#include #include using namespace std; namespace my{ #define eb emplace_back #define LL(...) ll __VA_ARGS__;lin(__VA_ARGS__) #define jo(a,b) a##b #define FO_IMPL(n,c) for(ll jo(_i,c)=n;jo(_i,c)-->0;) #define FO(n) FO_IMPL(n,__COUNTER__) #define FOR(i,...) for(auto[i,i##stop,i##step]=range(0,__VA_ARGS__);i{}) #define base_operator(op,type) auto operator op(const type&v)const{auto copy=*this;return copy op##=v;} #define entry void solve();void solve2();}int main(){my::io();my::solve();}namespace my{ #define use_ml using ml=atcoder::modint; auto&operator>>(istream&i,atcoder::modint&x){int t;i>>t;x=t;return i;} auto&operator<<(ostream&o,const atcoder::modint&x){return o<<(int)x.val();} auto&operator>>(istream&i,atcoder::modint998244353&x){int t;i>>t;x=t;return i;} auto&operator<<(ostream&o,const atcoder::modint998244353&x){return o<<(int)x.val();} void io(){cin.tie(nullptr)->sync_with_stdio(0);cout<>{a...});} auto min(auto...a){return min(initializer_list>{a...});} auto mod(auto a,auto b){return(a%=b)<0?a+b:a;} templatestruct pair{ A a;B b; pair()=default; pair(A a,B b):a(a),b(b){} pair(const std::pair&p):a(p.first),b(p.second){} auto operator<=>(const pair&)const=default; pair operator+(const pair&p)const{return{a+p.a,b+p.b};} friend istream&operator>>(istream&i,pair&p){return i>>p.a>>p.b;} friend ostream&operator<<(ostream&o,const pair&p){return o<using pack_back_t=tuple_element_t>; templateconcept vectorial=is_base_of_v::value_type>,remove_cvref_t>; templateconstexpr int rank(){if constexpr(vectorial)return rank()+1;else return 0;} templatestruct core_t_helper{using core_t=T;}; templatestruct core_t_helper{using core_t=typename core_t_helper::core_t;}; templateusing core_t=core_t_helper::core_t; templateistream&operator>>(istream&i,vector&v){fe(v,e)i>>e;return i;} templateostream&operator<<(ostream&o,const vector&v){ll n=v.size();fo(i,n)o<ostream&operator<<(ostream&o,const vector&v){ll n=v.size();fo(i,n)o<struct vec; templatestruct hvec_helper{using type=vec::type>;}; templatestruct hvec_helper<0,T>{using type=T;}; templateusing hvec=typename hvec_helper::type; templatestruct vec:vector{ static constexpr int R=rank>(); using C=core_t; using vector::vector; vec(const vector&v){vector::operator=(v);} vec(const auto&...a)requires(sizeof...(a)>=3){resizes(a...);} void resizes(const auto&...a){*this=make(a...);} static auto make(ll n,const auto&...a){ if constexpr(sizeof...(a)==1)return vec(n,array{a...}[0]); else return vec(n,make(a...)); } vec&operator^=(const vec&u){this->insert(this->end(),u.begin(),u.end());return*this;} vec&operator+=(const vec&u){vec&v=*this;assert(v.size()==u.size());fo(i,v.size())v[i]+=u[i];return v;} vec&operator-=(const vec&u){vec&v=*this;assert(v.size()==u.size());fo(i,v.size())v[i]-=u[i];return v;} vec&operator+=(const C&c){fe(*this,e)e+=c;return*this;} vec&operator*=(const C&c){fe(*this,e)e*=c;return*this;} base_operator(^,vec) base_operator(+,vec) base_operator(-,vec) base_operator(+,C); base_operator(*,C); vec&operator++(){fe(*this,e)++e;return*this;} vec&operator--(){fe(*this,e)--e;return*this;} ll size()const{return vector::size();} auto&emplace_back(auto&&...a){vector::emplace_back(std::forward(a)...);return*this;} auto pop_back(){auto r=this->back();vector::pop_back();return r;} auto scan(const auto&f)const{ pairr{}; fe(*this,e)if constexpr(!vectorial)r.b?f(r.a,e),r:r={e,1};else if(auto s=e.scan(f);s.b)r.b?f(r.a,s.a),r:r=s; return r; } auto max()const{return scan([](auto&a,auto b){if(arequires(sizeof...