/*
* Jalview - A Sequence Alignment Editor and Viewer ($$Version-Rel$$)
* Copyright (C) $$Year-Rel$$ The Jalview Authors
*
* This file is part of Jalview.
*
* Jalview is free software: you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* Jalview 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Jalview. If not, see .
* The Jalview Authors are detailed in the 'AUTHORS' file.
*/
package jalview.analysis;
import jalview.datamodel.AlignedCodonFrame;
import jalview.datamodel.Alignment;
import jalview.datamodel.AlignmentI;
import jalview.datamodel.DBRefEntry;
import jalview.datamodel.DBRefSource;
import jalview.datamodel.Mapping;
import jalview.datamodel.Sequence;
import jalview.datamodel.SequenceFeature;
import jalview.datamodel.SequenceI;
import jalview.util.DBRefUtils;
import jalview.util.MapList;
import jalview.ws.SequenceFetcherFactory;
import jalview.ws.seqfetcher.ASequenceFetcher;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.List;
/**
* Functions for cross-referencing sequence databases.
*
* @author JimP
*
*/
public class CrossRef
{
/*
* the dataset of the alignment for which we are searching for
* cross-references; in some cases we may resolve xrefs by
* searching in the dataset
*/
private AlignmentI dataset;
/*
* the sequences for which we are seeking cross-references
*/
private SequenceI[] fromSeqs;
/**
* matcher built from dataset
*/
SequenceIdMatcher matcher;
/**
* sequences found by cross-ref searches to fromSeqs
*/
List rseqs;
/**
* Constructor
*
* @param seqs
* the sequences for which we are seeking cross-references
* @param ds
* the containing alignment dataset (may be searched to resolve
* cross-references)
*/
public CrossRef(SequenceI[] seqs, AlignmentI ds)
{
fromSeqs = seqs;
dataset = ds.getDataset() == null ? ds : ds.getDataset();
}
/**
* Returns a list of distinct database sources for which sequences have either
*
* - a (dna-to-protein or protein-to-dna) cross-reference
* - an indirect cross-reference - a (dna-to-protein or protein-to-dna)
* reference from another sequence in the dataset which has a cross-reference
* to a direct DBRefEntry on the given sequence
*
*
* @param dna
* - when true, cross-references *from* dna returned. When false,
* cross-references *from* protein are returned
* @return
*/
public List findXrefSourcesForSequences(boolean dna)
{
List sources = new ArrayList();
for (SequenceI seq : fromSeqs)
{
if (seq != null)
{
findXrefSourcesForSequence(seq, dna, sources);
}
}
sources.remove(DBRefSource.EMBL); // hack to prevent EMBL xrefs resulting in
// redundant datasets
if (dna)
{
sources.remove(DBRefSource.ENSEMBL); // hack to prevent Ensembl and
// EnsemblGenomes xref option shown
// from cdna panel
sources.remove(DBRefSource.ENSEMBLGENOMES);
}
// redundant datasets
return sources;
}
/**
* Returns a list of distinct database sources for which a sequence has either
*
* - a (dna-to-protein or protein-to-dna) cross-reference
* - an indirect cross-reference - a (dna-to-protein or protein-to-dna)
* reference from another sequence in the dataset which has a cross-reference
* to a direct DBRefEntry on the given sequence
*
*
* @param seq
* the sequence whose dbrefs we are searching against
* @param fromDna
* when true, context is DNA - so sources identifying protein
* products will be returned.
