#include #include #include #include #include #include #include #include #define _fetch(_1, _2, _3, _4, name, ...) name #define rep2(i, n) rep3(i, 0, n) #define rep3(i, a, b) rep4(i, a, b, 1) #define rep4(i, a, b, c) for (int i = int(a); i < int(b); i += int(c)) #define rep(...) _fetch(__VA_ARGS__, rep4, rep3, rep2, _)(__VA_ARGS__) using namespace std; using i64 = long long; using u32 = unsigned; using u64 = unsigned long long; using f80 = long double; namespace ntt { template class Mod64 { private: using u128 = __uint128_t; static constexpr u64 mul_inv(u64 n, int e=6, u64 x=1) { return e == 0 ? x : mul_inv(n, e-1, x*(2-x*n)); } public: static constexpr u64 inv = mul_inv(mod); static constexpr u64 r2 = -u128(mod) % mod; static constexpr int level = __builtin_ctzll(mod - 1); static_assert(inv * mod == 1, "invalid 1/M modulo 2^64."); Mod64() {} Mod64(u64 n) : x(init(n)) {}; static u64 modulo() { return mod; } static u64 init(u64 w) { return reduce(u128(w) * r2); } static u64 reduce(const u128 w) { return u64(w >> 64) + mod - ((u128(u64(w) * inv) * mod) >> 64); } static Mod64 omega() { return Mod64(prim_root).pow((mod - 1) >> level); } Mod64& operator += (Mod64 rhs) { this->x += rhs.x; return *this; } Mod64& operator -= (Mod64 rhs) { this->x += 2 * mod - rhs.x; return *this; } Mod64& operator *= (Mod64 rhs) { this->x = reduce(u128(this->x) * rhs.x); return *this; } Mod64 operator + (Mod64 rhs) const { return Mod64(*this) += rhs; } Mod64 operator - (Mod64 rhs) const { return Mod64(*this) -= rhs; } Mod64 operator * (Mod64 rhs) const { return Mod64(*this) *= rhs; } u64 get() const { return reduce(this->x) % mod; } void set(u64 n) const { this->x = n; } Mod64 pow(u64 exp) const { Mod64 ret = Mod64(1); for (Mod64 base = *this; exp; exp >>= 1, base *= base) if (exp & 1) ret *= base; return ret; } Mod64 inverse() const { return pow(mod - 2); } friend ostream& operator << (ostream& os, const Mod64& m) { return os << m.get(); } static void debug() { printf("%llu %llu %llu %llu\n", mod, inv, r2, omega().get()); } u64 x; }; template void convolute(mod_t* A, int s1, mod_t* B, int s2, bool cyclic=false) { int s = (cyclic ? max(s1, s2) : s1 + s2 - 1); int size = 1; while (size < s) size <<= 1; mod_t roots[mod_t::level] = { mod_t::omega() }; rep(i, 1, mod_t::level) roots[i] = roots[i - 1] * roots[i - 1]; fill(A + s1, A + size, 0); ntt_dit4(A, size, 1, roots); if (A == B && s1 == s2) { rep(i, size) A[i] *= A[i]; } else { fill(B + s2, B + size, 0); ntt_dit4(B, size, 1, roots); rep(i, size) A[i] *= B[i]; } ntt_dit4(A, size, -1, roots); mod_t inv = mod_t(size).inverse(); rep(i, cyclic ? size : s) A[i] *= inv; } template void rev_permute(mod_t* A, int n) { int r = 0, nh = n >> 1; rep(i, 1, n) { for (int h = nh; !((r ^= h) & h); h >>= 1); if (r > i) swap(A[i], A[r]); } } template void ntt_dit4(mod_t* A, int n, int sign, mod_t* roots) { rev_permute(A, n); int logn = __builtin_ctz(n); if (logn & 1) rep(i, 0, n, 2) { mod_t a = A[i], b = A[i + 1]; A[i] = a + b; A[i + 1] = a - b; } mod_t imag = roots[mod_t::level - 2]; if (sign < 0) imag = imag.inverse(); mod_t one = mod_t(1); rep(e, 2 + (logn & 1), logn + 1, 2) { const int m = 1 << e; const int m4 = m >> 2; mod_t dw = roots[mod_t::level - e]; if (sign < 0) dw = dw.inverse(); const int block_size = max(m, (1 << 15) / int(sizeof(A[0]))); rep(k, 0, n, block_size) { mod_t w = one, w2 = one, w3 = one; rep(j, m4) { rep(i, k + j, k + block_size, m) { mod_t a0 = A[i + m4 * 0] * one, a2 = A[i + m4 * 1] * w2; mod_t a1 = A[i + m4 * 2] * w, a3 = A[i + m4 * 3] * w3; mod_t t02 = a0 + a2, t13 = a1 + a3; A[i + m4 * 0] = t02 + t13; A[i + m4 * 2] = t02 - t13; t02 = a0 - a2, t13 = (a1 - a3) * imag; A[i + m4 * 1] = t02 + t13; A[i + m4 * 3] = t02 - t13; } w *= dw; w2 = w * w; w3 = w2 * w; } } } } const int size = 1 << 22; using m64_1 = ntt::Mod64<34703335751681, 3>; using m64_2 = ntt::Mod64<35012573396993, 3>; m64_1 f1[size], g1[size]; m64_2 f2[size], g2[size]; } // namespace ntt using R = u32; class poly { public: poly() {} poly(int n) : coefs(n) {} poly(int n, int c) : coefs(n, c % mod) {} poly(const vector& v) : coefs(v) {} poly(const poly& f, int beg, int end=-1) { if (end < 0) end = beg, beg = 0; resize(end - beg); rep(i, beg, end) if (i < f.size()) coefs[i - beg] = f[i]; } static u32 ilog2(u64 n) { return 63 - __builtin_clzll(n); } int size() const { return coefs.size(); } void resize(int s) { coefs.resize(s); } void push_back(R c) { coefs.push_back(c); } const R* data() const { return coefs.data(); } R* data() { return coefs.data(); } const R& operator [] (int i) const { return coefs[i]; } R& operator [] (int i) { return coefs[i]; } static void add(R& a, R b) { if ((a += b) >= mod) a -= mod; } static void sub(R& a, R b) { if (int(a -= b) < 0) a += mod; } poly operator - () { poly ret = *this; rep(i, ret.size()) ret[i] = (ret[i] == 0 ? 0 : mod - ret[i]); return ret; } poly& operator += (const poly& rhs) { if (size() < rhs.size()) resize(rhs.size()); rep(i, rhs.size()) add(coefs[i], rhs[i]); return *this; } poly& operator -= (const poly& rhs) { if (size() < rhs.size()) resize(rhs.size()); rep(i, rhs.size()) sub(coefs[i], rhs[i]); return *this; } poly& operator *= (const poly& rhs) { return *this = *this * rhs; } poly operator + (const poly& rhs) const { return poly(*this) += rhs; } poly operator - (const poly& rhs) const { return poly(*this) -= rhs; } poly operator * (const poly& rhs) const { return this->mul(rhs); } struct fast_div { using u128 = __uint128_t; fast_div(u64 n) : m(n) { s = (n == 1) ? 0 : 127 - __builtin_clzll(n - 1); x = ((u128(1) << s) + n - 1) / n; } friend u64 operator / (u64 n, fast_div d) { return u128(n) * d.x >> d.s; } friend u64 operator % (u64 n, fast_div d) { return n - n / d * d.m; } u64 m, s, x; }; private: poly mul_crt(int beg, int end) const { using namespace ntt; auto inv = m64_2(m64_1::modulo()).inverse(); auto fast_mod = fast_div(mod); auto mod1 = m64_1::modulo() % fast_mod; poly ret(end - beg); rep(i, ret.size()) { u64 r1 = f1[i + beg].get(), r2 = f2[i + beg].get(); ret[i] = (r1 + (m64_2(r2 + m64_2::modulo() - r1) * inv).get() % fast_mod * mod1) % fast_mod; } return ret; } static void mul2(const poly& f, const poly &g, bool cyclic=false) { using namespace ntt; if (&f == &g) { rep(i, f.size()) f1[i] = f[i]; convolute(f1, f.size(), f1, f.size(), cyclic); rep(i, f.size()) f2[i] = f[i]; convolute(f2, f.size(), f2, f.size(), cyclic); } else { rep(i, f.size()) f1[i] = f[i]; rep(i, g.size()) g1[i] = g[i]; convolute(f1, f.size(), g1, g.size(), cyclic); rep(i, f.size()) f2[i] = f[i]; rep(i, g.size()) g2[i] = g[i]; convolute(f2, f.size(), g2, g.size(), cyclic); } } public: // 1.0 * M(n) poly mul(const poly& g) const { const auto& f = *this; if (f.size() == 0 || g.size() == 0) return poly(); mul2(f, g, false); return mul_crt(0, f.size() + g.size() - 1); } // 