diff microsatellite.py @ 0:20ab85af9505

Uploaded
author arkarachai-fungtammasan
date Fri, 03 Oct 2014 20:54:30 -0400
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children
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--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/microsatellite.py	Fri Oct 03 20:54:30 2014 -0400
@@ -0,0 +1,1271 @@
+#!/usr/bin/env python
+"""
+Snoop thru a fasta file looking for microsatellite repeats of given periods
+Output format: length_of_repeat left_flank_length right_flank_length  repeat_motif  hamming_distance  read_name read_sequence read_quality  (additional columns)
+
+If --r option turned on, output format will have additional columns behind:
+read_name read_chr  pre_s pre_e tr_s  tr_e  suf_s suf_e tr_len  tr_ref_seq
+
+pre_s           where the read start
+pre_e           the last position before microsatellite
+tr_s            where microsatellite start
+tr_e            where microsatellite end
+suf_s           first base after microsatellite
+tr_ref_seq      reference sequence corresponding to microsatellite
+
+* output positions are 0 based
+
+:Author: Chen Sun (cxs1031@cse.psu.edu); Bob Harris (rsharris@bx.psu.edu)
+          
+modifing log:
+
+09/27/2013
+replace function dense_intervals with function non_negative_intervals, which do not need to import such file.
+
+10/18/2013
+modify function find_repeat_element to get a quick speed, under the condition that hamming_distance = 0, which means do not allowed any mutation/indel
+
+02/25/2014
+add function that can deal with mapped reads
+with additional output
+
+02/28/2014
+modify the 0-based end point, as in 0-base area, it is half-open [ )
+so the 0-based site, should always be added by 1
+
+03/05/2014
+deal with multi-fasta
+"""
+from sys          import argv,stdin,stderr,exit
+from string       import maketrans
+from md5          import new as md5_new
+import re
+#from pyfracluster import dense_intervals
+
+def usage(s=None):
+    message = """
+usage: microsat_snoop [fasta_file] [options]
+  <fasta_file>                Name of file to read sequences from;  if absent,
+                              sequences are read from stdin
+  --fasta                     Input file is in fasta format
+                              (this is the default)
+  --fastq                     Input file is in fastq format
+                              (default is fasta unless filename is .fastq)
+  --fastq:noquals             Input file is in fastq format, but discard quals
+  --sam                       Input file is SAM file 
+  --r                         Indicate additional output information, if indicated,
+                              --ref option is mendatory
+  --ref=<filepath>            Reference file (absolute) path
+  --period=<length>           (mandatory,cumulative) repeat length(s) to be
+                              searched for
+                              <length> is expected to be small, less than 10
+                              <length> can also be a comma-separated list, or
+                              a range <low>..<high>
+  --rate=<fraction>           control the candidate repeat interval detector;
+                              it will consider intervals with at least
+                              <fraction> of matches when shifted by the period;
+                              <fraction> is between 0 and 1 and can be either a
+                              real number or <n>/<d>
+                              (default is 6/7)
+  --minlength=<length>        minimum length of intervals reported, in bp
+                              (default is 20)
+  --progress=<count>          how often to report the sequence we're searching
+                              (default is no progress report)
+  --allowduplicates           process all input sequences
+                              (this is the default)
+  --noduplicates              ignore any input sequence that's the same as an
+                              earlier sequence
+  --nonearduplicates          ignore any input sequence that has the same first
+                              100 bp as an earlier sequence
+  --nonearduplicate=<length>  ignore any input sequence that has the same first
+                              <length> bp as an earlier sequence
+  --hamming=<count>           Don't report candidate repeat intervals that have
+                              more than <count> mismatches
+                              (default is to do no such filtering)
+  --prefix=<length>           Don't report candidate repeat intervals that
+                              start within <length> of the sequence start
+                              (default is to do no such filtering)
+  --suffix=<length>           Don't report candidate repeat intervals that
+                              end within <length> of the sequence end
+                              (default is to do no such filtering)
+  --subsample=<k>/<n>         Process only the <k>th sequence of every group of
+                              <n> sequences;  <k> ranges from 1 to <n>
+  --multipleruns              Consider all candidate intervals in a sequence
+                              (default is to consider only the longest)
+  --partialmotifs             Consider microatelites with a partial motif
+                              (default is to consider only whole motifs)
+  --splitbyvalidity           Preprocess sequences, splitting at Ns;  this
+                              prevents candidates from including Ns
+                              (default is not to split)
+  --noflankdisplay            Show entire sequence as flanking regions
+                              (this is the default)
+  --flankdisplay=<length>     Limit length of flanking regions shown
+  --readnamesuffix=<string>   Root of suffix to append to read names;  e.g. 1
+                              for forward, 2 for reverse;  this triggers other
+                              info to be included in the suffix
+                              (default is "1" for fastq;  no suffix for fasta)
+  --head=<number>             limit the number of sequences processed
+  --markend                   Write a marker line upon completion
+                              (default is not to write a marker)
+  --help=details              Describe the process, and quit"""
+
+    if (s == None): exit (message)
+    else:           exit ("%s\n%s" % (s,message))
+
+
+detailedDescription = """In broad terms, the process works as follows:
+
+(1) Identify intervals that are highly correlated with the interval shifted by
+    P (the repeat period).  These intervals are called "runs" or "candidates".
+    The level of correlation required is controlled by rateThreshold. 
+    Depending on whether we want to look for more than one microsat, we either
+    find the longest such run (simple algorithm) or many runs (more complicated
+    algorithm). The following steps are then performed on each run.
+
+(2) Find the most likely repeat motif in the run.  This is done by counting
+    all kmers (of length P) and choosing the most frequent.  If that kmer is
+    itself covered by a sub-repeat we discard this run.  The idea is that we
+    can ignore a 6-mer like ACGACG because we will find it when we are looking
+    for 3-mers.
