/*
* This file is part of the GROMACS molecular simulation package.
*
- * Copyright (c) 2012,2013, by the GROMACS development team, led by
+ * Copyright (c) 2012,2013,2014, by the GROMACS development team, led by
* Mark Abraham, David van der Spoel, Berk Hess, and Erik Lindahl,
* and including many others, as listed in the AUTHORS file in the
* top-level source directory and at http://www.gromacs.org.
#ifndef GMX_SIMD_MATH_SSE2_DOUBLE_H
#define GMX_SIMD_MATH_SSE2_DOUBLE_H
+#include "gromacs/simd/simd_math.h"
-#include <stdio.h>
-#include <math.h>
-
-#include "general_x86_sse2.h"
-
-
-#ifndef M_PI
-# define M_PI 3.14159265358979323846264338327950288
-#endif
-
-
-
-/************************
- * *
- * Simple math routines *
- * *
- ************************/
-
-/* 1.0/sqrt(x) */
-static gmx_inline __m128d
-gmx_mm_invsqrt_pd(__m128d x)
-{
- const __m128d half = _mm_set1_pd(0.5);
- const __m128d three = _mm_set1_pd(3.0);
-
- /* Lookup instruction only exists in single precision, convert back and forth... */
- __m128d lu = _mm_cvtps_pd(_mm_rsqrt_ps( _mm_cvtpd_ps(x)));
-
- lu = _mm_mul_pd(half, _mm_mul_pd(_mm_sub_pd(three, _mm_mul_pd(_mm_mul_pd(lu, lu), x)), lu));
- return _mm_mul_pd(half, _mm_mul_pd(_mm_sub_pd(three, _mm_mul_pd(_mm_mul_pd(lu, lu), x)), lu));
-}
-
-/* 1.0/sqrt(x), done for a pair of arguments to improve throughput */
-static void
-gmx_mm_invsqrt_pair_pd(__m128d x1, __m128d x2, __m128d *invsqrt1, __m128d *invsqrt2)
-{
- const __m128d half = _mm_set1_pd(0.5);
- const __m128d three = _mm_set1_pd(3.0);
- const __m128 halff = _mm_set1_ps(0.5f);
- const __m128 threef = _mm_set1_ps(3.0f);
-
- __m128 xf, luf;
- __m128d lu1, lu2;
-
- /* Do first N-R step in float for 2x throughput */
- xf = _mm_shuffle_ps(_mm_cvtpd_ps(x1), _mm_cvtpd_ps(x2), _MM_SHUFFLE(1, 0, 1, 0));
- luf = _mm_rsqrt_ps(xf);
- luf = _mm_mul_ps(halff, _mm_mul_ps(_mm_sub_ps(threef, _mm_mul_ps(_mm_mul_ps(luf, luf), xf)), luf));
-
- lu2 = _mm_cvtps_pd(_mm_shuffle_ps(luf, luf, _MM_SHUFFLE(3, 2, 3, 2)));
- lu1 = _mm_cvtps_pd(luf);
-
- *invsqrt1 = _mm_mul_pd(half, _mm_mul_pd(_mm_sub_pd(three, _mm_mul_pd(_mm_mul_pd(lu1, lu1), x1)), lu1));
- *invsqrt2 = _mm_mul_pd(half, _mm_mul_pd(_mm_sub_pd(three, _mm_mul_pd(_mm_mul_pd(lu2, lu2), x2)), lu2));
-}
-
-
-/* sqrt(x) - Do NOT use this (but rather invsqrt) if you actually need 1.0/sqrt(x) */
-static gmx_inline __m128d
-gmx_mm_sqrt_pd(__m128d x)
-{
- __m128d mask;
- __m128d res;
-
- mask = _mm_cmpeq_pd(x, _mm_setzero_pd());
- res = _mm_andnot_pd(mask, gmx_mm_invsqrt_pd(x));
-
- res = _mm_mul_pd(x, res);
-
- return res;
-}
-
-/* 1.0/x */
-static gmx_inline __m128d
-gmx_mm_inv_pd(__m128d x)
-{
- const __m128d two = _mm_set1_pd(2.0);
-
- /* Lookup instruction only exists in single precision, convert back and forth... */
- __m128d lu = _mm_cvtps_pd(_mm_rcp_ps( _mm_cvtpd_ps(x)));
-
- /* Perform two N-R steps for double precision */
- lu = _mm_mul_pd(lu, _mm_sub_pd(two, _mm_mul_pd(x, lu)));
- return _mm_mul_pd(lu, _mm_sub_pd(two, _mm_mul_pd(x, lu)));
-}
-
-static gmx_inline __m128d
-gmx_mm_abs_pd(__m128d x)
-{
- const __m128d signmask = gmx_mm_castsi128_pd( _mm_set_epi32(0x7FFFFFFF, 0xFFFFFFFF, 0x7FFFFFFF, 0xFFFFFFFF) );
-
- return _mm_and_pd(x, signmask);
-}
-
-
-/*
- * 2^x function.
- *
- * The 2^w term is calculated from a (6,0)-th order (no denominator) Minimax polynomia on the interval
- * [-0.5,0.5].
- *
- * The approximation on [-0.5,0.5] is a rational Padé approximation, 1+2*P(x^2)/(Q(x^2)-P(x^2)),
- * according to the same algorithm as used in the Cephes/netlib math routines.
- */
-static __m128d
-gmx_mm_exp2_pd(__m128d x)
-{
- /* Lower bound: We do not allow numbers that would lead to an IEEE fp representation exponent smaller than -126. */
- const __m128d arglimit = _mm_set1_pd(1022.0);
- const __m128i expbase = _mm_set1_epi32(1023);
-
- const __m128d P2 = _mm_set1_pd(2.30933477057345225087e-2);
- const __m128d P1 = _mm_set1_pd(2.02020656693165307700e1);
- const __m128d P0 = _mm_set1_pd(1.51390680115615096133e3);
- /* Q2 == 1.0 */
- const __m128d Q1 = _mm_set1_pd(2.33184211722314911771e2);
- const __m128d Q0 = _mm_set1_pd(4.36821166879210612817e3);
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d two = _mm_set1_pd(2.0);
-
- __m128d valuemask;
- __m128i iexppart;
- __m128d fexppart;
- __m128d intpart;
- __m128d z, z2;
- __m128d PolyP, PolyQ;
-
- iexppart = _mm_cvtpd_epi32(x);
- intpart = _mm_cvtepi32_pd(iexppart);
-
- /* The two lowest elements of iexppart now contains 32-bit numbers with a correctly biased exponent.
- * To be able to shift it into the exponent for a double precision number we first need to
- * shuffle so that the lower half contains the first element, and the upper half the second.
- * This should really be done as a zero-extension, but since the next instructions will shift
- * the registers left by 52 bits it doesn't matter what we put there - it will be shifted out.
- * (thus we just use element 2 from iexppart).
- */
- iexppart = _mm_shuffle_epi32(iexppart, _MM_SHUFFLE(2, 1, 2, 0));
-
- /* Do the shift operation on the 64-bit registers */
- iexppart = _mm_add_epi32(iexppart, expbase);
- iexppart = _mm_slli_epi64(iexppart, 52);
-
- valuemask = _mm_cmpge_pd(arglimit, gmx_mm_abs_pd(x));
- fexppart = _mm_and_pd(valuemask, gmx_mm_castsi128_pd(iexppart));
-
- z = _mm_sub_pd(x, intpart);
- z2 = _mm_mul_pd(z, z);
-
- PolyP = _mm_mul_pd(P2, z2);
- PolyP = _mm_add_pd(PolyP, P1);
- PolyQ = _mm_add_pd(z2, Q1);
- PolyP = _mm_mul_pd(PolyP, z2);
- PolyQ = _mm_mul_pd(PolyQ, z2);
- PolyP = _mm_add_pd(PolyP, P0);
- PolyQ = _mm_add_pd(PolyQ, Q0);
- PolyP = _mm_mul_pd(PolyP, z);
-
- z = _mm_mul_pd(PolyP, gmx_mm_inv_pd(_mm_sub_pd(PolyQ, PolyP)));
- z = _mm_add_pd(one, _mm_mul_pd(two, z));
-
- z = _mm_mul_pd(z, fexppart);
-
- return z;
-}
-
-/* Exponential function. This could be calculated from 2^x as Exp(x)=2^(y), where y=log2(e)*x,
- * but there will then be a small rounding error since we lose some precision due to the
- * multiplication. This will then be magnified a lot by the exponential.
- *
- * Instead, we calculate the fractional part directly as a Padé approximation of
- * Exp(z) on [-0.5,0.5]. We use extended precision arithmetics to calculate the fraction
- * remaining after 2^y, which avoids the precision-loss.
- */
-static __m128d
-gmx_mm_exp_pd(__m128d exparg)
-{
- const __m128d argscale = _mm_set1_pd(1.4426950408889634073599);
- /* Lower bound: We do not allow numbers that would lead to an IEEE fp representation exponent smaller than -126. */
- const __m128d arglimit = _mm_set1_pd(1022.0);
- const __m128i expbase = _mm_set1_epi32(1023);
-
- const __m128d invargscale0 = _mm_set1_pd(6.93145751953125e-1);
- const __m128d invargscale1 = _mm_set1_pd(1.42860682030941723212e-6);
-
- const __m128d P2 = _mm_set1_pd(1.26177193074810590878e-4);
- const __m128d P1 = _mm_set1_pd(3.02994407707441961300e-2);
- /* P0 == 1.0 */
- const __m128d Q3 = _mm_set1_pd(3.00198505138664455042E-6);
- const __m128d Q2 = _mm_set1_pd(2.52448340349684104192E-3);
- const __m128d Q1 = _mm_set1_pd(2.27265548208155028766E-1);
- /* Q0 == 2.0 */
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d two = _mm_set1_pd(2.0);
-
- __m128d valuemask;
- __m128i iexppart;
- __m128d fexppart;
- __m128d intpart;
- __m128d x, z, z2;
- __m128d PolyP, PolyQ;
-
- x = _mm_mul_pd(exparg, argscale);
-
- iexppart = _mm_cvtpd_epi32(x);
- intpart = _mm_cvtepi32_pd(iexppart);
-
- /* The two lowest elements of iexppart now contains 32-bit numbers with a correctly biased exponent.
