8056026: Debug security logging should print Provider used for each crypto operation
Reviewed-by: mullan
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package javax.crypto;
import java.util.*;
import java.security.*;
import java.security.Provider.Service;
import java.security.spec.*;
import sun.security.util.Debug;
import sun.security.jca.*;
import sun.security.jca.GetInstance.Instance;
/**
* This class provides the functionality of a key agreement (or key
* exchange) protocol.
* <p>
* The keys involved in establishing a shared secret are created by one of the
* key generators (<code>KeyPairGenerator</code> or
* <code>KeyGenerator</code>), a <code>KeyFactory</code>, or as a result from
* an intermediate phase of the key agreement protocol.
*
* <p> For each of the correspondents in the key exchange, <code>doPhase</code>
* needs to be called. For example, if this key exchange is with one other
* party, <code>doPhase</code> needs to be called once, with the
* <code>lastPhase</code> flag set to <code>true</code>.
* If this key exchange is
* with two other parties, <code>doPhase</code> needs to be called twice,
* the first time setting the <code>lastPhase</code> flag to
* <code>false</code>, and the second time setting it to <code>true</code>.
* There may be any number of parties involved in a key exchange.
*
* <p> Every implementation of the Java platform is required to support the
* following standard <code>KeyAgreement</code> algorithm:
* <ul>
* <li><tt>DiffieHellman</tt></li>
* </ul>
* This algorithm is described in the <a href=
* "{@docRoot}/../technotes/guides/security/StandardNames.html#KeyAgreement">
* KeyAgreement section</a> of the
* Java Cryptography Architecture Standard Algorithm Name Documentation.
* Consult the release documentation for your implementation to see if any
* other algorithms are supported.
*
* @author Jan Luehe
*
* @see KeyGenerator
* @see SecretKey
* @since 1.4
*/
public class KeyAgreement {
private static final Debug debug =
Debug.getInstance("jca", "KeyAgreement");
private static final Debug pdebug =
Debug.getInstance("provider", "Provider");
private static final boolean skipDebug =
Debug.isOn("engine=") && !Debug.isOn("keyagreement");
// The provider
private Provider provider;
// The provider implementation (delegate)
private KeyAgreementSpi spi;
// The name of the key agreement algorithm.
private final String algorithm;
// next service to try in provider selection
// null once provider is selected
private Service firstService;
// remaining services to try in provider selection
// null once provider is selected
private Iterator<Service> serviceIterator;
private final Object lock;
/**
* Creates a KeyAgreement object.
*
* @param keyAgreeSpi the delegate
* @param provider the provider
* @param algorithm the algorithm
*/
protected KeyAgreement(KeyAgreementSpi keyAgreeSpi, Provider provider,
String algorithm) {
this.spi = keyAgreeSpi;
this.provider = provider;
this.algorithm = algorithm;
lock = null;
}
private KeyAgreement(Service s, Iterator<Service> t, String algorithm) {
firstService = s;
serviceIterator = t;
this.algorithm = algorithm;
lock = new Object();
}
/**
* Returns the algorithm name of this <code>KeyAgreement</code> object.
*
* <p>This is the same name that was specified in one of the
* <code>getInstance</code> calls that created this
* <code>KeyAgreement</code> object.
*
* @return the algorithm name of this <code>KeyAgreement</code> object.
*/
public final String getAlgorithm() {
return this.algorithm;
}
/**
* Returns a <code>KeyAgreement</code> object that implements the
* specified key agreement algorithm.
*
* <p> This method traverses the list of registered security Providers,
* starting with the most preferred Provider.
* A new KeyAgreement object encapsulating the
* KeyAgreementSpi implementation from the first
* Provider that supports the specified algorithm is returned.
*
* <p> 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 agreement
* algorithm.
* See the KeyAgreement section in the <a href=
* "{@docRoot}/../technotes/guides/security/StandardNames.html#KeyAgreement">
* Java Cryptography Architecture Standard Algorithm Name Documentation</a>
* for information about standard algorithm names.
*
* @return the new <code>KeyAgreement</code> object.
*
* @exception NullPointerException if the specified algorithm
* is null.
*
* @exception NoSuchAlgorithmException if no Provider supports a
* KeyAgreementSpi implementation for the
* specified algorithm.
