Exemple #1
0
def save_triangulated(V, Vint, F, outputdir, outputfile):
    logger.debug("triangulation")
    Ftr = triangulate_quads(F)
    if outputfile is not None:
        outputfile = os.path.join(outputdir, outputfile)
        writeFile(outputfile + "_sm_i_tr.obj", Vint, Ftr)
        writeFile(outputfile + "_sm_tr.obj", V, Ftr)
    return Ftr
def main():

    logger = logging.getLogger()
    logger.setLevel(logging.WARNING)
    ch = logging.StreamHandler()
    logger.addHandler(ch)

    # logger.debug('input params')

    # input parser
    parser = argparse.ArgumentParser(description="Laplacian smoothing")
    parser.add_argument('-i',
                        '--inputfile',
                        default=None,
                        required=True,
                        help='input file')
    parser.add_argument('-o',
                        '--outputfile',
                        default='smooth.obj',
                        help='input file')
    parser.add_argument('-v',
                        '--visualization',
                        action='store_true',
                        help='Use visualization')
    parser.add_argument('-d',
                        '--debug',
                        action='store_true',
                        help='Debug mode')

    args = parser.parse_args()
    if args.debug:
        logger.setLevel(logging.DEBUG)

    t0 = time.time()
    V, FV = readFile(args.inputfile)

    t1 = time.time()
    logger.info('Data imported                   %ss. #V: %i, #FV: %i' %
                (str(t1 - t0), len(V), len(FV)))

    # V2 = makeSmoothing(V, FV)
    V2 = iterativeLaplacianSmoothing(V, FV)

    if args.visualization:
        # t7 = time.time()
        # FV = triangulateSquares(FV)
        # tv1 = time.time()
        # logger.info('triangulation               %ss' %
        #             (str(tv1 - t7)))
        VIEW(STRUCT(MKPOLS((V2, FV))))


# write outputs
    writeFile(args.outputfile + '.pkl', V2, FV)
    writeFile(args.outputfile, V2, FV)
    logger.info("Data stored to ' %s" % (args.outputfile))
Exemple #3
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def main():
    logger = logging.getLogger()
    logger.setLevel(logging.WARNING)
    ch = logging.StreamHandler()
    logger.addHandler(ch)

    # logger.debug('input params')

    # input parser
    parser = argparse.ArgumentParser(
        description="Remove faces from file"
    )
    parser.add_argument(
        '-i', '--inputfile',
        default=None,
        required=True,
        help='input file'
    )
    parser.add_argument(
        '-o', '--outputfile',
        default=None,
        required=True,
        help='output file'
    )
    parser.add_argument(
        '-b', '--boxsize',
        default=None,
        type=int,
        metavar='N',
        nargs='+',
        help='Size of box'
    )
    parser.add_argument(
        '-a', '--alberto', action='store_true',
        help='Albertos algorithm')
    parser.add_argument(
        '-d', '--debug', action='store_true',
        help='Debug mode')
    args = parser.parse_args()
    if args.debug:
        logger.setLevel(logging.DEBUG)
    v, f = readFile(args.inputfile)
    print "Before"
    print "Number of vertexes: %i    Number of faces %i" % (len(v), len(f))
    # findBoxVertexesForAxis(v, 2, 0)
    # v, f = findBoundaryFaces(v, f, 2)
    v, f = removeDoubleVertexesAndFaces(v, f, args.boxsize,
                                        use_dict_algorithm=args.alberto)
    writeFile(args.outputfile, v, f)
    print "After"
    print "Number of vertexes: %i    Number of faces %i" % (len(v), len(f))
Exemple #4
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def makeCleaningAndSmoothing(V, F, outputfile=None):
    logger.debug("outputfile " + str(outputfile))
    # findBoxVertexesForAxis(v, 2, 0)
    # v, f = findBoundaryFaces(v, f, 2)

    # @TODO debug dict algorithm
    V, F = rmbox.removeDoubleVertexesAndFaces(V, F, use_dict_algorithm=False)
    if outputfile is not None:
        writeFile(outputfile + "_cl.obj", V, F)
    V = ls.makeSmoothing(V, F)
    # @TODO remove unused vertexes is too general and slow
    V, F = rmbox.removeDoubleVertexesAndFaces(V, F, use_dict_algorithm=False)
    V, F = __remove_first_vertex(V, F)

    if outputfile is not None:
        writeFile(outputfile + "_sm.obj",
                  V,
                  F,
                  ignore_empty_vertex_warning=True)
    return V, F
Exemple #5
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def makeSmooth(inputfile,
               bordersize=[2, 2, 2],
               outputdir='output',
               outputfile='out',
               visualization=False,
               borderdir='border',
               make_triangulation=True,
               label=2,
               smoothing=True):
    """

    :param inputfile: path to input data. It can be tiff, pklz, dicom or other 3d file or
     directory with dicom files or jpegs
    :param bordersize: Data are processed per partes. bordersize specify size of one part
    :param outputdir: directory with output stl files and temporary files. Acronyms in file names are:
    sm - smoothing, i - converted to integer, tr - triangulation, cl - cleaning done, do double faces.
    :param outputfile: name of outpu file
    :param visualization: output can be visualized by setting this parametr True
    :param borderdir: temporary directory with bordermatrix computation
    :param make_triangulation:
    :param label: expected value in object pixels of input data
    :return:
    """
    filepath, ext = os.path.splitext(inputfile)
    if ext == "obj":
        obj_input = inputfile
    else:
        print 'Processing pklz data'
        convert(inputfile,
                bordersize,
                outputdir,
                borderdir=borderdir,
                label=label)
        obj_input = 'stl/model-2.obj'
    # V, F = readFile(args.inputfile)
    V, F = readFile(os.path.join(outputdir, obj_input))
    print "Before"
    print "Number of vertexes: %i    Number of faces %i" % (len(V), len(F))
    # F = rmbox.shiftFaces(F, -1)
    V, F = makeCleaningAndSmoothing(V, F, os.path.join(outputdir, outputfile),
                                    smoothing)
    print "After"
    print "Number of vertexes: %i    Number of faces %i" % (len(V), len(F))
    # write to ints
    # fill empty vertexes
    V = [v if len(v) == 3 else [0, 0, 0] for v in V]
    # make tenimes bigger
    Vint = (np.asarray(V) * 10).astype(np.int).tolist()
    if outputfile is not None:
        writeFile(os.path.join(outputdir, outputfile + "_sm_i.obj"),
                  Vint,
                  F,
                  ignore_empty_vertex_warning=True)


# make triangulation
    if make_triangulation:
        Ftr = save_triangulated(V, Vint, F, outputdir, outputfile)

    if visualization:
        Ftr = triangulate_quads(F)
        vis.visualize(V, Ftr)

    return V, F