from .libngpy._geom2d import SplineGeometry, Solid2d, CSG2d, Rectangle, Circle, EdgeInfo from .meshing import meshsize unit_square = SplineGeometry() _pnts = [ (0,0), (1,0), (1,1), (0,1) ] _lines = [ (0,1,1,"bottom"), (1,2,2,"right"), (2,3,3,"top"), (3,0,4,"left") ] _pnums = [unit_square.AppendPoint(*p) for p in _pnts] for l1,l2,bc,bcname in _lines: unit_square.Append( ["line", _pnums[l1], _pnums[l2]], bc=bcname) def MakeRectangle (geo, p1, p2, bc=None, bcs=None, **args): p1x, p1y = p1 p2x, p2y = p2 p1x,p2x = min(p1x,p2x), max(p1x, p2x) p1y,p2y = min(p1y,p2y), max(p1y, p2y) if not bcs: bcs=4*[bc] pts = [geo.AppendPoint(*p) for p in [(p1x,p1y), (p2x, p1y), (p2x, p2y), (p1x, p2y)]] for p1,p2,bc in [(0,1,bcs[0]), (1, 2, bcs[1]), (2, 3, bcs[2]), (3, 0, bcs[3])]: geo.Append( ["line", pts[p1], pts[p2]], bc=bc, **args) def MakeCircle (geo, c, r, **args): cx,cy = c pts = [geo.AppendPoint(*p) for p in [(cx,cy-r), (cx+r,cy-r), (cx+r,cy), (cx+r,cy+r), \ (cx,cy+r), (cx-r,cy+r), (cx-r,cy), (cx-r,cy-r)]] for p1,p2,p3 in [(0,1,2), (2,3,4), (4, 5, 6), (6, 7, 0)]: geo.Append( ["spline3", pts[p1], pts[p2], pts[p3]], **args) def CreatePML(geo, pml_size, tol=1e-12): """Create a pml layer around the geometry. This function works only on convex geometries and the highest existing domain number must be named by using the function geo.SetMaterial(domnr, name). Points in the geometry are assumed to be the same if (pt1 - pt2).Norm() < tol. Returned is a dict with information to create the pml layer: normals: A dict from the names of the linear pml domains to the normal vectors pointing inside the pml.""" def Start(spline): if spline.rightdom == 0: return spline.StartPoint() return spline.EndPoint() def End(spline): if spline.rightdom == 0: return spline.EndPoint() return spline.StartPoint() splines = [] for i in range(geo.GetNSplines()): splines.append(geo.GetSpline(i)) border = [] is_closed = False current_endpoint = None while not is_closed: for spline in splines: if spline.leftdom == 0 or spline.rightdom == 0: if current_endpoint is not None: if (Start(spline)-current_endpoint).Norm() < tol: border.append(spline) current_endpoint = End(spline) if (current_endpoint - startpoint).Norm() < tol: is_closed = True break else: startpoint = Start(spline) current_endpoint = End(spline) border.append(spline) break else: raise Exception("Couldn't find closed spline around domain") endpointindex_map = [] for spline in border: pnt = End(spline) for i in range(geo.GetNPoints()): if (pnt - geo.GetPoint(i)).Norm() < tol: endpointindex_map.append(i) break else: raise Exception("Couldn't find endpoint of spline in geometry") start_ndoms = ndoms = geo.GetNDomains() + 1 new_spline_domains = [] normals = {} duplicate_cnt = 0 for i, spline in enumerate(border): if i == 0: global_start = Start(spline) + pml_size * spline.GetNormal(0) global_start_pnt = current_start = geo.AppendPoint(global_start[0], global_start[1]) next_spline = border[(i+1)%len(border)] new_end = End(spline) + pml_size * spline.GetNormal(1) spline_name = geo.GetBCName(spline.bc) if "pml_" + spline_name in normals \ and normals["pml_" + spline_name] != spline.GetNormal(0): duplicate_cnt += 1 spline_name = spline_name + "_duplicate_" + str(duplicate_cnt) if (new_end - global_start).Norm() < tol: new_spline_domains.append(ndoms) geo.Append(["line", current_start, global_start_pnt], bc="outer_" + spline_name, leftdomain = ndoms) geo.Append(["line", global_start_pnt, endpointindex_map[i]], leftdomain=ndoms, rightdomain=start_ndoms) geo.SetMaterial(ndoms, "pml_" + spline_name) normals["pml_" + spline_name] = spline.GetNormal(0) ndoms += 1 break end = geo.AppendPoint(new_end[0], new_end[1]) new_spline_domains.append(ndoms) geo.Append(["line", current_start, end], bc="outer_" + spline_name, leftdomain = ndoms) geo.Append(["line", end, endpointindex_map[i]], leftdomain=ndoms, rightdomain=ndoms+1) geo.SetMaterial(ndoms, "pml_" + spline_name) normals["pml_" + spline_name] = spline.GetNormal(0) ndoms += 1 new_start = Start(next_spline) + pml_size * next_spline.GetNormal(0) if (new_start - global_start).Norm() < tol: geo.Append(["line", end, global_start_pnt], bc="outer", leftdomain = ndoms) geo.Append(["line", global_start_pnt, endpointindex_map[i]], leftdomain=ndoms, rightdomain=start_ndoms) geo.SetMaterial(ndoms, "pml_corner") ndoms += 1 break if (new_end - new_start).Norm() < tol: current_start = end else: current_start = geo.AppendPoint(new_start[0], new_start[1]) geo.Append(["line", end, current_start], bc="outer", leftdomain = ndoms) geo.Append(["line", current_start, endpointindex_map[i]], leftdomain=ndoms, rightdomain=ndoms+1) geo.SetMaterial(ndoms, "pml_corner") ndoms += 1 for spline, domnr in zip(border, new_spline_domains): if spline.leftdom == 0: spline.leftdom = domnr else: spline.rightdom = domnr return {"normals" : normals} SplineGeometry.AddCircle = lambda geo, c, r, **args : MakeCircle(geo, c, r, **args) SplineGeometry.AddRectangle = lambda geo, p1, p2, **args : MakeRectangle(geo, p1, p2, **args) SplineGeometry.AddSegment = lambda *args, **kwargs : SplineGeometry.Append(*args, **kwargs) SplineGeometry.AddPoint = lambda *args, **kwargs : SplineGeometry.AppendPoint(*args, **kwargs) SplineGeometry.CreatePML = CreatePML bc = lambda s : EdgeInfo(bc=s) maxh = lambda h : EdgeInfo(maxh=h) def cp(p_or_px, py_or_none = None): if py_or_none is None: return EdgeInfo(control_point=p) else: return EdgeInfo(control_point=(p_or_px,py_or_none))