bcprov/src/main/java/org/bouncycastle/asn1/ASN1Sequence.java - platform/external/bouncycastle - Git at Google

 package org.bouncycastle.asn1;

 import java.io.IOException;
 import java.util.Enumeration;
 import java.util.Iterator;
 import java.util.Vector;

 import org.bouncycastle.util.Arrays;

 /**
  * ASN.1 <code>SEQUENCE</code> and <code>SEQUENCE OF</code> constructs.
  * <p>
  * DER form is always definite form length fields, while
  * BER support uses indefinite form.
  * <hr>
  * <p><b>X.690</b></p>
  * <p><b>8: Basic encoding rules</b></p>
  * <p><b>8.9 Encoding of a sequence value </b></p>
  * 8.9.1 The encoding of a sequence value shall be constructed.
  * <p>
  * <b>8.9.2</b> The contents octets shall consist of the complete
  * encoding of one data value from each of the types listed in
  * the ASN.1 definition of the sequence type, in the order of
  * their appearance in the definition, unless the type was referenced
  * with the keyword <b>OPTIONAL</b> or the keyword <b>DEFAULT</b>.
  * </p><p>
  * <b>8.9.3</b> The encoding of a data value may, but need not,
  * be present for a type which was referenced with the keyword
  * <b>OPTIONAL</b> or the keyword <b>DEFAULT</b>.
  * If present, it shall appear in the encoding at the point
  * corresponding to the appearance of the type in the ASN.1 definition.
  * </p><p>
  * <b>8.10 Encoding of a sequence-of value </b>
  * </p><p>
  * <b>8.10.1</b> The encoding of a sequence-of value shall be constructed.
  * <p>
  * <b>8.10.2</b> The contents octets shall consist of zero,
  * one or more complete encodings of data values from the type listed in
  * the ASN.1 definition.
  * <p>
  * <b>8.10.3</b> The order of the encodings of the data values shall be
  * the same as the order of the data values in the sequence-of value to
  * be encoded.
  * </p>
  * <p><b>9: Canonical encoding rules</b></p>
  * <p><b>9.1 Length forms</b></p>
  * If the encoding is constructed, it shall employ the indefinite-length form.
  * If the encoding is primitive, it shall include the fewest length octets necessary.
  * [Contrast with 8.1.3.2 b).]
  *
  * <p><b>11: Restrictions on BER employed by both CER and DER</b></p>
  * <p><b>11.5 Set and sequence components with default value</b></p>
  * The encoding of a set value or sequence value shall not include
  * an encoding for any component value which is equal to
  * its default value.
  */
 public abstract class ASN1Sequence
     extends ASN1Primitive
     implements org.bouncycastle.util.Iterable<ASN1Encodable>
 {
     protected Vector seq = new Vector();

     /**
      * Return an ASN1Sequence from the given object.
      *
      * @param obj the object we want converted.
      * @exception IllegalArgumentException if the object cannot be converted.
      * @return an ASN1Sequence instance, or null.
      */
     public static ASN1Sequence getInstance(
         Object  obj)
     {
         if (obj == null || obj instanceof ASN1Sequence)
         {
             return (ASN1Sequence)obj;
         }
         else if (obj instanceof ASN1SequenceParser)
         {
             return ASN1Sequence.getInstance(((ASN1SequenceParser)obj).toASN1Primitive());
         }
         else if (obj instanceof byte[])
         {
             try
             {
                 return ASN1Sequence.getInstance(fromByteArray((byte[])obj));
             }
             catch (IOException e)
             {
                 throw new IllegalArgumentException("failed to construct sequence from byte[]: " + e.getMessage());
             }
         }
         else if (obj instanceof ASN1Encodable)
         {
             ASN1Primitive primitive = ((ASN1Encodable)obj).toASN1Primitive();

             if (primitive instanceof ASN1Sequence)
             {
                 return (ASN1Sequence)primitive;
             }
         }

