From 0ffe3e7936844995675cbddb450a11aa59aa8393 Mon Sep 17 00:00:00 2001 From: Po-Chuan Hsieh Date: Fri, 25 Mar 2022 21:32:02 +0800 Subject: biology/py-crossmap: Fix build with setuptools 58.0.0+ With hat: python --- biology/py-crossmap/files/patch-2to3 | 2955 ++++++++++++++++++++++++++++++++++ 1 file changed, 2955 insertions(+) create mode 100644 biology/py-crossmap/files/patch-2to3 diff --git a/biology/py-crossmap/files/patch-2to3 b/biology/py-crossmap/files/patch-2to3 new file mode 100644 index 000000000000..c3b680224b43 --- /dev/null +++ b/biology/py-crossmap/files/patch-2to3 @@ -0,0 +1,2955 @@ +--- lib/cmmodule/SAM.py.orig 2018-12-17 16:05:26 UTC ++++ lib/cmmodule/SAM.py +@@ -150,52 +150,52 @@ class ParseSAM: + forward_SE +=1 + + if paired: +- print >>sys.stderr,"\n#==================================================" +- print >>sys.stderr,"#================Report (pair-end)=================" +- print >>sys.stderr, "%-25s%d" % ("Total Reads:",total_read) +- print >>sys.stderr, "%-25s%d" % ("Total Mapped Reads:", (mapped_read1 + mapped_read2)) +- print >>sys.stderr, "%-25s%d" % ("Total Unmapped Reads:",(unmapped_read1 + unmapped_read2)) +- print >>sys.stderr, "%-25s%d" % ("PCR duplicate:",pcr_duplicate) +- print >>sys.stderr, "%-25s%d" % ("QC-failed:",low_qual) +- print >>sys.stderr, "%-25s%d" % ("Not primary mapping:",secondary_hit) +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-25s%d" % ("Unmapped Read-1:",unmapped_read1) +- print >>sys.stderr, "%-25s%d" % ("Mapped Read-1:",mapped_read1) +- print >>sys.stderr, "%-25s%d" % (" Forward (+):",forward_read1) +- print >>sys.stderr, "%-25s%d" % (" Reverse (-):",reverse_read1) ++ print("\n#==================================================", file=sys.stderr) ++ print("#================Report (pair-end)=================", file=sys.stderr) ++ print("%-25s%d" % ("Total Reads:",total_read), file=sys.stderr) ++ print("%-25s%d" % ("Total Mapped Reads:", (mapped_read1 + mapped_read2)), file=sys.stderr) ++ print("%-25s%d" % ("Total Unmapped Reads:",(unmapped_read1 + unmapped_read2)), file=sys.stderr) ++ print("%-25s%d" % ("PCR duplicate:",pcr_duplicate), file=sys.stderr) ++ print("%-25s%d" % ("QC-failed:",low_qual), file=sys.stderr) ++ print("%-25s%d" % ("Not primary mapping:",secondary_hit), file=sys.stderr) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-25s%d" % ("Unmapped Read-1:",unmapped_read1), file=sys.stderr) ++ print("%-25s%d" % ("Mapped Read-1:",mapped_read1), file=sys.stderr) ++ print("%-25s%d" % (" Forward (+):",forward_read1), file=sys.stderr) ++ print("%-25s%d" % (" Reverse (-):",reverse_read1), file=sys.stderr) + +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-25s%d" % ("Unmapped Read-2:",unmapped_read2) +- print >>sys.stderr, "%-25s%d" % ("Mapped Read-2:",mapped_read2) +- print >>sys.stderr, "%-25s%d" % (" Forward (+):",forward_read2) +- print >>sys.stderr, "%-25s%d" % (" Reverse (-):",reverse_read2) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-25s%d" % ("Unmapped Read-2:",unmapped_read2), file=sys.stderr) ++ print("%-25s%d" % ("Mapped Read-2:",mapped_read2), file=sys.stderr) ++ print("%-25s%d" % (" Forward (+):",forward_read2), file=sys.stderr) ++ print("%-25s%d" % (" Reverse (-):",reverse_read2), file=sys.stderr) + +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-25s%d" % ("Mapped to (+/-):",plus_minus) +- print >>sys.stderr, "%-25s%d" % ("Mapped to (-/+):",minus_plus) +- print >>sys.stderr, "%-25s%d" % ("Mapped to (+/+):",plus_plus) +- print >>sys.stderr, "%-25s%d" % ("Mapped to (-/-):",minus_minus) +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-25s%d" % ("Spliced Hits:",_numSplitHit) +- print >>sys.stderr, "%-25s%d" % ("Non-spliced Hits:",_numMonoHit) +- print >>sys.stderr, "%-25s%d" % ("Reads have insertion:",_numInsertion) +- print >>sys.stderr, "%-25s%d" % ("Reads have deletion:",_numDeletion) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-25s%d" % ("Mapped to (+/-):",plus_minus), file=sys.stderr) ++ print("%-25s%d" % ("Mapped to (-/+):",minus_plus), file=sys.stderr) ++ print("%-25s%d" % ("Mapped to (+/+):",plus_plus), file=sys.stderr) ++ print("%-25s%d" % ("Mapped to (-/-):",minus_minus), file=sys.stderr) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-25s%d" % ("Spliced Hits:",_numSplitHit), file=sys.stderr) ++ print("%-25s%d" % ("Non-spliced Hits:",_numMonoHit), file=sys.stderr) ++ print("%-25s%d" % ("Reads have insertion:",_numInsertion), file=sys.stderr) ++ print("%-25s%d" % ("Reads have deletion:",_numDeletion), file=sys.stderr) + else: +- print >>sys.stderr,"\n#====================================================" +- print >>sys.stderr,"#================Report (single-end)=================" +- print >>sys.stderr, "%-25s%d" % ("Total Reads:",total_read) +- print >>sys.stderr, "%-25s%d" % ("Total Mapped Reads:", map_SE) +- print >>sys.stderr, "%-25s%d" % ("Total Unmapped Reads:",unmap_SE) +- print >>sys.stderr, "%-25s%d" % ("PCR duplicate:",pcr_duplicate) +- print >>sys.stderr, "%-25s%d" % ("QC-failed:",low_qual) +- print >>sys.stderr, "%-25s%d" % ("Not primary mapping:",secondary_hit) +- print >>sys.stderr, "%-25s%d" % ("froward (+):",forward_SE) +- print >>sys.stderr, "%-25s%d" % ("reverse (-):",reverse_SE) +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-25s%d" % ("Spliced Hits:",_numSplitHit) +- print >>sys.stderr, "%-25s%d" % ("Non-spliced Hits:",_numMonoHit) +- print >>sys.stderr, "%-25s%d" % ("Reads have insertion:",_numInsertion) +- print >>sys.stderr, "%-25s%d" % ("Reads have deletion:",_numDeletion) ++ print("\n#====================================================", file=sys.stderr) ++ print("#================Report (single-end)=================", file=sys.stderr) ++ print("%-25s%d" % ("Total Reads:",total_read), file=sys.stderr) ++ print("%-25s%d" % ("Total Mapped Reads:", map_SE), file=sys.stderr) ++ print("%-25s%d" % ("Total Unmapped Reads:",unmap_SE), file=sys.stderr) ++ print("%-25s%d" % ("PCR duplicate:",pcr_duplicate), file=sys.stderr) ++ print("%-25s%d" % ("QC-failed:",low_qual), file=sys.stderr) ++ print("%-25s%d" % ("Not primary mapping:",secondary_hit), file=sys.stderr) ++ print("%-25s%d" % ("froward (+):",forward_SE), file=sys.stderr) ++ print("%-25s%d" % ("reverse (-):",reverse_SE), file=sys.stderr) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-25s%d" % ("Spliced Hits:",_numSplitHit), file=sys.stderr) ++ print("%-25s%d" % ("Non-spliced Hits:",_numMonoHit), file=sys.stderr) ++ print("%-25s%d" % ("Reads have insertion:",_numInsertion), file=sys.stderr) ++ print("%-25s%d" % ("Reads have deletion:",_numDeletion), file=sys.stderr) + + def samTobed(self,outfile=None,mergePE=False): + """Convert SAM file to BED file. BED file will be saved as xxx.sam.bed unless otherwise specified. +@@ -204,7 +204,7 @@ class ParseSAM: + if outfile is None: + outfile=self.fileName + ".bed" + +- print >>sys.stderr,"\tWriting bed entries to\"",outfile,"\"...", ++ print("\tWriting bed entries to\"",outfile,"\"...", end=' ', file=sys.stderr) + FO=open(outfile,'w') + for line in self.f: + if line.startswith(('@','track')):continue #skip head lines +@@ -240,14 +240,14 @@ class ParseSAM: + for i in range(0,len(comb),2): + blockStart.append(str(sum(comb[:i]))) + blockStarts = ','.join(blockStart) +- print >>FO, string.join((str(i) for i in [chrom,chromStart,chromEnd,name,score,strand,thickStart,thickEnd,itemRgb,blockCount,blockSizes,blockStarts]),sep="\t") +- print >>sys.stderr, "Done" ++ print(string.join((str(i) for i in [chrom,chromStart,chromEnd,name,score,strand,thickStart,thickEnd,itemRgb,blockCount,blockSizes,blockStarts]),sep="\t"), file=FO) ++ print("Done", file=sys.stderr) + FO.close() + self.f.seek(0) + + if mergePE: + #creat another bed file. pair-end reads will be merged into single bed entry +- print >>sys.stderr, "Writing consoidated bed file ...", ++ print("Writing consoidated bed file ...", end=' ', file=sys.stderr) + bedfile = open(outfile,'r') + outfile_2 = outfile + ".consolidate.bed" + outfile_3 = outfile + '.filter' +@@ -292,11 +292,11 @@ class ParseSAM: + if(blocks[key] ==1): #single end, single hit + st = [i - txSt[key] for i in starts[key]] + st = string.join([str(i) for i in st],',') +- print >>FO, chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key,"\t","11\t",strand[key][0],"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sizes[key],','),"\t",st ++ print(chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key,"\t","11\t",strand[key][0],"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sizes[key],','),"\t",st, file=FO) + else: + st = [i - txSt[key] for i in starts[key]] #single end, spliced hit + st = string.join([str(i) for i in st],',') +- print >>FO, chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key,"\t","12\t",strand[key][0],"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sizes[key],','),"\t",st ++ print(chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key,"\t","12\t",strand[key][0],"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sizes[key],','),"\t",st, file=FO) + + elif(count[key]==2): #pair-end read + direction = string.join(strand[key],'/') +@@ -306,17 +306,17 @@ class ParseSAM: + #st=[string.atoi(i) for i in st] + if(len(chr[key])==1): #pair-end reads mapped to same chromosome + if blocks[key] ==2: #pair end, single hits +- print >>FO, chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key + "|strand=" + direction + "|chrom=same","\t","21\t",'.',"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sz,','),"\t",string.join([str(i) for i in st],',') ++ print(chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key + "|strand=" + direction + "|chrom=same","\t","21\t",'.',"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sz,','),"\t",string.join([str(i) for i in st],','), file=FO) + elif blocks[key] >2: # +- print >>FO, chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key + "|strand=" + direction + "|chrom=same","\t","22\t",'.',"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sz,','),"\t",string.join([str(i) for i in st],',') ++ print(chr[key].pop(),"\t",txSt[key],"\t",txEnd[key],"\t",key + "|strand=" + direction + "|chrom=same","\t","22\t",'.',"\t",txSt[key],"\t",txEnd[key],"\t","0,255,0\t",blocks[key],"\t",string.join(sz,','),"\t",string.join([str(i) for i in st],','), file=FO) + else: +- print >>FOF,key,"\t","pair-end mapped, but two ends mapped to different chromosome" ++ print(key,"\t","pair-end mapped, but two ends mapped to different chromosome", file=FOF) + elif(count[key] >2): #reads occur more than 2 times +- print >>FOF,key,"\t","occurs more than 2 times in sam file" ++ print(key,"\t","occurs more than 2 times in sam file", file=FOF) + continue + FO.close() + FOF.close() +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + def samTowig(self,outfile=None,log2scale=False,header=False,strandSpecific=False): +@@ -326,7 +326,7 @@ class ParseSAM: + if outfile is None: + outfile = self.fileName + ".wig" + FO=open(outfile,'w') +- print >>sys.stderr, "Writing wig file to\"",outfile,"\"..." ++ print("Writing wig file to\"",outfile,"\"...", file=sys.stderr) + + headline="track type=wiggle_0 name=" + outfile + " track_label description='' visibility=full color=255,0,0" + wig=collections.defaultdict(dict) +@@ -359,24 +359,24 @@ class ParseSAM: + + blocks = cigar.fetch_exon(chrom,txStart,field[5]) + for block in blocks: +- hits.extend(range(block[1]+1,block[2]+1)) ++ hits.extend(list(range(block[1]+1,block[2]+1))) + + if strandSpecific is not True: + for i in hits: +- if wig[chrom].has_key(i): ++ if i in wig[chrom]: + wig[chrom][i] +=1 + else: + wig[chrom][i]=1 + else: + if strand_rule[read_type + strand] == '-': + for i in hits: +- if Nwig[chrom].has_key(i): ++ if i in Nwig[chrom]: + Nwig[chrom][i] += 1 + else: + Nwig[chrom][i] = 1 + if strand_rule[read_type + strand] == '+': + for i in hits: +- if Pwig[chrom].has_key(i): ++ if i in Pwig[chrom]: + Pwig[chrom][i] +=1 + else: + Pwig[chrom][i]=1 +@@ -385,17 +385,17 @@ class ParseSAM: + + if strandSpecific is not True: + for chr in sorted(wig.keys()): +- print >>sys.stderr, "Writing ",chr, " ..." ++ print("Writing ",chr, " ...", file=sys.stderr) + FO.write('variableStep chrom='+chr+'\n') + for coord in sorted(wig[chr]): + if log2scale:FO.write("%d\t%5.3f\n" % (coord,math.log(wig[chr][coord],2))) + else:FO.write("%d\t%d\n" % (coord,wig[chr][coord])) + else: +- chroms=set(Pwig.keys() + Nwig.keys()) ++ chroms=set(list(Pwig.keys()) + list(Nwig.keys())) + for chr in sorted(chroms): +- print >>sys.stderr, "Writing ",chr, " ..." ++ print("Writing ",chr, " ...", file=sys.stderr) + FO.write('variableStep chrom='+chr+'\n') +- coords=sorted(set(Pwig[chr].keys() + Nwig[chr].keys())) ++ coords=sorted(set(list(Pwig[chr].keys()) + list(Nwig[chr].keys()))) + for coord in coords: + if ((coord in Pwig[chr]) and (coord not in Nwig[chr])): + FO.write("%d\t%d\n" % (coord,Pwig[chr][coord])) +@@ -418,7 +418,7 @@ class ParseSAM: + else: outfile = self.fileName + ".unmap.fa" + FO=open(outfile,'w') + unmapCount=0 +- print >>sys.stderr, "Writing unmapped reads to\"",outfile,"\"... ", ++ print("Writing unmapped reads to\"",outfile,"\"... ", end=' ', file=sys.stderr) + + for line in self.f: + hits=[] +@@ -438,7 +438,7 @@ class ParseSAM: + if fastq: FO.write('@' + seqID + '\n' + seq +'\n' + '+' +'\n' + qual+'\n') + else: FO.write('>' + seqID + '\n' + seq +'\n') + +- print >>sys.stderr, str(unmapCount) + " reads saved!\n" ++ print(str(unmapCount) + " reads saved!\n", file=sys.stderr) + FO.close() + self.f.seek(0) + +@@ -449,7 +449,7 @@ class ParseSAM: + outfile = self.fileName + ".PP.sam" + FO=open(outfile,'w') + PPcount=0 +- print >>sys.stderr, "Writing proper paired reads to\"",outfile,"\"... ", ++ print("Writing proper paired reads to\"",outfile,"\"... ", end=' ', file=sys.stderr) + for line in self.f: + hits=[] + if line[0] == '@':continue #skip head lines +@@ -460,7 +460,7 @@ class ParseSAM: + PPcount +=1 + FO.write(line) + FO.close() +- print >>sys.stderr, str(PPcount) + " reads were saved!\n", ++ print(str(PPcount) + " reads were saved!