/*
* Copyright 1996-2004 Sun Microsystems, Inc. All Rights Reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Sun designates this
* particular file as subject to the "Classpath" exception as provided
* by Sun in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*/
package com.zaranux.client.crypto.spec;
//import java.io.*;
//import java.util.Properties;
//import java.math.*;
//import com.openmashupos.crypto.client.KeyRep;
//import java.security.KeyFactory;
//import java.security.Security;
//import java.security.Provider;
//import sun.misc.HexDumpEncoder;
//import sun.security.x509.*;
//import sun.security.util.*;
import com.zaranux.client.crypto.AlgorithmId;
import com.zaranux.client.crypto.ByteArrayInputStream;
import com.zaranux.client.crypto.DerOutputStream;
import com.zaranux.client.crypto.DerValue;
import com.zaranux.client.crypto.IOException;
import com.zaranux.client.crypto.InputStream;
import com.zaranux.client.crypto.InvalidKeyException;
import com.zaranux.client.crypto.Key;
import com.zaranux.client.crypto.PrivateKey;
import com.zaranux.client.crypto.util.BigInteger;
/**
* Holds a PKCS#8 key, for example a private key
*
* @author Dave Brownell
* @author Benjamin Renaud
*/
public class PKCS8Key implements PrivateKey {
/** use serialVersionUID from JDK 1.1. for interoperability */
private static final long serialVersionUID = -3836890099307167124L;
/* The algorithm information (name, parameters, etc). */
protected AlgorithmId algid;
/* The key bytes, without the algorithm information */
protected byte[] key;
/* The encoded for the key. */
protected byte[] encodedKey;
/* The version for this key */
public static final BigInteger version = BigInteger.ZERO;
/**
* Default constructor. The key constructed must have its key
* and algorithm initialized before it may be used, for example
* by using <code>decode</code>.
*/
public PKCS8Key() { }
/*
* Build and initialize as a "default" key. All PKCS#8 key
* data is stored and transmitted losslessly, but no knowledge
* about this particular algorithm is available.
*/
private PKCS8Key (AlgorithmId algid, byte key [])
throws InvalidKeyException {
this.algid = algid;
this.key = key;
encode();
}
/*
* Binary backwards compatibility. New uses should call parseKey().
*/
/*
public static PKCS8Key parse (DerValue in) throws IOException {
PrivateKey key;
key = parseKey(in);
if (key instanceof PKCS8Key)
return (PKCS8Key)key;
throw new IOException("Provider did not return PKCS8Key");
}
*/
/**
* Construct PKCS#8 subject public key from a DER value. If
* the runtime environment is configured with a specific class for
* this kind of key, a subclass is returned. Otherwise, a generic
* PKCS8Key object is returned.
*
* <P>This mechanism gurantees that keys (and algorithms) may be
* freely manipulated and transferred, without risk of losing
* information. Also, when a key (or algorithm) needs some special
* handling, that specific need can be accomodated.
*
* @param in the DER-encoded SubjectPublicKeyInfo value
* @exception IOException on data format errors
*/
/*
public static PrivateKey parseKey (DerValue in) throws IOException
{
AlgorithmId algorithm;
PrivateKey privKey;
if (in.tag != DerValue.tag_Sequence)
throw new IOException ("corrupt private key");
BigInteger parsedVersion = in.data.getBigInteger();
if (!version.equals(parsedVersion)) {
throw new IOException("version mismatch: (supported: " // +
// Debug.toHexString(version) +
// ", parsed: " +
// Debug.toHexString(parsedVersion)
);
}
algorithm = AlgorithmId.parse (in.data.getDerValue ());
try {
privKey = buildPKCS8Key (algorithm, in.data.getOctetString ());
} catch (InvalidKeyException e) {
throw new IOException("corrupt private key");
}
if (in.data.available () != 0)
throw new IOException ("excess private key");
return privKey;
}
*/
/**
* Parse the key bits. This may be redefined by subclasses to take
* advantage of structure within the key. For example, RSA public
* keys encapsulate two unsigned integers (modulus and exponent) as
* DER values within the <code>key</code> bits; Diffie-Hellman and
* DSS/DSA keys encapsulate a single unsigned integer.
