/* Evaluate the TEC value for each pierce point - note: at the moment this is
* just the accumulation of one or more TID screens.
* TODO convert this to a stand-alone function.
*/
static void oskar_evaluate_TEC(oskar_WorkJonesZ* work, int num_pp,
const oskar_SettingsIonosphere* settings,
double gast, int* status)
{
int i;
/* FIXME(BM) For now limit number of screens to 1, this can be removed
* if a TEC model which is valid for multiple screens is implemented
*/
if (settings->num_TID_screens > 1)
*status = OSKAR_ERR_INVALID_ARGUMENT;
oskar_mem_set_value_real(work->total_TEC, 0.0, 0, 0, status);
/* Loop over TID screens to evaluate TEC values */
for (i = 0; i < settings->num_TID_screens; ++i)
{
oskar_mem_set_value_real(work->screen_TEC, 0.0, 0, 0, status);
/* Evaluate TEC values for the screen */
oskar_evaluate_tec_tid(work->screen_TEC, num_pp, work->pp_lon,
work->pp_lat, work->pp_rel_path, settings->TEC0,
&settings->TID[i], gast);
/* Accumulate into total TEC */
/* FIXME(BM) addition is not physical for more than one TEC screen in
* the way TIDs are currently evaluated as TEC0 is added into both
* screens.
*/
oskar_mem_add(work->total_TEC, work->total_TEC, work->screen_TEC,
oskar_mem_length(work->total_TEC), status);
}
}
void oskar_sky_set_gaussian_parameters(oskar_Sky* sky,
double FWHM_major, double FWHM_minor, double position_angle,
int* status)
{
/* Check if safe to proceed. */
if (*status) return;
oskar_mem_set_value_real(sky->fwhm_major_rad, FWHM_major, 0, 0, status);
oskar_mem_set_value_real(sky->fwhm_minor_rad, FWHM_minor, 0, 0, status);
oskar_mem_set_value_real(sky->pa_rad, position_angle, 0, 0, status);
}
TEST(element_weights_errors, test_evaluate)
{
int num_elements = 10000;
double element_gain = 1.0;
double element_gain_error = 0.0;
double element_phase = 0.0 * M_PI;
double element_phase_error = 0.0 * M_PI;
int error = 0;
unsigned int seed = 1;
oskar_Mem *d_gain, *d_gain_error, *d_phase, *d_phase_error, *d_errors;
d_gain = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &error);
d_gain_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &error);
d_phase = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &error);
d_phase_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &error);
d_errors = oskar_mem_create(OSKAR_DOUBLE_COMPLEX, OSKAR_GPU,
num_elements, &error);
ASSERT_EQ(0, error) << oskar_get_error_string(error);
oskar_mem_set_value_real(d_gain, element_gain, 0, 0, &error);
oskar_mem_set_value_real(d_gain_error, element_gain_error, 0, 0, &error);
oskar_mem_set_value_real(d_phase, element_phase, 0, 0, &error);
oskar_mem_set_value_real(d_phase_error, element_phase_error, 0, 0, &error);
oskar_mem_set_value_real(d_errors, 0.0, 0, 0, &error);
ASSERT_EQ(0, error) << oskar_get_error_string(error);
// Evaluate weights errors.
oskar_evaluate_element_weights_errors(num_elements,
d_gain, d_gain_error, d_phase, d_phase_error,
seed, 0, 0, d_errors, &error);
ASSERT_EQ(0, error) << oskar_get_error_string(error);
// Write memory to file for inspection.
const char* fname = "temp_test_element_errors.dat";
FILE* file = fopen(fname, "w");
oskar_mem_save_ascii(file, 5, num_elements, &error,
d_gain, d_gain_error, d_phase, d_phase_error, d_errors);
fclose(file);
remove(fname);
// Free memory.
