12tqian's Competitive Programming Library
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verify/yosupo/yosupo-frequency_table_of_tree_distance.test.cpp
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- Last update: 2022-08-21 11:26:50-04:00
- Problem: https://judge.yosupo.jp/problem/frequency_table_of_tree_distance
Depends on
- library/contest/template-full.hpp
- library/contest/template-minimal.hpp
- Sparse Table
(library/data-structures/1d-range-queries/sparse-table.hpp)
- library/graphs/centroid-decomposition.hpp
- LCA RMQ
(library/graphs/lca-rmq.hpp)
- library/misc/easy-io.hpp
- library/modular-arithmetic/mod-int.hpp
- library/modular-arithmetic/mod-int2.hpp
- library/polynomial/fast-fourier-transform.hpp
- library/polynomial/polynomial2.hpp
Code
#define PROBLEM "https://judge.yosupo.jp/problem/frequency_table_of_tree_distance"
#include "../../library/contest/template-full.hpp"
#include "../../library/graphs/centroid-decomposition.hpp"
#include "../../library/graphs/lca-rmq.hpp"
#include "../../library/polynomial/fast-fourier-transform.hpp"
#include "../../library/polynomial/polynomial2.hpp"
int main() {
using namespace FFT;
using namespace Polynomial;
set_io("");
int n;
re(n);
CentroidDecomposition cd;
cd.init(n);
LCARMQ lca;
lca.init(n);
vector<vi> g(n);
f0r(i, n - 1) {
int u, v;
re(u, v);
g[u].pb(v);
g[v].pb(u);
lca.ae(u, v);
cd.ae(u, v);
}
lca.gen();
cd.build();
vl ans(n);
function<vi(int)> dfs = [&](int u) { // return how many at dist x
vi verts;
vector<vl> polys;
polys.pb({1});
vl tmp;
each(v, cd.cg[u]) {
auto res = dfs(v);
each(x, res) verts.pb(x);
tmp.assign(res.size() + 1, 0);
each(x, res) {
++tmp[lca.dist(x, u)];
}
while (tmp.back() == 0) tmp.pop_back();
polys.pb(tmp);
}
vl sum;
each(x, polys) sum += x;
vl res = sum * sum;
each(x, polys) res -= x * x;
res /= 2;
f0r(i, sz(res)) {
ans[i] += res[i];
}
verts.pb(u);
return verts;
};
dfs(cd.root);
f1r(i, 1, n) {
pr(ans[i], ' ');
}
ps();
return 0;
}#define PROBLEM "https://judge.yosupo.jp/problem/frequency_table_of_tree_distance"
#include <algorithm>
#include <array>
#include <bitset>
#include <cassert>
#include <chrono>
#include <cmath>
#include <complex>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <ctime>
#include <deque>
#include <iostream>
#include <iomanip>
#include <list>
#include <map>
#include <numeric>
#include <queue>
#include <random>
#include <set>
#include <stack>
#include <string>
#include <unordered_map>
#include <vector>
using namespace std;
#include <ext/pb_ds/tree_policy.hpp>
#include <ext/pb_ds/assoc_container.hpp>
using namespace __gnu_pbds;
template <class T> using Tree = tree<T, null_type, less<T>, rb_tree_tag, tree_order_statistics_node_update>;
typedef long long ll;
typedef long double ld;
typedef double db;
typedef string str;
typedef pair<int, int> pi;
typedef pair<ll, ll> pl;
typedef pair<db, db> pd;
typedef vector<int> vi;
typedef vector<bool> vb;
typedef vector<ll> vl;
typedef vector<db> vd;
typedef vector<str> vs;
typedef vector<pi> vpi;
typedef vector<pl> vpl;
typedef vector<pd> vpd;
#define mp make_pair
#define f first
#define s second
#define sz(x) (int)(x).size()
#define all(x) begin(x), end(x)
#define rall(x) (x).rbegin(), (x).rend()
#define sor(x) sort(all(x))
#define rsz resize
#define resz resize
#define ins insert
#define ft front()
#define bk back()
#define pf push_front
#define pb push_back
