// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
//
// Contact: phylosoft @ gmail . com
-// WWW: www.phylosoft.org/forester
+// WWW: https://sites.google.com/site/cmzmasek/home/software/forester
package org.forester.rio;
import java.io.File;
import java.io.FileNotFoundException;
import java.io.IOException;
+import java.text.DecimalFormat;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.List;
import java.util.Set;
+import java.util.SortedSet;
+import java.util.TreeSet;
import org.forester.datastructures.IntMatrix;
+import org.forester.io.parsers.IteratingPhylogenyParser;
import org.forester.io.parsers.PhylogenyParser;
+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.util.ParserUtils;
import org.forester.phylogeny.Phylogeny;
import org.forester.phylogeny.PhylogenyMethods;
import org.forester.phylogeny.PhylogenyNode;
+import org.forester.phylogeny.data.Taxonomy;
import org.forester.phylogeny.factories.ParserBasedPhylogenyFactory;
import org.forester.phylogeny.factories.PhylogenyFactory;
+import org.forester.sdi.GSDI;
import org.forester.sdi.GSDIR;
-import org.forester.sdi.SDI.ALGORITHM;
-import org.forester.sdi.SDI.TaxonomyComparisonBase;
import org.forester.sdi.SDIException;
import org.forester.sdi.SDIR;
+import org.forester.sdi.SDIutil;
+import org.forester.sdi.SDIutil.ALGORITHM;
+import org.forester.sdi.SDIutil.TaxonomyComparisonBase;
+import org.forester.util.BasicDescriptiveStatistics;
import org.forester.util.ForesterUtil;
public final class RIO {
- private final static boolean ROOT_BY_MINIMIZING_SUM_OF_DUPS = true;
- private final static boolean ROOT_BY_MINIMIZING_TREE_HEIGHT = true;
- private Phylogeny[] _analyzed_gene_trees;
- private List<PhylogenyNode> _removed_gene_tree_nodes;
- private int _samples;
- private int _ext_nodes;
- private TaxonomyComparisonBase _gsdir_tax_comp_base;
+ public static final int DEFAULT_RANGE = -1;
+ private static final int END_OF_GT = Integer.MAX_VALUE;
+ private static IntMatrix _m;
+ private Phylogeny[] _analyzed_gene_trees;
+ private List<PhylogenyNode> _removed_gene_tree_nodes;
+ private int _ext_nodes;
+ private int _int_nodes;
+ private TaxonomyComparisonBase _gsdir_tax_comp_base;
+ private final StringBuilder _log;
+ private final BasicDescriptiveStatistics _duplications_stats;
+ private final boolean _produce_log;
+ private final boolean _verbose;
+ private final REROOTING _rerooting;
+ private final Phylogeny _species_tree;
+ private Phylogeny _min_dub_gene_tree;
- public RIO( final File gene_trees_file, final Phylogeny species_tree, final ALGORITHM algorithm )
- throws IOException, SDIException, RIOException {
- init();
- inferOrthologs( gene_trees_file, species_tree, algorithm );
+ private RIO( final IteratingPhylogenyParser p,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ int first,
+ int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException, RIOException {
+ if ( ( last == DEFAULT_RANGE ) && ( first >= 0 ) ) {
+ last = END_OF_GT;
+ }
+ else if ( ( first == DEFAULT_RANGE ) && ( last >= 0 ) ) {
+ first = 0;
+ }
+ removeSingleDescendentsNodes( species_tree, verbose );
+ p.reset();
+ checkPreconditions( p, species_tree, rerooting, outgroup, first, last );
+ _produce_log = produce_log;
+ _verbose = verbose;
+ _rerooting = rerooting;
+ _ext_nodes = -1;
+ _int_nodes = -1;
+ _log = new StringBuilder();
+ _gsdir_tax_comp_base = null;
+ _analyzed_gene_trees = null;
+ _removed_gene_tree_nodes = null;
+ _duplications_stats = new BasicDescriptiveStatistics();
+ p.reset();
+ inferOrthologs( p, species_tree, algorithm, outgroup, first, last, transfer_taxonomy );
+ _species_tree = species_tree;
+ }
+
+ private RIO( final Phylogeny[] gene_trees,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ int first,
+ int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException, RIOException {
+ if ( ( last == DEFAULT_RANGE ) && ( first >= 0 ) ) {
+ last = gene_trees.length - 1;
+ }
+ else if ( ( first == DEFAULT_RANGE ) && ( last >= 0 ) ) {
+ first = 0;
+ }
+ removeSingleDescendentsNodes( species_tree, verbose );
+ checkPreconditions( gene_trees, species_tree, rerooting, outgroup, first, last );
+ _produce_log = produce_log;
+ _verbose = verbose;
+ _rerooting = rerooting;
+ _ext_nodes = -1;
+ _int_nodes = -1;
+ _log = new StringBuilder();
+ _gsdir_tax_comp_base = null;
+ _analyzed_gene_trees = null;
+ _removed_gene_tree_nodes = null;
+ _duplications_stats = new BasicDescriptiveStatistics();
+ inferOrthologs( gene_trees, species_tree, algorithm, outgroup, first, last, transfer_taxonomy );
+ _species_tree = species_tree;
}
public final Phylogeny[] getAnalyzedGeneTrees() {
return _analyzed_gene_trees;
}
+ public final BasicDescriptiveStatistics getDuplicationsStatistics() {
+ return _duplications_stats;
+ }
+
/**
* Returns the numbers of number of ext nodes in gene trees analyzed (after
* stripping).