oskar_mem_free(d_gain, &error);
oskar_mem_free(d_gain_error, &error);
oskar_mem_free(d_phase, &error);
oskar_mem_free(d_phase_error, &error);
oskar_mem_free(d_errors, &error);
ASSERT_EQ(0, error) << oskar_get_error_string(error);
}
void oskar_station_resize(oskar_Station* station, int num_elements,
int* status)
{
/* Check if safe to proceed. */
if (*status) return;
/* Resize arrays in the model. */
oskar_mem_realloc(station->element_true_x_enu_metres, num_elements, status);
oskar_mem_realloc(station->element_true_y_enu_metres, num_elements, status);
oskar_mem_realloc(station->element_true_z_enu_metres, num_elements, status);
oskar_mem_realloc(station->element_measured_x_enu_metres,
num_elements, status);
oskar_mem_realloc(station->element_measured_y_enu_metres,
num_elements, status);
oskar_mem_realloc(station->element_measured_z_enu_metres,
num_elements, status);
oskar_mem_realloc(station->element_weight, num_elements, status);
oskar_mem_realloc(station->element_gain, num_elements, status);
oskar_mem_realloc(station->element_gain_error, num_elements, status);
oskar_mem_realloc(station->element_phase_offset_rad, num_elements, status);
oskar_mem_realloc(station->element_phase_error_rad, num_elements, status);
oskar_mem_realloc(station->element_x_alpha_cpu, num_elements, status);
oskar_mem_realloc(station->element_x_beta_cpu, num_elements, status);
oskar_mem_realloc(station->element_x_gamma_cpu, num_elements, status);
oskar_mem_realloc(station->element_y_alpha_cpu, num_elements, status);
oskar_mem_realloc(station->element_y_beta_cpu, num_elements, status);
oskar_mem_realloc(station->element_y_gamma_cpu, num_elements, status);
oskar_mem_realloc(station->element_types, num_elements, status);
oskar_mem_realloc(station->element_types_cpu, num_elements, status);
oskar_mem_realloc(station->element_mount_types_cpu, num_elements, status);
/* Initialise any new elements with default values. */
if (num_elements > station->num_elements)
{
int offset, num_new;
offset = station->num_elements;
num_new = num_elements - offset;
/* Must set default element weight, gain and orientation. */
oskar_mem_set_value_real(station->element_gain,
1.0, offset, num_new, status);
oskar_mem_set_value_real(station->element_weight,
1.0, offset, num_new, status);
memset(oskar_mem_char(station->element_mount_types_cpu) + offset,
'F', num_new);
}
/* Set the new number of elements. */
station->num_elements = num_elements;
}
void oskar_station_override_element_time_variable_phases(oskar_Station* s,
double phase_std, int* status)
{
int i;
/* Check if safe to proceed. */
if (*status) return;
/* Check if there are child stations. */
if (oskar_station_has_child(s))
{
/* Recursive call to find the last level (i.e. the element data). */
for (i = 0; i < s->num_elements; ++i)
{
oskar_station_override_element_time_variable_phases(
oskar_station_child(s, i), phase_std, status);
}
}
else
{
/* Override element data at last level. */
oskar_mem_set_value_real(s->element_phase_error_rad,
phase_std, 0, 0, status);
}
}
TEST(Mem, set_value_real_double_complex_matrix)
{
// Double precision complex matrix.
int n = 100, status = 0;
oskar_Mem *mem, *mem2;
mem = oskar_mem_create(OSKAR_DOUBLE_COMPLEX_MATRIX, OSKAR_GPU, n,
&status);
oskar_mem_set_value_real(mem, 6.5, 0, 0, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
mem2 = oskar_mem_create_copy(mem, OSKAR_CPU, &status);
double4c* v = oskar_mem_double4c(mem2, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
for (int i = 0; i < n; ++i)
{
EXPECT_DOUBLE_EQ(v[i].a.x, 6.5);
EXPECT_DOUBLE_EQ(v[i].a.y, 0.0);
EXPECT_DOUBLE_EQ(v[i].b.x, 0.0);
EXPECT_DOUBLE_EQ(v[i].b.y, 0.0);
EXPECT_DOUBLE_EQ(v[i].c.x, 0.0);
EXPECT_DOUBLE_EQ(v[i].c.y, 0.0);
EXPECT_DOUBLE_EQ(v[i].d.x, 6.5);
EXPECT_DOUBLE_EQ(v[i].d.y, 0.0);
}
oskar_mem_free(mem, &status);
oskar_mem_free(mem2, &status);
}
static void evaluate_station_beam_enu_directions(oskar_Mem* beam_pattern,
int np, const oskar_Mem* x, const oskar_Mem* y, const oskar_Mem* z,
const oskar_Station* station, oskar_StationWork* work,
int time_index, double frequency_hz, double GAST, int* status)
{
if (*status) return;
switch (oskar_station_type(station))
{
case OSKAR_STATION_TYPE_AA:
{
oskar_evaluate_station_beam_aperture_array(beam_pattern, station,
np, x, y, z, GAST, frequency_hz, work, time_index, status);
break;
}
case OSKAR_STATION_TYPE_ISOTROPIC:
{
oskar_mem_set_value_real(beam_pattern, 1.0, 0, np, status);
break;
}
case OSKAR_STATION_TYPE_GAUSSIAN_BEAM:
{
oskar_Mem *l, *m, *n; /* Relative direction cosines */
double fwhm, f0;
l = oskar_station_work_enu_direction_x(work);
m = oskar_station_work_enu_direction_y(work);
n = oskar_station_work_enu_direction_z(work);
compute_relative_directions(l, m, n, np, x, y, z, station, GAST,
status);
fwhm = oskar_station_gaussian_beam_fwhm_rad(station);
f0 =oskar_station_gaussian_beam_reference_freq_hz(station);
fwhm *= f0 / frequency_hz;
oskar_evaluate_station_beam_gaussian(beam_pattern, np, l, m, z,
fwhm, status);
break;
}
case OSKAR_STATION_TYPE_VLA_PBCOR:
{
oskar_Mem *l, *m, *n; /* Relative direction cosines */
l = oskar_station_work_enu_direction_x(work);
m = oskar_station_work_enu_direction_y(work);
n = oskar_station_work_enu_direction_z(work);
compute_relative_directions(l, m, n, np, x, y, z, station, GAST,
status);
oskar_evaluate_vla_beam_pbcor(beam_pattern, np, l, m, frequency_hz,
status);
break;
}
default:
{
*status = OSKAR_ERR_SETTINGS_TELESCOPE;
break;
}
};
}
TEST(Mem, set_value_real_single)
{
// Single precision real.
