Package java.security

Source Code of java.security.Signature$CipherAdapter

/*
* @(#)Signature.java  1.103 06/04/21
*
* Copyright 2006 Sun Microsystems, Inc. All rights reserved.
* SUN PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
*/
 
package java.security;

import java.security.spec.AlgorithmParameterSpec;
import java.util.*;
import java.util.concurrent.ConcurrentHashMap;
import java.io.*;
import java.security.cert.Certificate;
import java.security.cert.X509Certificate;

import java.nio.ByteBuffer;

import java.security.Provider.Service;

import javax.crypto.Cipher;
import javax.crypto.CipherSpi;
import javax.crypto.IllegalBlockSizeException;
import javax.crypto.BadPaddingException;
import javax.crypto.NoSuchPaddingException;

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

/**
* This Signature class is used to provide applications the functionality
* of a digital signature algorithm. Digital signatures are used for
* authentication and integrity assurance of digital data.
*
* <p> The signature algorithm can be, among others, the NIST standard
* DSA, using DSA and SHA-1. The DSA algorithm using the
* SHA-1 message digest algorithm can be specified as <tt>SHA1withDSA</tt>.
* In the case of RSA, there are multiple choices for the message digest
* algorithm, so the signing algorithm could be specified as, for example,
* <tt>MD2withRSA</tt>, <tt>MD5withRSA</tt>, or <tt>SHA1withRSA</tt>.
* The algorithm name must be specified, as there is no default.
*
* <p> A Signature object can be used to generate and verify digital
* signatures.
*
* <p> There are three phases to the use of a Signature object for
* either signing data or verifying a signature:<ol>
*
* <li>Initialization, with either
*
*     <ul>
*
*     <li>a public key, which initializes the signature for
*     verification (see {@link #initVerify(PublicKey) initVerify}), or
*
*     <li>a private key (and optionally a Secure Random Number Generator),
*     which initializes the signature for signing
*     (see {@link #initSign(PrivateKey)}
*     and {@link #initSign(PrivateKey, SecureRandom)}).
*
*     </ul><p>
*
* <li>Updating<p>
*
* <p>Depending on the type of initialization, this will update the
* bytes to be signed or verified. See the
* {@link #update(byte) update} methods.<p>
*
* <li>Signing or Verifying a signature on all updated bytes. See the
* {@link #sign() sign} methods and the {@link #verify(byte[]) verify}
* method.
*
* </ol>
*
* <p>Note that this class is abstract and extends from
* <code>SignatureSpi</code> for historical reasons.
* Application developers should only take notice of the methods defined in
* this <code>Signature</code> class; all the methods in
* the superclass are intended for cryptographic service providers who wish to
* supply their own implementations of digital signature algorithms.
*
* @author Benjamin Renaud
*
* @version 1.103, 04/21/06
*/

public abstract class Signature extends SignatureSpi {

    private static final Debug debug =
      Debug.getInstance("jca", "Signature");
   
    /*
     * The algorithm for this signature object.
     * This value is used to map an OID to the particular algorithm.
     * The mapping is done in AlgorithmObject.algOID(String algorithm)
     */
    private String algorithm;

    // The provider
    Provider provider;

    /**
     * Possible {@link #state} value, signifying that      
     * this signature object has not yet been initialized.
     */     
    protected final static int UNINITIALIZED = 0;      
      
    /**
     * Possible {@link #state} value, signifying that      
     * this signature object has been initialized for signing.
     */     
    protected final static int SIGN = 2;
      
    /**
     * Possible {@link #state} value, signifying that      
     * this signature object has been initialized for verification.
     */     
    protected final static int VERIFY = 3;

    /**
     * Current state of this signature object.
     */     
    protected int state = UNINITIALIZED;

    /**
     * Creates a Signature object for the specified algorithm.
     *
     * @param algorithm the standard string name of the algorithm.
     * See Appendix A in the <a href=
     * "../../../technotes/guides/security/crypto/CryptoSpec.html#AppA">
     * Java Cryptography Architecture API Specification &amp; Reference </a>
     * for information about standard algorithm names.
     */
    protected Signature(String algorithm) {
  this.algorithm = algorithm;
    }
   
    // name of the special signature alg
    private final static String RSA_SIGNATURE = "NONEwithRSA";

    // name of the equivalent cipher alg
    private final static String RSA_CIPHER = "RSA/ECB/PKCS1Padding";
   