* @param sources
* a list of sources to add matches to
*/
void findXrefSourcesForSequence(SequenceI seq, boolean fromDna,
List sources)
{
/*
* first find seq's xrefs (dna-to-peptide or peptide-to-dna)
*/
DBRefEntry[] rfs = DBRefUtils.selectDbRefs(!fromDna, seq.getDBRefs());
addXrefsToSources(rfs, sources);
if (dataset != null)
{
/*
* find sequence's direct (dna-to-dna, peptide-to-peptide) xrefs
*/
DBRefEntry[] lrfs = DBRefUtils.selectDbRefs(fromDna, seq.getDBRefs());
List foundSeqs = new ArrayList();
/*
* find sequences in the alignment which xref one of these DBRefs
* i.e. is xref-ed to a common sequence identifier
*/
searchDatasetXrefs(fromDna, seq, lrfs, foundSeqs, null);
/*
* add those sequences' (dna-to-peptide or peptide-to-dna) dbref sources
*/
for (SequenceI rs : foundSeqs)
{
DBRefEntry[] xrs = DBRefUtils
.selectDbRefs(!fromDna, rs.getDBRefs());
addXrefsToSources(xrs, sources);
}
}
}
/**
* Helper method that adds the source identifiers of some cross-references to
* a (non-redundant) list of database sources
*
* @param xrefs
* @param sources
*/
void addXrefsToSources(DBRefEntry[] xrefs, List sources)
{
if (xrefs != null)
{
for (DBRefEntry ref : xrefs)
{
/*
* avoid duplication e.g. ENSEMBL and Ensembl
*/
String source = DBRefUtils.getCanonicalName(ref.getSource());
if (!sources.contains(source))
{
sources.add(source);
}
}
}
}
/**
* Attempts to find cross-references from the sequences provided in the
* constructor to the given source database. Cross-references may be found
*
* - in dbrefs on the sequence which hold a mapping to a sequence
*
* - provided with a fetched sequence (e.g. ENA translation), or
* - populated previously after getting cross-references
*
* - as other sequences in the alignment which share a dbref identifier with
* the sequence
* - by fetching from the remote database
*
* The cross-referenced sequences, and mappings to them, are added to the
* alignment dataset.
*
* @param source
* @return cross-referenced sequences (as dataset sequences)
*/
public Alignment findXrefSequences(String source, boolean fromDna)
{
rseqs = new ArrayList();
AlignedCodonFrame cf = new AlignedCodonFrame();
matcher = new SequenceIdMatcher(dataset.getSequences());
for (SequenceI seq : fromSeqs)
{
SequenceI dss = seq;
while (dss.getDatasetSequence() != null)
{
dss = dss.getDatasetSequence();
}
boolean found = false;
DBRefEntry[] xrfs = DBRefUtils
.selectDbRefs(!fromDna, dss.getDBRefs());
// ENST & ENSP comes in to both Protein and nucleotide, so we need to
// filter them
// out later.
if ((xrfs == null || xrfs.length == 0) && dataset != null)
{
/*
* found no suitable dbrefs on sequence - look for sequences in the
* alignment which share a dbref with this one
*/
DBRefEntry[] lrfs = DBRefUtils.selectDbRefs(fromDna,
seq.getDBRefs());
/*
* find sequences (except this one!), of complementary type,
* which have a dbref to an accession id for this sequence,
* and add them to the results
*/
found = searchDatasetXrefs(fromDna, dss, lrfs, rseqs, cf);
}
if (xrfs == null && !found)
{
/*
* no dbref to source on this sequence or matched
* complementary sequence in the dataset
*/
continue;
}
List sourceRefs = DBRefUtils.searchRefsForSource(xrfs,
source);
Iterator refIterator = sourceRefs.iterator();
// At this point, if we are retrieving Ensembl, we still don't filter out
// ENST when looking for protein crossrefs.
while (refIterator.hasNext())
{
DBRefEntry xref = refIterator.next();
found = false;
// we're only interested in coding cross-references, not
// locus->transcript
if (xref.hasMap() && xref.getMap().getMap().isTripletMap())
{
SequenceI mappedTo = xref.getMap().getTo();
if (mappedTo != null)
{
/*
* dbref contains the sequence it maps to; add it to the
* results unless we have done so already (could happen if
* fetching xrefs for sequences which have xrefs in common)
* for example: UNIPROT {P0CE19, P0CE20} -> EMBL {J03321, X06707}
*/
found = true;
/*
* problem: matcher.findIdMatch() is lenient - returns a sequence
* with a dbref to the search arg e.g. ENST for ENSP - wrong
* but findInDataset() matches ENSP when looking for Uniprot...
