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/*
* Copyright (C) 2017 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;
import static com.android.internal.util.Preconditions.checkNotNull;
import android.annotation.IntDef;
import android.annotation.NonNull;
import android.annotation.RequiresFeature;
import android.annotation.RequiresPermission;
import android.annotation.SystemApi;
import android.annotation.SystemService;
import android.annotation.TestApi;
import android.content.Context;
import android.content.pm.PackageManager;
import android.os.Binder;
import android.os.ParcelFileDescriptor;
import android.os.RemoteException;
import android.os.ServiceSpecificException;
import android.system.ErrnoException;
import android.system.OsConstants;
import android.util.AndroidException;
import android.util.Log;
import com.android.internal.annotations.VisibleForTesting;
import dalvik.system.CloseGuard;
import java.io.FileDescriptor;
import java.io.IOException;
import java.lang.annotation.Retention;
import java.lang.annotation.RetentionPolicy;
import java.net.DatagramSocket;
import java.net.InetAddress;
import java.net.Socket;
/**
* This class contains methods for managing IPsec sessions. Once configured, the kernel will apply
* confidentiality (encryption) and integrity (authentication) to IP traffic.
*
* Note that not all aspects of IPsec are permitted by this API. Applications may create
* transport mode security associations and apply them to individual sockets. Applications looking
* to create a VPN should use {@link VpnService}.
*
* @see RFC 4301, Security Architecture for the
* Internet Protocol
*/
@SystemService(Context.IPSEC_SERVICE)
public final class IpSecManager {
private static final String TAG = "IpSecManager";
/**
* Used when applying a transform to direct traffic through an {@link IpSecTransform}
* towards the host.
*
*
See {@link #applyTransportModeTransform(Socket, int, IpSecTransform)}.
*/
public static final int DIRECTION_IN = 0;
/**
* Used when applying a transform to direct traffic through an {@link IpSecTransform}
* away from the host.
*
*
See {@link #applyTransportModeTransform(Socket, int, IpSecTransform)}.
*/
public static final int DIRECTION_OUT = 1;
/** @hide */
@IntDef(value = {DIRECTION_IN, DIRECTION_OUT})
@Retention(RetentionPolicy.SOURCE)
public @interface PolicyDirection {}
/**
* The Security Parameter Index (SPI) 0 indicates an unknown or invalid index.
*
*
No IPsec packet may contain an SPI of 0.
*
* @hide
*/
@TestApi public static final int INVALID_SECURITY_PARAMETER_INDEX = 0;
/** @hide */
public interface Status {
public static final int OK = 0;
public static final int RESOURCE_UNAVAILABLE = 1;
public static final int SPI_UNAVAILABLE = 2;
}
/** @hide */
public static final int INVALID_RESOURCE_ID = -1;
/**
* Thrown to indicate that a requested SPI is in use.
*
*
The combination of remote {@code InetAddress} and SPI must be unique across all apps on
* one device. If this error is encountered, a new SPI is required before a transform may be
* created. This error can be avoided by calling {@link
* IpSecManager#allocateSecurityParameterIndex}.
*/
public static final class SpiUnavailableException extends AndroidException {
private final int mSpi;
/**
* Construct an exception indicating that a transform with the given SPI is already in use
* or otherwise unavailable.
*
* @param msg description indicating the colliding SPI
* @param spi the SPI that could not be used due to a collision
*/
SpiUnavailableException(String msg, int spi) {
super(msg + " (spi: " + spi + ")");
mSpi = spi;
}
/** Get the SPI that caused a collision. */
public int getSpi() {
return mSpi;
}
}
/**
* Thrown to indicate that an IPsec resource is unavailable.
*
*
This could apply to resources such as sockets, {@link SecurityParameterIndex}, {@link
* IpSecTransform}, or other system resources. If this exception is thrown, users should release
* allocated objects of the type requested.
*/
public static final class ResourceUnavailableException extends AndroidException {
ResourceUnavailableException(String msg) {
super(msg);
}
}
private final Context mContext;
private final IIpSecService mService;
/**
* This class represents a reserved SPI.
*
*
Objects of this type are used to track reserved security parameter indices. They can be
* obtained by calling {@link IpSecManager#allocateSecurityParameterIndex} and must be released
* by calling {@link #close()} when they are no longer needed.
