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#+TITLE: Atomic Orbitals
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#+SETUPFILE: ../tools/theme.setup
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#+INCLUDE: ../tools/lib.org
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* Introduction
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The atomic basis set is defined as a list of shells. Each shell $s$ is
centered on a nucleus $A$, possesses a given angular momentum $l$ and a
radial function $R_s$. The radial function is a linear combination of
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/primitive/ functions that can be of type Slater ($p=1$) or
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Gaussian ($p=2$):
\[
R_s(\mathbf{r}) = \mathcal{N}_s |\mathbf{r}-\mathbf{R}_A|^{n_s}
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\sum_{k=1}^{N_{\text{prim}}} a_{ks}\, f_{ks}
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\exp \left( - \gamma_{ks} | \mathbf{r}-\mathbf{R}_A | ^p \right).
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\]
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In the case of Gaussian functions, $n_s$ is always zero. The
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normalization factor $\mathcal{N}_s$ ensures that all the functions of
the shell are normalized (integrate) to unity. Usually, basis sets are
given a combination of normalized primitives, so the normalization
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coefficients of the primitives, $f_{ks}$, need also to be provided.
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Atomic orbitals (AOs) are defined as
\[
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\chi_i (\mathbf{r}) = \mathcal{M}_i\, P_{\eta(i)}(\mathbf{r})\, R_{\theta(i)} (\mathbf{r})
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\]
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where $\theta(i)$ returns the shell on which the AO is expanded, and
$\eta(i)$ denotes which angular function is chosen and $P$ are the
generating functions of the given angular momentum $\eta(i)$. Here,
the parameter $\mathcal{M}_i$ is an extra parameter which allows the
normalization of the different functions of the same shell to be
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different, as in GAMESS for example.
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In this section we describe first how the basis set is stored in the
context, and then we present the kernels used to compute the values,
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gradients and Laplacian of the atomic basis functions.
* Headers :noexport:
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#+begin_src elisp :noexport :results none
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(org-babel-lob-ingest "../tools/lib.org")
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#+end_src
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#+begin_src c :tangle (eval h_private_func)
#ifndef QMCKL_AO_HPF
#define QMCKL_AO_HPF
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#include "qmckl_blas_private_type.h"
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#+end_src
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#+begin_src c :tangle (eval h_private_type)
#ifndef QMCKL_AO_HPT
#define QMCKL_AO_HPT
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#include <stdbool.h>
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#include <stdio.h>
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#include "qmckl_blas_private_type.h"
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#+end_src
#+begin_src f90 :tangle (eval f) :noweb yes
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#+end_src
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#+begin_src c :tangle (eval c_test) :noweb yes
#include "qmckl.h"
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#include "assert.h"
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#include <stdio.h>
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#include <math.h>
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#include <string.h>
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#include "chbrclf.h"
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#include "qmckl_ao_private_func.h"
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int main() {
qmckl_context context;
context = qmckl_context_create();
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#+end_src
#+begin_src c :tangle (eval c)
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#ifdef HAVE_STDINT_H
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#include <stdint.h>
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#elif HAVE_INTTYPES_H
#include <inttypes.h>
#endif
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#include <stdlib.h>
#include <string.h>
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#include <stdbool.h>
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#include <assert.h>
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#include <stdio.h>
#include <math.h>
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#include "qmckl.h"
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#include "qmckl_context_private_type.h"
#include "qmckl_memory_private_type.h"
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#include "qmckl_blas_private_type.h"
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#include "qmckl_memory_private_func.h"
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#include "qmckl_ao_private_type.h"
#include "qmckl_ao_private_func.h"
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#+end_src
* Context
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** Constant data
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The following arrays are stored in the context, and need to be set
when initializing the library:
#+NAME: constant_data
|---------------------+----------------------+----------------------------------------------------------------------|
| Variable | Type | Description |
|---------------------+----------------------+----------------------------------------------------------------------|
| ~type~ | ~char~ | Gaussian (~'G'~) or Slater (~'S'~) |
| ~shell_num~ | ~int64_t~ | Number of shells |
| ~prim_num~ | ~int64_t~ | Total number of primitives |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | Index of the first shell of each nucleus |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | Number of shells per nucleus |
| ~shell_ang_mom~ | ~int32_t[shell_num]~ | Angular momentum of each shell |
| ~shell_prim_num~ | ~int64_t[shell_num]~ | Number of primitives in each shell |
| ~shell_prim_index~ | ~int64_t[shell_num]~ | Address of the first primitive of each shell in the ~EXPONENT~ array |
| ~shell_factor~ | ~double[shell_num]~ | Normalization factor for each shell |
| ~exponent~ | ~double[prim_num]~ | Array of exponents |
| ~coefficient~ | ~double[prim_num]~ | Array of coefficients |
| ~prim_factor~ | ~double[prim_num]~ | Normalization factors of the primtives |
| ~ao_num~ | ~int64_t~ | Number of AOs |
| ~ao_cartesian~ | ~bool~ | If true, use polynomials. Otherwise, use spherical harmonics |
| ~ao_factor~ | ~double[ao_num]~ | Normalization factor of the AO |
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|---------------------+----------------------+----------------------------------------------------------------------|
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For H_2 with the following basis set,
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#+NAME: basis
#+BEGIN_EXAMPLE
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HYDROGEN
S 5
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1 3.387000E+01 6.068000E-03
2 5.095000E+00 4.530800E-02
3 1.159000E+00 2.028220E-01
4 3.258000E-01 5.039030E-01
5 1.027000E-01 3.834210E-01
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S 1
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1 3.258000E-01 1.000000E+00
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S 1
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1 1.027000E-01 1.000000E+00
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P 1
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1 1.407000E+00 1.000000E+00
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P 1
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1 3.880000E-01 1.000000E+00
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D 1
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1 1.057000E+00 1.0000000
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#+END_EXAMPLE
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we have:
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#+NAME: params
#+BEGIN_EXAMPLE
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type = 'G'
shell_num = 12
prim_num = 20
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ao_num = 38
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nucleus_index = [0 , 6]
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shell_ang_mom = [0, 0, 0, 1, 1, 2, 0, 0, 0, 1, 1, 2]
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shell_factor = [ 1., 1., 1., 1., 1., 1., 1., 1., 1., 1., 1., 1.]
shell_prim_num = [5, 1, 1, 1, 1, 1, 5, 1, 1, 1, 1, 1]
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shell_prim_index = [0 , 5 , 6 , 7 , 8 , 9 , 10, 15, 16, 17, 18, 19]
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exponent = [ 33.87, 5.095, 1.159, 0.3258, 0.1027, 0.3258, 0.1027, 1.407,
0.388, 1.057, 33.87, 5.095, 1.159, 0.3258, 0.1027, 0.3258, 0.1027, 1.407,
0.388, 1.057]
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coefficient = [ 0.006068, 0.045308, 0.202822, 0.503903, 0.383421, 1.0, 1.0,
1.0, 1.0, 1.0, 0.006068, 0.045308, 0.202822, 0.503903, 0.383421, 1.0, 1.0,
1.0, 1.0, 1.0]
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prim_factor = [ 1.0006253235944540e+01, 2.4169531573445120e+00, 7.9610924849766440e-01
3.0734305383061117e-01, 1.2929684417481876e-01, 3.0734305383061117e-01,
1.2929684417481876e-01, 2.1842769845268308e+00, 4.3649547399719840e-01,
1.8135965626177861e+00, 1.0006253235944540e+01, 2.4169531573445120e+00,
7.9610924849766440e-01, 3.0734305383061117e-01, 1.2929684417481876e-01,
3.0734305383061117e-01, 1.2929684417481876e-01, 2.1842769845268308e+00,
4.3649547399719840e-01, 1.8135965626177861e+00 ]
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#+END_EXAMPLE
A scalar variable ~$V$~ present in this table can be set or get by
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calling the functions:
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#+NAME: template_scalar_c
#+begin_src C :tangle no
qmckl_exit_code qmckl_set_ao_basis_$V$ ( qmckl_context context,
const $type_of_V$ $V$);
qmckl_exit_code qmckl_get_ao_basis_$V$ ( const qmckl_context context,
$type_of_V$ const $V$);
#+end_src
#+begin_src f90 :tangle no
interface
integer(c_int32_t) function qmckl_set_ao_basis_$V$ (context, $V$) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
$f_type_of_V$ , intent(in) , value :: $V$
end function qmckl_set_ao_basis_$V$
end interface
interface
integer(c_int32_t) function qmckl_get_ao_basis_$V$ (context, $V$) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
$f_type_of_V$ , intent(out) :: $V$
end function qmckl_get_ao_basis_$V$
end interface
#+end_src
For array variables, use the rule:
#+NAME: template_array_c
#+begin_src C :tangle no
qmckl_exit_code qmckl_set_ao_basis_$V$ ( qmckl_context context,
const $type_of_V$ $V$,
const int64_t size_max);
qmckl_exit_code qmckl_get_ao_basis_$V$ ( const qmckl_context context,
$type_of_V$ const $V$,
const int64_t size_max);
#+end_src
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#+begin_src f90 :tangle no
interface
integer(c_int32_t) function qmckl_set_ao_basis_$V$ (context, &
$V$, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
$f_type_of_V$ , intent(in) , value :: $V$
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_$V$
end interface
interface
integer(c_int32_t) function qmckl_get_ao_basis_$V$ (context, &
$V$, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
$f_type_of_V$ , intent(out) :: $V$
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_get_ao_basis_$V$
end interface
#+end_src
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*** Data structure :noexport:
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#+begin_src c :comments org :tangle (eval h_private_type) :noweb yes
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typedef struct qmckl_ao_basis_struct {
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int64_t shell_num;
int64_t prim_num;
int64_t ao_num;
int64_t * restrict nucleus_index;
int64_t * restrict nucleus_shell_num;
int32_t * restrict shell_ang_mom;
int64_t * restrict shell_prim_num;
int64_t * restrict shell_prim_index;
double * restrict shell_factor;
double * restrict exponent;
double * restrict coefficient;
double * restrict prim_factor;
double * restrict ao_factor;
int64_t * restrict nucleus_prim_index;
double * restrict coefficient_normalized;
int32_t * restrict nucleus_max_ang_mom;
double * restrict nucleus_range;
double * restrict primitive_vgl;
uint64_t primitive_vgl_date;
double * restrict shell_vgl;
uint64_t shell_vgl_date;
double * restrict ao_vgl;
uint64_t ao_vgl_date;
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double * restrict ao_value;
uint64_t ao_value_date;
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int32_t uninitialized;
bool provided;
bool ao_cartesian;
char type;
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#ifdef HAVE_HPC
<<HPC_struct>>
#endif
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} qmckl_ao_basis_struct;
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#+end_src
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The ~uninitialized~ integer contains one bit set to one for each
initialization function which has not been called. It becomes equal
to zero after all initialization functions have been called. The
struct is then initialized and ~provided == true~.
Some values are initialized by default, and are not concerned by
this mechanism.
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#+begin_src c :comments org :tangle (eval h_private_func)
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qmckl_exit_code qmckl_init_ao_basis(qmckl_context context);
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#+end_src
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
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#+begin_src c :comments org :tangle (eval c)
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qmckl_exit_code qmckl_init_ao_basis(qmckl_context context) {
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_init_ao_basis",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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ctx->ao_basis.uninitialized = (1 << 14) - 1;
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/* Default values */
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ctx->ao_basis.ao_cartesian = true;
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return QMCKL_SUCCESS;
}
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#+end_src
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
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*** Initialization functions
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~size_max~ is the dimension of the input array, which should be
equal of larger than the value given in the table of section [[Context]].
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**** C interface
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#+NAME:pre2
#+begin_src c :exports none
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_NULL_CONTEXT,
"qmckl_set_ao_*",
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NULL);
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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if (mask != 0 && !(ctx->ao_basis.uninitialized & mask)) {
return qmckl_failwith( context,
QMCKL_ALREADY_SET,
"qmckl_set_ao_*",
NULL);
}
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#+end_src
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#+NAME:post2
#+begin_src c :exports none
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ctx->ao_basis.uninitialized &= ~mask;
ctx->ao_basis.provided = (ctx->ao_basis.uninitialized == 0);
if (ctx->ao_basis.provided) {
qmckl_exit_code rc_ = qmckl_finalize_basis(context);
if (rc_ != QMCKL_SUCCESS) return rc_;
}
return QMCKL_SUCCESS;
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#+end_src
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To set the basis set, all the following functions need to be
called.
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_type (qmckl_context context,
const char basis_type);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_type(qmckl_context context,
const char basis_type)
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{
int32_t mask = 1;
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<<pre2>>
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if (basis_type != 'G' && basis_type != 'S') {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_type",
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NULL);
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}
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ctx->ao_basis.type = basis_type;
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<<post2>>
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_shell_num (qmckl_context context,
const int64_t shell_num);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_shell_num (qmckl_context context,
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const int64_t shell_num)
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{
int32_t mask = 1 << 1;
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<<pre2>>
if (shell_num <= 0) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"shell_num <= 0");
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}
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const int64_t prim_num = ctx->ao_basis.prim_num;
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if (0L < prim_num && prim_num < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"shell_num > prim_num");
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}
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ctx->ao_basis.shell_num = shell_num;
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<<post2>>
}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_prim_num (qmckl_context context,
const int64_t prim_num);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_prim_num (qmckl_context context,
const int64_t prim_num)
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{
int32_t mask = 1 << 2;
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<<pre2>>
if (prim_num <= 0) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"prim_num must be positive");
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}
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const int64_t shell_num = ctx->ao_basis.shell_num;
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if (shell_num <= 0L) {
return qmckl_failwith( context,
QMCKL_FAILURE,
"qmckl_set_ao_basis_shell_num",
"shell_num is not set");
}
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if (prim_num < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"prim_num < shell_num");
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}
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ctx->ao_basis.prim_num = prim_num;
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<<post2>>
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_set_ao_basis_nucleus_shell_num (qmckl_context context,
const int64_t* nucleus_shell_num,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_set_ao_basis_nucleus_shell_num (qmckl_context context,
const int64_t* nucleus_shell_num,
const int64_t size_max)
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{
int32_t mask = 1 << 3;
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<<pre2>>
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const int64_t nucl_num = ctx->nucleus.num;
if (nucl_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_nucleus_shell_num",
"shell_num is not set");
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}
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if (size_max < nucl_num) {
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return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_set_ao_basis_nucleus_shell_num",
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"input array too small");
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}
if (ctx->ao_basis.nucleus_shell_num != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.nucleus_shell_num);
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if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_nucleus_shell_num",
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NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = nucl_num * sizeof(int64_t);
int64_t* new_array = (int64_t*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_nucleus_shell_num",
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NULL);
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}
memcpy(new_array, nucleus_shell_num, mem_info.size);
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ctx->ao_basis.nucleus_shell_num = new_array;
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<<post2>>
}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_set_ao_basis_nucleus_index (qmckl_context context,
const int64_t* nucleus_index,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_set_ao_basis_nucleus_index (qmckl_context context,
const int64_t* nucleus_index,
const int64_t size_max)
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{
int32_t mask = 1 << 4;
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<<pre2>>
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const int64_t nucl_num = ctx->nucleus.num;
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if (nucl_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_nucleus_index",
"nucl_num is not set");
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}
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if (size_max < nucl_num) {
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return qmckl_failwith( context,
QMCKL_FAILURE,
"qmckl_set_ao_basis_nucleus_index",
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"input array too small");
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}
if (ctx->ao_basis.nucleus_index != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.nucleus_index);
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if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_nucleus_index",
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NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = nucl_num * sizeof(int64_t);
int64_t* new_array = (int64_t*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_nucleus_index",
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NULL);
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}
memcpy(new_array, nucleus_index, mem_info.size);
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ctx->ao_basis.nucleus_index = new_array;
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<<post2>>
}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_shell_ang_mom (qmckl_context context,
const int32_t* shell_ang_mom,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_shell_ang_mom (qmckl_context context,
const int32_t* shell_ang_mom,
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const int64_t size_max)
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{
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int32_t mask = 1 << 5;
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<<pre2>>
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const int64_t shell_num = ctx->ao_basis.shell_num;
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if (shell_num == 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_shell_ang_mom",
"shell_num is not set");
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}
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if (size_max < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_shell_ang_mom",
"input array too small");
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}
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if (ctx->ao_basis.shell_ang_mom != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.shell_ang_mom);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_shell_ang_mom",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = shell_num * sizeof(int32_t);
int32_t * new_array = (int32_t*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_shell_ang_mom",
NULL);
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}
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memcpy(new_array, shell_ang_mom, mem_info.size);
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ctx->ao_basis.shell_ang_mom = new_array;
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<<post2>>
}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_shell_prim_num (qmckl_context context,
const int64_t* shell_prim_num,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_shell_prim_num (qmckl_context context,
const int64_t* shell_prim_num,
const int64_t size_max)
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{
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int32_t mask = 1 << 6;
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<<pre2>>
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const int64_t shell_num = ctx->ao_basis.shell_num;
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if (shell_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_shell_prim_num",
"shell_num is not set");
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}
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if (size_max < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_shell_prim_num",
"input array too small");
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}
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if (ctx->ao_basis.shell_prim_num != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.shell_prim_num);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_shell_prim_num",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = shell_num * sizeof(int64_t);
int64_t* new_array = (int64_t*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_shell_prim_num",
NULL);
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}
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memcpy(new_array, shell_prim_num, mem_info.size);
ctx->ao_basis.shell_prim_num = new_array;
<<post2>>
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_shell_prim_index (qmckl_context context,
const int64_t* shell_prim_index,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_shell_prim_index (qmckl_context context,
const int64_t* shell_prim_index,
const int64_t size_max)
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{
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int32_t mask = 1 << 7;
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<<pre2>>
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const int64_t shell_num = ctx->ao_basis.shell_num;
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if (shell_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_shell_prim_index",
"shell_num is not set");
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}
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if (size_max < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_shell_prim_index",
"input array too small");
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}
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if (ctx->ao_basis.shell_prim_index != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.shell_prim_index);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_shell_prim_index",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = shell_num * sizeof(int64_t);
int64_t* new_array = (int64_t*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_shell_prim_index",
NULL);
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}
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memcpy(new_array, shell_prim_index, mem_info.size);
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ctx->ao_basis.shell_prim_index = new_array;
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<<post2>>
}
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_shell_factor (qmckl_context context,
const double* shell_factor,
const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_shell_factor (qmckl_context context,
const double* shell_factor,
const int64_t size_max)
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{
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int32_t mask = 1 << 8;
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<<pre2>>
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const int64_t shell_num = ctx->ao_basis.shell_num;
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if (shell_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_shell_factor",
"shell_num is not set");
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}
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if (size_max < shell_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_shell_factor",
"input array too small");
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}
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if (ctx->ao_basis.shell_factor != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.shell_factor);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_shell_factor",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = shell_num * sizeof(double);
double* new_array = (double*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_shell_factor",
NULL);
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}
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memcpy(new_array, shell_factor, mem_info.size);
ctx->ao_basis.shell_factor = new_array;
<<post2>>
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}
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_exponent (qmckl_context context,
const double* exponent,
const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_exponent (qmckl_context context,
const double* exponent,
const int64_t size_max)
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{
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int32_t mask = 1 << 9;
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<<pre2>>
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const int64_t prim_num = ctx->ao_basis.prim_num;
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if (prim_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_exponent",
"prim_num is not set");
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}
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if (size_max < prim_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_exponent",
"input array too small");
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}
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if (ctx->ao_basis.exponent != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.exponent);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_exponent",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = prim_num * sizeof(double);
double* new_array = (double*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_exponent",
NULL);
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}
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memcpy(new_array, exponent, mem_info.size);
ctx->ao_basis.exponent = new_array;
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<<post2>>
}
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#+end_src
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2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_coefficient (qmckl_context context,
const double* coefficient,
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const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_coefficient (qmckl_context context,
const double* coefficient,
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const int64_t size_max)
{
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int32_t mask = 1 << 10;
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<<pre2>>
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const int64_t prim_num = ctx->ao_basis.prim_num;
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if (prim_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_coefficient",
"prim_num is not set");
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}
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if (size_max < prim_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_coefficient",
"input array too small");
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}
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if (ctx->ao_basis.coefficient != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.coefficient);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_coefficient",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = prim_num * sizeof(double);
double* new_array = (double*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_coefficient",
NULL);
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}
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memcpy(new_array, coefficient, mem_info.size);
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ctx->ao_basis.coefficient = new_array;
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<<post2>>
}
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#+end_src
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2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
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qmckl_set_ao_basis_prim_factor (qmckl_context context,
const double* prim_factor,
const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_prim_factor (qmckl_context context,
const double* prim_factor,
const int64_t size_max)
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{
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int32_t mask = 1 << 11;
<<pre2>>
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const int64_t prim_num = ctx->ao_basis.prim_num;
if (prim_num <= 0L) {
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return qmckl_failwith( context,
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QMCKL_FAILURE,
"qmckl_set_ao_basis_prim_factor",
"prim_num is not set");
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}
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if (size_max < prim_num) {
return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_prim_factor",
"input array too small");
}
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if (ctx->ao_basis.prim_factor != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.prim_factor);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_prim_factor",
NULL);
}
}
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = prim_num * sizeof(double);
double* new_array = (double*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
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QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_prim_factor",
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NULL);
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}
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memcpy(new_array, prim_factor, mem_info.size);
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ctx->ao_basis.prim_factor = new_array;
<<post2>>
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
qmckl_exit_code
qmckl_set_ao_basis_ao_num (qmckl_context context,
const int64_t ao_num);
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_set_ao_basis_ao_num (qmckl_context context,
const int64_t ao_num)
{
int32_t mask = 1 << 12;
<<pre2>>
if (ao_num <= 0) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"ao_num must be positive");
}
const int64_t shell_num = ctx->ao_basis.shell_num;
if (shell_num <= 0L) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"shell_num is not set");
}
if (ao_num < shell_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_set_ao_basis_shell_num",
"ao_num < shell_num");
}
ctx->ao_basis.ao_num = ao_num;
<<post2>>
}
#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_set_ao_basis_ao_factor (qmckl_context context,
const double* ao_factor,
const int64_t size_max);
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#+end_src
2021-10-14 16:32:58 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
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qmckl_set_ao_basis_ao_factor (qmckl_context context,
const double* ao_factor,
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const int64_t size_max)
2022-01-06 02:28:13 +01:00
{
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int32_t mask = 1 << 13;
<<pre2>>
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const int64_t ao_num = ctx->ao_basis.ao_num;
if (ao_num <= 0L) {
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return qmckl_failwith( context,
2022-01-05 12:26:11 +01:00
QMCKL_FAILURE,
"qmckl_set_ao_basis_ao_factor",
"ao_num is not set");
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}
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if (size_max < ao_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_set_ao_basis_ao_factor",
"input array too small");
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}
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if (ctx->ao_basis.ao_factor != NULL) {
qmckl_exit_code rc = qmckl_free(context, ctx->ao_basis.ao_factor);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc,
"qmckl_set_ao_basis_ao_factor",
NULL);
}
}
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ao_num * sizeof(double);
double* new_array = (double*) qmckl_malloc(context, mem_info);
if (new_array == NULL) {
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return qmckl_failwith( context,
2022-01-05 12:26:11 +01:00
QMCKL_ALLOCATION_FAILED,
"qmckl_set_ao_basis_ao_factor",
NULL);
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}
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memcpy(new_array, ao_factor, mem_info.size);
ctx->ao_basis.ao_factor = new_array;
<<post2>>
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}
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#+end_src
2021-10-14 16:32:58 +02:00
2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_set_ao_basis_cartesian (qmckl_context context,
const bool cartesian);
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#+end_src
2021-07-09 00:45:17 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
2022-01-05 12:26:11 +01:00
qmckl_exit_code
qmckl_set_ao_basis_cartesian (qmckl_context context,
const bool cartesian)
{
int32_t mask = 1;
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<<pre2>>
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2022-01-06 02:28:13 +01:00
ctx->ao_basis.ao_cartesian = cartesian;
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<<post2>>
}
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#+end_src
2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
**** Fortran interface
#+begin_src f90 :tangle (eval fh_func) :comments org
interface
integer(c_int32_t) function qmckl_set_ao_basis_type (context, &
basis_type) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
character(c_char) , intent(in) , value :: basis_type
end function qmckl_set_ao_basis_type
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_shell_num(context, &
num) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: num
end function qmckl_set_ao_basis_shell_num
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_prim_num(context, &
num) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: num
end function qmckl_set_ao_basis_prim_num
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_nucleus_index(context, &
idx, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) :: idx(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_nucleus_index
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_nucleus_shell_num(context, &
shell_num, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) :: shell_num(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_nucleus_shell_num
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_shell_ang_mom(context, &
shell_ang_mom, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int32_t) , intent(in) :: shell_ang_mom(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_shell_ang_mom
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_shell_prim_num(context, &
shell_prim_num, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) :: shell_prim_num(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_shell_prim_num
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_shell_prim_index(context, &
shell_prim_index, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) :: shell_prim_index(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_shell_prim_index
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_shell_factor(context, &
shell_factor, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: shell_factor(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_shell_factor
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_exponent(context, &
exponent, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: exponent(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_exponent
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_coefficient(context, &
coefficient, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: coefficient(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_coefficient
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_prim_factor(context, &
prim_factor, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: prim_factor(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_prim_factor
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_ao_num(context, &
num) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: num
end function qmckl_set_ao_basis_ao_num
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_cartesian(context, &
cartesian) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
logical (c_bool) , intent(in) , value :: cartesian
end function qmckl_set_ao_basis_cartesian
end interface
interface
integer(c_int32_t) function qmckl_set_ao_basis_ao_factor(context, &
ao_factor, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: ao_factor(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_set_ao_basis_ao_factor
end interface
#+end_src
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*** Access functions
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~size_max~ is the dimension of the input array, which should be
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equal of larger than the value given in the table of section [[Context]].
