// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2007 Julien Pommier // Copyright (C) 2014 Pedro Gonnet (pedro.gonnet@gmail.com) // Copyright (C) 2009-2019 Gael Guennebaud // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed // with this file, You can obtain one at http://mozilla.org/MPL/2.0/. /* The exp and log functions of this file initially come from * Julien Pommier's sse math library: http://gruntthepeon.free.fr/ssemath/ */ #ifndef EIGEN_ARCH_GENERIC_PACKET_MATH_FUNCTIONS_H #define EIGEN_ARCH_GENERIC_PACKET_MATH_FUNCTIONS_H // IWYU pragma: private #include "../../InternalHeaderCheck.h" namespace Eigen { namespace internal { // Creates a Scalar integer type with same bit-width. template struct make_integer; template <> struct make_integer { typedef numext::int32_t type; }; template <> struct make_integer { typedef numext::int64_t type; }; template <> struct make_integer { typedef numext::int16_t type; }; template <> struct make_integer { typedef numext::int16_t type; }; template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Packet pfrexp_generic_get_biased_exponent(const Packet& a) { typedef typename unpacket_traits::type Scalar; typedef typename unpacket_traits::integer_packet PacketI; static constexpr int mantissa_bits = numext::numeric_limits::digits - 1; return pcast(plogical_shift_right(preinterpret(pabs(a)))); } // Safely applies frexp, correctly handles denormals. // Assumes IEEE floating point format. template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Packet pfrexp_generic(const Packet& a, Packet& exponent) { typedef typename unpacket_traits::type Scalar; typedef typename make_unsigned::type>::type ScalarUI; static constexpr int TotalBits = sizeof(Scalar) * CHAR_BIT, MantissaBits = numext::numeric_limits::digits - 1, ExponentBits = TotalBits - MantissaBits - 1; EIGEN_CONSTEXPR ScalarUI scalar_sign_mantissa_mask = ~(((ScalarUI(1) << ExponentBits) - ScalarUI(1)) << MantissaBits); // ~0x7f800000 const Packet sign_mantissa_mask = pset1frombits(static_cast(scalar_sign_mantissa_mask)); const Packet half = pset1(Scalar(0.5)); const Packet zero = pzero(a); const Packet normal_min = pset1((numext::numeric_limits::min)()); // Minimum normal value, 2^-126 // To handle denormals, normalize by multiplying by 2^(int(MantissaBits)+1). const Packet is_denormal = pcmp_lt(pabs(a), normal_min); EIGEN_CONSTEXPR ScalarUI scalar_normalization_offset = ScalarUI(MantissaBits + 1); // 24 // The following cannot be constexpr because bfloat16(uint16_t) is not constexpr. const Scalar scalar_normalization_factor = Scalar(ScalarUI(1) << int(scalar_normalization_offset)); // 2^24 const Packet normalization_factor = pset1(scalar_normalization_factor); const Packet normalized_a = pselect(is_denormal, pmul(a, normalization_factor), a); // Determine exponent offset: -126 if normal, -126-24 if denormal const Scalar scalar_exponent_offset = -Scalar((ScalarUI(1) << (ExponentBits - 1)) - ScalarUI(2)); // -126 Packet exponent_offset = pset1(scalar_exponent_offset); const Packet normalization_offset = pset1(-Scalar(scalar_normalization_offset)); // -24 exponent_offset = pselect(is_denormal, padd(exponent_offset, normalization_offset), exponent_offset); // Determine exponent and mantissa from normalized_a. exponent = pfrexp_generic_get_biased_exponent(normalized_a); // Zero, Inf and NaN return 'a' unmodified, exponent is zero // (technically the exponent is unspecified for inf/NaN, but GCC/Clang set it to zero) const Scalar scalar_non_finite_exponent = Scalar((ScalarUI(1) << ExponentBits) - ScalarUI(1)); // 255 const Packet non_finite_exponent = pset1(scalar_non_finite_exponent); const Packet is_zero_or_not_finite = por(pcmp_eq(a, zero), pcmp_eq(exponent, non_finite_exponent)); const Packet m = pselect(is_zero_or_not_finite, a, por(pand(normalized_a, sign_mantissa_mask), half)); exponent = pselect(is_zero_or_not_finite, zero, padd(exponent, exponent_offset)); return m; } // Safely applies ldexp, correctly handles overflows, underflows and denormals. // Assumes IEEE floating point format. template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Packet pldexp_generic(const Packet& a, const Packet& exponent) { // We want to return a * 2^exponent, allowing for all possible integer // exponents without overflowing or underflowing in intermediate // computations. // // Since 'a' and the output can be denormal, the maximum range of 'exponent' // to consider for a float is: // -255-23 -> 255+23 // Below -278 any finite float 'a' will become zero, and above +278 any // finite float will become inf, including when 'a' is the smallest possible // denormal. // // Unfortunately, 2^(278) cannot be represented using either one or two // finite normal floats, so we must split the scale factor into at least // three parts. It turns out to be faster to split 'exponent' into four // factors, since [exponent>>2] is much faster to compute that [exponent/3]. // // Set e = min(max(exponent, -278), 278); // b = floor(e/4); // out = ((((a * 2^(b)) * 2^(b)) * 2^(b)) * 2^(e-3*b)) // // This will avoid any intermediate overflows and correctly handle 0, inf, // NaN cases. typedef typename unpacket_traits::integer_packet PacketI; typedef typename unpacket_traits::type Scalar; typedef typename unpacket_traits::type ScalarI; static constexpr int TotalBits = sizeof(Scalar) * CHAR_BIT, MantissaBits = numext::numeric_limits::digits - 1, ExponentBits = TotalBits - MantissaBits - 1; const Packet max_exponent = pset1(Scalar((ScalarI(1) << ExponentBits) + ScalarI(MantissaBits - 1))); // 278 const PacketI bias = pset1((ScalarI(1) << (ExponentBits - 1)) - ScalarI(1)); // 127 const PacketI e = pcast(pmin(pmax(exponent, pnegate(max_exponent)), max_exponent)); PacketI b = parithmetic_shift_right<2>(e); // floor(e/4); Packet c = preinterpret(plogical_shift_left(padd(b, bias))); // 2^b Packet out = pmul(pmul(pmul(a, c), c), c); // a * 2^(3b) b = psub(psub(psub(e, b), b), b); // e - 3b c = preinterpret(plogical_shift_left(padd(b, bias))); // 2^(e-3*b) out = pmul(out, c); return out; } // Explicitly multiplies // a * (2^e) // clamping e to the range // [NumTraits::min_exponent()-2, NumTraits::max_exponent()] // // This is approx 7x faster than pldexp_impl, but will prematurely over/underflow // if 2^e doesn't fit into a normal floating-point Scalar. // // Assumes IEEE floating point format template struct pldexp_fast_impl { typedef typename unpacket_traits::integer_packet PacketI; typedef typename unpacket_traits::type Scalar; typedef typename unpacket_traits::type ScalarI; static constexpr int TotalBits = sizeof(Scalar) * CHAR_BIT, MantissaBits = numext::numeric_limits::digits - 1, ExponentBits = TotalBits - MantissaBits - 1; static EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC Packet run(const Packet& a, const Packet& exponent) { const Packet bias = pset1(Scalar((ScalarI(1) << (ExponentBits - 1)) - ScalarI(1))); // 127 const Packet limit = pset1(Scalar((ScalarI(1) << ExponentBits) - ScalarI(1))); // 255 // restrict biased exponent between 0 and 255 for float. const PacketI e = pcast(pmin(pmax(padd(exponent, bias), pzero(limit)), limit)); // exponent + 127 // return a * (2^e) return pmul(a, preinterpret(plogical_shift_left(e))); } }; // Natural or base 2 logarithm. // Computes log(x) as log(2^e * m) = C*e + log(m), where the constant C =log(2) // and m is in the range [sqrt(1/2),sqrt(2)). In this range, the logarithm can // be easily approximated by a polynomial centered on m=1 for stability. // TODO(gonnet): Further reduce the interval allowing for lower-degree // polynomial interpolants -> ... -> profit! template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog_impl_float(const Packet _x) { const Packet cst_1 = pset1(1.0f); const Packet cst_minus_inf = pset1frombits(static_cast(0xff800000u)); const Packet cst_pos_inf = pset1frombits(static_cast(0x7f800000u)); const Packet cst_cephes_SQRTHF = pset1(0.707106781186547524f); Packet e, x; // extract significant in the range [0.5,1) and exponent x = pfrexp(_x, e); // part2: Shift the inputs from the range [0.5,1) to [sqrt(1/2),sqrt(2)) // and shift by -1. The values are then centered around 0, which improves // the stability of the polynomial evaluation. // if( x < SQRTHF ) { // e -= 1; // x = x + x - 1.0; // } else { x = x - 1.0; } Packet mask = pcmp_lt(x, cst_cephes_SQRTHF); Packet tmp = pand(x, mask); x = psub(x, cst_1); e = psub(e, pand(cst_1, mask)); x = padd(x, tmp); // Polynomial coefficients for rational (3,3) r(x) = p(x)/q(x) // approximating log(1+x) on [sqrt(0.5)-1;sqrt(2)-1]. const Packet cst_p1 = pset1(1.0000000190281136f); const Packet cst_p2 = pset1(1.0000000190281063f); const Packet cst_p3 = pset1(0.18256296349849254f); const Packet cst_q1 = pset1(1.4999999999999927f); const Packet cst_q2 = pset1(0.59923249590823520f); const Packet cst_q3 = pset1(0.049616247954120038f); Packet