/src/main/java/org/distorted/objectlib/main/TwistyObject.java - Annotate - TwistyPuzzleLib - Distorted Android

distorted-objectlib / src / main / java / org / distorted / objectlib / main / TwistyObject.java @ 198c5bf0

-b82486
+///////////////////////////////////////////////////////////////////////////////////////////////////
 // Copyright 2020 Leszek Koltunski                                                               //
 //                                                                                               //
 // This file is part of Magic Cube.                                                              //
 //                                                                                               //
 // Magic Cube is free software: you can redistribute it and/or modify                            //
 // it under the terms of the GNU General Public License as published by                          //
 // the Free Software Foundation, either version 2 of the License, or                             //
 // (at your option) any later version.                                                           //
 //                                                                                               //
 // Magic Cube is distributed in the hope that it will be useful,                                 //
 // but WITHOUT ANY WARRANTY; without even the implied warranty of                                //
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the                                 //
 // GNU General Public License for more details.                                                  //
 //                                                                                               //
 // You should have received a copy of the GNU General Public License                             //
 // along with Magic Cube.  If not, see <http://www.gnu.org/licenses/>.                           //
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 package org.distorted.objectlib.main;
 import android.content.SharedPreferences;
 import android.content.res.Resources;
 import android.graphics.Bitmap;
 import android.graphics.Canvas;
 import android.graphics.Paint;
 import com.google.firebase.crashlytics.FirebaseCrashlytics;
 import org.distorted.library.effect.Effect;
 import org.distorted.library.effect.MatrixEffectMove;
 import org.distorted.library.effect.MatrixEffectQuaternion;
 import org.distorted.library.effect.MatrixEffectScale;
 import org.distorted.library.effect.VertexEffectQuaternion;
 import org.distorted.library.effect.VertexEffectRotate;
 import org.distorted.library.main.DistortedEffects;
 import org.distorted.library.main.DistortedLibrary;
 import org.distorted.library.main.DistortedNode;
 import org.distorted.library.main.DistortedTexture;
-            a706f8e0
+import org.distorted.library.main.QuatHelper;
-b82486
+import org.distorted.library.mesh.MeshBase;
 import org.distorted.library.mesh.MeshFile;
 import org.distorted.library.mesh.MeshJoined;
 import org.distorted.library.mesh.MeshSquare;
 import org.distorted.library.message.EffectListener;
 import org.distorted.library.type.Dynamic1D;
 import org.distorted.library.type.Static1D;
 import org.distorted.library.type.Static3D;
 import org.distorted.library.type.Static4D;
 import org.distorted.objectlib.BuildConfig;
-c5bf0
+import org.distorted.objectlib.helpers.FactoryCubit;
 import org.distorted.objectlib.helpers.FactorySticker;
 import org.distorted.objectlib.helpers.ObjectShape;
 import org.distorted.objectlib.helpers.ObjectSticker;
 import org.distorted.objectlib.helpers.ScrambleState;
-b82486
+            Leszek Koltunski
 import java.io.DataInputStream;
 import java.io.IOException;
 import java.io.InputStream;
 import java.util.Random;
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 public abstract class TwistyObject extends DistortedNode
+  {
   public static final int COLOR_YELLOW = 0xffffff00;
   public static final int COLOR_WHITE  = 0xffffffff;
   public static final int COLOR_BLUE   = 0xff0000ff;
   public static final int COLOR_GREEN  = 0xff00bb00;
   public static final int COLOR_RED    = 0xff990000;
   public static final int COLOR_ORANGE = 0xffff6200;
   public static final int COLOR_GREY   = 0xff727c7b;
   public static final int COLOR_VIOLET = 0xff7700bb;
   public static final int COLOR_BLACK  = 0xff000000;
   public static final int TEXTURE_HEIGHT = 256;
   static final int NUM_STICKERS_IN_ROW = 4;
   public static final float SQ2 = (float)Math.sqrt(2);
   public static final float SQ3 = (float)Math.sqrt(3);
   public static final float SQ5 = (float)Math.sqrt(5);
   public static final float SQ6 = (float)Math.sqrt(6);
   private static final float NODE_RATIO = 1.60f;
   private static final float MAX_SIZE_CHANGE = 1.35f;
   private static final float MIN_SIZE_CHANGE = 0.75f;
   private static final Static3D CENTER = new Static3D(0,0,0);
   private static final int POST_ROTATION_MILLISEC = 500;
   protected final int NUM_FACE_COLORS;
   protected final int NUM_TEXTURES;
