#line 1 "main.cpp" #define PROBLEM "https://yukicoder.me/problems/no/1216" #line 1 "library/my_template.hpp" #if defined(LOCAL) #include #else #pragma GCC optimize("Ofast") #pragma GCC optimize("unroll-loops") #include using namespace std; using ll = long long; using u32 = unsigned int; using u64 = unsigned long long; using i128 = __int128; template constexpr T infty = 0; template <> constexpr int infty = 1'000'000'000; template <> constexpr ll infty = ll(infty) * infty * 2; template <> constexpr u32 infty = infty; template <> constexpr u64 infty = infty; template <> constexpr i128 infty = i128(infty) * infty; template <> constexpr double infty = infty; template <> constexpr long double infty = infty; using pi = pair; using vi = vector; template using vc = vector; template using vvc = vector>; template using vvvc = vector>; template using vvvvc = vector>; template using vvvvvc = vector>; template using pq = priority_queue; template using pqg = priority_queue, greater>; #define vv(type, name, h, ...) \ vector> name(h, vector(__VA_ARGS__)) #define vvv(type, name, h, w, ...) \ vector>> name( \ h, vector>(w, vector(__VA_ARGS__))) #define vvvv(type, name, a, b, c, ...) \ vector>>> name( \ a, vector>>( \ b, vector>(c, vector(__VA_ARGS__)))) // https://trap.jp/post/1224/ #define FOR1(a) for (ll _ = 0; _ < ll(a); ++_) #define FOR2(i, a) for (ll i = 0; i < ll(a); ++i) #define FOR3(i, a, b) for (ll i = a; i < ll(b); ++i) #define FOR4(i, a, b, c) for (ll i = a; i < ll(b); i += (c)) #define FOR1_R(a) for (ll i = (a)-1; i >= ll(0); --i) #define FOR2_R(i, a) for (ll i = (a)-1; i >= ll(0); --i) #define FOR3_R(i, a, b) for (ll i = (b)-1; i >= ll(a); --i) #define overload4(a, b, c, d, e, ...) e #define overload3(a, b, c, d, ...) d #define FOR(...) overload4(__VA_ARGS__, FOR4, FOR3, FOR2, FOR1)(__VA_ARGS__) #define FOR_R(...) overload3(__VA_ARGS__, FOR3_R, FOR2_R, FOR1_R)(__VA_ARGS__) #define FOR_subset(t, s) \ for (ll t = (s); t >= 0; t = (t == 0 ? -1 : (t - 1) & (s))) #define all(x) x.begin(), x.end() #define len(x) ll(x.size()) #define elif else if #define eb emplace_back #define mp make_pair #define mt make_tuple #define fi first #define se second #define stoi stoll int popcnt(int x) { return __builtin_popcount(x); } int popcnt(u32 x) { return __builtin_popcount(x); } int popcnt(ll x) { return __builtin_popcountll(x); } int popcnt(u64 x) { return __builtin_popcountll(x); } // (0, 1, 2, 3, 4) -> (-1, 0, 1, 1, 2) int topbit(int x) { return (x == 0 ? -1 : 31 - __builtin_clz(x)); } int topbit(u32 x) { return (x == 0 ? -1 : 31 - __builtin_clz(x)); } int topbit(ll x) { return (x == 0 ? -1 : 63 - __builtin_clzll(x)); } int topbit(u64 x) { return (x == 0 ? -1 : 63 - __builtin_clzll(x)); } // (0, 1, 2, 3, 4) -> (-1, 0, 1, 0, 2) int lowbit(int x) { return (x == 0 ? -1 : __builtin_ctz(x)); } int lowbit(u32 x) { return (x == 0 ? -1 : __builtin_ctz(x)); } int lowbit(ll x) { return (x == 0 ? -1 : __builtin_ctzll(x)); } int lowbit(u64 x) { return (x == 0 ? -1 : __builtin_ctzll(x)); } template T ceil(T x, U y) { return (x > 0 ? (x + y - 1) / y : x / y); } template T floor(T x, U y) { return (x > 0 ? x / y : (x - y + 1) / y); } template pair divmod(T x, U y) { T q = floor(x, y); return {q, x - q * y}; } template T SUM(const vector &A) { T sum = 0; for (auto &&a: A) sum += a; return sum; } #define MIN(v) *min_element(all(v)) #define MAX(v) *max_element(all(v)) #define LB(c, x) distance((c).begin(), lower_bound(all(c), (x))) #define UB(c, x) distance((c).begin(), upper_bound(all(c), (x))) #define