static void InitializeViews(mitk::DataStorage::Pointer dataStorage)
{
mitk::NodePredicateNot::Pointer predicate = mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("includeInBoundingBox", mitk::BoolProperty::New(false)));
mitk::DataStorage::SetOfObjects::ConstPointer subset = dataStorage->GetSubset(predicate);
mitk::TimeSlicedGeometry::Pointer geometry = dataStorage->ComputeBoundingGeometry3D(subset);
mitk::RenderingManager::GetInstance()->InitializeViews(geometry);
}
int main(int argc, char* argv[])
{
if (argc < 2)
{
fprintf(stderr, "Usage: %s [filename1] [filename2] ...\n\n", "");
return 1;
}
// Create a DataStorage
m_DataStorage = mitk::StandaloneDataStorage::New();
//*************************************************************************
// Part II: Create some data by reading files
//*************************************************************************
int i;
for (i = 1; i < argc; ++i)
{
// For testing
if (strcmp(argv[i], "-testing") == 0)
continue;
// Create a DataNodeFactory to read a data format supported
// by the DataNodeFactory (many image formats, surface formats, etc.)
mitk::DataNodeFactory::Pointer nodeReader = mitk::DataNodeFactory::New();
const char * filename = argv[i];
try
{
nodeReader->SetFileName(filename);
nodeReader->Update();
// Since the DataNodeFactory directly creates a node,
// use the datastorage to add the read node
mitk::DataNode::Pointer node = nodeReader->GetOutput();
m_DataStorage->Add(node);
mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
if (image.IsNotNull())
{
// Set the property "volumerendering" to the Boolean value "true"
node->SetProperty("volumerendering", mitk::BoolProperty::New(false));
node->SetProperty("name", mitk::StringProperty::New("testimage"));
node->SetProperty("layer", mitk::IntProperty::New(1));
}
} catch (...)
{
fprintf(stderr, "Could not open file %s \n\n", filename);
exit(2);
}
}
//*************************************************************************
// Part V: Create window and pass the tree to it
//*************************************************************************
// Global Interaction initialize
// legacy because window manager relies still on existence if global interaction
mitk::GlobalInteraction::GetInstance()->Initialize("global");
//mitk::GlobalInteraction::GetInstance()->AddListener(m_DisplayInteractor);
// Create renderwindows
mitkWidget1 = mitk::RenderWindow::New();
mitkWidget2 = mitk::RenderWindow::New();
mitkWidget3 = mitk::RenderWindow::New();
mitkWidget4 = mitk::RenderWindow::New();
// Tell the renderwindow which (part of) the datastorage to render
mitkWidget1->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget2->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget3->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget4->GetRenderer()->SetDataStorage(m_DataStorage);
// Let NavigationControllers listen to GlobalInteraction
mitk::GlobalInteraction *gi = mitk::GlobalInteraction::GetInstance();
gi->AddListener(mitkWidget1->GetSliceNavigationController());
gi->AddListener(mitkWidget2->GetSliceNavigationController());
gi->AddListener(mitkWidget3->GetSliceNavigationController());
gi->AddListener(mitkWidget4->GetSliceNavigationController());
// instantiate display interactor
if (m_DisplayInteractor.IsNull())
{
m_DisplayInteractor = mitk::DisplayInteractor::New();
m_DisplayInteractor->LoadStateMachine("DisplayInteraction.xml");
m_DisplayInteractor->SetEventConfig("DisplayConfigMITK.xml");
// Register as listener via micro services
us::ModuleContext* context = us::GetModuleContext();
context->RegisterService<mitk::InteractionEventObserver>(
m_DisplayInteractor.GetPointer());
}
// Use it as a 2D View
mitkWidget1->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget2->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget3->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget4->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard3D);
