/* * Copyright (C) 2014 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "sync.h" #include #include #include "wifi_hal.h" #include "nan_i.h" #include "nancommand.h" #include //Function which calls the necessaryIndication callback //based on the indication type int NanCommand::handleNanIndication() { //Based on the message_id in the header determine the Indication type //and call the necessary callback handler u16 msg_id; int res = 0; msg_id = getIndicationType(); ALOGV("handleNanIndication msg_id:%u", msg_id); switch (msg_id) { case NAN_INDICATION_PUBLISH_REPLIED: NanPublishRepliedInd publishRepliedInd; memset(&publishRepliedInd, 0, sizeof(publishRepliedInd)); res = getNanPublishReplied(&publishRepliedInd); if (!res && mHandler.EventPublishReplied) { (*mHandler.EventPublishReplied)(&publishRepliedInd); } break; case NAN_INDICATION_PUBLISH_TERMINATED: NanPublishTerminatedInd publishTerminatedInd; memset(&publishTerminatedInd, 0, sizeof(publishTerminatedInd)); res = getNanPublishTerminated(&publishTerminatedInd); if (!res && mHandler.EventPublishTerminated) { (*mHandler.EventPublishTerminated)(&publishTerminatedInd); } break; case NAN_INDICATION_MATCH: NanMatchInd matchInd; memset(&matchInd, 0, sizeof(matchInd)); res = getNanMatch(&matchInd); if (!res && mHandler.EventMatch) { (*mHandler.EventMatch)(&matchInd); } break; case NAN_INDICATION_MATCH_EXPIRED: NanMatchExpiredInd matchExpiredInd; memset(&matchExpiredInd, 0, sizeof(matchExpiredInd)); res = getNanMatchExpired(&matchExpiredInd); if (!res && mHandler.EventMatchExpired) { (*mHandler.EventMatchExpired)(&matchExpiredInd); } break; case NAN_INDICATION_SUBSCRIBE_TERMINATED: NanSubscribeTerminatedInd subscribeTerminatedInd; memset(&subscribeTerminatedInd, 0, sizeof(subscribeTerminatedInd)); res = getNanSubscribeTerminated(&subscribeTerminatedInd); if (!res && mHandler.EventSubscribeTerminated) { (*mHandler.EventSubscribeTerminated)(&subscribeTerminatedInd); } break; case NAN_INDICATION_DE_EVENT: NanDiscEngEventInd discEngEventInd; memset(&discEngEventInd, 0, sizeof(discEngEventInd)); res = getNanDiscEngEvent(&discEngEventInd); if (!res && mHandler.EventDiscEngEvent) { (*mHandler.EventDiscEngEvent)(&discEngEventInd); } break; case NAN_INDICATION_FOLLOWUP: NanFollowupInd followupInd; memset(&followupInd, 0, sizeof(followupInd)); res = getNanFollowup(&followupInd); if (!res && mHandler.EventFollowup) { (*mHandler.EventFollowup)(&followupInd); } break; case NAN_INDICATION_DISABLED: NanDisabledInd disabledInd; memset(&disabledInd, 0, sizeof(disabledInd)); res = getNanDisabled(&disabledInd); if (!res && mHandler.EventDisabled) { (*mHandler.EventDisabled)(&disabledInd); } break; case NAN_INDICATION_TCA: NanTCAInd tcaInd; memset(&tcaInd, 0, sizeof(tcaInd)); res = getNanTca(&tcaInd); if (!res && mHandler.EventTca) { (*mHandler.EventTca)(&tcaInd); } break; case NAN_INDICATION_BEACON_SDF_PAYLOAD: NanBeaconSdfPayloadInd beaconSdfPayloadInd; memset(&beaconSdfPayloadInd, 0, sizeof(beaconSdfPayloadInd)); res = getNanBeaconSdfPayload(&beaconSdfPayloadInd); if (!res && mHandler.EventBeaconSdfPayload) { (*mHandler.EventBeaconSdfPayload)(&beaconSdfPayloadInd); } break; case NAN_INDICATION_SELF_TRANSMIT_FOLLOWUP: NanTransmitFollowupInd transmitFollowupInd; memset(&transmitFollowupInd, 0, sizeof(NanTransmitFollowupInd)); res = getNanTransmitFollowupInd(&transmitFollowupInd); if (!res && mHandler.EventTransmitFollowup) { (*mHandler.EventTransmitFollowup)(&transmitFollowupInd); } break; case NAN_INDICATION_RANGING_REQUEST_RECEIVED: NanRangeRequestInd rangeRequestInd; memset(&rangeRequestInd, 0, sizeof(NanRangeRequestInd)); res = getNanRangeRequestReceivedInd(&rangeRequestInd); if (!res && mHandler.EventRangeRequest) { (*mHandler.EventRangeRequest)(&rangeRequestInd); } break; case NAN_INDICATION_RANGING_RESULT: NanRangeReportInd rangeReportInd; memset(&rangeReportInd, 0, sizeof(NanRangeReportInd)); res = getNanRangeReportInd(&rangeReportInd); if (!res && mHandler.EventRangeReport) { (*mHandler.EventRangeReport)(&rangeReportInd); } break; default: ALOGE("handleNanIndication error invalid msg_id:%u", msg_id); res = (int)WIFI_ERROR_INVALID_REQUEST_ID; break; } return res; } //Function which will return the Nan Indication type based on //the initial few bytes of mNanVendorEvent NanIndicationType NanCommand::getIndicationType() { if (mNanVendorEvent == NULL) { ALOGE("%s: Invalid argument mNanVendorEvent:%p", __func__, mNanVendorEvent); return NAN_INDICATION_UNKNOWN; } NanMsgHeader *pHeader = (NanMsgHeader *)mNanVendorEvent; switch (pHeader->msgId) { case NAN_MSG_ID_PUBLISH_REPLIED_IND: return NAN_INDICATION_PUBLISH_REPLIED; case NAN_MSG_ID_PUBLISH_TERMINATED_IND: return NAN_INDICATION_PUBLISH_TERMINATED; case NAN_MSG_ID_MATCH_IND: return NAN_INDICATION_MATCH; case NAN_MSG_ID_MATCH_EXPIRED_IND: return NAN_INDICATION_MATCH_EXPIRED; case NAN_MSG_ID_FOLLOWUP_IND: return NAN_INDICATION_FOLLOWUP; case NAN_MSG_ID_SUBSCRIBE_TERMINATED_IND: return NAN_INDICATION_SUBSCRIBE_TERMINATED; case NAN_MSG_ID_DE_EVENT_IND: return NAN_INDICATION_DE_EVENT; case NAN_MSG_ID_DISABLE_IND: return NAN_INDICATION_DISABLED; case NAN_MSG_ID_TCA_IND: return NAN_INDICATION_TCA; case NAN_MSG_ID_BEACON_SDF_IND: return NAN_INDICATION_BEACON_SDF_PAYLOAD; case NAN_MSG_ID_SELF_TRANSMIT_FOLLOWUP_IND: return NAN_INDICATION_SELF_TRANSMIT_FOLLOWUP; case NAN_MSG_ID_RANGING_REQUEST_RECEVD_IND: return NAN_INDICATION_RANGING_REQUEST_RECEIVED; case NAN_MSG_ID_RANGING_RESULT_IND: return NAN_INDICATION_RANGING_RESULT; default: return NAN_INDICATION_UNKNOWN; } } int NanCommand::getNanPublishReplied(NanPublishRepliedInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanPublishRepliedIndMsg pRsp = (pNanPublishRepliedIndMsg)mNanVendorEvent; event->requestor_instance_id = pRsp->publishRepliedIndParams.matchHandle; event->rssi_value = 0; u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); if (remainingLen <= 0) { ALOGI("%s: No TLV's present",__func__); return WIFI_SUCCESS; } while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { switch (outputTlv.type) { case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > sizeof(event->addr)) { outputTlv.length = sizeof(event->addr); } memcpy(event->addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_RECEIVED_RSSI_VALUE: if (outputTlv.length > sizeof(event->rssi_value)) { outputTlv.length = sizeof(event->rssi_value); } memcpy(&event->rssi_value, outputTlv.value, outputTlv.length); break; default: ALOGI("Unknown TLV type skipped"); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv, 0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanPublishTerminated(NanPublishTerminatedInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanPublishTerminatedIndMsg pRsp = (pNanPublishTerminatedIndMsg)mNanVendorEvent; event->publish_id = pRsp->fwHeader.handle; NanErrorTranslation((NanInternalStatusType)pRsp->reason, 0, (void*)event, false); return WIFI_SUCCESS; } int NanCommand::getNanMatch(NanMatchInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanMatchIndMsg pRsp = (pNanMatchIndMsg)mNanVendorEvent; event->publish_subscribe_id = pRsp->fwHeader.handle; event->requestor_instance_id = pRsp->matchIndParams.matchHandle; event->match_occured_flag = pRsp->matchIndParams.matchOccuredFlag; event->out_of_resource_flag = pRsp->matchIndParams.outOfResourceFlag; u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader) + sizeof(NanMatchIndParams))); int ret = 0, idx = 0; //Has SDF match filter and service specific info TLV if (remainingLen <= 0) { ALOGV("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_SERVICE_SPECIFIC_INFO: if (outputTlv.length > NAN_MAX_SERVICE_NAME_LEN) { outputTlv.length = NAN_MAX_SERVICE_NAME_LEN; } event->service_specific_info_len = outputTlv.length; memcpy(event->service_specific_info, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_SDF_MATCH_FILTER: if (outputTlv.length > NAN_MAX_MATCH_FILTER_LEN) { outputTlv.length = NAN_MAX_MATCH_FILTER_LEN; } event->sdf_match_filter_len = outputTlv.length; memcpy(event->sdf_match_filter, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > sizeof(event->addr)) { outputTlv.length = sizeof(event->addr); } memcpy(event->addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_RECEIVED_RSSI_VALUE: if (outputTlv.length > sizeof(event->rssi_value)) { outputTlv.length = sizeof(event->rssi_value); } memcpy(&event->rssi_value, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_POST_NAN_CONNECTIVITY_CAPABILITIES_RECEIVE: if (outputTlv.length != sizeof(u32)) { ALOGE("NAN_TLV_TYPE_POST_NAN_CONNECTIVITY_CAPABILITIES_RECEIVE" "Incorrect size:%d expecting %zu", outputTlv.length, sizeof(u32)); break; } event->is_conn_capability_valid = 1; /* Populate conn_capability from received TLV */ getNanReceivePostConnectivityCapabilityVal(outputTlv.value, &event->conn_capability); break; case NAN_TLV_TYPE_POST_NAN_DISCOVERY_ATTRIBUTE_RECEIVE: /* Populate receive discovery attribute from received TLV */ idx = event->num_rx_discovery_attr; if (idx < 0 || idx >= NAN_MAX_POSTDISCOVERY_LEN) { ALOGE("NAN_TLV_TYPE_POST_NAN_DISCOVERY_ATTRIBUTE_RECEIVE" " Incorrect