*/
SequenceI matchInDataset = findInDataset(xref);
if (matchInDataset != null && xref.getMap().getTo() != null
&& matchInDataset != xref.getMap().getTo())
{
System.err
.println("Implementation problem (reopen JAL-2154): CrossRef.findInDataset seems to have recovered a different sequence than the one explicitly mapped for xref."
+ "Found:"
+ matchInDataset
+ "\nExpected:"
+ xref.getMap().getTo()
+ "\nFor xref:"
+ xref);
}
/*matcher.findIdMatch(mappedTo);*/
if (matchInDataset != null)
{
if (!rseqs.contains(matchInDataset))
{
rseqs.add(matchInDataset);
}
// even if rseqs contained matchInDataset - check mappings between
// these seqs are added
// need to try harder to only add unique mappings
if (xref.getMap().getMap().isTripletMap()
&& dataset.getMapping(seq, matchInDataset) == null
&& cf.getMappingBetween(seq, matchInDataset) == null)
{
// materialise a mapping for highlighting between these
// sequences
if (fromDna)
{
cf.addMap(dss, matchInDataset, xref.getMap().getMap(),
xref.getMap().getMappedFromId());
}
else
{
cf.addMap(matchInDataset, dss, xref.getMap().getMap()
.getInverse(), xref.getMap().getMappedFromId());
}
}
refIterator.remove();
continue;
}
// TODO: need to determine if this should be a deriveSequence
SequenceI rsq = new Sequence(mappedTo);
rseqs.add(rsq);
if (xref.getMap().getMap().isTripletMap())
{
// get sense of map correct for adding to product alignment.
if (fromDna)
{
// map is from dna seq to a protein product
cf.addMap(dss, rsq, xref.getMap().getMap(), xref.getMap()
.getMappedFromId());
}
else
{
// map should be from protein seq to its coding dna
cf.addMap(rsq, dss, xref.getMap().getMap().getInverse(),
xref.getMap().getMappedFromId());
}
}
}
}
if (!found)
{
SequenceI matchedSeq = matcher.findIdMatch(xref.getSource() + "|"
+ xref.getAccessionId());
// if there was a match, check it's at least the right type of
// molecule!
if (matchedSeq != null && matchedSeq.isProtein() == fromDna)
{
if (constructMapping(seq, matchedSeq, xref, cf, fromDna))
{
found = true;
}
}
}
if (!found)
{
// do a bit more work - search for sequences with references matching
// xrefs on this sequence.
found = searchDataset(fromDna, dss, xref, rseqs, cf, false);
}
if (found)
{
refIterator.remove();
}
}
/*
* fetch from source database any dbrefs we haven't resolved up to here
*/
if (!sourceRefs.isEmpty())
{
retrieveCrossRef(sourceRefs, seq, xrfs, fromDna, cf);
}
}
Alignment ral = null;
if (rseqs.size() > 0)
{
ral = new Alignment(rseqs.toArray(new SequenceI[rseqs.size()]));
if (!cf.isEmpty())
{
dataset.addCodonFrame(cf);
}
}
return ral;
}
private void retrieveCrossRef(List sourceRefs, SequenceI seq,
DBRefEntry[] xrfs, boolean fromDna, AlignedCodonFrame cf)
{
ASequenceFetcher sftch = SequenceFetcherFactory.getSequenceFetcher();
SequenceI[] retrieved = null;
SequenceI dss = seq.getDatasetSequence() == null ? seq : seq
.getDatasetSequence();
// first filter in case we are retrieving crossrefs that have already been
// retrieved. this happens for cases where a database record doesn't yield
// protein products for CDS
removeAlreadyRetrievedSeqs(sourceRefs, fromDna);
if (sourceRefs.size() == 0)
{
// no more work to do! We already had all requested sequence records in
// the dataset.
