QOJ.ac
QOJ
| ID | Problem | Submitter | Result | Time | Memory | Language | File size | Submit time | Judge time |
|---|---|---|---|---|---|---|---|---|---|
| #50479 | #2. Boat | xiaoyaowudi | 0 | 0ms | 0kb | C++17 | 48.5kb | 2022-09-26 14:58:47 | 2022-09-26 14:58:50 |
Judging History
answer
#define __AVX__ 1
#define __AVX2__ 1
#pragma GCC target("avx,avx2")
#include <iostream>
#include <immintrin.h>
#include <cstdint>
#include <memory>
#include <new>
#include <vector>
#include <array>
#include <exception>
#include <cstring>
#include <algorithm>
namespace library
{
typedef std::uint32_t ui;
typedef std::int32_t i32;
typedef std::int64_t ll;
typedef std::uint64_t ull;
typedef __uint128_t u128;
typedef __int128 i128;
constexpr ui default_mod=998244353;
struct fast_mod_32 {
ull b, m;
fast_mod_32(ull b) : b(b), m(ull((u128(1) << 64) / b)) {}
fast_mod_32(){}
fast_mod_32(const fast_mod_32 &d):b(d.b),m(d.m){}
ull reduce(ull a) {
ull q = (ull)((u128(m) * a) >> 64);
ull r = a - q * b;
return r >= b ? r - b : r;
}
};
fast_mod_32 global_fast_mod_32(default_mod);
struct montgomery_mi_lib{
constexpr static ui calc_k(ui MOD,ui len){ui ans=1;for(ui i=1;i<len;++i) ans=(ans*(MOD+1)+1);return ans;}
ui P,P2,NP,Pk;static constexpr ui ui_len = sizeof(ui)*8;
montgomery_mi_lib(ui P0):P(P0),P2(P0*2),NP((-ull(P0))%P0),Pk(calc_k(P0,ui_len)){}
montgomery_mi_lib(){}
#define INLINE_OP __attribute__((__always_inline__))
INLINE_OP ui redd(ui k) const {return k>=P2?k-P2:k;}INLINE_OP ui reds(ui k) const {return k>=P?k-P:k;}INLINE_OP ui redu(ull k) const {return (k+ull(ui(k)*Pk)*P)>>ui_len;}
INLINE_OP ui add(ui a,ui b) const {return redd(a+b);}INLINE_OP ui sub(ui a,ui b) const {return redd(a-b+P2);}INLINE_OP ui mul(ui a,ui b) const {return redu(ull(a)*b);}
INLINE_OP ui neg(ui a) const {return redd(P2-a);}INLINE_OP ui v(ui a) const {return redu(ull(a)*NP);}INLINE_OP ui rv(ui a) const {return reds(redu(a));}
#undef INLINE_OP
};
struct montgomery_mi{
static montgomery_mi_lib mlib;
ui val;
void init(ui a){val=mlib.redu(ull(a)*mlib.NP);}
montgomery_mi(){val=0;} montgomery_mi(const montgomery_mi &a):val(a.val){} montgomery_mi(ui v):val(mlib.redu(ull(v)*mlib.NP)){}
montgomery_mi& operator=(const montgomery_mi &b) {val=b.val;return *this;}
montgomery_mi& operator+=(const montgomery_mi &b) {val=mlib.redd(val+b.val);return *this;}
montgomery_mi& operator-=(const montgomery_mi &b) {val=mlib.redd(val-b.val+mlib.P2);return *this;}
montgomery_mi operator+(const montgomery_mi &b) const {return montgomery_mi(*this)+=b;}
montgomery_mi operator-(const montgomery_mi &b) const {return montgomery_mi(*this)-=b;}
montgomery_mi operator*=(const montgomery_mi &b) {val=mlib.redu(ull(val)*b.val);return *this;}
montgomery_mi operator*(const montgomery_mi &b) const {return montgomery_mi(*this)*=b;}
montgomery_mi operator-() const {montgomery_mi b;return b-=(*this);}
ui real_val() const {return mlib.reds(mlib.redu(val));}
ui get_val() const {return val;}
friend std::istream& operator>>(std::istream &in, montgomery_mi &m_int){ui inp;in>>inp;m_int.init(inp);return in;}
friend std::ostream& operator<<(std::ostream &out, const montgomery_mi &m_int){out<<m_int.real_val();return out;}
};
static __attribute__((__always_inline__)) inline montgomery_mi ui2mi(ui k){
union ui2mi_impl
{
ui uval;
montgomery_mi mval;
ui2mi_impl(){}
}T;
T.uval=k;
return T.mval;
}
typedef montgomery_mi mi;
typedef montgomery_mi_lib lmi;
#if defined(__AVX__) && defined(__AVX2__)
struct montgomery_mm256_lib{
alignas(32) __m256i P,P2,NP,Pk;static constexpr ui ui_len=sizeof(ui)*8;
montgomery_mm256_lib(ui P0){P=_mm256_set1_epi32(P0),P2=_mm256_set1_epi32(P0*2),
NP=_mm256_set1_epi32(ui((-ull(P0))%P0)),Pk=_mm256_set1_epi32(montgomery_mi_lib::calc_k(P0,ui_len));}
montgomery_mm256_lib(){}
#define INLINE_OP __attribute__((__always_inline__))
INLINE_OP __m256i redd(__m256i k){__m256i a=_mm256_sub_epi32(k,P2);__m256i b=_mm256_and_si256(_mm256_cmpgt_epi32(_mm256_setzero_si256(),a),P2);return _mm256_add_epi32(a,b);}
INLINE_OP __m256i reds(__m256i k){__m256i a=_mm256_sub_epi32(k,P); __m256i b=_mm256_and_si256(_mm256_cmpgt_epi32(_mm256_setzero_si256(),a),P); return _mm256_add_epi32(a,b);}
INLINE_OP __m256i redu(__m256i k){return _mm256_srli_epi64(_mm256_add_epi64(_mm256_mul_epu32(_mm256_mul_epu32(k,Pk),P),k),32);}
INLINE_OP __m256i mul(__m256i k1,__m256i k2){
return _mm256_or_si256(redu(_mm256_mul_epu32(k1,k2)),_mm256_slli_epi64(redu(_mm256_mul_epu32(_mm256_srli_epi64(k1,32),_mm256_srli_epi64(k2,32))),32));}
INLINE_OP __m256i add(__m256i k1,__m256i k2){return redd(_mm256_add_epi32(k1,k2));}
INLINE_OP __m256i sub(__m256i k1,__m256i k2){return redd(_mm256_add_epi32(P2,_mm256_sub_epi32(k1,k2)));}
#undef INLINE_OP
};
struct montgomery_mm256_int{
static montgomery_mm256_lib mlib;
__m256i val;
void init(__m256i a){val=mlib.mul(a,mlib.NP);}
montgomery_mm256_int(){val=_mm256_setzero_si256();} montgomery_mm256_int(const montgomery_mm256_int &a):val(a.val){} montgomery_mm256_int(__m256i v):val(mlib.mul(v,mlib.NP)){}
montgomery_mm256_int(ui v){init(_mm256_set1_epi32(v));}
montgomery_mm256_int& operator=(const montgomery_mm256_int &b) {val=b.val;return *this;}
montgomery_mm256_int& operator+=(const montgomery_mm256_int &b) {val=mlib.add(val,b.val);return *this;}
montgomery_mm256_int& operator-=(const montgomery_mm256_int &b) {val=mlib.sub(val,b.val);return *this;}
montgomery_mm256_int operator+(const montgomery_mm256_int &b) const {return montgomery_mm256_int(*this)+=b;}
montgomery_mm256_int operator-(const montgomery_mm256_int &b) const {return montgomery_mm256_int(*this)-=b;}
montgomery_mm256_int operator*=(const montgomery_mm256_int &b) {val=mlib.mul(val,b.val);return *this;}
montgomery_mm256_int operator*(const montgomery_mm256_int &b) const {return montgomery_mm256_int(*this)*=b;}
