/////////////////////////////////////////////////////////////////////////////// // Copyright Christopher Kormanyos 2002 - 2013. // Copyright 2011 -2013 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) // // This work is based on an earlier work: // "Algorithm 910: A Portable C++ Multiple-Precision System for Special-Function Calculations", // in ACM TOMS, {VOL 37, ISSUE 4, (February 2011)} (C) ACM, 2011. http://doi.acm.org/10.1145/1916461.1916469 // // Note that there are no "noexcept" specifications on the functions in this file: there are too many // calls to lexical_cast (and similar) to easily analyse the code for correctness. So until compilers // can detect noexcept misuse at compile time, the only realistic option is to simply not use it here. // #ifndef BOOST_MP_CPP_DEC_FLOAT_BACKEND_HPP #define BOOST_MP_CPP_DEC_FLOAT_BACKEND_HPP #include #include #include #ifndef BOOST_NO_CXX11_HDR_ARRAY #include #else #include #endif #include #include #include #include // // Headers required for Boost.Math integration: // #include namespace boost{ namespace multiprecision{ namespace backends{ template class cpp_dec_float; } // namespace template struct number_category > : public mpl::int_{}; namespace backends{ template class cpp_dec_float { private: static const boost::int32_t cpp_dec_float_digits10_setting = Digits10; // We need at least 16-bits in the exponent type to do anything sensible: BOOST_STATIC_ASSERT_MSG(boost::is_signed::value, "ExponentType must be a signed built in integer type."); BOOST_STATIC_ASSERT_MSG(sizeof(ExponentType) > 1, "ExponentType is too small."); public: typedef mpl::list signed_types; typedef mpl::list unsigned_types; typedef mpl::list float_types; typedef ExponentType exponent_type; static const boost::int32_t cpp_dec_float_radix = 10L; static const boost::int32_t cpp_dec_float_digits10_limit_lo = 9L; static const boost::int32_t cpp_dec_float_digits10_limit_hi = boost::integer_traits::const_max - 100; static const boost::int32_t cpp_dec_float_digits10 = ((cpp_dec_float_digits10_setting < cpp_dec_float_digits10_limit_lo) ? cpp_dec_float_digits10_limit_lo : ((cpp_dec_float_digits10_setting > cpp_dec_float_digits10_limit_hi) ? cpp_dec_float_digits10_limit_hi : cpp_dec_float_digits10_setting)); static const ExponentType cpp_dec_float_max_exp10 = (static_cast(1) << (std::numeric_limits::digits - 5)); static const ExponentType cpp_dec_float_min_exp10 = -cpp_dec_float_max_exp10; static const ExponentType cpp_dec_float_max_exp = cpp_dec_float_max_exp10; static const ExponentType cpp_dec_float_min_exp = cpp_dec_float_min_exp10; BOOST_STATIC_ASSERT((cpp_dec_float::cpp_dec_float_max_exp10 == -cpp_dec_float::cpp_dec_float_min_exp10)); private: static const boost::int32_t cpp_dec_float_elem_digits10 = 8L; static const boost::int32_t cpp_dec_float_elem_mask = 100000000L; BOOST_STATIC_ASSERT(0 == cpp_dec_float_max_exp10 % cpp_dec_float_elem_digits10); // There are three guard limbs. // 1) The first limb has 'play' from 1...8 decimal digits. // 2) The last limb also has 'play' from 1...8 decimal digits. // 3) One limb can get lost when justifying after multiply, // as only half of the triangle is multiplied and a carry // from below is missing. static const boost::int32_t cpp_dec_float_elem_number_request = static_cast((cpp_dec_float_digits10 / cpp_dec_float_elem_digits10) + (((cpp_dec_float_digits10 % cpp_dec_float_elem_digits10) != 0) ? 1 : 0)); // The number of elements needed (with a minimum of two) plus three added guard limbs. static const boost::int32_t cpp_dec_float_elem_number = static_cast(((cpp_dec_float_elem_number_request < 2L) ? 2L : cpp_dec_float_elem_number_request) + 3L); public: static const boost::int32_t cpp_dec_float_total_digits10 = static_cast(cpp_dec_float_elem_number * cpp_dec_float_elem_digits10); private: typedef enum enum_fpclass_type { cpp_dec_float_finite, cpp_dec_float_inf, cpp_dec_float_NaN } fpclass_type; #ifndef BOOST_NO_CXX11_HDR_ARRAY typedef typename mpl::if_, std::array, detail::dynamic_array >::type array_type; #else typedef typename mpl::if_, boost::array, detail::dynamic_array >::type array_type; #endif array_type data; ExponentType exp; bool neg; fpclass_type fpclass; boost::int32_t prec_elem; // // Special values constructor: // cpp_dec_float(fpclass_type c) : data(), exp (static_cast(0)), neg (false), fpclass (c), prec_elem(cpp_dec_float_elem_number) { } // // Static data initializer: // struct initializer { initializer() { cpp_dec_float::nan(); cpp_dec_float::inf(); (cpp_dec_float::min)(); (cpp_dec_float::max)(); cpp_dec_float::zero(); cpp_dec_float::one(); cpp_dec_float::two(); cpp_dec_float::half(); cpp_dec_float::double_min(); cpp_dec_float::double_max(); cpp_dec_float::long_double_max(); cpp_dec_float::long_double_min(); cpp_dec_float::long_long_max(); cpp_dec_float::long_long_min(); cpp_dec_float::ulong_long_max(); cpp_dec_float::eps(); cpp_dec_float::pow2(0); } void do_nothing(){} }; static initializer init; public: // Constructors cpp_dec_float() BOOST_NOEXCEPT_IF(noexcept(array_type())) : data(), exp (static_cast(0)), neg (false), fpclass (cpp_dec_float_finite), prec_elem(cpp_dec_float_elem_number) { } cpp_dec_float(const char* s) : data(), exp (static_cast(0)), neg (false), fpclass (cpp_dec_float_finite), prec_elem(cpp_dec_float_elem_number) { *this = s; } template cpp_dec_float(I i, typename enable_if >::type* = 0) : data(), exp (static_cast(0)), neg (false), fpclass (cpp_dec_float_finite), prec_elem(cpp_dec_float_elem_number) { from_unsigned_long_long(i); } template cpp_dec_float(I i, typename enable_if >::type* = 0) : data(), exp (static_cast(0)), neg (false), fpclass (cpp_dec_float_finite), prec_elem(cpp_dec_float_elem_number) { if(i < 0) { from_unsigned_long_long(boost::multiprecision::detail::unsigned_abs(i)); negate(); } else from_unsigned_long_long(i); } cpp_dec_float(const cpp_dec_float& f) BOOST_NOEXCEPT_IF(noexcept(array_type(std::declval()))) : data (f.data), exp (f.exp), neg (f.neg), fpclass (f.fpclass), prec_elem(f.prec_elem) { } template cpp_dec_float(const cpp_dec_float& f, typename enable_if_c::type* = 0) : data(), exp (f.exp), neg (f.neg), fpclass (static_cast(static_cast(f.fpclass))), prec_elem(cpp_dec_float_elem_number) { std::copy(f.data.begin(), f.data.begin() + f.prec_elem, data.begin()); } template explicit cpp_dec_float(const cpp_dec_float& f, typename disable_if_c::type* = 0) : data(), exp (f.exp), neg (f.neg), fpclass (static_cast(static_cast(f.fpclass))), prec_elem(cpp_dec_float_elem_number) { // TODO: this doesn't round! std::copy(f.data.begin(), f.data.begin() + prec_elem, data.begin()); } template cpp_dec_float(const F val, typename enable_if >::type* = 0) : data(), exp (static_cast(0)), neg (false), fpclass (cpp_dec_float_finite), prec_elem(cpp_dec_float_elem_number) { *this = val; } cpp_dec_float(const double mantissa, const ExponentType exponent); // Specific special values. static const cpp_dec_float& nan() { static const cpp_dec_float val(cpp_dec_float_NaN); init.do_nothing(); return val; } static const cpp_dec_float& inf() { static const cpp_dec_float val(cpp_dec_float_inf); init.do_nothing(); return val; } static const cpp_dec_float& (max)() { init.do_nothing(); static cpp_dec_float val_max = std::string("1.0e" + boost::lexical_cast(cpp_dec_float_max_exp10)).c_str(); return val_max; } static const cpp_dec_float& (min)() { init.do_nothing(); static cpp_dec_float val_min = std::string("1.0e" + boost::lexical_cast(cpp_dec_float_min_exp10)).c_str(); return val_min; } static const cpp_dec_float& zero() { init.do_nothing(); static cpp_dec_float val(static_cast(0u)); return val; } static const cpp_dec_float& one() { init.do_nothing(); static cpp_dec_float val(static_cast(1u)); return val; } static const cpp_dec_float& two() { init.do_nothing(); static cpp_dec_float val(static_cast(2u)); return val; } static const cpp_dec_float& half() { init.do_nothing(); static cpp_dec_float val(0.5L); return val; } static const cpp_dec_float& double_min() { init.do_nothing(); static cpp_dec_float val(static_cast((std::numeric_limits::min)())); return val; } static const cpp_dec_float& double_max() { init.do_nothing(); static cpp_dec_float val(static_cast((std::numeric_limits::max)())); return val; } static const cpp_dec_float& long_double_min() { init.do_nothing(); #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS static cpp_dec_float val(static_cast((std::numeric_limits::min)())); #else static cpp_dec_float val((std::numeric_limits::min)()); #endif return val; } static const cpp_dec_float& long_double_max() { init.do_nothing(); #ifdef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS static cpp_dec_float val(static_cast((std::numeric_limits::max)())); #else static cpp_dec_float val((std::numeric_limits::max)()); #endif return val; } static const cpp_dec_float& long_long_max() { init.do_nothing(); static cpp_dec_float val((std::numeric_limits::max)()); return val; } static const cpp_dec_float& long_long_min() { init.do_nothing(); static cpp_dec_float val((std::numeric_limits::min)()); return val; } static const cpp_dec_float& ulong_long_max() { init.do_nothing(); static cpp_dec_float val((std::numeric_limits::max)()); return val; } static const cpp_dec_float& eps() { init.do_nothing(); static cpp_dec_float val(1.0, 1 - static_cast(cpp_dec_float_digits10)); return val; } // Basic operations. cpp_dec_float& operator=(const cpp_dec_float& v) BOOST_NOEXCEPT_IF(noexcept(std::declval() = std::declval())) { data = v.data; exp = v.exp; neg = v.neg; fpclass = v.fpclass; prec_elem = v.prec_elem; return *this; } template cpp_dec_float& operator=(const cpp_dec_float& f) { exp = f.exp; neg = f.neg; fpclass = static_cast(static_cast(f.fpclass)); unsigned elems = (std::min)(f.prec_elem, cpp_dec_float_elem_number); std::copy(f.data.begin(), f.data.begin() + elems, data.begin()); std::fill(data.begin() + elems, data.end(), 0); prec_elem = cpp_dec_float_elem_number; return *this; } cpp_dec_float& operator=(long long v) { if(v < 0) { from_unsigned_long_long(-v); negate(); } else from_unsigned_long_long(v); return *this; } cpp_dec_float& operator=(unsigned long long v) { from_unsigned_long_long(v); return *this; } cpp_dec_float& operator=(long double v); cpp_dec_float& operator=(const char* v) { rd_string(v); return *this; } cpp_dec_float& operator+=(const cpp_dec_float& v); cpp_dec_float& operator-=(const cpp_dec_float& v); cpp_dec_float& operator*=(const