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The Bouncy Castle Java APIs for the TLS, including a JSSE provider. The APIs are designed primarily to be used in conjunction with the BC LTS provider but may also be used with other providers providing cryptographic services.

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package org.bouncycastle.tls;

import java.io.ByteArrayInputStream;
import java.io.ByteArrayOutputStream;
import java.io.EOFException;
import java.io.IOException;
import java.io.InputStream;
import java.io.InterruptedIOException;
import java.io.OutputStream;
import java.nio.ByteBuffer;
import java.util.Enumeration;
import java.util.Hashtable;
import java.util.Vector;

import org.bouncycastle.tls.crypto.TlsCrypto;
import org.bouncycastle.tls.crypto.TlsSecret;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.Integers;

public abstract class TlsProtocol
    implements TlsCloseable
{
    protected static final Integer EXT_RenegotiationInfo = Integers.valueOf(ExtensionType.renegotiation_info);
    protected static final Integer EXT_SessionTicket = Integers.valueOf(ExtensionType.session_ticket);

    /*
     * Connection States.
     * 
     * NOTE: Redirection of handshake messages to TLS 1.3 handlers assumes CS_START, CS_CLIENT_HELLO
     * are lower than any of the other values.
     */
    protected static final short CS_START = 0;
    protected static final short CS_CLIENT_HELLO = 1;
    protected static final short CS_SERVER_HELLO_RETRY_REQUEST = 2;
    protected static final short CS_CLIENT_HELLO_RETRY = 3;
    protected static final short CS_SERVER_HELLO = 4;
    protected static final short CS_SERVER_ENCRYPTED_EXTENSIONS = 5;
    protected static final short CS_SERVER_SUPPLEMENTAL_DATA = 6;
    protected static final short CS_SERVER_CERTIFICATE = 7;
    protected static final short CS_SERVER_CERTIFICATE_STATUS = 8;
    protected static final short CS_SERVER_CERTIFICATE_VERIFY = 9;
    protected static final short CS_SERVER_KEY_EXCHANGE = 10;
    protected static final short CS_SERVER_CERTIFICATE_REQUEST = 11;
    protected static final short CS_SERVER_HELLO_DONE = 12;
    protected static final short CS_CLIENT_END_OF_EARLY_DATA = 13;
    protected static final short CS_CLIENT_SUPPLEMENTAL_DATA = 14;
    protected static final short CS_CLIENT_CERTIFICATE = 15;
    protected static final short CS_CLIENT_KEY_EXCHANGE = 16;
    protected static final short CS_CLIENT_CERTIFICATE_VERIFY = 17;
    protected static final short CS_CLIENT_FINISHED = 18;
    protected static final short CS_SERVER_SESSION_TICKET = 19;
    protected static final short CS_SERVER_FINISHED = 20;
    protected static final short CS_END = 21;

    protected boolean isLegacyConnectionState()
    {
        switch (connection_state)
        {
        case CS_START:
        case CS_CLIENT_HELLO:
        case CS_SERVER_HELLO:
        case CS_SERVER_SUPPLEMENTAL_DATA:
        case CS_SERVER_CERTIFICATE:
        case CS_SERVER_CERTIFICATE_STATUS:
        case CS_SERVER_KEY_EXCHANGE:
        case CS_SERVER_CERTIFICATE_REQUEST:
        case CS_SERVER_HELLO_DONE:
        case CS_CLIENT_SUPPLEMENTAL_DATA:
        case CS_CLIENT_CERTIFICATE:
        case CS_CLIENT_KEY_EXCHANGE:
        case CS_CLIENT_CERTIFICATE_VERIFY:
        case CS_CLIENT_FINISHED:
        case CS_SERVER_SESSION_TICKET:
        case CS_SERVER_FINISHED:
        case CS_END:
            return true;

        case CS_SERVER_HELLO_RETRY_REQUEST:
        case CS_CLIENT_HELLO_RETRY:
        case CS_SERVER_ENCRYPTED_EXTENSIONS:
        case CS_SERVER_CERTIFICATE_VERIFY:
        case CS_CLIENT_END_OF_EARLY_DATA:
        default:
            return false;
        }
    }

    protected boolean isTLSv13ConnectionState()
    {
        switch (connection_state)
        {
        case CS_START:
        case CS_CLIENT_HELLO:
        case CS_SERVER_HELLO_RETRY_REQUEST:
        case CS_CLIENT_HELLO_RETRY:
        case CS_SERVER_HELLO:
        case CS_SERVER_ENCRYPTED_EXTENSIONS:
        case CS_SERVER_CERTIFICATE_REQUEST:
        case CS_SERVER_CERTIFICATE:
        case CS_SERVER_CERTIFICATE_VERIFY:
        case CS_SERVER_FINISHED:
        case CS_CLIENT_END_OF_EARLY_DATA:
        case CS_CLIENT_CERTIFICATE:
        case CS_CLIENT_CERTIFICATE_VERIFY:
        case CS_CLIENT_FINISHED:
        case CS_END:
            return true;

        case CS_SERVER_SUPPLEMENTAL_DATA:
        case CS_SERVER_CERTIFICATE_STATUS:
        case CS_SERVER_KEY_EXCHANGE:
        case CS_SERVER_HELLO_DONE:
        case CS_CLIENT_SUPPLEMENTAL_DATA:
        case CS_CLIENT_KEY_EXCHANGE:
        case CS_SERVER_SESSION_TICKET:
        default:
            return false;
        }
    }

    /*
     * Different modes to handle the known IV weakness
     */
    protected static final short ADS_MODE_1_Nsub1 = 0; // 1/n-1 record splitting
    protected static final short ADS_MODE_0_N = 1; // 0/n record splitting
    protected static final short ADS_MODE_0_N_FIRSTONLY = 2; // 0/n record splitting on first data fragment only

    /*
     * Queues for data from some protocols.
     */
    private ByteQueue applicationDataQueue = new ByteQueue(0);
    private ByteQueue alertQueue = new ByteQueue(2);
    private ByteQueue handshakeQueue = new ByteQueue(0);
//    private ByteQueue heartbeatQueue = new ByteQueue();

    final RecordStream recordStream;
    final Object recordWriteLock = new Object();

    private int maxHandshakeMessageSize = -1;

    TlsHandshakeHash handshakeHash;

    private TlsInputStream tlsInputStream = null;
    private TlsOutputStream tlsOutputStream = null;

    private volatile boolean closed = false;
    private volatile boolean failedWithError = false;
    private volatile boolean appDataReady = false;
    private volatile boolean appDataSplitEnabled = true;
    private volatile boolean keyUpdateEnabled = false;
//    private volatile boolean keyUpdatePendingReceive = false;
    private volatile boolean keyUpdatePendingSend = false;
    private volatile boolean resumableHandshake = false;
    private volatile int appDataSplitMode = ADS_MODE_1_Nsub1;

    protected TlsSession tlsSession = null;
    protected SessionParameters sessionParameters = null;
    protected TlsSecret sessionMasterSecret = null;

    protected byte[] retryCookie = null;
    protected int retryGroup = -1;
    protected Hashtable clientExtensions = null;
    protected Hashtable serverExtensions = null;

    protected short connection_state = CS_START;
    protected boolean selectedPSK13 = false;
    protected boolean receivedChangeCipherSpec = false;
    protected boolean expectSessionTicket = false;

    protected boolean blocking;
    protected ByteQueueInputStream inputBuffers;
    protected ByteQueueOutputStream outputBuffer;

    protected TlsProtocol()
    {
        this.blocking = false;
        this.inputBuffers = new ByteQueueInputStream();
        this.outputBuffer = new ByteQueueOutputStream();
        this.recordStream = new RecordStream(this, inputBuffers, outputBuffer);
    }

    protected TlsProtocol(InputStream input, OutputStream output)
    {
        this.blocking = true;
        this.recordStream = new RecordStream(this, input, output);
    }

