/* * 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 jalview.util.Comparison; import jalview.util.MapList; import java.util.Iterator; import java.util.NoSuchElementException; import java.util.Vector; public class Mapping { /** * An iterator that serves the aligned codon positions (with their protein * products). * * @author gmcarstairs * */ public class AlignedCodonIterator implements Iterator { /* * The gap character used in the aligned sequence */ private final char gap; /* * The characters of the aligned sequence e.g. "-cGT-ACgTG-" */ private final SequenceI alignedSeq; /* * the sequence start residue */ private int start; /* * Next position (base 0) in the aligned sequence */ private int alignedColumn = 0; /* * Count of bases up to and including alignedColumn position */ private int alignedBases = 0; /* * [start, end] from ranges (base 1) */ private Iterator fromRanges; /* * [start, end] to ranges (base 1) */ private Iterator toRanges; /* * The current [start, end] (base 1) from range */ private int[] currentFromRange = null; /* * The current [start, end] (base 1) to range */ private int[] currentToRange = null; /* * The next 'from' position (base 1) to process */ private int fromPosition = 0; /* * The next 'to' position (base 1) to process */ private int toPosition = 0; /** * Constructor * * @param seq * the aligned sequence * @param gapChar */ public AlignedCodonIterator(SequenceI seq, char gapChar) { this.alignedSeq = seq; this.start = seq.getStart(); this.gap = gapChar; fromRanges = map.getFromRanges().iterator(); toRanges = map.getToRanges().iterator(); if (fromRanges.hasNext()) { currentFromRange = fromRanges.next(); fromPosition = currentFromRange[0]; } if (toRanges.hasNext()) { currentToRange = toRanges.next(); toPosition = currentToRange[0]; } } /** * Returns true unless we have already traversed the whole mapping. */ @Override public boolean hasNext() { if (fromRanges.hasNext()) { return true; } if (currentFromRange == null || fromPosition >= currentFromRange[1]) { return false; } return true; } /** * Returns the next codon's aligned positions, and translated value. * * @throws NoSuchElementException * if hasNext() would have returned false * @throws IncompleteCodonException * if not enough mapped bases are left to make up a codon */ @Override public AlignedCodon next() throws IncompleteCodonException { if (!hasNext()) { throw new NoSuchElementException(); } int[] codon = getNextCodon(); int[] alignedCodon = getAlignedCodon(codon); String peptide = getPeptide(); int peptideCol = toPosition - 1 - Mapping.this.to.getStart(); return new AlignedCodon(alignedCodon[0], alignedCodon[1], alignedCodon[2], peptide, peptideCol); } /** * Retrieve the translation as the 'mapped to' position in the mapped to * sequence. * * @return * @throws NoSuchElementException * if the 'toRange' is exhausted (nothing to map to) */ private String getPeptide() { // TODO should ideally handle toRatio other than 1 as well... // i.e. code like getNextCodon() if (toPosition <= currentToRange[1]) { SequenceI seq = Mapping.this.to; char pep = seq.getCharAt(toPosition - seq.getStart()); toPosition++; return String.valueOf(pep); } if (!toRanges.hasNext()) { throw new NoSuchElementException( "Ran out of peptide at position " + toPosition); } currentToRange = toRanges.next(); toPosition = currentToRange[0]; return getPeptide(); } /** * Get the (base 1) dataset positions for the next codon in the mapping. * * @throws IncompleteCodonException * if less than 3 remaining bases are mapped */ private int[] getNextCodon() { int[] codon = new int[3]; int codonbase = 0; while (codonbase < 3) { if (fromPosition <= currentFromRange[1]) { /* * Add next position from the current start-end range */ codon[codonbase++] = fromPosition++; } else { /* * Move to the next range - if there is one */ if (!fromRanges.hasNext()) { throw new IncompleteCodonException(); } currentFromRange = fromRanges.next(); fromPosition = currentFromRange[0]; } } return codon; } /** * Get the aligned column positions (base 0) for the given sequence * positions (base 1), by counting ungapped characters in the aligned * sequence. * * @param codon * @return */ private int[] getAlignedCodon(int[] codon) { int[] aligned = new int[codon.length]; for (int i = 0; i < codon.length; i++) { aligned[i] = getAlignedColumn(codon[i]); } return aligned; } /** * Get the aligned column position (base 0) for the given sequence position * (base 1). * * @param sequencePos * @return */ private int getAlignedColumn(int sequencePos) { /* * allow for offset e.g. treat pos 8 as 2 if sequence starts at 7 */ int truePos = sequencePos - (start - 1); int length = alignedSeq.getLength(); while (alignedBases < truePos && alignedColumn < length) { char c = alignedSeq.getCharAt(alignedColumn++); if (c != gap && !Comparison.isGap(c)) { alignedBases++; } } return alignedColumn - 1; } @Override public void remove() { // ignore } } /* * Contains the start-end pairs mapping from the associated sequence to the * sequence in the database coordinate system. It also takes care of step * difference between coordinate systems. */ MapList map = null; /* * The sequence that map maps the associated sequence to (if any). */ SequenceI to = null; /* * optional sequence id for the 'from' ranges */ private String mappedFromId; public Mapping(MapList map) { super(); this.map = map; } public Mapping(SequenceI to, MapList map) { this(map); this.to = to; } /** * create a new mapping from * * @param to * the sequence being mapped * @param exon * int[] {start,end,start,end} series on associated sequence * @param is * int[] {start,end,...} ranges on the reference frame being mapped * to * @param i * step size on associated sequence * @param j * step size on mapped frame */ public Mapping(SequenceI to, int[] exon, int[] is, int i, int j) { this(to, new MapList(exon, is, i, j)); } /** * create a duplicate (and independent) mapping object with the same reference * to any SequenceI being mapped to. * * @param map2 */ public Mapping(Mapping map2) { if (map2 != this && map2 != null) { if (map2.map != null) { map = new MapList(map2.map); } to = map2.to; mappedFromId = map2.mappedFromId; } } /** * @return the map */ public MapList getMap() { return map; } /** * @param map * the map to set */ public void setMap(MapList map) { this.map = map; } /** * Equals that compares both the to references and MapList mappings. * * @param o * @return * @see MapList#equals */ @Override public boolean equals(Object o) { if (o == null || !(o instanceof Mapping)) { return false; } Mapping other = (Mapping) o; if (other == this) { return true; } if (other.to != to) { return false; } if ((map != null && other.map == null) || (map == null && other.map != null)) { return false; } if ((map == null && other.map == null) || map.equals(other.map)) { return true; } return false; } /** * Returns a hashCode made from the sequence and maplist */ @Override public int hashCode() { int hashCode = (this.to == null ? 1 : this.to.hashCode()); if (this.map != null) { hashCode = hashCode * 31 + this.map.hashCode(); } return hashCode; } /** * get the 'initial' position in the associated sequence for a position in the * mapped reference frame * * @param mpos * @return */ public int getPosition(int mpos) { if (map != null) { int[] mp = map.shiftTo(mpos); if (mp != null) { return mp[0]; } } return mpos; } /** * gets boundary in direction of mapping * * @param position * in mapped reference frame * @return int{start, end} positions in associated sequence (in direction of * mapped word) */ public int[] getWord(int mpos) { if (map != null) { return map.getToWord(mpos); } return null; } /** * width of mapped unit in associated sequence * */ public int getWidth() { if (map != null) { return map.getFromRatio(); } return 1; } /** * width of unit in mapped reference frame * * @return */ public int getMappedWidth() { if (map != null) { return map.getToRatio(); } return 1; } /** * get mapped position in the associated reference frame for position pos in * the associated sequence. * * @param pos * @return */ public int getMappedPosition(int pos) { if (map != null) { int[] mp = map.shiftFrom(pos); if (mp != null) { return mp[0]; } } return pos; } public int[] getMappedWord(int pos) { if (map != null) { int[] mp = map.shiftFrom(pos); if (mp != null) { return new int[] { mp[0], mp[0] + mp[2] * (map.getToRatio() - 1) }; } } return null; } /** * locates the region of feature f in the associated sequence's reference * frame * * @param f * @return one or more features corresponding to f */ public SequenceFeature[] locateFeature(SequenceFeature f) { if (true) { // f.getBegin()!