import argparse, io, math, struct # setup parser parser = argparse.ArgumentParser(description='The Mesh Converter.') parser.add_argument('-p', '--in-vpos', required=True, type=str, action='store', dest='in_vpos', metavar='vpos.bin') parser.add_argument('-n', '--in-vbml', required=True, type=str, action='store', dest='in_vnml', metavar='vnml.bin') parser.add_argument('-u', '--in-vuv', required=True, type=str, action='store', dest='in_vuv', metavar='vuv.bin') parser.add_argument('-i', '--in-findices', required=True, type=str, action='store', dest='in_findices', metavar='findices.bin') parser.add_argument('-o', '--out-obj', required=True, type=str, action='store', dest='out_obj', metavar='mesh.obj') parser.add_argument('-m', '--out-mtl', required=True, type=str, action='store', dest='out_mtl', metavar='mesh.mtl') Vector = tuple[float] Indices = tuple[int] def GetFileLength(fs: io.BufferedReader) -> int: pos = fs.tell() fs.seek(0, io.SEEK_END) fsize = fs.tell() fs.seek(pos, io.SEEK_SET) return fsize def EvaluateCount(filename: str, unit_size: int) -> int: with open(filename, 'rb') as fs: filesize = GetFileLength(fs) count, modrem = divmod(filesize, unit_size) if modrem != 0: raise Exception("invalid file length") return count def AssertFileSize(fs: io.BufferedReader, expected_size: int): if expected_size != GetFileLength(fs): raise Exception("invalid file length") def ReadFloats(filename: str, count: int) -> tuple[float]: with open(filename, 'rb') as fs: # construct class cstruct = struct.Struct(f'<{count}f') # assert file size AssertFileSize(fs, cstruct.size) # read return cstruct.unpack(fs.read(cstruct.size)) def ReadShorts(filename: str, count: int) -> tuple[float]: with open(filename, 'rb') as fs: # construct class cstruct = struct.Struct(f'<{count}H') # assert file size AssertFileSize(fs, cstruct.size) # read return cstruct.unpack(fs.read(cstruct.size)) def RecoupleTuple(fulllist: tuple, couple_count: int) -> tuple[tuple]: count, modrem = divmod(len(fulllist), couple_count) if modrem != 0: raise Exception("invalid tuple length") return tuple(map(lambda x: tuple(fulllist[x * couple_count:x * couple_count + couple_count]), range(count))) def GenerateObj(filename: str, vpos: tuple[Vector], vnml: tuple[Vector], vuv: tuple[Vector], findices: tuple[Indices]): with open(filename, 'w', encoding='utf-8') as fs: for v in vpos: fs.write('v {0} {1} {2}\n'.format(v[0], v[1], v[2])) for v in vnml: fs.write('vn {0} {1} {2}\n'.format(v[0], v[1], v[2])) for v in vuv: fs.write('vt {0} {1}\n'.format(v[0], v[1])) for f in findices: fs.write('f {0}/{0}/{0} {1}/{1}/{1} {2}/{2}/{2}\n'.format(f[0] + 1, f[1] + 1, f[2] + 1)) fs.write('g obj\n') if __name__ == '__main__': # parse arg args = parser.parse_args() #input("Prepare VertexPositions please.") vertexcount = EvaluateCount(args.in_vpos, 3 * 4) # 3 float(4 bytes) print(f'Vertex Count Evaluated: {vertexcount}') vpos = RecoupleTuple(ReadFloats(args.in_vpos, 3 * vertexcount), 3) #input("Prepare VertexNormals please.") vnml = RecoupleTuple(ReadFloats(args.in_vnml, 3 * vertexcount), 3) #input("Prepare VertexUVs please.") vuv = RecoupleTuple(ReadFloats(args.in_vuv, 2 * vertexcount), 2) #input("Prepare FaceIndices please.") facecount = EvaluateCount(args.in_findices, 3 * 2) # 3 WORD(2 bytes) print(f'Face Count Evaluated: {facecount}') findices = RecoupleTuple(ReadShorts(args.in_findices, 3 * facecount), 3) GenerateObj(args.out_obj, vpos, vnml, vuv, findices) print('Done')