index:%d >= %d", idx, NAN_MAX_POSTDISCOVERY_LEN); break; } ret = getNanReceivePostDiscoveryVal(outputTlv.value, outputTlv.length, &event->discovery_attr[idx]); if (ret == 0) { event->num_rx_discovery_attr++; } else { ALOGE("NAN_TLV_TYPE_POST_NAN_DISCOVERY_ATTRIBUTE_RECEIVE" "Incorrect"); } break; case NAN_TLV_TYPE_FURTHER_AVAILABILITY_MAP: /* Populate further availability bitmap from received TLV */ ret = getNanFurtherAvailabilityMap(outputTlv.value, outputTlv.length, &event->num_chans, &event->famchan[0]); if (ret < 0) ALOGE("NAN_TLV_TYPE_FURTHER_AVAILABILITY_MAP" "Incorrect"); break; case NAN_TLV_TYPE_CLUSTER_ATTRIBUTE: if (outputTlv.length > sizeof(event->cluster_attribute)) { outputTlv.length = sizeof(event->cluster_attribute); } memcpy(event->cluster_attribute, outputTlv.value, outputTlv.length); event->cluster_attribute_len = outputTlv.length; break; case NAN_TLV_TYPE_NAN_CSID: if (outputTlv.length > sizeof(event->peer_cipher_type)) { outputTlv.length = sizeof(event->peer_cipher_type); } memcpy(&event->peer_cipher_type, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_NAN_SCID: if (outputTlv.length > sizeof(event->scid)) { outputTlv.length = sizeof(event->scid); } event->scid_len = outputTlv.length; memcpy(event->scid, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_SDEA_CTRL_PARAMS: if (outputTlv.length != sizeof(u32)) { ALOGE("NAN_TLV_TYPE_SDEA_CTRL_PARAMS" "Incorrect size:%d expecting %zu", outputTlv.length, sizeof(u32)); break; } getNanReceiveSdeaCtrlParams(outputTlv.value, &event->peer_sdea_params); break; case NAN_TLV_TYPE_NAN20_RANGING_RESULT: if (outputTlv.length > sizeof(event->range_info)) { outputTlv.length = sizeof(event->range_info); } memcpy(&event->range_info, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_SDEA_SERVICE_SPECIFIC_INFO: if (outputTlv.length > NAN_MAX_SDEA_SERVICE_SPECIFIC_INFO_LEN) { outputTlv.length = NAN_MAX_SDEA_SERVICE_SPECIFIC_INFO_LEN; } event->sdea_service_specific_info_len = outputTlv.length; memcpy(event->sdea_service_specific_info, outputTlv.value, outputTlv.length); break; default: ALOGV("Unknown TLV type skipped"); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv, 0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanMatchExpired(NanMatchExpiredInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanMatchExpiredIndMsg pRsp = (pNanMatchExpiredIndMsg)mNanVendorEvent; event->publish_subscribe_id = pRsp->fwHeader.handle; event->requestor_instance_id = pRsp->matchExpiredIndParams.matchHandle; return WIFI_SUCCESS; } int NanCommand::getNanSubscribeTerminated(NanSubscribeTerminatedInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanSubscribeTerminatedIndMsg pRsp = (pNanSubscribeTerminatedIndMsg)mNanVendorEvent; event->subscribe_id = pRsp->fwHeader.handle; NanErrorTranslation((NanInternalStatusType)pRsp->reason, 0, (void*)event, false); return WIFI_SUCCESS; } int NanCommand::getNanFollowup(NanFollowupInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanFollowupIndMsg pRsp = (pNanFollowupIndMsg)mNanVendorEvent; event->publish_subscribe_id = pRsp->fwHeader.handle; event->requestor_instance_id = pRsp->followupIndParams.matchHandle; event->dw_or_faw = pRsp->followupIndParams.window; u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader) + sizeof(NanFollowupIndParams))); //Has service specific info and extended service specific info TLV if (remainingLen <= 0) { ALOGV("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_SERVICE_SPECIFIC_INFO: case NAN_TLV_TYPE_EXT_SERVICE_SPECIFIC_INFO: if (outputTlv.length > NAN_MAX_SERVICE_SPECIFIC_INFO_LEN) { outputTlv.length = NAN_MAX_SERVICE_SPECIFIC_INFO_LEN; } event->service_specific_info_len = outputTlv.length; memcpy(event->service_specific_info, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > sizeof(event->addr)) { outputTlv.length = sizeof(event->addr); } memcpy(event->addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_SDEA_SERVICE_SPECIFIC_INFO: if (outputTlv.length > NAN_MAX_SDEA_SERVICE_SPECIFIC_INFO_LEN) { outputTlv.length = NAN_MAX_SDEA_SERVICE_SPECIFIC_INFO_LEN; } event->sdea_service_specific_info_len = outputTlv.length; memcpy(event->sdea_service_specific_info, outputTlv.value, outputTlv.length); break; default: ALOGV("Unknown TLV type skipped"); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv, 0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanDiscEngEvent(NanDiscEngEventInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanEventIndMsg pRsp = (pNanEventIndMsg)mNanVendorEvent; memset(&event->data, 