return _ext_nodes;
}
- public final int getNumberOfSamples() {
- return _samples;
+ public final TaxonomyComparisonBase getGSDIRtaxCompBase() {
+ return _gsdir_tax_comp_base;
+ }
+
+ /**
+ * Returns the numbers of number of int nodes in gene trees analyzed (after
+ * stripping).
+ *
+ * @return number of int nodes in gene trees analyzed (after stripping)
+ */
+ public final int getIntNodesOfAnalyzedGeneTrees() {
+ return _int_nodes;
+ }
+
+ public final StringBuilder getLog() {
+ return _log;
+ }
+
+ final public Phylogeny getMinDuplicationsGeneTree() {
+ return _min_dub_gene_tree;
+ }
+
+ public final IntMatrix getOrthologTable() {
+ return _m;
}
public final List<PhylogenyNode> getRemovedGeneTreeNodes() {
return _removed_gene_tree_nodes;
}
- private final void inferOrthologs( final File gene_trees_file,
+ public final Phylogeny getSpeciesTree() {
+ return _species_tree;
+ }
+
+ private final void inferOrthologs( final IteratingPhylogenyParser parser,
final Phylogeny species_tree,
- final ALGORITHM algorithm ) throws SDIException, RIOException,
+ final ALGORITHM algorithm,
+ final String outgroup,
+ int first,
+ final int last,
+ final boolean transfer_taxonomy ) throws SDIException, RIOException,
FileNotFoundException, IOException {
- // Read in first tree to get its sequence names
- // and strip species_tree.
- final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance();
- final PhylogenyParser p = ParserUtils.createParserDependingOnFileType( gene_trees_file, true );
- if ( p instanceof NHXParser ) {
- final NHXParser nhx = ( NHXParser ) p;
- nhx.setReplaceUnderscores( false );
- nhx.setIgnoreQuotes( true );
- nhx.setTaxonomyExtraction( NHXParser.TAXONOMY_EXTRACTION.YES );
+ if ( !parser.hasNext() ) {
+ throw new RIOException( "no gene trees to analyze" );
}
- final Phylogeny[] gene_trees = factory.create( gene_trees_file, p );
- // Removes from species_tree all species not found in gene_tree.
- final List<PhylogenyNode> _removed_species_tree_ext_nodes = PhylogenyMethods
- .taxonomyBasedDeletionOfExternalNodes( gene_trees[ 0 ], species_tree );
- if ( species_tree.isEmpty() ) {
- throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ if ( log() ) {
+ preLog( -1, species_tree, algorithm, outgroup );
}
- _analyzed_gene_trees = new Phylogeny[ gene_trees.length ];
- int i = 0;
+ if ( _verbose ) {
+ System.out.println();
+ }
+ final DecimalFormat pf = new java.text.DecimalFormat( "000" );
int gene_tree_ext_nodes = 0;
- for( final Phylogeny gt : gene_trees ) {
- if ( algorithm == ALGORITHM.SDIR ) {
- // Removes from gene_tree all species not found in species_tree.
- PhylogenyMethods.taxonomyBasedDeletionOfExternalNodes( species_tree, gt );
+ int i = 0;
+ int counter = 0;
+ final boolean no_range = ( first < 0 ) || ( last < first );
+ while ( parser.hasNext() ) {
+ final Phylogeny gt = parser.next();
+ if ( no_range || ( ( i >= first ) && ( i <= last ) ) ) {
if ( gt.isEmpty() ) {
- throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ throw new RIOException( "gene tree #" + i + " is empty" );
+ }
+ if ( gt.getNumberOfExternalNodes() == 1 ) {
+ throw new RIOException( "gene tree #" + i + " has only one external node" );
+ }
+ if ( _verbose ) {
+ ForesterUtil.updateProgress( i, pf );
}
- if ( i == 0 ) {
+ if ( counter == 0 ) {
+ if ( algorithm == ALGORITHM.SDIR ) {
+ // Removes from species_tree all species not found in gene_tree.