//    public boolean renegotiate() throws IOException
//    {
//        TlsContext context = getContext();
//        if (null == context.getSecurityParametersConnection() || isClosed())
//        {
//            throw new IllegalStateException("No connection");
//        }
//        if (!appDataReady)
//        {
//            throw new IllegalStateException("Initial handshake in progress");
//        }
//        return null == context.getSecurityParametersHandshake() && CS_END == connection_state;
//    }

    public void resumeHandshake() throws IOException
    {
        if (!blocking)
        {
            throw new IllegalStateException("Cannot use resumeHandshake() in non-blocking mode!");
        }
        if (!isHandshaking())
        {
            throw new IllegalStateException("No handshake in progress");
        }

        blockForHandshake();
    }

    protected void closeConnection() throws IOException
    {
        recordStream.close();
    }

    protected abstract TlsContext getContext();

    abstract AbstractTlsContext getContextAdmin();

    protected abstract TlsPeer getPeer();

    protected int getRenegotiationPolicy()
    {
        return RenegotiationPolicy.DENY;
    }

    protected void handleAlertMessage(short alertLevel, short alertDescription)
        throws IOException
    {
        getPeer().notifyAlertReceived(alertLevel, alertDescription);

        if (alertLevel == AlertLevel.warning)
        {
            handleAlertWarningMessage(alertDescription);
        }
        else
        {
            handleFailure();

            throw new TlsFatalAlertReceived(alertDescription);
        }
    }

    protected void handleAlertWarningMessage(short alertDescription)
        throws IOException
    {
        switch (alertDescription)
        {
        /*
         * RFC 5246 7.2.1. The other party MUST respond with a close_notify alert of its own
         * and close down the connection immediately, discarding any pending writes.
         */
        case AlertDescription.close_notify:
        {
            if (!appDataReady)
            {
                throw new TlsFatalAlert(AlertDescription.handshake_failure);
            }
            handleClose(false);
            break;
        }
        case AlertDescription.no_certificate:
        {
            throw new TlsFatalAlert(AlertDescription.unexpected_message);
        }
        case AlertDescription.no_renegotiation:
        {
            // TODO[reneg] Give peer the option to tolerate this
            throw new TlsFatalAlert(AlertDescription.handshake_failure);
        }
        }
    }

    protected void handleChangeCipherSpecMessage() throws IOException
    {
    }

    protected void handleClose(boolean user_canceled)
        throws IOException
    {
        if (!closed)
        {
            this.closed = true;

            if (!appDataReady)
            {
                cleanupHandshake();

                if (user_canceled)
                {
                    raiseAlertWarning(AlertDescription.user_canceled, "User canceled handshake");
                }
            }

            raiseAlertWarning(AlertDescription.close_notify, "Connection closed");

            closeConnection();

            getPeer().notifyConnectionClosed();
        }
    }

    protected void handleException(short alertDescription, String message, Throwable e)
        throws IOException
    {
        if ((appDataReady || isResumableHandshake()) && (e instanceof InterruptedIOException))
        {
            return;
        }

        if (!closed)
        {
            raiseAlertFatal(alertDescription, message, e);

            handleFailure();
        }
    }

    protected void handleFailure() throws IOException
    {
        this.closed = true;
        this.failedWithError = true;

        /*
         * RFC 2246 7.2.1. The session becomes unresumable if any connection is terminated
         * without proper close_notify messages with level equal to warning.
         */
        // TODO This isn't quite in the right place. Also, as of TLS 1.1 the above is obsolete.
        invalidateSession();

        if (!appDataReady)
        {
            cleanupHandshake();
        }

        closeConnection();

        getPeer().notifyConnectionClosed();
    }

    protected abstract void handleHandshakeMessage(short type, HandshakeMessageInput buf)
        throws IOException;

    protected boolean handleRenegotiation() throws IOException
    {
        int renegotiationPolicy = RenegotiationPolicy.DENY;

        /*
         * Never renegotiate without secure renegotiation and server certificate authentication. Also, per RFC
         * 7627 5.4, renegotiation MUST be disabled for session resumption without extended_master_secret.
         */
        {
            SecurityParameters securityParameters = getContext().getSecurityParametersConnection();
            if (null != securityParameters &&
                securityParameters.isSecureRenegotiation() &&
                (!securityParameters.isResumedSession() || securityParameters.isExtendedMasterSecret()))
            {
                Certificate serverCertificate = ConnectionEnd.server == securityParameters.getEntity()
                    ?   securityParameters.getLocalCertificate()
                    :   securityParameters.getPeerCertificate();

                if (null != serverCertificate && !serverCertificate.isEmpty())
                {
                    renegotiationPolicy = getRenegotiationPolicy();
                }
            }
        }

        switch (renegotiationPolicy)
        {
        case RenegotiationPolicy.ACCEPT:
        {
            beginHandshake(true);
            return true;
        }
        case RenegotiationPolicy.IGNORE:
        {
            return false;
        }
        case RenegotiationPolicy.DENY:
        default:
        {
            refuseRenegotiation();
            return false;
        }
        }
    }

    protected void applyMaxFragmentLengthExtension(short maxFragmentLength) throws IOException
    {
        if (maxFragmentLength >= 0)
        {
            if (!MaxFragmentLength.isValid(maxFragmentLength))
            {
                throw new TlsFatalAlert(AlertDescription.internal_error);
            }

            int plainTextLimit = 1 << (8 + maxFragmentLength);
            recordStream.setPlaintextLimit(plainTextLimit);
        }
    }

    protected void checkReceivedChangeCipherSpec(boolean expected)
        throws IOException
    {
        if (expected != receivedChangeCipherSpec)
        {
            throw new TlsFatalAlert(AlertDescription.unexpected_message);
        }
    }

    protected void blockForHandshake() throws IOException
    {
        while (this.connection_state != CS_END)
        {
            if (isClosed())
            {
                // NOTE: Any close during the handshake should have raised an exception.
                throw new TlsFatalAlert(AlertDescription.internal_error);
            }

            safeReadRecord();
        }
    }

    protected void beginHandshake(boolean renegotiation)
        throws IOException
    {
        AbstractTlsContext context = getContextAdmin(); 
        TlsPeer peer = getPeer();

        this.maxHandshakeMessageSize = Math.max(1024, peer.getMaxHandshakeMessageSize());

        this.handshakeHash = new DeferredHash(context);
        this.connection_state = CS_START;
        this.selectedPSK13 = false;

        context.handshakeBeginning(peer);

        SecurityParameters securityParameters = context.getSecurityParametersHandshake();
        if (renegotiation != securityParameters.isRenegotiating())
        {
            throw new TlsFatalAlert(AlertDescription.internal_error);
        }

        securityParameters.extendedPadding = peer.shouldUseExtendedPadding();
    }

    protected void cleanupHandshake()
    {
        TlsContext context = getContext();
        if (null != context)
        {
            SecurityParameters securityParameters = context.getSecurityParameters();
            if (null != securityParameters)
            {
                securityParameters.clear();
            }
        }

        this.tlsSession = null;
        this.sessionParameters = null;
        this.sessionMasterSecret = null;

        this.retryCookie = null;
        this.retryGroup = -1;
        this.clientExtensions = null;
        this.serverExtensions = null;

        this.selectedPSK13 = false;
        this.receivedChangeCipherSpec = false;
        this.expectSessionTicket = false;
    }

    protected void completeHandshake()
        throws IOException
    {
        try
        {
            AbstractTlsContext context = getContextAdmin();
            SecurityParameters securityParameters = context.getSecurityParametersHandshake();

            if (!context.isHandshaking() ||
                null == securityParameters.getLocalVerifyData() ||
                null == securityParameters.getPeerVerifyData())
            {
                throw new TlsFatalAlert(AlertDescription.internal_error);
            }

            this.recordStream.finaliseHandshake();
            this.connection_state = CS_END;

