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package sun.security.tools.keytool;

import java.io.IOException;
import java.security.cert.X509Certificate;
import java.security.cert.CertificateException;
import java.security.cert.CertificateEncodingException;
import java.security.*;
import java.util.Date;

import sun.security.pkcs10.PKCS10;
import sun.security.x509.AlgorithmId;
import sun.security.x509.CertificateAlgorithmId;
import sun.security.x509.CertificateExtensions;
import sun.security.x509.CertificateIssuerName;
import sun.security.x509.CertificateSerialNumber;
import sun.security.x509.CertificateSubjectName;
import sun.security.x509.CertificateValidity;
import sun.security.x509.CertificateVersion;
import sun.security.x509.CertificateX509Key;
import sun.security.x509.KeyIdentifier;
import sun.security.x509.SubjectKeyIdentifierExtension;
import sun.security.x509.X500Name;
import sun.security.x509.X500Signer;
import sun.security.x509.X509Cert;
import sun.security.x509.X509CertImpl;
import sun.security.x509.X509CertInfo;
import sun.security.x509.X509Key;


Generate a pair of keys, and provide access to them. This class is provided primarily for ease of use.

This provides some simple certificate management functionality. Specifically, it allows you to create self-signed X.509 certificates as well as PKCS 10 based certificate signing requests.

Keys for some public key signature algorithms have algorithm parameters, such as DSS/DSA. Some sites' Certificate Authorities adopt fixed algorithm parameters, which speeds up some operations including key generation and signing. At this time, this interface does not provide a way to provide such algorithm parameters, e.g. by providing the CA certificate which includes those parameters.

Also, note that at this time only signature-capable keys may be acquired through this interface. Diffie-Hellman keys, used for secure key exchange, may be supported later.

Author:David Brownell, Hemma Prafullchandra
See Also:
/** * Generate a pair of keys, and provide access to them. This class is * provided primarily for ease of use. * * <P>This provides some simple certificate management functionality. * Specifically, it allows you to create self-signed X.509 certificates * as well as PKCS 10 based certificate signing requests. * * <P>Keys for some public key signature algorithms have algorithm * parameters, such as DSS/DSA. Some sites' Certificate Authorities * adopt fixed algorithm parameters, which speeds up some operations * including key generation and signing. <em>At this time, this interface * does not provide a way to provide such algorithm parameters, e.g. * by providing the CA certificate which includes those parameters.</em> * * <P>Also, note that at this time only signature-capable keys may be * acquired through this interface. Diffie-Hellman keys, used for secure * key exchange, may be supported later. * * @author David Brownell * @author Hemma Prafullchandra * @see PKCS10 * @see X509CertImpl */
public final class CertAndKeyGen {
Creates a CertAndKeyGen object for a particular key type and signature algorithm.
Params:
  • keyType – type of key, e.g. "RSA", "DSA"
  • sigAlg – name of the signature algorithm, e.g. "MD5WithRSA", "MD2WithRSA", "SHAwithDSA".
Throws:
/** * Creates a CertAndKeyGen object for a particular key type * and signature algorithm. * * @param keyType type of key, e.g. "RSA", "DSA" * @param sigAlg name of the signature algorithm, e.g. "MD5WithRSA", * "MD2WithRSA", "SHAwithDSA". * @exception NoSuchAlgorithmException on unrecognized algorithms. */
public CertAndKeyGen (String keyType, String sigAlg) throws NoSuchAlgorithmException { keyGen = KeyPairGenerator.getInstance(keyType); this.sigAlg = sigAlg; }
Creates a CertAndKeyGen object for a particular key type, signature algorithm, and provider.
Params:
  • keyType – type of key, e.g. "RSA", "DSA"
  • sigAlg – name of the signature algorithm, e.g. "MD5WithRSA", "MD2WithRSA", "SHAwithDSA".
  • providerName – name of the provider
Throws:
/** * Creates a CertAndKeyGen object for a particular key type, * signature algorithm, and provider. * * @param keyType type of key, e.g. "RSA", "DSA" * @param sigAlg name of the signature algorithm, e.g. "MD5WithRSA", * "MD2WithRSA", "SHAwithDSA". * @param providerName name of the provider * @exception NoSuchAlgorithmException on unrecognized algorithms. * @exception NoSuchProviderException on unrecognized providers. */
public CertAndKeyGen (String keyType, String sigAlg, String providerName) throws NoSuchAlgorithmException, NoSuchProviderException { if (providerName == null) { keyGen = KeyPairGenerator.getInstance(keyType); } else { try { keyGen = KeyPairGenerator.getInstance(keyType, providerName); } catch (Exception e) { // try first available provider instead keyGen = KeyPairGenerator.getInstance(keyType); } } this.sigAlg = sigAlg; }
Sets the source of random numbers used when generating keys. If you do not provide one, a system default facility is used. You may wish to provide your own source of random numbers to get a reproducible sequence of keys and signatures, or because you may be able to take advantage of strong sources of randomness/entropy in your environment.
/** * Sets the source of random numbers used when generating keys. * If you do not provide one, a system default facility is used. * You may wish to provide your own source of random numbers * to get a reproducible sequence of keys and signatures, or * because you may be able to take advantage of strong sources * of randomness/entropy in your environment. */
public void setRandom (SecureRandom generator) { prng = generator; } // want "public void generate (X509Certificate)" ... inherit DSA/D-H param
Generates a random public/private key pair, with a given key size. Different algorithms provide different degrees of security for the same key size, because of the "work factor" involved in brute force attacks. As computers become faster, it becomes easier to perform such attacks. Small keys are to be avoided.

