/*
* 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.datamodel;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.BitSet;
import java.util.Collection;
import java.util.Collections;
import java.util.Enumeration;
import java.util.Iterator;
import java.util.List;
import java.util.ListIterator;
import java.util.Vector;
import fr.orsay.lri.varna.models.rna.RNA;
import jalview.analysis.AlignSeq;
import jalview.datamodel.features.SequenceFeatures;
import jalview.datamodel.features.SequenceFeaturesI;
import jalview.util.Comparison;
import jalview.util.DBRefUtils;
import jalview.util.MapList;
import jalview.util.StringUtils;
/**
*
* Implements the SequenceI interface for a char[] based sequence object
*/
public class Sequence extends ASequence implements SequenceI
{
/**
* A subclass that gives us access to modCount, which tracks whether there
* have been any changes. We use this to update
*
* @author hansonr
*
* @param
*/
@SuppressWarnings("serial")
public class DBModList extends ArrayList
{
protected int getModCount()
{
return modCount;
}
}
SequenceI datasetSequence;
private String name;
private char[] sequence;
private String description;
private int start;
private int end;
private Vector pdbIds;
private String vamsasId;
private DBModList dbrefs; // controlled access
/**
* a flag to let us know that elements have changed in dbrefs
*
* @author Bob Hanson
*/
private int refModCount = 0;
private RNA rna;
/**
* This annotation is displayed below the alignment but the positions are tied
* to the residues of this sequence
*
* TODO: change to List<>
*/
private Vector annotation;
private SequenceFeaturesI sequenceFeatureStore;
/*
* A cursor holding the approximate current view position to the sequence,
* as determined by findIndex or findPosition or findPositions.
* Using a cursor as a hint allows these methods to be more performant for
* large sequences.
*/
private SequenceCursor cursor;
/*
* A number that should be incremented whenever the sequence is edited.
* If the value matches the cursor token, then we can trust the cursor,
* if not then it should be recomputed.
*/
private int changeCount;
/**
* Creates a new Sequence object.
*
* @param name
* display name string
* @param sequence
* string to form a possibly gapped sequence out of
* @param start
* first position of non-gap residue in the sequence
* @param end
* last position of ungapped residues (nearly always only used for
* display purposes)
*/
public Sequence(String name, String sequence, int start, int end)
{
this();
initSeqAndName(name, sequence.toCharArray(), start, end);
}
public Sequence(String name, char[] sequence, int start, int end)
{
this();
initSeqAndName(name, sequence, start, end);
}
/**
* Stage 1 constructor - assign name, sequence, and set start and end fields.
* start and end are updated values from name2 if it ends with /start-end
*
* @param name2
* @param sequence2
* @param start2
* @param end2
*/
protected void initSeqAndName(String name2, char[] sequence2, int start2,
int end2)
{
this.name = name2;
this.sequence = sequence2;
this.start = start2;
this.end = end2;
parseId();
checkValidRange();
}
/**
* If 'name' ends in /i-j, where i >= j > 0 are integers, extracts i and j as
* start and end respectively and removes the suffix from the name
*/
void parseId()
{
if (name == null)
{
System.err.println(
"POSSIBLE IMPLEMENTATION ERROR: null sequence name passed to constructor.");
name = "";
}
int slashPos = name.lastIndexOf('/');
if (slashPos > -1 && slashPos < name.length() - 1)
{
String suffix = name.substring(slashPos + 1);
String[] range = suffix.split("-");
if (range.length == 2)
{
try
{
int from = Integer.valueOf(range[0]);
int to = Integer.valueOf(range[1]);
if (from > 0 && to >= from)
{
name = name.substring(0, slashPos);
setStart(from);
setEnd(to);
checkValidRange();
}
} catch (NumberFormatException e)
{
// leave name unchanged if suffix is invalid
}
}
}
}
/**
* Ensures that 'end' is not before the end of the sequence, that is,
* (end-start+1) is at least as long as the count of ungapped positions. Note
* that end is permitted to be beyond the end of the sequence data.
*/
void checkValidRange()
{
// Note: JAL-774 :
// http://issues.jalview.org/browse/JAL-774?focusedCommentId=11239&page=com.atlassian.jira.plugin.system.issuetabpanels:comment-tabpanel#comment-11239
{
int endRes = 0;
for (int j = 0; j < sequence.length; j++)
{
if (!Comparison.isGap(sequence[j]))
{
endRes++;
}
}
if (endRes > 0)
{
endRes += start - 1;
}
if (end < endRes)
{
end = endRes;
}
}
}
/**
* default constructor
*/
private Sequence()
{
sequenceFeatureStore = new SequenceFeatures();
}
/**
* Creates a new Sequence object.
*
* @param name
* DOCUMENT ME!
* @param sequence
* DOCUMENT ME!
*/
public Sequence(String name, String sequence)
{
this(name, sequence, 1, -1);
}
/**
* Creates a new Sequence object with new AlignmentAnnotations but inherits
* any existing dataset sequence reference. If non exists, everything is
* copied.
*
* @param seq
* if seq is a dataset sequence, behaves like a plain old copy
* constructor
*/
public Sequence(SequenceI seq)
{
this(seq, seq.getAnnotation());
}
/**
* Create a new sequence object with new features, DBRefEntries, and PDBIds
* but inherits any existing dataset sequence reference, and duplicate of any
* annotation that is present in the given annotation array.