p = pmadd(x, cst_p3, cst_p2); p = pmadd(x, p, cst_p1); p = pmul(x, p); Packet q = pmadd(x, cst_q3, cst_q2); q = pmadd(x, q, cst_q1); q = pmadd(x, q, cst_1); x = pdiv(p, q); // Add the logarithm of the exponent back to the result of the interpolation. if (base2) { const Packet cst_log2e = pset1(static_cast(EIGEN_LOG2E)); x = pmadd(x, cst_log2e, e); } else { const Packet cst_ln2 = pset1(static_cast(EIGEN_LN2)); x = pmadd(e, cst_ln2, x); } Packet invalid_mask = pcmp_lt_or_nan(_x, pzero(_x)); Packet iszero_mask = pcmp_eq(_x, pzero(_x)); Packet pos_inf_mask = pcmp_eq(_x, cst_pos_inf); // Filter out invalid inputs, i.e.: // - negative arg will be NAN // - 0 will be -INF // - +INF will be +INF return pselect(iszero_mask, cst_minus_inf, por(pselect(pos_inf_mask, cst_pos_inf, x), invalid_mask)); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog_float(const Packet _x) { return plog_impl_float(_x); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog2_float(const Packet _x) { return plog_impl_float(_x); } /* Returns the base e (2.718...) or base 2 logarithm of x. * The argument is separated into its exponent and fractional parts. * The logarithm of the fraction in the interval [sqrt(1/2), sqrt(2)], * is approximated by * * log(1+x) = x - 0.5 x**2 + x**3 P(x)/Q(x). * * for more detail see: http://www.netlib.org/cephes/ */ template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog_impl_double(const Packet _x) { Packet x = _x; const Packet cst_1 = pset1(1.0); const Packet cst_neg_half = pset1(-0.5); const Packet cst_minus_inf = pset1frombits(static_cast(0xfff0000000000000ull)); const Packet cst_pos_inf = pset1frombits(static_cast(0x7ff0000000000000ull)); // Polynomial Coefficients for log(1+x) = x - x**2/2 + x**3 P(x)/Q(x) // 1/sqrt(2) <= x < sqrt(2) const Packet cst_cephes_SQRTHF = pset1(0.70710678118654752440E0); const Packet cst_cephes_log_p0 = pset1(1.01875663804580931796E-4); const Packet cst_cephes_log_p1 = pset1(4.97494994976747001425E-1); const Packet cst_cephes_log_p2 = pset1(4.70579119878881725854E0); const Packet cst_cephes_log_p3 = pset1(1.44989225341610930846E1); const Packet cst_cephes_log_p4 = pset1(1.79368678507819816313E1); const Packet cst_cephes_log_p5 = pset1(7.70838733755885391666E0); const Packet cst_cephes_log_q0 = pset1(1.0); const Packet cst_cephes_log_q1 = pset1(1.12873587189167450590E1); const Packet cst_cephes_log_q2 = pset1(4.52279145837532221105E1); const Packet cst_cephes_log_q3 = pset1(8.29875266912776603211E1); const Packet cst_cephes_log_q4 = pset1(7.11544750618563894466E1); const Packet cst_cephes_log_q5 = pset1(2.31251620126765340583E1); Packet e; // extract significant in the range [0.5,1) and exponent x = pfrexp(x, e); // Shift the inputs from the range [0.5,1) to [sqrt(1/2),sqrt(2)) // and shift by -1. The values are then centered around 0, which improves // the stability of the polynomial evaluation. // if( x < SQRTHF ) { // e -= 1; // x = x + x - 1.0; // } else { x = x - 1.0; } Packet mask = pcmp_lt(x, cst_cephes_SQRTHF); Packet tmp = pand(x, mask); x = psub(x, cst_1); e = psub(e, pand(cst_1, mask)); x = padd(x, tmp); Packet x2 = pmul(x, x); Packet x3 = pmul(x2, x); // Evaluate the polynomial approximant , probably to improve instruction-level parallelism. // y = x - 0.5*x^2 + x^3 * polevl( x, P, 5 ) / p1evl( x, Q, 5 ) ); Packet y, y1, y_; y = pmadd(cst_cephes_log_p0, x, cst_cephes_log_p1); y1 = pmadd(cst_cephes_log_p3, x, cst_cephes_log_p4); y = pmadd(y, x, cst_cephes_log_p2); y1 = pmadd(y1, x, cst_cephes_log_p5); y_ = pmadd(y, x3, y1); y = pmadd(cst_cephes_log_q0, x, cst_cephes_log_q1); y1 = pmadd(cst_cephes_log_q3, x, cst_cephes_log_q4); y = pmadd(y, x, cst_cephes_log_q2); y1 = pmadd(y1, x, cst_cephes_log_q5); y = pmadd(y, x3, y1); y_ = pmul(y_, x3); y = pdiv(y_, y); y = pmadd(cst_neg_half, x2, y); x = padd(x, y); // Add the logarithm of the exponent back to the result of the interpolation. if (base2) { const Packet cst_log2e = pset1(static_cast(EIGEN_LOG2E)); x = pmadd(x, cst_log2e, e); } else { const Packet cst_ln2 = pset1(static_cast(EIGEN_LN2)); x = pmadd(e, cst_ln2, x); } Packet invalid_mask = pcmp_lt_or_nan(_x, pzero(_x)); Packet iszero_mask = pcmp_eq(_x, pzero(_x)); Packet pos_inf_mask = pcmp_eq(_x, cst_pos_inf); // Filter out invalid inputs, i.e.: // - negative arg will be NAN // - 0 will be -INF // - +INF will be +INF return pselect(iszero_mask, cst_minus_inf, por(pselect(pos_inf_mask, cst_pos_inf, x), invalid_mask)); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog_double(const Packet _x) { return plog_impl_double(_x); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog2_double(const Packet _x) { return plog_impl_double(_x); } /** \internal \returns log(1 + x) computed using W. Kahan's formula. See: http://www.plunk.org/~hatch/rightway.php */ template Packet generic_plog1p(const Packet& x) { typedef typename unpacket_traits::type ScalarType; const Packet one = pset1(ScalarType(1)); Packet xp1 = padd(x, one); Packet small_mask = pcmp_eq(xp1, one); Packet log1 = plog(xp1); Packet inf_mask = pcmp_eq(xp1, log1); Packet log_large = pmul(x, pdiv(log1, psub(xp1, one))); return pselect(por(small_mask, inf_mask), x, log_large); } /** \internal \returns exp(x)-1 computed using W. Kahan's formula. See: http://www.plunk.org/~hatch/rightway.php */ template Packet generic_expm1(const Packet& x) { typedef typename unpacket_traits::type ScalarType; const Packet one = pset1(ScalarType(1)); const Packet neg_one = pset1(ScalarType(-1)); Packet u = pexp(x); Packet one_mask = pcmp_eq(u, one); Packet u_minus_one = psub(u, one); Packet neg_one_mask = pcmp_eq(u_minus_one, neg_one); Packet logu = plog(u); // The following comparison is to catch the case where // exp(x) = +inf. It is written in this way to avoid having // to form the constant +inf, which depends on the packet // type. Packet pos_inf_mask = pcmp_eq(logu, u); Packet expm1 = pmul(u_minus_one, pdiv(x, logu)); expm1 = pselect(pos_inf_mask, u, expm1); return pselect(one_mask, x, pselect(neg_one_mask, neg_one, expm1)); } // Exponential function. Works by writing "x = m*log(2) + r" where // "m = floor(x/log(2)+1/2)" and "r" is the remainder. The result is then // "exp(x) = 2^m*exp(r)" where exp(r) is in the range [-1,1). // exp(r) is computed using a 6th order minimax polynomial approximation. template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pexp_float(const Packet _x) { const Packet cst_zero = pset1(0.0f); const Packet cst_one = pset1(1.0f); const Packet cst_half = pset1(0.5f); const Packet cst_exp_hi = pset1(88.723f); const Packet cst_exp_lo = pset1(-104.f); const Packet cst_cephes_LOG2EF = pset1(1.44269504088896341f); const Packet cst_p2 = pset1(0.49999988079071044921875f); const Packet cst_p3 = pset1(0.16666518151760101318359375f); const Packet cst_p4 = pset1(4.166965186595916748046875e-2f); const Packet cst_p5 = pset1(8.36894474923610687255859375e-3f); const Packet cst_p6 = pset1(1.37449637986719608306884765625e-3f); // Clamp x. Packet zero_mask = pcmp_lt(_x, cst_exp_lo); Packet x = pmin(_x, cst_exp_hi); // Express exp(x) as exp(m*ln(2) + r), start by extracting // m = floor(x/ln(2) + 0.5). Packet m = pfloor(pmadd(x, cst_cephes_LOG2EF, cst_half)); // Get r = x - m*ln(2). If no FMA instructions are available, m*ln(2) is // subtracted out in two parts, m*C1+m*C2 = m*ln(2), to avoid accumulating // truncation errors. const Packet cst_cephes_exp_C1 = pset1(-0.693359375f); const Packet cst_cephes_exp_C2 = pset1(2.12194440e-4f); Packet r = pmadd(m, cst_cephes_exp_C1, x); r = pmadd(m, cst_cephes_exp_C2, r); // Evaluate the 6th order polynomial approximation to exp(r) // with r in the interval [-ln(2)/2;ln(2)/2]. const Packet r2 = pmul(r, r); Packet p_even = pmadd(r2, cst_p6, cst_p4); const Packet p_odd = pmadd(r2, cst_p5, cst_p3); p_even = pmadd(r2, p_even, cst_p2); const Packet p_low = padd(r, cst_one); Packet y = pmadd(r, p_odd, p_even); y = pmadd(r2, y, p_low); // Return 2^m * exp(r). // TODO: replace pldexp with faster implementation since y in [-1, 1). return pselect(zero_mask, cst_zero, pmax(pldexp(y, m), _x)); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pexp_double(const Packet _x) { Packet x = _x; const Packet cst_zero = pset1(0.0); const Packet cst_1 = pset1(1.0); const Packet cst_2 = pset1(2.0); const Packet cst_half = pset1(0.5); const Packet cst_exp_hi = pset1(709.784); const Packet cst_exp_lo = pset1(-709.784); const Packet cst_cephes_LOG2EF = pset1(1.4426950408889634073599); const Packet cst_cephes_exp_p0 = pset1(1.26177193074810590878e-4); const Packet cst_cephes_exp_p1 = pset1(3.02994407707441961300e-2); const Packet cst_cephes_exp_p2 = pset1(9.99999999999999999910e-1); const Packet cst_cephes_exp_q0 = pset1(3.00198505138664455042e-6); const Packet cst_cephes_exp_q1 = pset1(2.52448340349684104192e-3); const Packet cst_cephes_exp_q2 = pset1(2.27265548208155028766e-1); const