/* * * Copyright (c) 2020 Project CHIP Authors * Copyright (c) 2018 Nest Labs, Inc. * All rights reserved. * * 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. */ /** * @file * Provides the implementation of the Device Layer ConfigurationManager object * for webOS platforms. */ #include #include #include #include #include #include #include #include #include #include #include #include namespace chip { namespace DeviceLayer { using namespace ::chip::DeviceLayer::Internal; ConfigurationManagerImpl & ConfigurationManagerImpl::GetDefaultInstance() { static ConfigurationManagerImpl sInstance; return sInstance; } CHIP_ERROR ConfigurationManagerImpl::Init() { CHIP_ERROR err; uint32_t rebootCount; // Force initialization of NVS namespaces if they doesn't already exist. err = PosixConfig::EnsureNamespace(PosixConfig::kConfigNamespace_ChipFactory); SuccessOrExit(err); err = PosixConfig::EnsureNamespace(PosixConfig::kConfigNamespace_ChipConfig); SuccessOrExit(err); err = PosixConfig::EnsureNamespace(PosixConfig::kConfigNamespace_ChipCounters); SuccessOrExit(err); // Initialize the generic implementation base class. err = Internal::GenericConfigurationManagerImpl::Init(); SuccessOrExit(err); if (!PosixConfig::ConfigValueExists(PosixConfig::kConfigKey_VendorId)) { err = StoreVendorId(CHIP_DEVICE_CONFIG_DEVICE_VENDOR_ID); SuccessOrExit(err); } if (!PosixConfig::ConfigValueExists(PosixConfig::kConfigKey_ProductId)) { err = StoreProductId(CHIP_DEVICE_CONFIG_DEVICE_PRODUCT_ID); SuccessOrExit(err); } if (PosixConfig::ConfigValueExists(PosixConfig::kCounterKey_RebootCount)) { err = GetRebootCount(rebootCount); SuccessOrExit(err); err = StoreRebootCount(rebootCount + 1); SuccessOrExit(err); } else { // The first boot after factory reset of the Node. err = StoreRebootCount(1); SuccessOrExit(err); } if (!PosixConfig::ConfigValueExists(PosixConfig::kCounterKey_TotalOperationalHours)) { err = StoreTotalOperationalHours(0); SuccessOrExit(err); } if (!PosixConfig::ConfigValueExists(PosixConfig::kCounterKey_BootReason)) { err = StoreBootReason(to_underlying(BootReasonType::kUnspecified)); SuccessOrExit(err); } if (!PosixConfig::ConfigValueExists(PosixConfig::kConfigKey_RegulatoryLocation)) { uint32_t location = to_underlying(chip::app::Clusters::GeneralCommissioning::RegulatoryLocationTypeEnum::kIndoor); err = WriteConfigValue(PosixConfig::kConfigKey_RegulatoryLocation, location); SuccessOrExit(err); } if (!PosixConfig::ConfigValueExists(PosixConfig::kConfigKey_LocationCapability)) { uint32_t location = to_underlying(chip::app::Clusters::GeneralCommissioning::RegulatoryLocationTypeEnum::kIndoor); err = WriteConfigValue(PosixConfig::kConfigKey_LocationCapability, location); SuccessOrExit(err); } err = CHIP_NO_ERROR; exit: return err; } CHIP_ERROR ConfigurationManagerImpl::GetPrimaryWiFiMACAddress(uint8_t * buf) { struct ifaddrs * addresses = nullptr; CHIP_ERROR error = CHIP_NO_ERROR; bool found = false; VerifyOrExit(getifaddrs(&addresses) == 0, error = CHIP_ERROR_INTERNAL); for (auto addr = addresses; addr != nullptr; addr = addr->ifa_next) { if ((addr->ifa_addr) && (addr->ifa_addr->sa_family == AF_PACKET) && strncmp(addr->ifa_name, "lo", IFNAMSIZ) != 0) { struct sockaddr_ll * mac = (struct sockaddr_ll *) addr->ifa_addr; memcpy(buf, mac->sll_addr, mac->sll_halen); found = true; break; } } freeifaddrs(addresses); if (!found) { error = CHIP_ERROR_NO_ENDPOINT; } exit: return error; } bool ConfigurationManagerImpl::CanFactoryReset() { // TODO(#742): query the application to determine if factory reset is allowed. return true; } void ConfigurationManagerImpl::InitiateFactoryReset() { PlatformMgr().ScheduleWork(DoFactoryReset); } CHIP_ERROR ConfigurationManagerImpl::ReadPersistedStorageValue(::chip::Platform::PersistedStorage::Key key, uint32_t & value) { PosixConfig::Key configKey{ PosixConfig::kConfigNamespace_ChipCounters, key }; CHIP_ERROR err = ReadConfigValue(configKey, value); if (err == CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND) { err = CHIP_ERROR_PERSISTED_STORAGE_VALUE_NOT_FOUND; } return err; } CHIP_ERROR ConfigurationManagerImpl::WritePersistedStorageValue(::chip::Platform::PersistedStorage::Key key, uint32_t value) { PosixConfig::Key configKey{ PosixConfig::kConfigNamespace_ChipCounters, key }; return WriteConfigValue(configKey, value); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValue(Key key, bool & val) { return PosixConfig::ReadConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValue(Key key, uint16_t & val) { return