/usr/include/vtk-5.8/vtkFixedPointVolumeRayCastMapper.h is in libvtk5-dev 5.8.0-5.
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Program: Visualization Toolkit
Module: vtkFixedPointVolumeRayCastMapper.h
Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
All rights reserved.
See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notice for more information.
=========================================================================*/
// .NAME vtkFixedPointVolumeRayCastMapper - A fixed point mapper for volumes
// .SECTION Description
// This is a software ray caster for rendering volumes in vtkImageData.
// It works with all input data types and up to four components. It performs
// composite or MIP rendering, and can be intermixed with geometric data.
// Space leaping is used to speed up the rendering process. In addition,
// calculation are performed in 15 bit fixed point precision. This mapper
// is threaded, and will interleave scan lines across processors.
//
// This mapper is a good replacement for vtkVolumeRayCastMapper EXCEPT:
// - it does not do isosurface ray casting
// - it does only interpolate before classify compositing
// - it does only maximum scalar value MIP
//
// The vtkVolumeRayCastMapper CANNOT be used in these instances when a
// vtkFixedPointVolumeRayCastMapper can be used:
// - if the data is not unsigned char or unsigned short
// - if the data has more than one component
//
// This mapper handles all data type from unsigned char through double.
// However, some of the internal calcultions are performed in float and
// therefore even the full float range may cause problems for this mapper
// (both in scalar data values and in spacing between samples).
//
// Space leaping is performed by creating a sub-sampled volume. 4x4x4
// cells in the original volume are represented by a min, max, and
// combined gradient and flag value. The min max volume has three
// unsigned shorts per 4x4x4 group of cells from the original volume -
// one reprenting the minumum scalar index (the scalar value adjusted
// to fit in the 15 bit range), the maximum scalar index, and a
// third unsigned short which is both the maximum gradient opacity in
// the neighborhood (an unsigned char) and the flag that is filled
// in for the current lookup tables to indicate whether this region
// can be skipped.
// .SECTION see also
// vtkVolumeMapper
#ifndef __vtkFixedPointVolumeRayCastMapper_h
#define __vtkFixedPointVolumeRayCastMapper_h
#include "vtkVolumeMapper.h"
#define VTKKW_FP_SHIFT 15
#define VTKKW_FPMM_SHIFT 17
#define VTKKW_FP_MASK 0x7fff
#define VTKKW_FP_SCALE 32767.0
class vtkMatrix4x4;
class vtkMultiThreader;
class vtkPlaneCollection;
class vtkRenderer;
class vtkTimerLog;
class vtkVolume;
class vtkTransform;
class vtkRenderWindow;
class vtkColorTransferFunction;
class vtkPiecewiseFunction;
class vtkFixedPointVolumeRayCastMIPHelper;
class vtkFixedPointVolumeRayCastCompositeHelper;
class vtkFixedPointVolumeRayCastCompositeGOHelper;
class vtkFixedPointVolumeRayCastCompositeGOShadeHelper;
class vtkFixedPointVolumeRayCastCompositeShadeHelper;
class vtkVolumeRayCastSpaceLeapingImageFilter;
class vtkDirectionEncoder;
class vtkEncodedGradientShader;
class vtkFiniteDifferenceGradientEstimator;
class vtkRayCastImageDisplayHelper;
class vtkFixedPointRayCastImage;
class vtkDataArray;
//BTX
// Forward declaration needed for use by friend declaration below.
VTK_THREAD_RETURN_TYPE FixedPointVolumeRayCastMapper_CastRays( void *arg );
VTK_THREAD_RETURN_TYPE vtkFPVRCMSwitchOnDataType( void *arg );
//ETX
class VTK_VOLUMERENDERING_EXPORT vtkFixedPointVolumeRayCastMapper : public vtkVolumeMapper
{
public:
static vtkFixedPointVolumeRayCastMapper *New();
vtkTypeMacro(vtkFixedPointVolumeRayCastMapper,vtkVolumeMapper);
void PrintSelf( ostream& os, vtkIndent indent );
// Description:
// Set/Get the distance between samples used for rendering
// when AutoAdjustSampleDistances is off, or when this mapper
// has more than 1 second allocated to it for rendering.
vtkSetMacro( SampleDistance, float );
vtkGetMacro( SampleDistance, float );
// Description:
// Set/Get the distance between samples when interactive rendering is happening.