    // all the services we need to lookup for compatibility with Cipher
    private final static List<ServiceId> rsaIds = Arrays.asList(
  new ServiceId[] {
      new ServiceId("Signature", "NONEwithRSA"),
      new ServiceId("Cipher", "RSA/ECB/PKCS1Padding"),
      new ServiceId("Cipher", "RSA/ECB"),
      new ServiceId("Cipher", "RSA//PKCS1Padding"),
      new ServiceId("Cipher", "RSA"),
  }
    );

    /**
     * Returns a Signature object that implements the specified signature
     * algorithm.
     *
     * <p> This method traverses the list of registered security Providers,
     * starting with the most preferred Provider.
     * A new Signature object encapsulating the
     * SignatureSpi 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 algorithm requested.
     * See Appendix A in the <a href=
     * "../../../technotes/guides/security/crypto/CryptoSpec.html#AppA">
     * Java Cryptography Architecture API Specification &amp; Reference </a>
     * for information about standard algorithm names.
     *
     * @return the new Signature object.
     *
     * @exception NoSuchAlgorithmException if no Provider supports a
     *          Signature implementation for the
     *          specified algorithm.
     *
     * @see Provider
     */
    public static Signature getInstance(String algorithm)
      throws NoSuchAlgorithmException {
  List list;
  if (algorithm.equalsIgnoreCase(RSA_SIGNATURE)) {
      list = GetInstance.getServices(rsaIds);
  } else {
      list = GetInstance.getServices("Signature", algorithm);
  }
  Iterator t = list.iterator();
  if (t.hasNext() == false) {
      throw new NoSuchAlgorithmException
        (algorithm + " Signature not available");
  }
  // try services until we find an Spi or a working Signature subclass
  NoSuchAlgorithmException failure;
  do {
      Service s = (Service)t.next();
      if (isSpi(s)) {
    return new Delegate(s, t, algorithm);
      } else {
    // must be a subclass of Signature, disable dynamic selection
    try {
        Instance instance =
          GetInstance.getInstance(s, SignatureSpi.class);
        return getInstance(instance, algorithm);
    } catch (NoSuchAlgorithmException e) {
        failure = e;
    }
      }
  } while (t.hasNext());
  throw failure;
    }
   
    private static Signature getInstance(Instance instance, String algorithm) {
  Signature sig;
  if (instance.impl instanceof Signature) {
      sig = (Signature)instance.impl;
  } else {
      SignatureSpi spi = (SignatureSpi)instance.impl;
      sig = new Delegate(spi, algorithm);
  }
  sig.provider = instance.provider;
  return sig;
    }
   
    private final static Map<String,Boolean> signatureInfo;
   
    static {
      signatureInfo = new ConcurrentHashMap<String,Boolean>();
  Boolean TRUE = Boolean.TRUE;
  // pre-initialize with values for our SignatureSpi implementations
  signatureInfo.put("sun.security.provider.DSA$RawDSA", TRUE);
  signatureInfo.put("sun.security.provider.DSA$SHA1withDSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$MD2withRSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$MD5withRSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$SHA1withRSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$SHA256withRSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$SHA384withRSA", TRUE);
  signatureInfo.put("sun.security.rsa.RSASignature$SHA512withRSA", TRUE);
  signatureInfo.put("com.sun.net.ssl.internal.ssl.RSASignature", TRUE);
  signatureInfo.put("sun.security.pkcs11.P11Signature", TRUE);
    }
   
    private static boolean isSpi(Service s) {
  if (s.getType().equals("Cipher")) {
      // must be a CipherSpi, which we can wrap with the CipherAdapter
      return true;
  }
  String className = s.getClassName();
  Boolean result = signatureInfo.get(className);
  if (result == null) {
      try {
    Object instance = s.newInstance(null);
    // Signature extends SignatureSpi
    // so it is a "real" Spi if it is an
    // instance of SignatureSpi but not Signature
    boolean r = (instance instanceof SignatureSpi)
        && (instance instanceof Signature == false);
    if ((debug != null) && (r == false)) {
        debug.println("Not a SignatureSpi " + className);
        debug.println("Delayed provider selection may not be "
          + "available for algorithm " + s.getAlgorithm());
    }
    result = Boolean.valueOf(r);
    signatureInfo.put(className, result);
      } catch (Exception e) {
    // something is wrong, assume not an SPI
    return false;
      }
  }
  return result.booleanValue();
    }

