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package org.spongycastle.asn1;

import java.io.IOException;
import java.text.ParseException;
import java.text.SimpleDateFormat;
import java.util.Date;
import java.util.SimpleTimeZone;

import org.spongycastle.util.Arrays;
import org.spongycastle.util.Strings;

/**
 * UTC time object.
 */
public class DERUTCTime
    extends ASN1Primitive
{
    private byte[]      time;

    /**
     * return an UTC Time from the passed in object.
     *
     * @exception IllegalArgumentException if the object cannot be converted.
     */
    public static ASN1UTCTime getInstance(
        Object  obj)
    {
        if (obj == null || obj instanceof ASN1UTCTime)
        {
            return (ASN1UTCTime)obj;
        }

        if (obj instanceof DERUTCTime)
        {
            return new ASN1UTCTime(((DERUTCTime)obj).time);
        }

        throw new IllegalArgumentException("illegal object in getInstance: " + obj.getClass().getName());
    }

    /**
     * return an UTC Time from a tagged object.
     *
     * @param obj the tagged object holding the object we want
     * @param explicit true if the object is meant to be explicitly
     *              tagged false otherwise.
     * @exception IllegalArgumentException if the tagged object cannot
     *               be converted.
     */
    public static ASN1UTCTime getInstance(
        ASN1TaggedObject obj,
        boolean          explicit)
    {
        ASN1Object o = obj.getObject();

        if (explicit || o instanceof ASN1UTCTime)
        {
            return getInstance(o);
        }
        else
        {
            return new ASN1UTCTime(((ASN1OctetString)o).getOctets());
        }
    }
    
    /**
     * The correct format for this is YYMMDDHHMMSSZ (it used to be that seconds were
     * never encoded. When you're creating one of these objects from scratch, that's
     * what you want to use, otherwise we'll try to deal with whatever gets read from
     * the input stream... (this is why the input format is different from the getTime()
     * method output).
     * 

* * @param time the time string. */ public DERUTCTime( String time) { this.time = Strings.toByteArray(time); try { this.getDate(); } catch (ParseException e) { throw new IllegalArgumentException("invalid date string: " + e.getMessage()); } } /** * base constructer from a java.util.date object */ public DERUTCTime( Date time) { SimpleDateFormat dateF = new SimpleDateFormat("yyMMddHHmmss'Z'"); dateF.setTimeZone(new SimpleTimeZone(0,"Z")); this.time = Strings.toByteArray(dateF.format(time)); } DERUTCTime( byte[] time) { this.time = time; } /** * return the time as a date based on whatever a 2 digit year will return. For * standardised processing use getAdjustedDate(). * * @return the resulting date * @exception ParseException if the date string cannot be parsed. */ public Date getDate() throws ParseException { SimpleDateFormat dateF = new SimpleDateFormat("yyMMddHHmmssz"); return dateF.parse(getTime()); } /** * return the time as an adjusted date * in the range of 1950 - 2049. * * @return a date in the range of 1950 to 2049. * @exception ParseException if the date string cannot be parsed. */ public Date getAdjustedDate() throws ParseException { SimpleDateFormat dateF = new SimpleDateFormat("yyyyMMddHHmmssz"); dateF.setTimeZone(new SimpleTimeZone(0, "Z")); return dateF.parse(getAdjustedTime()); } /** * return the time - always in the form of * YYMMDDhhmmssGMT(+hh:mm|-hh:mm). *

* Normally in a certificate we would expect "Z" rather than "GMT", * however adding the "GMT" means we can just use: *

     *     dateF = new SimpleDateFormat("yyMMddHHmmssz");
     * 
* To read in the time and get a date which is compatible with our local * time zone. *

* Note: In some cases, due to the local date processing, this * may lead to unexpected results. If you want to stick the normal * convention of 1950 to 2049 use the getAdjustedTime() method. */ public String getTime() { String stime = Strings.fromByteArray(time); // // standardise the format. // if (stime.indexOf('-') < 0 && stime.indexOf('+') < 0) { if (stime.length() == 11) { return stime.substring(0, 10) + "00GMT+00:00"; } else { return stime.substring(0, 12) + "GMT+00:00"; } } else { int index = stime.indexOf('-'); if (index < 0) { index = stime.indexOf('+'); } String d = stime; if (index == stime.length() - 3) { d += "00"; } if (index == 10) { return d.substring(0, 10) + "00GMT" + d.substring(10, 13) + ":" + d.substring(13, 15); } else { return d.substring(0, 12) + "GMT" + d.substring(12, 15) + ":" + d.substring(15, 17); } } } /** * return a time string as an adjusted date with a 4 digit year. This goes * in the range of 1950 - 2049. */ public String getAdjustedTime() { String d = this.getTime(); if (d.charAt(0) < '5') { return "20" + d; } else { return "19" + d; } } boolean isConstructed() { return false; } int encodedLength() { int length = time.length; return 1 + StreamUtil.calculateBodyLength(length) + length; } void encode( ASN1OutputStream out) throws IOException { out.write(BERTags.UTC_TIME); int length = time.length; out.writeLength(length); for (int i = 0; i != length; i++) { out.write((byte)time[i]); } } boolean asn1Equals( ASN1Primitive o) { if (!(o instanceof DERUTCTime)) { return false; } return Arrays.areEqual(time, ((DERUTCTime)o).time); } public int hashCode() { return Arrays.hashCode(time); } public String toString() { return Strings.fromByteArray(time); } }





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