0, sizeof(event->data)); u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); //Has Self-STA Mac TLV if (remainingLen <= 0) { ALOGE("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_EVENT_SELF_STATION_MAC_ADDRESS: if (outputTlv.length > NAN_MAC_ADDR_LEN) { ALOGV("%s: Reading only first %d bytes of TLV", __func__, NAN_MAC_ADDR_LEN); outputTlv.length = NAN_MAC_ADDR_LEN; } memcpy(event->data.mac_addr.addr, outputTlv.value, outputTlv.length); event->event_type = NAN_EVENT_ID_DISC_MAC_ADDR; break; case NAN_TLV_TYPE_EVENT_STARTED_CLUSTER: if (outputTlv.length > NAN_MAC_ADDR_LEN) { ALOGV("%s: Reading only first %d bytes of TLV", __func__, NAN_MAC_ADDR_LEN); outputTlv.length = NAN_MAC_ADDR_LEN; } memcpy(event->data.cluster.addr, outputTlv.value, outputTlv.length); event->event_type = NAN_EVENT_ID_STARTED_CLUSTER; break; case NAN_TLV_TYPE_EVENT_JOINED_CLUSTER: if (outputTlv.length > NAN_MAC_ADDR_LEN) { ALOGV("%s: Reading only first %d bytes of TLV", __func__, NAN_MAC_ADDR_LEN); outputTlv.length = NAN_MAC_ADDR_LEN; } memcpy(event->data.cluster.addr, outputTlv.value, outputTlv.length); event->event_type = NAN_EVENT_ID_JOINED_CLUSTER; break; default: ALOGV("Unhandled TLV type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanDisabled(NanDisabledInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanDisableIndMsg pRsp = (pNanDisableIndMsg)mNanVendorEvent; NanErrorTranslation((NanInternalStatusType)pRsp->reason, 0, (void*)event, false); return WIFI_SUCCESS; } int NanCommand::getNanTca(NanTCAInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanTcaIndMsg pRsp = (pNanTcaIndMsg)mNanVendorEvent; memset(&event->data, 0, sizeof(event->data)); u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); //Has NAN_TCA_ID_CLUSTER_SIZE if (remainingLen <= 0) { ALOGE("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_CLUSTER_SIZE_RSP: if (outputTlv.length != 2 * sizeof(u32)) { ALOGE("%s: Wrong length %d in Tca Indication expecting %zu bytes", __func__, outputTlv.length, 2 * sizeof(u32)); break; } event->rising_direction_evt_flag = outputTlv.value[0] & 0x01; event->falling_direction_evt_flag = (outputTlv.value[0] & 0x02) >> 1; memcpy(&(event->data.cluster.cluster_size), &outputTlv.value[4], sizeof(event->data.cluster.cluster_size)); event->tca_type = NAN_TCA_ID_CLUSTER_SIZE; break; default: ALOGV("Unhandled TLV type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanBeaconSdfPayload(NanBeaconSdfPayloadInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanBeaconSdfPayloadIndMsg pRsp = (pNanBeaconSdfPayloadIndMsg)mNanVendorEvent; memset(&event->data, 0, sizeof(event->data)); u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); //Has Mac address if (remainingLen <= 0) { ALOGV("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > sizeof(event->addr)) { outputTlv.length = sizeof(event->addr); } memcpy(event->addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_VENDOR_SPECIFIC_ATTRIBUTE_RECEIVE: { NanReceiveVendorSpecificAttribute* recvVsaattr = &event->vsa; if (outputTlv.length < sizeof(u32)) { ALOGE("NAN_TLV_TYPE_VENDOR_SPECIFIC_ATTRIBUTE_RECEIVE" "Incorrect length:%d", outputTlv.length); break; } event->is_vsa_received = 1; recvVsaattr->vsa_received_on = (outputTlv.value[0] >> 1) & 0x07; memcpy(&recvVsaattr->vendor_oui, &outputTlv.value[1], 3); recvVsaattr->attr_len = outputTlv.length - 4; if (recvVsaattr->attr_len > NAN_MAX_VSA_DATA_LEN) { recvVsaattr->attr_len = NAN_MAX_VSA_DATA_LEN; } if (recvVsaattr->attr_len) { memcpy(recvVsaattr->vsa, &outputTlv.value[4], recvVsaattr->attr_len); } break; } case NAN_TLV_TYPE_BEACON_SDF_PAYLOAD_RECEIVE: event->is_beacon_sdf_payload_received = 1; event->data.frame_len = outputTlv.length; if (event->data.frame_len > NAN_MAX_FRAME_DATA_LEN) { event->data.frame_len = NAN_MAX_FRAME_DATA_LEN; } memcpy(&event->data.frame_data, &outputTlv.value[0], event->data.frame_len); break; default: ALOGV("Unhandled TLV Type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return WIFI_SUCCESS; } void NanCommand::getNanReceivePostConnectivityCapabilityVal( const u8 *pInValue, NanReceivePostConnectivityCapability *pRxCapab) { if (pInValue && pRxCapab) { pRxCapab->is_mesh_supported = (pInValue[0] & (0x01 << 5)); pRxCapab->is_ibss_supported = (pInValue[0] & (0x01 << 4)); pRxCapab->wlan_infra_field = (pInValue[0] & (0x01 << 3)); pRxCapab->is_tdls_supported = (pInValue[0] & (0x01 << 2)); pRxCapab->is_wfds_supported = (pInValue[0] & (0x01 << 1)); pRxCapab->is_wfd_supported = pInValue[0] & 0x01; } } void NanCommand::getNanReceiveSdeaCtrlParams(const