/*
- * Jalview - A Sequence Alignment Editor and Viewer
- * Copyright (C) 2007 AM Waterhouse, J Procter, G Barton, M Clamp, S Searle
- *
- * This program 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 2
+ * 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.
- *
- * This program 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.
- *
+ *
+ * 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 this program; if not, write to the Free Software
- * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
+ * along with Jalview. If not, see <http://www.gnu.org/licenses/>.
+ * The Jalview Authors are detailed in the 'AUTHORS' file.
*/
package jalview.util;
-import java.util.*;
+import java.util.ArrayList;
+import java.util.Arrays;
+import java.util.BitSet;
+import java.util.List;
/**
- * MapList
- * Simple way of bijectively mapping a non-contiguous linear range to another non-contiguous linear range
+ * A simple way of bijectively mapping a non-contiguous linear range to another
+ * non-contiguous linear range.
+ *
* Use at your own risk!
- * TODO: efficient implementation of private posMap method
- * TODO: test/ensure that sense of from and to ratio start position is conserved (codon start position recovery)
- * TODO: optimize to use int[][] arrays rather than vectors.
+ *
+ * TODO: test/ensure that sense of from and to ratio start position is conserved
+ * (codon start position recovery)
*/
public class MapList
{
- /* (non-Javadoc)
- * @see java.lang.Object#clone()
+
+ /*
+ * Subregions (base 1) described as { [start1, end1], [start2, end2], ...}
+ */
+ private List<int[]> fromShifts;
+
+ /*
+ * Same format as fromShifts, for the 'mapped to' sequence
+ */
+ private List<int[]> toShifts;
+
+ /*
+ * number of steps in fromShifts to one toRatio unit
+ */
+ private int fromRatio;
+
+ /*
+ * number of steps in toShifts to one fromRatio
*/
- protected Object clone() throws CloneNotSupportedException {
- // TODO Auto-generated method stub
- return super.clone();
+ private int toRatio;
+
+ /*
+ * lowest and highest value in the from Map
+ */
+ private int fromLowest;
+
+ private int fromHighest;
+
+ /*
+ * lowest and highest value in the to Map
+ */
+ private int toLowest;
+
+ private int toHighest;
+
+ /**
+ * Constructor
+ */
+ public MapList()
+ {
+ fromShifts = new ArrayList<>();
+ toShifts = new ArrayList<>();
}
- /* (non-Javadoc)
- * @see java.lang.Object#equals(java.lang.Object)
+
+ /**
+ * Two MapList objects are equal if they are the same object, or they both
+ * have populated shift ranges and all values are the same.
*/
- public boolean equals(MapList obj) {
- if (obj==this)
- return true;
- if (obj!=null && obj.fromRatio==fromRatio && obj.toRatio==toRatio
- && obj.fromShifts!=null && obj.toShifts!=null) {
- int i,iSize=fromShifts.size(),j,jSize=obj.fromShifts.size();
- if (iSize!=jSize)
- return false;
- for (i=0,iSize=fromShifts.size(),j=0, jSize=obj.fromShifts.size(); i<iSize;) {
- int[] mi=(int[]) fromShifts.elementAt(i++);
- int[] mj=(int[]) obj.fromShifts.elementAt(j++);
- if (mi[0]!=mj[0] || mi[1]!=mj[1])
- return false;
- }
- iSize=toShifts.size();
- jSize=obj.toShifts.size();
- if (iSize!=jSize)
- return false;
- for (i=0,j=0; i<iSize;) {
- int[] mi=(int[]) toShifts.elementAt(i++);
- int[] mj=(int[]) obj.toShifts.elementAt(j++);
- if (mi[0]!=mj[0] || mi[1]!=mj[1])
- return false;
- }
+ @Override
+ public boolean equals(Object o)
+ {
+ if (o == null || !(o instanceof MapList))
+ {
+ return false;
+ }
+
+ MapList obj = (MapList) o;
+ if (obj == this)
+ {
return true;
}
- return false;
+ if (obj.fromRatio != fromRatio || obj.toRatio != toRatio
+ || obj.fromShifts == null || obj.toShifts == null)
+ {
+ return false;
+ }
+ return Arrays.deepEquals(fromShifts.toArray(), obj.fromShifts.toArray())
+ && Arrays.deepEquals(toShifts.toArray(),
+ obj.toShifts.toArray());
}
- public Vector fromShifts;
- public Vector toShifts;
- int fromRatio; // number of steps in fromShifts to one toRatio unit
- int toRatio; // number of steps in toShifts to one fromRatio
+
/**
- * lowest and highest value in the from Map
+ * Returns a hashcode made from the fromRatio, toRatio, and from/to ranges
+ */
+ @Override
+ public int hashCode()
+ {
+ int hashCode = 31 * fromRatio;
+ hashCode = 31 * hashCode + toRatio;
+ for (int[] shift : fromShifts)
+ {
+ hashCode = 31 * hashCode + shift[0];
+ hashCode = 31 * hashCode + shift[1];
+ }
+ for (int[] shift : toShifts)
+ {
+ hashCode = 31 * hashCode + shift[0];
+ hashCode = 31 * hashCode + shift[1];
+ }
+
+ return hashCode;
+ }
+
+ /**
+ * Returns the 'from' ranges as {[start1, end1], [start2, end2], ...}
+ *
+ * @return
*/
- int[] fromRange=null;
+ public List<int[]> getFromRanges()
+ {
+ return fromShifts;
+ }
+
/**
- * lowest and highest value in the to Map
+ * Returns the 'to' ranges as {[start1, end1], [start2, end2], ...}
+ *
+ * @return
+ */
+ public List<int[]> getToRanges()
+ {
+ return toShifts;
+ }
+
+ /**
+ * Flattens a list of [start, end] into a single [start1, end1, start2,
+ * end2,...] array.