mitkWidget1->SetSize(400, 400);
mitkWidget2->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0] + 420,
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1]);
mitkWidget2->SetSize(400, 400);
mitkWidget3->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0],
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1] + 450);
mitkWidget3->SetSize(400, 400);
mitkWidget4->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0] + 420,
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1] + 450);
mitkWidget4->SetSize(400, 400);
InitializeWindows();
AddDisplayPlaneSubTree();
Fit();
// Initialize the RenderWindows
mitk::TimeSlicedGeometry::Pointer geo = m_DataStorage->ComputeBoundingGeometry3D(m_DataStorage->GetAll());
mitk::RenderingManager::GetInstance()->InitializeViews(geo);
m_DataStorage->Print(std::cout);
mitk::RenderingManager::GetInstance()->RequestUpdateAll();
// reinit the mitkVTKEventProvider;
// this is only necessary once after calling
// ForceImmediateUpdateAll() for the first time
mitkWidget1->ReinitEventProvider();
mitkWidget2->ReinitEventProvider();
mitkWidget3->ReinitEventProvider();
mitkWidget1->GetVtkRenderWindow()->Render();
mitkWidget2->GetVtkRenderWindow()->Render();
mitkWidget3->GetVtkRenderWindow()->Render();
mitkWidget4->GetVtkRenderWindow()->Render();
mitkWidget4->GetVtkRenderWindowInteractor()->Start();
return 0;
}
int main(int argc, char* argv[])
{
if (argc < 2)
{
fprintf(stderr, "Usage: %s [filename1] [filename2] ...\n\n", "");
return 1;
}
// Create a DataStorage
m_DataStorage = mitk::StandaloneDataStorage::New();
//*************************************************************************
// Part II: Create some data by reading files
//*************************************************************************
int i;
for (i = 1; i < argc; ++i)
{
// For testing
if (strcmp(argv[i], "-testing") == 0)
continue;
std::string filename = argv[i];
try
{
// Read the file and add it as a data node to the data storage
mitk::DataStorage::SetOfObjects::Pointer nodes = mitk::IOUtil::Load(filename, *m_DataStorage);
for (mitk::DataStorage::SetOfObjects::Iterator nodeIter = nodes->Begin(),
nodeIterEnd = nodes->End(); nodeIter != nodeIterEnd; ++nodeIter)
{
mitk::DataNode::Pointer node = nodeIter->Value();
mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(node->GetData());
if (image.IsNotNull())
{
// Set the property "volumerendering" to the Boolean value "true"
node->SetProperty("volumerendering", mitk::BoolProperty::New(false));
node->SetProperty("name", mitk::StringProperty::New("testimage"));
node->SetProperty("layer", mitk::IntProperty::New(1));
}
}
} catch (...)
{
std::cerr << "Could not open file " << filename << std::endl;
exit(2);
}
}
//*************************************************************************
// Part V: Create window and pass the tree to it
//*************************************************************************
// Create renderwindows
mitkWidget1 = mitk::RenderWindow::New();
mitkWidget2 = mitk::RenderWindow::New();
mitkWidget3 = mitk::RenderWindow::New();
mitkWidget4 = mitk::RenderWindow::New();
mitkWidget1->GetRenderer()->PrepareRender();
mitkWidget2->GetRenderer()->PrepareRender();
mitkWidget3->GetRenderer()->PrepareRender();
// Tell the renderwindow which (part of) the datastorage to render
mitkWidget1->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget2->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget3->GetRenderer()->SetDataStorage(m_DataStorage);
mitkWidget4->GetRenderer()->SetDataStorage(m_DataStorage);
// instantiate display interactor
if (m_DisplayInteractor.IsNull())
{
m_DisplayInteractor = mitk::DisplayInteractor::New();
m_DisplayInteractor->LoadStateMachine("DisplayInteraction.xml");
