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///////////////////////////////////////////////////////////////////////////////////////////////////
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// Copyright 2023 Leszek Koltunski //
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// //
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// This file is part of Magic Cube. //
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// //
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// Magic Cube is proprietary software licensed under an EULA which you should have received //
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// along with the code. If not, check https://distorted.org/magic/License-Magic-Cube.html //
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///////////////////////////////////////////////////////////////////////////////////////////////////
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package org.distorted.bandaged;
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import org.distorted.library.main.DistortedScreen;
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import org.distorted.library.mesh.MeshBase;
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import org.distorted.library.type.Static3D;
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import org.distorted.objectlib.helpers.FactoryBandagedCuboid;
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import org.distorted.objectlib.main.InitData;
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import org.distorted.objectlib.main.TwistyObject;
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import org.distorted.objectlib.objects.TwistyBandagedCuboid;
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import org.distorted.objectlib.shape.ShapeHexahedron;
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import org.distorted.objectlib.touchcontrol.TouchControlHexahedron;
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///////////////////////////////////////////////////////////////////////////////////////////////////
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public class BandagedObjectCuboid extends BandagedObject
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{
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BandagedObjectCuboid(DistortedScreen screen)
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{
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super(screen);
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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float[] getDist3D()
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{
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float max = mMax;
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float x = 0.5f*(mSize[0]/max);
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float y = 0.5f*(mSize[1]/max);
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float z = 0.5f*(mSize[2]/max);
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return new float[] {x,x,y,y,z,z};
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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float getDist2D()
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{
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return 0.5f;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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int[] getColors()
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{
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return ShapeHexahedron.FACE_COLORS;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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Static3D[] getFaceAxis()
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{
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return TouchControlHexahedron.FACE_AXIS;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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boolean isAdjacent(float dx, float dy, float dz)
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{
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return dx*dx + dy*dy + dz*dz == 1;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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float[][][] getPositions()
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{
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float[][][] pos = new float[1][mNumCubits][];
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int c=0;
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int sx = mSize[0];
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int sy = mSize[1];
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int sz = mSize[2];
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float begX = 0.5f*(1-sx);
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float begY = 0.5f*(1-sy);
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float begZ = 0.5f*(1-sz);
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for(int x=0; x<sx; x++)
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for(int y=0; y<sy; y++)
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for(int z=0; z<sz; z++)
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if( x==0 || x==sx-1 || y==0 || y==sy-1 || z==0 || z==sz-1 )
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{
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pos[0][c++] = new float[] { begX+x,begY+y,begZ+z };
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}
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return pos;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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void getTouchedPosition(float[] output, int face, float pointX, float pointY)
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{
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float x = mSize[0];
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float y = mSize[1];
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float z = mSize[2];
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switch(face)
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{
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case 0: output[0] = (x-1)/2;
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output[1] = (int)( y*pointY+y/2)-(y-1)/2;
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output[2] = (int)(-z*pointX-z/2)+(z-1)/2;
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break;
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case 1: output[0] =-(x-1)/2;
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output[1] = (int)( y*pointY+y/2)-(y-1)/2;
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output[2] = (int)( z*pointX+z/2)-(z-1)/2;
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break;
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case 2: output[0] = (int)( x*pointX+x/2)-(x-1)/2;
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output[1] = (y-1)/2;
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output[2] = (int)(-z*pointY-z/2)+(z-1)/2;
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break;
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case 3: output[0] = (int)( x*pointX+x/2)-(x-1)/2;
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output[1] =-(y-1)/2;
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output[2] = (int)( z*pointY+z/2)-(z-1)/2;
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break;
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case 4: output[0] = (int)( x*pointX+x/2)-(x-1)/2;
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output[1] = (int)( y*pointY+y/2)-(y-1)/2;
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output[2] = (z-1)/2;
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break;
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case 5: output[0] = (int)(-x*pointX-x/2)+(x-1)/2;
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output[1] = (int)( y*pointY+y/2)-(y-1)/2;
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output[2] =-(z-1)/2;
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break;
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}
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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boolean tryChangeObject(int x, int y, int z)
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{
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if( mSize[0]!=x || mSize[1]!=y || mSize[2]!=z )
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{
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mSize[0] = x;
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mSize[1] = y;
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mSize[2] = z;
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mMax = x>y ? Math.max(x,z) : Math.max(y,z);
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mNumCubits = ( x<=1 || y<=1 || z<=1 ) ? x*y*z : x*y*z-(x-2)*(y-2)*(z-2);
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return true;
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}
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return false;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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int computeProjectionAngle()
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{
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float quot1 = mSize[2]/ (float)mSize[0];
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float quot2 = mSize[2]/ (float)mSize[1];
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float quot3 = mSize[0]/ (float)mSize[2];
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float quot4 = mSize[0]/ (float)mSize[1];
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float quot5 = Math.max(quot1,quot2);
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float quot6 = Math.max(quot3,quot4);
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float quot7 = Math.max(quot5,quot6);
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if( quot7<=1.0f ) return 120;
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else if( quot7<=1.5f ) return 90;
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else if( quot7<=2.0f ) return 60;
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else return 30;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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boolean isInsideFace(int face, float[] p)
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{
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float max = mMax;
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switch(face/2)
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{
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case 0: p[0] *= (max/mSize[2]); p[1] *= (max/mSize[1]); break;
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case 1: p[0] *= (max/mSize[0]); p[1] *= (max/mSize[2]); break;
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case 2: p[0] *= (max/mSize[0]); p[1] *= (max/mSize[1]); break;
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}
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return ( p[0]<=mDist2D && p[0]>=-mDist2D && p[1]<=mDist2D && p[1]>=-mDist2D );
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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MeshBase createMesh(int variant, float[] pos, boolean round)
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{
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FactoryBandagedCuboid factory = FactoryBandagedCuboid.getInstance();
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return factory.createMesh(pos,mSize[0],mSize[1],mSize[2],false,round);
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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TwistyObject createObject(int mode, float size)
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{
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float[][] pos = getCubitPositions();
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InitData data = new InitData( mSize,pos);
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return new TwistyBandagedCuboid( TwistyObject.MESH_NICE, mode, ShapeHexahedron.DEFAULT_ROT, new Static3D(0,0,0), size, data, null );
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}
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}
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