public static VariantContext getVCFromAllelesRod(
      RefMetaDataTracker tracker,
      ReferenceContext ref,
      GenomeLoc loc,
      boolean requireSNP,
      Logger logger,
      final RodBinding<VariantContext> allelesBinding) {
    if (tracker == null || ref == null || logger == null) return null;
    VariantContext vc = null;

    // search for usable record
    for (final VariantContext vc_input : tracker.getValues(allelesBinding, loc)) {
      if (vc_input != null && !vc_input.isFiltered() && (!requireSNP || vc_input.isSNP())) {
        if (vc == null) {
          vc = vc_input;
        } else {
          logger.warn(
              "Multiple valid VCF records detected in the alleles input file at site "
                  + ref.getLocus()
                  + ", only considering the first record");
        }
      }
    }

    return vc;
  }
 public static BaseUtils.BaseSubstitutionType getSNPSubstitutionType(VariantContext context) {
   if (!context.isSNP() || !context.isBiallelic())
     throw new IllegalStateException(
         "Requested SNP substitution type for bialleic non-SNP " + context);
   return BaseUtils.SNPSubstitutionType(
       context.getReference().getBases()[0], context.getAlternateAllele(0).getBases()[0]);
 }
Esempio n. 3
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  public Map<String, Object> annotate(
      final RefMetaDataTracker tracker,
      final AnnotatorCompatible walker,
      final ReferenceContext ref,
      final Map<String, AlignmentContext> stratifiedContexts,
      final VariantContext vc,
      final Map<String, PerReadAlleleLikelihoodMap> stratifiedPerReadAlleleLikelihoodMap) {

    int run;
    if (vc.isMixed()) {
      Map<String, Object> map = new HashMap<String, Object>();
      map.put(getKeyNames().get(0), String.format("%s", "MIXED"));
      return map;

    } else if (vc.isIndel()) {
      String type = "";
      if (!vc.isBiallelic()) type = "MULTIALLELIC_INDEL";
      else {
        if (vc.isSimpleInsertion()) type = "INS.";
        else if (vc.isSimpleDeletion()) type = "DEL.";
        else type = "OTHER.";
        ArrayList<Integer> inds = IndelUtils.findEventClassificationIndex(vc, ref);
        for (int k : inds) {
          type = type + IndelUtils.getIndelClassificationName(k) + ".";
        }
      }
      Map<String, Object> map = new HashMap<String, Object>();
      map.put(getKeyNames().get(0), String.format("%s", type));
      return map;

    } else {
      return null;
    }
  }
  @Test(dataProvider = "mergeAlleles")
  public void testMergeAlleles(MergeAllelesTest cfg) {
    final List<VariantContext> inputs = new ArrayList<VariantContext>();

    int i = 0;
    for (final List<Allele> alleles : cfg.inputs) {
      final String name = "vcf" + ++i;
      inputs.add(makeVC(name, alleles));
    }

    final List<String> priority = vcs2priority(inputs);

    final VariantContext merged =
        VariantContextUtils.simpleMerge(
            genomeLocParser,
            inputs,
            priority,
            VariantContextUtils.FilteredRecordMergeType.KEEP_IF_ANY_UNFILTERED,
            VariantContextUtils.GenotypeMergeType.PRIORITIZE,
            false,
            false,
            "set",
            false,
            false);

    Assert.assertEquals(merged.getAlleles(), cfg.expected);
  }
Esempio n. 5
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  /**
   * Checks if vc has a variant call for (at least one of) the samples.
   *
   * @param vc the variant rod VariantContext. Here, the variant is the dataset you're looking for
   *     discordances to (e.g. HapMap)
   * @param compVCs the comparison VariantContext (discordance
   * @return
   */
  private boolean isDiscordant(VariantContext vc, Collection<VariantContext> compVCs) {
    if (vc == null) return false;

    // if we're not looking at specific samples then the absence of a compVC means discordance
    if (NO_SAMPLES_SPECIFIED) return (compVCs == null || compVCs.isEmpty());

