/// <summary> Creates a ROIDeScaler object. The information needed to create the
/// object is the Entropy decoder used and the parameters.
///
/// </summary>
/// <param name="src">The source of data that is to be descaled
///
/// </param>
/// <param name="pl">The parameter list (or options).
///
/// </param>
/// <param name="decSpec">The decoding specifications
///
/// </param>
/// <exception cref="IllegalArgumentException">If an error occurs while parsing
/// the options in 'pl'
///
/// </exception>
public static ROIDeScaler createInstance(CBlkQuantDataSrcDec src, ParameterList pl, DecoderSpecs decSpec)
{
System.String noRoi;
//int i;
// Check parameters
pl.checkList(OPT_PREFIX, CSJ2K.j2k.util.ParameterList.toNameArray(pinfo));
// Check if no_roi specified in command line or no roi signalled
// in bit stream
noRoi = pl.getParameter("Rno_roi");
if (noRoi != null || decSpec.rois == null)
{
// no_roi specified in commandline!
return new ROIDeScaler(src, null);
}
return new ROIDeScaler(src, decSpec.rois);
}
/// <summary> Instantiates the 'InvWTAdapter' object using the specified
/// 'MultiResImgData' source. The reconstruction resolution level is set to
/// full resolution (i.e. the maximum resolution level).
///
/// </summary>
/// <param name="src">From where to obtain the values to return
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
protected internal InvWTAdapter(MultiResImgData src, DecoderSpecs decSpec)
{
mressrc = src;
this.decSpec = decSpec;
maxImgRes = decSpec.dls.Min;
}
/// <summary> Constructs a new ForwCompTransf object that operates on the
/// specified source of image data.
///
/// </summary>
/// <param name="imgSrc">The source from where to get the data to be
/// transformed
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
/// <param name="utdepth">The bit depth of the un-transformed components
///
/// </param>
/// <param name="pl">The command line optinons of the decoder
///
/// </param>
/// <seealso cref="BlkImgDataSrc">
///
/// </seealso>
public InvCompTransf(BlkImgDataSrc imgSrc, DecoderSpecs decSpec, int[] utdepth, ParameterList pl):base(imgSrc)
{
this.cts = decSpec.cts;
this.wfs = decSpec.wfs;
src = imgSrc;
this.utdepth = utdepth;
noCompTransf = !(pl.getBooleanParameter("comp_transf"));
}
//private bool[][] reversible;
/// <summary> Initializes this object with the given source of wavelet
/// coefficients. It initializes the resolution level for full resolutioin
/// reconstruction.
///
/// </summary>
/// <param name="src">from where the wavelet coefficinets should be obtained.
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
public InvWTFull(CBlkWTDataSrcDec src, DecoderSpecs decSpec)
: base(src, decSpec)
{
this.src = src;
int nc = src.NumComps;
reconstructedComps = new DataBlk[nc];
ndl = new int[nc];
}
/// <summary> Returns the dequantizer parameters. Dequantizer parameters normally are
/// the quantization step sizes, see DequantizerParams.
///
/// </summary>
/// <param name="src">The source of data for the dequantizer.
///
/// </param>
/// <param name="rb">The number of range bits for each component. Must be
/// the number of range bits of the mixed components.
///
/// </param>
/// <param name="decSpec2">The DecoderSpecs instance after any image manipulation.
///
/// </param>
/// <returns> The dequantizer
///
/// </returns>
public Dequantizer createDequantizer(CBlkQuantDataSrcDec src, int[] rb, DecoderSpecs decSpec2)
{
return new StdDequantizer(src, rb, decSpec2);
}
/// <summary> Reads the SIZ marker segment and realigns the codestream at the point
/// where the next marker segment should be found.
