Merge "initial revision of NetworkDiagnostics" into mnc-dev

import com.android.internal.util.XmlUtils;

import com.android.server.am.BatteryStatsService;

import com.android.server.connectivity.DataConnectionStats;

import com.android.server.connectivity.NetworkDiagnostics;

import com.android.server.connectivity.Nat464Xlat;

import com.android.server.connectivity.NetworkAgentInfo;

import com.android.server.connectivity.NetworkMonitor;

        return ret;

    }

    private boolean shouldPerformDiagnostics(String[] args) {

        for (String arg : args) {

            if (arg.equals("--diag")) {

                return true;

            }

        }

        return false;

    }

    @Override

    protected void dump(FileDescriptor fd, PrintWriter writer, String[] args) {

        final IndentingPrintWriter pw = new IndentingPrintWriter(writer, "  ");

            return;

        }

        final List<NetworkDiagnostics> netDiags = new ArrayList<NetworkDiagnostics>();

        if (shouldPerformDiagnostics(args)) {

            final long DIAG_TIME_MS = 5000;

            for (NetworkAgentInfo nai : mNetworkAgentInfos.values()) {

                // Start gathering diagnostic information.

                netDiags.add(new NetworkDiagnostics(

                        nai.network,

                        new LinkProperties(nai.linkProperties),

                        DIAG_TIME_MS));

            }

            for (NetworkDiagnostics netDiag : netDiags) {

                pw.println();

                netDiag.waitForMeasurements();

                netDiag.dump(pw);

            }

            return;

        }

        pw.print("NetworkFactories for:");

        for (NetworkFactoryInfo nfi : mNetworkFactoryInfos.values()) {

            pw.print(" " + nfi.name);

/*

 * 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.

 */

package com.android.server.connectivity;

import static android.system.OsConstants.*;

import android.net.LinkProperties;

import android.net.Network;

import android.net.RouteInfo;

import android.os.SystemClock;

import android.system.ErrnoException;

import android.system.Os;

import android.system.StructTimeval;

import android.text.TextUtils;

import com.android.internal.util.IndentingPrintWriter;

import java.io.Closeable;

import java.io.FileDescriptor;

import java.io.InterruptedIOException;

import java.io.IOException;

import java.net.Inet4Address;

import java.net.Inet6Address;

import java.net.InetAddress;

import java.net.InetSocketAddress;

import java.net.NetworkInterface;

import java.net.SocketAddress;

import java.net.SocketException;

import java.net.UnknownHostException;

import java.nio.ByteBuffer;

import java.nio.charset.StandardCharsets;

import java.util.concurrent.CountDownLatch;

import java.util.concurrent.TimeUnit;

import java.util.Arrays;

import java.util.HashMap;

import java.util.Map;

import java.util.Random;

import libcore.io.IoUtils;

/**

 * NetworkDiagnostics

 *

 * A simple class to diagnose network connectivity fundamentals.  Current

 * checks performed are:

 *     - ICMPv4/v6 echo requests for all routers

 *     - ICMPv4/v6 echo requests for all DNS servers

 *     - DNS UDP queries to all DNS servers

 *

 * Currently unimplemented checks include:

 *     - report ARP/ND data about on-link neighbors

 *     - DNS TCP queries to all DNS servers

 *     - HTTP DIRECT and PROXY checks

 *     - port 443 blocking/TLS intercept checks

 *     - QUIC reachability checks

 *     - MTU checks

 *

 * The supplied timeout bounds the entire diagnostic process.  Each specific

 * check class must implement this upper bound on measurements in whichever

 * manner is most appropriate and effective.

 *

 * @hide

 */

public class NetworkDiagnostics {

    private static final String TAG = "NetworkDiagnostics";

    // For brevity elsewhere.

    private static final long now() {

        return SystemClock.elapsedRealtime();

    }

    // Values from RFC 1035 section 4.1.1, names from <arpa/nameser.h>.

