#include <bits/stdc++.h>
using namespace std;
ifstream fin("disjoint.in");
ofstream fout("disjoint.out");
class Graph {
public:
// dfs
void DFS(int v, vector<bool> &vis) {
vis[v] = true;
for (auto &x : m_ad[v]) {
if (!vis[x]) {
DFS(x, vis);
}
}
}
int components() {
int compCount = 0;
vector<bool> vis(m_n, false);
for (int i = 1; i <= m_n; ++i) {
if (!vis[i]) {
++compCount;
DFS(i, vis);
}
}
return compCount;
}
// bfs
void minDist(int start, ostream &out) {
vector<int> dist(m_n + 1, -1);
queue<int> Q;
int x;
dist[start] = 0;
Q.push(start);
while (!Q.empty()) {
x = Q.front(); Q.pop();
for (auto &y : m_ad[x]) {
if (dist[y] == -1) {
dist[y] = dist[x] + 1;
Q.push(y);
}
}
}
for (int i = 1; i <= m_n; ++i) {
out << dist[i] << ' ';
}
}
// sortare topologica
void topologicalSort(int v, vector<bool> &vis, vector<int> &stack) {
vis[v] = true;
for (auto &x : m_ad[v]) {
if (!vis[x]) {
topologicalSort(x, vis, stack);
}
}
stack.push_back(v);
}
void printTopoSorted(ostream &out) {
vector<bool> vis(m_n + 1, false);
vector<int> stack;
for (int i = 1; i <= m_n; ++i) {
if (!vis[i]) {
topologicalSort(i, vis, stack);
}
}
for (int i = stack.size() - 1; i >= 0; --i) {
out << stack[i] << ' ';
}
}
// ctc
void tDFS(int v, vector<bool> &vis, int compCount, vector<vector<int>> &comp) {
vis[v] = true;
comp[compCount - 1].push_back(v);
for (auto &x : m_tAd[v]) {
if (!vis[x]) {
tDFS(x, vis, compCount, comp);
}
}
}
void stronglyConnectedComponents(ostream &out) {
vector<bool> vis1(m_n + 1, false);
vector<bool> vis2(m_n + 1, false);
vector<int> stack;
int compCount = 0;
vector<vector<int>> comp;
for (int i = 1; i <= m_n; ++i) {
if (!vis1[i]) {
topologicalSort(i, vis1, stack);
}
}
for (int i = stack.size() - 1; i >= 0; --i) {
if (!vis2[stack[i]]) {
++compCount;
comp.emplace_back();
tDFS(stack[i], vis2, compCount, comp);
}
}
out << compCount << '\n';
for (int i = 0; i < compCount; ++i) {
for (auto &x : comp[i]) {
out << x << ' ';
}
out << '\n';
}
}
// biconex
void bccDFS(int v, int parent, vector<int> &disc, vector<int> &low,
vector<int> &stack, vector<vector<int>> &comp) {
static int time = 0;
int children = 0;
disc[v] = low[v] = ++time;
for (auto &w : m_ad[v]) {
if (w == parent) continue; // (w, v) e muchie de intoarcere
if (!disc[w]) {
++children;
stack.push_back(w);
bccDFS(w, v, disc, low, stack, comp);
low[v] = min(low[v], low[w]);
if (low[w] >= disc[v]) {
comp.emplace_back();
stack.push_back(v);
while (!stack.empty() && stack.back() != w) {
comp[comp.size() - 1].push_back(stack.back());
stack.pop_back();
}
if (!stack.empty()) {
comp[comp.size() - 1].push_back(stack.back());
stack.pop_back();
}
}
} else if (w != parent) {
low[v] = min(low[v], disc[w]);
}
}
}
void biconnectedComponents(ostream &out) {
vector<int> disc(m_n + 1, 0);
vector<int> low(m_n + 1, 0);
vector<int> stack;
vector<vector<int>> comp;
bccDFS(1, 0, disc, low, stack, comp);
out << comp.size() << '\n';
for (auto &c : comp) {
for (auto &v : c) {
out << v << ' ';
}
out << '\n';
}
}
// Havel Hakimi
static bool eligible(vector<int> &v) {
