51. N-Queens
Problem Description
The n-queens puzzle is a classic problem of placing n
queens on an n x n
chessboard in a way that no queens can attack each other. This means two queens can't be in the same row, column, or diagonal. The challenge is to find all the possible arrangements of the n
queens where these conditions are met.
Flowchart Walkthrough
Let's analyze LeetCode 51. N-Queens using the provided algorithm flowchart to determine the appropriate algorithm pattern:
Step-by-Step Flowchart Analysis:
-
Is it a graph?
- No: While N-Queens involves positioning queens on a board, it does not deal directly with graphs; instead, it involves a chessboard and placing queens such that no two queens attack each other.
-
Need to solve for kth smallest/largest?
- No: The objective of the problem is not to determine kth metrics but to find all possible arrangements of N queens on an N×N chessboard.
-
Involves Linked Lists?
- No: The N-Queens problem does not involve linked lists.
-
Does the problem have small constraints?
- Yes: The problem typically deals with a relatively small size of the board (N). For practical computations, the constraints are manageable (e.g., N is often considered up to 12 or 15).
-
Brute force / Backtracking?
- Yes: To find all valid arrangements of N queens, a brute-force search with backtracking is appropriate since each arrangement requires checking all previous placements for conflicts (such as checking rows, columns, and diagonals).
Conclusion: The N-Queens problem should be approached using the Backtracking pattern. This method systematically tries placing queens in each row and backtracks when no valid placement is possible, ensuring all solutions are explored. This fits model as described in the the Flowchart.
Intuition
To solve the n-queens puzzle, we can use a method called Depth-First Search (DFS), which is a type of backtracking algorithm. The idea is to place queens one by one in different columns, starting from the leftmost column and moving to the right. If we find a placement for a queen that does not lead to a conflict, we then move on to place the next queen in the next column. If at any step we cannot place a queen without a conflict, we backtrack and move the previous queen to a new position.
The efficiency of this backtracking algorithm can be drastically improved by keeping track of the columns, diagonals, and anti-diagonals that are already under attack by existing queens:
- To mark the columns that are occupied, an array called
col
is used, with a length equal to the number of columns (n
). - For the diagonals (
dg
), an array of size2n
is used, because there are2n - 1
possible diagonals on the board. A diagonal's index can be calculated by the sum of the row and column indices of a cell. - For the anti-diagonals (
udg
), an array with the same size as the diagonals is used. The anti-diagonal's index is obtained by the difference between the column index and the row index, plusn
to avoid negative indices.
Each time a queen is placed, we mark the corresponding column, diagonal, and anti-diagonal as occupied. We unmark them when we backtrack. This way, we ensure no two queens threaten each other, and we generate all valid solutions for the problem.
Learn more about Backtracking patterns.
Solution Approach
The solution approach to the n-queens puzzle involves implementing a recursive Depth-First Search (DFS) that tries to place queens one by one across each row. The given Python code defines a recursive function dfs
which attempts to place a queen in every row – the i
parameter corresponds to the current row index where the function tries to place a queen.
Here's a step-by-step explanation of the algorithm, along with the corresponding aspects of the provided code:
-
Initialization:
- Create a list
ans
to store the solutions. - Initialize a 2D list
g
withn
lists, each filled with a string ofn
periods ("."
). This represents the chessboard where a"."
is an empty space and will be replaced by a"Q"
when a queen is placed. - Initialize
col
,dg
, andudg
arrays which represent the columns, diagonals, and anti-diagonals that are already attacked by queens.
- Create a list
-
Recursive DFS Function
dfs(i)
:- The base case is when
i == n
, meaning all rows have been visited, and thus a valid configuration of the n-queens has been found. At this point, the current configuration is added toans
. - In each call of the
dfs
function, iterate through every columnj
in rowi
to try and place a queen.
- The base case is when
-
Checking Conditions for Placing a Queen:
- For each column
j
, check the safety by ensuring that there's no existing queen attacking the position(i, j)
. This is done by ensuringcol[j] + dg[i + j] + udg[n - i + j] == 0
. If this condition holds, it means placing a queen at position(i, j)
will not result in an attack.
- For each column
-
Placing a Queen and Marking the Attacks:
- When a safe spot is found, place the queen by setting
g[i][j] = "Q"
and mark the columncol[j]
, diagonaldg[i + j]
, and anti-diagonaludg[n - i + j]
as attacked by setting them to1
.