+
+(3) Once we identify the most likely repeat motif, we then modify the
+    interval, adjusting start and end to find the interval that has the fewest
+    mismatches vs. a sequence of the motif repeated (hamming distance).  Only
+    whole copies of the motif are considered.
+
+(4) At this point we have a valid microsat interval (in the eyes of the
+    program). It is subjected to some filtering stages (hamming distance or too
+    close to an end), and if it satisfies those conditions, it's reported to
+    the user."""
+
+def main():
+    global debug
+
+    #=== parse the command line ===
+
+    inputFilename         = None
+    referenceFileName     = None #add by Chen Sun on 02/25
+    inputFormat           = None
+    repeatPeriods         = []
+    rateThreshold         = 6 / 7.0
+    lengthThreshold       = 20
+    reportProgress        = None
+    discardDuplicates     = False
+    discardNearDuplicates = False
+    nearDuplicatePrefix   = 100
+    hammingThreshold      = 0
+    prefixThreshold       = None
+    suffixThreshold       = None
+    subsampleK            = None
+    subsampleN            = None
+    reportMultipleRuns    = False
+    allowPartialMotifs    = False
+    splitByValidity       = False
+    flankDisplayLimit     = None
+    readNameSuffix        = None
+    headLimit             = None
+    markEndOfFile         = False
+    additionalInfo        = False
+    debug                 = []
+
+    for arg in argv[1:]:
+        if (arg == "--fasta"):
+            inputFormat = "fasta"
+        elif (arg == "--fastq"):
+            inputFormat = "fastq"
+        elif (arg == "--fastq:noquals"):
+            inputFormat = "fastq:noquals"
+        elif (arg == "--sam"):
+            inputFormat = "sam"
+        elif (arg == "--r"):
+            additionalInfo = True
+        elif (arg.startswith("--ref=")):
+            referenceFileName = arg.split("=",1)[1]
+        elif (arg.startswith("--period=")):
+            val = arg.split("=",1)[1]
+            for period in val.split(","):
+                if (".." in period):
+                    (lowPeriod,highPeriod) = period.split("..",1)
+                    lowPeriod  = int(lowPeriod)
+                    highPeriod = int(highPeriod)
+                    for period in xrange(lowPeriod,highPeriod+1):
+                        repeatPeriods += [period]
+                else:
+                    repeatPeriods += [int(period)]
+        elif (arg.startswith("--rate=")):
+            val = arg.split("=",1)[1]
+            rateThreshold = float_or_fraction(val)
+            assert (0.0 < rateThreshold <= 1.0), "%s not a valid rate" % val
+        elif (arg.startswith("--minlength=")):
+            val = arg.split("=",1)[1]
+            lengthThreshold = int(val)
+            assert (lengthThreshold >= 0)
+        elif (arg.startswith("--progress=")):
+            val = arg.split("=",1)[1]
+            reportProgress = int(val)
+        elif (arg == "--allowduplicates"):
+            discardDuplicates     = False
+            discardNearDuplicates = False
+        elif (arg == "--noduplicates"):
+            discardDuplicates     = True
+            discardNearDuplicates = False
+        elif (arg == "--nonearduplicates"):
+            discardDuplicates     = False
+            discardNearDuplicates = True
+        elif (arg.startswith("--nonearduplicate=")):
+            val = arg.split("=",1)[1]
+            discardDuplicates     = False
+            discardNearDuplicates = True
+            nearDuplicatePrefix   = int(val)
+            assert (nearDuplicatePrefix > 0)
+        elif (arg.startswith("--hamming=")):
+            val = arg.split("=",1)[1]
+            hammingThreshold = int(val)
+            assert (hammingThreshold >= 0)
+        elif (arg.startswith("--prefix=")):
+            val = arg.split("=",1)[1]
+            prefixThreshold = int(val)
+            assert (prefixThreshold >= 0)
+        elif (arg.startswith("--suffix=")):
+            val = arg.split("=",1)[1]
+            suffixThreshold = int(val)
+            assert (suffixThreshold >= 0)
+        elif (arg.startswith("--subsample=")):
+            val = arg.split("=",1)[1]
+            (k,n) = val.split("/",2)
+            subsampleK = int(k)
+            subsampleN = int(n)
+            assert (0 < subsampleK <= subsampleN)
+        elif (arg == "--multipleruns"):
+            reportMultipleRuns = True
+        elif (arg == "--partialmotifs"):
+            allowPartialMotifs = True
+        elif (arg == "--splitbyvalidity"):
+            splitByValidity = True
+        elif (arg == "--noflankdisplay"):
+            flankDisplayLimit = None
+        elif (arg.startswith("--flankdisplay=")):
+            val = arg.split("=",1)[1]
+            flankDisplayLimit = int(val)
+            assert (flankDisplayLimit >= 0)
+        elif (arg.startswith("--readnamesuffix")):
+            readNameSuffix = arg.split("=",1)[1]
+        elif (arg.startswith("--head=")):
+            headLimit = int_with_unit(arg.split("=",1)[1])
+        elif (arg == "--markend"):
+            markEndOfFile = True
+        elif (arg == "--help=details"):
+            exit (detailedDescription)
+        elif (arg.startswith("--debug=")):
+            debug += (arg.split("=",1)[1]).split(",")
+        elif (arg.startswith("--")):
+            usage("unrecognized option: %s" % arg)
+        elif (inputFilename == None):
+            inputFilename = arg
+        else:
+            usage("unrecognized option: %s" % arg)
+
+    #=== determine periods of interest ===
+
+    if (repeatPeriods == []):
+        usage("you gotta give me a repeat period")
+
+    if (additionalInfo == True):
+        if (referenceFileName == None):
+            usage("reference file path needed. use --ref=<reference> to indicate")
+
+    periodSeed = {}
+    for period in repeatPeriods:
+        if (period < 1): usage("period %d is not valid" % period)
+        periodSeed[period] = True
+
+    repeatPeriods = [period for period in periodSeed]
+    repeatPeriods.sort()
+
+    #=== determine input format ===
+
+    if   (inputFormat == "fasta"):           sequence_reader = fasta_sequences
+    elif (inputFormat == "fastq"):           sequence_reader = fastq_sequences
+    elif (inputFormat == "fastq:noquals"):   sequence_reader = fastq_sequences
+    elif (inputFormat == "sam"):             sequence_reader = sam_sequences
+    elif (inputFilename == None):            sequence_reader = fasta_sequences
+    elif (inputFilename.endswith(".fastq")): sequence_reader = fastq_sequences