+ *
+ * @param shifts
+ * @return
+ */
+ protected static int[] getRanges(List<int[]> shifts)
+ {
+ int[] rnges = new int[2 * shifts.size()];
+ int i = 0;
+ for (int[] r : shifts)
+ {
+ rnges[i++] = r[0];
+ rnges[i++] = r[1];
+ }
+ return rnges;
+ }
+
+ /**
+ *
+ * @return length of mapped phrase in from
*/
- int[] toRange=null;
public int getFromRatio()
{
return fromRatio;
}
+
+ /**
+ *
+ * @return length of mapped phrase in to
+ */
public int getToRatio()
{
return toRatio;
}
- public int getFromLowest() {
- return fromRange[0];
- }
- public int getFromHighest() {
- return fromRange[1];
+
+ public int getFromLowest()
+ {
+ return fromLowest;
}
- public int getToLowest() {
- return toRange[0];
+
+ public int getFromHighest()
+ {
+ return fromHighest;
}
- public int getToHighest() {
- return toRange[1];
+
+ public int getToLowest()
+ {
+ return toLowest;
}
- private void ensureRange(int[] limits, int pos) {
- if (limits[0]>pos)
- limits[0]=pos;
- if (limits[1]<pos)
- limits[1]=pos;
+
+ public int getToHighest()
+ {
+ return toHighest;
}
+
+ /**
+ * Constructor given from and to ranges as [start1, end1, start2, end2,...].
+ * There is no validation check that the ranges do not overlap each other.
+ *
+ * @param from
+ * contiguous regions as [start1, end1, start2, end2, ...]
+ * @param to
+ * same format as 'from'
+ * @param fromRatio
+ * phrase length in 'from' (e.g. 3 for dna)
+ * @param toRatio
+ * phrase length in 'to' (e.g. 1 for protein)
+ */
public MapList(int from[], int to[], int fromRatio, int toRatio)
{
- fromRange=new int[] { from[0],from[1] };
- toRange=new int[] { to[0],to[1] };
+ this();
+ this.fromRatio = fromRatio;
+ this.toRatio = toRatio;
+ fromLowest = Integer.MAX_VALUE;
+ fromHighest = Integer.MIN_VALUE;
+
+ for (int i = 0; i < from.length; i += 2)
+ {
+ /*
+ * note lowest and highest values - bearing in mind the
+ * direction may be reversed
+ */
+ fromLowest = Math.min(fromLowest, Math.min(from[i], from[i + 1]));
+ fromHighest = Math.max(fromHighest, Math.max(from[i], from[i + 1]));
+ fromShifts.add(new int[] { from[i], from[i + 1] });
+ }
+
+ toLowest = Integer.MAX_VALUE;
+ toHighest = Integer.MIN_VALUE;
+ for (int i = 0; i < to.length; i += 2)
+ {
+ toLowest = Math.min(toLowest, Math.min(to[i], to[i + 1]));
+ toHighest = Math.max(toHighest, Math.max(to[i], to[i + 1]));
+ toShifts.add(new int[] { to[i], to[i + 1] });
+ }
+ }
+
+ /**
+ * Copy constructor. Creates an identical mapping.
+ *
+ * @param map
+ */
+ public MapList(MapList map)
+ {
+ this();
+ // TODO not used - remove?
+ this.fromLowest = map.fromLowest;
+ this.fromHighest = map.fromHighest;
+ this.toLowest = map.toLowest;
+ this.toHighest = map.toHighest;
+
+ this.fromRatio = map.fromRatio;
+ this.toRatio = map.toRatio;
+ if (map.fromShifts != null)
+ {
+ for (int[] r : map.fromShifts)
+ {
+ fromShifts.add(new int[] { r[0], r[1] });
+ }
+ }
+ if (map.toShifts != null)
+ {
+ for (int[] r : map.toShifts)
+ {
+ toShifts.add(new int[] { r[0], r[1] });
+ }
+ }
+ }
+
+ /**
+ * Constructor given ranges as lists of [start, end] positions. There is no
+ * validation check that the ranges do not overlap each other.
