void SoXipDicomExaminer::GLRender( SoGLRenderAction* action )
{
if (mViewAll)
{
SoXipDataImage* xipImage = ((SoXipSFDataImage *)mImage->getField(SbName("image")))->getValue();
if( !xipImage )
return ;
SbXipImage* image = xipImage->get();
if( image )
adjustCamera( action, image->getModelMatrix() );
// Store the information of the current displayed image
mImageModelMatrix = image->getModelMatrix();
mViewAll = FALSE;
}
if( mViewBoundingBox )
{
adjustCamera( action, boundingBox.getValue() );
mViewBoundingBox = false;
}
// Set the Dicom Element
setElement( action );
mImageSwitch->enableNotify( FALSE );
((SoSFInt32 *)mImageSwitch->getField(SbName("whichChild")))->setValue( drawImage.getValue() ? 0 : -1 );
mImageSwitch->enableNotify( TRUE );
SoXipKit::GLRender( action );
}
void SoXipDicomExaminer::updateCamera()
{
SoXipDataImage* xipImage = ((SoXipSFDataImage *)mImage->getField(SbName("image")))->getValue();
if( !xipImage )
return ;
SbXipImage* image = xipImage->get();
if( image )
{
SbVec3f newImagePos = image->getModelMatrix()[3];
SbVec3f oldImagePos = mImageModelMatrix[3];
SbVec3f cameraTranslation = (newImagePos - oldImagePos);
getCamera()->position.setValue( getCamera()->position.getValue() + cameraTranslation );
mImageModelMatrix = image->getModelMatrix();
SbVec3f t, s, normal;
SbRotation r, so;
mImageModelMatrix.getTransform(t, r, s, so);
normal = SbVec3f(mImageModelMatrix[2][0], mImageModelMatrix[2][1], mImageModelMatrix[2][2]);
normal.normalize();
SbPlane plane ( normal, t );
planeSlice.setValue ( plane ) ;
}
}
void SoVolumeMetrics::calculateVolumeMetris()
{
SoXipDataImage* maskData = inputVolume.getValue();
if (!maskData || !maskData->get())
{
SoDebugError::postInfo(__FILE__, "input volume data is NULL");
return;
}
SbXipImage* mask = maskData->get();
SbMatrix matMask = mask->getModelMatrix();
SbXipImageDimensions maskDimension = mask->getDimStored();
//decompose the model matrix
SbVec3f colVector, rowVector, norVector, volPosition;
colVector[0] = matMask[0][0];
colVector[1] = matMask[0][1];
colVector[2] = matMask[0][2];
rowVector[0] = matMask[1][0];
rowVector[1] = matMask[1][1];
rowVector[2] = matMask[1][2];
norVector[0] = matMask[2][0];
norVector[1] = matMask[2][1];
norVector[2] = matMask[2][2];
volPosition[0] = matMask[3][0];
volPosition[1] = matMask[3][1];
volPosition[2] = matMask[3][2];
float valSpacing[3];
valSpacing[0] = colVector.length() / (float)maskDimension[0];
valSpacing[1] = rowVector.length() / (float)maskDimension[1];
valSpacing[2] = norVector.length() / (float)maskDimension[2];
double volumeFactor = 0.001*valSpacing[0]*valSpacing[1]*valSpacing[2];
unsigned long volume=0, recist=0, who=0;
int nSize = maskDimension[0] * maskDimension[1];
unsigned char* pMask = (unsigned char*)mask->refBufferPtr();
for (int k = 0; k < maskDimension[2]; k++) {
unsigned char* pSlice = pMask + k * nSize;
for (int j = 0; j < nSize; j++) {
if (pSlice[j] != 0)
volume++;
}
}
_volume = (double)volume * volumeFactor;
mask->unrefBufferPtr();
}
void SoXipImageAttributes::evaluate()
{
SoXipDataImage *imgData = image.getValue();
if (imgData)
{
SbXipImage *img = imgData->get();
if (img)
{
SO_ENGINE_OUTPUT(modelMatrix, SoSFMatrix, setValue(img->getModelMatrix()));
SO_ENGINE_OUTPUT(bitsStored, SoSFShort, setValue(img->getBitsStored()));
