/** **************************************************************************************** * @addtogroup HTPTTASK * @{ **************************************************************************************** */ /* * INCLUDE FILES **************************************************************************************** */ #include "rwip_config.h" #if (BLE_HT_THERMOM) #include "gap.h" #include "gattc_task.h" #include "attm.h" #include "htpt.h" #include "htpt_task.h" #include "prf_utils.h" #include "ke_mem.h" #include "co_utils.h" /* * FUNCTION DEFINITIONS **************************************************************************************** */ /** **************************************************************************************** * @brief Handles reception of the @ref HTPT_ENABLE_REQ message. * The handler enables the Health Thermometer Profile Thermometer Role. * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int htpt_enable_req_handler(ke_msg_id_t const msgid, struct htpt_enable_req const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { uint8_t status = PRF_ERR_REQ_DISALLOWED; // check state of the task if(gapc_get_conhdl(param->conidx) != GAP_INVALID_CONHDL) { // restore Bond Data struct htpt_env_tag* htpt_env = PRF_ENV_GET(HTPT, htpt); htpt_env->ntf_ind_cfg[param->conidx] = param->ntf_ind_cfg; status = GAP_ERR_NO_ERROR; } // send response struct htpt_enable_rsp *rsp = KE_MSG_ALLOC(HTPT_ENABLE_RSP, src_id, dest_id, htpt_enable_rsp); rsp->conidx = param->conidx; rsp->status = status; ke_msg_send(rsp); return (KE_MSG_CONSUMED); } /** **************************************************************************************** * @brief Handles reception of the @ref HTPT_TEMP_SEND_REQ message. * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int htpt_temp_send_req_handler(ke_msg_id_t const msgid, struct htpt_temp_send_req const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { // Status int msg_status = KE_MSG_SAVED; uint8_t state = ke_state_get(dest_id); // check state of the task if(state == HTPT_IDLE) { // Get the address of the environment struct htpt_env_tag *htpt_env = PRF_ENV_GET(HTPT, htpt); // for intermediate measurement, feature must be enabled if(!(param->stable_meas) && (!HTPT_IS_FEATURE_SUPPORTED(htpt_env->features, HTPT_INTERM_TEMP_CHAR_SUP))) { struct htpt_temp_send_rsp *rsp = KE_MSG_ALLOC(HTPT_TEMP_SEND_RSP, src_id, dest_id, htpt_temp_send_rsp); rsp->status = PRF_ERR_FEATURE_NOT_SUPPORTED; ke_msg_send(rsp); } else { // allocate operation to execute htpt_env->operation = (struct htpt_op *) ke_malloc(sizeof(struct htpt_op) + HTPT_TEMP_MEAS_MAX_LEN, KE_MEM_ATT_DB); // Initialize operation parameters htpt_env->operation->cursor = 0; htpt_env->operation->dest_id = src_id; htpt_env->operation->conidx = GAP_INVALID_CONIDX; // Stable measurement indication or intermediate measurement notification if(param->stable_meas) { htpt_env->operation->op = HTPT_CFG_STABLE_MEAS_IND; htpt_env->operation->handle = HTPT_HANDLE(HTS_IDX_TEMP_MEAS_VAL); } else { htpt_env->operation->op = HTPT_CFG_INTERM_MEAS_NTF; htpt_env->operation->handle = HTPT_HANDLE(HTS_IDX_INTERM_TEMP_VAL); } //Pack the temperature measurement value htpt_env->operation->length = htpt_pack_temp_value(&(htpt_env->operation->data[0]), param->temp_meas); // put task in a busy state ke_state_set(dest_id, HTPT_BUSY); // execute operation htpt_exe_operation(); } msg_status = KE_MSG_CONSUMED; } return (msg_status); } /** **************************************************************************************** * @brief Request to update Measurement Interval Value * @param[in] msgid Id of the message received. * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int htpt_meas_intv_upd_req_handler(ke_msg_id_t const msgid, struct htpt_meas_intv_upd_req const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { int