Mercurial > repos > xuebing > sharplabtool
view tools/filters/sff_extract.py @ 1:cdcb0ce84a1b
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| author | xuebing |
|---|---|
| date | Fri, 09 Mar 2012 19:45:15 -0500 |
| parents | 9071e359b9a3 |
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#!/usr/bin/python '''This software extracts the seq, qual and ancillary information from an sff file, like the ones used by the 454 sequencer. Optionally, it can also split paired-end reads if given the linker sequence. The splitting is done with maximum match, i.e., every occurence of the linker sequence will be removed, even if occuring multiple times.''' #copyright Jose Blanca and Bastien Chevreux #COMAV institute, Universidad Politecnica de Valencia (UPV) #Valencia, Spain # additions to handle paired end reads by Bastien Chevreux # bugfixes for linker specific lengths: Lionel Guy #This program is free software: you 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/>. __author__ = 'Jose Blanca and Bastien Chevreux' __copyright__ = 'Copyright 2008, Jose Blanca, COMAV, and Bastien Chevreux' __license__ = 'GPLv3 or later' __version__ = '0.2.8' __email__ = 'jblanca@btc.upv.es' __status__ = 'beta' import struct import sys import os import subprocess import tempfile fake_sff_name = 'fake_sff_name' # readname as key: lines with matches from SSAHA, one best match ssahapematches = {} # linker readname as key: length of linker sequence linkerlengths = {} # set to true if something really fishy is going on with the sequences stern_warning = True def read_bin_fragment(struct_def, fileh, offset=0, data=None, byte_padding=None): '''It reads a chunk of a binary file. You have to provide the struct, a file object, the offset (where to start reading). Also you can provide an optional dict that will be populated with the extracted data. If a byte_padding is given the number of bytes read will be a multiple of that number, adding the required pad at the end. It returns the number of bytes reads and the data dict. ''' if data is None: data = {} #we read each item bytes_read = 0 for item in struct_def: #we go to the place and read fileh.seek(offset + bytes_read) n_bytes = struct.calcsize(item[1]) buffer = fileh.read(n_bytes) read = struct.unpack('>' + item[1], buffer) if len(read) == 1: read = read[0] data[item[0]] = read bytes_read += n_bytes #if there is byte_padding the bytes_to_read should be a multiple of the #byte_padding if byte_padding is not None: pad = byte_padding bytes_read = ((bytes_read + pad - 1) // pad) * pad return (bytes_read, data) def check_magic(magic): '''It checks that the magic number of the file matches the sff magic.''' if magic != 779314790: raise RuntimeError('This file does not seems to be an sff file.') def check_version(version): '''It checks that the version is supported, otherwise it raises an error.''' supported = ('\x00', '\x00', '\x00', '\x01') i = 0 for item in version: if version[i] != supported[i]: raise RuntimeError('SFF version not supported. Please contact the author of the software.') i += 1 def read_header(fileh): '''It reads the header from the sff file and returns a dict with the information''' #first we read the first part of the header head_struct = [ ('magic_number', 'I'), ('version', 'cccc'), ('index_offset', 'Q'), ('index_length', 'I'), ('number_of_reads', 'I'), ('header_length', 'H'), ('key_length', 'H'), ('number_of_flows_per_read', 'H'), ('flowgram_format_code', 'B'), ] data = {} first_bytes, data = read_bin_fragment(struct_def=head_struct, fileh=fileh, offset=0, data=data) check_magic(data['magic_number']) check_version(data['version']) #now that we know the number_of_flows_per_read and the key_length #we can read the second part of the header struct2 = [ ('flow_chars', str(data['number_of_flows_per_read']) + 'c'), ('key_sequence', str(data['key_length']) + 'c') ] read_bin_fragment(struct_def=struct2, fileh=fileh, offset=first_bytes, data=data) return data def read_sequence(header, fileh, fposition): '''It reads one read from the sff file located at the fposition and returns a dict with the information.''' header_length = header['header_length'] index_offset = header['index_offset'] index_length = header['index_length'] #the sequence struct read_header_1 = [ ('read_header_length', 'H'), ('name_length', 'H'), ('number_of_bases', 'I'), ('clip_qual_left', 'H'), ('clip_qual_right', 'H'), ('clip_adapter_left', 'H'), ('clip_adapter_right', 'H'), ] def read_header_2(name_length): '''It returns the struct definition for the second part of the header''' return [('name', str(name_length) +'c')] def read_data(number_of_bases): '''It returns the struct definition for the read data section.''' #size = {'c': 1, 'B':1, 'H':2, 'I':4, 'Q':8} if header['flowgram_format_code'] == 1: flow_type = 'H' else: raise Error('file version not supported') number_of_bases = str(number_of_bases) return [ ('flowgram_values', str(header['number_of_flows_per_read']) + flow_type), ('flow_index_per_base', number_of_bases + 'B'), ('bases', number_of_bases + 'c'), ('quality_scores', number_of_bases + 'B'), ] data = {} #we read the first part of the header bytes_read, data = read_bin_fragment(struct_def=read_header_1, fileh=fileh, offset=fposition, data=data) read_bin_fragment(struct_def=read_header_2(data['name_length']), fileh=fileh, offset=fposition + bytes_read, data=data) #we join the letters of the name data['name'] = ''.join(data['name']) offset = data['read_header_length'] #we read the sequence and the quality read_data_st = read_data(data['number_of_bases']) bytes_read, data = read_bin_fragment(struct_def=read_data_st, fileh=fileh, offset=fposition + offset, data=data, byte_padding=8) #we join the bases data['bases'] = ''.join(data['bases']) #print data #print "pre cqr: ", data['clip_qual_right'] #print "pre car: ", data['clip_adapter_right'] #print "pre cql: ", data['clip_qual_left'] #print "pre cal: ", data['clip_adapter_left'] # correct for the case the right clip is <= than the left clip # in this case, left clip is 0 are set to 0 (right clip == 0 means # "whole sequence") if data['clip_qual_right'] <= data['clip_qual_left'] : data['clip_qual_right'] = 0 data['clip_qual_left'] = 0 if data['clip_adapter_right'] <= data['clip_adapter_left'] : data['clip_adapter_right'] = 0 data['clip_adapter_left'] = 0 #the clipping section follows the NCBI's guidelines Trace Archive RFC #http://www.ncbi.nlm.nih.gov/Traces/trace.cgi?cmd=show&f=rfc&m=doc&s=rfc #if there's no adapter clip: qual -> vector #else: qual-> qual # adapter -> vector if not data['clip_adapter_left']: data['clip_adapter_left'], data['clip_qual_left'] = data['clip_qual_left'], data['clip_adapter_left'] if not data['clip_adapter_right']: data['clip_adapter_right'], data['clip_qual_right'] = data['clip_qual_right'], data['clip_adapter_right'] # see whether we have to override the minimum left clips if config['min_leftclip'] > 0: if data['clip_adapter_left'] >0 and data['clip_adapter_left'] < config['min_leftclip']: data['clip_adapter_left'] = config['min_leftclip'] if data['clip_qual_left'] >0 and data['clip_qual_left'] < config['min_leftclip']: data['clip_qual_left'] = config['min_leftclip'] #print "post cqr: ", data['clip_qual_right'] #print "post car: ", data['clip_adapter_right'] #print "post cql: ", data['clip_qual_left'] #print "post cal: ", data['clip_adapter_left'] # for handling the -c (clip) option gently, we already clip here # and set all clip points to the sequence end points if config['clip']: data['bases'], data['quality_scores'] = clip_read(data) data['number_of_bases']=len(data['bases']) data['clip_qual_right'] = data['number_of_bases'] data['clip_adapter_right'] = data['number_of_bases'] data['clip_qual_left'] = 0 data['clip_adapter_left'] = 0 return data['read_header_length'] + bytes_read, data def sequences(fileh, header): '''It returns a generator with the data for each read.''' #now we can read all the sequences fposition = header['header_length'] #position in the file reads_read = 0 while True: if fposition == header['index_offset']: #we have to skip the index section fposition += index_length continue else: bytes_read, seq_data = read_sequence(header=header, fileh=fileh, fposition=fposition) yield seq_data fposition += bytes_read reads_read += 1 if reads_read >= header['number_of_reads']: break def remove_last_xmltag_in_file(fname, tag=None): '''Given an xml file name and a tag, it removes the last tag of the file if it matches the given tag. Tag removal is performed via file truncation. It the given tag is not the last in the file, a RunTimeError will be raised. The resulting xml file will be not xml valid. This function is a hack that allows to append records to xml files in a quick and dirty way. ''' fh = open(fname, 'r+') #we have to read from the end to the start of the file and keep the #string enclosed by </ > i = -1 last_tag = [] #the chars that form the last tag start_offset = None #in which byte does the last tag starts? end_offset = None #in which byte does the last tag ends? while True: fh.seek(i, 2) char = fh.read(1) if not char.isspace(): last_tag.append(char) if char == '>': end_offset = i if char == '<': start_offset = i break i -= 1 #we have read the last tag backwards last_tag = ''.join(last_tag[::-1]) #we remove the </ and > last_tag = last_tag.rstrip('>').lstrip('</') #we check that we're removing the asked tag if tag is not None and tag != last_tag: raise RuntimeError("The given xml tag wasn't the last one in the file") # while we are at it: also remove all white spaces in that line :-) i -= 1 while True: fh.seek(i, 2) char = fh.read(1) if not char == ' ' and not char == '\t': break; if fh.tell() == 1: break; i -= 1 fh.truncate(); fh.close() return last_tag def create_basic_xml_info(readname, fname): '''Formats a number of read specific infos into XML format. Currently formated: name and the tags set from command line ''' to_print = [' <trace>\n'] to_print.append(' <trace_name>') to_print.append(readname) to_print.append('</trace_name>\n') #extra information #do we have extra info for this file? info = None if config['xml_info']: #with this name? if fname in config['xml_info']: info = config['xml_info'][fname] else: #with no name? try: info = config['xml_info'][fake_sff_name] except KeyError: pass #we print the info that we have if info: for key in info: to_print.append(' <' + key + '>' + info[key] + \ '</' + key +'>\n') return ''.join(to_print) def