    // check if we find it in the variant rod
    Map<String, Genotype> genotypes = vc.getGenotypes(samples);
    for (Genotype g : genotypes.values()) {
      if (sampleHasVariant(g)) {
        // There is a variant called (or filtered with not exclude filtered option set) that is not
        // HomRef for at least one of the samples.
        if (compVCs == null) return true;
        // Look for this sample in the all vcs of the comp ROD track.
        boolean foundVariant = false;
        for (VariantContext compVC : compVCs) {
          if (sampleHasVariant(compVC.getGenotype(g.getSampleName()))) {
            foundVariant = true;
            break;
          }
        }
        // if (at least one sample) was not found in all VCs of the comp ROD, we have discordance
        if (!foundVariant) return true;
      }
    }
    return false; // we only get here if all samples have a variant in the comp rod.
  }
Esempio n. 6
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  private boolean isConcordant(VariantContext vc, Collection<VariantContext> compVCs) {
    if (vc == null || compVCs == null || compVCs.isEmpty()) return false;

    // if we're not looking for specific samples then the fact that we have both VCs is enough to
    // call it concordant.
    if (NO_SAMPLES_SPECIFIED) return true;

    // make a list of all samples contained in this variant VC that are being tracked by the user
    // command line arguments.
    Set<String> variantSamples = vc.getSampleNames();
    variantSamples.retainAll(samples);

    // check if we can find all samples from the variant rod in the comp rod.
    for (String sample : variantSamples) {
      boolean foundSample = false;
      for (VariantContext compVC : compVCs) {
        Genotype varG = vc.getGenotype(sample);
        Genotype compG = compVC.getGenotype(sample);
        if (haveSameGenotypes(varG, compG)) {
          foundSample = true;
          break;
        }
      }
      // if at least one sample doesn't have the same genotype, we don't have concordance
      if (!foundSample) {
        return false;
      }
    }
    return true;
  }
Esempio n. 7
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  protected final void printCallInfo(
      final VariantContext vc,
      final double[] log10AlleleFrequencyPriors,
      final long runtimeNano,
      final AFCalcResult result) {
    printCallElement(vc, "type", "ignore", vc.getType());

    int allelei = 0;
    for (final Allele a : vc.getAlleles())
      printCallElement(vc, "allele", allelei++, a.getDisplayString());

    for (final Genotype g : vc.getGenotypes())
      printCallElement(vc, "PL", g.getSampleName(), g.getLikelihoodsString());

    for (int priorI = 0; priorI < log10AlleleFrequencyPriors.length; priorI++)
      printCallElement(vc, "priorI", priorI, log10AlleleFrequencyPriors[priorI]);

    printCallElement(vc, "runtime.nano", "ignore", runtimeNano);
    printCallElement(vc, "log10PosteriorOfAFEq0", "ignore", result.getLog10PosteriorOfAFEq0());
    printCallElement(vc, "log10PosteriorOfAFGt0", "ignore", result.getLog10PosteriorOfAFGT0());

    for (final Allele allele : result.getAllelesUsedInGenotyping()) {
      if (allele.isNonReference()) {
        printCallElement(vc, "MLE", allele, result.getAlleleCountAtMLE(allele));
        printCallElement(
            vc, "pNonRefByAllele", allele, result.getLog10PosteriorOfAFGt0ForAllele(allele));
      }
    }

    callReport.flush();
  }
Esempio n. 8
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  @Override
  public Integer map(RefMetaDataTracker tracker, ReferenceContext ref, AlignmentContext context) {
    // First, verify that the metadata tracker is not null (meaning there is a variant at this locus
    // to process).
    if (tracker != null) {
      // Get all of the "VariantContext" objects that span this locus.  A VariantContext represents
      // a line in a VCF file.
      Collection<VariantContext> vcs =
          tracker.getVariantContexts(ref, "variant", null, context.getLocation(), true, false);