- * To be able to shift it into the exponent for a double precision number we first need to
- * shuffle so that the lower half contains the first element, and the upper half the second.
- * This should really be done as a zero-extension, but since the next instructions will shift
- * the registers left by 52 bits it doesn't matter what we put there - it will be shifted out.
- * (thus we just use element 2 from iexppart).
- */
- iexppart = _mm_shuffle_epi32(iexppart, _MM_SHUFFLE(2, 1, 2, 0));
-
- /* Do the shift operation on the 64-bit registers */
- iexppart = _mm_add_epi32(iexppart, expbase);
- iexppart = _mm_slli_epi64(iexppart, 52);
-
- valuemask = _mm_cmpge_pd(arglimit, gmx_mm_abs_pd(x));
- fexppart = _mm_and_pd(valuemask, gmx_mm_castsi128_pd(iexppart));
-
- z = _mm_sub_pd(exparg, _mm_mul_pd(invargscale0, intpart));
- z = _mm_sub_pd(z, _mm_mul_pd(invargscale1, intpart));
-
- z2 = _mm_mul_pd(z, z);
-
- PolyQ = _mm_mul_pd(Q3, z2);
- PolyQ = _mm_add_pd(PolyQ, Q2);
- PolyP = _mm_mul_pd(P2, z2);
- PolyQ = _mm_mul_pd(PolyQ, z2);
- PolyP = _mm_add_pd(PolyP, P1);
- PolyQ = _mm_add_pd(PolyQ, Q1);
- PolyP = _mm_mul_pd(PolyP, z2);
- PolyQ = _mm_mul_pd(PolyQ, z2);
- PolyP = _mm_add_pd(PolyP, one);
- PolyQ = _mm_add_pd(PolyQ, two);
-
- PolyP = _mm_mul_pd(PolyP, z);
-
- z = _mm_mul_pd(PolyP, gmx_mm_inv_pd(_mm_sub_pd(PolyQ, PolyP)));
- z = _mm_add_pd(one, _mm_mul_pd(two, z));
-
- z = _mm_mul_pd(z, fexppart);
-
- return z;
-}
-
-
-
-static __m128d
-gmx_mm_log_pd(__m128d x)
-{
- /* Same algorithm as cephes library */
- const __m128d expmask = gmx_mm_castsi128_pd( _mm_set_epi32(0x7FF00000, 0x00000000, 0x7FF00000, 0x00000000) );
-
- const __m128i expbase_m1 = _mm_set1_epi32(1023-1); /* We want non-IEEE format */
-
- const __m128d half = _mm_set1_pd(0.5);
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d two = _mm_set1_pd(2.0);
- const __m128d invsq2 = _mm_set1_pd(1.0/sqrt(2.0));
-
- const __m128d corr1 = _mm_set1_pd(-2.121944400546905827679e-4);
- const __m128d corr2 = _mm_set1_pd(0.693359375);
-
- const __m128d P5 = _mm_set1_pd(1.01875663804580931796e-4);
- const __m128d P4 = _mm_set1_pd(4.97494994976747001425e-1);
- const __m128d P3 = _mm_set1_pd(4.70579119878881725854e0);
- const __m128d P2 = _mm_set1_pd(1.44989225341610930846e1);
- const __m128d P1 = _mm_set1_pd(1.79368678507819816313e1);
- const __m128d P0 = _mm_set1_pd(7.70838733755885391666e0);
-
- const __m128d Q4 = _mm_set1_pd(1.12873587189167450590e1);
- const __m128d Q3 = _mm_set1_pd(4.52279145837532221105e1);
- const __m128d Q2 = _mm_set1_pd(8.29875266912776603211e1);
- const __m128d Q1 = _mm_set1_pd(7.11544750618563894466e1);
- const __m128d Q0 = _mm_set1_pd(2.31251620126765340583e1);
-
- const __m128d R2 = _mm_set1_pd(-7.89580278884799154124e-1);
- const __m128d R1 = _mm_set1_pd(1.63866645699558079767e1);
- const __m128d R0 = _mm_set1_pd(-6.41409952958715622951e1);
-
- const __m128d S2 = _mm_set1_pd(-3.56722798256324312549E1);
- const __m128d S1 = _mm_set1_pd(3.12093766372244180303E2);
- const __m128d S0 = _mm_set1_pd(-7.69691943550460008604E2);
-
- __m128d fexp;
- __m128i iexp;
-
- __m128d mask1, mask2;
- __m128d corr, t1, t2, q;
- __m128d zA, yA, xA, zB, yB, xB, z;
- __m128d polyR, polyS;
- __m128d polyP1, polyP2, polyQ1, polyQ2;
-
- /* Separate x into exponent and mantissa, with a mantissa in the range [0.5..1[ (not IEEE754 standard!) */
- fexp = _mm_and_pd(x, expmask);
- iexp = gmx_mm_castpd_si128(fexp);
- iexp = _mm_srli_epi64(iexp, 52);
- iexp = _mm_sub_epi32(iexp, expbase_m1);
- iexp = _mm_shuffle_epi32(iexp, _MM_SHUFFLE(1, 1, 2, 0) );
- fexp = _mm_cvtepi32_pd(iexp);
-
- x = _mm_andnot_pd(expmask, x);
- x = _mm_or_pd(x, one);
- x = _mm_mul_pd(x, half);
-
- mask1 = _mm_cmpgt_pd(gmx_mm_abs_pd(fexp), two);
- mask2 = _mm_cmplt_pd(x, invsq2);
-
- fexp = _mm_sub_pd(fexp, _mm_and_pd(mask2, one));
-
- /* If mask1 is set ('A') */
- zA = _mm_sub_pd(x, half);
- t1 = _mm_or_pd( _mm_andnot_pd(mask2, zA), _mm_and_pd(mask2, x) );
- zA = _mm_sub_pd(t1, half);
- t2 = _mm_or_pd( _mm_andnot_pd(mask2, x), _mm_and_pd(mask2, zA) );
- yA = _mm_mul_pd(half, _mm_add_pd(t2, one));
-
- xA = _mm_mul_pd(zA, gmx_mm_inv_pd(yA));
- zA = _mm_mul_pd(xA, xA);
-
- /* EVALUATE POLY */
- polyR = _mm_mul_pd(R2, zA);
- polyR = _mm_add_pd(polyR, R1);
- polyR = _mm_mul_pd(polyR, zA);
- polyR = _mm_add_pd(polyR, R0);
-
- polyS = _mm_add_pd(zA, S2);
- polyS = _mm_mul_pd(polyS, zA);
- polyS = _mm_add_pd(polyS, S1);
- polyS = _mm_mul_pd(polyS, zA);
- polyS = _mm_add_pd(polyS, S0);
-
- q = _mm_mul_pd(polyR, gmx_mm_inv_pd(polyS));
- zA = _mm_mul_pd(_mm_mul_pd(xA, zA), q);
-
- zA = _mm_add_pd(zA, _mm_mul_pd(corr1, fexp));
- zA = _mm_add_pd(zA, xA);
- zA = _mm_add_pd(zA, _mm_mul_pd(corr2, fexp));
-
- /* If mask1 is not set ('B') */
- corr = _mm_and_pd(mask2, x);
- xB = _mm_add_pd(x, corr);
- xB = _mm_sub_pd(xB, one);
- zB = _mm_mul_pd(xB, xB);
-
- polyP1 = _mm_mul_pd(P5, zB);
- polyP2 = _mm_mul_pd(P4, zB);
- polyP1 = _mm_add_pd(polyP1, P3);
- polyP2 = _mm_add_pd(polyP2, P2);
- polyP1 = _mm_mul_pd(polyP1, zB);
- polyP2 = _mm_mul_pd(polyP2, zB);
- polyP1 = _mm_add_pd(polyP1, P1);
- polyP2 = _mm_add_pd(polyP2, P0);
- polyP1 = _mm_mul_pd(polyP1, xB);
- polyP1 = _mm_add_pd(polyP1, polyP2);
-
- polyQ2 = _mm_mul_pd(Q4, zB);
- polyQ1 = _mm_add_pd(zB, Q3);
- polyQ2 = _mm_add_pd(polyQ2, Q2);
- polyQ1 = _mm_mul_pd(polyQ1, zB);
- polyQ2 = _mm_mul_pd(polyQ2, zB);
- polyQ1 = _mm_add_pd(polyQ1, Q1);
- polyQ2 = _mm_add_pd(polyQ2, Q0);
- polyQ1 = _mm_mul_pd(polyQ1, xB);
- polyQ1 = _mm_add_pd(polyQ1, polyQ2);
-
- fexp = _mm_and_pd(fexp, _mm_cmpneq_pd(fexp, _mm_setzero_pd()));
-
- q = _mm_mul_pd(polyP1, gmx_mm_inv_pd(polyQ1));
- yB = _mm_mul_pd(_mm_mul_pd(xB, zB), q);
-
- yB = _mm_add_pd(yB, _mm_mul_pd(corr1, fexp));
- yB = _mm_sub_pd(yB, _mm_mul_pd(half, zB));
- zB = _mm_add_pd(xB, yB);
- zB = _mm_add_pd(zB, _mm_mul_pd(corr2, fexp));
-
- z = _mm_or_pd( _mm_andnot_pd(mask1, zB), _mm_and_pd(mask1, zA) );
-
- return z;
-}
-
-
-
-static __m128d
-gmx_mm_erf_pd(__m128d x)
-{
- /* Coefficients for minimax approximation of erf(x)=x*(CAoffset + P(x^2)/Q(x^2)) in range [-0.75,0.75] */
- const __m128d CAP4 = _mm_set1_pd(-0.431780540597889301512e-4);
- const __m128d CAP3 = _mm_set1_pd(-0.00578562306260059236059);
- const __m128d CAP2 = _mm_set1_pd(-0.028593586920219752446);
- const __m128d CAP1 = _mm_set1_pd(-0.315924962948621698209);
- const __m128d CAP0 = _mm_set1_pd(0.14952975608477029151);
-
- const __m128d CAQ5 = _mm_set1_pd(-0.374089300177174709737e-5);
- const __m128d CAQ4 = _mm_set1_pd(0.00015126584532155383535);
