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*
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
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package sun.security.ssl;
import java.util.*;
import java.math.BigInteger;
import java.security.*;
import java.security.interfaces.RSAPublicKey;
import java.security.spec.*;
import javax.crypto.*;
// explicit import to override the Provider class in this package
import java.security.Provider;
// need internal Sun classes for FIPS tricks
import sun.security.jca.Providers;
import sun.security.jca.ProviderList;
import sun.security.util.ECUtil;
import static sun.security.ssl.SunJSSE.cryptoProvider;
/**
* This class contains a few static methods for interaction with the JCA/JCE
* to obtain implementations, etc.
*
* @author Andreas Sterbenz
*/
final class JsseJce {
private final static ProviderList fipsProviderList;
// Flag indicating whether EC crypto is available.
// If null, then we have not checked yet.
// If yes, then all the EC based crypto we need is available.
private static Boolean ecAvailable;
// Flag indicating whether Kerberos crypto is available.
// If true, then all the Kerberos-based crypto we need is available.
private final static boolean kerberosAvailable;
static {
boolean temp;
try {
AccessController.doPrivileged(
new PrivilegedExceptionAction<Void>() {
@Override
public Void run() throws Exception {
// Test for Kerberos using the bootstrap class loader
Class.forName("sun.security.krb5.PrincipalName", true,
null);
return null;
}
});
temp = true;
} catch (Exception e) {
temp = false;
}
kerberosAvailable = temp;
}
static {
// force FIPS flag initialization
// Because isFIPS() is synchronized and cryptoProvider is not modified
// after it completes, this also eliminates the need for any further
// synchronization when accessing cryptoProvider
if (SunJSSE.isFIPS() == false) {
fipsProviderList = null;
} else {
// Setup a ProviderList that can be used by the trust manager
// during certificate chain validation. All the crypto must be
// from the FIPS provider, but we also allow the required
// certificate related services from the SUN provider.
Provider sun = Security.getProvider("SUN");
if (sun == null) {
throw new RuntimeException
("FIPS mode: SUN provider must be installed");
}
Provider sunCerts = new SunCertificates(sun);
fipsProviderList = ProviderList.newList(cryptoProvider, sunCerts);
}
}
private static final class SunCertificates extends Provider {
private static final long serialVersionUID = -3284138292032213752L;
SunCertificates(final Provider p) {
super("SunCertificates", 1.8d, "SunJSSE internal");
AccessController.doPrivileged(new PrivilegedAction<Object>() {
@Override
public Object run() {
// copy certificate related services from the Sun provider
for (Map.Entry<Object,Object> entry : p.entrySet()) {
String key = (String)entry.getKey();
if (key.startsWith("CertPathValidator.")
|| key.startsWith("CertPathBuilder.")
|| key.startsWith("CertStore.")
|| key.startsWith("CertificateFactory.")) {
put(key, entry.getValue());
}
}
return null;
}
});
}
}
/**
* JCE transformation string for RSA with PKCS#1 v1.5 padding.
* Can be used for encryption, decryption, signing, verifying.
*/
final static String CIPHER_RSA_PKCS1 = "RSA/ECB/PKCS1Padding";
/**
* JCE transformation string for the stream cipher RC4.
*/
final static String CIPHER_RC4 = "RC4";
/**
* JCE transformation string for DES in CBC mode without padding.
*/
final static String CIPHER_DES = "DES/CBC/NoPadding";
/**
* JCE transformation string for (3-key) Triple DES in CBC mode
* without padding.
*/
final static String CIPHER_3DES = "DESede/CBC/NoPadding";
/**
* JCE transformation string for AES in CBC mode
* without padding.
*/
final static String CIPHER_AES = "AES/CBC/NoPadding";
/**
* JCE transformation string for AES in GCM mode
* without padding.
*/
final static String CIPHER_AES_GCM = "AES/GCM/NoPadding";
/**
* JCA identifier string for DSA, i.e. a DSA with SHA-1.
*/
final static String SIGNATURE_DSA = "DSA";
/**
* JCA identifier string for ECDSA, i.e. a ECDSA with SHA-1.
*/
final static String SIGNATURE_ECDSA = "SHA1withECDSA";
/**
* JCA identifier string for Raw DSA, i.e. a DSA signature without
* hashing where the application provides the SHA-1 hash of the data.
* Note that the standard name is "NONEwithDSA" but we use "RawDSA"
* for compatibility.
*/
final static String SIGNATURE_RAWDSA = "RawDSA";
/**
* JCA identifier string for Raw ECDSA, i.e. a DSA signature without
* hashing where the application provides the SHA-1 hash of the data.
*/
final static String SIGNATURE_RAWECDSA = "NONEwithECDSA";
/**
* JCA identifier string for Raw RSA, i.e. a RSA PKCS#1 v1.5 signature
* without hashing where the application provides the hash of the data.
* Used for RSA client authentication with a 36 byte hash.
*/
final static String SIGNATURE_RAWRSA = "NONEwithRSA";
/**
* JCA identifier string for the SSL/TLS style RSA Signature. I.e.