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**** C interface
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_type (const qmckl_context context,
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char* const basis_type);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_type (const qmckl_context context,
char* const basis_type)
{
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_type",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1;
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_type",
NULL);
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}
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assert (ctx->ao_basis.type != (char) 0);
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basis_type[0] = ctx->ao_basis.type;
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_shell_num (const qmckl_context context,
int64_t* const shell_num);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_shell_num (const qmckl_context context,
int64_t* const shell_num)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_factor",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 1;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_shell_num",
NULL);
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}
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assert (ctx->ao_basis.shell_num > (int64_t) 0);
,*shell_num = ctx->ao_basis.shell_num;
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_prim_num (const qmckl_context context,
int64_t* const prim_num);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_prim_num (const qmckl_context context,
int64_t* const prim_num)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_prim_num",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 2;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_prim_num",
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NULL);
}
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assert (ctx->ao_basis.prim_num > (int64_t) 0);
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,*prim_num = ctx->ao_basis.prim_num;
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_nucleus_shell_num (const qmckl_context context,
int64_t* const nucleus_shell_num,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_nucleus_shell_num (const qmckl_context context,
int64_t* const nucleus_shell_num,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_nucleus_shell_num",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 3;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_nucleus_shell_num",
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NULL);
}
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if (nucleus_shell_num == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_nucleus_shell_num",
"NULL pointer");
}
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if (size_max < ctx->nucleus.num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_nucleus_shell_num",
"Array too small. Expected nucl_num");
}
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assert (ctx->ao_basis.nucleus_shell_num != NULL);
memcpy(nucleus_shell_num, ctx->ao_basis.nucleus_shell_num,
(size_t) ctx->nucleus.num * sizeof(int64_t));
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_nucleus_index (const qmckl_context context,
int64_t* const nucleus_index,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_nucleus_index (const qmckl_context context,
int64_t* const nucleus_index,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_nucleus_index",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 4;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_nucleus_index",
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NULL);
}
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if (nucleus_index == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_nucleus_index",
"NULL pointer");
}
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if (size_max < ctx->nucleus.num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_nucleus_index",
"Array too small. Expected shell_num");
}
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assert (ctx->ao_basis.nucleus_index != NULL);
memcpy(nucleus_index, ctx->ao_basis.nucleus_index,
(size_t) ctx->nucleus.num * sizeof(int64_t));
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_shell_ang_mom (const qmckl_context context,
int32_t* const shell_ang_mom,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_shell_ang_mom (const qmckl_context context,
int32_t* const shell_ang_mom,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_ang_mom",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 5;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_shell_ang_mom",
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NULL);
}
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if (shell_ang_mom == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_shell_ang_mom",
"NULL pointer");
}
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if (size_max < ctx->ao_basis.shell_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_shell_ang_mom",
"Array too small. Expected shell_num");
}
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assert (ctx->ao_basis.shell_ang_mom != NULL);
memcpy(shell_ang_mom, ctx->ao_basis.shell_ang_mom,
(size_t) ctx->ao_basis.shell_num * sizeof(int32_t));
return QMCKL_SUCCESS;
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}
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#+end_src
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#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_shell_prim_num (const qmckl_context context,
int64_t* const shell_prim_num,
const int64_t size_max);
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_shell_prim_num (const qmckl_context context,
int64_t* const shell_prim_num,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_prim_num",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 6;
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if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_shell_prim_num",
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NULL);
}
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if (shell_prim_num == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_shell_prim_num",
"NULL pointer");
}
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if (size_max < ctx->ao_basis.shell_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_shell_prim_num",
"Array too small. Expected shell_num");
}
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assert (ctx->ao_basis.shell_prim_num != NULL);
memcpy(shell_prim_num, ctx->ao_basis.shell_prim_num,
(size_t) ctx->ao_basis.shell_num * sizeof(int64_t));
return QMCKL_SUCCESS;
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}
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#+end_src
2021-04-01 01:19:33 +02:00
2021-10-14 16:32:58 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_shell_prim_index (const qmckl_context context,
int64_t* const shell_prim_index,
const int64_t size_max);
2022-01-05 15:56:25 +01:00
#+end_src
2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_shell_prim_index (const qmckl_context context,
int64_t* const shell_prim_index,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_prim_index",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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2022-01-05 12:26:11 +01:00
int32_t mask = 1 << 7;
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2022-01-05 12:26:11 +01:00
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_shell_prim_index",
2021-04-01 01:19:33 +02:00
NULL);
}
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if (shell_prim_index == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_shell_prim_index",
"NULL pointer");
}
2021-04-30 01:26:19 +02:00
2022-01-05 12:26:11 +01:00
if (size_max < ctx->ao_basis.shell_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_shell_prim_index",
"Array too small. Expected shell_num");
}
2021-04-01 01:19:33 +02:00
2022-01-05 12:26:11 +01:00
assert (ctx->ao_basis.shell_prim_index != NULL);
memcpy(shell_prim_index, ctx->ao_basis.shell_prim_index,
(size_t) ctx->ao_basis.shell_num * sizeof(int64_t));
return QMCKL_SUCCESS;
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}
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#+end_src
2021-04-30 01:26:19 +02:00
2021-04-01 01:19:33 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_shell_factor (const qmckl_context context,
double* const shell_factor,
const int64_t size_max);
2022-01-05 15:56:25 +01:00
#+end_src
2021-10-14 16:32:58 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_shell_factor (const qmckl_context context,
double* const shell_factor,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_factor",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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2022-01-05 12:26:11 +01:00
int32_t mask = 1 << 8;
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2022-01-05 12:26:11 +01:00
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_shell_factor",
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NULL);
}
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if (shell_factor == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_shell_factor",
"NULL pointer");
}
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2022-01-05 12:26:11 +01:00
if (size_max < ctx->ao_basis.shell_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_shell_factor",
"Array too small. Expected shell_num");
}
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assert (ctx->ao_basis.shell_factor != NULL);
memcpy(shell_factor, ctx->ao_basis.shell_factor,
(size_t) ctx->ao_basis.shell_num * sizeof(double));
return QMCKL_SUCCESS;
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}
2021-04-30 01:26:19 +02:00
2021-04-01 01:19:33 +02:00
2022-01-05 15:56:25 +01:00
#+end_src
2021-04-01 01:19:33 +02:00
2021-10-14 16:32:58 +02:00
2022-01-06 02:28:13 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_exponent (const qmckl_context context,
double* const exponent,
const int64_t size_max);
2022-01-05 15:56:25 +01:00
#+end_src
2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_exponent (const qmckl_context context,
double* const exponent,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_exponent",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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2022-01-05 12:26:11 +01:00
int32_t mask = 1 << 9;
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2022-01-05 12:26:11 +01:00
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_exponent",
2021-04-01 01:19:33 +02:00
NULL);
}
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if (exponent == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_exponent",
"NULL pointer");
}
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2022-01-05 12:26:11 +01:00
if (size_max < ctx->ao_basis.prim_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_exponent",
"Array too small. Expected prim_num");
}
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assert (ctx->ao_basis.exponent != NULL);
memcpy(exponent, ctx->ao_basis.exponent,
(size_t) ctx->ao_basis.prim_num * sizeof(double));
return QMCKL_SUCCESS;
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}
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#+end_src
2021-04-30 01:26:19 +02:00
2021-06-03 18:26:00 +02:00
2022-01-06 02:28:13 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_coefficient (const qmckl_context context,
double* const coefficient,
const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_coefficient (const qmckl_context context,
double* const coefficient,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_coefficient",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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2022-01-05 12:26:11 +01:00
int32_t mask = 1 << 10;
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
return qmckl_failwith( context,
QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_coefficient",
NULL);
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}
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if (coefficient == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_coefficient",
"NULL pointer");
}
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2022-01-05 12:26:11 +01:00
if (size_max < ctx->ao_basis.prim_num) {
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return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_coefficient",
"Array too small. Expected prim_num");
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}
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assert (ctx->ao_basis.coefficient != NULL);
memcpy(coefficient, ctx->ao_basis.coefficient,
(size_t) ctx->ao_basis.prim_num * sizeof(double));
return QMCKL_SUCCESS;
}
2021-06-03 18:26:00 +02:00
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#+end_src
2021-06-03 18:26:00 +02:00
2022-01-05 12:26:11 +01:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_prim_factor (const qmckl_context context,
double* const prim_factor,
const int64_t size_max);
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#+end_src
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2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_prim_factor (const qmckl_context context,
double* const prim_factor,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_prim_factor",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
int32_t mask = 1 << 11;
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_prim_factor",
NULL);
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}
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2022-01-05 12:26:11 +01:00
if (prim_factor == NULL) {
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return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
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"qmckl_get_ao_basis_prim_factor",
"NULL pointer");
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}
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if (size_max < ctx->ao_basis.prim_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_prim_factor",
"Array too small. Expected prim_num");
}
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assert (ctx->ao_basis.prim_factor != NULL);
memcpy(prim_factor, ctx->ao_basis.prim_factor,
(size_t) ctx->ao_basis.prim_num * sizeof(double));
return QMCKL_SUCCESS;
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}
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#+end_src
2021-07-09 00:45:17 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_ao_num (const qmckl_context context,
int64_t* const ao_num);
2022-01-05 15:56:25 +01:00
#+end_src
2021-10-14 16:32:58 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_ao_num (const qmckl_context context,
int64_t* const ao_num)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
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QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_ao_num",
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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2022-01-05 12:26:11 +01:00
int32_t mask = 1 << 12;
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2022-01-05 12:26:11 +01:00
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
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return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_ao_num",
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NULL);
}
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assert (ctx->ao_basis.ao_num > (int64_t) 0);
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*ao_num = ctx->ao_basis.ao_num;
return QMCKL_SUCCESS;
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}
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#+end_src
2021-04-01 01:19:33 +02:00
2021-06-10 00:10:19 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
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qmckl_exit_code
qmckl_get_ao_basis_ao_factor (const qmckl_context context,
double* const ao_factor,
const int64_t size_max);
2022-01-05 15:56:25 +01:00
#+end_src
2021-06-10 00:10:19 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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qmckl_exit_code
qmckl_get_ao_basis_ao_factor (const qmckl_context context,
double* const ao_factor,
const int64_t size_max)
{
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
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return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
2022-01-05 12:26:11 +01:00
"qmckl_get_ao_basis_ao_factor",
2021-10-14 16:32:58 +02:00
NULL);
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}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int32_t mask = 1 << 13;
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2022-01-05 12:26:11 +01:00
if ( (ctx->ao_basis.uninitialized & mask) != 0) {
return qmckl_failwith( context,
QMCKL_NOT_PROVIDED,
"qmckl_get_ao_basis_ao_factor",
NULL);
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}
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if (ao_factor == NULL) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_2,
"qmckl_get_ao_basis_ao_factor",
"NULL pointer");
2021-06-10 22:57:59 +02:00
}
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if (size_max < ctx->ao_basis.ao_num) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_ao_factor",
"Array too small. Expected ao_num");
}
2021-07-08 19:20:19 +02:00
2022-01-05 12:26:11 +01:00
assert (ctx->ao_basis.ao_factor != NULL);
memcpy(ao_factor, ctx->ao_basis.ao_factor, ctx->ao_basis.ao_num * sizeof(double));
return QMCKL_SUCCESS;
}
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#+end_src
2022-01-05 15:56:25 +01:00
When all the data for the AOs have been provided, the following
function returns ~true~.
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval h_func)
2022-01-05 12:26:11 +01:00
bool qmckl_ao_basis_provided (const qmckl_context context);
2022-01-05 15:56:25 +01:00
#+end_src
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
2022-01-05 15:56:25 +01:00
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
2022-01-05 12:26:11 +01:00
bool qmckl_ao_basis_provided(const qmckl_context context) {
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2022-01-05 12:26:11 +01:00
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return false;
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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return ctx->ao_basis.provided;
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}
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#+end_src
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
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**** Fortran interface
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#+begin_src f90 :tangle (eval fh_func) :comments org
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_type (context, &
basis_type) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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character(c_char) , intent(out) :: basis_type
end function qmckl_get_ao_basis_type
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_num(context, &
num) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: num
end function qmckl_get_ao_basis_shell_num
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_prim_num(context, &
num) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: num
end function qmckl_get_ao_basis_prim_num
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_nucleus_shell_num(context, &
shell_num, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: shell_num(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_nucleus_shell_num
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_nucleus_index(context, &
idx, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: idx(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_nucleus_index
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_ang_mom(context, &
shell_ang_mom, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int32_t) , intent(out) :: shell_ang_mom(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_shell_ang_mom
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_prim_num(context, &
shell_prim_num, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: shell_prim_num(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_shell_prim_num
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_prim_index(context, &
shell_prim_index, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: shell_prim_index(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_shell_prim_index
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_factor(context, &
shell_factor, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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real (c_double) , intent(out) :: shell_factor(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_shell_factor
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_exponent(context, &
exponent, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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real (c_double) , intent(out) :: exponent(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_exponent
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_coefficient(context, &
coefficient, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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real (c_double) , intent(out) :: coefficient(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_coefficient
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_prim_factor(context, &
prim_factor, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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real (c_double) , intent(out) :: prim_factor(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_prim_factor
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_ao_num(context, &
num) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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integer (c_int64_t) , intent(out) :: num
end function qmckl_get_ao_basis_ao_num
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_cartesian(context, &
cartesian) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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logical (c_bool) , intent(out) :: cartesian
end function qmckl_get_ao_basis_cartesian
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end interface
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interface
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integer(c_int32_t) function qmckl_get_ao_basis_ao_factor(context, &
ao_factor, size_max) bind(C)
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use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
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real (c_double) , intent(out) :: ao_factor(*)
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integer (c_int64_t) , intent(in) , value :: size_max
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end function qmckl_get_ao_basis_ao_factor
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end interface
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#+end_src
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*** Test :noexport:
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#+begin_src c :tangle (eval c_test) :exports none :exports none
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const int64_t nucl_num = chbrclf_nucl_num;
const double* nucl_charge = chbrclf_charge;
const double* nucl_coord = &(chbrclf_nucl_coord[0][0]);
qmckl_exit_code rc;
rc = qmckl_set_nucleus_num (context, nucl_num);
assert(rc == QMCKL_SUCCESS);
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rc = qmckl_set_nucleus_coord (context, 'T', &(nucl_coord[0]), 3*nucl_num);
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assert(rc == QMCKL_SUCCESS);
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rc = qmckl_set_nucleus_charge(context, nucl_charge, nucl_num);
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assert(rc == QMCKL_SUCCESS);
assert(qmckl_nucleus_provided(context));
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const int64_t shell_num = chbrclf_shell_num;
const int64_t prim_num = chbrclf_prim_num;
const int64_t ao_num = chbrclf_ao_num;
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const int64_t * nucleus_index = &(chbrclf_basis_nucleus_index[0]);
const int64_t * nucleus_shell_num = &(chbrclf_basis_nucleus_shell_num[0]);
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const int32_t * shell_ang_mom = &(chbrclf_basis_shell_ang_mom[0]);
const int64_t * shell_prim_num = &(chbrclf_basis_shell_prim_num[0]);
const int64_t * shell_prim_index = &(chbrclf_basis_shell_prim_index[0]);
const double * shell_factor = &(chbrclf_basis_shell_factor[0]);
const double * exponent = &(chbrclf_basis_exponent[0]);
const double * coefficient = &(chbrclf_basis_coefficient[0]);
const double * prim_factor = &(chbrclf_basis_prim_factor[0]);
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const double * ao_factor = &(chbrclf_basis_ao_factor[0]);
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const char typ = 'G';
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assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_type (context, typ);
assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_shell_num (context, shell_num);
assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_prim_num (context, prim_num);
assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_nucleus_index (context, nucleus_index, nucl_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_nucleus_index (context, nucleus_index, nucl_num);
assert(rc == QMCKL_ALREADY_SET);
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rc = qmckl_set_ao_basis_nucleus_shell_num (context, nucleus_shell_num, nucl_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_shell_ang_mom (context, shell_ang_mom, shell_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_shell_factor (context, shell_factor, shell_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_shell_prim_num (context, shell_prim_num, shell_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_shell_prim_index (context, shell_prim_index, shell_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_exponent (context, exponent, prim_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_coefficient (context, coefficient, prim_num);
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assert(rc == QMCKL_SUCCESS);
assert(!qmckl_ao_basis_provided(context));
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rc = qmckl_set_ao_basis_prim_factor (context, prim_factor, prim_num);
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assert(rc == QMCKL_SUCCESS);
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rc = qmckl_set_ao_basis_ao_num(context, ao_num);
assert(rc == QMCKL_SUCCESS);
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rc = qmckl_set_ao_basis_ao_factor (context, ao_factor, ao_num);
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assert(rc == QMCKL_SUCCESS);
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assert(qmckl_ao_basis_provided(context));
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int64_t shell_num_test ;
int64_t prim_num_test ;
int64_t ao_num_test ;
int64_t * nucleus_index_test ;
int64_t * nucleus_shell_num_test;
int32_t * shell_ang_mom_test ;
int64_t * shell_prim_num_test ;
int64_t * shell_prim_index_test ;
double * shell_factor_test ;
double * exponent_test ;
double * coefficient_test ;
double * prim_factor_test ;
double * ao_factor_test ;
char typ_test ;
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rc = qmckl_get_ao_basis_type (context, &typ_test);
assert (rc == QMCKL_SUCCESS);
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assert(typ == typ_test);
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rc = qmckl_get_ao_basis_shell_num (context, &shell_num_test);
assert (rc == QMCKL_SUCCESS);
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assert(shell_num == shell_num_test);
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rc = qmckl_get_ao_basis_prim_num (context, &prim_num_test);
assert (rc == QMCKL_SUCCESS);
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assert(prim_num == prim_num_test);
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nucleus_index_test = (int64_t*) malloc (nucl_num * sizeof(int64_t));
rc = qmckl_get_ao_basis_nucleus_index (context, nucleus_index_test, nucl_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < nucl_num ; ++i) {
assert(nucleus_index_test[i] == nucleus_index[i]);
}
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free(nucleus_index_test);
nucleus_shell_num_test = (int64_t*) malloc ( nucl_num * sizeof(int64_t));
rc = qmckl_get_ao_basis_nucleus_shell_num (context, nucleus_shell_num_test, nucl_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < nucl_num ; ++i) {
assert(nucleus_shell_num_test[i] == nucleus_shell_num[i]);
}
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free(nucleus_shell_num_test);
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shell_ang_mom_test = (int32_t*) malloc ( shell_num * sizeof(int32_t));
rc = qmckl_get_ao_basis_shell_ang_mom (context, shell_ang_mom_test, shell_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < shell_num ; ++i) {
assert(shell_ang_mom_test[i] == shell_ang_mom[i]);
}
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free(shell_ang_mom_test);
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shell_factor_test = (double*) malloc ( shell_num * sizeof(double));
rc = qmckl_get_ao_basis_shell_factor (context, shell_factor_test, shell_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < shell_num ; ++i) {
assert(shell_factor_test[i] == shell_factor[i]);
}
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free(shell_factor_test);
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shell_prim_num_test = (int64_t*) malloc ( shell_num * sizeof(int64_t));
rc = qmckl_get_ao_basis_shell_prim_num (context, shell_prim_num_test, shell_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < shell_num ; ++i) {
assert(shell_prim_num_test[i] == shell_prim_num[i]);
}
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free(shell_prim_num_test);
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shell_prim_index_test = (int64_t*) malloc ( shell_num * sizeof(int64_t));
rc = qmckl_get_ao_basis_shell_prim_index (context, shell_prim_index_test, shell_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < shell_num ; ++i) {
assert(shell_prim_index_test[i] == shell_prim_index[i]);
}
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free(shell_prim_index_test);
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exponent_test = (double*) malloc ( prim_num * sizeof(double));
rc = qmckl_get_ao_basis_exponent(context, exponent_test, prim_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < prim_num ; ++i) {
assert(exponent_test[i] == exponent[i]);
}
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free(exponent_test);
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coefficient_test = (double*) malloc ( prim_num * sizeof(double));
rc = qmckl_get_ao_basis_coefficient(context, coefficient_test, prim_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < prim_num ; ++i) {
assert(coefficient_test[i] == coefficient[i]);
}
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free(coefficient_test);
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prim_factor_test = (double*) malloc ( prim_num * sizeof(double));
rc = qmckl_get_ao_basis_prim_factor (context, prim_factor_test, prim_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < prim_num ; ++i) {
assert(prim_factor_test[i] == prim_factor[i]);
}
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free(prim_factor_test);
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rc = qmckl_get_ao_basis_ao_num(context, &ao_num_test);
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assert(ao_num == ao_num_test);
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ao_factor_test = (double*) malloc ( ao_num * sizeof(double));
rc = qmckl_get_ao_basis_ao_factor (context, ao_factor_test, ao_num);
assert (rc == QMCKL_SUCCESS);
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for (int64_t i=0 ; i < ao_num ; ++i) {
assert(ao_factor_test[i] == ao_factor[i]);
}
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free(ao_factor_test);
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#+end_src
** Computed data
The following data is computed as described in the next sections:
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|----------------------+-----------------------------------+----------------------------------------------------------------------------------------------|
| Variable | Type | Description |
|----------------------+-----------------------------------+----------------------------------------------------------------------------------------------|
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| ~primitive_vgl~ | ~double[point_num][5][prim_num]~ | Value, gradients, Laplacian of the primitives at current positions |
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| ~primitive_vgl_date~ | ~uint64_t~ | Last modification date of Value, gradients, Laplacian of the primitives at current positions |
| ~shell_vgl~ | ~double[point_num][5][shell_num]~ | Value, gradients, Laplacian of the primitives at current positions |
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| ~shell_vgl_date~ | ~uint64_t~ | Last modification date of Value, gradients, Laplacian of the AOs at current positions |
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| ~ao_vgl~ | ~double[point_num][5][ao_num]~ | Value, gradients, Laplacian of the AOs at current positions |
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| ~ao_vgl_date~ | ~uint64_t~ | Last modification date of Value, gradients, Laplacian of the AOs at current positions |
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| ~ao_value~ | ~double[point_num][ao_num]~ | Values of the the AOs at current positions |
| ~ao_value_date~ | ~uint64_t~ | Last modification date of the values of the AOs at current positions |
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|----------------------+-----------------------------------+----------------------------------------------------------------------------------------------|
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*** After initialization
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When the basis set is completely entered, extra data structures may be
computed to accelerate the calculations. The primitives within each
contraction are sorted in ascending order of their exponents, such
that as soon as a primitive is zero all the following functions
vanish. Also, it is possible to compute a nuclear radius beyond which
all the primitives are zero up to the numerical accuracy defined in
the context.
#+begin_src c :comments org :tangle (eval h_private_func) :noweb yes :exports none
qmckl_exit_code qmckl_finalize_basis (qmckl_context context);
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code qmckl_finalize_basis(qmckl_context context) {
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
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"qmckl_finalize_basis",
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NULL);
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int64_t nucl_num = 0;
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qmckl_exit_code rc = qmckl_get_nucleus_num(context, &nucl_num);
if (rc != QMCKL_SUCCESS) return rc;
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/* nucleus_prim_index */
{
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = (ctx->nucleus.num + (int64_t) 1) * sizeof(int64_t);
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ctx->ao_basis.nucleus_prim_index = (int64_t*) qmckl_malloc(context, mem_info);
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if (ctx->ao_basis.nucleus_prim_index == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"ao_basis.nucleus_prim_index",
NULL);
}
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for (int64_t i=0 ; i<nucl_num ; ++i) {
int64_t shell_idx = ctx->ao_basis.nucleus_index[i];
ctx->ao_basis.nucleus_prim_index[i] = ctx->ao_basis.shell_prim_index[shell_idx];
}
ctx->ao_basis.nucleus_prim_index[nucl_num] = ctx->ao_basis.prim_num;
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}
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/* Normalize coefficients */
{
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->ao_basis.prim_num * sizeof(double);
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ctx->ao_basis.coefficient_normalized = (double *) qmckl_malloc(context, mem_info);
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if (ctx->ao_basis.coefficient_normalized == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"ao_basis.coefficient_normalized",
NULL);
}
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for (int64_t ishell=0 ; ishell < ctx->ao_basis.shell_num ; ++ishell) {
for (int64_t iprim=ctx->ao_basis.shell_prim_index[ishell] ;
iprim < ctx->ao_basis.shell_prim_index[ishell]+ctx->ao_basis.shell_prim_num[ishell] ;
++iprim) {
ctx->ao_basis.coefficient_normalized[iprim] =
ctx->ao_basis.coefficient[iprim] * ctx->ao_basis.prim_factor[iprim] *
ctx->ao_basis.shell_factor[ishell];
}
}
}
/* Find max angular momentum on each nucleus */
{
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->nucleus.num * sizeof(int32_t);
ctx->ao_basis.nucleus_max_ang_mom = (int32_t *) qmckl_malloc(context, mem_info);
if (ctx->ao_basis.nucleus_max_ang_mom == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"ao_basis.nucleus_max_ang_mom",
NULL);
}
for (int64_t inucl=0 ; inucl < nucl_num ; ++inucl) {
ctx->ao_basis.nucleus_max_ang_mom[inucl] = 0;
for (int64_t ishell=ctx->ao_basis.nucleus_index[inucl] ;
ishell < ctx->ao_basis.nucleus_index[inucl] + ctx->ao_basis.nucleus_shell_num[inucl] ;
++ishell) {
ctx->ao_basis.nucleus_max_ang_mom[inucl] =
ctx->ao_basis.nucleus_max_ang_mom[inucl] > ctx->ao_basis.shell_ang_mom[ishell] ?
ctx->ao_basis.nucleus_max_ang_mom[inucl] : ctx->ao_basis.shell_ang_mom[ishell] ;
}
}
}
/* Find distance beyond which all AOs are zero.
The distance is obtained by sqrt(log(cutoff)*range) */
{
if (ctx->ao_basis.type == 'G') {
qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->nucleus.num * sizeof(double);
ctx->ao_basis.nucleus_range = (double *) qmckl_malloc(context, mem_info);
if (ctx->ao_basis.nucleus_range == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"ao_basis.nucleus_range",
NULL);
}
for (int64_t inucl=0 ; inucl < ctx->nucleus.num ; ++inucl) {
ctx->ao_basis.nucleus_range[inucl] = 0.;
for (int64_t ishell=ctx->ao_basis.nucleus_index[inucl] ;
ishell < ctx->ao_basis.nucleus_index[inucl] + ctx->ao_basis.nucleus_shell_num[inucl] ;
++ishell) {
for (int64_t iprim=ctx->ao_basis.shell_prim_index[ishell] ;
iprim < ctx->ao_basis.shell_prim_index[ishell] + ctx->ao_basis.shell_prim_num[ishell] ;
++iprim) {
double range = 1./ctx->ao_basis.exponent[iprim];
ctx->ao_basis.nucleus_range[inucl] =
ctx->ao_basis.nucleus_range[inucl] > range ?
ctx->ao_basis.nucleus_range[inucl] : range;
}
}
}
}
}
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#ifdef HAVE_HPC
rc = qmckl_finalize_basis_hpc(context);
if (rc != QMCKL_SUCCESS) return rc;
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#endif
return qmckl_context_touch(context);
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}
#+end_src
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*** TODO HPC-specific data structures
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For faster access, we provide extra arrays for the shell information as:
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- $C_{psa}$ = =coef_per_nucleus[inucl][ishell][iprim]=
- $\gamma_{pa}$ =expo_per_nucleus[inucl][iprim]=
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such that the computation of the radial parts can be vectorized.
