cfg2lammps.py
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Created: Fri, May 24, 00:41

cfg2lammps.py
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	#!/usr/local/bin/python-2.5/bin/python

	Info="""
	Module name: cfg2lammps.py

	Author: (c) Andres Jaramillo-Botero
	California Institute of Technology
	ajaramil@wag.caltech.edu
	Project: pEFF
	Version: August 2009

	Reads in an eff .cfg file and produces the corresponding lammps data and input files

	NOTE: Unsupported functions will be reported in the output log

	12/2010: Added support for fixed-core and pseudo-core structures
	"""

	# import essentials:
	import sys, os
	from math import log10
	from shutil import rmtree
	from getopt import gnu_getopt as getopt
	import numpy

	def printHelp():
	print Info
	print "Usage: python cfg2lammps cfgfile\n"
	return

	general="""
	# Created %s

	# General parameters

	variable sname index %s
	log ${sname}.log

	units electron
	newton on
	boundary %s

	atom_style electron

	read_data data.${sname}

	pair_style eff/cut %s
	pair_coeff * *

	compute energies all pair eff/cut
	variable eke equal c_energies[1]
	variable epauli equal c_energies[2]
	variable estatics equal c_energies[3]
	variable errestrain equal c_energies[4]

	communicate single vel yes

	compute peratom all stress/atom
	compute p all reduce sum c_peratom[1] c_peratom[2] c_peratom[3]
	variable press equal -(c_p[1]+c_p[2]+c_p[3])/(3*vol)

	compute effTemp all temp/eff
	compute effPress all pressure effTemp

	thermo %s
	thermo_style custom step etotal pe ke v_eke v_epauli v_estatics v_errestrain temp press v_press
	thermo_modify temp effTemp press effPress
	"""
	#%(date,name,boundary,cutoff,period)

	minimize="""
	# Minimization

	min_style cg
	dump 1 %s xyz %s ${sname}.min.xyz
	dump 2 %s custom %s ${sname}.min.lammpstrj id type q spin eradius x y z fx fy fz erforce
	min_modify line quadratic
	minimize 0 1.0e-5 %s %s

	undump 1
	undump 2
	"""
	#%(group,period,group,period,iterations,fcalls)

	single_pt="""
	# Single point energy

	run 0
	"""
	dynamics="""

	# %s Dynamics

	timestep %s

	fix %s

	dump 1 %s custom %s ${sname}.%s.lammpstrj id type q spin eradius x y z
	dump 2 %s custom %s ${sname}.%s.xyz

	run %s

	unfix 1
	undump 1
	undump 2
	"""

	task={'single_pt':single_pt,'minimize':minimize,'dynamics':dynamics}

	q2m={1:'1.007940',2:'4.002602',3:'6.941000',4:'9.012182',5:'10.811000',6:'12.010700',7:'14.006700',8:'15.999400',
	9:'18.9984032',10:'20.179700',11:'22.98976928',12:'24.305000',13:'26.9815386',14:'28.085500',15:'30.973762',
	16:'32.065000',17:'35.453000',18:'39.948000'}

	def generate_lammps_input(infile):

	# Defaults values
	ensemble={"nve":"1 %s nve/eff",'nvt':"1 %s nvt/eff %s %s %s %s",'npt':"1 %s npt/eff %s %s %s %s %s %s"}
	boundary="f f f"
	xbound="-1000.000 1000.0 xlo xhi\n"
	ybound="-1000.000 1000.0 ylo yhi\n"
	zbound="-1000.000 1000.0 zlo zhi\n"
	cutoff=1000.0
	period="1"
	emass=0
	vels=""

	datafile=open("data."+infile[:-4],'w')
	scriptfile=open("in."+infile[:-4],'w')

	print "Reading %s ... [WAIT]"%infile,
	fin = open(infile,'r')
	lines = fin.xreadlines()
	print 7*"\b"+"[DONE]"

	numcores=0
	numnuclei=0
	numelec=0
	cores={}
	nuclei={}
	electrons={}
	masses=[]
	massstr="Masses\n\n"
	types=1
	q2type={}
	Tflag=False # Default ensemble is NVE
	steps='1000'

	print "Extracting run parameters from %s ... "%(infile),
	for line in lines:

	# 1st level keywords
	if line.find("@params")==0:
	flag='params'
	continue
	elif line.find("@cores")==0:
	flag='cores'
	continue
	elif line.find("@nuclei")==0:
	flag='nuclei'
	continue
	elif line.find("@electrons")==0:
	flag='electrons'
	continue
	elif line.find("@nuc_velocities")==0:
	flag='n_vels'
	continue
	elif line.find("@elec_velocities")==0:
	flag='e_vels'
	continue
	elif line.find("@nuc_masses")==0:
	flag='n_mass'
	continue
	elif line.find("@elec_masses")==0:
	flag='e_mass'
	continue
	elif line.find("@restraints")==0:
	flag='restraints'
	continue

	# 2nd level keywords
	if flag=='params':
	if line.find("calc")>=0:
	op=line.split()[2]
	if line.find("print_every")>=0:
	period=line.split()[2]
	if line.find("num_steps")>=0:
	steps=line.split()[2]
	if line.find("min_freeze")>=0:
	setforce="velocity\t% set 0.0 0.0 0.0\nfix\tfreeze %s setforce 0.0 0.0 0.0"%(line.split()[2],line.split()[2])
	if line.find("thermostat")>=0:
	tflag=True
	#ensemble="fix\t1 all nvt/eff "
	if line.find("start_temperature")>=0:
	Tstart=line.split()[2]
	#ensemble+=Tstart
	if line.find("end_temperature")>=0:
	Tstop=line.split()[2]
	#ensemble+=Tstop
	if line.find("andersen_coupling")>=0 or line.find("nose_hoover_coupling")>=0:
	Tdamp=line.split()[2]
	#ensemble+=Tdamp
	if line.find("dt")>=0:
	dt=line.split()[2]
	if line.find("electron_mass")>=0:
	emass=line.split()[2]
	if line.find("adaptive_step_size")>=0:
	continue
	if line.find("adaptive_energy")>=0:
	continue
	if line.find("e_field_freq")>=0:
	continue
	if line.find("e_field_packet_duration")>=0:
	continue
	if line.find("e_field")>=0:
	field=line.split()[2:5]
	efield="fix\field all efield %s %s %s"%(field[0],field[1],field[2])
	if line.find("e_field_packet_duration")>=0:
	continue
	if line.find("set_limit")>=0:
	continue # need to add this constraint
	if line.find("set_limit_stiffness")>=0:
	continue
	if line.find("output_position")>=0:
	dump_pos="dump\t1 all custom %s ${sname}.lammpstrj id type q spin eradius x y z "%(period)
	if line.find("output_velocities")>=0:
	dump_pos+="vx vy vz "
	if line.find("output_energy_forces")>=0:
	dump_pos="compute\tenergy all pe/atom\n"+dump_pos
	dump_pos+="c_energy fx fy fz\n"
	if line.find("output_restart")>=0:
	restart="restart\t%s ${sname}.restart1 ${sname}.restart2"%(period)
	if line.find("output_restraints")>=0:
	continue
	if line.find("ewald_re_cutoff")>=0 or line.find("ewald_autoset")>=0 or line.find("ewald_log_precision")>=0 or line.find("ewald_max_re")>=0 or \
	line.find("ewald_r_cutoff")>=0 or line.find("ewald_k_cutoff")>=0 or line.find("ewald_nuc_r")>=0:
	continue
	if line.find("periodic")>=0:
	bounds=line.split()[2]
	if bounds=="True": boundary="p p p"
	elif bounds=="minimage_x": boundary="p f f"
	elif bounds=="minimage_xy": boundary="p p f"
	elif bounds=="minimage_y": boundary="f p f"
	elif bounds=="minimage_xyz": boundary="p p p"
	elif bounds=="minimage_z": boundary="f f p"
	if line.find("x_bound")>=0:
	xbnds=line.split()[2:4]
	xbound="%s %s xlo xhi\n"%(xbnds[0],xbnds[1])
	if line.find("y_bound")>=0:
	ybnds=line.split()[2:4]
	ybound="%s %s ylo yhi\n"%(ybnds[0],ybnds[1])
	if line.find("z_bound")>=0:
	zbnds=line.split()[2:4]
	zbound="%s %s zlo zhi\n"%(zbnds[0],zbnds[1])
	if line.find("taper_cutoff")>=0:
	cutoff=line.split()[2]
	continue

	if flag=='cores' and len(line)>1:
	numcores+=1
	ln=line.split()
	nc=' '.join(ln[0:3])
	q=ln[3]
	spin='3'
	radius=ln[4]
	m=q2m[int(float(q))]
	if m not in masses:
	masses.append(m)
	massstr+="%d %s\n"%(types,m)
	q2type[q]=types
	types+=1
	cores[numcores]=[nc,q,spin,radius]
	continue

