def test_crosssubtract_datamodel(self): self.actualSetUp(zerow=True) future_vis = rsexecute.scatter(self.vis_list[0]) future_skymodel_list = rsexecute.scatter(self.skymodel_list) skymodel_vislist = predict_skymodel_list_rsexecute_workflow(future_vis, future_skymodel_list, context='2d', docal=True) skymodel_vislist = rsexecute.compute(skymodel_vislist, sync=True) vobs = sum_predict_results(skymodel_vislist) future_vobs = rsexecute.scatter(vobs) skymodel_vislist = crosssubtract_datamodels_skymodel_list_rsexecute_workflow(future_vobs, skymodel_vislist) skymodel_vislist = rsexecute.compute(skymodel_vislist, sync=True) result_skymodel = [SkyModel(components=None, image=self.skymodel_list[-1].image) for v in skymodel_vislist] self.vis_list = rsexecute.scatter(self.vis_list) result_skymodel = invert_skymodel_list_rsexecute_workflow(skymodel_vislist, result_skymodel, context='2d', docal=True) results = rsexecute.compute(result_skymodel, sync=True) assert numpy.max(numpy.abs(results[0][0].data)) > 0.0 assert numpy.max(numpy.abs(results[0][1])) > 0.0 if self.plot: import matplotlib.pyplot as plt from rascil.processing_components.image.operations import show_image show_image(results[0][0], title='Dirty image after cross-subtraction', vmax=0.1, vmin=-0.01) plt.show()
def test_mpccal_ICAL_onesource(self): self.actualSetup(nsources=1, nvoronoi=1) model = create_empty_image_like(self.theta_list[0].image) if rsexecute.using_dask: progress = None else: progress = self.progress future_vis = rsexecute.scatter(self.all_skymodel_noniso_vis) future_model = rsexecute.scatter(model) future_theta_list = rsexecute.scatter(self.theta_list) result = mpccal_skymodel_list_rsexecute_workflow(future_vis, future_model, future_theta_list, mpccal_progress=progress, nmajor=5, context='2d', algorithm='hogbom', scales=[0, 3, 10], fractional_threshold=0.15, threshold=0.05, gain=0.1, niter=1000, psf_support=256, deconvolve_facets=8, deconvolve_overlap=16, deconvolve_taper='tukey') (self.theta_list, residual) = rsexecute.compute(result, sync=True) combined_model = calculate_skymodel_equivalent_image(self.theta_list) psf_obs = invert_list_rsexecute_workflow([self.all_skymodel_noniso_vis], [model], context='2d', dopsf=True) result = restore_list_rsexecute_workflow([combined_model], psf_obs, [(residual, 0.0)]) result = rsexecute.compute(result, sync=True) if self.persist: export_image_to_fits(residual, rascil_path('test_results/test_mpccal_ical_onesource_residual.fits')) if self.persist: export_image_to_fits(result[0], rascil_path('test_results/test_mpccal_ical_onesource_restored.fits')) if self.persist: export_image_to_fits(combined_model, rascil_path('test_results/test_mpccal_ical_onesource_deconvolved.fits')) recovered_mpccal_components = find_skycomponents(result[0], fwhm=2, threshold=0.32, npixels=12) def max_flux(elem): return numpy.max(elem.flux) recovered_mpccal_components = sorted(recovered_mpccal_components, key=max_flux, reverse=True) assert recovered_mpccal_components[0].name == 'Segment 0', recovered_mpccal_components[0].name assert numpy.abs(recovered_mpccal_components[0].flux[0, 0] - 1.138095494391862) < 1e-6, \ recovered_mpccal_components[0].flux[0, 0] newscreen = create_empty_image_like(self.screen) gaintables = [th.gaintable for th in self.theta_list] newscreen, weights = grid_gaintable_to_screen(self.all_skymodel_noniso_blockvis, gaintables, newscreen) if self.persist: export_image_to_fits(newscreen, rascil_path('test_results/test_mpccal_ical_onesource_screen.fits')) if self.persist: export_image_to_fits(weights, rascil_path('test_results/test_mpccal_ical_onesource_screenweights.fits')) rsexecute.close()
def test_predict(self): self.actualSetUp(zerow=True) self.skymodel_list = [ rsexecute.execute(create_low_test_skymodel_from_gleam)( npixel=self.npixel, cellsize=self.cellsize, frequency=[self.frequency[f]], phasecentre=self.phasecentre, polarisation_frame=PolarisationFrame("stokesI"), flux_limit=0.3, flux_threshold=1.0, flux_max=5.0) for f, freq in enumerate(self.frequency) ] self.skymodel_list = rsexecute.compute(self.skymodel_list, sync=True) assert isinstance(self.skymodel_list[0].image, Image), self.skymodel_list[0].image assert isinstance(self.skymodel_list[0].components[0], Skycomponent), self.skymodel_list[0].components[0] assert len(self.skymodel_list[0].components) == 25, len( self.skymodel_list[0].components) assert numpy.max(numpy.abs( self.skymodel_list[0].image.data)) > 0.0, "Image is empty" self.skymodel_list = rsexecute.scatter(self.skymodel_list) skymodel_vislist = predict_skymodel_list_rsexecute_workflow( self.vis_list[0], self.skymodel_list, context='2d') skymodel_vislist = rsexecute.compute(skymodel_vislist, sync=True) assert numpy.max(numpy.abs(skymodel_vislist[0].vis)) > 0.0
