def recover_micro_hook(micro_filename, region, macro, naming_scheme='step_iel', recovery_file_tag=''): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove('equations') pb = ProblemDefinition.from_conf_file(micro_filename, required=required, other=other, init_equations=False, init_solvers=False) coefs_filename = pb.conf.options.get_default_attr('coefs_filename', 'coefs') output_dir = pb.conf.options.get_default_attr('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5(coefs_filename) corrs = get_correctors_from_file(dump_names=coefs.dump_names) recovery_hook = get_default_attr(pb.conf.options, 'recovery_hook', None) if recovery_hook is not None: recovery_hook = pb.conf.get_function(recovery_hook) aux = max(pb.domain.shape.n_gr, 2) format = get_print_info( aux, fill = '0' )[1] \ + '_' + get_print_info( pb.domain.mesh.n_el, fill = '0' )[1] for ig, ii, iel in region.iter_cells(): print 'ig: %d, ii: %d, iel: %d' % (ig, ii, iel) local_macro = {} for k, v in macro.iteritems(): local_macro[k] = v[ii, 0] out = recovery_hook(pb, corrs, local_macro) # save data suffix = format % (ig, iel) micro_name = pb.get_output_name(extra='recovered_'\ + recovery_file_tag + suffix) filename = op.join(output_dir, op.basename(micro_name)) fpv = pb.conf.options.get_default_attr('file_per_var', False) pb.save_state(filename, out=out, file_per_var=fpv)
def recover_micro_hook( micro_filename, region, macro, naming_scheme = 'step_iel', recovery_file_tag='' ): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove( 'equations' ) pb = ProblemDefinition.from_conf_file(micro_filename, required=required, other=other, init_equations=False, init_solvers=False) coefs_filename = pb.conf.options.get_default_attr('coefs_filename', 'coefs') output_dir = pb.conf.options.get_default_attr('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5( coefs_filename ) corrs = get_correctors_from_file( dump_names = coefs.dump_names ) recovery_hook = get_default_attr( pb.conf.options, 'recovery_hook', None ) if recovery_hook is not None: recovery_hook = getattr( pb.conf.funmod, recovery_hook ) aux = max(pb.domain.shape.n_gr, 2) format = get_print_info( aux, fill = '0' )[1] \ + '_' + get_print_info( pb.domain.mesh.n_el, fill = '0' )[1] for ig, ii, iel in region.iter_cells(): print 'ig: %d, ii: %d, iel: %d' % (ig, ii, iel) local_macro = {} for k, v in macro.iteritems(): local_macro[k] = v[ii,0] out = recovery_hook( pb, corrs, local_macro ) # save data suffix = format % (ig, iel) micro_name = pb.get_output_name(extra='recovered_'\ + recovery_file_tag + suffix) filename = op.join(output_dir, op.basename(micro_name)) fpv = pb.conf.options.get_default_attr('file_per_var', False) pb.save_state(filename, out=out, file_per_var=fpv)
def recover_micro_hook_eps(micro_filename, region, eval_var, nodal_values, const_values, eps0, recovery_file_tag='', define_args=None, verbose=False): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove('equations') conf = ProblemConf.from_file(micro_filename, required, other, verbose=False, define_args=define_args) coefs_filename = conf.options.get('coefs_filename', 'coefs') output_dir = conf.options.get('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5(coefs_filename) corrs = get_correctors_from_file(dump_names=coefs.dump_names) recovery_hook = conf.options.get('recovery_hook', None) if recovery_hook is not None: recovery_hook = conf.get_function(recovery_hook) pb = Problem.from_conf(conf, init_equations=False, init_solvers=False) # Get tiling of a given region rcoors = region.domain.mesh.coors[region.get_entities(0), :] rcmin = nm.min(rcoors, axis=0) rcmax = nm.max(rcoors, axis=0) nn = nm.round((rcmax - rcmin) / eps0) if nm.prod(nn) == 0: output('inconsistency in recovery region and microstructure size!') return cs = [] for ii, n in enumerate(nn): cs.append(nm.arange(n) * eps0 + rcmin[ii]) x0 = nm.empty((int(nm.prod(nn)), nn.shape[0]), dtype=nm.float64) for ii, icoor in enumerate(nm.meshgrid(*cs, indexing='ij')): x0[:, ii] = icoor.flatten() mesh = pb.domain.mesh coors, conn, outs, ndoffset = [], [], [], 0 # Recover region mic_coors = (mesh.coors - mesh.get_bounding_box()[0, :]) * eps0 evfield = eval_var.field output('recovering microsctructures...') tt = time.clock() output_fun = output.output_function output_level = output.level for ii, c0 in enumerate(x0): local_macro = {'eps0': eps0} local_coors = mic_coors + c0 # Inside recovery region? v = nm.ones((evfield.region.entities[0].shape[0], 1)) v[evfield.vertex_remap[region.entities[0]]] = 0 no = nm.sum(v) aux = evfield.evaluate_at(local_coors, v) if (nm.sum(aux) / no) > 1e-3: continue output.level = output_level output('micro: %d' % ii) for k, v in six.iteritems(nodal_values): local_macro[k] = evfield.evaluate_at(local_coors, v) for k, v in six.iteritems(const_values): local_macro[k] = v output.set_output(quiet=not(verbose)) outs.append(recovery_hook(pb, corrs, local_macro)) output.output_function = output_fun coors.append(local_coors) conn.append(mesh.get_conn(mesh.descs[0]) + ndoffset) ndoffset += mesh.n_nod output('...done in %.2f s' % (time.clock() - tt)) # Collect output variables outvars = {} for k, v in six.iteritems(outs[0]): if v.var_name in outvars: outvars[v.var_name].append(k) else: outvars[v.var_name] = [k] # Split output by variables/regions pvs = pb.create_variables(outvars.keys()) outregs = {k: pvs[k].field.region.get_entities(-1) for k in outvars.keys()} nrve = len(coors) coors = nm.vstack(coors) ngroups = nm.tile(mesh.cmesh.vertex_groups.squeeze(), (nrve,)) conn = nm.vstack(conn) cgroups = nm.tile(mesh.cmesh.cell_groups.squeeze(), (nrve,)) # Get region mesh and data for k, cidxs in six.iteritems(outregs): gcidxs = nm.hstack([cidxs + mesh.n_el * ii for ii in range(nrve)]) rconn = conn[gcidxs] remap = -nm.ones((coors.shape[0],), dtype=nm.int32) remap[rconn] = 1 vidxs = nm.where(remap > 0)[0] remap[vidxs] = nm.arange(len(vidxs)) rconn = remap[rconn] rcoors = coors[vidxs, :] out = {} for ifield in outvars[k]: data = [outs[ii][ifield].data for ii in range(nrve)] out[ifield] = Struct(name='output_data', mode=outs[0][ifield].mode, dofs=None, var_name=k, data=nm.vstack(data)) micro_name = pb.get_output_name(extra='recovered%s_%s' % (recovery_file_tag, k)) filename = op.join(output_dir, op.basename(micro_name)) mesh_out = Mesh.from_data('recovery_%s' % k, rcoors, ngroups[vidxs], [rconn], [cgroups[gcidxs]], [mesh.descs[0]]) mesh_out.write(filename, io='auto', out=out)
