LineageOS/android_packages_modules_Connectivity
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
Files
beb28405b14ec4e20849741a190e75b9f28b584e
android_packages_modules_Co…/Tethering/src/android/net/ip/IpServer.java
Lorenzo Colitti beb28405b1 Migrate to TetherOffloadRuleParcel in IpServer 
The netd tethering offload IPCs are changing from taking a list
of primitives to taking a TetherOffloadRuleParcel. Modify their
only caller.

Bug: 140541991
Test: atest IpServerTest
Change-Id: I83718c80ef9d31199c87021b4dd5821717fd5ba5
2020-04-04 16:24:58 +09:00

1300 lines
51 KiB
Java
Raw Blame History

/*
* 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.
*/
package android.net.ip;
import static android.net.InetAddresses.parseNumericAddress;
import static android.net.RouteInfo.RTN_UNICAST;
import static android.net.TetheringManager.TetheringRequest.checkStaticAddressConfiguration;
import static android.net.dhcp.IDhcpServer.STATUS_SUCCESS;
import static android.net.shared.Inet4AddressUtils.intToInet4AddressHTH;
import static android.net.util.NetworkConstants.FF;
import static android.net.util.NetworkConstants.RFC7421_PREFIX_LENGTH;
import static android.net.util.NetworkConstants.asByte;
import static android.net.util.TetheringMessageBase.BASE_IPSERVER;
import static android.system.OsConstants.RT_SCOPE_UNIVERSE;
import android.net.INetd;
import android.net.INetworkStackStatusCallback;
import android.net.IpPrefix;
import android.net.LinkAddress;
import android.net.LinkProperties;
import android.net.MacAddress;
import android.net.RouteInfo;
import android.net.TetherOffloadRuleParcel;
import android.net.TetheredClient;
import android.net.TetheringManager;
import android.net.TetheringRequestParcel;
import android.net.dhcp.DhcpLeaseParcelable;
import android.net.dhcp.DhcpServerCallbacks;
import android.net.dhcp.DhcpServingParamsParcel;
import android.net.dhcp.DhcpServingParamsParcelExt;
import android.net.dhcp.IDhcpLeaseCallbacks;
import android.net.dhcp.IDhcpServer;
import android.net.ip.IpNeighborMonitor.NeighborEvent;
import android.net.ip.RouterAdvertisementDaemon.RaParams;
import android.net.shared.NetdUtils;
import android.net.shared.RouteUtils;
import android.net.util.InterfaceParams;
import android.net.util.InterfaceSet;
import android.net.util.SharedLog;
import android.os.Handler;
import android.os.Looper;
import android.os.Message;
import android.os.RemoteException;
import android.os.ServiceSpecificException;
import android.util.Log;
import android.util.SparseArray;
import androidx.annotation.NonNull;
import com.android.internal.util.MessageUtils;
import com.android.internal.util.State;
import com.android.internal.util.StateMachine;
import java.io.IOException;
import java.net.Inet4Address;
import java.net.Inet6Address;
import java.net.InetAddress;
import java.net.NetworkInterface;
import java.net.UnknownHostException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.HashSet;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Objects;
import java.util.Random;
import java.util.Set;
/**
* Provides the interface to IP-layer serving functionality for a given network
* interface, e.g. for tethering or "local-only hotspot" mode.
*
* @hide
*/
public class IpServer extends StateMachine {
public static final int STATE_UNAVAILABLE = 0;
public static final int STATE_AVAILABLE = 1;
public static final int STATE_TETHERED = 2;
public static final int STATE_LOCAL_ONLY = 3;
/** Get string name of |state|.*/
public static String getStateString(int state) {
switch (state) {
case STATE_UNAVAILABLE: return "UNAVAILABLE";
case STATE_AVAILABLE: return "AVAILABLE";
case STATE_TETHERED: return "TETHERED";
case STATE_LOCAL_ONLY: return "LOCAL_ONLY";
}
return "UNKNOWN: " + state;
}
private static final byte DOUG_ADAMS = (byte) 42;
private static final String USB_NEAR_IFACE_ADDR = "192.168.42.129";
private static final int USB_PREFIX_LENGTH = 24;
private static final String WIFI_HOST_IFACE_ADDR = "192.168.43.1";
private static final int WIFI_HOST_IFACE_PREFIX_LENGTH = 24;
private static final String WIFI_P2P_IFACE_ADDR = "192.168.49.1";
private static final int WIFI_P2P_IFACE_PREFIX_LENGTH = 24;
private static final String ETHERNET_IFACE_ADDR = "192.168.50.1";
private static final int ETHERNET_IFACE_PREFIX_LENGTH = 24;
// TODO: have PanService use some visible version of this constant
private static final String BLUETOOTH_IFACE_ADDR = "192.168.44.1";
private static final int BLUETOOTH_DHCP_PREFIX_LENGTH = 24;
// TODO: have this configurable
private static final int DHCP_LEASE_TIME_SECS = 3600;
private static final String TAG = "IpServer";
private static final boolean DBG = false;
private static final boolean VDBG = false;
private static final Class[] sMessageClasses = {
IpServer.class
};
private static final SparseArray<String> sMagicDecoderRing =
MessageUtils.findMessageNames(sMessageClasses);
/** IpServer callback. */
public static class Callback {
/**
* Notify that |who| has changed its tethering state.
*
* @param who the calling instance of IpServer
* @param state one of STATE_*
* @param lastError one of TetheringManager.TETHER_ERROR_*
*/
public void updateInterfaceState(IpServer who, int state, int lastError) { }
/**
* Notify that |who| has new LinkProperties.
*
* @param who the calling instance of IpServer
* @param newLp the new LinkProperties to report
*/
public void updateLinkProperties(IpServer who, LinkProperties newLp) { }
/**
* Notify that the DHCP leases changed in one of the IpServers.
