// $Id: // FORESTER -- software libraries and applications // for evolutionary biology research and applications. // // Copyright (C) 2014 Christian M. Zmasek // Copyright (C) 2014 Sanford-Burnham Medical Research Institute // All rights reserved // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2.1 of the License, or (at your option) any later version. // // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA // // WWW: https://sites.google.com/site/cmzmasek/home/software/forester package org.forester.test; import java.io.ByteArrayInputStream; import java.io.File; import java.io.FileInputStream; import java.io.IOException; import java.io.StringWriter; import java.io.Writer; import java.net.URL; import java.util.ArrayList; import java.util.Date; import java.util.HashSet; import java.util.Iterator; import java.util.List; import java.util.Locale; import java.util.Set; import java.util.SortedSet; import org.forester.application.support_transfer; import org.forester.archaeopteryx.AptxUtil; import org.forester.archaeopteryx.TreePanelUtil; import org.forester.archaeopteryx.webservices.WebserviceUtil; import org.forester.clade_analysis.CladeAnalysisTest; import org.forester.development.DevelopmentTools; import org.forester.evoinference.TestPhylogenyReconstruction; import org.forester.evoinference.matrix.character.CharacterStateMatrix; import org.forester.evoinference.matrix.character.CharacterStateMatrix.BinaryStates; import org.forester.go.TestGo; import org.forester.io.parsers.FastaParser; import org.forester.io.parsers.GeneralMsaParser; import org.forester.io.parsers.HmmscanPerDomainTableParser; import org.forester.io.parsers.HmmscanPerDomainTableParser.INDIVIDUAL_SCORE_CUTOFF; import org.forester.io.parsers.nexus.NexusBinaryStatesMatrixParser; import org.forester.io.parsers.nexus.NexusCharactersParser; import org.forester.io.parsers.nexus.NexusPhylogeniesParser; import org.forester.io.parsers.nhx.NHXParser; import org.forester.io.parsers.nhx.NHXParser.TAXONOMY_EXTRACTION; import org.forester.io.parsers.phyloxml.PhyloXmlParser; import org.forester.io.parsers.tol.TolParser; import org.forester.io.parsers.util.ParserUtils; import org.forester.io.writers.PhylogenyWriter; import org.forester.io.writers.SequenceWriter; import org.forester.msa.BasicMsa; import org.forester.msa.DeleteableMsa; import org.forester.msa.Mafft; import org.forester.msa.Msa; import org.forester.msa.Msa.MSA_FORMAT; import org.forester.msa.MsaInferrer; import org.forester.msa.MsaMethods; import org.forester.pccx.TestPccx; import org.forester.phylogeny.Phylogeny; import org.forester.phylogeny.PhylogenyBranch; import org.forester.phylogeny.PhylogenyMethods; import org.forester.phylogeny.PhylogenyNode; import org.forester.phylogeny.PhylogenyNode.NH_CONVERSION_SUPPORT_VALUE_STYLE; import org.forester.phylogeny.data.Accession; import org.forester.phylogeny.data.Accession.Source; import org.forester.phylogeny.data.BinaryCharacters; import org.forester.phylogeny.data.BranchWidth; import org.forester.phylogeny.data.Confidence; import org.forester.phylogeny.data.Distribution; import org.forester.phylogeny.data.DomainArchitecture; import org.forester.phylogeny.data.Event; import org.forester.phylogeny.data.Identifier; import org.forester.phylogeny.data.PhylogenyData; import org.forester.phylogeny.data.PhylogenyDataUtil; import org.forester.phylogeny.data.Polygon; import org.forester.phylogeny.data.PropertiesList; import org.forester.phylogeny.data.Property; import org.forester.phylogeny.data.Property.AppliesTo; import org.forester.phylogeny.data.ProteinDomain; import org.forester.phylogeny.data.Taxonomy; import org.forester.phylogeny.factories.ParserBasedPhylogenyFactory; import org.forester.phylogeny.factories.PhylogenyFactory; import org.forester.phylogeny.iterators.PhylogenyNodeIterator; import org.forester.protein.BasicDomain; import org.forester.protein.BasicProtein; import org.forester.protein.Domain; import org.forester.protein.Protein; import org.forester.protein.ProteinId; import org.forester.rio.TestRIO; import org.forester.sdi.SDI; import org.forester.sdi.SDIR; import org.forester.sdi.TestGSDI; import org.forester.sequence.BasicSequence; import org.forester.sequence.MolecularSequence; import org.forester.species.BasicSpecies; import org.forester.species.Species; import org.forester.surfacing.TestSurfacing; import org.forester.tools.ConfidenceAssessor; import org.forester.tools.SupportCount; import org.forester.tools.TreeSplitMatrix; import org.forester.util.AsciiHistogram; import org.forester.util.BasicDescriptiveStatistics; import org.forester.util.BasicTable; import org.forester.util.BasicTableParser; import org.forester.util.DescriptiveStatistics; import org.forester.util.ForesterConstants; import org.forester.util.ForesterUtil; import org.forester.util.GeneralTable; import org.forester.util.SequenceAccessionTools; import org.forester.ws.seqdb.SequenceDatabaseEntry; import org.forester.ws.seqdb.SequenceDbWsTools; import org.forester.ws.seqdb.UniProtTaxonomy; @SuppressWarnings( "unused") public final class Test { private final static String PATH_TO_RESOURCES = System.getProperty( "user.dir" ) + ForesterUtil.getFileSeparator() + "resources" + ForesterUtil.getFileSeparator(); private final static String PATH_TO_TEST_DATA = System.getProperty( "user.dir" ) + ForesterUtil.getFileSeparator() + "test_data" + ForesterUtil.getFileSeparator(); private final static boolean PERFORM_DB_TESTS = false; private static final boolean PERFORM_WEB_TREE_ACCESS = false; private static final String PHYLOXML_LOCAL_XSD = PATH_TO_RESOURCES + "phyloxml_schema/" + ForesterConstants.PHYLO_XML_VERSION + "/" + ForesterConstants.PHYLO_XML_XSD; private static final String PHYLOXML_REMOTE_XSD = ForesterConstants.PHYLO_XML_LOCATION + "/" + ForesterConstants.PHYLO_XML_VERSION + "/" + ForesterConstants.PHYLO_XML_XSD; private final static boolean USE_LOCAL_PHYLOXML_SCHEMA = true; private final static double ZERO_DIFF = 1.0E-9; private static boolean isEqual( final double a, final double b ) { return ( ( Math.abs( a - b ) ) < Test.ZERO_DIFF ); } public static void main( final String[] args ) { System.out.println( "[Java version: " + ForesterUtil.JAVA_VERSION + " " + ForesterUtil.JAVA_VENDOR + "]" ); System.out.println( "[OS: " + ForesterUtil.OS_NAME + " " + ForesterUtil.OS_ARCH + " " + ForesterUtil.OS_VERSION + "]" ); Locale.setDefault( Locale.US ); System.out.println( "[Locale: " + Locale.getDefault() + "]" ); int failed = 0; int succeeded = 0; System.out.print( "[Test if directory with files for testing exists/is readable: " ); if ( Test.testDir( PATH_TO_TEST_DATA ) ) { System.out.println( "OK.]" ); } else { System.out.println( "could not find/read from directory \"" + PATH_TO_TEST_DATA + "\".]" ); System.out.println( "Testing aborted." ); System.exit( -1 ); } System.out.print( "[Test if resources directory exists/is readable: " ); if ( testDir( PATH_TO_RESOURCES ) ) { System.out.println( "OK.]" ); } else { System.out.println( "could not find/read from directory \"" + Test.PATH_TO_RESOURCES + "\".]" ); System.out.println( "Testing aborted." ); System.exit( -1 ); } final long start_time = new Date().getTime(); System.out.print( "Basic node methods: " ); if ( Test.testBasicNodeMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Protein id: " ); if ( !testProteinId() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Species: " ); if ( !testSpecies() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Basic domain: " ); if ( !testBasicDomain() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Basic protein: " ); if ( !testBasicProtein() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Common prefix: " ); if ( !testCommonPrefix() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Common prefix sep: " ); if ( !testCommonPrefixSep() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Sequence writer: " ); if ( testSequenceWriter() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Sequence id parsing: " ); if ( testSequenceIdParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "UniProtKB id extraction: " ); if ( Test.testExtractUniProtKbProteinSeqIdentifier() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Sequence DB tools 1: " ); if ( testSequenceDbWsTools1() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Hmmscan output parser: " ); if ( testHmmscanOutputParser() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Overlap removal: " ); if ( !org.forester.test.Test.testOverlapRemoval() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Engulfing overlap removal: " ); if ( !Test.testEngulfingOverlapRemoval() ) { System.out.println( "failed." ); failed++; } else { succeeded++; } System.out.println( "OK." ); System.out.print( "Taxonomy data extraction: " ); if ( Test.testExtractTaxonomyDataFromNodeName() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Taxonomy code extraction: " ); if ( Test.testExtractTaxonomyCodeFromNodeName() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "SN extraction: " ); if ( Test.testExtractSNFromNodeName() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Taxonomy extraction (general): " ); if ( Test.testTaxonomyExtraction() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Uri for Aptx web sequence accession: " ); if ( Test.testCreateUriForSeqWeb() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Basic node construction and parsing of NHX (node level): " ); if ( Test.testNHXNodeParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Node construction and parsing of NHX (node level): " ); if ( Test.testNHXNodeParsing2() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing iterating: " ); if ( Test.testNHParsingIter() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NH parsing: " ); if ( Test.testNHParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NH parsing - special chars: " ); if ( Test.testNHParsingSpecialChars() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Conversion to NHX (node level): " ); if ( Test.testNHXconversion() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing: " ); if ( Test.testNHXParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing with quotes: " ); if ( Test.testNHXParsingQuotes() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing (MrBayes): " ); if ( Test.testNHXParsingMB() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Nexus characters parsing: " ); if ( Test.testNexusCharactersParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Nexus tree parsing iterating: " ); if ( Test.testNexusTreeParsingIterating() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Nexus tree parsing: " ); if ( Test.testNexusTreeParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Nexus tree parsing (translating): " ); if ( Test.testNexusTreeParsingTranslating() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Nexus matrix parsing: " ); if ( Test.testNexusMatrixParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Basic phyloXML parsing: " ); if ( Test.testBasicPhyloXMLparsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Basic phyloXML parsing (validating against schema): " ); if ( testBasicPhyloXMLparsingValidating() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "phyloXML parsing (validating against schema): " ); if ( testPhyloXMLparsingValidating() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Roundtrip phyloXML parsing (validating against schema): " ); if ( Test.testBasicPhyloXMLparsingRoundtrip() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "phyloXML Distribution Element: " ); if ( Test.testPhyloXMLparsingOfDistributionElement() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Tol XML parsing: " ); if ( Test.testBasicTolXMLparsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "UTF-8 parsing from file: " ); if ( Test.testUTF8ParsingFromFile() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Copying of node data: " ); if ( Test.testCopyOfNodeData() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Tree copy: " ); if ( Test.testTreeCopy() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Basic tree methods: " ); if ( Test.testBasicTreeMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Tree methods: " ); if ( Test.testTreeMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Phylogeny methods:" ); if ( Test.testPhylogenyMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Postorder Iterator: " ); if ( Test.testPostOrderIterator() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Preorder Iterator: " ); if ( Test.testPreOrderIterator() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Levelorder Iterator: " ); if ( Test.testLevelOrderIterator() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Re-id methods: " ); if ( Test.testReIdMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Methods on last external nodes: " ); if ( Test.testLastExternalNodeMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Methods on external nodes: " ); if ( Test.testExternalNodeRelatedMethods() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Deletion of external nodes: " ); if ( Test.testDeletionOfExternalNodes() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Subtree deletion: " ); if ( Test.testSubtreeDeletion() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Phylogeny branch: " ); if ( Test.testPhylogenyBranch() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Rerooting: " ); if ( Test.testRerooting() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Mipoint rooting: " ); if ( Test.testMidpointrooting() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Node removal: " ); if ( Test.testNodeRemoval() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Support count: " ); if ( Test.testSupportCount() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Support transfer: " ); if ( Test.testSupportTransfer() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Finding of LCA: " ); if ( Test.testGetLCA() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Finding of LCA 2: " ); if ( Test.testGetLCA2() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Calculation of distance between nodes: " ); if ( Test.testGetDistance() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Descriptive statistics: " ); if ( Test.testDescriptiveStatistics() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Data objects and methods: " ); if ( Test.testDataObjects() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Properties map: " ); if ( Test.testPropertiesMap() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "SDIse: " ); if ( Test.testSDIse() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "SDIunrooted: " ); if ( Test.testSDIunrooted() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "GSDI: " ); if ( TestGSDI.test() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "RIO: " ); if ( TestRIO.test() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Clade analyis: " ); if ( CladeAnalysisTest.test() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Phylogeny reconstruction:" ); System.out.println(); if ( TestPhylogenyReconstruction.test( new File( PATH_TO_TEST_DATA ) ) ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Analysis of domain architectures: " ); System.out.println(); if ( TestSurfacing.test( new File( PATH_TO_TEST_DATA ) ) ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "GO: " ); System.out.println(); if ( TestGo.test( new File( PATH_TO_TEST_DATA ) ) ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Modeling tools: " ); if ( TestPccx.test() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Split Matrix strict: " ); if ( Test.testSplitStrict() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Split Matrix: " ); if ( Test.testSplit() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Confidence Assessor: " ); if ( Test.testConfidenceAssessor() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Basic table: " ); if ( Test.testBasicTable() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "General table: " ); if ( Test.testGeneralTable() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Amino acid sequence: " ); if ( Test.testAminoAcidSequence() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "General MSA parser: " ); if ( Test.testGeneralMsaParser() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Fasta parser for msa: " ); if ( Test.testFastaParser() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Creation of balanced phylogeny: " ); if ( Test.testCreateBalancedPhylogeny() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Genbank accessor parsing: " ); if ( Test.testGenbankAccessorParsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } String path = ""; final String os = ForesterUtil.OS_NAME.toLowerCase(); if ( ( os.indexOf( "mac" ) >= 0 ) && ( os.indexOf( "os" ) > 0 ) ) { path = "/usr/local/bin/mafft"; } else if ( os.indexOf( "win" ) >= 0 ) { path = "C:\\Program Files\\mafft-win\\mafft.bat"; } else { path = "mafft"; if ( !MsaInferrer.isInstalled( path ) ) { path = "/usr/bin/mafft"; } if ( !MsaInferrer.isInstalled( path ) ) { path = "/usr/local/bin/mafft"; } } if ( MsaInferrer.isInstalled( path ) ) { System.out.print( "MAFFT (external program): " ); if ( Test.testMafft( path ) ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed [will not count towards failed tests]" ); } } System.out.print( "Next nodes with collapsed: " ); if ( Test.testNextNodeWithCollapsing() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Simple MSA quality: " ); if ( Test.testMsaQualityMethod() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Deleteable MSA: " ); if ( Test.testDeleteableMsa() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "MSA entropy: " ); if ( Test.testMsaEntropy() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } if ( PERFORM_DB_TESTS ) { System.out.print( "Uniprot Entry Retrieval: " ); if ( Test.testUniprotEntryRetrieval() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Ebi Entry Retrieval: " ); if ( Test.testEbiEntryRetrieval() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Sequence DB tools 2: " ); if ( testSequenceDbWsTools2() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; System.exit( -1 ); } System.out.print( "Uniprot Taxonomy Search: " ); if ( Test.testUniprotTaxonomySearch() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } } if ( PERFORM_WEB_TREE_ACCESS ) { System.out.print( "TreeBase acccess: " ); if ( Test.testTreeBaseReading() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "ToL access: " ); if ( Test.testToLReading() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing from URL: " ); if ( Test.testNHXparsingFromURL() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "NHX parsing from URL 2: " ); if ( Test.testNHXparsingFromURL2() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "phyloXML parsing from URL: " ); if ( Test.testPhyloXMLparsingFromURL() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "TreeFam access: " ); if ( Test.testTreeFamReading() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } System.out.print( "Pfam tree access: " ); if ( Test.testPfamTreeReading() ) { System.out.println( "OK." ); succeeded++; } else { System.out.println( "failed." ); failed++; } } System.out.println(); final Runtime rt = java.lang.Runtime.getRuntime(); final long free_memory = rt.freeMemory() / 1000000; final long total_memory = rt.totalMemory() / 1000000; System.out.println( "Running time : " + ( new Date().getTime() - start_time ) + "ms " + "(free memory: " + free_memory + "MB, total memory: " + total_memory + "MB)" ); System.out.println(); System.out.println( "Successful tests: " + succeeded ); System.out.println( "Failed tests: " + failed ); System.out.println(); if ( failed < 1 ) { System.out.println( "OK." ); } else { System.out.println( "Not OK." ); } } private static boolean testEngulfingOverlapRemoval() { try { final Domain d0 = new BasicDomain( "d0", 0, 8, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d1 = new BasicDomain( "d1", 0, 1, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d2 = new BasicDomain( "d2", 0, 2, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d3 = new BasicDomain( "d3", 7, 8, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d4 = new BasicDomain( "d4", 7, 9, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d5 = new BasicDomain( "d4", 0, 9, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d6 = new BasicDomain( "d4", 4, 5, ( short ) 1, ( short ) 1, 0.1, 1 ); final List covered = new ArrayList(); covered.add( true ); // 0 covered.add( false ); // 1 covered.add( true ); // 2 covered.add( false ); // 3 covered.add( true ); // 4 covered.add( true ); // 5 covered.add( false ); // 6 covered.add( true ); // 7 covered.add( true ); // 8 if ( ForesterUtil.isEngulfed( d0, covered ) ) { return false; } if ( ForesterUtil.isEngulfed( d1, covered ) ) { return false; } if ( ForesterUtil.isEngulfed( d2, covered ) ) { return false; } if ( !ForesterUtil.isEngulfed( d3, covered ) ) { return false; } if ( ForesterUtil.isEngulfed( d4, covered ) ) { return false; } if ( ForesterUtil.isEngulfed( d5, covered ) ) { return false; } if ( !ForesterUtil.isEngulfed( d6, covered ) ) { return false; } final Domain a = new BasicDomain( "a", 0, 10, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain b = new BasicDomain( "b", 8, 20, ( short ) 1, ( short ) 1, 0.2, 1 ); final Domain c = new BasicDomain( "c", 15, 16, ( short ) 1, ( short ) 1, 0.3, 1 ); final Protein abc = new BasicProtein( "abc", "nemve", 0 ); abc.addProteinDomain( a ); abc.addProteinDomain( b ); abc.addProteinDomain( c ); final Protein abc_r1 = ForesterUtil.removeOverlappingDomains( 3, false, abc ); final Protein abc_r2 = ForesterUtil.removeOverlappingDomains( 3, true, abc ); if ( abc.getNumberOfProteinDomains() != 3 ) { return false; } if ( abc_r1.getNumberOfProteinDomains() != 3 ) { return false; } if ( abc_r2.getNumberOfProteinDomains() != 2 ) { return false; } if ( !abc_r2.getProteinDomain( 0 ).getDomainId().equals( "a" ) ) { return false; } if ( !abc_r2.getProteinDomain( 1 ).getDomainId().equals( "b" ) ) { return false; } final Domain d = new BasicDomain( "d", 0, 10, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain e = new BasicDomain( "e", 8, 20, ( short ) 1, ( short ) 1, 0.3, 1 ); final Domain f = new BasicDomain( "f", 15, 16, ( short ) 1, ( short ) 1, 0.2, 1 ); final Protein def = new BasicProtein( "def", "nemve", 0 ); def.addProteinDomain( d ); def.addProteinDomain( e ); def.addProteinDomain( f ); final Protein def_r1 = ForesterUtil.removeOverlappingDomains( 5, false, def ); final Protein def_r2 = ForesterUtil.removeOverlappingDomains( 5, true, def ); if ( def.getNumberOfProteinDomains() != 3 ) { return false; } if ( def_r1.getNumberOfProteinDomains() != 3 ) { return false; } if ( def_r2.getNumberOfProteinDomains() != 3 ) { return false; } if ( !def_r2.getProteinDomain( 0 ).getDomainId().equals( "d" ) ) { return false; } if ( !def_r2.getProteinDomain( 1 ).getDomainId().equals( "f" ) ) { return false; } if ( !def_r2.getProteinDomain( 2 ).getDomainId().equals( "e" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static final boolean testNHXparsingFromURL2() { try { final String s = "https://sites.google.com/site/cmzmasek/home/software/archaeopteryx/examples/simple/simple_1.nh"; final Phylogeny phys[] = AptxUtil .readPhylogeniesFromUrl( new URL( s ), false, false, false, TAXONOMY_EXTRACTION.NO, false ); if ( ( phys == null ) || ( phys.length != 5 ) ) { return false; } if ( !phys[ 0 ].toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { System.out.println( phys[ 0 ].toNewHampshire() ); return false; } if ( !phys[ 1 ].toNewHampshire().equals( "((1,2,3),(4,5,6),(7,8,9));" ) ) { System.out.println( phys[ 1 ].toNewHampshire() ); return false; } final Phylogeny phys2[] = AptxUtil .readPhylogeniesFromUrl( new URL( s ), false, false, false, TAXONOMY_EXTRACTION.NO, false ); if ( ( phys2 == null ) || ( phys2.length != 5 ) ) { return false; } if ( !phys2[ 0 ].toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { System.out.println( phys2[ 0 ].toNewHampshire() ); return false; } if ( !phys2[ 1 ].toNewHampshire().equals( "((1,2,3),(4,5,6),(7,8,9));" ) ) { System.out.println( phys2[ 1 ].toNewHampshire() ); return false; } final Phylogeny phys3[] = AptxUtil.readPhylogeniesFromUrl( new URL( "http://swisstree.vital-it.ch:80/" + "SwissTree/ST001/consensus_tree.nhx" ), false, false, false, TAXONOMY_EXTRACTION.NO, false ); if ( ( phys3 == null ) || ( phys3.length != 1 ) ) { return false; } if ( !phys3[ 0 ].toNewHampshire() .equals( "((((POP23a_CIOIN_ENSCING00000016202,POP23b_CIOIN_ENSCING00000016169),POP23_CIOSA_ENSCSAVG00000000248),((POP23a_BRAFL_C3ZMF1,POP23b_BRAFL_121417),(((POP3_ORYLA_ENSORLG00000019669,POP3_GASAC_ENSGACG00000014023,POP3_DANRE_Q6JWW1),(POP3_XENTR_B1H1F6,(POP3_CHICK_Q9DG25,(POP3_ORNAN_ENSOANG00000004179,POP3_MONDO_ENSMODG00000018033,((POP3_MOUSE_Q9ES81,POP3_RAT_Q3BCU3),POP3_RABIT_ENSOCUG00000025973,POP3_MACMU_ENSMMUG00000014473,POP3_HUMAN_Q9HBV1))))),(((POP2_GASAC_ENSGACG00000001420,POP2_ORYLA_ENSORLG00000008627,POP2_TAKRU_ENSTRUG00000015933),POP2_DANRE_ENSDARG00000069922),POP2_XENTR_ENSXETG00000018064,(((POP2_TAEGU_ENSTGUG00000013383,POP2_CHICK_Q6T9Z5),POP2_ANOCA_ENSACAG00000003557),((POP2_MACEU_ENSMEUG00000015825,POP2_MONDO_ENSMODG00000018205),((POP2_RABIT_ENSOCUG00000009515,(POP2_RAT_Q6P722,POP2_MOUSE_Q9ES82)),(POP2_MACMU_ENSMMUG00000000905,POP2_HUMAN_Q9HBU9)))))))),((POP1_CIOSA_ENSCSAVG00000000247,POP1_CIOIN_ENSCING00000000496),((POP1_DANRE_Q5PQZ7,(POP1_ORYLA_ENSORLG00000019663,POP1_GASAC_ENSGACG00000014015,POP1_TAKRU_ENSORLG00000019663)),(POP1_XENTR_B1H1G2,(POP1_ANOCA_ENSACAG00000003910,(POP1_TAEGU_ENSTGUG00000012218,POP1_CHICK_Q9DG23)),POP1_ORNAN_ENSOANG00000004180,POP1_MONDO_ENSMODG00000018034,(POP1_RABIT_ENSOCUG00000016944,(POP1_RAT_Q3BCU4,POP1_MOUSE_Q9ES83),(POP1_HUMAN_Q8NE79,POP1_MACMU_ENSMMUG00000014471))))));" ) ) { System.out.println( phys3[ 0 ].toNewHampshire() ); return false; } final Phylogeny phys4[] = AptxUtil.readPhylogeniesFromUrl( new URL( "http://swisstree.vital-it.ch:80/" + "SwissTree/ST001/consensus_tree.nhx" ), false, false, false, TAXONOMY_EXTRACTION.NO, false ); if ( ( phys4 == null ) || ( phys4.length != 1 ) ) { return false; } if ( !phys4[ 0 ].toNewHampshire() .equals( "((((POP23a_CIOIN_ENSCING00000016202,POP23b_CIOIN_ENSCING00000016169),POP23_CIOSA_ENSCSAVG00000000248),((POP23a_BRAFL_C3ZMF1,POP23b_BRAFL_121417),(((POP3_ORYLA_ENSORLG00000019669,POP3_GASAC_ENSGACG00000014023,POP3_DANRE_Q6JWW1),(POP3_XENTR_B1H1F6,(POP3_CHICK_Q9DG25,(POP3_ORNAN_ENSOANG00000004179,POP3_MONDO_ENSMODG00000018033,((POP3_MOUSE_Q9ES81,POP3_RAT_Q3BCU3),POP3_RABIT_ENSOCUG00000025973,POP3_MACMU_ENSMMUG00000014473,POP3_HUMAN_Q9HBV1))))),(((POP2_GASAC_ENSGACG00000001420,POP2_ORYLA_ENSORLG00000008627,POP2_TAKRU_ENSTRUG00000015933),POP2_DANRE_ENSDARG00000069922),POP2_XENTR_ENSXETG00000018064,(((POP2_TAEGU_ENSTGUG00000013383,POP2_CHICK_Q6T9Z5),POP2_ANOCA_ENSACAG00000003557),((POP2_MACEU_ENSMEUG00000015825,POP2_MONDO_ENSMODG00000018205),((POP2_RABIT_ENSOCUG00000009515,(POP2_RAT_Q6P722,POP2_MOUSE_Q9ES82)),(POP2_MACMU_ENSMMUG00000000905,POP2_HUMAN_Q9HBU9)))))))),((POP1_CIOSA_ENSCSAVG00000000247,POP1_CIOIN_ENSCING00000000496),((POP1_DANRE_Q5PQZ7,(POP1_ORYLA_ENSORLG00000019663,POP1_GASAC_ENSGACG00000014015,POP1_TAKRU_ENSORLG00000019663)),(POP1_XENTR_B1H1G2,(POP1_ANOCA_ENSACAG00000003910,(POP1_TAEGU_ENSTGUG00000012218,POP1_CHICK_Q9DG23)),POP1_ORNAN_ENSOANG00000004180,POP1_MONDO_ENSMODG00000018034,(POP1_RABIT_ENSOCUG00000016944,(POP1_RAT_Q3BCU4,POP1_MOUSE_Q9ES83),(POP1_HUMAN_Q8NE79,POP1_MACMU_ENSMMUG00000014471))))));" ) ) { System.out.println( phys4[ 0 ].toNewHampshire() ); return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static final boolean testNHXparsingFromURL() { try { final String s = "https://sites.google.com/site/cmzmasek/home/software/archaeopteryx/examples/simple/simple_1.nh"; final URL u = new URL( s ); final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny[] phys = factory.create( u, new NHXParser() ); if ( ( phys == null ) || ( phys.length != 5 ) ) { return false; } if ( !phys[ 0 ].toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { System.out.println( phys[ 0 ].toNewHampshire() ); return false; } if ( !phys[ 1 ].toNewHampshire().equals( "((1,2,3),(4,5,6),(7,8,9));" ) ) { System.out.println( phys[ 1 ].toNewHampshire() ); return false; } final URL u2 = new URL( s ); final Phylogeny[] phys2 = factory.create( u2.openStream(), new NHXParser() ); if ( ( phys2 == null ) || ( phys2.length != 5 ) ) { return false; } if ( !phys2[ 0 ].toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { System.out.println( phys2[ 0 ].toNewHampshire() ); return false; } final PhylogenyFactory factory2 = ParserBasedPhylogenyFactory.getInstance(); final NHXParser p = new NHXParser(); final URL u3 = new URL( s ); p.setSource( u3 ); if ( !p.hasNext() ) { return false; } if ( !p.next().toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { return false; } if ( !p.hasNext() ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } if ( !p.next().toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { return false; } if ( !p.next().toNewHampshire().equals( "((1,2,3),(4,5,6),(7,8,9));" ) ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } if ( !p.next().toNewHampshire().equals( "((((A,B),C),D),(E,F));" ) ) { return false; } if ( !p.next().toNewHampshire().equals( "((1,2,3),(4,5,6),(7,8,9));" ) ) { return false; } } catch ( final Exception e ) { System.out.println( e.toString() ); e.printStackTrace(); return false; } return true; } private static boolean testOverlapRemoval() { try { final Domain d0 = new BasicDomain( "d0", ( short ) 2, ( short ) 5, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d1 = new BasicDomain( "d1", ( short ) 7, ( short ) 10, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d2 = new BasicDomain( "d2", ( short ) 0, ( short ) 20, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d3 = new BasicDomain( "d3", ( short ) 9, ( short ) 10, ( short ) 1, ( short ) 1, 0.1, 1 ); final Domain d4 = new BasicDomain( "d4", ( short ) 7, ( short ) 8, ( short ) 1, ( short ) 1, 0.1, 1 ); final List covered = new ArrayList(); covered.add( true ); // 0 covered.add( false ); // 1 covered.add( true ); // 2 covered.add( false ); // 3 covered.add( true ); // 4 covered.add( true ); // 5 covered.add( false ); // 6 covered.add( true ); // 7 covered.add( true ); // 8 if ( ForesterUtil.calculateOverlap( d0, covered ) != 3 ) { return false; } if ( ForesterUtil.calculateOverlap( d1, covered ) != 2 ) { return false; } if ( ForesterUtil.calculateOverlap( d2, covered ) != 6 ) { return false; } if ( ForesterUtil.calculateOverlap( d3, covered ) != 0 ) { return false; } if ( ForesterUtil.calculateOverlap( d4, covered ) != 2 ) { return false; } final Domain a = new BasicDomain( "a", ( short ) 2, ( short ) 5, ( short ) 1, ( short ) 1, 1, -1 ); final Domain b = new BasicDomain( "b", ( short ) 2, ( short ) 10, ( short ) 1, ( short ) 1, 0.1, -1 ); final Protein ab = new BasicProtein( "ab", "varanus", 0 ); ab.addProteinDomain( a ); ab.addProteinDomain( b ); final Protein ab_s0 = ForesterUtil.removeOverlappingDomains( 3, false, ab ); if ( ab.getNumberOfProteinDomains() != 2 ) { return false; } if ( ab_s0.getNumberOfProteinDomains() != 1 ) { return false; } if ( !ab_s0.getProteinDomain( 0 ).getDomainId().equals( "b" ) ) { return false; } final Protein ab_s1 = ForesterUtil.removeOverlappingDomains( 4, false, ab ); if ( ab.getNumberOfProteinDomains() != 2 ) { return false; } if ( ab_s1.getNumberOfProteinDomains() != 2 ) { return false; } final Domain c = new BasicDomain( "c", ( short ) 20000, ( short ) 20500, ( short ) 1, ( short ) 1, 10, 1 ); final Domain d = new BasicDomain( "d", ( short ) 10000, ( short ) 10500, ( short ) 1, ( short ) 1, 0.0000001, 1 ); final Domain e = new BasicDomain( "e", ( short ) 5000, ( short ) 5500, ( short ) 1, ( short ) 1, 0.0001, 1 ); final Protein cde = new BasicProtein( "cde", "varanus", 0 ); cde.addProteinDomain( c ); cde.addProteinDomain( d ); cde.addProteinDomain( e ); final Protein cde_s0 = ForesterUtil.removeOverlappingDomains( 0, false, cde ); if ( cde.getNumberOfProteinDomains() != 3 ) { return false; } if ( cde_s0.getNumberOfProteinDomains() != 3 ) { return false; } final Domain f = new BasicDomain( "f", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 10, 1 ); final Domain g = new BasicDomain( "g", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 0.01, 1 ); final Domain h = new BasicDomain( "h", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 0.0001, 1 ); final Domain i = new BasicDomain( "i", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 0.5, 1 ); final Domain i2 = new BasicDomain( "i", ( short ) 5, ( short ) 30, ( short ) 1, ( short ) 1, 0.5, 10 ); final Protein fghi = new BasicProtein( "fghi", "varanus", 0 ); fghi.addProteinDomain( f ); fghi.addProteinDomain( g ); fghi.addProteinDomain( h ); fghi.addProteinDomain( i ); fghi.addProteinDomain( i ); fghi.addProteinDomain( i ); fghi.addProteinDomain( i2 ); final Protein fghi_s0 = ForesterUtil.removeOverlappingDomains( 10, false, fghi ); if ( fghi.getNumberOfProteinDomains() != 7 ) { return false; } if ( fghi_s0.getNumberOfProteinDomains() != 1 ) { return false; } if ( !fghi_s0.getProteinDomain( 0 ).getDomainId().equals( "h" ) ) { return false; } final Protein fghi_s1 = ForesterUtil.removeOverlappingDomains( 11, false, fghi ); if ( fghi.getNumberOfProteinDomains() != 7 ) { return false; } if ( fghi_s1.getNumberOfProteinDomains() != 7 ) { return false; } final Domain j = new BasicDomain( "j", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 10, 1 ); final Domain k = new BasicDomain( "k", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 0.01, 1 ); final Domain l = new BasicDomain( "l", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 1, 0.0001, 1 ); final Domain m = new BasicDomain( "m", ( short ) 10, ( short ) 20, ( short ) 1, ( short ) 4, 0.5, 1 ); final Domain m0 = new BasicDomain( "m", ( short ) 10, ( short ) 20, ( short ) 2, ( short ) 4, 0.5, 1 ); final Domain m1 = new BasicDomain( "m", ( short ) 10, ( short ) 20, ( short ) 3, ( short ) 4, 0.5, 1 ); final Domain m2 = new BasicDomain( "m", ( short ) 5, ( short ) 30, ( short ) 4, ( short ) 4, 0.5, 10 ); final Protein jklm = new BasicProtein( "jklm", "varanus", 0 ); jklm.addProteinDomain( j ); jklm.addProteinDomain( k ); jklm.addProteinDomain( l ); jklm.addProteinDomain( m ); jklm.addProteinDomain( m0 ); jklm.addProteinDomain( m1 ); jklm.addProteinDomain( m2 ); final Protein jklm_s0 = ForesterUtil.removeOverlappingDomains( 10, false, jklm ); if ( jklm.getNumberOfProteinDomains() != 7 ) { return false; } if ( jklm_s0.getNumberOfProteinDomains() != 1 ) { return false; } if ( !jklm_s0.getProteinDomain( 0 ).getDomainId().equals( "l" ) ) { return false; } final Protein jklm_s1 = ForesterUtil.removeOverlappingDomains( 11, false, jklm ); if ( jklm.getNumberOfProteinDomains() != 7 ) { return false; } if ( jklm_s1.getNumberOfProteinDomains() != 7 ) { return false; } final Domain only = new BasicDomain( "only", ( short ) 5, ( short ) 30, ( short ) 4, ( short ) 4, 0.5, 10 ); final Protein od = new BasicProtein( "od", "varanus", 0 ); od.addProteinDomain( only ); final Protein od_s0 = ForesterUtil.removeOverlappingDomains( 0, false, od ); if ( od.getNumberOfProteinDomains() != 1 ) { return false; } if ( od_s0.getNumberOfProteinDomains() != 1 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static final boolean testPfamTreeReading() { try { final URL u = new URL( WebserviceUtil.PFAM_SERVER + "/family/PF" + "01849" + "/tree/download" ); final NHXParser parser = new NHXParser(); parser.setTaxonomyExtraction( NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); parser.setReplaceUnderscores( false ); parser.setGuessRootedness( true ); final Phylogeny[] phys = ForesterUtil.readPhylogeniesFromUrl( u, parser ); if ( ( phys == null ) || ( phys.length != 1 ) ) { return false; } if ( phys[ 0 ].getNumberOfExternalNodes() < 10 ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static final boolean testPhyloXMLparsingFromURL() { try { final String s = "https://sites.google.com/site/cmzmasek/home/software/archaeopteryx/examples/archaeopteryx_a/apaf_bcl2.xml"; final URL u = new URL( s ); final Phylogeny[] phys = ForesterUtil.readPhylogeniesFromUrl( u, PhyloXmlParser.createPhyloXmlParser() ); if ( ( phys == null ) || ( phys.length != 2 ) ) { return false; } final Phylogeny[] phys2 = ForesterUtil.readPhylogeniesFromUrl( u, PhyloXmlParser.createPhyloXmlParser() ); if ( ( phys2 == null ) || ( phys2.length != 2 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static final boolean testToLReading() { try { final URL u = new URL( WebserviceUtil.TOL_URL_BASE + "15079" ); final Phylogeny[] phys = ForesterUtil.readPhylogeniesFromUrl( u, new TolParser() ); if ( ( phys == null ) || ( phys.length != 1 ) ) { return false; } if ( !phys[ 0 ].getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "15079" ) ) { return false; } if ( !phys[ 0 ].getRoot().getNodeData().getTaxonomy().getScientificName() .equals( "Protacanthopterygii" ) ) { return false; } if ( phys[ 0 ].getNumberOfExternalNodes() < 5 ) { return false; } // final URL u2 = new URL( WebserviceUtil.TOL_URL_BASE + "17706" ); final Phylogeny[] phys2 = ForesterUtil.readPhylogeniesFromUrl( u2, new TolParser() ); if ( ( phys2 == null ) || ( phys2.length != 1 ) ) { return false; } if ( !phys2[ 0 ].getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "17706" ) ) { return false; } if ( phys2[ 0 ].getNumberOfExternalNodes() < 5 ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static final boolean testTreeBaseReading() { try { final URL u = new URL( WebserviceUtil.TREEBASE_PHYLOWS_TREE_URL_BASE + "72557?format=nexus" ); final NexusPhylogeniesParser parser = new NexusPhylogeniesParser(); parser.setReplaceUnderscores( true ); final Phylogeny[] phys = ForesterUtil.readPhylogeniesFromUrl( u, parser ); if ( ( phys == null ) || ( phys.length != 1 ) ) { return false; } final URL u_1 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_TREE_URL_BASE + "2406?format=nexus" ); final NexusPhylogeniesParser parser_1 = new NexusPhylogeniesParser(); final Phylogeny[] phys_1 = ForesterUtil.readPhylogeniesFromUrl( u_1, parser_1 ); if ( ( phys_1 == null ) || ( phys_1.length != 1 ) ) { return false; } final URL u_2 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_TREE_URL_BASE + "422?format=nexus" ); final NexusPhylogeniesParser parser_2 = new NexusPhylogeniesParser(); final Phylogeny[] phys_2 = ForesterUtil.readPhylogeniesFromUrl( u_2, parser_2 ); if ( ( phys_2 == null ) || ( phys_2.length != 1 ) ) { return false; } final URL u_3 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_TREE_URL_BASE + "2654?format=nexus" ); final NexusPhylogeniesParser parser_3 = new NexusPhylogeniesParser(); final Phylogeny[] phys_3 = ForesterUtil.readPhylogeniesFromUrl( u_3, parser_3 ); if ( ( phys_3 == null ) || ( phys_3.length != 1 ) ) { return false; } final URL u_4 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_TREE_URL_BASE + "825?format=nexus" ); final NexusPhylogeniesParser parser_4 = new NexusPhylogeniesParser(); final Phylogeny[] phys_4 = ForesterUtil.readPhylogeniesFromUrl( u_4, parser_4 ); if ( ( phys_4 == null ) || ( phys_4.length != 1 ) ) { return false; } final URL u2 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "15613?format=nexus" ); final NexusPhylogeniesParser parser2 = new NexusPhylogeniesParser(); parser2.setReplaceUnderscores( true ); final Phylogeny[] phys2 = ForesterUtil.readPhylogeniesFromUrl( u2, parser2 ); if ( ( phys2 == null ) || ( phys2.length != 9 ) ) { return false; } final URL u3 = new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "14909?format=nexus" ); final NexusPhylogeniesParser parser3 = new NexusPhylogeniesParser(); final Phylogeny[] phys3 = ForesterUtil.readPhylogeniesFromUrl( u3, parser3 ); if ( ( phys3 == null ) || ( phys3.length != 2 ) ) { return false; } final Phylogeny[] phys4 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "14525?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys4 == null ) || ( phys4.length != 1 ) ) { return false; } final Phylogeny[] phys5 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "15632?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys5 == null ) || ( phys5.length != 1 ) ) { return false; } final Phylogeny[] phys6 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "10190?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys6 == null ) || ( phys6.length != 1 ) ) { return false; } final Phylogeny[] phys7 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "13246?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys7 == null ) || ( phys7.length != 2 ) ) { return false; } final Phylogeny[] phys8 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "11662?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys8 == null ) || ( phys8.length != 2 ) ) { return false; } final Phylogeny[] phys9 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "562?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys9 == null ) || ( phys9.length != 4 ) ) { return false; } final Phylogeny[] phys16424 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "16424?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys16424 == null ) || ( phys16424.length != 1 ) ) { return false; } final Phylogeny[] phys17878 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "17878?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys17878 == null ) || ( phys17878.length != 17 ) ) { return false; } final Phylogeny[] phys18804 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "18804?