284 lines
11 KiB
C
284 lines
11 KiB
C
// Perform Ewald summation (2D xy-lattice in 3D space ) of SSWFs with different Ewald parameters and check whether the difference is inside the tolerance range.
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// run as
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// test_scalar_ewald32 lMax a1.x a1.y a2.x a2.y wavenum.real wavenum.imag k.x k.y particle_shift.x particle_shift.y csphase rtol atol maxR maxK eta1 [eta2 [eta 3 ...]]
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// c99 -o ewaldshift3g_vargeom -ggdb -Wall -I ../ ewaldshift3g_vargeom.c ../qpms/ewald.c ../qpms/ewaldsf.c ../qpms/lattices2d.c ../qpms/latticegens.c -lgsl -lm -lblas
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// implementation of the [LT(4.16)] test
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#include <math.h>
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#define M_SQRTPI 1.7724538509055160272981674833411452
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#define M_SQRT3 1.7320508075688772935274463415058724
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#include <qpms/ewald.h>
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#include <qpms/tiny_inlines.h>
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#include <qpms/indexing.h>
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#include <stdlib.h>
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#include <stdio.h>
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#include <string.h>
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#include <float.h>
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#include <gsl/gsl_sf_legendre.h>
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#include <fenv.h>
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typedef struct ewaldtest2d_params {
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qpms_l_t lMax;
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point2d b1, b2;
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point2d beta;
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point2d particle_shift;
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complex double k;
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//double a;
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double eta;
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double maxR;
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double maxK;
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double csphase;
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} ewaldtest2d_params;
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typedef struct ewaldtest2d_results {
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ewaldtest2d_params p;
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complex double *sigmas_short,
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*sigmas_long,
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sigma0,
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*sigmas_total;
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double *err_sigmas_short,
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*err_sigmas_long,
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err_sigma0,
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*err_sigmas_total;
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complex double *regsigmas_416;
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} ewaldtest2d_results;
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void ewaldtest2d_results_free(ewaldtest2d_results *r) {
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free(r->sigmas_short);
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free(r->sigmas_long);
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free(r->sigmas_total);
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free(r->err_sigmas_long);
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free(r->err_sigmas_total);
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free(r->err_sigmas_short);
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free(r->regsigmas_416);
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free(r);
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}
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static inline double san(double x) {
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return fabs(x) < 1e-13 ? 0 : x;
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}
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int isclose_cmplx(complex double a, complex double b, double rtol, double atol) {
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return cabs(a-b) <= atol + rtol * .5 * (cabs(a) + cabs(b));
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}
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ewaldtest2d_results *ewaldtest2d(const ewaldtest2d_params p);
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int main(int argc, char **argv) {
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feenableexcept(FE_INVALID | FE_OVERFLOW);
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bool verbose = !!getenv("QPMS_VERBOSE_TESTS");
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gsl_set_error_handler(IgnoreUnderflowsGSLErrorHandler);
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QPMS_ENSURE(argc >= 18, "At least 16 arguments expected, I see only %d.", argc-1);
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int netas = argc - 17;
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ewaldtest2d_params plist[netas];
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double atol, rtol;
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plist[0].lMax = atoi(argv[1]);
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plist[0].b1.x = strtod(argv[2], NULL);
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plist[0].b1.y = strtod(argv[3], NULL);
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plist[0].b2.x = strtod(argv[4], NULL);
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plist[0].b2.y = strtod(argv[5], NULL);
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plist[0].k = strtod(argv[6], NULL) + I*strtod(argv[7], NULL);
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plist[0].beta.x = strtod(argv[8], NULL);
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plist[0].beta.y = strtod(argv[9], NULL);
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plist[0].particle_shift.x = strtod(argv[10], NULL);
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plist[0].particle_shift.y = strtod(argv[11], NULL);
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plist[0].csphase = strtod(argv[12], NULL);
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atol = strtod(argv[13], NULL);
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rtol = strtod(argv[14], NULL);
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plist[0].maxR = strtod(argv[15], NULL);
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plist[0].maxK = strtod(argv[16], NULL);
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plist[0].eta = strtod(argv[17], NULL);
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for(int i = 1; i < netas; ++i) {
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plist[i] = plist[0];
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plist[i].eta = strtod(argv[17+i], NULL);
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}
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ewaldtest2d_results *r[netas];
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int fails = 0;
