Disable "hard" examples in CI
[qpms.git] / qpms / translations.h
blob008ff04fac4ac83980da80b115854a68bf8105b5
1 /*! \file translations.h
2 * \brief VSWF translation operator.
4 * ### Argument conventions
6 * A single wave with indices mu, nu is re-expanded at kdlj into waves with indices m, n,
7 * i.e. in the following functions, the first arguments over which one sums (multiplied
8 * by the waves with new origin).
10 * HOWEVER, this means that if a field has an expansion with coeffs a(mu, nu)
11 * at the original origin, with the basis at the new origin, the coeffs will be
12 * a(m, n) = \sum_{mu,nu} A(m, n, mu, nu) a(mu, nu).
14 * With qpms_trans_calculator_get_AB_arrays_buf (and other functions from *AB_arrays*
15 * family), one can choose the stride. And it seems that the former stride argument (now called
16 * destride) and the latter (now called srcstride) are connected to (m,n) and (mu,nu) indices,
17 * respectively. Seems consistent.
20 * #### r_ge_d argument:
22 * If r_ge_d == true, the translation coefficients are calculated using regular bessel functions,
23 * regardless of what J argument is.
27 #ifndef QPMS_TRANSLATIONS_H
28 #define QPMS_TRANSLATIONS_H
29 #include "vectors.h"
30 #include "qpms_types.h"
31 #include <complex.h>
32 #include <stdbool.h>
33 #include <stddef.h>
35 #if defined LATTICESUMS32 || defined LATTICESUMS31
36 #include "ewald.h"
37 #endif
40 complex double qpms_trans_single_A(qpms_normalisation_t norm, qpms_m_t m, qpms_l_t n, qpms_m_t mu, qpms_l_t nu, csph_t kdlj,
41 bool r_ge_d, qpms_bessel_t J);
43 complex double qpms_trans_single_B(qpms_normalisation_t norm, qpms_m_t m, qpms_l_t n, qpms_m_t mu, qpms_l_t nu, csph_t kdlj,
44 bool r_ge_d, qpms_bessel_t J);
46 /// Structure holding the constant factors in normalisation operators.
47 /**
48 * The VSWF translation operator elements are rather complicated linear
49 * combinations of Bessel functions and spherical harmonics.
50 * The preceding factors are rather complicated but need to be calculated
51 * (for a single normalisation convention)
52 * only once and then recycled during the operator evaluation for different
53 * translations.
55 * This structure is initialised with qpms_trans_calculator_t() and
56 * holds all the constant factors up to a truncation
57 * degree \a lMax.
59 * The destructor function is qpms_trans_calculator_free().
61 * If Ewald sums are enabled at build, it also holds the constant
62 * factors useful for lattice sums of translation operator.
64 typedef struct qpms_trans_calculator {
65 qpms_normalisation_t normalisation;
66 qpms_l_t lMax;
67 qpms_y_t nelem;
68 complex double **A_multipliers;
69 complex double **B_multipliers;
70 #if 0
71 // Normalised values of the Legendre functions and derivatives
72 // for θ == π/2, i.e. for the 2D case.
73 double *leg0;
74 double *pi0;
75 double *tau0;
76 // Spherical Bessel function coefficients:
77 // TODO
78 #endif
80 #if defined LATTICESUMS32 || defined LATTICESUMS31
81 qpms_ewald3_constants_t *e3c;
82 #endif
83 double *legendre0; // Zero-argument Legendre functions – this might go outside #ifdef in the end...
84 } qpms_trans_calculator;
86 /// Initialise a qpms_trans_calculator_t instance for a given convention and truncation degree.
87 qpms_trans_calculator *qpms_trans_calculator_init(qpms_l_t lMax, ///< Truncation degree.
88 qpms_normalisation_t nt
90 /// Destructor for qpms_trans_calculator_t.
