def testNoOverlap(self):
     """test empty input."""
     self.assertEqual(Intervals.truncate([(0, 5), (10, 15)], [(5, 10)]),
                      [(0, 5), (10, 15)])
     self.assertEqual(Intervals.truncate([(5, 10)], [(0, 5), (10, 15)]),
                      [(5, 10)])
     self.assertEqual(Intervals.truncate([(0, 5), (5, 10)], [(10, 15)]),
                      [(0, 5), (5, 10)])
 def testMultiple(self):
     """test empty input."""
     self.assertEqual(Intervals.truncate([(0, 5), (10, 15)], [(0, 5)]),
                      [(10, 15)])
     self.assertEqual(Intervals.truncate([(0, 5), (10, 15)], [(0, 10)]),
                      [(10, 15)])
     self.assertEqual(Intervals.truncate([(0, 5), (10, 15)], [(0, 15)]), [])
     self.assertEqual(Intervals.truncate([(0, 5), (5, 10)], [(0, 10)]), [])
     self.assertEqual(Intervals.truncate([(0, 5), (5, 10)], []), [(0, 5),
                                                                  (5, 10)])
 def testSingle(self):
     """test empty input."""
     self.assertEqual(Intervals.truncate([(0, 5)], [(0, 5)]), [])
     self.assertEqual(Intervals.truncate([(0, 5)], [(0, 3)]), [(3, 5)])
     self.assertEqual(Intervals.truncate([(0, 3)], [(0, 5)]), [])
     self.assertEqual(Intervals.truncate([(0, 5)], [(3, 5)]), [(0, 3)])
     self.assertEqual(Intervals.truncate([(3, 5)], [(0, 5)]), [])
     self.assertEqual(Intervals.truncate([(5, 10)], [(5, 10)]), [])
     self.assertEqual(Intervals.truncate([(5, 10)], [(5, 20)]), [])
     self.assertEqual(Intervals.truncate([(5, 10)], [(0, 10)]), [])
     self.assertEqual(Intervals.truncate([(5, 10)], [(0, 10)]), [])
     self.assertEqual(Intervals.truncate([(5, 10)], [(0, 20)]), [])
 def testEmpty(self):
     """test empty input."""
     self.assertEqual(Intervals.truncate([], []), [])
 def testHalfEmpty(self):
     """test empty input."""
     self.assertEqual(Intervals.truncate([], [(0, 5)]), [])
     self.assertEqual(Intervals.truncate([(0, 5)], []), [(0, 5)])
Beispiel #6
0
def annotateGenome(iterator, fasta, options, default_code=DEFAULT_CODE):
    """annotate a genome given by the indexed *fasta* file and 
    an iterator over gtf annotations.
    """

    annotations = {}
    contig_sizes = fasta.getContigSizes(with_synonyms=False)
    E.info("allocating memory for %i contigs and %i bytes" %
           (len(contig_sizes),
            sum(contig_sizes.values()) * array.array("B").itemsize))
    # AString.AString( "a").itemsize ))

    for contig, size in list(contig_sizes.items()):
        E.debug("allocating %s: %i bases" % (contig, size))
        # annotations[contig] = AString.AString( default_code * size )
        # annotations[contig] = array.array("", default_code * size)
        # Go to list for py3 compatibility, patch
        annotations[contig] = [default_code] * size

    E.info("allocated memory for %i contigs" % len(fasta))

    counter = E.Counter()

    # output splice junctions
    outfile_junctions = E.open_output_file("junctions")
    outfile_junctions.write(
        "contig\tstrand\tpos1\tpos2\tframe\tgene_id\ttranscript_id\n")
    for gtfs in iterator:

        counter.input += 1

        if counter.input % options.report_step == 0:
            E.info("iteration %i" % counter.input)

        try:
            contig = fasta.getToken(gtfs[0].contig)
        except KeyError as msg:
            E.warn("contig %s not found - annotation ignored" % gtfs[0].contig)
            counter.skipped_contig += 1
            continue

        lcontig = fasta.getLength(contig)

