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Former-commit-id: 03503b9541198b86495636cef73271f5cce1d759
2018-11-22 00:02:31 +00:00 · 2018-11-22 00:02:31 +00:00 · 577a4a5a28
parent de316bdfb1
commit 577a4a5a28
1 changed files with 126 additions and 0 deletions
--- a/qpms/ewald.c
+++ b/qpms/ewald.c
@ -340,6 +340,132 @@ int ewald32_sigma_long_points_and_shift (
  return 0;
 }
 int ewald3_21_xy_sigma_long (
    complex double *target, // must be c->nelem_sc long
    double *err,
    const qpms_ewald32_constants_t *c,
    const double unitcell_volume /* with the corresponding lattice dimensionality */,
    const LatticeDimensionality latdim,
    PGenSph *pgen_K, const bool pgen_generates_shifted_points
    /* If false, the behaviour corresponds to the old ewald32_sigma_long_points_and_shift,
     * so the function assumes that the generated points correspond to the unshifted reciprocal Bravais lattice,
     * and adds beta to the generated points before calculations.
     * If true, it assumes that they are already shifted.
     */,
    const cart3_t beta,
    const cart3_t particle_shift
    )
 {
  const qpms_y_t nelem_sc = c->nelem_sc;
  const qpms_l_t lMax = c->lMax;
  // Manual init of the ewald summation targets
  complex double *target_c = calloc(nelem_sc, sizeof(complex double));
  memset(target, 0, nelem_sc * sizeof(complex double));
  double *err_c = NULL;
  if (err) {
    err_c = calloc(nelem_sc, sizeof(double));
    memset(err, 0, nelem_sc * sizeof(double));
  }
  const double commonfac = 1/(k*k*unitcell_area); // used in the very end (CFC)
  assert(commonfac > 0);
  PGenSingleReturnData pgen_retdata;
 #ifndef NDEBUG
  double rbeta_pq_prev;
 #endif
  // recycleable values if rbeta_pq stays the same:
  complex double gamma_pq;
  complex double z;
  // space for Gamma_pq[j]'s
  qpms_csf_result Gamma_pq[lMax/2+1];
  // CHOOSE POINT BEGIN
  while ((pgen_retdata = PGenSph_next(pgen_K)).flags & PGEN_NOTDONE) { // BEGIN POINT LOOP
    cart3_t K_pq_cart;
    sph_t beta_pq_sph;
    if (pgen_generates_shifted_points) {
      beta_pq_sph = pgen_retdata.point_sph;
      const cart3_t beta_pq_cart = sph2cart(beta_pq_sph);
      K_pq_cart = cart3_add(cart3_scale(-1, beta), beta_pq_cart);
    } else { // as in the old _points_and_shift functions
      const sph_t K_pq_sph = pgen_retdata.point_sph;
      K_pq_cart = sph2cart(K_pq_sph);
      const cart3_t beta_pq_cart = cart3_add(K_pq_cart, beta);
      beta_pq_sph = cart2sph(beta_pq_cart);
    }
    const double rbeta_pq = beta_pq_sph.r;
    const double arg_pq = beta_pq_sph.phi;
    const double beta_pq_theta = beta_pq_sph.theta;
  // CHOOSE POINT END
    const complex double phasefac = cexp(I*cart3_dot(K_pq_cart,particle_shift)); // POINT-DEPENDENT (PFC) // !!!CHECKSIGN!!!
    const bool new_rbeta_pq = (!pgen_generates_shifted_points) || (pgen_retdata.flags & PGEN_NEWR);
    if (!new_rbeta_pq) assert(rbeta_pq == rbeta_pq_prev);
    // R-DEPENDENT BEGIN
    if (new_rbeta_pq) {
      gamma_pq = lilgamma(rbeta_pq/k);
      z = csq(gamma_pq*k/(2*eta)); // Když o tom tak přemýšlím, tak tohle je vlastně vždy reálné
      for(qpms_l_t j = 0; j <= lMax/2; ++j) {
        int retval = complex_gamma_inc_e(0.5-j, z, Gamma_pq+j);
        // we take the other branch, cf. [Linton, p. 642 in the middle]: FIXME instead use the C11 CMPLX macros and fill in -O*I part to z in the line above
        if(creal(z) < 0) 
          Gamma_pq[j].val = conj(Gamma_pq[j].val); //FIXME as noted above
        if(!(retval==0 ||retval==GSL_EUNDRFLW)) abort();
      }
      // --------------- ZDE JSEM SKONČIL. TODO NEZAPOMEŇ TAKY POŘEŠIT PŘÍPAD 1D VS 2D
    }
    // R-DEPENDENT END
    // TODO optimisations: all the j-dependent powers can be done for each j only once, stored in array
    // and just fetched for each n, m pair
    for(qpms_l_t n = 0; n <= lMax; ++n)
      for(qpms_m_t m = -n; m <= n; ++m) {
        if((m+n) % 2 != 0) // odd coefficients are zero.
          continue;
        const qpms_y_t y = qpms_mn2y_sc(m, n);
        const complex double e_imalpha_pq = cexp(I*m*arg_pq);
        complex double jsum, jsum_c; ckahaninit(&jsum, &jsum_c);
        double jsum_err, jsum_err_c; kahaninit(&jsum_err, &jsum_err_c); // TODO do I really need to kahan sum errors?
        assert((n-abs(m))/2 == c->s1_jMaxes[y]);
        for(qpms_l_t j = 0; j <= c->s1_jMaxes[y]/*(n-abs(m))/2*/; ++j) { // FIXME </<= ?
          complex double summand = pow(rbeta_pq/k, n-2*j) 
            * e_imalpha_pq  * c->legendre0[gsl_sf_legendre_array_index(n,abs(m))] * min1pow_m_neg(m) // This line can actually go outside j-loop
            * cpow(gamma_pq, 2*j-1) // * Gamma_pq[j] bellow (GGG) after error computation
            * c->s1_constfacs[y][j];
          if(err) {
            // FIXME include also other errors than Gamma_pq's relative error
             kahanadd(&jsum_err, &jsum_err_c, Gamma_pq[j].err * cabs(summand));
          }
          summand *= Gamma_pq[j].val; // GGG
          ckahanadd(&jsum, &jsum_c, summand);
        }
        jsum *= phasefac; // PFC
        ckahanadd(target + y, target_c + y, jsum);
        if(err) kahanadd(err + y, err_c + y, jsum_err);
      }
 #ifndef NDEBUG
    rbeta_pq_prev = rbeta_pq;
 #endif
  } // END POINT LOOP
  free(err_c);
  free(target_c);
  for(qpms_y_t y = 0; y < nelem_sc; ++y) // CFC common factor from above
    target[y] *= commonfac;
  if(err)
    for(qpms_y_t y = 0; y < nelem_sc; ++y)
      err[y] *= commonfac;
  return 0;
 }
 struct sigma2_integrand_params {
  int n;