    /**
     * Returns a Signature object that implements the specified signature
     * algorithm.
     *
     * <p> A new Signature object encapsulating the
     * SignatureSpi 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 name of the algorithm requested.
     * See Appendix A in the <a href=
     * "../../../technotes/guides/security/crypto/CryptoSpec.html#AppA">
     * Java Cryptography Architecture API Specification &amp; Reference </a>
     * for information about standard algorithm names.
     *
     * @param provider the name of the provider.
     *
     * @return the new Signature object.
     *
     * @exception NoSuchAlgorithmException if a SignatureSpi
     *    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 name is null
     *    or empty.
     *
     * @see Provider
     */
    public static Signature getInstance(String algorithm, String provider)
      throws NoSuchAlgorithmException, NoSuchProviderException {
  if (algorithm.equalsIgnoreCase(RSA_SIGNATURE)) {
      // exception compatibility with existing code
      if ((provider == null) || (provider.length() == 0)) {
    throw new IllegalArgumentException("missing provider");
      }
      Provider p = Security.getProvider(provider);
      if (p == null) {
    throw new NoSuchProviderException
        ("no such provider: " + provider);
      }
      return getInstanceRSA(p);
  }
  Instance instance = GetInstance.getInstance
    ("Signature", SignatureSpi.class, algorithm, provider);
  return getInstance(instance, algorithm);
    }
   
    /**
     * Returns a Signature object that implements the specified
     * signature algorithm.
     *
     * <p> A new Signature object encapsulating the
     * SignatureSpi 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 name of the algorithm requested.
     * See Appendix A in the <a href=
     * "../../../technotes/guides/security/crypto/CryptoSpec.html#AppA">
     * Java Cryptography Architecture API Specification &amp; Reference </a>
     * for information about standard algorithm names.
     *
     * @param provider the provider.
     *
     * @return the new Signature object.
     *
     * @exception NoSuchAlgorithmException if a SignatureSpi
     *    implementation for the specified algorithm is not available
     *    from the specified Provider object.
     *
     * @exception IllegalArgumentException if the provider is null.
     *
     * @see Provider
     *
     * @since 1.4
     */
    public static Signature getInstance(String algorithm, Provider provider)
      throws NoSuchAlgorithmException {
  if (algorithm.equalsIgnoreCase(RSA_SIGNATURE)) {
      // exception compatibility with existing code
      if (provider == null) {
    throw new IllegalArgumentException("missing provider");
      }
      return getInstanceRSA(provider);
  }
  Instance instance = GetInstance.getInstance
    ("Signature", SignatureSpi.class, algorithm, provider);
  return getInstance(instance, algorithm);
    }

    // return an implementation for NONEwithRSA, which is a special case
    // because of the Cipher.RSA/ECB/PKCS1Padding compatibility wrapper
    private static Signature getInstanceRSA(Provider p)
      throws NoSuchAlgorithmException {
  // try Signature first
  Service s = p.getService("Signature", RSA_SIGNATURE);
  if (s != null) {
      Instance instance = GetInstance.getInstance(s, SignatureSpi.class);
      return getInstance(instance, RSA_SIGNATURE);
  }
  // check Cipher
  try {
      Cipher c = Cipher.getInstance(RSA_CIPHER, p);
      return new Delegate(new CipherAdapter(c), RSA_SIGNATURE);
  } catch (GeneralSecurityException e) {
      // throw Signature style exception message to avoid confusion,
      // but append Cipher exception as cause
      throw new NoSuchAlgorithmException("no such algorithm: "
    + RSA_SIGNATURE + " for provider " + p.getName(), e);
  }
    }

    /**
     * Returns the provider of this signature object.
     *
     * @return the provider of this signature object
     */
    public final Provider getProvider() {
  chooseFirstProvider();
  return this.provider;
    }
   
    void chooseFirstProvider() {
  // empty, overridden in Delegate
    }

    /**
     * Initializes this object for verification. If this method is called
     * again with a different argument, it negates the effect
     * of this call.
     *
     * @param publicKey the public key of the identity whose signature is
     * going to be verified.
     *
     * @exception InvalidKeyException if the key is invalid.
     */
    public final void initVerify(PublicKey publicKey)
      throws InvalidKeyException {
  engineInitVerify(publicKey);
  state = VERIFY;
    }

    /**
     * Initializes this object for verification, using the public key from
     * the given certificate.
     * <p>If the certificate is of type X.509 and has a <i>key usage</i>
     * extension field marked as critical, and the value of the <i>key usage</i>
     * extension field implies that the public key in
     * the certificate and its corresponding private key are not
     * supposed to be used for digital signatures, an
     * <code>InvalidKeyException</code> is thrown.
     *
     * @param certificate the certificate of the identity whose signature is
     * going to be verified.
     *
     * @exception InvalidKeyException  if the public key in the certificate
     * is not encoded properly or does not include required  parameter
     * information or cannot be used for digital signature purposes.
     * @since 1.3
     */
    public final void initVerify(Certificate certificate)
      throws InvalidKeyException {
  // If the certificate is of type X509Certificate,
  // we should check whether it has a Key Usage
  // extension marked as critical.
  if (certificate instanceof java.security.cert.X509Certificate) {
      // Check whether the cert has a key usage extension
      // marked as a critical extension.
      // The OID for KeyUsage extension is 2.5.29.15.
      X509Certificate cert = (X509Certificate)certificate;
      Set critSet = cert.getCriticalExtensionOIDs();

