gradient.cpp
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Created: Wed, Feb 12, 10:37

gradient.cpp
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	#include <iostream>
	#include <string.h>
	//#include <cuda_runtime.h>
	#include <math.h>
	#include <sys/time.h>
	#include <fstream>
	#include <immintrin.h>

	#include "simd_math.h"
	#include "gradient.hpp"
	#include "structure.h"
	//#include "iacaMarks.h"

	//#define __INV RCP
	//#define __INV RCP_1NR
	#define __INV RCP_2NR
	//#define __SQRT _mm256_sqrt_pd
	//#define __SQRT SQRT
	//#define __SQRT SQRT_1NR
	#define __SQRT SQRT_2NR



	//
	//
	//

	/** usefull functions for PIEMD profile : see old lenstool **/

	/** I*w,v=0.5 Kassiola & Kovner, 1993 PIEMD, paragraph 4.1
	*
	* Global variables used :
	* - none
	*/

	/** @brief This module function calculates profile depended information like the impactparameter b0 and the potential ellipticity epot
	*
	* @param lens: mass distribution for which to calculate parameters
	*/
	void module_readParameters_calculatePotentialparameter(Potential *lens)
	{
	//std::cout << "module_readParameters_calculatePotentialparameter..." << std::endl;
	switch (lens->type)
	{

	case(5): /Elliptical Isothermal Sphere/
	//impact parameter b0
	lens->b0 = 4* pi_c2 * lens->vdisp * lens->vdisp ;
	//ellipticity_potential
	lens->ellipticity_potential = lens->ellipticity/3 ;
	break;

	case(8): /* PIEMD */
	//impact parameter b0
	lens->b0 = 6.pi_c2 lens->vdisp * lens->vdisp;
	//ellipticity_parameter
	if ( lens->ellipticity == 0. && lens->ellipticity_potential != 0. ){
	// emass is (a2-b2)/(a2+b2)
	lens->ellipticity = 2.lens->ellipticity_potential / (1. + lens->ellipticity_potential lens->ellipticity_potential);
	//printf("1 : %f %f \n",lens->ellipticity,lens->ellipticity_potential);
	}
	else if ( lens->ellipticity == 0. && lens->ellipticity_potential == 0. ){
	lens->ellipticity_potential = 0.00001;
	//printf("2 : %f %f \n",lens->ellipticity,lens->ellipticity_potential);
	}
	else{
	// epot is (a-b)/(a+b)
	lens->ellipticity_potential = (1. - sqrt(1 - lens->ellipticity * lens->ellipticity)) / lens->ellipticity;
	//printf("3 : %f %f \n",lens->ellipticity,lens->ellipticity_potential);
	}
	break;

	default:
	std::cout << "ERROR: LENSPARA profil type of clump "<< lens->name << " unknown : "<< lens->type << std::endl;
	//printf( "ERROR: LENSPARA profil type of clump %s unknown : %d\n",lens->name, lens->type);
	break;
	};
	}
	//
	//
	//
	void module_readParameters_calculatePotentialparameter_SOA(Potential_SOA *lens, int ii)
	{
	//std::cout << "module_readParameters_calculatePotentialparameter..." << std::endl;
	switch (lens->type[ii])
	{

	case(5): /Elliptical Isothermal Sphere/
	//impact parameter b0
	lens->b0[ii] = 4* pi_c2 * lens->vdisp[ii] * lens->vdisp[ii] ;
	//ellipticity_potential
	lens->ellipticity_potential[ii] = lens->ellipticity[ii]/3 ;
	break;

