public void TestMarkerList()
{
jpeg_decompress_struct cinfo = new jpeg_decompress_struct();
using (FileStream input = new FileStream(Tester.MapOpenPath("PARROTS.JPG"), FileMode.Open))
{
/* Specify data source for decompression */
cinfo.jpeg_stdio_src(input);
const int markerDataLengthLimit = 1000;
cinfo.jpeg_save_markers((int)JPEG_MARKER.COM, markerDataLengthLimit);
cinfo.jpeg_save_markers((int)JPEG_MARKER.APP0, markerDataLengthLimit);
/* Read file header, set default decompression parameters */
cinfo.jpeg_read_header(true);
Assert.AreEqual(cinfo.Marker_list.Count, 3);
int[] expectedMarkerType = { (int)JPEG_MARKER.APP0, (int)JPEG_MARKER.APP0, (int)JPEG_MARKER.COM };
int[] expectedMarkerOriginalLength = { 14, 3072, 10 };
for (int i = 0; i < cinfo.Marker_list.Count; ++i)
{
jpeg_marker_struct marker = cinfo.Marker_list[i];
Assert.IsNotNull(marker);
Assert.AreEqual(marker.Marker, expectedMarkerType[i]);
Assert.AreEqual(marker.OriginalLength, expectedMarkerOriginalLength[i]);
Assert.LessOrEqual(marker.Data.Length, markerDataLengthLimit);
}
}
}
// the algorithm flow is based on:
// https://bitmiracle.github.io/libjpeg.net/help/articles/KB/decompression-details.html
private DecompressionResult DecompressJpgToRaw(byte[] image)
{
var cinfo = new jpeg_decompress_struct(new jpeg_error_mgr());
using (var memoryStream = new MemoryStream(image))
{
cinfo.jpeg_stdio_src(memoryStream);
cinfo.jpeg_read_header(true);
cinfo.Out_color_space = J_COLOR_SPACE.JCS_RGB;
cinfo.jpeg_start_decompress();
// there are 3 components: R, G, B
var rowStride = 3 * cinfo.Output_width;
var result = new byte[rowStride * cinfo.Output_height];
var resultOffset = 0;
var buffer = new byte[1][];
buffer[0] = new byte[rowStride];
while (cinfo.Output_scanline < cinfo.Output_height)
{
var ct = cinfo.jpeg_read_scanlines(buffer, 1);
if (ct > 0)
{
Array.Copy(buffer[0], 0, result, resultOffset, buffer[0].Length);
resultOffset += buffer[0].Length;
}
}
cinfo.jpeg_finish_decompress();
return(new DecompressionResult(result, cinfo.Output_width, cinfo.Output_height));
}
}
private void Enc(string inputPath, string outputPath, byte[] data)
{
var input = new jpeg_decompress_struct();
using (var fileStream = new FileStream(inputPath, FileMode.Open))
{
input.jpeg_stdio_src(fileStream);
input.jpeg_read_header(false);
var coefficients = input.jpeg_read_coefficients();
var channels = coefficients.Take(3).Select(JpegHelper.GetBuffer).ToArray();
Encrypt(channels, data);
var output = new jpeg_compress_struct();
using (var outfile = new FileStream(outputPath, FileMode.Create))
{
output.jpeg_stdio_dest(outfile);
input.jpeg_copy_critical_parameters(output);
output.jpeg_write_coefficients(coefficients);
output.jpeg_finish_compress();
}
}
}
/// <summary>
/// The DCT coefficients are returned in a structure where the different components are separated in 2D arrays od shorts[][].
/// The first dimension of the array contains the Blocks and the second dimension the 64 values for that block.
