dhcp/dhcpv4_config.cc - aosp/platform/system/connectivity/shill - Git at Google

 //
 // Copyright (C) 2015 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 "shill/dhcp/dhcpv4_config.h"

 #include <arpa/inet.h>

 #include <base/files/file_util.h>
 #include <base/strings/string_split.h>
 #include <base/strings/stringprintf.h>
 #include <chromeos/dbus/service_constants.h>

 #include "shill/dhcp/dhcp_provider.h"
 #include "shill/logging.h"
 #include "shill/metrics.h"
 #include "shill/net/ip_address.h"

 using std::string;
 using std::vector;

 namespace shill {

 namespace Logging {
 static auto kModuleLogScope = ScopeLogger::kDHCP;
 static string ObjectID(DHCPv4Config* d) {
   if (d == nullptr)
     return "(DHCPv4_config)";
   else
     return d->device_name();
 }
 }

 // static
 const char DHCPv4Config::kDHCPCDPathFormatPID[] =
     "var/run/dhcpcd/dhcpcd-%s-4.pid";
 const char DHCPv4Config::kConfigurationKeyBroadcastAddress[] =
     "BroadcastAddress";
 const char DHCPv4Config::kConfigurationKeyClasslessStaticRoutes[] =
     "ClasslessStaticRoutes";
 const char DHCPv4Config::kConfigurationKeyDNS[] = "DomainNameServers";
 const char DHCPv4Config::kConfigurationKeyDomainName[] = "DomainName";
 const char DHCPv4Config::kConfigurationKeyDomainSearch[] = "DomainSearch";
 const char DHCPv4Config::kConfigurationKeyHostname[] = "Hostname";
 const char DHCPv4Config::kConfigurationKeyIPAddress[] = "IPAddress";
 const char DHCPv4Config::kConfigurationKeyiSNSOptionData[] = "iSNSOptionData";
 const char DHCPv4Config::kConfigurationKeyLeaseTime[] = "DHCPLeaseTime";
 const char DHCPv4Config::kConfigurationKeyMTU[] = "InterfaceMTU";
 const char DHCPv4Config::kConfigurationKeyRouters[] = "Routers";
 const char DHCPv4Config::kConfigurationKeySubnetCIDR[] = "SubnetCIDR";
 const char DHCPv4Config::kConfigurationKeyVendorEncapsulatedOptions[] =
     "VendorEncapsulatedOptions";
 const char DHCPv4Config::kConfigurationKeyWebProxyAutoDiscoveryUrl[] =
     "WebProxyAutoDiscoveryUrl";
 const char DHCPv4Config::kReasonBound[] = "BOUND";
 const char DHCPv4Config::kReasonFail[] = "FAIL";
 const char DHCPv4Config::kReasonGatewayArp[] = "GATEWAY-ARP";
 const char DHCPv4Config::kReasonNak[] = "NAK";
 const char DHCPv4Config::kReasonRebind[] = "REBIND";
 const char DHCPv4Config::kReasonReboot[] = "REBOOT";
 const char DHCPv4Config::kReasonRenew[] = "RENEW";
 const char DHCPv4Config::kStatusArpGateway[] = "ArpGateway";
 const char DHCPv4Config::kStatusArpSelf[] = "ArpSelf";
 const char DHCPv4Config::kStatusBound[] = "Bound";
 const char DHCPv4Config::kStatusDiscover[] = "Discover";
 const char DHCPv4Config::kStatusIgnoreAdditionalOffer[] =
     "IgnoreAdditionalOffer";
 const char DHCPv4Config::kStatusIgnoreFailedOffer[] = "IgnoreFailedOffer";
 const char DHCPv4Config::kStatusIgnoreInvalidOffer[] = "IgnoreInvalidOffer";
 const char DHCPv4Config::kStatusIgnoreNonOffer[] = "IgnoreNonOffer";
 const char DHCPv4Config::kStatusInform[] = "Inform";
 const char DHCPv4Config::kStatusInit[] = "Init";
 const char DHCPv4Config::kStatusNakDefer[] = "NakDefer";
 const char DHCPv4Config::kStatusRebind[] = "Rebind";
 const char DHCPv4Config::kStatusReboot[] = "Reboot";
 const char DHCPv4Config::kStatusRelease[] = "Release";
 const char DHCPv4Config::kStatusRenew[] = "Renew";
 const char DHCPv4Config::kStatusRequest[] = "Request";
 const char DHCPv4Config::kType[] = "dhcp";