*
* @param seq
* the sequence to be copied
* @param alAnnotation
* an array of annotation including some associated with seq
*/
public Sequence(SequenceI seq, AlignmentAnnotation[] alAnnotation)
{
this();
initSeqFrom(seq, alAnnotation);
}
/**
* does the heavy lifting when cloning a dataset sequence, or coping data from
* dataset to a new derived sequence.
*
* @param seq
* - source of attributes.
* @param alAnnotation
* - alignment annotation present on seq that should be copied onto
* this sequence
*/
protected void initSeqFrom(SequenceI seq,
AlignmentAnnotation[] alAnnotation)
{
char[] oseq = seq.getSequence(); // returns a copy of the array
initSeqAndName(seq.getName(), oseq, seq.getStart(), seq.getEnd());
description = seq.getDescription();
if (seq != datasetSequence)
{
setDatasetSequence(seq.getDatasetSequence());
}
/*
* only copy DBRefs and seqfeatures if we really are a dataset sequence
*/
if (datasetSequence == null)
{
List dbr = seq.getDBRefs();
if (dbr != null)
{
for (int i = 0, n = dbr.size(); i < n; i++)
{
addDBRef(new DBRefEntry(dbr.get(i)));
}
}
/*
* make copies of any sequence features
*/
for (SequenceFeature sf : seq.getSequenceFeatures())
{
addSequenceFeature(new SequenceFeature(sf));
}
}
if (seq.getAnnotation() != null)
{
AlignmentAnnotation[] sqann = seq.getAnnotation();
for (int i = 0; i < sqann.length; i++)
{
if (sqann[i] == null)
{
continue;
}
boolean found = (alAnnotation == null);
if (!found)
{
for (int apos = 0; !found && apos < alAnnotation.length; apos++)
{
found = (alAnnotation[apos] == sqann[i]);
}
}
if (found)
{
// only copy the given annotation
AlignmentAnnotation newann = new AlignmentAnnotation(sqann[i]);
addAlignmentAnnotation(newann);
}
}
}
if (seq.getAllPDBEntries() != null)
{
Vector ids = seq.getAllPDBEntries();
for (PDBEntry pdb : ids)
{
this.addPDBId(new PDBEntry(pdb));
}
}
}
@Override
public void setSequenceFeatures(List features)
{
if (datasetSequence != null)
{
datasetSequence.setSequenceFeatures(features);
return;
}
sequenceFeatureStore = new SequenceFeatures(features);
}
@Override
public synchronized boolean addSequenceFeature(SequenceFeature sf)
{
if (sf.getType() == null)
{
System.err.println(
"SequenceFeature type may not be null: " + sf.toString());
return false;
}
if (datasetSequence != null)
{
return datasetSequence.addSequenceFeature(sf);
}
return sequenceFeatureStore.add(sf);
}
@Override
public void deleteFeature(SequenceFeature sf)
{
if (datasetSequence != null)
{
datasetSequence.deleteFeature(sf);
}
else
{
sequenceFeatureStore.delete(sf);
}
}
/**
* {@inheritDoc}
*
* @return
*/
@Override
public List getSequenceFeatures()
{
if (datasetSequence != null)
{
return datasetSequence.getSequenceFeatures();
}
return sequenceFeatureStore.getAllFeatures();
}
@Override
public SequenceFeaturesI getFeatures()
{
return datasetSequence != null ? datasetSequence.getFeatures()
: sequenceFeatureStore;
}
@Override
public boolean addPDBId(PDBEntry entry)
{
if (pdbIds == null)
{
pdbIds = new Vector<>();
pdbIds.add(entry);
return true;
}
for (PDBEntry pdbe : pdbIds)
{
if (pdbe.updateFrom(entry))
{
return false;
}
}
pdbIds.addElement(entry);
return true;
}
/**
* DOCUMENT ME!
*
* @param id
* DOCUMENT ME!
*/
@Override
public void setPDBId(Vector id)
{
pdbIds = id;
}
/**
* DOCUMENT ME!
*
* @return DOCUMENT ME!
*/
@Override
public Vector getAllPDBEntries()
{
return pdbIds == null ? new Vector<>() : pdbIds;
}
/**
* Answers the sequence name, with '/start-end' appended if jvsuffix is true
*
* @return
*/
@Override
public String getDisplayId(boolean jvsuffix)
{
if (!jvsuffix)
{
return name;
}
StringBuilder result = new StringBuilder(name);
result.append("/").append(start).append("-").append(end);
return result.toString();
}
/**
* Sets the sequence name. If the name ends in /start-end, then the start-end
* values are parsed out and set, and the suffix is removed from the name.
*
* @param theName
*/
@Override
public void setName(String theName)
{
this.name = theName;
this.parseId();
}
/**
* DOCUMENT ME!
*
* @return DOCUMENT ME!
*/
@Override
public String getName()
{
return this.name;
}
/**
* DOCUMENT ME!
*
* @param start
* DOCUMENT ME!
*/
@Override
public void setStart(int start)
{
this.start = start;
sequenceChanged();
}
/**
* DOCUMENT ME!
*
* @return DOCUMENT ME!
*/
@Override
public int getStart()
{
return this.start;
}
/**
* DOCUMENT ME!
*
* @param end
* DOCUMENT ME!
*/
@Override
public void setEnd(int end)
{
this.end = end;
}
/**
* DOCUMENT ME!
*
* @return DOCUMENT ME!
*/
@Override
public int getEnd()
{
return this.end;
}
/**
* DOCUMENT ME!
*
* @return DOCUMENT ME!
*/
@Override
public int getLength()
{
return this.sequence.length;
}
/**
* DOCUMENT ME!