    // Should be a member of DnsUdpCheck, but "compiler says no".

    public static enum DnsResponseCode { NOERROR, FORMERR, SERVFAIL, NXDOMAIN, NOTIMP, REFUSED };

    private final Network mNetwork;

    private final LinkProperties mLinkProperties;

    private final Integer mInterfaceIndex;

    private final long mTimeoutMs;

    private final long mStartTime;

    private final long mDeadlineTime;

    // A counter, initialized to the total number of measurements,

    // so callers can wait for completion.

    private final CountDownLatch mCountDownLatch;

    private class Measurement {

        private static final String SUCCEEDED = "SUCCEEDED";

        private static final String FAILED = "FAILED";

        // TODO: Refactor to make these private for better encapsulation.

        public String description = "";

        public long startTime;

        public long finishTime;

        public String result = "";

        public Thread thread;

        public void recordSuccess(String msg) {

            maybeFixupTimes();

            if (mCountDownLatch != null) {

                mCountDownLatch.countDown();

            }

            result = SUCCEEDED + ": " + msg;

        }

        public void recordFailure(String msg) {

            maybeFixupTimes();

            if (mCountDownLatch != null) {

                mCountDownLatch.countDown();

            }

            result = FAILED + ": " + msg;

        }

        private void maybeFixupTimes() {

            // Allows the caller to just set success/failure and not worry

            // about also setting the correct finishing time.

            if (finishTime == 0) { finishTime = now(); }

            // In cases where, for example, a failure has occurred before the

            // measurement even began, fixup the start time to reflect as much.

            if (startTime == 0) { startTime = finishTime; }

        }

        @Override

        public String toString() {

            return description + ": " + result + " (" + (finishTime - startTime) + "ms)";

        }

    }

    private final Map<InetAddress, Measurement> mIcmpChecks = new HashMap<>();

    private final Map<InetAddress, Measurement> mDnsUdpChecks = new HashMap<>();

    private final String mDescription;

    public NetworkDiagnostics(Network network, LinkProperties lp, long timeoutMs) {

        mNetwork = network;

        mLinkProperties = lp;

        mInterfaceIndex = getInterfaceIndex(mLinkProperties.getInterfaceName());

        mTimeoutMs = timeoutMs;

        mStartTime = now();

        mDeadlineTime = mStartTime + mTimeoutMs;

        for (RouteInfo route : mLinkProperties.getRoutes()) {

            if (route.hasGateway()) {

                prepareIcmpMeasurement(route.getGateway());

            }

        }

        for (InetAddress nameserver : mLinkProperties.getDnsServers()) {

                prepareIcmpMeasurement(nameserver);

                prepareDnsMeasurement(nameserver);

        }

        mCountDownLatch = new CountDownLatch(totalMeasurementCount());

        startMeasurements();

        mDescription = "ifaces{" + TextUtils.join(",", mLinkProperties.getAllInterfaceNames()) + "}"

                + " index{" + mInterfaceIndex + "}"

                + " network{" + mNetwork + "}"

                + " nethandle{" + mNetwork.getNetworkHandle() + "}";

    }

    private static Integer getInterfaceIndex(String ifname) {

        try {

            NetworkInterface ni = NetworkInterface.getByName(ifname);

            return ni.getIndex();

        } catch (NullPointerException | SocketException e) {

            return null;

        }

    }

    private void prepareIcmpMeasurement(InetAddress target) {

        if (!mIcmpChecks.containsKey(target)) {

            Measurement measurement = new Measurement();

            measurement.thread = new Thread(new IcmpCheck(target, measurement));

            mIcmpChecks.put(target, measurement);

        }

    }

    private void prepareDnsMeasurement(InetAddress target) {

        if (!mDnsUdpChecks.containsKey(target)) {

            Measurement measurement = new Measurement();

            measurement.thread = new Thread(new DnsUdpCheck(target, measurement));

            mDnsUdpChecks.put(target, measurement);

        }

    }

    private int totalMeasurementCount() {

        return mIcmpChecks.size() + mDnsUdpChecks.size();