 DHCPv4Config::DHCPv4Config(ControlInterface* control_interface,
                            EventDispatcher* dispatcher,
                            DHCPProvider* provider,
                            const string& device_name,
                            const string& lease_file_suffix,
                            bool arp_gateway,
                            const DhcpProperties& dhcp_props,
                            Metrics* metrics)
     : DHCPConfig(control_interface,
                  dispatcher,
                  provider,
                  device_name,
                  kType,
                  lease_file_suffix),
       arp_gateway_(arp_gateway),
       is_gateway_arp_active_(false),
       metrics_(metrics) {
   dhcp_props.GetValueForProperty(DhcpProperties::kHostnameProperty, &hostname_);
   dhcp_props.GetValueForProperty(DhcpProperties::kVendorClassProperty,
                                  &vendor_class_);
   SLOG(this, 2) << __func__ << ": " << device_name;
 }

 DHCPv4Config::~DHCPv4Config() {
   SLOG(this, 2) << __func__ << ": " << device_name();
 }

 void DHCPv4Config::ProcessEventSignal(const string& reason,
                                       const KeyValueStore& configuration) {
   LOG(INFO) << "Event reason: " << reason;
   if (reason == kReasonFail) {
     LOG(ERROR) << "Received failure event from DHCP client.";
     NotifyFailure();
     return;
   } else if (reason == kReasonNak) {
     // If we got a NAK, this means the DHCP server is active, and any
     // Gateway ARP state we have is no longer sufficient.
     LOG_IF(ERROR, is_gateway_arp_active_)
         << "Received NAK event for our gateway-ARP lease.";
     is_gateway_arp_active_ = false;
     return;
   } else if (reason != kReasonBound &&
       reason != kReasonRebind &&
       reason != kReasonReboot &&
       reason != kReasonRenew &&
       reason != kReasonGatewayArp) {
     LOG(WARNING) << "Event ignored.";
     return;
   }
   IPConfig::Properties properties;
   CHECK(ParseConfiguration(configuration, &properties));

   // This needs to be set before calling UpdateProperties() below since
   // those functions may indirectly call other methods like ReleaseIP that
   // depend on or change this value.
   set_is_lease_active(true);

   if (reason == kReasonGatewayArp) {
     // This is a non-authoritative confirmation that we or on the same
     // network as the one we received a lease on previously.  The DHCP
     // client is still running, so we should not cancel the timeout
     // until that completes.  In the meantime, however, we can tentatively
     // configure our network in anticipation of successful completion.
     IPConfig::UpdateProperties(properties, false);
     is_gateway_arp_active_ = true;
   } else {
     DHCPConfig::UpdateProperties(properties, true);
     is_gateway_arp_active_ = false;
   }
 }

 void DHCPv4Config::ProcessStatusChangeSignal(const string& status) {
   SLOG(this, 2) << __func__ << ": " << status;

   if (status == kStatusArpGateway) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusArpGateway);
   } else if (status == kStatusArpSelf) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusArpSelf);
   } else if (status == kStatusBound) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusBound);
   } else if (status == kStatusDiscover) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusDiscover);
   } else if (status == kStatusIgnoreAdditionalOffer) {
     metrics_->NotifyDhcpClientStatus(
         Metrics::kDhcpClientStatusIgnoreAdditionalOffer);
   } else if (status == kStatusIgnoreFailedOffer) {
     metrics_->NotifyDhcpClientStatus(
         Metrics::kDhcpClientStatusIgnoreFailedOffer);
   } else if (status == kStatusIgnoreInvalidOffer) {
     metrics_->NotifyDhcpClientStatus(
         Metrics::kDhcpClientStatusIgnoreInvalidOffer);
   } else if (status == kStatusIgnoreNonOffer) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusIgnoreNonOffer);
   } else if (status == kStatusInform) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusInform);
   } else if (status == kStatusInit) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusInit);
   } else if (status == kStatusNakDefer) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusNakDefer);
   } else if (status == kStatusRebind) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRebind);
   } else if (status == kStatusReboot) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusReboot);
   } else if (status == kStatusRelease) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRelease);
   } else if (status == kStatusRenew) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRenew);
   } else if (status == kStatusRequest) {
     metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRequest);
   } else {
     LOG(ERROR) << "DHCP client reports unknown status " << status;
   }
 }

 void DHCPv4Config::CleanupClientState() {
   DHCPConfig::CleanupClientState();

