Libs/Optimize/Domain/ImageDomain.h
Namespaces
| Name |
|---|
| shapeworks User usage reporting (telemetry) |
Classes
| Name | |
|---|---|
| class | shapeworks::ImageDomain |
Source code
#pragma once
#include <itkImage.h>
#include <itkImageRegionConstIteratorWithIndex.h>
#include <itkImageToVTKImageFilter.h>
#include <itkZeroCrossingImageFilter.h>
#include <vtkContourFilter.h>
#include <vtkMassProperties.h>
#include <chrono>
#include <fstream>
#include "ParticleRegionDomain.h"
// we have to undef foreach here because both Qt and OpenVDB define foreach
#undef foreach
#ifndef Q_MOC_RUN
#include <openvdb/math/Math.h>
#include <openvdb/math/Transform.h>
#include <openvdb/openvdb.h>
#include <openvdb/tools/GridOperators.h>
#include <openvdb/tools/Interpolation.h>
#include <openvdb/tools/SignedFloodFill.h>
#endif
namespace shapeworks {
template <class T>
class ImageDomain : public ParticleRegionDomain {
public:
using Pointer = std::shared_ptr<ImageDomain>;
using ImageType = itk::Image<T, DIMENSION>;
using PointType = ParticleRegionDomain::PointType;
void SetImage(ImageType* I, double narrow_band) {
this->m_FixedDomain = false;
// this->Modified();
openvdb::initialize(); // It is safe to initialize multiple times.
// Set a large background value, so that we quickly catch particles outside or on the edge the narrow band.
// (Downside: its more difficult to display the correct location of the point of failure.)
m_VDBImage = openvdb::FloatGrid::create(1e8);
m_VDBImage->setGridClass(openvdb::GRID_LEVEL_SET);
auto vdbAccessor = m_VDBImage->getAccessor();
// Save properties of the Image needed for the optimizer
m_Size = I->GetRequestedRegion().GetSize();
m_Spacing = I->GetSpacing();
m_Origin = I->GetOrigin();
m_Index = I->GetRequestedRegion().GetIndex();
// Transformation from index space to world space
openvdb::math::Mat4f mat;
mat.setIdentity();
mat.postScale(openvdb::Vec3f(m_Spacing[0], m_Spacing[1], m_Spacing[2]));
mat.postTranslate(openvdb::Vec3f(m_Origin[0], m_Origin[1], m_Origin[2]));
const auto xform = openvdb::math::Transform::createLinearTransform(mat);
m_VDBImage->setTransform(xform);
itk::ImageRegionIterator<ImageType> it(I, I->GetRequestedRegion());
it.GoToBegin();
while (!it.IsAtEnd()) {
const auto idx = it.GetIndex();
const auto pixel = it.Get();
if (abs(pixel) > narrow_band) {
++it;
continue;
}
const auto coord = openvdb::Coord(idx[0], idx[1], idx[2]);
vdbAccessor.setValue(coord, pixel);
++it;
}
typename ImageType::PointType l0;
I->TransformIndexToPhysicalPoint(m_Index, l0);
for (unsigned int i = 0; i < DIMENSION; i++) m_Index[i] += m_Size[i] - 1;
typename ImageType::PointType u0;
I->TransformIndexToPhysicalPoint(m_Index, u0);
// Cast points to higher precision if needed. Parent class uses doubles
// because they are compared directly with points in the particle system,
// which are always double precision.
PointType l;
PointType u;
for (unsigned int i = 0; i < DIMENSION; i++) {
l[i] = static_cast<double>(l0[i]);
u[i] = static_cast<double>(u0[i]);
}
this->SetLowerBound(l);
this->SetUpperBound(u);
// Precompute and save values that are used in parts of the optimizer
this->SetupImageForCrossingPointUpdate(I); // this->UpdateZeroCrossingPoint(I);
this->UpdateSurfaceArea(I);
}
inline double GetSurfaceArea() const override {
throw std::runtime_error("Surface area is not computed currently.");
return m_SurfaceArea;
}
inline PointType GetOrigin() const { return m_Origin; }
inline typename ImageType::SizeType GetSize() const { return m_Size; }
inline typename ImageType::SpacingType GetSpacing() const { return m_Spacing; }
inline typename ImageType::RegionType::IndexType GetIndex() const { return m_Index; }
inline PointType GetValidLocationNear(PointType p) const override {
// todo why is this function ignoring the argument? Also see Optimize::AddSinglePoint
return m_ZeroCrossingPoint;
}
inline T Sample(const PointType& p) const {
if (this->IsInsideBuffer(p)) {
const auto coord = this->ToVDBCoord(p);
return openvdb::tools::BoxSampler::sample(m_VDBImage->tree(), coord);
} else {
std::ostringstream message;
message << "Domain " << m_DomainID << ": " << m_DomainName << " : Distance transform queried for a Point, " << p
<< ", outside the given image domain. Consider increasing the padding in grooming or the narrow band optimization parameter";
throw std::runtime_error(message.str());
}
}
inline double GetMaxDiameter() const override {
double bestRadius = 0;
double maxdim = 0;
for (unsigned int i = 0; i < ImageType::ImageDimension; i++) {
if (GetSize()[i] > maxdim) {
maxdim = GetSize()[i];
bestRadius = maxdim * GetSpacing()[i];
}
}
return bestRadius;
}
void DeleteImages() override { m_VDBImage = 0; }
// Updates zero crossing points. Raster scans candidate zero crossing points, and finds one that does not violate any
// constraints.
