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Frontier-CS / algorithmic /problems /112 /chk.cc

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

	const double EPS_SPHERE = 1e-9; // Very strict for sphere constraint
	const double EPS_DISTANCE = 1e-6; // For distance comparison (as per problem statement)

	int n;

	double distance(double x1, double y1, double z1, double x2, double y2, double z2) {
	double dx = x1 - x2;
	double dy = y1 - y2;
	double dz = z1 - z2;
	return sqrt(dx * dx + dy * dy + dz * dz);
	}

	bool doubleEqual(double a, double b, double eps) {
	// Handle both absolute and relative error
	if (abs(a) < eps && abs(b) < eps) return true;
	return abs(a - b) <= eps * max(1.0, max(abs(a), abs(b)));
	}

	int main(int argc, char* argv[]) {
	registerTestlibCmd(argc, argv);

	// Read input
	n = inf.readInt();

	// Read reference answer
	double ref_answer = ans.readDouble();

	// Read participant's output
	if (ouf.seekEof()) {
	quitf(_wa, "No output provided");
	}

	double claimed_min_dist = ouf.readDouble();

	if (claimed_min_dist < 0) {
	quitf(_wa, "Minimum distance cannot be negative: %.10f", claimed_min_dist);
	}

	vector<tuple<double, double, double>> points;

	// Read all n points
	for (int i = 0; i < n; i++) {
	if (ouf.seekEof()) {
	quitf(_wa, "Expected %d points, but only found %d", n, i);
	}

	double x = ouf.readDouble();
	double y = ouf.readDouble();
	double z = ouf.readDouble();

	// Check if point is within unit sphere (strict tolerance)
	double dist_from_origin = sqrt(x * x + y * y + z * z);
	if (dist_from_origin > 1.0 + EPS_SPHERE) {
	quitf(_wa, "Point %d at (%.10f, %.10f, %.10f) is outside the unit sphere (distance from origin: %.15f)",
	i + 1, x, y, z, dist_from_origin);
	}

	points.push_back({x, y, z});
	}

	if (!ouf.seekEof()) {
	quitf(_wa, "Extra output found after %d points", n);
	}

	// Calculate actual minimum pairwise distance
	double actual_min_dist = 1e18;
	for (int i = 0; i < n; i++) {
	for (int j = i + 1; j < n; j++) {
	double d = distance(get<0>(points[i]), get<1>(points[i]), get<2>(points[i]),
	get<0>(points[j]), get<1>(points[j]), get<2>(points[j]));
	actual_min_dist = min(actual_min_dist, d);
	}
	}

	// Verify claimed distance matches actual distance (looser tolerance)
	if (!doubleEqual(actual_min_dist, claimed_min_dist, EPS_DISTANCE)) {
	quitf(_wa, "Claimed minimum distance %.10f does not match actual minimum distance %.10f (difference: %.10f)",
	claimed_min_dist, actual_min_dist, abs(claimed_min_dist - actual_min_dist));
	}

	// Calculate score
	double score_ratio = claimed_min_dist / ref_answer;
	if (score_ratio < 0) score_ratio = 0.0;
	double unbounded_ratio = max(0.0, score_ratio);
	score_ratio = min(1.0, score_ratio);

	quitp(score_ratio, "Min distance: %.10f. Ratio: %.6f, RatioUnbounded: %.6f", claimed_min_dist, score_ratio, unbounded_ratio);

	return 0;
	}