*/
public void dhcpLeasesChanged() { }
}
/** Capture IpServer dependencies, for injection. */
public abstract static class Dependencies {
/** Create an IpNeighborMonitor to be used by this IpServer */
public IpNeighborMonitor getIpNeighborMonitor(Handler handler, SharedLog log,
IpNeighborMonitor.NeighborEventConsumer consumer) {
return new IpNeighborMonitor(handler, log, consumer);
}
/** Create a RouterAdvertisementDaemon instance to be used by IpServer.*/
public RouterAdvertisementDaemon getRouterAdvertisementDaemon(InterfaceParams ifParams) {
return new RouterAdvertisementDaemon(ifParams);
}
/** Get |ifName|'s interface information.*/
public InterfaceParams getInterfaceParams(String ifName) {
return InterfaceParams.getByName(ifName);
}
/** Get |ifName|'s interface index. */
public int getIfindex(String ifName) {
try {
return NetworkInterface.getByName(ifName).getIndex();
} catch (IOException | NullPointerException e) {
Log.e(TAG, "Can't determine interface index for interface " + ifName);
return 0;
}
}
/** Create a DhcpServer instance to be used by IpServer. */
public abstract void makeDhcpServer(String ifName, DhcpServingParamsParcel params,
DhcpServerCallbacks cb);
}
// request from the user that it wants to tether
public static final int CMD_TETHER_REQUESTED = BASE_IPSERVER + 1;
// request from the user that it wants to untether
public static final int CMD_TETHER_UNREQUESTED = BASE_IPSERVER + 2;
// notification that this interface is down
public static final int CMD_INTERFACE_DOWN = BASE_IPSERVER + 3;
// notification from the master SM that it had trouble enabling IP Forwarding
public static final int CMD_IP_FORWARDING_ENABLE_ERROR = BASE_IPSERVER + 4;
// notification from the master SM that it had trouble disabling IP Forwarding
public static final int CMD_IP_FORWARDING_DISABLE_ERROR = BASE_IPSERVER + 5;
// notification from the master SM that it had trouble starting tethering
public static final int CMD_START_TETHERING_ERROR = BASE_IPSERVER + 6;
// notification from the master SM that it had trouble stopping tethering
public static final int CMD_STOP_TETHERING_ERROR = BASE_IPSERVER + 7;
// notification from the master SM that it had trouble setting the DNS forwarders
public static final int CMD_SET_DNS_FORWARDERS_ERROR = BASE_IPSERVER + 8;
// the upstream connection has changed
public static final int CMD_TETHER_CONNECTION_CHANGED = BASE_IPSERVER + 9;
// new IPv6 tethering parameters need to be processed
public static final int CMD_IPV6_TETHER_UPDATE = BASE_IPSERVER + 10;
// new neighbor cache entry on our interface
public static final int CMD_NEIGHBOR_EVENT = BASE_IPSERVER + 11;
private final State mInitialState;
private final State mLocalHotspotState;
private final State mTetheredState;
private final State mUnavailableState;
private final SharedLog mLog;
private final INetd mNetd;
private final Callback mCallback;
private final InterfaceController mInterfaceCtrl;
private final String mIfaceName;
private final int mInterfaceType;
private final LinkProperties mLinkProperties;
private final boolean mUsingLegacyDhcp;
private final Dependencies mDeps;
private int mLastError;
private int mServingMode;
private InterfaceSet mUpstreamIfaceSet; // may change over time
private InterfaceParams mInterfaceParams;
// TODO: De-duplicate this with mLinkProperties above. Currently, these link
// properties are those selected by the IPv6TetheringCoordinator and relayed
// to us. By comparison, mLinkProperties contains the addresses and directly
// connected routes that have been formed from these properties iff. we have
// succeeded in configuring them and are able to announce them within Router
// Advertisements (otherwise, we do not add them to mLinkProperties at all).
private LinkProperties mLastIPv6LinkProperties;
private RouterAdvertisementDaemon mRaDaemon;
// To be accessed only on the handler thread
private int mDhcpServerStartIndex = 0;
private IDhcpServer mDhcpServer;
private RaParams mLastRaParams;
private LinkAddress mIpv4Address;
private LinkAddress mStaticIpv4ServerAddr;
private LinkAddress mStaticIpv4ClientAddr;
@NonNull
private List<TetheredClient> mDhcpLeases = Collections.emptyList();
private int mLastIPv6UpstreamIfindex = 0;
private class MyNeighborEventConsumer implements IpNeighborMonitor.NeighborEventConsumer {
public void accept(NeighborEvent e) {
sendMessage(CMD_NEIGHBOR_EVENT, e);
}
}
static class Ipv6ForwardingRule {
public final int upstreamIfindex;
public final int downstreamIfindex;
public final Inet6Address address;
public final MacAddress srcMac;
public final MacAddress dstMac;
Ipv6ForwardingRule(int upstreamIfindex, int downstreamIfIndex, Inet6Address address,
MacAddress srcMac, MacAddress dstMac) {
this.upstreamIfindex = upstreamIfindex;
this.downstreamIfindex = downstreamIfIndex;
this.address = address;
this.srcMac = srcMac;
this.dstMac = dstMac;
}
public Ipv6ForwardingRule onNewUpstream(int newUpstreamIfindex) {
return new Ipv6ForwardingRule(newUpstreamIfindex, downstreamIfindex, address, srcMac,
dstMac);
}
// Don't manipulate TetherOffloadRuleParcel directly because implementing onNewUpstream()
// would be error-prone due to generated stable AIDL classes not having a copy constructor.