def recover_micro_hook(micro_filename, region, macro, naming_scheme='step_iel', recovery_file_tag='', define_args=None, verbose=False): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove('equations') conf = ProblemConf.from_file(micro_filename, required, other, verbose=False, define_args=define_args) coefs_filename = conf.options.get('coefs_filename', 'coefs') output_dir = conf.options.get('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5(coefs_filename) corrs = get_correctors_from_file(dump_names=coefs.dump_names) recovery_hook = conf.options.get('recovery_hook', None) if recovery_hook is not None: recovery_hook = conf.get_function(recovery_hook) pb = Problem.from_conf(conf, init_equations=False, init_solvers=False) format = get_print_info(pb.domain.mesh.n_el, fill='0')[1] output('recovering microsctructures...') tt = time.clock() output_fun = output.output_function output_level = output.level for ii, iel in enumerate(region.cells): output.level = output_level output('micro: %d (el=%d)' % (ii, iel)) local_macro = {} for k, v in six.iteritems(macro): local_macro[k] = v[ii, 0] output.set_output(quiet=not(verbose)) out = recovery_hook(pb, corrs, local_macro) output.output_function = output_fun if ii == 0: new_keys = [] new_data = {} new_idxs = [] for k in six.iterkeys(local_macro): if k not in macro: new_keys.append(k) new_data[k] = [] new_idxs.append(ii) for jj in new_keys: new_data[jj].append(local_macro[jj]) # save data if out is not None: suffix = format % iel micro_name = pb.get_output_name(extra='recovered_' + recovery_file_tag + suffix) filename = op.join(output_dir, op.basename(micro_name)) fpv = pb.conf.options.get('file_per_var', False) pb.save_state(filename, out=out, file_per_var=fpv) output('...done in %.2f s' % (time.clock() - tt)) for jj in new_keys: lout = new_data[jj] macro[jj] = nm.zeros((nm.max(new_idxs) + 1, 1) + lout[0].shape, dtype=lout[0].dtype) out = macro[jj] for kk, ii in enumerate(new_idxs): out[ii, 0] = lout[kk]
def recover_micro_hook( micro_filename, region, macro, naming_scheme = 'step_iel', recovery_file_tag='' ): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove( 'equations' ) pb = Problem.from_conf_file(micro_filename, required=required, other=other, init_equations=False, init_solvers=False) coefs_filename = pb.conf.options.get('coefs_filename', 'coefs') output_dir = pb.conf.options.get('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5( coefs_filename ) corrs = get_correctors_from_file( dump_names = coefs.dump_names ) recovery_hook = pb.conf.options.get('recovery_hook', None) if recovery_hook is not None: recovery_hook = pb.conf.get_function(recovery_hook) aux = max(pb.domain.shape.n_gr, 2) format = get_print_info( aux, fill = '0' )[1] \ + '_' + get_print_info( pb.domain.mesh.n_el, fill = '0' )[1] for ig, ii, iel in region.iter_cells(): print 'ig: %d, ii: %d, iel: %d' % (ig, ii, iel) local_macro = {} for k, v in macro.iteritems(): local_macro[k] = v[ii,0] out = recovery_hook( pb, corrs, local_macro ) if ii == 0: new_keys = [] new_data = {} new_idxs = [] for k in local_macro.iterkeys(): if k not in macro: new_keys.append(k) new_data[k] = [] new_idxs.append(ii) for jj in new_keys: new_data[jj].append(local_macro[jj]) # save data if out is not None: suffix = format % (ig, iel) micro_name = pb.get_output_name(extra='recovered_'\ + recovery_file_tag + suffix) filename = op.join(output_dir, op.basename(micro_name)) fpv = pb.conf.options.get('file_per_var', False) pb.save_state(filename, out=out, file_per_var=fpv) for jj in new_keys: lout = new_data[jj] macro[jj] = nm.zeros((nm.max(new_idxs) + 1,1) + lout[0].shape, dtype=lout[0].dtype) out = macro[jj] for kk, ii in enumerate(new_idxs): out[ii,0] = lout[kk]
