/** * Finds the adaptor boundary around the read and returns the first base inside the adaptor that * is closest to the read boundary. If the read is in the positive strand, this is the first base * after the end of the fragment (Picard calls it 'insert'), if the read is in the negative * strand, this is the first base before the beginning of the fragment. * * <p>There are two cases we need to treat here: * * <p>1) Our read is in the reverse strand : * * <p><----------------------| * |---------------------> * * <p>in these cases, the adaptor boundary is at the mate start (minus one) * * <p>2) Our read is in the forward strand : * * <p>|----------------------> * <----------------------| * * <p>in these cases the adaptor boundary is at the start of the read plus the inferred insert * size (plus one) * * @param read the read being tested for the adaptor boundary * @return the reference coordinate for the adaptor boundary (effectively the first base IN the * adaptor, closest to the read. NULL if the read is unmapped or the mate is mapped to another * contig. */ public static Integer getAdaptorBoundary(final SAMRecord read) { final int MAXIMUM_ADAPTOR_LENGTH = 8; final int insertSize = Math.abs( read .getInferredInsertSize()); // the inferred insert size can be negative if the mate // is mapped before the read (so we take the absolute // value) if (insertSize == 0 || read .getReadUnmappedFlag()) // no adaptors in reads with mates in another chromosome or // unmapped pairs return null; Integer adaptorBoundary; // the reference coordinate for the adaptor boundary (effectively the first // base IN the adaptor, closest to the read) if (read.getReadNegativeStrandFlag()) adaptorBoundary = read.getMateAlignmentStart() - 1; // case 1 (see header) else adaptorBoundary = read.getAlignmentStart() + insertSize + 1; // case 2 (see header) if ((adaptorBoundary < read.getAlignmentStart() - MAXIMUM_ADAPTOR_LENGTH) || (adaptorBoundary > read.getAlignmentEnd() + MAXIMUM_ADAPTOR_LENGTH)) adaptorBoundary = null; // we are being conservative by not allowing the adaptor boundary to go beyond what // we belive is the maximum size of an adaptor return adaptorBoundary; }
private void collectReadData(final SAMRecord record, final ReferenceSequence ref) { metrics.TOTAL_READS++; readLengthHistogram.increment(record.getReadBases().length); if (!record.getReadFailsVendorQualityCheckFlag()) { metrics.PF_READS++; if (isNoiseRead(record)) metrics.PF_NOISE_READS++; if (record.getReadUnmappedFlag()) { // If the read is unmapped see if it's adapter sequence final byte[] readBases = record.getReadBases(); if (!(record instanceof BAMRecord)) StringUtil.toUpperCase(readBases); if (isAdapterSequence(readBases)) { this.adapterReads++; } } else if (doRefMetrics) { metrics.PF_READS_ALIGNED++; if (!record.getReadNegativeStrandFlag()) numPositiveStrand++; if (record.getReadPairedFlag() && !record.getMateUnmappedFlag()) { metrics.READS_ALIGNED_IN_PAIRS++; // Check that both ends have mapq > minimum final Integer mateMq = record.getIntegerAttribute("MQ"); if (mateMq == null || mateMq >= MAPPING_QUALITY_THRESOLD && record.getMappingQuality() >= MAPPING_QUALITY_THRESOLD) { ++this.chimerasDenominator; // With both reads mapped we can see if this pair is chimeric if (Math.abs(record.getInferredInsertSize()) > maxInsertSize || !record.getReferenceIndex().equals(record.getMateReferenceIndex())) { ++this.chimeras; } } } } } }
private static void updateSAM( SAMRecord rec, ReferenceSequence sequence, SAMProgramRecord programRecord, AlignHeapNode bestAlignHeapNode, SRMAUtil.Space space, String read, String qualities, String softClipStartBases, String softClipStartQualities, String softClipEndBases, String softClipEndQualities, boolean strand, boolean correctBases) throws Exception { AlignHeapNode curAlignHeapNode = null; AlignHeapNode prevAlignHeapNode = null; int alignmentStart = 0; int readIndex = -1; byte readBases[] = null; byte baseQualities[] = null; byte colorErrors[] = null; int i; int numEdits = 0; List<String> optFieldTags = new LinkedList<String>(); List<Object> optFieldValues = new LinkedList<Object>(); Object attr; // Debugging stuff String readName = rec.getReadName(); if (null == bestAlignHeapNode) { // Do not modify the alignment return; } // To generate a new CIGAR