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Exponents are sorted in increasing order to exit loops quickly,
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and only unique exponents are kept. This also allows to pack the
exponents to enable vectorization of exponentials.
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The computation of the radial part is made as
\[
R_{sa} = \sum_p C_{psa} \gamma_{pa}
\]
which is a matrix-vector product.
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#+NAME:HPC_struct
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#+begin_src c :comments org :exports none
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/* HPC specific data structures */
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int32_t* restrict prim_num_per_nucleus;
qmckl_tensor coef_per_nucleus;
qmckl_matrix expo_per_nucleus;
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#+end_src
#+begin_src c :comments org :tangle (eval h_private_func) :exports none
#ifdef HAVE_HPC
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qmckl_exit_code qmckl_finalize_basis_hpc (qmckl_context context);
#endif
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#+end_src
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#+begin_src c :comments org :tangle (eval c) :exports none
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/* Data structure for sorting */
struct combined {
double expo;
int64_t index;
};
/* Comparison function */
int compare_basis( const void * l, const void * r )
{
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const struct combined * restrict _l= (const struct combined *)l;
const struct combined * restrict _r= (const struct combined *)r;
if( _l->expo > _r->expo ) return 1;
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if( _l->expo < _r->expo ) return -1;
return 0;
}
#ifdef HAVE_HPC
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qmckl_exit_code qmckl_finalize_basis_hpc (qmckl_context context)
{
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->nucleus.num * sizeof(int32_t);
ctx->ao_basis.prim_num_per_nucleus = (int32_t*) qmckl_malloc(context, mem_info);
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/* Find max number of primitives per nucleus */
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int64_t shell_max = 0;
int64_t prim_max = 0;
int64_t nucl_num = ctx->nucleus.num;
for (int inucl=0 ; inucl < nucl_num ; ++inucl) {
shell_max = ctx->ao_basis.nucleus_shell_num[inucl] > shell_max ?
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ctx->ao_basis.nucleus_shell_num[inucl] : shell_max;
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int64_t prim_num = 0;
const int64_t ishell_start = ctx->ao_basis.nucleus_index[inucl];
const int64_t ishell_end = ctx->ao_basis.nucleus_index[inucl] + ctx->ao_basis.nucleus_shell_num[inucl];
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
prim_num += ctx->ao_basis.shell_prim_num[ishell];
}
prim_max = prim_num > prim_max ?
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prim_num : prim_max;
ctx->ao_basis.prim_num_per_nucleus[inucl] = prim_num;
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}
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int64_t size[3] = { prim_max, shell_max, nucl_num };
ctx->ao_basis.coef_per_nucleus = qmckl_tensor_alloc( context, 3, size );
ctx->ao_basis.coef_per_nucleus = qmckl_tensor_set(ctx->ao_basis.coef_per_nucleus, 0.);
ctx->ao_basis.expo_per_nucleus = qmckl_matrix_alloc( context, prim_max, nucl_num );
ctx->ao_basis.expo_per_nucleus = qmckl_matrix_set(ctx->ao_basis.expo_per_nucleus, 0.);
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struct combined expo[prim_max];
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double coef[shell_max][prim_max];
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double newcoef[prim_max];
for (int64_t inucl=0 ; inucl < nucl_num ; ++inucl) {
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memset(expo, 0, sizeof(expo));
memset(coef, 0, sizeof(expo));
int64_t idx = 0;
const int64_t ishell_start = ctx->ao_basis.nucleus_index[inucl];
const int64_t ishell_end = ctx->ao_basis.nucleus_index[inucl] + ctx->ao_basis.nucleus_shell_num[inucl];
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
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const int64_t iprim_start = ctx->ao_basis.shell_prim_index[ishell];
const int64_t iprim_end = ctx->ao_basis.shell_prim_index[ishell] + ctx->ao_basis.shell_prim_num[ishell];
for (int64_t iprim = iprim_start ; iprim < iprim_end ; ++iprim) {
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expo[idx].expo = ctx->ao_basis.exponent[iprim];
expo[idx].index = idx;
idx += 1;
}
}
/* Sort exponents */
qsort( expo, (size_t) idx, sizeof(struct combined), compare_basis );
idx = 0;
int64_t idx2 = 0;
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
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memset(newcoef, 0, sizeof(newcoef));
const int64_t iprim_start = ctx->ao_basis.shell_prim_index[ishell];
const int64_t iprim_end = ctx->ao_basis.shell_prim_index[ishell] + ctx->ao_basis.shell_prim_num[ishell];
for (int64_t iprim = iprim_start ; iprim < iprim_end ; ++iprim) {
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newcoef[idx] = ctx->ao_basis.coefficient_normalized[iprim];
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idx += 1;
}
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for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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idx2 = expo[i].index;
coef[ishell - ishell_start][i] = newcoef[idx2];
}
}
/* Apply ordering to coefficients */
/* Remove duplicates */
int64_t newidx[prim_max];
int64_t idxmax = 0;
idx = 0;
newidx[0] = 0;
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for (int32_t i=1 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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if (expo[i].expo != expo[i-1].expo) {
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idx += 1;
}
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newidx[i] = idx;
}
idxmax = idx;
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for (int32_t j=0 ; j<ishell_end-ishell_start ; ++j) {
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memset(newcoef, 0, sizeof(newcoef));
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for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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newcoef[newidx[i]] += coef[j][i];
}
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for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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coef[j][i] = newcoef[i];
}
}
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for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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expo[newidx[i]].expo = expo[i].expo;
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}
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ctx->ao_basis.prim_num_per_nucleus[inucl] = idxmax+1;
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for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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qmckl_mat( ctx->ao_basis.expo_per_nucleus, i, inucl ) = expo[i].expo;
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}
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for (int32_t j=0 ; j<ishell_end-ishell_start ; ++j) {
for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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qmckl_ten3( ctx->ao_basis.coef_per_nucleus, i, j, inucl ) = coef[j][i];
}
}
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/*
for (int32_t i=0 ; i<ctx->ao_basis.prim_num_per_nucleus[inucl] ; ++i) {
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printf("%4ld %4ld %15.5e | ", inucl, i, qmckl_mat( ctx->ao_basis.expo_per_nucleus, i, inucl ));
for (int64_t j=0 ; j<ishell_end-ishell_start ; ++j) {
printf("%8.5f ", qmckl_ten3( ctx->ao_basis.coef_per_nucleus, i, j, inucl ));
}
printf("\n");
}
printf("\n");
*/
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}
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return QMCKL_SUCCESS;
}
#endif
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2022-02-25 20:39:20 +01:00
#+end_src
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*** Access functions
#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_primitive_vgl (qmckl_context context,
double* const primitive_vgl,
const int64_t size_max);
#+end_src
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Returns the array of values, gradients an Laplacian of primitive
basis functions evaluated at the current coordinates.
See section [[Computation of primitives]].
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_primitive_vgl (qmckl_context context,
double* const primitive_vgl,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_primitive_vgl",
NULL);
}
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if (size_max <= 0) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_primitive_vgl",
"size_max <= 0");
}
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qmckl_exit_code rc;
rc = qmckl_provide_ao_basis_primitive_vgl(context);
if (rc != QMCKL_SUCCESS) return rc;
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int64_t sze = ctx->ao_basis.prim_num * 5 * ctx->point.num;
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if (size_max < sze) {
return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_get_ao_basis_primitive_vgl",
"input array too small");
}
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memcpy(primitive_vgl, ctx->ao_basis.primitive_vgl, (size_t) sze * sizeof(double));
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return QMCKL_SUCCESS;
}
#+end_src
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#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_get_ao_basis_primitive_vgl &
(context, primitive_vgl, size_max) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: primitive_vgl(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function
end interface
#+end_src
#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_shell_vgl (qmckl_context context,
double* const shell_vgl,
const int64_t size_max);
#+end_src
Returns the array of values, gradients an Laplacian of contracted shells
evaluated at the current coordinates. See section [[Computation of shells]].
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_shell_vgl (qmckl_context context,
double* const shell_vgl,
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const int64_t size_max)
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{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_shell_vgl",
NULL);
}
qmckl_exit_code rc;
rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) return rc;
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int64_t sze = ctx->ao_basis.shell_num * 5 * ctx->point.num;
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if (size_max < sze) {
return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_get_ao_basis_shell_vgl",
"input array too small");
}
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memcpy(shell_vgl, ctx->ao_basis.shell_vgl, (size_t)sze * sizeof(double));
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return QMCKL_SUCCESS;
}
#+end_src
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
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integer(c_int32_t) function qmckl_get_ao_basis_shell_vgl &
(context, shell_vgl, size_max) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: shell_vgl(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function
end interface
#+end_src
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
2022-01-05 19:22:16 +01:00
#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_ao_vgl (qmckl_context context,
double* const ao_vgl,
const int64_t size_max);
#+end_src
Returns the array of values, gradients an Laplacian of the atomic orbitals
evaluated at the current coordinates.
See section [[Combining radial and polynomial parts]].
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_ao_vgl (qmckl_context context,
double* const ao_vgl,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
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"qmckl_get_ao_basis_ao_vgl",
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NULL);
}
qmckl_exit_code rc;
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rc = qmckl_provide_ao_basis_ao_vgl(context);
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if (rc != QMCKL_SUCCESS) return rc;
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
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int64_t sze = ctx->ao_basis.ao_num * 5 * ctx->point.num;
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if (size_max < sze) {
return qmckl_failwith( context,
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QMCKL_INVALID_ARG_3,
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"qmckl_get_ao_basis_ao_vgl",
"input array too small");
}
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memcpy(ao_vgl, ctx->ao_basis.ao_vgl, (size_t) sze * sizeof(double));
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return QMCKL_SUCCESS;
}
#+end_src
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_get_ao_basis_ao_vgl (context, &
ao_vgl, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: ao_vgl(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_get_ao_basis_ao_vgl
end interface
#+end_src
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Uses the given array to compute the VGL.
#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_ao_vgl_inplace (qmckl_context context,
double* const ao_vgl,
const int64_t size_max);
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_ao_vgl_inplace (qmckl_context context,
double* const ao_vgl,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_ao_vgl",
NULL);
}
qmckl_exit_code rc;
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
assert (ctx != NULL);
int64_t sze = ctx->ao_basis.ao_num * 5 * ctx->point.num;
if (size_max < sze) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_ao_vgl",
"input array too small");
}
rc = qmckl_context_touch(context);
if (rc != QMCKL_SUCCESS) return rc;
double* old_array = ctx->ao_basis.ao_vgl;
ctx->ao_basis.ao_vgl = ao_vgl;
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rc = qmckl_provide_ao_basis_ao_vgl(context);
if (rc != QMCKL_SUCCESS) return rc;
ctx->ao_basis.ao_vgl = old_array;
return QMCKL_SUCCESS;
}
#+end_src
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_get_ao_basis_ao_vgl_inplace (context, &
ao_vgl, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: ao_vgl(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_get_ao_basis_ao_vgl_inplace
end interface
#+end_src
2022-05-10 19:18:19 +02:00
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#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_ao_value (qmckl_context context,
double* const ao_value,
const int64_t size_max);
#+end_src
Returns the array of values of the atomic orbitals evaluated at
the current coordinates. See section [[Combining radial and polynomial parts]].
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_ao_value (qmckl_context context,
double* const ao_value,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_ao_value",
NULL);
}
qmckl_exit_code rc;
rc = qmckl_provide_ao_basis_ao_value(context);
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if (rc != QMCKL_SUCCESS) return rc;
qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
assert (ctx != NULL);
int64_t sze = ctx->ao_basis.ao_num * ctx->point.num;
if (size_max < sze) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_ao_value",
"input array too small");
}
memcpy(ao_value, ctx->ao_basis.ao_value, (size_t) sze * sizeof(double));
return QMCKL_SUCCESS;
}
#+end_src
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_get_ao_basis_ao_value (context, &
ao_value, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: ao_value(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_get_ao_basis_ao_value
end interface
#+end_src
Uses the given array to compute the value.
#+begin_src c :comments org :tangle (eval h_func) :noweb yes
qmckl_exit_code
qmckl_get_ao_basis_ao_value_inplace (qmckl_context context,
double* const ao_value,
const int64_t size_max);
#+end_src
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#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
qmckl_exit_code
qmckl_get_ao_basis_ao_value_inplace (qmckl_context context,
double* const ao_value,
const int64_t size_max)
{
if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_get_ao_basis_ao_value",
NULL);
}
qmckl_exit_code rc;
qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
assert (ctx != NULL);
int64_t sze = ctx->ao_basis.ao_num * ctx->point.num;
if (size_max < sze) {
return qmckl_failwith( context,
QMCKL_INVALID_ARG_3,
"qmckl_get_ao_basis_ao_value",
"input array too small");
}
rc = qmckl_context_touch(context);
if (rc != QMCKL_SUCCESS) return rc;
double* old_array = ctx->ao_basis.ao_value;
ctx->ao_basis.ao_value = ao_value;
rc = qmckl_provide_ao_basis_ao_value(context);
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if (rc != QMCKL_SUCCESS) return rc;
ctx->ao_basis.ao_value = old_array;
return QMCKL_SUCCESS;
}
#+end_src
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_get_ao_basis_ao_value_inplace (context, &
ao_value, size_max) bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
double precision, intent(out) :: ao_value(*)
integer (c_int64_t) , intent(in) , value :: size_max
end function qmckl_get_ao_basis_ao_value_inplace
end interface
#+end_src
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* Radial part
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** General functions for Gaussian basis functions
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~qmckl_ao_gaussian_vgl~ computes the values, gradients and
Laplacians at a given point of ~n~ Gaussian functions centered at
the same point:
\[ v_i = \exp(-a_i |X-R|^2) \]
\[ \nabla_x v_i = -2 a_i (X_x - R_x) v_i \]
\[ \nabla_y v_i = -2 a_i (X_y - R_y) v_i \]
\[ \nabla_z v_i = -2 a_i (X_z - R_z) v_i \]
\[ \Delta v_i = a_i (4 |X-R|^2 a_i - 6) v_i \]
|--------------+------------------+------------------------------------------------------|
| Variable | Type | Description |
|--------------+------------------+------------------------------------------------------|
| ~context~ | ~qmckl_context~ | Global state |
| ~X(3)~ | ~double[3]~ | Array containing the coordinates of the points |
| ~R(3)~ | ~double[3]~ | Array containing the x,y,z coordinates of the center |
| ~n~ | ~int64_t~ | Number of computed Gaussians |
| ~A(n)~ | ~double[n]~ | Exponents of the Gaussians |
| ~VGL(ldv,5)~ | ~double[5][ldv]~ | Value, gradients and Laplacian of the Gaussians |
| ~ldv~ | ~int64_t~ | Leading dimension of array ~VGL~ |
|--------------+------------------+------------------------------------------------------|
Requirements:
- ~context~ \ne 0
- ~n~ > 0
- ~ldv~ >= 5
- ~A(i)~ > 0 for all ~i~
- ~X~ is allocated with at least $3 \times 8$ bytes
- ~R~ is allocated with at least $3 \times 8$ bytes
- ~A~ is allocated with at least $n \times 8$ bytes
- ~VGL~ is allocated with at least $n \times 5 \times 8$ bytes
#+begin_src c :tangle (eval h_func)
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qmckl_exit_code
qmckl_ao_gaussian_vgl(const qmckl_context context,
const double *X,
const double *R,
const int64_t *n,
const int64_t *A,
const double *VGL,
const int64_t ldv);
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#+end_src
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#+begin_src f90 :tangle (eval f)
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integer function qmckl_ao_gaussian_vgl_f(context, X, R, n, A, VGL, ldv) result(info)
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use qmckl
implicit none
integer*8 , intent(in) :: context
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real*8 , intent(in) :: X(3), R(3)
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integer*8 , intent(in) :: n
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real*8 , intent(in) :: A(n)
real*8 , intent(out) :: VGL(ldv,5)
integer*8 , intent(in) :: ldv
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integer*8 :: i,j
real*8 :: Y(3), r2, t, u, v
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info = QMCKL_SUCCESS
if (context == QMCKL_NULL_CONTEXT) then
info = QMCKL_INVALID_CONTEXT
return
endif
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if (n <= 0) then
info = QMCKL_INVALID_ARG_4
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return
endif
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if (ldv < n) then
info = QMCKL_INVALID_ARG_7
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return
endif
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do i=1,3
Y(i) = X(i) - R(i)
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end do
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r2 = Y(1)*Y(1) + Y(2)*Y(2) + Y(3)*Y(3)
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do i=1,n
VGL(i,1) = dexp(-A(i) * r2)
end do
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do i=1,n
VGL(i,5) = A(i) * VGL(i,1)
end do
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t = -2.d0 * ( X(1) - R(1) )
u = -2.d0 * ( X(2) - R(2) )
v = -2.d0 * ( X(3) - R(3) )
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do i=1,n
VGL(i,2) = t * VGL(i,5)
VGL(i,3) = u * VGL(i,5)
VGL(i,4) = v * VGL(i,5)
end do
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t = 4.d0 * r2
do i=1,n
VGL(i,5) = (t * A(i) - 6.d0) * VGL(i,5)
end do
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end function qmckl_ao_gaussian_vgl_f
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#+end_src
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#+begin_src f90 :tangle (eval f) :exports none
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integer(c_int32_t) function qmckl_ao_gaussian_vgl(context, X, R, n, A, VGL, ldv) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double) , intent(in) :: X(3), R(3)
integer (c_int64_t) , intent(in) , value :: n
real (c_double) , intent(in) :: A(n)
real (c_double) , intent(out) :: VGL(ldv,5)
integer (c_int64_t) , intent(in) , value :: ldv
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integer, external :: qmckl_ao_gaussian_vgl_f
info = qmckl_ao_gaussian_vgl_f(context, X, R, n, A, VGL, ldv)
end function qmckl_ao_gaussian_vgl
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#+end_src
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#+begin_src f90 :tangle (eval fh_func) :exports none
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interface
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integer(c_int32_t) function qmckl_ao_gaussian_vgl(context, &
X, R, n, A, VGL, ldv) bind(C)
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use, intrinsic :: iso_c_binding
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: ldv
integer (c_int64_t) , intent(in) , value :: n
real (c_double) , intent(in) :: X(3), R(3), A(n)
real (c_double) , intent(out) :: VGL(ldv,5)
end function qmckl_ao_gaussian_vgl
end interface
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#+end_src
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*** Test :noexport:
#+begin_src f90 :tangle (eval f_test)
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integer(c_int32_t) function test_qmckl_ao_gaussian_vgl(context) bind(C)
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use qmckl
implicit none
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integer(c_int64_t), intent(in), value :: context
integer*8 :: n, ldv, j, i
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double precision :: X(3), R(3), Y(3), r2, z
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double precision, allocatable :: VGL(:,:), A(:)
double precision :: epsilon
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epsilon = 3.d0 * qmckl_get_numprec_epsilon(context)
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X = (/ 1.1 , 2.2 , 3.3 /)
R = (/ 0.1 , 1.2 , -2.3 /)
Y(:) = X(:) - R(:)
r2 = Y(1)**2 + Y(2)**2 + Y(3)**2
n = 10;
ldv = 100;
allocate (A(n), VGL(ldv,5))
do i=1,n
A(i) = 0.0013 * dble(ishft(1,i))
end do
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test_qmckl_ao_gaussian_vgl = &
qmckl_ao_gaussian_vgl(context, X, R, n, A, VGL, ldv)
if (test_qmckl_ao_gaussian_vgl /= 0) return
test_qmckl_ao_gaussian_vgl = -1
do i=1,n
test_qmckl_ao_gaussian_vgl = -11
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z = dabs(1.d0 - VGL(i,1) / (dexp(-A(i) * r2)) )
if ( z > epsilon ) then
print *, z, epsilon
return
end if
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test_qmckl_ao_gaussian_vgl = -12
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z = dabs(1.d0 - VGL(i,2) / (&
-2.d0 * A(i) * Y(1) * dexp(-A(i) * r2) ))
if ( z > epsilon ) then
print *, z, epsilon
return
end if
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test_qmckl_ao_gaussian_vgl = -13
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z = dabs(1.d0 - VGL(i,3) / (&
-2.d0 * A(i) * Y(2) * dexp(-A(i) * r2) ))
if ( z > epsilon ) then
print *, z, epsilon
return
end if
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test_qmckl_ao_gaussian_vgl = -14
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z = dabs(1.d0 - VGL(i,4) / (&
-2.d0 * A(i) * Y(3) * dexp(-A(i) * r2) ))
if ( z > epsilon ) then
print *, z, epsilon
return
end if
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test_qmckl_ao_gaussian_vgl = -15
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z = dabs(1.d0 - VGL(i,5) / (&
A(i) * (4.d0*r2*A(i) - 6.d0) * dexp(-A(i) * r2) ))
if ( z > epsilon ) then
print *, z, epsilon
return
end if
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end do
test_qmckl_ao_gaussian_vgl = 0
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deallocate(VGL)
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end function test_qmckl_ao_gaussian_vgl
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#+end_src
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#+begin_src c :tangle (eval c_test) :exports none
int test_qmckl_ao_gaussian_vgl(qmckl_context context);
assert(0 == test_qmckl_ao_gaussian_vgl(context));
#+end_src
** TODO General functions for Slater basis functions :noexport:
** TODO General functions for Radial functions on a grid :noexport:
** TODO Helper functions to accelerate calculations :noexport:
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|--------------------------+---------------------+--------------------------------------------------------|
| Variable | Type | Description |
|--------------------------+---------------------+--------------------------------------------------------|
| ~coefficient_normalized~ | ~double[prim_num]~ | Normalized primitive coefficients |
| ~nucleus_prim_index~ | ~int64_t[nucl_num]~ | Index of the first primitive for each nucleus |
| ~nucleus_max_ang_mom~ | ~int32_t[nucl_num]~ | Maximum angular momentum for each nucleus |
| ~nucleus_range~ | ~double[nucl_num]~ | Distance beyond which all the AOs are zero |
|--------------------------+---------------------+--------------------------------------------------------|
| ~nucl_shell_index~ | ~int64_t[nucl_num]~ | Index of the first shell for each nucleus |
| ~exponent_sorted~ | ~double[prim_num]~ | Array of exponents for sorted primitives |
| ~coeff_norm_sorted~ | ~double[prim_num]~ | Array of normalized coefficients for sorted primitives |
| ~prim_factor_sorted~ | ~double[prim_num]~ | Normalization factors of the sorted primtives |
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** Computation of primitives
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:PROPERTIES:
:Name: qmckl_compute_ao_basis_primitive_gaussian_vgl
:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
#+NAME: qmckl_ao_basis_primitive_gaussian_vgl_args
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| Variable | Type | In/Out | Description |
|----------------------+----------------------------------+--------+--------------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~prim_num~ | ~int64_t~ | in | Number of primitives |
| ~point_num~ | ~int64_t~ | in | Number of points considered |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~nucleus_prim_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st primitive of each nucleus |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~expo~ | ~double[prim_num]~ | in | Exponents of the primitives |
| ~primitive_vgl~ | ~double[point_num][5][prim_num]~ | out | Value, gradients and Laplacian of the primitives |
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#+CALL: generate_c_header(table=qmckl_ao_basis_primitive_gaussian_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_basis_primitive_gaussian_vgl"))
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#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_compute_ao_basis_primitive_gaussian_vgl (
const qmckl_context context,
const int64_t prim_num,
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const int64_t point_num,
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const int64_t nucl_num,
const int64_t* nucleus_prim_index,
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const double* coord,
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const double* nucl_coord,
const double* expo,
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double* const primitive_vgl );
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#+end_src
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Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
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#+begin_src f90 :comments org :tangle (eval f) :noweb yes
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integer function qmckl_compute_ao_basis_primitive_gaussian_vgl_f( &
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context, prim_num, point_num, nucl_num, &
nucleus_prim_index, coord, nucl_coord, &
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expo, primitive_vgl) &
result(info)
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use qmckl
implicit none
integer(qmckl_context), intent(in) :: context
integer*8 , intent(in) :: prim_num
integer*8 , intent(in) :: nucl_num
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integer*8 , intent(in) :: point_num
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integer*8 , intent(in) :: nucleus_prim_index(nucl_num+1)
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double precision , intent(in) :: coord(point_num,3)
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double precision , intent(in) :: nucl_coord(nucl_num,3)
double precision , intent(in) :: expo(prim_num)
double precision , intent(out) :: primitive_vgl(prim_num,5,point_num)
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integer*8 :: inucl, iprim, ipoint
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double precision :: x, y, z, two_a, ar2, r2, v, cutoff
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info = QMCKL_SUCCESS
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! Don't compute exponentials when the result will be almost zero.
