/*============================================================================= This file is part of FLINT. FLINT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. FLINT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with FLINT; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =============================================================================*/ /****************************************************************************** Copyright (C) 2013 Tom Bachmann ******************************************************************************/ #ifndef ARITHXX_H #define ARITHXX_H #include "arith.h" #include "fmpq_polyxx.h" #include "fmpqxx.h" #include "fmpz_matxx.h" #include "fmpz_vecxx.h" #include "fmpzxx.h" #include "nmod_vecxx.h" // TODO namespace arith? // TODO arith_hrr_expsum_factored // TODO codegen / vector improvements namespace flint { namespace detail { template inline typename T::wrapped_traits::data_srcref_t extract_data(const T& t, typename mp::enable_if >::type* = 0) { return t._data().inner; } template inline typename T::wrapped_traits::data_ref_t extract_data(T& t, typename mp::enable_if >::type* = 0) { return t._data().inner; } template const T& extract_data(const T& t, typename mp::disable_if >::type* = 0) { return t; } template typename T::arrayref_t extract_data(T& t, typename mp::disable_if >::type* = 0, typename mp::enable_if, rules::FMPQ_VECXX_COND_S > >::type* = 0) { return t._array(); } } #define ARITHXX_DEFINE_UNOP(name, Return, Cond) \ FLINT_DEFINE_UNOP(name) \ namespace rules { \ FLINT_DEFINE_UNARY_EXPR_COND(name##_op, Return, Cond, \ arith_##name(detail::extract_data(to), detail::extract_data(from))) \ } #define ARITHXX_DEFINE_BINOP(name, Return, Cond1, Cond2) \ FLINT_DEFINE_BINOP(name) \ namespace rules { \ FLINT_DEFINE_BINARY_EXPR_COND2(name##_op, Return, Cond1, Cond2, \ arith_##name(detail::extract_data(to), detail::extract_data(e1), \ detail::extract_data(e2))) \ } namespace at { template struct slong : traits::fits_into_slong { }; template struct ulong : traits::is_unsigned_integer { }; } // at ARITHXX_DEFINE_UNOP(primorial, fmpzxx, at::slong) ARITHXX_DEFINE_UNOP(harmonic_number, fmpqxx, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_1u, fmpzxx, at::slong, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_1, fmpzxx, at::slong, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_2, fmpzxx, at::slong, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_1u_vec, fmpz_vecxx, at::slong, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_1_vec, fmpz_vecxx, at::slong, at::slong) ARITHXX_DEFINE_BINOP(stirling_number_2_vec, fmpz_vecxx, at::slong, at::slong) FLINT_DEFINE_BINOP(stirling_number_1u_vec_next) FLINT_DEFINE_BINOP(stirling_number_1_vec_next) FLINT_DEFINE_BINOP(stirling_number_2_vec_next) FLINT_DEFINE_BINOP(stirling_matrix_1u) FLINT_DEFINE_BINOP(stirling_matrix_1) FLINT_DEFINE_BINOP(stirling_matrix_2) namespace vectors { template<> struct outsize { template static unsigned get(const Expr& e) {return e._data().second();} }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; template<> struct outsize { template static unsigned get(const Expr& e) { slong r = e._data().first().size(); if(r == e._data().second()) return r + 1; return r; } }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; } // vectors namespace matrices { template<> struct outsize { template static slong rows(const Expr& e) {return e._data().first();} template static slong cols(const Expr& e) {return e._data().second();} }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; } // matrices namespace rules { FLINT_DEFINE_BINARY_EXPR_COND2(stirling_number_1u_vec_next_op, fmpz_vecxx, FMPZ_VECXX_COND_S, at::slong, arith_stirling_number_1u_vec_next(to._array(), e1._array(), e2, e1.size() + (e1.size() == e2))) FLINT_DEFINE_BINARY_EXPR_COND2(stirling_number_1_vec_next_op, fmpz_vecxx, FMPZ_VECXX_COND_S, at::slong, arith_stirling_number_1_vec_next(to._array(), e1._array(), e2, e1.size() + (e1.size() == e2))) FLINT_DEFINE_BINARY_EXPR_COND2(stirling_number_2_vec_next_op, fmpz_vecxx, FMPZ_VECXX_COND_S, at::slong, arith_stirling_number_2_vec_next(to._array(), e1._array(), e2, e1.size() + (e1.size() == e2))) FLINT_DEFINE_BINARY_EXPR_COND2(stirling_matrix_1u_op, fmpz_matxx, at::slong, at::slong, arith_stirling_matrix_1u(to._mat())) FLINT_DEFINE_BINARY_EXPR_COND2(stirling_matrix_1_op, fmpz_matxx, at::slong, at::slong, arith_stirling_matrix_1(to._mat())) FLINT_DEFINE_BINARY_EXPR_COND2(stirling_matrix_2_op, fmpz_matxx, at::slong, at::slong, arith_stirling_matrix_2(to._mat())) } // rules