## Monday, April 14, 2014

### RubikFX: Solving the Rubik's Cube with JavaFX 3D

Hi all!

It's really been a while since my last post... But in the middle, three major conferences kept me away from my blog. I said to myself I had to blog about the topics of my talks, but I had no chance at all.

Now, with JavaOne still far in the distance, and after finishing my collaboration in the book, soon to be published, JavaFX 8, Introduction by Example, with my friends Carl Dea, Gerrit Grunwald, Mark Heckler and Sean Phillips, I've had the chance to play with Java 8 and JavaFX 3D for a few weeks, and this post is the result of my findings.

It happens that my kids had recently at home a Rubik's cube, and we also built the Lego Mindstorms EV3 solver thanks to this incredible project from David Gilday, the guy behind the CubeStormer 3 with the world record of fastest solving.

After playing with the cube for a while, I thought about the possibility of creating a JavaFX application for solving the cube, and that's how RubikFX was born.

If you're eager to know what this is about, here is a link to a video in YouTube which will show you most of it.

Basically, in this post I'll talk about importing 3D models in a JavaFX scene, with the ability to zoom, rotate, scale them, add lights, move the camera,... Once we have a nice 3D model of the Rubik's cube, we will try to create a way of moving layers independently from the rest of the model, keeping track of the changes made. Finally, we'll add mouse picking for selecting faces and rotating layers.

Please read this if you're not familiar with Rubik's cube notation and the basic steps for solving it.

Before we start

By now you should know that Java 8 is GA since the 18th of March, so the code in this project is based on this version. In case you haven't done it yet, please download from here the new SDK and update your system. Also, I use NetBeans 8.0 for its support for Java 8 including lambdas and the new Streams API, among other things. You can update your IDE from here.

I use two external dependencies. One for importing the model, from a experimental project called 3DViewer, which is part of the OpenJFX project. So we need to download it and build it. The second one is from the ControlsFX project, for adding cool dialogs to the application. Download it from here.

Finally, we need a 3D model for the cube. You can build it yourself or use a free model, like this, submitted by 3dregenerator, which you can download in 3ds or OBJ formats.

Once you've got all this ingredients, it's easy to get this picture:

For that, just extract the files, rename 'Rubik's Cube.mtl' to 'Cube.mtl' and 'Rubik's Cube.obj' to 'Cube.obj', edit this file and change the third line to 'mtllib Cube.mtl', and save the file.

Now run the 3DViewer application, and drag 'Cube.obj' to the viewer. Open Settings tab, and select Lights, turn on the ambient light with a white color, and off the puntual Light 1. You can zoom in or out (mouse wheel, right button or navigation bar), rotate the cube with the left button (modifying rotation speed with Ctrl or Shift), or translate the model with both mouse buttons pressed.

Now select Options and click Wireframe, so you can see the triangle meshes used to build the model.

Each one of the 27 cubies is given a name in the obj file, like 'Block46' and so on. All of its triangles are grouped in meshes defined by the material assigned, so each cubie is made of 1 to 6 meshes, with names like 'Block46', 'Block46 (2)' and so on, and there are a total number of 117 meshes.

The color of each cubie meshes is asigned in the 'Cube.mtl' file with the Kd constant relative to the diffuse color.

1. The Rubik's Cube - Lite Version

Importing the 3D model

So once we know how is our model, we need to construct the MeshView nodes for each mesh. The ObjImporter class from 3DViewer provide a getMeshes() method that returns a Set of names of the blocks for every mesh. So we will define a HashMap to bind every name to its MeshView. For each mesh name s we get the MeshView object with buildMeshView(s) method.

By design, the cube materials in this model don't reflect light (Ns=0), so we'll change this to allow interaction with puntual lights, by modifying the material specular power property, defined in the PhongMaterial class.

Finally, we will rotate the original model so we have the white face on the top, and the blue one on the front.

public class Model3D {

// Cube.obj contains 117 meshes, marked as "Block46",...,"Block72 (6)" in this set:
private Set<String> meshes;

// HashMap to store a MeshView of each mesh with its key
private final Map<String,Meshview> mapMeshes=new HashMap<>();

public void importObj(){
try {// cube.obj
ObjImporter reader = new ObjImporter(getClass().getResource("Cube.obj").toExternalForm());
meshes=reader.getMeshes(); // set with the names of 117 meshes

Affine affineIni=new Affine();
affineIni.prepend(new Rotate(-90, Rotate.X_AXIS));
affineIni.prepend(new Rotate(90, Rotate.Z_AXIS));
meshes.stream().forEach(s-> {
MeshView cubiePart = reader.buildMeshView(s);
// every part of the cubie is transformed with both rotations:
// since the model has Ns=0 it doesn't reflect light, so we change it to 1
PhongMaterial material = (PhongMaterial) cubiePart.getMaterial();
material.setSpecularPower(1);
cubiePart.setMaterial(material);
// finally, add the name of the part and the cubie part to the hashMap:
mapMeshes.put(s,cubiePart);
});
} catch (IOException e) {
}
}
public Map<String, MeshView> getMapMeshes() {
return mapMeshes;
}
}


Since the model is oriented with white to the right (X axis) and red in the front (Z axis) (see picture above), two rotations are required: first rotate -90 degrees towards X axis, to put blue in the front, and then rotate 90 degrees arount Z axis to put white on top.

