TwistyPuzzleLib

///////////////////////////////////////////////////////////////////////////////////////////////////

// Copyright 2022 Leszek Koltunski                                                               //

//                                                                                               //

// This file is part of Magic Cube.                                                              //

//                                                                                               //

// Magic Cube is proprietary software licensed under an EULA which you should have received      //

// along with the code. If not, check https://distorted.org/magic/License-Magic-Cube.html        //

///////////////////////////////////////////////////////////////////////////////////////////////////

package org.distorted.objectlib.objects;

import org.distorted.library.type.Static3D;

import org.distorted.library.type.Static4D;

import org.distorted.objectlib.helpers.FactoryCubit;

import org.distorted.objectlib.helpers.ObjectFaceShape;

import org.distorted.objectlib.helpers.ObjectShape;

import org.distorted.objectlib.helpers.ObjectSignature;

import org.distorted.objectlib.helpers.ObjectVertexEffects;

import org.distorted.objectlib.main.InitData;

import org.distorted.objectlib.main.ObjectType;

import org.distorted.objectlib.shape.ShapeTetrahedron;

import org.distorted.objectlib.touchcontrol.TouchControlTetrahedron;

import java.io.InputStream;

import static org.distorted.objectlib.touchcontrol.TouchControl.TC_CHANGING_SHAPEMOD;

import static org.distorted.objectlib.touchcontrol.TouchControl.TYPE_NOT_SPLIT;

///////////////////////////////////////////////////////////////////////////////////////////////////

public class TwistyMorphix extends ShapeTetrahedron

{

  // size>=3: if length of the edge of the whole tetrahedron is = 1.0, then

  // length of the edge of the corner cubit is equal to DIST. (separate for size 3 and 4)

  private static final float DIST3 = 0.39f;

  private static final float DIST4 = 0.365f;

  static final Static3D[] ROT_AXIS = new Static3D[]

         {

           new Static3D( SQ2/2, 0.0f, SQ2/2),

           new Static3D(  0.0f, 1.0f,  0.0f),

           new Static3D( SQ2/2, 0.0f,-SQ2/2),

         };

  private int[][] mEdges;

  private int[][] mBasicAngle;

  private float[][] mCuts;

  private float[][] mCenters;

  private int[] mQuatIndex;

///////////////////////////////////////////////////////////////////////////////////////////////////

  public TwistyMorphix(InitData data, int meshState, int iconMode, Static4D quat, Static3D move, float scale, InputStream stream)

    {

    super(data, meshState, iconMode, data.getNumLayers()[0], quat, move, scale, stream);

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  @Override

  public float getPillowCoeff()

    {

    return 1.5f;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  @Override

  public int getInternalColor()

    {

    return getNumLayers()[0]==2 ? 0xff000000 : 0xff333333;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  private void insertSection(int[] table, int startIndex, int size, int startAlg, int state)

    {

    for(int i=0; i<size; i++)

      {

      table[2*(i+startIndex)  ] = startAlg +i;

      table[2*(i+startIndex)+1] = state;

      }

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  private int[] createEdge(int sizeX, int sizeY, int sizeZ, int stateX, int stateY, int stateZ)

    {

    int num = 0;

    if( stateX>=0 ) num += (3*sizeX);

    if( stateY>=0 ) num += (3*sizeY);

    if( stateZ>=0 ) num += (3*sizeZ);

    int[] ret = new int[2*num];

    if( stateX>=0 )

      {

      insertSection(ret,0,3*sizeX,0,stateX);

      if( stateY>=0 )

        {

        insertSection(ret,3*sizeX,3*sizeY,3*sizeX,stateY);

        if( stateZ>=0 ) insertSection(ret,3*sizeX+3*sizeY,3*sizeZ,3*sizeX+3*sizeY,stateZ);

        }

      else

        {

        insertSection(ret,3*sizeX,3*sizeZ,3*sizeX+3*sizeY,stateZ);