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

     /**
      * Return an ASN1 sequence from a tagged object. There is a special
      * case here, if an object appears to have been explicitly tagged on
      * reading but we were expecting it to be implicitly tagged in the
      * normal course of events it indicates that we lost the surrounding
      * sequence - so we need to add it back (this will happen if the tagged
      * object is a sequence that contains other sequences). If you are
      * dealing with implicitly tagged sequences you really <b>should</b>
      * be using this method.
      *
      * @param obj the tagged object.
      * @param explicit true if the object is meant to be explicitly tagged,
      *          false otherwise.
      * @exception IllegalArgumentException if the tagged object cannot
      *          be converted.
      * @return an ASN1Sequence instance.
      */
     public static ASN1Sequence getInstance(
         ASN1TaggedObject    obj,
         boolean             explicit)
     {
         if (explicit)
         {
             if (!obj.isExplicit())
             {
                 throw new IllegalArgumentException("object implicit - explicit expected.");
             }

             return ASN1Sequence.getInstance(obj.getObject().toASN1Primitive());
         }
         else
         {
             //
             // constructed object which appears to be explicitly tagged
             // when it should be implicit means we have to add the
             // surrounding sequence.
             //
             if (obj.isExplicit())
             {
                 if (obj instanceof BERTaggedObject)
                 {
                     return new BERSequence(obj.getObject());
                 }
                 else
                 {
                     return new DLSequence(obj.getObject());
                 }
             }
             else
             {
                 if (obj.getObject() instanceof ASN1Sequence)
                 {
                     return (ASN1Sequence)obj.getObject();
                 }
             }
         }

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

     /**
      * Create an empty sequence
      */
     protected ASN1Sequence()
     {
     }

     /**
      * Create a sequence containing one object
      * @param obj the object to be put in the SEQUENCE.
      */
     protected ASN1Sequence(
         ASN1Encodable obj)
     {
         seq.addElement(obj);
     }

     /**
      * Create a sequence containing a vector of objects.
      * @param v the vector of objects to be put in the SEQUENCE
      */
     protected ASN1Sequence(
         ASN1EncodableVector v)
     {
         for (int i = 0; i != v.size(); i++)
         {
             seq.addElement(v.get(i));
         }
     }

     /*
      * Create a sequence containing a vector of objects.
      */
     protected ASN1Sequence(
         ASN1Encodable[]   array)
     {
         for (int i = 0; i != array.length; i++)
         {
             seq.addElement(array[i]);
         }
     }

     public ASN1Encodable[] toArray()
     {
         ASN1Encodable[] values = new ASN1Encodable[this.size()];

         for (int i = 0; i != this.size(); i++)
         {
             values[i] = this.getObjectAt(i);
         }

         return values;
     }

     public Enumeration getObjects()
     {
         return seq.elements();
     }

     public ASN1SequenceParser parser()
     {
         final ASN1Sequence outer = this;

         return new ASN1SequenceParser()
         {
             private final int max = size();

             private int index;

             public ASN1Encodable readObject() throws IOException
             {
                 if (index == max)
                 {
                     return null;
                 }

                 ASN1Encodable obj = getObjectAt(index++);
                 if (obj instanceof ASN1Sequence)
                 {
                     return ((ASN1Sequence)obj).parser();
                 }
                 if (obj instanceof ASN1Set)
                 {
                     return ((ASN1Set)obj).parser();
                 }

                 return obj;
             }

             public ASN1Primitive getLoadedObject()
             {
                 return outer;
             }

             public ASN1Primitive toASN1Primitive()
             {
                 return outer;
             }
         };
     }

     /**
      * Return the object at the sequence position indicated by index.
      *
      * @param index the sequence number (starting at zero) of the object
      * @return the object at the sequence position indicated by index.
      */
     public ASN1Encodable getObjectAt(
         int index)
     {
         return (ASN1Encodable)seq.elementAt(index);
     }