+ PhylogenyMethods.taxonomyBasedDeletionOfExternalNodes( gt, species_tree );
+ if ( species_tree.isEmpty() ) {
+ throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ }
+ }
gene_tree_ext_nodes = gt.getNumberOfExternalNodes();
}
else if ( gene_tree_ext_nodes != gt.getNumberOfExternalNodes() ) {
- throw new RIOException( "(cleaned up) gene tree #" + ( i + 1 )
- + " has a different number of external nodes (" + gt.getNumberOfExternalNodes()
- + ") than those gene trees preceding it (" + gene_tree_ext_nodes + ")" );
+ throw new RIOException( "gene tree #" + i + " has a different number of external nodes ("
+ + gt.getNumberOfExternalNodes() + ") than the preceding gene tree(s) ("
+ + gene_tree_ext_nodes + ")" );
+ }
+ if ( algorithm == ALGORITHM.SDIR ) {
+ // Removes from gene_tree all species not found in species_tree.
+ PhylogenyMethods.taxonomyBasedDeletionOfExternalNodes( species_tree, gt );
+ if ( gt.isEmpty() ) {
+ throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ }
}
+ final Phylogeny analyzed_gt = performOrthologInference( gt,
+ species_tree,
+ algorithm,
+ outgroup,
+ counter,
+ transfer_taxonomy );
+ RIO.calculateOrthologTable( analyzed_gt, true, counter );
+ ++counter;
}
- _analyzed_gene_trees[ i ] = performOrthologInference( gt, species_tree, algorithm, i );
++i;
}
- setNumberOfSamples( gene_trees.length );
+ if ( ( first >= 0 ) && ( counter == 0 ) && ( i > 0 ) ) {
+ throw new RIOException( "attempt to analyze first gene tree #" + first + " in a set of " + i );
+ }
+ if ( no_range ) {
+ first = 0;
+ }
+ if ( log() ) {
+ postLog( species_tree, first, first + counter - 1 );
+ }
+ if ( _verbose ) {
+ System.out.println();
+ System.out.println();
+ }
}
- private final void init() {
- _samples = 1;
- _ext_nodes = 0;
+ private final void inferOrthologs( final Phylogeny[] gene_trees,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean transfer_taxonomy ) throws SDIException, RIOException,
+ FileNotFoundException, IOException {
+ if ( algorithm == ALGORITHM.SDIR ) {
+ // Removes from species_tree all species not found in gene_tree.
+ PhylogenyMethods.taxonomyBasedDeletionOfExternalNodes( gene_trees[ 0 ], species_tree );
+ if ( species_tree.isEmpty() ) {
+ throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ }
+ }
+ final Phylogeny[] my_gene_trees;
+ if ( ( first >= 0 ) && ( last >= first ) && ( last < gene_trees.length ) ) {
+ my_gene_trees = new Phylogeny[ ( 1 + last ) - first ];
+ int c = 0;
+ for( int i = first; i <= last; ++i ) {
+ my_gene_trees[ c++ ] = gene_trees[ i ];
+ }
+ }
+ else {
+ my_gene_trees = gene_trees;
+ }
+ if ( log() ) {
+ preLog( gene_trees.length, species_tree, algorithm, outgroup );
+ }
+ if ( _verbose && ( my_gene_trees.length >= 4 ) ) {
+ System.out.println();
+ }
+ _analyzed_gene_trees = new Phylogeny[ my_gene_trees.length ];
+ int gene_tree_ext_nodes = 0;
+ for( int i = 0; i < my_gene_trees.length; ++i ) {
+ final Phylogeny gt = my_gene_trees[ i ];
+ if ( gt.isEmpty() ) {
+ throw new RIOException( "gene tree #" + i + " is empty" );
+ }
+ if ( gt.getNumberOfExternalNodes() == 1 ) {
+ throw new RIOException( "gene tree #" + i + " has only one external node" );
+ }
+ if ( _verbose && ( my_gene_trees.length > 4 ) ) {
+ ForesterUtil.updateProgress( ( ( double ) i ) / my_gene_trees.length );
+ }
+ if ( i == 0 ) {
+ gene_tree_ext_nodes = gt.getNumberOfExternalNodes();
+ }
+ else if ( gene_tree_ext_nodes != gt.getNumberOfExternalNodes() ) {
+ throw new RIOException( "gene tree #" + i + " has a different number of external nodes ("
+ + gt.getNumberOfExternalNodes() + ") than the preceding gene tree(s) (" + gene_tree_ext_nodes
+ + ")" );
+ }
+ if ( algorithm == ALGORITHM.SDIR ) {
+ // Removes from gene_tree all species not found in species_tree.