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for (size_t i = 0; i < netas; ++i) {
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ewaldtest2d_params p = plist[i];
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r[i] = ewaldtest2d(p);
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// TODO print per-test header here
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printf("===============================\n");
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printf("b1 = (%g, %g), b2 = (%g, %g)," /* "K1 = (%g, %g), K2 = (%g, %g),"*/ " Kmax = %g, Rmax = %g, lMax = %d, eta = %g, k = %g%+gj, beta = (%g,%g), ps = (%g,%g), csphase = %g\n",
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p.b1.x, p.b1.y, p.b2.x, p.b2.y,/*TODO K1, K2*/ p.maxK, p.maxR, p.lMax, p.eta, creal(p.k), cimag(p.k), p.beta.x, p.beta.y, p.particle_shift.x, p.particle_shift.y, p.csphase);
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printf("sigma0: %.16g%+.16gj\n", creal(r[i]->sigma0), cimag(r[i]->sigma0));
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for (qpms_l_t n = 0; n <= p.lMax; ++n) {
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for (qpms_m_t m = -n; m <= n; ++m){
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if ((m+n)%2) continue;
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qpms_y_t y = qpms_mn2y_sc(m,n);
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qpms_y_t y_conj = qpms_mn2y_sc(-m,n);
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// y n m sigma_total (err), regsigmas_416 regsigmas_415_recon
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if (verbose) printf("%zd %d %d: T:%.16g%+.16gj(%.3g) L:%.16g%+.16gj(%.3g) S:%.16g%+.16gj(%.3g) \n"
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//"| predict %.16g%+.16gj \n| actual %.16g%+.16gj\n"
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,
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y, n, m, creal(san(r[i]->sigmas_total[y])), san(cimag(r[i]->sigmas_total[y])),
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r[i]->err_sigmas_total[y],
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san(creal(r[i]->sigmas_long[y])), san(cimag(r[i]->sigmas_long[y])),
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r[i]->err_sigmas_long[y],
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san(creal(r[i]->sigmas_short[y])), san(cimag(r[i]->sigmas_short[y])),
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r[i]->err_sigmas_short[y]
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// TODO and count big differences as failures.
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//san(creal(r[i]->regsigmas_416[y])), san(cimag(r[i]->regsigmas_416[y])),
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//san(creal(r[i]->sigmas_total[y]) + creal(r[i]->sigmas_total[y_conj])),
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//san(cimag(r[i]->sigmas_total[y]) - cimag(r[i]->sigmas_total[y_conj]))
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);
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}
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}
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}
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bool toprint[netas];
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for (qpms_l_t n = 0; n <= plist[0].lMax; ++n) {
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for (qpms_m_t m = -n; m <= n; ++m){
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memset(toprint, 0, netas*sizeof(bool));
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if ((m+n)%2) continue;
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qpms_y_t y = qpms_mn2y_sc(m,n);
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qpms_y_t y_conj = qpms_mn2y_sc(-m,n);
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for (size_t i = 0; i < netas; ++i) {
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for (size_t j = i+1; j < netas; ++j){
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if (!isclose_cmplx(r[i]->sigmas_total[y], r[j]->sigmas_total[y], rtol, atol))
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toprint[i] = toprint[j] = true;
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}
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if (toprint[i]) {
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++fails;
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printf("with eta = %.16g:\n", plist[i].eta);
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printf("%zd %d %d: T:%.16g%+.16gj(%.3g) L:%.16g%+.16gj(%.3g) S:%.16g%+.16gj(%.3g) \n"
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//"| predict %.16g%+.16gj \n| actual %.16g%+.16gj\n"
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,
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y, n, m, creal(san(r[i]->sigmas_total[y])), san(cimag(r[i]->sigmas_total[y])),
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r[i]->err_sigmas_total[y],
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san(creal(r[i]->sigmas_long[y])), san(cimag(r[i]->sigmas_long[y])),
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r[i]->err_sigmas_long[y],
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san(creal(r[i]->sigmas_short[y])), san(cimag(r[i]->sigmas_short[y])),
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r[i]->err_sigmas_short[y]
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// TODO and count big differences as failures.
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//san(creal(r[i]->regsigmas_416[y])), san(cimag(r[i]->regsigmas_416[y])),
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//san(creal(r[i]->sigmas_total[y]) + creal(r[i]->sigmas_total[y_conj])),
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//san(cimag(r[i]->sigmas_total[y]) - cimag(r[i]->sigmas_total[y_conj]))
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);
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//if(!y) printf("0:%.16g%+.16g\n", san(creal(r[i]->sigma0)), san(cimag(r[i]->sigma0)));
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}
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}
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}
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}
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for (size_t i = 0; i < netas; ++i)
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ewaldtest2d_results_free(r[i]);
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return fails;
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}
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int ewaldtest_counter = 0;
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ewaldtest2d_results *ewaldtest2d(const ewaldtest2d_params p) {
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cart3_t beta3 = cart22cart3xy(p.beta);
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cart3_t particle_shift3 = cart22cart3xy(p.particle_shift);
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cart2_t b1 = p.b1, b2 = p.b2, rb1, rb2;
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if (QPMS_SUCCESS != l2d_reciprocalBasis2pi(b1, b2, &rb1, &rb2))
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abort();
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const double A = l2d_unitcell_area(b1, b2); // sqrt(3) * a * a / 2.; // unit cell size
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const double K_len = cart2norm(rb1)+cart2norm(rb2); //4*M_PI/a/sqrt(3); // reciprocal vector length
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ewaldtest2d_results *results = malloc(sizeof(ewaldtest2d_results));