     /**
      * Return the number of objects in this sequence.
      *
      * @return the number of objects in this sequence.
      */
     public int size()
     {
         return seq.size();
     }

     public int hashCode()
     {
         Enumeration             e = this.getObjects();
         int                     hashCode = size();

         while (e.hasMoreElements())
         {
             Object o = getNext(e);
             hashCode *= 17;

             hashCode ^= o.hashCode();
         }

         return hashCode;
     }

     boolean asn1Equals(
         ASN1Primitive o)
     {
         if (!(o instanceof ASN1Sequence))
         {
             return false;
         }

         ASN1Sequence   other = (ASN1Sequence)o;

         if (this.size() != other.size())
         {
             return false;
         }

         Enumeration s1 = this.getObjects();
         Enumeration s2 = other.getObjects();

         while (s1.hasMoreElements())
         {
             ASN1Encodable obj1 = getNext(s1);
             ASN1Encodable obj2 = getNext(s2);

             ASN1Primitive o1 = obj1.toASN1Primitive();
             ASN1Primitive o2 = obj2.toASN1Primitive();

             if (o1 == o2 || o1.equals(o2))
             {
                 continue;
             }

             return false;
         }

         return true;
     }

     private ASN1Encodable getNext(Enumeration e)
     {
         ASN1Encodable encObj = (ASN1Encodable)e.nextElement();

         return encObj;
     }

     /**
      * Change current SEQUENCE object to be encoded as {@link DERSequence}.
      * This is part of Distinguished Encoding Rules form serialization.
      */
     ASN1Primitive toDERObject()
     {
         ASN1Sequence derSeq = new DERSequence();

         derSeq.seq = this.seq;

         return derSeq;
     }

     /**
      * Change current SEQUENCE object to be encoded as {@link DLSequence}.
      * This is part of Direct Length form serialization.
      */
     ASN1Primitive toDLObject()
     {
         ASN1Sequence dlSeq = new DLSequence();

         dlSeq.seq = this.seq;

         return dlSeq;
     }

     boolean isConstructed()
     {
         return true;
     }

     abstract void encode(ASN1OutputStream out)
         throws IOException;

     public String toString()
     {
         return seq.toString();
     }

     public Iterator<ASN1Encodable> iterator()
     {
         return new Arrays.Iterator<ASN1Encodable>(toArray());
     }
 }
	package org.bouncycastle.asn1;

	import java.io.IOException;
	import java.util.Enumeration;
	import java.util.Iterator;
	import java.util.Vector;

	import org.bouncycastle.util.Arrays;

	/**
	* ASN.1 <code>SEQUENCE</code> and <code>SEQUENCE OF</code> constructs.
	* <p>
	* DER form is always definite form length fields, while
	* BER support uses indefinite form.
	* <hr>
	* <p><b>X.690</b></p>
	* <p><b>8: Basic encoding rules</b></p>
	* <p><b>8.9 Encoding of a sequence value </b></p>
	* 8.9.1 The encoding of a sequence value shall be constructed.
	* <p>
	* <b>8.9.2</b> The contents octets shall consist of the complete
	* encoding of one data value from each of the types listed in
	* the ASN.1 definition of the sequence type, in the order of
	* their appearance in the definition, unless the type was referenced
	* with the keyword <b>OPTIONAL</b> or the keyword <b>DEFAULT</b>.
	* </p><p>
	* <b>8.9.3</b> The encoding of a data value may, but need not,
	* be present for a type which was referenced with the keyword
	* <b>OPTIONAL</b> or the keyword <b>DEFAULT</b>.
	* If present, it shall appear in the encoding at the point
	* corresponding to the appearance of the type in the ASN.1 definition.
	* </p><p>
	* <b>8.10 Encoding of a sequence-of value </b>
	* </p><p>
	* <b>8.10.1</b> The encoding of a sequence-of value shall be constructed.
	* <p>
	* <b>8.10.2</b> The contents octets shall consist of zero,
	* one or more complete encodings of data values from the type listed in
	* the ASN.1 definition.
	* <p>
	* <b>8.10.3</b> The order of the encodings of the data values shall be
	* the same as the order of the data values in the sequence-of value to
	* be encoded.
	* </p>
	* <p><b>9: Canonical encoding rules</b></p>
	* <p><b>9.1 Length forms</b></p>
	* If the encoding is constructed, it shall employ the indefinite-length form.
	* If the encoding is primitive, it shall include the fewest length octets necessary.
	* [Contrast with 8.1.3.2 b).]
	*
	* <p><b>11: Restrictions on BER employed by both CER and DER</b></p>
	* <p><b>11.5 Set and sequence components with default value</b></p>
	* The encoding of a set value or sequence value shall not include
	* an encoding for any component value which is equal to
	* its default value.
	*/
	public abstract class ASN1Sequence
	extends ASN1Primitive
	implements org.bouncycastle.util.Iterable<ASN1Encodable>
	{
	protected Vector seq = new Vector();