	case(8): /* PIEMD */
	//impact parameter b0
	lens->b0[ii] = 6.pi_c2 lens->vdisp[ii] * lens->vdisp[ii];
	//ellipticity_parameter
	if ( lens->ellipticity[ii] == 0. && lens->ellipticity_potential[ii] != 0. ){
	// emass is (a2-b2)/(a2+b2)
	lens->ellipticity[ii] = 2.lens->ellipticity_potential[ii] / (1. + lens->ellipticity_potential[ii] lens->ellipticity_potential[ii]);
	//printf("1 : %f %f \n",lens->ellipticity[ii],lens->ellipticity_potential[ii]);
	}
	else if ( lens->ellipticity[ii] == 0. && lens->ellipticity_potential[ii] == 0. ){
	lens->ellipticity_potential[ii] = 0.00001;
	//printf("2 : %f %f \n",lens->ellipticity[ii],lens->ellipticity_potential[ii]);
	}
	else{
	// epot is (a-b)/(a+b)
	lens->ellipticity_potential[ii] = (1. - sqrt(1 - lens->ellipticity[ii] * lens->ellipticity[ii])) / lens->ellipticity[ii];
	//printf("3 : %f %f \n",lens->ellipticity[ii],lens->ellipticity_potential[ii]);
	}
	break;

	default:
	std::cout << "ERROR: LENSPARA profil type of clump "<< lens->name << " unknown : "<< lens->type << std::endl;
	//printf( "ERROR: LENSPARA profil type of clump %s unknown : %d\n",lens->name, lens->type);
	break;
	};
	}


	//
	/**@brief Return the gradient of the projected lens potential for one clump
	* !!! You have to multiply by dlsds to obtain the true gradient
	* for the expressions, see the papers : JP Kneib & P Natarajan, Cluster Lenses, The Astronomy and Astrophysics Review (2011) for 1 and 2
	* and JP Kneib PhD (1993) for 3
	*
	* @param pImage point where the result is computed in the lens plane
	* @param lens mass distribution
	*/

	//
	/// Useful functions
	//
	//static
	complex
	piemd_1derivatives_ci05(double x, double y, double eps, double rc)
	{
	double sqe, cx1, cxro, cyro, rem2;
	complex zci, znum, zden, zis, zres;
	double norm;
	//
	//std::cout << "piemd_lderivatives" << std::endl;
	sqe = sqrt(eps);
	cx1 = (1. - eps) / (1. + eps);
	cxro = (1. + eps) * (1. + eps);
	cyro = (1. - eps) * (1. - eps);
	//
	rem2 = x * x / cxro + y * y / cyro;
	/zci=cpx(0.,-0.5(1.-eps*eps)/sqe);
	znum=cpx(cx1x,(2.sqesqrt(rcrc+rem2)-y/cx1));
	zden=cpx(x,(2.rcsqe-y));
	zis=pcpx(zci,lncpx(dcpx(znum,zden)));
	zres=pcpxflt(zis,b0);*/

	// --> optimized code
	zci.re = 0;
	zci.im = -0.5 * (1. - eps * eps) / sqe;
	znum.re = cx1 * x;
	znum.im = 2.sqe sqrt(rc * rc + rem2) - y / cx1;
	zden.re = x;
	zden.im = 2.rc sqe - y;
	norm = zden.re * zden.re + zden.im * zden.im; // zis = znum/zden
	zis.re = (znum.re * zden.re + znum.im * zden.im) / norm;
	zis.im = (znum.im * zden.re - znum.re * zden.im) / norm;
	norm = zis.re;
	zis.re = log(sqrt(norm * norm + zis.im * zis.im)); // ln(zis) = ln(\|zis\|)+i.Arg(zis)
	zis.im = atan2(zis.im, norm);
	// norm = zis.re;
	zres.re = zci.re * zis.re - zci.im * zis.im; // Re( zci*ln(zis) )
	zres.im = zci.im * zis.re + zis.im * zci.re; // Im( zci*ln(zis) )
	//
	//zres.re = zis.re*b0;
	//zres.im = zis.im*b0;
	//
	return(zres);
	}
	//
	//// changes the coordinates of point P into a new basis (rotation of angle theta)
	//// y' y x'
	//// * \| /
	//// * \| / theta
	//// * \| /
	//// *\|--------->x
	//
	struct point rotateCoordinateSystem(struct point P, double theta)
	{
	struct point Q;