Mathematically, the second rotation matrix in Z must by multiplied on the left to the first matrix in X. But according to this link if we use add or append matrix rotations are operated on the right, and this will be wrong:

cubiePart.getTransforms().addAll(new Rotate(-90, Rotate.X_AXIS),
new Rotate(90, Rotate.Z_AXIS));


as it will perform a first rotation in Z and a second one in X, putting red on top and yellow on front. Also this is wrong too:

cubiePart.getTransforms().addAll(new Rotate(90, Rotate.Z_AXIS),
new Rotate(-90, Rotate.X_AXIS));


Though it does the right rotations, then it will require for further rotations of any cubie to be rotated from its original position, which is quite more complicated than rotating always from the last state.

So prepend is the right way to proceed here, and we just need to prepend the last rotation matrix to the Affine matrix of the cubie with all the previous rotations stored there.

Handling the model

After importing the obj file, we can figure out which is the number of each cubie, and once the cube it's well positioned (white face top, blue face front), the scheme we're going to use is a List<Integer> with 27 items:
• first 9 indexes are the 9 cubies in the (F)Front face, from top left (R/W/B) to down right (Y/O/B).
• second 9 indexes are from the (S)Standing face, from top left (R/W) to down right (Y/O).
• last 9 indexes are from (B)Back face, from top left (G/R/W) to down right (G/Y/O).
But for performing rotations of these cubies, the best way is the internal use of a 3D array of integers:

    private final int[][][] cube={{{50,51,52},{49,54,53},{59,48,46}},
{{58,55,60},{57,62,61},{47,56,63}},
{{67,64,69},{66,71,70},{68,65,72}}};


where 50 is the number of the R/W/B cubie and 72 is the number for the G/Y/O.

The Rotations class will take care of any face rotation.

    // This is the method to perform any rotation on the 3D array just by swapping indexes
// first index refers to faces F-S-B
// second index refers to faces U-E-D
// third index refers to faces L-M-R
public void turn(String rot){
int t = 0;
for(int y = 2; y >= 0; --y){
for(int x = 0; x < 3; x++){
switch(rot){
case "L":  tempCube[x][t] = cube[y][x]; break;
case "Li": tempCube[t][x] = cube[x][y]; break;
case "M":  tempCube[x][t] = cube[y][x]; break;
case "Mi": tempCube[t][x] = cube[x][y]; break;
case "R":  tempCube[t][x] = cube[x][y]; break;
case "Ri": tempCube[x][t] = cube[y][x]; break;
case "U":  tempCube[t][x] = cube[x][y]; break;
case "Ui": tempCube[x][t] = cube[y][x]; break;
case "E":  tempCube[x][t] = cube[y][x]; break;
case "Ei": tempCube[t][x] = cube[x][y]; break;
case "D":  tempCube[x][t] = cube[y][x]; break;
case "Di": tempCube[t][x] = cube[x][y]; break;
case "F":  tempCube[x][t] = cube[y][x]; break;
case "Fi": tempCube[t][x] = cube[x][y]; break;
case "S":  tempCube[x][t] = cube[y][x]; break;
case "Si": tempCube[t][x] = cube[x][y]; break;
case "B":  tempCube[t][x] = cube[x][y]; break;
case "Bi": tempCube[x][t] = cube[y][x]; break;
}
}
t++;
}

save();
}


Similar rotations can be performed to the whole cube (X, Y or Z).

The content model

Once we have our model, we need a scene to display it. For that we'll use a object as content container, wrapped in a ContentModel class, where camera, lights and orientation axis are added, which is based in the ContentModel class from 3DViewer application:

public class ContentModel {
public ContentModel(double paneW, double paneH, double dimModel) {
this.paneW=paneW;
this.paneH=paneH;
this.dimModel=dimModel;
buildCamera();
buildSubScene();
buildAxes();
}

private void buildCamera() {
camera.setNearClip(1.0);
camera.setFarClip(10000.0);
camera.setFieldOfView(2d*dimModel/3d);
cameraLookXRotate,cameraLookZRotate);
cameraPosition.setZ(-2d*dimModel);

// Rotate camera to show isometric view X right, Y top, Z 120º left-down from each
cameraXform.setRx(-30.0);
cameraXform.setRy(30);

