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pyscf.py
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pyscf.py
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"""
/******************************************************************************
This source file is part of the Avogadro project.
This source code is released under the New BSD License, (the "License").
******************************************************************************/
"""
import argparse
import json
import sys
# Some globals:
targetName = 'PYSCF'
extension = 'py'
debug = False
basis_list = ['STO-3G', '3-21g', 'cc-pvdz']
theory_list = ['RHF', 'ROHF', 'UHF', 'MP2']
def getOptions():
userOptions = {}
userOptions['Title'] = {}
userOptions['Title']['type'] = 'string'
userOptions['Title']['default'] = ''
userOptions['Calculation Type'] = {}
userOptions['Calculation Type']['type'] = 'stringList'
userOptions['Calculation Type']['default'] = 0
userOptions['Calculation Type']['values'] = \
['Single Point']
userOptions['Theory'] = {}
userOptions['Theory']['type'] = 'stringList'
userOptions['Theory']['default'] = 0
userOptions['Theory']['values'] = theory_list
userOptions['Basis'] = {}
userOptions['Basis']['type'] = 'stringList'
userOptions['Basis']['default'] = 0
userOptions['Basis']['values'] = basis_list
userOptions['Filename Base'] = {}
userOptions['Filename Base']['type'] = 'string'
userOptions['Filename Base']['default'] = 'job'
userOptions['Charge'] = {}
userOptions['Charge']['type'] = 'integer'
userOptions['Charge']['default'] = 0
userOptions['Charge']['minimum'] = -9
userOptions['Charge']['maximum'] = 9
userOptions['Multiplicity'] = {}
userOptions['Multiplicity']['type'] = 'integer'
userOptions['Multiplicity']['default'] = 1
userOptions['Multiplicity']['minimum'] = 1
userOptions['Multiplicity']['maximum'] = 6
opts = {'userOptions': userOptions}
opts['inputMoleculeFormat'] = 'cjson'
return opts
def generateInputFile(cjson, opts):
title = opts['Title']
calculate = opts['Calculation Type']
theory = opts['Theory']
basis = opts['Basis']
charge = opts['Charge']
multiplicity = opts['Multiplicity']
# Convert to code-specific strings
basisStr = ''
if basis in basis_list:
if basis == '3-21g':
pybasis = '321g'
basisStr = pybasis
if basis == 'cc-pvdz':
pybasis = 'ccpvdz'
basisStr = pybasis
else:
basisStr = basis
else:
raise Exception('Unhandled basis type: {}'.format(basis))
theoryImport = ''
theoryLines = []
# Intentionally not using elif here:
if theory == 'RHF':
theoryImport = "from pyscf import gto,scf\n"
theoryLines.append('mf = scf.{}(mol)\n'.format(theory))
theoryLines.append('mf.kernel()\n')
elif theory == 'ROHF':
theoryImport = "from pyscf import gto,scf\n"
theoryLines.append('mf = scf.{}(mol)\n'.format(theory))
theoryLines.append('Amf.kernel()\n')
elif theory == 'UHF':
theoryImport = "from pyscf import gto,scf\n"
theoryLines.append('mf = scf.{}(mol)\n'.format(theory))
theoryLines.append('mf.kernel()\n')
elif theory == 'MP2':
theoryImport = "from pyscf import gto,scf,mp\n"
theoryLines.append('# Must run SCF before MP2 in PYSCF\n')
if multiplicity == 1:
theoryLines.append('mf = scf.RHF(mol)\n')
theoryLines.append('mf.kernel()\n')
theoryLines.append('mf2 = mp.{}(mf)\n'.format(theory))
theoryLines.append('mf2.kernel()\n')
else:
theoryLines.append('mf = scf.UHF(mol)\n')
theoryLines.append('mf.kernel()\n')
theoryLines.append('mf2 = mp.{}(mf)\n'.format(theory))
theoryLines.append('mf2.kernel()\n')
else:
raise Exception('Unhandled theory type:'.format(theory))
calcStr = ''
if calculate == 'Single Point':
pass
else:
raise Exception('Unhandled calculation type:'.format(calculate))
# Create input file
output = ''
output += "# Title: {}\n".format(title)
output += "{}".format(theoryImport)
output += "mol = gto.Mole()\n"
output += "mol.atom = '''\n"
output += '$$coords:___Sxyz$$\n'
output += "'''\n"
output += 'mol.basis = \'{}\'\n'.format(basisStr)
output += 'mol.charge = {}\n'.format(charge)
output += 'mol.spin = {}\n'.format(multiplicity - 1)
output += 'mol.build()\n'
for line in theoryLines:
output += line
return output
def generateInput():
# Read options from stdin
stdinStr = sys.stdin.read()
# Parse the JSON strings
opts = json.loads(stdinStr)
# Generate the input file
inp = generateInputFile(opts['cjson'], opts['options'])
# Basename for input files:
baseName = opts['options']['Filename Base']
# Prepare the result
result = {}
# Input file text -- will appear in the same order in the GUI as they are
# listed in the array:
files = []
files.append({'filename': '{}.{}'.format(
baseName, extension), 'contents': inp})
if debug:
files.append({'filename': 'debug_info', 'contents': stdinStr})
result['files'] = files
# Specify the main input file. This will be used by MoleQueue to determine
# the value of the $$inputFileName$$ and $$inputFileBaseName$$ keywords.
result['mainFile'] = '{}.{}'.format(baseName, extension)
return result
if __name__ == "__main__":
parser = argparse.ArgumentParser(
'Generate a {} input file.'.format(targetName))
parser.add_argument('--debug', action='store_true')
parser.add_argument('--print-options', action='store_true')
parser.add_argument('--generate-input', action='store_true')
parser.add_argument('--display-name', action='store_true')
parser.add_argument('--lang', nargs='?', default='en')
args = vars(parser.parse_args())
debug = args['debug']
if args['display_name']:
print(targetName)
if args['print_options']:
print(json.dumps(getOptions()))
elif args['generate_input']:
print(json.dumps(generateInput()))