Eigen/src/Core/arch/AVX/MathFunctions.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2014 Pedro Gonnet (pedro.gonnet@gmail.com)
 //
 // 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/.

 #ifndef EIGEN_MATH_FUNCTIONS_AVX_H
 #define EIGEN_MATH_FUNCTIONS_AVX_H

 /* The sin, cos, exp, and log functions of this file are loosely derived from
  * Julien Pommier's sse math library: http://gruntthepeon.free.fr/ssemath/
  */

 namespace Eigen {

 namespace internal {

 inline Packet8i pshiftleft(Packet8i v, int n)
 {
 #ifdef EIGEN_VECTORIZE_AVX2
   return _mm256_slli_epi32(v, n);
 #else
   __m128i lo = _mm_slli_epi32(_mm256_extractf128_si256(v, 0), n);
   __m128i hi = _mm_slli_epi32(_mm256_extractf128_si256(v, 1), n);
   return _mm256_insertf128_si256(_mm256_castsi128_si256(lo), (hi), 1);
 #endif
 }

 inline Packet8f pshiftright(Packet8f v, int n)
 {
 #ifdef EIGEN_VECTORIZE_AVX2
   return _mm256_cvtepi32_ps(_mm256_srli_epi32(_mm256_castps_si256(v), n));
 #else
   __m128i lo = _mm_srli_epi32(_mm256_extractf128_si256(_mm256_castps_si256(v), 0), n);
   __m128i hi = _mm_srli_epi32(_mm256_extractf128_si256(_mm256_castps_si256(v), 1), n);
   return _mm256_cvtepi32_ps(_mm256_insertf128_si256(_mm256_castsi128_si256(lo), (hi), 1));
 #endif
 }

 // Sine function
 // Computes sin(x) by wrapping x to the interval [-Pi/4,3*Pi/4] and
 // evaluating interpolants in [-Pi/4,Pi/4] or [Pi/4,3*Pi/4]. The interpolants
 // are (anti-)symmetric and thus have only odd/even coefficients
 template <>
 EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
 psin<Packet8f>(const Packet8f& _x) {
   Packet8f x = _x;

   // Some useful values.
   _EIGEN_DECLARE_CONST_Packet8i(one, 1);
   _EIGEN_DECLARE_CONST_Packet8f(one, 1.0f);
   _EIGEN_DECLARE_CONST_Packet8f(two, 2.0f);
   _EIGEN_DECLARE_CONST_Packet8f(one_over_four, 0.25f);
   _EIGEN_DECLARE_CONST_Packet8f(one_over_pi, 3.183098861837907e-01f);
   _EIGEN_DECLARE_CONST_Packet8f(neg_pi_first, -3.140625000000000e+00f);
   _EIGEN_DECLARE_CONST_Packet8f(neg_pi_second, -9.670257568359375e-04f);
   _EIGEN_DECLARE_CONST_Packet8f(neg_pi_third, -6.278329571784980e-07f);
   _EIGEN_DECLARE_CONST_Packet8f(four_over_pi, 1.273239544735163e+00f);

   // Map x from [-Pi/4,3*Pi/4] to z in [-1,3] and subtract the shifted period.
   Packet8f z = pmul(x, p8f_one_over_pi);
   Packet8f shift = _mm256_floor_ps(padd(z, p8f_one_over_four));
   x = pmadd(shift, p8f_neg_pi_first, x);
   x = pmadd(shift, p8f_neg_pi_second, x);
   x = pmadd(shift, p8f_neg_pi_third, x);
   z = pmul(x, p8f_four_over_pi);

   // Make a mask for the entries that need flipping, i.e. wherever the shift
   // is odd.
   Packet8i shift_ints = _mm256_cvtps_epi32(shift);
   Packet8i shift_isodd = _mm256_castps_si256(_mm256_and_ps(_mm256_castsi256_ps(shift_ints), _mm256_castsi256_ps(p8i_one)));
   Packet8i sign_flip_mask = pshiftleft(shift_isodd, 31);

   // Create a mask for which interpolant to use, i.e. if z > 1, then the mask
   // is set to ones for that entry.
   Packet8f ival_mask = _mm256_cmp_ps(z, p8f_one, _CMP_GT_OQ);

   // Evaluate the polynomial for the interval [1,3] in z.
   _EIGEN_DECLARE_CONST_Packet8f(coeff_right_0, 9.999999724233232e-01f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_right_2, -3.084242535619928e-01f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_right_4, 1.584991525700324e-02f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_right_6, -3.188805084631342e-04f);
   Packet8f z_minus_two = psub(z, p8f_two);
   Packet8f z_minus_two2 = pmul(z_minus_two, z_minus_two);
   Packet8f right = pmadd(p8f_coeff_right_6, z_minus_two2, p8f_coeff_right_4);
   right = pmadd(right, z_minus_two2, p8f_coeff_right_2);
   right = pmadd(right, z_minus_two2, p8f_coeff_right_0);

