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/*
* Copyright 2014 The Netty Project
*
* The Netty Project 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:
*
* https://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 io.netty5.handler.ssl;
import io.netty5.util.internal.UnstableApi;
import io.netty5.util.internal.logging.InternalLogger;
import io.netty5.util.internal.logging.InternalLoggerFactory;
import java.util.Collections;
import java.util.HashMap;
import java.util.Map;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
import static java.util.Collections.singletonMap;
/**
* Converts a Java cipher suite string to an OpenSSL cipher suite string and vice versa.
*
* @see Wikipedia page about cipher suite
*/
@UnstableApi
public final class CipherSuiteConverter {
private static final InternalLogger logger = InternalLoggerFactory.getInstance(CipherSuiteConverter.class);
/**
* 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 assumes 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_(.*)_(.*)$");
/**
* A-B-C, where:
*
* A - handshake algorithm (key exchange and authentication algorithms to be precise)
* B - bulk cipher
* C - HMAC algorithm
*
* This regular expression assumes that:
*
* 1) A has some deterministic pattern as shown below, and
* 2) C is always a single word
*/
private static final Pattern OPENSSL_CIPHERSUITE_PATTERN =
// Be very careful not to break the indentation while editing.
Pattern.compile(
"^(?:(" + // BEGIN handshake algorithm
"(?:(?:EXP-)?" +
"(?:" +
"(?:DHE|EDH|ECDH|ECDHE|SRP|RSA)-(?:DSS|RSA|ECDSA|PSK)|" +
"(?:ADH|AECDH|KRB5|PSK|SRP)" +
')' +
")|" +
"EXP" +
")-)?" + // END handshake algorithm
"(.*)-(.*)$");
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<>();
private static final Map j2oTls13;
private static final Map> o2jTls13;
static {
Map j2oTls13Map = new HashMap<>();
j2oTls13Map.put("TLS_AES_128_GCM_SHA256", "AEAD-AES128-GCM-SHA256");
j2oTls13Map.put("TLS_AES_256_GCM_SHA384", "AEAD-AES256-GCM-SHA384");
j2oTls13Map.put("TLS_CHACHA20_POLY1305_SHA256", "AEAD-CHACHA20-POLY1305-SHA256");
j2oTls13 = Collections.unmodifiableMap(j2oTls13Map);
Map> o2jTls13Map = new HashMap<>();
o2jTls13Map.put("TLS_AES_128_GCM_SHA256", singletonMap("TLS", "TLS_AES_128_GCM_SHA256"));
o2jTls13Map.put("TLS_AES_256_GCM_SHA384", singletonMap("TLS", "TLS_AES_256_GCM_SHA384"));
o2jTls13Map.put("TLS_CHACHA20_POLY1305_SHA256", singletonMap("TLS", "TLS_CHACHA20_POLY1305_SHA256"));
o2jTls13Map.put("AEAD-AES128-GCM-SHA256", singletonMap("TLS", "TLS_AES_128_GCM_SHA256"));
o2jTls13Map.put("AEAD-AES256-GCM-SHA384", singletonMap("TLS", "TLS_AES_256_GCM_SHA384"));
o2jTls13Map.put("AEAD-CHACHA20-POLY1305-SHA256", singletonMap("TLS", "TLS_CHACHA20_POLY1305_SHA256"));
o2jTls13 = Collections.unmodifiableMap(o2jTls13Map);
}
/**
* 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 suite to its corresponding OpenSSL cipher suite name.
*
* @return {@code null} if the conversion has failed
*/
public static String toOpenSsl(String javaCipherSuite, boolean boringSSL) {
String converted = j2o.get(javaCipherSuite);
if (converted != null) {
return converted;
}
return cacheFromJava(javaCipherSuite, boringSSL);
}
private static String cacheFromJava(String javaCipherSuite, boolean boringSSL) {
String converted = j2oTls13.get(javaCipherSuite);
if (converted != null) {
return boringSSL ? converted : javaCipherSuite;
}
String openSslCipherSuite = toOpenSslUncached(javaCipherSuite, boringSSL);
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);
logger.debug("Cipher suite mapping: {} => {}", javaCipherSuite, openSslCipherSuite);
return openSslCipherSuite;
}
static String toOpenSslUncached(String javaCipherSuite, boolean boringSSL) {
String converted = j2oTls13.get(javaCipherSuite);
if (converted != null) {
return boringSSL ? converted : 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.isEmpty()) {
return bulkCipher + '-' + hmacAlgo;
} else if (bulkCipher.contains("CHACHA20")) {
return handshakeAlgo + '-' + bulkCipher;
} 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.isEmpty()) {
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);
// This may happen if this method is queried when OpenSSL doesn't yet have a cipher setup. It will return
// "(NONE)" in this case.