cpp_dec_float& v); cpp_dec_float& operator/=(const cpp_dec_float& v); cpp_dec_float& add_unsigned_long_long(const unsigned long long n) { cpp_dec_float t; t.from_unsigned_long_long(n); return *this += t; } cpp_dec_float& sub_unsigned_long_long(const unsigned long long n) { cpp_dec_float t; t.from_unsigned_long_long(n); return *this -= t; } cpp_dec_float& mul_unsigned_long_long(const unsigned long long n); cpp_dec_float& div_unsigned_long_long(const unsigned long long n); // Elementary primitives. cpp_dec_float& calculate_inv (); cpp_dec_float& calculate_sqrt(); void negate() { if(!iszero()) neg = !neg; } // Comparison functions bool isnan BOOST_PREVENT_MACRO_SUBSTITUTION() const { return (fpclass == cpp_dec_float_NaN); } bool isinf BOOST_PREVENT_MACRO_SUBSTITUTION() const { return (fpclass == cpp_dec_float_inf); } bool isfinite BOOST_PREVENT_MACRO_SUBSTITUTION() const { return (fpclass == cpp_dec_float_finite); } bool iszero () const { return ((fpclass == cpp_dec_float_finite) && (data[0u] == 0u)); } bool isone () const; bool isint () const; bool isneg () const { return neg; } // Operators pre-increment and pre-decrement cpp_dec_float& operator++() { return *this += one(); } cpp_dec_float& operator--() { return *this -= one(); } std::string str(boost::intmax_t digits, std::ios_base::fmtflags f)const; int compare(const cpp_dec_float& v)const; template int compare(const V& v)const { cpp_dec_float t; t = v; return compare(t); } void swap(cpp_dec_float& v) { data.swap(v.data); std::swap(exp, v.exp); std::swap(neg, v.neg); std::swap(fpclass, v.fpclass); std::swap(prec_elem, v.prec_elem); } double extract_double() const; long double extract_long_double() const; signed long long extract_signed_long_long() const; unsigned long long extract_unsigned_long_long() const; void extract_parts(double& mantissa, ExponentType& exponent) const; cpp_dec_float extract_integer_part() const; void precision(const boost::int32_t prec_digits) { if(prec_digits >= cpp_dec_float_total_digits10) { prec_elem = cpp_dec_float_elem_number; } else { const boost::int32_t elems = static_cast( static_cast( (prec_digits + (cpp_dec_float_elem_digits10 / 2)) / cpp_dec_float_elem_digits10) + static_cast(((prec_digits % cpp_dec_float_elem_digits10) != 0) ? 1 : 0)); prec_elem = (std::min)(cpp_dec_float_elem_number, (std::max)(elems, static_cast(2))); } } static cpp_dec_float pow2(long long i); ExponentType order()const { const bool bo_order_is_zero = ((!(isfinite)()) || (data[0] == static_cast(0u))); // // Binary search to find the order of the leading term: // ExponentType prefix = 0; if(data[0] >= 100000UL) { if(data[0] >= 10000000UL) { if(data[0] >= 100000000UL) { if(data[0] >= 1000000000UL) prefix = 9; else prefix = 8; } else prefix = 7; } else { if(data[0] >= 1000000UL) prefix = 6; else prefix = 5; } } else { if(data[0] >= 1000UL) { if(data[0] >= 10000UL) prefix = 4; else prefix = 3; } else { if(data[0] >= 100) prefix = 2; else if(data[0] >= 10) prefix = 1; } } return (bo_order_is_zero ? static_cast(0) : static_cast(exp + prefix)); } template void serialize(Archive & ar, const unsigned int /*version*/) { for(unsigned i = 0; i < data.size(); ++i) ar & data[i]; ar & exp; ar & neg; ar & fpclass; ar & prec_elem; } private: static bool data_elem_is_non_zero_predicate(const boost::uint32_t& d) { return (d != static_cast(0u)); } static bool data_elem_is_non_nine_predicate(const boost::uint32_t& d) { return (d != static_cast(cpp_dec_float::cpp_dec_float_elem_mask - 1)); } static bool char_is_nonzero_predicate(const char& c) { return (c != static_cast('0')); } void from_unsigned_long_long(const unsigned long long u); int cmp_data(const array_type& vd) const; static boost::uint32_t mul_loop_uv(boost::uint32_t* const u, const boost::uint32_t* const v, const boost::int32_t p); static boost::uint32_t mul_loop_n (boost::uint32_t* const u, boost::uint32_t n, const boost::int32_t p); static boost::uint32_t div_loop_n (boost::uint32_t* const u, boost::uint32_t n, const boost::int32_t p); bool rd_string(const char* const s); template friend class cpp_dec_float; }; template typename cpp_dec_float::initializer cpp_dec_float::init; template const boost::int32_t cpp_dec_float::cpp_dec_float_radix; template const boost::int32_t cpp_dec_float::cpp_dec_float_digits10_setting; template const boost::int32_t cpp_dec_float::cpp_dec_float_digits10_limit_lo; template const boost::int32_t cpp_dec_float::cpp_dec_float_digits10_limit_hi; template const boost::int32_t cpp_dec_float::cpp_dec_float_digits10; template const ExponentType cpp_dec_float::cpp_dec_float_max_exp; template const ExponentType cpp_dec_float::cpp_dec_float_min_exp; template const ExponentType cpp_dec_float::cpp_dec_float_max_exp10; template const ExponentType cpp_dec_float::cpp_dec_float_min_exp10; template const boost::int32_t cpp_dec_float::cpp_dec_float_elem_digits10; template const boost::int32_t cpp_dec_float::cpp_dec_float_elem_number_request; template const boost::int32_t cpp_dec_float::cpp_dec_float_elem_number; template const boost::int32_t cpp_dec_float::cpp_dec_float_elem_mask; template cpp_dec_float& cpp_dec_float::operator+=(const cpp_dec_float& v) { if((isnan)()) { return *this; } if((isinf)()) { if((v.isinf)() && (isneg() != v.isneg())) { *this = nan(); } return *this; } if(iszero()) { return operator=(v); } // Get the offset for the add/sub operation. static const ExponentType max_delta_exp = static_cast((cpp_dec_float_elem_number - 1) * cpp_dec_float_elem_digits10); const ExponentType ofs_exp = static_cast(exp - v.exp); // Check if the operation is out of range, requiring special handling. if(v.iszero() || (ofs_exp > max_delta_exp)) { // Result is *this unchanged since v is negligible compared to *this. return *this; } else if(ofs_exp < -max_delta_exp) { // Result is *this = v since *this is negligible compared to v. return operator=(v); } // Do the add/sub operation. typename array_type::iterator p_u = data.begin(); typename array_type::const_iterator p_v = v.data.begin(); bool b_copy = false; const boost::int32_t ofs = static_cast(static_cast(ofs_exp) / cpp_dec_float_elem_digits10); array_type n_data; if(neg == v.neg) { // Add v to *this, where the data array of either *this or v // might have to be treated with a positive, negative or zero offset. // The result is stored in *this. The data are added one element // at a time, each element with carry. if(ofs >= static_cast(0)) { std::copy(v.data.begin(), v.data.end() - static_cast(ofs), n_data.begin() + static_cast(ofs)); std::fill(n_data.begin(), n_data.begin() + static_cast(ofs), static_cast(0u)); p_v = n_data.begin(); } else { std::copy(data.begin(), data.end() - static_cast(-ofs), n_data.begin() + static_cast(-ofs)); std::fill(n_data.begin(), n_data.begin() + static_cast(-ofs), static_cast(0u)); p_u = n_data.begin(); b_copy = true; } // Addition algorithm boost::uint32_t carry = static_cast(0u); for(boost::int32_t j = static_cast(cpp_dec_float_elem_number - static_cast(1)); j >= static_cast(0); j--) { boost::uint32_t t = static_cast(static_cast(p_u[j] + p_v[j]) + carry); carry = t / static_cast(cpp_dec_float_elem_mask); p_u[j] = static_cast(t - static_cast(carry * static_cast(cpp_dec_float_elem_mask))); } if(b_copy) { data = n_data; exp = v.exp; } // There needs to be a carry into the element -1 of the array data if(carry != static_cast(0u)) { std::copy_backward(data.begin(), data.end() - static_cast(1u), data.end()); data[0] = carry; exp += static_cast(cpp_dec_float_elem_digits10); } } else { // Subtract v from *this, where the data array of either *this or v // might have to be treated with a positive, negative or zero offset. if((ofs > static_cast(0)) || ( (ofs == static_cast(0)) && (cmp_data(v.data) > static_cast(0))) ) { // In this case, |u| > |v| and ofs is positive. // Copy the data of v, shifted down to a lower value // into the data array m_n. Set the operand pointer p_v // to point to the copied, shifted data m_n. std::copy(v.data.begin(), v.data.end() - static_cast(ofs), n_data.begin() + static_cast(ofs)); std::fill(n_data.begin(), n_data.begin() + static_cast(ofs), static_cast(0u)); p_v = n_data.begin(); } else { if(ofs != static_cast(0)) { // In this case, |u| < |v| and ofs is negative. // Shift the data of u down to a lower value. std::copy_backward(data.begin(), data.end() - static_cast(-ofs), data.end()); std::fill(data.begin(), data.begin() + static_cast(-ofs), static_cast(0u)); } // Copy the data of v into the data array n_data. // Set the u-pointer p_u to point to m_n and the // operand pointer p_v to point to the shifted // data m_data. n_data = v.data; p_u = n_data.begin(); p_v = data.begin(); b_copy = true; } boost::int32_t j; // Subtraction algorithm boost::int32_t borrow = static_cast(0); for(j = static_cast(cpp_dec_float_elem_number - static_cast(1)); j >= static_cast(0); j--) { boost::int32_t t = static_cast(static_cast( static_cast(p_u[j]) - static_cast(p_v[j])) - borrow); // Underflow? Borrow? if(t < static_cast(0)) { // Yes, underflow and borrow t += static_cast(cpp_dec_float_elem_mask); borrow = static_cast(1); } else { borrow = static_cast(0); } p_u[j] = static_cast(static_cast(t) % static_cast(cpp_dec_float_elem_mask)); } if(b_copy) { data = n_data; exp = v.exp; neg = v.neg; } // Is it necessary to justify the data? const typename array_type::const_iterator first_nonzero_elem = std::find_if(data.begin(), data.end(), data_elem_is_non_zero_predicate); if(first_nonzero_elem != data.begin()) { if(first_nonzero_elem == data.end()) { // This result of the subtraction is exactly zero. // Reset the sign and the exponent. neg = false; exp = static_cast(0); } else { // Justify the data const std::size_t sj = static_cast(std::distance(data.begin(), first_nonzero_elem)); std::copy(data.begin() + static_cast(sj), data.end(), data.begin()); std::fill(data.end() - sj, data.end(), static_cast(0u)); exp -= static_cast(sj * static_cast(cpp_dec_float_elem_digits10)); } } } // Handle underflow. if(iszero()) return (*this = zero()); // Check for potential overflow. const bool b_result_might_overflow = (exp >= static_cast(cpp_dec_float_max_exp10)); // Handle overflow. if(b_result_might_overflow) { const bool b_result_is_neg = neg; neg = false; if(compare((cpp_dec_float::max)()) > 0) *this = inf(); neg = b_result_is_neg; } return *this; } template cpp_dec_float& cpp_dec_float::operator-=(const cpp_dec_float& v) { // Use *this - v = -(-*this + v). negate(); *this += v; negate(); return *this; } template cpp_dec_float& cpp_dec_float::operator*=(const cpp_dec_float& v) { // Evaluate the sign of the result. const bool b_result_is_neg = (neg != v.neg); // Artificially set the sign of the result to be positive. neg = false; // Handle special cases like zero, inf and NaN. const bool b_u_is_inf = (isinf)(); const bool b_v_is_inf = (v.isinf)(); const bool b_u_is_zero = iszero(); const bool b_v_is_zero = v.iszero(); if( ((isnan)() || (v.isnan)()) || (b_u_is_inf && b_v_is_zero) || (b_v_is_inf && b_u_is_zero) ) { *this = nan(); return *this; } if(b_u_is_inf || b_v_is_inf) { *this = inf(); if(b_result_is_neg) negate(); return *this; } if(b_u_is_zero || b_v_is_zero) { return *this = zero(); } // Check for potential overflow or underflow. const bool b_result_might_overflow = ((exp + v.exp) >= static_cast(cpp_dec_float_max_exp10)); const bool b_result_might_underflow = ((exp + v.exp) <= static_cast(cpp_dec_float_min_exp10)); // Set the exponent of the result. exp += v.exp; const boost::int32_t prec_mul = (std::min)(prec_elem, v.prec_elem); const boost::uint32_t carry = mul_loop_uv(data.data(), v.data.data(), prec_mul); // Handle a potential carry. if(carry != static_cast(0u)) { exp += cpp_dec_float_elem_digits10; // Shift the result of the multiplication one element to the right... std::copy_backward(data.begin(), data.begin() + static_cast(prec_elem - static_cast(1)), data.begin() + static_cast(prec_elem)); // ... And insert the carry. data.front() = carry; } // Handle overflow. if(b_result_might_overflow && (compare((cpp_dec_float::max)()) > 0)) { *this = inf(); } // Handle underflow. if(b_result_might_underflow && (compare((cpp_dec_float::min)()) < 0)) { *this = zero(); return *this; } // Set the sign of the result. neg = b_result_is_neg; return *this; } template cpp_dec_float& cpp_dec_float::operator/=(const cpp_dec_float& v) { const bool u_and_v_are_finite_and_identical = ( (isfinite)() && (fpclass == v.fpclass) && (exp == v.exp) && (cmp_data(v.data) == static_cast(0))); if(u_and_v_are_finite_and_identical) { if(neg != v.neg) { *this = one(); negate(); } else *this = one(); return *this; } else { if(iszero()) { if((v.isnan)() || v.iszero()) { return *this = v; } return *this; } cpp_dec_float t(v); t.calculate_inv(); return operator*=(t); } } template cpp_dec_float& cpp_dec_float::mul_unsigned_long_long(const unsigned long long n) { // Multiply *this with a constant unsigned long long. // Evaluate the sign of the result. const bool b_neg = neg; // Artificially set the sign of the result to be positive. neg = false; // Handle special cases like zero, inf and NaN. const bool b_u_is_inf = (isinf)(); const bool b_n_is_zero = (n == static_cast(0)); if((isnan)() || (b_u_is_inf && b_n_is_zero)) { return (*this = nan()); } if(b_u_is_inf) { *this = inf(); if(b_neg) negate(); return *this; } if(iszero() || b_n_is_zero) { // Multiplication by zero. return *this = zero(); } if(n >= static_cast(cpp_dec_float_elem_mask)) { neg = b_neg; cpp_dec_float t; t = n; return operator*=(t); } if(n == static_cast(1u)) { neg = b_neg; return *this; } // Set up the multiplication loop. const boost::uint32_t nn = static_cast(n); const boost::uint32_t carry = mul_loop_n(data.data(), nn, prec_elem); // Handle the carry and adjust the exponent. if(carry != static_cast(0u)) { exp += static_cast(cpp_dec_float_elem_digits10); // Shift the result of the multiplication one element to the right. std::copy_backward(data.begin(), data.begin() + static_cast(prec_elem - static_cast(1)), data.begin() + static_cast(prec_elem)); data.front() = static_cast(carry); } // Check for potential overflow. const bool b_result_might_overflow = (exp >= cpp_dec_float_max_exp10); // Handle overflow. if(b_result_might_overflow && (compare((cpp_dec_float::max)()) > 0)) { *this = inf(); } // Set the sign. neg = b_neg; return *this; } template cpp_dec_float& cpp_dec_float::div_unsigned_long_long(const unsigned long long n) { // Divide *this by a constant unsigned long long. // Evaluate the sign of the result. const bool b_neg = neg; // Artificially set the sign of the result to be positive. neg = false; // Handle special cases like zero, inf and NaN. if((isnan)()) { return *this; } if((isinf)()) { *this = inf(); if(b_neg) negate(); return *this; } if(n == static_cast(0u)) { // Divide by 0. if(iszero()) { *this = nan(); return *this; } else { *this = inf(); if(isneg()) negate(); return *this; } } if(iszero()) { return *this; } if(n >= static_cast(cpp_dec_float_elem_mask)) { neg = b_neg; cpp_dec_float t; t = n; return operator/=(t); } const boost::uint32_t nn = static_cast(n); if(nn > static_cast(1u)) { // Do the division loop. const boost::uint32_t prev = div_loop_n(data.data(), nn, prec_elem); // Determine if one leading zero is in the result data. if(data[0] == static_cast(0u)) { // Adjust the exponent exp -= static_cast(cpp_dec_float_elem_digits10); // Shift result of the division one element to the left. std::copy(data.begin() + static_cast(1u), data.begin() + static_cast(prec_elem - static_cast(1)), data.begin()); data[prec_elem - static_cast(1)] = static_cast(static_cast(prev * static_cast(cpp_dec_float_elem_mask)) / nn); } } // Check