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package java.security;

import java.util.*;

import java.security.spec.AlgorithmParameterSpec;

import java.security.Provider.Service;

import sun.security.jca.*;
import sun.security.jca.GetInstance.Instance;
import sun.security.util.Debug;

/**
 * The KeyPairGenerator class is used to generate pairs of
 * public and private keys. Key pair generators are constructed using the
 * {@code getInstance} factory methods (static methods that
 * return instances of a given class).
 *
 * 

A Key pair generator for a particular algorithm creates a public/private * key pair that can be used with this algorithm. It also associates * algorithm-specific parameters with each of the generated keys. * *

There are two ways to generate a key pair: in an algorithm-independent * manner, and in an algorithm-specific manner. * The only difference between the two is the initialization of the object: * *

    *
  • Algorithm-Independent Initialization *

    All key pair generators share the concepts of a keysize and a * source of randomness. The keysize is interpreted differently for different * algorithms (e.g., in the case of the DSA algorithm, the keysize * corresponds to the length of the modulus). * There is an * {@link #initialize(int, java.security.SecureRandom) initialize} * method in this KeyPairGenerator class that takes these two universally * shared types of arguments. There is also one that takes just a * {@code keysize} argument, and uses the {@code SecureRandom} * implementation of the highest-priority installed provider as the source * of randomness. (If none of the installed providers supply an implementation * of {@code SecureRandom}, a system-provided source of randomness is * used.) * *

    Since no other parameters are specified when you call the above * algorithm-independent {@code initialize} 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. * *

    If the algorithm is the DSA algorithm, and the keysize (modulus * size) is 512, 768, 1024, or 2048, then the Sun provider uses a set of * precomputed values for the {@code p}, {@code q}, and * {@code g} parameters. If the modulus size is not one of the above * values, the Sun provider creates a new set of parameters. Other * providers might have precomputed parameter sets for more than just the * modulus sizes mentioned above. Still others might not have a list of * precomputed parameters at all and instead always create new parameter sets. * *

  • Algorithm-Specific Initialization *

    For situations where a set of algorithm-specific parameters already * exists (e.g., so-called community parameters in DSA), there are two * {@link #initialize(java.security.spec.AlgorithmParameterSpec) * initialize} methods that have an {@code AlgorithmParameterSpec} * argument. One also has a {@code SecureRandom} argument, while * the other uses the {@code SecureRandom} * implementation of the highest-priority installed provider as the source * of randomness. (If none of the installed providers supply an implementation * of {@code SecureRandom}, a system-provided source of randomness is * used.) *

* *

In case the client does not explicitly initialize the KeyPairGenerator * (via a call to an {@code initialize} method), each provider must * supply (and document) a default initialization. * See the Keysize Restriction sections of the * {@extLink security_guide_jdk_providers JDK Providers} * document for information on the KeyPairGenerator defaults used by * JDK providers. * However, note that defaults may vary across different providers. * Additionally, the default value for a provider may change in a future * version. Therefore, it is recommended to explicitly initialize the * KeyPairGenerator instead of relying on provider-specific defaults. * *

Note that this class is abstract and extends from * {@code KeyPairGeneratorSpi} for historical reasons. * Application developers should only take notice of the methods defined in * this {@code KeyPairGenerator} class; all the methods in * the superclass are intended for cryptographic service providers who wish to * supply their own implementations of key pair generators. * *

Every implementation of the Java platform is required to support the * following standard {@code KeyPairGenerator} algorithms and keysizes in * parentheses: *

    *
  • {@code DiffieHellman} (1024, 2048, 4096)
  • *
  • {@code DSA} (1024, 2048)
  • *
  • {@code RSA} (1024, 2048, 4096)
  • *
* These algorithms are described in the * KeyPairGenerator section of the * Java Security Standard Algorithm Names Specification. * Consult the release documentation for your implementation to see if any * other algorithms are supported. * * @author Benjamin Renaud * @since 1.1 * * @see java.security.spec.AlgorithmParameterSpec */ public abstract class KeyPairGenerator extends KeyPairGeneratorSpi { private static final Debug pdebug = Debug.getInstance("provider", "Provider"); private static final boolean skipDebug = Debug.isOn("engine=") && !Debug.isOn("keypairgenerator"); private final String algorithm; // The provider Provider provider; /** * Creates a KeyPairGenerator object for the specified algorithm. * * @param algorithm the standard string name of the algorithm. * See the KeyPairGenerator section in the * Java Security Standard Algorithm Names Specification * for information about standard algorithm names. */ protected KeyPairGenerator(String algorithm) { this.algorithm = algorithm; } /** * Returns the standard name of the algorithm for this key pair generator. * See the KeyPairGenerator section in the * Java Security Standard Algorithm Names Specification * for information about standard algorithm names. * * @return the standard string name of the algorithm. */ public String getAlgorithm() { return this.algorithm; } private static KeyPairGenerator getInstance(Instance instance, String algorithm) { KeyPairGenerator kpg; if (instance.impl instanceof KeyPairGenerator) { kpg = (KeyPairGenerator)instance.impl; } else { KeyPairGeneratorSpi spi = (KeyPairGeneratorSpi)instance.impl; kpg = new Delegate(spi, algorithm); } kpg.provider = instance.provider; if (!skipDebug && pdebug != null) { pdebug.println("KeyPairGenerator." + algorithm + " algorithm from: " + kpg.provider.getName()); } return kpg; } /** * Returns a KeyPairGenerator object that generates public/private * key pairs for the specified algorithm. * *

