/////////////////////////////////////////////////////////////////////////////// // Copyright 2011 John Maddock. Distributed under the Boost // Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_MATH_ER_GMP_BACKEND_HPP #define BOOST_MATH_ER_GMP_BACKEND_HPP #include #include #include #include #include #include #ifdef BOOST_MSVC # pragma warning(push) # pragma warning(disable:4127) #endif #include #ifdef BOOST_MSVC # pragma warning(pop) #endif #include #include #include namespace boost{ namespace multiprecision{ namespace backends{ #ifdef BOOST_MSVC // warning C4127: conditional expression is constant #pragma warning(push) #pragma warning(disable:4127) #endif template struct gmp_float; struct gmp_int; struct gmp_rational; } // namespace backends template<> struct number_category : public mpl::int_{}; template<> struct number_category : public mpl::int_{}; template struct number_category > : public mpl::int_{}; namespace backends{ // // Within this file, the only functions we mark as noexcept are those that manipulate // (but don't create) an mpf_t. All other types may allocate at pretty much any time // via a user-supplied allocator, and therefore throw. // namespace detail{ template struct gmp_float_imp { typedef mpl::list signed_types; typedef mpl::list unsigned_types; typedef mpl::list float_types; typedef long exponent_type; gmp_float_imp() BOOST_NOEXCEPT {} gmp_float_imp(const gmp_float_imp& o) { // // We have to do an init followed by a set here, otherwise *this may be at // a lower precision than o: seems like mpf_init_set copies just enough bits // to get the right value, but if it's then used in further calculations // things go badly wrong!! // mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); if(o.m_data[0]._mp_d) mpf_set(m_data, o.m_data); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float_imp(gmp_float_imp&& o) BOOST_NOEXCEPT { m_data[0] = o.m_data[0]; o.m_data[0]._mp_d = 0; } #endif gmp_float_imp& operator = (const gmp_float_imp& o) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); if(o.m_data[0]._mp_d) mpf_set(m_data, o.m_data); return *this; } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float_imp& operator = (gmp_float_imp&& o) BOOST_NOEXCEPT { mpf_swap(m_data, o.m_data); return *this; } #endif gmp_float_imp& operator = (unsigned long long i) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); unsigned long long mask = ((1uLL << std::numeric_limits::digits) - 1); unsigned shift = 0; mpf_t t; mpf_init2(t, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); mpf_set_ui(m_data, 0); while(i) { mpf_set_ui(t, static_cast(i & mask)); if(shift) mpf_mul_2exp(t, t, shift); mpf_add(m_data, m_data, t); shift += std::numeric_limits::digits; i >>= std::numeric_limits::digits; } mpf_clear(t); return *this; } gmp_float_imp& operator = (long long i) { BOOST_MP_USING_ABS if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); bool neg = i < 0; *this = static_cast(abs(i)); if(neg) mpf_neg(m_data, m_data); return *this; } gmp_float_imp& operator = (unsigned long i) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); mpf_set_ui(m_data, i); return *this; } gmp_float_imp& operator = (long i) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); mpf_set_si(m_data, i); return *this; } gmp_float_imp& operator = (double d) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); mpf_set_d(m_data, d); return *this; } gmp_float_imp& operator = (long double a) { using std::frexp; using std::ldexp; using std::floor; if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); if (a == 0) { mpf_set_si(m_data, 0); return *this; } if (a == 1) { mpf_set_si(m_data, 1); return *this; } BOOST_ASSERT(!(boost::math::isinf)(a)); BOOST_ASSERT(!(boost::math::isnan)(a)); int e; long double f, term; mpf_init_set_ui(m_data, 0u); f = frexp(a, &e); static const int shift = std::numeric_limits::digits - 1; while(f) { // extract int sized bits from f: f = ldexp(f, shift); term = floor(f); e -= shift; mpf_mul_2exp(m_data, m_data, shift); if(term > 0) mpf_add_ui(m_data, m_data, static_cast(term)); else mpf_sub_ui(m_data, m_data, static_cast(-term)); f -= term; } if(e > 0) mpf_mul_2exp(m_data, m_data, e); else if(e < 0) mpf_div_2exp(m_data, m_data, -e); return *this; } gmp_float_imp& operator = (const char* s) { if(m_data[0]._mp_d == 0) mpf_init2(m_data, multiprecision::detail::digits10_2_2(digits10 ? digits10 : get_default_precision())); if(0 != mpf_set_str(m_data, s, 10)) BOOST_THROW_EXCEPTION(std::runtime_error(std::string("The string \"") + s + std::string("\"could not be interpreted as a valid floating point number."))); return *this; } void swap(gmp_float_imp& o) BOOST_NOEXCEPT { mpf_swap(m_data, o.m_data); } std::string str(std::streamsize digits, std::ios_base::fmtflags f)const { BOOST_ASSERT(m_data[0]._mp_d); bool scientific = (f & std::ios_base::scientific) == std::ios_base::scientific; bool fixed = (f & std::ios_base::fixed) == std::ios_base::fixed; std::streamsize org_digits(digits); if(scientific && digits) ++digits; std::string result; mp_exp_t e; void *(*alloc_func_ptr) (size_t); void *(*realloc_func_ptr) (void *, size_t, size_t); void (*free_func_ptr) (void *, size_t); mp_get_memory_functions(&alloc_func_ptr, &realloc_func_ptr, &free_func_ptr); if(mpf_sgn(m_data) == 0) { e = 0; result = "0"; if(fixed && digits) ++digits; } else { char* ps = mpf_get_str (0, &e, 10, static_cast(digits), m_data); --e; // To match with what our formatter expects. if(fixed && e != -1) { // Oops we actually need a different number of digits to what we asked for: (*free_func_ptr)((void*)ps, std::strlen(ps) + 1); digits += e + 1; if(digits == 0) { // We need to get *all* the digits and then possibly round up, // we end up with either "0" or "1" as the result. ps = mpf_get_str (0, &e, 10, 0, m_data); --e; unsigned offset = *ps == '-' ? 1 : 0; if(ps[offset] > '5') { ++e; ps[offset] = '1'; ps[offset + 1] = 0; } else if(ps[offset] == '5') { unsigned i = offset + 1; bool round_up = false; while(ps[i] != 0) { if(ps[i] != '0') { round_up = true; break; } } if(round_up) { ++e; ps[offset] = '1'; ps[offset + 1] = 0; } else { ps[offset] = '0'; ps[offset + 1] = 0; } } else { ps[offset] = '0'; ps[offset + 1] = 0; } } else if(digits > 0) { ps = mpf_get_str (0, &e, 10, static_cast(digits), m_data); --e; // To match with what our formatter expects. } else { ps = mpf_get_str (0, &e, 10, 1, m_data); --e; unsigned offset = *ps == '-' ? 1 : 0; ps[offset] = '0'; ps[offset + 1] = 0; } } result = ps; (*free_func_ptr)((void*)ps, std::strlen(ps) + 1); } boost::multiprecision::detail::format_float_string(result, e, org_digits, f, mpf_sgn(m_data) == 0); return result; } ~gmp_float_imp() BOOST_NOEXCEPT { if(m_data[0]._mp_d) mpf_clear(m_data); } void negate() BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d); mpf_neg(m_data, m_data); } int compare(const gmp_float& o)const BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d && o.m_data[0]._mp_d); return mpf_cmp(m_data, o.m_data); } int compare(long i)const BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d); return mpf_cmp_si(m_data, i); } int compare(unsigned long i)const BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d); return mpf_cmp_ui(m_data, i); } template typename enable_if, int>::type compare(V v)const { gmp_float d; d = v; return compare(d); } mpf_t& data() BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d); return m_data; } const mpf_t& data()const BOOST_NOEXCEPT { BOOST_ASSERT(m_data[0]._mp_d); return m_data; } protected: mpf_t m_data; static unsigned& get_default_precision() BOOST_NOEXCEPT { static unsigned val = 50; return val; } }; } // namespace detail struct gmp_int; struct gmp_rational; template struct gmp_float : public detail::gmp_float_imp { gmp_float() { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); } gmp_float(const gmp_float& o) : detail::gmp_float_imp(o) {} template gmp_float(const gmp_float& o, typename enable_if_c::type* = 0); template explicit gmp_float(const gmp_float& o, typename disable_if_c::type* = 0); gmp_float(const gmp_int& o); gmp_float(const gmp_rational& o); gmp_float(const mpf_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set(this->m_data, val); } gmp_float(const mpz_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set_z(this->m_data, val); } gmp_float(const mpq_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set_q(this->m_data, val); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float(gmp_float&& o) BOOST_NOEXCEPT : detail::gmp_float_imp(static_cast&&>(o)) {} #endif gmp_float& operator=(const gmp_float& o) { *static_cast*>(this) = static_cast const&>(o); return *this; } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float& operator=(gmp_float&& o) BOOST_NOEXCEPT { *static_cast*>(this) = static_cast&&>(o); return *this; } #endif template gmp_float& operator=(const gmp_float& o); gmp_float& operator=(const gmp_int& o); gmp_float& operator=(const gmp_rational& o); gmp_float& operator=(const mpf_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set(this->m_data, val); return *this; } gmp_float& operator=(const mpz_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set_z(this->m_data, val); return *this; } gmp_float& operator=(const mpq_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set_q(this->m_data, val); return *this; } template gmp_float& operator=(const V& v) { *static_cast*>(this) = v; return *this; } }; template <> struct gmp_float<0> : public detail::gmp_float_imp<0> { gmp_float() { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); } gmp_float(const mpf_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set(this->m_data, val); } gmp_float(const mpz_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_z(this->m_data, val); } gmp_float(const mpq_t val) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_q(this->m_data, val); } gmp_float(const gmp_float& o) : detail::gmp_float_imp<0>(o) {} template gmp_float(const gmp_float& o) { mpf_init2(this->m_data, mpf_get_prec(o.data())); mpf_set(this->m_data, o.data()); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float(gmp_float&& o) BOOST_NOEXCEPT : detail::gmp_float_imp<0>(static_cast&&>(o)) {} #endif gmp_float(const gmp_int& o); gmp_float(const gmp_rational& o); gmp_float(const gmp_float& o, unsigned digits10) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(digits10)); mpf_set(this->m_data, o.data()); } gmp_float& operator=(const gmp_float& o) { *static_cast*>(this) = static_cast const&>(o); return *this; } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_float& operator=(gmp_float&& o) BOOST_NOEXCEPT { *static_cast*>(this) = static_cast &&>(o); return *this; } #endif template gmp_float& operator=(const gmp_float& o) { if(this->m_data[0]._mp_d == 0) { mpf_init2(this->m_data, mpf_get_prec(o.data())); } else { mpf_set_prec(this->m_data, mpf_get_prec(o.data())); } mpf_set(this->m_data, o.data()); return *this; } gmp_float& operator=(const gmp_int& o); gmp_float& operator=(const gmp_rational& o); gmp_float& operator=(const mpf_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set(this->m_data, val); return *this; } gmp_float& operator=(const mpz_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_z(this->m_data, val); return *this; } gmp_float& operator=(const mpq_t val) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_q(this->m_data, val); return *this; } template gmp_float& operator=(const V& v) { *static_cast*>(this) = v; return *this; } static unsigned default_precision() BOOST_NOEXCEPT { return get_default_precision(); } static void default_precision(unsigned v) BOOST_NOEXCEPT { get_default_precision() = v; } unsigned precision()const BOOST_NOEXCEPT { return multiprecision::detail::digits2_2_10(mpf_get_prec(this->m_data)); } void precision(unsigned digits10) BOOST_NOEXCEPT { mpf_set_prec(this->m_data, multiprecision::detail::digits10_2_2(digits10)); } }; template inline typename enable_if_c::value, bool>::type eval_eq(const gmp_float& a, const T& b) BOOST_NOEXCEPT { return a.compare(b) == 0; } template inline typename enable_if_c::value, bool>::type eval_lt(const gmp_float& a, const T& b) BOOST_NOEXCEPT { return a.compare(b) < 0; } template inline typename enable_if_c::value, bool>::type eval_gt(const gmp_float& a, const T& b) BOOST_NOEXCEPT { return a.compare(b) > 0; } template inline void eval_add(gmp_float& result, const gmp_float& o) { mpf_add(result.data(), result.data(), o.data()); } template inline void eval_subtract(gmp_float& result, const gmp_float& o) { mpf_sub(result.data(), result.data(), o.data()); } template inline void eval_multiply(gmp_float& result, const gmp_float& o) { mpf_mul(result.data(), result.data(), o.data()); } template inline bool eval_is_zero(const gmp_float& val) BOOST_NOEXCEPT { return mpf_sgn(val.data()) == 0; } template inline void eval_divide(gmp_float& result, const gmp_float& o) { if(eval_is_zero(o)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_div(result.data(), result.data(), o.data()); } template inline void eval_add(gmp_float& result, unsigned long i) { mpf_add_ui(result.data(), result.data(), i); } template inline void eval_subtract(gmp_float& result, unsigned long i) { mpf_sub_ui(result.data(), result.data(), i); } template inline void eval_multiply(gmp_float& result, unsigned long i) { mpf_mul_ui(result.data(), result.data(), i); } template inline void eval_divide(gmp_float& result, unsigned long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_div_ui(result.data(), result.data(), i); } template inline void eval_add(gmp_float& result, long i) { if(i > 0) mpf_add_ui(result.data(), result.data(), i); else mpf_sub_ui(result.data(), result.data(), std::abs(i)); } template inline void eval_subtract(gmp_float& result, long i) { if(i > 0) mpf_sub_ui(result.data(), result.data(), i); else mpf_add_ui(result.data(), result.data(), std::abs(i)); } template inline void eval_multiply(gmp_float& result, long i) { mpf_mul_ui(result.data(), result.data(), std::abs(i)); if(i < 0) mpf_neg(result.data(), result.data()); } template inline void eval_divide(gmp_float& result, long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_div_ui(result.data(), result.data(), std::abs(i)); if(i < 0) mpf_neg(result.data(), result.data()); } // // Specialised 3 arg versions of the basic operators: // template inline void eval_add(gmp_float& a, const gmp_float& x, const gmp_float& y) { mpf_add(a.data(), x.data(), y.data()); } template inline void eval_add(gmp_float& a, const gmp_float& x, unsigned long y) { mpf_add_ui(a.data(), x.data(), y); } template inline void eval_add(gmp_float& a, const gmp_float& x, long y) { if(y < 0) mpf_sub_ui(a.data(), x.data(), -y); else mpf_add_ui(a.data(), x.data(), y); } template inline void eval_add(gmp_float& a, unsigned long x, const gmp_float& y) { mpf_add_ui(a.data(), y.data(), x); } template inline void eval_add(gmp_float& a, long x, const gmp_float& y) { if(x < 0) { mpf_ui_sub(a.data(), -x, y.data()); mpf_neg(a.data(), a.data()); } else mpf_add_ui(a.data(), y.data(), x); } template inline void eval_subtract(gmp_float& a, const gmp_float& x, const gmp_float& y) { mpf_sub(a.data(), x.data(), y.data()); } template inline void eval_subtract(gmp_float& a, const gmp_float& x, unsigned long y) { mpf_sub_ui(a.data(), x.data(), y); } template inline void eval_subtract(gmp_float& a, const gmp_float& x, long y) { if(y < 0) mpf_add_ui(a.data(), x.data(), -y); else mpf_sub_ui(a.data(), x.data(), y); } template inline void eval_subtract(gmp_float& a, unsigned long x, const