int ScaleEnergyFunction::GetDataCostReverseThreshold(int labelId, int nodeId, int penaltyCost)
{
CvPoint point = _mapping2D->GetMappedPoint(nodeId);
DoublePoint mappedPoint = _labelMapping->GetMappedPoint(labelId, point);
if(mappedPoint.x < 0 || mappedPoint.x > _inputSize.width - 1)
return penaltyCost;
if(mappedPoint.y < 0 || mappedPoint.y > _inputSize.height - 1)
return penaltyCost;
if(!IsSatisfiedBoundary(point.x, mappedPoint.x, _inputSize.width, _outputSize.width))
return penaltyCost;
if(!IsSatisfiedBoundary(point.y, mappedPoint.y, _inputSize.height, _outputSize.height))
return penaltyCost;
CvScalar saliency = GetInterpolatedValue(mappedPoint, _saliency);
double scale = _labelMapping->GetScale(labelId);
int scaleId = _labelMapping->GetScaleId(labelId);
//DisplayImage(_saliency, "saliency");
int value = saliency.val[0] + saliency.val[1] + saliency.val[2];
int threshold = 150 * 3;
if(value > threshold)
value = threshold + (value - threshold) * scale;
else
value = threshold - (threshold - value) * scale;
return value;
}
int ScaleEnergyFunction::GetDataCostReverseSaliency(int labelId, int nodeId, int penaltyCost)
{
CvPoint point = _mapping2D->GetMappedPoint(nodeId);
DoublePoint mappedPoint = _labelMapping->GetMappedPoint(labelId, point);
if(mappedPoint.x < 0 || mappedPoint.x > _inputSize.width - 1)
return penaltyCost;
if(mappedPoint.y < 0 || mappedPoint.y > _inputSize.height - 1)
return penaltyCost;
if(!IsSatisfiedBoundary(point.x, mappedPoint.x, _inputSize.width, _outputSize.width))
return penaltyCost;
if(!IsSatisfiedBoundary(point.y, mappedPoint.y, _inputSize.height, _outputSize.height))
return penaltyCost;
CvScalar saliency = GetInterpolatedValue(mappedPoint, _saliency);
double scale = _labelMapping->GetScale(labelId);
int scaleId = _labelMapping->GetScaleId(labelId);
//DisplayImage(_saliency, "saliency");
if(scaleId == 0)
return saliency.val[0] + saliency.val[1] + saliency.val[2];
else
return _maxSaliency - (saliency.val[0] + saliency.val[1] + saliency.val[2]);
}
int ScaleEnergyFunction::GetDataCostAreaCost(int labelId, int nodeId, int penaltyCost)
{
CvPoint point = _mapping2D->GetMappedPoint(nodeId);
DoublePoint mappedPoint = _labelMapping->GetMappedPoint(labelId, point);
if(mappedPoint.x < 0 || mappedPoint.x > _inputSize.width - 1)
return penaltyCost;
if(mappedPoint.y < 0 || mappedPoint.y > _inputSize.height - 1)
return penaltyCost;
if(!IsSatisfiedBoundary(point.x, mappedPoint.x, _inputSize.width, _outputSize.width))
return penaltyCost * 2;
if(!IsSatisfiedBoundary(point.y, mappedPoint.y, _inputSize.height, _outputSize.height))
return penaltyCost * 2;
CvScalar saliency = GetInterpolatedValue(mappedPoint, _saliency);
int scaleId = _labelMapping->GetScaleId(labelId);
double scaleX = _labelMapping->GetScaleX(scaleId);
double scaleY = _labelMapping->GetScaleY(scaleId);
int distortionCost = GetDistortionCost(point, _image, labelId, 3, scaleX, scaleY);
int areaCost = 255 * scaleX * scaleY;
int energy = (_distortionWeight * distortionCost + _areaWeight * areaCost) / _smoothWeight;
//printf("investigate: %i %i \n", nodeId, labelId);
return energy;
// return (saliency.val[0] + saliency.val[1] + saliency.val[2]) * scale;
}
int ScaleEnergyFunction::GetDistortionCost(CvPoint point, IplImage* image, int label, int patch_size, double scaleX, double scaleY)
{
vector<CvScalar>* scaled_points = new vector<CvScalar>(patch_size * patch_size);
for(int i = 0; i < patch_size; i++)
for(int j = 0; j < patch_size; j++)
{
DoublePoint currPoint = _labelMapping->GetMappedPoint(label, cvPoint(point.x + i, point.y + j));