create_clip_xml_info(readlen, adapl, adapr, quall, qualr): '''Takes the clip values of the read and formats them into XML Corrects "wrong" values that might have resulted through simplified calculations earlier in the process of conversion (especially during splitting of paired-end reads) ''' to_print = [""] # if right borders are >= to read length, they don't need # to be printed if adapr >= readlen: adapr = 0 if qualr >= readlen: qualr = 0 # BaCh # when called via split_paired_end(), some values may be < 0 # (when clip values were 0 previously) # instead of putting tons of if clauses for different calculations there, # I centralise corrective measure here # set all values <0 to 0 if adapr < 0: adapr = 0 if qualr <0: qualr = 0 if adapl < 0: adapl = 0 if quall <0: quall = 0 if quall: to_print.append(' <clip_quality_left>') to_print.append(str(quall)) to_print.append('</clip_quality_left>\n') if qualr: to_print.append(' <clip_quality_right>') to_print.append(str(qualr)) to_print.append('</clip_quality_right>\n') if adapl: to_print.append(' <clip_vector_left>') to_print.append(str(adapl)) to_print.append('</clip_vector_left>\n') if adapr: to_print.append(' <clip_vector_right>') to_print.append(str(adapr)) to_print.append('</clip_vector_right>\n') return ''.join(to_print) def create_xml_for_unpaired_read(data, fname): '''Given the data for one read it returns an str with the xml ancillary data.''' to_print = [create_basic_xml_info(data['name'],fname)] #clippings in the XML only if we do not hard clip if not config['clip']: to_print.append(create_clip_xml_info(data['number_of_bases'],data['clip_adapter_left'], data['clip_adapter_right'], data['clip_qual_left'], data['clip_qual_right'])); to_print.append(' </trace>\n') return ''.join(to_print) def format_as_fasta(name,seq,qual): name_line = ''.join(('>', name,'\n')) seqstring = ''.join((name_line, seq, '\n')) qual_line = ' '.join([str(q) for q in qual]) qualstring = ''.join((name_line, qual_line, '\n')) return seqstring, qualstring def format_as_fastq(name,seq,qual): qual_line = ''.join([chr(q+33) for q in qual]) #seqstring = ''.join(('@', name,'\n', seq, '\n+', name,'\n', qual_line, '\n')) seqstring = ''.join(('@', name,'\n', seq, '\n+\n', qual_line, '\n')) return seqstring def get_read_data(data): '''Given the data for one read it returns 2 strs with the fasta seq and fasta qual.''' #seq and qual if config['mix_case']: seq = sequence_case(data) qual = data['quality_scores'] else : seq = data['bases'] qual = data['quality_scores'] return seq, qual def extract_read_info(data, fname): '''Given the data for one read it returns 3 strs with the fasta seq, fasta qual and xml ancillary data.''' seq,qual = get_read_data(data) seqstring, qualstring = format_as_fasta(data['name'],seq,qual) #name_line = ''.join(('>', data['name'],'\n')) #seq = ''.join((name_line, seq, '\n')) #qual_line = ' '.join([str(q) for q in qual]) #qual = ''.join((name_line, qual_line, '\n')) xmlstring = create_xml_for_unpaired_read(data, fname) return seqstring, qualstring, xmlstring def write_sequence(name,seq,qual,seq_fh,qual_fh): '''Write sequence and quality FASTA and FASTA qual filehandles (or into FASTQ and XML) if sequence length is 0, don't write''' if len(seq) == 0 : return if qual_fh is None: seq_fh.write(format_as_fastq(name,seq,qual)) else: seqstring, qualstring = format_as_fasta(name,seq,qual) seq_fh.write(seqstring) qual_fh.write(qualstring) return def write_unpaired_read(data, sff_fh, seq_fh, qual_fh, xml_fh): '''Writes an unpaired read into FASTA, FASTA qual and XML filehandles (or into FASTQ and XML) if sequence length is 0, don't write''' seq,qual = get_read_data(data) if len(seq) == 0 : return write_sequence(data['name'],seq,qual,seq_fh,qual_fh) anci = create_xml_for_unpaired_read(data, sff_fh.name) if anci is not None: xml_fh.write(anci) return def reverse_complement(seq): '''Returns the reverse complement of a DNA sequence as string''' compdict = { 'a': 't', 'c': 'g', 'g': 'c', 't': 'a', 'u': 't', 'm': 'k', 'r': 'y', 'w': 'w', 's': 's', 'y': 'r', 'k': 'm', 'v': 'b', 'h': 'd', 'd': 'h', 'b': 'v', 'x': 'x', 'n': 'n', 'A': 'T', 'C': 'G', 'G': 'C', 'T': 'A', 'U': 'T', 'M': 'K', 'R': 'Y', 'W': 'W', 'S': 'S', 'Y': 'R', 'K': 'M', 'V': 'B', 'H': 'D', 'D': 'H', 'B': 'V', 'X': 'X', 'N': 'N', '*': '*' } complseq = ''.join([compdict[base] for base in seq]) # python hack to reverse a list/string/etc complseq = complseq[::-1] return complseq def mask_sequence(seq, maskchar, fpos, tpos): '''Given a sequence, mask it with maskchar starting at fpos (including) and ending at tpos (excluding) ''' if len(maskchar) > 1: raise RuntimeError("Internal error: more than one character given to mask_sequence") if fpos<0: fpos = 0 if tpos > len(seq): tpos = len(seq) newseq = ''.join((seq[:fpos],maskchar*(tpos-fpos), seq[tpos:])) return newseq def fragment_sequences(sequence, qualities, splitchar): '''Works like split() on strings, except it does this on a sequence and the corresponding list with quality values. Returns a tuple for each fragment, each sublist has the fragment sequence as first and the fragment qualities as second elemnt''' # this is slow (due to zip and list appends... use an iterator over # the sequence find