*/
public static final class SecurityParameterIndex implements AutoCloseable {
private final IIpSecService mService;
private final InetAddress mDestinationAddress;
private final CloseGuard mCloseGuard = CloseGuard.get();
private int mSpi = INVALID_SECURITY_PARAMETER_INDEX;
private int mResourceId = INVALID_RESOURCE_ID;
/** Get the underlying SPI held by this object. */
public int getSpi() {
return mSpi;
}
/**
* Release an SPI that was previously reserved.
*
*
Release an SPI for use by other users in the system. If a SecurityParameterIndex is
* applied to an IpSecTransform, it will become unusable for future transforms but should
* still be closed to ensure system resources are released.
*/
@Override
public void close() {
try {
mService.releaseSecurityParameterIndex(mResourceId);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
} catch (Exception e) {
// On close we swallow all random exceptions since failure to close is not
// actionable by the user.
Log.e(TAG, "Failed to close " + this + ", Exception=" + e);
} finally {
mResourceId = INVALID_RESOURCE_ID;
mCloseGuard.close();
}
}
/** Check that the SPI was closed properly. */
@Override
protected void finalize() throws Throwable {
if (mCloseGuard != null) {
mCloseGuard.warnIfOpen();
}
close();
}
private SecurityParameterIndex(
@NonNull IIpSecService service, InetAddress destinationAddress, int spi)
throws ResourceUnavailableException, SpiUnavailableException {
mService = service;
mDestinationAddress = destinationAddress;
try {
IpSecSpiResponse result =
mService.allocateSecurityParameterIndex(
destinationAddress.getHostAddress(), spi, new Binder());
if (result == null) {
throw new NullPointerException("Received null response from IpSecService");
}
int status = result.status;
switch (status) {
case Status.OK:
break;
case Status.RESOURCE_UNAVAILABLE:
throw new ResourceUnavailableException(
"No more SPIs may be allocated by this requester.");
case Status.SPI_UNAVAILABLE:
throw new SpiUnavailableException("Requested SPI is unavailable", spi);
default:
throw new RuntimeException(
"Unknown status returned by IpSecService: " + status);
}
mSpi = result.spi;
mResourceId = result.resourceId;
if (mSpi == INVALID_SECURITY_PARAMETER_INDEX) {
throw new RuntimeException("Invalid SPI returned by IpSecService: " + status);
}
if (mResourceId == INVALID_RESOURCE_ID) {
throw new RuntimeException(
"Invalid Resource ID returned by IpSecService: " + status);
}
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
mCloseGuard.open("open");
}
/** @hide */
@VisibleForTesting
public int getResourceId() {
return mResourceId;
}
@Override
public String toString() {
return new StringBuilder()
.append("SecurityParameterIndex{spi=")
.append(mSpi)
.append(",resourceId=")
.append(mResourceId)
.append("}")
.toString();
}
}
/**
* Reserve a random SPI for traffic bound to or from the specified destination address.
*
*
If successful, this SPI is guaranteed available until released by a call to {@link
* SecurityParameterIndex#close()}.
*
* @param destinationAddress the destination address for traffic bearing the requested SPI.
* For inbound traffic, the destination should be an address currently assigned on-device.
* @return the reserved SecurityParameterIndex
* @throws {@link #ResourceUnavailableException} indicating that too many SPIs are
* currently allocated for this user
*/
@NonNull
public SecurityParameterIndex allocateSecurityParameterIndex(
@NonNull InetAddress destinationAddress) throws ResourceUnavailableException {
try {
return new SecurityParameterIndex(
mService,
destinationAddress,
IpSecManager.INVALID_SECURITY_PARAMETER_INDEX);
} catch (ServiceSpecificException e) {
throw rethrowUncheckedExceptionFromServiceSpecificException(e);
} catch (SpiUnavailableException unlikely) {
// Because this function allocates a totally random SPI, it really shouldn't ever
// fail to allocate an SPI; we simply need this because the exception is checked.
throw new ResourceUnavailableException("No SPIs available");
}
}
/**
* Reserve the requested SPI for traffic bound to or from the specified destination address.
*
*
If successful, this SPI is guaranteed available until released by a call to {@link
* SecurityParameterIndex#close()}.