      // There may be more than one variant at this locus.  Process them all.
      for (VariantContext vc : vcs) {
        out.println(
            "Hello, ref="
                + vc.getReference()
                + ",alt="
                + vc.getAltAlleleWithHighestAlleleCount()
                + " at "
                + vc.getChr()
                + ":"
                + vc.getStart());
      }

      // Return 1, indicating that we saw a variant.
      return 1;
    }

    // We saw nothing of interest, so return 0.
    return 0;
  }
  @Test
  public void testAnnotationSet() {
    for (final boolean annotate : Arrays.asList(true, false)) {
      for (final String set : Arrays.asList("set", "combine", "x")) {
        final List<String> priority = Arrays.asList("1", "2");
        VariantContext vc1 = makeVC("1", Arrays.asList(Aref, T), VariantContext.PASSES_FILTERS);
        VariantContext vc2 = makeVC("2", Arrays.asList(Aref, T), VariantContext.PASSES_FILTERS);

        final VariantContext merged =
            VariantContextUtils.simpleMerge(
                genomeLocParser,
                Arrays.asList(vc1, vc2),
                priority,
                VariantContextUtils.FilteredRecordMergeType.KEEP_IF_ANY_UNFILTERED,
                VariantContextUtils.GenotypeMergeType.PRIORITIZE,
                annotate,
                false,
                set,
                false,
                false);

        if (annotate)
          Assert.assertEquals(merged.getAttribute(set), VariantContextUtils.MERGE_INTERSECTION);
        else Assert.assertFalse(merged.hasAttribute(set));
      }
    }
  }
  @Test(dataProvider = "mergeFiltered")
  public void testMergeFiltered(MergeFilteredTest cfg) {
    final List<String> priority = vcs2priority(cfg.inputs);
    final VariantContext merged =
        VariantContextUtils.simpleMerge(
            genomeLocParser,
            cfg.inputs,
            priority,
            cfg.type,
            VariantContextUtils.GenotypeMergeType.PRIORITIZE,
            true,
            false,
            "set",
            false,
            false);

    // test alleles are equal
    Assert.assertEquals(merged.getAlleles(), cfg.expected.getAlleles());

    // test set field
    Assert.assertEquals(merged.getAttribute("set"), cfg.setExpected);

    // test filter field
    Assert.assertEquals(merged.getFilters(), cfg.expected.getFilters());
  }
  /**
   * Returns a context identical to this with the REF and ALT alleles reverse complemented.
   *
   * @param vc variant context
   * @return new vc
   */
  public static VariantContext reverseComplement(VariantContext vc) {
    // create a mapping from original allele to reverse complemented allele
    HashMap<Allele, Allele> alleleMap = new HashMap<Allele, Allele>(vc.getAlleles().size());
    for (Allele originalAllele : vc.getAlleles()) {
      Allele newAllele;
      if (originalAllele.isNoCall() || originalAllele.isNull()) newAllele = originalAllele;
      else
        newAllele =
            Allele.create(
                BaseUtils.simpleReverseComplement(originalAllele.getBases()),
                originalAllele.isReference());
      alleleMap.put(originalAllele, newAllele);
    }

    // create new Genotype objects
    GenotypesContext newGenotypes = GenotypesContext.create(vc.getNSamples());
    for (final Genotype genotype : vc.getGenotypes()) {
      List<Allele> newAlleles = new ArrayList<Allele>();
      for (Allele allele : genotype.getAlleles()) {
        Allele newAllele = alleleMap.get(allele);
        if (newAllele == null) newAllele = Allele.NO_CALL;
        newAlleles.add(newAllele);
      }
      newGenotypes.add(Genotype.modifyAlleles(genotype, newAlleles));
    }

    return new VariantContextBuilder(vc).alleles(alleleMap.values()).genotypes(newGenotypes).make();
  }
  private static void mergeGenotypes(
      GenotypesContext mergedGenotypes,
      VariantContext oneVC,
      AlleleMapper alleleMapping,
      boolean uniqifySamples) {
    for (Genotype g : oneVC.getGenotypes()) {
      String name = mergedSampleName(oneVC.getSource(), g.getSampleName(), uniqifySamples);
      if (!mergedGenotypes.containsSample(name)) {
        // only add if the name is new
        Genotype newG = g;

