def plot_control_mesh(ax, control_points, label=False): """ Plot the control mesh of a NURBS given by its control points. """ dim = control_points.shape[-1] ax = _get_axes(ax, dim) shape = control_points.shape conn, desc = get_tensor_product_conn(nm.array(shape[:-1])) gel = GeometryElement(desc) coors = control_points.reshape((-1, dim)) ax = pd.plot_mesh(ax, coors, conn, gel.edges) pd.plot_points(ax, coors) if label: for ii, cc in enumerate(coors): if dim == 3: cx, cy, cz = cc ax.text(cx, cy, cz, '%d' % ii, color='g', fontsize=12, weight='bold') else: cx, cy = cc ax.text(cx, cy, '%d' % ii, color='g', fontsize=12, weight='bold') return ax
def plot_geometry(ax, gel): """ Plot a geometry element as a wireframe. """ ax = plot_mesh(ax, gel.coors, [gel.conn], gel.edges) ax = plot_global_dofs(ax, gel.coors, [gel.conn]) return ax
def plot_geometry(ax, gel, show=False): """ Plot a geometry element as a wireframe. """ ax = plot_mesh(ax, gel.coors, [gel.conn], gel.edges, show=False) ax = plot_global_dofs(ax, gel.coors, [gel.conn], show=show) return ax
def plot_bezier_mesh(ax, control_points, conn, degrees, label=False): """ Plot the Bezier mesh of a NURBS given by its control points and connectivity. """ dim = control_points.shape[-1] ax = _get_axes(ax, dim) edges = _get_edges(conn.shape[1], nm.asarray(degrees) + 1) ax = pd.plot_mesh(ax, control_points, conn, edges) pd.plot_points(ax, control_points) if label: ax = pd.plot_global_dofs(ax, control_points, conn) return ax
def plot_control_mesh(ax, control_points, label=False): """ Plot the control mesh of a NURBS given by its control points. """ dim = control_points.shape[-1] ax = _get_axes(ax, dim) shape = control_points.shape conn, desc = get_tensor_product_conn(nm.array(shape[:-1])) gel = GeometryElement(desc) coors = control_points.reshape((-1, dim)) ax = pd.plot_mesh(ax, coors, conn, gel.edges) pd.plot_points(ax, coors) if label: for ii, cc in enumerate(coors): ax.text(*cc, s="%d" % ii, color="g", fontsize=12, weight="bold") return ax
def plot_parametric_mesh(ax, knots): """ Plot the parametric mesh of a NURBS given by its knots. """ knots = _get_knots_tuple(knots) dim = len(knots) ax = _get_axes(ax, dim) uknots = [nm.unique(ii) for ii in knots] shape = [len(ii) for ii in uknots] ngrid = nm.mgrid[[slice(ii) for ii in shape]] coors = nm.r_[[uknots[ii][ig].ravel() for ii, ig in enumerate(ngrid)]].T conn, desc = get_tensor_product_conn(nm.array(shape)) gel = GeometryElement(desc) ax = pd.plot_mesh(ax, coors, conn, gel.edges) pd.plot_points(ax, coors) return ax
def main(): parser = OptionParser(usage=usage, version='%prog') parser.add_option('-b', '--basis', metavar='name', action='store', dest='basis', default='lagrange', help=help['basis']) parser.add_option('-d', '--derivative', metavar='d', type=int, action='store', dest='derivative', default=0, help=help['derivative']) parser.add_option('-n', '--max-order', metavar='order', type=int, action='store', dest='max_order', default=2, help=help['max_order']) parser.add_option('-g', '--geometry', metavar='name', action='store', dest='geometry', default='2_4', help=help['geometry']) parser.add_option('-m', '--mesh', metavar='mesh', action='store', dest='mesh', default=None, help=help['mesh']) parser.add_option('', '--permutations', metavar='permutations', action='store', dest='permutations', default=None, help=help['permutations']) parser.add_option('', '--dofs', metavar='dofs', action='store', dest='dofs', default=None, help=help['dofs']) parser.add_option('-l', '--lin-options', metavar='options', action='store', dest='lin_options', default='min_level=2,max_level=5,eps=1e-3', help=help['lin_options']) parser.add_option('', '--plot-dofs', action='store_true', dest='plot_dofs', default=False, help=help['plot_dofs']) options, args = parser.parse_args() if len(args) == 1: output_dir = args[0] else: parser.print_help(), return