   // Delete lease file if it is ephemeral.
   if (IsEphemeralLease()) {
     base::DeleteFile(root().Append(
         base::StringPrintf(DHCPProvider::kDHCPCDPathFormatLease,
                            device_name().c_str())), false);
   }
   base::DeleteFile(root().Append(
       base::StringPrintf(kDHCPCDPathFormatPID, device_name().c_str())), false);
   is_gateway_arp_active_ = false;
 }

 bool DHCPv4Config::ShouldFailOnAcquisitionTimeout() {
   // Continue to use previous lease if gateway ARP is active.
   return !is_gateway_arp_active_;
 }

 bool DHCPv4Config::ShouldKeepLeaseOnDisconnect() {
   // If we are using gateway unicast ARP to speed up re-connect, don't
   // give up our leases when we disconnect.
   return arp_gateway_;
 }

 vector<string> DHCPv4Config::GetFlags() {
   // Get default flags first.
   vector<string> flags = DHCPConfig::GetFlags();

   flags.push_back("-4");  // IPv4 only.

   // Apply options from DhcpProperties when applicable.
   if (!hostname_.empty()) {
     flags.push_back("-h");  // Request hostname from server
     flags.push_back(hostname_);
   }
   if (!vendor_class_.empty()) {
     flags.push_back("-i");
     flags.push_back(vendor_class_);
   }

   if (arp_gateway_) {
     flags.push_back("-R");  // ARP for default gateway.
     flags.push_back("-P");  // Enable unicast ARP on renew.
   }
   return flags;
 }

 // static
 string DHCPv4Config::GetIPv4AddressString(unsigned int address) {
   char str[INET_ADDRSTRLEN];
   if (inet_ntop(AF_INET, &address, str, arraysize(str))) {
     return str;
   }
   LOG(ERROR) << "Unable to convert IPv4 address to string: " << address;
   return "";
 }

 // static
 bool DHCPv4Config::ParseClasslessStaticRoutes(
     const string& classless_routes, IPConfig::Properties* properties) {
   if (classless_routes.empty()) {
     // It is not an error for this string to be empty.
     return true;
   }

   vector<string> route_strings = base::SplitString(
       classless_routes, " ", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL);
   if (route_strings.size() % 2) {
     LOG(ERROR) << "In " << __func__ << ": Size of route_strings array "
                << "is a non-even number: " << route_strings.size();
     return false;
   }

   vector<IPConfig::Route> routes;
   vector<string>::iterator route_iterator = route_strings.begin();
   // Classless routes are a space-delimited array of
   // "destination/prefix gateway" values.  As such, we iterate twice
   // for each pass of the loop below.
   while (route_iterator != route_strings.end()) {
     const string& destination_as_string(*route_iterator);
     route_iterator++;
     IPAddress destination(IPAddress::kFamilyIPv4);
     if (!destination.SetAddressAndPrefixFromString(
              destination_as_string)) {
       LOG(ERROR) << "In " << __func__ << ": Expected an IP address/prefix "
                  << "but got an unparsable: " << destination_as_string;
       return false;
     }

