/* * Copyright (C) 2017 The Android Open Source Project * * Portions copyright (C) 2017 Broadcom Limited * * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "sync.h" #define LOG_TAG "WifiHAL" //#define LOG_NDEBUG 0 //uncomment to enable verbose logging #include #include #include "common.h" #include "cpp_bindings.h" typedef enum { GSCAN_ATTRIBUTE_NUM_BUCKETS = 10, GSCAN_ATTRIBUTE_BASE_PERIOD, GSCAN_ATTRIBUTE_BUCKETS_BAND, GSCAN_ATTRIBUTE_BUCKET_ID, GSCAN_ATTRIBUTE_BUCKET_PERIOD, GSCAN_ATTRIBUTE_BUCKET_NUM_CHANNELS, GSCAN_ATTRIBUTE_BUCKET_CHANNELS, GSCAN_ATTRIBUTE_NUM_AP_PER_SCAN, GSCAN_ATTRIBUTE_REPORT_THRESHOLD, GSCAN_ATTRIBUTE_NUM_SCANS_TO_CACHE, GSCAN_ATTRIBUTE_BAND = GSCAN_ATTRIBUTE_BUCKETS_BAND, GSCAN_ATTRIBUTE_ENABLE_FEATURE = 20, GSCAN_ATTRIBUTE_SCAN_RESULTS_COMPLETE, /* indicates no more results */ GSCAN_ATTRIBUTE_FLUSH_FEATURE, /* Flush all the configs */ GSCAN_ENABLE_FULL_SCAN_RESULTS, GSCAN_ATTRIBUTE_REPORT_EVENTS, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_NUM_OF_RESULTS = 30, GSCAN_ATTRIBUTE_FLUSH_RESULTS, GSCAN_ATTRIBUTE_SCAN_RESULTS, /* flat array of wifi_scan_result */ GSCAN_ATTRIBUTE_SCAN_ID, /* indicates scan number */ GSCAN_ATTRIBUTE_SCAN_FLAGS, /* indicates if scan was aborted */ GSCAN_ATTRIBUTE_AP_FLAGS, /* flags on significant change event */ GSCAN_ATTRIBUTE_NUM_CHANNELS, GSCAN_ATTRIBUTE_CHANNEL_LIST, GSCAN_ATTRIBUTE_CH_BUCKET_BITMASK, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_SSID = 40, GSCAN_ATTRIBUTE_BSSID, GSCAN_ATTRIBUTE_CHANNEL, GSCAN_ATTRIBUTE_RSSI, GSCAN_ATTRIBUTE_TIMESTAMP, GSCAN_ATTRIBUTE_RTT, GSCAN_ATTRIBUTE_RTTSD, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_HOTLIST_BSSIDS = 50, GSCAN_ATTRIBUTE_RSSI_LOW, GSCAN_ATTRIBUTE_RSSI_HIGH, GSCAN_ATTRIBUTE_HOTLIST_ELEM, GSCAN_ATTRIBUTE_HOTLIST_FLUSH, GSCAN_ATTRIBUTE_HOTLIST_BSSID_COUNT, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_RSSI_SAMPLE_SIZE = 60, GSCAN_ATTRIBUTE_LOST_AP_SAMPLE_SIZE, GSCAN_ATTRIBUTE_MIN_BREACHING, GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_BSSIDS, GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH, /* EPNO */ GSCAN_ATTRIBUTE_EPNO_SSID_LIST = 70, GSCAN_ATTRIBUTE_EPNO_SSID, GSCAN_ATTRIBUTE_EPNO_SSID_LEN, GSCAN_ATTRIBUTE_EPNO_RSSI, GSCAN_ATTRIBUTE_EPNO_FLAGS, GSCAN_ATTRIBUTE_EPNO_AUTH, GSCAN_ATTRIBUTE_EPNO_SSID_NUM, GSCAN_ATTRIBUTE_EPNO_FLUSH, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_WHITELIST_SSID = 80, GSCAN_ATTRIBUTE_NUM_WL_SSID, GSCAN_ATTRIBUTE_WL_SSID_LEN, GSCAN_ATTRIBUTE_WL_SSID_FLUSH, GSCAN_ATTRIBUTE_WHITELIST_SSID_ELEM, GSCAN_ATTRIBUTE_NUM_BSSID, GSCAN_ATTRIBUTE_BSSID_PREF_LIST, GSCAN_ATTRIBUTE_BSSID_PREF_FLUSH, GSCAN_ATTRIBUTE_BSSID_PREF, GSCAN_ATTRIBUTE_RSSI_MODIFIER, /* remaining reserved for additional attributes */ GSCAN_ATTRIBUTE_A_BAND_BOOST_THRESHOLD = 90, GSCAN_ATTRIBUTE_A_BAND_PENALTY_THRESHOLD, GSCAN_ATTRIBUTE_A_BAND_BOOST_FACTOR, GSCAN_ATTRIBUTE_A_BAND_PENALTY_FACTOR, GSCAN_ATTRIBUTE_A_BAND_MAX_BOOST, GSCAN_ATTRIBUTE_LAZY_ROAM_HYSTERESIS, GSCAN_ATTRIBUTE_ALERT_ROAM_RSSI_TRIGGER, GSCAN_ATTRIBUTE_LAZY_ROAM_ENABLE, /* BSSID blacklist */ GSCAN_ATTRIBUTE_BSSID_BLACKLIST_FLUSH = 100, GSCAN_ATTRIBUTE_BLACKLIST_BSSID, /* ANQPO */ GSCAN_ATTRIBUTE_ANQPO_HS_LIST = 110, GSCAN_ATTRIBUTE_ANQPO_HS_LIST_SIZE, GSCAN_ATTRIBUTE_ANQPO_HS_NETWORK_ID, GSCAN_ATTRIBUTE_ANQPO_HS_NAI_REALM, GSCAN_ATTRIBUTE_ANQPO_HS_ROAM_CONSORTIUM_ID, GSCAN_ATTRIBUTE_ANQPO_HS_PLMN, /* Adaptive scan attributes */ GSCAN_ATTRIBUTE_BUCKET_STEP_COUNT = 120, GSCAN_ATTRIBUTE_BUCKET_MAX_PERIOD, /* ePNO cfg */ GSCAN_ATTRIBUTE_EPNO_5G_RSSI_THR = 130, GSCAN_ATTRIBUTE_EPNO_2G_RSSI_THR, GSCAN_ATTRIBUTE_EPNO_INIT_SCORE_MAX, GSCAN_ATTRIBUTE_EPNO_CUR_CONN_BONUS, GSCAN_ATTRIBUTE_EPNO_SAME_NETWORK_BONUS, GSCAN_ATTRIBUTE_EPNO_SECURE_BONUS, GSCAN_ATTRIBUTE_EPNO_5G_BONUS, /* Roaming features */ GSCAN_ATTRIBUTE_ROAM_STATE_SET = 140, GSCAN_ATTRIBUTE_MAX } GSCAN_ATTRIBUTE; typedef struct { int num_bssid; // number of blacklisted BSSIDs mac_addr bssids[MAX_BLACKLIST_BSSID]; // blacklisted BSSIDs } wifi_bssid_params; // helper methods wifi_error wifi_enable_full_scan_results(wifi_request_id id, wifi_interface_handle iface, wifi_scan_result_handler handler); wifi_error wifi_disable_full_scan_results(wifi_request_id id, wifi_interface_handle iface); int wifi_handle_full_scan_event(wifi_request_id id, WifiEvent& event, wifi_scan_result_handler handler); void convert_to_hal_result(wifi_scan_result *to, wifi_gscan_result_t *from); void convert_to_hal_result(wifi_scan_result *to, wifi_gscan_result_t *from) { to->ts = from->ts; to->channel = from->channel; to->rssi = from->rssi; to->rtt = from->rtt; to->rtt_sd = from->rtt_sd; to->beacon_period = from->beacon_period; to->capability = from->capability; memcpy(to->ssid, from->ssid, (DOT11_MAX_SSID_LEN+1)); memcpy(&to->bssid, &from->bssid, sizeof(mac_addr)); } ///////////////////////////////////////////////////////////////////////////// class GetCapabilitiesCommand : public WifiCommand { void *mCapabilities; uint16_t mRequesttype; int mRequestsize; public: GetCapabilitiesCommand(wifi_interface_handle iface, void *capabitlites, uint16_t request_type, int request_size) : WifiCommand("GetGscanCapabilitiesCommand", iface, 0), mCapabilities(capabitlites), mRequesttype(request_type), mRequestsize(request_size) { memset(mCapabilities, 0, mRequestsize); } virtual int create() { ALOGV("Creating message to get scan capabilities; iface = %d", mIfaceInfo->id); int ret = mMsg.create(GOOGLE_OUI, mRequesttype); if (ret < 0) { return ret; } return ret; } protected: virtual int handleResponse(WifiEvent& reply) { ALOGV("In GetCapabilities::handleResponse"); if (reply.get_cmd() != NL80211_CMD_VENDOR) { ALOGD("Ignoring reply with cmd = %d", reply.get_cmd()); return NL_SKIP; } int id = reply.get_vendor_id(); int subcmd = reply.get_vendor_subcmd(); void *data = reply.get_vendor_data(); int len = reply.get_vendor_data_len(); ALOGV("Id = %0x, subcmd = 0x%x, len = %d, expected len = %d", id, subcmd, len, mRequestsize); memcpy(mCapabilities, data, min(len, mRequestsize)); return NL_OK; } }; wifi_error wifi_get_gscan_capabilities(wifi_interface_handle handle, wifi_gscan_capabilities *capabilities) { GetCapabilitiesCommand command(handle, capabilities, GSCAN_SUBCMD_GET_CAPABILITIES, (int)sizeof(wifi_gscan_capabilities)); return (wifi_error) command.requestResponse(); } /* Function