+    elif (inputFilename.endswith(".fq")):    sequence_reader = fastq_sequences
+    elif (inputFilename.endswith(".sam")):   sequence_reader = sam_sequences
+    else:                                    sequence_reader = fasta_sequences
+
+    if (inputFilename != None): inputF = file(inputFilename,"rt")
+    else:                       inputF = stdin
+
+    if   (readNameSuffix == None) \
+     and (sequence_reader == fastq_sequences) \
+     and (inputFormat != "fastq:noquals"):
+        readNameSuffix = "1"
+
+    #=== process the sequences ===
+    
+    refSequence = {}
+    rightName = ""
+    sequence = ""
+    if additionalInfo:
+        firstFasta = True
+        originalRefF = open(referenceFileName)
+        for line in originalRefF.readlines():
+            line = line.replace('\r','')
+            line = line.replace('\n','')
+            if line.startswith(">"):
+                if firstFasta:
+                    firstFasta = False
+                else:
+                    refSequence[rightName] = sequence
+                rightName = line[1:]
+                sequence = ""
+                continue
+            sequence += line
+        originalRefF.close()
+        refSequence[rightName] = sequence
+
+    sequenceSeen = {}
+
+    numSequences = 0
+    for seqInfo in sequence_reader(inputF):
+        numSequences += 1
+        if (headLimit != None) and (numSequences > headLimit):
+            print >>stderr, "limit of %d sequences reached" % headLimit
+            break
+
+        if (sequence_reader == sam_sequences):
+            #seqName,"".join(seqNucs).upper().translate(nonDnaMap), refName, pre_s, cigar
+            (name, sequence, refName, pre_s, cigar) = seqInfo
+            quals = None
+        elif (sequence_reader == fastq_sequences):
+            (name,sequence,quals) = seqInfo
+            if (inputFormat == "fastq:noquals"): quals = None
+        else:
+            (name,sequence) = seqInfo
+            quals = None
+
+        if (reportProgress != None) and (numSequences % reportProgress == 0):
+            print >>stderr, "%s %d" % (name,numSequences)
+
+        # if we're subsampling and not interested in this sequence, skip it
+
+        if (subsampleN != None):
+            if ((numSequences-1) % subsampleN != (subsampleK-1)):
+                continue
+
+        # if this sequence is shorter than the length of interest, skip it
+
+        seqLen = len(sequence)
+        if (seqLen < period) or (seqLen < lengthThreshold): continue
+
+        # if we're not interested in duplicates and this is one, skip it;
+        # note that we assume no hash collisions occur, i.e. that all hash
+        # matches are truly sequence matches
+
+        if (discardDuplicates):
+            h = hash108(sequence)
+            if (h in sequenceSeen): continue
+            sequenceSeen[h] = True
+        elif (discardNearDuplicates):
+            h = hash108(sequence[:nearDuplicatePrefix])
+            if (h in sequenceSeen): continue
+            sequenceSeen[h] = True
+
+        # split the sequence into chunks of valid nucleotides
+
+        if (splitByValidity):
+            chunks = [(start,end) for (start,end) in nucleotide_runs(sequence)]
+        else:
+            chunks = [(0,len(sequence))]
+
+        # evaluate for each period of interest
+
+        for period in repeatPeriods:
+
+            # operate on each chunk
+
+            for (chunkStart,chunkEnd) in chunks:
+                chunkLen = chunkEnd - chunkStart
+                if (chunkLen < period) or (chunkLen < lengthThreshold): continue
+
+                if ("validity" in debug) or ("correlation" in debug) or ("runs" in debug):
+                    print >>stderr, ">%s_%d_%d" % (name,chunkStart,chunkEnd)
+
+                # compute correlation sequence
+
+                corr = correlation_sequence(sequence,period,chunkStart,chunkEnd)
+
+                if ("correlation" in debug) or ("runs" in debug):
+                    print >>stderr, sequence[chunkStart:chunkEnd]
+                    print >>stderr, corr
+
+                # find runs (candidates for being a microsat) 
+
+                if (reportMultipleRuns):
+                    runs = all_suitable_runs(corr,lengthThreshold-period,rateThreshold, hammingThreshold)
+                else:
+                    runs = longest_suitable_run(corr,lengthThreshold,rateThreshold)
+                if (runs == []): continue
+
+
+                if ("runs" in debug):
+                    for (start,end) in runs:
+                        run = [" "] * seqLen
+                        for ix in xrange(start-period,end):
+                            run[ix] = "*"
+                        print >>stderr, "".join(run)
+
+                if ("candidates" in debug):
+                    for (start,end) in runs:
+                        print >>stderr, "%s %d %d" % (name,start,end)
+
+                # process runs and report those that pass muster
+
+                runCount = 0
+                for (start,end) in runs:
+                    runCount += 1
+
+                    start = chunkStart + start - period
+                    end   = chunkStart + end
+
+                    (kmer,d,start,end) = find_repeat_element(hammingThreshold, period,sequence,start,end,allowPartials=allowPartialMotifs)
+                    if (kmer == None): continue    # (no useful repeat kmer was found)
+
+                    rptExtent = end - start
+                    prefixLen = start
+                    suffixLen = seqLen - end
+                    if (rptExtent <= period): continue
+                    if (hammingThreshold != None) and (d         > hammingThreshold): continue
+                    if (prefixThreshold  != None) and (prefixLen < prefixThreshold):  continue
+                    if (suffixThreshold  != None) and (suffixLen < suffixThreshold):  continue
+
+                    if (flankDisplayLimit == None):
+                        seq = sequence[:start] \
+                            + sequence[start:end].lower() \
+                            + sequence[end:]
+                    else:
+                        seq = sequence[max(chunkStart,start-flankDisplayLimit):start] \
+                            + sequence[start:end].lower() \
+                            + sequence[end:min(chunkEnd,end+flankDisplayLimit)]
+                    reportName = name
+                    if (readNameSuffix != None):
+                        reportName += "_"+readNameSuffix+"_per"+str(period)+"_"+str(runCount)
+                    if (quals == None or quals == "." or quals == "\t."): quals = "\t."