            // TODO Prefer to set to null, but would need guards elsewhere
            this.handshakeHash = new DeferredHash(context);

            this.alertQueue.shrink();
            this.handshakeQueue.shrink();

            ProtocolVersion negotiatedVersion = securityParameters.getNegotiatedVersion();

            this.appDataSplitEnabled = !TlsUtils.isTLSv11(negotiatedVersion);
            this.appDataReady = true;

            this.keyUpdateEnabled = TlsUtils.isTLSv13(negotiatedVersion);

            if (blocking)
            {
                this.tlsInputStream = new TlsInputStream(this);
                this.tlsOutputStream = new TlsOutputStream(this);
            }

            if (this.sessionParameters == null)
            {
                this.sessionMasterSecret = securityParameters.getMasterSecret();

                this.sessionParameters = new SessionParameters.Builder()
                    .setCipherSuite(securityParameters.getCipherSuite())
                    .setExtendedMasterSecret(securityParameters.isExtendedMasterSecret())
                    .setLocalCertificate(securityParameters.getLocalCertificate())
                    .setMasterSecret(context.getCrypto().adoptSecret(this.sessionMasterSecret))
                    .setNegotiatedVersion(securityParameters.getNegotiatedVersion())
                    .setPeerCertificate(securityParameters.getPeerCertificate())
                    .setPSKIdentity(securityParameters.getPSKIdentity())
                    .setSRPIdentity(securityParameters.getSRPIdentity())
                    // TODO Consider filtering extensions that aren't relevant to resumed sessions
                    .setServerExtensions(this.serverExtensions)
                    .build();

                this.tlsSession = TlsUtils.importSession(securityParameters.getSessionID(), this.sessionParameters);
            }
            else
            {
                securityParameters.localCertificate = sessionParameters.getLocalCertificate();
                securityParameters.peerCertificate = sessionParameters.getPeerCertificate();
                securityParameters.pskIdentity = sessionParameters.getPSKIdentity();
                securityParameters.srpIdentity = sessionParameters.getSRPIdentity();
            }

            context.handshakeComplete(getPeer(), this.tlsSession);
        }
        finally
        {
            cleanupHandshake();
        }
    }

    protected void processRecord(short protocol, byte[] buf, int off, int len)
        throws IOException
    {
        /*
         * Have a look at the protocol type, and add it to the correct queue.
         */
        switch (protocol)
        {
        case ContentType.alert:
        {
            alertQueue.addData(buf, off, len);
            processAlertQueue();
            break;
        }
        case ContentType.application_data:
        {
            if (!appDataReady)
            {
                throw new TlsFatalAlert(AlertDescription.unexpected_message);
            }
            applicationDataQueue.addData(buf, off, len);
            processApplicationDataQueue();
            break;
        }
        case ContentType.change_cipher_spec:
        {
            processChangeCipherSpec(buf, off, len);
            break;
        }
        case ContentType.handshake:
        {
            if (handshakeQueue.available() > 0)
            {
                handshakeQueue.addData(buf, off, len);
                processHandshakeQueue(handshakeQueue);
            }
            else
            {
                ByteQueue tmpQueue = new ByteQueue(buf, off, len);
                processHandshakeQueue(tmpQueue);
                int remaining = tmpQueue.available();
                if (remaining > 0)
                {
                    handshakeQueue.addData(buf, off + len - remaining, remaining);
                }
            }
            break;
        }
//        case ContentType.heartbeat:
//        {
//            if (!appDataReady)
//            {
//                throw new TlsFatalAlert(AlertDescription.unexpected_message);
//            }
//            // TODO[RFC 6520]
////            heartbeatQueue.addData(buf, off, len);
////            processHeartbeatQueue();
//            break;
//        }
        default:
            throw new TlsFatalAlert(AlertDescription.unexpected_message);
        }
    }

    private void processHandshakeQueue(ByteQueue queue)
        throws IOException
    {
        /*
         * We need the first 4 bytes, they contain type and length of the message.
         */
        while (queue.available() >= 4)
        {
            int header = queue.readInt32();

            short type = (short)(header >>> 24);
            if (!HandshakeType.isRecognized(type))
            {
                throw new TlsFatalAlert(AlertDescription.unexpected_message,
                    "Handshake message of unrecognized type: " + type);
            }

            int length = header & 0x00FFFFFF;
            if (length > maxHandshakeMessageSize)
            {
                throw new TlsFatalAlert(AlertDescription.internal_error,
                    "Handshake message length exceeds the maximum: " + HandshakeType.getText(type) + ", " + length
                        + " > " + maxHandshakeMessageSize);
            }

            int totalLength = 4 + length;
            if (queue.available() < totalLength)
            {
                // Not enough bytes in the buffer to read the full message.
                break;
            }

            /*
             * Check ChangeCipherSpec status
             */
            switch (type)
            {
            case HandshakeType.hello_request:
                break;

            default:
            {
                ProtocolVersion negotiatedVersion = getContext().getServerVersion();
                if (null != negotiatedVersion && TlsUtils.isTLSv13(negotiatedVersion))
                {
                    break;
                }

                checkReceivedChangeCipherSpec(HandshakeType.finished == type);
                break;
            }
            }

            HandshakeMessageInput buf = queue.readHandshakeMessage(totalLength);

            switch (type)
            {
            /*
             * These message types aren't included in the transcript.
             */
            case HandshakeType.hello_request:
            case HandshakeType.key_update:
                break;

            /*
             * Not included in the transcript for (D)TLS 1.3+
             */
            case HandshakeType.new_session_ticket:
            {
                ProtocolVersion negotiatedVersion = getContext().getServerVersion();
                if (null != negotiatedVersion && !TlsUtils.isTLSv13(negotiatedVersion))
                {
                    buf.updateHash(handshakeHash);
                }

                break;
            }

            /*
             * These message types are deferred to the handler to explicitly update the transcript.
             */
            case HandshakeType.certificate_verify:
            case HandshakeType.client_hello:
            case HandshakeType.finished:
            case HandshakeType.server_hello:
                break;