*
* @param seq
* DOCUMENT ME!
*/
@Override
public void setSequence(String seq)
{
this.sequence = seq.toCharArray();
checkValidRange();
sequenceChanged();
}
@Override
public String getSequenceAsString()
{
return new String(sequence);
}
@Override
public String getSequenceAsString(int start, int end)
{
return new String(getSequence(start, end));
}
@Override
public char[] getSequence()
{
// return sequence;
return sequence == null ? null
: Arrays.copyOf(sequence, sequence.length);
}
/*
* (non-Javadoc)
*
* @see jalview.datamodel.SequenceI#getSequence(int, int)
*/
@Override
public char[] getSequence(int start, int end)
{
if (start < 0)
{
start = 0;
}
// JBPNote - left to user to pad the result here (TODO:Decide on this
// policy)
if (start >= sequence.length)
{
return new char[0];
}
if (end >= sequence.length)
{
end = sequence.length;
}
char[] reply = new char[end - start];
System.arraycopy(sequence, start, reply, 0, end - start);
return reply;
}
@Override
public SequenceI getSubSequence(int start, int end)
{
if (start < 0)
{
start = 0;
}
char[] seq = getSequence(start, end);
if (seq.length == 0)
{
return null;
}
int nstart = findPosition(start);
int nend = findPosition(end) - 1;
// JBPNote - this is an incomplete copy.
SequenceI nseq = new Sequence(this.getName(), seq, nstart, nend);
nseq.setDescription(description);
if (datasetSequence != null)
{
nseq.setDatasetSequence(datasetSequence);
}
else
{
nseq.setDatasetSequence(this);
}
return nseq;
}
/**
* Returns the character of the aligned sequence at the given position (base
* zero), or space if the position is not within the sequence's bounds
*
* @return
*/
@Override
public char getCharAt(int i)
{
if (i >= 0 && i < sequence.length)
{
return sequence[i];
}
else
{
return ' ';
}
}
/**
* Sets the sequence description, and also parses out any special formats of
* interest
*
* @param desc
*/
@Override
public void setDescription(String desc)
{
this.description = desc;
}
@Override
public void setGeneLoci(String speciesId, String assemblyId,
String chromosomeId, MapList map)
{
addDBRef(new GeneLocus(speciesId, assemblyId, chromosomeId,
new Mapping(map)));
}
/**
* Returns the gene loci mapping for the sequence (may be null)
*
* @return
*/
@Override
public GeneLociI getGeneLoci()
{
List refs = getDBRefs();
if (refs != null)
{
for (final DBRefEntry ref : refs)
{
if (ref instanceof GeneLociI)
{
return (GeneLociI) ref;
}
}
}
return null;
}
/**
* Answers the description
*
* @return
*/
@Override
public String getDescription()
{
return this.description;
}
/**
* {@inheritDoc}
*/
@Override
public int findIndex(int pos)
{
/*
* use a valid, hopefully nearby, cursor if available
*/
if (isValidCursor(cursor))
{
return findIndex(pos, cursor);
}
int j = start;
int i = 0;
int startColumn = 0;
/*
* traverse sequence from the start counting gaps; make a note of
* the column of the first residue to save in the cursor
*/
while ((i < sequence.length) && (j <= end) && (j <= pos))
{
if (!Comparison.isGap(sequence[i]))
{
if (j == start)
{
startColumn = i;
}
j++;
}
i++;
}
if (j == end && j < pos)
{
return end + 1;
}
updateCursor(pos, i, startColumn);
return i;
}
/**
* Updates the cursor to the latest found residue and column position
*
* @param residuePos
* (start..)
* @param column
* (1..)
* @param startColumn
* column position of the first sequence residue
*/
protected void updateCursor(int residuePos, int column, int startColumn)
{
/*
* preserve end residue column provided cursor was valid
*/
int endColumn = isValidCursor(cursor) ? cursor.lastColumnPosition : 0;
if (residuePos == this.end)
{
endColumn = column;
}
cursor = new SequenceCursor(this, residuePos, column, startColumn,
endColumn, this.changeCount);
}
/**
* Answers the aligned column position (1..) for the given residue position
* (start..) given a 'hint' of a residue/column location in the neighbourhood.
* The hint may be left of, at, or to the right of the required position.
