uLib/src/Vtk/HEP/MuonTomography/vtkVoxRaytracerRepresentation.cpp

/*//////////////////////////////////////////////////////////////////////////////
// CMT Cosmic Muon Tomography project //////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////

  Copyright (c) 2014, Universita' degli Studi di Padova, INFN sez. di Padova
  All rights reserved

  Authors: Andrea Rigoni Garola < andrea.rigoni@pd.infn.it >

  ------------------------------------------------------------------
  This library is free software;  you  can  redistribute  it  and/or
  modify it  under the  terms  of  the  GNU  Lesser  General  Public
  License as published  by  the  Free  Software  Foundation;  either
  version 3.0 of the License, or (at your option) any later version.

  This library is  distributed in  the hope that it will  be useful,
  but  WITHOUT ANY WARRANTY;  without  even  the implied warranty of
  MERCHANTABILITY  or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  Lesser General Public License for more details.

  You should have received a copy of  the GNU Lesser General  Public
  License along with this library.

//////////////////////////////////////////////////////////////////////////////*/

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include "Vtk/HEP/MuonTomography/vtkVoxRaytracerRepresentation.h"

#include "Math/VoxRaytracer.h"

// #include "Vtk/HEP/Detectors/vtkMuonEvent.h"
#include "Vtk/HEP/Detectors/vtkMuonScatter.h"

namespace uLib {
namespace Vtk {

////////////////////////////////////////////////////////////////////////////////
////// VOX RAYTRACER REPRESENTATION  ///////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////

vtkVoxRaytracerRepresentation::vtkVoxRaytracerRepresentation(Content &content)
    : m_Content(&content),
      m_Sphere1(vtkSphereSource::New()), m_Sphere2(vtkSphereSource::New()),
      m_Line1(vtkLineSource::New()), m_Line2(vtkLineSource::New()),
      m_Line3(vtkLineSource::New()), m_RayLine(vtkAppendPolyData::New()),
      m_RayLineActor(vtkActor::New()),
      m_RayRepresentation(vtkAppendPolyData::New()),
      m_RayRepresentationActor(vtkActor::New()),
      m_Transform(vtkTransform::New()),
      m_Asm(vtkAssembly::New()),
      m_HasMuon(false), m_HasPoca(false) {
  default_radius = content.GetImage()->GetSpacing()(0) / 4;
  m_Sphere1->SetRadius(default_radius);
  m_Sphere2->SetRadius(default_radius);
  m_SelectedElement = m_RayLine;

  this->SetSelectable(false);
  InstallPipe();
  
  if (m_Content && m_Content->GetImage()) {
      Object::connect(m_Content->GetImage(), &StructuredGrid::Updated, this, &vtkVoxRaytracerRepresentation::imageUpdate);
  }
}

vtkVoxRaytracerRepresentation::~vtkVoxRaytracerRepresentation() {
  m_RayLine->Delete();
  m_RayLineActor->Delete();
  m_RayRepresentationActor->Delete();
  m_Transform->Delete();
}

uLib::VoxRaytracer *vtkVoxRaytracerRepresentation::GetRaytracerAlgorithm() {
  return m_Content;
}

void vtkVoxRaytracerRepresentation::Update() {
   this->imageUpdate();
}

void vtkVoxRaytracerRepresentation::imageUpdate() {
   if (m_HasMuon) {
       if (m_HasPoca) {
           this->SetMuon(m_Muon, m_Poca);
       } else {
           this->SetMuon(m_Muon);
       }
   }
}

vtkPolyData *vtkVoxRaytracerRepresentation::GetPolyData() const {
  std::cout << "get Raytracer polydata\n";
  m_SelectedElement->Update();
  return m_SelectedElement->GetOutput();
}

void vtkVoxRaytracerRepresentation::SetRepresentationElements(
    vtkVoxRaytracerRepresentation::RepresentationElements el) {
  switch (el) {
  case Vtk::vtkVoxRaytracerRepresentation::RayElements:
    m_SelectedElement = m_RayLine;
    break;
  case Vtk::vtkVoxRaytracerRepresentation::VoxelsElements:
    m_SelectedElement = m_RayRepresentation;
    break;
  default:
    m_SelectedElement = m_RayLine;
    break;
  }
}

void vtkVoxRaytracerRepresentation::SetMuon(MuonScatter &muon) {
  m_Muon = muon;
  m_HasMuon = true;
  m_HasPoca = false;