   // Evaluate the polynomial for the interval [-1,1] in z.
   _EIGEN_DECLARE_CONST_Packet8f(coeff_left_1, 7.853981525427295e-01f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_left_3, -8.074536727092352e-02f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_left_5, 2.489871967827018e-03f);
   _EIGEN_DECLARE_CONST_Packet8f(coeff_left_7, -3.587725841214251e-05f);
   Packet8f z2 = pmul(z, z);
   Packet8f left = pmadd(p8f_coeff_left_7, z2, p8f_coeff_left_5);
   left = pmadd(left, z2, p8f_coeff_left_3);
   left = pmadd(left, z2, p8f_coeff_left_1);
   left = pmul(left, z);

   // Assemble the results, i.e. select the left and right polynomials.
   left = _mm256_andnot_ps(ival_mask, left);
   right = _mm256_and_ps(ival_mask, right);
   Packet8f res = _mm256_or_ps(left, right);

   // Flip the sign on the odd intervals and return the result.
   res = _mm256_xor_ps(res, _mm256_castsi256_ps(sign_flip_mask));
   return res;
 }

 // Natural 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 EIGEN_UNUSED Packet8f
 plog<Packet8f>(const Packet8f& _x) {
   Packet8f x = _x;
   _EIGEN_DECLARE_CONST_Packet8f(1, 1.0f);
   _EIGEN_DECLARE_CONST_Packet8f(half, 0.5f);
   _EIGEN_DECLARE_CONST_Packet8f(126f, 126.0f);

   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(inv_mant_mask, ~0x7f800000);

   // The smallest non denormalized float number.
   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(min_norm_pos, 0x00800000);
   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(minus_inf, 0xff800000);

   // Polynomial coefficients.
   _EIGEN_DECLARE_CONST_Packet8f(cephes_SQRTHF, 0.707106781186547524f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p0, 7.0376836292E-2f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p1, -1.1514610310E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p2, 1.1676998740E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p3, -1.2420140846E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p4, +1.4249322787E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p5, -1.6668057665E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p6, +2.0000714765E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p7, -2.4999993993E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_p8, +3.3333331174E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_q1, -2.12194440e-4f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_log_q2, 0.693359375f);

   Packet8f invalid_mask = _mm256_cmp_ps(x, _mm256_setzero_ps(), _CMP_NGE_UQ); // not greater equal is true if x is NaN
   Packet8f iszero_mask = _mm256_cmp_ps(x, _mm256_setzero_ps(), _CMP_EQ_OQ);

   // Truncate input values to the minimum positive normal.
   x = pmax(x, p8f_min_norm_pos);

   Packet8f emm0 = pshiftright(x,23);
   Packet8f e = _mm256_sub_ps(emm0, p8f_126f);

   // Set the exponents to -1, i.e. x are in the range [0.5,1).
   x = _mm256_and_ps(x, p8f_inv_mant_mask);
   x = _mm256_or_ps(x, p8f_half);

   // 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; }
   Packet8f mask = _mm256_cmp_ps(x, p8f_cephes_SQRTHF, _CMP_LT_OQ);
   Packet8f tmp = _mm256_and_ps(x, mask);
   x = psub(x, p8f_1);
   e = psub(e, _mm256_and_ps(p8f_1, mask));
   x = padd(x, tmp);

   Packet8f x2 = pmul(x, x);
   Packet8f x3 = pmul(x2, x);

   // Evaluate the polynomial approximant of degree 8 in three parts, probably
   // to improve instruction-level parallelism.
   Packet8f y, y1, y2;
   y = pmadd(p8f_cephes_log_p0, x, p8f_cephes_log_p1);
   y1 = pmadd(p8f_cephes_log_p3, x, p8f_cephes_log_p4);
   y2 = pmadd(p8f_cephes_log_p6, x, p8f_cephes_log_p7);
   y = pmadd(y, x, p8f_cephes_log_p2);
   y1 = pmadd(y1, x, p8f_cephes_log_p5);
   y2 = pmadd(y2, x, p8f_cephes_log_p8);
   y = pmadd(y, x3, y1);
   y = pmadd(y, x3, y2);
   y = pmul(y, x3);

   // Add the logarithm of the exponent back to the result of the interpolation.
   y1 = pmul(e, p8f_cephes_log_q1);
   tmp = pmul(x2, p8f_half);
   y = padd(y, y1);
   x = psub(x, tmp);
   y2 = pmul(e, p8f_cephes_log_q2);
   x = padd(x, y);
   x = padd(x, y2);

   // Filter out invalid inputs, i.e. negative arg will be NAN, 0 will be -INF.
   return _mm256_or_ps(
       _mm256_andnot_ps(iszero_mask, _mm256_or_ps(x, invalid_mask)),
       _mm256_and_ps(iszero_mask, p8f_minus_inf));
 }

 // 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).
 template <>
 EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
 pexp<Packet8f>(const Packet8f& _x) {
   _EIGEN_DECLARE_CONST_Packet8f(1, 1.0f);
   _EIGEN_DECLARE_CONST_Packet8f(half, 0.5f);
   _EIGEN_DECLARE_CONST_Packet8f(127, 127.0f);

   _EIGEN_DECLARE_CONST_Packet8f(exp_hi, 88.3762626647950f);
   _EIGEN_DECLARE_CONST_Packet8f(exp_lo, -88.3762626647949f);