///
/// <p>SIZ is a fixed information marker segment containing informations
/// about image and tile sizes. It is required in the main header
/// immediately after SOC.</p>
///
/// </summary>
/// <param name="ehs">The encoded header stream
///
/// </param>
/// <exception cref="IOException">If an I/O error occurs while reading from the
/// encoded header stream
///
/// </exception>
//UPGRADE_TODO: Class 'java.io.DataInputStream' was converted to 'System.IO.BinaryReader' which has a different behavior. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1073_javaioDataInputStream'"
private void readSIZ(System.IO.BinaryReader ehs)
{
HeaderInfo.SIZ ms = hi.NewSIZ;
hi.sizValue = ms;
// Read the length of SIZ marker segment (Lsiz)
ms.lsiz = ehs.ReadUInt16();
// Read the capability of the codestream (Rsiz)
ms.rsiz = ehs.ReadUInt16();
if (ms.rsiz > 2)
{
throw new System.ApplicationException("Codestream capabiities not JPEG 2000 - Part I" + " compliant");
}
// Read image size
ms.xsiz = ehs.ReadInt32();
ms.ysiz = ehs.ReadInt32();
if (ms.xsiz <= 0 || ms.ysiz <= 0)
{
throw new System.IO.IOException("JJ2000 does not support images whose " + "width and/or height not in the " + "range: 1 -- (2^31)-1");
}
// Read image offset
ms.x0siz = ehs.ReadInt32();
ms.y0siz = ehs.ReadInt32();
if (ms.x0siz < 0 || ms.y0siz < 0)
{
throw new System.IO.IOException("JJ2000 does not support images offset " + "not in the range: 0 -- (2^31)-1");
}
// Read size of tile
ms.xtsiz = ehs.ReadInt32();
ms.ytsiz = ehs.ReadInt32();
if (ms.xtsiz <= 0 || ms.ytsiz <= 0)
{
throw new System.IO.IOException("JJ2000 does not support tiles whose " + "width and/or height are not in " + "the range: 1 -- (2^31)-1");
}
// Read upper-left tile offset
ms.xt0siz = ehs.ReadInt32();
ms.yt0siz = ehs.ReadInt32();
if (ms.xt0siz < 0 || ms.yt0siz < 0)
{
throw new System.IO.IOException("JJ2000 does not support tiles whose " + "offset is not in " + "the range: 0 -- (2^31)-1");
}
// Read number of components and initialize related arrays
nComp = ms.csiz = ehs.ReadUInt16();
if (nComp < 1 || nComp > 16384)
{
throw new System.ArgumentException("Number of component out of " + "range 1--16384: " + nComp);
}
ms.ssiz = new int[nComp];
ms.xrsiz = new int[nComp];
ms.yrsiz = new int[nComp];
// Read bit-depth and down-sampling factors of each component
for (int i = 0; i < nComp; i++)
{
ms.ssiz[i] = ehs.ReadByte();
ms.xrsiz[i] = ehs.ReadByte();
ms.yrsiz[i] = ehs.ReadByte();
}
// Check marker length
checkMarkerLength(ehs, "SIZ marker");
// Create needed ModuleSpec
nTiles = ms.NumTiles;
// Finish initialization of decSpec
decSpec = new DecoderSpecs(nTiles, nComp);
}
/// <summary> Creates an empty PktDecoder object associated with given decoder
/// specifications and HeaderDecoder. This object must be initialized
/// thanks to the restart method before being used.
///
/// </summary>
/// <param name="decSpec">The decoder specifications.
///
/// </param>
/// <param name="hd">The HeaderDecoder instance.
///
/// </param>
/// <param name="ehs">The stream where to read data from.
///
/// </param>
/// <param name="src">The bit stream reader agent.
///
/// </param>
/// <param name="isTruncMode">Whether or not truncation mode is required.
///
/// </param>
/// <param name="maxCB">The maximum number of code-blocks to read before ncbquit
///
///
/// </param>
public PktDecoder(DecoderSpecs decSpec, HeaderDecoder hd, RandomAccessIO ehs, BitstreamReaderAgent src, bool isTruncMode, int maxCB)
{
this.decSpec = decSpec;
this.hd = hd;
this.ehs = ehs;
this.isTruncMode = isTruncMode;
bin = new PktHeaderBitReader(ehs);
this.src = src;
ncb = 0;
ncbQuit = false;
this.maxCB = maxCB;
}
/// <summary> Initializes the source of compressed data. And sets the number of range
/// bits and fraction bits and receives the parameters for the dequantizer.