*
* @param pos
* @param curs
* @return
*/
protected int findIndex(final int pos, SequenceCursor curs)
{
if (!isValidCursor(curs))
{
/*
* wrong or invalidated cursor, compute de novo
*/
return findIndex(pos);
}
if (curs.residuePosition == pos)
{
return curs.columnPosition;
}
/*
* move left or right to find pos from hint.position
*/
int col = curs.columnPosition - 1; // convert from base 1 to base 0
int newPos = curs.residuePosition;
int delta = newPos > pos ? -1 : 1;
while (newPos != pos)
{
col += delta; // shift one column left or right
if (col < 0)
{
break;
}
if (col == sequence.length)
{
col--; // return last column if we failed to reach pos
break;
}
if (!Comparison.isGap(sequence[col]))
{
newPos += delta;
}
}
col++; // convert back to base 1
/*
* only update cursor if we found the target position
*/
if (newPos == pos)
{
updateCursor(pos, col, curs.firstColumnPosition);
}
return col;
}
/**
* {@inheritDoc}
*/
@Override
public int findPosition(final int column)
{
/*
* use a valid, hopefully nearby, cursor if available
*/
if (isValidCursor(cursor))
{
return findPosition(column + 1, cursor);
}
// TODO recode this more naturally i.e. count residues only
// as they are found, not 'in anticipation'
/*
* traverse the sequence counting gaps; note the column position
* of the first residue, to save in the cursor
*/
int firstResidueColumn = 0;
int lastPosFound = 0;
int lastPosFoundColumn = 0;
int seqlen = sequence.length;
if (seqlen > 0 && !Comparison.isGap(sequence[0]))
{
lastPosFound = start;
lastPosFoundColumn = 0;
}
int j = 0;
int pos = start;
while (j < column && j < seqlen)
{
if (!Comparison.isGap(sequence[j]))
{
lastPosFound = pos;
lastPosFoundColumn = j;
if (pos == this.start)
{
firstResidueColumn = j;
}
pos++;
}
j++;
}
if (j < seqlen && !Comparison.isGap(sequence[j]))
{
lastPosFound = pos;
lastPosFoundColumn = j;
if (pos == this.start)
{
firstResidueColumn = j;
}
}
/*
* update the cursor to the last residue position found (if any)
* (converting column position to base 1)
*/
if (lastPosFound != 0)
{
updateCursor(lastPosFound, lastPosFoundColumn + 1,
firstResidueColumn + 1);
}
return pos;
}
/**
* Answers true if the given cursor is not null, is for this sequence object,
* and has a token value that matches this object's changeCount, else false.
* This allows us to ignore a cursor as 'stale' if the sequence has been
* modified since the cursor was created.
*
* @param curs
* @return
*/
protected boolean isValidCursor(SequenceCursor curs)
{
if (curs == null || curs.sequence != this || curs.token != changeCount)
{
return false;
}
/*
* sanity check against range
*/
if (curs.columnPosition < 0 || curs.columnPosition > sequence.length)
{
return false;
}
if (curs.residuePosition < start || curs.residuePosition > end)
{
return false;
}
return true;
}
/**
* Answers the sequence position (start..) for the given aligned column
* position (1..), given a hint of a cursor in the neighbourhood. The cursor
* may lie left of, at, or to the right of the column position.
*
* @param col
* @param curs
* @return
*/
protected int findPosition(final int col, SequenceCursor curs)
{
if (!isValidCursor(curs))
{
/*
* wrong or invalidated cursor, compute de novo
*/
return findPosition(col - 1);// ugh back to base 0
}
if (curs.columnPosition == col)
{
cursor = curs; // in case this method becomes public
return curs.residuePosition; // easy case :-)
}
if (curs.lastColumnPosition > 0 && curs.lastColumnPosition < col)
{
/*
* sequence lies entirely to the left of col
* - return last residue + 1
*/
return end + 1;
}
if (curs.firstColumnPosition > 0 && curs.firstColumnPosition > col)
{
/*
* sequence lies entirely to the right of col
* - return first residue
*/
return start;
}
// todo could choose closest to col out of column,
// firstColumnPosition, lastColumnPosition as a start point
/*
* move left or right to find pos from cursor position
*/
int firstResidueColumn = curs.firstColumnPosition;
int column = curs.columnPosition - 1; // to base 0
int newPos = curs.residuePosition;
int delta = curs.columnPosition > col ? -1 : 1;
boolean gapped = false;
int lastFoundPosition = curs.residuePosition;
int lastFoundPositionColumn = curs.columnPosition;
while (column != col - 1)
{
column += delta; // shift one column left or right
if (column < 0 || column == sequence.length)
{
break;
}
gapped = Comparison.isGap(sequence[column]);
if (!gapped)
{
newPos += delta;
lastFoundPosition = newPos;
lastFoundPositionColumn = column + 1;
if (lastFoundPosition == this.start)
{
firstResidueColumn = column + 1;
}
}
}
if (cursor == null || lastFoundPosition != cursor.residuePosition)
{
updateCursor(lastFoundPosition, lastFoundPositionColumn,
firstResidueColumn);
}
/*
* hack to give position to the right if on a gap
* or beyond the length of the sequence (see JAL-2562)
*/
if (delta > 0 && (gapped || column >= sequence.length))
{
newPos++;
}
return newPos;
}
/**
* {@inheritDoc}
*/
@Override
public ContiguousI findPositions(int fromColumn, int toColumn)
{
if (toColumn < fromColumn || fromColumn < 1)
{
return null;
}
/*
* find the first non-gapped position, if any
*/
int firstPosition = 0;
int col = fromColumn - 1;
int length = sequence.length;
while (col < length && col < toColumn)
{
if (!Comparison.isGap(sequence[col]))
{
firstPosition = findPosition(col++);
break;
}
col++;
}
if (firstPosition == 0)
{
return null;
}
/*
* find the last non-gapped position
*/
int lastPosition = firstPosition;
while (col < length && col < toColumn)
{
if (!Comparison.isGap(sequence[col++]))