// In this case, interactive is defined as this volume mapper having less than 1
// second allocated for rendering. When AutoAdjustSampleDistance is On, and the
// allocated render time is less than 1 second, then this InteractiveSampleDistance
// will be used instead of the SampleDistance above.
vtkSetMacro( InteractiveSampleDistance, float );
vtkGetMacro( InteractiveSampleDistance, float );
// Description:
// Sampling distance in the XY image dimensions. Default value of 1 meaning
// 1 ray cast per pixel. If set to 0.5, 4 rays will be cast per pixel. If
// set to 2.0, 1 ray will be cast for every 4 (2 by 2) pixels. This value
// will be adjusted to meet a desired frame rate when AutoAdjustSampleDistances
// is on.
vtkSetClampMacro( ImageSampleDistance, float, 0.1f, 100.0f );
vtkGetMacro( ImageSampleDistance, float );
// Description:
// This is the minimum image sample distance allow when the image
// sample distance is being automatically adjusted.
vtkSetClampMacro( MinimumImageSampleDistance, float, 0.1f, 100.0f );
vtkGetMacro( MinimumImageSampleDistance, float );
// Description:
// This is the maximum image sample distance allow when the image
// sample distance is being automatically adjusted.
vtkSetClampMacro( MaximumImageSampleDistance, float, 0.1f, 100.0f );
vtkGetMacro( MaximumImageSampleDistance, float );
// Description:
// If AutoAdjustSampleDistances is on, the the ImageSampleDistance
// and the SampleDistance will be varied to achieve the allocated
// render time of this prop (controlled by the desired update rate
// and any culling in use). If this is an interactive render (more
// than 1 frame per second) the SampleDistance will be increased,
// otherwise it will not be altered (a binary decision, as opposed
// to the ImageSampleDistance which will vary continuously).
vtkSetClampMacro( AutoAdjustSampleDistances, int, 0, 1 );
vtkGetMacro( AutoAdjustSampleDistances, int );
vtkBooleanMacro( AutoAdjustSampleDistances, int );
// Description:
// Automatically compute the sample distance from the data spacing. When
// the number of voxels is 8, the sample distance will be roughly 1/200
// the average voxel size. The distance will grow proportionally to
// numVoxels^(1/3) until it reaches 1/2 average voxel size when number of
// voxels is 1E6. Note that ScalarOpacityUnitDistance is still taken into
// account and if different than 1, will effect the sample distance.
vtkSetClampMacro( LockSampleDistanceToInputSpacing, int, 0, 1 );
vtkGetMacro( LockSampleDistanceToInputSpacing, int );
vtkBooleanMacro( LockSampleDistanceToInputSpacing, int );
// Description:
// Set/Get the number of threads to use. This by default is equal to
// the number of available processors detected.
void SetNumberOfThreads( int num );
int GetNumberOfThreads();
// Description:
// If IntermixIntersectingGeometry is turned on, the zbuffer will be
// captured and used to limit the traversal of the rays.
vtkSetClampMacro( IntermixIntersectingGeometry, int, 0, 1 );
vtkGetMacro( IntermixIntersectingGeometry, int );
vtkBooleanMacro( IntermixIntersectingGeometry, int );
// Description:
// What is the image sample distance required to achieve the desired time?
// A version of this method is provided that does not require the volume
// argument since if you are using an LODProp3D you may not know this information.
// If you use this version you must be certain that the ray cast mapper is
// only used for one volume (and not shared among multiple volumes)
float ComputeRequiredImageSampleDistance( float desiredTime,
vtkRenderer *ren );
float ComputeRequiredImageSampleDistance( float desiredTime,
vtkRenderer *ren,
vtkVolume *vol );
//BTX
// Description:
// WARNING: INTERNAL METHOD - NOT INTENDED FOR GENERAL USE
// Initialize rendering for this volume.