    }

    private void startMeasurements() {

        for (Measurement measurement : mIcmpChecks.values()) {

            measurement.thread.start();

        }

        for (Measurement measurement : mDnsUdpChecks.values()) {

            measurement.thread.start();

        }

    }

    public void waitForMeasurements() {

        try {

            mCountDownLatch.await(mDeadlineTime - now(), TimeUnit.MILLISECONDS);

        } catch (InterruptedException ignored) {}

    }

    public void dump(IndentingPrintWriter pw) {

        pw.println(TAG + ":" + mDescription);

        final long unfinished = mCountDownLatch.getCount();

        if (unfinished > 0) {

            // This can't happen unless a caller forgets to call waitForMeasurements()

            // or a measurement isn't implemented to correctly honor the timeout.

            pw.println("WARNING: countdown wait incomplete: "

                    + unfinished + " unfinished measurements");

        }

        pw.increaseIndent();

        for (Map.Entry<InetAddress, Measurement> entry : mIcmpChecks.entrySet()) {

            if (entry.getKey() instanceof Inet4Address) {

                pw.println(entry.getValue().toString());

            }

        }

        for (Map.Entry<InetAddress, Measurement> entry : mIcmpChecks.entrySet()) {

            if (entry.getKey() instanceof Inet6Address) {

                pw.println(entry.getValue().toString());

            }

        }

        for (Map.Entry<InetAddress, Measurement> entry : mDnsUdpChecks.entrySet()) {

            if (entry.getKey() instanceof Inet4Address) {

                pw.println(entry.getValue().toString());

            }

        }

        for (Map.Entry<InetAddress, Measurement> entry : mDnsUdpChecks.entrySet()) {

            if (entry.getKey() instanceof Inet6Address) {

                pw.println(entry.getValue().toString());

            }

        }

        pw.decreaseIndent();

    }

    private class SimpleSocketCheck implements Closeable {

        protected final InetAddress mTarget;

        protected final int mAddressFamily;

        protected final Measurement mMeasurement;

        protected FileDescriptor mFileDescriptor;

        protected SocketAddress mSocketAddress;

        protected SimpleSocketCheck(InetAddress target, Measurement measurement) {

            mMeasurement = measurement;

            if (target instanceof Inet6Address) {

                Inet6Address targetWithScopeId = null;

                if (target.isLinkLocalAddress() && mInterfaceIndex != null) {

                    try {

                        targetWithScopeId = Inet6Address.getByAddress(

                                null, target.getAddress(), mInterfaceIndex);

                    } catch (UnknownHostException e) {

                        mMeasurement.recordFailure(e.toString());

                    }

                }

                mTarget = (targetWithScopeId != null) ? targetWithScopeId : target;

                mAddressFamily = AF_INET6;

            } else {

                mTarget = target;

                mAddressFamily = AF_INET;

            }

        }

        protected void setupSocket(

                int sockType, int protocol, long writeTimeout, long readTimeout, int dstPort)

                throws ErrnoException, IOException {

            mFileDescriptor = Os.socket(mAddressFamily, sockType, protocol);

            // Setting SNDTIMEO is purely for defensive purposes.

            Os.setsockoptTimeval(mFileDescriptor,

                    SOL_SOCKET, SO_SNDTIMEO, StructTimeval.fromMillis(writeTimeout));

            Os.setsockoptTimeval(mFileDescriptor,

                    SOL_SOCKET, SO_RCVTIMEO, StructTimeval.fromMillis(readTimeout));

            // TODO: Use IP_RECVERR/IPV6_RECVERR, pending OsContants availability.

            mNetwork.bindSocket(mFileDescriptor);

            Os.connect(mFileDescriptor, mTarget, dstPort);

            mSocketAddress = Os.getsockname(mFileDescriptor);

        }

        protected String getSocketAddressString() {

            // The default toString() implementation is not the prettiest.