PosixConfig::ReadConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValue(Key key, uint32_t & val) { return PosixConfig::ReadConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValue(Key key, uint64_t & val) { return PosixConfig::ReadConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValueStr(Key key, char * buf, size_t bufSize, size_t & outLen) { return PosixConfig::ReadConfigValueStr(key, buf, bufSize, outLen); } CHIP_ERROR ConfigurationManagerImpl::ReadConfigValueBin(Key key, uint8_t * buf, size_t bufSize, size_t & outLen) { return PosixConfig::ReadConfigValueBin(key, buf, bufSize, outLen); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValue(Key key, bool val) { return PosixConfig::WriteConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValue(Key key, uint16_t val) { return PosixConfig::WriteConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValue(Key key, uint32_t val) { return PosixConfig::WriteConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValue(Key key, uint64_t val) { return PosixConfig::WriteConfigValue(key, val); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValueStr(Key key, const char * str) { return PosixConfig::WriteConfigValueStr(key, str); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValueStr(Key key, const char * str, size_t strLen) { return PosixConfig::WriteConfigValueStr(key, str, strLen); } CHIP_ERROR ConfigurationManagerImpl::WriteConfigValueBin(Key key, const uint8_t * data, size_t dataLen) { return PosixConfig::WriteConfigValueBin(key, data, dataLen); } void ConfigurationManagerImpl::RunConfigUnitTest() { PosixConfig::RunConfigUnitTest(); } void ConfigurationManagerImpl::DoFactoryReset(intptr_t arg) { CHIP_ERROR err; ChipLogProgress(DeviceLayer, "Performing factory reset"); err = PosixConfig::FactoryResetConfig(); if (err != CHIP_NO_ERROR) { ChipLogError(DeviceLayer, "Failed to factory reset configurations: %s", ErrorStr(err)); } err = PosixConfig::FactoryResetCounters(); if (err != CHIP_NO_ERROR) { ChipLogError(DeviceLayer, "Failed to factory reset counters: %s", ErrorStr(err)); } #if CHIP_DEVICE_CONFIG_ENABLE_THREAD ChipLogProgress(DeviceLayer, "Clearing Thread provision"); ThreadStackMgr().ErasePersistentInfo(); #endif // CHIP_DEVICE_CONFIG_ENABLE_THREAD // Restart the system. ChipLogProgress(DeviceLayer, "System restarting (not implemented)"); // TODO(#742): restart CHIP exe } CHIP_ERROR ConfigurationManagerImpl::StoreVendorId(uint16_t vendorId) { return WriteConfigValue(PosixConfig::kConfigKey_VendorId, vendorId); } CHIP_ERROR ConfigurationManagerImpl::StoreProductId(uint16_t productId) { return WriteConfigValue(PosixConfig::kConfigKey_ProductId, productId); } CHIP_ERROR ConfigurationManagerImpl::GetRebootCount(uint32_t & rebootCount) { return ReadConfigValue(PosixConfig::kCounterKey_RebootCount, rebootCount); } CHIP_ERROR ConfigurationManagerImpl::StoreRebootCount(uint32_t rebootCount) { return WriteConfigValue(PosixConfig::kCounterKey_RebootCount, rebootCount); } CHIP_ERROR ConfigurationManagerImpl::GetTotalOperationalHours(uint32_t & totalOperationalHours) { return ReadConfigValue(PosixConfig::kCounterKey_TotalOperationalHours, totalOperationalHours); } CHIP_ERROR ConfigurationManagerImpl::StoreTotalOperationalHours(uint32_t totalOperationalHours) { return WriteConfigValue(PosixConfig::kCounterKey_TotalOperationalHours, totalOperationalHours); } CHIP_ERROR ConfigurationManagerImpl::GetBootReason(uint32_t & bootReason) { return ReadConfigValue(PosixConfig::kCounterKey_BootReason, bootReason); } CHIP_ERROR ConfigurationManagerImpl::StoreBootReason(uint32_t bootReason) { return WriteConfigValue(PosixConfig::kCounterKey_BootReason, bootReason); } CHIP_ERROR ConfigurationManagerImpl::GetRegulatoryLocation(uint8_t & location) { uint32_t value = 0; CHIP_ERROR err = ReadConfigValue(PosixConfig::kConfigKey_RegulatoryLocation, value); if (err == CHIP_NO_ERROR) { VerifyOrReturnError(value <= UINT8_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE); location = static_cast(value); } return err; } CHIP_ERROR ConfigurationManagerImpl::GetLocationCapability(uint8_t & location) { uint32_t value = 0; CHIP_ERROR err = ReadConfigValue(PosixConfig::kConfigKey_LocationCapability, value); if (err == CHIP_NO_ERROR) { VerifyOrReturnError(value <= UINT8_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE); location = static_cast(value); } return err; } ConfigurationManager & ConfigurationMgrImpl() { return ConfigurationManagerImpl::GetDefaultInstance(); } } // namespace DeviceLayer } // namespace chip