#define eb emplace_back
#define lb lower_bound
#define ub upper_bound
#define f1r(i, a, b) for (int i = (a); i < (b); ++i)
#define f0r(i, a) f1r(i, 0, a)
#define r1f(i, a, b) for (int i = (b); i --> (a); )
#define r0f(i, a) r1f(i, 0, a)
#define FOR(i, a, b) for (int i = (a); i < (b); ++i)
#define F0R(i, a) FOR(i, 0, a)
#define ROF(i, a, b) for (int i = (b) - 1; i >= (a); --i)
#define R0F(i, a) ROF(i, 0, a)
#define each(a, x) for (auto& a : x)
mt19937 rng((uint32_t)chrono::steady_clock::now().time_since_epoch().count());
template <class T> bool ckmin(T& a, const T& b) { return b < a ? a = b, 1 : 0; }
template <class T> bool ckmax(T& a, const T& b) { return a < b ? a = b, 1 : 0; }
template <class T> using V = vector<T>;
template <class T> using VV = V<V<T>>;
template <class T> using VVV = V<V<V<T>>>;
template <class T> using VVVV = V<V<V<V<T>>>>;
template <typename T, typename S> ostream& operator<<(ostream& os, const pair<T, S>& p) {
return os << "(" << p.first << ", " << p.second << ")";
}
template <typename C, typename T = decay<decltype(*begin(declval<C>()))>, typename enable_if<!is_same<C, string>::value>::type* = nullptr>
ostream& operator << (ostream& os, const C& c) {
bool f = true;
os << "{";
for (const auto& x : c) {
if (!f)
os << ", ";
f = false; os << x;
}
return os << "}";
}
template <typename T> void debug(string s, T x) { cerr << s << " = " << x << "\n"; }
template <typename T, typename... Args> void debug(string s, T x, Args... args) {
cerr << s.substr(0, s.find(',')) << " = " << x << " | ";
debug(s.substr(s.find(',') + 2), args...);
}
constexpr int pct(int x) { return __builtin_popcount(x); }
constexpr int bits(int x) { return 31 - __builtin_clz(x); } // floor(log2(x))
inline namespace Helpers {
//////////// is_iterable
// https://stackoverflow.com/questions/13830158/check-if-a-variable-type-is-iterable
// this gets used only when we can call begin() and end() on that type
template <class T, class = void> struct is_iterable : false_type {};
template <class T> struct is_iterable<T, void_t<decltype(begin(declval<T>())),
decltype(end(declval<T>()))
>
> : true_type {};
template <class T> constexpr bool is_iterable_v = is_iterable<T>::value;
//////////// is_readable
template <class T, class = void> struct is_readable : false_type {};
template <class T> struct is_readable<T,
typename std::enable_if_t<
is_same_v<decltype(cin >> declval<T&>()), istream&>
>
> : true_type {};
template <class T> constexpr bool is_readable_v = is_readable<T>::value;
//////////// is_printable
// // https://nafe.es/posts/2020-02-29-is-printable/
template <class T, class = void> struct is_printable : false_type {};
template <class T> struct is_printable<T,
typename std::enable_if_t<
is_same_v<decltype(cout << declval<T>()), ostream&>
>
> : true_type {};
template <class T> constexpr bool is_printable_v = is_printable<T>::value;
}
inline namespace Input {
template <class T> constexpr bool needs_input_v = !is_readable_v<T> && is_iterable_v<T>;
template <class T, class... U> void re(T& t, U&... u);
template <class T, class U> void re(pair<T, U>& p); // pairs
// re: read
template <class T> typename enable_if<is_readable_v<T>, void>::type re(T& x) { cin >> x; } // default
template <class T> void re(complex<T>& c) { T a, b; re(a, b); c = {a, b}; } // complex
template <class T> typename enable_if<needs_input_v<T>, void>::type re(T& i); // ex. vectors, arrays