///
/// </summary>
/// <param name="src">From where to obtain the quantized data.
///
/// </param>
/// <param name="rb">The number of "range bits" (bitdepth) for each component
/// (must be the "range bits" of the un-transformed components). For a
/// definition of "range bits" see the getNomRangeBits() method.
///
/// </param>
/// <param name="qts">The quantizer type spec
///
/// </param>
/// <param name="qsss">The dequantizer step sizes spec
///
/// </param>
/// <seealso cref="Dequantizer.getNomRangeBits">
///
/// </seealso>
/// <exception cref="IllegalArgumentException">Thrown if 'outdt' is neither
/// TYPE_FLOAT nor TYPE_INT, or if 'param' specify reversible quantization
/// and 'outdt' is not TYPE_INT or 'fp' has non-zero values, or if 'outdt'
/// is TYPE_FLOAT and 'fp' has non-zero values.
///
/// </exception>
public StdDequantizer(CBlkQuantDataSrcDec src, int[] utrb, DecoderSpecs decSpec):base(src, utrb, decSpec)
{
if (utrb.Length != src.NumComps)
{
throw new System.ArgumentException("Invalid rb argument");
}
this.qsss = decSpec.qsss;
this.qts = decSpec.qts;
this.gbs = decSpec.gbs;
}
/// <summary> Initializes members of this class. This constructor takes a
/// HeaderDecoder object. This object must be initialized by the
/// constructor of the implementing class from the header of the bit
/// stream.
///
/// </summary>
/// <param name="hd">The decoded header of the bit stream from where to initialize
/// the values.
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
protected internal BitstreamReaderAgent(HeaderDecoder hd, DecoderSpecs decSpec)
{
Coord co;
//int i, j, max;
this.decSpec = decSpec;
this.hd = hd;
// Number of components
nc = hd.NumComps;
offX = new int[nc];
offY = new int[nc];
culx = new int[nc];
culy = new int[nc];
// Image size and origin
imgW = hd.ImgWidth;
imgH = hd.ImgHeight;
ax = hd.ImgULX;
ay = hd.ImgULY;
// Tiles
co = hd.getTilingOrigin(null);
px = co.x;
py = co.y;
ntW = hd.NomTileWidth;
ntH = hd.NomTileHeight;
ntX = (ax + imgW - px + ntW - 1) / ntW;
ntY = (ay + imgH - py + ntH - 1) / ntH;
nt = ntX * ntY;
}
/// <summary> Instantiates a new entropy decoder engine, with the specified source of
/// data, nominal block width and height.
///
/// </summary>
/// <param name="src">The source of data
///
/// </param>
/// <param name="opt">The options to use for this encoder. It is a mix of the
/// 'OPT_TERM_PASS', 'OPT_RESET_MQ', 'OPT_VERT_STR_CAUSAL', 'OPT_BYPASS'
/// and 'OPT_SEG_SYMBOLS' option flags.
///
/// </param>
/// <param name="doer">If true error detection will be performed, if any error
/// detection features have been enabled.
///
/// </param>
/// <param name="verber">This flag indicates if the entropy decoder should be
/// verbose about bit stream errors that are detected and concealed.
///
/// </param>
/// <param name="mQuit">the maximum number of bit planes to decode according to
/// the m quit condition
///
/// </param>
public StdEntropyDecoder(CodedCBlkDataSrcDec src, DecoderSpecs decSpec, bool doer, bool verber, int mQuit):base(src)
{
this.decSpec = decSpec;
this.doer = doer;
this.verber = verber;
this.mQuit = mQuit;
// If we do timing create necessary structures
#if DO_TIMING
time = new long[src.NumComps];
// If we are timing make sure that 'finalize' gets called.
//UPGRADE_ISSUE: Method 'java.lang.System.runFinalizersOnExit' was not converted. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1000_javalangSystem'"
// CONVERSION PROBLEM?
