wavescholar/GDI Bitmap Conversion

## GDI Bitmap Conversion
using System;
class klGDIBitmapConversion
{
    public static System.Drawing.Bitmap MainConv(System.Drawing.Bitmap img)
    {
        System.Drawing.Bitmap b = img;// new System.Drawing.Bitmap("test.jpg");
        SplashImage(b, 0, 0);
        DateTime dtFaq = DateTime.Now;
        System.Drawing.Bitmap b0 = CopyToBpp(b, 8);
        TimeSpan tsFaq = DateTime.Now - dtFaq;
        return b0;
       }

    // Fast copy a bitmap into a 1bpp/8bpp bitmap of the same dimensions
     static System.Drawing.Bitmap CopyToBpp(System.Drawing.Bitmap b, int bpp)
    {
        if (bpp != 1 && bpp != 8) throw new System.ArgumentException("1 or 8", "bpp");

        // Plan: built into Windows GDI is the ability to convert
        // bitmaps from one format to another. Most of the time, this
        // job is actually done by the graphics hardware accelerator card
        // and so is extremely fast. The rest of the time, the job is done by
        // very fast native code.
        // We will call into this GDI functionality from C#. Our plan:
        // (1) Convert our Bitmap into a GDI hbitmap (ie. copy unmanaged->managed)
        // (2) Create a GDI monochrome hbitmap
        // (3) Use GDI "BitBlt" function to copy from hbitmap into monochrome (as above)
        // (4) Convert the monochrone hbitmap into a Bitmap (ie. copy unmanaged->managed)

        int w = b.Width, h = b.Height;
        IntPtr hbm = b.GetHbitmap(); // this is step (1)
        //
        // Step (2): create the monochrome bitmap.
        // "BITMAPINFO" is an interop-struct which we define below.
        // In GDI terms, it's a BITMAPHEADERINFO followed by an array of two RGBQUADs
        BITMAPINFO bmi = new BITMAPINFO();
        bmi.biSize = 40;  // the size of the BITMAPHEADERINFO struct
        bmi.biWidth = w;
        bmi.biHeight = h;
        bmi.biPlanes = 1; // "planes" are confusing. We always use just 1. Read MSDN for more info.
        bmi.biBitCount = (short)bpp; // ie. 1bpp or 8bpp
        bmi.biCompression = BI_RGB; // ie. the pixels in our RGBQUAD table are stored as RGBs, not palette indexes
        bmi.biSizeImage = (uint)(((w + 7) & 0xFFFFFFF8) * h / 8);
        bmi.biXPelsPerMeter = 1000000; // not really important
        bmi.biYPelsPerMeter = 1000000; // not really important
        // Now for the colour table.
        uint ncols = (uint)1 << bpp; // 2 colours for 1bpp; 256 colours for 8bpp
        bmi.biClrUsed = ncols;
        bmi.biClrImportant = ncols;
        bmi.cols = new uint[256]; // The structure always has fixed size 256, even if we end up using fewer colours
        if (bpp == 1) { bmi.cols[0] = MAKERGB(0, 0, 0); bmi.cols[1] = MAKERGB(255, 255, 255); }
        else { for (int i = 0; i < ncols; i++) bmi.cols[i] = MAKERGB(i, i, i); }
        // For 8bpp we've created an palette with just greyscale colours.
        // You can set up any palette you want here. Here are some possibilities:
        // greyscale: for (int i=0; i<256; i++) bmi.cols[i]=MAKERGB(i,i,i);
        // rainbow: bmi.biClrUsed=216; bmi.biClrImportant=216; int[] colv=new int[6]{0,51,102,153,204,255};
        //          for (int i=0; i<216; i++) bmi.cols[i]=MAKERGB(colv[i/36],colv[(i/6)%6],colv[i%6]);
        //
        // Now create the indexed bitmap "hbm0"
        IntPtr bits0; // not used for our purposes. It returns a pointer to the raw bits that make up the bitmap.
        IntPtr hbm0 = CreateDIBSection(IntPtr.Zero, ref bmi, DIB_RGB_COLORS, out bits0, IntPtr.Zero, 0);
        //
        // Step (3): use GDI's BitBlt function to copy from original hbitmap into monocrhome bitmap
        // GDI programming is kind of confusing... nb. The GDI equivalent of "Graphics" is called a "DC".
        IntPtr sdc = GetDC(IntPtr.Zero);       // First we obtain the DC for the screen
        // Next, create a DC for the original hbitmap
        IntPtr hdc = CreateCompatibleDC(sdc); SelectObject(hdc, hbm);
        // and create a DC for the monochrome hbitmap
        IntPtr hdc0 = CreateCompatibleDC(sdc); SelectObject(hdc0, hbm0);
        // Now we can do the BitBlt:
        BitBlt(hdc0, 0, 0, w, h, hdc, 0, 0, SRCCOPY);
        // Step (4): convert this monochrome hbitmap back into a Bitmap:
        System.Drawing.Bitmap b0 = System.Drawing.Bitmap.FromHbitmap(hbm0);
        //
        // Finally some cleanup.
        DeleteDC(hdc);
        DeleteDC(hdc0);
        ReleaseDC(IntPtr.Zero, sdc);
        DeleteObject(hbm);
        DeleteObject(hbm0);
        //
        return b0;
    }

