ソースコード

#include <array>
#include <cmath>
#include <string>
#include <vector>
#include <cassert>
#include <iostream>
#include <algorithm>
using namespace std;

class action {
public:
	static constexpr int D = 14;
	static constexpr int ACTION_BUILD = 1;
	static constexpr int ACTION_LEVEL = 2;
	static constexpr int ACTION_MONEY = 3;
	int tp, id;
	action() : tp(-1), id(-1) {}
	action(int tp_) : tp(tp_), id(-1) {
		assert(tp == 2 || tp == 3);
	}
	action(int tp_, int id_) : tp(tp_), id(id_) {
		assert(tp == 1 && 0 <= id && id < D * (D - 1) * 2);
	}
	string to_string() const {
		assert(tp != -1);
		if (tp == 2 || tp == 3) {
			return std::to_string(tp);
		}
		int xa, ya, xb, yb;
		if (id < D * (D - 1)) {
			xa = id / D;
			ya = id % D;
			xb = xa + 1;
			yb = ya;
		}
		else {
			xa = (id - D * (D - 1)) / (D - 1);
			ya = (id - D * (D - 1)) % (D - 1);
			xb = xa;
			yb = ya + 1;
		}
		// output in 1-indexed
		return std::to_string(tp) + " " + std::to_string(xa + 1) + " " + std::to_string(ya + 1) + " " + std::to_string(xb + 1) + " " + std::to_string(yb + 1);
	}
};

uint64_t seed = 123456789;
uint64_t xorshift64() {
	seed ^= seed << 13;
	seed ^= seed >> 7;
	seed ^= seed << 17;
	return seed;
}

int main() {
	// step #1. initial input
	const int INF = 1012345678;
	const int D = action::D;
	int N, T;
	cin >> N >> T;
	vector<int> X(N), Y(N);
	for (int i = 0; i < N; i++) {
		int a, b, c, d;
		cin >> a >> b >> c >> d;
		X[i] = (a - 1) * D + (b - 1);
		Y[i] = (c - 1) * D + (d - 1);
	}

	// step #2. make graph-like list of citizens
	vector<int> deg(D * D);
	for (int i = 0; i < N; i++) {
		deg[X[i]] += 1;
		deg[Y[i]] += 1;
	}
	vector<vector<int> > G(D * D);
	for (int i = 0; i < N; i++) {
		if (deg[X[i]] > deg[Y[i]] || (deg[X[i]] == deg[Y[i]] && X[i] < Y[i])) {
			G[X[i]].push_back(Y[i]);
		}
		else {
			G[Y[i]].push_back(X[i]);
		}
	}