   protected final Cubit[] CUBITS;
   MeshBase[] mMeshes;
   final Static4D[] OBJECT_QUATS;
   final int NUM_CUBITS;
   final int NUM_AXIS;
   final int NUM_QUATS;
   private final int mNumCubitFaces;
   private final Static3D[] mAxis;
   private final float[][] mCuts;
   private final int[] mNumCuts;
   private final int mNodeSize;
   private final float[][] mOrigPos;
   private final Static3D mNodeScale;
   private final Static4D mQuat;
   private final int mNumLayers, mRealSize;
   private final DistortedEffects mEffects;
   private final VertexEffectRotate mRotateEffect;
   private final Dynamic1D mRotationAngle;
   private final Static3D mRotationAxis;
   private final Static3D mObjectScale;
   private final int[] mQuatDebug;
   private final float mCameraDist;
   private final Static1D mRotationAngleStatic, mRotationAngleMiddle, mRotationAngleFinal;
   private final DistortedTexture mTexture;
   private final float mInitScreenRatio;
   private final int mSolvedFunctionIndex;
   private final boolean mIsBandaged;
   private float mObjectScreenRatio;
   private int[][] mSolvedQuats;
   private int[][] mQuatMult;
   private int[] mTmpQuats;
   private int mNumTexRows, mNumTexCols;
   private int mRotRowBitmap;
   private int mRotAxis;
   private MeshBase mMesh;
   private final TwistyObjectScrambler mScrambler;
   //////////////////// SOLVED1 ////////////////////////
   private int[] mFaceMap;
   private int[][] mScramble;
   private int[] mColors;
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   TwistyObject(int numLayers, int realSize, Static4D quat, DistortedTexture nodeTexture, MeshSquare nodeMesh,
-aa85e4
+               DistortedEffects nodeEffects, int[][] moves, Resources res, int screenWidth)
-b82486
+            Leszek Koltunski
     super(nodeTexture,nodeEffects,nodeMesh);
     mNodeSize = screenWidth;
     resizeFBO(mNodeSize, (int)(NODE_RATIO*mNodeSize));
     mNumLayers = numLayers;
     mRealSize = realSize;
     mOrigPos = getCubitPositions(mNumLayers);
     mAxis = getRotationAxis();
     mInitScreenRatio = getScreenRatio();
     mObjectScreenRatio = 1.0f;
     mNumCubitFaces = getNumCubitFaces();
     mSolvedFunctionIndex = getSolvedFunctionIndex();
     mCuts = getCuts(mNumLayers);
     mNumCuts = new int[mAxis.length];
     if( mCuts==null ) for(int i=0; i<mAxis.length; i++) mNumCuts[i] = 0;
     else              for(int i=0; i<mAxis.length; i++) mNumCuts[i] = mCuts[i].length;
     OBJECT_QUATS = getQuats();
     NUM_CUBITS  = mOrigPos.length;
     NUM_FACE_COLORS = getNumFaceColors();
     NUM_TEXTURES = getNumStickerTypes(mNumLayers)*NUM_FACE_COLORS;
     NUM_AXIS = mAxis.length;
     NUM_QUATS = OBJECT_QUATS.length;
     int scramblingType = getScrambleType();
     ScrambleState[] states = getScrambleStates();
     mScrambler = new TwistyObjectScrambler(scramblingType,NUM_AXIS,numLayers,states);
     boolean bandaged=false;
     for(int c=0; c<NUM_CUBITS; c++)
+      {
       if( mOrigPos[c].length>3 )
+        {
         bandaged=true;
         break;
+        }
+      }
     mIsBandaged = bandaged;
     mQuatDebug = new int[NUM_CUBITS];
     if( mObjectScreenRatio>MAX_SIZE_CHANGE) mObjectScreenRatio = MAX_SIZE_CHANGE;
     if( mObjectScreenRatio<MIN_SIZE_CHANGE) mObjectScreenRatio = MIN_SIZE_CHANGE;
-            e607083f
+    mNodeScale= new Static3D(screenWidth,NODE_RATIO*screenWidth,screenWidth);
-b82486
+    mQuat = quat;
     mRotationAngle= new Dynamic1D();
     mRotationAxis = new Static3D(1,0,0);
     mRotateEffect = new VertexEffectRotate(mRotationAngle, mRotationAxis, CENTER);
     mRotationAngleStatic = new Static1D(0);
     mRotationAngleMiddle = new Static1D(0);
     mRotationAngleFinal  = new Static1D(0);
     float scale  = mObjectScreenRatio*mInitScreenRatio*mNodeSize/mRealSize;
     mObjectScale = new Static3D(scale,scale,scale);
     MatrixEffectScale scaleEffect = new MatrixEffectScale(mObjectScale);
     MatrixEffectQuaternion quatEffect  = new MatrixEffectQuaternion(quat, CENTER);
     MatrixEffectScale nodeScaleEffect = new MatrixEffectScale(mNodeScale);
     nodeEffects.apply(nodeScaleEffect);
     mNumTexCols = NUM_STICKERS_IN_ROW;
     mNumTexRows = (NUM_TEXTURES+1)/NUM_STICKERS_IN_ROW;
     if( mNumTexCols*mNumTexRows < NUM_TEXTURES+1 ) mNumTexRows++;
     CUBITS = new Cubit[NUM_CUBITS];
-aa85e4
+    createMeshAndCubits(res);
-b82486
+    createDataStructuresForSolved(numLayers);
     mTexture = new DistortedTexture();
     mEffects = new DistortedEffects();
-a316d92
+    createTexture();
-b82486
+    for(int q=0; q<NUM_QUATS; q++)
+      {
       VertexEffectQuaternion vq = new VertexEffectQuaternion(OBJECT_QUATS[q],CENTER);
       vq.setMeshAssociation(0,q);
       mEffects.apply(vq);
+      }
     mEffects.apply(mRotateEffect);
     mEffects.apply(quatEffect);
     mEffects.apply(scaleEffect);
     // Now postprocessed effects (the glow when you solve an object) require component centers. In
     // order for the effect to be in front of the object, we need to set the center to be behind it.
