jtheisen/Stegman.cs

## Stegman.cs
using System;
using System.Windows;
using System.Windows.Controls;
using System.Windows.Documents;
using System.Windows.Ink;
using System.Windows.Input;
using System.Windows.Media;
using System.Windows.Media.Animation;
using System.Windows.Shapes;
using System.IO;
using System.Windows.Browser;
using System.Reflection;

namespace Stegman
{
    public class PngEncoder
    {
        private const int _ADLER32_BASE = 65521;
        private const int _MAXBLOCK = 0xFFFF;
        private static byte[] _HEADER = { 0x89, 0x50, 0x4E, 0x47, 0x0D, 0x0A, 0x1A, 0x0A };
        private static byte[] _IHDR = { (byte)'I', (byte)'H', (byte)'D', (byte)'R' };
        private static byte[] _GAMA = { (byte)'g', (byte)'A', (byte)'M', (byte)'A' };
        private static byte[] _IDAT = { (byte)'I', (byte)'D', (byte)'A', (byte)'T' };
        private static byte[] _IEND = { (byte)'I', (byte)'E', (byte)'N', (byte)'D' };
        private static byte[] _4BYTEDATA = { 0, 0, 0, 0 };
        private static byte[] _ARGB = { 0, 0, 0, 0, 0, 0, 0, 0, 8, 6, 0, 0, 0 };

        public static Stream Encode(int[] pixels, int width, int height)
        {
            var data = new byte[height * (width * 4 + 1)];

            int sp = 0;
            int dp = 0;
            for (int y = 0; y < height; ++y, dp += 1)
            {
                data[dp] = 0;
                for (int x = 0; x < width; ++x, dp += 4, sp++)
                {
                    var value = pixels[sp];
                    data[dp + 1] = (byte)(value >> 0);
                    data[dp + 2] = (byte)(value >> 8);
                    data[dp + 3] = (byte)(value >> 16);
                    data[dp + 4] = (byte)(value >> 24);
                }
            }

            return Encode(data, width, height);
        }

        public static Stream Encode(byte[] data, int width, int height)
        {
            MemoryStream ms = new MemoryStream();
            byte[] size;

            // Write PNG header
            ms.Write(_HEADER, 0, _HEADER.Length);

            // Write IHDR
            //  Width:              4 bytes
            //  Height:             4 bytes
            //  Bit depth:          1 byte
            //  Color type:         1 byte
            //  Compression method: 1 byte
            //  Filter method:      1 byte
            //  Interlace method:   1 byte

            size = BitConverter.GetBytes(width);
            _ARGB[0] = size[3]; _ARGB[1] = size[2]; _ARGB[2] = size[1]; _ARGB[3] = size[0];

            size = BitConverter.GetBytes(height);
            _ARGB[4] = size[3]; _ARGB[5] = size[2]; _ARGB[6] = size[1]; _ARGB[7] = size[0];

            // Write IHDR chunk
            WriteChunk(ms, _IHDR, _ARGB);

            // Set gamma = 1
            size = BitConverter.GetBytes(1 * 100000);
            _4BYTEDATA[0] = size[3]; _4BYTEDATA[1] = size[2]; _4BYTEDATA[2] = size[1]; _4BYTEDATA[3] = size[0];

            // Write gAMA chunk
            WriteChunk(ms, _GAMA, _4BYTEDATA);

            // Write IDAT chunk
            uint widthLength = (uint)(width * 4) + 1;
            uint dcSize = widthLength * (uint)height;

            // First part of ZLIB header is 78 1101 1010 (DA) 0000 00001 (01)
            // ZLIB info
            //
            // CMF Byte: 78
            //  CINFO = 7 (32K window size)
            //  CM = 8 = (deflate compression)
            // FLG Byte: DA
            //  FLEVEL = 3 (bits 6 and 7 - ignored but signifies max compression)
            //  FDICT = 0 (bit 5, 0 - no preset dictionary)
            //  FCHCK = 26 (bits 0-4 - ensure CMF*256+FLG / 31 has no remainder)
            // Compressed data
            //  FLAGS: 0 or 1
            //    00000 00 (no compression) X (X=1 for last block, 0=not the last block)
            //    LEN = length in bytes (equal to ((width*4)+1)*height
            //    NLEN = one's compliment of LEN
            //    Example: 1111 1011 1111 1111 (FB), 0000 0100 0000 0000 (40)
            //    Data for each line: 0 [RGBA] [RGBA] [RGBA] ...
            //    ADLER32

            uint adler = ComputeAdler32(data);
            MemoryStream comp = new MemoryStream();

