#include "config.h" #include "ethernet_interface.hpp" #include "config_parser.hpp" #include "neighbor.hpp" #include "network_manager.hpp" #include "routing_table.hpp" #include "vlan_interface.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace phosphor { namespace network { using namespace phosphor::logging; using namespace sdbusplus::xyz::openbmc_project::Common::Error; using NotAllowed = sdbusplus::xyz::openbmc_project::Common::Error::NotAllowed; using NotAllowedArgument = xyz::openbmc_project::Common::NotAllowed; using Argument = xyz::openbmc_project::Common::InvalidArgument; constexpr auto RESOLVED_SERVICE = "org.freedesktop.resolve1"; constexpr auto RESOLVED_INTERFACE = "org.freedesktop.resolve1.Link"; constexpr auto PROPERTY_INTERFACE = "org.freedesktop.DBus.Properties"; constexpr auto RESOLVED_SERVICE_PATH = "/org/freedesktop/resolve1/link/"; constexpr auto METHOD_GET = "Get"; struct EthernetIntfSocket { EthernetIntfSocket(int domain, int type, int protocol) { if ((sock = socket(domain, type, protocol)) < 0) { log("socket creation failed:", entry("ERROR=%s", strerror(errno))); } } ~EthernetIntfSocket() { if (sock >= 0) { close(sock); } } int sock{-1}; }; std::map mapDHCPToSystemd = { {EthernetInterface::DHCPConf::both, "true"}, {EthernetInterface::DHCPConf::v4, "ipv4"}, {EthernetInterface::DHCPConf::v6, "ipv6"}, {EthernetInterface::DHCPConf::none, "false"}}; EthernetInterface::EthernetInterface(sdbusplus::bus::bus& bus, const std::string& objPath, DHCPConf dhcpEnabled, Manager& parent, bool emitSignal, std::optional enabled) : Ifaces(bus, objPath.c_str(), true), bus(bus), manager(parent), objPath(objPath) { auto intfName = objPath.substr(objPath.rfind("/") + 1); std::replace(intfName.begin(), intfName.end(), '_', '.'); interfaceName(intfName); EthernetInterfaceIntf::dhcpEnabled(dhcpEnabled); EthernetInterfaceIntf::ipv6AcceptRA(getIPv6AcceptRAFromConf()); EthernetInterfaceIntf::nicEnabled(enabled ? *enabled : queryNicEnabled()); route::Table routingTable; auto gatewayList = routingTable.getDefaultGateway(); auto gateway6List = routingTable.getDefaultGateway6(); std::string defaultGateway; std::string defaultGateway6; for (auto& gateway : gatewayList) { if (gateway.first == intfName) { defaultGateway = gateway.second; break; } } for (auto& gateway6 : gateway6List) { if (gateway6.first == intfName) { defaultGateway6 = gateway6.second; break; } } EthernetInterfaceIntf::defaultGateway(defaultGateway); EthernetInterfaceIntf::defaultGateway6(defaultGateway6); // Don't get the mac address from the system as the mac address // would be same as parent interface. if (intfName.find(".") == std::string::npos) { MacAddressIntf::macAddress(getMACAddress(intfName)); } EthernetInterfaceIntf::ntpServers(getNTPServersFromConf()); EthernetInterfaceIntf::linkUp(linkUp()); EthernetInterfaceIntf::mtu(mtu()); #ifdef NIC_SUPPORTS_ETHTOOL InterfaceInfo ifInfo = EthernetInterface::getInterfaceInfo(); EthernetInterfaceIntf::autoNeg(std::get<2>(ifInfo)); EthernetInterfaceIntf::speed(std::get<0>(ifInfo)); #endif // Emit deferred signal. if (emitSignal) { this->emit_object_added(); } } static IP::Protocol convertFamily(int family) { switch (family) { case AF_INET: return IP::Protocol::IPv4; case AF_INET6: return IP::Protocol::IPv6; } throw std::invalid_argument("Bad address family"); } void EthernetInterface::disableDHCP(IP::Protocol protocol) { DHCPConf dhcpState = EthernetInterfaceIntf::dhcpEnabled(); if (dhcpState == EthernetInterface::DHCPConf::both) { if (protocol == IP::Protocol::IPv4) { dhcpEnabled(EthernetInterface::DHCPConf::v6); } else if (protocol == IP::Protocol::IPv6) { dhcpEnabled(EthernetInterface::DHCPConf::v4); } } else if ((dhcpState == EthernetInterface::DHCPConf::v4) && (protocol == IP::Protocol::IPv4)) { dhcpEnabled(EthernetInterface::DHCPConf::none); } else if ((dhcpState == EthernetInterface::DHCPConf::v6) && (protocol == IP::Protocol::IPv6)) { dhcpEnabled(EthernetInterface::DHCPConf::none); } } bool