Discussion on Ema's Supercomputer Challenge

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1 day ago+ 0 comments

#!/bin/python3

import math
import os
import random
import re
import sys
from itertools import combinations

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

def twoPluses(grid):
    h, w = len(grid), len(grid[0])
    pluses = []

    def is_good(r, c):
        return 0 <= r < h and 0 <= c < w and grid[r][c] == 'G'

    # Generate all valid pluses
    for r in range(h):
        for c in range(w):
            if not is_good(r, c):
                continue
            size = 0
            occupied = {(r, c)}
            pluses.append((1, occupied.copy()))  # Add single cell plus
            while True:
                size += 1
                cells = {(r+i, c) for i in range(-size, size+1)} | {(r, c+i) for i in range(-size, size+1)}
                if all(is_good(x, y) for x, y in cells):
                    pluses.append((len(cells), cells.copy()))
                else:
                    break

    # Try all combinations of 2 pluses and find max area product of non-overlapping ones
    max_product = 0
    for (area1, cells1), (area2, cells2) in combinations(pluses, 2):
        if cells1.isdisjoint(cells2):
            max_product = max(max_product, area1 * area2)

    return max_product if max_product else 1  # At least one plus is guaranteed

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

    nm = input().split()
    n = int(nm[0])
    m = int(nm[1])

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

    result = twoPluses(grid)

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

1 day ago+ 0 comments

#!/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):
    # Write your code here
    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))  # (row, col, arm, area)    
    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()

1 day ago+ 0 comments

Ema's Supercomputer solution in Python

#!/bin/python3

import math
import os
import random
import re
import sys
import copy

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

class ValidPlus:
    def __init__(self):
        self.area = 1
        self.length = 1
        self.cells = []

    def addCell(self, cell):
        self.cells.append(cell)

class Cell:

    def __init__(self, row, column):
        self.row = row
        self.column = column

    def __str__(self):
        return str(self.row) + str(self.column)

    def __hash__(self):
        return hash(str(self))

    def __eq__(self, other):
        return self.row == other.row and self.column == other.column

    def __gt__(self, other):
        return self.row > other.row and self.column > other.column

    def __lt__(self, other):
        return self.row < other.row and self.column < other.column


if __name__ == '__main__':
    n, m = input().strip().split(' ')
    n, m = [int(n), int(m)]
    grid = []
    grid_i = 0
    for grid_i in range(n):
        grid_t = str(input().strip())
        grid.append(grid_t)
    validPluses = []
    for i in range(n):
        for j in range(m):
            current_cell = grid[i][j]
            if current_cell == 'G':
                there_is_a_good_cell = True
                validPlus = ValidPlus()
                length = 1
                validPlus.addCell(Cell(i,j))
                validPluses.append(validPlus)
                while there_is_a_good_cell:
                    if (i - length >= 0 and grid[i - length][j] == 'G') and (i + length < n and grid[i + length][j] == 'G') and (j - length >= 0 and grid[i][j - length] == 'G') and (j + length < m and grid[i][j + length] == 'G'):
                        new_valid_plus = copy.deepcopy(validPlus)
                        new_valid_plus.addCell(Cell(i - length, j))
                        new_valid_plus.addCell(Cell(i + length, j))
                        new_valid_plus.addCell(Cell(i, j - length))
                        new_valid_plus.addCell(Cell(i, j + length))
                        length += 1
                        new_valid_plus.area = 1 + (4 * (length - 1))
                        new_valid_plus.length = length
                        validPluses.append(new_valid_plus)
                        validPlus = copy.deepcopy(new_valid_plus)
                    else:
                        there_is_a_good_cell = False
    max_area = 0
    for i in range(len(validPluses)):
        current_valid_plus = validPluses[i]
        for j in range(i + 1, len(validPluses)):
            other_valid_plus = validPluses[j]
            current_area = current_valid_plus.area * other_valid_plus.area
            if current_area > max_area:
                current_cells = current_valid_plus.cells
                other_cells = other_valid_plus.cells
                common_cells = set(current_cells) - (set(current_cells) - set(other_cells))
                if len(common_cells) == 0:
                    max_area = current_area
    print(max_area)

2 months ago+ 0 comments

Here is problem solution in python java c++ c and Javascript - https://programmingoneonone.com/hackerrank-emas-supercomputer-problem-solution.html

3 months ago+ 0 comments

/* Helper functions. */ public static String point(int x, int y) { return String.format("%d,%d", x, y); } public static String point(int[] p) { return String.format("%d,%d", p[0], p[1]); } public static int[] add(int[] a, int[] b) { return new int[]{a[0] + b[0], a[1] + b[1]}; }

/*
 * Returns a list of sets where each set 
 * contains cell positions that make up a valid plus.
 * Starting at center x, y expand outwards as much as possible.
 * We save each plus we find in order to compare all possible pluses.
*/
public static List<Set<String>> allPluses(int x, int y, List<String> grid, Set<String> bad)
{
    List<Set<String>> allCombos = new ArrayList<>();

    int N = grid.size();
    int M = grid.get(0).length();
    int[][] directions = {
        {-1, 0}, //up
        {1, 0}, //down
        {0, -1}, //left
        {0, 1} //right
    };

    int[] up = new int[]{x, y};
    int[] down = new int[]{x, y};
    int[] left = new int[]{x, y};
    int[] right = new int[]{x, y};

    Set<String> cells = new HashSet<>();
    while(up[0] >= 0 && down[0] < N && left[1] >= 0 && right[1] < M)
    {
        if(bad.contains(point(up)) || bad.contains(point(left)) || bad.contains(point(right)) ||
                bad.contains(point(down)))
        {
            break;
        }

        Set<String> curr = new HashSet<>(cells);
        curr.add(point(up));
        curr.add(point(down));
        curr.add(point(left));
        curr.add(point(right));
        allCombos.add(curr);
        cells.addAll(curr);

        up = add(up, directions[0]);
        down = add(down, directions[1]);
        left = add(left, directions[2]);
        right = add(right, directions[3]);
    }
    return allCombos;
}

public static int twoPluses(List<String> grid) {
// Write your code here
final int N = grid.size();
final int M = grid.get(0).length();

//create set of all positions that are bad cells.
Set<String> badCells = new HashSet<>();
for(int x = 0; x < N; x++)
    for(int y = 0; y < M; y++)
        if(grid.get(x).charAt(y) != 'G')
            badCells.add(point(x,y));

//find every possible plus you can make for a cell.
Map<String, List<Set<String>>> pluses = new HashMap<>();
for(int x = 0; x < N; x++)
    for(int y = 0; y < M; y++)
        pluses.put(point(x,y), allPluses(x, y, grid, badCells));

/*
 * for every 2 cells compare each possible plus combination
 * keep the max.
*/
int maxArea = 0;
for(String cell_one : pluses.keySet())
    for(String cell_two : pluses.keySet())
        if(!cell_one.equals(cell_two))
            for(Set<String> c1_plus : pluses.get(cell_one))
                for(Set<String> c2_plus : pluses.get(cell_two))
                    if(Collections.disjoint(c1_plus, c2_plus))
                        maxArea = Math.max(maxArea, c1_plus.size() * c2_plus.size());

return maxArea;
}

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