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IO.py
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IO.py
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#######################
## 8 # STRUCTURE I/O ## -> @IO <-
#######################
import logging, math, random, sys
import MAP, SS, FUNC
#----+---------+
## A | PDB I/O |
#----+---------+
d2r = 3.14159265358979323846264338327950288/180
# Reformatting of lines in structure file
pdbBoxLine = "CRYST1%9.3f%9.3f%9.3f%7.2f%7.2f%7.2f P 1 1\n"
def pdbBoxString(box):
# Box vectors
u, v, w = box[0:3], box[3:6], box[6:9]
# Box vector lengths
nu, nv, nw = [math.sqrt(FUNC.norm2(i)) for i in (u, v, w)]
# Box vector angles
alpha = nv*nw == 0 and 90 or math.acos(FUNC.cos_angle(v, w))/d2r
beta = nu*nw == 0 and 90 or math.acos(FUNC.cos_angle(u, w))/d2r
gamma = nu*nv == 0 and 90 or math.acos(FUNC.cos_angle(u, v))/d2r
return pdbBoxLine % (10*FUNC.norm(u), 10*FUNC.norm(v), 10*FUNC.norm(w), alpha, beta, gamma)
def pdbAtom(a):
##01234567890123456789012345678901234567890123456789012345678901234567890123456789
##ATOM 2155 HH11 ARG C 203 116.140 48.800 6.280 1.00 0.00
if a.startswith("TER"):
return 0
# NOTE: The 27th field of an ATOM line in the PDB definition can contain an
# insertion code. We shift that 20 bits and add it to the residue number
# to ensure that residue numbers will be unique.
## ===> atom name, res name, res id, chain,
atom = [a[12:16].strip(), a[17:20].strip(), int(a[22:26])+(ord(a[26])<<20), a[21],
# x, y, z
float(a[30:38]), float(a[38:46]), float(a[46:54])]
# If the chain identifier is empty, the chain is to None
if atom[3].strip() == '':
atom[3] = None
return tuple(atom)
def pdbOut(atom, i=1, **kwargs):
# insc contains the insertion code, shifted by 20-bitwise.
# This means there are multiple residues with the same "resi",
# which we circumvent by subtracting "insc" from "resi".
# At other places this subtraction as to be inverted.
insc = atom[2] >> 20
resi = atom[2]-(insc << 20)
if atom[3] == None:
chain = ' '
else:
chain = atom[3]
pdbline = "ATOM %5i %-3s %3s%2s%4i%1s %8.3f%8.3f%8.3f%6.2f%6.2f %1s \n"
if "ssid" in kwargs and type(kwargs["ssid"]) == type(int()):
occupancy = kwargs["ssid"]
else:
occupancy = 40
return pdbline % ((i, atom[0][:3], atom[1], chain, resi, chr(insc)) + atom[4:] + (1, occupancy, atom[0][0]))
def isPdbAtom(a):
return a.startswith("ATOM") or (options["-hetatm"] and a.startswith("HETATM")) or a.startswith("TER")
def pdbBoxRead(a):
fa, fb, fc, aa, ab, ac = [float(i) for i in a.split()[1:7]]
ca, cb, cg, sg = math.cos(d2r*aa), math.cos(d2r*ab), math.cos(d2r*ac), math.sin(d2r*ac)
wx, wy = 0.1*fc*cb, 0.1*fc*(ca-cb*cg)/sg
wz = math.sqrt(0.01*fc*fc - wx*wx - wy*wy)
return [0.1*fa, 0, 0, 0.1*fb*cg, 0.1*fb*sg, 0, wx, wy, wz]
# Function for splitting a PDB file in chains, based
# on chain identifiers and TER statements
def pdbChains(pdbAtomList):
chain = []
for atom in pdbAtomList:
if not atom: # Was a "TER" statement
if chain:
yield chain
else:
logging.info("Skipping empty chain definition")
chain = []
continue
if not chain or chain[-1][3] == atom[3]:
chain.append(atom)
else:
yield chain
chain = [atom]
if chain:
yield chain
# Simple PDB iterator
def pdbFrameIterator(streamIterator):
title, atoms, box = [], [], []
for i in streamIterator:
if i.startswith("ENDMDL"):
yield "".join(title), atoms, box
title, atoms, box = [], [], []
elif i.startswith("TITLE"):
title.append(i)
elif i.startswith("CRYST1"):
box = pdbBoxRead(i)
elif i.startswith("ATOM") or i.startswith("HETATM"):
atoms.append(pdbAtom(i))
if atoms:
yield "".join(title), atoms, box
#----+---------+
## B | GRO I/O |
#----+---------+
groline = "%5d%-5s%5s%5d%8.3f%8.3f%8.3f\n"
def groBoxRead(a):
b = [float(i) for i in a.split()] + 6*[0] # Padding for rectangular boxes
return b[0], b[3], b[4], b[5], b[1], b[6], b[7], b[8], b[2] # Return full definition xx,xy,xz,yx,yy,yz,zx,zy,zz
def groAtom(a):
