import java.io.IOException;
public class SetTime {
public static void main(String args[]){
String osName = System.getProperty("os.name");
String cmd = "";
try {
if (osName.matches("^(?i)Windows.*$")) {// Window 系统
// 格式 HH:mm:ss
cmd = " cmd /c time 22:35:00";
Runtime.getRuntime().exec(cmd);
// 格式:yyyy-MM-dd
cmd = " cmd /c date 2009-03-26";
Runtime.getRuntime().exec(cmd);
} else {// Linux 系统
// 格式:yyyyMMdd
cmd = " date -s 20090326";
Runtime.getRuntime().exec(cmd);
// 格式 HH:mm:ss
cmd = " date -s 22:35:00";
Runtime.getRuntime().exec(cmd);
}
} catch (IOException e) {
e.printStackTrace();
}
}
}
---------------获取互联网时间-------------------
public static void main(String[] args) throws Exception {
// TODO Auto-generated method stub
URL url=new URL("http://www.bjtime.cn");//取得资源对象
URLConnection uc=url.openConnection();//生成连接对象
uc.connect(); //发出连接
long ld=uc.getDate(); //取得网站日期时间
Date date=new Date(ld); //转换为标准时间对象
System.out.println(date);
}
------通过ntp 获取系统准确时间---------
本程序是java通过网络访问NTP时间服务器,而获得精准的时间。不是获得本地时间import java.io.IOException;
import java.io.InterruptedIOException;
import java.net.ConnectException;
import java.net.DatagramPacket;
import java.net.DatagramSocket;
import java.net.InetAddress;
import java.net.NoRouteToHostException;
import java.net.UnknownHostException;
public class TestNtp{
public static void main(String[] args){
int retry = 2;
int port = 123;
int timeout = 3000;
// get the address and NTP address request
//
InetAddress ipv4Addr = null;
try {
ipv4Addr = InetAddress.getByName("203.117.180.36");//更多NTP时间服务器参考附注
} catch (UnknownHostException e1) {
e1.printStackTrace();
}
int serviceStatus = -1;
DatagramSocket socket = null;
long responseTime = -1;
try {
socket = new DatagramSocket();
socket.setSoTimeout(timeout); // will force the
// InterruptedIOException
for (int attempts = 0; attempts import java.text.DecimalFormat;
import java.text.SimpleDateFormat;
import java.util.Date;
public class NtpMessage {
/** *//**
* This is a two-bit code warning of an impending leap second to be
* inserted/deleted in the last minute of the current day. It''s values may
* be as follows:
*
* Value Meaning ----- ------- 0 no warning 1 last minute has 61 seconds 2
* last minute has 59 seconds) 3 alarm condition (clock not synchronized)
*/
public byte leapIndicator = 0;
/** *//**
* This value indicates the NTP/SNTP version number. The version number is 3
* for Version 3 (IPv4 only) and 4 for Version 4 (IPv4, IPv6 and OSI). If
* necessary to distinguish between IPv4, IPv6 and OSI, the encapsulating
* context must be inspected.
*/
public byte version = 3;
/** *//**
* This value indicates the mode, with values defined as follows:
*
* Mode Meaning ---- ------- 0 reserved 1 symmetric active 2 symmetric
* passive 3 client 4 server 5 broadcast 6 reserved for NTP control message
* 7 reserved for private use
*
* In unicast and anycast modes, the client sets this field to 3 (client) in
* the request and the server sets it to 4 (server) in the reply. In
* multicast mode, the server sets this field to 5 (broadcast).
*/
public byte mode = 0;
/** *//**
* This value indicates the stratum level of the local clock, with values
* defined as follows:
*
* Stratum Meaning ---------------------------------------------- 0
* unspecified or unavailable 1 primary reference (e.g., radio clock) 2-15
* secondary reference (via NTP or SNTP) 16-255 reserved
*/
public short stratum = 0;
/** *//**
* This value indicates the maximum interval between successive messages, in
* seconds to the nearest power of two. The values that can appear in this
* field presently range from 4 (16 s) to 14 (16284 s); however, most
* applications use only the sub-range 6 (64 s) to 10 (1024 s).
