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import os
import pprint
import re
from urllib import urlretrieve
import zipfile

import datetime

try:
    from subprocess import Popen, PIPE
except ImportError:
    from os import popen3
else:
    def popen3(cmd):
        p = Popen(cmd, shell=True, close_fds=True,
                  stdin=PIPE, stdout=PIPE, stderr=PIPE)
        return p.stdin, p.stdout, p.stderr

import numpy as np

import ase.io
from ase.atom import Atom
from ase.atoms import Atoms
from ase.data import atomic_numbers, chemical_symbols
from ase.data import ground_state_magnetic_moments

# Transition Metals First-row (TM1R): 10.1021/ct6001187 # 32 compounds
# Transition Metals Second-row (TM2R): 10.1021/ct700178y # 19 compounds
# Transition Metals Third-row (TM3R): 10.1021/ct800172j # 25 compounds

#http://pubs.acs.org/doi/suppl/10.1021/ct6001187/suppl_file/ct6001187-file002.pdf
#http://pubs.acs.org/doi/suppl/10.1021/ct700178y/suppl_file/ct700178y-file002.pdf
#http://pubs.acs.org/doi/suppl/10.1021/ct800172j/suppl_file/ct800172j_si_001.pdf

url_root = 'http://pubs.acs.org/doi/suppl/'
journal = '10.1021'
database_files = {
    'TM1R2006': {'doi': journal + '/ct6001187', 'module': 'TMXR200X_TM1R2006'},
    'TM2R2007': {'doi': journal + '/ct700178y', 'module': 'TMXR200X_TM2R2007'},
    'TM3R2008': {'doi': journal + '/ct800172j', 'module': 'TMXR200X_TM3R2008'},
    }

database_files['TM1R2006']['pdf'] = database_files['TM1R2006']['doi'] + '/suppl_file/ct6001187-file002.pdf'

database_files['TM2R2007']['pdf'] = database_files['TM2R2007']['doi'] + '/suppl_file/ct700178y-file002.pdf'

database_files['TM3R2008']['pdf'] = database_files['TM3R2008']['doi'] + '/suppl_file/ct800172j_si_001.pdf'

def download_file(url, filename, dir='.'):
    # do not mirror subdirectory structure of url
    outfile = os.path.join(dir, os.path.basename(filename))
    if 0: # fails, use files from disk
        urlretrieve(os.path.join(url, filename), outfile)
    return outfile

