捕获桌面，使其256色，并通过互联网发送

for (int y=0;y<900;y++) //loop through the height
     for (int x=0;x<1600;x++) //loop through the width
         for (int p=0;p<256;p++) //loop through palette colors
             {
                calculate Euclidean distance of each pixel for each color in pallette and 
                 find the nearest color
                 ** these nested loops take 7 seconds to complete
             }

OK。经过几天与许多捕获方法和颜色量化器的斗争，我终于找到了一个解决方案。现在我可以以10~14 FPS的速度发送整个桌面图像，并以20~30 FPS的速度发送桌面的更改区域。

在代码中，我使用rcravens的类来捕获屏幕和屏幕的变化。然后我将图像裁剪成10个小块。之后，我用八叉树颜色量化器把它们做成256色，感谢@Dai给我指出了这个方向。在颜色还原后，我将每个片段转换为字节数组并使用LZ4压缩它们。网络图书馆。

代码如下:

    int all_count = 0;
    Bitmap _desktop = null;
    Bitmap _merged_bitmap = new Bitmap(1600, 900);
    int _height_part_ = 0;
    int _total_rows = 10;
    Bitmap[] crops = null;
    Bitmap[] _new_crops = null;
    Stopwatch sw = new Stopwatch();
    int _desktop_height = 0;
    int _desktop_width = 0;
    ImageManipulation.OctreeQuantizer _q ;
    RLC.RemoteDesktop.ScreenCapture cap = new RLC.RemoteDesktop.ScreenCapture();

   private void CaptureAndSend()
    {
        sw.Restart();
        //cap = new RLC.RemoteDesktop.ScreenCapture();
        int _left = -1, _top = -1; //Changed regions
        _desktop = cap.Screen(out _left, out _top); //Capture desktop or changed region of it
        if (_desktop == null) return; //if nothing has changed since last capture skip everything
        _desktop_height = _desktop.Height;
        _desktop_width = _desktop.Width;
        // If very small part has changed since last capture skip everything
        if (_desktop_height < 10 || _desktop_width < 10) return; 
        TotalRows(_total_rows); // Calculate the total number of rows 
        crops = new Bitmap[_total_rows]; // Cropped pieces of image
        _new_crops = new Bitmap[_total_rows];
        for (int i = 0; i < _total_rows - 1; i++) //Take whole image and split it into smaller images
            crops[i] = CropRow(i);
        crops[_total_rows - 1] = CropLastRow(_total_rows - 1);

        Parallel.For(0, _total_rows, i =>
        {
            ImageManipulation.OctreeQuantizer _q = new ImageManipulation.OctreeQuantizer(255, 4); // Initialize Octree
            _new_crops[i] = _q.Quantize(crops[i]);
            using (MemoryStream ms=new MemoryStream())
            { 
                _new_crops[i].Save(ms, ImageFormat.Png);
                //Install-Package LZ4.net
                //Compress each part and send them over network
                byte[] data = Lz4Net.Lz4.CompressBytes(ms.ToArray(), Lz4Net.Lz4Mode.HighCompression);
                all_count += data.Length; //Just to check the final size of image
            }                  
        });

        Console.WriteLine(String.Format("{0:0.0} FPS , {1} seconds , size {2} kb", 1.0 / sw.Elapsed.TotalSeconds, sw.Elapsed.TotalSeconds.ToString(), all_count / 1024));
        all_count = 0;
    }
    private void TotalRows(int parts)
    {
        _height_part_ = _desktop_height / parts;
    }
    private Bitmap CropRow(int row)
    {
        return Crop(_desktop, new Rectangle(0, row * _height_part_, _desktop_width, _height_part_));
    }
    private Bitmap CropLastRow(int row)
    {
        return Crop(_desktop, new Rectangle(0, row * _height_part_, _desktop_width, _desktop_height - (row * _height_part_)));
    }
 [DllImport("msvcrt.dll", CallingConvention = CallingConvention.Cdecl)]
    private unsafe static extern int memcpy(byte* dest, byte* src, long count);
    private unsafe Bitmap Crop(Bitmap srcImg, Rectangle rectangle)
    {
        if ((srcImg.Width == rectangle.Width) && (srcImg.Height == rectangle.Height))
            return srcImg;
        var srcImgBitmapData = srcImg.LockBits(new Rectangle(0, 0, srcImg.Width, srcImg.Height), ImageLockMode.ReadOnly, srcImg.PixelFormat);
        var bpp = srcImgBitmapData.Stride / srcImgBitmapData.Width; // 3 or 4
        var srcPtr = (byte*)srcImgBitmapData.Scan0.ToPointer() + rectangle.Y * srcImgBitmapData.Stride + rectangle.X * bpp;
        var srcStride = srcImgBitmapData.Stride;
        var dstImg = new Bitmap(rectangle.Width, rectangle.Height, srcImg.PixelFormat);
        var dstImgBitmapData = dstImg.LockBits(new Rectangle(0, 0, dstImg.Width, dstImg.Height), ImageLockMode.WriteOnly, dstImg.PixelFormat);
        var dstPtr = (byte*)dstImgBitmapData.Scan0.ToPointer();
        var dstStride = dstImgBitmapData.Stride;
        for (int y = 0; y < rectangle.Height; y++)
        {
            memcpy(dstPtr, srcPtr, dstStride);
            srcPtr += srcStride;
            dstPtr += dstStride;
        }
        srcImg.UnlockBits(srcImgBitmapData);
        dstImg.UnlockBits(dstImgBitmapData);
        return dstImg;
    }

我知道我的代码不是内存有效的。如果有人能帮我优化这段代码，我将不胜感激。再次感谢我的朋友A. Abramov, Dai, HansPassant, TaW和其他人。

EDIT 2:我完全删除了我的旧帖子，因为它不相关!你说的256色，我以为你指的是256位——而你说的是256字节!我把原始坐标(900 x 900)代入计算器，然后乘以256表示颜色。结果是20,7360,000位，大致是2.5 MB位。压缩后，它可以达到1 MB -而位颜色等效(除以8)将是300 KB基数，压缩后会小得多。解决办法很简单——拍这样一张照片确实需要这么长时间。你所说的大多数应用，比如teamviewer，都有较低的FPS。较低的图像质量，基于计算机性能。因此，我很抱歉，但解决方案是，用像你这样的电脑，可能不可能在你要求的时间内完成。

编辑3: Hans在你的问题下面的评论中做了数学计算——我们说的是22 GB。这不是一台普通电脑的正常工作。这不是不可能的，但从2015年开始，家用电脑在一秒钟内处理这么多数据是很不常见的。