	/**
	* Return an ASN1Sequence from the given object.
	*
	* @param obj the object we want converted.
	* @exception IllegalArgumentException if the object cannot be converted.
	* @return an ASN1Sequence instance, or null.
	*/
	public static ASN1Sequence getInstance(
	Object obj)
	{
	if (obj == null \|\| obj instanceof ASN1Sequence)
	{
	return (ASN1Sequence)obj;
	}
	else if (obj instanceof ASN1SequenceParser)
	{
	return ASN1Sequence.getInstance(((ASN1SequenceParser)obj).toASN1Primitive());
	}
	else if (obj instanceof byte[])
	{
	try
	{
	return ASN1Sequence.getInstance(fromByteArray((byte[])obj));
	}
	catch (IOException e)
	{
	throw new IllegalArgumentException("failed to construct sequence from byte[]: " + e.getMessage());
	}
	}
	else if (obj instanceof ASN1Encodable)
	{
	ASN1Primitive primitive = ((ASN1Encodable)obj).toASN1Primitive();

	if (primitive instanceof ASN1Sequence)
	{
	return (ASN1Sequence)primitive;
	}
	}

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

	/**
	* Return an ASN1 sequence from a tagged object. There is a special
	* case here, if an object appears to have been explicitly tagged on
	* reading but we were expecting it to be implicitly tagged in the
	* normal course of events it indicates that we lost the surrounding
	* sequence - so we need to add it back (this will happen if the tagged
	* object is a sequence that contains other sequences). If you are
	* dealing with implicitly tagged sequences you really <b>should</b>
	* be using this method.
	*
	* @param obj the tagged object.
	* @param explicit true if the object is meant to be explicitly tagged,
	* false otherwise.
	* @exception IllegalArgumentException if the tagged object cannot
	* be converted.
	* @return an ASN1Sequence instance.
	*/
	public static ASN1Sequence getInstance(
	ASN1TaggedObject obj,
	boolean explicit)
	{
	if (explicit)
	{
	if (!obj.isExplicit())
	{
	throw new IllegalArgumentException("object implicit - explicit expected.");
	}

	return ASN1Sequence.getInstance(obj.getObject().toASN1Primitive());
	}
	else
	{
	//
	// constructed object which appears to be explicitly tagged
	// when it should be implicit means we have to add the
	// surrounding sequence.
	//
	if (obj.isExplicit())
	{
	if (obj instanceof BERTaggedObject)
	{
	return new BERSequence(obj.getObject());
	}
	else
	{
	return new DLSequence(obj.getObject());
	}
	}
	else
	{
	if (obj.getObject() instanceof ASN1Sequence)
	{
	return (ASN1Sequence)obj.getObject();
	}
	}
	}

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

	/**
	* Create an empty sequence
	*/
	protected ASN1Sequence()
	{
	}

	/**
	* Create a sequence containing one object
	* @param obj the object to be put in the SEQUENCE.
	*/
	protected ASN1Sequence(
	ASN1Encodable obj)
	{
	seq.addElement(obj);
	}

	/**
	* Create a sequence containing a vector of objects.
	* @param v the vector of objects to be put in the SEQUENCE
	*/
	protected ASN1Sequence(
	ASN1EncodableVector v)
	{
	for (int i = 0; i != v.size(); i++)
	{
	seq.addElement(v.get(i));
	}
	}

