/* * Copyright (c) 1997, 2013, Oracle and/or its affiliates. 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. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle 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 Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package javax.crypto; import java.util.*; import java.security.*; import java.security.Provider.Service; import java.security.spec.*; import sun.security.jca.*; import sun.security.jca.GetInstance.Instance; /** * This class provides the functionality of a secret (symmetric) key generator. * *
Key generators are constructed using one of the getInstance
* class methods of this class.
*
*
KeyGenerator objects are reusable, i.e., after a key has been * generated, the same KeyGenerator object can be re-used to generate further * keys. * *
There are two ways to generate a key: in an algorithm-independent * manner, and in an algorithm-specific manner. * The only difference between the two is the initialization of the object: * *
All key generators share the concepts of a keysize and a
* source of randomness.
* There is an
* {@link #init(int, java.security.SecureRandom) init}
* method in this KeyGenerator class that takes these two universally
* shared types of arguments. There is also one that takes just a
* keysize
argument, and uses the SecureRandom implementation
* of the highest-priority installed provider as the source of randomness
* (or a system-provided source of randomness if none of the installed
* providers supply a SecureRandom implementation), and one that takes just a
* source of randomness.
*
*
Since no other parameters are specified when you call the above
* algorithm-independent init
methods, it is up to the
* provider what to do about the algorithm-specific parameters (if any) to be
* associated with each of the keys.
*
* *
For situations where a set of algorithm-specific parameters already
* exists, there are two
* {@link #init(java.security.spec.AlgorithmParameterSpec) init}
* methods that have an AlgorithmParameterSpec
* argument. One also has a SecureRandom
argument, while the
* other uses the SecureRandom implementation
* of the highest-priority installed provider as the source of randomness
* (or a system-provided source of randomness if none of the installed
* providers supply a SecureRandom implementation).
*
In case the client does not explicitly initialize the KeyGenerator
* (via a call to an init
method), each provider must
* supply (and document) a default initialization.
*
*
Every implementation of the Java platform is required to support the
* following standard KeyGenerator
algorithms with the keysizes in
* parentheses:
*
KeyGenerator
object.
*
* This is the same name that was specified in one of the
* getInstance
calls that created this
* KeyGenerator
object.
*
* @return the algorithm name of this KeyGenerator
object.
*/
public final String getAlgorithm() {
return this.algorithm;
}
/**
* Returns a KeyGenerator
object that generates secret keys
* for the specified algorithm.
*
*
This method traverses the list of registered security Providers, * starting with the most preferred Provider. * A new KeyGenerator object encapsulating the * KeyGeneratorSpi implementation from the first * Provider that supports the specified algorithm is returned. * *
Note that the list of registered providers may be retrieved via
* the {@link Security#getProviders() Security.getProviders()} method.
*
* @param algorithm the standard name of the requested key algorithm.
* See the KeyGenerator section in the
* Java Cryptography Architecture Standard Algorithm Name Documentation
* for information about standard algorithm names.
*
* @return the new KeyGenerator
object.
*
* @exception NullPointerException if the specified algorithm is null.
*
* @exception NoSuchAlgorithmException if no Provider supports a
* KeyGeneratorSpi implementation for the
* specified algorithm.
*
* @see java.security.Provider
*/
public static final KeyGenerator getInstance(String algorithm)
throws NoSuchAlgorithmException {
return new KeyGenerator(algorithm);
}
/**
* Returns a KeyGenerator
object that generates secret keys
* for the specified algorithm.
*
*
A new KeyGenerator object encapsulating the * KeyGeneratorSpi implementation from the specified provider * is returned. The specified provider must be registered * in the security provider list. * *
Note that the list of registered providers may be retrieved via
* the {@link Security#getProviders() Security.getProviders()} method.
*
* @param algorithm the standard name of the requested key algorithm.
* See the KeyGenerator section in the
* Java Cryptography Architecture Standard Algorithm Name Documentation
* for information about standard algorithm names.
