buf_add_mem(buf, ¶ms->override_config_6, sizeof(params->override_config_6)); override_parameters_length += sizeof(params->override_config_6); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_7_MASK) { net_buf_add_mem(buf, ¶ms->override_config_7, sizeof(params->override_config_7)); override_parameters_length += sizeof(params->override_config_7); } if (params->override_config & BT_HCI_OP_LE_CS_TEST_OVERRIDE_CONFIG_8_MASK) { net_buf_add_mem(buf, ¶ms->override_config_8, sizeof(params->override_config_8)); override_parameters_length += sizeof(params->override_config_8); } cp->override_parameters_length = override_parameters_length; return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_TEST, buf, NULL); } #endif /* CONFIG_BT_CHANNEL_SOUNDING_TEST */ void bt_hci_le_cs_subevent_result(struct net_buf *buf) { struct bt_conn *conn = NULL; struct bt_hci_evt_le_cs_subevent_result *evt; struct bt_conn_le_cs_subevent_result result; struct bt_conn_le_cs_subevent_result *p_result = &result; struct net_buf_simple step_data_buf; struct net_buf *reassembly_buf = NULL; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); uint16_t conn_handle = sys_le16_to_cpu(evt->conn_handle); #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) if (conn_handle == BT_HCI_LE_CS_TEST_CONN_HANDLE) { if (!cs_test_callbacks.le_cs_test_subevent_data_available) { LOG_WRN("No callback registered. Discarded subevent results from CS Test."); return; } } else #endif /* CONFIG_BT_CHANNEL_SOUNDING_TEST */ { conn = bt_conn_lookup_handle(conn_handle, BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Unknown connection handle when processing subevent results"); return; } } if (evt->subevent_done_status != BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_PARTIAL) { p_result->step_data_buf = NULL; if (evt->num_steps_reported) { net_buf_simple_init_with_data(&step_data_buf, evt->steps, buf->len); p_result->step_data_buf = &step_data_buf; } } else { if (evt->procedure_done_status != BT_HCI_LE_CS_PROCEDURE_DONE_STATUS_PARTIAL) { LOG_WRN("Procedure status is inconsistent with subevent status. Discarding " "subevent results"); goto abort; } if (!evt->num_steps_reported) { LOG_WRN("Discarding partial results without step data"); goto abort; } reassembly_buf = start_reassembly(conn_handle, evt->steps, buf->len); if (!reassembly_buf) { goto abort; } p_result = &reassembled_result; p_result->step_data_buf = (struct net_buf_simple *)&reassembly_buf->data; } p_result->header.procedure_counter = sys_le16_to_cpu(evt->procedure_counter); p_result->header.frequency_compensation = sys_le16_to_cpu(evt->frequency_compensation); p_result->header.procedure_done_status = evt->procedure_done_status; p_result->header.subevent_done_status = evt->subevent_done_status; p_result->header.procedure_abort_reason = evt->procedure_abort_reason; p_result->header.subevent_abort_reason = evt->subevent_abort_reason; p_result->header.reference_power_level = evt->reference_power_level; p_result->header.num_antenna_paths = evt->num_antenna_paths; p_result->header.num_steps_reported = evt->num_steps_reported; p_result->header.abort_step = evt->subevent_done_status == BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_ABORTED ? 