8187443: Forest Consolidation: Move files to unified layout
Reviewed-by: darcy, ihse
/*
* Copyright (c) 2011, 2016, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* 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).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
//
// SunJSSE does not support dynamic system properties, no way to re-use
// system properties in samevm/agentvm mode.
//
/*
* @test
* @bug 7105780
* @summary Add SSLSocket client/SSLEngine server to templates directory.
* @run main/othervm SSLSocketSSLEngineTemplate
*/
/**
* A SSLSocket/SSLEngine interop test case. This is not the way to
* code SSLEngine-based servers, but works for what we need to do here,
* which is to make sure that SSLEngine/SSLSockets can talk to each other.
* SSLEngines can use direct or indirect buffers, and different code
* is used to get at the buffer contents internally, so we test that here.
*
* The test creates one SSLSocket (client) and one SSLEngine (server).
* The SSLSocket talks to a raw ServerSocket, and the server code
* does the translation between byte [] and ByteBuffers that the SSLEngine
* can use. The "transport" layer consists of a Socket Input/OutputStream
* and two byte buffers for the SSLEngines: think of them
* as directly connected pipes.
*
* Again, this is a *very* simple example: real code will be much more
* involved. For example, different threading and I/O models could be
* used, transport mechanisms could close unexpectedly, and so on.
*
* When this application runs, notice that several messages
* (wrap/unwrap) pass before any application data is consumed or
* produced. (For more information, please see the SSL/TLS
* specifications.) There may several steps for a successful handshake,
* so it's typical to see the following series of operations:
*
* client server message
* ====== ====== =======
* write() ... ClientHello
* ... unwrap() ClientHello
* ... wrap() ServerHello/Certificate
* read() ... ServerHello/Certificate
* write() ... ClientKeyExchange
* write() ... ChangeCipherSpec
* write() ... Finished
* ... unwrap() ClientKeyExchange
* ... unwrap() ChangeCipherSpec
* ... unwrap() Finished
* ... wrap() ChangeCipherSpec
* ... wrap() Finished
* read() ... ChangeCipherSpec
* read() ... Finished
*/
import javax.net.ssl.*;
import javax.net.ssl.SSLEngineResult.*;
import java.io.*;
import java.net.*;
import java.security.*;
import java.nio.*;
public class SSLSocketSSLEngineTemplate {
/*
* Enables logging of the SSL/TLS operations.
*/
private static final boolean logging = true;
/*
* Enables the JSSE system debugging system property:
*
* -Djavax.net.debug=all
*
* This gives a lot of low-level information about operations underway,
* including specific handshake messages, and might be best examined
* after gaining some familiarity with this application.
*/
private static final boolean debug = false;
private final SSLContext sslc;
private SSLEngine serverEngine; // server-side SSLEngine
private final byte[] serverMsg =
"Hi there Client, I'm a Server.".getBytes();
private final byte[] clientMsg =
"Hello Server, I'm a Client! Pleased to meet you!".getBytes();
private ByteBuffer serverOut; // write side of serverEngine
private ByteBuffer serverIn; // read side of serverEngine
private volatile Exception clientException;
private volatile Exception serverException;
/*
* For data transport, this example uses local ByteBuffers.
*/
private ByteBuffer cTOs; // "reliable" transport client->server
private ByteBuffer sTOc; // "reliable" transport server->client
/*
* The following is to set up the keystores/trust material.
*/
private static final String pathToStores = "../etc";
private static final String keyStoreFile = "keystore";
private static final String trustStoreFile = "truststore";
private static final String passwd = "passphrase";
private static final String keyFilename =
System.getProperty("test.src", ".") + "/" + pathToStores
+ "/" + keyStoreFile;
private static final String trustFilename =
System.getProperty("test.src", ".") + "/" + pathToStores
+ "/" + trustStoreFile;
/*
* Main entry point for this test.
*/
public static void main(String args[]) throws Exception {
// reset security properties to make sure that the algorithms
// and keys used in this test are not disabled.
Security.setProperty("jdk.tls.disabledAlgorithms", "");
Security.setProperty("jdk.certpath.disabledAlgorithms", "");
if (debug) {
System.setProperty("javax.net.debug", "all");
}
String [] protocols = new String [] {
"SSLv3", "TLSv1", "TLSv1.1", "TLSv1.2" };
for (String protocol : protocols) {
log("Testing " + protocol);
/*
* Run the tests with direct and indirect buffers.
