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Example 6 with GeneFeature

use of io.repseq.core.GeneFeature in project mixcr by milaboratory.

the class FieldExtractors method getFields.

public static synchronized Field[] getFields() {
    if (descriptors == null) {
        List<Field> descriptorsList = new ArrayList<>();
        // Number of targets
        descriptorsList.add(new PL_O("-targets", "Export number of targets", "Number of targets", "numberOfTargets") {

            @Override
            protected String extract(VDJCObject object) {
                return Integer.toString(object.numberOfTargets());
            }
        });
        // Best hits
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Hit", "Export best " + l + " hit", "Best " + l + " hit", "best" + l + "Hit") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit bestHit = object.getBestHit(type);
                    if (bestHit == null)
                        return NULL;
                    return bestHit.getGene().getName();
                }
            });
        }
        // Best gene
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Gene", "Export best " + l + " hit gene name (e.g. TRBV12-3 for TRBV12-3*00)", "Best " + l + " gene", "best" + l + "Gene") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit bestHit = object.getBestHit(type);
                    if (bestHit == null)
                        return NULL;
                    return bestHit.getGene().getGeneName();
                }
            });
        }
        // Best family
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Family", "Export best " + l + " hit family name (e.g. TRBV12 for TRBV12-3*00)", "Best " + l + " family", "best" + l + "Family") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit bestHit = object.getBestHit(type);
                    if (bestHit == null)
                        return NULL;
                    return bestHit.getGene().getFamilyName();
                }
            });
        }
        // Best hit score
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "HitScore", "Export score for best " + l + " hit", "Best " + l + " hit score", "best" + l + "HitScore") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit bestHit = object.getBestHit(type);
                    if (bestHit == null)
                        return NULL;
                    return String.valueOf(bestHit.getScore());
                }
            });
        }
        // All hits
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "HitsWithScore", "Export all " + l + " hits with score", "All " + l + " hits", "all" + l + "HitsWithScore") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit[] hits = object.getHits(type);
                    if (hits.length == 0)
                        return "";
                    StringBuilder sb = new StringBuilder();
                    for (int i = 0; ; i++) {
                        sb.append(hits[i].getGene().getName()).append("(").append(SCORE_FORMAT.format(hits[i].getScore())).append(")");
                        if (i == hits.length - 1)
                            break;
                        sb.append(",");
                    }
                    return sb.toString();
                }
            });
        }
        // All hits without score
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Hits", "Export all " + l + " hits", "All " + l + " Hits", "all" + l + "Hits") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit[] hits = object.getHits(type);
                    if (hits.length == 0)
                        return "";
                    StringBuilder sb = new StringBuilder();
                    for (int i = 0; ; i++) {
                        sb.append(hits[i].getGene().getName());
                        if (i == hits.length - 1)
                            break;
                        sb.append(",");
                    }
                    return sb.toString();
                }
            });
        }
        // All gene names
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new StringExtractor("-" + Character.toLowerCase(l) + "Genes", "Export all " + l + " gene names (e.g. TRBV12-3 for TRBV12-3*00)", "All " + l + " genes", "all" + l + "Genes", type) {

                @Override
                String extractStringForHit(VDJCHit hit) {
                    return hit.getGene().getGeneName();
                }
            });
        }
        // All families
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new StringExtractor("-" + Character.toLowerCase(l) + "Families", "Export all " + l + " gene family anmes (e.g. TRBV12 for TRBV12-3*00)", "All " + l + " families", "all" + l + "Families", type) {