EthernetInterface::dhcpIsEnabled(IP::Protocol family, bool ignoreProtocol) { return ((EthernetInterfaceIntf::dhcpEnabled() == EthernetInterface::DHCPConf::both) || ((EthernetInterfaceIntf::dhcpEnabled() == EthernetInterface::DHCPConf::v6) && ((family == IP::Protocol::IPv6) || ignoreProtocol)) || ((EthernetInterfaceIntf::dhcpEnabled() == EthernetInterface::DHCPConf::v4) && ((family == IP::Protocol::IPv4) || ignoreProtocol))); } bool EthernetInterface::dhcpToBeEnabled(IP::Protocol family, const std::string& nextDHCPState) { return ((nextDHCPState == "true") || ((nextDHCPState == "ipv6") && (family == IP::Protocol::IPv6)) || ((nextDHCPState == "ipv4") && (family == IP::Protocol::IPv4))); } bool EthernetInterface::originIsManuallyAssigned(IP::AddressOrigin origin) { return ( #ifdef LINK_LOCAL_AUTOCONFIGURATION (origin == IP::AddressOrigin::Static) #else (origin == IP::AddressOrigin::Static || origin == IP::AddressOrigin::LinkLocal) #endif ); } void EthernetInterface::createIPAddressObjects() { addrs.clear(); auto addrs = getInterfaceAddrs()[interfaceName()]; for (auto& addr : addrs) { IP::Protocol addressType = convertFamily(addr.addrType); IP::AddressOrigin origin = IP::AddressOrigin::Static; if (dhcpIsEnabled(addressType)) { origin = IP::AddressOrigin::DHCP; } if (isLinkLocalIP(addr.ipaddress)) { origin = IP::AddressOrigin::LinkLocal; } // Obsolete parameter std::string gateway = ""; std::string ipAddressObjectPath = generateObjectPath( addressType, addr.ipaddress, addr.prefix, gateway, origin); this->addrs.insert_or_assign( addr.ipaddress, std::make_shared( bus, ipAddressObjectPath.c_str(), *this, addressType, addr.ipaddress, origin, addr.prefix, gateway)); } } void EthernetInterface::createStaticNeighborObjects() { staticNeighbors.clear(); NeighborFilter filter; filter.interface = ifIndex(); filter.state = NUD_PERMANENT; auto neighbors = getCurrentNeighbors(filter); for (const auto& neighbor : neighbors) { if (!neighbor.mac) { continue; } std::string ip = toString(neighbor.address); std::string mac = mac_address::toString(*neighbor.mac); std::string objectPath = generateStaticNeighborObjectPath(ip, mac); staticNeighbors.emplace(ip, std::make_shared( bus, objectPath.c_str(), *this, ip, mac, Neighbor::State::Permanent)); } } unsigned EthernetInterface::ifIndex() const { unsigned idx = if_nametoindex(interfaceName().c_str()); if (idx == 0) { throw std::system_error(errno, std::generic_category(), "if_nametoindex"); } return idx; } ObjectPath EthernetInterface::ip(IP::Protocol protType, std::string ipaddress, uint8_t prefixLength, std::string gateway) { if (dhcpIsEnabled(protType)) { log("DHCP enabled on the interface"), entry("INTERFACE=%s", interfaceName().c_str()); disableDHCP(protType); } IP::AddressOrigin origin = IP::AddressOrigin::Static; int addressFamily = (protType == IP::Protocol::IPv4) ? AF_INET : AF_INET6; if (!isValidIP(addressFamily, ipaddress)) { log("Not a valid IP address"), entry("ADDRESS=%s", ipaddress.c_str()); elog(Argument::ARGUMENT_NAME("ipaddress"), Argument::ARGUMENT_VALUE(ipaddress.c_str())); } // Gateway is an obsolete parameter gateway = ""; if (!isValidPrefix(addressFamily, prefixLength)) { log("PrefixLength is not correct "), entry("PREFIXLENGTH=%" PRIu8, prefixLength); elog( Argument::ARGUMENT_NAME("prefixLength"), Argument::ARGUMENT_VALUE(std::to_string(prefixLength).c_str())); } std::string objectPath = generateObjectPath(protType, ipaddress, prefixLength, gateway, origin); this->addrs.insert_or_assign(ipaddress, std::make_shared( bus, objectPath.c_str(), *this, protType, ipaddress, origin, prefixLength, gateway)); manager.writeToConfigurationFile(); return objectPath; } ObjectPath EthernetInterface::neighbor(std::string ipAddress, std::string macAddress) { if (!isValidIP(AF_INET, ipAddress) && !isValidIP(AF_INET6, ipAddress)) { log("Not a valid IP