[Swift]LeetCode37. 解数独 | Sudoku Solver

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➤微信公众号：山青咏芝（shanqingyongzhi）
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Write a program to solve a Sudoku puzzle by filling the empty cells.

A sudoku solution must satisfy all of the following rules:

1. Each of the digits 1-9 must occur exactly once in each row.
2. Each of the digits 1-9 must occur exactly once in each column.
3. Each of the the digits 1-9 must occur exactly once in each of the 9 3x3 sub-boxes of the grid.

Empty cells are indicated by the character '.'.

A sudoku puzzle...

...and its solution numbers marked in red.

Note:

• The given board contain only digits 1-9 and the character '.'.
• You may assume that the given Sudoku puzzle will have a single unique solution.
• The given board size is always 9x9.

---

 编写一个程序，通过已填充的空格来解决数独问题。

一个数独的解法需遵循如下规则：

1. 数字 1-9 在每一行只能出现一次。
2. 数字 1-9 在每一列只能出现一次。
3. 数字 1-9 在每一个以粗实线分隔的 3x3 宫内只能出现一次。

空白格用 '.' 表示。

一个数独。

答案被标成红色。

Note:

• 给定的数独序列只包含数字 1-9 和字符 '.' 。
• 你可以假设给定的数独只有唯一解。
• 给定数独永远是 9x9 形式的。

---

 264ms

class Solution {
    func solveSudoku(_ board: inout [[Character]]) {
        guard board.count != 0 || board[0].count != 0 else {
            return
        }
        helper(&board)
    }
    
    private func helper(_ board: inout [[Character]]) -> Bool {
        let m = board.count, n = board[0].count
    
        for i in 0..<m {
            for j in 0..<n {
                if board[i][j] == "." {
                    for num in 1...9 {
                        if isValid(board, i, j, Character(String(num))) {
                            board[i][j] = Character(String(num))
                            
                            if helper(&board) {
                                return true
                            } else {
                                board[i][j] = "."
                            }
                        }
                    }
                    return false
                }
            }
        }
        
        return true
    }
    
    private func isValid(_ board: [[Character]], _ i: Int, _ j: Int, _ num: Character) -> Bool {
        let m = board.count, n = board[0].count
    
        // check row
        for x in 0..<n {
            if board[i][x] == num {
                return false
            }
        }
        
        // check col
        for y in 0..<m {
            if board[y][j] == num {
                return false
            }
        }
        
        // check square
        for x in i / 3 * 3..<i / 3 * 3 + 3 {
            for y in j / 3 * 3..<j / 3 * 3 + 3 {
                if board[x][y] == num {
                    return false
                }
            }
        }
        
        return true
    }
}

---

328ms

class Solution {
    func isValidSudoku(_ board: inout [[Character]], row: Int, column: Int, char: Character) -> Bool {
        for i in 0..<9 {
            if board[i][column] == char {
                return false
            }

            if board[row][i] == char {
                return false
            }

            if board[3 * (row / 3) + i / 3][3 * (column / 3) + i % 3] == char {
                return false
            }
        }
        return true
    }

    func solve(_ board: inout [[Character]]) -> Bool {
        let digits: [Character] = ["1", "2", "3", "4", "5", "6", "7", "8", "9"]
        for i in 0..<9 {
            for j in 0..<9 {
                guard board[i][j] == "." else { continue }

                for char in digits {
                    guard isValidSudoku(&board, row: i, column: j, char: char) else { continue }

                    board[i][j] = char
                    if solve(&board) {
                        return true
                    } else {
                        board[i][j] = "."
                    }
                }
                
                return false
            }
        }
        return true
    }

    func solveSudoku(_ board: inout [[Character]]) {
        solve(&board)
    }
}

---

460ms

class Solution {
    func solveSudoku(_ board: inout [[Character]]) {
        solve(&board)
    }
    
    func solve(_ board: inout [[Character]]) -> Bool{
        for i in 0..<9{
            for j in 0..<9{
                if board[i][j] == "."{
                    for k in "123456789"{
                        if valid(board, i, j, k){
                            board[i][j] = k
                            if solve(&board){
                                return true
                            }
                            board[i][j] = "."
                        }
                    }
                    return false
                }
            }
        }
         return true
    }
    
    func valid(_ board: [[Character]], _ i: Int, _ j: Int, _ k: Character) -> Bool{
        for m in 0..<9{
            if board[i][m] != "." && board[i][m] == k{
                return false
            }
            
            if board[m][j] != "." && board[m][j] == k{
                return false
            }
            
            var rowIndex = i / 3 * 3 + m / 3
            var colIndex = j / 3 * 3 + m % 3
            if board[rowIndex][colIndex] != "." && board[rowIndex][colIndex] == k{
                return false
            }
            