ARITHXX_DEFINE_UNOP(bell_number, fmpzxx, at::ulong) ARITHXX_DEFINE_UNOP(bell_number_bsplit, fmpzxx, at::ulong) ARITHXX_DEFINE_UNOP(bell_number_multi_mod, fmpzxx, at::ulong) ARITHXX_DEFINE_UNOP(bell_number_vec, fmpz_vecxx, at::slong) ARITHXX_DEFINE_UNOP(bell_number_vec_recursive, fmpz_vecxx, at::slong) ARITHXX_DEFINE_UNOP(bell_number_vec_multi_mod, fmpz_vecxx, at::slong) FLINT_DEFINE_BINOP(bell_number_nmod) FLINT_DEFINE_BINOP(bell_number_nmod_vec) FLINT_DEFINE_BINOP(bell_number_nmod_vec_recursive) FLINT_DEFINE_BINOP(bell_number_nmod_vec_series) namespace vectors { template<> struct outsize { template static unsigned get(const Expr& e) {return e._data().first();} }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; } // vectors namespace at { template struct nmod : mp::or_, mp::equal_types > { }; } // at #define NMODXX_DEFINE_FIND_CTX_BY_OP(exprname, eval) \ namespace traits { \ template \ struct has_nmodxx_ctx< exprname, Data> > : mp::true_ { }; \ } \ namespace detail { \ template \ struct get_nmodxx_ctx > \ { \ template \ static nmodxx_ctx_srcref get(const T& e) {return eval;} \ }; \ } #define FLINTXX_COMMA() , NMODXX_DEFINE_FIND_CTX_BY_OP(nmodxx_expression struct outsize { template static unsigned get(const Expr& e) {return e._data().first();} }; } // vectors ARITHXX_DEFINE_UNOP(euler_number, fmpzxx, at::ulong) ARITHXX_DEFINE_UNOP(euler_number_vec, fmpz_vecxx, at::ulong) ARITHXX_DEFINE_UNOP(euler_polynomial, fmpq_polyxx, at::ulong) namespace vectors { template<> struct outsize : outsize { }; } ARITHXX_DEFINE_UNOP(legendre_polynomial, fmpq_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(chebyshev_t_polynomial, fmpz_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(chebyshev_u_polynomial, fmpz_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(euler_phi, fmpzxx, FMPZXX_COND_S) ARITHXX_DEFINE_BINOP(divisor_sigma, fmpzxx, FMPZXX_COND_S, at::ulong) ARITHXX_DEFINE_UNOP(divisors, fmpz_polyxx, FMPZXX_COND_S) ARITHXX_DEFINE_UNOP(ramanujan_tau, fmpzxx, FMPZXX_COND_S) ARITHXX_DEFINE_UNOP(ramanujan_tau_series, fmpz_polyxx, at::slong) ARITHXX_DEFINE_UNOP(cyclotomic_polynomial, fmpz_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(cos_minpoly, fmpz_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(swinnerton_dyer_polynomial, fmpz_polyxx, at::ulong) ARITHXX_DEFINE_UNOP(landau_function_vec, fmpz_vecxx, at::slong) namespace vectors { template<> struct outsize : outsize { }; } ARITHXX_DEFINE_BINOP(dedekind_sum_naive, fmpqxx, FMPZXX_COND_S, FMPZXX_COND_S) ARITHXX_DEFINE_BINOP(dedekind_sum_coprime_large, fmpqxx, FMPZXX_COND_S, FMPZXX_COND_S) ARITHXX_DEFINE_BINOP(dedekind_sum_coprime, fmpqxx, FMPZXX_COND_S, FMPZXX_COND_S) ARITHXX_DEFINE_BINOP(dedekind_sum, fmpqxx, FMPZXX_COND_S, FMPZXX_COND_S) ARITHXX_DEFINE_UNOP(number_of_partitions_vec, fmpz_vecxx, at::slong) ARITHXX_DEFINE_UNOP(number_of_partitions, fmpzxx, at::ulong) FLINT_DEFINE_BINOP(number_of_partitions_nmod_vec) namespace vectors { template<> struct outsize : outsize { }; template<> struct outsize : outsize { }; } NMODXX_DEFINE_FIND_CTX_BY_OP(vector_expression struct outsize : outsize { }; } inline double bell_number_size(ulong n) {return arith_bell_number_size(n);} inline double bernoulli_number_size(ulong n) {return arith_bernoulli_number_size(n);} inline double euler_number_size(ulong n) {return arith_euler_number_size(n);} inline double dedekind_sum_coprime_d(double h, double k) {return arith_dedekind_sum_coprime_d(h, k);} template inline typename mp::enable_if, int>::type moebius_mu( const Fmpz& n) { return arith_moebius_mu(n.evaluate()._fmpz()); } } // flint #endif