return;
}
try
{
retrieved = sftch.getSequences(sourceRefs, !fromDna);
} catch (Exception e)
{
System.err
.println("Problem whilst retrieving cross references for Sequence : "
+ seq.getName());
e.printStackTrace();
}
if (retrieved != null)
{
boolean addedXref = false;
List newDsSeqs = new ArrayList(), doNotAdd = new ArrayList();
for (SequenceI retrievedSequence : retrieved)
{
// dataset gets contaminated ccwith non-ds sequences. why ??!
// try: Ensembl -> Nuc->Ensembl, Nuc->Uniprot-->Protein->EMBL->
SequenceI retrievedDss = retrievedSequence.getDatasetSequence() == null ? retrievedSequence
: retrievedSequence.getDatasetSequence();
addedXref |= importCrossRefSeq(cf, newDsSeqs, doNotAdd, dss,
retrievedDss);
}
if (!addedXref)
{
// try again, after looking for matching IDs
// shouldn't need to do this unless the dbref mechanism has broken.
updateDbrefMappings(seq, xrfs, retrieved, cf, fromDna);
for (SequenceI retrievedSequence : retrieved)
{
// dataset gets contaminated ccwith non-ds sequences. why ??!
// try: Ensembl -> Nuc->Ensembl, Nuc->Uniprot-->Protein->EMBL->
SequenceI retrievedDss = retrievedSequence.getDatasetSequence() == null ? retrievedSequence
: retrievedSequence.getDatasetSequence();
addedXref |= importCrossRefSeq(cf, newDsSeqs, doNotAdd, dss,
retrievedDss);
}
}
for (SequenceI newToSeq : newDsSeqs)
{
if (!doNotAdd.contains(newToSeq)
&& dataset.findIndex(newToSeq) == -1)
{
dataset.addSequence(newToSeq);
matcher.add(newToSeq);
}
}
}
}
/**
* Search dataset for sequences with a primary reference contained in
* sourceRefs.
*
* @param sourceRefs
* - list of references to filter.
* @param fromDna
* - type of sequence to search for matching primary reference.
*/
private void removeAlreadyRetrievedSeqs(List sourceRefs,
boolean fromDna)
{
DBRefEntry[] dbrSourceSet = sourceRefs.toArray(new DBRefEntry[0]);
for (SequenceI sq : dataset.getSequences())
{
boolean dupeFound = false;
// !fromDna means we are looking only for nucleotide sequences, not
// protein
if (sq.isProtein() == fromDna)
{
for (DBRefEntry dbr : sq.getPrimaryDBRefs())
{
for (DBRefEntry found : DBRefUtils.searchRefs(dbrSourceSet, dbr))
{
sourceRefs.remove(found);
dupeFound = true;
}
}
}
if (dupeFound)
{
// rebuild the search array from the filtered sourceRefs list
dbrSourceSet = sourceRefs.toArray(new DBRefEntry[0]);
}
}
}
/**
* process sequence retrieved via a dbref on source sequence to resolve and
* transfer data
*
* @param cf
* @param sourceSequence
* @param retrievedSequence
* @return true if retrieveSequence was imported
*/
private boolean importCrossRefSeq(AlignedCodonFrame cf,
List newDsSeqs, List doNotAdd,
SequenceI sourceSequence, SequenceI retrievedSequence)
{
/**
* set when retrievedSequence has been verified as a crossreference for
* sourceSequence
*/
boolean imported = false;
DBRefEntry[] dbr = retrievedSequence.getDBRefs();
if (dbr != null)
{
for (DBRefEntry dbref : dbr)
{
SequenceI matched = findInDataset(dbref);
if (matched == sourceSequence)
{
// verified retrieved and source sequence cross-reference each other
imported = true;
}
// find any entry where we should put in the sequence being
// cross-referenced into the map
Mapping map = dbref.getMap();
if (map != null)
{
if (map.getTo() != null && map.getMap() != null)
{
if (map.getTo() == sourceSequence)
{
// already called to import once, and most likely this sequence
// already imported !
continue;
}
if (matched == null)
{
/*
* sequence is new to dataset, so save a reference so it can be added.