- const __m128d CAQ3 = _mm_set1_pd(0.00536692680669480725423);
- const __m128d CAQ2 = _mm_set1_pd(0.0668686825594046122636);
- const __m128d CAQ1 = _mm_set1_pd(0.402604990869284362773);
- /* CAQ0 == 1.0 */
- const __m128d CAoffset = _mm_set1_pd(0.9788494110107421875);
-
- /* Coefficients for minimax approximation of erfc(x)=exp(-x^2)*x*(P(x-1)/Q(x-1)) in range [1.0,4.5] */
- const __m128d CBP6 = _mm_set1_pd(2.49650423685462752497647637088e-10);
- const __m128d CBP5 = _mm_set1_pd(0.00119770193298159629350136085658);
- const __m128d CBP4 = _mm_set1_pd(0.0164944422378370965881008942733);
- const __m128d CBP3 = _mm_set1_pd(0.0984581468691775932063932439252);
- const __m128d CBP2 = _mm_set1_pd(0.317364595806937763843589437418);
- const __m128d CBP1 = _mm_set1_pd(0.554167062641455850932670067075);
- const __m128d CBP0 = _mm_set1_pd(0.427583576155807163756925301060);
- const __m128d CBQ7 = _mm_set1_pd(0.00212288829699830145976198384930);
- const __m128d CBQ6 = _mm_set1_pd(0.0334810979522685300554606393425);
- const __m128d CBQ5 = _mm_set1_pd(0.2361713785181450957579508850717);
- const __m128d CBQ4 = _mm_set1_pd(0.955364736493055670530981883072);
- const __m128d CBQ3 = _mm_set1_pd(2.36815675631420037315349279199);
- const __m128d CBQ2 = _mm_set1_pd(3.55261649184083035537184223542);
- const __m128d CBQ1 = _mm_set1_pd(2.93501136050160872574376997993);
- /* CBQ0 == 1.0 */
-
- /* Coefficients for minimax approximation of erfc(x)=exp(-x^2)/x*(P(1/x)/Q(1/x)) in range [4.5,inf] */
- const __m128d CCP6 = _mm_set1_pd(-2.8175401114513378771);
- const __m128d CCP5 = _mm_set1_pd(-3.22729451764143718517);
- const __m128d CCP4 = _mm_set1_pd(-2.5518551727311523996);
- const __m128d CCP3 = _mm_set1_pd(-0.687717681153649930619);
- const __m128d CCP2 = _mm_set1_pd(-0.212652252872804219852);
- const __m128d CCP1 = _mm_set1_pd(0.0175389834052493308818);
- const __m128d CCP0 = _mm_set1_pd(0.00628057170626964891937);
-
- const __m128d CCQ6 = _mm_set1_pd(5.48409182238641741584);
- const __m128d CCQ5 = _mm_set1_pd(13.5064170191802889145);
- const __m128d CCQ4 = _mm_set1_pd(22.9367376522880577224);
- const __m128d CCQ3 = _mm_set1_pd(15.930646027911794143);
- const __m128d CCQ2 = _mm_set1_pd(11.0567237927800161565);
- const __m128d CCQ1 = _mm_set1_pd(2.79257750980575282228);
- /* CCQ0 == 1.0 */
- const __m128d CCoffset = _mm_set1_pd(0.5579090118408203125);
-
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d two = _mm_set1_pd(2.0);
-
- const __m128d signbit = gmx_mm_castsi128_pd( _mm_set_epi32(0x80000000, 0x00000000, 0x80000000, 0x00000000) );
-
- __m128d xabs, x2, x4, t, t2, w, w2;
- __m128d PolyAP0, PolyAP1, PolyAQ0, PolyAQ1;
- __m128d PolyBP0, PolyBP1, PolyBQ0, PolyBQ1;
- __m128d PolyCP0, PolyCP1, PolyCQ0, PolyCQ1;
- __m128d res_erf, res_erfcB, res_erfcC, res_erfc, res;
- __m128d mask, expmx2;
-
- /* Calculate erf() */
- xabs = gmx_mm_abs_pd(x);
- x2 = _mm_mul_pd(x, x);
- x4 = _mm_mul_pd(x2, x2);
-
- PolyAP0 = _mm_mul_pd(CAP4, x4);
- PolyAP1 = _mm_mul_pd(CAP3, x4);
- PolyAP0 = _mm_add_pd(PolyAP0, CAP2);
- PolyAP1 = _mm_add_pd(PolyAP1, CAP1);
- PolyAP0 = _mm_mul_pd(PolyAP0, x4);
- PolyAP1 = _mm_mul_pd(PolyAP1, x2);
- PolyAP0 = _mm_add_pd(PolyAP0, CAP0);
- PolyAP0 = _mm_add_pd(PolyAP0, PolyAP1);
-
- PolyAQ1 = _mm_mul_pd(CAQ5, x4);
- PolyAQ0 = _mm_mul_pd(CAQ4, x4);
- PolyAQ1 = _mm_add_pd(PolyAQ1, CAQ3);
- PolyAQ0 = _mm_add_pd(PolyAQ0, CAQ2);
- PolyAQ1 = _mm_mul_pd(PolyAQ1, x4);
- PolyAQ0 = _mm_mul_pd(PolyAQ0, x4);
- PolyAQ1 = _mm_add_pd(PolyAQ1, CAQ1);
- PolyAQ0 = _mm_add_pd(PolyAQ0, one);
- PolyAQ1 = _mm_mul_pd(PolyAQ1, x2);
- PolyAQ0 = _mm_add_pd(PolyAQ0, PolyAQ1);
-
- res_erf = _mm_mul_pd(PolyAP0, gmx_mm_inv_pd(PolyAQ0));
- res_erf = _mm_add_pd(CAoffset, res_erf);
- res_erf = _mm_mul_pd(x, res_erf);
-
- /* Calculate erfc() in range [1,4.5] */
- t = _mm_sub_pd(xabs, one);
- t2 = _mm_mul_pd(t, t);
-
- PolyBP0 = _mm_mul_pd(CBP6, t2);
- PolyBP1 = _mm_mul_pd(CBP5, t2);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP4);
- PolyBP1 = _mm_add_pd(PolyBP1, CBP3);
- PolyBP0 = _mm_mul_pd(PolyBP0, t2);
- PolyBP1 = _mm_mul_pd(PolyBP1, t2);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP2);
- PolyBP1 = _mm_add_pd(PolyBP1, CBP1);
- PolyBP0 = _mm_mul_pd(PolyBP0, t2);
- PolyBP1 = _mm_mul_pd(PolyBP1, t);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP0);
- PolyBP0 = _mm_add_pd(PolyBP0, PolyBP1);
-
- PolyBQ1 = _mm_mul_pd(CBQ7, t2);
- PolyBQ0 = _mm_mul_pd(CBQ6, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ5);
- PolyBQ0 = _mm_add_pd(PolyBQ0, CBQ4);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t2);
- PolyBQ0 = _mm_mul_pd(PolyBQ0, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ3);
- PolyBQ0 = _mm_add_pd(PolyBQ0, CBQ2);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t2);
- PolyBQ0 = _mm_mul_pd(PolyBQ0, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ1);
- PolyBQ0 = _mm_add_pd(PolyBQ0, one);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t);
- PolyBQ0 = _mm_add_pd(PolyBQ0, PolyBQ1);
-
- res_erfcB = _mm_mul_pd(PolyBP0, gmx_mm_inv_pd(PolyBQ0));
-
- res_erfcB = _mm_mul_pd(res_erfcB, xabs);
-
- /* Calculate erfc() in range [4.5,inf] */
- w = gmx_mm_inv_pd(xabs);
- w2 = _mm_mul_pd(w, w);
-
- PolyCP0 = _mm_mul_pd(CCP6, w2);
- PolyCP1 = _mm_mul_pd(CCP5, w2);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP4);
- PolyCP1 = _mm_add_pd(PolyCP1, CCP3);
- PolyCP0 = _mm_mul_pd(PolyCP0, w2);
- PolyCP1 = _mm_mul_pd(PolyCP1, w2);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP2);
- PolyCP1 = _mm_add_pd(PolyCP1, CCP1);
- PolyCP0 = _mm_mul_pd(PolyCP0, w2);
- PolyCP1 = _mm_mul_pd(PolyCP1, w);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP0);
- PolyCP0 = _mm_add_pd(PolyCP0, PolyCP1);
-
- PolyCQ0 = _mm_mul_pd(CCQ6, w2);
- PolyCQ1 = _mm_mul_pd(CCQ5, w2);
- PolyCQ0 = _mm_add_pd(PolyCQ0, CCQ4);
- PolyCQ1 = _mm_add_pd(PolyCQ1, CCQ3);
- PolyCQ0 = _mm_mul_pd(PolyCQ0, w2);
- PolyCQ1 = _mm_mul_pd(PolyCQ1, w2);
- PolyCQ0 = _mm_add_pd(PolyCQ0, CCQ2);
- PolyCQ1 = _mm_add_pd(PolyCQ1, CCQ1);
- PolyCQ0 = _mm_mul_pd(PolyCQ0, w2);
- PolyCQ1 = _mm_mul_pd(PolyCQ1, w);
- PolyCQ0 = _mm_add_pd(PolyCQ0, one);
- PolyCQ0 = _mm_add_pd(PolyCQ0, PolyCQ1);
-
- expmx2 = gmx_mm_exp_pd( _mm_or_pd(signbit, x2) );
-
- res_erfcC = _mm_mul_pd(PolyCP0, gmx_mm_inv_pd(PolyCQ0));
- res_erfcC = _mm_add_pd(res_erfcC, CCoffset);
- res_erfcC = _mm_mul_pd(res_erfcC, w);
-
- mask = _mm_cmpgt_pd(xabs, _mm_set1_pd(4.5));
- res_erfc = _mm_or_pd(_mm_andnot_pd(mask, res_erfcB), _mm_and_pd(mask, res_erfcC));
-