            /*
             * For all others we automatically update the transcript immediately. 
             */
            default:
            {
                buf.updateHash(handshakeHash);
                break;
            }
            }

            buf.skip(4);

            handleHandshakeMessage(type, buf);
        }
    }

    private void processApplicationDataQueue()
    {
        /*
         * There is nothing we need to do here.
         * 
         * This function could be used for callbacks when application data arrives in the future.
         */
    }

    private void processAlertQueue()
        throws IOException
    {
        while (alertQueue.available() >= 2)
        {
            /*
             * An alert is always 2 bytes. Read the alert.
             */
            byte[] alert = alertQueue.removeData(2, 0);
            short alertLevel = alert[0];
            short alertDescription = alert[1];

            handleAlertMessage(alertLevel, alertDescription);
        }
    }

    /**
     * This method is called, when a change cipher spec message is received.
     *
     * @throws IOException If the message has an invalid content or the handshake is not in the correct
     * state.
     */
    private void processChangeCipherSpec(byte[] buf, int off, int len)
        throws IOException
    {
        ProtocolVersion negotiatedVersion = getContext().getServerVersion();
        if (null == negotiatedVersion || TlsUtils.isTLSv13(negotiatedVersion))
        {
            // See RFC 8446 D.4.
            throw new TlsFatalAlert(AlertDescription.unexpected_message);
        }

        for (int i = 0; i < len; ++i)
        {
            short message = TlsUtils.readUint8(buf, off + i);

            if (message != ChangeCipherSpec.change_cipher_spec)
            {
                throw new TlsFatalAlert(AlertDescription.decode_error);
            }

            if (this.receivedChangeCipherSpec
                || alertQueue.available() > 0
                || handshakeQueue.available() > 0)
            {
                throw new TlsFatalAlert(AlertDescription.unexpected_message);
            }

            recordStream.notifyChangeCipherSpecReceived();

            this.receivedChangeCipherSpec = true;

            handleChangeCipherSpecMessage();
        }
    }

    public int applicationDataAvailable()
    {
        return applicationDataQueue.available();
    }

    /**
     * Read data from the network. The method will return immediately, if there is still some data left in the
     * buffer, or block until some application data has been read from the network.
     *
     * @param buf The buffer where the data will be copied to.
     * @param off The position where the data will be placed in the buffer.
     * @param len The maximum number of bytes to read.
     * @return The number of bytes read.
     * @throws IOException If something goes wrong during reading data.
     */
    public int readApplicationData(byte[] buf, int off, int len)
        throws IOException
    {
        // TODO Use method once available in bc-fips-java
//        Streams.validateBufferArguments(buf, off, len);
        {
            if (buf == null)
            {
                throw new NullPointerException();
            }
            int available = buf.length - off;
            int remaining = available - len;
            if ((off | len | available | remaining) < 0)
            {
                throw new IndexOutOfBoundsException();
            }
        }

        if (!appDataReady)
        {
            throw new IllegalStateException("Cannot read application data until initial handshake completed.");
        }

        if (len < 1)
        {
            return 0;
        }

        while (applicationDataQueue.available() < 1)
        {
            if (this.closed)
            {
                if (this.failedWithError)
                {
                    throw new IOException("Cannot read application data on failed TLS connection");
                }
                return -1;
            }

            /*
             * NOTE: Only called more than once when empty records are received, so no special
             * InterruptedIOException handling is necessary.
             */
            safeReadRecord();
        }

        len = Math.min(len, applicationDataQueue.available());
        applicationDataQueue.removeData(buf, off, len, 0);
        return len;
    }

    protected RecordPreview safePreviewRecordHeader(byte[] recordHeader)
        throws IOException
    {
        try
        {
            return recordStream.previewRecordHeader(recordHeader);
        }
        catch (TlsFatalAlert e)
        {
            handleException(e.getAlertDescription(), "Failed to read record", e);
            throw e;
        }
        catch (IOException e)
        {
            handleException(AlertDescription.internal_error, "Failed to read record", e);
            throw e;
        }
        catch (RuntimeException e)
        {
            handleException(AlertDescription.internal_error, "Failed to read record", e);
            throw new TlsFatalAlert(AlertDescription.internal_error, e);
        }
    }

    protected void safeReadRecord()
        throws IOException
    {
        try
        {
            if (recordStream.readRecord())
            {
                return;
            }

            if (!appDataReady)
            {
                throw new TlsFatalAlert(AlertDescription.handshake_failure);
            }

            if (!getPeer().requiresCloseNotify())
            {
                handleClose(false);
                return;
            }
        }
        catch (TlsFatalAlertReceived e)
        {
            // Connection failure already handled at source
            throw e;
        }
        catch (TlsFatalAlert e)
        {
            handleException(e.getAlertDescription(), "Failed to read record", e);
            throw e;
        }
        catch (IOException e)
        {
            handleException(AlertDescription.internal_error, "Failed to read record", e);
            throw e;
        }
        catch (RuntimeException e)
        {
            handleException(AlertDescription.internal_error, "Failed to read record", e);
            throw new TlsFatalAlert(AlertDescription.internal_error, e);
        }

        handleFailure();

        throw new TlsNoCloseNotifyException();
    }

    protected boolean safeReadFullRecord(byte[] input, int inputOff, int inputLen)
        throws IOException
    {
        try
        {
            return recordStream.readFullRecord(input, inputOff, inputLen);
        }
        catch (TlsFatalAlert e)
        {
            handleException(e.getAlertDescription(), "Failed to process record", e);
            throw e;
        }
        catch (IOException e)
        {
            handleException(AlertDescription.internal_error, "Failed to process record", e);
            throw e;
        }
        catch (RuntimeException e)
        {
            handleException(AlertDescription.internal_error, "Failed to process record", e);
            throw new TlsFatalAlert(AlertDescription.internal_error, e);
        }
    }

    protected void safeWriteRecord(short type, byte[] buf, int offset, int len)
        throws IOException
    {
        try
        {
            recordStream.writeRecord(type, buf, offset, len);
        }
        catch (TlsFatalAlert e)
        {
            handleException(e.getAlertDescription(), "Failed to write record", e);
            throw e;
        }
        catch (IOException e)
        {
            handleException(AlertDescription.internal_error, "Failed to write record", e);
            throw e;
        }
        catch (RuntimeException e)
        {
            handleException(AlertDescription.internal_error, "Failed to write record", e);
            throw new TlsFatalAlert(AlertDescription.internal_error, e);
        }
    }