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cutoff = 27.631021115928547 ! -dlog(1.d-12)
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do inucl=1,nucl_num
! C is zero-based, so shift bounds by one
do iprim = nucleus_prim_index(inucl)+1, nucleus_prim_index(inucl+1)
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do ipoint = 1, point_num
x = coord(ipoint,1) - nucl_coord(inucl,1)
y = coord(ipoint,2) - nucl_coord(inucl,2)
z = coord(ipoint,3) - nucl_coord(inucl,3)
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r2 = x*x + y*y + z*z
ar2 = expo(iprim)*r2
if (ar2 > cutoff) cycle
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v = dexp(-ar2)
two_a = -2.d0 * expo(iprim) * v
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primitive_vgl(iprim, 1, ipoint) = v
primitive_vgl(iprim, 2, ipoint) = two_a * x
primitive_vgl(iprim, 3, ipoint) = two_a * y
primitive_vgl(iprim, 4, ipoint) = two_a * z
primitive_vgl(iprim, 5, ipoint) = two_a * (3.d0 - 2.d0*ar2)
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end do
end do
end do
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end function qmckl_compute_ao_basis_primitive_gaussian_vgl_f
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#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_basis_primitive_gaussian_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_basis_primitive_gaussian_vgl"))
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#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
integer(c_int32_t) function qmckl_compute_ao_basis_primitive_gaussian_vgl &
(context, &
prim_num, &
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point_num, &
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nucl_num, &
nucleus_prim_index, &
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coord, &
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nucl_coord, &
expo, &
primitive_vgl) &
bind(C) result(info)
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use, intrinsic :: iso_c_binding
implicit none
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integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: prim_num
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integer (c_int64_t) , intent(in) , value :: point_num
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integer (c_int64_t) , intent(in) , value :: nucl_num
integer (c_int64_t) , intent(in) :: nucleus_prim_index(nucl_num)
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real (c_double ) , intent(in) :: coord(point_num,3)
real (c_double ) , intent(in) :: nucl_coord(nucl_num,3)
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real (c_double ) , intent(in) :: expo(prim_num)
real (c_double ) , intent(out) :: primitive_vgl(prim_num,5,point_num)
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integer(c_int32_t), external :: qmckl_compute_ao_basis_primitive_gaussian_vgl_f
info = qmckl_compute_ao_basis_primitive_gaussian_vgl_f &
(context, &
prim_num, &
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point_num, &
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nucl_num, &
nucleus_prim_index, &
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coord, &
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nucl_coord, &
expo, &
primitive_vgl)
end function qmckl_compute_ao_basis_primitive_gaussian_vgl
#+end_src
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*** Provide :noexport:
#+CALL: write_provider_header( group="ao_basis", data="primitive_vgl" )
#+RESULTS:
#+begin_src c :comments org :tangle (eval h_private_func) :noweb yes :export none
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qmckl_exit_code qmckl_provide_ao_basis_primitive_vgl(qmckl_context context);
#+end_src
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#+CALL: write_provider_pre( group="ao_basis", data="primitive_vgl", dimension="ctx->ao_basis.prim_num * 5 * ctx->point.num")
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
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qmckl_exit_code qmckl_provide_ao_basis_primitive_vgl(qmckl_context context)
{
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qmckl_exit_code rc = QMCKL_SUCCESS;
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_provide_ao_basis_primitive_vgl",
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NULL);
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
if (!ctx->ao_basis.provided) {
return qmckl_failwith( context,
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QMCKL_NOT_PROVIDED,
"qmckl_provide_ao_basis_primitive_vgl",
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NULL);
}
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
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/* Compute if necessary */
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if (ctx->point.date > ctx->ao_basis.primitive_vgl_date) {
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->ao_basis.prim_num * 5 * ctx->point.num * sizeof(double);
if (ctx->ao_basis.primitive_vgl != NULL) {
qmckl_memory_info_struct mem_info_test = qmckl_memory_info_struct_zero;
rc = qmckl_get_malloc_info(context, ctx->ao_basis.primitive_vgl, &mem_info_test);
/* if rc != QMCKL_SUCCESS, we are maybe in an _inplace function because the
memory was not allocated with qmckl_malloc */
if ((rc == QMCKL_SUCCESS) && (mem_info_test.size != mem_info.size)) {
rc = qmckl_free(context, ctx->ao_basis.primitive_vgl);
assert (rc == QMCKL_SUCCESS);
ctx->ao_basis.primitive_vgl = NULL;
}
}
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/* Allocate array */
if (ctx->ao_basis.primitive_vgl == NULL) {
double* primitive_vgl = (double*) qmckl_malloc(context, mem_info);
if (primitive_vgl == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"qmckl_ao_basis_primitive_vgl",
NULL);
}
ctx->ao_basis.primitive_vgl = primitive_vgl;
}
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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if (ctx->ao_basis.type == 'G') {
rc = qmckl_compute_ao_basis_primitive_gaussian_vgl(context,
ctx->ao_basis.prim_num,
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ctx->point.num,
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ctx->nucleus.num,
ctx->ao_basis.nucleus_prim_index,
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ctx->point.coord.data,
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ctx->nucleus.coord.data,
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ctx->ao_basis.exponent,
ctx->ao_basis.primitive_vgl);
} else {
return qmckl_failwith( context,
QMCKL_FAILURE,
"compute_ao_basis_primitive_vgl",
"Not yet implemented");
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
}
#+end_src
#+CALL: write_provider_post( group="ao_basis", data="shell_vgl" )
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
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if (rc != QMCKL_SUCCESS) {
return rc;
}
ctx->ao_basis.shell_vgl_date = ctx->date;
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}
return QMCKL_SUCCESS;
}
#+end_src
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*** Test :noexport:
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#+begin_src python :results output :exports none :exports none
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import numpy as np
def f(a,x,y):
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
return np.exp( -a*(np.linalg.norm(x-y))**2 )
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def df(a,x,y,n):
h0 = 1.e-6
if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
return ( f(a,x+h,y) - f(a,x-h,y) ) / (2.*h0)
def d2f(a,x,y,n):
h0 = 1.e-6
if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
return ( f(a,x+h,y) - 2.*f(a,x,y) + f(a,x-h,y) ) / h0**2
def lf(a,x,y):
return d2f(a,x,y,1) + d2f(a,x,y,2) + d2f(a,x,y,3)
elec_26_w1 = np.array( [ 1.49050402641, 2.90106987953, -1.05920815468 ] )
nucl_1 = np.array( [ 1.096243353458458e+00, 8.907054016973815e-01, 7.777092280258892e-01 ] )
nucl_2 = np.array( [ 1.168459237342663e+00, 1.125660720053393e+00, 2.833370314829343e+00 ] )
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#double prim_vgl[prim_num][5][elec_num];
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a = 0.9059; x = elec_26_w1 ; y = nucl_1
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print ( "[7][0][26] : %e"% f(a,x,y))
print ( "[7][1][26] : %e"% df(a,x,y,1))
print ( "[7][2][26] : %e"% df(a,x,y,2))
print ( "[7][3][26] : %e"% df(a,x,y,3))
print ( "[7][4][26] : %e"% lf(a,x,y))
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#+end_src
#+RESULTS:
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: [7][0][26] : 1.050157e-03
: [7][1][26] : -7.501497e-04
: [7][2][26] : -3.825069e-03
: [7][3][26] : 3.495056e-03
: [7][4][26] : 2.040013e-02
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#+begin_src c :tangle (eval c_test) :exports none
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{
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#define walk_num 1 // chbrclf_walk_num
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#define elec_num chbrclf_elec_num
#define prim_num chbrclf_prim_num
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int64_t elec_up_num = chbrclf_elec_up_num;
int64_t elec_dn_num = chbrclf_elec_dn_num;
double* elec_coord = &(chbrclf_elec_coord[0][0][0]);
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rc = qmckl_set_electron_num (context, elec_up_num, elec_dn_num);
assert (rc == QMCKL_SUCCESS);
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assert(qmckl_electron_provided(context));
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const int64_t point_num = elec_num;
rc = qmckl_set_point(context, 'N', point_num, elec_coord, point_num*3);
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assert(rc == QMCKL_SUCCESS);
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double prim_vgl[point_num][5][prim_num];
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rc = qmckl_get_ao_basis_primitive_vgl(context, &(prim_vgl[0][0][0]),
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(int64_t) 5*point_num*prim_num );
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assert (rc == QMCKL_SUCCESS);
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printf("prim_vgl[26][0][7] = %e\n",prim_vgl[26][0][7]);
assert( fabs(prim_vgl[26][0][7] - ( 1.0501570432064878E-003)) < 1.e-14 );
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printf("prim_vgl[26][1][7] = %e\n",prim_vgl[26][1][7]);
assert( fabs(prim_vgl[26][1][7] - (-7.5014974095310560E-004)) < 1.e-14 );
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printf("prim_vgl[26][2][7] = %e\n",prim_vgl[26][2][7]);
assert( fabs(prim_vgl[26][2][7] - (-3.8250692897610380E-003)) < 1.e-14 );
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printf("prim_vgl[26][3][7] = %e\n",prim_vgl[26][3][7]);
assert( fabs(prim_vgl[26][3][7] - ( 3.4950559194080275E-003)) < 1.e-14 );
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printf("prim_vgl[26][4][7] = %e\n",prim_vgl[26][4][7]);
assert( fabs(prim_vgl[26][4][7] - ( 2.0392163767356572E-002)) < 1.e-14 );
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}
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#+end_src
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*** Ideas for improvement :noexport:
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#+begin_src c
// j : electrons
// l : primitives
k=0;
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for (j=0 ; j<point_num ; ++j) {
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for (i=0 ; i<nucl_num ; ++i) {
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r2 = nucl_point_dist[i][j];
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if (r2 < nucl_radius2[i]) {
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for (l=0 ; l<prim_num ; ++l) {
tmp[k].i = i;
tmp[k].j = j;
tmp[k].m = m;
tmp[k].ar2 = -expo[l] *r2;
++k;
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}
}
}
}
// sort(tmp) in increasing ar2;
// Identify first ar2 above numerical accuracy threshold
// Compute vectorized exponentials on significant values
#+end_src
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** Computation of shells
:PROPERTIES:
:Name: qmckl_compute_ao_basis_shell_gaussian_vgl
:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
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#+NAME: qmckl_ao_basis_shell_gaussian_vgl_args
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| Variable | Type | In/Out | Description |
|---------------------+-----------------------------------+--------+----------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~prim_num~ | ~int64_t~ | in | Number of primitives |
| ~shell_num~ | ~int64_t~ | in | Number of shells |
| ~point_num~ | ~int64_t~ | in | Number of points |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | in | Number of shells for each nucleus |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st shell of each nucleus |
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| ~nucleus_range~ | ~double[nucl_num]~ | in | Range of the nucleus |
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| ~shell_prim_index~ | ~int64_t[shell_num]~ | in | Index of the 1st primitive of each shell |
| ~shell_prim_num~ | ~int64_t[shell_num]~ | in | Number of primitives per shell |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~expo~ | ~double[prim_num]~ | in | Exponents of the primitives |
| ~coef_normalized~ | ~double[prim_num]~ | in | Coefficients of the primitives |
| ~shell_vgl~ | ~double[point_num][5][shell_num]~ | out | Value, gradients and Laplacian of the shells |
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#+CALL: generate_c_header(table=qmckl_ao_basis_shell_gaussian_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_basis_shell_gaussian_vgl"))
#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_compute_ao_basis_shell_gaussian_vgl (
const qmckl_context context,
const int64_t prim_num,
const int64_t shell_num,
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const int64_t point_num,
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const int64_t nucl_num,
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const int64_t* nucleus_shell_num,
const int64_t* nucleus_index,
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const double* nucleus_range,
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const int64_t* shell_prim_index,
const int64_t* shell_prim_num,
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const double* coord,
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const double* nucl_coord,
const double* expo,
const double* coef_normalized,
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double* const shell_vgl );
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#+end_src
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#+begin_src f90 :comments org :tangle (eval f) :noweb yes
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integer function qmckl_compute_ao_basis_shell_gaussian_vgl_f( &
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context, prim_num, shell_num, point_num, nucl_num, &
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nucleus_shell_num, nucleus_index, nucleus_range, &
shell_prim_index, shell_prim_num, coord, nucl_coord, &
expo, coef_normalized, shell_vgl) &
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result(info)
use qmckl
implicit none
integer(qmckl_context), intent(in) :: context
integer*8 , intent(in) :: prim_num
integer*8 , intent(in) :: shell_num
integer*8 , intent(in) :: nucl_num
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integer*8 , intent(in) :: point_num
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integer*8 , intent(in) :: nucleus_shell_num(nucl_num)
integer*8 , intent(in) :: nucleus_index(nucl_num)
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double precision , intent(in) :: nucleus_range(nucl_num)
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integer*8 , intent(in) :: shell_prim_index(shell_num)
integer*8 , intent(in) :: shell_prim_num(shell_num)
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double precision , intent(in) :: coord(point_num,3)
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double precision , intent(in) :: nucl_coord(nucl_num,3)
double precision , intent(in) :: expo(prim_num)
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double precision , intent(in) :: coef_normalized(prim_num)
double precision , intent(out) :: shell_vgl(shell_num,5,point_num)
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integer*8 :: inucl, iprim, ipoint, ishell
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integer*8 :: ishell_start, ishell_end
integer*8 :: iprim_start , iprim_end
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double precision :: x, y, z, two_a, ar2, r2, v, cutoff
info = QMCKL_SUCCESS
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
2021-06-22 23:33:09 +02:00
! Don't compute exponentials when the result will be almost zero.
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
! TODO : Use numerical precision here
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cutoff = 27.631021115928547 !-dlog(1.d-12)
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do ipoint = 1, point_num
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do inucl=1,nucl_num
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x = coord(ipoint,1) - nucl_coord(inucl,1)
y = coord(ipoint,2) - nucl_coord(inucl,2)
z = coord(ipoint,3) - nucl_coord(inucl,3)
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r2 = x*x + y*y + z*z
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if (r2 > cutoff*nucleus_range(inucl)) then
cycle
end if
! C is zero-based, so shift bounds by one
ishell_start = nucleus_index(inucl) + 1
ishell_end = nucleus_index(inucl) + nucleus_shell_num(inucl)
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do ishell=ishell_start, ishell_end
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shell_vgl(ishell, 1, ipoint) = 0.d0
shell_vgl(ishell, 2, ipoint) = 0.d0
shell_vgl(ishell, 3, ipoint) = 0.d0
shell_vgl(ishell, 4, ipoint) = 0.d0
shell_vgl(ishell, 5, ipoint) = 0.d0
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iprim_start = shell_prim_index(ishell) + 1
iprim_end = shell_prim_index(ishell) + shell_prim_num(ishell)
do iprim = iprim_start, iprim_end
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ar2 = expo(iprim)*r2
if (ar2 > cutoff) then
cycle
end if
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v = coef_normalized(iprim) * dexp(-ar2)
two_a = -2.d0 * expo(iprim) * v
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
shell_vgl(ishell, 1, ipoint) = &
shell_vgl(ishell, 1, ipoint) + v
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
shell_vgl(ishell, 2, ipoint) = &
shell_vgl(ishell, 2, ipoint) + two_a * x
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
shell_vgl(ishell, 3, ipoint) = &
shell_vgl(ishell, 3, ipoint) + two_a * y
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
shell_vgl(ishell, 4, ipoint) = &
shell_vgl(ishell, 4, ipoint) + two_a * z
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shell_vgl(ishell, 5, ipoint) = &
shell_vgl(ishell, 5, ipoint) + two_a * (3.d0 - 2.d0*ar2)
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
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end do
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end do
end do
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end do
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
2021-07-07 13:42:42 +02:00
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end function qmckl_compute_ao_basis_shell_gaussian_vgl_f
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#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_basis_shell_gaussian_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_basis_shell_gaussian_vgl"))
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#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
integer(c_int32_t) function qmckl_compute_ao_basis_shell_gaussian_vgl &
(context, &
prim_num, &
shell_num, &
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point_num, &
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nucl_num, &
nucleus_shell_num, &
nucleus_index, &
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nucleus_range, &
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shell_prim_index, &
shell_prim_num, &
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coord, &
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nucl_coord, &
expo, &
coef_normalized, &
shell_vgl) &
bind(C) result(info)
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use, intrinsic :: iso_c_binding
implicit none
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integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: prim_num
integer (c_int64_t) , intent(in) , value :: shell_num
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integer (c_int64_t) , intent(in) , value :: point_num
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integer (c_int64_t) , intent(in) , value :: nucl_num
integer (c_int64_t) , intent(in) :: nucleus_shell_num(nucl_num)
integer (c_int64_t) , intent(in) :: nucleus_index(nucl_num)
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real (c_double ) , intent(in) :: nucleus_range(nucl_num)
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integer (c_int64_t) , intent(in) :: shell_prim_index(shell_num)
integer (c_int64_t) , intent(in) :: shell_prim_num(shell_num)
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real (c_double ) , intent(in) :: coord(point_num,3)
real (c_double ) , intent(in) :: nucl_coord(nucl_num,3)
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real (c_double ) , intent(in) :: expo(prim_num)
real (c_double ) , intent(in) :: coef_normalized(prim_num)
real (c_double ) , intent(out) :: shell_vgl(shell_num,5,point_num)
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integer(c_int32_t), external :: qmckl_compute_ao_basis_shell_gaussian_vgl_f
info = qmckl_compute_ao_basis_shell_gaussian_vgl_f &
(context, &
prim_num, &
shell_num, &
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point_num, &
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nucl_num, &
nucleus_shell_num, &
nucleus_index, &
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nucleus_range, &
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shell_prim_index, &
shell_prim_num, &
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coord, &
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nucl_coord, &
expo, &
coef_normalized, &
shell_vgl)
end function qmckl_compute_ao_basis_shell_gaussian_vgl
#+end_src
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*** Provide :noexport:
#+CALL: write_provider_header( group="ao_basis", data="shell_vgl" )
#+RESULTS:
#+begin_src c :comments org :tangle (eval h_private_func) :noweb yes :export none
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qmckl_exit_code qmckl_provide_ao_basis_shell_vgl(qmckl_context context);
#+end_src
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#+CALL: write_provider_pre( group="ao_basis", data="shell_vgl", dimension="ctx->ao_basis.shell_num * 5 * ctx->point.num")
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
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qmckl_exit_code qmckl_provide_ao_basis_shell_vgl(qmckl_context context)
{
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qmckl_exit_code rc = QMCKL_SUCCESS;
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_provide_ao_basis_shell_vgl",
NULL);
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
if (!ctx->ao_basis.provided) {
return qmckl_failwith( context,
QMCKL_NOT_PROVIDED,
"qmckl_provide_ao_basis_shell_vgl",
NULL);
}
/* Compute if necessary */
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if (ctx->point.date > ctx->ao_basis.shell_vgl_date) {
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->ao_basis.shell_num * 5 * ctx->point.num * sizeof(double);
if (ctx->ao_basis.shell_vgl != NULL) {
qmckl_memory_info_struct mem_info_test = qmckl_memory_info_struct_zero;
rc = qmckl_get_malloc_info(context, ctx->ao_basis.shell_vgl, &mem_info_test);
/* if rc != QMCKL_SUCCESS, we are maybe in an _inplace function because the
memory was not allocated with qmckl_malloc */
if ((rc == QMCKL_SUCCESS) && (mem_info_test.size != mem_info.size)) {
rc = qmckl_free(context, ctx->ao_basis.shell_vgl);
assert (rc == QMCKL_SUCCESS);
ctx->ao_basis.shell_vgl = NULL;
}
}
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/* Allocate array */
if (ctx->ao_basis.shell_vgl == NULL) {
double* shell_vgl = (double*) qmckl_malloc(context, mem_info);
if (shell_vgl == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"qmckl_ao_basis_shell_vgl",
NULL);
}
ctx->ao_basis.shell_vgl = shell_vgl;
}
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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if (ctx->ao_basis.type == 'G') {
rc = qmckl_compute_ao_basis_shell_gaussian_vgl(context,
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ctx->ao_basis.prim_num,
ctx->ao_basis.shell_num,
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ctx->point.num,
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ctx->nucleus.num,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_index,
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ctx->ao_basis.nucleus_range,
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ctx->ao_basis.shell_prim_index,
ctx->ao_basis.shell_prim_num,
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ctx->point.coord.data,
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ctx->nucleus.coord.data,
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ctx->ao_basis.exponent,
ctx->ao_basis.coefficient_normalized,
ctx->ao_basis.shell_vgl);
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} else {
return qmckl_failwith( context,
QMCKL_FAILURE,
"compute_ao_basis_shell_vgl",
"Not yet implemented");
}
#+end_src
#+CALL: write_provider_post( group="ao_basis", data="shell_vgl" )
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
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if (rc != QMCKL_SUCCESS) {
return rc;
}
ctx->ao_basis.shell_vgl_date = ctx->date;
}
return QMCKL_SUCCESS;
}
#+end_src
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*** Test :noexport:
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#+begin_src python :results output :exports none
import numpy as np
def f(a,x,y):
Integration of Verificarlo CI tests (#1) * comment * Update distance test code The distance test has been updated to the latest version, with a first attempt at using vfc_probes inside it * Functional implementation of vfc_probes in the distance tests This commit has the first functional vfc_ci tests. Verificarlo tests should be written over the existing tests, and they can be enabled with the following configure command: QMCKL_DEVEL=1 ./configure --prefix=$PWD/_install --enable-maintainer-mode --enable-vfc_ci CC="verificarlo-f -Mpreprocess -D VFC_CI" FC="verificarlo-f -Mpreprocess -D VFC_CI" --host=x86_64 The --enable-vfc_ci flag will trigger the linking of the vfc_ci library. Moreover, as of now, the "-Mpreprocess" and "-D VFC_CI" flags have to be specified directly here. There is probably an appropriate macro to place those flags into but I couldn't find it yet, and could only manage to build the tests this way. When the VFC_CI preprocessor is defined, somme additional code to register and export the test probes can be executed (see qmckl_distance.org). As of now, the tests are built as normal, even though they are expected to fail : make all make check From there, the test_qmckl_distance (and potentially the others) executable can be called at will. This will typically be done automatically by vfc_ci, but one could manually execute the executable by defining the following env variables : VFC_PROBES_OUTPUT="test.csv" VFC_BACKENDS="libinterflop_ieee.so" depending on the export file and the Verificarlo backend to be used. The next steps will be to define more tests such as this one, and to integrate them into a Verificarlo CI workflow (by writing a vfc_tests_config.json file and using the automatic CI setup command). * Error in FOrtran interface fixed * Added missing Fortran interfaces * Modify distance test and install process integration All probes are now ignored using only the preprocessor (instead of checking for a facultative argument) in the distance test. Moreover,preprocessing can now be enabled correctly using FCFLAGS (the issue seemed to come from the order of the arguments passed to gfortran/verificarlo-f with the preprocessor arg having to come first). * Add vfc_probes to AO tests vfc_probes have been added to qmckl_ao.org in the same way as qmckl_distance.org, which means that it can be enabled or disabled at compile time using the --enable-vfc_ci option. qmckl_distance.org has been slightly modified with a better indentation, and configure.ac now adds the "-D VFC_CI" flag to CFLAGS when vfc_ci is enabled. Co-authored-by: Anthony Scemama <scemama@irsamc.ups-tlse.fr>
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return np.sum( [c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] )
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def df(a,x,y,n):
h0 = 1.e-6
if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
return ( f(a,x+h,y) - f(a,x-h,y) ) / (2.*h0)
def d2f(a,x,y,n):
h0 = 1.e-6
if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
return ( f(a,x+h,y) - 2.*f(a,x,y) + f(a,x-h,y) ) / h0**2
def lf(a,x,y):
return d2f(a,x,y,1) + d2f(a,x,y,2) + d2f(a,x,y,3)
elec_26_w1 = np.array( [ 1.49050402641, 2.90106987953, -1.05920815468 ] )
elec_15_w2 = np.array( [ -2.20180344582,-1.9113150239, 2.2193744778600002 ] )
nucl_1 = np.array( [ 1.096243353458458e+00, 8.907054016973815e-01, 7.777092280258892e-01 ] )
nucl_2 = np.array( [ 1.168459237342663e+00, 1.125660720053393e+00, 2.833370314829343e+00 ] )
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#double prim_vgl[prim_num][5][point_num];
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x = elec_26_w1 ; y = nucl_1
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a = [( 8.236000E+03, -1.130000E-04 * 6.1616545431994848e+02 ),
( 1.235000E+03, -8.780000E-04 * 1.4847738511079908e+02 ),
( 2.808000E+02, -4.540000E-03 * 4.8888635917437597e+01 ),
( 7.927000E+01, -1.813300E-02 * 1.8933972232608955e+01 ),
( 2.559000E+01, -5.576000E-02 * 8.1089160941724145e+00 ),
( 8.997000E+00, -1.268950E-01 * 3.7024003863155635e+00 ),
( 3.319000E+00, -1.703520E-01 * 1.7525302846177560e+00 ),
( 9.059000E-01, 1.403820E-01 * 6.6179013183966806e-01 ),
( 3.643000E-01, 5.986840E-01 * 3.3419848027174592e-01 ),
( 1.285000E-01, 3.953890E-01 * 1.5296336817449557e-01 )]
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print ( "[1][0][26] : %25.15e"% f(a,x,y))
print ( "[1][1][26] : %25.15e"% df(a,x,y,1))
print ( "[1][2][26] : %25.15e"% df(a,x,y,2))
print ( "[1][3][26] : %25.15e"% df(a,x,y,3))
print ( "[1][4][26] : %25.15e"% lf(a,x,y))
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#+end_src
#+RESULTS:
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: [1][0][26] : 3.564393437193867e-02
: [1][1][26] : -6.030177988891605e-03
: [1][2][26] : -3.074832579871845e-02
: [1][3][26] : 2.809546963133958e-02
: [1][4][26] : 1.903338597841753e-02
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#+begin_src c :tangle (eval c_test) :exports none
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{
#define shell_num chbrclf_shell_num
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double* elec_coord = &(chbrclf_elec_coord[0][0][0]);
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assert(qmckl_electron_provided(context));
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const int64_t point_num = elec_num;
rc = qmckl_set_point(context, 'N', point_num, elec_coord, point_num*3);
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assert(rc == QMCKL_SUCCESS);
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double shell_vgl[point_num][5][shell_num];
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rc = qmckl_get_ao_basis_shell_vgl(context, &(shell_vgl[0][0][0]),
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(int64_t) 5*point_num*shell_num);
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assert (rc == QMCKL_SUCCESS);
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printf(" shell_vgl[26][0][1] %25.15e\n", shell_vgl[26][0][1]);
printf(" shell_vgl[26][1][1] %25.15e\n", shell_vgl[26][1][1]);
printf(" shell_vgl[26][2][1] %25.15e\n", shell_vgl[26][2][1]);
printf(" shell_vgl[26][3][1] %25.15e\n", shell_vgl[26][3][1]);
printf(" shell_vgl[26][4][1] %25.15e\n", shell_vgl[26][4][1]);
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assert( fabs(shell_vgl[26][0][1] - ( 3.564393437193868e-02)) < 1.e-14 );
assert( fabs(shell_vgl[26][1][1] - (-6.030177987072189e-03)) < 1.e-14 );
assert( fabs(shell_vgl[26][2][1] - (-3.074832579537582e-02)) < 1.e-14 );
assert( fabs(shell_vgl[26][3][1] - ( 2.809546963519935e-02)) < 1.e-14 );
assert( fabs(shell_vgl[26][4][1] - ( 1.896046117183968e-02)) < 1.e-14 );
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}
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#+end_src
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* Polynomial part
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Going from the atomic basis set to AOs implies a systematic
construction of all the angular functions of each shell. We
consider two cases for the angular functions: the real-valued
spherical harmonics, and the polynomials in Cartesian coordinates.