public TetherOffloadRuleParcel toTetherOffloadRuleParcel() {
final TetherOffloadRuleParcel parcel = new TetherOffloadRuleParcel();
parcel.inputInterfaceIndex = upstreamIfindex;
parcel.outputInterfaceIndex = downstreamIfindex;
parcel.destination = address.getAddress();
parcel.prefixLength = 128;
parcel.srcL2Address = srcMac.toByteArray();
parcel.dstL2Address = dstMac.toByteArray();
return parcel;
}
}
private final LinkedHashMap<Inet6Address, Ipv6ForwardingRule> mIpv6ForwardingRules =
new LinkedHashMap<>();
private final IpNeighborMonitor mIpNeighborMonitor;
public IpServer(
String ifaceName, Looper looper, int interfaceType, SharedLog log,
INetd netd, Callback callback, boolean usingLegacyDhcp, Dependencies deps) {
super(ifaceName, looper);
mLog = log.forSubComponent(ifaceName);
mNetd = netd;
mCallback = callback;
mInterfaceCtrl = new InterfaceController(ifaceName, mNetd, mLog);
mIfaceName = ifaceName;
mInterfaceType = interfaceType;
mLinkProperties = new LinkProperties();
mUsingLegacyDhcp = usingLegacyDhcp;
mDeps = deps;
resetLinkProperties();
mLastError = TetheringManager.TETHER_ERROR_NO_ERROR;
mServingMode = STATE_AVAILABLE;
mIpNeighborMonitor = mDeps.getIpNeighborMonitor(getHandler(), mLog,
new MyNeighborEventConsumer());
if (!mIpNeighborMonitor.start()) {
mLog.e("Failed to create IpNeighborMonitor on " + mIfaceName);
}
mInitialState = new InitialState();
mLocalHotspotState = new LocalHotspotState();
mTetheredState = new TetheredState();
mUnavailableState = new UnavailableState();
addState(mInitialState);
addState(mLocalHotspotState);
addState(mTetheredState);
addState(mUnavailableState);
setInitialState(mInitialState);
}
/** Interface name which IpServer served.*/
public String interfaceName() {
return mIfaceName;
}
/**
* Tethering downstream type. It would be one of TetheringManager#TETHERING_*.
*/
public int interfaceType() {
return mInterfaceType;
}
/** Last error from this IpServer. */
public int lastError() {
return mLastError;
}
/** Serving mode is the current state of IpServer state machine. */
public int servingMode() {
return mServingMode;
}
/** The properties of the network link which IpServer is serving. */
public LinkProperties linkProperties() {
return new LinkProperties(mLinkProperties);
}
/**
* Get the latest list of DHCP leases that was reported. Must be called on the IpServer looper
* thread.
*/
public List<TetheredClient> getAllLeases() {
return Collections.unmodifiableList(mDhcpLeases);
}
/** Stop this IpServer. After this is called this IpServer should not be used any more. */
public void stop() {
sendMessage(CMD_INTERFACE_DOWN);
}
/**
* Tethering is canceled. IpServer state machine will be available and wait for
* next tethering request.
*/
public void unwanted() {
sendMessage(CMD_TETHER_UNREQUESTED);
}
/** Internals. */
private boolean startIPv4() {
return configureIPv4(true);
}
/**
* Convenience wrapper around INetworkStackStatusCallback to run callbacks on the IpServer
* handler.
*
* <p>Different instances of this class can be created for each call to IDhcpServer methods,
* with different implementations of the callback, to differentiate handling of success/error in
* each call.
*/
private abstract class OnHandlerStatusCallback extends INetworkStackStatusCallback.Stub {
@Override
public void onStatusAvailable(int statusCode) {
getHandler().post(() -> callback(statusCode));
}
public abstract void callback(int statusCode);
@Override
public int getInterfaceVersion() {
return this.VERSION;
}
@Override
public String getInterfaceHash() {
return this.HASH;
}
}
private class DhcpServerCallbacksImpl extends DhcpServerCallbacks {
private final int mStartIndex;
private DhcpServerCallbacksImpl(int startIndex) {
mStartIndex = startIndex;
}
@Override
public void onDhcpServerCreated(int statusCode, IDhcpServer server) throws RemoteException {
getHandler().post(() -> {
// We are on the handler thread: mDhcpServerStartIndex can be read safely.
if (mStartIndex != mDhcpServerStartIndex) {
// This start request is obsolete. When the |server| binder token goes out of
// scope, the garbage collector will finalize it, which causes the network stack
// process garbage collector to collect the server itself.