//System_Renamed.runFinalizersOnExit(true);
#endif
// Initialize internal variables
state = new int[(decSpec.cblks.MaxCBlkWidth + 2) * ((decSpec.cblks.MaxCBlkHeight + 1) / 2 + 2)];
}
/// <summary> Creates a bit stream reader of the correct type that works on the
/// provided RandomAccessIO, with the special parameters from the parameter
/// list.
///
/// </summary>
/// <param name="in">The RandomAccessIO source from which to read the bit stream.
///
/// </param>
/// <param name="hd">Header of the codestream.
///
/// </param>
/// <param name="pl">The parameter list containing parameters applicable to the
/// bit stream read (other parameters may also be present).
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
/// <param name="cdstrInfo">Whether or not to print information found in
/// codestream.
///
/// </param>
/// <param name="hi">Reference to the HeaderInfo instance.
///
/// </param>
/// <exception cref="IOException">If an I/O error occurs while reading initial
/// data from the bit stream.
/// </exception>
/// <exception cref="IllegalArgumentException">If an unrecognised bit stream
/// reader option is present.
///
/// </exception>
public static BitstreamReaderAgent createInstance(RandomAccessIO in_Renamed, HeaderDecoder hd, ParameterList pl, DecoderSpecs decSpec, bool cdstrInfo, HeaderInfo hi)
{
// Check parameters
pl.checkList(BitstreamReaderAgent.OPT_PREFIX, CSJ2K.j2k.util.ParameterList.toNameArray(BitstreamReaderAgent.ParameterInfo));
return new FileBitstreamReaderAgent(hd, in_Renamed, decSpec, pl, cdstrInfo, hi);
}
/// <summary> Initializes this object with the given source of wavelet
/// coefficients. It initializes the resolution level for full resolutioin
/// reconstruction (i.e. the maximum resolution available from the 'src'
/// source).
///
/// <p>It is assumed here that all tiles and components have the same
/// reconstruction resolution level. If that was not the case it should be
/// the value for the current tile of the source.</p>
///
/// </summary>
/// <param name="src">from where the wavelet coefficinets should be obtained.
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
public InverseWT(MultiResImgData src, DecoderSpecs decSpec)
: base(src, decSpec)
{
}
/// <summary> Creates an InverseWT object that works on the data type of the source,
/// with the special additional parameters from the parameter
/// list. Currently the parameter list is ignored since no special
/// parameters can be specified for the inverse wavelet transform yet.
///
/// </summary>
/// <param name="src">The source of data for the inverse wavelet
/// transform.
///
/// </param>
/// <param name="pl">The parameter list containing parameters applicable to the
/// inverse wavelet transform (other parameters can also be present).
///
/// </param>
public static InverseWT createInstance(CBlkWTDataSrcDec src, DecoderSpecs decSpec)
{
// full page wavelet transform
return new InvWTFull(src, decSpec);
}
/// <summary> Initializes the source of compressed data.
///
/// </summary>
/// <param name="src">From where to obtain the quantized data.
///
/// </param>
/// <param name="rb">The number of "range bits" for each component (must be the
/// "range bits" of the un-transformed components. For a definition of
/// "range bits" see the getNomRangeBits() method.
///
/// </param>
/// <seealso cref="getNomRangeBits">
///
/// </seealso>
public Dequantizer(CBlkQuantDataSrcDec src, int[] utrb, DecoderSpecs decSpec):base(src)
{
if (utrb.Length != src.NumComps)
{
throw new System.ArgumentException();
}
this.src = src;
this.utrb = utrb;
this.cts = decSpec.cts;
this.wfs = decSpec.wfs;
}
/// <summary> Creates and returns the ROIDeScaler corresponding to the information
/// read from the codestream header and with the special additional
/// parameters from the parameter list.
///
/// </summary>
/// <param name="src">The bit stream reader agent where to get code-block data
/// from.
///
/// </param>
/// <param name="pl">The parameter list containing parameters applicable to the
/// entropy decoder (other parameters can also be present).
///
/// </param>
/// <param name="decSpec2">The DecoderSpecs instance after any image manipulation.