            InetSocketAddress inetSockAddr = (InetSocketAddress) mSocketAddress;

            InetAddress localAddr = inetSockAddr.getAddress();

            return String.format(

                    (localAddr instanceof Inet6Address ? "[%s]:%d" : "%s:%d"),

                    localAddr.getHostAddress(), inetSockAddr.getPort());

        }

        @Override

        public void close() {

            IoUtils.closeQuietly(mFileDescriptor);

        }

    }

    private class IcmpCheck extends SimpleSocketCheck implements Runnable {

        private static final int TIMEOUT_SEND = 100;

        private static final int TIMEOUT_RECV = 300;

        private static final int ICMPV4_ECHO_REQUEST = 8;

        private static final int ICMPV6_ECHO_REQUEST = 128;

        private static final int PACKET_BUFSIZE = 512;

        private final int mProtocol;

        private final int mIcmpType;

        public IcmpCheck(InetAddress target, Measurement measurement) {

            super(target, measurement);

            if (mAddressFamily == AF_INET6) {

                mProtocol = IPPROTO_ICMPV6;

                mIcmpType = ICMPV6_ECHO_REQUEST;

                mMeasurement.description = "ICMPv6";

            } else {

                mProtocol = IPPROTO_ICMP;

                mIcmpType = ICMPV4_ECHO_REQUEST;

                mMeasurement.description = "ICMPv4";

            }

            mMeasurement.description += " dst{" + mTarget.getHostAddress() + "}";

        }

        @Override

        public void run() {

            // Check if this measurement has already failed during setup.

            if (mMeasurement.finishTime > 0) {

                // If the measurement failed during construction it didn't

                // decrement the countdown latch; do so here.

                mCountDownLatch.countDown();

                return;

            }

            try {

                setupSocket(SOCK_DGRAM, mProtocol, TIMEOUT_SEND, TIMEOUT_RECV, 0);

            } catch (ErrnoException | IOException e) {

                mMeasurement.recordFailure(e.toString());

                return;

            }

            mMeasurement.description += " src{" + getSocketAddressString() + "}";

            // Build a trivial ICMP packet.

            final byte[] icmpPacket = {

                    (byte) mIcmpType, 0, 0, 0, 0, 0, 0, 0  // ICMP header

            };

            int count = 0;

            mMeasurement.startTime = now();

            while (now() < mDeadlineTime - (TIMEOUT_SEND + TIMEOUT_RECV)) {

                count++;

                icmpPacket[icmpPacket.length - 1] = (byte) count;

                try {

                    Os.write(mFileDescriptor, icmpPacket, 0, icmpPacket.length);

                } catch (ErrnoException | InterruptedIOException e) {

                    mMeasurement.recordFailure(e.toString());

                    break;

                }

                try {

                    ByteBuffer reply = ByteBuffer.allocate(PACKET_BUFSIZE);

                    Os.read(mFileDescriptor, reply);

                    // TODO: send a few pings back to back to guesstimate packet loss.

                    mMeasurement.recordSuccess("1/" + count);

                    break;

                } catch (ErrnoException | InterruptedIOException e) {

                    continue;

                }

            }

            if (mMeasurement.finishTime == 0) {

                mMeasurement.recordFailure("0/" + count);

            }

            close();

        }

    }

    private class DnsUdpCheck extends SimpleSocketCheck implements Runnable {

        private static final int TIMEOUT_SEND = 100;

        private static final int TIMEOUT_RECV = 500;

        private static final int DNS_SERVER_PORT = 53;

        private static final int RR_TYPE_A = 1;

        private static final int RR_TYPE_AAAA = 28;

        private static final int PACKET_BUFSIZE = 512;

        private final Random mRandom = new Random();

        // Should be static, but the compiler mocks our puny, human attempts at reason.

        private String responseCodeStr(int rcode) {

            try {

                return DnsResponseCode.values()[rcode].toString();

            } catch (IndexOutOfBoundsException e) {

                return String.valueOf(rcode);