void UpdateZeroCrossingPoint() override {
for (size_t i = 0; i < m_possible_zero_crossings.size(); i++) {
this->m_ZeroCrossingPoint = m_possible_zero_crossings[i];
if (!this->GetConstraints()->isAnyViolated(this->m_ZeroCrossingPoint)) {
// std::cout << "Chosen initial point " << this->m_ZeroCrossingPoint << std::endl;
break;
}
}
if (this->GetConstraints()->isAnyViolated(this->m_ZeroCrossingPoint)) {
std::cerr << "A particle initialization violates at least one constraint. Make sure at least one point satisfies "
"all constraints"
<< std::endl;
}
}
protected:
openvdb::FloatGrid::Ptr GetVDBImage() const { return m_VDBImage; }
ImageDomain() {}
virtual ~ImageDomain(){};
void PrintSelf(std::ostream& os, itk::Indent indent) const {
ParticleRegionDomain::PrintSelf(os, indent);
os << indent << "VDB Active Voxels = " << m_VDBImage->activeVoxelCount() << std::endl;
}
inline openvdb::math::Transform::Ptr transform() const { return this->m_VDBImage->transformPtr(); }
// Converts a coordinate from an ITK Image point in world space to the corresponding
// coordinate in OpenVDB Index space. Raises an exception if the narrow band is not
// sufficiently large to sample the point.
inline openvdb::Vec3R ToVDBCoord(const PointType& p) const {
const auto worldCoord = openvdb::Vec3R(p[0], p[1], p[2]);
const auto idxCoord = this->transform()->worldToIndex(worldCoord);
// Make sure the coordinate is part of the narrow band
if (m_VDBImage->tree().isValueOff(
openvdb::Coord::round(idxCoord))) { // `isValueOff` requires an integer coordinate
// If multiple threads crash here at the same time, the error message displayed is just "terminate called
// recursively", which isn't helpful. So we std::cerr the error to make sure its printed to the console.
std::cerr << "Sampled point outside the narrow band: " << p << std::endl;
std::ostringstream message;
message << "Attempt to sample at a point outside the narrow band: " << p
<< ". Consider increasing the narrow band";
throw std::runtime_error(message.str());
}
return idxCoord;
}
private:
openvdb::FloatGrid::Ptr m_VDBImage;
typename ImageType::SizeType m_Size;
typename ImageType::SpacingType m_Spacing;
PointType m_Origin;
PointType m_ZeroCrossingPoint;
typename ImageType::RegionType::IndexType m_Index; // Index defining the corner of the region
double m_SurfaceArea;
std::vector<PointType> m_possible_zero_crossings;
// Computes possible zero crossing points. Later on, one can find the ones that do not violate constraints.
void SetupImageForCrossingPointUpdate(ImageType* I) {
typename itk::ZeroCrossingImageFilter<ImageType, ImageType>::Pointer zc =
itk::ZeroCrossingImageFilter<ImageType, ImageType>::New();
zc->SetInput(I);
zc->Update();
typename itk::ImageRegionConstIteratorWithIndex<ImageType> zcIt(zc->GetOutput(),
zc->GetOutput()->GetRequestedRegion());
for (zcIt.GoToReverseBegin(); !zcIt.IsAtReverseEnd(); --zcIt) {
if (zcIt.Get() == 1.0) {
PointType pos;
I->TransformIndexToPhysicalPoint(zcIt.GetIndex(), pos);
this->m_ZeroCrossingPoint = pos;
m_possible_zero_crossings.push_back(pos);
}
}
}
void UpdateSurfaceArea(ImageType* I) {
// TODO: This code has been copied from Optimize.cpp. It does not work
/*
typename itk::ImageToVTKImageFilter < ImageType > ::Pointer itk2vtkConnector;
itk2vtkConnector = itk::ImageToVTKImageFilter < ImageType > ::New();
itk2vtkConnector->SetInput(I);
vtkSmartPointer < vtkContourFilter > ls = vtkSmartPointer < vtkContourFilter > ::New();
ls->SetInputData(itk2vtkConnector->GetOutput());
ls->SetValue(0, 0.0);
ls->Update();
vtkSmartPointer < vtkMassProperties > mp = vtkSmartPointer < vtkMassProperties > ::New();
mp->SetInputData(ls->GetOutput());
mp->Update();
m_SurfaceArea = mp->GetSurfaceArea();
*/
}
};
} // end namespace shapeworks
Updated on 2024-03-17 at 12:58:44 -0600