   _EIGEN_DECLARE_CONST_Packet8f(cephes_LOG2EF, 1.44269504088896341f);

   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p0, 1.9875691500E-4f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p1, 1.3981999507E-3f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p2, 8.3334519073E-3f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p3, 4.1665795894E-2f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p4, 1.6666665459E-1f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p5, 5.0000001201E-1f);

   // Clamp x.
   Packet8f x = pmax(pmin(_x, p8f_exp_hi), p8f_exp_lo);

   // Express exp(x) as exp(m*ln(2) + r), start by extracting
   // m = floor(x/ln(2) + 0.5).
   Packet8f m = _mm256_floor_ps(pmadd(x, p8f_cephes_LOG2EF, p8f_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. Note that we don't use the "pmadd" function here to
 // ensure that a precision-preserving FMA instruction is used.
 #ifdef EIGEN_VECTORIZE_FMA
   _EIGEN_DECLARE_CONST_Packet8f(nln2, -0.6931471805599453f);
   Packet8f r = _mm256_fmadd_ps(m, p8f_nln2, x);
 #else
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_C1, 0.693359375f);
   _EIGEN_DECLARE_CONST_Packet8f(cephes_exp_C2, -2.12194440e-4f);
   Packet8f r = psub(x, pmul(m, p8f_cephes_exp_C1));
   r = psub(r, pmul(m, p8f_cephes_exp_C2));
 #endif

   Packet8f r2 = pmul(r, r);

   // TODO(gonnet): Split into odd/even polynomials and try to exploit
   //               instruction-level parallelism.
   Packet8f y = p8f_cephes_exp_p0;
   y = pmadd(y, r, p8f_cephes_exp_p1);
   y = pmadd(y, r, p8f_cephes_exp_p2);
   y = pmadd(y, r, p8f_cephes_exp_p3);
   y = pmadd(y, r, p8f_cephes_exp_p4);
   y = pmadd(y, r, p8f_cephes_exp_p5);
   y = pmadd(y, r2, r);
   y = padd(y, p8f_1);

   // Build emm0 = 2^m.
   Packet8i emm0 = _mm256_cvttps_epi32(padd(m, p8f_127));
   emm0 = pshiftleft(emm0, 23);

   // Return 2^m * exp(r).
   return pmax(pmul(y, _mm256_castsi256_ps(emm0)), _x);
 }

 // Hyperbolic Tangent function.
 template <>
 EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
 ptanh<Packet8f>(const Packet8f& x) {
   return internal::generic_fast_tanh_float(x);
 }

 template <>
 EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet4d
 pexp<Packet4d>(const Packet4d& _x) {
   Packet4d x = _x;

   _EIGEN_DECLARE_CONST_Packet4d(1, 1.0);
   _EIGEN_DECLARE_CONST_Packet4d(2, 2.0);
   _EIGEN_DECLARE_CONST_Packet4d(half, 0.5);

   _EIGEN_DECLARE_CONST_Packet4d(exp_hi, 709.437);
   _EIGEN_DECLARE_CONST_Packet4d(exp_lo, -709.436139303);

   _EIGEN_DECLARE_CONST_Packet4d(cephes_LOG2EF, 1.4426950408889634073599);

   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p0, 1.26177193074810590878e-4);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p1, 3.02994407707441961300e-2);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p2, 9.99999999999999999910e-1);

   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q0, 3.00198505138664455042e-6);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q1, 2.52448340349684104192e-3);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q2, 2.27265548208155028766e-1);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q3, 2.00000000000000000009e0);

   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_C1, 0.693145751953125);
   _EIGEN_DECLARE_CONST_Packet4d(cephes_exp_C2, 1.42860682030941723212e-6);
   _EIGEN_DECLARE_CONST_Packet4i(1023, 1023);

   Packet4d tmp, fx;

   // clamp x
   x = pmax(pmin(x, p4d_exp_hi), p4d_exp_lo);
   // Express exp(x) as exp(g + n*log(2)).
   fx = pmadd(p4d_cephes_LOG2EF, x, p4d_half);

   // Get the integer modulus of log(2), i.e. the "n" described above.
   fx = _mm256_floor_pd(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, p4d_cephes_exp_C1);
   Packet4d z = pmul(fx, p4d_cephes_exp_C2);
   x = psub(x, tmp);
   x = psub(x, z);

   Packet4d x2 = pmul(x, x);

   // Evaluate the numerator polynomial of the rational interpolant.
   Packet4d px = p4d_cephes_exp_p0;
   px = pmadd(px, x2, p4d_cephes_exp_p1);
   px = pmadd(px, x2, p4d_cephes_exp_p2);
   px = pmul(px, x);

   // Evaluate the denominator polynomial of the rational interpolant.
   Packet4d qx = p4d_cephes_exp_q0;
   qx = pmadd(qx, x2, p4d_cephes_exp_q1);
   qx = pmadd(qx, x2, p4d_cephes_exp_q2);
   qx = pmadd(qx, x2, p4d_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 = _mm256_div_pd(px, psub(qx, px));
   x = pmadd(p4d_2, x, p4d_1);