- When a safe spot is found, place the queen by setting
-
Recursive Call for the Next Row:
- Call
dfs(i + 1)
to attempt to place a queen in the next row.
- Call
-
- If placing the next queen leads to a dead-end (no further valid placements), or after recording a valid setup when reaching the base case, the function will backtrack by resetting the queen's position and unmarking the attacked paths. This is done by setting
g[i][j] = "."
, and resettingcol[j]
,dg[i + j]
, andudg[n - i + j]
back to0
.
- If placing the next queen leads to a dead-end (no further valid placements), or after recording a valid setup when reaching the base case, the function will backtrack by resetting the queen's position and unmarking the attacked paths. This is done by setting
-
Starting the DFS:
- Initially call
dfs(0)
to start the process of attempting to place queens starting from the first row.
- Initially call
By applying DFS and backtracking effectively, this solution traverses the decision tree by trying different queen positions and backtracks whenever it encounters a conflict, ensuring that all possible valid arrangements of the queens on the board are found.
The elegance of this strategy lies in its ability to avoid checking for queen attacks for every placement, which would result in a slower, brute-force algorithm. Instead, the state is managed by strategically using arrays, decreasing the time complexity significantly. This makes the solution smart and efficient.
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Let's illustrate the solution approach using a small 4x4 board example for the n-queens puzzle. Our goal is to place 4 queens on this board so that no two queens can attack each other.
-
Initialization:
- We start with an empty solution list
ans
and an empty 4x4 chessboardg
represented by:[".", ".", ".", "."], [".", ".", ".", "."], [".", ".", ".", "."], [".", ".", ".", "."]
- We also initialize the arrays
col
,dg
, andudg
to track attacked columns, diagonals, and anti-diagonals. Since the board is 4x4,col
will have 4 elements, anddg
andudg
will each have 7 elements (since2n - 1 = 7
forn = 4
).
- We start with an empty solution list
-
Recursive DFS Function
dfs(0)
:- We start the DFS by calling
dfs(0)
, indicating that we're trying to place a queen in row0
.
- We start the DFS by calling
-
Checking Conditions for Placing a Queen:
- We try to place the first queen in row
0
, column0
. To check for safety, we ensure that no queen attacks position(0, 0)
by confirmingcol[0] + dg[0 + 0] + udg[4 - 0 + 0] == 0
. This is true, as all arrays are initialized with zeros.
- We try to place the first queen in row
-
Placing a Queen and Marking the Attacks:
- We place the queen at
(0, 0)
:["Q", ".", ".", "."], [".", ".", ".", "."], [".", ".", ".", "."], [".", ".", ".", "."]
- Mark the attacks by setting
col[0]
,dg[0 + 0]
, andudg[4 - 0 + 0]
to1
.
- We place the queen at
-
Recursive Call for the Next Row
dfs(1)
:- Now we call
dfs(1)
to try to place a queen in the next row.
- Now we call
-
Backtracking and Continuing the Search:
- In row
1
, the first column is attacked, so we try column1
. Position(1, 1)
is safe, so we place the queen there and proceed todfs(2)
. - In row
2
, columns0
and1
are attacked. We find that(2, 2)
is also under attack, but(2, 3)
is safe, so we place the queen there and calldfs(3)
. - In row
3
, columns0
,1
, and3
are under attack. We find that placing a queen at(3, 2)
is safe. - We have now successfully placed queens on all rows which give us one valid solution:
["Q", ".", ".", "."], [".", "Q", ".", "."], [".", ".", ".", "Q"], [".", ".", "Q", "."]
- We then record this solution and backtrack to find more. We remove the queen from
(3, 2)
, unmark the attacks, and go back to row2
to find a new position for a queen.- Trying to place another queen in row
2
finds no valid position, causing further backtracking to row1
. - We try a new position for the queen in row
1
, and if possible, proceed to row2
again. - We continue this process of backtracking and searching until all possible placements have been tried for all rows.
- Trying to place another queen in row
- In row
By following these steps, the recursive DFS algorithm ensures that all the conditions of the n-queens puzzle are respected, and thus all valid solutions are found. For the 4x4 board, there are two solutions, and both will be included in the ans
list.