/// </summary>
/// <returns></returns>
public static DCTCoefficients GetDctCoefficients(string JpegFilePath)
{
jpeg_decompress_struct jpds = new jpeg_decompress_struct();
FileStream fileStreamImg = new FileStream(JpegFilePath, FileMode.Open, FileAccess.Read);
jpds.jpeg_stdio_src(fileStreamImg);
jpds.jpeg_read_header(true);
// DCT coefficients
var jBlock = jpds.jpeg_read_coefficients();
// Initialize the list for all the dct
var dctFull = new List <short>();
var dctFullDc = new List <short>();
var dctFullAc = new List <short>();
// Get coeffs and fill the list _dctFull
List <short[]> dctCr = readDctCoeffs(EnumStegoChannel.Cr, jBlock, dctFull, dctFullDc, dctFullAc);
List <short[]> dctCb = readDctCoeffs(EnumStegoChannel.Cb, jBlock, dctFull, dctFullDc, dctFullAc);
List <short[]> dctY = readDctCoeffs(EnumStegoChannel.Y, jBlock, dctFull, dctFullDc, dctFullAc);
// Close decompress and filestream
jpds.jpeg_finish_decompress();
fileStreamImg.Close();
// Return DCT coefficients
DCTCoefficients dctCoeffs = new DCTCoefficients
{
DctY = dctY.ToArray(),
DctCb = dctCb.ToArray(),
DctCr = dctCr.ToArray(),
DctFull = dctFull.ToArray(),
DctFullDc = dctFullDc.ToArray(),
DctFullAc = dctFullAc.ToArray()
};
return(dctCoeffs);
}
/// <summary>
/// Tunes decompressor
/// </summary>
/// <param name="jpeg">Stream with input compressed JPEG data</param>
private void beforeDecompress(Stream jpeg)
{
m_decompressor.jpeg_stdio_src(jpeg);
/* Read file header, set default decompression parameters */
m_decompressor.jpeg_read_header(true);
applyParameters(m_decompressionParameters);
m_decompressor.jpeg_calc_output_dimensions();
}
private byte[] Dec(string inputPath, int len)
{
var input = new jpeg_decompress_struct();
input.jpeg_stdio_src(new FileStream(inputPath, FileMode.Open));
input.jpeg_read_header(false);
var coefficients = input.jpeg_read_coefficients();
var channels = coefficients.Take(3).Select(JpegHelper.GetBuffer).ToArray();
return(Decrypt(channels, len));
}
public byte[] DecodeJpeg(string inputPath, int len)
{
var input = new jpeg_decompress_struct();
using (var fs = new FileStream(inputPath, FileMode.Open))
{
input.jpeg_stdio_src(fs);
input.jpeg_read_header(false);
var coefficients = input.jpeg_read_coefficients();
var channels = coefficients.Take(3).Select(JpegHelper.GetBuffer).ToArray();
input.jpeg_finish_decompress();
return(DecodeBlocks(channels, len));
}
}
public static void ApplyQuantizationTable(string JpegFilePath, EnumStegoChannel Component = EnumStegoChannel.Y, int ScaleFactor = 50, int[] QuantizationTable = null)
{
var jpds = new jpeg_decompress_struct();
FileStream fileStreamImg = new FileStream(JpegFilePath, FileMode.Open, FileAccess.Read);
jpds.jpeg_stdio_src(fileStreamImg);
jpds.jpeg_read_header(true);
// DCT coefficients
var jBlock = jpds.jpeg_read_coefficients();
jpds.jpeg_finish_decompress();
fileStreamImg.Close();
if (null == QuantizationTable)
{
switch (Component)
{
case EnumStegoChannel.Y:
QuantizationTable = _qLuminance;
break;
case EnumStegoChannel.Cb:
case EnumStegoChannel.Cr:
QuantizationTable = _qChromiance;
break;
}
}
// Get fle info
FileInfo fInfo = new FileInfo(JpegFilePath);
string dir = fInfo.DirectoryName;
string fNane = fInfo.Name;
string stegFName = $"steg_{DateTime.Now.ToString("yyyyMMddHHmm")}_{fNane}";
string stegJpegFilePath = Path.Combine(dir, stegFName);
// Compress process
FileStream fileStream = File.Create(stegJpegFilePath);
jpeg_compress_struct jpcs = new jpeg_compress_struct();
jpcs.jpeg_stdio_dest(fileStream);
jpds.jpeg_copy_critical_parameters(jpcs);
jpcs.jpeg_write_coefficients(jBlock);
jpcs.jpeg_finish_compress();
fileStream.Close();
jpds.jpeg_abort_decompress();
}
private static void decompress(Stream input, DecompressOptions options, Stream output)
{
Debug.Assert(input != null);
Debug.Assert(options != null);
Debug.Assert(output != null);
/* Initialize the JPEG decompression object with default error handling. */
jpeg_decompress_struct cinfo = new jpeg_decompress_struct(new cd_jpeg_error_mgr());
/* Insert custom marker processor for COM and APP12.
* APP12 is used by some digital camera makers for textual info,
* so we provide the ability to display it as text.
* If you like, additional APPn marker types can be selected for display,
* but don't try to override APP0 or APP14 this way (see libjpeg.doc).
*/
cinfo.jpeg_set_marker_processor((int)JPEG_MARKER.COM, new jpeg_decompress_struct.jpeg_marker_parser_method(printTextMarker));
cinfo.jpeg_set_marker_processor((int)JPEG_MARKER.APP0 + 12, printTextMarker);
/* Specify data source for decompression */
cinfo.jpeg_stdio_src(input);
/* Read file header, set default decompression parameters */
cinfo.jpeg_read_header(true);
applyOptions(cinfo, options);
/* Initialize the output module now to let it override any crucial
* option settings (for instance, GIF wants to force color quantization).