  HPoint3f pt1, pt2, src;
  src = muon.LineIn().origin;
  m_Content->GetEntryPoint(muon.LineIn(), pt1);
  m_Sphere1->SetCenter(pt1(0), pt1(1), pt1(2));
  m_Line1->SetPoint1(src(0), src(1), src(2));
  m_Line1->SetPoint2(pt1(0), pt1(1), pt1(2));

  HLine3f line_out = muon.LineOut();
  src = line_out.origin;
  float *direction = line_out.direction.data();
  for (int i = 0; i < 3; ++i)
    direction[i] *= -1;
  m_Content->GetEntryPoint(line_out, pt2);
  m_Sphere2->SetCenter(pt2(0), pt2(1), pt2(2));
  m_Line2->SetPoint1(src(0), src(1), src(2));
  m_Line2->SetPoint2(pt2(0), pt2(1), pt2(2));

  m_Line3->SetPoint1(pt1(0), pt1(1), pt1(2));
  m_Line3->SetPoint2(pt2(0), pt2(1), pt2(2));

  vtkSmartPointer<vtkPoints> points = vtkSmartPointer<vtkPoints>::New();
  points->InsertNextPoint(pt1(0), pt1(1), pt1(2));
  points->InsertNextPoint(pt2(0), pt2(1), pt2(2));

  vtkSmartPointer<vtkCellArray> lines = vtkSmartPointer<vtkCellArray>::New();

  vtkSmartPointer<vtkLine> line = vtkSmartPointer<vtkLine>::New();
  line->GetPointIds()->SetId(0, 0);
  line->GetPointIds()->SetId(1, 1);
  lines->InsertNextCell(line);

  vtkSmartPointer<vtkPolyData> linesPolyData =
      vtkSmartPointer<vtkPolyData>::New();
  linesPolyData->SetPoints(points);
  linesPolyData->SetLines(lines);

  m_RayLine->RemoveAllInputs();
#if VTK_MAJOR_VERSION <= 5
  m_RayLine->AddInputConnection(linesPolyData->GetProducerPort());
#else
  m_RayLine->AddInputData(linesPolyData);
#endif
  m_RayLine->AddInputConnection(m_Line1->GetOutputPort());
  m_RayLine->AddInputConnection(m_Sphere1->GetOutputPort());
  m_RayLine->AddInputConnection(m_Line2->GetOutputPort());
  m_RayLine->AddInputConnection(m_Sphere2->GetOutputPort());

  vtkSmartPointer<vtkMatrix4x4> vmat = vtkSmartPointer<vtkMatrix4x4>::New();
  Matrix4f mat = m_Content->GetImage()->GetWorldMatrix();
  for (int i = 0; i < 4; ++i)
    for (int j = 0; j < 4; ++j)
      vmat->SetElement(i, j, mat(i, j));
  m_Transform->SetMatrix(vmat);

  this->SetRay(pt1, pt2);
}

void vtkVoxRaytracerRepresentation::SetMuon(MuonScatter &muon, HPoint3f poca) {
  m_Muon = muon;
  m_Poca = poca;
  m_HasMuon = true;
  m_HasPoca = true;

  HPoint3f pt1, pt2, src;
  src = muon.LineIn().origin;
  m_Content->GetEntryPoint(muon.LineIn(), pt1);
  m_Sphere1->SetCenter(pt1(0), pt1(1), pt1(2));
  m_Line1->SetPoint1(src(0), src(1), src(2));
  m_Line1->SetPoint2(pt1(0), pt1(1), pt1(2));