Note that not all values of "keyBits" are valid for all algorithms, and not all public key algorithms are currently supported for use in X.509 certificates. If the algorithm you specified does not produce X.509 compatible keys, an invalid key exception is thrown.

Params:
  • keyBits – the number of bits in the keys.
Throws:
  • InvalidKeyException – if the environment does not provide X.509 public keys for this signature algorithm.
/** * Generates a random public/private key pair, with a given key * size. Different algorithms provide different degrees of security * for the same key size, because of the "work factor" involved in * brute force attacks. As computers become faster, it becomes * easier to perform such attacks. Small keys are to be avoided. * * <P>Note that not all values of "keyBits" are valid for all * algorithms, and not all public key algorithms are currently * supported for use in X.509 certificates. If the algorithm * you specified does not produce X.509 compatible keys, an * invalid key exception is thrown. * * @param keyBits the number of bits in the keys. * @exception InvalidKeyException if the environment does not * provide X.509 public keys for this signature algorithm. */
public void generate (int keyBits) throws InvalidKeyException { KeyPair pair; try { if (prng == null) { prng = new SecureRandom(); } keyGen.initialize(keyBits, prng); pair = keyGen.generateKeyPair(); } catch (Exception e) { throw new IllegalArgumentException(e.getMessage()); } publicKey = pair.getPublic(); privateKey = pair.getPrivate(); }
Returns the public key of the generated key pair if it is of type X509Key, or null if the public key is of a different type. XXX Note: This behaviour is needed for backwards compatibility. What this method really should return is the public key of the generated key pair, regardless of whether or not it is an instance of X509Key. Accordingly, the return type of this method should be PublicKey.
/** * Returns the public key of the generated key pair if it is of type * <code>X509Key</code>, or null if the public key is of a different type. * * XXX Note: This behaviour is needed for backwards compatibility. * What this method really should return is the public key of the * generated key pair, regardless of whether or not it is an instance of * <code>X509Key</code>. Accordingly, the return type of this method * should be <code>PublicKey</code>. */
public X509Key getPublicKey() { if (!(publicKey instanceof X509Key)) { return null; } return (X509Key)publicKey; }
Returns the private key of the generated key pair.

Be extremely careful when handling private keys. When private keys are not kept secret, they lose their ability to securely authenticate specific entities ... that is a huge security risk!

/** * Returns the private key of the generated key pair. * * <P><STRONG><em>Be extremely careful when handling private keys. * When private keys are not kept secret, they lose their ability * to securely authenticate specific entities ... that is a huge * security risk!</em></STRONG> */
public PrivateKey getPrivateKey () { return privateKey; }
Returns a self-signed X.509v1 certificate for the public key. The certificate is immediately valid.

Such certificates normally are used to identify a "Certificate Authority" (CA). Accordingly, they will not always be accepted by other parties. However, such certificates are also useful when you are bootstrapping your security infrastructure, or deploying system prototypes.

Params:
  • myname – X.500 name of the subject (who is also the issuer)
  • validity – how long the certificate should be valid, in seconds
Deprecated:Use the new
/** * Returns a self-signed X.509v1 certificate for the public key. * The certificate is immediately valid. * * <P>Such certificates normally are used to identify a "Certificate * Authority" (CA). Accordingly, they will not always be accepted by * other parties. However, such certificates are also useful when * you are bootstrapping your security infrastructure, or deploying * system prototypes. * * @deprecated Use the new <a href = * "#getSelfCertificate(sun.security.x509.X500Name, long)"> * * @param myname X.500 name of the subject (who is also the issuer) * @param validity how long the certificate should be valid, in seconds */
@Deprecated public X509Cert getSelfCert (X500Name myname, long validity) throws InvalidKeyException, SignatureException, NoSuchAlgorithmException { X509Certificate cert; try { cert = getSelfCertificate(myname, validity); return new X509Cert(cert.getEncoded()); } catch (CertificateException e) { throw new SignatureException(e.getMessage()); } catch (NoSuchProviderException e) { throw new NoSuchAlgorithmException(e.getMessage()); } catch (IOException e) { throw new SignatureException(e.getMessage()); } }
Returns a self-signed X.509v3 certificate for the public key. The certificate is immediately valid. No extensions.