*
* @see java.security.Provider
*/
public static final KeyAgreement getInstance(String algorithm)
throws NoSuchAlgorithmException {
List<Service> services =
GetInstance.getServices("KeyAgreement", algorithm);
// make sure there is at least one service from a signed provider
Iterator<Service> t = services.iterator();
while (t.hasNext()) {
Service s = t.next();
if (JceSecurity.canUseProvider(s.getProvider()) == false) {
continue;
}
return new KeyAgreement(s, t, algorithm);
}
throw new NoSuchAlgorithmException
("Algorithm " + algorithm + " not available");
}
/**
* Returns a <code>KeyAgreement</code> object that implements the
* specified key agreement algorithm.
*
* <p> A new KeyAgreement object encapsulating the
* KeyAgreementSpi implementation from the specified provider
* is returned. The specified provider must be registered
* in the security provider list.
*
* <p> 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 agreement
* algorithm.
* See the KeyAgreement section in the <a href=
* "{@docRoot}/../technotes/guides/security/StandardNames.html#KeyAgreement">
* Java Cryptography Architecture Standard Algorithm Name Documentation</a>
* for information about standard algorithm names.
*
* @param provider the name of the provider.
*
* @return the new <code>KeyAgreement</code> object.
*
* @exception NullPointerException if the specified algorithm
* is null.
*
* @exception NoSuchAlgorithmException if a KeyAgreementSpi
* 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 <code>provider</code>
* is null or empty.
*
* @see java.security.Provider
*/
public static final KeyAgreement getInstance(String algorithm,
String provider) throws NoSuchAlgorithmException,
NoSuchProviderException {
Instance instance = JceSecurity.getInstance
("KeyAgreement", KeyAgreementSpi.class, algorithm, provider);
return new KeyAgreement((KeyAgreementSpi)instance.impl,
instance.provider, algorithm);
}
/**
* Returns a <code>KeyAgreement</code> object that implements the
* specified key agreement algorithm.
*
* <p> A new KeyAgreement object encapsulating the
* KeyAgreementSpi 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 agreement
* algorithm.
* See the KeyAgreement section in the <a href=
* "{@docRoot}/../technotes/guides/security/StandardNames.html#KeyAgreement">
* Java Cryptography Architecture Standard Algorithm Name Documentation</a>
* for information about standard algorithm names.
*
* @param provider the provider.
*
* @return the new <code>KeyAgreement</code> object.
*
* @exception NullPointerException if the specified algorithm
* is null.
*
* @exception NoSuchAlgorithmException if a KeyAgreementSpi
* implementation for the specified algorithm is not available
* from the specified Provider object.
*
* @exception IllegalArgumentException if the <code>provider</code>
* is null.
*
* @see java.security.Provider
*/
public static final KeyAgreement getInstance(String algorithm,
Provider provider) throws NoSuchAlgorithmException {
Instance instance = JceSecurity.getInstance
("KeyAgreement", KeyAgreementSpi.class, algorithm, provider);
return new KeyAgreement((KeyAgreementSpi)instance.impl,
instance.provider, algorithm);
}
// max number of debug warnings to print from chooseFirstProvider()
private static int warnCount = 10;
/**
* Choose the Spi from the first provider available. Used if
* delayed provider selection is not possible because init()
* is not the first method called.
*/
void chooseFirstProvider() {
if (spi != null) {
return;
}
synchronized (lock) {
if (spi != null) {
return;
}
if (debug != null) {
int w = --warnCount;
if (w >= 0) {
debug.println("KeyAgreement.init() not first method "
+ "called, disabling delayed provider selection");
if (w == 0) {
debug.println("Further warnings of this type will "
+ "be suppressed");
}
new Exception("Call trace").printStackTrace();
}
}
Exception lastException = null;
while ((firstService != null) || serviceIterator.hasNext()) {
Service s;
if (firstService != null) {
s = firstService;
firstService = null;
} else {
s = serviceIterator.next();
}
if (JceSecurity.canUseProvider(s.getProvider()) == false) {
continue;
}
try {
Object obj = s.newInstance(null);
if (obj instanceof KeyAgreementSpi == false) {
continue;
}
spi = (KeyAgreementSpi)obj;
provider = s.getProvider();
// not needed any more
firstService = null;
serviceIterator = null;
return;
} catch (Exception e) {
lastException = e;
}
}
ProviderException e = new ProviderException
("Could not construct KeyAgreementSpi instance");
if (lastException != null) {
e.initCause(lastException);
}
throw e;
}
}
private final static int I_NO_PARAMS = 1;
private final static int I_PARAMS = 2;
private void implInit(KeyAgreementSpi spi, int type, Key key,
AlgorithmParameterSpec params, SecureRandom random)
throws InvalidKeyException, InvalidAlgorithmParameterException {