- res_erfc = _mm_mul_pd(res_erfc, expmx2);
-
- /* erfc(x<0) = 2-erfc(|x|) */
- mask = _mm_cmplt_pd(x, _mm_setzero_pd());
- res_erfc = _mm_or_pd(_mm_andnot_pd(mask, res_erfc), _mm_and_pd(mask, _mm_sub_pd(two, res_erfc)));
-
- /* Select erf() or erfc() */
- mask = _mm_cmplt_pd(xabs, one);
- res = _mm_or_pd(_mm_andnot_pd(mask, _mm_sub_pd(one, res_erfc)), _mm_and_pd(mask, res_erf));
-
- return res;
-}
-
-
-static __m128d
-gmx_mm_erfc_pd(__m128d x)
-{
- /* Coefficients for minimax approximation of erf(x)=x*(CAoffset + P(x^2)/Q(x^2)) in range [-0.75,0.75] */
- const __m128d CAP4 = _mm_set1_pd(-0.431780540597889301512e-4);
- const __m128d CAP3 = _mm_set1_pd(-0.00578562306260059236059);
- const __m128d CAP2 = _mm_set1_pd(-0.028593586920219752446);
- const __m128d CAP1 = _mm_set1_pd(-0.315924962948621698209);
- const __m128d CAP0 = _mm_set1_pd(0.14952975608477029151);
-
- const __m128d CAQ5 = _mm_set1_pd(-0.374089300177174709737e-5);
- const __m128d CAQ4 = _mm_set1_pd(0.00015126584532155383535);
- const __m128d CAQ3 = _mm_set1_pd(0.00536692680669480725423);
- const __m128d CAQ2 = _mm_set1_pd(0.0668686825594046122636);
- const __m128d CAQ1 = _mm_set1_pd(0.402604990869284362773);
- /* CAQ0 == 1.0 */
- const __m128d CAoffset = _mm_set1_pd(0.9788494110107421875);
-
- /* Coefficients for minimax approximation of erfc(x)=exp(-x^2)*x*(P(x-1)/Q(x-1)) in range [1.0,4.5] */
- const __m128d CBP6 = _mm_set1_pd(2.49650423685462752497647637088e-10);
- const __m128d CBP5 = _mm_set1_pd(0.00119770193298159629350136085658);
- const __m128d CBP4 = _mm_set1_pd(0.0164944422378370965881008942733);
- const __m128d CBP3 = _mm_set1_pd(0.0984581468691775932063932439252);
- const __m128d CBP2 = _mm_set1_pd(0.317364595806937763843589437418);
- const __m128d CBP1 = _mm_set1_pd(0.554167062641455850932670067075);
- const __m128d CBP0 = _mm_set1_pd(0.427583576155807163756925301060);
- const __m128d CBQ7 = _mm_set1_pd(0.00212288829699830145976198384930);
- const __m128d CBQ6 = _mm_set1_pd(0.0334810979522685300554606393425);
- const __m128d CBQ5 = _mm_set1_pd(0.2361713785181450957579508850717);
- const __m128d CBQ4 = _mm_set1_pd(0.955364736493055670530981883072);
- const __m128d CBQ3 = _mm_set1_pd(2.36815675631420037315349279199);
- const __m128d CBQ2 = _mm_set1_pd(3.55261649184083035537184223542);
- const __m128d CBQ1 = _mm_set1_pd(2.93501136050160872574376997993);
- /* CBQ0 == 1.0 */
-
- /* Coefficients for minimax approximation of erfc(x)=exp(-x^2)/x*(P(1/x)/Q(1/x)) in range [4.5,inf] */
- const __m128d CCP6 = _mm_set1_pd(-2.8175401114513378771);
- const __m128d CCP5 = _mm_set1_pd(-3.22729451764143718517);
- const __m128d CCP4 = _mm_set1_pd(-2.5518551727311523996);
- const __m128d CCP3 = _mm_set1_pd(-0.687717681153649930619);
- const __m128d CCP2 = _mm_set1_pd(-0.212652252872804219852);
- const __m128d CCP1 = _mm_set1_pd(0.0175389834052493308818);
- const __m128d CCP0 = _mm_set1_pd(0.00628057170626964891937);
-
- const __m128d CCQ6 = _mm_set1_pd(5.48409182238641741584);
- const __m128d CCQ5 = _mm_set1_pd(13.5064170191802889145);
- const __m128d CCQ4 = _mm_set1_pd(22.9367376522880577224);
- const __m128d CCQ3 = _mm_set1_pd(15.930646027911794143);
- const __m128d CCQ2 = _mm_set1_pd(11.0567237927800161565);
- const __m128d CCQ1 = _mm_set1_pd(2.79257750980575282228);
- /* CCQ0 == 1.0 */
- const __m128d CCoffset = _mm_set1_pd(0.5579090118408203125);
-
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d two = _mm_set1_pd(2.0);
-
- const __m128d signbit = gmx_mm_castsi128_pd( _mm_set_epi32(0x80000000, 0x00000000, 0x80000000, 0x00000000) );
-
- __m128d xabs, x2, x4, t, t2, w, w2;
- __m128d PolyAP0, PolyAP1, PolyAQ0, PolyAQ1;
- __m128d PolyBP0, PolyBP1, PolyBQ0, PolyBQ1;
- __m128d PolyCP0, PolyCP1, PolyCQ0, PolyCQ1;
- __m128d res_erf, res_erfcB, res_erfcC, res_erfc, res;
- __m128d mask, expmx2;
-
- /* Calculate erf() */
- xabs = gmx_mm_abs_pd(x);
- x2 = _mm_mul_pd(x, x);
- x4 = _mm_mul_pd(x2, x2);
-
- PolyAP0 = _mm_mul_pd(CAP4, x4);
- PolyAP1 = _mm_mul_pd(CAP3, x4);
- PolyAP0 = _mm_add_pd(PolyAP0, CAP2);
- PolyAP1 = _mm_add_pd(PolyAP1, CAP1);
- PolyAP0 = _mm_mul_pd(PolyAP0, x4);
- PolyAP1 = _mm_mul_pd(PolyAP1, x2);
- PolyAP0 = _mm_add_pd(PolyAP0, CAP0);
- PolyAP0 = _mm_add_pd(PolyAP0, PolyAP1);
-
- PolyAQ1 = _mm_mul_pd(CAQ5, x4);
- PolyAQ0 = _mm_mul_pd(CAQ4, x4);
- PolyAQ1 = _mm_add_pd(PolyAQ1, CAQ3);
- PolyAQ0 = _mm_add_pd(PolyAQ0, CAQ2);
- PolyAQ1 = _mm_mul_pd(PolyAQ1, x4);
- PolyAQ0 = _mm_mul_pd(PolyAQ0, x4);
- PolyAQ1 = _mm_add_pd(PolyAQ1, CAQ1);
- PolyAQ0 = _mm_add_pd(PolyAQ0, one);
- PolyAQ1 = _mm_mul_pd(PolyAQ1, x2);
- PolyAQ0 = _mm_add_pd(PolyAQ0, PolyAQ1);
-
- res_erf = _mm_mul_pd(PolyAP0, gmx_mm_inv_pd(PolyAQ0));
- res_erf = _mm_add_pd(CAoffset, res_erf);
- res_erf = _mm_mul_pd(x, res_erf);
-
- /* Calculate erfc() in range [1,4.5] */
- t = _mm_sub_pd(xabs, one);
- t2 = _mm_mul_pd(t, t);
-
- PolyBP0 = _mm_mul_pd(CBP6, t2);
- PolyBP1 = _mm_mul_pd(CBP5, t2);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP4);
- PolyBP1 = _mm_add_pd(PolyBP1, CBP3);
- PolyBP0 = _mm_mul_pd(PolyBP0, t2);
- PolyBP1 = _mm_mul_pd(PolyBP1, t2);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP2);
- PolyBP1 = _mm_add_pd(PolyBP1, CBP1);
- PolyBP0 = _mm_mul_pd(PolyBP0, t2);
- PolyBP1 = _mm_mul_pd(PolyBP1, t);
- PolyBP0 = _mm_add_pd(PolyBP0, CBP0);
- PolyBP0 = _mm_add_pd(PolyBP0, PolyBP1);
-
- PolyBQ1 = _mm_mul_pd(CBQ7, t2);
- PolyBQ0 = _mm_mul_pd(CBQ6, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ5);
- PolyBQ0 = _mm_add_pd(PolyBQ0, CBQ4);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t2);
- PolyBQ0 = _mm_mul_pd(PolyBQ0, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ3);
- PolyBQ0 = _mm_add_pd(PolyBQ0, CBQ2);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t2);
- PolyBQ0 = _mm_mul_pd(PolyBQ0, t2);
- PolyBQ1 = _mm_add_pd(PolyBQ1, CBQ1);
- PolyBQ0 = _mm_add_pd(PolyBQ0, one);
- PolyBQ1 = _mm_mul_pd(PolyBQ1, t);
- PolyBQ0 = _mm_add_pd(PolyBQ0, PolyBQ1);
-
- res_erfcB = _mm_mul_pd(PolyBP0, gmx_mm_inv_pd(PolyBQ0));
-
- res_erfcB = _mm_mul_pd(res_erfcB, xabs);
-
- /* Calculate erfc() in range [4.5,inf] */
- w = gmx_mm_inv_pd(xabs);
- w2 = _mm_mul_pd(w, w);
-
- PolyCP0 = _mm_mul_pd(CCP6, w2);
- PolyCP1 = _mm_mul_pd(CCP5, w2);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP4);
- PolyCP1 = _mm_add_pd(PolyCP1, CCP3);
- PolyCP0 = _mm_mul_pd(PolyCP0, w2);
- PolyCP1 = _mm_mul_pd(PolyCP1, w2);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP2);
- PolyCP1 = _mm_add_pd(PolyCP1, CCP1);
- PolyCP0 = _mm_mul_pd(PolyCP0, w2);