        }

      }

    else

      {

      if( stateY>=0 )

        {

        insertSection(ret,0,3*sizeY,3*sizeX,stateY);

        if( stateZ>=0 ) insertSection(ret,3*sizeY,3*sizeZ,3*sizeX+3*sizeY,stateZ);

        }

      else

        {

        insertSection(ret,0,3*sizeZ,3*sizeX+3*sizeY,stateZ);

        }

      }

    return ret;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

// same as in a non-flat cuboids

  public int[][] getScrambleEdges()

    {

    if( mEdges==null )

      {

      int[] numLayers = getNumLayers();

      int X = numLayers[0];

      int Y = numLayers[1];

      int Z = numLayers[2];

      mEdges = new int[][]

        {

        createEdge(X,Y,Z, 1, 2, 3), // 0 0

        createEdge(X,Y,Z,-1, 4, 5), // 1 x

        createEdge(X,Y,Z, 6,-1, 7), // 2 y

        createEdge(X,Y,Z, 8, 9,-1), // 3 z

        createEdge(X,Y,Z,10,-1, 7), // 4 xy

        createEdge(X,Y,Z,11, 9,-1), // 5 xz

        createEdge(X,Y,Z,-1,12, 5), // 6 yx

        createEdge(X,Y,Z, 8,13,-1), // 7 yz

        createEdge(X,Y,Z,-1, 4,14), // 8 zx

        createEdge(X,Y,Z, 6,-1,15), // 9 zy

        createEdge(X,Y,Z,-1,-1, 5), // 10 xyx

        createEdge(X,Y,Z,-1, 4,-1), // 11 xzx

        createEdge(X,Y,Z,-1,-1, 7), // 12 yxy

        createEdge(X,Y,Z, 6,-1,-1), // 13 yzy

        createEdge(X,Y,Z,-1, 9,-1), // 14 zxz

        createEdge(X,Y,Z, 8,-1,-1), // 15 zyz

        };

      }

    return mEdges;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  private int[] createEdges(int size, int vertex)

    {

    int[] ret = new int[9*size];

    for(int l=0; l<size; l++)

      {

      ret[9*l  ] = l;

      ret[9*l+1] =-1;

      ret[9*l+2] = vertex;

      ret[9*l+3] = l;

      ret[9*l+4] = 1;

      ret[9*l+5] = vertex;

      ret[9*l+6] = l;

      ret[9*l+7] = 2;

      ret[9*l+8] = vertex;

      }

    return ret;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public float[][] getCuts(int[] numLayers)

    {

    if( mCuts==null )

      {

      int numL = numLayers[0];

      float[] cut = new float[numL-1];

      float DIST = numL==3 ? DIST3:DIST4;

      float dist = numL*(SQ2/2)*(0.5f-DIST);

      switch(numL)

        {

        case 2: cut[0] = 0;

                break;

        case 3: cut[0] = -dist;

                cut[1] =  dist;

                break;

        case 4: cut[0] = -dist;

                cut[1] = 0.0f;

                cut[2] =  dist;

                break;

        }

      mCuts = new float[][] { cut,cut,cut };

      }

    return mCuts;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public boolean[][] getLayerRotatable(int[] numLayers)

    {

    int numL = numLayers[0];

    boolean[] tmp = new boolean[numL];

    for(int i=0; i<numL; i++) tmp[i] = true;

    return new boolean[][] { tmp,tmp,tmp };

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public int getTouchControlType()

    {

    return TC_CHANGING_SHAPEMOD;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public int getTouchControlSplit()

    {

    return TYPE_NOT_SPLIT;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public int[][][] getEnabled()

    {

    return null;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public float[] getDist3D(int[] numLayers)

    {

    return TouchControlTetrahedron.D3D;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public Static3D[] getFaceAxis()

