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Ema's Supercomputer

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329 Discussions

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  • naufalfh19
     + 0 comments

    Python3 Section

    def plusSection(r, c, k):
    cells = {(r, c)}
    for i in range(1, k+1):
        cells.add((r+i, c))
        cells.add((r-i, c))
        cells.add((r, c+i))
        cells.add((r, c-i))
    return cells


def areaOfTwoPluses(p1, p2):
    r1, c1, area1, count1 = p1
    r2, c2, area2, count2 = p2

    cells1 = plusSection(r1, c1, count1)
    cells2 = plusSection(r2, c2, count2)

    if cells1 & cells2: 
        return max(area1, area2)

    return area1 * area2

    
def savePlusess(r, c, grid):
    row, col = len(grid), len(grid[0])
    count = 1
    
    plusess = []
    
    while True: 
        if r + count >= row:
            break
        if r - count < 0:
            break
        if c + count >= col:
            break
        if c - count < 0:
            break
        if grid[r+count][c] != "G":
            break
        if grid[r-count][c] != "G":
            break 
        if grid[r][c+count] != "G":
            break
        if grid[r][c-count] != "G":
            break
        
        count += 1
        
        plusess.append((1 + 4*(count-1), count-1))
            
    return plusess

def twoPluses(grid):
    row, col = len(grid), len(grid[0])
    plusess = []

    for r in range(row):
        for c in range(col):
            if grid[r][c] == "G":
                currPlusess = savePlusess(r, c, grid)
                for pluses in currPlusess:
                    area = pluses[0]
                    count = pluses[1]
                    plusess.append((r, c, area, count))
      
    if len(plusess) == 1:
        return plusess[0][2]
    
    res = 1
    for i in range(len(plusess)):
        for j in range(i+1, len(plusess)):
            area = areaOfTwoPluses(plusess[i], plusess[j])
            if area > res:
                res = area
        
    return res

  • petru_braha
     + 0 comments

    python solution (it took me way more time than expected):

    class Plus:
    def __init__(self, i, j, k):
        self.i = i
        self.j = j
        self.k = k
    
    def is_disjoint(self, another):
        if self.i == another.i:
            if self.j > another.j and self.j - self.k <= another.j + another.k:
                return False
            if self.j < another.j and self.j + self.k >= another.j - another.k:
                return False
        if self.j == another.j:
            if self.i > another.i and self.i - self.k <= another.i + another.k:
                return False
            if self.i < another.i and self.i + self.k >= another.i - another.k:
                return False
        
        if another.i - another.k <= self.i <= another.i + another.k:
            if self.j - self.k <= another.j <= self.j + self.k:
                return False
        if another.j - another.k <= self.j <= another.j + another.k:
            if self.i - self.k <= another.i <= self.i + self.k:
                return False
        return True
        
def get_pluses(grid, i, j, k_range):
    n = len(grid)
    m = len(grid[0])
    
    pluses = [Plus(i, j, 0)]
    for k in range(1, k_range):
        if i - k < 0 or i + k >= n:
            return pluses
        if j - k < 0 or j + k >= m:
            return pluses
                
        positions = [(i - k, j), (i, j + k), (i + k, j), (i, j - k)]
        for pos in positions:
            if grid[pos[0]][pos[1]] != 'G':
                return pluses
        pluses.append(Plus(i, j, k))
    return pluses

def twoPluses(grid):
    n = len(grid)
    m = len(grid[0])
    minimum_size = min(n, m)
    pluses = []
    
    for i in range(n):
        for j in range(m):
            if grid[i][j] != 'G':
                continue
            pluses += get_pluses(grid, i, j, (minimum_size+1)//2)
    
    maximum_area = 0
    for index_plus0 in range(len(pluses) - 1):
        for index_plus1 in range(index_plus0 + 1, len(pluses)):
            if pluses[index_plus0].is_disjoint(pluses[index_plus1]):
                area0 = pluses[index_plus0].k * 4 + 1
                area1 = pluses[index_plus1].k * 4 + 1
                current_area = area0 * area1
                if current_area > maximum_area:
                    maximum_area = current_area
    return maximum_area