     CHECK(route_iterator != route_strings.end());
     const string& gateway_as_string(*route_iterator);
     route_iterator++;
     IPAddress gateway(IPAddress::kFamilyIPv4);
     if (!gateway.SetAddressFromString(gateway_as_string)) {
       LOG(ERROR) << "In " << __func__ << ": Expected a router IP address "
                  << "but got an unparsable: " << gateway_as_string;
       return false;
     }

     if (destination.prefix() == 0 && properties->gateway.empty()) {
       // If a default route is provided in the classless parameters and
       // we don't already have one, apply this as the default route.
       SLOG(nullptr, 2) << "In " << __func__ << ": Setting default gateway to "
                     << gateway_as_string;
       CHECK(gateway.IntoString(&properties->gateway));
     } else {
       IPConfig::Route route;
       CHECK(destination.IntoString(&route.host));
       route.prefix = destination.prefix();
       CHECK(gateway.IntoString(&route.gateway));
       routes.push_back(route);
       SLOG(nullptr, 2) << "In " << __func__ << ": Adding route to to "
                     << destination_as_string << " via " << gateway_as_string;
     }
   }

   if (!routes.empty()) {
     properties->routes.swap(routes);
   }

   return true;
 }

 // static
 bool DHCPv4Config::ParseConfiguration(const KeyValueStore& configuration,
                                       IPConfig::Properties* properties) {
   SLOG(nullptr, 2) << __func__;
   properties->method = kTypeDHCP;
   properties->address_family = IPAddress::kFamilyIPv4;
   string classless_static_routes;
   bool default_gateway_parse_error = false;
   for (const auto it :  configuration.properties()) {
     const string& key = it.first;
     const brillo::Any& value = it.second;
     SLOG(nullptr, 2) << "Processing key: " << key;
     if (key == kConfigurationKeyIPAddress) {
       properties->address = GetIPv4AddressString(value.Get<uint32_t>());
       if (properties->address.empty()) {
         return false;
       }
     } else if (key == kConfigurationKeySubnetCIDR) {
       properties->subnet_prefix = value.Get<uint8_t>();
     } else if (key == kConfigurationKeyBroadcastAddress) {
       properties->broadcast_address =
           GetIPv4AddressString(value.Get<uint32_t>());
       if (properties->broadcast_address.empty()) {
         return false;
       }
     } else if (key == kConfigurationKeyRouters) {
       vector<uint32_t> routers = value.Get<vector<uint32_t>>();
       if (routers.empty()) {
         LOG(ERROR) << "No routers provided.";
         default_gateway_parse_error = true;
       } else {
         properties->gateway = GetIPv4AddressString(routers[0]);
         if (properties->gateway.empty()) {
           LOG(ERROR) << "Failed to parse router parameter provided.";
           default_gateway_parse_error = true;
         }
       }
     } else if (key == kConfigurationKeyDNS) {
       vector<uint32_t> servers = value.Get<vector<uint32_t>>();
       for (vector<unsigned int>::const_iterator it = servers.begin();
            it != servers.end(); ++it) {
         string server = GetIPv4AddressString(*it);
         if (server.empty()) {
           return false;
         }
         properties->dns_servers.push_back(server);
       }
     } else if (key == kConfigurationKeyDomainName) {
       properties->domain_name = value.Get<string>();
     } else if (key == kConfigurationKeyHostname) {
       properties->accepted_hostname = value.Get<string>();
     } else if (key == kConfigurationKeyDomainSearch) {
       properties->domain_search = value.Get<vector<string>>();
     } else if (key == kConfigurationKeyMTU) {
       int mtu = value.Get<uint16_t>();
       metrics_->SendSparseToUMA(Metrics::kMetricDhcpClientMTUValue, mtu);
       if (mtu >= minimum_mtu() && mtu != kMinIPv4MTU) {
         properties->mtu = mtu;
       }
     } else if (key == kConfigurationKeyClasslessStaticRoutes) {
       classless_static_routes = value.Get<string>();
     } else if (key == kConfigurationKeyVendorEncapsulatedOptions) {
       properties->vendor_encapsulated_options = value.Get<ByteArray>();
     } else if (key == kConfigurationKeyWebProxyAutoDiscoveryUrl) {
       properties->web_proxy_auto_discovery = value.Get<string>();
     } else if (key == kConfigurationKeyLeaseTime) {
       properties->lease_duration_seconds = value.Get<uint32_t>();
     } else if (key == kConfigurationKeyiSNSOptionData) {
       properties->isns_option_data = value.Get<ByteArray>();
     } else {
       SLOG(nullptr, 2) << "Key ignored.";
     }
   }
   ParseClasslessStaticRoutes(classless_static_routes, properties);
   if (default_gateway_parse_error && properties->gateway.empty()) {
     return false;
   }
   return true;
 }

