/** * Fills the PSM specific map. * * @param inputMap The input map * @param waitingHandler the handler displaying feedback to the user * @param shotgunProtocol information about the protocol * @param identificationParameters the identification parameters * @throws java.sql.SQLException exception thrown whenever an error occurred while interacting * with the back-end database * @throws java.io.IOException exception thrown whenever an error occurred while reading an * external file * @throws java.lang.ClassNotFoundException exception thrown whenever an error occurred while * deserializing an object * @throws java.lang.InterruptedException exception thrown whenever a threading error occurred * @throws uk.ac.ebi.jmzml.xml.io.MzMLUnmarshallerException exception thrown whenever an error * occurred while reading an mzML file */ public void selectBestHitAndFillPsmMap( InputMap inputMap, WaitingHandler waitingHandler, ShotgunProtocol shotgunProtocol, IdentificationParameters identificationParameters) throws SQLException, IOException, ClassNotFoundException, InterruptedException, MzMLUnmarshallerException { waitingHandler.setSecondaryProgressCounterIndeterminate(false); waitingHandler.setMaxSecondaryProgressCounter(identification.getSpectrumIdentificationSize()); PeptideSpectrumAnnotator spectrumAnnotator = new PeptideSpectrumAnnotator(); boolean multiSE = inputMap.isMultipleAlgorithms(); SequenceMatchingPreferences sequenceMatchingPreferences = identificationParameters.getSequenceMatchingPreferences(); AnnotationSettings annotationPreferences = identificationParameters.getAnnotationPreferences(); PeptideAssumptionFilter idFilter = identificationParameters.getPeptideAssumptionFilter(); // Keep a map of the spectrum keys grouped by peptide HashMap<String, ArrayList<String>> orderedPsmMap = null; if (MemoryConsumptionStatus.memoryUsed() < 0.8) { orderedPsmMap = new HashMap<String, ArrayList<String>>( identification.getSpectrumIdentificationMap().size()); } PSParameter psParameter = new PSParameter(); for (String spectrumFileName : identification.getSpectrumFiles()) { HashMap<String, ArrayList<String>> keysMap = null; if (orderedPsmMap != null) { keysMap = new HashMap<String, ArrayList<String>>(); } PsmIterator psmIterator = identification.getPsmIterator(spectrumFileName, null, true, waitingHandler); while (psmIterator.hasNext()) { SpectrumMatch advocateMatch = psmIterator.next(); String spectrumKey = advocateMatch.getKey(); // map of the peptide first hits for this spectrum: score -> max protein count -> max search // engine votes -> amino acids annotated -> min mass deviation -> peptide sequence HashMap< Double, HashMap< Integer, HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>>> peptideAssumptions = new HashMap< Double, HashMap< Integer, HashMap< Integer, HashMap< Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>>>(); // map of the tag first hits: score -> assumptions HashMap<Double, ArrayList<TagAssumption>> tagAssumptions = new HashMap<Double, ArrayList<TagAssumption>>(); ArrayList<String> identifications = new ArrayList<String>(); HashMap<Integer, HashMap<Double, ArrayList<SpectrumIdentificationAssumption>>> assumptions = identification.getAssumptions(spectrumKey); for (int searchEngine1 : assumptions.keySet()) { HashMap<Double, ArrayList<SpectrumIdentificationAssumption>> advocate1Map = assumptions.get(searchEngine1); double bestEvalue = Collections.min(advocate1Map.keySet()); for (SpectrumIdentificationAssumption assumption1 : advocate1Map.get(bestEvalue)) { if (assumption1 instanceof PeptideAssumption) { PeptideAssumption peptideAssumption1 = (PeptideAssumption) assumption1; String id = peptideAssumption1.getPeptide().getKey(); if (!identifications.contains(id)) { psParameter = (PSParameter) peptideAssumption1.getUrParam(psParameter); double p; if (multiSE && sequenceFactory.concatenatedTargetDecoy()) { p = psParameter.getSearchEngineProbability(); } else { p = peptideAssumption1.getScore(); } int nSE = 1; int proteinMax = 1; for (String protein : peptideAssumption1 .getPeptide() .getParentProteins(sequenceMatchingPreferences)) { Integer tempCount = proteinCount.get(protein); if (tempCount != null && tempCount > proteinMax) { proteinMax = tempCount; } } for (int searchEngine2 : assumptions.keySet()) { if (searchEngine1 != searchEngine2) { HashMap<Double, ArrayList<SpectrumIdentificationAssumption>> advocate2Map = assumptions.get(searchEngine2); boolean found = false; ArrayList<Double> eValues2 = new ArrayList<Double>(advocate2Map.keySet()); Collections.sort(eValues2); for (double eValue2 : eValues2) { for (SpectrumIdentificationAssumption assumption2 : advocate2Map.get(eValue2)) { if (assumption2 instanceof PeptideAssumption) { PeptideAssumption peptideAssumption2 = (PeptideAssumption) assumption2; if (peptideAssumption1 .getPeptide() .isSameSequenceAndModificationStatus( peptideAssumption2.getPeptide(), sequenceMatchingPreferences)) { PSParameter psParameter2 = (PSParameter) peptideAssumption2.getUrParam(psParameter); p = p * psParameter2.getSearchEngineProbability(); nSE++; found = true; break; } } } if (found) { break; } } } } identifications.add(id); HashMap< Integer, HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>> pMap = peptideAssumptions.get(p); if (pMap == null) { pMap = new HashMap< Integer, HashMap< Integer, HashMap< Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>>( advocate1Map.size()); peptideAssumptions.put(p, pMap); } HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>> proteinMaxMap = pMap.get(proteinMax); if (proteinMaxMap == null) { proteinMaxMap = new HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>(1); pMap.put(proteinMax, proteinMaxMap); } HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>> nSeMap = proteinMaxMap.get(nSE); if (nSeMap == null) { nSeMap = new HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>(1); proteinMaxMap.put(nSE, nSeMap); HashMap<Double, HashMap<String, PeptideAssumption>> coverageMap = new HashMap<Double, HashMap<String, PeptideAssumption>>(1); nSeMap.put(-1, coverageMap); HashMap<String, PeptideAssumption> assumptionMap = new HashMap<String, PeptideAssumption>(1); coverageMap.put(-1.0, assumptionMap); assumptionMap.put( peptideAssumption1.getPeptide().getSequenceWithLowerCasePtms(), peptideAssumption1); } else { MSnSpectrum spectrum = (MSnSpectrum) spectrumFactory.getSpectrum(spectrumKey); HashMap<Double, HashMap<String, PeptideAssumption>> coverageMap = nSeMap.get(-1); if (coverageMap != null) { HashMap<String, PeptideAssumption> assumptionMap = coverageMap.get(-1.0); for (PeptideAssumption tempAssumption : assumptionMap.values()) { // There should be only one Peptide peptide = tempAssumption.getPeptide(); SpecificAnnotationSettings specificAnnotationPreferences = annotationPreferences.getSpecificAnnotationPreferences( spectrum.getSpectrumKey(), tempAssumption, identificationParameters.getSequenceMatchingPreferences(), identificationParameters .getPtmScoringPreferences() .getSequenceMatchingPreferences()); HashMap<Integer, ArrayList<IonMatch>> coveredAminoAcids = spectrumAnnotator.getCoveredAminoAcids( annotationPreferences, specificAnnotationPreferences, (MSnSpectrum) spectrum, peptide); int nIons = coveredAminoAcids.size(); nSeMap.put(nIons, coverageMap); } nSeMap.remove(-1); } Peptide peptide = peptideAssumption1.getPeptide(); SpecificAnnotationSettings specificAnnotationPreferences = annotationPreferences.getSpecificAnnotationPreferences( spectrum.getSpectrumKey(), peptideAssumption1, identificationParameters.getSequenceMatchingPreferences(), identificationParameters .getPtmScoringPreferences() .getSequenceMatchingPreferences()); HashMap<Integer, ArrayList<IonMatch>> coveredAminoAcids = spectrumAnnotator.getCoveredAminoAcids( annotationPreferences, specificAnnotationPreferences, (MSnSpectrum) spectrum, peptide); int nIons = coveredAminoAcids.size(); coverageMap = nSeMap.get(nIons); if (coverageMap == null) { coverageMap = new HashMap<Double, HashMap<String, PeptideAssumption>>(1); HashMap<String, PeptideAssumption> assumptionMap = new