     getMesh().setComponentCenter(0,0,0,-0.1f);
     attach( new DistortedNode(mTexture,mEffects,mMesh) );
     setupPosition(moves);
     float fov = getFOV();
     double halfFOV = fov * (Math.PI/360);
     mCameraDist = 0.5f*NODE_RATIO / (float)Math.tan(halfFOV);
     setProjection( fov, 0.1f);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private Static3D getPos(float[] origPos)
+    {
     int len = origPos.length/3;
     float sumX = 0.0f;
     float sumY = 0.0f;
     float sumZ = 0.0f;
     for(int i=0; i<len; i++)
+      {
       sumX += origPos[3*i  ];
       sumY += origPos[3*i+1];
       sumZ += origPos[3*i+2];
+      }
     sumX /= len;
     sumY /= len;
     sumZ /= len;
     return new Static3D(sumX,sumY,sumZ);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-aa85e4
+  private void createMeshAndCubits(Resources res)
-b82486
+            Leszek Koltunski
-e1dc313
+    int resourceID= getResource(mNumLayers);
-b82486
+            Leszek Koltunski
     if( resourceID!=0 )
+      {
       InputStream is = res.openRawResource(resourceID);
       DataInputStream dos = new DataInputStream(is);
       mMesh = new MeshFile(dos);
       try
+        {
         is.close();
+        }
       catch(IOException e)
+        {
         android.util.Log.e("meshFile", "Error closing InputStream: "+e.toString());
+        }
       for(int i=0; i<NUM_CUBITS; i++)
+        {
         CUBITS[i] = new Cubit(this,mOrigPos[i], NUM_AXIS);
         mMesh.setEffectAssociation(i, CUBITS[i].computeAssociation(), 0);
+        }
       if( shouldResetTextureMaps() ) resetAllTextureMaps();
+      }
     else
+      {
       MeshBase[] cubitMesh = new MeshBase[NUM_CUBITS];
       for(int i=0; i<NUM_CUBITS; i++)
+        {
         CUBITS[i] = new Cubit(this,mOrigPos[i], NUM_AXIS);
         cubitMesh[i] = createCubitMesh(i,mNumLayers);
         Static3D pos = getPos(mOrigPos[i]);
         cubitMesh[i].apply(new MatrixEffectMove(pos),1,0);
         cubitMesh[i].setEffectAssociation(0, CUBITS[i].computeAssociation(), 0);
+        }
       mMesh = new MeshJoined(cubitMesh);
       resetAllTextureMaps();
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private MeshBase createCubitMesh(int cubit, int numLayers)
+    {
     int variant = getCubitVariant(cubit,numLayers);
     if( mMeshes==null )
+      {
       FactoryCubit factory = FactoryCubit.getInstance();
       factory.clear();
       mMeshes = new MeshBase[getNumCubitVariants(numLayers)];
+      }
     if( mMeshes[variant]==null )
+      {
       ObjectShape shape = getObjectShape(cubit,numLayers);
       FactoryCubit factory = FactoryCubit.getInstance();
       factory.createNewFaceTransform(shape);
       mMeshes[variant] = factory.createRoundedSolid(shape);
+      }
     MeshBase mesh = mMeshes[variant].copy(true);
     MatrixEffectQuaternion quat = new MatrixEffectQuaternion( getQuat(cubit,numLayers), new Static3D(0,0,0) );
     mesh.apply(quat,0xffffffff,0);
     return mesh;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private void createDataStructuresForSolved(int numLayers)
+    {
     mTmpQuats = new int[NUM_QUATS];
     mSolvedQuats = new int[NUM_CUBITS][];
     for(int c=0; c<NUM_CUBITS; c++)
+      {
       mSolvedQuats[c] = getSolvedQuats(c,numLayers);
+      }
+    }
-            c8bc83d9
+///////////////////////////////////////////////////////////////////////////////////////////////////
   private int getMultQuat(int index1, int index2)
+    {
     if( mQuatMult==null )
+      {
       mQuatMult = new int[NUM_QUATS][NUM_QUATS];
       for(int i=0; i<NUM_QUATS; i++)
         for(int j=0; j<NUM_QUATS; j++) mQuatMult[i][j] = -1;
+      }
     if( mQuatMult[index1][index2]==-1 )
+      {
       mQuatMult[index1][index2] = mulQuat(index1,index2);
+      }
     return mQuatMult[index1][index2];
+    }
-b82486
+///////////////////////////////////////////////////////////////////////////////////////////////////
 // This is used to build internal data structures for the generic 'isSolved()'
 //
 // if this is an internal cubit (all faces black): return -1
 // if this is a face cubit (one non-black face): return the color index of the only non-black face.
 // Color index, i.e. the index into the 'FACE_COLORS' table.
 // else (edge or corner cubit, more than one non-black face): return -2.