find variations and splices on seq and qual if len(sequence) != len(qualities): print sequence, qualities raise RuntimeError("Internal error: length of sequence and qualities don't match???") retlist = ([]) if len(sequence) == 0: return retlist actseq = ([]) actqual = ([]) if sequence[0] != splitchar: inseq = True else: inseq = False for char,qual in zip(sequence,qualities): if inseq: if char != splitchar: actseq.append(char) actqual.append(qual) else: retlist.append((''.join(actseq), actqual)) actseq = ([]) actqual = ([]) inseq = False else: if char != splitchar: inseq = True actseq.append(char) actqual.append(qual) if inseq and len(actseq): retlist.append((''.join(actseq), actqual)) return retlist def calc_subseq_boundaries(maskedseq, maskchar): '''E.g.: ........xxxxxxxx..........xxxxxxxxxxxxxxxxxxxxx......... to (0,8),(8,16),(16,26),(26,47),(47,56) ''' blist = ([]) if len(maskedseq) == 0: return blist inmask = True if maskedseq[0] != maskchar: inmask = False start = 0 for spos in range(len(maskedseq)): if inmask and maskedseq[spos] != maskchar: blist.append(([start,spos])) start = spos inmask = False elif not inmask and maskedseq[spos] == maskchar: blist.append(([start,spos])) start = spos inmask = True blist.append(([start,spos+1])) return blist def correct_for_smallhits(maskedseq, maskchar, linkername): '''If partial hits were found, take preventive measure: grow the masked areas by 20 bases in each direction Returns either unchanged "maskedseq" or a new sequence with some more characters masked. ''' global linkerlengths CEBUG = 0 if CEBUG : print "correct_for_smallhits" if CEBUG : print "Masked seq\n", maskedseq if CEBUG : print "Linkername: ", linkername if len(maskedseq) == 0: return maskedseq growl=40 growl2=growl/2 boundaries = calc_subseq_boundaries(maskedseq,maskchar) if CEBUG : print "Boundaries: ", boundaries foundpartial = False for bounds in boundaries: if CEBUG : print "\tbounds: ", bounds left, right = bounds if left != 0 and right != len(maskedseq): if maskedseq[left] == maskchar: # allow 10% discrepancy # -linkerlengths[linkername]/10 # that's a kind of safety net if there are slight sequencing # errors in the linker itself if right-left < linkerlengths[linkername]-linkerlengths[linkername]/10: if CEBUG : print "\t\tPartial: found " + str(right-left) + " gaps, " + linkername + " is " + str(linkerlengths[linkername]) + " nt long." foundpartial = True if not foundpartial: return maskedseq # grow newseq = "" for bounds in boundaries: if CEBUG : print "Bounds: ", bounds left, right = bounds if maskedseq[left] == maskchar: newseq += maskedseq[left:right] else: clearstart = 0 if left > 0 : clearstart = left+growl2 clearstop = len(maskedseq) if right < len(maskedseq): clearstop = right-growl2 if CEBUG : print "clearstart, clearstop: ",clearstart, clearstop if clearstop <= clearstart: newseq += maskchar * (right-left) else: if clearstart != left: newseq += maskchar * growl2 newseq += maskedseq[clearstart:clearstop] if clearstop != right: newseq += maskchar * growl2 #print "newseq\n",newseq return newseq def split_paired_end(data, sff_fh, seq_fh, qual_fh, xml_fh): '''Splits a paired end read and writes sequences into FASTA, FASTA qual and XML traceinfo file. Returns the number of sequences created. As the linker sequence may be anywhere in the read, including the ends and overlapping with bad quality sequence, we need to perform some computing and eventually set new clip points. If the resulting split yields only one sequence (because linker was not present or overlapping with left or right clip), only one sequence will be written with ".fn" appended to the name. If the read can be split, two reads will be written. The side left of the linker will be named ".r" and will be written in reverse complement into the file to conform with what approximately all assemblers expect when reading paired-end data: reads in forward direction in file. The side right of the linker will be named ".f" If SSAHA found partial linker (linker sequences < length of linker), the sequences will get a "_pl" furthermore be cut back thoroughly. If SSAHA found multiple occurences of the linker, the names will get an additional "_mlc" within the name to show that there was "multiple linker contamination". For multiple or partial linker, the "good" parts of the reads are stored with a ".part<number>" name, additionally they will not get template information in the XML ''' global ssahapematches CEBUG = 0 maskchar = "#" if CEBUG : print "Need to split: " + data['name'] numseqs = 0; readname = data['name'] readlen = data['number_of_bases'] leftclip, rightclip = return_merged_clips(data) seq, qual = get_read_data(data) if CEBUG : print "Original read:\n",seq maskedseq = seq if leftclip > 0: maskedseq = mask_sequence(maskedseq, maskchar, 0, leftclip-1) if rightclip < len(maskedseq): maskedseq = mask_sequence(maskedseq, maskchar, rightclip, len(maskedseq)) leftclip, rightclip = return_merged_clips(data) readlen = data['number_of_bases'] if CEBUG : print "Readname:", readname if CEBUG : print "Readlen:", readlen if CEBUG : print "Num matches:", str(len(ssahapematches[data['name']])) if CEBUG : print "matches:", ssahapematches[data['name']] for match in