return;
}
if (statusCode != STATUS_SUCCESS) {
mLog.e("Error obtaining DHCP server: " + statusCode);
handleError();
return;
}
mDhcpServer = server;
try {
mDhcpServer.startWithCallbacks(new OnHandlerStatusCallback() {
@Override
public void callback(int startStatusCode) {
if (startStatusCode != STATUS_SUCCESS) {
mLog.e("Error starting DHCP server: " + startStatusCode);
handleError();
}
}
}, new DhcpLeaseCallback());
} catch (RemoteException e) {
throw new IllegalStateException(e);
}
});
}
private void handleError() {
mLastError = TetheringManager.TETHER_ERROR_DHCPSERVER_ERROR;
transitionTo(mInitialState);
}
}
private class DhcpLeaseCallback extends IDhcpLeaseCallbacks.Stub {
@Override
public void onLeasesChanged(List<DhcpLeaseParcelable> leaseParcelables) {
final ArrayList<TetheredClient> leases = new ArrayList<>();
for (DhcpLeaseParcelable lease : leaseParcelables) {
final LinkAddress address = new LinkAddress(
intToInet4AddressHTH(lease.netAddr), lease.prefixLength,
0 /* flags */, RT_SCOPE_UNIVERSE /* as per RFC6724#3.2 */,
lease.expTime /* deprecationTime */, lease.expTime /* expirationTime */);
final MacAddress macAddress;
try {
macAddress = MacAddress.fromBytes(lease.hwAddr);
} catch (IllegalArgumentException e) {
Log.wtf(TAG, "Invalid address received from DhcpServer: "
+ Arrays.toString(lease.hwAddr));
return;
}
final TetheredClient.AddressInfo addressInfo = new TetheredClient.AddressInfo(
address, lease.hostname);
leases.add(new TetheredClient(
macAddress,
Collections.singletonList(addressInfo),
mInterfaceType));
}
getHandler().post(() -> {
mDhcpLeases = leases;
mCallback.dhcpLeasesChanged();
});
}
@Override
public int getInterfaceVersion() {
return this.VERSION;
}
@Override
public String getInterfaceHash() throws RemoteException {
return this.HASH;
}
}
private boolean startDhcp(final LinkAddress serverLinkAddr, final LinkAddress clientLinkAddr) {
if (mUsingLegacyDhcp) {
return true;
}
final Inet4Address addr = (Inet4Address) serverLinkAddr.getAddress();
final int prefixLen = serverLinkAddr.getPrefixLength();
final Inet4Address clientAddr = clientLinkAddr == null ? null :
(Inet4Address) clientLinkAddr.getAddress();
final DhcpServingParamsParcel params;
params = new DhcpServingParamsParcelExt()
.setDefaultRouters(addr)
.setDhcpLeaseTimeSecs(DHCP_LEASE_TIME_SECS)
.setDnsServers(addr)
.setServerAddr(serverLinkAddr)
.setMetered(true)
.setSingleClientAddr(clientAddr);
// TODO: also advertise link MTU
mDhcpServerStartIndex++;
mDeps.makeDhcpServer(
mIfaceName, params, new DhcpServerCallbacksImpl(mDhcpServerStartIndex));
return true;
}
private void stopDhcp() {
// Make all previous start requests obsolete so servers are not started later
mDhcpServerStartIndex++;
if (mDhcpServer != null) {
try {
mDhcpServer.stop(new OnHandlerStatusCallback() {
@Override
public void callback(int statusCode) {
if (statusCode != STATUS_SUCCESS) {
mLog.e("Error stopping DHCP server: " + statusCode);
mLastError = TetheringManager.TETHER_ERROR_DHCPSERVER_ERROR;
// Not much more we can do here
}
mDhcpLeases.clear();
getHandler().post(mCallback::dhcpLeasesChanged);
}
});
mDhcpServer = null;
} catch (RemoteException e) {
mLog.e("Error stopping DHCP", e);
// Not much more we can do here
}
}
}
private boolean configureDhcp(boolean enable, final LinkAddress serverAddr,
final LinkAddress clientAddr) {
if (enable) {
return startDhcp(serverAddr, clientAddr);
} else {
stopDhcp();
return true;
}
}
private void stopIPv4() {
configureIPv4(false);
// NOTE: All of configureIPv4() will be refactored out of existence
// into calls to InterfaceController, shared with startIPv4().
mInterfaceCtrl.clearIPv4Address();
mIpv4Address = null;
mStaticIpv4ServerAddr = null;
mStaticIpv4ClientAddr = null;
}
private boolean configureIPv4(boolean enabled) {
if (VDBG) Log.d(TAG, "configureIPv4(" + enabled + ")");
// TODO: Replace this hard-coded information with dynamically selected
// config passed down to us by a higher layer IP-coordinating element.
final Inet4Address srvAddr;
int prefixLen = 0;
try {
if (mStaticIpv4ServerAddr != null) {
srvAddr = (Inet4Address) mStaticIpv4ServerAddr.getAddress();
prefixLen = mStaticIpv4ServerAddr.getPrefixLength();
} else if (mInterfaceType == TetheringManager.TETHERING_USB
|| mInterfaceType == TetheringManager.TETHERING_NCM) {
srvAddr = (Inet4Address) parseNumericAddress(USB_NEAR_IFACE_ADDR);
prefixLen = USB_PREFIX_LENGTH;
} else if (mInterfaceType == TetheringManager.TETHERING_WIFI) {
srvAddr = (Inet4Address) parseNumericAddress(getRandomWifiIPv4Address());
prefixLen = WIFI_HOST_IFACE_PREFIX_LENGTH;
} else if (mInterfaceType == TetheringManager.TETHERING_WIFI_P2P) {
srvAddr = (Inet4Address) parseNumericAddress(WIFI_P2P_IFACE_ADDR);
prefixLen = WIFI_P2P_IFACE_PREFIX_LENGTH;
} else if (mInterfaceType == TetheringManager.TETHERING_ETHERNET) {
// TODO: randomize address for tethering too, similarly to wifi
srvAddr = (Inet4Address) parseNumericAddress(ETHERNET_IFACE_ADDR);
prefixLen = ETHERNET_IFACE_PREFIX_LENGTH;
} else {
// BT configures the interface elsewhere: only start DHCP.
// TODO: make all tethering types behave the same way, and delete the bluetooth
// code that calls into NetworkManagementService directly.
srvAddr = (Inet4Address) parseNumericAddress(BLUETOOTH_IFACE_ADDR);
mIpv4Address = new LinkAddress(srvAddr, BLUETOOTH_DHCP_PREFIX_LENGTH);
return configureDhcp(enabled, mIpv4Address, null /* clientAddress */);
}
mIpv4Address = new LinkAddress(srvAddr, prefixLen);
} catch (IllegalArgumentException e) {
mLog.e("Error selecting ipv4 address", e);
if (!enabled) stopDhcp();
return false;
}
final Boolean setIfaceUp;
if (mInterfaceType == TetheringManager.TETHERING_WIFI
|| mInterfaceType == TetheringManager.TETHERING_WIFI_P2P) {
// The WiFi stack has ownership of the interface up/down state.