*
* <P>This function is called when creating PKCS#8 SubjectPublicKeyInfo
* values using the PKCS8Key member functions, such as <code>parse</code>
* and <code>decode</code>.
*
* @exception IOException if a parsing error occurs.
* @exception InvalidKeyException if the key encoding is invalid.
*/
protected void parseKeyBits () throws IOException, InvalidKeyException {
encode();
}
/*
* Factory interface, building the kind of key associated with this
* specific algorithm ID or else returning this generic base class.
* See the description above.
*/
/*
static PrivateKey buildPKCS8Key (AlgorithmId algid, byte[] key)
throws IOException, InvalidKeyException
{
// * Use the algid and key parameters to produce the ASN.1 encoding
// * of the key, which will then be used as the input to the
// * key factory.
//
DerOutputStream pkcs8EncodedKeyStream = new DerOutputStream();
encode(pkcs8EncodedKeyStream, algid, key);
PKCS8EncodedKeySpec pkcs8KeySpec
= new PKCS8EncodedKeySpec(pkcs8EncodedKeyStream.toByteArray());
try {
// Instantiate the key factory of the appropriate algorithm
KeyFactory keyFac = KeyFactory.getInstance(algid.getName());
// Generate the private key
return keyFac.generatePrivate(pkcs8KeySpec);
} catch (NoSuchAlgorithmException e) {
// Return generic PKCS8Key with opaque key data (see below)
} catch (InvalidKeySpecException e) {
// Return generic PKCS8Key with opaque key data (see below)
}
//
// * Try again using JDK1.1-style for backwards compatibility.
//
String classname = "";
try {
Properties props;
String keytype;
Provider sunProvider;
sunProvider = Security.getProvider("SUN");
if (sunProvider == null)
throw new InstantiationException();
classname = sunProvider.getProperty("PrivateKey.PKCS#8." +
algid.getName());
if (classname == null) {
throw new InstantiationException();
}
Class keyClass = null;
try {
keyClass = Class.forName(classname);
} catch (ClassNotFoundException e) {
ClassLoader cl = ClassLoader.getSystemClassLoader();
if (cl != null) {
keyClass = cl.loadClass(classname);
}
}
Object inst = null;
PKCS8Key result;
if (keyClass != null)
inst = keyClass.newInstance();
if (inst instanceof PKCS8Key) {
result = (PKCS8Key) inst;
result.algid = algid;
result.key = key;
result.parseKeyBits();
return result;
}
} catch (ClassNotFoundException e) {
} catch (InstantiationException e) {
} catch (IllegalAccessException e) {
// this should not happen.
throw new IOException (classname + " [internal error]");
}
PKCS8Key result = new PKCS8Key();
result.algid = algid;
result.key = key;
return result;
}
*/
/**
* Returns the algorithm to be used with this key.
*/
public String getAlgorithm() {
return algid.getName();
}
/**
* Returns the algorithm ID to be used with this key.
*/
public AlgorithmId getAlgorithmId () { return algid; }
/**
* PKCS#8 sequence on the DER output stream.
*/
public final void encode(DerOutputStream out) throws IOException
{
encode(out, this.algid, this.key);
}
/**
* Returns the DER-encoded form of the key as a byte array.
*/
public /* synchronized */ byte[] getEncoded() {
byte[] result = null;
try {
result = encode();
} catch (InvalidKeyException e) {
}
return result;
}
/**
* Returns the format for this key: "PKCS#8"
*/
public String getFormat() {
return "PKCS#8";
}
/**
* Returns the DER-encoded form of the key as a byte array.
*
* @exception InvalidKeyException if an encoding error occurs.