*
* @param destinationAddress the destination address for traffic bearing the requested SPI.
* For inbound traffic, the destination should be an address currently assigned on-device.
* @param requestedSpi the requested SPI. The range 1-255 is reserved and may not be used. See
* RFC 4303 Section 2.1.
* @return the reserved SecurityParameterIndex
* @throws {@link #ResourceUnavailableException} indicating that too many SPIs are
* currently allocated for this user
* @throws {@link #SpiUnavailableException} indicating that the requested SPI could not be
* reserved
*/
@NonNull
public SecurityParameterIndex allocateSecurityParameterIndex(
@NonNull InetAddress destinationAddress, int requestedSpi)
throws SpiUnavailableException, ResourceUnavailableException {
if (requestedSpi == IpSecManager.INVALID_SECURITY_PARAMETER_INDEX) {
throw new IllegalArgumentException("Requested SPI must be a valid (non-zero) SPI");
}
try {
return new SecurityParameterIndex(mService, destinationAddress, requestedSpi);
} catch (ServiceSpecificException e) {
throw rethrowUncheckedExceptionFromServiceSpecificException(e);
}
}
/**
* Apply an IPsec transform to a stream socket.
*
*
This applies transport mode encapsulation to the given socket. Once applied, I/O on the
* socket will be encapsulated according to the parameters of the {@code IpSecTransform}. When
* the transform is removed from the socket by calling {@link #removeTransportModeTransforms},
* unprotected traffic can resume on that socket.
*
*
For security reasons, the destination address of any traffic on the socket must match the
* remote {@code InetAddress} of the {@code IpSecTransform}. Attempts to send traffic to any
* other IP address will result in an IOException. In addition, reads and writes on the socket
* will throw IOException if the user deactivates the transform (by calling {@link
* IpSecTransform#close()}) without calling {@link #removeTransportModeTransforms}.
*
*
Note that when applied to TCP sockets, calling {@link IpSecTransform#close()} on an
* applied transform before completion of graceful shutdown may result in the shutdown sequence
* failing to complete. As such, applications requiring graceful shutdown MUST close the socket
* prior to deactivating the applied transform. Socket closure may be performed asynchronously
* (in batches), so the returning of a close function does not guarantee shutdown of a socket.
* Setting an SO_LINGER timeout results in socket closure being performed synchronously, and is
* sufficient to ensure shutdown.
*
* Specifically, if the transform is deactivated (by calling {@link IpSecTransform#close()}),
* prior to the socket being closed, the standard [FIN - FIN/ACK - ACK], or the reset [RST]
* packets are dropped due to the lack of a valid Transform. Similarly, if a socket without the
* SO_LINGER option set is closed, the delayed/batched FIN packets may be dropped.
*
*
Rekey Procedure
*
* When applying a new tranform to a socket in the outbound direction, the previous transform
* will be removed and the new transform will take effect immediately, sending all traffic on
* the new transform; however, when applying a transform in the inbound direction, traffic
* on the old transform will continue to be decrypted and delivered until that transform is
* deallocated by calling {@link IpSecTransform#close()}. This overlap allows lossless rekey
* procedures where both transforms are valid until both endpoints are using the new transform
* and all in-flight packets have been received.
*
* @param socket a stream socket
* @param direction the direction in which the transform should be applied
* @param transform a transport mode {@code IpSecTransform}
* @throws IOException indicating that the transform could not be applied
*/
public void applyTransportModeTransform(@NonNull Socket socket,
@PolicyDirection int direction, @NonNull IpSecTransform transform) throws IOException {
// Ensure creation of FD. See b/77548890 for more details.
socket.getSoLinger();
applyTransportModeTransform(socket.getFileDescriptor$(), direction, transform);
}
/**
* Apply an IPsec transform to a datagram socket.
*
*
This applies transport mode encapsulation to the given socket. Once applied, I/O on the
* socket will be encapsulated according to the parameters of the {@code IpSecTransform}. When
* the transform is removed from the socket by calling {@link #removeTransportModeTransforms},
* unprotected traffic can resume on that socket.