*/
newDsSeqs.add(map.getTo());
continue;
}
/*
* there was a matching sequence in dataset, so now, check to see if we can update the map.getTo() sequence to the existing one.
*/
try
{
// compare ms with dss and replace with dss in mapping
// if map is congruent
SequenceI ms = map.getTo();
// TODO findInDataset requires exact sequence match but
// 'congruent' test is only for the mapped part
// maybe not a problem in practice since only ENA provide a
// mapping and it is to the full protein translation of CDS
// matcher.findIdMatch(map.getTo());
// TODO addendum: if matched is shorter than getTo, this will fail
// - when it should really succeed.
int sf = map.getMap().getToLowest();
int st = map.getMap().getToHighest();
SequenceI mappedrg = ms.getSubSequence(sf, st);
if (mappedrg.getLength() > 0
&& ms.getSequenceAsString().equals(
matched.getSequenceAsString()))
{
/*
* sequences were a match,
*/
String msg = "Mapping updated from " + ms.getName()
+ " to retrieved crossreference "
+ matched.getName();
System.out.println(msg);
DBRefEntry[] toRefs = map.getTo().getDBRefs();
if (toRefs != null)
{
/*
* transfer database refs
*/
for (DBRefEntry ref : toRefs)
{
if (dbref.getSrcAccString().equals(
ref.getSrcAccString()))
{
continue; // avoid overwriting the ref on source sequence
}
matched.addDBRef(ref); // add or update mapping
}
}
doNotAdd.add(map.getTo());
map.setTo(matched);
/*
* give the reverse reference the inverse mapping
* (if it doesn't have one already)
*/
setReverseMapping(matched, dbref, cf);
/*
* copy sequence features as well, avoiding
* duplication (e.g. same variation from two
* transcripts)
*/
SequenceFeature[] sfs = ms.getSequenceFeatures();
if (sfs != null)
{
for (SequenceFeature feat : sfs)
{
/*
* make a flyweight feature object which ignores Parent
* attribute in equality test; this avoids creating many
* otherwise duplicate exon features on genomic sequence
*/
SequenceFeature newFeature = new SequenceFeature(feat)
{
@Override
public boolean equals(Object o)
{
return super.equals(o, true);
}
};
matched.addSequenceFeature(newFeature);
}
}
}
cf.addMap(retrievedSequence, map.getTo(), map.getMap());
} catch (Exception e)
{
System.err
.println("Exception when consolidating Mapped sequence set...");
e.printStackTrace(System.err);
}
}
}
}
}
if (imported)
{
retrievedSequence.updatePDBIds();
rseqs.add(retrievedSequence);
if (dataset.findIndex(retrievedSequence) == -1)
{
dataset.addSequence(retrievedSequence);
matcher.add(retrievedSequence);
}
}
return imported;
}
/**
* Sets the inverse sequence mapping in the corresponding dbref of the mapped
* to sequence (if any). This is used after fetching a cross-referenced
* sequence, if the fetched sequence has a mapping to the original sequence,
* to set the mapping in the original sequence's dbref.