HashMap<String, PeptideAssumption>(1); assumptionMap.put( peptideAssumption1.getPeptide().getSequenceWithLowerCasePtms(), peptideAssumption1); coverageMap.put(-1.0, assumptionMap); nSeMap.put(nIons, coverageMap); } else { HashMap<String, PeptideAssumption> assumptionMap = coverageMap.get(-1.0); if (assumptionMap != null) { for (PeptideAssumption tempAssumption : assumptionMap.values()) { // There should be only one double massError = Math.abs( tempAssumption.getDeltaMass( spectrum.getPrecursor().getMz(), shotgunProtocol.isMs1ResolutionPpm())); coverageMap.put(massError, assumptionMap); } coverageMap.remove(-1.0); } double massError = Math.abs( peptideAssumption1.getDeltaMass( spectrum.getPrecursor().getMz(), shotgunProtocol.isMs1ResolutionPpm())); assumptionMap = coverageMap.get(massError); if (assumptionMap == null) { assumptionMap = new HashMap<String, PeptideAssumption>(1); coverageMap.put(massError, assumptionMap); } assumptionMap.put( peptideAssumption1.getPeptide().getSequenceWithLowerCasePtms(), peptideAssumption1); } } } } else if (assumption1 instanceof TagAssumption) { TagAssumption tagAssumption = (TagAssumption) assumption1; ArrayList<TagAssumption> assumptionList = tagAssumptions.get(bestEvalue); if (assumptionList == null) { assumptionList = new ArrayList<TagAssumption>(); tagAssumptions.put(bestEvalue, assumptionList); } assumptionList.add(tagAssumption); } } } SpectrumMatch spectrumMatch = new SpectrumMatch(spectrumKey); if (!peptideAssumptions.isEmpty()) { PeptideAssumption bestPeptideAssumption = null; ArrayList<Double> ps = new ArrayList<Double>(peptideAssumptions.keySet()); Collections.sort(ps); double retainedP = 0; for (double p : ps) { retainedP = p; HashMap< Integer, HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>>> pMap = peptideAssumptions.get(p); ArrayList<Integer> proteinMaxs = new ArrayList<Integer>(pMap.keySet()); Collections.sort(proteinMaxs, Collections.reverseOrder()); for (int proteinMax : proteinMaxs) { HashMap< Integer, HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>>> proteinMaxMap = pMap.get(proteinMax); ArrayList<Integer> nSEs = new ArrayList<Integer>(proteinMaxMap.keySet()); Collections.sort(nSEs, Collections.reverseOrder()); for (int nSE : nSEs) { HashMap<Integer, HashMap<Double, HashMap<String, PeptideAssumption>>> nSeMap = proteinMaxMap.get(nSE); ArrayList<Integer> coverages = new ArrayList<Integer>(nSeMap.keySet()); Collections.sort(coverages, Collections.reverseOrder()); for (Integer coverage : coverages) { HashMap<Double, HashMap<String, PeptideAssumption>> coverageMap = nSeMap.get(coverage); ArrayList<Double> minErrors = new ArrayList<Double>(coverageMap.keySet()); Collections.sort(minErrors); for (double minError : minErrors) { HashMap<String, PeptideAssumption> bestPeptideAssumptions = coverageMap.get(minError); ArrayList<String> sequences = new ArrayList<String>(bestPeptideAssumptions.keySet()); Collections.sort(sequences); for (String sequence : sequences) { PeptideAssumption peptideAssumption = bestPeptideAssumptions.get(sequence); if (idFilter.validateProteins( peptideAssumption.getPeptide(), sequenceMatchingPreferences)) { bestPeptideAssumption = peptideAssumption; break; } } if (bestPeptideAssumption != null) { break; } } if (bestPeptideAssumption != null) { break; } } if (bestPeptideAssumption != null) { break; } } if (bestPeptideAssumption != null) { break; } } if (bestPeptideAssumption != null) { break; } } if (bestPeptideAssumption != null) { if (multiSE) { // try to find the most likely modification localization based on the search engine // results HashMap<PeptideAssumption, ArrayList<Double>> assumptionPEPs = new HashMap<PeptideAssumption, ArrayList<Double>>(); String bestAssumptionKey = bestPeptideAssumption.getPeptide().getMatchingKey(sequenceMatchingPreferences); for (int searchEngine : assumptions.keySet()) { boolean found = false; HashMap<Double, ArrayList<SpectrumIdentificationAssumption>> advocateMap = assumptions.get(searchEngine); ArrayList<Double> eValues = new ArrayList<Double>(advocateMap.keySet()); Collections.sort(eValues); for (double eValue : eValues) { for (SpectrumIdentificationAssumption assumption : advocateMap.get(eValue)) { if (assumption instanceof PeptideAssumption) { PeptideAssumption peptideAssumption = (PeptideAssumption) assumption; if (peptideAssumption .getPeptide() .getMatchingKey(sequenceMatchingPreferences) .equals(bestAssumptionKey)) { found = true; boolean found2 = false; for (PeptideAssumption assumption1 : assumptionPEPs.keySet()) { if (assumption1 .getPeptide() .sameModificationsAs(peptideAssumption.getPeptide())) { found2 = true; psParameter = (PSParameter) assumption.getUrParam(psParameter); ArrayList<Double> peps = assumptionPEPs.get(assumption1); peps.add(psParameter.getSearchEngineProbability()); break; } } if (!found2) { ArrayList<Double> peps = new ArrayList<Double>(1); assumptionPEPs.put(peptideAssumption, peps); psParameter = (PSParameter) assumption.getUrParam(psParameter); peps.add(psParameter.getSearchEngineProbability()); } } } } if (found) { break; } } } Double bestSeP = null; int nSe = -1; for (PeptideAssumption peptideAssumption : assumptionPEPs.keySet()) { ArrayList<Double> peps = assumptionPEPs.get(peptideAssumption); Double sep = Collections.min(peps); if (bestSeP == null || bestSeP > sep) { bestSeP = sep; nSe = peps.size(); bestPeptideAssumption = peptideAssumption; } else if (peps.size() > nSe) { if (sep != null && (Math.abs(sep - bestSeP) <= 1e-10)) { nSe = peps.size(); bestPeptideAssumption = peptideAssumption; } } } } // create a PeptideShaker match based on the best search engine match Peptide sePeptide = bestPeptideAssumption.getPeptide(); ArrayList<String> psProteins = new ArrayList<String>(sePeptide.getParentProteins(sequenceMatchingPreferences)); ArrayList<ModificationMatch> psModificationMatches = null; if (sePeptide.isModified()) { psModificationMatches = new ArrayList<ModificationMatch>(sePeptide.getNModifications()); for (ModificationMatch seModMatch : sePeptide.getModificationMatches()) { psModificationMatches.add( new ModificationMatch( seModMatch.getTheoreticPtm(), seModMatch.isVariable(), seModMatch.getModificationSite())); } } Peptide psPeptide = new Peptide(sePeptide.getSequence(), psModificationMatches); psPeptide.setParentProteins(psProteins); PeptideAssumption psAssumption = new PeptideAssumption( psPeptide, 1, Advocate.peptideShaker.getIndex(), bestPeptideAssumption.getIdentificationCharge(), retainedP); spectrumMatch.setBestPeptideAssumption(psAssumption); if (orderedPsmMap != null) { String peptideKey = psPeptide.getMatchingKey(sequenceMatchingPreferences); ArrayList<String> spectrumKeys = keysMap.get(peptideKey); if (spectrumKeys == null) { spectrumKeys = new ArrayList<String>(); keysMap.put(peptideKey, spectrumKeys); } spectrumKeys.add(spectrumKey); } psParameter = new PSParameter(); psParameter.setSpectrumProbabilityScore(retainedP); PSParameter matchParameter = (PSParameter) bestPeptideAssumption.getUrParam(psParameter); psParameter.setSearchEngineProbability(matchParameter.getSearchEngineProbability()); psParameter.setAlgorithmDeltaPEP(matchParameter.getAlgorithmDeltaPEP()); psParameter.setDeltaPEP(matchParameter.getDeltaPEP()); matchesValidator .getPsmMap() .addPoint( psParameter.getPsmProbabilityScore(), spectrumMatch, sequenceMatchingPreferences); psParameter.setSpecificMapKey( spectrumMatch.getBestPeptideAssumption().getIdentificationCharge().value + ""); identification.addSpectrumMatchParameter(spectrumKey, psParameter); identification.updateSpectrumMatch(spectrumMatch); } } if (!tagAssumptions.isEmpty()) { ArrayList<Double> evalues = new ArrayList<Double>(tagAssumptions.keySet()); Double bestEvalue = Collections.min(evalues); TagAssumption bestAssumption = tagAssumptions.get(bestEvalue).get(0); spectrumMatch.setBestTagAssumption(bestAssumption); identification.updateSpectrumMatch(spectrumMatch); if (spectrumMatch.getBestPeptideAssumption() == null) { psParameter = new PSParameter(); if (!multiSE) { psParameter.setSpectrumProbabilityScore(bestEvalue); } PSParameter matchParameter = (PSParameter) bestAssumption.getUrParam(psParameter); psParameter.setSearchEngineProbability(matchParameter.getSearchEngineProbability()); psParameter.setAlgorithmDeltaPEP(matchParameter.getAlgorithmDeltaPEP()); psParameter.setDeltaPEP(matchParameter.getDeltaPEP()); psParameter.setSpecificMapKey( spectrumMatch.getBestTagAssumption().getIdentificationCharge().value + ""); identification.addSpectrumMatchParameter(spectrumKey, psParameter); } } waitingHandler.increaseSecondaryProgressCounter(); if (waitingHandler.isRunCanceled()) { return; } } if (orderedPsmMap != null) { ArrayList<String> orderedKeys = new ArrayList<String>( identification.getSpectrumIdentification(spectrumFileName).size()); for (ArrayList<String> keys : keysMap.values()) { orderedKeys.addAll(keys); } orderedPsmMap.put(spectrumFileName, orderedKeys); if (MemoryConsumptionStatus.memoryUsed() > 0.9) { orderedPsmMap = null; } } } if (orderedPsmMap != null) { metrics.setOrderedSpectrumKeys(orderedPsmMap); } // the protein count map is no longer needed proteinCount.clear(); waitingHandler.setSecondaryProgressCounterIndeterminate(true); }
/** * Indicates whether the match designated by the match key validates the given item using the * given comparator and value threshold. * * @param itemName the name of the item to filter on * @param filterItemComparator the comparator to use * @param value the value to use as a threshold * @param spectrumKey the key of the match of interest * @param peptideAssumption the assumption to validate * @param identification the identification objects where to get identification matches from * @param identificationFeaturesGenerator the identification feature generator where to get * identification features * @param identificationParameters the identification parameters used * @param peptideSpectrumAnnotator the annotator to use to annotate spectra when filtering on PSM * or assumptions * @return a boolean indicating whether the match designated by the protein key validates the * given item using the given comparator and value threshold. * @throws java.io.IOException exception thrown whenever an exception occurred while reading or * writing a file * @throws java.lang.InterruptedException exception thrown whenever a threading issue occurred * while validating that the match passes the filter * @throws java.lang.ClassNotFoundException exception thrown whenever an error occurred while * deserilalizing a match * @throws java.sql.SQLException exception thrown whenever an error occurred while interacting * with a database * @throws uk.ac.ebi.jmzml.xml.io.MzMLUnmarshallerException exception thrown whenever an error * occurred while reading an mzML file * @throws org.apache.commons.math.MathException exception thrown whenever an error occurred while * doing statistics on a distribution */ public boolean isValidated( String itemName, FilterItemComparator filterItemComparator, Object value, String spectrumKey, PeptideAssumption peptideAssumption, Identification identification, IdentificationFeaturesGenerator identificationFeaturesGenerator, IdentificationParameters identificationParameters, PeptideSpectrumAnnotator peptideSpectrumAnnotator) throws IOException, InterruptedException, ClassNotFoundException, SQLException, MzMLUnmarshallerException, MathException { AssumptionFilterItem filterItem = AssumptionFilterItem.getItem(itemName); if (filterItem == null) { throw new IllegalArgumentException( "Filter item " + itemName + "not recognized as spectrum assumption filter item."); } String input = value.toString(); switch (filterItem) { case precrusorMz: Precursor precursor = SpectrumFactory.getInstance().getPrecursor(spectrumKey); Double mz = precursor.getMz(); return filterItemComparator.passes(input, mz.toString()); case precrusorRT: precursor = SpectrumFactory.getInstance().getPrecursor(spectrumKey); Double rt = precursor.getRt(); return filterItemComparator.passes(input, rt.toString()); case precrusorCharge: Integer charge = peptideAssumption.getIdentificationCharge().value; return filterItemComparator.passes(input, charge.toString()); case precrusorMzErrorDa: precursor = SpectrumFactory.getInstance().getPrecursor(spectrumKey); SearchParameters searchParameters = identificationParameters.getSearchParameters(); Double mzError = Math.abs( peptideAssumption.getDeltaMass( precursor.getMz(), false, searchParameters.getMinIsotopicCorrection(), searchParameters.getMaxIsotopicCorrection())); return filterItemComparator.passes(input, mzError.toString()); case precrusorMzErrorPpm: searchParameters = identificationParameters.getSearchParameters(); precursor = SpectrumFactory.getInstance().getPrecursor(spectrumKey); mzError = Math.abs( peptideAssumption.getDeltaMass( precursor.getMz(), true, searchParameters.getMinIsotopicCorrection(), searchParameters.getMaxIsotopicCorrection())); return filterItemComparator.passes(input, mzError.toString()); case precrusorMzErrorStat: searchParameters = identificationParameters.getSearchParameters(); precursor = SpectrumFactory.getInstance().getPrecursor(spectrumKey); mzError = peptideAssumption.getDeltaMass( precursor.getMz(), identificationParameters.getSearchParameters().isPrecursorAccuracyTypePpm(), searchParameters.getMinIsotopicCorrection(), searchParameters.getMaxIsotopicCorrection()); NonSymmetricalNormalDistribution precDeviationDistribution = identificationFeaturesGenerator.getMassErrorDistribution( Spectrum.getSpectrumFile(spectrumKey)); Double p; if (mzError > precDeviationDistribution.getMean()) { p = precDeviationDistribution.getDescendingCumulativeProbabilityAt(mzError); } else { p = precDeviationDistribution.getCumulativeProbabilityAt(mzError); } return filterItemComparator.passes(input, p.toString()); case sequenceCoverage: SpectrumFactory spectrumFactory = SpectrumFactory.getInstance(); MSnSpectrum spectrum = (MSnSpectrum) spectrumFactory.getSpectrum(spectrumKey); Peptide peptide = peptideAssumption.getPeptide(); AnnotationSettings annotationPreferences = identificationParameters.getAnnotationPreferences(); SpecificAnnotationSettings specificAnnotationPreferences = annotationPreferences.getSpecificAnnotationPreferences( spectrum.getSpectrumKey(), peptideAssumption, identificationParameters.getSequenceMatchingPreferences(), identificationParameters .getPtmScoringPreferences() .getSequenceMatchingPreferences()); HashMap<Integer, ArrayList<IonMatch>> matches = peptideSpectrumAnnotator.getCoveredAminoAcids( annotationPreferences, specificAnnotationPreferences, (MSnSpectrum) spectrum, peptide); double nCovered = 0; int nAA = peptide.getSequence().length(); for (int i = 0; i <= nAA; i++) { ArrayList<IonMatch> matchesAtAa = matches.get(i); if (matchesAtAa != null && !matchesAtAa.isEmpty()) { nCovered++; } } Double coverage = 100.0 * nCovered / nAA; return filterItemComparator.passes(input, coverage.toString()); case algorithmScore: Double score = peptideAssumption.getRawScore(); if (score == null) { score = peptideAssumption.getScore(); } return filterItemComparator.passes(input, score.toString()); case fileNames: return filterItemComparator.passes(input, Spectrum.getSpectrumFile(spectrumKey)); case confidence: PSParameter psParameter = new PSParameter(); psParameter = (PSParameter) identification.getPeptideMatchParameter(spectrumKey, psParameter); Double confidence = psParameter.getProteinConfidence(); return filterItemComparator.passes(input, confidence.toString()); case validationStatus: psParameter = new PSParameter(); psParameter = (PSParameter) identification.getPeptideMatchParameter(spectrumKey, psParameter); Integer validation = psParameter.getMatchValidationLevel().getIndex(); return filterItemComparator.passes(input, validation.toString()); case stared: psParameter = new PSParameter(); psParameter = (PSParameter) identification.getPeptideMatchParameter(spectrumKey, psParameter); String starred; if (psParameter.isStarred()) { starred = FilterItemComparator.trueFalse[0]; } else { starred = FilterItemComparator.trueFalse[1]; } return filterItemComparator.passes(input, starred); default: throw new IllegalArgumentException( "Protein filter not implemented for item " + filterItem.name + "."); } }