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys18804 == null ) || ( phys18804.length != 2 ) ) { return false; } final Phylogeny[] phys346 = ForesterUtil.readPhylogeniesFromUrl( new URL( WebserviceUtil.TREEBASE_PHYLOWS_STUDY_URL_BASE + "346?format=nexus" ), new NexusPhylogeniesParser() ); if ( ( phys346 == null ) || ( phys346.length != 1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static final boolean testTreeFamReading() { try { final URL u = new URL( WebserviceUtil.TREE_FAM_URL_BASE + "101004" + "/tree/newick" ); final NHXParser parser = new NHXParser(); parser.setTaxonomyExtraction( NHXParser.TAXONOMY_EXTRACTION.NO ); parser.setReplaceUnderscores( false ); parser.setGuessRootedness( true ); final Phylogeny[] phys = ForesterUtil.readPhylogeniesFromUrl( u, parser ); if ( ( phys == null ) || ( phys.length != 1 ) ) { return false; } if ( phys[ 0 ].getNumberOfExternalNodes() < 10 ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private final static Phylogeny createPhylogeny( final String nhx ) throws IOException { final Phylogeny p = ParserBasedPhylogenyFactory.getInstance().create( nhx, new NHXParser() )[ 0 ]; return p; } private final static Event getEvent( final Phylogeny p, final String n1, final String n2 ) { return PhylogenyMethods.calculateLCA( p.getNode( n1 ), p.getNode( n2 ) ).getNodeData().getEvent(); } private static boolean testAminoAcidSequence() { try { final MolecularSequence aa1 = BasicSequence.createAaSequence( "aa1", "aAklm-?xX*z$#" ); if ( aa1.getLength() != 13 ) { return false; } if ( aa1.getResidueAt( 0 ) != 'A' ) { return false; } if ( aa1.getResidueAt( 2 ) != 'K' ) { return false; } if ( !new String( aa1.getMolecularSequence() ).equals( "AAKLM-XXX*ZXX" ) ) { return false; } final MolecularSequence aa2 = BasicSequence.createAaSequence( "aa3", "ARNDCQEGHILKMFPSTWYVX*-BZOJU" ); if ( !new String( aa2.getMolecularSequence() ).equals( "ARNDCQEGHILKMFPSTWYVX*-BZOXU" ) ) { return false; } final MolecularSequence dna1 = BasicSequence.createDnaSequence( "dna1", "ACGTUX*-?RYMKWSN" ); if ( !new String( dna1.getMolecularSequence() ).equals( "ACGTNN*-NRYMKWSN" ) ) { return false; } final MolecularSequence rna1 = BasicSequence.createRnaSequence( "rna1", "..ACGUTX*-?RYMKWSN" ); if ( !new String( rna1.getMolecularSequence() ).equals( "--ACGUNN*-NRYMKWSN" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testBasicDomain() { try { final Domain pd = new BasicDomain( "id", 23, 25, ( short ) 1, ( short ) 4, 0.1, -12 ); if ( !pd.getDomainId().equals( "id" ) ) { return false; } if ( pd.getNumber() != 1 ) { return false; } if ( pd.getTotalCount() != 4 ) { return false; } if ( !pd.equals( new BasicDomain( "id", 22, 111, ( short ) 1, ( short ) 4, 0.2, -12 ) ) ) { return false; } final Domain a1 = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 4, 0.1, -12 ); final BasicDomain a1_copy = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 4, 0.1, -12 ); final BasicDomain a1_equal = new BasicDomain( "a", 524, 743994, ( short ) 1, ( short ) 300, 3.0005, 230 ); final BasicDomain a2 = new BasicDomain( "a", 1, 10, ( short ) 2, ( short ) 4, 0.1, -12 ); final BasicDomain a3 = new BasicDomain( "A", 1, 10, ( short ) 1, ( short ) 4, 0.1, -12 ); if ( !a1.equals( a1 ) ) { return false; } if ( !a1.equals( a1_copy ) ) { return false; } if ( !a1.equals( a1_equal ) ) { return false; } if ( !a1.equals( a2 ) ) { return false; } if ( a1.equals( a3 ) ) { return false; } if ( a1.compareTo( a1 ) != 0 ) { return false; } if ( a1.compareTo( a1_copy ) != 0 ) { return false; } if ( a1.compareTo( a1_equal ) != 0 ) { return false; } if ( a1.compareTo( a2 ) != 0 ) { return false; } if ( a1.compareTo( a3 ) == 0 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicNodeMethods() { try { if ( PhylogenyNode.getNodeCount() != 0 ) { return false; } final PhylogenyNode n1 = new PhylogenyNode(); final PhylogenyNode n2 = PhylogenyNode .createInstanceFromNhxString( "", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); final PhylogenyNode n3 = PhylogenyNode .createInstanceFromNhxString( "n3", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); final PhylogenyNode n4 = PhylogenyNode .createInstanceFromNhxString( "n4:0.01", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( n1.isHasAssignedEvent() ) { return false; } if ( PhylogenyNode.getNodeCount() != 4 ) { return false; } if ( n3.getIndicator() != 0 ) { return false; } if ( n3.getNumberOfExternalNodes() != 1 ) { return false; } if ( !n3.isExternal() ) { return false; } if ( !n3.isRoot() ) { return false; } if ( !n4.getName().equals( "n4" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testCommonPrefix() { final List l0 = new ArrayList(); l0.add( "abc" ); if ( !ForesterUtil.greatestCommonPrefix( l0 ).equals( "abc" ) ) { return false; } final List l1 = new ArrayList(); l1.add( "abc" ); l1.add( "abX" ); if ( !ForesterUtil.greatestCommonPrefix( l1 ).equals( "ab" ) ) { return false; } final List l2 = new ArrayList(); l2.add( "abc" ); l2.add( "abX" ); l2.add( "axy" ); if ( !ForesterUtil.greatestCommonPrefix( l2 ).equals( "a" ) ) { return false; } final List l3 = new ArrayList(); l3.add( "abXsdfsdfsdfsdfsdfsd" ); l3.add( "abXsdfsdfsdfsdfsdfsd" ); l3.add( "abc" ); l3.add( "abXsdfsdfsdfsdfsdfsd" ); l3.add( "ab" ); l3.add( "abc" ); l3.add( "ab" ); if ( !ForesterUtil.greatestCommonPrefix( l3 ).equals( "ab" ) ) { return false; } final List l4 = new ArrayList(); l4.add( "abXsdfsdfsdfsdfsdfsd" ); l4.add( "abXsdfsdfsdfsdfsdfsd" ); l4.add( "abc" ); l4.add( "Xsdfsdfsdfsdfsdfsd" ); l4.add( "ab" ); l4.add( "abc" ); if ( !ForesterUtil.greatestCommonPrefix( l4 ).equals( "" ) ) { return false; } final List l5 = new ArrayList(); l5.add( "" ); if ( !ForesterUtil.greatestCommonPrefix( l5 ).equals( "" ) ) { return false; } final List l6 = new ArrayList(); l6.add( "abc" ); l6.add( "abX" ); l6.add( "" ); if ( !ForesterUtil.greatestCommonPrefix( l6 ).equals( "" ) ) { return false; } return true; } private static boolean testCommonPrefixSep() { final List l0 = new ArrayList(); l0.add( "a.b.c" ); if ( !ForesterUtil.greatestCommonPrefix( l0, ".").equals( "a.b.c" ) ) { return false; } final List l1 = new ArrayList(); l1.add( "a.b.c" ); l1.add( "a.b.X" ); if ( !ForesterUtil.greatestCommonPrefix( l1 , ".").equals( "a.b" ) ) { return false; } final List l2 = new ArrayList(); l2.add( "a.b.c." ); l2.add( "a.b.X." ); l2.add( "a.x.y." ); if ( !ForesterUtil.greatestCommonPrefix( l2, ".").equals( "a" ) ) { return false; } final List l3 = new ArrayList(); l3.add( "a/b/X/s/d/f/s/d/f/s/d/f/s/d/f/s/d/f/s/d/" ); l3.add( "a/b/X/s/d/f/s/d/f/s/d/f/s/d/f/s/d/f/s/d" ); l3.add( "a/b/c" ); l3.add( "a/b/X/s/d/f/s/d/f/s/d/f/s/d/f/s/d/f/s/d/" ); l3.add( "a/b/" ); l3.add( "a/b/c/" ); l3.add( "a/b////////" ); if ( !ForesterUtil.greatestCommonPrefix( l3, "/" ).equals( "a/b" ) ) { return false; } final List l4 = new ArrayList(); l4.add( "a.b.X.s.d.f.s.d.f.s.d.f.s.d.f.s.d.f.s.d" ); l4.add( "a.b.X.s.d.f.s.d.f.s.d.f.s.d.f.s.d.f.s.d" ); l4.add( "a.b.c" ); l4.add( "X.s.d.f.s.d.f.s.d.f.s.d.f.s.d.f.s.d..." ); l4.add( "a.b" ); l4.add( "a.b.c" ); if ( !ForesterUtil.greatestCommonPrefix( l4, "." ).equals( "" ) ) { return false; } final List l5 = new ArrayList(); l5.add( "" ); if ( !ForesterUtil.greatestCommonPrefix( l5, "_" ).equals( "" ) ) { return false; } final List l6 = new ArrayList(); l6.add( "_" ); l6.add( "__" ); if ( !ForesterUtil.greatestCommonPrefix( l6, "_" ).equals( "" ) ) { return false; } final List l7 = new ArrayList(); l7.add( "a,b,c" ); l7.add( "a,b,X" ); l7.add( "" ); l7.add( ",,,,,,,,,," ); if ( !ForesterUtil.greatestCommonPrefix( l7, "," ).equals( "" ) ) { return false; } final List l8 = new ArrayList(); l8.add( "123.304.403.04" ); l8.add( "123.304.403.04.02" ); l8.add( "123.304.403.03.03" ); if ( !ForesterUtil.greatestCommonPrefix( l8, "." ).equals( "123.304.403" ) ) { return false; } final List l9 = new ArrayList(); l9.add( "123.304.403.04" ); l9.add( "123.304.403.04.02" ); l9.add( "123.304.402.03.03" ); if ( !ForesterUtil.greatestCommonPrefix( l9, "." ).equals( "123.304" ) ) { return false; } return true; } private static boolean testUTF8ParsingFromFile() { try { final PhyloXmlParser xml_parser = PhyloXmlParser.createPhyloXmlParser(); final Phylogeny[] phylogenies_xml = ParserBasedPhylogenyFactory.getInstance() .create( new File( Test.PATH_TO_TEST_DATA + "chars.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_xml.length != 1 ) { return false; } final Phylogeny[] phylogenies_xml2 = ParserBasedPhylogenyFactory.getInstance() .create( new StringBuffer( phylogenies_xml[ 0 ].toPhyloXML( 0 ) ), xml_parser ); final Phylogeny[] phylogenies_nh = ParserBasedPhylogenyFactory.getInstance() .create( new File( Test.PATH_TO_TEST_DATA + "chars.nh" ), new NHXParser() ); if ( phylogenies_nh.length != 1 ) { return false; } final Phylogeny[] phylogenies_nex = ParserBasedPhylogenyFactory.getInstance() .create( new File( Test.PATH_TO_TEST_DATA + "chars.nex" ), new NexusPhylogeniesParser() ); if ( phylogenies_nex.length != 1 ) { return false; } final String[] xml_n = phylogenies_xml[ 0 ].getAllExternalNodeNames(); final String[] xml_n2 = phylogenies_xml2[ 0 ].getAllExternalNodeNames(); final String[] nh_n = phylogenies_nh[ 0 ].getAllExternalNodeNames(); final String[] nex_n = phylogenies_nex[ 0 ].getAllExternalNodeNames(); final String n0 = "AQ~!@#$%^&*()_+-=\\{}|;:\"<>?,./"; final String n1 = "€‚ƒ„…†‡ˆ‰Š‹ŒŽ‘’“”•–—˜˜˜™š›œžŸ¡¢£¤¥¦§¨©ª«¬®¯°±¹²³´µ¶·¸º»¼¿À÷þÿ"; final String n2 = "漢字ひらがなカタカナ"; final String n3 = "อักษรไทย"; final String n4 = "繁體字"; final String n5 = "한글"; final String n6 = "देवनागरी"; final String n7 = "chữ Quốc ngữ"; final String n8 = "ру́сский язы́к"; final String n9 = "អក្សរខ្មែរ"; if ( !xml_n[ 0 ].equals( n0 ) ) { System.out.println( xml_n[ 0 ] ); System.out.println( n0 ); return false; } if ( !xml_n2[ 0 ].equals( n0 ) ) { System.out.println( xml_n2[ 0 ] ); System.out.println( n0 ); return false; } if ( !nh_n[ 0 ].equals( n0 ) ) { System.out.println( nh_n[ 0 ] ); System.out.println( n0 ); return false; } if ( !nex_n[ 0 ].equals( n0 ) ) { System.out.println( nex_n[ 0 ] ); System.out.println( n0 ); return false; } if ( !xml_n[ 1 ].equals( n1 ) ) { System.out.println( xml_n[ 1 ] ); System.out.println( n1 ); return false; } if ( !xml_n2[ 1 ].equals( n1 ) ) { System.out.println( xml_n2[ 1 ] ); System.out.println( n1 ); return false; } if ( !nh_n[ 1 ].equals( n1 ) ) { System.out.println( nh_n[ 1 ] ); System.out.println( n1 ); return false; } if ( !nex_n[ 1 ].equals( n1 ) ) { System.out.println( nex_n[ 1 ] ); System.out.println( n1 ); return false; } if ( !xml_n[ 2 ].equals( n2 ) ) { System.out.println( xml_n[ 2 ] ); System.out.println( n2 ); return false; } if ( !xml_n2[ 2 ].equals( n2 ) ) { System.out.println( xml_n2[ 2 ] ); System.out.println( n2 ); return false; } if ( !nh_n[ 2 ].equals( n2 ) ) { System.out.println( nh_n[ 2 ] ); System.out.println( n2 ); return false; } if ( !nex_n[ 2 ].equals( n2 ) ) { System.out.println( nex_n[ 2 ] ); System.out.println( n2 ); return false; } // if ( !xml_n[ 3 ].equals( n3 ) ) { System.out.println( xml_n[ 3 ] ); System.out.println( n3 ); return false; } if ( !xml_n2[ 3 ].equals( n3 ) ) { System.out.println( xml_n2[ 3 ] ); System.out.println( n3 ); return false; } if ( !nh_n[ 3 ].equals( n3 ) ) { System.out.println( nh_n[ 3 ] ); System.out.println( n3 ); return false; } if ( !nex_n[ 3 ].equals( n3 ) ) { System.out.println( nex_n[ 3 ] ); System.out.println( n3 ); return false; } // if ( !xml_n[ 4 ].equals( n4 ) ) { System.out.println( xml_n[ 4 ] ); System.out.println( n4 ); return false; } if ( !nh_n[ 4 ].equals( n4 ) ) { System.out.println( nh_n[ 4 ] ); System.out.println( n4 ); return false; } if ( !nex_n[ 4 ].equals( n4 ) ) { System.out.println( nex_n[ 4 ] ); System.out.println( n4 ); return false; } // if ( !xml_n[ 5 ].equals( n5 ) ) { System.out.println( xml_n[ 5 ] ); System.out.println( n5 ); return false; } if ( !nh_n[ 5 ].equals( n5 ) ) { System.out.println( nh_n[ 5 ] ); System.out.println( n5 ); return false; } if ( !nex_n[ 5 ].equals( n5 ) ) { System.out.println( nex_n[ 5 ] ); System.out.println( n5 ); return false; } // if ( !xml_n[ 6 ].equals( n6 ) ) { System.out.println( xml_n[ 6 ] ); System.out.println( n6 ); return false; } if ( !nh_n[ 6 ].equals( n6 ) ) { System.out.println( nh_n[ 6 ] ); System.out.println( n6 ); return false; } if ( !nex_n[ 6 ].equals( n6 ) ) { System.out.println( nex_n[ 6 ] ); System.out.println( n6 ); return false; } // if ( !xml_n[ 7 ].equals( n7 ) ) { System.out.println( xml_n[ 7 ] ); System.out.println( n7 ); return false; } if ( !nh_n[ 7 ].equals( n7 ) ) { System.out.println( nh_n[ 7 ] ); System.out.println( n7 ); return false; } if ( !nex_n[ 7 ].equals( n7 ) ) { System.out.println( nex_n[ 7 ] ); System.out.println( n7 ); return false; } if ( !xml_n[ 8 ].equals( n8 ) ) { System.out.println( xml_n[ 8 ] ); System.out.println( n8 ); return false; } if ( !nh_n[ 8 ].equals( n8 ) ) { System.out.println( nh_n[ 8 ] ); System.out.println( n8 ); return false; } if ( !nex_n[ 8 ].equals( n8 ) ) { System.out.println( nex_n[ 8 ] ); System.out.println( n8 ); return false; } if ( !xml_n[ 9 ].equals( n9 ) ) { System.out.println( xml_n[ 9 ] ); System.out.println( n9 ); return false; } if ( !xml_n2[ 9 ].equals( n9 ) ) { System.out.println( xml_n2[ 9 ] ); System.out.println( n9 ); return false; } if ( !nh_n[ 9 ].equals( n9 ) ) { System.out.println( nh_n[ 9 ] ); System.out.println( n9 ); return false; } if ( !nex_n[ 9 ].equals( n9 ) ) { System.out.println( nex_n[ 9 ] ); System.out.println( n9 ); return false; } if ( !phylogenies_xml[ 0 ].toNewHampshire().equals( phylogenies_nh[ 0 ].toNewHampshire() ) ) { System.out.println( phylogenies_xml[ 0 ].toNewHampshire() ); System.out.println( phylogenies_nh[ 0 ].toNewHampshire() ); return false; } if ( !phylogenies_xml[ 0 ].toNewHampshire().equals( phylogenies_nex[ 0 ].toNewHampshire() ) ) { System.out.println( phylogenies_xml[ 0 ].toNewHampshire() ); System.out.println( phylogenies_nex[ 0 ].toNewHampshire() ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicPhyloXMLparsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final PhyloXmlParser xml_parser = PhyloXmlParser.createPhyloXmlParser(); final Phylogeny[] phylogenies_0 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_t1.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 4 ) { return false; } final Phylogeny t1 = phylogenies_0[ 0 ]; final Phylogeny t2 = phylogenies_0[ 1 ]; final Phylogeny t3 = phylogenies_0[ 2 ]; final Phylogeny t4 = phylogenies_0[ 3 ]; if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } if ( !t1.isRooted() ) { return false; } if ( t1.isRerootable() ) { return false; } if ( !t1.getType().equals( "gene_tree" ) ) { return false; } if ( t2.getNumberOfExternalNodes() != 2 ) { return false; } if ( !isEqual( t2.getNode( "node a" ).getDistanceToParent(), 1.0 ) ) { return false; } if ( !isEqual( t2.getNode( "node b" ).getDistanceToParent(), 2.0 ) ) { return false; } if ( t2.getNode( "node a" ).getNodeData().getTaxonomies().size() != 2 ) { return false; } if ( !t2.getNode( "node a" ).getNodeData().getTaxonomy( 0 ).getCommonName().equals( "some parasite" ) ) { return false; } if ( !t2.getNode( "node a" ).getNodeData().getTaxonomy( 1 ).getCommonName().equals( "the host" ) ) { return false; } if ( t2.getNode( "node a" ).getNodeData().getSequences().size() != 2 ) { return false; } if ( !t2.getNode( "node a" ).getNodeData().getSequence( 0 ).getMolecularSequence() .startsWith( "actgtgggggt" ) ) { return false; } if ( !t2.getNode( "node a" ).getNodeData().getSequence( 1 ).getMolecularSequence() .startsWith( "ctgtgatgcat" ) ) { return false; } if ( t3.getNumberOfExternalNodes() != 4 ) { return false; } if ( !t1.getName().equals( "t1" ) ) { return false; } if ( !t2.getName().equals( "t2" ) ) { return false; } if ( !t3.getName().equals( "t3" ) ) { return false; } if ( !t4.getName().equals( "t4" ) ) { return false; } if ( !t3.getIdentifier().getValue().equals( "1-1" ) ) { return false; } if ( !t3.getIdentifier().getProvider().equals( "treebank" ) ) { return false; } if ( !t3.getNode( "root node" ).isDuplication() ) { return false; } if ( !t3.getNode( "node a" ).isDuplication() ) { return false; } if ( t3.getNode( "node a" ).isSpeciation() ) { return false; } if ( t3.getNode( "node bc" ).isDuplication() ) { return false; } if ( !t3.getNode( "node bc" ).isSpeciation() ) { return false; } if ( !t3.getNode( "root node" ).getNodeData().getSequence().getType().equals( "protein" ) ) { return false; } if ( !t3.getNode( "root node" ).getNodeData().getSequence().getName() .equals( "Apoptosis facilitator Bcl-2-like 14 protein" ) ) { return false; } if ( !t3.getNode( "root node" ).getNodeData().getSequence().getSymbol().equals( "BCL2L14" ) ) { return false; } if ( !t3.getNode( "root node" ).getNodeData().getSequence().getAccession().getValue().equals( "Q9BZR8" ) ) { return false; } if ( !t3.getNode( "root node" ).getNodeData().getSequence().getAccession().getSource() .equals( "UniProtKB" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getDesc() .equals( "apoptosis" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getRef() .equals( "GO:0006915" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getSource() .equals( "UniProtKB" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getEvidence() .equals( "experimental" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getType() .equals( "function" ) ) { return false; } if ( ( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getConfidence() .getValue() != 1 ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getConfidence().getType() .equals( "ml" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getDesc() .equals( "apoptosis" ) ) { return false; } if ( ( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getAppliesTo() != AppliesTo.ANNOTATION ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getDataType().equals( "xsd:double" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getRef().equals( "AFFY:expression" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getUnit().equals( "AFFY:x" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getValue().equals( "0.2" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "MED:disease" ).get( 0 ).getValue().equals( "lymphoma" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 1 ) ).getRef() .equals( "GO:0005829" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 0 ) ).getDesc() .equals( "intracellular organelle" ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getUri( 0 ).getType().equals( "source" ) ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getUri( 0 ).getDescription() .equals( "UniProt link" ) ) ) { return false; } if ( !( t3.getNode( "root node" ).getNodeData().getSequence().getLocation().equals( "12p13-p12" ) ) ) { return false; } final SortedSet x = t3.getNode( "root node" ).getNodeData().getSequence().getCrossReferences(); if ( x.size() != 4 ) { return false; } int c = 0; for( final Accession acc : x ) { if ( c == 0 ) { if ( !acc.getSource().equals( "KEGG" ) ) { return false; } if ( !acc.getValue().equals( "hsa:596" ) ) { return false; } } c++; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicPhyloXMLparsingRoundtrip() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final PhyloXmlParser xml_parser = PhyloXmlParser.createPhyloXmlParser(); if ( USE_LOCAL_PHYLOXML_SCHEMA ) { xml_parser.setValidateAgainstSchema( PHYLOXML_LOCAL_XSD ); } else { xml_parser.setValidateAgainstSchema( PHYLOXML_REMOTE_XSD ); } final Phylogeny[] phylogenies_0 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_t1.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 4 ) { return false; } final StringBuffer t1_sb = new StringBuffer( phylogenies_0[ 0 ].toPhyloXML( 0 ) ); final Phylogeny[] phylogenies_t1 = factory.create( t1_sb, xml_parser ); if ( phylogenies_t1.length != 1 ) { return false; } final Phylogeny t1_rt = phylogenies_t1[ 0 ]; if ( !t1_rt.getDistanceUnit().equals( "cc" ) ) { return false; } if ( !t1_rt.isRooted() ) { return false; } if ( t1_rt.isRerootable() ) { return false; } if ( !t1_rt.getType().equals( "gene_tree" ) ) { return false; } final StringBuffer t2_sb = new StringBuffer( phylogenies_0[ 1 ].toPhyloXML( 0 ) ); final Phylogeny[] phylogenies_t2 = factory.create( t2_sb, xml_parser ); final Phylogeny t2_rt = phylogenies_t2[ 0 ]; if ( t2_rt.getNode( "node a" ).getNodeData().getTaxonomies().size() != 2 ) { return false; } if ( !t2_rt.getNode( "node a" ).getNodeData().getTaxonomy( 0 ).getCommonName().equals( "some parasite" ) ) { return false; } if ( !t2_rt.getNode( "node a" ).getNodeData().getTaxonomy( 1 ).getCommonName().equals( "the host" ) ) { return false; } if ( t2_rt.getNode( "node a" ).getNodeData().getSequences().size() != 2 ) { return false; } if ( !t2_rt.getNode( "node a" ).getNodeData().getSequence( 0 ).getMolecularSequence() .startsWith( "actgtgggggt" ) ) { return false; } if ( !t2_rt.getNode( "node a" ).getNodeData().getSequence( 1 ).getMolecularSequence() .startsWith( "ctgtgatgcat" ) ) { return false; } final StringBuffer t3_sb_0 = new StringBuffer( phylogenies_0[ 2 ].toPhyloXML( 0 ) ); final Phylogeny[] phylogenies_1_0 = factory.create( t3_sb_0, xml_parser ); final StringBuffer t3_sb = new StringBuffer( phylogenies_1_0[ 0 ].toPhyloXML( 0 ) ); final Phylogeny[] phylogenies_1 = factory.create( t3_sb, xml_parser ); if ( phylogenies_1.length != 1 ) { return false; } final Phylogeny t3_rt = phylogenies_1[ 0 ]; if ( !t3_rt.getName().equals( "t3" ) ) { return false; } if ( t3_rt.getNumberOfExternalNodes() != 4 ) { return false; } if ( !t3_rt.getIdentifier().getValue().equals( "1-1" ) ) { return false; } if ( !t3_rt.getIdentifier().getProvider().equals( "treebank" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getSequence().getType().equals( "protein" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getSequence().getName() .equals( "Apoptosis facilitator Bcl-2-like 14 protein" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getSequence().getSymbol().equals( "BCL2L14" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getSequence().getAccession().getValue() .equals( "Q9BZR8" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getSequence().getAccession().getSource() .equals( "UniProtKB" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getDesc() .equals( "apoptosis" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getRef() .equals( "GO:0006915" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getSource() .equals( "UniProtKB" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getEvidence() .equals( "experimental" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getType() .equals( "function" ) ) { return false; } if ( ( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getConfidence() .getValue() != 1 ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getConfidence() .getType().equals( "ml" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getDesc() .equals( "apoptosis" ) ) { return false; } if ( ( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getAppliesTo() != AppliesTo.ANNOTATION ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getDataType().equals( "xsd:double" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getRef().equals( "AFFY:expression" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getUnit().equals( "AFFY:x" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "AFFY:expression" ).get( 0 ).getValue().equals( "0.2" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 2 ) ).getProperties() .getProperties( "MED:disease" ).get( 0 ).getValue().equals( "lymphoma" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 1 ) ).getRef() .equals( "GO:0005829" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getAnnotation( 0 ) ).getDesc() .equals( "intracellular organelle" ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getUri( 0 ).getType() .equals( "source" ) ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getUri( 0 ).getDescription() .equals( "UniProt link" ) ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getSequence().getLocation().equals( "12p13-p12" ) ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getReference().getDoi() .equals( "10.1038/387489a0" ) ) ) { return false; } if ( !( t3_rt.getNode( "root node" ).getNodeData().getReference().getDescription() .equals( "Aguinaldo, A. M. A.; J. M. Turbeville, L. S. Linford, M. C. Rivera, J. R. Garey, R. A. Raff, & J. A. Lake (1997). \"Evidence for a clade of nematodes, arthropods and other moulting animals\". Nature 387 (6632): 489–493." ) ) ) { System.out.println( t3_rt.getNode( "root node" ).getNodeData().getReference().getDescription() ); return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getTaxonomy().getTaxonomyCode().equals( "ECDYS" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getTaxonomy().getScientificName().equals( "ecdysozoa" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getTaxonomy().getCommonName() .equals( "molting animals" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getTaxonomy().getIdentifier().getValue().equals( "1" ) ) { return false; } if ( !t3_rt.getNode( "root node" ).getNodeData().getTaxonomy().getIdentifier().getProvider() .equals( "ncbi" ) ) { return false; } if ( t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture() .getTotalLength() != 124 ) { return false; } if ( !t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ) .getName().equals( "B" ) ) { return false; } if ( t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ) .getFrom() != 21 ) { return false; } if ( t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ) .getTo() != 44 ) { return false; } if ( t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ) .getLength() != 24 ) { return false; } if ( t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ) .getConfidence() != 0 ) { return false; } if ( !t3_rt.getNode( "node bc" ).getNodeData().getSequence().getDomainArchitecture().getDomain( 0 ).getId() .equals( "pfam" ) ) { return false; } if ( t3_rt.getNode( "node bb" ).getNodeData().getBinaryCharacters().getGainedCharacters().size() != 3 ) { return false; } if ( t3_rt.getNode( "node bb" ).getNodeData().getBinaryCharacters().getPresentCharacters().size() != 2 ) { return false; } if ( t3_rt.getNode( "node bb" ).getNodeData().getBinaryCharacters().getLostCharacters().size() != 1 ) { return false; } if ( !t3_rt.getNode( "node bb" ).getNodeData().getBinaryCharacters().getType().equals( "domains" ) ) { return false; } final Taxonomy taxbb = t3_rt.getNode( "node bb" ).getNodeData().getTaxonomy(); if ( !taxbb.getAuthority().equals( "Stephenson, 1935" ) ) { return false; } if ( !taxbb.getCommonName().equals( "starlet sea anemone" ) ) { return false; } if ( !taxbb.getIdentifier().getProvider().equals( "EOL" ) ) { return false; } if ( !taxbb.getIdentifier().getValue().equals( "704294" ) ) { return false; } if ( !taxbb.getTaxonomyCode().equals( "NEMVE" ) ) { return false; } if ( !taxbb.getScientificName().equals( "Nematostella vectensis" ) ) { return false; } if ( taxbb.getSynonyms().size() != 2 ) { return false; } if ( !taxbb.getSynonyms().contains( "Nematostella vectensis Stephenson1935" ) ) { return false; } if ( !taxbb.getSynonyms().contains( "See Anemone" ) ) { return false; } if ( !taxbb.getUri( 0 ).getDescription().equals( "EOL" ) ) { return false; } if ( !taxbb.getUri( 0 ).getType().equals( "linkout" ) ) { return false; } if ( !taxbb.getUri( 0 ).getValue().toString().equals( "http://www.eol.org/pages/704294" ) ) { return false; } if ( ( ( BinaryCharacters ) t3_rt.getNode( "node bb" ).getNodeData().getBinaryCharacters().copy() ) .getLostCount() != BinaryCharacters.COUNT_DEFAULT ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getGainedCount() != 1 ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getGainedCharacters().size() != 1 ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getLostCount() != 3 ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getLostCharacters().size() != 3 ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getPresentCount() != 2 ) { return false; } if ( t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getPresentCharacters().size() != 2 ) { return false; } if ( !t3_rt.getNode( "node b" ).getNodeData().getBinaryCharacters().getType().equals( "characters" ) ) { return false; } if ( !t3_rt.getNode( "node ba" ).getNodeData().getDate().getDesc().equals( "Silurian" ) ) { return false; } if ( !t3_rt.getNode( "node ba" ).getNodeData().getDate().getValue().toPlainString() .equalsIgnoreCase( "435" ) ) { return false; } if ( !t3_rt.getNode( "node ba" ).getNodeData().getDate().getMin().toPlainString() .equalsIgnoreCase( "416" ) ) { return false; } if ( !t3_rt.getNode( "node ba" ).getNodeData().getDate().getMax().toPlainString() .equalsIgnoreCase( "443.7" ) ) { return false; } if ( !t3_rt.getNode( "node ba" ).getNodeData().getDate().getUnit().equals( "mya" ) ) { return false; } if ( !t3_rt.getNode( "node bb" ).getNodeData().getDate().getDesc().equals( "Triassic" ) ) { return false; } if ( !t3_rt.getNode( "node bc" ).getNodeData().getDate().getValue().toPlainString() .equalsIgnoreCase( "433" ) ) { return false; } final SortedSet x = t3_rt.getNode( "root node" ).getNodeData().getSequence() .getCrossReferences(); if ( x.size() != 4 ) { return false; } int c = 0; for( final Accession acc : x ) { if ( c == 0 ) { if ( !acc.getSource().equals( "KEGG" ) ) { return false; } if ( !acc.getValue().equals( "hsa:596" ) ) { return false; } } c++; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicPhyloXMLparsingValidating() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); PhyloXmlParser xml_parser = null; try { xml_parser = PhyloXmlParser.createPhyloXmlParserXsdValidating(); } catch ( final Exception e ) { // Do nothing -- means were not running from jar. } if ( xml_parser == null ) { xml_parser = PhyloXmlParser.createPhyloXmlParser(); if ( USE_LOCAL_PHYLOXML_SCHEMA ) { xml_parser.setValidateAgainstSchema( PHYLOXML_LOCAL_XSD ); } else { xml_parser.setValidateAgainstSchema( PHYLOXML_REMOTE_XSD ); } } final Phylogeny[] phylogenies_0 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_t1.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 4 ) { return false; } final Phylogeny t1 = phylogenies_0[ 0 ]; final Phylogeny t2 = phylogenies_0[ 1 ]; final Phylogeny t3 = phylogenies_0[ 2 ]; final Phylogeny t4 = phylogenies_0[ 3 ]; if ( !t1.getName().equals( "t1" ) ) { return false; } if ( !t2.getName().equals( "t2" ) ) { return false; } if ( !t3.getName().equals( "t3" ) ) { return false; } if ( !t4.getName().equals( "t4" ) ) { return false; } if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } if ( t2.getNumberOfExternalNodes() != 2 ) { return false; } if ( t3.getNumberOfExternalNodes() != 4 ) { return false; } final String x2 = Test.PATH_TO_TEST_DATA + "phyloxml_test_t1.xml"; final Phylogeny[] phylogenies_1 = factory.create( new File( x2 ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( "errors:" ); System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_1.length != 4 ) { return false; } final Phylogeny[] phylogenies_2 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_t3.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( "errors:" ); System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_2.length != 1 ) { return false; } if ( phylogenies_2[ 0 ].getNumberOfExternalNodes() != 2 ) { return false; } final Phylogeny[] phylogenies_3 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_t4.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_3.length != 2 ) { return false; } final Phylogeny a = phylogenies_3[ 0 ]; if ( !a.getName().equals( "tree 4" ) ) { return false; } if ( a.getNumberOfExternalNodes() != 3 ) { return false; } if ( !a.getNode( "node b1" ).getNodeData().getSequence().getName().equals( "b1 gene" ) ) { return false; } if ( !a.getNode( "node b1" ).getNodeData().getTaxonomy().getCommonName().equals( "b1 species" ) ) { return false; } final Phylogeny[] phylogenies_4 = factory .create( new File( Test.PATH_TO_TEST_DATA + "special_characters.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_4.length != 1 ) { return false; } final Phylogeny s = phylogenies_4[ 0 ]; if ( s.getNumberOfExternalNodes() != 6 ) { return false; } s.getNode( "first" ); s.getNode( "<>" ); s.getNode( "\"\"" ); s.getNode( "'''\"" ); s.getNode( "\"\"\"" ); s.getNode( "dick & doof" ); } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPhyloXMLparsingValidating() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); PhyloXmlParser xml_parser = null; try { xml_parser = PhyloXmlParser.createPhyloXmlParserXsdValidating(); } catch ( final Exception e ) { // Do nothing -- means were not running from jar. } if ( xml_parser == null ) { xml_parser = PhyloXmlParser.createPhyloXmlParser(); if ( USE_LOCAL_PHYLOXML_SCHEMA ) { xml_parser.setValidateAgainstSchema( PHYLOXML_LOCAL_XSD ); } else { xml_parser.setValidateAgainstSchema( PHYLOXML_REMOTE_XSD ); } } final Phylogeny[] phylogenies_0 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_test_1.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 3 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicProtein() { try { final BasicProtein p0 = new BasicProtein( "p0", "owl", 0 ); final Domain a = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain b = new BasicDomain( "b", 11, 20, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain c = new BasicDomain( "c", 9, 23, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain d = new BasicDomain( "d", 15, 30, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e = new BasicDomain( "e", 60, 70, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain x = new BasicDomain( "x", 100, 110, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain y = new BasicDomain( "y", 100, 110, ( short ) 1, ( short ) 5, 0.1, -12 ); p0.addProteinDomain( y ); p0.addProteinDomain( e ); p0.addProteinDomain( b ); p0.addProteinDomain( c ); p0.addProteinDomain( d ); p0.addProteinDomain( a ); p0.addProteinDomain( x ); if ( !p0.toDomainArchitectureString( "~" ).equals( "a~b~c~d~e~x~y" ) ) { return false; } if ( !p0.toDomainArchitectureString( "~", 3, "=" ).equals( "a~b~c~d~e~x~y" ) ) { return false; } // final BasicProtein aa0 = new BasicProtein( "aa", "owl", 0 ); final Domain a1 = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 5, 0.1, -12 ); aa0.addProteinDomain( a1 ); if ( !aa0.toDomainArchitectureString( "~" ).equals( "a" ) ) { return false; } if ( !aa0.toDomainArchitectureString( "~", 3, "" ).equals( "a" ) ) { return false; } // final BasicProtein aa1 = new BasicProtein( "aa", "owl", 0 ); final Domain a11 = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain a12 = new BasicDomain( "a", 2, 20, ( short ) 1, ( short ) 5, 0.1, -12 ); aa1.addProteinDomain( a11 ); aa1.addProteinDomain( a12 ); if ( !aa1.toDomainArchitectureString( "~" ).equals( "a~a" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 3, "" ).equals( "a~a" ) ) { return false; } aa1.addProteinDomain( new BasicDomain( "a", 20, 30, ( short ) 1, ( short ) 5, 0.1, -12 ) ); if ( !aa1.toDomainArchitectureString( "~" ).equals( "a~a~a" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 3, "" ).equals( "aaa" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 4, "" ).equals( "a~a~a" ) ) { return false; } aa1.addProteinDomain( new BasicDomain( "a", 30, 40, ( short ) 1, ( short ) 5, 0.1, -12 ) ); if ( !aa1.toDomainArchitectureString( "~" ).equals( "a~a~a~a" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 3, "" ).equals( "aaa" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 4, "" ).equals( "aaa" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 5, "" ).equals( "a~a~a~a" ) ) { return false; } aa1.addProteinDomain( new BasicDomain( "b", 32, 40, ( short ) 1, ( short ) 5, 0.1, -12 ) ); if ( !aa1.toDomainArchitectureString( "~" ).equals( "a~a~a~a~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 3, "" ).equals( "aaa~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 4, "" ).equals( "aaa~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 5, "" ).equals( "a~a~a~a~b" ) ) { return false; } aa1.addProteinDomain( new BasicDomain( "c", 1, 2, ( short ) 1, ( short ) 5, 0.1, -12 ) ); if ( !aa1.toDomainArchitectureString( "~" ).equals( "c~a~a~a~a~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 3, "" ).equals( "c~aaa~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 4, "" ).equals( "c~aaa~b" ) ) { return false; } if ( !aa1.toDomainArchitectureString( "~", 5, "" ).equals( "c~a~a~a~a~b" ) ) { return false; } // final BasicProtein p00 = new BasicProtein( "p0", "owl", 0 ); final Domain a0 = new BasicDomain( "a", 1, 10, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain b0 = new BasicDomain( "b", 11, 20, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain c0 = new BasicDomain( "c", 9, 23, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain d0 = new BasicDomain( "d", 15, 30, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e0 = new BasicDomain( "e", 60, 70, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e1 = new BasicDomain( "e", 61, 71, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e2 = new BasicDomain( "e", 62, 72, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e3 = new BasicDomain( "e", 63, 73, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e4 = new BasicDomain( "e", 64, 74, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain e5 = new BasicDomain( "e", 65, 75, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain x0 = new BasicDomain( "x", 100, 110, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain y0 = new BasicDomain( "y", 100, 110, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain y1 = new BasicDomain( "y", 120, 130, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain y2 = new BasicDomain( "y", 140, 150, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain y3 = new BasicDomain( "y", 160, 170, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain z0 = new BasicDomain( "z", 200, 210, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain z1 = new BasicDomain( "z", 300, 310, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain z2 = new BasicDomain( "z", 400, 410, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain zz0 = new BasicDomain( "Z", 500, 510, ( short ) 1, ( short ) 5, 0.1, -12 ); final Domain zz1 = new BasicDomain( "Z", 600, 610, ( short ) 1, ( short ) 5, 0.1, -12 ); p00.addProteinDomain( y0 ); p00.addProteinDomain( e0 ); p00.addProteinDomain( b0 ); p00.addProteinDomain( c0 ); p00.addProteinDomain( d0 ); p00.addProteinDomain( a0 ); p00.addProteinDomain( x0 ); p00.addProteinDomain( y1 ); p00.addProteinDomain( y2 ); p00.addProteinDomain( y3 ); p00.addProteinDomain( e1 ); p00.addProteinDomain( e2 ); p00.addProteinDomain( e3 ); p00.addProteinDomain( e4 ); p00.addProteinDomain( e5 ); p00.addProteinDomain( z0 ); p00.addProteinDomain( z1 ); p00.addProteinDomain( z2 ); p00.addProteinDomain( zz0 ); p00.addProteinDomain( zz1 ); if ( !p00.toDomainArchitectureString( "~", 3, "" ).equals( "a~b~c~d~eee~x~yyy~zzz~Z~Z" ) ) { return false; } if ( !p00.toDomainArchitectureString( "~", 4, "" ).equals( "a~b~c~d~eee~x~yyy~z~z~z~Z~Z" ) ) { return false; } if ( !p00.toDomainArchitectureString( "~", 5, "" ).equals( "a~b~c~d~eee~x~y~y~y~y~z~z~z~Z~Z" ) ) { return false; } if ( !p00.toDomainArchitectureString( "~", 6, "" ).equals( "a~b~c~d~eee~x~y~y~y~y~z~z~z~Z~Z" ) ) { return false; } if ( !p00.toDomainArchitectureString( "~", 7, "" ).equals( "a~b~c~d~e~e~e~e~e~e~x~y~y~y~y~z~z~z~Z~Z" ) ) { return false; } // A0 A10 B15 A20 B25 A30 B35 B40 C50 A60 C70 D80 final Domain A0 = new BasicDomain( "A", 0, 25, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain A10 = new BasicDomain( "A", 10, 11, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain B15 = new BasicDomain( "B", 11, 16, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain A20 = new BasicDomain( "A", 20, 100, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain B25 = new BasicDomain( "B", 25, 26, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain A30 = new BasicDomain( "A", 30, 31, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain B35 = new BasicDomain( "B", 31, 40, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain B40 = new BasicDomain( "B", 40, 600, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain C50 = new BasicDomain( "C", 50, 59, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain A60 = new BasicDomain( "A", 60, 395, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain C70 = new BasicDomain( "C", 70, 71, ( short ) 1, ( short ) 4, 0.1, -12 ); final Domain D80 = new BasicDomain( "D", 80, 81, ( short ) 1, ( short ) 4, 0.1, -12 ); final BasicProtein p = new BasicProtein( "p", "owl", 0 ); p.addProteinDomain( B15 ); p.addProteinDomain( C50 ); p.addProteinDomain( A60 ); p.addProteinDomain( A30 ); p.addProteinDomain( C70 ); p.addProteinDomain( B35 ); p.addProteinDomain( B40 ); p.addProteinDomain( A0 ); p.addProteinDomain( A10 ); p.addProteinDomain( A20 ); p.addProteinDomain( B25 ); p.addProteinDomain( D80 ); List domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "B" ); domains_ids.add( "C" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( !p.contains( domains_ids, true ) ) { return false; } domains_ids.add( "X" ); if ( p.contains( domains_ids, false ) ) { return false; } if ( p.contains( domains_ids, true ) ) { return false; } domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "C" ); domains_ids.add( "D" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( !p.contains( domains_ids, true ) ) { return false; } domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "D" ); domains_ids.add( "C" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( p.contains( domains_ids, true ) ) { return false; } domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "A" ); domains_ids.add( "B" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( !p.contains( domains_ids, true ) ) { return false; } domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "A" ); domains_ids.add( "A" ); domains_ids.add( "B" ); domains_ids.add( "B" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( !p.contains( domains_ids, true ) ) { return false; } domains_ids = new ArrayList(); domains_ids.add( "A" ); domains_ids.add( "A" ); domains_ids.add( "B" ); domains_ids.add( "A" ); domains_ids.add( "B" ); domains_ids.add( "B" ); domains_ids.add( "A" ); domains_ids.add( "B" ); domains_ids.add( "C" ); domains_ids.add( "A" ); domains_ids.add( "C" ); domains_ids.add( "D" ); if ( !p.contains( domains_ids, false ) ) { return false; } if ( p.contains( domains_ids, true ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicTable() { try { final BasicTable t0 = new BasicTable(); if ( t0.getNumberOfColumns() != 0 ) { return false; } if ( t0.getNumberOfRows() != 0 ) { return false; } t0.setValue( 3, 2, "23" ); t0.setValue( 10, 1, "error" ); t0.setValue( 10, 1, "110" ); t0.setValue( 9, 1, "19" ); t0.setValue( 1, 10, "101" ); t0.setValue( 10, 10, "1010" ); t0.setValue( 100, 10, "10100" ); t0.setValue( 0, 0, "00" ); if ( !t0.getValue( 3, 2 ).equals( "23" ) ) { return false; } if ( !t0.getValue( 10, 1 ).equals( "110" ) ) { return false; } if ( !t0.getValueAsString( 1, 10 ).equals( "101" ) ) { return false; } if ( !t0.getValueAsString( 10, 10 ).equals( "1010" ) ) { return false; } if ( !t0.getValueAsString( 100, 10 ).equals( "10100" ) ) { return false; } if ( !t0.getValueAsString( 9, 1 ).equals( "19" ) ) { return false; } if ( !t0.getValueAsString( 0, 0 ).equals( "00" ) ) { return false; } if ( t0.getNumberOfColumns() != 101 ) { return false; } if ( t0.getNumberOfRows() != 11 ) { return false; } if ( t0.getValueAsString( 49, 4 ) != null ) { return false; } final String l = ForesterUtil.getLineSeparator(); final StringBuffer source = new StringBuffer(); source.append( "" + l ); source.append( "# 1 1 1 1 1 1 1 1" + l ); source.append( " 00 01 02 03" + l ); source.append( " 10 11 12 13 " + l ); source.append( "20 21 22 23 " + l ); source.append( " 30 31 32 33" + l ); source.append( "40 41 42 43" + l ); source.append( " # 1 1 1 1 1 " + l ); source.append( "50 51 52 53 54" + l ); final BasicTable t1 = BasicTableParser.parse( source.toString(), ' ' ); if ( t1.getNumberOfColumns() != 5 ) { return false; } if ( t1.getNumberOfRows() != 6 ) { return false; } if ( !t1.getValueAsString( 0, 0 ).equals( "00" ) ) { return false; } if ( !t1.getValueAsString( 1, 0 ).equals( "01" ) ) { return false; } if ( !t1.getValueAsString( 3, 0 ).equals( "03" ) ) { return false; } if ( !t1.getValueAsString( 4, 5 ).equals( "54" ) ) { return false; } final StringBuffer source1 = new StringBuffer(); source1.append( "" + l ); source1.append( "# 1; 1; 1; 1 ;1 ;1; 1 ;1;" + l ); source1.append( " 00; 01 ;02;03" + l ); source1.append( " 10; 11; 12; 13 " + l ); source1.append( "20; 21; 22; 23 " + l ); source1.append( " 30; 31; 32; 33" + l ); source1.append( "40;41;42;43" + l ); source1.append( " # 1 1 1 1 1 " + l ); source1.append( ";;;50 ; ;52; 53;;54 " + l ); final BasicTable t2 = BasicTableParser.parse( source1.toString(), ';' ); if ( t2.getNumberOfColumns() != 5 ) { return false; } if ( t2.getNumberOfRows() != 6 ) { return false; } if ( !t2.getValueAsString( 0, 0 ).equals( "00" ) ) { return false; } if ( !t2.getValueAsString( 1, 0 ).equals( "01" ) ) { return false; } if ( !t2.getValueAsString( 3, 0 ).equals( "03" ) ) { return false; } if ( !t2.getValueAsString( 3, 3 ).equals( "33" ) ) { return false; } if ( !t2.getValueAsString( 3, 5 ).equals( "53" ) ) { return false; } if ( !t2.getValueAsString( 1, 5 ).equals( "" ) ) { return false; } final StringBuffer source2 = new StringBuffer(); source2.append( "" + l ); source2.append( "comment: 1; 1; 1; 1 ;1 ;1; 1 ;1;" + l ); source2.append( " 00; 01 ;02;03" + l ); source2.append( " 10; 11; 12; 13 " + l ); source2.append( "20; 21; 22; 23 " + l ); source2.append( " " + l ); source2.append( " 30; 31; 32; 33" + l ); source2.append( "40;41;42;43" + l ); source2.append( " comment: 1 1 1 1 1 " + l ); source2.append( ";;;50 ; 52; 53;;54 " + l ); final List> tl = BasicTableParser.parse( source2.toString(), ';', false, false, "comment:", false ); if ( tl.size() != 2 ) { return false; } final BasicTable t3 = tl.get( 0 ); final BasicTable t4 = tl.get( 1 ); if ( t3.getNumberOfColumns() != 4 ) { return false; } if ( t3.getNumberOfRows() != 3 ) { return false; } if ( t4.getNumberOfColumns() != 4 ) { return false; } if ( t4.getNumberOfRows() != 3 ) { return false; } if ( !t3.getValueAsString( 0, 0 ).equals( "00" ) ) { return false; } if ( !t4.getValueAsString( 0, 0 ).equals( "30" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicTolXMLparsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final TolParser parser = new TolParser(); final Phylogeny[] phylogenies_0 = factory.create( Test.PATH_TO_TEST_DATA + "tol_2484.tol", parser ); if ( parser.getErrorCount() > 0 ) { System.out.println( parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 1 ) { return false; } final Phylogeny t1 = phylogenies_0[ 0 ]; if ( t1.getNumberOfExternalNodes() != 5 ) { return false; } if ( !t1.isRooted() ) { return false; } if ( !t1.getRoot().getNodeData().getTaxonomy().getScientificName().equals( "Mesozoa" ) ) { return false; } if ( !t1.getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "2484" ) ) { return false; } if ( !t1.getRoot().getChildNode( 0 ).getNodeData().getTaxonomy().getScientificName() .equals( "Rhombozoa" ) ) { return false; } if ( t1.getRoot().getChildNode( 0 ).getNumberOfDescendants() != 3 ) { return false; } final Phylogeny[] phylogenies_1 = factory.create( Test.PATH_TO_TEST_DATA + "tol_2.tol", parser ); if ( parser.getErrorCount() > 0 ) { System.out.println( parser.getErrorMessages().toString() ); return false; } if ( phylogenies_1.length != 1 ) { return false; } final Phylogeny t2 = phylogenies_1[ 0 ]; if ( t2.getNumberOfExternalNodes() != 664 ) { return false; } if ( !t2.isRooted() ) { return false; } if ( !t2.getRoot().getNodeData().getTaxonomy().getScientificName().equals( "Eubacteria" ) ) { return false; } if ( !t2.getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "2" ) ) { return false; } if ( t2.getRoot().getNumberOfDescendants() != 24 ) { return false; } if ( t2.getRoot().getNumberOfDescendants() != 24 ) { return false; } if ( !t2.getRoot().getChildNode( 0 ).getNodeData().getTaxonomy().getScientificName() .equals( "Aquificae" ) ) { return false; } if ( !t2.getRoot().getChildNode( 0 ).getChildNode( 0 ).getNodeData().getTaxonomy().getScientificName() .equals( "Aquifex" ) ) { return false; } final Phylogeny[] phylogenies_2 = factory.create( Test.PATH_TO_TEST_DATA + "tol_5.tol", parser ); if ( parser.getErrorCount() > 0 ) { System.out.println( parser.getErrorMessages().toString() ); return false; } if ( phylogenies_2.length != 1 ) { return false; } final Phylogeny t3 = phylogenies_2[ 0 ]; if ( t3.getNumberOfExternalNodes() != 184 ) { return false; } if ( !t3.getRoot().getNodeData().getTaxonomy().getScientificName().equals( "Viruses" ) ) { return false; } if ( !t3.getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "5" ) ) { return false; } if ( t3.getRoot().getNumberOfDescendants() != 6 ) { return false; } final Phylogeny[] phylogenies_3 = factory.create( Test.PATH_TO_TEST_DATA + "tol_4567.tol", parser ); if ( parser.getErrorCount() > 0 ) { System.out.println( parser.getErrorMessages().toString() ); return false; } if ( phylogenies_3.length != 1 ) { return false; } final Phylogeny t4 = phylogenies_3[ 0 ]; if ( t4.getNumberOfExternalNodes() != 1 ) { return false; } if ( !t4.getRoot().getNodeData().getTaxonomy().getScientificName().equals( "Marpissa decorata" ) ) { return false; } if ( !t4.getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "4567" ) ) { return false; } if ( t4.getRoot().getNumberOfDescendants() != 0 ) { return false; } final Phylogeny[] phylogenies_4 = factory.create( Test.PATH_TO_TEST_DATA + "tol_16299.tol", parser ); if ( parser.getErrorCount() > 0 ) { System.out.println( parser.getErrorMessages().toString() ); return false; } if ( phylogenies_4.length != 1 ) { return false; } final Phylogeny t5 = phylogenies_4[ 0 ]; if ( t5.getNumberOfExternalNodes() != 13 ) { return false; } if ( !t5.getRoot().getNodeData().getTaxonomy().getScientificName().equals( "Hominidae" ) ) { return false; } if ( !t5.getRoot().getNodeData().getTaxonomy().getIdentifier().getValue().equals( "16299" ) ) { return false; } if ( t5.getRoot().getNumberOfDescendants() != 2 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testBasicTreeMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t2 = factory.create( "((A:1,B:2)AB:1,(C:3,D:5)CD:3)ABCD:0.5", new NHXParser() )[ 0 ]; if ( t2.getNumberOfExternalNodes() != 4 ) { return false; } if ( t2.calculateHeight( false ) != 8.5 ) { return false; } if ( !t2.isCompletelyBinary() ) { return false; } if ( t2.isEmpty() ) { return false; } final Phylogeny t3 = factory.create( "((A:1,B:2,C:10)ABC:1,(D:3,E:5)DE:3)", new NHXParser() )[ 0 ]; if ( t3.getNumberOfExternalNodes() != 5 ) { return false; } if ( t3.calculateHeight( true ) != 11 ) { return false; } if ( t3.isCompletelyBinary() ) { return false; } final PhylogenyNode n = t3.getNode( "ABC" ); final Phylogeny t4 = factory.create( "((A:1,B:2,C:10)ABC:1,(D:3,E:5)DE:3,(F,G,H,I))", new NHXParser() )[ 0 ]; if ( t4.getNumberOfExternalNodes() != 9 ) { return false; } if ( t4.calculateHeight( false ) != 11 ) { return false; } if ( t4.isCompletelyBinary() ) { return false; } final StringBuffer sb5 = new StringBuffer( "(((A11:2)A1:2,(A21:1,A22:2,A23)A2:11,A3:2)A:2,B:10,C:3,D:8)" ); final Phylogeny t5 = factory.create( sb5.toString(), new NHXParser() )[ 0 ]; if ( t5.getNumberOfExternalNodes() != 8 ) { return false; } if ( t5.calculateHeight( false ) != 15 ) { return false; } final StringBuffer sb6 = new StringBuffer( "(X,Y,Z,(((A111)A11:2)A1:2,(X,Y,Z,A21:1,A22:2,A23)A2:11,A3:2)A:2,B:10,C:3,D:8)" ); final Phylogeny t6 = factory.create( sb6.toString(), new NHXParser() )[ 0 ]; if ( t6.calculateHeight( true ) != 15 ) { return false; } final StringBuffer sb7 = new StringBuffer( "(((A11:2)A1:2,(A21:1,A22:2,A23)A2:11,A3:2)A:2,B:10,C:15,D:8)" ); final Phylogeny t7 = factory.create( sb7.toString(), new NHXParser() )[ 0 ]; if ( t7.calculateHeight( true ) != 15 ) { return false; } final StringBuffer sb8 = new StringBuffer( "(((A11:11)A1:2,(A21:2,A22:2,A23,A24,AA:)A2:11,A3:2)A:2,B:15,C:15,D:15)" ); final Phylogeny t8 = factory.create( sb8.toString(), new NHXParser() )[ 0 ]; if ( t8.getNumberOfExternalNodes() != 10 ) { return false; } if ( t8.calculateHeight( true ) != 15 ) { return false; } final char[] a9 = new char[] { 'a' }; final Phylogeny t9 = factory.create( a9, new NHXParser() )[ 0 ]; if ( t9.calculateHeight( true ) != 0 ) { return false; } final char[] a10 = new char[] { 'a', ':', '6' }; final Phylogeny t10 = factory.create( a10, new NHXParser() )[ 0 ]; if ( t10.calculateHeight( true ) != 6 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testConfidenceAssessor() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((((A,B)ab,C)abc,D)abcd,E)abcde", new NHXParser() )[ 0 ]; final Phylogeny[] ev0 = factory.create( "((((A,B),C),D),E);((((A,B),C),D),E);((((A,B),C),D),E);((((A,B),C),D),E);", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev0, t0, false, 1, 0, 2 ); if ( !isEqual( t0.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue(), 3 ) ) { return false; } if ( !isEqual( t0.getNode( "abc" ).getBranchData().getConfidence( 0 ).getValue(), 3 ) ) { return false; } final Phylogeny t1 = factory.create( "((((A,B)ab[&&NHX:B=50],C)abc,D)abcd,E)abcde", new NHXParser() )[ 0 ]; final Phylogeny[] ev1 = factory.create( "((((A,B),C),D),E);((A,B),((E,D),C));(((A,B),C),(E,D));(A,(((E,D),C),B));(B,(A,((E,D),C)));(C,((E,D),(A,B)));(D,(E,((A,B),C)));", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev1, t1, false, 1 ); if ( !isEqual( t1.getNode( "ab" ).getBranchData().getConfidence( 1 ).getValue(), 7 ) ) { return false; } if ( !isEqual( t1.getNode( "abc" ).getBranchData().getConfidence( 0 ).getValue(), 7 ) ) { return false; } final Phylogeny t_b = factory.create( "((((A,C)ac,D)acd,E)acde,B)abcde", new NHXParser() )[ 0 ]; final Phylogeny[] ev_b = factory.create( "((A,C),X);((A,X),C);(A,C);((((A,B),C),D),E);((A,B),((E,D),C));(((A,B),C),(E,D));(A,(((E,D),C),B));(B,(A,((E,D),C)));(C,((E,D),(A,B)));(D,(E,((A,B),C)));((((A,C)ac,D)acd,E)acde,B)abcd", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev_b, t_b, false, 1 ); if ( !isEqual( t_b.getNode( "ac" ).getBranchData().getConfidence( 0 ).getValue(), 4 ) ) { return false; } if ( !isEqual( t_b.getNode( "acd" ).getBranchData().getConfidence( 0 ).getValue(), 1 ) ) { return false; } // final Phylogeny t1x = factory.create( "((((A,B)ab,C)abc,D)abcd,E)abcde", new NHXParser() )[ 0 ]; final Phylogeny[] ev1x = factory.create( "((((A,B),C),D),E);((A,B),((E,D),C));(((A,B),C),(E,D));(A,(((E,D),C),B));(B,(A,((E,D),C)));(C,((E,D),(A,B)));(D,(E,((A,B),C)));", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev1x, t1x, true, 1 ); if ( !isEqual( t1x.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue(), 7 ) ) { return false; } if ( !isEqual( t1x.getNode( "abc" ).getBranchData().getConfidence( 0 ).getValue(), 7 ) ) { return false; } final Phylogeny t_bx = factory.create( "((((A,C)ac,D)acd,E)acde,B)abcde", new NHXParser() )[ 0 ]; final Phylogeny[] ev_bx = factory.create( "((((A,B),C),D),E);((A,B),((E,D),C));(((A,B),C),(E,D));(A,(((E,D),C),B));(B,(A,((E,D),C)));(C,((E,D),(A,B)));(D,(E,((A,B),C)));((((A,C)ac,D)acd,E)acde,B)abcd", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev_bx, t_bx, true, 1 ); if ( !isEqual( t_bx.getNode( "ac" ).getBranchData().getConfidence( 0 ).getValue(), 1 ) ) { return false; } if ( !isEqual( t_bx.getNode( "acd" ).getBranchData().getConfidence( 0 ).getValue(), 1 ) ) { return false; } final Phylogeny[] t2 = factory.create( "((((a,b),c),d),e);(((a,b),c),(d,e));(((((a,b),c),d),e),f);((((a,b),c),(d,e)),f);(((a,b),c),d,e);((a,b,c),d,e);", new NHXParser() ); final Phylogeny[] ev2 = factory.create( "((((a,b),c),d),e);((((a,b),c),d),e);((((a,b),e),d),c);((((a,b),e),d),c);(((a,b),(c,d)),e);((a,b),x);((a,b),(x,y));(a,b);(a,e);(a,b,c);", new NHXParser() ); for( final Phylogeny target : t2 ) { ConfidenceAssessor.evaluate( "bootstrap", ev2, target, false, 1 ); } final Phylogeny t4 = factory.create( "((((((A,B)ab,C)abc,D)abcd,E)abcde,F)abcdef,G)abcdefg", new NHXParser() )[ 0 ]; final Phylogeny[] ev4 = factory.create( "(((A,B),C),(X,Y));((F,G),((A,B,C),(D,E)))", new NHXParser() ); ConfidenceAssessor.evaluate( "bootstrap", ev4, t4, false, 1 ); if ( !isEqual( t4.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue(), 1 ) ) { return false; } if ( !isEqual( t4.getNode( "abc" ).getBranchData().getConfidence( 0 ).getValue(), 2 ) ) { return false; } if ( !isEqual( t4.getNode( "abcde" ).getBranchData().getConfidence( 0 ).getValue(), 1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testCopyOfNodeData() { try { final PhylogenyNode n1 = PhylogenyNode .createInstanceFromNhxString( "n5:0.1[&&NHX:S=Ecoli:E=1.1.1.1:D=Y:Co=Y:B=56:T=1:O=22:SO=33:SN=44:W=2:C=10.20.30:XN=S=tag1=value1=unit1]" ); final PhylogenyNode n2 = n1.copyNodeData(); if ( !n1.toNewHampshireX().equals( n2.toNewHampshireX() ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testCreateBalancedPhylogeny() { try { final Phylogeny p0 = DevelopmentTools.createBalancedPhylogeny( 6, 5 ); if ( p0.getRoot().getNumberOfDescendants() != 5 ) { return false; } if ( p0.getNumberOfExternalNodes() != 15625 ) { return false; } final Phylogeny p1 = DevelopmentTools.createBalancedPhylogeny( 2, 10 ); if ( p1.getRoot().getNumberOfDescendants() != 10 ) { return false; } if ( p1.getNumberOfExternalNodes() != 100 ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testCreateUriForSeqWeb() { try { final PhylogenyNode n = new PhylogenyNode(); n.setName( "tr|B3RJ64" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.UNIPROT_KB + "B3RJ64" ) ) { return false; } n.setName( "B0LM41_HUMAN" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ) .equals( ForesterUtil.UNIPROT_KB + "B0LM41_HUMAN" ) ) { return false; } n.setName( "NP_001025424" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ) .equals( ForesterUtil.NCBI_PROTEIN + "NP_001025424" ) ) { return false; } n.setName( "_NM_001030253-" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ) .equals( ForesterUtil.NCBI_NUCCORE + "NM_001030253" ) ) { return false; } n.setName( "XM_002122186" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ) .equals( ForesterUtil.NCBI_NUCCORE + "XM_002122186" ) ) { return false; } n.setName( "dgh_AAA34956_gdg" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.NCBI_PROTEIN + "AAA34956" ) ) { return false; } n.setName( "AAA34956" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.NCBI_PROTEIN + "AAA34956" ) ) { return false; } n.setName( "GI:394892" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.NCBI_GI + "394892" ) ) { System.out.println( TreePanelUtil.createUriForSeqWeb( n, null, null ) ); return false; } n.setName( "gi_394892" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.NCBI_GI + "394892" ) ) { System.out.println( TreePanelUtil.createUriForSeqWeb( n, null, null ) ); return false; } n.setName( "gi6335_gi_394892_56635_Gi_43" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.NCBI_GI + "394892" ) ) { System.out.println( TreePanelUtil.createUriForSeqWeb( n, null, null ) ); return false; } n.setName( "P12345" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.UNIPROT_KB + "P12345" ) ) { System.out.println( TreePanelUtil.createUriForSeqWeb( n, null, null ) ); return false; } n.setName( "gi_fdgjmn-3jk5-243 mnefmn fg023-0 P12345 4395jtmnsrg02345m1ggi92450jrg890j4t0j240" ); if ( !TreePanelUtil.createUriForSeqWeb( n, null, null ).equals( ForesterUtil.UNIPROT_KB + "P12345" ) ) { System.out.println( TreePanelUtil.createUriForSeqWeb( n, null, null ) ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testDataObjects() { try { final Confidence s0 = new Confidence(); final Confidence s1 = new Confidence(); if ( !s0.isEqual( s1 ) ) { return false; } final Confidence s2 = new Confidence( 0.23, "bootstrap" ); final Confidence s3 = new Confidence( 0.23, "bootstrap" ); if ( s2.isEqual( s1 ) ) { return false; } if ( !s2.isEqual( s3 ) ) { return false; } final Confidence s4 = ( Confidence ) s3.copy(); if ( !s4.isEqual( s3 ) ) { return false; } s3.asSimpleText(); s3.asText(); // Taxonomy // ---------- final Taxonomy t1 = new Taxonomy(); final Taxonomy t2 = new Taxonomy(); final Taxonomy t3 = new Taxonomy(); final Taxonomy t4 = new Taxonomy(); final Taxonomy t5 = new Taxonomy(); t1.setIdentifier( new Identifier( "ecoli" ) ); t1.setTaxonomyCode( "ECOLI" ); t1.setScientificName( "E. coli" ); t1.setCommonName( "coli" ); final Taxonomy t0 = ( Taxonomy ) t1.copy(); if ( !t1.isEqual( t0 ) ) { return false; } t2.setIdentifier( new Identifier( "ecoli" ) ); t2.setTaxonomyCode( "OTHER" ); t2.setScientificName( "what" ); t2.setCommonName( "something" ); if ( !t1.isEqual( t2 ) ) { return false; } t2.setIdentifier( new Identifier( "nemve" ) ); if ( t1.isEqual( t2 ) ) { return false; } t1.setIdentifier( null ); t3.setTaxonomyCode( "ECOLI" ); t3.setScientificName( "what" ); t3.setCommonName( "something" ); if ( !t1.isEqual( t3 ) ) { return false; } t1.setIdentifier( null ); t1.setTaxonomyCode( "" ); t4.setScientificName( "E. ColI" ); t4.setCommonName( "something" ); if ( !t1.isEqual( t4 ) ) { return false; } t4.setScientificName( "B. subtilis" ); t4.setCommonName( "something" ); if ( t1.isEqual( t4 ) ) { return false; } t1.setIdentifier( null ); t1.setTaxonomyCode( "" ); t1.setScientificName( "" ); t5.setCommonName( "COLI" ); if ( !t1.isEqual( t5 ) ) { return false; } t5.setCommonName( "vibrio" ); if ( t1.isEqual( t5 ) ) { return false; } // Identifier // ---------- final Identifier id0 = new Identifier( "123", "pfam" ); final Identifier id1 = ( Identifier ) id0.copy(); if ( !id1.isEqual( id1 ) ) { return false; } if ( !id1.isEqual( id0 ) ) { return false; } if ( !id0.isEqual( id1 ) ) { return false; } id1.asSimpleText(); id1.asText(); // ProteinDomain // --------------- final ProteinDomain pd0 = new ProteinDomain( "abc", 100, 200 ); final ProteinDomain pd1 = ( ProteinDomain ) pd0.copy(); if ( !pd1.isEqual( pd1 ) ) { return false; } if ( !pd1.isEqual( pd0 ) ) { return false; } pd1.asSimpleText(); pd1.asText(); final ProteinDomain pd2 = new ProteinDomain( pd0.getName(), pd0.getFrom(), pd0.getTo(), "id" ); final ProteinDomain pd3 = ( ProteinDomain ) pd2.copy(); if ( !pd3.isEqual( pd3 ) ) { return false; } if ( !pd2.isEqual( pd3 ) ) { return false; } if ( !pd0.isEqual( pd3 ) ) { return false; } pd3.asSimpleText(); pd3.asText(); // DomainArchitecture // ------------------ final ProteinDomain d0 = new ProteinDomain( "domain0", 10, 20 ); final ProteinDomain d1 = new ProteinDomain( "domain1", 30, 40 ); final ProteinDomain d2 = new ProteinDomain( "domain2", 50, 60 ); final ProteinDomain d3 = new ProteinDomain( "domain3", 70, 80 ); final ProteinDomain d4 = new ProteinDomain( "domain4", 90, 100 ); final ArrayList domains0 = new ArrayList(); domains0.add( d2 ); domains0.add( d0 ); domains0.add( d3 ); domains0.add( d1 ); final DomainArchitecture ds0 = new DomainArchitecture( domains0, 110 ); if ( ds0.getNumberOfDomains() != 4 ) { return false; } final DomainArchitecture ds1 = ( DomainArchitecture ) ds0.copy(); if ( !ds0.isEqual( ds0 ) ) { return false; } if ( !ds0.isEqual( ds1 ) ) { return false; } if ( ds1.getNumberOfDomains() != 4 ) { return false; } final ArrayList domains1 = new ArrayList(); domains1.add( d1 ); domains1.add( d2 ); domains1.add( d4 ); domains1.add( d0 ); final DomainArchitecture ds2 = new DomainArchitecture( domains1, 200 ); if ( ds0.isEqual( ds2 ) ) { return false; } ds1.asSimpleText(); ds1.asText(); ds1.toNHX(); final DomainArchitecture ds3 = new DomainArchitecture( "120>30>40>0.9>b>50>60>0.4>c>10>20>0.1>a" ); if ( !ds3.toNHX().toString().equals( ":DS=120>10>20>0.1>a>30>40>0.9>b>50>60>0.4>c" ) ) { System.out.println( ds3.toNHX() ); return false; } if ( ds3.getNumberOfDomains() != 3 ) { return false; } // Event // ----- final Event e1 = new Event( Event.EventType.fusion ); if ( e1.isDuplication() ) { return false; } if ( !e1.isFusion() ) { return false; } if ( !e1.asText().toString().equals( "fusion" ) ) { return false; } if ( !e1.asSimpleText().toString().equals( "fusion" ) ) { return false; } final Event e11 = new Event( Event.EventType.fusion ); if ( !e11.isEqual( e1 ) ) { return false; } if ( !e11.toNHX().toString().equals( "" ) ) { return false; } final Event e2 = new Event( Event.EventType.speciation_or_duplication ); if ( e2.isDuplication() ) { return false; } if ( !e2.isSpeciationOrDuplication() ) { return false; } if ( !e2.asText().toString().equals( "speciation_or_duplication" ) ) { return false; } if ( !e2.asSimpleText().toString().equals( "?" ) ) { return false; } if ( !e2.toNHX().toString().equals( ":D=?" ) ) { return false; } if ( e11.isEqual( e2 ) ) { return false; } final Event e2c = ( Event ) e2.copy(); if ( !e2c.isEqual( e2 ) ) { return false; } Event e3 = new Event( 1, 2, 3 ); if ( e3.isDuplication() ) { return false; } if ( e3.isSpeciation() ) { return false; } if ( e3.isGeneLoss() ) { return false; } if ( !e3.asText().toString().equals( "duplications [1] speciations [2] gene-losses [3]" ) ) { return false; } final Event e3c = ( Event ) e3.copy(); final Event e3cc = ( Event ) e3c.copy(); if ( !e3c.asSimpleText().toString().equals( "D2S3L" ) ) { return false; } e3 = null; if ( !e3c.isEqual( e3cc ) ) { return false; } Event e4 = new Event( 1, 2, 3 ); if ( !e4.asText().toString().equals( "duplications [1] speciations [2] gene-losses [3]" ) ) { return false; } if ( !e4.asSimpleText().toString().equals( "D2S3L" ) ) { return false; } final Event e4c = ( Event ) e4.copy(); e4 = null; final Event e4cc = ( Event ) e4c.copy(); if ( !e4cc.asText().toString().equals( "duplications [1] speciations [2] gene-losses [3]" ) ) { return false; } if ( !e4c.isEqual( e4cc ) ) { return false; } final Event e5 = new Event(); if ( !e5.isUnassigned() ) { return false; } if ( !e5.asText().toString().equals( "unassigned" ) ) { return false; } if ( !e5.asSimpleText().toString().equals( "" ) ) { return false; } final Event e6 = new Event( 1, 0, 0 ); if ( !e6.asText().toString().equals( "duplication" ) ) { return false; } if ( !e6.asSimpleText().toString().equals( "D" ) ) { return false; } final Event e7 = new Event( 0, 1, 0 ); if ( !e7.asText().toString().equals( "speciation" ) ) { return false; } if ( !e7.asSimpleText().toString().equals( "S" ) ) { return false; } final Event e8 = new Event( 0, 0, 1 ); if ( !e8.asText().toString().equals( "gene-loss" ) ) { return false; } if ( !e8.asSimpleText().toString().equals( "L" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testDeletionOfExternalNodes() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "A", new NHXParser() )[ 0 ]; final PhylogenyWriter w = new PhylogenyWriter(); if ( t0.isEmpty() ) { return false; } if ( t0.getNumberOfExternalNodes() != 1 ) { return false; } t0.deleteSubtree( t0.getNode( "A" ), false ); if ( t0.getNumberOfExternalNodes() != 0 ) { return false; } if ( !t0.isEmpty() ) { return false; } final Phylogeny t1 = factory.create( "(A,B)r", new NHXParser() )[ 0 ]; if ( t1.getNumberOfExternalNodes() != 2 ) { return false; } t1.deleteSubtree( t1.getNode( "A" ), false ); if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } if ( !t1.getNode( "B" ).getName().equals( "B" ) ) { return false; } t1.deleteSubtree( t1.getNode( "B" ), false ); if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } t1.deleteSubtree( t1.getNode( "r" ), false ); if ( !t1.isEmpty() ) { return false; } final Phylogeny t2 = factory.create( "((A,B),C)", new NHXParser() )[ 0 ]; if ( t2.getNumberOfExternalNodes() != 3 ) { return false; } t2.deleteSubtree( t2.getNode( "B" ), false ); if ( t2.getNumberOfExternalNodes() != 2 ) { return false; } t2.toNewHampshireX(); PhylogenyNode n = t2.getNode( "A" ); if ( !n.getNextExternalNode().getName().equals( "C" ) ) { return false; } t2.deleteSubtree( t2.getNode( "A" ), false ); if ( t2.getNumberOfExternalNodes() != 2 ) { return false; } t2.deleteSubtree( t2.getNode( "C" ), true ); if ( t2.getNumberOfExternalNodes() != 1 ) { return false; } final Phylogeny t3 = factory.create( "((A,B),(C,D))", new NHXParser() )[ 0 ]; if ( t3.getNumberOfExternalNodes() != 4 ) { return false; } t3.deleteSubtree( t3.getNode( "B" ), true ); if ( t3.getNumberOfExternalNodes() != 3 ) { return false; } n = t3.getNode( "A" ); if ( !n.getNextExternalNode().getName().equals( "C" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getNextExternalNode().getName().equals( "D" ) ) { return false; } t3.deleteSubtree( t3.getNode( "A" ), true ); if ( t3.getNumberOfExternalNodes() != 2 ) { return false; } n = t3.getNode( "C" ); if ( !n.getNextExternalNode().getName().equals( "D" ) ) { return false; } t3.deleteSubtree( t3.getNode( "C" ), true ); if ( t3.getNumberOfExternalNodes() != 1 ) { return false; } t3.deleteSubtree( t3.getNode( "D" ), true ); if ( t3.getNumberOfExternalNodes() != 0 ) { return false; } final Phylogeny t4 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; if ( t4.getNumberOfExternalNodes() != 6 ) { return false; } t4.deleteSubtree( t4.getNode( "B2" ), true ); if ( t4.getNumberOfExternalNodes() != 5 ) { return false; } String s = w.toNewHampshire( t4, true ).toString(); if ( !s.equals( "((A,(B11,B12)),(C,D));" ) ) { return false; } t4.deleteSubtree( t4.getNode( "B11" ), true ); if ( t4.getNumberOfExternalNodes() != 4 ) { return false; } t4.deleteSubtree( t4.getNode( "C" ), true ); if ( t4.getNumberOfExternalNodes() != 3 ) { return false; } n = t4.getNode( "A" ); n = n.getNextExternalNode(); if ( !n.getName().equals( "B12" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "D" ) ) { return false; } s = w.toNewHampshire( t4, true ).toString(); if ( !s.equals( "((A,B12),D);" ) ) { return false; } final Phylogeny t5 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t5.deleteSubtree( t5.getNode( "A" ), true ); if ( t5.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t5, true ).toString(); if ( !s.equals( "(((B11,B12),B2),(C,D));" ) ) { return false; } final Phylogeny t6 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t6.deleteSubtree( t6.getNode( "B11" ), true ); if ( t6.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t6, false ).toString(); if ( !s.equals( "((A,(B12,B2)),(C,D));" ) ) { return false; } final Phylogeny t7 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t7.deleteSubtree( t7.getNode( "B12" ), true ); if ( t7.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t7, true ).toString(); if ( !s.equals( "((A,(B11,B2)),(C,D));" ) ) { return false; } final Phylogeny t8 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t8.deleteSubtree( t8.getNode( "B2" ), true ); if ( t8.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t8, false ).toString(); if ( !s.equals( "((A,(B11,B12)),(C,D));" ) ) { return false; } final Phylogeny t9 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t9.deleteSubtree( t9.getNode( "C" ), true ); if ( t9.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t9, true ).toString(); if ( !s.equals( "((A,((B11,B12),B2)),D);" ) ) { return false; } final Phylogeny t10 = factory.create( "((A,((B11,B12),B2)),(C,D))", new NHXParser() )[ 0 ]; t10.deleteSubtree( t10.getNode( "D" ), true ); if ( t10.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t10, true ).toString(); if ( !s.equals( "((A,((B11,B12),B2)),C);" ) ) { return false; } final Phylogeny t11 = factory.create( "(A,B,C)", new NHXParser() )[ 0 ]; t11.deleteSubtree( t11.getNode( "A" ), true ); if ( t11.getNumberOfExternalNodes() != 2 ) { return false; } s = w.toNewHampshire( t11, true ).toString(); if ( !s.equals( "(B,C);" ) ) { return false; } t11.deleteSubtree( t11.getNode( "C" ), true ); if ( t11.getNumberOfExternalNodes() != 1 ) { return false; } s = w.toNewHampshire( t11, false ).toString(); if ( !s.equals( "B;" ) ) { return false; } final Phylogeny t12 = factory.create( "((A1,A2,A3),(B1,B2,B3),(C1,C2,C3))", new NHXParser() )[ 0 ]; t12.deleteSubtree( t12.getNode( "B2" ), true ); if ( t12.getNumberOfExternalNodes() != 8 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "((A1,A2,A3),(B1,B3),(C1,C2,C3));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "B3" ), true ); if ( t12.getNumberOfExternalNodes() != 7 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "((A1,A2,A3),B1,(C1,C2,C3));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "C3" ), true ); if ( t12.getNumberOfExternalNodes() != 6 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "((A1,A2,A3),B1,(C1,C2));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "A1" ), true ); if ( t12.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "((A2,A3),B1,(C1,C2));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "B1" ), true ); if ( t12.getNumberOfExternalNodes() != 4 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "((A2,A3),(C1,C2));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "A3" ), true ); if ( t12.getNumberOfExternalNodes() != 3 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "(A2,(C1,C2));" ) ) { return false; } t12.deleteSubtree( t12.getNode( "A2" ), true ); if ( t12.getNumberOfExternalNodes() != 2 ) { return false; } s = w.toNewHampshire( t12, true ).toString(); if ( !s.equals( "(C1,C2);" ) ) { return false; } final Phylogeny t13 = factory.create( "(A,B,C,(D:1.0,E:2.0):3.0)", new NHXParser() )[ 0 ]; t13.deleteSubtree( t13.getNode( "D" ), true ); if ( t13.getNumberOfExternalNodes() != 4 ) { return false; } s = w.toNewHampshire( t13, true ).toString(); if ( !s.equals( "(A,B,C,E:5.0);" ) ) { return false; } final Phylogeny t14 = factory.create( "((A,B,C,(D:0.1,E:0.4):1.0),F)", new NHXParser() )[ 0 ]; t14.deleteSubtree( t14.getNode( "E" ), true ); if ( t14.getNumberOfExternalNodes() != 5 ) { return false; } s = w.toNewHampshire( t14, true ).toString(); if ( !s.equals( "((A,B,C,D:1.1),F);" ) ) { return false; } final Phylogeny t15 = factory.create( "((A1,A2,A3,A4),(B1,B2,B3,B4),(C1,C2,C3,C4))", new NHXParser() )[ 0 ]; t15.deleteSubtree( t15.getNode( "B2" ), true ); if ( t15.getNumberOfExternalNodes() != 11 ) { return false; } t15.deleteSubtree( t15.getNode( "B1" ), true ); if ( t15.getNumberOfExternalNodes() != 10 ) { return false; } t15.deleteSubtree( t15.getNode( "B3" ), true ); if ( t15.getNumberOfExternalNodes() != 9 ) { return false; } t15.deleteSubtree( t15.getNode( "B4" ), true ); if ( t15.getNumberOfExternalNodes() != 8 ) { return false; } t15.deleteSubtree( t15.getNode( "A1" ), true ); if ( t15.getNumberOfExternalNodes() != 7 ) { return false; } t15.deleteSubtree( t15.getNode( "C4" ), true ); if ( t15.getNumberOfExternalNodes() != 6 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testDescriptiveStatistics() { try { final DescriptiveStatistics dss1 = new BasicDescriptiveStatistics(); dss1.addValue( 82 ); dss1.addValue( 78 ); dss1.addValue( 70 ); dss1.addValue( 58 ); dss1.addValue( 42 ); if ( dss1.getN() != 5 ) { return false; } if ( !Test.isEqual( dss1.getMin(), 42 ) ) { return false; } if ( !Test.isEqual( dss1.getMax(), 82 ) ) { return false; } if ( !Test.isEqual( dss1.arithmeticMean(), 66 ) ) { return false; } if ( !Test.isEqual( dss1.sampleStandardDeviation(), 16.24807680927192 ) ) { return false; } if ( !Test.isEqual( dss1.median(), 70 ) ) { return false; } if ( !Test.isEqual( dss1.midrange(), 62 ) ) { return false; } if ( !Test.isEqual( dss1.sampleVariance(), 264 ) ) { return false; } if ( !Test.isEqual( dss1.pearsonianSkewness(), -0.7385489458759964 ) ) { return false; } if ( !Test.isEqual( dss1.coefficientOfVariation(), 0.24618298195866547 ) ) { return false; } if ( !Test.isEqual( dss1.sampleStandardUnit( 66 - 16.24807680927192 ), -1.0 ) ) { return false; } if ( !Test.isEqual( dss1.getValue( 1 ), 78 ) ) { return false; } dss1.addValue( 123 ); if ( !Test.isEqual( dss1.arithmeticMean(), 75.5 ) ) { return false; } if ( !Test.isEqual( dss1.getMax(), 123 ) ) { return false; } if ( !Test.isEqual( dss1.standardErrorOfMean(), 11.200446419674531 ) ) { return false; } final DescriptiveStatistics dss2 = new BasicDescriptiveStatistics(); dss2.addValue( -1.85 ); dss2.addValue( 57.5 ); dss2.addValue( 92.78 ); dss2.addValue( 57.78 ); if ( !Test.isEqual( dss2.median(), 57.64 ) ) { return false; } if ( !Test.isEqual( dss2.sampleStandardDeviation(), 39.266984753946495 ) ) { return false; } final double[] a = dss2.getDataAsDoubleArray(); if ( !Test.isEqual( a[ 3 ], 57.78 ) ) { return false; } dss2.addValue( -100 ); if ( !Test.isEqual( dss2.sampleStandardDeviation(), 75.829111296388 ) ) { return false; } if ( !Test.isEqual( dss2.sampleVariance(), 5750.05412 ) ) { return false; } final double[] ds = new double[ 14 ]; ds[ 0 ] = 34; ds[ 1 ] = 23; ds[ 2 ] = 1; ds[ 3 ] = 32; ds[ 4 ] = 11; ds[ 5 ] = 2; ds[ 6 ] = 12; ds[ 7 ] = 33; ds[ 8 ] = 13; ds[ 9 ] = 22; ds[ 10 ] = 21; ds[ 11 ] = 35; ds[ 12 ] = 24; ds[ 13 ] = 31; final int[] bins = BasicDescriptiveStatistics.performBinning( ds, 0, 40, 4 ); if ( bins.length != 4 ) { return false; } if ( bins[ 0 ] != 2 ) { return false; } if ( bins[ 1 ] != 3 ) { return false; } if ( bins[ 2 ] != 4 ) { return false; } if ( bins[ 3 ] != 5 ) { return false; } final double[] ds1 = new double[ 9 ]; ds1[ 0 ] = 10.0; ds1[ 1 ] = 19.0; ds1[ 2 ] = 9.999; ds1[ 3 ] = 0.0; ds1[ 4 ] = 39.9; ds1[ 5 ] = 39.999; ds1[ 6 ] = 30.0; ds1[ 7 ] = 19.999; ds1[ 8 ] = 30.1; final int[] bins1 = BasicDescriptiveStatistics.performBinning( ds1, 0, 40, 4 ); if ( bins1.length != 4 ) { return false; } if ( bins1[ 0 ] != 2 ) { return false; } if ( bins1[ 1 ] != 3 ) { return false; } if ( bins1[ 2 ] != 0 ) { return false; } if ( bins1[ 3 ] != 4 ) { return false; } final int[] bins1_1 = BasicDescriptiveStatistics.performBinning( ds1, 0, 40, 3 ); if ( bins1_1.length != 3 ) { return false; } if ( bins1_1[ 0 ] != 3 ) { return false; } if ( bins1_1[ 1 ] != 2 ) { return false; } if ( bins1_1[ 2 ] != 4 ) { return false; } final int[] bins1_2 = BasicDescriptiveStatistics.performBinning( ds1, 1, 39, 3 ); if ( bins1_2.length != 3 ) { return false; } if ( bins1_2[ 0 ] != 2 ) { return false; } if ( bins1_2[ 1 ] != 2 ) { return false; } if ( bins1_2[ 2 ] != 2 ) { return false; } final DescriptiveStatistics dss3 = new BasicDescriptiveStatistics(); dss3.addValue( 1 ); dss3.addValue( 1 ); dss3.addValue( 1 ); dss3.addValue( 2 ); dss3.addValue( 3 ); dss3.addValue( 4 ); dss3.addValue( 5 ); dss3.addValue( 5 ); dss3.addValue( 5 ); dss3.addValue( 6 ); dss3.addValue( 7 ); dss3.addValue( 8 ); dss3.addValue( 9 ); dss3.addValue( 10 ); dss3.addValue( 10 ); dss3.addValue( 10 ); final AsciiHistogram histo = new AsciiHistogram( dss3 ); histo.toStringBuffer( 10, '=', 40, 5 ); histo.toStringBuffer( 3, 8, 10, '=', 40, 5, null ); } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testDir( final String file ) { try { final File f = new File( file ); if ( !f.exists() ) { return false; } if ( !f.isDirectory() ) { return false; } if ( !f.canRead() ) { return false; } } catch ( final Exception e ) { return false; } return true; } private static boolean testEbiEntryRetrieval() { try { final SequenceDatabaseEntry entry = SequenceDbWsTools.obtainEntry( "AAK41263" ); if ( !entry.getAccession().equals( "AAK41263" ) ) { System.out.println( entry.getAccession() ); return false; } if ( !entry.getTaxonomyScientificName().equals( "Sulfolobus solfataricus P2" ) ) { System.out.println( entry.getTaxonomyScientificName() ); return false; } if ( !entry.getSequenceName() .equals( "Sulfolobus solfataricus P2 Glycogen debranching enzyme, hypothetical (treX-like)" ) ) { System.out.println( entry.getSequenceName() ); return false; } if ( !entry.getGeneName().equals( "treX-like" ) ) { System.out.println( entry.getGeneName() ); return false; } if ( !entry.getTaxonomyIdentifier().equals( "273057" ) ) { System.out.println( entry.getTaxonomyIdentifier() ); return false; } if ( !entry.getAnnotations().first().getRefValue().equals( "3.2.1.33" ) ) { System.out.println( entry.getAnnotations().first().getRefValue() ); return false; } if ( !entry.getAnnotations().first().getRefSource().equals( "EC" ) ) { System.out.println( entry.getAnnotations().first().getRefSource() ); return false; } if ( entry.getCrossReferences().size() < 1 ) { return false; } final SequenceDatabaseEntry entry1 = SequenceDbWsTools.obtainEntry( "ABJ16409" ); if ( !entry1.getAccession().equals( "ABJ16409" ) ) { return false; } if ( !entry1.getTaxonomyScientificName().equals( "Felis catus" ) ) { System.out.println( entry1.getTaxonomyScientificName() ); return false; } if ( !entry1.getSequenceName().equals( "Felis catus (domestic cat) partial BCL2" ) ) { System.out.println( entry1.getSequenceName() ); return false; } if ( !entry1.getTaxonomyIdentifier().equals( "9685" ) ) { System.out.println( entry1.getTaxonomyIdentifier() ); return false; } if ( !entry1.getGeneName().equals( "BCL2" ) ) { System.out.println( entry1.getGeneName() ); return false; } if ( entry1.getCrossReferences().size() < 1 ) { return false; } final SequenceDatabaseEntry entry2 = SequenceDbWsTools.obtainEntry( "NM_184234" ); if ( !entry2.getAccession().equals( "NM_184234" ) ) { return false; } if ( !entry2.getTaxonomyScientificName().equals( "Homo sapiens" ) ) { System.out.println( entry2.getTaxonomyScientificName() ); return false; } if ( !entry2.getSequenceName() .equals( "Homo sapiens RNA binding motif protein 39 (RBM39), transcript variant 1, mRNA" ) ) { System.out.println( entry2.getSequenceName() ); return false; } if ( !entry2.getTaxonomyIdentifier().equals( "9606" ) ) { System.out.println( entry2.getTaxonomyIdentifier() ); return false; } if ( !entry2.getGeneName().equals( "RBM39" ) ) { System.out.println( entry2.getGeneName() ); return false; } if ( entry2.getCrossReferences().size() < 1 ) { return false; } if ( !entry2.getChromosome().equals( "20" ) ) { return false; } if ( !entry2.getMap().equals( "20q11.22" ) ) { return false; } final SequenceDatabaseEntry entry3 = SequenceDbWsTools.obtainEntry( "HM043801" ); if ( !entry3.getAccession().equals( "HM043801" ) ) { return false; } if ( !entry3.getTaxonomyScientificName().equals( "Bursaphelenchus xylophilus" ) ) { System.out.println( entry3.getTaxonomyScientificName() ); return false; } if ( !entry3.getSequenceName().equals( "Bursaphelenchus xylophilus RAF gene, complete cds" ) ) { System.out.println( entry3.getSequenceName() ); return false; } if ( !entry3.getTaxonomyIdentifier().equals( "6326" ) ) { System.out.println( entry3.getTaxonomyIdentifier() ); return false; } if ( !entry3.getSequenceSymbol().equals( "RAF" ) ) { System.out.println( entry3.getSequenceSymbol() ); return false; } if ( !ForesterUtil.isEmpty( entry3.getGeneName() ) ) { return false; } if ( entry3.getCrossReferences().size() < 1 ) { return false; } final SequenceDatabaseEntry entry4 = SequenceDbWsTools.obtainEntry( "AAA36557.1" ); if ( !entry4.getAccession().equals( "AAA36557" ) ) { return false; } if ( !entry4.getTaxonomyScientificName().equals( "Homo sapiens" ) ) { System.out.println( entry4.getTaxonomyScientificName() ); return false; } if ( !entry4.getSequenceName().equals( "Homo sapiens (human) ras protein" ) ) { System.out.println( entry4.getSequenceName() ); return false; } if ( !entry4.getTaxonomyIdentifier().equals( "9606" ) ) { System.out.println( entry4.getTaxonomyIdentifier() ); return false; } if ( !entry4.getGeneName().equals( "ras" ) ) { System.out.println( entry4.getGeneName() ); return false; } final SequenceDatabaseEntry entry5 = SequenceDbWsTools.obtainEntry( "AAZ45343.1" ); if ( !entry5.getAccession().equals( "AAZ45343" ) ) { return false; } if ( !entry5.getTaxonomyScientificName().equals( "Dechloromonas aromatica RCB" ) ) { System.out.println( entry5.getTaxonomyScientificName() ); return false; } if ( !entry5.getSequenceName().equals( "Dechloromonas aromatica RCB 1,4-alpha-glucan branching enzyme" ) ) { System.out.println( entry5.getSequenceName() ); return false; } if ( !entry5.getTaxonomyIdentifier().equals( "159087" ) ) { System.out.println( entry5.getTaxonomyIdentifier() ); return false; } final SequenceDatabaseEntry entry6 = SequenceDbWsTools.obtainEntry( "M30539" ); if ( !entry6.getAccession().equals( "M30539" ) ) { return false; } if ( !entry6.getGeneName().equals( "ras" ) ) { return false; } if ( !entry6.getSequenceName().equals( "Human SK2 c-Ha-ras-1 oncogene-encoded protein gene, exon 1" ) ) { return false; } if ( !entry6.getTaxonomyIdentifier().equals( "9606" ) ) { return false; } if ( !entry6.getTaxonomyScientificName().equals( "Homo sapiens" ) ) { return false; } if ( entry6.getCrossReferences().size() < 1 ) { return false; } } catch ( final IOException e ) { System.out.println(); System.out.println( "the following might be due to absence internet connection:" ); e.printStackTrace( System.out ); return true; } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testExternalNodeRelatedMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t1 = factory.create( "((A,B),(C,D))", new NHXParser() )[ 0 ]; PhylogenyNode n = t1.getNode( "A" ); n = n.getNextExternalNode(); if ( !n.getName().equals( "B" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "C" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "D" ) ) { return false; } n = t1.getNode( "B" ); while ( !n.isLastExternalNode() ) { n = n.getNextExternalNode(); } final Phylogeny t2 = factory.create( "(((A,B),C),D)", new NHXParser() )[ 0 ]; n = t2.getNode( "A" ); n = n.getNextExternalNode(); if ( !n.getName().equals( "B" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "C" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "D" ) ) { return false; } n = t2.getNode( "B" ); while ( !n.isLastExternalNode() ) { n = n.getNextExternalNode(); } final Phylogeny t3 = factory.create( "(((A,B),(C,D)),((E,F),(G,H)))", new NHXParser() )[ 0 ]; n = t3.getNode( "A" ); n = n.getNextExternalNode(); if ( !n.getName().equals( "B" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "C" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "D" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "E" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "F" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "G" ) ) { return false; } n = n.getNextExternalNode(); if ( !n.getName().equals( "H" ) ) { return false; } n = t3.getNode( "B" ); while ( !n.isLastExternalNode() ) { n = n.getNextExternalNode(); } final Phylogeny t4 = factory.create( "((A,B),(C,D))", new NHXParser() )[ 0 ]; for( final PhylogenyNodeIterator iter = t4.iteratorExternalForward(); iter.hasNext(); ) { final PhylogenyNode node = iter.next(); } final Phylogeny t5 = factory.create( "(((A,B),(C,D)),((E,F),(G,H)))", new NHXParser() )[ 0 ]; for( final PhylogenyNodeIterator iter = t5.iteratorExternalForward(); iter.hasNext(); ) { final PhylogenyNode node = iter.next(); } final Phylogeny t6 = factory.create( "((((((A))),(((B))),((C)),((((D)))),E)),((F)))", new NHXParser() )[ 0 ]; final PhylogenyNodeIterator iter = t6.iteratorExternalForward(); if ( !iter.next().getName().equals( "A" ) ) { return false; } if ( !iter.next().getName().equals( "B" ) ) { return false; } if ( !iter.next().getName().equals( "C" ) ) { return false; } if ( !iter.next().getName().equals( "D" ) ) { return false; } if ( !iter.next().getName().equals( "E" ) ) { return false; } if ( !iter.next().getName().equals( "F" ) ) { return false; } if ( iter.hasNext() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testExtractSNFromNodeName() { try { if ( !ParserUtils.extractScientificNameFromNodeName( "BCDO2_Mus_musculus" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "BCDO2 Mus musculus" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_BCDO2" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus musculus musculus BCDO2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_musculus_BCDO2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "BCDO2 Mus musculus musculus" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Bcl Mus musculus musculus" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "vcl Mus musculus musculus" ) != null ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "could_be_anything_Mus_musculus_musculus_BCDO2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "could_be_anything_Mus_musculus_musculus_Musculus" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( ParserUtils .extractScientificNameFromNodeName( "could_be_anything_Mus_musculus_musculus_musculus" ) != null ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "musculus" ) != null ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "mus_musculus" ) != null ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "mus_musculus_musculus" ) != null ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_musculus_1" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_1" ).equals( "Mus musculus" ) ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_bcl" ) != null ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_BCL" ).equals( "Mus musculus" ) ) { return false; } if ( ParserUtils.extractScientificNameFromNodeName( "Mus musculus bcl" ) != null ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus musculus BCL" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus musculus xBCL" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus musculus x1" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( " -XS12_Mus_musculus_12" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( " -1234_Mus_musculus_12 affrre e" ) .equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( " -1234_Mus_musculus_12_affrre_e" ) .equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_musculus_2bcl2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_musculus_2bcl2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_musculus_bcl2" ) .equals( "Mus musculus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Mus_musculus_123" ).equals( "Mus musculus" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Pilostyles mexicana Mexico Breedlove 27233" ) .equals( "Pilostyles mexicana" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia_coli_strain_K12/DH10B" ) .equals( "Escherichia coli strain K12/DH10B" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia_coli_str_K12/DH10B" ) .equals( "Escherichia coli str. K12/DH10B" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli str. K12/DH10B" ) .equals( "Escherichia coli str. K12/DH10B" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis_lyrata_subsp_lyrata" ) .equals( "Arabidopsis lyrata subsp. lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis lyrata subsp. lyrata" ) .equals( "Arabidopsis lyrata subsp. lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis lyrata subsp. lyrata 395" ) .equals( "Arabidopsis lyrata subsp. lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis lyrata subsp. lyrata bcl2" ) .equals( "Arabidopsis lyrata subsp. lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis lyrata subsp lyrata bcl2" ) .equals( "Arabidopsis lyrata subsp. lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Arabidopsis lyrata subspecies lyrata bcl2" ) .equals( "Arabidopsis lyrata subspecies lyrata" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Verbascum sinuatum var. adenosepalum bcl2" ) .equals( "Verbascum sinuatum var. adenosepalum" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (strain K12)" ) .equals( "Escherichia coli (strain K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (strain K12) bcl2" ) .equals( "Escherichia coli (strain K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (str. K12)" ) .equals( "Escherichia coli (str. K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (str K12)" ) .equals( "Escherichia coli (str. K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (str. K12) bcl2" ) .equals( "Escherichia coli (str. K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli (var K12) bcl2" ) .equals( "Escherichia coli (var. K12)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli str. K-12 substr. MG1655star" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli str K-12 substr MG1655star" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils .extractScientificNameFromNodeName( "could be anything Escherichia coli str K-12 substr MG1655star" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia coli str K-12 substr MG1655star gene1" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils .extractScientificNameFromNodeName( "could be anything Escherichia coli str K-12 substr MG1655star GENE1" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia_coli_str_K-12_substr_MG1655star" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Escherichia_coli_str_K-12_substr_MG1655star" ) .equals( "Escherichia coli str. K-12 substr. MG1655star" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Macrocera sp." ).equals( "Macrocera sp." ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Macrocera sp. 123" ).equals( "Macrocera sp." ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Macrocera sp. K12" ).equals( "Macrocera sp." ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "something Macrocera sp. K12" ) .equals( "Macrocera sp." ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Macrocera sp" ).equals( "Macrocera sp." ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Sesamum rigidum ssp merenskyanum 07 48" ) .equals( "Sesamum rigidum subsp. merenskyanum" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Sesamum rigidum ssp. merenskyanum" ) .equals( "Sesamum rigidum subsp. merenskyanum" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Sesamum rigidum (ssp. merenskyanum)" ) .equals( "Sesamum rigidum (subsp. merenskyanum)" ) ) { return false; } if ( !ParserUtils.extractScientificNameFromNodeName( "Sesamum rigidum (ssp merenskyanum)" ) .equals( "Sesamum rigidum (subsp. merenskyanum)" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testExtractTaxonomyDataFromNodeName() { try { PhylogenyNode n = new PhylogenyNode( "tr|B1AM49|B1AM49_HUMAN" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "tr|B1AM49|B1AM49_HUMAN~1-2" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "tr|B1AM49|HNRPR_HUMAN" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "tr|B1AM49|HNRPR_HUMAN|" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "tr|B1AM49|HNRPR_HUMAN~12" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "HNRPR_HUMAN" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } n = new PhylogenyNode( "HNRPR_HUMAN_X" ); if ( !ParserUtils.extractTaxonomyDataFromNodeName( n, TAXONOMY_EXTRACTION.AGGRESSIVE ).equals( "HUMAN" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testExtractTaxonomyCodeFromNodeName() { try { if ( ParserUtils.extractTaxonomyCodeFromNodeName( "MOUSE", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( " ARATH ", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "ARATH" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( " ARATH ", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "ARATH" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "RAT", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "RAT" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "RAT", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "RAT" ) ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "RAT1", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( " _SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "qwerty SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "qwerty_SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "ABCD_SOYBN ", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "SOYBN", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( ",SOYBN,", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "xxx,SOYBN,xxx", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "xxxSOYBNxxx", TAXONOMY_EXTRACTION.AGGRESSIVE ) != null ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "-SOYBN~", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "SOYBN" ) ) { return false; } if ( !ParserUtils .extractTaxonomyCodeFromNodeName( "NNN8_ECOLI/1-2:0.01", TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ) .equals( "ECOLI" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "blagg_9YX45-blag", TAXONOMY_EXTRACTION.AGGRESSIVE ) .equals( "9YX45" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSE function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "MOUSE" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSE+function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "MOUSE" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSE|function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "MOUSE" ) ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSEfunction = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSEFunction = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RAT function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "RAT" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RAT function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "RAT" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RAT|function = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "RAT" ) ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RATfunction = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RATFunction = 23445", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_RAT/1-3", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "RAT" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_PIG/1-3", TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ) .equals( "PIG" ) ) { return false; } if ( !ParserUtils .extractTaxonomyCodeFromNodeName( "BCL2_MOUSE/1-3", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) .equals( "MOUSE" ) ) { return false; } if ( !ParserUtils.extractTaxonomyCodeFromNodeName( "BCL2_MOUSE/1-3", TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ) .equals( "MOUSE" ) ) { return false; } if ( ParserUtils.extractTaxonomyCodeFromNodeName( "_MOUSE ", TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ) != null ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testExtractUniProtKbProteinSeqIdentifier() { try { PhylogenyNode n = new PhylogenyNode(); n.setName( "tr|B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr.B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr=B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr-B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr/B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr\\B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "tr_B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( " tr|B3RJ64 " ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "-tr|B3RJ64-" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "-tr=B3RJ64-" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "_tr=B3RJ64_" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( " tr_tr|B3RJ64_sp|123 " ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "sp|B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "sp|B3RJ64C" ); if ( SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ) != null ) { return false; } n.setName( "sp B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n.setName( "sp|B3RJ6X" ); if ( SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ) != null ) { return false; } n.setName( "sp|B3RJ6" ); if ( SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ) != null ) { return false; } n.setName( "K1PYK7_CRAGI" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_CRAGI" ) ) { return false; } n.setName( "K1PYK7_PEA" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_PEA" ) ) { return false; } n.setName( "K1PYK7_RAT" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_RAT" ) ) { return false; } n.setName( "K1PYK7_PIG" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_PIG" ) ) { return false; } n.setName( "~K1PYK7_PIG~" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_PIG" ) ) { return false; } n.setName( "123456_ECOLI-K1PYK7_CRAGI-sp" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_CRAGI" ) ) { return false; } n.setName( "K1PYKX_CRAGI" ); if ( SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ) != null ) { return false; } n.setName( "XXXXX_CRAGI" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "XXXXX_CRAGI" ) ) { return false; } n.setName( "tr|H3IB65|H3IB65_STRPU~2-2" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "H3IB65" ) ) { return false; } n.setName( "jgi|Lacbi2|181470|Lacbi1.estExt_GeneWisePlus_human.C_10729~2-3" ); if ( SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ) != null ) { return false; } n.setName( "sp|Q86U06|RBM23_HUMAN~2-2" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "Q86U06" ) ) { return false; } n = new PhylogenyNode(); org.forester.phylogeny.data.Sequence seq = new org.forester.phylogeny.data.Sequence(); seq.setSymbol( "K1PYK7_CRAGI" ); n.getNodeData().addSequence( seq ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_CRAGI" ) ) { return false; } seq.setSymbol( "tr|B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n = new PhylogenyNode(); seq = new org.forester.phylogeny.data.Sequence(); seq.setName( "K1PYK7_CRAGI" ); n.getNodeData().addSequence( seq ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK7_CRAGI" ) ) { return false; } seq.setName( "tr|B3RJ64" ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } n = new PhylogenyNode(); seq = new org.forester.phylogeny.data.Sequence(); seq.setAccession( new Accession( "K1PYK8_CRAGI", "?" ) ); n.getNodeData().addSequence( seq ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "K1PYK8_CRAGI" ) ) { return false; } n = new PhylogenyNode(); seq = new org.forester.phylogeny.data.Sequence(); seq.setAccession( new Accession( "tr|B3RJ64", "?" ) ); n.getNodeData().addSequence( seq ); if ( !SequenceAccessionTools.obtainUniProtAccessorFromDataFields( n ).equals( "B3RJ64" ) ) { return false; } // n = new PhylogenyNode(); n.setName( "ACP19736" ); if ( !SequenceAccessionTools.obtainGenbankAccessorFromDataFields( n ).equals( "ACP19736" ) ) { return false; } n = new PhylogenyNode(); n.setName( "|ACP19736|" ); if ( !SequenceAccessionTools.obtainGenbankAccessorFromDataFields( n ).equals( "ACP19736" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testFastaParser() { try { final FileInputStream fis1 = new FileInputStream( PATH_TO_TEST_DATA + "fasta_0.fasta" ); if ( !FastaParser.isLikelyFasta( fis1 ) ) { fis1.close(); return false; } else { fis1.close(); } final FileInputStream fis2 = new FileInputStream( PATH_TO_TEST_DATA + "msa_3.txt" ); if ( FastaParser.isLikelyFasta( fis2 ) ) { fis2.close(); return false; } else { fis2.close(); } final Msa msa_0 = FastaParser.parseMsa( new FileInputStream( PATH_TO_TEST_DATA + "fasta_0.fasta" ) ); if ( !msa_0.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "ACGTGKXFMFDMXEXXXSFMFMF" ) ) { return false; } if ( !msa_0.getIdentifier( 0 ).equals( "one dumb" ) ) { return false; } if ( !msa_0.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "DKXASDFXSFXFKFKSXDFKSLX" ) ) { return false; } if ( !msa_0.getSequenceAsString( 2 ).toString().equalsIgnoreCase( "SXDFKSXLFSFPWEXPROWXERR" ) ) { return false; } if ( !msa_0.getSequenceAsString( 3 ).toString().equalsIgnoreCase( "AAAAAAAAAAAAAAAAAAAAAAA" ) ) { return false; } if ( !msa_0.getSequenceAsString( 4 ).toString().equalsIgnoreCase( "DDDDDDDDDDDDDDDDDDDDAXF" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testGenbankAccessorParsing() { //The format for GenBank Accession numbers are: //Nucleotide: 1 letter + 5 numerals OR 2 letters + 6 numerals //Protein: 3 letters + 5 numerals //http://www.ncbi.nlm.nih.gov/Sequin/acc.html if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "AY423861" ).equals( "AY423861" ) ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( ".AY423861.2" ).equals( "AY423861.2" ) ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "345_.AY423861.24_345" ) .equals( "AY423861.24" ) ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "AAY423861" ) != null ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "AY4238612" ) != null ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "AAY4238612" ) != null ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "Y423861" ) != null ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "S12345" ).equals( "S12345" ) ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "|S12345|" ).equals( "S12345" ) ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "|S123456" ) != null ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "ABC123456" ) != null ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "ABC12345" ).equals( "ABC12345" ) ) { return false; } if ( !SequenceAccessionTools.parseGenbankAccessorFromString( "&ABC12345&" ).equals( "ABC12345" ) ) { return false; } if ( SequenceAccessionTools.parseGenbankAccessorFromString( "ABCD12345" ) != null ) { return false; } return true; } private static boolean testGeneralMsaParser() { try { final String msa_str_0 = "seq1 abcd\n\nseq2 efgh\n"; final Msa msa_0 = GeneralMsaParser.parseMsa( new ByteArrayInputStream( msa_str_0.getBytes() ) ); final String msa_str_1 = "seq1 abc\nseq2 ghi\nseq1 def\nseq2 jkm\n"; final Msa msa_1 = GeneralMsaParser.parseMsa( new ByteArrayInputStream( msa_str_1.getBytes() ) ); final String msa_str_2 = "seq1 abc\nseq2 ghi\n\ndef\njkm\n"; final Msa msa_2 = GeneralMsaParser.parseMsa( new ByteArrayInputStream( msa_str_2.getBytes() ) ); final String msa_str_3 = "seq1 abc\n def\nseq2 ghi\n jkm\n"; final Msa msa_3 = GeneralMsaParser.parseMsa( new ByteArrayInputStream( msa_str_3.getBytes() ) ); if ( !msa_1.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdef" ) ) { return false; } if ( !msa_1.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "ghixkm" ) ) { return false; } if ( !msa_1.getIdentifier( 0 ).toString().equals( "seq1" ) ) { return false; } if ( !msa_1.getIdentifier( 1 ).toString().equals( "seq2" ) ) { return false; } if ( !msa_2.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdef" ) ) { return false; } if ( !msa_2.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "ghixkm" ) ) { return false; } if ( !msa_2.getIdentifier( 0 ).toString().equals( "seq1" ) ) { return false; } if ( !msa_2.getIdentifier( 1 ).toString().equals( "seq2" ) ) { return false; } if ( !msa_3.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdef" ) ) { return false; } if ( !msa_3.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "ghixkm" ) ) { return false; } if ( !msa_3.getIdentifier( 0 ).toString().equals( "seq1" ) ) { return false; } if ( !msa_3.getIdentifier( 1 ).toString().equals( "seq2" ) ) { return false; } final Msa msa_4 = GeneralMsaParser.parseMsa( new FileInputStream( PATH_TO_TEST_DATA + "msa_1.txt" ) ); if ( !msa_4.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdefeeeeeeeexx" ) ) { return false; } if ( !msa_4.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "efghixffffffffyy" ) ) { return false; } if ( !msa_4.getSequenceAsString( 2 ).toString().equalsIgnoreCase( "klmnxphhhhhhhhzz" ) ) { return false; } final Msa msa_5 = GeneralMsaParser.parseMsa( new FileInputStream( PATH_TO_TEST_DATA + "msa_2.txt" ) ); if ( !msa_5.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdefxx" ) ) { return false; } if ( !msa_5.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "efghixyy" ) ) { return false; } if ( !msa_5.getSequenceAsString( 2 ).toString().equalsIgnoreCase( "klmnxpzz" ) ) { return false; } final Msa msa_6 = GeneralMsaParser.parseMsa( new FileInputStream( PATH_TO_TEST_DATA + "msa_3.txt" ) ); if ( !msa_6.getSequenceAsString( 0 ).toString().equalsIgnoreCase( "abcdefeeeeeeeexx" ) ) { return false; } if ( !msa_6.getSequenceAsString( 1 ).toString().equalsIgnoreCase( "efghixffffffffyy" ) ) { return false; } if ( !msa_6.getSequenceAsString( 2 ).toString().equalsIgnoreCase( "klmnxphhhhhhhhzz" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testGeneralTable() { try { final GeneralTable t0 = new GeneralTable(); t0.setValue( 3, 2, "23" ); t0.setValue( 10, 1, "error" ); t0.setValue( 10, 1, "110" ); t0.setValue( 9, 1, "19" ); t0.setValue( 1, 10, "101" ); t0.setValue( 10, 10, "1010" ); t0.setValue( 100, 10, "10100" ); t0.setValue( 0, 0, "00" ); if ( !t0.getValue( 3, 2 ).equals( "23" ) ) { return false; } if ( !t0.getValue( 10, 1 ).equals( "110" ) ) { return false; } if ( !t0.getValueAsString( 1, 10 ).equals( "101" ) ) { return false; } if ( !t0.getValueAsString( 10, 10 ).equals( "1010" ) ) { return false; } if ( !t0.getValueAsString( 100, 10 ).equals( "10100" ) ) { return false; } if ( !t0.getValueAsString( 9, 1 ).equals( "19" ) ) { return false; } if ( !t0.getValueAsString( 0, 0 ).equals( "00" ) ) { return false; } if ( !t0.getValueAsString( 49, 4 ).equals( "" ) ) { return false; } if ( !t0.getValueAsString( 22349, 3434344 ).equals( "" ) ) { return false; } final GeneralTable t1 = new GeneralTable(); t1.setValue( "3", "2", "23" ); t1.setValue( "10", "1", "error" ); t1.setValue( "10", "1", "110" ); t1.setValue( "9", "1", "19" ); t1.setValue( "1", "10", "101" ); t1.setValue( "10", "10", "1010" ); t1.setValue( "100", "10", "10100" ); t1.setValue( "0", "0", "00" ); t1.setValue( "qwerty", "zxcvbnm", "asdef" ); if ( !t1.getValue( "3", "2" ).equals( "23" ) ) { return false; } if ( !t1.getValue( "10", "1" ).equals( "110" ) ) { return false; } if ( !t1.getValueAsString( "1", "10" ).equals( "101" ) ) { return false; } if ( !t1.getValueAsString( "10", "10" ).equals( "1010" ) ) { return false; } if ( !t1.getValueAsString( "100", "10" ).equals( "10100" ) ) { return false; } if ( !t1.getValueAsString( "9", "1" ).equals( "19" ) ) { return false; } if ( !t1.getValueAsString( "0", "0" ).equals( "00" ) ) { return false; } if ( !t1.getValueAsString( "qwerty", "zxcvbnm" ).equals( "asdef" ) ) { return false; } if ( !t1.getValueAsString( "49", "4" ).equals( "" ) ) { return false; } if ( !t1.getValueAsString( "22349", "3434344" ).equals( "" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testGetDistance() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "(((A:1,B:2,X:100)ab:3,C:4)abc:5,(D:7,(E:9,F:10)ef:8)def:6)r", new NHXParser() )[ 0 ]; if ( PhylogenyMethods.calculateDistance( p1.getNode( "C" ), p1.getNode( "C" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "def" ), p1.getNode( "def" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "ef" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "r" ), p1.getNode( "r" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "A" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "B" ) ) != 3 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "B" ), p1.getNode( "A" ) ) != 3 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "C" ) ) != 8 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "C" ), p1.getNode( "A" ) ) != 8 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "D" ) ) != 22 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "E" ) ) != 32 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "E" ), p1.getNode( "A" ) ) != 32 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "F" ) ) != 33 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "F" ), p1.getNode( "A" ) ) != 33 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "ab" ) ) != 1 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ab" ), p1.getNode( "A" ) ) != 1 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "abc" ) ) != 4 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "abc" ), p1.getNode( "A" ) ) != 4 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "r" ) ) != 9 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "r" ), p1.getNode( "A" ) ) != 9 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "def" ) ) != 15 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "def" ), p1.getNode( "A" ) ) != 15 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "A" ), p1.getNode( "ef" ) ) != 23 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "A" ) ) != 23 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "def" ) ) != 8 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "def" ), p1.getNode( "ef" ) ) != 8 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "r" ) ) != 14 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "abc" ) ) != 19 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ef" ), p1.getNode( "ab" ) ) != 22 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "ab" ), p1.getNode( "ef" ) ) != 22 ) { return false; } if ( PhylogenyMethods.calculateDistance( p1.getNode( "def" ), p1.getNode( "abc" ) ) != 11 ) { return false; } final Phylogeny p2 = factory.create( "((A:4,B:5,C:6)abc:1,(D:7,E:8,F:9)def:2,(G:10,H:11,I:12)ghi:3)r", new NHXParser() )[ 0 ]; if ( PhylogenyMethods.calculateDistance( p2.getNode( "A" ), p2.getNode( "B" ) ) != 9 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "A" ), p2.getNode( "C" ) ) != 10 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "A" ), p2.getNode( "D" ) ) != 14 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "A" ), p2.getNode( "ghi" ) ) != 8 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "A" ), p2.getNode( "I" ) ) != 20 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "G" ), p2.getNode( "ghi" ) ) != 10 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "r" ), p2.getNode( "r" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "r" ), p2.getNode( "G" ) ) != 13 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "G" ), p2.getNode( "r" ) ) != 13 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "G" ), p2.getNode( "H" ) ) != 21 ) { return false; } if ( PhylogenyMethods.calculateDistance( p2.getNode( "G" ), p2.getNode( "I" ) ) != 22 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testGetLCA() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "((((((A,B)ab,C)abc,D)abcd,E)abcde,F)abcdef,(G,H)gh)abcdefgh", new NHXParser() )[ 0 ]; final PhylogenyNode A = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "A" ) ); if ( !A.getName().equals( "A" ) ) { return false; } final PhylogenyNode gh = PhylogenyMethods.calculateLCA( p1.getNode( "gh" ), p1.getNode( "gh" ) ); if ( !gh.getName().equals( "gh" ) ) { return false; } final PhylogenyNode ab = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "B" ) ); if ( !ab.getName().equals( "ab" ) ) { return false; } final PhylogenyNode ab2 = PhylogenyMethods.calculateLCA( p1.getNode( "B" ), p1.getNode( "A" ) ); if ( !ab2.getName().equals( "ab" ) ) { return false; } final PhylogenyNode gh2 = PhylogenyMethods.calculateLCA( p1.getNode( "H" ), p1.getNode( "G" ) ); if ( !gh2.getName().equals( "gh" ) ) { return false; } final PhylogenyNode gh3 = PhylogenyMethods.calculateLCA( p1.getNode( "G" ), p1.getNode( "H" ) ); if ( !gh3.getName().equals( "gh" ) ) { return false; } final PhylogenyNode abc = PhylogenyMethods.calculateLCA( p1.getNode( "C" ), p1.getNode( "A" ) ); if ( !abc.getName().equals( "abc" ) ) { return false; } final PhylogenyNode abc2 = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "C" ) ); if ( !abc2.getName().equals( "abc" ) ) { return false; } final PhylogenyNode abcd = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "D" ) ); if ( !abcd.getName().equals( "abcd" ) ) { return false; } final PhylogenyNode abcd2 = PhylogenyMethods.calculateLCA( p1.getNode( "D" ), p1.getNode( "A" ) ); if ( !abcd2.getName().equals( "abcd" ) ) { return false; } final PhylogenyNode abcdef = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "F" ) ); if ( !abcdef.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef2 = PhylogenyMethods.calculateLCA( p1.getNode( "F" ), p1.getNode( "A" ) ); if ( !abcdef2.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef3 = PhylogenyMethods.calculateLCA( p1.getNode( "ab" ), p1.getNode( "F" ) ); if ( !abcdef3.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef4 = PhylogenyMethods.calculateLCA( p1.getNode( "F" ), p1.getNode( "ab" ) ); if ( !abcdef4.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcde = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "E" ) ); if ( !abcde.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode abcde2 = PhylogenyMethods.calculateLCA( p1.getNode( "E" ), p1.getNode( "A" ) ); if ( !abcde2.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode r = PhylogenyMethods.calculateLCA( p1.getNode( "abcdefgh" ), p1.getNode( "abcdefgh" ) ); if ( !r.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode r2 = PhylogenyMethods.calculateLCA( p1.getNode( "A" ), p1.getNode( "H" ) ); if ( !r2.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode r3 = PhylogenyMethods.calculateLCA( p1.getNode( "H" ), p1.getNode( "A" ) ); if ( !r3.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode abcde3 = PhylogenyMethods.calculateLCA( p1.getNode( "E" ), p1.getNode( "abcde" ) ); if ( !abcde3.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode abcde4 = PhylogenyMethods.calculateLCA( p1.getNode( "abcde" ), p1.getNode( "E" ) ); if ( !abcde4.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode ab3 = PhylogenyMethods.calculateLCA( p1.getNode( "ab" ), p1.getNode( "B" ) ); if ( !ab3.getName().equals( "ab" ) ) { return false; } final PhylogenyNode ab4 = PhylogenyMethods.calculateLCA( p1.getNode( "B" ), p1.getNode( "ab" ) ); if ( !ab4.getName().equals( "ab" ) ) { return false; } final Phylogeny p2 = factory.create( "(a,b,(((c,d)cd,e)cde,f)cdef)r", new NHXParser() )[ 0 ]; final PhylogenyNode cd = PhylogenyMethods.calculateLCA( p2.getNode( "c" ), p2.getNode( "d" ) ); if ( !cd.getName().equals( "cd" ) ) { return false; } final PhylogenyNode cd2 = PhylogenyMethods.calculateLCA( p2.getNode( "d" ), p2.getNode( "c" ) ); if ( !cd2.getName().equals( "cd" ) ) { return false; } final PhylogenyNode cde = PhylogenyMethods.calculateLCA( p2.getNode( "c" ), p2.getNode( "e" ) ); if ( !cde.getName().equals( "cde" ) ) { return false; } final PhylogenyNode cde2 = PhylogenyMethods.calculateLCA( p2.getNode( "e" ), p2.getNode( "c" ) ); if ( !cde2.getName().equals( "cde" ) ) { return false; } final PhylogenyNode cdef = PhylogenyMethods.calculateLCA( p2.getNode( "c" ), p2.getNode( "f" ) ); if ( !cdef.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode cdef2 = PhylogenyMethods.calculateLCA( p2.getNode( "d" ), p2.getNode( "f" ) ); if ( !cdef2.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode cdef3 = PhylogenyMethods.calculateLCA( p2.getNode( "f" ), p2.getNode( "d" ) ); if ( !cdef3.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode rt = PhylogenyMethods.calculateLCA( p2.getNode( "c" ), p2.getNode( "a" ) ); if ( !rt.getName().equals( "r" ) ) { return false; } final Phylogeny p3 = factory.create( "((((a,(b,c)bc)abc,(d,e)de)abcde,f)abcdef,(((g,h)gh,(i,j)ij)ghij,k)ghijk,l)", new NHXParser() )[ 0 ]; final PhylogenyNode bc_3 = PhylogenyMethods.calculateLCA( p3.getNode( "b" ), p3.getNode( "c" ) ); if ( !bc_3.getName().equals( "bc" ) ) { return false; } final PhylogenyNode ac_3 = PhylogenyMethods.calculateLCA( p3.getNode( "a" ), p3.getNode( "c" ) ); if ( !ac_3.getName().equals( "abc" ) ) { return false; } final PhylogenyNode ad_3 = PhylogenyMethods.calculateLCA( p3.getNode( "a" ), p3.getNode( "d" ) ); if ( !ad_3.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode af_3 = PhylogenyMethods.calculateLCA( p3.getNode( "a" ), p3.getNode( "f" ) ); if ( !af_3.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode ag_3 = PhylogenyMethods.calculateLCA( p3.getNode( "a" ), p3.getNode( "g" ) ); if ( !ag_3.getName().equals( "" ) ) { return false; } if ( !ag_3.isRoot() ) { return false; } final PhylogenyNode al_3 = PhylogenyMethods.calculateLCA( p3.getNode( "a" ), p3.getNode( "l" ) ); if ( !al_3.getName().equals( "" ) ) { return false; } if ( !al_3.isRoot() ) { return false; } final PhylogenyNode kl_3 = PhylogenyMethods.calculateLCA( p3.getNode( "k" ), p3.getNode( "l" ) ); if ( !kl_3.getName().equals( "" ) ) { return false; } if ( !kl_3.isRoot() ) { return false; } final PhylogenyNode fl_3 = PhylogenyMethods.calculateLCA( p3.getNode( "f" ), p3.getNode( "l" ) ); if ( !fl_3.getName().equals( "" ) ) { return false; } if ( !fl_3.isRoot() ) { return false; } final PhylogenyNode gk_3 = PhylogenyMethods.calculateLCA( p3.getNode( "g" ), p3.getNode( "k" ) ); if ( !gk_3.getName().equals( "ghijk" ) ) { return false; } final Phylogeny p4 = factory.create( "(a,b,c)r", new NHXParser() )[ 0 ]; final PhylogenyNode r_4 = PhylogenyMethods.calculateLCA( p4.getNode( "b" ), p4.getNode( "c" ) ); if ( !r_4.getName().equals( "r" ) ) { return false; } final Phylogeny p5 = factory.create( "((a,b),c,d)root", new NHXParser() )[ 0 ]; final PhylogenyNode r_5 = PhylogenyMethods.calculateLCA( p5.getNode( "a" ), p5.getNode( "c" ) ); if ( !r_5.getName().equals( "root" ) ) { return false; } final Phylogeny p6 = factory.create( "((a,b),c,d)rot", new NHXParser() )[ 0 ]; final PhylogenyNode r_6 = PhylogenyMethods.calculateLCA( p6.getNode( "c" ), p6.getNode( "a" ) ); if ( !r_6.getName().equals( "rot" ) ) { return false; } final Phylogeny p7 = factory.create( "(((a,b)x,c)x,d,e)rott", new NHXParser() )[ 0 ]; final PhylogenyNode r_7 = PhylogenyMethods.calculateLCA( p7.getNode( "a" ), p7.getNode( "e" ) ); if ( !r_7.getName().equals( "rott" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testGetLCA2() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); // final Phylogeny p_a = factory.create( "(a)", new NHXParser() )[ 0 ]; final Phylogeny p_a = NHXParser.parse( "(a)" )[ 0 ]; PhylogenyMethods.preOrderReId( p_a ); final PhylogenyNode p_a_1 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_a.getNode( "a" ), p_a.getNode( "a" ) ); if ( !p_a_1.getName().equals( "a" ) ) { return false; } final Phylogeny p_b = NHXParser.parse( "((a)b)" )[ 0 ]; PhylogenyMethods.preOrderReId( p_b ); final PhylogenyNode p_b_1 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_b.getNode( "b" ), p_b.getNode( "a" ) ); if ( !p_b_1.getName().equals( "b" ) ) { return false; } final PhylogenyNode p_b_2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_b.getNode( "a" ), p_b.getNode( "b" ) ); if ( !p_b_2.getName().equals( "b" ) ) { return false; } final Phylogeny p_c = factory.create( "(((a)b)c)", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p_c ); final PhylogenyNode p_c_1 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_c.getNode( "b" ), p_c.getNode( "a" ) ); if ( !p_c_1.getName().equals( "b" ) ) { return false; } final PhylogenyNode p_c_2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_c.getNode( "a" ), p_c.getNode( "c" ) ); if ( !p_c_2.getName().equals( "c" ) ) { System.out.println( p_c_2.getName() ); System.exit( -1 ); return false; } final PhylogenyNode p_c_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_c.getNode( "a" ), p_c.getNode( "b" ) ); if ( !p_c_3.getName().equals( "b" ) ) { return false; } final PhylogenyNode p_c_4 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p_c.getNode( "c" ), p_c.getNode( "a" ) ); if ( !p_c_4.getName().equals( "c" ) ) { return false; } final Phylogeny p1 = factory.create( "((((((A,B)ab,C)abc,D)abcd,E)abcde,F)abcdef,(G,H)gh)abcdefgh", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p1 ); final PhylogenyNode A = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "A" ) ); if ( !A.getName().equals( "A" ) ) { return false; } final PhylogenyNode gh = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "gh" ), p1.getNode( "gh" ) ); if ( !gh.getName().equals( "gh" ) ) { return false; } final PhylogenyNode ab = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "B" ) ); if ( !ab.getName().equals( "ab" ) ) { return false; } final PhylogenyNode ab2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "B" ), p1.getNode( "A" ) ); if ( !ab2.getName().equals( "ab" ) ) { return false; } final PhylogenyNode gh2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "H" ), p1.getNode( "G" ) ); if ( !gh2.getName().equals( "gh" ) ) { return false; } final PhylogenyNode gh3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "G" ), p1.getNode( "H" ) ); if ( !gh3.getName().equals( "gh" ) ) { return false; } final PhylogenyNode abc = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "C" ), p1.getNode( "A" ) ); if ( !abc.getName().equals( "abc" ) ) { return false; } final PhylogenyNode abc2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "C" ) ); if ( !abc2.getName().equals( "abc" ) ) { return false; } final PhylogenyNode abcd = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "D" ) ); if ( !abcd.getName().equals( "abcd" ) ) { return false; } final PhylogenyNode abcd2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "D" ), p1.getNode( "A" ) ); if ( !abcd2.getName().equals( "abcd" ) ) { return false; } final PhylogenyNode abcdef = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "F" ) ); if ( !abcdef.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "F" ), p1.getNode( "A" ) ); if ( !abcdef2.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "ab" ), p1.getNode( "F" ) ); if ( !abcdef3.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcdef4 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "F" ), p1.getNode( "ab" ) ); if ( !abcdef4.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode abcde = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "E" ) ); if ( !abcde.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode abcde2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "E" ), p1.getNode( "A" ) ); if ( !abcde2.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode r = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "abcdefgh" ), p1.getNode( "abcdefgh" ) ); if ( !r.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode r2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "A" ), p1.getNode( "H" ) ); if ( !r2.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode r3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "H" ), p1.getNode( "A" ) ); if ( !r3.getName().equals( "abcdefgh" ) ) { return false; } final PhylogenyNode abcde3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "E" ), p1.getNode( "abcde" ) ); if ( !abcde3.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode abcde4 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "abcde" ), p1.getNode( "E" ) ); if ( !abcde4.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode ab3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "ab" ), p1.getNode( "B" ) ); if ( !ab3.getName().equals( "ab" ) ) { return false; } final PhylogenyNode ab4 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p1.getNode( "B" ), p1.getNode( "ab" ) ); if ( !ab4.getName().equals( "ab" ) ) { return false; } final Phylogeny p2 = factory.create( "(a,b,(((c,d)cd,e)cde,f)cdef)r", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p2 ); final PhylogenyNode cd = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "c" ), p2.getNode( "d" ) ); if ( !cd.getName().equals( "cd" ) ) { return false; } final PhylogenyNode cd2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "d" ), p2.getNode( "c" ) ); if ( !cd2.getName().equals( "cd" ) ) { return false; } final PhylogenyNode cde = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "c" ), p2.getNode( "e" ) ); if ( !cde.getName().equals( "cde" ) ) { return false; } final PhylogenyNode cde2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "e" ), p2.getNode( "c" ) ); if ( !cde2.getName().equals( "cde" ) ) { return false; } final PhylogenyNode cdef = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "c" ), p2.getNode( "f" ) ); if ( !cdef.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode cdef2 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "d" ), p2.getNode( "f" ) ); if ( !cdef2.