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

	struct TestCase {
	int n;
	long long k;
	vector<vector<long long>> A;
	long long answer;
	};

	mt19937_64 rng_gen(42);

	TestCase gen_matrix(int n, long long k, function<long long(int,int)> valfn) {
	TestCase tc; tc.n = n; tc.k = k;
	tc.A.assign(n+1, vector<long long>(n+1, 0));
	vector<long long> all;
	for (int i = 1; i <= n; i++)
	for (int j = 1; j <= n; j++) { tc.A[i][j] = valfn(i, j); all.push_back(tc.A[i][j]); }
	sort(all.begin(), all.end());
	tc.answer = all[k-1];
	return tc;
	}
	TestCase gen_multiplicative(int n, long long k) { return gen_matrix(n, k, [](int i, int j) -> long long { return (long long)i * j; }); }
	TestCase gen_shifted(int n, long long k) { return gen_matrix(n, k, [n](int i, int j) -> long long { return (long long)(i + n) * (j + n); }); }
	TestCase gen_additive(int n, long long k) { return gen_matrix(n, k, [](int i, int j) -> long long { return i + j; }); }
	TestCase gen_random_sorted(int n, long long k) {
	TestCase tc; tc.n = n; tc.k = k;
	tc.A.assign(n+1, vector<long long>(n+1, 0));
	for (int i = 1; i <= n; i++) for (int j = 1; j <= n; j++) tc.A[i][j] = (long long)i * 1000000 + (long long)j * 1000 + (rng_gen() % 500);
	for (int i = 1; i <= n; i++) for (int j = 2; j <= n; j++) tc.A[i][j] = max(tc.A[i][j], tc.A[i][j-1]);
	for (int j = 1; j <= n; j++) for (int i = 2; i <= n; i++) tc.A[i][j] = max(tc.A[i][j], tc.A[i-1][j]);
	vector<long long> all;
	for (int i = 1; i <= n; i++) for (int j = 1; j <= n; j++) all.push_back(tc.A[i][j]);
	sort(all.begin(), all.end());
	tc.answer = all[k-1];
	return tc;
	}

	struct Solver {
	const TestCase& tc;
	int query_count;
	vector<long long> memo;
	int n;
	// diagnostics
	vector<double> split_ratios;

	Solver(const TestCase& t) : tc(t), query_count(0), n(t.n) { memo.assign(2002 * 2002, -1); }

	long long do_query(int r, int c) {
	int key = r * 2001 + c;
	if (memo[key] != -1) return memo[key];
	query_count++;
	memo[key] = tc.A[r][c];
	return memo[key];
	}

	long long solve() {
	long long k = tc.k;
	long long N2 = (long long)n * n;
	if (n == 1) return do_query(1, 1);

	long long heap_k = min(k, N2 - k + 1);
	if (heap_k + n <= 24000) {
	if (k <= N2 - k + 1) {
	priority_queue<tuple<long long, int, int>, vector<tuple<long long, int, int>>, greater<>> pq;
	vector<vector<bool>> vis(n + 1, vector<bool>(n + 1, false));
	pq.emplace(do_query(1, 1), 1, 1); vis[1][1] = true;
	long long result = -1;
	for (long long i = 0; i < k; i++) {
	auto [v, r, c] = pq.top(); pq.pop(); result = v;
	if (r + 1 <= n && !vis[r + 1][c]) { vis[r + 1][c] = true; pq.emplace(do_query(r + 1, c), r + 1, c); }
	if (c + 1 <= n && !vis[r][c + 1]) { vis[r][c + 1] = true; pq.emplace(do_query(r, c + 1), r, c + 1); }
	}
	return result;
	} else {
	long long kk = N2 - k + 1;
	priority_queue<tuple<long long, int, int>> pq;
	vector<vector<bool>> vis(n + 1, vector<bool>(n + 1, false));
	pq.emplace(do_query(n, n), n, n); vis[n][n] = true;
	long long result = -1;
	for (long long i = 0; i < kk; i++) {
	auto [v, r, c] = pq.top(); pq.pop(); result = v;
	if (r - 1 >= 1 && !vis[r - 1][c]) { vis[r - 1][c] = true; pq.emplace(do_query(r - 1, c), r - 1, c); }
	if (c - 1 >= 1 && !vis[r][c - 1]) { vis[r][c - 1] = true; pq.emplace(do_query(r, c - 1), r, c - 1); }
	}
	return result;
	}
	}

	vector<int> L(n + 1, 1), R(n + 1, n);
	long long k_rem = k;

	for (int iter = 0; iter < 100; iter++) {
	vector<int> active;
	long long total_cand = 0;
	for (int i = 1; i <= n; i++) {
	if (L[i] <= R[i]) { active.push_back(i); total_cand += R[i] - L[i] + 1; }
	}
	int na = active.size();
	if (total_cand == 0) break;
	if (total_cand == 1) { for (int i : active) return do_query(i, L[i]); break; }