def test_predictcal(self): self.actualSetUp(zerow=True) future_vis = rsexecute.scatter(self.vis_list[0]) future_skymodel = rsexecute.scatter(self.skymodel_list) skymodel_vislist = predict_skymodel_list_rsexecute_workflow(future_vis, future_skymodel, context='2d', docal=True) skymodel_vislist = rsexecute.compute(skymodel_vislist, sync=True) vobs = sum_predict_results(skymodel_vislist) if self.plot: def plotvis(i, v): import matplotlib.pyplot as plt uvr = numpy.hypot(v.u, v.v) amp = numpy.abs(v.vis[:, 0]) plt.plot(uvr, amp, '.') plt.title(str(i)) plt.show() plotvis(0, vobs)
def actualSetUp(self, add_errors=False, nfreqwin=7, dospectral=True, dopol=False, zerow=True): self.npixel = 512 self.low = create_named_configuration('LOWBD2', rmax=750.0) self.freqwin = nfreqwin self.vis_list = list() self.ntimes = 5 self.times = numpy.linspace(-3.0, +3.0, self.ntimes) * numpy.pi / 12.0 self.frequency = numpy.linspace(0.8e8, 1.2e8, self.freqwin) if self.freqwin > 1: self.channelwidth = numpy.array( self.freqwin * [self.frequency[1] - self.frequency[0]]) else: self.channelwidth = numpy.array([1e6]) if dopol: self.vis_pol = PolarisationFrame('linear') self.image_pol = PolarisationFrame('stokesIQUV') f = numpy.array([100.0, 20.0, 0.0, 0.0]) else: self.vis_pol = PolarisationFrame('stokesI') self.image_pol = PolarisationFrame('stokesI') f = numpy.array([100.0]) if dospectral: flux = numpy.array( [f * numpy.power(freq / 1e8, -0.7) for freq in self.frequency]) else: flux = numpy.array([f]) self.phasecentre = SkyCoord(ra=+180.0 * u.deg, dec=-60.0 * u.deg, frame='icrs', equinox='J2000') self.blockvis_list = \ [rsexecute.execute(ingest_unittest_visibility, nout=1)(self.low, [self.frequency[i]], [self.channelwidth[i]], self.times, self.vis_pol, self.phasecentre, block=True, zerow=zerow) for i in range(nfreqwin)] self.blockvis_list = rsexecute.compute(self.blockvis_list, sync=True) self.blockvis_list = rsexecute.scatter(self.blockvis_list) self.vis_list = [ rsexecute.execute(convert_blockvisibility_to_visibility, nout=1)(bv) for bv in self.blockvis_list ] self.vis_list = rsexecute.compute(self.vis_list, sync=True) self.vis_list = rsexecute.scatter(self.vis_list) self.model_imagelist = [ rsexecute.execute(create_unittest_model, nout=1)(self.vis_list[i], self.image_pol, npixel=self.npixel, cellsize=0.0005) for i in range(nfreqwin) ] self.model_imagelist = rsexecute.compute(self.model_imagelist, sync=True) self.model_imagelist = rsexecute.scatter(self.model_imagelist) self.components_list = [ rsexecute.execute(create_unittest_components)( self.model_imagelist[freqwin], flux[freqwin, :][numpy.newaxis, :]) for freqwin, m in enumerate(self.model_imagelist) ] self.components_list = rsexecute.compute(self.components_list, sync=True) self.components_list = rsexecute.scatter(self.components_list) self.blockvis_list = [ rsexecute.execute(dft_skycomponent_visibility)( self.blockvis_list[freqwin], self.components_list[freqwin]) for freqwin, _ in enumerate(self.blockvis_list) ] self.blockvis_list = rsexecute.compute(self.blockvis_list, sync=True) self.vis = self.blockvis_list[0] self.blockvis_list = rsexecute.scatter(self.blockvis_list) self.model_imagelist = [ rsexecute.execute(insert_skycomponent, nout=1)(self.model_imagelist[freqwin], self.components_list[freqwin]) for freqwin in range(nfreqwin) ] self.model_imagelist = rsexecute.compute(self.model_imagelist, sync=True) model = self.model_imagelist[0] self.cmodel = smooth_image(model) if self.persist: export_image_to_fits( model, '%s/test_pipelines_rsexecute_model.fits' % self.dir) export_image_to_fits( self.cmodel, '%s/test_pipelines_rsexecute_cmodel.fits' % self.dir) if add_errors: gt = create_gaintable_from_blockvisibility(self.vis) gt = simulate_gaintable(gt, phase_error=0.1, amplitude_error=0.0, smooth_channels=1, leakage=0.0) self.blockvis_list = [ rsexecute.execute(apply_gaintable, nout=1)(self.blockvis_list[i], gt) for i in range(self.freqwin) ] self.blockvis_list = rsexecute.compute(self.blockvis_list, sync=True) self.blockvis_list = rsexecute.scatter(self.blockvis_list) self.vis_list = [ rsexecute.execute(convert_blockvisibility_to_visibility)(bv) for bv in self.blockvis_list ] self.vis_list = rsexecute.compute(self.vis_list, sync=True) self.vis_list = rsexecute.scatter(self.vis_list) self.model_imagelist = [ rsexecute.execute(create_unittest_model, nout=1)(self.vis_list[i], self.image_pol, npixel=self.npixel, cellsize=0.0005) for i in range(nfreqwin) ] self.model_imagelist = rsexecute.compute(self.model_imagelist, sync=True) self.model_imagelist = rsexecute.scatter(self.model_imagelist)