msg_status = KE_MSG_SAVED; uint8_t state = ke_state_get(dest_id); // check state of the task if(state == HTPT_IDLE) { // Get the address of the environment struct htpt_env_tag *htpt_env = PRF_ENV_GET(HTPT, htpt); // update measurement interval htpt_env->meas_intv = param->meas_intv; //Check if Measurement Interval indication is supported if(!HTPT_IS_FEATURE_SUPPORTED(htpt_env->features, HTPT_MEAS_INTV_CHAR_SUP)) { struct htpt_meas_intv_upd_rsp *rsp = KE_MSG_ALLOC(HTPT_MEAS_INTV_UPD_RSP, src_id, dest_id, htpt_meas_intv_upd_rsp); rsp->status = PRF_ERR_FEATURE_NOT_SUPPORTED; ke_msg_send(rsp); } else { // update internal measurement interval value htpt_env->meas_intv = param->meas_intv; // no indication to trigger if(!HTPT_IS_FEATURE_SUPPORTED(htpt_env->features, HTPT_MEAS_INTV_IND_SUP)) { struct htpt_meas_intv_upd_rsp *rsp = KE_MSG_ALLOC(HTPT_MEAS_INTV_UPD_RSP, src_id, dest_id, htpt_meas_intv_upd_rsp); rsp->status = GAP_ERR_NO_ERROR; ke_msg_send(rsp); } // trigger measurement update indication else { // allocate operation to execute htpt_env->operation = (struct htpt_op *) ke_malloc(sizeof(struct htpt_op) + HTPT_MEAS_INTV_MAX_LEN, KE_MEM_ATT_DB); // Initialize operation parameters htpt_env->operation->op = HTPT_CFG_MEAS_INTV_IND; htpt_env->operation->handle = HTPT_HANDLE(HTS_IDX_MEAS_INTV_VAL); htpt_env->operation->dest_id = src_id; htpt_env->operation->cursor = 0; htpt_env->operation->conidx = GAP_INVALID_CONIDX; // Pack the interval value htpt_env->operation->length = HTPT_MEAS_INTV_MAX_LEN; co_write16p(htpt_env->operation->data, param->meas_intv); // put task in a busy state ke_state_set(dest_id, HTPT_BUSY); // execute operation htpt_exe_operation(); } } msg_status = KE_MSG_CONSUMED; } return (msg_status); } /** **************************************************************************************** * @brief Handles reception of the attribute info request message. * * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int gattc_att_info_req_ind_handler(ke_msg_id_t const msgid, struct gattc_att_info_req_ind *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { struct htpt_env_tag* htpt_env = PRF_ENV_GET(HTPT, htpt); uint8_t att_idx = HTPT_IDX(param->handle); struct gattc_att_info_cfm * cfm; //Send write response cfm = KE_MSG_ALLOC(GATTC_ATT_INFO_CFM, src_id, dest_id, gattc_att_info_cfm); cfm->handle = param->handle; switch(att_idx) { case HTS_IDX_MEAS_INTV_VAL: { // force length to zero to reject any write starting from something != 0 cfm->length = 0; cfm->status = GAP_ERR_NO_ERROR; }break; case HTS_IDX_TEMP_MEAS_IND_CFG: case HTS_IDX_INTERM_TEMP_CFG: case HTS_IDX_MEAS_INTV_CFG: { cfm->length = HTPT_IND_NTF_CFG_MAX_LEN; cfm->status = GAP_ERR_NO_ERROR; }break; default: { cfm->status = ATT_ERR_REQUEST_NOT_SUPPORTED; }break; } ke_msg_send(cfm); return (KE_MSG_CONSUMED); } /** **************************************************************************************** * @brief Handles reception of the @ref GL2C_CODE_ATT_WR_CMD_IND message. * The handler compares the new values with current ones and notifies them if they changed. * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int gattc_write_req_ind_handler(ke_msg_id_t const msgid, struct gattc_write_req_ind const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { struct htpt_env_tag* htpt_env = PRF_ENV_GET(HTPT, htpt); uint8_t conidx = KE_IDX_GET(src_id); uint8_t status = ATT_ERR_NO_ERROR; int msg_status = KE_MSG_CONSUMED; // to check if confirmation message should be send bool send_cfm = true; // retrieve handle information uint8_t att_idx = HTPT_IDX(param->handle); if(param->length != HTPT_MEAS_INTV_MAX_LEN) { status = PRF_ERR_UNEXPECTED_LEN; } else { switch(att_idx) { case HTS_IDX_MEAS_INTV_VAL: { uint16_t meas_intv = co_read16p(param->value); // check measurement length validity if(((meas_intv >= htpt_env->meas_intv_min) && (meas_intv <= htpt_env->meas_intv_max)) // notification can be disabled anyway || (meas_intv == 0)) { uint8_t state = ke_state_get(dest_id); send_cfm = false; // check state of the task to know if it can be proceed immediately if(state == HTPT_IDLE) { // inform application that update of measurement interval is requested by peer device. struct htpt_meas_intv_chg_req_ind * req_ind = KE_MSG_ALLOC(HTPT_MEAS_INTV_CHG_REQ_IND, prf_dst_task_get(&htpt_env->prf_env, conidx), dest_id, htpt_meas_intv_chg_req_ind); req_ind->conidx = conidx; req_ind->intv = meas_intv; ke_msg_send(req_ind); // allocate operation to execute htpt_env->operation = (struct htpt_op *) ke_malloc(sizeof(struct htpt_op) + HTPT_MEAS_INTV_MAX_LEN, KE_MEM_ATT_DB); // Initialize operation parameters htpt_env->operation->op = HTPT_CFG_MEAS_INTV_IND; htpt_env->operation->handle = HTPT_HANDLE(HTS_IDX_MEAS_INTV_VAL); htpt_env->operation->dest_id = dest_id; htpt_env->operation->conidx = conidx; // to be sure that no notification will be triggered htpt_env->operation->cursor = 0xFF; // Pack the interval value htpt_env->operation->length = HTPT_MEAS_INTV_MAX_LEN; co_write16p(htpt_env->operation->data, meas_intv); // put task in a busy state ke_state_set(dest_id, HTPT_BUSY); } else { msg_status = KE_MSG_SAVED; } } else { // value not in expected range status = HTP_OUT_OF_RANGE_ERR_CODE; } }break; case HTS_IDX_TEMP_MEAS_IND_CFG: { status = htpt_update_ntf_ind_cfg(conidx, HTPT_CFG_STABLE_MEAS_IND, PRF_CLI_START_IND, co_read16p(param->value)); }break; case HTS_IDX_INTERM_TEMP_CFG: { status = htpt_update_ntf_ind_cfg(conidx, HTPT_CFG_INTERM_MEAS_NTF, PRF_CLI_START_NTF, co_read16p(param->value)); }break; case HTS_IDX_MEAS_INTV_CFG: { status = htpt_update_ntf_ind_cfg(conidx, HTPT_CFG_MEAS_INTV_IND, PRF_CLI_START_IND, co_read16p(param->value)); }break; default: { status = ATT_ERR_REQUEST_NOT_SUPPORTED; }break; } } if(send_cfm) { //Send write response struct gattc_write_cfm * cfm = KE_MSG_ALLOC(GATTC_WRITE_CFM, src_id, dest_id, gattc_write_cfm); cfm->handle = param->handle; cfm->status = status; ke_msg_send(cfm); } return (msg_status); } /** **************************************************************************************** * @brief Handles reception of the @ref GATTC_READ_REQ_IND message. * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int gattc_read_req_ind_handler(ke_msg_id_t const msgid, struct gattc_write_req_ind const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { struct htpt_env_tag* htpt_env = PRF_ENV_GET(HTPT, htpt); uint8_t conidx = KE_IDX_GET(src_id); uint8_t value[HTPT_MEAS_INTV_RANGE_MAX_LEN]; uint8_t value_size = 0; uint8_t status = ATT_ERR_NO_ERROR; // retrieve handle information uint8_t att_idx = HTPT_IDX(param->handle); switch(att_idx) { case HTS_IDX_MEAS_INTV_VAL: { value_size = HTPT_MEAS_INTV_MAX_LEN; co_write16p(&(value[0]), htpt_env->meas_intv); }break; case HTS_IDX_MEAS_INTV_VAL_RANGE: { value_size = HTPT_MEAS_INTV_RANGE_MAX_LEN; co_write16p(&(value[0]), htpt_env->meas_intv_min); co_write16p(&(value[2]), htpt_env->meas_intv_max); }break; case HTS_IDX_TEMP_MEAS_IND_CFG: { value_size = HTPT_IND_NTF_CFG_MAX_LEN; co_write16p(value, ((htpt_env->ntf_ind_cfg[conidx] & HTPT_CFG_STABLE_MEAS_IND) != 0) ? PRF_CLI_START_IND : PRF_CLI_STOP_NTFIND); }break; case HTS_IDX_INTERM_TEMP_CFG: { value_size = HTPT_IND_NTF_CFG_MAX_LEN; co_write16p(value, ((htpt_env->ntf_ind_cfg[conidx] & HTPT_CFG_INTERM_MEAS_NTF) != 0) ? PRF_CLI_START_NTF : PRF_CLI_STOP_NTFIND); }break; case HTS_IDX_MEAS_INTV_CFG: { value_size = HTPT_IND_NTF_CFG_MAX_LEN; co_write16p(value, ((htpt_env->ntf_ind_cfg[conidx] & HTPT_CFG_MEAS_INTV_IND) != 0) ? PRF_CLI_START_IND : PRF_CLI_STOP_NTFIND); }break; case HTS_IDX_TEMP_TYPE_VAL: { value_size = HTPT_TEMP_TYPE_MAX_LEN; value[0] = htpt_env->temp_type; }break; default: { status = ATT_ERR_REQUEST_NOT_SUPPORTED; }break; } // Send