    /**
     * Write some application data. Fragmentation is handled internally. Usable in both blocking/non-blocking
     * modes.
*
* In blocking mode, the output will be automatically sent via the underlying transport. In non-blocking * mode, call {@link #readOutput(byte[], int, int)} to get the output bytes to send to the peer.
*
* This method must not be called until after the initial handshake is complete. Attempting to call it * earlier will result in an {@link IllegalStateException}. * * @param buf The buffer containing application data to send * @param off The offset at which the application data begins * @param len The number of bytes of application data * @throws IllegalStateException If called before the initial handshake has completed. * @throws IOException If connection is already closed, or for encryption or transport errors. */ public void writeApplicationData(byte[] buf, int off, int len) throws IOException { // TODO Use method once available in bc-fips-java // Streams.validateBufferArguments(buf, off, len); { if (buf == null) { throw new NullPointerException(); } int available = buf.length - off; int remaining = available - len; if ((off | len | available | remaining) < 0) { throw new IndexOutOfBoundsException(); } } if (!appDataReady) { throw new IllegalStateException("Cannot write application data until initial handshake completed."); } synchronized (recordWriteLock) { while (len > 0) { if (closed) { throw new IOException("Cannot write application data on closed/failed TLS connection"); } /* * RFC 5246 6.2.1. Zero-length fragments of Application data MAY be sent as they are * potentially useful as a traffic analysis countermeasure. * * NOTE: Actually, implementations appear to have settled on 1/n-1 record splitting. */ if (appDataSplitEnabled) { /* * Protect against known IV attack! * * DO NOT REMOVE THIS CODE, EXCEPT YOU KNOW EXACTLY WHAT YOU ARE DOING HERE. */ switch (appDataSplitMode) { case ADS_MODE_0_N_FIRSTONLY: { this.appDataSplitEnabled = false; // NB: Fall through to next case label } case ADS_MODE_0_N: { safeWriteRecord(ContentType.application_data, TlsUtils.EMPTY_BYTES, 0, 0); break; } case ADS_MODE_1_Nsub1: default: { if (len > 1) { safeWriteRecord(ContentType.application_data, buf, off, 1); ++off; --len; } break; } } } else if (keyUpdateEnabled) { if (keyUpdatePendingSend) { send13KeyUpdate(false); } else if (recordStream.needsKeyUpdate()) { send13KeyUpdate(true); } } // Fragment data according to the current fragment limit. int toWrite = Math.min(len, recordStream.getPlaintextLimit()); safeWriteRecord(ContentType.application_data, buf, off, toWrite); off += toWrite; len -= toWrite; } } } public int getAppDataSplitMode() { return appDataSplitMode; } public void setAppDataSplitMode(int appDataSplitMode) { if (appDataSplitMode < ADS_MODE_1_Nsub1 || appDataSplitMode > ADS_MODE_0_N_FIRSTONLY) { throw new IllegalArgumentException("Illegal appDataSplitMode mode: " + appDataSplitMode); } this.appDataSplitMode = appDataSplitMode; } public boolean isResumableHandshake() { return resumableHandshake; } public void setResumableHandshake(boolean resumableHandshake) { this.resumableHandshake = resumableHandshake; } void writeHandshakeMessage(byte[] buf, int off, int len) throws IOException { if (len < 4) { throw new TlsFatalAlert(AlertDescription.internal_error); } short type = TlsUtils.readUint8(buf, off); switch (type) { /* * These message types aren't included in the transcript. */ case HandshakeType.hello_request: case HandshakeType.key_update: break; /* * Not included in the transcript for (D)TLS 1.3+ */ case HandshakeType.new_session_ticket: { ProtocolVersion negotiatedVersion = getContext().getServerVersion(); if (null != negotiatedVersion && !TlsUtils.isTLSv13(negotiatedVersion)) { handshakeHash.update(buf, off, len); } break; } /* * These message types are deferred to the writer to explicitly update the transcript. */ case HandshakeType.client_hello: break; /* * For all others we automatically update the transcript. */ default: { handshakeHash.update(buf, off, len); break; } } int total = 0; do { // Fragment data according to the current fragment limit. int toWrite = Math.min(len - total, recordStream.getPlaintextLimit()); safeWriteRecord(ContentType.handshake, buf, off + total, toWrite); total += toWrite; } while (total < len); } /** * @return An OutputStream which can be used to send data. Only allowed in blocking mode. */ public OutputStream getOutputStream() { if (!blocking) { throw new IllegalStateException("Cannot use OutputStream in non-blocking mode! Use offerOutput() instead."); } return this.tlsOutputStream; } /** * @return An InputStream which can be used to read data. Only allowed in blocking mode. */ public InputStream getInputStream() { if (!blocking) { throw new IllegalStateException("Cannot use InputStream in non-blocking mode! Use offerInput() instead."); } return this.tlsInputStream; } /** * Should be called in non-blocking mode when the input data reaches EOF. */ public void closeInput() throws IOException { if (blocking) { throw new IllegalStateException("Cannot use closeInput() in blocking mode!"); } if (closed) { return; } if (inputBuffers.available() > 0) { throw new EOFException(); } if (!appDataReady) { throw new TlsFatalAlert(AlertDescription.handshake_failure); } if (!getPeer().requiresCloseNotify()) { handleClose(false); return; } handleFailure(); throw new TlsNoCloseNotifyException(); } public RecordPreview previewInputRecord(byte[] recordHeader) throws IOException { if (blocking) { throw new IllegalStateException("Cannot use previewInputRecord() in blocking mode!"); } if (inputBuffers.available() != 0) { throw new IllegalStateException("Can only use previewInputRecord() for record-aligned input."); } if (closed) { throw new IOException("Connection is closed, cannot accept any more input"); } return safePreviewRecordHeader(recordHeader); } public int previewOutputRecord() { if (blocking) { throw new IllegalStateException("Cannot use previewOutputRecord() in blocking mode!"); } ByteQueue buffer = outputBuffer.getBuffer(); int available = buffer.available(); if (available < 1) { return 0; } if (available >= RecordFormat.FRAGMENT_OFFSET) { int length = buffer.readUint16(RecordFormat.LENGTH_OFFSET); int recordSize = RecordFormat.FRAGMENT_OFFSET + length; if (available >= recordSize) { return recordSize; } } throw new IllegalStateException("Can only use previewOutputRecord() for record-aligned output."); } public RecordPreview previewOutputRecord(int applicationDataSize) throws IOException { if (!appDataReady) { throw new IllegalStateException("Cannot use previewOutputRecord() until initial handshake completed."); } if (blocking) { throw new IllegalStateException("Cannot use previewOutputRecord() in blocking mode!"); } if (outputBuffer.getBuffer().available() != 0) { throw new IllegalStateException("Can only use previewOutputRecord() for record-aligned output."); } if (closed) { throw new IOException("Connection is closed, cannot produce any more output"); } if (applicationDataSize < 1) { return new RecordPreview(0, 0); } if (appDataSplitEnabled) { switch (appDataSplitMode) { case ADS_MODE_0_N_FIRSTONLY: case ADS_MODE_0_N: { RecordPreview a = recordStream.previewOutputRecord(0); RecordPreview b = recordStream.previewOutputRecord(applicationDataSize); return RecordPreview.combineAppData(a, b); } case ADS_MODE_1_Nsub1: default: { RecordPreview a = recordStream.previewOutputRecord(1); if (applicationDataSize > 1) { RecordPreview b = recordStream.previewOutputRecord(applicationDataSize - 1); a = RecordPreview.combineAppData(a, b); } return a; } } } else { RecordPreview a = recordStream.previewOutputRecord(applicationDataSize); if (keyUpdateEnabled && (keyUpdatePendingSend || recordStream.needsKeyUpdate())) { int keyUpdateLength = HandshakeMessageOutput.getLength(1); int recordSize = recordStream.previewOutputRecordSize(keyUpdateLength); a = RecordPreview.extendRecordSize(a, recordSize); } return a; } } /** * Equivalent to offerInput(input, 0, input.length) * @see TlsProtocol#offerInput(byte[], int, int) * @param input The input buffer to offer * @throws IOException If an error occurs while decrypting or processing a record */ public void offerInput(byte[] input) throws IOException { offerInput(input, 0, input.length); } /** * Offer input from an arbitrary source. Only allowed in non-blocking mode.
*
