def combine_pdfs(BP, c, use_product, weighting_scheme): L = [] R = [] for b_i in c: b = BP[b_i] L.append([b.left.start, b.left.end, b.left.p]) R.append([b.right.start, b.right.end, b.right.p]) [start_R, end_R, a_R] = l_bp.align_intervals(R) [start_L, end_L, a_L] = l_bp.align_intervals(L) p_L = [0] * len(a_L[0]) p_R = [0] * len(a_R[0]) wts = [1] * len(c) for c_i in range(len(c)): if weighting_scheme == 'evidence_wt': A = BP[c[c_i]].l.rstrip().split('\t', 10) m = l_bp.to_map(A[7]) wt = int(m['SU']) #sys.stderr.write("wt\t0\t"+str(wt)+"\n") a_L[c_i] = [wt * ali for ali in a_L[c_i]] a_R[c_i] = [wt * ari for ari in a_R[c_i]] elif weighting_scheme == 'carrier_wt': A = BP[c[c_i]].l.rstrip().split('\t', 10) m = l_bp.to_map(A[7]) wt = 1 if 'SNAME' in m: wt = len(m['SNAME'].split(',')) a_L[c_i] = [wt * ali for ali in a_L[c_i]] a_R[c_i] = [wt * ari for ari in a_R[c_i]] for i in range(len(a_L[c_i])): #sys.stderr.write("L\t"+str(i)+"\t"+str(c_i)+"\t"+str(a_L[c_i][i])+"\n") p_L[i] += a_L[c_i][i] for i in range(len(a_R[c_i])): #sys.stderr.write("R\t"+str(i)+"\t"+str(c_i)+"\t"+str(a_R[c_i][i])+"\n") p_R[i] += a_R[c_i][i] ALG = 'SUM' if use_product: pmax_i_L = p_L.index(max(p_L)) pmax_i_R = p_R.index(max(p_R)) miss = 0 for c_i in range(len(c)): if (a_L[c_i][pmax_i_L] == 0) or (a_R[c_i][pmax_i_R] == 0): miss += 1 if miss == 0: ALG = "PROD" ls_p_L = [ls.get_ls(1)] * len(a_L[0]) ls_p_R = [ls.get_ls(1)] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): ls_p_L[i] = ls.ls_multiply(ls_p_L[i], ls.get_ls(a_L[c_i][i])) for i in range(len(a_R[c_i])): ls_p_R[i] = ls.ls_multiply(ls_p_R[i], ls.get_ls(a_R[c_i][i])) ls_sum_L = ls.get_ls(0) ls_sum_R = ls.get_ls(0) for ls_p in ls_p_L: ls_sum_L = ls.ls_add(ls_sum_L, ls_p) for ls_p in ls_p_R: ls_sum_R = ls.ls_add(ls_sum_R, ls_p) p_L = [] for ls_p in ls_p_L: p_L.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_L))) p_R = [] for ls_p in ls_p_R: p_R.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_R))) sum_L = sum(p_L) sum_R = sum(p_R) p_L = [x / sum_L for x in p_L] p_R = [x / sum_L for x in p_R] [clip_start_L, clip_end_L] = l_bp.trim(p_L) [clip_start_R, clip_end_R] = l_bp.trim(p_R) [new_start_L, new_end_L] = [start_L + clip_start_L, end_L - clip_end_L] [new_start_R, new_end_R] = [start_R + clip_start_R, end_R - clip_end_R] p_L = p_L[clip_start_L:len(p_L) - clip_end_L] p_R = p_R[clip_start_R:len(p_R) - clip_end_R] s_p_L = sum(p_L) s_p_R = sum(p_R) p_L = [x / s_p_L for x in p_L] p_R = [x / s_p_R for x in p_R] #sys.exit(1) return new_start_L, new_start_R, p_L, p_R, ALG
def merge(BP, sample_order, v_id, use_product): if len(BP) == 1: A = BP[0].l.rstrip().split('\t') #tack on id to SNAME s_start = A[7].find('SNAME=') s_end = A[7].find(';', s_start) if (s_end > -1): A[7] = A[7][:s_start] + \ A[7][s_start:s_end] + \ ':' + A[2] + \ A[7][s_end:] else: A[7] += ':' + A[2] # reset the id to be unique in this file v_id += 1 A[2] = str(v_id) #clip out old mate id s_start = A[7].find('MATEID=') s_end = A[7].find(';', s_start) if (s_end > -1): A[7] = A[7][:s_start] + A[7][s_end + 1:] elif (s_start > -1): A[7] = A[7][:s_start] #clip out old event id s_start = A[7].find('EVENT=') s_end = A[7].find(';', s_start) if (s_end > -1): A[7] = A[7][:s_start] + A[7][s_end + 1:] elif (s_start > -1): A[7] = A[7][:s_start] #add new mate A[7] += ';EVENT=' + A[2] #add new alg if use_product: A[7] += ';ALG=PROD' else: A[7] += ';ALG=SUM' print_var_line('\t'.join(A)) return v_id #Sweep the set. Find the largest intersecting set. Remove it. Continue. import heapq BP.sort(key=lambda x: x.start_l) BP_i = range(len(BP)) # index set of each node in the graph C = [] while len(BP_i) > 0: h_l = [ ] #heap of left breakpoint end coordinates and node id (index). heapq is a min heap and the end coord is what will be used for the sorting. max_c = [] max_c_len = 0 for i in BP_i: # remove anything in the heap that doesn't intersect with the current breakpoint while (len(h_l) > 0) and (h_l[0][0] < BP[i].start_l): heapq.heappop(h_l) heapq.heappush(h_l, (BP[i].end_l, i)) # add to the heap # at this point everything in h_l intersects on the left # but we need to take into account what is going on on the right h_r = [] # heap with rightmost starts h_l_i = [x[1] for x in h_l ] # this is all of the node ids on the heap currently h_l_i.sort( key=lambda x: BP[x].start_r) # sort them by their right start for j in h_l_i: # remove anything in the heap that doesn't intersect with the current breakpoint on the right end while (len(h_r) > 0) and (h_r[0][0] < BP[j].start_r): heapq.heappop(h_r) # add something to the right heap heapq.heappush(h_r, (BP[j].end_r, j)) if max_c_len < len(h_r): # max clique! Register what nodes we have max_c_len = len(h_r) max_c = [y[1] for y in h_r] C.append(max_c) for c in max_c: BP_i.remove(c) for c in C: L = [] R = [] for b_i in c: b = BP[b_i] L.append([b.start_l, b.end_l, b.p_l]) R.append([b.start_r, b.end_r, b.p_r]) [start_R, end_R, a_R] = l_bp.align_intervals(R) [start_L, end_L, a_L] = l_bp.align_intervals(L) p_L = [0] * len(a_L[0]) p_R = [0] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): p_L[i] += a_L[c_i][i] for i in range(len(a_R[c_i])): p_R[i] += a_R[c_i][i] ALG = 'SUM' if use_product: pmax_i_L = p_L.index(max(p_L)) pmax_i_R = p_R.index(max(p_R)) miss = 0 for c_i in range(len(c)): if (a_L[c_i][pmax_i_L] == 0) or (a_R[c_i][pmax_i_R] == 0): miss += 1 if miss == 0: ALG = "PROD" ls_p_L = [ls.get_ls(1)] * len(a_L[0]) ls_p_R = [ls.get_ls(1)] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): ls_p_L[i] = ls.ls_multiply(ls_p_L[i], ls.get_ls(a_L[c_i][i])) for i in range(len(a_R[c_i])): ls_p_R[i] = ls.ls_multiply(ls_p_R[i], ls.get_ls(a_R[c_i][i])) ls_sum_L = ls.get_ls(0) ls_sum_R = ls.get_ls(0) for ls_p in ls_p_L: ls_sum_L = ls.ls_add(ls_sum_L, ls_p) for ls_p in ls_p_R: ls_sum_R = ls.ls_add(ls_sum_R, ls_p) p_L = [] for ls_p in ls_p_L: p_L.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_L))) p_R = [] for ls_p in ls_p_R: p_R.