// It is unclear whether the Bluetooth or USB stacks will manage their own
// state.
setIfaceUp = null;
} else {
setIfaceUp = enabled;
}
if (!mInterfaceCtrl.setInterfaceConfiguration(mIpv4Address, setIfaceUp)) {
mLog.e("Error configuring interface");
if (!enabled) stopDhcp();
return false;
}
// Directly-connected route.
final IpPrefix ipv4Prefix = new IpPrefix(mIpv4Address.getAddress(),
mIpv4Address.getPrefixLength());
final RouteInfo route = new RouteInfo(ipv4Prefix, null, null, RTN_UNICAST);
if (enabled) {
mLinkProperties.addLinkAddress(mIpv4Address);
mLinkProperties.addRoute(route);
} else {
mLinkProperties.removeLinkAddress(mIpv4Address);
mLinkProperties.removeRoute(route);
}
return configureDhcp(enabled, mIpv4Address, mStaticIpv4ClientAddr);
}
private String getRandomWifiIPv4Address() {
try {
byte[] bytes = parseNumericAddress(WIFI_HOST_IFACE_ADDR).getAddress();
bytes[3] = getRandomSanitizedByte(DOUG_ADAMS, asByte(0), asByte(1), FF);
return InetAddress.getByAddress(bytes).getHostAddress();
} catch (Exception e) {
return WIFI_HOST_IFACE_ADDR;
}
}
private boolean startIPv6() {
mInterfaceParams = mDeps.getInterfaceParams(mIfaceName);
if (mInterfaceParams == null) {
mLog.e("Failed to find InterfaceParams");
stopIPv6();
return false;
}
mRaDaemon = mDeps.getRouterAdvertisementDaemon(mInterfaceParams);
if (!mRaDaemon.start()) {
stopIPv6();
return false;
}
return true;
}
private void stopIPv6() {
mInterfaceParams = null;
setRaParams(null);
if (mRaDaemon != null) {
mRaDaemon.stop();
mRaDaemon = null;
}
}
// IPv6TetheringCoordinator sends updates with carefully curated IPv6-only
// LinkProperties. These have extraneous data filtered out and only the
// necessary prefixes included (per its prefix distribution policy).
//
// TODO: Evaluate using a data structure than is more directly suited to
// communicating only the relevant information.
private void updateUpstreamIPv6LinkProperties(LinkProperties v6only) {
if (mRaDaemon == null) return;
// Avoid unnecessary work on spurious updates.
if (Objects.equals(mLastIPv6LinkProperties, v6only)) {
return;
}
RaParams params = null;
int upstreamIfindex = 0;
if (v6only != null) {
final String upstreamIface = v6only.getInterfaceName();
params = new RaParams();
// We advertise an mtu lower by 16, which is the closest multiple of 8 >= 14,
// the ethernet header size. This makes kernel ebpf tethering offload happy.
// This hack should be reverted once we have the kernel fixed up.
// Note: this will automatically clamp to at least 1280 (ipv6 minimum mtu)
// see RouterAdvertisementDaemon.java putMtu()
params.mtu = v6only.getMtu() - 16;
params.hasDefaultRoute = v6only.hasIpv6DefaultRoute();
if (params.hasDefaultRoute) params.hopLimit = getHopLimit(upstreamIface);
for (LinkAddress linkAddr : v6only.getLinkAddresses()) {
if (linkAddr.getPrefixLength() != RFC7421_PREFIX_LENGTH) continue;
final IpPrefix prefix = new IpPrefix(
linkAddr.getAddress(), linkAddr.getPrefixLength());
params.prefixes.add(prefix);
final Inet6Address dnsServer = getLocalDnsIpFor(prefix);
if (dnsServer != null) {
params.dnses.add(dnsServer);
}
}
upstreamIfindex = mDeps.getIfindex(upstreamIface);
}
// If v6only is null, we pass in null to setRaParams(), which handles
// deprecation of any existing RA data.
setRaParams(params);
mLastIPv6LinkProperties = v6only;
updateIpv6ForwardingRules(mLastIPv6UpstreamIfindex, upstreamIfindex, null);
mLastIPv6UpstreamIfindex = upstreamIfindex;
}
private void configureLocalIPv6Routes(
HashSet<IpPrefix> deprecatedPrefixes, HashSet<IpPrefix> newPrefixes) {
// [1] Remove the routes that are deprecated.
if (!deprecatedPrefixes.isEmpty()) {
final ArrayList<RouteInfo> toBeRemoved =
getLocalRoutesFor(mIfaceName, deprecatedPrefixes);
// Remove routes from local network.
final int removalFailures = RouteUtils.removeRoutesFromLocalNetwork(
mNetd, toBeRemoved);
if (removalFailures > 0) {
mLog.e(String.format("Failed to remove %d IPv6 routes from local table.",
removalFailures));
}
for (RouteInfo route : toBeRemoved) mLinkProperties.removeRoute(route);
}
// [2] Add only the routes that have not previously been added.
if (newPrefixes != null && !newPrefixes.isEmpty()) {
HashSet<IpPrefix> addedPrefixes = (HashSet) newPrefixes.clone();
if (mLastRaParams != null) {
addedPrefixes.removeAll(mLastRaParams.prefixes);
}
if (!addedPrefixes.isEmpty()) {
final ArrayList<RouteInfo> toBeAdded =
getLocalRoutesFor(mIfaceName, addedPrefixes);
try {
// It's safe to call networkAddInterface() even if
// the interface is already in the local_network.
mNetd.networkAddInterface(INetd.LOCAL_NET_ID, mIfaceName);
try {
// Add routes from local network. Note that adding routes that
// already exist does not cause an error (EEXIST is silently ignored).
