fix: unified dt

vtk/src/CartographicTransformation.cpp

@@ -15,11 +15,11 @@ vtkSmartPointer<vtkCamera> createNormalisedCamera() {
     return camera;
 }
 
-vtkSmartPointer<vtkMatrix4x4> getCartographicTransformMatrix() {
-    const double XMin = -15.875;
-    const double XMax = 12.875;
-    const double YMin = 46.125;
-    const double YMax = 62.625;
+vtkSmartPointer<vtkMatrix4x4> getCartographicTransformMatrix(const std::shared_ptr<UVGrid> uvGrid) {
+    const double XMin = uvGrid->lons.front();
+    const double XMax = uvGrid->lons.back();
+    const double YMin = uvGrid->lats.front();
+    const double YMax = uvGrid->lats.back();
 
     double eyeTransform[] = {
             2/(XMax-XMin), 0, 0, -(XMax+XMin)/(XMax-XMin),
@@ -34,10 +34,10 @@ vtkSmartPointer<vtkMatrix4x4> getCartographicTransformMatrix() {
 }
 
 // Assumes Normalised camera is used
-vtkSmartPointer<vtkTransformFilter> createCartographicTransformFilter() {
+vtkSmartPointer<vtkTransformFilter> createCartographicTransformFilter(const std::shared_ptr<UVGrid> uvGrid) {
     vtkNew<vtkTransform> transform;
 
-    transform->SetMatrix(getCartographicTransformMatrix());
+    transform->SetMatrix(getCartographicTransformMatrix(uvGrid));
 
     vtkSmartPointer<vtkTransformFilter> transformFilter = vtkSmartPointer<vtkTransformFilter>::New();
     transformFilter->SetTransform(transform);

vtk/src/CartographicTransformation.h

@@ -1,5 +1,6 @@
 #include <vtkCamera.h>
 #include <vtkTransformFilter.h>
+#include "advection/UVGrid.h"
 
 #ifndef VTKBASE_NORMALISEDCARTOGRAPHICCAMERA_H
 #define VTKBASE_NORMALISEDCARTOGRAPHICCAMERA_H
@@ -16,15 +17,14 @@ vtkSmartPointer<vtkCamera> createNormalisedCamera();
 /**
  * Constructs a 4x4 projection matrix that maps homogenious (longitude, latitude, 0, 1) points
  * to the normalised space.
- * TODO: This will soon require UVGrid as a parameter after the advection code is merged properly.
  * TODO: This transformation has room for improvement see:
  * https://github.com/MakeNEnjoy/interactive-track-and-trace/issues/12
  * @return pointer to 4x4 matrix
  */
-vtkSmartPointer<vtkMatrix4x4> getCartographicTransformMatrix();
+vtkSmartPointer<vtkMatrix4x4> getCartographicTransformMatrix(const std::shared_ptr<UVGrid> uvGrid);
 
 /**
  * Convenience function that converts the 4x4 projection matrix into a vtkTransformFilter
  * @return pointer to transform filter
  */
-vtkSmartPointer<vtkTransformFilter> createCartographicTransformFilter();
+vtkSmartPointer<vtkTransformFilter> createCartographicTransformFilter(const std::shared_ptr<UVGrid> uvGrid);

vtk/src/Program.cpp

@@ -33,21 +33,22 @@ void Program::setWinProperties() {
   interact->SetInteractorStyle(style);
 }
 
-void Program::setupTimer() {
+void Program::setupTimer(int dt) {
   auto callback = vtkSmartPointer<TimerCallbackCommand>::New(this);
   callback->SetClientData(this);
+  callback->setDt(dt);
   this->interact->AddObserver(vtkCommand::TimerEvent, callback);
   this->interact->AddObserver(vtkCommand::KeyPressEvent, callback);
   this->interact->CreateRepeatingTimer(17); // 60 fps == 1000 / 60 == 16.7 ms per frame
 }
 
-Program::Program() {
+Program::Program(int timerDT) {
   this->win = vtkSmartPointer<vtkRenderWindow>::New();
   this->interact = vtkSmartPointer<vtkRenderWindowInteractor>::New();
 
   this->win->SetNumberOfLayers(0);
   setWinProperties();
-  setupTimer();
+  setupTimer(timerDT);
 }
 
 

vtk/src/Program.h

@@ -31,14 +31,14 @@ private:
 