u8* pInValue, NanSdeaCtrlParams *pPeerSdeaParams) { if (pInValue && pPeerSdeaParams) { pPeerSdeaParams->security_cfg = (NanDataPathSecurityCfgStatus)((pInValue[0] & BIT_6) ? NAN_DP_CONFIG_SECURITY : NAN_DP_CONFIG_NO_SECURITY); pPeerSdeaParams->ranging_state = (NanRangingState)((pInValue[0] & BIT_7) ? NAN_RANGING_ENABLE : NAN_RANGING_DISABLE); #if 0 pPeerSdeaParams->enable_ranging_limit = (NanRangingLimitState)((pInValue[0] & BIT_8) ? NAN_RANGING_LIMIT_ENABLE : NAN_RANGING_LIMIT_DISABLE); #endif } return; } int NanCommand::getNanReceivePostDiscoveryVal(const u8 *pInValue, u32 length, NanReceivePostDiscovery *pRxDisc) { int ret = 0; if (length <= 8 || pInValue == NULL) { ALOGE("%s: Invalid Arg TLV Len %d < 4", __func__, length); return -1; } pRxDisc->type = (NanConnectionType) pInValue[0]; pRxDisc->role = (NanDeviceRole) pInValue[1]; pRxDisc->duration = (NanAvailDuration) (pInValue[2] & 0x03); pRxDisc->mapid = ((pInValue[2] >> 2) & 0x0F); memcpy(&pRxDisc->avail_interval_bitmap, &pInValue[4], sizeof(pRxDisc->avail_interval_bitmap)); u8 *pInputTlv = (u8 *)&pInValue[8]; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (length - 8); //Has Mac address if (remainingLen <= 0) { ALOGE("%s: No TLV's present",__func__); return -1; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > sizeof(pRxDisc->addr)) { outputTlv.length = sizeof(pRxDisc->addr); } memcpy(pRxDisc->addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_WLAN_MESH_ID: if (outputTlv.length > sizeof(pRxDisc->mesh_id)) { outputTlv.length = sizeof(pRxDisc->mesh_id); } memcpy(pRxDisc->mesh_id, outputTlv.value, outputTlv.length); pRxDisc->mesh_id_len = outputTlv.length; break; case NAN_TLV_TYPE_WLAN_INFRA_SSID: if (outputTlv.length > sizeof(pRxDisc->infrastructure_ssid_val)) { outputTlv.length = sizeof(pRxDisc->infrastructure_ssid_val); } memcpy(pRxDisc->infrastructure_ssid_val, outputTlv.value, outputTlv.length); pRxDisc->infrastructure_ssid_len = outputTlv.length; default: ALOGV("Unhandled TLV Type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return ret; } int NanCommand::getNanFurtherAvailabilityMap(const u8 *pInValue, u32 length, u8 *num_chans, NanFurtherAvailabilityChannel *pFac) { int idx = 0; if ((length == 0) || pInValue == NULL) { ALOGE("%s: Invalid Arg TLV Len %d or pInValue NULL", __func__, length); return -1; } *num_chans = pInValue[0]; if (*num_chans > NAN_MAX_FAM_CHANNELS) { ALOGE("%s: Unable to accommodate numchans %d", __func__, *num_chans); return -1; } if (length < (sizeof(u8) + (*num_chans * sizeof(NanFurtherAvailabilityChan)))) { ALOGE("%s: Invalid TLV Length", __func__); return -1; } for (idx = 0; idx < *num_chans; idx++) { pNanFurtherAvailabilityChan pRsp = \ (pNanFurtherAvailabilityChan)((u8 *)&pInValue[1] + \ (idx * sizeof(NanFurtherAvailabilityChan))); pFac->entry_control = \ (NanAvailDuration)(pRsp->entryCtrl.availIntDuration); pFac->mapid = pRsp->entryCtrl.mapId; pFac->class_val = pRsp->opClass; pFac->channel = pRsp->channel; memcpy(&pFac->avail_interval_bitmap, &pRsp->availIntBitmap, sizeof(pFac->avail_interval_bitmap)); pFac++; } return 0; } wifi_error NanCommand::getNanStaParameter(wifi_interface_handle iface, NanStaParameter *pRsp) { wifi_error ret = WIFI_ERROR_NONE; transaction_id id = 1; interface_info *ifaceInfo = getIfaceInfo(iface); ret = create(); if (ret != WIFI_SUCCESS) goto cleanup; /* Set the interface Id of the message. */ ret = set_iface_id(ifaceInfo->name); if (ret != WIFI_SUCCESS) goto cleanup; /* Construct NL message to get the sync stats parameter which has all the parameter required by staparameter. */ NanStatsRequest syncStats; memset(&syncStats, 0, sizeof(syncStats)); syncStats.stats_type = NAN_STATS_ID_DE_TIMING_SYNC; syncStats.clear = 0; mStaParam = pRsp; ret = putNanStats(id, &syncStats); if (ret != WIFI_SUCCESS) { ALOGE("%s: putNanStats Error:%d",__func__, ret); goto cleanup; } ret = requestEvent(); if (ret != 0) { ALOGE("%s: requestEvent Error:%d",__func__, ret); goto cleanup; } struct timespec abstime; abstime.tv_sec = 4; abstime.tv_nsec = 0; ret = mCondition.wait(abstime); if (ret == WIFI_ERROR_TIMED_OUT) { ALOGE("%s: Time out happened.", __func__); goto cleanup; } ALOGV("%s: NanStaparameter Master_pref:%x," \ " Random_factor:%x, hop_count:%x " \ " beacon_transmit_time:%d" \ " ndp_channel_freq:%d", __func__, pRsp->master_pref, pRsp->random_factor, pRsp->hop_count, pRsp->beacon_transmit_time, pRsp->ndp_channel_freq); cleanup: mStaParam = NULL; return ret; } int NanCommand::getNanTransmitFollowupInd(NanTransmitFollowupInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanSelfTransmitFollowupIndMsg pRsp = (pNanSelfTransmitFollowupIndMsg)mNanVendorEvent; event->id = pRsp->fwHeader.transactionId; NanErrorTranslation((NanInternalStatusType)pRsp->reason, 0, (void*)event, false); return WIFI_SUCCESS; } //Function which calls the necessaryIndication callback //based on the indication type int NanCommand::handleNdpIndication(u32 ndpCmdType, struct nlattr **tb_vendor) { //Based on the message_id in the header determine the Indication type //and call the necessary callback handler int res = 0; ALOGI("handleNdpIndication msg_id:%u", ndpCmdType); switch (ndpCmdType) { case QCA_WLAN_VENDOR_ATTR_NDP_REQUEST_IND: NanDataPathRequestInd ndpRequestInd; memset(&ndpRequestInd, 0, sizeof(ndpRequestInd)); res = getNdpRequest(tb_vendor, &ndpRequestInd); if (!res && mHandler.EventDataRequest) { (*mHandler.EventDataRequest)(&ndpRequestInd); } break; case QCA_WLAN_VENDOR_ATTR_NDP_CONFIRM_IND: NanDataPathConfirmInd ndpConfirmInd; memset(&ndpConfirmInd, 0, sizeof(ndpConfirmInd)); res = getNdpConfirm(tb_vendor, &ndpConfirmInd); if (!res && mHandler.EventDataConfirm) { (*mHandler.EventDataConfirm)(&ndpConfirmInd); } break; case QCA_WLAN_VENDOR_ATTR_NDP_END_IND: { NanDataPathEndInd *ndpEndInd = NULL; u8 num_ndp_ids = 0; if (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } num_ndp_ids = (u8)(nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY])/sizeof(u32)); ALOGD("%s: NDP Num Instance Ids : val %d", __FUNCTION__, num_ndp_ids); if (num_ndp_ids) { ndpEndInd = (NanDataPathEndInd *)malloc(sizeof(NanDataPathEndInd)+ (sizeof(u32) * num_ndp_ids)); if (!ndpEndInd) { ALOGE("%s: ndp_instance_id malloc Failed", __FUNCTION__); return WIFI_ERROR_OUT_OF_MEMORY; } ndpEndInd->num_ndp_instances = num_ndp_ids; nla_memcpy(ndpEndInd->ndp_instance_id, tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY], sizeof(u32) * ndpEndInd->num_ndp_instances); } if (mHandler.EventDataEnd) { (*mHandler.EventDataEnd)(ndpEndInd); } free(ndpEndInd); break; } case QCA_WLAN_VENDOR_ATTR_NDP_SCHEDULE_UPDATE_IND: { NanDataPathScheduleUpdateInd *pNdpScheduleUpdateInd; u32 num_channels = 0, num_ndp_ids = 0; if ((!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_SCHEDULE_UPDATE_REASON]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY])) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } if (tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NUM_CHANNELS]) { num_channels = nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NUM_CHANNELS]); ALOGD("%s: num_channels = %d", __FUNCTION__, num_channels); if ((num_channels > NAN_MAX_CHANNEL_INFO_SUPPORTED) && (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO])) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } } num_ndp_ids = (u8)(nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY])/sizeof(u32)); ALOGD("%s: NDP Num Instance Ids : val %d", __FUNCTION__, num_ndp_ids); pNdpScheduleUpdateInd = (NanDataPathScheduleUpdateInd *)malloc(sizeof(NanDataPathScheduleUpdateInd) + (sizeof(u32) * num_ndp_ids)); if (!pNdpScheduleUpdateInd) { ALOGE("%s: NdpScheduleUpdate malloc Failed", __FUNCTION__); return WIFI_ERROR_OUT_OF_MEMORY; } pNdpScheduleUpdateInd->num_channels = num_channels; pNdpScheduleUpdateInd->num_ndp_instances = num_ndp_ids; res = getNdpScheduleUpdate(tb_vendor, pNdpScheduleUpdateInd); if (!res && mHandler.EventScheduleUpdate) { (*mHandler.EventScheduleUpdate)(pNdpScheduleUpdateInd); } free(pNdpScheduleUpdateInd); break; } default: ALOGE("handleNdpIndication error invalid ndpCmdType:%u", ndpCmdType); res = (int)WIFI_ERROR_INVALID_REQUEST_ID; break; } return res; } int NanCommand::getNdpRequest(struct nlattr **tb_vendor, NanDataPathRequestInd *event) { u32 len = 0; if (event == NULL || tb_vendor == NULL) { ALOGE("%s: Invalid input argument event:%p tb_vendor:%p", __FUNCTION__, event, tb_vendor); return WIFI_ERROR_INVALID_ARGS; } if ((!