*/
public byte pollInterval = 0;
/** *//**
* This value indicates the precision of the local clock, in seconds to the
* nearest power of two. The values that normally appear in this field
* range from -6 for mains-frequency clocks to -20 for microsecond clocks
* found in some workstations.
*/
public byte precision = 0;
/** *//**
* This value indicates the total roundtrip delay to the primary reference
* source, in seconds. Note that this variable can take on both positive and
* negative values, depending on the relative time and frequency offsets.
* The values that normally appear in this field range from negative values
* of a few milliseconds to positive values of several hundred milliseconds.
*/
public double rootDelay = 0;
/** *//**
* This value indicates the nominal error relative to the primary reference
* source, in seconds. The values that normally appear in this field range
* from 0 to several hundred milliseconds.
*/
public double rootDispersion = 0;
/** *//**
* This is a 4-byte array identifying the particular reference source. In
* the case of NTP Version 3 or Version 4 stratum-0 (unspecified) or
* stratum-1 (primary) servers, this is a four-character ASCII string, left
* justified and zero padded to 32 bits. In NTP Version 3 secondary servers,
* this is the 32-bit IPv4 address of the reference source. In NTP Version 4
* secondary servers, this is the low order 32 bits of the latest transmit
* timestamp of the reference source. NTP primary (stratum 1) servers should
* set this field to a code identifying the external reference source
* according to the following list. If the external reference is one of
* those listed, the associated code should be used. Codes for sources not
* listed can be contrived as appropriate.
*
* Code External Reference Source ---- ------------------------- LOCL
* uncalibrated local clock used as a primary reference for a subnet without
* external means of synchronization PPS atomic clock or other
* pulse-per-second source individually calibrated to national standards
* ACTS NIST dialup modem service USNO USNO modem service PTB PTB (Germany)
* modem service TDF Allouis (France) Radio 164 kHz DCF Mainflingen
* (Germany) Radio 77.5 kHz MSF Rugby (UK) Radio 60 kHz WWV Ft. Collins (US)
* Radio 2.5, 5, 10, 15, 20 MHz WWVB Boulder (US) Radio 60 kHz WWVH Kaui
* Hawaii (US) Radio 2.5, 5, 10, 15 MHz CHU Ottawa (Canada) Radio 3330,
* 7335, 14670 kHz LORC LORAN-C radionavigation system OMEG OMEGA
* radionavigation system GPS Global Positioning Service GOES Geostationary
* Orbit Environment Satellite
*/
public byte[] referenceIdentifier = { 0, 0, 0, 0 };
/** *//**
* This is the time at which the local clock was last set or corrected, in
* seconds since 00:00 1-Jan-1900.
*/
public double referenceTimestamp = 0;
/** *//**
* This is the time at which the request departed the client for the server,
* in seconds since 00:00 1-Jan-1900.
*/
public double originateTimestamp = 0;
/** *//**
* This is the time at which the request arrived at the server, in seconds
* since 00:00 1-Jan-1900.
*/
public double receiveTimestamp = 0;
/** *//**
* This is the time at which the reply departed the server for the client,
* in seconds since 00:00 1-Jan-1900.
*/
public double transmitTimestamp = 0;
/** *//**
* Constructs a new NtpMessage from an array of bytes.