if (p2j == null) {
return null;
}
}
String javaCipherSuite = p2j.get(protocol);
if (javaCipherSuite == null) {
String cipher = p2j.get("");
if (cipher == null) {
return null;
}
javaCipherSuite = protocol + '_' + cipher;
}
return javaCipherSuite;
}
private static Map cacheFromOpenSsl(String openSslCipherSuite) {
Map converted = o2jTls13.get(openSslCipherSuite);
if (converted != null) {
return converted;
}
String javaCipherSuiteSuffix = toJavaUncached0(openSslCipherSuite, false);
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);
logger.debug("Cipher suite mapping: {} => {}", javaCipherSuiteTls, openSslCipherSuite);
logger.debug("Cipher suite mapping: {} => {}", javaCipherSuiteSsl, openSslCipherSuite);
return p2j;
}
static String toJavaUncached(String openSslCipherSuite) {
return toJavaUncached0(openSslCipherSuite, true);
}
private static String toJavaUncached0(String openSslCipherSuite, boolean checkTls13) {
if (checkTls13) {
Map converted = o2jTls13.get(openSslCipherSuite);
if (converted != null) {
return converted.get("TLS");
}
}
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));
String javaCipherSuite = handshakeAlgo + "_WITH_" + bulkCipher + '_' + hmacAlgo;
// For historical reasons the CHACHA20 ciphers do not follow OpenSSL's custom naming convention and omits the
// HMAC algorithm portion of the name. There is currently no way to derive this information because it is
// omitted from the OpenSSL cipher name, but they currently all use SHA256 for HMAC [1].
// [1] https://www.openssl.org/docs/man1.1.0/apps/ciphers.html
return bulkCipher.contains("CHACHA20") ? javaCipherSuite + "_SHA256" : javaCipherSuite;
}
private static String toJavaHandshakeAlgo(String handshakeAlgo, boolean export) {
if (handshakeAlgo.isEmpty()) {
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;
}
/**
* Convert the given ciphers if needed to OpenSSL format and append them to the correct {@link StringBuilder}
* depending on if its a TLSv1.3 cipher or not. If this methods returns without throwing an exception its
* guaranteed that at least one of the {@link StringBuilder}s contain some ciphers that can be used to configure
* OpenSSL.
*/
static void convertToCipherStrings(Iterable cipherSuites, StringBuilder cipherBuilder,
StringBuilder cipherTLSv13Builder, boolean boringSSL) {
for (String c: cipherSuites) {
if (c == null) {
break;
}
String converted = toOpenSsl(c, boringSSL);
if (converted == null) {
converted = c;
}
if (!OpenSsl.isCipherSuiteAvailable(converted)) {
throw new IllegalArgumentException("unsupported cipher suite: " + c + '(' + converted + ')');
}
if (SslUtils.isTLSv13Cipher(converted) || SslUtils.isTLSv13Cipher(c)) {
cipherTLSv13Builder.append(converted);
cipherTLSv13Builder.append(':');
} else {
cipherBuilder.append(converted);
cipherBuilder.append(':');
}
}
if (cipherBuilder.length() == 0 && cipherTLSv13Builder.length() == 0) {
throw new IllegalArgumentException("empty cipher suites");
}
if (cipherBuilder.length() > 0) {
cipherBuilder.setLength(cipherBuilder.length() - 1);
}
if (cipherTLSv13Builder.length() > 0) {
cipherTLSv13Builder.setLength(cipherTLSv13Builder.length() - 1);
}
}
private CipherSuiteConverter() { }
}
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