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make_ktaxonomy.py
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make_ktaxonomy.py
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#!/usr/bin/env python
######################################################################
#make_taxonomy.py takes in three files: nodes.dmp, names.dmp, and
#seqid2taxid.map to create a condensed taxonomy file
#Copyright (C) 2020 Jennifer Lu, [email protected]
#
#This file is part of KrakenTools
#KrakenTools is free software; oyu can redistribute it and/or modify
#it under the terms of the GNU General Public License as published by
#the Free Software Foundation; either version 3 of the license, or
#(at your option) any later version.
#
#This program is distributed in the hope that it will be useful,
#but WITHOUT ANY WARRANTY; without even the implied warranty of
#MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
#GNU General Public License for more details.
#
#You should have received a copy of the GNU General Public License
#along with this program; if not, see <http://www.gnu.org/licenses/>.
#
######################################################################
#Jennifer Lu, [email protected]
#Updated: 04/14/2020
#
#This program creates a condensed taxonomy file for a given Kraken database
#To create a taxonomy, the nodes.dmp, names.dmp, and seqid2taxid.map files
#must be provided
#
#Required Parameters:
# --nodes X...........................nodes.dmp file
# --names X...........................names.dmp file
# --seqid2taxid X.....................seqid2taxid.map file
# -o, --output X......................output file with taxonomy info
#Optional Parameters:
# -h, --help..........................show help message.
#################################################################################
import os, sys, argparse
from time import gmtime
from time import strftime
#################################################################################
#Tree Class
#usage: tree node used in constructing taxonomy tree
class Tree(object):
'Tree node.'
def __init__(self, taxid, level_rank, parent=None,children=None):
self.taxid = taxid
self.level_rank= level_rank
#Other attributes for later
self.name = ''
self.level_num = -1
self.p_taxid = -1
#Parent/children attributes
self.children = []
self.parent = parent
if children is not None:
for child in children:
self.add_child(child)
def add_child(self, node):
assert isinstance(node,Tree)
self.children.append(node)
#################################################################################
#Main method
def main():
#Parse arguments
parser = argparse.ArgumentParser()
parser.add_argument('--nodes',dest='nodes_file', required=True,
help='nodes.dmp file from taxonomy')
parser.add_argument('--names',dest='names_file', required=True,
help='names.dmp file from taxonomy')
parser.add_argument('--seqid2taxid',dest='s2t_file', required=True,
help='seqid2taxid.map file')
parser.add_argument('-o','--output',dest='out_file', required=True,
help='output taxonomy file')
args = parser.parse_args()
#Start Program
time = strftime("%m-%d-%Y %H:%M:%S", gmtime())
sys.stdout.write("PROGRAM START TIME: " + time + '\n')
map_ranks = {'superkingdom':'D',
'phylum':'P',
'class':'C',
'order':'O',
'family':'F',
'genus':'G',
'species':'S'}
#STEP 1/5: PARSE NODES.DMP FILE
root_node = -1
taxid2node = {}
p_notsaved = {}
nodes_f = open(args.nodes_file,'r')
sys.stdout.write(">> STEP 1/5: Reading %s\n" % args.nodes_file)
sys.stdout.write("\t%0 nodes read")
count_nodes = 0
for line in nodes_f:
count_nodes += 1
if (count_nodes % 100) == 0:
sys.stdout.write("\r\t%i nodes read" % count_nodes)
sys.stdout.flush()
[curr_taxid,parent_taxid,rank] = line.strip().split("\t|\t")[0:3]
#Make/Save node
newrank = '-'
if rank in map_ranks:
newrank = map_ranks[rank]
curr_node = Tree(curr_taxid, newrank)
taxid2node[curr_taxid] = curr_node
#root
if curr_taxid == "1":
curr_node.level_rank = 'R'
root_node = curr_node
elif parent_taxid in taxid2node:
#save parent
curr_node.parent = taxid2node[parent_taxid]
curr_node.p_taxid = parent_taxid
taxid2node[parent_taxid].add_child(curr_node)
else:
#parent not linked
p_notsaved[curr_taxid] = curr_node
curr_node.p_taxid = parent_taxid
nodes_f.close()
sys.stdout.write("\r\t%i nodes read\n" % count_nodes)
sys.stdout.flush()
#Fix parents