	long long budget = 49500 - query_count;
	if (k_rem + na <= budget) {
	priority_queue<tuple<long long, int, int>, vector<tuple<long long, int, int>>, greater<>> pq;
	for (int i : active) pq.emplace(do_query(i, L[i]), i, L[i]);
	for (long long t = 1; t < k_rem; t++) {
	auto [v, r, c] = pq.top(); pq.pop();
	if (c + 1 <= R[r]) pq.emplace(do_query(r, c + 1), r, c + 1);
	}
	return get<0>(pq.top());
	}
	long long rev_k = total_cand - k_rem + 1;
	if (rev_k + na <= budget) {
	priority_queue<tuple<long long, int, int>> pq;
	for (int i : active) pq.emplace(do_query(i, R[i]), i, R[i]);
	for (long long t = 1; t < rev_k; t++) {
	auto [v, r, c] = pq.top(); pq.pop();
	if (c - 1 >= L[r]) pq.emplace(do_query(r, c - 1), r, c - 1);
	}
	return get<0>(pq.top());
	}

	// Pivot selection: sample from ALL active rows at target_frac position
	// Use WEIGHTED quantile selection
	double target_frac = (double)(k_rem - 0.5) / total_cand;

	// Sample from ALL active rows
	vector<pair<long long, int>> vw; // (value, weight=width)
	for (int i : active) {
	int width = R[i] - L[i] + 1;
	int col = L[i] + (int)(target_frac * (width - 1));
	col = max(L[i], min(R[i], col));
	vw.push_back({do_query(i, col), width});
	}

	sort(vw.begin(), vw.end());

	// WEIGHTED quantile: find value at target_frac of total weight
	long long total_w = 0;
	for (auto& [v, w] : vw) total_w += w;
	long long target_w = max(1LL, (long long)(target_frac * total_w));
	long long cum = 0;
	long long pivot = vw.back().first;
	for (auto& [v, w] : vw) {
	cum += w;
	if (cum >= target_w) { pivot = v; break; }
	}

	// Staircase walk (bottom-to-top)
	vector<int> p_le(n + 1, 0);
	{
	int j = 0;
	for (int idx = na - 1; idx >= 0; idx--) {
	int i = active[idx];
	j = max(j, L[i]);
	while (j <= R[i] && do_query(i, j) <= pivot) j++;
	p_le[i] = j - 1;
	}
	}

	long long cle = 0;
	for (int i : active) {
	int rl = min(p_le[i], R[i]);
	if (rl >= L[i]) cle += rl - L[i] + 1;
	}

	double ratio = (double)min(cle, total_cand - cle) / total_cand;
	split_ratios.push_back(ratio);

	if (cle >= k_rem) {
	for (int i : active) R[i] = min(R[i], p_le[i]);
	} else {
	k_rem -= cle;
	for (int i : active) L[i] = max(L[i], p_le[i] + 1);
	}
	}
	return -1;
	}
	};

	int main() {
	struct TestDef { string name; function<TestCase()> gen; };
	vector<TestDef> tests;
	tests.push_back({"additive n=100 k=5000", []{ return gen_additive(100, 5000); }});
	tests.push_back({"mult n=100 k=5000", []{ return gen_multiplicative(100, 5000); }});
	tests.push_back({"additive n=500 k=125000", []{ return gen_additive(500, 125000); }});
	tests.push_back({"mult n=500 k=125000", []{ return gen_multiplicative(500, 125000); }});
	tests.push_back({"random n=500 k=125000", []{ return gen_random_sorted(500, 125000); }});
	tests.push_back({"additive n=2000 k=2000000", []{ return gen_additive(2000, 2000000); }});
	tests.push_back({"mult n=2000 k=2000000", []{ return gen_multiplicative(2000, 2000000); }});
	tests.push_back({"shifted n=2000 k=2000000", []{ return gen_shifted(2000, 2000000); }});
	tests.push_back({"random n=2000 k=2000000", []{ return gen_random_sorted(2000, 2000000); }});
	tests.push_back({"mult n=2000 k=100000", []{ return gen_multiplicative(2000, 100000); }});
	tests.push_back({"mult n=2000 k=3900000", []{ return gen_multiplicative(2000, 3900000); }});

	for (auto& t : tests) {
	auto tc = t.gen();
	Solver s(tc);
	long long result = s.solve();
	bool correct = (result == tc.answer);
	int used = s.query_count;
	double score = !correct ? 0.0 : (used <= tc.n ? 1.0 : (used >= 50000 ? 0.0 : (50000.0 - used) / (50000.0 - tc.n)));
	printf("%-45s q=%6d %s score=%.4f splits:", t.name.c_str(), used, correct ? "OK" : "WRONG", score);
	for (double r : s.split_ratios) printf(" %.3f", r);
	printf("\n");
	}
	}