Mercurial > hg > Applications > TreeVNC
view src/main/java/com/glavsoft/rfb/encoding/decoder/ZRLEDecoder.java @ 534:a3d0ba67e8cf
try 512 tiles / 256 tiles flush
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 06 May 2019 16:59:25 +0900 |
| parents | 4be31e107121 |
| children | 17a2d0ea5c03 |
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// Copyright (C) 2010, 2011, 2012, 2013 GlavSoft LLC. // All rights reserved. // //------------------------------------------------------------------------- // This file is part of the TightVNC software. Please visit our Web site: // // http://www.tightvnc.com/ // // This program 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 program 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 program; if not, write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. //------------------------------------------------------------------------- // package com.glavsoft.rfb.encoding.decoder; import com.glavsoft.drawing.Renderer; import com.glavsoft.exceptions.TransportException; import com.glavsoft.rfb.encoding.EncodingType; import com.glavsoft.transport.Reader; import jp.ac.u_ryukyu.treevnc.CheckDelay; import jp.ac.u_ryukyu.treevnc.TreeRFBProto; import java.io.UnsupportedEncodingException; import java.nio.ByteBuffer; import java.util.LinkedList; import java.util.zip.Deflater; public class ZRLEDecoder extends ZlibDecoder { private static final int MAX_TILE_SIZE = 64; private int[] decodedBitmap; private int[] palette; class TileLoop { private int deflate_size = 65507; private ByteBuffer c1; private int width; // phase2 length private FramebufferUpdateRectangle c1rect; private int c1headerPos; private int prevLineOffset; private int prevC1Offset; private int prevoffset; private Deflater deflater; private int rectPos; private int ztileInLine; private int hwidth; private int hc1width; private int hoffset; private int hc1offset; /** * Multicast framebufferUpdate to children. * read FrameBuffferUpdate. If it is ZLE, make it ZLEE which is self contained compressed packet. * put the packet to the multicastqueue. Then normal rendering engine read the same stream using is.reset(). * * Haeder * messageID ( FrameBuffer Update * 1 byte padding * 2 byte numberofrectangle * 2 - U16 - x-position * 2 - U16 - y-position * 2 - U16 - width * 2 - U16 - height * 4 - S32 - encoding-type * 4 byte datalengths * datalengths databyte * * @throws TransportException * @throws UnsupportedEncodingException */ public TileLoop(int offset) { prevoffset = prevLineOffset = prevC1Offset = offset; } private void zrleeBlocking(TreeRFBProto rfb, ByteBuffer header, FramebufferUpdateRectangle rect) { // dump32(inputs); deflater = rfb.deflater; newMulticastPacket(rfb, rect); c1.put(header.get(0)); c1rect = new FramebufferUpdateRectangle(rect.x, rect.y, 0, 0); return; } private void newMulticastPacket(TreeRFBProto rfb, FramebufferUpdateRectangle rect) { c1 = rfb.multicastqueue.allocate(deflate_size); if (rfb.addSerialNum) c1.putLong(rfb.counter++); if (rfb.checkDelay) CheckDelay.checkDelay(c1, rect.x, rect.y, rect.width, rect.height, System.currentTimeMillis(), EncodingType.CHECK_DELAY); c1headerPos = c1.position(); c1.put((byte) 0); c1.put((byte) 0); c1.putShort((short) 0); c1.position(c1.position()+16); c1.putInt(0); // should be data length width = 0; rectPos = 4; ztileInLine = 0; } int spanGap = 128; /** * * Series of tiles compose at most three rectangles. SYNC_FLUSH is necessary on * rectangle boundaries. * * +----+ * | | | phase 0 * +---------------+ * | | | phase 1 * +----+----------+ * | | | phase 2 * +----+ * * Broadcast packet have to less than 64kbytes * A tile 8x8x3 192byte, a packet can contain 340 raw tiles, when these are * compressed 500 to 2000 tiles can be stored. It is impossible to predict the * compression rate. To check the compressed capacity, Deflate.needsInputs() can * be used. If needsInputs() is false on SYNC_FLUSH, smaller input is necessary. * * We'll try 512 tiles before SYNC_FLUSH in a phase, if it fails try 256. * If it will failed again, flush the previous line and try again. * If 256 tiles are failed in new packet, discard it. * * @param rfb * @param last * @param rect * @param bytes * @param offset * @param tileW * @param tileH */ int MAX_ZTILE = 512; public void multicastPut(TreeRFBProto rfb, boolean last, FramebufferUpdateRectangle rect, byte[] bytes, int offset, int tileW, int tileH) { int span = offset - prevoffset; deflater.setInput(bytes,prevoffset,span); prevoffset = offset; c1rect.width += tileW; width += tileW; if (c1rect.x > rect.x) { // phase 0 if (c1rect.x+c1rect.width < rect.x+rect.width) { compressAndCheckFlush(rfb, rect, bytes, offset,false, last); } else { c1rect.width = rect.x+rect.width-c1rect.x ; c1rect.height += tileH; compressAndCheckFlush(rfb,rect,bytes,offset,true, last); } } else if (!last && c1.remaining() > spanGap) { // phase 1 if (width >= rect.width) { c1rect.width = rect.width; width = 0; c1rect.height += tileH; prevLineOffset = offset; prevC1Offset = c1.position(); compressAndCheckFlush(rfb,rect,bytes,offset,true, last); } else { compressAndCheckFlush(rfb,rect,bytes,offset,false, last); } } else { // phase2 // rewind to the last line finish phase 1 int savew = width; c1.position(prevC1Offset); flushRectangle(rect); if (savew>0) { // recompress overrun and flush phase 2 c1rect.width = savew; c1rect.height = tileH; compressAndCheckFlush(rfb,rect,bytes,offset,true, last); } } } private void compressAndCheckFlush(TreeRFBProto rfb, FramebufferUpdateRectangle rect, byte[] bytes, int offset, boolean flush, boolean last) { if (!flush && ztileInLine++ < MAX_ZTILE) { if (ztileInLine == MAX_ZTILE/2) { hwidth = width; hc1width = c1rect.width; hoffset = offset; hc1offset = c1.position(); } deflater.deflate(c1, Deflater.NO_FLUSH); } else { deflater.deflate(c1, Deflater.SYNC_FLUSH); if (!deflater.needsInput()) { // too large, try half line width = hwidth; c1rect.width = hc1width; c1.position(hc1offset); deflater.setInput(bytes, prevLineOffset, hoffset - prevC1Offset); deflater.deflate(c1, Deflater.SYNC_FLUSH); int from, len; if (!deflater.needsInput()) { // flush previous line and start new packet c1.position(prevC1Offset); unputrectangle(); flushMuticast(rfb); newMulticastPacket(rfb, rect); nextRectangle(rect); // we already reached MIX_ZTILE do half of them, do compress right now from = prevC1Offset; len = offset - prevLineOffset; deflater.setInput(bytes, from, len); deflater.deflate(c1, Deflater.SYNC_FLUSH); if (deflater.needsInput()) { flushRectangle(rect); // we are the flushed last line return; } // half size should always succeed from = prevC1Offset; len = hoffset - prevLineOffset; deflater.setInput(bytes, from, len); deflater.deflate(c1, Deflater.SYNC_FLUSH); if (!deflater.needsInput()) { /* fatal error discard this line */ if (!last) { newMulticastPacket(rfb, rect); nextRectangle(rect); } return; } else flushRectangle(rect); // normal case // later half is remain continue } else { flushMuticast(rfb); newMulticastPacket(rfb,rect); nextRectangle(rect); } // do later half in new Packet from = hoffset ; len = offset - hoffset; deflater.setInput(bytes, from, len); deflater.deflate(c1, Deflater.NO_FLUSH); hwidth = width; hoffset = offset; hc1offset = c1.position(); ztileInLine = MAX_ZTILE/2; } } } /** * fix rectangle header * create next rectangle header * update position paramater * send muticast pacate if nessesally */ private void flushRectangle(FramebufferUpdateRectangle rect) { c1.putShort(rectPos + 0, (short)c1rect.x); c1.putShort(rectPos + 2, (short)c1rect.y); c1.putShort(rectPos + 4, (short)c1rect.width); c1.putShort(rectPos + 6, (short)c1rect.height); c1.putInt(rectPos + 8,EncodingType.ZRLEE.getId()); c1.putInt(rectPos + 12, c1.position()-rectPos-12); // data length rectPos = c1.position(); c1.putShort(2,(short)(c1.getShort(2)+1)); // increment rectangle count nextRectangle(rect); ztileInLine = 0; } private void unputrectangle() { c1.putShort(2,(short)(c1.getShort(2)-1)); // last rectangle is canceled } private void nextRectangle(FramebufferUpdateRectangle rect) { if (c1rect.x+c1rect.width < rect.x+rect.width) { c1rect.x = c1rect.width; // next rectangle is phase 1 } else { c1rect.x = rect.x; c1rect.y += c1rect.height; } width = 0; c1rect.width = 0; c1rect.height = 0; } private void flushMuticast(TreeRFBProto rfb) { c1.flip(); //System.out.println("multicastPut: " + c1rect + " length: " + (c1.remaining()-c1headerPos-header.limit())); try { deflater.reset(); LinkedList<ByteBuffer> bufs = new LinkedList<ByteBuffer>(); bufs.add(c1); if (rfb.isTreeManager() && rfb.connectionPresenter.isUseMulticast()) { for (ByteBuffer buf : bufs) rfb.getViewer().getRfbBroadcastListener().multicastUpdateRectangle(buf); } else { rfb.multicastqueue.waitput(bufs); } } catch (InterruptedException e) { e.printStackTrace(); } } } @Override public void decode(Reader reader, Renderer renderer, FramebufferUpdateRectangle rect) throws TransportException { int zippedLength = (int) reader.readUInt32(); if (0 == zippedLength) return; int length = rect.width * rect.height * renderer.getBytesPerPixel(); byte[] bytes = unzip(reader, zippedLength, length, rect.getEncodingType()); decode1(renderer, null, rect, bytes, zippedLength, null); } public void multicastDecode(Reader reader, Renderer renderer, FramebufferUpdateRectangle rect, TreeRFBProto rfb) throws TransportException { ByteBuffer header = ByteBuffer.allocate(16); reader.read(header.array()); int zippedLength = (int) reader.readUInt32(); if (0 == zippedLength) return; int length = rect.width * rect.height * renderer.getBytesPerPixel(); byte[] bytes = unzip(reader, zippedLength, length, rect.getEncodingType()); decode1(renderer, header, rect, bytes, zippedLength, rfb); } public void decode1(Renderer renderer, ByteBuffer header, FramebufferUpdateRectangle rect, byte[] bytes, int zippedLength, TreeRFBProto rfbProto) throws TransportException { int offset = zippedLength; int maxX = rect.x + rect.width; int maxY = rect.y + rect.height; TileLoop tileloop = new TileLoop(zippedLength); //System.out.println("decode1: "+rect); if (null == palette) { palette = new int [128]; } if (null == decodedBitmap) { decodedBitmap = new int[MAX_TILE_SIZE * MAX_TILE_SIZE]; } if (rfbProto.multicastBlocking) { tileloop.zrleeBlocking(rfbProto, header, rect); } for (int tileY = rect.y; tileY < maxY; tileY += MAX_TILE_SIZE) { int tileHeight = Math.min(maxY - tileY, MAX_TILE_SIZE); for (int tileX = rect.x; tileX < maxX; tileX += MAX_TILE_SIZE) { int tileWidth = Math.min(maxX - tileX, MAX_TILE_SIZE); int subencoding = bytes[offset++] & 0x0ff; if(subencoding!