for potential underflow. const bool b_result_might_underflow = (exp <= cpp_dec_float_min_exp10); // Handle underflow. if(b_result_might_underflow && (compare((cpp_dec_float::min)()) < 0)) return (*this = zero()); // Set the sign of the result. neg = b_neg; return *this; } template cpp_dec_float& cpp_dec_float::calculate_inv() { // Compute the inverse of *this. const bool b_neg = neg; neg = false; // Handle special cases like zero, inf and NaN. if(iszero()) { *this = inf(); if(b_neg) negate(); return *this; } if((isnan)()) { return *this; } if((isinf)()) { return *this = zero(); } if(isone()) { if(b_neg) negate(); return *this; } // Save the original *this. cpp_dec_float x(*this); // Generate the initial estimate using division. // Extract the mantissa and exponent for a "manual" // computation of the estimate. double dd; ExponentType ne; x.extract_parts(dd, ne); // Do the inverse estimate using double precision estimates of mantissa and exponent. operator=(cpp_dec_float(1.0 / dd, -ne)); // Compute the inverse of *this. Quadratically convergent Newton-Raphson iteration // is used. During the iterative steps, the precision of the calculation is limited // to the minimum required in order to minimize the run-time. static const boost::int32_t double_digits10_minus_a_few = std::numeric_limits::digits10 - 3; for(boost::int32_t digits = double_digits10_minus_a_few; digits <= cpp_dec_float_total_digits10; digits *= static_cast(2)) { // Adjust precision of the terms. precision(static_cast((digits + 10) * static_cast(2))); x.precision(static_cast((digits + 10) * static_cast(2))); // Next iteration. cpp_dec_float t(*this); t *= x; t -= two(); t.negate(); *this *= t; } neg = b_neg; prec_elem = cpp_dec_float_elem_number; return *this; } template cpp_dec_float& cpp_dec_float::calculate_sqrt() { // Compute the square root of *this. if(isneg() || (!(isfinite)())) { *this = nan(); return *this; } if(iszero() || isone()) { return *this; } // Save the original *this. cpp_dec_float x(*this); // Generate the initial estimate using division. // Extract the mantissa and exponent for a "manual" // computation of the estimate. double dd; ExponentType ne; extract_parts(dd, ne); // Force the exponent to be an even multiple of two. if((ne % static_cast(2)) != static_cast(0)) { ++ne; dd /= 10.0; } // Setup the iteration. // Estimate the square root using simple manipulations. const double sqd = std::sqrt(dd); *this = cpp_dec_float(sqd, static_cast(ne / static_cast(2))); // Estimate 1.0 / (2.0 * x0) using simple manipulations. cpp_dec_float vi(0.5 / sqd, static_cast(-ne / static_cast(2))); // Compute the square root of x. Coupled Newton iteration // as described in "Pi Unleashed" is used. During the // iterative steps, the precision of the calculation is // limited to the minimum required in order to minimize // the run-time. // // Book references: // http://www.jjj.de/pibook/pibook.html // http://www.amazon.com/exec/obidos/tg/detail/-/3540665722/qid=1035535482/sr=8-7/ref=sr_8_7/104-3357872-6059916?v=glance&n=507846 static const boost::uint32_t double_digits10_minus_a_few = std::numeric_limits::digits10 - 3; for(boost::int32_t digits = double_digits10_minus_a_few; digits <= cpp_dec_float_total_digits10; digits *= 2u) { // Adjust precision of the terms. precision((digits + 10) * 2); vi.precision((digits + 10) * 2); // Next iteration of vi cpp_dec_float t(*this); t *= vi; t.negate(); t.mul_unsigned_long_long(2u); t += one(); t *= vi; vi += t; // Next iteration of *this t = *this; t *= *this; t.negate(); t += x; t *= vi; *this += t; } prec_elem = cpp_dec_float_elem_number; return *this; } template int cpp_dec_float::cmp_data(const array_type& vd) const { // Compare the data of *this with those of v. // Return +1 for *this > v // 0 for *this = v // -1 for *this < v const std::pair mismatch_pair = std::mismatch(data.begin(), data.end(), vd.begin()); const bool is_equal = ((mismatch_pair.first == data.end()) && (mismatch_pair.second == vd.end())); if(is_equal) { return 0; } else { return ((*mismatch_pair.first > *mismatch_pair.second) ? 1 : -1); } } template int cpp_dec_float::compare(const cpp_dec_float& v) const { // Compare v with *this. // Return +1 for *this > v // 0 for *this = v // -1 for *this < v // Handle all non-finite cases. if((!(isfinite)()) || (!(v.isfinite)())) { // NaN can never equal NaN. Return an implementation-dependent // signed result. Also note that comparison of NaN with NaN // using operators greater-than or less-than is undefined. if((isnan)() || (v.isnan)()) { return ((isnan)() ? 1 : -1); } if((isinf)() && (v.isinf)()) { // Both *this and v are infinite. They are equal if they have the same sign. // Otherwise, *this is less than v if and only if *this is negative. return ((neg == v.neg) ? 0 : (neg ? -1 : 1)); } if((isinf)()) { // *this is infinite, but v is finite. // So negative infinite *this is less than any finite v. // Whereas positive infinite *this is greater than any finite v. return (isneg() ? -1 : 1); } else { // *this is finite, and v is infinite. // So any finite *this is greater than negative infinite v. // Whereas any finite *this is less than positive infinite v. return (v.neg ? 