UNIQUE(x) \ sort(all(x)), x.erase(unique(all(x)), x.end()), x.shrink_to_fit() template T POP(deque &que) { T a = que.front(); que.pop_front(); return a; } template T POP(pq &que) { T a = que.top(); que.pop(); return a; } template T POP(pqg &que) { assert(!que.empty()); T a = que.top(); que.pop(); return a; } template T POP(vc &que) { assert(!que.empty()); T a = que.back(); que.pop_back(); return a; } template ll binary_search(F check, ll ok, ll ng, bool check_ok = true) { if (check_ok) assert(check(ok)); while (abs(ok - ng) > 1) { auto x = (ng + ok) / 2; tie(ok, ng) = (check(x) ? mp(x, ng) : mp(ok, x)); } return ok; } template double binary_search_real(F check, double ok, double ng, int iter = 100) { FOR(iter) { double x = (ok + ng) / 2; tie(ok, ng) = (check(x) ? mp(x, ng) : mp(ok, x)); } return (ok + ng) / 2; } template inline bool chmax(T &a, const S &b) { return (a < b ? a = b, 1 : 0); } template inline bool chmin(T &a, const S &b) { return (a > b ? a = b, 1 : 0); } // ? は -1 vc s_to_vi(const string &S, char first_char) { vc A(S.size()); FOR(i, S.size()) { A[i] = (S[i] != '?' ? S[i] - first_char : -1); } return A; } template vector cumsum(vector &A, int off = 1) { int N = A.size(); vector B(N + 1); FOR(i, N) { B[i + 1] = B[i] + A[i]; } if (off == 0) B.erase(B.begin()); return B; } // stable sort template vector argsort(const vector &A) { vector ids(len(A)); iota(all(ids), 0); sort(all(ids), [&](int i, int j) { return (A[i] == A[j] ? i < j : A[i] < A[j]); }); return ids; } // A[I[0]], A[I[1]], ... template vc rearrange(const vc &A, const vc &I) { vc B(len(I)); FOR(i, len(I)) B[i] = A[I[i]]; return B; } #endif #line 1 "library/other/io.hpp" // based on yosupo's fastio #include namespace fastio { #define FASTIO // クラスが read(), print() を持っているかを判定するメタ関数 struct has_write_impl { template static auto check(T &&x) -> decltype(x.write(), std::true_type{}); template static auto check(...) -> std::false_type; }; template class has_write : public decltype(has_write_impl::check(std::declval())) { }; struct has_read_impl { template static auto check(T &&x) -> decltype(x.read(), std::true_type{}); template static auto check(...) -> std::false_type; }; template class has_read : public decltype(has_read_impl::check(std::declval())) {}; struct Scanner { FILE *fp; char line[(1 << 15) + 1]; size_t st = 0, ed = 0; void reread() { memmove(line, line + st, ed - st); ed -= st; st = 0; ed += fread(line + ed, 1, (1 << 15) - ed, fp); line[ed] = '\0'; } bool succ() { while (true) { if (st == ed) { reread(); if (st == ed) return false; } while (st != ed && isspace(line[st])) st++; if (st != ed) break; } if (ed - st <= 50) { bool sep = false; for (size_t i = st; i < ed; i++) { if (isspace(line[i])) { sep = true; break; } } if (!sep) reread(); } return true; } template ::value, int> = 0> bool read_single(T &ref) { if (!succ()) return false; while (true) { size_t sz = 0; while (st + sz < ed && !isspace(line[st + sz])) sz++; ref.append(line + st, sz); st += sz; if (!sz || st != ed) break; reread(); } return true; } template ::value, int> = 0> bool read_single(T &ref) { if (!succ()) return false; bool neg = false; if (line[st] == '-') { neg = true; st++; } ref = T(0); while (isdigit(line[st])) { ref = 10 * ref + (line[st++] & 0xf); } if (neg) ref = -ref; return true; } template ::value>::type * = nullptr> inline bool read_single(T &x) { x.read(); return true; } bool read_single(double &ref) { string s; if (!read_single(s)) return false; ref = std::stod(s); return true; } bool read_single(char &ref) { string s; if (!read_single(s) || s.size() != 1) return false; ref = s[0]; return true; } template bool read_single(vector &ref) { for (auto &d: ref) { if (!read_single(d)) return false; } return true; } template bool read_single(pair &p) { return (read_single(p.first) && read_single(p.second)); } template void read_single_tuple(T &t) { if constexpr (N < std::tuple_size::value) { auto &x = std::get(t); read_single(x); read_single_tuple(t); } } template bool read_single(tuple &tpl) { read_single_tuple(tpl); return true; } void read() {} template void read(H &h, T &... t) { bool f = read_single(h); assert(f); read(t...); } Scanner(FILE *fp) : fp(fp) {} }; struct Printer { Printer(FILE *_fp) : fp(_fp) {} ~Printer() { flush(); } static constexpr size_t SIZE = 1 << 15; FILE *fp; char line[SIZE], small[50]; size_t pos = 0; void flush() { fwrite(line, 1, pos, fp); pos = 0; } void write(const char val) { if (pos == SIZE) flush(); line[pos++] = val; } template ::value, int> = 0> void write(T val) { if (pos > (1 << 15) - 50) flush(); if (val == 0) { write('0'); return; } if (val < 0) { write('-'); val = -val; // todo min } size_t len = 0; while (val) { small[len++] = char(0x30 | (val % 10)); val /= 10; } for (size_t i = 0; i < len; i++) { line[pos + i] = small[len - 1 - i]; } pos += len; } void write(const string s) { for (char c: s) write(c); } void write(const char *s) { size_t len = strlen(s); for (size_t i = 0; i < len; i++) write(s[i]); } void write(const double x) { ostringstream oss; oss << fixed << setprecision(15) << x; string s = oss.str(); write(s); } void write(const long double x) { ostringstream oss; oss << fixed << setprecision(15) << x; string s = oss.str(); write(s); } template ::value>::type * = nullptr> inline void write(T x) { x.write(); } template void write(const vector val) { auto n = val.size(); for (size_t i = 0; i < n; i++) { if (i) write(' '); write(val[i]); } } template void write(const pair val) { write(val.first); write(' '); write(val.second); } template void write_tuple(const T t) { if constexpr (N < std::tuple_size::value) { if constexpr (N > 0) { write(' '); } const auto x = std::get(t); write(x); write_tuple(t); } } template bool write(tuple tpl) { write_tuple(tpl); return true; } template void write(const array val) { auto n = val.size(); for (size_t i = 0; i < n; i++) { if (i) write(' '); write(val[i]); } } void write(i128 val) { string s; bool negative = 0; if (val < 0) { negative = 1; val = -val; } while (val) { s += '0' + int(val % 10); val /= 10; } if (negative) s += "-"; reverse(all(s)); if (len(s) == 0) s = "0"; write(s); } }; Scanner scanner = Scanner(stdin); Printer printer = Printer(stdout); void flush() { printer.flush(); } void print() { printer.write('\n'); } template void print(Head &&head, Tail &&... tail) { printer.write(head); if (sizeof...(Tail)) printer.write(' '); print(forward(tail)...); } void read() {} template void read(Head &head, Tail &... tail) { scanner.read(head); read(tail...); } } // namespace fastio using fastio::print; using fastio::flush; using fastio::read; #define INT(...) \ int __VA_ARGS__; \ read(__VA_ARGS__) #define LL(...) \ ll __VA_ARGS__; \ read(__VA_ARGS__) #define STR(...) \ string __VA_ARGS__; \ read(__VA_ARGS__) #define CHAR(...) \ char __VA_ARGS__; \ read(__VA_ARGS__) #define DBL(...) \ double __VA_ARGS__; \ read(__VA_ARGS__) #define VEC(type, name, size) \ vector name(size); \ read(name) #define