   // Build e=2^n by constructing the exponents in a 128-bit vector and
   // shifting them to where they belong in double-precision values.
   __m128i emm0 = _mm256_cvtpd_epi32(fx);
   emm0 = _mm_add_epi32(emm0, p4i_1023);
   emm0 = _mm_shuffle_epi32(emm0, _MM_SHUFFLE(3, 1, 2, 0));
   __m128i lo = _mm_slli_epi64(emm0, 52);
   __m128i hi = _mm_slli_epi64(_mm_srli_epi64(emm0, 32), 52);
   __m256i e = _mm256_insertf128_si256(_mm256_setzero_si256(), lo, 0);
   e = _mm256_insertf128_si256(e, hi, 1);

   // Construct the result 2^n * exp(g) = e * x. The max is used to catch
   // non-finite values in the input.
   return pmax(pmul(x, _mm256_castsi256_pd(e)), _x);
 }

 // Functions for sqrt.
 // The EIGEN_FAST_MATH version uses the _mm_rsqrt_ps approximation and one step
 // of Newton's method, at a cost of 1-2 bits of precision as opposed to the
 // exact solution. It does not handle +inf, or denormalized numbers correctly.
 // The main advantage of this approach is not just speed, but also the fact that
 // it can be inlined and pipelined with other computations, further reducing its
 // effective latency. This is similar to Quake3's fast inverse square root.
 // For detail see here: http://www.beyond3d.com/content/articles/8/
 #if EIGEN_FAST_MATH
 template <>
 EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
 psqrt<Packet8f>(const Packet8f& _x) {
   Packet8f half = pmul(_x, pset1<Packet8f>(.5f));
   Packet8f denormal_mask = _mm256_and_ps(
       _mm256_cmp_ps(_x, pset1<Packet8f>((std::numeric_limits<float>::min)()),
                     _CMP_LT_OQ),
       _mm256_cmp_ps(_x, _mm256_setzero_ps(), _CMP_GE_OQ));

   // Compute approximate reciprocal sqrt.
   Packet8f x = _mm256_rsqrt_ps(_x);
   // Do a single step of Newton's iteration.
   x = pmul(x, psub(pset1<Packet8f>(1.5f), pmul(half, pmul(x,x))));
   // Flush results for denormals to zero.
   return _mm256_andnot_ps(denormal_mask, pmul(_x,x));
 }
 #else
 template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
 Packet8f psqrt<Packet8f>(const Packet8f& x) {
   return _mm256_sqrt_ps(x);
 }
 #endif
 template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
 Packet4d psqrt<Packet4d>(const Packet4d& x) {
   return _mm256_sqrt_pd(x);
 }
 #if EIGEN_FAST_MATH

 template<> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
 Packet8f prsqrt<Packet8f>(const Packet8f& _x) {
   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(inf, 0x7f800000);
   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(nan, 0x7fc00000);
   _EIGEN_DECLARE_CONST_Packet8f(one_point_five, 1.5f);
   _EIGEN_DECLARE_CONST_Packet8f(minus_half, -0.5f);
   _EIGEN_DECLARE_CONST_Packet8f_FROM_INT(flt_min, 0x00800000);

   Packet8f neg_half = pmul(_x, p8f_minus_half);

   // select only the inverse sqrt of positive normal inputs (denormals are
   // flushed to zero and cause infs as well).
   Packet8f le_zero_mask = _mm256_cmp_ps(_x, p8f_flt_min, _CMP_LT_OQ);
   Packet8f x = _mm256_andnot_ps(le_zero_mask, _mm256_rsqrt_ps(_x));

   // Fill in NaNs and Infs for the negative/zero entries.
   Packet8f neg_mask = _mm256_cmp_ps(_x, _mm256_setzero_ps(), _CMP_LT_OQ);
   Packet8f zero_mask = _mm256_andnot_ps(neg_mask, le_zero_mask);
   Packet8f infs_and_nans = _mm256_or_ps(_mm256_and_ps(neg_mask, p8f_nan),
                                         _mm256_and_ps(zero_mask, p8f_inf));

   // Do a single step of Newton's iteration.
   x = pmul(x, pmadd(neg_half, pmul(x, x), p8f_one_point_five));

   // Insert NaNs and Infs in all the right places.
   return _mm256_or_ps(x, infs_and_nans);
 }

 #else
 template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
 Packet8f prsqrt<Packet8f>(const Packet8f& x) {
   _EIGEN_DECLARE_CONST_Packet8f(one, 1.0f);
   return _mm256_div_ps(p8f_one, _mm256_sqrt_ps(x));
 }
 #endif

 template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
 Packet4d prsqrt<Packet4d>(const Packet4d& x) {
   _EIGEN_DECLARE_CONST_Packet4d(one, 1.0);
   return _mm256_div_pd(p4d_one, _mm256_sqrt_pd(x));
 }


 }  // end namespace internal

 }  // end namespace Eigen

 #endif  // EIGEN_MATH_FUNCTIONS_AVX_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2014 Pedro Gonnet (pedro.gonnet@gmail.com)
	//
	// 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/.