=f.getEnd()) { if (map != null) { int[] frange = map.locateInFrom(f.getBegin(), f.getEnd()); if (frange == null) { // JBPNote - this isprobably not the right thing to doJBPHack return null; } SequenceFeature[] vf = new SequenceFeature[frange.length / 2]; for (int i = 0, v = 0; i < frange.length; i += 2, v++) { vf[v] = new SequenceFeature(f, frange[i], frange[i + 1], f.getFeatureGroup(), f.getScore()); if (frange.length > 2) { vf[v].setDescription(f.getDescription() + "\nPart " + (v + 1)); } } return vf; } } // give up and just return the feature. return new SequenceFeature[] { f }; } /** * return a series of contigs on the associated sequence corresponding to the * from,to interval on the mapped reference frame * * @param from * @param to * @return int[] { from_i, to_i for i=1 to n contiguous regions in the * associated sequence} */ public int[] locateRange(int from, int to) { if (map != null) { if (from <= to) { from = (map.getToLowest() < from) ? from : map.getToLowest(); to = (map.getToHighest() > to) ? to : map.getToHighest(); if (from > to) { return null; } } else { from = (map.getToHighest() > from) ? from : map.getToHighest(); to = (map.getToLowest() < to) ? to : map.getToLowest(); if (from < to) { return null; } } return map.locateInFrom(from, to); } return new int[] { from, to }; } /** * return a series of mapped contigs mapped from a range on the associated * sequence * * @param from * @param to * @return */ public int[] locateMappedRange(int from, int to) { if (map != null) { if (from <= to) { from = (map.getFromLowest() < from) ? from : map.getFromLowest(); to = (map.getFromHighest() > to) ? to : map.getFromHighest(); if (from > to) { return null; } } else { from = (map.getFromHighest() > from) ? from : map.getFromHighest(); to = (map.getFromLowest() < to) ? to : map.getFromLowest(); if (from < to) { return null; } } return map.locateInTo(from, to); } return new int[] { from, to }; } /** * return a new mapping object with a maplist modifed to only map the visible * regions defined by viscontigs. * * @param viscontigs * @return */ public Mapping intersectVisContigs(int[] viscontigs) { Mapping copy = new Mapping(this); if (map != null) { int vpos = 0; int apos = 0; Vector toRange = new Vector(); Vector fromRange = new Vector(); for (int vc = 0; vc < viscontigs.length; vc += 2) { // find a mapped range in this visible region int[] mpr = locateMappedRange(1 + viscontigs[vc], viscontigs[vc + 1] - 1); if (mpr != null) { for (int m = 0; m < mpr.length; m += 2) { toRange.addElement(new int[] { mpr[m], mpr[m + 1] }); int[] xpos = locateRange(mpr[m], mpr[m + 1]); for (int x = 0; x < xpos.length; x += 2) { fromRange.addElement(new int[] { xpos[x], xpos[x + 1] }); } } } } int[] from = new int[fromRange.size() * 2]; int[] to = new int[toRange.size() * 2]; int[] r; for (int f = 0, fSize = fromRange.size(); f < fSize; f++) { r = (int[]) fromRange.elementAt(f); from[f * 2] = r[0]; from[f * 2 + 1] = r[1]; } for (int f = 0, fSize = toRange.size(); f < fSize; f++) { r = (int[]) toRange.elementAt(f); to[f * 2] = r[0]; to[f * 2 + 1] = r[1]; } copy.setMap( new MapList(from, to, map.getFromRatio(), map.getToRatio())); } return copy; } /** * get the sequence being mapped to - if any * * @return null or a dataset sequence */ public SequenceI getTo() { return to; } /** * set the dataset sequence being mapped to if any * * @param tto */ public void setTo(SequenceI tto) { to = tto; } /** * Returns an iterator which can serve up the aligned codon column positions * and their corresponding peptide products * * @param seq * an aligned (i.e. possibly gapped) sequence * @param gapChar * @return */ public Iterator getCodonIterator(SequenceI seq, char gapChar) { return new AlignedCodonIterator(seq, gapChar); } /** * Readable representation for debugging only, not guaranteed not to change */ @Override public String toString() { return String.format("%s %s", this.map.toString(), this.to == null ? "" : this.to.getName()); } /** * Returns the identifier for the 'from' range sequence, or null if not set * * @return */ public String getMappedFromId() { return mappedFromId; } /** * Sets the identifier for the 'from' range sequence */ public void setMappedFromId(String mappedFromId) { this.mappedFromId = mappedFromId; } }