Mercurial > repos > bgruening > openbabel_svg_depiction
view distance_finder.py @ 10:ff95203c7e4b draft
"planemo upload for repository https://github.com/bgruening/galaxytools/tree/master/chemicaltoolbox/openbabel commit 6c84abdd07f292048bf2194073e2e938e94158c4"
author | bgruening |
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date | Wed, 25 Mar 2020 16:42:44 -0400 |
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children | d3b48303045b |
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# Reports distances of ligands to reference points. An example input for the points is: # # 5.655 1.497 18.223 # 1.494 -8.367 18.574 # 13.034 6.306 25.232 # # Data can be space or tab separated but must contain 3 and only 3 numbers for the x, y and z coordinates # # That would encode 3 points. # Each record in the SDF input is read and the closest heavy atom to each of the reference points is recorded as # a property named distance1 where the numeric part is the index (starting from 1) of the points (in that example # there would be properties for distance1, distance2 and distance3. import argparse, os, sys, math from openbabel import pybel def log(*args, **kwargs): """Log output to STDERR """ print(*args, file=sys.stderr, ** kwargs) def execute(ligands_sdf, points_file, outfile): """ :param ligands_sdf: A SDF with the 3D molecules to test :param points_file: A file with the points to consider. :param outfile: The name of the file for the SDF output :return: """ points = [] # read the points with open(points_file, 'r') as f: for line in f.readlines(): line.strip() if line: p = line.split() if len(p) == 3: points.append((float(p[0]), float(p[1]), float(p[2]))) log("Read points",p) continue log("Failed to read line:", line) log('Found', len(points), 'atom points') sdf_writer = pybel.Outputfile("sdf", outfile, overwrite=True) count = 0 for mol in pybel.readfile("sdf", ligands_sdf): count += 1 if count % 50000 == 0: log('Processed', count) try: # print("Processing mol", mol.title) clone = pybel.Molecule(mol) clone.removeh() coords = [] for atom in clone.atoms: coords.append(atom.coords) p = 0 for point in points: p += 1 distances = [] for i in coords: # calculates distance based on cartesian coordinates distance = math.sqrt((point[0] - i[0])**2 + (point[1] - i[1])**2 + (point[2] - i[2])**2) distances.append(distance) # log("distance:", distance) min_distance = min(distances) # log('Min:', min_distance) # log(count, p, min_distance) mol.data['distance' + str(p)] = min_distance sdf_writer.write(mol) except Exception as e: log('Failed to handle molecule: '+ str(e)) continue sdf_writer.close() log('Wrote', count, 'molecules') def main(): global work_dir parser = argparse.ArgumentParser(description='XChem distances - measure distances to particular points') parser.add_argument('-i', '--input', help="SDF containing the 3D molecules to score)") parser.add_argument('-p', '--points', help="PDB format file with atoms") parser.add_argument('-o', '--outfile', default='output.sdf', help="File name for results") args = parser.parse_args() log("XChem distances args: ", args) execute(args.input, args.points, args.outfile) if __name__ == "__main__": main()