    // Draws a bitmap onto the screen. Note: this will be overpainted
    // by other windows when they come to draw themselves. Only use it
    // if you want to draw something quickly and can't be bothered with forms.
    static void SplashImage(System.Drawing.Bitmap b, int x, int y)
    { // Drawing onto the screen is supported by GDI, but not by the Bitmap/Graphics class.
        // So we use interop:
        // (1) Copy the Bitmap into a GDI hbitmap
        IntPtr hbm = b.GetHbitmap();
        // (2) obtain the GDI equivalent of a "Graphics" for the screen
        IntPtr sdc = GetDC(IntPtr.Zero);
        // (3) obtain the GDI equivalent of a "Graphics" for the hbitmap
        IntPtr hdc = CreateCompatibleDC(sdc);
        SelectObject(hdc, hbm);
        // (4) Draw from the hbitmap's "Graphics" onto the screen's "Graphics"
        BitBlt(sdc, x, y, b.Width, b.Height, hdc, 0, 0, SRCCOPY);
        // and do boring GDI cleanup:
        DeleteDC(hdc);
        ReleaseDC(IntPtr.Zero, sdc);
        DeleteObject(hbm);
    }


    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    public static extern bool DeleteObject(IntPtr hObject);

    [System.Runtime.InteropServices.DllImport("user32.dll")]
    public static extern int InvalidateRect(IntPtr hwnd, IntPtr rect, int bErase);

    [System.Runtime.InteropServices.DllImport("user32.dll")]
    public static extern IntPtr GetDC(IntPtr hwnd);

    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    public static extern IntPtr CreateCompatibleDC(IntPtr hdc);

    [System.Runtime.InteropServices.DllImport("user32.dll")]
    public static extern int ReleaseDC(IntPtr hwnd, IntPtr hdc);

    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    public static extern int DeleteDC(IntPtr hdc);

    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    public static extern IntPtr SelectObject(IntPtr hdc, IntPtr hgdiobj);

    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    public static extern int BitBlt(IntPtr hdcDst, int xDst, int yDst, int w, int h, IntPtr hdcSrc, int xSrc, int ySrc, int rop);
    static int SRCCOPY = 0x00CC0020;

    //Specifies the raster operation to be performed.
    //Raster-operation codes define how the GDI combines colors in output operations that involve a current brush, a possible source bitmap, and a destination bitmap.
    //See BitBlt in the Platform SDK for a list of the raster-operation codes for dwRop and their descriptions
    //dwRop

    [System.Runtime.InteropServices.DllImport("gdi32.dll")]
    static extern IntPtr CreateDIBSection(IntPtr hdc, ref BITMAPINFO bmi, uint Usage, out IntPtr bits, IntPtr hSection, uint dwOffset);
    static uint BI_RGB = 0;
    static uint DIB_RGB_COLORS = 0;
    [System.Runtime.InteropServices.StructLayout(System.Runtime.InteropServices.LayoutKind.Sequential)]
    public struct BITMAPINFO
    {
        public uint biSize;
        public int biWidth, biHeight;
        public short biPlanes, biBitCount;
        public uint biCompression, biSizeImage;
        public int biXPelsPerMeter, biYPelsPerMeter;
        public uint biClrUsed, biClrImportant;
        [System.Runtime.InteropServices.MarshalAs(System.Runtime.InteropServices.UnmanagedType.ByValArray, SizeConst = 256)]
        public uint[] cols;
    }

    static uint MAKERGB(int r, int g, int b)
    {
        return ((uint)(b & 255)) | ((uint)((r & 255) << 8)) | ((uint)((g & 255) << 16));
    }