///
/// </param>
/// <returns> The ROI descaler.
///
/// </returns>
public virtual ROIDeScaler createROIDeScaler(CBlkQuantDataSrcDec src, ParameterList pl, DecoderSpecs decSpec2)
{
return ROIDeScaler.createInstance(src, pl, decSpec2);
}
/// <summary> Reads all tiles headers and keep offset of their first
/// packet. Finally it calls the rate allocation method.
///
/// </summary>
/// <param name="hd">HeaderDecoder of the codestream.
///
/// </param>
/// <param name="ehs">The input stream where to read bit-stream.
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
/// <param name="pl">The ParameterList instance created from the
/// command-line arguments.
///
/// </param>
/// <param name="cdstrInfo">Whether or not to print information found in
/// codestream.
///
/// </param>
/// <seealso cref="allocateRate">
///
/// </seealso>
public FileBitstreamReaderAgent(HeaderDecoder hd, RandomAccessIO ehs, DecoderSpecs decSpec, ParameterList pl, bool cdstrInfo, HeaderInfo hi):base(hd, decSpec)
{
this.pl = pl;
this.printInfo = cdstrInfo;
this.hi = hi;
// Check whether quit conditiosn used
usePOCQuit = pl.getBooleanParameter("poc_quit");
// Get decoding rate
bool rateInBytes;
bool parsing = pl.getBooleanParameter("parsing");
try
{
trate = pl.getFloatParameter("rate");
if (trate == - 1)
{
trate = System.Single.MaxValue;
}
}
catch (System.FormatException)
{
throw new System.ApplicationException("Invalid value in 'rate' option: " + pl.getParameter("rate"));
}
catch (System.ArgumentException)
{
throw new System.ApplicationException("'rate' option is missing");
}
try
{
tnbytes = pl.getIntParameter("nbytes");
}
catch (System.FormatException)
{
throw new System.ApplicationException("Invalid value in 'nbytes' option: " + pl.getParameter("nbytes"));
}
catch (System.ArgumentException)
{
throw new System.ApplicationException("'nbytes' option is missing");
}
// Check that '-rate' and '-nbytes' are not used at the same time
ParameterList defaults = pl.DefaultParameterList;
if (tnbytes != defaults.getFloatParameter("nbytes"))
{
rateInBytes = true;
}
else
{
rateInBytes = false;
}
if (rateInBytes)
{
trate = tnbytes * 8f / hd.MaxCompImgWidth / hd.MaxCompImgHeight;
}
else
{
//UPGRADE_WARNING: Data types in Visual C# might be different. Verify the accuracy of narrowing conversions. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1042'"
tnbytes = (int) (trate * hd.MaxCompImgWidth * hd.MaxCompImgHeight) / 8;
if (tnbytes < 0) tnbytes = int.MaxValue;
}
isTruncMode = !pl.getBooleanParameter("parsing");
// Check if quit conditions are being used
int ncbQuit;
try
{
ncbQuit = pl.getIntParameter("ncb_quit");
}
catch (System.FormatException)
{
throw new System.ApplicationException("Invalid value in 'ncb_quit' option: " + pl.getParameter("ncb_quit"));
}
catch (System.ArgumentException)
{
throw new System.ApplicationException("'ncb_quit' option is missing");
}
if (ncbQuit != - 1 && !isTruncMode)
{
throw new System.ApplicationException("Cannot use -parsing and -ncb_quit condition at " + "the same time.");
}
try
{
lQuit = pl.getIntParameter("l_quit");
}
catch (System.FormatException)
{
throw new System.ApplicationException("Invalid value in 'l_quit' option: " + pl.getParameter("l_quit"));
}
catch (System.ArgumentException)
{
throw new System.ApplicationException("'l_quit' option is missing");
}
// initializations
in_Renamed = ehs;
pktDec = new PktDecoder(decSpec, hd, ehs, this, isTruncMode, ncbQuit);
tileParts = new int[nt];
totTileLen = new int[nt];
tilePartLen = new int[nt][];
tilePartNum = new int[nt][];
firstPackOff = new int[nt][];
tilePartsRead = new int[nt];
totTileHeadLen = new int[nt];
tilePartHeadLen = new int[nt][];
nBytes = new int[nt];
baknBytes = new int[nt];
hd.nTileParts = new int[nt];
// CONVERSION PROBLEM?