+                    else:               quals = "\t" + quals
+                    if not additionalInfo:
+                        print "%d\t%d\t%d\t%s\t%d\t%s\t%s%s" \
+                            % (rptExtent,prefixLen,suffixLen,kmer,d,reportName,seq,quals)
+                    else:
+                        #pre_e = pre_s + prefixLen - 1
+                        refPoint = pre_s
+                        donorPoint = 0
+                        
+                        donorBeforeStart = prefixLen - 1 #pre_e
+                        donorMicroStart = prefixLen     #tr_s
+                        donorMicroEnd = donorMicroStart + rptExtent - 1 #tr_e
+                        donorAfterMicro = donorMicroEnd + 1 #suf_s
+                        donorEnd = len(seq) - 1    #suf_e
+                        
+                        set_pre_e = False
+                        set_tr_s = False
+                        set_tr_e = False
+                        set_suf_s = False
+                        set_suf_e = False
+                        
+                        pre_e = 0
+                        tr_s = 0
+                        tr_e = 0
+                        suf_s = 0
+                        suf_e = 0
+                        
+                        matchList = re.findall('(\d+)([IDM])', cigar)
+                        unCognitiveCigar = False
+                        for matchN, matchType in matchList:
+                            matchNum = int(matchN)
+                            if matchType == "M":
+                                donorPoint = donorPoint + matchNum
+                                refPoint = refPoint + matchNum
+                            elif matchType == "D":
+                                refPoint = refPoint + matchNum
+                                continue
+                            elif matchType == "I":
+                                donorPoint = donorPoint + matchNum
+                            else:
+                                unCognitiveCigar = True
+                                break
+
+                            if not set_pre_e:
+                                if donorPoint >= donorBeforeStart:
+                                    pre_e = refPoint - (donorPoint - donorBeforeStart)
+                                    set_pre_e = True
+                                else:
+                                    continue
+                                    
+                            if not set_tr_s:
+                                if donorPoint >= donorMicroStart:
+                                    tr_s = refPoint - (donorPoint - donorMicroStart)
+                                    set_tr_s = True
+                                else:
+                                    continue
+                                    
+                            if not set_tr_e:
+                                if donorPoint >= donorMicroEnd:
+                                    tr_e = refPoint - (donorPoint - donorMicroEnd)
+                                    set_tr_e = True
+                                else:
+                                    continue
+                                    
+                            if not set_suf_s:
+                                if donorPoint >= donorAfterMicro:
+                                    suf_s = refPoint - (donorPoint - donorAfterMicro)
+                                    set_suf_s = True
+                                else:
+                                    continue
+                                    
+                            if not set_suf_e:
+                                if donorPoint >= donorEnd:
+                                    suf_e = refPoint - (donorPoint - donorEnd)
+                                    set_suf_e = True
+                                else:
+                                    continue
+                                
+                        if unCognitiveCigar:
+                            break
+                        tr_len = tr_e - tr_s + 1
+
+                        if refName not in refSequence:
+                            tr_ref_seq = "."
+                        else:
+                            if refSequence[refName] == "":
+                                tr_ref_seq = "."
+                            elif len(refSequence[refName]) <= tr_e:
+                                tr_ref_seq = "."
+                            else:
+                                tr_ref_seq = refSequence[refName][tr_s:tr_e+1]
+
+                        pre_e += 1
+                        tr_e += 1
+                        suf_e += 1
+                        print "%d\t%d\t%d\t%s\t%d\t%s\t%s%s\t%s\t%s\t%d\t%d\t%d\t%d\t%d\t%d\t%d\t%s" \
+                            % (rptExtent,prefixLen,suffixLen,kmer,d,reportName,seq,quals,reportName,refName,pre_s,pre_e,tr_s,tr_e,suf_s,suf_e,tr_len,tr_ref_seq)
+
+    if (markEndOfFile):
+        print "# microsat_snoop end-of-file"
+
+    if (inputF != stdin):
+        inputF.close()
+
+# non_negative_intervals
+#     find intervals with exactly + and no -
+#     from string like this : +++++++++---+++++++++
+def non_negative_intervals(seq, minLength=None):
+
+    start = -1
+    end = -1
+    firstPlus = 1
+    #print seq
+    for ix in range(len(seq)): # for every char in seq    
+        ch = seq[ix]
+        if(ch == "+"):
+            if(firstPlus):
+                firstPlus = 0
+                start = ix
+            else:
+                continue
+        elif(ch == "-"):
+            if(start >= 0):
+                end = ix-1
+                if((end - start + 1) >= minLength):
+                    yield (start,end+1)
+                start = -1
+                firstPlus = 1
+    if(start > 0):
+        if((ix - start + 1) >= minLength):
+            yield (start, ix+1)
+
+
+###################################################################
+# modified by Chen Sun on 7/11/2014
+# We do not want other modules, so parse these functions inside
+#
+###################################################################
+
+# parse a string of the form {positives}/{positives_and_neutrals}
+
+def parse_spec(s):
+    if ("/" not in s): raise ValueError
+    (n,d) = s.split("/",1)
+    if (not n.startswith("{")) or (not n.endswith("}")): raise ValueError
+    if (not d.startswith("{")) or (not d.endswith("}")): raise ValueError
+
+    positives = n[1:-1]
+    d         = d[1:-1]
+
+    for ch in positives:
+        if (ch not in d): raise ValueError
+
+    neutrals = [ch for ch in d if (ch not in positives)]
+    return (positives,neutrals)
+
+
+# convert a string to a number, allowing fractions
+
+def float_or_fraction(s):
+    if ("/" in s):
+        (numer,denom) = s.split("/",1)
+        return float(numer)/float(denom)
+    else:
+        return float(s)
+
+
+# dense_intervals--
+#    Find all non-overlapping runs with a good enough rate (of positives), and
+#    which meet our length threshold.