ssahapematches[data['name']]: score = int(match[0]) linkername = match[2] leftreadhit = int(match[3]) rightreadhit = int(match[4]) #leftlinkerhit = int(match[5]) #rightlinkerhit = int(match[6]) #direction = match[7] #hitlen = int(match[8]) #hitidentity = float(match[9]) if CEBUG : print match if CEBUG : print "Match with score:", score if CEBUG : print "Read before:\n", maskedseq maskedseq = mask_sequence(maskedseq, maskchar, leftreadhit-1, rightreadhit) if CEBUG : print "Masked seq:\n", maskedseq correctedseq = correct_for_smallhits(maskedseq, maskchar, linkername) if len(maskedseq) != len(correctedseq): raise RuntimeError("Internal error: maskedseq != correctedseq") partialhits = False if correctedseq != maskedseq: if CEBUG : print "Partial hits in", readname if CEBUG : print "Original seq:\n", seq if CEBUG : print "Masked seq:\n", maskedseq if CEBUG : print "Corrected seq\n", correctedseq partialhits = True readname += "_pl" maskedseq = correctedseq fragments = fragment_sequences(maskedseq, qual, maskchar) if CEBUG : print "Fragments (", len(fragments), "): ", fragments mlcflag = False #if len(ssahapematches[data['name']]) > 1: # #print "Multi linker contamination" # mlcflag = True # readname += "_mlc" if len(fragments) > 2: if CEBUG : print "Multi linker contamination" mlcflag = True readname += "_mlc" #print fragments if mlcflag or partialhits: fragcounter = 1 readname += ".part" for frag in fragments: actseq = frag[0] if len(actseq) >= 20: actqual = frag[1] oname = readname + str(fragcounter) #seq_fh.write(">"+oname+"\n") #seq_fh.write(actseq+"\n") #qual_fh.write(">"+oname+"\n") #qual_fh.write(' '.join((str(q) for q in actqual))) #qual_fh.write("\n") write_sequence(oname,actseq,actqual,seq_fh,qual_fh) to_print = [create_basic_xml_info(oname,sff_fh.name)] # No clipping in XML ... the multiple and partial fragments # are clipped "hard" # No template ID and trace_end: we don't know the # orientation of the frahments. Even if it were # only two, the fact we had multiple linkers # says something went wrong, so simply do not # write any paired-end information for all these fragments to_print.append(' </trace>\n') xml_fh.write(''.join(to_print)) numseqs += 1 fragcounter += 1 else: if len(fragments) >2: raise RuntimeError("Unexpected: more than two fragments detected in " + readname + ". please contact the authors.") # nothing will happen for 0 fragments if len(fragments) == 1: #print "Tada1" boundaries = calc_subseq_boundaries(maskedseq,maskchar) if len(boundaries) < 1 or len(boundaries) >3: raise RuntimeError("Unexpected case: ", str(len(boundaries)), "boundaries for 1 fragment of ", readname) if len(boundaries) == 3: # case: mask char on both sides of sequence #print "bounds3" data['clip_adapter_left']=1+boundaries[0][1] data['clip_adapter_right']=boundaries[2][0] elif len(boundaries) == 2: # case: mask char left or right of sequence #print "bounds2", if maskedseq[0] == maskchar : # case: mask char left #print "left" data['clip_adapter_left']=1+boundaries[0][1] else: # case: mask char right #print "right" data['clip_adapter_right']=boundaries[1][0] data['name'] = data['name'] + ".fn" write_unpaired_read(data, sff_fh, seq_fh, qual_fh, xml_fh) numseqs = 1 elif len(fragments) == 2: #print "Tada2" oname = readname + ".r" seq, qual = get_read_data(data) startsearch = False for spos in range(len(maskedseq)): if maskedseq[spos] != maskchar: startsearch = True; else: if startsearch: break #print "\nspos: ", spos lseq=seq[:spos] #print "lseq:", lseq actseq = reverse_complement(lseq) lreadlen = len(actseq) lqual = qual[:spos]; # python hack to reverse a list/string/etc lqual = lqual[::-1]; #seq_fh.write(">"+oname+"\n") #seq_fh.write(actseq+"\n") #qual_fh.write(">"+oname+"\n") #qual_fh.write(' '.join((str(q) for q in lqual))) #qual_fh.write("\n") write_sequence(oname,actseq,lqual,seq_fh,qual_fh) to_print = [create_basic_xml_info(oname,sff_fh.name)] to_print.append(create_clip_xml_info(lreadlen, 0, lreadlen+1-data['clip_adapter_left'], 0, lreadlen+1-data['clip_qual_left'])); to_print.append(' <template_id>') to_print.append(readname) to_print.append('</template_id>\n') to_print.append(' <trace_end>r</trace_end>\n') to_print.append(' </trace>\n') xml_fh.write(''.join(to_print)) oname = readname + ".f" startsearch = False for spos in range(len(maskedseq)-1,-1,-1): if maskedseq[spos] != maskchar: startsearch = True; else: if startsearch: break actseq = seq[spos+1:] actqual = qual[spos+1:]; #print "\nspos: ", spos #print "rseq:", actseq #seq_fh.write(">"+oname+"\n") #seq_fh.write(actseq+"\n") #qual_fh.write(">"+oname+"\n") #qual_fh.write(' '.join((str(q) for q in actqual))) #qual_fh.write("\n") write_sequence(oname,actseq,actqual,seq_fh,qual_fh) rreadlen = len(actseq) to_print = [create_basic_xml_info(oname,sff_fh.name)] to_print.append(create_clip_xml_info(rreadlen, 0, rreadlen-(readlen-data['clip_adapter_right']), 0, rreadlen-(readlen-data['clip_qual_right']))); to_print.append(' <template_id>') to_print.append(readname) to_print.append('</template_id>\n') to_print.append(' <trace_end>f</trace_end>\n') to_print.append(' </trace>\n') xml_fh.write(''.join(to_print)) numseqs = 2 return numseqs def extract_reads_from_sff(config, sff_files): '''Given