using System; using System.Globalization; using System.Text; using Org.BouncyCastle.Utilities; namespace Org.BouncyCastle.Asn1 { /** * UTC time object. */ public class DerUtcTime : Asn1Object { private readonly string time; /** * return an UTC Time from the passed in object. * * @exception ArgumentException if the object cannot be converted. */ public static DerUtcTime GetInstance( object obj) { if (obj == null || obj is DerUtcTime) { return (DerUtcTime)obj; } throw new ArgumentException("illegal object in GetInstance: " + Platform.GetTypeName(obj)); } /** * return an UTC Time from a tagged object. * * @param obj the tagged object holding the object we want * @param explicitly true if the object is meant to be explicitly * tagged false otherwise. * @exception ArgumentException if the tagged object cannot * be converted. */ public static DerUtcTime GetInstance( Asn1TaggedObject obj, bool isExplicit) { Asn1Object o = obj.GetObject(); if (isExplicit || o is DerUtcTime) { return GetInstance(o); } return new DerUtcTime(((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) { if (time == null) throw new ArgumentNullException("time"); this.time = time; try { ToDateTime(); } catch (FormatException e) { throw new ArgumentException("invalid date string: " + e.Message); } } /** * base constructor from a DateTime object */ public DerUtcTime( DateTime time) { #if PORTABLE this.time = time.ToUniversalTime().ToString("yyMMddHHmmss", CultureInfo.InvariantCulture) + "Z"; #else this.time = time.ToString("yyMMddHHmmss", CultureInfo.InvariantCulture) + "Z"; #endif } internal DerUtcTime( byte[] bytes) { // // explicitly convert to characters // this.time = Strings.FromAsciiByteArray(bytes); } // public DateTime ToDateTime() // { // string tm = this.AdjustedTimeString; // // return new DateTime( // Int16.Parse(tm.Substring(0, 4)), // Int16.Parse(tm.Substring(4, 2)), // Int16.Parse(tm.Substring(6, 2)), // Int16.Parse(tm.Substring(8, 2)), // Int16.Parse(tm.Substring(10, 2)), // Int16.Parse(tm.Substring(12, 2))); // } /** * return the time as a date based on whatever a 2 digit year will return. For * standardised processing use ToAdjustedDateTime(). * * @return the resulting date * @exception ParseException if the date string cannot be parsed. */ public DateTime ToDateTime() { return ParseDateString(TimeString, @"yyMMddHHmmss'GMT'zzz"); } /** * 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 DateTime ToAdjustedDateTime() { return ParseDateString(AdjustedTimeString, @"yyyyMMddHHmmss'GMT'zzz"); } private DateTime ParseDateString( string dateStr, string formatStr) { DateTime dt = DateTime.ParseExact( dateStr, formatStr, DateTimeFormatInfo.InvariantInfo); return dt.ToUniversalTime(); } /** * 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 TimeString { get { // // standardise the format. // if (time.IndexOf('-') < 0 && time.IndexOf('+') < 0) { if (time.Length == 11) { return time.Substring(0, 10) + "00GMT+00:00"; } else { return time.Substring(0, 12) + "GMT+00:00"; } } else { int index = time.IndexOf('-'); if (index < 0) { index = time.IndexOf('+'); } string d = time; if (index == time.Length - 3) { d += "00"; } if (index == 10) { return d.Substring(0, 10) + "00GMT" + d.Substring(10, 3) + ":" + d.Substring(13, 2); } else { return d.Substring(0, 12) + "GMT" + d.Substring(12, 3) + ":" + d.Substring(15, 2); } } } } [Obsolete("Use 'AdjustedTimeString' property instead")] public string AdjustedTime { get { return AdjustedTimeString; } } /// /// Return a time string as an adjusted date with a 4 digit year. /// This goes in the range of 1950 - 2049. /// public string AdjustedTimeString { get { string d = TimeString; string c = d[0] < '5' ? "20" : "19"; return c + d; } } private byte[] GetOctets() { return Strings.ToAsciiByteArray(time); } internal override bool EncodeConstructed(int encoding) { return false; } internal override int EncodedLength(int encoding, bool withID) { return Asn1OutputStream.GetLengthOfEncodingDL(withID, time.Length); } internal override void Encode(Asn1OutputStream asn1Out, bool withID) { asn1Out.WriteEncodingDL(withID, Asn1Tags.UtcTime, GetOctets()); } protected override bool Asn1Equals( Asn1Object asn1Object) { DerUtcTime other = asn1Object as DerUtcTime; if (other == null) return false; return this.time.Equals(other.time); } protected override int Asn1GetHashCode() { return time.GetHashCode(); } public override string ToString() { return time; } } }