1 : -1); } } // And now handle all *finite* cases. if(iszero()) { // The value of *this is zero and v is either zero or non-zero. return (v.iszero() ? 0 : (v.neg ? 1 : -1)); } else if(v.iszero()) { // The value of v is zero and *this is non-zero. return (neg ? -1 : 1); } else { // Both *this and v are non-zero. if(neg != v.neg) { // The signs are different. return (neg ? -1 : 1); } else if(exp != v.exp) { // The signs are the same and the exponents are different. const int val_cexpression = ((exp < v.exp) ? 1 : -1); return (neg ? val_cexpression : -val_cexpression); } else { // The signs are the same and the exponents are the same. // Compare the data. const int val_cmp_data = cmp_data(v.data); return ((!neg) ? val_cmp_data : -val_cmp_data); } } } template bool cpp_dec_float::isone() const { // Check if the value of *this is identically 1 or very close to 1. const bool not_negative_and_is_finite = ((!neg) && (isfinite)()); if(not_negative_and_is_finite) { if((data[0u] == static_cast(1u)) && (exp == static_cast(0))) { const typename array_type::const_iterator it_non_zero = std::find_if(data.begin(), data.end(), data_elem_is_non_zero_predicate); return (it_non_zero == data.end()); } else if((data[0u] == static_cast(cpp_dec_float_elem_mask - 1)) && (exp == static_cast(-cpp_dec_float_elem_digits10))) { const typename array_type::const_iterator it_non_nine = std::find_if(data.begin(), data.end(), data_elem_is_non_nine_predicate); return (it_non_nine == data.end()); } } return false; } template bool cpp_dec_float::isint() const { if(fpclass != cpp_dec_float_finite) { return false; } if(iszero()) { return true; } if(exp < static_cast(0)) { return false; } // |*this| < 1. const typename array_type::size_type offset_decimal_part = static_cast(exp / cpp_dec_float_elem_digits10) + 1u; if(offset_decimal_part >= static_cast(cpp_dec_float_elem_number)) { // The number is too large to resolve the integer part. // It considered to be a pure integer. return true; } typename array_type::const_iterator it_non_zero = std::find_if(data.begin() + offset_decimal_part, data.end(), data_elem_is_non_zero_predicate); return (it_non_zero == data.end()); } template void cpp_dec_float::extract_parts(double& mantissa, ExponentType& exponent) const { // Extract the approximate parts mantissa and base-10 exponent from the input cpp_dec_float value x. // Extracts the mantissa and exponent. exponent = exp; boost::uint32_t p10 = static_cast(1u); boost::uint32_t test = data[0u]; for(;;) { test /= static_cast(10u); if(test == static_cast(0u)) { break; } p10 *= static_cast(10u); ++exponent; } // Establish the upper bound of limbs for extracting the double. const int max_elem_in_double_count = static_cast(static_cast(std::numeric_limits::digits10) / cpp_dec_float_elem_digits10) + (static_cast(static_cast(std::numeric_limits::digits10) % cpp_dec_float_elem_digits10) != 0 ? 1 : 0) + 1; // And make sure this upper bound stays within bounds of the elems. const std::size_t max_elem_extract_count = static_cast((std::min)(static_cast(max_elem_in_double_count), cpp_dec_float_elem_number)); // Extract into the mantissa the first limb, extracted as a double. mantissa = static_cast(data[0]); double scale = 1.0; // Extract the rest of the mantissa piecewise from the limbs. for(std::size_t i = 1u; i < max_elem_extract_count; i++) { scale /= static_cast(cpp_dec_float_elem_mask); mantissa += (static_cast(data[i]) * scale); } mantissa /= static_cast(p10); if(neg) { mantissa = -mantissa; } } template double cpp_dec_float::extract_double() const { // Returns the double conversion of a cpp_dec_float. // Check for non-normal cpp_dec_float. if(!(isfinite)()) { if((isnan)()) { return std::numeric_limits::quiet_NaN(); } else { return ((!neg) ? std::numeric_limits::infinity() : -std::numeric_limits::infinity()); } } cpp_dec_float xx(*this); if(xx.isneg()) xx.negate(); // Check if *this cpp_dec_float is zero. if(iszero() || (xx.compare(double_min()) < 0)) { return 0.0; } // Check if *this cpp_dec_float exceeds the maximum of double. if(xx.compare(double_max()) > 0) { return ((!neg) ? std::numeric_limits::infinity() : -std::numeric_limits::infinity()); } std::stringstream ss; ss << str(std::numeric_limits::digits10 + (2 + 1), std::ios_base::scientific); double d; ss >> d; return d; } template long double cpp_dec_float::extract_long_double() const { // Returns the long double conversion of a cpp_dec_float. // Check if *this cpp_dec_float is subnormal. if(!