+#
+#    The algorithm used is adapted from Zhang, Berman, Miller, "Post-processing
+#    long pairwise alignments", Bioinformatics Vol. 15 no. 12 1999.
+#
+# $$$ we use the denominator as the threshold, but we really should use the
+# $$$ .. numerator, comparing it to minLength*rate
+
+def dense_intervals(seq,rate,positives,neutrals,blockers="",minLength=None):
+
+    if (blockers == None):
+        blockers = "".join([chr(n) for n in range(1,256)
+                                   if  (chr(n) not in positives)
+                                   and (chr(n) not in neutrals)])
+
+    stackLeft       = [None]    # stack with each entry containing five
+    stackRight      = [None]    # .. elements;  note that entry zero is not
+    stackLeftScore  = [None]    # .. used
+    stackRightScore = [None]
+    stackLower      = [None]
+    top   = 0
+    score = 0
+
+    for ix in range(len(seq)):
+        ch = seq[ix]
+        if (ch in blockers):
+            # emit intervals
+
+            for sp in range(1,top+1):
+                left  = stackLeft [sp] + 1
+                right = stackRight[sp]
+
+                while (left < right) and (seq[left]  not in positives): left  += 1
+                while (right > left) and (seq[right] not in positives): right -= 1
+
+                right += 1
+                if (minLength == None) or (right - left >= minLength):
+                    yield (left,right)
+
+            #empty stack
+
+            stackLeft       = [None]
+            stackRight      = [None]
+            stackLeftScore  = [None]
+            stackRightScore = [None]
+            stackLower      = [None]
+            top   = 0
+            score = 0
+            continue
+
+        if   (ch in positives): weight = 1-rate
+        elif (ch in neutrals):  weight = -rate
+        else: raise ValueError
+
+        score += weight
+        #if ("algorithm" in debug):
+        #    print >>sys.stderr, "%3d: %c %5.2f" % (ix, ch, score),
+
+        if (weight < 0):
+            #if ("algorithm" in debug):
+            #    print >>sys.stderr
+            continue
+
+        if (top > 0) and (stackRight[top] == ix-1):
+            # add this site to the interval on top of the stack
+
+            stackRight     [top] = ix
+            stackRightScore[top] = score
+
+            #if ("algorithm" in debug):
+            #    print >>sys.stderr, \
+            #          " extending [%d] %d-%d %4.1f %4.1f" \
+            #        % (top,
+            #           stackLeft     [top], stackRight     [top],
+            #           stackLeftScore[top], stackRightScore[top]),
+
+        else:
+            # create a one site interval
+
+            top += 1
+            if (top >= len(stackLeft)):
+                stackLeft       += [None]
+                stackRight      += [None]
+                stackLeftScore  += [None]
+                stackRightScore += [None]
+                stackLower      += [None]
+
+            stackLeft      [top] = ix - 1
+            stackLeftScore [top] = score - weight
+            stackRight     [top] = ix
+            stackRightScore[top] = score
+            stackLower     [top] = top - 1
+
+            while (stackLower[top] > 0) \
+              and (stackLeftScore[stackLower[top]] > stackLeftScore[top]):
+                stackLower[top] = stackLower[stackLower[top]]
+
+            #if ("algorithm" in debug):
+            #    print >>sys.stderr, \
+            #          " creating  [%d] %d-%d %4.1f %4.1f -> %d" \
+            #        % (top,
+            #           stackLeft     [top], stackRight     [top],
+            #           stackLeftScore[top], stackRightScore[top],
+            #           stackLower    [top]),
+
+        # merge intervals;  if there is a previous interval with a no-higher
+        # left score and no-higher right score, merge this interval (and all
+        # intervening ones) into that one
+
+        while (top > 1) \
+          and (stackLower[top] > 0) \
+          and (stackRightScore[stackLower[top]] <= stackRightScore[top]):
+            stackRight     [stackLower[top]] = stackRight     [top]
+            stackRightScore[stackLower[top]] = stackRightScore[top]
+            top = stackLower[top]
+
+            #if ("algorithm" in debug):
+            #    print >>sys.stderr, \
+            #          "\n%*s merging   [%d] %d-%d %4.1f %4.1f" \
+            #        % (13, "", top,
+            #           stackLeft[top],      stackRight     [top],
+            #           stackLeftScore[top], stackRightScore[top]),
+
+        #if ("algorithm" in debug):
+        #    print >>sys.stderr
+
+    # emit intervals
+
+    for sp in range(1,top+1):
+        left  = stackLeft [sp] + 1
+        right = stackRight[sp]
+
+        while (left < right) and (seq[left]  not in positives): left  += 1
+        while (right > left) and (seq[right] not in positives): right -= 1
+
+        right += 1
+        if (minLength == None) or (right - left >= minLength):
+            yield (left,right)
+            
+            
+###################################################################
+# modified by Chen Sun on 7/11/2014
+#
+###################################################################
+
+# correlation_sequence--
+#    Compute the correlation sequence for a given period.  This is a sequence
+#    of + and - indicating whether the base at a given position matches the one
+#    P positions earlier (where P is the period).  The first P positions are
+#    blank.  Positions with single character runs longer than the period are
+#    considered as non-matches, unless the period is 1.