Packet cst_cephes_exp_q3 = pset1(2.00000000000000000009e0); const Packet cst_cephes_exp_C1 = pset1(0.693145751953125); const Packet cst_cephes_exp_C2 = pset1(1.42860682030941723212e-6); Packet tmp, fx; // clamp x Packet zero_mask = pcmp_lt(_x, cst_exp_lo); x = pmin(x, cst_exp_hi); // Express exp(x) as exp(g + n*log(2)). fx = pmadd(cst_cephes_LOG2EF, x, cst_half); // Get the integer modulus of log(2), i.e. the "n" described above. fx = pfloor(fx); // Get the remainder modulo log(2), i.e. the "g" described above. Subtract // n*log(2) out in two steps, i.e. n*C1 + n*C2, C1+C2=log2 to get the last // digits right. tmp = pmul(fx, cst_cephes_exp_C1); Packet z = pmul(fx, cst_cephes_exp_C2); x = psub(x, tmp); x = psub(x, z); Packet x2 = pmul(x, x); // Evaluate the numerator polynomial of the rational interpolant. Packet px = cst_cephes_exp_p0; px = pmadd(px, x2, cst_cephes_exp_p1); px = pmadd(px, x2, cst_cephes_exp_p2); px = pmul(px, x); // Evaluate the denominator polynomial of the rational interpolant. Packet qx = cst_cephes_exp_q0; qx = pmadd(qx, x2, cst_cephes_exp_q1); qx = pmadd(qx, x2, cst_cephes_exp_q2); qx = pmadd(qx, x2, cst_cephes_exp_q3); // I don't really get this bit, copied from the SSE2 routines, so... // TODO(gonnet): Figure out what is going on here, perhaps find a better // rational interpolant? x = pdiv(px, psub(qx, px)); x = pmadd(cst_2, x, cst_1); // Construct the result 2^n * exp(g) = e * x. The max is used to catch // non-finite values in the input. // TODO: replace pldexp with faster implementation since x in [-1, 1). return pselect(zero_mask, cst_zero, pmax(pldexp(x, fx), _x)); } // The following code is inspired by the following stack-overflow answer: // https://stackoverflow.com/questions/30463616/payne-hanek-algorithm-implementation-in-c/30465751#30465751 // It has been largely optimized: // - By-pass calls to frexp. // - Aligned loads of required 96 bits of 2/pi. This is accomplished by // (1) balancing the mantissa and exponent to the required bits of 2/pi are // aligned on 8-bits, and (2) replicating the storage of the bits of 2/pi. // - Avoid a branch in rounding and extraction of the remaining fractional part. // Overall, I measured a speed up higher than x2 on x86-64. inline float trig_reduce_huge(float xf, Eigen::numext::int32_t* quadrant) { using Eigen::numext::int32_t; using Eigen::numext::int64_t; using Eigen::numext::uint32_t; using Eigen::numext::uint64_t; const double pio2_62 = 3.4061215800865545e-19; // pi/2 * 2^-62 const uint64_t zero_dot_five = uint64_t(1) << 61; // 0.5 in 2.62-bit fixed-point format // 192 bits of 2/pi for Payne-Hanek reduction // Bits are introduced by packet of 8 to enable aligned reads. static const uint32_t two_over_pi[] = { 0x00000028, 0x000028be, 0x0028be60, 0x28be60db, 0xbe60db93, 0x60db9391, 0xdb939105, 0x9391054a, 0x91054a7f, 0x054a7f09, 0x4a7f09d5, 0x7f09d5f4, 0x09d5f47d, 0xd5f47d4d, 0xf47d4d37, 0x7d4d3770, 0x4d377036, 0x377036d8, 0x7036d8a5, 0x36d8a566, 0xd8a5664f, 0xa5664f10, 0x664f10e4, 0x4f10e410, 0x10e41000, 0xe4100000}; uint32_t xi = numext::bit_cast(xf); // Below, -118 = -126 + 8. // -126 is to get the exponent, // +8 is to enable alignment of 2/pi's bits on 8 bits. // This is possible because the fractional part of x as only 24 meaningful bits. uint32_t e = (xi >> 23) - 118; // Extract the mantissa and shift it to align it wrt the exponent xi = ((xi & 0x007fffffu) | 0x00800000u) << (e & 0x7); uint32_t i = e >> 3; uint32_t twoopi_1 = two_over_pi[i - 1]; uint32_t twoopi_2 = two_over_pi[i + 3]; uint32_t twoopi_3 = two_over_pi[i + 7]; // Compute x * 2/pi in 2.62-bit fixed-point format. uint64_t p; p = uint64_t(xi) * twoopi_3; p = uint64_t(xi) * twoopi_2 + (p >> 32); p = (uint64_t(xi * twoopi_1) << 32) + p; // Round to nearest: add 0.5 and extract integral part. uint64_t q = (p + zero_dot_five) >> 62; *quadrant = int(q); // Now it remains to compute "r = x - q*pi/2" with high accuracy, // since we have p=x/(pi/2) with high accuracy, we can more efficiently compute r as: // r = (p-q)*pi/2, // where the product can be be carried out with sufficient accuracy using double precision. p -= q << 62; return float(double(int64_t(p)) * pio2_62); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS #if EIGEN_COMP_GNUC_STRICT __attribute__((optimize("-fno-unsafe-math-optimizations"))) #endif Packet psincos_float(const Packet& _x) { typedef typename unpacket_traits::integer_packet PacketI; const Packet cst_2oPI = pset1(0.636619746685028076171875f); // 2/PI const Packet cst_rounding_magic = pset1(12582912); // 2^23 for rounding const PacketI csti_1 = pset1(1); const Packet cst_sign_mask = pset1frombits(static_cast(0x80000000u)); Packet x = pabs(_x); // Scale x by 2/Pi to find x's octant. Packet y = pmul(x, cst_2oPI); // Rounding trick to find nearest integer: Packet y_round = padd(y, cst_rounding_magic); EIGEN_OPTIMIZATION_BARRIER(y_round) PacketI y_int = preinterpret(y_round); // last 23 digits represent integer (if abs(x)<2^24) y = psub(y_round, cst_rounding_magic); // nearest integer to x * (2/pi) // Subtract y * Pi/2 to reduce x to the interval -Pi/4 <= x <= +Pi/4 // using "Extended precision modular arithmetic" #if defined(EIGEN_VECTORIZE_FMA) // This version requires true FMA for high accuracy. // It provides a max error of 1ULP up to (with absolute_error < 5.9605e-08): const float huge_th = ComputeSine ? 117435.992f : 71476.0625f; x = pmadd(y, pset1(-1.57079601287841796875f), x); x = pmadd(y, pset1(-3.1391647326017846353352069854736328125e-07f), x); x = pmadd(y, pset1(-5.390302529957764765544681040410068817436695098876953125e-15f), x); #else // Without true FMA, the previous set of coefficients maintain 1ULP accuracy // up to x<15.7 (for sin), but accuracy is immediately lost for x>15.7. // We thus use one more iteration to maintain 2ULPs up to reasonably large inputs. // The following set of coefficients maintain 1ULP up to 9.43 and 14.16 for sin and cos respectively. // and 2 ULP up to: const float huge_th = ComputeSine ? 25966.f : 18838.f; x = pmadd(y, pset1(-1.5703125), x); // = 0xbfc90000 EIGEN_OPTIMIZATION_BARRIER(x) x = pmadd(y, pset1(-0.000483989715576171875), x); // = 0xb9fdc000 EIGEN_OPTIMIZATION_BARRIER(x) x = pmadd(y, pset1(1.62865035235881805419921875e-07), x); // = 0x342ee000 x = pmadd(y, pset1(5.5644315544167710640977020375430583953857421875e-11), x); // = 0x2e74b9ee // For the record, the following set of coefficients maintain 2ULP up // to a slightly larger range: // const float huge_th = ComputeSine ? 51981.f : 39086.125f; // but it slightly fails to maintain 1ULP for two values of sin below pi. // x = pmadd(y, pset1(-3.140625/2.), x); // x = pmadd(y, pset1(-0.00048351287841796875), x); // x = pmadd(y, pset1(-3.13855707645416259765625e-07), x); // x = pmadd(y, pset1(-6.0771006282767103812147979624569416046142578125e-11), x); // For the record, with only 3 iterations it is possible to maintain // 1 ULP up to 3PI (maybe more) and 2ULP up to 255. // The coefficients are: 0xbfc90f80, 0xb7354480, 0x2e74b9ee #endif if (predux_any(pcmp_le(pset1(huge_th), pabs(_x)))) { const int PacketSize = unpacket_traits::size; EIGEN_ALIGN_TO_BOUNDARY(sizeof(Packet)) float vals[PacketSize]; EIGEN_ALIGN_TO_BOUNDARY(sizeof(Packet)) float x_cpy[PacketSize]; EIGEN_ALIGN_TO_BOUNDARY(sizeof(Packet)) Eigen::numext::int32_t y_int2[PacketSize]; pstoreu(vals, pabs(_x)); pstoreu(x_cpy, x); pstoreu(y_int2, y_int); for (int k = 0; k < PacketSize; ++k) { float val = vals[k]; if (val >= huge_th && (numext::isfinite)(val)) x_cpy[k] = trig_reduce_huge(val, &y_int2[k]); } x = ploadu(x_cpy); y_int = ploadu(y_int2); } // Compute the sign to apply to the polynomial. // sin: sign = second_bit(y_int) xor signbit(_x) // cos: sign = second_bit(y_int+1) Packet sign_bit = ComputeSine ? pxor(_x, preinterpret(plogical_shift_left<30>(y_int))) : preinterpret(plogical_shift_left<30>(padd(y_int, csti_1))); sign_bit = pand(sign_bit, cst_sign_mask); // clear all but left most bit // Get the polynomial selection mask from the second bit of y_int // We'll calculate both (sin and cos) polynomials and then select from the two. Packet poly_mask = preinterpret(pcmp_eq(pand(y_int, csti_1), pzero(y_int))); Packet x2 = pmul(x, x); // Evaluate the cos(x) polynomial. (-Pi/4 <= x <= Pi/4) Packet y1 = pset1(2.4372266125283204019069671630859375e-05f); y1 = pmadd(y1, x2, pset1(-0.00138865201734006404876708984375f)); y1 = pmadd(y1, x2, pset1(0.041666619479656219482421875f)); y1 = pmadd(y1, x2, pset1(-0.5f)); y1 = pmadd(y1, x2, pset1(1.f)); // Evaluate the sin(x) polynomial. (Pi/4 <= x <= Pi/4) // octave/matlab code to compute those coefficients: // x = (0:0.0001:pi/4)'; // A = [x.^3 x.^5 x.^7]; // w = ((1.-(x/(pi/4)).^2).