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*
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package sun.security.ssl;
import java.net.Socket;
import java.security.*;
import java.security.cert.*;
import java.util.*;
import javax.net.ssl.*;
import sun.security.util.AnchorCertificates;
import sun.security.util.HostnameChecker;
import sun.security.validator.*;
/**
* This class implements the SunJSSE X.509 trust manager using the internal
* validator API in J2SE core. The logic in this class is minimal.
*
* This class supports both the Simple validation algorithm from previous
* JSSE versions and PKIX validation. Currently, it is not possible for the
* application to specify PKIX parameters other than trust anchors. This will
* be fixed in a future release using new APIs. When that happens, it may also
* make sense to separate the Simple and PKIX trust managers into separate
* classes.
*
* @author Andreas Sterbenz
*/
final class X509TrustManagerImpl extends X509ExtendedTrustManager
implements X509TrustManager {
private final String validatorType;
/**
* The Set of trusted X509Certificates.
*/
private final Collection trustedCerts;
private final PKIXBuilderParameters pkixParams;
// note that we need separate validator for client and server due to
// the different extension checks. They are initialized lazily on demand.
private volatile Validator clientValidator, serverValidator;
X509TrustManagerImpl(String validatorType,
Collection trustedCerts) {
this.validatorType = validatorType;
this.pkixParams = null;
if (trustedCerts == null) {
trustedCerts = Collections.emptySet();
}
this.trustedCerts = trustedCerts;
if (SSLLogger.isOn && SSLLogger.isOn("ssl,trustmanager")) {
SSLLogger.fine("adding as trusted certificates",
(Object[])trustedCerts.toArray(new X509Certificate[0]));
}
}
X509TrustManagerImpl(String validatorType, PKIXBuilderParameters params) {
this.validatorType = validatorType;
this.pkixParams = params;
// create server validator eagerly so that we can conveniently
// get the trusted certificates
// clients need it anyway eventually, and servers will not mind
// the little extra footprint
Validator v = getValidator(Validator.VAR_TLS_SERVER);
trustedCerts = v.getTrustedCertificates();
serverValidator = v;
if (SSLLogger.isOn && SSLLogger.isOn("ssl,trustmanager")) {
SSLLogger.fine("adding as trusted certificates",
(Object[])trustedCerts.toArray(new X509Certificate[0]));
}
}
@Override
public void checkClientTrusted(X509Certificate[] chain, String authType)
throws CertificateException {
checkTrusted(chain, authType, (Socket)null, true);
}
@Override
public void checkServerTrusted(X509Certificate[] chain, String authType)
throws CertificateException {
checkTrusted(chain, authType, (Socket)null, false);
}
@Override
public X509Certificate[] getAcceptedIssuers() {
X509Certificate[] certsArray = new X509Certificate[trustedCerts.size()];
trustedCerts.toArray(certsArray);
return certsArray;
}
@Override
public void checkClientTrusted(X509Certificate[] chain, String authType,
Socket socket) throws CertificateException {
checkTrusted(chain, authType, socket, true);
}
@Override
public void checkServerTrusted(X509Certificate[] chain, String authType,
Socket socket) throws CertificateException {
checkTrusted(chain, authType, socket, false);
}
@Override
public void checkClientTrusted(X509Certificate[] chain, String authType,
SSLEngine engine) throws CertificateException {
checkTrusted(chain, authType, engine, true);
}
@Override
public void checkServerTrusted(X509Certificate[] chain, String authType,
SSLEngine engine) throws CertificateException {
checkTrusted(chain, authType, engine, false);
}
private Validator checkTrustedInit(X509Certificate[] chain,
String authType, boolean isClient) {
if (chain == null || chain.length == 0) {
throw new IllegalArgumentException(
"null or zero-length certificate chain");
}
if (authType == null || authType.isEmpty()) {
throw new IllegalArgumentException(
"null or zero-length authentication type");
}
Validator v = null;
if (isClient) {
v = clientValidator;
if (v == null) {
synchronized (this) {
v = clientValidator;
if (v == null) {
v = getValidator(Validator.VAR_TLS_CLIENT);
clientValidator = v;
}
}
}
} else {
// assume double checked locking with a volatile flag works
// (guaranteed under the new Tiger memory model)
v = serverValidator;
if (v == null) {
synchronized (this) {
v = serverValidator;
if (v == null) {
v = getValidator(Validator.VAR_TLS_SERVER);
serverValidator = v;
}
}
}
}
return v;
}
