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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.solvers;
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import android.content.res.Resources;
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import org.distorted.main.R;
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import org.distorted.objectlib.helpers.OperatingSystemInterface;
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import org.distorted.solverui.ScreenSolver;
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import org.distorted.objectlib.main.TwistyObject;
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import org.distorted.objectlib.kociemba.SolverSearch;
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///////////////////////////////////////////////////////////////////////////////////////////////////
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public class SolverCube3
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{
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private final Resources mRes;
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private final OperatingSystemInterface mOS;
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private final TwistyObject mObject;
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private int mColorID;
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///////////////////////////////////////////////////////////////////////////////////////////////////
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private int mapCubitToFace(int cubit, int face)
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{
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if( cubit<8 )
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{
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switch(face)
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{
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case 0: return 1;
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case 1: if( cubit==2 ) return 5;
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if( cubit==1 ) return 3;
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return 1;
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case 2: return cubit==7 ? 5 : 3;
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case 3: if( cubit==1 ) return 1;
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return cubit==4 ? 5 : 3;
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case 4: return cubit==7 ? 3 : 5;
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case 5: if( cubit==2 ) return 1;
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if( cubit==4 ) return 3;
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return 5;
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}
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}
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if( cubit>19 ) return 4;
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switch(face)
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{
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case 0: return cubit==15 || cubit==18 ? 3 : 5;
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case 1: return cubit==13 || cubit==16 ? 3 : 5;
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case 2: return cubit==10 ? 5 : 3;
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case 3: return cubit== 8 ? 3 : 5;
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case 4: return cubit== 9 ? 3 : 5;
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case 5: return cubit== 8 ? 5 : 3;
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}
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return -1;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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private int checkPosition(String position)
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{
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int[] numColors = new int[6];
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int len = position.length();
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for(int i=0; i<len; i++)
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{
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char ch = position.charAt(i);
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switch(ch)
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{
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case 'R': numColors[0]++; break;
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case 'L': numColors[1]++; break;
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case 'U': numColors[2]++; break;
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case 'D': numColors[3]++; break;
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case 'F': numColors[4]++; break;
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case 'B': numColors[5]++; break;
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}
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}
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if( numColors[0]<9 ) { mColorID = R.string.color_yellow1; return numColors[0]; }
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if( numColors[1]<9 ) { mColorID = R.string.color_white1 ; return numColors[1]; }
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if( numColors[2]<9 ) { mColorID = R.string.color_blue1 ; return numColors[2]; }
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if( numColors[3]<9 ) { mColorID = R.string.color_green1 ; return numColors[3]; }
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if( numColors[4]<9 ) { mColorID = R.string.color_red1 ; return numColors[4]; }
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if( numColors[5]<9 ) { mColorID = R.string.color_orange1; return numColors[5]; }
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return -1;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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// order: Up --> Right --> Front --> Down --> Left --> Back
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// (because the first implemented Solver - the two-phase Cube3 one - expects such order)
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//
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// Solved 3x3x3 Cube maps to "UUUUUUUUURRRRRRRRRFFFFFFFFFDDDDDDDDDLLLLLLLLLBBBBBBBBB"
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private String preparePosition()
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{
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StringBuilder objectString = new StringBuilder();
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final int R = 0;
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final int L = 1;
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final int U = 2;
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final int D = 3;
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final int F = 4;
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final int B = 5;
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// 'I' - interior, theoretically can happen
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final char[] FACE_NAMES = { 'R', 'L', 'U', 'D', 'F', 'B', 'I'};
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final int[] U_INDEX = { 2,10, 6,17,22,19, 3,11, 7};
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final int[] R_INDEX = { 7,19, 6,15,20,14, 5,18, 4};
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final int[] F_INDEX = { 3,11, 7,13,24,15, 1, 9, 5};
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final int[] D_INDEX = { 1, 9, 5,16,23,18, 0, 8, 4};
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final int[] L_INDEX = { 2,17, 3,12,21,13, 0,16, 1};
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final int[] B_INDEX = { 6,10, 2,14,25,12, 4, 8, 0};
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(U_INDEX[i],U);
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int color = mObject.getCubitFaceStickerIndex(U_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(R_INDEX[i],R);
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int color = mObject.getCubitFaceStickerIndex(R_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(F_INDEX[i],F);
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int color = mObject.getCubitFaceStickerIndex(F_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(D_INDEX[i],D);
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int color = mObject.getCubitFaceStickerIndex(D_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(L_INDEX[i],L);
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int color = mObject.getCubitFaceStickerIndex(L_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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for(int i=0; i<9; i++)
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{
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int face = mapCubitToFace(B_INDEX[i],B);
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int color = mObject.getCubitFaceStickerIndex(B_INDEX[i], face);
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objectString.append(FACE_NAMES[color]);
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}
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return objectString.toString();
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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// PUBLIC API
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///////////////////////////////////////////////////////////////////////////////////////////////////
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public SolverCube3(OperatingSystemInterface os, Resources res, TwistyObject object)
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{
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mRes = res;
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mOS = os;
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mObject= object;
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}
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///////////////////////////////////////////////////////////////////////////////////////////////////
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public void solve(ScreenSolver solver)
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{
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String result;
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SolverSearch.prepare(mOS);
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String objectPosition = preparePosition();
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int check = checkPosition(objectPosition);
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if( check<0 )
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{
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result = SolverSearch.solution(objectPosition, 24, 20);
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if (result.contains("Error"))
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{
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switch (result.charAt(result.length() - 1))
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{
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case '1': result = mRes.getString(R.string.solver_cube3_error1); break;
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case '2': result = mRes.getString(R.string.solver_cube3_error2); break;
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case '3': result = mRes.getString(R.string.solver_generic_edge_twist); break;
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case '4': result = mRes.getString(R.string.solver_cube3_error4); break;
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case '5': result = mRes.getString(R.string.solver_generic_corner_twist); break;
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case '6': result = mRes.getString(R.string.solver_cube3_error6); break;
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case '7': result = mRes.getString(R.string.solver_cube3_error7); break;
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case '8': result = mRes.getString(R.string.solver_cube3_error8); break;
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case '9': result = mRes.getString(R.string.solver_cube3_error9); break;
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}
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solver.displayImpossibleDialog(result);
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}
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else
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{
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solver.setSolved(result);
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}
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}
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else
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{
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String color = mRes.getString(mColorID);
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result = mRes.getString(R.string.solver_cube3_error1,check,color);
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solver.displayImpossibleDialog(result);
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}
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}
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}
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