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      1 /*
      2  * Copyright (C) 2008 The Android Open Source Project
      3  *
      4  * Licensed under the Apache License, Version 2.0 (the "License");
      5  * you may not use this file except in compliance with the License.
      6  * You may obtain a copy of the License at
      7  *
      8  *      http://www.apache.org/licenses/LICENSE-2.0
      9  *
     10  * Unless required by applicable law or agreed to in writing, software
     11  * distributed under the License is distributed on an "AS IS" BASIS,
     12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
     13  * See the License for the specific language governing permissions and
     14  * limitations under the License.
     15  */
     16 
     17 package android.net;
     18 
     19 import android.os.SystemClock;
     20 import android.util.Log;
     21 
     22 import java.io.IOException;
     23 import java.net.DatagramPacket;
     24 import java.net.DatagramSocket;
     25 import java.net.InetAddress;
     26 
     27 /**
     28  * {@hide}
     29  *
     30  * Simple SNTP client class for retrieving network time.
     31  *
     32  * Sample usage:
     33  * <pre>SntpClient client = new SntpClient();
     34  * if (client.requestTime("time.foo.com")) {
     35  *     long now = client.getNtpTime() + SystemClock.elapsedRealtime() - client.getNtpTimeReference();
     36  * }
     37  * </pre>
     38  */
     39 public class SntpClient
     40 {
     41     private static final String TAG = "SntpClient";
     42 
     43     private static final int REFERENCE_TIME_OFFSET = 16;
     44     private static final int ORIGINATE_TIME_OFFSET = 24;
     45     private static final int RECEIVE_TIME_OFFSET = 32;
     46     private static final int TRANSMIT_TIME_OFFSET = 40;
     47     private static final int NTP_PACKET_SIZE = 48;
     48 
     49     private static final int NTP_PORT = 123;
     50     private static final int NTP_MODE_CLIENT = 3;
     51     private static final int NTP_VERSION = 3;
     52 
     53     // Number of seconds between Jan 1, 1900 and Jan 1, 1970
     54     // 70 years plus 17 leap days
     55     private static final long OFFSET_1900_TO_1970 = ((365L * 70L) + 17L) * 24L * 60L * 60L;
     56 
     57     // system time computed from NTP server response
     58     private long mNtpTime;
     59 
     60     // value of SystemClock.elapsedRealtime() corresponding to mNtpTime
     61     private long mNtpTimeReference;
     62 
     63     // round trip time in milliseconds
     64     private long mRoundTripTime;
     65 
     66     /**
     67      * Sends an SNTP request to the given host and processes the response.
     68      *
     69      * @param host host name of the server.
     70      * @param timeout network timeout in milliseconds.
     71      * @return true if the transaction was successful.
     72      */
     73     public boolean requestTime(String host, int timeout) {
     74         DatagramSocket socket = null;
     75         try {
     76             socket = new DatagramSocket();
     77             socket.setSoTimeout(timeout);
     78             InetAddress address = InetAddress.getByName(host);
     79             byte[] buffer = new byte[NTP_PACKET_SIZE];
     80             DatagramPacket request = new DatagramPacket(buffer, buffer.length, address, NTP_PORT);
     81 
     82             // set mode = 3 (client) and version = 3
     83             // mode is in low 3 bits of first byte
     84             // version is in bits 3-5 of first byte
     85             buffer[0] = NTP_MODE_CLIENT | (NTP_VERSION << 3);
     86 
     87             // get current time and write it to the request packet
     88             long requestTime = System.currentTimeMillis();
     89             long requestTicks = SystemClock.elapsedRealtime();
     90             writeTimeStamp(buffer, TRANSMIT_TIME_OFFSET, requestTime);
     91 
     92             socket.send(request);
     93 
     94             // read the response
     95             DatagramPacket response = new DatagramPacket(buffer, buffer.length);
     96             socket.receive(response);
     97             long responseTicks = SystemClock.elapsedRealtime();
     98             long responseTime = requestTime + (responseTicks - requestTicks);
     99 
    100             // extract the results
    101             long originateTime = readTimeStamp(buffer, ORIGINATE_TIME_OFFSET);
    102             long receiveTime = readTimeStamp(buffer, RECEIVE_TIME_OFFSET);
    103             long transmitTime = readTimeStamp(buffer, TRANSMIT_TIME_OFFSET);
    104             long roundTripTime = responseTicks - requestTicks - (transmitTime - receiveTime);
    105             // receiveTime = originateTime + transit + skew
    106             // responseTime = transmitTime + transit - skew
    107             // clockOffset = ((receiveTime - originateTime) + (transmitTime - responseTime))/2
    108             //             = ((originateTime + transit + skew - originateTime) +
    109             //                (transmitTime - (transmitTime + transit - skew)))/2
    110             //             = ((transit + skew) + (transmitTime - transmitTime - transit + skew))/2
    111             //             = (transit + skew - transit + skew)/2
    112             //             = (2 * skew)/2 = skew
    113             long clockOffset = ((receiveTime - originateTime) + (transmitTime - responseTime))/2;
    114             // if (false) Log.d(TAG, "round trip: " + roundTripTime + " ms");
    115             // if (false) Log.d(TAG, "clock offset: " + clockOffset + " ms");
    116 
    117             // save our results - use the times on this side of the network latency
    118             // (response rather than request time)
    119             mNtpTime = responseTime + clockOffset;
    120             mNtpTimeReference = responseTicks;
    121             mRoundTripTime = roundTripTime;
    122         } catch (Exception e) {
    123             if (false) Log.d(TAG, "request time failed: " + e);
    124             return false;
    125         } finally {
    126             if (socket != null) {
    127                 socket.close();
    128             }
    129         }
    130 
    131         return true;
    132     }
    133 
    134     /**
    135      * Returns the time computed from the NTP transaction.
