Esempio n. 1
0
bool ImageLoaderJPG::LoadParams(Image &cImage, File &cFile, bool bBlockSmoothing, bool bFancyUpsampling)
{
    jpeg_decompress_struct sInfo;
    jpeg_error_mgr sError;

    sInfo.err = jpeg_std_error(&sError);
    sInfo.err->error_exit = ExitErrorHandle;

    jpeg_create_decompress(&sInfo);

    // Set the user given parameters
    sInfo.do_block_smoothing  = bBlockSmoothing;
    sInfo.do_fancy_upsampling = bFancyUpsampling;

    jpeg_read_init(&sInfo, &cFile);

    jpeg_read_header(&sInfo, TRUE);
    jpeg_start_decompress(&sInfo);

    // Get the color format
    EColorFormat nColorFormat;
    switch (sInfo.num_components) {
    case 1:
        nColorFormat = ColorGrayscale;
        break;

    case 3:
        nColorFormat = ColorRGB;
        break;

    case 4:
        nColorFormat = ColorRGBA;
        break;

    default:
        // Error: Unsupported color format
        return false;
    }

    // Create image buffer
    ImageBuffer *pImageBuffer = cImage.CreatePart()->CreateMipmap();
    pImageBuffer->CreateImage(DataByte, nColorFormat, Vector3i(sInfo.output_width, sInfo.output_height, 1));

    // Read in the data
    uint8 *pCurrentData = pImageBuffer->GetData();
    while (sInfo.output_scanline < sInfo.output_height) {
        jpeg_read_scanlines(&sInfo, &pCurrentData, 1);
        pCurrentData += pImageBuffer->GetBytesPerRow();
    }

    // Cleanup
    jpeg_finish_decompress(&sInfo);
    jpeg_destroy_decompress(&sInfo);

    // Done
    return true;
}
//[-------------------------------------------------------]
//[ Public RTTI methods                                   ]
//[-------------------------------------------------------]
bool TransferFunctionLoaderTABLE::Load(TransferFunction &cTransferFunction, File &cFile)
{
	// Get the image holding the transfer function
	Image &cImage = cTransferFunction.GetImage();

	// A "table"-file (simple ASCII) looks like this
	/*
		1 1 1 1
		baseOpacity: 0.698039
		NoTags
		0 0 0 0
		. . . .
		. . . .
		. . . .
	*/

	// Use the tokenizer in order to gather all required information, ignore the rest
	// Startup the tokenizer
	Tokenizer cTokenizer;
	cTokenizer.Start(cFile.GetContentAsString());

	// Ignore the first line ("1 1 1 1")
	cTokenizer.GetNextToken();
	cTokenizer.GetNextToken();
	cTokenizer.GetNextToken();
	cTokenizer.GetNextToken();

	// Ignore base opacity ("baseOpacity: 0.698039")
	cTokenizer.GetNextToken();
	cTokenizer.GetNextToken();

	// Ignore tags to keep this loader simple ("NoTags")
	cTokenizer.GetNextToken();

	// Create image buffer
	ImageBuffer *pImageBuffer = cImage.CreatePart()->CreateMipmap();
	pImageBuffer->CreateImage(DataByte, ColorRGBA, Vector3i(256, 1, 1));

	// Read in the palette
	uint8 *pImageData = pImageBuffer->GetData();
	for (uint32 i=0; i<256; i++) {
		// Read RGBA entry
		*pImageData = cTokenizer.GetNextToken().GetUInt8();
		pImageData++;
		*pImageData = cTokenizer.GetNextToken().GetUInt8();
		pImageData++;
		*pImageData = cTokenizer.GetNextToken().GetUInt8();
		pImageData++;
		*pImageData = cTokenizer.GetNextToken().GetUInt8();
		pImageData++;
	}

	// Done
	return true;
}
Esempio n. 3
0
//[-------------------------------------------------------]
//[ Public RTTI methods                                   ]
//[-------------------------------------------------------]
bool VolumeLoaderDAT::Load(Volume &cVolume, File &cFile)
{
	Url cObjectFilename;
	Vector3i vResolution;
	EDataFormat nFormat = DataByte;

	// Get the image holding the volumetric data
	Image &cImage = cVolume.GetVolumeImage();

	{ // Use the tokenizer in order to gather all required information, ignore the rest
		// A "dat"-file (simple ASCII) looks like this
		/*
			ObjectFileName: Teddybear.raw
			TaggedFileName: ---
			Resolution:     128 128 62
			SliceThickness: 2.8 2.8 5
			Format:         UCHAR
			NbrTags:        0
			ObjectType:     TEXTURE_VOLUME_OBJECT
			ObjectModel:    RGBA
			GridType:       EQUIDISTANT
		*/

		// Startup the tokenizer
		Tokenizer cTokenizer;
		cTokenizer.Start(cFile.GetContentAsString());

		// Loop through all tokens
		String sToken = cTokenizer.GetNextToken();
		while (sToken.GetLength()) {
			// ObjectFileName
			if (sToken == "ObjectFileName:") {
				// The file format specification says:
				//	"The object file name refers to the name of the data file, which contains the raw voxel data.
				//	 This can be either an absolute path or a relative path with respect to the storage position of the dat file."

				// Get the value
				cObjectFilename = cTokenizer.GetNextToken();

			// Resolution
			} else if (sToken == "Resolution:") {
				// The file format specification says:
				//	"The volume data set consists of a large array of voxel values. The resolution of the data set is given
				//	 by the number of voxels in x-, y- and z- direction."