  • ds1b_1641540100
     + 0 comments

    **Solution in Python 3 **

    #!/bin/python3

import math
import os
import random
import re
import sys

#
# Complete the 'twoPluses' function below.
#
# The function is expected to return an INTEGER.
# The function accepts STRING_ARRAY grid as parameter.
#

def twoPluses(grid):
    n, m = len(grid), len(grid[0])
    up = [[0]*m for _ in range(n)]
    down = [[0]*m for _ in range(n)]
    left = [[0]*m for _ in range(n)]
    right = [[0]*m for _ in range(n)] 
    for i in range(n):
        for j in range(m):
            if grid[i][j] == 'G':
                up[i][j] = 1 + (up[i-1][j] if i > 0 else 0)
                left[i][j] = 1 + (left[i][j-1] if j > 0 else 0)
    for i in reversed(range(n)):
        for j in reversed(range(m)):
            if grid[i][j] == 'G':
                down[i][j] = 1 + (down[i+1][j] if i < n-1 else 0)
                right[i][j] = 1 + (right[i][j+1] if j < m-1 else 0)
    pluses = []
    for i in range(n):
        for j in range(m):
            if grid[i][j] == 'G':
                arm_len = min(up[i][j], down[i][j], left[i][j], right[i][j]) - 1
                for length in range(arm_len + 1):
                    pluses.append((i, j, length, 4*length + 1))  
    
    def cells_of_plus(r, c, arm):
        cells = {(r, c)}
        for k in range(1, arm+1):
            cells.add((r+k, c))
            cells.add((r-k, c))
            cells.add((r, c+k))
            cells.add((r, c-k))
        return cells
    max_product = 0
    for i in range(len(pluses)):
        r1, c1, arm1, area1 = pluses[i]
        cells1 = cells_of_plus(r1, c1, arm1)
        for j in range(i+1, len(pluses)):
            r2, c2, arm2, area2 = pluses[j]
            cells2 = cells_of_plus(r2, c2, arm2)
            if cells1.isdisjoint(cells2):
                product = area1 * area2
                if product > max_product:
                    max_product = product
    return max_product


if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    first_multiple_input = input().rstrip().split()

    n = int(first_multiple_input[0])

    m = int(first_multiple_input[1])

    grid = []

    for _ in range(n):
        grid_item = input()
        grid.append(grid_item)

    result = twoPluses(grid)

    fptr.write(str(result) + '\n')

    fptr.close()

  • aliraza413063321
     + 0 comments

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  • anarod_val25
     + 0 comments

    Respectfully, this problem is not "medium", it's freaking hard! (ಥ﹏ಥ)

    Heres is my c++ solutions, hope is helps someone.

    struct Plus {
    int area;
    vector<pair<int,int>> cells;
};

vector<Plus> allPlussesAt(int y, int x, const vector<string>& grid) {
    vector<Plus> result;
    if (grid[y][x] != 'G') return result;

    int arm = 0;
    int rows = grid.size(), cols = grid[0].size();

    while (y-arm >= 0 && y+arm < rows &&
           x-arm >= 0 && x+arm < cols &&
           grid[y-arm][x] == 'G' &&
           grid[y+arm][x] == 'G' &&
           grid[y][x-arm] == 'G' &&
           grid[y][x+arm] == 'G') {
        
        vector<pair<int,int>> cells;
        cells.push_back({y,x});
        for (int k=1; k<=arm; k++) {
            cells.push_back({y-k,x});
            cells.push_back({y+k,x});
            cells.push_back({y,x-k});
            cells.push_back({y,x+k});
        }
        
        result.push_back({1 + 4*arm, cells});
        arm++;
    }

    return result;
}

vector<Plus> allPlusses(const vector<string>& grid) {
    vector<Plus> plusses;
    for (int y=0; y<grid.size(); y++) {
        for (int x=0; x<grid[0].size(); x++) {
            auto p = allPlussesAt(y, x, grid);
            plusses.insert(plusses.end(), p.begin(), p.end());
        }
    }
    return plusses;
}

bool overlap(const Plus& a, const Plus& b) {
    for (auto &cellA : a.cells) {
        for (auto &cellB : b.cells) {
            if (cellA == cellB) return true;
        }
    }
    return false;
}

int maxPlusAreaAt(int y, int x, const vector<string>& grid) {
    if (grid[y][x] != 'G') return 0;

    int arm = 0;
    int rows = grid.size(), cols = grid[0].size();

    while (y-arm >= 0 && y+arm < rows &&
           x-arm >= 0 && x+arm < cols &&
           grid[y-arm][x] == 'G' &&
           grid[y+arm][x] == 'G' &&
           grid[y][x-arm] == 'G' &&
           grid[y][x+arm] == 'G') {
        arm++;
    }
    arm--; 
    
    return 1 + 4*arm;
}

int twoPluses(vector<string> grid) {
    vector<Plus> plusses = allPlusses(grid);

    int best = 0;
    for (int i=0; i<plusses.size(); i++) {
        for (int j=i+1; j<plusses.size(); j++) {
            if (!overlap(plusses[i], plusses[j])) {
                best = max(best, plusses[i].area * plusses[j].area);
            }
        }
    }

    return best;
}