print(" Using %s Dask workers" % nworkers) # Uniform weighting psf_list = [ rsexecute.execute(create_image_from_visibility)( v, npixel=npixel, frequency=frequency, nchan=nfreqwin, cellsize=cellsize, phasecentre=phasecentre, polarisation_frame=PolarisationFrame("stokesI")) for v in future_bvis_list ] psf_list = rsexecute.compute(psf_list, sync=True) future_psf_list = rsexecute.scatter(psf_list) del psf_list if use_natural: print("Using natural weighting") else: print("Using uniform weighting") vis_list = [ rsexecute.execute(convert_blockvisibility_to_visibility)(bvis) for bvis in future_bvis_list ] vis_list = weight_list_rsexecute_workflow(vis_list, future_psf_list) bvis_list = [ rsexecute.execute(convert_visibility_to_blockvisibility)(vis) for vis in vis_list
def actualSetup(self, nsources=None, nvoronoi=None): # Set up the observation: 10 minutes at transit, with 10s integration. # Skip 5/6 points to avoid outstation redundancy nfreqwin = 1 ntimes = 3 self.rmax = 2500.0 dec = -40.0 * u.deg frequency = [1e8] channel_bandwidth = [0.1e8] times = numpy.linspace(-10.0, 10.0, ntimes) * numpy.pi / (3600.0 * 12.0) phasecentre = SkyCoord(ra=+0.0 * u.deg, dec=dec, frame='icrs', equinox='J2000') low = create_named_configuration('LOWBD2', rmax=self.rmax) centre = numpy.mean(low.xyz, axis=0) distance = numpy.hypot(low.xyz[:, 0] - centre[0], low.xyz[:, 1] - centre[1], low.xyz[:, 2] - centre[2]) lowouter = low.data[distance > 1000.0][::6] lowcore = low.data[distance < 1000.0][::3] low.data = numpy.hstack((lowcore, lowouter)) blockvis = create_blockvisibility(low, times, frequency=frequency, channel_bandwidth=channel_bandwidth, weight=1.0, phasecentre=phasecentre, polarisation_frame=PolarisationFrame("stokesI"), zerow=True) vis = convert_blockvisibility_to_visibility(blockvis) advice = advise_wide_field(vis, guard_band_image=2.0, delA=0.02) cellsize = advice['cellsize'] npixel = 512 small_model = create_image_from_visibility( blockvis, npixel=512, frequency=frequency, nchan=nfreqwin, cellsize=cellsize, phasecentre=phasecentre) vis.data['imaging_weight'][...] = vis.data['weight'][...] vis = weight_list_serial_workflow([vis], [small_model])[0] vis = taper_list_serial_workflow([vis], 3 * cellsize)[0] blockvis = convert_visibility_to_blockvisibility(vis) # ### Generate the model from the GLEAM catalog, including application of the primary beam. beam = create_image_from_visibility(blockvis, npixel=npixel, frequency=frequency, nchan=nfreqwin, cellsize=cellsize, phasecentre=phasecentre) beam = create_low_test_beam(beam, use_local=False) flux_limit = 0.5 original_gleam_components = create_low_test_skycomponents_from_gleam(flux_limit=flux_limit, phasecentre=phasecentre, frequency=frequency, polarisation_frame=PolarisationFrame( 'stokesI'), radius=0.15) all_components = apply_beam_to_skycomponent(original_gleam_components, beam) all_components = filter_skycomponents_by_flux(all_components, flux_min=flux_limit) voronoi_components = filter_skycomponents_by_flux(all_components, flux_min=1.5) def max_flux(elem): return numpy.max(elem.flux) voronoi_components = sorted(voronoi_components, key=max_flux, reverse=True) if nsources is not None: all_components = [all_components[0]] if nvoronoi is not None: voronoi_components = [voronoi_components[0]] self.screen = import_image_from_fits(rascil_data_path('models/test_mpc_screen.fits')) all_gaintables = create_gaintable_from_screen(blockvis, all_components, self.screen) gleam_skymodel_noniso = [SkyModel(components=[all_components[i]], gaintable=all_gaintables[i]) for i, sm in enumerate(all_components)] # ### Now predict the visibility for each skymodel and apply the gaintable for that skymodel, # returning a list of visibilities, one for each skymodel. We then sum these to obtain # the total predicted visibility. All images and skycomponents in the same skymodel # get the same gaintable applied which means that in this case each skycomponent has a separate gaintable. self.all_skymodel_noniso_vis = convert_blockvisibility_to_visibility(blockvis) ngroup = 8 future_vis = rsexecute.scatter(self.all_skymodel_noniso_vis) chunks = [gleam_skymodel_noniso[i:i + ngroup] for i in range(0, len(gleam_skymodel_noniso), ngroup)] for chunk in chunks: result = predict_skymodel_list_rsexecute_workflow(future_vis, chunk, context='2d', docal=True) work_vis = rsexecute.compute(result, sync=True) for w in work_vis: self.all_skymodel_noniso_vis.data['vis'] += w.data['vis'] assert numpy.max(numpy.abs(self.all_skymodel_noniso_vis.data['vis'])) > 0.0 self.all_skymodel_noniso_blockvis = convert_visibility_to_blockvisibility(self.all_skymodel_noniso_vis) # ### Remove weaker of components that are too close (0.02 rad) idx, voronoi_components = remove_neighbouring_components(voronoi_components, 0.02) model = create_image_from_visibility(blockvis, npixel=npixel, frequency=frequency, nchan=nfreqwin, cellsize=cellsize, phasecentre=phasecentre) # Use the gaintable for the brightest component as the starting gaintable all_gaintables[0].gain[...] = numpy.conjugate(all_gaintables[0].gain[...]) all_gaintables[0].gain[...] = 1.0 + 0.0j self.theta_list = initialize_skymodel_voronoi(model, voronoi_components, all_gaintables[0])
def actualSetUp(self, add_errors=False, freqwin=7, block=False, dospectral=True, dopol=False, zerow=True): self.npixel = 256 self.low = create_named_configuration('LOWBD2', rmax=750.0) self.freqwin = freqwin self.vis_list = list() self.ntimes = 5 cellsize = 0.001 self.times = numpy.linspace(-3.0, +3.0, self.ntimes) * numpy.pi / 12.0 self.frequency = numpy.linspace(0.8e8, 1.2e8, self.freqwin) if freqwin > 1: self.channelwidth = numpy.array(freqwin * [self.frequency[1] - self.frequency[0]]) else: self.channelwidth = numpy.array([1e6]) if dopol: self.vis_pol = PolarisationFrame('linear') self.image_pol = PolarisationFrame('stokesIQUV') f = numpy.array([100.0, 20.0, -10.0, 1.0]) else: self.vis_pol = PolarisationFrame('stokesI') self.image_pol = PolarisationFrame('stokesI') f = numpy.array([100.0]) if dospectral: flux = numpy.array([f * numpy.power(freq / 1e8, -0.7) for freq in self.frequency]) else: flux = numpy.array([f]) self.phasecentre = SkyCoord(ra=+180.0 * u.deg, dec=-60.0 * u.deg, frame='icrs', equinox='J2000') self.vis_list = [rsexecute.execute(ingest_unittest_visibility)(self.low, [self.frequency[freqwin]], [self.channelwidth[freqwin]], self.times, self.vis_pol, self.phasecentre, block=block, zerow=zerow) for freqwin, _ in enumerate(self.frequency)] self.model_imagelist = [rsexecute.execute(create_unittest_model, nout=freqwin)(self.vis_list[freqwin], self.image_pol, cellsize=cellsize, npixel=self.npixel) for freqwin, _ in enumerate(self.frequency)] self.componentlist = [rsexecute.execute(create_unittest_components)(self.model_imagelist[freqwin], flux[freqwin, :][numpy.newaxis, :]) for freqwin, _ in enumerate(self.frequency)] self.model_imagelist = [rsexecute.execute(insert_skycomponent, nout=1)(self.model_imagelist[freqwin], self.componentlist[freqwin]) for freqwin, _ in enumerate(self.frequency)] self.vis_list = [rsexecute.execute(predict_skycomponent_visibility)(self.vis_list[freqwin], self.componentlist[freqwin]) for freqwin, _ in enumerate(self.frequency)] # Calculate the model convolved with a Gaussian. self.model_imagelist = rsexecute.compute(self.model_imagelist, sync=True) model = self.model_imagelist[0] self.cmodel = smooth_image(model) if self.persist: export_image_to_fits(model, '%s/test_imaging_rsexecute_deconvolved_model.fits' % self.dir) if self.persist: export_image_to_fits(self.cmodel, '%s/test_imaging_rsexecute_deconvolved_cmodel.fits' % self.dir) if add_errors and block: self.vis_list = [rsexecute.execute(insert_unittest_errors)(self.vis_list[i]) for i, _ in enumerate(self.frequency)] # self.vis_list = rsexecute.compute(self.vis_list, sync=True) self.vis_list = rsexecute.persist(self.vis_list) self.model_imagelist = rsexecute.scatter(self.model_imagelist)
def trial_case(results, seed=180555, context='wstack', nworkers=8, threads_per_worker=1, memory=8, processes=True, order='frequency', nfreqwin=7, ntimes=3, rmax=750.0, facets=1, wprojection_planes=1, use_dask=True, use_serial_imaging=True, flux_limit=0.3, nmajor=5, dft_threshold=1.0, use_serial_clean=True, write_fits=False): """ Single trial for performance-timings Simulates visibilities from GLEAM including phase errors Makes dirty image and PSF Runs ICAL pipeline The results are in a dictionary: 'context': input - a string describing concisely the purpose of the test 'time overall', overall execution time (s) 'time predict', time to execute GLEAM prediction graph 'time invert', time to make dirty image 'time invert graph', time to make dirty image graph 'time ICAL graph', time to create ICAL graph 'time ICAL', time to execute ICAL graph 'context', type of imaging e.g. 