+
+def correlation_sequence(sequence,period,start=None,end=None):
+    if (start == None): start = 0
+    if (end   == None): end   = len(sequence)
+
+    prevCh = sequence[start]
+    run    = 1
+    for ix in xrange(start+1,start+period):
+        ch = sequence[ix]
+        if (ch != prevCh): run =  1
+        else:              run += 1
+        prevCh = ch
+
+    corr = [" "] * period
+    for ix in xrange(start+period,end):
+        rptCh = sequence[ix-period]
+        ch    = sequence[ix]
+        if (ch != prevCh): run =  1
+        else:              run += 1
+        if    (ch    in "ACGT") \
+          and (ch == rptCh) \
+          and ((period == 1) or (run < period)):
+            corr += ["+"]
+        else:
+            corr += ["-"]
+        prevCh = ch
+
+    return "".join(corr)
+
+
+# longest_suitable_run--
+#    Find longest run with a good enough rate (of positives).
+#
+#    We score a "+" as 1-r and anything else as -r.  This is based on the fol-
+#    lowing derivation (p is the number of "+"s, n is the number of non-"+"s):
+#        p/(p+n) >= r
+#        ==> p >= rp + rn
+#        ==> (1-r)p - rn >= 0
+#
+#    We adapt an algorithm from "Programming Pearls", pg. 81 (2000 printing).
+#
+# $$$ we use the denominator as the threshold, but we really should use the
+# $$$ .. numerator, comparing it to minLength*rate
+#
+# $$$ this needs to account for $$$ this situation:
+# $$$   sequence: ACGACGACGACGTTATTATTATTA
+# $$$   matches:     +++++++++---+++++++++
+# $$$ this is currently considered to be one interval (if rate <= 6/7), but it
+# $$$ ought to be two;  we can't just post-process, though, because some other
+# $$$ interval might be longer than the longest half of this;  maybe what we
+# $$$ need to do is consider matches at distances -P and -2P, or if we match
+# $$$ -P but that itself was a mismatch, we should carry the mismatch forward
+
+def longest_suitable_run(seq,minLength,rate):
+    maxEndingHere = 0
+    maxSoFar      = 0
+    start         = None
+
+    for ix in xrange(len(seq)):
+        if (seq[ix] == "+"): s = 1-rate
+        else:                s = -rate
+
+        if (maxEndingHere+s < 0):
+            maxEndingHere = 0
+            block         = ix
+        else:
+            maxEndingHere += s
+            if (maxEndingHere >= maxSoFar):
+                maxSoFar = maxEndingHere
+                start    = block + 1
+                end      = ix + 1
+
+    if (start == None) or (end - start < minLength):
+        return []
+    else:
+        return [(start,end)]
+
+
+# all_suitable_runs--
+#    Find all non-overlapping runs with a good enough rate (of positives), and
+#    which meet our length threshold.
+# $$$ this needs to post-process the intervals, splitting them to account for
+# $$$ this situation:
+# $$$   sequence: ACGACGACGACGTTATTATTATTA
+# $$$   matches:     +++++++++---+++++++++
+# $$$ this is currently reported as one interval (if rate <= 6/7), but it
+# $$$ ought to be two
+
+def all_suitable_runs(seq,minCorrLength,rate, hammingThreshold):
+    
+    ################################################################
+    # modified by Chen Sun on 07/11/2014
+    #
+    ################################################################
+    
+    if hammingThreshold > 0:
+        return [(start,end) for (start,end) in dense_intervals(seq,rate,"+","-",blockers=None,minLength=minCorrLength)]
+    elif hammingThreshold == 0:
+        return [(start,end) for (start,end) in non_negative_intervals(seq, minLength=minCorrLength)]
+
+
+# find_repeat_element--
+#    Find the most plausible repeat element for a run, and nudge the ends of
+#    the run if needed.  Note that we will not consider kmers that represent
+#    shorter repeats.  For example, we won't report ACTACT as a 6-mer since we
+#    consider this to have a shorter period than 6.
+
+def find_repeat_element(hammingThreshold, period,seq,start,end,allowPartials=False):
+
+    if hammingThreshold > 0:
+        (kmer,bestD,bestStart,bestEnd) = find_hamming_repeat_element(period,seq,start,end,allowPartials)
+        return (kmer,bestD,bestStart,bestEnd)
+    # count the number of occurences of each k-mer;  note that we can't
+    # reject kmers containing smaller repeats yet, since for a sequence like
+    # ACACACACACAAACACACACACACACACAC we must first discover ACACAC as the best
+    # 6-mer, and THEN reject it;  if we reject ACACAC while counting, we'd end
+    # up reporting something like ACACAA as the best motif 
+
+    if ("element" in debug):
+        print >>stderr, "find_repeat_element(%d,%d,%d)" % (period,start,end)
+
+    if ("partial" in debug):
+        print period, seq, start, end, allowPartials;
+        print seq[start:end]
+
+    kmerToCount = {}
+    kmerToFirst = {}
+    for ix in xrange(start,end-(period-1)):
+        kmer = seq[ix:ix+period]
+        if ("N" in kmer): continue
+        if (kmer not in kmerToCount):
+            kmerToCount[kmer] = 1
+            kmerToFirst[kmer] = ix
+        else:
+            kmerToCount[kmer] += 1
+        #if ("element" in debug):
+        #    print >>stderr, "    %d: %s" % (ix,kmer)
+
+    # choose the best k-mer;  this is simply the most frequently occurring one,
+    # with ties broken by whichever one came first
+
+    kmers = [(-kmerToCount[kmer],kmerToFirst[kmer],kmer) for kmer in kmerToCount]
+    if (kmers == []): return (None,None,start,end)
+    kmers.sort()
+
+    if ("element" in debug):
+        for (count,first,kmer) in kmers:
+            print >>stderr, "    %s: %d" % (kmer,-count)
