Submission #828296

# Submission time Handle Problem Language Result Execution time Memory
828296 2023-08-17T07:57:31 Z 박상훈(#10381) Toxic Gene (NOI23_toxic) C++17
89.2 / 100
14 ms 384 KB
#include "toxic.h"
#include <bits/stdc++.h>

using namespace std;
typedef long long ll;

mt19937 seed(1557);

int I[303], mem;
vector<char> typ;

pair<vector<int>, vector<int>> query_exp(const vector<int> &V, const vector<int> &W){
	vector<int> Q;
	for (int i=0;i<(int)V.size();i++){
		for (int j=0;j<(1<<i);j++) Q.push_back(V[i]);
	}

	for (int i=0;i<(int)W.size();i++) Q.push_back(W[i]);

	for (auto &x:Q) x = I[x];
	int ret = query_sample(Q);
	mem = (int)Q.size() - ret;
	vector<int> dead, alive;

	for (int i=0;i<(int)V.size();i++){
		if (ret&(1<<i)) alive.push_back(V[i]);
		else dead.push_back(V[i]);
	}

	return {dead, alive};
}

int query_linear(const vector<int> &V){
	vector<int> Q;
	for (auto &x:V) Q.push_back(I[x]);
	return query_sample(Q);
}

int search(const vector<int> &dead, vector<pair<int, int>> &P){
	int l = 0, r = (int)dead.size()-1;
	while(l<r){
		int m = (l+r)>>1;
		vector<int> V, fuck;
		for (int i=l;i<=m;i++) V.push_back(dead[i]);

		if (!P.empty()){
			auto [l2, r2] = P.back();
			for (int i=l2;i<=r2;i++) fuck.push_back(i);

			auto [deadF, aliveF] = query_exp(fuck, V);
			if (mem==0) l = m+1;
			else{
				for (auto &x:deadF) typ[x] = 'R';
				for (auto &x:aliveF) typ[x] = 'S';
				P.pop_back();
				r = m;
			}
		}

		else{
			if (query_linear(V)==(int)V.size()) l = m+1;
			else r = m;
		}
		
	}

	return dead[l];
}

void determine_type(int n){
	for (int i=1;i<=n;i++) I[i] = i;
	shuffle(I+1, I+n+1, seed);
	
	typ.clear();
	typ.resize(n+1);
	vector<int> toxic;
	vector<pair<int, int>> P;
	vector<vector<int>> que;

	for (int i=1;i<=n;i+=8){
		int r = min(n, i+7);

		vector<int> V;
		for (int j=i;j<=r;j++) V.push_back(j);
		
		auto [dead, alive] = query_exp(V, vector<int>());
		if (dead.empty()){P.emplace_back(i, r); continue;}

		for (auto &x:alive) typ[x] = 'S';

		que.emplace_back(dead);
		continue;

		// printf("dead: ");
		// for (auto &x:dead) printf("%d ", x);
		// printf("\n");

		// printf("alive: ");
		// for (auto &x:alive) printf("%d ", x);
		// printf("\n");
		
		while(true){
			int p = search(dead, P);
			toxic.push_back(p);
			typ[p] = 'T';

			// printf("found toxic: %d\n", I[p]);

			dead.erase(find(dead.begin(), dead.end(), p));
			if (query_linear(dead)==(int)dead.size()) break;
		}

		for (auto &x:dead) typ[x] = 'R';
	}

	for (auto &dead:que){
		while(true){
			int p = search(dead, P);
			toxic.push_back(p);
			typ[p] = 'T';

			dead.erase(find(dead.begin(), dead.end(), p));
			if (query_linear(dead)==(int)dead.size()) break;
		}

		for (auto &x:dead) typ[x] = 'R';
	}

	for (auto &[l, r]:P){
		vector<int> V;
		for (int j=l;j<=r;j++) V.push_back(j);

		auto [dead, alive] = query_exp(V, vector<int>(1, toxic[0]));
		for (auto &x:dead) typ[x] = 'R';
		for (auto &x:alive) typ[x] = 'S';
	}

	for (int i=1;i<=n;i++) answer_type(I[i], typ[i]);
}
# Verdict Execution time Memory Grader output
1 Correct 0 ms 212 KB Output is correct
2 Partially correct 10 ms 340 KB Partially correct
3 Partially correct 10 ms 376 KB Partially correct
4 Partially correct 10 ms 376 KB Partially correct
5 Partially correct 10 ms 380 KB Partially correct
6 Partially correct 10 ms 376 KB Partially correct
7 Partially correct 10 ms 340 KB Partially correct
8 Partially correct 10 ms 376 KB Partially correct
9 Partially correct 13 ms 380 KB Partially correct
10 Partially correct 10 ms 340 KB Partially correct
11 Correct 10 ms 384 KB Output is correct
12 Partially correct 10 ms 340 KB Partially correct
13 Partially correct 11 ms 380 KB Partially correct
14 Partially correct 10 ms 380 KB Partially correct
15 Partially correct 10 ms 340 KB Partially correct
16 Partially correct 13 ms 380 KB Partially correct
17 Partially correct 10 ms 340 KB Partially correct
18 Partially correct 10 ms 340 KB Partially correct
19 Partially correct 10 ms 376 KB Partially correct
20 Partially correct 10 ms 340 KB Partially correct
21 Correct 9 ms 380 KB Output is correct
22 Correct 9 ms 340 KB Output is correct
23 Correct 8 ms 340 KB Output is correct
24 Partially correct 14 ms 340 KB Partially correct
25 Partially correct 10 ms 380 KB Partially correct
26 Partially correct 10 ms 340 KB Partially correct
27 Correct 11 ms 340 KB Output is correct
28 Correct 10 ms 376 KB Output is correct
29 Partially correct 10 ms 380 KB Partially correct
30 Partially correct 10 ms 340 KB Partially correct
31 Partially correct 11 ms 340 KB Partially correct
32 Partially correct 10 ms 340 KB Partially correct
33 Correct 9 ms 340 KB Output is correct
34 Partially correct 10 ms 376 KB Partially correct
35 Partially correct 13 ms 376 KB Partially correct
36 Partially correct 2 ms 212 KB Partially correct