Datasets:

FrontierCS
/

Frontier-CS

	#include "testlib.h"
	#include <bits/stdc++.h>
	using namespace std;

	struct PairHash {
	size_t operator()(const pair<int,int>& p) const noexcept {
	return (size_t)p.first * 1000003u ^ (size_t)p.second;
	}
	};

	struct Tree {
	int n, LOG;
	vector<vector<pair<int,int>>> adj; // (to, w)
	vector<int> depth;
	vector<long long> dist;
	vector<vector<int>> up; // up[k][v]
	vector<bool> visited;

	Tree() {}
	Tree(int n): n(n) {
	adj.assign(n + 1, {});
	}

	void addEdge(int u, int v, int w) {
	adj[u].push_back({v, w});
	adj[v].push_back({u, w});
	}

	void build(int root = 1) {
	depth.assign(n + 1, 0);
	dist.assign(n + 1, 0);
	visited.assign(n + 1, false);
	LOG = 1;
	while ((1ll << LOG) <= n) ++LOG;
	up.assign(LOG, vector<int>(n + 1, 0));

	// BFS to set parent (up[0]), depth, dist
	queue<int> q;
	vector<int> parent(n + 1, 0);
	parent[root] = root;
	up[0][root] = root;
	depth[root] = 0;
	dist[root] = 0;
	visited[root] = true;
	q.push(root);
	while (!q.empty()) {
	int u = q.front(); q.pop();
	visited[u] = true;
	for (auto [v, w] : adj[u]) {
	if (v == parent[u] \|\| visited[v]) continue;
	parent[v] = u;
	up[0][v] = u;
	depth[v] = depth[u] + 1;
	dist[v] = dist[u] + w;
	visited[v] = true;
	q.push(v);
	}
	}

	for (int k = 1; k < LOG; ++k) {
	for (int v = 1; v <= n; ++v) {
	up[k][v] = up[k - 1][ up[k - 1][v] ];
	}
	}
	}

	int lca(int a, int b) const {
	if (depth[a] < depth[b]) swap(a, b);
	int diff = depth[a] - depth[b];
	for (int k = LOG - 1; k >= 0; --k) {
	if ((diff >> k) & 1) a = up[k][a];
	}
	if (a == b) return a;
	for (int k = LOG - 1; k >= 0; --k) {
	if (up[k][a] != up[k][b]) {
	a = up[k][a];
	b = up[k][b];
	}
	}
	return up[0][a];
	}

	long long distance(int u, int v) const {
	int w = lca(u, v);
	return dist[u] + dist[v] - 2LL * dist[w];
	}

	~Tree(){
	adj.clear();
	depth.clear();
	dist.clear();
	up.clear();
	}

	};

	int main(int argc, char* argv[]) {
	registerInteraction(argc, argv);
	double score = 1.0;

	// case1: quitp(score, "Correct. Ratio: %.4f", score);
	// case2: quitp(score, "score ratio: %.4f.", score);

	// Read public data
	int T = inf.readInt(); // number of test cases
	println(T); // Echo to player

	double final_ratio = 0;


	// Score accumulation: average by group
	double total_ratio = 0.0;
	double total_unbounded_ratio = 0.0;
	bool flag_error = false;

	for (int tc = 1; tc <= T; ++tc) {
	int n = inf.readInt();
	println(n); // Echo to player

	// Read hidden tree from .ans (non-adaptive)
	Tree tree(n);
	// For fast answer verification, prepare expectedEdges: key=(min(u,v), max(u,v)) -> w
	unordered_map<pair<int,int>, int, PairHash> expectedEdges;
	// expectedEdges.reserve((size_t).(n * 2));

	for (int i = 0; i < n - 1; ++i) {
	int u = ans.readInt();
	int v = ans.readInt();
	int w = ans.readInt();
	// if (u < 1 \|\| u > n \|\| v < 1 \|\| v > n \|\| u == v) {
	// quitf(_fail, "Secret tree invalid at test %d: edge (%d, %d, %d) out of range.", tc, u, v, w);
	// }
	// if (w < 1 \|\| w > 10000) {
	// quitf(_fail, "Secret edge weight out of range at test %d: w=%d.", tc, w);
	// }
	int a = min(u, v), b = max(u, v);
	auto key = make_pair(a, b);
	// if (expectedEdges.count(key)) {
	// quitf(_fail, "Secret tree has duplicate edge at test %d: (%d, %d).", tc, a, b);
	// }
	expectedEdges[key] = w;
	tree.addEdge(u, v, w);
	}

