inline void eval_acos(T& result, const T& x) { BOOST_STATIC_ASSERT_MSG(number_category<T>::value == number_kind_floating_point, "The acos function is only valid for floating point types."); typedef typename boost::multiprecision::detail::canonical<boost::uint32_t, T>::type ui_type; switch(eval_fpclassify(x)) { case FP_NAN: case FP_INFINITE: if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) { result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); errno = EDOM; } else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; case FP_ZERO: result = get_constant_pi<T>(); eval_ldexp(result, result, -1); // divide by two. return; } eval_abs(result, x); int c = result.compare(ui_type(1)); if(c > 0) { if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) { result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); errno = EDOM; } else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; } else if(c == 0) { if(eval_get_sign(x) < 0) result = get_constant_pi<T>(); else result = ui_type(0); return; } eval_asin(result, x); T t; eval_ldexp(t, get_constant_pi<T>(), -1); eval_subtract(result, t); result.negate(); }
void eval_asin(T& result, const T& x) { BOOST_STATIC_ASSERT_MSG(number_category<T>::value == number_kind_floating_point, "The asin function is only valid for floating point types."); typedef typename boost::multiprecision::detail::canonical<boost::uint32_t, T>::type ui_type; typedef typename mpl::front<typename T::float_types>::type fp_type; if(&result == &x) { T t(x); eval_asin(result, t); return; } switch(eval_fpclassify(x)) { case FP_NAN: case FP_INFINITE: if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; case FP_ZERO: result = ui_type(0); return; default: ; } const bool b_neg = eval_get_sign(x) < 0; T xx(x); if(b_neg) xx.negate(); int c = xx.compare(ui_type(1)); if(c > 0) { if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; } else if(c == 0) { result = get_constant_pi<T>(); eval_ldexp(result, result, -1); if(b_neg) result.negate(); return; } if(xx.compare(fp_type(1e-4)) < 0) { // http://functions.wolfram.com/ElementaryFunctions/ArcSin/26/01/01/ eval_multiply(xx, xx); T t1, t2; t1 = fp_type(0.5f); t2 = fp_type(1.5f); hyp2F1(result, t1, t1, t2, xx); eval_multiply(result, x); return; } else if(xx.compare(fp_type(1 - 1e-4f)) > 0) { T dx1; T t1, t2; eval_subtract(dx1, ui_type(1), xx); t1 = fp_type(0.5f); t2 = fp_type(1.5f); eval_ldexp(dx1, dx1, -1); hyp2F1(result, t1, t1, t2, dx1); eval_ldexp(dx1, dx1, 2); eval_sqrt(t1, dx1); eval_multiply(result, t1); eval_ldexp(t1, get_constant_pi<T>(), -1); result.negate(); eval_add(result, t1); if(b_neg) result.negate(); return; } #ifndef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS typedef typename boost::multiprecision::detail::canonical<long double, T>::type guess_type; #else typedef fp_type guess_type; #endif // Get initial estimate using standard math function asin. guess_type dd; eval_convert_to(&dd, xx); result = (guess_type)(std::asin(dd)); unsigned current_digits = std::numeric_limits<guess_type>::digits - 5; unsigned target_precision = boost::multiprecision::detail::digits2<number<T, et_on> >::value; // Newton-Raphson iteration while(current_digits < target_precision) { T sine, cosine; eval_sin(sine, result); eval_cos(cosine, result); eval_subtract(sine, xx); eval_divide(sine, cosine); eval_subtract(result, sine); current_digits *= 2; /* T lim; eval_ldexp(lim, result, 1 - boost::multiprecision::detail::digits2<number<T, et_on> >::value); if(eval_get_sign(s) < 0) s.negate(); if(eval_get_sign(lim) < 0) lim.negate(); if(lim.compare(s) >= 0) break; */ } if(b_neg) result.negate(); }
void eval_asin(T& result, const T& x) { BOOST_STATIC_ASSERT_MSG(number_category<T>::value == number_kind_floating_point, "The asin function is only valid for floating point types."); typedef typename boost::multiprecision::detail::canonical<boost::uint32_t, T>::type ui_type; typedef typename mpl::front<typename T::float_types>::type fp_type; if(&result == &x) { T t(x); eval_asin(result, t); return; } switch(eval_fpclassify(x)) { case FP_NAN: case FP_INFINITE: if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) { result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); errno = EDOM; } else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; case FP_ZERO: result = x; return; default: ; } const bool b_neg = eval_get_sign(x) < 0; T xx(x); if(b_neg) xx.negate(); int c = xx.compare(ui_type(1)); if(c > 