                @Override
                String extractStringForHit(VDJCHit hit) {
                    return hit.getGene().getFamilyName();
                }
            });
        }
        // Best alignment
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Alignment", "Export best " + l + " alignment", "Best " + l + " alignment", "best" + l + "Alignment") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit bestHit = object.getBestHit(type);
                    if (bestHit == null)
                        return NULL;
                    StringBuilder sb = new StringBuilder();
                    for (int i = 0; ; i++) {
                        Alignment<NucleotideSequence> alignment = bestHit.getAlignment(i);
                        if (alignment == null)
                            sb.append(NULL);
                        else
                            sb.append(alignment.toCompactString());
                        if (i == object.numberOfTargets() - 1)
                            break;
                        sb.append(",");
                    }
                    return sb.toString();
                }
            });
        }
        // All alignments
        for (final GeneType type : GeneType.values()) {
            char l = type.getLetter();
            descriptorsList.add(new PL_O("-" + Character.toLowerCase(l) + "Alignments", "Export all " + l + " alignments", "All " + l + " alignments", "all" + l + "Alignments") {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit[] hits = object.getHits(type);
                    if (hits.length == 0)
                        return "";
                    StringBuilder sb = new StringBuilder();
                    for (int j = 0; ; ++j) {
                        for (int i = 0; ; i++) {
                            Alignment<NucleotideSequence> alignment = hits[j].getAlignment(i);
                            if (alignment == null)
                                sb.append(NULL);
                            else
                                sb.append(alignment.toCompactString());
                            if (i == object.numberOfTargets() - 1)
                                break;
                            sb.append(',');
                        }
                        if (j == hits.length - 1)
                            break;
                        sb.append(';');
                    }
                    return sb.toString();
                }
            });
        }
        descriptorsList.add(new FeatureExtractors.NSeqExtractor("-nFeature", "Export nucleotide sequence of specified gene feature", "N. Seq. ", "nSeq") {

            @Override
            public String convert(NSequenceWithQuality seq) {
                return seq.getSequence().toString();
            }
        });
        descriptorsList.add(new FeatureExtractors.NSeqExtractor("-qFeature", "Export quality string of specified gene feature", "Qual. ", "qual") {

            @Override
            public String convert(NSequenceWithQuality seq) {
                return seq.getQuality().toString();
            }
        });
        descriptorsList.add(new FeatureExtractors.WithHeader("-aaFeature", "Export amino acid sequence of specified gene feature", 1, new String[] { "AA. Seq. " }, new String[] { "aaSeq" }) {

            @Override
            protected String extractValue(VDJCObject object, GeneFeature[] parameters) {
                GeneFeature geneFeature = parameters[parameters.length - 1];
                NSequenceWithQuality feature = object.getFeature(geneFeature);
                if (feature == null)
                    return NULL;
                int targetId = object.getTargetContainingFeature(geneFeature);
                TranslationParameters tr = targetId == -1 ? TranslationParameters.FromLeftWithIncompleteCodon : object.getPartitionedTarget(targetId).getPartitioning().getTranslationParameters(geneFeature);
                if (tr == null)
                    return NULL;
                return AminoAcidSequence.translate(feature.getSequence(), tr).toString();
            }
        });
        // descriptorsList.add(new FeatureExtractorDescriptor("-aaFeatureFromLeft", "Export amino acid sequence of " +
        // "specified gene feature starting from the leftmost nucleotide (differs from -aaFeature only for " +
        // "sequences which length are not multiple of 3)", "AA. Seq.", "aaSeq") {
        // @Override
        // public String convert(NSequenceWithQuality seq) {
        // return AminoAcidSequence.translate(seq.getSequence(), FromLeftWithoutIncompleteCodon).toString();
        // }
        // });
        // 
        // descriptorsList.add(new FeatureExtractorDescriptor("-aaFeatureFromRight", "Export amino acid sequence of " +
        // "specified gene feature starting from the rightmost nucleotide (differs from -aaFeature only for " +
        // "sequences which length are not multiple of 3)", "AA. Seq.", "aaSeq") {
        // @Override
        // public String convert(NSequenceWithQuality seq) {
        // return AminoAcidSequence.translate(seq.getSequence(), FromRightWithoutIncompleteCodon).toString();
        // }
        // });
        descriptorsList.add(new FeatureExtractors.NSeqExtractor("-minFeatureQuality", "Export minimal quality of specified gene feature", "Min. qual. ", "minQual") {