}

private void buildSubScene() {

subScene = new SubScene(root3D,paneW,paneH,true,javafx.scene.SceneAntialiasing.BALANCED);
subScene.setCamera(camera);
setListeners(true);
}

private void buildAxes() {
double length = 2d*dimModel;
double width = dimModel/100d;
double radius = 2d*dimModel/100d;
final PhongMaterial redMaterial = new PhongMaterial();
redMaterial.setDiffuseColor(Color.DARKRED);
redMaterial.setSpecularColor(Color.RED);
final PhongMaterial greenMaterial = new PhongMaterial();
greenMaterial.setDiffuseColor(Color.DARKGREEN);
greenMaterial.setSpecularColor(Color.GREEN);
final PhongMaterial blueMaterial = new PhongMaterial();
blueMaterial.setDiffuseColor(Color.DARKBLUE);
blueMaterial.setSpecularColor(Color.BLUE);

Sphere xSphere = new Sphere(radius);
Sphere ySphere = new Sphere(radius);
Sphere zSphere = new Sphere(radius);
xSphere.setMaterial(redMaterial);
ySphere.setMaterial(greenMaterial);
zSphere.setMaterial(blueMaterial);

xSphere.setTranslateX(dimModel);
ySphere.setTranslateY(dimModel);
zSphere.setTranslateZ(dimModel);

Box xAxis = new Box(length, width, width);
Box yAxis = new Box(width, length, width);
Box zAxis = new Box(width, width, length);
xAxis.setMaterial(redMaterial);
yAxis.setMaterial(greenMaterial);
zAxis.setMaterial(blueMaterial);

}

light1.setTranslateX(dimModel*0.6);
light1.setTranslateY(dimModel*0.6);
light1.setTranslateZ(dimModel*0.6);
}
}


For the camera, a Xform class from 3DViewer is used to change easily its rotation values. This also allows the initial rotation of the camera to show an isometric view:

    cameraXform.setRx(-30.0);
cameraXform.setRy(30);


Other valid ways to perform these rotations could be based on obtaining the vector and angle of rotation to combine two rotations, which involve calculate the rotation matrix first and then the vector and angle (as I explained here):

    camera.setRotationAxis(new Point3D(-0.694747,0.694747,0.186157));
camera.setRotate(42.1812);


Or prepending the two rotations to all the previous transformations, by appending all of them in a single Affine matrix before prepending these two rotations:

    Affine affineCamIni=new Affine();
camera.getTransforms().stream().forEach(affineCamIni::append);
affineCamIni.prepend(new Rotate(-30, Rotate.X_AXIS));
affineCamIni.prepend(new Rotate(30, Rotate.Y_AXIS));
camera.getTransforms().setAll(affineCamIni);


Then we add the listeners to the subscene, so the camera can be easily rotated.

    private void setListeners(boolean addListeners){
} else {
subScene.removeEventHandler(MouseEvent.ANY, mouseEventHandler);
}
}

private final EventHandler<MouseEvent> mouseEventHandler = event -> {
double xFlip = -1.0, yFlip=1.0; // y Up
if (event.getEventType() == MouseEvent.MOUSE_PRESSED) {
mousePosX = event.getSceneX();
mousePosY = event.getSceneY();
mouseOldX = event.getSceneX();
mouseOldY = event.getSceneY();

} else if (event.getEventType() == MouseEvent.MOUSE_DRAGGED) {
double modifier = event.isControlDown()?0.1:event.isShiftDown()?3.0:1.0;

mouseOldX = mousePosX;
mouseOldY = mousePosY;
mousePosX = event.getSceneX();
mousePosY = event.getSceneY();
mouseDeltaX = (mousePosX - mouseOldX);
mouseDeltaY = (mousePosY - mouseOldY);

if(event.isMiddleButtonDown() || (event.isPrimaryButtonDown() && event.isSecondaryButtonDown())) {
cameraXform2.setTx(cameraXform2.t.getX() + xFlip*mouseDeltaX*modifierFactor*modifier*0.3);
cameraXform2.setTy(cameraXform2.t.getY() + yFlip*mouseDeltaY*modifierFactor*modifier*0.3);
}
else if(event.isPrimaryButtonDown()) {
cameraXform.setRy(cameraXform.ry.getAngle() - yFlip*mouseDeltaX*modifierFactor*modifier*2.0);
cameraXform.setRx(cameraXform.rx.getAngle() + xFlip*mouseDeltaY*modifierFactor*modifier*2.0);
}
else if(event.isSecondaryButtonDown()) {
double z = cameraPosition.getZ();
double newZ = z - xFlip*(mouseDeltaX+mouseDeltaY)*modifierFactor*modifier;
cameraPosition.setZ(newZ);
}
}
};


Handling the model

Now we can put all together and create the Rubik class, where the 3D model is imported, all the meshviews are created and grouped in cube, which is added to the content subscene. At the same time, rot is instantiated with the original position of the cubies.

public class Rubik {
public Rubik(){
// Import Rubik's Cube model and arrows
Model3D model=new Model3D();
model.importObj();
mapMeshes=model.getMapMeshes();
cube.getChildren().setAll(mapMeshes.values());
dimCube=cube.getBoundsInParent().getWidth();

// Create content subscene, add cube, set camera and lights
content = new ContentModel(800,600,dimCube);
content.setContent(cube);

