source: trunk/vnc/vnc_javasrc/VncCanvas.java @ 66

//
//  Copyright (C) 2004 Horizon Wimba.  All Rights Reserved.
//  Copyright (C) 2001-2003 HorizonLive.com, Inc.  All Rights Reserved.
//  Copyright (C) 2001,2002 Constantin Kaplinsky.  All Rights Reserved.
//  Copyright (C) 2000 Tridia Corporation.  All Rights Reserved.
//  Copyright (C) 1999 AT&T Laboratories Cambridge.  All Rights Reserved.
//
//  This is free software; you can redistribute it and/or modify
//  it under the terms of the GNU General Public License as published by
//  the Free Software Foundation; either version 2 of the License, or
//  (at your option) any later version.
//
//  This software 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 for more details.
//
//  You should have received a copy of the GNU General Public License
//  along with this software; if not, write to the Free Software
//  Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307,
//  USA.
//

import java.awt.*;
import java.awt.event.*;
import java.awt.image.*;
import java.io.*;
import java.lang.*;
import java.util.zip.*;


//
// VncCanvas is a subclass of Canvas which draws a VNC desktop on it.
//

class VncCanvas extends Canvas
  implements KeyListener, MouseListener, MouseMotionListener {

  VncViewer viewer;
  RfbProto rfb;
  ColorModel cm8, cm24;
  Color[] colors;
  int bytesPixel;

  int maxWidth = 0, maxHeight = 0;
  int scalingFactor;
  int scaledWidth, scaledHeight;

  Image memImage;
  Graphics memGraphics;

  Image rawPixelsImage;
  MemoryImageSource pixelsSource;
  byte[] pixels8;
  int[] pixels24;

  // ZRLE encoder's data.
  byte[] zrleBuf;
  int zrleBufLen = 0;
  byte[] zrleTilePixels8;
  int[] zrleTilePixels24;
  ZlibInStream zrleInStream;
  boolean zrleRecWarningShown = false;

  // Zlib encoder's data.
  byte[] zlibBuf;
  int zlibBufLen = 0;
  Inflater zlibInflater;

  // Tight encoder's data.
  final static int tightZlibBufferSize = 512;
  Inflater[] tightInflaters;

  // Since JPEG images are loaded asynchronously, we have to remember
  // their position in the framebuffer. Also, this jpegRect object is
  // used for synchronization between the rfbThread and a JVM's thread
  // which decodes and loads JPEG images.
  Rectangle jpegRect;

  // True if we process keyboard and mouse events.
  boolean inputEnabled;

  //
  // The constructors.
  //

  public VncCanvas(VncViewer v, int maxWidth_, int maxHeight_)
    throws IOException {

    viewer = v;
    maxWidth = maxWidth_;
    maxHeight = maxHeight_;

    rfb = viewer.rfb;
    scalingFactor = viewer.options.scalingFactor;

    tightInflaters = new Inflater[4];

    cm8 = new DirectColorModel(8, 7, (7 << 3), (3 << 6));
    cm24 = new DirectColorModel(24, 0xFF0000, 0x00FF00, 0x0000FF);

    colors = new Color[256];
    for (int i = 0; i < 256; i++)
      colors[i] = new Color(cm8.getRGB(i));

    setPixelFormat();

    inputEnabled = false;
    if (!viewer.options.viewOnly)
      enableInput(true);

    // Keyboard listener is enabled even in view-only mode, to catch
    // 'r' or 'R' key presses used to request screen update.
    addKeyListener(this);
  }

  public VncCanvas(VncViewer v) throws IOException {
    this(v, 0, 0);
  }

  //
  // Callback methods to determine geometry of our Component.
  //

  public Dimension getPreferredSize() {
    return new Dimension(scaledWidth, scaledHeight);
  }

  public Dimension getMinimumSize() {
    return new Dimension(scaledWidth, scaledHeight);
  }

  public Dimension getMaximumSize() {
    return new Dimension(scaledWidth, scaledHeight);
  }

  //
  // All painting is performed here.
  //

  public void update(Graphics g) {
    paint(g);
  }

  public void paint(Graphics g) {
    synchronized(memImage) {
      if (rfb.framebufferWidth == scaledWidth) {
        g.drawImage(memImage, 0, 0, null);
      } else {
        paintScaledFrameBuffer(g);
      }
    }
    if (showSoftCursor) {
      int x0 = cursorX - hotX, y0 = cursorY - hotY;
      Rectangle r = new Rectangle(x0, y0, cursorWidth, cursorHeight);
      if (r.intersects(g.getClipBounds())) {
        g.drawImage(softCursor, x0, y0, null);
      }
    }
  }

  public void paintScaledFrameBuffer(Graphics g) {
    g.drawImage(memImage, 0, 0, scaledWidth, scaledHeight, null);
  }

  //
  // Override the ImageObserver interface method to handle drawing of
  // JPEG-encoded data.
  //

  public boolean imageUpdate(Image img, int infoflags,
                             int x, int y, int width, int height) {
    if ((infoflags & (ALLBITS | ABORT)) == 0) {
      return true;              // We need more image data.
    } else {
      // If the whole image is available, draw it now.
      if ((infoflags & ALLBITS) != 0) {
        if (jpegRect != null) {
          synchronized(jpegRect) {
            memGraphics.drawImage(img, jpegRect.x, jpegRect.y, null);
            scheduleRepaint(jpegRect.x, jpegRect.y,
                            jpegRect.width, jpegRect.height);
            jpegRect.notify();
          }
        }
      }
      return false;             // All image data was processed.
    }
  }

  //
  // Start/stop receiving mouse events. Keyboard events are received
  // even in view-only mode, because we want to map the 'r' key to the
  // screen refreshing function.
  //

  public synchronized void enableInput(boolean enable) {
    if (enable && !inputEnabled) {
      inputEnabled = true;
      addMouseListener(this);
      addMouseMotionListener(this);
      if (viewer.showControls) {
        viewer.buttonPanel.enableRemoteAccessControls(true);
      }
      createSoftCursor();       // scaled cursor
    } else if (!enable && inputEnabled) {
      inputEnabled = false;
      removeMouseListener(this);
      removeMouseMotionListener(this);
      if (viewer.showControls) {
        viewer.buttonPanel.enableRemoteAccessControls(false);
      }
      createSoftCursor();       // non-scaled cursor
    }
  }

  public void setPixelFormat() throws IOException {
    if (viewer.options.eightBitColors) {
      rfb.writeSetPixelFormat(8, 8, false, true, 7, 7, 3, 0, 3, 6);
      bytesPixel = 1;
    } else {
      rfb.writeSetPixelFormat(32, 24, false, true, 255, 255, 255, 16, 8, 0);
      bytesPixel = 4;
    }
    updateFramebufferSize();
  }

  void updateFramebufferSize() {

    // Useful shortcuts.
    int fbWidth = rfb.framebufferWidth;
    int fbHeight = rfb.framebufferHeight;

    // Calculate scaling factor for auto scaling.
    if (maxWidth > 0 && maxHeight > 0) {
      int f1 = maxWidth * 100 / fbWidth;
      int f2 = maxHeight * 100 / fbHeight;
      scalingFactor = Math.min(f1, f2);
      if (scalingFactor > 100)
        scalingFactor = 100;
      System.out.println("Scaling desktop at " + scalingFactor + "%");
    }