*
* @param provider the name of the provider.
*
* @return the new KeyGenerator
object.
*
* @exception NullPointerException if the specified algorithm is null.
*
* @exception NoSuchAlgorithmException if a KeyGeneratorSpi
* implementation for the specified algorithm is not
* available from the specified provider.
*
* @exception NoSuchProviderException if the specified provider is not
* registered in the security provider list.
*
* @exception IllegalArgumentException if the provider
* is null or empty.
*
* @see java.security.Provider
*/
public static final KeyGenerator getInstance(String algorithm,
String provider) throws NoSuchAlgorithmException,
NoSuchProviderException {
Instance instance = JceSecurity.getInstance("KeyGenerator",
KeyGeneratorSpi.class, algorithm, provider);
return new KeyGenerator((KeyGeneratorSpi)instance.impl,
instance.provider, algorithm);
}
/**
* Returns a KeyGenerator
object that generates secret keys
* for the specified algorithm.
*
*
A new KeyGenerator object encapsulating the
* KeyGeneratorSpi implementation from the specified Provider
* object is returned. Note that the specified Provider object
* does not have to be registered in the provider list.
*
* @param algorithm the standard name of the requested key algorithm.
* See the KeyGenerator section in the
* Java Cryptography Architecture Standard Algorithm Name Documentation
* for information about standard algorithm names.
*
* @param provider the provider.
*
* @return the new KeyGenerator
object.
*
* @exception NullPointerException if the specified algorithm is null.
*
* @exception NoSuchAlgorithmException if a KeyGeneratorSpi
* implementation for the specified algorithm is not available
* from the specified Provider object.
*
* @exception IllegalArgumentException if the provider
* is null.
*
* @see java.security.Provider
*/
public static final KeyGenerator getInstance(String algorithm,
Provider provider) throws NoSuchAlgorithmException {
Instance instance = JceSecurity.getInstance("KeyGenerator",
KeyGeneratorSpi.class, algorithm, provider);
return new KeyGenerator((KeyGeneratorSpi)instance.impl,
instance.provider, algorithm);
}
/**
* Returns the provider of this KeyGenerator
object.
*
* @return the provider of this KeyGenerator
object
*/
public final Provider getProvider() {
synchronized (lock) {
disableFailover();
return provider;
}
}
/**
* Update the active spi of this class and return the next
* implementation for failover. If no more implemenations are
* available, this method returns null. However, the active spi of
* this class is never set to null.
*/
private KeyGeneratorSpi nextSpi(KeyGeneratorSpi oldSpi,
boolean reinit) {
synchronized (lock) {
// somebody else did a failover concurrently
// try that spi now
if ((oldSpi != null) && (oldSpi != spi)) {
return spi;
}
if (serviceIterator == null) {
return null;
}
while (serviceIterator.hasNext()) {
Service s = serviceIterator.next();
if (JceSecurity.canUseProvider(s.getProvider()) == false) {
continue;
}
try {
Object inst = s.newInstance(null);
// ignore non-spis
if (inst instanceof KeyGeneratorSpi == false) {
continue;
}
KeyGeneratorSpi spi = (KeyGeneratorSpi)inst;
if (reinit) {
if (initType == I_SIZE) {
spi.engineInit(initKeySize, initRandom);
} else if (initType == I_PARAMS) {
spi.engineInit(initParams, initRandom);
} else if (initType == I_RANDOM) {
spi.engineInit(initRandom);
} else if (initType != I_NONE) {
throw new AssertionError
("KeyGenerator initType: " + initType);
}
}
provider = s.getProvider();
this.spi = spi;
return spi;
} catch (Exception e) {
// ignore
}
}
disableFailover();
return null;
}
}
void disableFailover() {
serviceIterator = null;
initType = 0;
initParams = null;
initRandom = null;
}
/**
* Initializes this key generator.