def read_geometries(filename, dir='.'):
    txt = os.path.join(dir, filename)
    fh = open(txt, 'rb')
    table = fh.read()
    firstsplit = '(in xyz format):' # TM1R2006 and TM2R2007
    dataformat = 'xyz'
    if table.find('(Gaussian archive entries):') != -1:
        firstsplit = '(Gaussian archive entries):' # TM3R2008
        dataformat = 'gaussian'
    table = table.split(firstsplit)
    table = table[1]
    # remove one or two digit numbers (page numbers/numbers of atoms in xyz format)
    table = re.sub('\n\d\d\n', '\n', table)
    table = re.sub('\n\d\n', '\n', table)
    # remove S + two digit numbers (page numbers)
    table = re.sub('\nS\d\d\n', '\n', table)
    # remove S + one digit (page numbers)
    table = re.sub('\nS\d\n', '\n', table)
    # remove empty lines
    # http://stackoverflow.com/questions/1140958/whats-a-quick-one-liner-to-remove-empty-lines-from-a-python-string
    table = os.linesep.join([s for s in table.splitlines() if s])
    geometries = []
    if dataformat == 'xyz':
        # split on new lines
        table = table.split('\n')
        # mark compound names with ':' tags
        for n, line in enumerate(table):
            if not (line.find('.') != -1):
                # remove method/basis set information
                table[n] = table[n].replace(' BP86/qzvp', '')
                table[n] = ':' + table[n] + ':'
        table = '\n'.join([s for s in table])
        # split into compounds
        # http://simonwillison.net/2003/Oct/26/reSplit/
        # http://stackoverflow.com/questions/647655/python-regex-split-and-special-character
        table = re.compile('(:.*:)').split(table)
        # remove empty elements
        table = [l.strip() for l in table]
        table = [l for l in table if len(l) > 1]
        # extract compounds
        for n in range(0, len(table), 2):
            compound = table[n].replace(':', '').replace(' ', '_')
            geometry = []
            for atom in table[n+1].split('\n'):
                geometry.append(Atom(symbol=atom.split()[0], position=atom.split()[1:]))
            atoms = Atoms(geometry)
            # set the charge and magnetic moment on the heaviest atom (better ideas?)
            heaviest = max([a.get_atomic_number() for a in atoms])
            heaviest_index = [a.get_atomic_number() for a in atoms].index(heaviest)
            charge = 0.0
            if abs(charge) > 0.0:
                charges = [0.0 for a in atoms]
                charges[heaviest_index] = charge
                atoms.set_charges(charges)
            if compound in [ # see corresponding articles
                'Ti(BH4)3',  # TM1R2006
                'V(NMe2)4',  # TM1R2006
                'Cu(acac)2',  # TM1R2006
                'Nb(Cp)(C7H7)_Cs', # TM2R2007
                'CdMe_C3v', # TM2R2007
                ]:
                multiplicity = 2.0
            else:
                multiplicity = 1.0
            if multiplicity > 1.0:
                magmoms = [0.0 for a in atoms]
                magmoms[heaviest_index] = multiplicity - 1
                atoms.set_initial_magnetic_moments(magmoms)
            geometries.append((compound, atoms))
    elif dataformat == 'gaussian':
        # remove new lines
        table = table.replace('\n', '')
        # fix: MeHg(Cl) written as MeHg(CN)
        table = table.replace(
            'MeHg(CN), qzvp (SDD/def-qzvp for metal)\\\\0,1\\Hg,0.,0.,0.1975732257',
            'MeHg(Cl), qzvp (SDD/def-qzvp for metal)\\\\0,1\\Hg,0.,0.,0.1975732257')
        # split on compound end marks
        table = table.split('\\\@')
        # remove empty elements
        table = [l.strip() for l in table]
        table = [l for l in table if len(l) > 1]
        # extract compounds
        for n, line in enumerate(table):
            # split on gaussian separator '\\'
            entries = line.split('\\\\')
            compound = entries[2].split(',')[0].split(' ')[0]
            # charge and multiplicity from gaussian archive
            charge, multiplicity = entries[3].split('\\')[0].split(',')
            charge = float(charge)
            multiplicity = float(multiplicity)
            if compound in ['Au(Me)PMe3']: # in gzmat format!
                # check openbabel version (babel >= 2.2 needed)
                cmd = popen3('babel -V')[1]
                output = cmd.read().strip()
                cmd.close()
                v1, v2, v3 = output.split()[2].split('.')
                v1, v2, v3 = int(v1), int(v2), int(v3)
                if not (v1 > 2 or ((v1 == 2) and (v2 >= 2))):
                    print compound + ': skipped - version of babel does not support gzmat format'
                    continue # this one is given in z-matrix format
                finame = compound.replace('(', '').replace(')', '') + '.orig'
                foname = finame.split('.')[0] + '.xyz'
                fi = open(finame, 'w')
                fo = open(foname, 'w')
                if 1: # how to extract zmat by hand
                    zmat = ['#'] # must start with gaussian input start
                    zmat.extend('@') # separated by newline
                    zmat.extend([compound])
                    zmat.extend('@') # separated by newline
                    zmat.extend([str(int(charge)) + ' ' + str(int(multiplicity))])
                    zmat.extend(entries[3].replace(',', ' ').split('\\')[1:])
                    zmat.extend('@') # atom and variable definitions separated by newline
                    zmat.extend(entries[4].split('\\'))
                    zmat.extend('@') # end with newline
                    for l in zmat:
                        fi.write(l.replace('@', '').replace('=', ' ') + '\n')
                    fi.close()
                if 0:
                    # or use the whole gausian archive entry
                    entries = ''.join(entries)
                    fi.write(entries)
                # convert gzmat into xyz using openbabel (babel >= 2.2 needed)
                cmd = popen3('babel -i gzmat ' + finame + ' -o xyz ' + foname)[2]
                error = cmd.read().strip()
                cmd.close()
                fo.close()
                if not (error.find('0 molecules') != -1):
                    atoms = ase.io.read(foname)
                else:
                    print compound + ': babel conversion failed'
                    continue # conversion failed
            else:
                positions = entries[3].replace(',', ' ').split('\\')[1:]
                geometry = []
                for k, atom in enumerate(positions):
                    geometry.append(Atom(symbol=atom.split()[0],
                                         position=[float(p) for p in atom.split()[1:]]))
                atoms = Atoms(geometry)
            #
            # set the charge and magnetic moment on the heaviest atom (better ideas?)
            heaviest = max([a.get_atomic_number() for a in atoms])
            heaviest_index = [a.get_atomic_number() for a in atoms].index(heaviest)
            if abs(charge) > 0.0:
                charges = [0.0 for a in atoms]
                charges[heaviest_index] = charge
                atoms.set_charges(charges)
            if multiplicity > 1.0:
                magmoms = [0.0 for a in atoms]
                magmoms[heaviest_index] = multiplicity - 1
                atoms.set_initial_magnetic_moments(magmoms)
            geometries.append((compound, atoms))
    return geometries

def pdftotext(filename):
    os.system('pdftotext -raw -nopgbrk '+ filename)
    return os.path.splitext(filename)[0] + '.txt'

from ase.data.gmtkn30 import format_data

def main():
    if not os.path.isdir('TMXR200X'):
        os.makedirs('TMXR200X')
    #for database in ['TM1R2006']:
    for database in database_files.keys():
        fh = open(database_files[database]['module'].lower() + '.py', 'w')
        fh.write('# Computer generated code! Hands off!\n')
        fh.write('# Generated: ' + str(datetime.date.today()) + '\n')
        fh.write('from numpy import array\n')
        fh.write('data = ')
        data = {} # specification of molecules
        info = {} # reference/calculation info
        # download structures
        file = database_files[database]['pdf']
        f = os.path.abspath(download_file(url_root, file, dir='TMXR200X'))
        f = pdftotext(f)
        geometries = read_geometries(f)
        # set number of unpaired electrons and charges
        no_unpaired_electrons = []
        charges = []
        for a in geometries:
            magmom = sum(a[1].get_initial_magnetic_moments())
            if magmom > 0.0:
                no_unpaired_electrons.append((a[0], magmom))
            charge = sum(a[1].get_charges())
            if abs(charge) > 0.0:
                charges.append((a[0], charge))
        data = format_data(database, geometries, no_unpaired_electrons, charges)
        # all constituent atoms
        atoms = []
        for formula, geometry in geometries:
            atoms.extend(list(set(geometry.get_chemical_symbols())))
        atoms=list(set(atoms))
        atoms.sort()
        for atom in atoms:
            magmom=ground_state_magnetic_moments[atomic_numbers[atom]]
            data[atom] = {
                'database': database,
                'name': atom,
                'symbols': atom,
                'magmoms': [magmom], # None or list
                'charges': None, # None or list
                'positions': np.array([[0.0]*3]),
                }
            Atom(atom, magmom=magmom)
        pprint.pprint(data, stream=fh)
        fh.close()

if __name__ == '__main__':
    main()