ソースコード

#line 2 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\misc\\nyaanio.hpp"
#include <cstring>
#include <type_traits>
#include <utility>
#include <cstdio>
#include <string>
#include <cstdint>

namespace fastio {
static constexpr int SZ = 1 << 17;
char inbuf[SZ], outbuf[SZ];
int in_left = 0, in_right = 0, out_right = 0;

struct Pre {
    char num[40000];
    constexpr Pre() : num() {
        for (int i = 0; i < 10000; i++) {
        int n = i;
            for (int j = 3; j >= 0; j--) {
                num[i * 4 + j] = n % 10 + '0';
                n /= 10;
            }
        }
    }
} constexpr pre;

inline void load() {
    int len = in_right - in_left;
    memmove(inbuf, inbuf + in_left, len);
    in_right = len + fread(inbuf + len, 1, SZ - len, stdin);
    in_left = 0;
    if(in_right != SZ) inbuf[in_right] = '\000';
}

inline void flush() {
    fwrite(outbuf, 1, out_right, stdout);
    out_right = 0;
}

inline void skip_space() {
    if (in_left + 32 > in_right) load();
    while (inbuf[in_left] <= ' ') in_left++;
}

inline void rd(char& c) {
    if (in_left + 32 > in_right) load();
    c = inbuf[in_left++];
}
template <typename T>
inline void rd(T& x) {
    if (in_left + (int)sizeof(T) * 8 > in_right) load();
    char c;
    do c = inbuf[in_left++];
    while (c < '-');
    [[maybe_unused]] bool minus = false;
    if constexpr (std::is_signed<T>::value == true) {
        if (c == '-') minus = true, c = inbuf[in_left++];
    }
    x = 0;
    while (c >= '0') {
        x = x * 10 + (c & 15);
        c = inbuf[in_left++];
    }
    if constexpr (std::is_signed<T>::value == true) {
        if (minus) x = -x;
    }
}

inline void wt(char c) {
    if (out_right > SZ - 32) flush();
    outbuf[out_right++] = c;
}
inline void wt(bool b) {
    if (out_right > SZ - 32) flush();
    outbuf[out_right++] = b ? '1' : '0';
}
inline void wt(const std::string &s) {
    if (out_right + s.size() > SZ - 32) flush();
    if (s.size() > SZ - 32){ fwrite(s.c_str(), 1, s.size(), stdout); return; }
    memcpy(outbuf + out_right, s.data(), sizeof(char) * s.size());
    out_right += s.size();
}
inline void wt(const char* s) {
    wt(std::string(s));
}
template <typename T>
inline void wt(T x) {
    if (out_right > SZ - (int)sizeof(T) * 8) flush();
    if (!x) {
        outbuf[out_right++] = '0';
        return;
    }
    if constexpr (std::is_signed<T>::value == true) {
        if (x < 0) outbuf[out_right++] = '-', x = -x;
    }
    constexpr int SZT = sizeof(T) * 8;
    int i = SZT - 4;
    char buf[SZT];
    while (x >= 10000) {
        memcpy(buf + i, pre.num + (x % 10000) * 4, 4);
        x /= 10000;
        i -= 4;
    }
    if (x < 100) {
        if (x < 10) {
            outbuf[out_right] = '0' + x;
            ++out_right;
        } else {
            uint32_t q = (uint32_t(x) * 205) >> 11;
            uint32_t r = uint32_t(x) - q * 10;
            outbuf[out_right] = '0' + q;
            outbuf[out_right + 1] = '0' + r;
            out_right += 2;
        }
    } else {
        if (x < 1000) {
            memcpy(outbuf + out_right, pre.num + (x << 2) + 1, 3);
            out_right += 3;
        } else {
            memcpy(outbuf + out_right, pre.num + (x << 2), 4);
            out_right += 4;
        }
    }
    memcpy(outbuf + out_right, buf + i + 4, SZT - 4 - i);
    out_right += SZT - 4 - i;
}

} // namespace fastio

namespace nachia{

struct CInStream{} cin;
template <typename T>
inline CInStream& operator>>(CInStream& c, T& dest){ fastio::rd(dest); return c; }
struct COutStream{
	~COutStream(){ atexit(fastio::flush); }
} cout;
template <typename T>
inline COutStream& operator<<(COutStream& c, const T& src){ fastio::wt(src); return c; }