montgomery_mm256_int operator-() const {montgomery_mm256_int b;return b-=(*this);}
__m256i real_val() const {return mlib.reds(_mm256_or_si256(_mm256_slli_epi64(mlib.redu(_mm256_srli_epi64(val,32)),32),
mlib.redu(_mm256_srli_epi64(_mm256_slli_epi64(val,32),32))));}
__m256i get_val() const {return val;}
};
typedef montgomery_mm256_int mai;
typedef montgomery_mm256_lib lma;
#endif
#if defined(__AVX512F__) && defined(__AVX512DQ__)
struct montgomery_mm512_lib{
alignas(64) __m512i P,P2,NP,Pk;static constexpr ui ui_len=sizeof(ui)*8;
montgomery_mm512_lib(ui P0){P=_mm512_set1_epi32(P0),P2=_mm512_set1_epi32(P0*2),
NP=_mm512_set1_epi32(ui((-ull(P0))%P0)),Pk=_mm512_set1_epi32(montgomery_mi_lib::calc_k(P0,ui_len));}
montgomery_mm512_lib(){}
#define INLINE_OP __attribute__((__always_inline__))
INLINE_OP __m512i redd(__m512i k){__m512i a=_mm512_sub_epi32(k,P2);return _mm512_mask_add_epi32(a,_mm512_movepi32_mask(a),a,P2);}
INLINE_OP __m512i reds(__m512i k){__m512i a=_mm512_sub_epi32(k,P);return _mm512_mask_add_epi32(a,_mm512_movepi32_mask(a),a,P);}
INLINE_OP __m512i redu(__m512i k){return _mm512_srli_epi64(_mm512_add_epi64(_mm512_mul_epu32(_mm512_mul_epu32(k,Pk),P),k),32);}
INLINE_OP __m512i mul(__m512i k1,__m512i k2){
return _mm512_or_si512(redu(_mm512_mul_epu32(k1,k2)),_mm512_slli_epi64(redu(_mm512_mul_epu32(_mm512_srli_epi64(k1,32),_mm512_srli_epi64(k2,32))),32));}
INLINE_OP __m512i add(__m512i k1,__m512i k2){return redd(_mm512_add_epi32(k1,k2));}
INLINE_OP __m512i sub(__m512i k1,__m512i k2){return redd(_mm512_add_epi32(P2,_mm512_sub_epi32(k1,k2)));}
#undef INLINE_OP
};
struct montgomery_mm512_int{
static montgomery_mm512_lib mlib;
__m512i val;
void init(__m512i a){val=mlib.mul(a,mlib.NP);}
montgomery_mm512_int(){val=_mm512_setzero_si512();} montgomery_mm512_int(const montgomery_mm512_int &a):val(a.val){} montgomery_mm512_int(__m512i v):val(mlib.mul(v,mlib.NP)){}
montgomery_mm512_int(ui v){init(_mm512_set1_epi32(v));}
montgomery_mm512_int& operator=(const montgomery_mm512_int &b) {val=b.val;return *this;}
montgomery_mm512_int& operator+=(const montgomery_mm512_int &b) {val=mlib.add(val,b.val);return *this;}
montgomery_mm512_int& operator-=(const montgomery_mm512_int &b) {val=mlib.sub(val,b.val);return *this;}
montgomery_mm512_int operator+(const montgomery_mm512_int &b) const {return montgomery_mm512_int(*this)+=b;}
montgomery_mm512_int operator-(const montgomery_mm512_int &b) const {return montgomery_mm512_int(*this)-=b;}
montgomery_mm512_int operator*=(const montgomery_mm512_int &b) {val=mlib.mul(val,b.val);return *this;}
montgomery_mm512_int operator*(const montgomery_mm512_int &b) const {return montgomery_mm512_int(*this)*=b;}
montgomery_mm512_int operator-() const {montgomery_mm512_int b;return b-=(*this);}
__m512i real_val() const {return mlib.reds(_mm512_or_si512(_mm512_slli_epi64(mlib.redu(_mm512_srli_epi64(val,32)),32),
mlib.redu(_mm512_srli_epi64(_mm512_slli_epi64(val,32),32))));}
__m512i get_val() const {return val;}
};
typedef montgomery_mm512_int m5i;
typedef montgomery_mm512_lib lm5;
#endif
ui global_mod_mi=default_mod;
void set_mod_mi(ui p);
#if defined(__AVX__) && defined(__AVX2__)
ui global_mod_mai=default_mod;
void set_mod_mai(ui p);
#endif
#if defined(__AVX512F__) && defined(__AVX512DQ__)
ui global_mod_m5i=default_mod;
void set_mod_m5i(ui p);
#endif
montgomery_mi_lib mi::mlib(default_mod);
void set_mod_mi(ui p){
mi::mlib=montgomery_mi_lib(p);
global_fast_mod_32=fast_mod_32(p);
global_mod_mi=p;
}
#if defined(__AVX__) && defined(__AVX2__)
montgomery_mm256_lib mai::mlib(default_mod);
void set_mod_mai(ui p){
mai::mlib=montgomery_mm256_lib(p);
global_mod_mai=p;
}
#endif
#if defined(__AVX512F__) && defined(__AVX512DQ__)
montgomery_mm512_lib m5i::mlib(default_mod);
void set_mod_m5i(ui p){
m5i::mlib=montgomery_mm512_lib(p);
global_mod_m5i=p;
}
#endif
template<typename T,size_t align_val>
struct aligned_delete {
void operator()(T* ptr) const {
operator delete[](ptr,std::align_val_t(align_val));
}
};
template<typename T,size_t align_val>
using aligned_array=std::unique_ptr<T[],aligned_delete<T,align_val>>;
template<typename T,size_t align_val>
aligned_array<T,align_val> create_aligned_array(size_t size){
return aligned_array<T,align_val>(new(std::align_val_t(align_val)) T[size]);
}
#define restrict __restrict
#define NTT_partition_size 10
typedef std::vector<mi> poly;
class polynomial_kernel_ntt
{
private:
static constexpr ui tmp_size=9;
aligned_array<ui,64> ws0,ws1,_inv,tt[tmp_size],num;ui P,G;
ui fn,fb,mx;
void release(){
ws0.reset();ws1.reset();
_inv.reset();num.reset();
fn=fb=mx=0;
for(ui i=0;i<tmp_size;++i) tt[i].reset();
}
ui _fastpow(ui a,ui b){ui ans=li.v(1),off=a;while(b){if(b&1) ans=li.mul(ans,off);off=li.mul(off,off);b>>=1;}return ans;}
void dif(ui* restrict p,ui n){
ui len=(1<<n);
ui* restrict ws=ws0.get();
if(len<8){
ui t1,t2;
for(ui l=len;l>=2;l>>=1) for(ui j=0,mid=(l>>1);j<len;j+=l){
ui restrict *p1=p+j,*p2=p+j+mid,*ww=ws+mid;
for(ui i=0;i<mid;++i,++p1,++p2,++ww) t1=*p1,t2=*p2,*p1=li.add(t1,t2),*p2=li.mul(li.sub(t1,t2),(*ww));
}
}else if(len<=(1<<NTT_partition_size)){
__m256i* pp=(__m256i*)p,*p1,*p2,*ww;
__m256i msk,val;
for(ui l=len;l>8;l>>=1){
ui mid=(l>>1);
for(ui j=0;j<len;j+=l){
p1=(__m256i*)(p+j),p2=(__m256i*)(p+j+mid),ww=(__m256i*)(ws+mid);
for(ui i=0;i<mid;i+=8,++p1,++p2,++ww){
__m256i x=*p1,y=*p2;
*p1=la.add(x,y);
*p2=la.mul(la.sub(x,y),*ww);
}
}
}
val=_mm256_setr_epi32(ws[4],ws[4],ws[4],ws[4],
ws[4],ws[5],ws[6],ws[7]);
msk=_mm256_setr_epi32(0,0,0,0,P*2,P*2,P*2,P*2);
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_permute4x64_epi64(*pp,0x4E);
__m256i y=_mm256_add_epi32(_mm256_sign_epi32(*pp,_mm256_setr_epi32(1,1,1,1,-1,-1,-1,-1)),msk);
*pp=la.mul(la.add(x,y),val);
}
val=_mm256_setr_epi32(ws[2],ws[2],ws[2],ws[3],
ws[2],ws[2],ws[2],ws[3]);
msk=_mm256_setr_epi32(0,0,P*2,P*2,0,0,P*2,P*2);