// Initialize 3D array of indexes and a copy of original/solved position
rot=new Rotations();
order=rot.getCube();

// save original position
mapMeshes.forEach((k,v)->mapTransformsOriginal.put(k, v.getTransforms().get(0)));
orderOriginal=order.stream().collect(Collectors.toList());

// Listener to perform an animated face rotation
rotMap=(ov,angOld,angNew)->{
mapMeshes.forEach((k,v)->{
layer.stream().filter(l->k.contains(l.toString()))
.findFirst().ifPresent(l->{
Affine a=new Affine(v.getTransforms().get(0));
a.prepend(new Rotate(angNew.doubleValue()-angOld.doubleValue(),axis));
v.getTransforms().setAll(a);
});
});
};
}
}


Finally we create a listener for rotating layers of cubies in a Timeline animation. As the rotations are prepended to the actual affine matrix of the cubies, to perform a smooth animation we'll change the angle between 0 and 90º, and listen how the timeline internally interpolate it, making small rotations between angNew and angOld angles.

So the method to perform the rotation could be like this:

    public void rotateFace(final String btRot){
if(onRotation.get()){
return;
}
onRotation.set(true);

// rotate cube indexes
rot.turn(btRot);
// get new indexes in terms of blocks numbers from original order
reorder=rot.getCube();
// select cubies to rotate: those in reorder different from order.
AtomicInteger index = new AtomicInteger();
layer=order.stream()
.filter(o->!Objects.equals(o, reorder.get(index.getAndIncrement())))
.collect(Collectors.toList());
// add central cubie
// set rotation axis
axis=Utils.getAxis(btRot);

// define rotation
double angEnd=90d*(btRot.endsWith("i")?1d:-1d);

rotation.set(0d);
// add listener to rotation changes

// create animation
Timeline timeline=new Timeline();
new KeyFrame(Duration.millis(600), e->{
// remove listener
rotation.removeListener(rotMap);
onRotation.set(false);
},  new KeyValue(rotation,angEnd)));
timeline.playFromStart();

// update order with last list
order=reorder.stream().collect(Collectors.toList());
}


RubikFX, Lite Version

Later on we'll add more features, but for now let's create a JavaFX application, with a BorderPane, add content to the center of the pane, and a few toolbars with buttons to perform rotations.

public class TestRubikFX extends Application {

private final BorderPane pane=new BorderPane();
private Rubik rubik;

@Override
public void start(Stage stage) {
rubik=new Rubik();
// create toolbars
ToolBar tbTop=new ToolBar(new Button("U"),new Button("Ui"),new Button("F"),
new Button("Fi"),new Separator(),new Button("Y"),
new Button("Yi"),new Button("Z"),new Button("Zi"));
pane.setTop(tbTop);
ToolBar tbBottom=new ToolBar(new Button("B"),new Button("Bi"),new Button("D"),
new Button("Di"),new Button("E"),new Button("Ei"));
pane.setBottom(tbBottom);
ToolBar tbRight=new ToolBar(new Button("R"),new Button("Ri"),new Separator(),
new Button("X"),new Button("Xi"));
tbRight.setOrientation(Orientation.VERTICAL);
pane.setRight(tbRight);
ToolBar tbLeft=new ToolBar(new Button("L"),new Button("Li"),new Button("M"),
new Button("Mi"),new Button("S"),new Button("Si"));
tbLeft.setOrientation(Orientation.VERTICAL);
pane.setLeft(tbLeft);

pane.setCenter(rubik.getSubScene());

pane.getChildren().stream()
.filter(n->(n instanceof ToolBar))
.forEach(tb->{
((ToolBar)tb).getItems().stream()
.filter(n->(n instanceof Button))
.forEach(n->((Button)n).setOnAction(e->rubik.rotateFace(((Button)n).getText())));
});
pane.getChildren().stream()
.filter(n->(n instanceof ToolBar))
.forEach(tb->tb.setDisable(b1));
});
final Scene scene = new Scene(pane, 880, 680, true);
scene.setFill(Color.ALICEBLUE);
stage.setTitle("Rubik's Cube - JavaFX3D");
stage.setScene(scene);
stage.show();
}
}


Now this is what we have already accomplished:

If you're interested in having a deeper look at the application, you can find the source code in my GitHub repository. Note you'll need to add the 3DViewer.jar.

How does it work?