            // Calculate number of 64K blocks
            uint rowsPerBlock = _MAXBLOCK / widthLength;
            uint blockSize = rowsPerBlock * widthLength;
            uint blockCount;
            ushort length;
            uint remainder = dcSize;

            if ((dcSize % blockSize) == 0)
            {
                blockCount = dcSize / blockSize;
            }
            else
            {
                blockCount = (dcSize / blockSize) + 1;
            }

            // Write headers
            comp.WriteByte(0x78);
            comp.WriteByte(0xDA);

            for (uint blocks = 0; blocks < blockCount; blocks++)
            {
                // Write LEN
                length = (ushort)((remainder < blockSize) ? remainder : blockSize);

                if (length == remainder)
                {
                    comp.WriteByte(0x01);
                }
                else
                {
                    comp.WriteByte(0x00);
                }

                comp.Write(BitConverter.GetBytes(length), 0, 2);

                // Write one's compliment of LEN
                comp.Write(BitConverter.GetBytes((ushort)~length), 0, 2);

                // Write blocks
                comp.Write(data, (int)(blocks * blockSize), length);

                // Next block
                remainder -= blockSize;
            }

            WriteReversedBuffer(comp, BitConverter.GetBytes(adler));
            comp.Seek(0, SeekOrigin.Begin);

            byte[] dat = new byte[comp.Length];
            comp.Read(dat, 0, (int)comp.Length);

            WriteChunk(ms, _IDAT, dat);

            // Write IEND chunk
            WriteChunk(ms, _IEND, new byte[0]);

            // Reset stream
            ms.Seek(0, SeekOrigin.Begin);

            return ms;

            // See http://www.libpng.org/pub/png//spec/1.2/PNG-Chunks.html
            // See http://www.libpng.org/pub/png/book/chapter08.html#png.ch08.div.4
            // See http://www.gzip.org/zlib/rfc-zlib.html (ZLIB format)
            // See ftp://ftp.uu.net/pub/archiving/zip/doc/rfc1951.txt (ZLIB compression format)
        }

        private static void WriteReversedBuffer(Stream stream, byte[] data)
        {
            int size = data.Length;
            byte[] reorder = new byte[size];

            for (int idx = 0; idx < size; idx++)
            {
                reorder[idx] = data[size - idx - 1];
            }
            stream.Write(reorder, 0, size);
        }

        private static void WriteChunk(Stream stream, byte[] type, byte[] data)
        {
            int idx;
            int size = type.Length;
            byte[] buffer = new byte[type.Length + data.Length];

            // Initialize buffer
            for (idx = 0; idx < type.Length; idx++)
            {
                buffer[idx] = type[idx];
            }

            for (idx = 0; idx < data.Length; idx++)
            {
                buffer[idx + size] = data[idx];
            }

            // Write length
            WriteReversedBuffer(stream, BitConverter.GetBytes(data.Length));

            // Write type and data
            stream.Write(buffer, 0, buffer.Length);   // Should always be 4 bytes

            // Compute and write the CRC
            WriteReversedBuffer(stream, BitConverter.GetBytes(GetCRC(buffer)));
        }

        private static uint[] _crcTable = new uint[256];
        private static bool _crcTableComputed = false;

        private static void MakeCRCTable()
        {
            uint c;

            for (int n = 0; n < 256; n++)
            {
                c = (uint)n;
                for (int k = 0; k < 8; k++)
                {
                    if ((c & (0x00000001)) > 0)
                        c = 0xEDB88320 ^ (c >> 1);
                    else
                        c = c >> 1;
                }
                _crcTable[n] = c;
            }

            _crcTableComputed = true;
        }

        private static uint UpdateCRC(uint crc, byte[] buf, int len)
        {
            uint c = crc;

            if (!_crcTableComputed)
            {
                MakeCRCTable();
            }

            for (int n = 0; n < len; n++)
            {
                c = _crcTable[(c ^ buf[n]) & 0xFF] ^ (c >> 8);
            }

            return c;
        }

        /* Return the CRC of the bytes buf[0..len-1]. */
        private static uint GetCRC(byte[] buf)
        {
            return UpdateCRC(0xFFFFFFFF, buf, buf.Length) ^ 0xFFFFFFFF;
        }

        private static uint ComputeAdler32(byte[] buf)
        {
            uint s1 = 1;
            uint s2 = 0;
            int length = buf.Length;

            for (int idx = 0; idx < length; idx++)
            {
                s1 = (s1 + (uint)buf[idx]) % _ADLER32_BASE;
                s2 = (s2 + s1) % _ADLER32_BASE;
            }