\n", end=' ', file=sys.stderr) + self.f.seek(0) + + def samNVC(self,outfile=None): +@@ -481,7 +481,7 @@ class ParseSAM: + c_count=[] + g_count=[] + t_count=[] +- print >>sys.stderr, "reading sam file ... " ++ print("reading sam file ... ", file=sys.stderr) + for line in self.f: + if line.startswith('@'):continue #skip head lines + if ParseSAM._reExpr2.match(line):continue #skip blank lines +@@ -492,44 +492,44 @@ class ParseSAM: + RNA_read = field[9].upper() + else: + RNA_read = field[9].upper().translate(transtab)[::-1] +- for i in xrange(len(RNA_read)): ++ for i in range(len(RNA_read)): + key = str(i) + RNA_read[i] + base_freq[key] += 1 + +- print >>sys.stderr, "generating data matrix ..." +- print >>FO, "Position\tA\tC\tG\tT\tN\tX" +- for i in xrange(len(RNA_read)): +- print >>FO, str(i) + '\t', +- print >>FO, str(base_freq[str(i) + "A"]) + '\t', ++ print("generating data matrix ...", file=sys.stderr) ++ print("Position\tA\tC\tG\tT\tN\tX", file=FO) ++ for i in range(len(RNA_read)): ++ print(str(i) + '\t', end=' ', file=FO) ++ print(str(base_freq[str(i) + "A"]) + '\t', end=' ', file=FO) + a_count.append(str(base_freq[str(i) + "A"])) +- print >>FO, str(base_freq[str(i) + "C"]) + '\t', ++ print(str(base_freq[str(i) + "C"]) + '\t', end=' ', file=FO) + c_count.append(str(base_freq[str(i) + "C"])) +- print >>FO, str(base_freq[str(i) + "G"]) + '\t', ++ print(str(base_freq[str(i) + "G"]) + '\t', end=' ', file=FO) + g_count.append(str(base_freq[str(i) + "G"])) +- print >>FO, str(base_freq[str(i) + "T"]) + '\t', ++ print(str(base_freq[str(i) + "T"]) + '\t', end=' ', file=FO) + t_count.append(str(base_freq[str(i) + "T"])) +- print >>FO, str(base_freq[str(i) + "N"]) + '\t', +- print >>FO, str(base_freq[str(i) + "X"]) + '\t' ++ print(str(base_freq[str(i) + "N"]) + '\t', end=' ', file=FO) ++ print(str(base_freq[str(i) + "X"]) + '\t', file=FO) + FO.close() + + #generating R scripts +- print >>sys.stderr, "generating R script ..." +- print >>RS, "position=c(" + ','.join([str(i) for i in xrange(len(RNA_read))]) + ')' +- print >>RS, "A_count=c(" + ','.join(a_count) + ')' +- print >>RS, "C_count=c(" + ','.join(c_count) + ')' +- print >>RS, "G_count=c(" + ','.join(g_count) + ')' +- print >>RS, "T_count=c(" + ','.join(t_count) + ')' +- print >>RS, "total= A_count + C_count + G_count + T_count" +- print >>RS, "ym=max(A_count/total,C_count/total,G_count/total,T_count/total) + 0.05" +- print >>RS, "yn=min(A_count/total,C_count/total,G_count/total,T_count/total)" ++ print("generating R script ...", file=sys.stderr) ++ print("position=c(" + ','.join([str(i) for i in range(len(RNA_read))]) + ')', file=RS) ++ print("A_count=c(" + ','.join(a_count) + ')', file=RS) ++ print("C_count=c(" + ','.join(c_count) + ')', file=RS) ++ print("G_count=c(" + ','.join(g_count) + ')', file=RS) ++ print("T_count=c(" + ','.join(t_count) + ')', file=RS) ++ print("total= A_count + C_count + G_count + T_count", file=RS) ++ print("ym=max(A_count/total,C_count/total,G_count/total,T_count/total) + 0.05", file=RS) ++ print("yn=min(A_count/total,C_count/total,G_count/total,T_count/total)", file=RS) + +- print >>RS, 'pdf("NVC_plot.pdf")' +- print >>RS, 'plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")' +- print >>RS, 'lines(position,T_count/total,type="o",pch=20,col="red")' +- print >>RS, 'lines(position,G_count/total,type="o",pch=20,col="blue")' +- print >>RS, 'lines(position,C_count/total,type="o",pch=20,col="cyan")' +- print >>RS, 'legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C"),col=c("dark green","red","blue","cyan"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan"))' +- print >>RS, "dev.off()" ++ print('pdf("NVC_plot.pdf")', file=RS) ++ print('plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")', file=RS) ++ print('lines(position,T_count/total,type="o",pch=20,col="red")', file=RS) ++ print('lines(position,G_count/total,type="o",pch=20,col="blue")', file=RS) ++ print('lines(position,C_count/total,type="o",pch=20,col="cyan")', file=RS) ++ print('legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C"),col=c("dark green","red","blue","cyan"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan"))', file=RS) ++ print("dev.off()", file=RS) + + RS.close() + #self.f.seek(0) +@@ -546,7 +546,7 @@ class ParseSAM: + RS=open(outfile2,'w') + + gc_hist=collections.defaultdict(int) #key is GC percent, value is count of reads +- print >>sys.stderr, "reading sam file ... " ++ print("reading sam file ... ", file=sys.stderr) + for line in self.f: + if line[0] == '@':continue #skip head lines + if ParseSAM._reExpr2.match(line):continue #skip blank lines +@@ -556,18 +556,18 @@ class ParseSAM: + #print gc_percent + gc_hist[gc_percent] += 1 + +- print >>sys.stderr, "writing GC content ..." ++ print("writing GC content ...", file=sys.stderr) + +- print >>FO, "GC%\tread_count" +- for i in gc_hist.keys(): +- print >>FO, i + '\t' + str(gc_hist[i]) ++ print("GC%\tread_count", file=FO) ++ for i in list(gc_hist.keys()): ++ print(i + '\t' + str(gc_hist[i]), file=FO) + +- print >>sys.stderr, "writing R script ..." +- print >>RS, "pdf('GC_content.pdf')" +- print >>RS, 'gc=rep(c(' + ','.join([i for i in gc_hist.keys()]) + '),' + 'times=c(' + ','.join([str(i) for i in gc_hist.values()]) + '))' +- print >>RS, 'hist(gc,probability=T,breaks=%d,xlab="GC content (%%)",ylab="Density of Reads",border="blue",main="")' % 100 ++ print("writing R script ...", file=sys.stderr) ++ print("pdf('GC_content.pdf')", file=RS) ++ print('gc=rep(c(' + ','.join([i for i in list(gc_hist.keys())]) + '),' + 'times=c(' + ','.join([str(i) for i in list(gc_hist.values())]) + '))', file=RS) ++ print('hist(gc,probability=T,breaks=%d,xlab="GC content (%%)",ylab="Density of Reads",border="blue",main="")' % 100, file=RS) + #print >>RS, "lines(density(gc),col='red')" +- print >>RS ,"dev.off()" ++ print("dev.off()", file=RS) + #self.f.seek(0) + + def samDupRate(self,outfile=None,up_bound=500): +@@ -589,7 +589,7 @@ class ParseSAM: + + seqDup_count=collections.defaultdict(int) + posDup_count=collections.defaultdict(int) +- print >>sys.stderr, "reading sam file ... " ++ print("reading sam file ... ", file=sys.stderr) + for line in self.f: + if line[0] == '@':continue #skip head lines + if ParseSAM._reExpr2.match(line):continue #skip blank lines +@@ -616,37 +616,37 @@ class ParseSAM: + coord = chrom + ":" + str(chromStart) + "-" + str(chromEnd) + ":" + blockSizes + ":" + blockStarts + posDup[coord] +=1 + +- print >>sys.stderr, "report duplicte rate based on sequence ..." +- print >>SEQ, "Occurrence\tUniqReadNumber" +- for i in seqDup.values(): #key is occurence, value is uniq reads number (based on seq) ++ print("report duplicte rate based on sequence ...", file=sys.stderr) ++ print("Occurrence\tUniqReadNumber", file=SEQ) ++ for i in list(seqDup.values()): #key is occurence, value is uniq reads number (based on seq) + seqDup_count[i] +=1 +- for k in sorted(seqDup_count.iterkeys()): +- print >>SEQ, str(k) +'\t'+ str(seqDup_count[k]) ++ for k in sorted(seqDup_count.keys()): ++ print(str(k) +'\t'+ str(seqDup_count[k]), file=SEQ) + SEQ.close() + +- print >>sys.stderr, "report duplicte rate based on mapping ..." +- print >>POS, "Occurrence\tUniqReadNumber" +- for i in posDup.values(): #key is occurence, value is uniq reads number (based on coord) ++ print("report duplicte rate based on mapping ...", file=sys.stderr) ++ print("Occurrence\tUniqReadNumber", file=POS) ++ for i in list(posDup.values()): #key is occurence, value is uniq reads number (based on coord) + posDup_count[i] +=1 +- for k in sorted(posDup_count.iterkeys()): +- print >>POS, str(k) +'\t'+ str(posDup_count[k]) ++ for k in sorted(posDup_count.keys()): ++ print(str(k) +'\t'+ str(posDup_count[k]), file=POS) + POS.close() + + +- print >>sys.stderr, "generate R script ..." +- print >>RS, "pdf('duplicateRead.pdf')" +- print >>RS, "par(mar=c(5,4,4,5),las=0)" +- print >>RS, "seq_occ=c(" + ','.join([str(i) for i in sorted(seqDup_count.iterkeys()) ]) + ')' +- print >>RS, "seq_uniqRead=c(" + ','.join([str(seqDup_count[i]) for i in sorted(seqDup_count.iterkeys()) ]) + ')' +- print >>RS, "pos_occ=c(" + ','.join([str(i) for i in sorted(posDup_count.iterkeys()) ]) + ')' +- print >>RS, "pos_uniqRead=c(" + ','.join([str(posDup_count[i]) for i in sorted(posDup_count.iterkeys()) ]) + ')' +- print >>RS, "plot(pos_occ,log10(pos_uniqRead),ylab='Number of Reads (log10)',xlab='Frequency',pch=4,cex=0.8,col='blue',xlim=c(1,%d),yaxt='n')" % up_bound +- print >>RS, "points(seq_occ,log10(seq_uniqRead),pch=20,cex=0.8,col='red')" +- print >>RS, 'ym=floor(max(log10(pos_uniqRead)))' +- print >>RS, "legend(%d,ym,legend=c('Sequence-base','Mapping-base'),col=c('red','blue'),pch=c(4,20))" % max(up_bound-200,1) +- print >>RS, 'axis(side=2,at=0:ym,labels=0:ym)' +- print >>RS, 'axis(side=4,at=c(log10(pos_uniqRead[1]),log10(pos_uniqRead[2]),log10(pos_uniqRead[3]),log10(pos_uniqRead[4])), labels=c(round(pos_uniqRead[1]*100/sum(pos_uniqRead)),round(pos_uniqRead[2]*100/sum(pos_uniqRead)),round(pos_uniqRead[3]*100/sum(pos_uniqRead)),round(pos_uniqRead[4]*100/sum(pos_uniqRead))))' +- print >>RS, 'mtext(4, text = "Reads %", line = 2)' ++ print("generate R script ...", file=sys.stderr) ++ print("pdf('duplicateRead.pdf')", file=RS) ++ print("par(mar=c(5,4,4,5),las=0)", file=RS) ++ print("seq_occ=c(" + ','.join([str(i) for i in sorted(seqDup_count.keys()) ]) + ')', file=RS) ++ print("seq_uniqRead=c(" + ','.join([str(seqDup_count[i]) for i in sorted(seqDup_count.keys()) ]) + ')', file=RS) ++ print("pos_occ=c(" + ','.join([str(i) for i in sorted(posDup_count.keys()) ]) + ')', file=RS) ++ print("pos_uniqRead=c(" + ','.join([str(posDup_count[i]) for i in sorted(posDup_count.keys()) ]) + ')', file=RS) ++ print("plot(pos_occ,log10(pos_uniqRead),ylab='Number of Reads (log10)',xlab='Frequency',pch=4,cex=0.8,col='blue',xlim=c(1,%d),yaxt='n')" % up_bound, file=RS) ++ print("points(seq_occ,log10(seq_uniqRead),pch=20,cex=0.8,col='red')", file=RS) ++ print('ym=floor(max(log10(pos_uniqRead)))', file=RS) ++ print("legend(%d,ym,legend=c('Sequence-base','Mapping-base'),col=c('red','blue'),pch=c(4,20))" % max(up_bound-200,1), file=RS) ++ print('axis(side=2,at=0:ym,labels=0:ym)', file=RS) ++ print('axis(side=4,at=c(log10(pos_uniqRead[1]),log10(pos_uniqRead[2]),log10(pos_uniqRead[3]),log10(pos_uniqRead[4])), labels=c(round(pos_uniqRead[1]*100/sum(pos_uniqRead)),round(pos_uniqRead[2]*100/sum(pos_uniqRead)),round(pos_uniqRead[3]*100/sum(pos_uniqRead)),round(pos_uniqRead[4]*100/sum(pos_uniqRead))))', file=RS) ++ print('mtext(4, text = "Reads %", line = 2)', file=RS) + #self.f.seek(0) + + def getUniqMapRead(self,outfile=None): +@@ -655,7 +655,7 @@ class ParseSAM: + outfile = self.fileName + ".uniq.sam" + FO=open(outfile,'w') + Uniqcount=0 +- print >>sys.stderr, "Writing uniquely mapped reads to\"",outfile,"\"... ", ++ print("Writing uniquely mapped reads to\"",outfile,"\"... ", end=' ', file=sys.stderr) + for line in self.f: + hits=[] + if line[0] == '@':continue #skip head lines +@@ -667,11 +667,11 @@ class ParseSAM: + #else: + #print >>sys.stderr,line, + if (ParseSAM._uniqueHit_pat.search(line)): +- print >>sys.stderr,line, ++ print(line, end=' ', file=sys.stderr) + Uniqcount +=1 + FO.write(line) + FO.close() +- print >>sys.stderr, str(Uniqcount) + " reads were saved!\n", ++ print(str(Uniqcount) + " reads were saved!\n", end=' ', file=sys.stderr) + self.f.seek(0) + + def getWrongStrand(self,outfile=None): +@@ -680,7 +680,7 @@ class ParseSAM: + outfile = self.fileName + ".wrongStrand.sam" + FO=open(outfile,'w') + wrongStrand=0 +- print >>sys.stderr, "Writing incorrectly stranded reads to\"",outfile,"\"... ", ++ print("Writing incorrectly stranded reads to\"",outfile,"\"... ", end=' ', file=sys.stderr) + for line in self.f: + hits=[] + if line.startswith('@'):continue #skip head lines +@@ -701,7 +701,7 @@ class ParseSAM: + wrongStrand+=1 + + FO.close() +- print >>sys.stderr, str(wrongStrand) + " reads were saved!\n", ++ print(str(wrongStrand) + " reads were saved!\n", end=' ', file=sys.stderr) + self.f.seek(0) + + def filterSpliceRead(self,outfile=None,min_overhang=8,min_gap=50,max_gap=1000000): +@@ -714,7 +714,7 @@ class ParseSAM: + outfile = self.fileName + ".SR.sam" + #outfile2 = self.fileName + ".SR.filter.sam" + splice_sites=collections.defaultdict(set) +- print >>sys.stderr, "\tDetermine splice sites with proper overhang, intron size ... ", ++ print("\tDetermine splice sites with proper overhang, intron size ... ", end=' ', file=sys.stderr) + for line in self.f: + if line[0] == '@':continue #skip head lines + if ParseSAM._reExpr2.match(line):continue #skip blank lines +@@ -741,12 +741,12 @@ class ParseSAM: + if (comb[2] >= min_overhang): + splice_sites[chrom].add(map_st + comb[0] + comb[1]) + self.f.seek(0) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + FO=open(outfile,'w') + #FO2=open(outfile2,'w') +- print >>sys.stderr, "\tExtracting splicing reads ... ", ++ print("\tExtracting splicing reads ... ", end=' ', file=sys.stderr) + total_SR =0 + extract_SR =0 + total_read =0 +@@ -778,10 +778,10 @@ class ParseSAM: + else: + #FO2.write(line) + continue +- print >>sys.stderr, "Done" +- print >>sys.stderr, "\tTotal mapped Read: " + str(total_read) +- print >>sys.stderr, "\tTotal Splicing Read: " + str(total_SR) +- print >>sys.stderr, "\Usable Splicing Read: " + str(extract_SR) ++ print("Done", file=sys.stderr) ++ print("\tTotal mapped Read: " + str(total_read), file=sys.stderr) ++ print("\tTotal Splicing Read: " + str(total_SR), file=sys.stderr) ++ print("\\Usable Splicing Read: " + str(extract_SR), file=sys.stderr) + FO.close() + #FO2.close() + self.f.seek(0) +@@ -792,7 +792,7 @@ class ParseSAM: + if outfile is None: + outfile = self.fileName + ".SR.sam" + FO=open(outfile,'w') +- print >>sys.stderr, "\tExtract splicing reads without any filter ...", ++ print("\tExtract splicing reads without any filter ...", end=' ', file=sys.stderr) + for line in self.f: + if line[0] == '@':continue #skip head lines + if ParseSAM._reExpr2.match(line):continue #skip blank lines +@@ -803,7 +803,7 @@ class ParseSAM: + if (len(comb)>=3): + FO.write(line) + +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + self.f.seek(0) + FO.close() + +@@ -812,7 +812,7 @@ class ParseSAM: + The original SAM file must be sorted before hand. if not, using linux command like "sort -k3,3 -k4,4n myfile.sam >myfile.sorted.sam" ''' + if outfile is None: + outfile = self.fileName + ".collapsed.sam" +- print >>sys.stderr, "Writing collapsed SAM file to\"",outfile,"\"... " ++ print("Writing collapsed SAM file to\"",outfile,"\"... ", file=sys.stderr) + FO=open(outfile,'w') + flag="" + for line in self.f: +@@ -840,7 +840,7 @@ class ParseSAM: + else: + outfile = outfile + ".qual.plot.r" + FO=open(outfile,'w') +- print >>sys.stderr, "\tcalculating quality score ... " ++ print("\tcalculating quality score ... ", file=sys.stderr) + qual_min={} + qual_max={} + qual_sum={} +@@ -875,16 +875,16 @@ class ParseSAM: + max_qualities =[str(qual_max[i]) for i in range(0,read_len)] + avg_qualities = [str(qual_sum[i]/total_read) for i in range(0,read_len)] + nt_pos = [str(i) for i in range(0,read_len)] +- print >>FO, "nt_pos=c(" + ','.join(nt_pos) + ')' +- print >>FO, "max_qual=c(" + ','.join(max_qualities) + ')' +- print >>FO, "min_qual=c(" + ','.join(min_qualities) + ')' +- print >>FO, "avg_qual=c(" + ','.join(avg_qualities) + ')' +- print >>FO, "pdf('phred_qual.pdf')" +- print >>FO, "plot(nt_pos,avg_qual, xlab=\"Nucleotide Position (5'->3')\", ylab='Phred Quality',ylim=c(0,97),lwd=2,type='s')" +- print >>FO, 'lines(nt_pos,max_qual,type="s",lwd=2,col="red")' +- print >>FO, 'lines(nt_pos,min_qual,type="s",lwd=2,col="blue")' +- print >>FO, 'legend(0,100,legend=c("Max","Average","Min"),col=c("red","black","blue"),lwd=2)' +- print >>FO, 'dev.off()' ++ print("nt_pos=c(" + ','.join(nt_pos) + ')', file=FO) ++ print("max_qual=c(" + ','.join(max_qualities) + ')', file=FO) ++ print("min_qual=c(" + ','.join(min_qualities) + ')', file=FO) ++ print("avg_qual=c(" + ','.join(avg_qualities) + ')', file=FO) ++ print("pdf('phred_qual.pdf')", file=FO) ++ print("plot(nt_pos,avg_qual, xlab=\"Nucleotide Position (5'->3')\", ylab='Phred Quality',ylim=c(0,97),lwd=2,type='s')", file=FO) ++ print('lines(nt_pos,max_qual,type="s",lwd=2,col="red")', file=FO) ++ print('lines(nt_pos,min_qual,type="s",lwd=2,col="blue")', file=FO) ++ print('legend(0,100,legend=c("Max","Average","Min"),col=c("red","black","blue"),lwd=2)', file=FO) ++ print('dev.off()', file=FO) + #for i in range(0,read_len): + # print >>sys.stderr, str(i) + '\t' + str(qual_max[i]) + '\t' + str(qual_min[i]) + '\t' + str(qual_sum[i]/total_read) + #self.f.seek(0) +@@ -918,7 +918,7 @@ class ParseSAM: + scores[chrom][pos] =1 + else: + scores[chrom][pos] +=1 +- if lines % 10000 == 0: print >>sys.stderr, "%i lines loaded \r" % lines ++ if lines % 10000 == 0: print("%i lines loaded \r" % lines, file=sys.stderr) + return scores + self.f.seek(0) + +@@ -943,7 +943,7 @@ class QCSAM: + The 5th column is number of reads fallen into the region defined by the first 3 columns''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + exon_count = self.fileName + "_exon.count.bed" +@@ -968,7 +968,7 @@ class QCSAM: + splicedReads=0 + + #read SAM +- print >>sys.stderr, "reading "+ self.fileName + '...', ++ print("reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -990,10 +990,10 @@ class QCSAM: + ranges[chrom].add_interval( Interval( mid, mid ) ) + + self.f.seek(0) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #read refbed file +- print >>sys.stderr, "Assign reads to "+ refbed + '...', ++ print("Assign reads to "+ refbed + '...', end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith('#'):continue +@@ -1007,14 +1007,14 @@ class QCSAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + intron_starts = exon_ends[:-1] + intron_ends=exon_starts[1:] + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + # assign reads to intron +@@ -1050,28 +1050,28 @@ class QCSAM: + EXON_OUT.write(chrom + "\t" + str(st) + "\t" + str(end) + "\t" + geneName + "_exon_" + str(exonNum) + "\t" + str(hits) + "\t" + strand + '\n') + exonNum += 1 + intergenicReads=totalReads-exonReads-intronReads-splicedReads +- print >>sys.stderr, "Done." + '\n' +- print >>sys.stderr, "Total reads:\t" + str(totalReads) +- print >>sys.stderr, "Exonic reads:\t" + str(exonReads) +- print >>sys.stderr, "Intronic reads:\t" + str(intronReads) +- print >>sys.stderr, "Splicing reads:\t" + str(splicedReads) +- print >>sys.stderr, "Intergenic reads:\t" + str(intergenicReads) ++ print("Done." + '\n', file=sys.stderr) ++ print("Total reads:\t" + str(totalReads), file=sys.stderr) ++ print("Exonic reads:\t" + str(exonReads), file=sys.stderr) ++ print("Intronic reads:\t" + str(intronReads), file=sys.stderr) ++ print("Splicing reads:\t" + str(splicedReads), file=sys.stderr) ++ print("Intergenic reads:\t" + str(intergenicReads), file=sys.stderr) + +- print >>sys.stderr,"writing R script ...", ++ print("writing R script ...", end=' ', file=sys.stderr) + totalReads=float(totalReads) +- print >>R_OUT, "pdf('%s')" % rpdf +- print >>R_OUT, "dat=c(%d,%d,%d,%d)" % (exonReads,splicedReads,intronReads,intergenicReads) +- print >>R_OUT, "lb=c('exon(%.2f)','junction(%.2f)','intron(%.2f)','intergenic(%.2f)')" % (exonReads/totalReads,splicedReads/totalReads,intronReads/totalReads,intergenicReads/totalReads) +- print >>R_OUT, "pie(dat,labels=lb,col=rainbow(4),clockwise=TRUE,main='Total reads = %d')" % int(totalReads) +- print >>R_OUT, "dev.off()" +- print >>sys.stderr, "Done." ++ print("pdf('%s')" % rpdf, file=R_OUT) ++ print("dat=c(%d,%d,%d,%d)" % (exonReads,splicedReads,intronReads,intergenicReads), file=R_OUT) ++ print("lb=c('exon(%.2f)','junction(%.2f)','intron(%.2f)','intergenic(%.2f)')" % (exonReads/totalReads,splicedReads/totalReads,intronReads/totalReads,intergenicReads/totalReads), file=R_OUT) ++ print("pie(dat,labels=lb,col=rainbow(4),clockwise=TRUE,main='Total reads = %d')" % int(totalReads), file=R_OUT) ++ print("dev.off()", file=R_OUT) ++ print("Done.", file=sys.stderr) + + + def coverageGeneBody(self,refbed,outfile=None): + '''Calculate reads coverage over gene body, from 5'to 3'. each gene will be equally divied + into 100 regsions''' + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + outfile1 = self.fileName + ".geneBodyCoverage_plot.r" +@@ -1088,7 +1088,7 @@ class QCSAM: + rpkm={} + + #read SAM +- print >>sys.stderr, "reading "+ self.fileName + '...', ++ print("reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1114,9 +1114,9 @@ class QCSAM: + ranges[chrom] = Intersecter() + else: + ranges[chrom].add_interval( Interval( st, st+size ) ) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "calculating coverage over gene body ..." ++ print("calculating coverage over gene body ...", file=sys.stderr) + coverage=collections.defaultdict(int) + flag=0 + for line in open(refbed,'r'): +@@ -1130,19 +1130,19 @@ class QCSAM: + geneName = fields[3] + strand = fields[5] + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + gene_all_base=[] + percentile_base=[] + mRNA_len =0 + flag=0 + for st,end in zip(exon_starts,exon_ends): +- gene_all_base.extend(range(st+1,end+1)) #0-based coordinates on genome ++ gene_all_base.extend(list(range(st+1,end+1))) #0-based coordinates on genome + mRNA_len = len(gene_all_base) + if mRNA_len <100: + flag=1 +@@ -1159,18 +1159,18 @@ class QCSAM: + coverage[i] += len(ranges[chrom].find(percentile_base[i], percentile_base[i]+1)) + x_coord=[] + y_coord=[] +- print >>OUT2, "Total reads: " + str(totalReads) +- print >>OUT2, "Fragment number: " + str(fragment_num) +- print >>OUT2, "percentile\tcount" ++ print("Total reads: " + str(totalReads), file=OUT2) ++ print("Fragment number: " + str(fragment_num), file=OUT2) ++ print("percentile\tcount", file=OUT2) + for i in coverage: + x_coord.append(str(i)) + y_coord.append(str(coverage[i])) +- print >>OUT2, str(i) + '\t' + str(coverage[i]) +- print >>OUT1, "pdf('geneBody_coverage.pdf')" +- print >>OUT1, "x=0:100" +- print >>OUT1, "y=c(" + ','.join(y_coord) + ')' +- print >>OUT1, "plot(x,y,xlab=\"percentile of gene body (5'->3')\",ylab='read number',type='s')" +- print >>OUT1, "dev.off()" ++ print(str(i) + '\t' + str(coverage[i]), file=OUT2) ++ print("pdf('geneBody_coverage.pdf')", file=OUT1) ++ print("x=0:100", file=OUT1) ++ print("y=c(" + ','.join(y_coord) + ')', file=OUT1) ++ print("plot(x,y,xlab=\"percentile of gene body (5'->3')\",ylab='read number',type='s')", file=OUT1) ++ print("dev.off()", file=OUT1) + + def calculateRPKM(self,refbed,outfile=None): + '''calculate RPKM values for each gene in refbed. Only uniquely aligned reads are used. +@@ -1178,7 +1178,7 @@ class QCSAM: + exon per Million mapped reads) for each exon, intron and mRNA''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + rpkm_file = self.fileName + ".rpkm.xls" +@@ -1194,7 +1194,7 @@ class QCSAM: + rpkm={} + + #read SAM +- print >>sys.stderr, "reading "+ self.fileName + '...', ++ print("reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1228,17 +1228,17 @@ class QCSAM: + ranges[chrom].add_interval( Interval( mid, mid ) ) + + self.f.seek(0) +- print >>sys.stderr, "Done" +- print >>RPKM_OUT, "Total mapped reads (TR): " + str(totalReads) +- print >>RPKM_OUT, "Multiple mapped reads (MR): " + str(multiMapReads) +- print >>RPKM_OUT, "Uniquely mapped reads (UR): " + str(totalReads - multiMapReads) +- print >>RPKM_OUT, "Spliced mapped reads (SR): " + str(sR) +- print >>RPKM_OUT, "Corrected uniquely mapped reads (cUR): " + str(cUR) ++ print("Done", file=sys.stderr) ++ print("Total mapped reads (TR): " + str(totalReads), file=RPKM_OUT) ++ print("Multiple mapped reads (MR): " + str(multiMapReads), file=RPKM_OUT) ++ print("Uniquely mapped reads (UR): " + str(totalReads - multiMapReads), file=RPKM_OUT) ++ print("Spliced mapped reads (SR): " + str(sR), file=RPKM_OUT) ++ print("Corrected uniquely mapped reads (cUR): " + str(cUR), file=RPKM_OUT) + if totalReads ==0: + sys.exit(1) + + #read refbed file +- print >>sys.stderr, "Assign reads to "+ refbed + '...', ++ print("Assign reads to "+ refbed + '...', end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith('#'):continue +@@ -1252,16 +1252,16 @@ class QCSAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + intron_starts = exon_ends[:-1] + intron_ends=exon_starts[1:] + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + # assign reads to intron +@@ -1309,7 +1309,7 @@ class QCSAM: + except: + RPKM_OUT.write(chrom.lower() + "\t" + str(tx_start) + "\t" + str(tx_end) + "\t" + geneName + "_mRNA" + "\t" + str(0) + "\t" + strand + '\t' + str(0) +'\n') + rpkm[key] = 0 +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + return rpkm + self.f.seek(0) + +@@ -1320,7 +1320,7 @@ class QCSAM: + NOTE: intronic reads are not counted as part of total reads''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + rpkm_file = self.fileName + ".rpkm.xls" +@@ -1338,7 +1338,7 @@ class QCSAM: + rpkm={} + + #read gene model file, the purpose is to remove intronic reads +- print >>sys.stderr, "Reading reference gene model "+ refbed + '...' ++ print("Reading reference gene model "+ refbed + '...', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -1351,12 +1351,12 @@ class QCSAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + for st,end in zip(exon_starts,exon_ends): +@@ -1366,7 +1366,7 @@ class QCSAM: + exon_ranges[chrom].add_interval( Interval( st, end ) ) + + #read SAM +- print >>sys.stderr, "reading "+ self.fileName + '...', ++ print("reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1401,22 +1401,22 @@ class QCSAM: + ranges[chrom] = Intersecter() + else: + ranges[chrom].add_interval( Interval( mid, mid ) ) +- else: #if this framgnet is intronic, skip it. ++ else: #if this framgnet is intronic, skip it. + #intronic +=1 +- continue ++ continue + self.f.seek(0) +- print >>sys.stderr, "Done" +- print >>RPKM_OUT, "Total mapped reads (TR): " + str(totalReads) +- print >>RPKM_OUT, "Multiple mapped reads (MR): " + str(multiMapReads) +- print >>RPKM_OUT, "Uniquely mapped reads (UR): " + str(totalReads - multiMapReads) +- print >>RPKM_OUT, "Spliced mapped reads (SR): " + str(sR) +- print >>RPKM_OUT, "Corrected uniquely mapped reads (cUR, non-intronic fragments): " + str(cUR) ++ print("Done", file=sys.stderr) ++ print("Total mapped reads (TR): " + str(totalReads), file=RPKM_OUT) ++ print("Multiple mapped reads (MR): " + str(multiMapReads), file=RPKM_OUT) ++ print("Uniquely mapped reads (UR): " + str(totalReads - multiMapReads), file=RPKM_OUT) ++ print("Spliced mapped reads (SR): " + str(sR), file=RPKM_OUT) ++ print("Corrected uniquely mapped reads (cUR, non-intronic fragments): " + str(cUR), file=RPKM_OUT) + #print >>RPKM_OUT, "Intronic Fragments (IF): " + str(intronic) + if totalReads ==0: + sys.exit(1) + + #read refbed file +- print >>sys.stderr, "Assign reads to "+ refbed + '...', ++ print("Assign reads to "+ refbed + '...', end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith('#'):continue +@@ -1430,16 +1430,16 @@ class QCSAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + intron_starts = exon_ends[:-1] + intron_ends=exon_starts[1:] + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + # assign reads to intron +@@ -1487,7 +1487,7 @@ class QCSAM: + except: + RPKM_OUT.write(chrom.lower() + "\t" + str(tx_start) + "\t" + str(tx_end) + "\t" + geneName + "_mRNA" + "\t" + str(0) + "\t" + strand + '\t' + str(0) +'\n') + rpkm[key] = 0 +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + return rpkm + self.f.seek(0) + +@@ -1499,7 +1499,7 @@ class QCSAM: + unknownReads=0 + ranges={} + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + + if outfile is None: +@@ -1508,7 +1508,7 @@ class QCSAM: + out_file = outfile + ".unknownReads.SAM" + OUT=open(out_file,'w') + +- print >>sys.stderr, "Reading reference gene model "+ refbed + '...' ++ print("Reading reference gene model "+ refbed + '...', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -1521,12 +1521,12 @@ class QCSAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + for st,end in zip(exon_starts,exon_ends): +@@ -1535,7 +1535,7 @@ class QCSAM: + else: + ranges[chrom].add_interval( Interval( st, end ) ) + +- print >>sys.stderr, "Processing SAM file "+ self.fileName + '...' ++ print("Processing SAM file "+ self.fileName + '...', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1564,8 +1564,8 @@ class QCSAM: + OUT.write(line) + unknownReads +=1 + OUT.close() +- print >>sys.stderr, "Total reads mapped to genome: " + str(totalReads) +- print >>sys.stderr, "Total reads not overlapped with any exon: " + str(unknownReads) ++ print("Total reads mapped to genome: " + str(totalReads), file=sys.stderr) ++ print("Total reads not overlapped with any exon: " + str(unknownReads), file=sys.stderr) + self.f.seek(0) + + def genomicFragSize(self,outfile=None,low_bound=0,up_bound=1000,step=10): +@@ -1589,16 +1589,16 @@ class QCSAM: + ranges={} + ranges[chrom]=Intersecter() + +- window_left_bound = range(low_bound,up_bound,step) +- frag_size=0 ++ window_left_bound = list(range(low_bound,up_bound,step)) ++ frag_size=0 + +- pair_num=0.0 +- ultra_low=0.0 +- ultra_high=0.0 +- size=[] +- counts=[] +- count=0 +- print >>sys.stderr, "Reading SAM file "+ self.fileName + ' ... ', ++ pair_num=0.0 ++ ultra_low=0.0 ++ ultra_high=0.0 ++ size=[] ++ counts=[] ++ count=0 ++ print("Reading SAM file "+ self.fileName + ' ... ', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1606,7 +1606,7 @@ class QCSAM: + # continue + flagCode=string.atoi(fields[1]) + if (flagCode & 0x0001) ==0: +- print >>sys.stderr,"NOT pair-end sequencing" ++ print("NOT pair-end sequencing", file=sys.stderr) + sys.exit(1) + if (flagCode & 0x0004) != 0: continue #skip unmap reads + if not ParseSAM._uniqueHit_pat.search(line): #skip multiple mapped reads +@@ -1632,29 +1632,29 @@ class QCSAM: + ultra_high +=1 + continue + ranges[chrom].add_interval( Interval( frag_size-1, frag_size ) ) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + if pair_num==0: +- print >>sys.stderr, "Cannot find paired reads" ++ print("Cannot find paired reads", file=sys.stderr) + sys.exit(0) +- print >>FQ, "Total paired read " + str(pair_num) +- print >>FQ, "<=" + str(low_bound) + "\t"+ str(ultra_low) ++ print("Total paired read " + str(pair_num), file=FQ) ++ print("<=" + str(low_bound) + "\t"+ str(ultra_low), file=FQ) + for st in window_left_bound: + size.append(str(st + step/2)) + count = str(len(ranges[chrom].find(st,st + step))) + counts.append(count) +- print >>FQ, str(st) + '\t' + str(st+step) +'\t' + count +- print >>FQ, ">" + str(up_bound) + "\t"+ str(ultra_high) ++ print(str(st) + '\t' + str(st+step) +'\t' + count, file=FQ) ++ print(">" + str(up_bound) + "\t"+ str(ultra_high), file=FQ) + +- print >>RS, "pdf('gFragSize.pdf')" +- print >>RS, "par(mfrow=c(2,1),cex.main=0.8,cex.lab=0.8,cex.axis=0.8,mar=c(4,4,4,1))" +- print >>RS, 'pie(c(%d,%d,%d),col=rainbow(3),cex=0.5,radius=1,main="Total %d fragments",labels=c("fraSize <= %d\\n(%4.2f%%)","fragSize > %d\\n(%4.2f%%)","%d < fragSize <= %d\\n(%4.2f%%)"), density=rep(80,80,80),angle=c(90,140,170))' % (ultra_low, ultra_high, pair_num -ultra_low -ultra_high, pair_num, low_bound, ultra_low*100/pair_num, up_bound, ultra_high*100/pair_num, low_bound, up_bound, 100-ultra_low*100/pair_num - ultra_high*100/pair_num) +- print >>RS, 'fragsize=rep(c(' + ','.join(size) + '),' + 'times=c(' + ','.join(counts) + '))' +- print >>RS, 'frag_sd = round(sd(fragsize))' +- print >>RS, 'frag_mean = round(mean(fragsize))' +- print >>RS, 'hist(fragsize,probability=T,breaks=%d,xlab="Fragment size (bp)",main=paste(c("Mean=",frag_mean,";","SD=",frag_sd),collapse=""),border="blue")' % len(window_left_bound) +- print >>RS, "lines(density(fragsize,bw=%d),col='red')" % (2*step) +- print >>RS ,"dev.off()" ++ print("pdf('gFragSize.pdf')", file=RS) ++ print("par(mfrow=c(2,1),cex.main=0.8,cex.lab=0.8,cex.axis=0.8,mar=c(4,4,4,1))", file=RS) ++ print('pie(c(%d,%d,%d),col=rainbow(3),cex=0.5,radius=1,main="Total %d fragments",labels=c("fraSize <= %d\\n(%4.2f%%)","fragSize > %d\\n(%4.2f%%)","%d < fragSize <= %d\\n(%4.2f%%)"), density=rep(80,80,80),angle=c(90,140,170))' % (ultra_low, ultra_high, pair_num -ultra_low -ultra_high, pair_num, low_bound, ultra_low*100/pair_num, up_bound, ultra_high*100/pair_num, low_bound, up_bound, 100-ultra_low*100/pair_num - ultra_high*100/pair_num), file=RS) ++ print('fragsize=rep(c(' + ','.join(size) + '),' + 'times=c(' + ','.join(counts) + '))', file=RS) ++ print('frag_sd = round(sd(fragsize))', file=RS) ++ print('frag_mean = round(mean(fragsize))', file=RS) ++ print('hist(fragsize,probability=T,breaks=%d,xlab="Fragment size (bp)",main=paste(c("Mean=",frag_mean,";","SD=",frag_sd),collapse=""),border="blue")' % len(window_left_bound), file=RS) ++ print("lines(density(fragsize,bw=%d),col='red')" % (2*step), file=RS) ++ print("dev.off()", file=RS) + FO.close() + FQ.close() + RS.close() +@@ -1665,7 +1665,7 @@ class QCSAM: + '''for each gene, check if its RPKM (epxresion level) has already been saturated or not''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + rpkm_file = self.fileName + ".eRPKM.xls" +@@ -1685,7 +1685,7 @@ class QCSAM: + #read SAM + my_pat = re.compile(r'NH:i:(\d+)\b') + NH_tag=0 +- print >>sys.stderr, "Reading "+ self.fileName + '...', ++ print("Reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1698,7 +1698,7 @@ class QCSAM: + elif len(hitNum) ==1: + if int(hitNum[0])>1: continue #skip multiple mapped reads + else: +- print >>sys.stderr, "More than 1 NH tag found within a single line. Incorrect SAM format!" ++ print("More than 1 NH tag found within a single line. Incorrect SAM format!", file=sys.stderr) + sys.exit(1) + + chrom = fields[2].upper() +@@ -1719,12 +1719,12 @@ class QCSAM: + block_list.append(chrom + ":" + str(mid)) + + if NH_tag==1: +- print >>sys.stderr, "Warn: NO NH tag found. Cannot determine uniqueness of alignment. All alignments will be used" +- print >>sys.stderr, "Done" ++ print("Warn: NO NH tag found. Cannot determine uniqueness of alignment. All alignments will be used", file=sys.stderr) ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "shuffling alignments ...", ++ print("shuffling alignments ...", end=' ', file=sys.stderr) + random.shuffle(block_list) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + ranges={} +@@ -1734,7 +1734,7 @@ class QCSAM: + rawCount_table=collections.defaultdict(list) + RPKM_head=['chr','start','end','name','score','strand'] + +- tmp=range(sample_start,sample_end,sample_step) ++ tmp=list(range(sample_start,sample_end,sample_step)) + tmp.append(100) + #=========================sampling uniquely mapped reads from population + for pertl in tmp: #[5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95,100] +@@ -1744,7 +1744,7 @@ class QCSAM: + sample_size += index_end -index_st + + RPKM_head.append(str(pertl) + '%') +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(sample_size) + ") fragments ...", ++ print("sampling " + str(pertl) +"% (" + str(sample_size) + ") fragments ...", end=' ', file=sys.stderr) + for i in range(index_st, index_end): + (chr,coord) = block_list[i].split(':') + if chr not in ranges: +@@ -1763,14 +1763,14 @@ class QCSAM: + tx_end = int( fields[2] ) + geneName = fields[3] + strand = fields[5].replace(" ","_") +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, file=sys.stderr) + continue + mRNA_count=0 #we need to initializ it to 0 for each gene + mRNA_len=sum(exon_sizes) +@@ -1778,24 +1778,24 @@ class QCSAM: + if chrom in ranges: + mRNA_count += len(ranges[chrom].find(st,end)) + if mRNA_len ==0: +- print >>sys.stderr, geneName + " has 0 nucleotides. Exit!" ++ print(geneName + " has 0 nucleotides. Exit!", file=sys.stderr) + sys.exit(1) + if sample_size == 0: +- print >>sys.stderr, "Too few reads to sample. Exit!" ++ print("Too few reads to sample. Exit!", file=sys.stderr) + sys.exit(1) + mRNA_RPKM = (mRNA_count * 1000000000.0)/(mRNA_len * sample_size) + RPKM_table[key].append(str(mRNA_RPKM)) + rawCount_table[key].append(str(mRNA_count)) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #self.f.seek(0) +- print >>RPKM_OUT, '\t'.join(RPKM_head) +- print >>RAW_OUT, '\t'.join(RPKM_head) ++ print('\t'.join(RPKM_head), file=RPKM_OUT) ++ print('\t'.join(RPKM_head), file=RAW_OUT) + for key in RPKM_table: +- print >>RPKM_OUT, key + '\t', +- print >>RPKM_OUT, '\t'.join(RPKM_table[key]) +- print >>RAW_OUT, key + '\t', +- print >>RAW_OUT, '\t'.join(rawCount_table[key]) ++ print(key + '\t', end=' ', file=RPKM_OUT) ++ print('\t'.join(RPKM_table[key]), file=RPKM_OUT) ++ print(key + '\t', end=' ', file=RAW_OUT) ++ print('\t'.join(rawCount_table[key]), file=RAW_OUT) + + def saturation_junction(self,refgene,outfile=None,sample_start=5,sample_step=5,sample_end=100,min_intron=50,recur=1): + '''check if an RNA-seq experiment is saturated in terms of detecting known splicing junction''' +@@ -1805,7 +1805,7 @@ class QCSAM: + else: + out_file = outfile + ".junctionSaturation_plot.r" + if refgene is None: +- print >>sys.stderr, "You must provide reference gene model in bed format." ++ print("You must provide reference gene model in bed format.", file=sys.stderr) + sys.exit(1) + + OUT = open(out_file,'w') +@@ -1813,12 +1813,12 @@ class QCSAM: + + #reading reference gene + knownSpliceSites= set() +- print >>sys.stderr, "reading reference bed file: ",refgene, " ... ", ++ print("reading reference bed file: ",refgene, " ... ", end=' ', file=sys.stderr) + for line in open(refgene,'r'): + if line.startswith(('#','track','browser')):continue + fields = line.split() + if(len(fields)<12): +- print >>sys.stderr, "Invalid bed line (skipped):",line, ++ print("Invalid bed line (skipped):",line, end=' ', file=sys.stderr) + continue + chrom = fields[0].upper() + tx_start = int( fields[1] ) +@@ -1826,15 +1826,15 @@ class QCSAM: + if int(fields[9] ==1): + continue + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + intron_start = exon_ends[:-1] + intron_end=exon_starts[1:] + for st,end in zip (intron_start, intron_end): + knownSpliceSites.add(chrom + ":" + str(st) + "-" + str(end)) +- print >>sys.stderr,"Done! Total "+str(len(knownSpliceSites)) + " known splicing sites" ++ print("Done! Total "+str(len(knownSpliceSites)) + " known splicing sites", file=sys.stderr) + + + #read SAM file +@@ -1842,7 +1842,7 @@ class QCSAM: + intron_start=[] + intron_end=[] + uniqSpliceSites=collections.defaultdict(int) +- print >>sys.stderr, "Reading "+ self.fileName + '...', ++ print("Reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -1883,13 +1883,13 @@ class QCSAM: + for st,end in zip(intron_st, intron_end): + samSpliceSites.append(chrom + ":" + str(st) + "-" + str(end)) + #self.f.seek(0) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + +- print >>sys.stderr, "shuffling alignments ...", ++ print("shuffling alignments ...", end=' ', file=sys.stderr) + random.shuffle(samSpliceSites) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #resampling + SR_num = len(samSpliceSites) +@@ -1898,7 +1898,7 @@ class QCSAM: + known_junc=[] + all_junc=[] + #=========================sampling uniquely mapped reads from population +- tmp=range(sample_start,sample_end,sample_step) ++ tmp=list(range(sample_start,sample_end,sample_step)) + tmp.append(100) + for pertl in tmp: #[5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95,100] + knownSpliceSites_num = 0 +@@ -1907,26 +1907,26 @@ class QCSAM: + if index_st < 0: index_st = 0 + sample_size += index_end -index_st + +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(sample_size) + ") unique splicing alignments ...", ++ print("sampling " + str(pertl) +"% (" + str(sample_size) + ") unique splicing alignments ...", end=' ', file=sys.stderr) + for i in range(index_st, index_end): + uniqSpliceSites[samSpliceSites[i]] +=1 +- all_junc.append(str(len(uniqSpliceSites.keys()))) ++ all_junc.append(str(len(list(uniqSpliceSites.keys())))) + for sj in uniqSpliceSites: + if sj in knownSpliceSites and uniqSpliceSites[sj] >= recur: + knownSpliceSites_num +=1 +- print >>sys.stderr, str(knownSpliceSites_num) + " known splicing junctions" ++ print(str(knownSpliceSites_num) + " known splicing junctions", file=sys.stderr) + known_junc.append(str(knownSpliceSites_num)) + + #for j in uniq_SJ: + #print >>OUT, j + "\t" + str(uniq_SJ[j]) +- print >>OUT, "pdf('junction_saturation.pdf')" +- print >>OUT, "x=c(" + ','.join([str(i) for i in tmp]) + ')' +- print >>OUT, "y=c(" + ','.join(known_junc) + ')' +- print >>OUT, "z=c(" + ','.join(all_junc) + ')' +- print >>OUT, "plot(x,z/1000,xlab='percent of total reads',ylab='Number of splicing junctions (x1000)',type='o',col='blue',ylim=c(%d,%d))" % (int(int(known_junc[0])/1000), int(int(all_junc[-1])/1000)) +- print >>OUT, "points(x,y/1000,type='o',col='red')" +- print >>OUT, 'legend(5,%d, legend=c("All detected junction","Annotated junction"),col=c("blue","red"),lwd=1,pch=1)' % int(int(all_junc[-1])/1000) +- print >>OUT, "dev.off()" ++ print("pdf('junction_saturation.pdf')", file=OUT) ++ print("x=c(" + ','.join([str(i) for i in tmp]) + ')', file=OUT) ++ print("y=c(" + ','.join(known_junc) + ')', file=OUT) ++ print("z=c(" + ','.join(all_junc) + ')', file=OUT) ++ print("plot(x,z/1000,xlab='percent of total reads',ylab='Number of splicing junctions (x1000)',type='o',col='blue',ylim=c(%d,%d))" % (int(int(known_junc[0])/1000), int(int(all_junc[-1])/1000)), file=OUT) ++ print("points(x,y/1000,type='o',col='red')", file=OUT) ++ print('legend(5,%d, legend=c("All detected junction","Annotated junction"),col=c("blue","red"),lwd=1,pch=1)' % int(int(all_junc[-1])/1000), file=OUT) ++ print("dev.off()", file=OUT) + + + def annotate_junction(self,refgene,outfile=None,min_intron=50): +@@ -1941,7 +1941,7 @@ class QCSAM: + out_file = outfile + ".junction.xls" + out_file2 = outfile + ".junction_plot.r" + if refgene is None: +- print >>sys.stderr, "You must provide reference gene model in bed format." ++ print("You must provide reference gene model in bed format.", file=sys.stderr) + sys.exit(1) + OUT = open(out_file,'w') + ROUT = open(out_file2,'w') +@@ -1955,13 +1955,13 @@ class QCSAM: + known_junc =0 + splicing_events=collections.defaultdict(int) + +- print >>sys.stderr, "\treading reference bed file: ",refgene, " ... ", ++ print("\treading reference bed file: ",refgene, " ... ", end=' ', file=sys.stderr) + for line in open(refgene,'r'): + if line.startswith(('#','track','browser')):continue + # Parse fields from gene tabls + fields = line.split() + if(len(fields)<12): +- print >>sys.stderr, "Invalid bed line (skipped):",line, ++ print("Invalid bed line (skipped):",line, end=' ', file=sys.stderr) + continue + chrom = fields[0].upper() + tx_start = int( fields[1] ) +@@ -1969,19 +1969,19 @@ class QCSAM: + if int(fields[9] ==1): + continue + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + intron_start = exon_ends[:-1] + intron_end=exon_starts[1:] + for i_st,i_end in zip (intron_start, intron_end): + refIntronStarts[chrom][i_st] =i_st + refIntronEnds[chrom][i_end] =i_end +- print >>sys.stderr,"Done" ++ print("Done", file=sys.stderr) + + #reading input SAM file +- print >>sys.stderr, "\tProcessing "+ self.fileName + '...', ++ print("\tProcessing "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -2022,25 +2022,25 @@ class QCSAM: + intron_end = blockStart[1:] + for i_st,i_end in zip(intron_st, intron_end): + splicing_events[chrom + ":" + str(i_st) + ":" + str(i_end)] += 1 +- if (refIntronStarts[chrom].has_key(i_st) and refIntronEnds[chrom].has_key(i_end)): ++ if (i_st in refIntronStarts[chrom] and i_end in refIntronEnds[chrom]): + known_junc +=1 #known both +- elif (not refIntronStarts[chrom].has_key(i_st) and not refIntronEnds[chrom].has_key(i_end)): ++ elif (i_st not in refIntronStarts[chrom] and i_end not in refIntronEnds[chrom]): + novel35_junc +=1 + else: + novel3or5_junc +=1 + #self.f.seek(0) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>ROUT, 'pdf("splicing_events_pie.pdf")' +- print >>ROUT, "events=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc)])+ ')' +- print >>ROUT, 'pie(events,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing events",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)) +- print >>ROUT, "dev.off()" ++ print('pdf("splicing_events_pie.pdf")', file=ROUT) ++ print("events=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc)])+ ')', file=ROUT) ++ print('pie(events,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing events",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)), file=ROUT) ++ print("dev.off()", file=ROUT) + +- print >>sys.stderr, "\n===================================================================" +- print >>sys.stderr, "Total splicing Events:\t" + str(total_junc) +- print >>sys.stderr, "Known Splicing Events:\t" + str(known_junc) +- print >>sys.stderr, "Partial Novel Splicing Events:\t" + str(novel3or5_junc) +- print >>sys.stderr, "Novel Splicing Events:\t" + str(novel35_junc) ++ print("\n===================================================================", file=sys.stderr) ++ print("Total splicing Events:\t" + str(total_junc), file=sys.stderr) ++ print("Known Splicing Events:\t" + str(known_junc), file=sys.stderr) ++ print("Partial Novel Splicing Events:\t" + str(novel3or5_junc), file=sys.stderr) ++ print("Novel Splicing Events:\t" + str(novel35_junc), file=sys.stderr) + + #reset variables + total_junc =0 +@@ -2048,34 +2048,34 @@ class QCSAM: + novel3or5_junc =0 + known_junc =0 + +- print >>OUT, "chrom\tintron_st(0-based)\tintron_end(1-based)\tread_count\tannotation" ++ print("chrom\tintron_st(0-based)\tintron_end(1-based)\tread_count\tannotation", file=OUT) + for i in splicing_events: + total_junc += 1 + (chrom, i_st, i_end) = i.split(":") +- print >>OUT, '\t'.join([chrom.replace("CHR","chr"),i_st,i_end]) + '\t' + str(splicing_events[i]) + '\t', ++ print('\t'.join([chrom.replace("CHR","chr"),i_st,i_end]) + '\t' + str(splicing_events[i]) + '\t', end=' ', file=OUT) + i_st = int(i_st) + i_end = int(i_end) +- if (refIntronStarts[chrom].has_key(i_st) and refIntronEnds[chrom].has_key(i_end)): +- print >>OUT, "annotated" ++ if (i_st in refIntronStarts[chrom] and i_end in refIntronEnds[chrom]): ++ print("annotated", file=OUT) + known_junc +=1 +- elif (not refIntronStarts[chrom].has_key(i_st) and not refIntronEnds[chrom].has_key(i_end)): +- print >>OUT, 'complete_novel' ++ elif (i_st not in refIntronStarts[chrom] and i_end not in refIntronEnds[chrom]): ++ print('complete_novel', file=OUT) + novel35_junc +=1 + else: +- print >>OUT, 'partial_novel' ++ print('partial_novel', file=OUT) + novel3or5_junc +=1 + + +- print >>sys.stderr, "\nTotal splicing Junctions:\t" + str(total_junc) +- print >>sys.stderr, "Known Splicing Junctions:\t" + str(known_junc) +- print >>sys.stderr, "Partial Novel Splicing Junctions:\t" + str(novel3or5_junc) +- print >>sys.stderr, "Novel Splicing Junctions:\t" + str(novel35_junc) +- print >>sys.stderr, "\n===================================================================" ++ print("\nTotal splicing Junctions:\t" + str(total_junc), file=sys.stderr) ++ print("Known Splicing Junctions:\t" + str(known_junc), file=sys.stderr) ++ print("Partial Novel Splicing Junctions:\t" + str(novel3or5_junc), file=sys.stderr) ++ print("Novel Splicing Junctions:\t" + str(novel35_junc), file=sys.stderr) ++ print("\n===================================================================", file=sys.stderr) + +- print >>ROUT, 'pdf("splicing_junction_pie.pdf")' +- print >>ROUT, "junction=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc,)])+ ')' +- print >>ROUT, 'pie(junction,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing junctions",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)) +- print >>ROUT, "dev.off()" ++ print('pdf("splicing_junction_pie.pdf")', file=ROUT) ++ print("junction=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc,)])+ ')', file=ROUT) ++ print('pie(junction,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing junctions",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)), file=ROUT) ++ print("dev.off()", file=ROUT) + #print >>ROUT, "mat=matrix(c(events,junction),byrow=T,ncol=3)" + #print >>ROUT, 'barplot(mat,beside=T,ylim=c(0,100),names=c("known","partial\nnovel","complete\nnovel"),legend.text=c("splicing events","splicing junction"),ylab="Percent")' + +@@ -2083,7 +2083,7 @@ class QCSAM: + '''calculate mRNA's RPKM value''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if outfile is None: + rpkm_file = self.fileName + ".RPKM.xls" +@@ -2101,7 +2101,7 @@ class QCSAM: + RPKM_head=['chr','start','end','name','score','strand','length','rawCount','RPKM'] + + #read SAM +- print >>sys.stderr, "Reading "+ self.fileName + '...', ++ print("Reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -2131,10 +2131,10 @@ class QCSAM: + else: + ranges[chrom].add_interval( Interval( mid, mid ) ) + +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + +- print >>sys.stderr, "Calculating RPKM ...", ++ print("Calculating RPKM ...", end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -2145,14 +2145,14 @@ class QCSAM: + tx_end = int( fields[2] ) + geneName = fields[3] + strand = fields[5].replace(" ","_") +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, file=sys.stderr) + continue + mRNA_count=0 #we need to initializ it to 0 for each gene + mRNA_len=sum(exon_sizes) +@@ -2164,14 +2164,14 @@ class QCSAM: + mRNAlen_table[key] = mRNA_len + RPKM_table[key] = str(mRNA_RPKM) + rawCount_table[key] = str(mRNA_count) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>RPKM_OUT, '\t'.join(RPKM_head) ++ print('\t'.join(RPKM_head), file=RPKM_OUT) + for k in RPKM_table: +- print >>RPKM_OUT, k + '\t', +- print >>RPKM_OUT, str(mRNAlen_table[k]) + '\t', +- print >>RPKM_OUT, str(rawCount_table[k]) + '\t', +- print >>RPKM_OUT, str(RPKM_table[k]) + '\t' ++ print(k + '\t', end=' ', file=RPKM_OUT) ++ print(str(mRNAlen_table[k]) + '\t', end=' ', file=RPKM_OUT) ++ print(str(rawCount_table[k]) + '\t', end=' ', file=RPKM_OUT) ++ print(str(RPKM_table[k]) + '\t', file=RPKM_OUT) + return RPKM_table + self.f.seek(0) + +@@ -2180,10 +2180,10 @@ class QCSAM: + use the parental gene as standard, for spliced read, use the splicing motif as strandard''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + if genome is None: +- print >>sys.stderr,"You must specify genome sequence in fasta format\n" ++ print("You must specify genome sequence in fasta format\n", file=sys.stderr) + exit(0) + + if outfile is None: +@@ -2191,19 +2191,19 @@ class QCSAM: + else: + strand_file = outfile + ".strand.infor" + OUT = open(strand_file,'w') +- print >>OUT,"read_type\tread_id\tread_seq\tchr\tStart\tCigar\tprotocol_strand\tgene_strand" ++ print("read_type\tread_id\tread_seq\tchr\tStart\tCigar\tprotocol_strand\tgene_strand", file=OUT) + + transtab = string.maketrans("ACGTNX","TGCANX") + motif=sp.upper().split(',') + motif_rev = [m.translate(transtab)[::-1] for m in motif] + + #load genome +- print >>sys.stderr, "\tloading "+genome+'...' ++ print("\tloading "+genome+'...', file=sys.stderr) + tmp=fasta.Fasta(genome) + + #load reference gene model + gene_ranges={} +- print >>sys.stderr, "reading reference gene model ...", ++ print("reading reference gene model ...", end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -2215,12 +2215,12 @@ class QCSAM: + geneName = fields[3] + strand = fields[5] + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, file=sys.stderr) + continue + if chrom not in gene_ranges: + gene_ranges[chrom]=Intersecter() + gene_ranges[chrom].insert(tx_start,tx_end,strand) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #read SAM + +@@ -2228,7 +2228,7 @@ class QCSAM: + strand_from_protocol = 'unknown' + strand_from_gene='unknown' + strand_stat=collections.defaultdict(int) +- print >>sys.stderr, "Reading "+ self.fileName + '...', ++ print("Reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -2258,9 +2258,9 @@ class QCSAM: + else: + strand_from_gene="intergenic" + +- print >>OUT,read_type + '\t' + fields[0] + '\t' + fields[9] + '\t' + fields[2] + '\t' + fields[3] + '\t' + fields[5] +'\t', +- print >>OUT,strand_from_protocol + '\t' + strand_from_gene +- strand_stat[read_type + '\t' + strand_from_protocol +'\t' + strand_from_gene] +=1 ++ print(read_type + '\t' + fields[0] + '\t' + fields[9] + '\t' + fields[2] + '\t' + fields[3] + '\t' + fields[5] +'\t', end=' ', file=OUT) ++ print(strand_from_protocol + '\t' + strand_from_gene, file=OUT) ++ strand_stat[read_type + '\t' + strand_from_protocol +'\t' + strand_from_gene] +=1 + + + #for spliced read +@@ -2273,14 +2273,14 @@ class QCSAM: + blockStart.append(readStart + sum(comb[:i]) ) + for i in range(0,len(comb),2): + blockSize.append(comb[i]) +- blockEnd=map((lambda x,y:x+y),blockStart,blockSize) ++ blockEnd=list(map((lambda x,y:x+y),blockStart,blockSize)) + intron_start=blockEnd[:-1] + intron_end=blockStart[1:] + for st,end in zip(intron_start,intron_end): + try: + splice_motif = str(tmp.fetchSeq(chrom, st, st+2)) + str(tmp.fetchSeq(chrom, end-2,end)) + except: +- print line ++ print(line) + if splice_motif in motif: + splice_strand.append('+') + elif splice_motif in motif_rev: +@@ -2293,16 +2293,16 @@ class QCSAM: + strand_from_splice = 'unknown motif' + else: + strand_from_splice = set(splice_strand).pop() +- print >>OUT,read_type + '\t' + fields[0] + '\t' + fields[9] + '\t' + fields[2] + '\t' + fields[3] + '\t' + fields[5] +'\t', +- print >>OUT,strand_from_protocol + '\t' + strand_from_splice ++ print(read_type + '\t' + fields[0] + '\t' + fields[9] + '\t' + fields[2] + '\t' + fields[3] + '\t' + fields[5] +'\t', end=' ', file=OUT) ++ print(strand_from_protocol + '\t' + strand_from_splice, file=OUT) + + strand_stat[read_type + '\t' + strand_from_protocol +'\t' + strand_from_splice] +=1 + +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print "read_type\tstrand_expected\tstrand_observed\tcount" ++ print("read_type\tstrand_expected\tstrand_observed\tcount") + for i in sorted(strand_stat): +- print str(i) +'\t' + str(strand_stat[i]) ++ print(str(i) +'\t' + str(strand_stat[i])) + + def clipping_profile(self,outfile=None): + '''calculate profile of soft clipping''' +@@ -2315,7 +2315,7 @@ class QCSAM: + + OUT=open(out_file1,'w') + ROUT=open(out_file2,'w') +- print >>OUT, "Position\tRead_Total\tRead_clipped" ++ print("Position\tRead_Total\tRead_clipped", file=OUT) + soft_p = re.compile(r'(.*?)(\d+)S') + read_part = re.compile(r'(\d+)[MIS=X]') + total_read =0 +@@ -2324,7 +2324,7 @@ class QCSAM: + + read_pos=[] + clip_count=[] +- print >>sys.stderr, "Reading "+ self.fileName + '...' ++ print("Reading "+ self.fileName + '...', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -2349,12 +2349,12 @@ class QCSAM: + for i in soft_clip_profile: + read_pos.append(str(i)) + clip_count.append(str(soft_clip_profile[i])) +- print >>OUT, str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]) +- print >>ROUT, "pdf('clipping_profile.pdf')" +- print >>ROUT, "read_pos=c(" + ','.join(read_pos) + ')' +- print >>ROUT, "count=c(" + ','.join(clip_count) + ')' +- print >>ROUT, 'plot(read_pos,1-(count/%d),col="blue",main="clipping profile",xlab="Position of reads",ylab="Mappability",type="b")' % total_read +- print >>ROUT, "dev.off()" ++ print(str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]), file=OUT) ++ print("pdf('clipping_profile.pdf')", file=ROUT) ++ print("read_pos=c(" + ','.join(read_pos) + ')', file=ROUT) ++ print("count=c(" + ','.join(clip_count) + ')', file=ROUT) ++ print('plot(read_pos,1-(count/%d),col="blue",main="clipping profile",xlab="Position of reads",ylab="Mappability",type="b")' % total_read, file=ROUT) ++ print("dev.off()", file=ROUT) + + def insertion_profile(self,read_len,outfile=None): + '''calculate profile of insertion (insertion means insertion to the reference)''' +@@ -2367,13 +2367,13 @@ class QCSAM: + + OUT=open(out_file1,'w') + ROUT=open(out_file2,'w') +- print >>OUT, "Position\tRead_Total\tRead_clipped" ++ print("Position\tRead_Total\tRead_clipped", file=OUT) + soft_p = re.compile(r'(.*?)(\d+)I') + read_part = re.compile(r'(\d+)[MIS=X]') + total_read =0 + skip_part_of_read =0 + soft_clip_profile=collections.defaultdict(int) +- print >>sys.stderr, "Reading "+ self.fileName + '...', ++ print("Reading "+ self.fileName + '...', end=' ', file=sys.stderr) + for line in self.f: + if line.startswith("@"):continue + fields=line.rstrip('\n ').split() +@@ -2396,7 +2396,7 @@ class QCSAM: + soft_clip_profile[n]+=1 + skip_part_of_read += int(j[1]) + for i in range(0,read_len): +- print >>OUT, str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]) ++ print(str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]), file=OUT) + + class ParseBAM: + '''This class provides fuctions to parsing/processing/transforming SAM or BAM files. The input +@@ -2408,13 +2408,13 @@ class ParseBAM: + try: + self.samfile = pysam.Samfile(inputFile,'rb') + if len(self.samfile.header) ==0: +- print >>sys.stderr, "BAM/SAM file has no header section. Exit!" ++ print("BAM/SAM file has no header section. Exit!", file=sys.stderr) + sys.exit(1) + self.bam_format = True + except: + self.samfile = pysam.Samfile(inputFile,'r') + if len(self.samfile.header) ==0: +- print >>sys.stderr, "BAM/SAM file has no header section. Exit!" ++ print("BAM/SAM file has no header section. Exit!", file=sys.stderr) + sys.exit(1) + self.bam_format = False + +@@ -2437,13 +2437,13 @@ class ParseBAM: + R_splice=0 + R_properPair =0 + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + R_total +=1 + if aligned_read.is_qcfail: #skip QC fail read + R_qc_fail +=1 +@@ -2487,26 +2487,26 @@ class ParseBAM: + R_properPair +=1 + + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + #self.samfile.seek(current_pos) + +- print >>sys.stderr,"\n#==================================================" +- print >>sys.stderr, "%-30s%d" % ("Total Reads (Records):",R_total) +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-30s%d" % ("QC failed:",R_qc_fail) +- print >>sys.stderr, "%-30s%d" % ("Optical/PCR duplicate:", R_duplicate) +- print >>sys.stderr, "%-30s%d" % ("Non Primary Hits", R_nonprimary) +- print >>sys.stderr, "%-30s%d" % ("Unmapped reads:",R_unmap) +- print >>sys.stderr, "%-30s%d" % ("Multiple mapped reads:",R_multipleHit) +- print >>sys.stderr, "\n", +- print >>sys.stderr, "%-30s%d" % ("Uniquely mapped:",R_uniqHit) +- print >>sys.stderr, "%-30s%d" % ("Read-1:",R_read1) +- print >>sys.stderr, "%-30s%d" % ("Read-2:",R_read2) +- print >>sys.stderr, "%-30s%d" % ("Reads map to '+':",R_forward) +- print >>sys.stderr, "%-30s%d" % ("Reads map to '-':",R_reverse) +- print >>sys.stderr, "%-30s%d" % ("Non-splice reads:",R_nonSplice) +- print >>sys.stderr, "%-30s%d" % ("Splice reads:",R_splice) +- print >>sys.stderr, "%-30s%d" % ("Reads mapped in proper pairs:",R_properPair) ++ print("\n#==================================================", file=sys.stderr) ++ print("%-30s%d" % ("Total Reads (Records):",R_total), file=sys.stderr) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-30s%d" % ("QC failed:",R_qc_fail), file=sys.stderr) ++ print("%-30s%d" % ("Optical/PCR duplicate:", R_duplicate), file=sys.stderr) ++ print("%-30s%d" % ("Non Primary Hits", R_nonprimary), file=sys.stderr) ++ print("%-30s%d" % ("Unmapped reads:",R_unmap), file=sys.stderr) ++ print("%-30s%d" % ("Multiple mapped reads:",R_multipleHit), file=sys.stderr) ++ print("\n", end=' ', file=sys.stderr) ++ print("%-30s%d" % ("Uniquely mapped:",R_uniqHit), file=sys.stderr) ++ print("%-30s%d" % ("Read-1:",R_read1), file=sys.stderr) ++ print("%-30s%d" % ("Read-2:",R_read2), file=sys.stderr) ++ print("%-30s%d" % ("Reads map to '+':",R_forward), file=sys.stderr) ++ print("%-30s%d" % ("Reads map to '-':",R_reverse), file=sys.stderr) ++ print("%-30s%d" % ("Non-splice reads:",R_nonSplice), file=sys.stderr) ++ print("%-30s%d" % ("Splice reads:",R_splice), file=sys.stderr) ++ print("%-30s%d" % ("Reads mapped in proper pairs:",R_properPair), file=sys.stderr) + + def configure_experiment(self,refbed,sample_size = 200000): + '''Given a BAM/SAM file, this function will try to guess the RNA-seq experiment: +@@ -2521,7 +2521,7 @@ class ParseBAM: + s_strandness=collections.defaultdict(int) + #load reference gene model + gene_ranges={} +- print >>sys.stderr, "Reading reference gene model " + refbed + ' ...', ++ print("Reading reference gene model " + refbed + ' ...', end=' ', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -2533,22 +2533,22 @@ class ParseBAM: + geneName = fields[3] + strand = fields[5] + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, file=sys.stderr) + continue + if chrom not in gene_ranges: + gene_ranges[chrom]=Intersecter() + gene_ranges[chrom].insert(tx_start,tx_end,strand) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #read SAM/BAM file + #current_pos = self.samfile.tell() +- print >>sys.stderr, "Loading SAM/BAM file ... ", ++ print("Loading SAM/BAM file ... ", end=' ', file=sys.stderr) + try: + while(1): + if count >= sample_size: + break + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail: #skip low quanlity + continue + if aligned_read.is_duplicate: #skip duplicate read +@@ -2596,10 +2596,10 @@ class ParseBAM: + count += 1 + + except StopIteration: +- print >>sys.stderr, "Finished" ++ print("Finished", file=sys.stderr) + #self.samfile.seek(current_pos) + +- print >>sys.stderr, "Total " + str(count) + " usable reads were sampled" ++ print("Total " + str(count) + " usable reads were sampled", file=sys.stderr) + protocol="unknown" + strandness=None + spec1=0.0 +@@ -2640,7 +2640,7 @@ class ParseBAM: + elif len(strand_rule.split(',')) ==2: #singeEnd, strand-specific + for i in strand_rule.split(','):strandRule[i[0]]=i[1] + else: +- print >>sys.stderr, "Unknown value of option :'strand_rule' " + strand_rule ++ print("Unknown value of option :'strand_rule' " + strand_rule, file=sys.stderr) + sys.exit(1) + if len(strandRule) == 0: + FWO = open(outfile + '.wig','w') +@@ -2650,13 +2650,13 @@ class ParseBAM: + + + read_id='' +- for chr_name, chr_size in chrom_sizes.items(): #iterate each chrom ++ for chr_name, chr_size in list(chrom_sizes.items()): #iterate each chrom + try: + self.samfile.fetch(chr_name,0,chr_size) + except: +- print >>sys.stderr, "No alignments for " + chr_name + '. skipped' ++ print("No alignments for " + chr_name + '. skipped', file=sys.stderr) + continue +- print >>sys.stderr, "Processing " + chr_name + " ..." ++ print("Processing " + chr_name + " ...", file=sys.stderr) + if len(strandRule) == 0: FWO.write('variableStep chrom='+chr_name+'\n') + else: + FWO.write('variableStep chrom='+chr_name+'\n') +@@ -2699,12 +2699,12 @@ class ParseBAM: + + if len(strandRule) == 0: #this is NOT strand specific. + for pos in sorted (Fwig.keys()): +- print >>FWO, "%d\t%.2f" % (pos,Fwig[pos]) ++ print("%d\t%.2f" % (pos,Fwig[pos]), file=FWO) + else: + for pos in sorted (Fwig.keys()): +- print >>FWO, "%d\t%.2f" % (pos,Fwig[pos]) ++ print("%d\t%.2f" % (pos,Fwig[pos]), file=FWO) + for pos in sorted (Rwig.keys()): +- print >>RVO, "%d\t%.2f" % (pos,Rwig[pos]) ++ print("%d\t%.2f" % (pos,Rwig[pos]), file=RVO) + + + def calculate_rpkm(self,geneFile,outfile,strand_rule=None): +@@ -2732,7 +2732,7 @@ class ParseBAM: + elif len(strand_rule.split(',')) ==2: #singeEnd, strand-specific + for i in strand_rule.split(','):strandRule[i[0]]=i[1] + else: +- print >>sys.stderr, "Unknown value of option :'strand_rule' " + strand_rule ++ print("Unknown value of option :'strand_rule' " + strand_rule, file=sys.stderr) + sys.exit(1) + + uniq_read=0 +@@ -2744,14 +2744,14 @@ class ParseBAM: + rpkm_value={} + + RPKM_OUT = open(outfile,'w') +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + #current_pos = self.samfile.tell() + try: + while(1): + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -2801,11 +2801,11 @@ class ParseBAM: + else:unstrand_ranges[chrom].add_interval( Interval( mid,mid+1 ) ) + + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + #self.samfile.seek(current_pos) +- print >>RPKM_OUT, "#Total uniquely mapped reads = " + str(uniq_read) +- print >>RPKM_OUT, "#Total fragments = " + str(total_tags) +- print >>sys.stderr, "Assign reads to "+ geneFile + '...', ++ print("#Total uniquely mapped reads = " + str(uniq_read), file=RPKM_OUT) ++ print("#Total fragments = " + str(total_tags), file=RPKM_OUT) ++ print("Assign reads to "+ geneFile + '...', end=' ', file=sys.stderr) + for line in open(geneFile,'r'): + try: + if line.startswith('#'):continue +@@ -2819,16 +2819,16 @@ class ParseBAM: + geneName = fields[3] + strand = fields[5].replace(" ","_") + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + intron_starts = exon_ends[:-1] + intron_ends=exon_starts[1:] + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + + +@@ -2892,7 +2892,7 @@ class ParseBAM: + RPKM_OUT.write(chrom.lower() + "\t" + str(tx_start) + "\t" + str(tx_end) + "\t" + geneName + "_mRNA" + "\t" + str(mRNA_count) + "\t" + strand + '\t' + str(mRNA_count*1000000000.0/(mRNA_len*total_tags)) +'\n') + except: + RPKM_OUT.write(chrom.lower() + "\t" + str(tx_start) + "\t" + str(tx_end) + "\t" + geneName + "_mRNA" + "\t" + str(0) + "\t" + strand + '\t' + str(0) +'\n') +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + def readsNVC(self,outfile=None,nx=True): + '''for each read, calculate nucleotide frequency vs position''' +@@ -2914,12 +2914,12 @@ class ParseBAM: + t_count=[] + n_count=[] + x_count=[] +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + #if aligned_read.is_unmapped:continue #skip unmapped read + #if aligned_read.is_qcfail:continue #skip low quality + RNA_read = aligned_read.seq.upper() +@@ -2929,62 +2929,62 @@ class ParseBAM: + key = str(i) + j + base_freq[key] += 1 + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "generating data matrix ..." +- print >>FO, "Position\tA\tC\tG\tT\tN\tX" +- for i in xrange(len(RNA_read)): +- print >>FO, str(i) + '\t', +- print >>FO, str(base_freq[str(i) + "A"]) + '\t', ++ print("generating data matrix ...", file=sys.stderr) ++ print("Position\tA\tC\tG\tT\tN\tX", file=FO) ++ for i in range(len(RNA_read)): ++ print(str(i) + '\t', end=' ', file=FO) ++ print(str(base_freq[str(i) + "A"]) + '\t', end=' ', file=FO) + a_count.append(str(base_freq[str(i) + "A"])) +- print >>FO, str(base_freq[str(i) + "C"]) + '\t', ++ print(str(base_freq[str(i) + "C"]) + '\t', end=' ', file=FO) + c_count.append(str(base_freq[str(i) + "C"])) +- print >>FO, str(base_freq[str(i) + "G"]) + '\t', ++ print(str(base_freq[str(i) + "G"]) + '\t', end=' ', file=FO) + g_count.append(str(base_freq[str(i) + "G"])) +- print >>FO, str(base_freq[str(i) + "T"]) + '\t', ++ print(str(base_freq[str(i) + "T"]) + '\t', end=' ', file=FO) + t_count.append(str(base_freq[str(i) + "T"])) +- print >>FO, str(base_freq[str(i) + "N"]) + '\t', ++ print(str(base_freq[str(i) + "N"]) + '\t', end=' ', file=FO) + n_count.append(str(base_freq[str(i) + "N"])) +- print >>FO, str(base_freq[str(i) + "X"]) + '\t' ++ print(str(base_freq[str(i) + "X"]) + '\t', file=FO) + x_count.append(str(base_freq[str(i) + "X"])) + FO.close() + + #generating R scripts +- print >>sys.stderr, "generating R script ..." +- print >>RS, "position=c(" + ','.join([str(i) for i in xrange(len(RNA_read))]) + ')' +- print >>RS, "A_count=c(" + ','.join(a_count) + ')' +- print >>RS, "C_count=c(" + ','.join(c_count) + ')' +- print >>RS, "G_count=c(" + ','.join(g_count) + ')' +- print >>RS, "T_count=c(" + ','.join(t_count) + ')' +- print >>RS, "N_count=c(" + ','.join(n_count) + ')' +- print >>RS, "X_count=c(" + ','.join(x_count) + ')' ++ print("generating R script ...", file=sys.stderr) ++ print("position=c(" + ','.join([str(i) for i in range(len(RNA_read))]) + ')', file=RS) ++ print("A_count=c(" + ','.join(a_count) + ')', file=RS) ++ print("C_count=c(" + ','.join(c_count) + ')', file=RS) ++ print("G_count=c(" + ','.join(g_count) + ')', file=RS) ++ print("T_count=c(" + ','.join(t_count) + ')', file=RS) ++ print("N_count=c(" + ','.join(n_count) + ')', file=RS) ++ print("X_count=c(" + ','.join(x_count) + ')', file=RS) + + if nx: +- print >>RS, "total= A_count + C_count + G_count + T_count + N_count + X_count" +- print >>RS, "ym=max(A_count/total,C_count/total,G_count/total,T_count/total,N_count/total,X_count/total) + 0.05" +- print >>RS, "yn=min(A_count/total,C_count/total,G_count/total,T_count/total,N_count/total,X_count/total)" ++ print("total= A_count + C_count + G_count + T_count + N_count + X_count", file=RS) ++ print("ym=max(A_count/total,C_count/total,G_count/total,T_count/total,N_count/total,X_count/total) + 0.05", file=RS) ++ print("yn=min(A_count/total,C_count/total,G_count/total,T_count/total,N_count/total,X_count/total)", file=RS) + +- print >>RS, 'pdf(\"%s\")' % (outfile +".NVC_plot.pdf") +- print >>RS, 'plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")' +- print >>RS, 'lines(position,T_count/total,type="o",pch=20,col="red")' +- print >>RS, 'lines(position,G_count/total,type="o",pch=20,col="blue")' +- print >>RS, 'lines(position,C_count/total,type="o",pch=20,col="cyan")' +- print >>RS, 'lines(position,N_count/total,type="o",pch=20,col="black")' +- print >>RS, 'lines(position,X_count/total,type="o",pch=20,col="grey")' +- print >>RS, 'legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C","N","X"),col=c("dark green","red","blue","cyan","black","grey"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan","black","grey"))' +- print >>RS, "dev.off()" ++ print('pdf(\"%s\")' % (outfile +".NVC_plot.pdf"), file=RS) ++ print('plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")', file=RS) ++ print('lines(position,T_count/total,type="o",pch=20,col="red")', file=RS) ++ print('lines(position,G_count/total,type="o",pch=20,col="blue")', file=RS) ++ print('lines(position,C_count/total,type="o",pch=20,col="cyan")', file=RS) ++ print('lines(position,N_count/total,type="o",pch=20,col="black")', file=RS) ++ print('lines(position,X_count/total,type="o",pch=20,col="grey")', file=RS) ++ print('legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C","N","X"),col=c("dark green","red","blue","cyan","black","grey"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan","black","grey"))', file=RS) ++ print("dev.off()", file=RS) + else: +- print >>RS, "total= A_count + C_count + G_count + T_count" +- print >>RS, "ym=max(A_count/total,C_count/total,G_count/total,T_count/total) + 0.05" +- print >>RS, "yn=min(A_count/total,C_count/total,G_count/total,T_count/total)" ++ print("total= A_count + C_count + G_count + T_count", file=RS) ++ print("ym=max(A_count/total,C_count/total,G_count/total,T_count/total) + 0.05", file=RS) ++ print("yn=min(A_count/total,C_count/total,G_count/total,T_count/total)", file=RS) + +- print >>RS, 'pdf(\"%s\")' % (outfile +".NVC_plot.pdf") +- print >>RS, 'plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")' +- print >>RS, 'lines(position,T_count/total,type="o",pch=20,col="red")' +- print >>RS, 'lines(position,G_count/total,type="o",pch=20,col="blue")' +- print >>RS, 'lines(position,C_count/total,type="o",pch=20,col="cyan")' +- print >>RS, 'legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C"),col=c("dark green","red","blue","cyan"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan"))' +- print >>RS, "dev.off()" ++ print('pdf(\"%s\")' % (outfile +".NVC_plot.pdf"), file=RS) ++ print('plot(position,A_count/total,type="o",pch=20,ylim=c(yn,ym),col="dark green",xlab="Position of Read",ylab="Nucleotide Frequency")', file=RS) ++ print('lines(position,T_count/total,type="o",pch=20,col="red")', file=RS) ++ print('lines(position,G_count/total,type="o",pch=20,col="blue")', file=RS) ++ print('lines(position,C_count/total,type="o",pch=20,col="cyan")', file=RS) ++ print('legend('+ str(len(RNA_read)-10) + ',ym,legend=c("A","T","G","C"),col=c("dark green","red","blue","cyan"),lwd=2,pch=20,text.col=c("dark green","red","blue","cyan"))', file=RS) ++ print("dev.off()", file=RS) + + RS.close() + #self.f.seek(0) +@@ -2995,8 +2995,8 @@ class ParseBAM: + output = outfile + ".qual.r" + FO=open(output,'w') + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + quality = collections.defaultdict(dict) #read_pos=>quality score=>count + q_max = -1 +@@ -3005,7 +3005,7 @@ class ParseBAM: + i_box={} #key is read postion,value is + try: + while(1): +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + + #if aligned_read.is_unmapped:continue #skip unmapped read + #if aligned_read.is_qcfail:continue #skip low quality +@@ -3024,14 +3024,14 @@ class ParseBAM: + except: + quality[i][q] = 1 + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + for p in range(0,read_len): + #print str(p) + ':', + val=[] + occurrence=[] + for q in range(q_min,q_max+1): +- if quality.has_key(p) and quality[p].has_key(q): ++ if p in quality and q in quality[p]: + val.append(str(q)) + occurrence.append(str(quality[p][q])) + q_list.append(str(quality[p][q])) +@@ -3041,21 +3041,21 @@ class ParseBAM: + + + #generate R script for boxplot +- print >>FO, "pdf(\'%s\')" % (outfile + ".qual.boxplot.pdf") ++ print("pdf(\'%s\')" % (outfile + ".qual.boxplot.pdf"), file=FO) + for i in sorted(i_box): +- print >>FO,'p'+str(i) + '<-' + i_box[i] +- print >>FO, 'boxplot(' + ','.join(['p'+str(i) for i in i_box]) + ',xlab=\"Position of Read(5\'->3\')\",ylab=\"Phred Quality Score\",outline=F' + ')' +- print >>FO,"dev.off()" ++ print('p'+str(i) + '<-' + i_box[i], file=FO) ++ print('boxplot(' + ','.join(['p'+str(i) for i in i_box]) + ',xlab=\"Position of Read(5\'->3\')\",ylab=\"Phred Quality Score\",outline=F' + ')', file=FO) ++ print("dev.off()", file=FO) + + + #generate R script for heatmap +- print >>FO, '\n' +- print >>FO, "pdf(\'%s\')" % (outfile + ".qual.heatmap.pdf") +- print >>FO, "qual=c(" + ','.join(q_list) + ')' +- print >>FO, "mat=matrix(qual,ncol=%s,byrow=F)" % (read_len) +- print >>FO, 'Lab.palette <- colorRampPalette(c("blue", "orange", "red3","red2","red1","red"), space = "rgb",interpolate=c(\'spline\'))' +- print >>FO, "heatmap(mat,Rowv=NA,Colv=NA,xlab=\"Position of Read\",ylab=\"Phred Quality Score\",labRow=seq(from=%s,to=%s),col = Lab.palette(256),scale=\"none\" )" % (q_min,q_max) +- print >>FO, 'dev.off()' ++ print('\n', file=FO) ++ print("pdf(\'%s\')" % (outfile + ".qual.heatmap.pdf"), file=FO) ++ print("qual=c(" + ','.join(q_list) + ')', file=FO) ++ print("mat=matrix(qual,ncol=%s,byrow=F)" % (read_len), file=FO) ++ print('Lab.palette <- colorRampPalette(c("blue", "orange", "red3","red2","red1","red"), space = "rgb",interpolate=c(\'spline\'))', file=FO) ++ print("heatmap(mat,Rowv=NA,Colv=NA,xlab=\"Position of Read\",ylab=\"Phred Quality Score\",labRow=seq(from=%s,to=%s),col = Lab.palette(256),scale=\"none\" )" % (q_min,q_max), file=FO) ++ print('dev.off()', file=FO) + + + def readGC(self,outfile=None): +@@ -3071,12 +3071,12 @@ class ParseBAM: + + gc_hist=collections.defaultdict(int) #key is GC percent, value is count of reads + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_unmapped:continue #skip unmapped read + if aligned_read.is_qcfail:continue #skip low quality + RNA_read = aligned_read.seq.upper() +@@ -3084,19 +3084,19 @@ class ParseBAM: + #print gc_percent + gc_hist[gc_percent] += 1 + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "writing GC content ..." +- print >>FO, "GC%\tread_count" +- for i in gc_hist.keys(): +- print >>FO, i + '\t' + str(gc_hist[i]) ++ print("writing GC content ...", file=sys.stderr) ++ print("GC%\tread_count", file=FO) ++ for i in list(gc_hist.keys()): ++ print(i + '\t' + str(gc_hist[i]), file=FO) + +- print >>sys.stderr, "writing R script ..." +- print >>RS, "pdf(\"%s\")" % (outfile + ".GC_plot.pdf") +- print >>RS, 'gc=rep(c(' + ','.join([i for i in gc_hist.keys()]) + '),' + 'times=c(' + ','.join([str(i) for i in gc_hist.values()]) + '))' +- print >>RS, 'hist(gc,probability=T,breaks=%d,xlab="GC content (%%)",ylab="Density of Reads",border="blue",main="")' % 100 ++ print("writing R script ...", file=sys.stderr) ++ print("pdf(\"%s\")" % (outfile + ".GC_plot.pdf"), file=RS) ++ print('gc=rep(c(' + ','.join([i for i in list(gc_hist.keys())]) + '),' + 'times=c(' + ','.join([str(i) for i in list(gc_hist.values())]) + '))', file=RS) ++ print('hist(gc,probability=T,breaks=%d,xlab="GC content (%%)",ylab="Density of Reads",border="blue",main="")' % 100, file=RS) + #print >>RS, "lines(density(gc),col='red')" +- print >>RS ,"dev.off()" ++ print("dev.off()", file=RS) + #self.f.seek(0) + + +@@ -3120,13 +3120,13 @@ class ParseBAM: + seqDup_count=collections.defaultdict(int) + posDup_count=collections.defaultdict(int) + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): + exon_boundary="" +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_unmapped:continue #skip unmapped read + if aligned_read.is_qcfail:continue #skip low quality + RNA_read = aligned_read.seq.upper() +@@ -3142,40 +3142,40 @@ class ParseBAM: + posDup[key] +=1 + + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "report duplicte rate based on sequence ..." +- print >>SEQ, "Occurrence\tUniqReadNumber" +- for i in seqDup.values(): #key is occurence, value is uniq reads number (based on seq) ++ print("report duplicte rate based on sequence ...", file=sys.stderr) ++ print("Occurrence\tUniqReadNumber", file=SEQ) ++ for i in list(seqDup.values()): #key is occurence, value is uniq reads number (based on seq) + seqDup_count[i] +=1 +- for k in sorted(seqDup_count.iterkeys()): +- print >>SEQ, str(k) +'\t'+ str(seqDup_count[k]) ++ for k in sorted(seqDup_count.keys()): ++ print(str(k) +'\t'+ str(seqDup_count[k]), file=SEQ) + SEQ.close() + +- print >>sys.stderr, "report duplicte rate based on mapping ..." +- print >>POS, "Occurrence\tUniqReadNumber" +- for i in posDup.values(): #key is occurence, value is uniq reads number (based on coord) ++ print("report duplicte rate based on mapping ...", file=sys.stderr) ++ print("Occurrence\tUniqReadNumber", file=POS) ++ for i in list(posDup.values()): #key is occurence, value is uniq reads number (based on coord) + posDup_count[i] +=1 +- for k in sorted(posDup_count.iterkeys()): +- print >>POS, str(k) +'\t'+ str(posDup_count[k]) ++ for k in sorted(posDup_count.keys()): ++ print(str(k) +'\t'+ str(posDup_count[k]), file=POS) + POS.close() + + +- print >>sys.stderr, "generate R script ..." +- print >>RS, "pdf(\'%s\')" % (outfile +".DupRate_plot.pdf") +- print >>RS, "par(mar=c(5,4,4,5),las=0)" +- print >>RS, "seq_occ=c(" + ','.join([str(i) for i in sorted(seqDup_count.iterkeys()) ]) + ')' +- print >>RS, "seq_uniqRead=c(" + ','.join([str(seqDup_count[i]) for i in sorted(seqDup_count.iterkeys()) ]) + ')' +- print >>RS, "pos_occ=c(" + ','.join([str(i) for i in sorted(posDup_count.iterkeys()) ]) + ')' +- print >>RS, "pos_uniqRead=c(" + ','.join([str(posDup_count[i]) for i in sorted(posDup_count.iterkeys()) ]) + ')' +- print >>RS, "plot(pos_occ,log10(pos_uniqRead),ylab='Number of Reads (log10)',xlab='Frequency',pch=4,cex=0.8,col='blue',xlim=c(1,%d),yaxt='n')" % up_bound +- print >>RS, "points(seq_occ,log10(seq_uniqRead),pch=20,cex=0.8,col='red')" +- print >>RS, 'ym=floor(max(log10(pos_uniqRead)))' +- print >>RS, "legend(%d,ym,legend=c('Sequence-base','Mapping-base'),col=c('red','blue'),pch=c(4,20))" % max(up_bound-200,1) +- print >>RS, 'axis(side=2,at=0:ym,labels=0:ym)' +- print >>RS, 'axis(side=4,at=c(log10(pos_uniqRead[1]),log10(pos_uniqRead[2]),log10(pos_uniqRead[3]),log10(pos_uniqRead[4])), labels=c(round(pos_uniqRead[1]*100/sum(pos_uniqRead)),round(pos_uniqRead[2]*100/sum(pos_uniqRead)),round(pos_uniqRead[3]*100/sum(pos_uniqRead)),round(pos_uniqRead[4]*100/sum(pos_uniqRead))))' +- print >>RS, 'mtext(4, text = "Reads %", line = 2)' +- print >>RS, 'dev.off()' ++ print("generate R script ...", file=sys.stderr) ++ print("pdf(\'%s\')" % (outfile +".DupRate_plot.pdf"), file=RS) ++ print("par(mar=c(5,4,4,5),las=0)", file=RS) ++ print("seq_occ=c(" + ','.join([str(i) for i in sorted(seqDup_count.keys()) ]) + ')', file=RS) ++ print("seq_uniqRead=c(" + ','.join([str(seqDup_count[i]) for i in sorted(seqDup_count.keys()) ]) + ')', file=RS) ++ print("pos_occ=c(" + ','.join([str(i) for i in sorted(posDup_count.keys()) ]) + ')', file=RS) ++ print("pos_uniqRead=c(" + ','.join([str(posDup_count[i]) for i in sorted(posDup_count.keys()) ]) + ')', file=RS) ++ print("plot(pos_occ,log10(pos_uniqRead),ylab='Number of Reads (log10)',xlab='Frequency',pch=4,cex=0.8,col='blue',xlim=c(1,%d),yaxt='n')" % up_bound, file=RS) ++ print("points(seq_occ,log10(seq_uniqRead),pch=20,cex=0.8,col='red')", file=RS) ++ print('ym=floor(max(log10(pos_uniqRead)))', file=RS) ++ print("legend(%d,ym,legend=c('Sequence-base','Mapping-base'),col=c('red','blue'),pch=c(4,20))" % max(up_bound-200,1), file=RS) ++ print('axis(side=2,at=0:ym,labels=0:ym)', file=RS) ++ print('axis(side=4,at=c(log10(pos_uniqRead[1]),log10(pos_uniqRead[2]),log10(pos_uniqRead[3]),log10(pos_uniqRead[4])), labels=c(round(pos_uniqRead[1]*100/sum(pos_uniqRead)),round(pos_uniqRead[2]*100/sum(pos_uniqRead)),round(pos_uniqRead[3]*100/sum(pos_uniqRead)),round(pos_uniqRead[4]*100/sum(pos_uniqRead))))', file=RS) ++ print('mtext(4, text = "Reads %", line = 2)', file=RS) ++ print('dev.off()', file=RS) + #self.f.seek(0) + + def clipping_profile(self,outfile): +@@ -3185,7 +3185,7 @@ class ParseBAM: + + OUT=open(out_file1,'w') + ROUT=open(out_file2,'w') +- print >>OUT, "Position\tRead_Total\tRead_clipped" ++ print("Position\tRead_Total\tRead_clipped", file=OUT) + soft_p = re.compile(r'(.*?)(\d+)S') + read_part = re.compile(r'(\d+)[MIS=X]') + total_read =0 +@@ -3195,13 +3195,13 @@ class ParseBAM: + read_pos=[] + clip_count=[] + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): + exon_boundary="" +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_unmapped:continue #skip unmapped read + if aligned_read.is_qcfail:continue #skip low quality + +@@ -3217,24 +3217,24 @@ class ParseBAM: + soft_clip_profile[n]+=1 + skip_part_of_read += int(j[1]) + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + for i in soft_clip_profile: + read_pos.append(str(i)) + clip_count.append(str(soft_clip_profile[i])) +- print >>OUT, str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]) +- print >>ROUT, "pdf('clipping_profile.pdf')" +- print >>ROUT, "read_pos=c(" + ','.join(read_pos) + ')' +- print >>ROUT, "count=c(" + ','.join(clip_count) + ')' +- print >>ROUT, 'plot(read_pos,1-(count/%d),col="blue",main="clipping profile",xlab="Position of reads",ylab="Mappability",type="b")' % total_read +- print >>ROUT, "dev.off()" ++ print(str(i) + '\t' + str(total_read) + '\t' + str(soft_clip_profile[i]), file=OUT) ++ print("pdf('clipping_profile.pdf')", file=ROUT) ++ print("read_pos=c(" + ','.join(read_pos) + ')', file=ROUT) ++ print("count=c(" + ','.join(clip_count) + ')', file=ROUT) ++ print('plot(read_pos,1-(count/%d),col="blue",main="clipping profile",xlab="Position of reads",ylab="Mappability",type="b")' % total_read, file=ROUT) ++ print("dev.off()", file=ROUT) + + def coverageGeneBody(self,refbed,outfile): + '''Calculate reads coverage over gene body, from 5'to 3'. each gene will be equally divided + into 100 regsions''' + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + OUT1 = open(outfile + ".geneBodyCoverage_plot.r",'w') + OUT2 = open(outfile + ".geneBodyCoverage.txt",'w') +@@ -3245,12 +3245,12 @@ class ParseBAM: + rpkm={} + + #read SAM +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -3269,9 +3269,9 @@ class ParseBAM: + else: + ranges[chrom].add_interval( Interval( exon[1], exon[2] ) ) + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "calculating coverage over gene body ..." ++ print("calculating coverage over gene body ...", file=sys.stderr) + coverage=collections.defaultdict(int) + flag=0 + for line in open(refbed,'r'): +@@ -3285,19 +3285,19 @@ class ParseBAM: + geneName = fields[3] + strand = fields[5] + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line, ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, end=' ', file=sys.stderr) + continue + gene_all_base=[] + percentile_base=[] + mRNA_len =0 + flag=0 + for st,end in zip(exon_starts,exon_ends): +- gene_all_base.extend(range(st+1,end+1)) #0-based coordinates on genome ++ gene_all_base.extend(list(range(st+1,end+1))) #0-based coordinates on genome + mRNA_len = len(gene_all_base) + if mRNA_len <100: + flag=1 +@@ -3314,18 +3314,18 @@ class ParseBAM: + coverage[i] += len(ranges[chrom].find(percentile_base[i], percentile_base[i]+1)) + x_coord=[] + y_coord=[] +- print >>OUT2, "Total reads: " + str(totalReads) +- print >>OUT2, "Fragment number: " + str(fragment_num) +- print >>OUT2, "percentile\tcount" ++ print("Total reads: " + str(totalReads), file=OUT2) ++ print("Fragment number: " + str(fragment_num), file=OUT2) ++ print("percentile\tcount", file=OUT2) + for i in coverage: + x_coord.append(str(i)) + y_coord.append(str(coverage[i])) +- print >>OUT2, str(i) + '\t' + str(coverage[i]) +- print >>OUT1, "pdf(\'%s\')" % (outfile + ".geneBodyCoverage.pdf") +- print >>OUT1, "x=0:100" +- print >>OUT1, "y=c(" + ','.join(y_coord) + ')' +- print >>OUT1, "plot(x,y,xlab=\"percentile of gene body (5'->3')\",ylab='read number',type='s')" +- print >>OUT1, "dev.off()" ++ print(str(i) + '\t' + str(coverage[i]), file=OUT2) ++ print("pdf(\'%s\')" % (outfile + ".geneBodyCoverage.pdf"), file=OUT1) ++ print("x=0:100", file=OUT1) ++ print("y=c(" + ','.join(y_coord) + ')', file=OUT1) ++ print("plot(x,y,xlab=\"percentile of gene body (5'->3')\",ylab='read number',type='s')", file=OUT1) ++ print("dev.off()", file=OUT1) + + def mRNA_inner_distance(self,outfile,refbed,low_bound=0,up_bound=1000,step=10): + '''estimate the inner distance of mRNA pair end fragment. fragment size = insert_size + 2 x read_length''' +@@ -3342,33 +3342,33 @@ class ParseBAM: + ranges={} + ranges[fchrom]=Intersecter() + +- window_left_bound = range(low_bound,up_bound,step) +- frag_size=0 ++ window_left_bound = list(range(low_bound,up_bound,step)) ++ frag_size=0 + + inner_distance_bitsets=BinnedBitSet() + tmp = BinnedBitSet() + tmp.set_range(0,0) +- pair_num=0.0 +- sizes=[] +- counts=[] +- count=0 +- +- print >>sys.stderr, "Get intron regions from " + refbed + " ..." +- bed_obj = BED.ParseBED(refbed) +- ref_exons = [] +- +- for exn in bed_obj.getExon(): +- ref_exons.append([exn[0].upper(), exn[1], exn[2]]) ++ pair_num=0.0 ++ sizes=[] ++ counts=[] ++ count=0 ++ ++ print("Get intron regions from " + refbed + " ...", file=sys.stderr) ++ bed_obj = BED.ParseBED(refbed) ++ ref_exons = [] ++ ++ for exn in bed_obj.getExon(): ++ ref_exons.append([exn[0].upper(), exn[1], exn[2]]) + exon_bitsets = binned_bitsets_from_list(ref_exons) + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): + splice_intron_size=0 + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -3430,28 +3430,28 @@ class ParseBAM: + ranges[fchrom].add_interval( Interval( inner_distance-1, inner_distance ) ) + + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + if pair_num==0: +- print >>sys.stderr, "Cannot find paired reads" ++ print("Cannot find paired reads", file=sys.stderr) + sys.exit(0) + #print >>FQ, "Total paired read " + str(pair_num) + for st in window_left_bound: + sizes.append(str(st + step/2)) + count = str(len(ranges[fchrom].find(st,st + step))) + counts.append(count) +- print >>FQ, str(st) + '\t' + str(st+step) +'\t' + count ++ print(str(st) + '\t' + str(st+step) +'\t' + count, file=FQ) + +- print >>RS, "pdf(\'%s\')" % (outfile + ".inner_distance_plot.pdf") ++ print("pdf(\'%s\')" % (outfile + ".inner_distance_plot.pdf"), file=RS) + #print >>RS, "par(mfrow=c(2,1),cex.main=0.8,cex.lab=0.8,cex.axis=0.8,mar=c(4,4,4,1))" + #print >>RS, 'pie(c(%d,%d,%d),col=rainbow(3),cex=0.5,radius=1,main="Total %d fragments",labels=c("fraSize <= %d\\n(%4.2f%%)","fragSize > %d\\n(%4.2f%%)","%d < fragSize <= %d\\n(%4.2f%%)"), density=rep(80,80,80),angle=c(90,140,170))' % (ultra_low, ultra_high, pair_num -ultra_low -ultra_high, pair_num, low_bound, ultra_low*100/pair_num, up_bound, ultra_high*100/pair_num, low_bound, up_bound, 100-ultra_low*100/pair_num - ultra_high*100/pair_num) +- print >>RS, 'fragsize=rep(c(' + ','.join(sizes) + '),' + 'times=c(' + ','.join(counts) + '))' +- print >>RS, 'frag_sd = round(sd(fragsize))' +- print >>RS, 'frag_mean = round(mean(fragsize))' +- print >>RS, 'hist(fragsize,probability=T,breaks=%d,xlab="mRNA insert size (bp)",main=paste(c("Mean=",frag_mean,";","SD=",frag_sd),collapse=""),border="blue")' % len(window_left_bound) +- print >>RS, "lines(density(fragsize,bw=%d),col='red')" % (2*step) +- print >>RS ,"dev.off()" ++ print('fragsize=rep(c(' + ','.join(sizes) + '),' + 'times=c(' + ','.join(counts) + '))', file=RS) ++ print('frag_sd = round(sd(fragsize))', file=RS) ++ print('frag_mean = round(mean(fragsize))', file=RS) ++ print('hist(fragsize,probability=T,breaks=%d,xlab="mRNA insert size (bp)",main=paste(c("Mean=",frag_mean,";","SD=",frag_sd),collapse=""),border="blue")' % len(window_left_bound), file=RS) ++ print("lines(density(fragsize,bw=%d),col='red')" % (2*step), file=RS) ++ print("dev.off()", file=RS) + FO.close() + FQ.close() + RS.close() +@@ -3465,7 +3465,7 @@ class ParseBAM: + out_file = outfile + ".junction.xls" + out_file2 = outfile + ".junction_plot.r" + if refgene is None: +- print >>sys.stderr, "You must provide reference gene model in bed format." ++ print("You must provide reference gene model in bed format.", file=sys.stderr) + sys.exit(1) + OUT = open(out_file,'w') + ROUT = open(out_file2,'w') +@@ -3479,13 +3479,13 @@ class ParseBAM: + known_junc =0 + splicing_events=collections.defaultdict(int) + +- print >>sys.stderr, "Reading reference bed file: ",refgene, " ... ", ++ print("Reading reference bed file: ",refgene, " ... ", end=' ', file=sys.stderr) + for line in open(refgene,'r'): + if line.startswith(('#','track','browser')):continue + # Parse fields from gene tabls + fields = line.split() + if(len(fields)<12): +- print >>sys.stderr, "Invalid bed line (skipped):",line, ++ print("Invalid bed line (skipped):",line, end=' ', file=sys.stderr) + continue + chrom = fields[0].upper() + tx_start = int( fields[1] ) +@@ -3493,25 +3493,25 @@ class ParseBAM: + if int(fields[9] ==1): + continue + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + intron_start = exon_ends[:-1] + intron_end=exon_starts[1:] + for i_st,i_end in zip (intron_start, intron_end): + refIntronStarts[chrom][i_st] =i_st + refIntronEnds[chrom][i_end] =i_end +- print >>sys.stderr,"Done" ++ print("Done", file=sys.stderr) + + #reading input SAM file +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + + try: + while(1): + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -3534,28 +3534,28 @@ class ParseBAM: + total_junc +=1 + if intrn[2] - intrn[1] < min_intron:continue + splicing_events[intrn[0] + ":" + str(intrn[1]) + ":" + str(intrn[2])] += 1 +- if (refIntronStarts[chrom].has_key(intrn[1]) and refIntronEnds[chrom].has_key(intrn[2])): ++ if (intrn[1] in refIntronStarts[chrom] and intrn[2] in refIntronEnds[chrom]): + known_junc +=1 #known both +- elif (not refIntronStarts[chrom].has_key(intrn[1]) and not refIntronEnds[chrom].has_key(intrn[2])): ++ elif (intrn[1] not in refIntronStarts[chrom] and intrn[2] not in refIntronEnds[chrom]): + novel35_junc +=1 + else: + novel3or5_junc +=1 + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print "total = " + str(total_junc) ++ print("total = " + str(total_junc)) + #self.f.seek(0) + +- print >>ROUT, 'pdf(\"%s\")' % (outfile + ".junction_plot.pdf") +- print >>ROUT, "events=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc)])+ ')' +- print >>ROUT, 'pie(events,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing events",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)) +- print >>ROUT, "dev.off()" ++ print('pdf(\"%s\")' % (outfile + ".junction_plot.pdf"), file=ROUT) ++ print("events=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc)])+ ')', file=ROUT) ++ print('pie(events,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing events",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)), file=ROUT) ++ print("dev.off()", file=ROUT) + +- print >>sys.stderr, "\n===================================================================" +- print >>sys.stderr, "Total splicing Events:\t" + str(total_junc) +- print >>sys.stderr, "Known Splicing Events:\t" + str(known_junc) +- print >>sys.stderr, "Partial Novel Splicing Events:\t" + str(novel3or5_junc) +- print >>sys.stderr, "Novel Splicing Events:\t" + str(novel35_junc) ++ print("\n===================================================================", file=sys.stderr) ++ print("Total splicing Events:\t" + str(total_junc), file=sys.stderr) ++ print("Known Splicing Events:\t" + str(known_junc), file=sys.stderr) ++ print("Partial Novel Splicing Events:\t" + str(novel3or5_junc), file=sys.stderr) ++ print("Novel Splicing Events:\t" + str(novel35_junc), file=sys.stderr) + + #reset variables + total_junc =0 +@@ -3563,36 +3563,36 @@ class ParseBAM: + novel3or5_junc =0 + known_junc =0 + +- print >>OUT, "chrom\tintron_st(0-based)\tintron_end(1-based)\tread_count\tannotation" ++ print("chrom\tintron_st(0-based)\tintron_end(1-based)\tread_count\tannotation", file=OUT) + for i in splicing_events: + total_junc += 1 + (chrom, i_st, i_end) = i.split(":") +- print >>OUT, '\t'.join([chrom.replace("CHR","chr"),i_st,i_end]) + '\t' + str(splicing_events[i]) + '\t', ++ print('\t'.join([chrom.replace("CHR","chr"),i_st,i_end]) + '\t' + str(splicing_events[i]) + '\t', end=' ', file=OUT) + i_st = int(i_st) + i_end = int(i_end) +- if (refIntronStarts[chrom].has_key(i_st) and refIntronEnds[chrom].has_key(i_end)): +- print >>OUT, "annotated" ++ if (i_st in refIntronStarts[chrom] and i_end in refIntronEnds[chrom]): ++ print("annotated", file=OUT) + known_junc +=1 +- elif (not refIntronStarts[chrom].has_key(i_st) and not refIntronEnds[chrom].has_key(i_end)): +- print >>OUT, 'complete_novel' ++ elif (i_st not in refIntronStarts[chrom] and i_end not in refIntronEnds[chrom]): ++ print('complete_novel', file=OUT) + novel35_junc +=1 + else: +- print >>OUT, 'partial_novel' ++ print('partial_novel', file=OUT) + novel3or5_junc +=1 + + if total_junc ==0: +- print >>sys.stderr, "No splice read found" ++ print("No splice read found", file=sys.stderr) + sys.exit(1) +- print >>sys.stderr, "\nTotal splicing Junctions:\t" + str(total_junc) +- print >>sys.stderr, "Known Splicing Junctions:\t" + str(known_junc) +- print >>sys.stderr, "Partial Novel Splicing Junctions:\t" + str(novel3or5_junc) +- print >>sys.stderr, "Novel Splicing Junctions:\t" + str(novel35_junc) +- print >>sys.stderr, "\n===================================================================" ++ print("\nTotal splicing Junctions:\t" + str(total_junc), file=sys.stderr) ++ print("Known Splicing Junctions:\t" + str(known_junc), file=sys.stderr) ++ print("Partial Novel Splicing Junctions:\t" + str(novel3or5_junc), file=sys.stderr) ++ print("Novel Splicing Junctions:\t" + str(novel35_junc), file=sys.stderr) ++ print("\n===================================================================", file=sys.stderr) + +- print >>ROUT, 'pdf("splicing_junction_pie.pdf")' +- print >>ROUT, "junction=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc,)])+ ')' +- print >>ROUT, 'pie(junction,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing junctions",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)) +- print >>ROUT, "dev.off()" ++ print('pdf("splicing_junction_pie.pdf")', file=ROUT) ++ print("junction=c(" + ','.join([str(i*100.0/total_junc) for i in (novel3or5_junc,novel35_junc,known_junc,)])+ ')', file=ROUT) ++ print('pie(junction,col=c(2,3,4),init.angle=30,angle=c(60,120,150),density=c(70,70,70),main="splicing junctions",labels=c("partial_novel %d%%","complete_novel %d%%","known %d%%"))' % (round(novel3or5_junc*100.0/total_junc),round(novel35_junc*100.0/total_junc),round(known_junc*100.0/total_junc)), file=ROUT) ++ print("dev.off()", file=ROUT) + #print >>ROUT, "mat=matrix(c(events,junction),byrow=T,ncol=3)" + #print >>ROUT, 'barplot(mat,beside=T,ylim=c(0,100),names=c("known","partial\nnovel","complete\nnovel"),legend.text=c("splicing events","splicing junction"),ylab="Percent")' + +@@ -3601,7 +3601,7 @@ class ParseBAM: + + out_file = outfile + ".junctionSaturation_plot.r" + if refgene is None: +- print >>sys.stderr, "You must provide reference gene model in bed format." ++ print("You must provide reference gene model in bed format.", file=sys.stderr) + sys.exit(1) + + OUT = open(out_file,'w') +@@ -3609,12 +3609,12 @@ class ParseBAM: + + #reading reference gene + knownSpliceSites= set() +- print >>sys.stderr, "reading reference bed file: ",refgene, " ... ", ++ print("reading reference bed file: ",refgene, " ... ", end=' ', file=sys.stderr) + for line in open(refgene,'r'): + if line.startswith(('#','track','browser')):continue + fields = line.split() + if(len(fields)<12): +- print >>sys.stderr, "Invalid bed line (skipped):",line, ++ print("Invalid bed line (skipped):",line, end=' ', file=sys.stderr) + continue + chrom = fields[0].upper() + tx_start = int( fields[1] ) +@@ -3622,15 +3622,15 @@ class ParseBAM: + if int(fields[9] ==1): + continue + +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends); ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)); + intron_start = exon_ends[:-1] + intron_end=exon_starts[1:] + for st,end in zip (intron_start, intron_end): + knownSpliceSites.add(chrom + ":" + str(st) + "-" + str(end)) +- print >>sys.stderr,"Done! Total "+str(len(knownSpliceSites)) + " known splicing junctions." ++ print("Done! Total "+str(len(knownSpliceSites)) + " known splicing junctions.", file=sys.stderr) + + + #read SAM file +@@ -3639,12 +3639,12 @@ class ParseBAM: + intron_end=[] + uniqSpliceSites=collections.defaultdict(int) + +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + try: + while(1): + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -3667,11 +3667,11 @@ class ParseBAM: + if intrn[2] - intrn[1] < min_intron:continue + samSpliceSites.append(intrn[0] + ":" + str(intrn[1]) + "-" + str(intrn[2])) + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + +- print >>sys.stderr, "shuffling alignments ...", ++ print("shuffling alignments ...", end=' ', file=sys.stderr) + random.shuffle(samSpliceSites) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + #resampling + SR_num = len(samSpliceSites) +@@ -3681,7 +3681,7 @@ class ParseBAM: + all_junc=[] + unknown_junc=[] + #=========================sampling uniquely mapped reads from population +- tmp=range(sample_start,sample_end,sample_step) ++ tmp=list(range(sample_start,sample_end,sample_step)) + tmp.append(100) + for pertl in tmp: #[5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95,100] + knownSpliceSites_num = 0 +@@ -3690,21 +3690,21 @@ class ParseBAM: + if index_st < 0: index_st = 0 + sample_size += index_end -index_st + +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(sample_size) + ") splicing reads.", ++ print("sampling " + str(pertl) +"% (" + str(sample_size) + ") splicing reads.", end=' ', file=sys.stderr) + + #all splice juntion + for i in range(index_st, index_end): + uniqSpliceSites[samSpliceSites[i]] +=1 +- all_junctionNum = len(uniqSpliceSites.keys()) ++ all_junctionNum = len(list(uniqSpliceSites.keys())) + all_junc.append(str(all_junctionNum)) +- print >>sys.stderr, str(all_junctionNum) + " splicing junctions.", ++ print(str(all_junctionNum) + " splicing junctions.", end=' ', file=sys.stderr) + + #known splice junction + known_junctionNum = 0 + for sj in uniqSpliceSites: + if sj in knownSpliceSites and uniqSpliceSites[sj] >= recur: + known_junctionNum +=1 +- print >>sys.stderr, str(known_junctionNum) + " known splicing junctions.", ++ print(str(known_junctionNum) + " known splicing junctions.", end=' ', file=sys.stderr) + known_junc.append(str(known_junctionNum)) + + #unknown splice junction +@@ -3713,28 +3713,28 @@ class ParseBAM: + if sj not in knownSpliceSites: + unknown_junctionNum +=1 + unknown_junc.append(str(unknown_junctionNum)) +- print >>sys.stderr, str(unknown_junctionNum) + " novel splicing junctions." ++ print(str(unknown_junctionNum) + " novel splicing junctions.", file=sys.stderr) + + #for j in uniq_SJ: + #print >>OUT, j + "\t" + str(uniq_SJ[j]) +- print >>OUT, "pdf(\'%s\')" % (outfile + '.junctionSaturation_plot.pdf') +- print >>OUT, "x=c(" + ','.join([str(i) for i in tmp]) + ')' +- print >>OUT, "y=c(" + ','.join(known_junc) + ')' +- print >>OUT, "z=c(" + ','.join(all_junc) + ')' +- print >>OUT, "w=c(" + ','.join(unknown_junc) + ')' +- print >>OUT, "m=max(%d,%d,%d)" % (int(int(known_junc[-1])/1000), int(int(all_junc[-1])/1000),int(int(unknown_junc[-1])/1000)) +- print >>OUT, "n=min(%d,%d,%d)" % (int(int(known_junc[0])/1000), int(int(all_junc[0])/1000),int(int(unknown_junc[0])/1000)) +- print >>OUT, "plot(x,z/1000,xlab='percent of total reads',ylab='Number of splicing junctions (x1000)',type='o',col='blue',ylim=c(n,m))" +- print >>OUT, "points(x,y/1000,type='o',col='red')" +- print >>OUT, "points(x,w/1000,type='o',col='green')" +- print >>OUT, 'legend(5,%d, legend=c("All junctions","known junctions", "novel junctions"),col=c("blue","red","green"),lwd=1,pch=1)' % int(int(all_junc[-1])/1000) +- print >>OUT, "dev.off()" ++ print("pdf(\'%s\')" % (outfile + '.junctionSaturation_plot.pdf'), file=OUT) ++ print("x=c(" + ','.join([str(i) for i in tmp]) + ')', file=OUT) ++ print("y=c(" + ','.join(known_junc) + ')', file=OUT) ++ print("z=c(" + ','.join(all_junc) + ')', file=OUT) ++ print("w=c(" + ','.join(unknown_junc) + ')', file=OUT) ++ print("m=max(%d,%d,%d)" % (int(int(known_junc[-1])/1000), int(int(all_junc[-1])/1000),int(int(unknown_junc[-1])/1000)), file=OUT) ++ print("n=min(%d,%d,%d)" % (int(int(known_junc[0])/1000), int(int(all_junc[0])/1000),int(int(unknown_junc[0])/1000)), file=OUT) ++ print("plot(x,z/1000,xlab='percent of total reads',ylab='Number of splicing junctions (x1000)',type='o',col='blue',ylim=c(n,m))", file=OUT) ++ print("points(x,y/1000,type='o',col='red')", file=OUT) ++ print("points(x,w/1000,type='o',col='green')", file=OUT) ++ print('legend(5,%d, legend=c("All junctions","known junctions", "novel junctions"),col=c("blue","red","green"),lwd=1,pch=1)' % int(int(all_junc[-1])/1000), file=OUT) ++ print("dev.off()", file=OUT) + + def saturation_RPKM(self,refbed,outfile,sample_start=5,sample_step=5,sample_end=100,skip_multi=True, strand_rule=None): + '''for each gene, check if its RPKM (epxresion level) has already been saturated or not''' + + if refbed is None: +- print >>sys.stderr,"You must specify a bed file representing gene model\n" ++ print("You must specify a bed file representing gene model\n", file=sys.stderr) + exit(0) + rpkm_file = outfile + ".eRPKM.xls" + raw_file = outfile + ".rawCount.xls" +@@ -3759,17 +3759,17 @@ class ParseBAM: + elif len(strand_rule.split(',')) ==2: #singeEnd, strand-specific + for i in strand_rule.split(','):strandRule[i[0]]=i[1] + else: +- print >>sys.stderr, "Unknown value of: 'strand_rule' " + strand_rule ++ print("Unknown value of: 'strand_rule' " + strand_rule, file=sys.stderr) + sys.exit(1) + + + #read SAM or BAM +- if self.bam_format:print >>sys.stderr, "Load BAM file ... ", +- else:print >>sys.stderr, "Load SAM file ... ", ++ if self.bam_format:print("Load BAM file ... ", end=' ', file=sys.stderr) ++ else:print("Load SAM file ... ", end=' ', file=sys.stderr) + try: + while(1): + flag=0 +- aligned_read = self.samfile.next() ++ aligned_read = next(self.samfile) + if aligned_read.is_qcfail:continue #skip low quanlity + if aligned_read.is_duplicate:continue #skip duplicate read + if aligned_read.is_secondary:continue #skip non primary hit +@@ -3812,14 +3812,14 @@ class ParseBAM: + for exn in exon_blocks: + block_list.append(exn[0] + ":" + str(exn[1] + (exn[2]-exn[1])/2 )) + except StopIteration: +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + +- print >>sys.stderr, "shuffling alignments ...", ++ print("shuffling alignments ...", end=' ', file=sys.stderr) + random.shuffle(block_list_plus) + random.shuffle(block_list_minus) + random.shuffle(block_list) +- print >>sys.stderr, "Done" ++ print("Done", file=sys.stderr) + + + ranges_plus={} +@@ -3830,7 +3830,7 @@ class ParseBAM: + rawCount_table=collections.defaultdict(list) + RPKM_head=['#chr','start','end','name','score','strand'] + +- tmp=range(sample_start,sample_end,sample_step) ++ tmp=list(range(sample_start,sample_end,sample_step)) + tmp.append(100) + #=========================sampling uniquely mapped reads from population + for pertl in tmp: #[5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95,100] +@@ -3841,27 +3841,27 @@ class ParseBAM: + RPKM_head.append(str(pertl) + '%') + + if strand_rule is not None: +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(int(cUR_plus * percent_end)) + ") forward strand fragments ..." ++ print("sampling " + str(pertl) +"% (" + str(int(cUR_plus * percent_end)) + ") forward strand fragments ...", file=sys.stderr) + for i in block_list_plus[int(cUR_plus*percent_st):int(cUR_plus*percent_end)]: + (chr,coord) = i.split(':') + if chr not in ranges_plus:ranges_plus[chr] = Intersecter() + else:ranges_plus[chr].add_interval( Interval( int(coord), int(coord)+1 ) ) + +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(int(cUR_minus * percent_end)) + ") reverse strand fragments ..." ++ print("sampling " + str(pertl) +"% (" + str(int(cUR_minus * percent_end)) + ") reverse strand fragments ...", file=sys.stderr) + for i in block_list_minus[int(cUR_minus*percent_st):int(cUR_minus*percent_end)]: + (chr,coord) = i.split(':') + if chr not in ranges_minus:ranges_minus[chr] = Intersecter() + else:ranges_minus[chr].add_interval( Interval( int(coord), int(coord)+1 ) ) + + else: +- print >>sys.stderr, "sampling " + str(pertl) +"% (" + str(int(sample_size)) + ") fragments ..." ++ print("sampling " + str(pertl) +"% (" + str(int(sample_size)) + ") fragments ...", file=sys.stderr) + for i in block_list[int(cUR_num*percent_st):int(cUR_num*percent_end)]: + (chr,coord) = i.split(':') + if chr not in ranges:ranges[chr] = Intersecter() + else:ranges[chr].add_interval( Interval( int(coord), int(coord)+1 ) ) + + #========================= calculating RPKM based on sub-population +- print >>sys.stderr, "assign reads to transcripts in " + refbed + ' ...' ++ print("assign reads to transcripts in " + refbed + ' ...', file=sys.stderr) + for line in open(refbed,'r'): + try: + if line.startswith(('#','track','browser')):continue +@@ -3872,14 +3872,14 @@ class ParseBAM: + tx_end = int( fields[2] ) + geneName = fields[3] + strand = fields[5] +- exon_starts = map( int, fields[11].rstrip( ',\n' ).split( ',' ) ) +- exon_starts = map((lambda x: x + tx_start ), exon_starts) +- exon_ends = map( int, fields[10].rstrip( ',\n' ).split( ',' ) ) +- exon_ends = map((lambda x, y: x + y ), exon_starts, exon_ends) +- exon_sizes = map(int,fields[10].rstrip(',\n').split(',')) ++ exon_starts = list(map( int, fields[11].rstrip( ',\n' ).split( ',' ) )) ++ exon_starts = list(map((lambda x: x + tx_start ), exon_starts)) ++ exon_ends = list(map( int, fields[10].rstrip( ',\n' ).split( ',' ) )) ++ exon_ends = list(map((lambda x, y: x + y ), exon_starts, exon_ends)) ++ exon_sizes = list(map(int,fields[10].rstrip(',\n').split(','))) + key='\t'.join((chrom.lower(),str(tx_start),str(tx_end),geneName,'0',strand)) + except: +- print >>sys.stderr,"[NOTE:input bed must be 12-column] skipped this line: " + line ++ print("[NOTE:input bed must be 12-column] skipped this line: " + line, file=sys.stderr) + continue + mRNA_count=0 #we need to initializ it to 0 for each gene + mRNA_len=sum(exon_sizes) +@@ -3892,24 +3892,24 @@ class ParseBAM: + if chrom in ranges: + mRNA_count += len(ranges[chrom].find(st,end)) + if mRNA_len ==0: +- print >>sys.stderr, geneName + " has 0 nucleotides. Exit!" ++ print(geneName + " has 0 nucleotides. Exit!", file=sys.stderr) + sys.exit(1) + if sample_size == 0: +- print >>sys.stderr, "Too few reads to sample. Exit!" ++ print("Too few reads to sample. Exit!", file=sys.stderr) + sys.exit(1) + mRNA_RPKM = (mRNA_count * 1000000000.0)/(mRNA_len * sample_size) + RPKM_table[key].append(str(mRNA_RPKM)) + rawCount_table[key].append(str(mRNA_count)) +- print >>sys.stderr, "" ++ print("", file=sys.stderr) + + #self.f.seek(0) +- print >>RPKM_OUT, '\t'.join(RPKM_head) +- print >>RAW_OUT, '\t'.join(RPKM_head) ++ print('\t'.join(RPKM_head), file=RPKM_OUT) ++ print('\t'.join(RPKM_head), file=RAW_OUT) + for key in RPKM_table: +- print >>RPKM_OUT, key + '\t', +- print >>RPKM_OUT, '\t'.join(RPKM_table[key]) +- print >>RAW_OUT, key + '\t', +- print >>RAW_OUT, '\t'.join(rawCount_table[key]) ++ print(key + '\t', end=' ', file=RPKM_OUT) ++ print('\t'.join(RPKM_table[key]), file=RPKM_OUT) ++ print(key + '\t', end=' ', file=RAW_OUT) ++ print('\t'.join(rawCount_table[key]), file=RAW_OUT) + + def fetchAlignments(self,chr,st,end): + '''fetch alignment from sorted BAM file based on chr, st, end +@@ -3927,4 +3927,4 @@ def print_bits_as_bed( bits ): + start = bits.next_set( end ) + if start == bits.size: break + end = bits.next_clear( start ) +- print "%d\t%d" % ( start, end ) ++ print("%d\t%d" % ( start, end )) -- cgit v1.2.3