def recover_micro_hook_eps(micro_filename, region, eval_var, nodal_values, const_values, eps0, recovery_file_tag='', define_args=None): # Create a micro-problem instance. required, other = get_standard_keywords() required.remove('equations') conf = ProblemConf.from_file(micro_filename, required, other, verbose=False, define_args=define_args) coefs_filename = conf.options.get('coefs_filename', 'coefs') output_dir = conf.options.get('output_dir', '.') coefs_filename = op.join(output_dir, coefs_filename) + '.h5' # Coefficients and correctors coefs = Coefficients.from_file_hdf5(coefs_filename) corrs = get_correctors_from_file(dump_names=coefs.dump_names) recovery_hook = conf.options.get('recovery_hook', None) if recovery_hook is not None: recovery_hook = conf.get_function(recovery_hook) pb = Problem.from_conf(conf, init_equations=False, init_solvers=False) # Get tiling of a given region rcoors = region.domain.mesh.coors[region.get_entities(0), :] rcmin = nm.min(rcoors, axis=0) rcmax = nm.max(rcoors, axis=0) nn = nm.round((rcmax - rcmin) / eps0) if nm.prod(nn) == 0: output('inconsistency in recovery region and microstructure size!') return cs = [] for ii, n in enumerate(nn): cs.append(nm.arange(n) * eps0 + rcmin[ii]) x0 = nm.empty((int(nm.prod(nn)), nn.shape[0]), dtype=nm.float64) for ii, icoor in enumerate(nm.meshgrid(*cs, indexing='ij')): x0[:, ii] = icoor.flatten() mesh = pb.domain.mesh coors, conn, outs, ndoffset = [], [], [], 0 # Recover region for ii, c0 in enumerate(x0): local_macro = {'eps0': eps0} local_coors = pb.domain.mesh.coors * eps0 + c0 # Inside recovery region? v = nm.ones((eval_var.field.region.entities[0].shape[0], 1)) v[region.entities[0]] = 0 no = nm.sum(v) aux = eval_var.field.evaluate_at(local_coors, v) if (nm.sum(aux) / no) > 1e-3: continue output('ii: %d' % ii) for k, v in six.iteritems(nodal_values): local_macro[k] = eval_var.field.evaluate_at(local_coors, v) for k, v in six.iteritems(const_values): local_macro[k] = v outs.append(recovery_hook(pb, corrs, local_macro)) coors.append(local_coors) conn.append(mesh.get_conn(mesh.descs[0]) + ndoffset) ndoffset += mesh.n_nod # Collect output variables outvars = {} for k, v in six.iteritems(outs[0]): if v.var_name in outvars: outvars[v.var_name].append(k) else: outvars[v.var_name] = [k] # Split output by variables/regions pvs = pb.create_variables(outvars.keys()) outregs = {k: pvs[k].field.region.get_entities(-1) for k in outvars.keys()} nrve = len(coors) coors = nm.vstack(coors) ngroups = nm.tile(mesh.cmesh.vertex_groups.squeeze(), (nrve,)) conn = nm.vstack(conn) cgroups = nm.tile(mesh.cmesh.cell_groups.squeeze(), (nrve,)) # Get region mesh and data for k, cidxs in six.iteritems(outregs): gcidxs = nm.hstack([cidxs + mesh.n_el * ii for ii in range(nrve)]) rconn = conn[gcidxs] remap = -nm.ones((coors.shape[0],), dtype=nm.int32) remap[rconn] = 1 vidxs = nm.where(remap > 0)[0] remap[vidxs] = nm.arange(len(vidxs)) rconn = remap[rconn] rcoors = coors[vidxs, :] out = {} for ifield in outvars[k]: data = [outs[ii][ifield].data for ii in range(nrve)] out[ifield] = Struct(name='output_data', mode=outs[0][ifield].mode, dofs=None, var_name=k, data=nm.vstack(data)) micro_name = pb.get_output_name(extra='recovered%s_%s' % (recovery_file_tag, k)) filename = op.join(output_dir, op.basename(micro_name)) mesh_out = Mesh.from_data('recovery_%s' % k, rcoors, ngroups[vidxs], [rconn], [cgroups[gcidxs]], [mesh.descs[0]]) mesh_out.write(filename, io='auto', out=out)