m_DisplayInteractor->SetEventConfig("DisplayConfigMITK.xml");
// Register as listener via micro services
us::ModuleContext* context = us::GetModuleContext();
context->RegisterService<mitk::InteractionEventObserver>(
m_DisplayInteractor.GetPointer());
}
// Use it as a 2D View
mitkWidget1->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget2->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget3->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard2D);
mitkWidget4->GetRenderer()->SetMapperID(mitk::BaseRenderer::Standard3D);
mitkWidget1->SetSize(400, 400);
mitkWidget2->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0] + 420,
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1]);
mitkWidget2->SetSize(400, 400);
mitkWidget3->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0],
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1] + 450);
mitkWidget3->SetSize(400, 400);
mitkWidget4->GetVtkRenderWindow()->SetPosition(mitkWidget1->GetVtkRenderWindow()->GetPosition()[0] + 420,
mitkWidget1->GetVtkRenderWindow()->GetPosition()[1] + 450);
mitkWidget4->SetSize(400, 400);
InitializeWindows();
AddDisplayPlaneSubTree();
Fit();
// Initialize the RenderWindows
mitk::TimeGeometry::Pointer geo = m_DataStorage->ComputeBoundingGeometry3D(m_DataStorage->GetAll());
mitk::RenderingManager::GetInstance()->InitializeViews(geo);
m_DataStorage->Print(std::cout);
mitk::RenderingManager::GetInstance()->RequestUpdateAll();
// reinit the mitkVTKEventProvider;
// this is only necessary once after calling
// ForceImmediateUpdateAll() for the first time
mitkWidget1->ReinitEventProvider();
mitkWidget2->ReinitEventProvider();
mitkWidget3->ReinitEventProvider();
mitkWidget1->GetVtkRenderWindow()->Render();
mitkWidget2->GetVtkRenderWindow()->Render();
mitkWidget3->GetVtkRenderWindow()->Render();
mitkWidget4->GetVtkRenderWindow()->Render();
mitkWidget4->GetVtkRenderWindowInteractor()->Start();
return 0;
}
void Run(berry::IWorkbenchPartSite::Pointer workbenchPartSite, mitk::DataStorage::Pointer dataStorage, const QList<mitk::DataNode::Pointer>& selectedNodes /*= QList<mitk::DataNode::Pointer>()*/, mitk::BaseRenderer* baseRenderer /*= nullptr*/)
{
if (selectedNodes.empty())
{
return;
}
auto renderWindow = mitk::WorkbenchUtil::GetRenderWindowPart(workbenchPartSite->GetPage(), mitk::WorkbenchUtil::NONE);
if (nullptr == renderWindow)
{
renderWindow = mitk::WorkbenchUtil::OpenRenderWindowPart(workbenchPartSite->GetPage(), false);
if (nullptr == renderWindow)
{
// no render window available
return;
}
}
auto boundingBoxPredicate = mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("includeInBoundingBox", mitk::BoolProperty::New(false), baseRenderer));
mitk::DataStorage::SetOfObjects::Pointer nodes = mitk::DataStorage::SetOfObjects::New();
for (const auto& dataNode : selectedNodes)
{
if (boundingBoxPredicate->CheckNode(dataNode))
{
nodes->InsertElement(nodes->Size(), dataNode);
}
}
if (nodes->empty())
{
return;
}
if (1 == nodes->Size()) // Special case: If exactly one ...
{
auto image = dynamic_cast<mitk::Image*>(nodes->ElementAt(0)->GetData());
if (nullptr != image) // ... image is selected, reinit is expected to rectify askew images.
{
if (nullptr == baseRenderer)
{
mitk::RenderingManager::GetInstance()->InitializeViews(image->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true);
}
else
{
mitk::RenderingManager::GetInstance()->InitializeView(baseRenderer->GetRenderWindow(), image->GetTimeGeometry(), true);
}
return;
}
}
auto boundingGeometry = dataStorage->ComputeBoundingGeometry3D(nodes, "visible", baseRenderer);
if (nullptr == baseRenderer)
{
mitk::RenderingManager::GetInstance()->InitializeViews(boundingGeometry);
}
else
{
mitk::RenderingManager::GetInstance()->InitializeView(baseRenderer->GetRenderWindow(), boundingGeometry);
}
}