right_idx_offset = optics.receptor_dir_slicer["left"].stop right_triangles = [] for tri in left_triangles: newtri = [] for idx in tri: newtri.append(idx + right_idx_offset) right_triangles.append(newtri) triangles = list(left_triangles) + right_triangles right_edges = [] for edge in left_edges: newedge = [] for idx in edge: newedge.append(idx + right_idx_offset) right_edges.append(newedge) edges = list(left_edges) + right_edges edge_slicer = { None: slice(0, len(edges), 1), "left": slice(0, len(left_edges), 1), "right": slice(len(left_edges), len(edges), 1), } if 1: fd = open("precomputed_buchner71_emd_edges.py", "wb") fd.write("# Automatically generated by %s\n" % os.path.split(__name__)[-1]) save_as_python(fd, edge_slicer, "edge_slicer", fname_extra="_buchner71") save_as_python(fd, edges, "edges", fname_extra="_buchner_1971") fd.close()
receptor_dir_slicer = {None:slice(0,len(receptor_dirs),1)} edge_slicer = {None:slice(0,len(edges),1)} # fd = open('precomputed_synthetic.py','wb') fd.write( '# Automatically generated by %s\n'%os.path.split(__name__)[-1]) fd.write( 'import numpy\n') fd.write( 'import scipy\n') fd.write( 'import scipy.sparse\n') fd.write( 'import scipy.io\n') fd.write( 'import cgtypes # cgkit 1.x\n') fd.write( 'from cgtypes import vec3, quat #cgkit 1.x\n') fd.write( 'import os\n') fd.write( 'datadir = os.path.split(__file__)[0]\n') fd.write( 'cube_order = %s\n'%repr(cube_order) ) save_as_python(fd, receptor_dir_slicer, 'receptor_dir_slicer', fname_extra='_synthetic' ) save_as_python(fd, edge_slicer, 'edge_slicer', fname_extra='_synthetic' ) save_as_python(fd, spmat_64, 'receptor_weight_matrix_64', fname_extra='_synthetic' ) save_as_python(fd, map(make_repr_able,receptor_dirs), 'receptor_dirs', fname_extra='_synthetic' ) save_as_python(fd, tris, 'triangles') save_as_python(fd, edges, 'edges') save_as_python(fd, map(make_repr_able,faces), 'hex_faces') save_as_python(fd, receptors_by_phi, 'receptors_by_phi',fname_extra='_synthetic' ) fd.write( '\n') fd.write( '\n') fd.write( '\n') extra = open('plot_receptors_vtk.py','r').read() fd.write( extra ) fd.close()
def precompute_generic(configuration_name, receptor_dirs, tris): script_dir = os.path.abspath(os.path.split(__file__)[0]) os.chdir(script_dir) ######################################################## # SAVE INFO (from save_sparse_weights.py) ######################################################## # receptor_dirs, tris = make_subdivided_unit_icosahedron(n_subdivides=3) # n_subidivisions # receptors_by_phi = sort_receptors_by_phi(receptor_dirs,nbins = 32) edges = find_edges( tris ) verts = receptor_dirs rad2deg = 180/math.pi v0 = verts[0] a_degs = [v0.angle(v)*rad2deg for v in verts[1:]] a_degs.sort() delta_phi_deg = a_degs[0] # inter receptor angle, 6.848549293 when 3 subdivisions of icosahedron print 'delta_phi_deg',delta_phi_deg delta_phi = delta_phi_deg/rad2deg delta_rho = delta_phi * 1.1 # rough approximation. follows from caption of Fig. 18, Buchner, 1984 (in Ali) weight_maps_64 = make_receptor_sensitivities( receptor_dirs, delta_rho_q=delta_rho, res=64 ) print 'weight_maps calculated' ##################################### clip_thresh=1e-5 floattype=numpy.float32 weights = flatten_cubemap( weight_maps_64[0] ) # get first one to take size n_receptors = len(receptor_dirs) len_wm = len(weights) print 'allocating memory...' bigmat_64 = numpy.zeros( (n_receptors, len_wm), dtype=floattype ) print 'done' print 'flattening, clipping, casting...' for i, weight_cubemap in enumerate(weight_maps_64): weights = flatten_cubemap( weight_cubemap ) if clip_thresh is not None: weights = numpy.choose(weights<clip_thresh,(weights,0)) bigmat_64[i,:] = weights.astype( bigmat_64.dtype ) print 'done' print 'worst gain (should be unity)',min(numpy.sum( bigmat_64, axis=1)) print 'filling spmat_64...' sys.stdout.flush() spmat_64 = scipy.sparse.csc_matrix(bigmat_64) print 'done' M,N = bigmat_64.shape print 'Compressed to %d of %d'%(len(spmat_64.data),M*N) faces = pseudo_voronoi(receptor_dirs,tris) ################################################## # Save matlab version fd = open('precomputed_%s.m' % configuration_name,'w') fd.write( 'receptor_dirs = [ ...') for rdir in receptor_dirs: fd.write( '\n %s %s %s;'%( repr(rdir[0]), repr(rdir[1]), repr(rdir[2]) ) ) fd.write( '];\n\n') fd.write( 'edges = [ ...') for e in edges: fd.write( '\n %d %d;'%( e[0]+1, e[1]+1 )) # convert to 1-based indexing fd.write( '];\n\n') fd.close() ################################################## receptor_dir_slicer = {None:slice(0,len(receptor_dirs),1)} edge_slicer = {None:slice(0,len(edges),1)} # fd = open('precomputed_%s.py' % configuration_name,'wb') fd.write( '# Automatically generated by %s\n'%os.path.split(__name__)[-1]) fd.write( 'import numpy\n') fd.write( 'import scipy\n') fd.write( 'import scipy.sparse\n') fd.write( 'import scipy.io\n') fd.write( 'import cgtypes # cgkit 1.x\n') fd.write( 'from cgtypes import vec3, quat #cgkit 1.x\n') fd.write( 'import os\n') fd.write( 'datadir = os.path.split(__file__)[0]\n') fd.write( 'cube_order = %s\n'%repr(cube_order) ) save_as_python(fd, receptor_dir_slicer, 'receptor_dir_slicer', fname_extra='_synthetic' ) save_as_python(fd, edge_slicer, 'edge_slicer', fname_extra='_synthetic' ) save_as_python(fd, spmat_64, 'receptor_weight_matrix_64', fname_extra='_synthetic' ) save_as_python(fd, map(make_repr_able,receptor_dirs), 'receptor_dirs', fname_extra='_synthetic' ) save_as_python(fd, tris, 'triangles') save_as_python(fd, edges, 'edges') save_as_python(fd, map(make_repr_able,faces), 'hex_faces') # save_as_python(fd, receptors_by_phi, 'receptors_by_phi',fname_extra='_synthetic' ) fd.write( '\n') fd.write( '\n') fd.write( '\n') extra = open('plot_receptors_vtk.py','r').read() fd.write( extra ) fd.close()
right_idx_offset = optics.receptor_dir_slicer['left'].stop right_triangles = [] for tri in left_triangles: newtri = [] for idx in tri: newtri.append( idx+right_idx_offset ) right_triangles.append(newtri) triangles = list(left_triangles) + right_triangles right_edges = [] for edge in left_edges: newedge = [] for idx in edge: newedge.append( idx+right_idx_offset ) right_edges.append(newedge) edges = list(left_edges) + right_edges edge_slicer = {None:slice(0,len(edges),1), 'left':slice(0,len(left_edges),1), 'right':slice(len(left_edges),len(edges),1)} if 1: fd = open('precomputed_buchner71_emd_edges.py','wb') fd.write( '# Automatically generated by %s\n'%os.path.split(__name__)[-1]) save_as_python(fd, edge_slicer, 'edge_slicer', fname_extra='_buchner71' ) save_as_python(fd, edges, 'edges', fname_extra='_buchner_1971' ) fd.close()