(*scaled_points)[i * patch_size + j] = GetInterpolatedValue(currPoint, image);
}
int scaled_patch_size = patch_size / scaleX * scaleY;
DoublePoint mappedPoint = _labelMapping->GetMappedPoint(label, point);
int x = (int)mappedPoint.x;
int y = (int)mappedPoint.y;
int minDistortion = 10000000;
for(int i = x; i < x + scaled_patch_size - patch_size + 1; i++)
for(int j = y; j < y + scaled_patch_size - patch_size + 1; j++)
{
int distortion = GetDistortionCostPatch(scaled_points, cvPoint(i,j), image, patch_size);
if(distortion < minDistortion)
minDistortion = distortion;
}
//scaled_points->clear();
delete scaled_points;
return minDistortion;
}
int ScaleEnergyFunction::GetSmoothCostPreventCrossingPatch(int labelId1, int labelId2, int nodeId1, int nodeId2, int penaltyCost, int threshold, int patchsize)
{
CvPoint point1 = _mapping2D->GetMappedPoint(nodeId1);
CvPoint point2 = _mapping2D->GetMappedPoint(nodeId2);
int energy = 0;
DoublePoint mappedPoint1 = _labelMapping->GetMappedPoint(labelId1, point1);
DoublePoint mappedPoint2 = _labelMapping->GetMappedPoint(labelId2, point2);
if(!IsInside(mappedPoint1, _inputSize) || !IsInside(mappedPoint2, _inputSize))
return penaltyCost;
int scaleId1 = _labelMapping->GetScaleId(labelId1);
int scaleId2 = _labelMapping->GetScaleId(labelId2);
if(scaleId1 != scaleId2)
{
CvScalar saliency1 = GetInterpolatedValue(mappedPoint1, _saliency);
CvScalar saliency2 = GetInterpolatedValue(mappedPoint2, _saliency);
if(saliency1.val[0] + saliency1.val[1] + saliency1.val[2] > threshold
&& saliency2.val[0] + saliency2.val[1] + saliency2.val[2] > threshold)
return penaltyCost;
}
DoublePoint mappedNeighbor1 = _labelMapping->GetMappedPoint(labelId1, point2);
DoublePoint mappedNeighbor2 = _labelMapping->GetMappedPoint(labelId2, point1);
if(!IsInside(mappedNeighbor1, _inputSize) || !IsInside(mappedNeighbor2, _inputSize))
return penaltyCost;
energy += GetPatchDifference(point2, point2, labelId1, labelId2, _image, _labelMapping, patchsize);
energy += GetPatchDifference(point1, point1, labelId1, labelId2, _image, _labelMapping, patchsize);
energy += GetPatchDifference(point2, point2, labelId1, labelId2, _gradient, _labelMapping, patchsize);
energy += GetPatchDifference(point1, point1, labelId1, labelId2, _gradient, _labelMapping, patchsize);
return energy;
}
void Fluid::Advect(
float timeStep,
const View2f& velocities,
const View<SampleType, 1>& u,
View<SampleType, 1>* uAdvected) const {
const int width = Width();
const int height = Height();
for (int y = 0; y < height; ++y) {
for (int x = 0; x < width; ++x) {
// Trace back in time by following the velocity field.
const Vector2 pos = Vector2(x, y) - timeStep * _gridScale * FlipY(GetValue(x, y, velocities));
const SampleType uNew = GetInterpolatedValue(pos, u);
SetValue(x, y, uNew, uAdvected);
}
}
}
// normal data cost with boundary constraint
int ScaleEnergyFunction::GetDataCostOrigin(int labelId, int nodeId, int penaltyCost)
{
CvPoint point = _mapping2D->GetMappedPoint(nodeId);
DoublePoint mappedPoint = _labelMapping->GetMappedPoint(labelId, point);
if(mappedPoint.x < 0 || mappedPoint.x > _inputSize.width - 1)
return penaltyCost;
if(mappedPoint.y < 0 || mappedPoint.y > _inputSize.height - 1)
return penaltyCost;
if(!IsSatisfiedBoundary(point.x, mappedPoint.x, _inputSize.width, _outputSize.width))
return penaltyCost;
if(!IsSatisfiedBoundary(point.y, mappedPoint.y, _inputSize.height, _outputSize.height))
return penaltyCost;
CvScalar saliency = GetInterpolatedValue(mappedPoint, _saliency);
return saliency.val[0] + saliency.val[1] + saliency.val[2];
}