In the case of spherical harmonics, the AOs are ordered in
increasing magnetic quantum number ($-l \le m \le l$), and in the
case of polynomials we choose the canonical ordering, i.e
\begin{eqnarray}
p & : & p_x, p_y, p_z \nonumber \\
d & : & d_{xx}, d_{xy}, d_{xz}, d_{yy}, d_{yz}, d_{zz} \nonumber \\
f & : & f_{xxx}, f_{xxy}, f_{xxz}, f_{xyy}, f_{xyz}, f_{xzz}, f_{yyy}, f_{yyz}, f_{yzz}, f_{zzz} \nonumber \\
{\rm etc.} \nonumber
\end{eqnarray}
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** General functions for Powers of $x-X_i$
:PROPERTIES:
:Name: qmckl_ao_power
:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
The ~qmckl_ao_power~ function computes all the powers of the ~n~
input data up to the given maximum value given in input for each of
the $n$ points:
\[ P_{ik} = X_i^k \]
#+NAME: qmckl_ao_power_args
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| Variable | Type | In/Out | Description |
|-----------+-----------------+--------+---------------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~n~ | int64_t | in | Number of values |
| ~X~ | double[n] | in | Array containing the input values |
| ~LMAX~ | int32_t[n] | in | Array containing the maximum power for each value |
| ~P~ | double[n][ldp] | out | Array containing all the powers of ~X~ |
| ~ldp~ | int64_t | in | Leading dimension of array ~P~ |
Requirements:
- ~context~ is not ~QMCKL_NULL_CONTEXT~
- ~n~ > 0
- ~X~ is allocated with at least $n \times 8$ bytes
- ~LMAX~ is allocated with at least $n \times 4$ bytes
- ~P~ is allocated with at least $n \times \max_i \text{LMAX}_i \times 8$ bytes
- ~LDP~ >= $\max_i$ ~LMAX[i]~
#+CALL: generate_c_header(table=qmckl_ao_power_args,rettyp=get_value("CRetType"),fname="qmckl_ao_power")
#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
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qmckl_exit_code qmckl_ao_power (
const qmckl_context context,
const int64_t n,
const double* X,
const int32_t* LMAX,
double* const P,
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const int64_t ldp );
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#+end_src
#+begin_src f90 :tangle (eval f)
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integer function qmckl_ao_power_f(context, n, X, LMAX, P, ldp) result(info)
use qmckl
implicit none
integer*8 , intent(in) :: context
integer*8 , intent(in) :: n
real*8 , intent(in) :: X(n)
integer , intent(in) :: LMAX(n)
real*8 , intent(out) :: P(ldp,n)
integer*8 , intent(in) :: ldp
integer*8 :: i,k
info = QMCKL_SUCCESS
if (context == QMCKL_NULL_CONTEXT) then
info = QMCKL_INVALID_CONTEXT
return
endif
if (n <= ldp) then
info = QMCKL_INVALID_ARG_2
return
endif
k = MAXVAL(LMAX)
if (LDP < k) then
info = QMCKL_INVALID_ARG_6
return
endif
if (k <= 0) then
info = QMCKL_INVALID_ARG_4
return
endif
do i=1,n
P(1,i) = X(i)
do k=2,LMAX(i)
P(k,i) = P(k-1,i) * X(i)
end do
end do
end function qmckl_ao_power_f
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#+end_src
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#+CALL: generate_f_interface(table=qmckl_ao_power_args,rettyp=get_value("CRetType"),fname="qmckl_ao_power")
#+RESULTS:
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_ao_power &
(context, n, X, LMAX, P, ldp) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: n
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real (c_double ) , intent(in) :: X(n)
integer (c_int32_t) , intent(in) :: LMAX(n)
real (c_double ) , intent(out) :: P(ldp,n)
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integer (c_int64_t) , intent(in) , value :: ldp
end function qmckl_ao_power
end interface
#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_power_args,rettyp=get_value("CRetType"),fname="qmckl_ao_power")
#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
integer(c_int32_t) function qmckl_ao_power &
(context, n, X, LMAX, P, ldp) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: n
real (c_double ) , intent(in) :: X(n)
integer (c_int32_t) , intent(in) :: LMAX(n)
real (c_double ) , intent(out) :: P(ldp,n)
integer (c_int64_t) , intent(in) , value :: ldp
integer(c_int32_t), external :: qmckl_ao_power_f
info = qmckl_ao_power_f &
(context, n, X, LMAX, P, ldp)
end function qmckl_ao_power
#+end_src
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*** Test :noexport:
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#+begin_src f90 :tangle (eval f_test)
integer(c_int32_t) function test_qmckl_ao_power(context) bind(C)
use qmckl
implicit none
integer(qmckl_context), intent(in), value :: context
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integer*8 :: n, LDP
integer, allocatable :: LMAX(:)
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double precision, allocatable :: X(:), P(:,:)
integer*8 :: i,j
double precision :: epsilon
epsilon = qmckl_get_numprec_epsilon(context)
n = 100;
LDP = 10;
allocate(X(n), P(LDP,n), LMAX(n))
do j=1,n
X(j) = -5.d0 + 0.1d0 * dble(j)
LMAX(j) = 1 + int(mod(j, 5),4)
end do
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test_qmckl_ao_power = qmckl_ao_power(context, n, X, LMAX, P, LDP)
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if (test_qmckl_ao_power /= QMCKL_SUCCESS) return
test_qmckl_ao_power = QMCKL_FAILURE
do j=1,n
do i=1,LMAX(j)
if ( X(j)**i == 0.d0 ) then
if ( P(i,j) /= 0.d0) return
else
if ( dabs(1.d0 - P(i,j) / (X(j)**i)) > epsilon ) return
end if
end do
end do
test_qmckl_ao_power = QMCKL_SUCCESS
deallocate(X,P,LMAX)
end function test_qmckl_ao_power
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#+end_src
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#+begin_src c :tangle (eval c_test) :exports none
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int test_qmckl_ao_power(qmckl_context context);
assert(0 == test_qmckl_ao_power(context));
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#+end_src
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** General functions for Value, Gradient and Laplacian of a polynomial
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:PROPERTIES:
:Name: qmckl_ao_polynomial_vgl
:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
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A polynomial is centered on a nucleus $\mathbf{R}_i$
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\[
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P_l(\mathbf{r},\mathbf{R}_i) = (x-X_i)^a (y-Y_i)^b (z-Z_i)^c
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\]
The gradients with respect to electron coordinates are
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\begin{eqnarray*}
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\frac{\partial }{\partial x} P_l\left(\mathbf{r},\mathbf{R}_i \right) &
= & a (x-X_i)^{a-1} (y-Y_i)^b (z-Z_i)^c \\
\frac{\partial }{\partial y} P_l\left(\mathbf{r},\mathbf{R}_i \right) &
= & b (x-X_i)^a (y-Y_i)^{b-1} (z-Z_i)^c \\
\frac{\partial }{\partial z} P_l\left(\mathbf{r},\mathbf{R}_i \right) &
= & c (x-X_i)^a (y-Y_i)^b (z-Z_i)^{c-1} \\
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\end{eqnarray*}
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and the Laplacian is
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\begin{eqnarray*}
\left( \frac{\partial }{\partial x^2} +
\frac{\partial }{\partial y^2} +
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\frac{\partial }{\partial z^2} \right) P_l
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\left(\mathbf{r},\mathbf{R}_i \right) & = &
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a(a-1) (x-X_i)^{a-2} (y-Y_i)^b (z-Z_i)^c + \\
&& b(b-1) (x-X_i)^a (y-Y_i)^{b-1} (z-Z_i)^c + \\
&& c(c-1) (x-X_i)^a (y-Y_i)^b (z-Z_i)^{c-1}.
\end{eqnarray*}
~qmckl_ao_polynomial_vgl~ computes the values, gradients and
Laplacians at a given point in space, of all polynomials with an
angular momentum up to ~lmax~.
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#+NAME: qmckl_ao_polynomial_vgl_args
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| Variable | Type | In/Out | Description |
|-----------+-------------------+--------+------------------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~X~ | ~double[3]~ | in | Array containing the coordinates of the points |
| ~R~ | ~double[3]~ | in | Array containing the x,y,z coordinates of the center |
| ~lmax~ | ~int32_t~ | in | Maximum angular momentum |
| ~n~ | ~int64_t~ | inout | Number of computed polynomials |
| ~L~ | ~int32_t[n][ldl]~ | out | Contains a,b,c for all ~n~ results |
| ~ldl~ | ~int64_t~ | in | Leading dimension of ~L~ |
| ~VGL~ | ~double[n][ldv]~ | out | Value, gradients and Laplacian of the polynomials |
| ~ldv~ | ~int64_t~ | in | Leading dimension of array ~VGL~ |
Requirements:
- ~context~ \ne ~QMCKL_NULL_CONTEXT~
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- ~n~ > 0
- ~lmax~ >= 0
- ~ldl~ >= 3
- ~ldv~ >= 5
- ~X~ is allocated with at least $3 \times 8$ bytes
- ~R~ is allocated with at least $3 \times 8$ bytes
- ~n~ >= ~(lmax+1)(lmax+2)(lmax+3)/6~
- ~L~ is allocated with at least $3 \times n \times 4$ bytes
- ~VGL~ is allocated with at least $5 \times n \times 8$ bytes
- On output, ~n~ should be equal to ~(lmax+1)(lmax+2)(lmax+3)/6~
- On output, the powers are given in the following order (l=a+b+c):
- Increasing values of ~l~
- Within a given value of ~l~, alphabetical order of the
string made by a*"x" + b*"y" + c*"z" (in Python notation).
For example, with a=0, b=2 and c=1 the string is "yyz"
#+CALL: generate_c_header(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname=get_value("Name"))
#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_ao_polynomial_vgl (
const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
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const int64_t ldv );
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#+end_src
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#+CALL: generate_c_header(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_vgl_doc")
#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_ao_polynomial_vgl_doc (
const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
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const int64_t ldv );
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#+end_src
#+begin_src c :tangle (eval c) :comments org
qmckl_exit_code
qmckl_ao_polynomial_vgl (const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
const int64_t ldv )
{
#ifdef HAVE_HPC
//return qmckl_ao_polynomial_vgl_hpc (context, X, R, lmax, n, L, ldl, VGL, ldv);
return qmckl_ao_polynomial_vgl_doc (context, X, R, lmax, n, L, ldl, VGL, ldv);
#else
return qmckl_ao_polynomial_vgl_doc (context, X, R, lmax, n, L, ldl, VGL, ldv);
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#endif
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}
#+end_src
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#+begin_src f90 :tangle (eval f)
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integer function qmckl_ao_polynomial_vgl_doc_f (context, &
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X, R, lmax, n, L, ldl, VGL, ldv) result(info)
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use qmckl
implicit none
integer*8 , intent(in) :: context
real*8 , intent(in) :: X(3), R(3)
integer , intent(in) :: lmax
integer*8 , intent(out) :: n
integer , intent(out) :: L(ldl,(lmax+1)*(lmax+2)*(lmax+3)/6)
integer*8 , intent(in) :: ldl
real*8 , intent(out) :: VGL(ldv,(lmax+1)*(lmax+2)*(lmax+3)/6)
integer*8 , intent(in) :: ldv
integer*8 :: i,j
integer :: a,b,c,d
real*8 :: Y(3)
real*8 :: pows(-2:lmax,3)
double precision :: xy, yz, xz
double precision :: da, db, dc, dd
info = 0
if (context == QMCKL_NULL_CONTEXT) then
info = QMCKL_INVALID_CONTEXT
return
endif
if (lmax < 0) then
info = QMCKL_INVALID_ARG_4
return
endif
if (ldl < 3) then
info = QMCKL_INVALID_ARG_7
return
endif
if (ldv < 5) then
info = QMCKL_INVALID_ARG_9
return
endif
do i=1,3
Y(i) = X(i) - R(i)
end do
if (lmax == 0) then
VGL(1,1) = 1.d0
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VGL(2:5,1) = 0.d0
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l(1:3,1) = 0
n=1
else if (lmax > 0) then
pows(-2:0,1:3) = 1.d0
do i=1,lmax
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pows(i,1) = pows(i-1,1) * Y(1)
pows(i,2) = pows(i-1,2) * Y(2)
pows(i,3) = pows(i-1,3) * Y(3)
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end do
VGL(1:5,1:4) = 0.d0
l (1:3,1:4) = 0
VGL(1 ,1 ) = 1.d0
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VGL(1:5,2:4) = 0.d0
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l (1,2) = 1
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VGL(1,2) = pows(1,1)
VGL(2,2) = 1.d0
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l (2,3) = 1
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VGL(1,3) = pows(1,2)
VGL(3,3) = 1.d0
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l (3,4) = 1
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VGL(1,4) = pows(1,3)
VGL(4,4) = 1.d0
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n=4
endif
! l>=2
dd = 2.d0
do d=2,lmax
da = dd
do a=d,0,-1
db = dd-da
do b=d-a,0,-1
c = d - a - b
dc = dd - da - db
n = n+1
l(1,n) = a
l(2,n) = b
l(3,n) = c
xy = pows(a,1) * pows(b,2)
yz = pows(b,2) * pows(c,3)
xz = pows(a,1) * pows(c,3)
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VGL(1,n) = xy * pows(c,3)
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xy = dc * xy
xz = db * xz
yz = da * yz
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VGL(2,n) = pows(a-1,1) * yz
VGL(3,n) = pows(b-1,2) * xz
VGL(4,n) = pows(c-1,3) * xy
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VGL(5,n) = &
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(da-1.d0) * pows(a-2,1) * yz + &
(db-1.d0) * pows(b-2,2) * xz + &
(dc-1.d0) * pows(c-2,3) * xy
db = db - 1.d0
end do
da = da - 1.d0
end do
dd = dd + 1.d0
end do
info = QMCKL_SUCCESS
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end function qmckl_ao_polynomial_vgl_doc_f
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#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_vgl_doc" )
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#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
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integer(c_int32_t) function qmckl_ao_polynomial_vgl_doc &
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(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
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integer(c_int32_t), external :: qmckl_ao_polynomial_vgl_doc_f
info = qmckl_ao_polynomial_vgl_doc_f &
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(context, X, R, lmax, n, L, ldl, VGL, ldv)
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end function qmckl_ao_polynomial_vgl_doc
#+end_src
#+CALL: generate_f_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("FRetType"),fname="qmckl_ao_polynomial_vgl_doc" )
#+RESULTS:
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_ao_polynomial_vgl_doc &
(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
end function qmckl_ao_polynomial_vgl_doc
end interface
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#+end_src
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#+CALL: generate_f_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("FRetType"),fname="qmckl_ao_polynomial_vgl" )
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#+RESULTS:
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_ao_polynomial_vgl &
(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
end function qmckl_ao_polynomial_vgl
end interface
#+end_src
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#+CALL: generate_c_header(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_transp_vgl")
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#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_ao_polynomial_transp_vgl (
const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
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const int64_t ldv );
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#+end_src
#+CALL: generate_c_header(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_transp_vgl_doc")
#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_ao_polynomial_transp_vgl_doc (
const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
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const int64_t ldv );
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#+end_src
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# #+CALL: generate_c_header(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_transp_vgl_hpc")
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#+RESULTS:
#+begin_src c :tangle (eval h_func) :comments org
qmckl_exit_code qmckl_ao_polynomial_transp_vgl_hpc (
const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
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const int64_t ldv );
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#+end_src
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#+begin_src c :tangle (eval c) :comments org
qmckl_exit_code
qmckl_ao_polynomial_transp_vgl (const qmckl_context context,
const double* X,
const double* R,
const int32_t lmax,
int64_t* n,
int32_t* const L,
const int64_t ldl,
double* const VGL,
const int64_t ldv )
{
#ifdef HAVE_HPC
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return qmckl_ao_polynomial_transp_vgl_hpc (context, X, R, lmax, n, L, ldl, VGL, ldv);
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#else
return qmckl_ao_polynomial_transp_vgl_doc (context, X, R, lmax, n, L, ldl, VGL, ldv);
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#endif
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}
#+end_src
#+begin_src f90 :tangle (eval f)
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integer function qmckl_ao_polynomial_transp_vgl_doc_f (context, &
X, R, lmax, n, L, ldl, VGL, ldv) result(info)
use qmckl
implicit none
integer*8 , intent(in) :: context
real*8 , intent(in) :: X(3), R(3)
integer , intent(in) :: lmax
integer*8 , intent(out) :: n
integer , intent(out) :: L(ldl,(lmax+1)*(lmax+2)*(lmax+3)/6)
integer*8 , intent(in) :: ldl
real*8 , intent(out) :: VGL(ldv,5)
integer*8 , intent(in) :: ldv
integer*8 :: i,j
integer :: a,b,c,d
real*8 :: Y(3)
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real*8 :: pows(-2:21,3) ! lmax < 22
double precision :: xy, yz, xz
double precision :: da, db, dc, dd
info = 0
if (context == QMCKL_NULL_CONTEXT) then
info = QMCKL_INVALID_CONTEXT
return
endif
if (lmax < 0) then
info = QMCKL_INVALID_ARG_4
return
endif
if (ldl < 3) then
info = QMCKL_INVALID_ARG_7
return
endif
if (ldv < (lmax+1)*(lmax+2)*(lmax+3)/6) then
info = QMCKL_INVALID_ARG_9
return
endif
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if (lmax > 0) then
do i=1,3
Y(i) = X(i) - R(i)
end do
pows(-2:0,1:3) = 1.d0
do i=1,lmax
pows(i,1) = pows(i-1,1) * Y(1)
pows(i,2) = pows(i-1,2) * Y(2)
pows(i,3) = pows(i-1,3) * Y(3)
end do
l (1:3,1:4) = 0
VGL(1:4,1:5) = 0.d0
VGL(1 ,1 ) = 1.d0
l (1,2) = 1
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VGL(2,1) = Y(1)
VGL(2,2) = 1.d0
l (2,3) = 1
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VGL(3,1) = Y(2)
VGL(3,3) = 1.d0
l (3,4) = 1
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VGL(4,1) = Y(3)
VGL(4,4) = 1.d0
n=4
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else
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VGL(1,1) = 1.d0
VGL(1,2:5) = 0.d0
l(1:3,1) = 0
n=1
return
endif
! l>=2
dd = 2.d0
do d=2,lmax
da = dd
do a=d,0,-1
db = dd-da
do b=d-a,0,-1
c = d - a - b
dc = dd - da - db
n = n+1
xy = pows(a,1) * pows(b,2)
yz = pows(b,2) * pows(c,3)
xz = pows(a,1) * pows(c,3)
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l(1,n) = a
l(2,n) = b
l(3,n) = c
VGL(n,1) = xy * pows(c,3)
xy = dc * xy
xz = db * xz
yz = da * yz
VGL(n,2) = pows(a-1,1) * yz
VGL(n,3) = pows(b-1,2) * xz
VGL(n,4) = pows(c-1,3) * xy
VGL(n,5) = &
(da-1.d0) * pows(a-2,1) * yz + &
(db-1.d0) * pows(b-2,2) * xz + &
(dc-1.d0) * pows(c-2,3) * xy
db = db - 1.d0
end do
da = da - 1.d0
end do
dd = dd + 1.d0
end do
info = QMCKL_SUCCESS
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end function qmckl_ao_polynomial_transp_vgl_doc_f
#+end_src
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#+begin_src c :tangle (eval c) :comments org
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static inline qmckl_exit_code
qmckl_ao_polynomial_transp_vgl_hpc_inline (const qmckl_context context,
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const double* restrict X,
const double* restrict R,
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const int32_t lmax,
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int64_t* n,
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int32_t* restrict const L,
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const int64_t ldl,
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double* restrict const VGL,
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const int64_t ldv )
{
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const qmckl_context_struct* ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL && X != NULL && R != NULL && n != NULL && L != NULL && VGL != NULL);
if (lmax < 0) return QMCKL_INVALID_ARG_4;
if (ldl < 3) return QMCKL_INVALID_ARG_7;
int32_t m;
switch (lmax) {
case 0:
{
if (ldv < 1) return QMCKL_INVALID_ARG_9;
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L[0] = 0; L[1] = 0; L[2] = 0;
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VGL[0 ] = 1.0;
VGL[ldv ] = 0.0;
VGL[ldv<<1 ] = 0.0;
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VGL[(ldv<<1)+ldv] = 0.0;
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VGL[ldv<<2 ] = 0.0;
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m=1;
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break;
}
case 1:
{
if (ldv < 4) return QMCKL_INVALID_ARG_9;
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if (ldl == 3) {
const int32_t ltmp[12] = {0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1};
for (int i=0 ; i<12 ; ++i)
L[i] = ltmp[i];
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} else {
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int32_t* restrict const l[4] = {L, L+ldl, L+(ldl<<1), L+ldl+(ldl<<1)};
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l[0][0] = 0; l[0][1] = 0; l[0][2] = 0;
l[1][0] = 1; l[1][1] = 0; l[1][2] = 0;
l[2][0] = 0; l[2][1] = 1; l[2][2] = 0;
l[3][0] = 0; l[3][1] = 0; l[3][2] = 1;
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}
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if (ldv == 4) {
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const double tmp[20] = {1.0, X[0]-R[0], X[1]-R[1], X[2]-R[2],
0.0, 1.0, 0.0, 0.0,
0.0, 0.0, 1.0, 0.0,
0.0, 0.0, 0.0, 1.0,
0.0, 0.0, 0.0, 0.0};
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for (int i=0 ; i<20 ; ++i)
VGL[i] = tmp[i];
} else {
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double* restrict const vgl1 = VGL;
double* restrict const vgl2 = VGL + ldv;
double* restrict const vgl3 = VGL + (ldv << 1);
double* restrict const vgl4 = VGL + ldv + (ldv << 1);
double* restrict const vgl5 = VGL + (ldv << 2);
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for (int32_t k=0 ; k<4 ; ++k) {
vgl2[k] = 0.0;
vgl3[k] = 0.0;
vgl4[k] = 0.0;
vgl5[k] = 0.0;
}
vgl1[0] = 1.0;
vgl1[1] = X[0]-R[0];
vgl1[2] = X[1]-R[1];
vgl1[3] = X[2]-R[2];
vgl2[1] = 1.0;
vgl3[2] = 1.0;
vgl4[3] = 1.0;
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}
m=4;
break;
}
case 2:
{
if (ldv < 10) return QMCKL_INVALID_ARG_9;
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if (ldl == 3) {
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const int32_t ltmp[30] = {0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1,
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2, 0, 0, 1, 1, 0, 1, 0, 1, 0, 2, 0,
0, 1, 1, 0, 0, 2};
for (int i=0 ; i<30 ; ++i)
L[i] = ltmp[i];
} else {
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int32_t* restrict l[10];
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for (int32_t i=0 ; i<10 ; ++i) {
l[i] = L + i*ldl;
}
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l[0][0] = 0; l[0][1] = 0; l[0][2] = 0;
l[1][0] = 1; l[1][1] = 0; l[1][2] = 0;
l[2][0] = 0; l[2][1] = 1; l[2][2] = 0;
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l[3][0] = 0; l[3][1] = 0; l[3][2] = 1;
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l[4][0] = 2; l[4][1] = 0; l[4][2] = 0;
l[5][0] = 1; l[5][1] = 1; l[5][2] = 0;
l[6][0] = 1; l[6][1] = 0; l[6][2] = 1;
l[7][0] = 0; l[7][1] = 2; l[7][2] = 0;
l[8][0] = 0; l[8][1] = 1; l[8][2] = 1;
l[9][0] = 0; l[9][1] = 0; l[9][2] = 2;
}
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const double Y[3] = { X[0]-R[0],
X[1]-R[1],
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X[2]-R[2] };
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if (ldv == 50) {
const double tmp[50] = {
1.0, Y[0], Y[1], Y[2], Y[0] * Y[0],
Y[0] * Y[1], Y[0] * Y[2], Y[1] * Y[1], Y[1] * Y[2], Y[2] * Y[2],
0.0, 1.0, 0.0, 0.0, Y[0] + Y[0],
Y[1], Y[2], 0.0, 0.0, 0.0,
0.0, 0.0, 1.0, 0.0, 0.0,
Y[0], 0.0, Y[1] + Y[1], Y[2], 0.0,
0.0, 0.0, 0.0, 1.0, 0.0,
0.0, Y[0], 0.0, Y[1], Y[2] + Y[2],
0.0, 0.0, 0.0, 0.0, 2.0,
0.0, 0.0, 2.0, 0., 2.0 };
for (int i=0 ; i<50 ; ++i)
VGL[i] = tmp[i];
} else {
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double* restrict const vgl1 = VGL;
double* restrict const vgl2 = VGL + ldv;
double* restrict const vgl3 = VGL + (ldv << 1);
double* restrict const vgl4 = VGL + 3*ldv;
double* restrict const vgl5 = VGL + (ldv << 2);
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vgl1[0] = 1.0 ; vgl1[1] = Y[0] ; vgl1[2] = Y[1];
vgl1[3] = Y[2] ; vgl1[4] = Y[0]*Y[0]; vgl1[5] = Y[0]*Y[1];
vgl1[6] = Y[0]*Y[2]; vgl1[7] = Y[1]*Y[1]; vgl1[8] = Y[1]*Y[2];
vgl1[9] = Y[2]*Y[2];
vgl2[0] = 0.0 ; vgl2[1] = 1.0 ; vgl2[2] = 0.0 ;
vgl2[3] = 0.0 ; vgl2[4] = Y[0]+Y[0]; vgl2[5] = Y[1];
vgl2[6] = Y[2]; vgl2[7] = 0.0 ; vgl2[8] = 0.0 ;
vgl2[9] = 0.0 ;
vgl3[0] = 0.0; vgl3[1] = 0.0 ; vgl3[2] = 1.0 ;
vgl3[3] = 0.0; vgl3[4] = 0.0 ; vgl3[5] = Y[0];
vgl3[6] = 0.0; vgl3[7] = Y[1]+Y[1]; vgl3[8] = Y[2];
vgl3[9] = 0.0;
vgl4[0] = 0.0 ; vgl4[1] = 0.0; vgl4[2] = 0.0 ;
vgl4[3] = 1.0 ; vgl4[4] = 0.0; vgl4[5] = 0.0 ;
vgl4[6] = Y[0] ; vgl4[7] = 0.0; vgl4[8] = Y[1];
vgl4[9] = Y[2]+Y[2];
vgl5[0] = 0.0; vgl5[1] = 0.0; vgl5[2] = 0.0;
vgl5[3] = 0.0; vgl5[4] = 2.0; vgl5[5] = 0.0;
vgl5[6] = 0.0; vgl5[7] = 2.0; vgl5[8] = 0.0;
vgl5[9] = 2.0;
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}
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m=10;
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break;
}
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default:
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{
const int32_t size_max = (lmax+1)*(lmax+2)*(lmax+3)/6;
if (ldv < size_max) return QMCKL_INVALID_ARG_9;
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double* restrict const vgl1 = VGL;
double* restrict const vgl2 = VGL + ldv;
double* restrict const vgl3 = VGL + (ldv<<1);
double* restrict const vgl4 = VGL + ldv + (ldv<<1);
double* restrict const vgl5 = VGL + (ldv<<2);
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const double Y[3] = { X[0]-R[0],
X[1]-R[1],
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X[2]-R[2] };
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assert(size_max > lmax+3);
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double pows[3][size_max];
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for (int32_t i=0 ; i<3 ; ++i) {
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pows[0][i] = 1.0;
pows[1][i] = 1.0;
pows[2][i] = 1.0;
}
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for (int32_t i=3 ; i<=lmax+2 ; ++i) {
pows[0][i] = pows[0][i-1] * Y[0];
pows[1][i] = pows[1][i-1] * Y[1];
pows[2][i] = pows[2][i-1] * Y[2];
}
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int32_t* l[size_max];
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for (int32_t i=0 ; i<size_max ; ++i) {
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l[i] = &(L[i*ldl]);
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}
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for (int32_t i=0 ; i<4 ; ++i) {
l[i][0] = 0;
l[i][1] = 0;
l[i][2] = 0;
}
l[1][0] = 1;
l[2][1] = 1;
l[3][2] = 1;
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for (int32_t k=0 ; k<4 ; ++k) {
vgl2[k] = 0.0;
vgl3[k] = 0.0;
vgl4[k] = 0.0;
vgl5[k] = 0.0;
}
vgl1[0] = 1.0;
vgl1[1] = Y[0];
vgl1[2] = Y[1];
vgl1[3] = Y[2];
vgl2[1] = 1.0;
vgl3[2] = 1.0;
vgl4[3] = 1.0;
m=4;
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double dd = 2.0;
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for (int32_t d=2 ; d<= lmax ; ++d) {
double da = dd;
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for (int32_t a=d ; a>=0 ; --a) {
double db = dd-da;
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for (int32_t b=d-a ; b>=0 ; --b) {
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const int32_t c = d - a - b;
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const double dc = dd - da - db;
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double xy = pows[0][a+2] * pows[1][b+2];
double yz = pows[1][b+2] * pows[2][c+2];
double xz = pows[0][a+2] * pows[2][c+2];
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l[m][0] = a;
l[m][1] = b;
l[m][2] = c;
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vgl1[m] = xy * pows[2][c+2];
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xy *= dc;
xz *= db;
yz *= da;
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vgl2[m] = pows[0][a+1] * yz;
vgl3[m] = pows[1][b+1] * xz;
vgl4[m] = pows[2][c+1] * xy;
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vgl5[m] = (da-1.) * pows[0][a] * yz +
(db-1.) * pows[1][b] * xz +
(dc-1.) * pows[2][c] * xy;
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db -= 1.0;
++m;
}
da -= 1.0;
}
dd += 1.0;
}
}
}
,*n = m;
return QMCKL_SUCCESS;
}
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qmckl_exit_code
qmckl_ao_polynomial_transp_vgl_hpc (const qmckl_context context,
const double* restrict X,
const double* restrict R,
const int32_t lmax,
int64_t* n,
int32_t* restrict const L,
const int64_t ldl,
double* restrict const VGL,
const int64_t ldv )