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_R))) sum_L = sum(p_L) sum_R = sum(p_R) p_L = [x / sum_L for x in p_L] p_R = [x / sum_L for x in p_R] [clip_start_L, clip_end_L] = l_bp.trim(p_L) [clip_start_R, clip_end_R] = l_bp.trim(p_R) new_start_L = start_L + clip_start_L new_end_L = end_L - clip_end_L new_start_R = start_R + clip_start_R new_end_R = end_R - clip_end_R p_L = p_L[clip_start_L:len(p_L) - clip_end_L] p_R = p_R[clip_start_R:len(p_R) - clip_end_R] s_p_L = sum(p_L) s_p_R = sum(p_R) p_L = [x / s_p_L for x in p_L] p_R = [x / s_p_R for x in p_R] max_i_L = p_L.index(max(p_L)) max_i_R = p_R.index(max(p_R)) ninefive_i_L_start = max_i_L ninefive_i_L_end = max_i_L ninefive_i_L_total = p_L[max_i_L] updated = 0 while (ninefive_i_L_total < 0.95): if (ninefive_i_L_start <= 0) and (ninefive_i_L_end >= (len(p_L) - 1)): break ninefive_i_L_start = max(0, ninefive_i_L_start - 1) ninefive_i_L_end = min(len(p_L) - 1, ninefive_i_L_end + 1) ninefive_i_L_total = sum(p_L[ninefive_i_L_start:ninefive_i_L_end + 1]) ninefive_i_L_start = ninefive_i_L_start - max_i_L ninefive_i_L_end = ninefive_i_L_end - max_i_L ninefive_i_R_start = max_i_R ninefive_i_R_end = max_i_R ninefive_i_R_total = p_R[max_i_R] updated = 0 while (ninefive_i_R_total < 0.95): if (ninefive_i_R_start <= 0) and (ninefive_i_R_end >= len(p_R) - 1): break ninefive_i_R_start = max(0, ninefive_i_R_start - 1) ninefive_i_R_end = min(len(p_R) - 1, ninefive_i_R_end + 1) ninefive_i_R_total = sum(p_R[ninefive_i_R_start:ninefive_i_R_end + 1]) ninefive_i_R_end = ninefive_i_R_end - max_i_R ninefive_i_R_start = ninefive_i_R_start - max_i_R CIPOS95 = str(ninefive_i_L_start) + ',' + str(ninefive_i_L_end) CIEND95 = str(ninefive_i_R_start) + ',' + str(ninefive_i_R_end) CHROM = BP[c[0]].chr_l POS = new_start_L + max_i_L v_id += 1 ID = str(v_id) REF = 'N' ALT = '' if BP[c[0]].sv_type == 'BND': if BP[c[0]].strands[:2] == '++': ALT = 'N]' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ ']' elif BP[c[0]].strands[:2] == '-+': ALT = ']' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ ']N' elif BP[c[0]].strands[:2] == '+-': ALT = 'N[' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ '[' elif BP[c[0]].strands[:2] == '--': ALT = '[' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ '[N' else: ALT = '<' + BP[c[0]].sv_type + '>' QUAL = 0.0 FILTER = '.' FORMAT = BP[c[0]].l.split('\t')[8] SVTYPE = BP[c[0]].sv_type STRANDS = '' strand_map = {} e_type_map = {} SU = 0 PE = 0 SR = 0 s_name_list = [] gt_list = [] for b_i in c: A = BP[b_i].l.rstrip().split('\t') if A[5].isdigit(): QUAL += float(A[5]) m = l_bp.to_map(A[7]) for strand_entry in m['STRANDS'].split(','): s_type, s_count = strand_entry.split(':') if s_type not in strand_map: strand_map[s_type] = 0 strand_map[s_type] += int(s_count) SU += int(m['SU']) PE += int(m['PE']) SR += int(m['SR']) s_name_list.append(m['SNAME'] + ':' + A[2]) gt_list += A[9:] SNAME = ','.join(s_name_list) GTS = '\t'.join(gt_list) strand_types_counts = [] for strand in strand_map: strand_types_counts.append(strand + ':' + str(strand_map[strand])) STRANDS = ','.join(strand_types_counts) if