* an signature using RSA with PKCS#1 v1.5 padding signing a
* concatenation of an MD5 and SHA-1 digest.
*/
final static String SIGNATURE_SSLRSA = "MD5andSHA1withRSA";
private JsseJce() {
// no instantiation of this class
}
synchronized static boolean isEcAvailable() {
if (ecAvailable == null) {
try {
JsseJce.getSignature(SIGNATURE_ECDSA);
JsseJce.getSignature(SIGNATURE_RAWECDSA);
JsseJce.getKeyAgreement("ECDH");
JsseJce.getKeyFactory("EC");
JsseJce.getKeyPairGenerator("EC");
ecAvailable = true;
} catch (Exception e) {
ecAvailable = false;
}
}
return ecAvailable;
}
synchronized static void clearEcAvailable() {
ecAvailable = null;
}
static boolean isKerberosAvailable() {
return kerberosAvailable;
}
/**
* Return an JCE cipher implementation for the specified algorithm.
*/
static Cipher getCipher(String transformation)
throws NoSuchAlgorithmException {
try {
if (cryptoProvider == null) {
return Cipher.getInstance(transformation);
} else {
return Cipher.getInstance(transformation, cryptoProvider);
}
} catch (NoSuchPaddingException e) {
throw new NoSuchAlgorithmException(e);
}
}
/**
* Return an JCA signature implementation for the specified algorithm.
* The algorithm string should be one of the constants defined
* in this class.
*/
static Signature getSignature(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return Signature.getInstance(algorithm);
} else {
// reference equality
if (algorithm == SIGNATURE_SSLRSA) {
// The SunPKCS11 provider currently does not support this
// special algorithm. We allow a fallback in this case because
// the SunJSSE implementation does the actual crypto using
// a NONEwithRSA signature obtained from the cryptoProvider.
if (cryptoProvider.getService("Signature", algorithm) == null) {
// Calling Signature.getInstance() and catching the
// exception would be cleaner, but exceptions are a little
// expensive. So we check directly via getService().
try {
return Signature.getInstance(algorithm, "SunJSSE");
} catch (NoSuchProviderException e) {
throw new NoSuchAlgorithmException(e);
}
}
}
return Signature.getInstance(algorithm, cryptoProvider);
}
}
static KeyGenerator getKeyGenerator(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return KeyGenerator.getInstance(algorithm);
} else {
return KeyGenerator.getInstance(algorithm, cryptoProvider);
}
}
static KeyPairGenerator getKeyPairGenerator(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return KeyPairGenerator.getInstance(algorithm);
} else {
return KeyPairGenerator.getInstance(algorithm, cryptoProvider);
}
}
static KeyAgreement getKeyAgreement(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return KeyAgreement.getInstance(algorithm);
} else {
return KeyAgreement.getInstance(algorithm, cryptoProvider);
}
}
static Mac getMac(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return Mac.getInstance(algorithm);
} else {
return Mac.getInstance(algorithm, cryptoProvider);
}
}
static KeyFactory getKeyFactory(String algorithm)
throws NoSuchAlgorithmException {
if (cryptoProvider == null) {
return KeyFactory.getInstance(algorithm);
} else {
return KeyFactory.getInstance(algorithm, cryptoProvider);
}
}
static SecureRandom getSecureRandom() throws KeyManagementException {
if (cryptoProvider == null) {
return new SecureRandom();
}
// Try "PKCS11" first. If that is not supported, iterate through
// the provider and return the first working implementation.
try {
return SecureRandom.getInstance("PKCS11", cryptoProvider);
} catch (NoSuchAlgorithmException e) {
// ignore
}
for (Provider.Service s : cryptoProvider.getServices()) {
if (s.getType().equals("SecureRandom")) {
try {
return SecureRandom.getInstance(s.getAlgorithm(), cryptoProvider);
} catch (NoSuchAlgorithmException ee) {
// ignore
}
}
}
throw new KeyManagementException("FIPS mode: no SecureRandom "
+ " implementation found in provider " + cryptoProvider.getName());
}
static MessageDigest getMD5() {
return getMessageDigest("MD5");
}
static MessageDigest getSHA() {
return getMessageDigest("SHA");
}
static MessageDigest getMessageDigest(String algorithm) {
try {
if (cryptoProvider == null) {
return MessageDigest.getInstance(algorithm);
} else {
return MessageDigest.getInstance(algorithm, cryptoProvider);
}
} catch (NoSuchAlgorithmException e) {
throw new RuntimeException
("Algorithm " + algorithm + " not available", e);
}
}
static int getRSAKeyLength(PublicKey key) {
BigInteger modulus;
if (key instanceof RSAPublicKey) {
modulus = ((RSAPublicKey)key).getModulus();
} else {
RSAPublicKeySpec spec = getRSAPublicKeySpec(key);
modulus = spec.getModulus();
}
return modulus.bitLength();
}
static RSAPublicKeySpec getRSAPublicKeySpec(PublicKey key) {
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