Take, for instance, a initial "F" rotation. We apply it to rot:

        // rotate cube indexes
rot.turn(btRot);
// get new indexes in terms of blocks numbers from original order
reorder=rot.getCube();


Using rot.printCube() we can see the numbers of cubies for the solved cube (order) and for the new one, with the frontal layer rotated clockwise (reorder):

order:    50 51 52 49 54 53 59 48 46 || 58 55 60 57 62 61 47 56 63 || 67 64 69 66 71 70 68 65 72
reorder:  59 49 50 48 54 51 46 53 52 || 58 55 60 57 62 61 47 56 63 || 67 64 69 66 71 70 68 65 72

By comparing both lists and getting the different items, we know which cubies must be rotated, though we have to add the number of the central cubie (54), as it is the same in both lists, but it should be rotated too. So we create the list layer with these nine cubies:

    // select cubies to rotate: those in reorder different from order.
AtomicInteger index = new AtomicInteger();
layer=order.stream()
.filter(o->!Objects.equals(o, reorder.get(index.getAndIncrement())))
.collect(Collectors.toList());
// add central cubie
// set rotation axis
axis=Utils.getAxis(btRot);


Utils is a class that manage the values for each type of rotation. For this case:

   public static Point3D getAxis(String face){
Point3D p=new Point3D(0,0,0);
switch(face.substring(0,1)){
case "F":
case "S":  p=new Point3D(0,0,1);
break;
}
return p;
}

public static int getCenter(String face){
int c=0;
switch(face.substring(0,1)){
case "F":  c=4;  break;
}
return c;
}


Once we've got the cubies and the axis of rotation, now it's worth noticing how the rotation listener works. With the timeline, the angle goes from 0 to 90º with an EASE_BOTH interpolation (by default), so the angle increments are smaller at the beginning, bigger in the middle and smaller again at the end. This could be a possible list of increments: 0.125º-3º-4.6º-2.2º-2.48º-...-2.43º-4.78º-2.4º-2.4º-0.55º.

For every value in angNew, the listener rotMap applies a small rotation to a layer of cubies. For that we look in our HashMap which meshviews belongs to these cubies, and prepend a new rotation to their previous affine matrix:

   // Listener to perform an animated face rotation
rotMap=(ov,angOld,angNew)->{
mapMeshes.forEach((k,v)->{
layer.stream().filter(l->k.contains(l.toString()))
.findFirst().ifPresent(l->{
Affine a=new Affine(v.getTransforms().get(0));
a.prepend(new Rotate(angNew.doubleValue()-angOld.doubleValue(),axis));
v.getTransforms().setAll(a);
});
});
};


So in 600 ms we apply around 30 to 40 small rotations to a bunch of around 40 meshviews.

Finally, after the rotation is done, we just need to update order with the last list of cubies, so we can start all over again with a new rotation.

2. The Rubik's Cube - Full Version

Now that we've got a working but pretty basic Rubik's cube JavaFX application, it's time for adding a few extra features, like graphic arrows and preview rotations to show the direction of rotation before they're performed.

Scramble and Sequences

Let's start by adding a scramble routine, to scramble the cubies before start solving the cube. To do that we generate a sequence of 25 random moves from a list of valid rotations.

   private static final List<String> movements =
Arrays.asList("F", "Fi", "F2", "R", "Ri", "R2",
"B", "Bi", "B2", "L", "Li", "L2",
"U", "Ui", "U2", "D", "Di", "D2");

private String last="V", get="V";
public void doScramble(){
StringBuilder sb=new StringBuilder();
IntStream.range(0, 25).boxed().forEach(i->{
while(last.substring(0, 1).equals(get.substring(0, 1))){
// avoid repeating the same/opposite rotations
get=movements.get((int)(Math.floor(Math.random()*movements.size())));
}
last=get;
if(get.contains("2")){
get=get.substring(0,1);
sb.append(get).append(" ");
}
sb.append(get).append(" ");
});
doSequence(sb.toString().trim());
}


Then we have to perform this sequence, by rotating each movement.  First we extract the rotations from the string, converting other notations (like lower letters or ' instead of 'i' for counter clockwise rotations) to the one used.

A listener is added to onRotation, so only when the last rotation finishes, a new rotation starts. By adding a second listener to the index property, when the end of the list plus one is reached, this listener is stopped, allowing for the last rotation to finish properly, and saving the rotations for a further replay option.

   public void doSequence(String list){
onScrambling.set(true);
List<String> asList = Arrays.asList(list.replaceAll("’", "i").replaceAll("'", "i").split(" "));

sequence=new ArrayList<>();
asList.stream().forEach(s->{
if(s.contains("2")){
} else if(s.length()==1 && s.matches("[a-z]")){
} else {
}
});
System.out.println("seq: "+sequence);

IntegerProperty index=new SimpleIntegerProperty(1);
ChangeListener<boolean> lis=(ov,b,b1)->{
if(!b1){
if(index.get()<sequence.size()){
rotateFace(sequence.get(index.get()));
} else {
// save transforms
mapMeshes.forEach((k,v)->mapTransformsScramble.put(k, v.getTransforms().get(0)));
orderScramble=reorder.stream().collect(Collectors.toList());
}
index.set(index.get()+1);
}
};
if(v1.intValue()==sequence.size()+1){
onScrambling.set(false);
onRotation.removeListener(lis);
count.set(-1);
}
});
rotateFace(sequence.get(0));
}


Note that we use a Dialog from ControlsFX to prevent losing previous moves.

