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311 lines
12 KiB
C++
311 lines
12 KiB
C++
/*************************** vectormath_common.h ****************************
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* Author: Agner Fog
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* Date created: 2014-04-18
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* Last modified: 2014-10-16
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* Version: 1.16
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* Project: vector classes
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* Description:
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* Header file containing common code for inline version of mathematical functions.
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*
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* Theory, methods and inspiration based partially on these sources:
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* > Moshier, Stephen Lloyd Baluk: Methods and programs for mathematical functions.
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* Ellis Horwood, 1989.
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* > VDT library developed on CERN by Danilo Piparo, Thomas Hauth and
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* Vincenzo Innocente, 2012, https://svnweb.cern.ch/trac/vdt
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* > Cephes math library by Stephen L. Moshier 1992,
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* http://www.netlib.org/cephes/
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*
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* Calculation methods:
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* Some functions are using Padé approximations f(x) = P(x)/Q(x)
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* Most single precision functions are using Taylor expansions
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*
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* For detailed instructions, see VectorClass.pdf
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*
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* (c) Copyright 2014 GNU General Public License http://www.gnu.org/licenses
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******************************************************************************/
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#ifndef VECTORMATH_COMMON_H
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#define VECTORMATH_COMMON_H 1
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#ifdef VECTORMATH_LIB_H
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#error conflicting header files: vectormath_lib.h for external math functions, other vectormath_xxx.h for inline math functions
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#endif
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#include <math.h>
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#include "vectorclass.h"
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/******************************************************************************
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define mathematical constants
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******************************************************************************/
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#define VM_PI 3.14159265358979323846 // pi
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#define VM_PI_2 1.57079632679489661923 // pi / 2
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#define VM_PI_4 0.785398163397448309616 // pi / 4
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#define VM_SQRT2 1.41421356237309504880 // sqrt(2)
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#define VM_LOG2E 1.44269504088896340736 // 1/log(2)
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#define VM_LOG10E 0.434294481903251827651 // 1/log(10)
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#define VM_LN2 0.693147180559945309417 // log(2)
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#define VM_LN10 2.30258509299404568402 // log(10)
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#define VM_SMALLEST_NORMAL 2.2250738585072014E-308 // smallest normal number, double
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#define VM_SMALLEST_NORMALF 1.17549435E-38f // smallest normal number, float
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/******************************************************************************
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templates for producing infinite and nan in desired vector type
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******************************************************************************/
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template <class VTYPE>
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static inline VTYPE infinite_vec();
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template <>
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inline Vec2d infinite_vec<Vec2d>() {
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return infinite2d();
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}
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template <>
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inline Vec4f infinite_vec<Vec4f>() {
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return infinite4f();
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}
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#if MAX_VECTOR_SIZE >= 256
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template <>
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inline Vec4d infinite_vec<Vec4d>() {
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return infinite4d();
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}
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template <>
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inline Vec8f infinite_vec<Vec8f>() {
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return infinite8f();
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}
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#endif // MAX_VECTOR_SIZE >= 256
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#if MAX_VECTOR_SIZE >= 512
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template <>
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inline Vec8d infinite_vec<Vec8d>() {
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return infinite8d();
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}
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template <>
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inline Vec16f infinite_vec<Vec16f>() {
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return infinite16f();
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}
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#endif // MAX_VECTOR_SIZE >= 512
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// template for producing quiet NAN
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template <class VTYPE>
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static inline VTYPE nan_vec(int n = 0x100);
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template <>
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inline Vec2d nan_vec<Vec2d>(int n) {
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return nan2d(n);
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}
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template <>
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inline Vec4f nan_vec<Vec4f>(int n) {
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return nan4f(n);
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}
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#if MAX_VECTOR_SIZE >= 256
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template <>
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inline Vec4d nan_vec<Vec4d>(int n) {
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return nan4d(n);
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}
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template <>
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inline Vec8f nan_vec<Vec8f>(int n) {
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return nan8f(n);
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}
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#endif // MAX_VECTOR_SIZE >= 256
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#if MAX_VECTOR_SIZE >= 512
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template <>
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inline Vec8d nan_vec<Vec8d>(int n) {
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return nan8d(n);
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}
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template <>
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inline Vec16f nan_vec<Vec16f>(int n) {
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return nan16f(n);
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}
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#endif // MAX_VECTOR_SIZE >= 512
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// Define NAN trace values
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#define NAN_LOG 0x101 // logarithm for x<0
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#define NAN_POW 0x102 // negative number raised to non-integer power
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#define NAN_HYP 0x104 // acosh for x<1 and atanh for abs(x)>1
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/******************************************************************************
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templates for polynomials
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Using Estrin's scheme to make shorter dependency chains and use FMA, starting
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longest dependency chains first.