            return (s2 << 16) + s1;
        }
    }
}
	using System;
	using System.Windows;
	using System.Windows.Controls;
	using System.Windows.Documents;
	using System.Windows.Ink;
	using System.Windows.Input;
	using System.Windows.Media;
	using System.Windows.Media.Animation;
	using System.Windows.Shapes;
	using System.IO;
	using System.Windows.Browser;
	using System.Reflection;

	namespace Stegman
	{
	public class PngEncoder
	{
	private const int _ADLER32_BASE = 65521;
	private const int _MAXBLOCK = 0xFFFF;
	private static byte[] _HEADER = { 0x89, 0x50, 0x4E, 0x47, 0x0D, 0x0A, 0x1A, 0x0A };
	private static byte[] _IHDR = { (byte)'I', (byte)'H', (byte)'D', (byte)'R' };
	private static byte[] _GAMA = { (byte)'g', (byte)'A', (byte)'M', (byte)'A' };
	private static byte[] _IDAT = { (byte)'I', (byte)'D', (byte)'A', (byte)'T' };
	private static byte[] _IEND = { (byte)'I', (byte)'E', (byte)'N', (byte)'D' };
	private static byte[] _4BYTEDATA = { 0, 0, 0, 0 };
	private static byte[] _ARGB = { 0, 0, 0, 0, 0, 0, 0, 0, 8, 6, 0, 0, 0 };

	public static Stream Encode(int[] pixels, int width, int height)
	{
	var data = new byte[height * (width * 4 + 1)];

	int sp = 0;
	int dp = 0;
	for (int y = 0; y < height; ++y, dp += 1)
	{
	data[dp] = 0;
	for (int x = 0; x < width; ++x, dp += 4, sp++)
	{
	var value = pixels[sp];
	data[dp + 1] = (byte)(value >> 0);
	data[dp + 2] = (byte)(value >> 8);
	data[dp + 3] = (byte)(value >> 16);
	data[dp + 4] = (byte)(value >> 24);
	}
	}

	return Encode(data, width, height);
	}

	public static Stream Encode(byte[] data, int width, int height)
	{
	MemoryStream ms = new MemoryStream();
	byte[] size;

	// Write PNG header
	ms.Write(_HEADER, 0, _HEADER.Length);

	// Write IHDR
	// Width: 4 bytes
	// Height: 4 bytes
	// Bit depth: 1 byte
	// Color type: 1 byte
	// Compression method: 1 byte
	// Filter method: 1 byte
	// Interlace method: 1 byte

	size = BitConverter.GetBytes(width);
	_ARGB[0] = size[3]; _ARGB[1] = size[2]; _ARGB[2] = size[1]; _ARGB[3] = size[0];

	size = BitConverter.GetBytes(height);
	_ARGB[4] = size[3]; _ARGB[5] = size[2]; _ARGB[6] = size[1]; _ARGB[7] = size[0];

	// Write IHDR chunk
	WriteChunk(ms, _IHDR, _ARGB);

	// Set gamma = 1
	size = BitConverter.GetBytes(1 * 100000);
	_4BYTEDATA[0] = size[3]; _4BYTEDATA[1] = size[2]; _4BYTEDATA[2] = size[1]; _4BYTEDATA[3] = size[0];

	// Write gAMA chunk
	WriteChunk(ms, _GAMA, _4BYTEDATA);

	// Write IDAT chunk
	uint widthLength = (uint)(width * 4) + 1;
	uint dcSize = widthLength * (uint)height;

	// First part of ZLIB header is 78 1101 1010 (DA) 0000 00001 (01)
	// ZLIB info
	//
	// CMF Byte: 78
	// CINFO = 7 (32K window size)
	// CM = 8 = (deflate compression)
	// FLG Byte: DA
	// FLEVEL = 3 (bits 6 and 7 - ignored but signifies max compression)
	// FDICT = 0 (bit 5, 0 - no preset dictionary)
	// FCHCK = 26 (bits 0-4 - ensure CMF*256+FLG / 31 has no remainder)
	// Compressed data
	// FLAGS: 0 or 1
	// 00000 00 (no compression) X (X=1 for last block, 0=not the last block)
	// LEN = length in bytes (equal to ((width4)+1)height
	// NLEN = one's compliment of LEN
	// Example: 1111 1011 1111 1111 (FB), 0000 0100 0000 0000 (40)
	// Data for each line: 0 [RGBA] [RGBA] [RGBA] ...
	// ADLER32

	uint adler = ComputeAdler32(data);
	MemoryStream comp = new MemoryStream();