{
return qmckl_ao_polynomial_transp_vgl_hpc_inline (context,
X, R, lmax, n, L, ldl, VGL, ldv );
}
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#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("CRetType"),fname="qmckl_ao_polynomial_transp_vgl_doc")
#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
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integer(c_int32_t) function qmckl_ao_polynomial_transp_vgl_doc &
(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
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real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
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integer(c_int32_t), external :: qmckl_ao_polynomial_transp_vgl_doc_f
info = qmckl_ao_polynomial_transp_vgl_doc_f &
(context, X, R, lmax, n, L, ldl, VGL, ldv)
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end function qmckl_ao_polynomial_transp_vgl_doc
#+end_src
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#+CALL: generate_f_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("FRetType"),fname="qmckl_ao_polynomial_transp_vgl_doc")
#+RESULTS:
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_ao_polynomial_transp_vgl_doc &
(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
end function qmckl_ao_polynomial_transp_vgl_doc
end interface
#+end_src
#+CALL: generate_f_interface(table=qmckl_ao_polynomial_vgl_args,rettyp=get_value("FRetType"),fname="qmckl_ao_polynomial_transp_vgl")
#+RESULTS:
#+begin_src f90 :tangle (eval fh_func) :comments org :exports none
interface
integer(c_int32_t) function qmckl_ao_polynomial_transp_vgl &
(context, X, R, lmax, n, L, ldl, VGL, ldv) &
bind(C)
use, intrinsic :: iso_c_binding
import
implicit none
integer (c_int64_t) , intent(in) , value :: context
real (c_double ) , intent(in) :: X(3)
real (c_double ) , intent(in) :: R(3)
integer (c_int32_t) , intent(in) , value :: lmax
integer (c_int64_t) , intent(inout) :: n
integer (c_int32_t) , intent(out) :: L(ldl,n)
integer (c_int64_t) , intent(in) , value :: ldl
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real (c_double ) , intent(out) :: VGL(ldv,n)
integer (c_int64_t) , intent(in) , value :: ldv
end function qmckl_ao_polynomial_transp_vgl
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end interface
#+end_src
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*** Test :noexport:
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#+begin_src f90 :tangle (eval f_test)
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integer(c_int32_t) function test_qmckl_ao_polynomial_vgl(context) bind(C)
use qmckl
implicit none
integer(c_int64_t), intent(in), value :: context
integer :: lmax, d, i
integer, allocatable :: L(:,:)
integer*8 :: n, ldl, ldv, j
double precision :: X(3), R(3), Y(3)
double precision, allocatable :: VGL(:,:)
double precision :: w
double precision :: epsilon
epsilon = qmckl_get_numprec_epsilon(context)
X = (/ 1.1 , 2.2 , 3.3 /)
R = (/ 0.1 , 1.2 , -2.3 /)
Y(:) = X(:) - R(:)
lmax = 4;
ldl = 3;
ldv = 100;
d = (lmax+1)*(lmax+2)*(lmax+3)/6
allocate (L(ldl,d), VGL(ldv,d))
test_qmckl_ao_polynomial_vgl = &
qmckl_ao_polynomial_vgl(context, X, R, lmax, n, L, ldl, VGL, ldv)
if (test_qmckl_ao_polynomial_vgl /= QMCKL_SUCCESS) return
if (n /= d) return
do j=1,n
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
do i=1,3
if (L(i,j) < 0) return
end do
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
if (dabs(1.d0 - VGL(1,j) / (&
Y(1)**L(1,j) * Y(2)**L(2,j) * Y(3)**L(3,j) &
)) > epsilon ) return
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
if (L(1,j) < 1) then
if (VGL(2,j) /= 0.d0) return
else
if (dabs(1.d0 - VGL(2,j) / (&
L(1,j) * Y(1)**(L(1,j)-1) * Y(2)**L(2,j) * Y(3)**L(3,j) &
)) > epsilon ) return
end if
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
if (L(2,j) < 1) then
if (VGL(3,j) /= 0.d0) return
else
if (dabs(1.d0 - VGL(3,j) / (&
L(2,j) * Y(1)**L(1,j) * Y(2)**(L(2,j)-1) * Y(3)**L(3,j) &
)) > epsilon ) return
end if
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
if (L(3,j) < 1) then
if (VGL(4,j) /= 0.d0) return
else
if (dabs(1.d0 - VGL(4,j) / (&
L(3,j) * Y(1)**L(1,j) * Y(2)**L(2,j) * Y(3)**(L(3,j)-1) &
)) > epsilon ) return
end if
test_qmckl_ao_polynomial_vgl = QMCKL_FAILURE
w = 0.d0
if (L(1,j) > 1) then
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w = w + L(1,j) * (L(1,j)-1) * Y(1)**(L(1,j)-2) * Y(2)**L(2,j) * Y(3)**L(3,j)
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end if
if (L(2,j) > 1) then
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w = w + L(2,j) * (L(2,j)-1) * Y(1)**L(1,j) * Y(2)**(L(2,j)-2) * Y(3)**L(3,j)
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end if
if (L(3,j) > 1) then
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w = w + L(3,j) * (L(3,j)-1) * Y(1)**L(1,j) * Y(2)**L(2,j) * Y(3)**(L(3,j)-2)
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end if
if (dabs(1.d0 - VGL(5,j) / w) > epsilon ) return
end do
test_qmckl_ao_polynomial_vgl = QMCKL_SUCCESS
deallocate(L,VGL)
end function test_qmckl_ao_polynomial_vgl
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#+end_src
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#+begin_src c :tangle (eval c_test)
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int test_qmckl_ao_polynomial_vgl(qmckl_context context);
assert(0 == test_qmckl_ao_polynomial_vgl(context));
double X[3] = { 1.1, 2.2, 3.3 };
double R[3] = { 0.2, 1.1, 3.0 };
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int32_t ldv[8] = {1, 4, 10, 20, 35, 56, 84, 120};
for (int32_t ldl=3 ; ldl<=5 ; ++ldl) {
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int64_t n;
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int32_t L0[200][ldl];
int32_t L1[200][ldl];
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printf("ldl=%d\n", ldl);
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for (int32_t lmax=0 ; lmax<=7 ; lmax++) {
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double VGL0[5][ldv[lmax]];
double VGL1[5][ldv[lmax]];
memset(&L0[0][0], 0, sizeof(L0));
memset(&L1[0][0], 0, sizeof(L1));
memset(&VGL0[0][0], 0, sizeof(VGL0));
memset(&VGL1[0][0], 0, sizeof(VGL1));
rc = qmckl_ao_polynomial_transp_vgl_doc (context, X, R, lmax, &n, &(L0[0][0]), ldl, &(VGL0[0][0]), ldv[lmax]);
assert (rc == QMCKL_SUCCESS);
rc = qmckl_ao_polynomial_transp_vgl_hpc (context, X, R, lmax, &n, &(L1[0][0]), ldl, &(VGL1[0][0]), ldv[lmax]);
assert (rc == QMCKL_SUCCESS);
printf("lmax=%d\n", lmax);
for (int32_t l=0 ; l<n ; ++l) {
for (int32_t k=0 ; k<3 ; ++k) {
printf("L[%d][%d] = %d %d\n", l, k, L0[l][k], L1[l][k]);
assert( L0[l][k] == L1[l][k] );
}
}
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for (int32_t k=0 ; k<5 ; ++k) {
for (int32_t l=0 ; l<n ; ++l) {
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printf("VGL[%d][%d] = %e %e %e\n", k, l, VGL0[k][l], VGL1[k][l], VGL0[k][l]-VGL1[k][l]);
assert( fabs(1.-(VGL0[k][l]+1.e-100)/(VGL1[k][l]+1.e-100)) < 1.e-15 );
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}
}
}
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}
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#+end_src
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* Combining radial and polynomial parts
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** Values only
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:PROPERTIES:
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:Name: qmckl_compute_ao_value
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:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
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*** Unoptimized version
#+NAME: qmckl_ao_value_args_doc
| Variable | Type | In/Out | Description |
|-----------------------+-----------------------------------+--------+----------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~ao_num~ | ~int64_t~ | in | Number of AOs |
| ~shell_num~ | ~int64_t~ | in | Number of shells |
| ~point_num~ | ~int64_t~ | in | Number of points |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st shell of each nucleus |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | in | Number of shells per nucleus |
| ~nucleus_range~ | ~double[nucl_num]~ | in | Range beyond which all is zero |
| ~nucleus_max_ang_mom~ | ~int32_t[nucl_num]~ | in | Maximum angular momentum per nucleus |
| ~shell_ang_mom~ | ~int32_t[shell_num]~ | in | Angular momentum of each shell |
| ~ao_factor~ | ~double[ao_num]~ | in | Normalization factor of the AOs |
| ~shell_vgl~ | ~double[point_num][5][shell_num]~ | in | Value, gradients and Laplacian of the shells |
| ~ao_value~ | ~double[point_num][ao_num]~ | out | Values of the AOs |
#+begin_src f90 :comments org :tangle (eval f) :noweb yes
integer function qmckl_compute_ao_value_doc_f(context, &
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ao_num, shell_num, point_num, nucl_num, &
coord, nucl_coord, nucleus_index, nucleus_shell_num, &
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nucleus_range, nucleus_max_ang_mom, shell_ang_mom, &
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ao_factor, shell_vgl, ao_value) &
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result(info)
use qmckl
implicit none
integer(qmckl_context), intent(in) :: context
integer*8 , intent(in) :: ao_num
integer*8 , intent(in) :: shell_num
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integer*8 , intent(in) :: point_num
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integer*8 , intent(in) :: nucl_num
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double precision , intent(in) :: coord(point_num,3)
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double precision , intent(in) :: nucl_coord(nucl_num,3)
integer*8 , intent(in) :: nucleus_index(nucl_num)
integer*8 , intent(in) :: nucleus_shell_num(nucl_num)
double precision , intent(in) :: nucleus_range(nucl_num)
integer , intent(in) :: nucleus_max_ang_mom(nucl_num)
integer , intent(in) :: shell_ang_mom(shell_num)
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double precision , intent(in) :: ao_factor(ao_num)
double precision , intent(in) :: shell_vgl(shell_num,5,point_num)
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double precision , intent(out) :: ao_value(ao_num,point_num)
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double precision :: e_coord(3), n_coord(3)
integer*8 :: n_poly
integer :: l, il, k
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integer*8 :: ipoint, inucl, ishell
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integer*8 :: ishell_start, ishell_end
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integer :: lstart(0:20)
double precision :: x, y, z, r2
double precision :: cutoff
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integer, external :: qmckl_ao_polynomial_vgl_doc_f
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double precision, allocatable :: poly_vgl(:,:)
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integer , allocatable :: powers(:,:), ao_index(:)
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allocate(poly_vgl(5,ao_num), powers(3,ao_num), ao_index(ao_num))
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! Pre-computed data
do l=0,20
lstart(l) = l*(l+1)*(l+2)/6 +1
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end do
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k=1
do inucl=1,nucl_num
ishell_start = nucleus_index(inucl) + 1
ishell_end = nucleus_index(inucl) + nucleus_shell_num(inucl)
do ishell = ishell_start, ishell_end
l = shell_ang_mom(ishell)
ao_index(ishell) = k
k = k + lstart(l+1) - lstart(l)
end do
end do
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info = QMCKL_SUCCESS
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! Don't compute polynomials when the radial part is zero.
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cutoff = 27.631021115928547 !-dlog(1.d-12)
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do ipoint = 1, point_num
e_coord(1) = coord(ipoint,1)
e_coord(2) = coord(ipoint,2)
e_coord(3) = coord(ipoint,3)
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do inucl=1,nucl_num
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n_coord(1) = nucl_coord(inucl,1)
n_coord(2) = nucl_coord(inucl,2)
n_coord(3) = nucl_coord(inucl,3)
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! Test if the point is in the range of the nucleus
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x = e_coord(1) - n_coord(1)
y = e_coord(2) - n_coord(2)
z = e_coord(3) - n_coord(3)
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r2 = x*x + y*y + z*z
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if (r2 > cutoff*nucleus_range(inucl)) then
cycle
end if
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! Compute polynomials
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info = qmckl_ao_polynomial_vgl_doc_f(context, e_coord, n_coord, &
nucleus_max_ang_mom(inucl), n_poly, powers, 3_8, &
poly_vgl, 5_8)
! Loop over shells
ishell_start = nucleus_index(inucl) + 1
ishell_end = nucleus_index(inucl) + nucleus_shell_num(inucl)
do ishell = ishell_start, ishell_end
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k = ao_index(ishell)
l = shell_ang_mom(ishell)
do il = lstart(l), lstart(l+1)-1
! Value
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ao_value(k,ipoint) = &
poly_vgl(1,il) * shell_vgl(ishell,1,ipoint) * ao_factor(k)
k = k+1
end do
end do
end do
end do
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deallocate(poly_vgl, powers)
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end function qmckl_compute_ao_value_doc_f
#+end_src
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*** HPC version
#+NAME: qmckl_ao_value_args_hpc_gaussian
| Variable | Type | In/Out | Description |
|-----------------------+-----------------------------+--------+----------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~ao_num~ | ~int64_t~ | in | Number of AOs |
| ~shell_num~ | ~int64_t~ | in | Number of shells |
| ~prim_num~ | ~int64_t~ | in | Number of primitives |
| ~point_num~ | ~int64_t~ | in | Number of points |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st shell of each nucleus |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | in | Number of shells per nucleus |
| ~nucleus_range~ | ~double[nucl_num]~ | in | Range beyond which all is zero |
| ~nucleus_max_ang_mom~ | ~int32_t[nucl_num]~ | in | Maximum angular momentum per nucleus |
| ~shell_ang_mom~ | ~int32_t[shell_num]~ | in | Angular momentum of each shell |
| ~shell_prim_index~ | ~int64_t[shell_num]~ | in | Index of the 1st primitive of each shell |
| ~shell_prim_num~ | ~int64_t[shell_num]~ | in | Number of primitives per shell |
| ~ao_factor~ | ~double[ao_num]~ | in | Normalization factor of the AOs |
| ~ao_expo~ | ~double[prim_num]~ | in | Value, gradients and Laplacian of the shells |
| ~coef_normalized~ | ~double[prim_num]~ | in | Value, gradients and Laplacian of the shells |
| ~ao_value~ | ~double[point_num][ao_num]~ | out | Values of the AOs |
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#+NAME:ao_value_constants
#+begin_src c :exports none
int32_t lstart[32] __attribute__((aligned(64)));
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for (int32_t l=0 ; l<32 ; ++l) {
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lstart[l] = l*(l+1)*(l+2)/6;
}
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int64_t ao_index[shell_num+1] __attribute__((aligned(64)));
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int64_t size_max = 0;
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int64_t prim_max = 0;
int64_t shell_max = 0;
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{
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int64_t k=0;
for (int inucl=0 ; inucl < nucl_num ; ++inucl) {
prim_max = prim_num_per_nucleus[inucl] > prim_max ?
prim_num_per_nucleus[inucl] : prim_max;
shell_max = nucleus_shell_num[inucl] > shell_max ?
nucleus_shell_num[inucl] : shell_max;
const int64_t ishell_start = nucleus_index[inucl];
const int64_t ishell_end = nucleus_index[inucl] + nucleus_shell_num[inucl];
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
const int l = shell_ang_mom[ishell];
ao_index[ishell] = k;
k += lstart[l+1] - lstart[l];
size_max = size_max < lstart[l+1] ? lstart[l+1] : size_max;
}
}
ao_index[shell_num] = ao_num+1;
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}
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/* Don't compute polynomials when the radial part is zero. */
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double cutoff = 27.631021115928547; // -log(1.e-12)
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#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
#ifdef HAVE_HPC
qmckl_exit_code
qmckl_compute_ao_value_hpc_gaussian (const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
const int32_t* restrict prim_num_per_nucleus,
const int64_t point_num,
const int64_t nucl_num,
const double* restrict coord,
const double* restrict nucl_coord,
const int64_t* restrict nucleus_index,
const int64_t* restrict nucleus_shell_num,
const double* nucleus_range,
const int32_t* restrict nucleus_max_ang_mom,
const int32_t* restrict shell_ang_mom,
const double* restrict ao_factor,
const qmckl_matrix expo_per_nucleus,
const qmckl_tensor coef_per_nucleus,
double* restrict const ao_value )
{
<<ao_value_constants>>
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#ifdef HAVE_OPENMP
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#pragma omp parallel if (point_num > 16)
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#endif
{
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qmckl_exit_code rc;
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double ar2[prim_max] __attribute__((aligned(64)));
int32_t powers[3*size_max] __attribute__((aligned(64)));
double poly_vgl[5*size_max] __attribute__((aligned(64)));
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double exp_mat[prim_max] __attribute__((aligned(64)));
double ce_mat[shell_max] __attribute__((aligned(64)));
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int32_t coef_mat_sparse_idx[nucl_num][shell_max][prim_max+1] __attribute__((aligned(64)));
double coef_mat_sparse [nucl_num][shell_max][prim_max+1] __attribute__((aligned(64)));
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for (int i=0 ; i<nucl_num ; ++i) {
for (int j=0 ; j<shell_max; ++j) {
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int l=1;
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for (int k=0 ; k<prim_max; ++k) {
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const double c = qmckl_ten3(coef_per_nucleus,k, j, i);
if (c != 0.) {
coef_mat_sparse_idx[i][j][l] = k;
coef_mat_sparse[i][j][l] = c;
l+=1;
}
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}
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coef_mat_sparse_idx[i][j][0] = l;
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}
}
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#ifdef HAVE_OPENMP
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#pragma omp for
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#endif
for (int64_t ipoint=0 ; ipoint < point_num ; ++ipoint) {
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const double e_coord[3] __attribute__((aligned(64))) =
{ coord[ipoint],
coord[ipoint + point_num],
coord[ipoint + 2*point_num] };
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for (int64_t inucl=0 ; inucl < nucl_num ; ++inucl) {
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const double n_coord[3] __attribute__((aligned(64))) =
{ nucl_coord[inucl],
nucl_coord[inucl + nucl_num],
nucl_coord[inucl + 2*nucl_num] };
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/* Test if the point is in the range of the nucleus */
const double x = e_coord[0] - n_coord[0];
const double y = e_coord[1] - n_coord[1];
const double z = e_coord[2] - n_coord[2];
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const double r2 = x*x + y*y + z*z;
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if (r2 > cutoff * nucleus_range[inucl]) {
continue;
}
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int64_t n_poly;
switch (nucleus_max_ang_mom[inucl]) {
case 0:
break;
case 1:
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poly_vgl[0] = 1.;
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poly_vgl[1] = x;
poly_vgl[2] = y;
poly_vgl[3] = z;
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break;
case 2:
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poly_vgl[0] = 1.;
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poly_vgl[1] = x;
poly_vgl[2] = y;
poly_vgl[3] = z;
poly_vgl[4] = x*x;
poly_vgl[5] = x*y;
poly_vgl[6] = x*z;
poly_vgl[7] = y*y;
poly_vgl[8] = y*z;
poly_vgl[9] = z*z;
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break;
default:
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rc = qmckl_ao_polynomial_transp_vgl_hpc_inline(context, e_coord, n_coord,
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nucleus_max_ang_mom[inucl],
&n_poly, powers, (int64_t) 3,
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poly_vgl, size_max);
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assert (rc == QMCKL_SUCCESS);
break;
}
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/* Compute all exponents */
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int64_t nidx = 0;
for (int64_t iprim = 0 ; iprim < prim_num_per_nucleus[inucl] ; ++iprim) {
const double v = qmckl_mat(expo_per_nucleus, iprim, inucl) * r2;
if (v <= cutoff) {
ar2[iprim] = v;
++nidx;
} else {
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break;
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}
}
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for (int64_t iprim = 0 ; iprim < nidx ; ++iprim) {
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exp_mat[iprim] = exp(-ar2[iprim]);
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}
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for (int i=0 ; i<nucleus_shell_num[inucl] ; ++i) {
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ce_mat[i] = 0.;
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const int32_t* restrict idx = &(coef_mat_sparse_idx[inucl][i][0]);
const double* restrict v = &(coef_mat_sparse[inucl][i][0]);
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for (int l=1 ; l<coef_mat_sparse_idx[inucl][i][0]; ++l) {
const int k = idx[l];
if (k >= nidx) break;
ce_mat[i] += v[l] * exp_mat[k];
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}
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}
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const int64_t ishell_start = nucleus_index[inucl];
const int64_t ishell_end = nucleus_index[inucl] + nucleus_shell_num[inucl];
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
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const double s1 = ce_mat[ishell-ishell_start];
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const int64_t k = ao_index[ishell];
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double* restrict const ao_value_1 = ao_value + ipoint*ao_num + k;
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const int32_t l = shell_ang_mom[ishell];
const int32_t n = lstart[l+1]-lstart[l];
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if (s1 == 0.0) {
for (int64_t il=0 ; il<n ; ++il) {
ao_value_1[il] = 0.;
}
continue;
}
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double* restrict poly_vgl_1 = NULL;
if (nidx > 0) {
const double* restrict f = ao_factor + k;
const int64_t idx = lstart[l];
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poly_vgl_1 = &(poly_vgl[idx]);
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switch (n) {
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case 1:
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ao_value_1[0] = s1 * f[0];
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break;
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case 3:
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#ifdef HAVE_OPENMP
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#pragma omp simd
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#endif
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for (int il=0 ; il<3 ; ++il) {
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ao_value_1[il] = poly_vgl_1[il] * s1 * f[il];
}
break;
case(6):
#ifdef HAVE_OPENMP
#pragma omp simd
#endif
for (int il=0 ; il<6 ; ++il) {
ao_value_1[il] = poly_vgl_1[il] * s1 * f[il];
}
break;
default:
#ifdef HAVE_OPENMP
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#pragma omp simd
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#endif
for (int il=0 ; il<n ; ++il) {
ao_value_1[il] = poly_vgl_1[il] * s1 * f[il];
}
break;
}
} else {
for (int64_t il=0 ; il<n ; ++il) {
ao_value_1[il] = 0.0;
}
}
}
}
}
}
return QMCKL_SUCCESS;
}
#endif
#+end_src
*** Interfaces
# #+CALL: generate_c_header(table=qmckl_ao_value_args_doc,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_value"))
# (Commented because the header needs to go into h_private_func)
#+begin_src c :tangle (eval h_private_func) :comments org
qmckl_exit_code qmckl_compute_ao_value_doc (
const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
const int64_t point_num,
const int64_t nucl_num,
const double* coord,
const double* nucl_coord,
const int64_t* nucleus_index,
const int64_t* nucleus_shell_num,
const double* nucleus_range,
const int32_t* nucleus_max_ang_mom,
const int32_t* shell_ang_mom,
const double* ao_factor,
const double* shell_vgl,
double* const ao_value );
#+end_src
#+begin_src c :tangle (eval h_private_func) :comments org
#ifdef HAVE_HPC
qmckl_exit_code qmckl_compute_ao_value_hpc_gaussian (
const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
const int32_t* prim_num_per_nucleus,
const int64_t point_num,
const int64_t nucl_num,
const double* coord,
const double* nucl_coord,
const int64_t* nucleus_index,
const int64_t* nucleus_shell_num,
const double* nucleus_range,
const int32_t* nucleus_max_ang_mom,
const int32_t* shell_ang_mom,
const double* ao_factor,
const qmckl_matrix expo_per_nucleus,
const qmckl_tensor coef_per_nucleus,
double* const ao_value );
#endif
#+end_src
#+CALL: generate_c_interface(table=qmckl_ao_value_args_doc,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_value_doc"))
#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
integer(c_int32_t) function qmckl_compute_ao_value_doc &
(context, &
ao_num, &
shell_num, &
point_num, &
nucl_num, &
coord, &
nucl_coord, &
nucleus_index, &
nucleus_shell_num, &
nucleus_range, &
nucleus_max_ang_mom, &
shell_ang_mom, &
ao_factor, &
shell_vgl, &
ao_value) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: ao_num
integer (c_int64_t) , intent(in) , value :: shell_num
integer (c_int64_t) , intent(in) , value :: point_num
integer (c_int64_t) , intent(in) , value :: nucl_num
real (c_double ) , intent(in) :: coord(point_num,3)
real (c_double ) , intent(in) :: nucl_coord(nucl_num,3)
integer (c_int64_t) , intent(in) :: nucleus_index(nucl_num)
integer (c_int64_t) , intent(in) :: nucleus_shell_num(nucl_num)
real (c_double ) , intent(in) :: nucleus_range(nucl_num)
integer (c_int32_t) , intent(in) :: nucleus_max_ang_mom(nucl_num)
integer (c_int32_t) , intent(in) :: shell_ang_mom(shell_num)
real (c_double ) , intent(in) :: ao_factor(ao_num)
real (c_double ) , intent(in) :: shell_vgl(shell_num,5,point_num)
real (c_double ) , intent(out) :: ao_value(ao_num,point_num)
integer(c_int32_t), external :: qmckl_compute_ao_value_doc_f
info = qmckl_compute_ao_value_doc_f &
(context, &
ao_num, &
shell_num, &
point_num, &
nucl_num, &
coord, &
nucl_coord, &
nucleus_index, &
nucleus_shell_num, &
nucleus_range, &
nucleus_max_ang_mom, &
shell_ang_mom, &
ao_factor, &
shell_vgl, &
ao_value)
end function qmckl_compute_ao_value_doc
#+end_src
**** Provide :noexport:
#+CALL: write_provider_header( group="ao_basis", data="ao_value" )
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#+RESULTS:
#+begin_src c :comments org :tangle (eval h_private_func) :noweb yes :export none
qmckl_exit_code qmckl_provide_ao_basis_ao_value(qmckl_context context);
#+end_src
#+CALL: write_provider_pre( group="ao_basis", data="ao_value", dimension="ctx->ao_basis.ao_num * ctx->point.num")
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
qmckl_exit_code qmckl_provide_ao_basis_ao_value(qmckl_context context)
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{
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qmckl_exit_code rc = QMCKL_SUCCESS;
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
"qmckl_provide_ao_basis_ao_value",
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NULL);
}
qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
assert (ctx != NULL);
if (!ctx->ao_basis.provided) {
return qmckl_failwith( context,
QMCKL_NOT_PROVIDED,
"qmckl_provide_ao_basis_ao_value",
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NULL);
}
/* Compute if necessary */
if (ctx->point.date > ctx->ao_basis.ao_value_date) {
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->ao_basis.ao_num * ctx->point.num * sizeof(double);
if (ctx->ao_basis.ao_value != NULL) {
qmckl_memory_info_struct mem_info_test = qmckl_memory_info_struct_zero;
rc = qmckl_get_malloc_info(context, ctx->ao_basis.ao_value, &mem_info_test);
/* if rc != QMCKL_SUCCESS, we are maybe in an _inplace function because the
memory was not allocated with qmckl_malloc */
if ((rc == QMCKL_SUCCESS) && (mem_info_test.size != mem_info.size)) {
rc = qmckl_free(context, ctx->ao_basis.ao_value);
assert (rc == QMCKL_SUCCESS);
ctx->ao_basis.ao_value = NULL;
}
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}
/* Allocate array */
if (ctx->ao_basis.ao_value == NULL) {
double* ao_value = (double*) qmckl_malloc(context, mem_info);
if (ao_value == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"qmckl_ao_basis_ao_value",
NULL);
}
ctx->ao_basis.ao_value = ao_value;
}
#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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if (ctx->ao_basis.ao_vgl_date == ctx->point.date) {
// ao_vgl has been computed at this step: Just copy the data.