{
lastPosition++;
}
}
return new Range(firstPosition, lastPosition);
}
/**
* Returns an int array where indices correspond to each residue in the
* sequence and the element value gives its position in the alignment
*
* @return int[SequenceI.getEnd()-SequenceI.getStart()+1] or null if no
* residues in SequenceI object
*/
@Override
public int[] gapMap()
{
String seq = jalview.analysis.AlignSeq.extractGaps(
jalview.util.Comparison.GapChars, new String(sequence));
int[] map = new int[seq.length()];
int j = 0;
int p = 0;
while (j < sequence.length)
{
if (!jalview.util.Comparison.isGap(sequence[j]))
{
map[p++] = j;
}
j++;
}
return map;
}
/**
* Build a bitset corresponding to sequence gaps
*
* @return a BitSet where set values correspond to gaps in the sequence
*/
@Override
public BitSet gapBitset()
{
BitSet gaps = new BitSet(sequence.length);
int j = 0;
while (j < sequence.length)
{
if (jalview.util.Comparison.isGap(sequence[j]))
{
gaps.set(j);
}
j++;
}
return gaps;
}
@Override
public int[] findPositionMap()
{
int map[] = new int[sequence.length];
int j = 0;
int pos = start;
int seqlen = sequence.length;
while ((j < seqlen))
{
map[j] = pos;
if (!jalview.util.Comparison.isGap(sequence[j]))
{
pos++;
}
j++;
}
return map;
}
@Override
public List getInsertions()
{
ArrayList map = new ArrayList<>();
int lastj = -1, j = 0;
// int pos = start;
int seqlen = sequence.length;
while ((j < seqlen))
{
if (jalview.util.Comparison.isGap(sequence[j]))
{
if (lastj == -1)
{
lastj = j;
}
}
else
{
if (lastj != -1)
{
map.add(new int[] { lastj, j - 1 });
lastj = -1;
}
}
j++;
}
if (lastj != -1)
{
map.add(new int[] { lastj, j - 1 });
lastj = -1;
}
return map;
}
@Override
public BitSet getInsertionsAsBits()
{
BitSet map = new BitSet();
int lastj = -1, j = 0;
// int pos = start;
int seqlen = sequence.length;
while ((j < seqlen))
{
if (jalview.util.Comparison.isGap(sequence[j]))
{
if (lastj == -1)
{
lastj = j;
}
}
else
{
if (lastj != -1)
{
map.set(lastj, j);
lastj = -1;
}
}
j++;
}
if (lastj != -1)
{
map.set(lastj, j);
lastj = -1;
}
return map;
}
@Override
public void deleteChars(final int i, final int j)
{
int newstart = start, newend = end;
if (i >= sequence.length || i < 0)
{
return;
}
char[] tmp = StringUtils.deleteChars(sequence, i, j);
boolean createNewDs = false;
// TODO: take a (second look) at the dataset creation validation method for
// the very large sequence case
int startIndex = findIndex(start) - 1;
int endIndex = findIndex(end) - 1;
int startDeleteColumn = -1; // for dataset sequence deletions
int deleteCount = 0;
for (int s = i; s < j && s < sequence.length; s++)
{
if (Comparison.isGap(sequence[s]))
{
continue;
}
deleteCount++;
if (startDeleteColumn == -1)
{
startDeleteColumn = findPosition(s) - start;
}
if (createNewDs)
{
newend--;
}
else
{
if (startIndex == s)
{
/*
* deleting characters from start of sequence; new start is the
* sequence position of the next column (position to the right
* if the column position is gapped)
*/
newstart = findPosition(j);
break;
}
else
{
if (endIndex < j)
{
/*
* deleting characters at end of sequence; new end is the sequence
* position of the column before the deletion; subtract 1 if this is
* gapped since findPosition returns the next sequence position
*/
newend = findPosition(i - 1);
if (Comparison.isGap(sequence[i - 1]))
{
newend--;
}
break;
}
else
{
createNewDs = true;
newend--;
}
}
}
}
if (createNewDs && this.datasetSequence != null)
{
/*
* if deletion occured in the middle of the sequence,
* construct a new dataset sequence and delete the residues
* that were deleted from the aligned sequence
*/
Sequence ds = new Sequence(datasetSequence);
ds.deleteChars(startDeleteColumn, startDeleteColumn + deleteCount);
datasetSequence = ds;
// TODO: remove any non-inheritable properties ?
// TODO: create a sequence mapping (since there is a relation here ?)
}
start = newstart;
end = newend;
sequence = tmp;
sequenceChanged();
}
@Override
public void insertCharAt(int i, int length, char c)
{
char[] tmp = new char[sequence.length + length];
if (i >= sequence.length)
{
System.arraycopy(sequence, 0, tmp, 0, sequence.length);
i = sequence.length;
}
else
{
System.arraycopy(sequence, 0, tmp, 0, i);
}
int index = i;
while (length > 0)
{
tmp[index++] = c;
length--;
}
if (i < sequence.length)
{
System.arraycopy(sequence, i, tmp, index, sequence.length - i);
}
sequence = tmp;
sequenceChanged();
}
@Override
public void insertCharAt(int i, char c)
{
insertCharAt(i, 1, c);
}
@Override
public String getVamsasId()
{
return vamsasId;
}
@Override
public void setVamsasId(String id)
{
vamsasId = id;
}
@Deprecated
@Override
public void setDBRefs(DBModList newDBrefs)
{
if (dbrefs == null && datasetSequence != null
&& this != datasetSequence)
{
datasetSequence.setDBRefs(newDBrefs);
return;
}
dbrefs = newDBrefs;
refModCount = 0;
}
@Override
public DBModList getDBRefs()
{
if (dbrefs == null && datasetSequence != null
&& this != datasetSequence)
{
return datasetSequence.getDBRefs();
}
return dbrefs;
}
@Override
public void addDBRef(DBRefEntry entry)
{
// TODO JAL-3980 maintain as sorted list
if (datasetSequence != null)
{
datasetSequence.addDBRef(entry);
return;
}
if (dbrefs == null)
{
dbrefs = new DBModList<>();
}
// TODO JAL-3979 LOOK UP RATHER THAN SWEEP FOR EFFICIENCY
for (int ib = 0, nb = dbrefs.size(); ib < nb; ib++)
{
if (dbrefs.get(ib).updateFrom(entry))
{
/*
* found a dbref that either matched, or could be
* updated from, the new entry - no need to add it
*/
return;
}
}
// /// BH OUCH!