int n = 100, status = 0;
oskar_Mem *mem;
mem = oskar_mem_create(OSKAR_SINGLE, OSKAR_CPU, n, &status);
oskar_mem_set_value_real(mem, 4.5, 0, 0, &status);
float* v = oskar_mem_float(mem, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
for (int i = 0; i < n; ++i)
{
EXPECT_FLOAT_EQ(v[i], 4.5);
}
oskar_mem_free(mem, &status);
}
TEST(Mem, set_value_real_double)
{
// Double precision real.
int n = 100, status = 0;
oskar_Mem *mem;
mem = oskar_mem_create(OSKAR_DOUBLE, OSKAR_CPU, n, &status);
oskar_mem_set_value_real(mem, 4.5, 0, 0, &status);
double* v = oskar_mem_double(mem, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
for (int i = 0; i < n; ++i)
{
EXPECT_DOUBLE_EQ(v[i], 4.5);
}
oskar_mem_free(mem, &status);
}
TEST(Mem, set_value_real_single_complex)
{
// Single precision complex.
int n = 100, status = 0;
oskar_Mem *mem, *mem2;
mem = oskar_mem_create(OSKAR_SINGLE_COMPLEX, OSKAR_GPU, n,
&status);
oskar_mem_set_value_real(mem, 6.5, 0, 0, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
mem2 = oskar_mem_create_copy(mem, OSKAR_CPU, &status);
float2* v = oskar_mem_float2(mem2, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
for (int i = 0; i < n; ++i)
{
EXPECT_FLOAT_EQ(v[i].x, 6.5);
EXPECT_FLOAT_EQ(v[i].y, 0.0);
}
oskar_mem_free(mem, &status);
oskar_mem_free(mem2, &status);
}
TEST(element_weights_errors, test_reinit)
{
int num_elements = 5;
int status = 0;
double gain = 1.5;
double gain_error = 0.2;
double phase = 0.1 * M_PI;
double phase_error = (5 / 180.0) * M_PI;
oskar_Mem *d_errors, *d_gain, *d_gain_error, *d_phase, *d_phase_error;
d_errors = oskar_mem_create(OSKAR_DOUBLE_COMPLEX, OSKAR_GPU,
num_elements, &status);
d_gain = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_gain_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_phase = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_phase_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
oskar_mem_set_value_real(d_gain, gain, 0, 0, &status);
oskar_mem_set_value_real(d_gain_error, gain_error, 0, 0, &status);
oskar_mem_set_value_real(d_phase, phase, 0, 0, &status);
oskar_mem_set_value_real(d_phase_error, phase_error, 0, 0, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
int num_channels = 2;
int num_chunks = 3;
int num_stations = 5;
int num_times = 3;
unsigned int seed = 1;
const char* fname = "temp_test_weights_error_reinit.dat";
FILE* file = fopen(fname, "w");
for (int chan = 0; chan < num_channels; ++chan)
{
fprintf(file, "channel: %i\n", chan);
for (int chunk = 0; chunk < num_chunks; ++chunk)
{
fprintf(file, " chunk: %i\n", chunk);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
for (int t = 0; t < num_times; ++t)
{
fprintf(file, " time: %i\n", t);
for (int s = 0; s < num_stations; ++s)
{
fprintf(file, " station: %i ==> ", s);
oskar_evaluate_element_weights_errors(num_elements,
d_gain, d_gain_error, d_phase, d_phase_error,
seed, t, s, d_errors, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
oskar_Mem *h_errors = oskar_mem_create_copy(d_errors,
OSKAR_CPU, &status);
double2* errors = oskar_mem_double2(h_errors, &status);
for (int i = 0; i < num_elements; ++i)
{
fprintf(file, "(% -6.4f, % -6.4f), ",
errors[i].x, errors[i].y);
}
fprintf(file, "\n");
oskar_mem_free(h_errors, &status);
}
}
ASSERT_EQ(0, status) << oskar_get_error_string(status);
}
}
fclose(file);
// remove(fname);
oskar_mem_free(d_gain, &status);
oskar_mem_free(d_gain_error, &status);
oskar_mem_free(d_phase, &status);
oskar_mem_free(d_phase_error, &status);
oskar_mem_free(d_errors, &status);
}
TEST(element_weights_errors, test_apply)
{
int num_elements = 10000;
int status = 0;
double gain = 1.5;
double gain_error = 0.2;
double phase = 0.1 * M_PI;
double phase_error = (5 / 180.0) * M_PI;
double weight_gain = 1.0;
double weight_phase = 0.5 * M_PI;
double2 weight;
weight.x = weight_gain * cos(weight_phase);
weight.y = weight_gain * sin(weight_phase);
oskar_Mem *d_gain, *d_gain_error, *d_phase, *d_phase_error, *d_errors;
oskar_Mem *h_weights, *d_weights;
d_errors = oskar_mem_create(OSKAR_DOUBLE_COMPLEX, OSKAR_GPU,
num_elements, &status);