*
*
For security reasons, the destination address of any traffic on the socket must match the
* remote {@code InetAddress} of the {@code IpSecTransform}. Attempts to send traffic to any
* other IP address will result in an IOException. In addition, reads and writes on the socket
* will throw IOException if the user deactivates the transform (by calling {@link
* IpSecTransform#close()}) without calling {@link #removeTransportModeTransforms}.
*
*
Rekey Procedure
*
* When applying a new tranform to a socket in the outbound direction, the previous transform
* will be removed and the new transform will take effect immediately, sending all traffic on
* the new transform; however, when applying a transform in the inbound direction, traffic
* on the old transform will continue to be decrypted and delivered until that transform is
* deallocated by calling {@link IpSecTransform#close()}. This overlap allows lossless rekey
* procedures where both transforms are valid until both endpoints are using the new transform
* and all in-flight packets have been received.
*
* @param socket a datagram socket
* @param direction the direction in which the transform should be applied
* @param transform a transport mode {@code IpSecTransform}
* @throws IOException indicating that the transform could not be applied
*/
public void applyTransportModeTransform(@NonNull DatagramSocket socket,
@PolicyDirection int direction, @NonNull IpSecTransform transform) throws IOException {
applyTransportModeTransform(socket.getFileDescriptor$(), direction, transform);
}
/**
* Apply an IPsec transform to a socket.
*
*
This applies transport mode encapsulation to the given socket. Once applied, I/O on the
* socket will be encapsulated according to the parameters of the {@code IpSecTransform}. When
* the transform is removed from the socket by calling {@link #removeTransportModeTransforms},
* unprotected traffic can resume on that socket.
*
*
For security reasons, the destination address of any traffic on the socket must match the
* remote {@code InetAddress} of the {@code IpSecTransform}. Attempts to send traffic to any
* other IP address will result in an IOException. In addition, reads and writes on the socket
* will throw IOException if the user deactivates the transform (by calling {@link
* IpSecTransform#close()}) without calling {@link #removeTransportModeTransforms}.
*
*
Note that when applied to TCP sockets, calling {@link IpSecTransform#close()} on an
* applied transform before completion of graceful shutdown may result in the shutdown sequence
* failing to complete. As such, applications requiring graceful shutdown MUST close the socket
* prior to deactivating the applied transform. Socket closure may be performed asynchronously
* (in batches), so the returning of a close function does not guarantee shutdown of a socket.
* Setting an SO_LINGER timeout results in socket closure being performed synchronously, and is
* sufficient to ensure shutdown.
*
* Specifically, if the transform is deactivated (by calling {@link IpSecTransform#close()}),
* prior to the socket being closed, the standard [FIN - FIN/ACK - ACK], or the reset [RST]
* packets are dropped due to the lack of a valid Transform. Similarly, if a socket without the
* SO_LINGER option set is closed, the delayed/batched FIN packets may be dropped.
*
*
Rekey Procedure
*
* When applying a new tranform to a socket in the outbound direction, the previous transform
* will be removed and the new transform will take effect immediately, sending all traffic on
* the new transform; however, when applying a transform in the inbound direction, traffic
* on the old transform will continue to be decrypted and delivered until that transform is
* deallocated by calling {@link IpSecTransform#close()}. This overlap allows lossless rekey
* procedures where both transforms are valid until both endpoints are using the new transform
* and all in-flight packets have been received.
*
* @param socket a socket file descriptor
* @param direction the direction in which the transform should be applied
* @param transform a transport mode {@code IpSecTransform}
* @throws IOException indicating that the transform could not be applied
*/
public void applyTransportModeTransform(@NonNull FileDescriptor socket,
@PolicyDirection int direction, @NonNull IpSecTransform transform) throws IOException {
// We dup() the FileDescriptor here because if we don't, then the ParcelFileDescriptor()
// constructor takes control and closes the user's FD when we exit the method.
try (ParcelFileDescriptor pfd = ParcelFileDescriptor.dup(socket)) {
mService.applyTransportModeTransform(pfd, direction, transform.getResourceId());
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
}
/**
* Remove an IPsec transform from a stream socket.
*
*
Once removed, traffic on the socket will not be encrypted. Removing transforms from a
* socket allows the socket to be reused for communication in the clear.
*
*
If an {@code IpSecTransform} object applied to this socket was deallocated by calling
* {@link IpSecTransform#close()}, then communication on the socket will fail until this method
* is called.