void Render( vtkRenderer *, vtkVolume * );
unsigned int ToFixedPointPosition( float val );
void ToFixedPointPosition( float in[3], unsigned int out[3] );
unsigned int ToFixedPointDirection( float dir );
void ToFixedPointDirection( float in[3], unsigned int out[3] );
void FixedPointIncrement( unsigned int position[3], unsigned int increment[3] );
void GetFloatTripleFromPointer( float v[3], float *ptr );
void GetUIntTripleFromPointer( unsigned int v[3], unsigned int *ptr );
void ShiftVectorDown( unsigned int in[3], unsigned int out[3] );
int CheckMinMaxVolumeFlag( unsigned int pos[3], int c );
int CheckMIPMinMaxVolumeFlag( unsigned int pos[3], int c, unsigned short maxIdx, int flip );
void LookupColorUC( unsigned short *colorTable,
unsigned short *scalarOpacityTable,
unsigned short index,
unsigned char color[4] );
void LookupDependentColorUC( unsigned short *colorTable,
unsigned short *scalarOpacityTable,
unsigned short index[4],
int components,
unsigned char color[4] );
void LookupAndCombineIndependentColorsUC(
unsigned short *colorTable[4],
unsigned short *scalarOpacityTable[4],
unsigned short index[4],
float weights[4],
int components,
unsigned char color[4] );
int CheckIfCropped( unsigned int pos[3] );
//ETX
vtkGetObjectMacro( RenderWindow, vtkRenderWindow );
vtkGetObjectMacro( MIPHelper, vtkFixedPointVolumeRayCastMIPHelper );
vtkGetObjectMacro( CompositeHelper, vtkFixedPointVolumeRayCastCompositeHelper );
vtkGetObjectMacro( CompositeGOHelper, vtkFixedPointVolumeRayCastCompositeGOHelper );
vtkGetObjectMacro( CompositeGOShadeHelper, vtkFixedPointVolumeRayCastCompositeGOShadeHelper );
vtkGetObjectMacro( CompositeShadeHelper, vtkFixedPointVolumeRayCastCompositeShadeHelper );
vtkGetVectorMacro( TableShift, float, 4 );
vtkGetVectorMacro( TableScale, float, 4 );
vtkGetMacro( ShadingRequired, int );
vtkGetMacro( GradientOpacityRequired, int );
vtkGetObjectMacro( CurrentScalars, vtkDataArray );
vtkGetObjectMacro( PreviousScalars, vtkDataArray );
int *GetRowBounds() {return this->RowBounds;}
unsigned short *GetColorTable(int c) {return this->ColorTable[c];}
unsigned short *GetScalarOpacityTable(int c) {return this->ScalarOpacityTable[c];}
unsigned short *GetGradientOpacityTable(int c) {return this->GradientOpacityTable[c];}
vtkVolume *GetVolume() {return this->Volume;}
unsigned short **GetGradientNormal() {return this->GradientNormal;}
unsigned char **GetGradientMagnitude() {return this->GradientMagnitude;}
unsigned short *GetDiffuseShadingTable(int c) {return this->DiffuseShadingTable[c];}
unsigned short *GetSpecularShadingTable(int c) {return this->SpecularShadingTable[c];}
void ComputeRayInfo( int x, int y,
unsigned int pos[3],
unsigned int dir[3],
unsigned int *numSteps );
void InitializeRayInfo( vtkVolume *vol );
int ShouldUseNearestNeighborInterpolation( vtkVolume *vol );
// Description:
// Set / Get the underlying image object. One will be automatically
// created - only need to set it when using from an AMR mapper which
// renders multiple times into the same image.
void SetRayCastImage( vtkFixedPointRayCastImage * );
vtkGetObjectMacro( RayCastImage, vtkFixedPointRayCastImage );
int PerImageInitialization( vtkRenderer *, vtkVolume *, int,
double *, double *, int * );
void PerVolumeInitialization( vtkRenderer *, vtkVolume * );
void PerSubVolumeInitialization( vtkRenderer *, vtkVolume *, int );
void RenderSubVolume();
void DisplayRenderedImage( vtkRenderer *, vtkVolume * );
void AbortRender();
void CreateCanonicalView( vtkVolume *volume,
vtkImageData *image,
int blend_mode,
double viewDirection[3],
double viewUp[3] );
// Description:
// Get an estimate of the rendering time for a given volume / renderer.