This method traverses the list of registered security Providers, * starting with the most preferred Provider. * A new KeyPairGenerator object encapsulating the * KeyPairGeneratorSpi 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. * * @implNote * The JDK Reference Implementation additionally uses the * {@code jdk.security.provider.preferred} * {@link Security#getProperty(String) Security} property to determine * the preferred provider order for the specified algorithm. This * may be different than the order of providers returned by * {@link Security#getProviders() Security.getProviders()}. * * @param algorithm the standard string name of the algorithm. * See the KeyPairGenerator section in the * Java Security Standard Algorithm Names Specification * for information about standard algorithm names. * * @return the new {@code KeyPairGenerator} object * * @throws NoSuchAlgorithmException if no {@code Provider} supports a * {@code KeyPairGeneratorSpi} implementation for the * specified algorithm * * @throws NullPointerException if {@code algorithm} is {@code null} * * @see Provider */ public static KeyPairGenerator getInstance(String algorithm) throws NoSuchAlgorithmException { Objects.requireNonNull(algorithm, "null algorithm name"); List list = GetInstance.getServices("KeyPairGenerator", algorithm); Iterator t = list.iterator(); if (t.hasNext() == false) { throw new NoSuchAlgorithmException (algorithm + " KeyPairGenerator not available"); } // find a working Spi or KeyPairGenerator subclass NoSuchAlgorithmException failure = null; do { Service s = t.next(); try { Instance instance = GetInstance.getInstance(s, KeyPairGeneratorSpi.class); if (instance.impl instanceof KeyPairGenerator) { return getInstance(instance, algorithm); } else { return new Delegate(instance, t, algorithm); } } catch (NoSuchAlgorithmException e) { if (failure == null) { failure = e; } } } while (t.hasNext()); throw failure; } /** * Returns a KeyPairGenerator object that generates public/private * key pairs for the specified algorithm. * *

A new KeyPairGenerator object encapsulating the * KeyPairGeneratorSpi 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 string name of the algorithm. * See the KeyPairGenerator section in the * Java Security Standard Algorithm Names Specification * for information about standard algorithm names. * * @param provider the string name of the provider. * * @return the new {@code KeyPairGenerator} object * * @throws IllegalArgumentException if the provider name is {@code null} * or empty * * @throws NoSuchAlgorithmException if a {@code KeyPairGeneratorSpi} * implementation for the specified algorithm is not * available from the specified provider * * @throws NoSuchProviderException if the specified provider is not * registered in the security provider list * * @throws NullPointerException if {@code algorithm} is {@code null} * * @see Provider */ public static KeyPairGenerator getInstance(String algorithm, String provider) throws NoSuchAlgorithmException, NoSuchProviderException { Objects.requireNonNull(algorithm, "null algorithm name"); Instance instance = GetInstance.getInstance("KeyPairGenerator", KeyPairGeneratorSpi.class, algorithm, provider); return getInstance(instance, algorithm); } /** * Returns a KeyPairGenerator object that generates public/private * key pairs for the specified algorithm. * *