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_SERVICE_INSTANCE_ID]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID])) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } event->service_instance_id = nla_get_u16(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_SERVICE_INSTANCE_ID]); ALOGD("%s: Service Instance id : val %d", __FUNCTION__, event->service_instance_id); len = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]); len = ((sizeof(event->peer_disc_mac_addr) <= len) ? sizeof(event->peer_disc_mac_addr) : len); memcpy(&event->peer_disc_mac_addr[0], nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]), len); event->ndp_instance_id = nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID]); ALOGD("%s: Ndp Instance id: %d", __FUNCTION__, event->ndp_instance_id); if (tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]) { len = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]); len = ((sizeof(event->app_info.ndp_app_info) <= len) ? sizeof(event->app_info.ndp_app_info) : len); memcpy(&event->app_info.ndp_app_info[0], nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]), len); event->app_info.ndp_app_info_len = len; } else { ALOGD("%s: NDP App Info not present", __FUNCTION__); } return WIFI_SUCCESS; } int NanCommand::getNdpConfirm(struct nlattr **tb_vendor, NanDataPathConfirmInd *event) { u32 len = 0; NanInternalStatusType drv_reason_code; struct nlattr *chInfo; NanChannelInfo *pChInfo; int rem; u32 i = 0; if (event == NULL || tb_vendor == NULL) { ALOGE("%s: Invalid input argument event:%p tb_vendor:%p", __FUNCTION__, event, tb_vendor); return WIFI_ERROR_INVALID_ARGS; } if ((!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NDI_MAC_ADDR]) || (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_RESPONSE_CODE])) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } event->ndp_instance_id = nla_get_u16(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID]); ALOGD("%s: Service Instance id : val %d", __FUNCTION__, event->ndp_instance_id); len = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NDI_MAC_ADDR]); len = ((sizeof(event->peer_ndi_mac_addr) <= len) ? sizeof(event->peer_ndi_mac_addr) : len); memcpy(&event->peer_ndi_mac_addr[0], nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NDI_MAC_ADDR]), len); event->rsp_code = (NanDataPathResponseCode)nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_RESPONSE_CODE]); ALOGD("%s: Response code %d", __FUNCTION__, event->rsp_code); if (tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]) { len = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]); len = ((sizeof(event->app_info.ndp_app_info) <= len) ? sizeof(event->app_info.ndp_app_info) : len); memcpy(&event->app_info.ndp_app_info[0], nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_APP_INFO]), len); event->app_info.ndp_app_info_len = len; } else { ALOGD("%s: NDP App Info not present", __FUNCTION__); } drv_reason_code = (NanInternalStatusType)nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_DRV_RETURN_VALUE]); ALOGD("%s: Drv reason code %d", __FUNCTION__, drv_reason_code); switch (drv_reason_code) { case NDP_I_MGMT_FRAME_REQUEST_FAILED: case NDP_I_MGMT_FRAME_RESPONSE_FAILED: case NDP_I_MGMT_FRAME_CONFIRM_FAILED: case NDP_I_MGMT_FRAME_SECURITY_INSTALL_FAILED: event->reason_code = NAN_STATUS_PROTOCOL_FAILURE; break; default: event->reason_code = (NanStatusType)drv_reason_code; break; } ALOGD("%s: Reason code %d", __FUNCTION__, event->reason_code); if (tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NUM_CHANNELS]) { event->num_channels = nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_NUM_CHANNELS]); ALOGD("%s: num_channels = %d", __FUNCTION__, event->num_channels); if ((event->num_channels > NAN_MAX_CHANNEL_INFO_SUPPORTED) && (!tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO])) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } } if (event->num_channels != 0) { for (chInfo = (struct nlattr *) nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO]), rem = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO]); (i < NAN_MAX_CHANNEL_INFO_SUPPORTED && nla_ok(chInfo, rem)); chInfo = nla_next(chInfo, &(rem))) { struct nlattr *tb2[QCA_WLAN_VENDOR_ATTR_NDP_PARAMS_MAX + 1]; pChInfo = (NanChannelInfo *) ((u8 *)event->channel_info + (i++ * (sizeof(NanChannelInfo)))); nla_parse(tb2, QCA_WLAN_VENDOR_ATTR_NDP_PARAMS_MAX, (struct nlattr *) nla_data(chInfo), nla_len(chInfo), NULL); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_CHANNEL not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->channel = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL]); ALOGD("%s: Channel = %d", __FUNCTION__, pChInfo->channel); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->bandwidth = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH]); ALOGD("%s: Channel BW = %d", __FUNCTION__, pChInfo->bandwidth); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_NSS]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_NSS not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->nss = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_NSS]); ALOGD("%s: No. Spatial Stream = %d", __FUNCTION__, pChInfo->nss); } } return WIFI_SUCCESS; } int