// Only valid if this mapper has been used to render that volume for
// that renderer previously. Estimate is good when the viewing parameters
// have not changed much since that last render.
float GetEstimatedRenderTime( vtkRenderer *ren,
vtkVolume *vol )
{ return this->RetrieveRenderTime( ren, vol ); }
float GetEstimatedRenderTime( vtkRenderer *ren )
{ return this->RetrieveRenderTime( ren ); }
// Description:
// Set/Get the window / level applied to the final color.
// This allows brightness / contrast adjustments on the
// final image.
// window is the width of the window.
// level is the center of the window.
// Initial window value is 1.0
// Initial level value is 0.5
// window cannot be null but can be negative, this way
// values will be reversed.
// |window| can be larger than 1.0
// level can be any real value.
vtkSetMacro( FinalColorWindow, float );
vtkGetMacro( FinalColorWindow, float );
vtkSetMacro( FinalColorLevel, float );
vtkGetMacro( FinalColorLevel, float );
// Here to be used by the mapper to tell the helper
// to flip the MIP comparison in order to support
// minimum intensity blending
vtkGetMacro( FlipMIPComparison, int );
protected:
vtkFixedPointVolumeRayCastMapper();
~vtkFixedPointVolumeRayCastMapper();
// The helper class that displays the image
vtkRayCastImageDisplayHelper *ImageDisplayHelper;
// The distance between sample points along the ray
float SampleDistance;
float InteractiveSampleDistance;
// The distance between rays in the image
float ImageSampleDistance;
float MinimumImageSampleDistance;
float MaximumImageSampleDistance;
int AutoAdjustSampleDistances;
int LockSampleDistanceToInputSpacing;
// Saved values used to restore
float OldSampleDistance;
float OldImageSampleDistance;
// Internal method for computing matrices needed during
// ray casting
void ComputeMatrices( double volumeOrigin[3],
double volumeSpacing[3],
int volumeExtent[6],
vtkRenderer *ren,
vtkVolume *vol );
int ComputeRowBounds( vtkRenderer *ren,
int imageFlag, int rowBoundsFlag,
int volumeExtent[6]);
void CaptureZBuffer( vtkRenderer *ren );
friend VTK_THREAD_RETURN_TYPE FixedPointVolumeRayCastMapper_CastRays( void *arg );
friend VTK_THREAD_RETURN_TYPE vtkFPVRCMSwitchOnDataType( void *arg );
vtkMultiThreader *Threader;
vtkMatrix4x4 *PerspectiveMatrix;
vtkMatrix4x4 *ViewToWorldMatrix;
vtkMatrix4x4 *ViewToVoxelsMatrix;
vtkMatrix4x4 *VoxelsToViewMatrix;
vtkMatrix4x4 *WorldToVoxelsMatrix;
vtkMatrix4x4 *VoxelsToWorldMatrix;
vtkMatrix4x4 *VolumeMatrix;
vtkTransform *PerspectiveTransform;
vtkTransform *VoxelsTransform;
vtkTransform *VoxelsToViewTransform;
// This object encapsulated the image and all related information
vtkFixedPointRayCastImage *RayCastImage;
int *RowBounds;
int *OldRowBounds;
float *RenderTimeTable;
vtkVolume **RenderVolumeTable;
vtkRenderer **RenderRendererTable;
int RenderTableSize;
int RenderTableEntries;
void StoreRenderTime( vtkRenderer *ren, vtkVolume *vol, float t );
float RetrieveRenderTime( vtkRenderer *ren, vtkVolume *vol );
float RetrieveRenderTime( vtkRenderer *ren );
int IntermixIntersectingGeometry;
float MinimumViewDistance;
vtkColorTransferFunction *SavedRGBFunction[4];
vtkPiecewiseFunction *SavedGrayFunction[4];
vtkPiecewiseFunction *SavedScalarOpacityFunction[4];
vtkPiecewiseFunction *SavedGradientOpacityFunction[4];
int SavedColorChannels[4];
float SavedScalarOpacityDistance[4];
int SavedBlendMode;
vtkImageData *SavedParametersInput;
vtkTimeStamp SavedParametersMTime;