VV(type, name, h, w) \ vector> name(h, vector(w)); \ read(name) void YES(bool t = 1) { print(t ? "YES" : "NO"); } void NO(bool t = 1) { YES(!t); } void Yes(bool t = 1) { print(t ? "Yes" : "No"); } void No(bool t = 1) { Yes(!t); } void yes(bool t = 1) { print(t ? "yes" : "no"); } void no(bool t = 1) { yes(!t); } #line 2 "library/graph/tree.hpp" #line 2 "library/graph/base.hpp" template struct Edge { int frm, to; T cost; int id; }; template struct Graph { int N, M; using cost_type = T; using edge_type = Edge; vector edges; vector indptr; vector csr_edges; vc vc_deg, vc_indeg, vc_outdeg; bool prepared; class OutgoingEdges { public: OutgoingEdges(const Graph* G, int l, int r) : G(G), l(l), r(r) {} const edge_type* begin() const { if (l == r) { return 0; } return &G->csr_edges[l]; } const edge_type* end() const { if (l == r) { return 0; } return &G->csr_edges[r]; } private: const Graph* G; int l, r; }; bool is_prepared() { return prepared; } constexpr bool is_directed() { return directed; } Graph() : N(0), M(0), prepared(0) {} Graph(int N) : N(N), M(0), prepared(0) {} void build(int n) { N = n, M = 0; prepared = 0; edges.clear(); indptr.clear(); csr_edges.clear(); vc_deg.clear(); vc_indeg.clear(); vc_outdeg.clear(); } void add(int frm, int to, T cost = 1, int i = -1) { assert(!prepared); assert(0 <= frm && 0 <= to && to < N); if (i == -1) i = M; auto e = edge_type({frm, to, cost, i}); edges.eb(e); ++M; } // wt, off void read_tree(bool wt = false, int off = 1) { read_graph(N - 1, wt, off); } void read_graph(int M, bool wt = false, int off = 1) { for (int m = 0; m < M; ++m) { INT(a, b); a -= off, b -= off; if (!wt) { add(a, b); } else { T c; read(c); add(a, b, c); } } build(); } void build() { assert(!prepared); prepared = true; indptr.assign(N + 1, 0); for (auto&& e: edges) { indptr[e.frm + 1]++; if (!directed) indptr[e.to + 1]++; } for (int v = 0; v < N; ++v) { indptr[v + 1] += indptr[v]; } auto counter = indptr; csr_edges.resize(indptr.back() + 1); for (auto&& e: edges) { csr_edges[counter[e.frm]++] = e; if (!directed) csr_edges[counter[e.to]++] = edge_type({e.to, e.frm, e.cost, e.id}); } } OutgoingEdges operator[](int v) const { assert(prepared); return {this, indptr[v], indptr[v + 1]}; } vc deg_array() { if (vc_deg.empty()) calc_deg(); return vc_deg; } pair, vc> deg_array_inout() { if (vc_indeg.empty()) calc_deg_inout(); return {vc_indeg, vc_outdeg}; } int deg(int v) { if (vc_deg.empty()) calc_deg(); return vc_deg[v]; } int in_deg(int v) { if (vc_indeg.empty()) calc_deg_inout(); return vc_indeg[v]; } int out_deg(int v) { if (vc_outdeg.empty()) calc_deg_inout(); return vc_outdeg[v]; } void debug() { print("Graph"); if (!prepared) { print("frm to cost id"); for (auto&& e: edges) print(e.frm, e.to, e.cost, e.id); } else { print("indptr", indptr); print("frm to cost id"); FOR(v, N) for (auto&& e: (*this)[v]) print(e.frm, e.to, e.cost, e.id); } } vc new_idx; vc used_e; // G における頂点 V[i] が、新しいグラフで i になるようにする // {G, es} pair, vc> rearrange(vc V) { if (len(new_idx) != N) new_idx.assign(N, -1); if (len(used_e) != M) used_e.assign(M, 0); int n = len(V); FOR(i, n) new_idx[V[i]] = i; Graph G(n); vc es; FOR(i, n) { for (auto&& e: (*this)[V[i]]) { if (used_e[e.id]) continue; int a = e.frm, b = e.to; if (new_idx[a] != -1 && new_idx[b] != -1) { used_e[e.id] = 1; G.add(new_idx[a], new_idx[b], e.cost); es.eb(e.id); } } } FOR(i, n) new_idx[V[i]] = -1; for (auto&& eid: es) used_e[eid] = 0; G.build(); return {G, es}; } private: void calc_deg() { assert(vc_deg.empty()); vc_deg.resize(N); for (auto&& e: edges) vc_deg[e.frm]++, vc_deg[e.to]++; } void calc_deg_inout() { assert(vc_indeg.empty()); vc_indeg.resize(N); vc_outdeg.resize(N); for (auto&& e: edges) { vc_indeg[e.to]++, vc_outdeg[e.frm]++; } } }; #line 4 "library/graph/tree.hpp" // HLD euler tour をとっていろいろ。 // 木以外、非連結でも dfs 順序や親がとれる。 template struct Tree { using Graph_type = GT; GT &G; using WT = typename GT::cost_type; int N; vector LID, RID, head, V, parent, VtoE; vc depth; vc depth_weighted; Tree(GT &G, int r = 0, bool hld = 1) : G(G) { build(r, hld); } void build(int r = 0, bool hld = 1) { if (r == -1) return; // build を遅延したいとき N = G.N; LID.assign(N, -1), RID.assign(N, -1), head.assign(N, r); V.assign(N, -1), parent.assign(N, -1), VtoE.assign(N, -1); depth.assign(N, -1), depth_weighted.assign(N, 0); assert(G.is_prepared()); int t1 = 0; dfs_sz(r, -1, hld); dfs_hld(r, t1); } void dfs_sz(int v, int p, bool hld) { auto &sz = RID; parent[v] = p; depth[v] = (p == -1 ? 0 : depth[p] + 1); sz[v] = 1; int l = G.indptr[v], r = G.indptr[v + 1]; auto &csr = G.csr_edges; // 使う辺があれば先頭にする for (int i = r - 2; i >= l; --i) { if (hld && depth[csr[i + 1].to] == -1) swap(csr[i], csr[i + 1]); } int hld_sz = 0; for (int i = l; i < r; ++i) { auto e = csr[i]; if (depth[e.to] != -1) continue; depth_weighted[e.to] = depth_weighted[v] + e.cost; VtoE[e.to] = e.id; dfs_sz(e.to, v, hld); sz[v] += sz[e.to]; if (hld && chmax(hld_sz, sz[e.to]) && l < i) { swap(csr[l], csr[i]); } } } void dfs_hld(int v, int ×) { LID[v] = times++; RID[v] += LID[v]; V[LID[v]] = v; bool heavy = true; for (auto &&e: G[v]) { if (depth[e.to] <= depth[v]) continue; head[e.to] = (heavy ? head[v] : e.to); heavy = false; dfs_hld(e.to, times); } } vc heavy_path_at(int v) { vc P = {v}; while (1) { int a = P.back(); for (auto &&e: G[a]) { if (e.to != parent[a] && head[e.to] == v) { P.eb(e.to); break; } } if (P.back() == a) break; } return P; } int e_to_v(int eid) { auto e = G.edges[eid]; return (parent[e.frm] == e.to ? e.frm : e.to); } int v_to_e(int v) { return VtoE[v]; } int ELID(int v) { return 2 * LID[v] - depth[v]; } int ERID(int v) { return 2 * RID[v] - depth[v] - 1; } /* k: 0-indexed */ int LA(int v, int k) { assert(k <= depth[v]); while (1) { int u = head[v]; if (LID[v] - k >= LID[u]) return V[LID[v] - k]; k -= LID[v] - LID[u] + 1; v = parent[u]; } } int la(int u, int v) { return LA(u, v); } int LCA(int u, int v) { for (;; v = parent[head[v]]) { if (LID[u] > LID[v]) swap(u, v); if (head[u] == head[v]) return u; } } // root を根とした場合の lca int LCA_root(int u, int v, int root) { return LCA(u, v) ^ LCA(u, root) ^ LCA(v, root); } int lca(int u, int v) { return LCA(u, v); } int lca_root(int u, int v, int root) { return LCA_root(u, v, root); } int subtree_size(int v, int root = -1) { if (root == -1) return RID[v] - LID[v]; if (v == root) return N; int x = jump(v, root, 1); if (in_subtree(v, x)) return RID[v] - LID[v]; return N - RID[x] + LID[x]; } int dist(int a, int b) { int c = LCA(a, b); return depth[a] + depth[b] - 2 * depth[c]; } WT dist_weighted(int a, int b) { int c = LCA(a, b); return depth_weighted[a] + depth_weighted[b] - WT(2) * depth_weighted[c]; } // a is in b bool in_subtree(int a, int b) { return LID[b] <= LID[a] && LID[a] < RID[b]; } int jump(int a, int b, ll k) { if (k == 1) { if (a == b) return -1; return (in_subtree(b, a) ? LA(b, depth[b] - depth[a] - 1) : parent[a]); } int c = LCA(a, b); int d_ac = depth[a] - depth[c]; int d_bc = depth[b] - depth[c]; if (k > d_ac + d_bc) return -1; if (k <= d_ac) return LA(a, k); return LA(b, d_ac + d_bc - k); } vc collect_child(int v) { vc res; for (auto &&e: G[v]) if (e.to != parent[v]) res.eb(e.to); return res; } vc> get_path_decomposition(int u, int v, bool edge) { // [始点, 終点] の"閉"区間列。 