^5)*2000+1; # weights trading relative accuracy // c = (A'*diag(w)*A)\(A'*diag(w)*(sin(x)-x)); # weighted LS, linear coeff forced to 1 // printf('%.64f\n %.64f\n%.64f\n', c(3), c(2), c(1)) // Packet y2 = pset1(-0.0001959234114083702898469196984621021329076029360294342041015625f); y2 = pmadd(y2, x2, pset1(0.0083326873655616851693794799871284340042620897293090820312500000f)); y2 = pmadd(y2, x2, pset1(-0.1666666203982298255503735617821803316473960876464843750000000000f)); y2 = pmul(y2, x2); y2 = pmadd(y2, x, x); // Select the correct result from the two polynomials. if (ComputeBoth) { Packet peven = peven_mask(x); Packet ysin = pselect(poly_mask, y2, y1); Packet ycos = pselect(poly_mask, y1, y2); Packet sign_bit_sin = pxor(_x, preinterpret(plogical_shift_left<30>(y_int))); Packet sign_bit_cos = preinterpret(plogical_shift_left<30>(padd(y_int, csti_1))); sign_bit_sin = pand(sign_bit_sin, cst_sign_mask); // clear all but left most bit sign_bit_cos = pand(sign_bit_cos, cst_sign_mask); // clear all but left most bit y = pselect(peven, pxor(ysin, sign_bit_sin), pxor(ycos, sign_bit_cos)); } else { y = ComputeSine ? pselect(poly_mask, y2, y1) : pselect(poly_mask, y1, y2); y = pxor(y, sign_bit); } // Update the sign and filter huge inputs return y; } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet psin_float(const Packet& x) { return psincos_float(x); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pcos_float(const Packet& x) { return psincos_float(x); } // Generic implementation of acos(x). template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pacos_float(const Packet& x_in) { typedef typename unpacket_traits::type Scalar; static_assert(std::is_same::value, "Scalar type must be float"); const Packet cst_one = pset1(Scalar(1)); const Packet cst_pi = pset1(Scalar(EIGEN_PI)); const Packet p6 = pset1(Scalar(2.36423197202384471893310546875e-3)); const Packet p5 = pset1(Scalar(-1.1368644423782825469970703125e-2)); const Packet p4 = pset1(Scalar(2.717843465507030487060546875e-2)); const Packet p3 = pset1(Scalar(-4.8969544470310211181640625e-2)); const Packet p2 = pset1(Scalar(8.8804088532924652099609375e-2)); const Packet p1 = pset1(Scalar(-0.214591205120086669921875)); const Packet p0 = pset1(Scalar(1.57079637050628662109375)); // For x in [0:1], we approximate acos(x)/sqrt(1-x), which is a smooth // function, by a 6'th order polynomial. // For x in [-1:0) we use that acos(-x) = pi - acos(x). const Packet neg_mask = psignbit(x_in); const Packet abs_x = pabs(x_in); // Evaluate the polynomial using Horner's rule: // P(x) = p0 + x * (p1 + x * (p2 + ... (p5 + x * p6)) ... ) . // We evaluate even and odd terms independently to increase // instruction level parallelism. Packet x2 = pmul(x_in, x_in); Packet p_even = pmadd(p6, x2, p4); Packet p_odd = pmadd(p5, x2, p3); p_even = pmadd(p_even, x2, p2); p_odd = pmadd(p_odd, x2, p1); p_even = pmadd(p_even, x2, p0); Packet p = pmadd(p_odd, abs_x, p_even); // The polynomial approximates acos(x)/sqrt(1-x), so // multiply by sqrt(1-x) to get acos(x). // Conveniently returns NaN for arguments outside [-1:1]. Packet denom = psqrt(psub(cst_one, abs_x)); Packet result = pmul(denom, p); // Undo mapping for negative arguments. return pselect(neg_mask, psub(cst_pi, result), result); } // Generic implementation of asin(x). template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pasin_float(const Packet& x_in) { typedef typename unpacket_traits::type Scalar; static_assert(std::is_same::value, "Scalar type must be float"); constexpr float kPiOverTwo = static_cast(EIGEN_PI / 2); const Packet cst_half = pset1(0.5f); const Packet cst_one = pset1(1.0f); const Packet cst_two = pset1(2.0f); const Packet cst_pi_over_two = pset1(kPiOverTwo); // For |x| < 0.5 approximate asin(x)/x by an 8th order polynomial with // even terms only. const Packet p9 = pset1(5.08838854730129241943359375e-2f); const Packet p7 = pset1(3.95139865577220916748046875e-2f); const Packet p5 = pset1(7.550220191478729248046875e-2f); const Packet p3 = pset1(0.16664917767047882080078125f); const Packet p1 = pset1(1.00000011920928955078125f); const Packet abs_x = pabs(x_in); const Packet sign_mask = pandnot(x_in, abs_x); const Packet invalid_mask = pcmp_lt(cst_one, abs_x); // For arguments |x| > 0.5, we map x back to [0:0.5] using // the transformation x_large = sqrt(0.5*(1-x)), and use the // identity // asin(x) = pi/2 - 2 * asin( sqrt( 0.5 * (1 - x))) const Packet x_large = psqrt(pnmadd(cst_half, abs_x, cst_half)); const Packet large_mask = pcmp_lt(cst_half, abs_x); const Packet x = pselect(large_mask, x_large, abs_x); const Packet x2 = pmul(x, x); // Compute polynomial. // x * (p1 + x^2*(p3 + x^2*(p5 + x^2*(p7 + x^2*p9)))) Packet p = pmadd(p9, x2, p7); p = pmadd(p, x2, p5); p = pmadd(p, x2, p3); p = pmadd(p, x2, p1); p = pmul(p, x); const Packet p_large = pnmadd(cst_two, p, cst_pi_over_two); p = pselect(large_mask, p_large, p); // Flip the sign for negative arguments. p = pxor(p, sign_mask); // Return NaN for arguments outside [-1:1]. return por(invalid_mask, p); } // Computes elementwise atan(x) for x in [-1:1] with 2 ulp accuracy. template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet patan_reduced_float(const Packet& x) { const Packet q0 = pset1(-0.3333314359188079833984375f); const Packet q2 = pset1(0.19993579387664794921875f); const Packet q4 = pset1(-0.14209578931331634521484375f); const Packet q6 = pset1(0.1066047251224517822265625f); const Packet q8 = pset1(-7.5408883392810821533203125e-2f); const Packet q10 = pset1(4.3082617223262786865234375e-2f); const Packet q12 = pset1(-1.62907354533672332763671875e-2f); const Packet q14 = pset1(2.90188402868807315826416015625e-3f); // Approximate atan(x) by a polynomial of the form // P(x) = x + x^3 * Q(x^2), // where Q(x^2) is a 7th order polynomial in x^2. // We evaluate even and odd terms in x^2 in parallel // to take advantage of instruction level parallelism // and hardware with multiple FMA units. // note: if x == -0, this returns +0 const Packet x2 = pmul(x, x); const Packet x4 = pmul(x2, x2); Packet q_odd = pmadd(q14, x4, q10); Packet q_even = pmadd(q12, x4, q8); q_odd = pmadd(q_odd, x4, q6); q_even = pmadd(q_even, x4, q4); q_odd = pmadd(q_odd, x4, q2); q_even = pmadd(q_even, x4, q0); const Packet q = pmadd(q_odd, x2, q_even); return pmadd(q, pmul(x, x2), x); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet patan_float(const Packet& x_in) { typedef typename unpacket_traits::type Scalar; static_assert(std::is_same::value, "Scalar type must be float"); constexpr float kPiOverTwo = static_cast(EIGEN_PI / 2); const Packet cst_signmask = pset1(-0.0f); const Packet cst_one = pset1(1.0f); const Packet cst_pi_over_two = pset1(kPiOverTwo); // "Large": For |x| > 1, use atan(1/x) = sign(x)*pi/2 - atan(x). // "Small": For |x| <= 1, approximate atan(x) directly by a polynomial // calculated using Sollya. const Packet abs_x = pabs(x_in); const Packet x_signmask = pand(x_in, cst_signmask); const Packet large_mask = pcmp_lt(cst_one, abs_x); const Packet x = pselect(large_mask, preciprocal(abs_x), abs_x); const Packet p = patan_reduced_float(x); // Apply transformations according to the range reduction masks. Packet result = pselect(large_mask, psub(cst_pi_over_two, p), p); // Return correct sign return pxor(result, x_signmask); } // Computes elementwise atan(x) for x in [-tan(pi/8):tan(pi/8)] // with 2 ulp accuracy. template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet patan_reduced_double(const Packet& x) { const Packet q0 = pset1(-0.33333333333330028569463365784031338989734649658203); const Packet q2 = pset1(0.199999999990664090177006073645316064357757568359375); const Packet q4 = pset1(-0.142857141937123677255527809393242932856082916259766); const Packet q6 = pset1(0.111111065991039953404495577160560060292482376098633); const Packet q8 = pset1(-9.0907812986129224452902519715280504897236824035645e-2); const Packet q10 = pset1(7.6900542950704739442180368769186316058039665222168e-2); const Packet q12 = pset1(-6.6410112986494976294871150912513257935643196105957e-2); const Packet q14 = pset1(5.6920144995467943094258345126945641823112964630127e-2); const Packet q16 = pset1(-4.3577020814990513608577771265117917209863662719727e-2); const Packet q18 = pset1(2.1244050233624342527427586446719942614436149597168e-2); // Approximate atan(x) on [0:tan(pi/8)] by a polynomial of the form // P(x) = x + x^3 * Q(x^2), // where Q(x^2) is a 9th order polynomial in x^2. // We evaluate even and odd terms in x^2 in parallel // to take advantage of instruction level parallelism // and hardware with multiple FMA units. const Packet x2 = pmul(x, x); const Packet x4 = pmul(x2, x2); Packet q_odd = pmadd(q18, x4, q14); Packet q_even = pmadd(q16, x4, q12); q_odd = pmadd(q_odd, x4, q10); q_even = pmadd(q_even, x4, q8); q_odd = pmadd(q_odd, x4, q6); q_even = pmadd(q_even, x4, q4); q_odd = pmadd(q_odd, x4, q2); q_even = pmadd(q_even, x4, q0); const Packet p = pmadd(q_odd, x2, q_even); return pmadd(p, pmul(x, x2), x); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet patan_double(const Packet& x_in) { typedef typename unpacket_traits::type Scalar; static_assert(std::is_same::value, "Scalar type must be double"); constexpr double kPiOverTwo = static_cast(EIGEN_PI / 2); constexpr double kPiOverFour = static_cast(EIGEN_PI / 4); constexpr double kTanPiOverEight = 0.4142135623730950488016887; constexpr double kTan3PiOverEight = 2.4142135623730950488016887; const Packet cst_signmask = pset1(-0.0); const Packet cst_one = pset1(1.0); const Packet cst_pi_over_two = pset1(kPiOverTwo); const Packet cst_pi_over_four = pset1(kPiOverFour); const Packet cst_large = pset1(kTan3PiOverEight); const Packet cst_medium = pset1(kTanPiOverEight); // Use the same range reduction strategy (to [0:tan(pi/8)]) as the // Cephes library: // "Large": For x >= tan(3*pi/8), use atan(1/x) = pi/2 - atan(x). // "Medium": For x in [tan(pi/8) : tan(3*pi/8)), // use atan(x) = pi/4 + atan((x-1)/(x+1)). // "Small": For x < tan(pi/8), approximate atan(x) directly by a polynomial // calculated using Sollya. const Packet abs_x = pabs(x_in); const Packet x_signmask = pand(x_in, cst_signmask); const Packet large_mask = pcmp_lt(cst_large, abs_x); const Packet medium_mask = pandnot(pcmp_lt(cst_medium, abs_x), large_mask); Packet x = abs_x; x = pselect(large_mask, preciprocal(abs_x), x); x = pselect(medium_mask, pdiv(psub(abs_x, cst_one), padd(abs_x, cst_one)), x); // Compute approximation of p ~= atan(x') where x' is the argument reduced to // [0:tan(pi/8)]. Packet p = patan_reduced_double(x); // Apply transformations according to the range reduction masks. p = pselect(large_mask, psub(cst_pi_over_two, p), p); p = pselect(medium_mask, padd(cst_pi_over_four, p), p); // Return the correct sign return pxor(p, x_signmask); } /** \internal \returns the hyperbolic tan of \a a (coeff-wise) Doesn't do anything fancy, just a 13/6-degree rational interpolant which is accurate up to a couple of ulps in the (approximate) range [-8, 8], outside of which tanh(x) = +/-1 in single precision. The input is clamped to the range [-c, c]. The value c is chosen as the smallest value where the approximation evaluates to exactly 1. In the reange [-0.0004, 0.0004] the approximation tanh(x) ~= x is used for better accuracy as x tends to zero. This implementation works on both scalars and packets. */ template T ptanh_float(const T& a_x) { // Clamp the inputs to the range [-c, c] #ifdef EIGEN_VECTORIZE_FMA const T plus_clamp = pset1(7.99881172180175781f); const T minus_clamp = pset1(-7.99881172180175781f); #else const T plus_clamp = pset1(7.90531110763549805f); const T minus_clamp = pset1(-7.90531110763549805f); #endif const T tiny = pset1(0.0004f); const T x = pmax(pmin(a_x, plus_clamp), minus_clamp); const T tiny_mask = pcmp_lt(pabs(a_x), tiny); // The monomial coefficients of the numerator polynomial (odd). const T alpha_1 = pset1(4.89352455891786e-03f); const T alpha_3 = pset1(6.37261928875436e-04f); const T alpha_5 = pset1(1.48572235717979e-05f); const T alpha_7 = pset1(5.12229709037114e-08f); const T alpha_9 = pset1(-8.60467152213735e-11f); const T alpha_11 = pset1(2.00018790482477e-13f); const T alpha_13 = pset1(-2.76076847742355e-16f); // The monomial coefficients of the denominator polynomial (even). const T beta_0 = pset1(4.89352518554385e-03f); const T beta_2 = pset1(2.26843463243900e-03f); const T beta_4 = pset1(1.18534705686654e-04f); const T beta_6 = pset1(1.19825839466702e-06f); // Since the polynomials are odd/even, we need x^2. const T x2 = pmul(x, x); // Evaluate the numerator polynomial p. T p = pmadd(x2, alpha_13, alpha_11); p = pmadd(x2, p, alpha_9); p = pmadd(x2, p, alpha_7); p = pmadd(x2, p, alpha_5); p = pmadd(x2, p, alpha_3); p = pmadd(x2, p, alpha_1); p = pmul(x, p); // Evaluate the denominator polynomial q. T q = pmadd(x2, beta_6, beta_4); q = pmadd(x2, q, beta_2); q = pmadd(x2, q, beta_0); // Divide the numerator by the denominator. return pselect(tiny_mask, x, pdiv(p, q)); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet patanh_float(const Packet& x) { typedef typename unpacket_traits::type Scalar; static_assert(std::is_same::value, "Scalar type must be float"); const Packet half = pset1(0.5f); const Packet x_gt_half = pcmp_le(half, pabs(x)); // For |x| in [0:0.5] we use a polynomial approximation of the form // P(x) = x + x^3*(c3 + x^2 * (c5 + x^2 * (... x^2 * c11) ... )). const Packet C3 = pset1(0.3333373963832855224609375f); const Packet C5 = pset1(0.1997792422771453857421875f); const Packet C7 = pset1(0.14672131836414337158203125f); const Packet C9 = pset1(8.2311116158962249755859375e-2f); const Packet C11 = pset1(0.1819281280040740966796875f); const Packet x2 = pmul(x, x); Packet p = pmadd(C11, x2, C9); p = pmadd(x2, p, C7); p = pmadd(x2, p, C5); p = pmadd(x2, p, C3); p = pmadd(pmul(x, x2), p, x); // For |x| in ]0.5:1.0] we use atanh = 0.5*ln((1+x)/(1-x)); const Packet one = pset1(1.0f); Packet r = pdiv(padd(one, x), psub(one, x)); r = pmul(half, plog(r)); return pselect(x_gt_half, r, p); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pdiv_complex(const Packet& x, const Packet& y) { typedef typename unpacket_traits::as_real RealPacket; // In the following we annotate the code for the case where the inputs // are a pair length-2 SIMD vectors representing a single pair of complex // numbers x = a + i*b, y = c + i*d. const RealPacket y_abs = pabs(y.v); // |c|, |d| const RealPacket y_abs_flip = pcplxflip(Packet(y_abs)).v; // |d|, |c| const RealPacket y_max = pmax(y_abs, y_abs_flip); // max(|c|, |d|), max(|c|, |d|) const RealPacket y_scaled = pdiv(y.v, y_max); // c / max(|c|, |d|), d / max(|c|, |d|) // Compute scaled denominator. const RealPacket y_scaled_sq = pmul(y_scaled, y_scaled); // c'**2, d'**2 const RealPacket denom = padd(y_scaled_sq, pcplxflip(Packet(y_scaled_sq)).v); Packet result_scaled = pmul(x, pconj(Packet(y_scaled))); // a * c' + b * d', -a * d + b * c // Divide elementwise by denom. result_scaled = Packet(pdiv(result_scaled.v, denom)); // Rescale result return Packet(pdiv(result_scaled.v, y_max)); } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet plog_complex(const Packet& x) { typedef typename unpacket_traits::type Scalar; typedef typename Scalar::value_type RealScalar; typedef typename unpacket_traits::as_real RealPacket; RealPacket real_mask_rp = peven_mask(x.v); Packet real_mask(real_mask_rp); // Real part RealPacket x_flip = pcplxflip(x).v; // b, a Packet x_norm = phypot_complex(x); // sqrt(a^2 + b^2), sqrt(a^2 + b^2) RealPacket xlogr = plog(x_norm.v); // log(sqrt(a^2 + b^2)), log(sqrt(a^2 + b^2)) // Imag part RealPacket ximg = patan2(x.v, x_flip); // atan2(a, b), atan2(b, a) const RealPacket cst_pos_inf = pset1(NumTraits::infinity()); RealPacket x_abs = pabs(x.v); RealPacket is_x_pos_inf = pcmp_eq(x_abs, cst_pos_inf); RealPacket is_y_pos_inf = pcplxflip(Packet(is_x_pos_inf)).v; RealPacket is_any_inf = por(is_x_pos_inf, is_y_pos_inf); RealPacket xreal = pselect(is_any_inf, cst_pos_inf, xlogr); Packet xres = pselect(real_mask, Packet(xreal), Packet(ximg)); // log(sqrt(a^2 + b^2)), atan2(b, a) return xres; } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet pexp_complex(const Packet& a) { typedef typename unpacket_traits::as_real RealPacket; typedef typename unpacket_traits::type Scalar; typedef typename Scalar::value_type RealScalar; const RealPacket even_mask = peven_mask(a.v); const Packet even_maskp = Packet(even_mask); const RealPacket odd_mask = pcplxflip(Packet(even_mask)).v; Packet p0y = Packet(pand(odd_mask, a.v)); Packet py0 = pcplxflip(p0y); Packet pyy = padd(p0y, py0); RealPacket sincos = psincos_float(pyy.v); RealPacket cossin = pcplxflip(Packet(sincos)).v; const RealPacket cst_pos_inf = pset1(NumTraits::infinity()); const RealPacket cst_neg_inf = pset1(-NumTraits::infinity()); Packet x_is_inf = Packet(pcmp_eq(a.v, cst_pos_inf)); Packet x_is_minf = Packet(pcmp_eq(a.v, cst_neg_inf)); Packet x_is_zero = Packet(pcmp_eq(pzero(a).v, a.v)); Packet x_real_is_inf = pand(even_maskp, x_is_inf); Packet x_real_is_minf = pand(even_maskp, x_is_minf); Packet inf0 = pset1(Scalar(NumTraits::infinity(), RealScalar(0))); Packet x_is_inf0 = pand(x_real_is_inf, pcplxflip(x_is_zero)); x_is_inf0 = por(x_is_inf0, pcplxflip(x_is_inf0)); Packet x_imag_goes_zero = pand(por(x_is_minf, x_is_inf), pcplxflip(x_real_is_minf)); Packet x_is_nan = Packet(pisnan(a.v)); Packet x_real_goes_zero = pand(x_is_nan, pcplxflip(x_real_is_minf)); RealPacket pexp_real = pexp(a.v); Packet pexp_half = Packet(pand(even_mask, pexp_real)); RealPacket xexp_flip_rp = pcplxflip(pexp_half).v; RealPacket xexp = padd(pexp_half.v, xexp_flip_rp); Packet result(pmul(cossin, xexp)); result = pselect(x_is_inf0, inf0, result); result = pselect(x_real_is_minf, pzero(a), result); result = pselect(x_imag_goes_zero, pzero(a), result); result = pselect(x_real_goes_zero, pzero(a), result); return