vtkImageData *SavedGradientsInput;
vtkTimeStamp SavedGradientsMTime;
float SavedSampleDistance;
unsigned short ColorTable[4][32768*3];
unsigned short ScalarOpacityTable[4][32768];
unsigned short GradientOpacityTable[4][256];
int TableSize[4];
float TableScale[4];
float TableShift[4];
float GradientMagnitudeScale[4];
float GradientMagnitudeShift[4];
unsigned short **GradientNormal;
unsigned char **GradientMagnitude;
unsigned short *ContiguousGradientNormal;
unsigned char *ContiguousGradientMagnitude;
int NumberOfGradientSlices;
vtkDirectionEncoder *DirectionEncoder;
vtkEncodedGradientShader *GradientShader;
vtkFiniteDifferenceGradientEstimator *GradientEstimator;
unsigned short DiffuseShadingTable [4][65536*3];
unsigned short SpecularShadingTable[4][65536*3];
int ShadingRequired;
int GradientOpacityRequired;
vtkDataArray *CurrentScalars;
vtkDataArray *PreviousScalars;
vtkRenderWindow *RenderWindow;
vtkVolume *Volume;
int ClipRayAgainstVolume( float rayStart[3],
float rayEnd[3],
float rayDirection[3],
double bounds[6] );
int UpdateColorTable( vtkVolume *vol );
int UpdateGradients( vtkVolume *vol );
int UpdateShadingTable( vtkRenderer *ren,
vtkVolume *vol );
void UpdateCroppingRegions();
void ComputeGradients( vtkVolume *vol );
int ClipRayAgainstClippingPlanes( float rayStart[3],
float rayEnd[3],
int numClippingPlanes,
float *clippingPlanes );
unsigned int FixedPointCroppingRegionPlanes[6];
unsigned int CroppingRegionMask[27];
// Get the ZBuffer value corresponding to location (x,y) where (x,y)
// are indexing into the ImageInUse image. This must be converted to
// the zbuffer image coordinates. Nearest neighbor value is returned.
float GetZBufferValue( int x, int y );
vtkFixedPointVolumeRayCastMIPHelper *MIPHelper;
vtkFixedPointVolumeRayCastCompositeHelper *CompositeHelper;
vtkFixedPointVolumeRayCastCompositeGOHelper *CompositeGOHelper;
vtkFixedPointVolumeRayCastCompositeShadeHelper *CompositeShadeHelper;
vtkFixedPointVolumeRayCastCompositeGOShadeHelper *CompositeGOShadeHelper;
// Some variables used for ray computation
float ViewToVoxelsArray[16];
float WorldToVoxelsArray[16];
float VoxelsToWorldArray[16];
double CroppingBounds[6];
int NumTransformedClippingPlanes;
float *TransformedClippingPlanes;
double SavedSpacing[3];
// Min Max structure used to do space leaping
unsigned short *MinMaxVolume;
int MinMaxVolumeSize[4];
vtkImageData *SavedMinMaxInput;
vtkImageData *MinMaxVolumeCache;
vtkVolumeRayCastSpaceLeapingImageFilter * SpaceLeapFilter;
void UpdateMinMaxVolume( vtkVolume *vol );
void FillInMaxGradientMagnitudes( int fullDim[3],
int smallDim[3] );
float FinalColorWindow;
float FinalColorLevel;
int FlipMIPComparison;
void ApplyFinalColorWindowLevel();
private:
vtkFixedPointVolumeRayCastMapper(const vtkFixedPointVolumeRayCastMapper&); // Not implemented.
void operator=(const vtkFixedPointVolumeRayCastMapper&); // Not implemented.
};
inline unsigned int vtkFixedPointVolumeRayCastMapper::ToFixedPointPosition( float val )
{
return static_cast<unsigned int>(val * VTKKW_FP_SCALE + 0.5);
}
inline void vtkFixedPointVolumeRayCastMapper::ToFixedPointPosition( float in[3], unsigned int out[3] )
{
out[0] = static_cast<unsigned int>(in[0] * VTKKW_FP_SCALE + 0.5);
out[1] = static_cast<unsigned int>(in[1] * VTKKW_FP_SCALE + 0.5);
out[2] = static_cast<unsigned int>(in[2] * VTKKW_FP_SCALE + 0.5);
}
inline unsigned int vtkFixedPointVolumeRayCastMapper::ToFixedPointDirection( float dir )
{
return ((dir<0.0)?