      if (critSet != null && !critSet.isEmpty()
    && critSet.contains("2.5.29.15")) {
    boolean[] keyUsageInfo = cert.getKeyUsage();
    // keyUsageInfo[0] is for digitalSignature.
    if ((keyUsageInfo != null) && (keyUsageInfo[0] == false))
        throw new InvalidKeyException("Wrong key usage");
      }
  }
     
  PublicKey publicKey = certificate.getPublicKey();
  engineInitVerify(publicKey);
  state = VERIFY;
    }

    /**
     * Initialize this object for signing. If this method is called
     * again with a different argument, it negates the effect
     * of this call.
     *
     * @param privateKey the private key of the identity whose signature
     * is going to be generated.
     *
     * @exception InvalidKeyException if the key is invalid. 
     */
    public final void initSign(PrivateKey privateKey)
      throws InvalidKeyException {
  engineInitSign(privateKey);
  state = SIGN;
    }

    /**
     * Initialize this object for signing. If this method is called
     * again with a different argument, it negates the effect
     * of this call.
     *
     * @param privateKey the private key of the identity whose signature
     * is going to be generated.
     *
     * @param random the source of randomness for this signature.
     *
     * @exception InvalidKeyException if the key is invalid. 
     */
    public final void initSign(PrivateKey privateKey, SecureRandom random)
      throws InvalidKeyException {
  engineInitSign(privateKey, random);
  state = SIGN;
    }

    /**
     * Returns the signature bytes of all the data updated.
     * The format of the signature depends on the underlying
     * signature scheme.
     *
     * <p>A call to this method resets this signature object to the state
     * it was in when previously initialized for signing via a
     * call to <code>initSign(PrivateKey)</code>. That is, the object is
     * reset and available to generate another signature from the same
     * signer, if desired, via new calls to <code>update</code> and
     * <code>sign</code>.    
     *
     * @return the signature bytes of the signing operation's result.
     *
     * @exception SignatureException if this signature object is not
     * initialized properly or if this signature algorithm is unable to
     * process the input data provided.
     */
    public final byte[] sign() throws SignatureException {
  if (state == SIGN) {
      return engineSign();
  }
  throw new SignatureException("object not initialized for " +
             "signing");
    }

    /**
     * Finishes the signature operation and stores the resulting signature
     * bytes in the provided buffer <code>outbuf</code>, starting at
     * <code>offset</code>.
     * The format of the signature depends on the underlying
     * signature scheme.
     *
     * <p>This signature object is reset to its initial state (the state it
     * was in after a call to one of the <code>initSign</code> methods) and
     * can be reused to generate further signatures with the same private key.
     *
     * @param outbuf buffer for the signature result.
     *
     * @param offset offset into <code>outbuf</code> where the signature is
     * stored.
     *
     * @param len number of bytes within <code>outbuf</code> allotted for the
     * signature.
     *
     * @return the number of bytes placed into <code>outbuf</code>.
     *
     * @exception SignatureException if this signature object is not
     * initialized properly, if this signature algorithm is unable to
     * process the input data provided, or if <code>len</code> is less
     * than the actual signature length.
     *
     * @since 1.2
     */
    public final int sign(byte[] outbuf, int offset, int len)
  throws SignatureException {
  if (outbuf == null) {
      throw new IllegalArgumentException("No output buffer given");
  }
  if (outbuf.length - offset < len) {
      throw new IllegalArgumentException
    ("Output buffer too small for specified offset and length");
  }
  if (state != SIGN) {
      throw new SignatureException("object not initialized for " +
           "signing");
  }
  return engineSign(outbuf, offset, len);
    }

    /**
     * Verifies the passed-in signature.
     *
     * <p>A call to this method resets this signature object to the state
     * it was in when previously initialized for verification via a
     * call to <code>initVerify(PublicKey)</code>. That is, the object is
     * reset and available to verify another signature from the identity
     * whose public key was specified in the call to <code>initVerify</code>.
     *     
     * @param signature the signature bytes to be verified.
     *
     * @return true if the signature was verified, false if not.
     *
     * @exception SignatureException if this signature object is not
     * initialized properly, the passed-in signature is improperly
     * encoded or of the wrong type, if this signature algorithm is unable to
     * process the input data provided, etc.
     */
    public final boolean verify(byte[] signature) throws SignatureException {
  if (state == VERIFY) {
      return engineVerify(signature);
  }
  throw new SignatureException("object not initialized for " +
             "verification");
    }