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_shuffle_epi32(*pp,0x4E);
__m256i y=_mm256_add_epi32(_mm256_sign_epi32(*pp,_mm256_setr_epi32(1,1,-1,-1,1,1,-1,-1)),msk);
*pp=la.mul(la.add(x,y),val);
}
msk=_mm256_setr_epi32(0,P*2,0,P*2,0,P*2,0,P*2);
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_shuffle_epi32(*pp,0xB1);
__m256i y=_mm256_add_epi32(_mm256_sign_epi32(*pp,_mm256_setr_epi32(1,-1,1,-1,1,-1,1,-1)),msk);
*pp=la.add(x,y);
}
}
else{
__m256i *p1=(__m256i*)(p),*p2=(__m256i*)(p+(len>>2)),*p3=(__m256i*)(p+(len>>1)),*p4=(__m256i*)(p+(len>>2)*3),*w1=(__m256i*)(ws0.get()+(len>>1)),
*w2=(__m256i*)(ws0.get()+(len>>1)+(len>>2)),*w3=(__m256i*)(ws0.get()+(len>>2));
for(ui i=0;i<(len>>2);i+=8,++p1,++p2,++p3,++p4,++w2,++w3,++w1){
__m256i x=(*(p1)),y=(*(p2)),z=(*(p3)),w=(*(p4));
__m256i r=la.add(x,z),s=la.mul(la.sub(x,z),*w1);
__m256i t=la.add(y,w),q=la.mul(la.sub(y,w),*w2);
(*(p1))=la.add(r,t);(*(p2))=la.mul(la.sub(r,t),*w3);
(*(p3))=la.add(s,q);(*(p4))=la.mul(la.sub(s,q),*w3);
}
dif(p,n-2);dif(p+(1<<(n-2)),n-2);dif(p+(1<<(n-1)),n-2);dif(p+(1<<(n-2))*3,n-2);
}
}
void dit(ui* restrict p,ui n,bool inverse_coef=true){
ui len=(1<<n);
ui* restrict ws=ws1.get();
if(len<8){
ui t1,t2;
for(ui l=2;l<=len;l<<=1) for(ui j=0,mid=(l>>1);j<len;j+=l){
ui restrict *p1=p+j,*p2=p+j+mid,*ww=ws+mid;
for(ui i=0;i<mid;++i,++p1,++p2,++ww) t1=*p1,t2=li.mul((*p2),(*ww)),*p1=li.add(t1,t2),*p2=li.sub(t1,t2);
}
ui co=_inv[len-1];ui* restrict p1=p;
for(ui i=0;i<len;++i,++p1) (*p1)=li.mul(co,(*p1));
}else if(len<=(1<<NTT_partition_size)){
__m256i* pp=(__m256i*)p,*p1,*p2,*ww;
__m256i msk,val;
msk=_mm256_setr_epi32(0,P*2,0,P*2,0,P*2,0,P*2);
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_shuffle_epi32(*pp,0xB1);
__m256i y=_mm256_add_epi32(_mm256_sign_epi32(*pp,_mm256_setr_epi32(1,-1,1,-1,1,-1,1,-1)),msk);
*pp=la.add(x,y);
}
val=_mm256_setr_epi32(ws[2],ws[3],li.neg(ws[2]),li.neg(ws[3]),
ws[2],ws[3],li.neg(ws[2]),li.neg(ws[3]));
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_shuffle_epi32(*pp,0x44);
__m256i y=_mm256_shuffle_epi32(*pp,0xEE);
*pp=la.add(x,la.mul(y,val));
}
val=_mm256_setr_epi32( ws[4], ws[5], ws[6], ws[7],
li.neg(ws[4]),li.neg(ws[5]),li.neg(ws[6]),li.neg(ws[7]));
pp=(__m256i*)p;
for(ui j=0;j<len;j+=8,++pp){
__m256i x=_mm256_permute4x64_epi64(*pp,0x44);
__m256i y=_mm256_permute4x64_epi64(*pp,0xEE);
*pp=la.add(x,la.mul(y,val));
}
for(ui l=16;l<=len;l<<=1){
ui mid=(l>>1);
for(ui j=0;j<len;j+=l){
p1=(__m256i*)(p+j),p2=(__m256i*)(p+j+mid),ww=(__m256i*)(ws+mid);
for(ui i=0;i<mid;i+=8,++p1,++p2,++ww){
__m256i x=*p1,y=la.mul(*p2,*ww);
*p1=la.add(x,y);
*p2=la.sub(x,y);
}
}
}
if(inverse_coef){
__m256i co=_mm256_set1_epi32(_inv[len-1]);
pp=(__m256i*)p;
for(ui i=0;i<len;i+=8,++pp) (*pp)=la.mul(*pp,co);
}
}
else{
dit(p,n-2,false);dit(p+(1<<(n-2)),n-2,false);dit(p+(1<<(n-1)),n-2,false);dit(p+(1<<(n-2))*3,n-2,false);
__m256i *p1=(__m256i*)(p),*p2=(__m256i*)(p+(len>>2)),*p3=(__m256i*)(p+(len>>1)),*p4=(__m256i*)(p+(len>>2)*3),*w1=(__m256i*)(ws+(len>>1)),
*w2=(__m256i*)(ws+(len>>1)+(len>>2)),*w3=(__m256i*)(ws+(len>>2));
for(ui i=0;i<(len>>2);i+=8,++p1,++p2,++p3,++p4,++w2,++w3,++w1){
__m256i x=(*(p1)),y=(*(p2)),z=(*(p3)),w=(*(p4));
__m256i h=la.mul(y,*w3),
k=la.mul(w,*w3);
__m256i t=la.mul(la.add(z,k),*w1),q=la.mul(la.sub(z,k),*w2);
__m256i r=la.add(x,h),s=la.sub(x,h);
(*(p1))=la.add(r,t);(*(p2))=la.add(s,q);
(*(p3))=la.sub(r,t);(*(p4))=la.sub(s,q);
}
if(inverse_coef){
__m256i co=_mm256_set1_epi32(_inv[len-1]);
p1=(__m256i*)p;
for(ui i=0;i<len;i+=8,++p1) (*p1)=la.mul(*p1,co);
}
}
}
void dif_xni(ui* restrict arr,ui n){
#if defined(__AVX__) && defined(__AVX2__)
ui* restrict ws=ws0.get();
ui len=(1<<n);
if(len<=4){
for(ui i=0;i<len;++i) arr[i]=li.mul(arr[i],ws[(len<<1)+i]);
}else{
__m256i restrict *p1=(__m256i*)arr,*p2=(__m256i*)(ws+(len<<1));
for(ui i=0;i<len;i+=8,++p1,++p2) *p1=la.mul(*p1,*p2);
}
#else
ui* restrict ws=ws0.get();
ui len=(1<<n);
for(ui i=0;i<len;++i) arr[i]=li.mul(arr[i],ws[(len<<1)+i]);
#endif
dif(arr,n);
}
void dit_xni(ui* restrict arr,ui n){
dit(arr,n);
#if defined(__AVX__) && defined(__AVX2__)
ui* restrict ws=ws1.get();
ui len=(1<<n);
if(len<=4){
for(ui i=0;i<len;++i) arr[i]=li.mul(arr[i],ws[(len<<1)+i]);
}else{
__m256i restrict *p1=(__m256i*)arr,*p2=(__m256i*)(ws+(len<<1));
for(ui i=0;i<len;i+=8,++p1,++p2) *p1=la.mul(*p1,*p2);
}
#else
ui* restrict ws=ws1.get();
ui len=(1<<n);
for(ui i=0;i<len;++i) arr[i]=li.mul(arr[i],ws[(len<<1)+i]);
#endif
}
void internal_mul(ui* restrict src1,ui* restrict src2,ui* restrict dst,ui m){
dif(src1,m);
dif(src2,m);
#if defined (__AVX__) && defined(__AVX2__)
if((1<<m)<8){
for(ui i=0;i<(1<<m);++i) dst[i]=li.mul(src1[i],src2[i]);
}
else{
__m256i restrict *p1=(__m256i*)src1, *p2=(__m256i*)src2, *p3=(__m256i*)dst;
for(ui i=0;i<(1<<m);i+=8,++p1,++p2,++p3) *p3=la.mul(*p1,*p2);
}
#else
for(ui i=0;i<(1<<m);++i) dst[i]=li.mul(src1[i],src2[i]);
#endif
dit(dst,m);
}
void internal_transpose_mul(ui* restrict src1,ui* restrict src2,ui* restrict dst,ui m){
std::reverse(src1,src1+(1<<m));
internal_mul(src1,src2,dst,m);
std::reverse(dst,dst+(1<<m));
}
void internal_inv(ui* restrict src,ui* restrict dst,ui* restrict tmp,ui* restrict tmp2,ui len){//10E(n) x^n->x^{2n}
if(len==1){dst[0]=_fastpow(src[0],P-2);return;}
internal_inv(src,dst,tmp,tmp2,len>>1);
std::memcpy(tmp,src,sizeof(ui)*len);std::memcpy(tmp2,dst,sizeof(ui)*(len>>1));std::memset(tmp2+(len>>1),0,sizeof(ui)*(len>>1));
std::memset(dst+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp,__builtin_ctz(len));dif(tmp2,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=4){
for(ui i=0;i<len;++i) tmp[i]=li.mul(tmp[i],tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)tmp;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p2)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<len;++i) tmp[i]=li.mul(tmp[i],tmp2[i]);
#endif