(static_cast<unsigned int>(-dir * VTKKW_FP_SCALE + 0.5)):
(0x80000000+static_cast<unsigned int>(dir*VTKKW_FP_SCALE + 0.5)));
}
inline void vtkFixedPointVolumeRayCastMapper::ToFixedPointDirection( float in[3], unsigned int out[3] )
{
out[0] = ((in[0]<0.0)?
(static_cast<unsigned int>(-in[0] * VTKKW_FP_SCALE + 0.5)):
(0x80000000+
static_cast<unsigned int>(in[0]*VTKKW_FP_SCALE + 0.5)));
out[1] = ((in[1]<0.0)?
(static_cast<unsigned int>(-in[1] * VTKKW_FP_SCALE + 0.5)):
(0x80000000+
static_cast<unsigned int>(in[1]*VTKKW_FP_SCALE + 0.5)));
out[2] = ((in[2]<0.0)?
(static_cast<unsigned int>(-in[2] * VTKKW_FP_SCALE + 0.5)):
(0x80000000+
static_cast<unsigned int>(in[2]*VTKKW_FP_SCALE + 0.5)));
}
inline void vtkFixedPointVolumeRayCastMapper::FixedPointIncrement( unsigned int position[3], unsigned int increment[3] )
{
if ( increment[0]&0x80000000 )
{
position[0] += (increment[0]&0x7fffffff);
}
else
{
position[0] -= increment[0];
}
if ( increment[1]&0x80000000 )
{
position[1] += (increment[1]&0x7fffffff);
}
else
{
position[1] -= increment[1];
}
if ( increment[2]&0x80000000 )
{
position[2] += (increment[2]&0x7fffffff);
}
else
{
position[2] -= increment[2];
}
}
inline void vtkFixedPointVolumeRayCastMapper::GetFloatTripleFromPointer( float v[3], float *ptr )
{
v[0] = *(ptr);
v[1] = *(ptr+1);
v[2] = *(ptr+2);
}
inline void vtkFixedPointVolumeRayCastMapper::GetUIntTripleFromPointer( unsigned int v[3], unsigned int *ptr )
{
v[0] = *(ptr);
v[1] = *(ptr+1);
v[2] = *(ptr+2);
}
inline void vtkFixedPointVolumeRayCastMapper::ShiftVectorDown( unsigned int in[3],
unsigned int out[3] )
{
out[0] = in[0] >> VTKKW_FP_SHIFT;
out[1] = in[1] >> VTKKW_FP_SHIFT;
out[2] = in[2] >> VTKKW_FP_SHIFT;
}
inline int vtkFixedPointVolumeRayCastMapper::CheckMinMaxVolumeFlag( unsigned int mmpos[3], int c )
{
unsigned int offset =
static_cast<unsigned int>(this->MinMaxVolumeSize[3]) *
( mmpos[2]*static_cast<unsigned int>(
this->MinMaxVolumeSize[0]*this->MinMaxVolumeSize[1]) +
mmpos[1]*static_cast<unsigned int>(this->MinMaxVolumeSize[0]) +
mmpos[0] ) + static_cast<unsigned int>(c);
return ((*(this->MinMaxVolume + 3*offset + 2))&0x00ff);
}
inline int vtkFixedPointVolumeRayCastMapper::CheckMIPMinMaxVolumeFlag( unsigned int mmpos[3], int c,
unsigned short maxIdx, int flip )
{
unsigned int offset =
static_cast<unsigned int>(this->MinMaxVolumeSize[3]) *
( mmpos[2]*static_cast<unsigned int>(
this->MinMaxVolumeSize[0]*this->MinMaxVolumeSize[1]) +
mmpos[1]*static_cast<unsigned int>(this->MinMaxVolumeSize[0]) +
mmpos[0] ) + static_cast<unsigned int>(c);
if ( (*(this->MinMaxVolume + 3*offset + 2)&0x00ff) )
{
if (flip)
{
return ( *(this->MinMaxVolume + 3*offset) < maxIdx );
}
else
{
return ( *(this->MinMaxVolume + 3*offset + 1) > maxIdx );
}
}
else
{
return 0;
}
}
inline void vtkFixedPointVolumeRayCastMapper::LookupColorUC( unsigned short *colorTable,
unsigned short *scalarOpacityTable,
unsigned short index,
unsigned char color[4] )
{
unsigned short alpha = scalarOpacityTable[index];
color[0] = static_cast<unsigned char>
((colorTable[3*index ]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[1] = static_cast<unsigned char>