(A)>=2)vec(const A&...a)->vec>>; vec(ll)->vec; void lin(auto&...a){(cin>>...>>a);} auto sin(){string s;lin(s);return s;} void pp(const auto&...a){ll n=sizeof...(a);((cout<0,space)),...);cout<concept modulary=requires(T t){t.mod();}; namespace fft{ using real=double; struct complex{ real x,y; complex()=default; complex(real x,real y):x(x),y(y){} inline complex operator+(const complex &c)const{return complex(x+c.x,y+c.y);} inline complex operator-(const complex &c)const{return complex(x-c.x,y-c.y);} inline complex operator*(const complex &c)const{return complex(x*c.x-y*c.y,x*c.y+y*c.x);} inline complex conj()const{return complex(x,-y);} }; const real PI=acosl(-1); ll base=1; vectorrts={{0,0},{1,0}}; vectorfft_rev={0,1}; void ensure_base(int nbase){ if(nbase<=base)return; fft_rev.resize(1<>1]>>1)+((i&1)<<(nbase-1)); while(base&a,int n){ assert((n&(n-1))==0); int zeros=__builtin_ctz(n); ensure_base(zeros); int shift=base-zeros; fo(i,n)if(i<(fft_rev[i]>>shift))swap(a[i],a[fft_rev[i]>>shift]); for(int k=1;kstruct arbitrary_mod_convolution{ using real=fft::real; using complex=fft::complex; arbitrary_mod_convolution(){} std::vectormultiply(const std::vector&a,const std::vector&b,int need=-1){ if(need==-1)need=a.size()+b.size()-1; int nbase=0; while((1<fa(sz); fo(i,a.size())fa[i]=complex(a[i].val()&((1<<15)-1),a[i].val()>>15); fft::fast_fourier_transform(fa,sz); std::vectorfb(sz); if(a==b){ fb=fa; }else{ fo(i,b.size())fb[i]=complex(b[i].val()&((1<<15)-1),b[i].val()>>15); fft::fast_fourier_transform(fb,sz); } real ratio=0.25/sz; complex r2(0,-1),r3(ratio,0),r4(0,-ratio),r5(0,1); for(int i=0;i<=(sz>>1);i++){ int j=(sz-i)&(sz-1); complex a1=(fa[i]+fa[j].conj()); complex a2=(fa[i]-fa[j].conj())*r2; complex b1=(fb[i]+fb[j].conj())*r3; complex b2=(fb[i]-fb[j].conj())*r4; if(i!=j){ complex c1=(fa[j]+fa[i].conj()); complex c2=(fa[j]-fa[i].conj())*r2; complex d1=(fb[j]+fb[i].conj())*r3; complex d2=(fb[j]-fb[i].conj())*r4; fa[i]=c1*d1+c2*d2*r5; fb[i]=c1*d2+c2*d1; } fa[j]=a1*b1+a2*b2*r5; fb[j]=a1*b2+a2*b1; } fft::fast_fourier_transform(fa,sz); fft::fast_fourier_transform(fb,sz); std::vectorret(need); fo(i,need){ int64_t aa=llround(fa[i].x); int64_t bb=llround(fb[i].x); int64_t cc=llround(fa[i].y); aa=T(aa).val(),bb=T(bb).val(),cc=T(cc).val(); ret[i]=aa+(bb<<15)+(cc<<30); } return ret; } }; templatestruct formal_power_series:vec{ using vec::vec; using fps=formal_power_series; static constexpr ll SPARSE_THRESHOLD=20; static inline arbitrary_mod_convolutionfft; static fps mul(const fps&a,const fps&b){ if constexpr(!modulary)return atcoder::convolution_ll(a,b); else if constexpr(is_same_v)return atcoder::convolution(a,b); else return fft.multiply(a,b); } auto