+ *
+ * @param fromRange
+ * @param toRange
+ * @param fromRatio
+ * @param toRatio
+ */
+ public MapList(List<int[]> fromRange, List<int[]> toRange, int fromRatio,
+ int toRatio)
+ {
+ this();
+ fromRange = coalesceRanges(fromRange);
+ toRange = coalesceRanges(toRange);
+ this.fromShifts = fromRange;
+ this.toShifts = toRange;
+ this.fromRatio = fromRatio;
+ this.toRatio = toRatio;
- fromShifts = new Vector();
- for (int i=0;i<from.length; i+=2)
+ fromLowest = Integer.MAX_VALUE;
+ fromHighest = Integer.MIN_VALUE;
+ for (int[] range : fromRange)
{
- ensureRange(fromRange, from[i]);
- ensureRange(fromRange, from[i+1]);
+ if (range.length != 2)
+ {
+ // throw new IllegalArgumentException(range);
+ System.err.println("Invalid format for fromRange "
+ + Arrays.toString(range) + " may cause errors");
+ }
+ fromLowest = Math.min(fromLowest, Math.min(range[0], range[1]));
+ fromHighest = Math.max(fromHighest, Math.max(range[0], range[1]));
+ }
- fromShifts.addElement(new int[]
- {from[i], from[i + 1]});
+ toLowest = Integer.MAX_VALUE;
+ toHighest = Integer.MIN_VALUE;
+ for (int[] range : toRange)
+ {
+ if (range.length != 2)
+ {
+ // throw new IllegalArgumentException(range);
+ System.err.println("Invalid format for toRange "
+ + Arrays.toString(range) + " may cause errors");
+ }
+ toLowest = Math.min(toLowest, Math.min(range[0], range[1]));
+ toHighest = Math.max(toHighest, Math.max(range[0], range[1]));
}
- toShifts = new Vector();
- for (int i=0;i<to.length; i+=2)
+ }
+
+ /**
+ * Consolidates a list of ranges so that any contiguous ranges are merged.
+ * This assumes the ranges are already in start order (does not sort them).
+ * <p>
+ * The main use case for this method is when mapping cDNA sequence to its
+ * protein product, based on CDS feature ranges which derive from spliced
+ * exons, but are contiguous on the cDNA sequence. For example
+ *
+ * <pre>
+ * CDS 1-20 // from exon1
+ * CDS 21-35 // from exon2
+ * CDS 36-71 // from exon3
+ * 'coalesce' to range 1-71
+ * </pre>
+ *
+ * @param ranges
+ * @return the same list (if unchanged), else a new merged list, leaving the
+ * input list unchanged
+ */
+ public static List<int[]> coalesceRanges(final List<int[]> ranges)
+ {
+ if (ranges == null || ranges.size() < 2)
{
- ensureRange(toRange, to[i]);
- ensureRange(toRange, to[i+1]);
- toShifts.addElement(new int[]
- {to[i], to[i + 1]});
+ return ranges;
}
- this.fromRatio=fromRatio;
- this.toRatio=toRatio;
+
+ boolean changed = false;
+ List<int[]> merged = new ArrayList<>();
+ int[] lastRange = ranges.get(0);
+ int lastDirection = lastRange[1] >= lastRange[0] ? 1 : -1;
+ lastRange = new int[] { lastRange[0], lastRange[1] };
+ merged.add(lastRange);
+ boolean first = true;
+
+ for (final int[] range : ranges)
+ {
+ if (first)
+ {
+ first = false;
+ continue;
+ }
+
+ int direction = range[1] >= range[0] ? 1 : -1;
+
+ /*
+ * if next range is in the same direction as last and contiguous,
+ * just update the end position of the last range
+ */
+ boolean sameDirection = range[1] == range[0]
+ || direction == lastDirection;
+ boolean extending = range[0] == lastRange[1] + lastDirection;
+ if (sameDirection && extending)
+ {
+ lastRange[1] = range[1];
+ changed = true;
+ }
+ else
+ {
+ lastRange = new int[] { range[0], range[1] };
+ merged.add(lastRange);
+ // careful: merging [5, 5] after [7, 6] should keep negative direction
+ lastDirection = (range[1] == range[0]) ? lastDirection : direction;
+ }
+ }
+
+ return changed ? merged : ranges;
}
+
/**
* get all mapped positions from 'from' to 'to'
- * @return int[][] { int[] { fromStart, fromFinish, toStart, toFinish }, int [fromFinish-fromStart+2] { toStart..toFinish mappings}}
+ *
+ * @return int[][] { int[] { fromStart, fromFinish, toStart, toFinish }, int
+ * [fromFinish-fromStart+2] { toStart..toFinish mappings}}
*/
- public int[][] makeFromMap()
+ protected int[][] makeFromMap()
{
+ // TODO only used for test - remove??
return posMap(fromShifts, fromRatio, toShifts, toRatio);
}
+
/**
* get all mapped positions from 'to' to 'from'
+ *
* @return int[to position]=position mapped in from
*/
- public int[][] makeToMap()
+ protected int[][] makeToMap()
{
- return posMap(toShifts,toRatio, fromShifts, fromRatio);
+ // TODO only used for test - remove??