            }

        }

        private final int mQueryType;

        public DnsUdpCheck(InetAddress target, Measurement measurement) {

            super(target, measurement);

            // TODO: Ideally, query the target for both types regardless of address family.

            if (mAddressFamily == AF_INET6) {

                mQueryType = RR_TYPE_AAAA;

            } else {

                mQueryType = RR_TYPE_A;

            }

            mMeasurement.description = "DNS UDP dst{" + mTarget.getHostAddress() + "}";

        }

        @Override

        public void run() {

            // Check if this measurement has already failed during setup.

            if (mMeasurement.finishTime > 0) {

                // If the measurement failed during construction it didn't

                // decrement the countdown latch; do so here.

                mCountDownLatch.countDown();

                return;

            }

            try {

                setupSocket(SOCK_DGRAM, IPPROTO_UDP, TIMEOUT_SEND, TIMEOUT_RECV, DNS_SERVER_PORT);

            } catch (ErrnoException | IOException e) {

                mMeasurement.recordFailure(e.toString());

                return;

            }

            mMeasurement.description += " src{" + getSocketAddressString() + "}";

            // This needs to be fixed length so it can be dropped into the pre-canned packet.

            final String sixRandomDigits =

                    Integer.valueOf(mRandom.nextInt(900000) + 100000).toString();

            mMeasurement.description += " qtype{" + mQueryType + "}"

                    + " qname{" + sixRandomDigits + "-android-ds.metric.gstatic.com}";

            // Build a trivial DNS packet.

            final byte[] dnsPacket = getDnsQueryPacket(sixRandomDigits);

            int count = 0;

            mMeasurement.startTime = now();

            while (now() < mDeadlineTime - (TIMEOUT_RECV + TIMEOUT_RECV)) {

                count++;

                try {

                    Os.write(mFileDescriptor, dnsPacket, 0, dnsPacket.length);

                } catch (ErrnoException | InterruptedIOException e) {

                    mMeasurement.recordFailure(e.toString());

                    break;

                }

                try {

                    ByteBuffer reply = ByteBuffer.allocate(PACKET_BUFSIZE);

                    Os.read(mFileDescriptor, reply);

                    // TODO: more correct and detailed evaluation of the response,

                    // possibly adding the returned IP address(es) to the output.

                    final String rcodeStr = (reply.limit() > 3)

                            ? " " + responseCodeStr((int) (reply.get(3)) & 0x0f)

                            : "";

                    mMeasurement.recordSuccess("1/" + count + rcodeStr);

                    break;

                } catch (ErrnoException | InterruptedIOException e) {

                    continue;

                }

            }

            if (mMeasurement.finishTime == 0) {

                mMeasurement.recordFailure("0/" + count);

            }

            close();

        }

        private byte[] getDnsQueryPacket(String sixRandomDigits) {

            byte[] rnd = sixRandomDigits.getBytes(StandardCharsets.US_ASCII);

            return new byte[] {

                (byte) mRandom.nextInt(), (byte) mRandom.nextInt(),  // [0-1]   query ID

                1, 0,  // [2-3]   flags; byte[2] = 1 for recursion desired (RD).

                0, 1,  // [4-5]   QDCOUNT (number of queries)

                0, 0,  // [6-7]   ANCOUNT (number of answers)

                0, 0,  // [8-9]   NSCOUNT (number of name server records)

                0, 0,  // [10-11] ARCOUNT (number of additional records)

                17, rnd[0], rnd[1], rnd[2], rnd[3], rnd[4], rnd[5],

                        '-', 'a', 'n', 'd', 'r', 'o', 'i', 'd', '-', 'd', 's',

                6, 'm', 'e', 't', 'r', 'i', 'c',

                7, 'g', 's', 't', 'a', 't', 'i', 'c',

                3, 'c', 'o', 'm',

                0,  // null terminator of FQDN (root TLD)

                0, (byte) mQueryType,  // QTYPE

                0, 1  // QCLASS, set to 1 = IN (Internet)

            };

        }

    }

}