private void checkTrusted(X509Certificate[] chain, String authType,
Socket socket, boolean isClient) throws CertificateException {
Validator v = checkTrustedInit(chain, authType, isClient);
X509Certificate[] trustedChain = null;
if ((socket != null) && socket.isConnected() &&
(socket instanceof SSLSocket)) {
SSLSocket sslSocket = (SSLSocket)socket;
SSLSession session = sslSocket.getHandshakeSession();
if (session == null) {
throw new CertificateException("No handshake session");
}
// create the algorithm constraints
boolean isExtSession = (session instanceof ExtendedSSLSession);
AlgorithmConstraints constraints;
if (isExtSession &&
ProtocolVersion.useTLS12PlusSpec(session.getProtocol())) {
ExtendedSSLSession extSession = (ExtendedSSLSession)session;
String[] localSupportedSignAlgs =
extSession.getLocalSupportedSignatureAlgorithms();
constraints = new SSLAlgorithmConstraints(
sslSocket, localSupportedSignAlgs, false);
} else {
constraints = new SSLAlgorithmConstraints(sslSocket, false);
}
// Grab any stapled OCSP responses for use in validation
List responseList = Collections.emptyList();
if (!isClient && isExtSession) {
responseList =
((ExtendedSSLSession)session).getStatusResponses();
}
trustedChain = validate(v, chain, responseList,
constraints, isClient ? null : authType);
// check if EE certificate chains to a public root CA (as
// pre-installed in cacerts)
boolean chainsToPublicCA = AnchorCertificates.contains(
trustedChain[trustedChain.length-1]);
// check endpoint identity
String identityAlg = sslSocket.getSSLParameters().
getEndpointIdentificationAlgorithm();
if (identityAlg != null && !identityAlg.isEmpty()) {
checkIdentity(session, trustedChain[0], identityAlg, isClient,
getRequestedServerNames(socket), chainsToPublicCA);
}
} else {
trustedChain = validate(v, chain, Collections.emptyList(),
null, isClient ? null : authType);
}
if (SSLLogger.isOn && SSLLogger.isOn("ssl,trustmanager")) {
SSLLogger.fine("Found trusted certificate",
trustedChain[trustedChain.length - 1]);
}
}
private void checkTrusted(X509Certificate[] chain, String authType,
SSLEngine engine, boolean isClient) throws CertificateException {
Validator v = checkTrustedInit(chain, authType, isClient);
X509Certificate[] trustedChain = null;
if (engine != null) {
SSLSession session = engine.getHandshakeSession();
if (session == null) {
throw new CertificateException("No handshake session");
}
// create the algorithm constraints
boolean isExtSession = (session instanceof ExtendedSSLSession);
AlgorithmConstraints constraints;
if (isExtSession &&
ProtocolVersion.useTLS12PlusSpec(session.getProtocol())) {
ExtendedSSLSession extSession = (ExtendedSSLSession)session;
String[] localSupportedSignAlgs =
extSession.getLocalSupportedSignatureAlgorithms();
constraints = new SSLAlgorithmConstraints(
engine, localSupportedSignAlgs, false);
} else {
constraints = new SSLAlgorithmConstraints(engine, false);
}
// Grab any stapled OCSP responses for use in validation
List responseList = Collections.emptyList();
if (!isClient && isExtSession) {
responseList =
((ExtendedSSLSession)session).getStatusResponses();
}
trustedChain = validate(v, chain, responseList,
constraints, isClient ? null : authType);
// check if EE certificate chains to a public root CA (as
// pre-installed in cacerts)
boolean chainsToPublicCA = AnchorCertificates.contains(
trustedChain[trustedChain.length-1]);
// check endpoint identity
String identityAlg = engine.getSSLParameters().
getEndpointIdentificationAlgorithm();
if (identityAlg != null && !identityAlg.isEmpty()) {
checkIdentity(session, trustedChain[0], identityAlg, isClient,
getRequestedServerNames(engine), chainsToPublicCA);
}
} else {
trustedChain = validate(v, chain, Collections.emptyList(),
null, isClient ? null : authType);
}
if (SSLLogger.isOn && SSLLogger.isOn("ssl,trustmanager")) {
SSLLogger.fine("Found trusted certificate",
trustedChain[trustedChain.length - 1]);
}
}
private Validator getValidator(String variant) {
Validator v;
if (pkixParams == null) {
v = Validator.getInstance(validatorType, variant, trustedCerts);
} else {
v = Validator.getInstance(validatorType, variant, pkixParams);
}
return v;
}
private static X509Certificate[] validate(Validator v,
X509Certificate[] chain, List responseList,
AlgorithmConstraints constraints, String authType)
throws CertificateException {
Object o = JsseJce.beginFipsProvider();
try {
return v.validate(chain, null, responseList, constraints, authType);
} finally {
JsseJce.endFipsProvider(o);
}
}
// Get string representation of HostName from a list of server names.