// /*
// * extend the array to make room for one more
// */
// // TODO use an ArrayList instead
// int j = dbrefs.length;
// List temp = new DBRefEntry[j + 1];
// System.arraycopy(dbrefs, 0, temp, 0, j);
// temp[temp.length - 1] = entry;
//
// dbrefs = temp;
dbrefs.add(entry);
}
@Override
public void setDatasetSequence(SequenceI seq)
{
if (seq == this)
{
throw new IllegalArgumentException(
"Implementation Error: self reference passed to SequenceI.setDatasetSequence");
}
if (seq != null && seq.getDatasetSequence() != null)
{
throw new IllegalArgumentException(
"Implementation error: cascading dataset sequences are not allowed.");
}
datasetSequence = seq;
}
@Override
public SequenceI getDatasetSequence()
{
return datasetSequence;
}
@Override
public AlignmentAnnotation[] getAnnotation()
{
return annotation == null ? null
: annotation
.toArray(new AlignmentAnnotation[annotation.size()]);
}
@Override
public boolean hasAnnotation(AlignmentAnnotation ann)
{
return annotation == null ? false : annotation.contains(ann);
}
@Override
public void addAlignmentAnnotation(AlignmentAnnotation annotation)
{
if (this.annotation == null)
{
this.annotation = new Vector<>();
}
if (!this.annotation.contains(annotation))
{
this.annotation.addElement(annotation);
}
annotation.setSequenceRef(this);
}
@Override
public void removeAlignmentAnnotation(AlignmentAnnotation annotation)
{
if (this.annotation != null)
{
this.annotation.removeElement(annotation);
if (this.annotation.size() == 0)
{
this.annotation = null;
}
}
}
/**
* test if this is a valid candidate for another sequence's dataset sequence.
*
*/
private boolean isValidDatasetSequence()
{
if (datasetSequence != null)
{
return false;
}
for (int i = 0; i < sequence.length; i++)
{
if (jalview.util.Comparison.isGap(sequence[i]))
{
return false;
}
}
return true;
}
@Override
public SequenceI deriveSequence()
{
Sequence seq = null;
if (datasetSequence == null)
{
if (isValidDatasetSequence())
{
// Use this as dataset sequence
seq = new Sequence(getName(), "", 1, -1);
seq.setDatasetSequence(this);
seq.initSeqFrom(this, getAnnotation());
return seq;
}
else
{
// Create a new, valid dataset sequence
createDatasetSequence();
}
}
return new Sequence(this);
}
private boolean _isNa;
private int _seqhash = 0;
private List primaryRefs;
/**
* Answers false if the sequence is more than 85% nucleotide (ACGTU), else
* true
*/
@Override
public boolean isProtein()
{
if (datasetSequence != null)
{
return datasetSequence.isProtein();
}
if (_seqhash != sequence.hashCode())
{
_seqhash = sequence.hashCode();
_isNa = Comparison.isNucleotide(this);
}
return !_isNa;
}
/*
* (non-Javadoc)
*
* @see jalview.datamodel.SequenceI#createDatasetSequence()
*/
@Override
public SequenceI createDatasetSequence()
{
if (datasetSequence == null)
{
Sequence dsseq = new Sequence(getName(),
AlignSeq.extractGaps(jalview.util.Comparison.GapChars,
getSequenceAsString()),
getStart(), getEnd());
datasetSequence = dsseq;
dsseq.setDescription(description);
// move features and database references onto dataset sequence
dsseq.sequenceFeatureStore = sequenceFeatureStore;
sequenceFeatureStore = null;
dsseq.dbrefs = dbrefs;
dbrefs = null;
// TODO: search and replace any references to this sequence with
// references to the dataset sequence in Mappings on dbref
dsseq.pdbIds = pdbIds;
pdbIds = null;
datasetSequence.updatePDBIds();
if (annotation != null)
{
// annotation is cloned rather than moved, to preserve what's currently
// on the alignment
for (AlignmentAnnotation aa : annotation)
{
AlignmentAnnotation _aa = new AlignmentAnnotation(aa);
_aa.sequenceRef = datasetSequence;
_aa.adjustForAlignment(); // uses annotation's own record of
// sequence-column mapping
datasetSequence.addAlignmentAnnotation(_aa);
// transfer contact matrices
ContactMatrixI cm = getContactMatrixFor(aa);
if (cm != null)
{
datasetSequence.addContactListFor(_aa, cm);
}
}
}
}
return datasetSequence;
}
/*
* (non-Javadoc)
*
* @see
* jalview.datamodel.SequenceI#setAlignmentAnnotation(AlignmmentAnnotation[]
* annotations)
*/
@Override
public void setAlignmentAnnotation(AlignmentAnnotation[] annotations)
{
if (annotation != null)
{
annotation.removeAllElements();
}
if (annotations != null)
{
for (int i = 0; i < annotations.length; i++)
{
if (annotations[i] != null)
{
addAlignmentAnnotation(annotations[i]);
}
}
}
}
@Override
public AlignmentAnnotation[] getAnnotation(String label)
{
if (annotation == null || annotation.size() == 0)
{
return null;
}
Vector subset = new Vector<>();
Enumeration e = annotation.elements();
while (e.hasMoreElements())
{
AlignmentAnnotation ann = e.nextElement();
if (ann.label != null && ann.label.equals(label))
{
subset.addElement(ann);