if (type == I_NO_PARAMS) {
spi.engineInit(key, random);
} else { // I_PARAMS
spi.engineInit(key, params, random);
}
}
private void chooseProvider(int initType, Key key,
AlgorithmParameterSpec params, SecureRandom random)
throws InvalidKeyException, InvalidAlgorithmParameterException {
synchronized (lock) {
if (spi != null) {
implInit(spi, initType, key, params, random);
return;
}
Exception lastException = null;
while ((firstService != null) || serviceIterator.hasNext()) {
Service s;
if (firstService != null) {
s = firstService;
firstService = null;
} else {
s = serviceIterator.next();
}
// if provider says it does not support this key, ignore it
if (s.supportsParameter(key) == false) {
continue;
}
if (JceSecurity.canUseProvider(s.getProvider()) == false) {
continue;
}
try {
KeyAgreementSpi spi = (KeyAgreementSpi)s.newInstance(null);
implInit(spi, initType, key, params, random);
provider = s.getProvider();
this.spi = spi;
firstService = null;
serviceIterator = null;
return;
} catch (Exception e) {
// NoSuchAlgorithmException from newInstance()
// InvalidKeyException from init()
// RuntimeException (ProviderException) from init()
if (lastException == null) {
lastException = e;
}
}
}
// no working provider found, fail
if (lastException instanceof InvalidKeyException) {
throw (InvalidKeyException)lastException;
}
if (lastException instanceof InvalidAlgorithmParameterException) {
throw (InvalidAlgorithmParameterException)lastException;
}
if (lastException instanceof RuntimeException) {
throw (RuntimeException)lastException;
}
String kName = (key != null) ? key.getClass().getName() : "(null)";
throw new InvalidKeyException
("No installed provider supports this key: "
+ kName, lastException);
}
}
/**
* Returns the provider of this <code>KeyAgreement</code> object.
*
* @return the provider of this <code>KeyAgreement</code> object
*/
public final Provider getProvider() {
chooseFirstProvider();
return this.provider;
}
/**
* Initializes this key agreement with the given key, which is required to
* contain all the algorithm parameters required for this key agreement.
*
* <p> If this key agreement 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 key the party's private information. For example, in the case
* of the Diffie-Hellman key agreement, this would be the party's own
* Diffie-Hellman private key.
*
* @exception InvalidKeyException if the given key is
* inappropriate for this key agreement, e.g., is of the wrong type or
* has an incompatible algorithm type.
*/
public final void init(Key key) throws InvalidKeyException {
init(key, JceSecurity.RANDOM);
}
/**
* Initializes this key agreement with the given key and source of
* randomness. The given key is required to contain all the algorithm
* parameters required for this key agreement.
*
* <p> If the key agreement algorithm requires random bytes, it gets them
* from the given source of randomness, <code>random</code>.
* However, if the underlying
* algorithm implementation does not require any random bytes,
* <code>random</code> is ignored.
*
* @param key the party's private information. For example, in the case
* of the Diffie-Hellman key agreement, this would be the party's own
* Diffie-Hellman private key.
* @param random the source of randomness
*
* @exception InvalidKeyException if the given key is
* inappropriate for this key agreement, e.g., is of the wrong type or
* has an incompatible algorithm type.
*/
public final void init(Key key, SecureRandom random)
throws InvalidKeyException {
if (spi != null) {
spi.engineInit(key, random);
} else {
try {
chooseProvider(I_NO_PARAMS, key, null, random);
} catch (InvalidAlgorithmParameterException e) {
// should never occur
throw new InvalidKeyException(e);
}
}
if (!skipDebug && pdebug != null) {
pdebug.println("KeyAgreement." + algorithm + " algorithm from: " +
this.provider.getName());
}
}
/**
* Initializes this key agreement with the given key and set of
* algorithm parameters.
*
* <p> If this key agreement 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 key the party's private information. For example, in the case
* of the Diffie-Hellman key agreement, this would be the party's own
* Diffie-Hellman private key.
* @param params the key agreement parameters
*
* @exception InvalidKeyException if the given key is
* inappropriate for this key agreement, e.g., is of the wrong type or
* has an incompatible algorithm type.
* @exception InvalidAlgorithmParameterException if the given parameters
* are inappropriate for this key agreement.
*/
public final void init(Key key, AlgorithmParameterSpec params)
throws InvalidKeyException, InvalidAlgorithmParameterException
{
init(key, params, JceSecurity.RANDOM);
}
/**
* Initializes this key agreement with the given key, set of
* algorithm parameters, and source of randomness.