- PolyCP1 = _mm_mul_pd(PolyCP1, w);
- PolyCP0 = _mm_add_pd(PolyCP0, CCP0);
- PolyCP0 = _mm_add_pd(PolyCP0, PolyCP1);
-
- PolyCQ0 = _mm_mul_pd(CCQ6, w2);
- PolyCQ1 = _mm_mul_pd(CCQ5, w2);
- PolyCQ0 = _mm_add_pd(PolyCQ0, CCQ4);
- PolyCQ1 = _mm_add_pd(PolyCQ1, CCQ3);
- PolyCQ0 = _mm_mul_pd(PolyCQ0, w2);
- PolyCQ1 = _mm_mul_pd(PolyCQ1, w2);
- PolyCQ0 = _mm_add_pd(PolyCQ0, CCQ2);
- PolyCQ1 = _mm_add_pd(PolyCQ1, CCQ1);
- PolyCQ0 = _mm_mul_pd(PolyCQ0, w2);
- PolyCQ1 = _mm_mul_pd(PolyCQ1, w);
- PolyCQ0 = _mm_add_pd(PolyCQ0, one);
- PolyCQ0 = _mm_add_pd(PolyCQ0, PolyCQ1);
-
- expmx2 = gmx_mm_exp_pd( _mm_or_pd(signbit, x2) );
-
- res_erfcC = _mm_mul_pd(PolyCP0, gmx_mm_inv_pd(PolyCQ0));
- res_erfcC = _mm_add_pd(res_erfcC, CCoffset);
- res_erfcC = _mm_mul_pd(res_erfcC, w);
-
- mask = _mm_cmpgt_pd(xabs, _mm_set1_pd(4.5));
- res_erfc = _mm_or_pd(_mm_andnot_pd(mask, res_erfcB), _mm_and_pd(mask, res_erfcC));
-
- res_erfc = _mm_mul_pd(res_erfc, expmx2);
-
- /* erfc(x<0) = 2-erfc(|x|) */
- mask = _mm_cmplt_pd(x, _mm_setzero_pd());
- res_erfc = _mm_or_pd(_mm_andnot_pd(mask, res_erfc), _mm_and_pd(mask, _mm_sub_pd(two, res_erfc)));
-
- /* Select erf() or erfc() */
- mask = _mm_cmplt_pd(xabs, one);
- res = _mm_or_pd(_mm_andnot_pd(mask, res_erfc), _mm_and_pd(mask, _mm_sub_pd(one, res_erf)));
-
- return res;
-}
-
-
-/* Calculate the force correction due to PME analytically.
- *
- * This routine is meant to enable analytical evaluation of the
- * direct-space PME electrostatic force to avoid tables.
- *
- * The direct-space potential should be Erfc(beta*r)/r, but there
- * are some problems evaluating that:
- *
- * First, the error function is difficult (read: expensive) to
- * approxmiate accurately for intermediate to large arguments, and
- * this happens already in ranges of beta*r that occur in simulations.
- * Second, we now try to avoid calculating potentials in Gromacs but
- * use forces directly.
- *
- * We can simply things slight by noting that the PME part is really
- * a correction to the normal Coulomb force since Erfc(z)=1-Erf(z), i.e.
- *
- * V= 1/r - Erf(beta*r)/r
- *
- * The first term we already have from the inverse square root, so
- * that we can leave out of this routine.
- *
- * For pme tolerances of 1e-3 to 1e-8 and cutoffs of 0.5nm to 1.8nm,
- * the argument beta*r will be in the range 0.15 to ~4. Use your
- * favorite plotting program to realize how well-behaved Erf(z)/z is
- * in this range!
- *
- * We approximate f(z)=erf(z)/z with a rational minimax polynomial.
- * However, it turns out it is more efficient to approximate f(z)/z and
- * then only use even powers. This is another minor optimization, since
- * we actually WANT f(z)/z, because it is going to be multiplied by
- * the vector between the two atoms to get the vectorial force. The
- * fastest flops are the ones we can avoid calculating!
- *
- * So, here's how it should be used:
- *
- * 1. Calculate r^2.
- * 2. Multiply by beta^2, so you get z^2=beta^2*r^2.
- * 3. Evaluate this routine with z^2 as the argument.
- * 4. The return value is the expression:
- *
- *
- * 2*exp(-z^2) erf(z)
- * ------------ - --------
- * sqrt(Pi)*z^2 z^3
- *
- * 5. Multiply the entire expression by beta^3. This will get you
- *
- * beta^3*2*exp(-z^2) beta^3*erf(z)
- * ------------------ - ---------------
- * sqrt(Pi)*z^2 z^3
- *
- * or, switching back to r (z=r*beta):
- *
- * 2*beta*exp(-r^2*beta^2) erf(r*beta)
- * ----------------------- - -----------
- * sqrt(Pi)*r^2 r^3
- *
- *
- * With a bit of math exercise you should be able to confirm that
- * this is exactly D[Erf[beta*r]/r,r] divided by r another time.
- *
- * 6. Add the result to 1/r^3, multiply by the product of the charges,
- * and you have your force (divided by r). A final multiplication
- * with the vector connecting the two particles and you have your
- * vectorial force to add to the particles.
- *
+/* Temporary:
+ * Alias some old SSE definitions to new SIMD definitions so we don't need
+ * to modify _all_ group kernels - they will anyway be replaced with a new
+ * generic SIMD version soon.
*/
-static __m128d
-gmx_mm_pmecorrF_pd(__m128d z2)
-{
- const __m128d FN10 = _mm_set1_pd(-8.0072854618360083154e-14);
- const __m128d FN9 = _mm_set1_pd(1.1859116242260148027e-11);
- const __m128d FN8 = _mm_set1_pd(-8.1490406329798423616e-10);
- const __m128d FN7 = _mm_set1_pd(3.4404793543907847655e-8);
- const __m128d FN6 = _mm_set1_pd(-9.9471420832602741006e-7);
- const __m128d FN5 = _mm_set1_pd(0.000020740315999115847456);
- const __m128d FN4 = _mm_set1_pd(-0.00031991745139313364005);
- const __m128d FN3 = _mm_set1_pd(0.0035074449373659008203);
- const __m128d FN2 = _mm_set1_pd(-0.031750380176100813405);
- const __m128d FN1 = _mm_set1_pd(0.13884101728898463426);
- const __m128d FN0 = _mm_set1_pd(-0.75225277815249618847);
-
- const __m128d FD5 = _mm_set1_pd(0.000016009278224355026701);
- const __m128d FD4 = _mm_set1_pd(0.00051055686934806966046);
- const __m128d FD3 = _mm_set1_pd(0.0081803507497974289008);
- const __m128d FD2 = _mm_set1_pd(0.077181146026670287235);
- const __m128d FD1 = _mm_set1_pd(0.41543303143712535988);
- const __m128d FD0 = _mm_set1_pd(1.0);
-
- __m128d z4;
- __m128d polyFN0, polyFN1, polyFD0, polyFD1;
-
- z4 = _mm_mul_pd(z2, z2);
-
- polyFD1 = _mm_mul_pd(FD5, z4);
- polyFD0 = _mm_mul_pd(FD4, z4);
- polyFD1 = _mm_add_pd(polyFD1, FD3);
- polyFD0 = _mm_add_pd(polyFD0, FD2);
- polyFD1 = _mm_mul_pd(polyFD1, z4);
- polyFD0 = _mm_mul_pd(polyFD0, z4);
- polyFD1 = _mm_add_pd(polyFD1, FD1);
- polyFD0 = _mm_add_pd(polyFD0, FD0);
- polyFD1 = _mm_mul_pd(polyFD1, z2);
- polyFD0 = _mm_add_pd(polyFD0, polyFD1);
-
- polyFD0 = gmx_mm_inv_pd(polyFD0);
-
- polyFN0 = _mm_mul_pd(FN10, z4);
- polyFN1 = _mm_mul_pd(FN9, z4);
- polyFN0 = _mm_add_pd(polyFN0, FN8);
- polyFN1 = _mm_add_pd(polyFN1, FN7);
- polyFN0 = _mm_mul_pd(polyFN0, z4);
- polyFN1 = _mm_mul_pd(polyFN1, z4);
- polyFN0 = _mm_add_pd(polyFN0, FN6);
- polyFN1 = _mm_add_pd(polyFN1, FN5);
- polyFN0 = _mm_mul_pd(polyFN0, z4);
- polyFN1 = _mm_mul_pd(polyFN1, z4);
- polyFN0 = _mm_add_pd(polyFN0, FN4);
- polyFN1 = _mm_add_pd(polyFN1, FN3);
- polyFN0 = _mm_mul_pd(polyFN0, z4);
- polyFN1 = _mm_mul_pd(polyFN1, z4);
- polyFN0 = _mm_add_pd(polyFN0, FN2);
- polyFN1 = _mm_add_pd(polyFN1, FN1);
- polyFN0 = _mm_mul_pd(polyFN0, z4);
- polyFN1 = _mm_mul_pd(polyFN1, z2);
- polyFN0 = _mm_add_pd(polyFN0, FN0);
- polyFN0 = _mm_add_pd(polyFN0, polyFN1);
-
- return _mm_mul_pd(polyFN0, polyFD0);
-}
-
-
-
-
-/* Calculate the potential correction due to PME analytically.