'wstack' 'nworkers', number of workers to create 'threads_per_worker', 'nnodes', Number of nodes, 'processes', 'order', Ordering of data_models 'nfreqwin', Number of frequency windows in simulation 'ntimes', Number of hour angles in simulation 'rmax', Maximum radius of stations used in simulation (m) 'facets', Number of facets in deconvolution and imaging 'wprojection_planes', Number of wprojection planes 'vis_slices', Number of visibility slices (per Visibbility) 'npixel', Number of pixels in image 'cellsize', Cellsize in radians 'seed', Random number seed 'dirty_max', Maximum in dirty image 'dirty_min', Minimum in dirty image 'restored_max', 'restored_min', 'deconvolved_max', 'deconvolved_min', 'residual_max', 'residual_min', 'git_info', GIT hash (not definitive since local mods are possible) :param results: Initial state :param seed: Random number seed (used in gain simulations) :param context: imaging context :param context: Type of context: '2d'|'timeslice'|'wstack' :param nworkers: Number of dask workers to use :param threads_per_worker: Number of threads per worker :param processes: Use processes instead of threads 'processes'|'threads' :param order: See simulate_list_list_rsexecute_workflow_workflowkflow :param nfreqwin: See simulate_list_list_rsexecute_workflow_workflowkflow :param ntimes: See simulate_list_list_rsexecute_workflow_workflowkflow :param rmax: See simulate_list_list_rsexecute_workflow_workflowkflow :param facets: Number of facets to use :param wprojection_planes: Number of wprojection planes to use :param use_dask: Use dask or immediate evaluation :return: results dictionary """ if use_dask: scheduler = os.getenv('RASCIL_DASK_SCHEDULER', None) if scheduler is not None: client = get_dask_client(n_workers=nworkers, memory_limit=memory * 1024 * 1024 * 1024, threads_per_worker=threads_per_worker) rsexecute.set_client(client=client) else: rsexecute.set_client(threads_per_worker=threads_per_worker, processes=threads_per_worker == 1, memory_limit=memory * 1024 * 1024 * 1024, n_workers=nworkers) print("Defined %d workers" % (nworkers)) else: rsexecute.set_client(use_dask=use_dask) results['nnodes'] = 1 def init_logging(): logging.basicConfig( filename='pipelines_rsexecute_timings.log', filemode='w', format='%(asctime)s,%(msecs)d %(name)s %(levelname)s %(message)s', datefmt='%H:%M:%S', level=logging.INFO) init_logging() log = logging.getLogger() # Initialise logging on the workers. This appears to only work using the process scheduler. rsexecute.run(init_logging) def lprint(*args): log.info(*args) print(*args) lprint("Starting pipelines_rsexecute_timings") numpy.random.seed(seed) results['seed'] = seed start_all = time.time() results['context'] = context results['hostname'] = socket.gethostname() results['git_hash'] = git_hash() results['epoch'] = time.strftime("%Y-%m-%d %H:%M:%S") lprint("Context is %s" % context) results['nworkers'] = nworkers results['threads_per_worker'] = threads_per_worker results['processes'] = processes results['memory'] = memory results['order'] = order results['nfreqwin'] = nfreqwin results['ntimes'] = ntimes results['rmax'] = rmax results['facets'] = facets results['wprojection_planes'] = wprojection_planes results['dft threshold'] = dft_threshold results['use_dask'] = use_dask lprint("At start, configuration is:") lprint(sort_dict(results)) # Parameters determining scale of simulation. frequency = numpy.linspace(1.0e8, 1.2e8, nfreqwin) centre = nfreqwin // 2 if nfreqwin > 1: channel_bandwidth = numpy.array(nfreqwin * [frequency[1] - frequency[0]]) else: channel_bandwidth = numpy.array([1e6]) times = numpy.linspace(-numpy.pi / 4.0, numpy.pi / 4.0, ntimes) phasecentre = SkyCoord(ra=+0.0 * u.deg, dec=-40.0 * u.deg, frame='icrs', equinox='J2000') lprint("****** Visibility creation ******") # Create the empty BlockVisibility's and persist these on the cluster tmp_bvis_list = simulate_list_rsexecute_workflow( 'LOWBD2', frequency=frequency, channel_bandwidth=channel_bandwidth, times=times, phasecentre=phasecentre, order=order, format='blockvis', rmax=rmax) tmp_vis_list = [ rsexecute.execute(convert_blockvisibility_to_visibility)(bv) for bv in tmp_bvis_list ] tmp_vis_list = rsexecute.client.compute(tmp_vis_list, sync=True) vis_list = rsexecute.gather(tmp_vis_list) import matplotlib.pyplot as plt