A new KeyPairGenerator object encapsulating the * KeyPairGeneratorSpi 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 string name of the algorithm. * See the KeyPairGenerator section in the * Java Security Standard Algorithm Names Specification * for information about standard algorithm names. * * @param provider the provider. * * @return the new {@code KeyPairGenerator} object * * @throws IllegalArgumentException if the specified provider is * {@code null} * * @throws NoSuchAlgorithmException if a {@code KeyPairGeneratorSpi} * implementation for the specified algorithm is not available * from the specified {@code Provider} object * * @throws NullPointerException if {@code algorithm} is {@code null} * * @see Provider * * @since 1.4 */ public static KeyPairGenerator getInstance(String algorithm, Provider provider) throws NoSuchAlgorithmException { Objects.requireNonNull(algorithm, "null algorithm name"); Instance instance = GetInstance.getInstance("KeyPairGenerator", KeyPairGeneratorSpi.class, algorithm, provider); return getInstance(instance, algorithm); } /** * Returns the provider of this key pair generator object. * * @return the provider of this key pair generator object */ public final Provider getProvider() { disableFailover(); return this.provider; } void disableFailover() { // empty, overridden in Delegate } /** * Initializes the key pair generator for a certain keysize using * a default parameter set and the {@code SecureRandom} * implementation of the highest-priority installed provider as the source * of randomness. * (If none of the installed providers supply an implementation of * {@code SecureRandom}, a system-provided source of randomness is * used.) * * @param keysize the keysize. This is an * algorithm-specific metric, such as modulus length, specified in * number of bits. * * @throws InvalidParameterException if the {@code keysize} is not * supported by this KeyPairGenerator object. */ public void initialize(int keysize) { initialize(keysize, JCAUtil.getDefSecureRandom()); } /** * Initializes the key pair generator for a certain keysize with * the given source of randomness (and a default parameter set). * * @param keysize the keysize. This is an * algorithm-specific metric, such as modulus length, specified in * number of bits. * @param random the source of randomness. * * @throws InvalidParameterException if the {@code keysize} is not * supported by this KeyPairGenerator object. * * @since 1.2 */ public void initialize(int keysize, SecureRandom random) { // This does nothing, because either // 1. the implementation object returned by getInstance() is an // instance of KeyPairGenerator which has its own // initialize(keysize, random) method, so the application would // be calling that method directly, or // 2. the implementation returned by getInstance() is an instance // of Delegate, in which case initialize(keysize, random) is // overridden to call the corresponding SPI method. // (This is a special case, because the API and SPI method have the // same name.) } /** * Initializes the key pair generator using the specified parameter * set and the {@code SecureRandom} * implementation of the highest-priority installed provider as the source * of randomness. * (If none of the installed providers supply an implementation of * {@code SecureRandom}, a system-provided source of randomness is * used.) * *

This concrete method has been added to this previously-defined * abstract class. * This method calls the KeyPairGeneratorSpi * {@link KeyPairGeneratorSpi#initialize( * java.security.spec.AlgorithmParameterSpec, * java.security.SecureRandom) initialize} method, * passing it {@code params} and a source of randomness (obtained * from the highest-priority installed provider or system-provided if none * of the installed providers supply one). * That {@code initialize} method always throws an * UnsupportedOperationException if it is not overridden by the provider. * * @param params the parameter set used to generate the keys. * * @throws InvalidAlgorithmParameterException if the given parameters * are inappropriate for this key pair generator. * * @since 1.2 */ public void initialize(AlgorithmParameterSpec params) throws InvalidAlgorithmParameterException { initialize(params, JCAUtil.getDefSecureRandom()); } /** * Initializes the key pair generator with the given parameter * set and source of randomness. * *

This concrete method has been added to this previously-defined * abstract class. * This method calls the KeyPairGeneratorSpi {@link * KeyPairGeneratorSpi#initialize( * java.security.spec.AlgorithmParameterSpec, * java.security.SecureRandom) initialize} method, * passing it {@code params} and {@code random}. * That {@code initialize} * method always throws an * UnsupportedOperationException if it is not overridden by the provider. * * @param params the parameter set used to generate the keys. * @param random the source of randomness. * * @throws InvalidAlgorithmParameterException if the given parameters * are inappropriate for this key pair generator. * * @since 1.2 */ public void initialize(AlgorithmParameterSpec params, SecureRandom random) throws InvalidAlgorithmParameterException { // This does nothing, because either // 1. the implementation object returned by getInstance() is an // instance of KeyPairGenerator which has its own // initialize(params, random) method, so the application would // be calling that method directly, or // 2. the implementation returned by getInstance() is an instance // of Delegate, in which case initialize(params, random) is // overridden to call the corresponding SPI method. // (This is a special case, because the API and SPI method have the // same name.) } /** * Generates a key pair. * *

If this KeyPairGenerator has not been initialized explicitly, * provider-specific defaults will be used for the size and other * (algorithm-specific) values of the generated keys. * *

This will generate a new key pair every time it is called. * *

This method is functionally equivalent to * {@link #generateKeyPair() generateKeyPair}. * * @return the generated key pair * * @since 1.2 */ public final KeyPair genKeyPair() { return generateKeyPair(); } /** * Generates a key pair. * *