}
}
if (subset.size() == 0)
{
return null;
}
AlignmentAnnotation[] anns = new AlignmentAnnotation[subset.size()];
int i = 0;
e = subset.elements();
while (e.hasMoreElements())
{
anns[i++] = e.nextElement();
}
subset.removeAllElements();
return anns;
}
@Override
public boolean updatePDBIds()
{
if (datasetSequence != null)
{
// TODO: could merge DBRefs
return datasetSequence.updatePDBIds();
}
if (dbrefs == null || dbrefs.size() == 0)
{
return false;
}
boolean added = false;
for (int ib = 0, nb = dbrefs.size(); ib < nb; ib++)
{
DBRefEntry dbr = dbrefs.get(ib);
if (DBRefSource.PDB.equals(dbr.getSource()))
{
/*
* 'Add' any PDB dbrefs as a PDBEntry - add is only performed if the
* PDB id is not already present in a 'matching' PDBEntry
* Constructor parses out a chain code if appended to the accession id
* (a fudge used to 'store' the chain code in the DBRef)
*/
PDBEntry pdbe = new PDBEntry(dbr);
added |= addPDBId(pdbe);
}
}
return added;
}
@Override
public void transferAnnotation(SequenceI entry, Mapping mp)
{
if (datasetSequence != null)
{
datasetSequence.transferAnnotation(entry, mp);
return;
}
if (entry.getDatasetSequence() != null)
{
transferAnnotation(entry.getDatasetSequence(), mp);
return;
}
// transfer any new features from entry onto sequence
if (entry.getSequenceFeatures() != null)
{
List sfs = entry.getSequenceFeatures();
for (SequenceFeature feature : sfs)
{
SequenceFeature sf[] = (mp != null) ? mp.locateFeature(feature)
: new SequenceFeature[]
{ new SequenceFeature(feature) };
if (sf != null)
{
for (int sfi = 0; sfi < sf.length; sfi++)
{
addSequenceFeature(sf[sfi]);
}
}
}
}
// transfer PDB entries
if (entry.getAllPDBEntries() != null)
{
Enumeration e = entry.getAllPDBEntries().elements();
while (e.hasMoreElements())
{
PDBEntry pdb = e.nextElement();
addPDBId(pdb);
}
}
// transfer database references
List entryRefs = entry.getDBRefs();
if (entryRefs != null)
{
for (int r = 0, n = entryRefs.size(); r < n; r++)
{
DBRefEntry newref = new DBRefEntry(entryRefs.get(r));
if (newref.getMap() != null && mp != null)
{
// remap ref using our local mapping
}
// we also assume all version string setting is done by dbSourceProxy
/*
* if (!newref.getSource().equalsIgnoreCase(dbSource)) {
* newref.setSource(dbSource); }
*/
addDBRef(newref);
}
}
}
@Override
public void setRNA(RNA r)
{
rna = r;
}
@Override
public RNA getRNA()
{
return rna;
}
@Override
public List getAlignmentAnnotations(String calcId,
String label)
{
return getAlignmentAnnotations(calcId, label, null, true);
}
@Override
public List getAlignmentAnnotations(String calcId,
String label, String description)
{
return getAlignmentAnnotations(calcId, label, description, false);
}
private List getAlignmentAnnotations(String calcId,
String label, String description, boolean ignoreDescription)
{
List result = new ArrayList<>();
if (this.annotation != null)
{
for (AlignmentAnnotation ann : annotation)
{
if ((ann.calcId != null && ann.calcId.equals(calcId))
&& (ann.label != null && ann.label.equals(label))
&& ((ignoreDescription && description == null)
|| (ann.description != null
&& ann.description.equals(description))))
{
result.add(ann);
}
}
}
return result;
}
@Override
public String toString()
{
return getDisplayId(false);
}
@Override
public PDBEntry getPDBEntry(String pdbIdStr)
{
if (getDatasetSequence() != null)
{
return getDatasetSequence().getPDBEntry(pdbIdStr);
}
if (pdbIds == null)
{
return null;
}
List entries = getAllPDBEntries();
for (PDBEntry entry : entries)
{
if (entry.getId().equalsIgnoreCase(pdbIdStr))
{
return entry;
}
}
return null;
}
private List tmpList;
@Override
public List getPrimaryDBRefs()
{
if (datasetSequence != null)
{
return datasetSequence.getPrimaryDBRefs();
}
if (dbrefs == null || dbrefs.size() == 0)
{
return Collections.emptyList();
}
synchronized (dbrefs)
{
if (refModCount == dbrefs.getModCount() && primaryRefs != null)
{
return primaryRefs; // no changes
}
refModCount = dbrefs.getModCount();
List primaries = (primaryRefs == null
? (primaryRefs = new ArrayList<>())
: primaryRefs);
primaries.clear();
if (tmpList == null)
{
tmpList = new ArrayList<>();
tmpList.add(null); // for replacement
}
for (int i = 0, n = dbrefs.size(); i < n; i++)
{
DBRefEntry ref = dbrefs.get(i);
if (!ref.isPrimaryCandidate())
{
continue;
}
if (ref.hasMap())
{
MapList mp = ref.getMap().getMap();
if (mp.getFromLowest() > start || mp.getFromHighest() < end)
{
// map only involves a subsequence, so cannot be primary
continue;
}
}
// whilst it looks like it is a primary ref, we also sanity check type
if (DBRefSource.PDB_CANONICAL_NAME
.equals(ref.getCanonicalSourceName()))
{
// PDB dbrefs imply there should be a PDBEntry associated