gmp_float& y) { mpf_ui_sub(a.data(), x, y.data()); } template inline void eval_subtract(gmp_float& a, long x, const gmp_float& y) { if(x < 0) { mpf_add_ui(a.data(), y.data(), -x); mpf_neg(a.data(), a.data()); } else mpf_ui_sub(a.data(), x, y.data()); } template inline void eval_multiply(gmp_float& a, const gmp_float& x, const gmp_float& y) { mpf_mul(a.data(), x.data(), y.data()); } template inline void eval_multiply(gmp_float& a, const gmp_float& x, unsigned long y) { mpf_mul_ui(a.data(), x.data(), y); } template inline void eval_multiply(gmp_float& a, const gmp_float& x, long y) { if(y < 0) { mpf_mul_ui(a.data(), x.data(), -y); a.negate(); } else mpf_mul_ui(a.data(), x.data(), y); } template inline void eval_multiply(gmp_float& a, unsigned long x, const gmp_float& y) { mpf_mul_ui(a.data(), y.data(), x); } template inline void eval_multiply(gmp_float& a, long x, const gmp_float& y) { if(x < 0) { mpf_mul_ui(a.data(), y.data(), -x); mpf_neg(a.data(), a.data()); } else mpf_mul_ui(a.data(), y.data(), x); } template inline void eval_divide(gmp_float& a, const gmp_float& x, const gmp_float& y) { if(eval_is_zero(y)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_div(a.data(), x.data(), y.data()); } template inline void eval_divide(gmp_float& a, const gmp_float& x, unsigned long y) { if(y == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_div_ui(a.data(), x.data(), y); } template inline void eval_divide(gmp_float& a, const gmp_float& x, long y) { if(y == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); if(y < 0) { mpf_div_ui(a.data(), x.data(), -y); a.negate(); } else mpf_div_ui(a.data(), x.data(), y); } template inline void eval_divide(gmp_float& a, unsigned long x, const gmp_float& y) { if(eval_is_zero(y)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpf_ui_div(a.data(), x, y.data()); } template inline void eval_divide(gmp_float& a, long x, const gmp_float& y) { if(eval_is_zero(y)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); if(x < 0) { mpf_ui_div(a.data(), -x, y.data()); mpf_neg(a.data(), a.data()); } else mpf_ui_div(a.data(), x, y.data()); } template inline int eval_get_sign(const gmp_float& val) BOOST_NOEXCEPT { return mpf_sgn(val.data()); } template inline void eval_convert_to(unsigned long* result, const gmp_float& val) BOOST_NOEXCEPT { if(0 == mpf_fits_ulong_p(val.data())) *result = (std::numeric_limits::max)(); else *result = mpf_get_ui(val.data()); } template inline void eval_convert_to(long* result, const gmp_float& val) BOOST_NOEXCEPT { if(0 == mpf_fits_slong_p(val.data())) { *result = (std::numeric_limits::max)(); *result *= mpf_sgn(val.data()); } else *result = mpf_get_si(val.data()); } template inline void eval_convert_to(double* result, const gmp_float& val) BOOST_NOEXCEPT { *result = mpf_get_d(val.data()); } #ifdef BOOST_HAS_LONG_LONG template inline void eval_convert_to(long long* result, const gmp_float& val) { gmp_float t(val); if(eval_get_sign(t) < 0) t.negate(); long digits = std::numeric_limits::digits - std::numeric_limits::digits; if(digits > 0) mpf_div_2exp(t.data(), t.data(), digits); if(!mpf_fits_slong_p(t.data())) { if(eval_get_sign(val) < 0) *result = (std::numeric_limits::min)(); else *result = (std::numeric_limits::max)(); return; }; *result = mpf_get_si(t.data()); while(digits > 0) { *result <<= digits; digits -= std::numeric_limits::digits; mpf_mul_2exp(t.data(), t.data(), digits >= 0 ? std::numeric_limits::digits : std::numeric_limits::digits + digits); unsigned long l = mpf_get_ui(t.data()); if(digits < 0) l >>= -digits; *result |= l; } if(eval_get_sign(val) < 0) *result = -*result; } template inline void eval_convert_to(unsigned long long* result, const gmp_float& val) { gmp_float t(val); long digits = std::numeric_limits::digits - std::numeric_limits::digits; if(digits > 0) mpf_div_2exp(t.data(), t.data(), digits); if(!mpf_fits_ulong_p(t.data())) { *result = (std::numeric_limits::max)(); return; } *result = mpf_get_ui(t.data()); while(digits > 0) { *result <<= digits; digits -= std::numeric_limits::digits; mpf_mul_2exp(t.data(), t.data(), digits >= 0 ? std::numeric_limits::digits : std::numeric_limits::digits + digits); unsigned long l = mpf_get_ui(t.data()); if(digits < 0) l >>= -digits; *result |= l; } } #endif // // Native non-member operations: // template inline void eval_sqrt(gmp_float& result, const gmp_float& val) { mpf_sqrt(result.data(), val.data()); } template inline void eval_abs(gmp_float& result, const gmp_float& val) { mpf_abs(result.data(), val.data()); } template inline void eval_fabs(gmp_float& result, const gmp_float& val) { mpf_abs(result.data(), val.data()); } template inline void eval_ceil(gmp_float& result, const gmp_float& val) { mpf_ceil(result.data(), val.data()); } template inline void eval_floor(gmp_float& result, const gmp_float& val) { mpf_floor(result.data(), val.data()); } template inline void eval_trunc(gmp_float& result, const gmp_float& val) { mpf_trunc(result.data(), val.data()); } template inline void eval_ldexp(gmp_float& result, const gmp_float& val, long e) { if(e > 0) mpf_mul_2exp(result.data(), val.data(), e); else if(e < 0) mpf_div_2exp(result.data(), val.data(), -e); else result = val; } template inline void eval_frexp(gmp_float& result, const gmp_float& val, int* e) { long v; mpf_get_d_2exp(&v, val.data()); *e = v; eval_ldexp(result, val, -v); } template inline void eval_frexp(gmp_float& result, const gmp_float& val, long* e) { mpf_get_d_2exp(e, val.data()); eval_ldexp(result, val, -*e); } struct gmp_int { typedef mpl::list signed_types; typedef mpl::list unsigned_types; typedef mpl::list float_types; gmp_int() { mpz_init(this->m_data); } gmp_int(const gmp_int& o) { if(o.m_data[0]._mp_d) mpz_init_set(m_data, o.m_data); else mpz_init(this->m_data); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_int(gmp_int&& o) BOOST_NOEXCEPT { m_data[0] = o.m_data[0]; o.m_data[0]._mp_d = 0; } #endif explicit gmp_int(const mpf_t val) { mpz_init(this->m_data); mpz_set_f(this->m_data, val); } gmp_int(const mpz_t val) { mpz_init_set(this->m_data, val); } explicit gmp_int(const mpq_t val) { mpz_init(this->m_data); mpz_set_q(this->m_data, val); } template explicit gmp_int(const gmp_float& o) { mpz_init(this->m_data); mpz_set_f(this->m_data, o.data()); } explicit gmp_int(const gmp_rational& o); gmp_int& operator = (const gmp_int& o) { if(o.m_data[0]._mp_d) mpz_set(m_data, o.m_data); return *this; } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_int& operator = (gmp_int&& o) BOOST_NOEXCEPT { mpz_swap(m_data, o.m_data); return *this; } #endif gmp_int& operator = (unsigned long long i) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); unsigned long long mask = ((1uLL << std::numeric_limits::digits) - 1); unsigned shift = 0; mpz_t t; mpz_set_ui(m_data, 0); mpz_init_set_ui(t, 0); while(i) { mpz_set_ui(t, static_cast(i & mask)); if(shift) mpz_mul_2exp(t, t, shift); mpz_add(m_data, m_data, t); shift += std::numeric_limits::digits; i >>= std::numeric_limits::digits; } mpz_clear(t); return *this; } gmp_int& operator = (long long i) { BOOST_MP_USING_ABS if(m_data[0]._mp_d == 0) mpz_init(this->m_data); bool neg = i < 0; *this = static_cast(abs(i)); if(neg) mpz_neg(m_data, m_data); return *this; } gmp_int& operator = (unsigned long i) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_ui(m_data, i); return *this; } gmp_int& operator = (long i) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_si(m_data, i); return *this; } gmp_int& operator = (double d) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_d(m_data, d); return *this; } gmp_int& operator = (long double a) { using std::frexp; using std::ldexp; using std::floor; if(m_data[0]._mp_d == 0) mpz_init(this->m_data); if (a == 0) { mpz_set_si(m_data, 0); return *this; } if (a == 1) { mpz_set_si(m_data, 1); return *this; } BOOST_ASSERT(!