	#ifndef EIGEN_MATH_FUNCTIONS_AVX_H
	#define EIGEN_MATH_FUNCTIONS_AVX_H

	/* The sin, cos, exp, and log functions of this file are loosely derived from
	* Julien Pommier's sse math library: http://gruntthepeon.free.fr/ssemath/
	*/

	namespace Eigen {

	namespace internal {

	inline Packet8i pshiftleft(Packet8i v, int n)
	{
	#ifdef EIGEN_VECTORIZE_AVX2
	return _mm256_slli_epi32(v, n);
	#else
	__m128i lo = _mm_slli_epi32(_mm256_extractf128_si256(v, 0), n);
	__m128i hi = _mm_slli_epi32(_mm256_extractf128_si256(v, 1), n);
	return _mm256_insertf128_si256(_mm256_castsi128_si256(lo), (hi), 1);
	#endif
	}

	inline Packet8f pshiftright(Packet8f v, int n)
	{
	#ifdef EIGEN_VECTORIZE_AVX2
	return _mm256_cvtepi32_ps(_mm256_srli_epi32(_mm256_castps_si256(v), n));
	#else
	__m128i lo = _mm_srli_epi32(_mm256_extractf128_si256(_mm256_castps_si256(v), 0), n);
	__m128i hi = _mm_srli_epi32(_mm256_extractf128_si256(_mm256_castps_si256(v), 1), n);
	return _mm256_cvtepi32_ps(_mm256_insertf128_si256(_mm256_castsi128_si256(lo), (hi), 1));
	#endif
	}

	// Sine function
	// Computes sin(x) by wrapping x to the interval [-Pi/4,3*Pi/4] and
	// evaluating interpolants in [-Pi/4,Pi/4] or [Pi/4,3*Pi/4]. The interpolants
	// are (anti-)symmetric and thus have only odd/even coefficients
	template <>
	EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
	psin<Packet8f>(const Packet8f& _x) {
	Packet8f x = _x;

	// Some useful values.
	_EIGEN_DECLARE_CONST_Packet8i(one, 1);
	_EIGEN_DECLARE_CONST_Packet8f(one, 1.0f);
	_EIGEN_DECLARE_CONST_Packet8f(two, 2.0f);
	_EIGEN_DECLARE_CONST_Packet8f(one_over_four, 0.25f);
	_EIGEN_DECLARE_CONST_Packet8f(one_over_pi, 3.183098861837907e-01f);
	_EIGEN_DECLARE_CONST_Packet8f(neg_pi_first, -3.140625000000000e+00f);
	_EIGEN_DECLARE_CONST_Packet8f(neg_pi_second, -9.670257568359375e-04f);
	_EIGEN_DECLARE_CONST_Packet8f(neg_pi_third, -6.278329571784980e-07f);
	_EIGEN_DECLARE_CONST_Packet8f(four_over_pi, 1.273239544735163e+00f);

	// Map x from [-Pi/4,3*Pi/4] to z in [-1,3] and subtract the shifted period.
	Packet8f z = pmul(x, p8f_one_over_pi);
	Packet8f shift = _mm256_floor_ps(padd(z, p8f_one_over_four));
	x = pmadd(shift, p8f_neg_pi_first, x);
	x = pmadd(shift, p8f_neg_pi_second, x);
	x = pmadd(shift, p8f_neg_pi_third, x);
	z = pmul(x, p8f_four_over_pi);

	// Make a mask for the entries that need flipping, i.e. wherever the shift
	// is odd.
	Packet8i shift_ints = _mm256_cvtps_epi32(shift);
	Packet8i shift_isodd = _mm256_castps_si256(_mm256_and_ps(_mm256_castsi256_ps(shift_ints), _mm256_castsi256_ps(p8i_one)));
	Packet8i sign_flip_mask = pshiftleft(shift_isodd, 31);

	// Create a mask for which interpolant to use, i.e. if z > 1, then the mask
	// is set to ones for that entry.
	Packet8f ival_mask = _mm256_cmp_ps(z, p8f_one, _CMP_GT_OQ);

	// Evaluate the polynomial for the interval [1,3] in z.
	_EIGEN_DECLARE_CONST_Packet8f(coeff_right_0, 9.999999724233232e-01f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_right_2, -3.084242535619928e-01f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_right_4, 1.584991525700324e-02f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_right_6, -3.188805084631342e-04f);
	Packet8f z_minus_two = psub(z, p8f_two);
	Packet8f z_minus_two2 = pmul(z_minus_two, z_minus_two);
	Packet8f right = pmadd(p8f_coeff_right_6, z_minus_two2, p8f_coeff_right_4);
	right = pmadd(right, z_minus_two2, p8f_coeff_right_2);
	right = pmadd(right, z_minus_two2, p8f_coeff_right_0);

	// Evaluate the polynomial for the interval [-1,1] in z.
	_EIGEN_DECLARE_CONST_Packet8f(coeff_left_1, 7.853981525427295e-01f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_left_3, -8.074536727092352e-02f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_left_5, 2.489871967827018e-03f);
	_EIGEN_DECLARE_CONST_Packet8f(coeff_left_7, -3.587725841214251e-05f);
	Packet8f z2 = pmul(z, z);
	Packet8f left = pmadd(p8f_coeff_left_7, z2, p8f_coeff_left_5);
	left = pmadd(left, z2, p8f_coeff_left_3);
	left = pmadd(left, z2, p8f_coeff_left_1);
	left = pmul(left, z);