+ return posMap(toShifts, toRatio, fromShifts, fromRatio);
}
+
/**
* construct an int map for intervals in intVals
- * @param intVals
- * @return int[] { from, to pos in range }, int[range.to-range.from+1] returning mapped position
+ *
+ * @param shiftTo
+ * @return int[] { from, to pos in range }, int[range.to-range.from+1]
+ * returning mapped position
*/
- private int[][] posMap(Vector intVals, int ratio, Vector toIntVals,
- int toRatio)
+ private int[][] posMap(List<int[]> shiftTo, int sourceRatio,
+ List<int[]> shiftFrom, int targetRatio)
{
- int iv=0,ivSize = intVals.size();
- if (iv>=ivSize)
+ // TODO only used for test - remove??
+ int iv = 0, ivSize = shiftTo.size();
+ if (iv >= ivSize)
{
return null;
}
- int[] intv=(int[]) intVals.elementAt(iv++);
- int from=intv[0],to=intv[1];
+ int[] intv = shiftTo.get(iv++);
+ int from = intv[0], to = intv[1];
if (from > to)
{
from = intv[1];
- to=intv[0];
+ to = intv[0];
}
- while (iv<ivSize)
+ while (iv < ivSize)
{
- intv = (int[]) intVals.elementAt(iv++);
- if (intv[0]<from)
+ intv = shiftTo.get(iv++);
+ if (intv[0] < from)
{
- from=intv[0];
+ from = intv[0];
}
- if (intv[1]<from)
+ if (intv[1] < from)
{
- from=intv[1];
+ from = intv[1];
}
- if (intv[0]>to)
+ if (intv[0] > to)
{
- to=intv[0];
+ to = intv[0];
}
- if (intv[1]>to)
+ if (intv[1] > to)
{
- to=intv[1];
+ to = intv[1];
}
}
- int tF=0,tT=0;
- int mp[][] = new int[to-from+2][];
+ int tF = 0, tT = 0;
+ int mp[][] = new int[to - from + 2][];
for (int i = 0; i < mp.length; i++)
{
- int[] m = shift(i+from,intVals,ratio,toIntVals, toRatio);
+ int[] m = shift(i + from, shiftTo, sourceRatio, shiftFrom, targetRatio);
if (m != null)
{
if (i == 0)
{
- tF=tT=m[0];
+ tF = tT = m[0];
}
else
{
if (m[0] < tF)
{
- tF=m[0];
+ tF = m[0];
}
if (m[0] > tT)
{
- tT=m[0];
+ tT = m[0];
}
}
}
mp[i] = m;
}
- int[][] map = new int[][]
- {
- new int[]
- {
- from, to, tF, tT}, new int[to - from + 2]};
+ int[][] map = new int[][] { new int[] { from, to, tF, tT },
+ new int[to - from + 2] };
map[0][2] = tF;
map[0][3] = tT;
{
if (mp[i] != null)
{
- map[1][i] = mp[i][0]-tF;
+ map[1][i] = mp[i][0] - tF;
}
else
{
}
return map;
}
+
/**
* addShift
- * @param pos start position for shift (in original reference frame)
- * @param shift length of shift
- *
- public void addShift(int pos, int shift)
- {
- int sidx = 0;
- int[] rshift=null;
- while (sidx<shifts.size() && (rshift=(int[]) shifts.elementAt(sidx))[0]<pos)
- sidx++;
- if (sidx==shifts.size())
- shifts.insertElementAt(new int[] { pos, shift}, sidx);
- else
- rshift[1]+=shift;
- }
+ *
+ * @param pos
+ * start position for shift (in original reference frame)
+ * @param shift
+ * length of shift
+ *
+ * public void addShift(int pos, int shift) { int sidx = 0; int[]
+ * rshift=null; while (sidx<shifts.size() && (rshift=(int[])
+ * shifts.elementAt(sidx))[0]<pos) sidx++; if (sidx==shifts.size())
+ * shifts.insertElementAt(new int[] { pos, shift}, sidx); else
+ * rshift[1]+=shift; }
*/
+
/**
* shift from pos to To(pos)
- *
- * @param pos int
- * @return int shifted position in To, frameshift in From, direction of mapped symbol in To
+ *
+ * @param pos
+ * int
+ * @return int shifted position in To, frameshift in From, direction of mapped
+ * symbol in To
*/
public int[] shiftFrom(int pos)
{
/**
* inverse of shiftFrom - maps pos in To to a position in From
- * @param pos (in To)
- * @return shifted position in From, frameshift in To, direction of mapped symbol in From
+ *
+ * @param pos
+ * (in To)
+ * @return shifted position in From, frameshift in To, direction of mapped
+ * symbol in From
*/
public int[] shiftTo(int pos)
{
return shift(pos, toShifts, toRatio, fromShifts, fromRatio);
}
+
/**
- *
- * @param fromShifts
+ *
+ * @param shiftTo
* @param fromRatio
- * @param toShifts
+ * @param shiftFrom
* @param toRatio
* @return
*/
- private int[] shift(int pos, Vector fromShifts, int fromRatio,
- Vector toShifts, int toRatio)
+ protected static int[] shift(int pos, List<int[]> shiftTo, int fromRatio,
+ List<int[]> shiftFrom, int toRatio)
{
- int[] fromCount = countPos(fromShifts, pos);
- if (fromCount==null)
+ // TODO: javadoc; tests