*/
SSLSocketSSLEngineTemplate test =
new SSLSocketSSLEngineTemplate(protocol);
log("-------------------------------------");
log("Testing " + protocol + " for direct buffers ...");
test.runTest(true);
log("---------------------------------------");
log("Testing " + protocol + " for indirect buffers ...");
test.runTest(false);
}
System.out.println("Test Passed.");
}
/*
* Create an initialized SSLContext to use for these tests.
*/
public SSLSocketSSLEngineTemplate(String protocol) throws Exception {
KeyStore ks = KeyStore.getInstance("JKS");
KeyStore ts = KeyStore.getInstance("JKS");
char[] passphrase = "passphrase".toCharArray();
try (FileInputStream keyFile = new FileInputStream(keyFilename);
FileInputStream trustFile = new FileInputStream(trustFilename)) {
ks.load(keyFile, passphrase);
ts.load(trustFile, passphrase);
}
KeyManagerFactory kmf = KeyManagerFactory.getInstance("SunX509");
kmf.init(ks, passphrase);
TrustManagerFactory tmf = TrustManagerFactory.getInstance("SunX509");
tmf.init(ts);
SSLContext sslCtx = SSLContext.getInstance(protocol);
sslCtx.init(kmf.getKeyManagers(), tmf.getTrustManagers(), null);
sslc = sslCtx;
}
/*
* Run the test.
*
* Sit in a tight loop, with the server engine calling wrap/unwrap
* regardless of whether data is available or not. We do this until
* we get the application data. Then we shutdown and go to the next one.
*
* The main loop handles all of the I/O phases of the SSLEngine's
* lifetime:
*
* initial handshaking
* application data transfer
* engine closing
*
* One could easily separate these phases into separate
* sections of code.
*/
private void runTest(boolean direct) throws Exception {
boolean serverClose = direct;
// generates the server-side Socket
try (ServerSocket serverSocket = new ServerSocket()) {
serverSocket.setReuseAddress(false);
serverSocket.bind(null);
int port = serverSocket.getLocalPort();
Thread thread = createClientThread(port, serverClose);
createSSLEngine();
createBuffers(direct);
// server-side socket that will read
try (Socket socket = serverSocket.accept()) {
socket.setSoTimeout(500);
boolean closed = false;
// will try to read one more time in case client message
// is fragmented to multiple pieces
boolean retry = true;
InputStream is = socket.getInputStream();
OutputStream os = socket.getOutputStream();
SSLEngineResult serverResult; // results from last operation
/*
* Examining the SSLEngineResults could be much more involved,
* and may alter the overall flow of the application.
*
* For example, if we received a BUFFER_OVERFLOW when trying
* to write to the output pipe, we could reallocate a larger
* pipe, but instead we wait for the peer to drain it.
*/
byte[] inbound = new byte[8192];
byte[] outbound = new byte[8192];
while (!isEngineClosed(serverEngine)) {
int len;
// Inbound data
log("================");
// Read from the Client side.
try {
len = is.read(inbound);
if (len == -1) {
throw new Exception("Unexpected EOF");
}
cTOs.put(inbound, 0, len);
} catch (SocketTimeoutException ste) {
// swallow. Nothing yet, probably waiting on us.
}
cTOs.flip();
serverResult = serverEngine.unwrap(cTOs, serverIn);
log("server unwrap: ", serverResult);
runDelegatedTasks(serverResult, serverEngine);
cTOs.compact();
// Outbound data
log("----");
serverResult = serverEngine.wrap(serverOut, sTOc);
log("server wrap: ", serverResult);
runDelegatedTasks(serverResult, serverEngine);
sTOc.flip();
if ((len = sTOc.remaining()) != 0) {
sTOc.get(outbound, 0, len);
os.write(outbound, 0, len);
// Give the other side a chance to process
}
sTOc.compact();
if (!closed && (serverOut.remaining() == 0)) {
closed = true;
/*
* We'll alternate initiatating the shutdown.
* When the server initiates, it will take one more
* loop, but tests the orderly shutdown.
*/
if (serverClose) {
serverEngine.closeOutbound();
}
serverIn.flip();
/*
* A sanity check to ensure we got what was sent.
*/
if (serverIn.remaining() != clientMsg.length) {
if (retry &&
serverIn.remaining() < clientMsg.length) {
log("Need to read more from client");
serverIn.compact();
retry = false;
continue;
} else {
throw new Exception(
"Client: Data length error");
}
}
for (int i = 0; i < clientMsg.length; i++) {
if (clientMsg[i] != serverIn.get()) {
throw new Exception(
"Client: Data content error");
}
}
serverIn.compact();
}
}
} catch (Exception e) {
serverException = e;
} finally {
// Wait for the client to join up with us.
if (thread != null) {
thread.join();
}
}
} finally {
if (serverException != null) {
if (clientException != null) {
serverException.initCause(clientException);
}
throw serverException;
}
if (clientException != null) {
if (serverException != null) {
clientException.initCause(serverException);
}
throw clientException;
}
}
}
/*
* Create a client thread which does simple SSLSocket operations.