+ PhylogenyMethods.taxonomyBasedDeletionOfExternalNodes( species_tree, gt );
+ if ( gt.isEmpty() ) {
+ throw new RIOException( "failed to establish species based mapping between gene and species trees" );
+ }
+ }
+ _analyzed_gene_trees[ i ] = performOrthologInference( gt,
+ species_tree,
+ algorithm,
+ outgroup,
+ i,
+ transfer_taxonomy );
+ }
+ if ( log() ) {
+ postLog( species_tree, first, last );
+ }
+ if ( _verbose && ( my_gene_trees.length > 4 ) ) {
+ System.out.println();
+ System.out.println();
+ }
+ }
+
+ private final boolean log() {
+ return _produce_log;
+ }
+
+ private final void log( final String s ) {
+ _log.append( s );
+ _log.append( ForesterUtil.LINE_SEPARATOR );
+ }
+
+ private final void logRemovedGeneTreeNodes() {
+ log( "Species stripped from gene trees:" );
+ final SortedSet<String> rn = new TreeSet<String>();
+ for( final PhylogenyNode n : getRemovedGeneTreeNodes() ) {
+ final Taxonomy t = n.getNodeData().getTaxonomy();
+ switch ( getGSDIRtaxCompBase() ) {
+ case CODE: {
+ rn.add( t.getTaxonomyCode() );
+ break;
+ }
+ case ID: {
+ rn.add( t.getIdentifier().toString() );
+ break;
+ }
+ case SCIENTIFIC_NAME: {
+ rn.add( t.getScientificName() );
+ break;
+ }
+ }
+ }
+ for( final String s : rn ) {
+ log( s );
+ }
+ log( "" );
}
private final Phylogeny performOrthologInference( final Phylogeny gene_tree,
final Phylogeny species_tree,
final ALGORITHM algorithm,
- final int i ) throws SDIException, RIOException {
+ final String outgroup,
+ final int i,
+ final boolean transfer_taxonomy ) throws SDIException,
+ RIOException {
final Phylogeny assigned_tree;
switch ( algorithm ) {
case SDIR: {
- final SDIR sdir = new SDIR();
- assigned_tree = sdir.infer( gene_tree,
- species_tree,
- false,
- RIO.ROOT_BY_MINIMIZING_SUM_OF_DUPS,
- RIO.ROOT_BY_MINIMIZING_TREE_HEIGHT,
- true,
- 1 )[ 0 ];
+ assigned_tree = performOrthologInferenceBySDI( gene_tree, species_tree );
break;
}
case GSDIR: {
- final GSDIR gsdir = new GSDIR( gene_tree, species_tree, true, i == 0 );
- assigned_tree = gsdir.getMinDuplicationsSumGeneTrees().get( 0 );
- _gsdir_tax_comp_base = gsdir.getTaxCompBase();
+ assigned_tree = performOrthologInferenceByGSDI( gene_tree, species_tree, outgroup, i, transfer_taxonomy );
break;
}
default: {
throw new IllegalArgumentException( "illegal algorithm: " + algorithm );
}
}
- setExtNodesOfAnalyzedGeneTrees( assigned_tree.getNumberOfExternalNodes() );
+ if ( i == 0 ) {
+ _ext_nodes = assigned_tree.getNumberOfExternalNodes();
+ _int_nodes = assigned_tree.getNumberOfInternalNodes();
+ }
+ else if ( _ext_nodes != assigned_tree.getNumberOfExternalNodes() ) {
+ throw new RIOException( "after stripping gene tree #" + i + " has a different number of external nodes ("
+ + assigned_tree.getNumberOfExternalNodes() + ") than the preceding gene tree(s) (" + _ext_nodes
+ + ")" );
+ }
+ return assigned_tree;
+ }
+
+ private final Phylogeny performOrthologInferenceByGSDI( final Phylogeny gene_tree,
+ final Phylogeny species_tree,
+ final String outgroup,
+ final int i,
+ final boolean transfer_taxonomy ) throws SDIException,
+ RIOException {
+ final Phylogeny assigned_tree;
+ final int dups;
+ if ( _rerooting == REROOTING.BY_ALGORITHM ) {
+ final GSDIR gsdir = new GSDIR( gene_tree, species_tree, true, i == 0, transfer_taxonomy );
+ assigned_tree = gsdir.getMinDuplicationsSumGeneTree();
+ if ( i == 0 ) {
+ _removed_gene_tree_nodes = gsdir.getStrippedExternalGeneTreeNodes();
+ for( final PhylogenyNode r : _removed_gene_tree_nodes ) {
+ if ( !r.getNodeData().isHasTaxonomy() ) {
+ throw new RIOException( "node with no (appropriate) taxonomic information found in gene tree #"
+ + i + ": " + r.toString() );
+ }
+ }
+ }
+ if ( i == 0 ) {
+ _gsdir_tax_comp_base = gsdir.getTaxCompBase();
+ }
+ dups = gsdir.getMinDuplicationsSum();
+ }
+ else {
+ if ( _rerooting == REROOTING.MIDPOINT ) {
+ PhylogenyMethods.midpointRoot( gene_tree );
+ }
+ else if ( _rerooting == REROOTING.OUTGROUP ) {