	// step #3. function to calculate score
	auto calc = [&](const vector<int>& road) {
		int answer = 0;
		vector<int> q1(D * D), q2(D * D);
		for (int i = 0; i < D * D; i++) {
			if (G[i].empty()) {
				continue;
			}
			vector<int> dist(D * D, INF);
			dist[i] = 0;
			int ql1 = 0, qr1 = 1;
			int ql2 = 0, qr2 = 0;
			q1[0] = i;
			while (ql1 != qr1 || ql2 != qr2) {
				int c1 = (ql1 != qr1 ? q1[ql1] : INF);
				int c2 = (ql2 != qr2 ? q2[ql2] : INF);
				int pos = -1, curdist = 0;
				if (c1 <= c2) {
					curdist = (c1 >> 12);
					pos = (c1 & ((1 << 12) - 1));
					ql1 += 1;
				}
				else {
					curdist = (c2 >> 12);
					pos = (c2 & ((1 << 12) - 1));
					ql2 += 1;
				}
				int px = pos / D, py = pos % D;
				// direction 1: down
				if (px != D - 1 && road[px * D + py] == 0) {
					if (dist[pos + D] > curdist + 1000) {
						dist[pos + D] = curdist + 1000;
						q1[qr1++] = (dist[pos + D] << 12) | (pos + D);
					}
				}
				if (px != D - 1 && road[px * D + py] == 1) {
					if (dist[pos + D] > curdist + 223) {
						dist[pos + D] = curdist + 223;
						q2[qr2++] = (dist[pos + D] << 12) | (pos + D);
					}
				}
				// direction 2: up
				if (px != 0 && road[(px - 1) * D + py] == 0) {
					if (dist[pos - D] > curdist + 1000) {
						dist[pos - D] = curdist + 1000;
						q1[qr1++] = (dist[pos - D] << 12) | (pos - D);
					}
				}
				if (px != 0 && road[(px - 1) * D + py] == 1) {
					if (dist[pos - D] > curdist + 223) {
						dist[pos - D] = curdist + 223;
						q2[qr2++] = (dist[pos - D] << 12) | (pos - D);
					}
				}
				// direction 3: right
				if (py != D - 1 && road[D * (D - 1) + px * (D - 1) + py] == 0) {
					if (dist[pos + 1] > curdist + 1000) {
						dist[pos + 1] = curdist + 1000;
						q1[qr1++] = (dist[pos + 1] << 12) | (pos + 1);
					}
				}
				if (py != D - 1 && road[D * (D - 1) + px * (D - 1) + py] == 1) {
					if (dist[pos + 1] > curdist + 223) {
						dist[pos + 1] = curdist + 223;
						q2[qr2++] = (dist[pos + 1] << 12) | (pos + 1);
					}
				}
				// direction 4: left
				if (py != 0 && road[D * (D - 1) + px * (D - 1) + py - 1] == 0) {
					if (dist[pos - 1] > curdist + 1000) {
						dist[pos - 1] = curdist + 1000;
						q1[qr1++] = (dist[pos - 1] << 12) | (pos - 1);
					}
				}
				if (py != 0 && road[D * (D - 1) + px * (D - 1) + py - 1] == 1) {
					if (dist[pos - 1] > curdist + 223) {
						dist[pos - 1] = curdist + 223;
						q2[qr2++] = (dist[pos - 1] << 12) | (pos - 1);
					}
				}
			}
			for (int j : G[i]) {
				answer += (dist[j] * 287) % 1000;
			}
		}
		return answer;
	};

	// step #4. process queries
	int current_money = 1000000;
	int current_level = 1;
	int used_roads = 0;
	vector<int> road(D * (D - 1) * 2, 0);
	for (int i = 0; i < T; i++) {
		int tmp1, tmp2;
		cin >> tmp1 >> tmp2;
		// decide action
		int required_money = int(10000000 / sqrt(current_level));
		action a;
		if (i < 33) {
			a = action(action::ACTION_LEVEL);
		}
		else if (used_roads == 0 && current_money < required_money) {
			a = action(action::ACTION_MONEY);
		}
		else if (i < 190) {
			if (current_money >= required_money) {
				int opt_choice = -1;
				int opt_score = -INF;
				for (int j = 0; j < D * (D - 1) * 2; j++) {
					if (road[j] == 0 && xorshift64() % 15 == 0) {
						road[j] = 1;
						int subscore = calc(road);
						if (opt_score < subscore) {
							opt_score = subscore;
							opt_choice = j;
						}
						road[j] = 0;
					}
				}
				a = action(action::ACTION_BUILD, opt_choice);
				used_roads += 1;
			}
			else {
				a = action(action::ACTION_LEVEL);
			}
		}
		else {
			a = action(action::ACTION_MONEY);
		}
		// process action
		if (a.tp == action::ACTION_BUILD) {
			road[a.id] = 1;
			used_roads += 1;
			current_money -= required_money;
		}
		if (a.tp == action::ACTION_LEVEL) {
			current_level += 1;
		}
		if (a.tp == action::ACTION_MONEY) {
			current_money += 50000;
		}
		current_money += calc(road) * 60;
		cout << a.to_string() << endl;
		// cerr << "! " << i << ": level = " << current_level << ", money = " << current_money << ", score = " << calc(road) << endl;
	}

	return 0;
}