template <class T, class U> void re(pair<T, U>& p) { re(p.first, p.second); }
template <class T> typename enable_if<needs_input_v<T>, void>::type re(T& i) {
for (auto& x : i) re(x); }
template <class T, class... U> void re(T& t, U&... u) { re(t); re(u...); } // read multiple
// rv: resize and read vectors
void rv(std::size_t) {}
template <class T, class... U> void rv(std::size_t N, vector<T>& t, U&... u);
template <class...U> void rv(std::size_t, std::size_t N2, U&... u);
template <class T, class... U> void rv(std::size_t N, vector<T>& t, U&... u) {
t.resize(N); re(t);
rv(N, u...); }
template <class...U> void rv(std::size_t, std::size_t N2, U&... u) {
rv(N2, u...); }
// dumb shortcuts to read in ints
void decrement() {} // subtract one from each
template <class T, class... U> void decrement(T& t, U&... u) { --t; decrement(u...); }
#define ints(...) int __VA_ARGS__; re(__VA_ARGS__);
#define int1(...) ints(__VA_ARGS__); decrement(__VA_ARGS__);
}
inline namespace ToString {
template <class T> constexpr bool needs_output_v = !is_printable_v<T> && is_iterable_v<T>;
// ts: string representation to print
template <class T> typename enable_if<is_printable_v<T>, string>::type ts(T v) {
stringstream ss; ss << fixed << setprecision(15) << v;
return ss.str(); } // default
template <class T> string bit_vec(T t) { // bit vector to string
string res = "{"; for (int i = 0; i < (int)t.size(); ++i) res += ts(t[i]);
res += "}"; return res; }
string ts(vector<bool> v) { return bit_vec(v); }
template <std::size_t SZ> string ts(bitset<SZ> b) { return bit_vec(b); } // bit vector
template <class T, class U> string ts(pair<T, U> p); // pairs
template <class T> typename enable_if<needs_output_v<T>, string>::type ts(T v); // vectors, arrays
template <class T, class U> string ts(pair<T, U> p) { return "(" + ts(p.first) + ", " + ts(p.second) + ")"; }
template <class T> typename enable_if<is_iterable_v<T>, string>::type ts_sep(T v, string sep) {
// convert container to string w/ separator sep
bool fst = 1; string res = "";
for (const auto& x : v) {
if (!fst) res += sep;
fst = 0; res += ts(x);
}
return res;
}
template <class T> typename enable_if<needs_output_v<T>, string>::type ts(T v) {
return "{" + ts_sep(v, ", ") + "}"; }
// for nested DS
template <int, class T> typename enable_if<!needs_output_v<T>, vector<string>>::type
ts_lev(const T& v) { return {ts(v)}; }
template <int lev, class T> typename enable_if<needs_output_v<T>, vector<string>>::type
ts_lev(const T& v) {
if (lev == 0 || !(int)v.size()) return {ts(v)};
vector<string> res;
for (const auto& t : v) {
if ((int)res.size()) res.back() += ",";
vector<string> tmp = ts_lev<lev - 1>(t);
res.insert(res.end(), tmp.begin(), tmp.end());
}
for (int i = 0; i < (int)res.size(); ++i) {
string bef = " "; if (i == 0) bef = "{";
res[i] = bef + res[i];
}
res.back() += "}";
return res;
}
}
inline namespace Output {
template <class T> void pr_sep(ostream& os, string, const T& t) { os << ts(t); }
template <class T, class... U> void pr_sep(ostream& os, string sep, const T& t, const U&... u) {
pr_sep(os, sep, t); os << sep; pr_sep(os, sep, u...); }
// print w/ no spaces
template <class... T> void pr(const T&... t) { pr_sep(cout, "", t...); }
// print w/ spaces, end with newline
void ps() { cout << "\n"; }
template <class... T> void ps(const T&... t) { pr_sep(cout, " ", t...); ps(); }