=0) System.out.println("----------------"+subencoding); // 128 -plain RLE, 130-255 - Palette RLE boolean isRle = (subencoding & 128) != 0; // 2 to 16 for raw packed palette data, 130 to 255 for Palette RLE (subencoding - 128) int paletteSize = subencoding & 127; offset += readPalette(bytes, offset, renderer, paletteSize); if (1 == subencoding) { // A solid tile consisting of a single colour renderer.fillRect(palette[0], tileX, tileY, tileWidth, tileHeight); } else if (isRle) { if (0 == paletteSize) { // subencoding == 128 (or paletteSize == 0) - Plain RLE offset += decodePlainRle(bytes, offset, renderer, tileX, tileY, tileWidth, tileHeight); } else { offset += decodePaletteRle(bytes, offset, renderer, tileX, tileY, tileWidth, tileHeight); } } else { if (0 == paletteSize) { // subencoding == 0 (or paletteSize == 0) - raw CPIXEL data offset += decodeRaw(bytes, offset, renderer, tileX, tileY, tileWidth, tileHeight); // System.out.println("offset:"+offset); } else { offset += decodePacked(bytes, offset, renderer, paletteSize, tileX, tileY, tileWidth, tileHeight); } } if (rfbProto != null && rfbProto.multicastBlocking) tileloop.multicastPut(rfbProto, false, rect, bytes, offset, tileWidth, tileHeight); } } if (rfbProto != null && rfbProto.multicastBlocking) tileloop.multicastPut(rfbProto, true, rect, bytes, offset, 0, 0); } private int decodePlainRle(byte[] bytes, int offset, Renderer renderer, int tileX, int tileY, int tileWidth, int tileHeight) { int bytesPerCPixel = renderer.getBytesPerCPixel(); int decodedOffset = 0; int decodedEnd = tileWidth * tileHeight; int index = offset; while (decodedOffset < decodedEnd) { int color = renderer.getCompactPixelColor(bytes, index); index += bytesPerCPixel; int rlength = 1; do { rlength += bytes[index] & 0x0ff; } while ((bytes[index++] & 0x0ff) == 255); assert rlength <= decodedEnd - decodedOffset; renderer.fillColorBitmapWithColor(decodedBitmap, decodedOffset, rlength, color); decodedOffset += rlength; } renderer.drawColoredBitmap(decodedBitmap, tileX, tileY, tileWidth, tileHeight); return index - offset; } private int decodePaletteRle(byte[] bytes, int offset, Renderer renderer, int tileX, int tileY, int tileWidth, int tileHeight) { int decodedOffset = 0; int decodedEnd = tileWidth * tileHeight; int index = offset; while (decodedOffset < decodedEnd) { int colorIndex = bytes[index++]; int color = palette[colorIndex & 127]; int rlength = 1; if ((colorIndex & 128) != 0) { do { rlength += bytes[index] & 0x0ff; } while (bytes[index++] == (byte) 255); } assert rlength <= decodedEnd - decodedOffset; renderer.fillColorBitmapWithColor(decodedBitmap, decodedOffset, rlength, color); decodedOffset += rlength; } renderer.drawColoredBitmap(decodedBitmap, tileX, tileY, tileWidth, tileHeight); return index - offset; } private int decodePacked(byte[] bytes, int offset, Renderer renderer, int paletteSize, int tileX, int tileY, int tileWidth, int tileHeight) { int bitsPerPalletedPixel = paletteSize > 16 ? 8 : paletteSize > 4 ? 4 : paletteSize > 2 ? 2 : 1; int packedOffset = offset; int decodedOffset = 0; for (int i = 0; i < tileHeight; ++i) { int decodedRowEnd = decodedOffset + tileWidth; int byteProcessed = 0; int bitsRemain = 0; while (decodedOffset < decodedRowEnd) { if (bitsRemain == 0) { byteProcessed = bytes[packedOffset++]; bitsRemain = 8; } bitsRemain -= bitsPerPalletedPixel; int index = byteProcessed >> bitsRemain & (1 << bitsPerPalletedPixel) - 1 & 127; int color = palette[index]; renderer.fillColorBitmapWithColor(decodedBitmap, decodedOffset, 1, color); ++decodedOffset; } } renderer.drawColoredBitmap(decodedBitmap, tileX, tileY, tileWidth, tileHeight); return packedOffset - offset; } private int decodeRaw(byte[] bytes, int offset, Renderer renderer, int tileX, int tileY, int tileWidth, int tileHeight) throws TransportException { return renderer.drawCompactBytes(bytes, offset, tileX, tileY, tileWidth, tileHeight); } private int readPalette(byte[] bytes, int offset, Renderer renderer, int paletteSize) { final int bytesPerCPixel = renderer.getBytesPerCPixel(); for (int i=0; i<paletteSize; ++i) { palette[i] = renderer.getCompactPixelColor(bytes, offset + i* bytesPerCPixel); } return paletteSize * bytesPerCPixel; } }