vc> up, down; while (1) { if (head[u] == head[v]) break; if (LID[u] < LID[v]) { down.eb(LID[head[v]], LID[v]); v = parent[head[v]]; } else { up.eb(LID[u], LID[head[u]]); u = parent[head[u]]; } } if (LID[u] < LID[v]) down.eb(LID[u] + edge, LID[v]); elif (LID[v] + edge <= LID[u]) up.eb(LID[u], LID[v] + edge); reverse(all(down)); up.insert(up.end(), all(down)); return up; } vc restore_path(int u, int v) { vc P; for (auto &&[a, b]: get_path_decomposition(u, v, 0)) { if (a <= b) { FOR(i, a, b + 1) P.eb(V[i]); } else { FOR_R(i, b, a + 1) P.eb(V[i]); } } return P; } }; #line 2 "library/ds/sparse_table/disjoint_sparse_table.hpp" template struct Disjoint_Sparse_Table { using MX = Monoid; using X = typename MX::value_type; int n, log; vvc dat; Disjoint_Sparse_Table() {} Disjoint_Sparse_Table(int n) { build(n); } template Disjoint_Sparse_Table(int n, F f) { build(n, f); } Disjoint_Sparse_Table(const vc& v) { build(v); } void build(int m) { build(m, [](int i) -> X { return MX::unit(); }); } void build(const vc& v) { build(len(v), [&](int i) -> X { return v[i]; }); } template void build(int m, F f) { n = m, log = 1; while ((1 << log) < n) ++log; dat.resize(log); dat[0].reserve(n); FOR(i, n) dat[0].eb(f(i)); FOR(i, 1, log) { auto& v = dat[i]; v = dat[0]; int b = 1 << i; for (int m = b; m <= n; m += 2 * b) { int L = m - b, R = min(n, m + b); FOR_R(j, L + 1, m) v[j - 1] = MX::op(v[j - 1], v[j]); FOR(j, m, R - 1) v[j + 1] = MX::op(v[j], v[j + 1]); } } } X prod(int L, int R) { if (L == R) return MX::unit(); --R; if (L == R) return dat[0][L]; int k = 31 - __builtin_clz(L ^ R); return MX::op(dat[k][L], dat[k][R]); } template int max_right(const F check, int L) { assert(0 <= L && L <= n && check(MX::unit())); if (L == n) return n; int ok = L, ng = n + 1; while (ok + 1 < ng) { int k = (ok + ng) / 2; bool bl = check(prod(L, k)); if (bl) ok = k; if (!bl) ng = k; } return ok; } template int min_left(const F check, int R) { assert(0 <= R && R <= n && check(MX::unit())); if (R == 0) return 0; int ok = R, ng = -1; while (ng + 1 < ok) { int k = (ok + ng) / 2; bool bl = check(prod(k, R)); if (bl) ok = k; if (!bl) ng = k; } return ok; } }; #line 2 "library/alg/monoid/monoid_reverse.hpp" template struct Monoid_Reverse { using value_type = typename Monoid::value_type; using X = value_type; static constexpr X op(const X &x, const X &y) { return Monoid::op(y, x); } static constexpr X unit() { return Monoid::unit(); } static const bool commute = Monoid::commute; }; #line 4 "library/graph/ds/static_tree_monoid.hpp" template struct Static_Tree_Monoid { using MX = Monoid; using X = typename Monoid::value_type; TREE &tree; int N; Disjoint_Sparse_Table seg; Disjoint_Sparse_Table> seg_r; Static_Tree_Monoid(TREE &tree) : tree(tree), N(tree.N) { build([](int i) -> X { return MX::unit(); }); } Static_Tree_Monoid(TREE &tree, vc &dat) : tree(tree), N(tree.N) { build([&](int i) -> X { return dat[i]; }); } template Static_Tree_Monoid(TREE &tree, F f) : tree(tree), N(tree.N) { build(f); } template void build(F f) { if (!edge) { auto f_v = [&](int i) -> X { return f(tree.V[i]); }; seg.build(N, f_v); if constexpr (!MX::commute) seg_r.build(N, f_v); } else { auto f_e = [&](int i) -> X { return (i == 0 ? MX::unit() : f(tree.v_to_e(tree.V[i]))); }; seg.build(N, f_e); if