   /** This function sets up and connects a TimerCallbackCommand with the program.
     */ 
-  void setupTimer();
+  void setupTimer(int dt);
 
   void setupInteractions();
 
 public:
   /** Constructor.
     */ 
-  Program();
+  Program(int timerDT);
 
   /** This function adds a new layer (and thus vtkRenderer) to the program.
     * The layer is expected to set its own position in the vtkRenderWindow layer system.

vtk/src/advection/AdvectionKernel.h

@@ -11,7 +11,6 @@
  */
 class AdvectionKernel {
 public:
-    const static int DT = 15 * 60 * 15; // 60 sec/min * 15 mins
     /**
      * This function must take a time, latitude and longitude of a particle and must output
      * a new latitude and longitude after being advected once for AdvectionKernel::DT time as defined above.

vtk/src/advection/EulerAdvectionKernel.cpp

@@ -4,10 +4,10 @@
 
 using namespace std;
 
-EulerAdvectionKernel::EulerAdvectionKernel(std::shared_ptr<UVGrid> grid): grid(grid) { }
+EulerAdvectionKernel::EulerAdvectionKernel(std::shared_ptr<UVGrid> grid, int dt) : grid(grid), dt(dt) {}
 
 std::pair<double, double> EulerAdvectionKernel::advect(int time, double latitude, double longitude) const {
-    auto [u, v] = bilinearinterpolate(*grid, time, latitude, longitude);
+  auto [u, v] = bilinearinterpolate(*grid, time, latitude, longitude);
 
-    return {latitude+metreToDegrees(v*DT), longitude+metreToDegrees(u*DT)};
+  return {latitude + metreToDegrees(v * dt), longitude + metreToDegrees(u * dt)};
 }

vtk/src/advection/EulerAdvectionKernel.h

@@ -15,8 +15,9 @@
 class EulerAdvectionKernel: public AdvectionKernel {
 private:
     std::shared_ptr<UVGrid> grid;
+    int dt;
 public:
-    explicit EulerAdvectionKernel(std::shared_ptr<UVGrid> grid);
+    explicit EulerAdvectionKernel(std::shared_ptr<UVGrid> grid, int dt);
     std::pair<double, double> advect(int time, double latitude, double longitude) const override;
 
 };

vtk/src/advection/RK4AdvectionKernel.cpp

@@ -3,33 +3,33 @@
 
 using namespace std;
 
-RK4AdvectionKernel::RK4AdvectionKernel(std::shared_ptr<UVGrid> grid): grid(grid) { }
+RK4AdvectionKernel::RK4AdvectionKernel(std::shared_ptr<UVGrid> grid, int dt): grid(grid), dt(dt) { }
 
 std::pair<double, double> RK4AdvectionKernel::advect(int time, double latitude, double longitude) const {
     auto [u1, v1] = bilinearinterpolate(*grid, time, latitude, longitude);
 //    lon1, lat1 = (particle.lon + u1*.5*particle.dt, particle.lat + v1*.5*particle.dt);
-    double lon1 = longitude + metreToDegrees(u1 * 0.5*DT);
-    double lat1 = latitude + metreToDegrees(v1 * 0.5*DT);
+    double lon1 = longitude + metreToDegrees(u1 * 0.5*dt);
+    double lat1 = latitude + metreToDegrees(v1 * 0.5*dt);
 
 //    (u2, v2) = fieldset.UV[time + .5 * particle.dt, particle.depth, lat1, lon1, particle]
-    auto [u2, v2] = bilinearinterpolate(*grid, time + 0.5 * DT, lat1, lon1);
+    auto [u2, v2] = bilinearinterpolate(*grid, time + 0.5 * dt, lat1, lon1);
 
 //    lon2, lat2 = (particle.lon + u2*.5*particle.dt, particle.lat + v2*.5*particle.dt)
-    double lon2 = longitude + metreToDegrees(u2 * 0.5 * DT);
-    double lat2 = latitude + metreToDegrees(v2 * 0.5 * DT);
+    double lon2 = longitude + metreToDegrees(u2 * 0.5 * dt);
+    double lat2 = latitude + metreToDegrees(v2 * 0.5 * dt);
 
 //    (u3, v3) = fieldset.UV[time + .5 * particle.dt, particle.depth, lat2, lon2, particle]
-    auto [u3, v3] = bilinearinterpolate(*grid, time + 0.5 * DT, lat2, lon2);
+    auto [u3, v3] = bilinearinterpolate(*grid, time + 0.5 * dt, lat2, lon2);
 