} // namespace nachia
#line 3 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\array\\csr-array.hpp"
#include <vector>
#include <algorithm>

namespace nachia{

template<class Elem>
class CsrArray{
public:
    struct ListRange{
        using iterator = typename std::vector<Elem>::iterator;
        iterator begi, endi;
        iterator begin() const { return begi; }
        iterator end() const { return endi; }
        int size() const { return (int)std::distance(begi, endi); }
        Elem& operator[](int i) const { return begi[i]; }
    };
    struct ConstListRange{
        using iterator = typename std::vector<Elem>::const_iterator;
        iterator begi, endi;
        iterator begin() const { return begi; }
        iterator end() const { return endi; }
        int size() const { return (int)std::distance(begi, endi); }
        const Elem& operator[](int i) const { return begi[i]; }
    };
private:
    int m_n;
    std::vector<Elem> m_list;
    std::vector<int> m_pos;
public:
    CsrArray() : m_n(0), m_list(), m_pos() {}
    static CsrArray Construct(int n, std::vector<std::pair<int, Elem>> items){
        CsrArray res;
        res.m_n = n;
        std::vector<int> buf(n+1, 0);
        for(auto& [u,v] : items){ ++buf[u]; }
        for(int i=1; i<=n; i++) buf[i] += buf[i-1];
        res.m_list.resize(buf[n]);
        for(int i=(int)items.size()-1; i>=0; i--){
            res.m_list[--buf[items[i].first]] = std::move(items[i].second);
        }
        res.m_pos = std::move(buf);
        return res;
    }
    static CsrArray FromRaw(std::vector<Elem> list, std::vector<int> pos){
        CsrArray res;
        res.m_n = pos.size() - 1;
        res.m_list = std::move(list);
        res.m_pos = std::move(pos);
        return res;
    }
    ListRange operator[](int u) { return ListRange{ m_list.begin() + m_pos[u], m_list.begin() + m_pos[u+1] }; }
    ConstListRange operator[](int u) const { return ConstListRange{ m_list.begin() + m_pos[u], m_list.begin() + m_pos[u+1] }; }
    int size() const { return m_n; }
    int fullSize() const { return (int)m_list.size(); }
};

} // namespace nachia
#line 4 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\graph\\graph.hpp"
#include <cassert>
#line 6 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\graph\\graph.hpp"

namespace nachia{


struct Graph {
public:
    struct Edge{
        int from, to;
        void reverse(){ std::swap(from, to); }
    };
    using Base = std::vector<std::pair<int, int>>;
    Graph(int n = 0, bool undirected = false, int m = 0) : m_n(n), m_e(m), m_isUndir(undirected) {}
    Graph(int n, const std::vector<std::pair<int, int>>& edges, bool undirected = false) : m_n(n), m_isUndir(undirected){
        m_e.resize(edges.size());
        for(std::size_t i=0; i<edges.size(); i++) m_e[i] = { edges[i].first, edges[i].second };
    }
    template<class Cin>
    static Graph Input(Cin& cin, int n, bool undirected, int m, bool offset = 0){
        Graph res(n, undirected, m);
        for(int i=0; i<m; i++){
            int u, v; cin >> u >> v;
            res[i].from = u - offset;
            res[i].to = v - offset;
        }
        return res;
    }
    int numVertices() const noexcept { return m_n; }
    int numEdges() const noexcept { return int(m_e.size()); }
    int addNode() noexcept { return m_n++; }
    int addEdge(int from, int to){ m_e.push_back({ from, to }); return numEdges() - 1; }
    Edge& operator[](int ei) noexcept { return m_e[ei]; }
    const Edge& operator[](int ei) const noexcept { return m_e[ei]; }
    Edge& at(int ei) { return m_e.at(ei); }
    const Edge& at(int ei) const { return m_e.at(ei); }
    auto begin(){ return m_e.begin(); }
    auto end(){ return m_e.end(); }
    auto begin() const { return m_e.begin(); }
    auto end() const { return m_e.end(); }
    bool isUndirected() const noexcept { return m_isUndir; }
    void reverseEdges() noexcept { for(auto& e : m_e) e.reverse(); }
    void contract(int newV, const std::vector<int>& mapping){
        assert(numVertices() == int(mapping.size()));
        for(int i=0; i<numVertices(); i++) assert(0 <= mapping[i] && mapping[i] < newV);
        for(auto& e : m_e){ e.from = mapping[e.from]; e.to = mapping[e.to]; }
        m_n = newV;
    }
    std::vector<Graph> induce(int num, const std::vector<int>& mapping) const {
        int n = numVertices();
        assert(n == int(mapping.size()));
        for(int i=0; i<n; i++) assert(-1 <= mapping[i] && mapping[i] < num);
        std::vector<int> indexV(n), newV(num);
        for(int i=0; i<n; i++) if(mapping[i] >= 0) indexV[i] = newV[mapping[i]]++;
        std::vector<Graph> res; res.reserve(num);
        for(int i=0; i<num; i++) res.emplace_back(newV[i], isUndirected());
        for(auto e : m_e) if(mapping[e.from] == mapping[e.to] && mapping[e.to] >= 0) res[mapping[e.to]].addEdge(indexV[e.from], indexV[e.to]);
        return res;
    }
    CsrArray<int> getEdgeIndexArray(bool undirected) const {
        std::vector<std::pair<int, int>> src;
        src.reserve(numEdges() * (undirected ? 2 : 1));
        for(int i=0; i<numEdges(); i++){
            auto e = operator[](i);
            src.emplace_back(e.from, i);
            if(undirected) src.emplace_back(e.to, i);
        }
        return CsrArray<int>::Construct(numVertices(), src);
    }
    CsrArray<int> getEdgeIndexArray() const { return getEdgeIndexArray(isUndirected()); }
    CsrArray<int> getAdjacencyArray(bool undirected) const {
        std::vector<std::pair<int, int>> src;
        src.reserve(numEdges() * (undirected ? 2 : 1));
        for(auto e : m_e){
            src.emplace_back(e.from, e.to);
            if(undirected) src.emplace_back(e.to, e.from);
        }
        return CsrArray<int>::Construct(numVertices(), src);
    }
    CsrArray<int> getAdjacencyArray() const { return getAdjacencyArray(isUndirected()); }
private:
    int m_n;
    std::vector<Edge> m_e;
    bool m_isUndir;
};