    // Update scaled framebuffer geometry.
    scaledWidth = (fbWidth * scalingFactor + 50) / 100;
    scaledHeight = (fbHeight * scalingFactor + 50) / 100;

    // Create new off-screen image either if it does not exist, or if
    // its geometry should be changed. It's not necessary to replace
    // existing image if only pixel format should be changed.
    if (memImage == null) {
      memImage = viewer.vncContainer.createImage(fbWidth, fbHeight);
      memGraphics = memImage.getGraphics();
    } else if (memImage.getWidth(null) != fbWidth ||
               memImage.getHeight(null) != fbHeight) {
      synchronized(memImage) {
        memImage = viewer.vncContainer.createImage(fbWidth, fbHeight);
        memGraphics = memImage.getGraphics();
      }
    }

    // Images with raw pixels should be re-allocated on every change
    // of geometry or pixel format.
    if (bytesPixel == 1) {

      pixels24 = null;
      pixels8 = new byte[fbWidth * fbHeight];

      pixelsSource =
        new MemoryImageSource(fbWidth, fbHeight, cm8, pixels8, 0, fbWidth);

      zrleTilePixels24 = null;
      zrleTilePixels8 = new byte[64 * 64];

    } else {

      pixels8 = null;
      pixels24 = new int[fbWidth * fbHeight];

      pixelsSource =
        new MemoryImageSource(fbWidth, fbHeight, cm24, pixels24, 0, fbWidth);

      zrleTilePixels8 = null;
      zrleTilePixels24 = new int[64 * 64];

    }
    pixelsSource.setAnimated(true);
    rawPixelsImage = Toolkit.getDefaultToolkit().createImage(pixelsSource);

    // Update the size of desktop containers.
    if (viewer.inSeparateFrame) {
      if (viewer.desktopScrollPane != null)
        resizeDesktopFrame();
    } else {
      setSize(scaledWidth, scaledHeight);
    }
    viewer.moveFocusToDesktop();
  }

  void resizeDesktopFrame() {
    setSize(scaledWidth, scaledHeight);

    // FIXME: Find a better way to determine correct size of a
    // ScrollPane.  -- const
    Insets insets = viewer.desktopScrollPane.getInsets();
    viewer.desktopScrollPane.setSize(scaledWidth +
                                     2 * Math.min(insets.left, insets.right),
                                     scaledHeight +
                                     2 * Math.min(insets.top, insets.bottom));

    viewer.vncFrame.pack();

    // Try to limit the frame size to the screen size.

    Dimension screenSize = viewer.vncFrame.getToolkit().getScreenSize();
    Dimension frameSize = viewer.vncFrame.getSize();
    Dimension newSize = frameSize;

    // Reduce Screen Size by 30 pixels in each direction;
    // This is a (poor) attempt to account for
    //     1) Menu bar on Macintosh (should really also account for
    //        Dock on OSX).  Usually 22px on top of screen.
    //     2) Taxkbar on Windows (usually about 28 px on bottom)
    //     3) Other obstructions.

    screenSize.height -= 30;
    screenSize.width  -= 30;

    boolean needToResizeFrame = false;
    if (frameSize.height > screenSize.height) {
      newSize.height = screenSize.height;
      needToResizeFrame = true;
    }
    if (frameSize.width > screenSize.width) {
      newSize.width = screenSize.width;
      needToResizeFrame = true;
    }
    if (needToResizeFrame) {
      viewer.vncFrame.setSize(newSize);
    }

    viewer.desktopScrollPane.doLayout();
  }

  //
  // processNormalProtocol() - executed by the rfbThread to deal with the
  // RFB socket.
  //

  public void processNormalProtocol() throws Exception {

    // Start/stop session recording if necessary.
    viewer.checkRecordingStatus();

    rfb.writeFramebufferUpdateRequest(0, 0, rfb.framebufferWidth,
                                      rfb.framebufferHeight, false);

    //
    // main dispatch loop
    //

    while (true) {

      // Read message type from the server.
      int msgType = rfb.readServerMessageType();

      // Process the message depending on its type.
      switch (msgType) {
      case RfbProto.FramebufferUpdate:
        rfb.readFramebufferUpdate();

        boolean cursorPosReceived = false;

        for (int i = 0; i < rfb.updateNRects; i++) {
          rfb.readFramebufferUpdateRectHdr();
          int rx = rfb.updateRectX, ry = rfb.updateRectY;
          int rw = rfb.updateRectW, rh = rfb.updateRectH;

          if (rfb.updateRectEncoding == rfb.EncodingLastRect)
            break;

          if (rfb.updateRectEncoding == rfb.EncodingNewFBSize) {
            rfb.setFramebufferSize(rw, rh);
            updateFramebufferSize();
            break;
          }

          if (rfb.updateRectEncoding == rfb.EncodingXCursor ||
              rfb.updateRectEncoding == rfb.EncodingRichCursor) {
            handleCursorShapeUpdate(rfb.updateRectEncoding, rx, ry, rw, rh);
            continue;
          }

          if (rfb.updateRectEncoding == rfb.EncodingPointerPos) {
            softCursorMove(rx, ry);
            cursorPosReceived = true;
            continue;
          }

          rfb.startTiming();

          switch (rfb.updateRectEncoding) {
          case RfbProto.EncodingRaw:
            handleRawRect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingCopyRect:
            handleCopyRect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingRRE:
            handleRRERect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingCoRRE:
            handleCoRRERect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingHextile:
            handleHextileRect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingZRLE:
            handleZRLERect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingZlib:
            handleZlibRect(rx, ry, rw, rh);
            break;
          case RfbProto.EncodingTight:
            handleTightRect(rx, ry, rw, rh);
            break;
          default:
            throw new Exception("Unknown RFB rectangle encoding " +
                                rfb.updateRectEncoding);
          }

          rfb.stopTiming();
        }

        boolean fullUpdateNeeded = false;

        // Start/stop session recording if necessary. Request full
        // update if a new session file was opened.
        if (viewer.checkRecordingStatus())
          fullUpdateNeeded = true;

        // Defer framebuffer update request if necessary. But wake up
        // immediately on keyboard or mouse event. Also, don't sleep
        // if there is some data to receive, or if the last update
        // included a PointerPos message.
        if (viewer.deferUpdateRequests > 0 &&
            rfb.is.available() == 0 && !cursorPosReceived) {
          synchronized(rfb) {
            try {
              rfb.wait(viewer.deferUpdateRequests);
            } catch (InterruptedException e) {
            }
          }
        }

        // Before requesting framebuffer update, check if the pixel
        // format should be changed. If it should, request full update
        // instead of an incremental one.
        if (viewer.options.eightBitColors != (bytesPixel == 1)) {
          setPixelFormat();
          fullUpdateNeeded = true;
        }

        viewer.autoSelectEncodings();

        rfb.writeFramebufferUpdateRequest(0, 0, rfb.framebufferWidth,
                                          rfb.framebufferHeight,
                                          !fullUpdateNeeded);

        break;

      case RfbProto.SetColourMapEntries:
        throw new Exception("Can't handle SetColourMapEntries message");

      case RfbProto.Bell:
        Toolkit.getDefaultToolkit().beep();
        break;

      case RfbProto.ServerCutText:
        String s = rfb.readServerCutText();
        viewer.clipboard.setCutText(s);
        break;

      default:
        throw new Exception("Unknown RFB message type " + msgType);
      }
    }
  }