to get chipset supported roaming capabilities */ wifi_error wifi_get_roaming_capabilities(wifi_interface_handle handle, wifi_roaming_capabilities *capabilities) { GetCapabilitiesCommand command(handle, capabilities, WIFI_SUBCMD_ROAM_CAPABILITY, (int)sizeof(wifi_roaming_capabilities)); return (wifi_error) command.requestResponse(); } class GetChannelListCommand : public WifiCommand { wifi_channel *channels; int max_channels; int *num_channels; int band; public: GetChannelListCommand(wifi_interface_handle iface, wifi_channel *channel_buf, int *ch_num, int num_max_ch, int band) : WifiCommand("GetChannelListCommand", iface, 0), channels(channel_buf), max_channels(num_max_ch), num_channels(ch_num), band(band) { memset(channels, 0, sizeof(wifi_channel) * max_channels); } virtual int create() { ALOGV("Creating message to get channel list; iface = %d", mIfaceInfo->id); int ret = mMsg.create(GOOGLE_OUI, GSCAN_SUBCMD_GET_CHANNEL_LIST); if (ret < 0) { return ret; } nlattr *data = mMsg.attr_start(NL80211_ATTR_VENDOR_DATA); ret = mMsg.put_u32(GSCAN_ATTRIBUTE_BAND, band); if (ret < 0) { return ret; } mMsg.attr_end(data); return ret; } protected: virtual int handleResponse(WifiEvent& reply) { ALOGV("In GetChannelList::handleResponse"); if (reply.get_cmd() != NL80211_CMD_VENDOR) { ALOGD("Ignoring reply with cmd = %d", reply.get_cmd()); return NL_SKIP; } int id = reply.get_vendor_id(); int subcmd = reply.get_vendor_subcmd(); int num_channels_to_copy = 0; nlattr *vendor_data = reply.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = reply.get_vendor_data_len(); ALOGV("Id = %0x, subcmd = %d, len = %d", id, subcmd, len); if (vendor_data == NULL || len == 0) { ALOGE("no vendor data in GetChannelList response; ignoring it"); return NL_SKIP; } for (nl_iterator it(vendor_data); it.has_next(); it.next()) { if (it.get_type() == GSCAN_ATTRIBUTE_NUM_CHANNELS) { num_channels_to_copy = it.get_u32(); ALOGI("Got channel list with %d channels", num_channels_to_copy); if(num_channels_to_copy > max_channels) num_channels_to_copy = max_channels; *num_channels = num_channels_to_copy; } else if (it.get_type() == GSCAN_ATTRIBUTE_CHANNEL_LIST && num_channels_to_copy) { memcpy(channels, it.get_data(), sizeof(int) * num_channels_to_copy); } else { ALOGW("Ignoring invalid attribute type = %d, size = %d", it.get_type(), it.get_len()); } } return NL_OK; } }; wifi_error wifi_get_valid_channels(wifi_interface_handle handle, int band, int max_channels, wifi_channel *channels, int *num_channels) { GetChannelListCommand command(handle, channels, num_channels, max_channels, band); return (wifi_error) command.requestResponse(); } ///////////////////////////////////////////////////////////////////////////// /* helper functions */ int createFeatureRequest(WifiRequest& request, int subcmd, int enable) { int result = request.create(GOOGLE_OUI, subcmd); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ATTRIBUTE_ENABLE_FEATURE, enable); if (result < 0) { return result; } request.attr_end(data); return WIFI_SUCCESS; } ///////////////////////////////////////////////////////////////////////////// class FullScanResultsCommand : public WifiCommand { int *mParams; wifi_scan_result_handler mHandler; public: FullScanResultsCommand(wifi_interface_handle iface, int id, int *params, wifi_scan_result_handler handler) : WifiCommand("FullScanResultsCommand", iface, id), mParams(params), mHandler(handler) {*mParams = 0;} int createRequest(WifiRequest& request, int subcmd, int enable) { int result = request.create(GOOGLE_OUI, subcmd); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ENABLE_FULL_SCAN_RESULTS, enable); if (result < 0) { return result; } request.attr_end(data); return WIFI_SUCCESS; } int start() { ALOGV("Enabling Full scan results"); WifiRequest request(familyId(), ifaceId()); int result = createRequest(request, GSCAN_SUBCMD_ENABLE_FULL_SCAN_RESULTS, 1); if (result != WIFI_SUCCESS) { ALOGE("failed to create request; result = %d", result); return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_FULL_SCAN_RESULTS); result = requestResponse(request); if (result != WIFI_SUCCESS) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_FULL_SCAN_RESULTS); ALOGE("failed to enable full scan results; result = %d", result); return result; } return result; } virtual int cancel() { ALOGV("Disabling Full scan results"); WifiRequest request(familyId(), ifaceId()); int result = createRequest(request, GSCAN_SUBCMD_ENABLE_FULL_SCAN_RESULTS, 0); if (result != WIFI_SUCCESS) { ALOGE("failed to create request; result = %d", result); } else { result = requestResponse(request); if (result != WIFI_SUCCESS) { ALOGE("failed to disable full scan results;result = %d", result); } } unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_FULL_SCAN_RESULTS); return WIFI_SUCCESS; } virtual int handleResponse(WifiEvent& reply) { ALOGD("Request complete!"); /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { ALOGV("Full scan results: Got an event"); return wifi_handle_full_scan_event(id(), event, mHandler); } }; ///////////////////////////////////////////////////////////////////////////// class ScanCommand : public WifiCommand { wifi_scan_cmd_params *mParams; wifi_scan_result_handler mHandler; public: ScanCommand(wifi_interface_handle iface, int id, wifi_scan_cmd_params *params, wifi_scan_result_handler handler) : WifiCommand("ScanCommand", iface, id), mParams(params), mHandler(handler) { } int createSetupRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_CONFIG); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ATTRIBUTE_BASE_PERIOD, mParams->base_period); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_NUM_BUCKETS, mParams->num_buckets); if (result < 0) { return result; } for (int i = 0; i < mParams->num_buckets; i++) { nlattr * bucket = request.attr_start(i); // next bucket result = request.put_u32(GSCAN_ATTRIBUTE_BUCKET_ID, mParams->buckets[i].bucket); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_BUCKET_PERIOD, mParams->buckets[i].period); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_BUCKETS_BAND, mParams->buckets[i].band); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_BUCKET_STEP_COUNT, mParams->buckets[i].step_count); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_BUCKET_MAX_PERIOD, mParams->buckets[i].max_period); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_REPORT_EVENTS, mParams->buckets[i].report_events); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_BUCKET_NUM_CHANNELS, mParams->buckets[i].num_channels); if (result < 0) { return result; } if (mParams->buckets[i].num_channels) { nlattr *channels = request.attr_start(GSCAN_ATTRIBUTE_BUCKET_CHANNELS); ALOGV(" channels: "); for (int j = 0; j < mParams->buckets[i].num_channels; j++) { result = request.put_u32(j, mParams->buckets[i].channels[j].channel); ALOGV(" %u", mParams->buckets[i].channels[j].channel); if (result < 0) { return result; } } request.attr_end(channels); } request.attr_end(bucket); } request.attr_end(data); return WIFI_SUCCESS; } int createScanConfigRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_SCAN_CONFIG); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ATTRIBUTE_NUM_AP_PER_SCAN, mParams->max_ap_per_scan); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_REPORT_THRESHOLD, mParams->report_threshold_percent); if (result < 0) { return result; } int num_scans = mParams->report_threshold_num_scans; result = request.put_u32(GSCAN_ATTRIBUTE_NUM_SCANS_TO_CACHE, num_scans); if (result < 0) { return result; } request.attr_end(data); return WIFI_SUCCESS; } int createStartRequest(WifiRequest& request) { return createFeatureRequest(request, GSCAN_SUBCMD_ENABLE_GSCAN, 1); } int createStopRequest(WifiRequest& request) { return createFeatureRequest(request, GSCAN_SUBCMD_ENABLE_GSCAN, 0); } void unregisterVendorHandlerAll() { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_COMPLETE_SCAN); unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SCAN_RESULTS_AVAILABLE); unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_FULL_SCAN_RESULTS); } int start() { ALOGV("GSCAN start"); WifiRequest request(familyId(), ifaceId()); int result = createSetupRequest(request); if (result != WIFI_SUCCESS) { ALOGE("failed to create setup request; result = %d", result); return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SCAN_RESULTS_AVAILABLE); registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_COMPLETE_SCAN); registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_FULL_SCAN_RESULTS); result = requestResponse(request); if (result != WIFI_SUCCESS) { unregisterVendorHandlerAll(); ALOGE("failed to configure setup; result = %d", result); return result; } request.destroy(); result = createScanConfigRequest(request); if (result != WIFI_SUCCESS) { unregisterVendorHandlerAll(); ALOGE("failed to create scan config request; result = %d", result); return result; } result = requestResponse(request); if (result != WIFI_SUCCESS) { unregisterVendorHandlerAll(); ALOGE("failed to configure scan; result = %d", result); return result; } ALOGV(" ....starting scan"); result = createStartRequest(request); if (result != WIFI_SUCCESS) { unregisterVendorHandlerAll(); ALOGE("failed to create start request; result = %d", result); return result; } result = requestResponse(request); if (result != WIFI_SUCCESS) { unregisterVendorHandlerAll(); ALOGE("failed to start scan; result = %d", result); return result; } return result; } virtual int cancel() { ALOGV("Stopping scan"); WifiRequest request(familyId(), ifaceId()); int result = createStopRequest(request); if (result != WIFI_SUCCESS) { ALOGE("failed to create stop request; result = %d", result); } else { result = requestResponse(request); if (result != WIFI_SUCCESS) { ALOGE("failed to stop scan; result = %d", result); } } unregisterVendorHandlerAll(); return WIFI_SUCCESS; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { ALOGV("Got a scan results event"); //event.log(); nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = event.get_vendor_data_len(); int event_id = event.get_vendor_subcmd(); if ((event_id == GSCAN_EVENT_COMPLETE_SCAN) || (event_id == GSCAN_EVENT_SCAN_RESULTS_AVAILABLE)) { if (vendor_data == NULL || len != 4) { ALOGI("Bad event data!"); return NL_SKIP; } wifi_scan_event evt_type; evt_type = (wifi_scan_event) event.get_u32(NL80211_ATTR_VENDOR_DATA); ALOGV("Received event type %d", evt_type); if(*mHandler.on_scan_event) (*mHandler.on_scan_event)(id(), evt_type); } else if (event_id == GSCAN_EVENT_FULL_SCAN_RESULTS) { wifi_handle_full_scan_event(id(), event, mHandler); } return NL_SKIP; } }; wifi_error wifi_start_gscan( wifi_request_id id, wifi_interface_handle iface, wifi_scan_cmd_params params, wifi_scan_result_handler handler) { wifi_handle handle = getWifiHandle(iface); ALOGV("Starting GScan, halHandle = %p", handle); ScanCommand *cmd = new ScanCommand(iface, id, ¶ms, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } wifi_error wifi_stop_gscan(wifi_request_id id, wifi_interface_handle iface) { wifi_handle handle = getWifiHandle(iface); ALOGV("Stopping GScan, wifi_request_id = %d, halHandle = %p", id, handle); if (id == -1) { wifi_scan_result_handler handler; wifi_scan_cmd_params dummy_params; memset(&handler, 0, sizeof(handler)); ScanCommand *cmd = new ScanCommand(iface, id, &dummy_params, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); cmd->cancel(); cmd->releaseRef(); return WIFI_SUCCESS; } return wifi_cancel_cmd(id, iface); } wifi_error wifi_enable_full_scan_results( wifi_request_id id, wifi_interface_handle iface, wifi_scan_result_handler handler) { wifi_handle handle = getWifiHandle(iface); int params_dummy; ALOGV("Enabling full scan results, halHandle = %p", handle); FullScanResultsCommand *cmd = new FullScanResultsCommand(iface, id, ¶ms_dummy, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } int wifi_handle_full_scan_event( wifi_request_id id, WifiEvent& event, wifi_scan_result_handler handler) { nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); unsigned int len = event.get_vendor_data_len(); if (vendor_data == NULL || len < sizeof(wifi_gscan_full_result_t)) { ALOGI("Full scan results: No scan results found"); return NL_SKIP; } wifi_gscan_full_result_t *drv_res = (wifi_gscan_full_result_t *)event.get_vendor_data(); /* To protect against corrupted data, put a ceiling */ int ie_len = min(MAX_PROBE_RESP_IE_LEN, drv_res->ie_length); wifi_scan_result *full_scan_result; wifi_gscan_result_t *fixed = &drv_res->fixed; if ((ie_len + offsetof(wifi_gscan_full_result_t, ie_data)) > len) { ALOGE("BAD event data, len %d ie_len %d fixed length %lu!