	Q.x = P.xcos(theta) + P.ysin(theta);
	Q.y = P.ycos(theta) - P.xsin(theta);

	return(Q);
	}

	__attribute__((noinline))
	static struct point
	grad_halo(const struct point pImage, const struct Potential lens)
	{
	struct point true_coord, true_coord_rotation, result;
	double R, angular_deviation;
	complex zis;
	//
	//std::cout << "grad_halo..." << lens->type << std::endl;
	result.x = result.y = 0.;
	//
	/positionning at the potential center/
	// Change the origin of the coordinate system to the center of the clump
	true_coord.x = pImage->x - lens->position.x;
	true_coord.y = pImage->y - lens->position.y;
	//
	switch (lens->type)
	{
	case(5): /Elliptical Isothermal Sphere/
	/rotation of the coordiante axes to match the potential axes/
	true_coord_rotation = rotateCoordinateSystem(true_coord, lens->ellipticity_angle);
	//
	R=sqrt(true_coord_rotation.xtrue_coord_rotation.x(1 - lens->ellipticity/3.) + true_coord_rotation.ytrue_coord_rotation.y(1 + lens->ellipticity/3.)); //ellippot = ellipmass/3
	result.x = (1 - lens->ellipticity/3.)lens->b0true_coord_rotation.x/(R);
	result.y = (1 + lens->ellipticity/3.)lens->b0true_coord_rotation.y/(R);
	break;
	case(8): /* PIEMD */
	/rotation of the coordiante axes to match the potential axes/
	true_coord_rotation = rotateCoordinateSystem(true_coord, lens->ellipticity_angle);
	/Doing something..../
	zis = piemd_1derivatives_ci05(true_coord_rotation.x, true_coord_rotation.y, lens->ellipticity_potential, lens->rcore);
	//
	result.x = lens->b0*zis.re;
	result.y = lens->b0*zis.im;
	break;
	default:
	std::cout << "ERROR: Grad 1 profil type of clump "<< lens->name << " unknown : "<< lens->type << std::endl;
	break;
	};
	return result;
	}
	//
	//
	//
	struct point module_potentialDerivatives_totalGradient(const runmode_param runmode, const struct point pImage, const struct Potential *lens)
	{
	struct point grad, clumpgrad;
	grad.x = 0;
	grad.y = 0;
	std::cout << "nhalos = " << runmode->nhalos << std::endl;
	for(int i = 0; i < runmode->nhalos; i++)
	{
	clumpgrad = grad_halo(pImage, &lens[i]); //compute gradient for each clump separately
	//nan check
	//std::cout << clumpgrad.x << " " << clumpgrad.y << std::endl;
	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y)
	{
	// add the gradients
	grad.x += clumpgrad.x;
	grad.y += clumpgrad.y;
	}
	}
	//
	return(grad);
	}

	struct point grad_halo_piemd_SOA(const struct point pImage, int iterator, const struct Potential_SOA lens)
	{
	struct point clumpgrad;
	clumpgrad.x = 0;
	clumpgrad.y = 0;


