"""
Question:
Given a binary matrix mat of size n * m, find out the maximum size square
sub-matrix with all 1s.
---
Example 1:
Input:
n = 2, m = 2
mat = [[1, 1],
[1, 1]]
Output:
2
Explanation: The maximum size of the square
sub-matrix is 2. The matrix itself is the
maximum sized sub-matrix in this case.
---
Example 2
Input:
n = 2, m = 2
mat = [[0, 0],
[0, 0]]
Output: 0
Explanation: There is no 1 in the matrix.
Approach:
We initialize another matrix (dp) with the same dimensions
as the original one initialized with all 0’s.
dp_array(i,j) represents the side length of the maximum square whose
bottom right corner is the cell with index (i,j) in the original matrix.
Starting from index (0,0), for every 1 found in the original matrix,
we update the value of the current element as
dp_array(i,j)=dp_array(dp(i−1,j),dp_array(i−1,j−1),dp_array(i,j−1)) + 1.
"""
def largest_square_area_in_matrix_top_down_approch(
rows: int, cols: int, mat: list[list[int]]
) -> int:
"""
Function updates the largest_square_area[0], if recursive call found
square with maximum area.
We aren't using dp_array here, so the time complexity would be exponential.
>>> largest_square_area_in_matrix_top_down_approch(2, 2, [[1,1], [1,1]])
2
>>> largest_square_area_in_matrix_top_down_approch(2, 2, [[0,0], [0,0]])
0
"""
def update_area_of_max_square(row: int, col: int) -> int:
if row >= rows or col >= cols:
return 0
right = update_area_of_max_square(row, col + 1)
diagonal = update_area_of_max_square(row + 1, col + 1)
down = update_area_of_max_square(row + 1, col)
if mat[row][col]:
sub_problem_sol = 1 + min([right, diagonal, down])
largest_square_area[0] = max(largest_square_area[0], sub_problem_sol)
return sub_problem_sol
else:
return 0
largest_square_area = [0]
update_area_of_max_square(0, 0)
return largest_square_area[0]
def largest_square_area_in_matrix_top_down_approch_with_dp(
rows: int, cols: int, mat: list[list[int]]
) -> int:
"""
Function updates the largest_square_area[0], if recursive call found
square with maximum area.
We are using dp_array here, so the time complexity would be O(N^2).
>>> largest_square_area_in_matrix_top_down_approch_with_dp(2, 2, [[1,1], [1,1]])
2
>>> largest_square_area_in_matrix_top_down_approch_with_dp(2, 2, [[0,0], [0,0]])
0
"""
def update_area_of_max_square_using_dp_array(
row: int, col: int, dp_array: list[list[int]]
) -> int:
if row >= rows or col >= cols:
return 0
if dp_array[row][col] != -1:
return dp_array[row][col]
right = update_area_of_max_square_using_dp_array(row, col + 1, dp_array)
diagonal = update_area_of_max_square_using_dp_array(row + 1, col + 1, dp_array)
down = update_area_of_max_square_using_dp_array(row + 1, col, dp_array)
if mat[row][col]:
sub_problem_sol = 1 + min([right, diagonal, down])
largest_square_area[0] = max(largest_square_area[0], sub_problem_sol)
dp_array[row][col] = sub_problem_sol
return sub_problem_sol
else:
return 0
largest_square_area = [0]
dp_array = [[-1] * cols for _ in range(rows)]
update_area_of_max_square_using_dp_array(0, 0, dp_array)
return largest_square_area[0]
def largest_square_area_in_matrix_bottom_up(
rows: int, cols: int, mat: list[list[int]]
) -> int:
"""
Function updates the largest_square_area, using bottom up approach.
>>> largest_square_area_in_matrix_bottom_up(2, 2, [[1,1], [1,1]])
2
>>> largest_square_area_in_matrix_bottom_up(2, 2, [[0,0], [0,0]])
0
"""
dp_array = [[0] * (cols + 1) for _ in range(rows + 1)]
largest_square_area = 0
for row in range(rows - 1, -1, -1):
for col in range(cols - 1, -1, -1):
right = dp_array[row][col + 1]
diagonal = dp_array[row + 1][col + 1]
bottom = dp_array[row + 1][col]
if mat[row][col] == 1:
dp_array[row][col] = 1 + min(right, diagonal, bottom)
largest_square_area = max(dp_array[row][col], largest_square_area)
else:
dp_array[row][col] = 0
return largest_square_area
def largest_square_area_in_matrix_bottom_up_space_optimization(
rows: int, cols: int, mat: list[list[int]]
) -> int:
"""
Function updates the largest_square_area, using bottom up
approach. with space optimization.
>>> largest_square_area_in_matrix_bottom_up_space_optimization(2, 2, [[1,1], [1,1]])
2
>>> largest_square_area_in_matrix_bottom_up_space_optimization(2, 2, [[0,0], [0,0]])
0
"""
current_row = [0] * (cols + 1)
next_row = [0] * (cols + 1)
largest_square_area = 0
for row in range(rows - 1, -1, -1):
for col in range(cols - 1, -1, -1):
right = current_row[col + 1]
diagonal = next_row[col + 1]
bottom = next_row[col]
if mat[row][col] == 1:
current_row[col] = 1 + min(right, diagonal, bottom)
largest_square_area = max(current_row[col], largest_square_area)
else:
current_row[col] = 0
next_row = current_row
return largest_square_area
if __name__ == "__main__":
import doctest
doctest.testmod()
print(largest_square_area_in_matrix_bottom_up(2, 2, [[1, 1], [1, 1]]))