  //
  // Handle a raw rectangle. The second form with paint==false is used
  // by the Hextile decoder for raw-encoded tiles.
  //

  void handleRawRect(int x, int y, int w, int h) throws IOException {
    handleRawRect(x, y, w, h, true);
  }

  void handleRawRect(int x, int y, int w, int h, boolean paint)
    throws IOException {

    if (bytesPixel == 1) {
      for (int dy = y; dy < y + h; dy++) {
        rfb.readFully(pixels8, dy * rfb.framebufferWidth + x, w);
        if (rfb.rec != null) {
          rfb.rec.write(pixels8, dy * rfb.framebufferWidth + x, w);
        }
      }
    } else {
      byte[] buf = new byte[w * 4];
      int i, offset;
      for (int dy = y; dy < y + h; dy++) {
        rfb.readFully(buf);
        if (rfb.rec != null) {
          rfb.rec.write(buf);
        }
        offset = dy * rfb.framebufferWidth + x;
        for (i = 0; i < w; i++) {
          pixels24[offset + i] =
            (buf[i * 4 + 2] & 0xFF) << 16 |
            (buf[i * 4 + 1] & 0xFF) << 8 |
            (buf[i * 4] & 0xFF);
        }
      }
    }

    handleUpdatedPixels(x, y, w, h);
    if (paint)
      scheduleRepaint(x, y, w, h);
  }

  //
  // Handle a CopyRect rectangle.
  //

  void handleCopyRect(int x, int y, int w, int h) throws IOException {

    rfb.readCopyRect();
    memGraphics.copyArea(rfb.copyRectSrcX, rfb.copyRectSrcY, w, h,
                         x - rfb.copyRectSrcX, y - rfb.copyRectSrcY);

    scheduleRepaint(x, y, w, h);
  }

  //
  // Handle an RRE-encoded rectangle.
  //

  void handleRRERect(int x, int y, int w, int h) throws IOException {

    int nSubrects = rfb.is.readInt();

    byte[] bg_buf = new byte[bytesPixel];
    rfb.readFully(bg_buf);
    Color pixel;
    if (bytesPixel == 1) {
      pixel = colors[bg_buf[0] & 0xFF];
    } else {
      pixel = new Color(bg_buf[2] & 0xFF, bg_buf[1] & 0xFF, bg_buf[0] & 0xFF);
    }
    memGraphics.setColor(pixel);
    memGraphics.fillRect(x, y, w, h);

    byte[] buf = new byte[nSubrects * (bytesPixel + 8)];
    rfb.readFully(buf);
    DataInputStream ds = new DataInputStream(new ByteArrayInputStream(buf));

    if (rfb.rec != null) {
      rfb.rec.writeIntBE(nSubrects);
      rfb.rec.write(bg_buf);
      rfb.rec.write(buf);
    }

    int sx, sy, sw, sh;

    for (int j = 0; j < nSubrects; j++) {
      if (bytesPixel == 1) {
        pixel = colors[ds.readUnsignedByte()];
      } else {
        ds.skip(4);
        pixel = new Color(buf[j*12+2] & 0xFF,
                          buf[j*12+1] & 0xFF,
                          buf[j*12]   & 0xFF);
      }
      sx = x + ds.readUnsignedShort();
      sy = y + ds.readUnsignedShort();
      sw = ds.readUnsignedShort();
      sh = ds.readUnsignedShort();

      memGraphics.setColor(pixel);
      memGraphics.fillRect(sx, sy, sw, sh);
    }

    scheduleRepaint(x, y, w, h);
  }

  //
  // Handle a CoRRE-encoded rectangle.
  //

  void handleCoRRERect(int x, int y, int w, int h) throws IOException {
    int nSubrects = rfb.is.readInt();

    byte[] bg_buf = new byte[bytesPixel];
    rfb.readFully(bg_buf);
    Color pixel;
    if (bytesPixel == 1) {
      pixel = colors[bg_buf[0] & 0xFF];
    } else {
      pixel = new Color(bg_buf[2] & 0xFF, bg_buf[1] & 0xFF, bg_buf[0] & 0xFF);
    }
    memGraphics.setColor(pixel);
    memGraphics.fillRect(x, y, w, h);

    byte[] buf = new byte[nSubrects * (bytesPixel + 4)];
    rfb.readFully(buf);

    if (rfb.rec != null) {
      rfb.rec.writeIntBE(nSubrects);
      rfb.rec.write(bg_buf);
      rfb.rec.write(buf);
    }

    int sx, sy, sw, sh;
    int i = 0;

    for (int j = 0; j < nSubrects; j++) {
      if (bytesPixel == 1) {
        pixel = colors[buf[i++] & 0xFF];
      } else {
        pixel = new Color(buf[i+2] & 0xFF, buf[i+1] & 0xFF, buf[i] & 0xFF);
        i += 4;
      }
      sx = x + (buf[i++] & 0xFF);
      sy = y + (buf[i++] & 0xFF);
      sw = buf[i++] & 0xFF;
      sh = buf[i++] & 0xFF;

      memGraphics.setColor(pixel);
      memGraphics.fillRect(sx, sy, sw, sh);
    }

    scheduleRepaint(x, y, w, h);
  }

  //
  // Handle a Hextile-encoded rectangle.
  //

  // These colors should be kept between handleHextileSubrect() calls.
  private Color hextile_bg, hextile_fg;

  void handleHextileRect(int x, int y, int w, int h) throws IOException {

    hextile_bg = new Color(0);
    hextile_fg = new Color(0);

    for (int ty = y; ty < y + h; ty += 16) {
      int th = 16;
      if (y + h - ty < 16)
        th = y + h - ty;

      for (int tx = x; tx < x + w; tx += 16) {
        int tw = 16;
        if (x + w - tx < 16)
          tw = x + w - tx;

        handleHextileSubrect(tx, ty, tw, th);
      }

      // Finished with a row of tiles, now let's show it.
      scheduleRepaint(x, y, w, h);
    }
  }

  //
  // Handle one tile in the Hextile-encoded data.
  //

  void handleHextileSubrect(int tx, int ty, int tw, int th)
    throws IOException {

    int subencoding = rfb.is.readUnsignedByte();
    if (rfb.rec != null) {
      rfb.rec.writeByte(subencoding);
    }

    // Is it a raw-encoded sub-rectangle?
    if ((subencoding & rfb.HextileRaw) != 0) {
      handleRawRect(tx, ty, tw, th, false);
      return;
    }

    // Read and draw the background if specified.
    byte[] cbuf = new byte[bytesPixel];
    if ((subencoding & rfb.HextileBackgroundSpecified) != 0) {
      rfb.readFully(cbuf);
      if (bytesPixel == 1) {
        hextile_bg = colors[cbuf[0] & 0xFF];
      } else {
        hextile_bg = new Color(cbuf[2] & 0xFF, cbuf[1] & 0xFF, cbuf[0] & 0xFF);
      }
      if (rfb.rec != null) {
        rfb.rec.write(cbuf);
      }
    }
    memGraphics.setColor(hextile_bg);
    memGraphics.fillRect(tx, ty, tw, th);