	struct point true_coord, true_coord_rotation; //, result;
	//double R, angular_deviation;
	complex zis;
	//
	//result.x = result.y = 0.;
	//
	true_coord.x = pImage->x - lens->position_x[iterator];
	true_coord.y = pImage->y - lens->position_y[iterator];
	//
	// std::cout << "grad_halo..." << lens->type << std::endl;
	//
	/positionning at the potential center/
	// Change the origin of the coordinate system to the center of the clump
	true_coord_rotation = rotateCoordinateSystem(true_coord, lens->ellipticity_angle[iterator]);
	// std::cout << i << ": " << true_coord.x << " " << true_coord.y << " -> "
	// << true_coord_rotation.x << " " << true_coord_rotation.y << std::endl;
	//
	//double sqe, cx1, cxro, cyro, rem2;
	//
	double x = true_coord_rotation.x;
	double y = true_coord_rotation.y;
	double eps = lens->ellipticity_potential[iterator];
	double rc = lens->rcore[iterator];
	//
	//std::cout << "piemd_lderivatives" << std::endl;
	//
	double sqe = sqrt(eps);
	//
	double cx1 = (1. - eps)/(1. + eps);
	double cxro = (1. + eps)*(1. + eps);
	double cyro = (1. - eps)*(1. - eps);
	//
	double rem2 = xx/cxro + yy/cyro;
	//
	/zci=cpx(0.,-0.5(1.-eps*eps)/sqe);
	znum=cpx(cx1x,(2.sqesqrt(rcrc+rem2)-y/cx1));
	zden=cpx(x,(2.rcsqe-y));
	zis=pcpx(zci,lncpx(dcpx(znum,zden)));
	zres=pcpxflt(zis,b0);*/
	// --> optimized code
	complex zci, znum, zden, zres;
	double norm;
	//
	zci.re = 0;
	zci.im = -0.5(1. - epseps)/sqe;
	//
	znum.re = cx1*x;
	znum.im = 2.sqesqrt(rc*rc + rem2) - y/cx1;
	//
	zden.re = x;
	zden.im = 2.rcsqe - y;
	norm = (zden.rezden.re + zden.imzden.im); // zis = znum/zden
	//
	zis.re = (znum.rezden.re + znum.imzden.im)/norm;
	zis.im = (znum.imzden.re - znum.rezden.im)/norm;
	norm = zis.re;
	zis.re = log(sqrt(normnorm + zis.imzis.im)); // ln(zis) = ln(\|zis\|)+i.Arg(zis)
	zis.im = atan2(zis.im, norm);
	// norm = zis.re;
	zres.re = zci.rezis.re - zci.imzis.im; // Re( zci*ln(zis) )
	zres.im = zci.imzis.re + zis.imzci.re; // Im( zci*ln(zis) )
	//
	zis.re = zres.re;
	zis.im = zres.im;
	//
	//zres.re = zis.re*b0;
	//zres.im = zis.im*b0;
	//
	//
	clumpgrad.x = lens->b0[iterator]*zis.re;
	clumpgrad.y = lens->b0[iterator]*zis.im;
	//nan check
	//
	return(clumpgrad);
	}

	struct point grad_halo_sis_SOA(const struct point pImage, int iterator, const struct Potential_SOA lens)
	{
	struct point true_coord, true_coord_rotation, result;
	double R, angular_deviation;
	complex zis;

	result.x = result.y = 0.;

	/positionning at the potential center/
	true_coord.x = pImage->x - lens->position_x[iterator]; // Change the origin of the coordinate system to the center of the clump
	true_coord.y = pImage->y - lens->position_y[iterator];

	/Elliptical Isothermal Sphere/
	/rotation of the coordiante axes to match the potential axes/
	true_coord_rotation = rotateCoordinateSystem(true_coord, lens->ellipticity_angle[iterator]);

	R=sqrt(true_coord_rotation.xtrue_coord_rotation.x(1-lens->ellipticity[iterator]/3.)+true_coord_rotation.ytrue_coord_rotation.y(1+lens->ellipticity[iterator]/3.)); //ellippot = ellipmass/3
	result.x=(1-lens->ellipticity[iterator]/3.)lens->b0[iterator]true_coord_rotation.x/(R);
	result.y=(1+lens->ellipticity[iterator]/3.)lens->b0[iterator]true_coord_rotation.y/(R);

	return result;
	}

	struct point module_potentialDerivatives_totalGradient_SOA(const int Nlens, const struct point pImage, const struct Potential_SOA *lens)
	{
	struct point grad, clumpgrad;
	grad.x=0;
	grad.y=0;

	//This here could be done with function pointer to better acomodate future ass distributions functions
	// However I'm unsure of the time of function pointers -> ask gilles
	//for the moment lens and Nlens is organised the following way : 1. SIS, 2. PIEMD