	// Assemble the results, i.e. select the left and right polynomials.
	left = _mm256_andnot_ps(ival_mask, left);
	right = _mm256_and_ps(ival_mask, right);
	Packet8f res = _mm256_or_ps(left, right);

	// Flip the sign on the odd intervals and return the result.
	res = _mm256_xor_ps(res, _mm256_castsi256_ps(sign_flip_mask));
	return res;
	}

	// Natural 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 EIGEN_UNUSED Packet8f
	plog<Packet8f>(const Packet8f& _x) {
	Packet8f x = _x;
	_EIGEN_DECLARE_CONST_Packet8f(1, 1.0f);
	_EIGEN_DECLARE_CONST_Packet8f(half, 0.5f);
	_EIGEN_DECLARE_CONST_Packet8f(126f, 126.0f);

	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(inv_mant_mask, ~0x7f800000);

	// The smallest non denormalized float number.
	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(min_norm_pos, 0x00800000);
	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(minus_inf, 0xff800000);

	// Polynomial coefficients.
	_EIGEN_DECLARE_CONST_Packet8f(cephes_SQRTHF, 0.707106781186547524f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p0, 7.0376836292E-2f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p1, -1.1514610310E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p2, 1.1676998740E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p3, -1.2420140846E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p4, +1.4249322787E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p5, -1.6668057665E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p6, +2.0000714765E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p7, -2.4999993993E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_p8, +3.3333331174E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_q1, -2.12194440e-4f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_log_q2, 0.693359375f);

	Packet8f invalid_mask = _mm256_cmp_ps(x, _mm256_setzero_ps(), _CMP_NGE_UQ); // not greater equal is true if x is NaN
	Packet8f iszero_mask = _mm256_cmp_ps(x, _mm256_setzero_ps(), _CMP_EQ_OQ);

	// Truncate input values to the minimum positive normal.
	x = pmax(x, p8f_min_norm_pos);

	Packet8f emm0 = pshiftright(x,23);
	Packet8f e = _mm256_sub_ps(emm0, p8f_126f);

	// Set the exponents to -1, i.e. x are in the range [0.5,1).
	x = _mm256_and_ps(x, p8f_inv_mant_mask);
	x = _mm256_or_ps(x, p8f_half);

	// 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; }
	Packet8f mask = _mm256_cmp_ps(x, p8f_cephes_SQRTHF, _CMP_LT_OQ);
	Packet8f tmp = _mm256_and_ps(x, mask);
	x = psub(x, p8f_1);
	e = psub(e, _mm256_and_ps(p8f_1, mask));
	x = padd(x, tmp);

	Packet8f x2 = pmul(x, x);
	Packet8f x3 = pmul(x2, x);

	// Evaluate the polynomial approximant of degree 8 in three parts, probably
	// to improve instruction-level parallelism.
	Packet8f y, y1, y2;
	y = pmadd(p8f_cephes_log_p0, x, p8f_cephes_log_p1);
	y1 = pmadd(p8f_cephes_log_p3, x, p8f_cephes_log_p4);
	y2 = pmadd(p8f_cephes_log_p6, x, p8f_cephes_log_p7);
	y = pmadd(y, x, p8f_cephes_log_p2);
	y1 = pmadd(y1, x, p8f_cephes_log_p5);
	y2 = pmadd(y2, x, p8f_cephes_log_p8);
	y = pmadd(y, x3, y1);
	y = pmadd(y, x3, y2);
	y = pmul(y, x3);

	// Add the logarithm of the exponent back to the result of the interpolation.
	y1 = pmul(e, p8f_cephes_log_q1);
	tmp = pmul(x2, p8f_half);
	y = padd(y, y1);
	x = psub(x, tmp);
	y2 = pmul(e, p8f_cephes_log_q2);
	x = padd(x, y);
	x = padd(x, y2);

	// Filter out invalid inputs, i.e. negative arg will be NAN, 0 will be -INF.
	return _mm256_or_ps(
	_mm256_andnot_ps(iszero_mask, _mm256_or_ps(x, invalid_mask)),
	_mm256_and_ps(iszero_mask, p8f_minus_inf));
	}

	// 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).
	template <>
	EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
	pexp<Packet8f>(const Packet8f& _x) {
	_EIGEN_DECLARE_CONST_Packet8f(1, 1.0f);
	_EIGEN_DECLARE_CONST_Packet8f(half, 0.5f);
	_EIGEN_DECLARE_CONST_Packet8f(127, 127.0f);

	_EIGEN_DECLARE_CONST_Packet8f(exp_hi, 88.3762626647950f);
	_EIGEN_DECLARE_CONST_Packet8f(exp_lo, -88.3762626647949f);

	_EIGEN_DECLARE_CONST_Packet8f(cephes_LOG2EF, 1.44269504088896341f);

	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p0, 1.9875691500E-4f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p1, 1.3981999507E-3f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p2, 8.3334519073E-3f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p3, 4.1665795894E-2f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p4, 1.6666665459E-1f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_p5, 5.0000001201E-1f);

