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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package org.wildfly.openssl;

import java.util.HashMap;
import java.util.Map;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.logging.Level;
import java.util.logging.Logger;
import java.util.regex.Matcher;
import java.util.regex.Pattern;

/**
 * Converts a Java cipher suite string to an OpenSSL cipher suite string and vice versa.
 *
 * @see Wikipedia page about cipher suite
 */
public final class CipherSuiteConverter {

    private static final Logger LOG = Logger.getLogger(CipherSuiteConverter.class.getName());

    /**
     * A_B_WITH_C_D, where:
     * 

* A - TLS or SSL (protocol) * B - handshake algorithm (key exchange and authentication algorithms to be precise) * C - bulk cipher * D - HMAC algorithm *

* This regular expression assumees that: *

* 1) A is always TLS or SSL, and * 2) D is always a single word. */ private static final Pattern JAVA_CIPHERSUITE_PATTERN = Pattern.compile("^(?:TLS|SSL)_((?:(?!_WITH_).)+)_WITH_(.*)_(.*)$"); /** * A-B-C, where: *

* A - handshake algorithm (key exchange and authentication algorithms to be precise) * B - bulk cipher * C - HMAC algorithm *

* This regular expression assumes that: *

* 1) A has some deterministic pattern as shown below, and * 2) C is always a single word */ private static final Pattern OPENSSL_CIPHERSUITE_PATTERN = // Be very careful not to break the indentation while editing. Pattern.compile( "^(?:(" + // BEGIN handshake algorithm "(?:(?:EXP-)?" + "(?:" + "(?:DHE|EDH|ECDH|ECDHE|SRP)-(?:DSS|RSA|ECDSA)|" + "(?:ADH|AECDH|KRB5|PSK|SRP)" + ')' + ")|" + "EXP" + ")-)?" + // END handshake algorithm "(.*)-(.*)$"); private static final Pattern JAVA_AES_CBC_PATTERN = Pattern.compile("^(AES)_([0-9]+)_CBC$"); private static final Pattern JAVA_AES_PATTERN = Pattern.compile("^(AES)_([0-9]+)_(.*)$"); private static final Pattern OPENSSL_AES_CBC_PATTERN = Pattern.compile("^(AES)([0-9]+)$"); private static final Pattern OPENSSL_AES_PATTERN = Pattern.compile("^(AES)([0-9]+)-(.*)$"); /** * Java-to-OpenSSL cipher suite conversion map * Note that the Java cipher suite has the protocol prefix (TLS_, SSL_) */ private static final ConcurrentMap j2o = new ConcurrentHashMap<>(); /** * OpenSSL-to-Java cipher suite conversion map. * Note that one OpenSSL cipher suite can be converted to more than one Java cipher suites because * a Java cipher suite has the protocol name prefix (TLS_, SSL_) */ private static final ConcurrentMap> o2j = new ConcurrentHashMap<>(); /** * Clears the cache for testing purpose. */ static void clearCache() { j2o.clear(); o2j.clear(); } /** * Tests if the specified key-value pair has been cached in Java-to-OpenSSL cache. */ static boolean isJ2OCached(String key, String value) { return value.equals(j2o.get(key)); } /** * Tests if the specified key-value pair has been cached in OpenSSL-to-Java cache. */ static boolean isO2JCached(String key, String protocol, String value) { Map p2j = o2j.get(key); if (p2j == null) { return false; } else { return value.equals(p2j.get(protocol)); } } /** * Converts the specified Java cipher suites to the colon-separated OpenSSL cipher suite specification. */ public static String toOpenSsl(Iterable javaCipherSuites) { final StringBuilder buf = new StringBuilder(); for (String c : javaCipherSuites) { if (c == null) { break; } String converted = toOpenSsl(c); if (converted != null) { c = converted; } buf.append(c); buf.append(':'); } if (buf.length() > 0) { buf.setLength(buf.length() - 1); return buf.toString(); } else { return ""; } } /** * Converts the specified Java cipher suite to its corresponding OpenSSL cipher suite name. * * @return {@code null} if the conversion has failed */ public static String toOpenSsl(String javaCipherSuite) { String converted = j2o.get(javaCipherSuite); if (converted != null) { return converted; } else { return cacheFromJava(javaCipherSuite); } } private static String cacheFromJava(String javaCipherSuite) { String openSslCipherSuite = toOpenSslUncached(javaCipherSuite); if (openSslCipherSuite == null) { return null; } // Cache the mapping. j2o.putIfAbsent(javaCipherSuite, openSslCipherSuite); // Cache the reverse mapping after stripping the protocol prefix (TLS_ or SSL_) final String javaCipherSuiteSuffix = javaCipherSuite.substring(4); Map p2j = new HashMap<>(4); p2j.put("", javaCipherSuiteSuffix); p2j.put("SSL", "SSL_" + javaCipherSuiteSuffix); p2j.put("TLS", "TLS_" + javaCipherSuiteSuffix); o2j.put(openSslCipherSuite, p2j); if (LOG.isLoggable(Level.FINE)) { LOG.fine("mapping java cipher " + javaCipherSuite + " to " + openSslCipherSuite); } return openSslCipherSuite; } static String toOpenSslUncached(String javaCipherSuite) { Matcher m = JAVA_CIPHERSUITE_PATTERN.matcher(javaCipherSuite); if (!m.matches()) { return null; } String handshakeAlgo = toOpenSslHandshakeAlgo(m.group(1)); String bulkCipher = toOpenSslBulkCipher(m.group(2)); String hmacAlgo = toOpenSslHmacAlgo(m.group(3)); if (handshakeAlgo.length() == 0) { return bulkCipher + '-' + hmacAlgo; } else { return handshakeAlgo + '-' + bulkCipher + '-' + hmacAlgo; } } private static String toOpenSslHandshakeAlgo(String handshakeAlgo) { final boolean export = handshakeAlgo.endsWith("_EXPORT"); if (export) { handshakeAlgo = handshakeAlgo.substring(0, handshakeAlgo.length() - 7); } if ("RSA".equals(handshakeAlgo)) { handshakeAlgo = ""; } else if (handshakeAlgo.endsWith("_anon")) { handshakeAlgo = 'A' + handshakeAlgo.substring(0, handshakeAlgo.length() - 5); } if (export) { if (handshakeAlgo.length() == 0) { handshakeAlgo = "EXP"; } else { handshakeAlgo = "EXP-" + handshakeAlgo; } } return handshakeAlgo.replace('_', '-'); } private static String toOpenSslBulkCipher(String bulkCipher) { if (bulkCipher.startsWith("AES_")) { Matcher m = JAVA_AES_CBC_PATTERN.matcher(bulkCipher); if (m.matches()) { return m.replaceFirst("$1$2"); } m = JAVA_AES_PATTERN.matcher(bulkCipher); if (m.matches()) { return m.replaceFirst("$1$2-$3"); } } if ("3DES_EDE_CBC".equals(bulkCipher)) { return "DES-CBC3"; } if ("RC4_128".equals(bulkCipher) || "RC4_40".equals(bulkCipher)) { return "RC4"; } if ("DES40_CBC".equals(bulkCipher) || "DES_CBC_40".equals(bulkCipher)) { return "DES-CBC"; } if ("RC2_CBC_40".equals(bulkCipher)) { return "RC2-CBC"; } return bulkCipher.replace('_', '-'); } private static String toOpenSslHmacAlgo(String hmacAlgo) { // Java and OpenSSL use the same algorithm names for: // // * SHA // * SHA256 // * MD5 // return hmacAlgo; } /** * Convert from OpenSSL cipher suite name convention to java cipher suite name convention. * * @param openSslCipherSuite An OpenSSL cipher suite name. * @param protocol The cryptographic protocol (i.e. SSL, TLS, ...). * @return The translated cipher suite name according to java conventions. This will