+ int[] fromCount = countPositions(shiftTo, pos);
+ if (fromCount == null)
{
return null;
}
- int fromRemainder=(fromCount[0]-1) % fromRatio;
- int toCount = 1+(((fromCount[0]-1) / fromRatio) * toRatio);
- int[] toPos = countToPos(toShifts, toCount);
- if (toPos==null)
+ int fromRemainder = (fromCount[0] - 1) % fromRatio;
+ int toCount = 1 + (((fromCount[0] - 1) / fromRatio) * toRatio);
+ int[] toPos = traverseToPosition(shiftFrom, toCount);
+ if (toPos == null)
{
- return null; // throw new Error("Bad Mapping!");
+ return null;
}
- //System.out.println(fromCount[0]+" "+fromCount[1]+" "+toCount);
- return new int[]
- {
- toPos[0], fromRemainder, toPos[1]};
+ return new int[] { toPos[0], fromRemainder, toPos[1] };
}
+
/**
- * count how many positions pos is along the series of intervals.
- * @param intVals
+ * Counts how many positions pos is along the series of intervals. Returns an
+ * array of two values:
+ * <ul>
+ * <li>the number of positions traversed (inclusive) to reach {@code pos}</li>
+ * <li>+1 if the last interval traversed is forward, -1 if in a negative
+ * direction</li>
+ * </ul>
+ * Returns null if {@code pos} does not lie in any of the given intervals.
+ *
+ * @param intervals
+ * a list of start-end intervals
* @param pos
- * @return number of positions or null if pos is not within intervals
+ * a position that may lie in one (or more) of the intervals
+ * @return
*/
- private int[] countPos(Vector intVals, int pos)
+ protected static int[] countPositions(List<int[]> intervals, int pos)
{
- int count=0,intv[],iv=0,ivSize=intVals.size();
- while (iv<ivSize)
+ int count = 0;
+ int iv = 0;
+ int ivSize = intervals.size();
+
+ while (iv < ivSize)
{
- intv = (int[])intVals.elementAt(iv++);
+ int[] intv = intervals.get(iv++);
if (intv[0] <= intv[1])
{
+ /*
+ * forwards interval
+ */
if (pos >= intv[0] && pos <= intv[1])
{
- return new int[]
- {
- count + pos - intv[0] + 1, +1};
+ return new int[] { count + pos - intv[0] + 1, +1 };
}
else
{
- count+=intv[1]-intv[0]+1;
+ count += intv[1] - intv[0] + 1;
}
}
else
{
+ /*
+ * reverse interval
+ */
if (pos >= intv[1] && pos <= intv[0])
{
- return new int[]
- {
- count + intv[0] - pos + 1, -1};
+ return new int[] { count + intv[0] - pos + 1, -1 };
}
else
{
- count+=intv[0]-intv[1]+1;
+ count += intv[0] - intv[1] + 1;
}
}
}
return null;
}
+
/**
- * count out pos positions into a series of intervals and return the position
- * @param intVals
- * @param pos
- * @return position pos in interval set
+ * Reads through the given intervals until {@code count} positions have been
+ * traversed, and returns an array consisting of two values:
+ * <ul>
+ * <li>the value at the {@code count'th} position</li>
+ * <li>+1 if the last interval read is forwards, -1 if reverse direction</li>
+ * </ul>
+ * Returns null if the ranges include less than {@code count} positions, or if
+ * {@code count < 1}.
+ *
+ * @param intervals
+ * a list of [start, end] ranges
+ * @param count
+ * the number of positions to traverse
+ * @return
*/
- private int[] countToPos(Vector intVals, int pos)
+ protected static int[] traverseToPosition(List<int[]> intervals,
+ final int count)
{
- int count = 0, diff = 0, iv=0,ivSize=intVals.size(), intv[] =
+ int traversed = 0;
+ int ivSize = intervals.size();
+ int iv = 0;
+
+ if (count < 1)
{
- 0, 0};
- while (iv<ivSize)
+ return null;
+ }
+
+ while (iv < ivSize)
{
- intv = (int[])intVals.elementAt(iv++);
- diff = intv[1]-intv[0];
+ int[] intv = intervals.get(iv++);
+ int diff = intv[1] - intv[0];
if (diff >= 0)
{
- if (pos <= count + 1 + diff)
+ if (count <= traversed + 1 + diff)
{
- return new int[]
- {
- pos - count - 1 + intv[0], +1};
+ return new int[] { intv[0] + (count - traversed - 1), +1 };
}
else
{
- count+=1+diff;
+ traversed += 1 + diff;
}
}
else
{
- if (pos <= count + 1 - diff)
+ if (count <= traversed + 1 - diff)
{
- return new int[]
- {
- intv[0] - (pos - count - 1), -1};
+ return new int[] { intv[0] - (count - traversed - 1), -1 };
}
else
{
- count+=1-diff;
+ traversed += 1 - diff;
}
}
}
- return null;//(diff<0) ? (intv[1]-1) : (intv[0]+1);
- }
- /**
- * find series of intervals mapping from start-end in the From map.