SVTYPE == 'DEL': SVLEN = (new_start_L + max_i_L) - (new_start_R + max_i_R) else: SVLEN = (new_start_R + max_i_R) - (new_start_L + max_i_L) # Don't set SVLEN if we have an interchromosomal event. Doesn't make any sense. if BP[c[0]].chr_l != BP[c[0]].chr_r: SVLEN = None END = new_start_R + max_i_R CIPOS = ','.join( [str(x) for x in [-1 * max_i_L, len(p_L) - max_i_L - 1]]) CIEND = ','.join( [str(x) for x in [-1 * max_i_R, len(p_R) - max_i_R - 1]]) IMPRECISE = 'IMPRECISE' PRPOS = ','.join([str(x) for x in p_L]) PREND = ','.join([str(x) for x in p_R]) if (int(CIPOS.split(',')[0]) > int(CIPOS95.split(',')[0])) or \ (int(CIPOS.split(',')[1]) < int(CIPOS95.split(',')[1])) or \ (int(CIEND.split(',')[0]) > int(CIEND95.split(',')[0])) or \ (int(CIEND.split(',')[1]) < int(CIEND95.split(',')[1])): sys.stderr.write(CIPOS + "\t" + str(CIPOS95) + "\n") sys.stderr.write(CIEND + "\t" + str(CIEND95) + "\n") I = ['SVTYPE=' + str(SVTYPE), 'STRANDS=' + str(STRANDS)] if SVLEN: I += ['SVLEN=' + str(SVLEN)] I += [ 'CIPOS=' + str(CIPOS), 'CIEND=' + str(CIEND), 'CIPOS95=' + str(CIPOS95), 'CIEND95=' + str(CIEND95), str(IMPRECISE), 'SU=' + str(SU), 'PE=' + str(PE), 'SR=' + str(SR), 'PRPOS=' + str(PRPOS), 'PREND=' + str(PREND), 'ALG=' + str(ALG), 'SNAME=' + str(SNAME) ] if BP[c[0]].sv_type == 'BND': I.append('EVENT=' + str(ID)) else: I.append('END=' + str(END)) INFO = ';'.join(I) QUAL = str(QUAL) O = [CHROM, POS, ID, REF, ALT, QUAL, FILTER, INFO] print_var_line('\t'.join([str(o) for o in O])) return v_id
def combine_pdfs(BP, c, use_product, weighting_scheme): L = [] R = [] for b_i in c: b = BP[b_i] L.append([b.left.start, b.left.end, b.left.p]) R.append([b.right.start, b.right.end, b.right.p]) [start_R, end_R, a_R] = l_bp.align_intervals(R) [start_L, end_L, a_L] = l_bp.align_intervals(L) p_L = [0] * len(a_L[0]) p_R = [0] * len(a_R[0]) wts = [1] * len(c) for c_i in range(len(c)): if weighting_scheme == 'evidence_wt': A = BP[c[c_i]].l.rstrip().split('\t', 10) m = l_bp.to_map(A[7]) wt=int(m['SU']) #sys.stderr.write("wt\t0\t"+str(wt)+"\n") a_L[c_i]=[wt*ali for ali in a_L[c_i]] a_R[c_i]=[wt*ari for ari in a_R[c_i]] elif weighting_scheme == 'carrier_wt': A = BP[c[c_i]].l.rstrip().split('\t', 10) m = l_bp.to_map(A[7]) wt = 1 if 'SNAME' in m: wt=len(m['SNAME'].split(',')) a_L[c_i]=[wt*ali for ali in a_L[c_i]] a_R[c_i]=[wt*ari for ari in a_R[c_i]] for i in range(len(a_L[c_i])): #sys.stderr.write("L\t"+str(i)+"\t"+str(c_i)+"\t"+str(a_L[c_i][i])+"\n") p_L[i] += a_L[c_i][i] for i in range(len(a_R[c_i])): #sys.stderr.write("R\t"+str(i)+"\t"+str(c_i)+"\t"+str(a_R[c_i][i])+"\n") p_R[i] += a_R[c_i][i] ALG = 'SUM' if use_product: pmax_i_L = p_L.index(max(p_L)) pmax_i_R = p_R.index(max(p_R)) miss = 0 for c_i in range(len(c)): if (a_L[c_i][pmax_i_L] == 0) or (a_R[c_i][pmax_i_R] == 0): miss += 1 if miss == 0: ALG = "PROD" ls_p_L = [ls.get_ls(1)] * len(a_L[0]) ls_p_R = [ls.get_ls(1)] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): ls_p_L[i] = ls.ls_multiply(ls_p_L[i], ls.get_ls(a_L[c_i][i])) for i in range(len(a_R[c_i])): ls_p_R[i] = ls.ls_multiply(ls_p_R[i], ls.get_ls(a_R[c_i][i])) ls_sum_L = ls.get_ls(0) ls_sum_R = ls.get_ls(0) for ls_p in ls_p_L: ls_sum_L = ls.ls_add(ls_sum_L, ls_p) for ls_p in ls_p_R: ls_sum_R = ls.ls_add(ls_sum_R, ls_p) p_L = [] for ls_p in ls_p_L: p_L.