Solution Implementation
1class Solution:
2 def solveNQueens(self, n: int) -> List[List[str]]:
3 def backtrack(row: int):
4 # When the row number equals 'n', it means all queens are placed successfully
5 if row == n:
6 # Save a solution by converting each row's list representation to a string
7 solution.append([''.join(row_state) for row_state in board])
8 return
9 # Iterate over columns to try placing a queen
10 for col in range(n):
11 # Check if placing a queen here violates no constraints
12 if column[col] + diagonal[row + col] + anti_diagonal[n - row + col] == 0:
13 # Place the queen by updating the board and marking the corresponding constraints
14 board[row][col] = "Q"
15 column[col] = diagonal[row + col] = anti_diagonal[n - row + col] = 1
16 # Move on to the next row
17 backtrack(row + 1)
18 # Backtrack: remove the queen and the constraints
19 column[col] = diagonal[row + col] = anti_diagonal[n - row + col] = 0
20 board[row][col] = "."
21
22 # Initialize solution list
23 solution = []
24 # Initialize board with dots representing empty spaces
25 board = [["."] * n for _ in range(n)]
26 # Prepare constraint lists to check the columns and diagonals/anti-diagonals
27 column = [0] * n
28 diagonal = [0] * (2 * n)
29 anti_diagonal = [0] * (2 * n)
30 # Start the backtracking algorithm from the first row
31 backtrack(0)
32 # Return the list of all the solutions after converting them to the expected output format
33 return solution
34
1import java.util.List;
2import java.util.ArrayList;
3import java.util.Arrays;
4
5public class Solution {
6 // The list that will contain all possible solutions
7 private List<List<String>> solutions = new ArrayList<>();
8
9 // Arrays to mark if a column, diagonal, or anti-diagonal is occupied
10 private int[] columns;
11 private int[] diagonals;
12 private int[] antiDiagonals;
13
14 // Chessboard representation
15 private String[][] board;
16
17 // Size of the board
18 private int size;
19
20 // The public method to solve the N-Queens problem
21 public List<List<String>> solveNQueens(int n) {
22 this.size = n;
23 columns = new int[n];
24 diagonals = new int[2 * n];
25 antiDiagonals = new int[2 * n];
26 board = new String[n][n];
27
28 // Initialize the board with empty strings
29 for (int i = 0; i < n; ++i) {
30 Arrays.fill(board[i], ".");
31 }
32
33 // Begin the depth-first search from the first row
34 depthFirstSearch(0);
35 return solutions;
36 }
37
38 // The recursive method to place a queen on the board
39 private void depthFirstSearch(int row) {
40 // If all queens are placed
41 if (row == size) {
42 List<String> oneSolution = new ArrayList<>();
43 for (int i = 0; i < size; ++i) {
44 // Join the row to form the string
45 oneSolution.add(String.join("", board[i]));
46 }
47 // Add the current board configuration to the solutions list
48 solutions.add(oneSolution);
49 return;
50 }
51 // Iterate through each column for the current row
52 for (int col = 0; col < size; ++col) {
53 // Check if the current position is safe for placing a queen
54 if (columns[col] + diagonals[row + col] + antiDiagonals[size - row + col] == 0) {
55 // Place the queen
56 board[row][col] = "Q";
57 // Mark current column, diagonal, and anti-diagonal as occupied
58 columns[col] = diagonals[row + col] = antiDiagonals[size - row + col] = 1;
59 // Continue to place the next queen
60 depthFirstSearch(row + 1);
61 // Backtrack and remove the queen
62 columns[col] = diagonals[row + col] = antiDiagonals[size - row + col] = 0;
63 board[row][col] = ".";
64 }
65 }
66 }
67}
68
1#include <vector>
2#include <string>
3#include <functional>
4
5class Solution {
6public:
7 std::vector<std::vector<std::string>> solveNQueens(int n) {
8 // Arrays to mark the columns and diagonals as occupied.
9 std::vector<int> col_occupied(n, 0);
10 std::vector<int> diag_occupied(2 * n, 0);
11 std::vector<int> anti_diag_occupied(2 * n, 0);
12
13 // Answer array to store all possible configurations.
14 std::vector<std::vector<std::string>> solutions;
15
16 // Temporary board to build one configuration at a time.
17 std::vector<std::string> board(n, std::string(n, '.'));
18
19 // Lambda function for backtracking.
20 std::function<void(int)> backtrack = [&](int row) -> void {
21 // Base case: If we placed all queens, add the configuration to the solution.
22 if (row == n) {
23 solutions.push_back(board);
24 return;
25 }
26
27 // Try placing a queen in each column of the current row.