        if (uniqifySamples || alleleMapping.needsRemapping()) {
          final List<Allele> alleles =
              alleleMapping.needsRemapping() ? alleleMapping.remap(g.getAlleles()) : g.getAlleles();
          newG =
              new Genotype(
                  name,
                  alleles,
                  g.getLog10PError(),
                  g.getFilters(),
                  g.getAttributes(),
                  g.isPhased());
        }

        mergedGenotypes.add(newG);
      }
    }
  }
 /**
  * Update the attributes of the attributes map in the VariantContextBuilder to reflect the proper
  * chromosome-based VCF tags based on the current VC produced by builder.make()
  *
  * @param builder the VariantContextBuilder we are updating
  * @param removeStaleValues should we remove stale values from the mapping?
  */
 public static void calculateChromosomeCounts(
     VariantContextBuilder builder, boolean removeStaleValues) {
   final VariantContext vc = builder.make();
   final Map<String, Object> attrs =
       calculateChromosomeCounts(
           vc, new HashMap<String, Object>(vc.getAttributes()), removeStaleValues);
   builder.attributes(attrs);
 }
  private static final List<String> vcs2priority(final Collection<VariantContext> vcs) {
    final List<String> priority = new ArrayList<String>();

    for (final VariantContext vc : vcs) {
      priority.add(vc.getSource());
    }

    return priority;
  }
Esempio n. 15
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    public MergedAllelesData(byte[] intermediateBases, VariantContext vc1, VariantContext vc2) {
      this.mergedAlleles =
          new HashMap<
              AlleleOneAndTwo, Allele>(); // implemented equals() and hashCode() for AlleleOneAndTwo
      this.intermediateBases = intermediateBases;
      this.intermediateLength = this.intermediateBases != null ? this.intermediateBases.length : 0;

      this.ensureMergedAllele(vc1.getReference(), vc2.getReference(), true);
    }
  public static boolean allelesAreSubset(VariantContext vc1, VariantContext vc2) {
    // if all alleles of vc1 are a contained in alleles of vc2, return true
    if (!vc1.getReference().equals(vc2.getReference())) return false;

    for (Allele a : vc1.getAlternateAlleles()) {
      if (!vc2.getAlternateAlleles().contains(a)) return false;
    }

    return true;
  }
Esempio n. 17
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 @Override
 public String toString() {
   return String.format(
       "ExactCall %s:%d alleles=%s nSamples=%s orig.pNonRef=%.2f orig.runtime=%s",
       vc.getChr(),
       vc.getStart(),
       vc.getAlleles(),
       vc.getNSamples(),
       originalCall.getLog10PosteriorOfAFGT0(),
       new AutoFormattingTime(runtime / 1e9).toString());
 }
 private int getIndex(VariantContext vc) {
   int i = priorityListOfVCs.indexOf(vc.getSource());
   if (i == -1)
     throw new UserException.BadArgumentValue(
         Utils.join(",", priorityListOfVCs),
         "Priority list "
             + priorityListOfVCs
             + " doesn't contain variant context "
             + vc.getSource());
   return i;
 }
Esempio n. 19
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  static boolean allSamplesAreMergeable(VariantContext vc1, VariantContext vc2) {
    // Check that each sample's genotype in vc2 is uniquely appendable onto its genotype in vc1:
    for (final Genotype gt1 : vc1.getGenotypes()) {
      Genotype gt2 = vc2.getGenotype(gt1.getSampleName());

      if (!alleleSegregationIsKnown(gt1, gt2)) // can merge if: phased, or if either is a hom
      return false;
    }