-            c8bc83d9
+  protected int retCubitSolvedStatus(int cubit, int numLayers)
-b82486
+            Leszek Koltunski
     int numNonBlack=0, nonBlackIndex=-1, color;
     for(int face=0; face<mNumCubitFaces; face++)
+      {
       color = getFaceColor(cubit,face,numLayers);
       if( color<NUM_TEXTURES )
+        {
         numNonBlack++;
         nonBlackIndex = color%NUM_FACE_COLORS;
+        }
+      }
     if( numNonBlack==0 ) return -1;
     if( numNonBlack>=2 ) return -2;
     return nonBlackIndex;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-            c8bc83d9
+  protected boolean shouldResetTextureMaps()
-b82486
+            Leszek Koltunski
     return false;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-            c8bc83d9
+  protected int[] buildSolvedQuats(Static3D faceAx, Static4D[] quats)
-b82486
+            Leszek Koltunski
     final float MAXD = 0.0001f;
     float x = faceAx.get0();
     float y = faceAx.get1();
     float z = faceAx.get2();
     float a,dx,dy,dz,qx,qy,qz;
     Static4D quat;
     int len = quats.length;
     int place = 0;
     for(int q=1; q<len; q++)
+      {
       quat = quats[q];
       qx = quat.get0();
       qy = quat.get1();
       qz = quat.get2();
            if( x!=0.0f ) { a = qx/x; }
       else if( y!=0.0f ) { a = qy/y; }
       else               { a = qz/z; }
       dx = a*x-qx;
       dy = a*y-qy;
       dz = a*z-qz;
       if( dx>-MAXD && dx<MAXD && dy>-MAXD && dy<MAXD && dz>-MAXD && dz<MAXD )
+        {
         mTmpQuats[place++] = q;
+        }
+      }
     if( place!=0 )
+      {
       int[] ret = new int[place];
       System.arraycopy(mTmpQuats,0,ret,0,place);
       return ret;
+      }
     return null;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-            c8bc83d9
+  private boolean isSolved0()
-b82486
+            Leszek Koltunski
     int len, q1,q = CUBITS[0].mQuatIndex;
     int[] solved;
     boolean skip;
     for(int c=1; c<NUM_CUBITS; c++)
+      {
       q1 = CUBITS[c].mQuatIndex;
       if( q1==q ) continue;
       skip = false;
       solved = mSolvedQuats[c];
       len = solved==null ? 0:solved.length;
       for(int i=0; i<len; i++)
+        {
         if( q1==getMultQuat(q,solved[i]) )
+          {
           skip = true;
           break;
+          }
+        }
       if( !skip ) return false;
+      }
     return true;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private int computeScramble(int quatNum, int centerNum)
+    {
     float MAXDIFF = 0.01f;
     float[] center= mOrigPos[centerNum];
     Static4D sc = new Static4D(center[0], center[1], center[2], 1.0f);
     Static4D result = QuatHelper.rotateVectorByQuat(sc,OBJECT_QUATS[quatNum]);
     float x = result.get0();
     float y = result.get1();
     float z = result.get2();
     for(int c=0; c<NUM_CUBITS; c++)
+      {
       float[] cent = mOrigPos[c];
       float qx = cent[0] - x;
       float qy = cent[1] - y;
       float qz = cent[2] - z;
       if( qx>-MAXDIFF && qx<MAXDIFF &&
           qy>-MAXDIFF && qy<MAXDIFF &&
           qz>-MAXDIFF && qz<MAXDIFF  ) return c;
+      }
     return -1;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Dino4 uses this. It is solved if and only if groups of cubits
 // (0,3,7), (1,2,5), (4,8,9), (6,10,11)
 // or
 // (0,1,4), (2,3,6), (5,9,10), (7,8,11)
 // are all the same color.
-            c8bc83d9
+  private boolean isSolved1()
-b82486
+            Leszek Koltunski
     if( mScramble==null )
+      {
       mScramble = new int[NUM_QUATS][NUM_CUBITS];
       mColors   = new int[NUM_CUBITS];
       for(int q=0; q<NUM_QUATS; q++)
         for(int c=0; c<NUM_CUBITS; c++) mScramble[q][c] = computeScramble(q,c);
+      }
     if( mFaceMap==null )
+      {
       mFaceMap = new int[] { 4, 2, 2, 4, 0, 2, 1, 4, 0, 0, 1, 1 };
+      }
     for(int c=0; c<NUM_CUBITS; c++)
+      {
       int index = mScramble[CUBITS[c].mQuatIndex][c];
       mColors[index] = mFaceMap[c];
+      }
     if( mColors[0]==mColors[3] && mColors[0]==mColors[7] &&
         mColors[1]==mColors[2] && mColors[1]==mColors[5] &&
         mColors[4]==mColors[8] && mColors[4]==mColors[9]  ) return true;
     if( mColors[0]==mColors[1] && mColors[0]==mColors[4] &&
         mColors[2]==mColors[3] && mColors[2]==mColors[6] &&
         mColors[5]==mColors[9] && mColors[5]==mColors[10] ) return true;
     return false;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Dino6 uses this. It is solved if and only if:
 //
 // All four 'X' cubits (i.e. those whose longest edge goes along the X axis) are rotated
 // by the same quaternion qX, similarly all four 'Y' cubits by the same qY and all four 'Z'
 // by the same qZ, and then either:
 //
 // a) qX = qY = qZ
 // b) qY = qX*Q2 and qZ = qX*Q8  (i.e. swap of WHITE and YELLOW faces)
 // c) qX = qY*Q2 and qZ = qY*Q10 (i.e. swap of BLUE and GREEN faces)
 // d) qX = qZ*Q8 and qY = qZ*Q10 (i.e. swap of RED and BROWN faces)
 //
 // BUT: cases b), c) and d) are really the same - it's all just a mirror image of the original.
 //
 // X cubits: 0, 2, 8, 10
 // Y cubits: 1, 3, 9, 11
 // Z cubits: 4, 5, 6, 7
-            c8bc83d9
+  private boolean isSolved2()
-b82486
+            Leszek Koltunski
     int qX = CUBITS[0].mQuatIndex;
     int qY = CUBITS[1].mQuatIndex;
     int qZ = CUBITS[4].mQuatIndex;
     if( CUBITS[2].mQuatIndex != qX || CUBITS[8].mQuatIndex != qX || CUBITS[10].mQuatIndex != qX ||
         CUBITS[3].mQuatIndex != qY || CUBITS[9].mQuatIndex != qY || CUBITS[11].mQuatIndex != qY ||
         CUBITS[5].mQuatIndex != qZ || CUBITS[6].mQuatIndex != qZ || CUBITS[ 7].mQuatIndex != qZ  )
+      {
       return false;
+      }
     return ( qX==qY && qX==qZ ) || ( qY==mulQuat(qX,2) && qZ==mulQuat(qX,8) );
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Square-2 is solved iff
 // a) all of its cubits are rotated with the same quat
 // b) its two 'middle' cubits are rotated with the same quat, the 6 'front' and 6 'back'
 // edges and corners with this quat multiplied by QUATS[18] (i.e. those are upside down)
 // and all the 12 left and right edges and corners also with the same quat multiplied by
 // QUATS[12] - i.e. also upside down.