 }  // namespace shill
	//
	// Copyright (C) 2015 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 "shill/dhcp/dhcpv4_config.h"

	#include <arpa/inet.h>

	#include <base/files/file_util.h>
	#include <base/strings/string_split.h>
	#include <base/strings/stringprintf.h>
	#include <chromeos/dbus/service_constants.h>

	#include "shill/dhcp/dhcp_provider.h"
	#include "shill/logging.h"
	#include "shill/metrics.h"
	#include "shill/net/ip_address.h"

	using std::string;
	using std::vector;

	namespace shill {

	namespace Logging {
	static auto kModuleLogScope = ScopeLogger::kDHCP;
	static string ObjectID(DHCPv4Config* d) {
	if (d == nullptr)
	return "(DHCPv4_config)";
	else
	return d->device_name();
	}
	}

	// static
	const char DHCPv4Config::kDHCPCDPathFormatPID[] =
	"var/run/dhcpcd/dhcpcd-%s-4.pid";
	const char DHCPv4Config::kConfigurationKeyBroadcastAddress[] =
	"BroadcastAddress";
	const char DHCPv4Config::kConfigurationKeyClasslessStaticRoutes[] =
	"ClasslessStaticRoutes";
	const char DHCPv4Config::kConfigurationKeyDNS[] = "DomainNameServers";
	const char DHCPv4Config::kConfigurationKeyDomainName[] = "DomainName";
	const char DHCPv4Config::kConfigurationKeyDomainSearch[] = "DomainSearch";
	const char DHCPv4Config::kConfigurationKeyHostname[] = "Hostname";
	const char DHCPv4Config::kConfigurationKeyIPAddress[] = "IPAddress";
	const char DHCPv4Config::kConfigurationKeyiSNSOptionData[] = "iSNSOptionData";
	const char DHCPv4Config::kConfigurationKeyLeaseTime[] = "DHCPLeaseTime";
	const char DHCPv4Config::kConfigurationKeyMTU[] = "InterfaceMTU";
	const char DHCPv4Config::kConfigurationKeyRouters[] = "Routers";
	const char DHCPv4Config::kConfigurationKeySubnetCIDR[] = "SubnetCIDR";
	const char DHCPv4Config::kConfigurationKeyVendorEncapsulatedOptions[] =
	"VendorEncapsulatedOptions";
	const char DHCPv4Config::kConfigurationKeyWebProxyAutoDiscoveryUrl[] =
	"WebProxyAutoDiscoveryUrl";
	const char DHCPv4Config::kReasonBound[] = "BOUND";
	const char DHCPv4Config::kReasonFail[] = "FAIL";
	const char DHCPv4Config::kReasonGatewayArp[] = "GATEWAY-ARP";
	const char DHCPv4Config::kReasonNak[] = "NAK";
	const char DHCPv4Config::kReasonRebind[] = "REBIND";
	const char DHCPv4Config::kReasonReboot[] = "REBOOT";
	const char DHCPv4Config::kReasonRenew[] = "RENEW";
	const char DHCPv4Config::kStatusArpGateway[] = "ArpGateway";
	const char DHCPv4Config::kStatusArpSelf[] = "ArpSelf";
	const char DHCPv4Config::kStatusBound[] = "Bound";
	const char DHCPv4Config::kStatusDiscover[] = "Discover";
	const char DHCPv4Config::kStatusIgnoreAdditionalOffer[] =
	"IgnoreAdditionalOffer";
	const char DHCPv4Config::kStatusIgnoreFailedOffer[] = "IgnoreFailedOffer";
	const char DHCPv4Config::kStatusIgnoreInvalidOffer[] = "IgnoreInvalidOffer";
	const char DHCPv4Config::kStatusIgnoreNonOffer[] = "IgnoreNonOffer";
	const char DHCPv4Config::kStatusInform[] = "Inform";
	const char DHCPv4Config::kStatusInit[] = "Init";
	const char DHCPv4Config::kStatusNakDefer[] = "NakDefer";
	const char DHCPv4Config::kStatusRebind[] = "Rebind";
	const char DHCPv4Config::kStatusReboot[] = "Reboot";
	const char DHCPv4Config::kStatusRelease[] = "Release";
	const char DHCPv4Config::kStatusRenew[] = "Renew";
	const char DHCPv4Config::kStatusRequest[] = "Request";
	const char DHCPv4Config::kType[] = "dhcp";