*
* @param mapFrom
* the sequence mapped from
* @param dbref
* @param mappings
*/
void setReverseMapping(SequenceI mapFrom, DBRefEntry dbref,
AlignedCodonFrame mappings)
{
SequenceI mapTo = dbref.getMap().getTo();
if (mapTo == null)
{
return;
}
DBRefEntry[] dbrefs = mapTo.getDBRefs();
if (dbrefs == null)
{
return;
}
for (DBRefEntry toRef : dbrefs)
{
if (toRef.hasMap() && mapFrom == toRef.getMap().getTo())
{
/*
* found the reverse dbref; update its mapping if null
*/
if (toRef.getMap().getMap() == null)
{
MapList inverse = dbref.getMap().getMap().getInverse();
toRef.getMap().setMap(inverse);
mappings.addMap(mapTo, mapFrom, inverse);
}
}
}
}
/**
* Returns null or the first sequence in the dataset which is identical to
* xref.mapTo, and has a) a primary dbref matching xref, or if none found, the
* first one with an ID source|xrefacc
*
* @param xref
* with map and mapped-to sequence
* @return
*/
SequenceI findInDataset(DBRefEntry xref)
{
if (xref == null || !xref.hasMap() || xref.getMap().getTo() == null)
{
return null;
}
SequenceI mapsTo = xref.getMap().getTo();
String name = xref.getAccessionId();
String name2 = xref.getSource() + "|" + name;
SequenceI dss = mapsTo.getDatasetSequence() == null ? mapsTo : mapsTo
.getDatasetSequence();
// first check ds if ds is directly referenced
if (dataset.findIndex(dss) > -1)
{
return dss;
}
DBRefEntry template = new DBRefEntry(xref.getSource(), null,
xref.getAccessionId());
/**
* remember the first ID match - in case we don't find a match to template
*/
SequenceI firstIdMatch = null;
for (SequenceI seq : dataset.getSequences())
{
// first check primary refs.
List match = DBRefUtils.searchRefs(seq.getPrimaryDBRefs()
.toArray(new DBRefEntry[0]), template);
if (match != null && match.size() == 1 && sameSequence(seq, dss))
{
return seq;
}
/*
* clumsy alternative to using SequenceIdMatcher which currently
* returns sequences with a dbref to the matched accession id
* which we don't want
*/
if (firstIdMatch == null
&& (name.equals(seq.getName()) || seq.getName().startsWith(
name2)))
{
if (sameSequence(seq, dss))
{
firstIdMatch = seq;
}
}
}
return firstIdMatch;
}
/**
* Answers true if seq1 and seq2 contain exactly the same characters (ignoring
* case), else false. This method compares the lengths, then each character in
* turn, in order to 'fail fast'. For case-sensitive comparison, it would be
* possible to use Arrays.equals(seq1.getSequence(), seq2.getSequence()).
*
* @param seq1
* @param seq2
* @return
*/
// TODO move to Sequence / SequenceI
static boolean sameSequence(SequenceI seq1, SequenceI seq2)
{
if (seq1 == seq2)
{
return true;
}
if (seq1 == null || seq2 == null)
{
return false;
}
char[] c1 = seq1.getSequence();
char[] c2 = seq2.getSequence();
if (c1.length != c2.length)
{
return false;
}
for (int i = 0; i < c1.length; i++)
{
int diff = c1[i] - c2[i];
/*
* same char or differ in case only ('a'-'A' == 32)
*/
if (diff != 0 && diff != 32 && diff != -32)
{
return false;
}
}
return true;
}
/**
* Updates any empty mappings in the cross-references with one to a compatible
* retrieved sequence if found, and adds any new mappings to the
* AlignedCodonFrame
*
* @param mapFrom
* @param xrefs
* @param retrieved
* @param acf
*/
void updateDbrefMappings(SequenceI mapFrom, DBRefEntry[] xrefs,
SequenceI[] retrieved, AlignedCodonFrame acf, boolean fromDna)
{