    /**
     * Verifies the passed-in signature in the specified array
     * of bytes, starting at the specified offset.
     *
     * <p>A call to this method resets this signature object to the state
     * it was in when previously initialized for verification via a
     * call to <code>initVerify(PublicKey)</code>. That is, the object is
     * reset and available to verify another signature from the identity
     * whose public key was specified in the call to <code>initVerify</code>.
     *
     *     
     * @param signature the signature bytes to be verified.
     * @param offset the offset to start from in the array of bytes.
     * @param length the number of bytes to use, starting at offset.
     *
     * @return true if the signature was verified, false if not.
     *
     * @exception SignatureException if this signature object is not
     * initialized properly, the passed-in signature is improperly
     * encoded or of the wrong type, if this signature algorithm is unable to
     * process the input data provided, etc.
     * @exception IllegalArgumentException if the <code>signature</code>
     * byte array is null, or the <code>offset</code> or <code>length</code>
     * is less than 0, or the sum of the <code>offset</code> and
     * <code>length</code> is greater than the length of the
     * <code>signature</code> byte array.
     * @since 1.4
     */
    public final boolean verify(byte[] signature, int offset, int length)
  throws SignatureException {
  if (state == VERIFY) {
      if ((signature == null) || (offset < 0) || (length < 0) ||
    (offset + length > signature.length)) {
    throw new IllegalArgumentException("Bad arguments");
      }

      return engineVerify(signature, offset, length);
  }
  throw new SignatureException("object not initialized for " +
             "verification");
    }

    /**
     * Updates the data to be signed or verified by a byte.
     *
     * @param b the byte to use for the update.
     *
     * @exception SignatureException if this signature object is not
     * initialized properly.    
     */
    public final void update(byte b) throws SignatureException {
  if (state == VERIFY || state == SIGN) {
      engineUpdate(b);
  } else {
      throw new SignatureException("object not initialized for "
           + "signature or verification");
  }
    }

    /**
     * Updates the data to be signed or verified, using the specified
     * array of bytes.
     *
     * @param data the byte array to use for the update.      
     *
     * @exception SignatureException if this signature object is not
     * initialized properly.         
     */
    public final void update(byte[] data) throws SignatureException {
  update(data, 0, data.length);
    }

    /**
     * Updates the data to be signed or verified, using the specified
     * array of bytes, starting at the specified offset. 
     *
     * @param data the array of bytes. 
     * @param off the offset to start from in the array of bytes. 
     * @param len the number of bytes to use, starting at offset.
     * 
     * @exception SignatureException if this signature object is not
     * initialized properly.         
     */
    public final void update(byte[] data, int off, int len)
      throws SignatureException {
  if (state == SIGN || state == VERIFY) {
      engineUpdate(data, off, len);
  } else {
      throw new SignatureException("object not initialized for "
           + "signature or verification");
  }
    }

    /**
     * Updates the data to be signed or verified using the specified
     * ByteBuffer. Processes the <code>data.remaining()</code> bytes
     * starting at at <code>data.position()</code>.
     * Upon return, the buffer's position will be equal to its limit;
     * its limit will not have changed.
     *
     * @param data the ByteBuffer
     *
     * @exception SignatureException if this signature object is not
     * initialized properly.
     * @since 1.5
     */
    public final void update(ByteBuffer data) throws SignatureException {
  if ((state != SIGN) && (state != VERIFY)) {
      throw new SignatureException("object not initialized for "
           + "signature or verification");
  }
  if (data == null) {
      throw new NullPointerException();
  }
  engineUpdate(data);
    }

    /**
     * Returns the name of the algorithm for this signature object.
     *
     * @return the name of the algorithm for this signature object.
     */
    public final String getAlgorithm() {
  return this.algorithm;
    }

    /**
     * Returns a string representation of this signature object,      
     * providing information that includes the state of the object      
     * and the name of the algorithm used.      
     *
     * @return a string representation of this signature object.
     */
    public String toString() {
  String initState = "";
  switch (state) {
  case UNINITIALIZED:
      initState = "<not initialized>";
      break;
  case VERIFY:
      initState = "<initialized for verifying>";
      break;       
  case SIGN:
      initState = "<initialized for signing>";
      break;       
  }
  return "Signature object: " + getAlgorithm() + initState;
    }