   Button bSc=new Button("Scramble");
bSc.setOnAction(e->{
if(moves.getNumMoves()>0){
Action response = Dialogs.create()
.owner(stage)
.title("Warning Dialog")
.message( "You will lose all your previous movements. Do you want to continue?")
.showConfirm();
if(response==Dialog.Actions.YES){
rubik.doReset();
doScramble();
}
} else {
doScramble();
}
});


If you want to load a sequence, like any of these, another Dialog with input allowed is used.

   Button bSeq=new Button("Sequence");
bSeq.setOnAction(e->{
String response;
if(moves.getNumMoves()>0){
response = Dialogs.create()
.owner(stage)
.title("Warning Dialog")
.message("Add a valid sequence of movements:\n(previous movements will be discarded)")
.showTextInput(moves.getSequence());
} else {
response = Dialogs.create()
.owner(stage)
.title("Information Dialog")
.message( "Add a valid sequence of movements")
.showTextInput();
}
if(response!=null && !response.isEmpty()){
rubik.doReset();
rubik.doSequence(response.trim());
}
});


The results of scrambling a cube or adding a sequence of rotations can be seen in this video.

Timer and moves counter

Let's add now a timer using the new Date and Time API for Java 8. You may have noticed the timer in the bottom toolbar in the previous video.

For that, we use the following code in RubikFX class:

    private LocalTime time=LocalTime.now();
private Timeline timer;
private final StringProperty clock = new SimpleStringProperty("00:00:00");
private final DateTimeFormatter fmt = DateTimeFormatter.ofPattern("HH:mm:ss").withZone(ZoneId.systemDefault());

@Override
public void start(Stage stage) {
...
Label lTime=new Label();
lTime.textProperty().bind(clock);

timer=new Timeline(new KeyFrame(Duration.ZERO, e->{
clock.set(LocalTime.now().minusNanos(time.toNanoOfDay()).format(fmt));
}),new KeyFrame(Duration.seconds(1)));
timer.setCycleCount(Animation.INDEFINITE);

if(b1){
timer.stop();
}
});

time=LocalTime.now();
timer.playFromStart();
}


For the counter, we'll add two classes. Move is a simple POJO class, with a string for the name of the rotation and a long for the timestamp of the movement. Moves class will contain a list of moves.

public class Moves {
private final List<Move> moves=new ArrayList<>();

public Moves(){
moves.clear();
}

public List<Move> getMoves() { return moves; }
public Move getMove(int index){
if(index>-1 && index<moves.size()){
return moves.get(index);
}
return null;
}
public String getSequence(){
StringBuilder sb=new StringBuilder("");
moves.forEach(m->sb.append(m.getFace()).append(" "));
return sb.toString().trim();
}
}


For adding the number of rotations, we use the following code in RubikFX class:

    private Moves moves=new Moves();

@Override
public void start(Stage stage) {
...
if(!v1.isEmpty()){
}
});

Label lMov=new Label();
lMov.setText("Movements: "+(v1.intValue()+1));
});
}


Replay

We can also replay the list of movements the user has done stored in moves. For that we need to restore first the state of the cube right after the scramble, and performe one by one all the rotations from the list.

    public void doReplay(List<Move> moves){
if(moves.isEmpty()){
return;
}
content.resetCam();
//restore scramble
if(mapTransformsScramble.size()>0){
mapMeshes.forEach((k,v)->v.getTransforms().setAll(mapTransformsScramble.get(k)));
order=orderScramble.stream().collect(Collectors.toList());
rot.setCube(order);
count.set(-1);
} else {
// restore original
doReset();
}

onReplaying.set(true);
IntegerProperty index=new SimpleIntegerProperty(1);
ChangeListener<boolean> lis=(ov,v,v1)->{
if(!v1 && moves.size()>1){
if(index.get()<moves.size()){
timestamp.set(moves.get(index.get()).getTimestamp());
rotateFace(moves.get(index.get()).getFace());
}
index.set(index.get()+1);
}
};
if(v1.intValue()==moves.size()+1){
onReplaying.set(false);
onRotation.removeListener(lis);
acuAngle=0;
}
});
timestamp.set(moves.get(0).getTimestamp());
rotateFace(moves.get(0).getFace());
}


Rotation direction preview

Time for a new feature: 3D arrows will be shown in the rotating face or axis, to show the direction.

Actually, JavaFX 3D API doesn't supply any way of building 3D complex models. There's an impressive ongoing work by Michael Hoffer to provide a way by using Constructive Solid Geometry (CSG) here, kudos Michael!!

By using primitives and boolean operations with CSG you can build a model, and even export it with STL format.

You can use free or commercial 3D software for this task too. I designed these arrows with SketchUp Make and exported them to OBJ format so I could import them as we did with the cube using ObjImporter from 3DViewer.

While the design is fast, it requires manual editting of the created obj file to convert long faces of more than 4 vertixes as they are not properly imported.

Other approach could be exporting the file to *.3ds and use the proper importer from August Lammersdorf.

Edit: Michael Hoffer kindly added an option to export to OBJ format, so now it would be possible to import the arrow model generated with CSG in JavaFXScad in our scene. Thanks Michael!