SequenceIdMatcher idMatcher = new SequenceIdMatcher(retrieved);
for (DBRefEntry xref : xrefs)
{
if (!xref.hasMap())
{
String targetSeqName = xref.getSource() + "|"
+ xref.getAccessionId();
SequenceI[] matches = idMatcher.findAllIdMatches(targetSeqName);
if (matches == null)
{
return;
}
for (SequenceI seq : matches)
{
constructMapping(mapFrom, seq, xref, acf, fromDna);
}
}
}
}
/**
* Tries to make a mapping between sequences. If successful, adds the mapping
* to the dbref and the mappings collection and answers true, otherwise
* answers false. The following methods of making are mapping are tried in
* turn:
*
* - if 'mapTo' holds a mapping to 'mapFrom', take the inverse; this is, for
* example, the case after fetching EMBL cross-references for a Uniprot
* sequence
* - else check if the dna translates exactly to the protein (give or take
* start and stop codons>
* - else try to map based on CDS features on the dna sequence
*
*
* @param mapFrom
* @param mapTo
* @param xref
* @param mappings
* @return
*/
boolean constructMapping(SequenceI mapFrom, SequenceI mapTo,
DBRefEntry xref, AlignedCodonFrame mappings, boolean fromDna)
{
MapList mapping = null;
SequenceI dsmapFrom = mapFrom.getDatasetSequence() == null ? mapFrom
: mapFrom.getDatasetSequence();
SequenceI dsmapTo = mapTo.getDatasetSequence() == null ? mapTo : mapTo
.getDatasetSequence();
/*
* look for a reverse mapping, if found make its inverse.
* Note - we do this on dataset sequences only.
*/
if (dsmapTo.getDBRefs() != null)
{
for (DBRefEntry dbref : dsmapTo.getDBRefs())
{
String name = dbref.getSource() + "|" + dbref.getAccessionId();
if (dbref.hasMap() && dsmapFrom.getName().startsWith(name))
{
/*
* looks like we've found a map from 'mapTo' to 'mapFrom'
* - invert it to make the mapping the other way
*/
MapList reverse = dbref.getMap().getMap().getInverse();
xref.setMap(new Mapping(dsmapTo, reverse));
mappings.addMap(mapFrom, dsmapTo, reverse);
return true;
}
}
}
if (fromDna)
{
mapping = AlignmentUtils.mapCdnaToProtein(mapTo, mapFrom);
}
else
{
mapping = AlignmentUtils.mapCdnaToProtein(mapFrom, mapTo);
if (mapping != null)
{
mapping = mapping.getInverse();
}
}
if (mapping == null)
{
return false;
}
xref.setMap(new Mapping(mapTo, mapping));
/*
* and add a reverse DbRef with the inverse mapping
*/
if (mapFrom.getDatasetSequence() != null && false)
// && mapFrom.getDatasetSequence().getSourceDBRef() != null)
{
// possible need to search primary references... except, why doesn't xref
// == getSourceDBRef ??
// DBRefEntry dbref = new DBRefEntry(mapFrom.getDatasetSequence()
// .getSourceDBRef());
// dbref.setMap(new Mapping(mapFrom.getDatasetSequence(), mapping
// .getInverse()));
// mapTo.addDBRef(dbref);
}
if (fromDna)
{
AlignmentUtils.computeProteinFeatures(mapFrom, mapTo, mapping);
mappings.addMap(mapFrom, mapTo, mapping);
}
else
{
mappings.addMap(mapTo, mapFrom, mapping.getInverse());
}
return true;
}
/**
* find references to lrfs in the cross-reference set of each sequence in
* dataset (that is not equal to sequenceI) Identifies matching DBRefEntry
* based on source and accession string only - Map and Version are nulled.
*
* @param fromDna
* - true if context was searching from Dna sequences, false if
* context was searching from Protein sequences
* @param sequenceI
* @param lrfs
* @param foundSeqs
* @return true if matches were found.