SO_ENGINE_OUTPUT(width, SoSFShort, setValue(img->getDimStored()[0]));
SO_ENGINE_OUTPUT(height, SoSFShort, setValue(img->getDimStored()[1]));
SO_ENGINE_OUTPUT(depth, SoSFShort, setValue(img->getDimStored()[2]));
SbMatrix modelMat = img->getModelMatrix();
SbVec3f t, s;
SbRotation r, so;
modelMat.getTransform(t, r, s, so);
modelMat.multVecMatrix(SbVec3f(0.5, 0.5, 0.5), t);
// scale MPR model matrix always to max. individual dimension by default
float maxScale = s[0] > s[1] ? s[0] : s[1] > s[2] ? s[1] : s[2];
// modelMat.setTransform(t, r, SbVec3f(maxScale, maxScale, maxScale), so);
// when using get/setTransform, the rotation is derived from normal vector
// but for gantry tilt, we need to compute normal from row and column vector
SbVec3f rot[3];
rot[0] = SbVec3f(modelMat[0][0], modelMat[0][1], modelMat[0][2]);
rot[1] = SbVec3f(modelMat[1][0], modelMat[1][1], modelMat[1][2]);
rot[2] = rot[0].cross(rot[1]);
rot[0].normalize();
rot[1].normalize();
rot[2].normalize();
rot[0] *= maxScale;
rot[1] *= maxScale;
rot[2] *= maxScale;
modelMat = SbMatrix(
rot[0][0], rot[0][1], rot[0][2], 0,
rot[1][0], rot[1][1], rot[1][2], 0,
rot[2][0], rot[2][1], rot[2][2], 0,
t[0], t[1], t[2], 1);
// update engine outputs
SbMatrix tmp = SbMatrix::identity();
// flip default viewing direction
tmp.setRotate(SbRotation(SbVec3f(1, 0, 0), M_PI));
SbMatrix defOrient = tmp * modelMat;
// adjust so plane falls onto original plane
defOrient.getTransform(t, r, s, so);
SbVec3f object;
modelMat = img->getModelMatrix();
modelMat.inverse().multVecMatrix(t, object);
object[0] = int(object[0] * img->getDimStored()[0] + 0.5);
object[1] = int(object[1] * img->getDimStored()[1] + 0.5);
object[2] = int(object[2] * img->getDimStored()[2] + 0.5);
object[0] /= img->getDimStored()[0];
object[1] /= img->getDimStored()[1];
object[2] /= img->getDimStored()[2];
modelMat.multVecMatrix(object, t);
defOrient.setTransform(t, r, s, so);
SO_ENGINE_OUTPUT(defaultOrientation, SoSFMatrix, setValue(defOrient));
SbMatrix ortho1, ortho2, ortho3;
int which = XipGeomUtils::orthoOrientations(defOrient, ortho1, ortho2, ortho3);
SO_ENGINE_OUTPUT(orthoScanOrientation, SoSFShort, setValue(which));
SO_ENGINE_OUTPUT(orthoOrientation1, SoSFMatrix, setValue(ortho1));
SO_ENGINE_OUTPUT(orthoOrientation2, SoSFMatrix, setValue(ortho2));
SO_ENGINE_OUTPUT(orthoOrientation3, SoSFMatrix, setValue(ortho3));
defOrient.getTransform(t, r, s, so);
SO_ENGINE_OUTPUT(defaultCenter, SoSFVec3f, setValue(t));
return;
}
}
SO_ENGINE_OUTPUT(modelMatrix, SoSFMatrix, setValue(SbMatrix::identity()));
SO_ENGINE_OUTPUT(bitsStored, SoSFShort, setValue(0));
SO_ENGINE_OUTPUT(width, SoSFShort, setValue(0));
SO_ENGINE_OUTPUT(height, SoSFShort, setValue(0));
SO_ENGINE_OUTPUT(depth, SoSFShort, setValue(0));
SbMatrix rot1, rot2;
SO_ENGINE_OUTPUT(defaultOrientation, SoSFMatrix, setValue(SbMatrix::identity()));
SO_ENGINE_OUTPUT(orthoScanOrientation, SoSFShort, setValue(0));
SO_ENGINE_OUTPUT(orthoOrientation1, SoSFMatrix, setValue(SbMatrix::identity()));
rot1.setRotate(SbRotation(SbVec3f(1, 0, 0), -M_PI / 2.f));
SO_ENGINE_OUTPUT(orthoOrientation2, SoSFMatrix, setValue(rot1));
rot2.setRotate(SbRotation(SbVec3f(0, 1, 0), M_PI / 2.f));
SO_ENGINE_OUTPUT(orthoOrientation3, SoSFMatrix, setValue(rot2 * rot1));