Once we have the model, we have to add it, scale and rotate it, so we can show the arrow in the rotating face.

For a rotation like 'Ui':

    public void updateArrow(String face, boolean hover){
boolean bFaceArrow=!(face.startsWith("X")||face.startsWith("Y")||face.startsWith("Z"));
MeshView arrow=bFaceArrow?faceArrow:axisArrow;

if(hover && onRotation.get()){
return;
}
arrow.getTransforms().clear();
if(hover){
double d0=arrow.getBoundsInParent().getHeight()/2d;
Affine aff=Utils.getAffine(dimCube, d0, bFaceArrow, face);
arrow.getTransforms().setAll(aff);
arrow.setMaterial(Utils.getMaterial(face));
if(previewFace.get().isEmpty()) {
previewFace.set(face);
onPreview.set(true);
rotateFace(face,true,false);
}
} else if(previewFace.get().equals(face)){
rotateFace(Utils.reverseRotation(face),true,true);
} else if(previewFace.get().equals("V")){
previewFace.set("");
onPreview.set(false);
}
}


where the affine is calculated in the Utils class for the current face:

    public static Affine getAffine(double dimCube, double d0, boolean bFaceArrow, String face){
Affine aff=new Affine(new Scale(3,3,3));
aff.append(new Translate(0,-d0,0));
switch(face){
case "U":
case "Ui":  aff.prepend(new Rotate(face.equals("Ui")?180:0,Rotate.Z_AXIS));
aff.prepend(new Rotate(face.equals("Ui")?45:-45,Rotate.Y_AXIS));
aff.prepend(new Translate(0,dimCube/2d,0));
break;
}
return aff;
}


To trigger the drawing of the arrow, we set a listener to the buttons on the toolbars based on the mouse hovering.

We can also add a small rotation (5º) as preview of the full rotation (90º) in the face selected, by calling rotateFace again, with bPreview=true at this point.

If the user clicks on the button, the rotation is completed (from 5º to 90º). Otherwise the rotation is cancelled (from 5º to 0º). In both cases, with a smooth animation.

Select rotation by picking

Finally, the rotation could be performed based on the mouse picking of a cubie face, with visual aid showing the arrow and performing a small rotation of 5º. If the mouse is dragged far enough the full rotation will be performed after it is released. If the mouse is released close to the origin, the rotation is cancelled.

For this feature, the critical part is being able to know which mesh we are selecting with the mouse click. And for that, the API provides MouseEvent.getPickResult().getIntersectedNode(), which returns one of the meshviews on the cube.

So the next step is find which is this meshview and what cubie does it belongs to. As all the meshes have a name, like 'Block46 (2)', looking at the number of block we identify the cubie.

Now we need to find which of the faces we have selected. For that we use the triangles coordinates of the mesh, as for the faces they define a plane, so with the cross product we know the normal direction of this plane. Note we must update the operations with the actual set of transformations applied.

    private static Point3D getMeshNormal(MeshView mesh){
TriangleMesh tm=(TriangleMesh)mesh.getMesh();
float[] fPoints=new float[tm.getPoints().size()];
tm.getPoints().toArray(fPoints);
Point3D BA=new Point3D(fPoints-fPoints,fPoints-fPoints,fPoints-fPoints);
Point3D CA=new Point3D(fPoints-fPoints,fPoints-fPoints,fPoints-fPoints);
Point3D normal=BA.crossProduct(CA);
Affine a=new Affine(mesh.getTransforms().get(0));
return a.transform(normal.normalize());
}

public static String getPickedRotation(int cubie, MeshView mesh){
Point3D normal=getMeshNormal(mesh);
String rots=""; // Rx-Ry
switch(cubie){
case 0: rots=(normal.getZ()>0.99)?"Ui-Li":
((normal.getX()<-0.99)?"Ui-F":((normal.getY()>0.99)?"Ui-Li":""));
break;
}
return rots;
}


Once we have the normal, we can provide the user with two possible rotations (and their possible two directions). To select which one to perform, we'll look how the user moves the mouse while it's being dragged. Note the mouse coordinates are 2D.

    public static String getRightRotation(Point3D p, String selFaces){
double angle=Math.atan2(p.getY(),p.getX());
String face="";
String[] faces=selFaces.split("-");
// select rotation if p.getX>p.getY
if(-Math.PI/4d<=angle && angle<Math.PI/4d){ // X
face=faces;
} else if(Math.PI/4d<=angle && angle<3d*Math.PI/4d){ // Y
face=faces;
} else if((3d*Math.PI/4d<=angle && angle<=Math.PI) ||
(-Math.PI<=angle && angle<-3d*Math.PI/4d)){ // -X
face=reverseRotation(faces);
} else { //-Y
face=reverseRotation(faces);
}
System.out.println("face: "+face);
} else if(!face.isEmpty() && radius<radMinimum){ // reset previous face
face="";
}
return face;
}


Now that we have the layer to rotate, we make a small rotation as a preview of rotation if the mouse is dragged far from the initial click point, with a minimum distance. Then if the user releases the mouse and the distance from the initial point is greater than a distance radClick, the rotation is completed. But if the distance is lower or the mouse is dragged under the distance radMinimum, the rotation is cancelled.