*/
private boolean searchDatasetXrefs(boolean fromDna, SequenceI sequenceI,
DBRefEntry[] lrfs, List foundSeqs, AlignedCodonFrame cf)
{
boolean found = false;
if (lrfs == null)
{
return false;
}
for (int i = 0; i < lrfs.length; i++)
{
DBRefEntry xref = new DBRefEntry(lrfs[i]);
// add in wildcards
xref.setVersion(null);
xref.setMap(null);
found |= searchDataset(fromDna, sequenceI, xref, foundSeqs, cf, false);
}
return found;
}
/**
* Searches dataset for DBRefEntrys matching the given one (xrf) and adds the
* associated sequence to rseqs
*
* @param fromDna
* true if context was searching for refs *from* dna sequence, false
* if context was searching for refs *from* protein sequence
* @param fromSeq
* a sequence to ignore (start point of search)
* @param xrf
* a cross-reference to try to match
* @param foundSeqs
* result list to add to
* @param mappings
* a set of sequence mappings to add to
* @param direct
* - indicates the type of relationship between returned sequences,
* xrf, and sequenceI that is required.
*
* - direct implies xrf is a primary reference for sequenceI AND
* the sequences to be located (eg a uniprot ID for a protein
* sequence, and a uniprot ref on a transcript sequence).
* - indirect means xrf is a cross reference with respect to
* sequenceI or all the returned sequences (eg a genomic reference
* associated with a locus and one or more transcripts)
*
* @return true if relationship found and sequence added.
*/
boolean searchDataset(boolean fromDna, SequenceI fromSeq, DBRefEntry xrf,
List foundSeqs, AlignedCodonFrame mappings,
boolean direct)
{
boolean found = false;
if (dataset == null)
{
return false;
}
if (dataset.getSequences() == null)
{
System.err.println("Empty dataset sequence set - NO VECTOR");
return false;
}
List ds;
synchronized (ds = dataset.getSequences())
{
for (SequenceI nxt : ds)
{
if (nxt != null)
{
if (nxt.getDatasetSequence() != null)
{
System.err
.println("Implementation warning: CrossRef initialised with a dataset alignment with non-dataset sequences in it! ("
+ nxt.getDisplayId(true)
+ " has ds reference "
+ nxt.getDatasetSequence().getDisplayId(true)
+ ")");
}
if (nxt == fromSeq || nxt == fromSeq.getDatasetSequence())
{
continue;
}
/*
* only look at same molecule type if 'direct', or
* complementary type if !direct
*/
{
boolean isDna = !nxt.isProtein();
if (direct ? (isDna != fromDna) : (isDna == fromDna))
{
// skip this sequence because it is wrong molecule type
continue;
}
}
// look for direct or indirect references in common
DBRefEntry[] poss = nxt.getDBRefs();
List cands = null;
// todo: indirect specifies we select either direct references to nxt
// that match xrf which is indirect to sequenceI, or indirect
// references to nxt that match xrf which is direct to sequenceI
cands = DBRefUtils.searchRefs(poss, xrf);
// else
// {
// poss = DBRefUtils.selectDbRefs(nxt.isProtein()!fromDna, poss);
// cands = DBRefUtils.searchRefs(poss, xrf);
// }
if (!cands.isEmpty())
{
if (foundSeqs.contains(nxt))
{
continue;
}
found = true;
foundSeqs.add(nxt);
if (mappings != null && !direct)
{
/*
* if the matched sequence has mapped dbrefs to
* protein product / cdna, add equivalent mappings to
* our source sequence
*/
for (DBRefEntry candidate : cands)
{
Mapping mapping = candidate.getMap();
if (mapping != null)
{
MapList map = mapping.getMap();
if (mapping.getTo() != null
&& map.getFromRatio() != map.getToRatio())
{
/*
* add a mapping, as from dna to peptide sequence
*/
if (map.getFromRatio() == 3)
{
mappings.addMap(nxt, fromSeq, map);
}
else
{
mappings.addMap(nxt, fromSeq, map.getInverse());
}
}
}
}
}
}
}
}
}
return found;
}
}