Uolevin kalansaalis

#include <iostream>
#include <utility>
#include <functional>
#include <map>
#include <unordered_map>
using namespace std;

struct p_hash {
    size_t operator()(const pair<int, int>& p) const {
        const size_t prime = 31;
        size_t hash = 17;

        hash = hash * prime + std::hash<int>{}(p.first);
        hash = hash * prime + std::hash<int>{}(p.second);

        return hash;
    }
};
unordered_map<pair<int, int>, int, p_hash> hex_grid;

void insert(pair<int, int>& p_behind, pair<int, int>& p_ahead, map<pair<int, int>, char>& inputs){
    hex_grid[p_ahead] = hex_grid[p_behind];
    if(inputs.find(p_ahead) != inputs.end()){
        if(inputs[p_ahead] == 'H')
            hex_grid[p_ahead] += 1;
        else
            hex_grid[p_ahead] -= 10;
    }
}

int main(){
    int n, m, k;
    cin >> n >> m >> k;

    map<pair<int, int>, char> inputs;
    for(int i = 0; i < k; i++){
        int a, b; char c;
        cin >> a >> b >> c;
        inputs[make_pair(a, b)] = c;
    }

    for(int a = 1; a <= n; a++){
        for(int b = 0; b <= m+1; b++){
            auto p_ahead = make_pair(a, b);
            auto p_behind = make_pair(a, b-1);
            if(b == 0)
                p_behind = make_pair(a-1, m+1);
            insert(p_behind, p_ahead, inputs);
        }
    }

    for(int a = 1; a <= n; a++){
        for(int b = 0; b <= m+1; b++)
            cout << hex_grid[make_pair(a, b)] << " ";
        cout << "\n";
    };

    int largest = hex_grid[make_pair(1, 1)];
    for(int a = 1; a <= n; a++){
        for(int b = 1; b <= n; b++){
            auto left = make_pair(a, b);
            int up_temp = 0;
            int down_temp = 0;

            int counter = 0;
            bool loop = true;
            while(loop){
                loop = false;

                if((hex_grid.find(make_pair(left.first, left.second - 1)) != hex_grid.end()) && (hex_grid.find(make_pair(left.first, left.second + counter + 1)) != hex_grid.end())){
                    loop = true;
                    up_temp += (hex_grid[make_pair(left.first, left.second + counter)] - hex_grid[make_pair(left.first, left.second - 1)]);
                }

                if((hex_grid.find(make_pair(left.first + counter, left.second - 1)) != hex_grid.end()) && (hex_grid.find(make_pair(left.first + counter, left.second + counter + 1)) != hex_grid.end())){
                    loop = true;
                    down_temp += (hex_grid[make_pair(left.first + counter, (left.second+1)%2)] - hex_grid[make_pair(left.first + counter, (left.second+1)%2)]);
                }

                largest = min(largest, up_temp);
                largest = min(largest, down_temp);
                left = make_pair(left.first - 1, left.second - left.first%2);
                counter += 1;
            }
            
        }
    }

    cout << hex_grid[make_pair(n, m)] - largest;
}

Test 1

Group: 1, 2

Verdict: WRONG ANSWER

Test 2

Group: 1, 2

Verdict: WRONG ANSWER

Test 3

Group: 1, 2

Verdict: WRONG ANSWER

Test 4

Group: 1, 2

Verdict: WRONG ANSWER

Test 5

Group: 1, 2

Verdict: WRONG ANSWER

Test 6

Group: 1, 2

Verdict: WRONG ANSWER

Test 7

Group: 1, 2

Verdict: WRONG ANSWER

Test 8

Group: 1, 2

Verdict: WRONG ANSWER

Test 9

Group: 1, 2

Verdict: WRONG ANSWER

Test 10

Group: 1, 2

Verdict: WRONG ANSWER

Test 11

Group: 1, 2

Verdict: WRONG ANSWER

Test 12

Group: 1, 2

Verdict: WRONG ANSWER

Test 13

Group: 1, 2

Verdict: WRONG ANSWER

Test 14

Group: 1, 2

Verdict: WRONG ANSWER

Test 15

Group: 1, 2

Verdict: WRONG ANSWER

Test 16

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 17

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 18

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 19

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 20

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 21

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 22

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 23

Group: 2

Verdict: TIME LIMIT EXCEEDED

Test 24

Group: 2

Verdict: TIME LIMIT EXCEEDED