If this KeyPairGenerator has not been initialized explicitly, * provider-specific defaults will be used for the size and other * (algorithm-specific) values of the generated keys. * *

This will generate a new key pair every time it is called. * *

This method is functionally equivalent to * {@link #genKeyPair() genKeyPair}. * * @return the generated key pair */ public KeyPair generateKeyPair() { // This does nothing (except returning null), because either: // // 1. the implementation object returned by getInstance() is an // instance of KeyPairGenerator which has its own implementation // of generateKeyPair (overriding this one), so the application // would be calling that method directly, or // // 2. the implementation returned by getInstance() is an instance // of Delegate, in which case generateKeyPair is // overridden to invoke the corresponding SPI method. // // (This is a special case, because in JDK 1.1.x the generateKeyPair // method was used both as an API and a SPI method.) return null; } /* * The following class allows providers to extend from KeyPairGeneratorSpi * rather than from KeyPairGenerator. It represents a KeyPairGenerator * with an encapsulated, provider-supplied SPI object (of type * KeyPairGeneratorSpi). * If the provider implementation is an instance of KeyPairGeneratorSpi, * the getInstance() methods above return an instance of this class, with * the SPI object encapsulated. * * Note: All SPI methods from the original KeyPairGenerator class have been * moved up the hierarchy into a new class (KeyPairGeneratorSpi), which has * been interposed in the hierarchy between the API (KeyPairGenerator) * and its original parent (Object). */ // // error failover notes: // // . we failover if the implementation throws an error during init // by retrying the init on other providers // // . we also failover if the init succeeded but the subsequent call // to generateKeyPair() fails. In order for this to work, we need // to remember the parameters to the last successful call to init // and initialize() the next spi using them. // // . although not specified, KeyPairGenerators could be thread safe, // so we make sure we do not interfere with that // // . failover is not available, if: // . getInstance(algorithm, provider) was used // . a provider extends KeyPairGenerator rather than // KeyPairGeneratorSpi (JDK 1.1 style) // . once getProvider() is called // private static final class Delegate extends KeyPairGenerator { // The provider implementation (delegate) private volatile KeyPairGeneratorSpi spi; private final Object lock = new Object(); private Iterator serviceIterator; private static final int I_NONE = 1; private static final int I_SIZE = 2; private static final int I_PARAMS = 3; private int initType; private int initKeySize; private AlgorithmParameterSpec initParams; private SecureRandom initRandom; // constructor Delegate(KeyPairGeneratorSpi spi, String algorithm) { super(algorithm); this.spi = spi; } Delegate(Instance instance, Iterator serviceIterator, String algorithm) { super(algorithm); spi = (KeyPairGeneratorSpi)instance.impl; provider = instance.provider; this.serviceIterator = serviceIterator; initType = I_NONE; if (!skipDebug && pdebug != null) { pdebug.println("KeyPairGenerator." + algorithm + " algorithm from: " + provider.getName()); } } /** * 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 KeyPairGeneratorSpi nextSpi(KeyPairGeneratorSpi 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(); try { Object inst = s.newInstance(null); // ignore non-spis if (!(inst instanceof KeyPairGeneratorSpi spi)) { continue; } if (inst instanceof KeyPairGenerator) { continue; } if (reinit) { if (initType == I_SIZE) { spi.initialize(initKeySize, initRandom); } else if (initType == I_PARAMS) { spi.initialize(initParams, initRandom); } else if (initType != I_NONE) { throw new AssertionError ("KeyPairGenerator 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; } // engine method public void initialize(int keysize, SecureRandom random) { if (serviceIterator == null) { spi.initialize(keysize, random); return; } RuntimeException failure = null; KeyPairGeneratorSpi mySpi = spi; do { try { mySpi.initialize(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; } // engine method public void initialize(AlgorithmParameterSpec params, SecureRandom random) throws InvalidAlgorithmParameterException { if (serviceIterator == null) { spi.initialize(params, random); return; } Exception failure = null; KeyPairGeneratorSpi mySpi = spi; do { try { mySpi.initialize(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 RuntimeException) { throw (RuntimeException)failure; } // must be an InvalidAlgorithmParameterException throw (InvalidAlgorithmParameterException)failure; } // engine method public KeyPair generateKeyPair() { if (serviceIterator == null) { return spi.generateKeyPair(); } RuntimeException failure = null; KeyPairGeneratorSpi mySpi = spi; do { try { return mySpi.generateKeyPair(); } catch (RuntimeException e) { if (failure == null) { failure = e; } mySpi = nextSpi(mySpi, true); } } while (mySpi != null); throw failure; } } }





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