    136      *
    137      * @return time value computed from NTP server response.
    138      */
    139     public long getNtpTime() {
    140         return mNtpTime;
    141     }
    142 
    143     /**
    144      * Returns the reference clock value (value of SystemClock.elapsedRealtime())
    145      * corresponding to the NTP time.
    146      *
    147      * @return reference clock corresponding to the NTP time.
    148      */
    149     public long getNtpTimeReference() {
    150         return mNtpTimeReference;
    151     }
    152 
    153     /**
    154      * Returns the round trip time of the NTP transaction
    155      *
    156      * @return round trip time in milliseconds.
    157      */
    158     public long getRoundTripTime() {
    159         return mRoundTripTime;
    160     }
    161 
    162     /**
    163      * Reads an unsigned 32 bit big endian number from the given offset in the buffer.
    164      */
    165     private long read32(byte[] buffer, int offset) {
    166         byte b0 = buffer[offset];
    167         byte b1 = buffer[offset+1];
    168         byte b2 = buffer[offset+2];
    169         byte b3 = buffer[offset+3];
    170 
    171         // convert signed bytes to unsigned values
    172         int i0 = ((b0 & 0x80) == 0x80 ? (b0 & 0x7F) + 0x80 : b0);
    173         int i1 = ((b1 & 0x80) == 0x80 ? (b1 & 0x7F) + 0x80 : b1);
    174         int i2 = ((b2 & 0x80) == 0x80 ? (b2 & 0x7F) + 0x80 : b2);
    175         int i3 = ((b3 & 0x80) == 0x80 ? (b3 & 0x7F) + 0x80 : b3);
    176 
    177         return ((long)i0 << 24) + ((long)i1 << 16) + ((long)i2 << 8) + (long)i3;
    178     }
    179 
    180     /**
    181      * Reads the NTP time stamp at the given offset in the buffer and returns
    182      * it as a system time (milliseconds since January 1, 1970).
    183      */
    184     private long readTimeStamp(byte[] buffer, int offset) {
    185         long seconds = read32(buffer, offset);
    186         long fraction = read32(buffer, offset + 4);
    187         return ((seconds - OFFSET_1900_TO_1970) * 1000) + ((fraction * 1000L) / 0x100000000L);
    188     }
    189 
    190     /**
    191      * Writes system time (milliseconds since January 1, 1970) as an NTP time stamp
    192      * at the given offset in the buffer.
    193      */
    194     private void writeTimeStamp(byte[] buffer, int offset, long time) {
    195         long seconds = time / 1000L;
    196         long milliseconds = time - seconds * 1000L;
    197         seconds += OFFSET_1900_TO_1970;
    198 
    199         // write seconds in big endian format
    200         buffer[offset++] = (byte)(seconds >> 24);
    201         buffer[offset++] = (byte)(seconds >> 16);
    202         buffer[offset++] = (byte)(seconds >> 8);
    203         buffer[offset++] = (byte)(seconds >> 0);
    204 
    205         long fraction = milliseconds * 0x100000000L / 1000L;
    206         // write fraction in big endian format
    207         buffer[offset++] = (byte)(fraction >> 24);
    208         buffer[offset++] = (byte)(fraction >> 16);
    209         buffer[offset++] = (byte)(fraction >> 8);
    210         // low order bits should be random data
    211         buffer[offset++] = (byte)(Math.random() * 255.0);
    212     }
    213 }
    214