 //    lon3, lat3 = (particle.lon + u3*particle.dt, particle.lat + v3*particle.dt)
-    double lon3 = longitude + metreToDegrees(u3 * DT);
-    double lat3 = latitude + metreToDegrees(v3 * DT);
+    double lon3 = longitude + metreToDegrees(u3 * dt);
+    double lat3 = latitude + metreToDegrees(v3 * dt);
 
 //    (u4, v4) = fieldset.UV[time + particle.dt, particle.depth, lat3, lon3, particle]
-    auto [u4, v4] = bilinearinterpolate(*grid, time + DT, lat3, lon3);
+    auto [u4, v4] = bilinearinterpolate(*grid, time + dt, lat3, lon3);
 
-    double lonFinal = longitude + metreToDegrees((u1 + 2 * u2 + 2 * u3 + u4) / 6.0 * DT);
-    double latFinal = latitude + metreToDegrees((v1 + 2 * v2 + 2 * v3 + v4) / 6.0 * DT);
+    double lonFinal = longitude + metreToDegrees((u1 + 2 * u2 + 2 * u3 + u4) / 6.0 * dt);
+    double latFinal = latitude + metreToDegrees((v1 + 2 * v2 + 2 * v3 + v4) / 6.0 * dt);
 
     return {latFinal, lonFinal};
 }

vtk/src/advection/RK4AdvectionKernel.h

@@ -12,8 +12,9 @@
 class RK4AdvectionKernel: public AdvectionKernel {
 private:
     std::shared_ptr<UVGrid> grid;
+    int dt;
 public:
-    explicit RK4AdvectionKernel(std::shared_ptr<UVGrid> grid);
+    explicit RK4AdvectionKernel(std::shared_ptr<UVGrid> grid, int dt);
     std::pair<double, double> advect(int time, double latitude, double longitude) const override;
 
 };