(boost::math::isinf)(a)); BOOST_ASSERT(!(boost::math::isnan)(a)); int e; long double f, term; mpz_set_ui(m_data, 0u); f = frexp(a, &e); static const int shift = std::numeric_limits::digits - 1; while(f) { // extract int sized bits from f: f = ldexp(f, shift); term = floor(f); e -= shift; mpz_mul_2exp(m_data, m_data, shift); if(term > 0) mpz_add_ui(m_data, m_data, static_cast(term)); else mpz_sub_ui(m_data, m_data, static_cast(-term)); f -= term; } if(e > 0) mpz_mul_2exp(m_data, m_data, e); else if(e < 0) mpz_div_2exp(m_data, m_data, -e); return *this; } gmp_int& operator = (const char* s) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); std::size_t n = s ? std::strlen(s) : 0; int radix = 10; if(n && (*s == '0')) { if((n > 1) && ((s[1] == 'x') || (s[1] == 'X'))) { radix = 16; s +=2; n -= 2; } else { radix = 8; n -= 1; } } if(n) { if(0 != mpz_set_str(m_data, s, radix)) BOOST_THROW_EXCEPTION(std::runtime_error(std::string("The string \"") + s + std::string("\"could not be interpreted as a valid integer."))); } else mpz_set_ui(m_data, 0); return *this; } gmp_int& operator=(const mpf_t val) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_f(this->m_data, val); return *this; } gmp_int& operator=(const mpz_t val) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set(this->m_data, val); return *this; } gmp_int& operator=(const mpq_t val) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_q(this->m_data, val); return *this; } template gmp_int& operator=(const gmp_float& o) { if(m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_f(this->m_data, o.data()); return *this; } gmp_int& operator=(const gmp_rational& o); void swap(gmp_int& o) { mpz_swap(m_data, o.m_data); } std::string str(std::streamsize /*digits*/, std::ios_base::fmtflags f)const { BOOST_ASSERT(m_data[0]._mp_d); int base = 10; if((f & std::ios_base::oct) == std::ios_base::oct) base = 8; else if((f & std::ios_base::hex) == std::ios_base::hex) base = 16; // // sanity check, bases 8 and 16 are only available for positive numbers: // if((base != 10) && (mpz_sgn(m_data) < 0)) BOOST_THROW_EXCEPTION(std::runtime_error("Formatted output in bases 8 or 16 is only available for positive numbers")); void *(*alloc_func_ptr) (size_t); void *(*realloc_func_ptr) (void *, size_t, size_t); void (*free_func_ptr) (void *, size_t); const char* ps = mpz_get_str (0, base, m_data); std::string s = ps; mp_get_memory_functions(&alloc_func_ptr, &realloc_func_ptr, &free_func_ptr); (*free_func_ptr)((void*)ps, std::strlen(ps) + 1); if((base != 10) && (f & std::ios_base::showbase)) { int pos = s[0] == '-' ? 1 : 0; const char* pp = base == 8 ? "0" : "0x"; s.insert(pos, pp); } if((f & std::ios_base::showpos) && (s[0] != '-')) s.insert(0, 1, '+'); return s; } ~gmp_int() { if(m_data[0]._mp_d) mpz_clear(m_data); } void negate() { BOOST_ASSERT(m_data[0]._mp_d); mpz_neg(m_data, m_data); } int compare(const gmp_int& o)const { BOOST_ASSERT(m_data[0]._mp_d && o.m_data[0]._mp_d); return mpz_cmp(m_data, o.m_data); } int compare(long i)const { BOOST_ASSERT(m_data[0]._mp_d); return mpz_cmp_si(m_data, i); } int compare(unsigned long i)const { BOOST_ASSERT(m_data[0]._mp_d); return mpz_cmp_ui(m_data, i); } template int compare(V v)const { gmp_int d; d = v; return compare(d); } mpz_t& data() { BOOST_ASSERT(m_data[0]._mp_d); return m_data; } const mpz_t& data()const { BOOST_ASSERT(m_data[0]._mp_d); return m_data; } protected: mpz_t m_data; }; template inline typename enable_if, bool>::type eval_eq(const gmp_int& a, const T& b) { return a.compare(b) == 0; } template inline typename enable_if, bool>::type eval_lt(const gmp_int& a, const T& b) { return a.compare(b) < 0; } template inline typename enable_if, bool>::type eval_gt(const gmp_int& a, const T& b) { return a.compare(b) > 0; } inline bool eval_is_zero(const gmp_int& val) { return mpz_sgn(val.data()) == 0; } inline void eval_add(gmp_int& t, const gmp_int& o) { mpz_add(t.data(), t.data(), o.data()); } inline void eval_multiply_add(gmp_int& t, const gmp_int& a, const gmp_int& b) { mpz_addmul(t.data(), a.data(), b.data()); } inline void eval_multiply_subtract(gmp_int& t, const gmp_int& a, const gmp_int& b) { mpz_submul(t.data(), a.data(), b.data()); } inline void eval_subtract(gmp_int& t, const gmp_int& o) { mpz_sub(t.data(), t.data(), o.data()); } inline void eval_multiply(gmp_int& t, const gmp_int& o) { mpz_mul(t.data(), t.data(), o.data()); } inline void eval_divide(gmp_int& t, const gmp_int& o) { if(eval_is_zero(o)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q(t.data(), t.data(), o.data()); } inline void eval_modulus(gmp_int& t, const gmp_int& o) { mpz_tdiv_r(t.data(), t.data(), o.data()); } inline void eval_add(gmp_int& t, unsigned long i) { mpz_add_ui(t.data(), t.data(), i); } inline void eval_multiply_add(gmp_int& t, const gmp_int& a, unsigned long i) { mpz_addmul_ui(t.data(), a.data(), i); } inline void eval_multiply_subtract(gmp_int& t, const gmp_int& a, unsigned long i) { mpz_submul_ui(t.data(), a.data(), i); } inline void eval_subtract(gmp_int& t, unsigned long i) { mpz_sub_ui(t.data(), t.data(), i); } inline void eval_multiply(gmp_int& t, unsigned long i) { mpz_mul_ui(t.data(), t.data(), i); } inline void eval_modulus(gmp_int& t, unsigned long i) { mpz_tdiv_r_ui(t.data(), t.data(), i); } inline void eval_divide(gmp_int& t, unsigned long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q_ui(t.data(), t.data(), i); } inline void eval_add(gmp_int& t, long i) { if(i > 0) mpz_add_ui(t.data(), t.data(), i); else mpz_sub_ui(t.data(), t.data(), -i); } inline void eval_multiply_add(gmp_int& t, const gmp_int& a, long i) { if(i > 0) mpz_addmul_ui(t.data(), a.data(), i); else mpz_submul_ui(t.data(), a.data(), -i); } inline void eval_multiply_subtract(gmp_int& t, const gmp_int& a, long i) { if(i > 0) mpz_submul_ui(t.data(), a.data(), i); else mpz_addmul_ui(t.data(), a.data(), -i); } inline void eval_subtract(gmp_int& t, long i) { if(i > 0) mpz_sub_ui(t.data(), t.data(), i); else mpz_add_ui(t.data(), t.data(), -i); } inline void eval_multiply(gmp_int& t, long i) { mpz_mul_ui(t.data(), t.data(), std::abs(i)); if(i < 0) mpz_neg(t.data(), t.data()); } inline void eval_modulus(gmp_int& t, long i) { mpz_tdiv_r_ui(t.data(), t.data(), std::abs(i)); } inline void eval_divide(gmp_int& t, long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q_ui(t.data(), t.data(), std::abs(i)); if(i < 0) mpz_neg(t.data(), t.data()); } template inline void eval_left_shift(gmp_int& t, UI i) { mpz_mul_2exp(t.data(), t.data(), static_cast(i)); } template inline void eval_right_shift(gmp_int& t, UI i) { mpz_fdiv_q_2exp(t.data(), t.data(), static_cast(i)); } template inline void eval_left_shift(gmp_int& t, const gmp_int& v, UI i) { mpz_mul_2exp(t.data(), v.data(), static_cast(i)); } template inline void eval_right_shift(gmp_int& t, const gmp_int& v, UI i) { mpz_fdiv_q_2exp(t.data(), v.data(), static_cast(i)); } inline void eval_bitwise_and(gmp_int& result, const gmp_int& v) { mpz_and(result.data(), result.data(), v.data()); } inline void eval_bitwise_or(gmp_int& result, const gmp_int& v) { mpz_ior(result.data(), result.data(), v.data()); } inline void eval_bitwise_xor(gmp_int& result, const gmp_int& v) { mpz_xor(result.data(), result.data(), v.data()); } inline void eval_add(gmp_int& t, const gmp_int& p, const gmp_int& o) { mpz_add(t.data(), p.data(), o.data()); } inline void eval_subtract(gmp_int& t, const gmp_int& p, const gmp_int& o) { mpz_sub(t.data(), p.data(), o.data()); } inline void eval_multiply(gmp_int& t, const gmp_int& p, const gmp_int& o) { mpz_mul(t.data(), p.data(), o.data()); } inline void eval_divide(gmp_int& t, const gmp_int& p, const gmp_int& o) { if(eval_is_zero(o)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q(t.data(), p.data(), o.data()); } inline