/* * Copyright (C) 2016 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 #include #include #include #include "wifi_hidl_call_util.h" #include "wifi_hidl_test_utils.h" using ::android::hardware::wifi::V1_0::IWifi; using ::android::hardware::wifi::V1_0::IWifiApIface; using ::android::hardware::wifi::V1_0::IWifiChip; using ::android::hardware::wifi::V1_0::IWifiIface; using ::android::hardware::wifi::V1_0::IWifiNanIface; using ::android::hardware::wifi::V1_0::IWifiP2pIface; using ::android::hardware::wifi::V1_0::IWifiRttController; using ::android::hardware::wifi::V1_0::IWifiStaIface; using ::android::hardware::wifi::V1_0::ChipModeId; using ::android::hardware::wifi::V1_0::ChipId; using ::android::hardware::wifi::V1_0::IfaceType; using ::android::hardware::wifi::V1_0::WifiStatus; using ::android::hardware::wifi::V1_0::WifiStatusCode; using ::android::sp; using ::android::hardware::hidl_string; using ::android::hardware::hidl_vec; using ::android::wifi_system::InterfaceTool; namespace { constexpr uint32_t kHalStartRetryMaxCount = 5; constexpr uint32_t kHalStartRetryIntervalInMs = 2; bool findAnyModeSupportingIfaceType( IfaceType desired_type, const std::vector& modes, ChipModeId* mode_id) { for (const auto& mode : modes) { for (const auto& combination : mode.availableCombinations) { for (const auto& iface_limit : combination.limits) { const auto& iface_types = iface_limit.types; if (std::find(iface_types.begin(), iface_types.end(), desired_type) != iface_types.end()) { *mode_id = mode.id; return true; } } } } return false; } bool configureChipToSupportIfaceTypeInternal(const sp& wifi_chip, IfaceType type, ChipModeId* configured_mode_id) { if (!configured_mode_id || !wifi_chip.get()) { return false; } const auto& status_and_modes = HIDL_INVOKE(wifi_chip, getAvailableModes); if (status_and_modes.first.code != WifiStatusCode::SUCCESS) { return false; } if (!findAnyModeSupportingIfaceType(type, status_and_modes.second, configured_mode_id)) { return false; } if (HIDL_INVOKE(wifi_chip, configureChip, *configured_mode_id).code != WifiStatusCode::SUCCESS) { return false; } return true; } bool configureChipToSupportIfaceTypeInternal(const sp& wifi_chip, IfaceType type) { ChipModeId mode_id; return configureChipToSupportIfaceTypeInternal(wifi_chip, type, &mode_id); } bool doesChipSupportIfaceTypeInternal(const sp& wifi_chip, IfaceType type) { ChipModeId mode_id; if (!wifi_chip.get()) { return false; } const auto& status_and_modes = HIDL_INVOKE(wifi_chip, getAvailableModes); if (status_and_modes.first.code != WifiStatusCode::SUCCESS) { return false; } if (!findAnyModeSupportingIfaceType(type, status_and_modes.second, &mode_id)) { return false; } return true; } } // namespace sp getWifi(const std::string& instance_name) { return IWifi::getService(instance_name); } sp getWifiChip(const std::string& instance_name) { sp wifi = getWifi(instance_name); if (!wifi.get()) { return nullptr; } uint32_t retry_count = 0; auto status = HIDL_INVOKE(wifi, start); while (retry_count < kHalStartRetryMaxCount && status.code == WifiStatusCode::ERROR_NOT_AVAILABLE) { retry_count++; usleep(kHalStartRetryIntervalInMs * 1000); status = HIDL_INVOKE(wifi, start); } if (status.code != WifiStatusCode::SUCCESS) { return nullptr; } const auto& status_and_chip_ids = HIDL_INVOKE(wifi, getChipIds); const auto& chip_ids = status_and_chip_ids.second; if (status_and_chip_ids.first.code != WifiStatusCode::SUCCESS || chip_ids.size() < 1) { return nullptr; } const auto& status_and_chip = HIDL_INVOKE(wifi, getChip, chip_ids[0]); if (status_and_chip.first.code != WifiStatusCode::SUCCESS) { return nullptr; } return status_and_chip.second; } void setIfaceUp(const sp& iface) { // Set the iface up before retrurning the object. const auto& status_and_name = HIDL_INVOKE(iface, getName); if (status_and_name.first.code == WifiStatusCode::SUCCESS) { const auto& iface_name = status_and_name.second; InterfaceTool iface_tool; iface_tool.SetUpState(iface_name.c_str(), true); } } sp getWifiApIface(const std::string& instance_name) { sp wifi_chip = getWifiChip(instance_name); if (!wifi_chip.get()) { return nullptr; } if (!configureChipToSupportIfaceTypeInternal(wifi_chip, IfaceType::AP)) { return nullptr; } const auto& status_and_iface = HIDL_INVOKE(wifi_chip, createApIface); if (status_and_iface.first.code != WifiStatusCode::SUCCESS) { return nullptr; } setIfaceUp(status_and_iface.second); return status_and_iface.second; } sp getWifiNanIface(const std::string& instance_name) { sp wifi_chip = getWifiChip(instance_name); if (!wifi_chip.get()) { return nullptr; } if (!configureChipToSupportIfaceTypeInternal(wifi_chip, IfaceType::NAN)) { return nullptr; } const auto& status_and_iface = HIDL_INVOKE(wifi_chip, createNanIface); if (status_and_iface.first.code != WifiStatusCode::SUCCESS) { return nullptr; } setIfaceUp(status_and_iface.second); return status_and_iface.second; } sp getWifiP2pIface(const std::string& instance_name) { sp wifi_chip = getWifiChip(instance_name); if (!wifi_chip.get()) { return nullptr; } if (!configureChipToSupportIfaceTypeInternal(wifi_chip, IfaceType::P2P)) { return nullptr; } const auto& status_and_iface = HIDL_INVOKE(wifi_chip, createP2pIface); if (status_and_iface.first.code != WifiStatusCode::SUCCESS) { return nullptr; } setIfaceUp(status_and_iface.second); return status_and_iface.second; } sp getWifiStaIface(const std::string& instance_name) { sp wifi_chip = getWifiChip(instance_name); if (!wifi_chip.get()) { return nullptr; } if (!configureChipToSupportIfaceTypeInternal(wifi_chip, IfaceType::STA)) { return nullptr; } const auto& status_and_iface = HIDL_INVOKE(wifi_chip, createStaIface); if (status_and_iface.first.code != WifiStatusCode::SUCCESS) { return nullptr; } setIfaceUp(status_and_iface.second); return status_and_iface.second; } bool configureChipToSupportIfaceType(const sp& wifi_chip, IfaceType type, ChipModeId* configured_mode_id) { return configureChipToSupportIfaceTypeInternal(wifi_chip, type, configured_mode_id); } bool doesChipSupportIfaceType(const sp& wifi_chip, IfaceType type) { return doesChipSupportIfaceTypeInternal(wifi_chip, type); } void stopWifi(const std::string& instance_name) { sp wifi = IWifi::getService(instance_name); ASSERT_NE(wifi, nullptr); HIDL_INVOKE(wifi, stop); } uint32_t getChipCapabilitiesLatest(const sp& wifi_chip) { sp<::android::hardware::wifi::V1_5::IWifiChip> chip_converted15 = ::android::hardware::wifi::V1_5::IWifiChip::castFrom(wifi_chip); sp<::android::hardware::wifi::V1_3::IWifiChip> chip_converted13 = ::android::hardware::wifi::V1_3::IWifiChip::castFrom(wifi_chip); std::pair status_and_caps; if (chip_converted15 != nullptr) { // Call the newer HAL 1.5 version status_and_caps = HIDL_INVOKE(chip_converted15, getCapabilities_1_5); } else if (chip_converted13 != nullptr) { // Call the newer HAL 1.3 version status_and_caps = HIDL_INVOKE(chip_converted13, getCapabilities_1_3); } else { status_and_caps = HIDL_INVOKE(wifi_chip, getCapabilities); } EXPECT_EQ(WifiStatusCode::SUCCESS, status_and_caps.first.code); return status_and_caps.second; }