double * v = &(ctx->ao_basis.ao_value[0]);
double * vgl = &(ctx->ao_basis.ao_vgl[0]);
for (int i=0 ; i<ctx->point.num ; ++i) {
for (int k=0 ; k<ctx->ao_basis.ao_num ; ++k) {
v[k] = vgl[k];
}
v += ctx->ao_basis.ao_num;
vgl += ctx->ao_basis.ao_num * 5;
}
} else {
#ifdef HAVE_HPC
if (ctx->ao_basis.type == 'G') {
rc = qmckl_compute_ao_value_hpc_gaussian(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->ao_basis.prim_num_per_nucleus,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.expo_per_nucleus,
ctx->ao_basis.coef_per_nucleus,
ctx->ao_basis.ao_value);
/*
} else if (ctx->ao_basis.type == 'S') {
rc = qmck_compute_ao_value_hpc_slater(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->ao_basis.prim_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.shell_prim_index,
ctx->ao_basis.shell_prim_num,
ctx->ao_basis.ao_factor,
ctx->ao_basis.exponent,
ctx->ao_basis.coefficient_normalized,
ctx->ao_basis.ao_value);
,*/
} else {
/* Provide required data */
rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc, "qmckl_provide_ao_basis_shell_vgl", NULL);
}
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rc = qmckl_compute_ao_value_doc(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.shell_vgl,
ctx->ao_basis.ao_value);
}
#else
/* Provide required data */
rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc, "qmckl_provide_ao_basis_shell_vgl", NULL);
}
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rc = qmckl_compute_ao_value_doc(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.shell_vgl,
ctx->ao_basis.ao_value);
#endif
}
#+end_src
#+CALL: write_provider_post( group="ao_basis", data="ao_value" )
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#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
if (rc != QMCKL_SUCCESS) {
return rc;
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}
ctx->ao_basis.ao_value_date = ctx->date;
}
return QMCKL_SUCCESS;
}
#+end_src
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**** Test :noexport:
#+begin_src python :results output :exports none
import numpy as np
from math import sqrt
h0 = 1.e-4
def f(a,x,y):
return np.sum( [c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] )
elec_26_w1 = np.array( [ 1.49050402641, 2.90106987953, -1.05920815468 ] )
elec_15_w2 = np.array( [ -2.20180344582,-1.9113150239, 2.2193744778600002 ] )
nucl_1 = np.array( [ -2.302574592081335e+00, -3.542027060505035e-01, -5.334129934317614e-02] )
#double ao_value[prim_num][5][elec_num];
x = elec_26_w1 ; y = nucl_1
a = [( 4.0382999999999998e+02, 1.4732000000000000e-03 * 5.9876577632594533e+04),
( 1.2117000000000000e+02, 1.2672500000000000e-02 * 7.2836806319891484e+03),
( 4.6344999999999999e+01, 5.8045100000000002e-02 * 1.3549226646722386e+03),
( 1.9721000000000000e+01, 1.7051030000000000e-01 * 3.0376315094739988e+02),
( 8.8623999999999992e+00, 3.1859579999999998e-01 * 7.4924579607137730e+01),
( 3.9962000000000000e+00, 3.8450230000000002e-01 * 1.8590543353806009e+01),
( 1.7636000000000001e+00, 2.7377370000000001e-01 * 4.4423176930919421e+00),
( 7.0618999999999998e-01, 7.4396699999999996e-02 * 8.9541051939952665e-01)]
norm = sqrt(3.)
# x^2 * g(r)
print ( "[26][0][219] : %25.15e"%(fx(a,x,y)) )
print ( "[26][1][219] : %25.15e"%(df(a,x,y,1)) )
print ( "[26][2][219] : %25.15e"%(df(a,x,y,2)) )
print ( "[26][3][219] : %25.15e"%(df(a,x,y,3)) )
print ( "[26][4][219] : %25.15e"%(lf(a,x,y)) )
print ( "[26][0][220] : %25.15e"%(norm*f(a,x,y) * (x[0] - y[0]) * (x[1] - y[1]) ))
print ( "[26][1][220] : %25.15e"%(norm*df(a,x,y,1)* (x[0] - y[0]) * (x[1] - y[1]) + norm*f(a,x,y) * (x[1] - y[1])) )
print ( "[26][0][221] : %25.15e"%(norm*f(a,x,y) * (x[0] - y[0]) * (x[2] - y[2])) )
print ( "[26][1][221] : %25.15e"%(norm*df(a,x,y,1)* (x[0] - y[0]) * (x[2] - y[2]) + norm*f(a,x,y) * (x[2] - y[2])) )
print ( "[26][0][222] : %25.15e"%(f(a,x,y) * (x[1] - y[1]) * (x[1] - y[1])) )
print ( "[26][1][222] : %25.15e"%(df(a,x,y,1)* (x[1] - y[1]) * (x[1] - y[1])) )
print ( "[26][0][223] : %25.15e"%(norm*f(a,x,y) * (x[1] - y[1]) * (x[2] - y[2])) )
print ( "[26][1][223] : %25.15e"%(norm*df(a,x,y,1)* (x[1] - y[1]) * (x[2] - y[2])) )
print ( "[26][0][224] : %25.15e"%(f(a,x,y) * (x[2] - y[2]) * (x[2] - y[2])) )
print ( "[26][1][224] : %25.15e"%(df(a,x,y,1)* (x[2] - y[2]) * (x[2] - y[2])) )
#+end_src
#+RESULTS:
#+begin_src c :tangle (eval c_test) :exports none
{
#define shell_num chbrclf_shell_num
#define ao_num chbrclf_ao_num
double* elec_coord = &(chbrclf_elec_coord[0][0][0]);
assert(qmckl_electron_provided(context));
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const int64_t point_num = elec_num;
rc = qmckl_set_point(context, 'N', point_num, elec_coord, point_num*3);
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assert(rc == QMCKL_SUCCESS);
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double ao_value[point_num][ao_num];
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rc = qmckl_get_ao_basis_ao_value(context, &(ao_value[0][0]),
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(int64_t) point_num*ao_num);
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assert (rc == QMCKL_SUCCESS);
printf("\n");
printf(" ao_value ao_value[26][219] %25.15e\n", ao_value[26][219]);
printf(" ao_value ao_value[26][220] %25.15e\n", ao_value[26][220]);
printf(" ao_value ao_value[26][221] %25.15e\n", ao_value[26][221]);
printf(" ao_value ao_value[26][222] %25.15e\n", ao_value[26][222]);
printf(" ao_value ao_value[26][223] %25.15e\n", ao_value[26][223]);
printf(" ao_value ao_value[26][224] %25.15e\n", ao_value[26][224]);
printf("\n");
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printf("%e %e\n", ao_value[26][219], 1.020298798341620e-08);
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assert( fabs(ao_value[26][219] - ( 1.020298798341620e-08)) < 1.e-14 );
assert( fabs(ao_value[26][220] - ( 1.516643537739178e-08)) < 1.e-14 );
assert( fabs(ao_value[26][221] - ( -4.686370882518819e-09)) < 1.e-14 );
assert( fabs(ao_value[26][222] - ( 7.514816980753531e-09)) < 1.e-14 );
assert( fabs(ao_value[26][223] - ( -4.021908374204471e-09)) < 1.e-14 );
assert( fabs(ao_value[26][224] - ( 7.175045873560788e-10)) < 1.e-14 );
}
#+end_src
** Value, gradients, Laplacian
:PROPERTIES:
:Name: qmckl_compute_ao_vgl
:CRetType: qmckl_exit_code
:FRetType: qmckl_exit_code
:END:
*** Unoptimized version
#+NAME: qmckl_ao_vgl_args_doc
| Variable | Type | In/Out | Description |
|-----------------------+-----------------------------------+--------+----------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~ao_num~ | ~int64_t~ | in | Number of AOs |
| ~shell_num~ | ~int64_t~ | in | Number of shells |
| ~point_num~ | ~int64_t~ | in | Number of points |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st shell of each nucleus |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | in | Number of shells per nucleus |
| ~nucleus_range~ | ~double[nucl_num]~ | in | Range beyond which all is zero |
| ~nucleus_max_ang_mom~ | ~int32_t[nucl_num]~ | in | Maximum angular momentum per nucleus |
| ~shell_ang_mom~ | ~int32_t[shell_num]~ | in | Angular momentum of each shell |
| ~ao_factor~ | ~double[ao_num]~ | in | Normalization factor of the AOs |
| ~shell_vgl~ | ~double[point_num][5][shell_num]~ | in | Value, gradients and Laplacian of the shells |
| ~ao_vgl~ | ~double[point_num][5][ao_num]~ | out | Value, gradients and Laplacian of the AOs |
#+begin_src f90 :comments org :tangle (eval f) :noweb yes
integer function qmckl_compute_ao_vgl_doc_f(context, &
ao_num, shell_num, point_num, nucl_num, &
coord, nucl_coord, nucleus_index, nucleus_shell_num, &
nucleus_range, nucleus_max_ang_mom, shell_ang_mom, &
ao_factor, shell_vgl, ao_vgl) &
result(info)
use qmckl
implicit none
integer(qmckl_context), intent(in) :: context
integer*8 , intent(in) :: ao_num
integer*8 , intent(in) :: shell_num
integer*8 , intent(in) :: point_num
integer*8 , intent(in) :: nucl_num
double precision , intent(in) :: coord(point_num,3)
double precision , intent(in) :: nucl_coord(nucl_num,3)
integer*8 , intent(in) :: nucleus_index(nucl_num)
integer*8 , intent(in) :: nucleus_shell_num(nucl_num)
double precision , intent(in) :: nucleus_range(nucl_num)
integer , intent(in) :: nucleus_max_ang_mom(nucl_num)
integer , intent(in) :: shell_ang_mom(shell_num)
double precision , intent(in) :: ao_factor(ao_num)
double precision , intent(in) :: shell_vgl(shell_num,5,point_num)
double precision , intent(out) :: ao_vgl(ao_num,5,point_num)
double precision :: e_coord(3), n_coord(3)
integer*8 :: n_poly
integer :: l, il, k
integer*8 :: ipoint, inucl, ishell
integer*8 :: ishell_start, ishell_end
integer :: lstart(0:20)
double precision :: x, y, z, r2
double precision :: cutoff
integer, external :: qmckl_ao_polynomial_vgl_doc_f
double precision, allocatable :: poly_vgl(:,:)
integer , allocatable :: powers(:,:), ao_index(:)
allocate(poly_vgl(5,ao_num), powers(3,ao_num), ao_index(ao_num))
! Pre-computed data
do l=0,20
lstart(l) = l*(l+1)*(l+2)/6 +1
end do
k=1
do inucl=1,nucl_num
ishell_start = nucleus_index(inucl) + 1
ishell_end = nucleus_index(inucl) + nucleus_shell_num(inucl)
do ishell = ishell_start, ishell_end
l = shell_ang_mom(ishell)
ao_index(ishell) = k
k = k + lstart(l+1) - lstart(l)
end do
end do
info = QMCKL_SUCCESS
! Don't compute polynomials when the radial part is zero.
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cutoff = 27.631021115928547 ! -dlog(1.d-12)
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do ipoint = 1, point_num
e_coord(1) = coord(ipoint,1)
e_coord(2) = coord(ipoint,2)
e_coord(3) = coord(ipoint,3)
do inucl=1,nucl_num
n_coord(1) = nucl_coord(inucl,1)
n_coord(2) = nucl_coord(inucl,2)
n_coord(3) = nucl_coord(inucl,3)
! Test if the point is in the range of the nucleus
x = e_coord(1) - n_coord(1)
y = e_coord(2) - n_coord(2)
z = e_coord(3) - n_coord(3)
r2 = x*x + y*y + z*z
if (r2 > cutoff*nucleus_range(inucl)) then
cycle
end if
! Compute polynomials
info = qmckl_ao_polynomial_vgl_doc_f(context, e_coord, n_coord, &
nucleus_max_ang_mom(inucl), n_poly, powers, 3_8, &
poly_vgl, 5_8)
! Loop over shells
ishell_start = nucleus_index(inucl) + 1
ishell_end = nucleus_index(inucl) + nucleus_shell_num(inucl)
do ishell = ishell_start, ishell_end
k = ao_index(ishell)
l = shell_ang_mom(ishell)
do il = lstart(l), lstart(l+1)-1
! Value
ao_vgl(k,1,ipoint) = &
poly_vgl(1,il) * shell_vgl(ishell,1,ipoint) * ao_factor(k)
! Grad_x
ao_vgl(k,2,ipoint) = ( &
poly_vgl(2,il) * shell_vgl(ishell,1,ipoint) + &
poly_vgl(1,il) * shell_vgl(ishell,2,ipoint) &
) * ao_factor(k)
! Grad_y
ao_vgl(k,3,ipoint) = ( &
poly_vgl(3,il) * shell_vgl(ishell,1,ipoint) + &
poly_vgl(1,il) * shell_vgl(ishell,3,ipoint) &
) * ao_factor(k)
! Grad_z
ao_vgl(k,4,ipoint) = ( &
poly_vgl(4,il) * shell_vgl(ishell,1,ipoint) + &
poly_vgl(1,il) * shell_vgl(ishell,4,ipoint) &
) * ao_factor(k)
! Lapl_z
ao_vgl(k,5,ipoint) = ( &
poly_vgl(5,il) * shell_vgl(ishell,1,ipoint) + &
poly_vgl(1,il) * shell_vgl(ishell,5,ipoint) + &
2.d0 * ( &
poly_vgl(2,il) * shell_vgl(ishell,2,ipoint) + &
poly_vgl(3,il) * shell_vgl(ishell,3,ipoint) + &
poly_vgl(4,il) * shell_vgl(ishell,4,ipoint) ) &
) * ao_factor(k)
k = k+1
end do
end do
end do
end do
deallocate(poly_vgl, powers)
end function qmckl_compute_ao_vgl_doc_f
#+end_src
*** HPC version
#+NAME: qmckl_ao_vgl_args_hpc_gaussian
| Variable | Type | In/Out | Description |
|-----------------------+--------------------------------+--------+----------------------------------------------|
| ~context~ | ~qmckl_context~ | in | Global state |
| ~ao_num~ | ~int64_t~ | in | Number of AOs |
| ~shell_num~ | ~int64_t~ | in | Number of shells |
| ~prim_num~ | ~int64_t~ | in | Number of primitives |
| ~point_num~ | ~int64_t~ | in | Number of points |
| ~nucl_num~ | ~int64_t~ | in | Number of nuclei |
| ~coord~ | ~double[3][point_num]~ | in | Coordinates |
| ~nucl_coord~ | ~double[3][nucl_num]~ | in | Nuclear coordinates |
| ~nucleus_index~ | ~int64_t[nucl_num]~ | in | Index of the 1st shell of each nucleus |
| ~nucleus_shell_num~ | ~int64_t[nucl_num]~ | in | Number of shells per nucleus |
| ~nucleus_range~ | ~double[nucl_num]~ | in | Range beyond which all is zero |
| ~nucleus_max_ang_mom~ | ~int32_t[nucl_num]~ | in | Maximum angular momentum per nucleus |
| ~shell_ang_mom~ | ~int32_t[shell_num]~ | in | Angular momentum of each shell |
| ~shell_prim_index~ | ~int64_t[shell_num]~ | in | Index of the 1st primitive of each shell |
| ~shell_prim_num~ | ~int64_t[shell_num]~ | in | Number of primitives per shell |
| ~ao_factor~ | ~double[ao_num]~ | in | Normalization factor of the AOs |
| ~ao_expo~ | ~double[prim_num]~ | in | Value, gradients and Laplacian of the shells |
| ~coef_normalized~ | ~double[prim_num]~ | in | Value, gradients and Laplacian of the shells |
| ~ao_vgl~ | ~double[point_num][5][ao_num]~ | out | Value, gradients and Laplacian of the AOs |
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
#ifdef HAVE_HPC
qmckl_exit_code
qmckl_compute_ao_vgl_hpc_gaussian (
const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
const int32_t* restrict prim_num_per_nucleus,
const int64_t point_num,
const int64_t nucl_num,
const double* restrict coord,
const double* restrict nucl_coord,
const int64_t* restrict nucleus_index,
const int64_t* restrict nucleus_shell_num,
const double* nucleus_range,
const int32_t* restrict nucleus_max_ang_mom,
const int32_t* restrict shell_ang_mom,
const double* restrict ao_factor,
const qmckl_matrix expo_per_nucleus,
const qmckl_tensor coef_per_nucleus,
double* restrict const ao_vgl )
{
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<<ao_value_constants>>
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#ifdef HAVE_OPENMP
#pragma omp parallel if (point_num > 16)
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#endif
{
qmckl_exit_code rc;
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double ar2[prim_max] __attribute__((aligned(64)));
int32_t powers[3*size_max] __attribute__((aligned(64)));
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double exp_mat[prim_max][8] __attribute__((aligned(64))) ;
double ce_mat[shell_max][8] __attribute__((aligned(64))) ;
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int32_t coef_mat_sparse_idx[nucl_num][shell_max][prim_max+1] __attribute__((aligned(64)));
double coef_mat_sparse [nucl_num][shell_max][prim_max+1] __attribute__((aligned(64)));
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for (int i=0 ; i<nucl_num ; ++i) {
for (int j=0 ; j<shell_max; ++j) {
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int l=1;
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for (int k=0 ; k<prim_max; ++k) {
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const double c = qmckl_ten3(coef_per_nucleus,k, j, i);
if (c != 0.) {
coef_mat_sparse_idx[i][j][l] = k;
coef_mat_sparse[i][j][l] = c;
l+=1;
}
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}
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coef_mat_sparse_idx[i][j][0] = l;
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}
}
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double poly_vgl_l1[4][4] __attribute__((aligned(64))) =
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{{1.0, 0.0, 0.0, 0.0},
{0.0, 1.0, 0.0, 0.0},
{0.0, 0.0, 1.0, 0.0},
{0.0, 0.0, 0.0, 1.0}};
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double poly_vgl_l2[5][10]__attribute__((aligned(64))) =
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{{1., 0., 0., 0., 0., 0., 0., 0., 0., 0.},
{0., 1., 0., 0., 0., 0., 0., 0., 0., 0.},
{0., 0., 1., 0., 0., 0., 0., 0., 0., 0.},
{0., 0., 0., 1., 0., 0., 0., 0., 0., 0.},
{0., 0., 0., 0., 2., 0., 0., 2., 0., 2.}};
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double poly_vgl[5][size_max] __attribute__((aligned(64)));
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#ifdef HAVE_OPENMP
#pragma omp for
#endif
for (int64_t ipoint=0 ; ipoint < point_num ; ++ipoint) {
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const double e_coord[3] __attribute__((aligned(64))) =
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{ coord[ipoint],
coord[ipoint + point_num],
coord[ipoint + 2*point_num] };
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for (int64_t inucl=0 ; inucl < nucl_num ; ++inucl) {
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const double n_coord[3] __attribute__((aligned(64))) =
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{ nucl_coord[inucl],
nucl_coord[inucl + nucl_num],
nucl_coord[inucl + 2*nucl_num] };
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/* Test if the point is in the range of the nucleus */
const double x = e_coord[0] - n_coord[0];
const double y = e_coord[1] - n_coord[1];
const double z = e_coord[2] - n_coord[2];
const double r2 = x*x + y*y + z*z;
if (r2 > cutoff * nucleus_range[inucl]) {
continue;
}
int64_t n_poly;
switch (nucleus_max_ang_mom[inucl]) {
case 0:
break;
case 1:
poly_vgl_l1[0][1] = x;
poly_vgl_l1[0][2] = y;
poly_vgl_l1[0][3] = z;
break;
case 2:
poly_vgl_l2[0][1] = x;
poly_vgl_l2[0][2] = y;
poly_vgl_l2[0][3] = z;
poly_vgl_l2[0][4] = x*x;
poly_vgl_l2[0][5] = x*y;
poly_vgl_l2[0][6] = x*z;
poly_vgl_l2[0][7] = y*y;
poly_vgl_l2[0][8] = y*z;
poly_vgl_l2[0][9] = z*z;
poly_vgl_l2[1][4] = x+x;
poly_vgl_l2[1][5] = y;
poly_vgl_l2[1][6] = z;
poly_vgl_l2[2][5] = x;
poly_vgl_l2[2][7] = y+y;
poly_vgl_l2[2][8] = z;
poly_vgl_l2[3][6] = x;
poly_vgl_l2[3][8] = y;
poly_vgl_l2[3][9] = z+z;
break;
default:
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rc = qmckl_ao_polynomial_transp_vgl_hpc_inline(context, e_coord, n_coord,
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nucleus_max_ang_mom[inucl],
&n_poly, powers, (int64_t) 3,
&(poly_vgl[0][0]), size_max);
assert (rc == QMCKL_SUCCESS);
break;
}
/* Compute all exponents */
int64_t nidx = 0;
for (int64_t iprim = 0 ; iprim < prim_num_per_nucleus[inucl] ; ++iprim) {
const double v = qmckl_mat(expo_per_nucleus, iprim, inucl) * r2;
if (v <= cutoff) {
ar2[iprim] = v;
++nidx;
} else {
break;
}
}
for (int64_t iprim = 0 ; iprim < nidx ; ++iprim) {
exp_mat[iprim][0] = exp(-ar2[iprim]);
}
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for (int64_t iprim = 0 ; iprim < nidx ; ++iprim) {
double f = qmckl_mat(expo_per_nucleus, iprim, inucl) * exp_mat[iprim][0];
f = -f-f;
exp_mat[iprim][1] = f * x;
exp_mat[iprim][2] = f * y;
exp_mat[iprim][3] = f * z;
exp_mat[iprim][4] = f * (3.0 - 2.0 * ar2[iprim]);
}
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/* --- */
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// if (do_sparse) {
for (int i=0 ; i<nucleus_shell_num[inucl] ; ++i) {
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#ifdef HAVE_OPENMP
#pragma omp simd
#endif
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for (int j=0 ; j<8 ; ++j) {
ce_mat[i][j] = 0.;
}
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const int32_t* restrict idx = &(coef_mat_sparse_idx[inucl][i][0]);
const double* restrict v = &(coef_mat_sparse[inucl][i][0]);
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for (int l=1 ; l<idx[0]; ++l) {
const int k = idx[l];
if (k >= nidx) break;
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#ifdef HAVE_OPENMP
#pragma omp simd
#endif
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for (int j=0 ; j<8 ; ++j) {
ce_mat[i][j] += v[l] * exp_mat[k][j];
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}
}
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}
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const int64_t ishell_start = nucleus_index[inucl];
const int64_t ishell_end = nucleus_index[inucl] + nucleus_shell_num[inucl];
for (int64_t ishell = ishell_start ; ishell < ishell_end ; ++ishell) {
const double s1 = ce_mat[ishell-ishell_start][0];
const int64_t k = ao_index[ishell];
double* restrict const ao_vgl_1 = ao_vgl + ipoint*5*ao_num + k;
const int32_t l = shell_ang_mom[ishell];
const int32_t n = lstart[l+1]-lstart[l];
double* restrict const ao_vgl_2 = ao_vgl_1 + ao_num;
double* restrict const ao_vgl_3 = ao_vgl_1 + (ao_num<<1);
double* restrict const ao_vgl_4 = ao_vgl_1 + (ao_num<<1) + ao_num;
double* restrict const ao_vgl_5 = ao_vgl_1 + (ao_num<<2);
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if (s1 == 0.0) {
for (int64_t il=0 ; il<n ; ++il) {
ao_vgl_1[il] = 0.0;
ao_vgl_2[il] = 0.0;
ao_vgl_3[il] = 0.0;
ao_vgl_4[il] = 0.0;
ao_vgl_5[il] = 0.0;
}
continue;
}
const double s2 = ce_mat[ishell-ishell_start][1];
const double s3 = ce_mat[ishell-ishell_start][2];
const double s4 = ce_mat[ishell-ishell_start][3];
const double s5 = ce_mat[ishell-ishell_start][4];
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double* restrict poly_vgl_1 = NULL;
double* restrict poly_vgl_2 = NULL;
double* restrict poly_vgl_3 = NULL;
double* restrict poly_vgl_4 = NULL;
double* restrict poly_vgl_5 = NULL;
if (nidx > 0) {
const double* restrict f = ao_factor + k;
const int64_t idx = lstart[l];
switch (nucleus_max_ang_mom[inucl]) {
case 0:
break;
case 1:
poly_vgl_1 = &(poly_vgl_l1[0][idx]);
poly_vgl_2 = &(poly_vgl_l1[1][idx]);
poly_vgl_3 = &(poly_vgl_l1[2][idx]);
poly_vgl_4 = &(poly_vgl_l1[3][idx]);
break;
case 2:
poly_vgl_1 = &(poly_vgl_l2[0][idx]);
poly_vgl_2 = &(poly_vgl_l2[1][idx]);
poly_vgl_3 = &(poly_vgl_l2[2][idx]);
poly_vgl_4 = &(poly_vgl_l2[3][idx]);
poly_vgl_5 = &(poly_vgl_l2[4][idx]);
break;
default:
poly_vgl_1 = &(poly_vgl[0][idx]);
poly_vgl_2 = &(poly_vgl[1][idx]);
poly_vgl_3 = &(poly_vgl[2][idx]);
poly_vgl_4 = &(poly_vgl[3][idx]);
poly_vgl_5 = &(poly_vgl[4][idx]);
}
switch (n) {
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case 1:
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ao_vgl_1[0] = s1 * f[0];
ao_vgl_2[0] = s2 * f[0];
ao_vgl_3[0] = s3 * f[0];
ao_vgl_4[0] = s4 * f[0];
ao_vgl_5[0] = s5;
break;
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case 3:
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#ifdef HAVE_OPENMP
#pragma omp simd
#endif
for (int il=0 ; il<3 ; ++il) {
ao_vgl_1[il] = poly_vgl_1[il] * s1 * f[il];
ao_vgl_2[il] = (poly_vgl_2[il] * s1 + poly_vgl_1[il] * s2) * f[il];
ao_vgl_3[il] = (poly_vgl_3[il] * s1 + poly_vgl_1[il] * s3) * f[il];
ao_vgl_4[il] = (poly_vgl_4[il] * s1 + poly_vgl_1[il] * s4) * f[il];
ao_vgl_5[il] = (poly_vgl_1[il] * s5 +
2.0*(poly_vgl_2[il] * s2 +
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poly_vgl_3[il] * s3 +
poly_vgl_4[il] * s4 )) * f[il];
}
break;
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case 6:
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#ifdef HAVE_OPENMP
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#pragma omp simd
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#endif
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for (int il=0 ; il<6 ; ++il) {
ao_vgl_1[il] = poly_vgl_1[il] * s1 * f[il];
ao_vgl_2[il] = (poly_vgl_2[il] * s1 + poly_vgl_1[il] * s2) * f[il];
ao_vgl_3[il] = (poly_vgl_3[il] * s1 + poly_vgl_1[il] * s3) * f[il];
ao_vgl_4[il] = (poly_vgl_4[il] * s1 + poly_vgl_1[il] * s4) * f[il];
ao_vgl_5[il] = (poly_vgl_5[il] * s1 + poly_vgl_1[il] * s5 +
2.0*(poly_vgl_2[il] * s2 +
poly_vgl_3[il] * s3 +
poly_vgl_4[il] * s4 )) * f[il];
}
break;
default:
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#ifdef HAVE_OPENMP
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#pragma omp simd
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#endif
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for (int il=0 ; il<n ; ++il) {
ao_vgl_1[il] = poly_vgl_1[il] * s1 * f[il];
ao_vgl_2[il] = (poly_vgl_2[il] * s1 + poly_vgl_1[il] * s2) * f[il];
ao_vgl_3[il] = (poly_vgl_3[il] * s1 + poly_vgl_1[il] * s3) * f[il];
ao_vgl_4[il] = (poly_vgl_4[il] * s1 + poly_vgl_1[il] * s4) * f[il];
ao_vgl_5[il] = (poly_vgl_5[il] * s1 + poly_vgl_1[il] * s5 +
2.0*(poly_vgl_2[il] * s2 +
poly_vgl_3[il] * s3 +
poly_vgl_4[il] * s4 )) * f[il];
}
break;
}
} else {
for (int64_t il=0 ; il<n ; ++il) {
ao_vgl_1[il] = 0.0;