# In PDB files, there might by an insertion code. To handle this, we internally add
# constant to all resids. To be consistent, we have to do the same for gro files.
# 32 equal ord(' '), eg an empty insertion code
constant = 32 << 20
#012345678901234567890123456789012345678901234567890
# 1PRN N 1 4.168 11.132 5.291
# ===> atom name, res name, res id, chain,
return (a[10:15].strip(), a[5:10].strip(), int(a[:5])+constant, None,
# x, y, z
10*float(a[20:28]), 10*float(a[28:36]), 10*float(a[36:44]))
# Simple GRO iterator
def groFrameIterator(streamIterator):
while True:
try:
title = streamIterator.next()
except StopIteration:
break
natoms = streamIterator.next().strip()
if not natoms:
break
natoms = int(natoms)
atoms = [groAtom(streamIterator.next()) for i in range(natoms)]
box = groBoxRead(streamIterator.next())
yield title, atoms, box
#----+-------------+
## C | GENERAL I/O |
#----+-------------+
# It is not entirely clear where this fits in best.
# Called from main.
def getChargeType(resname, resid, choices):
'''Get user input for the charge of residues, based on list with choises.'''
print 'Which %s type do you want for residue %s:' % (resname, resid+1)
for i, choice in choices.iteritems():
print '%s. %s' % (i, choice)
choice = None
while choice not in choices.keys():
choice = input('Type a number:')
return choices[choice]
# *NOTE*: This should probably be a CheckableStream class that
# reads in lines until either of a set of specified conditions
# is met, then setting the type and from thereon functioning as
# a normal stream.
def streamTag(stream):
# Tag the stream with the type of structure file
# If necessary, open the stream, taking care of
# opening using gzip for gzipped files
# First check whether we have have an open stream or a file
# If it's a file, check whether it's zipped and open it
if type(stream) == str:
if stream.endswith("gz"):
logging.info('Read input structure from zipped file.')
s = gzip.open(stream)
else:
logging.info('Read input structure from file.')
s = open(stream)
else:
logging.info('Read input structure from command-line')
s = stream
# Read a few lines, but save them
x = [s.readline(), s.readline()]
if x[-1].strip().isdigit():
# Must be a GRO file
logging.info("Input structure is a GRO file. Chains will be labeled consecutively.")
yield "GRO"
else:
# Must be a PDB file then
# Could wind further to see if we encounter an "ATOM" record
logging.info("Input structure is a PDB file.")
yield "PDB"
# Hand over the lines that were stored
for i in x:
yield i
# Now give the rest of the lines from the stream
for i in s:
yield i
#----+-----------------+
## D | STRUCTURE STUFF |
#----+-----------------+
# This list allows to retrieve atoms based on the name or the index
# If standard, dictionary type indexing is used, only exact matches are
# returned. Alternatively, partial matching can be achieved by setting
# a second 'True' argument.
class Residue(list):
def __getitem__(self, tag):
if type(tag) == int:
# Call the parent class __getitem__
return list.__getitem__(self, tag)
if type(tag) == str:
for i in self:
if i[0] == tag:
return i
else:
return
if tag[1]:
return [i for i in self if tag[0] in i[0]] # Return partial matches
else:
return [i for i in self if i[0] == tag[0]] # Return exact matches only
def residues(atomList):
residue = [atomList[0]]
for atom in atomList[1:]:
if (atom[1] == residue[-1][1] and # Residue name check
atom[2] == residue[-1][2] and # Residue id check
atom[3] == residue[-1][3]): # Chain id check
residue.append(atom)
else:
yield Residue(residue)
residue = [atom]
yield Residue(residue)
def residueDistance2(r1, r2):
return min([FUNC.distance2(i, j) for i in r1 for j in r2])
def breaks(residuelist, selection=("N", "CA", "C"), cutoff=2.5):
# Extract backbone atoms coordinates
bb = [[atom[4:] for atom in residue if atom[0] in selection] for residue in residuelist]
# Needed to remove waters residues from mixed residues.
bb = [res for res in bb if res != []]
# We cannot rely on some standard order for the backbone atoms.
# Therefore breaks are inferred from the minimal distance between
# backbone atoms from adjacent residues.
return [i+1 for i in range(len(bb)-1) if residueDistance2(bb[i], bb[i+1]) > cutoff]
def contacts(atoms, cutoff=5):
rla = range(len(atoms))
crd = [atom[4:] for atom in atoms]
return [(i, j) for i in rla[:-1] for j in rla[i+1:]
if FUNC.distance2(crd[i], crd[j]) < cutoff]
def add_dummy(beads, dist=0.11, n=2):
# Generate a random vector in a sphere of -1 to +1, to add to the bead position
v = [random.random()*2.-1, random.random()*2.-1, random.random()*2.-1]
# Calculated the length of the vector and divide by the final distance of the dummy bead
norm_v = FUNC.norm(v)/dist
# Resize the vector
vn = [i/norm_v for i in v]
# m sets the direction of the added vector, currently only works when adding one or two beads.
m = 1
for j in range(n):
newName = 'SCD'
newBead = (newName, tuple([i+(m*j) for i, j in zip(beads[-1][1], vn)]), beads[-1][2])
beads.append(newBead)
m *= -2
return beads
def check_merge(chains, m_list=[], l_list=[], ss_cutoff=0):
chainIndex = range(len(chains))
if 'all' in m_list:
logging.info("All chains will be merged in a single moleculetype.")
return chainIndex, [chainIndex]
chainID = [chain.id for chain in chains]
# Mark the combinations of chains that need to be merged
merges = []
if m_list:
# Build a dictionary of chain IDs versus index
# To give higher priority to top chains the lists are reversed
# before building the dictionary
chainIndex.reverse()
chainID.reverse()
dct = dict(zip(chainID, chainIndex))
chainIndex.reverse()
# Convert chains in the merge_list to numeric, if necessary
# NOTE The internal numbering is zero-based, while the
# command line chain indexing is one-based. We have to add
# one to the number in the dictionary to bring it on par with
# the numbering from the command line, but then from the
# result we need to subtract one again to make indexing
# zero-based
merges = [[(i.isdigit() and int(i) or dct[i]+1)-1 for i in j] for j in m_list]
for i in merges:
i.sort()
# Rearrange merge list to a list of pairs
pairs = [(i[j], i[k]) for i in merges for j in range(len(i)-1) for k in range(j+1, len(i))]
# Check each combination of chains for connections based on
# ss-bridges, links and distance restraints
for i in chainIndex[:-1]:
for j in chainIndex[i+1:]:
if (i, j) in pairs:
continue
# Check whether any link links these two groups
for a, b in l_list:
if ((a in chains[i] and b in chains[j]) or (a in chains[j] and b in chains[i])):
logging.info("Merging chains %d and %d to allow link %s" % (i+1, j+1, str((a, b))))
pairs.append(i < j and (i, j) or (j, i))
break
if (i, j) in pairs:
continue
# Check whether any cystine bond given links these two groups
#for a,b in s_list:
# if ((a in chains[i] and b in chains[j]) or
# (a in chains[j] and b in chains[i])):
# logging.info("Merging chains %d and %d to allow cystine bridge"%(i+1,j+1))
# pairs.append( i<j and (i,j) or (j,i) )
# break
#if (i,j) in pairs:
# continue
# Check for cystine bridges based on distance
if not ss_cutoff:
continue
# Get SG atoms from cysteines from either chain
# Check this pair of chains
for cysA in chains[i]["CYS"]:
for cysB in chains[j]["CYS"]:
d2 = FUNC.distance2(cysA["SG"][4:7], cysB["SG"][4:7])
if d2 <= ss_cutoff:
logging.info("Found SS contact linking chains %d and %d (%f nm)" % (i+1, j+1, math.sqrt(d2)/10))
pairs.append((i, j))
break
if (i, j) in pairs:
break
# Sort the combinations
pairs.sort(reverse=True)
merges = []
while pairs:
merges.append(set([pairs[-1][0]]))
for i in range(len(pairs)-1, -1, -1):
if pairs[i][0] in merges[-1]:
merges[-1].add(pairs.pop(i)[1])
elif pairs[i][1] in merges[-1]:
merges[-1].add(pairs.pop(i)[0])
merges = [list(i) for i in merges]
for i in merges:
i.sort()
order = [j for i in merges for j in i]
if merges:
logging.warning("Merging chains.")
logging.warning("This may change the order of atoms and will change the number of topology files.")
logging.info("Merges: " + ", ".join([str([j+1 for j in i]) for i in merges]))
if len(merges) == 1 and len(merges[0]) > 1 and set(merges[0]) == set(chainIndex):
logging.info("All chains will be merged in a single moleculetype")
# Determine the order for writing; merged chains go first
merges.extend([[j] for j in chainIndex if j not in order])
order.extend([j for j in chainIndex if j not in order])
return order, merges
## !! NOTE !! ##
## XXX The chain class needs to be simplified by extracting things to separate functions/classes
class Chain:
# Attributes defining a chain
# When copying a chain, or slicing, the attributes in this list have to
# be handled accordingly.
_attributes = ("residues", "sequence", "seq", "ss", "ssclass", "sstypes")
def __init__(self, options, residuelist=[], name=None, multiscale=False):
self.residues = residuelist
self._atoms = [atom[:3] for residue in residuelist for atom in residue]
self.sequence = [residue[0][1] for residue in residuelist]
# *NOTE*: Check for unknown residues and remove them if requested
# before proceeding.
self.seq = "".join([MAP.AA321.get(i, "X") for i in self.sequence])
self.ss = ""
self.ssclass = ""
self.sstypes = ""
self.mapping = []
self.multiscale = multiscale
self.options = options
# Unknown residues
self.unknowns = "X" in self.seq
# Determine the type of chain
self._type = ""
self.type()
# Determine number of atoms
self.natoms = len(self._atoms)
# BREAKS: List of indices of residues where a new fragment starts
# Only when polymeric (protein, DNA, RNA, ...)
# For now, let's remove it for the Nucleic acids...
self.breaks = self.type() in ("Protein", "Mixed") and breaks(self.residues) or []
# LINKS: List of pairs of pairs of indices of linked residues/atoms
# This list is used for cysteine bridges and peptide bonds involving side chains
# The list has items like ((#resi1, #atid1), (#resi2, #atid2))
# When merging chains, the residue number needs ot be update, but the atom id
# remains unchanged.
# For the coarse grained system, it needs to be checked which beads the respective
# atoms fall in, and bonded terms need to be added there.
self.links = []
# Chain identifier; try to read from residue definition if no name is given
self.id = name or residuelist and residuelist[0][0][3] or ""
# Container for coarse grained beads
self._cg = None
def __len__(self):