    {

    return TouchControlTetrahedron.FACE_AXIS;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public float[][] getCubitPositions(int[] numLayers)

    {

    if( mCenters==null )

      {

      int numL = numLayers[0];

      float DIST = numL==3 ? DIST3:DIST4;

      final float C = numL==2 ? 1.0f : 6*numL*(0.25f-DIST/3);

      final float A = C*SQ2/6;

      final float B = C/3;

      final float D = (SQ2/12)*numL;

      final float E = (1.0f/6)*numL;

      if( numL==2 )

        {

        mCenters = new float[][]

           {

             {0.0f, -A,   +B},

             {0.0f, -A,   -B},

             {  +B,  A, 0.0f},

             {  -B,  A, 0.0f},

             {0.0f,  D,   +E},

             {0.0f,  D,   -E},

             {  +E, -D, 0.0f},

             {  -E, -D, 0.0f}

           };

        }

      else if( numL==3 )

        {

        final float X1 = 0.5f*(3*DIST-1)*numL;

        final float X2 = 0.5f*DIST*numL;

        final float X = 0.25f*numL*(1-DIST);

        final float Y = numL*(1-DIST)*(SQ2/4);

        final float F = 0.5f*(1-DIST)*numL - X2 + X1/2;

        final float G = 0.5f*F;

        final float H = (SQ2/2)*F;

        mCenters = new float[][]

           {

             {0.0f, -A,   +B},

             {0.0f, -A,   -B},

             {  +B,  A, 0.0f},

             {  -B,  A, 0.0f},

             {0.0f,  D,   +E},

             {0.0f,  D,   -E},

             {  +E, -D, 0.0f},

             {  -E, -D, 0.0f},

             {0.0f,  +Y,0.0f},

             {0.0f,  -Y,0.0f},

             {  +X,0.0f,  +X},

             {  +X,0.0f,  -X},

             {  -X,0.0f,  +X},

             {  -X,0.0f,  -X},

             {0.0f,0.0f,   F},

             {   G,   H,   G},

             {  -G,   H,   G},

             {0.0f,0.0f,  -F},

             {   G,   H,  -G},

             {  -G,   H,  -G},

             {   F,0.0f,0.0f},

             {   G,  -H,   G},

             {   G,  -H,  -G},

             {  -F,0.0f,0.0f},

             {  -G,  -H,   G},

             {  -G,  -H,  -G},

           };

        }

      else

        {

        final float X1 = 0.5f*(3*DIST-1)*numL;

        final float X2 = 0.5f*DIST*numL;

        final float X = 0.25f*numL*(1-DIST);

        final float Y = numL*(1-DIST)*(SQ2/4);

        final float Z = numL*(1-2*DIST)/(2*numL-4);

        final float F = 0.5f*(1-DIST)*numL - X2 + X1/2;

        final float G = 0.5f*F;

        final float H = (SQ2/2)*F;

        final float I = (0.25f-DIST/2)*numL;

        mCenters = new float[][]