	DHCPv4Config::DHCPv4Config(ControlInterface* control_interface,
	EventDispatcher* dispatcher,
	DHCPProvider* provider,
	const string& device_name,
	const string& lease_file_suffix,
	bool arp_gateway,
	const DhcpProperties& dhcp_props,
	Metrics* metrics)
	: DHCPConfig(control_interface,
	dispatcher,
	provider,
	device_name,
	kType,
	lease_file_suffix),
	arp_gateway_(arp_gateway),
	is_gateway_arp_active_(false),
	metrics_(metrics) {
	dhcp_props.GetValueForProperty(DhcpProperties::kHostnameProperty, &hostname_);
	dhcp_props.GetValueForProperty(DhcpProperties::kVendorClassProperty,
	&vendor_class_);
	SLOG(this, 2) << __func__ << ": " << device_name;
	}

	DHCPv4Config::~DHCPv4Config() {
	SLOG(this, 2) << __func__ << ": " << device_name();
	}

	void DHCPv4Config::ProcessEventSignal(const string& reason,
	const KeyValueStore& configuration) {
	LOG(INFO) << "Event reason: " << reason;
	if (reason == kReasonFail) {
	LOG(ERROR) << "Received failure event from DHCP client.";
	NotifyFailure();
	return;
	} else if (reason == kReasonNak) {
	// If we got a NAK, this means the DHCP server is active, and any
	// Gateway ARP state we have is no longer sufficient.
	LOG_IF(ERROR, is_gateway_arp_active_)
	<< "Received NAK event for our gateway-ARP lease.";
	is_gateway_arp_active_ = false;
	return;
	} else if (reason != kReasonBound &&
	reason != kReasonRebind &&
	reason != kReasonReboot &&
	reason != kReasonRenew &&
	reason != kReasonGatewayArp) {
	LOG(WARNING) << "Event ignored.";
	return;
	}
	IPConfig::Properties properties;
	CHECK(ParseConfiguration(configuration, &properties));

	// This needs to be set before calling UpdateProperties() below since
	// those functions may indirectly call other methods like ReleaseIP that
	// depend on or change this value.
	set_is_lease_active(true);

	if (reason == kReasonGatewayArp) {
	// This is a non-authoritative confirmation that we or on the same
	// network as the one we received a lease on previously. The DHCP
	// client is still running, so we should not cancel the timeout
	// until that completes. In the meantime, however, we can tentatively
	// configure our network in anticipation of successful completion.
	IPConfig::UpdateProperties(properties, false);
	is_gateway_arp_active_ = true;
	} else {
	DHCPConfig::UpdateProperties(properties, true);
	is_gateway_arp_active_ = false;
	}
	}

	void DHCPv4Config::ProcessStatusChangeSignal(const string& status) {
	SLOG(this, 2) << __func__ << ": " << status;

	if (status == kStatusArpGateway) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusArpGateway);
	} else if (status == kStatusArpSelf) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusArpSelf);
	} else if (status == kStatusBound) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusBound);
	} else if (status == kStatusDiscover) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusDiscover);
	} else if (status == kStatusIgnoreAdditionalOffer) {
	metrics_->NotifyDhcpClientStatus(
	Metrics::kDhcpClientStatusIgnoreAdditionalOffer);
	} else if (status == kStatusIgnoreFailedOffer) {
	metrics_->NotifyDhcpClientStatus(
	Metrics::kDhcpClientStatusIgnoreFailedOffer);
	} else if (status == kStatusIgnoreInvalidOffer) {
	metrics_->NotifyDhcpClientStatus(
	Metrics::kDhcpClientStatusIgnoreInvalidOffer);
	} else if (status == kStatusIgnoreNonOffer) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusIgnoreNonOffer);
	} else if (status == kStatusInform) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusInform);
	} else if (status == kStatusInit) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusInit);
	} else if (status == kStatusNakDefer) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusNakDefer);
	} else if (status == kStatusRebind) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRebind);
	} else if (status == kStatusReboot) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusReboot);
	} else if (status == kStatusRelease) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRelease);
	} else if (status == kStatusRenew) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRenew);
	} else if (status == kStatusRequest) {
	metrics_->NotifyDhcpClientStatus(Metrics::kDhcpClientStatusRequest);
	} else {
	LOG(ERROR) << "DHCP client reports unknown status " << status;
	}
	}

	void DHCPv4Config::CleanupClientState() {
	DHCPConfig::CleanupClientState();