result; } template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet psqrt_complex(const Packet& a) { typedef typename unpacket_traits::type Scalar; typedef typename Scalar::value_type RealScalar; typedef typename unpacket_traits::as_real RealPacket; // Computes the principal sqrt of the complex numbers in the input. // // For example, for packets containing 2 complex numbers stored in interleaved format // a = [a0, a1] = [x0, y0, x1, y1], // where x0 = real(a0), y0 = imag(a0) etc., this function returns // b = [b0, b1] = [u0, v0, u1, v1], // such that b0^2 = a0, b1^2 = a1. // // To derive the formula for the complex square roots, let's consider the equation for // a single complex square root of the number x + i*y. We want to find real numbers // u and v such that // (u + i*v)^2 = x + i*y <=> // u^2 - v^2 + i*2*u*v = x + i*v. // By equating the real and imaginary parts we get: // u^2 - v^2 = x // 2*u*v = y. // // For x >= 0, this has the numerically stable solution // u = sqrt(0.5 * (x + sqrt(x^2 + y^2))) // v = 0.5 * (y / u) // and for x < 0, // v = sign(y) * sqrt(0.5 * (-x + sqrt(x^2 + y^2))) // u = 0.5 * (y / v) // // To avoid unnecessary over- and underflow, we compute sqrt(x^2 + y^2) as // l = max(|x|, |y|) * sqrt(1 + (min(|x|, |y|) / max(|x|, |y|))^2) , // In the following, without lack of generality, we have annotated the code, assuming // that the input is a packet of 2 complex numbers. // // Step 1. Compute l = [l0, l0, l1, l1], where // l0 = sqrt(x0^2 + y0^2), l1 = sqrt(x1^2 + y1^2) // To avoid over- and underflow, we use the stable formula for each hypotenuse // l0 = (min0 == 0 ? max0 : max0 * sqrt(1 + (min0/max0)**2)), // where max0 = max(|x0|, |y0|), min0 = min(|x0|, |y0|), and similarly for l1. RealPacket a_abs = pabs(a.v); // [|x0|, |y0|, |x1|, |y1|] RealPacket a_abs_flip = pcplxflip(Packet(a_abs)).v; // [|y0|, |x0|, |y1|, |x1|] RealPacket a_max = pmax(a_abs, a_abs_flip); RealPacket a_min = pmin(a_abs, a_abs_flip); RealPacket a_min_zero_mask = pcmp_eq(a_min, pzero(a_min)); RealPacket a_max_zero_mask = pcmp_eq(a_max, pzero(a_max)); RealPacket r = pdiv(a_min, a_max); const RealPacket cst_one = pset1(RealScalar(1)); RealPacket l = pmul(a_max, psqrt(padd(cst_one, pmul(r, r)))); // [l0, l0, l1, l1] // Set l to a_max if a_min is zero. l = pselect(a_min_zero_mask, a_max, l); // Step 2. Compute [rho0, *, rho1, *], where // rho0 = sqrt(0.5 * (l0 + |x0|)), rho1 = sqrt(0.5 * (l1 + |x1|)) // We don't care about the imaginary parts computed here. They will be overwritten later. const RealPacket cst_half = pset1(RealScalar(0.5)); Packet rho; rho.v = psqrt(pmul(cst_half, padd(a_abs, l))); // Step 3. Compute [rho0, eta0, rho1, eta1], where // eta0 = (y0 / l0) / 2, and eta1 = (y1 / l1) / 2. // set eta = 0 of input is 0 + i0. RealPacket eta = pandnot(pmul(cst_half, pdiv(a.v, pcplxflip(rho).v)), a_max_zero_mask); RealPacket real_mask = peven_mask(a.v); Packet positive_real_result; // Compute result for inputs with positive real part. positive_real_result.v = pselect(real_mask, rho.v, eta); // Step 4. Compute solution for inputs with negative real part: // [|eta0|, sign(y0)*rho0, |eta1|, sign(y1)*rho1] const RealPacket cst_imag_sign_mask = pset1(Scalar(RealScalar(0.0), RealScalar(-0.0))).v; RealPacket imag_signs = pand(a.v, cst_imag_sign_mask); Packet negative_real_result; // Notice that rho is positive, so taking it's absolute value is a noop. negative_real_result.v = por(pabs(pcplxflip(positive_real_result).v), imag_signs); // Step 5. Select solution branch based on the sign of the real parts. Packet negative_real_mask; negative_real_mask.v = pcmp_lt(pand(real_mask, a.v), pzero(a.v)); negative_real_mask.v = por(negative_real_mask.v, pcplxflip(negative_real_mask).v); Packet result = pselect(negative_real_mask, negative_real_result, positive_real_result); // Step 6. Handle special cases for infinities: // * If z is (x,+∞), the result is (+∞,+∞) even if x is NaN // * If z is (x,-∞), the result is (+∞,-∞) even if x is NaN // * If z is (-∞,y), the result is (0*|y|,+∞) for finite or NaN y // * If z is (+∞,y), the result is (+∞,0*|y|) for finite or NaN y const RealPacket cst_pos_inf = pset1(NumTraits::infinity()); Packet is_inf; is_inf.v = pcmp_eq(a_abs, cst_pos_inf); Packet is_real_inf; is_real_inf.v = pand(is_inf.v, real_mask); is_real_inf = por(is_real_inf, pcplxflip(is_real_inf)); // prepare packet of (+∞,0*|y|) or (0*|y|,+∞), depending on the sign of the infinite real part. Packet real_inf_result; real_inf_result.v = pmul(a_abs, pset1(Scalar(RealScalar(1.0), RealScalar(0.0))).v); real_inf_result.v = pselect(negative_real_mask.v, pcplxflip(real_inf_result).v, real_inf_result.v); // prepare packet of (+∞,+∞) or (+∞,-∞), depending on the sign of the infinite imaginary part. Packet is_imag_inf; is_imag_inf.v = pandnot(is_inf.v, real_mask); is_imag_inf = por(is_imag_inf, pcplxflip(is_imag_inf)); Packet imag_inf_result; imag_inf_result.v = por(pand(cst_pos_inf, real_mask), pandnot(a.v, real_mask)); // unless otherwise specified, if either the real or imaginary component is nan, the entire result is nan Packet result_is_nan = pisnan(result); result = por(result_is_nan, result); return pselect(is_imag_inf, imag_inf_result, pselect(is_real_inf, real_inf_result, result)); } // \internal \returns the norm of a complex number z = x + i*y, defined as sqrt(x^2 + y^2). // Implemented using the hypot(a,b) algorithm from https://doi.org/10.48550/arXiv.1904.09481 template EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS Packet phypot_complex(const Packet& a) { typedef typename unpacket_traits::type Scalar; typedef typename Scalar::value_type RealScalar; typedef typename unpacket_traits::as_real RealPacket; const RealPacket cst_zero_rp = pset1(static_cast(0.0)); const RealPacket cst_minus_one_rp = pset1(static_cast(-1.0)); const RealPacket cst_two_rp = pset1(static_cast(2.0)); const RealPacket evenmask = peven_mask(a.v); RealPacket a_abs = pabs(a.v); RealPacket a_flip = pcplxflip(Packet(a_abs)).v; // |b|, |a| RealPacket a_all = pselect(evenmask, a_abs, a_flip); // |a|, |a| RealPacket b_all = pselect(evenmask, a_flip, a_abs); // |b|, |b| RealPacket a2 = pmul(a.v, a.v); // |a^2, b^2| RealPacket a2_flip = pcplxflip(Packet(a2)).v; // |b^2, a^2| RealPacket h = psqrt(padd(a2, a2_flip)); // |sqrt(a^2 + b^2), sqrt(a^2 + b^2)| RealPacket h_sq = pmul(h, h); // |a^2 + b^2, a^2 + b^2| RealPacket a_sq = pselect(evenmask, a2, a2_flip); // |a^2, a^2| RealPacket m_h_sq = pmul(h_sq, cst_minus_one_rp); RealPacket m_a_sq = pmul(a_sq, cst_minus_one_rp); RealPacket x = psub(psub(pmadd(h, h, m_h_sq), pmadd(b_all, b_all, psub(a_sq, h_sq))), pmadd(a_all, a_all, m_a_sq)); h = psub(h, pdiv(x, pmul(cst_two_rp, h))); // |h - x/(2*h), h - x/(2*h)| // handle zero-case RealPacket iszero = pcmp_eq(por(a_abs, a_flip), cst_zero_rp); h = pandnot(h, iszero); // |sqrt(a^2+b^2), sqrt(a^2+b^2)| return Packet(h); // |sqrt(a^2+b^2), sqrt(a^2+b^2)| } template struct psign_impl::type>::IsComplex && !NumTraits::type>::IsInteger>> { static EIGEN_DEVICE_FUNC inline Packet run(const Packet& a) { using Scalar = typename unpacket_traits::type; const Packet cst_one = pset1(Scalar(1)); const Packet cst_zero = pzero(a); const Packet abs_a = pabs(a); const Packet sign_mask = pandnot(a, abs_a); const Packet nonzero_mask = pcmp_lt(cst_zero, abs_a); return pselect(nonzero_mask, por(sign_mask, cst_one), abs_a); } }; template struct psign_impl::type>::IsComplex && NumTraits::type>::IsSigned && NumTraits::type>::IsInteger>> { static EIGEN_DEVICE_FUNC inline Packet run(const Packet& a) { using Scalar = typename unpacket_traits::type; const Packet cst_one = pset1(Scalar(1)); const Packet cst_minus_one = pset1(Scalar(-1)); const Packet cst_zero = pzero(a); const Packet positive_mask = pcmp_lt(cst_zero, a); const Packet positive = pand(positive_mask, cst_one); const Packet negative_mask = pcmp_lt(a, cst_zero); const Packet negative = pand(negative_mask, cst_minus_one); return por(positive, negative); } }; template struct psign_impl::type>::IsComplex && !NumTraits::type>::IsSigned && NumTraits::type>::IsInteger>> { static EIGEN_DEVICE_FUNC inline Packet run(const Packet& a) { using Scalar = typename unpacket_traits::type; const Packet cst_one = pset1(Scalar(1)); const Packet cst_zero = pzero(a); const Packet zero_mask = pcmp_eq(cst_zero, a); return pandnot(cst_one, zero_mask); } }; // \internal \returns the the sign of a complex number z, defined as z / abs(z). template struct psign_impl::type>::IsComplex && unpacket_traits::vectorizable>> { static EIGEN_DEVICE_FUNC inline Packet run(const Packet& a) { typedef typename unpacket_traits::type Scalar; typedef typename Scalar::value_type RealScalar; typedef typename unpacket_traits::as_real RealPacket; // Step 1. Compute (for each element z = x + i*y in a) // l = abs(z) = sqrt(x^2 + y^2). // To avoid over- and underflow, we use the stable formula for each