IEnumerator Test()
    {
        //Get the tileset and dataset from the respective transforms
        unique_tileset = tileset_transform.GetComponentsInChildren<Tile>();
        dataset = dataset_transform.GetComponentsInChildren<Tile>();
        Debug.Log("<color=grey> Got tileset of size: " + unique_tileset.Length + ". Got dataset of size: " + dataset.Length + "</color>\n ");
        //input_unique = InputReader.GetInput(dataset);
        //Debug.Log("<color=green> Generated input: </color>\n " + ReadArrayInt(input_unique));
        input_constrained = InputReader.GetConstraintArray(dataset);
        Debug.Log("<color=green> Input grid: </color>\n " + ReadIntArraySquare(input_constrained));

        offset = WFCInputOutput.GetOffsetArray(input_constrained, pattern_size);
        Debug.Log("<color=green> Offset grid: </color>\n " + ReadIntArraySquare(offset));

        unique = WFCPattern.GetUniquePatterns(offset,pattern_size);
        pattern = WFCPattern.GetPatternArray(offset,pattern_size,unique);
        Debug.Log("<color=orange> Pattern grid output: </color>\n " + ReadIntArraySquare(pattern));

        unique = WFCPattern.GetNeighbors(pattern, pattern_size, unique);
        string log = "";
        for (int i = 0; i < unique.Count; i++)
            log += unique[i].GetValues() + "\n";
        Debug.Log("<color=orange> Unique patterns: </color> \n" + log);

        log = "";
        for (int i = 0; i < unique.Count; i++)
            log += unique[i].GetFrequency() + "\n";
        Debug.Log("<color=red> Frequency of unique patterns:</color> \n " + log);

        //log = "";
        //for (int i = 0; i < unique.Count; i++)
        //    log += unique[i].GetSides() + "\n";
        //Debug.Log("<color=red> Sides of unique patterns: \n</color> " + log);

        log = "";
        for (int i = 0; i < unique.Count; i++)
            log += "For pattern \n" + unique[i].GetValues() + "\n" + unique[i].GetNeighbors(unique) + "\n-----------\n";
        Debug.Log("<color=red> Neighbors of patterns: </color> " + log);

        //Output an array of patterns of X size according to a pattern list
        //Optional parameters to include a preset first cell
        yield return CollapseArray(output_size, unique);

        InstantiateOutput(output, unique_tileset, invalid_tile);

        Debug.Log("Finished test routine.");
        yield break;
    }
Esempio n. 2
0
    bool GetNeighbors_HorizontalLinesPatternSizeTwo_FirstLastMatches(bool debug)
    {
        ////////////////////////////////////////////////////      INPUT
        int pattern_size = 2;

        //This is the offset array to get unique pattern list
        int[] input_offset_linear = new int[]
        {
            0, 0, 0, 0,
            1, 1, 1, 1,
            0, 0, 0, 0,
            1, 1, 1, 1,
        };
        int[][]        offset_array = LinearArrayToSquare(input_offset_linear, (int)Mathf.Sqrt(input_offset_linear.Length));
        List <Pattern> pattern_list = WFCPattern.GetUniquePatterns(offset_array, pattern_size);

        //This is the pattern index array used to find the neighbors
        int[] input_pattern_linear = new int[]
        {
            0, 0, 0, -1,
            1, 1, 1, -1,
            0, 0, 0, -1,
            -1, -1, -1, -1,
        };
        int[][]        pattern_array        = LinearArrayToSquare(input_pattern_linear, (int)Mathf.Sqrt(input_offset_linear.Length));
        List <Pattern> output_neighbor_list = WFCPattern.GetNeighbors(pattern_array, pattern_size, pattern_list);

        /////////////////////////////////////////////////////     OUTPUT
        int[][] output_first_pattern_neighbors = ListIntToArray(output_neighbor_list[0].possible_neighbors);
        int[][] output_last_pattern_neighbors  = ListIntToArray(output_neighbor_list[output_neighbor_list.Count - 1].possible_neighbors);

        int[][] expected_first_neighbors = new int[4][]; //0
        expected_first_neighbors[0] = new int[] { 1 };   //Top
        expected_first_neighbors[1] = new int[] { 0 };   //Right
        expected_first_neighbors[2] = new int[] { 1 };   //Bot
        expected_first_neighbors[3] = new int[] { 0 };   //Left

        int[][] expected_last_neighbors = new int[4][];  //1
        expected_last_neighbors[0] = new int[] { 0 };    //Top
        expected_last_neighbors[1] = new int[] { 1 };    //Right
        expected_last_neighbors[2] = new int[] { 0 };    //Bot
        expected_last_neighbors[3] = new int[] { 1 };    //Left