address", entry("ADDRESS=%s", ipAddress.c_str())); elog(Argument::ARGUMENT_NAME("ipAddress"), Argument::ARGUMENT_VALUE(ipAddress.c_str())); } if (!mac_address::isUnicast(mac_address::fromString(macAddress))) { log("Not a valid MAC address", entry("MACADDRESS=%s", ipAddress.c_str())); elog(Argument::ARGUMENT_NAME("macAddress"), Argument::ARGUMENT_VALUE(macAddress.c_str())); } std::string objectPath = generateStaticNeighborObjectPath(ipAddress, macAddress); staticNeighbors.emplace(ipAddress, std::make_shared( bus, objectPath.c_str(), *this, ipAddress, macAddress, Neighbor::State::Permanent)); manager.writeToConfigurationFile(); return objectPath; } #ifdef NIC_SUPPORTS_ETHTOOL /* Enable this code if your NIC driver supports the ETHTOOL features. Do this by adding the following to your phosphor-network*.bbappend file. EXTRA_OECONF_append = " --enable-nic-ethtool=yes" The default compile mode is to omit getInterfaceInfo() */ InterfaceInfo EthernetInterface::getInterfaceInfo() const { ifreq ifr = {}; ethtool_cmd edata = {}; LinkSpeed speed = {}; Autoneg autoneg = {}; DuplexMode duplex = {}; LinkUp linkState = {}; NICEnabled enabled = {}; MTU mtuSize = {}; EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); if (eifSocket.sock < 0) { return std::make_tuple(speed, duplex, autoneg, linkState, enabled, mtuSize); } std::strncpy(ifr.ifr_name, interfaceName().c_str(), IFNAMSIZ - 1); ifr.ifr_data = reinterpret_cast(&edata); edata.cmd = ETHTOOL_GSET; if (ioctl(eifSocket.sock, SIOCETHTOOL, &ifr) >= 0) { speed = edata.speed; duplex = edata.duplex; autoneg = edata.autoneg; } enabled = nicEnabled(); linkState = linkUp(); mtuSize = mtu(); return std::make_tuple(speed, duplex, autoneg, linkState, enabled, mtuSize); } #endif /** @brief get the mac address of the interface. * @return macaddress on success */ std::string EthernetInterface::getMACAddress(const std::string& interfaceName) const { std::string activeMACAddr = MacAddressIntf::macAddress(); EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); if (eifSocket.sock < 0) { return activeMACAddr; } ifreq ifr = {}; std::strncpy(ifr.ifr_name, interfaceName.c_str(), IFNAMSIZ - 1); if (ioctl(eifSocket.sock, SIOCGIFHWADDR, &ifr) != 0) { log("ioctl failed for SIOCGIFHWADDR:", entry("ERROR=%s", strerror(errno))); elog(); } static_assert(sizeof(ifr.ifr_hwaddr.sa_data) >= sizeof(ether_addr)); std::string_view hwaddr(reinterpret_cast(ifr.ifr_hwaddr.sa_data), sizeof(ifr.ifr_hwaddr.sa_data)); return mac_address::toString(stdplus::raw::copyFrom(hwaddr)); } std::string EthernetInterface::generateId(const std::string& ipaddress, uint8_t prefixLength, const std::string& gateway, const std::string& origin) { std::stringstream hexId; std::string hashString = ipaddress; hashString += std::to_string(prefixLength); hashString += gateway; hashString += origin; // Only want 8 hex digits. hexId << std::hex << ((std::hash{}(hashString)) & 0xFFFFFFFF); return hexId.str(); } std::string EthernetInterface::generateNeighborId(const std::string& ipAddress, const std::string& macAddress) { std::stringstream hexId; std::string hashString = ipAddress + macAddress; // Only want 8 hex digits. hexId << std::hex << ((std::hash{}(hashString)) & 0xFFFFFFFF); return hexId.str(); } void EthernetInterface::deleteObject(const std::string& ipaddress) { auto it = addrs.find(ipaddress); if (it == addrs.end()) { log("DeleteObject:Unable to find the object."); return; } this->addrs.erase(it); manager.writeToConfigurationFile(); } void EthernetInterface::deleteStaticNeighborObject(const std::string& ipAddress) { auto it = staticNeighbors.find(ipAddress); if (it == staticNeighbors.end()) { log( "DeleteStaticNeighborObject:Unable to find the object."); return; } staticNeighbors.erase(it); manager.writeToConfigurationFile(); } void EthernetInterface::deleteVLANFromSystem(const std::string& interface) { auto confDir = manager.getConfDir(); fs::path networkFile = confDir; networkFile /= systemd::config::networkFilePrefix + interface + systemd::config::networkFileSuffix; fs::path deviceFile = confDir; deviceFile /= interface + systemd::config::deviceFileSuffix; // delete the vlan network file if (fs::is_regular_file(networkFile)) { fs::remove(networkFile); } // delete the vlan device file if (fs::is_regular_file(deviceFile)) { fs::remove(deviceFile); } // TODO systemd doesn't delete the virtual network interface // even after deleting all the related configuartion. // https://github.com/systemd/systemd/issues/6600 try { deleteInterface(interface); } catch (const InternalFailure& e) { commit(); } } void EthernetInterface::deleteVLANObject(const std::string& interface) { auto it = vlanInterfaces.find(interface); if (it == vlanInterfaces.end()) { log("DeleteVLANObject:Unable to find the object", entry("INTERFACE=%s", interface.c_str())); return; } deleteVLANFromSystem(interface); // delete the interface vlanInterfaces.erase(it); manager.writeToConfigurationFile(); } std::string EthernetInterface::generateObjectPath( IP::Protocol addressType, const std::string& ipaddress, uint8_t prefixLength, const std::string& gateway, IP::AddressOrigin origin) const { std::string type = convertForMessage(addressType); type = type.substr(type.rfind('.') + 1); std::transform(type.begin(), type.end(), type.begin(), ::tolower); std::filesystem::path objectPath; objectPath /= objPath; objectPath /= type; objectPath /= generateId(ipaddress, prefixLength, gateway, convertForMessage(origin)); return objectPath.string(); } std::string EthernetInterface::generateStaticNeighborObjectPath( const std::string& ipAddress, const std::string& macAddress) const { std::filesystem::path objectPath; objectPath /= objPath; objectPath /= "static_neighbor"; objectPath /= generateNeighborId(ipAddress, macAddress); return objectPath.string(); } bool EthernetInterface::ipv6AcceptRA(bool value) { if (value == EthernetInterfaceIntf::ipv6AcceptRA()) { return value; } EthernetInterfaceIntf::ipv6AcceptRA(value); manager.writeToConfigurationFile(); return value; } EthernetInterface::DHCPConf EthernetInterface::dhcpEnabled(DHCPConf value) { if (value == EthernetInterfaceIntf::dhcpEnabled()) { return value; } EthernetInterfaceIntf::dhcpEnabled(value); manager.writeToConfigurationFile(); return value; } bool EthernetInterface::linkUp() const { EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); bool value = EthernetInterfaceIntf::linkUp(); if (eifSocket.sock < 0) { return value; } ifreq ifr = {}; std::strncpy(ifr.ifr_name, interfaceName().c_str(), IF_NAMESIZE - 1); if (ioctl(eifSocket.sock, SIOCGIFFLAGS, &ifr) == 0) { value = static_cast(ifr.ifr_flags & IFF_RUNNING); } else { log("ioctl failed for SIOCGIFFLAGS:", entry("ERROR=%s", strerror(errno))); } return value; } size_t EthernetInterface::mtu() const { EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); size_t value = EthernetInterfaceIntf::mtu(); if (eifSocket.sock < 0) { return value; } ifreq ifr = {}; std::strncpy(ifr.ifr_name, interfaceName().c_str(), IF_NAMESIZE - 1); if (ioctl(eifSocket.sock, SIOCGIFMTU, &ifr) == 0) { value = ifr.ifr_mtu; } else { log("ioctl failed for SIOCGIFMTU:", entry("ERROR=%s", strerror(errno))); } return value; } size_t EthernetInterface::mtu(size_t value) { if (value == EthernetInterfaceIntf::mtu()) { return value; } else if (value == 0) { return EthernetInterfaceIntf::mtu(); } EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); if (eifSocket.sock < 0) { return EthernetInterfaceIntf::mtu(); } ifreq ifr = {}; std::strncpy(ifr.ifr_name, interfaceName().c_str(), IF_NAMESIZE - 1); ifr.ifr_mtu = value; if (ioctl(eifSocket.sock, SIOCSIFMTU, &ifr) != 0) { log("ioctl failed for SIOCSIFMTU:", entry("ERROR=%s", strerror(errno))); return EthernetInterfaceIntf::mtu(); } EthernetInterfaceIntf::mtu(value); return value; } bool EthernetInterface::queryNicEnabled() const { constexpr auto svc = "org.freedesktop.network1"; constexpr auto intf = "org.freedesktop.network1.Link"; constexpr auto prop = "AdministrativeState"; char* rpath; sd_bus_path_encode("/org/freedesktop/network1/link", std::to_string(ifIndex()).c_str(), &rpath); std::string path(rpath); free(rpath); // Store / Parser for the AdministrativeState return value std::optional ret; auto cb = [&](const std::string& state) { if (state != "initialized") { ret = state != "unmanaged"; } }; // Build a matcher before making the property call to ensure we // can eventually get the value. sdbusplus::bus::match::match match( bus, fmt::format("type='signal',sender='{}',path='{}',interface='{}',member=" "'PropertiesChanged',arg0='{}',", svc, path, PROPERTY_INTERFACE, intf) .c_str(), [&](sdbusplus::message::message& m) { std::string intf; std::unordered_map> values; try { m.read(intf, values); auto it = values.find(prop); // Ignore properties that aren't AdministrativeState if (it != values.end()) { cb(std::get(it->second)); } } catch (const std::exception& e) { log( fmt::format( "AdministrativeState match parsing failed on {}: {}", interfaceName(), e.what()) .c_str(), entry("INTERFACE=%s", interfaceName().c_str()), entry("ERROR=%s", e.what())); } }); // Actively call for the value in case the interface is already configured auto method = bus.new_method_call(svc, path.c_str(), PROPERTY_INTERFACE, METHOD_GET); method.append(intf, prop); try { auto reply = bus.call(method); std::variant state; reply.read(state); cb(std::get(state)); } catch (const std::exception& e) { log( fmt::format("Failed to get AdministrativeState on {}: {}", interfaceName(), e.what()) .c_str(), entry("INTERFACE=%s", interfaceName().c_str()), entry("ERROR=%s", e.what())); } // The interface is not yet configured by systemd-networkd, wait until it // signals us a valid state. while (!ret) { bus.wait(); bus.process_discard(); } return *ret; } bool EthernetInterface::nicEnabled(bool value) { if (value == EthernetInterfaceIntf::nicEnabled()) { return value; } EthernetIntfSocket eifSocket(PF_INET, SOCK_DGRAM, IPPROTO_IP); if (eifSocket.sock < 0) { return EthernetInterfaceIntf::nicEnabled(); } ifreq ifr = {}; std::strncpy(ifr.ifr_name, interfaceName().c_str(), IF_NAMESIZE - 1); if (ioctl(eifSocket.sock, SIOCGIFFLAGS, &ifr) != 0) { log("ioctl failed for SIOCGIFFLAGS:", entry("ERROR=%s", strerror(errno))); return EthernetInterfaceIntf::nicEnabled(); } ifr.ifr_flags &= ~IFF_UP; ifr.ifr_flags |= value ? IFF_UP : 0; if (ioctl(eifSocket.sock, SIOCSIFFLAGS, &ifr) != 0) { log("ioctl failed for SIOCSIFFLAGS:", entry("ERROR=%s", strerror(errno))); return EthernetInterfaceIntf::nicEnabled(); } EthernetInterfaceIntf::nicEnabled(value); writeConfigurationFile(); return value; } ServerList EthernetInterface::nameservers(ServerList /*value*/) { elog(NotAllowedArgument::REASON("ReadOnly Property")); return EthernetInterfaceIntf::nameservers(); } ServerList EthernetInterface::staticNameServers(ServerList value) { for (const auto& nameserverip : value) { if (!isValidIP(AF_INET, nameserverip) && !isValidIP(AF_INET6, nameserverip)) { log("Not a valid IP address"), entry("ADDRESS=%s", nameserverip.c_str()); elog( Argument::ARGUMENT_NAME("StaticNameserver"), Argument::ARGUMENT_VALUE(nameserverip.c_str())); } } try { EthernetInterfaceIntf::staticNameServers(value); writeConfigurationFile(); // resolved reads the DNS server configuration from the // network file. manager.restartSystemdUnit(networkdService); } catch (const InternalFailure& e) { log("Exception processing DNS entries"); } return EthernetInterfaceIntf::staticNameServers(); } void EthernetInterface::loadNameServers() { EthernetInterfaceIntf::nameservers(getNameServerFromResolvd()); EthernetInterfaceIntf::staticNameServers(getstaticNameServerFromConf()); } ServerList EthernetInterface::getstaticNameServerFromConf() { fs::path confPath = manager.getConfDir(); std::string fileName = systemd::config::networkFilePrefix + interfaceName() + systemd::config::networkFileSuffix; confPath /= fileName; ServerList servers; config::Parser parser(confPath.string()); auto rc = config::ReturnCode::SUCCESS; std::tie(rc, servers) = parser.getValues("Network", "DNS"); if (rc != config::ReturnCode::SUCCESS) { log("Unable to get the value for network[DNS]", entry("RC=%d", rc)); } return servers; } ServerList EthernetInterface::getNameServerFromResolvd() { ServerList servers; std::string OBJ_PATH = RESOLVED_SERVICE_PATH + std::to_string(ifIndex()); /* The DNS property under org.freedesktop.resolve1.Link interface contains an array containing all DNS servers currently used by resolved. It contains similar information as the DNS server data written to /run/systemd/resolve/resolv.conf. Each structure in the array consists of a numeric network interface index, an address family, and a byte array containing the DNS server address (either 4 bytes in length for IPv4 or 16 bytes in lengths for IPv6). The array contains DNS servers configured system-wide, including those possibly read from a foreign /etc/resolv.conf or the DNS= setting in /etc/systemd/resolved.conf, as well as per-interface DNS server information either retrieved from systemd-networkd or configured by external software via SetLinkDNS(). */ using type = std::vector>>; std::variant name; // Variable to capture the DNS property auto method = bus.new_method_call(RESOLVED_SERVICE, OBJ_PATH.c_str(), PROPERTY_INTERFACE, METHOD_GET); method.append(RESOLVED_INTERFACE, "DNS"); auto reply = bus.call(method); try { reply.read(name); } catch (const sdbusplus::exception::exception& e) { log("Failed to get DNS information from Systemd-Resolved"); } auto tupleVector = std::get_if(&name); for (auto i = tupleVector->begin(); i != tupleVector->end(); ++i) { int addressFamily = std::get<0>(*i); std::vector& ipaddress = std::get<1>(*i); switch (addressFamily) { case AF_INET: if (ipaddress.size() == sizeof(struct in_addr)) { servers.push_back(toString( *reinterpret_cast(ipaddress.data()))); } else { log( "Invalid data recived from Systemd-Resolved"); } break; case AF_INET6: if (ipaddress.size() == sizeof(struct in6_addr)) { servers.push_back(toString( *reinterpret_cast(ipaddress.data()))); } else { log( "Invalid data recived from Systemd-Resolved"); } break; default: log( "Unsupported address family in DNS from Systemd-Resolved"); break; } } return servers; } void EthernetInterface::loadVLAN(VlanId id) { std::string vlanInterfaceName = interfaceName() + "." + std::to_string(id); std::string path = objPath; path += "_" + std::to_string(id); DHCPConf dhcpEnabled = getDHCPValue(manager.getConfDir().string(), vlanInterfaceName); auto vlanIntf = std::make_unique( bus, path.c_str(), dhcpEnabled, EthernetInterfaceIntf::nicEnabled(), id, *this, manager); // Fetch the ip address from the system // and create the dbus object. vlanIntf->createIPAddressObjects(); vlanIntf->createStaticNeighborObjects(); this->vlanInterfaces.emplace(std::move(vlanInterfaceName), std::move(vlanIntf)); } ObjectPath EthernetInterface::createVLAN(VlanId id) { std::string vlanInterfaceName = interfaceName() + "." + std::to_string(id); std::string path = objPath; path += "_" + std::to_string(id); // Pass the parents nicEnabled property, so that the child // VLAN interface can inherit. auto vlanIntf = std::make_unique( bus, path.c_str(), EthernetInterface::DHCPConf::none, EthernetInterfaceIntf::nicEnabled(), id, *this, manager); // write the device file for the vlan interface. vlanIntf->writeDeviceFile(); this->vlanInterfaces.emplace(vlanInterfaceName, std::move(vlanIntf)); // write the new vlan device entry to the configuration(network) file. manager.writeToConfigurationFile(); return path; } bool EthernetInterface::getIPv6AcceptRAFromConf() { fs::path confPath = manager.getConfDir(); std::string fileName = systemd::config::networkFilePrefix + interfaceName() + systemd::config::networkFileSuffix; confPath /= fileName; config::ValueList values; config::Parser