Submission #150255

# Submission time Handle Problem Language Result Execution time Memory
150255 2019-09-01T07:59:49 Z ummm(#3574, cerberus, aayush9, knandy) Organizing the Best Squad (FXCUP4_squad) C++17
28 / 100
1355 ms 499508 KB
/* cerberus97 - Hanit Banga */

#include "squad.h"
#include <iostream>
#include <iomanip>
#include <cassert>
#include <cmath>
#include <cstdio>
#include <cstring>
#include <cstdlib>
#include <map>
#include <set>
#include <queue>
#include <stack>
#include <vector>
#include <algorithm>

using namespace std;

#define pb push_back
#define fast_cin() ios_base::sync_with_stdio(false); cin.tie(NULL)

typedef long long ll;
typedef long double ld;
typedef pair <int, int> pii;
typedef pair <ll, ll> pll;

const int N = 3e5 + 10;

bool del[N];

// Attribution - t3nsor codebook
struct ConvexHullTrick {
	typedef long long LL;
	vector<int> M;
	vector<int> B;
	vector<int> ids;
	vector<double> left;
	ConvexHullTrick() {}
	bool bad(int m1, int b1, int m2, int b2, int m3, int b3) {
			// Careful, this may overflow
			return ll(b3-b1)*(m1-m2) < ll(b2-b1)*(m1-m3);
	}
	// Add a new line to the structure, y = mx + b.
	// Lines must be added in decreasing order of slope.
	void add(int m, int b, int id) {
			while (M.size() >= 2 && bad(M[M.size()-2], B[B.size()-2], M.back(), B.back(), m, b)) {
					del[ids.back()] = true;
					M.pop_back(); B.pop_back(); ids.pop_back(); left.pop_back();
			}
			if (M.size() && M.back() == m) {
					if (B.back() > b) {
							del[ids.back()] = true;
							M.pop_back(); B.pop_back(); ids.pop_back(); left.pop_back();
					} else {
							return;
					}
			}
			if (M.size() == 0) {
					left.push_back(-numeric_limits<double>::infinity());
			} else {
					left.push_back((double)(b - B.back())/(M.back() - m));
			}
			M.push_back(m);
			B.push_back(b);
			ids.push_back(id);
	}
	// Get the minimum value of mx + b among all lines in the structure.
	// There must be at least one line.
    pll query(LL x, LL y) {
            int i = upper_bound(left.begin(), left.end(), double(y) / x) - left.begin();
            return {-(M[i-1]*y + B[i-1]*x), ids[i - 1]};
    }
};

struct player_t {
	int a, d, p;
	bool operator<(const player_t &o) const {
		return p < o.p;
	}
};

int n;
player_t player[N];
ConvexHullTrick atree[4 * N], dtree[4 * N];

void build(int i, int l, int r);
// pll query(ConvexHullTrick* tree, int i, int l, int r, int ql, int qr, int x, int y);
pll query2(ConvexHullTrick* tree, int i, int l, int r, int avoid, int x, int y);

void Init(std::vector<int> A, std::vector<int> D, std::vector<int> P){
	n = A.size();
	for (int i = 1; i <= n; ++i) {
		player[i] = {A[i - 1], D[i - 1], P[i - 1]};
	}
	sort(player + 1, player + n + 1);
	build(1, 1, n);
}

ll BestSquad(int x, int y) {
	auto ba = query2(atree, 1, 1, n, -1, x, y);
	auto bd = query2(dtree, 1, 1, n, -1, x, y);
	if (ba.second != bd.second) {
		return ba.first + bd.first;
	}
	// auto td = max(query(dtree, 1, 1, n, 1, ba.second - 1, x, y), query(dtree, 1, 1, n, ba.second + 1, n, x, y));
	// auto ta = max(query(atree, 1, 1, n, 1, bd.second - 1, x, y), query(atree, 1, 1, n, bd.second + 1, n, x, y));
	auto td = query2(dtree, 1, 1, n, ba.second, x, y);
	auto ta = query2(atree, 1, 1, n, bd.second, x, y);
	return max(ba.first + td.first, bd.first + ta.first);
}

void build(int i, int l, int r) {
	if (l < r) {
		int mid = (l + r) / 2, lc = 2 * i, rc = lc + 1;
		build(lc, l, mid);
		build(rc, mid + 1, r);
		atree[i] = atree[lc];
		dtree[i] = dtree[lc];
		int s = (l == mid ? l : mid + 1);
		for (int j = s; j <= r; ++j) {
			if (!del[j]) {
				dtree[i].add(-player[j].p, -player[j].d, j);
				atree[i].add(-player[j].p, -player[j].a, j);
			}
		}
	}
}

// pll query(ConvexHullTrick* tree, int i, int l, int r, int ql, int qr, int x, int y) {
// 	if (l > qr or ql > r) {
// 		return {-1, -1};
// 	} else if (l == r) {
// 		if (tree == atree) {
// 			return {ll(x) * player[l].a + ll(y) * player[l].p, l};
// 		} else {
// 			return {ll(x) * player[l].d + ll(y) * player[l].p, l};
// 		}
// 	} else if (ql <= l and r <= qr) {
// 		return tree[i].query(x, y);
// 	} else {
// 		int mid = (l + r) / 2, lc = 2 * i, rc = lc + 1;
// 		auto a1 = query(tree, lc, l, mid, ql, qr, x, y);
// 		auto a2 = query(tree, rc, mid + 1, r, ql, qr, x, y);
// 		if (a1.first > a2.first) {
// 			return a1;
// 		} else {
// 			return a2;
// 		}
// 	}
// }

pll query2(ConvexHullTrick* tree, int i, int l, int r, int avoid, int x, int y) {
	if (l == r and l == avoid) {
		return {-1, -1};
	} else if (l == r) {
		if (tree == atree) {
			return {ll(x) * player[l].a + ll(y) * player[l].p, l};
		} else {
			return {ll(x) * player[l].d + ll(y) * player[l].p, l};
		}
	} else {
		auto cur = tree[i].query(x, y);
		if (cur.second != avoid) {
			return cur;
		}
		int mid = (l + r) / 2, lc = 2 * i, rc = lc + 1;
		auto a1 = query2(tree, lc, l, mid, avoid, x, y);
		auto a2 = query2(tree, rc, mid + 1, r, avoid, x, y);
		if (a1.first > a2.first) {
			return a1;
		} else {
			return a2;
		}
	}
}
# Verdict Execution time Memory Grader output
1 Correct 123 ms 225784 KB Output is correct
2 Incorrect 127 ms 226176 KB Output isn't correct
3 Halted 0 ms 0 KB -
# Verdict Execution time Memory Grader output
1 Correct 126 ms 225784 KB Output is correct
2 Correct 124 ms 226680 KB Output is correct
3 Correct 910 ms 338744 KB Output is correct
4 Correct 878 ms 338740 KB Output is correct
5 Correct 158 ms 235000 KB Output is correct
6 Correct 1304 ms 499508 KB Output is correct
7 Correct 1355 ms 499460 KB Output is correct
8 Correct 1346 ms 499456 KB Output is correct
# Verdict Execution time Memory Grader output
1 Correct 123 ms 225784 KB Output is correct
2 Incorrect 127 ms 226176 KB Output isn't correct
3 Halted 0 ms 0 KB -