*
* @param socket a socket that previously had a transform applied to it
* @throws IOException indicating that the transform could not be removed from the socket
*/
public void removeTransportModeTransforms(@NonNull Socket socket) throws IOException {
// Ensure creation of FD. See b/77548890 for more details.
socket.getSoLinger();
removeTransportModeTransforms(socket.getFileDescriptor$());
}
/**
* Remove an IPsec transform from a datagram socket.
*
*
Once removed, traffic on the socket will not be encrypted. Removing transforms from a
* socket allows the socket to be reused for communication in the clear.
*
*
If an {@code IpSecTransform} object applied to this socket was deallocated by calling
* {@link IpSecTransform#close()}, then communication on the socket will fail until this method
* is called.
*
* @param socket a socket that previously had a transform applied to it
* @throws IOException indicating that the transform could not be removed from the socket
*/
public void removeTransportModeTransforms(@NonNull DatagramSocket socket) throws IOException {
removeTransportModeTransforms(socket.getFileDescriptor$());
}
/**
* Remove an IPsec transform from a socket.
*
*
Once removed, traffic on the socket will not be encrypted. Removing transforms from a
* socket allows the socket to be reused for communication in the clear.
*
*
If an {@code IpSecTransform} object applied to this socket was deallocated by calling
* {@link IpSecTransform#close()}, then communication on the socket will fail until this method
* is called.
*
* @param socket a socket that previously had a transform applied to it
* @throws IOException indicating that the transform could not be removed from the socket
*/
public void removeTransportModeTransforms(@NonNull FileDescriptor socket) throws IOException {
try (ParcelFileDescriptor pfd = ParcelFileDescriptor.dup(socket)) {
mService.removeTransportModeTransforms(pfd);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
}
/**
* Remove a Tunnel Mode IPsec Transform from a {@link Network}. This must be used as part of
* cleanup if a tunneled Network experiences a change in default route. The Network will drop
* all traffic that cannot be routed to the Tunnel's outbound interface. If that interface is
* lost, all traffic will drop.
*
*
TODO: Update javadoc for tunnel mode APIs at the same time the APIs are re-worked.
*
* @param net a network that currently has transform applied to it.
* @param transform a Tunnel Mode IPsec Transform that has been previously applied to the given
* network
* @hide
*/
public void removeTunnelModeTransform(Network net, IpSecTransform transform) {}
/**
* This class provides access to a UDP encapsulation Socket.
*
*
{@code UdpEncapsulationSocket} wraps a system-provided datagram socket intended for IKEv2
* signalling and UDP encapsulated IPsec traffic. Instances can be obtained by calling {@link
* IpSecManager#openUdpEncapsulationSocket}. The provided socket cannot be re-bound by the
* caller. The caller should not close the {@code FileDescriptor} returned by {@link
* #getFileDescriptor}, but should use {@link #close} instead.
*
*
Allowing the user to close or unbind a UDP encapsulation socket could impact the traffic
* of the next user who binds to that port. To prevent this scenario, these sockets are held
* open by the system so that they may only be closed by calling {@link #close} or when the user
* process exits.
*/
public static final class UdpEncapsulationSocket implements AutoCloseable {
private final ParcelFileDescriptor mPfd;
private final IIpSecService mService;
private int mResourceId = INVALID_RESOURCE_ID;
private final int mPort;
private final CloseGuard mCloseGuard = CloseGuard.get();
private UdpEncapsulationSocket(@NonNull IIpSecService service, int port)
throws ResourceUnavailableException, IOException {
mService = service;
try {
IpSecUdpEncapResponse result =
mService.openUdpEncapsulationSocket(port, new Binder());
switch (result.status) {
case Status.OK:
break;
case Status.RESOURCE_UNAVAILABLE:
throw new ResourceUnavailableException(
"No more Sockets may be allocated by this requester.");
default:
throw new RuntimeException(
"Unknown status returned by IpSecService: " + result.status);
}
mResourceId = result.resourceId;
mPort = result.port;
mPfd = result.fileDescriptor;
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
mCloseGuard.open("constructor");
}
/** Get the encapsulation socket's file descriptor. */
public FileDescriptor getFileDescriptor() {
if (mPfd == null) {
return null;
}
return mPfd.getFileDescriptor();
}
/** Get the bound port of the wrapped socket. */
public int getPort() {
return mPort;
}
/**
* Close this socket.