           {

             {0.0f, -A,   +B},

             {0.0f, -A,   -B},

             {  +B,  A, 0.0f},

             {  -B,  A, 0.0f},

             {0.0f,  D,   +E},

             {0.0f,  D,   -E},

             {  +E, -D, 0.0f},

             {  -E, -D, 0.0f},

             {  +Z,  +Y,0.0f},

             {  -Z,  +Y,0.0f},

             {0.0f,  -Y,  +Z},

             {0.0f,  -Y,  -Z},

             {   X-Z/2,-(SQ2/2)*Z,   X+Z/2},

             {   X+Z/2, (SQ2/2)*Z,   X-Z/2},

             {   X-Z/2,-(SQ2/2)*Z,  -X-Z/2},

             {   X+Z/2, (SQ2/2)*Z,  -X+Z/2},

             {  -X+Z/2,-(SQ2/2)*Z,   X+Z/2},

             {  -X-Z/2, (SQ2/2)*Z,   X-Z/2},

             {  -X+Z/2,-(SQ2/2)*Z,  -X-Z/2},

             {  -X-Z/2, (SQ2/2)*Z,  -X+Z/2},

             {0.0f,-I*(SQ2/2),   F+I*0.5f},

             {   G+0.75f*I,   H+(SQ2/4)*I,   G-0.25f*I},

             {  -G-0.75f*I,   H+(SQ2/4)*I,   G-0.25f*I},

             {0.0f,-I*(SQ2/2),  -F-I*0.5f},

             {   G+0.75f*I,   H+(SQ2/4)*I,  -G+0.25f*I},

             {  -G-0.75f*I,   H+(SQ2/4)*I,  -G+0.25f*I},

             {   F+0.5f*I, I*(SQ2/2),0.0f},

             {   G-0.25f*I,  -H-(SQ2/4)*I,   G+0.75f*I},

             {   G-0.25f*I,  -H-(SQ2/4)*I,  -G-0.75f*I},

             {  -F-0.5f*I, I*(SQ2/2),0.0f},

             {  -G+0.25f*I,  -H-(SQ2/4)*I,   G+0.75f*I},

             {  -G+0.25f*I,  -H-(SQ2/4)*I,  -G-0.75f*I},

             {        0.0f,   I*(SQ2/2),     F+I*0.5f},

             {   G-0.25f*I,   H+(SQ2/4)*I,   G+0.75f*I},

             {  -G+0.25f*I,   H+(SQ2/4)*I,   G+0.75f*I},

             {        0.0f,   I*(SQ2/2),    -F-I*0.5f},

             {   G-0.25f*I,   H+(SQ2/4)*I,  -G-0.75f*I},

             {  -G+0.25f*I,   H+(SQ2/4)*I,  -G-0.75f*I},

             {   F+0.5f*I,   -I*(SQ2/2),          0.0f},

             {   G+0.75f*I,  -H-(SQ2/4)*I,   G-0.25f*I},

             {   G+0.75f*I,  -H-(SQ2/4)*I,  -G+0.25f*I},

             {  -F-0.5f*I,   -I*(SQ2/2),          0.0f},

             {  -G-0.75f*I,  -H-(SQ2/4)*I,   G-0.25f*I},

             {  -G-0.75f*I,  -H-(SQ2/4)*I,  -G+0.25f*I},

             {0.0f,    Y,   +Z},

             {0.0f,    Y,   -Z},

             {  +Z,   -Y, 0.0f},

             {  -Z,   -Y, 0.0f},

             { (SQ2/2)*Y-Z/2, (SQ2/2)*Z, (SQ2/2)*Y+Z/2},

             { (SQ2/2)*Y+Z/2,-(SQ2/2)*Z, (SQ2/2)*Y-Z/2},

             {-(SQ2/2)*Y+Z/2, (SQ2/2)*Z, (SQ2/2)*Y+Z/2},

             {-(SQ2/2)*Y-Z/2,-(SQ2/2)*Z, (SQ2/2)*Y-Z/2},

             { (SQ2/2)*Y-Z/2, (SQ2/2)*Z,-(SQ2/2)*Y-Z/2},

             { (SQ2/2)*Y+Z/2,-(SQ2/2)*Z,-(SQ2/2)*Y+Z/2},

             {-(SQ2/2)*Y+Z/2, (SQ2/2)*Z,-(SQ2/2)*Y-Z/2},

             {-(SQ2/2)*Y-Z/2,-(SQ2/2)*Z,-(SQ2/2)*Y+Z/2},

           };

        }

      }

    return mCenters;

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public Static4D getCubitQuats(int cubit, int[] numLayers)

    {

    if( mQuatIndex==null )

      {

      switch(numLayers[0])