-            c8bc83d9
+  private boolean isSolved3()
-b82486
+            Leszek Koltunski
     int index = CUBITS[0].mQuatIndex;
     if( CUBITS[1].mQuatIndex!=index ) return false;
     boolean solved = true;
     for(int i=2; i<NUM_CUBITS; i++)
+      {
       if( CUBITS[i].mQuatIndex!=index )
+        {
         solved = false;
         break;
+        }
+      }
     if( solved ) return true;
     int indexX = mulQuat(index,12);  // QUATS[12] = 180deg (1,0,0)
     int indexZ = mulQuat(index,18);  // QUATS[18] = 180deg (0,0,1)
     for(int i= 2; i<        18; i+=2) if( CUBITS[i].mQuatIndex != indexZ ) return false;
     for(int i= 3; i<        18; i+=2) if( CUBITS[i].mQuatIndex != indexX ) return false;
     for(int i=18; i<NUM_CUBITS; i+=2) if( CUBITS[i].mQuatIndex != indexX ) return false;
     for(int i=19; i<NUM_CUBITS; i+=2) if( CUBITS[i].mQuatIndex != indexZ ) return false;
     return true;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   int computeRow(float[] pos, int axisIndex)
+    {
     int ret=0;
     int len = pos.length / 3;
     Static3D axis = mAxis[axisIndex];
     float axisX = axis.get0();
     float axisY = axis.get1();
     float axisZ = axis.get2();
     float casted;
     for(int i=0; i<len; i++)
+      {
       casted = pos[3*i]*axisX + pos[3*i+1]*axisY + pos[3*i+2]*axisZ;
       ret |= computeSingleRow(axisIndex,casted);
+      }
     return ret;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private int computeSingleRow(int axisIndex,float casted)
+    {
     int num = mNumCuts[axisIndex];
     for(int i=0; i<num; i++)
+      {
       if( casted<mCuts[axisIndex][i] ) return (1<<i);
+      }
     return (1<<num);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private boolean wasRotateApplied()
+    {
     return mEffects.exists(mRotateEffect.getID());
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private boolean belongsToRotation( int cubit, int axis, int rowBitmap)
+    {
     return (CUBITS[cubit].getRotRow(axis) & rowBitmap) != 0;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // note the minus in front of the sin() - we rotate counterclockwise
 // when looking towards the direction where the axis increases in values.
   private Static4D makeQuaternion(int axisIndex, int angleInDegrees)
+    {
     Static3D axis = mAxis[axisIndex];
     while( angleInDegrees<0 ) angleInDegrees += 360;
     angleInDegrees %= 360;
     float cosA = (float)Math.cos(Math.PI*angleInDegrees/360);
     float sinA =-(float)Math.sqrt(1-cosA*cosA);
     return new Static4D(axis.get0()*sinA, axis.get1()*sinA, axis.get2()*sinA, cosA);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private synchronized void setupPosition(int[][] moves)
+    {
     if( moves!=null )
+      {
       Static4D quat;
       int index, axis, rowBitmap, angle;
       int[] basic = getBasicAngle();
       for(int[] move: moves)
+        {
         axis     = move[0];
         rowBitmap= move[1];
         angle    = move[2]*(360/basic[axis]);
         quat     = makeQuaternion(axis,angle);
         for(int j=0; j<NUM_CUBITS; j++)
           if( belongsToRotation(j,axis,rowBitmap) )
+            {
             index = CUBITS[j].removeRotationNow(quat);
             mMesh.setEffectAssociation(j, CUBITS[j].computeAssociation(),index);
+            }
+        }
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-ac32
+  protected int getScrambleType()
-b82486
+            Leszek Koltunski
     return 0;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   int computeBitmapFromRow(int rowBitmap, int axis)
+    {
     if( mIsBandaged )
+      {
       int bitmap, initBitmap=0;
       while( initBitmap!=rowBitmap )
+        {
         initBitmap = rowBitmap;
         for(int cubit=0; cubit<NUM_CUBITS; cubit++)
+          {
           bitmap = CUBITS[cubit].getRotRow(axis);
           if( (rowBitmap & bitmap) != 0 ) rowBitmap |= bitmap;
+          }
+        }
+      }
     return rowBitmap;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Clamp all rotated positions to one of those original ones to avoid accumulating errors.
 // Do so only if minimal Error is appropriately low (shape-shifting puzzles - Square-1)
   void clampPos(float[] pos, int offset)
+    {
     float currError, minError = Float.MAX_VALUE;
     int minErrorIndex1 = -1;
     int minErrorIndex2 = -1;
     float x = pos[offset  ];
     float y = pos[offset+1];
     float z = pos[offset+2];
     float xo,yo,zo;
     for(int i=0; i<NUM_CUBITS; i++)
+      {
       int len = mOrigPos[i].length / 3;
       for(int j=0; j<len; j++)
+        {
         xo = mOrigPos[i][3*j  ];
         yo = mOrigPos[i][3*j+1];
         zo = mOrigPos[i][3*j+2];
         currError = (xo-x)*(xo-x) + (yo-y)*(yo-y) + (zo-z)*(zo-z);
         if( currError<minError )
+          {
           minError = currError;
           minErrorIndex1 = i;
           minErrorIndex2 = j;
+          }
+        }
+      }
     if( minError< 0.1f ) // TODO: 0.1 ?