data to peer device struct gattc_read_cfm* cfm = KE_MSG_ALLOC_DYN(GATTC_READ_CFM, src_id, dest_id, gattc_read_cfm, value_size); cfm->length = value_size; memcpy(cfm->value, value, value_size); cfm->handle = param->handle; cfm->status = status; // Send value to peer device. ke_msg_send(cfm); return (KE_MSG_CONSUMED); } /** **************************************************************************************** * @brief Handles reception of the @ref HTPT_MEAS_INTV_UPD_CFM message. * @param[in] msgid Id of the message received (probably unused). * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance (probably unused). * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int htpt_meas_intv_chg_cfm_handler(ke_msg_id_t const msgid, struct htpt_meas_intv_chg_cfm const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { struct htpt_env_tag* htpt_env = PRF_ENV_GET(HTPT, htpt); uint8_t state = ke_state_get(dest_id); // check state of the task if(state == HTPT_BUSY) { // retrieve connection index from operation uint8_t conidx = htpt_env->operation->conidx; //Send write response struct gattc_write_cfm * cfm = KE_MSG_ALLOC(GATTC_WRITE_CFM, KE_BUILD_ID(TASK_GATTC, conidx), dest_id, gattc_write_cfm); cfm->handle = HTPT_HANDLE(HTS_IDX_MEAS_INTV_VAL); cfm->status = (param->conidx == conidx) ? param->status : PRF_APP_ERROR; ke_msg_send(cfm); // check if no error occurs if(cfm->status == GAP_ERR_NO_ERROR) { // update the current measurement interval htpt_env->meas_intv = co_read16p(htpt_env->operation->data); // check if an indication of new measurement interval should be triggered if(HTPT_IS_FEATURE_SUPPORTED(htpt_env->features, HTPT_MEAS_INTV_IND_SUP)) { // set back cursor to zero in order to send indication htpt_env->operation->cursor = 0; } } // send indication or terminate operation htpt_exe_operation(); } return (KE_MSG_CONSUMED); } /** **************************************************************************************** * @brief Handles @ref GATTC_CMP_EVT for GATTC_NOTIFY and GATT_INDICATE message meaning * that Measurement notification/indication has been correctly sent to peer device * * * @param[in] msgid Id of the message received. * @param[in] param Pointer to the parameters of the message. * @param[in] dest_id ID of the receiving task instance * @param[in] src_id ID of the sending task instance. * @return If the message was consumed or not. **************************************************************************************** */ __STATIC int gattc_cmp_evt_handler(ke_msg_id_t const msgid, struct gattc_cmp_evt const *param, ke_task_id_t const dest_id, ke_task_id_t const src_id) { // continue operation execution htpt_exe_operation(); return (KE_MSG_CONSUMED); } /* * GLOBAL VARIABLE DEFINITIONS **************************************************************************************** */ /// Default State handlers definition KE_MSG_HANDLER_TAB(htpt) { {HTPT_ENABLE_REQ, (ke_msg_func_t) htpt_enable_req_handler}, {GATTC_ATT_INFO_REQ_IND, (ke_msg_func_t) gattc_att_info_req_ind_handler}, {GATTC_WRITE_REQ_IND, (ke_msg_func_t) gattc_write_req_ind_handler}, {GATTC_READ_REQ_IND, (ke_msg_func_t) gattc_read_req_ind_handler}, {GATTC_CMP_EVT, (ke_msg_func_t) gattc_cmp_evt_handler}, {HTPT_TEMP_SEND_REQ, (ke_msg_func_t) htpt_temp_send_req_handler}, {HTPT_MEAS_INTV_UPD_REQ, (ke_msg_func_t) htpt_meas_intv_upd_req_handler}, {HTPT_MEAS_INTV_CHG_CFM, (ke_msg_func_t) htpt_meas_intv_chg_cfm_handler}, }; void htpt_task_init(struct ke_task_desc *task_desc) { BLE_PRF_HP_FUNC_ENTER(); // Get the address of the environment struct htpt_env_tag *htpt_env = PRF_ENV_GET(HTPT, htpt); task_desc->msg_handler_tab = htpt_msg_handler_tab; task_desc->msg_cnt = ARRAY_LEN(htpt_msg_handler_tab); task_desc->state = htpt_env->state; task_desc->idx_max = HTPT_IDX_MAX; BLE_PRF_HP_FUNC_LEAVE(); } #endif //BLE_HT_THERMOM /// @} HTPTTASK