// debug to cerr
template <class... T> void dbg_out(const T&... t) {
pr_sep(cerr, " | ", t...); cerr << endl; }
void loc_info(int line, string names) {
cerr << "Line(" << line << ") -> [" << names << "]: "; }
template <int lev, class T> void dbgl_out(const T& t) {
cerr << "\n\n" << ts_sep(ts_lev<lev>(t), "\n") << "\n" << endl; }
#ifdef LOCAL
#define dbg(...) loc_info(__LINE__, #__VA_ARGS__), dbg_out(__VA_ARGS__)
#define dbgl(lev, x) loc_info(__LINE__, #x), dbgl_out<lev>(x)
#else // don't actually submit with this
#define dbg(...) 0
#define dbgl(lev, x) 0
#endif
}
inline namespace FileIO {
void set_in(string s) { (void)!freopen(s.c_str(), "r", stdin); }
void set_out(string s) { (void)!freopen(s.c_str(), "w", stdout); }
void set_io(string s = "") {
cin.tie(0)->sync_with_stdio(0); // unsync C / C++ I/O streams
// cin.exceptions(cin.failbit);
// throws exception when do smth illegal
// ex. try to read letter into int
if (!s.empty()) set_in(s + ".in"), set_out(s + ".out"); // for old USACO
}
}
const int MOD = 1e9 + 7; // 998244353
typedef std::decay<decltype(MOD)>::type mod_t;
struct mi {
mod_t v;
explicit operator mod_t() const { return v; }
explicit operator bool() const { return v != 0; }
mi() { v = 0; }
mi(const long long& _v) {
v = (-MOD <= _v && _v < MOD) ? _v : _v % MOD;
if (v < 0) v += MOD; }
friend std::istream& operator>>(std::istream& in, mi& a) {
long long x; std::cin >> x; a = mi(x); return in; }
friend std::ostream& operator<<(std::ostream& os, const mi& a) { return os << a.v; }
friend bool operator==(const mi& a, const mi& b) { return a.v == b.v; }
friend bool operator!=(const mi& a, const mi& b) { return !(a == b); }
friend bool operator<(const mi& a, const mi& b) { return a.v < b.v; }
friend bool operator>(const mi& a, const mi& b) { return a.v > b.v; }
friend bool operator<=(const mi& a, const mi& b) { return a.v <= b.v; }
friend bool operator>=(const mi& a, const mi& b) { return a.v >= b.v; }
mi operator-() const { return mi(-v); }
mi& operator+=(const mi& m) {
if ((v += m.v) >= MOD) v -= MOD;
return *this; }
mi& operator-=(const mi& m) {
if ((v -= m.v) < 0) v += MOD;
return *this; }
mi& operator*=(const mi& m) { v = (long long)v * m.v % MOD;
return *this; }
friend mi pow(mi a, long long p) {
mi ans = 1; assert(p >= 0);
for (; p; p /= 2, a *= a) if (p & 1) ans *= a;
return ans; }
friend mi inv(const mi& a) { assert(a != 0); return pow(a, MOD - 2); }
mi& operator/=(const mi& m) { return (*this) *= inv(m); }
friend mi operator+(mi a, const mi& b) { return a += b; }
friend mi operator-(mi a, const mi& b) { return a -= b; }
friend mi operator*(mi a, const mi& b) { return a *= b; }
friend mi operator/(mi a, const mi& b) { return a /= b; }
};
const ld PI = acos((ld)-1);
typedef pair<mi, mi> pmi;
typedef vector<mi> vmi;
typedef vector<pmi> vpmi;
struct CentroidDecomposition {
int n;
std::vector<std::vector<int>> g, cg; // cg is directed tree for centroids
std::vector<bool> vis;
std::vector<int> size;
std::vector<int> parent;
int root;
void init(int n_) {
n = n_;
g.assign(n, std::vector<int>());
cg.assign(n, std::vector<int>());
vis.assign(n, false);
parent.assign(n, 0);
size.assign(n, 0);
}
void ae(int u, int v) {
g[u].push_back(v);
g[v].push_back(u);
}
void dfs_size(int src, int par = -1) {
size[src] = 1;
for (int nxt : g[src]) {
if (nxt == par || vis[nxt])
continue;
dfs_size(nxt, src);
size[src] += size[nxt];