*
*
This closes the wrapped socket. Open encapsulation sockets count against a user's
* resource limits, and forgetting to close them eventually will result in {@link
* ResourceUnavailableException} being thrown.
*/
@Override
public void close() throws IOException {
try {
mService.closeUdpEncapsulationSocket(mResourceId);
mResourceId = INVALID_RESOURCE_ID;
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
} catch (Exception e) {
// On close we swallow all random exceptions since failure to close is not
// actionable by the user.
Log.e(TAG, "Failed to close " + this + ", Exception=" + e);
} finally {
mResourceId = INVALID_RESOURCE_ID;
mCloseGuard.close();
}
try {
mPfd.close();
} catch (IOException e) {
Log.e(TAG, "Failed to close UDP Encapsulation Socket with Port= " + mPort);
throw e;
}
}
/** Check that the socket was closed properly. */
@Override
protected void finalize() throws Throwable {
if (mCloseGuard != null) {
mCloseGuard.warnIfOpen();
}
close();
}
/** @hide */
@VisibleForTesting
public int getResourceId() {
return mResourceId;
}
@Override
public String toString() {
return new StringBuilder()
.append("UdpEncapsulationSocket{port=")
.append(mPort)
.append(",resourceId=")
.append(mResourceId)
.append("}")
.toString();
}
};
/**
* Open a socket for UDP encapsulation and bind to the given port.
*
*
See {@link UdpEncapsulationSocket} for the proper way to close the returned socket.
*
* @param port a local UDP port
* @return a socket that is bound to the given port
* @throws IOException indicating that the socket could not be opened or bound
* @throws ResourceUnavailableException indicating that too many encapsulation sockets are open
*/
// Returning a socket in this fashion that has been created and bound by the system
// is the only safe way to ensure that a socket is both accessible to the user and
// safely usable for Encapsulation without allowing a user to possibly unbind from/close
// the port, which could potentially impact the traffic of the next user who binds to that
// socket.
@NonNull
public UdpEncapsulationSocket openUdpEncapsulationSocket(int port)
throws IOException, ResourceUnavailableException {
/*
* Most range checking is done in the service, but this version of the constructor expects
* a valid port number, and zero cannot be checked after being passed to the service.
*/
if (port == 0) {
throw new IllegalArgumentException("Specified port must be a valid port number!");
}
try {
return new UdpEncapsulationSocket(mService, port);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
}
}
/**
* Open a socket for UDP encapsulation.
*
*
See {@link UdpEncapsulationSocket} for the proper way to close the returned socket.
*
*
The local port of the returned socket can be obtained by calling {@link
* UdpEncapsulationSocket#getPort()}.
*
* @return a socket that is bound to a local port
* @throws IOException indicating that the socket could not be opened or bound
* @throws ResourceUnavailableException indicating that too many encapsulation sockets are open
*/
// Returning a socket in this fashion that has been created and bound by the system
// is the only safe way to ensure that a socket is both accessible to the user and
// safely usable for Encapsulation without allowing a user to possibly unbind from/close
// the port, which could potentially impact the traffic of the next user who binds to that
// socket.
@NonNull
public UdpEncapsulationSocket openUdpEncapsulationSocket()
throws IOException, ResourceUnavailableException {
try {
return new UdpEncapsulationSocket(mService, 0);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
}
}
/**
* This class represents an IpSecTunnelInterface
*
*
IpSecTunnelInterface objects track tunnel interfaces that serve as
* local endpoints for IPsec tunnels.
*
*
Creating an IpSecTunnelInterface creates a device to which IpSecTransforms may be
* applied to provide IPsec security to packets sent through the tunnel. While a tunnel
* cannot be used in standalone mode within Android, the higher layers may use the tunnel
* to create Network objects which are accessible to the Android system.