parser(confPath.string()); auto rc = config::ReturnCode::SUCCESS; std::tie(rc, values) = parser.getValues("Network", "IPv6AcceptRA"); if (rc != config::ReturnCode::SUCCESS) { log("Unable to get the value for Network[IPv6AcceptRA]", entry("rc=%d", rc)); return false; } return (values[0] == "true"); } ServerList EthernetInterface::getNTPServersFromConf() { fs::path confPath = manager.getConfDir(); std::string fileName = systemd::config::networkFilePrefix + interfaceName() + systemd::config::networkFileSuffix; confPath /= fileName; ServerList servers; config::Parser parser(confPath.string()); auto rc = config::ReturnCode::SUCCESS; std::tie(rc, servers) = parser.getValues("Network", "NTP"); if (rc != config::ReturnCode::SUCCESS) { log("Unable to get the value for Network[NTP]", entry("rc=%d", rc)); } return servers; } ServerList EthernetInterface::ntpServers(ServerList servers) { auto ntpServers = EthernetInterfaceIntf::ntpServers(servers); writeConfigurationFile(); // timesynchd reads the NTP server configuration from the // network file. manager.restartSystemdUnit(networkdService); return ntpServers; } // Need to merge the below function with the code which writes the // config file during factory reset. // TODO openbmc/openbmc#1751 void EthernetInterface::writeConfigurationFile() { // write all the static ip address in the systemd-network conf file using namespace std::string_literals; namespace fs = std::filesystem; // if there is vlan interafce then write the configuration file // for vlan also. for (const auto& intf : vlanInterfaces) { intf.second->writeConfigurationFile(); } fs::path confPath = manager.getConfDir(); std::string fileName = systemd::config::networkFilePrefix + interfaceName() + systemd::config::networkFileSuffix; confPath /= fileName; std::fstream stream; stream.open(confPath.c_str(), std::fstream::out); if (!stream.is_open()) { log("Unable to open the file", entry("FILE=%s", confPath.c_str())); elog(); } // Write the device stream << "[Match]\n"; stream << "Name=" << interfaceName() << "\n"; auto addrs = getAddresses(); // Write the link section stream << "[Link]\n"; auto mac = MacAddressIntf::macAddress(); if (!mac.empty()) { stream << "MACAddress=" << mac << "\n"; } if (!EthernetInterfaceIntf::nicEnabled()) { stream << "Unmanaged=yes\n"; } // write the network section stream << "[Network]\n"; #ifdef LINK_LOCAL_AUTOCONFIGURATION stream << "LinkLocalAddressing=yes\n"; #else stream << "LinkLocalAddressing=no\n"; #endif stream << std::boolalpha << "IPv6AcceptRA=" << EthernetInterfaceIntf::ipv6AcceptRA() << "\n"; // Add the VLAN entry for (const auto& intf : vlanInterfaces) { stream << "VLAN=" << intf.second->EthernetInterface::interfaceName() << "\n"; } // Add the NTP server for (const auto& ntp : EthernetInterfaceIntf::ntpServers()) { stream << "NTP=" << ntp << "\n"; } // Add the DNS entry for (const auto& dns : EthernetInterfaceIntf::staticNameServers()) { stream << "DNS=" << dns << "\n"; } // Add the DHCP entry stream << "DHCP="s + mapDHCPToSystemd[EthernetInterfaceIntf::dhcpEnabled()] + "\n"; // Static IP addresses for (const auto& addr : addrs) { if (originIsManuallyAssigned(addr.second->origin()) && !dhcpIsEnabled(addr.second->type())) { // Process all static addresses std::string address = addr.second->address() + "/" + std::to_string(addr.second->prefixLength()); // build the address entries. Do not use [Network] shortcuts to // insert address entries. stream << "[Address]\n"; stream << "Address=" << address << "\n"; } } if (!dhcpIsEnabled(IP::Protocol::IPv4)) { auto gateway = EthernetInterfaceIntf::defaultGateway(); if (!gateway.empty()) { stream << "[Route]\n"; stream << "Gateway=" << gateway << "\n"; } } if (!dhcpIsEnabled(IP::Protocol::IPv6)) { auto gateway6 = EthernetInterfaceIntf::defaultGateway6(); if (!gateway6.empty()) { stream << "[Route]\n"; stream << "Gateway=" << gateway6 << "\n"; } } // Write the neighbor sections for (const auto& neighbor : staticNeighbors) { stream << "[Neighbor]" << "\n"; stream << "Address=" << neighbor.second->ipAddress() << "\n"; stream << "MACAddress=" << neighbor.second->macAddress() << "\n"; } // Write the dhcp section irrespective of whether DHCP is enabled or not writeDHCPSection(stream); stream.close(); } void EthernetInterface::writeDHCPSection(std::fstream& stream) { using namespace std::string_literals; // write the dhcp section stream << "[DHCP]\n"; // Hardcoding the client identifier to mac, to address below issue // https://github.com/openbmc/openbmc/issues/1280 stream << "ClientIdentifier=mac\n"; if (manager.getDHCPConf()) { auto value = manager.getDHCPConf()->dnsEnabled() ? "true"s : "false"s; stream << "UseDNS="s + value + "\n"; value = manager.getDHCPConf()->ntpEnabled() ? "true"s : "false"s; stream << "UseNTP="s + value + "\n"; value = manager.getDHCPConf()->hostNameEnabled() ? "true"s : "false"s; stream << "UseHostname="s + value + "\n"; value = manager.getDHCPConf()->sendHostNameEnabled() ? "true"s : "false"s; stream << "SendHostname="s + value + "\n"; } } std::string EthernetInterface::macAddress(std::string value) { ether_addr newMAC; try { newMAC = mac_address::fromString(value); } catch (const std::invalid_argument&) { log("MACAddress is not valid.", entry("MAC=%s", value.c_str())); elog(Argument::ARGUMENT_NAME("MACAddress"), Argument::ARGUMENT_VALUE(value.c_str())); } if (!mac_address::isUnicast(newMAC)) { log("MACAddress is not valid.", entry("MAC=%s", value.c_str())); elog(Argument::ARGUMENT_NAME("MACAddress"), Argument::ARGUMENT_VALUE(value.c_str())); } auto interface = interfaceName(); std::string validMAC = mac_address::toString(newMAC); // We don't need to update the system if the address is unchanged ether_addr oldMAC = mac_address::fromString(MacAddressIntf::macAddress()); if (!stdplus::raw::equal(newMAC, oldMAC)) { // Update everything that depends on the MAC value for (const auto& [name, intf] : vlanInterfaces) { intf->MacAddressIntf::macAddress(validMAC); } MacAddressIntf::macAddress(validMAC); // TODO: would remove the call below and // just restart systemd-netwokd // through https://github.com/systemd/systemd/issues/6696 execute("/sbin/ip", "ip", "link", "set", "dev", interface.c_str(), "down"); manager.writeToConfigurationFile(); } #ifdef HAVE_UBOOT_ENV // Ensure that the valid address is stored in the u-boot-env auto envVar = interfaceToUbootEthAddr(interface.c_str()); if (envVar) { // Trimming MAC addresses that are out of range. eg: AA:FF:FF:FF:FF:100; // and those having more than 6 bytes. eg: AA:AA:AA:AA:AA:AA:BB execute("/sbin/fw_setenv", "fw_setenv", envVar->c_str(), validMAC.c_str()); } #endif // HAVE_UBOOT_ENV return value; } void EthernetInterface::deleteAll() { if (dhcpIsEnabled(IP::Protocol::IPv4, true)) { log("DHCP enabled on the interface"), entry("INTERFACE=%s", interfaceName().c_str()); } // clear all the ip on the interface addrs.clear(); manager.writeToConfigurationFile(); } std::string EthernetInterface::defaultGateway(std::string gateway) { auto gw = EthernetInterfaceIntf::defaultGateway(); if (gw == gateway) { return gw; } if (!isValidIP(AF_INET, gateway)) { log("Not a valid v4 Gateway", entry("GATEWAY=%s", gateway.c_str())); elog(Argument::ARGUMENT_NAME("GATEWAY"), Argument::ARGUMENT_VALUE(gateway.c_str())); } gw = EthernetInterfaceIntf::defaultGateway(gateway); manager.writeToConfigurationFile(); return gw; } std::string EthernetInterface::defaultGateway6(std::string gateway) { auto gw = EthernetInterfaceIntf::defaultGateway6(); if (gw == gateway) { return gw; } if (!isValidIP(AF_INET6, gateway)) { log("Not a valid v6 Gateway", entry("GATEWAY=%s", gateway.c_str())); elog(Argument::ARGUMENT_NAME("GATEWAY"), Argument::ARGUMENT_VALUE(gateway.c_str())); } gw = EthernetInterfaceIntf::defaultGateway6(gateway); manager.writeToConfigurationFile(); return gw; } } // namespace network } // namespace phosphor