Such certificates normally are used to identify a "Certificate Authority" (CA). Accordingly, they will not always be accepted by other parties. However, such certificates are also useful when you are bootstrapping your security infrastructure, or deploying system prototypes.

Params:
  • myname – X.500 name of the subject (who is also the issuer)
  • firstDate – the issue time of the certificate
  • validity – how long the certificate should be valid, in seconds
Throws:
/** * Returns a self-signed X.509v3 certificate for the public key. * The certificate is immediately valid. No extensions. * * <P>Such certificates normally are used to identify a "Certificate * Authority" (CA). Accordingly, they will not always be accepted by * other parties. However, such certificates are also useful when * you are bootstrapping your security infrastructure, or deploying * system prototypes. * * @param myname X.500 name of the subject (who is also the issuer) * @param firstDate the issue time of the certificate * @param validity how long the certificate should be valid, in seconds * @exception CertificateException on certificate handling errors. * @exception InvalidKeyException on key handling errors. * @exception SignatureException on signature handling errors. * @exception NoSuchAlgorithmException on unrecognized algorithms. * @exception NoSuchProviderException on unrecognized providers. */
public X509Certificate getSelfCertificate ( X500Name myname, Date firstDate, long validity) throws CertificateException, InvalidKeyException, SignatureException, NoSuchAlgorithmException, NoSuchProviderException { X500Signer issuer; X509CertImpl cert; Date lastDate; try { issuer = getSigner (myname); lastDate = new Date (); lastDate.setTime (firstDate.getTime () + validity * 1000); CertificateValidity interval = new CertificateValidity(firstDate,lastDate); X509CertInfo info = new X509CertInfo(); // Add all mandatory attributes info.set(X509CertInfo.VERSION, new CertificateVersion(CertificateVersion.V3)); info.set(X509CertInfo.SERIAL_NUMBER, new CertificateSerialNumber((int)(firstDate.getTime()/1000))); AlgorithmId algID = issuer.getAlgorithmId(); info.set(X509CertInfo.ALGORITHM_ID, new CertificateAlgorithmId(algID)); info.set(X509CertInfo.SUBJECT, new CertificateSubjectName(myname)); info.set(X509CertInfo.KEY, new CertificateX509Key(publicKey)); info.set(X509CertInfo.VALIDITY, interval); info.set(X509CertInfo.ISSUER, new CertificateIssuerName(issuer.getSigner())); if (System.getProperty("sun.security.internal.keytool.skid") != null) { CertificateExtensions ext = new CertificateExtensions(); ext.set(SubjectKeyIdentifierExtension.NAME, new SubjectKeyIdentifierExtension( new KeyIdentifier(publicKey).getIdentifier())); info.set(X509CertInfo.EXTENSIONS, ext); } cert = new X509CertImpl(info); cert.sign(privateKey, this.sigAlg); return (X509Certificate)cert; } catch (IOException e) { throw new CertificateEncodingException("getSelfCert: " + e.getMessage()); } } // Keep the old method public X509Certificate getSelfCertificate (X500Name myname, long validity) throws CertificateException, InvalidKeyException, SignatureException, NoSuchAlgorithmException, NoSuchProviderException { return getSelfCertificate(myname, new Date(), validity); }
Returns a PKCS #10 certificate request. The caller uses either PKCS10.print or PKCS10.toByteArray operations on the result, to get the request in an appropriate transmission format.

PKCS #10 certificate requests are sent, along with some proof of identity, to Certificate Authorities (CAs) which then issue X.509 public key certificates.

Params:
  • myname – X.500 name of the subject
Throws:
/** * Returns a PKCS #10 certificate request. The caller uses either * <code>PKCS10.print</code> or <code>PKCS10.toByteArray</code> * operations on the result, to get the request in an appropriate * transmission format. * * <P>PKCS #10 certificate requests are sent, along with some proof * of identity, to Certificate Authorities (CAs) which then issue * X.509 public key certificates. * * @param myname X.500 name of the subject * @exception InvalidKeyException on key handling errors. * @exception SignatureException on signature handling errors. */
public PKCS10 getCertRequest (X500Name myname) throws InvalidKeyException, SignatureException { PKCS10 req = new PKCS10 (publicKey); try { req.encodeAndSign (getSigner (myname)); } catch (CertificateException e) { throw new SignatureException (sigAlg + " CertificateException"); } catch (IOException e) { throw new SignatureException (sigAlg + " IOException"); } catch (NoSuchAlgorithmException e) { // "can't happen" throw new SignatureException (sigAlg + " unavailable?"); } return req; } private X500Signer getSigner (X500Name me) throws InvalidKeyException, NoSuchAlgorithmException { Signature signature = Signature.getInstance(sigAlg); // XXX should have a way to pass prng to the signature // algorithm ... appropriate for DSS/DSA, not RSA signature.initSign (privateKey); return new X500Signer (signature, me); } private SecureRandom prng; private String sigAlg; private KeyPairGenerator keyGen; private PublicKey publicKey; private PrivateKey privateKey; }