        # make sure that exons are sorted by coordinate
        gtfs.sort(key=lambda x: x.start)

        is_positive = Genomics.IsPositiveStrand(gtfs[0].strand)
        source = gtfs[0].source

        # process non-coding data
        if source in MAP_ENSEMBL:
            code = MAP_ENSEMBL[source]

            intervals = [(x.start, x.end) for x in gtfs]
            addSegments(annotations[contig], intervals, is_positive, code)

        elif source == "protein_coding":

            # collect exons for utr
            exons = [(x.start, x.end) for x in gtfs if x.feature == "exon"]
            cds = [(x.start, x.end) for x in gtfs if x.feature == "CDS"]
            if len(cds) == 0:
                counter.skipped_transcripts += 1
                E.warn("protein-coding transcript %s without CDS - skipped" %
                       gtfs[0].transcript_id)
                continue

            exons = Intervals.truncate(exons, cds)
            start, end = cds[0][0], cds[-1][1]

            UTR5 = [x for x in exons if x[1] < start]
            UTR3 = [x for x in exons if x[0] >= end]

            if not is_positive:
                UTR5, UTR3 = UTR3, UTR5
                splice_code = "S"
            else:
                splice_code = "s"

            addSegments(annotations[contig], UTR5, is_positive, "u")

            addIntrons(annotations[contig], UTR5, is_positive,
                       options.max_frameshift_length)

            addSegments(annotations[contig], UTR3, is_positive, "v")

            addIntrons(annotations[contig], UTR3, is_positive,
                       options.max_frameshift_length)

            # output CDS according to frame
            addCDS(annotations[contig],
                   [x for x in gtfs if x.feature == "CDS"], is_positive)

            # add introns between CDS
            addIntrons(annotations[contig], cds, is_positive,
                       options.max_frameshift_length)

            # output splice junctions
            cds = [x for x in gtfs if x.feature == "CDS"]

            # apply corrections for 1-past end coordinates
            # to point between residues within CDS
            if is_positive:
                ender = lambda x: x.end - 1
                starter = lambda x: x.start
                out_positive = "+"
            else:
                ender = lambda x: lcontig - x.start - 1
                starter = lambda x: lcontig - x.end
                out_positive = "-"
                cds.reverse()

            end = ender(cds[0])
            for c in cds[1:]:
                start = starter(c)
                outfile_junctions.write("%s\t%s\t%i\t%i\t%s\t%s\t%s\n" % (
                    contig,
                    out_positive,
                    end,
                    start,
                    c.frame,
                    c.gene_id,
                    c.transcript_id,
                ))
                end = ender(c)

    E.info("finished reading genes: %s" % str(counter))

    outfile_junctions.close()

    E.info("started counting")
    outfile = E.open_output_file("counts")
    outputCounts(outfile, annotations)
    outfile.close()

    E.info("started output")
    for k in sorted(annotations.keys()):
        # options.stdout.write(">%s\n%s\n" % (k, annotations[k].tostring()))
        options.stdout.write(">%s\n%s\n" % (k, "".join(annotations[k])))
Beispiel #7
0
def main(argv=None):
    """script main.

    parses command line options in sys.argv, unless *argv* is given.
    """

    if argv is None:
        argv = sys.argv

    parser = E.OptionParser(version="%prog version: $Id$",
                            usage=globals()["__doc__"])

    parser.add_option("--is-gtf",
                      dest="is_gtf",
                      action="store_true",
                      help="input is gtf instead of gff.")

    parser.add_option("-g",
                      "--genome-file",
                      dest="genome_file",
                      type="string",
                      help="filename with genome [default=%default].")

    parser.add_option("-m",
                      "--merge-adjacent",
                      dest="merge",
                      action="store_true",
                      help="merge adjacent intervals with the same attributes."
                      " [default=%default]")

    parser.add_option("-e",
                      "--feature",
                      dest="feature",
                      type="string",
                      help="filter by a feature, for example 'exon', 'CDS'."
                      " If set to the empty string, all entries are output "
                      "[%default].")