} // namespace nachia
#line 6 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\tree\\heavy-light-decomposition.hpp"

namespace nachia{

struct HeavyLightDecomposition{
private:

    int N;
    std::vector<int> P;
    std::vector<int> PP;
    std::vector<int> PD;
    std::vector<int> D;
    std::vector<int> I;

    std::vector<int> rangeL;
    std::vector<int> rangeR;

public:

    HeavyLightDecomposition(const CsrArray<int>& E = CsrArray<int>::Construct(1, {}), int root = 0){
        N = E.size();
        P.assign(N, -1);
        I = {root};
        I.reserve(N);
        for(int i=0; i<(int)I.size(); i++){
            int p = I[i];
            for(int e : E[p]) if(P[p] != e){
                I.push_back(e);
                P[e] = p;
            }
        }
        std::vector<int> Z(N, 1);
        std::vector<int> nx(N, -1);
        PP.resize(N);
        for(int i=0; i<N; i++) PP[i] = i;
        for(int i=N-1; i>=1; i--){
            int p = I[i];
            Z[P[p]] += Z[p];
            if(nx[P[p]] == -1) nx[P[p]] = p;
            if(Z[nx[P[p]]] < Z[p]) nx[P[p]] = p;
        }

        for(int p : I) if(nx[p] != -1) PP[nx[p]] = p;

        PD.assign(N,N);
        PD[root] = 0;
        D.assign(N,0);
        for(int p : I) if(p != root){
            PP[p] = PP[PP[p]];
            PD[p] = std::min(PD[PP[p]], PD[P[p]]+1);
            D[p] = D[P[p]]+1;
        }
        
        rangeL.assign(N,0);
        rangeR.assign(N,0);
        
        for(int p : I){
            rangeR[p] = rangeL[p] + Z[p];
            int ir = rangeR[p];
            for(int e : E[p]) if(P[p] != e) if(e != nx[p]){
                rangeL[e] = (ir -= Z[e]);
            }
            if(nx[p] != -1){
                rangeL[nx[p]] = rangeL[p] + 1;
            }
        }