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results->p = p;
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// skip zeroth point if it coincides with origin
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bool include_origin = !(fabs(p.particle_shift.x) == 0
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&& fabs(p.particle_shift.y) == 0);
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PGen Rlgen = PGen_xyWeb_new(b1, b2, BASIS_RTOL, CART2_ZERO, 0, include_origin, p.maxR, false);
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//PGen Rlgen_plus_shift = PGen_xyWeb_new(b1, b2, BASIS_RTOL, cart2_scale(-1 /* CHECKSIGN */, particle_shift2), 0, include_origin, p.maxR + a, false);
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PGen Klgen = PGen_xyWeb_new(rb1, rb2, BASIS_RTOL, CART2_ZERO, 0, true, p.maxK + K_len, false);
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//PGen Klgen_plus_beta = PGen_xyWeb_new(rb1, rb2, BASIS_RTOL, beta2, 0, true, p.maxK + K_len, false);
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qpms_y_t nelem_sc = qpms_lMax2nelem_sc(p.lMax);
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results->sigmas_short = malloc(sizeof(complex double)*nelem_sc);
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results->sigmas_long = malloc(sizeof(complex double)*nelem_sc);
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results->sigmas_total = malloc(sizeof(complex double)*nelem_sc);
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results->err_sigmas_short = malloc(sizeof(double)*nelem_sc);
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results->err_sigmas_long = malloc(sizeof(double)*nelem_sc);
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results->err_sigmas_total = malloc(sizeof(double)*nelem_sc);
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qpms_ewald3_constants_t *c = qpms_ewald3_constants_init(p.lMax, p.csphase);
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if (0!=ewald3_sigma_long(results->sigmas_long,
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results->err_sigmas_long, c, p.eta, p.k, A,
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LAT_2D_IN_3D_XYONLY, &Klgen, false, beta3, particle_shift3))
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abort();
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if (0!=ewald3_sigma_short(
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results->sigmas_short, results->err_sigmas_short, c,
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p.eta, p.k, LAT_2D_IN_3D_XYONLY, &Rlgen, false, beta3, particle_shift3))
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abort();
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if (0!=ewald3_sigma0(&(results->sigma0), &(results->err_sigma0), c, p.eta, p.k))
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abort();
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for(qpms_y_t y = 0; y < nelem_sc; ++y) {
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results->sigmas_total[y] = results->sigmas_short[y] + results->sigmas_long[y];
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results->err_sigmas_total[y] = results->err_sigmas_short[y] + results->err_sigmas_long[y];
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}
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if(!include_origin) { // "Renormalised" contribution of origin point
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results->sigmas_total[0] += results->sigma0;
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results->err_sigmas_total[0] += results->err_sigma0;
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}
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// Now calculate the reference values [LT(4.16)]
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results->regsigmas_416 = calloc(nelem_sc, sizeof(complex double));
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results->regsigmas_416[0] = -2 * c->legendre0[gsl_sf_legendre_array_index(0,0)];
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#if 0 // not yet implemented for the new API
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{
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double legendres[gsl_sf_legendre_array_n(p.lMax)];
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points2d_rordered_t sel =
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points2d_rordered_annulus(Kpoints_plus_beta, 0, true, p.k, false);
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if (0 != sel.nrs)
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{
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point2d *beta_pq_lessthan_k = sel.base + sel.r_offsets[0];
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size_t beta_pq_lessthan_k_count = sel.r_offsets[sel.nrs] - sel.r_offsets[0];
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for(size_t i = 0; i < beta_pq_lessthan_k_count; ++i) {
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point2d beta_pq = beta_pq_lessthan_k[i];
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double rbeta_pq = cart2norm(beta_pq);
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double arg_pq = atan2(beta_pq.y, beta_pq.x);
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double denom = sqrt(p.k*p.k - rbeta_pq*rbeta_pq);
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if( gsl_sf_legendre_array_e(GSL_SF_LEGENDRE_NONE,
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p.lMax, denom/p.k, p.csphase, legendres) != 0)
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abort();
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for (qpms_y_t y = 0; y < nelem_sc; ++y) {
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qpms_l_t n; qpms_m_t m;
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qpms_y2mn_sc_p(y, &m, &n);
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if ((m+n)%2 != 0)
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continue;
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complex double eimf = cexp(I*m*arg_pq);
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results->regsigmas_416[y] +=
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4*M_PI*ipow(n)/p.k/A
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* eimf * legendres[gsl_sf_legendre_array_index(n,abs(m))] * min1pow_m_neg(m)
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/ denom;
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}
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}
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}
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}
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#else
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for(qpms_y_t y = 0; y < nelem_sc; ++y) {
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qpms_l_t n; qpms_m_t m;
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qpms_y2mn_sc_p(y, &m, &n);
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if ((m+n)%2 != 0)
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continue;
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results->regsigmas_416[y] = NAN;
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}
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#endif
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qpms_ewald3_constants_free(c);
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++ewaldtest_counter;
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return results;
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}
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