* This method will decrypt and process all records that are fully available. * If only part of a record is available, the buffer will be retained until the * remainder of the record is offered.
*
* If any records containing application data were processed, the decrypted data * can be obtained using {@link #readInput(byte[], int, int)}. If any records * containing protocol data were processed, a response may have been generated. * You should always check to see if there is any available output after calling * this method by calling {@link #getAvailableOutputBytes()}. * @param input The input buffer to offer * @param inputOff The offset within the input buffer that input begins * @param inputLen The number of bytes of input being offered * @throws IOException If an error occurs while decrypting or processing a record */ public void offerInput(byte[] input, int inputOff, int inputLen) throws IOException { if (blocking) { throw new IllegalStateException("Cannot use offerInput() in blocking mode! Use getInputStream() instead."); } if (closed) { throw new IOException("Connection is closed, cannot accept any more input"); } // Fast path if the input is arriving one record at a time if (inputBuffers.available() == 0 && safeReadFullRecord(input, inputOff, inputLen)) { if (closed) { if (!appDataReady) { // NOTE: Any close during the handshake should have raised an exception. throw new TlsFatalAlert(AlertDescription.internal_error); } } return; } inputBuffers.addBytes(input, inputOff, inputLen); // loop while there are enough bytes to read the length of the next record while (inputBuffers.available() >= RecordFormat.FRAGMENT_OFFSET) { byte[] recordHeader = new byte[RecordFormat.FRAGMENT_OFFSET]; if (RecordFormat.FRAGMENT_OFFSET != inputBuffers.peek(recordHeader)) { throw new TlsFatalAlert(AlertDescription.internal_error); } RecordPreview preview = safePreviewRecordHeader(recordHeader); if (inputBuffers.available() < preview.getRecordSize()) { // not enough bytes to read a whole record break; } // NOTE: This is actually reading from inputBuffers, so InterruptedIOException shouldn't be possible safeReadRecord(); if (closed) { if (!appDataReady) { // NOTE: Any close during the handshake should have raised an exception. throw new TlsFatalAlert(AlertDescription.internal_error); } break; } } } public int getApplicationDataLimit() { return recordStream.getPlaintextLimit(); } /** * Gets the amount of received application data. A call to {@link #readInput(byte[], int, int)} * is guaranteed to be able to return at least this much data.
*
* Only allowed in non-blocking mode. * @return The number of bytes of available application data */ public int getAvailableInputBytes() { if (blocking) { throw new IllegalStateException("Cannot use getAvailableInputBytes() in blocking mode! Use getInputStream().available() instead."); } return applicationDataAvailable(); } /** * Retrieves received application data. Use {@link #getAvailableInputBytes()} to check * how much application data is currently available. This method functions similarly to * {@link InputStream#read(byte[], int, int)}, except that it never blocks. If no data * is available, nothing will be copied and zero will be returned.
*
* Only allowed in non-blocking mode. * @param buffer The buffer to hold the application data * @param offset The start offset in the buffer at which the data is written * @param length The maximum number of bytes to read * @return The total number of bytes copied to the buffer. May be less than the * length specified if the length was greater than the amount of available data. */ public int readInput(byte[] buffer, int offset, int length) { if (blocking) { throw new IllegalStateException("Cannot use readInput() in blocking mode! Use getInputStream() instead."); } length = Math.min(length, applicationDataQueue.available()); if (length < 1) { return 0; } applicationDataQueue.removeData(buffer, offset, length, 0); return length; } /** * Retrieves received application data into a {@link ByteBuffer}. Use {@link #getAvailableInputBytes()} to * check how much application data is currently available. This method functions similarly to * {@link InputStream#read(byte[], int, int)}, except that it never blocks. If no data is available, * nothing will be copied and zero will be returned.
*
* Only allowed in non-blocking mode. * * @param buffer The {@link ByteBuffer} to hold the application data * @param length The maximum number of bytes to read * @return The total number of bytes copied to the buffer. May be less than the length specified if the * length was greater than the amount of available data. */ public int readInput(ByteBuffer buffer, int length) { if (blocking) { throw new IllegalStateException("Cannot use readInput() in blocking mode! Use getInputStream() instead."); } length = Math.min(length, applicationDataQueue.available()); if (length < 1) { return 0; } applicationDataQueue.removeData(buffer, length, 0); return length; } /** * Gets the amount of encrypted data available to be sent. A call to * {@link #readOutput(byte[], int, int)} is guaranteed to be able to return at * least this much data.
*
* Only allowed in non-blocking mode. * @return The number of bytes of available encrypted data */ public int getAvailableOutputBytes() { if (blocking) { throw new IllegalStateException("Cannot use getAvailableOutputBytes() in blocking mode! Use getOutputStream() instead."); } return outputBuffer.getBuffer().available(); } /** * Retrieves encrypted data to be sent. Use {@link #getAvailableOutputBytes()} to check * how much encrypted data is currently available. This method functions similarly to * {@link InputStream#read(byte[], int, int)}, except that it never blocks. If no data * is available, nothing will be copied and zero will be returned.
*
* Only allowed in non-blocking mode. * @param buffer The buffer to hold the encrypted data * @param offset The start offset in the buffer at which the data is written * @param length The maximum number of bytes to read * @return The total number of bytes copied to the buffer. May be less than the * length specified if the length was greater than the amount of available data. */ public int readOutput(byte[] buffer, int offset, int length) { if (blocking) { throw new IllegalStateException("Cannot use readOutput() in blocking mode! Use getOutputStream() instead."); } int bytesToRead = Math.min(getAvailableOutputBytes(), length); outputBuffer.getBuffer().removeData(buffer, offset, bytesToRead, 0); return bytesToRead; } /** * Retrieves encrypted data to be sent. Use {@link #getAvailableOutputBytes()} to check * how much encrypted data is currently available. This method functions similarly to * {@link InputStream#read(byte[], int, int)}, except that it never blocks. If no data * is available, nothing will be copied and zero will be returned.
*
* Only allowed in non-blocking mode. * @param buffer The {@link ByteBuffer} to hold the encrypted data * @param length The maximum number of bytes to read * @return The total number of bytes copied to the buffer. May be less than the * length specified if the length was greater than the amount of available data. */ public int readOutput(ByteBuffer buffer, int length) { if (blocking) { throw new IllegalStateException("Cannot use readOutput() in blocking mode! Use getOutputStream() instead."); } int bytesToRead = Math.min(getAvailableOutputBytes(), length); outputBuffer.getBuffer().removeData(buffer, bytesToRead, 0); return bytesToRead; } protected boolean establishSession(TlsSession sessionToResume) { this.tlsSession = null; this.sessionParameters = null; this.sessionMasterSecret = null; if (null == sessionToResume || !sessionToResume.isResumable()) { return false; } SessionParameters sessionParameters = sessionToResume.exportSessionParameters(); if (null == sessionParameters) { return false; } ProtocolVersion sessionVersion = sessionParameters.getNegotiatedVersion(); if (null == sessionVersion || !sessionVersion.isTLS()) { return false; } boolean isEMS = sessionParameters.isExtendedMasterSecret(); if (sessionVersion.isSSL()) { if (isEMS) { return false; } } else if (!TlsUtils.isExtendedMasterSecretOptional(sessionVersion)) { if (!isEMS) { return false; } } TlsCrypto crypto = getContext().getCrypto(); TlsSecret sessionMasterSecret = TlsUtils.getSessionMasterSecret(crypto, sessionParameters.getMasterSecret()); if (null == sessionMasterSecret) { return