	// Calculate number of 64K blocks
	uint rowsPerBlock = _MAXBLOCK / widthLength;
	uint blockSize = rowsPerBlock * widthLength;
	uint blockCount;
	ushort length;
	uint remainder = dcSize;

	if ((dcSize % blockSize) == 0)
	{
	blockCount = dcSize / blockSize;
	}
	else
	{
	blockCount = (dcSize / blockSize) + 1;
	}

	// Write headers
	comp.WriteByte(0x78);
	comp.WriteByte(0xDA);

	for (uint blocks = 0; blocks < blockCount; blocks++)
	{
	// Write LEN
	length = (ushort)((remainder < blockSize) ? remainder : blockSize);

	if (length == remainder)
	{
	comp.WriteByte(0x01);
	}
	else
	{
	comp.WriteByte(0x00);
	}

	comp.Write(BitConverter.GetBytes(length), 0, 2);

	// Write one's compliment of LEN
	comp.Write(BitConverter.GetBytes((ushort)~length), 0, 2);

	// Write blocks
	comp.Write(data, (int)(blocks * blockSize), length);

	// Next block
	remainder -= blockSize;
	}

	WriteReversedBuffer(comp, BitConverter.GetBytes(adler));
	comp.Seek(0, SeekOrigin.Begin);

	byte[] dat = new byte[comp.Length];
	comp.Read(dat, 0, (int)comp.Length);

	WriteChunk(ms, _IDAT, dat);

	// Write IEND chunk
	WriteChunk(ms, _IEND, new byte[0]);

	// Reset stream
	ms.Seek(0, SeekOrigin.Begin);

	return ms;

	// See http://www.libpng.org/pub/png//spec/1.2/PNG-Chunks.html
	// See http://www.libpng.org/pub/png/book/chapter08.html#png.ch08.div.4
	// See http://www.gzip.org/zlib/rfc-zlib.html (ZLIB format)
	// See ftp://ftp.uu.net/pub/archiving/zip/doc/rfc1951.txt (ZLIB compression format)
	}

	private static void WriteReversedBuffer(Stream stream, byte[] data)
	{
	int size = data.Length;
	byte[] reorder = new byte[size];

	for (int idx = 0; idx < size; idx++)
	{
	reorder[idx] = data[size - idx - 1];
	}
	stream.Write(reorder, 0, size);
	}

	private static void WriteChunk(Stream stream, byte[] type, byte[] data)
	{
	int idx;
	int size = type.Length;
	byte[] buffer = new byte[type.Length + data.Length];

	// Initialize buffer
	for (idx = 0; idx < type.Length; idx++)
	{
	buffer[idx] = type[idx];
	}

	for (idx = 0; idx < data.Length; idx++)
	{
	buffer[idx + size] = data[idx];
	}

	// Write length
	WriteReversedBuffer(stream, BitConverter.GetBytes(data.Length));

	// Write type and data
	stream.Write(buffer, 0, buffer.Length); // Should always be 4 bytes

	// Compute and write the CRC
	WriteReversedBuffer(stream, BitConverter.GetBytes(GetCRC(buffer)));
	}

	private static uint[] _crcTable = new uint[256];
	private static bool _crcTableComputed = false;

	private static void MakeCRCTable()
	{
	uint c;

	for (int n = 0; n < 256; n++)
	{
	c = (uint)n;
	for (int k = 0; k < 8; k++)
	{
	if ((c & (0x00000001)) > 0)
	c = 0xEDB88320 ^ (c >> 1);
	else
	c = c >> 1;
	}
	_crcTable[n] = c;
	}

	_crcTableComputed = true;
	}

	private static uint UpdateCRC(uint crc, byte[] buf, int len)
	{
	uint c = crc;

	if (!_crcTableComputed)
	{
	MakeCRCTable();
	}

	for (int n = 0; n < len; n++)
	{
	c = _crcTable[(c ^ buf[n]) & 0xFF] ^ (c >> 8);
	}

	return c;
	}

	/* Return the CRC of the bytes buf[0..len-1]. */
	private static uint GetCRC(byte[] buf)
	{
	return UpdateCRC(0xFFFFFFFF, buf, buf.Length) ^ 0xFFFFFFFF;
	}

	private static uint ComputeAdler32(byte[] buf)
	{
	uint s1 = 1;
	uint s2 = 0;
	int length = buf.Length;

	for (int idx = 0; idx < length; idx++)
	{
	s1 = (s1 + (uint)buf[idx]) % _ADLER32_BASE;
	s2 = (s2 + s1) % _ADLER32_BASE;
	}

	return (s2 << 16) + s1;
	}
	}
	}