hypotenuse // l = (zmin == 0 ? zmax : zmax * sqrt(1 + (zmin/zmax)**2)), // where zmax = max(|x|, |y|), zmin = min(|x|, |y|), RealPacket a_abs = pabs(a.v); RealPacket a_abs_flip = pcplxflip(Packet(a_abs)).v; RealPacket a_max = pmax(a_abs, a_abs_flip); RealPacket a_min = pmin(a_abs, a_abs_flip); RealPacket a_min_zero_mask = pcmp_eq(a_min, pzero(a_min)); RealPacket a_max_zero_mask = pcmp_eq(a_max, pzero(a_max)); RealPacket r = pdiv(a_min, a_max); const RealPacket cst_one = pset1(RealScalar(1)); RealPacket l = pmul(a_max, psqrt(padd(cst_one, pmul(r, r)))); // [l0, l0, l1, l1] // Set l to a_max if a_min is zero, since the roundtrip sqrt(a_max^2) may be // lossy. l = pselect(a_min_zero_mask, a_max, l); // Step 2 compute a / abs(a). RealPacket sign_as_real = pandnot(pdiv(a.v, l), a_max_zero_mask); Packet sign; sign.v = sign_as_real; return sign; } }; // TODO(rmlarsen): The following set of utilities for double word arithmetic // should perhaps be refactored as a separate file, since it would be generally // useful for special function implementation etc. Writing the algorithms in // terms if a double word type would also make the code more readable. // This function splits x into the nearest integer n and fractional part r, // such that x = n + r holds exactly. template EIGEN_STRONG_INLINE void absolute_split(const Packet& x, Packet& n, Packet& r) { n = pround(x); r = psub(x, n); } // This function computes the sum {s, r}, such that x + y = s_hi + s_lo // holds exactly, and s_hi = fl(x+y), if |x| >= |y|. template EIGEN_STRONG_INLINE void fast_twosum(const Packet& x, const Packet& y, Packet& s_hi, Packet& s_lo) { s_hi = padd(x, y); const Packet t = psub(s_hi, x); s_lo = psub(y, t); } #ifdef EIGEN_VECTORIZE_FMA // This function implements the extended precision product of // a pair of floating point numbers. Given {x, y}, it computes the pair // {p_hi, p_lo} such that x * y = p_hi + p_lo holds exactly and // p_hi = fl(x * y). template EIGEN_STRONG_INLINE void twoprod(const Packet& x, const Packet& y, Packet& p_hi, Packet& p_lo) { p_hi = pmul(x, y); p_lo = pmsub(x, y, p_hi); } #else // This function implements the Veltkamp splitting. Given a floating point // number x it returns the pair {x_hi, x_lo} such that x_hi + x_lo = x holds // exactly and that half of the significant of x fits in x_hi. // This is Algorithm 3 from Jean-Michel Muller, "Elementary Functions", // 3rd edition, Birkh\"auser, 2016. template EIGEN_STRONG_INLINE void veltkamp_splitting(const Packet& x, Packet& x_hi, Packet& x_lo) { typedef typename unpacket_traits::type Scalar; EIGEN_CONSTEXPR int shift = (NumTraits::digits() + 1) / 2; const Scalar shift_scale = Scalar(uint64_t(1) << shift); // Scalar constructor not necessarily constexpr. const Packet gamma = pmul(pset1(shift_scale + Scalar(1)), x); Packet rho = psub(x, gamma); x_hi = padd(rho, gamma); x_lo = psub(x, x_hi); } // This function implements Dekker's algorithm for products x * y. // Given floating point numbers {x, y} computes the pair // {p_hi, p_lo} such that x * y = p_hi + p_lo holds exactly and // p_hi = fl(x * y). template EIGEN_STRONG_INLINE void twoprod(const Packet& x, const Packet& y, Packet& p_hi, Packet& p_lo) { Packet x_hi, x_lo, y_hi, y_lo; veltkamp_splitting(x, x_hi, x_lo); veltkamp_splitting(y, y_hi, y_lo); p_hi = pmul(x, y); p_lo = pmadd(x_hi, y_hi, pnegate(p_hi)); p_lo = pmadd(x_hi, y_lo, p_lo); p_lo = pmadd(x_lo, y_hi, p_lo); p_lo = pmadd(x_lo, y_lo, p_lo); } #endif // EIGEN_VECTORIZE_FMA // This function implements Dekker's algorithm for the addition // of two double word numbers represented by {x_hi, x_lo} and {y_hi, y_lo}. // It returns the result as a pair {s_hi, s_lo} such that // x_hi + x_lo + y_hi + y_lo = s_hi + s_lo holds exactly. // This is Algorithm 5 from Jean-Michel Muller, "Elementary Functions", // 3rd edition, Birkh\"auser, 2016. template EIGEN_STRONG_INLINE void twosum(const Packet& x_hi, const Packet& x_lo, const Packet& y_hi, const Packet& y_lo, Packet& s_hi, Packet& s_lo) { const Packet x_greater_mask = pcmp_lt(pabs(y_hi), pabs(x_hi)); Packet r_hi_1, r_lo_1; fast_twosum(x_hi, y_hi, r_hi_1, r_lo_1); Packet r_hi_2, r_lo_2; fast_twosum(y_hi, x_hi, r_hi_2, r_lo_2); const Packet r_hi = pselect(x_greater_mask, r_hi_1, r_hi_2); const Packet s1 = padd(padd(y_lo, r_lo_1), x_lo); const Packet s2 = padd(padd(x_lo, r_lo_2), y_lo); const Packet s = pselect(x_greater_mask, s1, s2); fast_twosum(r_hi, s, s_hi, s_lo); } // This is a version of twosum for double word numbers, // which assumes that |x_hi| >= |y_hi|. template EIGEN_STRONG_INLINE void fast_twosum(const Packet& x_hi, const Packet& x_lo, const Packet& y_hi, const Packet& y_lo, Packet& s_hi, Packet& s_lo) { Packet r_hi, r_lo; fast_twosum(x_hi, y_hi, r_hi, r_lo); const Packet s = padd(padd(y_lo, r_lo), x_lo); fast_twosum(r_hi, s, s_hi, s_lo); } // This is a version of twosum for adding a floating point number x to // double word number {y_hi, y_lo} number, with the assumption // that |x| >= |y_hi|. template EIGEN_STRONG_INLINE void fast_twosum(const Packet& x, const Packet& y_hi, const Packet& y_lo, Packet& s_hi, Packet& s_lo) { Packet r_hi, r_lo; fast_twosum(x, y_hi, r_hi, r_lo); const Packet s = padd(y_lo, r_lo); fast_twosum(r_hi, s, s_hi, s_lo); } // This function implements the multiplication of a double word // number represented by {x_hi, x_lo} by a floating point number y. // It returns the result as a pair {p_hi, p_lo} such that // (x_hi + x_lo) * y = p_hi + p_lo hold with a relative error // of less than 2*2^{-2p}, where p is the number of significand bit // in the floating point type. // This is Algorithm 7 from Jean-Michel Muller, "Elementary Functions", // 3rd edition, Birkh\"auser, 2016. template EIGEN_STRONG_INLINE void twoprod(const Packet& x_hi, const Packet& x_lo, const Packet& y, Packet& p_hi, Packet& p_lo) { Packet c_hi, c_lo1; twoprod(x_hi, y, c_hi, c_lo1); const Packet c_lo2 = pmul(x_lo, y); Packet t_hi, t_lo1; fast_twosum(c_hi, c_lo2, t_hi, t_lo1); const Packet t_lo2 = padd(t_lo1, c_lo1); fast_twosum(t_hi, t_lo2, p_hi, p_lo); } // This function implements the multiplication of two double word // numbers represented by {x_hi, x_lo} and {y_hi, y_lo}. // It returns the result as a pair {p_hi, p_lo} such that // (x_hi + x_lo) * (y_hi + y_lo) = p_hi + p_lo holds with a relative error // of less than 2*2^{-2p}, where p is the number of significand bit // in the floating point type. template EIGEN_STRONG_INLINE void twoprod(const Packet& x_hi, const Packet& x_lo, const Packet& y_hi, const Packet& y_lo, Packet& p_hi, Packet& p_lo) { Packet p_hi_hi, p_hi_lo; twoprod(x_hi, x_lo, y_hi, p_hi_hi, p_hi_lo); Packet p_lo_hi, p_lo_lo; twoprod(x_hi, x_lo, y_lo, p_lo_hi, p_lo_lo); fast_twosum(p_hi_hi, p_hi_lo, p_lo_hi, p_lo_lo, p_hi, p_lo); } // This function implements the division of double word {x_hi, x_lo} // by float y. This is Algorithm 15 from "Tight and rigourous error bounds // for basic building blocks of double-word arithmetic", Joldes, Muller, & Popescu, // 2017. https://hal.archives-ouvertes.fr/hal-01351529 template void doubleword_div_fp(const Packet& x_hi, const Packet& x_lo, const Packet& y, Packet& z_hi, Packet& z_lo) { const Packet t_hi = pdiv(x_hi, y); Packet pi_hi, pi_lo; twoprod(t_hi, y, pi_hi, pi_lo); const Packet delta_hi = psub(x_hi, pi_hi); const Packet delta_t = psub(delta_hi, pi_lo); const Packet delta = padd(delta_t, x_lo); const Packet t_lo = pdiv(delta, y); fast_twosum(t_hi, t_lo, z_hi, z_lo); } // This function computes log2(x) and returns the result as a double word. template struct accurate_log2 { template EIGEN_STRONG_INLINE void operator()(const Packet& x, Packet& log2_x_hi, Packet& log2_x_lo) { log2_x_hi = plog2(x); log2_x_lo = pzero(x); } }; // This specialization uses a more accurate algorithm to compute log2(x) for // floats in [1/sqrt(2);sqrt(2)] with a relative accuracy of ~6.42e-10. // This additional accuracy is needed to counter the error-magnification // inherent in multiplying by a potentially large exponent in pow(x,y). // The minimax polynomial used was calculated using the Sollya tool. // See sollya.org. template <> struct accurate_log2 { template EIGEN_STRONG_INLINE void operator()(const Packet& z, Packet& log2_x_hi, Packet& log2_x_lo) { // The function log(1+x)/x is approximated in the interval // [1/sqrt(2)-1;sqrt(2)-1] by a degree 10 polynomial of the form // Q(x) = (C0 + x * (C1 + x * (C2 + x * (C3 + x * P(x))))), // where the degree 6 polynomial P(x) is evaluated in single precision, // while the remaining 4 terms of Q(x), as well as the final multiplication by x // to reconstruct log(1+x) are evaluated in extra precision using // double word arithmetic. C0 through C3 are extra precise constants // stored as double words. // // The polynomial coefficients were calculated using Sollya commands: // > n = 10; // > f = log2(1+x)/x; // > interval = [sqrt(0.5)-1;sqrt(2)-1]; // > p = fpminimax(f,n,[|double,double,double,double,single...