false; } this.tlsSession = sessionToResume; this.sessionParameters = sessionParameters; this.sessionMasterSecret = sessionMasterSecret; return true; } protected void cancelSession() { if (this.sessionMasterSecret != null) { this.sessionMasterSecret.destroy(); this.sessionMasterSecret = null; } if (this.sessionParameters != null) { this.sessionParameters.clear(); this.sessionParameters = null; } this.tlsSession = null; } protected void invalidateSession() { if (this.tlsSession != null) { this.tlsSession.invalidate(); } cancelSession(); } protected void processFinishedMessage(ByteArrayInputStream buf) throws IOException { TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); boolean isServerContext = context.isServer(); byte[] verify_data = TlsUtils.readFully(securityParameters.getVerifyDataLength(), buf); assertEmpty(buf); byte[] expected_verify_data = TlsUtils.calculateVerifyData(context, handshakeHash, !isServerContext); /* * Compare both checksums. */ if (!Arrays.constantTimeAreEqual(expected_verify_data, verify_data)) { /* * Wrong checksum in the finished message. */ throw new TlsFatalAlert(AlertDescription.decrypt_error); } securityParameters.peerVerifyData = expected_verify_data; if (!securityParameters.isResumedSession() || securityParameters.isExtendedMasterSecret()) { if (null == securityParameters.getLocalVerifyData()) { securityParameters.tlsUnique = expected_verify_data; } } } protected void process13FinishedMessage(ByteArrayInputStream buf) throws IOException { TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); boolean isServerContext = context.isServer(); byte[] verify_data = TlsUtils.readFully(securityParameters.getVerifyDataLength(), buf); assertEmpty(buf); byte[] expected_verify_data = TlsUtils.calculateVerifyData(context, handshakeHash, !isServerContext); /* * Compare both checksums. */ if (!Arrays.constantTimeAreEqual(expected_verify_data, verify_data)) { /* * Wrong checksum in the finished message. */ throw new TlsFatalAlert(AlertDescription.decrypt_error); } securityParameters.peerVerifyData = expected_verify_data; securityParameters.tlsUnique = null; } protected void raiseAlertFatal(short alertDescription, String message, Throwable cause) throws IOException { getPeer().notifyAlertRaised(AlertLevel.fatal, alertDescription, message, cause); byte[] alert = new byte[]{ (byte)AlertLevel.fatal, (byte)alertDescription }; try { recordStream.writeRecord(ContentType.alert, alert, 0, 2); } catch (Exception e) { // We are already processing an exception, so just ignore this } } protected void raiseAlertWarning(short alertDescription, String message) throws IOException { getPeer().notifyAlertRaised(AlertLevel.warning, alertDescription, message, null); byte[] alert = new byte[]{ (byte)AlertLevel.warning, (byte)alertDescription }; safeWriteRecord(ContentType.alert, alert, 0, 2); } protected void receive13KeyUpdate(ByteArrayInputStream buf) throws IOException { // TODO[tls13] This is interesting enough to notify the TlsPeer for possible logging/vetting if (!(appDataReady && keyUpdateEnabled)) { throw new TlsFatalAlert(AlertDescription.unexpected_message); } short requestUpdate = TlsUtils.readUint8(buf); assertEmpty(buf); if (!KeyUpdateRequest.isValid(requestUpdate)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter); } boolean updateRequested = (KeyUpdateRequest.update_requested == requestUpdate); TlsUtils.update13TrafficSecretPeer(getContext()); recordStream.notifyKeyUpdateReceived(); // this.keyUpdatePendingReceive &= updateRequested; this.keyUpdatePendingSend |= updateRequested; } protected void sendCertificateMessage(Certificate certificate, OutputStream endPointHash) throws IOException { TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); if (null != securityParameters.getLocalCertificate()) { throw new TlsFatalAlert(AlertDescription.internal_error); } if (null == certificate) { certificate = Certificate.EMPTY_CHAIN; } if (certificate.isEmpty() && !context.isServer() && securityParameters.getNegotiatedVersion().isSSL()) { String message = "SSLv3 client didn't provide credentials"; raiseAlertWarning(AlertDescription.no_certificate, message); } else { HandshakeMessageOutput message = new HandshakeMessageOutput(HandshakeType.certificate); certificate.encode(context, message, endPointHash); message.send(this); } securityParameters.localCertificate = certificate; } protected void send13CertificateMessage(Certificate certificate) throws IOException { if (null == certificate) { throw new TlsFatalAlert(AlertDescription.internal_error); } TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); if (null != securityParameters.getLocalCertificate()) { throw new TlsFatalAlert(AlertDescription.internal_error); } HandshakeMessageOutput message = new HandshakeMessageOutput(HandshakeType.certificate); certificate.encode(context, message, null); message.send(this); securityParameters.localCertificate = certificate; } protected void send13CertificateVerifyMessage(DigitallySigned certificateVerify) throws IOException { HandshakeMessageOutput message = new HandshakeMessageOutput(HandshakeType.certificate_verify); certificateVerify.encode(message); message.send(this); } protected void sendChangeCipherSpec() throws IOException { sendChangeCipherSpecMessage(); recordStream.enablePendingCipherWrite(); } protected void sendChangeCipherSpecMessage() throws IOException { byte[] message = new byte[]{ 1 }; safeWriteRecord(ContentType.change_cipher_spec, message, 0, message.length); } protected void sendFinishedMessage() throws IOException { TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); boolean isServerContext = context.isServer(); byte[] verify_data = TlsUtils.calculateVerifyData(context, handshakeHash, isServerContext); securityParameters.localVerifyData = verify_data; if (!securityParameters.isResumedSession() || securityParameters.isExtendedMasterSecret()) { if (null == securityParameters.getPeerVerifyData()) { securityParameters.tlsUnique = verify_data; } } HandshakeMessageOutput.send(this, HandshakeType.finished, verify_data); } protected void send13FinishedMessage() throws IOException { TlsContext context = getContext(); SecurityParameters securityParameters = context.getSecurityParametersHandshake(); boolean isServerContext = context.isServer(); byte[] verify_data = TlsUtils.calculateVerifyData(context, handshakeHash, isServerContext); securityParameters.localVerifyData = verify_data; securityParameters.tlsUnique = null; HandshakeMessageOutput.send(this, HandshakeType.finished, verify_data); } protected void send13KeyUpdate(boolean updateRequested) throws IOException { // TODO[tls13] This is interesting enough to notify the TlsPeer for possible logging/vetting if (!(appDataReady && keyUpdateEnabled)) { throw new TlsFatalAlert(AlertDescription.internal_error); } short requestUpdate = updateRequested ? KeyUpdateRequest.update_requested : KeyUpdateRequest.update_not_requested; HandshakeMessageOutput.send(this, HandshakeType.key_update, TlsUtils.encodeUint8(requestUpdate)); TlsUtils.update13TrafficSecretLocal(getContext()); recordStream.notifyKeyUpdateSent(); // this.keyUpdatePendingReceive |= updateRequested; this.keyUpdatePendingSend &= updateRequested; } protected void sendSupplementalDataMessage(Vector supplementalData) throws IOException { HandshakeMessageOutput message = new HandshakeMessageOutput(HandshakeType.supplemental_data); writeSupplementalData(message, supplementalData); message.send(this); } /** * Closes this connection. * * @throws IOException If something goes wrong during closing. */ public void close() throws IOException { handleClose(true); } public void flush() throws IOException { } boolean isApplicationDataReady() { return appDataReady; } public boolean isClosed() { return closed; } public boolean isConnected() { if (closed) { return false; } AbstractTlsContext context = getContextAdmin(); return null != context && context.isConnected(); } public boolean isHandshaking() { if (closed) { return false; } AbstractTlsContext context = getContextAdmin(); return null != context && context.isHandshaking(); } /** * @deprecated Will be removed. */ protected short processMaxFragmentLengthExtension(Hashtable clientExtensions, Hashtable serverExtensions, short alertDescription) throws IOException { return TlsUtils.processMaxFragmentLengthExtension(clientExtensions, serverExtensions, alertDescription); } protected void refuseRenegotiation() throws