91 void qpms_trans_calculator_free(qpms_trans_calculator *);
93 complex double qpms_trans_calculator_get_A(const qpms_trans_calculator *c,
94 qpms_m_t m, qpms_l_t n, qpms_m_t mu, qpms_l_t nu, csph_t kdlj,
95 bool r_ge_d, qpms_bessel_t J);
96 complex double qpms_trans_calculator_get_B(const qpms_trans_calculator *c,
97 qpms_m_t m, qpms_l_t n, qpms_m_t mu, qpms_l_t nu, csph_t kdlj,
98 bool r_ge_d, qpms_bessel_t J);
99 int qpms_trans_calculator_get_AB_p(const qpms_trans_calculator *c,
100 complex double *Adest, complex double *Bdest,
101 qpms_m_t m, qpms_l_t n, qpms_m_t mu, qpms_l_t nu, csph_t kdlj,
102 bool r_ge_d, qpms_bessel_t J);
103 int qpms_trans_calculator_get_AB_arrays(const qpms_trans_calculator *c,
104 complex double *Adest, complex double *Bdest,
105 size_t deststride, size_t srcstride,
106 csph_t kdlj, bool r_ge_d, qpms_bessel_t J);
108 // TODO update the types later
109 complex double qpms_trans_calculator_get_A_ext(const qpms_trans_calculator *c,
110 int m, int n, int mu, int nu, complex double kdlj_r,
111 double kdlj_th, double kdlj_phi, int r_ge_d, int J);
113 complex double qpms_trans_calculator_get_B_ext(const qpms_trans_calculator *c,
114 int m, int n, int mu, int nu, complex double kdlj_r,
115 double kdlj_th, double kdlj_phi, int r_ge_d, int J);
117 int qpms_trans_calculator_get_AB_p_ext(const qpms_trans_calculator *c,
118 complex double *Adest, complex double *Bdest,
119 int m, int n, int mu, int nu, complex double kdlj_r,
120 double kdlj_th, double kdlj_phi, int r_ge_d, int J);
122 int qpms_trans_calculator_get_AB_arrays_ext(const qpms_trans_calculator *c,
123 complex double *Adest, complex double *Bdest,
124 size_t deststride, size_t srcstride,
125 complex double kdlj_r, double kdlj_theta, double kdlj_phi,
126 int r_ge_d, int J);
128 // Convenience functions using VSWF base specs
129 qpms_errno_t qpms_trans_calculator_get_trans_array(const qpms_trans_calculator *c,
130 complex double *target,
131 /// Must be destspec->lMax <= c-> lMax && destspec->norm == c->norm.
132 const qpms_vswf_set_spec_t *destspec, size_t deststride,
133 /// Must be srcspec->lMax <= c-> lMax && srcspec->norm == c->norm.
134 const qpms_vswf_set_spec_t *srcspec, size_t srcstride,
135 csph_t kdlj, bool r_ge_d, qpms_bessel_t J);
137 /// Version with \a k and cartesian particle positions
138 /// and with automatic \a r_ge_d = `false`.
139 qpms_errno_t qpms_trans_calculator_get_trans_array_lc3p(
140 const qpms_trans_calculator *c,
141 complex double *target,
142 /// Must be destspec->lMax <= c-> lMax && destspec->norm == c->norm.
143 const qpms_vswf_set_spec_t *destspec, size_t deststride,
144 /// Must be srcspec->lMax <= c-> lMax && srcspec->norm == c->norm.