+ final PhylogenyNode n = gene_tree.getNode( outgroup );
+ gene_tree.reRoot( n );
+ }
+ final GSDI gsdi = new GSDI( gene_tree, species_tree, true, true, true, transfer_taxonomy );
+ _removed_gene_tree_nodes = gsdi.getStrippedExternalGeneTreeNodes();
+ for( final PhylogenyNode r : _removed_gene_tree_nodes ) {
+ if ( !r.getNodeData().isHasTaxonomy() ) {
+ throw new RIOException( "node with no (appropriate) taxonomic information found in gene tree #" + i
+ + ": " + r.toString() );
+ }
+ }
+ assigned_tree = gene_tree;
+ if ( i == 0 ) {
+ _gsdir_tax_comp_base = gsdi.getTaxCompBase();
+ }
+ dups = gsdi.getDuplicationsSum();
+ }
+ if ( ( i == 0 ) || ( dups < _duplications_stats.getMin() ) ) {
+ _min_dub_gene_tree = assigned_tree;
+ }
+ _duplications_stats.addValue( dups );
return assigned_tree;
}
- private final void setExtNodesOfAnalyzedGeneTrees( final int i ) {
- _ext_nodes = i;
+ private final Phylogeny performOrthologInferenceBySDI( final Phylogeny gene_tree, final Phylogeny species_tree )
+ throws SDIException {
+ final SDIR sdir = new SDIR();
+ return sdir.infer( gene_tree, species_tree, false, true, true, true, 1 )[ 0 ];
}
- private final void setNumberOfSamples( int i ) {
- if ( i < 1 ) {
- i = 1;
+ private final void postLog( final Phylogeny species_tree, final int first, final int last ) {
+ log( "" );
+ if ( ( getRemovedGeneTreeNodes() != null ) && ( getRemovedGeneTreeNodes().size() > 0 ) ) {
+ logRemovedGeneTreeNodes();
}
- _samples = i;
+ log( "Species tree external nodes (after stripping) : " + species_tree.getNumberOfExternalNodes() );
+ log( "Species tree polytomies (after stripping) : "
+ + PhylogenyMethods.countNumberOfPolytomies( species_tree ) );
+ log( "Taxonomy linking based on : " + getGSDIRtaxCompBase() );
+ final java.text.DecimalFormat df = new java.text.DecimalFormat( "0.#" );
+ if ( ( first >= 0 ) && ( last >= 0 ) ) {
+ log( "Gene trees analyzed range : " + first + "-" + last );
+ }
+ log( "Gene trees analyzed : " + _duplications_stats.getN() );
+ log( "Mean number of duplications : " + df.format( _duplications_stats.arithmeticMean() )
+ + " (sd: " + df.format( _duplications_stats.sampleStandardDeviation() ) + ")" + " ("
+ + df.format( ( 100.0 * _duplications_stats.arithmeticMean() ) / getIntNodesOfAnalyzedGeneTrees() )
+ + "%)" );
+ if ( _duplications_stats.getN() > 3 ) {
+ log( "Median number of duplications : " + df.format( _duplications_stats.median() )
+ + " (" + df.format( ( 100.0 * _duplications_stats.median() ) / getIntNodesOfAnalyzedGeneTrees() )
+ + "%)" );
+ }
+ log( "Minimum duplications : " + ( int ) _duplications_stats.getMin() + " ("
+ + df.format( ( 100.0 * _duplications_stats.getMin() ) / getIntNodesOfAnalyzedGeneTrees() ) + "%)" );
+ log( "Maximum duplications : " + ( int ) _duplications_stats.getMax() + " ("
+ + df.format( ( 100.0 * _duplications_stats.getMax() ) / getIntNodesOfAnalyzedGeneTrees() ) + "%)" );
+ log( "Gene tree internal nodes : " + getIntNodesOfAnalyzedGeneTrees() );
+ log( "Gene tree external nodes : " + getExtNodesOfAnalyzedGeneTrees() );
+ }
+
+ private final void preLog( final int gene_trees,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final String outgroup ) {
+ if ( gene_trees > 0 ) {
+ log( "Number of gene trees (total) : " + gene_trees );
+ }
+ log( "Algorithm : " + algorithm );
+ log( "Species tree external nodes (prior to stripping): " + species_tree.getNumberOfExternalNodes() );
+ log( "Species tree polytomies (prior to stripping) : "
+ + PhylogenyMethods.countNumberOfPolytomies( species_tree ) );
+ String rs = "";
+ switch ( _rerooting ) {
+ case BY_ALGORITHM: {
+ rs = "minimizing duplications";
+ break;
+ }
+ case MIDPOINT: {
+ rs = "midpoint";
+ break;
+ }
+ case OUTGROUP: {
+ rs = "outgroup: " + outgroup;
+ break;
+ }
+ case NONE: {
+ rs = "none";
+ break;
+ }
+ }
+ log( "Re-rooting : " + rs );
}
public final static IntMatrix calculateOrthologTable( final Phylogeny[] analyzed_gene_trees, final boolean sort )
throws RIOException {