	// Clamp x.
	Packet8f x = pmax(pmin(_x, p8f_exp_hi), p8f_exp_lo);

	// Express exp(x) as exp(m*ln(2) + r), start by extracting
	// m = floor(x/ln(2) + 0.5).
	Packet8f m = _mm256_floor_ps(pmadd(x, p8f_cephes_LOG2EF, p8f_half));

	// Get r = x - mln(2). If no FMA instructions are available, mln(2) is
	// subtracted out in two parts, mC1+mC2 = m*ln(2), to avoid accumulating
	// truncation errors. Note that we don't use the "pmadd" function here to
	// ensure that a precision-preserving FMA instruction is used.
	#ifdef EIGEN_VECTORIZE_FMA
	_EIGEN_DECLARE_CONST_Packet8f(nln2, -0.6931471805599453f);
	Packet8f r = _mm256_fmadd_ps(m, p8f_nln2, x);
	#else
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_C1, 0.693359375f);
	_EIGEN_DECLARE_CONST_Packet8f(cephes_exp_C2, -2.12194440e-4f);
	Packet8f r = psub(x, pmul(m, p8f_cephes_exp_C1));
	r = psub(r, pmul(m, p8f_cephes_exp_C2));
	#endif

	Packet8f r2 = pmul(r, r);

	// TODO(gonnet): Split into odd/even polynomials and try to exploit
	// instruction-level parallelism.
	Packet8f y = p8f_cephes_exp_p0;
	y = pmadd(y, r, p8f_cephes_exp_p1);
	y = pmadd(y, r, p8f_cephes_exp_p2);
	y = pmadd(y, r, p8f_cephes_exp_p3);
	y = pmadd(y, r, p8f_cephes_exp_p4);
	y = pmadd(y, r, p8f_cephes_exp_p5);
	y = pmadd(y, r2, r);
	y = padd(y, p8f_1);

	// Build emm0 = 2^m.
	Packet8i emm0 = _mm256_cvttps_epi32(padd(m, p8f_127));
	emm0 = pshiftleft(emm0, 23);

	// Return 2^m * exp(r).
	return pmax(pmul(y, _mm256_castsi256_ps(emm0)), _x);
	}

	// Hyperbolic Tangent function.
	template <>
	EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
	ptanh<Packet8f>(const Packet8f& x) {
	return internal::generic_fast_tanh_float(x);
	}

	template <>
	EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet4d
	pexp<Packet4d>(const Packet4d& _x) {
	Packet4d x = _x;

	_EIGEN_DECLARE_CONST_Packet4d(1, 1.0);
	_EIGEN_DECLARE_CONST_Packet4d(2, 2.0);
	_EIGEN_DECLARE_CONST_Packet4d(half, 0.5);

	_EIGEN_DECLARE_CONST_Packet4d(exp_hi, 709.437);
	_EIGEN_DECLARE_CONST_Packet4d(exp_lo, -709.436139303);

	_EIGEN_DECLARE_CONST_Packet4d(cephes_LOG2EF, 1.4426950408889634073599);

	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p0, 1.26177193074810590878e-4);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p1, 3.02994407707441961300e-2);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_p2, 9.99999999999999999910e-1);

	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q0, 3.00198505138664455042e-6);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q1, 2.52448340349684104192e-3);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q2, 2.27265548208155028766e-1);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_q3, 2.00000000000000000009e0);

	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_C1, 0.693145751953125);
	_EIGEN_DECLARE_CONST_Packet4d(cephes_exp_C2, 1.42860682030941723212e-6);
	_EIGEN_DECLARE_CONST_Packet4i(1023, 1023);

	Packet4d tmp, fx;

	// clamp x
	x = pmax(pmin(x, p4d_exp_hi), p4d_exp_lo);
	// Express exp(x) as exp(g + n*log(2)).
	fx = pmadd(p4d_cephes_LOG2EF, x, p4d_half);

	// Get the integer modulus of log(2), i.e. the "n" described above.
	fx = _mm256_floor_pd(fx);

	// Get the remainder modulo log(2), i.e. the "g" described above. Subtract
	// nlog(2) out in two steps, i.e. nC1 + n*C2, C1+C2=log2 to get the last
	// digits right.
	tmp = pmul(fx, p4d_cephes_exp_C1);
	Packet4d z = pmul(fx, p4d_cephes_exp_C2);
	x = psub(x, tmp);
	x = psub(x, z);

	Packet4d x2 = pmul(x, x);

	// Evaluate the numerator polynomial of the rational interpolant.
	Packet4d px = p4d_cephes_exp_p0;
	px = pmadd(px, x2, p4d_cephes_exp_p1);
	px = pmadd(px, x2, p4d_cephes_exp_p2);
	px = pmul(px, x);

	// Evaluate the denominator polynomial of the rational interpolant.
	Packet4d qx = p4d_cephes_exp_q0;
	qx = pmadd(qx, x2, p4d_cephes_exp_q1);
	qx = pmadd(qx, x2, p4d_cephes_exp_q2);
	qx = pmadd(qx, x2, p4d_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 = _mm256_div_pd(px, psub(qx, px));
	x = pmadd(p4d_2, x, p4d_1);