+
+    (count,first,kmer) = kmers[0]
+    if (contains_repeat(kmer)): return (None,None,start,end)
+
+    # determine the hamming distance between the run and a simple repeat, for
+    # each "plausible" start and end;  we compute the distance for each such
+    # interval, and choose the one with the lowest hamming distance;  ties are
+    # broken in a deterministic-but-unspecified manner
+
+    bestD = bestStart = bestEnd = None
+    ###################################################################################
+    # modified by Chen Sun(cxs1031@cse.psu.edu) on 10/18/2013
+    #     since we do not allow hamming_distance > 0, which means we do not allow mutation,
+    # we do not need this section to produce bestStart and End
+    ###################################################################################
+
+    #for (s,e) in plausible_intervals(start,end,period,len(seq),allowPartials=allowPartials):
+    #    d = hamming_distance(seq,s,e,kmer)
+    #    if (d == None): continue
+    #    if (bestD == None) or (d <= bestD):
+    #        (bestD,bestStart,bestEnd) = (d,s,e)
+    
+
+
+    bestStart = start
+
+    if(allowPartials):
+        bestEnd = end
+    elif(not allowPartials):
+        bestEnd = start
+        pattern = seq[start:start+period]
+        if ("partial" in debug):
+            print "kmer:", kmer
+            if(pattern != kmer):
+                print "pattern:", pattern
+
+        while(bestEnd <= end-period):
+            bestEnd += period
+
+    # bestD will always be 0, as we do not allow mutation
+    bestD = 0
+    
+    if ("partial" in debug):
+        print bestD, bestStart, bestEnd
+
+    ###################################################################################
+    # modified by Chen Sun(cxs1031@cse.psu.edu) on 10/10
+    # 
+    ###################################################################################
+    return (kmer,bestD,bestStart,bestEnd)
+
+
+def find_hamming_repeat_element(period,seq,start,end,allowPartials=False):
+    
+    # count the number of occurences of each k-mer;  note that we can't
+    # reject kmers containing smaller repeats yet, since for a sequence like
+    # ACACACACACAAACACACACACACACACAC we must first discover ACACAC as the best
+    # 6-mer, and THEN reject it;  if we reject ACACAC while counting, we'd end
+    # up reporting something like ACACAA as the best motif 
+
+    if ("element" in debug):
+        print >>stderr, "find_repeat_element(%d,%d,%d)" % (period,start,end)
+
+    kmerToCount = {}
+    kmerToFirst = {}
+    for ix in xrange(start,end-(period-1)):
+        kmer = seq[ix:ix+period]
+        if ("N" in kmer): continue
+        if (kmer not in kmerToCount):
+            kmerToCount[kmer] = 1
+            kmerToFirst[kmer] = ix
+        else:
+            kmerToCount[kmer] += 1
+        #if ("element" in debug):
+        #    print >>stderr, "    %d: %s" % (ix,kmer)
+
+    # choose the best k-mer;  this is simply the most frequently occurring one,
+    # with ties broken by whichever one came first
+
+    kmers = [(-kmerToCount[kmer],kmerToFirst[kmer],kmer) for kmer in kmerToCount]
+    if (kmers == []): return (None,None,start,end)
+    kmers.sort()
+
+    if ("element" in debug):
+        for (count,first,kmer) in kmers:
+            print >>stderr, "    %s: %d" % (kmer,-count)
+
+    (count,first,kmer) = kmers[0]
+    if (contains_repeat(kmer)): return (None,None,start,end)
+
+    # determine the hamming distance between the run and a simple repeat, for
+    # each "plausible" start and end;  we compute the distance for each such
+    # interval, and choose the one with the lowest hamming distance;  ties are
+    # broken in a deterministic-but-unspecified manner
+
+    bestD = bestStart = bestEnd = None
+
+    for (s,e) in plausible_intervals(start,end,period,len(seq),allowPartials=allowPartials):
+        d = hamming_distance(seq,s,e,kmer)
+        if (d == None): continue
+        if (bestD == None) or (d <= bestD):
+            (bestD,bestStart,bestEnd) = (d,s,e)
+
+    return (kmer,bestD,bestStart,bestEnd)
+
+# plausible_intervals--
+#    Yield all plausible intervals intersecting with a run.  We generate all
+#    starts within P bp of the run's start.  For each of these, we either (a) try
+#    all ends within P bp of run's end, or (b) trim the new interval to a whole
+#    multiple of the period, and report this short interval and the longer
+#    interval with one more period appended.  Case (a) allows partial motifs,
+#    while case (b) only allows whole motifs.
+
+def plausible_intervals(start,end,period,seqLen,allowPartials=False):
+
+    # generate intervals that allow a partial copy of the motif
+
+    if (allowPartials):
+        for candStart in xrange(start-(period-1),start+period):
+            if (candStart < 0): continue
+            for candEnd in xrange(end-(period-1),end+period):
+                if (candEnd > seqLen): continue
+                if (candEnd <= candStart+period): continue
+                yield (candStart,candEnd)
+
+    # -OR- generate intervals that allow only whole copies of the motif
+
+    else:
+        for candStart in xrange(start-(period-1),start+period):
+            if (candStart < 0): continue
+            candEnd = candStart + ((end-candStart)/period)*period
+            yield (candStart,candEnd)
+            candEnd += period
+            if (candEnd <= seqLen): yield (candStart,candEnd)
+
+
+# hamming_distance--
+#    Determine the hamming distance between the run and a simple repeat.