vtk/src/advection/main.cpp

@@ -1,95 +0,0 @@
-#include <ranges>
-#include <iomanip>
-#include <stdexcept>
-
-#include "interpolate.h"
-#include "Vel.h"
-#include "EulerAdvectionKernel.h"
-#include "RK4AdvectionKernel.h"
-#include "interpolate.h"
-
-#define NotAKernelError "Template parameter T must derive from AdvectionKernel"
-
-using namespace std;
-
-template <typename AdvectionKernelImpl>
-void advectForSomeTime(const UVGrid &uvGrid, const AdvectionKernelImpl &kernel, double latstart, double lonstart, int i, char colour[10]) {
-
-    // Require at compile time that kernel derives from the abstract class AdvectionKernel
-    static_assert(std::is_base_of<AdvectionKernel, AdvectionKernelImpl>::value, NotAKernelError);
-
-    double lat1 = latstart, lon1 = lonstart;
-    for(int time = 0; time <= 31536000.; time += AdvectionKernel::DT) {
-//        cout << setprecision(8) << lat1 << "," << setprecision(8) << lon1 << ",end" << i << "," << colour << endl;
-        try {
-            auto [templat, templon] = kernel.advect(time, lat1, lon1);
-            lat1 = templat;
-            lon1 = templon;
-        } catch (const out_of_range& e) {
-            cerr << "broke out of loop!" << endl;
-            time = 31536001;
-        }
-    }
-    cout << setprecision(8) << latstart << "," << setprecision(8) << lonstart << ",begin" << i << "," << colour << endl;
-    cout << setprecision(8) << lat1 << "," << setprecision(8) << lon1 << ",end" << i << "," << colour << endl;
-}
-
-void testGridIndexing(const UVGrid *uvGrid) {
-    int time = 20000;
-    cout << "=== land === (should all give 0)" << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 53.80956379699079, -1.6496306344654406) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 55.31428895563707, -2.851581041325997) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 47.71548983067583, -1.8704054037408626) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 56.23521060314398, 8.505979324950573) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 53.135645440244375, 8.505979324950573) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 56.44761278775708, -4.140629303756164) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 52.67625153110339, 0.8978569759455872) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 52.07154079279377, 4.627951041411331) << endl;
-
-    cout << "=== ocean === (should give not 0)" << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 47.43923166616274, -4.985451481829083) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 50.68943556852362, -9.306162999561733) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 53.70606799886677, -4.518347647034465) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 60.57987114267971, -12.208262973672621) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 46.532221548197285, -13.408189172582638) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 50.92725094937812, 1.3975824052375256) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 51.4028921682209, 2.4059571950925203) << endl;
-    cout << bilinearinterpolate(*uvGrid, time, 53.448445236769004, 0.7996966058017515) << endl;
-//    cout << bilinearinterpolate(*uvGrid, time, ) << endl;
-}
-
-int main() {
-    std::shared_ptr<UVGrid> uvGrid = std::make_shared<UVGrid>();
-
-    uvGrid->streamSlice(cout, 900);
-
-    auto kernelRK4 = RK4AdvectionKernel(uvGrid);
-
-//    You can use https://maps.co/gis/ to visualise these points
-    cout << "======= RK4 Integration =======" << endl;
-    advectForSomeTime(*uvGrid, kernelRK4, 53.53407391652826, 6.274975037862238, 0, "#ADD8E6");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.494053820479365, 5.673454142386921, 1, "#DC143C");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.49321966653616, 5.681867022043919, 2, "#50C878");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.581548701694324, 6.552600066543153, 3, "#FFEA00");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.431446729744124, 5.241592961691523, 4, "#663399");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.27913608324572, 4.82094897884165, 5, "#FFA500");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.18597595482688, 4.767667388308705, 6, "#008080");
-    advectForSomeTime(*uvGrid, kernelRK4, 53.01592078792383, 4.6064205160882, 7, "#FFB6C1");
-    advectForSomeTime(*uvGrid, kernelRK4, 52.72816940158886, 4.5853883152993635, 8, "#36454F"); // on land
-    advectForSomeTime(*uvGrid, kernelRK4, 52.56142091881038, 4.502661662924255, 9, "#1E90FF"); // Dodger Blue
-    advectForSomeTime(*uvGrid, kernelRK4, 52.23202593893584, 4.2825246383181845, 10, "#FFD700"); // Gold
-    advectForSomeTime(*uvGrid, kernelRK4, 52.08062567609582, 4.112864890830927, 11, "#6A5ACD"); // Slate Blue
-    advectForSomeTime(*uvGrid, kernelRK4, 51.89497719759734, 3.8114033568921686, 12, "#20B2AA"); // Light Sea Green
-    advectForSomeTime(*uvGrid, kernelRK4, 51.752848503723634, 3.664177951809339, 13, "#FF69B4"); // Hot Pink
-    advectForSomeTime(*uvGrid, kernelRK4, 51.64595756528835, 3.626319993352851, 14, "#800080"); // Purple
-    advectForSomeTime(*uvGrid, kernelRK4, 51.55140730645238, 3.4326152213887986, 15, "#FF4500"); // Orange Red
-    advectForSomeTime(*uvGrid, kernelRK4, 51.45679776223422, 3.4452813365018384, 16, "#A52A2A"); // Brown
-    advectForSomeTime(*uvGrid, kernelRK4, 51.41444662720727, 3.4648562416765363, 17, "#4682B4"); // Steel Blue
-    advectForSomeTime(*uvGrid, kernelRK4, 51.37421261203866, 3.2449264214689455, 18, "#FF6347"); // Tomato
-    advectForSomeTime(*uvGrid, kernelRK4, 51.29651848898365, 2.9547572241424773, 19, "#008000"); // Green
-    advectForSomeTime(*uvGrid, kernelRK4, 51.19705098468974, 2.7647654914530024, 20, "#B8860B"); // Dark Goldenrod
-    advectForSomeTime(*uvGrid, kernelRK4, 51.114719857442665, 2.577076679365129, 21, "#FFC0CB"); // Pink
-//    advectForSomeTime(*uvGrid, kernelRK4, ,0);
-
-    return 0;
-}

vtk/src/commands/SpawnPointCallback.cpp

@@ -9,68 +9,74 @@
 
 #include "../CartographicTransformation.h"
 
-void convertDisplayToWorld(vtkRenderer* renderer, int x, int y, double *worldPos) {
-    double displayPos[3] = {static_cast<double>(x), static_cast<double>(y), 0.0};
-    renderer->SetDisplayPoint(displayPos);
-    renderer->DisplayToWorld();
-    renderer->GetWorldPoint(worldPos);
+void convertDisplayToWorld(vtkRenderer *renderer, int x, int y, double *worldPos) {
+  double displayPos[3] = {static_cast<double>(x), static_cast<double>(y), 0.0};
+  renderer->SetDisplayPoint(displayPos);
+  renderer->DisplayToWorld();
+  renderer->GetWorldPoint(worldPos);
 }
 
 void SpawnPointCallback::Execute(vtkObject *caller, unsigned long evId, void *callData) {
-    // Note the use of reinterpret_cast to cast the caller to the expected type.
-    auto interactor = reinterpret_cast<vtkRenderWindowInteractor *>(caller);
+  // Note the use of reinterpret_cast to cast the caller to the expected type.
+  auto interactor = reinterpret_cast<vtkRenderWindowInteractor *>(caller);
 