    return true;
  }
Esempio n. 20
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 @Requires({
   "vc != null",
   "variable != null",
   "key != null",
   "value != null",
   "callReport != null"
 })
 private void printCallElement(
     final VariantContext vc, final Object variable, final Object key, final Object value) {
   final String loc = String.format("%s:%d", vc.getChr(), vc.getStart());
   callReport.println(Utils.join("\t", Arrays.asList(loc, variable, key, value)));
 }
  private static void verifyUniqueSampleNames(Collection<VariantContext> unsortedVCs) {
    Set<String> names = new HashSet<String>();
    for (VariantContext vc : unsortedVCs) {
      for (String name : vc.getSampleNames()) {
        // System.out.printf("Checking %s %b%n", name, names.contains(name));
        if (names.contains(name))
          throw new UserException(
              "REQUIRE_UNIQUE sample names is true but duplicate names were discovered " + name);
      }

      names.addAll(vc.getSampleNames());
    }
  }
  /**
   * Update the attributes of the attributes map given the VariantContext to reflect the proper
   * chromosome-based VCF tags
   *
   * @param vc the VariantContext
   * @param attributes the attributes map to populate; must not be null; may contain old values
   * @param removeStaleValues should we remove stale values from the mapping?
   * @return the attributes map provided as input, returned for programming convenience
   */
  public static Map<String, Object> calculateChromosomeCounts(
      VariantContext vc, Map<String, Object> attributes, boolean removeStaleValues) {
    final int AN = vc.getCalledChrCount();

    // if everyone is a no-call, remove the old attributes if requested
    if (AN == 0 && removeStaleValues) {
      if (attributes.containsKey(VCFConstants.ALLELE_COUNT_KEY))
        attributes.remove(VCFConstants.ALLELE_COUNT_KEY);
      if (attributes.containsKey(VCFConstants.ALLELE_FREQUENCY_KEY))
        attributes.remove(VCFConstants.ALLELE_FREQUENCY_KEY);
      if (attributes.containsKey(VCFConstants.ALLELE_NUMBER_KEY))
        attributes.remove(VCFConstants.ALLELE_NUMBER_KEY);
      return attributes;
    }

    if (vc.hasGenotypes()) {
      attributes.put(VCFConstants.ALLELE_NUMBER_KEY, AN);

      // if there are alternate alleles, record the relevant tags
      if (vc.getAlternateAlleles().size() > 0) {
        final ArrayList<String> alleleFreqs = new ArrayList<String>();
        final ArrayList<Integer> alleleCounts = new ArrayList<Integer>();
        for (Allele allele : vc.getAlternateAlleles()) {
          int altChromosomes = vc.getCalledChrCount(allele);
          alleleCounts.add(altChromosomes);
          if (AN == 0) {
            alleleFreqs.add("0.0");
          } else {
            // todo -- this is a performance problem
            final String freq =
                String.format(
                    makePrecisionFormatStringFromDenominatorValue((double) AN),
                    ((double) altChromosomes / (double) AN));
            alleleFreqs.add(freq);
          }
        }

        attributes.put(
            VCFConstants.ALLELE_COUNT_KEY,
            alleleCounts.size() == 1 ? alleleCounts.get(0) : alleleCounts);
        attributes.put(
            VCFConstants.ALLELE_FREQUENCY_KEY,
            alleleFreqs.size() == 1 ? alleleFreqs.get(0) : alleleFreqs);
      } else {
        attributes.put(VCFConstants.ALLELE_COUNT_KEY, 0);
        attributes.put(VCFConstants.ALLELE_FREQUENCY_KEY, 0.0);
      }
    }

    return attributes;
  }
Esempio n. 23
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 private Type getType(VariantContext vc) {
   switch (vc.getType()) {
     case SNP:
       return Type.SNP;
     case INDEL:
       for (int l : vc.getIndelLengths()) if (Math.abs(l) > MAX_INDEL_LENGTH) return Type.CNV;
       return Type.INDEL;
     case SYMBOLIC:
       return Type.CNV;
     default:
       // throw new UserException.BadInput("Unexpected variant context type: " + vc);
       return null;
   }
 }
Esempio n. 24
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  private Map<String, Object> calculateIC(final VariantContext vc) {
    final GenotypesContext genotypes =
        (founderIds == null || founderIds.isEmpty())
            ? vc.getGenotypes()
            : vc.getGenotypes(founderIds);
    if (genotypes == null || genotypes.size() < MIN_SAMPLES) return null;