	// Delete lease file if it is ephemeral.
	if (IsEphemeralLease()) {
	base::DeleteFile(root().Append(
	base::StringPrintf(DHCPProvider::kDHCPCDPathFormatLease,
	device_name().c_str())), false);
	}
	base::DeleteFile(root().Append(
	base::StringPrintf(kDHCPCDPathFormatPID, device_name().c_str())), false);
	is_gateway_arp_active_ = false;
	}

	bool DHCPv4Config::ShouldFailOnAcquisitionTimeout() {
	// Continue to use previous lease if gateway ARP is active.
	return !is_gateway_arp_active_;
	}

	bool DHCPv4Config::ShouldKeepLeaseOnDisconnect() {
	// If we are using gateway unicast ARP to speed up re-connect, don't
	// give up our leases when we disconnect.
	return arp_gateway_;
	}

	vector<string> DHCPv4Config::GetFlags() {
	// Get default flags first.
	vector<string> flags = DHCPConfig::GetFlags();

	flags.push_back("-4"); // IPv4 only.

	// Apply options from DhcpProperties when applicable.
	if (!hostname_.empty()) {
	flags.push_back("-h"); // Request hostname from server
	flags.push_back(hostname_);
	}
	if (!vendor_class_.empty()) {
	flags.push_back("-i");
	flags.push_back(vendor_class_);
	}

	if (arp_gateway_) {
	flags.push_back("-R"); // ARP for default gateway.
	flags.push_back("-P"); // Enable unicast ARP on renew.
	}
	return flags;
	}

	// static
	string DHCPv4Config::GetIPv4AddressString(unsigned int address) {
	char str[INET_ADDRSTRLEN];
	if (inet_ntop(AF_INET, &address, str, arraysize(str))) {
	return str;
	}
	LOG(ERROR) << "Unable to convert IPv4 address to string: " << address;
	return "";
	}

	// static
	bool DHCPv4Config::ParseClasslessStaticRoutes(
	const string& classless_routes, IPConfig::Properties* properties) {
	if (classless_routes.empty()) {
	// It is not an error for this string to be empty.
	return true;
	}

	vector<string> route_strings = base::SplitString(
	classless_routes, " ", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL);
	if (route_strings.size() % 2) {
	LOG(ERROR) << "In " << __func__ << ": Size of route_strings array "
	<< "is a non-even number: " << route_strings.size();
	return false;
	}

	vector<IPConfig::Route> routes;
	vector<string>::iterator route_iterator = route_strings.begin();
	// Classless routes are a space-delimited array of
	// "destination/prefix gateway" values. As such, we iterate twice
	// for each pass of the loop below.
	while (route_iterator != route_strings.end()) {
	const string& destination_as_string(*route_iterator);
	route_iterator++;
	IPAddress destination(IPAddress::kFamilyIPv4);
	if (!destination.SetAddressAndPrefixFromString(
	destination_as_string)) {
	LOG(ERROR) << "In " << __func__ << ": Expected an IP address/prefix "
	<< "but got an unparsable: " << destination_as_string;
	return false;
	}

	CHECK(route_iterator != route_strings.end());
	const string& gateway_as_string(*route_iterator);
	route_iterator++;
	IPAddress gateway(IPAddress::kFamilyIPv4);
	if (!gateway.SetAddressFromString(gateway_as_string)) {
	LOG(ERROR) << "In " << __func__ << ": Expected a router IP address "
	<< "but got an unparsable: " << gateway_as_string;
	return false;
	}