	if flag=='nuclei' and len(line)>1:
	numnuclei+=1
	ln=line.split()
	np=' '.join(ln[0:3])
	q=ln[3]
	m=q2m[int(float(q))]
	if m not in masses:
	masses.append(m)
	massstr+="%d %s\n"%(types,m)
	q2type[q]=types
	types+=1
	nuclei[numnuclei]=[np,q]
	continue

	if flag=='electrons' and len(line)>1:
	numelec+=1
	ln=line.split()
	ep=' '.join(ln[0:3])
	spin=ln[3]
	radius=ln[4]
	electrons[numelec]=[ep,spin,radius]
	if numelec==1:
	if emass!=0: massstr+="%d %s\n\n"%(types,emass) # electron mass=1
	else: massstr+="%d 1.000000\n\n"%(types)
	continue

	if flag=='n_vels' and len(line)>1:
	vels+=line+" 0.0"
	continue

	if flag=='e_vels' and len(line)>1:
	ln=line.split()
	ln[0]=ln[0]+numnuclei
	vels+=ln[0]+" "+ln[1]+" "+ln[2]+" "+ln[3]+" "+ln[4]+"\n"
	continue

	if flag=='n_mass' and len(line)>1:
	print "Setting nuclear masses is unsupported\n"
	continue

	if flag=='e_mass' and len(line)>1:
	print "Setting electron masses is unsupported\n"
	continue

	print "\bDone"

	# Build data file
	print "Writing datafile to %s ... "%('data.'+infile),
	sys.stdout.flush()
	print "\b"*19+"General section ",
	datafile.writelines("Created using cfg2lammps (c) AJB-2009\n\n%d atoms\n%d atom types\n\n%s%s%s\n"%(numcores+numnuclei+numelec,types,xbound,ybound,zbound))
	print "\b"*19+"Masses section ",
	datafile.writelines(massstr)
	print "\b"*19+"Atoms section ",
	datafile.writelines("Atoms\n\n")
	for n in range(numcores):
	datafile.writelines("%d %d %2.2f %s %s %s\n"%(n+1,q2type[cores[n+1][1]],float(cores[n+1][1]),cores[n+1][2],cores[n+1][3],cores[n+1][0]))
	for n in range(numnuclei):
	datafile.writelines("%d %d %2.2f 0 0.0 %s\n"%(n+numcores+1,q2type[nuclei[n+1][1]],float(nuclei[n+1][1]),nuclei[n+1][0]))
	for e in range(numelec):
	datafile.write("%d %d 0.0 %s %s %s\n"%(e+numnuclei+numcores+1,types,electrons[e+1][1],electrons[e+1][2],electrons[e+1][0]))
	print "\b"*19+"Velocities section\n",
	datafile.writelines(vels)
	datafile.writelines("\n")
	print "DONE .... GOODBYE !!"
	datafile.close()

	# Build input script
	import datetime
	scriptfile.writelines(general%(datetime.date.today(),infile[:-4],boundary,cutoff,period))
	if op=='minimize':
	scriptfile.writelines(minimize%('all',period,'all',period,steps,'10000'))
	#%(group,period,group,period,iterations,fcalls)
	elif op=='single_pt':
	scriptfile.writelines(single_pt%())
	elif op=='dynamics':
	if Tflag==True:
	scriptfile.writelines(dynamics%('NVT',dt,ensemble['nvt']%('all',Tstart,Tstop,Tdamp,''),'all',period,'nvt','all',period,'nve',steps))
	#%(ensemble,dt,group,ensemble%(group,tstart,tstop,tdamp,options))
	else:
	scriptfile.writelines(dynamics%('NVE',dt,ensemble['nve']%('all'),'all',period,'nve','all',period,'nve',steps))
	#%(ensemble,dt,group,ensemble%(group))
	scriptfile.writelines("\n")

	if __name__ == '__main__':

	# set defaults

	# check for input:
	opts, argv = getopt(sys.argv[1:], 'h')

	# if no input, print help and exit
	if len(argv) != 1:
	printHelp()
	sys.exit(1)
	else:
	infile=argv[0]

	# read options
	for opt, arg in opts:
	if opt == '-h': # -h: print help
	printHelp()

	generate_lammps_input(infile)

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