    int idxAA = 0, idxAB = 1, idxBB = 2;

    if (!vc.isBiallelic()) {
      // for non-bliallelic case, do test with most common alt allele.
      // Get then corresponding indeces in GL vectors to retrieve GL of AA,AB and BB.
      int[] idxVector = vc.getGLIndecesOfAlternateAllele(vc.getAltAlleleWithHighestAlleleCount());
      idxAA = idxVector[0];
      idxAB = idxVector[1];
      idxBB = idxVector[2];
    }

    double refCount = 0.0;
    double hetCount = 0.0;
    double homCount = 0.0;
    int N = 0; // number of samples that have likelihoods
    for (final Genotype g : genotypes) {
      if (g.isNoCall() || !g.hasLikelihoods()) continue;

      if (g.getPloidy() != 2) // only work for diploid samples
      continue;

      N++;
      final double[] normalizedLikelihoods =
          MathUtils.normalizeFromLog10(g.getLikelihoods().getAsVector());
      refCount += normalizedLikelihoods[idxAA];
      hetCount += normalizedLikelihoods[idxAB];
      homCount += normalizedLikelihoods[idxBB];
    }

    if (N < MIN_SAMPLES) {
      return null;
    }

    final double p =
        (2.0 * refCount + hetCount)
            / (2.0 * (refCount + hetCount + homCount)); // expected reference allele frequency
    final double q = 1.0 - p; // expected alternative allele frequency
    final double F = 1.0 - (hetCount / (2.0 * p * q * (double) N)); // inbreeding coefficient

    Map<String, Object> map = new HashMap<String, Object>();
    map.put(getKeyNames().get(0), String.format("%.4f", F));
    return map;
  }
  public Map<String, Object> annotate(
      RefMetaDataTracker tracker,
      AnnotatorCompatibleWalker walker,
      ReferenceContext ref,
      AlignmentContext stratifiedContext,
      VariantContext vc,
      Genotype g) {
    if (g == null || !g.isCalled()) return null;

    if (vc.isSNP()) return annotateSNP(stratifiedContext, vc);
    if (vc.isIndel()) return annotateIndel(stratifiedContext, vc);

    return null;
  }
  public static VariantContext purgeUnallowedGenotypeAttributes(
      VariantContext vc, Set<String> allowedAttributes) {
    if (allowedAttributes == null) return vc;

    GenotypesContext newGenotypes = GenotypesContext.create(vc.getNSamples());
    for (final Genotype genotype : vc.getGenotypes()) {
      Map<String, Object> attrs = new HashMap<String, Object>();
      for (Map.Entry<String, Object> attr : genotype.getAttributes().entrySet()) {
        if (allowedAttributes.contains(attr.getKey())) attrs.put(attr.getKey(), attr.getValue());
      }
      newGenotypes.add(Genotype.modifyAttributes(genotype, attrs));
    }

    return new VariantContextBuilder(vc).genotypes(newGenotypes).make();
  }
  private static Allele determineReferenceAllele(List<VariantContext> VCs) {
    Allele ref = null;

    for (VariantContext vc : VCs) {
      Allele myRef = vc.getReference();
      if (ref == null || ref.length() < myRef.length()) ref = myRef;
      else if (ref.length() == myRef.length() && !ref.equals(myRef))
        throw new UserException.BadInput(
            String.format(
                "The provided variant file(s) have inconsistent references for the same position(s) at %s:%d, %s vs. %s",
                vc.getChr(), vc.getStart(), ref, myRef));
    }