-    if (evId == vtkCommand::LeftButtonPressEvent) {
-        dragging = true;
-    }
-    if (evId == vtkCommand::LeftButtonReleaseEvent) {
-        dragging = false;
-    }
-    if (!dragging) {
-        return;
-    }
+  if (evId == vtkCommand::LeftButtonPressEvent) {
+    dragging = true;
+  }
+  if (evId == vtkCommand::LeftButtonReleaseEvent) {
+    dragging = false;
+  }
+  if (!dragging) {
+    return;
+  }
 
-    int x, y;
-    interactor->GetEventPosition(x, y);
+  int x, y;
+  interactor->GetEventPosition(x, y);
 
-    double worldPos[4] = {2, 0 ,0, 0};
-    double displayPos[3] = {static_cast<double>(x), static_cast<double>(y), 0.0};
-    ren->SetDisplayPoint(displayPos);
-    ren->DisplayToWorld();
-    ren->GetWorldPoint(worldPos);
-    inverseCartographicProjection->MultiplyPoint(worldPos, worldPos);
-    cout << "clicked on lon = " << worldPos[0] << " and lat = " << worldPos[1] << endl;
+  double worldPos[4] = {2, 0, 0, 0};
+  double displayPos[3] = {static_cast<double>(x), static_cast<double>(y), 0.0};
+  ren->SetDisplayPoint(displayPos);
+  ren->DisplayToWorld();
+  ren->GetWorldPoint(worldPos);
+  inverseCartographicProjection->MultiplyPoint(worldPos, worldPos);
+  cout << "clicked on lon = " << worldPos[0] << " and lat = " << worldPos[1] << endl;
 
-    vtkIdType id = points->InsertNextPoint(worldPos[0], worldPos[1], 0);
-    data->SetPoints(points);
+  vtkIdType id = points->InsertNextPoint(worldPos[0], worldPos[1], 0);
+  data->SetPoints(points);
 
-    vtkSmartPointer<vtkVertex> vertex = vtkSmartPointer<vtkVertex>::New();
-    vertex->GetPointIds()->SetId(0, id);
+  vtkSmartPointer<vtkVertex> vertex = vtkSmartPointer<vtkVertex>::New();
+  vertex->GetPointIds()->SetId(0, id);
 
-    vtkSmartPointer<vtkCellArray> vertices = vtkSmartPointer<vtkCellArray>::New();
-    vertices->InsertNextCell(vertex);
-    data->SetVerts(vertices);
-    ren->GetRenderWindow()->Render();
+  vtkSmartPointer<vtkCellArray> vertices = vtkSmartPointer<vtkCellArray>::New();
+  vertices->InsertNextCell(vertex);
+  data->SetVerts(vertices);
+  ren->GetRenderWindow()->Render();
 }
 
 
-SpawnPointCallback::SpawnPointCallback() : data(nullptr), points(nullptr), inverseCartographicProjection(nullptr) {
-    inverseCartographicProjection = getCartographicTransformMatrix();
-    inverseCartographicProjection->Invert();
-}
+SpawnPointCallback::SpawnPointCallback() : data(nullptr),
+                                           points(nullptr),
+                                           inverseCartographicProjection(nullptr),
+                                           uvGrid(nullptr) { }
 