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode cdef3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "f" ), p2.getNode( "d" ) ); if ( !cdef3.getName().equals( "cdef" ) ) { return false; } final PhylogenyNode rt = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p2.getNode( "c" ), p2.getNode( "a" ) ); if ( !rt.getName().equals( "r" ) ) { return false; } final Phylogeny p3 = factory.create( "((((a,(b,c)bc)abc,(d,e)de)abcde,f)abcdef,(((g,h)gh,(i,j)ij)ghij,k)ghijk,l)", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p3 ); final PhylogenyNode bc_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "b" ), p3.getNode( "c" ) ); if ( !bc_3.getName().equals( "bc" ) ) { return false; } final PhylogenyNode ac_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "a" ), p3.getNode( "c" ) ); if ( !ac_3.getName().equals( "abc" ) ) { return false; } final PhylogenyNode ad_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "a" ), p3.getNode( "d" ) ); if ( !ad_3.getName().equals( "abcde" ) ) { return false; } final PhylogenyNode af_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "a" ), p3.getNode( "f" ) ); if ( !af_3.getName().equals( "abcdef" ) ) { return false; } final PhylogenyNode ag_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "a" ), p3.getNode( "g" ) ); if ( !ag_3.getName().equals( "" ) ) { return false; } if ( !ag_3.isRoot() ) { return false; } final PhylogenyNode al_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "a" ), p3.getNode( "l" ) ); if ( !al_3.getName().equals( "" ) ) { return false; } if ( !al_3.isRoot() ) { return false; } final PhylogenyNode kl_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "k" ), p3.getNode( "l" ) ); if ( !kl_3.getName().equals( "" ) ) { return false; } if ( !kl_3.isRoot() ) { return false; } final PhylogenyNode fl_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "f" ), p3.getNode( "l" ) ); if ( !fl_3.getName().equals( "" ) ) { return false; } if ( !fl_3.isRoot() ) { return false; } final PhylogenyNode gk_3 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p3.getNode( "g" ), p3.getNode( "k" ) ); if ( !gk_3.getName().equals( "ghijk" ) ) { return false; } final Phylogeny p4 = factory.create( "(a,b,c)r", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p4 ); final PhylogenyNode r_4 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p4.getNode( "b" ), p4.getNode( "c" ) ); if ( !r_4.getName().equals( "r" ) ) { return false; } final Phylogeny p5 = factory.create( "((a,b),c,d)root", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p5 ); final PhylogenyNode r_5 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p5.getNode( "a" ), p5.getNode( "c" ) ); if ( !r_5.getName().equals( "root" ) ) { return false; } final Phylogeny p6 = factory.create( "((a,b),c,d)rot", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p6 ); final PhylogenyNode r_6 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p6.getNode( "c" ), p6.getNode( "a" ) ); if ( !r_6.getName().equals( "rot" ) ) { return false; } final Phylogeny p7 = factory.create( "(((a,b)x,c)x,d,e)rott", new NHXParser() )[ 0 ]; PhylogenyMethods.preOrderReId( p7 ); final PhylogenyNode r_7 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "a" ), p7.getNode( "e" ) ); if ( !r_7.getName().equals( "rott" ) ) { return false; } final PhylogenyNode r_71 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "e" ), p7.getNode( "a" ) ); if ( !r_71.getName().equals( "rott" ) ) { return false; } final PhylogenyNode r_72 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "e" ), p7.getNode( "rott" ) ); if ( !r_72.getName().equals( "rott" ) ) { return false; } final PhylogenyNode r_73 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "rott" ), p7.getNode( "a" ) ); if ( !r_73.getName().equals( "rott" ) ) { return false; } final PhylogenyNode r_74 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "rott" ), p7.getNode( "rott" ) ); if ( !r_74.getName().equals( "rott" ) ) { return false; } final PhylogenyNode r_75 = PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( p7.getNode( "e" ), p7.getNode( "e" ) ); if ( !r_75.getName().equals( "e" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testHmmscanOutputParser() { final String test_dir = Test.PATH_TO_TEST_DATA; try { final HmmscanPerDomainTableParser parser1 = new HmmscanPerDomainTableParser( new File( test_dir + ForesterUtil.getFileSeparator() + "hmmscan30b3_output_1" ), "MONBR", INDIVIDUAL_SCORE_CUTOFF.NONE ); parser1.parse(); final HmmscanPerDomainTableParser parser2 = new HmmscanPerDomainTableParser( new File( test_dir + ForesterUtil.getFileSeparator() + "hmmscan30b3_output_2" ), "MONBR", INDIVIDUAL_SCORE_CUTOFF.NONE ); final List proteins = parser2.parse(); if ( parser2.getProteinsEncountered() != 4 ) { return false; } if ( proteins.size() != 4 ) { return false; } if ( parser2.getDomainsEncountered() != 69 ) { return false; } if ( parser2.getDomainsIgnoredDueToDuf() != 0 ) { return false; } if ( parser2.getDomainsIgnoredDueToFsEval() != 0 ) { return false; } if ( parser2.getDomainsIgnoredDueToIEval() != 0 ) { return false; } final Protein p1 = proteins.get( 0 ); if ( p1.getNumberOfProteinDomains() != 15 ) { return false; } if ( p1.getLength() != 850 ) { return false; } final Protein p2 = proteins.get( 1 ); if ( p2.getNumberOfProteinDomains() != 51 ) { return false; } if ( p2.getLength() != 1291 ) { return false; } final Protein p3 = proteins.get( 2 ); if ( p3.getNumberOfProteinDomains() != 2 ) { return false; } final Protein p4 = proteins.get( 3 ); if ( p4.getNumberOfProteinDomains() != 1 ) { return false; } if ( !p4.getProteinDomain( 0 ).getDomainId().toString().equals( "DNA_pol_B_new" ) ) { return false; } if ( p4.getProteinDomain( 0 ).getFrom() != 51 ) { return false; } if ( p4.getProteinDomain( 0 ).getTo() != 395 ) { return false; } if ( !Test.isEqual( p4.getProteinDomain( 0 ).getPerDomainEvalue(), 1.2e-39 ) ) { return false; } if ( !Test.isEqual( p4.getProteinDomain( 0 ).getPerDomainScore(), 135.7 ) ) { return false; } if ( !Test.isEqual( p4.getProteinDomain( 0 ).getNumber(), 1 ) ) { return false; } if ( !Test.isEqual( p4.getProteinDomain( 0 ).getTotalCount(), 1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testLastExternalNodeMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final char[] a0 = { '(', '(', 'A', ',', 'B', ')', ',', '(', 'C', ',', 'D', ')', ')', }; final Phylogeny t0 = factory.create( a0, new NHXParser() )[ 0 ]; final PhylogenyNode n1 = t0.getNode( "A" ); if ( n1.isLastExternalNode() ) { return false; } final PhylogenyNode n2 = t0.getNode( "B" ); if ( n2.isLastExternalNode() ) { return false; } final PhylogenyNode n3 = t0.getNode( "C" ); if ( n3.isLastExternalNode() ) { return false; } final PhylogenyNode n4 = t0.getNode( "D" ); if ( !n4.isLastExternalNode() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testLevelOrderIterator() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((A,B)ab,(C,D)cd)r", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it0; for( it0 = t0.iteratorLevelOrder(); it0.hasNext(); ) { it0.next(); } for( it0.reset(); it0.hasNext(); ) { it0.next(); } final PhylogenyNodeIterator it = t0.iteratorLevelOrder(); if ( !it.next().getName().equals( "r" ) ) { return false; } if ( !it.next().getName().equals( "ab" ) ) { return false; } if ( !it.next().getName().equals( "cd" ) ) { return false; } if ( !it.next().getName().equals( "A" ) ) { return false; } if ( !it.next().getName().equals( "B" ) ) { return false; } if ( !it.next().getName().equals( "C" ) ) { return false; } if ( !it.next().getName().equals( "D" ) ) { return false; } if ( it.hasNext() ) { return false; } final Phylogeny t2 = factory.create( "(((1,2,(a,(X,Y,Z)b)3,4,5,6)A,B,C)abc,(D,E,(f1,(f21)f2,f3)F,G)defg)r", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it2; for( it2 = t2.iteratorLevelOrder(); it2.hasNext(); ) { it2.next(); } for( it2.reset(); it2.hasNext(); ) { it2.next(); } final PhylogenyNodeIterator it3 = t2.iteratorLevelOrder(); if ( !it3.next().getName().equals( "r" ) ) { return false; } if ( !it3.next().getName().equals( "abc" ) ) { return false; } if ( !it3.next().getName().equals( "defg" ) ) { return false; } if ( !it3.next().getName().equals( "A" ) ) { return false; } if ( !it3.next().getName().equals( "B" ) ) { return false; } if ( !it3.next().getName().equals( "C" ) ) { return false; } if ( !it3.next().getName().equals( "D" ) ) { return false; } if ( !it3.next().getName().equals( "E" ) ) { return false; } if ( !it3.next().getName().equals( "F" ) ) { return false; } if ( !it3.next().getName().equals( "G" ) ) { return false; } if ( !it3.next().getName().equals( "1" ) ) { return false; } if ( !it3.next().getName().equals( "2" ) ) { return false; } if ( !it3.next().getName().equals( "3" ) ) { return false; } if ( !it3.next().getName().equals( "4" ) ) { return false; } if ( !it3.next().getName().equals( "5" ) ) { return false; } if ( !it3.next().getName().equals( "6" ) ) { return false; } if ( !it3.next().getName().equals( "f1" ) ) { return false; } if ( !it3.next().getName().equals( "f2" ) ) { return false; } if ( !it3.next().getName().equals( "f3" ) ) { return false; } if ( !it3.next().getName().equals( "a" ) ) { return false; } if ( !it3.next().getName().equals( "b" ) ) { return false; } if ( !it3.next().getName().equals( "f21" ) ) { return false; } if ( !it3.next().getName().equals( "X" ) ) { return false; } if ( !it3.next().getName().equals( "Y" ) ) { return false; } if ( !it3.next().getName().equals( "Z" ) ) { return false; } if ( it3.hasNext() ) { return false; } final Phylogeny t4 = factory.create( "((((D)C)B)A)r", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it4; for( it4 = t4.iteratorLevelOrder(); it4.hasNext(); ) { it4.next(); } for( it4.reset(); it4.hasNext(); ) { it4.next(); } final PhylogenyNodeIterator it5 = t4.iteratorLevelOrder(); if ( !it5.next().getName().equals( "r" ) ) { return false; } if ( !it5.next().getName().equals( "A" ) ) { return false; } if ( !it5.next().getName().equals( "B" ) ) { return false; } if ( !it5.next().getName().equals( "C" ) ) { return false; } if ( !it5.next().getName().equals( "D" ) ) { return false; } final Phylogeny t5 = factory.create( "A", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it6; for( it6 = t5.iteratorLevelOrder(); it6.hasNext(); ) { it6.next(); } for( it6.reset(); it6.hasNext(); ) { it6.next(); } final PhylogenyNodeIterator it7 = t5.iteratorLevelOrder(); if ( !it7.next().getName().equals( "A" ) ) { return false; } if ( it.hasNext() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testMafft( final String path ) { try { final List opts = new ArrayList(); opts.add( "--maxiterate" ); opts.add( "1000" ); opts.add( "--localpair" ); opts.add( "--quiet" ); Msa msa = null; final MsaInferrer mafft = Mafft.createInstance( path ); msa = mafft.infer( new File( PATH_TO_TEST_DATA + "ncbi_sn.fasta" ), opts ); if ( ( msa == null ) || ( msa.getLength() < 20 ) || ( msa.getNumberOfSequences() != 19 ) ) { return false; } if ( !msa.getIdentifier( 0 ).toString().equals( "a" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testMidpointrooting() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "(A:1,B:4,C:2,D:2,E:6,F:1,G:1,H:1)", new NHXParser() )[ 0 ]; PhylogenyMethods.midpointRoot( t0 ); if ( !isEqual( t0.getNode( "E" ).getDistanceToParent(), 5 ) ) { return false; } if ( !isEqual( t0.getNode( "B" ).getDistanceToParent(), 4 ) ) { return false; } if ( !isEqual( PhylogenyMethods.calculateLCA( t0.getNode( "F" ), t0.getNode( "G" ) ).getDistanceToParent(), 1 ) ) { return false; } final Phylogeny t1 = factory.create( "((A:1,B:2)AB:1[&&NHX:B=55],(C:3,D:4)CD:3[&&NHX:B=10])ABCD:0.5", new NHXParser() )[ 0 ]; if ( !t1.isRooted() ) { return false; } PhylogenyMethods.midpointRoot( t1 ); if ( !isEqual( t1.getNode( "A" ).getDistanceToParent(), 1 ) ) { return false; } if ( !isEqual( t1.getNode( "B" ).getDistanceToParent(), 2 ) ) { return false; } if ( !isEqual( t1.getNode( "C" ).getDistanceToParent(), 3 ) ) { return false; } if ( !isEqual( t1.getNode( "D" ).getDistanceToParent(), 4 ) ) { return false; } if ( !isEqual( t1.getNode( "CD" ).getDistanceToParent(), 1 ) ) { return false; } if ( !isEqual( t1.getNode( "AB" ).getDistanceToParent(), 3 ) ) { return false; } t1.reRoot( t1.getNode( "A" ) ); PhylogenyMethods.midpointRoot( t1 ); if ( !isEqual( t1.getNode( "A" ).getDistanceToParent(), 1 ) ) { return false; } if ( !isEqual( t1.getNode( "B" ).getDistanceToParent(), 2 ) ) { return false; } if ( !isEqual( t1.getNode( "C" ).getDistanceToParent(), 3 ) ) { return false; } if ( !isEqual( t1.getNode( "D" ).getDistanceToParent(), 4 ) ) { return false; } if ( !isEqual( t1.getNode( "CD" ).getDistanceToParent(), 1 ) ) { System.exit( -1 ); return false; } if ( !isEqual( t1.getNode( "AB" ).getDistanceToParent(), 3 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testMsaQualityMethod() { try { final MolecularSequence s0 = BasicSequence.createAaSequence( "a", "ABAXEFGHIJJE-" ); final MolecularSequence s1 = BasicSequence.createAaSequence( "b", "ABBXEFGHIJJBB" ); final MolecularSequence s2 = BasicSequence.createAaSequence( "c", "AXCXEFGHIJJ--" ); final MolecularSequence s3 = BasicSequence.createAaSequence( "d", "AXDDEFGHIJ---" ); final List l = new ArrayList(); l.add( s0 ); l.add( s1 ); l.add( s2 ); l.add( s3 ); final Msa msa = BasicMsa.createInstance( l ); if ( !isEqual( 1, MsaMethods.calculateIdentityRatio( msa, 0 ) ) ) { return false; } if ( !isEqual( 0.5, MsaMethods.calculateIdentityRatio( msa, 1 ) ) ) { return false; } if ( !isEqual( 0.25, MsaMethods.calculateIdentityRatio( msa, 2 ) ) ) { return false; } if ( !isEqual( 0.75, MsaMethods.calculateIdentityRatio( msa, 3 ) ) ) { return false; } if ( !isEqual( 0.75, MsaMethods.calculateIdentityRatio( msa, 10 ) ) ) { return false; } if ( !isEqual( 0.25, MsaMethods.calculateIdentityRatio( msa, 11 ) ) ) { return false; } if ( !isEqual( 0.25, MsaMethods.calculateIdentityRatio( msa, 12 ) ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testMsaEntropy() { try { final MolecularSequence s0 = BasicSequence.createAaSequence( "a", "AAAAAAA" ); final MolecularSequence s1 = BasicSequence.createAaSequence( "b", "AAAIACC" ); final MolecularSequence s2 = BasicSequence.createAaSequence( "c", "AAIIIIF" ); final MolecularSequence s3 = BasicSequence.createAaSequence( "d", "AIIIVVW" ); final List l = new ArrayList(); l.add( s0 ); l.add( s1 ); l.add( s2 ); l.add( s3 ); final Msa msa = BasicMsa.createInstance( l ); //TODO need to DO the tests!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! //FIXME // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 0 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 1 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 2 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 3 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 4 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 5 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa, 6 ) ); // System.out.println(); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 0 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 1 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 2 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 3 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 4 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 5 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 6, msa, 6 ) ); final List l2 = new ArrayList(); l2.add( BasicSequence.createAaSequence( "1", "AAAAAAA" ) ); l2.add( BasicSequence.createAaSequence( "2", "AAAIACC" ) ); l2.add( BasicSequence.createAaSequence( "3", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "4", "AIIIVVW" ) ); l2.add( BasicSequence.createAaSequence( "5", "AAAAAAA" ) ); l2.add( BasicSequence.createAaSequence( "6", "AAAIACC" ) ); l2.add( BasicSequence.createAaSequence( "7", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "8", "AIIIVVW" ) ); l2.add( BasicSequence.createAaSequence( "9", "AAAAAAA" ) ); l2.add( BasicSequence.createAaSequence( "10", "AAAIACC" ) ); l2.add( BasicSequence.createAaSequence( "11", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "12", "AIIIVVW" ) ); l2.add( BasicSequence.createAaSequence( "13", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "14", "AIIIVVW" ) ); l2.add( BasicSequence.createAaSequence( "15", "AAAAAAA" ) ); l2.add( BasicSequence.createAaSequence( "16", "AAAIACC" ) ); l2.add( BasicSequence.createAaSequence( "17", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "18", "AIIIVVW" ) ); l2.add( BasicSequence.createAaSequence( "19", "AAAAAAA" ) ); l2.add( BasicSequence.createAaSequence( "20", "AAAIACC" ) ); l2.add( BasicSequence.createAaSequence( "21", "AAIIIIF" ) ); l2.add( BasicSequence.createAaSequence( "22", "AIIIVVW" ) ); final Msa msa2 = BasicMsa.createInstance( l2 ); // System.out.println(); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa2, 0 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa2, 1 ) ); // System.out.println( MsaMethods.calcNormalizedShannonsEntropy( 20, msa2, 2 ) ); } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testDeleteableMsa() { try { final MolecularSequence s0 = BasicSequence.createAaSequence( "a", "AAAA" ); final MolecularSequence s1 = BasicSequence.createAaSequence( "b", "BAAA" ); final MolecularSequence s2 = BasicSequence.createAaSequence( "c", "CAAA" ); final MolecularSequence s3 = BasicSequence.createAaSequence( "d", "DAAA" ); final MolecularSequence s4 = BasicSequence.createAaSequence( "e", "EAAA" ); final MolecularSequence s5 = BasicSequence.createAaSequence( "f", "FAAA" ); final List l0 = new ArrayList(); l0.add( s0 ); l0.add( s1 ); l0.add( s2 ); l0.add( s3 ); l0.add( s4 ); l0.add( s5 ); final DeleteableMsa dmsa0 = DeleteableMsa.createInstance( l0 ); dmsa0.deleteRow( "b", false ); if ( !dmsa0.getIdentifier( 1 ).equals( "c" ) ) { return false; } dmsa0.deleteRow( "e", false ); dmsa0.deleteRow( "a", false ); dmsa0.deleteRow( "f", false ); if ( dmsa0.getLength() != 4 ) { return false; } if ( dmsa0.getNumberOfSequences() != 2 ) { return false; } if ( !dmsa0.getIdentifier( 0 ).equals( "c" ) ) { return false; } if ( !dmsa0.getIdentifier( 1 ).equals( "d" ) ) { return false; } if ( dmsa0.getResidueAt( 0, 0 ) != 'C' ) { return false; } if ( !dmsa0.getSequenceAsString( 0 ).toString().equals( "CAAA" ) ) { return false; } if ( dmsa0.getColumnAt( 0 ).size() != 2 ) { return false; } dmsa0.deleteRow( "c", false ); dmsa0.deleteRow( "d", false ); if ( dmsa0.getNumberOfSequences() != 0 ) { return false; } // final MolecularSequence s_0 = BasicSequence.createAaSequence( "a", "--A---B-C--X----" ); final MolecularSequence s_1 = BasicSequence.createAaSequence( "b", "--B-----C-------" ); final MolecularSequence s_2 = BasicSequence.createAaSequence( "c", "--C--AB-C------Z" ); final MolecularSequence s_3 = BasicSequence.createAaSequence( "d", "--D--AA-C-------" ); final MolecularSequence s_4 = BasicSequence.createAaSequence( "e", "--E--AA-C-------" ); final MolecularSequence s_5 = BasicSequence.createAaSequence( "f", "--F--AB-CD--Y---" ); final List l1 = new ArrayList(); l1.add( s_0 ); l1.add( s_1 ); l1.add( s_2 ); l1.add( s_3 ); l1.add( s_4 ); l1.add( s_5 ); final DeleteableMsa dmsa1 = DeleteableMsa.createInstance( l1 ); dmsa1.deleteGapOnlyColumns(); dmsa1.deleteRow( "a", false ); dmsa1.deleteRow( "f", false ); dmsa1.deleteRow( "d", false ); dmsa1.deleteGapOnlyColumns(); if ( !dmsa1.getSequenceAsString( 0 ).toString().equals( "B--C-" ) ) { return false; } if ( !dmsa1.getSequenceAsString( 1 ).toString().equals( "CABCZ" ) ) { return false; } if ( !dmsa1.getSequenceAsString( 2 ).toString().equals( "EAAC-" ) ) { return false; } dmsa1.deleteRow( "c", false ); dmsa1.deleteGapOnlyColumns(); final Writer w0 = new StringWriter(); dmsa1.write( w0, MSA_FORMAT.FASTA ); final Writer w1 = new StringWriter(); dmsa1.write( w1, MSA_FORMAT.PHYLIP ); if ( !dmsa1.getSequenceAsString( 0 ).toString().equals( "B--C" ) ) { return false; } if ( !dmsa1.getSequenceAsString( 1 ).toString().equals( "EAAC" ) ) { return false; } final MolecularSequence s__0 = BasicSequence.createAaSequence( "a", "A------" ); final MolecularSequence s__1 = BasicSequence.createAaSequence( "b", "BB-----" ); final MolecularSequence s__2 = BasicSequence.createAaSequence( "c", "CCC----" ); final MolecularSequence s__3 = BasicSequence.createAaSequence( "d", "DDDD---" ); final MolecularSequence s__4 = BasicSequence.createAaSequence( "e", "EEEEE--" ); final MolecularSequence s__5 = BasicSequence.createAaSequence( "f", "FFFFFF-" ); final List l2 = new ArrayList(); l2.add( s__0 ); l2.add( s__1 ); l2.add( s__2 ); l2.add( s__3 ); l2.add( s__4 ); l2.add( s__5 ); final DeleteableMsa dmsa2 = DeleteableMsa.createInstance( l2 ); dmsa2.deleteGapColumns( 0.5 ); if ( !dmsa2.getSequenceAsString( 0 ).toString().equals( "A---" ) ) { return false; } if ( !dmsa2.getSequenceAsString( 1 ).toString().equals( "BB--" ) ) { return false; } if ( !dmsa2.getSequenceAsString( 2 ).toString().equals( "CCC-" ) ) { return false; } dmsa2.deleteGapColumns( 0.2 ); if ( !dmsa2.getSequenceAsString( 0 ).toString().equals( "A-" ) ) { return false; } if ( !dmsa2.getSequenceAsString( 1 ).toString().equals( "BB" ) ) { return false; } if ( !dmsa2.getSequenceAsString( 2 ).toString().equals( "CC" ) ) { return false; } dmsa2.deleteGapColumns( 0 ); dmsa2.deleteRow( "a", false ); dmsa2.deleteRow( "b", false ); dmsa2.deleteRow( "f", false ); dmsa2.deleteRow( "e", false ); dmsa2.setIdentifier( 0, "new_c" ); dmsa2.setIdentifier( 1, "new_d" ); dmsa2.setResidueAt( 0, 0, 'x' ); final MolecularSequence s = dmsa2.deleteRow( "new_d", true ); if ( !s.getMolecularSequenceAsString().equals( "D" ) ) { return false; } final Writer w = new StringWriter(); dmsa2.write( w, MSA_FORMAT.PHYLIP ); final String phylip = w.toString(); if ( !phylip.equals( "1 1" + ForesterUtil.LINE_SEPARATOR + "new_c x" + ForesterUtil.LINE_SEPARATOR ) ) { System.out.println( phylip ); return false; } final Writer w2 = new StringWriter(); dmsa2.write( w2, MSA_FORMAT.FASTA ); final String fasta = w2.toString(); if ( !fasta.equals( ">new_c" + ForesterUtil.LINE_SEPARATOR + "x" + ForesterUtil.LINE_SEPARATOR ) ) { System.out.println( fasta ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNextNodeWithCollapsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); PhylogenyNode n; List ext = new ArrayList(); final StringBuffer sb0 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t0 = factory.create( sb0.toString(), new NHXParser() )[ 0 ]; t0.getNode( "cd" ).setCollapse( true ); t0.getNode( "cde" ).setCollapse( true ); n = t0.getFirstExternalNode(); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "cde" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "h" ) ) { return false; } ext.clear(); final StringBuffer sb1 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t1 = factory.create( sb1.toString(), new NHXParser() )[ 0 ]; t1.getNode( "ab" ).setCollapse( true ); t1.getNode( "cd" ).setCollapse( true ); t1.getNode( "cde" ).setCollapse( true ); n = t1.getNode( "ab" ); ext = new ArrayList(); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "cde" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "h" ) ) { return false; } ext.clear(); final StringBuffer sb2 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t2 = factory.create( sb2.toString(), new NHXParser() )[ 0 ]; t2.getNode( "ab" ).setCollapse( true ); t2.getNode( "cd" ).setCollapse( true ); t2.getNode( "cde" ).setCollapse( true ); t2.getNode( "c" ).setCollapse( true ); t2.getNode( "d" ).setCollapse( true ); t2.getNode( "e" ).setCollapse( true ); t2.getNode( "gh" ).setCollapse( true ); n = t2.getNode( "ab" ); ext = new ArrayList(); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "cde" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "gh" ) ) { return false; } ext.clear(); final StringBuffer sb3 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t3 = factory.create( sb3.toString(), new NHXParser() )[ 0 ]; t3.getNode( "ab" ).setCollapse( true ); t3.getNode( "cd" ).setCollapse( true ); t3.getNode( "cde" ).setCollapse( true ); t3.getNode( "c" ).setCollapse( true ); t3.getNode( "d" ).setCollapse( true ); t3.getNode( "e" ).setCollapse( true ); t3.getNode( "gh" ).setCollapse( true ); t3.getNode( "fgh" ).setCollapse( true ); n = t3.getNode( "ab" ); ext = new ArrayList(); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "cde" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "fgh" ) ) { return false; } ext.clear(); final StringBuffer sb4 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t4 = factory.create( sb4.toString(), new NHXParser() )[ 0 ]; t4.getNode( "ab" ).setCollapse( true ); t4.getNode( "cd" ).setCollapse( true ); t4.getNode( "cde" ).setCollapse( true ); t4.getNode( "c" ).setCollapse( true ); t4.getNode( "d" ).setCollapse( true ); t4.getNode( "e" ).setCollapse( true ); t4.getNode( "gh" ).setCollapse( true ); t4.getNode( "fgh" ).setCollapse( true ); t4.getNode( "abcdefgh" ).setCollapse( true ); n = t4.getNode( "abcdefgh" ); if ( n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes() != null ) { return false; } final StringBuffer sb5 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t5 = factory.create( sb5.toString(), new NHXParser() )[ 0 ]; ext.clear(); n = t5.getFirstExternalNode(); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 8 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 7 ).getName().equals( "h" ) ) { return false; } final StringBuffer sb6 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t6 = factory.create( sb6.toString(), new NHXParser() )[ 0 ]; ext.clear(); t6.getNode( "ab" ).setCollapse( true ); n = t6.getNode( "ab" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 7 ) { return false; } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "h" ) ) { return false; } final StringBuffer sb7 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t7 = factory.create( sb7.toString(), new NHXParser() )[ 0 ]; ext.clear(); t7.getNode( "cd" ).setCollapse( true ); n = t7.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 7 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "cd" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "h" ) ) { return false; } final StringBuffer sb8 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h))fgh)cdefgh)abcdefgh" ); final Phylogeny t8 = factory.create( sb8.toString(), new NHXParser() )[ 0 ]; ext.clear(); t8.getNode( "cd" ).setCollapse( true ); t8.getNode( "c" ).setCollapse( true ); t8.getNode( "d" ).setCollapse( true ); n = t8.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 7 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "cd" ) ) { System.out.println( "2 fail" ); return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "g" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "h" ) ) { return false; } final StringBuffer sb9 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t9 = factory.create( sb9.toString(), new NHXParser() )[ 0 ]; ext.clear(); t9.getNode( "gh" ).setCollapse( true ); n = t9.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 7 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "gh" ) ) { return false; } final StringBuffer sb10 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t10 = factory.create( sb10.toString(), new NHXParser() )[ 0 ]; ext.clear(); t10.getNode( "gh" ).setCollapse( true ); t10.getNode( "g" ).setCollapse( true ); t10.getNode( "h" ).setCollapse( true ); n = t10.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 7 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "f" ) ) { return false; } if ( !ext.get( 6 ).getName().equals( "gh" ) ) { return false; } final StringBuffer sb11 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t11 = factory.create( sb11.toString(), new NHXParser() )[ 0 ]; ext.clear(); t11.getNode( "gh" ).setCollapse( true ); t11.getNode( "fgh" ).setCollapse( true ); n = t11.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 6 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "fgh" ) ) { return false; } final StringBuffer sb12 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t12 = factory.create( sb12.toString(), new NHXParser() )[ 0 ]; ext.clear(); t12.getNode( "gh" ).setCollapse( true ); t12.getNode( "fgh" ).setCollapse( true ); t12.getNode( "g" ).setCollapse( true ); t12.getNode( "h" ).setCollapse( true ); t12.getNode( "f" ).setCollapse( true ); n = t12.getNode( "a" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 6 ) { return false; } if ( !ext.get( 0 ).getName().equals( "a" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "b" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "fgh" ) ) { return false; } final StringBuffer sb13 = new StringBuffer( "((a,b)ab,(((c,d)cd,e)cde,(f,(g,h)gh)fgh)cdefgh)abcdefgh" ); final Phylogeny t13 = factory.create( sb13.toString(), new NHXParser() )[ 0 ]; ext.clear(); t13.getNode( "ab" ).setCollapse( true ); t13.getNode( "b" ).setCollapse( true ); t13.getNode( "fgh" ).setCollapse( true ); t13.getNode( "gh" ).setCollapse( true ); n = t13.getNode( "ab" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 5 ) { return false; } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "fgh" ) ) { return false; } final StringBuffer sb14 = new StringBuffer( "((a,b,0)ab,(((c,d)cd,e)cde,(f,(g,h,1,2)gh,0)fgh)cdefgh)abcdefgh" ); final Phylogeny t14 = factory.create( sb14.toString(), new NHXParser() )[ 0 ]; ext.clear(); t14.getNode( "ab" ).setCollapse( true ); t14.getNode( "a" ).setCollapse( true ); t14.getNode( "fgh" ).setCollapse( true ); t14.getNode( "gh" ).setCollapse( true ); n = t14.getNode( "ab" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 5 ) { return false; } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "fgh" ) ) { return false; } final StringBuffer sb15 = new StringBuffer( "((a,b,0)ab,(((c,d)cd,e)cde,x,(f,(g,h,1,2)gh,0)fgh)cdefgh)abcdefgh" ); final Phylogeny t15 = factory.create( sb15.toString(), new NHXParser() )[ 0 ]; ext.clear(); t15.getNode( "ab" ).setCollapse( true ); t15.getNode( "a" ).setCollapse( true ); t15.getNode( "fgh" ).setCollapse( true ); t15.getNode( "gh" ).setCollapse( true ); n = t15.getNode( "ab" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 6 ) { return false; } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "c" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "d" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "e" ) ) { return false; } if ( !ext.get( 4 ).getName().equals( "x" ) ) { return false; } if ( !ext.get( 5 ).getName().equals( "fgh" ) ) { return false; } // // final StringBuffer sb16 = new StringBuffer( "((a,b,0)ab,(((c,d)cd,e)cde,x,(f,(g,h,1,2)gh,0)fgh)cdefgh)abcdefgh" ); final Phylogeny t16 = factory.create( sb16.toString(), new NHXParser() )[ 0 ]; ext.clear(); t16.getNode( "ab" ).setCollapse( true ); t16.getNode( "a" ).setCollapse( true ); t16.getNode( "fgh" ).setCollapse( true ); t16.getNode( "gh" ).setCollapse( true ); t16.getNode( "cd" ).setCollapse( true ); t16.getNode( "cde" ).setCollapse( true ); t16.getNode( "d" ).setCollapse( true ); t16.getNode( "x" ).setCollapse( true ); n = t16.getNode( "ab" ); while ( n != null ) { ext.add( n ); n = n.getNextExternalNodeWhileTakingIntoAccountCollapsedNodes(); } if ( ext.size() != 4 ) { return false; } if ( !ext.get( 0 ).getName().equals( "ab" ) ) { return false; } if ( !ext.get( 1 ).getName().equals( "cde" ) ) { return false; } if ( !ext.get( 2 ).getName().equals( "x" ) ) { return false; } if ( !ext.get( 3 ).getName().equals( "fgh" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNexusCharactersParsing() { try { final NexusCharactersParser parser = new NexusCharactersParser(); parser.setSource( new File( Test.PATH_TO_TEST_DATA + "nexus_test_7.nex" ) ); parser.parse(); String[] labels = parser.getCharStateLabels(); if ( labels.length != 7 ) { return false; } if ( !labels[ 0 ].equals( "14-3-3" ) ) { return false; } if ( !labels[ 1 ].equals( "2-Hacid_dh" ) ) { return false; } if ( !labels[ 2 ].equals( "2-Hacid_dh_C" ) ) { return false; } if ( !labels[ 3 ].equals( "2-oxoacid_dh" ) ) { return false; } if ( !labels[ 4 ].equals( "2OG-FeII_Oxy" ) ) { return false; } if ( !labels[ 5 ].equals( "3-HAO" ) ) { return false; } if ( !labels[ 6 ].equals( "3_5_exonuc" ) ) { return false; } parser.setSource( new File( Test.PATH_TO_TEST_DATA + "nexus_test_8.nex" ) ); parser.parse(); labels = parser.getCharStateLabels(); if ( labels.length != 7 ) { return false; } if ( !labels[ 0 ].equals( "14-3-3" ) ) { return false; } if ( !labels[ 1 ].equals( "2-Hacid_dh" ) ) { return false; } if ( !labels[ 2 ].equals( "2-Hacid_dh_C" ) ) { return false; } if ( !labels[ 3 ].equals( "2-oxoacid_dh" ) ) { return false; } if ( !labels[ 4 ].equals( "2OG-FeII_Oxy" ) ) { return false; } if ( !labels[ 5 ].equals( "3-HAO" ) ) { return false; } if ( !labels[ 6 ].equals( "3_5_exonuc" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNexusMatrixParsing() { try { final NexusBinaryStatesMatrixParser parser = new NexusBinaryStatesMatrixParser(); parser.setSource( new File( Test.PATH_TO_TEST_DATA + "nexus_test_9.nex" ) ); parser.parse(); final CharacterStateMatrix m = parser.getMatrix(); if ( m.getNumberOfCharacters() != 9 ) { return false; } if ( m.getNumberOfIdentifiers() != 5 ) { return false; } if ( m.getState( 0, 0 ) != BinaryStates.PRESENT ) { return false; } if ( m.getState( 0, 1 ) != BinaryStates.ABSENT ) { return false; } if ( m.getState( 1, 0 ) != BinaryStates.PRESENT ) { return false; } if ( m.getState( 2, 0 ) != BinaryStates.ABSENT ) { return false; } if ( m.getState( 4, 8 ) != BinaryStates.PRESENT ) { return false; } if ( !m.getIdentifier( 0 ).equals( "MOUSE" ) ) { return false; } if ( !m.getIdentifier( 4 ).equals( "ARATH" ) ) { return false; } // if ( labels.length != 7 ) { // return false; // } // if ( !labels[ 0 ].equals( "14-3-3" ) ) { // return false; // } // if ( !labels[ 1 ].equals( "2-Hacid_dh" ) ) { // return false; // } // if ( !labels[ 2 ].equals( "2-Hacid_dh_C" ) ) { // return false; // } // if ( !labels[ 3 ].equals( "2-oxoacid_dh" ) ) { // return false; // } // if ( !labels[ 4 ].equals( "2OG-FeII_Oxy" ) ) { // return false; // } // if ( !labels[ 5 ].equals( "3-HAO" ) ) { // return false; // } // if ( !labels[ 6 ].equals( "3_5_exonuc" ) ) { // return false; // } // parser.setSource( new File( Test.PATH_TO_TEST_DATA + "nexus_test_8.nex" ) ); // parser.parse(); // labels = parser.getCharStateLabels(); // if ( labels.length != 7 ) { // return false; // } // if ( !labels[ 0 ].equals( "14-3-3" ) ) { // return false; // } // if ( !labels[ 1 ].equals( "2-Hacid_dh" ) ) { // return false; // } // if ( !labels[ 2 ].equals( "2-Hacid_dh_C" ) ) { // return false; // } // if ( !labels[ 3 ].equals( "2-oxoacid_dh" ) ) { // return false; // } // if ( !labels[ 4 ].equals( "2OG-FeII_Oxy" ) ) { // return false; // } // if ( !labels[ 5 ].equals( "3-HAO" ) ) { // return false; // } // if ( !labels[ 6 ].equals( "3_5_exonuc" ) ) { // return false; // } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNexusTreeParsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final NexusPhylogeniesParser parser = new NexusPhylogeniesParser(); Phylogeny[] phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_1.nex", parser ); if ( phylogenies.length != 1 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 25 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "" ) ) { return false; } phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_2.nex", parser ); if ( phylogenies.length != 1 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "name" ) ) { return false; } phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_3.nex", parser ); if ( phylogenies.length != 1 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "" ) ) { return false; } if ( phylogenies[ 0 ].isRooted() ) { return false; } phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_4.nex", parser ); if ( phylogenies.length != 18 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "tree 0" ) ) { return false; } if ( !phylogenies[ 1 ].getName().equals( "tree 1" ) ) { return false; } if ( phylogenies[ 1 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( phylogenies[ 2 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( phylogenies[ 3 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( phylogenies[ 4 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( phylogenies[ 5 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( phylogenies[ 6 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( phylogenies[ 7 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 8 ].getName().equals( "tree 8" ) ) { return false; } if ( phylogenies[ 8 ].isRooted() ) { return false; } if ( phylogenies[ 8 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 9 ].getName().equals( "tree 9" ) ) { return false; } if ( !phylogenies[ 9 ].isRooted() ) { return false; } if ( phylogenies[ 9 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 10 ].getName().equals( "tree 10" ) ) { return false; } if ( !phylogenies[ 10 ].isRooted() ) { return false; } if ( phylogenies[ 10 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 11 ].getName().equals( "tree 11" ) ) { return false; } if ( phylogenies[ 11 ].isRooted() ) { return false; } if ( phylogenies[ 11 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 12 ].getName().equals( "tree 12" ) ) { return false; } if ( !phylogenies[ 12 ].isRooted() ) { return false; } if ( phylogenies[ 12 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 13 ].getName().equals( "tree 13" ) ) { return false; } if ( !phylogenies[ 13 ].isRooted() ) { return false; } if ( phylogenies[ 13 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 14 ].getName().equals( "tree 14" ) ) { return false; } if ( !phylogenies[ 14 ].isRooted() ) { return false; } if ( phylogenies[ 14 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( !phylogenies[ 15 ].getName().equals( "tree 15" ) ) { return false; } if ( phylogenies[ 15 ].isRooted() ) { return false; } if ( phylogenies[ 15 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( !phylogenies[ 16 ].getName().equals( "tree 16" ) ) { return false; } if ( !phylogenies[ 16 ].isRooted() ) { return false; } if ( phylogenies[ 16 ].getNumberOfExternalNodes() != 10 ) { return false; } if ( !phylogenies[ 17 ].getName().equals( "tree 17" ) ) { return false; } if ( phylogenies[ 17 ].isRooted() ) { return false; } if ( phylogenies[ 17 ].getNumberOfExternalNodes() != 10 ) { return false; } final NexusPhylogeniesParser p2 = new NexusPhylogeniesParser(); phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "S15613.nex", p2 ); if ( phylogenies.length != 9 ) { return false; } if ( !isEqual( 0.48039661496919533, phylogenies[ 0 ].getNode( "Diadocidia_spinosula" ).getDistanceToParent() ) ) { return false; } if ( !isEqual( 0.3959796191512233, phylogenies[ 0 ].getNode( "Diadocidia_stanfordensis" ).getDistanceToParent() ) ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "Family Diadocidiidae MLT (Imported_tree_0)" ) ) { return false; } if ( !phylogenies[ 1 ].getName().equals( "Family Diadocidiidae BAT (con_50_majrule)" ) ) { return false; } if ( !phylogenies[ 2 ].getName().equals( "Family Diadocidiidae BAT (con_50_majrule)" ) ) { return false; } if ( !isEqual( 0.065284, phylogenies[ 7 ].getNode( "Bradysia_amoena" ).getDistanceToParent() ) ) { return false; } if ( !isEqual( 0.065284, phylogenies[ 8 ].getNode( "Bradysia_amoena" ).getDistanceToParent() ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNexusTreeParsingIterating() { try { final NexusPhylogeniesParser p = new NexusPhylogeniesParser(); p.setSource( Test.PATH_TO_TEST_DATA + "nexus_test_1.nex" ); if ( !p.hasNext() ) { return false; } Phylogeny phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 25 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 25 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } p.setSource( Test.PATH_TO_TEST_DATA + "nexus_test_2.nex" ); if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "name" ) ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "name" ) ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } p.setSource( Test.PATH_TO_TEST_DATA + "nexus_test_3.nex" ); if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( phy.isRooted() ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } // p.reset(); if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } // p.setSource( Test.PATH_TO_TEST_DATA + "nexus_test_4_1.nex" ); if ( !p.hasNext() ) { return false; } //0 phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "tree 0" ) ) { return false; } //1 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "tree 1" ) ) { return false; } //2 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { System.out.println( phy.toString() ); return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( phy.isRooted() ) { return false; } //3 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 4 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //4 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 5 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //5 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( phy.isRooted() ) { return false; } //6 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 2 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //7 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((a,b),c);" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //8 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((AA,BB),CC);" ) ) { return false; } if ( !phy.getName().equals( "tree 8" ) ) { return false; } //9 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((a,b),cc);" ) ) { return false; } if ( !phy.getName().equals( "tree 9" ) ) { return false; } //10 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((a,b),c);" ) ) { return false; } if ( !phy.getName().equals( "tree 10" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //11 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((1,2),3);" ) ) { return false; } if ( !phy.getName().equals( "tree 11" ) ) { return false; } if ( phy.isRooted() ) { return false; } //12 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((aa,bb),cc);" ) ) { return false; } if ( !phy.getName().equals( "tree 12" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //13 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.toNewHampshire().equals( "((a,b),c);" ) ) { return false; } if ( !phy.getName().equals( "tree 13" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //14 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 10 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.toNewHampshire() .equals( "(1:0.212481,8:0.297838,(9:0.222729,((6:0.201563,7:0.194547):0.282035,(4:1.146091,(3:1.008881,(10:0.384105,(2:0.235682,5:0.353432):0.32368):0.103875):0.41354):0.254687):0.095341):0.079254):0.0;" ) ) { System.out.println( phy.toNewHampshire() ); return false; } if ( !phy.getName().equals( "tree 14" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //15 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 10 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.toNewHampshire() .equals( "(1:0.212481,8:0.297838,(9:0.222729,((6:0.201563,7:0.194547):0.282035,(4:1.146091,(3:1.008881,(10:0.384105,(2:0.235682,5:0.353432):0.32368):0.103875):0.41354):0.254687):0.095341):0.079254):0.0;" ) ) { System.out.println( phy.toNewHampshire() ); return false; } if ( !phy.getName().equals( "tree 15" ) ) { return false; } if ( phy.isRooted() ) { return false; } //16 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 10 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.toNewHampshire() .equals( "(1:0.212481,8:0.297838,(9:0.222729,((6:0.201563,7:0.194547):0.282035,(4:1.146091,(3:1.008881,(10:0.384105,(2:0.235682,5:0.353432):0.32368):0.103875):0.41354):0.254687):0.095341):0.079254):0.0;" ) ) { System.out.println( phy.toNewHampshire() ); return false; } if ( !phy.getName().equals( "tree 16" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //17 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy.getNumberOfExternalNodes() != 10 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.toNewHampshire() .equals( "(1:0.212481,8:0.297838,(9:0.222729,((6:0.201563,7:0.194547):0.282035,(4:1.146091,(3:1.008881,(10:0.384105,(2:0.235682,5:0.353432):0.32368):0.103875):0.41354):0.254687):0.095341):0.079254):0.0;" ) ) { System.out.println( phy.toNewHampshire() ); return false; } if ( !phy.getName().equals( "tree 17" ) ) { return false; } if ( phy.isRooted() ) { return false; } // if ( p.hasNext() ) { return false; } phy = p.next(); if ( phy != null ) { return false; } p.reset(); //0 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "tree 0" ) ) { return false; } //1 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 10 ) { return false; } if ( !phy.getName().equals( "tree 1" ) ) { return false; } //2 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( phy.isRooted() ) { return false; } //3 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 4 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //4 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 5 ) { System.out.println( phy.getNumberOfExternalNodes() ); return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( !phy.isRooted() ) { return false; } //5 if ( !p.hasNext() ) { return false; } phy = p.next(); if ( phy == null ) { return false; } if ( phy.getNumberOfExternalNodes() != 3 ) { return false; } if ( !phy.getName().equals( "" ) ) { return false; } if ( phy.isRooted() ) { return false; } // final NexusPhylogeniesParser p2 = new NexusPhylogeniesParser(); p2.setSource( Test.PATH_TO_TEST_DATA + "S15613.nex" ); // 0 if ( !p2.hasNext() ) { return false; } phy = p2.next(); if ( !isEqual( 0.48039661496919533, phy.getNode( "Diadocidia_spinosula" ).getDistanceToParent() ) ) { return false; } if ( !isEqual( 0.3959796191512233, phy.getNode( "Diadocidia_stanfordensis" ).getDistanceToParent() ) ) { return false; } // 1 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 2 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 3 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 4 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 5 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 6 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 7 if ( !p2.hasNext() ) { return false; } phy = p2.next(); // 8 if ( !p2.hasNext() ) { return false; } phy = p2.next(); if ( !isEqual( 0.065284, phy.getNode( "Bradysia_amoena" ).getDistanceToParent() ) ) { return false; } if ( p2.hasNext() ) { return false; } phy = p2.next(); if ( phy != null ) { return false; } // 0 p2.reset(); if ( !p2.hasNext() ) { return false; } phy = p2.next(); if ( !isEqual( 0.48039661496919533, phy.getNode( "Diadocidia_spinosula" ).getDistanceToParent() ) ) { return false; } if ( !isEqual( 0.3959796191512233, phy.getNode( "Diadocidia_stanfordensis" ).getDistanceToParent() ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNexusTreeParsingTranslating() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final NexusPhylogeniesParser parser = new NexusPhylogeniesParser(); Phylogeny[] phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_5.nex", parser ); if ( phylogenies.length != 1 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "Tree0" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_6.nex", parser ); if ( phylogenies.length != 3 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "Tree0" ) ) { return false; } if ( phylogenies[ 0 ].isRooted() ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } if ( phylogenies[ 1 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 1 ].getName().equals( "Tree1" ) ) { return false; } if ( phylogenies[ 1 ].isRooted() ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } if ( phylogenies[ 2 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 2 ].getName().equals( "Tree2" ) ) { return false; } if ( !phylogenies[ 2 ].isRooted() ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } phylogenies = null; phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "nexus_test_7.nex", parser ); if ( phylogenies.length != 3 ) { return false; } if ( phylogenies[ 0 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 0 ].getName().equals( "Tree0" ) ) { return false; } if ( phylogenies[ 0 ].isRooted() ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 0 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } if ( phylogenies[ 1 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 1 ].getName().equals( "Tree1" ) ) { return false; } if ( phylogenies[ 1 ].isRooted() ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 1 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } if ( phylogenies[ 2 ].getNumberOfExternalNodes() != 3 ) { return false; } if ( !phylogenies[ 2 ].getName().equals( "Tree2" ) ) { return false; } if ( !phylogenies[ 2 ].isRooted() ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getName().equals( "Scarabaeus" ) ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getNextExternalNode().getName().equals( "Drosophila" ) ) { return false; } if ( !phylogenies[ 2 ].getFirstExternalNode().getNextExternalNode().getNextExternalNode().getName() .equals( "Aranaeus" ) ) { return false; } phylogenies = factory.create( Test.PATH_TO_TEST_DATA + "S14117.nex", parser ); if ( phylogenies.length != 3 ) { return false; } if ( !isEqual( phylogenies[ 2 ].getNode( "Aloysia lycioides 251-76-02169" ).getDistanceToParent(), 0.00100049 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHParsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "(A,B1)", new NHXParser() )[ 0 ]; if ( !p1.toNewHampshireX().equals( "(A,B1)" ) ) { return false; } final NHXParser nhxp = new NHXParser(); nhxp.setTaxonomyExtraction( NHXParser.TAXONOMY_EXTRACTION.NO ); nhxp.setReplaceUnderscores( true ); final Phylogeny uc0 = factory.create( "(A__A_,_B_B)", nhxp )[ 0 ]; if ( !uc0.getRoot().getChildNode( 0 ).getName().equals( "A A" ) ) { return false; } if ( !uc0.getRoot().getChildNode( 1 ).getName().equals( "B B" ) ) { return false; } final Phylogeny p1b = factory.create( " \n \t \b \r \f ; ( \n \t \b \r \f; A ; \n \t \b \r \f, \n \t \b \r \f; B ; \n \t \b \r \f 1 \n \t \b \r \f ; \n \t \b \r \f );;;;; \n \t \b \r \f;;; \n \t \b \r \f ", new NHXParser() )[ 0 ]; if ( !p1b.toNewHampshireX().equals( "(';A;',';B;1;')" ) ) { return false; } if ( !p1b.toNewHampshire().equals( "(';A;',';B;1;');" ) ) { return false; } final Phylogeny p2 = factory.create( new StringBuffer( "(A,B2)" ).toString(), new NHXParser() )[ 0 ]; final Phylogeny p3 = factory.create( new char[] { '(', 'A', ',', 'B', '3', ')' }, new NHXParser() )[ 0 ]; final Phylogeny p4 = factory.create( "(A,B4);", new NHXParser() )[ 0 ]; final Phylogeny p5 = factory.create( new StringBuffer( "(A,B5);" ).toString(), new NHXParser() )[ 0 ]; final Phylogeny[] p7 = factory.create( "(A,B7);(C,D7)", new NHXParser() ); final Phylogeny[] p8 = factory.create( "(A,B8) (C,D8)", new NHXParser() ); final Phylogeny[] p9 = factory.create( "(A,B9)\n(C,D9)", new NHXParser() ); final Phylogeny[] p10 = factory.create( "(A,B10);(C,D10);", new NHXParser() ); final Phylogeny[] p11 = factory.create( "(A,B11);(C,D11) (E,F11)\t(G,H11)", new NHXParser() ); final Phylogeny[] p12 = factory.create( "(A,B12) (C,D12) (E,F12) (G,H12)", new NHXParser() ); final Phylogeny[] p13 = factory.create( " ; (;A; , ; B ; 1 3 ; \n)\t ( \n ;" + " C ; ,; D;13;);;;;;;(;E;,;F;13 ;) ; " + "; ; ( \t\n\r\b; G ;, ;H ;1 3; ) ; ; ;", new NHXParser() ); if ( !p13[ 0 ].toNewHampshireX().equals( "(';A;',';B;13;')" ) ) { return false; } if ( !p13[ 1 ].toNewHampshireX().equals( "(';C;',';D;13;')" ) ) { return false; } if ( !p13[ 2 ].toNewHampshireX().equals( "(';E;',';F;13;')" ) ) { return false; } if ( !p13[ 3 ].toNewHampshireX().equals( "(';G;',';H;13;')" ) ) { return false; } final Phylogeny[] p14 = factory.create( "(A,B14)ab", new NHXParser() ); final Phylogeny[] p15 = factory.create( "(A,B15)ab;", new NHXParser() ); final String p16_S = "((A,B),C)"; final Phylogeny[] p16 = factory.create( p16_S, new NHXParser() ); if ( p16.length != 1 ) { return false; } if ( !p16[ 0 ].toNewHampshireX().equals( p16_S ) ) { return false; } final String p17_S = "(C,(A,B))"; final Phylogeny[] p17 = factory.create( p17_S, new NHXParser() ); if ( p17.length != 1 ) { return false; } if ( !p17[ 0 ].toNewHampshireX().equals( p17_S ) ) { return false; } final String p18_S = "((A,B),(C,D))"; final Phylogeny[] p18 = factory.create( p18_S, new NHXParser() ); if ( p18.length != 1 ) { return false; } if ( !p18[ 0 ].toNewHampshireX().equals( p18_S ) ) { return false; } final String p19_S = "(((A,B),C),D)"; final Phylogeny[] p19 = factory.create( p19_S, new NHXParser() ); if ( p19.length != 1 ) { return false; } if ( !p19[ 0 ].toNewHampshireX().equals( p19_S ) ) { return false; } final String p20_S = "(A,(B,(C,D)))"; final Phylogeny[] p20 = factory.create( p20_S, new NHXParser() ); if ( p20.length != 1 ) { return false; } if ( !p20[ 0 ].toNewHampshireX().equals( p20_S ) ) { return false; } final String p21_S = "(A,(B,(C,(D,E))))"; final Phylogeny[] p21 = factory.create( p21_S, new NHXParser() ); if ( p21.length != 1 ) { return false; } if ( !p21[ 0 ].toNewHampshireX().equals( p21_S ) ) { return false; } final String p22_S = "((((A,B),C),D),E)"; final Phylogeny[] p22 = factory.create( p22_S, new NHXParser() ); if ( p22.length != 1 ) { return false; } if ( !p22[ 0 ].toNewHampshireX().equals( p22_S ) ) { return false; } final String p23_S = "(A,(B,(C,(D,E)de)cde)bcde)abcde"; final Phylogeny[] p23 = factory.create( p23_S, new NHXParser() ); if ( p23.length != 1 ) { System.out.println( "xl=" + p23.length ); System.exit( -1 ); return false; } if ( !p23[ 0 ].toNewHampshireX().equals( p23_S ) ) { return false; } final String p24_S = "((((A,B)ab,C)abc,D)abcd,E)abcde"; final Phylogeny[] p24 = factory.create( p24_S, new NHXParser() ); if ( p24.length != 1 ) { return false; } if ( !p24[ 0 ].toNewHampshireX().equals( p24_S ) ) { return false; } final String p241_S1 = "(A,(B,(C,(D,E)de)cde)bcde)abcde"; final String p241_S2 = "((((A,B)ab,C)abc,D)abcd,E)abcde"; final Phylogeny[] p241 = factory.create( p241_S1 + p241_S2, new NHXParser() ); if ( p241.length != 2 ) { return false; } if ( !p241[ 0 ].toNewHampshireX().equals( p241_S1 ) ) { return false; } if ( !p241[ 1 ].toNewHampshireX().equals( p241_S2 ) ) { return false; } final String p25_S = "((((((((((((((A,B)ab,C)abc,D)abcd,E)" + "abcde,(B,(C,(D,E)de)cde)bcde)abcde,(B,((A,(B,(C,(D," + "E)de)cde)bcde)abcde,(D,E)de)cde)bcde)abcde,B)ab,C)" + "abc,((((A,B)ab,C)abc,D)abcd,E)abcde)abcd,E)abcde," + "((((A,((((((((A,B)ab,C)abc,((((A,B)ab,C)abc,D)abcd," + "E)abcde)abcd,E)abcde,((((A,B)ab,C)abc,D)abcd,E)abcde)" + "ab,C)abc,((((A,B)ab,C)abc,D)abcd,E)abcde)abcd,E)abcde" + ")ab,C)abc,D)abcd,E)abcde)ab,C)abc,((((A,B)ab,C)abc,D)" + "abcd,E)abcde)abcd,E)abcde"; final Phylogeny[] p25 = factory.create( p25_S, new NHXParser() ); if ( !p25[ 0 ].toNewHampshireX().equals( p25_S ) ) { return false; } final String p26_S = "(A,B)ab"; final Phylogeny[] p26 = factory.create( p26_S, new NHXParser() ); if ( !p26[ 0 ].toNewHampshireX().equals( p26_S ) ) { return false; } final String p27_S = "((((A,B)ab,C)abc,D)abcd,E)abcde"; final Phylogeny[] p27s = factory.create( p27_S, new NHXParser() ); if ( p27s.length != 1 ) { System.out.println( "xxl=" + p27s.length ); System.exit( -1 ); return false; } if ( !p27s[ 0 ].toNewHampshireX().equals( p27_S ) ) { System.out.println( p27s[ 0 ].toNewHampshireX() ); System.exit( -1 ); return false; } final Phylogeny[] p27 = factory.create( new File( Test.PATH_TO_TEST_DATA + "phylogeny27.nhx" ), new NHXParser() ); if ( p27.length != 1 ) { System.out.println( "yl=" + p27.length ); System.exit( -1 ); return false; } if ( !p27[ 0 ].toNewHampshireX().equals( p27_S ) ) { System.out.println( p27[ 0 ].toNewHampshireX() ); System.exit( -1 ); return false; } final String p28_S1 = "((((A,B)ab,C)abc,D)abcd,E)abcde"; final String p28_S2 = "(A,(B,(C,(D,E)de)cde)bcde)abcde"; final String p28_S3 = "(A,B)ab"; final String p28_S4 = "((((A,B),C),D),;E;)"; final Phylogeny[] p28 = factory.create( new File( Test.PATH_TO_TEST_DATA + "phylogeny28.nhx" ), new NHXParser() ); if ( !p28[ 0 ].toNewHampshireX().equals( p28_S1 ) ) { return false; } if ( !p28[ 1 ].toNewHampshireX().equals( p28_S2 ) ) { return false; } if ( !p28[ 2 ].toNewHampshireX().equals( p28_S3 ) ) { return false; } if ( !p28[ 3 ].toNewHampshireX().equals( "((((A,B),C),D),';E;')" ) ) { return false; } if ( p28.length != 4 ) { return false; } final String p29_S = "((((A:0.01,B:0.684)ab:0.345,C:0.3451)abc:0.3451,D:1.5)abcd:0.134,E:0.32)abcde:0.1345"; final Phylogeny[] p29 = factory.create( p29_S, new NHXParser() ); if ( !p29[ 0 ].toNewHampshireX().equals( p29_S ) ) { return false; } final String p30_S = "((((A:0.01,B:0.02):0.93,C:0.04):0.05,D:1.4):0.06,E):0.72"; final Phylogeny[] p30 = factory.create( p30_S, new NHXParser() ); if ( !p30[ 0 ].toNewHampshireX().equals( p30_S ) ) { return false; } final String p32_S = " ; ; \n \t \b \f \r ;;;;;; "; final Phylogeny[] p32 = factory.create( p32_S, new NHXParser() ); if ( ( p32.length != 0 ) ) { return false; } final String p33_S = "A"; final Phylogeny[] p33 = factory.create( p33_S, new NHXParser() ); if ( !p33[ 0 ].toNewHampshireX().equals( p33_S ) ) { return false; } final String p34_S = "B;"; final Phylogeny[] p34 = factory.create( p34_S, new NHXParser() ); if ( !p34[ 0 ].toNewHampshireX().equals( "B" ) ) { return false; } final String p35_S = "B:0.2"; final Phylogeny[] p35 = factory.create( p35_S, new NHXParser() ); if ( !p35[ 0 ].toNewHampshireX().equals( p35_S ) ) { return false; } final String p36_S = "(A)"; final Phylogeny[] p36 = factory.create( p36_S, new NHXParser() ); if ( !p36[ 0 ].toNewHampshireX().equals( p36_S ) ) { return false; } final String p37_S = "((A))"; final Phylogeny[] p37 = factory.create( p37_S, new NHXParser() ); if ( !p37[ 0 ].toNewHampshireX().equals( p37_S ) ) { return false; } final String p38_S = "(((((((A:0.2):0.2):0.3):0.4):0.5):0.6):0.7):0.8"; final Phylogeny[] p38 = factory.create( p38_S, new NHXParser() ); if ( !p38[ 0 ].toNewHampshireX().equals( p38_S ) ) { return false; } final String p39_S = "(((B,((((A:0.2):0.2):0.3):0.4):0.5):0.6):0.7):0.8"; final Phylogeny[] p39 = factory.create( p39_S, new NHXParser() ); if ( !p39[ 0 ].toNewHampshireX().equals( p39_S ) ) { return false; } final String p40_S = "(A,B,C)"; final Phylogeny[] p40 = factory.create( p40_S, new NHXParser() ); if ( !p40[ 0 ].toNewHampshireX().equals( p40_S ) ) { return false; } final String p41_S = "(A,B,C,D,E,F,G,H,I,J,K)"; final Phylogeny[] p41 = factory.create( p41_S, new NHXParser() ); if ( !p41[ 0 ].toNewHampshireX().equals( p41_S ) ) { return false; } final String p42_S = "(A,B,(X,Y,Z),D,E,F,G,H,I,J,K)"; final Phylogeny[] p42 = factory.create( p42_S, new NHXParser() ); if ( !p42[ 0 ].toNewHampshireX().equals( p42_S ) ) { return false; } final String p43_S = "(A,B,C,(AA,BB,CC,(CCC,DDD,EEE,(FFFF,GGGG)x)y,DD,EE,FF,GG,HH),D,E,(EE,FF),F,G,H,(((((5)4)3)2)1),I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,(XX,(YY)),Y,Z)"; final Phylogeny[] p43 = factory.create( p43_S, new NHXParser() ); if ( !p43[ 0 ].toNewHampshireX().equals( p43_S ) ) { return false; } final String p44_S = "(((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)))"; final Phylogeny[] p44 = factory.create( p44_S, new NHXParser() ); if ( !p44[ 0 ].toNewHampshireX().equals( p44_S ) ) { return false; } final String p45_S = "((((((((((A))))))))),(((((((((B))))))))),(((((((((C))))))))))"; final Phylogeny[] p45 = factory.create( p45_S, new NHXParser() ); if ( !p45[ 0 ].toNewHampshireX().equals( p45_S ) ) { return false; } final String p46_S = ""; final Phylogeny[] p46 = factory.create( p46_S, new NHXParser() ); if ( p46.length != 0 ) { return false; } final Phylogeny p47 = factory.create( new StringBuffer( "((A,B)ab:2[0.44],C)" ).toString(), new NHXParser() )[ 0 ]; if ( !isEqual( 0.44, p47.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p48 = factory.create( new StringBuffer( "((A,B)ab:2[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( !isEqual( 88, p48.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p49 = factory .create( new StringBuffer( "((A,B)a[comment:a,b;(a)]b:2[0.44][comment(a,b,b);],C)" ).toString(), new NHXParser() )[ 0 ]; if ( !isEqual( 0.44, p49.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p50 = factory.create( new StringBuffer( "((\"A\",B)ab:2[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( p50.getNode( "A" ) == null ) { return false; } if ( !p50.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ) .equals( "((A,B)ab:2.0[88],C);" ) ) { return false; } if ( !p50.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.NONE ).equals( "((A,B)ab:2.0,C);" ) ) { return false; } if ( !p50.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.AS_INTERNAL_NODE_NAMES ) .equals( "((A,B)88:2.0,C);" ) ) { return false; } final Phylogeny p51 = factory.create( new StringBuffer( "((\"A(A\",B)ab:2[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( p51.getNode( "A(A" ) == null ) { return false; } final Phylogeny p52 = factory.create( new StringBuffer( "(('A(A',B)ab:2[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( p52.getNode( "A(A" ) == null ) { return false; } final Phylogeny p53 = factory .create( new StringBuffer( "(('A(A',\"B (x (a' ,b) f(x);\"[com])[ment]ab:2[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( p53.getNode( "B (x (a' ,b) f(x);" ) == null ) { return false; } final Phylogeny p54 = factory.create( new StringBuffer( "((A,B):[88],C)" ).toString(), new NHXParser() )[ 0 ]; if ( p54.getNode( "A" ) == null ) { return false; } if ( !p54.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ) .equals( "((A,B)[88],C);" ) ) { return false; } final Phylogeny p55 = factory .create( new StringBuffer( "((\"lcl|HPV32_L1.:1 s\":0.195593,\"lcl|HPV30_L1.1|;a\":0.114237):0.0359322,\"lcl|HPV56_L1.1|,d\":0.0727412,\"lcl|HPV66_L1.1x\":0.0798012);" ) .toString(), new NHXParser() )[ 0 ]; if ( !p55.toNewHampshire() .equals( "(('lcl|HPV32_L1.:1 s':0.195593,'lcl|HPV30_L1.1|;a':0.114237):0.0359322,'lcl|HPV56_L1.1|,d':0.0727412,lcl|HPV66_L1.1x:0.0798012);" ) ) { System.out.println( p55.toNewHampshire() ); return false; } final Phylogeny p56 = factory .create( new StringBuffer( "((\"lcl|HPV32_L1.:1 s\":0.195593,\"lcl|HPV30_L1.1|;a\":0.114\n237):0.0359322,\"lcl|HPV56_L1.1|,d\":0.0727412,\"lcl|HPV66_L1.1:x\":0.0798012);" ) .toString(), new NHXParser() )[ 0 ]; if ( !p56.toNewHampshire() .equals( "(('lcl|HPV32_L1.:1 s':0.195593,'lcl|HPV30_L1.1|;a':0.114237):0.0359322,'lcl|HPV56_L1.1|,d':0.0727412,'lcl|HPV66_L1.1:x':0.0798012);" ) ) { System.out.println( p56.toNewHampshire() ); return false; } final Phylogeny p57 = factory .create( new StringBuffer( "((\"lcl|HPV32_L1.:1 s\":0.195593,\"lcl|HPV30_L1.1|;a\":0.114\n237):0.0359322,\"lcl|HPV56_L1.1|,d\":0.0727412,\"lcl|HPV66_L1.1:x\":0.0798012);" ) .toString(), new NHXParser() )[ 0 ]; if ( !p57.toNewHampshire() .equals( "(('lcl|HPV32_L1.:1 s':0.195593,'lcl|HPV30_L1.1|;a':0.114237):0.0359322,'lcl|HPV56_L1.1|,d':0.0727412,'lcl|HPV66_L1.1:x':0.0798012);" ) ) { System.out.println( p56.toNewHampshire() ); return false; } final String s58 = "('Homo \"man\" sapiens:1',\"Homo 'man' sapiens;\")';root \"1_ )';"; final Phylogeny p58 = factory.create( s58, new NHXParser() )[ 0 ]; if ( !p58.toNewHampshire().equals( s58 ) ) { System.out.println( p58.toNewHampshire() ); return false; } final String s59 = "('Homo \"man sapiens:1',\"Homo 'man sapiens\")\"root; '1_ )\";"; final Phylogeny p59 = factory.create( s59, new NHXParser() )[ 0 ]; if ( !p59.toNewHampshire().equals( s59 ) ) { System.out.println( p59.toNewHampshire() ); return false; } final String s60 = "('\" ;,:\":\"',\"'abc def' g's_\",'=:0.45+,.:%~`!@#$%^&*()_-+={} | ;,');"; final Phylogeny p60 = factory.create( s60, new NHXParser() )[ 0 ]; if ( !p60.toNewHampshire().equals( s60 ) ) { System.out.println( p60.toNewHampshire() ); return false; } final String s61 = "('H[omo] \"man\" sapiens:1',\"H[omo] 'man' sapiens;\",H[omo] sapiens)';root \"1_ )';"; final Phylogeny p61 = factory.create( s61, new NHXParser() )[ 0 ]; if ( !p61.toNewHampshire() .equals( "('H{omo} \"man\" sapiens:1',\"H{omo} 'man' sapiens;\",Hsapiens)';root \"1_ )';" ) ) { System.out.println( p61.toNewHampshire() ); return false; } final String s62 = "(1[&type=\"X\",size=123,subtree=(1,2);]:0.003,2[&type=\"(X,Y:3)\"]:0.004)[&type=\"(X,Y)\"]:0.0;"; final Phylogeny p62 = factory.create( s62, new NHXParser() )[ 0 ]; if ( !p62.toNewHampshire().equals( "(1:0.003,2:0.004):0.0;" ) ) { System.out.println( p62.toNewHampshire() ); return false; } final String s63 = "(1:0.003[&type=\"X\",size=123,subtree=(1,2);],2:0.004[&type=\"(X,Y:3)\"]):0.0[&type=\"(X,Y)\"];"; final Phylogeny p63 = factory.create( s63, new NHXParser() )[ 0 ]; if ( !p63.toNewHampshire().equals( "(1:0.003,2:0.004):0.0;" ) ) { System.out.println( p63.toNewHampshire() ); return false; } final String s64 = "((1,2):[95.5],3);"; final Phylogeny p64 = factory.create( s64, new NHXParser() )[ 0 ]; if ( !p64.toNewHampshireX().equals( "((1,2)[&&NHX:B=95.5],3)" ) ) { System.out.println( p64.toNewHampshireX() ); return false; } final String s65 = "((1:0.1,2:0.2):0.3[10.2],3);"; final Phylogeny p65 = factory.create( s65, new NHXParser() )[ 0 ]; if ( !p65.toNewHampshireX().equals( "((1:0.1,2:0.2):0.3[&&NHX:B=10.2],3)" ) ) { System.out.println( p65.toNewHampshireX() ); return false; } final Phylogeny p66 = factory.create( "((A,B)ab:2[0.44],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0.44, p66.getNode( "ab" ).getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p67 = factory.create( "((A,B):2[0.67],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0.67, p67.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p68 = factory.create( "((A,B):[0.68],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0.68, p68.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p69 = factory.create( "((A,B)[0.69],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0.69, p69.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p70 = factory.create( "((A,B)[+0.7],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0.7, p70.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p71 = factory.create( "((A,B)[-0.71],C)", new NHXParser() )[ 0 ]; if ( !isEqual( -0.71, p71.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p72 = factory.create( "((A,B)[],C)", new NHXParser() )[ 0 ]; if ( !p72.toNewHampshireX().equals( "((A,B),C)" ) ) { return false; } final Phylogeny p73 = factory.create( "((A,B)[12x],C)", new NHXParser() )[ 0 ]; if ( !p73.toNewHampshireX().equals( "((A,B),C)" ) ) { return false; } final Phylogeny p74 = factory.create( "((A,B)[12+],C)", new NHXParser() )[ 0 ]; if ( !p74.toNewHampshireX().equals( "((A,B),C)" ) ) { return false; } final Phylogeny p75 = factory.create( "((A,B)ab[222]:3,C)", new NHXParser() )[ 0 ]; if ( !isEqual( 222, p75.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p76 = factory.create( "((A,B)[100]:12,C)", new NHXParser() )[ 0 ]; if ( !isEqual( 100, p76.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p77 = factory.create( "((A,B)abcde:13[77],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 77, p77.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final Phylogeny p78 = factory.create( "((A,B):14[0],C)", new NHXParser() )[ 0 ]; if ( !isEqual( 0, p78.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() ) ) { return false; } final String the_one = "((((((a,b)ab:3.0[2],c):12.0[100],(d,e)de)abcde:13.0[2],f):14.0[0]):0.0[0]):0.0[0];"; final Phylogeny p79 = factory.create( "((((((a,b)ab[2]:3,c)[100]:12,(d,e)de)abcde:13[2],f):14[0]):0[0])[0]:0;", new NHXParser() )[ 0 ]; final String str79 = p79.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ); if ( !str79.equals( the_one ) ) { System.out.println( str79 ); return false; } final Phylogeny p80 = factory.create( "((((((a[a)],b[12])ab[2]:3,c)[+100]:12,(d,e)de[12d,)])ab[]c[]de:13[2],f):14[0]):0[0])[0]:0;", new NHXParser() )[ 0 ]; final String str80 = p80.toNewHampshire( NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ); if ( !str80.equals( the_one ) ) { System.out.println( str80 ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHParsingSpecialChars() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final String i0 = "(A!+=~QWERTY!@#$%^&*-,€‚ƒ„…†‡ˆ‰Š‹ŒŽ‘’“”•–—˜˜˜™š›œžŸ¡¢£¤¥¦§¨©ª«¬®¯°±¹²³´µ¶·¸º»¼¿À÷þÿ)"; final Phylogeny p0 = factory.create( i0, new NHXParser() )[ 0 ]; if ( !p0.toNewHampshireX().equals( i0 ) ) { System.out.println(); System.out.println( p0.toNewHampshireX() ); System.out.println( i0 ); return false; } final String i1 = "(हिंदी,한글,ไทย,'Tiếng Việt',ひらがなカタカナ漢字,繁體字,русский)"; final Phylogeny p1 = factory.create( i1, new NHXParser() )[ 0 ]; if ( !p1.toNewHampshireX().equals( i1 ) ) { System.out.println(); System.out.println( p1.toNewHampshireX() ); System.out.println( i1 ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHParsingIter() { try { final String p0_str = "(A,B);"; final NHXParser p = new NHXParser(); p.setSource( p0_str ); if ( !p.hasNext() ) { return false; } final Phylogeny p0 = p.next(); if ( !p0.toNewHampshire().equals( p0_str ) ) { System.out.println( p0.toNewHampshire() ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p00_str = "(A,B)root;"; p.setSource( p00_str ); final Phylogeny p00 = p.next(); if ( !p00.toNewHampshire().equals( p00_str ) ) { System.out.println( p00.toNewHampshire() ); return false; } // final String p000_str = "A;"; p.setSource( p000_str ); final Phylogeny p000 = p.next(); if ( !p000.toNewHampshire().equals( p000_str ) ) { System.out.println( p000.toNewHampshire() ); return false; } // final String p0000_str = "A"; p.setSource( p0000_str ); final Phylogeny p0000 = p.next(); if ( !p0000.toNewHampshire().equals( "A;" ) ) { System.out.println( p0000.toNewHampshire() ); return false; } // p.setSource( "(A)" ); final Phylogeny p00000 = p.next(); if ( !p00000.toNewHampshire().equals( "(A);" ) ) { System.out.println( p00000.toNewHampshire() ); return false; } // final String p1_str = "(A,B)(C,D)(E,F)(G,H)"; p.setSource( p1_str ); if ( !p.hasNext() ) { return false; } final Phylogeny p1_0 = p.next(); if ( !p1_0.toNewHampshire().equals( "(A,B);" ) ) { System.out.println( p1_0.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } final Phylogeny p1_1 = p.next(); if ( !p1_1.toNewHampshire().equals( "(C,D);" ) ) { System.out.println( "(C,D) != " + p1_1.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } final Phylogeny p1_2 = p.next(); if ( !p1_2.toNewHampshire().equals( "(E,F);" ) ) { System.out.println( "(E,F) != " + p1_2.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } final Phylogeny p1_3 = p.next(); if ( !p1_3.toNewHampshire().equals( "(G,H);" ) ) { System.out.println( "(G,H) != " + p1_3.toNewHampshire() ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p2_str = "((1,2,3),B);(C,D) (E,F)root;(G,H); ;(X)"; p.setSource( p2_str ); if ( !p.hasNext() ) { return false; } Phylogeny p2_0 = p.next(); if ( !p2_0.toNewHampshire().equals( "((1,2,3),B);" ) ) { System.out.println( p2_0.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } Phylogeny p2_1 = p.next(); if ( !p2_1.toNewHampshire().equals( "(C,D);" ) ) { System.out.println( "(C,D) != " + p2_1.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } Phylogeny p2_2 = p.next(); if ( !p2_2.toNewHampshire().equals( "(E,F)root;" ) ) { System.out.println( "(E,F)root != " + p2_2.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } Phylogeny p2_3 = p.next(); if ( !p2_3.toNewHampshire().equals( "(G,H);" ) ) { System.out.println( "(G,H) != " + p2_3.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } Phylogeny p2_4 = p.next(); if ( !p2_4.toNewHampshire().equals( "(X);" ) ) { System.out.println( "(X) != " + p2_4.toNewHampshire() ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } //// p.reset(); if ( !p.hasNext() ) { return false; } p2_0 = p.next(); if ( !p2_0.toNewHampshire().equals( "((1,2,3),B);" ) ) { System.out.println( p2_0.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } p2_1 = p.next(); if ( !p2_1.toNewHampshire().equals( "(C,D);" ) ) { System.out.println( "(C,D) != " + p2_1.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } p2_2 = p.next(); if ( !p2_2.toNewHampshire().equals( "(E,F)root;" ) ) { System.out.println( "(E,F)root != " + p2_2.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } p2_3 = p.next(); if ( !p2_3.toNewHampshire().equals( "(G,H);" ) ) { System.out.println( "(G,H) != " + p2_3.toNewHampshire() ); return false; } if ( !p.hasNext() ) { return false; } p2_4 = p.next(); if ( !p2_4.toNewHampshire().equals( "(X);" ) ) { System.out.println( "(X) != " + p2_4.toNewHampshire() ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p3_str = "((A,B),C)abc"; p.setSource( p3_str ); if ( !p.hasNext() ) { return false; } final Phylogeny p3_0 = p.next(); if ( !p3_0.toNewHampshire().equals( "((A,B),C)abc;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p4_str = "((A,B)ab,C)abc"; p.setSource( p4_str ); if ( !p.hasNext() ) { return false; } final Phylogeny p4_0 = p.next(); if ( !p4_0.toNewHampshire().equals( "((A,B)ab,C)abc;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p5_str = "(((A,B)ab,C)abc,D)abcd"; p.setSource( p5_str ); if ( !p.hasNext() ) { return false; } final Phylogeny p5_0 = p.next(); if ( !p5_0.toNewHampshire().equals( "(((A,B)ab,C)abc,D)abcd;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p6_str = "(A,(B,(C,(D,E)de)cde)bcde)abcde"; p.setSource( p6_str ); if ( !p.hasNext() ) { return false; } Phylogeny p6_0 = p.next(); if ( !p6_0.toNewHampshire().equals( "(A,(B,(C,(D,E)de)cde)bcde)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } p6_0 = p.next(); if ( !p6_0.toNewHampshire().equals( "(A,(B,(C,(D,E)de)cde)bcde)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p7_str = "((((A,B)ab,C)abc,D)abcd,E)abcde"; p.setSource( p7_str ); if ( !p.hasNext() ) { return false; } Phylogeny p7_0 = p.next(); if ( !p7_0.toNewHampshire().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } p7_0 = p.next(); if ( !p7_0.toNewHampshire().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p8_str = "((((A,B)ab,C)abc,D)abcd,E)abcde ((((a,b)ab,c)abc,d)abcd,e)abcde"; p.setSource( p8_str ); if ( !p.hasNext() ) { return false; } Phylogeny p8_0 = p.next(); if ( !p8_0.toNewHampshire().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde;" ) ) { return false; } if ( !p.hasNext() ) { return false; } if ( !p.hasNext() ) { return false; } Phylogeny p8_1 = p.next(); if ( !p8_1.toNewHampshire().equals( "((((a,b)ab,c)abc,d)abcd,e)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } p8_0 = p.next(); if ( !p8_0.toNewHampshire().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde;" ) ) { return false; } if ( !p.hasNext() ) { return false; } p8_1 = p.next(); if ( !p8_1.toNewHampshire().equals( "((((a,b)ab,c)abc,d)abcd,e)abcde;" ) ) { return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } p.reset(); // p.setSource( "" ); if ( p.hasNext() ) { return false; } // p.setSource( new File( Test.PATH_TO_TEST_DATA + "phylogeny27.nhx" ) ); if ( !p.hasNext() ) { return false; } Phylogeny p_27 = p.next(); if ( !p_27.toNewHampshireX().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde" ) ) { System.out.println( p_27.toNewHampshireX() ); System.exit( -1 ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } p.reset(); if ( !p.hasNext() ) { return false; } p_27 = p.next(); if ( !p_27.toNewHampshireX().equals( "((((A,B)ab,C)abc,D)abcd,E)abcde" ) ) { System.out.println( p_27.toNewHampshireX() ); System.exit( -1 ); return false; } if ( p.hasNext() ) { return false; } if ( p.next() != null ) { return false; } // final String p30_str = "(A,B);(C,D)"; final NHXParser p30 = new NHXParser(); p30.setSource( p30_str ); if ( !p30.hasNext() ) { return false; } Phylogeny phy30 = p30.next(); if ( !phy30.toNewHampshire().equals( "(A,B);" ) ) { System.out.println( phy30.toNewHampshire() ); return false; } if ( !p30.hasNext() ) { return false; } Phylogeny phy301 = p30.next(); if ( !phy301.toNewHampshire().equals( "(C,D);" ) ) { System.out.println( phy301.toNewHampshire() ); return false; } if ( p30.hasNext() ) { return false; } if ( p30.hasNext() ) { return false; } if ( p30.next() != null ) { return false; } if ( p30.next() != null ) { return false; } p30.reset(); if ( !p30.hasNext() ) { return false; } phy30 = p30.next(); if ( !phy30.toNewHampshire().equals( "(A,B);" ) ) { System.out.println( phy30.toNewHampshire() ); return false; } if ( !p30.hasNext() ) { return false; } phy301 = p30.next(); if ( !phy301.toNewHampshire().equals( "(C,D);" ) ) { System.out.println( phy301.toNewHampshire() ); return false; } if ( p30.hasNext() ) { return false; } if ( p30.hasNext() ) { return false; } if ( p30.next() != null ) { return false; } if ( p30.next() != null ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHXconversion() { try { final PhylogenyNode n1 = new PhylogenyNode(); final PhylogenyNode n2 = PhylogenyNode.createInstanceFromNhxString( "" ); final PhylogenyNode n3 = PhylogenyNode.createInstanceFromNhxString( "n3" ); final PhylogenyNode n4 = PhylogenyNode.createInstanceFromNhxString( "n4:0.01" ); final PhylogenyNode n5 = PhylogenyNode .createInstanceFromNhxString( "n5:0.1[&&NHX:S=Ecoli:E=1.1.1.1:D=Y:Co=Y:B=56:T=1]" ); final PhylogenyNode n6 = PhylogenyNode .createInstanceFromNhxString( "n6:0.000001[&&NHX:S=Ecoli:E=1.1.1.1:D=N:Co=N:B=100:T=1]" ); if ( !n1.toNewHampshireX().equals( "" ) ) { return false; } if ( !n2.toNewHampshireX().equals( "" ) ) { return false; } if ( !n3.toNewHampshireX().equals( "n3" ) ) { return false; } if ( !n4.toNewHampshireX().equals( "n4:0.01" ) ) { return false; } if ( !n5.toNewHampshireX().equals( "n5:0.1[&&NHX:T=1:S=Ecoli:D=Y:B=56]" ) ) { return false; } if ( !n6.toNewHampshireX().equals( "n6:1.0E-6[&&NHX:T=1:S=Ecoli:D=N:B=100]" ) ) { System.out.println( n6.toNewHampshireX() ); return false; } final PhylogenyNode n7 = new PhylogenyNode(); n7.setName( " gks:dr-m4 \" ' `@:[]sadq04 " ); if ( !n7.toNewHampshire( true, PhylogenyNode.NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ) .equals( "'gks:dr-m4 \" ` `@:[]sadq04'" ) ) { System.out.println( n7 .toNewHampshire( true, PhylogenyNode.NH_CONVERSION_SUPPORT_VALUE_STYLE.IN_SQUARE_BRACKETS ) ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHXNodeParsing() { try { final PhylogenyNode n1 = new PhylogenyNode(); final PhylogenyNode n2 = PhylogenyNode.createInstanceFromNhxString( "" ); final PhylogenyNode n3 = PhylogenyNode.createInstanceFromNhxString( "n3" ); final PhylogenyNode n4 = PhylogenyNode.createInstanceFromNhxString( "n4:0.01" ); final PhylogenyNode n5 = PhylogenyNode .createInstanceFromNhxString( "n5:0.1[&&NHX:S=Ecoli:E=1.1.1.1:D=Y:B=56:T=1:On=22:SOn=33:SNn=44:W=2:C=10.20.30:XN=S=tag1=value1=unit1:XN=S=tag3=value3=unit3]" ); if ( !n3.getName().equals( "n3" ) ) { return false; } if ( n3.getDistanceToParent() != PhylogenyDataUtil.BRANCH_LENGTH_DEFAULT ) { return false; } if ( n3.isDuplication() ) { return false; } if ( n3.isHasAssignedEvent() ) { return false; } if ( PhylogenyMethods.getBranchWidthValue( n3 ) != BranchWidth.BRANCH_WIDTH_DEFAULT_VALUE ) { return false; } if ( !n4.getName().equals( "n4" ) ) { return false; } if ( n4.getDistanceToParent() != 0.01 ) { return false; } if ( !n5.getName().equals( "n5" ) ) { return false; } if ( PhylogenyMethods.getConfidenceValue( n5 ) != 56 ) { return false; } if ( n5.getDistanceToParent() != 0.1 ) { return false; } if ( !PhylogenyMethods.getSpecies( n5 ).equals( "Ecoli" ) ) { return false; } if ( !n5.isDuplication() ) { return false; } if ( !n5.isHasAssignedEvent() ) { return false; } final PhylogenyNode n8 = PhylogenyNode .createInstanceFromNhxString( "ABCD_ECOLI/1-2:0.01", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n8.getName().equals( "ABCD_ECOLI/1-2" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n8 ).equals( "ECOLI" ) ) { return false; } final PhylogenyNode n9 = PhylogenyNode .createInstanceFromNhxString( "ABCD_ECOLI/1-12:0.01", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n9.getName().equals( "ABCD_ECOLI/1-12" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n9 ).equals( "ECOLI" ) ) { return false; } final PhylogenyNode n10 = PhylogenyNode .createInstanceFromNhxString( "n10.ECOLI", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n10.getName().equals( "n10.ECOLI" ) ) { return false; } final PhylogenyNode n20 = PhylogenyNode .createInstanceFromNhxString( "ABCD_ECOLI/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n20.getName().equals( "ABCD_ECOLI/1-2" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n20 ).equals( "ECOLI" ) ) { return false; } final PhylogenyNode n20x = PhylogenyNode .createInstanceFromNhxString( "N20_ECOL1/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n20x.getName().equals( "N20_ECOL1/1-2" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n20x ).equals( "ECOL1" ) ) { return false; } final PhylogenyNode n20xx = PhylogenyNode .createInstanceFromNhxString( "N20_eCOL1/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n20xx.getName().equals( "N20_eCOL1/1-2" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n20xx ).length() > 0 ) { return false; } final PhylogenyNode n20xxx = PhylogenyNode .createInstanceFromNhxString( "n20_ecoli/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n20xxx.getName().equals( "n20_ecoli/1-2" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n20xxx ).length() > 0 ) { return false; } final PhylogenyNode n20xxxx = PhylogenyNode .createInstanceFromNhxString( "n20_Ecoli/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n20xxxx.getName().equals( "n20_Ecoli/1-2" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n20xxxx ).length() > 0 ) { return false; } final PhylogenyNode n21 = PhylogenyNode .createInstanceFromNhxString( "N21_PIG", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n21.getName().equals( "N21_PIG" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n21 ).equals( "PIG" ) ) { return false; } final PhylogenyNode n21x = PhylogenyNode .createInstanceFromNhxString( "n21_PIG", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n21x.getName().equals( "n21_PIG" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n21x ).length() > 0 ) { return false; } final PhylogenyNode n22 = PhylogenyNode .createInstanceFromNhxString( "n22/PIG", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n22.getName().equals( "n22/PIG" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n22 ).length() > 0 ) { return false; } final PhylogenyNode n23 = PhylogenyNode .createInstanceFromNhxString( "n23/PIG_1", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n23.getName().equals( "n23/PIG_1" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n23 ).length() > 0 ) { return false; } final PhylogenyNode a = PhylogenyNode .createInstanceFromNhxString( "ABCD_ECOLI/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !a.getName().equals( "ABCD_ECOLI/1-2" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( a ).equals( "ECOLI" ) ) { return false; } final PhylogenyNode c1 = PhylogenyNode .createInstanceFromNhxString( "n10_BOVIN/1000-2000", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !c1.getName().equals( "n10_BOVIN/1000-2000" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( c1 ).equals( "BOVIN" ) ) { return false; } final PhylogenyNode c2 = PhylogenyNode .createInstanceFromNhxString( "N10_Bovin_1/1000-2000", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !c2.getName().equals( "N10_Bovin_1/1000-2000" ) ) { return false; } if ( PhylogenyMethods.getSpecies( c2 ).length() > 0 ) { return false; } final PhylogenyNode e3 = PhylogenyNode .createInstanceFromNhxString( "n10_RAT~", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !e3.getName().equals( "n10_RAT~" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( e3 ).equals( "RAT" ) ) { return false; } final PhylogenyNode n11 = PhylogenyNode .createInstanceFromNhxString( "N111111_ECOLI/1-2:0.4", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n11.getName().equals( "N111111_ECOLI/1-2" ) ) { return false; } if ( n11.getDistanceToParent() != 0.4 ) { return false; } if ( !PhylogenyMethods.getSpecies( n11 ).equals( "ECOLI" ) ) { return false; } final PhylogenyNode n12 = PhylogenyNode .createInstanceFromNhxString( "N111111-ECOLI---/jdj:0.4", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n12.getName().equals( "N111111-ECOLI---/jdj" ) ) { return false; } if ( n12.getDistanceToParent() != 0.4 ) { return false; } if ( PhylogenyMethods.getSpecies( n12 ).length() > 0 ) { return false; } final PhylogenyNode o = PhylogenyNode .createInstanceFromNhxString( "ABCD_MOUSE", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !o.getName().equals( "ABCD_MOUSE" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( o ).equals( "MOUSE" ) ) { return false; } if ( n1.getName().compareTo( "" ) != 0 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( n1 ) != Confidence.CONFIDENCE_DEFAULT_VALUE ) { return false; } if ( n1.getDistanceToParent() != PhylogenyDataUtil.BRANCH_LENGTH_DEFAULT ) { return false; } if ( n2.getName().compareTo( "" ) != 0 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( n2 ) != Confidence.CONFIDENCE_DEFAULT_VALUE ) { return false; } if ( n2.getDistanceToParent() != PhylogenyDataUtil.BRANCH_LENGTH_DEFAULT ) { return false; } final PhylogenyNode n00 = PhylogenyNode .createInstanceFromNhxString( "n7:0.000001[&&NHX:GN=gene_name:AC=accession123:S=Ecoli:D=N:Co=N:B=100:T=1]" ); if ( !n00.getNodeData().getSequence().getName().equals( "gene_name" ) ) { return false; } if ( !n00.getNodeData().getSequence().getAccession().getValue().equals( "accession123" ) ) { return false; } final PhylogenyNode nx = PhylogenyNode.createInstanceFromNhxString( "n5:0.1[&&NHX:S=Ecoli:GN=gene_1]" ); if ( !nx.getNodeData().getSequence().getName().equals( "gene_1" ) ) { return false; } final PhylogenyNode n13 = PhylogenyNode .createInstanceFromNhxString( "BLAH_12345/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n13.getName().equals( "BLAH_12345/1-2" ) ) { return false; } if ( PhylogenyMethods.getSpecies( n13 ).equals( "12345" ) ) { return false; } if ( !n13.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "12345" ) ) { return false; } if ( !n13.getNodeData().getTaxonomy().getIdentifier().getProvider().equals( "uniprot" ) ) { return false; } final PhylogenyNode n14 = PhylogenyNode .createInstanceFromNhxString( "BLA1_9QX45/1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n14.getName().equals( "BLA1_9QX45/1-2" ) ) { return false; } if ( !PhylogenyMethods.getSpecies( n14 ).equals( "9QX45" ) ) { return false; } final PhylogenyNode n15 = PhylogenyNode .createInstanceFromNhxString( "something_wicked[123]", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n15.getName().equals( "something_wicked" ) ) { return false; } if ( n15.getBranchData().getNumberOfConfidences() != 1 ) { return false; } if ( !isEqual( n15.getBranchData().getConfidence( 0 ).getValue(), 123 ) ) { return false; } final PhylogenyNode n16 = PhylogenyNode .createInstanceFromNhxString( "something_wicked2[9]", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n16.getName().equals( "something_wicked2" ) ) { return false; } if ( n16.getBranchData().getNumberOfConfidences() != 1 ) { return false; } if ( !isEqual( n16.getBranchData().getConfidence( 0 ).getValue(), 9 ) ) { return false; } final PhylogenyNode n17 = PhylogenyNode .createInstanceFromNhxString( "something_wicked3[a]", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !n17.getName().equals( "something_wicked3" ) ) { return false; } if ( n17.getBranchData().getNumberOfConfidences() != 0 ) { return false; } final PhylogenyNode n18 = PhylogenyNode .createInstanceFromNhxString( ":0.5[91]", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( !isEqual( n18.getDistanceToParent(), 0.5 ) ) { return false; } if ( n18.getBranchData().getNumberOfConfidences() != 1 ) { return false; } if ( !isEqual( n18.getBranchData().getConfidence( 0 ).getValue(), 91 ) ) { return false; } final PhylogenyNode n19 = PhylogenyNode .createInstanceFromNhxString( "BLAH_1-roejojoej", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n19.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "1" ) ) { return false; } if ( !n19.getNodeData().getTaxonomy().getIdentifier().getProvider().equals( "uniprot" ) ) { return false; } final PhylogenyNode n30 = PhylogenyNode .createInstanceFromNhxString( "BLAH_1234567-roejojoej", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n30.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "1234567" ) ) { return false; } if ( !n30.getNodeData().getTaxonomy().getIdentifier().getProvider().equals( "uniprot" ) ) { return false; } final PhylogenyNode n31 = PhylogenyNode .createInstanceFromNhxString( "BLAH_12345678-roejojoej", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n31.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n32 = PhylogenyNode .createInstanceFromNhxString( "sd_12345678", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n32.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n40 = PhylogenyNode .createInstanceFromNhxString( "BCL2_12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n40.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "12345" ) ) { return false; } final PhylogenyNode n41 = PhylogenyNode .createInstanceFromNhxString( "12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n41.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n42 = PhylogenyNode .createInstanceFromNhxString( "12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_STRICT ); if ( n42.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n43 = PhylogenyNode.createInstanceFromNhxString( "12345", NHXParser.TAXONOMY_EXTRACTION.NO ); if ( n43.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n44 = PhylogenyNode .createInstanceFromNhxString( "12345~1-2", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n44.getNodeData().isHasTaxonomy() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHXNodeParsing2() { try { final PhylogenyNode n0_0 = PhylogenyNode.createInstanceFromNhxString( "n0:[ignore me 123]:1E-3", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n0_0.getName().equals( "n0" ) ) { return false; } if ( !isEqual( n0_0.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n0_1 = PhylogenyNode.createInstanceFromNhxString( "n0[ignore me 123]:1E-3", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n0_1.getName().equals( "n0" ) ) { return false; } if ( !isEqual( n0_1.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n0_2 = PhylogenyNode.createInstanceFromNhxString( "n0:1E-3[ignore me 123]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n0_2.getName().equals( "n0" ) ) { return false; } if ( !isEqual( n0_2.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n0_3 = PhylogenyNode.createInstanceFromNhxString( "n0:1E-3:[ignore me 123]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n0_3.getName().equals( "n0" ) ) { return false; } if ( !isEqual( n0_3.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n0_4 = PhylogenyNode.createInstanceFromNhxString( "n0:0.001:[ignore me 123]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n0_4.getName().equals( "n0" ) ) { return false; } if ( !isEqual( n0_4.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n1_0 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada[&!color=#FFFFFF]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_0.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( n1_0.getBranchData().getBranchColor().getValue().getGreen() != 255 ) { return false; } final PhylogenyNode n1_1 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada[&!color=#FFFFFF]:0.001", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_1.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( n1_1.getBranchData().getBranchColor().getValue().getGreen() != 255 ) { return false; } if ( !isEqual( n1_1.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n1_2 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada:0.001[&!color=#FFFFFF]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_2.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( n1_2.getBranchData().getBranchColor().getValue().getGreen() != 255 ) { return false; } if ( !isEqual( n1_2.getDistanceToParent(), 0.001 ) ) { return false; } final PhylogenyNode n1_3 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada:1e-3[&boostrap=69,&!color=#FFFFFF]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_3.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( n1_3.getBranchData().getBranchColor().getValue().getGreen() != 255 ) { return false; } if ( !isEqual( n1_3.getDistanceToParent(), 0.001 ) ) { return false; } if ( !isEqual( n1_3.getBranchData().getConfidence( 0 ).getValue(), 69 ) ) { return false; } if ( !n1_3.getBranchData().getConfidence( 0 ).getType().equals( "bootstrap" ) ) { return false; } final PhylogenyNode n1_4 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada[&bootstrap=69,&!colour=#FFFFFF]:1e-3", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_4.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( n1_4.getBranchData().getBranchColor().getValue().getGreen() != 255 ) { return false; } if ( !isEqual( n1_4.getDistanceToParent(), 0.001 ) ) { return false; } if ( !isEqual( n1_4.getBranchData().getConfidence( 0 ).getValue(), 69 ) ) { return false; } if ( !n1_4.getBranchData().getConfidence( 0 ).getType().equals( "bootstrap" ) ) { return false; } final PhylogenyNode n1_5 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada:1e-3[69.0]", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_5.