\n", len, ie_len, offsetof(wifi_gscan_full_result_t, ie_data)); return NL_SKIP; } full_scan_result = (wifi_scan_result *) malloc((ie_len + offsetof(wifi_scan_result, ie_data))); if (!full_scan_result) { ALOGE("Full scan results: Can't malloc!\n"); return NL_SKIP; } convert_to_hal_result(full_scan_result, fixed); full_scan_result->ie_length = ie_len; memcpy(full_scan_result->ie_data, drv_res->ie_data, ie_len); if(handler.on_full_scan_result) handler.on_full_scan_result(id, full_scan_result, drv_res->scan_ch_bucket); ALOGV("Full scan result: %-32s %02x:%02x:%02x:%02x:%02x:%02x %d %d %ld %lx %lx %x %d\n", fixed->ssid, fixed->bssid[0], fixed->bssid[1], fixed->bssid[2], fixed->bssid[3], fixed->bssid[4], fixed->bssid[5], fixed->rssi, fixed->channel, fixed->ts, fixed->rtt, fixed->rtt_sd, drv_res->scan_ch_bucket, drv_res->ie_length); free(full_scan_result); return NL_SKIP; } wifi_error wifi_disable_full_scan_results(wifi_request_id id, wifi_interface_handle iface) { ALOGV("Disabling full scan results"); if(id == -1) { wifi_scan_result_handler handler; int params_dummy; memset(&handler, 0, sizeof(handler)); FullScanResultsCommand *cmd = new FullScanResultsCommand(iface, 0, ¶ms_dummy, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); cmd->cancel(); cmd->releaseRef(); return WIFI_SUCCESS; } return wifi_cancel_cmd(id, iface); } ///////////////////////////////////////////////////////////////////////////// class GetScanResultsCommand : public WifiCommand { wifi_cached_scan_results *mScans; int mMax; int *mNum; int mRetrieved; byte mFlush; int mCompleted; public: GetScanResultsCommand(wifi_interface_handle iface, byte flush, wifi_cached_scan_results *results, int max, int *num) : WifiCommand("GetScanResultsCommand", iface, -1), mScans(results), mMax(max), mNum(num), mRetrieved(0), mFlush(flush), mCompleted(0) { } int createRequest(WifiRequest& request, int num, byte flush) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_GET_SCAN_RESULTS); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ATTRIBUTE_NUM_OF_RESULTS, num); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_FLUSH_RESULTS, flush); if (result < 0) { return result; } request.attr_end(data); return WIFI_SUCCESS; } int execute() { WifiRequest request(familyId(), ifaceId()); ALOGV("retrieving %d scan results", mMax); for (int i = 0; i < 10 && mRetrieved < mMax; i++) { int num_to_retrieve = mMax - mRetrieved; // ALOGI("retrieving %d scan results in one shot", num_to_retrieve); int result = createRequest(request, num_to_retrieve, mFlush); if (result < 0) { ALOGE("failed to create request"); return result; } int prev_retrieved = mRetrieved; result = requestResponse(request); if (result != WIFI_SUCCESS) { ALOGE("failed to retrieve scan results; result = %d", result); return result; } if (mRetrieved == prev_retrieved || mCompleted) { /* no more items left to retrieve */ break; } request.destroy(); } ALOGV("GetScanResults read %d results", mRetrieved); *mNum = mRetrieved; return WIFI_SUCCESS; } virtual int handleResponse(WifiEvent& reply) { ALOGV("In GetScanResultsCommand::handleResponse"); if (reply.get_cmd() != NL80211_CMD_VENDOR) { ALOGD("Ignoring reply with cmd = %d", reply.get_cmd()); return NL_SKIP; } int id = reply.get_vendor_id(); int subcmd = reply.get_vendor_subcmd(); ALOGV("Id = %0x, subcmd = %d", id, subcmd); /* if (subcmd != GSCAN_SUBCMD_SCAN_RESULTS) { ALOGE("Invalid response to GetScanResultsCommand; ignoring it"); return NL_SKIP; } */ nlattr *vendor_data = reply.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = reply.get_vendor_data_len(); if (vendor_data == NULL || len == 0) { ALOGE("no vendor data in GetScanResults response; ignoring it"); return NL_SKIP; } for (nl_iterator it(vendor_data); it.has_next(); it.next()) { if (it.get_type() == GSCAN_ATTRIBUTE_SCAN_RESULTS_COMPLETE) { mCompleted = it.get_u8(); ALOGV("retrieved mCompleted flag : %d", mCompleted); } else if (it.get_type() == GSCAN_ATTRIBUTE_SCAN_RESULTS || it.get_type() == 0) { int scan_id = 0, flags = 0, num = 0, scan_ch_bucket_mask = 0; for (nl_iterator it2(it.get()); it2.has_next(); it2.next()) { if (it2.get_type() == GSCAN_ATTRIBUTE_SCAN_ID) { scan_id = it2.get_u32(); ALOGV("retrieved scan_id : 0x%0x", scan_id); } else if (it2.get_type() == GSCAN_ATTRIBUTE_SCAN_FLAGS) { flags = it2.get_u8(); ALOGV("retrieved scan_flags : 0x%0x", flags); } else if (it2.get_type() == GSCAN_ATTRIBUTE_NUM_OF_RESULTS) { num = it2.get_u32(); ALOGV("retrieved num_results: %d", num); } else if (it2.get_type() == GSCAN_ATTRIBUTE_CH_BUCKET_BITMASK) { scan_ch_bucket_mask = it2.get_u32(); ALOGD("retrieved scan_ch_bucket_mask: %x", scan_ch_bucket_mask); } else if (it2.get_type() == GSCAN_ATTRIBUTE_SCAN_RESULTS && num) { if (mRetrieved >= mMax) { ALOGW("Stored %d scans, ignoring excess results", mRetrieved); break; } num = min(num, (int)(it2.get_len()/sizeof(wifi_gscan_result))); num = min(num, (int)MAX_AP_CACHE_PER_SCAN); ALOGV("Copying %d scan results", num); wifi_gscan_result_t *results = (wifi_gscan_result_t *)it2.get_data(); wifi_scan_result *mScanResults = mScans[mRetrieved].results; for (int i = 0; i < num; i++) { wifi_gscan_result_t *result = &results[i]; convert_to_hal_result(&mScanResults[i], result); mScanResults[i].ie_length = 0; ALOGV("%02d %-32s %02x:%02x:%02x:%02x:%02x:%02x %04d", i, result->ssid, result->bssid[0], result->bssid[1], result->bssid[2], result->bssid[3], result->bssid[4], result->bssid[5], result->rssi); } mScans[mRetrieved].scan_id = scan_id; mScans[mRetrieved].flags = flags; mScans[mRetrieved].num_results = num; mScans[mRetrieved].buckets_scanned = scan_ch_bucket_mask; ALOGV("Setting result of scan_id : 0x%0x", mScans[mRetrieved].scan_id); mRetrieved++; } else { ALOGW("Ignoring invalid attribute type = %d, size = %d", it.get_type(), it.get_len()); } } } else { ALOGW("Ignoring invalid attribute type = %d, size = %d", it.get_type(), it.get_len()); } } ALOGV("GetScanResults read %d results", mRetrieved); return NL_OK; } }; wifi_error wifi_get_cached_gscan_results(wifi_interface_handle iface, byte flush, int max, wifi_cached_scan_results *results, int *num) { ALOGV("Getting cached scan results, iface handle = %p, num = %d", iface, *num); GetScanResultsCommand *cmd = new GetScanResultsCommand(iface, flush, results, max, num); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error