28 for (int column = 0; column < n; ++column) {
29 // Check if the column, diagonal, and anti-diagonal are not occupied.
30 if (!col_occupied[column] && !diag_occupied[row + column]
31 && !anti_diag_occupied[n - row + column]) {
32 // Place the queen.
33 board[row][column] = 'Q';
34 // Mark the column and diagonals as occupied.
35 col_occupied[column] = diag_occupied[row + column]
36 = anti_diag_occupied[n - row + column] = 1;
37
38 // Move to the next row.
39 backtrack(row + 1);
40
41 // Undo the move before backtracking.
42 col_occupied[column] = diag_occupied[row + column]
43 = anti_diag_occupied[n - row + column] = 0;
44 board[row][column] = '.';
45 }
46 }
47 };
48
49 // Start the backtracking process from the first row.
50 backtrack(0);
51
52 // Return all possible valid boards.
53 return solutions;
54 }
55};
56
1function solveNQueens(n: number): string[][] {
2 // These arrays record if a column or diagonal is under attack
3 const columns: number[] = new Array(n).fill(0);
4 const diag: number[] = new Array(n * 2).fill(0);
5 const antiDiag: number[] = new Array(n * 2).fill(0);
6 // This is the solution set
7 const solutions: string[][] = [];
8 // Temporary matrix to build the current state
9 const board: string[][] = Array(n)
10 .fill(0)
11 .map(() => Array(n).fill('.'));
12
13 // Depth-first search function
14 const dfs = (row: number) => {
15 // If all rows are filled, add the current board state to solutions
16 if (row === n) {
17 solutions.push(board.map(row => row.join('')));
18 return;
19 }
20
21 // Iterate over columns in the current row
22 for (let col = 0; col < n; ++col) {
23 // Ensure the position is not under attack by checking the markers
24 if (columns[col] + diag[row + col] + antiDiag[n - row + col] === 0) {
25 // Place a queen and mark the column and diagonals as under attack
26 board[row][col] = 'Q';
27 columns[col] = diag[row + col] = antiDiag[n - row + col] = 1;
28 // Move to the next row
29 dfs(row + 1);
30 // Backtrack: remove the queen and remove the attack markers
31 columns[col] = diag[row + col] = antiDiag[n - row + col] = 0;
32 board[row][col] = '.';
33 }
34 }
35 };
36
37 // Start DFS from the first row
38 dfs(0);
39
40 return solutions;
41}
42
Time and Space Complexity
The given Python code is a solution for the N-Queens problem, where the objective is to place n
queens on an n x n
chessboard so that no two queens threaten each other.
Time Complexity
The time complexity of the solution is determined primarily by the number of valid queen placements that are possible on the board. The DFS function dfs(i: int)
is called recursively for every row (where i
is the row index), and in each call, it attempts to place a queen in each column of the current row.
- The main time complexity comes from the potential number of recursive calls in the depth-first search (DFS). For each row, we attempt to place a queen in every column, yielding a branching factor of
n
. - However, due to the constraint checks (
col[j]
,dg[i + j]
,udg[n - i + j]
), the actual number of recursive calls will be less thann
for subsequent rows. - The upper bound complexity can be represented by
O(n!)
, since there aren
possibilities for the first row,n - 1
for the second, and so on until the base case is reached. - The average complexity is hard to determine due to the constraint checks pruning the recursion tree, but it is significantly less than the upper bound.
Space Complexity
The space complexity accounts for the storage required for the recursive calls, the grid g
, and the arrays for maintaining column, diagonal, and anti-diagonal checks (col
, dg
, udg
).
- The grid
g
consumesO(n^2)
space as it is a 2D matrix. - The arrays
col
,dg
,udg
consumeO(n)
,O(2n)
(orO(n)
) andO(2n)
(orO(n)
) space respectively, since there are2n - 1
possible diagonals and anti-diagonals on ann x n
chessboard. Scaled down, they contributeO(n)
to the space complexity. - The depth of the recursion stack is
O(n)
because there can be at mostn
recursive calls (one for each row) at any given time.
Hence, the space complexity is O(n^2)
from the grid g
, which dominates the space complexity relative to the recursive call stack and additional arrays.
In summary:
- The time complexity is
O(n!)
as an upper bound. - The space complexity is
O(n^2)
due to the grid used to store intermediate solutions.
Learn more about how to find time and space complexity quickly using problem constraints.
Which of the following array represent a max heap?
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