145 const qpms_vswf_set_spec_t *srcspec, size_t srcstride,
146 complex double k, cart3_t destpos, cart3_t srcpos,
147 qpms_bessel_t J
148 /// Workspace has to be at least 2 * c->neleme**2 long
151 #ifdef LATTICESUMS32
152 // for the time being there are only those relatively low-level quick&dirty functions
153 // according to what has been implemented from ewald.h;
154 // TODO more high-level functions with more advanced lattice generators etc. (after
155 // the prerequisities from lattices2d.h are implememted)
158 int qpms_trans_calculator_get_AB_arrays_e32(const qpms_trans_calculator *c,
159 complex double *Adest, double *Aerr,
160 complex double *Bdest, double *Berr,
161 const ptrdiff_t deststride, const ptrdiff_t srcstride,
162 const double eta, const complex double wavenumber,
163 cart2_t b1, cart2_t b2,
164 const cart2_t beta,
165 const cart3_t particle_shift,
166 double maxR, double maxK
169 int qpms_trans_calculator_get_AB_arrays_e32_e(const qpms_trans_calculator *c,
170 complex double *Adest, double *Aerr,
171 complex double *Bdest, double *Berr,
172 const ptrdiff_t deststride, const ptrdiff_t srcstride,
173 const double eta, const complex double wavenumber,
174 cart2_t b1, cart2_t b2,
175 const cart2_t beta,
176 const cart3_t particle_shift,
177 double maxR, double maxK,
178 qpms_ewald_part parts
181 // Convenience functions using VSWF base specs
182 qpms_errno_t qpms_trans_calculator_get_trans_array_e32(const qpms_trans_calculator *c,
183 complex double *target, double *err,
184 /// Must be destspec->lMax <= c-> lMax && destspec->norm == c->norm.
185 const qpms_vswf_set_spec_t *destspec, size_t deststride,
186 /// Must be srcspec->lMax <= c-> lMax && srcspec->norm == c->norm.
187 const qpms_vswf_set_spec_t *srcspec, size_t srcstride,
188 const double eta, const complex double wavenumber,
189 cart2_t b1, cart2_t b2,
190 const cart2_t beta,
191 const cart3_t particle_shift,
192 double maxR, double maxK
195 qpms_errno_t qpms_trans_calculator_get_trans_array_e32_e(const qpms_trans_calculator *c,
196 complex double *target, double *err,
197 /// Must be destspec->lMax <= c-> lMax && destspec->norm == c->norm.
198 const qpms_vswf_set_spec_t *destspec, size_t deststride,
199 /// Must be srcspec->lMax <= c-> lMax && srcspec->norm == c->norm.
200 const qpms_vswf_set_spec_t *srcspec, size_t srcstride,
201 const double eta, const complex double wavenumber,
202 cart2_t b1, cart2_t b2,
203 const cart2_t beta,
204 const cart3_t particle_shift,
205 double maxR, double maxK,
206 qpms_ewald_part parts
209 #endif //LATTICESUMS32
211 #ifdef LATTICESUMS31
212 // e31z means that the particles are positioned along the z-axis;
213 // their positions and K-values are then denoted by a single z-coordinate
214 int qpms_trans_calculator_get_AB_arrays_e31z_both_points_and_shift(const qpms_trans_calculator *c,
215 complex double *Adest, double *Aerr,
216 complex double *Bdest, double *Berr,
217 const ptrdiff_t deststride, const ptrdiff_t srcstride,
218 const double eta, const double k,
219 const double unitcell_area, // just lattice period
220 const size_t nRpoints, const cart2_t *Rpoints,
221 const size_t nKpoints, const cart2_t *Kpoints,
222 const double beta,
223 const double particle_shift
225 #endif
230 #ifdef QPMS_COMPILE_PYTHON_EXTENSIONS
231 #include <Python.h>
232 #include <numpy/npy_common.h>
233 int qpms_cython_trans_calculator_get_AB_arrays_loop(
234 const qpms_trans_calculator *c, qpms_bessel_t J, const int resnd,
235 int daxis, int saxis,
236 char *A_data, const npy_intp *A_shape, const npy_intp *A_strides,
237 char *B_data, const npy_intp *B_shape, const npy_intp *B_strides,
238 const char *r_data, const npy_intp *r_shape, const npy_intp *r_strides,
239 const char *theta_data, const npy_intp *theta_shape, const npy_intp *theta_strides,
240 const char *phi_data, const npy_intp *phi_shape, const npy_intp *phi_strides,
241 const char *r_ge_d_data, const npy_intp *r_ge_d_shape, const npy_intp *r_ge_d_strides);
244 #endif //QPMS_COMPILE_PYTHON_EXTENSIONS
247 #endif // QPMS_TRANSLATIONS_H