  HLine3f line_out = muon.LineOut();
  src = line_out.origin;
  float *direction = line_out.direction.data();
  for (int i = 0; i < 3; ++i)
    direction[i] *= -1;
  m_Content->GetEntryPoint(line_out, pt2);
  m_Sphere2->SetCenter(pt2(0), pt2(1), pt2(2));
  m_Line2->SetPoint1(src(0), src(1), src(2));
  m_Line2->SetPoint2(pt2(0), pt2(1), pt2(2));

  m_Line3->SetPoint1(pt1(0), pt1(1), pt1(2));
  m_Line3->SetPoint2(pt2(0), pt2(1), pt2(2));

  vtkSmartPointer<vtkPoints> points = vtkSmartPointer<vtkPoints>::New();
  points->InsertNextPoint(pt1(0), pt1(1), pt1(2));
  points->InsertNextPoint(poca(0), poca(1), poca(2));
  points->InsertNextPoint(pt2(0), pt2(1), pt2(2));

  vtkSmartPointer<vtkCellArray> lines = vtkSmartPointer<vtkCellArray>::New();
  for (unsigned int i = 0; i < 2; i++) {
    vtkSmartPointer<vtkLine> line = vtkSmartPointer<vtkLine>::New();
    line->GetPointIds()->SetId(0, i);
    line->GetPointIds()->SetId(1, i + 1);
    lines->InsertNextCell(line);
  }

  vtkSmartPointer<vtkPolyData> linesPolyData =
      vtkSmartPointer<vtkPolyData>::New();
  linesPolyData->SetPoints(points);
  linesPolyData->SetLines(lines);

  m_RayLine->RemoveAllInputs();
#if VTK_MAJOR_VERSION <= 5
  m_RayLine->AddInputConnection(linesPolyData->GetProducerPort());
#else
  m_RayLine->AddInputData(linesPolyData);
#endif
  m_RayLine->AddInputConnection(m_Line1->GetOutputPort());
  m_RayLine->AddInputConnection(m_Sphere1->GetOutputPort());
  m_RayLine->AddInputConnection(m_Line2->GetOutputPort());
  m_RayLine->AddInputConnection(m_Sphere2->GetOutputPort());

  vtkSmartPointer<vtkSphereSource> poca_sphere =
      vtkSmartPointer<vtkSphereSource>::New();
  poca_sphere->SetRadius(default_radius);
  poca_sphere->SetCenter(poca(0), poca(1), poca(2));
  m_RayLine->AddInputConnection(poca_sphere->GetOutputPort());

  vtkSmartPointer<vtkMatrix4x4> vmat = vtkSmartPointer<vtkMatrix4x4>::New();
  Matrix4f mat = m_Content->GetImage()->GetWorldMatrix();
  for (int i = 0; i < 4; ++i)
    for (int j = 0; j < 4; ++j)
      vmat->SetElement(i, j, mat(i, j));
  m_Transform->SetMatrix(vmat);

  if (m_Content->GetImage()->IsInsideBounds(poca))
    this->SetRay(pt1, poca, pt2);
  else
    this->SetRay(pt1, pt2);
}

void vtkVoxRaytracerRepresentation::SetMuon(vtkMuonScatter &muon) {
  HPoint3f poca = muon.GetPocaPoint();
  MuonScatter &mu = muon.GetContent();
  this->SetMuon(mu, poca);
}