        I.resize(N);
        for(int i=0; i<N; i++) I[rangeL[i]] = i;
    }
    
    HeavyLightDecomposition(const Graph& tree, int root = 0)
        : HeavyLightDecomposition(tree.getAdjacencyArray(true), root) {}

    int numVertices() const { return N; }
    int depth(int p) const { return D[p]; }
    int toSeq(int vertex) const { return rangeL[vertex]; }
    int toVtx(int seqidx) const { return I[seqidx]; }
    int toSeq2In(int vertex) const { return rangeL[vertex] * 2 - D[vertex]; }
    int toSeq2Out(int vertex) const { return rangeR[vertex] * 2 - D[vertex] - 1; }
    int parentOf(int v) const { return P[v]; }
    int heavyRootOf(int v) const { return PP[v]; }
    int heavyChildOf(int v) const {
        if(toSeq(v) == N-1) return -1;
        int cand = toVtx(toSeq(v) + 1);
        if(PP[v] == PP[cand]) return cand;
        return -1;
    }

    int lca(int u, int v) const {
        if(PD[u] < PD[v]) std::swap(u, v);
        while(PD[u] > PD[v]) u = P[PP[u]];
        while(PP[u] != PP[v]){ u = P[PP[u]]; v = P[PP[v]]; }
        return (D[u] > D[v]) ? v : u;
    }

    int dist(int u, int v) const {
        return depth(u) + depth(v) - depth(lca(u,v)) * 2;
    }

    std::vector<std::pair<int,int>> path(int r, int c, bool include_root = true, bool reverse_path = false) const {
        if(PD[c] < PD[r]) return {};
        std::vector<std::pair<int,int>> res(PD[c]-PD[r]+1);
        for(int i=0; i<(int)res.size()-1; i++){
            res[i] = std::make_pair(rangeL[PP[c]], rangeL[c]+1);
            c = P[PP[c]];
        }
        if(PP[r] != PP[c] || D[r] > D[c]) return {};
        res.back() = std::make_pair(rangeL[r]+(include_root?0:1), rangeL[c]+1);
        if(res.back().first == res.back().second) res.pop_back();
        if(!reverse_path) std::reverse(res.begin(),res.end());
        else for(auto& a : res) a = std::make_pair(N - a.second, N - a.first);
        return res;
    }

    std::pair<int,int> subtree(int p){
        return std::make_pair(rangeL[p], rangeR[p]);
    }

    int median(int x, int y, int z) const {
        return lca(x,y) ^ lca(y,z) ^ lca(x,z);
    }

    int la(int from, int to, int d) const {
        if(d < 0) return -1;
        int g = lca(from,to);
        int dist0 = D[from] - D[g] * 2 + D[to];
        if(dist0 < d) return -1;
        int p = from;
        if(D[from] - D[g] < d){ p = to; d = dist0 - d; }
        while(D[p] - D[PP[p]] < d){
            d -= D[p] - D[PP[p]] + 1;
            p = P[PP[p]];
        }
        return I[rangeL[p] - d];
    }
};

} // namespace nachia
#line 1 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\array\\dual-segment-tree.hpp"

#line 3 "D:\\Programming\\VSCode\\competitive-cpp\\nachia\\array\\dual-segment-tree.hpp"

namespace nachia{

template<
    class F,
    F composition(F f, F x)
>
struct DualSegtree {

    struct Node { F f; bool propagated; };
    int N;
    int logN;
    std::vector<Node> A;

    void mapf(Node& a, F f) {
        a.propagated = false;
        a.f = composition(f, a.f);
    }
    void spread(int i) {
        if(A[i].propagated || !(i < N)) return;
        mapf(A[i*2], A[i].f);
        mapf(A[i*2+1], A[i].f);
        A[i] = A[0];
    }

    DualSegtree(int n, F id) {
        N=1; logN=0;
        while(N<n){ N *= 2; logN++; }
        A.assign(N*2, { id, true });
    }
    DualSegtree(const std::vector<F>& a) : DualSegtree(a.size()) {
        for(int i=0; i<a.size(); i++){ A[i+N].f = a[i]; A[i+N].propagated = false; }
    }

    void clear(int p) {
        p += N;
        for(int d=logN; d; d--) spread(p >> d);
        A[p] = A[0];
    }
    F get(int p){
        p += N;
        for(int d=logN; d; d--) spread(p >> d);
        return A[p].f;
    }
    void apply(int l, int r, F f){
        if(!(l < r)) return;
        if(l == 0 && r == N){ mapf(A[1], f); return; }
        l += N; r += N;
        for(int d=logN; d; d--){
            if((l >> d) << d != l) spread(l >> d);
            if((r >> d) << d != r) spread(r >> d);
        }
        while(l < r){
            if(l&1){ mapf(A[l++], f); } l /= 2;
            if(r&1){ mapf(A[--r], f); } r /= 2;
        }
    }
    void apply(int p, F f){
        p += N;
        for(int d=logN; d; d--) spread(p >> d);
        mapf(A[p], f);
    }
};