*/
djpeg_dest_struct dest_mgr = null;
switch (options.OutputFormat)
{
case IMAGE_FORMATS.FMT_BMP:
dest_mgr = new bmp_dest_struct(cinfo, false);
break;
case IMAGE_FORMATS.FMT_OS2:
dest_mgr = new bmp_dest_struct(cinfo, true);
break;
default:
cinfo.ERREXIT((int)ADDON_MESSAGE_CODE.JERR_UNSUPPORTED_FORMAT);
break;
}
dest_mgr.output_file = output;
/* Start decompressor */
cinfo.jpeg_start_decompress();
/* Write output file header */
dest_mgr.start_output();
/* Process data */
while (cinfo.Output_scanline < cinfo.Output_height)
{
int num_scanlines = cinfo.jpeg_read_scanlines(dest_mgr.buffer, dest_mgr.buffer_height);
dest_mgr.put_pixel_rows(num_scanlines);
}
/* Finish decompression and release memory.
* I must do it in this order because output module has allocated memory
* of lifespan JPOOL_IMAGE; it needs to finish before releasing memory.
*/
dest_mgr.finish_output();
cinfo.jpeg_finish_decompress();
/* All done. */
if (cinfo.Err.Num_warnings != 0)
{
Console.WriteLine("Corrupt-data warning count is not zero");
}
}
static string outfilename; /* for -outfile switch */
public static void Main(string[] args)
{
progname = Path.GetFileName(Environment.GetCommandLineArgs()[0]);
/* Initialize the JPEG decompression object with default error handling. */
cd_jpeg_error_mgr err = new cd_jpeg_error_mgr();
jpeg_decompress_struct cinfo = new jpeg_decompress_struct(err);
/* Insert custom marker processor for COM and APP12.
* APP12 is used by some digital camera makers for textual info,
* so we provide the ability to display it as text.
* If you like, additional APPn marker types can be selected for display,
* but don't try to override APP0 or APP14 this way (see libjpeg.doc).
*/
cinfo.jpeg_set_marker_processor((int)JPEG_MARKER.COM, new jpeg_decompress_struct.jpeg_marker_parser_method(print_text_marker));
cinfo.jpeg_set_marker_processor((int)JPEG_MARKER.APP0 + 12, print_text_marker);
/* Scan command line to find file names. */
/* It is convenient to use just one switch-parsing routine, but the switch
* values read here are ignored; we will rescan the switches after opening
* the input file.
* (Exception: tracing level set here controls verbosity for COM markers
* found during jpeg_read_header...)
*/
int file_index;
if (!parse_switches(cinfo, args, false, out file_index))
{
usage();
return;
}
/* Must have either -outfile switch or explicit output file name */
if (outfilename == null)
{
// file_index should point to input file
if (file_index != args.Length - 2)
{
Console.WriteLine(string.Format("{0}: must name one input and one output file.", progname));
usage();
return;
}
// output file comes right after input one
outfilename = args[file_index + 1];
}
else
{
// file_index should point to input file
if (file_index != args.Length - 1)
{
Console.WriteLine(string.Format("{0}: must name one input and one output file.", progname));
usage();
return;
}
}
/* Open the input file. */
FileStream input_file = null;
if (file_index < args.Length)
{
try
{
input_file = new FileStream(args[file_index], FileMode.Open);
}
catch (Exception e)
{
Console.WriteLine(string.Format("{0}: can't open {1}", progname, args[file_index]));
Console.WriteLine(e.Message);
return;
}
}
else
{
Console.WriteLine(string.Format("{0}: sorry, can't read file from console"));
return;
}
/* Open the output file. */
FileStream output_file = null;
if (outfilename != null)
{
try
{
output_file = new FileStream(outfilename, FileMode.Create);
}
catch (Exception e)
{
Console.WriteLine(string.Format("{0}: can't open {1}", progname, args[file_index]));
Console.WriteLine(e.Message);
return;
}
}
else
{
Console.WriteLine(string.Format("{0}: sorry, can't write file to console"));
return;
}
/* Specify data source for decompression */
cinfo.jpeg_stdio_src(input_file);
/* Read file header, set default decompression parameters */
cinfo.jpeg_read_header(true);
/* Adjust default decompression parameters by re-parsing the options */
parse_switches(cinfo, args, true, out file_index);
/* Initialize the output module now to let it override any crucial
* option settings (for instance, GIF wants to force color quantization).
