91 #ifndef vtkLagrangianParticleTracker_h
92 #define vtkLagrangianParticleTracker_h
96 #include "vtkFiltersFlowPathsModule.h"
117 struct IntegratingFunctor;
129 STEP_CUR_CELL_LENGTH = 1,
130 STEP_CUR_CELL_VEL_DIR = 3,
131 STEP_CUR_CELL_DIV_THEO = 5
132 } CellLengthComputation;
158 vtkSetMacro(GeneratePolyVertexInteractionOutput,
bool);
159 vtkGetMacro(GeneratePolyVertexInteractionOutput,
bool);
176 vtkSetMacro(CellLengthComputationMode,
int);
177 vtkGetMacro(CellLengthComputationMode,
int);
184 vtkSetMacro(StepFactor,
double);
185 vtkGetMacro(StepFactor,
double);
192 vtkSetMacro(StepFactorMin,
double);
193 vtkGetMacro(StepFactorMin,
double);
200 vtkSetMacro(StepFactorMax,
double);
201 vtkGetMacro(StepFactorMax,
double);
208 vtkSetMacro(MaximumNumberOfSteps,
int);
209 vtkGetMacro(MaximumNumberOfSteps,
int);
217 vtkSetMacro(MaximumIntegrationTime,
double);
218 vtkGetMacro(MaximumIntegrationTime,
double);
228 vtkSetMacro(AdaptiveStepReintegration,
bool);
229 vtkGetMacro(AdaptiveStepReintegration,
bool);
230 vtkBooleanMacro(AdaptiveStepReintegration,
bool);
238 vtkSetMacro(GenerateParticlePathsOutput,
bool);
239 vtkGetMacro(GenerateParticlePathsOutput,
bool);
240 vtkBooleanMacro(GenerateParticlePathsOutput,
bool);
314 std::queue<vtkLagrangianParticle*>& particles,
vtkPointData* seedData);
317 int nVar, std::queue<vtkLagrangianParticle*>& particles);
318 virtual bool UpdateSurfaceCacheIfNeeded(
vtkDataObject*& surfaces);
324 virtual bool InitializePathsOutput(
330 virtual bool InitializeInteractionOutput(
335 static void InsertPolyVertexCell(
vtkPolyData* polydata);
336 static void InsertVertexCells(
vtkPolyData* polydata);
338 virtual void GetParticleFeed(std::queue<vtkLagrangianParticle*>& particleQueue);
344 std::queue<vtkLagrangianParticle*>&,
vtkPolyData* particlePathsOutput,
351 vtkIdList* particlePathPointId,
bool prev =
false);
357 unsigned int interactedSurfaceFlatIndex,
vtkDataObject* interactionOutput);
369 double t,
double& delT,
double& delTActual,
double minStep,
double maxStep,
double cellLength,
388 bool GenerateParticlePathsOutput =
true;
403 bool FlowCacheInvalid =
true;
406 bool SurfaceCacheInvalid =
true;
409 friend struct IntegratingFunctor;
virtual int RequestDataObject(vtkInformation *, vtkInformationVector **, vtkInformationVector *)
This is called by the superclass.
int CellLengthComputationMode
vtkDataObject * SurfacesCache
vtkMTimeType SurfacesTime
represent and manipulate point attribute data
vtkTypeUInt32 vtkMTimeType
abstract class to specify dataset behavior
static vtkDataObjectAlgorithm * New()
vtkDataObject * FlowCache
vtkInitialValueProblemSolver * Integrator
struct to hold a user data
concrete dataset represents vertices, lines, polygons, and triangle strips
double MinimumReductionFactor
bool AdaptiveStepReintegration
vtkLagrangianThreadedData * SerialThreadedData
Proxy object to connect input/output ports.
dynamic, self-adjusting array of double
int FillOutputPortInformation(int port, vtkInformation *info) override
Fill the output port information objects for this algorithm.
std::atomic< vtkIdType > IntegratedParticleCounter
a simple class to control print indentation
vtkBoundingBox FlowBoundsCache
vtkFunctionSet abstract implementation to be used in the vtkLagrangianParticleTracker integrator...
list of point or cell ids
bool GeneratePolyVertexInteractionOutput
composite dataset to encapsulates pieces of dataset.
abstract superclass for arrays of numeric data
virtual vtkMTimeType GetMTime()
Return this object's modified time.
Basis class for Lagrangian particles.
double MaximumIntegrationTime
boost::graph_traits< vtkGraph * >::vertex_descriptor source(boost::graph_traits< vtkGraph * >::edge_descriptor e, vtkGraph *)
Superclass for algorithms that produce only data object as output.
object to represent cell connectivity
virtual int RequestData(vtkInformation *, vtkInformationVector **, vtkInformationVector *)
std::atomic< vtkIdType > ParticleCounter
vtkLagrangianBasicIntegrationModel * IntegrationModel
Composite dataset that organizes datasets into blocks.
int FillInputPortInformation(int port, vtkInformation *info) override
Fill the input port information objects for this algorithm.
vtkIdType IntegratedParticleCounterIncrement
general representation of visualization data
Filter to inject and track particles in a flow.
represent and manipulate 3D points
double MinimumVelocityMagnitude
cell represents a set of 1D lines
Fast, simple class for representing and operating on 3D bounds.
void PrintSelf(ostream &os, vtkIndent indent) override
Methods invoked by print to print information about the object including superclasses.
Integrate a set of ordinary differential equations (initial value problem) in time.