    // Read the foreground color if specified.
    if ((subencoding & rfb.HextileForegroundSpecified) != 0) {
      rfb.readFully(cbuf);
      if (bytesPixel == 1) {
        hextile_fg = colors[cbuf[0] & 0xFF];
      } else {
        hextile_fg = new Color(cbuf[2] & 0xFF, cbuf[1] & 0xFF, cbuf[0] & 0xFF);
      }
      if (rfb.rec != null) {
        rfb.rec.write(cbuf);
      }
    }

    // Done with this tile if there is no sub-rectangles.
    if ((subencoding & rfb.HextileAnySubrects) == 0)
      return;

    int nSubrects = rfb.is.readUnsignedByte();
    int bufsize = nSubrects * 2;
    if ((subencoding & rfb.HextileSubrectsColoured) != 0) {
      bufsize += nSubrects * bytesPixel;
    }
    byte[] buf = new byte[bufsize];
    rfb.readFully(buf);
    if (rfb.rec != null) {
      rfb.rec.writeByte(nSubrects);
      rfb.rec.write(buf);
    }

    int b1, b2, sx, sy, sw, sh;
    int i = 0;

    if ((subencoding & rfb.HextileSubrectsColoured) == 0) {

      // Sub-rectangles are all of the same color.
      memGraphics.setColor(hextile_fg);
      for (int j = 0; j < nSubrects; j++) {
        b1 = buf[i++] & 0xFF;
        b2 = buf[i++] & 0xFF;
        sx = tx + (b1 >> 4);
        sy = ty + (b1 & 0xf);
        sw = (b2 >> 4) + 1;
        sh = (b2 & 0xf) + 1;
        memGraphics.fillRect(sx, sy, sw, sh);
      }
    } else if (bytesPixel == 1) {

      // BGR233 (8-bit color) version for colored sub-rectangles.
      for (int j = 0; j < nSubrects; j++) {
        hextile_fg = colors[buf[i++] & 0xFF];
        b1 = buf[i++] & 0xFF;
        b2 = buf[i++] & 0xFF;
        sx = tx + (b1 >> 4);
        sy = ty + (b1 & 0xf);
        sw = (b2 >> 4) + 1;
        sh = (b2 & 0xf) + 1;
        memGraphics.setColor(hextile_fg);
        memGraphics.fillRect(sx, sy, sw, sh);
      }

    } else {

      // Full-color (24-bit) version for colored sub-rectangles.
      for (int j = 0; j < nSubrects; j++) {
        hextile_fg = new Color(buf[i+2] & 0xFF,
                               buf[i+1] & 0xFF,
                               buf[i] & 0xFF);
        i += 4;
        b1 = buf[i++] & 0xFF;
        b2 = buf[i++] & 0xFF;
        sx = tx + (b1 >> 4);
        sy = ty + (b1 & 0xf);
        sw = (b2 >> 4) + 1;
        sh = (b2 & 0xf) + 1;
        memGraphics.setColor(hextile_fg);
        memGraphics.fillRect(sx, sy, sw, sh);
      }

    }
  }

  //
  // Handle a ZRLE-encoded rectangle.
  //
  // FIXME: Currently, session recording is not fully supported for ZRLE.
  //

  void handleZRLERect(int x, int y, int w, int h) throws Exception {

    if (zrleInStream == null)
      zrleInStream = new ZlibInStream();

    int nBytes = rfb.is.readInt();
    if (nBytes > 64 * 1024 * 1024)
      throw new Exception("ZRLE decoder: illegal compressed data size");

    if (zrleBuf == null || zrleBufLen < nBytes) {
      zrleBufLen = nBytes + 4096;
      zrleBuf = new byte[zrleBufLen];
    }

    // FIXME: Do not wait for all the data before decompression.
    rfb.readFully(zrleBuf, 0, nBytes);

    if (rfb.rec != null) {
      if (rfb.recordFromBeginning) {
        rfb.rec.writeIntBE(nBytes);
        rfb.rec.write(zrleBuf, 0, nBytes);
      } else if (!zrleRecWarningShown) {
        System.out.println("Warning: ZRLE session can be recorded" +
                           " only from the beginning");
        System.out.println("Warning: Recorded file may be corrupted");
        zrleRecWarningShown = true;
      }
    }

    zrleInStream.setUnderlying(new MemInStream(zrleBuf, 0, nBytes), nBytes);

    for (int ty = y; ty < y+h; ty += 64) {

      int th = Math.min(y+h-ty, 64);

      for (int tx = x; tx < x+w; tx += 64) {

        int tw = Math.min(x+w-tx, 64);

        int mode = zrleInStream.readU8();
        boolean rle = (mode & 128) != 0;
        int palSize = mode & 127;
        int[] palette = new int[128];

        readZrlePalette(palette, palSize);

        if (palSize == 1) {
          int pix = palette[0];
          Color c = (bytesPixel == 1) ?
            colors[pix] : new Color(0xFF000000 | pix);
          memGraphics.setColor(c);
          memGraphics.fillRect(tx, ty, tw, th);
          continue;
        }

        if (!rle) {
          if (palSize == 0) {
            readZrleRawPixels(tw, th);
          } else {
            readZrlePackedPixels(tw, th, palette, palSize);
          }
        } else {
          if (palSize == 0) {
            readZrlePlainRLEPixels(tw, th);
          } else {
            readZrlePackedRLEPixels(tw, th, palette);
          }
        }
        handleUpdatedZrleTile(tx, ty, tw, th);
      }
    }

    zrleInStream.reset();

    scheduleRepaint(x, y, w, h);
  }

  int readPixel(InStream is) throws Exception {
    int pix;
    if (bytesPixel == 1) {
      pix = is.readU8();
    } else {
      int p1 = is.readU8();
      int p2 = is.readU8();
      int p3 = is.readU8();
      pix = (p3 & 0xFF) << 16 | (p2 & 0xFF) << 8 | (p1 & 0xFF);
    }
    return pix;
  }

  void readPixels(InStream is, int[] dst, int count) throws Exception {
    int pix;
    if (bytesPixel == 1) {
      byte[] buf = new byte[count];
      is.readBytes(buf, 0, count);
      for (int i = 0; i < count; i++) {
        dst[i] = (int)buf[i] & 0xFF;
      }
    } else {
      byte[] buf = new byte[count * 3];
      is.readBytes(buf, 0, count * 3);
      for (int i = 0; i < count; i++) {
        dst[i] = ((buf[i*3+2] & 0xFF) << 16 |
                  (buf[i*3+1] & 0xFF) << 8 |
                  (buf[i*3] & 0xFF));
      }
    }
  }

  void readZrlePalette(int[] palette, int palSize) throws Exception {
    readPixels(zrleInStream, palette, palSize);
  }

  void readZrleRawPixels(int tw, int th) throws Exception {
    if (bytesPixel == 1) {
      zrleInStream.readBytes(zrleTilePixels8, 0, tw * th);
    } else {
      readPixels(zrleInStream, zrleTilePixels24, tw * th); ///
    }
  }

  void readZrlePackedPixels(int tw, int th, int[] palette, int palSize)
    throws Exception {

    int bppp = ((palSize > 16) ? 8 :
                ((palSize > 4) ? 4 : ((palSize > 2) ? 2 : 1)));
    int ptr = 0;