constexpr (!MX::commute) seg_r.build(N, f_e); } } X prod_path(int u, int v) { auto pd = tree.get_path_decomposition(u, v, edge); X val = MX::unit(); for (auto &&[a, b]: pd) { val = MX::op(val, get_prod(a, b)); } return val; } // uv path 上で prod_path(u, x) が check を満たす最後の x // なければ -1 template int max_path(F check, int u, int v) { if (edge) return max_path_edge(check, u, v); if (!check(prod_path(u, u))) return -1; auto pd = tree.get_path_decomposition(u, v, edge); X val = MX::unit(); for (auto &&[a, b]: pd) { X x = get_prod(a, b); if (check(MX::op(val, x))) { val = MX::op(val, x); u = (tree.V[b]); continue; } auto check_tmp = [&](X x) -> bool { return check(MX::op(val, x)); }; if (a <= b) { // 下り int i = seg.max_right(check_tmp, a); return (i == a ? u : tree.V[i - 1]); } else { // 上り int i = 0; if constexpr (MX::commute) i = seg.min_left(check_tmp, a + 1); if constexpr (!MX::commute) i = seg_r.min_left(check_tmp, a + 1); if (i == a + 1) return u; return (edge ? tree.parent[tree.V[i]] : tree.V[i]); } } return v; } X prod_subtree(int u) { int l = tree.LID[u], r = tree.RID[u]; return seg.prod(l + edge, r); } // [a,b] heavy path 形式 inline X get_prod(int a, int b) { if constexpr (MX::commute) return (a <= b ? seg.prod(a, b + 1) : seg.prod(b, a + 1)); return (a <= b ? seg.prod(a, b + 1) : seg_r.prod(b, a + 1)); } private: template int max_path_edge(F check, int u, int v) { assert(edge); if (!check(MX::unit())) return -1; int lca = tree.lca(u, v); auto pd = tree.get_path_decomposition(u, lca, edge); X val = MX::unit(); // climb for (auto &&[a, b]: pd) { assert(a >= b); X x = prod_path(a, b); if (check(MX::op(val, x))) { val = MX::op(val, x); u = (tree.parent[tree.V[b]]); continue; } auto check_tmp = [&](X x) -> bool { return check(MX::op(val, x)); }; int i = 0; if constexpr (MX::commute) i = seg.min_left(check_tmp, a + 1); if constexpr (!MX::commute) i = seg_r.min_left(check_tmp, a + 1); if (i == a + 1) return u; return tree.parent[tree.V[i]]; } // down pd = tree.get_path_decomposition(lca, v, edge); for (auto &&[a, b]: pd) { assert(a <= b); X x = seg.prod(a, b + 1); if (check(MX::op(val, x))) { val = MX::op(val, x); u = (tree.V[b]); continue; } auto check_tmp = [&](X x) -> bool { return check(MX::op(val, x)); }; auto i = seg.max_right(check_tmp, a); return (i == a ? u : tree.V[i - 1]); } return v; } }; #line 2 "library/alg/monoid/add.hpp" template struct Monoid_Add { using value_type = X; static constexpr X op(const X &x, const X &y) noexcept { return x + y; } static constexpr X inverse(const X &x) noexcept { return -x; } static constexpr X power(const X &x, ll n) noexcept { return X(n) * x; } static constexpr X unit() { return X(0); } static constexpr bool commute = true; }; #line 2 "library/ds/fenwicktree/fenwicktree_2d.hpp" template struct FenwickTree_2D { using G = Monoid; using E = typename G::value_type; static_assert(G::commute); int N; vc keyX; XY min_X; vc indptr; vc keyY; vc dat; FenwickTree_2D(vc& X, vc& Y, vc wt) { build(X, Y, wt); } FenwickTree_2D(vc& X, vc& Y) { vc wt(len(X), G::unit()); build(X, Y, wt); } inline int xtoi(XY x) { return (SMALL_X ? clamp(x - min_X, 0, N) : LB(keyX, x)); } inline int nxt(int i) { return i + ((i + 1) & -(i + 1)); } inline int prev(int i) { return i - ((i + 1) & -(i + 1)); } void build(vc& X, vc& Y, vc wt) { assert(len(X) == len(Y) && len(X) == len(wt)); if (!SMALL_X) { keyX = X; UNIQUE(keyX); N = len(keyX); } else { min_X = (len(X) == 0 ? 0 : MIN(X)); N = (len(X) == 0 ? 