            
        }
        return true
    }
    
    
}

---

520ms

class Solution {
    var count: Int = 0
    func solveSudoku(_ board: inout [[Character]]) {
        // var result = board
        solve(row: 0, col: 0, board: &board)
    }
    
    func solve(row: Int, col: Int, board: inout [[Character]]) -> Bool {
        for i in 0 ..< 9 {
            for j in 0 ..< 9 {
                if board[i][j] == "." {
                    let possibilities = getPossibilities(row: i, col: j, board: board)
                    for current in possibilities {
                        count += 1
                        board[i][j] = current
                        if solve(row: i, col: j, board: &board) {
                            return true
                        } else {
                            board[i][j] = "."
                        }
                    }
                    return false
                }
            }
        }
        return true
    }
    
    func getPossibilities(row: Int, col: Int, board: [[Character]]) -> [Character] {
        var taken : [Character] = []
        for i in 0 ..< 9 {
            if board[row][i] != "." {
                taken.append(board[row][i])
            }
        }
        for i in 0 ..< 9 {
            if board[i][col] != "." {
                taken.append(board[i][col])
            }
        }
        let cubeR = (row/3)*3
        let cubeC = (col/3)*3
        for i in cubeR ..< cubeR + 3 {
            for j in cubeC ..< cubeC + 3 {
                if board[i][j] != "." {
                    taken.append(board[i][j])
                }
            }
        }
        let all:[Character] = ["1","2","3","4","5","6","7","8","9"]
        var available: [Character] = []
        for each in all {
            if !taken.contains(each) {
                available.append(each)
            }
        }
        // print("row:(row) col:(col) available:(available)")
        return available
    }
}

---

636ms

class Solution {
    func solveSudoku(_ board: inout [[Character]]) {
        dfs(&board, 0, 0)
    }
    
    func dfs(_ board: inout [[Character]], _ x: Int, _ y: Int) -> Bool {
        if x > 8 || y > 8 {
            return true
        }
        
        if board[x][y] == "." {
            for k in 1...9 {
                if isValid(&board, x, y, Character.init("(k)")) {
                    board[x][y] = Character.init("(k)")
                    var nextX = x
                    var nextY = y + 1
                    if nextY == 9 {
                        nextY = 0
                        nextX += 1
                    }
                    if dfs(&board, nextX, nextY) {
                        return true
                    }
                    board[x][y] = "."
                }
            }
            return false
        } else {
            var nextX = x
            var nextY = y + 1
            if nextY == 9 {
                nextY = 0
                nextX += 1
            }
            return dfs(&board, nextX, nextY)
        }
    }
    
    func isValid(_ board: inout [[Character]], _ x:  Int, _ y: Int, _ k: Character) -> Bool {
        for i in 0..<9 {
            if board[i][y] == k || board[x][i] == k {
                return false
            }
        }
        
        for i in 0..<3 {
            for j in 0..<3 {
                if board[3*(x/3)+i][3*(y/3)+j] == k {
                    return false
                }
            }
        }
        return true
    }
}

---

668ms

class Solution {
  
  func solveSudoku(_ board: inout [[Character]]) {
    
    solveSudoku2(&board)
  }
    
  func solveSudoku2(_ board: inout [[Character]]) -> Bool {
    for i in 0 ..< board.count {
      for j in 0 ..< board[0].count {
        if board[i][j] == "." {
          
          
          for n in ["1", "2", "3", "4", "5", "6", "7", "8", "9"] {
            var tempBoard = board
            if canPlace(board, Character(n), i, j) {
              tempBoard[i][j] = Character(n)
              
              if isSolved(tempBoard) {
                board = tempBoard
                return true
              } else {
                if solveSudoku2(&tempBoard) {
                  board = tempBoard
                  return true
                }
              }
            }
          }
          
          return false
        }
      }
    }
    
    return true
  }
  
  
  func canPlace(_ board: [[Character]], _ ch: Character, _ i: Int, _ j: Int) -> Bool {
    if board[i].contains(ch) {
      return false
    }
    
    for ii in 0 ..< board.count {
      if board[ii][j] == ch {
        return false
      }
    }
    
    var iMax = 3
    
    if i <= 2 {
      iMax = 3
    } else if i <= 5 {
      iMax = 6
    } else {
      iMax = 9
    }
    
    var jMax = 3
    
    if j <= 2 {
      jMax = 3
    } else if j <= 5 {
      jMax = 6
    } else {
      jMax = 9
    }
    
    for ii in iMax - 3 ..< iMax {
      for jj in jMax - 3 ..< jMax {
        if board[ii][jj] == ch {
          return false
        }
      }
    }
    
    return true
  }
  
  func isSolved(_ board: [[Character]]) -> Bool {
    for i in 0 ..< board.count {
      for j in 0 ..< board[0].count {
        if board[i][j] == "." {
          return false
        }
      }
    }
    
    return true
  }
}

---

692ms

class Solution {
    func solveSudoku(_ board: inout [[Character]]) {
        guard board.count != 0 || board[0].count != 0 else {
            return
        }
        helper(&board)
    }
    
    private func helper(_ board: inout [[Character]]) -> Bool {
        let m = board.count, n = board[0].count
    
        for i in 0..<m {
            for j in 0..<n {
                if board[i][j] == "." {
                    for num in 1...9 {
                        if isValid(board, i, j, Character(String(num))) {
                            board[i][j] = Character(String(num))
                            
                            if helper(&board) {
                                return true
                            } else {
                                board[i][j] = "."
                            }
                        }
                    }
                    return false
                }
            }
        }
        
        return true
    }
    
    private func isValid(_ board: [[Character]], _ i: Int, _ j: Int, _ num: Character) -> Bool {
        let m = board.count, n = board[0].count
    
        // check row
        for x in 0..<n {
            if board[i][x] == num {
                return false
            }
        }
        
        // check col
        for y in 0..<m {
            if board[y][j] == num {
                return false
            }
        }
        
        // check square
        for x in i / 3 * 3..<i / 3 * 3 + 3 {
            for y in j / 3 * 3..<j / 3 * 3 + 3 {
                if board[x][y] == num {
                    return false
                }
            }
        }
        
        return true
    }
}