+# $$$ improve this by allowing gaps, and stopping when we reach a threshold
+
+kmerToDiffs = {}  # (this is used for memo-ization)
+
+def hamming_distance(seq,start,end,kmer):
+    period = len(kmer)
+    if (end < start + period): return None
+
+    wholeEnd = start + ((end-start)/period)*period
+
+    if (kmer not in kmerToDiffs):
+        kmerToDiffs[kmer] = { kmer:0 }
+
+    d = 0
+    for ix in xrange(start,wholeEnd,period):
+        qmer = seq[ix:ix+period]    # same size as the kmer motif
+        if (qmer in kmerToDiffs[kmer]):
+            d += kmerToDiffs[kmer][qmer]
+            continue
+        diffs = 0
+        for iy in xrange(0,period):
+            if (qmer[iy] != kmer[iy]): diffs += 1
+        kmerToDiffs[kmer][qmer] = diffs
+        d += diffs
+
+    if (end > wholeEnd):
+        qmer = seq[wholeEnd:end]    # shorter than the kmer motif
+        if (qmer in kmerToDiffs[kmer]):
+            d += kmerToDiffs[kmer][qmer]
+        else:
+            diffs = 0
+            for iy in xrange(0,len(qmer)):
+                if (qmer[iy] != kmer[iy]): diffs += 1
+            kmerToDiffs[kmer][qmer] = diffs
+            d += diffs
+
+    return d
+
+
+# fasta_sequences--
+#    Read the fasta sequences from a file.  Note that we convert to upper case,
+#    and convert any letter other than ACGT to N.
+
+nonDnaMap = maketrans("BDEFHIJKLMOPQRSUVWXYZ","NNNNNNNNNNNNNNNNNNNNN")
+
+def fasta_sequences(f):
+    seqName = None
+    seqNucs = None
+
+    for line in f:
+        line = line.strip()
+        if (line.startswith(">")):
+            if (seqName != None):
+                yield (seqName,"".join(seqNucs))
+            seqName = sequence_name(line)
+            seqNucs = []
+        elif (seqName == None):
+            assert (False), "first sequence has no header"
+        else:
+            seqNucs += [line]
+
+    if (seqName != None):
+        yield (seqName,"".join(seqNucs).upper().translate(nonDnaMap))
+
+
+# fastq_sequences--
+#    Read the fastq sequences from a file.  Note that we convert to upper case,
+#    and convert any letter other than ACGT to N.
+
+def fastq_sequences(f):
+    lineNum = 0
+    for line in f:
+        lineNum += 1
+        line = line.strip()
+
+        if (lineNum % 4 == 1):
+            assert (line.startswith("@")), \
+                   "bad read name at line %d" % lineNum
+            seqName = line[1:]
+            continue
+
+        if (lineNum % 4 == 2):
+            seqNucs = line
+            continue
+
+        if (lineNum % 4 == 3):
+            assert (line.startswith("+")), \
+                   "can't understand line %d:\n%s" % (lineNum,line)
+            continue
+
+        quals = line
+        assert (len(quals) == len(seqNucs)), \
+               "length mismatch read vs. qualities at line %d" % lineNum
+        yield (seqName,"".join(seqNucs).upper().translate(nonDnaMap),quals)
+
+    assert (lineNum % 4 == 0), \
+           "incomplete read at end of file"
+
+def sam_sequences(f):
+    lineNum = 0
+    for line in f:
+        lineNum += 1
+        line = line.strip()
+
+        if line.startswith("@"):
+            continue
+
+        columns = line.split("\t")
+        seqName = columns[0]
+        refName = columns[2]
+        pre_s = int(columns[3]) - 1
+        cigar = columns[5]
+        seqNucs = columns[9]
+        
+        yield (seqName,"".join(seqNucs).upper().translate(nonDnaMap), refName, pre_s, cigar)
+
+# sequence_name--
+#    Extract the sequence name from a fasta header.
+#    $$$ this may need to be improved $$$
+
+def sequence_name(s):
+    s = s[1:].strip()
+    if (s == ""): return ""
+    else:         return s.split()[0]
+
+
+# nucleotide_runs--
+#    Yield (start,end) for all runs of valid nucleotides in a sequence.
+
+def nucleotide_runs(s):
+    runs  = []
+    start = None
+    for (ix,nuc) in enumerate(s):
+        if (nuc in "ACGT"):
+            if (start == None):
+                start = ix
+        else:
+            if (start != None):
+                yield (start,ix)
+                start = None
+
+    if (start != None): yield (start,len(s))
+
+
+# contains_repeat--
+#    Determine whether a short sequence contains a repeated element, such as a
+#    6-mer containing a repeated 2-mer (ACACAC) or 3-mer (ACTACT).  The repeat
+#    must cover the entire sequence, without mismatches.
+
+def contains_repeat(kmer):
+    kmerLength = len(kmer)
+    hasRepeat = False
+    rptLen = 1
+    while (not hasRepeat) and (2 * rptLen <= kmerLength):
+        if (kmerLength % rptLen != 0):
+            rptLen += 1
+            continue
+        isRepeat = True
+        for i in xrange(rptLen,kmerLength,rptLen):
+            if (kmer[i:i+rptLen] != kmer[:rptLen]):
+                isRepeat = False
+                break
+        if (isRepeat):
+            hasRepeat = True
+            break
+        rptLen += 1
+    return hasRepeat
+
+
+# hash108--
+#    Return a 108-bit hash "value" of a string
+
+def hash108(s):
+    m = md5_new()
+    m.update(s)
+    return m.hexdigest()[:27]
+
+
+# float_or_fraction--
+#    Convert a string to a number, allowing fractions
+
+def float_or_fraction(s):
+    if ("/" in s):
+        (numer,denom) = s.split("/",1)
+        return float(numer)/float(denom)
+    else:
+        return float(s)
+
+
+# int_with_unit--
+#    Parse a string as an integer, allowing unit suffixes
+
+def int_with_unit(s):
+    if (s.endswith("K")):
+        multiplier = 1000
+        s = s[:-1]
+    elif (s.endswith("M")):
+        multiplier = 1000 * 1000
+        s = s[:-1]
+    elif (s.endswith("G")):
+        multiplier = 1000 * 1000 * 1000
+        s = s[:-1]
+    else:
+        multiplier = 1
+
+    try:               return               int(s)   * multiplier
+    except ValueError: return int(math.ceil(float(s) * multiplier))
+
+
+if __name__ == "__main__": main()
+