            @Override
            public String convert(NSequenceWithQuality seq) {
                return "" + seq.getQuality().minValue();
            }
        });
        descriptorsList.add(new FeatureExtractors.NSeqExtractor("-avrgFeatureQuality", "Export average quality of specified gene feature", "Mean. qual. ", "meanQual") {

            @Override
            public String convert(NSequenceWithQuality seq) {
                return "" + seq.getQuality().meanValue();
            }
        });
        descriptorsList.add(new FeatureExtractors.NSeqExtractor("-lengthOf", "Exports length of specified gene feature.", "Length of ", "lengthOf") {

            @Override
            public String convert(NSequenceWithQuality seq) {
                return "" + seq.size();
            }
        });
        descriptorsList.add(new FeatureExtractors.MutationsExtractor("-nMutations", "Extract nucleotide mutations for specific gene feature; relative to germline sequence.", 1, new String[] { "N. Mutations in " }, new String[] { "nMutations" }) {

            @Override
            String convert(Mutations<NucleotideSequence> mutations, NucleotideSequence seq1, NucleotideSequence seq2, TranslationParameters tr) {
                return mutations.encode(",");
            }
        });
        descriptorsList.add(new FeatureExtractors.MutationsExtractor("-nMutationsRelative", "Extract nucleotide mutations for specific gene feature relative to another feature.", 2, new String[] { "N. Mutations in ", " relative to " }, new String[] { "nMutationsIn", "Relative" }) {

            @Override
            String convert(Mutations<NucleotideSequence> mutations, NucleotideSequence seq1, NucleotideSequence seq2, TranslationParameters tr) {
                return mutations.encode(",");
            }
        });
        final class AAMutations extends FeatureExtractors.MutationsExtractor {

            AAMutations(String command, String description, int nArgs, String[] hPrefix, String[] sPrefix) {
                super(command, description, nArgs, hPrefix, sPrefix);
            }

            @Override
            String convert(Mutations<NucleotideSequence> mutations, NucleotideSequence seq1, NucleotideSequence seq2, TranslationParameters tr) {
                if (tr == null)
                    return "-";
                Mutations<AminoAcidSequence> aaMuts = MutationsUtil.nt2aa(seq1, mutations, tr);
                if (aaMuts == null)
                    return "-";
                return aaMuts.encode(",");
            }
        }
        descriptorsList.add(new AAMutations("-aaMutations", "Extract amino acid mutations for specific gene feature", 1, new String[] { "AA. Mutations in " }, new String[] { "aaMutations" }));
        descriptorsList.add(new AAMutations("-aaMutationsRelative", "Extract amino acid mutations for specific gene feature relative to another feature.", 2, new String[] { "AA. Mutations in ", " relative to " }, new String[] { "aaMutationsIn", "Relative" }));
        final class MutationsDetailed extends FeatureExtractors.MutationsExtractor {

            MutationsDetailed(String command, String description, int nArgs, String[] hPrefix, String[] sPrefix) {
                super(command, description, nArgs, hPrefix, sPrefix);
            }

            @Override
            String convert(Mutations<NucleotideSequence> mutations, NucleotideSequence seq1, NucleotideSequence seq2, TranslationParameters tr) {
                if (tr == null)
                    return "-";
                MutationsUtil.MutationNt2AADescriptor[] descriptors = MutationsUtil.nt2aaDetailed(seq1, mutations, tr, 10);
                if (descriptors == null)
                    return "-";
                StringBuilder sb = new StringBuilder();
                for (int i = 0; i < descriptors.length; i++) {
                    sb.append(descriptors[i]);
                    if (i == descriptors.length - 1)
                        break;
                    sb.append(",");
                }
                return sb.toString();
            }
        }
        String detailedMutationsFormat = "Format <nt_mutation>:<aa_mutation_individual>:<aa_mutation_cumulative>, where <aa_mutation_individual> is an expected amino acid " + "mutation given no other mutations have occurred, and <aa_mutation_cumulative> amino acid mutation is the observed amino acid " + "mutation combining effect from all other. WARNING: format may change in following versions.";
        descriptorsList.add(new MutationsDetailed("-mutationsDetailed", "Detailed list of nucleotide and corresponding amino acid mutations. " + detailedMutationsFormat, 1, new String[] { "Detailed mutations in " }, new String[] { "mutationsDetailedIn" }));
        descriptorsList.add(new MutationsDetailed("-mutationsDetailedRelative", "Detailed list of nucleotide and corresponding amino acid mutations written, positions relative to specified gene feature. " + detailedMutationsFormat, 2, new String[] { "Detailed mutations in ", " relative to " }, new String[] { "mutationsDetailedIn", "Relative" }));
        descriptorsList.add(new ExtractReferencePointPosition());
        descriptorsList.add(new ExtractDefaultReferencePointsPositions());
        descriptorsList.add(new PL_A("-readId", "Export id of read corresponding to alignment", "Read id", "readId") {