output('polynomial space:', options.basis) output('max. order:', options.max_order) lin = Struct(kind='adaptive', min_level=2, max_level=5, eps=1e-3) for opt in options.lin_options.split(','): key, val = opt.split('=') setattr(lin, key, eval(val)) if options.mesh is None: dim, n_ep = int(options.geometry[0]), int(options.geometry[2]) output('reference element geometry:') output(' dimension: %d, vertices: %d' % (dim, n_ep)) gel = GeometryElement(options.geometry) gps = PolySpace.any_from_args(None, gel, 1, base=options.basis) ps = PolySpace.any_from_args(None, gel, options.max_order, base=options.basis) n_digit, _format = get_print_info(ps.n_nod, fill='0') name_template = os.path.join(output_dir, 'bf_%s.vtk' % _format) for ip in get_dofs(options.dofs, ps.n_nod): output('shape function %d...' % ip) def eval_dofs(iels, rx): if options.derivative == 0: bf = ps.eval_base(rx).squeeze() rvals = bf[None, :, ip:ip+1] else: bfg = ps.eval_base(rx, diff=True) rvals = bfg[None, ..., ip] return rvals def eval_coors(iels, rx): bf = gps.eval_base(rx).squeeze() coors = nm.dot(bf, gel.coors)[None, ...] return coors (level, coors, conn, vdofs, mat_ids) = create_output(eval_dofs, eval_coors, 1, ps, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) out = { 'bf' : Struct(name='output_data', mode='vertex', data=vdofs, var_name='bf', dofs=None) } mesh = Mesh.from_data('bf_mesh', coors, None, [conn], [mat_ids], [options.geometry]) name = name_template % ip mesh.write(name, out=out) output('...done (%s)' % name) else: mesh = Mesh.from_file(options.mesh) output('mesh geometry:') output(' dimension: %d, vertices: %d, elements: %d' % (mesh.dim, mesh.n_nod, mesh.n_el)) domain = Domain('domain', mesh) if options.permutations: permutations = [int(ii) for ii in options.permutations.split(',')] output('using connectivity permutations:', permutations) for group in domain.iter_groups(): perms = group.gel.get_conn_permutations()[permutations] offsets = nm.arange(group.shape.n_el) * group.shape.n_ep group.conn[:] = group.conn.take(perms + offsets[:, None]) domain.setup_facets() omega = domain.create_region('Omega', 'all') field = Field.from_args('f', nm.float64, shape=1, region=omega, approx_order=options.max_order, poly_space_base=options.basis) var = FieldVariable('u', 'unknown', field, 1) if options.plot_dofs: import sfepy.postprocess.plot_dofs as pd group = domain.groups[0] ax = pd.plot_mesh(None, mesh.coors, mesh.conns[0], group.gel.edges) ax = pd.plot_global_dofs(ax, field.get_coor(), field.aps[0].econn) ax = pd.plot_local_dofs(ax, field.get_coor(), field.aps[0].econn) pd.plt.show() output('dofs: %d' % var.n_dof) vec = nm.empty(var.n_dof, dtype=var.dtype) n_digit, _format = get_print_info(var.n_dof, fill='0') name_template = os.path.join(output_dir, 'dof_%s.vtk' % _format) for ip in get_dofs(options.dofs, var.n_dof): output('dof %d...' % ip) vec.fill(0.0) vec[ip] = 1.0 var.data_from_any(vec) if options.derivative == 0: out = var.create_output(vec, linearization=lin) else: out = create_expression_output('ev_grad.ie.Elements(u)', 'u', 'f', {'f' : field}, None, Variables([var]), mode='qp', verbose=False, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) name = name_template % ip out['u'].mesh.write(name, out=out) output('...done (%s)' % name)
def save_basis_on_mesh(mesh, options, output_dir, lin, permutations=None, suffix=''): if permutations is not None: mesh = mesh.copy() for ig, conn in enumerate(mesh.conns): gel = GeometryElement(mesh.descs[ig]) perms = gel.get_conn_permutations()[permutations] n_el, n_ep = conn.shape offsets = nm.arange(n_el) * n_ep conn[:] = conn.take(perms + offsets[:, None]) domain = Domain('domain', mesh) omega = domain.create_region('Omega', 'all') field = Field.from_args('f', nm.float64, shape=1, region=omega, approx_order=options.max_order, poly_space_base=options.basis) var = FieldVariable('u', 