final List<String> labels = new ArrayList<String>();
final Set<String> labels_set = new HashSet<String>();
- String label;
for( final PhylogenyNode n : analyzed_gene_trees[ 0 ].getExternalNodes() ) {
- if ( n.getNodeData().isHasSequence() && !ForesterUtil.isEmpty( n.getNodeData().getSequence().getName() ) ) {
- label = n.getNodeData().getSequence().getName();
- }
- else if ( n.getNodeData().isHasSequence()
- && !ForesterUtil.isEmpty( n.getNodeData().getSequence().getSymbol() ) ) {
- label = n.getNodeData().getSequence().getSymbol();
- }
- else if ( !ForesterUtil.isEmpty( n.getName() ) ) {
- label = n.getName();
- }
- else {
- throw new IllegalArgumentException( "node " + n + " has no appropriate label" );
- }
- if ( labels_set.contains( label ) ) {
- throw new IllegalArgumentException( "label " + label + " is not unique" );
- }
+ final String label = obtainLabel( labels_set, n );
labels_set.add( label );
labels.add( label );
}
int counter = 0;
for( final Phylogeny gt : analyzed_gene_trees ) {
counter++;
- PhylogenyMethods.preOrderReId( gt );
- final HashMap<String, PhylogenyNode> map = PhylogenyMethods.createNameToExtNodeMap( gt );
- for( int x = 0; x < m.size(); ++x ) {
- final String mx = m.getLabel( x );
- final PhylogenyNode nx = map.get( mx );
- if ( nx == null ) {
- throw new RIOException( "node \"" + mx + "\" not present in gene tree #" + counter );
+ updateCounts( m, counter, gt );
+ }
+ return m;
+ }
+
+ public final static RIO executeAnalysis( final File gene_trees_file,
+ final File species_tree_file,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ final Phylogeny[] gene_trees = parseGeneTrees( gene_trees_file );
+ if ( gene_trees.length < 1 ) {
+ throw new RIOException( "\"" + gene_trees_file + "\" is devoid of appropriate gene trees" );
+ }
+ final Phylogeny species_tree = SDIutil.parseSpeciesTree( gene_trees[ 0 ],
+ species_tree_file,
+ false,
+ true,
+ TAXONOMY_EXTRACTION.NO );
+ return new RIO( gene_trees,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ first,
+ last,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final File gene_trees_file,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( parseGeneTrees( gene_trees_file ),
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ DEFAULT_RANGE,
+ DEFAULT_RANGE,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final File gene_trees_file,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( parseGeneTrees( gene_trees_file ),
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ first,
+ last,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final IteratingPhylogenyParser p,
+ final File species_tree_file,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ final Phylogeny g0 = p.next();
+ if ( ( g0 == null ) || g0.isEmpty() || ( g0.getNumberOfExternalNodes() < 2 ) ) {
+ throw new RIOException( "input file does not seem to contain any gene trees" );
+ }
+ final Phylogeny species_tree = SDIutil.parseSpeciesTree( g0,
+ species_tree_file,
+ false,
+ true,
+ TAXONOMY_EXTRACTION.NO );
+ p.reset();
+ return new RIO( p,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ first,
+ last,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final IteratingPhylogenyParser p,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( p,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ DEFAULT_RANGE,
+ DEFAULT_RANGE,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final IteratingPhylogenyParser p,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( p,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ first,
+ last,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final Phylogeny[] gene_trees, final Phylogeny species_tree )
+ throws IOException, SDIException, RIOException {
+ return new RIO( gene_trees,
+ species_tree,
+ ALGORITHM.GSDIR,
+ REROOTING.BY_ALGORITHM,
+ null,
+ DEFAULT_RANGE,
+ DEFAULT_RANGE,
+ false,
+ false,
+ false );
+ }
+
