#include using namespace std; template< typename T > struct edge { int src, to; T cost; edge(int to, T cost) : src(-1), to(to), cost(cost) {} edge(int src, int to, T cost) : src(src), to(to), cost(cost) {} edge &operator=(const int &x) { to = x; return *this; } operator int() const { return to; } }; template< typename T > using Edges = vector< edge< T > >; template< typename T > using WeightedGraph = vector< Edges< T > >; using UnWeightedGraph = vector< vector< int > >; template< typename T > using Matrix = vector< vector< T > >; template< typename G > struct HeavyLightDecomposition { G &g; vector< int > sz, in, out, head, rev, par; HeavyLightDecomposition(G &g) : g(g), sz(g.size()), in(g.size()), out(g.size()), head(g.size()), rev(g.size()), par(g.size()) {} void dfs_sz(int idx, int p) { par[idx] = p; sz[idx] = 1; if(g[idx].size() && g[idx][0] == p) swap(g[idx][0], g[idx].back()); for(auto &to : g[idx]) { if(to == p) continue; dfs_sz(to, idx); sz[idx] += sz[to]; if(sz[g[idx][0]] < sz[to]) swap(g[idx][0], to); } } void dfs_hld(int idx, int par, int ×) { in[idx] = times++; rev[in[idx]] = idx; for(auto &to : g[idx]) { if(to == par) continue; head[to] = (g[idx][0] == to ? head[idx] : to); dfs_hld(to, idx, times); } out[idx] = times; } void build() { dfs_sz(0, -1); int t = 0; dfs_hld(0, -1, t); } int lca(int u, int v) { for(;; v = par[head[v]]) { if(in[u] > in[v]) swap(u, v); if(head[u] == head[v]) return u; } } template< typename T, typename Q, typename F > T query(int u, int v, const T &ti, const Q &q, const F &f, bool edge = false) { T l = ti, r = ti; for(;; v = par[head[v]]) { if(in[u] > in[v]) swap(u, v), swap(l, r); if(head[u] == head[v]) break; l = f(q(in[head[v]], in[v] + 1), l); } return f(f(q(in[u] + edge, in[v] + 1), l), r); } template< typename Q > void add(int u, int v, const Q &q, bool edge = false) { for(;; v = par[head[v]]) { if(in[u] > in[v]) swap(u, v); if(head[u] == head[v]) break; q(in[head[v]], in[v] + 1); } q(in[u] + edge, in[v] + 1); } }; struct UnionFind { vector< int > data; UnionFind(int sz) { data.assign(sz, -1); } bool unite(int x, int y) { x = find(x), y = find(y); if(x == y) return (false); if(data[x] > data[y]) swap(x, y); data[x] += data[y]; data[y] = x; return (true); } int find(int k) { if(data[k] < 0) return (k); return (data[k] = find(data[k])); } int size(int k) { return (-data[find(k)]); } }; template< typename G > struct LowLink { const G &g; UnionFind uf; vector< int > used, ord, low, parent; LowLink(const G &g) : g(g), uf(g.size()), used(g.size()), ord(g.size()), low(g.size()), parent(g.size(), -1) {} void dfs(int idx, int &k, int par = -1) { used[idx] = true; ord[idx] = k++; low[idx] = ord[idx]; for(auto &to : g[idx]) { if(!used[to]) { dfs(to, k, idx); low[idx] = min(low[idx], low[to]); parent[to] = idx; if(ord[idx] >= low[to]) uf.unite(idx, to); } else if(to != par) { low[idx] = min(low[idx], ord[to]); } } } void dfs() { int k = 0; dfs(0, k); } }; template< typename G > struct BiConnectedComponents : LowLink< G > { using LL = LowLink< G >; vector< int > comp; BiConnectedComponents(const G &g) : LL(g), comp(g.size()) {} int operator[](int k) { return (comp[k]); } vector< pair< int, int > > build(UnWeightedGraph &t) { LL::dfs(); int ptr = 0; vector< int > cc(LL::g.size()); for(int i = 0; i < LL::g.size(); i++) { if(i == LL::uf.find(i)) cc[i] = ptr++; } t.resize(ptr); for(int i = 0; i < LL::g.size(); i++) { comp[i] = cc[LL::uf.find(i)]; } vector< pair< int, int > > edges; for(int i = 0; i < LL::g.size(); i++) { for(auto &to : LL::g[i]) edges.emplace_back(minmax(i, to)); } sort(begin(edges), end(edges)); edges.erase(unique(begin(edges), end(edges)), end(edges)); vector< pair< int, int > > vs; for(auto &e : edges) { int x = comp[e.first], y = comp[e.second]; if(x == y) continue; vs.emplace_back(e.first, e.second); t[x].push_back(y); t[y].push_back(x); } sort(begin(vs), end(vs)); return (vs); } }; template< typename Monoid > struct SegmentTree { using F = function< Monoid(Monoid, Monoid) >; int sz; vector< Monoid > seg; const F f; const Monoid M1; SegmentTree(int n, const F f, const Monoid &M1) : f(f), M1(M1) { sz = 1; while(sz < n) sz <<= 1; seg.assign(2 * sz, M1); } void set(int k, const Monoid &x) { seg[k + sz] = x; } void build() { for(int k = sz - 1; k > 0; k--) { seg[k] = f(seg[2 * k + 0], seg[2 * k + 1]); } } void update(int k, const Monoid &x) { k += sz; seg[k] = x; while(k >>= 1) { seg[k] = f(seg[2 * k + 0], seg[2 * k + 1]); } } Monoid query(int a, int b) { Monoid L = M1, R = M1; for(a += sz, b += sz; a < b; a >>= 1, b >>= 1) { if(a & 1) L = f(L, seg[a++]); if(b & 1) R = f(seg[--b], R); } return f(L, R); } Monoid operator[](const int &k) const { return seg[k + sz]; } }; int main() { int N, M, Q; scanf("%d %d %d", &N, &M, &Q); UnWeightedGraph g(N); BiConnectedComponents< UnWeightedGraph > bc(g); for(int i = 0; i < M; i++) { int A, B; scanf("%d %d", &A, &B); --A, --B; g[A].emplace_back(B); g[B].emplace_back(A); } vector< vector< int > > graph; bc.build(graph); HeavyLightDecomposition< UnWeightedGraph > hld(graph); hld.build(); auto f = [](int a, int b) { return max(a, b); }; SegmentTree< int > seg(graph.size(), f, -1); vector< priority_queue< int > > que(graph.size()); unordered_map< int, int > pos; for(int i = 0; i < Q; i++) { int T, A, B; scanf("%d %d %d", &T, &A, &B); if(T == 1) { A = bc[--A]; pos[B] = A; que[A].push(B); if(que[A].top() == B) seg.update(hld.in[A], que[A].top()); } else { int value = hld.query(bc[--A], bc[--B], 0, [&](int a, int b) { return seg.query(a, b); }, [](int a, int b) { return max(a, b); }); printf("%d\n", value); if(value >= 1) { int idx = pos[value]; que[idx].pop(); seg.update(hld.in[idx], que[idx].empty() ? -1 : que[idx].top()); } } } }