# Copyright (c) 2020-2022 NVIDIA CORPORATION & AFFILIATES. All rights reserved. # # NVIDIA CORPORATION, its affiliates and licensors retain all intellectual # property and proprietary rights in and to this material, related # documentation and any modifications thereto. Any use, reproduction, # disclosure or distribution of this material and related documentation # without an express license agreement from NVIDIA CORPORATION or # its affiliates is strictly prohibited. import os import torch from . import texture from . import mesh from . import material ###################################################################################### # Utility functions ###################################################################################### def _find_mat(materials, name): for mat in materials: if mat['name'] == name: return mat return materials[0] # Materials 0 is the default ###################################################################################### # Create mesh object from objfile ###################################################################################### def load_obj(filename, clear_ks=True, mtl_override=None, mtl_default=None, use_default=False, no_additional=False): obj_path = os.path.dirname(filename) # Read entire file with open(filename, 'r') as f: lines = f.readlines() # Load materials if mtl_default is None: all_materials = [ { 'name' : '_default_mat', 'bsdf' : 'pbr', 'kd' : texture.Texture2D(torch.tensor([0.5, 0.5, 0.5], dtype=torch.float32, device='cuda')), 'ks' : texture.Texture2D(torch.tensor([0.0, 0.0, 0.0], dtype=torch.float32, device='cuda')) } ] else: print("Load use-defined default mtl") all_materials = [mtl_default] if not no_additional: if mtl_override is None: for line in lines: if len(line.split()) == 0: continue if line.split()[0] == 'mtllib': all_materials += material.load_mtl(os.path.join(obj_path, line.split()[1]), clear_ks, avoid_pure_black=True) # Read in entire material library else: all_materials += material.load_mtl(mtl_override) else: print("Skip loading non-default materials") # load vertices vertices, texcoords, normals = [], [], [] for line in lines: if len(line.split()) == 0: continue prefix = line.split()[0].lower() if prefix == 'v': vertices.append([float(v) for v in line.split()[1:]]) elif prefix == 'vt': val = [float(v) for v in line.split()[1:]] texcoords.append([val[0], 1.0 - val[1]]) elif prefix == 'vn': normals.append([float(v) for v in line.split()[1:]]) print(all_materials) # load faces activeMatIdx = None used_materials = [] faces, tfaces, nfaces, mfaces = [], [], [], [] for line in lines: if len(line.split()) == 0: continue prefix = line.split()[0].lower() if prefix == 'usemtl': # Track used materials mat = _find_mat(all_materials, line.split()[1]) if not mat in used_materials: used_materials.append(mat) activeMatIdx = used_materials.index(mat) elif prefix == 'f': # Parse face vs = line.split()[1:] nv = len(vs) vv = vs[0].split('/') v0 = int(vv[0]) - 1 # t1 = int(vv[1]) - 1 if vv[1] != "" else -1 # n1 = int(vv[2]) - 1 if vv[2] != "" else -1 try: t0 = int(vv[1]) - 1 if vv[1] != "" else -1 n0 = int(vv[2]) - 1 if vv[2] != "" else -1 except: t0 = n0 = -1 for i in range(nv - 2): # Triangulate polygons vv = vs[i + 1].split('/') v1 = int(vv[0]) - 1 # t1 = int(vv[1]) - 1 if vv[1] != "" else -1 # n1 = int(vv[2]) - 1 if vv[2] != "" else -1 try: t1 = int(vv[1]) - 1 if vv[1] != "" else -1 n1 = int(vv[2]) - 1 if vv[2] != "" else -1 except: t1 = n1 = -1 vv = vs[i + 2].split('/') v2 = int(vv[0]) - 1 # t2 = int(vv[1]) - 