*/
public NtpMessage(byte[] array) {
// See the packet format diagram in RFC 2030 for details
leapIndicator = (byte) ((array[0] >> 6) & 0x3);
version = (byte) ((array[0] >> 3) & 0x7);
mode = (byte) (array[0] & 0x7);
stratum = unsignedByteToShort(array[1]);
pollInterval = array[2];
precision = array[3];
rootDelay = (array[4] * 256.0) + unsignedByteToShort(array[5]) + (unsignedByteToShort(array[6]) / 256.0) + (unsignedByteToShort(array[7]) / 65536.0);
rootDispersion = (unsignedByteToShort(array[8]) * 256.0) + unsignedByteToShort(array[9]) + (unsignedByteToShort(array[10]) / 256.0) + (unsignedByteToShort(array[11]) / 65536.0);
referenceIdentifier[0] = array[12];
referenceIdentifier[1] = array[13];
referenceIdentifier[2] = array[14];
referenceIdentifier[3] = array[15];
referenceTimestamp = decodeTimestamp(array, 16);
originateTimestamp = decodeTimestamp(array, 24);
receiveTimestamp = decodeTimestamp(array, 32);
transmitTimestamp = decodeTimestamp(array, 40);
}
/** *//**
* Constructs a new NtpMessage
*/
public NtpMessage(byte leapIndicator, byte version, byte mode, short stratum, byte pollInterval, byte precision, double rootDelay, double rootDispersion, byte[] referenceIdentifier, double referenceTimestamp, double originateTimestamp, double receiveTimestamp, double transmitTimestamp) {
// ToDo: Validity checking
this.leapIndicator = leapIndicator;
this.version = version;
this.mode = mode;
this.stratum = stratum;
this.pollInterval = pollInterval;
this.precision = precision;
this.rootDelay = rootDelay;
this.rootDispersion = rootDispersion;
this.referenceIdentifier = referenceIdentifier;
this.referenceTimestamp = referenceTimestamp;
this.originateTimestamp = originateTimestamp;
this.receiveTimestamp = receiveTimestamp;
this.transmitTimestamp = transmitTimestamp;
}
/** *//**
* Constructs a new NtpMessage in client -> server mode, and sets the
* transmit timestamp to the current time.
*/
public NtpMessage() {
// Note that all the other member variables are already set with
// appropriate default values.
this.mode = 3;
this.transmitTimestamp = (System.currentTimeMillis() / 1000.0) + 2208988800.0;
}
/** *//**
* This method constructs the data bytes of a raw NTP packet.
*/
public byte[] toByteArray() {
// All bytes are automatically set to 0
byte[] p = new byte[48];
p[0] = (byte) (leapIndicator > 24) & 0xFF);
p[5] = (byte) ((l >> 16) & 0xFF);
p[6] = (byte) ((l >> 8) & 0xFF);
p[7] = (byte) (l & 0xFF);
// root dispersion is an unsigned 16.16-bit FP, in Java there are no
// unsigned primitive types, so we use a long which is 64-bits
long ul = (long) (rootDispersion * 65536.0);
p[8] = (byte) ((ul >> 24) & 0xFF);
p[9] = (byte) ((ul >> 16) & 0xFF);
p[10] = (byte) ((ul >> 8) & 0xFF);
p[11] = (byte) (ul & 0xFF);
p[12] = referenceIdentifier[0];
p[13] = referenceIdentifier[1];
p[14] = referenceIdentifier[2];
p[15] = referenceIdentifier[3];
encodeTimestamp(p, 16, referenceTimestamp);
encodeTimestamp(p, 24, originateTimestamp);
encodeTimestamp(p, 32, receiveTimestamp);
encodeTimestamp(p, 40, transmitTimestamp);
return p;
}
/** *//**
* Returns a string representation of a NtpMessage
*/
public String toString() {
String precisionStr = new DecimalFormat("0.#E0").format(Math.pow(2, precision));
return "Leap indicator: " + leapIndicator + " " + "Version: " + version + " " + "Mode: " + mode + " " + "Stratum: " + stratum + " " + "Poll: " + pollInterval + " " + "Precision: " + precision + " (" + precisionStr + " seconds) " + "Root delay: " + new DecimalFormat("0.00").format(rootDelay * 1000) + " ms " + "Root dispersion: " + new DecimalFormat("0.00").format(rootDispersion * 1000) + " ms " + "Reference identifier: " + referenceIdentifierToString(referenceIdentifier, stratum, version) + " " + "Reference timestamp: " + timestampToString(referenceTimestamp) + " " + "Originate timestamp: " + timestampToString(originateTimestamp) + " " + "Receive timestamp: " + timestampToString(receiveTimestamp) + " " + "Transmit timestamp: " + timestampToString(transmitTimestamp);
}
/** *//**
* Converts an unsigned byte to a short. By default, Java assumes that a
* byte is signed.
*/
public static short unsignedByteToShort(byte b) {
if ((b & 0x80) == 0x80)
return (short) (128 + (b & 0x7f));
else
return (short) b;
}
/** *//**
* Will read 8 bytes of a message beginning at pointer and
* return it as a double, according to the NTP 64-bit timestamp format.
*/
public static double decodeTimestamp(byte[] array, int pointer) {
double r = 0.0;
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