    return ref;
  }
Esempio n. 28
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 /**
  * Copy constructor
  *
  * @param other the VariantContext to copy
  */
 protected VariantContext(VariantContext other) {
   this(
       other.getSource(),
       other.getID(),
       other.getChr(),
       other.getStart(),
       other.getEnd(),
       other.getAlleles(),
       other.getGenotypes(),
       other.getLog10PError(),
       other.getFiltersMaybeNull(),
       other.getAttributes(),
       other.REFERENCE_BASE_FOR_INDEL,
       NO_VALIDATION);
 }
  // decide whether we are currently processing SNPs, indels, neither, or both
  private List<GenotypeLikelihoodsCalculationModel.Model> getGLModelsToUse(
      final RefMetaDataTracker tracker,
      final ReferenceContext refContext,
      final AlignmentContext rawContext) {

    final List<GenotypeLikelihoodsCalculationModel.Model> models =
        new ArrayList<GenotypeLikelihoodsCalculationModel.Model>(2);
    String modelPrefix = "";
    if (UAC.GLmodel.name().toUpperCase().contains("BOTH"))
      modelPrefix = UAC.GLmodel.name().toUpperCase().replaceAll("BOTH", "");

    if (!UAC.GLmodel.name().contains(GPSTRING)
        && UAC.samplePloidy != VariantContextUtils.DEFAULT_PLOIDY)
      modelPrefix = GPSTRING + modelPrefix;

    // if we're genotyping given alleles and we have a requested SNP at this position, do SNP
    if (UAC.GenotypingMode
        == GenotypeLikelihoodsCalculationModel.GENOTYPING_MODE.GENOTYPE_GIVEN_ALLELES) {
      final VariantContext vcInput =
          getVCFromAllelesRod(
              tracker, refContext, rawContext.getLocation(), false, logger, UAC.alleles);
      if (vcInput == null) return models;

      if (vcInput.isSNP()) {
        // ignore SNPs if the user chose INDEL mode only
        if (UAC.GLmodel.name().toUpperCase().contains("BOTH")
            || UAC.GLmodel.name().toUpperCase().contains("SNP"))
          models.add(GenotypeLikelihoodsCalculationModel.Model.valueOf(modelPrefix + "SNP"));
      } else if (vcInput.isIndel() || vcInput.isMixed()) {
        // ignore INDELs if the user chose SNP mode only
        if (UAC.GLmodel.name().toUpperCase().contains("BOTH")
            || UAC.GLmodel.name().toUpperCase().contains("INDEL"))
          models.add(GenotypeLikelihoodsCalculationModel.Model.valueOf(modelPrefix + "INDEL"));
      }
      // No support for other types yet
    } else {
      if (UAC.GLmodel.name().toUpperCase().contains("BOTH")) {
        models.add(GenotypeLikelihoodsCalculationModel.Model.valueOf(modelPrefix + "SNP"));
        models.add(GenotypeLikelihoodsCalculationModel.Model.valueOf(modelPrefix + "INDEL"));
      } else {
        models.add(
            GenotypeLikelihoodsCalculationModel.Model.valueOf(
                modelPrefix + UAC.GLmodel.name().toUpperCase()));
      }
    }

    return models;
  }
Esempio n. 30
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  private static List<String> calcVCFGenotypeKeys(VariantContext vc) {
    Set<String> keys = new HashSet<String>();

    boolean sawGoodGT = false;
    boolean sawGoodQual = false;
    boolean sawGenotypeFilter = false;
    for (Genotype g : vc.getGenotypes().values()) {
      keys.addAll(g.getAttributes().keySet());
      if (g.isAvailable()) sawGoodGT = true;
      if (g.hasNegLog10PError()) sawGoodQual = true;
      if (g.isFiltered() && g.isCalled()) sawGenotypeFilter = true;
    }

    if (sawGoodQual) keys.add(VCFConstants.GENOTYPE_QUALITY_KEY);

    if (sawGenotypeFilter) keys.add(VCFConstants.GENOTYPE_FILTER_KEY);

    List<String> sortedList = ParsingUtils.sortList(new ArrayList<String>(keys));

    // make sure the GT is first
    if (sawGoodGT) {
      List<String> newList = new ArrayList<String>(sortedList.size() + 1);
      newList.add(VCFConstants.GENOTYPE_KEY);
      newList.addAll(sortedList);
      sortedList = newList;
    }

    return sortedList;
  }