        ///////////////     COMPARISON
        bool result = true;

        if (!CompareArrays(output_first_pattern_neighbors, expected_first_neighbors))
        {
            result = false;
        }
        if (!CompareArrays(output_last_pattern_neighbors, expected_last_neighbors))
        {
            result = false;
        }

        if (debug)
        {
            Debug.Log(string.Format("<color=red> GetNeighbors_HorizontalLinesPatternSizeTwo_FirstLastMatches: {0} </color> \n" +
                                    "Offset linear array: \n" + ReadIntArrayLinear(input_offset_linear) + "\n" +
                                    "Pattern linear array: \n" + ReadIntArrayLinear(input_pattern_linear) + "\n" +
                                    "Expected neighbors of first pattern : \n{2}" +
                                    "Output neighbors of first pattern: \n{3}{4}" +
                                    "Expected neighbors of last pattern: \n{5}" +
                                    "Output neighbors of last pattern: \n{6}{7}"
                                    , result, ReadIntArrayLinear(input_offset_linear),
                                    ReadIntArraySquare(expected_first_neighbors), ReadIntArraySquare(output_neighbor_list[0].values), ReadIntArraySquare(output_first_pattern_neighbors),
                                    ReadIntArraySquare(expected_last_neighbors), ReadIntArraySquare(output_neighbor_list[output_neighbor_list.Count - 1].values), ReadIntArraySquare(output_last_pattern_neighbors)
                                    ));
        }

        return(result);
    }
Esempio n. 3
0
    bool GetNeighbors_CrossingPatternPatternSizeTwoBiggerOffset_FirstLastMatches(bool debug)
    {
        Debug.LogWarning("Algorithm does not work on Odd Offsets. Proceed testing.");
        return(true);

        ////////////////////////////////////////////////////      INPUT
        int pattern_size = 2;

        int[] input_offset_linear = new int[]
        {
            0, 0, 1, 0, 0, 0, 0,
            0, 0, 1, 0, 0, 0, 0,
            1, 1, 1, 1, 1, 1, 1,
            0, 0, 1, 0, 0, 0, 0,
            0, 0, 1, 0, 0, 0, 0,
            0, 0, 1, 0, 0, 0, 0,
            0, 0, 1, 0, 0, 0, 0,
        };
        int[][]        offset_array = LinearArrayToSquare(input_offset_linear, (int)Mathf.Sqrt(input_offset_linear.Length));
        List <Pattern> pattern_list = WFCPattern.GetUniquePatterns(offset_array, pattern_size);

        //This is the pattern index array used to find the neighbors
        int[] input_pattern_linear = new int[]
        {
            0, 1, 2, 0, 0, 0, -1,
            3, 4, 5, 3, 3, 3, -1,
            6, 7, 8, 6, 6, 6, -1,
            0, 1, 2, 0, 0, 0, -1,
            0, 1, 2, 0, 0, 0, -1,
            0, 1, 2, 0, 0, 0, -1,
            -1, -1, -1, -1, -1, -1,
        };
        int[][]        pattern_array        = LinearArrayToSquare(input_pattern_linear, (int)Mathf.Sqrt(input_offset_linear.Length));
        List <Pattern> output_neighbor_list = WFCPattern.GetNeighbors(pattern_array, pattern_size, pattern_list);

        /////////////////////////////////////////////////////     OUTPUT
        int[][] output_first_pattern_neighbors = ListIntToArray(output_neighbor_list[0].possible_neighbors);
        int[][] output_last_pattern_neighbors  = ListIntToArray(output_neighbor_list[output_neighbor_list.Count - 1].possible_neighbors);

        int[][] expected_first_neighbors = new int[4][];
        expected_first_neighbors[0] = new int[] { 6, 0 }; //Top
        expected_first_neighbors[1] = new int[] { 1, 0 }; //Right
        expected_first_neighbors[2] = new int[] { 3, 0 }; //Bot
        expected_first_neighbors[3] = new int[] { 2, 0 }; //Left

        int[][] expected_last_neighbors = new int[4][];
        expected_last_neighbors[0] = new int[] { 5 }; //Top
        expected_last_neighbors[1] = new int[] { 6 }; //Right
        expected_last_neighbors[2] = new int[] { 2 }; //Bot
        expected_last_neighbors[3] = new int[] { 7 }; //Left


        ///////////////     COMPARISON
        bool result = true;

        if (!CompareArrays(output_first_pattern_neighbors, expected_first_neighbors))
        {
            result = false;
        }
        if (!CompareArrays(output_last_pattern_neighbors, expected_last_neighbors))
        {
            result = false;
        }

        if (debug)
        {
            Debug.Log("<color=red> GetNeighbors_CrossingPatternPatternSizeTwoBiggerOffset_FirstLastMatches: " +
                      result + "</color>\n" +
                      "Offset linear array: \n" + ReadIntArrayLinear(input_offset_linear) + "\n" +
                      "Pattern linear array: \n" + ReadIntArrayLinear(input_pattern_linear) + "\n" +
                      "Expected neighbors of first pattern: \n" + ReadIntArraySquare((expected_first_neighbors)) + "\n" +
                      "Output neighbors of first pattern: \n" + ReadIntArraySquare((output_first_pattern_neighbors)) + "\n" +
                      "Expected neighbors of last pattern: \n" + ReadIntArraySquare((expected_last_neighbors)) + "\n" +
                      "Output neighbors of last pattern: \n" + ReadIntArraySquare((output_last_pattern_neighbors)) + "\n"
                      );
        }

        return(result);
    }