dit(tmp,__builtin_ctz(len));std::memset(tmp,0,sizeof(ui)*(len>>1));dif(tmp,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=4){
for(ui i=0;i<len;++i) tmp[i]=li.mul(tmp[i],tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)tmp;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p2)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<len;++i) tmp[i]=li.mul(tmp[i],tmp2[i]);
#endif
dit(tmp,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=(len>>1);i<len;++i) dst[i]=li.neg(tmp[i]);
}else{
__m256i restrict *p1=(__m256i*)(tmp+(len>>1)),*p2=(__m256i*)(dst+(len>>1));
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p2)=la.sub(_mm256_setzero_si256(),(*p1));
}
#else
for(ui i=(len>>1);i<len;++i) dst[i]=li.neg(tmp[i]);
#endif
}
void internal_inv_faster(ui* restrict src,ui* restrict dst,ui* restrict tmp,ui* restrict tmp2,ui* restrict tmp3,ui len){//9E(n) x^n->x^{2n}
if(len==1){dst[0]=_fastpow(src[0],P-2);return;}
internal_inv_faster(src,dst,tmp,tmp2,tmp3,len>>1);
std::memcpy(tmp,src,sizeof(ui)*(len>>1));std::memcpy(tmp2,dst,sizeof(ui)*(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
ui mip=ws0[3];
for(ui i=0;i<(len>>1);++i) tmp[i]=li.add(tmp[i],li.mul(mip,src[i+(len>>1)]));
}
else{
__m256i mip=_mm256_set1_epi32(ws0[3]);
__m256i restrict *p1=(__m256i*)(src+(len>>1)),*p2=(__m256i*)tmp;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p2)=la.add((*p2),la.mul((*p1),mip));
}
#else
ui mip=ws0[3];
for(ui i=0;i<(len>>1);++i) tmp[i]=li.add(tmp[i],li.mul(mip,src[i+(len>>1)]));
#endif
dif_xni(tmp,__builtin_ctz(len>>1));
dif_xni(tmp2,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp[i]=li.mul(li.mul(tmp2[i],tmp2[i]),tmp[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)tmp;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p2)=la.mul((*p2),la.mul((*p1),(*p1)));
}
#else
for(ui i=0;i<(len>>1);++i) tmp[i]=li.mul(li.mul(tmp2[i],tmp2[i]),tmp[i]);
#endif
dit_xni(tmp,__builtin_ctz(len>>1));
std::memcpy(tmp2,src,sizeof(ui)*len);std::memcpy(tmp3,dst,sizeof(ui)*(len>>1));std::memset(tmp3+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp2,__builtin_ctz(len));dif(tmp3,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<len;++i) tmp2[i]=li.mul(li.mul(tmp3[i],tmp3[i]),tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp3,*p2=(__m256i*)tmp2;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p2)=la.mul((*p2),la.mul((*p1),(*p1)));
}
#else
for(ui i=0;i<len;++i) tmp2[i]=li.mul(li.mul(tmp3[i],tmp3[i]),tmp2[i]);
#endif
dit(tmp2,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
ui mip=ws0[3],iv2=_inv[1];
for(ui i=0;i<(len>>1);++i) dst[i+(len>>1)]=li.mul(li.sub(li.mul(li.sub(li.add(tmp[i],tmp2[i]),li.add(dst[i],dst[i])),mip),tmp2[i+(len>>1)]),iv2);
}
else{
__m256i restrict *p1=(__m256i*)tmp,*p2=(__m256i*)(tmp2+(len>>1)),*p3=(__m256i*)(tmp2),*p4=(__m256i*)(dst+(len>>1)),*p5=(__m256i*)(dst);
__m256i mip=_mm256_set1_epi32(ws0[3]),iv2=_mm256_set1_epi32(_inv[1]);
for(ui i=0;i<(len>>1);i+=8,++p1,++p2,++p3,++p4,++p5) (*p4)=la.mul(la.sub(la.mul(la.sub(la.add((*p1),(*p3)),la.add((*p5),(*p5))),mip),(*p2)),iv2);
}
#else
{
ui mip=ws0[3],iv2=_inv[1];
for(ui i=0;i<(len>>1);++i) dst[i+(len>>1)]=li.mul(li.sub(li.mul(li.sub(li.add(tmp[i],tmp2[i]),li.add(dst[i],dst[i])),mip),tmp2[i+(len>>1)]),iv2);
}
#endif
}
void internal_ln(ui* restrict src,ui* restrict dst,ui* restrict tmp1,ui* restrict tmp2,ui* restrict tmp3,ui len){
#if defined(__AVX__) && defined(__AVX2__)
ui pos=1;__m256i restrict *pp=(__m256i*)tmp1,*iv=(__m256i*)num.get();ui restrict *p1=src+1;
for(;pos+8<=len;pos+=8,p1+=8,++pp,++iv) *pp=la.mul(_mm256_loadu_si256((__m256i*)p1),*iv);
for(;pos<len;++pos) tmp1[pos-1]=li.mul(src[pos],num[pos-1]);tmp1[len-1]=li.v(0);
#else
ui restrict *p1=src+1,*p2=tmp1,*p3=num.get();
for(ui i=1;i<len;++i,++p1,++p2,++p3) *p2=li.mul((*p1),(*p3));
tmp1[len-1]=li.v(0);
#endif
internal_inv(src,dst,tmp2,tmp3,len);
std::memset(dst+len,0,sizeof(ui)*len);std::memset(tmp1+len,0,sizeof(ui)*len);
internal_mul(tmp1,dst,tmp2,__builtin_ctz(len<<1));
#if defined(__AVX__) && defined(__AVX2__)
ui ps=1;__m256i restrict *pp0=(__m256i*)tmp2,*iv0=(__m256i*)_inv.get();ui restrict *p10=dst+1;
for(;ps+8<=len;ps+=8,p10+=8,++pp0,++iv0) _mm256_storeu_si256((__m256i*)p10,la.mul(*pp0,*iv0));
dst[0]=li.v(0);
for(;ps<len;++ps) dst[ps]=li.mul(_inv[ps-1],tmp2[ps-1]);
#else
dst[0]=li.v(0);
ui restrict *p10=dst+1,*p20=tmp2,*p30=_inv.get();
for(ui i=1;i<len;++i,++p10,++p20,++p30) *p10=li.mul((*p20),(*p30));
#endif
}
void internal_ln_faster(ui* restrict src,ui* restrict dst,ui* restrict tmp1,ui* restrict tmp2,ui* restrict tmp3,ui* restrict tmp4,ui len){
if(len<4){internal_ln(src,dst,tmp1,tmp2,tmp3,len);return;}
#if defined(__AVX__) && defined(__AVX2__)
ui pos=1;__m256i restrict *pp=(__m256i*)tmp1,*iv=(__m256i*)num.get();ui restrict *p1=src+1;
for(;pos+8<=len;pos+=8,p1+=8,++pp,++iv) *pp=la.mul(_mm256_loadu_si256((__m256i*)p1),*iv);
for(;pos<len;++pos) tmp1[pos-1]=li.mul(src[pos],num[pos-1]);tmp1[len-1]=li.v(0);
#else
ui restrict *p1=src+1,*p2=tmp1,*p3=num.get();
for(ui i=1;i<len;++i,++p1,++p2,++p3) *p2=li.mul((*p1),(*p3));
tmp1[len-1]=li.v(0);
#endif
internal_inv_faster(src,dst,tmp2,tmp3,tmp4,(len>>1));//tmp4=F_{n/2}(g0 mod x^{n/4})
std::memcpy(dst,dst+(len>>2),sizeof(ui)*(len>>2));std::memset(dst+(len>>2),0,sizeof(ui)*(len>>2));
dif(dst,__builtin_ctz(len>>1));
std::memcpy(tmp2,tmp1+(len>>2),sizeof(ui)*(len>>2));std::memset(tmp2+(len>>2),0,sizeof(ui)*(len>>2));
dif(tmp2,__builtin_ctz(len>>1));
std::memset(tmp1+(len>>2),0,sizeof(ui)*(len>>2));
dif(tmp1,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.add(li.mul(tmp2[i],tmp4[i]),li.mul(dst[i],tmp1[i])),tmp1[i]=li.mul(tmp1[i],tmp4[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)tmp4,*p3=(__m256i*)dst,*p4=(__m256i*)tmp1;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2,++p3,++p4) (*p1)=la.add(la.mul((*p1),(*p2)),la.mul((*p3),(*p4))),(*p4)=la.mul((*p2),(*p4));