 SpawnPointCallback *SpawnPointCallback::New() {
     return new SpawnPointCallback;
 }
 
 void SpawnPointCallback::setData(const vtkSmartPointer<vtkPolyData> &data) {
-    this->data = data;
+  this->data = data;
 }
 
 void SpawnPointCallback::setPoints(const vtkSmartPointer<vtkPoints> &points) {
-    this->points = points;
+  this->points = points;
 }
 
 void SpawnPointCallback::setRen(const vtkSmartPointer<vtkRenderer> &ren) {
-    this->ren = ren;
+  this->ren = ren;
+}
+
+void SpawnPointCallback::setUVGrid(const std::shared_ptr<UVGrid> &uvGrid) {
+  this->uvGrid = uvGrid;
+  inverseCartographicProjection = getCartographicTransformMatrix(uvGrid);
+  inverseCartographicProjection->Invert();
 }

vtk/src/commands/SpawnPointCallback.h

@@ -7,26 +7,33 @@
 #include <vtkPoints.h>
 #include <vtkPolyData.h>
 #include <vtkMatrix4x4.h>
+#include "../advection/UVGrid.h"
 
 class SpawnPointCallback : public vtkCallbackCommand {
 
 public:
-    static SpawnPointCallback *New();
-    SpawnPointCallback();
+  static SpawnPointCallback *New();
 
-    void setPoints(const vtkSmartPointer<vtkPoints> &points);
+  SpawnPointCallback();
 
-    void setData(const vtkSmartPointer<vtkPolyData> &data);
+  void setPoints(const vtkSmartPointer<vtkPoints> &points);
+
+  void setData(const vtkSmartPointer<vtkPolyData> &data);
+
+  void setRen(const vtkSmartPointer<vtkRenderer> &ren);
+
+  void setUVGrid(const std::shared_ptr<UVGrid> &uvGrid);
 
-    void setRen(const vtkSmartPointer<vtkRenderer> &ren);
 private:
-    vtkSmartPointer<vtkPolyData> data;
-    vtkSmartPointer<vtkPoints> points;
-    vtkSmartPointer<vtkRenderer> ren;
-    vtkSmartPointer<vtkMatrix4x4> inverseCartographicProjection;
+  vtkSmartPointer<vtkPolyData> data;
+  vtkSmartPointer<vtkPoints> points;
+  vtkSmartPointer<vtkRenderer> ren;
+  std::shared_ptr<UVGrid> uvGrid;
+  vtkSmartPointer<vtkMatrix4x4> inverseCartographicProjection;
 
-    void Execute(vtkObject *caller, unsigned long evId, void *callData) override;
-    bool dragging = false;
+  void Execute(vtkObject *caller, unsigned long evId, void *callData) override;
+
+  bool dragging = false;
 };
 
 

vtk/src/commands/TimerCallbackCommand.cpp

@@ -38,3 +38,7 @@ void TimerCallbackCommand::setProgram(Program *program) {
 void TimerCallbackCommand::setPaused(const bool val) {
   this->paused = val;
 }
+
+void TimerCallbackCommand::setDt(int dt) {
+  this->dt = dt;
+}

vtk/src/commands/TimerCallbackCommand.h

@@ -13,6 +13,8 @@ public:
   void setProgram(Program *program);
   void setPaused(const bool val);
 
+  void setDt(int dt);
+
 private:
   int time;
   int dt;

vtk/src/layers/EGlyphLayer.cpp

@@ -50,9 +50,8 @@ void EGlyphLayer::readCoordinates() {
     int lonIndex = 0;
     for (double lon: uvGrid->lons) {
       auto [u, v] = (*uvGrid)[0, latIndex, lonIndex];
-      direction->SetTuple3(i, 2*v, 2*u, 0);
+      direction->SetTuple3(i, 5*u, 5*v, 0);
       points->InsertPoint(i++, lon, lat, 0);
-      // see also https://vtk.org/doc/nightly/html/classvtkPolyDataMapper2D.html
       lonIndex++;
     }
     latIndex++;
@@ -61,7 +60,7 @@ void EGlyphLayer::readCoordinates() {
   this->data->GetPointData()->AddArray(this->direction);
   this->data->GetPointData()->SetActiveVectors("direction");
 
-  vtkSmartPointer<vtkTransformFilter> transformFilter = createCartographicTransformFilter();
+  vtkSmartPointer<vtkTransformFilter> transformFilter = createCartographicTransformFilter(uvGrid);
   transformFilter->SetInputData(data);
 
   vtkNew<vtkGlyphSource2D> arrowSource;
@@ -101,7 +100,8 @@ void EGlyphLayer::updateData(int t) {
   for (int lat = 0; lat < uvGrid->latSize; lat++) {
     for (int lon = 0; lon < uvGrid->lonSize; lon++) {
       auto [u, v] = (*uvGrid)[t/3600, lat, lon];
-      this->direction->SetTuple3(i, 5*v, 5*u, 0); // FIXME: fetch data from file.
+      // TODO: The 5*v stuff should really be a filter transform
+      this->direction->SetTuple3(i, 5*u, 5*v, 0);
       i++;
     }
   }

vtk/src/layers/LGlyphLayer.cpp

@@ -23,6 +23,7 @@ vtkSmartPointer<SpawnPointCallback> LGlyphLayer::createSpawnPointCallback() {
     newPointCallBack->setData(data);
     newPointCallBack->setPoints(points);
     newPointCallBack->setRen(ren);
+    newPointCallBack->setUVGrid(uvGrid);
     return newPointCallBack;
 }
 