//this.isTruncMode = isTruncMode;
int t = 0, pos, tp = 0, tptot = 0;
// Keeps main header's length, takes file format overhead into account
int cdstreamStart = hd.mainHeadOff; // Codestream offset in the file
mainHeadLen = in_Renamed.Pos - cdstreamStart;
headLen = mainHeadLen;
// If ncb and lbody quit conditions are used, headers are not counted
if (ncbQuit == - 1)
{
anbytes = mainHeadLen;
}
else
{
anbytes = 0;
}
// If cannot even read the first tile-part
if (anbytes > tnbytes)
{
throw new System.ApplicationException("Requested bitrate is too small.");
}
// Read all tile-part headers from all tiles.
int tilePartStart;
bool rateReached = false;
int mdl;
//int numtp = 0;
totAllTileLen = 0;
remainingTileParts = nt; // at least as many tile-parts as tiles
int maxTP = nt; // If maximum 1 tile part per tile specified
try
{
while (remainingTileParts != 0)
{
tilePartStart = in_Renamed.Pos;
// Read tile-part header
try
{
t = readTilePartHeader();
if (isEOCFound)
{
// Some tiles are missing but the
// codestream is OK
break;
}
tp = tilePartsRead[t];
if (isPsotEqualsZero)
{
// Psot may equals zero for the
// last tile-part: it is assumed that this tile-part
// contain all data until EOC
tilePartLen[t][tp] = in_Renamed.length() - 2 - tilePartStart;
}
}
catch (System.IO.EndOfStreamException e)
{
firstPackOff[t][tp] = in_Renamed.length();
throw e;
}
pos = in_Renamed.Pos;
// In truncation mode, if target decoding rate is reached in
// tile-part header, skips the tile-part and stop reading
// unless the ncb and lbody quit condition is in use
if (isTruncMode && ncbQuit == - 1)
{
if ((pos - cdstreamStart) > tnbytes)
{
firstPackOff[t][tp] = in_Renamed.length();
rateReached = true;
break;
}
}
// Set tile part position and header length
firstPackOff[t][tp] = pos;
tilePartHeadLen[t][tp] = (pos - tilePartStart);
// Update length counters
totTileLen[t] += tilePartLen[t][tp];
totTileHeadLen[t] += tilePartHeadLen[t][tp];
totAllTileLen += tilePartLen[t][tp];
if (isTruncMode)
{
if (anbytes + tilePartLen[t][tp] > tnbytes)
{
anbytes += tilePartHeadLen[t][tp];
headLen += tilePartHeadLen[t][tp];
rateReached = true;
nBytes[t] += (tnbytes - anbytes);
break;
}
else
{
anbytes += tilePartHeadLen[t][tp];
headLen += tilePartHeadLen[t][tp];
nBytes[t] += (tilePartLen[t][tp] - tilePartHeadLen[t][tp]);
}
}
else
{
if (anbytes + tilePartHeadLen[t][tp] > tnbytes)
{
break;
}
else
{
anbytes += tilePartHeadLen[t][tp];
headLen += tilePartHeadLen[t][tp];
}
}
// If this is first tile-part, remember header length
if (tptot == 0)
firstTilePartHeadLen = tilePartHeadLen[t][tp];
// Go to the beginning of next tile part
tilePartsRead[t]++;
in_Renamed.seek(tilePartStart + tilePartLen[t][tp]);
remainingTileParts--;
maxTP--;
tptot++;
// If Psot of the current tile-part was equal to zero, it is
// assumed that it contains all data until the EOC marker
if (isPsotEqualsZero)
{
if (remainingTileParts != 0)
{
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "Some tile-parts have not " + "been found. The codestream may be corrupted.");
}
break;
}
}
}
catch (System.IO.EndOfStreamException)
{
if (printInfo)
{
}
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "Codestream truncated in tile " + t);
// Set specified rate to end of file if valid
int fileLen = in_Renamed.length();
if (fileLen < tnbytes)
{
tnbytes = fileLen;