// TODO: tighten PDB dbrefs
// formally imply Jalview has actually downloaded and
// parsed the pdb file. That means there should be a cached file
// handle on the PDBEntry, and a real mapping between sequence and
// extracted sequence from PDB file
PDBEntry pdbentry = getPDBEntry(ref.getAccessionId());
if (pdbentry == null || pdbentry.getFile() == null)
{
continue;
}
}
else
{
// check standard protein or dna sources
tmpList.set(0, ref);
List res = DBRefUtils.selectDbRefs(!isProtein(),
tmpList);
if (res == null || res.get(0) != tmpList.get(0))
{
continue;
}
}
primaries.add(ref);
}
// version must be not null, as otherwise it will not be a candidate,
// above
DBRefUtils.ensurePrimaries(this, primaries);
return primaries;
}
}
/**
* {@inheritDoc}
*/
@Override
public List findFeatures(int fromColumn, int toColumn,
String... types)
{
int startPos = findPosition(fromColumn - 1); // convert base 1 to base 0
int endPos = fromColumn == toColumn ? startPos
: findPosition(toColumn - 1);
List result = getFeatures().findFeatures(startPos,
endPos, types);
/*
* if end column is gapped, endPos may be to the right,
* and we may have included adjacent or enclosing features;
* remove any that are not enclosing, non-contact features
*/
boolean endColumnIsGapped = toColumn > 0 && toColumn <= sequence.length
&& Comparison.isGap(sequence[toColumn - 1]);
if (endPos > this.end || endColumnIsGapped)
{
ListIterator it = result.listIterator();
while (it.hasNext())
{
SequenceFeature sf = it.next();
int sfBegin = sf.getBegin();
int sfEnd = sf.getEnd();
int featureStartColumn = findIndex(sfBegin);
if (featureStartColumn > toColumn)
{
it.remove();
}
else if (featureStartColumn < fromColumn)
{
int featureEndColumn = sfEnd == sfBegin ? featureStartColumn
: findIndex(sfEnd);
if (featureEndColumn < fromColumn)
{
it.remove();
}
else if (featureEndColumn > toColumn && sf.isContactFeature())
{
/*
* remove an enclosing feature if it is a contact feature
*/
it.remove();
}
}
}
}
return result;
}
/**
* Invalidates any stale cursors (forcing recalculation) by incrementing the
* token that has to match the one presented by the cursor
*/
@Override
public void sequenceChanged()
{
changeCount++;
}
/**
* {@inheritDoc}
*/
@Override
public int replace(char c1, char c2)
{
if (c1 == c2)
{
return 0;
}
int count = 0;
synchronized (sequence)
{
for (int c = 0; c < sequence.length; c++)
{
if (sequence[c] == c1)
{
sequence[c] = c2;
count++;
}
}
}
if (count > 0)
{
sequenceChanged();
}
return count;
}
@Override
public String getSequenceStringFromIterator(Iterator it)
{
StringBuilder newSequence = new StringBuilder();
while (it.hasNext())
{
int[] block = it.next();
if (it.hasNext())
{
newSequence.append(getSequence(block[0], block[1] + 1));
}
else
{
newSequence.append(getSequence(block[0], block[1]));
}
}
return newSequence.toString();
}
@Override
public int firstResidueOutsideIterator(Iterator regions)
{
int start = 0;
if (!regions.hasNext())
{
return findIndex(getStart()) - 1;
}
// Simply walk along the sequence whilst watching for region
// boundaries
int hideStart = getLength();
int hideEnd = -1;
boolean foundStart = false;
// step through the non-gapped positions of the sequence
for (int i = getStart(); i <= getEnd() && (!foundStart); i++)
{
// get alignment position of this residue in the sequence
int p = findIndex(i) - 1;
// update region start/end
while (hideEnd < p && regions.hasNext())
{
int[] region = regions.next();
hideStart = region[0];
hideEnd = region[1];
}
if (hideEnd < p)
{
hideStart = getLength();
}
// update boundary for sequence
if (p < hideStart)
{
start = p;
foundStart = true;
}
}
if (foundStart)
{
return start;
}
// otherwise, sequence was completely hidden
return 0;
}
////
//// Contact Matrix Holder Boilerplate
////
ContactMapHolderI cmholder = new ContactMapHolder();
@Override
public Collection getContactMaps()
{
return cmholder.getContactMaps();
}
@Override
public ContactMatrixI getContactMatrixFor(AlignmentAnnotation ann)
{
return cmholder.getContactMatrixFor(ann);
}
@Override
public ContactListI getContactListFor(AlignmentAnnotation _aa, int column)
{
return cmholder.getContactListFor(_aa, column);
}
@Override
public AlignmentAnnotation addContactList(ContactMatrixI cm)
{
AlignmentAnnotation aa = cmholder.addContactList(cm);
Annotation _aa[] = new Annotation[getLength()];
Annotation dummy = new Annotation(0.0f);
for (int i = 0; i < _aa.length; _aa[i++] = dummy)
{
;
}
aa.annotations = _aa;
aa.setSequenceRef(this);
aa.createSequenceMapping(this, getStart(), false);
addAlignmentAnnotation(aa);
return aa;
}
@Override
public void addContactListFor(AlignmentAnnotation annotation,
ContactMatrixI cm)
{
cmholder.addContactListFor(annotation, cm);
}
}