- * @param start position in to map
- * @param end position in to map
- * @return series of ranges in from map
- */
- public int[] locateInFrom(int start, int end) {
- // inefficient implementation
- int fromStart[] = shiftTo(start);
- int fromEnd[] = shiftTo(end);
- if (fromStart==null || fromEnd==null)
- return null;
- int iv[] = getIntervals(fromShifts, fromStart, fromEnd,fromRatio);
- return iv;
+ return null;
}
/**
- * find series of intervals mapping from start-end in the to map.
- * @param start position in from map
- * @param end position in from map
- * @return series of ranges in to map
- */
- public int[] locateInTo(int start, int end) {
- // inefficient implementation
- int toStart[] = shiftFrom(start);
- int toEnd[] = shiftFrom(end);
- if (toStart==null || toEnd==null)
- return null;
- int iv[] = getIntervals(toShifts, toStart, toEnd, toRatio);
- return iv;
- }
- /**
- * like shift - except returns the intervals in the given vector of shifts which were spanned
- * in traversing fromStart to fromEnd
- * @param fromShifts2
+ * like shift - except returns the intervals in the given vector of shifts
+ * which were spanned in traversing fromStart to fromEnd
+ *
+ * @param shiftFrom
* @param fromStart
* @param fromEnd
* @param fromRatio2
- * @return
+ * @return series of from,to intervals from from first position of starting
+ * region to final position of ending region inclusive
*/
- private int[] getIntervals(Vector fromShifts2, int[] fromStart, int[] fromEnd, int fromRatio2)
- {
- // correct for word direction for start and end
- int startpos = fromStart[0]+fromStart[2]*(fromRatio2-1);
- int endpos = fromEnd[0]+fromEnd[2]*(fromRatio2-1);
- int intv=0,intvSize= fromShifts2.size();
- int iv[],i=0,fs=-1,fe=-1; // containing intervals
- while (intv<intvSize && (fs==-1 || fe==-1)) {
- iv = (int[]) fromShifts2.elementAt(intv++);
- if (iv[0]<=iv[1]) {
- if (fs==-1 && startpos>=iv[0] && startpos<=iv[1]) {
+ protected static int[] getIntervals(List<int[]> shiftFrom,
+ int[] fromStart, int[] fromEnd, int fromRatio2)
+ {
+ if (fromStart == null || fromEnd == null)
+ {
+ return null;
+ }
+ int startpos, endpos;
+ startpos = fromStart[0]; // first position in fromStart
+ endpos = fromEnd[0]; // last position in fromEnd
+ int endindx = (fromRatio2 - 1); // additional positions to get to last
+ // position from endpos
+ int intv = 0, intvSize = shiftFrom.size();
+ int iv[], i = 0, fs = -1, fe_s = -1, fe = -1; // containing intervals
+ // search intervals to locate ones containing startpos and count endindx
+ // positions on from endpos
+ while (intv < intvSize && (fs == -1 || fe == -1))
+ {
+ iv = shiftFrom.get(intv++);
+ if (fe_s > -1)
+ {
+ endpos = iv[0]; // start counting from beginning of interval
+ endindx--; // inclusive of endpos
+ }
+ if (iv[0] <= iv[1])
+ {
+ if (fs == -1 && startpos >= iv[0] && startpos <= iv[1])
+ {
fs = i;
}
- if (fe==-1 && endpos>=iv[0] && endpos<=iv[1]) {
- fe = i;
+ if (endpos >= iv[0] && endpos <= iv[1])
+ {
+ if (fe_s == -1)
+ {
+ fe_s = i;
+ }
+ if (fe_s != -1)
+ {
+ if (endpos + endindx <= iv[1])
+ {
+ fe = i;
+ endpos = endpos + endindx; // end of end token is within this
+ // interval
+ }
+ else
+ {
+ endindx -= iv[1] - endpos; // skip all this interval too
+ }
+ }
}
- } else {
- if (fs==-1 && startpos<=iv[0] && startpos>=iv[1]) {
+ }
+ else
+ {
+ if (fs == -1 && startpos <= iv[0] && startpos >= iv[1])
+ {
fs = i;
}
- if (fe==-1 && endpos<=iv[0] && endpos>=iv[1]) {
- fe = i;
+ if (endpos <= iv[0] && endpos >= iv[1])
+ {
+ if (fe_s == -1)
+ {
+ fe_s = i;
+ }
+ if (fe_s != -1)
+ {
+ if (endpos - endindx >= iv[1])
+ {
+ fe = i;
+ endpos = endpos - endindx; // end of end token is within this
+ // interval
+ }
+ else
+ {
