Given a matrix of m x n elements (m rows, n columns), return all elements of the matrix in spiral order.
For example,Given the following matrix:
[ [ 1, 2, 3 ], [ 4, 5, 6 ], [ 7, 8, 9 ]]
You should return [1,2,3,6,9,8,7,4,5].
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给定一个包含 m x n 个要素的矩阵,(m 行, n 列),按照螺旋顺序,返回该矩阵中的所有要素。
样例
给定如下矩阵:
[
[ 1, 2, 3 ],
[ 4, 5, 6 ],
[ 7, 8, 9 ]
]
应返回 [1,2,3,6,9,8,7,4,5]。
solution
方法一 traverse
利用遍历的方法和规则,设置遍历时,规则的变化,边界的改变,很直观,具体看代码
public class Solution {
public List<Integer> spiralOrder(int[][] matrix) {
List<Integer> res = new ArrayList<Integer>();
if ( matrix == null || matrix.length == 0) {
return res;
}
int rowBegin = 0;
int rowEnd = matrix.length - 1;
int colBegin = 0;
int colEnd = matrix[0].length - 1;
while( rowBegin <= rowEnd && colBegin <= colEnd) {
//traverse right
for(int i=colBegin;i<=colEnd;i++)
res.add(matrix[rowBegin][i]);
rowBegin++;
//traverse down
for(int i=rowBegin;i<=rowEnd;i++)
res.add(matrix[i][colEnd]);
colEnd--;
//traverse left
if(rowBegin <= rowEnd) {
for(int i=colEnd;i>=colBegin;i--)
res.add(matrix[rowEnd][i]);
rowEnd--;
}
//traverse up
if(colBegin <= colEnd) {
for(int i=rowEnd;i>=rowBegin;i--)
res.add(matrix[i][colBegin]);
colBegin++;
}
}
return res;
}
}
方法二 direction
新建一个direction类,用它来控制坐标的移动,有两个函数,一个move,一个是turn。
public class Solution {
/**
* @param matrix a matrix of m x n elements
* @return an integer list
*/
public List<Integer> spiralOrder(int[][] matrix) {
// Write your code here
List<Integer> order = new ArrayList<Integer>();
// check corner case
if (matrix == null || matrix.length == 0) {
return order;
}
int n = matrix.length;
if (matrix[0] == null || matrix[0].length == 0) {
return order;
}
int m = matrix[0].length;
int direction = Direction.RIGHT;
int[] cursor = new int[]{0, 0};
for (int i = 0; i < n * m; i++) {
order.add(matrix[cursor[0]][cursor[1]]);
// mark the visited position as -1
matrix[cursor[0]][cursor[1]] = -1;
int[] nextCursor = Direction.move(cursor, direction);
// if outside of matrix or marked before, turn right
if (nextCursor[0] < 0 || nextCursor[0] >= n ||
nextCursor[1] < 0 || nextCursor[1] >= m ||
matrix[nextCursor[0]][nextCursor[1]] == -1) {
direction = Direction.turnRight(direction);
nextCursor = Direction.move(cursor, direction);
}
cursor = nextCursor;
}
return order;
}
}
class Direction {
public static int DOWN = 0;
public static int RIGHT = 1;
public static int LEFT = 2;
public static int UP = 3;
private static int[] dx = new int[]{1, 0, 0, -1};
private static int[] dy = new int[]{0, 1, -1, 0};
public static int turnRight(int direction) {
if (direction == DOWN) {
return LEFT;
} else if (direction == RIGHT) {
return DOWN;
} else if (direction == LEFT) {
return UP;
} else if (direction == UP) {
return RIGHT;
}
return -1;
}
public static int[] move(int[] cursor, int direction) {
int[] nextCursor = new int[2];
nextCursor[0] = cursor[0] + dx[direction];
nextCursor[1] = cursor[1] + dy[direction];
return nextCursor;
}
}