1 if vv[1] != "" else -1 # n2 = int(vv[2]) - 1 if vv[2] != "" else -1 try: t2 = int(vv[1]) - 1 if vv[1] != "" else -1 n2 = int(vv[2]) - 1 if vv[2] != "" else -1 except: t2 = n2 = -1 mfaces.append(activeMatIdx) faces.append([v0, v1, v2]) tfaces.append([t0, t1, t2]) nfaces.append([n0, n1, n2]) assert len(tfaces) == len(faces) and len(nfaces) == len (faces) # # Create an "uber" material by combining all textures into a larger texture # # if len(used_materials) > 1: # if True: # uber_material, texcoords, tfaces = material.merge_materials(used_materials, texcoords, tfaces, mfaces) # elif len(used_materials) == 1: # uber_material = used_materials[0] # else: # uber_material = None vertices = torch.tensor(vertices, dtype=torch.float32, device='cuda') # texcoords = torch.tensor(texcoords, dtype=torch.float32, device='cuda') if len(texcoords) > 0 else None # normals = torch.tensor(normals, dtype=torch.float32, device='cuda') if len(normals) > 0 else None # # normals = None faces = torch.tensor(faces, dtype=torch.int64, device='cuda') # tfaces = torch.tensor(tfaces, dtype=torch.int64, device='cuda') if texcoords is not None else None # nfaces = torch.tensor(nfaces, dtype=torch.int64, device='cuda') if normals is not None else None # print(uber_material) uber_material = all_materials[0] texcoords = normals = tfaces = nfaces = None # return mesh.Mesh(vertices, faces, normals, nfaces, texcoords, tfaces, material=uber_material) imesh = mesh.Mesh(vertices, faces, normals, nfaces, texcoords, tfaces, material=uber_material) imesh = mesh.auto_normals(imesh) return imesh ###################################################################################### # Save mesh object to objfile ###################################################################################### def write_obj(folder, mesh, save_material=True): obj_file = os.path.join(folder, 'mesh.obj') print("Writing mesh: ", obj_file) with open(obj_file, "w") as f: # f.write("mtllib mesh.mtl\n") f.write("g default\n") v_pos = mesh.v_pos.detach().cpu().numpy() if mesh.v_pos is not None else None # v_nrm = mesh.v_nrm.detach().cpu().numpy() if mesh.v_nrm is not None else None # v_tex = mesh.v_tex.detach().cpu().numpy() if mesh.v_tex is not None else None v_nrm = None v_tex = None t_pos_idx = mesh.t_pos_idx.detach().cpu().numpy() if mesh.t_pos_idx is not None else None # t_nrm_idx = mesh.t_nrm_idx.detach().cpu().numpy() if mesh.t_nrm_idx is not None else None # t_tex_idx = mesh.t_tex_idx.detach().cpu().numpy() if mesh.t_tex_idx is not None else None print(" writing %d vertices" % len(v_pos)) for v in v_pos: f.write('v {} {} {} \n'.format(v[0], v[1], v[2])) # if v_tex is not None: # print(" writing %d texcoords" % len(v_tex)) # assert(len(t_pos_idx) == len(t_tex_idx)) # for v in v_tex: # f.write('vt {} {} \n'.format(v[0], 1.0 - v[1])) # if v_nrm is not None: # print(" writing %d normals" % len(v_nrm)) # assert(len(t_pos_idx) == len(t_nrm_idx)) # for v in v_nrm: # f.write('vn {} {} {}\n'.format(v[0], v[1], v[2])) # faces f.write("s 1 \n") f.write("g pMesh1\n") f.write("usemtl defaultMat\n") # Write faces print(" writing %d faces" % len(t_pos_idx)) for i in range(len(t_pos_idx)): f.write("f ") for j in range(3): f.write(' %s/%s/%s' % (str(t_pos_idx[i][j]+1), '' if v_tex is None else str(t_tex_idx[i][j]+1), '' if v_nrm is None else str(t_nrm_idx[i][j]+1))) f.write("\n") if save_material: mtl_file = os.path.join(folder, 'mesh.mtl') print("Writing material: ", mtl_file) material.save_mtl(mtl_file, mesh.material) print("Done exporting mesh")