+ endindx -= endpos - iv[1]; // skip all this interval too
+ }
+ }
}
}
i++;
}
- if (fs==fe && fe==-1)
+ if (fs == fe && fe == -1)
+ {
return null;
- Vector ranges=new Vector();
- if (fs<=fe) {
+ }
+ List<int[]> ranges = new ArrayList<>();
+ if (fs <= fe)
+ {
intv = fs;
- i=fs;
+ i = fs;
// truncate initial interval
- iv = (int[]) fromShifts2.elementAt(intv++);
- iv = new int[] { iv[0], iv[1]};// clone
- if (i==fs)
+ iv = shiftFrom.get(intv++);
+ iv = new int[] { iv[0], iv[1] };// clone
+ if (i == fs)
+ {
iv[0] = startpos;
- while (i!=fe) {
- ranges.addElement(iv); // add initial range
- iv = (int[]) fromShifts2.elementAt(intv++); // get next interval
- iv = new int[] { iv[0], iv[1]};// clone
+ }
+ while (i != fe)
+ {
+ ranges.add(iv); // add initial range
+ iv = shiftFrom.get(intv++); // get next interval
+ iv = new int[] { iv[0], iv[1] };// clone
i++;
}
- if (i==fe)
+ if (i == fe)
+ {
iv[1] = endpos;
- ranges.addElement(iv); // add only - or final range
- } else {
+ }
+ ranges.add(iv); // add only - or final range
+ }
+ else
+ {
// walk from end of interval.
- i=fromShifts2.size()-1;
- while (i>fs) {
+ i = shiftFrom.size() - 1;
+ while (i > fs)
+ {
i--;
}
- iv = (int[]) fromShifts2.elementAt(i);
- iv = new int[] { iv[1], iv[0]};// reverse and clone
+ iv = shiftFrom.get(i);
+ iv = new int[] { iv[1], iv[0] };// reverse and clone
// truncate initial interval
- if (i==fs)
+ if (i == fs)
{
iv[0] = startpos;
}
- while (i!=fe) {
- ranges.addElement(iv); // add (truncated) reversed interval
- iv = (int[]) fromShifts2.elementAt(--i);
+ while (--i != fe)
+ { // fix apparent logic bug when fe==-1
+ ranges.add(iv); // add (truncated) reversed interval
+ iv = shiftFrom.get(i);
iv = new int[] { iv[1], iv[0] }; // reverse and clone
}
- if (i==fe) {
+ if (i == fe)
+ {
// interval is already reversed
iv[1] = endpos;
}
- ranges.addElement(iv); // add only - or final range
+ ranges.add(iv); // add only - or final range
}
// create array of start end intervals.
int[] range = null;
- if (ranges!=null && ranges.size()>0)
+ if (ranges != null && ranges.size() > 0)
{
- range = new int[ranges.size()*2];
+ range = new int[ranges.size() * 2];
intv = 0;
- intvSize=ranges.size();
- i=0;
- while (intv<intvSize)
+ intvSize = ranges.size();
+ i = 0;
+ while (intv < intvSize)
{
- iv = (int[]) ranges.elementAt(intv);
+ iv = ranges.get(intv);
range[i++] = iv[0];
range[i++] = iv[1];
- ranges.setElementAt(null, intv++); // remove
+ ranges.set(intv++, null); // remove
}
}
return range;
}
+
+ /**
+ * get the 'initial' position of mpos in To
+ *
+ * @param mpos
+ * position in from
+ * @return position of first word in to reference frame
+ */
+ public int getToPosition(int mpos)
+ {
+ int[] mp = shiftTo(mpos);
+ if (mp != null)
+ {
+ return mp[0];
+ }
+ return mpos;
+ }
+
+ /**
+ *
+ * @return a MapList whose From range is this maplist's To Range, and vice
+ * versa
+ */
+ public MapList getInverse()
+ {
+ return new MapList(getToRanges(), getFromRanges(), getToRatio(),
+ getFromRatio());
+ }
+
+ /**
+ * String representation - for debugging, not guaranteed not to change
+ */
+ @Override
+ public String toString()
+ {
+ StringBuilder sb = new StringBuilder(64);
+ sb.append("[");
+ for (int[] shift : fromShifts)
+ {
+ sb.append(" ").append(Arrays.toString(shift));
+ }
+ sb.append(" ] ");
+ sb.append(fromRatio).append(":").append(toRatio);
+ sb.append(" to [");
+ for (int[] shift : toShifts)
+ {
+ sb.append(" ").append(Arrays.toString(shift));
+ }
+ sb.append(" ]");
+ return sb.toString();
+ }
+
+ /**
+ * Extend this map list by adding the given map's ranges. There is no
+ * validation check that the ranges do not overlap existing ranges (or each
+ * other), but contiguous ranges are merged.