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_L))) p_R = [] for ls_p in ls_p_R: p_R.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_R))) sum_L = sum(p_L) sum_R = sum(p_R) p_L = [x/sum_L for x in p_L] p_R = [x/sum_L for x in p_R] [clip_start_L, clip_end_L] = l_bp.trim(p_L) [clip_start_R, clip_end_R] = l_bp.trim(p_R) [ new_start_L, new_end_L ] = [ start_L + clip_start_L, end_L - clip_end_L ] [ new_start_R, new_end_R ] = [ start_R + clip_start_R, end_R - clip_end_R ] p_L = p_L[clip_start_L:len(p_L)-clip_end_L] p_R = p_R[clip_start_R:len(p_R)-clip_end_R] s_p_L = sum(p_L) s_p_R = sum(p_R) p_L = [x/s_p_L for x in p_L] p_R = [x/s_p_R for x in p_R] #sys.exit(1) return new_start_L, new_start_R, p_L, p_R, ALG
def merge(BP, sample_order, v_id, use_product): if len(BP) == 1: A = BP[0].l.rstrip().split('\t') #tack on id to SNAME s_start=A[7].find('SNAME=') s_end=A[7].find(';',s_start) if (s_end > -1): A[7] = A[7][:s_start] + \ A[7][s_start:s_end] + \ ':' + A[2] + \ A[7][s_end:] else: A[7]+= ':' + A[2] # reset the id to be unique in this file v_id += 1 A[2] = str(v_id) #clip out old mate id s_start=A[7].find('MATEID=') s_end=A[7].find(';',s_start) if (s_end > -1): A[7] = A[7][:s_start] + A[7][s_end+1:] elif (s_start > -1): A[7] = A[7][:s_start] #clip out old event id s_start=A[7].find('EVENT=') s_end=A[7].find(';', s_start) if (s_end > -1): A[7] = A[7][:s_start] + A[7][s_end+1:] elif (s_start > -1): A[7] = A[7][:s_start] #add new mate A[7]+= ';EVENT=' + A[2] #add new alg if use_product: A[7]+= ';ALG=PROD' else: A[7] += ';ALG=SUM' print_var_line('\t'.join(A)) return v_id #Sweep the set. Find the largest intersecting set. Remove it. Continue. import heapq BP.sort(key=lambda x: x.start_l) BP_i = range(len(BP)) # index set of each node in the graph C = [] while len(BP_i) > 0: h_l = [] #heap of left breakpoint end coordinates and node id (index). heapq is a min heap and the end coord is what will be used for the sorting. max_c = [] max_c_len = 0 for i in BP_i: # remove anything in the heap that doesn't intersect with the current breakpoint while (len(h_l) > 0) and (h_l[0][0] < BP[i].start_l): heapq.heappop(h_l) heapq.heappush(h_l, (BP[i].end_l, i)) # add to the heap # at this point everything in h_l intersects on the left # but we need to take into account what is going on on the right h_r = [] # heap with rightmost starts h_l_i = [x[1] for x in h_l] # this is all of the node ids on the heap currently h_l_i.sort(key=lambda x:BP[x].start_r) # sort them by their right start for j in h_l_i: # remove anything in the heap that doesn't intersect with the current breakpoint on the right end while (len(h_r) > 0) and (h_r[0][0] < BP[j].start_r): heapq.heappop(h_r) # add something to the right heap