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( !isEqual( n1_5.getDistanceToParent(), 0.001 ) ) { return false; } if ( !isEqual( n1_5.getBranchData().getConfidence( 0 ).getValue(), 69 ) ) { return false; } final PhylogenyNode n1_6 = PhylogenyNode .createInstanceFromNhxString( "xyz|A/American_duck/NH/00321/|Duck|Canada[&prob=0.9500000000000000e+00,prob_stddev=0.1100000000000000e+00]:1e-3", NHXParser.TAXONOMY_EXTRACTION.NO, true, true ); if ( !n1_6.getName().equals( "xyz|A/American duck/NH/00321/|Duck|Canada" ) ) { return false; } if ( !isEqual( n1_6.getDistanceToParent(), 0.001 ) ) { return false; } if ( !isEqual( n1_6.getBranchData().getConfidence( 0 ).getStandardDeviation(), 0.11 ) ) { return false; } if ( !isEqual( n1_6.getBranchData().getConfidence( 0 ).getValue(), 0.95 ) ) { return false; } if ( !n1_6.getBranchData().getConfidence( 0 ).getType().equals( "posterior probability" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHXParsing() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "(A [&&NHX:S=a_species],B1[&&NHX:S=b_species])", new NHXParser() )[ 0 ]; if ( !p1.toNewHampshireX().equals( "(A[&&NHX:S=a_species],B1[&&NHX:S=b_species])" ) ) { return false; } final String p2_S = "(((((((A:0.2[&&NHX:S=qwerty]):0.2[&&NHX:S=uiop]):0.3[&&NHX:S=asdf]):0.4[&&NHX:S=zxc]):0.5[&&NHX:S=a]):0.6[&&NHX:S=asd]):0.7[&&NHX:S=za]):0.8[&&NHX:S=zaq]"; final Phylogeny[] p2 = factory.create( p2_S, new NHXParser() ); if ( !p2[ 0 ].toNewHampshireX().equals( p2_S ) ) { return false; } final String p2b_S = "(((((((A:0.2[&NHX:S=qw,erty]):0.2[&:S=u(io)p]):0.3[&NHX:S=asdf]):0.4[S=zxc]):0.5[]):0.6[&&NH:S=asd]):0.7[&&HX:S=za]):0.8[&&:S=zaq]"; final Phylogeny[] p2b = factory.create( p2b_S, new NHXParser() ); if ( !p2b[ 0 ].toNewHampshireX().equals( "(((((((A:0.2):0.2):0.3):0.4):0.5):0.6):0.7):0.8" ) ) { return false; } final Phylogeny[] p3 = factory.create( "[ comment&&NHX,())))](((((((A:0.2[&&NHX:S=qwerty]):0.2[&&NHX:S=uiop]):0.3[&&NHX:S=asdf]):0.4[&&NHX:S=zxc]):0.5[&&NHX:S=a]):0.6[&&NHX:S=asd]):0.7[&&NHX:S=za]):0.8[&&NHX:S=zaq]", new NHXParser() ); if ( !p3[ 0 ].toNewHampshireX().equals( p2_S ) ) { return false; } final Phylogeny[] p4 = factory.create( "(((((((A:0.2[&&NHX:S=qwerty]):0.2[&&NHX:S=uiop]):0.3[&&NHX:S=asdf]):0.4[&&NHX:S=zxc]):0.5[&&NHX:S=a]):0.6[&&NHX:S=asd]):0.7[&&NHX:S=za]):0.8[&&NHX:S=zaq][comment(]", new NHXParser() ); if ( !p4[ 0 ].toNewHampshireX().equals( p2_S ) ) { return false; } final Phylogeny[] p5 = factory.create( "[] ( [][ ][ ] ([((( &&NHXcomment only![[[[[[]([]((((A:0.2[&&NHX:S=q[comment )))]werty][,,,,))]):0.2[&&NHX:S=uiop]):0.3[&&NHX:S=a[comment,,))]sdf])[comment(((]:0.4[&&NHX:S=zxc][comment(((][comment(((]):0.5[&&NHX:S=a]):0.6[&&NHX:S=a[comment(((]sd]):0.7[&&NHX:S=za]):0.8[&&NHX:S=zaq][comment(((]", new NHXParser() ); if ( !p5[ 0 ].toNewHampshireX().equals( p2_S ) ) { return false; } final String p6_S_C = "(A[][][][1][22][333][4444][55555][666666][&&NHX:S=Aspecies],B[))],C,(AA,BB,CC,(CCC,DDD,EEE,[comment](FFFF,GGGG)x)y,D[comment]D,EE,FF,GG,HH),D,E,(EE,FF),F,G,H,(((((5)4)3)2)1),I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,(XX,(YY)),Y,Z)"; final String p6_S_WO_C = "(A[&&NHX:S=Aspecies],B,C,(AA,BB,CC,(CCC,DDD,EEE,(FFFF,GGGG)x)y,DD,EE,FF,GG,HH),D,E,(EE,FF),F,G,H,(((((5)4)3)2)1),I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,(XX,(YY)),Y,Z)"; final Phylogeny[] p6 = factory.create( p6_S_C, new NHXParser() ); if ( !p6[ 0 ].toNewHampshireX().equals( p6_S_WO_C ) ) { return false; } final String p7_S_C = "(((A [&&NHX:S=species_a], B [&&NHX:S=Vstorri] , C , D),(A,B,C,D[comment])[],[c][]([xxx]A[comment],[comment]B[comment][comment],[comment][comment]C[comment][comment],[comment][comment]D[comment][comment])[comment][comment],[comment] [comment](A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C[comment][comment][comment][comment][comment] [comment],D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),[comment][comment]((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)))"; final String p7_S_WO_C = "(((A[&&NHX:S=species_a],B[&&NHX:S=Vstorri],C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)),((A,B,C,D),(A,B,C,D),(A,B,C,D),(A,B,C,D)))"; final Phylogeny[] p7 = factory.create( p7_S_C, new NHXParser() ); if ( !p7[ 0 ].toNewHampshireX().equals( p7_S_WO_C ) ) { return false; } final String p8_S_C = "[cmt](((([]([))))))](((((A[&&NHX:S= [a comment] a])))))))[too many comments!:)])),(((((((((B[&&NHX[ a comment in a bad place]:S =b])))))[] [] )))),(((((((((C[&&NHX:S=c]) ))[,,, ])))))))"; final String p8_S_WO_C = "((((((((((A[&&NHX:S=a]))))))))),(((((((((B[&&NHX:S=b]))))))))),(((((((((C[&&NHX:S=c]))))))))))"; final Phylogeny[] p8 = factory.create( p8_S_C, new NHXParser() ); if ( !p8[ 0 ].toNewHampshireX().equals( p8_S_WO_C ) ) { return false; } final Phylogeny p9 = factory.create( "((A:0.2,B:0.3):0.5[91],C:0.1)root:0.1[100]", new NHXParser() )[ 0 ]; if ( !p9.toNewHampshireX().equals( "((A:0.2,B:0.3):0.5[&&NHX:B=91],C:0.1)root:0.1[&&NHX:B=100]" ) ) { return false; } final Phylogeny p10 = factory.create( " [79] ( (A [co mment] :0 .2[comment],B:0.3[com])[com ment]: 0. 5 \t[ 9 1 ][ comment],C: 0.1)[comment]root:0.1[100] [comment]", new NHXParser() )[ 0 ]; if ( !p10.toNewHampshireX().equals( "((A:0.2,B:0.3):0.5[&&NHX:B=91],C:0.1)root:0.1[&&NHX:B=100]" ) ) { return false; } final Phylogeny p11 = factory.create( " [79] ( ('A: \" ' [co mment] :0 .2[comment],B:0.3[com])[com ment]: 0. 5 \t[ 9 1 ][ comment],C: 0.1)[comment]root:0.1[100] [comment]", new NHXParser() )[ 0 ]; if ( !p11.toNewHampshireX().equals( "(('A: \"':0.2,B:0.3):0.5[&&NHX:B=91],C:0.1)root:0.1[&&NHX:B=100]" ) ) { return false; } final Phylogeny p12 = factory.create( "((A:0.2,B:0.3):0.5[&&NHX:B=91],C:0.1)root:0.1[&&NHX:B=100]", new NHXParser() )[ 0 ]; if ( !p12.toNewHampshireX().equals( "((A:0.2,B:0.3):0.5[&&NHX:B=91],C:0.1)root:0.1[&&NHX:B=100]" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNHXParsingMB() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "(1[&prob=0.9500000000000000e+00,prob_stddev=0.1100000000000000e+00," + "prob_range={1.000000000000000e+00,1.000000000000000e+00},prob(percent)=\"100\"," + "prob+-sd=\"100+-0\"]:4.129000000000000e-02[&length_mean=4.153987461671767e-02," + "length_median=4.129000000000000e-02,length_95%HPD={3.217800000000000e-02," + "5.026800000000000e-02}],2[&prob=0.810000000000000e+00,prob_stddev=0.000000000000000e+00," + "prob_range={1.000000000000000e+00,1.000000000000000e+00},prob(percent)=\"100\"," + "prob+-sd=\"100+-0\"]:6.375699999999999e-02[&length_mean=6.395210411945065e-02," + "length_median=6.375699999999999e-02,length_95%HPD={5.388600000000000e-02," + "7.369400000000000e-02}])", new NHXParser() )[ 0 ]; if ( !isEqual( p1.getNode( "1" ).getDistanceToParent(), 4.129e-02 ) ) { return false; } if ( !isEqual( p1.getNode( "1" ).getBranchData().getConfidence( 0 ).getValue(), 0.9500000000000000e+00 ) ) { return false; } if ( !isEqual( p1.getNode( "1" ).getBranchData().getConfidence( 0 ).getStandardDeviation(), 0.1100000000000000e+00 ) ) { return false; } if ( !isEqual( p1.getNode( "2" ).getDistanceToParent(), 6.375699999999999e-02 ) ) { return false; } if ( !isEqual( p1.getNode( "2" ).getBranchData().getConfidence( 0 ).getValue(), 0.810000000000000e+00 ) ) { return false; } final Phylogeny p2 = factory .create( "(1[something_else(?)s,prob=0.9500000000000000e+00{}(((,p)rob_stddev=0.110000000000e+00," + "prob_range={1.000000000000000e+00,1.000000000000000e+00},prob(percent)=\"100\"," + "prob+-sd=\"100+-0\"]:4.129000000000000e-02[&length_mean=4.153987461671767e-02," + "length_median=4.129000000000000e-02,length_95%HPD={3.217800000000000e-02," + "5.026800000000000e-02}],2[&prob=0.810000000000000e+00,prob_stddev=0.000000000000000e+00," + "prob_range={1.000000000000000e+00,1.000000000000000e+00},prob(percent)=\"100\"," + "prob+-sd=\"100+-0\"]:6.375699999999999e-02[&length_mean=6.395210411945065e-02," + "length_median=6.375699999999999e-02,length_95%HPD={5.388600000000000e-02," + "7.369400000000000e-02}])", new NHXParser() )[ 0 ]; if ( p2.getNode( "1" ) == null ) { return false; } if ( p2.getNode( "2" ) == null ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); System.exit( -1 ); return false; } return true; } private static boolean testNHXParsingQuotes() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final NHXParser p = new NHXParser(); final Phylogeny[] phylogenies_0 = factory.create( new File( Test.PATH_TO_TEST_DATA + "quotes.nhx" ), p ); if ( phylogenies_0.length != 5 ) { return false; } final Phylogeny phy = phylogenies_0[ 4 ]; if ( phy.getNumberOfExternalNodes() != 7 ) { return false; } if ( phy.getNodes( "a name in double quotes from tree ((a,b),c)" ).size() != 1 ) { return false; } if ( phy.getNodes( "charles darwin 'origin of species'" ).size() != 1 ) { return false; } if ( !phy.getNodes( "charles darwin 'origin of species'" ).get( 0 ).getNodeData().getTaxonomy() .getScientificName().equals( "hsapiens" ) ) { return false; } if ( phy.getNodes( "shouldbetogether single quotes" ).size() != 1 ) { return false; } if ( phy.getNodes( "'single quotes' inside double quotes" ).size() != 1 ) { return false; } if ( phy.getNodes( "\"double quotes\" inside single quotes" ).size() != 1 ) { return false; } if ( phy.getNodes( "noquotes" ).size() != 1 ) { return false; } if ( phy.getNodes( "A ( B C '" ).size() != 1 ) { return false; } final NHXParser p1p = new NHXParser(); p1p.setIgnoreQuotes( true ); final Phylogeny p1 = factory.create( "(\"A\",'B1')", p1p )[ 0 ]; if ( !p1.toNewHampshire().equals( "(A,B1);" ) ) { return false; } final NHXParser p2p = new NHXParser(); p1p.setIgnoreQuotes( false ); final Phylogeny p2 = factory.create( "(\"A\",'B1')", p2p )[ 0 ]; if ( !p2.toNewHampshire().equals( "(A,B1);" ) ) { return false; } final NHXParser p3p = new NHXParser(); p3p.setIgnoreQuotes( false ); final Phylogeny p3 = factory.create( "(\"A)\",'B1')", p3p )[ 0 ]; if ( !p3.toNewHampshire().equals( "('A)',B1);" ) ) { return false; } final NHXParser p4p = new NHXParser(); p4p.setIgnoreQuotes( false ); final Phylogeny p4 = factory.create( "(\"A)\",'B(),; x')", p4p )[ 0 ]; if ( !p4.toNewHampshire().equals( "('A)','B(),; x');" ) ) { return false; } final Phylogeny p10 = factory.create( " [79] ( (\"A \n\tB \" [co mment] :0 .2[comment],'B':0.3[com])[com ment]: 0. 5 \t[ 9 1 ][ comment],'C (or D?\\//;,))': 0.1)[comment]'\nroot is here (cool, was! ) ':0.1[100] [comment]", new NHXParser() )[ 0 ]; final String p10_clean_str = "(('A B':0.2,B:0.3):0.5[&&NHX:B=91],'C (or D?\\//;,))':0.1)'root is here (cool, was! )':0.1[&&NHX:B=100]"; if ( !p10.toNewHampshireX().equals( p10_clean_str ) ) { return false; } final Phylogeny p11 = factory.create( p10.toNewHampshireX(), new NHXParser() )[ 0 ]; if ( !p11.toNewHampshireX().equals( p10_clean_str ) ) { return false; } final Phylogeny p12 = factory.create( " [79] ( (\"A \n\tB \" [[][] :0 .2[comment][\t&\t&\n N\tH\tX:S=mo\tnkey !],'\tB\t\b\t\n\f\rB B ':0.0\b3[])\t[com ment]: 0. 5 \t[ 9 1 ][ \ncomment],'C\t (or D?\\//;,))': 0.\b1)[comment]'\nroot \tis here (cool, \b\t\n\f\r was! ) ':0.1[100] [comment]", new NHXParser() )[ 0 ]; final String p12_clean_str = "(('A B':0.2[&&NHX:S=monkey!],'BB B':0.03):0.5[&&NHX:B=91],'C (or D?\\//;,))':0.1)'root is here (cool, was! )':0.1[&&NHX:B=100]"; if ( !p12.toNewHampshireX().equals( p12_clean_str ) ) { return false; } final Phylogeny p13 = factory.create( p12.toNewHampshireX(), new NHXParser() )[ 0 ]; if ( !p13.toNewHampshireX().equals( p12_clean_str ) ) { return false; } final String p12_clean_str_nh = "(('A B':0.2,'BB B':0.03):0.5,'C (or D?\\//;,))':0.1)'root is here (cool, was! )':0.1;"; if ( !p13.toNewHampshire().equals( p12_clean_str_nh ) ) { return false; } final Phylogeny p14 = factory.create( p13.toNewHampshire(), new NHXParser() )[ 0 ]; if ( !p14.toNewHampshire().equals( p12_clean_str_nh ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testNodeRemoval() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((a)b)", new NHXParser() )[ 0 ]; PhylogenyMethods.removeNode( t0.getNode( "b" ), t0 ); if ( !t0.toNewHampshire().equals( "(a);" ) ) { return false; } final Phylogeny t1 = factory.create( "((a:2)b:4)", new NHXParser() )[ 0 ]; PhylogenyMethods.removeNode( t1.getNode( "b" ), t1 ); if ( !t1.toNewHampshire().equals( "(a:6.0);" ) ) { return false; } final Phylogeny t2 = factory.create( "((a,b),c)", new NHXParser() )[ 0 ]; PhylogenyMethods.removeNode( t2.getNode( "b" ), t2 ); if ( !t2.toNewHampshire().equals( "((a),c);" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPhylogenyBranch() { try { final PhylogenyNode a1 = PhylogenyNode.createInstanceFromNhxString( "a" ); final PhylogenyNode b1 = PhylogenyNode.createInstanceFromNhxString( "b" ); final PhylogenyBranch a1b1 = new PhylogenyBranch( a1, b1 ); final PhylogenyBranch b1a1 = new PhylogenyBranch( b1, a1 ); if ( !a1b1.equals( a1b1 ) ) { return false; } if ( !a1b1.equals( b1a1 ) ) { return false; } if ( !b1a1.equals( a1b1 ) ) { return false; } final PhylogenyBranch a1_b1 = new PhylogenyBranch( a1, b1, true ); final PhylogenyBranch b1_a1 = new PhylogenyBranch( b1, a1, true ); final PhylogenyBranch a1_b1_ = new PhylogenyBranch( a1, b1, false ); if ( a1_b1.equals( b1_a1 ) ) { return false; } if ( a1_b1.equals( a1_b1_ ) ) { return false; } final PhylogenyBranch b1_a1_ = new PhylogenyBranch( b1, a1, false ); if ( !a1_b1.equals( b1_a1_ ) ) { return false; } if ( a1_b1_.equals( b1_a1_ ) ) { return false; } if ( !a1_b1_.equals( b1_a1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPhyloXMLparsingOfDistributionElement() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); PhyloXmlParser xml_parser = null; try { xml_parser = PhyloXmlParser.createPhyloXmlParserXsdValidating(); } catch ( final Exception e ) { // Do nothing -- means were not running from jar. } if ( xml_parser == null ) { xml_parser = PhyloXmlParser.createPhyloXmlParser(); if ( USE_LOCAL_PHYLOXML_SCHEMA ) { xml_parser.setValidateAgainstSchema( PHYLOXML_LOCAL_XSD ); } else { xml_parser.setValidateAgainstSchema( PHYLOXML_REMOTE_XSD ); } } final Phylogeny[] phylogenies_0 = factory .create( new File( Test.PATH_TO_TEST_DATA + "phyloxml_distribution.xml" ), xml_parser ); if ( xml_parser.getErrorCount() > 0 ) { System.out.println( xml_parser.getErrorMessages().toString() ); return false; } if ( phylogenies_0.length != 1 ) { return false; } final Phylogeny t1 = phylogenies_0[ 0 ]; PhylogenyNode n = null; Distribution d = null; n = t1.getNode( "root node" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 1 ) { return false; } d = n.getNodeData().getDistribution(); if ( !d.getDesc().equals( "Hirschweg 38" ) ) { return false; } if ( d.getPoints().size() != 1 ) { return false; } if ( d.getPolygons() != null ) { return false; } if ( !d.getPoints().get( 0 ).getAltitude().toString().equals( "472" ) ) { return false; } if ( !d.getPoints().get( 0 ).getAltiudeUnit().equals( "m" ) ) { return false; } if ( !d.getPoints().get( 0 ).getGeodeticDatum().equals( "WGS84" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "47.48148427110029" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "8.768951296806335" ) ) { return false; } n = t1.getNode( "node a" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 2 ) { return false; } d = n.getNodeData().getDistribution( 1 ); if ( !d.getDesc().equals( "San Diego" ) ) { return false; } if ( d.getPoints().size() != 1 ) { return false; } if ( d.getPolygons() != null ) { return false; } if ( !d.getPoints().get( 0 ).getAltitude().toString().equals( "104" ) ) { return false; } if ( !d.getPoints().get( 0 ).getAltiudeUnit().equals( "m" ) ) { return false; } if ( !d.getPoints().get( 0 ).getGeodeticDatum().equals( "WGS84" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "32.880933" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "-117.217543" ) ) { return false; } n = t1.getNode( "node bb" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 1 ) { return false; } d = n.getNodeData().getDistribution( 0 ); if ( d.getPoints().size() != 3 ) { return false; } if ( d.getPolygons().size() != 2 ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "1" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "2" ) ) { return false; } if ( !d.getPoints().get( 1 ).getLatitude().toString().equals( "3" ) ) { return false; } if ( !d.getPoints().get( 1 ).getLongitude().toString().equals( "4" ) ) { return false; } if ( !d.getPoints().get( 2 ).getLatitude().toString().equals( "5" ) ) { return false; } if ( !d.getPoints().get( 2 ).getLongitude().toString().equals( "6" ) ) { return false; } Polygon p = d.getPolygons().get( 0 ); if ( p.getPoints().size() != 3 ) { return false; } if ( !p.getPoints().get( 0 ).getLatitude().toString().equals( "0.1" ) ) { return false; } if ( !p.getPoints().get( 0 ).getLongitude().toString().equals( "0.2" ) ) { return false; } if ( !p.getPoints().get( 0 ).getAltitude().toString().equals( "10" ) ) { return false; } if ( !p.getPoints().get( 2 ).getLatitude().toString().equals( "0.5" ) ) { return false; } if ( !p.getPoints().get( 2 ).getLongitude().toString().equals( "0.6" ) ) { return false; } if ( !p.getPoints().get( 2 ).getAltitude().toString().equals( "30" ) ) { return false; } p = d.getPolygons().get( 1 ); if ( p.getPoints().size() != 3 ) { return false; } if ( !p.getPoints().get( 0 ).getLatitude().toString().equals( "1.49348902489947473" ) ) { return false; } if ( !p.getPoints().get( 0 ).getLongitude().toString().equals( "2.567489393947847492" ) ) { return false; } if ( !p.getPoints().get( 0 ).getAltitude().toString().equals( "10" ) ) { return false; } // Roundtrip: final StringBuffer t1_sb = new StringBuffer( t1.toPhyloXML( 0 ) ); final Phylogeny[] rt = factory.create( t1_sb, xml_parser ); if ( rt.length != 1 ) { return false; } final Phylogeny t1_rt = rt[ 0 ]; n = t1_rt.getNode( "root node" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 1 ) { return false; } d = n.getNodeData().getDistribution(); if ( !d.getDesc().equals( "Hirschweg 38" ) ) { return false; } if ( d.getPoints().size() != 1 ) { return false; } if ( d.getPolygons() != null ) { return false; } if ( !d.getPoints().get( 0 ).getAltitude().toString().equals( "472" ) ) { return false; } if ( !d.getPoints().get( 0 ).getAltiudeUnit().equals( "m" ) ) { return false; } if ( !d.getPoints().get( 0 ).getGeodeticDatum().equals( "WGS84" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "47.48148427110029" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "8.768951296806335" ) ) { return false; } n = t1_rt.getNode( "node a" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 2 ) { return false; } d = n.getNodeData().getDistribution( 1 ); if ( !d.getDesc().equals( "San Diego" ) ) { return false; } if ( d.getPoints().size() != 1 ) { return false; } if ( d.getPolygons() != null ) { return false; } if ( !d.getPoints().get( 0 ).getAltitude().toString().equals( "104" ) ) { return false; } if ( !d.getPoints().get( 0 ).getAltiudeUnit().equals( "m" ) ) { return false; } if ( !d.getPoints().get( 0 ).getGeodeticDatum().equals( "WGS84" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "32.880933" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "-117.217543" ) ) { return false; } n = t1_rt.getNode( "node bb" ); if ( !n.getNodeData().isHasDistribution() ) { return false; } if ( n.getNodeData().getDistributions().size() != 1 ) { return false; } d = n.getNodeData().getDistribution( 0 ); if ( d.getPoints().size() != 3 ) { return false; } if ( d.getPolygons().size() != 2 ) { return false; } if ( !d.getPoints().get( 0 ).getLatitude().toString().equals( "1" ) ) { return false; } if ( !d.getPoints().get( 0 ).getLongitude().toString().equals( "2" ) ) { return false; } if ( !d.getPoints().get( 1 ).getLatitude().toString().equals( "3" ) ) { return false; } if ( !d.getPoints().get( 1 ).getLongitude().toString().equals( "4" ) ) { return false; } if ( !d.getPoints().get( 2 ).getLatitude().toString().equals( "5" ) ) { return false; } if ( !d.getPoints().get( 2 ).getLongitude().toString().equals( "6" ) ) { return false; } p = d.getPolygons().get( 0 ); if ( p.getPoints().size() != 3 ) { return false; } if ( !p.getPoints().get( 0 ).getLatitude().toString().equals( "0.1" ) ) { return false; } if ( !p.getPoints().get( 0 ).getLongitude().toString().equals( "0.2" ) ) { return false; } if ( !p.getPoints().get( 0 ).getAltitude().toString().equals( "10" ) ) { return false; } if ( !p.getPoints().get( 2 ).getLatitude().toString().equals( "0.5" ) ) { return false; } if ( !p.getPoints().get( 2 ).getLongitude().toString().equals( "0.6" ) ) { return false; } if ( !p.getPoints().get( 2 ).getAltitude().toString().equals( "30" ) ) { return false; } p = d.getPolygons().get( 1 ); if ( p.getPoints().size() != 3 ) { return false; } if ( !p.getPoints().get( 0 ).getLatitude().toString().equals( "1.49348902489947473" ) ) { return false; } if ( !p.getPoints().get( 0 ).getLongitude().toString().equals( "2.567489393947847492" ) ) { return false; } if ( !p.getPoints().get( 0 ).getAltitude().toString().equals( "10" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPostOrderIterator() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((A,B)ab,(C,D)cd)r", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it0; for( it0 = t0.iteratorPostorder(); it0.hasNext(); ) { it0.next(); } for( it0.reset(); it0.hasNext(); ) { it0.next(); } final Phylogeny t1 = factory.create( "(((A,B)ab,(C,D)cd)abcd,((E,F)ef,(G,H)gh)efgh)r", new NHXParser() )[ 0 ]; final PhylogenyNodeIterator it = t1.iteratorPostorder(); if ( !it.next().getName().equals( "A" ) ) { return false; } if ( !it.next().getName().equals( "B" ) ) { return false; } if ( !it.next().getName().equals( "ab" ) ) { return false; } if ( !it.next().getName().equals( "C" ) ) { return false; } if ( !it.next().getName().equals( "D" ) ) { return false; } if ( !it.next().getName().equals( "cd" ) ) { return false; } if ( !it.next().getName().equals( "abcd" ) ) { return false; } if ( !it.next().getName().equals( "E" ) ) { return false; } if ( !it.next().getName().equals( "F" ) ) { return false; } if ( !it.next().getName().equals( "ef" ) ) { return false; } if ( !it.next().getName().equals( "G" ) ) { return false; } if ( !it.next().getName().equals( "H" ) ) { return false; } if ( !it.next().getName().equals( "gh" ) ) { return false; } if ( !it.next().getName().equals( "efgh" ) ) { return false; } if ( !it.next().getName().equals( "r" ) ) { return false; } if ( it.hasNext() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPreOrderIterator() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((A,B)ab,(C,D)cd)r", new NHXParser() )[ 0 ]; PhylogenyNodeIterator it0; for( it0 = t0.iteratorPreorder(); it0.hasNext(); ) { it0.next(); } for( it0.reset(); it0.hasNext(); ) { it0.next(); } PhylogenyNodeIterator it = t0.iteratorPreorder(); if ( !it.next().getName().equals( "r" ) ) { return false; } if ( !it.next().getName().equals( "ab" ) ) { return false; } if ( !it.next().getName().equals( "A" ) ) { return false; } if ( !it.next().getName().equals( "B" ) ) { return false; } if ( !it.next().getName().equals( "cd" ) ) { return false; } if ( !it.next().getName().equals( "C" ) ) { return false; } if ( !it.next().getName().equals( "D" ) ) { return false; } if ( it.hasNext() ) { return false; } final Phylogeny t1 = factory.create( "(((A,B)ab,(C,D)cd)abcd,((E,F)ef,(G,H)gh)efgh)r", new NHXParser() )[ 0 ]; it = t1.iteratorPreorder(); if ( !it.next().getName().equals( "r" ) ) { return false; } if ( !it.next().getName().equals( "abcd" ) ) { return false; } if ( !it.next().getName().equals( "ab" ) ) { return false; } if ( !it.next().getName().equals( "A" ) ) { return false; } if ( !it.next().getName().equals( "B" ) ) { return false; } if ( !it.next().getName().equals( "cd" ) ) { return false; } if ( !it.next().getName().equals( "C" ) ) { return false; } if ( !it.next().getName().equals( "D" ) ) { return false; } if ( !it.next().getName().equals( "efgh" ) ) { return false; } if ( !it.next().getName().equals( "ef" ) ) { return false; } if ( !it.next().getName().equals( "E" ) ) { return false; } if ( !it.next().getName().equals( "F" ) ) { return false; } if ( !it.next().getName().equals( "gh" ) ) { return false; } if ( !it.next().getName().equals( "G" ) ) { return false; } if ( !it.next().getName().equals( "H" ) ) { return false; } if ( it.hasNext() ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPropertiesMap() { try { final PropertiesList pm = new PropertiesList(); final Property p0 = new Property( "dimensions:diameter", "1", "metric:mm", "xsd:decimal", AppliesTo.NODE ); final Property p1 = new Property( "dimensions:length", "2", "metric:mm", "xsd:decimal", AppliesTo.NODE ); final Property p2 = new Property( "something:else", "?", "improbable:research", "xsd:decimal", AppliesTo.NODE ); pm.addProperty( p0 ); pm.addProperty( p1 ); pm.addProperty( p2 ); if ( !pm.getProperties( "dimensions:diameter" ).get( 0 ).getValue().equals( "1" ) ) { return false; } if ( !pm.getProperties( "dimensions:length" ).get( 0 ).getValue().equals( "2" ) ) { return false; } if ( pm.getProperties().size() != 3 ) { return false; } if ( pm.getPropertiesWithGivenReferencePrefix( "dimensions" ).size() != 2 ) { return false; } if ( pm.getPropertiesWithGivenReferencePrefix( "something" ).size() != 1 ) { return false; } if ( pm.getProperties().size() != 3 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testProteinId() { try { final ProteinId id1 = new ProteinId( "a" ); final ProteinId id2 = new ProteinId( "a" ); final ProteinId id3 = new ProteinId( "A" ); final ProteinId id4 = new ProteinId( "b" ); if ( !id1.equals( id1 ) ) { return false; } if ( id1.getId().equals( "x" ) ) { return false; } if ( id1.getId().equals( null ) ) { return false; } if ( !id1.equals( id2 ) ) { return false; } if ( id1.equals( id3 ) ) { return false; } if ( id1.hashCode() != id1.hashCode() ) { return false; } if ( id1.hashCode() != id2.hashCode() ) { return false; } if ( id1.hashCode() == id3.hashCode() ) { return false; } if ( id1.compareTo( id1 ) != 0 ) { return false; } if ( id1.compareTo( id2 ) != 0 ) { return false; } if ( id1.compareTo( id3 ) != 0 ) { return false; } if ( id1.compareTo( id4 ) >= 0 ) { return false; } if ( id4.compareTo( id1 ) <= 0 ) { return false; } if ( !id4.getId().equals( "b" ) ) { return false; } final ProteinId id5 = new ProteinId( " C " ); if ( !id5.getId().equals( "C" ) ) { return false; } if ( id5.equals( id1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testReIdMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p = factory.create( "((1,2)A,(((X,Y,Z)a,b)3)B,(4,5,6)C)r", new NHXParser() )[ 0 ]; final long count = PhylogenyNode.getNodeCount(); p.levelOrderReID(); if ( p.getNode( "r" ).getId() != count ) { return false; } if ( p.getNode( "A" ).getId() != ( count + 1 ) ) { return false; } if ( p.getNode( "B" ).getId() != ( count + 1 ) ) { return false; } if ( p.getNode( "C" ).getId() != ( count + 1 ) ) { return false; } if ( p.getNode( "1" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "2" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "3" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "4" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "5" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "6" ).getId() != ( count + 2 ) ) { return false; } if ( p.getNode( "a" ).getId() != ( count + 3 ) ) { return false; } if ( p.getNode( "b" ).getId() != ( count + 3 ) ) { return false; } if ( p.getNode( "X" ).getId() != ( count + 4 ) ) { return false; } if ( p.getNode( "Y" ).getId() != ( count + 4 ) ) { return false; } if ( p.getNode( "Z" ).getId() != ( count + 4 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testRerooting() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t1 = factory.create( "((A:1,B:2)AB:1[&&NHX:B=55],(C:3,D:5)CD:3[&&NHX:B=10])ABCD:0.5", new NHXParser() )[ 0 ]; if ( !t1.isRooted() ) { return false; } t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "CD" ) ); t1.reRoot( t1.getNode( "A" ) ); t1.reRoot( t1.getNode( "B" ) ); t1.reRoot( t1.getNode( "AB" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "C" ) ); t1.reRoot( t1.getNode( "CD" ) ); t1.reRoot( t1.getNode( "A" ) ); t1.reRoot( t1.getNode( "B" ) ); t1.reRoot( t1.getNode( "AB" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "C" ) ); t1.reRoot( t1.getNode( "A" ) ); t1.reRoot( t1.getNode( "B" ) ); t1.reRoot( t1.getNode( "AB" ) ); t1.reRoot( t1.getNode( "C" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "CD" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "A" ) ); t1.reRoot( t1.getNode( "B" ) ); t1.reRoot( t1.getNode( "AB" ) ); t1.reRoot( t1.getNode( "C" ) ); t1.reRoot( t1.getNode( "D" ) ); t1.reRoot( t1.getNode( "CD" ) ); t1.reRoot( t1.getNode( "D" ) ); if ( !isEqual( t1.getNode( "A" ).getDistanceToParent(), 1 ) ) { return false; } if ( !isEqual( t1.getNode( "B" ).getDistanceToParent(), 2 ) ) { return false; } if ( !isEqual( t1.getNode( "C" ).getDistanceToParent(), 3 ) ) { return false; } if ( !isEqual( t1.getNode( "D" ).getDistanceToParent(), 2.5 ) ) { return false; } if ( !isEqual( t1.getNode( "CD" ).getDistanceToParent(), 2.5 ) ) { return false; } if ( !isEqual( t1.getNode( "AB" ).getDistanceToParent(), 4 ) ) { return false; } final Phylogeny t2 = factory.create( "(((A:1,B:2)AB:10[&&NHX:B=55],C)ABC:3[&&NHX:B=33],D:5)ABCD:0.5", new NHXParser() )[ 0 ]; t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "A" ) ); t2.reRoot( t2.getNode( "B" ) ); t2.reRoot( t2.getNode( "AB" ) ); t2.reRoot( t2.getNode( "C" ) ); t2.reRoot( t2.getNode( "D" ) ); t2.reRoot( t2.getNode( "ABC" ) ); t2.reRoot( t2.getNode( "D" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } t2.reRoot( t2.getNode( "ABC" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } t2.reRoot( t2.getNode( "AB" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "D" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } t2.reRoot( t2.getNode( "AB" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "D" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } t2.reRoot( t2.getNode( "D" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } t2.reRoot( t2.getNode( "ABC" ) ); if ( !isEqual( t2.getNode( "AB" ).getBranchData().getConfidence( 0 ).getValue(), 55 ) ) { return false; } if ( !isEqual( t2.getNode( "ABC" ).getBranchData().getConfidence( 0 ).getValue(), 33 ) ) { return false; } final Phylogeny t3 = factory.create( "(A[&&NHX:B=10],B[&&NHX:B=20],C[&&NHX:B=30],D[&&NHX:B=40])", new NHXParser() )[ 0 ]; t3.reRoot( t3.getNode( "B" ) ); if ( t3.getNode( "B" ).getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getNumberOfDescendants() != 3 ) { return false; } t3.reRoot( t3.getNode( "B" ) ); if ( t3.getNode( "B" ).getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getNumberOfDescendants() != 3 ) { return false; } t3.reRoot( t3.getRoot() ); if ( t3.getNode( "B" ).getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getBranchData().getConfidence( 0 ).getValue() != 20 ) { return false; } if ( t3.getNode( "A" ).getParent().getNumberOfDescendants() != 3 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSDIse() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny species1 = factory.create( "[&&NHX:S=yeast]", new NHXParser() )[ 0 ]; final Phylogeny gene1 = factory.create( "(A1[&&NHX:S=yeast],A2[&&NHX:S=yeast])", new NHXParser() )[ 0 ]; gene1.setRooted( true ); species1.setRooted( true ); final SDI sdi = new SDI( gene1, species1 ); if ( !gene1.getRoot().isDuplication() ) { return false; } final Phylogeny species2 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B]),[&&NHX:S=C]),[&&NHX:S=D]),([&&NHX:S=E],[&&NHX:S=F]))", new NHXParser() )[ 0 ]; final Phylogeny gene2 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B])ab,[&&NHX:S=C])abc,[&&NHX:S=D])abcd,([&&NHX:S=E],[&&NHX:S=F])ef)r", new NHXParser() )[ 0 ]; species2.setRooted( true ); gene2.setRooted( true ); final SDI sdi2 = new SDI( gene2, species2 ); if ( sdi2.getDuplicationsSum() != 0 ) { return false; } if ( !gene2.getNode( "ab" ).isSpeciation() ) { return false; } if ( !gene2.getNode( "ab" ).isHasAssignedEvent() ) { return false; } if ( !gene2.getNode( "abc" ).isSpeciation() ) { return false; } if ( !gene2.getNode( "abc" ).isHasAssignedEvent() ) { return false; } if ( !gene2.getNode( "r" ).isSpeciation() ) { return false; } if ( !gene2.getNode( "r" ).isHasAssignedEvent() ) { return false; } final Phylogeny species3 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B]),[&&NHX:S=C]),[&&NHX:S=D]),([&&NHX:S=E],[&&NHX:S=F]))", new NHXParser() )[ 0 ]; final Phylogeny gene3 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=A])aa,[&&NHX:S=C])abc,[&&NHX:S=D])abcd,([&&NHX:S=E],[&&NHX:S=F])ef)r", new NHXParser() )[ 0 ]; species3.setRooted( true ); gene3.setRooted( true ); final SDI sdi3 = new SDI( gene3, species3 ); if ( sdi3.getDuplicationsSum() != 1 ) { return false; } if ( !gene3.getNode( "aa" ).isDuplication() ) { return false; } if ( !gene3.getNode( "aa" ).isHasAssignedEvent() ) { return false; } final Phylogeny species4 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B]),[&&NHX:S=C]),[&&NHX:S=D]),([&&NHX:S=E],[&&NHX:S=F]))", new NHXParser() )[ 0 ]; final Phylogeny gene4 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=C])ac,[&&NHX:S=B])abc,[&&NHX:S=D])abcd,([&&NHX:S=E],[&&NHX:S=F])ef)r", new NHXParser() )[ 0 ]; species4.setRooted( true ); gene4.setRooted( true ); final SDI sdi4 = new SDI( gene4, species4 ); if ( sdi4.getDuplicationsSum() != 1 ) { return false; } if ( !gene4.getNode( "ac" ).isSpeciation() ) { return false; } if ( !gene4.getNode( "abc" ).isDuplication() ) { return false; } if ( gene4.getNode( "abcd" ).isDuplication() ) { return false; } if ( species4.getNumberOfExternalNodes() != 6 ) { return false; } if ( gene4.getNumberOfExternalNodes() != 6 ) { return false; } final Phylogeny species5 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B]),[&&NHX:S=C]),[&&NHX:S=D]),([&&NHX:S=E],[&&NHX:S=F]))", new NHXParser() )[ 0 ]; final Phylogeny gene5 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=D])ad,[&&NHX:S=C])adc,[&&NHX:S=B])abcd,([&&NHX:S=E],[&&NHX:S=F])ef)r", new NHXParser() )[ 0 ]; species5.setRooted( true ); gene5.setRooted( true ); final SDI sdi5 = new SDI( gene5, species5 ); if ( sdi5.getDuplicationsSum() != 2 ) { return false; } if ( !gene5.getNode( "ad" ).isSpeciation() ) { return false; } if ( !gene5.getNode( "adc" ).isDuplication() ) { return false; } if ( !gene5.getNode( "abcd" ).isDuplication() ) { return false; } if ( species5.getNumberOfExternalNodes() != 6 ) { return false; } if ( gene5.getNumberOfExternalNodes() != 6 ) { return false; } // Trees from Louxin Zhang 1997 "On a Mirkin-Muchnik-Smith // Conjecture for Comparing Molecular Phylogenies" // J. of Comput Bio. Vol. 4, No 2, pp.177-187 final Phylogeny species6 = factory.create( "(((1:[&&NHX:S=1],5:[&&NHX:S=5])1-5,((4:[&&NHX:S=4],6:[&&NHX:S=6])4-6,2:[&&NHX:S=2])4-6-2)1-5-4-6-2," + "((9:[&&NHX:S=9],3:[&&NHX:S=3])9-3,(8:[&&NHX:S=8],7:[&&NHX:S=7])8-7)9-3-8-7)", new NHXParser() )[ 0 ]; final Phylogeny gene6 = factory.create( "(((1:0.1[&&NHX:S=1],2:0.1[&&NHX:S=2])1-2:0.1,3:0.1[&&NHX:S=3])1-2-3:0.1," + "((4:0.1[&&NHX:S=4],(5:0.1[&&NHX:S=5],6:0.1[&&NHX:S=6])5-6:0.1)4-5-6:0.1," + "(7:0.1[&&NHX:S=7],(8:0.1[&&NHX:S=8],9:0.1[&&NHX:S=9])8-9:0.1)7-8-9:0.1)4-5-6-7-8-9:0.1)r;", new NHXParser() )[ 0 ]; species6.setRooted( true ); gene6.setRooted( true ); final SDI sdi6 = new SDI( gene6, species6 ); if ( sdi6.getDuplicationsSum() != 3 ) { return false; } if ( !gene6.getNode( "r" ).isDuplication() ) { return false; } if ( !gene6.getNode( "4-5-6" ).isDuplication() ) { return false; } if ( !gene6.getNode( "7-8-9" ).isDuplication() ) { return false; } if ( !gene6.getNode( "1-2" ).isSpeciation() ) { return false; } if ( !gene6.getNode( "1-2-3" ).isSpeciation() ) { return false; } if ( !gene6.getNode( "5-6" ).isSpeciation() ) { return false; } if ( !gene6.getNode( "8-9" ).isSpeciation() ) { return false; } if ( !gene6.getNode( "4-5-6-7-8-9" ).isSpeciation() ) { return false; } sdi6.computeMappingCostL(); if ( sdi6.computeMappingCostL() != 17 ) { return false; } if ( species6.getNumberOfExternalNodes() != 9 ) { return false; } if ( gene6.getNumberOfExternalNodes() != 9 ) { return false; } final Phylogeny species7 = Test.createPhylogeny( "(((((((" + "([&&NHX:S=a1],[&&NHX:S=a2])," + "([&&NHX:S=b1],[&&NHX:S=b2])" + "),[&&NHX:S=x]),(" + "([&&NHX:S=m1],[&&NHX:S=m2])," + "([&&NHX:S=n1],[&&NHX:S=n2])" + ")),(" + "([&&NHX:S=i1],[&&NHX:S=i2])," + "([&&NHX:S=j1],[&&NHX:S=j2])" + ")),(" + "([&&NHX:S=e1],[&&NHX:S=e2])," + "([&&NHX:S=f1],[&&NHX:S=f2])" + ")),[&&NHX:S=y]),[&&NHX:S=z])" ); species7.setRooted( true ); final Phylogeny gene7_1 = Test .createPhylogeny( "((((((((a1[&&NHX:S=a1],a2[&&NHX:S=a2]),b1[&&NHX:S=b1]),x[&&NHX:S=x]),m1[&&NHX:S=m1]),i1[&&NHX:S=i1]),e1[&&NHX:S=e1]),y[&&NHX:S=y]),z[&&NHX:S=z])" ); gene7_1.setRooted( true ); final SDI sdi7 = new SDI( gene7_1, species7 ); if ( sdi7.getDuplicationsSum() != 0 ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "a2" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "b1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "x" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "m1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "i1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "e1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "y" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_1, "a1", "z" ).isSpeciation() ) { return false; } final Phylogeny gene7_2 = Test .createPhylogeny( "(((((((((a1[&&NHX:S=a1],a2[&&NHX:S=a2]),b1[&&NHX:S=b1]),x[&&NHX:S=x]),m1[&&NHX:S=m1]),i1[&&NHX:S=i1]),j2[&&NHX:S=j2]),e1[&&NHX:S=e1]),y[&&NHX:S=y]),z[&&NHX:S=z])" ); gene7_2.setRooted( true ); final SDI sdi7_2 = new SDI( gene7_2, species7 ); if ( sdi7_2.getDuplicationsSum() != 1 ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "a2" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "b1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "x" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "m1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "i1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "j2" ).isDuplication() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "e1" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "y" ).isSpeciation() ) { return false; } if ( !Test.getEvent( gene7_2, "a1", "z" ).isSpeciation() ) { return false; } } catch ( final Exception e ) { return false; } return true; } private static boolean testSDIunrooted() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p0 = factory.create( "((((A,B)ab,(C1,C2)cc)abc,D)abcd,(E,F)ef)abcdef", new NHXParser() )[ 0 ]; final List l = SDIR.getBranchesInPreorder( p0 ); final Iterator iter = l.iterator(); PhylogenyBranch br = iter.next(); if ( !br.getFirstNode().getName().equals( "abcd" ) && !br.getFirstNode().getName().equals( "ef" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abcd" ) && !br.getSecondNode().getName().equals( "ef" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abcd" ) && !br.getFirstNode().getName().equals( "abc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abcd" ) && !br.getSecondNode().getName().equals( "abc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abc" ) && !br.getFirstNode().getName().equals( "ab" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abc" ) && !br.getSecondNode().getName().equals( "ab" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "A" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "A" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "B" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "B" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "abc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "abc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abc" ) && !br.getFirstNode().getName().equals( "cc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abc" ) && !br.getSecondNode().getName().equals( "cc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "C1" ) && !br.getFirstNode().getName().equals( "cc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "C1" ) && !br.getSecondNode().getName().equals( "cc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "C2" ) && !br.getFirstNode().getName().equals( "cc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "C2" ) && !br.getSecondNode().getName().equals( "cc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abc" ) && !br.getFirstNode().getName().equals( "cc" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abc" ) && !br.getSecondNode().getName().equals( "cc" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abc" ) && !br.getFirstNode().getName().equals( "abcd" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abc" ) && !br.getSecondNode().getName().equals( "abcd" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "abcd" ) && !br.getFirstNode().getName().equals( "D" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "abcd" ) && !br.getSecondNode().getName().equals( "D" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ef" ) && !br.getFirstNode().getName().equals( "abcd" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ef" ) && !br.getSecondNode().getName().equals( "abcd" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ef" ) && !br.getFirstNode().getName().equals( "E" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ef" ) && !br.getSecondNode().getName().equals( "E" ) ) { return false; } br = iter.next(); if ( !br.getFirstNode().getName().equals( "ef" ) && !br.getFirstNode().getName().equals( "F" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ef" ) && !br.getSecondNode().getName().equals( "F" ) ) { return false; } if ( iter.hasNext() ) { return false; } final Phylogeny p1 = factory.create( "(C,(A,B)ab)abc", new NHXParser() )[ 0 ]; final List l1 = SDIR.getBranchesInPreorder( p1 ); final Iterator iter1 = l1.iterator(); br = iter1.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "C" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "C" ) ) { return false; } br = iter1.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "A" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "A" ) ) { return false; } br = iter1.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "B" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "B" ) ) { return false; } if ( iter1.hasNext() ) { return false; } final Phylogeny p2 = factory.create( "((A,B)ab,C)abc", new NHXParser() )[ 0 ]; final List l2 = SDIR.getBranchesInPreorder( p2 ); final Iterator iter2 = l2.iterator(); br = iter2.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "C" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "C" ) ) { return false; } br = iter2.