((colorTable[3*index+1]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[2] = static_cast<unsigned char>
((colorTable[3*index+2]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[3] = static_cast<unsigned char>(alpha>>(VTKKW_FP_SHIFT - 8));
}
inline void vtkFixedPointVolumeRayCastMapper::LookupDependentColorUC( unsigned short *colorTable,
unsigned short *scalarOpacityTable,
unsigned short index[4],
int components,
unsigned char color[4] )
{
unsigned short alpha;
switch ( components )
{
case 2:
alpha = scalarOpacityTable[index[1]];
color[0] = static_cast<unsigned char>
((colorTable[3*index[0] ]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[1] = static_cast<unsigned char>
((colorTable[3*index[0]+1]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[2] = static_cast<unsigned char>
((colorTable[3*index[0]+2]*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
color[3] = static_cast<unsigned char>(alpha>>(VTKKW_FP_SHIFT - 8));
break;
case 4:
alpha = scalarOpacityTable[index[3]];
color[0] = static_cast<unsigned char>((index[0]*alpha + 0x7fff)>>VTKKW_FP_SHIFT );
color[1] = static_cast<unsigned char>((index[1]*alpha + 0x7fff)>>VTKKW_FP_SHIFT );
color[2] = static_cast<unsigned char>((index[2]*alpha + 0x7fff)>>VTKKW_FP_SHIFT );
color[3] = static_cast<unsigned char>(alpha>>(VTKKW_FP_SHIFT - 8));
break;
}
}
inline void vtkFixedPointVolumeRayCastMapper::LookupAndCombineIndependentColorsUC( unsigned short *colorTable[4],
unsigned short *scalarOpacityTable[4],
unsigned short index[4],
float weights[4],
int components,
unsigned char color[4] )
{
unsigned int tmp[4] = {0,0,0,0};
for ( int i = 0; i < components; i++ )
{
unsigned short alpha = static_cast<unsigned short>(static_cast<float>(scalarOpacityTable[i][index[i]])*weights[i]);
tmp[0] += static_cast<unsigned char>(((colorTable[i][3*index[i] ])*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
tmp[1] += static_cast<unsigned char>(((colorTable[i][3*index[i]+1])*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
tmp[2] += static_cast<unsigned char>(((colorTable[i][3*index[i]+2])*alpha + 0x7fff)>>(2*VTKKW_FP_SHIFT - 8));
tmp[3] += static_cast<unsigned char>(alpha>>(VTKKW_FP_SHIFT - 8));
}
color[0] = static_cast<unsigned char>((tmp[0]>255)?(255):(tmp[0]));
color[1] = static_cast<unsigned char>((tmp[1]>255)?(255):(tmp[1]));
color[2] = static_cast<unsigned char>((tmp[2]>255)?(255):(tmp[2]));
color[3] = static_cast<unsigned char>((tmp[3]>255)?(255):(tmp[3]));
}
inline int vtkFixedPointVolumeRayCastMapper::CheckIfCropped( unsigned int pos[3] )
{
int idx;
if ( pos[2] < this->FixedPointCroppingRegionPlanes[4] )
{
idx = 0;
}
else if ( pos[2] > this->FixedPointCroppingRegionPlanes[5] )
{
idx = 18;
}
else
{
idx = 9;
}
if ( pos[1] >= this->FixedPointCroppingRegionPlanes[2] )
{
if ( pos[1] > this->FixedPointCroppingRegionPlanes[3] )
{
idx += 6;
}
else
{
idx += 3;
}
}
if ( pos[0] >= this->FixedPointCroppingRegionPlanes[0] )
{
if ( pos[0] > this->FixedPointCroppingRegionPlanes[1] )
{
idx += 2;
}
else
{
idx += 1;
}
}
return !(static_cast<unsigned int>(this->CroppingRegionFlags)
&this->CroppingRegionMask[idx]);
}
#endif
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