* We'll write and read one data packet.
*/
private Thread createClientThread(final int port,
final boolean serverClose) throws Exception {
Thread t = new Thread("ClientThread") {
@Override
public void run() {
// client-side socket
try (SSLSocket sslSocket = (SSLSocket)sslc.getSocketFactory().
createSocket("localhost", port)) {
OutputStream os = sslSocket.getOutputStream();
InputStream is = sslSocket.getInputStream();
// write(byte[]) goes in one shot.
os.write(clientMsg);
byte[] inbound = new byte[2048];
int pos = 0;
int len;
while ((len = is.read(inbound, pos, 2048 - pos)) != -1) {
pos += len;
// Let the client do the closing.
if ((pos == serverMsg.length) && !serverClose) {
sslSocket.close();
break;
}
}
if (pos != serverMsg.length) {
throw new Exception("Client: Data length error");
}
for (int i = 0; i < serverMsg.length; i++) {
if (inbound[i] != serverMsg[i]) {
throw new Exception("Client: Data content error");
}
}
} catch (Exception e) {
clientException = e;
}
}
};
t.start();
return t;
}
/*
* Using the SSLContext created during object creation,
* create/configure the SSLEngines we'll use for this test.
*/
private void createSSLEngine() throws Exception {
/*
* Configure the serverEngine to act as a server in the SSL/TLS
* handshake.
*/
serverEngine = sslc.createSSLEngine();
serverEngine.setUseClientMode(false);
serverEngine.getNeedClientAuth();
}
/*
* Create and size the buffers appropriately.
*/
private void createBuffers(boolean direct) {
SSLSession session = serverEngine.getSession();
int appBufferMax = session.getApplicationBufferSize();
int netBufferMax = session.getPacketBufferSize();
/*
* We'll make the input buffers a bit bigger than the max needed
* size, so that unwrap()s following a successful data transfer
* won't generate BUFFER_OVERFLOWS.
*
* We'll use a mix of direct and indirect ByteBuffers for
* tutorial purposes only. In reality, only use direct
* ByteBuffers when they give a clear performance enhancement.
*/
if (direct) {
serverIn = ByteBuffer.allocateDirect(appBufferMax + 50);
cTOs = ByteBuffer.allocateDirect(netBufferMax);
sTOc = ByteBuffer.allocateDirect(netBufferMax);
} else {
serverIn = ByteBuffer.allocate(appBufferMax + 50);
cTOs = ByteBuffer.allocate(netBufferMax);
sTOc = ByteBuffer.allocate(netBufferMax);
}
serverOut = ByteBuffer.wrap(serverMsg);
}
/*
* If the result indicates that we have outstanding tasks to do,
* go ahead and run them in this thread.
*/
private static void runDelegatedTasks(SSLEngineResult result,
SSLEngine engine) throws Exception {
if (result.getHandshakeStatus() == HandshakeStatus.NEED_TASK) {
Runnable runnable;
while ((runnable = engine.getDelegatedTask()) != null) {
log("\trunning delegated task...");
runnable.run();
}
HandshakeStatus hsStatus = engine.getHandshakeStatus();
if (hsStatus == HandshakeStatus.NEED_TASK) {
throw new Exception(
"handshake shouldn't need additional tasks");
}
log("\tnew HandshakeStatus: " + hsStatus);
}
}
private static boolean isEngineClosed(SSLEngine engine) {
return (engine.isOutboundDone() && engine.isInboundDone());
}
/*
* Logging code
*/
private static boolean resultOnce = true;
private static void log(String str, SSLEngineResult result) {
if (!logging) {
return;
}
if (resultOnce) {
resultOnce = false;
System.out.println("The format of the SSLEngineResult is: \n"
+ "\t\"getStatus() / getHandshakeStatus()\" +\n"
+ "\t\"bytesConsumed() / bytesProduced()\"\n");
}
HandshakeStatus hsStatus = result.getHandshakeStatus();
log(str
+ result.getStatus() + "/" + hsStatus + ", "
+ result.bytesConsumed() + "/" + result.bytesProduced()
+ " bytes");
if (hsStatus == HandshakeStatus.FINISHED) {
log("\t...ready for application data");
}
}
private static void log(String str) {
if (logging) {
System.out.println(str);
}
}
}