*/
djpeg_dest_struct dest_mgr = null;
switch (requested_fmt)
{
case IMAGE_FORMATS.FMT_BMP:
dest_mgr = new bmp_dest_struct(cinfo, false);
break;
case IMAGE_FORMATS.FMT_OS2:
dest_mgr = new bmp_dest_struct(cinfo, true);
break;
default:
cinfo.ERREXIT((int)ADDON_MESSAGE_CODE.JERR_UNSUPPORTED_FORMAT);
break;
}
dest_mgr.output_file = output_file;
/* Start decompressor */
cinfo.jpeg_start_decompress();
/* Write output file header */
dest_mgr.start_output();
/* Process data */
while (cinfo.Output_scanline < cinfo.Output_height)
{
int num_scanlines = cinfo.jpeg_read_scanlines(dest_mgr.buffer, dest_mgr.buffer_height);
dest_mgr.put_pixel_rows(num_scanlines);
}
/* Finish decompression and release memory.
* I must do it in this order because output module has allocated memory
* of lifespan JPOOL_IMAGE; it needs to finish before releasing memory.
*/
dest_mgr.finish_output();
cinfo.jpeg_finish_decompress();
/* Close files, if we opened them */
input_file.Close();
input_file.Dispose();
output_file.Close();
output_file.Dispose();
/* All done. */
if (cinfo.Err.Num_warnings != 0)
{
Console.WriteLine("Corrupt-data warning count is not zero");
}
}
/// <summary>
/// For bits 0-63 only the LSB of DCT coefficients is written (it takes the full length of the bits to read). From bit 64 every DCT coefficient is written with the last 2 LSBs.
/// </summary>
/// <param name="jpegFilePath"></param>
/// <param name="bits"></param>
/// <param name="securityLevel"></param>
private static void changeDctCoefficients(string jpegFilePath, BitArray bits, int securityLevel)
{
var jpds = new jpeg_decompress_struct();
FileStream fileStreamImg = new FileStream(jpegFilePath, FileMode.Open, FileAccess.Read);
jpds.jpeg_stdio_src(fileStreamImg);
jpds.jpeg_read_header(true);
// DCT coefficients
var jBlock = jpds.jpeg_read_coefficients();
var bitsLen = bits.Length;
int currentBit = 0;
bool canIterate = true;
int cntAcCoeffNotZero = 0;
// Write on position 0 then 1
// Start with Cr component
int component = (int)EnumStegoChannel.Cr;
while ((component >= 0) && canIterate)
{
int z = 0;
while (canIterate)
{
int countCrRows;
try
{
countCrRows = jBlock[component].Access(z, 1)[0].Length;
}
catch
{
break;
}
int i = 0;
while ((i < countCrRows) && canIterate)
{
// Skip DC coefficients j = 0
int j = 1;
while ((j < 64) && canIterate)
{
short currentVal = jBlock[component].Access(z, 1)[0][i][j];
// Skip bits 0 and dct according to the security level (steps)
if (0 != currentVal) // Set only 1 bit for the first 64 AC coefficients
{
// Define the step of bits to write after 64 bits
if ((0 == cntAcCoeffNotZero % securityLevel) || (currentBit < 64))
{
// Get the current bit
bool bit = bits[currentBit];
// Write the new value in position 0
short newVal = getNewValForComponent(currentVal, bit, 0);
jBlock[component].Access(z, 1)[0][i][j] = newVal;
currentBit++;
canIterate = currentBit < bitsLen;
// Start writing on bit 1 after 64 bits to encode the content length
if (canIterate && currentBit > 64)
{
// Get the current bit
bit = bits[currentBit];
// Write the new value in position 1
newVal = getNewValForComponent(newVal, bit, 1);
jBlock[component].Access(z, 1)[0][i][j] = newVal;
currentBit++;
canIterate = currentBit < bitsLen;
}
}
cntAcCoeffNotZero++;
}
j++;
}
i++;
}
z++;
}
component--;
}
jpds.jpeg_finish_decompress();
fileStreamImg.Close();
// Get file info
FileInfo fInfo = new FileInfo(jpegFilePath);
string dir = fInfo.DirectoryName;
string fName = fInfo.Name;
var docPath = Environment.GetFolderPath(Environment.SpecialFolder.MyDocuments);
var stegJpegFilePath = $@"{docPath}\StegImageUI\steg_{DateTime.Now.ToString("yyyyMMddHHmmss")}_{fName}";
// Compress process
FileStream fileStream = File.Create(stegJpegFilePath);
jpeg_compress_struct jpcs = new jpeg_compress_struct();
jpcs.jpeg_stdio_dest(fileStream);
jpds.jpeg_copy_critical_parameters(jpcs);
jpcs.jpeg_write_coefficients(jBlock);
jpcs.jpeg_finish_compress();
fileStream.Close();
jpds.jpeg_abort_decompress();
}