            @Override
            protected String extract(VDJCAlignments object) {
                return "" + object.getMinReadId();
            }

            @Override
            public FieldExtractor<VDJCAlignments> create(OutputMode outputMode, String[] args) {
                System.out.println("WARNING: -readId is deprecated. Use -readIds");
                return super.create(outputMode, args);
            }
        });
        descriptorsList.add(new PL_A("-readIds", "Export id of read corresponding to alignment", "Read id", "readId") {

            @Override
            protected String extract(VDJCAlignments object) {
                long[] readIds = object.getReadIds();
                StringBuilder sb = new StringBuilder();
                for (int i = 0; ; i++) {
                    sb.append(readIds[i]);
                    if (i == readIds.length - 1)
                        return sb.toString();
                    sb.append(",");
                }
            }
        });
        descriptorsList.add(new ExtractSequence(VDJCAlignments.class, "-sequence", "Export aligned sequence (initial read), or 2 sequences in case of paired-end reads", "Read(s) sequence", "readSequence"));
        descriptorsList.add(new ExtractSequenceQuality(VDJCAlignments.class, "-quality", "Export initial read quality, or 2 qualities in case of paired-end reads", "Read(s) sequence qualities", "readQuality"));
        descriptorsList.add(new PL_C("-cloneId", "Unique clone identifier", "Clone ID", "cloneId") {

            @Override
            protected String extract(Clone object) {
                return "" + object.getId();
            }
        });
        descriptorsList.add(new PL_C("-count", "Export clone count", "Clone count", "cloneCount") {

            @Override
            protected String extract(Clone object) {
                return "" + object.getCount();
            }
        });
        descriptorsList.add(new PL_C("-fraction", "Export clone fraction", "Clone fraction", "cloneFraction") {

            @Override
            protected String extract(Clone object) {
                return "" + object.getFraction();
            }
        });
        descriptorsList.add(new ExtractSequence(Clone.class, "-sequence", "Export aligned sequence (initial read), or 2 sequences in case of paired-end reads", "Clonal sequence(s)", "clonalSequence"));
        descriptorsList.add(new ExtractSequenceQuality(Clone.class, "-quality", "Export initial read quality, or 2 qualities in case of paired-end reads", "Clonal sequence quality(s)", "clonalSequenceQuality"));
        descriptorsList.add(new PL_A("-descrR1", "Export description line from initial .fasta or .fastq file " + "of the first read (only available if --save-description was used in align command)", "Description R1", "descrR1") {

            @Override
            protected String extract(VDJCAlignments object) {
                List<SequenceRead> reads = object.getOriginalReads();
                if (reads == null)
                    throw new IllegalArgumentException("Error for option \'-descrR1\':\n" + "No description available for read: either re-run align action with -OsaveOriginalReads=true option " + "or don't use \'-descrR1\' in exportAlignments");
                return reads.get(0).getRead(0).getDescription();
            }