        {

        case 2: mQuatIndex = new int[] { 0,5,2,8,

                                         0,5,2,8

                                       };

                break;

        case 3: mQuatIndex = new int[] { 0,5,2,8,

                                         0,5,2,8,

                                         0,2,15,10,20,13,

                                         0,21,15,5,13,10,2,12,23,8,22,20

                                       };

                break;

        default:mQuatIndex = new int[] { 0,5,2,8,

                                         0,5,2,8,

                                         0,0,2,2,15,15,10,10,20,20,13,13,

                                         0,21,15,5,13,10,2,12,23,8,22,20,

                                         0,21,15,5,13,10,2,12,23,8,22,20,

                                         0,5,2,8,15,23,21,20,10,12,13,22

                                       };

        }

      }

    return mObjectQuats[mQuatIndex[cubit]];

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  private float[][] getVertices(int variant)

    {

    int numL = getNumLayers()[0];

    float DIST = numL==3 ? DIST3:DIST4;

    if( variant==0 )

      {

      final float Z = numL==2 ? 1.0f : numL*DIST;

      final float Y = (SQ2/2)*Z;

      return new float[][]

          {

              {0.0f,-2*Y/3, 2*Z/3 },

              {0.0f,-2*Y/3,  -Z/3 },

              { Z/2,   Y/3,   Z/6 },

              {-Z/2,   Y/3,   Z/6 },

              {0.0f,   Y/3,  -Z/3 }

          };

      }

    else if( variant==1 )

      {

      final float X = numL==2 ? 1.0f : numL*(3*DIST-1);

      final float Y = (SQ2/2)*X;

      final float Z = 0.5f*X;

      return new float[][]

          {

              {-X/2,  -Y/3,   Z/3 },

              { X/2,  -Y/3,   Z/3 },

              {0.0f, 2*Y/3,-2*Z/3 },

              {0.0f,  -Y/3,-2*Z/3 }

          };

      }

    else if( variant==2 )

      {

      final float X = numL*(1-2*DIST)/(2*numL-4);

      final float Y = (SQ2/4)*DIST*numL;

      return new float[][]

          {

              {  +X,     +Y,  0.0f },

              {  -X,     +Y,  0.0f },

              {0.0f,Y-X*SQ2,    +X },

              {0.0f,Y-X*SQ2,    -X },

              {  +X,     -Y,  0.0f },

              {  -X,     -Y,  0.0f },

              {0.0f,     -Y,    +X },

              {0.0f,     -Y,    -X },

          };

      }

    else if( variant==3 )

      {

      final float C = numL==3 ? 3*DIST-1 : 2*DIST-0.5f;

      final float X1 = 0.5f*C*numL;

      final float X2 = 0.5f*DIST*numL;

      final float Y  = (SQ2/4)*numL*(1-2*DIST)/(numL-2);

      return new float[][]

          {

              {  +X1,+Y, X1/2 },

              {  -X1,+Y, X1/2 },

              { 0.0f,+Y,-X1/2 },

              {  +X2,-Y, X2-X1/2 },

              {  -X2,-Y, X2-X1/2 },

              { 0.0f,-Y,-X1/2 },

          };

      }

    else if( variant==4 )

      {

      final float X1 = 0.5f*(3*DIST-1)*numL;

      final float X2 = 0.5f*(2*DIST-0.5f)*numL;

      final float Y  = (SQ2/4)*numL*(1-2*DIST)/(numL-2);

      return new float[][]

          {

              {  +X1,+Y,+X1-X2/2 },

              {  -X1,+Y,+X1-X2/2 },

              { 0.0f,+Y,-X2/2 },

              {  +X2,-Y,+X2/2 },

              {  -X2,-Y,+X2/2 },

              { 0.0f,-Y,-X2/2 },

          };

      }

    else

      {

      final float X = numL*(1-2*DIST)/(2*numL-4);

      final float Y = (SQ2/4)*DIST*numL;

      return new float[][]