	//SIS is the first
	for(int i=0; i<Nlens[0]; i++){
	clumpgrad=grad_halo_sis_SOA(pImage,i,&lens[0]); //compute gradient for each clump separately

	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y){ //nan check
	grad.x+=clumpgrad.x;
	grad.y+=clumpgrad.y;
	} // add the gradients
	}

	//PIEMD is the second
	for(int i=0; i<Nlens[1]; i++){
	clumpgrad=grad_halo_piemd_SOA(pImage,i,&lens[1]); //compute gradient for each clump separately

	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y){ //nan check
	grad.x+=clumpgrad.x;
	grad.y+=clumpgrad.y;
	} // add the gradients
	}

	return(grad);
	}


	struct point grad_halo_piemd_SOA_AVX(const int Nlens, const struct point pImage, const struct Potential_SOA lens)
	{
	struct point grad, clumpgrad;
	grad.x = 0;
	grad.y = 0;
	//std::cout << "optimized gradient: nhalos = " << runmode->nhalos << std::endl;
	//
	// smearing the image coordinates on registers
	__m256d image_x = _mm256_set1_pd(pImage->x);
	__m256d image_y = _mm256_set1_pd(pImage->y);
	//
	//#pragma unroll
	for(int i = 0; i < Nlens; i = i + 4)
	{
	//IACA_START;
	//
	//std::cout << "starting loop " << std::endl;
	__m256d two = _mm256_set1_pd(2.);
	__m256d one = _mm256_set1_pd(1.);
	__m256d zero = _mm256_set1_pd(0.);
	__m256d half = _mm256_set1_pd(0.5);
	__m256d mhalf = _mm256_set1_pd(-0.5);
	//
	// 2 loads
	__m256d true_coord_x = _mm256_sub_pd(image_x, _mm256_loadu_pd(&lens->position_x[i]));
	__m256d true_coord_y = _mm256_sub_pd(image_y, _mm256_loadu_pd(&lens->position_y[i]));
	// 2 loafs
	__m256d rc = _mm256_loadu_pd(&lens->rcore[i]);
	__m256d b0 = _mm256_loadu_pd(&lens->b0[i]);
	// 2 loads
	__m256d eps = _mm256_loadu_pd(&lens->ellipticity_potential[i]);
	//
	__m256d one_minus_eps = _mm256_sub_pd(one, eps);
	__m256d one_plus_eps = _mm256_add_pd(one, eps);
	__m256d one_plus_eps_rcp = __INV(one_plus_eps);
	// 1 load
	__m256d theta = _mm256_loadu_pd(&lens->ellipticity_angle[i]);
	/positionning at the potential center/
	__m256d cos_theta = _mm256_cos_pd(theta);
	__m256d sin_theta = _mm256_sin_pd(theta);
	// rotation: 6 ops
	__m256d x = _mm256_add_pd(_mm256_mul_pd(true_coord_x, cos_theta), _mm256_mul_pd(true_coord_y, sin_theta));
	__m256d y = _mm256_sub_pd(_mm256_mul_pd(true_coord_y, cos_theta), _mm256_mul_pd(true_coord_x, sin_theta));
	//
	__m256d sqe = __SQRT(eps);
	//
	// (1. - eps)/(1. + eps); 3 ops
	__m256d cx1 = one_minus_eps*one_plus_eps_rcp;
	// (1. + eps)*(1. + eps); 3 ops
	__m256d cxro = one_plus_eps*one_plus_eps;
	// (1. - eps)*(1. - eps); 3 ops
	__m256d cyro = one_minus_eps*one_minus_eps;
	//__m256d rem2 = xx/(cxro) + yy/(cyro);
	// ~5 ops
	__m256d rem2 = xx__INV(cxro) + yy__INV(cyro);
	//
	__m256d zci_re = zero;
