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  1. Prepare
  2. Algorithms
  3. Implementation
  4. Matrix Layer Rotation
  5. Discussions

Matrix Layer Rotation

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  • yuzhuo_w
     + 0 comments

    My Python3 solution. The rationale is that for each onion layer: 1. Get a list of coordinates on this layer (dst) 2. Rotate this list of coordinates to make a new list (src) 3. For each coordinate in dst, set the value of this coordinate in the output matrix to the value of the corresponding src coordinate in the original matrix

    def get_layer_points(
    m: int,
    n: int,
    layer: int,
) -> list[tuple[int, int]]:
    points: list[tuple[int, int]] = []
    for row in range(layer, m - layer - 1):
        points.append((row, layer))
    for col in range(layer, n - layer - 1):
        points.append((m - layer - 1, col))
    for row in range(m - layer - 1, layer, -1):
        points.append((row, n - layer - 1))
    for col in range(n - layer - 1, layer, -1):
        points.append((layer, col))
    return points

        
def matrixRotation(matrix: list[list[int]], r: int):
    # Write your code here
    m = len(matrix)
    n = len(matrix[0])
    output = [line.copy() for line in matrix]
    for layer in range(min(m, n) // 2):
        dst = get_layer_points(m, n, layer)
        steps = r % len(dst)
        src = dst[-steps:] + dst[:-steps]
        for i in range(len(dst)):
            output[dst[i][0]][dst[i][1]] = matrix[src[i][0]][src[i][1]]
    for line in output:
        print(*line, sep=" ")

  • wisemana
     + 0 comments

    My C#. All test cases now passing. Uses 'strands' wrapping around each 'shell'. These are unwrapped, rotated and then reassembled to make the final grid.

    public static void matrixRotation(List<List<int>> matrix, int r)
    {
        int shells = Math.Min(matrix.Count, matrix[0].Count) / 2;

        var strands = new List<List<int>>();

        for (int shell = 0; shell < shells; shell++)
        {
            var strand = new List<int>();

            int col;
            int row = shell;

            // East
            for (col=shell; col < matrix[row].Count - shell; col++)
            {
                strand.Add(matrix[row][col]);
            }
            // South
            col -= 1;
            for (row = shell+1; row < matrix.Count - shell; row++)
            {
                strand.Add(matrix[row][col]);
            }
            // West
            row -= 1;
            for (col = matrix[row].Count - shell - 2; col >= shell; col--)
            {
                strand.Add(matrix[row][col]);
            }
            // North
            col += 1;
            for (row = matrix.Count - shell - 2; row > shell; row--)
            {
                strand.Add(matrix[row][col]);
            }

            for (int rotation = 0; rotation < (r % strand.Count); rotation++)
            {
                int first = strand[0];
                strand.RemoveAt(0);
                strand.Add(first);
            }

            strands.Add(strand);
        }
        /*
        foreach (var strand in strands)
        {
            foreach (var item in strand)
                Console.Write(item + " ");
            Console.WriteLine();
        }
        Console.WriteLine();
        */
        var result = new int[matrix.Count,matrix[0].Count];

        for (int shell = 0; shell < shells; shell++)
        {
            int col;
            int row = shell;
            int n = 0;

            // East
            for (col = shell; col < matrix[row].Count - shell; col++)
            {
                result[row, col] = strands[shell][n];
                n++;
            }
            // South
            col -= 1;
            for (row = shell + 1; row < matrix.Count - shell; row++)
            {
                result[row, col] = strands[shell][n];
                n++;
            }
            // West
            row -= 1;
            for (col = matrix[row].Count - shell - 2; col >= shell; col--)
            {
                result[row, col] = strands[shell][n];
                n++;
            }
            // North
            col += 1;
            for (row = matrix.Count - shell - 2; row > shell; row--)
            {
                result[row, col] = strands[shell][n];
                n++;
            }

        }

        for (int row = 0; row < matrix.Count; row++)
        {
            for (int col = 0; col < matrix[0].Count; col++)
            {
                Console.Write(result[row, col] + " ");
            }
            Console.WriteLine();
        }

    }

}

  • ght1696
     + 0 comments

    Python 3

    def matrixRotation(matrix, r):
    # Write your code here
    circles = min(len(matrix), len(matrix[0]))
    
    m, n = len(matrix), len(matrix[0])
    
    _matrix = matrix.copy()
    for circle in range((int) (circles/2)):
        _m = (m - 2 * circle) - 1
        _n = (n - 2 * circle) - 1
        