+      {
       pos[offset  ] = mOrigPos[minErrorIndex1][3*minErrorIndex2  ];
       pos[offset+1] = mOrigPos[minErrorIndex1][3*minErrorIndex2+1];
       pos[offset+2] = mOrigPos[minErrorIndex1][3*minErrorIndex2+2];
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // remember about the double cover or unit quaternions!
   int mulQuat(int q1, int q2)
+    {
     Static4D result = QuatHelper.quatMultiply(OBJECT_QUATS[q1],OBJECT_QUATS[q2]);
     float rX = result.get0();
     float rY = result.get1();
     float rZ = result.get2();
     float rW = result.get3();
     final float MAX_ERROR = 0.1f;
     float dX,dY,dZ,dW;
     for(int i=0; i<NUM_QUATS; i++)
+      {
       dX = OBJECT_QUATS[i].get0() - rX;
       dY = OBJECT_QUATS[i].get1() - rY;
       dZ = OBJECT_QUATS[i].get2() - rZ;
       dW = OBJECT_QUATS[i].get3() - rW;
       if( dX<MAX_ERROR && dX>-MAX_ERROR &&
           dY<MAX_ERROR && dY>-MAX_ERROR &&
           dZ<MAX_ERROR && dZ>-MAX_ERROR &&
           dW<MAX_ERROR && dW>-MAX_ERROR  ) return i;
       dX = OBJECT_QUATS[i].get0() + rX;
       dY = OBJECT_QUATS[i].get1() + rY;
       dZ = OBJECT_QUATS[i].get2() + rZ;
       dW = OBJECT_QUATS[i].get3() + rW;
       if( dX<MAX_ERROR && dX>-MAX_ERROR &&
           dY<MAX_ERROR && dY>-MAX_ERROR &&
           dZ<MAX_ERROR && dZ>-MAX_ERROR &&
           dW<MAX_ERROR && dW>-MAX_ERROR  ) return i;
+      }
     return -1;
+    }
-            c8bc83d9
+///////////////////////////////////////////////////////////////////////////////////////////////////
   private float getAngle()
+    {
     int pointNum = mRotationAngle.getNumPoints();
     if( pointNum>=1 )
+      {
       return mRotationAngle.getPoint(pointNum-1).get0();
+      }
     else
+      {
       FirebaseCrashlytics crashlytics = FirebaseCrashlytics.getInstance();
       crashlytics.log("points in RotationAngle: "+pointNum);
       return 0;
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   private void recordQuatsState(String message)
+    {
     StringBuilder quats = new StringBuilder();
     for(int j=0; j<NUM_CUBITS; j++)
+      {
       quats.append(mQuatDebug[j]);
       quats.append(" ");
+      }
     String name = intGetObjectType(mNumLayers).name();
     if( BuildConfig.DEBUG )
+      {
       android.util.Log.e("quats" , quats.toString());
       android.util.Log.e("object", name);
+      }
     else
+      {
       Exception ex = new Exception(message);
       FirebaseCrashlytics crashlytics = FirebaseCrashlytics.getInstance();
       crashlytics.setCustomKey("quats" , quats.toString());
       crashlytics.setCustomKey("object", name);
       crashlytics.recordException(ex);
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // PUBLIC API
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public boolean isSolved()
+    {
     if( mSolvedFunctionIndex==0 ) return isSolved0();
     if( mSolvedFunctionIndex==1 ) return isSolved1();
     if( mSolvedFunctionIndex==2 ) return isSolved2();
     if( mSolvedFunctionIndex==3 ) return isSolved3();
     return false;
+    }
-c5bf0
+///////////////////////////////////////////////////////////////////////////////////////////////////
 // the getFaceColors + final black in a grid (so that we do not exceed the maximum texture size)
   public void createTexture()
+    {
     Bitmap bitmap;
     Paint paint = new Paint();
     bitmap = Bitmap.createBitmap( mNumTexCols*TEXTURE_HEIGHT, mNumTexRows*TEXTURE_HEIGHT, Bitmap.Config.ARGB_8888);
     Canvas canvas = new Canvas(bitmap);
     paint.setAntiAlias(true);
     paint.setTextAlign(Paint.Align.CENTER);
     paint.setStyle(Paint.Style.FILL);
     paint.setColor(COLOR_BLACK);
     canvas.drawRect(0, 0, mNumTexCols*TEXTURE_HEIGHT, mNumTexRows*TEXTURE_HEIGHT, paint);
     int face = 0;
     FactorySticker factory = FactorySticker.getInstance();
     for(int row=0; row<mNumTexRows; row++)
       for(int col=0; col<mNumTexCols; col++)
+        {
         if( face>=NUM_TEXTURES ) break;
         ObjectSticker sticker = retSticker(face);
         factory.drawRoundedPolygon(canvas, paint, col*TEXTURE_HEIGHT, row*TEXTURE_HEIGHT, getColor(face%NUM_FACE_COLORS), sticker);
         face++;
+        }
     if( !mTexture.setTexture(bitmap) )
+      {
       int max = DistortedLibrary.getMaxTextureSize();
       FirebaseCrashlytics crashlytics = FirebaseCrashlytics.getInstance();
       crashlytics.log("failed to set texture of size "+bitmap.getWidth()+"x"+bitmap.getHeight()+" max is "+max);
+      }
+    }
-            c8bc83d9
+///////////////////////////////////////////////////////////////////////////////////////////////////
   public void setObjectRatio(float sizeChange)
+    {
     mObjectScreenRatio *= (1.0f+sizeChange)/2;
     if( mObjectScreenRatio>MAX_SIZE_CHANGE) mObjectScreenRatio = MAX_SIZE_CHANGE;
     if( mObjectScreenRatio<MIN_SIZE_CHANGE) mObjectScreenRatio = MIN_SIZE_CHANGE;
     float scale = mObjectScreenRatio*mInitScreenRatio*mNodeSize/mRealSize;
     mObjectScale.set(scale,scale,scale);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public float getObjectRatio()
+    {
     return mObjectScreenRatio*mInitScreenRatio;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public int getCubitFaceColorIndex(int cubit, int face)
+    {
     Static4D texMap = mMesh.getTextureMap(NUM_FACE_COLORS*cubit + face);