*
* @param key the party's private information. For example, in the case
* of the Diffie-Hellman key agreement, this would be the party's own
* Diffie-Hellman private key.
* @param params the key agreement parameters
* @param random the source of randomness
*
* @exception InvalidKeyException if the given key is
* inappropriate for this key agreement, e.g., is of the wrong type or
* has an incompatible algorithm type.
* @exception InvalidAlgorithmParameterException if the given parameters
* are inappropriate for this key agreement.
*/
public final void init(Key key, AlgorithmParameterSpec params,
SecureRandom random)
throws InvalidKeyException, InvalidAlgorithmParameterException
{
if (spi != null) {
spi.engineInit(key, params, random);
} else {
chooseProvider(I_PARAMS, key, params, random);
}
if (!skipDebug && pdebug != null) {
pdebug.println("KeyAgreement." + algorithm + " algorithm from: " +
this.provider.getName());
}
}
/**
* Executes the next phase of this key agreement with the given
* key that was received from one of the other parties involved in this key
* agreement.
*
* @param key the key for this phase. For example, in the case of
* Diffie-Hellman between 2 parties, this would be the other party's
* Diffie-Hellman public key.
* @param lastPhase flag which indicates whether or not this is the last
* phase of this key agreement.
*
* @return the (intermediate) key resulting from this phase, or null
* if this phase does not yield a key
*
* @exception InvalidKeyException if the given key is inappropriate for
* this phase.
* @exception IllegalStateException if this key agreement has not been
* initialized.
*/
public final Key doPhase(Key key, boolean lastPhase)
throws InvalidKeyException, IllegalStateException
{
chooseFirstProvider();
return spi.engineDoPhase(key, lastPhase);
}
/**
* Generates the shared secret and returns it in a new buffer.
*
* <p>This method resets this <code>KeyAgreement</code> object, so that it
* can be reused for further key agreements. Unless this key agreement is
* reinitialized with one of the <code>init</code> methods, the same
* private information and algorithm parameters will be used for
* subsequent key agreements.
*
* @return the new buffer with the shared secret
*
* @exception IllegalStateException if this key agreement has not been
* completed yet
*/
public final byte[] generateSecret() throws IllegalStateException {
chooseFirstProvider();
return spi.engineGenerateSecret();
}
/**
* Generates the shared secret, and places it into the buffer
* <code>sharedSecret</code>, beginning at <code>offset</code> inclusive.
*
* <p>If the <code>sharedSecret</code> buffer is too small to hold the
* result, a <code>ShortBufferException</code> is thrown.
* In this case, this call should be repeated with a larger output buffer.
*
* <p>This method resets this <code>KeyAgreement</code> object, so that it
* can be reused for further key agreements. Unless this key agreement is
* reinitialized with one of the <code>init</code> methods, the same
* private information and algorithm parameters will be used for
* subsequent key agreements.
*
* @param sharedSecret the buffer for the shared secret
* @param offset the offset in <code>sharedSecret</code> where the
* shared secret will be stored
*
* @return the number of bytes placed into <code>sharedSecret</code>
*
* @exception IllegalStateException if this key agreement has not been
* completed yet
* @exception ShortBufferException if the given output buffer is too small
* to hold the secret
*/
public final int generateSecret(byte[] sharedSecret, int offset)
throws IllegalStateException, ShortBufferException
{
chooseFirstProvider();
return spi.engineGenerateSecret(sharedSecret, offset);
}
/**
* Creates the shared secret and returns it as a <code>SecretKey</code>
* object of the specified algorithm.
*
* <p>This method resets this <code>KeyAgreement</code> object, so that it
* can be reused for further key agreements. Unless this key agreement is
* reinitialized with one of the <code>init</code> methods, the same
* private information and algorithm parameters will be used for
* subsequent key agreements.
*
* @param algorithm the requested secret-key algorithm
*
* @return the shared secret key
*
* @exception IllegalStateException if this key agreement has not been
* completed yet
* @exception NoSuchAlgorithmException if the specified secret-key
* algorithm is not available
* @exception InvalidKeyException if the shared secret-key material cannot
* be used to generate a secret key of the specified algorithm (e.g.,
* the key material is too short)
*/
public final SecretKey generateSecret(String algorithm)
throws IllegalStateException, NoSuchAlgorithmException,
InvalidKeyException
{
chooseFirstProvider();
return spi.engineGenerateSecret(algorithm);
}
}