void eval_modulus(gmp_int& t, const gmp_int& p, const gmp_int& o) { mpz_tdiv_r(t.data(), p.data(), o.data()); } inline void eval_add(gmp_int& t, const gmp_int& p, unsigned long i) { mpz_add_ui(t.data(), p.data(), i); } inline void eval_subtract(gmp_int& t, const gmp_int& p, unsigned long i) { mpz_sub_ui(t.data(), p.data(), i); } inline void eval_multiply(gmp_int& t, const gmp_int& p, unsigned long i) { mpz_mul_ui(t.data(), p.data(), i); } inline void eval_modulus(gmp_int& t, const gmp_int& p, unsigned long i) { mpz_tdiv_r_ui(t.data(), p.data(), i); } inline void eval_divide(gmp_int& t, const gmp_int& p, unsigned long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q_ui(t.data(), p.data(), i); } inline void eval_add(gmp_int& t, const gmp_int& p, long i) { if(i > 0) mpz_add_ui(t.data(), p.data(), i); else mpz_sub_ui(t.data(), p.data(), -i); } inline void eval_subtract(gmp_int& t, const gmp_int& p, long i) { if(i > 0) mpz_sub_ui(t.data(), p.data(), i); else mpz_add_ui(t.data(), p.data(), -i); } inline void eval_multiply(gmp_int& t, const gmp_int& p, long i) { mpz_mul_ui(t.data(), p.data(), std::abs(i)); if(i < 0) mpz_neg(t.data(), t.data()); } inline void eval_modulus(gmp_int& t, const gmp_int& p, long i) { mpz_tdiv_r_ui(t.data(), p.data(), std::abs(i)); } inline void eval_divide(gmp_int& t, const gmp_int& p, long i) { if(i == 0) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpz_tdiv_q_ui(t.data(), p.data(), std::abs(i)); if(i < 0) mpz_neg(t.data(), t.data()); } inline void eval_bitwise_and(gmp_int& result, const gmp_int& u, const gmp_int& v) { mpz_and(result.data(), u.data(), v.data()); } inline void eval_bitwise_or(gmp_int& result, const gmp_int& u, const gmp_int& v) { mpz_ior(result.data(), u.data(), v.data()); } inline void eval_bitwise_xor(gmp_int& result, const gmp_int& u, const gmp_int& v) { mpz_xor(result.data(), u.data(), v.data()); } inline void eval_complement(gmp_int& result, const gmp_int& u) { mpz_com(result.data(), u.data()); } inline int eval_get_sign(const gmp_int& val) { return mpz_sgn(val.data()); } inline void eval_convert_to(unsigned long* result, const gmp_int& val) { if(0 == mpz_fits_ulong_p(val.data())) { *result = (std::numeric_limits::max)(); } else *result = mpz_get_ui(val.data()); } inline void eval_convert_to(long* result, const gmp_int& val) { if(0 == mpz_fits_slong_p(val.data())) { *result = (std::numeric_limits::max)(); *result *= mpz_sgn(val.data()); } else *result = mpz_get_si(val.data()); } inline void eval_convert_to(double* result, const gmp_int& val) { *result = mpz_get_d(val.data()); } inline void eval_abs(gmp_int& result, const gmp_int& val) { mpz_abs(result.data(), val.data()); } inline void eval_gcd(gmp_int& result, const gmp_int& a, const gmp_int& b) { mpz_gcd(result.data(), a.data(), b.data()); } inline void eval_lcm(gmp_int& result, const gmp_int& a, const gmp_int& b) { mpz_lcm(result.data(), a.data(), b.data()); } template inline typename enable_if_c<(is_unsigned::value && (sizeof(I) <= sizeof(unsigned long)))>::type eval_gcd(gmp_int& result, const gmp_int& a, const I b) { mpz_gcd_ui(result.data(), a.data(), b); } template inline typename enable_if_c<(is_unsigned::value && (sizeof(I) <= sizeof(unsigned long)))>::type eval_lcm(gmp_int& result, const gmp_int& a, const I b) { mpz_lcm_ui(result.data(), a.data(), b); } template inline typename enable_if_c<(is_signed::value && (sizeof(I) <= sizeof(long)))>::type eval_gcd(gmp_int& result, const gmp_int& a, const I b) { mpz_gcd_ui(result.data(), a.data(), std::abs(b)); } template inline typename enable_if_c::value && ((sizeof(I) <= sizeof(long)))>::type eval_lcm(gmp_int& result, const gmp_int& a, const I b) { mpz_lcm_ui(result.data(), a.data(), std::abs(b)); } inline unsigned eval_lsb(const gmp_int& val) { int c = eval_get_sign(val); if(c == 0) { BOOST_THROW_EXCEPTION(std::range_error("No bits were set in the operand.")); } if(c < 0) { BOOST_THROW_EXCEPTION(std::range_error("Testing individual bits in negative values is not supported - results are undefined.")); } return mpz_scan1(val.data(), 0); } inline bool eval_bit_test(const gmp_int& val, unsigned index) { return mpz_tstbit(val.data(), index) ? true : false; } inline void eval_bit_set(gmp_int& val, unsigned index) { mpz_setbit(val.data(), index); } inline void eval_bit_unset(gmp_int& val, unsigned index) { mpz_clrbit(val.data(), index); } inline void eval_bit_flip(gmp_int& val, unsigned index) { mpz_combit(val.data(), index); } inline void eval_qr(const gmp_int& x, const gmp_int& y, gmp_int& q, gmp_int& r) { mpz_tdiv_qr(q.data(), r.data(), x.data(), y.data()); } template inline typename enable_if, Integer>::type eval_integer_modulus(const gmp_int& x, Integer val) { if((sizeof(Integer) <= sizeof(long)) || (val <= (std::numeric_limits::max)())) { return mpz_tdiv_ui(x.data(), val); } else { return default_ops::eval_integer_modulus(x, val); } } template inline typename enable_if, Integer>::type eval_integer_modulus(const gmp_int& x, Integer val) { typedef typename make_unsigned::type unsigned_type; return eval_integer_modulus(x, static_cast(std::abs(val))); } inline void eval_powm(gmp_int& result, const gmp_int& base, const gmp_int& p, const gmp_int& m) { if(eval_get_sign(p) < 0) { BOOST_THROW_EXCEPTION(std::runtime_error("powm requires a positive exponent.")); } mpz_powm(result.data(), base.data(), p.data(), m.data()); } template inline typename enable_if< mpl::and_< is_unsigned, mpl::bool_ > >::type eval_powm(gmp_int& result, const gmp_int& base, Integer p, const gmp_int& m) { mpz_powm_ui(result.data(), base.data(), p, m.data()); } template inline typename enable_if< mpl::and_< is_signed, mpl::bool_ > >::type eval_powm(gmp_int& result, const gmp_int& base, Integer p, const gmp_int& m) { if(p < 0) { BOOST_THROW_EXCEPTION(std::runtime_error("powm requires a positive exponent.")); } mpz_powm_ui(result.data(), base.data(), p, m.data()); } struct gmp_rational; void eval_add(gmp_rational& t, const gmp_rational& o); struct gmp_rational { typedef mpl::list signed_types; typedef mpl::list unsigned_types; typedef mpl::list float_types; gmp_rational() { mpq_init(this->m_data); } gmp_rational(const gmp_rational& o) { mpq_init(m_data); if(o.m_data[0]._mp_num._mp_d) mpq_set(m_data, o.m_data); } gmp_rational(const gmp_int& o) { mpq_init(m_data); mpq_set_z(m_data, o.data()); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_rational(gmp_rational&& o) BOOST_NOEXCEPT { m_data[0]._mp_num = o.data()[0]._mp_num; m_data[0]._mp_den = o.data()[0]._mp_den; o.m_data[0]._mp_num._mp_d = 0; o.m_data[0]._mp_den._mp_d = 0; } #endif gmp_rational(const mpq_t o) { mpq_init(m_data); mpq_set(m_data, o); } gmp_rational(const mpz_t o) { mpq_init(m_data); mpq_set_z(m_data, o); } gmp_rational& operator = (const gmp_rational& o) { if(o.m_data[0]._mp_num._mp_d) mpq_set(m_data, o.m_data); return *this; } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES gmp_rational& operator = (gmp_rational&& o) BOOST_NOEXCEPT { mpq_swap(m_data, o.m_data); return *this; } #endif gmp_rational& operator = (unsigned long long i) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); unsigned long long mask = ((1uLL << std::numeric_limits::digits) - 1); unsigned shift = 0; mpq_t t; mpq_set_ui(m_data, 0, 1); mpq_init(t); while(i) { mpq_set_ui(t, static_cast(i & mask), 1); if(shift) mpq_mul_2exp(t, t, shift); mpq_add(m_data, m_data, t); shift += std::numeric_limits::digits; i >>= std::numeric_limits::digits; } mpq_clear(t); return *this; } gmp_rational& operator = (long long i) { BOOST_MP_USING_ABS if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); bool neg = i < 0; *this = static_cast(abs(i)); if(neg) mpq_neg(m_data, m_data); return *this; } gmp_rational& operator = (unsigned long i) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set_ui(m_data, i, 1); return *this; } gmp_rational& operator = (long i) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set_si(m_data, i, 1); return *this; } gmp_rational& operator = (double d) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set_d(m_data, d); return *this; } gmp_rational& operator = (long double a) { using std::frexp; using std::ldexp; using std::floor; using default_ops::eval_add; using default_ops::eval_subtract; if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); if (a == 0) { mpq_set_si(m_data, 0, 1); return *this; } if (a == 1) { mpq_set_si(m_data, 1, 1); return *this; } BOOST_ASSERT(!