}
#else
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.add(li.mul(tmp2[i],tmp4[i]),li.mul(dst[i],tmp1[i])),tmp1[i]=li.mul(tmp1[i],tmp4[i]);
#endif
dit(tmp1,__builtin_ctz(len>>1));dit(tmp2,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=16){
for(ui i=0;i<(len>>2);++i) tmp1[i+(len>>2)]=li.add(tmp1[i+(len>>2)],tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)(tmp1+(len>>2)),*p2=(__m256i*)tmp2;
for(ui i=0;i<(len>>2);i+=8,++p1,++p2) (*p1)=la.add((*p1),(*p2));
}
#else
for(ui i=0;i<(len>>2);++i) tmp1[i+(len>>2)]=li.add(tmp1[i+(len>>2)],tmp2[i]);
#endif
std::memcpy(tmp2,tmp1,sizeof(ui)*(len>>1));
std::memset(tmp2+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp2,__builtin_ctz(len));std::memcpy(tmp3,src,sizeof(ui)*len);
dif(tmp3,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=4){
for(ui i=0;i<len;++i) tmp3[i]=li.mul(tmp3[i],tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)(tmp3),*p2=(__m256i*)tmp2;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p1)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<len;++i) tmp3[i]=li.mul(tmp3[i],tmp2[i]);
#endif
dit(tmp3,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp3[i+(len>>1)]=li.sub(tmp1[i+(len>>1)],tmp3[i+(len>>1)]);
}
else{
__m256i restrict *p1=(__m256i*)(tmp3+(len>>1)),*p2=(__m256i*)(tmp1+(len>>1));
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p1)=la.sub((*p2),(*p1));
}
#else
for(ui i=0;i<(len>>1);++i) tmp3[i+(len>>1)]=li.sub(tmp1[i+(len>>1)],tmp3[i+(len>>1)]);
#endif
std::memcpy(tmp3,tmp3+(len>>2)*3,sizeof(ui)*(len>>2));std::memset(tmp3+(len>>2),0,sizeof(ui)*(len>>2));
std::memcpy(tmp2,tmp3+(len>>1),sizeof(ui)*(len>>2));std::memset(tmp2+(len>>2),0,sizeof(ui)*(len>>2));
dif(tmp3,__builtin_ctz(len>>1));dif(tmp2,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp3[i]=li.add(li.mul(tmp3[i],tmp4[i]),li.mul(dst[i],tmp2[i])),tmp2[i]=li.mul(tmp2[i],tmp4[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp3,*p2=(__m256i*)tmp4,*p3=(__m256i*)dst,*p4=(__m256i*)tmp2;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2,++p3,++p4) (*p1)=la.add(la.mul((*p1),(*p2)),la.mul((*p3),(*p4))),(*p4)=la.mul((*p2),(*p4));
}
#else
for(ui i=0;i<(len>>1);++i) tmp3[i]=li.add(li.mul(tmp3[i],tmp4[i]),li.mul(dst[i],tmp2[i])),tmp2[i]=li.mul(tmp2[i],tmp4[i]);
#endif
dit(tmp3,__builtin_ctz(len>>1));dit(tmp2,__builtin_ctz(len>>1));
std::memcpy(tmp1+(len>>1),tmp2,sizeof(mi)*(len>>2));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=16){
for(ui i=0;i<(len>>2);++i) tmp1[i+(len>>2)*3]=li.add(tmp2[i+(len>>2)],tmp3[i]);
}
else{
__m256i restrict *p1=(__m256i*)(tmp1+(len>>2)*3),*p2=(__m256i*)(tmp2+(len>>2)),*p3=(__m256i*)(tmp3);
for(ui i=0;i<(len>>2);i+=8,++p1,++p2,++p3) (*p1)=la.add((*p2),(*p3));
}
#else
for(ui i=0;i<(len>>2);++i) tmp1[i+(len>>2)*3]=li.add(tmp2[i+(len>>2)],tmp3[i]);
#endif
#if defined(__AVX__) && defined(__AVX2__)
ui ps=1;__m256i restrict *pp0=(__m256i*)tmp1,*iv0=(__m256i*)_inv.get();ui restrict *p10=dst+1;
for(;ps+8<=len;ps+=8,p10+=8,++pp0,++iv0) _mm256_storeu_si256((__m256i*)p10,la.mul(*pp0,*iv0));
dst[0]=li.v(0);
for(;ps<len;++ps) dst[ps]=li.mul(_inv[ps-1],tmp1[ps-1]);
#else
dst[0]=li.v(0);
ui restrict *p10=dst+1,*p20=tmp1,*p30=_inv.get();
for(ui i=1;i<len;++i,++p10,++p20,++p30) *p10=li.mul((*p20),(*p30));
#endif
}
void internal_exp(ui* restrict src,ui* restrict dst,ui* restrict gn,ui* restrict gxni,
ui* restrict h,ui* restrict tmp1,ui* restrict tmp2,ui* restrict tmp3,ui len,bool calc_h=false){
if(len==1){dst[0]=li.v(1);return;}
else if(len==2){dst[0]=li.v(1);dst[1]=src[1];gn[0]=li.add(dst[0],dst[1]),gn[1]=li.sub(dst[0],dst[1]);gxni[0]=li.add(li.mul(dst[1],ws0[3]),dst[0]);h[0]=li.v(1);h[1]=li.neg(dst[1]);return;}
internal_exp(src,dst,gn,gxni,h,tmp1,tmp2,tmp3,(len>>1),true);
#if defined(__AVX__) && defined(__AVX2__)
{
ui pos=1;__m256i restrict *pp=(__m256i*)tmp1,*iv=(__m256i*)num.get();ui restrict *p1=src+1;
for(;pos+8<=(len>>1);pos+=8,p1+=8,++pp,++iv) *pp=la.mul(_mm256_loadu_si256((__m256i*)p1),*iv);
for(;pos<(len>>1);++pos) tmp1[pos-1]=li.mul(src[pos],num[pos-1]);tmp1[(len>>1)-1]=li.v(0);
}
#else
{
ui restrict *p1=src+1,*p2=tmp1,*p3=num.get();
for(ui i=1;i<(len>>1);++i,++p1,++p2,++p3) *p2=li.mul((*p1),(*p3));
tmp1[(len>>1)-1]=li.v(0);
}
#endif
dif(tmp1,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<8){
for(ui i=0;i<(len>>1);++i) tmp1[i]=li.mul(tmp1[i],gn[i]);
}else{
__m256i restrict *p1=(__m256i*)(tmp1),*p2=(__m256i*)(gn);
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p1)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<(len>>1);++i) tmp1[i]=li.mul(tmp1[i],gn[i]);
#endif
dit(tmp1,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
{
ui pos=1;__m256i restrict *pp=(__m256i*)tmp1,*iv=(__m256i*)num.get();ui restrict *p1=dst+1;
for(;pos+8<=(len>>1);pos+=8,p1+=8,++pp,++iv) *pp=la.sub(la.mul(_mm256_loadu_si256((__m256i*)p1),*iv),(*pp));
for(;pos<(len>>1);++pos) tmp1[pos-1]=li.sub(li.mul(dst[pos],num[pos-1]),tmp1[pos-1]);tmp1[(len>>1)-1]=li.neg(tmp1[(len>>1)-1]);
}
#else
{
ui restrict *p1=dst+1,*p2=tmp1,*p3=num.get();
for(ui i=1;i<(len>>1);++i,++p1,++p2,++p3) *p2=li.sub(li.mul((*p1),(*p3)),(*p2));
tmp1[(len>>1)-1]=li.neg(tmp1[(len>>1)-1]);
}
#endif
std::memmove(tmp1+1,tmp1,sizeof(ui)*(len>>1));tmp1[0]=tmp1[(len>>1)];
std::memset(tmp1+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp1,__builtin_ctz(len));
std::memcpy(tmp3,h,sizeof(ui)*(len>>1));std::memset(tmp3+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp3,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<8){
for(ui i=0;i<len;++i) tmp1[i]=li.mul(tmp3[i],tmp1[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp1,*p2=(__m256i*)tmp3;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p1)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<len;++i) tmp1[i]=li.mul(tmp3[i],tmp1[i]);
#endif