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "A" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "A" ) ) { return false; } br = iter2.next(); if ( !br.getFirstNode().getName().equals( "ab" ) && !br.getFirstNode().getName().equals( "B" ) ) { return false; } if ( !br.getSecondNode().getName().equals( "ab" ) && !br.getSecondNode().getName().equals( "B" ) ) { return false; } if ( iter2.hasNext() ) { return false; } final Phylogeny species0 = factory.create( "(((([&&NHX:S=A],[&&NHX:S=B]),[&&NHX:S=C]),[&&NHX:S=D]),([&&NHX:S=E],[&&NHX:S=F]))", new NHXParser() )[ 0 ]; final Phylogeny gene1 = factory.create( "(((((A:0.6[&&NHX:S=A],B:0.1[&&NHX:S=B])ab:0.1,C:0.1[&&NHX:S=C])abc:0.3,D:1.0[&&NHX:S=D])abcd:0.2,E:0.1[&&NHX:S=E])abcde:0.2,F:0.2[&&NHX:S=F])", new NHXParser() )[ 0 ]; species0.setRooted( true ); gene1.setRooted( true ); final SDIR sdi_unrooted = new SDIR(); sdi_unrooted.infer( gene1, species0, false, true, true, true, 10 ); if ( sdi_unrooted.getCount() != 1 ) { return false; } if ( sdi_unrooted.getMinimalDuplications() != 0 ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalDiffInSubTreeHeights(), 0.4 ) ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalTreeHeight(), 1.0 ) ) { return false; } if ( sdi_unrooted.getMinimalMappingCost() != Integer.MAX_VALUE ) { return false; } final Phylogeny gene2 = factory.create( "(((((A:2.6[&&NHX:S=A],B:0.1[&&NHX:S=B])ab:0.1,C:0.1[&&NHX:S=C])abc:0.3,D:1.0[&&NHX:S=D])abcd:0.2,E:0.1[&&NHX:S=E])abcde:0.2,F:0.2[&&NHX:S=F])", new NHXParser() )[ 0 ]; gene2.setRooted( true ); sdi_unrooted.infer( gene2, species0, false, false, true, true, 10 ); if ( sdi_unrooted.getCount() != 1 ) { return false; } if ( sdi_unrooted.getMinimalDuplications() != 3 ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalDiffInSubTreeHeights(), 0.0 ) ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalTreeHeight(), 2.0 ) ) { return false; } if ( sdi_unrooted.getMinimalMappingCost() != Integer.MAX_VALUE ) { return false; } final Phylogeny species6 = factory.create( "(((1:[&&NHX:S=1],5:[&&NHX:S=5])1-5,((4:[&&NHX:S=4],6:[&&NHX:S=6])4-6,2:[&&NHX:S=2])4-6-2)1-5-4-6-2," + "((9:[&&NHX:S=9],3:[&&NHX:S=3])9-3,(8:[&&NHX:S=8],7:[&&NHX:S=7])8-7)9-3-8-7)", new NHXParser() )[ 0 ]; final Phylogeny gene6 = factory.create( "((5:0.1[&&NHX:S=5],6:0.1[&&NHX:S=6])5-6:0.05[&&NHX:S=6],(4:0.1[&&NHX:S=4]," + "(((1:0.1[&&NHX:S=1],2:0.1[&&NHX:S=2])1-2:0.1[&&NHX:S=2],3:0.25[&&NHX:S=3])1-2-3:0.2[&&NHX:S=2]," + "(7:0.1[&&NHX:S=7],(8:0.1[&&NHX:S=8]," + "9:0.1[&&NHX:S=9])8-9:0.1[&&NHX:S=9])7-8-9:0.1[&&NHX:S=8])" + "4-5-6-7-8-9:0.1[&&NHX:S=5])4-5-6:0.05[&&NHX:S=5])", new NHXParser() )[ 0 ]; species6.setRooted( true ); gene6.setRooted( true ); Phylogeny[] p6 = sdi_unrooted.infer( gene6, species6, false, true, true, true, 10 ); if ( sdi_unrooted.getCount() != 1 ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalDiffInSubTreeHeights(), 0.0 ) ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalTreeHeight(), 0.375 ) ) { return false; } if ( sdi_unrooted.getMinimalDuplications() != 3 ) { return false; } if ( sdi_unrooted.getMinimalMappingCost() != Integer.MAX_VALUE ) { return false; } if ( !p6[ 0 ].getRoot().isDuplication() ) { return false; } if ( !p6[ 0 ].getNode( "4-5-6" ).isDuplication() ) { return false; } if ( !p6[ 0 ].getNode( "7-8-9" ).isDuplication() ) { return false; } if ( p6[ 0 ].getNode( "1-2" ).isDuplication() ) { return false; } if ( p6[ 0 ].getNode( "1-2-3" ).isDuplication() ) { return false; } if ( p6[ 0 ].getNode( "5-6" ).isDuplication() ) { return false; } if ( p6[ 0 ].getNode( "8-9" ).isDuplication() ) { return false; } if ( p6[ 0 ].getNode( "4-5-6-7-8-9" ).isDuplication() ) { return false; } p6 = null; final Phylogeny species7 = factory.create( "(((1:[&&NHX:S=1],5:[&&NHX:S=5])1-5,((4:[&&NHX:S=4],6:[&&NHX:S=6])4-6,2:[&&NHX:S=2])4-6-2)1-5-4-6-2," + "((9:[&&NHX:S=9],3:[&&NHX:S=3])9-3,(8:[&&NHX:S=8],7:[&&NHX:S=7])8-7)9-3-8-7)", new NHXParser() )[ 0 ]; final Phylogeny gene7 = factory.create( "((5:0.1[&&NHX:S=5],6:0.1[&&NHX:S=6])5-6:0.05[&&NHX:S=6],(4:0.1[&&NHX:S=4]," + "(((1:0.1[&&NHX:S=1],2:0.1[&&NHX:S=2])1-2:0.1[&&NHX:S=2],3:0.25[&&NHX:S=3])1-2-3:0.2[&&NHX:S=2]," + "(7:0.1[&&NHX:S=7],(8:0.1[&&NHX:S=8]," + "9:0.1[&&NHX:S=9])8-9:0.1[&&NHX:S=9])7-8-9:0.1[&&NHX:S=8])" + "4-5-6-7-8-9:0.1[&&NHX:S=5])4-5-6:0.05[&&NHX:S=5])", new NHXParser() )[ 0 ]; species7.setRooted( true ); gene7.setRooted( true ); Phylogeny[] p7 = sdi_unrooted.infer( gene7, species7, true, true, true, true, 10 ); if ( sdi_unrooted.getCount() != 1 ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalDiffInSubTreeHeights(), 0.0 ) ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalTreeHeight(), 0.375 ) ) { return false; } if ( sdi_unrooted.getMinimalDuplications() != 3 ) { return false; } if ( sdi_unrooted.getMinimalMappingCost() != 17 ) { return false; } if ( !p7[ 0 ].getRoot().isDuplication() ) { return false; } if ( !p7[ 0 ].getNode( "4-5-6" ).isDuplication() ) { return false; } if ( !p7[ 0 ].getNode( "7-8-9" ).isDuplication() ) { return false; } if ( p7[ 0 ].getNode( "1-2" ).isDuplication() ) { return false; } if ( p7[ 0 ].getNode( "1-2-3" ).isDuplication() ) { return false; } if ( p7[ 0 ].getNode( "5-6" ).isDuplication() ) { return false; } if ( p7[ 0 ].getNode( "8-9" ).isDuplication() ) { return false; } if ( p7[ 0 ].getNode( "4-5-6-7-8-9" ).isDuplication() ) { return false; } p7 = null; final Phylogeny species8 = factory.create( "(((1:[&&NHX:S=1],5:[&&NHX:S=5])1-5,((4:[&&NHX:S=4],6:[&&NHX:S=6])4-6,2:[&&NHX:S=2])4-6-2)1-5-4-6-2," + "((9:[&&NHX:S=9],3:[&&NHX:S=3])9-3,(8:[&&NHX:S=8],7:[&&NHX:S=7])8-7)9-3-8-7)", new NHXParser() )[ 0 ]; final Phylogeny gene8 = factory.create( "((5:0.1[&&NHX:S=5],6:0.1[&&NHX:S=6])5-6:0.05[&&NHX:S=6],(4:0.1[&&NHX:S=4]," + "(((1:0.1[&&NHX:S=1],2:0.1[&&NHX:S=2])1-2:0.1[&&NHX:S=2],3:0.25[&&NHX:S=3])1-2-3:0.2[&&NHX:S=2]," + "(7:0.1[&&NHX:S=7],(8:0.1[&&NHX:S=8]," + "9:0.1[&&NHX:S=9])8-9:0.1[&&NHX:S=9])7-8-9:0.1[&&NHX:S=8])" + "4-5-6-7-8-9:0.1[&&NHX:S=5])4-5-6:0.05[&&NHX:S=5])", new NHXParser() )[ 0 ]; species8.setRooted( true ); gene8.setRooted( true ); Phylogeny[] p8 = sdi_unrooted.infer( gene8, species8, false, false, true, true, 10 ); if ( sdi_unrooted.getCount() != 1 ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalDiffInSubTreeHeights(), 0.0 ) ) { return false; } if ( !Test.isEqual( sdi_unrooted.getMinimalTreeHeight(), 0.375 ) ) { return false; } if ( sdi_unrooted.getMinimalDuplications() != 3 ) { return false; } if ( sdi_unrooted.getMinimalMappingCost() != Integer.MAX_VALUE ) { return false; } if ( !p8[ 0 ].getRoot().isDuplication() ) { return false; } if ( !p8[ 0 ].getNode( "4-5-6" ).isDuplication() ) { return false; } if ( !p8[ 0 ].getNode( "7-8-9" ).isDuplication() ) { return false; } if ( p8[ 0 ].getNode( "1-2" ).isDuplication() ) { return false; } if ( p8[ 0 ].getNode( "1-2-3" ).isDuplication() ) { return false; } if ( p8[ 0 ].getNode( "5-6" ).isDuplication() ) { return false; } if ( p8[ 0 ].getNode( "8-9" ).isDuplication() ) { return false; } if ( p8[ 0 ].getNode( "4-5-6-7-8-9" ).isDuplication() ) { return false; } p8 = null; } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSequenceDbWsTools1() { try { final PhylogenyNode n = new PhylogenyNode(); n.setName( "NP_001025424" ); Accession acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.REFSEQ.toString() ) || !acc.getValue().equals( "NP_001025424" ) ) { return false; } n.setName( "340 0559 -- _NP_001025424_dsfdg15 05" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.REFSEQ.toString() ) || !acc.getValue().equals( "NP_001025424" ) ) { return false; } n.setName( "NP_001025424.1" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.REFSEQ.toString() ) || !acc.getValue().equals( "NP_001025424" ) ) { return false; } n.setName( "NM_001030253" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.REFSEQ.toString() ) || !acc.getValue().equals( "NM_001030253" ) ) { return false; } n.setName( "BCL2_HUMAN" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.UNIPROT.toString() ) || !acc.getValue().equals( "BCL2_HUMAN" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "P10415" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.UNIPROT.toString() ) || !acc.getValue().equals( "P10415" ) ) { System.out.println( acc.toString() ); return false; } n.setName( " P10415 " ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.UNIPROT.toString() ) || !acc.getValue().equals( "P10415" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "_P10415|" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.UNIPROT.toString() ) || !acc.getValue().equals( "P10415" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "AY695820" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AY695820" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "_AY695820_" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AY695820" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "AAA59452" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AAA59452" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "_AAA59452_" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AAA59452" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "AAA59452.1" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AAA59452.1" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "_AAA59452.1_" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AAA59452.1" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "GI:94894583" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.GI.toString() ) || !acc.getValue().equals( "94894583" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "gi|71845847|1,4-alpha-glucan branching enzyme [Dechloromonas aromatica RCB]" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.GI.toString() ) || !acc.getValue().equals( "71845847" ) ) { System.out.println( acc.toString() ); return false; } n.setName( "gi|71845847|gb|AAZ45343.1| 1,4-alpha-glucan branching enzyme [Dechloromonas aromatica RCB]" ); acc = SequenceDbWsTools.obtainSeqAccession( n ); if ( ( acc == null ) || !acc.getSource().equals( Source.NCBI.toString() ) || !acc.getValue().equals( "AAZ45343.1" ) ) { System.out.println( acc.toString() ); return false; } } catch ( final Exception e ) { return false; } return true; } private static boolean testSequenceDbWsTools2() { try { final PhylogenyNode n1 = new PhylogenyNode( "NP_001025424" ); SequenceDbWsTools.obtainSeqInformation( n1 ); if ( !n1.getNodeData().getSequence().getName().equals( "Bcl2" ) ) { return false; } if ( !n1.getNodeData().getTaxonomy().getScientificName().equals( "Danio rerio" ) ) { return false; } if ( !n1.getNodeData().getSequence().getAccession().getSource().equals( Source.REFSEQ.toString() ) ) { return false; } if ( !n1.getNodeData().getSequence().getAccession().getValue().equals( "NP_001025424" ) ) { return false; } final PhylogenyNode n2 = new PhylogenyNode( "NM_001030253" ); SequenceDbWsTools.obtainSeqInformation( n2 ); if ( !n2.getNodeData().getSequence().getName() .equals( "Danio rerio B-cell CLL/lymphoma 2a (bcl2a), mRNA" ) ) { return false; } if ( !n2.getNodeData().getTaxonomy().getScientificName().equals( "Danio rerio" ) ) { return false; } if ( !n2.getNodeData().getSequence().getAccession().getSource().equals( Source.REFSEQ.toString() ) ) { return false; } if ( !n2.getNodeData().getSequence().getAccession().getValue().equals( "NM_001030253" ) ) { return false; } final PhylogenyNode n3 = new PhylogenyNode( "NM_184234.2" ); SequenceDbWsTools.obtainSeqInformation( n3 ); if ( !n3.getNodeData().getSequence().getName() .equals( "Homo sapiens RNA binding motif protein 39 (RBM39), transcript variant 1, mRNA" ) ) { return false; } if ( !n3.getNodeData().getTaxonomy().getScientificName().equals( "Homo sapiens" ) ) { return false; } if ( !n3.getNodeData().getSequence().getAccession().getSource().equals( Source.REFSEQ.toString() ) ) { return false; } if ( !n3.getNodeData().getSequence().getAccession().getValue().equals( "NM_184234" ) ) { return false; } } catch ( final IOException e ) { System.out.println(); System.out.println( "the following might be due to absence internet connection:" ); e.printStackTrace( System.out ); return true; } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testSequenceIdParsing() { try { Accession id = SequenceAccessionTools.parseAccessorFromString( "gb_ADF31344_segmented_worms_" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "ADF31344" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "segmented worms|gb_ADF31344" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "ADF31344" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "segmented worms gb_ADF31344 and more" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "ADF31344" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "gb_AAA96518_1" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "AAA96518" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "gb_EHB07727_1_rodents_" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "EHB07727" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "dbj_BAF37827_1_turtles_" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "BAF37827" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "emb_CAA73223_1_primates_" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "CAA73223" ) || !id.getSource().equals( "ncbi" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "mites|ref_XP_002434188_1" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "XP_002434188" ) || !id.getSource().equals( "refseq" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "mites_ref_XP_002434188_1_bla_XP_12345" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "XP_002434188" ) || !id.getSource().equals( "refseq" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "P4A123" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "P4A123" ) || !id.getSource().equals( "uniprot" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "XP_12345" ); if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); return false; } id = SequenceAccessionTools.parseAccessorFromString( "N3B004Z009" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "N3B004Z009" ) || !id.getSource().equals( "uniprot" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "A4CAA4ZBB9" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "A4CAA4ZBB9" ) || !id.getSource().equals( "uniprot" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "ecoli_A4CAA4ZBB9_rt" ); if ( ( id == null ) || ForesterUtil.isEmpty( id.getValue() ) || ForesterUtil.isEmpty( id.getSource() ) || !id.getValue().equals( "A4CAA4ZBB9" ) || !id.getSource().equals( "uniprot" ) ) { if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); } return false; } id = SequenceAccessionTools.parseAccessorFromString( "Q4CAA4ZBB9" ); if ( id != null ) { System.out.println( "value =" + id.getValue() ); System.out.println( "provider=" + id.getSource() ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSequenceWriter() { try { final String n = ForesterUtil.LINE_SEPARATOR; if ( !SequenceWriter.toFasta( "name", "awes", 5 ).toString().equals( ">name" + n + "awes" ) ) { return false; } if ( !SequenceWriter.toFasta( "name", "awes", 4 ).toString().equals( ">name" + n + "awes" ) ) { return false; } if ( !SequenceWriter.toFasta( "name", "awes", 3 ).toString().equals( ">name" + n + "awe" + n + "s" ) ) { return false; } if ( !SequenceWriter.toFasta( "name", "awes", 2 ).toString().equals( ">name" + n + "aw" + n + "es" ) ) { return false; } if ( !SequenceWriter.toFasta( "name", "awes", 1 ).toString() .equals( ">name" + n + "a" + n + "w" + n + "e" + n + "s" ) ) { return false; } if ( !SequenceWriter.toFasta( "name", "abcdefghij", 3 ).toString() .equals( ">name" + n + "abc" + n + "def" + n + "ghi" + n + "j" ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testSpecies() { try { final Species s1 = new BasicSpecies( "a" ); final Species s2 = new BasicSpecies( "a" ); final Species s3 = new BasicSpecies( "A" ); final Species s4 = new BasicSpecies( "b" ); if ( !s1.equals( s1 ) ) { return false; } if ( s1.getSpeciesId().equals( "x" ) ) { return false; } if ( s1.getSpeciesId().equals( null ) ) { return false; } if ( !s1.equals( s2 ) ) { return false; } if ( s1.equals( s3 ) ) { return false; } if ( s1.hashCode() != s1.hashCode() ) { return false; } if ( s1.hashCode() != s2.hashCode() ) { return false; } if ( s1.hashCode() == s3.hashCode() ) { return false; } if ( s1.compareTo( s1 ) != 0 ) { return false; } if ( s1.compareTo( s2 ) != 0 ) { return false; } if ( s1.compareTo( s3 ) != 0 ) { return false; } if ( s1.compareTo( s4 ) >= 0 ) { return false; } if ( s4.compareTo( s1 ) <= 0 ) { return false; } if ( !s4.getSpeciesId().equals( "b" ) ) { return false; } final Species s5 = new BasicSpecies( " C " ); if ( !s5.getSpeciesId().equals( "C" ) ) { return false; } if ( s5.equals( s1 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSplit() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p0 = factory.create( "(((A,B,C),D),(E,(F,G)))R", new NHXParser() )[ 0 ]; //Archaeopteryx.createApplication( p0 ); final Set ex = new HashSet(); ex.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); final TreeSplitMatrix s0 = new TreeSplitMatrix( p0, false, ex ); // System.out.println( s0.toString() ); // Set query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( !s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); if ( !s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( !s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } ///////// // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "A" ) ); // query_nodes.add( new PhylogenyNode( "B" ) ); // query_nodes.add( new PhylogenyNode( "C" ) ); // query_nodes.add( new PhylogenyNode( "D" ) ); // query_nodes.add( new PhylogenyNode( "E" ) ); // query_nodes.add( new PhylogenyNode( "F" ) ); // query_nodes.add( new PhylogenyNode( "G" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "A" ) ); // query_nodes.add( new PhylogenyNode( "B" ) ); // query_nodes.add( new PhylogenyNode( "C" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // // // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "D" ) ); // query_nodes.add( new PhylogenyNode( "E" ) ); // query_nodes.add( new PhylogenyNode( "F" ) ); // query_nodes.add( new PhylogenyNode( "G" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // // // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "A" ) ); // query_nodes.add( new PhylogenyNode( "B" ) ); // query_nodes.add( new PhylogenyNode( "C" ) ); // query_nodes.add( new PhylogenyNode( "D" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // // // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "E" ) ); // query_nodes.add( new PhylogenyNode( "F" ) ); // query_nodes.add( new PhylogenyNode( "G" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // // // query_nodes = new HashSet(); // query_nodes.add( new PhylogenyNode( "X" ) ); // query_nodes.add( new PhylogenyNode( "Y" ) ); // query_nodes.add( new PhylogenyNode( "F" ) ); // query_nodes.add( new PhylogenyNode( "G" ) ); // if ( !s0.match( query_nodes ) ) { // return false; // } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } /////////////////////////// // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "X" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "Y" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testSplitStrict() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p0 = factory.create( "(((A,B,C),D),(E,(F,G)))R", new NHXParser() )[ 0 ]; final Set ex = new HashSet(); ex.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); ex.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); final TreeSplitMatrix s0 = new TreeSplitMatrix( p0, true, ex ); Set query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( !s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "C" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "F" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "B" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); if ( s0.match( query_nodes ) ) { return false; } // query_nodes = new HashSet(); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "E" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "D" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "A" ) ); query_nodes.add( PhylogenyNode.createInstanceFromNhxString( "G" ) ); if ( s0.match( query_nodes ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testSubtreeDeletion() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t1 = factory.create( "((A,B,C)abc,(D,E,F)def)r", new NHXParser() )[ 0 ]; t1.deleteSubtree( t1.getNode( "A" ), false ); if ( t1.getNumberOfExternalNodes() != 5 ) { return false; } t1.toNewHampshireX(); t1.deleteSubtree( t1.getNode( "E" ), false ); if ( t1.getNumberOfExternalNodes() != 4 ) { return false; } t1.toNewHampshireX(); t1.deleteSubtree( t1.getNode( "F" ), false ); if ( t1.getNumberOfExternalNodes() != 3 ) { return false; } t1.toNewHampshireX(); t1.deleteSubtree( t1.getNode( "D" ), false ); t1.toNewHampshireX(); if ( t1.getNumberOfExternalNodes() != 3 ) { return false; } t1.deleteSubtree( t1.getNode( "def" ), false ); t1.toNewHampshireX(); if ( t1.getNumberOfExternalNodes() != 2 ) { return false; } t1.deleteSubtree( t1.getNode( "B" ), false ); t1.toNewHampshireX(); if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } t1.deleteSubtree( t1.getNode( "C" ), false ); t1.toNewHampshireX(); if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } t1.deleteSubtree( t1.getNode( "abc" ), false ); t1.toNewHampshireX(); if ( t1.getNumberOfExternalNodes() != 1 ) { return false; } t1.deleteSubtree( t1.getNode( "r" ), false ); if ( t1.getNumberOfExternalNodes() != 0 ) { return false; } if ( !t1.isEmpty() ) { return false; } final Phylogeny t2 = factory.create( "(((1,2,3)A,B,C)abc,(D,E,F)def)r", new NHXParser() )[ 0 ]; t2.deleteSubtree( t2.getNode( "A" ), false ); t2.toNewHampshireX(); if ( t2.getNumberOfExternalNodes() != 5 ) { return false; } t2.deleteSubtree( t2.getNode( "abc" ), false ); t2.toNewHampshireX(); if ( t2.getNumberOfExternalNodes() != 3 ) { return false; } t2.deleteSubtree( t2.getNode( "def" ), false ); t2.toNewHampshireX(); if ( t2.getNumberOfExternalNodes() != 1 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSupportCount() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0_1 = factory.create( "(((A,B),C),(D,E))", new NHXParser() )[ 0 ]; final Phylogeny[] phylogenies_1 = factory.create( "(((A,B),C),(D,E)) " + "(((C,B),A),(D,E))" + "(((A,B),C),(D,E)) " + "(((A,B),C),(D,E))" + "(((A,B),C),(D,E))" + "(((C,B),A),(D,E))" + "(((E,B),D),(C,A))" + "(((C,B),A),(D,E))" + "(((A,B),C),(D,E))" + "(((A,B),C),(D,E))", new NHXParser() ); SupportCount.count( t0_1, phylogenies_1, true, false ); final Phylogeny t0_2 = factory.create( "(((((A,B),C),D),E),(F,G))", new NHXParser() )[ 0 ]; final Phylogeny[] phylogenies_2 = factory.create( "(((((A,B),C),D),E),(F,G))" + "(((((A,B),C),D),E),((F,G),X))" + "(((((A,Y),B),C),D),((F,G),E))" + "(((((A,B),C),D),E),(F,G))" + "(((((A,B),C),D),E),(F,G))" + "(((((A,B),C),D),E),(F,G))" + "(((((A,B),C),D),E),(F,G),Z)" + "(((((A,B),C),D),E),(F,G))" + "((((((A,B),C),D),E),F),G)" + "(((((X,Y),F,G),E),((A,B),C)),D)", new NHXParser() ); SupportCount.count( t0_2, phylogenies_2, true, false ); final PhylogenyNodeIterator it = t0_2.iteratorPostorder(); while ( it.hasNext() ) { final PhylogenyNode n = it.next(); if ( !n.isExternal() && ( PhylogenyMethods.getConfidenceValue( n ) != 10 ) ) { return false; } } final Phylogeny t0_3 = factory.create( "(((A,B)ab,C)abc,((D,E)de,F)def)", new NHXParser() )[ 0 ]; final Phylogeny[] phylogenies_3 = factory.create( "(((A,B),C),((D,E),F))" + "(((A,C),B),((D,F),E))" + "(((C,A),B),((F,D),E))" + "(((A,B),F),((D,E),C))" + "(((((A,B),C),D),E),F)", new NHXParser() ); SupportCount.count( t0_3, phylogenies_3, true, false ); t0_3.reRoot( t0_3.getNode( "def" ).getId() ); if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "ab" ) ) != 3 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "abc" ) ) != 4 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "def" ) ) != 4 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "de" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "A" ) ) != 5 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "B" ) ) != 5 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "C" ) ) != 5 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "D" ) ) != 5 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "E" ) ) != 5 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_3.getNode( "F" ) ) != 5 ) { return false; } final Phylogeny t0_4 = factory.create( "(((((A,B)1,C)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; final Phylogeny[] phylogenies_4 = factory .create( "((((((A,X),C),B),D),E),F) " + "(((A,B,Z),C,Q),(((D,Y),E),F))", new NHXParser() ); SupportCount.count( t0_4, phylogenies_4, true, false ); t0_4.reRoot( t0_4.getNode( "F" ).getId() ); if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "1" ) ) != 1 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "2" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "3" ) ) != 1 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "4" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "A" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "B" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "C" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "D" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "E" ) ) != 2 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( t0_4.getNode( "F" ) ) != 2 ) { return false; } Phylogeny a = factory.create( "(((((A,B)1,C)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; final Phylogeny b1 = factory.create( "(((((B,A)1,C)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; double d = SupportCount.compare( b1, a, true, true, true ); if ( !Test.isEqual( d, 5.0 / 5.0 ) ) { return false; } a = factory.create( "(((((A,B)1,C)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; final Phylogeny b2 = factory.create( "(((((C,B)1,A)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; d = SupportCount.compare( b2, a, true, true, true ); if ( !Test.isEqual( d, 4.0 / 5.0 ) ) { return false; } a = factory.create( "(((((A,B)1,C)2,D)3,E)4,F)", new NHXParser() )[ 0 ]; final Phylogeny b3 = factory.create( "(((((F,C)1,A)2,B)3,D)4,E)", new NHXParser() )[ 0 ]; d = SupportCount.compare( b3, a, true, true, true ); if ( !Test.isEqual( d, 2.0 / 5.0 ) ) { return false; } a = factory.create( "(((((A,B)1,C)2,D)3,E)4,F)r", new NHXParser() )[ 0 ]; final Phylogeny b4 = factory.create( "(((((F,C)1,A)2,B)3,D)4,E)r", new NHXParser() )[ 0 ]; d = SupportCount.compare( b4, a, true, true, false ); if ( !Test.isEqual( d, 1.0 / 5.0 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testSupportTransfer() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny p1 = factory.create( "(((A,B)ab:97,C)abc:57,((D,E)de:10,(F,G)fg:50,(H,I)hi:64)defghi)", new NHXParser() )[ 0 ]; final Phylogeny p2 = factory.create( "(((A:0.1,B:0.3)ab:0.4,C)abc:0.5,((D,E)de,(F,G)fg,(H,I)hi:0.59)defghi)", new NHXParser() )[ 0 ]; if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "ab" ) ) >= 0.0 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "abc" ) ) >= 0.0 ) { return false; } support_transfer.moveBranchLengthsToBootstrap( p1 ); support_transfer.transferSupportValues( p1, p2 ); if ( p2.getNode( "ab" ).getDistanceToParent() != 0.4 ) { return false; } if ( p2.getNode( "abc" ).getDistanceToParent() != 0.5 ) { return false; } if ( p2.getNode( "hi" ).getDistanceToParent() != 0.59 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "ab" ) ) != 97 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "abc" ) ) != 57 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "de" ) ) != 10 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "fg" ) ) != 50 ) { return false; } if ( PhylogenyMethods.getConfidenceValue( p2.getNode( "hi" ) ) != 64 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testTaxonomyExtraction() { try { final PhylogenyNode n0 = PhylogenyNode .createInstanceFromNhxString( "sd_12345678", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n0.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n1 = PhylogenyNode .createInstanceFromNhxString( "sd_12345x", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n1.getNodeData().isHasTaxonomy() ) { System.out.println( n1.toString() ); return false; } final PhylogenyNode n2x = PhylogenyNode .createInstanceFromNhxString( "12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n2x.getNodeData().isHasTaxonomy() ) { return false; } final PhylogenyNode n3 = PhylogenyNode .createInstanceFromNhxString( "BLAGG_12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n3.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "12345" ) ) { System.out.println( n3.toString() ); return false; } final PhylogenyNode n4 = PhylogenyNode .createInstanceFromNhxString( "blag-12345", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n4.getNodeData().isHasTaxonomy() ) { System.out.println( n4.toString() ); return false; } final PhylogenyNode n5 = PhylogenyNode .createInstanceFromNhxString( "12345-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n5.getNodeData().isHasTaxonomy() ) { System.out.println( n5.toString() ); return false; } final PhylogenyNode n6 = PhylogenyNode .createInstanceFromNhxString( "BLAGG-12345-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n6.getNodeData().isHasTaxonomy() ) { System.out.println( n6.toString() ); return false; } final PhylogenyNode n7 = PhylogenyNode .createInstanceFromNhxString( "BL-12345_blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n7.getNodeData().isHasTaxonomy() ) { System.out.println( n7.toString() ); return false; } final PhylogenyNode n8 = PhylogenyNode .createInstanceFromNhxString( "BLAGG_12345-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n8.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "12345" ) ) { System.out.println( n8.toString() ); return false; } final PhylogenyNode n9 = PhylogenyNode .createInstanceFromNhxString( "BLAGG_12345/blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n9.getNodeData().getTaxonomy().getIdentifier().getValue().equals( "12345" ) ) { System.out.println( n9.toString() ); return false; } final PhylogenyNode n10x = PhylogenyNode .createInstanceFromNhxString( "BLAG!_12X45-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n10x.getNodeData().isHasTaxonomy() ) { System.out.println( n10x.toString() ); return false; } final PhylogenyNode n10xx = PhylogenyNode .createInstanceFromNhxString( "BLAG!_1YX45-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( n10xx.getNodeData().isHasTaxonomy() ) { System.out.println( n10xx.toString() ); return false; } final PhylogenyNode n10 = PhylogenyNode .createInstanceFromNhxString( "BLAGG_9YX45-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n10.getNodeData().getTaxonomy().getTaxonomyCode().equals( "9YX45" ) ) { System.out.println( n10.toString() ); return false; } final PhylogenyNode n10v = PhylogenyNode .createInstanceFromNhxString( "BLAGG_BPM1-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n10v.getNodeData().getTaxonomy().getTaxonomyCode().equals( "BPM1" ) ) { System.out.println( n10v.toString() ); return false; } final PhylogenyNode n10v2 = PhylogenyNode .createInstanceFromNhxString( "BLAGG_ABV-blag", NHXParser.TAXONOMY_EXTRACTION.PFAM_STYLE_RELAXED ); if ( !n10v2.getNodeData().getTaxonomy().getTaxonomyCode().equals( "ABV" ) ) { System.out.println( n10v2.toString() ); return false; } final PhylogenyNode n11 = PhylogenyNode .createInstanceFromNhxString( "BLAG@_Mus_musculus", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n11.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus" ) ) { System.out.println( n11.toString() ); return false; } final PhylogenyNode n12 = PhylogenyNode .createInstanceFromNhxString( "BLA_G_Mus_musculus_musculus", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n12.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus musculus" ) ) { System.out.println( n12.toString() ); return false; } final PhylogenyNode n13 = PhylogenyNode .createInstanceFromNhxString( "BLAaG_Mus_musculus1", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( n13.getNodeData().isHasTaxonomy() ) { System.out.println( n13.toString() ); return false; } final PhylogenyNode n14 = PhylogenyNode .createInstanceFromNhxString( "Mus_musculus_392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n14.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus" ) ) { System.out.println( n14.toString() ); return false; } final PhylogenyNode n15 = PhylogenyNode .createInstanceFromNhxString( "Mus_musculus_K392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n15.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus" ) ) { System.out.println( n15.toString() ); return false; } final PhylogenyNode n16 = PhylogenyNode .createInstanceFromNhxString( "Mus musculus 392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n16.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus" ) ) { System.out.println( n16.toString() ); return false; } final PhylogenyNode n17 = PhylogenyNode .createInstanceFromNhxString( "Mus musculus K392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n17.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus" ) ) { System.out.println( n17.toString() ); return false; } final PhylogenyNode n18 = PhylogenyNode .createInstanceFromNhxString( "Mus_musculus_musculus_392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n18.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus musculus" ) ) { System.out.println( n18.toString() ); return false; } final PhylogenyNode n19 = PhylogenyNode .createInstanceFromNhxString( "Mus_musculus_musculus_K392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n19.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus musculus" ) ) { System.out.println( n19.toString() ); return false; } final PhylogenyNode n20 = PhylogenyNode .createInstanceFromNhxString( "Mus musculus musculus 392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n20.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus musculus" ) ) { System.out.println( n20.toString() ); return false; } final PhylogenyNode n21 = PhylogenyNode .createInstanceFromNhxString( "Mus musculus musculus K392", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n21.getNodeData().getTaxonomy().getScientificName().equals( "Mus musculus musculus" ) ) { System.out.println( n21.toString() ); return false; } final PhylogenyNode n23 = PhylogenyNode .createInstanceFromNhxString( "9EMVE_Nematostella_vectensis", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n23.getNodeData().getTaxonomy().getScientificName().equals( "Nematostella vectensis" ) ) { System.out.println( n23.toString() ); return false; } final PhylogenyNode n24 = PhylogenyNode .createInstanceFromNhxString( "9EMVE_Nematostella", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n24.getNodeData().getTaxonomy().getTaxonomyCode().equals( "9EMVE" ) ) { System.out.println( n24.toString() ); return false; } // final PhylogenyNode n25 = PhylogenyNode .createInstanceFromNhxString( "Nematostella_vectensis_NEMVE", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n25.getNodeData().getTaxonomy().getTaxonomyCode().equals( "NEMVE" ) ) { System.out.println( n25.toString() ); return false; } final PhylogenyNode n26 = PhylogenyNode .createInstanceFromNhxString( "Nematostella_vectensis_9EMVE", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n26.getNodeData().getTaxonomy().getScientificName().equals( "Nematostella vectensis" ) ) { System.out.println( n26.toString() ); return false; } final PhylogenyNode n27 = PhylogenyNode .createInstanceFromNhxString( "Nematostella_9EMVE", NHXParser.TAXONOMY_EXTRACTION.AGGRESSIVE ); if ( !n27.getNodeData().getTaxonomy().getTaxonomyCode().equals( "9EMVE" ) ) { System.out.println( n27.toString() ); return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testTreeCopy() { try { final String str_0 = "((((a,b),c),d)[&&NHX:S=lizards],e[&&NHX:S=reptiles])r[&&NHX:S=animals]"; final Phylogeny t0 = Phylogeny.createInstanceFromNhxString( str_0 ); final Phylogeny t1 = t0.copy(); if ( !t1.toNewHampshireX().equals( t0.toNewHampshireX() ) ) { return false; } if ( !t1.toNewHampshireX().equals( str_0 ) ) { return false; } t0.deleteSubtree( t0.getNode( "c" ), true ); t0.deleteSubtree( t0.getNode( "a" ), true ); t0.getRoot().getNodeData().getTaxonomy().setScientificName( "metazoa" ); t0.getNode( "b" ).setName( "Bee" ); if ( !t0.toNewHampshireX().equals( "((Bee,d)[&&NHX:S=lizards],e[&&NHX:S=reptiles])r[&&NHX:S=metazoa]" ) ) { return false; } if ( !t1.toNewHampshireX().equals( str_0 ) ) { return false; } t0.deleteSubtree( t0.getNode( "e" ), true ); t0.deleteSubtree( t0.getNode( "Bee" ), true ); t0.deleteSubtree( t0.getNode( "d" ), true ); if ( !t1.toNewHampshireX().equals( str_0 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace(); return false; } return true; } private static boolean testTreeMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((((A,B)ab,C)abc,D)abcd,E)", new NHXParser() )[ 0 ]; PhylogenyMethods.collapseSubtreeStructure( t0.getNode( "abcd" ) ); if ( !t0.toNewHampshireX().equals( "((A,B,C,D)abcd,E)" ) ) { System.out.println( t0.toNewHampshireX() ); return false; } final Phylogeny t1 = factory.create( "((((A:0.1,B)ab:0.2,C)abc:0.3,D)abcd:0.4,E)", new NHXParser() )[ 0 ]; PhylogenyMethods.collapseSubtreeStructure( t1.getNode( "abcd" ) ); if ( !isEqual( t1.getNode( "A" ).getDistanceToParent(), 0.6 ) ) { return false; } if ( !isEqual( t1.getNode( "B" ).getDistanceToParent(), 0.5 ) ) { return false; } if ( !isEqual( t1.getNode( "C" ).getDistanceToParent(), 0.3 ) ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testPhylogenyMethods() { try { final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance(); final Phylogeny t0 = factory.create( "((((A,B)ab,C)abc,D)abcd,E)r", new NHXParser() )[ 0 ]; if ( PhylogenyMethods.calculateLevel( t0.getNode( "A" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "B" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "ab" ) ) != 1 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "C" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "abc" ) ) != 2 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "D" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "abcd" ) ) != 3 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "E" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t0.getNode( "r" ) ) != 4 ) { return false; } final Phylogeny t1 = factory.create( "((((A,B)ab,C)abc,D)abcd,E,((((((X)1)2)3)4)5)6)r", new NHXParser() )[ 0 ]; if ( PhylogenyMethods.calculateLevel( t1.getNode( "r" ) ) != 7 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "X" ) ) != 0 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "6" ) ) != 6 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "5" ) ) != 5 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "4" ) ) != 4 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "3" ) ) != 3 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "2" ) ) != 2 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "1" ) ) != 1 ) { return false; } if ( PhylogenyMethods.calculateLevel( t1.getNode( "abcd" ) ) != 3 ) { return false; } } catch ( final Exception e ) { e.printStackTrace( System.out ); return false; } return true; } private static boolean testUniprotEntryRetrieval() { try { final SequenceDatabaseEntry entry = SequenceDbWsTools.obtainUniProtEntry( "P12345", 5000 ); if ( !entry.getAccession().equals( "P12345" ) ) { return false; } if ( !entry.getTaxonomyScientificName().equals( "Oryctolagus cuniculus" ) ) { return false; } if ( !entry.getSequenceName().equals( "Aspartate aminotransferase, mitochondrial" ) ) { return false; } if ( !entry.getSequenceSymbol().equals( "mAspAT" ) ) { return false; } if ( !entry.getGeneName().equals( "GOT2" ) ) { return false; } if ( !entry.getTaxonomyIdentifier().equals( "9986" ) ) { return false; } if ( entry.getMolecularSequence() == null ) { return false; } if ( !entry.getMolecularSequence().getMolecularSequenceAsString() .startsWith( "MALLHSARVLSGVASAFHPGLAAAASARASSWWAHVEMGPPDPILGVTEAYKRDTNSKKMNLGVGAYRDDNGKPYVLPSVRKAEAQIAAKGLDKEYLPIGGLAEFCRASAELALGENSEV" ) || !entry.getMolecularSequence().getMolecularSequenceAsString().endsWith( "LAHAIHQVTK" ) ) { System.out.println( "got: " + entry.getMolecularSequence().getMolecularSequenceAsString() ); System.out.println( "expected something else." ); return false; } } catch ( final IOException e ) { System.out.println(); System.out.println( "the following might be due to absence internet connection:" ); e.printStackTrace( System.out ); return true; } catch ( final NullPointerException f ) { f.printStackTrace( System.out ); return false; } catch ( final Exception e ) { return false; } return true; } private static boolean testUniprotTaxonomySearch() { try { List results = SequenceDbWsTools.getTaxonomiesFromCommonNameStrict( "starlet sea anemone", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "NEMVE" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "starlet sea anemone" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "45351" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Nematostella vectensis" ) ) { return false; } results = null; results = SequenceDbWsTools.getTaxonomiesFromScientificNameStrict( "Nematostella vectensis", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "NEMVE" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "starlet sea anemone" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "45351" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Nematostella vectensis" ) ) { return false; } results = null; results = SequenceDbWsTools.getTaxonomiesFromId( "45351", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "NEMVE" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "starlet sea anemone" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "45351" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Nematostella vectensis" ) ) { return false; } results = null; results = SequenceDbWsTools.getTaxonomiesFromTaxonomyCode( "NEMVE", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "NEMVE" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "starlet sea anemone" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "45351" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Nematostella vectensis" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( 1 ).equals( "Eukaryota" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( 2 ).equals( "Metazoa" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( results.get( 0 ).getLineage().size() - 1 ) .equals( "Nematostella vectensis" ) ) { System.out.println( results.get( 0 ).getLineage() ); return false; } // results = null; results = SequenceDbWsTools.getTaxonomiesFromScientificNameStrict( "Xenopus tropicalis", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "XENTR" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "Western clawed frog" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "8364" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Xenopus tropicalis" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( results.get( 0 ).getLineage().size() - 1 ) .equals( "Xenopus tropicalis" ) ) { System.out.println( results.get( 0 ).getLineage() ); return false; } // results = null; results = SequenceDbWsTools.getTaxonomiesFromId( "8364", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "XENTR" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "Western clawed frog" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "8364" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Xenopus tropicalis" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( results.get( 0 ).getLineage().size() - 1 ) .equals( "Xenopus tropicalis" ) ) { System.out.println( results.get( 0 ).getLineage() ); return false; } // results = null; results = SequenceDbWsTools.getTaxonomiesFromTaxonomyCode( "XENTR", 10 ); if ( results.size() != 1 ) { return false; } if ( !results.get( 0 ).getCode().equals( "XENTR" ) ) { return false; } if ( !results.get( 0 ).getCommonName().equalsIgnoreCase( "Western clawed frog" ) ) { return false; } if ( !results.get( 0 ).getId().equalsIgnoreCase( "8364" ) ) { return false; } if ( !results.get( 0 ).getRank().equalsIgnoreCase( "species" ) ) { return false; } if ( !results.get( 0 ).getScientificName().equals( "Xenopus tropicalis" ) ) { return false; } if ( !results.get( 0 ).getLineage().get( results.get( 0 ).getLineage().size() - 1 ) .equals( "Xenopus tropicalis" ) ) { System.out.println( results.get( 0 ).getLineage() ); return false; } } catch ( final IOException e ) { System.out.println(); System.out.println( "the following might be due to absence internet connection:" ); e.printStackTrace( System.out ); return true; } catch ( final Exception e ) { return false; } return true; } }