            @Override
            public FieldExtractor<VDJCAlignments> create(OutputMode outputMode, String[] args) {
                System.out.println("WARNING: -descrR1 is deprecated. Use -descrsR1");
                return super.create(outputMode, args);
            }
        });
        descriptorsList.add(new PL_A("-descrR2", "Export description line from initial .fasta or .fastq file " + "of the second read (only available if --save-description was used in align command)", "Description R2", "descrR2") {

            @Override
            protected String extract(VDJCAlignments object) {
                List<SequenceRead> reads = object.getOriginalReads();
                if (reads == null)
                    throw new IllegalArgumentException("Error for option \'-descrR1\':\n" + "No description available for read: either re-run align action with -OsaveOriginalReads=true option " + "or don't use \'-descrR1\' in exportAlignments");
                SequenceRead read = reads.get(0);
                if (read.numberOfReads() < 2)
                    throw new IllegalArgumentException("Error for option \'-descrR2\':\n" + "No description available for second read: your input data was single-end");
                return read.getRead(1).getDescription();
            }

            @Override
            public FieldExtractor<VDJCAlignments> create(OutputMode outputMode, String[] args) {
                System.out.println("WARNING: -descrR2 is deprecated. Use -descrsR2");
                return super.create(outputMode, args);
            }
        });
        descriptorsList.add(new PL_A("-descrsR1", "Export description lines from initial .fasta or .fastq file " + "of the first reads (only available if -OsaveOriginalReads=true was used in align command)", "Descriptions R1", "descrsR1") {

            @Override
            protected String extract(VDJCAlignments object) {
                List<SequenceRead> reads = object.getOriginalReads();
                if (reads == null)
                    throw new IllegalArgumentException("Error for option \'-descrR1\':\n" + "No description available for read: either re-run align action with -OsaveOriginalReads option " + "or don't use \'-descrR1\' in exportAlignments");
                StringBuilder sb = new StringBuilder();
                for (int i = 0; ; i++) {
                    sb.append(reads.get(i).getRead(0).getDescription());
                    if (i == reads.size() - 1)
                        return sb.toString();
                    sb.append(",");
                }
            }
        });
        descriptorsList.add(new PL_A("-descrsR2", "Export description lines from initial .fasta or .fastq file " + "of the second reads (only available if -OsaveOriginalReads=true was used in align command)", "Descriptions R2", "descrsR2") {

            @Override
            protected String extract(VDJCAlignments object) {
                List<SequenceRead> reads = object.getOriginalReads();
                if (reads == null)
                    throw new IllegalArgumentException("Error for option \'-descrR1\':\n" + "No description available for read: either re-run align action with -OsaveOriginalReads option " + "or don't use \'-descrR1\' in exportAlignments");
                StringBuilder sb = new StringBuilder();
                for (int i = 0; ; i++) {
                    SequenceRead read = reads.get(i);
                    if (read.numberOfReads() < 2)
                        throw new IllegalArgumentException("Error for option \'-descrsR2\':\n" + "No description available for second read: your input data was single-end");
                    sb.append(read.getRead(1).getDescription());
                    if (i == reads.size() - 1)
                        return sb.toString();
                    sb.append(",");
                }
            }
        });
        descriptorsList.add(new PL_A("-readHistory", "Export read history", "Read history", "readHistory") {

            @Override
            protected String extract(VDJCAlignments object) {
                try {
                    return GlobalObjectMappers.toOneLine(object.getHistory());
                } catch (JsonProcessingException ex) {
                    throw new RuntimeException(ex);
                }
            }
        });
        for (final GeneType type : GeneType.values()) {
            String c = Character.toLowerCase(type.getLetter()) + "IdentityPercents";
            descriptorsList.add(new PL_O("-" + c, type.getLetter() + " alignment identity percents", type.getLetter() + " alignment identity percents", c) {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit[] hits = object.getHits(type);
                    if (hits == null)
                        return NULL;
                    StringBuilder sb = new StringBuilder();
                    sb.append("");
                    for (int i = 0; ; i++) {
                        sb.append(hits[i].getIdentity());
                        if (i == hits.length - 1)
                            return sb.toString();
                        sb.append(",");
                    }
                }
            });
        }
        for (final GeneType type : GeneType.values()) {
            String c = Character.toLowerCase(type.getLetter()) + "BestIdentityPercent";
            descriptorsList.add(new PL_O("-" + c, type.getLetter() + "best alignment identity percent", type.getLetter() + "best alignment identity percent", c) {