heapq.heappush(h_r, (BP[j].end_r, j)) if max_c_len < len(h_r): # max clique! Register what nodes we have max_c_len = len(h_r) max_c = [y[1] for y in h_r] C.append(max_c) for c in max_c: BP_i.remove(c) for c in C: L = [] R = [] for b_i in c: b = BP[b_i] L.append([b.start_l,b.end_l,b.p_l]) R.append([b.start_r,b.end_r,b.p_r]) [start_R, end_R, a_R] = l_bp.align_intervals(R) [start_L, end_L, a_L] = l_bp.align_intervals(L) p_L = [0] * len(a_L[0]) p_R = [0] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): p_L[i] += a_L[c_i][i] for i in range(len(a_R[c_i])): p_R[i] += a_R[c_i][i] ALG = 'SUM' if use_product: pmax_i_L = p_L.index(max(p_L)) pmax_i_R = p_R.index(max(p_R)) miss = 0 for c_i in range(len(c)): if (a_L[c_i][pmax_i_L] == 0) or (a_R[c_i][pmax_i_R] == 0): miss += 1 if miss == 0: ALG = "PROD" ls_p_L = [ls.get_ls(1)] * len(a_L[0]) ls_p_R = [ls.get_ls(1)] * len(a_R[0]) for c_i in range(len(c)): for i in range(len(a_L[c_i])): ls_p_L[i] = ls.ls_multiply(ls_p_L[i], ls.get_ls(a_L[c_i][i])) for i in range(len(a_R[c_i])): ls_p_R[i] = ls.ls_multiply(ls_p_R[i], ls.get_ls(a_R[c_i][i])) ls_sum_L = ls.get_ls(0) ls_sum_R = ls.get_ls(0) for ls_p in ls_p_L: ls_sum_L = ls.ls_add(ls_sum_L, ls_p) for ls_p in ls_p_R: ls_sum_R = ls.ls_add(ls_sum_R, ls_p) p_L = [] for ls_p in ls_p_L: p_L.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_L))) p_R = [] for ls_p in ls_p_R: p_R.append(ls.get_p(ls.ls_divide(ls_p, ls_sum_R))) sum_L = sum(p_L) sum_R = sum(p_R) p_L = [x/sum_L for x in p_L] p_R = [x/sum_L for x in p_R] [clip_start_L, clip_end_L] = l_bp.trim(p_L) [clip_start_R, clip_end_R] = l_bp.trim(p_R) new_start_L = start_L + clip_start_L new_end_L = end_L - clip_end_L new_start_R = start_R + clip_start_R new_end_R = end_R - clip_end_R p_L = p_L[clip_start_L:len(p_L)-clip_end_L] p_R = p_R[clip_start_R:len(p_R)-clip_end_R] s_p_L = sum(p_L) s_p_R = sum(p_R) p_L = [x/s_p_L for x in p_L] p_R = [x/s_p_R for x in p_R] max_i_L = p_L.index(max(p_L)) max_i_R = p_R.index(max(p_R)) ninefive_i_L_start = max_i_L ninefive_i_L_end = max_i_L ninefive_i_L_total = p_L[max_i_L] updated = 0 while (ninefive_i_L_total < 0.95): if (ninefive_i_L_start <= 0) and (ninefive_i_L_end >= (len(p_L)-1)): break ninefive_i_L_start = max(0, ninefive_i_L_start - 1) ninefive_i_L_end = min(len(p_L)-1, ninefive_i_L_end +1) ninefive_i_L_total = sum(p_L[ninefive_i_L_start:ninefive_i_L_end+1]) ninefive_i_L_start = ninefive_i_L_start - max_i_L ninefive_i_L_end = ninefive_i_L_end - max_i_L ninefive_i_R_start = max_i_R ninefive_i_R_end = max_i_R ninefive_i_R_total = p_R[max_i_R] updated = 0 while (ninefive_i_R_total < 0.95): if (ninefive_i_R_start <= 0) and (ninefive_i_R_end >= len(p_R)-1): break ninefive_i_R_start = max(0, ninefive_i_R_start - 1) ninefive_i_R_end = min(len(p_R)-1, ninefive_i_R_end +1) ninefive_i_R_total = sum(p_R[ninefive_i_R_start:ninefive_i_R_end+1]) ninefive_i_R_end = ninefive_i_R_end - max_i_R ninefive_i_R_start = ninefive_i_R_start - max_i_R CIPOS95=str(ninefive_i_L_start) + ',' + str(ninefive_i_L_end) CIEND95=str(ninefive_i_R_start) + ',' + str(ninefive_i_R_end) CHROM = BP[c[0]].chr_l POS = new_start_L + max_i_L v_id += 1 ID = str(v_id) REF = 'N' ALT = '' if BP[c[0]].sv_type == 'BND': if BP[c[0]].strands[:2] == '++': ALT = 'N]' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ ']' elif BP[c[0]].strands[:2] == '-+': ALT = ']' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ ']N' elif BP[c[0]].strands[:2] == '+-': ALT = 'N[' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ '[' elif BP[c[0]].strands[:2] == '--': ALT = '[' + \ BP[c[0]].chr_r + \ ':' + \ str(new_start_R + max_i_R) + \ '[N' else: ALT = '<' + BP[c[0]].sv_type + '>' QUAL = 0.0 FILTER = '.' FORMAT = BP[c[0]].l.split('\t')[8] SVTYPE = BP[c[0]].sv_type STRANDS = '' strand_map = {} e_type_map = {} SU = 0 PE = 0 SR = 0 s_name_list = [] gt_list = [] for b_i in c: A = BP[b_i].l.rstrip().split('\t') if A[5].isdigit(): QUAL += float(A[5]) m = l_bp.to_map(A[7]) for strand_entry in m['STRANDS'].split(','): s_type,s_count = strand_entry.split(':') if s_type not in strand_map: strand_map[s_type] = 0 strand_map[s_type] += int(s_count) SU += int(m['SU']) PE += int(m['PE']) SR += int(m['SR']) s_name_list.append(m['SNAME'] + ':' + A[2]) gt_list += A[9:] SNAME=','.join(s_name_list) GTS = '\t'.join(gt_list) strand_types_counts = [] for strand in strand_map: strand_types_counts.append(strand + ':' + str(strand_map[strand])) STRANDS = ','.join(strand_types_counts) if SVTYPE=='DEL': SVLEN = (new_start_L + max_i_L) - (new_start_R + max_i_R) else: SVLEN = (new_start_R + max_i_R) - (new_start_L + max_i_L) # Don't set SVLEN if we have an interchromosomal event. Doesn't make any sense. if BP[c[0]].chr_l != BP[c[0]].chr_r: SVLEN = None END = new_start_R + max_i_R CIPOS=','.join([str(x) for x in [-1*max_i_L, len(p_L) - max_i_L - 1]]) CIEND=','.join([str(x) for x in [-1*max_i_R, len(p_R) - max_i_R - 1]]) IMPRECISE='IMPRECISE' PRPOS=','.join([str(x) for x in p_L]) PREND=','.join([str(x) for x in p_R]) if (int(CIPOS.split(',')[0]) > int(CIPOS95.split(',')[0])) or \ (int(CIPOS.split(',')[1]) < int(CIPOS95.split(',')[1])) or \ (int(CIEND.split(',')[0]) > int(CIEND95.split(',')[0])) or \ (int(CIEND.split(',')[1]) < int(CIEND95.split(',')[1])): sys.stderr.write(CIPOS + "\t" + str(CIPOS95) + "\n") sys.stderr.write(CIEND + "\t" + str(CIEND95) + "\n") I = ['SVTYPE=' + str(SVTYPE), 'STRANDS=' + str(STRANDS) ] if SVLEN: I += ['SVLEN=' + str(SVLEN)] I += ['CIPOS=' + str(CIPOS), 'CIEND=' + str(CIEND), 'CIPOS95=' + str(CIPOS95), 'CIEND95=' + str(CIEND95), str(IMPRECISE), 'SU=' + str(SU), 'PE=' + str(PE), 'SR=' + str(SR), 'PRPOS=' + str(PRPOS), 'PREND=' + str(PREND), 'ALG=' + str(ALG), 'SNAME=' + str(SNAME)] if BP[c[0]].sv_type == 'BND': I.append('EVENT=' + str(ID)) else: I.append('END=' + str(END)) INFO = ';'.join(I) QUAL = str(QUAL) O = [CHROM,POS,ID,REF,ALT,QUAL,FILTER,INFO] print_var_line('\t'.join([str(o) for o in O])) return v_id
def test_ls_divide(self): x = 2 y = 1 self.assertEqual(ls.ls_divide(x, y), 1.0) self.assertEqual(ls.ls_divide(x, x), 0.0)