* @hide
*/
@SystemApi
public static final class IpSecTunnelInterface implements AutoCloseable {
private final String mOpPackageName;
private final IIpSecService mService;
private final InetAddress mRemoteAddress;
private final InetAddress mLocalAddress;
private final Network mUnderlyingNetwork;
private final CloseGuard mCloseGuard = CloseGuard.get();
private String mInterfaceName;
private int mResourceId = INVALID_RESOURCE_ID;
/** Get the underlying SPI held by this object. */
@NonNull
public String getInterfaceName() {
return mInterfaceName;
}
/**
* Add an address to the IpSecTunnelInterface
*
*
Add an address which may be used as the local inner address for
* tunneled traffic.
*
* @param address the local address for traffic inside the tunnel
* @param prefixLen length of the InetAddress prefix
* @hide
*/
@SystemApi
@RequiresFeature(PackageManager.FEATURE_IPSEC_TUNNELS)
@RequiresPermission(android.Manifest.permission.MANAGE_IPSEC_TUNNELS)
public void addAddress(@NonNull InetAddress address, int prefixLen) throws IOException {
try {
mService.addAddressToTunnelInterface(
mResourceId, new LinkAddress(address, prefixLen), mOpPackageName);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
}
/**
* Remove an address from the IpSecTunnelInterface
*
*
Remove an address which was previously added to the IpSecTunnelInterface
*
* @param address to be removed
* @param prefixLen length of the InetAddress prefix
* @hide
*/
@SystemApi
@RequiresFeature(PackageManager.FEATURE_IPSEC_TUNNELS)
@RequiresPermission(android.Manifest.permission.MANAGE_IPSEC_TUNNELS)
public void removeAddress(@NonNull InetAddress address, int prefixLen) throws IOException {
try {
mService.removeAddressFromTunnelInterface(
mResourceId, new LinkAddress(address, prefixLen), mOpPackageName);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
}
private IpSecTunnelInterface(@NonNull Context ctx, @NonNull IIpSecService service,
@NonNull InetAddress localAddress, @NonNull InetAddress remoteAddress,
@NonNull Network underlyingNetwork)
throws ResourceUnavailableException, IOException {
mOpPackageName = ctx.getOpPackageName();
mService = service;
mLocalAddress = localAddress;
mRemoteAddress = remoteAddress;
mUnderlyingNetwork = underlyingNetwork;
try {
IpSecTunnelInterfaceResponse result =
mService.createTunnelInterface(
localAddress.getHostAddress(),
remoteAddress.getHostAddress(),
underlyingNetwork,
new Binder(),
mOpPackageName);
switch (result.status) {
case Status.OK:
break;
case Status.RESOURCE_UNAVAILABLE:
throw new ResourceUnavailableException(
"No more tunnel interfaces may be allocated by this requester.");
default:
throw new RuntimeException(
"Unknown status returned by IpSecService: " + result.status);
}
mResourceId = result.resourceId;
mInterfaceName = result.interfaceName;
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
mCloseGuard.open("constructor");
}
/**
* Delete an IpSecTunnelInterface
*
*
Calling close will deallocate the IpSecTunnelInterface and all of its system
* resources. Any packets bound for this interface either inbound or outbound will
* all be lost.
*/
@Override
public void close() {
try {
mService.deleteTunnelInterface(mResourceId, mOpPackageName);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
} catch (Exception e) {
// On close we swallow all random exceptions since failure to close is not
// actionable by the user.
Log.e(TAG, "Failed to close " + this + ", Exception=" + e);
} finally {
mResourceId = INVALID_RESOURCE_ID;
mCloseGuard.close();
}
}
/** Check that the Interface was closed properly. */
@Override
protected void finalize() throws Throwable {
if (mCloseGuard != null) {
mCloseGuard.warnIfOpen();
}
close();
}
/** @hide */
@VisibleForTesting
public int getResourceId() {
return mResourceId;
}
@Override
public String toString() {
return new StringBuilder()
.append("IpSecTunnelInterface{ifname=")
.append(mInterfaceName)
.append(",resourceId=")
.append(mResourceId)
.append("}")
.toString();
}
}
/**
* Create a new IpSecTunnelInterface as a local endpoint for tunneled IPsec traffic.
*
*
An application that creates tunnels is responsible for cleaning up the tunnel when the
* underlying network goes away, and the onLost() callback is received.
*
* @param localAddress The local addres of the tunnel
* @param remoteAddress The local addres of the tunnel
* @param underlyingNetwork the {@link Network} that will carry traffic for this tunnel.