    static System.Drawing.Bitmap CopyTo1bpp(System.Drawing.Bitmap b)
    {
        int w = b.Width, h = b.Height; System.Drawing.Rectangle r = new System.Drawing.Rectangle(0, 0, w, h);
        if (b.PixelFormat != System.Drawing.Imaging.PixelFormat.Format32bppPArgb)
        {
            System.Drawing.Bitmap temp = new System.Drawing.Bitmap(w, h, System.Drawing.Imaging.PixelFormat.Format32bppPArgb);
            System.Drawing.Graphics g = System.Drawing.Graphics.FromImage(temp);
            g.DrawImage(b, r, 0, 0, w, h, System.Drawing.GraphicsUnit.Pixel);
            g.Dispose(); b = temp;
        }
        System.Drawing.Imaging.BitmapData bdat = b.LockBits(r, System.Drawing.Imaging.ImageLockMode.ReadOnly, b.PixelFormat);
        System.Drawing.Bitmap b0 = new System.Drawing.Bitmap(w, h, System.Drawing.Imaging.PixelFormat.Format1bppIndexed);
        System.Drawing.Imaging.BitmapData b0dat = b0.LockBits(r, System.Drawing.Imaging.ImageLockMode.ReadWrite, System.Drawing.Imaging.PixelFormat.Format1bppIndexed);
        for (int y = 0; y < h; y++)
        {
            for (int x = 0; x < w; x++)
            {
                int index = y * bdat.Stride + (x * 4);
                if (System.Drawing.Color.FromArgb(System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index + 2), System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index + 1), System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index)).GetBrightness() > 0.5f)
                {
                    int index0 = y * b0dat.Stride + (x >> 3);
                    byte p = System.Runtime.InteropServices.Marshal.ReadByte(b0dat.Scan0, index0);
                    byte mask = (byte)(0x80 >> (x & 0x7));
                    System.Runtime.InteropServices.Marshal.WriteByte(b0dat.Scan0, index0, (byte)(p | mask));
                }
            }
        }
        b0.UnlockBits(b0dat);
        b.UnlockBits(bdat);
        return b0;
    }

}
	using System;
	class klGDIBitmapConversion
	{
	public static System.Drawing.Bitmap MainConv(System.Drawing.Bitmap img)
	{
	System.Drawing.Bitmap b = img;// new System.Drawing.Bitmap("test.jpg");
	SplashImage(b, 0, 0);
	DateTime dtFaq = DateTime.Now;
	System.Drawing.Bitmap b0 = CopyToBpp(b, 8);
	TimeSpan tsFaq = DateTime.Now - dtFaq;
	return b0;
	}

	// Fast copy a bitmap into a 1bpp/8bpp bitmap of the same dimensions
	static System.Drawing.Bitmap CopyToBpp(System.Drawing.Bitmap b, int bpp)
	{
	if (bpp != 1 && bpp != 8) throw new System.ArgumentException("1 or 8", "bpp");

	// Plan: built into Windows GDI is the ability to convert
	// bitmaps from one format to another. Most of the time, this
	// job is actually done by the graphics hardware accelerator card
	// and so is extremely fast. The rest of the time, the job is done by
	// very fast native code.
	// We will call into this GDI functionality from C#. Our plan:
	// (1) Convert our Bitmap into a GDI hbitmap (ie. copy unmanaged->managed)
	// (2) Create a GDI monochrome hbitmap
	// (3) Use GDI "BitBlt" function to copy from hbitmap into monochrome (as above)
	// (4) Convert the monochrone hbitmap into a Bitmap (ie. copy unmanaged->managed)