}
}
int get_centroid(int src) {
dfs_size(src);
int num = size[src];
int par = -1;
do {
int go = -1;
for (int nxt : g[src]) {
if (nxt == par || vis[nxt])
continue;
if (2 * size[nxt] > num)
go = nxt;
}
par = src;
src = go;
} while (src != -1);
return par;
}
int build_dfs(int src, int par = -1) {
int c = get_centroid(src);
vis[c] = true;
parent[c] = par;
if (par != -1) {
cg[par].push_back(c);
}
for (int nxt : g[c]) {
if (vis[nxt])
continue;
build_dfs(nxt, c);
}
return c;
}
void build() {
root = build_dfs(0);
}
};
template <class T> struct SparseTable {
std::vector<T> v;
std::vector<std::vector<int>> jump;
int level(int x) { return 31 - __builtin_clz(x); }
int comb(int a, int b) {
return v[a] == v[b] ? std::min(a, b) : (v[a] < v[b] ? a : b);
}
void init(const std::vector<T>& _v) {
v = _v;
jump = {std::vector<int>((int)v.size())};
iota(jump[0].begin(), jump[0].end(), 0);
for (int j = 1; (1 << j) <= (int)v.size(); j++) {
jump.push_back(std::vector<int>((int)v.size() - (1 << j) + 1));
for (int i = 0; i < (int)jump[j].size(); i++) {
jump[j][i] = comb(jump[j - 1][i], jump[j - 1][i + (1 << (j - 1))]);
}
}
}
int index(int l, int r) {
assert(l <= r);
int d = level(r - l + 1);
return comb(jump[d][l], jump[d][r - (1 << d) + 1]);
}
T query(int l, int r) {
return v[index(l, r)];
}
};
struct LCARMQ {
int n;
std::vector<std::vector<int>> adj;
std::vector<int> dep, in, par, rev, out, pos;
std::vector<std::pair<int, int>> tmp;
SparseTable<std::pair<int, int>> S;
std::vector<std::vector<int>> sparse;
int ti = 0;
void init(int _n) {
n = _n;
adj.resize(n);
dep = in = out = par = rev = pos = std::vector<int>(n);
sparse = {std::vector<int>(n)};
for (int j = 1; (1 << j) <= n; j++) {
sparse.push_back(std::vector<int>(n - (1 << j) + 1));
}
}
void ae(int u, int v) {
adj[u].push_back(v);
adj[v].push_back(u);
}
void dfs(int src) {
in[src] = ti++;
sparse[0][in[src]] = src;
pos[src] = (int)tmp.size();
tmp.emplace_back(dep[src], src);
for (auto &nxt : adj[src]) {
if (nxt == par[src]) continue;
dep[nxt] = dep[par[nxt] = src] + 1;
dfs(nxt);
tmp.emplace_back(dep[src], src);
}
out[src] = ti;
}
inline int mini(int u, int v) {
return (dep[u] < dep[v] || (dep[u] == dep[v] && in[u] > in[v])) ? u : v;
}
void gen(int root = 0) {
par[root] = root;
dfs(root);
S.init(tmp);
for (int j = 1; j < (int)sparse.size(); j++) {
for (int i = 0; i < (int)sparse[j].size(); i++) {
sparse[j][i] = mini(sparse[j - 1][i], sparse[j - 1][i + (1 << (j - 1))]);
}
}
}
int lca(int u, int v) {
u = pos[u];
v = pos[v];
if (u > v) std::swap(u, v);
return S.query(u, v).second;
}
int dist(int u, int v) {
return dep[u] + dep[v] - 2 * dep[lca(u, v)];
}
bool is_ancestor(int anc, int src) {
return in[anc] <= in[src] && out[anc] >= out[src];
}
int get_child(int anc, int src) {
if (!is_ancestor(anc, src)) return -1;
int l = in[anc] + 1;
int r = in[src];
int d = 31 - __builtin_clz(r - l + 1);
return mini(sparse[d][l], sparse[d][r - (1 << d) + 1]);
}
std::vector<std::pair<int, int>> compress(std::vector<int> nodes) {
auto cmp = [&](int a, int b) {
return pos[a] < pos[b];
};
sort(nodes.begin(), nodes.end(), cmp);
for (int i = (int)nodes.size() - 2; i >= 0; i--) {
nodes.push_back(lca(nodes[i], nodes[i + 1]));
}
sort(nodes.begin(), nodes.end(), cmp);
nodes.erase(unique(nodes.begin(), nodes.end()), nodes.end());
std::vector<std::pair<int, int>> ret{{0, nodes[0]}};