     int x = (int)(texMap.get0()/texMap.get2());
     int y = (int)(texMap.get1()/texMap.get3());
     return (mNumTexRows-1-y)*NUM_STICKERS_IN_ROW + x;
+    }
-b82486
+///////////////////////////////////////////////////////////////////////////////////////////////////
   public int getNumLayers()
+    {
     return mNumLayers;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void continueRotation(float angleInDegrees)
+    {
     mRotationAngleStatic.set0(angleInDegrees);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public Static4D getRotationQuat()
+      {
       return mQuat;
+      }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void recomputeScaleFactor(int scrWidth)
+    {
     mNodeScale.set(scrWidth,NODE_RATIO*scrWidth,scrWidth);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void savePreferences(SharedPreferences.Editor editor)
+    {
     for(int i=0; i<NUM_CUBITS; i++) CUBITS[i].savePreferences(editor);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public synchronized void restorePreferences(SharedPreferences preferences)
+    {
     boolean error = false;
     for(int i=0; i<NUM_CUBITS; i++)
+      {
       mQuatDebug[i] = CUBITS[i].restorePreferences(preferences);
       if( mQuatDebug[i]>=0 && mQuatDebug[i]<NUM_QUATS)
+        {
         CUBITS[i].modifyCurrentPosition(OBJECT_QUATS[mQuatDebug[i]]);
         mMesh.setEffectAssociation(i, CUBITS[i].computeAssociation(),mQuatDebug[i]);
+        }
       else
+        {
         error = true;
+        }
+      }
     if( error )
+      {
       for(int i=0; i<NUM_CUBITS; i++)
+        {
         CUBITS[i].solve();
         mMesh.setEffectAssociation(i, CUBITS[i].computeAssociation(),0);
+        }
       recordQuatsState("Failed to restorePreferences");
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void releaseResources()
+    {
     mTexture.markForDeletion();
     mMesh.markForDeletion();
     mEffects.markForDeletion();
     for(int j=0; j<NUM_CUBITS; j++)
+      {
       CUBITS[j].releaseResources();
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void apply(Effect effect, int position)
+    {
     mEffects.apply(effect, position);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void remove(long effectID)
+    {
     mEffects.abortById(effectID);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public synchronized void solve()
+    {
     for(int i=0; i<NUM_CUBITS; i++)
+      {
       CUBITS[i].solve();
       mMesh.setEffectAssociation(i, CUBITS[i].computeAssociation(), 0);
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void resetAllTextureMaps()
+    {
     final float ratioW = 1.0f/mNumTexCols;
     final float ratioH = 1.0f/mNumTexRows;
     int color, row, col;
     for(int cubit=0; cubit<NUM_CUBITS; cubit++)
+      {
       final Static4D[] maps = new Static4D[mNumCubitFaces];
       for(int cubitface=0; cubitface<mNumCubitFaces; cubitface++)
+        {
         color = getFaceColor(cubit,cubitface,mNumLayers);
         row = (mNumTexRows-1) - color/mNumTexCols;
         col = color%mNumTexCols;
         maps[cubitface] = new Static4D( col*ratioW, row*ratioH, ratioW, ratioH);
+        }
       mMesh.setTextureMap(maps,mNumCubitFaces*cubit);
+      }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void setTextureMap(int cubit, int face, int newColor)
+    {
     final float ratioW = 1.0f/mNumTexCols;
     final float ratioH = 1.0f/mNumTexRows;
     final Static4D[] maps = new Static4D[mNumCubitFaces];
     int row = (mNumTexRows-1) - newColor/mNumTexCols;
     int col = newColor%mNumTexCols;
     maps[face] = new Static4D( col*ratioW, row*ratioH, ratioW, ratioH);
     mMesh.setTextureMap(maps,mNumCubitFaces*cubit);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public synchronized void beginNewRotation(int axis, int row )
+    {
     if( axis<0 || axis>=NUM_AXIS )
+      {
       android.util.Log.e("object", "invalid rotation axis: "+axis);
       return;
+      }
     if( row<0 || row>=mNumLayers )
+      {
       android.util.Log.e("object", "invalid rotation row: "+row);
       return;
+      }
     mRotAxis     = axis;
     mRotRowBitmap= computeBitmapFromRow( (1<<row),axis );
     mRotationAngleStatic.set0(0.0f);
     mRotationAxis.set( mAxis[axis] );
     mRotationAngle.add(mRotationAngleStatic);
-            ad9f5cae
+    mRotateEffect.setMeshAssociation( mRotRowBitmap<<(axis*ObjectType.MAX_OBJECT_SIZE) , -1);
-b82486
+            Leszek Koltunski
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public synchronized long addNewRotation( int axis, int rowBitmap, int angle, long durationMillis, EffectListener listener )
+    {
     if( wasRotateApplied() )
+      {
       mRotAxis     = axis;
       mRotRowBitmap= computeBitmapFromRow( rowBitmap,axis );
       mRotationAngleStatic.set0(0.0f);
       mRotationAxis.set( mAxis[axis] );
       mRotationAngle.setDuration(durationMillis);
       mRotationAngle.resetToBeginning();
       mRotationAngle.add(new Static1D(0));
       mRotationAngle.add(new Static1D(angle));
-            ad9f5cae
+      mRotateEffect.setMeshAssociation( mRotRowBitmap<<(axis*ObjectType.MAX_OBJECT_SIZE) , -1);
-b82486
+      mRotateEffect.notifyWhenFinished(listener);
       return mRotateEffect.getID();
+      }