(boost::math::isinf)(a)); BOOST_ASSERT(!(boost::math::isnan)(a)); int e; long double f, term; mpq_set_ui(m_data, 0, 1); mpq_set_ui(m_data, 0u, 1); gmp_rational t; f = frexp(a, &e); static const int shift = std::numeric_limits::digits - 1; while(f) { // extract int sized bits from f: f = ldexp(f, shift); term = floor(f); e -= shift; mpq_mul_2exp(m_data, m_data, shift); t = static_cast(term); eval_add(*this, t); f -= term; } if(e > 0) mpq_mul_2exp(m_data, m_data, e); else if(e < 0) mpq_div_2exp(m_data, m_data, -e); return *this; } gmp_rational& operator = (const char* s) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); if(0 != mpq_set_str(m_data, s, 10)) BOOST_THROW_EXCEPTION(std::runtime_error(std::string("The string \"") + s + std::string("\"could not be interpreted as a valid rational number."))); return *this; } gmp_rational& operator=(const gmp_int& o) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set_z(m_data, o.data()); return *this; } gmp_rational& operator=(const mpq_t o) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set(m_data, o); return *this; } gmp_rational& operator=(const mpz_t o) { if(m_data[0]._mp_den._mp_d == 0) mpq_init(m_data); mpq_set_z(m_data, o); return *this; } void swap(gmp_rational& o) { mpq_swap(m_data, o.m_data); } std::string str(std::streamsize /*digits*/, std::ios_base::fmtflags /*f*/)const { BOOST_ASSERT(m_data[0]._mp_num._mp_d); // TODO make a better job of this including handling of f!! void *(*alloc_func_ptr) (size_t); void *(*realloc_func_ptr) (void *, size_t, size_t); void (*free_func_ptr) (void *, size_t); const char* ps = mpq_get_str (0, 10, m_data); std::string s = ps; mp_get_memory_functions(&alloc_func_ptr, &realloc_func_ptr, &free_func_ptr); (*free_func_ptr)((void*)ps, std::strlen(ps) + 1); return s; } ~gmp_rational() { if(m_data[0]._mp_num._mp_d || m_data[0]._mp_den._mp_d) mpq_clear(m_data); } void negate() { BOOST_ASSERT(m_data[0]._mp_num._mp_d); mpq_neg(m_data, m_data); } int compare(const gmp_rational& o)const { BOOST_ASSERT(m_data[0]._mp_num._mp_d && o.m_data[0]._mp_num._mp_d); return mpq_cmp(m_data, o.m_data); } template int compare(V v)const { gmp_rational d; d = v; return compare(d); } int compare(unsigned long v)const { BOOST_ASSERT(m_data[0]._mp_num._mp_d); return mpq_cmp_ui(m_data, v, 1); } int compare(long v)const { BOOST_ASSERT(m_data[0]._mp_num._mp_d); return mpq_cmp_si(m_data, v, 1); } mpq_t& data() { BOOST_ASSERT(m_data[0]._mp_num._mp_d); return m_data; } const mpq_t& data()const { BOOST_ASSERT(m_data[0]._mp_num._mp_d); return m_data; } protected: mpq_t m_data; }; inline bool eval_is_zero(const gmp_rational& val) { return mpq_sgn(val.data()) == 0; } template inline bool eval_eq(gmp_rational& a, const T& b) { return a.compare(b) == 0; } template inline bool eval_lt(gmp_rational& a, const T& b) { return a.compare(b) < 0; } template inline bool eval_gt(gmp_rational& a, const T& b) { return a.compare(b) > 0; } inline void eval_add(gmp_rational& t, const gmp_rational& o) { mpq_add(t.data(), t.data(), o.data()); } inline void eval_subtract(gmp_rational& t, const gmp_rational& o) { mpq_sub(t.data(), t.data(), o.data()); } inline void eval_multiply(gmp_rational& t, const gmp_rational& o) { mpq_mul(t.data(), t.data(), o.data()); } inline void eval_divide(gmp_rational& t, const gmp_rational& o) { if(eval_is_zero(o)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpq_div(t.data(), t.data(), o.data()); } inline void eval_add(gmp_rational& t, const gmp_rational& p, const gmp_rational& o) { mpq_add(t.data(), p.data(), o.data()); } inline void eval_subtract(gmp_rational& t, const gmp_rational& p, const gmp_rational& o) { mpq_sub(t.data(), p.data(), o.data()); } inline void eval_multiply(gmp_rational& t, const gmp_rational& p, const gmp_rational& o) { mpq_mul(t.data(), p.data(), o.data()); } inline void eval_divide(gmp_rational& t, const gmp_rational& p, const gmp_rational& o) { if(eval_is_zero(o)) BOOST_THROW_EXCEPTION(std::overflow_error("Division by zero.")); mpq_div(t.data(), p.data(), o.data()); } inline int eval_get_sign(const gmp_rational& val) { return mpq_sgn(val.data()); } inline void eval_convert_to(double* result, const gmp_rational& val) { *result = mpq_get_d(val.data()); } inline void eval_convert_to(long* result, const gmp_rational& val) { double r; eval_convert_to(&r, val); *result = static_cast(r); } inline void eval_convert_to(unsigned long* result, const gmp_rational& val) { double r; eval_convert_to(&r, val); *result = static_cast(r); } inline void eval_abs(gmp_rational& result, const gmp_rational& val) { mpq_abs(result.data(), val.data()); } inline void assign_components(gmp_rational& result, unsigned long v1, unsigned long v2) { mpq_set_ui(result.data(), v1, v2); mpq_canonicalize(result.data()); } inline void assign_components(gmp_rational& result, long v1, long v2) { mpq_set_si(result.data(), v1, v2); mpq_canonicalize(result.data()); } inline void assign_components(gmp_rational& result, gmp_int const& v1, gmp_int const& v2) { mpz_set(mpq_numref(result.data()), v1.data()); mpz_set(mpq_denref(result.data()), v2.data()); mpq_canonicalize(result.data()); } // // Some member functions that are dependent upon previous code go here: // template template inline gmp_float::gmp_float(const gmp_float& o, typename enable_if_c::type*) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set(this->m_data, o.data()); } template template inline gmp_float::gmp_float(const gmp_float& o, typename disable_if_c::type*) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set(this->m_data, o.data()); } template inline gmp_float::gmp_float(const gmp_int& o) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set_z(this->data(), o.data()); } template inline gmp_float::gmp_float(const gmp_rational& o) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set_q(this->data(), o.data()); } template template inline gmp_float& gmp_float::operator=(const gmp_float& o) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set(this->m_data, o.data()); return *this; } template inline gmp_float& gmp_float::operator=(const gmp_int& o) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set_z(this->data(), o.data()); return *this; } template inline gmp_float& gmp_float::operator=(const gmp_rational& o) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(Digits10 ? Digits10 : this->get_default_precision())); mpf_set_q(this->data(), o.data()); return *this; } inline gmp_float<0>::gmp_float(const gmp_int& o) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_z(this->data(), o.data()); } inline gmp_float<0>::gmp_float(const gmp_rational& o) { mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(get_default_precision())); mpf_set_q(this->data(), o.data()); } inline gmp_float<0>& gmp_float<0>::operator=(const gmp_int& o) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(this->get_default_precision())); mpf_set_z(this->data(), o.data()); return *this; } inline gmp_float<0>& gmp_float<0>::operator=(const gmp_rational& o) { if(this->m_data[0]._mp_d == 