        # print(_m,_n, circle)
        snake = []
        snake.extend([matrix[i][circle] for i in range(circle, circle + _m)])
        snake.extend([matrix[circle + _m][i] for i in range(circle, circle + _n)])
        snake.extend([matrix[i][circle + _n] for i in range(circle + _m, circle, -1)])
        snake.extend([matrix[circle][i] for i in range(circle + _n, circle, -1)])
        # print(snake)
        
        _r = r % len(snake)
        snake = deque(snake)
        snake.rotate(_r)
        
        idx = 0
        for i in range(circle, circle + _m):
            _matrix[i][circle] = snake[idx]
            idx += 1
        for i in range(circle, circle + _n):
            _matrix[circle + _m][i] = snake[idx]
            idx += 1
        for i in range(circle + _m, circle, -1):
            _matrix[i][circle + _n] = snake[idx]
            idx += 1
        for i in range(circle + _n, circle, -1):
            _matrix[circle][i] = snake[idx]
            idx += 1
    
    # print(_matrix)
    for i in range(m):
        print(" ".join([str(x) for x in _matrix[i]]))

  • Aklinahs
     + 0 comments

    Python 3 code

    def matrixRotation(matrix, r):


    m = len(matrix)
    n = len(matrix[1])
    m2 = [([0] * n) for i in range(m)]

    number_of_rings = min(int(m/2), int(n/2))

    m_rings = []
    n_rings = []

#creating a list of ring indexes
    
    for i in range(number_of_rings):
        elements_in_a_ring = 2*n + 2*(m-2)
        m_arr = []
        n_arr = []

        for j in range(n):
            m_arr.append(i)
            n_arr.append(n-j-1+i)
        for j in range(m-1):
            m_arr.append(j+1+i)
            n_arr.append(i)
        for j in range(n-1):
            m_arr.append(m-1+i)
            n_arr.append(j+1+i)
        for j in range(m-2):
            m_arr.append(m-j-2+i)
            n_arr.append(n-1+i)
    
    #Rotating index ring by r
		
        m_arr = [m_arr[(i-r) % len(m_arr)] for i, x in enumerate(m_arr)]
        n_arr = [n_arr[(i-r) % len(n_arr)] for i, x in enumerate(n_arr)]
        m_rings.append(m_arr)
        n_rings.append(n_arr)
        m -= 2
        n -= 2

    # print(f"m rings after: {m_rings}")
    # print(f"n rings after : {n_rings}")

    m = len(matrix)
    n = len(matrix[1])
    matr2 = [([0] * n) for i in range(m)]
    
#assign the data to the new matrix (matr2), from the data matrix (matrix) using the rotated data indexes 
    for i in range(number_of_rings):
        elements_in_a_ring = 2*n + 2*(m-2)

        for j in range(n):
            matr2[i][n-j-1+i] = matrix[m_rings[i][j]][n_rings[i][j]]
        for j in range(m-1):
            matr2[j+1+i][i] = matrix[m_rings[i][j+n]][n_rings[i][j+n]]
        for j in range(n-1):
            matr2[m-1+i][j+1+i] = matrix[m_rings[i][m+n-1+j]][n_rings[i][m+n-1+j]]
        for j in range(m-2):
            m_arr.append(m-j-2+i)
            n_arr.append(n-1+i)
            matr2[m-j-2+i][n-1+i] = matrix[m_rings[i][m+(2*n)-2+j]][n_rings[i][m+(2*n)-2+j]]

        m -= 2
        n -= 2

    # print(f"m matrix 1: {matrix}")
    # print(f"m matrix 2: {matr2}")

    m = len(matrix)
    for i in range(m):
        print(*matr2[i])

  • Aklinahs
     + 0 comments

    Python 3.

    Eventhough this solution is short, it takes too many ierations to complete the totations. So some test cases will exceed the time limit. I also commentd anothor optimized solution, that works for every test case.

    def matrixRotation(matrix, r):
    m = len(matrix)
    n = len(matrix[1])
    m2 = [([0]*n) for i in range(m)]

    for turns in range(r):
        m2 = [([0] * n) for i in range(m)]
        for i in range(min(int(m/2), int(n/2))):

            m2[i][n-i-1] = matrix[i+1][n-i-1]
            m2[m-i-1][i] = matrix[m-i-2][i]
            for j in range(n-(2*i)-1):
                m2[i][i+j] = matrix[i][i+j+1]
                m2[m-i-1][i+j+1] = matrix[m-i-1][i+j]
            for k in range(m-(2*i)-1):
                m2[k+i+1][i] = matrix[k+i][i]
                m2[k+i][n-i-1] = matrix[k+i+1][n-i-1]
                
        matrix = m2
        
    for i in range(m):
        print(*matrix[i])
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