The next listing shows an EventHandler<MouseEvent> implemented to provide this behaviour. Note that we have to stop the camera rotations while we are picking a face and rotating a layer.

    public EventHandler<MouseEvent> eventHandler=(MouseEvent event)->{
if (event.getEventType() == MouseEvent.MOUSE_PRESSED ||
event.getEventType() == MouseEvent.MOUSE_DRAGGED ||
event.getEventType() == MouseEvent.MOUSE_RELEASED) {

mouseNewX = event.getSceneX();
mouseNewY = -event.getSceneY();

if (event.getEventType() == MouseEvent.MOUSE_PRESSED) {
Node picked = event.getPickResult().getIntersectedNode();
if(null != picked && picked instanceof MeshView) {
mouse.set(MOUSE_PRESSED);
cursor.set(Cursor.CLOSED_HAND);
stopEventHandling();
stopEvents=true;
pickedMesh=(MeshView)picked;
String block=pickedMesh.getId().substring(5,7);
int indexOf = order.indexOf(new Integer(block));
selFaces=Utils.getPickedRotation(indexOf, pickedMesh);
mouseIniX=mouseNewX;
mouseIniY=mouseNewY;
myFace="";
myFaceOld="";
}
} else if (event.getEventType() == MouseEvent.MOUSE_DRAGGED) {
if(stopEvents && !selFaces.isEmpty()){
mouse.set(MOUSE_DRAGGED);
Point3D p=new Point3D(mouseNewX-mouseIniX,mouseNewY-mouseIniY,0);

if(myFaceOld.isEmpty()){
myFace=Utils.getRightRotation(p,selFaces);
if(!myFace.isEmpty() && !onRotation.get()){
updateArrow(myFace, true);
myFaceOld=myFace;
}
if(myFace.isEmpty()){
myFaceOld="";
}
}
// to cancel preselection, just go back to initial click point
myFaceOld="";
updateArrow(myFace, false);
myFace="";
}
}
} else if (stopEvents && event.getEventType() == MouseEvent.MOUSE_RELEASED) {
mouse.set(MOUSE_RELEASED);
if(!onRotation.get() && !myFace.isEmpty() && !myFaceOld.isEmpty()){
// if hand is moved far away do full rotation
rotateFace(myFace);
} else {
// else preview cancellation
updateArrow(myFace, false);
}
}
myFace=""; myFaceOld="";
stopEvents=false;
resumeEventHandling();
cursor.set(Cursor.DEFAULT);
}
}
};


Finally, we add this EventHandler to the scene:

scene.addEventHandler(MouseEvent.ANY, rubik.eventHandler);


This video shows how this event handling works.

Check if cube is solved

Finally, let's add a check routine. We know the initial solved order of cubies, but we need to take into account any of the 24 possible orientations of the faces, which can be acchieved with up to two rotations.

    private static final List<String> orientations=Arrays.asList("V-V","V-Y","V-Yi","V-Y2",
"X-V","X-Z","X-Zi","X-Z2",
"Xi-V","Xi-Z","Xi-Zi",
"X2-V","X2-Z","X2-Zi",
"X-Y","X-Yi","X-Y2",
"Xi-Y","Xi-Yi","X2-Y","X2-Yi",
"Z-V","Zi-V","Z2-V");

public static boolean checkOrientation(String r, List<Integer> order){
Rotations rot=new Rotations();
for(String s:r.split("-")){
if(s.contains("2")){
rot.turn(s.substring(0,1));
rot.turn(s.substring(0,1));
} else {
rot.turn(s);
}
}
return order.equals(rot.getCube());
}


So after any movement we have to check if the actual order matches any of these 24 solutions. For that we can use parallelStream() with a filter in which we rotate a new cube to one of the possible orientations and check if that matches the actual one:

    public static boolean checkSolution(List<Integer> order) {
return Utils.getOrientations().parallelStream()
.filter(r->Utils.checkOrientation(r,order)).findAny().isPresent();
}

Conclusions

All along this post, we've been discussing the new JavaFX 3D API. Powerfull enough, but with lack of some usual tools in the 3D modelling world. Maybe they will come soon...

We've used the new lambdas and Stream API. I hope by now you've got a clear view of what you can do with them. For sure, they will definetely change the way we write code.

The Rubik's cube application has proven to be a nice way of testing these new capabilities, while enjoying playing, humm, I mean, developing the code.

This final video shows most of what we've accomplished in this post. As I said, it's for begginers like me with the Rubik's cube...

In my repo you can find all the code for this full version. Fill free to fork it and play with it. There're tons of improvements to make, so any pull request will be welcome!

Edit: And if you just want to try it before having a look at the code, here you can download a single executable jar. Download it and run it with Java 8 installed.

As always, thanks for reading me! Please, try it for yourself and share any comment you may have.