dit(tmp1,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.sub(src[i+(len>>1)],li.mul(_inv[i+(len>>1)-1],tmp1[i]));
}else{
__m256i restrict *p1=(__m256i*)tmp1,*p3=(__m256i*)(tmp2),*p4=(__m256i*)(src+(len>>1));ui* restrict p2=_inv.get()+(len>>1)-1;
for(ui i=0;i<(len>>1);i+=8,++p1,p2+=8,++p3,++p4) (*p3)=la.sub((*p4),la.mul((*p1),_mm256_loadu_si256((__m256i*)p2)));
}
#else
{
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.sub(src[i+(len>>1)],li.mul(_inv[i+(len>>1)-1],tmp1[i]));
}
#endif
std::memset(tmp2+(len>>1),0,sizeof(ui)*(len>>1));
dif(tmp2,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=16){
ui mip=ws1[3];
for(ui i=0;i<(len>>2);++i) tmp1[i]=li.mul(li.mul(li.add(dst[i],li.mul(dst[i+(len>>2)],mip)),ws0[(len>>1)+i]),ws0[(len>>2)+i]);
}else{
__m256i restrict *p1=(__m256i*)dst,*p2=(__m256i*)(dst+(len>>2)),*p3=(__m256i*)(tmp1),*p4=(__m256i*)(ws0.get()+(len>>1)),*p5=(__m256i*)(ws0.get()+(len>>2));
__m256i mip=_mm256_set1_epi32(ws1[3]);
for(ui i=0;i<(len>>2);i+=8,++p1,++p2,++p3,++p4,++p5) (*p3)=la.mul(la.add((*p1),la.mul((*p2),mip)),la.mul((*p4),(*p5)));
}
#else
{
ui mip=ws1[3];
for(ui i=0;i<(len>>2);++i) tmp1[i]=li.mul(li.mul(li.add(dst[i],li.mul(dst[i+(len>>2)],mip)),ws0[(len>>1)+i]),ws0[(len>>2)+i]);
}
#endif
dif(tmp1,__builtin_ctz(len>>2));
std::memcpy(tmp1+(len>>2)*3,tmp1,sizeof(ui)*(len>>2));
std::memcpy(tmp1,gn,sizeof(ui)*(len>>1));
std::memcpy(tmp1+(len>>1),gxni,sizeof(ui)*(len>>2));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=4){
for(ui i=0;i<len;++i) tmp1[i]=li.mul(tmp2[i],tmp1[i]);
}else{
__m256i restrict *p1=(__m256i*)tmp1,*p2=(__m256i*)(tmp2);
for(ui i=0;i<len;i+=8,++p1,++p2) (*p1)=la.mul((*p1),(*p2));
}
#else
for(ui i=0;i<len;++i) tmp1[i]=li.mul(tmp2[i],tmp1[i]);
#endif
dit(tmp1,__builtin_ctz(len));
std::memcpy(dst+(len>>1),tmp1,sizeof(ui)*(len>>1));
//inv iteration start
if(!calc_h) return;
std::memcpy(gxni,dst,sizeof(ui)*(len>>1));std::memcpy(tmp2,h,sizeof(ui)*(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
ui mip=ws0[3];
for(ui i=0;i<(len>>1);++i) gxni[i]=li.add(gxni[i],li.mul(mip,dst[i+(len>>1)]));
}
else{
__m256i mip=_mm256_set1_epi32(ws0[3]);
__m256i restrict *p1=(__m256i*)(dst+(len>>1)),*p2=(__m256i*)gxni;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p2)=la.add((*p2),la.mul((*p1),mip));
}
#else
{
ui mip=ws0[3];
for(ui i=0;i<(len>>1);++i) gxni[i]=li.add(gxni[i],li.mul(mip,dst[i+(len>>1)]));
}
#endif
dif_xni(gxni,__builtin_ctz(len>>1));
dif_xni(tmp2,__builtin_ctz(len>>1));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.mul(li.mul(tmp2[i],gxni[i]),tmp2[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)gxni;
for(ui i=0;i<(len>>1);i+=8,++p1,++p2) (*p1)=la.mul((*p2),la.mul((*p1),(*p1)));
}
#else
for(ui i=0;i<(len>>1);++i) tmp2[i]=li.mul(li.mul(tmp2[i],gxni[i]),tmp2[i]);
#endif
dit_xni(tmp2,__builtin_ctz(len>>1));
std::memcpy(gn,dst,sizeof(ui)*len);
dif(gn,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
for(ui i=0;i<len;++i) tmp3[i]=li.mul(li.mul(tmp3[i],gn[i]),tmp3[i]);
}
else{
__m256i restrict *p1=(__m256i*)tmp3,*p2=(__m256i*)gn;
for(ui i=0;i<len;i+=8,++p1,++p2) (*p1)=la.mul((*p2),la.mul((*p1),(*p1)));
}
#else
for(ui i=0;i<len;++i) tmp3[i]=li.mul(li.mul(tmp3[i],gn[i]),tmp3[i]);
#endif
dit(tmp3,__builtin_ctz(len));
#if defined(__AVX__) && defined(__AVX2__)
if(len<=8){
ui mip=ws0[3],iv2=_inv[1];
for(ui i=0;i<(len>>1);++i) h[i+(len>>1)]=li.mul(li.sub(li.mul(li.sub(li.add(tmp2[i],tmp3[i]),li.add(h[i],h[i])),mip),tmp3[i+(len>>1)]),iv2);
}
else{
__m256i restrict *p1=(__m256i*)tmp2,*p2=(__m256i*)(tmp3+(len>>1)),*p3=(__m256i*)(tmp3),*p4=(__m256i*)(h+(len>>1)),*p5=(__m256i*)(h);
__m256i mip=_mm256_set1_epi32(ws0[3]),iv2=_mm256_set1_epi32(_inv[1]);
for(ui i=0;i<(len>>1);i+=8,++p1,++p2,++p3,++p4,++p5) (*p4)=la.mul(la.sub(la.mul(la.sub(la.add((*p1),(*p3)),la.add((*p5),(*p5))),mip),(*p2)),iv2);
}
#else
{
ui mip=ws0[3],iv2=_inv[1];
for(ui i=0;i<(len>>1);++i) h[i+(len>>1)]=li.mul(li.sub(li.mul(li.sub(li.add(tmp2[i],tmp3[i]),li.add(h[i],h[i])),mip),tmp3[i+(len>>1)]),iv2);
}
#endif
}
void internal_multipoint_eval_interpolation_calc_Q(std::vector<poly> &Q_storage,const poly &input_coef,ui l,ui r,ui id){
if(l==r){
Q_storage[id]={ui2mi(li.v(1)),ui2mi(li.neg(input_coef[l].get_val()))};
return;
}
ui mid=(l+r)>>1;
internal_multipoint_eval_interpolation_calc_Q(Q_storage,input_coef,l,mid,id<<1);
internal_multipoint_eval_interpolation_calc_Q(Q_storage,input_coef,mid+1,r,id<<1|1);
Q_storage[id]=mul(Q_storage[id<<1],Q_storage[id<<1|1]);
}
void internal_multipoint_eval_interpolation_calc_P(const std::vector<poly> &Q_storage,std::vector<poly> &P_stack,poly &result_coef,ui l,ui r,ui id,ui dep){
if(l==r){
result_coef[l]=P_stack[dep][0];
return;
}
P_stack[dep].resize(r-l+1);
ui mid=(l+r)>>1;
P_stack[dep+1]=transpose_mul(P_stack[dep],Q_storage[id<<1|1]);
internal_multipoint_eval_interpolation_calc_P(Q_storage,P_stack,result_coef,l,mid,id<<1,dep+1);
P_stack[dep+1]=transpose_mul(P_stack[dep],Q_storage[id<<1]);
internal_multipoint_eval_interpolation_calc_P(Q_storage,P_stack,result_coef,mid+1,r,id<<1|1,dep+1);
}
void internal_lagrange_interpolation_dvc_mul(ui l,ui r,const poly &a,ui id,std::vector<std::pair<poly,poly>> &R_storage){
if(l==r){
R_storage[id].first={ui2mi(li.neg(a[l].get_val())),ui2mi(li.v(1))};
return;
}
ui mid=(l+r)>>1;
internal_lagrange_interpolation_dvc_mul(l,mid,a,id<<1,R_storage);
internal_lagrange_interpolation_dvc_mul(mid+1,r,a,id<<1|1,R_storage);
ui m=32-__builtin_clz(r-l+1);
R_storage[id].first=mul(R_storage[id<<1].first,R_storage[id<<1|1].first);
R_storage[id<<1].second.resize((1<<m));
R_storage[id<<1|1].second.resize((1<<m));
std::memcpy(&R_storage[id<<1].second[0],tt[0].get(),sizeof(mi)*(1<<m));
std::memcpy(&R_storage[id<<1|1].second[0],tt[1].get(),sizeof(mi)*(1<<m));
}
void internal_lagrange_interpolation_calc_P(const std::vector<std::pair<poly,poly>> &R_storage,std::vector<poly> &P_stack,poly &result_coef,ui l,ui r,ui id,ui dep){