				// Get the values
				vResolution.x = cTokenizer.GetNextToken().GetInt();
				vResolution.y = cTokenizer.GetNextToken().GetInt();
				vResolution.z = cTokenizer.GetNextToken().GetInt();

			// SliceThickness
			} else if (sToken == "SliceThickness:") {
				// The file format specification says:
				//	"The size of one voxel in x-, y- and z- direction (usually in millimeters)."

				//						  mm to cm    cm to m
				static const float Scale = 0.1f    *   0.01f;

				// Get the values
				Vector3 vSliceThickness;
				vSliceThickness.x = cTokenizer.GetNextToken().GetFloat()*Scale;
				vSliceThickness.y = cTokenizer.GetNextToken().GetFloat()*Scale;
				vSliceThickness.z = cTokenizer.GetNextToken().GetFloat()*Scale;

				// Set the size of one voxel (without metric, but usually one unit is equal to one meter)
				cVolume.SetVoxelSize(vSliceThickness);

			// Format
			} else if (sToken == "Format:") {
				// The file format specification says:
				//	"The data format of one voxel. Can be either UCHAR (8 bit) or USHORT (16 bit)."

				// Get the value
				const String sFormat = cTokenizer.GetNextToken();
				if (sFormat == "UCHAR")
					nFormat = DataByte;	// Byte (8 bit)
				else if (sFormat == "USHORT")
					nFormat = DataWord;	// Word (16 bit)
			}

			// Next token, please
			sToken = cTokenizer.GetNextToken();
		}
	}

	// Valid settings? If so, open and read in the raw data...
	if (!cObjectFilename.IsEmpty() && vResolution.x > 0 && vResolution.y > 0 && vResolution.z > 0) {
		// The file format specification says:
		//	"The data file simply contains the raw voxel data as a large binary array which is indexed as
		//	 voxel(x,y,z) = array[z * YDIM * XDIM + y * XDIM + x],
		//	 with XDIM, YDIM and ZDIM referring to the resolution of the data set, as specified in line 3
		//	 of the header file. For 16 bit data, the data may be stored either in big endian or little endian format."
		//	-> We expect "Little Endian First"

		// Get the filename of the raw file
		const String sRawFilename = cObjectFilename.IsAbsolute() ? cObjectFilename.GetUrl() : (cFile.GetUrl().CutFilename() + cObjectFilename.GetUrl());

		// Open the raw file
		File cRawFile(sRawFilename);
		if (cRawFile.Open(File::FileRead)) {
			// Create image buffer
			ImageBuffer *pImageBuffer = cImage.CreatePart()->CreateMipmap();
			pImageBuffer->CreateImage(nFormat, ColorGrayscale, vResolution);

			// Read the data
			cRawFile.Read(pImageBuffer->GetData(), 1, pImageBuffer->GetDataSize());

			// Load the transfer function by using "<filename>.table", or at least try it
			cVolume.GetTransferFunction().LoadByFilename(cFile.GetUrl().CutExtension() + ".table");

			// Done
			return true;
		}
	}

	// Error!
	return false;
}
Esempio n. 4
0
bool IEScale::Apply(ImageBuffer &cImageBuffer) const
{
	// Get dimensions
	const uint32 nNewWidth  = m_vNewSize.x;
	const uint32 nNewHeight = m_vNewSize.y;
	const uint32 nOldWidth  = cImageBuffer.GetSize().x;
	const uint32 nOldHeight = cImageBuffer.GetSize().y;

	// [TODO] 3D support
	// [TODO] Currently we only support 'scale down'
	// New width and new height must be >0, ColorPalette as color format is not supported
	if (cImageBuffer.GetColorFormat() != ColorPalette && nNewWidth <= nOldWidth && nNewHeight <= nOldHeight && nNewWidth && nNewHeight) {
		// 3x3 filter matrix
		static const Matrix3x3 mFilter(0.1f, 0.5f, 0.1f,
									   0.5f, 1.0f, 0.5f,
									   0.1f, 0.5f, 0.1f);

		// Create the new image buffer
		ImageBuffer cOldImageBuffer = cImageBuffer;
		// [TODO] Currently compressing data is not implemented, yet
		cImageBuffer.CreateImage(cOldImageBuffer.GetDataFormat(), cOldImageBuffer.GetColorFormat(), Vector3i(nNewWidth, nNewHeight, 1));
//		cImageBuffer.CreateImage(cOldImageBuffer.GetDataFormat(), cOldImageBuffer.GetColorFormat(), Vector3i(nNewWidth, nNewHeight, 1), cOldImageBuffer.GetCompression());

		// Process data format dependent
		switch (cImageBuffer.GetDataFormat()) {
			case DataByte:
			{
				ScaleDownData<uint8> cScaleDownData(cOldImageBuffer, cImageBuffer, nNewWidth, nNewHeight, nOldWidth, nOldHeight, mFilter);
				break;
			}

			case DataWord:
			{
				ScaleDownData<uint16> cScaleDownData(cOldImageBuffer, cImageBuffer, nNewWidth, nNewHeight, nOldWidth, nOldHeight, mFilter);
				break;
			}

			case DataHalf:
			{
				ScaleDownHalfData(cOldImageBuffer, cImageBuffer, nNewWidth, nNewHeight, nOldWidth, nOldHeight, mFilter);
				break;
			}

			case DataFloat:
			{
				ScaleDownData<float> cScaleDownData(cOldImageBuffer, cImageBuffer, nNewWidth, nNewHeight, nOldWidth, nOldHeight, mFilter);
				break;
			}

			case DataDouble:
			{
				ScaleDownData<double> cScaleDownData(cOldImageBuffer, cImageBuffer, nNewWidth, nNewHeight, nOldWidth, nOldHeight, mFilter);
				break;
			}
		}

		// Done
		return true;
	}

	// Error!
	return false;
}