0.5 * M(n) poly mul_cyclically(const poly& g) const { const auto& f = *this; if (f.size() == 0 || g.size() == 0) return poly(); mul2(f, g, true); int s = max(f.size(), g.size()), size = 1; while (size < s) size <<= 1; return mul_crt(0, size); } // 1.0 * M(n) poly middle_product(const poly& g) const { const poly& f = *this; if (f.size() == 0 || g.size() == 0) return poly(); mul2(f, g, false); return mul_crt(f.size(), g.size()); } // 2.0 * M(n) poly inverse(int prec=-1) const { if (prec < 0) prec = size(); poly ret(1, 1); for (int e = 1, ne; e < prec; e = ne) { ne = min(2 * e, prec); poly h = poly(ret, ne - e) * -ret.middle_product(poly(*this, ne)); rep(i, e, ne) ret.push_back(h[i - e]); } return ret; } // 2.5 * M(n) poly quotient(const poly& b) const { assert(size() == b.size()); int s = size() / 2 + 1; poly inv = b.inverse(s); poly q1 = poly(poly(*this, s) * inv, s); poly lo = q1.middle_product(b); poly q2 = poly(inv, size() - s) * (poly(*this, s, size()) - lo); rep(i, size() - s) q1.push_back(q2[i]); return q1; } // 0.5 * M(n) : f - q * d static poly sub_mul(const poly& f, const poly& q, const poly& d) { int sq = q.size(); poly p = q.mul_cyclically(d); int mask = p.size() - 1; rep(i, sq) sub(p[i & mask], f[i & mask]); poly r = poly(f, sq, f.size()); rep(i, r.size()) sub(r[i], p[(sq + i) & mask]); return r; } // 3.0 * M(n) pair divrem(const poly& b) const { if (size() < b.size()) return make_pair(poly(), poly(*this)); assert(size() < 2 * b.size()); int sq = size() - b.size() + 1; poly q = poly(*this, sq).quotient(poly(b, sq)); poly r = sub_mul(*this, q, b); return make_pair(q, r); } // 3.0 * M(n) poly rem(const poly& b) const { return divrem(b).second; } // 1.5 * M(n) pair divrem_pre(const poly& b, const poly& inv) const { if (size() < b.size()) { return make_pair(poly(), poly(*this)); } int sq = size() - b.size() + 1; assert(size() >= sq && inv.size() >= sq); poly q = poly(poly(*this, sq) * poly(inv, sq), sq); poly r = sub_mul(*this, q, b); return make_pair(q, r); } // 1.5 * M(n) poly rem_pre(const poly& f, const poly& inv) const { return divrem_pre(f, inv).second; } // 13/6 * M(n) * log2_(e) : x^e (mod f) static poly x_pow_mod(u64 e, const poly& f) { if (e == 0) return poly(1, 1); poly ret = poly(vector({1, 0})); poly inv = f.inverse(f.size()); ret = ret.rem_pre(f, inv); u64 mask = (u64(1) << ilog2(e)) >> 1; while (mask) { ret *= ret; if (e & mask) ret.push_back(0); ret = ret.rem_pre(f, inv); mask >>= 1; } return ret; } public: vector coefs; static R mod; }; R poly::mod; u32 dp[301][3901]; poly init_poly(const u32* dice, u32 T) { rep(i, 0, T + 1) fill(dp[i], dp[i] + dice[5] * i + 1, 0); dp[0][0] = 1; rep(di, 6) rep(t, T) rep(i, t * dice[0], t * dice[di] + 1) if (dp[t][i]) { poly::add(dp[t + 1][i + dice[di]], dp[t][i]); } poly ret(dice[5] * T + 1); rep(i, dice[5] * T + 1) ret[i] = dp[T][i]; return ret; } void solve() { poly::mod = 1e9 + 7; const u32 Ps[] = {2, 3, 5, 7, 11, 13}; const u32 Cs[] = {4, 6, 8, 9, 10, 12}; u64 N; u32 P, C; while (~scanf("%llu %u %u", &N, &P, &C)) { auto p1 = init_poly(Ps, P); auto p2 = init_poly(Cs, C); auto mod_f = -(p1 * p2); mod_f[0] = 1; auto r = poly::x_pow_mod(N + mod_f.size() - 2, mod_f); u64 ans = 0; rep(i, r.size()) ans += r[i]; printf("%llu\n", ans % poly::mod); } } int main() { clock_t beg = clock(); solve(); clock_t end = clock(); fprintf(stderr, "%.3f sec\n", double(end - beg) / CLOCKS_PER_SEC); return 0; }