operator<=>(const fps&f)const{return this->size()<=>f.size();} auto&shrink(){while(this->size()>1&&this->back()==T{})this->pop_back();return*this;} fps pre(ll deg)const{fps r(this->begin(),this->begin()+min(this->size(),deg));r.resize(deg);return r;} fps&operator+=(const fps&g){if(g.size()>this->size())this->resize(g.size());fo(i,g.size())(*this)[i]+=g[i];return*this;} fps&operator-=(const fps&g){if(g.size()>this->size())this->resize(g.size());fo(i,g.size())(*this)[i]-=g[i];return*this;} fps&operator*=(const fps&g){return*this=(this->size()&&g.size()?mul(*this,g):fps{});} fps&operator>>=(ll sz){if(this->size()<=sz)return*this=fps{};this->erase(this->begin(),this->begin()+sz);return*this;} fps&operator<<=(ll sz){this->insert(this->begin(),sz,T{});return*this;} fps&operator/=(const fps&g){ ll I1=0,I2=0; while(I1size()&&(*this)[I1]==0)++I1; while(I2=I2); ll L=max(this->size(),g.size()); return*this=((*this>>I2)*(g>>I2).inv(L)).pre(L); } base_operator(+,fps) base_operator(-,fps) base_operator(*,fps) base_operator(/,fps) fps operator-()const{auto r=*this;fe(r,x)x=-x;return r;} fps operator>>(ll sz)const{return fps{*this}>>=sz;} fps operator<<(ll sz)const{return fps{*this}<<=sz;} fps&operator+=(const T&c){if(!this->size())this->resize(1);(*this)[0]+=c;return*this;} fps&operator-=(const T&c){if(!this->size())this->resize(1);(*this)[0]-=c;return*this;} fps&operator*=(const T&c){fo(i,this->size())(*this)[i]*=c;return*this;} fps&operator/=(const T&c){T c_inv=T{1}/c;fo(i,this->size())(*this)[i]*=c_inv;return*this;} base_operator(+,T) base_operator(-,T) base_operator(*,T) base_operator(/,T) T operator()(T x)const{T r=0,xi=1;fe(*this,ai)r+=ai*xi,xi*=x;return r;} fps inv_sparse(ll deg=-1)const{ assert((*this)[0]!=T{}); ll n=this->size(); if(deg==-1)deg=n; vec>p; fo(i,1,n)if((*this)[i]!=T{})p.eb(i,(*this)[i]); fps r(deg); r[0]=T{1}/(*this)[0]; fo(i,1,deg){ T t{}; fe(p,k,fk){ if(i-k<0)break; t-=fk*r[i-k]; } r[i]=r[0]*t; } return r; } ll nonzero_terms_count()const{ll r=0;fe(*this,e)r+=(e!=T{});return r;} fps inv(ll deg=-1)const{ assert((*this)[0]!=T{}); if(deg==-1)deg=this->size(); if(nonzero_terms_count()pre(i<<1)*(r*r)).pre(i<<1); return r.pre(deg); } fps rev()const{fps r{*this};ranges::reverse(r);return r;} static auto polynomial_division(const fps&f,const fps&g){ ll n=f.size()-g.size()+1; fps q=n>0?(f.rev().pre(n)*g.rev().inv(n)).pre(n).rev():fps{}; fps r=(f-g*q).shrink(); return pair{q,r}; } }; templateusing fps=formal_power_series; templateT bostan_mori(ll n,fpsP,fpsQ){ if(P.shrink().size()>=Q.shrink().size()){ auto[q,r]=fps::polynomial_division(P,Q); return(nQsym=Q; fo(i,1,Qsym.size(),2)Qsym[i]=-Qsym[i]; fpsPQ=P*Qsym; fpsQQ=Q*Qsym; bool f=n&1; fo(i,f,PQ.size(),2)P[i>>1]=PQ[i]; fo(i,0,QQ.size(),2)Q[i>>1]=QQ[i]; n>>=1; } return P[0]/Q[0]; } templateT kth_linear_recurrence_relation(ll n,const vec&a,const vec&c){ assert(a.size()==c.size()); fpsQ=(-fps(c)<<1)+1; fpsP=(Q*a).pre(a.size()); return bostan_mori(n,P,Q); } entry void solve(){ LL(N); use_ml ml::set_mod(1000); ml XN=kth_linear_recurrence_relation(N,vec{2,2},vec{2,2}); pp(XN-even(N)); }}