Mercurial > repos > artbio > small_rna_signatures
view signature.py @ 9:59ee49bfb7bb draft
planemo upload for repository https://github.com/ARTbio/tools-artbio/tree/master/tools/small_rna_signatures commit 1298e352c2b9b1c40c6be95fb2625fc803f94d64
author | artbio |
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date | Fri, 26 Apr 2019 09:01:17 -0400 |
parents | 07771982ef9b |
children | 8d3ca9652a5b |
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import argparse from collections import defaultdict import numpy import pysam def Parser(): the_parser = argparse.ArgumentParser() the_parser.add_argument( '--input', action="store", type=str, help="bam alignment file") the_parser.add_argument( '--minquery', type=int, help="Minimum readsize of query reads (nt) - must be an integer") the_parser.add_argument( '--maxquery', type=int, help="Maximum readsize of query reads (nt) - must be an integer") the_parser.add_argument( '--mintarget', type=int, help="Minimum readsize of target reads (nt) - must be an integer") the_parser.add_argument( '--maxtarget', type=int, help="Maximum readsize of target reads (nt) - must be an integer") the_parser.add_argument( '--minscope', type=int, help="Minimum overlap analyzed (nt) - must be an integer") the_parser.add_argument( '--maxscope', type=int, help="Maximum overlap analyzed (nt) - must be an integer") the_parser.add_argument( '--output_h', action="store", type=str, help="h-signature dataframe") the_parser.add_argument( '--output_z', action="store", type=str, help="z-signature dataframe") args = the_parser.parse_args() return args class Map: def __init__(self, bam_file, minquery=23, maxquery=29, mintarget=23, maxtarget=29, minscope=1, maxscope=19, output_h='', output_z=''): self.bam_object = pysam.AlignmentFile(bam_file, 'rb') self.query_range = range(minquery, maxquery + 1) self.target_range = range(mintarget, maxtarget + 1) self.scope = range(minscope, maxscope + 1) self.H = open(output_h, 'w') self.Z = open(output_z, 'w') self.chromosomes = dict(zip(self.bam_object.references, self.bam_object.lengths)) self.map_dict = self.create_map(self.bam_object) self.query_positions = self.compute_query_positions() self.Z.write(self.compute_signature_pairs()) self.H.write(self.compute_signature_h()) self.H.close() self.Z.close() def create_map(self, bam_object): ''' Returns a map_dictionary {(chromosome,read_position,polarity): [read_length, ...]} ''' map_dictionary = defaultdict(list) # get empty value for start and end of each chromosome for chrom in self.chromosomes: map_dictionary[(chrom, 1, 'F')] = [] map_dictionary[(chrom, self.chromosomes[chrom], 'F')] = [] for chrom in self.chromosomes: for read in bam_object.fetch(chrom): if read.is_reverse: map_dictionary[(chrom, read.reference_end, 'R')].append(read.query_alignment_length) else: map_dictionary[(chrom, read.reference_start+1, 'F')].append(read.query_alignment_length) return map_dictionary def compute_query_positions(self): ''' this method does not filter on read size, just forward reads that overlap reverse reads in the overlap range''' all_query_positions = defaultdict(list) for genomicKey in self.map_dict.keys(): chrom, coord, pol = genomicKey for i in self.scope: if pol == 'F' and len(self.map_dict[chrom, coord+i-1, 'R']) > 0: all_query_positions[chrom].append(coord) break for chrom in all_query_positions: all_query_positions[chrom] = sorted( list(set(all_query_positions[chrom]))) return all_query_positions def countpairs(self, uppers, lowers): query_range = self.query_range target_range = self.target_range uppers = [size for size in uppers if size in query_range or size in target_range] lowers = [size for size in lowers if size in query_range or size in target_range] paired = [] for upread in uppers: for downread in lowers: if (upread in query_range and downread in target_range) or ( upread in