     return 0;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public long finishRotationNow(EffectListener listener, int nearestAngleInDegrees)
+    {
     if( wasRotateApplied() )
+      {
       float angle = getAngle();
       mRotationAngleStatic.set0(angle);
       mRotationAngleFinal.set0(nearestAngleInDegrees);
       mRotationAngleMiddle.set0( nearestAngleInDegrees + (nearestAngleInDegrees-angle)*0.2f );
       mRotationAngle.setDuration(POST_ROTATION_MILLISEC);
       mRotationAngle.resetToBeginning();
       mRotationAngle.removeAll();
       mRotationAngle.add(mRotationAngleStatic);
       mRotationAngle.add(mRotationAngleMiddle);
       mRotationAngle.add(mRotationAngleFinal);
       mRotateEffect.notifyWhenFinished(listener);
       return mRotateEffect.getID();
+      }
     return 0;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public synchronized void removeRotationNow()
+    {
     float angle = getAngle();
     double nearestAngleInRadians = angle*Math.PI/180;
     float sinA =-(float)Math.sin(nearestAngleInRadians*0.5);
     float cosA = (float)Math.cos(nearestAngleInRadians*0.5);
     float axisX = mAxis[mRotAxis].get0();
     float axisY = mAxis[mRotAxis].get1();
     float axisZ = mAxis[mRotAxis].get2();
     Static4D quat = new Static4D( axisX*sinA, axisY*sinA, axisZ*sinA, cosA);
     mRotationAngle.removeAll();
     mRotationAngleStatic.set0(0);
     for(int i=0; i<NUM_CUBITS; i++)
       if( belongsToRotation(i,mRotAxis,mRotRowBitmap) )
+        {
         int index = CUBITS[i].removeRotationNow(quat);
         mMesh.setEffectAssociation(i, CUBITS[i].computeAssociation(),index);
+        }
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void initializeObject(int[][] moves)
+    {
     solve();
     setupPosition(moves);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public int getCubit(float[] point3D)
+    {
     float dist, minDist = Float.MAX_VALUE;
     int currentBest=-1;
     float multiplier = returnMultiplier();
     point3D[0] *= multiplier;
     point3D[1] *= multiplier;
     point3D[2] *= multiplier;
     for(int i=0; i<NUM_CUBITS; i++)
+      {
       dist = CUBITS[i].getDistSquared(point3D);
       if( dist<minDist )
+        {
         minDist = dist;
         currentBest = i;
+        }
+      }
     return currentBest;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public int computeNearestAngle(int axis, float angle, float speed)
+    {
     int[] basicArray = getBasicAngle();
     int basicAngle   = basicArray[axis>=basicArray.length ? 0 : axis];
     int nearestAngle = 360/basicAngle;
     int tmp = (int)((angle+nearestAngle/2)/nearestAngle);
     if( angle< -(nearestAngle*0.5) ) tmp-=1;
     if( tmp!=0 ) return nearestAngle*tmp;
     return speed> 1.2f ? nearestAngle*(angle>0 ? 1:-1) : 0;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public float getCameraDist()
+    {
     return mCameraDist;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public int getNodeSize()
+    {
     return mNodeSize;
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-            c8bc83d9
+  public ObjectType getObjectType()
-b82486
+            Leszek Koltunski
-            c8bc83d9
+    return intGetObjectType(mNumLayers);
-b82486
+            Leszek Koltunski
 ///////////////////////////////////////////////////////////////////////////////////////////////////
   public void randomizeNewScramble(int[][] scramble, Random rnd, int curr, int total)
+    {
     mScrambler.randomizeNewScramble(scramble,rnd,curr,total);
+    }
 ///////////////////////////////////////////////////////////////////////////////////////////////////
-ac32
+  protected abstract int getFOV();
   protected abstract float returnMultiplier();
   protected abstract float getScreenRatio();
   protected abstract int getNumFaceColors();
   protected abstract int getColor(int face);
-b82486
+  protected abstract float[][] getCuts(int numLayers);
   protected abstract int getNumCubitFaces();
   protected abstract Static4D[] getQuats();
   protected abstract float[][] getCubitPositions(int numLayers);
   protected abstract int getCubitVariant(int cubit, int numLayers);
   protected abstract int getNumCubitVariants(int numLayers);
   protected abstract Static4D getQuat(int cubit, int numLayers);
   protected abstract ObjectShape getObjectShape(int cubit, int numLayers);
   protected abstract int[] getSolvedQuats(int cubit, int numLayers);
   protected abstract int getSolvedFunctionIndex();
   protected abstract ScrambleState[] getScrambleStates();
   protected abstract int getNumStickerTypes(int numLayers);
   protected abstract ObjectSticker retSticker(int face);
   protected abstract int getFaceColor(int cubit, int cubitface, int numLayers);
-e1dc313
+  protected abstract int getResource(int mNumLayers);
-            c8bc83d9
+  protected abstract ObjectType intGetObjectType(int numLayers);
-b82486
+            Leszek Koltunski
   public abstract Movement getMovement();
   public abstract Static3D[] getRotationAxis();
   public abstract int[] getBasicAngle();
   public abstract int getObjectName(int numLayers);
   public abstract int getInventor(int numLayers);
   public abstract int getComplexity(int numLayers);
+  }

Project

General

Profile

TwistyPuzzleLib

distorted-objectlib / src / main / java / org / distorted / objectlib / main / TwistyObject.java @ 198c5bf0