for (int i = 0; i < (int)nodes.size(); i++) {
rev[nodes[i]] = i;
}
for (int i = 1; i < (int)nodes.size(); i++) {
ret.emplace_back(rev[lca(nodes[i - 1], nodes[i])], nodes[i]);
}
return ret;
}
};
// 5 is a root of both mods
template <int MOD, int RT> struct Mint {
static const int mod = MOD;
static constexpr Mint rt() { return RT; } // primitive root for FFT
static constexpr int md() { return MOD; } // primitive root for FFT
int v;
explicit operator int() const { return v; } // explicit -> don't silently convert to int
explicit operator bool() const { return v != 0; }
Mint() { v = 0; }
Mint(long long _v) { v = int((-MOD <= _v && _v < MOD) ? _v : _v % MOD); if (v < 0) v += MOD; }
friend bool operator==(const Mint& a, const Mint& b) { return a.v == b.v; }
friend bool operator!=(const Mint& a, const Mint& b) { return !(a == b); }
friend bool operator<(const Mint& a, const Mint& b) { return a.v < b.v; }
friend bool operator>(const Mint& a, const Mint& b) { return a.v > b.v; }
friend bool operator<=(const Mint& a, const Mint& b) { return a.v <= b.v; }
friend bool operator>=(const Mint& a, const Mint& b) { return a.v >= b.v; }
friend std::istream& operator >> (std::istream& in, Mint& a) {
long long x; std::cin >> x; a = Mint(x); return in; }
friend std::ostream& operator << (std::ostream& os, const Mint& a) { return os << a.v; }
Mint& operator+=(const Mint& m) {
if ((v += m.v) >= MOD) v -= MOD;
return *this; }
Mint& operator-=(const Mint& m) {
if ((v -= m.v) < 0) v += MOD;
return *this; }
Mint& operator*=(const Mint& m) {
v = (long long)v * m.v % MOD; return *this; }
Mint& operator/=(const Mint& m) { return (*this) *= inv(m); }
friend Mint pow(Mint a, long long p) {
Mint ans = 1; assert(p >= 0);
for (; p; p /= 2, a *= a) if (p & 1) ans *= a;
return ans;
}
friend Mint inv(const Mint& a) { assert(a.v != 0); return pow(a, MOD - 2); }
Mint operator-() const { return Mint(-v); }
Mint& operator++() { return *this += 1; }
Mint& operator--() { return *this -= 1; }
friend Mint operator+(Mint a, const Mint& b) { return a += b; }
friend Mint operator-(Mint a, const Mint& b) { return a -= b; }
friend Mint operator*(Mint a, const Mint& b) { return a *= b; }
friend Mint operator/(Mint a, const Mint& b) { return a /= b; }
};
namespace FFT {
template <class T> void fft(std::vector<T>& A, bool inv = 0) {
int n = (int)A.size();
assert((T::mod - 1) % n == 0);
std::vector<T> B(n);
for (int b = n / 2; b; b /= 2, A.swap(B)) {
T w = pow(T::rt(), (T::mod - 1) / n * b);
T m = 1;
for (int i = 0; i < n; i += b * 2, m *= w)
for (int j = 0; j < b; j++) {
T u = A[i + j];
T v = A[i + j + b] * m;
B[i / 2 + j] = u + v;
B[i / 2 + j + n / 2] = u - v;
}
}
if (inv) {
std::reverse(1 + A.begin(), A.end());
T z = T(1) / T(n);
for (auto& t : A)
t *= z;
}
}
template <class T> std::vector<T> multiply(std::vector<T> A, std::vector<T> B) {
int sa = (int)A.size();
int sb = (int)B.size();
if (!std::min(sa, sb))
return {};
int s = sa + sb - 1;
int n = 1;
for (; n < s; n *= 2);
bool eq = A == B;
A.resize(n);
fft(A);
if (eq)
B = A;
else
B.resize(n), fft(B);
for (int i = 0; i < n; i++)
A[i] *= B[i];
fft(A, 1);
A.resize(s);
return A;
}
template <class M, class T> std::vector<M> multiply_mod(std::vector<T> x, std::vector<T> y) {
auto convert = [](const std::vector<T>& v) {
std::vector<M> w((int)v.size());
for (int i = 0; i < (int)v.size(); i++)
w[i] = (int)v[i];
return w;
};