+ public final static RIO executeAnalysis( final Phylogeny[] gene_trees,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( gene_trees,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ DEFAULT_RANGE,
+ DEFAULT_RANGE,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ public final static RIO executeAnalysis( final Phylogeny[] gene_trees,
+ final Phylogeny species_tree,
+ final ALGORITHM algorithm,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last,
+ final boolean produce_log,
+ final boolean verbose,
+ final boolean transfer_taxonomy ) throws IOException, SDIException,
+ RIOException {
+ return new RIO( gene_trees,
+ species_tree,
+ algorithm,
+ rerooting,
+ outgroup,
+ first,
+ last,
+ produce_log,
+ verbose,
+ transfer_taxonomy );
+ }
+
+ private final static void calculateOrthologTable( final Phylogeny g, final boolean sort, final int counter )
+ throws RIOException {
+ if ( counter == 0 ) {
+ final List<String> labels = new ArrayList<String>();
+ final Set<String> labels_set = new HashSet<String>();
+ for( final PhylogenyNode n : g.getExternalNodes() ) {
+ final String label = obtainLabel( labels_set, n );
+ labels_set.add( label );
+ labels.add( label );
+ }
+ if ( sort ) {
+ Collections.sort( labels );
+ }
+ _m = new IntMatrix( labels );
+ }
+ updateCounts( _m, counter, g );
+ }
+
+ private final static void checkPreconditions( final IteratingPhylogenyParser p,
+ final Phylogeny species_tree,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last ) throws RIOException, IOException {
+ final Phylogeny g0 = p.next();
+ if ( ( g0 == null ) || g0.isEmpty() ) {
+ throw new RIOException( "input file does not seem to contain any gene trees" );
+ }
+ if ( g0.getNumberOfExternalNodes() < 2 ) {
+ throw new RIOException( "input file does not seem to contain any useable gene trees" );
+ }
+ if ( !species_tree.isRooted() ) {
+ throw new RIOException( "species tree is not rooted" );
+ }
+ if ( !( ( last == DEFAULT_RANGE ) && ( first == DEFAULT_RANGE ) )
+ && ( ( last < first ) || ( last < 0 ) || ( first < 0 ) ) ) {
+ throw new RIOException( "attempt to set range (0-based) of gene to analyze to: from " + first + " to "
+ + last );
+ }
+ if ( ( rerooting == REROOTING.OUTGROUP ) && ForesterUtil.isEmpty( outgroup ) ) {
+ throw new RIOException( "outgroup not set for midpoint rooting" );
+ }
+ if ( ( rerooting != REROOTING.OUTGROUP ) && !ForesterUtil.isEmpty( outgroup ) ) {
+ throw new RIOException( "outgroup only used for midpoint rooting" );
+ }
+ if ( ( rerooting == REROOTING.MIDPOINT ) && ( PhylogenyMethods.calculateMaxDistanceToRoot( g0 ) <= 0 ) ) {
+ throw new RIOException( "attempt to use midpoint rooting on gene trees which seem to have no (positive) branch lengths (cladograms)" );
+ }
+ if ( rerooting == REROOTING.OUTGROUP ) {
+ try {
+ g0.getNode( outgroup );
+ }
+ catch ( final IllegalArgumentException e ) {
+ throw new RIOException( "cannot perform re-rooting by outgroup: " + e.getLocalizedMessage() );
+ }
+ }
+ }
+
+ private final static void checkPreconditions( final Phylogeny[] gene_trees,
+ final Phylogeny species_tree,
+ final REROOTING rerooting,
+ final String outgroup,
+ final int first,
+ final int last ) throws RIOException {
+ if ( !species_tree.isRooted() ) {
+ throw new RIOException( "species tree is not rooted" );
+ }
+ if ( !( ( last == DEFAULT_RANGE ) && ( first == DEFAULT_RANGE ) )
+ && ( ( last < first ) || ( last >= gene_trees.length ) || ( last < 0 ) || ( first < 0 ) ) ) {
+ throw new RIOException( "attempt to set range (0-based) of gene to analyze to: from " + first + " to "
+ + last + " (out of " + gene_trees.length + ")" );
+ }
+ if ( ( rerooting == REROOTING.OUTGROUP ) && ForesterUtil.isEmpty( outgroup ) ) {
+ throw new RIOException( "outgroup not set for midpoint rooting" );
+ }
+ if ( ( rerooting != REROOTING.OUTGROUP ) && !ForesterUtil.isEmpty( outgroup ) ) {
+ throw new RIOException( "outgroup only used for midpoint rooting" );
+ }
+ if ( ( rerooting == REROOTING.MIDPOINT )