RouteUtils.addRoutesToLocalNetwork(mNetd, mIfaceName, toBeAdded);
} catch (IllegalStateException e) {
mLog.e("Failed to add IPv6 routes to local table: " + e);
}
} catch (ServiceSpecificException | RemoteException e) {
mLog.e("Failed to add " + mIfaceName + " to local table: ", e);
}
for (RouteInfo route : toBeAdded) mLinkProperties.addRoute(route);
}
}
}
private void configureLocalIPv6Dns(
HashSet<Inet6Address> deprecatedDnses, HashSet<Inet6Address> newDnses) {
// TODO: Is this really necessary? Can we not fail earlier if INetd cannot be located?
if (mNetd == null) {
if (newDnses != null) newDnses.clear();
mLog.e("No netd service instance available; not setting local IPv6 addresses");
return;
}
// [1] Remove deprecated local DNS IP addresses.
if (!deprecatedDnses.isEmpty()) {
for (Inet6Address dns : deprecatedDnses) {
if (!mInterfaceCtrl.removeAddress(dns, RFC7421_PREFIX_LENGTH)) {
mLog.e("Failed to remove local dns IP " + dns);
}
mLinkProperties.removeLinkAddress(new LinkAddress(dns, RFC7421_PREFIX_LENGTH));
}
}
// [2] Add only the local DNS IP addresses that have not previously been added.
if (newDnses != null && !newDnses.isEmpty()) {
final HashSet<Inet6Address> addedDnses = (HashSet) newDnses.clone();
if (mLastRaParams != null) {
addedDnses.removeAll(mLastRaParams.dnses);
}
for (Inet6Address dns : addedDnses) {
if (!mInterfaceCtrl.addAddress(dns, RFC7421_PREFIX_LENGTH)) {
mLog.e("Failed to add local dns IP " + dns);
newDnses.remove(dns);
}
mLinkProperties.addLinkAddress(new LinkAddress(dns, RFC7421_PREFIX_LENGTH));
}
}
try {
mNetd.tetherApplyDnsInterfaces();
} catch (ServiceSpecificException | RemoteException e) {
mLog.e("Failed to update local DNS caching server");
if (newDnses != null) newDnses.clear();
}
}
private void addIpv6ForwardingRule(Ipv6ForwardingRule rule) {
try {
mNetd.tetherOffloadRuleAdd(rule.toTetherOffloadRuleParcel());
mIpv6ForwardingRules.put(rule.address, rule);
} catch (RemoteException | ServiceSpecificException e) {
mLog.e("Could not add IPv6 downstream rule: ", e);
}
}
private void removeIpv6ForwardingRule(Ipv6ForwardingRule rule, boolean removeFromMap) {
try {
mNetd.tetherOffloadRuleRemove(rule.toTetherOffloadRuleParcel());
if (removeFromMap) {
mIpv6ForwardingRules.remove(rule.address);
}
} catch (RemoteException | ServiceSpecificException e) {
mLog.e("Could not remove IPv6 downstream rule: ", e);
}
}
private void clearIpv6ForwardingRules() {
for (Ipv6ForwardingRule rule : mIpv6ForwardingRules.values()) {
removeIpv6ForwardingRule(rule, false /*removeFromMap*/);
}
mIpv6ForwardingRules.clear();
}
// Convenience method to replace a rule with the same rule on a new upstream interface.
// Allows replacing the rules in one iteration pass without ConcurrentModificationExceptions.
// Relies on the fact that rules are in a map indexed by IP address.
private void updateIpv6ForwardingRule(Ipv6ForwardingRule rule, int newIfindex) {
addIpv6ForwardingRule(rule.onNewUpstream(newIfindex));
removeIpv6ForwardingRule(rule, false /*removeFromMap*/);
}
// Handles all updates to IPv6 forwarding rules. These can currently change only if the upstream
// changes or if a neighbor event is received.
private void updateIpv6ForwardingRules(int prevUpstreamIfindex, int upstreamIfindex,
NeighborEvent e) {
// If we no longer have an upstream, clear forwarding rules and do nothing else.
if (upstreamIfindex == 0) {
clearIpv6ForwardingRules();
return;
}
// If the upstream interface has changed, remove all rules and re-add them with the new
// upstream interface.
if (prevUpstreamIfindex != upstreamIfindex) {
for (Ipv6ForwardingRule rule : mIpv6ForwardingRules.values()) {
updateIpv6ForwardingRule(rule, upstreamIfindex);
}
}
// If we're here to process a NeighborEvent, do so now.
// mInterfaceParams must be non-null or the event would not have arrived.
if (e == null) return;
if (!(e.ip instanceof Inet6Address) || e.ip.isMulticastAddress()
|| e.ip.isLoopbackAddress() || e.ip.isLinkLocalAddress()) {
return;
}
Ipv6ForwardingRule rule = new Ipv6ForwardingRule(upstreamIfindex,
mInterfaceParams.index, (Inet6Address) e.ip, mInterfaceParams.macAddr,
e.macAddr);
if (e.isValid()) {
addIpv6ForwardingRule(rule);
} else {
removeIpv6ForwardingRule(rule, true /*removeFromMap*/);
}
}
private void handleNeighborEvent(NeighborEvent e) {
if (mInterfaceParams != null
&& mInterfaceParams.index == e.ifindex
&& mInterfaceParams.hasMacAddress) {
updateIpv6ForwardingRules(mLastIPv6UpstreamIfindex, mLastIPv6UpstreamIfindex, e);
}
}
private byte getHopLimit(String upstreamIface) {
try {
int upstreamHopLimit = Integer.parseUnsignedInt(
mNetd.getProcSysNet(INetd.IPV6, INetd.CONF, upstreamIface, "hop_limit"));
// Add one hop to account for this forwarding device
upstreamHopLimit++;
// Cap the hop limit to 255.