'unknown', field, 1) if options.plot_dofs: import sfepy.postprocess.plot_dofs as pd group = domain.groups[0] ax = pd.plot_mesh(None, mesh.coors, mesh.conns[0], group.gel.edges) ax = pd.plot_global_dofs(ax, field.get_coor(), field.aps[0].econn) ax = pd.plot_local_dofs(ax, field.get_coor(), field.aps[0].econn) if options.dofs is not None: ax = pd.plot_nodes(ax, field.get_coor(), field.aps[0].econn, field.aps[0].interp.poly_spaces['v'].nodes, get_dofs(options.dofs, var.n_dof)) pd.plt.show() output('dofs: %d' % var.n_dof) vec = nm.empty(var.n_dof, dtype=var.dtype) n_digit, _format = get_print_info(var.n_dof, fill='0') name_template = os.path.join(output_dir, 'dof_%s%s.vtk' % (_format, suffix)) for ip in get_dofs(options.dofs, var.n_dof): output('dof %d...' % ip) vec.fill(0.0) vec[ip] = 1.0 var.set_data(vec) if options.derivative == 0: out = var.create_output(vec, linearization=lin) else: out = create_expression_output('ev_grad.ie.Elements(u)', 'u', 'f', {'f': field}, None, Variables([var]), mode='qp', verbose=False, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) name = name_template % ip ensure_path(name) out['u'].mesh.write(name, out=out) output('...done (%s)' % name)
def save_basis_on_mesh(mesh, options, output_dir, lin, permutations=None, suffix=''): if permutations is not None: mesh = mesh.copy() for ig, conn in enumerate(mesh.conns): gel = GeometryElement(mesh.descs[ig]) perms = gel.get_conn_permutations()[permutations] n_el, n_ep = conn.shape offsets = nm.arange(n_el) * n_ep conn[:] = conn.take(perms + offsets[:, None]) domain = Domain('domain', mesh) omega = domain.create_region('Omega', 'all') field = Field.from_args('f', nm.float64, shape=1, region=omega, approx_order=options.max_order, poly_space_base=options.basis) var = FieldVariable('u', 'unknown', field, 1) if options.plot_dofs: import sfepy.postprocess.plot_dofs as pd group = domain.groups[0] ax = pd.plot_mesh(None, mesh.coors, mesh.conns[0], group.gel.edges) ax = pd.plot_global_dofs(ax, field.get_coor(), field.aps[0].econn) ax = pd.plot_local_dofs(ax, field.get_coor(), field.aps[0].econn) if options.dofs is not None: ax = pd.plot_nodes(ax, field.get_coor(), field.aps[0].econn, field.aps[0].interp.poly_spaces['v'].nodes, get_dofs(options.dofs, var.n_dof)) pd.plt.show() output('dofs: %d' % var.n_dof) vec = nm.empty(var.n_dof, dtype=var.dtype) n_digit, _format = get_print_info(var.n_dof, fill='0') name_template = os.path.join(output_dir, 'dof_%s%s.vtk' % (_format, suffix)) for ip in get_dofs(options.dofs, var.n_dof): output('dof %d...' % ip) vec.fill(0.0) vec[ip] = 1.0 var.set_data(vec) if options.derivative == 0: out = var.create_output(vec, linearization=lin) else: out = create_expression_output('ev_grad.ie.Elements(u)', 'u', 'f', {'f' : field}, None, Variables([var]), mode='qp', verbose=False, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) name = name_template % ip ensure_path(name) out['u'].mesh.write(name, out=out) output('...done (%s)' % name)
def main(): parser = OptionParser(usage=usage, version='%prog') parser.add_option('-b', '--basis', metavar='name', action='store', dest='basis', default='lagrange', help=help['basis']) parser.add_option('-d', '--derivative', metavar='d', type=int, action='store', dest='derivative', default=0, help=help['derivative']) parser.add_option('-n', '--max-order', metavar='order', type=int, action='store', dest='max_order', default=2, help=help['max_order']) parser.add_option('-g', '--geometry', metavar='name', action='store', dest='geometry', default='2_4', help=help['geometry']) parser.add_option('-m', '--mesh', metavar='mesh', action='store', dest='mesh', default=None, help=help['mesh']) parser.add_option('', '--permutations', metavar='permutations', action='store', dest='permutations', default=None, help=help['permutations']) parser.add_option('', '--dofs', metavar='dofs', action='store', dest='dofs', default=None, help=help['dofs']) parser.add_option('-l', '--lin-options', metavar='options', action='store', dest='lin_options', default='min_level=2,max_level=5,eps=1e-3', help=help['lin_options']) parser.add_option('', '--plot-dofs', action='store_true', dest='plot_dofs', default=False, help=help['plot_dofs']) options, args = parser.parse_args() if len(args) == 1: output_dir = args[0] else: parser.print_help(), return output('polynomial space:', options.basis) output('max. order:', options.max_order) lin = Struct(kind='adaptive', min_level=2, max_level=5, eps=1e-3) for opt in options.lin_options.split(','): key, val = opt.split('=') setattr(lin, key, eval(val)) if options.mesh is None: dim, n_ep = int(options.geometry[0]), int(options.geometry[2]) output('reference element geometry:') output(' dimension: %d, vertices: %d' % (dim, n_ep)) gel = GeometryElement(options.geometry) gps = PolySpace.any_from_args(None, gel, 1, base=options.basis) ps = PolySpace.any_from_args(None, gel, options.max_order, base=options.basis) n_digit, _format = get_print_info(ps.n_nod, fill='0') name_template = os.path.join(output_dir, 'bf_%s.vtk' % _format) for ip in get_dofs(options.dofs, ps.n_nod): output('shape function %d...' % ip) def eval_dofs(iels, rx): if options.derivative == 0: bf = ps.eval_base(rx).squeeze() rvals = bf[None, :, ip:ip + 1] else: bfg = ps.eval_base(rx, diff=True) rvals = bfg[None, ..., ip] return rvals def eval_coors(iels, rx): bf = gps.eval_base(rx).squeeze() coors = nm.dot(bf, gel.coors)[None, ...] return coors (level, coors, conn, vdofs, mat_ids) = create_output(eval_dofs, eval_coors, 1, ps, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) out = { 'bf': Struct(name='output_data', mode='vertex', data=vdofs, var_name='bf', dofs=None) } mesh = Mesh.from_data('bf_mesh', coors, None, [conn], [mat_ids], [options.geometry]) name = name_template % ip mesh.write(name, out=out) output('...done (%s)' % name) else: mesh = Mesh.from_file(options.mesh) output('mesh geometry:') output(' dimension: %d, vertices: %d, elements: %d' % (mesh.dim, mesh.n_nod, mesh.n_el)) domain = Domain('domain', mesh) if options.permutations: permutations = [int(ii) for ii in options.permutations.split(',')] output('using connectivity permutations:', permutations) for group in domain.iter_groups(): perms = group.gel.get_conn_permutations()[permutations] offsets = nm.arange(group.shape.n_el) * group.shape.n_ep group.conn[:] = group.conn.take(perms + offsets[:, None]) domain.setup_facets() omega = domain.create_region('Omega', 'all') field = Field.from_args('f', nm.float64, shape=1, region=omega, approx_order=options.max_order, poly_space_base=options.basis) var = FieldVariable('u', 'unknown', field, 1) if options.plot_dofs: import sfepy.postprocess.plot_dofs as pd group = domain.groups[0] ax = pd.plot_mesh(None, mesh.coors, mesh.conns[0], group.gel.edges) ax = pd.plot_global_dofs(ax, field.get_coor(), field.aps[0].econn) ax = pd.plot_local_dofs(ax, field.get_coor(), field.aps[0].econn) if options.dofs is not None: ax = pd.plot_nodes(ax, field.get_coor(), field.aps[0].econn, field.aps[0].interp.poly_spaces['v'].nodes, get_dofs(options.dofs, var.n_dof)) pd.plt.show() output('dofs: %d' % var.n_dof) vec = nm.empty(var.n_dof, dtype=var.dtype) n_digit, _format = get_print_info(var.n_dof, fill='0') name_template = os.path.join(output_dir, 'dof_%s.vtk' % _format) for ip in get_dofs(options.dofs, var.n_dof): output('dof %d...' % ip) vec.fill(0.0) vec[ip] = 1.0 var.set_data(vec) if options.derivative == 0: out = var.create_output(vec, linearization=lin) else: out = create_expression_output('ev_grad.ie.Elements(u)', 'u', 'f', {'f': field}, None, Variables([var]), mode='qp', verbose=False, min_level=lin.min_level, max_level=lin.max_level, eps=lin.eps) name = name_template % ip out['u'].mesh.write(name, out=out) output('...done (%s)' % name)