- *
- * See gmx_mm256_pmecorrF_ps() for details about the approximation.
- *
- * This routine calculates Erf(z)/z, although you should provide z^2
- * as the input argument.
- *
- * Here's how it should be used:
- *
- * 1. Calculate r^2.
- * 2. Multiply by beta^2, so you get z^2=beta^2*r^2.
- * 3. Evaluate this routine with z^2 as the argument.
- * 4. The return value is the expression:
- *
- *
- * erf(z)
- * --------
- * z
- *
- * 5. Multiply the entire expression by beta and switching back to r (z=r*beta):
- *
- * erf(r*beta)
- * -----------
- * r
- *
- * 6. Subtract the result from 1/r, multiply by the product of the charges,
- * and you have your potential.
- *
- */
-static __m128d
-gmx_mm_pmecorrV_pd(__m128d z2)
-{
- const __m128d VN9 = _mm_set1_pd(-9.3723776169321855475e-13);
- const __m128d VN8 = _mm_set1_pd(1.2280156762674215741e-10);
- const __m128d VN7 = _mm_set1_pd(-7.3562157912251309487e-9);
- const __m128d VN6 = _mm_set1_pd(2.6215886208032517509e-7);
- const __m128d VN5 = _mm_set1_pd(-4.9532491651265819499e-6);
- const __m128d VN4 = _mm_set1_pd(0.00025907400778966060389);
- const __m128d VN3 = _mm_set1_pd(0.0010585044856156469792);
- const __m128d VN2 = _mm_set1_pd(0.045247661136833092885);
- const __m128d VN1 = _mm_set1_pd(0.11643931522926034421);
- const __m128d VN0 = _mm_set1_pd(1.1283791671726767970);
-
- const __m128d VD5 = _mm_set1_pd(0.000021784709867336150342);
- const __m128d VD4 = _mm_set1_pd(0.00064293662010911388448);
- const __m128d VD3 = _mm_set1_pd(0.0096311444822588683504);
- const __m128d VD2 = _mm_set1_pd(0.085608012351550627051);
- const __m128d VD1 = _mm_set1_pd(0.43652499166614811084);
- const __m128d VD0 = _mm_set1_pd(1.0);
-
- __m128d z4;
- __m128d polyVN0, polyVN1, polyVD0, polyVD1;
-
- z4 = _mm_mul_pd(z2, z2);
-
- polyVD1 = _mm_mul_pd(VD5, z4);
- polyVD0 = _mm_mul_pd(VD4, z4);
- polyVD1 = _mm_add_pd(polyVD1, VD3);
- polyVD0 = _mm_add_pd(polyVD0, VD2);
- polyVD1 = _mm_mul_pd(polyVD1, z4);
- polyVD0 = _mm_mul_pd(polyVD0, z4);
- polyVD1 = _mm_add_pd(polyVD1, VD1);
- polyVD0 = _mm_add_pd(polyVD0, VD0);
- polyVD1 = _mm_mul_pd(polyVD1, z2);
- polyVD0 = _mm_add_pd(polyVD0, polyVD1);
-
- polyVD0 = gmx_mm_inv_pd(polyVD0);
-
- polyVN1 = _mm_mul_pd(VN9, z4);
- polyVN0 = _mm_mul_pd(VN8, z4);
- polyVN1 = _mm_add_pd(polyVN1, VN7);
- polyVN0 = _mm_add_pd(polyVN0, VN6);
- polyVN1 = _mm_mul_pd(polyVN1, z4);
- polyVN0 = _mm_mul_pd(polyVN0, z4);
- polyVN1 = _mm_add_pd(polyVN1, VN5);
- polyVN0 = _mm_add_pd(polyVN0, VN4);
- polyVN1 = _mm_mul_pd(polyVN1, z4);
- polyVN0 = _mm_mul_pd(polyVN0, z4);
- polyVN1 = _mm_add_pd(polyVN1, VN3);
- polyVN0 = _mm_add_pd(polyVN0, VN2);
- polyVN1 = _mm_mul_pd(polyVN1, z4);
- polyVN0 = _mm_mul_pd(polyVN0, z4);
- polyVN1 = _mm_add_pd(polyVN1, VN1);
- polyVN0 = _mm_add_pd(polyVN0, VN0);
- polyVN1 = _mm_mul_pd(polyVN1, z2);
- polyVN0 = _mm_add_pd(polyVN0, polyVN1);
-
- return _mm_mul_pd(polyVN0, polyVD0);
-}
-
-
-
-static int
-gmx_mm_sincos_pd(__m128d x,
- __m128d *sinval,
- __m128d *cosval)
-{
-#ifdef _MSC_VER
- __declspec(align(16))
- const double sintable[34] =
- {
- 1.00000000000000000e+00, 0.00000000000000000e+00,
- 9.95184726672196929e-01, 9.80171403295606036e-02,
- 9.80785280403230431e-01, 1.95090322016128248e-01,
- 9.56940335732208824e-01, 2.90284677254462331e-01,
- 9.23879532511286738e-01, 3.82683432365089782e-01,
- 8.81921264348355050e-01, 4.71396736825997642e-01,
- 8.31469612302545236e-01, 5.55570233019602178e-01,
- 7.73010453362736993e-01, 6.34393284163645488e-01,
- 7.07106781186547573e-01, 7.07106781186547462e-01,
- 6.34393284163645599e-01, 7.73010453362736882e-01,
- 5.55570233019602289e-01, 8.31469612302545125e-01,
- 4.71396736825997809e-01, 8.81921264348354939e-01,
- 3.82683432365089837e-01, 9.23879532511286738e-01,
- 2.90284677254462276e-01, 9.56940335732208935e-01,
- 1.95090322016128304e-01, 9.80785280403230431e-01,
- 9.80171403295607702e-02, 9.95184726672196818e-01,
- 0.0, 1.00000000000000000e+00
- };
-#else
- const __m128d sintable[17] =
- {
- _mm_set_pd( 0.0, 1.0 ),
- _mm_set_pd( sin( 1.0 * (M_PI/2.0) / 16.0), cos( 1.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 2.0 * (M_PI/2.0) / 16.0), cos( 2.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 3.0 * (M_PI/2.0) / 16.0), cos( 3.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 4.0 * (M_PI/2.0) / 16.0), cos( 4.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 5.0 * (M_PI/2.0) / 16.0), cos( 5.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 6.0 * (M_PI/2.0) / 16.0), cos( 6.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 7.0 * (M_PI/2.0) / 16.0), cos( 7.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 8.0 * (M_PI/2.0) / 16.0), cos( 8.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 9.0 * (M_PI/2.0) / 16.0), cos( 9.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 10.0 * (M_PI/2.0) / 16.0), cos( 10.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 11.0 * (M_PI/2.0) / 16.0), cos( 11.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 12.0 * (M_PI/2.0) / 16.0), cos( 12.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 13.0 * (M_PI/2.0) / 16.0), cos( 13.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 14.0 * (M_PI/2.0) / 16.0), cos( 14.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( sin( 15.0 * (M_PI/2.0) / 16.0), cos( 15.0 * (M_PI/2.0) / 16.0) ),
- _mm_set_pd( 1.0, 0.0 )
- };
-#endif
-
- const __m128d signmask = gmx_mm_castsi128_pd( _mm_set_epi32(0x7FFFFFFF, 0xFFFFFFFF, 0x7FFFFFFF, 0xFFFFFFFF) );
-
- const __m128d tabscale = _mm_set1_pd(32.0/M_PI);
- const __m128d invtabscale0 = _mm_set1_pd(9.81747508049011230469e-02);
- const __m128d invtabscale1 = _mm_set1_pd(1.96197799156550576057e-08);
- const __m128i ione = _mm_set1_epi32(1);
- const __m128i i32 = _mm_set1_epi32(32);
- const __m128i i16 = _mm_set1_epi32(16);
- const __m128i tabmask = _mm_set1_epi32(0x3F);
- const __m128d sinP7 = _mm_set1_pd(-1.0/5040.0);
- const __m128d sinP5 = _mm_set1_pd(1.0/120.0);
- const __m128d sinP3 = _mm_set1_pd(-1.0/6.0);
- const __m128d sinP1 = _mm_set1_pd(1.0);
-
- const __m128d cosP6 = _mm_set1_pd(-1.0/720.0);
- const __m128d cosP4 = _mm_set1_pd(1.0/24.0);