d_gain = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_gain_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_phase = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
d_phase_error = oskar_mem_create(OSKAR_DOUBLE, OSKAR_GPU,
num_elements, &status);
h_weights = oskar_mem_create(OSKAR_DOUBLE_COMPLEX, OSKAR_CPU,
num_elements, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
oskar_mem_set_value_real(d_gain, gain, 0, 0, &status);
oskar_mem_set_value_real(d_gain_error, gain_error, 0, 0, &status);
oskar_mem_set_value_real(d_phase, phase, 0, 0, &status);
oskar_mem_set_value_real(d_phase_error, phase_error, 0, 0, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
double2* h_weights_ = oskar_mem_double2(h_weights, &status);
for (int i = 0; i < num_elements; ++i)
{
h_weights_[i].x = weight.x;
h_weights_[i].y = weight.y;
}
d_weights = oskar_mem_create_copy(h_weights, OSKAR_GPU, &status);
oskar_evaluate_element_weights_errors(num_elements,
d_gain, d_gain_error, d_phase, d_phase_error,
0, 0, 0, d_errors, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
oskar_mem_element_multiply(NULL, d_weights, d_errors, num_elements, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
// Write memory to file for inspection.
const char* fname = "temp_test_weights.dat";
FILE* file = fopen(fname, "w");
oskar_mem_save_ascii(file, 7, num_elements, &status,
d_gain, d_gain_error, d_phase, d_phase_error, d_errors,
h_weights, d_weights);
fclose(file);
remove(fname);
// Free memory.
oskar_mem_free(d_gain, &status);
oskar_mem_free(d_gain_error, &status);
oskar_mem_free(d_phase, &status);
oskar_mem_free(d_phase_error, &status);
oskar_mem_free(d_errors, &status);
oskar_mem_free(h_weights, &status);
oskar_mem_free(d_weights, &status);
ASSERT_EQ(0, status) << oskar_get_error_string(status);
}
void oskar_element_evaluate(
const oskar_Element* model,
double orientation_x,
double orientation_y,
int offset_points,
int num_points,
const oskar_Mem* x,
const oskar_Mem* y,
const oskar_Mem* z,
double frequency_hz,
oskar_Mem* theta,
oskar_Mem* phi,
int offset_out,
oskar_Mem* output,
int* status)
{
double dipole_length_m;
if (*status) return;
if (!oskar_mem_is_complex(output))
{
*status = OSKAR_ERR_BAD_DATA_TYPE;
return;
}
oskar_mem_ensure(output, offset_out + num_points, status);
oskar_mem_ensure(theta, num_points, status);
oskar_mem_ensure(phi, num_points, status);
/* Get the element model properties. */
const int element_type = model->element_type;
const int taper_type = model->taper_type;
const int id = oskar_find_closest_match_d(frequency_hz,
oskar_element_num_freq(model),
oskar_element_freqs_hz_const(model));
dipole_length_m = model->dipole_length;
if (model->dipole_length_units == OSKAR_WAVELENGTHS)
dipole_length_m *= (C_0 / frequency_hz);
/* Compute modified theta and phi coordinates for dipole X. */
oskar_convert_enu_directions_to_theta_phi(offset_points, num_points,
x, y, z, (M_PI/2) - orientation_x, theta, phi, status);
/* Check if element type is isotropic. */
if (element_type == OSKAR_ELEMENT_TYPE_ISOTROPIC)
oskar_mem_set_value_real(output, 1.0, offset_out, num_points, status);
/* Evaluate polarised response if output array is matrix type. */
if (oskar_mem_is_matrix(output))
{
const int offset_out_real = offset_out * 8;
const int offset_out_cplx = offset_out * 4;
if (oskar_element_has_x_spherical_wave_data(model, id))
oskar_evaluate_spherical_wave_sum(num_points, theta, phi,
model->x_lmax[id], model->x_te[id], model->x_tm[id],
4, offset_out_cplx + 0, output, status);
else if (oskar_element_has_x_spline_data(model, id))
{
oskar_splines_evaluate(model->x_h_re[id], num_points, theta, phi,
8, offset_out_real + 0, output, status);
oskar_splines_evaluate(model->x_h_im[id], num_points, theta, phi,
8, offset_out_real + 1, output, status);
oskar_splines_evaluate(model->x_v_re[id], num_points, theta, phi,
8, offset_out_real + 2, output, status);
oskar_splines_evaluate(model->x_v_im[id], num_points, theta, phi,
8, offset_out_real + 3, output, status);
oskar_convert_ludwig3_to_theta_phi_components(num_points, phi,
4, offset_out_cplx + 0, output, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
oskar_evaluate_dipole_pattern(num_points, theta, phi,
frequency_hz, dipole_length_m,