(isfinite)()) { if((isnan)()) { return std::numeric_limits::quiet_NaN(); } else { return ((!neg) ? std::numeric_limits::infinity() : -std::numeric_limits::infinity()); } } cpp_dec_float xx(*this); if(xx.isneg()) xx.negate(); // Check if *this cpp_dec_float is zero. if(iszero() || (xx.compare(long_double_min()) < 0)) { return static_cast(0.0); } // Check if *this cpp_dec_float exceeds the maximum of double. if(xx.compare(long_double_max()) > 0) { return ((!neg) ? std::numeric_limits::infinity() : -std::numeric_limits::infinity()); } std::stringstream ss; ss << str(std::numeric_limits::digits10 + (2 + 1), std::ios_base::scientific); long double ld; ss >> ld; return ld; } template signed long long cpp_dec_float::extract_signed_long_long() const { // Extracts a signed long long from *this. // If (x > maximum of signed long long) or (x < minimum of signed long long), // then the maximum or minimum of signed long long is returned accordingly. if(exp < static_cast(0)) { return static_cast(0); } const bool b_neg = isneg(); unsigned long long val; if((!b_neg) && (compare(long_long_max()) > 0)) { return (std::numeric_limits::max)(); } else if(b_neg && (compare(long_long_min()) < 0)) { return (std::numeric_limits::min)(); } else { // Extract the data into an unsigned long long value. cpp_dec_float xn(extract_integer_part()); if(xn.isneg()) xn.negate(); val = static_cast(xn.data[0]); const boost::int32_t imax = (std::min)(static_cast(static_cast(xn.exp) / cpp_dec_float_elem_digits10), static_cast(cpp_dec_float_elem_number - static_cast(1))); for(boost::int32_t i = static_cast(1); i <= imax; i++) { val *= static_cast(cpp_dec_float_elem_mask); val += static_cast(xn.data[i]); } } if (!b_neg) { return static_cast(val); } else { // This strange expression avoids a hardware trap in the corner case // that val is the most negative value permitted in long long. // See https://svn.boost.org/trac/boost/ticket/9740. // signed long long sval = static_cast(val - 1); sval = -sval; --sval; return sval; } } template unsigned long long cpp_dec_float::extract_unsigned_long_long() const { // Extracts an unsigned long long from *this. // If x exceeds the maximum of unsigned long long, // then the maximum of unsigned long long is returned. // If x is negative, then the unsigned long long cast of // the signed long long extracted value is returned. if(isneg()) { return static_cast(extract_signed_long_long()); } if(exp < static_cast(0)) { return static_cast(0u); } const cpp_dec_float xn(extract_integer_part()); unsigned long long val; if(xn.compare(ulong_long_max()) > 0) { return (std::numeric_limits::max)(); } else { // Extract the data into an unsigned long long value. val = static_cast(xn.data[0]); const boost::int32_t imax = (std::min)(static_cast(static_cast(xn.exp) / cpp_dec_float_elem_digits10), static_cast(cpp_dec_float_elem_number - static_cast(1))); for(boost::int32_t i = static_cast(1); i <= imax; i++) { val *= static_cast(cpp_dec_float_elem_mask); val += static_cast(xn.data[i]); } } return val; } template cpp_dec_float cpp_dec_float::extract_integer_part() const { // Compute the signed integer part of x. if(!(isfinite)()) { return *this; } if(exp < static_cast(0)) { // The absolute value of the number is smaller than 1. // Thus the integer part is zero. return zero(); } // Truncate the digits from the decimal part, including guard digits // that do not belong to the integer part. // Make a local copy. cpp_dec_float x = *this; // Clear out the decimal portion const size_t first_clear = (static_cast(x.exp) / static_cast(cpp_dec_float_elem_digits10)) + 1u; const size_t last_clear = static_cast(cpp_dec_float_elem_number); if(first_clear < last_clear) std::fill(x.data.begin() + first_clear, x.data.begin() + last_clear, static_cast(0u)); return x; } template std::string cpp_dec_float::str(boost::intmax_t number_of_digits, std::ios_base::fmtflags f) const { if((this->isinf)()) { if(this->isneg()) return "-inf"; else if(f & std::ios_base::showpos) return "+inf"; else return "inf"; } else if((this->isnan)()) { return "nan"; } std::string str; boost::intmax_t org_digits(number_of_digits); ExponentType my_exp = order(); if(number_of_digits == 0) number_of_digits = cpp_dec_float_total_digits10; if(f & std::ios_base::fixed) { number_of_digits += my_exp + 1; } else if(f & std::ios_base::scientific) ++number_of_digits; // Determine the number of elements needed to provide the requested digits from cpp_dec_float. const std::size_t number_of_elements = (std::min)(static_cast((number_of_digits / static_cast(cpp_dec_float_elem_digits10)) + 2u), static_cast(cpp_dec_float_elem_number)); // Extract the remaining digits from cpp_dec_float after the decimal point. str = boost::lexical_cast(data[0]); // Extract all of the digits from cpp_dec_float, beginning with the first data element. for(std::size_t i = static_cast(1u); i < number_of_elements; i++) { std::stringstream ss; ss << std::setw(static_cast(cpp_dec_float_elem_digits10)) << std::setfill(static_cast('0')) << data[i]; str += ss.str(); } bool have_leading_zeros = false; if(number_of_digits == 0) { // We only get here if the output format is "fixed" and we just need to // round the first non-zero digit. number_of_digits -= my_exp + 1; // reset to original value str.insert(static_cast(0), std::string::size_type(number_of_digits), '0'); have_leading_zeros = true; } if(number_of_digits < 0) { str = "0"; if(isneg()) str.insert(static_cast(0), 1, '-'); boost::multiprecision::detail::format_float_string(str, 0, number_of_digits - my_exp - 1, f, this->iszero()); return str; } else { // Cut the output to the size of the precision. if(str.length() > static_cast(number_of_digits)) { // Get the digit after the last needed digit for rounding const boost::uint32_t round = static_cast(static_cast(str[static_cast(number_of_digits)]) - static_cast('0')); bool need_round_up = round >= 5u; if(round == 5u) { const boost::uint32_t ix = static_cast(static_cast