return (byte) Integer.min(upstreamHopLimit, 255);
} catch (Exception e) {
mLog.e("Failed to find upstream interface hop limit", e);
}
return RaParams.DEFAULT_HOPLIMIT;
}
private void setRaParams(RaParams newParams) {
if (mRaDaemon != null) {
final RaParams deprecatedParams =
RaParams.getDeprecatedRaParams(mLastRaParams, newParams);
configureLocalIPv6Routes(deprecatedParams.prefixes,
(newParams != null) ? newParams.prefixes : null);
configureLocalIPv6Dns(deprecatedParams.dnses,
(newParams != null) ? newParams.dnses : null);
mRaDaemon.buildNewRa(deprecatedParams, newParams);
}
mLastRaParams = newParams;
}
private void logMessage(State state, int what) {
mLog.log(state.getName() + " got " + sMagicDecoderRing.get(what, Integer.toString(what)));
}
private void sendInterfaceState(int newInterfaceState) {
mServingMode = newInterfaceState;
mCallback.updateInterfaceState(this, newInterfaceState, mLastError);
sendLinkProperties();
}
private void sendLinkProperties() {
mCallback.updateLinkProperties(this, new LinkProperties(mLinkProperties));
}
private void resetLinkProperties() {
mLinkProperties.clear();
mLinkProperties.setInterfaceName(mIfaceName);
}
private void maybeConfigureStaticIp(final TetheringRequestParcel request) {
// Ignore static address configuration if they are invalid or null. In theory, static
// addresses should not be invalid here because TetheringManager do not allow caller to
// specify invalid static address configuration.
if (request == null || request.localIPv4Address == null
|| request.staticClientAddress == null || !checkStaticAddressConfiguration(
request.localIPv4Address, request.staticClientAddress)) {
return;
}
mStaticIpv4ServerAddr = request.localIPv4Address;
mStaticIpv4ClientAddr = request.staticClientAddress;
}
class InitialState extends State {
@Override
public void enter() {
sendInterfaceState(STATE_AVAILABLE);
}
@Override
public boolean processMessage(Message message) {
logMessage(this, message.what);
switch (message.what) {
case CMD_TETHER_REQUESTED:
mLastError = TetheringManager.TETHER_ERROR_NO_ERROR;
switch (message.arg1) {
case STATE_LOCAL_ONLY:
maybeConfigureStaticIp((TetheringRequestParcel) message.obj);
transitionTo(mLocalHotspotState);
break;
case STATE_TETHERED:
maybeConfigureStaticIp((TetheringRequestParcel) message.obj);
transitionTo(mTetheredState);
break;
default:
mLog.e("Invalid tethering interface serving state specified.");
}
break;
case CMD_INTERFACE_DOWN:
transitionTo(mUnavailableState);
break;
case CMD_IPV6_TETHER_UPDATE:
updateUpstreamIPv6LinkProperties((LinkProperties) message.obj);
break;
default:
return NOT_HANDLED;
}
return HANDLED;
}
}
class BaseServingState extends State {
@Override
public void enter() {
if (!startIPv4()) {
mLastError = TetheringManager.TETHER_ERROR_IFACE_CFG_ERROR;
return;
}
try {
final IpPrefix ipv4Prefix = new IpPrefix(mIpv4Address.getAddress(),
mIpv4Address.getPrefixLength());
NetdUtils.tetherInterface(mNetd, mIfaceName, ipv4Prefix);
} catch (RemoteException | ServiceSpecificException | IllegalStateException e) {
mLog.e("Error Tethering: " + e);
mLastError = TetheringManager.TETHER_ERROR_TETHER_IFACE_ERROR;
return;
}
if (!startIPv6()) {
mLog.e("Failed to startIPv6");
// TODO: Make this a fatal error once Bluetooth IPv6 is sorted.
return;
}
}
@Override
public void exit() {
// Note that at this point, we're leaving the tethered state. We can fail any
// of these operations, but it doesn't really change that we have to try them
// all in sequence.
stopIPv6();
try {
NetdUtils.untetherInterface(mNetd, mIfaceName);
} catch (RemoteException | ServiceSpecificException e) {
mLastError = TetheringManager.TETHER_ERROR_UNTETHER_IFACE_ERROR;
mLog.e("Failed to untether interface: " + e);
}
stopIPv4();
resetLinkProperties();
}
@Override
public boolean processMessage(Message message) {
logMessage(this, message.what);
switch (message.what) {
case CMD_TETHER_UNREQUESTED:
transitionTo(mInitialState);
if (DBG) Log.d(TAG, "Untethered (unrequested)" + mIfaceName);
break;
case CMD_INTERFACE_DOWN:
transitionTo(mUnavailableState);
if (DBG) Log.d(TAG, "Untethered (ifdown)" + mIfaceName);
break;
case CMD_IPV6_TETHER_UPDATE:
updateUpstreamIPv6LinkProperties((LinkProperties) message.obj);
sendLinkProperties();
break;
case CMD_IP_FORWARDING_ENABLE_ERROR:
case CMD_IP_FORWARDING_DISABLE_ERROR:
case CMD_START_TETHERING_ERROR:
case CMD_STOP_TETHERING_ERROR:
case CMD_SET_DNS_FORWARDERS_ERROR:
mLastError = TetheringManager.TETHER_ERROR_INTERNAL_ERROR;
transitionTo(mInitialState);
break;
default:
return false;
}
return true;
}
}
// Handling errors in BaseServingState.enter() by transitioning is
// problematic because transitioning during a multi-state jump yields
// a Log.wtf(). Ultimately, there should be only one ServingState,
// and forwarding and NAT rules should be handled by a coordinating
// functional element outside of IpServer.
class LocalHotspotState extends BaseServingState {
@Override
public void enter() {
super.enter();
if (mLastError != TetheringManager.TETHER_ERROR_NO_ERROR) {
transitionTo(mInitialState);
}
if (DBG) Log.d(TAG, "Local hotspot " + mIfaceName);
sendInterfaceState(STATE_LOCAL_ONLY);
}
@Override
public boolean processMessage(Message message) {
if (super.processMessage(message)) return true;
logMessage(this, message.what);
switch (message.what) {
case CMD_TETHER_REQUESTED:
mLog.e("CMD_TETHER_REQUESTED while in local-only hotspot mode.");
break;
case CMD_TETHER_CONNECTION_CHANGED:
// Ignored in local hotspot state.
break;
default:
return false;
}
return true;
}
}
// Handling errors in BaseServingState.enter() by transitioning is
// problematic because transitioning during a multi-state jump yields
// a Log.wtf(). Ultimately, there should be only one ServingState,
// and forwarding and NAT rules should be handled by a coordinating
// functional element outside of IpServer.