return multiply(convert(x), convert(y));
}
template <class T> std::vector<T> general_multiply(const std::vector<T>& A, const std::vector<T>& B) {
// arbitrary modulus
using m0 = Mint<(119 << 23) + 1, 62>;
using m1 = Mint<(5 << 25) + 1, 62>;
using m2 = Mint<(7 << 26) + 1, 62>;
auto c0 = multiply_mod<m0>(A, B);
auto c1 = multiply_mod<m1>(A, B);
auto c2 = multiply_mod<m2>(A, B);
int n = (int)c0.size();
std::vector<T> res(n);
m1 r01 = 1 / m1(m0::mod);
m2 r02 = 1 / m2(m0::mod);
m2 r12 = 1 / m2(m1::mod);
for (int i = 0; i < n; i++) {
int a = c0[i].v;
int b = ((c1[i] - a) * r01).v;
int c = (((c2[i] - a) * r02 - b) * r12).v;
res[i] = (T(c) * m1::mod + b) * m0::mod + a;
}
return res;
}
} // namespace FFT
namespace Polynomial {
using T = long long;
using Poly = std::vector<T>;
T eval(const Poly& p, const T& x) {
T res = 0;
for (int i = (int)p.size() - 1; i >= 0; --i) {
res = x * res + p[i];
}
return res;
}
Poly& operator+=(Poly& l, const Poly& r) {
l.resize(std::max((int)l.size(), (int)r.size()));
for (int i = 0; i < (int)r.size(); ++i) {
l[i] += r[i];
}
return l;
}
Poly& operator-=(Poly& l, const Poly& r) {
l.resize(std::max((int)l.size(), (int)r.size()));
for (int i = 0; i < (int)r.size(); ++i) {
l[i] -= r[i];
}
return l;
}
Poly& operator*=(Poly& l, const T& r) {
for (int i = 0; i < (int)l.size(); ++i) {
l[i] *= r;
}
return l;
}
Poly& operator/=(Poly& l, const T& r) {
for (int i = 0; i < (int)l.size(); ++i) {
l[i] /= r;
}
return l;
}
Poly operator*(const Poly& l, const Poly& r) {
if (!std::min((int)l.size(), (int)r.size())) {
return {};
}
return FFT::general_multiply(l, r);
Poly res((int)l.size() + (int)r.size() - 1);
for (int i = 0; i < (int)l.size(); ++i) {
for (int j = 0; j < (int)r.size(); ++j) {
res[i + j] += l[i] * r[j];
}
}
return res;
}
Poly operator+(Poly l, const Poly& r) { return l += r; }
Poly operator-(Poly l, const Poly& r) { return l -= r; }
Poly operator-(Poly l) { for (auto &t : l) t *= -1; return l; }
Poly operator*(Poly l, const T& r) { return l *= r; }
Poly operator*(const T& r, const Poly& l) { return l * r; }
Poly operator/(Poly l, const T& r) { return l /= r; }
Poly& operator*=(Poly& l, const Poly& r) { return l = l * r; }
Poly derivative(const Poly& p) {
Poly res;
for (int i = 1; i < (int)p.size(); ++i) {
res.push_back(T(i) * p[i]);
}
return res;
}
Poly integral(const Poly& p) {
static Poly invs{0, 1};
for (int i = invs.size(); i <= (int)p.size(); ++i ){
invs.push_back(1 / T(i));
}
Poly res((int)p.size() + 1);
for (int i = 0; i < (int)p.size(); ++i) {
res[i + 1] = p[i] * invs[i + 1];
}
return res;
}
}
int main() {
using namespace FFT;
using namespace Polynomial;
set_io("");
int n;
re(n);
CentroidDecomposition cd;
cd.init(n);
LCARMQ lca;
lca.init(n);
vector<vi> g(n);
f0r(i, n - 1) {
int u, v;
re(u, v);
g[u].pb(v);
g[v].pb(u);
lca.ae(u, v);
cd.ae(u, v);
}
lca.gen();
cd.build();
vl ans(n);
function<vi(int)> dfs = [&](int u) { // return how many at dist x
vi verts;
vector<vl> polys;
polys.pb({1});
vl tmp;
each(v, cd.cg[u]) {
auto res = dfs(v);
each(x, res) verts.pb(x);
tmp.assign(res.size() + 1, 0);
each(x, res) {
++tmp[lca.dist(x, u)];
}
while (tmp.back() == 0) tmp.pop_back();
polys.pb(tmp);
}
vl sum;
each(x, polys) sum += x;
vl res = sum * sum;
each(x, polys) res -= x * x;
res /= 2;
f0r(i, sz(res)) {
ans[i] += res[i];
}
verts.pb(u);
return verts;
};
dfs(cd.root);
f1r(i, 1, n) {
pr(ans[i], ' ');
}
ps();
return 0;
}