Save2traj: Difference between revisions
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'''Note:''' See [[save_traj]] for an improved version of this script. | |||
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===Description=== | ===Description=== | ||
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#Read COORDINATES | #Read COORDINATES | ||
for | for frame in range(frames): | ||
fmt=str(NATOMS)+'f' | fmt=str(NATOMS)+'f' | ||
x=readFortran(f,fmt) | x=readFortran(f,fmt) |
Latest revision as of 06:20, 25 February 2019
Note: See save_traj for an improved version of this script.
Description
WARNING: This script is still under development so please use at your own risk!
This script can be used to generate a DCD trajectory file after you have loaded multiple states into a single object.
Currently, the only supported trajectory format is DCD but there will be support for other formats in the future.
USAGE
load the script using the run command
save2traj (selection, name)
"name" corresponds to the output name and ".dcd" will be appended to the end of the name automatically.
The trajectory file that is generated could be numbered differently than your PDB file since PyMOL modifies the RESID values. Thus, it may be necessary to open your original PDB file and save the molecule (with modified RESIDs) to a new file. Then, load the trajectory into that new file. Alternatively, one could retain the RESIDs as well before importing a PDB structure.
EXAMPLES
save2traj 1bna & c. A+B, output
This will select chains A and B from the object 1bna and save the selection from each state into the trajectory file called "output.dcd".
Script
WARNING: This script is still under development so please use at your own risk!
from pymol import cmd
from pymol import stored
import struct
def save2traj (selection,name,format="dcd"):
#Author: Sean Law
#Michigan State University
#Get NATOMS, NSTATES
NATOMS=cmd.count_atoms(selection)
NSTATES=cmd.count_states()
#Determine Trajectory Format
format=format.lower()
if (format == "charmm"):
name=name+".dcd"
elif (format == "amber"):
print "The amber format has not been implemented yet"
return
name=name+".trj"
elif (format == "trj"):
print "The amber format has not been implemented yet"
return
name=name+".trj"
format="amber"
else:
name=name+".dcd"
format="charmm"
f=open(name,'wb')
#Write Trajectory Header Information
if (format == "charmm"):
writeCHARMMheader(f,NSTATES,NATOMS)
elif (format == "amber"):
print "The amber format has not been implemented yet"
return
else:
print "Unknown format"
return
#Write Trajectory Coordinates
if (format == "charmm"):
fmt=str(NATOMS)+'f'
for state in range(cmd.count_states()):
stored.xyz=[]
cmd.iterate_state(state,selection,"stored.xyz.append([x,y,z])")
for xyz in range (3):
coor=[]
for atom in range (NATOMS):
coor.append(stored.xyz[atom][xyz])
writeFortran(f,coor,fmt,length=NATOMS*4)
elif (format == "amber"):
print "The amber format has not been implemented yet"
return
else:
print "Unknown format"
return
f.close()
return
cmd.extend("save2traj",save2traj)
def writeCHARMMheader (f,NSTATES,NATOMS):
header=['CORD']
fmt='4s9i1f10i'
icontrol=[]
for i in range(20):
#Initialize icontrol
icontrol.insert(i,0)
icontrol[0]=NSTATES
icontrol[1]=1
icontrol[2]=1
icontrol[3]=NSTATES
icontrol[7]=NATOMS*3-6
icontrol[9]=2.045473
icontrol[19]=27
for i in range(20):
header.append(icontrol[i])
writeFortran(f,header,fmt)
#Title
fmt='i80s80s'
title=[2]
title.append('* TITLE')
while (len(title[1])<80):
title[1]=title[1]+' '
title.append('* Generated by savetraj.py (Author: Sean Law)')
while (len(title[2])< 80):
title[2]=title[2]+' '
writeFortran(f,title,fmt,length=160+4)
#NATOM
fmt='i'
writeFortran(f,[NATOMS],fmt)
return
cmd.extend("writeCHARMMheader",writeCHARMMheader)
def readtraj (name):
f=open(name,'rb')
#Read Header
fmt='4s9i1f10i'
header=readFortran(f,fmt)
frames=header[1]
#Read Title
readCHARMMtitle(f)
#Read NATOMS
fmt='i'
[NATOMS]=readFortran(f,fmt)
#Read COORDINATES
for frame in range(frames):
fmt=str(NATOMS)+'f'
x=readFortran(f,fmt)
y=readFortran(f,fmt)
z=readFortran(f,fmt)
f.close()
return
cmd.extend("readtraj",readtraj)
def writeFortran (f,buffer,fmt,length=0):
if (length == 0):
length=len(buffer)*4
f.write(struct.pack('i',length)) #Fortran unformatted
f.write(struct.pack(fmt,*(buffer)))
f.write(struct.pack('i',length)) #Fortran unformatted
return
cmd.extend("writeFortran",writeFortran)
def readFortran (f,fmt):
[bytes]=struct.unpack('i',f.read(4))
buffer=struct.unpack(fmt,f.read(bytes))
[bytes]=struct.unpack('i',f.read(4))
return buffer
cmd.extend("readFortran",readFortran)
def readCHARMMtitle(f):
[bytes]=struct.unpack('i',f.read(4))
[lines]=struct.unpack('i',f.read(4))
fmt=''
for line in range(lines):
fmt=fmt+'80s'
buffer=(struct.unpack(fmt,f.read(80*lines)))
[bytes]=struct.unpack('i',f.read(4))
#print buffer
return
cmd.extend("readCHARMMtitle",readCHARMMtitle)