                @Override
                protected String extract(VDJCObject object) {
                    VDJCHit hit = object.getBestHit(type);
                    if (hit == null)
                        return NULL;
                    return Float.toString(hit.getIdentity());
                }
            });
        }
        descriptorsList.add(new PL_O("-chains", "Chains", "Chains", "Chains") {

            @Override
            protected String extract(VDJCObject object) {
                return object.commonChains().toString();
            }
        });
        descriptorsList.add(new PL_O("-topChains", "Top chains", "Top chains", "topChains") {

            @Override
            protected String extract(VDJCObject object) {
                return object.commonTopChains().toString();
            }
        });
        descriptors = descriptorsList.toArray(new Field[descriptorsList.size()]);
    }
    return descriptors;
}
Also used : GeneFeature(io.repseq.core.GeneFeature) ArrayList(java.util.ArrayList) VDJCObject(com.milaboratory.mixcr.basictypes.VDJCObject) Alignment(com.milaboratory.core.alignment.Alignment) AminoAcidSequence(com.milaboratory.core.sequence.AminoAcidSequence) NSequenceWithQuality(com.milaboratory.core.sequence.NSequenceWithQuality) ArrayList(java.util.ArrayList) List(java.util.List) VDJCAlignments(com.milaboratory.mixcr.basictypes.VDJCAlignments) JsonProcessingException(com.fasterxml.jackson.core.JsonProcessingException) Clone(com.milaboratory.mixcr.basictypes.Clone) Mutations(com.milaboratory.core.mutations.Mutations) ReferencePoint(io.repseq.core.ReferencePoint) TranslationParameters(com.milaboratory.core.sequence.TranslationParameters) NucleotideSequence(com.milaboratory.core.sequence.NucleotideSequence) SequenceRead(com.milaboratory.core.io.sequence.SequenceRead) GeneType(io.repseq.core.GeneType) VDJCHit(com.milaboratory.mixcr.basictypes.VDJCHit)

Example 7 with GeneFeature

use of io.repseq.core.GeneFeature in project mixcr by milaboratory.

the class AFilter method build.

public static AFilter build(String filterCode) {
    try {
        ScriptEngineManager manager = new ScriptEngineManager();
        ScriptEngine engine = manager.getEngineByName("JavaScript");
        Reader reader = null;
        String script = null;
        try {
            reader = new BufferedReader(new InputStreamReader(AFilter.class.getClassLoader().getResourceAsStream("js/filter_init.js")));
            char[] buffer = new char[1024];
            int size;
            StringBuilder sb = new StringBuilder();
            while ((size = reader.read(buffer)) >= 0) sb.append(buffer, 0, size);
            script = sb.toString();
        } catch (IOException e) {
            throw new RuntimeException(e);
        } finally {
            try {
                if (reader != null)
                    reader.close();
            } catch (IOException e) {
                throw new RuntimeException(e);
            }
        }
        int filterBegin = filterCode.lastIndexOf(';') + 1;
        script = script.replace("/*CODE*/", filterCode.substring(0, filterBegin));
        script = script.replace("/*FILTER*/", filterCode.substring(filterBegin));
        engine.eval(script);
        for (Map.Entry<GeneFeature, String> entry : GeneFeature.getNameByFeature().entrySet()) engine.put(entry.getValue(), entry.getKey());
        for (GeneType geneType : GeneType.values()) engine.put(new String(new char[] { geneType.getLetter() }), geneType);
        Invocable inv = (Invocable) engine;
        return new AFilter(engine, inv);
    } catch (ScriptException e) {
        throw new IllegalArgumentException(e);
    }
}
Also used : GeneFeature(io.repseq.core.GeneFeature) InputStreamReader(java.io.InputStreamReader) ScriptEngineManager(javax.script.ScriptEngineManager) Reader(java.io.Reader) InputStreamReader(java.io.InputStreamReader) BufferedReader(java.io.BufferedReader) IOException(java.io.IOException) ScriptEngine(javax.script.ScriptEngine) Invocable(javax.script.Invocable) ScriptException(javax.script.ScriptException) BufferedReader(java.io.BufferedReader) GeneType(io.repseq.core.GeneType) Map(java.util.Map)