0 : MAX(X)) - min_X + 1; keyX.resize(N); FOR(i, N) keyX[i] = min_X + i; } vvc keyY_raw(N); vvc dat_raw(N); for (auto&& i: argsort(Y)) { int ix = xtoi(X[i]); XY y = Y[i]; while (ix < N) { auto& KY = keyY_raw[ix]; if (len(KY) == 0 || KY.back() < y) { KY.eb(y); dat_raw[ix].eb(wt[i]); } else { dat_raw[ix].back() = G::op(dat_raw[ix].back(), wt[i]); } ix = nxt(ix); } } indptr.assign(N + 1, 0); FOR(i, N) indptr[i + 1] = indptr[i] + len(keyY_raw[i]); keyY.resize(indptr.back()); dat.resize(indptr.back()); FOR(i, N) FOR(j, indptr[i + 1] - indptr[i]) { keyY[indptr[i] + j] = keyY_raw[i][j]; dat[indptr[i] + j] = dat_raw[i][j]; } FOR(i, N) { int n = indptr[i + 1] - indptr[i]; FOR(j, n - 1) { int k = nxt(j); if (k < n) dat[indptr[i] + k] = G::op(dat[indptr[i] + k], dat[indptr[i] + j]); } } } void add(XY x, XY y, E val) { multiply(x, y, val); } void multiply(XY x, XY y, E val) { int i = xtoi(x); assert(keyX[i] == x); while (i < N) { multiply_i(i, y, val), i = nxt(i); } } E sum(XY lx, XY rx, XY ly, XY ry) { return prod(lx, rx, ly, ry); } E prod(XY lx, XY rx, XY ly, XY ry) { E pos = G::unit(), neg = G::unit(); int L = xtoi(lx) - 1, R = xtoi(rx) - 1; while (L < R) { pos = G::op(pos, prod_i(R, ly, ry)), R = prev(R); } while (R < L) { neg = G::op(neg, prod_i(L, ly, ry)), L = prev(L); } return G::op(pos, G::inverse(neg)); } E prefix_sum(XY rx, XY ry) { return prefix_prod(rx, ry); } E prefix_prod(XY rx, XY ry) { E pos = G::unit(); int R = xtoi(rx) - 1; while (R >= 0) { pos = G::op(pos, prefix_prod_i(R, ry)), R = prev(R); } return pos; } private: void multiply_i(int i, XY y, E val) { int LID = indptr[i], n = indptr[i + 1] - indptr[i]; auto it = keyY.begin() + LID; int j = lower_bound(it, it + n, y) - it; while (j < n) { dat[LID + j] = G::op(dat[LID + j], val), j = nxt(j); } } E prod_i(int i, XY ly, XY ry) { E pos = G::unit(), neg = G::unit(); int LID = indptr[i], n = indptr[i + 1] - indptr[i]; auto it = keyY.begin() + LID; int L = lower_bound(it, it + n, ly) - it - 1; int R = lower_bound(it, it + n, ry) - it - 1; while (L < R) { pos = G::op(pos, dat[LID + R]), R = prev(R); } while (R < L) { neg = G::op(neg, dat[LID + L]), L = prev(L); } return G::op(pos, G::inverse(neg)); } E prefix_prod_i(int i, XY ry) { E pos = G::unit(); int LID = indptr[i], n = indptr[i + 1] - indptr[i]; auto it = keyY.begin() + LID; int R = lower_bound(it, it + n, ry) - it - 1; while (R >= 0) { pos = G::op(pos, dat[LID + R]), R = prev(R); } return pos; } }; #line 7 "main.cpp" void solve() { LL(N, Q); Graph G(N); G.read_tree(1); Tree tree(G); vi dat(N - 1); FOR(i, N - 1) dat[i] = G.edges[i].cost; Static_Tree_Monoid, 1> TM(tree, dat); auto& dist = tree.depth_weighted; /* ・頂点 v に、根に着くのが時刻 t であるようなものを追加 ・(消す)はじめて消えて到達するのが w であるとき、w に -1 個追加 euler tour をとって */ using T = tuple; vc query; auto& LID = tree.LID; vi X, Y; iota(all(X), 0); FOR(Q) { LL(tp, v, t, l); --v; if (tp == 0) { // 追加クエリ // 消えないで到達できる最大の頂点 auto check = [&](auto e) -> bool { return e <= l; }; auto to = TM.max_path(check, v, 0); int w = tree.parent[to]; query.eb(1, LID[v], t + dist[v]); X.eb(LID[v]); Y.eb(t + dist[v]); if (w != -1) { X.eb(LID[w]); Y.eb(t + dist[v]); query.eb(-1, LID[w], t + dist[v]); } } if (tp == 1) { query.eb(0, v, t); } } FenwickTree_2D, ll, true> bit(X, Y); for (auto&& [tp, x, t]: query) { if (tp == 0) { int v = x; int l = tree.LID[v], r = tree.RID[v]; t += dist[v]; ll ANS = bit.sum(l, r, 0, t + 1); print(ANS); } if (tp == 1) { bit.add(x, t, 1); } if (tp == -1) { bit.add(x, t, -1); } } } signed main() { solve(); return 0; }