	__m256d zci_im = mhalf(one - epseps)*__INV(sqe); // ~4 ops
	// 2.sqesqrt(rc*rc + rem2) - y/cx1
	// 7 ops
	__m256d znum_re = cx1*x;
	__m256d znum_im = twosqe__SQRT(rcrc + rem2) - y__INV(cx1); // ~4 ops
	//
	__m256d zden_re = x;
	__m256d zden_im = _mm256_mul_pd(_mm256_set1_pd(2.), _mm256_mul_pd(rc, sqe));
	zden_im = _mm256_sub_pd(zden_im, y);
	//norm = (zden.rezden.re + zden.imzden.im); 3 ops
	__m256d norm = (zden_rezden_re + zden_imzden_im);
	__m256d zis_re = (znum_rezden_re + znum_imzden_im)*__INV(norm); // 3 ops
	__m256d zis_im = (znum_imzden_re - znum_rezden_im)*__INV(norm); // 3 ops
	norm = zis_re;
	//
	zis_re = _mm256_log_pd(__SQRT(normnorm + zis_imzis_im)); // 3 ops// ln(zis) = ln(\|zis\|)+i.Arg(zis)
	zis_re = _mm256_log_pd(__SQRT(normnorm + zis_imzis_im)); // 3 ops// ln(zis) = ln(\|zis\|)+i.Arg(zis)
	zis_im = _mm256_atan2_pd(zis_im, norm); //
	//
	__m256d zres_re = zci_rezis_re - zci_imzis_im; // Re( zci*ln(zis) ) 3 ops
	__m256d zres_im = zci_imzis_re + zis_imzci_re; // Im( zci*ln(zis) ) 3 ops
	//
	zis_re = zres_re;
	zis_im = zres_im;
	//
	__m256d b0_x, b0_y;
	//
	b0_x = _mm256_mul_pd(b0, zis_re); // 1 ops
	clumpgrad.x = ((double*) &b0_x)[0];
	clumpgrad.x += ((double*) &b0_x)[1];
	clumpgrad.x += ((double*) &b0_x)[2];
	clumpgrad.x += ((double*) &b0_x)[3];
	//
	b0_y = _mm256_mul_pd(b0, zis_im); // 1 ops
	clumpgrad.y = ((double*) &b0_y)[0];
	clumpgrad.y += ((double*) &b0_y)[1];
	clumpgrad.y += ((double*) &b0_y)[2];
	clumpgrad.y += ((double*) &b0_y)[3];
	//
	//nan check
	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y)
	{
	// add the gradients
	grad.x += clumpgrad.x;
	grad.y += clumpgrad.y;
	}
	}
	for(int i = Nlens - Nlens%4; i < Nlens; ++i){
	//std::cout << i << std::endl;
	clumpgrad=grad_halo_piemd_SOA(pImage,i,&lens[1]); //compute gradient for each clump separately
	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y)
	{ //nan check
	grad.x+=clumpgrad.x;
	grad.y+=clumpgrad.y;
	}



	}
	//IACA_END;
	//
	return(grad);
	}

	struct point module_potentialDerivatives_totalGradient_SOA_AVX(const int Nlens, const struct point pImage, const struct Potential_SOA *lens)
	{
	struct point grad, clumpgrad;
	grad.x = 0;
	grad.y = 0;

	//SIS is the first
	for(int i=0; i<Nlens[0]; i++){
	clumpgrad=grad_halo_sis_SOA(pImage,i,&lens[0]); //compute gradient for each clump separately

	if(clumpgrad.x == clumpgrad.x or clumpgrad.y == clumpgrad.y){ //nan check
	grad.x+=clumpgrad.x;
	grad.y+=clumpgrad.y;
	} // add the gradients
	}

	clumpgrad = grad_halo_piemd_SOA_AVX(Nlens[1],pImage,&lens[1]);
	//std::cout << clumpgrad.x << " " << clumpgrad.y << " " << Nlens[1] <<std::endl;
	grad.x+=clumpgrad.x;
	grad.y+=clumpgrad.y;

	return grad;

	}

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