} // namespace nachia;
#line 6 "..\\Main.cpp"
#include <atcoder/modint>
using namespace std;
using i32 = int;
using u32 = unsigned int;
using i64 = long long;
using u64 = unsigned long long;
#define rep(i,n) for(int i=0; i<(int)(n); i++)
const i64 INF = 1001001001001001001;

using Modint = atcoder::static_modint<998244353>;

struct Affine {
    Modint c, d;
    static Affine Construct(int c, int d){ return Affine{ Modint::raw(c), Modint::raw(d) }; }
    Modint eval(Modint x) const { return c*x+d; }
};
Affine f1(Affine a, Affine b){
    Affine res;
    res.c = a.c * b.c;
    res.d = a.c * b.d + a.d;
    return res;
}

int main(){
    using nachia::cin;
    using nachia::cout;
    int N, Q; cin >> N >> Q;
    auto tree = nachia::Graph::Input(cin, N, true, N-1, 1);
    auto hld = nachia::HeavyLightDecomposition(tree);
    tree = nachia::Graph(N, false);
    rep(i,N) if(hld.parentOf(i) >= 0) tree.addEdge(hld.parentOf(i), i);
    auto adj = tree.getAdjacencyArray();
    vector<int> seqL(N), seqR(N), pos(N);
    seqL[0] = 1; seqR[0] = N;
    rep(i,N-1){
        int pre = hld.toVtx(i);
        int v = hld.toVtx(i+1);
        seqL[v] = seqL[pre] + adj[pre].size();
        seqR[v] = seqL[v] + hld.subtree(v).second - hld.subtree(v).first - 1;
    }
    rep(v,N) rep(e,adj[v].size()) pos[adj[v][e]] = seqL[v] + e;
    vector<Modint> X(N);
    rep(i,N){ int x; cin >> x; X[i] = Modint::raw(x); }
    nachia::DualSegtree<Affine, f1> rq(N, Affine::Construct(1,0));
    nachia::DualSegtree<Affine, f1> rqh(N, Affine::Construct(1,0));
    auto applyVtx = [&](int v, Affine f){
        if(hld.heavyRootOf(v) == v){
            rq.apply(pos[v], f);
        }
        else{
            rqh.apply(hld.toSeq(v), f);
        }
    };
    auto applyPath = [&](int r, int c, Affine f){
        for(auto [a, b] : hld.path(r, c)){
            int av = hld.toVtx(a);
            if(hld.heavyRootOf(av) == av){
                applyVtx(av, f);
                a++;
            }
            rqh.apply(a, b, f);
        }
    };
    rep(i,Q){
        int t; cin >> t;
        if(t == 1){
            int v; cin >> v; v--;
            Affine f = (hld.heavyRootOf(v) == v ? rq.get(pos[v]) : rqh.get(hld.toSeq(v)));
            cout << f.eval(X[v]).val() << '\n';
        }
        if(t == 2){
            int v, k, c, d; cin >> v >> k >> c >> d; v--;
            Affine af = Affine::Construct(c, d);
            rq.apply(seqL[v], seqL[v] + adj[v].size(), af);
            applyVtx(v, af);
            if(hld.parentOf(v) >= 0) applyVtx(hld.parentOf(v), af);
            if(hld.heavyChildOf(v) >= 0) applyVtx(hld.heavyChildOf(v), af);
        }
        if(t == 3){
            int v, c, d; cin >> v >> c >> d; v--;
            Affine af = Affine::Construct(c, d);
            applyVtx(v, af);
            auto st = hld.subtree(v);
            rqh.apply(st.first + 1, st.second, af);
            rq.apply(seqL[v], seqR[v], af);
        }
        if(t == 4){
            int u, v, c, d; cin >> u >> v >> c >> d; u--; v--;
            Affine af = Affine::Construct(c, d);
            int h = hld.lca(u, v);
            applyPath(h, u, af);
            if(h != v) applyPath(hld.la(h, v, 1), v, af);
        }
    }
    return 0;
}