* This network should almost certainly be a network such as WiFi with an L2 address.
* @return a new {@link IpSecManager#IpSecTunnelInterface} with the specified properties
* @throws IOException indicating that the socket could not be opened or bound
* @throws ResourceUnavailableException indicating that too many encapsulation sockets are open
* @hide
*/
@SystemApi
@NonNull
@RequiresFeature(PackageManager.FEATURE_IPSEC_TUNNELS)
@RequiresPermission(android.Manifest.permission.MANAGE_IPSEC_TUNNELS)
public IpSecTunnelInterface createIpSecTunnelInterface(@NonNull InetAddress localAddress,
@NonNull InetAddress remoteAddress, @NonNull Network underlyingNetwork)
throws ResourceUnavailableException, IOException {
try {
return new IpSecTunnelInterface(
mContext, mService, localAddress, remoteAddress, underlyingNetwork);
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
}
}
/**
* Apply an active Tunnel Mode IPsec Transform to a {@link IpSecTunnelInterface}, which will
* tunnel all traffic for the given direction through the underlying network's interface with
* IPsec (applies an outer IP header and IPsec Header to all traffic, and expects an additional
* IP header and IPsec Header on all inbound traffic).
*
Applications should probably not use this API directly.
*
*
* @param tunnel The {@link IpSecManager#IpSecTunnelInterface} that will use the supplied
* transform.
* @param direction the direction, {@link DIRECTION_OUT} or {@link #DIRECTION_IN} in which
* the transform will be used.
* @param transform an {@link IpSecTransform} created in tunnel mode
* @throws IOException indicating that the transform could not be applied due to a lower
* layer failure.
* @hide
*/
@SystemApi
@RequiresFeature(PackageManager.FEATURE_IPSEC_TUNNELS)
@RequiresPermission(android.Manifest.permission.MANAGE_IPSEC_TUNNELS)
public void applyTunnelModeTransform(@NonNull IpSecTunnelInterface tunnel,
@PolicyDirection int direction, @NonNull IpSecTransform transform) throws IOException {
try {
mService.applyTunnelModeTransform(
tunnel.getResourceId(), direction,
transform.getResourceId(), mContext.getOpPackageName());
} catch (ServiceSpecificException e) {
throw rethrowCheckedExceptionFromServiceSpecificException(e);
} catch (RemoteException e) {
throw e.rethrowFromSystemServer();
}
}
/**
* Construct an instance of IpSecManager within an application context.
*
* @param context the application context for this manager
* @hide
*/
public IpSecManager(Context ctx, IIpSecService service) {
mContext = ctx;
mService = checkNotNull(service, "missing service");
}
private static void maybeHandleServiceSpecificException(ServiceSpecificException sse) {
// OsConstants are late binding, so switch statements can't be used.
if (sse.errorCode == OsConstants.EINVAL) {
throw new IllegalArgumentException(sse);
} else if (sse.errorCode == OsConstants.EAGAIN) {
throw new IllegalStateException(sse);
} else if (sse.errorCode == OsConstants.EOPNOTSUPP
|| sse.errorCode == OsConstants.EPROTONOSUPPORT) {
throw new UnsupportedOperationException(sse);
}
}
/**
* Convert an Errno SSE to the correct Unchecked exception type.
*
* This method never actually returns.
*/
// package
static RuntimeException
rethrowUncheckedExceptionFromServiceSpecificException(ServiceSpecificException sse) {
maybeHandleServiceSpecificException(sse);
throw new RuntimeException(sse);
}
/**
* Convert an Errno SSE to the correct Checked or Unchecked exception type.
*
* This method may throw IOException, or it may throw an unchecked exception; it will never
* actually return.
*/
// package
static IOException rethrowCheckedExceptionFromServiceSpecificException(
ServiceSpecificException sse) throws IOException {
// First see if this is an unchecked exception of a type we know.
// If so, then we prefer the unchecked (specific) type of exception.
maybeHandleServiceSpecificException(sse);
// If not, then all we can do is provide the SSE in the form of an IOException.
throw new ErrnoException(
"IpSec encountered errno=" + sse.errorCode, sse.errorCode).rethrowAsIOException();
}
}