	if (destination.prefix() == 0 && properties->gateway.empty()) {
	// If a default route is provided in the classless parameters and
	// we don't already have one, apply this as the default route.
	SLOG(nullptr, 2) << "In " << __func__ << ": Setting default gateway to "
	<< gateway_as_string;
	CHECK(gateway.IntoString(&properties->gateway));
	} else {
	IPConfig::Route route;
	CHECK(destination.IntoString(&route.host));
	route.prefix = destination.prefix();
	CHECK(gateway.IntoString(&route.gateway));
	routes.push_back(route);
	SLOG(nullptr, 2) << "In " << __func__ << ": Adding route to to "
	<< destination_as_string << " via " << gateway_as_string;
	}
	}

	if (!routes.empty()) {
	properties->routes.swap(routes);
	}

	return true;
	}

	// static
	bool DHCPv4Config::ParseConfiguration(const KeyValueStore& configuration,
	IPConfig::Properties* properties) {
	SLOG(nullptr, 2) << __func__;
	properties->method = kTypeDHCP;
	properties->address_family = IPAddress::kFamilyIPv4;
	string classless_static_routes;
	bool default_gateway_parse_error = false;
	for (const auto it : configuration.properties()) {
	const string& key = it.first;
	const brillo::Any& value = it.second;
	SLOG(nullptr, 2) << "Processing key: " << key;
	if (key == kConfigurationKeyIPAddress) {
	properties->address = GetIPv4AddressString(value.Get<uint32_t>());
	if (properties->address.empty()) {
	return false;
	}
	} else if (key == kConfigurationKeySubnetCIDR) {
	properties->subnet_prefix = value.Get<uint8_t>();
	} else if (key == kConfigurationKeyBroadcastAddress) {
	properties->broadcast_address =
	GetIPv4AddressString(value.Get<uint32_t>());
	if (properties->broadcast_address.empty()) {
	return false;
	}
	} else if (key == kConfigurationKeyRouters) {
	vector<uint32_t> routers = value.Get<vector<uint32_t>>();
	if (routers.empty()) {
	LOG(ERROR) << "No routers provided.";
	default_gateway_parse_error = true;
	} else {
	properties->gateway = GetIPv4AddressString(routers[0]);
	if (properties->gateway.empty()) {
	LOG(ERROR) << "Failed to parse router parameter provided.";
	default_gateway_parse_error = true;
	}
	}
	} else if (key == kConfigurationKeyDNS) {
	vector<uint32_t> servers = value.Get<vector<uint32_t>>();
	for (vector<unsigned int>::const_iterator it = servers.begin();
	it != servers.end(); ++it) {
	string server = GetIPv4AddressString(*it);
	if (server.empty()) {
	return false;
	}
	properties->dns_servers.push_back(server);
	}
	} else if (key == kConfigurationKeyDomainName) {
	properties->domain_name = value.Get<string>();
	} else if (key == kConfigurationKeyHostname) {
	properties->accepted_hostname = value.Get<string>();
	} else if (key == kConfigurationKeyDomainSearch) {
	properties->domain_search = value.Get<vector<string>>();
	} else if (key == kConfigurationKeyMTU) {
	int mtu = value.Get<uint16_t>();
	metrics_->SendSparseToUMA(Metrics::kMetricDhcpClientMTUValue, mtu);
	if (mtu >= minimum_mtu() && mtu != kMinIPv4MTU) {
	properties->mtu = mtu;
	}
	} else if (key == kConfigurationKeyClasslessStaticRoutes) {
	classless_static_routes = value.Get<string>();
	} else if (key == kConfigurationKeyVendorEncapsulatedOptions) {
	properties->vendor_encapsulated_options = value.Get<ByteArray>();
	} else if (key == kConfigurationKeyWebProxyAutoDiscoveryUrl) {
	properties->web_proxy_auto_discovery = value.Get<string>();
	} else if (key == kConfigurationKeyLeaseTime) {
	properties->lease_duration_seconds = value.Get<uint32_t>();
	} else if (key == kConfigurationKeyiSNSOptionData) {
	properties->isns_option_data = value.Get<ByteArray>();
	} else {
	SLOG(nullptr, 2) << "Key ignored.";
	}
	}
	ParseClasslessStaticRoutes(classless_static_routes, properties);
	if (default_gateway_parse_error && properties->gateway.empty()) {
	return false;
	}
	return true;
	}

	} // namespace shill