4, offset_out_cplx + 0, output, status);
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
oskar_evaluate_geometric_dipole_pattern(num_points, theta, phi,
4, offset_out_cplx + 0, output, status);
/* Compute modified theta and phi coordinates for dipole Y. */
oskar_convert_enu_directions_to_theta_phi(offset_points, num_points,
x, y, z, (M_PI/2) - orientation_y, theta, phi, status);
if (oskar_element_has_y_spherical_wave_data(model, id))
oskar_evaluate_spherical_wave_sum(num_points, theta, phi,
model->y_lmax[id], model->y_te[id], model->y_tm[id],
4, offset_out_cplx + 2, output, status);
else if (oskar_element_has_y_spline_data(model, id))
{
oskar_splines_evaluate(model->y_h_re[id], num_points, theta, phi,
8, offset_out_real + 4, output, status);
oskar_splines_evaluate(model->y_h_im[id], num_points, theta, phi,
8, offset_out_real + 5, output, status);
oskar_splines_evaluate(model->y_v_re[id], num_points, theta, phi,
8, offset_out_real + 6, output, status);
oskar_splines_evaluate(model->y_v_im[id], num_points, theta, phi,
8, offset_out_real + 7, output, status);
oskar_convert_ludwig3_to_theta_phi_components(num_points, phi,
4, offset_out_cplx + 2, output, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
oskar_evaluate_dipole_pattern(num_points, theta, phi,
frequency_hz, dipole_length_m,
4, offset_out_cplx + 2, output, status);
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
oskar_evaluate_geometric_dipole_pattern(num_points, theta, phi,
4, offset_out_cplx + 2, output, status);
}
else /* Scalar response. */
{
const int offset_out_real = offset_out * 2;
if (oskar_element_has_scalar_spline_data(model, id))
{
oskar_splines_evaluate(model->scalar_re[id], num_points, theta, phi,
2, offset_out_real + 0, output, status);
oskar_splines_evaluate(model->scalar_im[id], num_points, theta, phi,
2, offset_out_real + 1, output, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
oskar_evaluate_dipole_pattern(num_points, theta, phi,
frequency_hz, dipole_length_m,
1, offset_out, output, status);
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
oskar_evaluate_geometric_dipole_pattern(num_points, theta, phi,
1, offset_out, output, status);
}
/* Apply element tapering, if specified. */
if (taper_type == OSKAR_ELEMENT_TAPER_COSINE)
oskar_apply_element_taper_cosine(num_points,
model->cosine_power, theta, offset_out, output, status);
else if (taper_type == OSKAR_ELEMENT_TAPER_GAUSSIAN)
oskar_apply_element_taper_gaussian(num_points,
model->gaussian_fwhm_rad, theta, offset_out, output, status);
}
void oskar_imager_read_coords_vis(oskar_Imager* h, const char* filename,
int i_file, int num_files, int* percent_done, int* percent_next,
int* status)
{
oskar_Binary* vis_file;
oskar_VisHeader* header;
oskar_Mem *uu, *vv, *ww, *weight, *time_centroid, *time_slice;
int coord_prec, max_times_per_block, tags_per_block, i_block, num_blocks;
int num_times_total, num_stations, num_baselines, num_pols;
double time_start_mjd, time_inc_sec;
if (*status) return;
/* Read the header. */
vis_file = oskar_binary_create(filename, 'r', status);
header = oskar_vis_header_read(vis_file, status);
if (*status)
{
oskar_vis_header_free(header, status);
oskar_binary_free(vis_file);
return;
}
coord_prec = oskar_vis_header_coord_precision(header);
max_times_per_block = oskar_vis_header_max_times_per_block(header);
tags_per_block = oskar_vis_header_num_tags_per_block(header);
num_times_total = oskar_vis_header_num_times_total(header);
num_stations = oskar_vis_header_num_stations(header);
num_baselines = num_stations * (num_stations - 1) / 2;
num_pols = oskar_type_is_matrix(oskar_vis_header_amp_type(header)) ? 4 : 1;
num_blocks = (num_times_total + max_times_per_block - 1) /
max_times_per_block;
time_start_mjd = oskar_vis_header_time_start_mjd_utc(header) * 86400.0;
time_inc_sec = oskar_vis_header_time_inc_sec(header);
/* Set visibility meta-data. */
oskar_imager_set_vis_frequency(h,
oskar_vis_header_freq_start_hz(header),
oskar_vis_header_freq_inc_hz(header),
oskar_vis_header_num_channels_total(header));
oskar_imager_set_vis_phase_centre(h,
oskar_vis_header_phase_centre_ra_deg(header),
oskar_vis_header_phase_centre_dec_deg(header));