	int w = b.Width, h = b.Height;
	IntPtr hbm = b.GetHbitmap(); // this is step (1)
	//
	// Step (2): create the monochrome bitmap.
	// "BITMAPINFO" is an interop-struct which we define below.
	// In GDI terms, it's a BITMAPHEADERINFO followed by an array of two RGBQUADs
	BITMAPINFO bmi = new BITMAPINFO();
	bmi.biSize = 40; // the size of the BITMAPHEADERINFO struct
	bmi.biWidth = w;
	bmi.biHeight = h;
	bmi.biPlanes = 1; // "planes" are confusing. We always use just 1. Read MSDN for more info.
	bmi.biBitCount = (short)bpp; // ie. 1bpp or 8bpp
	bmi.biCompression = BI_RGB; // ie. the pixels in our RGBQUAD table are stored as RGBs, not palette indexes
	bmi.biSizeImage = (uint)(((w + 7) & 0xFFFFFFF8) * h / 8);
	bmi.biXPelsPerMeter = 1000000; // not really important
	bmi.biYPelsPerMeter = 1000000; // not really important
	// Now for the colour table.
	uint ncols = (uint)1 << bpp; // 2 colours for 1bpp; 256 colours for 8bpp
	bmi.biClrUsed = ncols;
	bmi.biClrImportant = ncols;
	bmi.cols = new uint[256]; // The structure always has fixed size 256, even if we end up using fewer colours
	if (bpp == 1) { bmi.cols[0] = MAKERGB(0, 0, 0); bmi.cols[1] = MAKERGB(255, 255, 255); }
	else { for (int i = 0; i < ncols; i++) bmi.cols[i] = MAKERGB(i, i, i); }
	// For 8bpp we've created an palette with just greyscale colours.
	// You can set up any palette you want here. Here are some possibilities:
	// greyscale: for (int i=0; i<256; i++) bmi.cols[i]=MAKERGB(i,i,i);
	// rainbow: bmi.biClrUsed=216; bmi.biClrImportant=216; int[] colv=new int[6]{0,51,102,153,204,255};
	// for (int i=0; i<216; i++) bmi.cols[i]=MAKERGB(colv[i/36],colv[(i/6)%6],colv[i%6]);
	//
	// Now create the indexed bitmap "hbm0"
	IntPtr bits0; // not used for our purposes. It returns a pointer to the raw bits that make up the bitmap.
	IntPtr hbm0 = CreateDIBSection(IntPtr.Zero, ref bmi, DIB_RGB_COLORS, out bits0, IntPtr.Zero, 0);
	//
	// Step (3): use GDI's BitBlt function to copy from original hbitmap into monocrhome bitmap
	// GDI programming is kind of confusing... nb. The GDI equivalent of "Graphics" is called a "DC".
	IntPtr sdc = GetDC(IntPtr.Zero); // First we obtain the DC for the screen
	// Next, create a DC for the original hbitmap
	IntPtr hdc = CreateCompatibleDC(sdc); SelectObject(hdc, hbm);
	// and create a DC for the monochrome hbitmap
	IntPtr hdc0 = CreateCompatibleDC(sdc); SelectObject(hdc0, hbm0);
	// Now we can do the BitBlt:
	BitBlt(hdc0, 0, 0, w, h, hdc, 0, 0, SRCCOPY);
	// Step (4): convert this monochrome hbitmap back into a Bitmap:
	System.Drawing.Bitmap b0 = System.Drawing.Bitmap.FromHbitmap(hbm0);
	//
	// Finally some cleanup.
	DeleteDC(hdc);
	DeleteDC(hdc0);
	ReleaseDC(IntPtr.Zero, sdc);
	DeleteObject(hbm);
	DeleteObject(hbm0);
	//
	return b0;
	}

	// Draws a bitmap onto the screen. Note: this will be overpainted
	// by other windows when they come to draw themselves. Only use it
	// if you want to draw something quickly and can't be bothered with forms.
	static void SplashImage(System.Drawing.Bitmap b, int x, int y)
	{ // Drawing onto the screen is supported by GDI, but not by the Bitmap/Graphics class.
	// So we use interop:
	// (1) Copy the Bitmap into a GDI hbitmap
	IntPtr hbm = b.GetHbitmap();
	// (2) obtain the GDI equivalent of a "Graphics" for the screen
	IntPtr sdc = GetDC(IntPtr.Zero);
	// (3) obtain the GDI equivalent of a "Graphics" for the hbitmap
	IntPtr hdc = CreateCompatibleDC(sdc);
	SelectObject(hdc, hbm);
	// (4) Draw from the hbitmap's "Graphics" onto the screen's "Graphics"
	BitBlt(sdc, x, y, b.Width, b.Height, hdc, 0, 0, SRCCOPY);
	// and do boring GDI cleanup:
	DeleteDC(hdc);
	ReleaseDC(IntPtr.Zero, sdc);
	DeleteObject(hbm);
	}


	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	public static extern bool DeleteObject(IntPtr hObject);

	[System.Runtime.InteropServices.DllImport("user32.dll")]
	public static extern int InvalidateRect(IntPtr hwnd, IntPtr rect, int bErase);