	/*
	* Create a sequence containing a vector of objects.
	*/
	protected ASN1Sequence(
	ASN1Encodable[] array)
	{
	for (int i = 0; i != array.length; i++)
	{
	seq.addElement(array[i]);
	}
	}

	public ASN1Encodable[] toArray()
	{
	ASN1Encodable[] values = new ASN1Encodable[this.size()];

	for (int i = 0; i != this.size(); i++)
	{
	values[i] = this.getObjectAt(i);
	}

	return values;
	}

	public Enumeration getObjects()
	{
	return seq.elements();
	}

	public ASN1SequenceParser parser()
	{
	final ASN1Sequence outer = this;

	return new ASN1SequenceParser()
	{
	private final int max = size();

	private int index;

	public ASN1Encodable readObject() throws IOException
	{
	if (index == max)
	{
	return null;
	}

	ASN1Encodable obj = getObjectAt(index++);
	if (obj instanceof ASN1Sequence)
	{
	return ((ASN1Sequence)obj).parser();
	}
	if (obj instanceof ASN1Set)
	{
	return ((ASN1Set)obj).parser();
	}

	return obj;
	}

	public ASN1Primitive getLoadedObject()
	{
	return outer;
	}

	public ASN1Primitive toASN1Primitive()
	{
	return outer;
	}
	};
	}

	/**
	* Return the object at the sequence position indicated by index.
	*
	* @param index the sequence number (starting at zero) of the object
	* @return the object at the sequence position indicated by index.
	*/
	public ASN1Encodable getObjectAt(
	int index)
	{
	return (ASN1Encodable)seq.elementAt(index);
	}

	/**
	* Return the number of objects in this sequence.
	*
	* @return the number of objects in this sequence.
	*/
	public int size()
	{
	return seq.size();
	}

	public int hashCode()
	{
	Enumeration e = this.getObjects();
	int hashCode = size();

	while (e.hasMoreElements())
	{
	Object o = getNext(e);
	hashCode *= 17;

	hashCode ^= o.hashCode();
	}

	return hashCode;
	}

	boolean asn1Equals(
	ASN1Primitive o)
	{
	if (!(o instanceof ASN1Sequence))
	{
	return false;
	}

	ASN1Sequence other = (ASN1Sequence)o;

	if (this.size() != other.size())
	{
	return false;
	}

	Enumeration s1 = this.getObjects();
	Enumeration s2 = other.getObjects();

	while (s1.hasMoreElements())
	{
	ASN1Encodable obj1 = getNext(s1);
	ASN1Encodable obj2 = getNext(s2);

	ASN1Primitive o1 = obj1.toASN1Primitive();
	ASN1Primitive o2 = obj2.toASN1Primitive();

	if (o1 == o2 \|\| o1.equals(o2))
	{
	continue;
	}

	return false;
	}

	return true;
	}

	private ASN1Encodable getNext(Enumeration e)
	{
	ASN1Encodable encObj = (ASN1Encodable)e.nextElement();

	return encObj;
	}

	/**
	* Change current SEQUENCE object to be encoded as {@link DERSequence}.
	* This is part of Distinguished Encoding Rules form serialization.
	*/
	ASN1Primitive toDERObject()
	{
	ASN1Sequence derSeq = new DERSequence();

	derSeq.seq = this.seq;

	return derSeq;
	}

	/**
	* Change current SEQUENCE object to be encoded as {@link DLSequence}.
	* This is part of Direct Length form serialization.
	*/
	ASN1Primitive toDLObject()
	{
	ASN1Sequence dlSeq = new DLSequence();

	dlSeq.seq = this.seq;

	return dlSeq;
	}

	boolean isConstructed()
	{
	return true;
	}

	abstract void encode(ASN1OutputStream out)
	throws IOException;

	public String toString()
	{
	return seq.toString();
	}

	public Iterator<ASN1Encodable> iterator()
	{
	return new Arrays.Iterator<ASN1Encodable>(toArray());
	}
	}