the configuration and the list of sff_files it writes the seqs, qualities and ancillary data into the output file(s). If file for paired-end linker was given, first extracts all sequences of an SFF and searches these against the linker(s) with SSAHA2 to create needed information to split reads. ''' global ssahapematches if len(sff_files) == 0 : raise RuntimeError("No SFF file given?") #we go through all input files for sff_file in sff_files: if not os.path.getsize(sff_file): raise RuntimeError('Empty file? : ' + sff_file) fh = open(sff_file, 'r') fh.close() openmode = 'w' if config['append']: openmode = 'a' seq_fh = open(config['seq_fname'], openmode) xml_fh = open(config['xml_fname'], openmode) if config['want_fastq']: qual_fh = None try: os.remove(config['qual_fname']) except : python_formattingwithoutbracesisdumb_dummy = 1 else: qual_fh = open(config['qual_fname'], openmode) if not config['append']: xml_fh.write('<?xml version="1.0"?>\n<trace_volume>\n') else: remove_last_xmltag_in_file(config['xml_fname'], "trace_volume") #we go through all input files for sff_file in sff_files: #print "Working on '" + sff_file + "':" ssahapematches.clear() seqcheckstore = ([]) debug = 0 if not debug and config['pelinker_fname']: #print "Creating temporary sequences from reads in '" + sff_file + "' ... ", sys.stdout.flush() if 0 : # for debugging pid = os.getpid() tmpfasta_fname = 'sffe.tmp.'+ str(pid)+'.fasta' tmpfasta_fh = open(tmpfasta_fname, 'w') else: tmpfasta_fh = tempfile.NamedTemporaryFile(prefix = 'sffeseqs_', suffix = '.fasta') sff_fh = open(sff_file, 'rb') header_data = read_header(fileh=sff_fh) for seq_data in sequences(fileh=sff_fh, header=header_data): seq,qual = get_read_data(seq_data) seqstring, qualstring = format_as_fasta(seq_data['name'],seq,qual) tmpfasta_fh.write(seqstring) #seq, qual, anci = extract_read_info(seq_data, sff_fh.name) #tmpfasta_fh.write(seq) #print "done." tmpfasta_fh.seek(0) if 0 : # for debugging tmpssaha_fname = 'sffe.tmp.'+str(pid)+'.ssaha2' tmpssaha_fh = open(tmpssaha_fname, 'w+') else: tmpssaha_fh = tempfile.NamedTemporaryFile(prefix = 'sffealig_', suffix = '.ssaha2') launch_ssaha(config['pelinker_fname'], tmpfasta_fh.name, tmpssaha_fh) tmpfasta_fh.close() tmpssaha_fh.seek(0) read_ssaha_data(tmpssaha_fh) tmpssaha_fh.close() if debug: tmpssaha_fh = open("sffe.tmp.10634.ssaha2", 'r') read_ssaha_data(tmpssaha_fh) #print "Converting '" + sff_file + "' ... ", sys.stdout.flush() sff_fh = open(sff_file, 'rb') #read_header(infile) header_data = read_header(fileh=sff_fh) #now convert all reads nseqs_sff = 0 nseqs_out = 0 for seq_data in sequences(fileh=sff_fh, header=header_data): nseqs_sff += 1 seq, qual = clip_read(seq_data) seqcheckstore.append(seq[0:50]) #if nseqs_sff >1000: # check_for_dubious_startseq(seqcheckstore,sff_file,seq_data) # sys.exit() if ssahapematches.has_key(seq_data['name']): #print "Paired end:",seq_data['name'] nseqs_out += split_paired_end(seq_data, sff_fh, seq_fh, qual_fh, xml_fh) else: #print "Normal:",seq_data['name'] if config['pelinker_fname']: seq_data['name'] = seq_data['name'] + ".fn" write_unpaired_read(seq_data, sff_fh, seq_fh, qual_fh, xml_fh) nseqs_out += 1 #print "done." #print 'Converted', str(nseqs_sff), 'reads into', str(nseqs_out), 'sequences.' sff_fh.close() check_for_dubious_startseq(seqcheckstore,sff_file,seq_data) seqcheckstore = ([]) xml_fh.write('</trace_volume>\n') xml_fh.close() seq_fh.close() if qual_fh is not None: qual_fh.close() return def check_for_dubious_startseq(seqcheckstore, sffname,seqdata): global stern_warning foundproblem = "" for checklen in range(1,len(seqcheckstore[0])): foundinloop = False seqdict = {} for seq in seqcheckstore: shortseq = seq[0:checklen] if shortseq in seqdict: seqdict[shortseq] += 1 else: seqdict[shortseq] = 1 for shortseq, count in seqdict.items(): if float(count)/len(seqcheckstore) >= 0.5: foundinloop = True stern_warning foundproblem = "\n"+"*" * 80 foundproblem += "\nWARNING: " foundproblem += "weird sequences in file " + sffname + "\n\n" foundproblem += "After applying left clips, " + str(count) + " sequences (=" foundproblem += '%.0f'%(100.0*float(count)/len(seqcheckstore)) foundproblem += "%) start with these bases:\n" + shortseq foundproblem += "\n\nThis does not look sane.\n\n" foundproblem += "Countermeasures you *probably* must take:\n" foundproblem += "1) Make your sequence provider aware of that problem and ask whether this can be\n corrected in the SFF.\n" foundproblem += "2) If you decide that this is not normal and your sequence provider does not\n react, use the --min_left_clip of sff_extract.