# Return the number of residues
# DNA/RNA contain non-CAP d/r to indicate type. We remove those first.
return len(''.join(i for i in self.seq if i.isupper()))
def __add__(self, other):
newchain = Chain(name=self.id+"+"+other.id)
# Combine the chain items that can be simply added
for attr in self._attributes:
setattr(newchain, attr, getattr(self, attr) + getattr(other, attr))
# Set chain items, shifting the residue numbers
shift = len(self)
newchain.breaks = self.breaks + [shift] + [i+shift for i in other.breaks]
newchain.links = self.links + [((i[0]+shift, i[1]), (j[0]+shift, j[1])) for i, j in other.links]
newchain.natoms = len(newchain.atoms())
newchain.multiscale = self.multiscale or other.multiscale
# Return the merged chain
return newchain
def __eq__(self, other):
return (self.seq == other.seq and
self.ss == other.ss and
self.breaks == other.breaks and
self.links == other.links and
self.multiscale == other.multiscale)
# Extract a residue by number or the list of residues of a given type
# This facilitates selecting residues for links, like chain["CYS"]
def __getitem__(self, other):
if type(other) == str:
if other not in self.sequence:
return []
return [i for i in self.residues if i[0][1] == other]
elif type(other) == tuple:
# This functionality is set up for links
# between coarse grained beads. So these are
# checked first,
for i in self.cg():
if other == i[:4]:
return i
else:
for i in self.atoms():
if other[:3] == i[:3]:
return i
else:
return []
return self.sequence[other]
# Extract a piece of a chain as a new chain
def __getslice__(self, i, j):
newchain = Chain(self.options, name=self.id)
# Extract the slices from all lists
for attr in self._attributes:
setattr(newchain, attr, getattr(self, attr)[i:j])
# Breaks that fall within the start and end of this chain need to be passed on.
# Residue numbering is increased by 20 bits!!
# XXX I don't know if this works.
ch_sta, ch_end = newchain.residues[0][0][2], newchain.residues[-1][0][2]
newchain.breaks = [crack for crack in self.breaks if ch_sta < (crack << 20) < ch_end]
newchain.links = [link for link in self.links if ch_sta < (link << 20) < ch_end]
newchain.multiscale = self.multiscale
newchain.natoms = len(newchain.atoms())
newchain.type()
# Return the chain slice
return newchain
def _contains(self, atomlist, atom):
atnm, resn, resi, chn = atom
# If the chain does not match, bail out
if chn != self.id:
return False
# Check if the whole tuple is in
if atnm and resn and resi:
return (atnm, resn, resi) in self.atoms()
# Fetch atoms with matching residue id
match = (not resi) and atomlist or [j for j in atomlist if j[2] == resi]
if not match:
return False
# Select atoms with matching residue name
match = (not resn) and match or [j for j in match if j[1] == resn]
if not match:
return False
# Check whether the atom is given and listed
if not atnm or [j for j in match if j[0] == atnm]:
return True
# It just is not in the list!
return False
def __contains__(self, other):
return self._contains(self.atoms(), other) or self._contains(self.cg(), other)
def __hash__(self):
return id(self)
def atoms(self):
if not self._atoms:
self._atoms = [atom[:3] for residue in self.residues for atom in residue]
return self._atoms
# Split a chain based on residue types; each subchain can have only one type
def split(self):
chains = []
chainStart = 0
for i in range(len(self.sequence)-1):
if MAP.residueTypes.get(self.sequence[i], "Unknown") != MAP.residueTypes.get(self.sequence[i+1], "Unknown"):