err = (wifi_error)cmd->execute(); cmd->releaseRef(); return err; } ///////////////////////////////////////////////////////////////////////////// class BssidHotlistCommand : public WifiCommand { private: wifi_bssid_hotlist_params mParams; wifi_hotlist_ap_found_handler mHandler; static const int MAX_RESULTS = 64; wifi_scan_result mResults[MAX_RESULTS]; public: BssidHotlistCommand(wifi_interface_handle handle, int id, wifi_bssid_hotlist_params params, wifi_hotlist_ap_found_handler handler) : WifiCommand("BssidHotlistCommand", handle, id), mParams(params), mHandler(handler) { } int createSetupRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_HOTLIST); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u8(GSCAN_ATTRIBUTE_HOTLIST_FLUSH, 1); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_LOST_AP_SAMPLE_SIZE, mParams.lost_ap_sample_size); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_HOTLIST_BSSID_COUNT, mParams.num_bssid); if (result < 0) { return result; } struct nlattr * attr = request.attr_start(GSCAN_ATTRIBUTE_HOTLIST_BSSIDS); for (int i = 0; i < mParams.num_bssid; i++) { nlattr *attr2 = request.attr_start(GSCAN_ATTRIBUTE_HOTLIST_ELEM); if (attr2 == NULL) { return WIFI_ERROR_OUT_OF_MEMORY; } result = request.put_addr(GSCAN_ATTRIBUTE_BSSID, mParams.ap[i].bssid); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_RSSI_HIGH, mParams.ap[i].high); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_RSSI_LOW, mParams.ap[i].low); if (result < 0) { return result; } request.attr_end(attr2); } request.attr_end(attr); request.attr_end(data); return result; } int createTeardownRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_HOTLIST); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u8(GSCAN_ATTRIBUTE_HOTLIST_FLUSH, 1); if (result < 0) { return result; } struct nlattr * attr = request.attr_start(GSCAN_ATTRIBUTE_HOTLIST_BSSIDS); request.attr_end(attr); request.attr_end(data); return result; } void unregisterVendorHandlerAll() { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_HOTLIST_RESULTS_FOUND); unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_HOTLIST_RESULTS_LOST); } int start() { ALOGI("Executing hotlist setup request, num = %d", mParams.num_bssid); WifiRequest request(familyId(), ifaceId()); int result = createSetupRequest(request); if (result < 0) { return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_HOTLIST_RESULTS_FOUND); registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_HOTLIST_RESULTS_LOST); result = requestResponse(request); if (result < 0) { unregisterVendorHandlerAll(); ALOGI("Failed to execute hotlist setup request, result = %d", result); return result; } ALOGI("Successfully set %d APs in the hotlist ", mParams.num_bssid); result = createFeatureRequest(request, GSCAN_SUBCMD_ENABLE_GSCAN, 1); if (result < 0) { unregisterVendorHandlerAll(); return result; } result = requestResponse(request); if (result < 0) { unregisterVendorHandlerAll(); return result; } ALOGI("successfully restarted the scan"); return result; } virtual int cancel() { /* unregister event handler */ unregisterVendorHandlerAll(); /* create set hotlist message with empty hotlist */ WifiRequest request(familyId(), ifaceId()); int result = createTeardownRequest(request); if (result < 0) { return result; } result = requestResponse(request); if (result < 0) { return result; } ALOGI("Successfully reset APs in current hotlist"); return result; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { ALOGI("Hotlist AP event"); int event_id = event.get_vendor_subcmd(); // event.log(); nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = event.get_vendor_data_len(); if (vendor_data == NULL || len == 0) { ALOGI("No scan results found"); return NL_SKIP; } memset(mResults, 0, sizeof(wifi_scan_result) * MAX_RESULTS); int num = len / sizeof(wifi_gscan_result_t); wifi_gscan_result_t *inp = (wifi_gscan_result_t *)event.get_vendor_data(); num = min(MAX_RESULTS, num); for (int i = 0; i < num; i++, inp++) { convert_to_hal_result(&(mResults[i]), inp); } if (event_id == GSCAN_EVENT_HOTLIST_RESULTS_FOUND) { ALOGI("FOUND %d hotlist APs", num); if (*mHandler.on_hotlist_ap_found) (*mHandler.on_hotlist_ap_found)(id(), num, mResults); } else if (event_id == GSCAN_EVENT_HOTLIST_RESULTS_LOST) { ALOGI("LOST %d hotlist APs", num); if (*mHandler.on_hotlist_ap_lost) (*mHandler.on_hotlist_ap_lost)(id(), num, mResults); } return NL_SKIP; } }; class ePNOCommand : public WifiCommand { private: wifi_epno_params epno_params; wifi_epno_handler mHandler; wifi_scan_result mResults[MAX_EPNO_NETWORKS]; public: ePNOCommand(wifi_interface_handle handle, int id, const wifi_epno_params *params, wifi_epno_handler handler) : WifiCommand("ePNOCommand", handle, id), mHandler(handler) { if (params != NULL) { memcpy(&epno_params, params, sizeof(wifi_epno_params)); } else { memset(&epno_params, 0, sizeof(wifi_epno_params)); } } int createSetupRequest(WifiRequest& request) { char tmp_buf[DOT11_MAX_SSID_LEN + 1]; if (epno_params.num_networks > MAX_EPNO_NETWORKS) { ALOGE("wrong epno num_networks:%d", epno_params.num_networks); return WIFI_ERROR_INVALID_ARGS; } int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_EPNO_SSID); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u8(GSCAN_ATTRIBUTE_EPNO_FLUSH, 1); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_EPNO_5G_RSSI_THR, (u8)epno_params.min5GHz_rssi); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_EPNO_2G_RSSI_THR, (u8)epno_params.min24GHz_rssi); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_EPNO_INIT_SCORE_MAX, epno_params.initial_score_max); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_EPNO_CUR_CONN_BONUS, epno_params.current_connection_bonus); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_EPNO_SAME_NETWORK_BONUS, epno_params.same_network_bonus); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_EPNO_SECURE_BONUS, epno_params.secure_bonus); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_EPNO_5G_BONUS, epno_params.band5GHz_bonus); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_EPNO_SSID_NUM, epno_params.num_networks); if (result < 0) { return result; } struct nlattr * attr = request.attr_start(GSCAN_ATTRIBUTE_EPNO_SSID_LIST); wifi_epno_network *ssid_list = epno_params.networks; for (int i = 0; i < epno_params.num_networks; i++) { nlattr *attr2 = request.attr_start(i); if (attr2 == NULL) { return WIFI_ERROR_OUT_OF_MEMORY; } strlcpy(tmp_buf, ssid_list[i].ssid, sizeof(tmp_buf)); result = request.put(GSCAN_ATTRIBUTE_EPNO_SSID, tmp_buf, strlen(tmp_buf)); ALOGI("PNO network: SSID %s flags %x auth %x", tmp_buf, ssid_list[i].flags, ssid_list[i].auth_bit_field); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_EPNO_SSID_LEN, strlen(tmp_buf)); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_EPNO_FLAGS, ssid_list[i].flags); if (result < 0) { return result; } result = request.put_u32(GSCAN_ATTRIBUTE_EPNO_AUTH, ssid_list[i].auth_bit_field); if (result < 0) { return result; } request.attr_end(attr2); } request.attr_end(attr); request.attr_end(data); return result; } int createTeardownRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_EPNO_SSID); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u8(GSCAN_ATTRIBUTE_EPNO_FLUSH, 1); if (result < 0) { return result; } request.attr_end(data); return result; } int start() { ALOGI("Executing ePNO setup request, num = %d", epno_params.num_networks); WifiRequest request(familyId(), ifaceId()); int result = createSetupRequest(request); if (result < 0) { return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_EPNO_EVENT); result = requestResponse(request); if (result < 0) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_EPNO_EVENT); ALOGI("Failed to execute ePNO setup request, result = %d", result); return result; } ALOGI("Successfully set %d SSIDs for ePNO", epno_params.num_networks); ALOGI("successfully restarted the scan"); return result; } virtual int cancel() { /* unregister event handler */ unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_EPNO_EVENT); /* create set hotlist message with empty hotlist */ WifiRequest request(familyId(), ifaceId()); int result = createTeardownRequest(request); if (result < 0) { return result; } result = requestResponse(request); if (result < 0) { return result; } ALOGI("Successfully reset APs in current hotlist"); return result; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { ALOGI("ePNO event"); // event.log(); nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = event.get_vendor_data_len(); if (vendor_data == NULL || len == 0) { ALOGI("No scan results found"); return NL_SKIP; } memset(mResults, 0, sizeof(wifi_scan_result) * MAX_EPNO_NETWORKS); unsigned int num = len / sizeof(wifi_pno_result_t); unsigned int i; num = min(MAX_EPNO_NETWORKS, num); wifi_pno_result_t *res = (wifi_pno_result_t *) event.get_vendor_data(); for (i = 0; i < num; i++) { if (res[i].flags == PNO_SSID_FOUND) { memcpy(mResults[i].ssid, res[i].ssid, res[i].ssid_len); memcpy(mResults[i].bssid, res[i].bssid, sizeof(mac_addr)); mResults[i].ssid[res[i].ssid_len] = '\0'; mResults[i].channel = res[i].channel; mResults[i].rssi = res[i].rssi; } } if (*mHandler.on_network_found) (*mHandler.on_network_found)(id(), num, mResults); return NL_SKIP; } }; wifi_error wifi_set_bssid_hotlist(wifi_request_id id, wifi_interface_handle iface, wifi_bssid_hotlist_params params, wifi_hotlist_ap_found_handler handler) { wifi_handle handle = getWifiHandle(iface); BssidHotlistCommand *cmd = new BssidHotlistCommand(iface, id, params, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } wifi_error wifi_reset_bssid_hotlist(wifi_request_id id, wifi_interface_handle iface) { return wifi_cancel_cmd(id, iface); } ///////////////////////////////////////////////////////////////////////////// class SignificantWifiChangeCommand : public WifiCommand { typedef struct { mac_addr bssid; // BSSID wifi_channel channel; // channel frequency in MHz int num_rssi; // number of rssi samples wifi_rssi rssi[8]; // RSSI history in db } wifi_significant_change_result_internal; private: wifi_significant_change_params mParams; wifi_significant_change_handler mHandler; static const int MAX_RESULTS = 64; wifi_significant_change_result_internal mResultsBuffer[MAX_RESULTS]; wifi_significant_change_result *mResults[MAX_RESULTS]; public: SignificantWifiChangeCommand(wifi_interface_handle handle, int id, wifi_significant_change_params params, wifi_significant_change_handler handler) : WifiCommand("SignificantWifiChangeCommand", handle, id), mParams(params), mHandler(handler) { } int createSetupRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_SIGNIFICANT_CHANGE_CONFIG); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u8(GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH, 1); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_RSSI_SAMPLE_SIZE, mParams.rssi_sample_size); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_LOST_AP_SAMPLE_SIZE, mParams.lost_ap_sample_size); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_MIN_BREACHING, mParams.min_breaching); if (result < 0) { return result; } result = request.put_u16(GSCAN_ATTRIBUTE_NUM_BSSID, mParams.num_bssid); if (result < 0) { return result; } if (mParams.num_bssid != 0) { nlattr* attr = request.attr_start(GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_BSSIDS); if (attr == NULL) { return WIFI_ERROR_OUT_OF_MEMORY; } for (int i = 0; i < mParams.num_bssid; i++) { nlattr* attr2 = request.attr_start(i); if (attr2 == NULL) { return WIFI_ERROR_OUT_OF_MEMORY; } result = request.put_addr(GSCAN_ATTRIBUTE_BSSID, mParams.ap[i].bssid); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_RSSI_HIGH, mParams.ap[i].high); if (result < 0) { return result; } result = request.put_u8(GSCAN_ATTRIBUTE_RSSI_LOW, mParams.ap[i].low); if (result < 0) { return result; } request.attr_end(attr2); } request.attr_end(attr); } request.attr_end(data); return result; } int createTeardownRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_SET_SIGNIFICANT_CHANGE_CONFIG); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u16(GSCAN_ATTRIBUTE_SIGNIFICANT_CHANGE_FLUSH, 1); if (result < 0) { return result; } request.attr_end(data); return result; } int start() { ALOGI("Set significant wifi change config"); WifiRequest request(familyId(), ifaceId()); int result = createSetupRequest(request); if (result < 0) { return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SIGNIFICANT_CHANGE_RESULTS); result = requestResponse(request); if (result < 0) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SIGNIFICANT_CHANGE_RESULTS); ALOGI("failed to set significant wifi change config %d", result); return result; } ALOGI("successfully set significant wifi change config"); result = createFeatureRequest(request, GSCAN_SUBCMD_ENABLE_GSCAN, 1); if (result < 0) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SIGNIFICANT_CHANGE_RESULTS); return result; } result = requestResponse(request); if (result < 0) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SIGNIFICANT_CHANGE_RESULTS); return result; } ALOGI("successfully restarted the scan"); return result; } virtual int cancel() { /* unregister event handler */ unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_SIGNIFICANT_CHANGE_RESULTS); /* create set significant change monitor message with empty hotlist */ WifiRequest request(familyId(), ifaceId()); int result = createTeardownRequest(request); if (result < 0) { return result; } result = requestResponse(request); if (result < 0) { return result; } ALOGI("successfully reset significant wifi change config"); return result; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { ALOGV("Got a significant wifi change event"); nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); int len = event.get_vendor_data_len(); if (vendor_data == NULL || len == 0) { ALOGI("No scan results found"); return NL_SKIP; } typedef struct { uint16_t flags; uint16_t channel; mac_addr bssid; s8 rssi_history[8]; } ChangeInfo; int num = min(len / sizeof(ChangeInfo), MAX_RESULTS); ChangeInfo *ci = (ChangeInfo *)event.get_vendor_data(); for (int i = 0; i < num; i++) { memcpy(mResultsBuffer[i].bssid, ci[i].bssid, sizeof(mac_addr)); mResultsBuffer[i].channel = ci[i].channel; mResultsBuffer[i].num_rssi = 8; for (int j = 0; j < mResultsBuffer[i].num_rssi; j++) mResultsBuffer[i].rssi[j] = (int) ci[i].rssi_history[j]; mResults[i] = reinterpret_cast(&(mResultsBuffer[i])); } ALOGV("Retrieved %d scan results", num); if (num != 0) { (*mHandler.on_significant_change)(id(), num, mResults); } else { ALOGW("No significant change reported"); } return NL_SKIP; } }; wifi_error wifi_set_significant_change_handler(wifi_request_id id, wifi_interface_handle iface, wifi_significant_change_params params, wifi_significant_change_handler handler) { wifi_handle handle = getWifiHandle(iface); SignificantWifiChangeCommand *cmd = new SignificantWifiChangeCommand( iface, id, params, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } wifi_error wifi_reset_significant_change_handler(wifi_request_id id, wifi_interface_handle iface) { return wifi_cancel_cmd(id, iface); } wifi_error wifi_reset_epno_list(wifi_request_id id, wifi_interface_handle iface) { if (id == -1) { wifi_epno_handler handler; memset(&handler, 0, sizeof(handler)); ePNOCommand *cmd = new ePNOCommand(iface, id, NULL, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); cmd->cancel(); cmd->releaseRef(); return WIFI_SUCCESS; } return wifi_cancel_cmd(id, iface); } wifi_error wifi_set_epno_list(wifi_request_id id, wifi_interface_handle iface, const wifi_epno_params *params, wifi_epno_handler handler) { wifi_handle handle = getWifiHandle(iface); if (handler.on_network_found == NULL) { return WIFI_ERROR_INVALID_ARGS; } ePNOCommand *cmd = new ePNOCommand(iface, id, params, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } class BssidBlacklistCommand : public WifiCommand { private: wifi_bssid_params *mParams; public: BssidBlacklistCommand(wifi_interface_handle handle, int id, wifi_bssid_params *params) : WifiCommand("BssidBlacklistCommand", handle, id), mParams(params) { } int createRequest(WifiRequest& request) { if ((mParams->num_bssid < 0) || (mParams->num_bssid > MAX_BLACKLIST_BSSID)) { return WIFI_ERROR_INVALID_ARGS; } int result = request.create(GOOGLE_OUI, WIFI_SUBCMD_SET_BSSID_BLACKLIST); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); if (!mParams->num_bssid) { result = request.put_u32(GSCAN_ATTRIBUTE_BSSID_BLACKLIST_FLUSH, 1); if (result < 0) { return result; } } else { result = request.put_u32(GSCAN_ATTRIBUTE_NUM_BSSID, mParams->num_bssid); if (result < 0) { return result; } for (int i = 0; i < mParams->num_bssid; i++) { result = request.put_addr(GSCAN_ATTRIBUTE_BLACKLIST_BSSID, mParams->bssids[i]); if (result < 0) { return result; } } } request.attr_end(data); return result; } int start() { ALOGV("Executing bssid blacklist request, num = %d", mParams->num_bssid); WifiRequest request(familyId(), ifaceId()); int result = createRequest(request); if (result < 0) { return result; } result = requestResponse(request); if (result < 0) { ALOGE("Failed to execute bssid blacklist request, result = %d", result); return result; } ALOGI("Successfully added %d blacklist bssids", mParams->num_bssid); return result; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } }; wifi_error wifi_set_bssid_blacklist(wifi_request_id id, wifi_interface_handle iface, wifi_bssid_params params) { BssidBlacklistCommand *cmd = new BssidBlacklistCommand(iface, id, ¶ms); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = (wifi_error)cmd->start(); //release the reference of command as well cmd->releaseRef(); return result; } wifi_error wifi_configure_roaming(wifi_interface_handle iface, wifi_roaming_config *roam_config) { wifi_error ret; wifi_bssid_params bssid_params; unsigned int i; wifi_request_id id = 0; /* Set bssid blacklist */ if (roam_config->num_blacklist_bssid == 0) { /* Flush request */ ALOGI("%s: num_blacklist_bssid == 0 (flush)", __FUNCTION__); } bssid_params.num_bssid = roam_config->num_blacklist_bssid; for (i = 0; i < roam_config->num_blacklist_bssid; i++) { mac_addr &addr1 = roam_config->blacklist_bssid[i]; memcpy(&bssid_params.bssids[i], &roam_config->blacklist_bssid[i], sizeof(mac_addr)); ALOGI("%02x:%02x:%02x:%02x:%02x:%02x\n", addr1[0], addr1[1], addr1[2], addr1[3], addr1[4], addr1[5]); } ret = wifi_set_bssid_blacklist(id, iface, bssid_params); if (ret != WIFI_SUCCESS) { ALOGE("%s: Failed to configure blacklist bssids", __FUNCTION__); return ret; } return ret; } class FirmwareRoamingStateCommand : public WifiCommand { private: fw_roaming_state_t roam_state; public: FirmwareRoamingStateCommand(wifi_interface_handle handle, fw_roaming_state_t state) : WifiCommand("FirmwareRoamingStateCommand", handle, -1), roam_state(state) { } int createRequest(WifiRequest& request) { int