    for (int i = 0; i < th; i++) {
      int eol = ptr + tw;
      int b = 0;
      int nbits = 0;

      while (ptr < eol) {
        if (nbits == 0) {
          b = zrleInStream.readU8();
          nbits = 8;
        }
        nbits -= bppp;
        int index = (b >> nbits) & ((1 << bppp) - 1) & 127;
        if (bytesPixel == 1) {
          zrleTilePixels8[ptr++] = (byte)palette[index];
        } else {
          zrleTilePixels24[ptr++] = palette[index];
        }
      }
    }
  }

  void readZrlePlainRLEPixels(int tw, int th) throws Exception {
    int ptr = 0;
    int end = ptr + tw * th;
    while (ptr < end) {
      int pix = readPixel(zrleInStream);
      int len = 1;
      int b;
      do {
        b = zrleInStream.readU8();
        len += b;
      } while (b == 255);

      if (!(len <= end - ptr))
        throw new Exception("ZRLE decoder: assertion failed" +
                            " (len <= end-ptr)");

      if (bytesPixel == 1) {
        while (len-- > 0) zrleTilePixels8[ptr++] = (byte)pix;
      } else {
        while (len-- > 0) zrleTilePixels24[ptr++] = pix;
      }
    }
  }

  void readZrlePackedRLEPixels(int tw, int th, int[] palette)
    throws Exception {

    int ptr = 0;
    int end = ptr + tw * th;
    while (ptr < end) {
      int index = zrleInStream.readU8();
      int len = 1;
      if ((index & 128) != 0) {
        int b;
        do {
          b = zrleInStream.readU8();
          len += b;
        } while (b == 255);
        
        if (!(len <= end - ptr))
          throw new Exception("ZRLE decoder: assertion failed" +
                              " (len <= end - ptr)");
      }

      index &= 127;
      int pix = palette[index];

      if (bytesPixel == 1) {
        while (len-- > 0) zrleTilePixels8[ptr++] = (byte)pix;
      } else {
        while (len-- > 0) zrleTilePixels24[ptr++] = pix;
      }
    }
  }

  //
  // Copy pixels from zrleTilePixels8 or zrleTilePixels24, then update.
  //

  void handleUpdatedZrleTile(int x, int y, int w, int h) {
    Object src, dst;
    if (bytesPixel == 1) {
      src = zrleTilePixels8; dst = pixels8;
    } else {
      src = zrleTilePixels24; dst = pixels24;
    }
    int offsetSrc = 0;
    int offsetDst = (y * rfb.framebufferWidth + x);
    for (int j = 0; j < h; j++) {
      System.arraycopy(src, offsetSrc, dst, offsetDst, w);
      offsetSrc += w;
      offsetDst += rfb.framebufferWidth;
    }
    handleUpdatedPixels(x, y, w, h);
  }

  //
  // Handle a Zlib-encoded rectangle.
  //

  void handleZlibRect(int x, int y, int w, int h) throws Exception {

    int nBytes = rfb.is.readInt();

    if (zlibBuf == null || zlibBufLen < nBytes) {
      zlibBufLen = nBytes * 2;
      zlibBuf = new byte[zlibBufLen];
    }

    rfb.readFully(zlibBuf, 0, nBytes);

    if (rfb.rec != null && rfb.recordFromBeginning) {
      rfb.rec.writeIntBE(nBytes);
      rfb.rec.write(zlibBuf, 0, nBytes);
    }

    if (zlibInflater == null) {
      zlibInflater = new Inflater();
    }
    zlibInflater.setInput(zlibBuf, 0, nBytes);

    if (bytesPixel == 1) {
      for (int dy = y; dy < y + h; dy++) {
        zlibInflater.inflate(pixels8, dy * rfb.framebufferWidth + x, w);
        if (rfb.rec != null && !rfb.recordFromBeginning)
          rfb.rec.write(pixels8, dy * rfb.framebufferWidth + x, w);
      }
    } else {
      byte[] buf = new byte[w * 4];
      int i, offset;
      for (int dy = y; dy < y + h; dy++) {
        zlibInflater.inflate(buf);
        offset = dy * rfb.framebufferWidth + x;
        for (i = 0; i < w; i++) {
          pixels24[offset + i] =
            (buf[i * 4 + 2] & 0xFF) << 16 |
            (buf[i * 4 + 1] & 0xFF) << 8 |
            (buf[i * 4] & 0xFF);
        }
        if (rfb.rec != null && !rfb.recordFromBeginning)
          rfb.rec.write(buf);
      }
    }

    handleUpdatedPixels(x, y, w, h);
    scheduleRepaint(x, y, w, h);
  }

  //
  // Handle a Tight-encoded rectangle.
  //

  void handleTightRect(int x, int y, int w, int h) throws Exception {

    int comp_ctl = rfb.is.readUnsignedByte();
    if (rfb.rec != null) {
      if (rfb.recordFromBeginning ||
          comp_ctl == (rfb.TightFill << 4) ||
          comp_ctl == (rfb.TightJpeg << 4)) {
        // Send data exactly as received.
        rfb.rec.writeByte(comp_ctl);
      } else {
        // Tell the decoder to flush each of the four zlib streams.
        rfb.rec.writeByte(comp_ctl | 0x0F);
      }
    }

    // Flush zlib streams if we are told by the server to do so.
    for (int stream_id = 0; stream_id < 4; stream_id++) {
      if ((comp_ctl & 1) != 0 && tightInflaters[stream_id] != null) {
        tightInflaters[stream_id] = null;
      }
      comp_ctl >>= 1;
    }

    // Check correctness of subencoding value.
    if (comp_ctl > rfb.TightMaxSubencoding) {
      throw new Exception("Incorrect tight subencoding: " + comp_ctl);
    }

    // Handle solid-color rectangles.
    if (comp_ctl == rfb.TightFill) {

      if (bytesPixel == 1) {
        int idx = rfb.is.readUnsignedByte();
        memGraphics.setColor(colors[idx]);
        if (rfb.rec != null) {
          rfb.rec.writeByte(idx);
        }
      } else {
        byte[] buf = new byte[3];
        rfb.readFully(buf);
        if (rfb.rec != null) {
          rfb.rec.write(buf);
        }
        Color bg = new Color(0xFF000000 | (buf[0] & 0xFF) << 16 |
                             (buf[1] & 0xFF) << 8 | (buf[2] & 0xFF));
        memGraphics.setColor(bg);
      }
      memGraphics.fillRect(x, y, w, h);
      scheduleRepaint(x, y, w, h);
      return;

    }

    if (comp_ctl == rfb.TightJpeg) {

      // Read JPEG data.
      byte[] jpegData = new byte[rfb.readCompactLen()];
      rfb.readFully(jpegData);
      if (rfb.rec != null) {
        if (!rfb.recordFromBeginning) {
          rfb.recordCompactLen(jpegData.length);
        }
        rfb.rec.write(jpegData);
      }

      // Create an Image object from the JPEG data.
      Image jpegImage = Toolkit.getDefaultToolkit().createImage(jpegData);

      // Remember the rectangle where the image should be drawn.
      jpegRect = new Rectangle(x, y, w, h);