@@ -31,7 +32,7 @@ vtkSmartPointer<SpawnPointCallback> LGlyphLayer::createSpawnPointCallback() {
 //
 // TODO: modelling all this in vtkClasses is workable, but ideally i would want to work with a native C++ class. See if this is doable and feasible.
 
-LGlyphLayer::LGlyphLayer(std::unique_ptr<AdvectionKernel> advectionKernel) {
+LGlyphLayer::LGlyphLayer(std::shared_ptr<UVGrid> uvGrid, std::unique_ptr<AdvectionKernel> advectionKernel) {
     this->ren = vtkSmartPointer<vtkRenderer>::New();
     this->ren->SetLayer(2);
 
@@ -40,13 +41,12 @@ LGlyphLayer::LGlyphLayer(std::unique_ptr<AdvectionKernel> advectionKernel) {
     this->data->SetPoints(this->points);
 
     advector = std::move(advectionKernel);
+    this->uvGrid = uvGrid;
 
     auto camera = createNormalisedCamera();
     ren->SetActiveCamera(camera);
 
-    auto transform = createCartographicTransformFilter();
-
-    vtkSmartPointer<vtkTransformFilter> transformFilter = createCartographicTransformFilter();
+    vtkSmartPointer<vtkTransformFilter> transformFilter = createCartographicTransformFilter(uvGrid);
     transformFilter->SetInputData(data);
 
     vtkNew<vtkGlyphSource2D> circleSource;
@@ -97,10 +97,7 @@ void LGlyphLayer::updateData(int t) {
 }
 
 void LGlyphLayer::addObservers(vtkSmartPointer<vtkRenderWindowInteractor> interactor) {
-    auto newPointCallBack = vtkSmartPointer<SpawnPointCallback>::New();
-    newPointCallBack->setData(data);
-    newPointCallBack->setPoints(points);
-    newPointCallBack->setRen(ren);
+    auto newPointCallBack = createSpawnPointCallback();
     interactor->AddObserver(vtkCommand::LeftButtonPressEvent, newPointCallBack);
     interactor->AddObserver(vtkCommand::LeftButtonReleaseEvent, newPointCallBack);
     interactor->AddObserver(vtkCommand::MouseMoveEvent, newPointCallBack);

vtk/src/layers/LGlyphLayer.h

@@ -15,13 +15,12 @@ private:
   vtkSmartPointer<vtkPoints> points;
   vtkSmartPointer<vtkPolyData> data;
   std::unique_ptr<AdvectionKernel> advector;
-
-
+  std::shared_ptr<UVGrid> uvGrid;
 
 public:
   /** Constructor.
     */
-  LGlyphLayer(std::unique_ptr<AdvectionKernel> advectionKernel);
+  LGlyphLayer(std::shared_ptr<UVGrid> uvGrid, std::unique_ptr<AdvectionKernel> advectionKernel);
 
   /** This function spoofs a few points in the dataset. Mostly used for testing.
     */

vtk/src/main.cpp

@@ -18,15 +18,16 @@
 
 using namespace std;
 
+#define DT 60 * 60 // 60 sec/min * 60 mins
 
 int main() {
   shared_ptr<UVGrid> uvGrid = std::make_shared<UVGrid>();
-  auto kernelRK4 = make_unique<RK4AdvectionKernel>(uvGrid);
+  auto kernelRK4 = make_unique<RK4AdvectionKernel>(uvGrid, DT);
 
-  auto l = new LGlyphLayer(move(kernelRK4));
+  auto l = new LGlyphLayer(uvGrid, move(kernelRK4));
 //  l->spoofPoints();
 
-  Program *program = new Program();
+  Program *program = new Program(DT);
   program->addLayer(new BackgroundImage("../../../../data/map_661-661.png"));
   program->addLayer(new EGlyphLayer(uvGrid));
   program->addLayer(l);