*/
public byte[] encode() throws InvalidKeyException {
if (encodedKey == null) {
try {
DerOutputStream out;
out = new DerOutputStream ();
encode (out);
encodedKey = out.toByteArray();
} catch (IOException e) {
throw new InvalidKeyException ("IOException : " +
e.getMessage());
}
}
//return encodedKey.clone();
byte[] result = encodedKey;
int len = result.length;
byte[] cloned = new byte[len];
for(int i=0;i<len;i++)
{
cloned[i] = result[i];
}
return cloned;
}
/*
* Returns a printable representation of the key
*/
public String toString ()
{
// HexDumpEncoder encoder = new HexDumpEncoder ();
return "algorithm = " + algid.toString ()
+ ", unparsed keybits = \n" ; //+ encoder.encodeBuffer (key);
}
/**
* Initialize an PKCS8Key object from an input stream. The data
* on that input stream must be encoded using DER, obeying the
* PKCS#8 format: a sequence consisting of a version, an algorithm
* ID and a bit string which holds the key. (That bit string is
* often used to encapsulate another DER encoded sequence.)
*
* <P>Subclasses should not normally redefine this method; they should
* instead provide a <code>parseKeyBits</code> method to parse any
* fields inside the <code>key</code> member.
*
* @param in an input stream with a DER-encoded PKCS#8
* SubjectPublicKeyInfo value
*
* @exception InvalidKeyException if a parsing error occurs.
*/
public void decode(InputStream in) throws InvalidKeyException
{
DerValue val;
try {
val = new DerValue (in);
if (val.tag != DerValue.tag_Sequence)
throw new InvalidKeyException ("invalid key format");
BigInteger version = val.data.getBigInteger();
if (!version.equals(this.version)) {
throw new IOException("version mismatch: (supported: " //+
// Debug.toHexString(this.version) +
// ", parsed: " +
// Debug.toHexString(version)
);
}
algid = AlgorithmId.parse (val.data.getDerValue ());
key = val.data.getOctetString ();
parseKeyBits ();
if (val.data.available () != 0) {
// OPTIONAL attributes not supported yet
}
} catch (IOException e) {
// e.printStackTrace ();
throw new InvalidKeyException("IOException : " +
e.getMessage());
}
}
public void decode(byte[] encodedKey) throws InvalidKeyException {
decode(new ByteArrayInputStream(encodedKey));
}
/*
protected Object writeReplace() throws java.io.ObjectStreamException {
return new KeyRep(KeyRep.Type.PRIVATE,
getAlgorithm(),
getFormat(),
getEncoded());
}
*/
/**
* Serialization read ... PKCS#8 keys serialize as
* themselves, and they're parsed when they get read back.
*/
/*
private void readObject (ObjectInputStream stream)
throws IOException {
try {
decode(stream);
} catch (InvalidKeyException e) {
e.printStackTrace();
throw new IOException("deserialized key is invalid: " +
e.getMessage());
}
}
*/
/*
* Produce PKCS#8 encoding from algorithm id and key material.
*/
static void encode(DerOutputStream out, AlgorithmId algid, byte[] key)
throws IOException {
DerOutputStream tmp = new DerOutputStream();
tmp.putInteger(version);
algid.encode(tmp);
tmp.putOctetString(key);
out.write(DerValue.tag_Sequence, tmp);
}
/**
* Compares two private keys. This returns false if the object with which
* to compare is not of type <code>Key</code>.
* Otherwise, the encoding of this key object is compared with the
* encoding of the given key object.
*
* @param object the object with which to compare
* @return <code>true</code> if this key has the same encoding as the
* object argument; <code>false</code> otherwise.
*/
public boolean equals(Object object) {
if (this == object) {
return true;
}
if (object instanceof Key) {
// this encoding
byte[] b1;
if (encodedKey != null) {
b1 = encodedKey;
} else {
b1 = getEncoded();
}
// that encoding
byte[] b2 = ((Key)object).getEncoded();
// do the comparison
int i;
if (b1.length != b2.length)
return false;
for (i = 0; i < b1.length; i++) {
if (b1[i] != b2[i]) {
return false;
}
}
return true;
}
return false;
}
/**
* Calculates a hash code value for this object. Objects
* which are equal will also have the same hashcode.
*/
public int hashCode() {
int retval = 0;
byte[] b1 = getEncoded();
for (int i = 1; i < b1.length; i++) {
retval += b1[i] * i;
}
return(retval);
}
}