      // Let the imageUpdate() method do the actual drawing, here just
      // wait until the image is fully loaded and drawn.
      synchronized(jpegRect) {
        Toolkit.getDefaultToolkit().prepareImage(jpegImage, -1, -1, this);
        try {
          // Wait no longer than three seconds.
          jpegRect.wait(3000);
        } catch (InterruptedException e) {
          throw new Exception("Interrupted while decoding JPEG image");
        }
      }

      // Done, jpegRect is not needed any more.
      jpegRect = null;
      return;

    }

    // Read filter id and parameters.
    int numColors = 0, rowSize = w;
    byte[] palette8 = new byte[2];
    int[] palette24 = new int[256];
    boolean useGradient = false;
    if ((comp_ctl & rfb.TightExplicitFilter) != 0) {
      int filter_id = rfb.is.readUnsignedByte();
      if (rfb.rec != null) {
        rfb.rec.writeByte(filter_id);
      }
      if (filter_id == rfb.TightFilterPalette) {
        numColors = rfb.is.readUnsignedByte() + 1;
        if (rfb.rec != null) {
          rfb.rec.writeByte(numColors - 1);
        }
        if (bytesPixel == 1) {
          if (numColors != 2) {
            throw new Exception("Incorrect tight palette size: " + numColors);
          }
          rfb.readFully(palette8);
          if (rfb.rec != null) {
            rfb.rec.write(palette8);
          }
        } else {
          byte[] buf = new byte[numColors * 3];
          rfb.readFully(buf);
          if (rfb.rec != null) {
            rfb.rec.write(buf);
          }
          for (int i = 0; i < numColors; i++) {
            palette24[i] = ((buf[i * 3] & 0xFF) << 16 |
                            (buf[i * 3 + 1] & 0xFF) << 8 |
                            (buf[i * 3 + 2] & 0xFF));
          }
        }
        if (numColors == 2)
          rowSize = (w + 7) / 8;
      } else if (filter_id == rfb.TightFilterGradient) {
        useGradient = true;
      } else if (filter_id != rfb.TightFilterCopy) {
        throw new Exception("Incorrect tight filter id: " + filter_id);
      }
    }
    if (numColors == 0 && bytesPixel == 4)
      rowSize *= 3;

    // Read, optionally uncompress and decode data.
    int dataSize = h * rowSize;
    if (dataSize < rfb.TightMinToCompress) {
      // Data size is small - not compressed with zlib.
      if (numColors != 0) {
        // Indexed colors.
        byte[] indexedData = new byte[dataSize];
        rfb.readFully(indexedData);
        if (rfb.rec != null) {
          rfb.rec.write(indexedData);
        }
        if (numColors == 2) {
          // Two colors.
          if (bytesPixel == 1) {
            decodeMonoData(x, y, w, h, indexedData, palette8);
          } else {
            decodeMonoData(x, y, w, h, indexedData, palette24);
          }
        } else {
          // 3..255 colors (assuming bytesPixel == 4).
          int i = 0;
          for (int dy = y; dy < y + h; dy++) {
            for (int dx = x; dx < x + w; dx++) {
              pixels24[dy * rfb.framebufferWidth + dx] =
                palette24[indexedData[i++] & 0xFF];
            }
          }
        }
      } else if (useGradient) {
        // "Gradient"-processed data
        byte[] buf = new byte[w * h * 3];
        rfb.readFully(buf);
        if (rfb.rec != null) {
          rfb.rec.write(buf);
        }
        decodeGradientData(x, y, w, h, buf);
      } else {
        // Raw truecolor data.
        if (bytesPixel == 1) {
          for (int dy = y; dy < y + h; dy++) {
            rfb.readFully(pixels8, dy * rfb.framebufferWidth + x, w);
            if (rfb.rec != null) {
              rfb.rec.write(pixels8, dy * rfb.framebufferWidth + x, w);
            }
          }
        } else {
          byte[] buf = new byte[w * 3];
          int i, offset;
          for (int dy = y; dy < y + h; dy++) {
            rfb.readFully(buf);
            if (rfb.rec != null) {
              rfb.rec.write(buf);
            }
            offset = dy * rfb.framebufferWidth + x;
            for (i = 0; i < w; i++) {
              pixels24[offset + i] =
                (buf[i * 3] & 0xFF) << 16 |
                (buf[i * 3 + 1] & 0xFF) << 8 |
                (buf[i * 3 + 2] & 0xFF);
            }
          }
        }
      }
    } else {
      // Data was compressed with zlib.
      int zlibDataLen = rfb.readCompactLen();
      byte[] zlibData = new byte[zlibDataLen];
      rfb.readFully(zlibData);
      if (rfb.rec != null && rfb.recordFromBeginning) {
        rfb.rec.write(zlibData);
      }
      int stream_id = comp_ctl & 0x03;
      if (tightInflaters[stream_id] == null) {
        tightInflaters[stream_id] = new Inflater();
      }
      Inflater myInflater = tightInflaters[stream_id];
      myInflater.setInput(zlibData);
      byte[] buf = new byte[dataSize];
      myInflater.inflate(buf);
      if (rfb.rec != null && !rfb.recordFromBeginning) {
        rfb.recordCompressedData(buf);
      }

      if (numColors != 0) {
        // Indexed colors.
        if (numColors == 2) {
          // Two colors.
          if (bytesPixel == 1) {
            decodeMonoData(x, y, w, h, buf, palette8);
          } else {
            decodeMonoData(x, y, w, h, buf, palette24);
          }
        } else {
          // More than two colors (assuming bytesPixel == 4).
          int i = 0;
          for (int dy = y; dy < y + h; dy++) {
            for (int dx = x; dx < x + w; dx++) {
              pixels24[dy * rfb.framebufferWidth + dx] =
                palette24[buf[i++] & 0xFF];
            }
          }
        }
      } else if (useGradient) {
        // Compressed "Gradient"-filtered data (assuming bytesPixel == 4).
        decodeGradientData(x, y, w, h, buf);
      } else {
        // Compressed truecolor data.
        if (bytesPixel == 1) {
          int destOffset = y * rfb.framebufferWidth + x;
          for (int dy = 0; dy < h; dy++) {
            System.arraycopy(buf, dy * w, pixels8, destOffset, w);
            destOffset += rfb.framebufferWidth;
          }
        } else {
          int srcOffset = 0;
          int destOffset, i;
          for (int dy = 0; dy < h; dy++) {
            myInflater.inflate(buf);
            destOffset = (y + dy) * rfb.framebufferWidth + x;
            for (i = 0; i < w; i++) {
              pixels24[destOffset + i] =
                (buf[srcOffset] & 0xFF) << 16 |
                (buf[srcOffset + 1] & 0xFF) << 8 |
                (buf[srcOffset + 2] & 0xFF);
              srcOffset += 3;
            }
          }
        }
      }
    }

    handleUpdatedPixels(x, y, w, h);
    scheduleRepaint(x, y, w, h);
  }

  //
  // Decode 1bpp-encoded bi-color rectangle (8-bit and 24-bit versions).
  //

  void decodeMonoData(int x, int y, int w, int h, byte[] src, byte[] palette) {

    int dx, dy, n;
    int i = y * rfb.framebufferWidth + x;
    int rowBytes = (w + 7) / 8;
    byte b;

    for (dy = 0; dy < h; dy++) {
      for (dx = 0; dx < w / 8; dx++) {
        b = src[dy*rowBytes+dx];
        for (n = 7; n >= 0; n--)
          pixels8[i++] = palette[b >> n & 1];
      }
      for (n = 7; n >= 8 - w % 8; n--) {
        pixels8[i++] = palette[src[dy*rowBytes+dx] >> n & 1];
      }
      i += (rfb.framebufferWidth - w);
    }
  }

  void decodeMonoData(int x, int y, int w, int h, byte[] src, int[] palette) {

    int dx, dy, n;
    int i = y * rfb.framebufferWidth + x;
    int rowBytes = (w + 7) / 8;
    byte b;

    for (dy = 0; dy < h; dy++) {
      for (dx = 0; dx < w / 8; dx++) {
        b = src[dy*rowBytes+dx];
        for (n = 7; n >= 0; n--)
          pixels24[i++] = palette[b >> n & 1];
      }
      for (n = 7; n >= 8 - w % 8; n--) {
        pixels24[i++] = palette[src[dy*rowBytes+dx] >> n & 1];
      }
      i += (rfb.framebufferWidth - w);
    }
  }