*
* @param random the source of randomness for this generator
*/
public final void init(SecureRandom random) {
if (serviceIterator == null) {
spi.engineInit(random);
return;
}
RuntimeException failure = null;
KeyGeneratorSpi mySpi = spi;
do {
try {
mySpi.engineInit(random);
initType = I_RANDOM;
initKeySize = 0;
initParams = null;
initRandom = random;
return;
} catch (RuntimeException e) {
if (failure == null) {
failure = e;
}
mySpi = nextSpi(mySpi, false);
}
} while (mySpi != null);
throw failure;
}
/**
* Initializes this key generator with the specified parameter set.
*
*
If this key generator requires any random bytes, it will get them
* using the
* {@link java.security.SecureRandom}
* implementation of the highest-priority installed
* provider as the source of randomness.
* (If none of the installed providers supply an implementation of
* SecureRandom, a system-provided source of randomness will be used.)
*
* @param params the key generation parameters
*
* @exception InvalidAlgorithmParameterException if the given parameters
* are inappropriate for this key generator
*/
public final void init(AlgorithmParameterSpec params)
throws InvalidAlgorithmParameterException
{
init(params, JceSecurity.RANDOM);
}
/**
* Initializes this key generator with the specified parameter
* set and a user-provided source of randomness.
*
* @param params the key generation parameters
* @param random the source of randomness for this key generator
*
* @exception InvalidAlgorithmParameterException if params
is
* inappropriate for this key generator
*/
public final void init(AlgorithmParameterSpec params, SecureRandom random)
throws InvalidAlgorithmParameterException
{
if (serviceIterator == null) {
spi.engineInit(params, random);
return;
}
Exception failure = null;
KeyGeneratorSpi mySpi = spi;
do {
try {
mySpi.engineInit(params, random);
initType = I_PARAMS;
initKeySize = 0;
initParams = params;
initRandom = random;
return;
} catch (Exception e) {
if (failure == null) {
failure = e;
}
mySpi = nextSpi(mySpi, false);
}
} while (mySpi != null);
if (failure instanceof InvalidAlgorithmParameterException) {
throw (InvalidAlgorithmParameterException)failure;
}
if (failure instanceof RuntimeException) {
throw (RuntimeException)failure;
}
throw new InvalidAlgorithmParameterException("init() failed", failure);
}
/**
* Initializes this key generator for a certain keysize.
*
*
If this key generator requires any random bytes, it will get them * using the * {@link java.security.SecureRandom} * implementation of the highest-priority installed * provider as the source of randomness. * (If none of the installed providers supply an implementation of * SecureRandom, a system-provided source of randomness will be used.) * * @param keysize the keysize. This is an algorithm-specific metric, * specified in number of bits. * * @exception InvalidParameterException if the keysize is wrong or not * supported. */ public final void init(int keysize) { init(keysize, JceSecurity.RANDOM); } /** * Initializes this key generator for a certain keysize, using a * user-provided source of randomness. * * @param keysize the keysize. This is an algorithm-specific metric, * specified in number of bits. * @param random the source of randomness for this key generator * * @exception InvalidParameterException if the keysize is wrong or not * supported. */ public final void init(int keysize, SecureRandom random) { if (serviceIterator == null) { spi.engineInit(keysize, random); return; } RuntimeException failure = null; KeyGeneratorSpi mySpi = spi; do { try { mySpi.engineInit(keysize, random); initType = I_SIZE; initKeySize = keysize; initParams = null; initRandom = random; return; } catch (RuntimeException e) { if (failure == null) { failure = e; } mySpi = nextSpi(mySpi, false); } } while (mySpi != null); throw failure; } /** * Generates a secret key. * * @return the new key */ public final SecretKey generateKey() { if (serviceIterator == null) { return spi.engineGenerateKey(); } RuntimeException failure = null; KeyGeneratorSpi mySpi = spi; do { try { return mySpi.engineGenerateKey(); } catch (RuntimeException e) { if (failure == null) { failure = e; } mySpi = nextSpi(mySpi, true); } } while (mySpi != null); throw failure; } }