\n" left,right = return_merged_clips(seqdata) foundproblem += " (Probably '--min_left_clip="+ str(left+len(shortseq))+"' but you should cross-check that)\n" foundproblem += "*" * 80 + "\n" if not foundinloop : break if len(foundproblem): print foundproblem def parse_extra_info(info): '''It parses the information that will go in the xml file. There are two formats accepted for the extra information: key1:value1, key2:value2 or: file1.sff{key1:value1, key2:value2};file2.sff{key3:value3} ''' if not info: return info finfos = info.split(';') #information for each file data_for_files = {} for finfo in finfos: #we split the file name from the rest items = finfo.split('{') if len(items) == 1: fname = fake_sff_name info = items[0] else: fname = items[0] info = items[1] #now we get each key,value pair in the info info = info.replace('}', '') data = {} for item in info.split(','): key, value = item.strip().split(':') key = key.strip() value = value.strip() data[key] = value data_for_files[fname] = data return data_for_files def return_merged_clips(data): '''It returns the left and right positions to clip.''' def max(a, b): '''It returns the max of the two given numbers. It won't take into account the zero values. ''' if not a and not b: return None if not a: return b if not b: return a if a >= b: return a else: return b def min(a, b): '''It returns the min of the two given numbers. It won't take into account the zero values. ''' if not a and not b: return None if not a: return b if not b: return a if a <= b: return a else: return b left = max(data['clip_adapter_left'], data['clip_qual_left']) right = min(data['clip_adapter_right'], data['clip_qual_right']) #maybe both clips where zero if left is None: left = 1 if right is None: right = data['number_of_bases'] return left, right def sequence_case(data): '''Given the data for one read it returns the seq with mixed case. The regions to be clipped will be lower case and the rest upper case. ''' left, right = return_merged_clips(data) seq = data['bases'] new_seq = ''.join((seq[:left-1].lower(), seq[left-1:right], seq[right:].lower())) return new_seq def clip_read(data): '''Given the data for one read it returns clipped seq and qual.''' qual = data['quality_scores'] left, right = return_merged_clips(data) seq = data['bases'] qual = data['quality_scores'] new_seq = seq[left-1:right] new_qual = qual[left-1:right] return new_seq, new_qual def tests_for_ssaha(linker_fname): '''Tests whether SSAHA2 can be successfully called.''' try: print "Testing whether SSAHA2 is installed and can be launched ... ", sys.stdout.flush() fh = open('/dev/null', 'w') retcode = subprocess.call(["ssaha2", "-v"], stdout = fh) fh.close() print "ok." except : print "nope? Uh oh ...\n\n" raise RuntimeError('Could not launch ssaha2. Have you installed it? Is it in your path?') def load_linker_sequences(linker_fname): '''Loads all linker sequences into memory, storing only the length of each linker.''' global linkerlengths if not os.path.getsize(linker_fname): raise RuntimeError("File empty? '" + linker_fname + "'") fh = open(linker_fname, 'r') linkerseqs = read_fasta(fh) if len(linkerseqs) == 0: raise RuntimeError(linker_fname + ": no sequence found?") for i in linkerseqs: if linkerlengths.has_key(i.name): raise RuntimeError(linker_fname + ": sequence '" + i.name + "' present multiple times. Aborting.") linkerlengths[i.name] = len(i.sequence) fh.close() def launch_ssaha(linker_fname, query_fname, output_fh): '''Launches SSAHA2 on the linker and query file, string SSAHA2 output into the output filehandle''' try: print "Searching linker sequences with SSAHA2 (this may take a while) ... ", sys.stdout.flush() retcode = subprocess.call(["ssaha2", "-output", "ssaha2", "-solexa", "-kmer", "4", "-skip", "1", linker_fname, query_fname], stdout = output_fh) if retcode: raise RuntimeError('Ups.') else: print "ok." except: print "\n" raise RuntimeError('An error occured during the SSAHA2 execution, aborting.') def read_ssaha_data(ssahadata_fh): '''Given file handle, reads file generated with SSAHA2 (with default output format) and stores all matches as list ssahapematches (ssaha paired-end matches) dictionary''' global ssahapematches print "Parsing SSAHA2 result file ... ", sys.stdout.flush() for line in ssahadata_fh: if line.startswith('ALIGNMENT'): ml = line.split() if len(ml) != 12 : print "\n", line, raise RuntimeError('Expected 12 elements in the SSAHA2 line with ALIGMENT keyword, but found ' + str(len(ml))) if not ssahapematches.has_key(ml[2]) : ssahapematches[ml[2]] = ([]) if ml[8] == 'F': #print line, # store everything except the first element (output # format name (ALIGNMENT)) and the last element # (length) ssahapematches[ml[2]].append(ml[1:-1]) else: #print ml ml[4],ml[5] = ml[5],ml[4] #print ml ssahapematches[ml[2]].append(ml[1:-1]) print "done." ########################################################################## # # BaCh: This block was shamelessly copied from # http://python.genedrift.org/2007/07/04/reading-fasta-files-conclusion/ # and then subsequently modified to read fasta correctly # It's still not fool proof, but should be good enough # ########################################################################## class Fasta: def __init__(self, name, sequence): self.name = name self.sequence = sequence def read_fasta(file): items = [] aninstance = Fasta('', '') linenum = 0 for line in file: linenum += 1 if line.startswith(">"): if len(aninstance.sequence): items.append(aninstance) aninstance = Fasta('', '') # name == all characters until the first whitespace # (split()[0]) but without the starting ">" ([1:]) aninstance.name = line.split()[0][1:] aninstance.sequence = '' if len(aninstance.name) == 0: raise RuntimeError(file.name + ': no name in line ' + str(linenum) + '?') else: if len(aninstance.name) == 0: raise RuntimeError(file.name + ': no sequence header at line ' + str(linenum) + '?') aninstance.sequence += line.strip() if len(aninstance.name) and len(aninstance.sequence): items.append(aninstance) return items ########################################################################## def version_string (): return "sff_extract " + __version__ def read_config(): '''It reads the configuration options from the command line arguments and it returns a dict with them.''' from optparse import OptionParser, OptionGroup usage = "usage: %prog [options] sff1 sff2 ..." desc = "Extract sequences from 454 SFF files into FASTA, FASTA quality"\ " and XML traceinfo format. When a paired-end linker sequence"\ " is given (-l), use SSAHA2 to scan the sequences for the linker,"\ " then split the sequences, removing the linker." parser = OptionParser(usage = usage, version = version_string(), description = desc) parser.add_option('-a', '--append', action="store_true", dest='append', help='append output to existing files', default=False) parser.add_option('-i', '--xml_info', dest='xml_info', help='extra info to write in the xml file') parser.add_option("-l", "--linker_file", dest="pelinker_fname", help="FASTA file with paired-end linker sequences", metavar="FILE") group = OptionGroup(parser, "File name options","") group.add_option('-c', '--clip', action="store_true", dest='clip', help='clip (completely remove) ends with low qual and/or adaptor sequence', default=False) group.add_option('-u', '--upper_case', action="store_false", dest='mix_case', help='all bases in upper case, including clipped ends', default=True) group.add_option('', '--min_left_clip', dest='min_leftclip', metavar="INTEGER", type = "int", help='if the left clip coming from the SFF is smaller than this value, override it', default=0) group.add_option('-Q', '--fastq', action="store_true", dest='want_fastq', help='store as FASTQ file instead of FASTA + FASTA quality file', default=False) parser.add_option_group(group) group = OptionGroup(parser, "File name options","") group.add_option("-o", "--out_basename", dest="basename", help="base name for all output files") group.add_option("-s", "--seq_file", dest="seq_fname", help="output sequence file name", metavar="FILE") group.add_option("-q", "--qual_file", dest="qual_fname", help="output quality file name", metavar="FILE") group.add_option("-x", "--xml_file", dest="xml_fname", help="output ancillary xml file name", metavar="FILE") parser.add_option_group(group) #default fnames #is there an sff file? basename = 'reads' if sys.argv[-1][-4:].lower() == '.sff': basename = sys.argv[-1][:-4] def_seq_fname = basename + '.fasta' def_qual_fname = basename + '.fasta.qual' def_xml_fname = basename + '.xml' def_pelinker_fname = '' parser.set_defaults(seq_fname = def_seq_fname) parser.set_defaults(qual_fname = def_qual_fname) parser.set_defaults(xml_fname = def_xml_fname) parser.set_defaults(pelinker_fname = def_pelinker_fname) #we parse the cmd line (options, args) = parser.parse_args() #we put the result in a dict global config config = {} for property in dir(options): if property[0] == '_' or property in ('ensure_value', 'read_file', 'read_module'): continue config[property] = getattr(options, property) if config['basename'] is None: config['basename']=basename #if we have not set a file name with -s, -q or -x we set the basename #based file name if config['want_fastq']: config['qual_fname'] = '' if config['seq_fname'] == def_seq_fname: config['seq_fname'] = config['basename'] + '.fastq' else: if config['seq_fname'] == def_seq_fname: config['seq_fname'] = config['basename'] + '.fasta' if config['qual_fname'] == def_qual_fname: config['qual_fname'] = config['basename'] + '.fasta.qual' if config['xml_fname'] == def_xml_fname: config['xml_fname'] = config['basename'] + '.xml' #we parse the extra info for the xml file config['xml_info'] = parse_extra_info(config['xml_info']) return config, args ########################################################################## def testsome(): sys.exit() return def debug(): try: dummy = 1 #debug() #testsome() config, args = read_config() load_linker_sequences(config['pelinker_fname']) #pid = os.getpid() pid = 15603 #tmpfasta_fname = 'sffe.tmp.'+ str(pid)+'.fasta' #tmpfasta_fh = open(tmpfasta_fname, 'w') tmpfasta_fname = 'FLVI58L05.fa' tmpfasta_fh = open(tmpfasta_fname, 'r') tmpssaha_fname = 'sffe.tmp.'+str(pid)+'.ssaha2' tmpssaha_fh = open(tmpssaha_fname, 'w') launch_ssaha(config['pelinker_fname'], tmpfasta_fh.name, tmpssaha_fh) tmpssaha_fh = open("sffe.tmp.15603.ssaha2", 'r') read_ssaha_data(tmpssaha_fh) sys.exit() extract_reads_from_sff(config, args) except (OSError, IOError, RuntimeError), errval: print errval sys.exit() sys.exit() def main(): argv = sys.argv if len(argv) == 1: sys.argv.append('-h') read_config() sys.exit() try: #debug(); config, args = read_config() if config['pelinker_fname']: #tests_for_ssaha(config['pelinker_fname']) load_linker_sequences(config['pelinker_fname']) if len(args) == 0: raise RuntimeError("No SFF file given?") extract_reads_from_sff(config, args) except (OSError, IOError, RuntimeError), errval: print errval return 1 if stern_warning: return 1 return 0 if __name__ == "__main__": sys.exit(main())