  //
  // Decode data processed with the "Gradient" filter.
  //

  void decodeGradientData (int x, int y, int w, int h, byte[] buf) {

    int dx, dy, c;
    byte[] prevRow = new byte[w * 3];
    byte[] thisRow = new byte[w * 3];
    byte[] pix = new byte[3];
    int[] est = new int[3];

    int offset = y * rfb.framebufferWidth + x;

    for (dy = 0; dy < h; dy++) {

      /* First pixel in a row */
      for (c = 0; c < 3; c++) {
        pix[c] = (byte)(prevRow[c] + buf[dy * w * 3 + c]);
        thisRow[c] = pix[c];
      }
      pixels24[offset++] =
        (pix[0] & 0xFF) << 16 | (pix[1] & 0xFF) << 8 | (pix[2] & 0xFF);

      /* Remaining pixels of a row */
      for (dx = 1; dx < w; dx++) {
        for (c = 0; c < 3; c++) {
          est[c] = ((prevRow[dx * 3 + c] & 0xFF) + (pix[c] & 0xFF) -
                    (prevRow[(dx-1) * 3 + c] & 0xFF));
          if (est[c] > 0xFF) {
            est[c] = 0xFF;
          } else if (est[c] < 0x00) {
            est[c] = 0x00;
          }
          pix[c] = (byte)(est[c] + buf[(dy * w + dx) * 3 + c]);
          thisRow[dx * 3 + c] = pix[c];
        }
        pixels24[offset++] =
          (pix[0] & 0xFF) << 16 | (pix[1] & 0xFF) << 8 | (pix[2] & 0xFF);
      }

      System.arraycopy(thisRow, 0, prevRow, 0, w * 3);
      offset += (rfb.framebufferWidth - w);
    }
  }

  //
  // Display newly updated area of pixels.
  //

  void handleUpdatedPixels(int x, int y, int w, int h) {

    // Draw updated pixels of the off-screen image.
    pixelsSource.newPixels(x, y, w, h);
    memGraphics.setClip(x, y, w, h);
    memGraphics.drawImage(rawPixelsImage, 0, 0, null);
    memGraphics.setClip(0, 0, rfb.framebufferWidth, rfb.framebufferHeight);
  }

  //
  // Tell JVM to repaint specified desktop area.
  //

  void scheduleRepaint(int x, int y, int w, int h) {
    // Request repaint, deferred if necessary.
    if (rfb.framebufferWidth == scaledWidth) {
      repaint(viewer.deferScreenUpdates, x, y, w, h);
    } else {
      int sx = x * scalingFactor / 100;
      int sy = y * scalingFactor / 100;
      int sw = ((x + w) * scalingFactor + 49) / 100 - sx + 1;
      int sh = ((y + h) * scalingFactor + 49) / 100 - sy + 1;
      repaint(viewer.deferScreenUpdates, sx, sy, sw, sh);
    }
  }

  //
  // Handle events.
  //

  public void keyPressed(KeyEvent evt) {
    processLocalKeyEvent(evt);
  }
  public void keyReleased(KeyEvent evt) {
    processLocalKeyEvent(evt);
  }
  public void keyTyped(KeyEvent evt) {
    evt.consume();
  }

  public void mousePressed(MouseEvent evt) {
    processLocalMouseEvent(evt, false);
  }
  public void mouseReleased(MouseEvent evt) {
    processLocalMouseEvent(evt, false);
  }
  public void mouseMoved(MouseEvent evt) {
    processLocalMouseEvent(evt, true);
  }
  public void mouseDragged(MouseEvent evt) {
    processLocalMouseEvent(evt, true);
  }

  public void processLocalKeyEvent(KeyEvent evt) {
    if (viewer.rfb != null && rfb.inNormalProtocol) {
      if (!inputEnabled) {
        if ((evt.getKeyChar() == 'r' || evt.getKeyChar() == 'R') &&
            evt.getID() == KeyEvent.KEY_PRESSED ) {
          // Request screen update.
          try {
            rfb.writeFramebufferUpdateRequest(0, 0, rfb.framebufferWidth,
                                              rfb.framebufferHeight, false);
          } catch (IOException e) {
            e.printStackTrace();
          }
        }
      } else {
        // Input enabled.
        synchronized(rfb) {
          try {
            rfb.writeKeyEvent(evt);
          } catch (Exception e) {
            e.printStackTrace();
          }
          rfb.notify();
        }
      }
    }
    // Don't ever pass keyboard events to AWT for default processing. 
    // Otherwise, pressing Tab would switch focus to ButtonPanel etc.
    evt.consume();
  }

  public void processLocalMouseEvent(MouseEvent evt, boolean moved) {
    if (viewer.rfb != null && rfb.inNormalProtocol) {
      if (moved) {
        softCursorMove(evt.getX(), evt.getY());
      }
      if (rfb.framebufferWidth != scaledWidth) {
        int sx = (evt.getX() * 100 + scalingFactor/2) / scalingFactor;
        int sy = (evt.getY() * 100 + scalingFactor/2) / scalingFactor;
        evt.translatePoint(sx - evt.getX(), sy - evt.getY());
      }
      synchronized(rfb) {
        try {
          rfb.writePointerEvent(evt);
        } catch (Exception e) {
          e.printStackTrace();
        }
        rfb.notify();
      }
    }
  }

  //
  // Ignored events.
  //

  public void mouseClicked(MouseEvent evt) {}
  public void mouseEntered(MouseEvent evt) {}
  public void mouseExited(MouseEvent evt) {}


  //////////////////////////////////////////////////////////////////
  //
  // Handle cursor shape updates (XCursor and RichCursor encodings).
  //

  boolean showSoftCursor = false;

  MemoryImageSource softCursorSource;
  Image softCursor;

  int cursorX = 0, cursorY = 0;
  int cursorWidth, cursorHeight;
  int origCursorWidth, origCursorHeight;
  int hotX, hotY;
  int origHotX, origHotY;

  //
  // Handle cursor shape update (XCursor and RichCursor encodings).
  //

  synchronized void
    handleCursorShapeUpdate(int encodingType,
                            int xhot, int yhot, int width, int height)
    throws IOException {

    softCursorFree();

    if (width * height == 0)
      return;