List<CigarElement> cigarElements = null; CigarOperator prevCigarOperator = null, curCigarOperator = null; int prevCigarOperatorLength = 0; // TODO // setInferredInsertSize (invalidates paired end reads) // setMappingQuality (?) // setFlag // update base qualities for color space reads // clear attributes, but save some Align.clearAttributes(rec, optFieldTags, optFieldValues); readBases = new byte[read.length()]; baseQualities = new byte[qualities.length()]; for (i = 0; i < qualities.length(); i++) { // Must subtract 33 for PHRED scaling baseQualities[i] = (byte) (qualities.charAt(i) - 33); } if (strand) { readIndex = 0; } else { readIndex = read.length() - 1; } cigarElements = new LinkedList<CigarElement>(); if (strand) { // reverse strand is the current position alignmentStart = bestAlignHeapNode.node.position; } else { alignmentStart = bestAlignHeapNode.startPosition; } assert null != bestAlignHeapNode; curAlignHeapNode = bestAlignHeapNode; while (null != curAlignHeapNode) { // Get the current cigar operator if (null != prevAlignHeapNode && CigarOperator.DELETION != prevCigarOperator && 1 < Math.abs(curAlignHeapNode.node.position - prevAlignHeapNode.node.position)) { curCigarOperator = CigarOperator.DELETION; } else { switch (curAlignHeapNode.node.type) { case Node.MISMATCH: // Fall through case Node.MATCH: curCigarOperator = CigarOperator.MATCH_OR_MISMATCH; break; case Node.INSERTION: // System.out.println("INS"); curCigarOperator = CigarOperator.INSERTION; break; default: throw new Exception("Unknown node type"); } if (space == SRMAUtil.Space.COLORSPACE || correctBases) { readBases[readIndex] = (byte) curAlignHeapNode.node.base; if (strand) { readIndex++; } else { readIndex--; } // count the number of mismatches switch (curAlignHeapNode.node.type) { case Node.MISMATCH: case Node.INSERTION: numEdits++; break; default: break; } } else { // count the number of mismatches switch (curAlignHeapNode.node.type) { case Node.MATCH: if (read.charAt(curAlignHeapNode.readOffset) != curAlignHeapNode.node.base) { numEdits++; } break; case Node.MISMATCH: // Fall through if (read.charAt(curAlignHeapNode.readOffset) != sequence.getBases()[curAlignHeapNode.node.position - 1]) { numEdits++; } break; case Node.INSERTION: numEdits++; break; default: break; } } } if (prevCigarOperator != curCigarOperator) { // different cigar operator // add the previous cigar operator if (null != prevCigarOperator) { if (strand) { // reverse // append cigarElements.add(new CigarElement(prevCigarOperatorLength, prevCigarOperator)); } else { // prepend cigarElements.add(0, new CigarElement(prevCigarOperatorLength, prevCigarOperator)); } } // update prevCigarOperator prevCigarOperator = curCigarOperator; if (curCigarOperator == CigarOperator.DELETION) { // length of deletion prevCigarOperatorLength = Math.abs(curAlignHeapNode.node.position - prevAlignHeapNode.node.position) - 1; numEdits += prevCigarOperatorLength; // deletions } else { prevCigarOperatorLength = 1; } } else { // same cigar operator prevCigarOperatorLength++; } // Update if (CigarOperator.DELETION != curCigarOperator) { prevAlignHeapNode = curAlignHeapNode; curAlignHeapNode = curAlignHeapNode.prev; } } if (0 < prevCigarOperatorLength) { if (null == prevCigarOperator || CigarOperator.DELETION == prevCigarOperator) { throw new Exception("Ended with a null cigar operator or a deletion cigar operator"); } if (strand) { // reverse // append cigarElements.add(new CigarElement(prevCigarOperatorLength, prevCigarOperator)); } else { // prepend cigarElements.add(0, new CigarElement(prevCigarOperatorLength, prevCigarOperator)); } } if (space == SRMAUtil.Space.COLORSPACE) { // color space, read bases already inferred // Get color error string colorErrors = new byte[read.length()]; char prevBase = SRMAUtil.COLORSPACE_ADAPTOR; if (strand) { // reverse for (i = 0; i < read.length(); i++) { char nextBase = SRMAUtil.colorSpaceNextBase(prevBase, read.charAt(i)); if (nextBase == SRMAUtil.getCompliment((char) readBases[read.length() - i - 1])) { colorErrors[i] = (byte) Alignment.GAP; } else { colorErrors[i] = (byte) read.charAt(i); } if (0 < i) { // qualities are assumed to be always in the same direction as the color errors baseQualities[read.length() - i] = getColorQuality( colorErrors[i - 1], colorErrors[i], (byte) (qualities.charAt(i - 1) - 33), (byte) (qualities.charAt(i) - 33)); } prevBase = SRMAUtil.getCompliment((char) readBases[read.length() - i - 1]); } // last color baseQualities[0] = (byte) (qualities.charAt(read.length() - 1) - 33); } else { for (i = 0; i < read.length(); i++) { char nextBase = SRMAUtil.colorSpaceNextBase(prevBase, read.charAt(i)); if (nextBase == readBases[i]) { colorErrors[i] = (byte) Alignment.GAP; } else { colorErrors[i] = (byte) read.charAt(i); } if (0 < i) { baseQualities[i - 1] = getColorQuality( colorErrors[i - 1], colorErrors[i], (byte) (qualities.charAt(i - 1) - 33), (byte) (qualities.charAt(i) - 33)); } prevBase = (char) readBases[i]; } // last color baseQualities[read.length() - 1] = (byte) (qualities.charAt(read.length() - 1) - 33); } } else if (correctBases) { // bases were corrected if (strand) { for (i = 0; i < read.length(); i++) { if (readBases[i] == (byte) read.charAt(read.length() - i - 1)) { baseQualities[i] = (byte) (qualities.charAt(read.length() - i - 1) - 33); } else { // TODO: how much to down-weight ? baseQualities[i] = (byte) (SRMAUtil.QUAL2CHAR( SRMAUtil.CHAR2QUAL(qualities.charAt(read.length() - i - 1)) - CORRECT_BASE_QUALITY_PENALTY) - 33); if (baseQualities[i] <= 0) { baseQualities[i] = 1; } } } } else { for (i = 0; i < read.length(); i++) { if (readBases[i] == (byte) read.charAt(i)) { baseQualities[i] = (byte) (qualities.charAt(i) - 33); } else { // TODO: how much to down-weight ? baseQualities[i] = (byte) (SRMAUtil.QUAL2CHAR( SRMAUtil.CHAR2QUAL(qualities.charAt(i)) - CORRECT_BASE_QUALITY_PENALTY) - 33); if (baseQualities[i] <= 0) { baseQualities[i] = 1; } } } } rec.setAttribute("XO", read); rec.setAttribute("XQ", qualities); } else { // bases not corrected readBases = new byte[read.length()]; baseQualities = new byte[qualities.length()]; // qualities.length() == read.length() if (strand) { // reverse for (i = 0; i < read.length(); i++) { readBases[i] = (byte) read.charAt(read.length() - i - 1); baseQualities[i] = (byte) (qualities.charAt(read.length() - i - 1) - 33); } } else { for (i = 0; i < read.length(); i++) { readBases[i] = (byte) read.charAt(i); baseQualities[i] = (byte) (qualities.charAt(i) - 33); } } } // Add in soft-clipping if (null != softClipStartBases) { // prepend cigarElements.add(0, new CigarElement(softClipStartBases.length(), CigarOperator.S)); byte tmpBases[] = new byte[readBases.length + softClipStartBases.length()]; System.arraycopy(readBases, 0, tmpBases, softClipStartBases.length(), readBases.length); readBases = tmpBases; for (i = 0; i < softClipStartBases.length(); i++) { readBases[i] = (byte) softClipStartBases.charAt(i); } byte tmpQualities[] = new byte[baseQualities.length + softClipStartQualities.length()]; System.arraycopy( baseQualities, 0, tmpQualities, softClipStartQualities.length(), baseQualities.length); baseQualities = tmpQualities; for (i = 0; i < softClipStartQualities.length(); i++) { baseQualities[i] = (byte) softClipStartQualities.charAt(i); } } if (null != softClipEndBases) { // append cigarElements.add(new CigarElement(softClipEndBases.length(), CigarOperator.S)); byte tmpBases[] = new byte[readBases.length + softClipEndBases.length()]; System.arraycopy(readBases, 0, tmpBases, 0, readBases.length); for (i = 0; i < softClipEndBases.length(); i++) { tmpBases[i + readBases.length] = (byte) softClipEndBases.charAt(i); } readBases = tmpBases; byte tmpQualities[] = new byte[baseQualities.length + softClipEndQualities.length()]; System.arraycopy(baseQualities, 0, tmpQualities, 0, baseQualities.length); for (i = 0; i < softClipEndQualities.length(); i++) { tmpQualities[i + baseQualities.length] = (byte) softClipEndQualities.charAt(i); } baseQualities = tmpQualities; } // Update SAM record rec.setCigar(new Cigar(cigarElements)); rec.setAlignmentStart(alignmentStart); rec.setReadBases(readBases); rec.setBaseQualities(baseQualities); // Reset saved attributes Align.resetAttributes(rec, optFieldTags, optFieldValues); // Set new attributes if (space == SRMAUtil.Space.COLORSPACE) { // set the XE attribute for colorError string rec.setAttribute("XE", new String(colorErrors)); } rec.setAttribute("AS", bestAlignHeapNode.score); rec.setAttribute("XC", bestAlignHeapNode.alleleCoverageSum); rec.setAttribute("PG", programRecord.getId()); rec.setAttribute("NM", numEdits); }