    /**
     * Sets the specified algorithm parameter to the specified value.
     * This method supplies a general-purpose mechanism through
     * which it is possible to set the various parameters of this object.
     * A parameter may be any settable parameter for the algorithm, such as
     * a parameter size, or a source of random bits for signature generation
     * (if appropriate), or an indication of whether or not to perform
     * a specific but optional computation. A uniform algorithm-specific
     * naming scheme for each parameter is desirable but left unspecified
     * at this time.
     *
     * @param param the string identifier of the parameter.
     * @param value the parameter value.
     *
     * @exception InvalidParameterException if <code>param</code> is an
     * invalid parameter for this signature algorithm engine,
     * the parameter is already set
     * and cannot be set again, a security exception occurs, and so on.
     *
     * @see #getParameter
     *
     * @deprecated Use
     * {@link #setParameter(java.security.spec.AlgorithmParameterSpec)
     * setParameter}.
     */
    @Deprecated
    public final void setParameter(String param, Object value)
      throws InvalidParameterException {
  engineSetParameter(param, value);
    }

    /**
     * Initializes this signature engine with the specified parameter set.
     *
     * @param params the parameters
     *
     * @exception InvalidAlgorithmParameterException if the given parameters
     * are inappropriate for this signature engine
     *
     * @see #getParameters
     */
    public final void setParameter(AlgorithmParameterSpec params)
      throws InvalidAlgorithmParameterException {
  engineSetParameter(params);
    }

    /**
     * Returns the parameters used with this signature object.
     *
     * <p>The returned parameters may be the same that were used to initialize
     * this signature, or may contain a combination of default and randomly
     * generated parameter values used by the underlying signature
     * implementation if this signature requires algorithm parameters but
     * was not initialized with any.
     *
     * @return the parameters used with this signature, or null if this
     * signature does not use any parameters.
     *
     * @see #setParameter(AlgorithmParameterSpec)
     * @since 1.4
     */
    public final AlgorithmParameters getParameters() {
  return engineGetParameters();
    }   

    /**
     * Gets the value of the specified algorithm parameter. This method
     * supplies a general-purpose mechanism through which it is possible to
     * get the various parameters of this object. A parameter may be any
     * settable parameter for the algorithm, such as a parameter size, or
     * a source of random bits for signature generation (if appropriate),
     * or an indication of whether or not to perform a specific but optional
     * computation. A uniform algorithm-specific naming scheme for each
     * parameter is desirable but left unspecified at this time.
     *
     * @param param the string name of the parameter.
     *
     * @return the object that represents the parameter value, or null if
     * there is none.
     *
     * @exception InvalidParameterException if <code>param</code> is an invalid
     * parameter for this engine, or another exception occurs while
     * trying to get this parameter.
     *
     * @see #setParameter(String, Object)
     *
     * @deprecated
     */
    @Deprecated
    public final Object getParameter(String param)
      throws InvalidParameterException {
  return engineGetParameter(param);
    }

    /**
     * Returns a clone if the implementation is cloneable.
     *
     * @return a clone if the implementation is cloneable.
     *
     * @exception CloneNotSupportedException if this is called
     * on an implementation that does not support <code>Cloneable</code>.
     */
    public Object clone() throws CloneNotSupportedException {
  if (this instanceof Cloneable) {
      return super.clone();
  } else {
      throw new CloneNotSupportedException();
  }
    }
   
    /*
     * The following class allows providers to extend from SignatureSpi
     * rather than from Signature. It represents a Signature with an
     * encapsulated, provider-supplied SPI object (of type SignatureSpi).
     * If the provider implementation is an instance of SignatureSpi, the
     * getInstance() methods above return an instance of this class, with
     * the SPI object encapsulated.
     *
     * Note: All SPI methods from the original Signature class have been
     * moved up the hierarchy into a new class (SignatureSpi), which has
     * been interposed in the hierarchy between the API (Signature)
     * and its original parent (Object).
     */

    private static class Delegate extends Signature {

  // The provider implementation (delegate)
  // filled in once the provider is selected
  private SignatureSpi sigSpi;
 
  // lock for mutex during provider selection
  private final Object lock;

  // 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 serviceIterator;
 
  // constructor
  Delegate(SignatureSpi sigSpi, String algorithm) {
      super(algorithm);
      this.sigSpi = sigSpi;
      this.lock = null; // no lock needed
  }
 
  // used with delayed provider selection
  Delegate(Service service, Iterator iterator, String algorithm) {
      super(algorithm);
      this.firstService = service;
      this.serviceIterator = iterator;
      this.lock = new Object();
  }
 