    // Ignore cursor shape data if requested by user.
    if (viewer.options.ignoreCursorUpdates) {
      int bytesPerRow = (width + 7) / 8;
      int bytesMaskData = bytesPerRow * height;

      if (encodingType == rfb.EncodingXCursor) {
        rfb.is.skipBytes(6 + bytesMaskData * 2);
      } else {
        // rfb.EncodingRichCursor
        rfb.is.skipBytes(width * height + bytesMaskData);
      }
      return;
    }

    // Decode cursor pixel data.
    softCursorSource = decodeCursorShape(encodingType, width, height);

    // Set original (non-scaled) cursor dimensions.
    origCursorWidth = width;
    origCursorHeight = height;
    origHotX = xhot;
    origHotY = yhot;

    // Create off-screen cursor image.
    createSoftCursor();

    // Show the cursor.
    showSoftCursor = true;
    repaint(viewer.deferCursorUpdates,
            cursorX - hotX, cursorY - hotY, cursorWidth, cursorHeight);
  }

  //
  // decodeCursorShape(). Decode cursor pixel data and return
  // corresponding MemoryImageSource instance.
  //

  synchronized MemoryImageSource
    decodeCursorShape(int encodingType, int width, int height)
    throws IOException {

    int bytesPerRow = (width + 7) / 8;
    int bytesMaskData = bytesPerRow * height;

    int[] softCursorPixels = new int[width * height];

    if (encodingType == rfb.EncodingXCursor) {

      // Read foreground and background colors of the cursor.
      byte[] rgb = new byte[6];
      rfb.readFully(rgb);
      int[] colors = { (0xFF000000 | (rgb[3] & 0xFF) << 16 |
                        (rgb[4] & 0xFF) << 8 | (rgb[5] & 0xFF)),
                       (0xFF000000 | (rgb[0] & 0xFF) << 16 |
                        (rgb[1] & 0xFF) << 8 | (rgb[2] & 0xFF)) };

      // Read pixel and mask data.
      byte[] pixBuf = new byte[bytesMaskData];
      rfb.readFully(pixBuf);
      byte[] maskBuf = new byte[bytesMaskData];
      rfb.readFully(maskBuf);

      // Decode pixel data into softCursorPixels[].
      byte pixByte, maskByte;
      int x, y, n, result;
      int i = 0;
      for (y = 0; y < height; y++) {
        for (x = 0; x < width / 8; x++) {
          pixByte = pixBuf[y * bytesPerRow + x];
          maskByte = maskBuf[y * bytesPerRow + x];
          for (n = 7; n >= 0; n--) {
            if ((maskByte >> n & 1) != 0) {
              result = colors[pixByte >> n & 1];
            } else {
              result = 0;       // Transparent pixel
            }
            softCursorPixels[i++] = result;
          }
        }
        for (n = 7; n >= 8 - width % 8; n--) {
          if ((maskBuf[y * bytesPerRow + x] >> n & 1) != 0) {
            result = colors[pixBuf[y * bytesPerRow + x] >> n & 1];
          } else {
            result = 0;         // Transparent pixel
          }
          softCursorPixels[i++] = result;
        }
      }

    } else {
      // encodingType == rfb.EncodingRichCursor

      // Read pixel and mask data.
      byte[] pixBuf = new byte[width * height * bytesPixel];
      rfb.readFully(pixBuf);
      byte[] maskBuf = new byte[bytesMaskData];
      rfb.readFully(maskBuf);

      // Decode pixel data into softCursorPixels[].
      byte pixByte, maskByte;
      int x, y, n, result;
      int i = 0;
      for (y = 0; y < height; y++) {
        for (x = 0; x < width / 8; x++) {
          maskByte = maskBuf[y * bytesPerRow + x];
          for (n = 7; n >= 0; n--) {
            if ((maskByte >> n & 1) != 0) {
              if (bytesPixel == 1) {
                result = cm8.getRGB(pixBuf[i]);
              } else {
                result = 0xFF000000 |
                  (pixBuf[i * 4 + 2] & 0xFF) << 16 |
                  (pixBuf[i * 4 + 1] & 0xFF) << 8 |
                  (pixBuf[i * 4] & 0xFF);
              }
            } else {
              result = 0;       // Transparent pixel
            }
            softCursorPixels[i++] = result;
          }
        }
        for (n = 7; n >= 8 - width % 8; n--) {
          if ((maskBuf[y * bytesPerRow + x] >> n & 1) != 0) {
            if (bytesPixel == 1) {
              result = cm8.getRGB(pixBuf[i]);
            } else {
              result = 0xFF000000 |
                (pixBuf[i * 4 + 2] & 0xFF) << 16 |
                (pixBuf[i * 4 + 1] & 0xFF) << 8 |
                (pixBuf[i * 4] & 0xFF);
            }
          } else {
            result = 0;         // Transparent pixel
          }
          softCursorPixels[i++] = result;
        }
      }

    }

    return new MemoryImageSource(width, height, softCursorPixels, 0, width);
  }

  //
  // createSoftCursor(). Assign softCursor new Image (scaled if necessary).
  // Uses softCursorSource as a source for new cursor image.
  //

  synchronized void
    createSoftCursor() {

    if (softCursorSource == null)
      return;

    int scaleCursor = viewer.options.scaleCursor;
    if (scaleCursor == 0 || !inputEnabled)
      scaleCursor = 100;

    // Save original cursor coordinates.
    int x = cursorX - hotX;
    int y = cursorY - hotY;
    int w = cursorWidth;
    int h = cursorHeight;

    cursorWidth = (origCursorWidth * scaleCursor + 50) / 100;
    cursorHeight = (origCursorHeight * scaleCursor + 50) / 100;
    hotX = (origHotX * scaleCursor + 50) / 100;
    hotY = (origHotY * scaleCursor + 50) / 100;
    softCursor = Toolkit.getDefaultToolkit().createImage(softCursorSource);

    if (scaleCursor != 100) {
      softCursor = softCursor.getScaledInstance(cursorWidth, cursorHeight,
                                                Image.SCALE_SMOOTH);
    }

    if (showSoftCursor) {
      // Compute screen area to update.
      x = Math.min(x, cursorX - hotX);
      y = Math.min(y, cursorY - hotY);
      w = Math.max(w, cursorWidth);
      h = Math.max(h, cursorHeight);

      repaint(viewer.deferCursorUpdates, x, y, w, h);
    }
  }

  //
  // softCursorMove(). Moves soft cursor into a particular location.
  //

  synchronized void softCursorMove(int x, int y) {
    int oldX = cursorX;
    int oldY = cursorY;
    cursorX = x;
    cursorY = y;
    if (showSoftCursor) {
      repaint(viewer.deferCursorUpdates,
              oldX - hotX, oldY - hotY, cursorWidth, cursorHeight);
      repaint(viewer.deferCursorUpdates,
              cursorX - hotX, cursorY - hotY, cursorWidth, cursorHeight);
    }
  }

  //
  // softCursorFree(). Remove soft cursor, dispose resources.
  //

  synchronized void softCursorFree() {
    if (showSoftCursor) {
      showSoftCursor = false;
      softCursor = null;
      softCursorSource = null;

      repaint(viewer.deferCursorUpdates,
              cursorX - hotX, cursorY - hotY, cursorWidth, cursorHeight);
    }
  }
}