    parser.add_option("-f",
                      "--maskregions-bed-file",
                      dest="filename_masks",
                      type="string",
                      metavar="gff",
                      help="mask sequences with regions given in gff file "
                      "[%default].")

    parser.add_option("--remove-masked-regions",
                      dest="remove_masked_regions",
                      action="store_true",
                      help="remove regions instead of masking [%default].")

    parser.add_option("--min-interval-length",
                      dest="min_length",
                      type="int",
                      help="set minimum length for sequences output "
                      "[%default]")

    parser.add_option("--max-length",
                      dest="max_length",
                      type="int",
                      help="set maximum length for sequences output "
                      "[%default]")

    parser.add_option("--extend-at",
                      dest="extend_at",
                      type="choice",
                      choices=("none", "3", "5", "both", "3only", "5only"),
                      help="extend at no end, 3', 5' or both ends. If "
                      "3only or 5only are set, only the added sequence "
                      "is returned [default=%default]")

    parser.add_option("--header-attributes",
                      dest="header_attr",
                      action="store_true",
                      help="add GFF entry attributes to the FASTA record"
                      " header section")

    parser.add_option("--extend-by",
                      dest="extend_by",
                      type="int",
                      help="extend by # bases [default=%default]")

    parser.add_option("--extend-with",
                      dest="extend_with",
                      type="string",
                      help="extend using base [default=%default]")

    parser.add_option("--masker",
                      dest="masker",
                      type="choice",
                      choices=("dust", "dustmasker", "softmask", "none"),
                      help="apply masker [%default].")

    parser.add_option("--fold-at",
                      dest="fold_at",
                      type="int",
                      help="fold sequence every n bases[%default].")

    parser.add_option(
        "--fasta-name-attribute",
        dest="naming_attribute",
        type="string",
        help="use attribute to name fasta entry. Currently only compatable"
        " with gff format [%default].")

    parser.set_defaults(
        is_gtf=False,
        genome_file=None,
        merge=False,
        feature=None,
        filename_masks=None,
        remove_masked_regions=False,
        min_length=0,
        max_length=0,
        extend_at=None,
        extend_by=100,
        extend_with=None,
        masker=None,
        fold_at=None,
        naming_attribute=False,
        header_attr=False,
    )

    (options, args) = E.start(parser)

    if options.genome_file:
        fasta = IndexedFasta.IndexedFasta(options.genome_file)
        contigs = fasta.getContigSizes()

    if options.is_gtf:
        iterator = GTF.transcript_iterator(GTF.iterator(options.stdin))
    else:
        gffs = GTF.iterator(options.stdin)
        if options.merge:
            iterator = GTF.joined_iterator(gffs)
        else:
            iterator = GTF.chunk_iterator(gffs)

    masks = None
    if options.filename_masks:
        masks = {}
        with iotools.open_file(options.filename_masks, "r") as infile:
            e = GTF.readAsIntervals(GTF.iterator(infile))

        # convert intervals to intersectors
        for contig in list(e.keys()):
            intersector = quicksect.IntervalTree()
            for start, end in e[contig]:
                intersector.add(start, end)
            masks[contig] = intersector

    ninput, noutput, nmasked, nskipped_masked = 0, 0, 0, 0
    nskipped_length = 0
    nskipped_noexons = 0

    feature = options.feature

    # iterator is a list containing groups (lists) of features.
    # Each group of features have in common the same transcript ID, in case of
    # GTF files.
    for ichunk in iterator:

        ninput += 1

        if feature:
            chunk = [x for x in ichunk if x.feature == feature]
        else:
            chunk = ichunk

        if len(chunk) == 0:
            nskipped_noexons += 1
            E.info("no features in entry from "
                   "%s:%i..%i - %s" % (ichunk[0].contig, ichunk[0].start,
                                       ichunk[0].end, str(ichunk[0])))
            continue