- const __m128d cosP2 = _mm_set1_pd(-1.0/2.0);
- const __m128d cosP0 = _mm_set1_pd(1.0);
-
- __m128d scalex;
- __m128i tabidx, corridx;
- __m128d xabs, z, z2, polySin, polyCos;
- __m128d xpoint;
- __m128d ypoint0, ypoint1;
-
- __m128d sinpoint, cospoint;
- __m128d xsign, ssign, csign;
- __m128i imask, sswapsign, cswapsign;
-
- xsign = _mm_andnot_pd(signmask, x);
- xabs = _mm_and_pd(x, signmask);
-
- scalex = _mm_mul_pd(tabscale, xabs);
- tabidx = _mm_cvtpd_epi32(scalex);
-
- xpoint = _mm_cvtepi32_pd(tabidx);
-
- /* Extended precision arithmetics */
- z = _mm_sub_pd(xabs, _mm_mul_pd(invtabscale0, xpoint));
- z = _mm_sub_pd(z, _mm_mul_pd(invtabscale1, xpoint));
-
- /* Range reduction to 0..2*Pi */
- tabidx = _mm_and_si128(tabidx, tabmask);
-
- /* tabidx is now in range [0,..,64] */
- imask = _mm_cmpgt_epi32(tabidx, i32);
- sswapsign = imask;
- cswapsign = imask;
- corridx = _mm_and_si128(imask, i32);
- tabidx = _mm_sub_epi32(tabidx, corridx);
-
- /* tabidx is now in range [0..32] */
- imask = _mm_cmpgt_epi32(tabidx, i16);
- cswapsign = _mm_xor_si128(cswapsign, imask);
- corridx = _mm_sub_epi32(i32, tabidx);
- tabidx = _mm_or_si128( _mm_and_si128(imask, corridx), _mm_andnot_si128(imask, tabidx) );
- /* tabidx is now in range [0..16] */
- ssign = _mm_cvtepi32_pd( _mm_or_si128( sswapsign, ione ) );
- csign = _mm_cvtepi32_pd( _mm_or_si128( cswapsign, ione ) );
-
-#ifdef _MSC_VER
- ypoint0 = _mm_load_pd(sintable + 2*gmx_mm_extract_epi32(tabidx, 0));
- ypoint1 = _mm_load_pd(sintable + 2*gmx_mm_extract_epi32(tabidx, 1));
-#else
- ypoint0 = sintable[gmx_mm_extract_epi32(tabidx, 0)];
- ypoint1 = sintable[gmx_mm_extract_epi32(tabidx, 1)];
-#endif
- sinpoint = _mm_unpackhi_pd(ypoint0, ypoint1);
- cospoint = _mm_unpacklo_pd(ypoint0, ypoint1);
-
- sinpoint = _mm_mul_pd(sinpoint, ssign);
- cospoint = _mm_mul_pd(cospoint, csign);
-
- z2 = _mm_mul_pd(z, z);
-
- polySin = _mm_mul_pd(sinP7, z2);
- polySin = _mm_add_pd(polySin, sinP5);
- polySin = _mm_mul_pd(polySin, z2);
- polySin = _mm_add_pd(polySin, sinP3);
- polySin = _mm_mul_pd(polySin, z2);
- polySin = _mm_add_pd(polySin, sinP1);
- polySin = _mm_mul_pd(polySin, z);
-
- polyCos = _mm_mul_pd(cosP6, z2);
- polyCos = _mm_add_pd(polyCos, cosP4);
- polyCos = _mm_mul_pd(polyCos, z2);
- polyCos = _mm_add_pd(polyCos, cosP2);
- polyCos = _mm_mul_pd(polyCos, z2);
- polyCos = _mm_add_pd(polyCos, cosP0);
-
- *sinval = _mm_xor_pd(_mm_add_pd( _mm_mul_pd(sinpoint, polyCos), _mm_mul_pd(cospoint, polySin) ), xsign);
- *cosval = _mm_sub_pd( _mm_mul_pd(cospoint, polyCos), _mm_mul_pd(sinpoint, polySin) );
-
- return 0;
-}
-
-/*
- * IMPORTANT: Do NOT call both sin & cos if you need both results, since each of them
- * will then call the sincos() routine and waste a factor 2 in performance!
- */
-static __m128d
-gmx_mm_sin_pd(__m128d x)
-{
- __m128d s, c;
- gmx_mm_sincos_pd(x, &s, &c);
- return s;
-}
-
-/*
- * IMPORTANT: Do NOT call both sin & cos if you need both results, since each of them
- * will then call the sincos() routine and waste a factor 2 in performance!
- */
-static __m128d
-gmx_mm_cos_pd(__m128d x)
-{
- __m128d s, c;
- gmx_mm_sincos_pd(x, &s, &c);
- return c;
-}
-
-
-
-static __m128d
-gmx_mm_tan_pd(__m128d x)
-{
- __m128d sinval, cosval;
- __m128d tanval;
-
- gmx_mm_sincos_pd(x, &sinval, &cosval);
-
- tanval = _mm_mul_pd(sinval, gmx_mm_inv_pd(cosval));
-
- return tanval;
-}
-
-
-
-static __m128d
-gmx_mm_asin_pd(__m128d x)
-{
- /* Same algorithm as cephes library */
- const __m128d signmask = gmx_mm_castsi128_pd( _mm_set_epi32(0x7FFFFFFF, 0xFFFFFFFF, 0x7FFFFFFF, 0xFFFFFFFF) );
- const __m128d limit1 = _mm_set1_pd(0.625);
- const __m128d limit2 = _mm_set1_pd(1e-8);
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d quarterpi = _mm_set1_pd(M_PI/4.0);
- const __m128d morebits = _mm_set1_pd(6.123233995736765886130e-17);
-
- const __m128d P5 = _mm_set1_pd(4.253011369004428248960e-3);
- const __m128d P4 = _mm_set1_pd(-6.019598008014123785661e-1);
- const __m128d P3 = _mm_set1_pd(5.444622390564711410273e0);
- const __m128d P2 = _mm_set1_pd(-1.626247967210700244449e1);
- const __m128d P1 = _mm_set1_pd(1.956261983317594739197e1);
- const __m128d P0 = _mm_set1_pd(-8.198089802484824371615e0);
-
- const __m128d Q4 = _mm_set1_pd(-1.474091372988853791896e1);
- const __m128d Q3 = _mm_set1_pd(7.049610280856842141659e1);
- const __m128d Q2 = _mm_set1_pd(-1.471791292232726029859e2);
- const __m128d Q1 = _mm_set1_pd(1.395105614657485689735e2);
- const __m128d Q0 = _mm_set1_pd(-4.918853881490881290097e1);
-
- const __m128d R4 = _mm_set1_pd(2.967721961301243206100e-3);
- const __m128d R3 = _mm_set1_pd(-5.634242780008963776856e-1);
- const __m128d R2 = _mm_set1_pd(6.968710824104713396794e0);
- const __m128d R1 = _mm_set1_pd(-2.556901049652824852289e1);
- const __m128d R0 = _mm_set1_pd(2.853665548261061424989e1);
-
- const __m128d S3 = _mm_set1_pd(-2.194779531642920639778e1);
- const __m128d S2 = _mm_set1_pd(1.470656354026814941758e2);
- const __m128d S1 = _mm_set1_pd(-3.838770957603691357202e2);
- const __m128d S0 = _mm_set1_pd(3.424398657913078477438e2);
-
- __m128d sign;
- __m128d mask;
- __m128d xabs;
- __m128d zz, ww, z, q, w, zz2, ww2;
- __m128d PA, PB;
- __m128d QA, QB;
- __m128d RA, RB;
- __m128d SA, SB;
- __m128d nom, denom;
-
- sign = _mm_andnot_pd(signmask, x);
- xabs = _mm_and_pd(x, signmask);
-
- mask = _mm_cmpgt_pd(xabs, limit1);
-
- zz = _mm_sub_pd(one, xabs);
- ww = _mm_mul_pd(xabs, xabs);
- zz2 = _mm_mul_pd(zz, zz);
- ww2 = _mm_mul_pd(ww, ww);
-
- /* R */
- RA = _mm_mul_pd(R4, zz2);
- RB = _mm_mul_pd(R3, zz2);
- RA = _mm_add_pd(RA, R2);
- RB = _mm_add_pd(RB, R1);
- RA = _mm_mul_pd(RA, zz2);
- RB = _mm_mul_pd(RB, zz);
- RA = _mm_add_pd(RA, R0);
- RA = _mm_add_pd(RA, RB);
-
- /* S, SA = zz2 */
- SB = _mm_mul_pd(S3, zz2);
- SA = _mm_add_pd(zz2, S2);
- SB = _mm_add_pd(SB, S1);
- SA = _mm_mul_pd(SA, zz2);
- SB = _mm_mul_pd(SB, zz);
- SA = _mm_add_pd(SA, S0);
- SA = _mm_add_pd(SA, SB);
-
- /* P */
- PA = _mm_mul_pd(P5, ww2);
- PB = _mm_mul_pd(P4, ww2);
- PA = _mm_add_pd(PA, P3);
- PB = _mm_add_pd(PB, P2);
- PA = _mm_mul_pd(PA, ww2);
- PB = _mm_mul_pd(PB, ww2);
- PA = _mm_add_pd(PA, P1);