	// Preprocess to answer distance queries in O(log n)
	tree.build(1);

	long long query_count = 0;
	long long limit_queries = n * (n + 1) / 2;

	// Interaction for this group
	while (query_count <= limit_queries) {
	string op = ouf.readWord();
	if (op == "?") {
	int u = ouf.readInt();
	int v = ouf.readInt();
	if (u < 1 \|\| u > n \|\| v < 1 \|\| v > n \|\| u == v) {
	quitf(_wa, "Invalid query at test %d: u=%d, v=%d (must be 1..%d and u!=v).", tc, u, v, n);
	}
	++query_count;
	long long d = tree.distance(u, v);
	println(d);
	} else if (op == "!") {
	// Read player's answer: 3*(n-1) integers
	unordered_set<pair<int,int>, PairHash> seen;
	// seen.reserve((size_t)(n * 2));
	bool ok = true;
	string err = "";

	for (int i = 0; i < n - 1; ++i) {
	int u = ouf.readInt();
	int v = ouf.readInt();
	int w = ouf.readInt();

	if (u < 1 \|\| u > n \|\| v < 1 \|\| v > n \|\| u == v) {
	ok = false;
	err = "Answer has invalid edge endpoint.";
	}
	if (!ok) continue;
	int a = min(u, v), b = max(u, v);
	auto key = make_pair(a, b);
	if (seen.count(key)) {
	ok = false;
	err = "Answer has duplicate edge.";
	continue;
	}
	seen.insert(key);
	auto it = expectedEdges.find(key);
	if (it == expectedEdges.end()) {
	ok = false;
	err = "Answer contains non-existing edge.";
	continue;
	}
	if (it->second != w) {
	ok = false;
	err = "Answer edge weight mismatch.";
	continue;
	}
	}

	// If count is wrong or not connected, seen.size() != n-1 will trigger above logic,
	// Complete edge and weight match means consistent with hidden tree.
	if (!ok) {
	// Score 0 for this group, continue to next
	flag_error = true;
	total_ratio += 0.0;
	quitf(_wa, "Error is test %d: %s", tc, err.c_str());
	} else {
	// Calculate score for this group (ratio in [0,1])
	// - q <= 5n: ratio = 1
	// - q >= n^2 / 3: ratio = 0
	// - Linear interpolation
	long long q = query_count;
	long long full_thr = 5LL * n;
	long long zero_thr = (long long)n * (long long)n / 3LL;
	double raw_ratio = 0.0;
	if (zero_thr <= full_thr) {
	raw_ratio = (q <= full_thr) ? 1.0 : 0.0;
	} else {
	double denom = (double)(zero_thr - full_thr);
	raw_ratio = 1.0 - (double)(q - full_thr) / denom;
	}
	double ratio = std::min(1.0, std::max(0.0, raw_ratio));
	double unbounded_ratio = std::max(0.0, raw_ratio);
	total_ratio += ratio;
	total_unbounded_ratio += unbounded_ratio;
	}

	// Move to next group
	break;
	} else {
	quitf(_wa, "Invalid operation at test %d: expected '?' or '!', got '%s'.", tc, op.c_str());
	}
	}
	}

	final_ratio = flag_error ? 0 : total_ratio / (double)T;
	double final_unbounded_ratio = flag_error ? 0 : total_unbounded_ratio / (double)T;
	long long score_value = llround(final_unbounded_ratio * 10000.0);
	// Output score ratio [0,1] with human-readable info (not sent to player, only for judge log)
	quitp(final_ratio, "Value: %lld. Ratio: %.4f, RatioUnbounded: %.4f", score_value, final_ratio, final_unbounded_ratio);

	return 0;
	}