          {

              {  +X,  Y-X*SQ2,  0.0f },

              {  -X,  Y-X*SQ2,  0.0f },

              {0.0f,Y-2*X*SQ2,    +X },

              {0.0f,Y        ,    -X },

              {  +X,       -Y,  0.0f },

              {  -X,       -Y,  0.0f },

              {0.0f,       -Y,    +X },

              {0.0f,       -Y,    -X },

          };

      }

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public ObjectShape getObjectShape(int variant)

    {

    if( variant==0 )

      {

      int[][] indices = { {0,2,3},{0,1,2},{0,3,1},{4,2,1},{4,1,3},{4,3,2} };

      return new ObjectShape(getVertices(variant), indices);

      }

    else if( variant==1 )

      {

      int[][] indices = { {1,2,0},{3,1,0},{1,3,2},{3,0,2} };

      return new ObjectShape(getVertices(variant), indices);

      }

    else if( variant==2 )

      {

      int[][] indices = { {0,1,2},{0,3,1},{0,2,6,4},{2,1,5,6},{3,0,4,7},{1,3,7,5},{6,5,7,4} };

      return new ObjectShape(getVertices(variant), indices);

      }

    else if( variant==3 )

      {

      int[][] indices = { {0,1,4,3},{0,3,5,2},{2,5,4,1},{0,2,1},{5,3,4} };

      return new ObjectShape(getVertices(variant), indices);

      }

    else if( variant==4 )

      {

      int[][] indices = { {0,1,4,3},{0,3,5,2},{2,5,4,1},{0,2,1},{5,3,4} };

      return new ObjectShape(getVertices(variant), indices);

      }

    else

      {

      int[][] indices = { {3,1,2,0},{0,2,6,4},{2,1,5,6},{3,0,4,7},{1,3,7,5},{6,5,7,4} };

      return new ObjectShape(getVertices(variant), indices);

      }

    }

///////////////////////////////////////////////////////////////////////////////////////////////////

  public ObjectFaceShape getObjectFaceShape(int variant)

    {

    float height = isInIconMode() ? 0.001f : 0.03f;

    float internal = 0.02f;

    int numL = getNumLayers()[0];

    if( variant==0 )

      {

      float eV = numL==2 ? 2 : 0;

      float[][] bands = { {height,30,0.15f,0.5f,5,1,eV}, {internal,30,0.2f,0.4f,5,1,eV} };

      int[] indices   = { 0,0,0,1,1,1 };

      return new ObjectFaceShape(bands,indices,null);

      }

    else if( variant==1 )

      {

      float eI = numL==2 ? 1 : 0;

      float eV = numL==2 ? 1 : 0;

      int N = numL==2 ? 5 : 4;

      float[][] bands = { {height,30,0.15f,0.5f,N,eI,eV}, {internal,30,0.25f,0.5f,N,eI,eV} };

      int[] indices   = { 0,1,1,1 };

      return new ObjectFaceShape(bands,indices,null);

      }

    else if( variant==2 )

      {

      float[][] bands = { {height,30,0.15f,0.5f,5,1,0}, {internal,30,0.25f,0.5f,5,1,0} };

      int[] indices   = { 0,0,1,1,1,1,1 };

      return new ObjectFaceShape(bands,indices,null);

      }

    else if( variant==3 || variant==4 )

      {

      float[][] bands = { {height,30,0.15f,0.5f,5,0,0}, {internal,30,0.25f,0.5f,4,0,0} };

      int[] indices   = { 0,1,1,1,1 };

      return new ObjectFaceShape(bands,indices,null);

      }

    else

      {

      float[][] bands = { {height,30,0.15f,0.5f,5,0,0}, {internal,30,0.25f,0.5f,3,0,0} };

      int[] indices   = { 0,1,1,1,1,1 };

      return new ObjectFaceShape(bands,indices,null);

      }

    }

///////////////////////////////////////////////////////////////////////////////////////////////////