0) { if(std::numeric_limits<number<T, et_on> >::has_quiet_NaN) { result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); errno = EDOM; } else BOOST_THROW_EXCEPTION(std::domain_error("Result is undefined or complex and there is no NaN for this number type.")); return; } else if(c == 0) { result = get_constant_pi<T>(); eval_ldexp(result, result, -1); if(b_neg) result.negate(); return; } if(xx.compare(fp_type(1e-4)) < 0) { // http://functions.wolfram.com/ElementaryFunctions/ArcSin/26/01/01/ eval_multiply(xx, xx); T t1, t2; t1 = fp_type(0.5f); t2 = fp_type(1.5f); hyp2F1(result, t1, t1, t2, xx); eval_multiply(result, x); return; } else if(xx.compare(fp_type(1 - 1e-4f)) > 0) { T dx1; T t1, t2; eval_subtract(dx1, ui_type(1), xx); t1 = fp_type(0.5f); t2 = fp_type(1.5f); eval_ldexp(dx1, dx1, -1); hyp2F1(result, t1, t1, t2, dx1); eval_ldexp(dx1, dx1, 2); eval_sqrt(t1, dx1); eval_multiply(result, t1); eval_ldexp(t1, get_constant_pi<T>(), -1); result.negate(); eval_add(result, t1); if(b_neg) result.negate(); return; } #ifndef BOOST_MATH_NO_LONG_DOUBLE_MATH_FUNCTIONS typedef typename boost::multiprecision::detail::canonical<long double, T>::type guess_type; #else typedef fp_type guess_type; #endif // Get initial estimate using standard math function asin. guess_type dd; eval_convert_to(&dd, xx); result = (guess_type)(std::asin(dd)); // Newton-Raphson iteration, we should double our precision with each iteration, // in practice this seems to not quite work in all cases... so terminate when we // have at least 2/3 of the digits correct on the assumption that the correction // we've just added will finish the job... boost::intmax_t current_precision = eval_ilogb(result); boost::intmax_t target_precision = current_precision - 1 - (std::numeric_limits<number<T> >::digits * 2) / 3; // Newton-Raphson iteration while(current_precision > target_precision) { T sine, cosine; eval_sin(sine, result); eval_cos(cosine, result); eval_subtract(sine, xx); eval_divide(sine, cosine); eval_subtract(result, sine); current_precision = eval_ilogb(sine); if(current_precision <= (std::numeric_limits<typename T::exponent_type>::min)() + 1) break; } if(b_neg) result.negate(); }
void eval_asin(T& result, const T& x) { BOOST_STATIC_ASSERT_MSG(number_category<T>::value == number_kind_floating_point, "The asin function is only valid for floating point types."); typedef typename boost::multiprecision::detail::canonical<boost::int32_t, T>::type si_type; typedef typename boost::multiprecision::detail::canonical<boost::uint32_t, T>::type ui_type; typedef typename T::exponent_type exp_type; typedef typename boost::multiprecision::detail::canonical<exp_type, T>::type canonical_exp_type; typedef typename mpl::front<typename T::float_types>::type fp_type; if(&result == &x) { T t(x); eval_asin(result, t); return; } switch(eval_fpclassify(x)) { case FP_NAN: case FP_INFINITE: result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); return; case FP_ZERO: result = ui_type(0); return; default: ; } const bool b_neg = eval_get_sign(x) < 0; T xx(x); if(b_neg) xx.negate(); int c = xx.compare(ui_type(1)); if(c > 0) { result = std::numeric_limits<number<T, et_on> >::quiet_NaN().backend(); return; } else if(c == 0) { result = get_constant_pi<T>(); eval_ldexp(result, result, -1); if(b_neg) result.negate(); return; } if(xx.compare(fp_type(1e-4)) < 0) { // http://functions.wolfram.com/ElementaryFunctions/ArcSin/26/01/01/ eval_multiply(xx, xx); T t1, t2; t1 = fp_type(0.5f); t2 = fp_type(1.5f); hyp2F1(result, t1, t1, t2, xx); eval_multiply(result, x); return; } else if(xx.compare(fp_type(1 - 1e-4f)) > 0) { T dx1; T t1, t2; eval_subtract(dx1, ui_type(1), xx); t1 = fp_type(0.5f); t2 = fp_type(1.5f); eval_ldexp(dx1, dx1, -1); hyp2F1(result, t1, t1, t2, dx1); eval_ldexp(dx1, dx1, 2); eval_sqrt(t1, dx1); eval_multiply(result, t1); eval_ldexp(t1, get_constant_pi<T>(), -1); result.negate(); eval_add(result, t1); if(b_neg) result.negate(); return; } // Get initial estimate using standard math function asin. double dd; eval_convert_to(&dd, xx); result = fp_type(std::asin(dd)); // Newton-Raphson iteration while(true) { T s, c; eval_sin(s, result); eval_cos(c, result); eval_subtract(s, xx); eval_divide(s, c); eval_subtract(result, s); T lim; eval_ldexp(lim, result, 1 - boost::multiprecision::detail::digits2<number<T, et_on> >::value); if(eval_get_sign(s) < 0) s.negate(); if(eval_get_sign(lim) < 0) lim.negate(); if(lim.compare(s) >= 0) break; } if(b_neg) result.negate(); }