        contig, strand = chunk[0].contig, chunk[0].strand

        if options.is_gtf:
            name = chunk[0].transcript_id
        else:
            if options.naming_attribute:
                attr_dict = {
                    x.split("=")[0]: x.split("=")[1]
                    for x in chunk[0].attributes.split(";")
                }
                name = attr_dict[options.naming_attribute]
            else:
                name = str(chunk[0].attributes)

        lcontig = contigs[contig]
        positive = Genomics.IsPositiveStrand(strand)
        intervals = [(x.start, x.end) for x in chunk]
        intervals.sort()

        if masks:
            if contig in masks:
                masked_regions = []
                for start, end in intervals:
                    masked_regions += [(x.start, x.end)
                                       for x in masks[contig].find(
                                           quicksect.Interval(start, end))]

                masked_regions = Intervals.combine(masked_regions)
                if len(masked_regions):
                    nmasked += 1

                if options.remove_masked_regions:
                    intervals = Intervals.truncate(intervals, masked_regions)
                else:
                    raise NotImplementedError("unimplemented")

                if len(intervals) == 0:
                    nskipped_masked += 1
                    if options.loglevel >= 1:
                        options.stdlog.write(
                            "# skipped because fully masked: "
                            "%s: regions=%s masks=%s\n" %
                            (name, str([(x.start, x.end)
                                        for x in chunk]), masked_regions))
                    continue

        out = intervals

        if options.extend_at and not options.extend_with:
            if options.extend_at == "5only":
                intervals = [(max(0, intervals[0][0] - options.extend_by),
                              intervals[0][0])]
            elif options.extend_at == "3only":
                intervals = [(intervals[-1][1],
                              min(lcontig,
                                  intervals[-1][1] + options.extend_by))]
            else:
                if options.extend_at in ("5", "both"):
                    intervals[0] = (max(0,
                                        intervals[0][0] - options.extend_by),
                                    intervals[0][1])
                if options.extend_at in ("3", "both"):
                    intervals[-1] = (intervals[-1][0],
                                     min(lcontig,
                                         intervals[-1][1] + options.extend_by))

        if not positive:
            intervals = [(lcontig - x[1], lcontig - x[0])
                         for x in intervals[::-1]]
            out.reverse()

        s = [
            fasta.getSequence(contig, strand, start, end)
            for start, end in intervals
        ]
        # IMS: allow for masking of sequences
        s = Masker.maskSequences(s, options.masker)
        l = sum([len(x) for x in s])
        if (l < options.min_length
                or (options.max_length and l > options.max_length)):
            nskipped_length += 1
            if options.loglevel >= 1:
                options.stdlog.write("# skipped because length out of bounds "
                                     "%s: regions=%s len=%i\n" %
                                     (name, str(intervals), l))
                continue

        if options.extend_at and options.extend_with:
            extension = "".join((options.extend_with, ) * options.extend_by)

            if options.extend_at in ("5", "both"):
                s[1] = extension + s[1]
            if options.extend_at in ("3", "both"):
                s[-1] = s[-1] + extension

        if options.fold_at:
            n = options.fold_at
            s = "".join(s)
            seq = "\n".join([s[i:i + n] for i in range(0, len(s), n)])
        else:
            seq = "\n".join(s)

        if options.header_attr:
            attributes = " ".join(
                [":".join([ax, ay]) for ax, ay in chunk[0].asDict().items()])
            options.stdout.write(
                ">%s %s:%s:%s feature:%s %s\n%s\n" %
                (name, contig, strand, ";".join(
                    ["%i-%i" % x
                     for x in out]), chunk[0].feature, attributes, seq))
        else:
            options.stdout.write(
                ">%s %s:%s:%s\n%s\n" %
                (name, contig, strand, ";".join(["%i-%i" % x
                                                 for x in out]), seq))

        noutput += 1

    E.info("ninput=%i, noutput=%i, nmasked=%i, nskipped_noexons=%i, "
           "nskipped_masked=%i, nskipped_length=%i" %
           (ninput, noutput, nmasked, nskipped_noexons, nskipped_masked,
            nskipped_length))

    E.stop()