class TetheredState extends BaseServingState {
@Override
public void enter() {
super.enter();
if (mLastError != TetheringManager.TETHER_ERROR_NO_ERROR) {
transitionTo(mInitialState);
}
if (DBG) Log.d(TAG, "Tethered " + mIfaceName);
sendInterfaceState(STATE_TETHERED);
}
@Override
public void exit() {
cleanupUpstream();
super.exit();
}
private void cleanupUpstream() {
if (mUpstreamIfaceSet == null) return;
for (String ifname : mUpstreamIfaceSet.ifnames) cleanupUpstreamInterface(ifname);
mUpstreamIfaceSet = null;
clearIpv6ForwardingRules();
}
private void cleanupUpstreamInterface(String upstreamIface) {
// Note that we don't care about errors here.
// Sometimes interfaces are gone before we get
// to remove their rules, which generates errors.
// Just do the best we can.
try {
mNetd.ipfwdRemoveInterfaceForward(mIfaceName, upstreamIface);
} catch (RemoteException | ServiceSpecificException e) {
mLog.e("Exception in ipfwdRemoveInterfaceForward: " + e.toString());
}
try {
mNetd.tetherRemoveForward(mIfaceName, upstreamIface);
} catch (RemoteException | ServiceSpecificException e) {
mLog.e("Exception in disableNat: " + e.toString());
}
}
@Override
public boolean processMessage(Message message) {
if (super.processMessage(message)) return true;
logMessage(this, message.what);
switch (message.what) {
case CMD_TETHER_REQUESTED:
mLog.e("CMD_TETHER_REQUESTED while already tethering.");
break;
case CMD_TETHER_CONNECTION_CHANGED:
final InterfaceSet newUpstreamIfaceSet = (InterfaceSet) message.obj;
if (noChangeInUpstreamIfaceSet(newUpstreamIfaceSet)) {
if (VDBG) Log.d(TAG, "Connection changed noop - dropping");
break;
}
if (newUpstreamIfaceSet == null) {
cleanupUpstream();
break;
}
for (String removed : upstreamInterfacesRemoved(newUpstreamIfaceSet)) {
cleanupUpstreamInterface(removed);
}
final Set<String> added = upstreamInterfacesAdd(newUpstreamIfaceSet);
// This makes the call to cleanupUpstream() in the error
// path for any interface neatly cleanup all the interfaces.
mUpstreamIfaceSet = newUpstreamIfaceSet;
for (String ifname : added) {
try {
mNetd.tetherAddForward(mIfaceName, ifname);
mNetd.ipfwdAddInterfaceForward(mIfaceName, ifname);
} catch (RemoteException | ServiceSpecificException e) {
mLog.e("Exception enabling NAT: " + e.toString());
cleanupUpstream();
mLastError = TetheringManager.TETHER_ERROR_ENABLE_FORWARDING_ERROR;
transitionTo(mInitialState);
return true;
}
}
break;
case CMD_NEIGHBOR_EVENT:
handleNeighborEvent((NeighborEvent) message.obj);
break;
default:
return false;
}
return true;
}
private boolean noChangeInUpstreamIfaceSet(InterfaceSet newIfaces) {
if (mUpstreamIfaceSet == null && newIfaces == null) return true;
if (mUpstreamIfaceSet != null && newIfaces != null) {
return mUpstreamIfaceSet.equals(newIfaces);
}
return false;
}
private Set<String> upstreamInterfacesRemoved(InterfaceSet newIfaces) {
if (mUpstreamIfaceSet == null) return new HashSet<>();
final HashSet<String> removed = new HashSet<>(mUpstreamIfaceSet.ifnames);
removed.removeAll(newIfaces.ifnames);
return removed;
}
private Set<String> upstreamInterfacesAdd(InterfaceSet newIfaces) {
final HashSet<String> added = new HashSet<>(newIfaces.ifnames);
if (mUpstreamIfaceSet != null) added.removeAll(mUpstreamIfaceSet.ifnames);
return added;
}
}
/**
* This state is terminal for the per interface state machine. At this
* point, the master state machine should have removed this interface
* specific state machine from its list of possible recipients of
* tethering requests. The state machine itself will hang around until
* the garbage collector finds it.
*/
class UnavailableState extends State {
@Override
public void enter() {
mLastError = TetheringManager.TETHER_ERROR_NO_ERROR;
sendInterfaceState(STATE_UNAVAILABLE);
}
}
// Accumulate routes representing "prefixes to be assigned to the local
// interface", for subsequent modification of local_network routing.
private static ArrayList<RouteInfo> getLocalRoutesFor(
String ifname, HashSet<IpPrefix> prefixes) {
final ArrayList<RouteInfo> localRoutes = new ArrayList<RouteInfo>();
for (IpPrefix ipp : prefixes) {
localRoutes.add(new RouteInfo(ipp, null, ifname, RTN_UNICAST));
}
return localRoutes;
}
// Given a prefix like 2001:db8::/64 return an address like 2001:db8::1.
private static Inet6Address getLocalDnsIpFor(IpPrefix localPrefix) {
final byte[] dnsBytes = localPrefix.getRawAddress();
dnsBytes[dnsBytes.length - 1] = getRandomSanitizedByte(DOUG_ADAMS, asByte(0), asByte(1));
try {
return Inet6Address.getByAddress(null, dnsBytes, 0);
} catch (UnknownHostException e) {
Log.wtf(TAG, "Failed to construct Inet6Address from: " + localPrefix);
return null;
}
}
private static byte getRandomSanitizedByte(byte dflt, byte... excluded) {
final byte random = (byte) (new Random()).nextInt();
for (int value : excluded) {
if (random == value) return dflt;
}
return random;
}
}
Reference in New Issue View Git Blame Copy Permalink