result = request.create(GOOGLE_OUI, WIFI_SUBCMD_FW_ROAM_POLICY); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); result = request.put_u32(GSCAN_ATTRIBUTE_ROAM_STATE_SET, roam_state); if (result < 0) { return result; } request.attr_end(data); return result; } int start() { ALOGV("Executing firmware roam state set, state = %d", roam_state); WifiRequest request(familyId(), ifaceId()); int result = createRequest(request); if (result < 0) { return result; } result = requestResponse(request); if (result < 0) { ALOGE("Failed to execute firmware roam state set, result = %d", result); return result; } ALOGI("Successfully set firmware roam state - %d", roam_state); return result; } virtual int handleResponse(WifiEvent& reply) { /* Nothing to do on response! */ return NL_SKIP; } }; wifi_error wifi_enable_firmware_roaming(wifi_interface_handle iface, fw_roaming_state_t state) { /* Set firmware roaming state */ FirmwareRoamingStateCommand *cmd = new FirmwareRoamingStateCommand(iface, state); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = (wifi_error)cmd->start(); //release the reference of command as well cmd->releaseRef(); return result; } //////////////////////////////////////////////////////////////////////////////// class AnqpoConfigureCommand : public WifiCommand { int num_hs; wifi_passpoint_network *mNetworks; wifi_passpoint_event_handler mHandler; wifi_scan_result *mResult; public: AnqpoConfigureCommand(wifi_request_id id, wifi_interface_handle iface, int num, wifi_passpoint_network *hs_list, wifi_passpoint_event_handler handler) : WifiCommand("AnqpoConfigureCommand", iface, id), num_hs(num), mNetworks(hs_list), mHandler(handler) { mResult = NULL; } int createRequest(WifiRequest& request, int val) { int result = request.create(GOOGLE_OUI, GSCAN_SUBCMD_ANQPO_CONFIG); result = request.put_u32(GSCAN_ATTRIBUTE_ANQPO_HS_LIST_SIZE, num_hs); if (result < 0) { return result; } nlattr *data = request.attr_start(NL80211_ATTR_VENDOR_DATA); struct nlattr * attr = request.attr_start(GSCAN_ATTRIBUTE_ANQPO_HS_LIST); for (int i = 0; i < num_hs; i++) { nlattr *attr2 = request.attr_start(i); if (attr2 == NULL) { return WIFI_ERROR_OUT_OF_MEMORY; } result = request.put_u32(GSCAN_ATTRIBUTE_ANQPO_HS_NETWORK_ID, mNetworks[i].id); if (result < 0) { return result; } result = request.put(GSCAN_ATTRIBUTE_ANQPO_HS_NAI_REALM, mNetworks[i].realm, 256); if (result < 0) { return result; } result = request.put(GSCAN_ATTRIBUTE_ANQPO_HS_ROAM_CONSORTIUM_ID, mNetworks[i].roamingConsortiumIds, 128); if (result < 0) { return result; } result = request.put(GSCAN_ATTRIBUTE_ANQPO_HS_PLMN, mNetworks[i].plmn, 3); if (result < 0) { return result; } request.attr_end(attr2); } request.attr_end(attr); request.attr_end(data); return WIFI_SUCCESS; } int start() { WifiRequest request(familyId(), ifaceId()); int result = createRequest(request, num_hs); if (result != WIFI_SUCCESS) { ALOGE("failed to create request; result = %d", result); return result; } registerVendorHandler(GOOGLE_OUI, GSCAN_EVENT_ANQPO_HOTSPOT_MATCH); result = requestResponse(request); if (result != WIFI_SUCCESS) { unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_ANQPO_HOTSPOT_MATCH); ALOGE("failed to set ANQPO networks; result = %d", result); return result; } return result; } virtual int cancel() { WifiRequest request(familyId(), ifaceId()); int result = createRequest(request, 0); if (result != WIFI_SUCCESS) { ALOGE("failed to create request; result = %d", result); } else { result = requestResponse(request); if (result != WIFI_SUCCESS) { ALOGE("failed to reset ANQPO networks;result = %d", result); } } unregisterVendorHandler(GOOGLE_OUI, GSCAN_EVENT_ANQPO_HOTSPOT_MATCH); return WIFI_SUCCESS; } virtual int handleResponse(WifiEvent& reply) { ALOGD("Request complete!"); /* Nothing to do on response! */ return NL_SKIP; } virtual int handleEvent(WifiEvent& event) { typedef struct { u16 channel; /* channel of GAS protocol */ u8 dialog_token; /* GAS dialog token */ u8 fragment_id; /* fragment id */ u16 status_code; /* status code on GAS completion */ u16 data_len; /* length of data to follow */ u8 data[1]; /* variable length specified by data_len */ } wifi_anqp_gas_resp; ALOGI("ANQPO hotspot matched event!"); nlattr *vendor_data = event.get_attribute(NL80211_ATTR_VENDOR_DATA); unsigned int len = event.get_vendor_data_len(); if (vendor_data == NULL || len < sizeof(wifi_scan_result)) { ALOGI("No scan results found"); return NL_SKIP; } mResult = (wifi_scan_result *)malloc(sizeof(wifi_scan_result)); if (!mResult) { return NL_SKIP; } wifi_gscan_full_result_t *drv_res = (wifi_gscan_full_result_t *)event.get_vendor_data(); wifi_gscan_result_t *fixed = &drv_res->fixed; convert_to_hal_result(mResult, fixed); byte *anqp = (byte *)drv_res + offsetof(wifi_gscan_full_result_t, ie_data) + drv_res->ie_length; wifi_anqp_gas_resp *gas = (wifi_anqp_gas_resp *)anqp; int anqp_len = offsetof(wifi_anqp_gas_resp, data) + gas->data_len; int networkId = *(int *)((byte *)anqp + anqp_len); ALOGI("%-32s\t", mResult->ssid); ALOGI("%02x:%02x:%02x:%02x:%02x:%02x ", mResult->bssid[0], mResult->bssid[1], mResult->bssid[2], mResult->bssid[3], mResult->bssid[4], mResult->bssid[5]); ALOGI("rssi:%d\t", mResult->rssi); ALOGI("channel:%d\t", mResult->channel); ALOGI("ts:0x%jx\t", mResult->ts); ALOGI("rtt:0x%jx\t", mResult->rtt); ALOGI("rtt_sd:0x%jx\n", mResult->rtt_sd); if(*mHandler.on_passpoint_network_found) (*mHandler.on_passpoint_network_found)(id(), networkId, mResult, anqp_len, anqp); free(mResult); return NL_SKIP; } }; wifi_error wifi_set_passpoint_list(wifi_request_id id, wifi_interface_handle iface, int num, wifi_passpoint_network *networks, wifi_passpoint_event_handler handler) { wifi_handle handle = getWifiHandle(iface); AnqpoConfigureCommand *cmd = new AnqpoConfigureCommand(id, iface, num, networks, handler); NULL_CHECK_RETURN(cmd, "memory allocation failure", WIFI_ERROR_OUT_OF_MEMORY); wifi_error result = wifi_register_cmd(handle, id, cmd); if (result != WIFI_SUCCESS) { cmd->releaseRef(); return result; } result = (wifi_error)cmd->start(); if (result != WIFI_SUCCESS) { wifi_unregister_cmd(handle, id); cmd->releaseRef(); return result; } return result; } wifi_error wifi_reset_passpoint_list(wifi_request_id id, wifi_interface_handle iface) { return wifi_cancel_cmd(id, iface); }