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******************************************************************************/
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// template <typedef VECTYPE, typedef CTYPE>
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template <class VTYPE, class CTYPE>
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static inline VTYPE polynomial_2(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2) {
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// calculates polynomial c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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//return = x2 * c2 + (x * c1 + c0);
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return mul_add(x2, c2, mul_add(x, c1, c0));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_3(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3) {
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// calculates polynomial c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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//return (c2 + c3*x)*x2 + (c1*x + c0);
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return mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_4(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4) {
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// calculates polynomial c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c2+c3*x)*x2 + ((c0+c1*x) + c4*x4);
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return mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0) + c4*x4);
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_4n(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3) {
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// calculates polynomial 1*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c2+c3*x)*x2 + ((c0+c1*x) + x4);
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return mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0) + x4);
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_5(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5) {
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// calculates polynomial c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c2+c3*x)*x2 + ((c4+c5*x)*x4 + (c0+c1*x));
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return mul_add(mul_add(c3,x,c2), x2, mul_add(mul_add(c5,x,c4), x4, mul_add(c1,x,c0)));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_5n(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4) {
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// calculates polynomial 1*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c2+c3*x)*x2 + ((c4+x)*x4 + (c0+c1*x));
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return mul_add( mul_add(c3,x,c2), x2, mul_add(c4+x,x4,mul_add(c1,x,c0)) );
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_6(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6) {
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// calculates polynomial c6*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c4+c5*x+c6*x2)*x4 + ((c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(c6,x2,mul_add(c5,x,c4)), x4, mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0)));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_6n(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5) {
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// calculates polynomial 1*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return (c4+c5*x+x2)*x4 + ((c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(c5,x,c4+x2), x4, mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0)));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_7(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7) {
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// calculates polynomial c7*x^7 + c6*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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//return ((c6+c7*x)*x2 + (c4+c5*x))*x4 + ((c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(mul_add(c7,x,c6), x2, mul_add(c5,x,c4)), x4, mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0)));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_8(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7, CTYPE c8) {
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// calculates polynomial c8*x^8 + c7*x^7 + c6*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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VTYPE x8 = x4 * x4;
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//return ((c6+c7*x)*x2 + (c4+c5*x))*x4 + (c8*x8 + (c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(mul_add(c7,x,c6), x2, mul_add(c5,x,c4)), x4,
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mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0)+c8*x8));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_9(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7, CTYPE c8, CTYPE c9) {
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// calculates polynomial c9*x^9 + c8*x^8 + c7*x^7 + c6*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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VTYPE x8 = x4 * x4;
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//return (((c6+c7*x)*x2 + (c4+c5*x))*x4 + (c8+c9*x)*x8) + ((c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(c9,x,c8), x8, mul_add(
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mul_add(mul_add(c7,x,c6), x2, mul_add(c5,x,c4)), x4,
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mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0))));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_10(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7, CTYPE c8, CTYPE c9, CTYPE c10) {
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// calculates polynomial c10*x^10 + c9*x^9 + c8*x^8 + c7*x^7 + c6*x^6 + c5*x^5 + c4*x^4 + c3*x^3 + c2*x^2 + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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VTYPE x8 = x4 * x4;
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//return (((c6+c7*x)*x2 + (c4+c5*x))*x4 + (c8+c9*x+c10*x2)*x8) + ((c2+c3*x)*x2 + (c0+c1*x));
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return mul_add(mul_add(x2,c10,mul_add(c9,x,c8)), x8,
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mul_add(mul_add(mul_add(c7,x,c6),x2,mul_add(c5,x,c4)), x4,
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mul_add(mul_add(c3,x,c2),x2,mul_add(c1,x,c0))));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_13(VTYPE const & x, CTYPE c0, CTYPE c1, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7, CTYPE c8, CTYPE c9, CTYPE c10, CTYPE c11, CTYPE c12, CTYPE c13) {
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// calculates polynomial c13*x^13 + c12*x^12 + ... + c1*x + c0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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VTYPE x8 = x4 * x4;
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return mul_add(
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mul_add(
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mul_add(c13,x,c12), x4,
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mul_add(mul_add(c11,x,c10), x2, mul_add(c9,x,c8))), x8,
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mul_add(
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mul_add(mul_add(c7,x,c6), x2, mul_add(c5,x,c4)), x4,
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mul_add(mul_add(c3,x,c2), x2, mul_add(c1,x,c0))));
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}
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template<class VTYPE, class CTYPE>
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static inline VTYPE polynomial_13m(VTYPE const & x, CTYPE c2, CTYPE c3, CTYPE c4, CTYPE c5, CTYPE c6, CTYPE c7, CTYPE c8, CTYPE c9, CTYPE c10, CTYPE c11, CTYPE c12, CTYPE c13) {
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// calculates polynomial c13*x^13 + c12*x^12 + ... + x + 0
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// VTYPE may be a vector type, CTYPE is a scalar type
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VTYPE x2 = x * x;
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VTYPE x4 = x2 * x2;
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VTYPE x8 = x4 * x4;
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// return ((c8+c9*x) + (c10+c11*x)*x2 + (c12+c13*x)*x4)*x8 + (((c6+c7*x)*x2 + (c4+c5*x))*x4 + ((c2+c3*x)*x2 + x));
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return mul_add(
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mul_add(mul_add(c13,x,c12), x4, mul_add(mul_add(c11,x,c10), x2, mul_add(c9,x,c8))), x8,
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mul_add( mul_add(mul_add(c7,x,c6), x2, mul_add(c5,x,c4)), x4, mul_add(mul_add(c3,x,c2),x2,x)));
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}
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#endif
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