int s = 0;
auto n = v.size();
for (auto &x : v) {
if (x > n - 1) {
return false;
}
s += x;
}
return s % 2 == 0;
}
static string canBuildGraph(vector<int> &v) {
if (!eligible(v)) {
return "No";
}
sort(v.begin(), v.end(), greater<>());
while (v[0]) {
for (int i = 1; i <= v[0]; ++i) {
if (v[i] == 0) {
return "No";
}
--v[i];
}
v.erase(v.begin());
sort(v.begin(), v.end(), greater<>());
}
return "Yes";
}
// graf
void findPaths(vector<vector<int>> &paths, vector<int> &path, vector<vector<int>> &parent, int current) {
if (current == -1) {
paths.push_back(path);
return;
}
for (auto &p : parent[current]) {
path.push_back(current);
findPaths(paths, path, parent, p);
path.pop_back();
}
}
void BFS(vector<vector<int>> &parents, int start) {
vector<int> dist(m_n + 1, 1 << 30);
queue<int> Q;
Q.push(start);
parents[start] = {-1};
dist[start] = 0;
while (!Q.empty()) {
int current = Q.front(); Q.pop();
for (auto &x : m_ad[current]) {
if (dist[current] + 1 < dist[x]) {
dist[x] = dist[current] + 1;
Q.push(x);
parents[x].clear();
parents[x].push_back(current);
} else if (dist[x] == dist[current] + 1) {
parents[x].push_back(current);
}
}
}
}
void optimalPaths(int start, int end, ostream &out) {
vector<vector<int>> paths;
vector<int> path;
vector<vector<int>> parents(m_n + 1);
BFS(parents, start);
findPaths(paths, path, parents, end);
vector<int> check(m_n + 1, 0);
int pathCount = paths.size(), count = 0;
for (auto &p : paths) {
for (auto &v : p) {
++check[v];
}
}
for (int i = 1; i <= m_n; ++i) {
if (check[i] == pathCount) {
++count;
}
}
out << count << '\n';
for (int i = 1; i <= m_n; ++i) {
if (check[i] == pathCount) {
out << i << ' ';
}
}
}
// disjoint
int find(int x, vector<int> &root) {
int rx = x, aux;
while (rx != root[rx]) {
rx = root[rx];
}
while (x != root[x]) {
aux = root[x];
root[x] = rx;
x = aux;
}
return rx;
}
void unite(int x, int y, vector<int> &root, vector<int> &size) {
int rx = find(x, root);
int ry = find(y, root);
if (size[rx] > size[ry]) {
root[ry] = rx;
size[rx] += size[ry];
} else {
root[rx] = ry;
size[ry] += size[rx];
}
}
void disjoint(int n, vector<pair<int, pair<int, int>>> &ops, ostream &out) {
vector<int> root(n + 1);
vector<int> size(n + 1, 1);
for (int i = 1; i <= n; ++i) {
root[i] = i;
}
for (auto &op : ops) {
if (op.first == 1) {
unite(op.second.first, op.second.second, root, size);
} else {
if (find(op.second.first, root) == find(op.second.second, root)) {
out << "DA\n";
} else {
out << "NU\n";
}
}
}
}
// constructori
Graph() : m_n(0), m_ad(), m_tAd() {}
Graph(int n, vector<vector<int>> &ad) :
m_n(n), m_ad(ad), m_tAd() {}
Graph(int n, vector<vector<int>> &ad, vector<vector<int>> &tAd) :
m_n(n), m_ad(ad), m_tAd(tAd) {}
private:
int m_n;
vector<vector<int>> m_ad;
vector<vector<int>> m_tAd;
};
int main() {
int n, m, type, x, y;
vector<pair<int, pair<int, int>>> ops;
fin >> n >> m;
for (int i = 1; i <= m; ++i) {
fin >> type >> x >> y;
ops.push_back({type, {x, y}});
}
Graph G;
G.disjoint(n, ops, fout);
}
David Bejenariu davidbejenariu2