target_range and downread in query_range): paired.append(upread) lowers.remove(downread) break return len(paired) def compute_signature_pairs(self): frequency_table = defaultdict(dict) scope = self.scope for chrom in self.chromosomes: for overlap in scope: frequency_table[chrom][overlap] = 0 for chrom in self.query_positions: for coord in self.query_positions[chrom]: for overlap in scope: uppers = self.map_dict[chrom, coord, 'F'] lowers = self.map_dict[chrom, coord+overlap-1, 'R'] frequency_table[chrom][overlap] += self.countpairs(uppers, lowers) # compute overlaps for all chromosomes merged for overlap in scope: accumulator = [] for chrom in frequency_table: if chrom != 'all_chromosomes': accumulator.append(frequency_table[chrom][overlap]) frequency_table['all_chromosomes'][overlap] = sum(accumulator) return self.stringify_table(frequency_table) def signature_tables(self): query_range = self.query_range target_range = self.target_range Query_table = defaultdict(dict) Target_table = defaultdict(dict) for key in self.map_dict: for size in self.map_dict[key]: if size in query_range or size in target_range: if key[2] == 'F': coordinate = key[1] else: coordinate = -key[1] if size in query_range: Query_table[key[0]][coordinate] = Query_table[key[0]].get( coordinate, 0) + 1 if size in target_range: Target_table[key[0]][coordinate] = \ Target_table[key[0]].get(coordinate, 0) + 1 return Query_table, Target_table def compute_signature_h(self): scope = self.scope Query_table, Target_table = self.signature_tables() frequency_table = defaultdict(dict) for chrom in self.chromosomes: for overlap in scope: frequency_table[chrom][overlap] = 0 for chrom in Query_table: Total_Query_Numb = 0 for coord in Query_table[chrom]: Total_Query_Numb += Query_table[chrom][coord] for coord in Query_table[chrom]: local_table = dict([(overlap, 0) for overlap in scope]) number_of_targets = 0 for overlap in scope: local_table[overlap] += Query_table[chrom][coord] * \ Target_table[chrom].get(-coord - overlap + 1, 0) number_of_targets += Target_table[chrom].get( -coord - overlap + 1, 0) for overlap in scope: try: frequency_table[chrom][overlap] += \ local_table[overlap] / number_of_targets \ / float(Total_Query_Numb) except ZeroDivisionError: continue # compute overlap probabilities for all chromosomes merged general_frequency_table = dict([(overlap, 0) for overlap in scope]) total_aligned_reads = 0 for chrom in frequency_table: for overlap in frequency_table[chrom]: total_aligned_reads += self.bam_object.count(chrom) for chrom in frequency_table: for overlap in frequency_table[chrom]: try: general_frequency_table[overlap] += \ frequency_table[chrom][overlap] / total_aligned_reads \ * self.bam_object.count(chrom) except ZeroDivisionError: continue for overlap in general_frequency_table: frequency_table['all_chromosomes'][overlap] = \ general_frequency_table[overlap] return self.stringify_table(frequency_table) def stringify_table(self, frequency_table): ''' method both to compute z-score and to return a writable string ''' tablestring = [] for chrom in sorted(frequency_table): accumulator = [] for overlap in frequency_table[chrom]: accumulator.append(frequency_table[chrom][overlap]) z_mean = numpy.mean(accumulator) z_std = numpy.std(accumulator) if z_std == 0: for overlap in sorted(frequency_table[chrom]): tablestring.append('%s\t%s\t%s\t%s\n' % ( chrom, str(overlap), str(frequency_table[chrom][overlap]), str(0))) else: for overlap in sorted(frequency_table[chrom]): tablestring.append('%s\t%s\t%s\t%s\n' % ( chrom, str(overlap), str(frequency_table[chrom][overlap]), str((frequency_table[chrom][overlap] - z_mean)/z_std))) return ''.join(tablestring) if __name__ == "__main__": args = Parser() mapobj = Map(args.input, args.minquery, args.maxquery, args.mintarget, args.maxtarget, args.minscope, args.maxscope, args.output_h, args.output_z)