plt.clf() plt.hist(vis_list[0].w, bins=100) plt.title('Histogram of w samples: rms=%.1f (wavelengths)' % numpy.std(vis_list[0].w)) plt.xlabel('W (wavelengths)') #plt.show() plt.clf() plt.hist(vis_list[0].uvdist, bins=100) plt.title('Histogram of uvdistance samples') plt.xlabel('UV Distance (wavelengths)') #plt.show() rsexecute.client.cancel(tmp_vis_list) future_vis_list = rsexecute.scatter(vis_list) # Find the best imaging parameters but don't bring the vis_list back here print("****** Finding wide field parameters ******") future_advice = [ rsexecute.execute(advise_wide_field)( v, guard_band_image=6.0, delA=0.1, facets=facets, wprojection_planes=wprojection_planes, oversampling_synthesised_beam=4.0) for v in future_vis_list ] future_advice = rsexecute.compute(future_advice) advice = rsexecute.client.gather(future_advice)[-1] rsexecute.client.cancel(future_advice) # Deconvolution via sub-images requires 2^n npixel = advice['npixels2'] results['npixel'] = npixel cellsize = advice['cellsize'] results['cellsize'] = cellsize lprint("Image will have %d by %d pixels, cellsize = %.6f rad" % (npixel, npixel, cellsize)) # Create an empty model image tmp_model_list = [ rsexecute.execute(create_image)( npixel=npixel, cellsize=cellsize, frequency=[frequency[f]], channel_bandwidth=[channel_bandwidth[f]], phasecentre=phasecentre, polarisation_frame=PolarisationFrame("stokesI")) for f, freq in enumerate(frequency) ] model_list = rsexecute.compute(tmp_model_list, sync=True) future_model_list = rsexecute.scatter(model_list) lprint("****** Setting up imaging parameters ******") # Now set up the imaging parameters template_model = create_image( npixel=npixel, cellsize=cellsize, frequency=[frequency[centre]], phasecentre=phasecentre, channel_bandwidth=[channel_bandwidth[centre]], polarisation_frame=PolarisationFrame("stokesI")) gcfcf = [create_pswf_convolutionfunction(template_model)] if context == 'timeslice': vis_slices = ntimes lprint("Using timeslice with %d slices" % vis_slices) elif context == '2d': vis_slices = 1 elif context == "wprojection": wstep = advice['wstep'] nw = advice['wprojection_planes'] vis_slices = 1 support = advice['nwpixels'] results['wprojection_planes'] = nw lprint("****** Starting W projection kernel creation ******") lprint("Using wprojection with %d planes with wstep %.1f wavelengths" % (nw, wstep)) lprint("Support of wprojection = %d pixels" % support) gcfcf = [ create_awterm_convolutionfunction(template_model, nw=nw, wstep=wstep, oversampling=4, support=support, use_aaf=True) ] lprint("Size of W projection gcf, cf = %.2E bytes" % get_size(gcfcf)) else: context = 'wstack' vis_slices = advice['vis_slices'] lprint("Using wstack with %d slices" % vis_slices) gcfcf = rsexecute.scatter(gcfcf, broadcast=True) results['vis_slices'] = vis_slices # Make a skymodel from gleam, with bright sources as components and weak sources in an image lprint("****** Starting GLEAM skymodel creation ******") future_skymodel_list = [ rsexecute.execute(create_low_test_skymodel_from_gleam)( npixel=npixel, cellsize=cellsize, frequency=[frequency[f]], phasecentre=phasecentre, polarisation_frame=PolarisationFrame("stokesI"), flux_limit=flux_limit, flux_threshold=dft_threshold, flux_max=5.0) for f, freq in enumerate(frequency) ] # We use predict_skymodel so that we can use skycomponents as well as images lprint("****** Starting GLEAM skymodel prediction ******") predicted_vis_list = [ predict_skymodel_list_rsexecute_workflow(future_vis_list[f], [future_skymodel_list[f]], context=context, vis_slices=vis_slices, facets=facets, gcfcf=gcfcf)[0] for f, freq in enumerate(frequency) ] # Corrupt the visibility for the GLEAM model lprint("****** Visibility corruption ******") tmp_corrupted_vis_list = corrupt_list_rsexecute_workflow( predicted_vis_list, phase_error=1.0, seed=seed) lprint("****** Weighting and tapering ******") tmp_corrupted_vis_list = weight_list_rsexecute_workflow( tmp_corrupted_vis_list, future_model_list) tmp_corrupted_vis_list = taper_list_rsexecute_workflow( tmp_corrupted_vis_list, 0.003 * 750.0 / rmax) tmp_corrupted_vis_list = rsexecute.compute(tmp_corrupted_vis_list, sync=True) corrupted_vis_list = rsexecute.gather(tmp_corrupted_vis_list) # rsexecute.client.cancel(predicted_vis_list) rsexecute.client.cancel(tmp_corrupted_vis_list) future_corrupted_vis_list = rsexecute.scatter(corrupted_vis_list) # At this point the only futures are of scatter'ed data so no repeated calculations should be # incurred. lprint("****** Starting dirty image calculation ******") start = time.time() dirty_list = invert_list_rsexecute_workflow( future_corrupted_vis_list, future_model_list, vis_slices=vis_slices, context=context, facets=facets, use_serial_invert=use_serial_imaging, gcfcf=gcfcf) results['size invert graph'] = get_size(dirty_list) lprint('Size of dirty graph is %.3E bytes' % (results['size invert graph'])) end = time.time() results['time invert graph'] = end - start lprint("Construction of invert graph took %.3f seconds" % (end - start)) start = time.time() dirty, sumwt = rsexecute.compute(dirty_list, sync=True)[centre] end = time.time() results['time invert'] = end - start lprint("Dirty image invert took %.3f seconds" % (end - start)) lprint("Maximum in dirty image is %f, sumwt is %s" % (numpy.max(numpy.abs(dirty.data)), str(sumwt))) qa = qa_image(dirty) results['dirty_max'] = qa.data['max'] results['dirty_min'] = qa.data['min'] if write_fits: export_image_to_fits( dirty, "pipelines_rsexecute_timings-%s-dirty.fits" % context) lprint("****** Starting prediction ******") start = time.time() tmp_vis_list = predict_list_rsexecute_workflow( future_corrupted_vis_list, future_model_list, vis_slices=vis_slices, context=context, facets=facets, use_serial_predict=use_serial_imaging, gcfcf=gcfcf) result = rsexecute.compute(tmp_vis_list, sync=True) # rsexecute.client.cancel(tmp_vis_list) end = time.time() results['time predict'] = end - start lprint("Predict took %.3f seconds" % (end - start)) # Create the ICAL pipeline to run major cycles, starting selfcal at cycle 1. A global solution across all # frequencies (i.e. Visibilities) is performed. print("Using subimage clean") deconvolve_facets = 8 deconvolve_overlap = 16 deconvolve_taper = 'tukey' lprint("****** Starting ICAL graph creation ******") controls = create_calibration_controls() controls['T']['first_selfcal'] = 1 controls['T']['timeslice'] = 'auto' start = time.time() ical_list = ical_list_rsexecute_workflow( future_corrupted_vis_list, model_imagelist=future_model_list, context=context, vis_slices=vis_slices, scales=[0, 3, 10], algorithm='mmclean', nmoment=3, niter=1000, fractional_threshold=0.1, threshold=0.01, nmajor=nmajor, gain=0.25, psf_support=64, deconvolve_facets=deconvolve_facets, deconvolve_overlap=deconvolve_overlap, deconvolve_taper=deconvolve_taper, timeslice='auto', global_solution=True, do_selfcal=True, calibration_context='T', controls=controls, use_serial_predict=use_serial_imaging, use_serial_invert=use_serial_imaging, use_serial_clean=use_serial_clean, gcfcf=gcfcf) results['size ICAL graph'] = get_size(ical_list) lprint('Size of ICAL graph is %.3E bytes' % results['size ICAL graph']) end = time.time() results['time ICAL graph'] = end - start lprint("Construction of ICAL graph took %.3f seconds" % (end - start)) print("Current objects on cluster: ") pp.pprint(rsexecute.client.who_has()) # # Execute the graph lprint("****** Executing ICAL graph ******") start = time.time() deconvolved, residual, restored, gaintables = rsexecute.compute(ical_list, sync=True) end = time.time() results['time ICAL'] = end - start lprint("ICAL graph execution took %.3f seconds" % (end - start)) qa = qa_image(deconvolved[centre]) results['deconvolved_max'] = qa.data['max'] results['deconvolved_min'] = qa.data['min'] deconvolved_cube = image_gather_channels(deconvolved) if write_fits: export_image_to_fits( deconvolved_cube, "pipelines_rsexecute_timings-%s-ical_deconvolved.fits" % context) qa = qa_image(residual[centre][0]) results['residual_max'] = qa.data['max'] results['residual_min'] = qa.data['min'] residual_cube = remove_sumwt(residual) residual_cube = image_gather_channels(residual_cube) if write_fits: export_image_to_fits( residual_cube, "pipelines_rsexecute_timings-%s-ical_residual.fits" % context) qa = qa_image(restored[centre]) results['restored_max'] = qa.data['max'] results['restored_min'] = qa.data['min'] restored_cube = image_gather_channels(restored) if write_fits: export_image_to_fits( restored_cube, "pipelines_rsexecute_timings-%s-ical_restored.fits" % context) # rsexecute.close() end_all = time.time() results['time overall'] = end_all - start_all lprint("At end, results are:") results = sort_dict(results) lprint(results) return results