|],interval,relative,floating); const Packet p6 = pset1(9.703654795885e-2f); const Packet p5 = pset1(-0.1690667718648f); const Packet p4 = pset1(0.1720575392246f); const Packet p3 = pset1(-0.1789081543684f); const Packet p2 = pset1(0.2050433009862f); const Packet p1 = pset1(-0.2404672354459f); const Packet p0 = pset1(0.2885761857032f); const Packet C3_hi = pset1(-0.360674142838f); const Packet C3_lo = pset1(-6.13283912543e-09f); const Packet C2_hi = pset1(0.480897903442f); const Packet C2_lo = pset1(-1.44861207474e-08f); const Packet C1_hi = pset1(-0.721347510815f); const Packet C1_lo = pset1(-4.84483164698e-09f); const Packet C0_hi = pset1(1.44269502163f); const Packet C0_lo = pset1(2.01711713999e-08f); const Packet one = pset1(1.0f); const Packet x = psub(z, one); // Evaluate P(x) in working precision. // We evaluate it in multiple parts to improve instruction level // parallelism. Packet x2 = pmul(x, x); Packet p_even = pmadd(p6, x2, p4); p_even = pmadd(p_even, x2, p2); p_even = pmadd(p_even, x2, p0); Packet p_odd = pmadd(p5, x2, p3); p_odd = pmadd(p_odd, x2, p1); Packet p = pmadd(p_odd, x, p_even); // Now evaluate the low-order tems of Q(x) in double word precision. // In the following, due to the alternating signs and the fact that // |x| < sqrt(2)-1, we can assume that |C*_hi| >= q_i, and use // fast_twosum instead of the slower twosum. Packet q_hi, q_lo; Packet t_hi, t_lo; // C3 + x * p(x) twoprod(p, x, t_hi, t_lo); fast_twosum(C3_hi, C3_lo, t_hi, t_lo, q_hi, q_lo); // C2 + x * p(x) twoprod(q_hi, q_lo, x, t_hi, t_lo); fast_twosum(C2_hi, C2_lo, t_hi, t_lo, q_hi, q_lo); // C1 + x * p(x) twoprod(q_hi, q_lo, x, t_hi, t_lo); fast_twosum(C1_hi, C1_lo, t_hi, t_lo, q_hi, q_lo); // C0 + x * p(x) twoprod(q_hi, q_lo, x, t_hi, t_lo); fast_twosum(C0_hi, C0_lo, t_hi, t_lo, q_hi, q_lo); // log(z) ~= x * Q(x) twoprod(q_hi, q_lo, x, log2_x_hi, log2_x_lo); } }; // This specialization uses a more accurate algorithm to compute log2(x) for // floats in [1/sqrt(2);sqrt(2)] with a relative accuracy of ~1.27e-18. // This additional accuracy is needed to counter the error-magnification // inherent in multiplying by a potentially large exponent in pow(x,y). // The minimax polynomial used was calculated using the Sollya tool. // See sollya.org. template <> struct accurate_log2 { template EIGEN_STRONG_INLINE void operator()(const Packet& x, Packet& log2_x_hi, Packet& log2_x_lo) { // We use a transformation of variables: // r = c * (x-1) / (x+1), // such that // log2(x) = log2((1 + r/c) / (1 - r/c)) = f(r). // The function f(r) can be approximated well using an odd polynomial // of the form // P(r) = ((Q(r^2) * r^2 + C) * r^2 + 1) * r, // For the implementation of log2 here, Q is of degree 6 with // coefficient represented in working precision (double), while C is a // constant represented in extra precision as a double word to achieve // full accuracy. // // The polynomial coefficients were computed by the Sollya script: // // c = 2 / log(2); // trans = c * (x-1)/(x+1); // itrans = (1+x/c)/(1-x/c); // interval=[trans(sqrt(0.5)); trans(sqrt(2))]; // print(interval); // f = log2(itrans(x)); // p=fpminimax(f,[|1,3,5,7,9,11,13,15,17|],[|1,DD,double...|],interval,relative,floating); const Packet q12 = pset1(2.87074255468000586e-9); const Packet q10 = pset1(2.38957980901884082e-8); const Packet q8 = pset1(2.31032094540014656e-7); const Packet q6 = pset1(2.27279857398537278e-6); const Packet q4 = pset1(2.31271023278625638e-5); const Packet q2 = pset1(2.47556738444535513e-4); const Packet q0 = pset1(2.88543873228900172e-3); const Packet C_hi = pset1(0.0400377511598501157); const Packet C_lo = pset1(-4.77726582251425391e-19); const Packet one = pset1(1.0); const Packet cst_2_log2e_hi = pset1(2.88539008177792677); const Packet cst_2_log2e_lo = pset1(4.07660016854549667e-17); // c * (x - 1) Packet t_hi, t_lo; // t = c * (x-1) twoprod(cst_2_log2e_hi, cst_2_log2e_lo, psub(x, one), t_hi, t_lo); // r = c * (x-1) / (x+1), Packet r_hi, r_lo; doubleword_div_fp(t_hi, t_lo, padd(x, one), r_hi, r_lo); // r2 = r * r Packet r2_hi, r2_lo; twoprod(r_hi, r_lo, r_hi, r_lo, r2_hi, r2_lo); // r4 = r2 * r2 Packet r4_hi, r4_lo; twoprod(r2_hi, r2_lo, r2_hi, r2_lo, r4_hi, r4_lo); // Evaluate Q(r^2) in working precision. We evaluate it in two parts // (even and odd in r^2) to improve instruction level parallelism. Packet q_even = pmadd(q12, r4_hi, q8); Packet q_odd = pmadd(q10, r4_hi, q6); q_even = pmadd(q_even, r4_hi, q4); q_odd = pmadd(q_odd, r4_hi, q2); q_even = pmadd(q_even, r4_hi, q0); Packet q = pmadd(q_odd, r2_hi, q_even); // Now evaluate the low order terms of P(x) in double word precision. // In the following, due to the increasing magnitude of the coefficients // and r being constrained to [-0.5, 0.5] we can use fast_twosum instead // of the slower twosum. // Q(r^2) * r^2 Packet p_hi, p_lo; twoprod(r2_hi, r2_lo, q, p_hi, p_lo); // Q(r^2) * r^2 + C Packet p1_hi, p1_lo; fast_twosum(C_hi, C_lo, p_hi, p_lo, p1_hi, p1_lo); // (Q(r^2) * r^2 + C) * r^2 Packet p2_hi, p2_lo; twoprod(r2_hi, r2_lo, p1_hi, p1_lo, p2_hi, p2_lo); // ((Q(r^2) * r^2 + C) * r^2 + 1) Packet p3_hi, p3_lo; fast_twosum(one, p2_hi, p2_lo, p3_hi, p3_lo); // log(z) ~= ((Q(r^2) * r^2 + C) * r^2 + 1) * r twoprod(p3_hi, p3_lo, r_hi, r_lo, log2_x_hi, log2_x_lo); } }; // This function computes exp2(x) (i.e. 2**x). template struct fast_accurate_exp2 { template EIGEN_STRONG_INLINE Packet operator()(const Packet& x) { // TODO(rmlarsen): Add a pexp2 packetop. return pexp(pmul(pset1(Scalar(EIGEN_LN2)), x)); } }; // This specialization uses a faster algorithm to compute exp2(x) for floats // in [-0.5;0.5] with a relative accuracy of 1 ulp. // The minimax polynomial used was calculated using the Sollya tool. // See sollya.org. template <> struct fast_accurate_exp2 { template EIGEN_STRONG_INLINE Packet operator()(const Packet& x) { // This function approximates exp2(x) by a degree 6 polynomial of the form // Q(x) = 1 + x * (C + x * P(x)), where the degree 4 polynomial P(x) is evaluated in // single precision, and the remaining steps are evaluated with extra precision using // double word arithmetic. C is an extra precise constant stored as a double word. // // The polynomial coefficients were calculated using Sollya commands: // > n = 6; // > f = 2^x; // > interval = [-0.5;0.5]; // > p = fpminimax(f,n,[|1,double,single...|],interval,relative,floating); const Packet p4 = pset1(1.539513905e-4f); const Packet p3 = pset1(1.340007293e-3f); const Packet p2 = pset1(9.618283249e-3f); const Packet p1 = pset1(5.550328270e-2f); const Packet p0 = pset1(0.2402264923f); const Packet C_hi = pset1(0.6931471825f); const Packet C_lo = pset1(2.36836577e-08f); const Packet one = pset1(1.0f); // Evaluate P(x) in working precision. // We evaluate even and odd parts of the polynomial separately // to gain some instruction level parallelism. Packet x2 = pmul(x, x); Packet p_even = pmadd(p4, x2, p2); Packet p_odd = pmadd(p3, x2, p1); p_even = pmadd(p_even, x2, p0); Packet p = pmadd(p_odd, x, p_even); // Evaluate the remaining terms of Q(x) with extra precision using // double word arithmetic. Packet p_hi, p_lo; // x * p(x) twoprod(p, x, p_hi, p_lo); // C + x * p(x) Packet q1_hi, q1_lo; twosum(p_hi, p_lo, C_hi, C_lo, q1_hi, q1_lo); // x * (C + x * p(x)) Packet q2_hi, q2_lo; twoprod(q1_hi, q1_lo, x, q2_hi, q2_lo); // 1 + x * (C + x * p(x)) Packet q3_hi, q3_lo; // Since |q2_hi| <= sqrt(2)-1 < 1, we can use fast_twosum // for adding it to unity here. fast_twosum(one, q2_hi, q3_hi, q3_lo); return padd(q3_hi, padd(q2_lo, q3_lo)); } }; // in [-0.5;0.5] with a relative accuracy of 1 ulp. // The minimax polynomial used was calculated using the Sollya tool. // See sollya.org. template <> struct fast_accurate_exp2 { template EIGEN_STRONG_INLINE Packet operator()(const Packet& x) { // This function approximates exp2(x) by a degree 10 polynomial of the form // Q(x) = 1 + x * (C + x * P(x)), where the degree 8 polynomial P(x) is evaluated in // single precision, and the remaining steps are evaluated with extra precision using // double word arithmetic. C is an extra precise constant stored as a double word. // // The polynomial coefficients were calculated using Sollya commands: // > n = 11; // > f = 2^x; // > interval = [-0.5;0.5]; // > p = fpminimax(f,n,[|1,DD,double...|],interval,relative,floating); const Packet p9 = pset1(4.431642109085495276e-10); const Packet p8 = pset1(7.073829923303358410e-9); const Packet p7 = pset1(1.017822306737031311e-7); const Packet p6 = pset1(1.321543498017646657e-6); const Packet p5 = pset1(1.525273342728892877e-5); const Packet p4 = pset1(1.540353045780084423e-4); const Packet p3 = pset1(1.333355814685869807e-3); const Packet p2 = pset1(9.618129107593478832e-3); const Packet p1 = pset1(5.550410866481961247e-2); const Packet p0 = pset1