0 : 255; p_result->header.config_id = 0; p_result->header.start_acl_conn_event = 0; if (conn) { p_result->header.config_id = evt->config_id; p_result->header.start_acl_conn_event = sys_le16_to_cpu(evt->start_acl_conn_event_counter); } if (evt->subevent_done_status != BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_PARTIAL) { invoke_subevent_result_callback(conn, p_result); } if (evt->procedure_done_status != BT_CONN_LE_CS_PROCEDURE_INCOMPLETE) { /* We can now clear the any reassembly buffer allocated for this procedure, * to avoid code duplication, we're using the abort label to do so */ goto abort; } if (conn) { bt_conn_unref(conn); conn = NULL; } return; abort: if (conn) { bt_conn_unref(conn); conn = NULL; } reassembly_buf = get_reassembly_buf(conn_handle, false); if (reassembly_buf) { free_reassembly_buf(&reassembly_buf); } } void bt_hci_le_cs_subevent_result_continue(struct net_buf *buf) { struct bt_conn *conn = NULL; struct bt_hci_evt_le_cs_subevent_result_continue *evt; struct net_buf *reassembly_buf = NULL; uint16_t conn_handle; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); conn_handle = sys_le16_to_cpu(evt->conn_handle); #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) if (conn_handle == BT_HCI_LE_CS_TEST_CONN_HANDLE) { if (!cs_test_callbacks.le_cs_test_subevent_data_available) { LOG_WRN("No callback registered. Discarded subevent results from CS Test."); return; } } else #endif /* CONFIG_BT_CHANNEL_SOUNDING_TEST */ { conn = bt_conn_lookup_handle(conn_handle, BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Unknown connection handle when processing subevent results"); return; } } uint16_t step_data_len = evt->num_steps_reported ? buf->len : 0; reassembly_buf = continue_reassembly(conn_handle, evt->steps, step_data_len); if (!reassembly_buf) { goto abort; } reassembled_result.header.procedure_done_status = evt->procedure_done_status; reassembled_result.header.subevent_done_status = evt->subevent_done_status; reassembled_result.header.procedure_abort_reason = evt->procedure_abort_reason; reassembled_result.header.subevent_abort_reason = evt->subevent_abort_reason; if (evt->num_antenna_paths != reassembled_result.header.num_antenna_paths) { LOG_WRN("Received inconsistent number of antenna paths from the controller: %d, " "previous number was: %d", evt->num_antenna_paths, reassembled_result.header.num_antenna_paths); } if (evt->subevent_done_status == BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_ABORTED && reassembled_result.header.num_steps_reported < reassembled_result.header.abort_step) { reassembled_result.header.abort_step = reassembled_result.header.num_steps_reported; } reassembled_result.header.num_steps_reported += evt->num_steps_reported; if (evt->subevent_done_status != BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_PARTIAL) { invoke_subevent_result_callback(conn, &reassembled_result); net_buf_reset(reassembly_buf); reset_reassembly_results(); } if (evt->procedure_done_status != BT_HCI_LE_CS_PROCEDURE_DONE_STATUS_PARTIAL) { if (evt->subevent_done_status == BT_HCI_LE_CS_SUBEVENT_DONE_STATUS_PARTIAL) { LOG_WRN("Procedure status is inconsistent with subevent status. Discarding " "subevent results"); goto abort; } free_reassembly_buf(&reassembly_buf); } if (conn) { bt_conn_unref(conn); conn = NULL; } return; abort: if (conn) { bt_conn_unref(conn); conn = NULL; } if (reassembly_buf) { free_reassembly_buf(&reassembly_buf); } } void bt_hci_le_cs_config_complete_event(struct net_buf *buf) { struct bt_hci_evt_le_cs_config_complete *evt; struct bt_conn_le_cs_config config; struct bt_conn *conn; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("CS Config failed (status 0x%02X)", evt->status); return; } conn = bt_conn_lookup_handle(sys_le16_to_cpu(evt->handle), BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Could not lookup connection handle when reading CS configuration"); return; } if (evt->action == BT_HCI_LE_CS_CONFIG_ACTION_REMOVED) { notify_cs_config_removed(conn, evt->config_id); bt_conn_unref(conn); return; } config.id = evt->config_id; config.main_mode_type = evt->main_mode_type; config.sub_mode_type = evt->sub_mode_type; config.min_main_mode_steps = evt->min_main_mode_steps; config.max_main_mode_steps = evt->max_main_mode_steps; config.main_mode_repetition = evt->main_mode_repetition; config.mode_0_steps = evt->mode_0_steps; config.role = evt->role; config.rtt_type = evt->rtt_type; config.cs_sync_phy = evt->cs_sync_phy; config.channel_map_repetition = evt->channel_map_repetition; config.channel_selection_type = evt->channel_selection_type; config.ch3c_shape = evt->ch3c_shape; config.ch3c_jump = evt->ch3c_jump; config.t_ip1_time_us = evt->t_ip1_time; config.t_ip2_time_us = evt->t_ip2_time; config.t_fcs_time_us = evt->t_fcs_time; config.t_pm_time_us = evt->t_pm_time; memcpy(config.channel_map, evt->channel_map, ARRAY_SIZE(config.channel_map)); notify_cs_config_created(conn, &config); bt_conn_unref(conn); } int bt_le_cs_create_config(struct bt_conn *conn, struct bt_le_cs_create_config_params *params, enum bt_le_cs_create_config_context context) { struct bt_hci_cp_le_cs_create_config *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_CREATE_CONFIG, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->config_id = params->id; cp->create_context = context; cp->main_mode_type = params->main_mode_type; cp->sub_mode_type = params->sub_mode_type; cp->min_main_mode_steps = params->min_main_mode_steps; cp->max_main_mode_steps = params->max_main_mode_steps; cp->main_mode_repetition = params->main_mode_repetition; cp->mode_0_steps = params->mode_0_steps; cp->role = params->role; cp->rtt_type = params->rtt_type; cp->cs_sync_phy = params->cs_sync_phy; cp->channel_map_repetition = params->channel_map_repetition; cp->channel_selection_type = params->channel_selection_type; cp->ch3c_shape = params->ch3c_shape; cp->ch3c_jump = params->ch3c_jump; cp->reserved = 0; memcpy(cp->channel_map, params->channel_map, ARRAY_SIZE(cp->channel_map)); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_CREATE_CONFIG, buf, NULL); } int bt_le_cs_remove_config(struct bt_conn *conn, uint8_t config_id) { struct bt_hci_cp_le_cs_remove_config *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_REMOVE_CONFIG, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->config_id = config_id; return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_REMOVE_CONFIG, buf, NULL); } int bt_le_cs_security_enable(struct bt_conn *conn) { struct bt_hci_cp_le_security_enable *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_SECURITY_ENABLE, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_SECURITY_ENABLE, buf, NULL); } int bt_le_cs_procedure_enable(struct bt_conn *conn, const struct bt_le_cs_procedure_enable_param *params) { struct bt_hci_cp_le_procedure_enable *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_PROCEDURE_ENABLE, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->config_id = params->config_id; cp->enable = params->enable; return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_PROCEDURE_ENABLE, buf, NULL); } int bt_le_cs_set_procedure_parameters(struct bt_conn *conn, const struct bt_le_cs_set_procedure_parameters_param *params) { struct bt_hci_cp_le_set_procedure_parameters *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_SET_PROCEDURE_PARAMETERS, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->config_id = params->config_id; cp->max_procedure_len = sys_cpu_to_le16(params->max_procedure_len); cp->min_procedure_interval = sys_cpu_to_le16(params->min_procedure_interval); cp->max_procedure_interval = sys_cpu_to_le16(params->max_procedure_interval); cp->max_procedure_count = sys_cpu_to_le16(params->max_procedure_count); sys_put_le24(params->min_subevent_len, cp->min_subevent_len); sys_put_le24(params->max_subevent_len, cp->max_subevent_len); cp->tone_antenna_config_selection = params->tone_antenna_config_selection; cp->phy = params->phy; cp->tx_power_delta = params->tx_power_delta; cp->preferred_peer_antenna = params->preferred_peer_antenna; cp->snr_control_initiator = params->snr_control_initiator; cp->snr_control_reflector = params->snr_control_reflector; return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_SET_PROCEDURE_PARAMETERS, buf, NULL); } int bt_le_cs_set_channel_classification(uint8_t channel_classification[10]) { uint8_t *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_SET_CHANNEL_CLASSIFICATION, 10); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, 10); memcpy(cp, channel_classification, 10); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_SET_CHANNEL_CLASSIFICATION, buf, NULL); } int bt_le_cs_read_local_supported_capabilities(struct bt_conn_le_cs_capabilities *ret) { struct bt_hci_rp_le_read_local_supported_capabilities *rp; struct net_buf *rsp; int err = bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_READ_LOCAL_SUPPORTED_CAPABILITIES, NULL, &rsp); if (err) { return err; } rp = (void *)rsp->data; uint8_t status = rp->status; ret->num_config_supported = rp->num_config_supported; ret->max_consecutive_procedures_supported = sys_le16_to_cpu(rp->max_consecutive_procedures_supported); ret->num_antennas_supported = rp->num_antennas_supported; ret->max_antenna_paths_supported = rp->max_antenna_paths_supported; ret->initiator_supported = rp->roles_supported & BT_HCI_LE_CS_INITIATOR_ROLE_MASK; ret->reflector_supported = rp->roles_supported & BT_HCI_LE_CS_REFLECTOR_ROLE_MASK; ret->mode_3_supported = rp->modes_supported & BT_HCI_LE_CS_MODES_SUPPORTED_MODE_3_MASK; ret->rtt_aa_only_n = rp->rtt_aa_only_n; ret->rtt_sounding_n = rp->rtt_sounding_n; ret->rtt_random_payload_n = rp->rtt_random_payload_n; if (rp->rtt_aa_only_n) { if (rp->rtt_capability & BT_HCI_LE_CS_RTT_AA_ONLY_N_10NS_MASK) { ret->rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_10NS; } else { ret->rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_150NS; } } else { ret->rtt_aa_only_precision = BT_CONN_LE_CS_RTT_AA_ONLY_NOT_SUPP; } if (rp->rtt_sounding_n) { if (rp->rtt_capability & BT_HCI_LE_CS_RTT_SOUNDING_N_10NS_MASK) { ret->rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_10NS; } else { ret->rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_150NS; } } else { ret->rtt_sounding_precision = BT_CONN_LE_CS_RTT_SOUNDING_NOT_SUPP; } if (rp->rtt_random_payload_n) { if (rp->rtt_capability & BT_HCI_LE_CS_RTT_RANDOM_PAYLOAD_N_10NS_MASK) { ret->rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_10NS; } else { ret->rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_150NS; } } else { ret->rtt_random_payload_precision = BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_NOT_SUPP; } ret->phase_based_nadm_sounding_supported = sys_le16_to_cpu(rp->nadm_sounding_capability) & BT_HCI_LE_CS_NADM_SOUNDING_CAPABILITY_PHASE_BASED_MASK; ret->phase_based_nadm_random_supported = sys_le16_to_cpu(rp->nadm_random_capability) & BT_HCI_LE_CS_NADM_RANDOM_CAPABILITY_PHASE_BASED_MASK; ret->cs_sync_2m_phy_supported = rp->cs_sync_phys_supported & BT_HCI_LE_CS_SYNC_PHYS_2M_MASK; ret->cs_sync_2m_2bt_phy_supported = rp->cs_sync_phys_supported & BT_HCI_LE_CS_SYNC_PHYS_2M_2BT_MASK; ret->cs_without_fae_supported = sys_le16_to_cpu(rp->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_NO_TX_FAE_MASK; ret->chsel_alg_3c_supported = sys_le16_to_cpu(rp->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_CHSEL_ALG_3C_MASK; ret->pbr_from_rtt_sounding_seq_supported = sys_le16_to_cpu(rp->subfeatures_supported) & BT_HCI_LE_CS_SUBFEATURE_PBR_FROM_RTT_SOUNDING_SEQ_MASK; ret->t_ip1_times_supported = sys_le16_to_cpu(rp->t_ip1_times_supported); ret->t_ip2_times_supported = sys_le16_to_cpu(rp->t_ip2_times_supported); ret->t_fcs_times_supported = sys_le16_to_cpu(rp->t_fcs_times_supported); ret->t_pm_times_supported = sys_le16_to_cpu(rp->t_pm_times_supported); ret->t_sw_time = rp->t_sw_time_supported; ret->tx_snr_capability = rp->tx_snr_capability; net_buf_unref(rsp); return status; } int bt_le_cs_write_cached_remote_supported_capabilities( struct bt_conn *conn, const struct bt_conn_le_cs_capabilities *params) { struct bt_hci_cp_le_write_cached_remote_supported_capabilities *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_WRITE_CACHED_REMOTE_SUPPORTED_CAPABILITIES, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); cp->num_config_supported = params->num_config_supported; cp->max_consecutive_procedures_supported = sys_cpu_to_le16(params->max_consecutive_procedures_supported); cp->num_antennas_supported = params->num_antennas_supported; cp->max_antenna_paths_supported = params->max_antenna_paths_supported; cp->roles_supported = 0; if (params->initiator_supported) { cp->roles_supported |= BT_HCI_LE_CS_INITIATOR_ROLE_MASK; } if (params->reflector_supported) { cp->roles_supported |= BT_HCI_LE_CS_REFLECTOR_ROLE_MASK; } cp->modes_supported = 0; if (params->mode_3_supported) { cp->modes_supported |= BT_HCI_LE_CS_MODES_SUPPORTED_MODE_3_MASK; } cp->rtt_aa_only_n = params->rtt_aa_only_n; cp->rtt_sounding_n = params->rtt_sounding_n; cp->rtt_random_payload_n = params->rtt_random_payload_n; cp->rtt_capability = 0; if (params->rtt_aa_only_precision == BT_CONN_LE_CS_RTT_AA_ONLY_10NS) { cp->rtt_capability |= BT_HCI_LE_CS_RTT_AA_ONLY_N_10NS_MASK; } if (params->rtt_sounding_precision == BT_CONN_LE_CS_RTT_SOUNDING_10NS) { cp->rtt_capability |= BT_HCI_LE_CS_RTT_SOUNDING_N_10NS_MASK; } if (params->rtt_random_payload_precision == BT_CONN_LE_CS_RTT_RANDOM_PAYLOAD_10NS) { cp->rtt_capability |= BT_HCI_LE_CS_RTT_RANDOM_PAYLOAD_N_10NS_MASK; } cp->nadm_sounding_capability = 0; if (params->phase_based_nadm_sounding_supported) { cp->nadm_sounding_capability |= sys_cpu_to_le16(BT_HCI_LE_CS_NADM_SOUNDING_CAPABILITY_PHASE_BASED_MASK); } cp->nadm_random_capability = 0; if (params->phase_based_nadm_random_supported) { cp->nadm_random_capability |= sys_cpu_to_le16(BT_HCI_LE_CS_NADM_RANDOM_CAPABILITY_PHASE_BASED_MASK); } cp->cs_sync_phys_supported = 0; if (params->cs_sync_2m_phy_supported) { cp->cs_sync_phys_supported |= BT_HCI_LE_CS_SYNC_PHYS_2M_MASK; } if (params->cs_sync_2m_2bt_phy_supported) { cp->cs_sync_phys_supported |= BT_HCI_LE_CS_SYNC_PHYS_2M_2BT_MASK; } cp->subfeatures_supported = 0; if (params->cs_without_fae_supported) { cp->subfeatures_supported |= sys_cpu_to_le16(BT_HCI_LE_CS_SUBFEATURE_NO_TX_FAE_MASK); } if (params->chsel_alg_3c_supported) { cp->subfeatures_supported |= sys_cpu_to_le16(BT_HCI_LE_CS_SUBFEATURE_CHSEL_ALG_3C_MASK); } if (params->pbr_from_rtt_sounding_seq_supported) { cp->subfeatures_supported |= sys_cpu_to_le16(BT_HCI_LE_CS_SUBFEATURE_PBR_FROM_RTT_SOUNDING_SEQ_MASK); } cp->t_ip1_times_supported = sys_cpu_to_le16(params->t_ip1_times_supported); cp->t_ip2_times_supported = sys_cpu_to_le16(params->t_ip2_times_supported); cp->t_fcs_times_supported = sys_cpu_to_le16(params->t_fcs_times_supported); cp->t_pm_times_supported = sys_cpu_to_le16(params->t_pm_times_supported); cp->t_sw_time_supported = params->t_sw_time; cp->tx_snr_capability = params->tx_snr_capability; return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_WRITE_CACHED_REMOTE_SUPPORTED_CAPABILITIES, buf, NULL); } int bt_le_cs_write_cached_remote_fae_table(struct bt_conn *conn, int8_t remote_fae_table[72]) { struct bt_hci_cp_le_write_cached_remote_fae_table *cp; struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_WRITE_CACHED_REMOTE_FAE_TABLE, sizeof(*cp)); if (!buf) { return -ENOBUFS; } cp = net_buf_add(buf, sizeof(*cp)); cp->handle = sys_cpu_to_le16(conn->handle); memcpy(cp->remote_fae_table, remote_fae_table, sizeof(cp->remote_fae_table)); return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_WRITE_CACHED_REMOTE_FAE_TABLE, buf, NULL); } void