+ && ( PhylogenyMethods.calculateMaxDistanceToRoot( gene_trees[ 0 ] ) <= 0 ) ) {
+ throw new RIOException( "attempt to use midpoint rooting on gene trees which seem to have no (positive) branch lengths (cladograms)" );
+ }
+ if ( rerooting == REROOTING.OUTGROUP ) {
+ try {
+ gene_trees[ 0 ].getNode( outgroup );
+ }
+ catch ( final IllegalArgumentException e ) {
+ throw new RIOException( "cannot perform re-rooting by outgroup: " + e.getLocalizedMessage() );
+ }
+ }
+ }
+
+ private final static String obtainLabel( final Set<String> labels_set, final PhylogenyNode n ) throws RIOException {
+ String label;
+ if ( n.getNodeData().isHasSequence() && !ForesterUtil.isEmpty( n.getNodeData().getSequence().getName() ) ) {
+ label = n.getNodeData().getSequence().getName();
+ }
+ else if ( n.getNodeData().isHasSequence() && !ForesterUtil.isEmpty( n.getNodeData().getSequence().getSymbol() ) ) {
+ label = n.getNodeData().getSequence().getSymbol();
+ }
+ else if ( n.getNodeData().isHasSequence()
+ && !ForesterUtil.isEmpty( n.getNodeData().getSequence().getGeneName() ) ) {
+ label = n.getNodeData().getSequence().getGeneName();
+ }
+ else if ( !ForesterUtil.isEmpty( n.getName() ) ) {
+ label = n.getName();
+ }
+ else {
+ throw new RIOException( "node " + n + " has no appropriate label" );
+ }
+ if ( labels_set.contains( label ) ) {
+ throw new RIOException( "label " + label + " is not unique" );
+ }
+ return label;
+ }
+
+ private final static Phylogeny[] parseGeneTrees( final File gene_trees_file ) throws FileNotFoundException,
+ IOException {
+ final PhylogenyFactory factory = ParserBasedPhylogenyFactory.getInstance();
+ final PhylogenyParser p = ParserUtils.createParserDependingOnFileType( gene_trees_file, true );
+ if ( p instanceof NHXParser ) {
+ final NHXParser nhx = ( NHXParser ) p;
+ nhx.setReplaceUnderscores( false );
+ nhx.setIgnoreQuotes( true );
+ nhx.setTaxonomyExtraction( TAXONOMY_EXTRACTION.AGGRESSIVE );
+ }
+ else if ( p instanceof NexusPhylogeniesParser ) {
+ final NexusPhylogeniesParser nex = ( NexusPhylogeniesParser ) p;
+ nex.setReplaceUnderscores( false );
+ nex.setIgnoreQuotes( true );
+ nex.setTaxonomyExtraction( TAXONOMY_EXTRACTION.AGGRESSIVE );
+ }
+ return factory.create( gene_trees_file, p );
+ }
+
+ private final static void removeSingleDescendentsNodes( final Phylogeny species_tree, final boolean verbose ) {
+ final int o = PhylogenyMethods.countNumberOfOneDescendantNodes( species_tree );
+ if ( o > 0 ) {
+ if ( verbose ) {
+ System.out.println( "warning: species tree has " + o
+ + " internal nodes with only one descendent which are therefore going to be removed" );
+ }
+ PhylogenyMethods.deleteInternalNodesWithOnlyOneDescendent( species_tree );
+ }
+ }
+
+ private final static void updateCounts( final IntMatrix m, final int counter, final Phylogeny g )
+ throws RIOException {
+ PhylogenyMethods.preOrderReId( g );
+ final HashMap<String, PhylogenyNode> map = PhylogenyMethods.createNameToExtNodeMap( g );
+ for( int x = 0; x < m.size(); ++x ) {
+ final String mx = m.getLabel( x );
+ final PhylogenyNode nx = map.get( mx );
+ if ( nx == null ) {
+ throw new RIOException( "node \"" + mx + "\" not present in gene tree #" + counter );
+ }
+ String my;
+ PhylogenyNode ny;
+ for( int y = 0; y < m.size(); ++y ) {
+ my = m.getLabel( y );
+ ny = map.get( my );
+ if ( ny == null ) {
+ throw new RIOException( "node \"" + my + "\" not present in gene tree #" + counter );
}
- String my;
- PhylogenyNode ny;
- for( int y = 0; y < m.size(); ++y ) {
- my = m.getLabel( y );
- ny = map.get( my );
- if ( ny == null ) {
- throw new RIOException( "node \"" + my + "\" not present in gene tree #" + counter );
- }
- if ( !PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( nx, ny ).isDuplication() ) {
- m.inreaseByOne( x, y );
- }
+ if ( !PhylogenyMethods.calculateLCAonTreeWithIdsInPreOrder( nx, ny ).isDuplication() ) {
+ m.inreaseByOne( x, y );
}
}
}
- return m;
+ }
+
+ public enum REROOTING {
+ NONE, BY_ALGORITHM, MIDPOINT, OUTGROUP;
}
}