Example 8 with GeneFeature

use of io.repseq.core.GeneFeature in project repseqio by repseqio.

the class GeneFeatureTest method testCoding1.

@Test
public void testCoding1() throws Exception {
    GeneFeature input = GeneFeature.parse("{CDR3Begin(-10):CDR3Begin(-1)}");
    GeneFeature cf = GeneFeature.getCodingGeneFeature(input);
    assertEquals(cf, input);
}
Also used : GeneFeature(io.repseq.core.GeneFeature) Test(org.junit.Test)

Example 9 with GeneFeature

use of io.repseq.core.GeneFeature in project repseqio by repseqio.

the class GeneFeatureTest method testIntersection8.

@Test(expected = IllegalArgumentException.class)
public void testIntersection8() throws Exception {
    GeneFeature f1, f2;
    f1 = create(new int[] { 1, 5, 7, 9, 10, 12 }, new int[] { -2, 0, 1, -3, -2, 5 });
    f2 = create(new int[] { 1, 5, 7, 9, 10, 12 }, new int[] { -3, 0, 2, -3, -2, 4 });
    GeneFeature.intersection(f2, f1);
}
Also used : GeneFeature(io.repseq.core.GeneFeature) Test(org.junit.Test)

Example 10 with GeneFeature

use of io.repseq.core.GeneFeature in project repseqio by repseqio.

the class GeneFeatureTest method create.

static final GeneFeature create(int[] indexes, int[] offsets) {
    GeneFeature[] res = new GeneFeature[indexes.length / 2];
    for (int i = 0; i < indexes.length; ) {
        res[i / 2] = new GeneFeature(new ReferencePoint(new ReferencePoint(BasicReferencePoint.getByIndex(indexes[i])), offsets[i]), new ReferencePoint(new ReferencePoint(BasicReferencePoint.getByIndex(indexes[i + 1])), offsets[i + 1]));
        i += 2;
    }
    return new GeneFeature(res);
}
Also used : GeneFeature(io.repseq.core.GeneFeature)

Aggregations

GeneFeature (io.repseq.core.GeneFeature)41 Test (org.junit.Test)23 NucleotideSequence (com.milaboratory.core.sequence.NucleotideSequence)10 GeneType (io.repseq.core.GeneType)9 VDJCGene (io.repseq.core.VDJCGene)6 NSequenceWithQuality (com.milaboratory.core.sequence.NSequenceWithQuality)3 VDJCAlignments (com.milaboratory.mixcr.basictypes.VDJCAlignments)3 ReferencePoint (io.repseq.core.ReferencePoint)3 VDJCLibrary (io.repseq.core.VDJCLibrary)3 VDJCLibraryRegistry (io.repseq.core.VDJCLibraryRegistry)3 Pattern (java.util.regex.Pattern)3 SequenceRead (com.milaboratory.core.io.sequence.SequenceRead)2 AminoAcidSequence (com.milaboratory.core.sequence.AminoAcidSequence)2 Clone (com.milaboratory.mixcr.basictypes.Clone)2 VDJCHit (com.milaboratory.mixcr.basictypes.VDJCHit)2 VDJCAlignerParameters (com.milaboratory.mixcr.vdjaligners.VDJCAlignerParameters)2 IntArrayList (com.milaboratory.util.IntArrayList)2 ArrayList (java.util.ArrayList)2 HashMap (java.util.HashMap)2 Well19937c (org.apache.commons.math3.random.Well19937c)2