ao_vgl_2[il] = 0.0;
ao_vgl_3[il] = 0.0;
ao_vgl_4[il] = 0.0;
ao_vgl_5[il] = 0.0;
}
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}
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}
}
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}
}
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return QMCKL_SUCCESS;
}
#endif
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#+end_src
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*** Interfaces
# #+CALL: generate_c_header(table=qmckl_ao_vgl_args_doc,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_vgl"))
# (Commented because the header needs to go into h_private_func)
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#+begin_src c :tangle (eval h_private_func) :comments org
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qmckl_exit_code qmckl_compute_ao_vgl_doc (
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const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
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const int64_t point_num,
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const int64_t nucl_num,
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const double* coord,
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const double* nucl_coord,
const int64_t* nucleus_index,
const int64_t* nucleus_shell_num,
const double* nucleus_range,
const int32_t* nucleus_max_ang_mom,
const int32_t* shell_ang_mom,
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const double* ao_factor,
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const double* shell_vgl,
double* const ao_vgl );
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#+end_src
#+begin_src c :tangle (eval h_private_func) :comments org
#ifdef HAVE_HPC
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qmckl_exit_code qmckl_compute_ao_vgl_hpc_gaussian (
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const qmckl_context context,
const int64_t ao_num,
const int64_t shell_num,
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const int32_t* prim_num_per_nucleus,
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const int64_t point_num,
const int64_t nucl_num,
const double* coord,
const double* nucl_coord,
const int64_t* nucleus_index,
const int64_t* nucleus_shell_num,
const double* nucleus_range,
const int32_t* nucleus_max_ang_mom,
const int32_t* shell_ang_mom,
const double* ao_factor,
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const qmckl_matrix expo_per_nucleus,
const qmckl_tensor coef_per_nucleus,
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double* const ao_vgl );
#endif
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#+end_src
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#+CALL: generate_c_interface(table=qmckl_ao_vgl_args_doc,rettyp=get_value("CRetType"),fname="qmckl_compute_ao_vgl_doc"))
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#+RESULTS:
#+begin_src f90 :tangle (eval f) :comments org :exports none
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integer(c_int32_t) function qmckl_compute_ao_vgl_doc &
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(context, &
ao_num, &
shell_num, &
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point_num, &
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nucl_num, &
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coord, &
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nucl_coord, &
nucleus_index, &
nucleus_shell_num, &
nucleus_range, &
nucleus_max_ang_mom, &
shell_ang_mom, &
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ao_factor, &
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shell_vgl, &
ao_vgl) &
bind(C) result(info)
use, intrinsic :: iso_c_binding
implicit none
integer (c_int64_t) , intent(in) , value :: context
integer (c_int64_t) , intent(in) , value :: ao_num
integer (c_int64_t) , intent(in) , value :: shell_num
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integer (c_int64_t) , intent(in) , value :: point_num
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integer (c_int64_t) , intent(in) , value :: nucl_num
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real (c_double ) , intent(in) :: coord(point_num,3)
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real (c_double ) , intent(in) :: nucl_coord(nucl_num,3)
integer (c_int64_t) , intent(in) :: nucleus_index(nucl_num)
integer (c_int64_t) , intent(in) :: nucleus_shell_num(nucl_num)
real (c_double ) , intent(in) :: nucleus_range(nucl_num)
integer (c_int32_t) , intent(in) :: nucleus_max_ang_mom(nucl_num)
integer (c_int32_t) , intent(in) :: shell_ang_mom(shell_num)
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real (c_double ) , intent(in) :: ao_factor(ao_num)
real (c_double ) , intent(in) :: shell_vgl(shell_num,5,point_num)
real (c_double ) , intent(out) :: ao_vgl(ao_num,5,point_num)
integer(c_int32_t), external :: qmckl_compute_ao_vgl_doc_f
info = qmckl_compute_ao_vgl_doc_f &
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(context, &
ao_num, &
shell_num, &
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point_num, &
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nucl_num, &
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coord, &
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nucl_coord, &
nucleus_index, &
nucleus_shell_num, &
nucleus_range, &
nucleus_max_ang_mom, &
shell_ang_mom, &
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ao_factor, &
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shell_vgl, &
ao_vgl)
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end function qmckl_compute_ao_vgl_doc
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#+end_src
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**** Provide :noexport:
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#+CALL: write_provider_header( group="ao_basis", data="ao_vgl" )
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#+RESULTS:
#+begin_src c :comments org :tangle (eval h_private_func) :noweb yes :export none
qmckl_exit_code qmckl_provide_ao_basis_ao_vgl(qmckl_context context);
#+end_src
#+CALL: write_provider_pre( group="ao_basis", data="ao_vgl", dimension="ctx->ao_basis.ao_num * 5 * ctx->point.num")
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
qmckl_exit_code qmckl_provide_ao_basis_ao_vgl(qmckl_context context)
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{
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qmckl_exit_code rc = QMCKL_SUCCESS;
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if (qmckl_context_check(context) == QMCKL_NULL_CONTEXT) {
return qmckl_failwith( context,
QMCKL_INVALID_CONTEXT,
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"qmckl_provide_ao_basis_ao_vgl",
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NULL);
}
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qmckl_context_struct* const ctx = (qmckl_context_struct*) context;
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assert (ctx != NULL);
if (!ctx->ao_basis.provided) {
return qmckl_failwith( context,
QMCKL_NOT_PROVIDED,
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"qmckl_provide_ao_basis_ao_vgl",
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NULL);
}
/* Compute if necessary */
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if (ctx->point.date > ctx->ao_basis.ao_vgl_date) {
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qmckl_memory_info_struct mem_info = qmckl_memory_info_struct_zero;
mem_info.size = ctx->ao_basis.ao_num * 5 * ctx->point.num * sizeof(double);
if (ctx->ao_basis.ao_vgl != NULL) {
qmckl_memory_info_struct mem_info_test = qmckl_memory_info_struct_zero;
rc = qmckl_get_malloc_info(context, ctx->ao_basis.ao_vgl, &mem_info_test);
/* if rc != QMCKL_SUCCESS, we are maybe in an _inplace function because the
memory was not allocated with qmckl_malloc */
if ((rc == QMCKL_SUCCESS) && (mem_info_test.size != mem_info.size)) {
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rc = qmckl_free(context, ctx->ao_basis.ao_vgl);
assert (rc == QMCKL_SUCCESS);
ctx->ao_basis.ao_vgl = NULL;
}
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}
/* Allocate array */
if (ctx->ao_basis.ao_vgl == NULL) {
double* ao_vgl = (double*) qmckl_malloc(context, mem_info);
if (ao_vgl == NULL) {
return qmckl_failwith( context,
QMCKL_ALLOCATION_FAILED,
"qmckl_ao_basis_ao_vgl",
NULL);
}
ctx->ao_basis.ao_vgl = ao_vgl;
}
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#+end_src
#+begin_src c :comments org :tangle (eval c) :noweb yes :exports none
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#ifdef HAVE_HPC
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if (ctx->ao_basis.type == 'G') {
rc = qmckl_compute_ao_vgl_hpc_gaussian(context,
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ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
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ctx->ao_basis.prim_num_per_nucleus,
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ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
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ctx->ao_basis.expo_per_nucleus,
ctx->ao_basis.coef_per_nucleus,
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ctx->ao_basis.ao_vgl);
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/* DEBUG
rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc, "qmckl_provide_ao_basis_shell_vgl", NULL);
}
int64_t K= ctx->ao_basis.ao_num * 5 * ctx->point.num;
double* check = malloc(K*sizeof(double));
rc = qmckl_compute_ao_vgl_doc(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.shell_vgl,
check);
for (int64_t i=0 ; i<K ; ++i) {
if (fabs(check[i] - ctx->ao_basis.ao_vgl[i]) > 1.e-10) {
int a, b, c;
a = i/(ctx->ao_basis.ao_num*5);
b = (i-a*ctx->ao_basis.ao_num*5)/ctx->ao_basis.ao_num;
c = (i-a*ctx->ao_basis.ao_num*5 -b*ctx->ao_basis.ao_num);
printf("%d: %d, %d, %d, %e %e\n", i, a, b, c, check[i], ctx->ao_basis.ao_vgl[i]);
}
}
*/
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/*
} else if (ctx->ao_basis.type == 'S') {
rc = qmck_compute_ao_vgl_hpc_slater(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->ao_basis.prim_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.shell_prim_index,
ctx->ao_basis.shell_prim_num,
ctx->ao_basis.ao_factor,
ctx->ao_basis.exponent,
ctx->ao_basis.coefficient_normalized,
ctx->ao_basis.ao_vgl);
,*/
} else {
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/* Provide required data */
rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc, "qmckl_provide_ao_basis_shell_vgl", NULL);
}
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rc = qmckl_compute_ao_vgl_doc(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.shell_vgl,
ctx->ao_basis.ao_vgl);
}
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#else
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rc = qmckl_provide_ao_basis_shell_vgl(context);
if (rc != QMCKL_SUCCESS) {
return qmckl_failwith( context, rc, "qmckl_provide_ao_basis_shell_vgl", NULL);
}
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rc = qmckl_compute_ao_vgl_doc(context,
ctx->ao_basis.ao_num,
ctx->ao_basis.shell_num,
ctx->point.num,
ctx->nucleus.num,
ctx->point.coord.data,
ctx->nucleus.coord.data,
ctx->ao_basis.nucleus_index,
ctx->ao_basis.nucleus_shell_num,
ctx->ao_basis.nucleus_range,
ctx->ao_basis.nucleus_max_ang_mom,
ctx->ao_basis.shell_ang_mom,
ctx->ao_basis.ao_factor,
ctx->ao_basis.shell_vgl,
ctx->ao_basis.ao_vgl);
#endif
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#+end_src
#+CALL: write_provider_post( group="ao_basis", data="ao_vgl" )
#+RESULTS:
#+begin_src c :comments org :tangle (eval c) :noweb yes :export none
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if (rc != QMCKL_SUCCESS) {
return rc;
}
ctx->ao_basis.ao_vgl_date = ctx->date;
}
return QMCKL_SUCCESS;
}
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#+end_src
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**** Test :noexport:
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#+begin_src python :results output :exports none
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import numpy as np
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from math import sqrt
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h0 = 1.e-4
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def f(a,x,y):
return np.sum( [c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] )
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def fx(a,x,y):
return f(a,x,y) * (x[0] - y[0])**2
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def df(a,x,y,n):
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if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
return ( fx(a,x+h,y) - fx(a,x-h,y) ) / (2.*h0)
# return np.sum( [-2.*b * c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] ) * (x-y)[n-1]
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def d2f(a,x,y,n):
if n == 1: h = np.array([h0,0.,0.])
elif n == 2: h = np.array([0.,h0,0.])
elif n == 3: h = np.array([0.,0.,h0])
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return ( fx(a,x+h,y) - 2.*fx(a,x,y) + fx(a,x-h,y) ) / h0**2
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# return np.sum( [( (2.*b*(x-y)[n-1])**2 -2.*b ) * c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] )
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def lf(a,x,y):
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# return np.sum( [( (2.*b*np.linalg.norm(x-y))**2 -6.*b ) * c * np.exp( -b*(np.linalg.norm(x-y))**2) for b,c in a] )
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return d2f(a,x,y,1) + d2f(a,x,y,2) + d2f(a,x,y,3)
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elec_26_w1 = np.array( [ 1.49050402641, 2.90106987953, -1.05920815468 ] )
elec_15_w2 = np.array( [ -2.20180344582,-1.9113150239, 2.2193744778600002 ] )
nucl_1 = np.array( [ -2.302574592081335e+00, -3.542027060505035e-01, -5.334129934317614e-02] )
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#double ao_vgl[prim_num][5][elec_num];
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x = elec_26_w1 ; y = nucl_1
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a = [( 4.0382999999999998e+02, 1.4732000000000000e-03 * 5.9876577632594533e+04),
( 1.2117000000000000e+02, 1.2672500000000000e-02 * 7.2836806319891484e+03),
( 4.6344999999999999e+01, 5.8045100000000002e-02 * 1.3549226646722386e+03),
( 1.9721000000000000e+01, 1.7051030000000000e-01 * 3.0376315094739988e+02),
( 8.8623999999999992e+00, 3.1859579999999998e-01 * 7.4924579607137730e+01),
( 3.9962000000000000e+00, 3.8450230000000002e-01 * 1.8590543353806009e+01),
( 1.7636000000000001e+00, 2.7377370000000001e-01 * 4.4423176930919421e+00),
( 7.0618999999999998e-01, 7.4396699999999996e-02 * 8.9541051939952665e-01)]
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norm = sqrt(3.)
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# x^2 * g(r)
print ( "[26][0][219] : %25.15e"%(fx(a,x,y)) )
print ( "[26][1][219] : %25.15e"%(df(a,x,y,1)) )
print ( "[26][2][219] : %25.15e"%(df(a,x,y,2)) )
print ( "[26][3][219] : %25.15e"%(df(a,x,y,3)) )
print ( "[26][4][219] : %25.15e"%(lf(a,x,y)) )
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print ( "[26][0][220] : %25.15e"%(norm*f(a,x,y) * (x[0] - y[0]) * (x[1] - y[1]) ))
print ( "[26][1][220] : %25.15e"%(norm*df(a,x,y,1)* (x[0] - y[0]) * (x[1] - y[1]) + norm*f(a,x,y) * (x[1] - y[1])) )
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print ( "[26][0][221] : %25.15e"%(norm*f(a,x,y) * (x[0] - y[0]) * (x[2] - y[2])) )
print ( "[26][1][221] : %25.15e"%(norm*df(a,x,y,1)* (x[0] - y[0]) * (x[2] - y[2]) + norm*f(a,x,y) * (x[2] - y[2])) )
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print ( "[26][0][222] : %25.15e"%(f(a,x,y) * (x[1] - y[1]) * (x[1] - y[1])) )
print ( "[26][1][222] : %25.15e"%(df(a,x,y,1)* (x[1] - y[1]) * (x[1] - y[1])) )
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print ( "[26][0][223] : %25.15e"%(norm*f(a,x,y) * (x[1] - y[1]) * (x[2] - y[2])) )
print ( "[26][1][223] : %25.15e"%(norm*df(a,x,y,1)* (x[1] - y[1]) * (x[2] - y[2])) )
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print ( "[26][0][224] : %25.15e"%(f(a,x,y) * (x[2] - y[2]) * (x[2] - y[2])) )
print ( "[26][1][224] : %25.15e"%(df(a,x,y,1)* (x[2] - y[2]) * (x[2] - y[2])) )
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#+end_src
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#+RESULTS:
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#+begin_src c :tangle (eval c_test) :exports none
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{
#define shell_num chbrclf_shell_num
#define ao_num chbrclf_ao_num
double* elec_coord = &(chbrclf_elec_coord[0][0][0]);
assert(qmckl_electron_provided(context));
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const int64_t point_num = elec_num;
rc = qmckl_set_point(context, 'N', point_num, elec_coord, point_num*3);
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assert(rc == QMCKL_SUCCESS);
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double ao_vgl[point_num][5][ao_num];
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rc = qmckl_get_ao_basis_ao_vgl(context, &(ao_vgl[0][0][0]),
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(int64_t) 5*point_num*ao_num);
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assert (rc == QMCKL_SUCCESS);
printf("\n");
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printf(" ao_vgl ao_vgl[26][0][219] %25.15e\n", ao_vgl[26][0][219]);
printf(" ao_vgl ao_vgl[26][1][219] %25.15e\n", ao_vgl[26][1][219]);
printf(" ao_vgl ao_vgl[26][2][219] %25.15e\n", ao_vgl[26][2][219]);
printf(" ao_vgl ao_vgl[26][3][219] %25.15e\n", ao_vgl[26][3][219]);
printf(" ao_vgl ao_vgl[26][4][219] %25.15e\n", ao_vgl[26][4][219]);
printf(" ao_vgl ao_vgl[26][0][220] %25.15e\n", ao_vgl[26][0][220]);
printf(" ao_vgl ao_vgl[26][1][220] %25.15e\n", ao_vgl[26][1][220]);
printf(" ao_vgl ao_vgl[26][2][220] %25.15e\n", ao_vgl[26][2][220]);
printf(" ao_vgl ao_vgl[26][3][220] %25.15e\n", ao_vgl[26][3][220]);
printf(" ao_vgl ao_vgl[26][4][220] %25.15e\n", ao_vgl[26][4][220]);
printf(" ao_vgl ao_vgl[26][0][221] %25.15e\n", ao_vgl[26][0][221]);
printf(" ao_vgl ao_vgl[26][1][221] %25.15e\n", ao_vgl[26][1][221]);
printf(" ao_vgl ao_vgl[26][2][221] %25.15e\n", ao_vgl[26][2][221]);
printf(" ao_vgl ao_vgl[26][3][221] %25.15e\n", ao_vgl[26][3][221]);
printf(" ao_vgl ao_vgl[26][4][221] %25.15e\n", ao_vgl[26][4][221]);
printf(" ao_vgl ao_vgl[26][0][222] %25.15e\n", ao_vgl[26][0][222]);
printf(" ao_vgl ao_vgl[26][1][222] %25.15e\n", ao_vgl[26][1][222]);
printf(" ao_vgl ao_vgl[26][2][222] %25.15e\n", ao_vgl[26][2][222]);
printf(" ao_vgl ao_vgl[26][3][222] %25.15e\n", ao_vgl[26][3][222]);
printf(" ao_vgl ao_vgl[26][4][222] %25.15e\n", ao_vgl[26][4][222]);
printf(" ao_vgl ao_vgl[26][0][223] %25.15e\n", ao_vgl[26][0][223]);
printf(" ao_vgl ao_vgl[26][1][223] %25.15e\n", ao_vgl[26][1][223]);
printf(" ao_vgl ao_vgl[26][2][223] %25.15e\n", ao_vgl[26][2][223]);
printf(" ao_vgl ao_vgl[26][3][223] %25.15e\n", ao_vgl[26][3][223]);
printf(" ao_vgl ao_vgl[26][4][223] %25.15e\n", ao_vgl[26][4][223]);
printf(" ao_vgl ao_vgl[26][0][224] %25.15e\n", ao_vgl[26][0][224]);
printf(" ao_vgl ao_vgl[26][1][224] %25.15e\n", ao_vgl[26][1][224]);
printf(" ao_vgl ao_vgl[26][2][224] %25.15e\n", ao_vgl[26][2][224]);
printf(" ao_vgl ao_vgl[26][3][224] %25.15e\n", ao_vgl[26][3][224]);
printf(" ao_vgl ao_vgl[26][4][224] %25.15e\n", ao_vgl[26][4][224]);
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printf("\n");
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assert( fabs(ao_vgl[26][0][219] - ( 1.020298798341620e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][219] - ( -4.928035238010602e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][219] - ( -4.691009312035986e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][219] - ( 1.449504046436699e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][219] - ( 4.296442111843973e-07)) < 1.e-14 );
assert( fabs(ao_vgl[26][0][220] - ( 1.516643537739178e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][220] - ( -7.725221462603871e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][220] - ( -6.507140835104833e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][220] - ( 2.154644255710413e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][220] - ( 6.365449359656352e-07)) < 1.e-14 );
assert( fabs(ao_vgl[26][0][221] - ( -4.686370882518819e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][221] - ( 2.387064067626827e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][221] - ( 2.154644255710412e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][221] - ( -1.998731863512374e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][221] - ( -1.966899656441993e-07)) < 1.e-14 );
assert( fabs(ao_vgl[26][0][222] - ( 7.514816980753531e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][222] - ( -4.025889138635182e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][222] - ( -2.993372555126361e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][222] - ( 1.067604670272904e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][222] - ( 3.168199650002648e-07)) < 1.e-14 );
assert( fabs(ao_vgl[26][0][223] - ( -4.021908374204471e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][223] - ( 2.154644255710413e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][223] - ( 1.725594944732276e-08)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][223] - ( -1.715339357718333e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][223] - ( -1.688020516893476e-07)) < 1.e-14 );
assert( fabs(ao_vgl[26][0][224] - ( 7.175045873560788e-10)) < 1.e-14 );
assert( fabs(ao_vgl[26][1][224] - ( -3.843864637762753e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][2][224] - ( -3.298857850451910e-09)) < 1.e-14 );
assert( fabs(ao_vgl[26][3][224] - ( -4.073047518790881e-10)) < 1.e-14 );
assert( fabs(ao_vgl[26][4][224] - ( 3.153244195820293e-08)) < 1.e-14 );
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}
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#+end_src
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* End of files :noexport:
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#+begin_src c :tangle (eval h_private_type)
#endif
#+end_src
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#+begin_src c :tangle (eval h_private_func)
#endif
#+end_src
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*** Test
#+begin_src c :tangle (eval c_test)
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rc = qmckl_context_destroy(context);
assert (rc == QMCKL_SUCCESS);
return 0;
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}
#+end_src
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*** Compute file names
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#+begin_src emacs-lisp
; The following is required to compute the file names
(setq pwd (file-name-directory buffer-file-name))
(setq name (file-name-nondirectory (substring buffer-file-name 0 -4)))
(setq f (concat pwd name "_f.f90"))
(setq fh (concat pwd name "_fh.f90"))
(setq c (concat pwd name ".c"))
(setq h (concat name ".h"))
(setq h_private (concat name "_private.h"))
(setq c_test (concat pwd "test_" name ".c"))
(setq f_test (concat pwd "test_" name "_f.f90"))
; Minted
(require 'ox-latex)
(setq org-latex-listings 'minted)
(add-to-list 'org-latex-packages-alist '("" "listings"))
(add-to-list 'org-latex-packages-alist '("" "color"))
#+end_src
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#+RESULTS:
| | color |
| | listings |
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# -*- mode: org -*-
# vim: syntax=c
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* TODO [0/1] Missing features :noexport:
- [ ] Error messages to tell what is missing when initializing