  /**
   * Returns a clone if the delegate is cloneable.   
   *
   * @return a clone if the delegate is cloneable.
   *
   * @exception CloneNotSupportedException if this is called on a
   * delegate that does not support <code>Cloneable</code>.
   */
  public Object clone() throws CloneNotSupportedException {
      chooseFirstProvider();
      if (sigSpi instanceof Cloneable) {
    SignatureSpi sigSpiClone = (SignatureSpi)sigSpi.clone();
    // Because 'algorithm' and 'provider' are private
    // members of our supertype, we must perform a cast to
    // access them.
    Signature that =
        new Delegate(sigSpiClone, ((Signature)this).algorithm);
    that.provider = ((Signature)this).provider;
    return that;
      } else {
    throw new CloneNotSupportedException();
      }
  }
 
  private static SignatureSpi newInstance(Service s)
    throws NoSuchAlgorithmException {
      if (s.getType().equals("Cipher")) {
    // must be NONEwithRSA
    try {
        Cipher c = Cipher.getInstance(RSA_CIPHER, s.getProvider());
        return new CipherAdapter(c);
    } catch (NoSuchPaddingException e) {
        throw new NoSuchAlgorithmException(e);
    }
      } else {
    Object o = s.newInstance(null);
    if (o instanceof SignatureSpi == false) {
        throw new NoSuchAlgorithmException
      ("Not a SignatureSpi: " + o.getClass().getName());
    }
    return (SignatureSpi)o;
      }
  }

  // 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 initSign()/
   * initVerify() is not the first method called.
   */
  void chooseFirstProvider() {
      if (sigSpi != null) {
    return;
      }
      synchronized (lock) {
    if (sigSpi != null) {
        return;
    }
    if (debug != null) {
        int w = --warnCount;
        if (w >= 0) {
      debug.println("Signature.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 = (Service)serviceIterator.next();
        }
        if (isSpi(s) == false) {
      continue;
        }
        try {
      sigSpi = newInstance(s);
      provider = s.getProvider();
      // not needed any more
      firstService = null;
      serviceIterator = null;
      return;
        } catch (NoSuchAlgorithmException e) {
      lastException = e;
        }
    }
    ProviderException e = new ProviderException
      ("Could not construct SignatureSpi instance");
    if (lastException != null) {
        e.initCause(lastException);
    }
    throw e;
      }
  }
 
  private void chooseProvider(int type, Key key, SecureRandom random)
    throws InvalidKeyException {
      synchronized (lock) {
    if (sigSpi != null) {
        init(sigSpi, type, key, random);
        return;
    }
    Exception lastException = null;
    while ((firstService != null) || serviceIterator.hasNext()) {
        Service s;
        if (firstService != null) {
      s = firstService;
      firstService = null;
        } else {
      s = (Service)serviceIterator.next();
        }
        // if provider says it does not support this key, ignore it
        if (s.supportsParameter(key) == false) {
      continue;
        }
        // if instance is not a SignatureSpi, ignore it
        if (isSpi(s) == false) {
      continue;
        }
        try {
      SignatureSpi spi = newInstance(s);
      init(spi, type, key, random);
      provider = s.getProvider();
      sigSpi = 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 RuntimeException) {
        throw (RuntimeException)lastException;
    }
    String k = (key != null) ? key.getClass().getName() : "(null)";
    throw new InvalidKeyException
        ("No installed provider supports this key: "
        + k, lastException);
      }
  }

  private final static int I_PUB     = 1;
  private final static int I_PRIV    = 2;
  private final static int I_PRIV_SR = 3;
 
  private void init(SignatureSpi spi, int type, Key  key,
    SecureRandom random) throws InvalidKeyException {
      switch (type) {
      case I_PUB:
    spi.engineInitVerify((PublicKey)key);
    break;
      case I_PRIV:
    spi.engineInitSign((PrivateKey)key);
    break;
      case I_PRIV_SR:
    spi.engineInitSign((PrivateKey)key, random);
    break;
      default:
    throw new AssertionError("Internal error: " + type);
      }
  }
 
  protected void engineInitVerify(PublicKey publicKey)
        throws InvalidKeyException {
      if (sigSpi != null) {
    sigSpi.engineInitVerify(publicKey);
      } else {
    chooseProvider(I_PUB, publicKey, null);
      }
  }
 
  protected void engineInitSign(PrivateKey privateKey)
        throws InvalidKeyException {
      if (sigSpi != null) {
    sigSpi.engineInitSign(privateKey);
      } else {
    chooseProvider(I_PRIV, privateKey, null);
      }
  }