	// Build e=2^n by constructing the exponents in a 128-bit vector and
	// shifting them to where they belong in double-precision values.
	__m128i emm0 = _mm256_cvtpd_epi32(fx);
	emm0 = _mm_add_epi32(emm0, p4i_1023);
	emm0 = _mm_shuffle_epi32(emm0, _MM_SHUFFLE(3, 1, 2, 0));
	__m128i lo = _mm_slli_epi64(emm0, 52);
	__m128i hi = _mm_slli_epi64(_mm_srli_epi64(emm0, 32), 52);
	__m256i e = _mm256_insertf128_si256(_mm256_setzero_si256(), lo, 0);
	e = _mm256_insertf128_si256(e, hi, 1);

	// Construct the result 2^n * exp(g) = e * x. The max is used to catch
	// non-finite values in the input.
	return pmax(pmul(x, _mm256_castsi256_pd(e)), _x);
	}

	// Functions for sqrt.
	// The EIGEN_FAST_MATH version uses the _mm_rsqrt_ps approximation and one step
	// of Newton's method, at a cost of 1-2 bits of precision as opposed to the
	// exact solution. It does not handle +inf, or denormalized numbers correctly.
	// The main advantage of this approach is not just speed, but also the fact that
	// it can be inlined and pipelined with other computations, further reducing its
	// effective latency. This is similar to Quake3's fast inverse square root.
	// For detail see here: http://www.beyond3d.com/content/articles/8/
	#if EIGEN_FAST_MATH
	template <>
	EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED Packet8f
	psqrt<Packet8f>(const Packet8f& _x) {
	Packet8f half = pmul(_x, pset1<Packet8f>(.5f));
	Packet8f denormal_mask = _mm256_and_ps(
	_mm256_cmp_ps(_x, pset1<Packet8f>((std::numeric_limits<float>::min)()),
	_CMP_LT_OQ),
	_mm256_cmp_ps(_x, _mm256_setzero_ps(), _CMP_GE_OQ));

	// Compute approximate reciprocal sqrt.
	Packet8f x = _mm256_rsqrt_ps(_x);
	// Do a single step of Newton's iteration.
	x = pmul(x, psub(pset1<Packet8f>(1.5f), pmul(half, pmul(x,x))));
	// Flush results for denormals to zero.
	return _mm256_andnot_ps(denormal_mask, pmul(_x,x));
	}
	#else
	template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
	Packet8f psqrt<Packet8f>(const Packet8f& x) {
	return _mm256_sqrt_ps(x);
	}
	#endif
	template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
	Packet4d psqrt<Packet4d>(const Packet4d& x) {
	return _mm256_sqrt_pd(x);
	}
	#if EIGEN_FAST_MATH

	template<> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
	Packet8f prsqrt<Packet8f>(const Packet8f& _x) {
	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(inf, 0x7f800000);
	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(nan, 0x7fc00000);
	_EIGEN_DECLARE_CONST_Packet8f(one_point_five, 1.5f);
	_EIGEN_DECLARE_CONST_Packet8f(minus_half, -0.5f);
	_EIGEN_DECLARE_CONST_Packet8f_FROM_INT(flt_min, 0x00800000);

	Packet8f neg_half = pmul(_x, p8f_minus_half);

	// select only the inverse sqrt of positive normal inputs (denormals are
	// flushed to zero and cause infs as well).
	Packet8f le_zero_mask = _mm256_cmp_ps(_x, p8f_flt_min, _CMP_LT_OQ);
	Packet8f x = _mm256_andnot_ps(le_zero_mask, _mm256_rsqrt_ps(_x));

	// Fill in NaNs and Infs for the negative/zero entries.
	Packet8f neg_mask = _mm256_cmp_ps(_x, _mm256_setzero_ps(), _CMP_LT_OQ);
	Packet8f zero_mask = _mm256_andnot_ps(neg_mask, le_zero_mask);
	Packet8f infs_and_nans = _mm256_or_ps(_mm256_and_ps(neg_mask, p8f_nan),
	_mm256_and_ps(zero_mask, p8f_inf));

	// Do a single step of Newton's iteration.
	x = pmul(x, pmadd(neg_half, pmul(x, x), p8f_one_point_five));

	// Insert NaNs and Infs in all the right places.
	return _mm256_or_ps(x, infs_and_nans);
	}

	#else
	template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
	Packet8f prsqrt<Packet8f>(const Packet8f& x) {
	_EIGEN_DECLARE_CONST_Packet8f(one, 1.0f);
	return _mm256_div_ps(p8f_one, _mm256_sqrt_ps(x));
	}
	#endif

	template <> EIGEN_DEFINE_FUNCTION_ALLOWING_MULTIPLE_DEFINITIONS EIGEN_UNUSED
	Packet4d prsqrt<Packet4d>(const Packet4d& x) {
	_EIGEN_DECLARE_CONST_Packet4d(one, 1.0);
	return _mm256_div_pd(p4d_one, _mm256_sqrt_pd(x));
	}


	} // end namespace internal

	} // end namespace Eigen

	#endif // EIGEN_MATH_FUNCTIONS_AVX_H