# Use the __getslice__ method to take a part of the chain.
chains.append(self[chainStart:i+1])
chainStart = i+1
if chains:
logging.debug('Splitting chain %s in %s chains' % (self.id, len(chains)+1))
return chains + [self[chainStart:]]
def getname(self, basename=None):
name = []
if basename: name.append(basename)
if self.type() and not basename: name.append(self.type())
if type(self.id) == int:
name.append(chr(64+self.id))
elif self.id.strip():
name.append(str(self.id))
return "_".join(name)
def set_ss(self, ss, source="self"):
if len(ss) == 1:
self.ss = len(self)*ss
else:
self.ss = ss
# Infer the Martini backbone secondary structure types
self.ssclass, self.sstypes = SS.ssClassification(self.ss, source)
def dss(self, method=None, executable=None):
# The method should take a list of atoms and return a
# string of secondary structure classifications
if self.type() == "Protein":
if method:
atomlist = [atom for residue in self.residues for atom in residue]
self.set_ss(SS.ssDetermination[method](self, atomlist, executable), source=method)
else:
self.set_ss(len(self)*"C")
else:
self.set_ss(len(self.sequence)*"-")
return self.ss
def type(self, other=None):
if other:
self._type = other
elif not self._type and len(self):
# Determine the type of chain
self._type = set([MAP.residueTypes.get(i, "Unknown") for i in set(self.sequence)])
self._type = len(self._type) > 1 and "Mixed" or list(self._type)[0]
return self._type
# XXX The following (at least the greater part of it) should be made a separate function, put under "MAPPING"
def cg(self, force=False, com=False):
# Generate the coarse grained structure
# Set the b-factor field to something that reflects the secondary structure
# If the coarse grained structure is set already, just return,
# unless regeneration is forced.
if self._cg and not force:
return self._cg
self._cg = []
atid = 1
bb = [1]
fail = False
previous = ''
for residue, rss, resname in zip(self.residues, self.sstypes, self.sequence):
# For DNA we need to get the O3' to the following residue when calculating COM
# The force and com options ensure that this part does not affect itp generation or anything else
if com:
# Just an initialization, this should complain if it isn't updated in the loop
store = 0
for ind, i in enumerate(residue):
if i[0] == "O3'":
if previous != '':
residue[ind] = previous
previous = i
else:
store = ind
previous = i
# We couldn't remove the O3' from the 5' end residue during the loop so we do it now
if store > 0:
del residue[store]
# Check if residues names has changed, for example because user has set residues interactively.
residue = [(atom[0], resname)+atom[2:] for atom in residue]
if residue[0][1] in ("SOL", "HOH", "TIP"):
continue
if not residue[0][1] in MAP.CoarseGrained.mapping.keys():
logging.warning("Skipped unknown residue %s\n" % residue[0][1])
continue
# Get the mapping for this residue
# CG.map returns bead coordinates and mapped atoms
# This will fail if there are (too many) atoms missing, which is
# only problematic if a mapped structure is written; the topology
# is inferred from the sequence. So this is the best place to raise
# an error
try:
beads, ids = MAP.map(residue, ca2bb=self.options['ForceField'].ca2bb)
beads = zip(MAP.CoarseGrained.names[residue[0][1]], beads, ids)
if residue[0][1] in self.options['ForceField'].polar:
beads = add_dummy(beads, dist=0.14, n=2)
elif residue[0][1] in self.options['ForceField'].charged:
beads = add_dummy(beads, dist=0.11, n=1)
except ValueError:
logging.error("Too many atoms missing from residue %s %d(ch:%s):",
residue[0][1], residue[0][2]-(32 << 20), residue[0][3])
logging.error(repr([i[0] for i in residue]))
fail = True
for name, (x, y, z), ids in beads:
# Add the bead with coordinates and secondary structure id to the list
self._cg.append((name, residue[0][1][:3], residue[0][2], residue[0][3], x, y, z, SS.ss2num[rss]))
# Add the ids to the list, after converting them to indices to the list of atoms
self.mapping.append([atid+i for i in ids])
# Increment the atom id; This pertains to the atoms that are included in the output.
atid += len(residue)
# Keep track of the numbers for CONECTing
bb.append(bb[-1]+len(beads))
if fail:
logging.error("Unable to generate coarse grained structure due to missing atoms.")
sys.exit(1)
return self._cg
def conect(self):
# Return pairs of numbers that should be CONECTed
# First extract the backbone IDs
cg = self.cg()
bb = [i+1 for i, j in zip(range(len(cg)), cg) if j[0] == "BB"]
bb = zip(bb, bb[1:]+[len(bb)])
# Set the backbone CONECTs (check whether the distance is consistent with binding)
conect = [(i, j) for i, j in bb[:-1] if FUNC.distance2(cg[i-1][4:7], cg[j-1][4:7]) < 14]
# Now add CONECTs for sidechains
for i, j in bb:
nsc = j-i-1