/* Create scratch arrays. Weights are all 1. */
uu = oskar_mem_create(coord_prec, OSKAR_CPU, 0, status);
vv = oskar_mem_create(coord_prec, OSKAR_CPU, 0, status);
ww = oskar_mem_create(coord_prec, OSKAR_CPU, 0, status);
time_centroid = oskar_mem_create(OSKAR_DOUBLE,
OSKAR_CPU, num_baselines * max_times_per_block, status);
time_slice = oskar_mem_create_alias(0, 0, 0, status);
weight = oskar_mem_create(h->imager_prec,
OSKAR_CPU, num_baselines * num_pols * max_times_per_block, status);
oskar_mem_set_value_real(weight, 1.0, 0, 0, status);
/* Loop over visibility blocks. */
for (i_block = 0; i_block < num_blocks; ++i_block)
{
int t, num_times, num_channels, start_time, start_chan, end_chan;
int dim_start_and_size[6];
size_t num_rows;
if (*status) break;
/* Read block metadata. */
oskar_timer_resume(h->tmr_read);
oskar_binary_set_query_search_start(vis_file,
i_block * tags_per_block, status);
oskar_binary_read(vis_file, OSKAR_INT,
OSKAR_TAG_GROUP_VIS_BLOCK,
OSKAR_VIS_BLOCK_TAG_DIM_START_AND_SIZE, i_block,
sizeof(dim_start_and_size), dim_start_and_size, status);
start_time = dim_start_and_size[0];
start_chan = dim_start_and_size[1];
num_times = dim_start_and_size[2];
num_channels = dim_start_and_size[3];
num_rows = num_times * num_baselines;
end_chan = start_chan + num_channels - 1;
/* Fill in the time centroid values. */
for (t = 0; t < num_times; ++t)
{
oskar_mem_set_alias(time_slice, time_centroid,
t * num_baselines, num_baselines, status);
oskar_mem_set_value_real(time_slice,
time_start_mjd + (start_time + t + 0.5) * time_inc_sec,
0, num_baselines, status);
}
/* Read the baseline coordinates. */
oskar_binary_read_mem(vis_file, uu, OSKAR_TAG_GROUP_VIS_BLOCK,
OSKAR_VIS_BLOCK_TAG_BASELINE_UU, i_block, status);
oskar_binary_read_mem(vis_file, vv, OSKAR_TAG_GROUP_VIS_BLOCK,
OSKAR_VIS_BLOCK_TAG_BASELINE_VV, i_block, status);
oskar_binary_read_mem(vis_file, ww, OSKAR_TAG_GROUP_VIS_BLOCK,
OSKAR_VIS_BLOCK_TAG_BASELINE_WW, i_block, status);
/* Update the imager with the data. */
oskar_timer_pause(h->tmr_read);
oskar_imager_update(h, num_rows, start_chan, end_chan, num_pols,
uu, vv, ww, 0, weight, time_centroid, status);
*percent_done = (int) round(100.0 * (
(i_block + 1) / (double)(num_blocks * num_files) +
i_file / (double)num_files));
if (h->log && percent_next && *percent_done >= *percent_next)
{
oskar_log_message(h->log, 'S', -2, "%3d%% ...", *percent_done);
*percent_next = 10 + 10 * (*percent_done / 10);
}
}
oskar_mem_free(uu, status);
oskar_mem_free(vv, status);
oskar_mem_free(ww, status);
oskar_mem_free(weight, status);
oskar_mem_free(time_centroid, status);
oskar_mem_free(time_slice, status);
oskar_vis_header_free(header, status);
oskar_binary_free(vis_file);
}
void oskar_element_evaluate(const oskar_Element* model, oskar_Mem* output,
double orientation_x, double orientation_y, int num_points,
const oskar_Mem* x, const oskar_Mem* y, const oskar_Mem* z,
double frequency_hz, oskar_Mem* theta, oskar_Mem* phi, int* status)
{
int element_type, taper_type, freq_id;
double dipole_length_m;
/* Check if safe to proceed. */
if (*status) return;
/* Check that the output array is complex. */
if (!oskar_mem_is_complex(output))
{
*status = OSKAR_ERR_BAD_DATA_TYPE;
return;
}
/* Resize output array if required. */
if ((int)oskar_mem_length(output) < num_points)
oskar_mem_realloc(output, num_points, status);
/* Get the element model properties. */
element_type = model->element_type;
taper_type = model->taper_type;
dipole_length_m = model->dipole_length;
if (model->dipole_length_units == OSKAR_WAVELENGTHS)
dipole_length_m *= (C_0 / frequency_hz);
/* Check if element type is isotropic. */
if (element_type == OSKAR_ELEMENT_TYPE_ISOTROPIC)
oskar_mem_set_value_real(output, 1.0, 0, 0, status);
/* Ensure there is enough space in the theta and phi work arrays. */
if ((int)oskar_mem_length(theta) < num_points)
oskar_mem_realloc(theta, num_points, status);
if ((int)oskar_mem_length(phi) < num_points)
oskar_mem_realloc(phi, num_points, status);
/* Compute modified theta and phi coordinates for dipole X. */
oskar_convert_enu_directions_to_theta_phi(num_points, x, y, z,