0) mpf_init2(this->m_data, multiprecision::detail::digits10_2_2(this->get_default_precision())); mpf_set_q(this->data(), o.data()); return *this; } inline gmp_int::gmp_int(const gmp_rational& o) { mpz_init(this->m_data); mpz_set_q(this->m_data, o.data()); } inline gmp_int& gmp_int::operator=(const gmp_rational& o) { if(this->m_data[0]._mp_d == 0) mpz_init(this->m_data); mpz_set_q(this->m_data, o.data()); return *this; } } //namespace backends using boost::multiprecision::backends::gmp_int; using boost::multiprecision::backends::gmp_rational; using boost::multiprecision::backends::gmp_float; template <> struct component_type > { typedef number type; }; template inline number numerator(const number& val) { number result; mpz_set(result.backend().data(), (mpq_numref(val.backend().data()))); return result; } template inline number denominator(const number& val) { number result; mpz_set(result.backend().data(), (mpq_denref(val.backend().data()))); return result; } #ifdef BOOST_NO_SFINAE_EXPR namespace detail{ template<> struct is_explicitly_convertible::type, gmp_int> : public mpl::true_ {}; template<> struct is_explicitly_convertible::type, gmp_int> : public mpl::true_ {}; template struct is_explicitly_convertible, gmp_int> : public mpl::true_ {}; template<> struct is_explicitly_convertible : public mpl::true_ {}; template struct is_explicitly_convertible, gmp_float > : public mpl::true_ {}; } #endif template<> struct number_category::type> : public mpl::int_{}; template<> struct number_category::type> : public mpl::int_{}; template<> struct number_category >::type> : public mpl::int_{}; typedef number > mpf_float_50; typedef number > mpf_float_100; typedef number > mpf_float_500; typedef number > mpf_float_1000; typedef number > mpf_float; typedef number mpz_int; typedef number mpq_rational; }} // namespaces namespace std{ // // numeric_limits [partial] specializations for the types declared in this header: // template class numeric_limits, ExpressionTemplates> > { typedef boost::multiprecision::number, ExpressionTemplates> number_type; public: BOOST_STATIC_CONSTEXPR bool is_specialized = true; // // min and max values chosen so as to not cause segfaults when calling // mpf_get_str on 64-bit Linux builds. Possibly we could use larger // exponent values elsewhere. // static number_type (min)() { initializer.do_nothing(); static std::pair value; if(!value.first) { value.first = true; value.second = 1; mpf_div_2exp(value.second.backend().data(), value.second.backend().data(), (std::numeric_limits::max)() / 64 + 1); } return value.second; } static number_type (max)() { initializer.do_nothing(); static std::pair value; if(!value.first) { value.first = true; value.second = 1; mpf_mul_2exp(value.second.backend().data(), value.second.backend().data(), (std::numeric_limits::max)() / 64 + 1); } return value.second; } BOOST_STATIC_CONSTEXPR number_type lowest() { return -(max)(); } BOOST_STATIC_CONSTEXPR int digits = static_cast((Digits10 * 1000L) / 301L + ((Digits10 * 1000L) % 301L ? 2 : 1)); BOOST_STATIC_CONSTEXPR int digits10 = Digits10; // Have to allow for a possible extra limb inside the gmp data structure: BOOST_STATIC_CONSTEXPR int max_digits10 = Digits10 + 2 + ((GMP_LIMB_BITS * 301L) / 1000L); BOOST_STATIC_CONSTEXPR bool is_signed = true; BOOST_STATIC_CONSTEXPR bool is_integer = false; BOOST_STATIC_CONSTEXPR bool is_exact = false; BOOST_STATIC_CONSTEXPR int radix = 2; static number_type epsilon() { initializer.do_nothing(); static std::pair value; if(!value.first) { value.first = true; value.second = 1; mpf_div_2exp(value.second.backend().data(), value.second.backend().data(), std::numeric_limits::digits - 1); } return value.second; } // What value should this be???? static number_type round_error() { // returns epsilon/2 initializer.do_nothing(); static std::pair value; if(!value.first) { value.first = true; value.second = 1; mpf_div_2exp(value.second.backend().data(), value.second.backend().data(), digits); } return value.second; } BOOST_STATIC_CONSTEXPR long min_exponent = LONG_MIN; BOOST_STATIC_CONSTEXPR long min_exponent10 = (LONG_MIN / 1000) * 301L; BOOST_STATIC_CONSTEXPR long max_exponent = LONG_MAX; BOOST_STATIC_CONSTEXPR long max_exponent10 = (LONG_MAX / 1000) * 301L; BOOST_STATIC_CONSTEXPR bool has_infinity = false; BOOST_STATIC_CONSTEXPR bool has_quiet_NaN = false; BOOST_STATIC_CONSTEXPR bool has_signaling_NaN = false; BOOST_STATIC_CONSTEXPR float_denorm_style has_denorm = denorm_absent; BOOST_STATIC_CONSTEXPR bool has_denorm_loss = false; BOOST_STATIC_CONSTEXPR number_type infinity() { return number_type(); } BOOST_STATIC_CONSTEXPR number_type quiet_NaN() { return number_type(); } BOOST_STATIC_CONSTEXPR number_type signaling_NaN() { return number_type(); } BOOST_STATIC_CONSTEXPR number_type denorm_min() { return number_type(); } BOOST_STATIC_CONSTEXPR bool is_iec559 = false; BOOST_STATIC_CONSTEXPR bool is_bounded = true; BOOST_STATIC_CONSTEXPR bool is_modulo = false; BOOST_STATIC_CONSTEXPR bool traps = true; BOOST_STATIC_CONSTEXPR bool tinyness_before = false; BOOST_STATIC_CONSTEXPR float_round_style round_style = round_to_nearest; private: struct data_initializer { data_initializer() { std::numeric_limits > >::epsilon(); std::numeric_limits > >::round_error(); (std::numeric_limits > >::min)(); (std::numeric_limits > >::max)(); } void do_nothing()const{} }; static const data_initializer initializer; }; template const typename numeric_limits, ExpressionTemplates> >::data_initializer numeric_limits, ExpressionTemplates> >::initializer; template class numeric_limits, ExpressionTemplates> > { typedef boost::multiprecision::number, ExpressionTemplates> number_type; public: BOOST_STATIC_CONSTEXPR bool is_specialized = false; static number_type (min)() { return number_type(); } static number_type (max)() { return number_type(); } static number_type lowest() { return number_type(); } BOOST_STATIC_CONSTEXPR int digits = 0; BOOST_STATIC_CONSTEXPR int digits10 = 0; BOOST_STATIC_CONSTEXPR int max_digits10 = 0; BOOST_STATIC_CONSTEXPR bool is_signed = false; BOOST_STATIC_CONSTEXPR bool is_integer = false; BOOST_STATIC_CONSTEXPR bool is_exact = false; BOOST_STATIC_CONSTEXPR int radix = 0; static number_type epsilon() { return number_type(); } static number_type round_error() { return number_type(); } BOOST_STATIC_CONSTEXPR int min_exponent = 0; BOOST_STATIC_CONSTEXPR int min_exponent10 = 0; BOOST_STATIC_CONSTEXPR int max_exponent = 0; BOOST_STATIC_CONSTEXPR int max_exponent10 = 0; BOOST_STATIC_CONSTEXPR bool has_infinity = false; BOOST_STATIC_CONSTEXPR bool has_quiet_NaN = false; BOOST_STATIC_CONSTEXPR bool has_signaling_NaN = false; BOOST_STATIC_CONSTEXPR float_denorm_style has_denorm = denorm_absent; BOOST_STATIC_CONSTEXPR bool has_denorm_loss = false; static number_type infinity() { return number_type(); } static number_type quiet_NaN() { return number_type(); } static number_type signaling_NaN() { return number_type(); } static number_type denorm_min() { return number_type(); } BOOST_STATIC_CONSTEXPR bool is_iec559 = false; BOOST_STATIC_CONSTEXPR bool is_bounded = false; BOOST_STATIC_CONSTEXPR bool is_modulo = false; BOOST_STATIC_CONSTEXPR bool traps = false; BOOST_STATIC_CONSTEXPR bool tinyness_before = false; BOOST_STATIC_CONSTEXPR float_round_style round_style = round_toward_zero; }; #ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::digits; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::digits10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::max_digits10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_signed; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_integer; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_exact; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::radix; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::min_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::min_exponent10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::max_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits, ExpressionTemplates> >::max_exponent10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::has_infinity; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::has_quiet_NaN; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::has_signaling_NaN; template