bt_hci_le_cs_security_enable_complete(struct net_buf *buf) { struct bt_conn *conn; struct bt_hci_evt_le_cs_security_enable_complete *evt; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("Security Enable failed with status 0x%02X", evt->status); return; } conn = bt_conn_lookup_handle(sys_le16_to_cpu(evt->handle), BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Can't lookup conn handle when reading Security Enable Complete event"); return; } notify_cs_security_enable_available(conn); bt_conn_unref(conn); } void bt_hci_le_cs_procedure_enable_complete(struct net_buf *buf) { struct bt_conn *conn; struct bt_hci_evt_le_cs_procedure_enable_complete *evt; struct bt_conn_le_cs_procedure_enable_complete params; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("Procedure Enable failed with status 0x%02X", evt->status); return; } conn = bt_conn_lookup_handle(sys_le16_to_cpu(evt->handle), BT_CONN_TYPE_LE); if (!conn) { LOG_ERR("Can't lookup conn handle when reading Procedure Enable Complete event"); return; } if (evt->state == BT_HCI_OP_LE_CS_PROCEDURES_DISABLED) { struct net_buf *reassembly_buf = get_reassembly_buf(conn->handle, false); if (reassembly_buf) { LOG_WRN("De-allocating a dangling reassembly buffer"); free_reassembly_buf(&reassembly_buf); } } params.config_id = evt->config_id; params.state = evt->state; params.tone_antenna_config_selection = evt->tone_antenna_config_selection; params.selected_tx_power = evt->selected_tx_power; params.subevent_len = sys_get_le24(evt->subevent_len); params.subevents_per_event = evt->subevents_per_event; params.subevent_interval = sys_le16_to_cpu(evt->subevent_interval); params.event_interval = sys_le16_to_cpu(evt->event_interval); params.procedure_interval = sys_le16_to_cpu(evt->procedure_interval); params.procedure_count = sys_le16_to_cpu(evt->procedure_count); params.max_procedure_len = sys_le16_to_cpu(evt->max_procedure_len); notify_cs_procedure_enable_available(conn, ¶ms); bt_conn_unref(conn); } #if defined(CONFIG_BT_CHANNEL_SOUNDING_TEST) int bt_le_cs_stop_test(void) { struct net_buf *buf; buf = bt_hci_cmd_create(BT_HCI_OP_LE_CS_TEST_END, 0); if (!buf) { return -ENOBUFS; } return bt_hci_cmd_send_sync(BT_HCI_OP_LE_CS_TEST_END, buf, NULL); } void bt_hci_le_cs_test_end_complete(struct net_buf *buf) { struct bt_hci_evt_le_cs_test_end_complete *evt; if (buf->len < sizeof(*evt)) { LOG_ERR("Unexpected end of buffer"); return; } evt = net_buf_pull_mem(buf, sizeof(*evt)); if (evt->status) { LOG_WRN("CS Test End failed with status 0x%02X", evt->status); return; } struct net_buf *reassembly_buf = get_reassembly_buf(BT_HCI_LE_CS_TEST_CONN_HANDLE, false); if (reassembly_buf) { LOG_WRN("De-allocating a dangling reassembly buffer"); free_reassembly_buf(&reassembly_buf); } if (cs_test_callbacks.le_cs_test_end_complete) { cs_test_callbacks.le_cs_test_end_complete(); } } #endif /* CONFIG_BT_CHANNEL_SOUNDING_TEST */ void bt_le_cs_step_data_parse(struct net_buf_simple *step_data_buf, bool (*func)(struct bt_le_cs_subevent_step *step, void *user_data), void *user_data) { if (!step_data_buf) { LOG_INF("Tried to parse empty step data."); return; } while (step_data_buf->len > 1) { struct bt_le_cs_subevent_step step; step.mode = net_buf_simple_pull_u8(step_data_buf); step.channel = net_buf_simple_pull_u8(step_data_buf); step.data_len = net_buf_simple_pull_u8(step_data_buf); if (step.data_len == 0) { LOG_WRN("Encountered zero-length step data."); return; } step.data = step_data_buf->data; if (step.data_len > step_data_buf->len) { LOG_WRN("Step data appears malformed."); return; } if (!func(&step, user_data)) { return; } net_buf_simple_pull(step_data_buf, step.data_len); } } #endif /* CONFIG_BT_CHANNEL_SOUNDING */