NanCommand::getNdpScheduleUpdate(struct nlattr **tb_vendor, NanDataPathScheduleUpdateInd *event) { u32 len = 0; struct nlattr *chInfo; NanChannelInfo *pChInfo; int rem; u32 i = 0; len = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]); len = ((sizeof(event->peer_mac_addr) <= len) ? sizeof(event->peer_mac_addr) : len); memcpy(&event->peer_mac_addr[0], nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_PEER_DISCOVERY_MAC_ADDR]), len); event->schedule_update_reason_code = nla_get_u32(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_SCHEDULE_UPDATE_REASON]); ALOGD("%s: Reason code %d", __FUNCTION__, event->schedule_update_reason_code); if (event->num_channels != 0) { for (chInfo = (struct nlattr *) nla_data(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO]), rem = nla_len(tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_INFO]); (i < NAN_MAX_CHANNEL_INFO_SUPPORTED && nla_ok(chInfo, rem)); chInfo = nla_next(chInfo, &(rem))) { struct nlattr *tb2[QCA_WLAN_VENDOR_ATTR_NDP_PARAMS_MAX + 1]; pChInfo = (NanChannelInfo *) ((u8 *)event->channel_info + (i++ * (sizeof(NanChannelInfo)))); nla_parse(tb2, QCA_WLAN_VENDOR_ATTR_NDP_PARAMS_MAX, (struct nlattr *) nla_data(chInfo), nla_len(chInfo), NULL); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_CHANNEL not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->channel = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL]); ALOGD("%s: Channel = %d", __FUNCTION__, pChInfo->channel); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->bandwidth = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_CHANNEL_WIDTH]); ALOGD("%s: Channel BW = %d", __FUNCTION__, pChInfo->bandwidth); if (!tb2[QCA_WLAN_VENDOR_ATTR_NDP_NSS]) { ALOGE("%s: QCA_WLAN_VENDOR_ATTR_NDP_NSS not found", __FUNCTION__); return WIFI_ERROR_INVALID_ARGS; } pChInfo->nss = nla_get_u32(tb2[QCA_WLAN_VENDOR_ATTR_NDP_NSS]); ALOGD("%s: No. Spatial Stream = %d", __FUNCTION__, pChInfo->nss); } } if (event->num_ndp_instances) { nla_memcpy(event->ndp_instance_id, tb_vendor[QCA_WLAN_VENDOR_ATTR_NDP_INSTANCE_ID_ARRAY], sizeof(u32) * event->num_ndp_instances); } return WIFI_SUCCESS; } int NanCommand::getNanRangeRequestReceivedInd(NanRangeRequestInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanFWRangeReqRecvdInd pRsp = (pNanFWRangeReqRecvdInd)mNanVendorEvent; u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); if (remainingLen <= 0) { ALOGE("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_NAN20_RANGING_REQUEST_RECEIVED: NanFWRangeReqRecvdMsg fwRangeReqRecvd; if (outputTlv.length > sizeof(fwRangeReqRecvd)) { outputTlv.length = sizeof(fwRangeReqRecvd); } memcpy(&fwRangeReqRecvd, outputTlv.value, outputTlv.length); FW_MAC_ADDR_TO_CHAR_ARRAY(fwRangeReqRecvd.range_mac_addr, event->range_req_intf_addr); event->publish_id = fwRangeReqRecvd.range_id; break; default: ALOGV("Unhandled TLV type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return WIFI_SUCCESS; } int NanCommand::getNanRangeReportInd(NanRangeReportInd *event) { if (event == NULL || mNanVendorEvent == NULL) { ALOGE("%s: Invalid input argument event:%p mNanVendorEvent:%p", __func__, event, mNanVendorEvent); return WIFI_ERROR_INVALID_ARGS; } pNanFWRangeReportInd pRsp = (pNanFWRangeReportInd)mNanVendorEvent; u8 *pInputTlv = pRsp->ptlv; NanTlv outputTlv; u16 readLen = 0; int remainingLen = (mNanDataLen - \ (sizeof(NanMsgHeader))); if (remainingLen <= 0) { ALOGE("%s: No TLV's present",__func__); return WIFI_SUCCESS; } ALOGV("%s: TLV remaining Len:%d",__func__, remainingLen); while ((remainingLen > 0) && (0 != (readLen = NANTLV_ReadTlv(pInputTlv, &outputTlv)))) { ALOGV("%s: Remaining Len:%d readLen:%d type:%d length:%d", __func__, remainingLen, readLen, outputTlv.type, outputTlv.length); switch (outputTlv.type) { case NAN_TLV_TYPE_MAC_ADDRESS: if (outputTlv.length > NAN_MAC_ADDR_LEN) { outputTlv.length = NAN_MAC_ADDR_LEN; } memcpy(event->range_req_intf_addr, outputTlv.value, outputTlv.length); break; case NAN_TLV_TYPE_NAN20_RANGING_RESULT: NanFWRangeReportParams range_params; if (outputTlv.length > sizeof(NanFWRangeReportParams)) { outputTlv.length = sizeof(NanFWRangeReportParams); } memcpy(&range_params, outputTlv.value, outputTlv.length); event->range_measurement_mm = range_params.range_measurement; event->publish_id = range_params.publish_id; // event->event_type = range_params.event_type; break; default: ALOGV("Unhandled TLV type:%d", outputTlv.type); break; } remainingLen -= readLen; pInputTlv += readLen; memset(&outputTlv,0, sizeof(outputTlv)); } return WIFI_SUCCESS; }