VoxRaytracer::RayData vtkVoxRaytracerRepresentation::GetRay() { return m_Ray; }

void vtkVoxRaytracerRepresentation::SetRay(HPoint3f in, HPoint3f out) {
  m_Ray = m_Content->TraceBetweenPoints(in, out);
  this->SetRay(&m_Ray);
}

void vtkVoxRaytracerRepresentation::SetRay(HPoint3f in, HPoint3f mid,
                                           HPoint3f out) {
  m_Ray = m_Content->TraceBetweenPoints(in, mid);
  m_Ray.AppendRay(m_Content->TraceBetweenPoints(mid, out));
  this->SetRay(&m_Ray);
}

void vtkVoxRaytracerRepresentation::SetRay(VoxRaytracer::RayData *ray) {
  vtkAppendPolyData *appender = m_RayRepresentation;
  appender->RemoveAllInputs();

  for (size_t i = 0; i < ray->Count(); ++i) {
    int id = ray->Data().at(i).vox_id;
    Vector3i idv = m_Content->GetImage()->UnMap(id);
    vtkSmartPointer<vtkCubeSource> cube = vtkSmartPointer<vtkCubeSource>::New();
    cube->SetBounds(idv(0), idv(0) + 1, idv(1), idv(1) + 1, idv(2), idv(2) + 1);
    cube->Update();
#if VTK_MAJOR_VERSION <= 5
    appender->AddInput(cube->GetOutput());
#else
    appender->AddInputData(cube->GetOutput());
#endif
  }
  appender->Modified();
}

void vtkVoxRaytracerRepresentation::SetVoxelsColor(Vector4f rgba) {
  this->SetColor(m_RayRepresentationActor, rgba);
}

void vtkVoxRaytracerRepresentation::SetRayColor(Vector4f rgba) {
  this->SetColor(m_RayLineActor, rgba);
}

void vtkVoxRaytracerRepresentation::SetColor(vtkActor *actor, Vector4f rgba) {
  if (!actor)
    return;
  vtkProperty *pr = actor->GetProperty();
  pr->SetDiffuseColor(rgba(0), rgba(1), rgba(2));
  pr->SetOpacity(rgba(3));
  pr->SetDiffuse(1);
}

void vtkVoxRaytracerRepresentation::InstallPipe() {

  vtkSmartPointer<vtkAppendPolyData> append =
      vtkSmartPointer<vtkAppendPolyData>::New();
  append->AddInputConnection(m_Sphere1->GetOutputPort());
  append->AddInputConnection(m_Sphere2->GetOutputPort());
  append->AddInputConnection(m_Line1->GetOutputPort());
  append->AddInputConnection(m_Line2->GetOutputPort());

  vtkSmartPointer<vtkPolyDataMapper> mapper =
      vtkSmartPointer<vtkPolyDataMapper>::New();
  mapper->SetInputConnection(append->GetOutputPort());

  vtkSmartPointer<vtkActor> actor = vtkActor::New();
  actor->SetMapper(mapper);
  actor->GetProperty()->SetColor(0.6, 0.6, 1);
  m_Asm->AddPart(actor);

  mapper = vtkSmartPointer<vtkPolyDataMapper>::New();
  mapper->SetInputConnection(m_RayLine->GetOutputPort());

  m_RayLineActor->SetMapper(mapper);
  m_RayLineActor->GetProperty()->SetColor(1, 0, 0);
  m_Asm->AddPart(m_RayLineActor);

  vtkSmartPointer<vtkTransformPolyDataFilter> polyfilter =
      vtkSmartPointer<vtkTransformPolyDataFilter>::New();

  polyfilter->SetInputConnection(m_RayRepresentation->GetOutputPort());
  polyfilter->SetTransform(m_Transform);

  mapper = vtkSmartPointer<vtkPolyDataMapper>::New();
  mapper->SetInputConnection(polyfilter->GetOutputPort());

  vtkActor *vra = m_RayRepresentationActor;
  vra->SetMapper(mapper);
  vra->GetProperty()->SetOpacity(0.2);
  vra->GetProperty()->SetEdgeVisibility(true);
  vra->GetProperty()->SetColor(0.5, 0.5, 0.5);

  m_Asm->AddPart(vra);
  
  this->SetProp(m_Asm);
}

} // namespace Vtk
} // namespace uLib