SO_ENGINE_OUTPUT(defaultCenter, SoSFVec3f, setValue(SbVec3f(0.5, 0.5, 0.5)));
}
void
SoXipComposeVec6::evaluate()
{
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, setNum(6));
// intersection of plane and volume
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(0, xmin.getValue()) );
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(1, xmax.getValue()) );
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(2, ymin.getValue()) );
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(3, ymax.getValue()) );
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(4, zmin.getValue()) );
SO_ENGINE_OUTPUT(outVOI, SoMFInt32, set1Value(5, zmax.getValue()) );
// Reset outputs
SO_ENGINE_OUTPUT( numSlices, SoSFShort, setValue(0) );
SO_ENGINE_OUTPUT( output, SoXipSFDataImage, setValue(0) );
SoXipDataImage* imageData = image.getValue();
if( mImageData != imageData )
{
mImageData = image.getValue();
// Reset previous outputs
mOutputs.setNum(0);
if( mImageData )
{
SbXipImage* image = mImageData->get();
if( !image )
return ;
// Initialize outputs
unsigned int numSlices = image->getDimStored()[2];
mOutputs.setNum( numSlices );
for( unsigned int i = 0; i < numSlices; ++ i )
mOutputs.set1Value( i, 0 );
}
}
if( imageData )
{
SbXipImage* image = mImageData->get();
if( !image )
return ;
SbXipImageDimensions dimensions = image->getDimStored();
SbXipImageDimensions sliceDimensions = dimensions;
sliceDimensions[2] = 1;
int sliceIndex = this->sliceIndex.getValue();
if( sliceIndex < 0 || sliceIndex >= dimensions[2] )
return ;
if( mOutputs[sliceIndex] == 0 )
{
// Compute the model matrix of the selected frame
SbMatrix sliceModelMatrix = image->getModelMatrix();
sliceModelMatrix[2][0] /= dimensions[2];
sliceModelMatrix[2][1] /= dimensions[2];
sliceModelMatrix[2][2] /= dimensions[2];
sliceModelMatrix[3][0] += sliceIndex * sliceModelMatrix[2][0];
sliceModelMatrix[3][1] += sliceIndex * sliceModelMatrix[2][1];
sliceModelMatrix[3][2] += sliceIndex * sliceModelMatrix[2][2];
// Pointer to the selected slice
char* imagePtr = (char *) image->refBufferPtr();
unsigned int cellSize;
switch( image->getType() )
{
case SbXipImage::UNSIGNED_BYTE: cellSize = sizeof(unsigned char); break ;
case SbXipImage::BYTE: cellSize = sizeof(char); break ;
case SbXipImage::UNSIGNED_SHORT: cellSize = sizeof(unsigned short); break ;
case SbXipImage::SHORT: cellSize = sizeof(short); break ;
case SbXipImage::UNSIGNED_INT: cellSize = sizeof(unsigned int); break ;
case SbXipImage::INT: cellSize = sizeof(int); break ;
case SbXipImage::FLOAT: cellSize = sizeof(float); break ;
case SbXipImage::DOUBLE: cellSize = sizeof(double); break ;
}
void* slicePtr = imagePtr + cellSize * image->getComponents() * dimensions[0] * dimensions[1] * sliceIndex;
SbXipImage* slice = new SbXipImage( sliceDimensions, image->getType(), image->getBitsStored(), slicePtr,
image->getComponents(), image->getComponentType(), image->getComponentLayoutType(), sliceModelMatrix,
image->getLineAlignment() );
image->unrefBufferPtr();
SoXipDataImage* output = new SoXipDataImage();
output->ref();
output->set( slice );
output->addRef( imageData );
mOutputs.set1Value( sliceIndex, output );
}
SO_ENGINE_OUTPUT( output, SoXipSFDataImage, setValue(mOutputs[sliceIndex]) );
}
}