trate = tnbytes * 8f / hd.MaxCompImgWidth / hd.MaxCompImgHeight;
}
// Bit-rate allocation
if (!isTruncMode)
{
allocateRate();
}
// Update 'res' value once all tile-part headers are read
if (pl.getParameter("res") == null)
{
targetRes = decSpec.dls.Min;
}
else
{
try
{
targetRes = pl.getIntParameter("res");
if (targetRes < 0)
{
throw new System.ArgumentException("Specified negative " + "resolution level " + "index: " + targetRes);
}
}
catch (System.FormatException)
{
throw new System.ArgumentException("Invalid resolution level " + "index ('-res' option) " + pl.getParameter("res"));
}
}
// Verify reduction in resolution level
mdl = decSpec.dls.Min;
if (targetRes > mdl)
{
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "Specified resolution level (" + targetRes + ") is larger" + " than the maximum value. Setting it to " + mdl + " (maximum value)");
targetRes = mdl;
}
// Backup nBytes
for (int tIdx = 0; tIdx < nt; tIdx++)
{
baknBytes[tIdx] = nBytes[tIdx];
}
return ;
}
remainingTileParts = 0;
// Update 'res' value once all tile-part headers are read
if (pl.getParameter("res") == null)
{
targetRes = decSpec.dls.Min;
}
else
{
try
{
targetRes = pl.getIntParameter("res");
if (targetRes < 0)
{
throw new System.ArgumentException("Specified negative " + "resolution level index: " + targetRes);
}
}
catch (System.FormatException)
{
throw new System.ArgumentException("Invalid resolution level " + "index ('-res' option) " + pl.getParameter("res"));
}
}
// Verify reduction in resolution level
mdl = decSpec.dls.Min;
if (targetRes > mdl)
{
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "Specified resolution level (" + targetRes + ") is larger" + " than the maximum possible. Setting it to " + mdl + " (maximum possible)");
targetRes = mdl;
}
if (printInfo)
{
}
// Check presence of EOC marker is decoding rate not reached or if
// this marker has not been found yet
if (!isEOCFound && !isPsotEqualsZero)
{
try
{
short eocCheck = 0;
if (in_Renamed.Pos + sizeof(short) <= in_Renamed.length())
eocCheck = in_Renamed.readShort();
if (!rateReached && !isPsotEqualsZero && eocCheck != CSJ2K.j2k.codestream.Markers.EOC)
{
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "EOC marker not found. " + "Codestream is corrupted.");
}
}
catch (System.IO.EndOfStreamException)
{
FacilityManager.getMsgLogger().printmsg(CSJ2K.j2k.util.MsgLogger_Fields.WARNING, "EOC marker is missing");
}
}
// Bit-rate allocation
if (!isTruncMode)
{
allocateRate();
}
else
{
// Take EOC into account if rate is not reached
if (in_Renamed.Pos >= tnbytes)
anbytes += 2;
}
// Backup nBytes
for (int tIdx = 0; tIdx < nt; tIdx++)
{
baknBytes[tIdx] = nBytes[tIdx];
if (printInfo)
{
FacilityManager.getMsgLogger().println("" + hi.toStringTileHeader(tIdx, tilePartLen[tIdx].Length), 2, 2);
}
}
}
//private bool[][] reversible;
/// <summary> Initializes this object with the given source of wavelet
/// coefficients. It initializes the resolution level for full resolutioin
/// reconstruction.
///
/// </summary>
/// <param name="src">from where the wavelet coefficinets should be obtained.
///
/// </param>
/// <param name="decSpec">The decoder specifications
///
/// </param>
public InvWTFull(CBlkWTDataSrcDec src, DecoderSpecs decSpec):base(src, decSpec)
{
this.src = src;
int nc = src.NumComps;
reconstructedComps = new DataBlk[nc];
ndl = new int[nc];
pw = FacilityManager.ProgressWatch;
}