433. 岛屿的个数

433. 岛屿的个数

中文English

给一个 01 矩阵,求不同的岛屿的个数。

0 代表海,1 代表岛,如果两个 1 相邻,那么这两个 1 属于同一个岛。我们只考虑上下左右为相邻。

样例

样例 1:

输入:
[
  [1,1,0,0,0],
  [0,1,0,0,1],
  [0,0,0,1,1],
  [0,0,0,0,0],
  [0,0,0,0,1]
]
输出:
3

样例 2:

输入:
[
  [1,1]
]
输出:
1
输入测试数据 (每行一个参数)如何理解测试数据?

DFS写法(递归找寻当前岛屿所有关联的岛屿,赋值False)

 

class Solution:
    """
    大致思路:
    1.主函数,循环grid,只要是True,就说明是新的岛屿,然后写一个dfs方法找寻该岛屿关联的所有岛屿
    """
    def numIslands(self, grid):
        # write your code here
        #dfs写法,递归找寻,一直关联查找
        if not grid: return 0
        
        len_x, len_y = len(grid), len(grid[0])
        count = 0 
        direction = [[0,1],[0,-1],[1,0],[-1,0]]
        
        #当前岛屿所关联的都会被找到,赋值False
        def dfs(x, y):
            #递归找寻,注意,当grid[x][y]是非岛屿的时候,也是不符合递归条件的
            if (x < 0 or y < 0 or x > len_x - 1 or y > len_y - 1 or not grid[x][y]):
                return 
            
            #当前岛屿递归找寻
            grid[x][y] = False
            
            dfs(x + 1, y)
            dfs(x - 1, y)
            dfs(x, y + 1)
            dfs(x, y - 1)
            
        #主函数
        for i in range(len_x):
            for j in range(len_y):
                if (grid[i][j]):
                    count += 1
                    #找寻该岛屿所关联的所有岛屿,都当做一个岛屿来看
                    dfs(i, j)
                    
        return count

BFS写法(当前岛屿四周找寻符合条件的岛屿,一直不停的四周循环)

class Solution:
    """
    @param grid: a boolean 2D matrix
    @return: an integer
    """
    def numIslands(self, grid):
        # write your code here
        #bfs写法,四周的找寻,放进队列里面,一直不停的找寻队列为岛屿的四周
        
        if not grid: return 0 
        
        len_x, len_y = len(grid), len(grid[0])
        count = 0 
        queue = []
        directon = [[1,0],[-1,0],[0,1],[0,-1]]
        
        def bfs(x, y):
            queue.append([x, y])
            
            while queue:
                pop_num = queue.pop(0)
                pop_x = pop_num[0]
                pop_y = pop_num[1]
                
                #四周的找寻
                for d in directon:
                    new_x = d[0] + pop_x 
                    new_y = d[1] + pop_y 
                    
                    #如果是这种情况,跳出处理
                    if (new_x < 0 or new_y < 0 or new_x > len_x - 1 or new_y > len_y - 1):
                        continue
                    
                    #否则判断是否是
                    if (grid[new_x][new_y]):
                        queue.append([new_x,new_y])
                        grid[new_x][new_y] = False 
        
        
        #主函数
        for i in range(len_x):
            for j in range(len_y):
                if (grid[i][j]):
                    count += 1 
                    #当前岛屿四周不停的找寻符合条件的,赋值False
                    bfs(i, j)
        
        return count

dfs会一直不停的找到当前该岛屿所关联的全部岛屿。而bfs只会找到当前岛屿的四周(上下左右),判断是否符合条件,不停的pop,append进行关联过去

并查集(UnionFind)

大致思路:当前节点判断是否和左上两个节点根节点相同,如果不同(一定不同,每个节点最开始指向自己),且相邻,说明是同一个岛屿 count -= 1

如果左上没有True,则当前是新的岛屿,count不变。(判断,右下效果一样)

class Solution:
    """
    @param grid: a boolean 2D matrix
    @return: an integer
    """
    def __init__(self):
        self.count = 0
        
    def numIslands(self, grid):
        # write your code here
        #并查集写法,每次需要考察右下两个方向的点,如果是相邻的点,则岛屿个数不加1
        #如果是相邻的两个点,则指向同一个根节点,相连
        if not grid: return 0
        
        #初始化
        len_x, len_y = len(grid), len(grid[0])
        father = {}
        for i in range(len_x):
            for j in range(len_y):
                if grid[i][j]:
                    self.count += 1 
                    
                cur = str(i) + 'and' + str(j)
                father[cur] = cur 
    
        #
        def connect(num1, num2):
            root_num1 = unionfind(num1)
            root_num2 = unionfind(num2)
            
            if (root_num1 != root_num2):
                father[root_num2] = root_num1
                self.count -= 1 
                
        
        def unionfind(num):
            orign_num = num
            if num == father[num]:
                return num
            
            while num != father[num]:
                num = father[num]
            
            #压缩路径
            while father[orign_num] != num:
                temp = father[orign_num]
                father[orign_num] = num
                orign_num = temp
            
            return num
        
        for i in range(len_x):
            for j in range(len_y):
                if (grid[i][j]):
                    cur = str(i) + 'and' + str(j)
                    if (i - 1 >= 0 and grid[i - 1][j]):
                        cur_new = str(i - 1) + 'and' + str(j)
                        connect(cur, cur_new)
                    if (j - 1 >= 0 and grid[i][j - 1]):
                        cur_new = str(i) + 'and' + str(j - 1)
                        connect(cur, cur_new)                    
        
        return self.count
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原文地址:https://www.cnblogs.com/yunxintryyoubest/p/13277222.html