M_PI_2 - orientation_x, theta, phi, status);
/* Evaluate polarised response if output array is matrix type. */
if (oskar_mem_is_matrix(output))
{
/* Check if spline data present for dipole X. */
if (oskar_element_has_x_spline_data(model))
{
/* Get the frequency index. */
freq_id = oskar_find_closest_match_d(frequency_hz,
oskar_element_num_freq(model),
oskar_element_freqs_hz_const(model));
/* Evaluate spline pattern for dipole X. */
oskar_splines_evaluate(output, 0, 8, model->x_h_re[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 1, 8, model->x_h_im[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 2, 8, model->x_v_re[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 3, 8, model->x_v_im[freq_id],
num_points, theta, phi, status);
/* Convert from Ludwig-3 to spherical representation. */
oskar_convert_ludwig3_to_theta_phi_components(output, 0, 4,
num_points, phi, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
{
/* Evaluate dipole pattern for dipole X. */
oskar_evaluate_dipole_pattern(output, num_points, theta, phi,
frequency_hz, dipole_length_m, 0, 4, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
{
/* Evaluate dipole pattern for dipole X. */
oskar_evaluate_geometric_dipole_pattern(output, num_points,
theta, phi, 0, 4, status);
}
/* Compute modified theta and phi coordinates for dipole Y. */
oskar_convert_enu_directions_to_theta_phi(num_points, x, y, z,
M_PI_2 - orientation_y, theta, phi, status);
/* Check if spline data present for dipole Y. */
if (oskar_element_has_y_spline_data(model))
{
/* Get the frequency index. */
freq_id = oskar_find_closest_match_d(frequency_hz,
oskar_element_num_freq(model),
oskar_element_freqs_hz_const(model));
/* Evaluate spline pattern for dipole Y. */
oskar_splines_evaluate(output, 4, 8, model->y_h_re[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 5, 8, model->y_h_im[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 6, 8, model->y_v_re[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 7, 8, model->y_v_im[freq_id],
num_points, theta, phi, status);
/* Convert from Ludwig-3 to spherical representation. */
oskar_convert_ludwig3_to_theta_phi_components(output, 2, 4,
num_points, phi, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
{
/* Evaluate dipole pattern for dipole Y. */
oskar_evaluate_dipole_pattern(output, num_points, theta, phi,
frequency_hz, dipole_length_m, 2, 4, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
{
/* Evaluate dipole pattern for dipole Y. */
oskar_evaluate_geometric_dipole_pattern(output, num_points,
theta, phi, 2, 4, status);
}
}
/* Scalar response. */
else
{
/* Check if scalar spline data present. */
if (oskar_element_has_scalar_spline_data(model))
{
/* Get the frequency index. */
freq_id = oskar_find_closest_match_d(frequency_hz,
oskar_element_num_freq(model),
oskar_element_freqs_hz_const(model));
oskar_splines_evaluate(output, 0, 2, model->scalar_re[freq_id],
num_points, theta, phi, status);
oskar_splines_evaluate(output, 1, 2, model->scalar_im[freq_id],
num_points, theta, phi, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_DIPOLE)
{
oskar_evaluate_dipole_pattern(output, num_points, theta, phi,
frequency_hz, dipole_length_m, 0, 1, status);
}
else if (element_type == OSKAR_ELEMENT_TYPE_GEOMETRIC_DIPOLE)
{
oskar_evaluate_geometric_dipole_pattern(output, num_points,
theta, phi, 0, 1, status);
}
}
/* Apply element tapering, if specified. */
if (taper_type == OSKAR_ELEMENT_TAPER_COSINE)
{
oskar_apply_element_taper_cosine(output, num_points,
model->cosine_power, theta, status);
}
else if (taper_type == OSKAR_ELEMENT_TAPER_GAUSSIAN)
{
oskar_apply_element_taper_gaussian(output, num_points,
model->gaussian_fwhm_rad, theta, status);
}
}
TEST(imager, grid_sum)
{
int status = 0, type = OSKAR_DOUBLE;
int size = 2048, grid_size = size * size;
// Create and set up the imager.
oskar_Imager* im = oskar_imager_create(type, &status);
oskar_imager_set_grid_kernel(im, "pillbox", 1, 1, &status);
oskar_imager_set_fov(im, 5.0);
oskar_imager_set_size(im, size, &status);
oskar_Mem* grid = oskar_mem_create(type | OSKAR_COMPLEX, OSKAR_CPU,
grid_size, &status);
ASSERT_EQ(0, status);
// Create visibility data.