if(l==r){
result_coef[l]=P_stack[dep][0];
return;
}
P_stack[dep].resize(r-l+1);
ui mid=(l+r)>>1;
P_stack[dep+1]=transpose_mul(P_stack[dep],rev(R_storage[id<<1|1].first));
internal_lagrange_interpolation_calc_P(R_storage,P_stack,result_coef,l,mid,id<<1,dep+1);
P_stack[dep+1]=transpose_mul(P_stack[dep],rev(R_storage[id<<1].first));
internal_lagrange_interpolation_calc_P(R_storage,P_stack,result_coef,mid+1,r,id<<1|1,dep+1);
}
poly internal_lagrange_interpolation_dvc_mul_ans(ui l,ui r,const poly &a,ui id,const std::vector<std::pair<poly,poly>> &R_storage){
if(l==r) return {a[l]};
ui mid=(l+r)>>1;
auto&& lp=internal_lagrange_interpolation_dvc_mul_ans(l,mid,a,id<<1,R_storage);
auto&& rp=internal_lagrange_interpolation_dvc_mul_ans(mid+1,r,a,id<<1|1,R_storage);
ui m=32-__builtin_clz(r-l+1);
std::memcpy(tt[0].get(),&lp[0],sizeof(mi)*(lp.size()));std::memset(tt[0].get()+lp.size(),0,sizeof(mi)*((1<<m)-lp.size()));
std::memcpy(tt[1].get(),&rp[0],sizeof(mi)*(rp.size()));std::memset(tt[1].get()+rp.size(),0,sizeof(mi)*((1<<m)-rp.size()));
dif(tt[0].get(),m);dif(tt[1].get(),m);
for(ui i=0;i<(1<<m);++i) tt[0][i]=li.add(li.mul(tt[0][i],R_storage[id<<1|1].second[i].get_val()),li.mul(tt[1][i],R_storage[id<<1].second[i].get_val()));
dit(tt[0].get(),m);
poly ret(r-l+1);
std::memcpy(&ret[0],tt[0].get(),sizeof(mi)*(r-l+1));
return ret;
}
lmi li;
#if defined(__AVX__) && defined(__AVX2__)
lma la;
#endif
#if defined(__AVX512F__) && defined(__AVX512DQ__)
lm5 l5;
#endif
public:
polynomial_kernel_ntt(ui max_conv_size,ui P0,ui G0){init(max_conv_size,P0,G0);}
void init(ui max_conv_size,ui P0,ui G0){
if(max_conv_size>=(1u<<30)) throw std::runtime_error("invalid range!");
max_conv_size=std::max(max_conv_size,16u);
li=lmi(P0);
#if defined(__AVX__) && defined(__AVX2__)
la=lma(P0);
#endif
#if defined(__AVX512F__) && defined(__AVX512DQ__)
l5=lm5(P0);
#endif
release();P=P0,G=G0;mx=max_conv_size;
fn=1;fb=0;while(fn<(max_conv_size<<1)) fn<<=1,++fb;
if((P0-1)%fn) throw std::runtime_error("invalid range!");
_inv=create_aligned_array<ui,64>(fn+32);ws0 =create_aligned_array<ui,64>(fn+32);
ws1 =create_aligned_array<ui,64>(fn+32);num =create_aligned_array<ui,64>(fn+32);
for(ui i=0;i<tmp_size;++i) tt[i] =create_aligned_array<ui,64>(fn+32);
_inv[0]=li.v(1);for(ui i=2;i<=fn+32;++i) _inv[i-1]=li.mul(li.v(P-P/i),_inv[(P%i)-1]);
for(ui i=1;i<=fn+32;++i) num[i-1]=li.v(i);
ui j0=_fastpow(li.v(G),(P-1)/fn),j1=_fastpow(_fastpow(li.v(G),(P-2)),(P-1)/fn);
for(ui mid=(fn>>1);mid>=1;mid>>=1,j0=li.mul(j0,j0),j1=li.mul(j1,j1)){
ui w0=li.v(1),w1=li.v(1);
for(ui i=0;i<mid;++i,w0=li.mul(w0,j0),w1=li.mul(w1,j1)) ws0[i+mid]=w0,ws1[i+mid]=w1;
}
}
polynomial_kernel_ntt(const polynomial_kernel_ntt &d);
polynomial_kernel_ntt(){fn=fb=mx=0;}
~polynomial_kernel_ntt(){release();}
poly rev(const poly &a){
poly ret(a);
std::reverse(ret.begin(),ret.end());
return ret;
}
poly mul(const poly &a,const poly &b){
ui la=a.size(),lb=b.size();if((!la) && (!lb)) return poly();
if(la>mx || lb>mx) throw std::runtime_error("Convolution size out of range!");
ui m=0;if(la+lb>2) m=32-__builtin_clz(la+lb-2);
std::memcpy(tt[0].get(),&a[0],sizeof(ui)*la);std::memset(tt[0].get()+la,0,sizeof(ui)*((1<<m)-la));
std::memcpy(tt[1].get(),&b[0],sizeof(ui)*lb);std::memset(tt[1].get()+lb,0,sizeof(ui)*((1<<m)-lb));
internal_mul(tt[0].get(),tt[1].get(),tt[2].get(),m);
poly ret(la+lb-1);
std::memcpy(&ret[0],tt[2].get(),sizeof(ui)*(la+lb-1));
return ret;
}
poly transpose_mul(const poly &a,const poly &b){
ui la=a.size(),lb=b.size();if((!la) && (!lb)) return poly();
if(la>mx || lb>mx) throw std::runtime_error("Convolution size out of range!");
ui m=0;if(la+lb>2) m=32-__builtin_clz(la+lb-2);
std::memcpy(tt[0].get(),&a[0],sizeof(ui)*la);std::memset(tt[0].get()+la,0,sizeof(ui)*((1<<m)-la));
std::memcpy(tt[1].get(),&b[0],sizeof(ui)*lb);std::memset(tt[1].get()+lb,0,sizeof(ui)*((1<<m)-lb));
internal_transpose_mul(tt[0].get(),tt[1].get(),tt[2].get(),m);
poly ret(la);
std::memcpy(&ret[0],tt[2].get(),sizeof(ui)*(la));
return ret;
}
poly multipoint_eval_interpolation(const poly &a,const poly &b){
ui point_count=b.size(),poly_count=a.size(),maxnm=std::max(point_count,poly_count);
if(!poly_count) throw std::runtime_error("Multipoint eval interpolation of empty polynomial!");
if(maxnm*4>fn) throw std::runtime_error("Multipoint eval interpolation size out of range!");
if(!point_count) return {};
std::vector<poly> Q_storage(point_count<<2),P_stack((32-__builtin_clz(point_count))*2);
internal_multipoint_eval_interpolation_calc_Q(Q_storage,b,0,point_count-1,1);
poly ans(point_count);
Q_storage[1].resize(maxnm);
P_stack[0]=transpose_mul(a,inv(Q_storage[1]));
internal_multipoint_eval_interpolation_calc_P(Q_storage,P_stack,ans,0,point_count-1,1,0);
return ans;
}
poly lagrange_interpolation(const std::vector<std::pair<mi,mi>> &a){
if(!a.size()) throw std::runtime_error("Lagrange interpolation of zero coefficients!");
auto d=a;
auto cmp=[](const std::pair<mi,mi> &a,const std::pair<mi,mi> &b){
return a.first.get_val()<b.first.get_val() || (a.first.get_val()==b.first.get_val() && a.second.get_val()<b.second.get_val());};
auto ceq=[](const std::pair<mi,mi> &a,const std::pair<mi,mi> &b){return a.first.get_val()==b.first.get_val() && a.second.get_val()==b.second.get_val();};
std::sort(d.begin(),d.end(),cmp);
d.resize(std::unique(d.begin(),d.end(),ceq)-d.begin());
ui len=d.size();
if(len*4>fn) throw std::runtime_error("Lagrange interpolation size out of range!");
for(ui i=1;i<len;++i) if(d[i].first.get_val()==d[i-1].first.get_val()) throw std::runtime_error("Polynomial has multiple values on one position!");
if(len==1){
poly ret=poly({d[0].second});
ret.resize(a.size());
return ret;
}
poly pts(len);
for(ui i=0;i<len;++i) pts[i]=d[i].first;