not be {@code null}. */ public static String toJava(String openSslCipherSuite, String protocol) { Map p2j = o2j.get(openSslCipherSuite); if (p2j == null) { p2j = cacheFromOpenSsl(openSslCipherSuite); } String javaCipherSuite = p2j.get(protocol); if (javaCipherSuite == null) { javaCipherSuite = protocol + '_' + p2j.get(""); } return javaCipherSuite; } private static Map cacheFromOpenSsl(String openSslCipherSuite) { String javaCipherSuiteSuffix = toJavaUncached(openSslCipherSuite); if (javaCipherSuiteSuffix == null) { return null; } final String javaCipherSuiteSsl = "SSL_" + javaCipherSuiteSuffix; final String javaCipherSuiteTls = "TLS_" + javaCipherSuiteSuffix; // Cache the mapping. final Map p2j = new HashMap<>(4); p2j.put("", javaCipherSuiteSuffix); p2j.put("SSL", javaCipherSuiteSsl); p2j.put("TLS", javaCipherSuiteTls); o2j.putIfAbsent(openSslCipherSuite, p2j); // Cache the reverse mapping after adding the protocol prefix (TLS_ or SSL_) j2o.putIfAbsent(javaCipherSuiteTls, openSslCipherSuite); j2o.putIfAbsent(javaCipherSuiteSsl, openSslCipherSuite); if (LOG.isLoggable(Level.FINE)) { LOG.fine("mapping java cipher " + javaCipherSuiteTls + " to " + openSslCipherSuite); LOG.fine("mapping java cipher " + javaCipherSuiteSsl + " to " + openSslCipherSuite); } return p2j; } static String toJavaUncached(String openSslCipherSuite) { Matcher m = OPENSSL_CIPHERSUITE_PATTERN.matcher(openSslCipherSuite); if (!m.matches()) { return null; } String handshakeAlgo = m.group(1); final boolean export; if (handshakeAlgo == null) { handshakeAlgo = ""; export = false; } else if (handshakeAlgo.startsWith("EXP-")) { handshakeAlgo = handshakeAlgo.substring(4); export = true; } else if ("EXP".equals(handshakeAlgo)) { handshakeAlgo = ""; export = true; } else { export = false; } handshakeAlgo = toJavaHandshakeAlgo(handshakeAlgo, export); String bulkCipher = toJavaBulkCipher(m.group(2), export); String hmacAlgo = toJavaHmacAlgo(m.group(3)); return handshakeAlgo + "_WITH_" + bulkCipher + '_' + hmacAlgo; } private static String toJavaHandshakeAlgo(String handshakeAlgo, boolean export) { if (handshakeAlgo.length() == 0) { handshakeAlgo = "RSA"; } else if ("ADH".equals(handshakeAlgo)) { handshakeAlgo = "DH_anon"; } else if ("AECDH".equals(handshakeAlgo)) { handshakeAlgo = "ECDH_anon"; } handshakeAlgo = handshakeAlgo.replace('-', '_'); if (export) { return handshakeAlgo + "_EXPORT"; } else { return handshakeAlgo; } } private static String toJavaBulkCipher(String bulkCipher, boolean export) { if (bulkCipher.startsWith("AES")) { Matcher m = OPENSSL_AES_CBC_PATTERN.matcher(bulkCipher); if (m.matches()) { return m.replaceFirst("$1_$2_CBC"); } m = OPENSSL_AES_PATTERN.matcher(bulkCipher); if (m.matches()) { return m.replaceFirst("$1_$2_$3"); } } if ("DES-CBC3".equals(bulkCipher)) { return "3DES_EDE_CBC"; } if ("RC4".equals(bulkCipher)) { if (export) { return "RC4_40"; } else { return "RC4_128"; } } if ("DES-CBC".equals(bulkCipher)) { if (export) { return "DES_CBC_40"; } else { return "DES_CBC"; } } if ("RC2-CBC".equals(bulkCipher)) { if (export) { return "RC2_CBC_40"; } else { return "RC2_CBC"; } } return bulkCipher.replace('-', '_'); } private static String toJavaHmacAlgo(String hmacAlgo) { // Java and OpenSSL use the same algorithm names for: // // * SHA // * SHA256 // * MD5 // return hmacAlgo; } private CipherSuiteConverter() { } }





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