int num_vis = 10000;
oskar_Mem* uu = oskar_mem_create(type, OSKAR_CPU, num_vis, &status);
oskar_Mem* vv = oskar_mem_create(type, OSKAR_CPU, num_vis, &status);
oskar_Mem* ww = oskar_mem_create(type, OSKAR_CPU, num_vis, &status);
oskar_Mem* vis = oskar_mem_create(type | OSKAR_COMPLEX, OSKAR_CPU, num_vis,
&status);
oskar_Mem* weight = oskar_mem_create(type, OSKAR_CPU, num_vis, &status);
oskar_mem_random_gaussian(uu, 0, 1, 2, 3, 100.0, &status);
oskar_mem_random_gaussian(vv, 4, 5, 6, 7, 100.0, &status);
oskar_mem_set_value_real(vis, 1.0, 0, num_vis, &status);
oskar_mem_set_value_real(weight, 1.0, 0, num_vis, &status);
// Grid visibility data.
double plane_norm = 0.0;
oskar_imager_update_plane(im, num_vis, uu, vv, ww, vis, weight, grid,
&plane_norm, 0, &status);
ASSERT_DOUBLE_EQ((double)num_vis, plane_norm);
// Sum the grid.
double2* t = oskar_mem_double2(grid, &status);
double sum = 0.0;
for (int i = 0; i < grid_size; i++) sum += t[i].x;
ASSERT_DOUBLE_EQ((double)num_vis, sum);
// Finalise the image.
oskar_imager_finalise_plane(im, grid, plane_norm, &status);
ASSERT_EQ(0, status);
#ifdef WRITE_FITS
// Get the real part only.
if (oskar_mem_precision(grid) == OSKAR_DOUBLE)
{
double *t = oskar_mem_double(grid, &status);
for (int j = 0; j < grid_size; ++j) t[j] = t[2 * j];
}
else
{
float *t = oskar_mem_float(grid, &status);
for (int j = 0; j < grid_size; ++j) t[j] = t[2 * j];
}
// Save the real part.
fitsfile* f;
long naxes[2] = {size, size}, firstpix[2] = {1, 1};
fits_create_file(&f, "test_imager_grid_sum.fits", &status);
fits_create_img(f, (type == OSKAR_DOUBLE ? DOUBLE_IMG : FLOAT_IMG),
2, naxes, &status);
fits_write_pix(f, (type == OSKAR_DOUBLE ? TDOUBLE : TFLOAT),
firstpix, grid_size, oskar_mem_void(grid), &status);
fits_close_file(f, &status);
#endif
// Clean up.
oskar_imager_free(im, &status);
oskar_mem_free(uu, &status);
oskar_mem_free(vv, &status);
oskar_mem_free(ww, &status);
oskar_mem_free(vis, &status);
oskar_mem_free(weight, &status);
oskar_mem_free(grid, &status);
}
void oskar_evaluate_tec_tid(oskar_Mem* tec, int num_directions,
const oskar_Mem* lon, const oskar_Mem* lat,
const oskar_Mem* rel_path_length, double TEC0,
oskar_SettingsTIDscreen* TID, double gast)
{
int i, j, type;
double pp_lon, pp_lat;
double pp_sec;
double pp_tec;
double amp, w, th, v; /* TID parameters */
double time;
double earth_radius = 6365.0; /* km -- FIXME */
int status = 0;
/* TODO check types, dimensions etc of memory */
type = oskar_mem_type(tec);
oskar_mem_set_value_real(tec, 0.0, 0, 0, &status);
/* Loop over TIDs */
for (i = 0; i < TID->num_components; ++i)
{
amp = TID->amp[i];
/* convert from km to rads */
w = TID->wavelength[i] / (earth_radius + TID->height_km);
th = TID->theta[i] * M_PI/180.;
/* convert from km/h to rad/s */
v = (TID->speed[i]/(earth_radius + TID->height_km)) / 3600;
time = gast * 86400.0; /* days->sec */
/* Loop over directions */
for (j = 0; j < num_directions; ++j)
{
if (type == OSKAR_DOUBLE)
{
pp_lon = oskar_mem_double_const(lon, &status)[j];
pp_lat = oskar_mem_double_const(lat, &status)[j];
pp_sec = oskar_mem_double_const(rel_path_length, &status)[j];
pp_tec = pp_sec * amp * TEC0 * (
cos( (2.0*M_PI/w) * (cos(th)*pp_lon - v*time) ) +
cos( (2.0*M_PI/w) * (sin(th)*pp_lat - v*time) )
);
pp_tec += TEC0;
oskar_mem_double(tec, &status)[j] += pp_tec;
}
else
{
pp_lon = (double)oskar_mem_float_const(lon, &status)[j];
pp_lat = (double)oskar_mem_float_const(lat, &status)[j];
pp_sec = (double)oskar_mem_float_const(rel_path_length, &status)[j];
pp_tec = pp_sec * amp * TEC0 * (
cos( (2.0*M_PI/w) * (cos(th)*pp_lon - v*time) ) +
cos( (2.0*M_PI/w) * (sin(th)*pp_lat - v*time) )
);
pp_tec += TEC0;
oskar_mem_float(tec, &status)[j] += (float)pp_tec;
}
} /* loop over directions */
} /* loop over components. */
}