- PB = _mm_add_pd(PB, P0);
- PA = _mm_mul_pd(PA, ww);
- PA = _mm_add_pd(PA, PB);
-
- /* Q, QA = ww2 */
- QB = _mm_mul_pd(Q4, ww2);
- QA = _mm_add_pd(ww2, Q3);
- QB = _mm_add_pd(QB, Q2);
- QA = _mm_mul_pd(QA, ww2);
- QB = _mm_mul_pd(QB, ww2);
- QA = _mm_add_pd(QA, Q1);
- QB = _mm_add_pd(QB, Q0);
- QA = _mm_mul_pd(QA, ww);
- QA = _mm_add_pd(QA, QB);
-
- RA = _mm_mul_pd(RA, zz);
- PA = _mm_mul_pd(PA, ww);
-
- nom = _mm_or_pd( _mm_andnot_pd(mask, PA), _mm_and_pd(mask, RA) );
- denom = _mm_or_pd( _mm_andnot_pd(mask, QA), _mm_and_pd(mask, SA) );
-
- q = _mm_mul_pd( nom, gmx_mm_inv_pd(denom) );
-
- zz = _mm_add_pd(zz, zz);
- zz = gmx_mm_sqrt_pd(zz);
- z = _mm_sub_pd(quarterpi, zz);
- zz = _mm_mul_pd(zz, q);
- zz = _mm_sub_pd(zz, morebits);
- z = _mm_sub_pd(z, zz);
- z = _mm_add_pd(z, quarterpi);
-
- w = _mm_mul_pd(xabs, q);
- w = _mm_add_pd(w, xabs);
-
- z = _mm_or_pd( _mm_andnot_pd(mask, w), _mm_and_pd(mask, z) );
-
- mask = _mm_cmpgt_pd(xabs, limit2);
- z = _mm_or_pd( _mm_andnot_pd(mask, xabs), _mm_and_pd(mask, z) );
-
- z = _mm_xor_pd(z, sign);
-
- return z;
-}
-
-
-static __m128d
-gmx_mm_acos_pd(__m128d x)
-{
- const __m128d one = _mm_set1_pd(1.0);
- const __m128d half = _mm_set1_pd(0.5);
- const __m128d quarterpi0 = _mm_set1_pd(7.85398163397448309616e-1);
- const __m128d quarterpi1 = _mm_set1_pd(6.123233995736765886130e-17);
-
-
- __m128d mask1;
-
- __m128d z, z1, z2;
-
- mask1 = _mm_cmpgt_pd(x, half);
- z1 = _mm_mul_pd(half, _mm_sub_pd(one, x));
- z1 = gmx_mm_sqrt_pd(z1);
- z = _mm_or_pd( _mm_andnot_pd(mask1, x), _mm_and_pd(mask1, z1) );
-
- z = gmx_mm_asin_pd(z);
-
- z1 = _mm_add_pd(z, z);
-
- z2 = _mm_sub_pd(quarterpi0, z);
- z2 = _mm_add_pd(z2, quarterpi1);
- z2 = _mm_add_pd(z2, quarterpi0);
-
- z = _mm_or_pd(_mm_andnot_pd(mask1, z2), _mm_and_pd(mask1, z1));
-
- return z;
-}
-
-static __m128d
-gmx_mm_atan_pd(__m128d x)
-{
- /* Same algorithm as cephes library */
- const __m128d signmask = gmx_mm_castsi128_pd( _mm_set_epi32(0x7FFFFFFF, 0xFFFFFFFF, 0x7FFFFFFF, 0xFFFFFFFF) );
- const __m128d limit1 = _mm_set1_pd(0.66);
- const __m128d limit2 = _mm_set1_pd(2.41421356237309504880);
- const __m128d quarterpi = _mm_set1_pd(M_PI/4.0);
- const __m128d halfpi = _mm_set1_pd(M_PI/2.0);
- const __m128d mone = _mm_set1_pd(-1.0);
- const __m128d morebits1 = _mm_set1_pd(0.5*6.123233995736765886130E-17);
- const __m128d morebits2 = _mm_set1_pd(6.123233995736765886130E-17);
-
- const __m128d P4 = _mm_set1_pd(-8.750608600031904122785E-1);
- const __m128d P3 = _mm_set1_pd(-1.615753718733365076637E1);
- const __m128d P2 = _mm_set1_pd(-7.500855792314704667340E1);
- const __m128d P1 = _mm_set1_pd(-1.228866684490136173410E2);
- const __m128d P0 = _mm_set1_pd(-6.485021904942025371773E1);
-
- const __m128d Q4 = _mm_set1_pd(2.485846490142306297962E1);
- const __m128d Q3 = _mm_set1_pd(1.650270098316988542046E2);
- const __m128d Q2 = _mm_set1_pd(4.328810604912902668951E2);
- const __m128d Q1 = _mm_set1_pd(4.853903996359136964868E2);
- const __m128d Q0 = _mm_set1_pd(1.945506571482613964425E2);
-
- __m128d sign;
- __m128d mask1, mask2;
- __m128d y, t1, t2;
- __m128d z, z2;
- __m128d P_A, P_B, Q_A, Q_B;
-
- sign = _mm_andnot_pd(signmask, x);
- x = _mm_and_pd(x, signmask);
-
- mask1 = _mm_cmpgt_pd(x, limit1);
- mask2 = _mm_cmpgt_pd(x, limit2);
-
- t1 = _mm_mul_pd(_mm_add_pd(x, mone), gmx_mm_inv_pd(_mm_sub_pd(x, mone)));
- t2 = _mm_mul_pd(mone, gmx_mm_inv_pd(x));
-
- y = _mm_and_pd(mask1, quarterpi);
- y = _mm_or_pd( _mm_and_pd(mask2, halfpi), _mm_andnot_pd(mask2, y) );
-
- x = _mm_or_pd( _mm_and_pd(mask1, t1), _mm_andnot_pd(mask1, x) );
- x = _mm_or_pd( _mm_and_pd(mask2, t2), _mm_andnot_pd(mask2, x) );
-
- z = _mm_mul_pd(x, x);
- z2 = _mm_mul_pd(z, z);
-
- P_A = _mm_mul_pd(P4, z2);
- P_B = _mm_mul_pd(P3, z2);
- P_A = _mm_add_pd(P_A, P2);
- P_B = _mm_add_pd(P_B, P1);
- P_A = _mm_mul_pd(P_A, z2);
- P_B = _mm_mul_pd(P_B, z);
- P_A = _mm_add_pd(P_A, P0);
- P_A = _mm_add_pd(P_A, P_B);
-
- /* Q_A = z2 */
- Q_B = _mm_mul_pd(Q4, z2);
- Q_A = _mm_add_pd(z2, Q3);
- Q_B = _mm_add_pd(Q_B, Q2);
- Q_A = _mm_mul_pd(Q_A, z2);
- Q_B = _mm_mul_pd(Q_B, z2);
- Q_A = _mm_add_pd(Q_A, Q1);
- Q_B = _mm_add_pd(Q_B, Q0);
- Q_A = _mm_mul_pd(Q_A, z);
- Q_A = _mm_add_pd(Q_A, Q_B);
-
- z = _mm_mul_pd(z, P_A);
- z = _mm_mul_pd(z, gmx_mm_inv_pd(Q_A));
- z = _mm_mul_pd(z, x);
- z = _mm_add_pd(z, x);
-
- t1 = _mm_and_pd(mask1, morebits1);
- t1 = _mm_or_pd( _mm_and_pd(mask2, morebits2), _mm_andnot_pd(mask2, t1) );
-
- z = _mm_add_pd(z, t1);
- y = _mm_add_pd(y, z);
-
- y = _mm_xor_pd(y, sign);
-
- return y;
-}
-
-
-static __m128d
-gmx_mm_atan2_pd(__m128d y, __m128d x)
-{
- const __m128d pi = _mm_set1_pd(M_PI);
- const __m128d minuspi = _mm_set1_pd(-M_PI);
- const __m128d halfpi = _mm_set1_pd(M_PI/2.0);
- const __m128d minushalfpi = _mm_set1_pd(-M_PI/2.0);
-
- __m128d z, z1, z3, z4;
- __m128d w;
- __m128d maskx_lt, maskx_eq;
- __m128d masky_lt, masky_eq;
- __m128d mask1, mask2, mask3, mask4, maskall;
-
- maskx_lt = _mm_cmplt_pd(x, _mm_setzero_pd());
- masky_lt = _mm_cmplt_pd(y, _mm_setzero_pd());
- maskx_eq = _mm_cmpeq_pd(x, _mm_setzero_pd());
- masky_eq = _mm_cmpeq_pd(y, _mm_setzero_pd());
-
- z = _mm_mul_pd(y, gmx_mm_inv_pd(x));
- z = gmx_mm_atan_pd(z);
-
- mask1 = _mm_and_pd(maskx_eq, masky_lt);
- mask2 = _mm_andnot_pd(maskx_lt, masky_eq);
- mask3 = _mm_andnot_pd( _mm_or_pd(masky_lt, masky_eq), maskx_eq);
- mask4 = _mm_and_pd(masky_eq, maskx_lt);
-
- maskall = _mm_or_pd( _mm_or_pd(mask1, mask2), _mm_or_pd(mask3, mask4) );
-
- z = _mm_andnot_pd(maskall, z);
- z1 = _mm_and_pd(mask1, minushalfpi);
- z3 = _mm_and_pd(mask3, halfpi);
- z4 = _mm_and_pd(mask4, pi);
-
- z = _mm_or_pd( _mm_or_pd(z, z1), _mm_or_pd(z3, z4) );
-
- w = _mm_or_pd(_mm_andnot_pd(masky_lt, pi), _mm_and_pd(masky_lt, minuspi));
- w = _mm_and_pd(w, maskx_lt);
-
- w = _mm_andnot_pd(maskall, w);
-
- z = _mm_add_pd(z, w);
- return z;
-}
+#define gmx_mm_invsqrt_pd gmx_simd_invsqrt_d
+#define gmx_mm_inv_pd gmx_simd_inv_d
+#define gmx_mm_log_pd gmx_simd_log_d
+#define gmx_mm_pmecorrF_pd gmx_simd_pmecorrF_d
+#define gmx_mm_pmecorrV_pd gmx_simd_pmecorrV_d
+#define gmx_mm_sincos_pd gmx_simd_sincos_d
#endif