BOOST_CONSTEXPR_OR_CONST float_denorm_style numeric_limits, ExpressionTemplates> >::has_denorm; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::has_denorm_loss; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_iec559; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_bounded; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::is_modulo; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::traps; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits, ExpressionTemplates> >::tinyness_before; template BOOST_CONSTEXPR_OR_CONST float_round_style numeric_limits, ExpressionTemplates> >::round_style; #endif template class numeric_limits > { typedef boost::multiprecision::number number_type; public: BOOST_STATIC_CONSTEXPR bool is_specialized = true; // // Largest and smallest numbers are bounded only by available memory, set // to zero: // static number_type (min)() { return number_type(); } static number_type (max)() { return number_type(); } static number_type lowest() { return (min)(); } BOOST_STATIC_CONSTEXPR int digits = INT_MAX; BOOST_STATIC_CONSTEXPR int digits10 = (INT_MAX / 1000) * 301L; BOOST_STATIC_CONSTEXPR int max_digits10 = digits10 + 2; BOOST_STATIC_CONSTEXPR bool is_signed = true; BOOST_STATIC_CONSTEXPR bool is_integer = true; BOOST_STATIC_CONSTEXPR bool is_exact = true; BOOST_STATIC_CONSTEXPR int radix = 2; static number_type epsilon() { return number_type(); } static number_type round_error() { return number_type(); } BOOST_STATIC_CONSTEXPR int min_exponent = 0; BOOST_STATIC_CONSTEXPR int min_exponent10 = 0; BOOST_STATIC_CONSTEXPR int max_exponent = 0; BOOST_STATIC_CONSTEXPR int max_exponent10 = 0; BOOST_STATIC_CONSTEXPR bool has_infinity = false; BOOST_STATIC_CONSTEXPR bool has_quiet_NaN = false; BOOST_STATIC_CONSTEXPR bool has_signaling_NaN = false; BOOST_STATIC_CONSTEXPR float_denorm_style has_denorm = denorm_absent; BOOST_STATIC_CONSTEXPR bool has_denorm_loss = false; static number_type infinity() { return number_type(); } static number_type quiet_NaN() { return number_type(); } static number_type signaling_NaN() { return number_type(); } static number_type denorm_min() { return number_type(); } BOOST_STATIC_CONSTEXPR bool is_iec559 = false; BOOST_STATIC_CONSTEXPR bool is_bounded = false; BOOST_STATIC_CONSTEXPR bool is_modulo = false; BOOST_STATIC_CONSTEXPR bool traps = false; BOOST_STATIC_CONSTEXPR bool tinyness_before = false; BOOST_STATIC_CONSTEXPR float_round_style round_style = round_toward_zero; }; #ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::digits; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::digits10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_digits10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_signed; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_integer; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_exact; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::radix; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::min_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::min_exponent10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_exponent10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_infinity; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_quiet_NaN; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_signaling_NaN; template BOOST_CONSTEXPR_OR_CONST float_denorm_style numeric_limits >::has_denorm; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_denorm_loss; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_iec559; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_bounded; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_modulo; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::traps; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::tinyness_before; template BOOST_CONSTEXPR_OR_CONST float_round_style numeric_limits >::round_style; #endif template class numeric_limits > { typedef boost::multiprecision::number number_type; public: BOOST_STATIC_CONSTEXPR bool is_specialized = true; // // Largest and smallest numbers are bounded only by available memory, set // to zero: // static number_type (min)() { return number_type(); } static number_type (max)() { return number_type(); } static number_type lowest() { return (min)(); } // Digits are unbounded, use zero for now: BOOST_STATIC_CONSTEXPR int digits = INT_MAX; BOOST_STATIC_CONSTEXPR int digits10 = (INT_MAX / 1000) * 301L; BOOST_STATIC_CONSTEXPR int max_digits10 = digits10 + 2; BOOST_STATIC_CONSTEXPR bool is_signed = true; BOOST_STATIC_CONSTEXPR bool is_integer = false; BOOST_STATIC_CONSTEXPR bool is_exact = true; BOOST_STATIC_CONSTEXPR int radix = 2; static number_type epsilon() { return number_type(); } static number_type round_error() { return number_type(); } BOOST_STATIC_CONSTEXPR int min_exponent = 0; BOOST_STATIC_CONSTEXPR int min_exponent10 = 0; BOOST_STATIC_CONSTEXPR int max_exponent = 0; BOOST_STATIC_CONSTEXPR int max_exponent10 = 0; BOOST_STATIC_CONSTEXPR bool has_infinity = false; BOOST_STATIC_CONSTEXPR bool has_quiet_NaN = false; BOOST_STATIC_CONSTEXPR bool has_signaling_NaN = false; BOOST_STATIC_CONSTEXPR float_denorm_style has_denorm = denorm_absent; BOOST_STATIC_CONSTEXPR bool has_denorm_loss = false; static number_type infinity() { return number_type(); } static number_type quiet_NaN() { return number_type(); } static number_type signaling_NaN() { return number_type(); } static number_type denorm_min() { return number_type(); } BOOST_STATIC_CONSTEXPR bool is_iec559 = false; BOOST_STATIC_CONSTEXPR bool is_bounded = false; BOOST_STATIC_CONSTEXPR bool is_modulo = false; BOOST_STATIC_CONSTEXPR bool traps = false; BOOST_STATIC_CONSTEXPR bool tinyness_before = false; BOOST_STATIC_CONSTEXPR float_round_style round_style = round_toward_zero; }; #ifndef BOOST_NO_INCLASS_MEMBER_INITIALIZATION template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::digits; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::digits10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_digits10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_signed; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_integer; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_exact; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::radix; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::min_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::min_exponent10; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_exponent; template BOOST_CONSTEXPR_OR_CONST int numeric_limits >::max_exponent10; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_infinity; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_quiet_NaN; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_signaling_NaN; template BOOST_CONSTEXPR_OR_CONST float_denorm_style numeric_limits >::has_denorm; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::has_denorm_loss; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_iec559; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_bounded; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::is_modulo; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::traps; template BOOST_CONSTEXPR_OR_CONST bool numeric_limits >::tinyness_before; template BOOST_CONSTEXPR_OR_CONST float_round_style numeric_limits >::round_style; #endif #ifdef BOOST_MSVC #pragma warning(pop) #endif } // namespace std #endif