IOException { /* * RFC 5746 4.5 SSLv3 clients [..] SHOULD use a fatal handshake_failure alert. */ if (TlsUtils.isSSL(getContext())) { throw new TlsFatalAlert(AlertDescription.handshake_failure); } raiseAlertWarning(AlertDescription.no_renegotiation, "Renegotiation not supported"); } /** * Make sure the InputStream 'buf' now empty. Fail otherwise. * * @param buf The InputStream to check. * @throws IOException If 'buf' is not empty. */ protected static void assertEmpty(ByteArrayInputStream buf) throws IOException { if (buf.available() > 0) { throw new TlsFatalAlert(AlertDescription.decode_error); } } protected static byte[] createRandomBlock(boolean useGMTUnixTime, TlsContext context) { byte[] result = context.getNonceGenerator().generateNonce(32); if (useGMTUnixTime) { TlsUtils.writeGMTUnixTime(result, 0); } return result; } protected static byte[] createRenegotiationInfo(byte[] renegotiated_connection) throws IOException { return TlsUtils.encodeOpaque8(renegotiated_connection); } protected static void establishMasterSecret(TlsContext context, TlsKeyExchange keyExchange) throws IOException { TlsSecret preMasterSecret = keyExchange.generatePreMasterSecret(); if (preMasterSecret == null) { throw new TlsFatalAlert(AlertDescription.internal_error); } try { context.getSecurityParametersHandshake().masterSecret = TlsUtils.calculateMasterSecret(context, preMasterSecret); } finally { /* * RFC 2246 8.1. The pre_master_secret should be deleted from memory once the * master_secret has been computed. */ preMasterSecret.destroy(); } } protected static Hashtable readExtensions(ByteArrayInputStream input) throws IOException { if (input.available() < 1) { return null; } byte[] extBytes = TlsUtils.readOpaque16(input); assertEmpty(input); return readExtensionsData(extBytes); } protected static Hashtable readExtensionsData(byte[] extBytes) throws IOException { // Integer -> byte[] Hashtable extensions = new Hashtable(); if (extBytes.length > 0) { ByteArrayInputStream buf = new ByteArrayInputStream(extBytes); do { int extension_type = TlsUtils.readUint16(buf); byte[] extension_data = TlsUtils.readOpaque16(buf); /* * RFC 3546 2.3 There MUST NOT be more than one extension of the same type. */ if (null != extensions.put(Integers.valueOf(extension_type), extension_data)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter, "Repeated extension: " + ExtensionType.getText(extension_type)); } } while (buf.available() > 0); } return extensions; } protected static Hashtable readExtensionsData13(int handshakeType, byte[] extBytes) throws IOException { // Integer -> byte[] Hashtable extensions = new Hashtable(); if (extBytes.length > 0) { ByteArrayInputStream buf = new ByteArrayInputStream(extBytes); do { int extension_type = TlsUtils.readUint16(buf); if (!TlsUtils.isPermittedExtensionType13(handshakeType, extension_type)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter, "Invalid extension: " + ExtensionType.getText(extension_type)); } byte[] extension_data = TlsUtils.readOpaque16(buf); /* * RFC 3546 2.3 There MUST NOT be more than one extension of the same type. */ if (null != extensions.put(Integers.valueOf(extension_type), extension_data)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter, "Repeated extension: " + ExtensionType.getText(extension_type)); } } while (buf.available() > 0); } return extensions; } protected static Hashtable readExtensionsDataClientHello(byte[] extBytes) throws IOException { /* * TODO[tls13] We are currently allowing any extensions to appear in ClientHello. It is * somewhat complicated to restrict what can appear based on the specific set of versions * the client is offering, and anyway could be fragile since clients may take a * "kitchen sink" approach to adding extensions independently of the offered versions. */ // Integer -> byte[] Hashtable extensions = new Hashtable(); if (extBytes.length > 0) { ByteArrayInputStream buf = new ByteArrayInputStream(extBytes); int extension_type = -1; boolean pre_shared_key_found = false; do { extension_type = TlsUtils.readUint16(buf); byte[] extension_data = TlsUtils.readOpaque16(buf); /* * RFC 3546 2.3 There MUST NOT be more than one extension of the same type. */ if (null != extensions.put(Integers.valueOf(extension_type), extension_data)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter, "Repeated extension: " + ExtensionType.getText(extension_type)); } pre_shared_key_found |= (ExtensionType.pre_shared_key == extension_type); } while (buf.available() > 0); if (pre_shared_key_found && (ExtensionType.pre_shared_key != extension_type)) { throw new TlsFatalAlert(AlertDescription.illegal_parameter, "'pre_shared_key' MUST be last in ClientHello"); } } return extensions; } protected static Vector readSupplementalDataMessage(ByteArrayInputStream input) throws IOException { byte[] supp_data = TlsUtils.readOpaque24(input, 1); assertEmpty(input); ByteArrayInputStream buf = new ByteArrayInputStream(supp_data); Vector supplementalData = new Vector(); while (buf.available() > 0) { int supp_data_type = TlsUtils.readUint16(buf); byte[] data = TlsUtils.readOpaque16(buf); supplementalData.addElement(new SupplementalDataEntry(supp_data_type, data)); } return supplementalData; } protected static void writeExtensions(OutputStream output, Hashtable extensions) throws IOException { writeExtensions(output, extensions, 0); } protected static void writeExtensions(OutputStream output, Hashtable extensions, int bindersSize) throws IOException { if (null == extensions || extensions.isEmpty()) { return; } byte[] extBytes = writeExtensionsData(extensions, bindersSize); int lengthWithBinders = extBytes.length + bindersSize; TlsUtils.checkUint16(lengthWithBinders); TlsUtils.writeUint16(lengthWithBinders, output); output.write(extBytes); } protected static byte[] writeExtensionsData(Hashtable extensions) throws IOException { return writeExtensionsData(extensions, 0); } protected static byte[] writeExtensionsData(Hashtable extensions, int bindersSize) throws IOException { ByteArrayOutputStream buf = new ByteArrayOutputStream(); writeExtensionsData(extensions, bindersSize, buf); return buf.toByteArray(); } protected static void writeExtensionsData(Hashtable extensions, int bindersSize, ByteArrayOutputStream buf) throws IOException { /* * NOTE: There are reports of servers that don't accept a zero-length extension as the last * one, so we write out any zero-length ones first as a best-effort workaround. */ writeSelectedExtensions(buf, extensions, true); writeSelectedExtensions(buf, extensions, false); writePreSharedKeyExtension(buf, extensions, bindersSize); } protected static void writePreSharedKeyExtension(OutputStream output, Hashtable extensions, int bindersSize) throws IOException { byte[] extension_data = (byte[])extensions.get(TlsExtensionsUtils.EXT_pre_shared_key); if (null != extension_data) { TlsUtils.checkUint16(ExtensionType.pre_shared_key); TlsUtils.writeUint16(ExtensionType.pre_shared_key, output); int lengthWithBinders = extension_data.length + bindersSize; TlsUtils.checkUint16(lengthWithBinders); TlsUtils.writeUint16(lengthWithBinders, output); output.write(extension_data); } } protected static void writeSelectedExtensions(OutputStream output, Hashtable extensions, boolean selectEmpty) throws IOException { Enumeration keys = extensions.keys(); while (keys.hasMoreElements()) { Integer key = (Integer)keys.nextElement(); int extension_type = key.intValue(); // NOTE: Must be last; handled by 'writePreSharedKeyExtension' if (ExtensionType.pre_shared_key == extension_type) { continue; } byte[] extension_data = (byte[])extensions.get(key); if (selectEmpty == (extension_data.length == 0)) { TlsUtils.checkUint16(extension_type); TlsUtils.writeUint16(extension_type, output); TlsUtils.writeOpaque16(extension_data, output); } } } protected static void writeSupplementalData(OutputStream output, Vector supplementalData) throws IOException { ByteArrayOutputStream buf = new ByteArrayOutputStream(); for (int i = 0; i < supplementalData.size(); ++i) { SupplementalDataEntry entry = (SupplementalDataEntry)supplementalData.elementAt(i); int supp_data_type = entry.getDataType(); TlsUtils.checkUint16(supp_data_type); TlsUtils.writeUint16(supp_data_type, buf); TlsUtils.writeOpaque16(entry.getData(), buf); } byte[] supp_data = buf.toByteArray(); TlsUtils.writeOpaque24(supp_data, output); } }




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