//
// We are only accepting host_name name type in the list.
private static String getHostNameInSNI(List sniNames) {
SNIHostName hostname = null;
for (SNIServerName sniName : sniNames) {
if (sniName.getType() != StandardConstants.SNI_HOST_NAME) {
continue;
}
if (sniName instanceof SNIHostName) {
hostname = (SNIHostName)sniName;
} else {
try {
hostname = new SNIHostName(sniName.getEncoded());
} catch (IllegalArgumentException iae) {
// unlikely to happen, just in case ...
if (SSLLogger.isOn && SSLLogger.isOn("ssl,trustmanager")) {
SSLLogger.fine("Illegal server name: " + sniName);
}
}
}
// no more than server name of the same name type
break;
}
if (hostname != null) {
return hostname.getAsciiName();
}
return null;
}
// Also used by X509KeyManagerImpl
static List getRequestedServerNames(Socket socket) {
if (socket != null && socket.isConnected() &&
socket instanceof SSLSocket) {
SSLSocket sslSocket = (SSLSocket)socket;
SSLSession session = sslSocket.getHandshakeSession();
if (session != null && (session instanceof ExtendedSSLSession)) {
ExtendedSSLSession extSession = (ExtendedSSLSession)session;
return extSession.getRequestedServerNames();
}
}
return Collections.emptyList();
}
// Also used by X509KeyManagerImpl
static List getRequestedServerNames(SSLEngine engine) {
if (engine != null) {
SSLSession session = engine.getHandshakeSession();
if (session != null && (session instanceof ExtendedSSLSession)) {
ExtendedSSLSession extSession = (ExtendedSSLSession)session;
return extSession.getRequestedServerNames();
}
}
return Collections.emptyList();
}
/*
* Per RFC 6066, if an application negotiates a server name using an
* application protocol and then upgrades to TLS, and if a server_name
* extension is sent, then the extension SHOULD contain the same name
* that was negotiated in the application protocol. If the server_name
* is established in the TLS session handshake, the client SHOULD NOT
* attempt to request a different server name at the application layer.
*
* According to the above spec, we only need to check either the identity
* in server_name extension or the peer host of the connection. Peer host
* is not always a reliable fully qualified domain name. The HostName in
* server_name extension is more reliable than peer host. So we prefer
* the identity checking aginst the server_name extension if present, and
* may failove to peer host checking.
*/
private static void checkIdentity(SSLSession session,
X509Certificate cert,
String algorithm,
boolean isClient,
List sniNames,
boolean chainsToPublicCA) throws CertificateException {
boolean identifiable = false;
String peerHost = session.getPeerHost();
if (isClient) {
String hostname = getHostNameInSNI(sniNames);
if (hostname != null) {
try {
checkIdentity(hostname, cert, algorithm, chainsToPublicCA);
identifiable = true;
} catch (CertificateException ce) {
if (hostname.equalsIgnoreCase(peerHost)) {
throw ce;
}
// otherwisw, failover to check peer host
}
}
}
if (!identifiable) {
checkIdentity(peerHost, cert, algorithm, chainsToPublicCA);
}
}
/*
* Identify the peer by its certificate and hostname.
*
* Lifted from sun.net.www.protocol.https.HttpsClient.
*/
static void checkIdentity(String hostname, X509Certificate cert,
String algorithm) throws CertificateException {
checkIdentity(hostname, cert, algorithm, false);
}
private static void checkIdentity(String hostname, X509Certificate cert,
String algorithm, boolean chainsToPublicCA)
throws CertificateException {
if (algorithm != null && !algorithm.isEmpty()) {
// if IPv6 strip off the "[]"
if ((hostname != null) && hostname.startsWith("[") &&
hostname.endsWith("]")) {
hostname = hostname.substring(1, hostname.length() - 1);
}
if (algorithm.equalsIgnoreCase("HTTPS")) {
HostnameChecker.getInstance(HostnameChecker.TYPE_TLS).match(
hostname, cert, chainsToPublicCA);
} else if (algorithm.equalsIgnoreCase("LDAP") ||
algorithm.equalsIgnoreCase("LDAPS")) {
HostnameChecker.getInstance(HostnameChecker.TYPE_LDAP).match(
hostname, cert, chainsToPublicCA);
} else {
throw new CertificateException(
"Unknown identification algorithm: " + algorithm);
}
}
}
}