for taxid in p_notsaved:
p_taxid = p_notsaved[taxid].p_taxid
if p_taxid not in taxid2node:
sys.stderr.write("ERROR: %s not found in nodes.dmp file\n" % p_taxid)
continue
p_node = taxid2node[p_taxid]
p_notsaved[taxid].parent = p_node
p_node.add_child(p_notsaved[taxid])
#STEP 2/5: PARSE SEQID2TAXID FILE TO GET LEAF NODES
sys.stdout.write(">> STEP 2/5: Reading %s\n" % args.s2t_file)
sys.stdout.write("\t%0 taxids read")
count_taxids = 0
s2t_f = open(args.s2t_file,'r')
leaves = {}
for line in s2t_f:
taxid = line.strip().split('\t')[-1]
#taxid not yet saved
if taxid not in leaves:
#node exists for taxid
if taxid in taxid2node:
leaves[taxid] = taxid2node[taxid]
count_taxids += 1
if (count_taxids % 100 == 0):
sys.stdout.write("\r\t%i taxids read" % count_taxids)
sys.stdout.flush()
else:
sys.stderr.write("ERROR: node for %s not found\n" % taxid)
s2t_f.close()
sys.stdout.write("\r\t%i taxids read\n" % count_taxids)
sys.stdout.flush()
#STEP 3/5: CONDENSE TAXONOMY TO ONLY INCLUDE TAXIDS IN SEQID2TAXID.MAP
sys.stdout.write(">> STEP 3/5: Condensing taxonomy\n")
sys.stdout.write("\t%saving 0 taxids")
count_final = 0
save_taxids = {}
for leaf in leaves:
if leaf in save_taxids:
continue
save_taxids[leaf] = leaves[leaf]
p_node = taxid2node[leaf].parent
count_final += 1
sys.stdout.write("\r\tsaving %i taxids" % count_final)
sys.stdout.flush()
while(p_node != None):
if p_node.taxid not in save_taxids:
#travel up path to root
save_taxids[p_node.taxid] = p_node
p_node = p_node.parent
count_final += 1
sys.stdout.write("\r\tsaving %i taxids" % count_final)
sys.stdout.flush()
else:
#Parent path already parsed
p_node = None
sys.stdout.write("\r\tsaving %i taxids\n" % count_final)
sys.stdout.flush()
#STEP 4/5: PARSE NAMES.DMP TO GET NAMES FOR TAXIDS IN TREE
sys.stdout.write(">> STEP 4/5: Reading %s\n" % args.names_file)
count_names = 0
sys.stdout.write("\t%i/%i names found" % (count_names, count_final))
names_f = open(args.names_file,'r')
for line in names_f:
[taxid,name] = line.strip().split('\t|\t')[0:2]
if taxid in save_taxids:
if save_taxids[taxid].name == '':
save_taxids[taxid].name = name
count_names += 1
sys.stdout.write("\r\t%i/%i names found" % (count_names, count_final))
sys.stdout.flush()
elif "scientific name" in line:
save_taxids[taxid].name = name
names_f.close()
sys.stdout.write("\r\t%i/%i names found\n" % (count_names, count_final))
sys.stdout.flush()
#STEP 5/5: PRINT NEW TAXONOMY
sys.stdout.write(">> STEP 5/5: Printing final taxonomy to %s\n" % args.out_file)
print_count = 0
sys.stdout.write("\t%i nodes printed" % print_count)
sys.stdout.flush()
o_file = open(args.out_file,'w')
parse_nodes = [root_node]
root_node.level_num = 0
printed_taxids = {"1":root_node}
while len(parse_nodes) > 0:
#Get the first node in list
curr_node = parse_nodes.pop(0)
print_count += 1
sys.stdout.write("\r\t%i nodes printed" % print_count)
sys.stdout.flush()
#Print current node
o_file.write("%s\t|\t" % curr_node.taxid)
if curr_node.taxid == "1":
o_file.write("1\t|\t")
else:
o_file.write("%s\t|\t" % curr_node.p_taxid)
o_file.write("%s\t|\t" % curr_node.level_rank)
o_file.write("%s\t|\t" % curr_node.level_num)
o_file.write("%s\n" % curr_node.name)
#Parse through children
for child in curr_node.children:
#Only save taxids needed
if child.taxid in save_taxids:
child.level_num = curr_node.level_num + 1
#Fix children ranks
if child.level_rank == '-':
if len(curr_node.level_rank) == 1:
child.level_rank = curr_node.level_rank + "1"
else:
new_num = int(curr_node.level_rank[1:]) + 1
child.level_rank = curr_node.level_rank[0] + str(new_num)
parse_nodes.append(child)
printed_taxids[child.taxid] = child
o_file.close()
sys.stdout.write("\r\t%i nodes printed\n" % print_count)
sys.stdout.flush()
#Error check
for taxid in save_taxids:
if taxid not in printed_taxids:
sys.stderr.write("ERROR: %s not linked to root\n" % taxid)
#End of program
time = strftime("%m-%d-%Y %H:%M:%S", gmtime())
sys.stdout.write("PROGRAM END TIME: " + time + '\n')
sys.exit(0)
#################################################################################
if __name__ == "__main__":
main()
#################################################################################
##################################END OF PROGRAM#################################
#################################################################################