LeetCode 第36、37题（数独问题）

LeetCode 第36题：有效的数独

题目描述

请你判断一个9*9的数独是否有效。只需要根据以下规则，验证已经填入的数字是否有效即可。

• 数字1-9在每一行只能出现一次
• 数字1-9在每一列只能出现一次
• 数字1-9在每一个以粗实线分隔的3*3宫内只能出现一次（请参考示例图）

注意：

• 一个有效数独（部分已填）不一定是可解的
• 只需要根据以上规则，验证已经填入的数字是否有效即可
• 空白格用‘.’表示

难度：中等

题目链接：36. 有效的数独 - 力扣（LeetCode）

示例1：

输入：board = 
[["5","3",".",".","7",".",".",".","."]
,["6",".",".","1","9","5",".",".","."]
,[".","9","8",".",".",".",".","6","."]
,["8",".",".",".","6",".",".",".","3"]
,["4",".",".","8",".","3",".",".","1"]
,["7",".",".",".","2",".",".",".","6"]
,[".","6",".",".",".",".","2","8","."]
,[".",".",".","4","1","9",".",".","5"]
,[".",".",".",".","8",".",".","7","9"]]
输出：true

示例2：

输入：board = 
[["8","3",".",".","7",".",".",".","."]
,["6",".",".","1","9","5",".",".","."]
,[".","9","8",".",".",".",".","6","."]
,["8",".",".",".","6",".",".",".","3"]
,["4",".",".","8",".","3",".",".","1"]
,["7",".",".",".","2",".",".",".","6"]
,[".","6",".",".",".",".","2","8","."]
,[".",".",".","4","1","9",".",".","5"]
,[".",".",".",".","8",".",".","7","9"]]
输出：false
解释：第一行的第一个数字 8 在第四行中重复出现

提示：

• board.length==9
• board[i].length==9
• board[i][j]是一个数字1-9或者‘.’

 解题思路：

哈希表记录

• 创建三个哈希表数组

1. rows[9]：记录每行的数字
2. cols[9]：记录每列的数字
3. boxes[9]：记录每个3*3方格的数字

• 遍历整个数独板

1. 计算当前位置属于哪个3*3方格
2. 检查数字在三个区域是否重复
3. 如果重复返回false

时间复杂度：O（1），因为是固定大小的9*9网格

空间复杂度：O（1），使用固定大小的哈希表

bool isVaildSudoku(char** board,int boardSize,int* boardColSize)
{
    char x[9][9]={0},y[9][9]={0},squre[3][3][9]={0};
    int i,j,num,squrex,squrey;
    for(i=0;i<9;i++)
    {
        for(j=0;j<9;j++)
        {
            if(board[i][j]=='.') continue;
            squrex = (int)(i/3);
            squrey = (int)(j/3);
            num = (int)(board[i][j]-'1');
            if(x[i][num]==1 || y[j][num]==1 || squre[squrex][squrey][num]==1)
                return false;
            x[i][num]=1;
            y[j][num]=1;
            squre[squrex][squrey][num]=1;
        }
    }
    return true;
}

bool isVaildSudoku(char** board,int boardSize,int* boardColSize)
{
    int row[9][9]={0},col[9][9]={0},rc[9][9]={0};
    for(int i=0;i<boardSize;i++)
    {
        for(int j=0;j<boardSize;j++)
        {
            if(board[i][j]!='.')
            {
                if(++row[i][board[i][j]-'1']>1 || ++col[j][board[i][j]-'1']>1 || 
                    ++rc[i/3*3+j/3][board[i][j]-'1']>1) 
                 return false;
            }}}
    return true;
}

 LeetCode 第37题：解数独

题目描述

编写一个程序，通过填充空格来解决数独问题。

数独的解法需遵循如下规则：

• 数字1-9在每一行只能出现一次
• 数字1-9在每一列只能出现一次
• 数字1-9在每一个以粗实线分隔的3*3宫内只能出现一次。（请参考示例图）

数独部分空格内已填入了数字，空白格用‘.’表示。

难度：困难

题目链接：37. 解数独 - 力扣（LeetCode）

示例2：

输入：board = 
[["5","3",".",".","7",".",".",".","."],
 ["6",".",".","1","9","5",".",".","."],
 [".","9","8",".",".",".",".","6","."],
 ["8",".",".",".","6",".",".",".","3"],
 ["4",".",".","8",".","3",".",".","1"],
 ["7",".",".",".","2",".",".",".","6"],
 [".","6",".",".",".",".","2","8","."],
 [".",".",".","4","1","9",".",".","5"],
 [".",".",".",".","8",".",".","7","9"]]
输出：
[["5","3","4","6","7","8","9","1","2"],
 ["6","7","2","1","9","5","3","4","8"],
 ["1","9","8","3","4","2","5","6","7"],
 ["8","5","9","7","6","1","4","2","3"],
 ["4","2","6","8","5","3","7","9","1"],
 ["7","1","3","9","2","4","8","5","6"],
 ["9","6","1","5","3","7","2","8","4"],
 ["2","8","7","4","1","9","6","3","5"],
 ["3","4","5","2","8","6","1","7","9"]]

提示：

• board.length==9
• board[i].length==9
• board[i][j]是一个数字或者‘.’
• 题目数据保证输入数独仅有一个解

/**
判断函数:循环判断当前行、列是否有重复函数，如果有返回false
判断当前九宫格左上角的位置，判断此九宫格是否有重复元素，若运行到最后返回true

填字函数：从上到下、从左到右依次遍历输入数组，board[i][j]=='.'表示无数字，依次填入1-9数字
判断当前位置是否满足条件，是则进入下一层，不是则判断下一个填入的数
判断下一层递归之后是否找到一种解法，是则返回true，不是则回溯，将当前位置清零board[i][j]='.'
若填入的9个数均不满足条件，返回false,说明此解法无效。
遍历完所有的棋盘，没有返回false，说明找到了解法，返回true

每一次的递归回溯都是从左上角开始
在填入1-9之后若没返回true，说明此法无解，返回false
判断当前元素是否满足条件isValid需要判断3种位置，当前元素所在的行、列和九宫格
**/
bool isValid(char** board,int row,int col,int k)
{
    for(int i=0;i<9;i++)
        if(board[i][col]==k)
            return false;
    for(int j=0;j<9;j++)
        if(board[row][j]==k)
            return false;
    int startRow = (row/3)*3;
    int startCol = (col/3)*3;
    for(int i=startRow;i<startRow+3;i++)
        for(int j=startCol;j<startCol+3;j++)
            if(board[i][j]==k)  return false;
    return true;
}
bool backtracking(char** board,int boardSize,int* boardColSize)
{
    for(int i=0;i<boardSize;i++){
        for(int j=0;j<*boardColSize;j++){
            if(board[i][j]!='.')  continue;
            for(int k='1';k<='9';k++){
                if(isValid(board,i,j,k))
                {
                    board[i][j]=k;
                    //判断下一层递归之后是否找到一种解法，是则返回true
                    if(backtracking(board,boardSize,boardColSize))
                    return true;
                    //回溯，将当前位置清零
                    board[i][j]='.';
                }
            }
        return false;
}
}
        return true;

}
void solveSudoku(char** board,int boardSize;int* boardColSize)(
    bool res = backtracking(board,boardSize,boardColSize);
}