        protected void engineInitSign(PrivateKey privateKey, SecureRandom sr)
              throws InvalidKeyException {
      if (sigSpi != null) {
    sigSpi.engineInitSign(privateKey, sr);
      } else {
    chooseProvider(I_PRIV_SR, privateKey, sr);
      }
        }

  protected void engineUpdate(byte b) throws SignatureException {
      chooseFirstProvider();
      sigSpi.engineUpdate(b);
  }

  protected void engineUpdate(byte[] b, int off, int len)
        throws SignatureException {
      chooseFirstProvider();
      sigSpi.engineUpdate(b, off, len);
  }
 
  protected void engineUpdate(ByteBuffer data) {
      chooseFirstProvider();
      sigSpi.engineUpdate(data);
  }

  protected byte[] engineSign() throws SignatureException {
      chooseFirstProvider();
      return sigSpi.engineSign();
  }

  protected int engineSign(byte[] outbuf, int offset, int len)
        throws SignatureException {
      chooseFirstProvider();
      return sigSpi.engineSign(outbuf, offset, len);
  }

  protected boolean engineVerify(byte[] sigBytes)
        throws SignatureException {
      chooseFirstProvider();
      return sigSpi.engineVerify(sigBytes);
  }

  protected boolean engineVerify(byte[] sigBytes, int offset, int length)
        throws SignatureException {
      chooseFirstProvider();
      return sigSpi.engineVerify(sigBytes, offset, length);
  }

  protected void engineSetParameter(String param, Object value)
        throws InvalidParameterException {
      chooseFirstProvider();
      sigSpi.engineSetParameter(param, value);
  }

  protected void engineSetParameter(AlgorithmParameterSpec params)
        throws InvalidAlgorithmParameterException {
      chooseFirstProvider();
      sigSpi.engineSetParameter(params);
  }

  protected Object engineGetParameter(String param)
    throws InvalidParameterException {
      chooseFirstProvider();
      return sigSpi.engineGetParameter(param);
  }

  protected AlgorithmParameters engineGetParameters() {
      chooseFirstProvider();
      return sigSpi.engineGetParameters();
  }
    }

    // adapter for RSA/ECB/PKCS1Padding ciphers
    private static class CipherAdapter extends SignatureSpi {
 
  private final Cipher cipher;
 
  private ByteArrayOutputStream data;
 
  CipherAdapter(Cipher cipher) {
      this.cipher = cipher;
  }
 
  protected void engineInitVerify(PublicKey publicKey)
    throws InvalidKeyException {
      cipher.init(Cipher.DECRYPT_MODE, publicKey);
      if (data == null) {
    data = new ByteArrayOutputStream(128);
      } else {
    data.reset();
      }
  }

  protected void engineInitSign(PrivateKey privateKey)
    throws InvalidKeyException {
      cipher.init(Cipher.ENCRYPT_MODE, privateKey);
      data = null;
  }
 
  protected void engineInitSign(PrivateKey privateKey,
    SecureRandom random) throws InvalidKeyException {
      cipher.init(Cipher.ENCRYPT_MODE, privateKey, random);
      data = null;
  }

  protected void engineUpdate(byte b) throws SignatureException {
      engineUpdate(new byte[] {b}, 0, 1);
  }

  protected void engineUpdate(byte[] b, int off, int len)
    throws SignatureException {
      if (data != null) {
    data.write(b, off, len);
    return;
      }
      byte[] out = cipher.update(b, off, len);
      if ((out != null) && (out.length != 0)) {
    throw new SignatureException
        ("Cipher unexpectedly returned data");
      }
  }
 
  protected byte[] engineSign() throws SignatureException {
      try {
    return cipher.doFinal();
      } catch (IllegalBlockSizeException e) {
    throw new SignatureException("doFinal() failed", e);
      } catch (BadPaddingException e) {
    throw new SignatureException("doFinal() failed", e);
      }
  }

  protected boolean engineVerify(byte[] sigBytes)
    throws SignatureException {
      try {
    byte[] out = cipher.doFinal(sigBytes);
    byte[] dataBytes = data.toByteArray();
    data.reset();
    return Arrays.equals(out, dataBytes);
      } catch (BadPaddingException e) {
    // e.g. wrong public key used
    // return false rather than throwing exception
    return false;
      } catch (IllegalBlockSizeException e) {
    throw new SignatureException("doFinal() failed", e);
      }
  }

  protected void engineSetParameter(String param, Object value)
    throws InvalidParameterException {
      throw new InvalidParameterException("Parameters not supported");
  }

  protected Object engineGetParameter(String param)
    throws InvalidParameterException {
      throw new InvalidParameterException("Parameters not supported");
  }
 
    }

}
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