	[System.Runtime.InteropServices.DllImport("user32.dll")]
	public static extern IntPtr GetDC(IntPtr hwnd);

	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	public static extern IntPtr CreateCompatibleDC(IntPtr hdc);

	[System.Runtime.InteropServices.DllImport("user32.dll")]
	public static extern int ReleaseDC(IntPtr hwnd, IntPtr hdc);

	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	public static extern int DeleteDC(IntPtr hdc);

	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	public static extern IntPtr SelectObject(IntPtr hdc, IntPtr hgdiobj);

	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	public static extern int BitBlt(IntPtr hdcDst, int xDst, int yDst, int w, int h, IntPtr hdcSrc, int xSrc, int ySrc, int rop);
	static int SRCCOPY = 0x00CC0020;

	//Specifies the raster operation to be performed.
	//Raster-operation codes define how the GDI combines colors in output operations that involve a current brush, a possible source bitmap, and a destination bitmap.
	//See BitBlt in the Platform SDK for a list of the raster-operation codes for dwRop and their descriptions
	//dwRop

	[System.Runtime.InteropServices.DllImport("gdi32.dll")]
	static extern IntPtr CreateDIBSection(IntPtr hdc, ref BITMAPINFO bmi, uint Usage, out IntPtr bits, IntPtr hSection, uint dwOffset);
	static uint BI_RGB = 0;
	static uint DIB_RGB_COLORS = 0;
	[System.Runtime.InteropServices.StructLayout(System.Runtime.InteropServices.LayoutKind.Sequential)]
	public struct BITMAPINFO
	{
	public uint biSize;
	public int biWidth, biHeight;
	public short biPlanes, biBitCount;
	public uint biCompression, biSizeImage;
	public int biXPelsPerMeter, biYPelsPerMeter;
	public uint biClrUsed, biClrImportant;
	[System.Runtime.InteropServices.MarshalAs(System.Runtime.InteropServices.UnmanagedType.ByValArray, SizeConst = 256)]
	public uint[] cols;
	}

	static uint MAKERGB(int r, int g, int b)
	{
	return ((uint)(b & 255)) \| ((uint)((r & 255) << 8)) \| ((uint)((g & 255) << 16));
	}

	static System.Drawing.Bitmap CopyTo1bpp(System.Drawing.Bitmap b)
	{
	int w = b.Width, h = b.Height; System.Drawing.Rectangle r = new System.Drawing.Rectangle(0, 0, w, h);
	if (b.PixelFormat != System.Drawing.Imaging.PixelFormat.Format32bppPArgb)
	{
	System.Drawing.Bitmap temp = new System.Drawing.Bitmap(w, h, System.Drawing.Imaging.PixelFormat.Format32bppPArgb);
	System.Drawing.Graphics g = System.Drawing.Graphics.FromImage(temp);
	g.DrawImage(b, r, 0, 0, w, h, System.Drawing.GraphicsUnit.Pixel);
	g.Dispose(); b = temp;
	}
	System.Drawing.Imaging.BitmapData bdat = b.LockBits(r, System.Drawing.Imaging.ImageLockMode.ReadOnly, b.PixelFormat);
	System.Drawing.Bitmap b0 = new System.Drawing.Bitmap(w, h, System.Drawing.Imaging.PixelFormat.Format1bppIndexed);
	System.Drawing.Imaging.BitmapData b0dat = b0.LockBits(r, System.Drawing.Imaging.ImageLockMode.ReadWrite, System.Drawing.Imaging.PixelFormat.Format1bppIndexed);
	for (int y = 0; y < h; y++)
	{
	for (int x = 0; x < w; x++)
	{
	int index = y * bdat.Stride + (x * 4);
	if (System.Drawing.Color.FromArgb(System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index + 2), System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index + 1), System.Runtime.InteropServices.Marshal.ReadByte(bdat.Scan0, index)).GetBrightness() > 0.5f)
	{
	int index0 = y * b0dat.Stride + (x >> 3);
	byte p = System.Runtime.InteropServices.Marshal.ReadByte(b0dat.Scan0, index0);
	byte mask = (byte)(0x80 >> (x & 0x7));
	System.Runtime.InteropServices.Marshal.WriteByte(b0dat.Scan0, index0, (byte)(p \| mask));
	}
	}
	}
	b0.UnlockBits(b0dat);
	b.UnlockBits(bdat);
	return b0;
	}

	}