def test_apply_voltage_pattern_image_pointsource(self): self.createVis(rmax=1e3) telescope = 'MID_FEKO_B2' vpol = PolarisationFrame("linear") self.times = numpy.linspace(-4, +4, 8) * numpy.pi / 12.0 bvis = create_blockvisibility(self.config, self.times, self.frequency, channel_bandwidth=self.channel_bandwidth, phasecentre=self.phasecentre, weight=1.0, polarisation_frame=vpol, zerow=True) cellsize = advise_wide_field(bvis)['cellsize'] pbmodel = create_image_from_visibility( bvis, cellsize=self.cellsize, npixel=self.npixel, override_cellsize=False, polarisation_frame=PolarisationFrame("stokesIQUV")) vpbeam = create_vp(pbmodel, telescope=telescope, use_local=False) vpbeam.wcs.wcs.ctype[0] = 'RA---SIN' vpbeam.wcs.wcs.ctype[1] = 'DEC--SIN' vpbeam.wcs.wcs.crval[0] = pbmodel.wcs.wcs.crval[0] vpbeam.wcs.wcs.crval[1] = pbmodel.wcs.wcs.crval[1] s3_components = create_test_skycomponents_from_s3( flux_limit=0.1, phasecentre=self.phasecentre, frequency=self.frequency, polarisation_frame=PolarisationFrame('stokesI'), radius=1.5 * numpy.pi / 180.0) for comp in s3_components: comp.polarisation_frame = PolarisationFrame('stokesIQUV') comp.flux = numpy.array([[comp.flux[0, 0], 0.0, 0.0, 0.0]]) s3_components = filter_skycomponents_by_flux(s3_components, 0.0, 10.0) from rascil.processing_components.image import show_image import matplotlib.pyplot as plt plt.clf() show_image(vpbeam, components=s3_components) plt.show(block=False) vpcomp = apply_voltage_pattern_to_skycomponent(s3_components, vpbeam) bvis.data['vis'][...] = 0.0 + 0.0j bvis = dft_skycomponent_visibility(bvis, vpcomp) rec_comp = idft_visibility_skycomponent(bvis, vpcomp)[0] stokes_comp = list() for comp in rec_comp: stokes_comp.append( convert_pol_frame(comp.flux[0], PolarisationFrame("linear"), PolarisationFrame("stokesIQUV"))) stokesI = numpy.abs( numpy.array([comp_flux[0] for comp_flux in stokes_comp]).real) stokesQ = numpy.abs( numpy.array([comp_flux[1] for comp_flux in stokes_comp]).real) stokesU = numpy.abs( numpy.array([comp_flux[2] for comp_flux in stokes_comp]).real) stokesV = numpy.abs( numpy.array([comp_flux[3] for comp_flux in stokes_comp]).real) plt.clf() plt.loglog(stokesI, stokesQ, '.', label='Q') plt.loglog(stokesI, stokesU, '.', label='U') plt.loglog(stokesI, stokesV, '.', label='V') plt.xlabel("Stokes Flux I (Jy)") plt.ylabel("Flux (Jy)") plt.legend() plt.savefig('%s/test_primary_beams_pol_rsexecute_stokes_errors.png' % self.dir) plt.show(block=False) split_times = False if split_times: bvis_list = list() for rows in vis_timeslice_iter(bvis, vis_slices=8): bvis_list.append(create_visibility_from_rows(bvis, rows)) else: bvis_list = [bvis] bvis_list = rsexecute.scatter(bvis_list) model_list = \ [rsexecute.execute(create_image_from_visibility, nout=1)(bv, cellsize=cellsize, npixel=4096, phasecentre=self.phasecentre, override_cellsize=False, polarisation_frame=PolarisationFrame("stokesIQUV")) for bv in bvis_list] model_list = rsexecute.persist(model_list) bvis_list = weight_list_rsexecute_workflow(bvis_list, model_list) continuum_imaging_list = \ continuum_imaging_list_rsexecute_workflow(bvis_list, model_list, context='2d', algorithm='hogbom', facets=1, niter=1000, fractional_threshold=0.1, threshold=1e-4, nmajor=5, gain=0.1, deconvolve_facets=4, deconvolve_overlap=32, deconvolve_taper='tukey', psf_support=64, restore_facets=4, psfwidth=1.0) clean, residual, restored = rsexecute.compute(continuum_imaging_list, sync=True) centre = 0 if self.persist: export_image_to_fits( clean[centre], '%s/test_primary_beams_pol_rsexecute_clean.fits' % self.dir) export_image_to_fits( residual[centre][0], '%s/test_primary_beams_pol_rsexecute_residual.fits' % self.dir) export_image_to_fits( restored[centre], '%s/test_primary_beams_pol_rsexecute_restored.fits' % self.dir) plt.clf() show_image(restored[centre]) plt.show(block=False) qa = qa_image(restored[centre]) assert numpy.abs(qa.data['max'] - 0.9953017707113947) < 1.0e-7, str(qa) assert numpy.abs(qa.data['min'] + 0.0036396480874570846) < 1.0e-7, str(qa)
cellsize = 0.001 npixel = 1024 pol_frame = PolarisationFrame("stokesI") model_list = [ rsexecute.execute(create_image_from_visibility)( v, npixel=npixel, cellsize=cellsize, polarisation_frame=pol_frame) for v in vis_list ] print('Creating model images') model_list = rsexecute.compute(model_list, sync=True) print('Creating graph') future_vis_list = rsexecute.scatter(vis_list) future_model_list = rsexecute.scatter(model_list) controls = create_calibration_controls() controls['T']['first_selfcal'] = 1 controls['T']['phase_only'] = True controls['T']['timeslice'] = 'auto' controls['G']['first_selfcal'] = 3 controls['G']['timeslice'] = 'auto' controls['B']['first_selfcal'] = 4 controls['B']['timeslice'] = 1e5 ical_list = ical_list_rsexecute_workflow(future_vis_list,