std::vector<std::pair<poly,poly>> R_storage(len<<2);
std::vector<poly> P_stack((32-__builtin_clz(len))*2);
internal_lagrange_interpolation_dvc_mul(0,len-1,pts,1,R_storage);
poly rf=rev(R_storage[1].first);rf.resize(len);
P_stack[0]=transpose_mul(derivative(R_storage[1].first),inv(rf));
poly coef(len);
internal_lagrange_interpolation_calc_P(R_storage,P_stack,coef,0,len-1,1,0);
for(ui i=0;i<len;++i) coef[i]=ui2mi(li.mul(_fastpow(coef[i].get_val(),P-2),d[i].second.get_val()));
poly ret=internal_lagrange_interpolation_dvc_mul_ans(0,len-1,coef,1,R_storage);
ret.resize(a.size());
return ret;
}
poly inv(const poly &src){
ui la=src.size();if(!la) throw std::runtime_error("Inversion calculation of empty polynomial!");
if((la*4)>fn) throw std::runtime_error("Inversion calculation size out of range!");
if(!li.rv(src[0].get_val())){
throw std::runtime_error("Inversion calculation of polynomial which has constant not equal to 1!");
}
ui m=0;if(la>1) m=32- __builtin_clz(la-1);
std::memcpy(tt[0].get(),&src[0],sizeof(ui)*la);std::memset(tt[0].get()+la,0,sizeof(ui)*((1<<m)-la));
// internal_inv(tt[0].get(),tt[1].get(),tt[2].get(),tt[3].get(),(1<<m));
internal_inv_faster(tt[0].get(),tt[1].get(),tt[2].get(),tt[3].get(),tt[4].get(),(1<<m));
poly ret(la);
std::memcpy(&ret[0],tt[1].get(),sizeof(ui)*la);
return ret;
}
poly ln(const poly &src){
ui la=src.size();if(!la) throw std::runtime_error("Ln calculation of empty polynomial!");
if((la*2)>fn) throw std::runtime_error("Ln calculation size out of range!");
if(li.rv(src[0].get_val())!=1){
throw std::runtime_error("Ln calculation of polynomial which has constant not equal to 1!");
}
ui m=0;if(la>1) m=32- __builtin_clz(la-1);
std::memcpy(tt[0].get(),&src[0],sizeof(ui)*la);std::memset(tt[0].get()+la,0,sizeof(ui)*((1<<m)-la));
// internal_ln(tt[0].get(),tt[1].get(),tt[2].get(),tt[3].get(),tt[4].get(),(1<<m));
internal_ln_faster(tt[0].get(),tt[1].get(),tt[2].get(),tt[3].get(),tt[4].get(),tt[5].get(),(1<<m));
poly ret(la);
std::memcpy(&ret[0],tt[1].get(),sizeof(ui)*la);
return ret;
}
poly exp(const poly &src){
ui la=src.size();if(!la) throw std::runtime_error("Exp calculation of empty polynomial!");
if((la*2)>fn) throw std::runtime_error("Exp calculation size out of range!");
if(li.rv(src[0].get_val())!=0){
throw std::runtime_error("Exp calculation of polynomial which has constant not equal to 0!");
}
ui m=0;if(la>1) m=32- __builtin_clz(la-1);
std::memcpy(tt[0].get(),&src[0],sizeof(ui)*la);std::memset(tt[0].get()+la,0,sizeof(ui)*((1<<m)-la));
internal_exp(tt[0].get(),tt[1].get(),tt[2].get(),tt[3].get(),tt[4].get(),tt[5].get(),tt[6].get(),tt[7].get(),(1<<m));
poly ret(la);
std::memcpy(&ret[0],tt[1].get(),sizeof(ui)*la);
return ret;
}
poly derivative(const poly &a){
if(!a.size()) throw std::runtime_error("Derivative calculation of empty polynomial!");
if(a.size()>fn) throw std::runtime_error("Derivative calculation size out of range!");
ui len=a.size();poly ret(len-1);
for(ui i=0;i<len-1;++i) ret[i]=ui2mi(li.mul(li.v(i+1),a[i+1].get_val()));
return ret;
}
poly integrate(const poly &a){
if(!a.size()) throw std::runtime_error("Integrate calculation of empty polynomial!");
if(a.size()>=fn) throw std::runtime_error("Integrate calculation size out of range!");
ui len=a.size();poly ret(len+1);ret[0]=ui2mi(li.v(0));
for(ui i=1;i<=len;++i) ret[i]=ui2mi(li.mul(_inv[i-1],a[i-1].get_val()));
return ret;
}
poly add(const poly &a,const poly &b){
ui la=a.size(),lb=b.size(),len=std::max(la,lb);poly ret(len);
std::memcpy(&ret[0],&b[0],sizeof(mi)*(lb));
for(ui i=0;i<la;++i) ret[i]=ui2mi(li.add(ret[i].get_val(),a[i].get_val()));
return ret;
}
poly sub(const poly &a,const poly &b){
ui la=a.size(),lb=b.size(),len=std::max(la,lb);poly ret(len);
std::memcpy(&ret[0],&a[0],sizeof(mi)*(la));
for(ui i=0;i<lb;++i) ret[i]=ui2mi(li.sub(ret[i].get_val(),b[i].get_val()));
return ret;
}
};
#undef restrict
#undef NTT_partition_size
}
using library::polynomial_kernel_ntt;
using library::poly;
using library::mi;
using library::set_mod_mi;
constexpr int N=10010,P=998244353;
mi fac[N],ifac[N],inv[N];
mi fp(mi a,int b){mi ans(1),off=a;while(b){if(b&1) ans=ans*off;off=off*off;b>>=1;}return ans;}
int main(){
set_mod_mi(P);
int m,n;scanf("%d%d",&n,&m);
polynomial_kernel_ntt p(m*2+1,P,3);
fac[0]=mi(1);
for(int i=1;i<=m+1;++i) fac[i]=fac[i-1]*mi(i);
ifac[m+1]=fp(fac[m+1],P-2);inv[1]=mi(1);
for(int i=m;i>=1;--i) ifac[i]=ifac[i+1]*mi(i+1),inv[i+1]=ifac[i+1]*fac[i];
// printf("%u\n",inv[2].real_val());
poly B(m+1);
for(int i=0;i<=m;++i) B[i]=ifac[i+1];
B=p.inv(B);
poly C=p.ln(B);
poly D(m+1);
mi j(n+1),t=j;
for(int i=0;i<=m;++i,t*=j) D[i]=t*ifac[i+1];
D=p.mul(D,B);D.resize(m+1);
// for(int i=0;i<=m;++i) printf("%u ",(D[i]*fac[i]).real_val());printf("\n");
poly E(m+1);
for(int i=0;i<=m;++i) E[i]=(mi(n)-fac[i]*D[i])*C[i];
E[0]=mi(0);
E=p.exp(E);
printf("%u\n",(E[m]*fac[m]).real_val());
return 0;
}
Details
Tip: Click on the bar to expand more detailed information
Subtask #1:
score: 0
Dangerous Syscalls
Test #1:
score: 0
Dangerous Syscalls
input:
500 308810287 308810287 53564892 53564892 316377768 316377768 420249597 420249597 731165653 731165653 319087025 319087025 153776963 153776963 425464316 425464316 651047701 651047701 142502072 142502072 31632388 31632388 572337890 572337890 400220429 400220429 414382974 414382974 279400752 279400752 ...
output:
result:
Subtask #2:
score: 0
Skipped
Dependency #1:
0%
Subtask #3:
score: 0
Dangerous Syscalls
Test #41:
score: 0
Dangerous Syscalls
input:
100 191358459 947004691 342443850 366915813 22574423 36448174 228846908 747282766 190110113 253913299 93029730 879223713 290883541 747723417 162887369 973643964 586349400 863191444 242642824 878391136 18343882 502405347 18658435 174450786 308510413 787915209 79222154 665119810 422422946 793255277 53...
output:
result:
Subtask #4:
score: 0
Skipped
Dependency #1:
0%