+ *
+ * @param map
+ */
+ public void addMapList(MapList map)
+ {
+ if (this.equals(map))
+ {
+ return;
+ }
+ this.fromLowest = Math.min(fromLowest, map.fromLowest);
+ this.toLowest = Math.min(toLowest, map.toLowest);
+ this.fromHighest = Math.max(fromHighest, map.fromHighest);
+ this.toHighest = Math.max(toHighest, map.toHighest);
+
+ for (int[] range : map.getFromRanges())
+ {
+ addRange(range, fromShifts);
+ }
+ for (int[] range : map.getToRanges())
+ {
+ addRange(range, toShifts);
+ }
+ }
+
+ /**
+ * Adds the given range to a list of ranges. If the new range just extends
+ * existing ranges, the current endpoint is updated instead.
+ *
+ * @param range
+ * @param addTo
+ */
+ static void addRange(int[] range, List<int[]> addTo)
+ {
+ /*
+ * list is empty - add to it!
+ */
+ if (addTo.size() == 0)
+ {
+ addTo.add(range);
+ return;
+ }
+
+ int[] last = addTo.get(addTo.size() - 1);
+ boolean lastForward = last[1] >= last[0];
+ boolean newForward = range[1] >= range[0];
+
+ /*
+ * contiguous range in the same direction - just update endpoint
+ */
+ if (lastForward == newForward && last[1] == range[0])
+ {
+ last[1] = range[1];
+ return;
+ }
+
+ /*
+ * next range starts at +1 in forward sense - update endpoint
+ */
+ if (lastForward && newForward && range[0] == last[1] + 1)
+ {
+ last[1] = range[1];
+ return;
+ }
+
+ /*
+ * next range starts at -1 in reverse sense - update endpoint
+ */
+ if (!lastForward && !newForward && range[0] == last[1] - 1)
+ {
+ last[1] = range[1];
+ return;
+ }
+
+ /*
+ * just add the new range
+ */
+ addTo.add(range);
+ }
+
/**
- * test routine. not incremental.
- * @param ml
- * @param fromS
- * @param fromE
+ * Returns true if mapping is from forward strand, false if from reverse
+ * strand. Result is just based on the first 'from' range that is not a single
+ * position. Default is true unless proven to be false. Behaviour is not well
+ * defined if the mapping has a mixture of forward and reverse ranges.
+ *
+ * @return
*/
- public static void testMap(MapList ml, int fromS, int fromE)
+ public boolean isFromForwardStrand()
{
- for (int from = 1; from <= 25; from++)
+ return isForwardStrand(getFromRanges());
+ }
+
+ /**
+ * Returns true if mapping is to forward strand, false if to reverse strand.
+ * Result is just based on the first 'to' range that is not a single position.
+ * Default is true unless proven to be false. Behaviour is not well defined if
+ * the mapping has a mixture of forward and reverse ranges.
+ *
+ * @return
+ */
+ public boolean isToForwardStrand()
+ {
+ return isForwardStrand(getToRanges());
+ }
+
+ /**
+ * A helper method that returns true unless at least one range has start >
+ * end. Behaviour is undefined for a mixture of forward and reverse ranges.
+ *
+ * @param ranges
+ * @return
+ */
+ private boolean isForwardStrand(List<int[]> ranges)
+ {
+ boolean forwardStrand = true;
+ for (int[] range : ranges)
{
- int[] too=ml.shiftFrom(from);
- System.out.print("ShiftFrom("+from+")==");
- if (too==null)
+ if (range[1] > range[0])
{
- System.out.print("NaN\n");
+ break; // forward strand confirmed
}
- else
+ else if (range[1] < range[0])
{
- System.out.print(too[0]+" % "+too[1]+" ("+too[2]+")");
- System.out.print("\t+--+\t");
- int[] toofrom=ml.shiftTo(too[0]);
- if (toofrom != null)
- {
- if (toofrom[0]!=from)
- {
- System.err.println("Mapping not reflexive:" + from + " " + too[0] +
- "->" + toofrom[0]);
- }
- System.out.println("ShiftTo(" + too[0] + ")==" + toofrom[0] + " % " +
- toofrom[1]+" ("+toofrom[2]+")");
- }
- else
- {
- System.out.println("ShiftTo(" + too[0] + ")==" +
- "NaN! - not Bijective Mapping!");
- }
+ forwardStrand = false;
+ break; // reverse strand confirmed
}
}
- int mmap[][] = ml.makeFromMap();
- System.out.println("FromMap : (" + mmap[0][0] + " " + mmap[0][1] + " " +
- mmap[0][2] + " " + mmap[0][3] + " ");
- for (int i = 1; i <= mmap[1].length; i++)
+ return forwardStrand;
+ }
+
+ /**
+ *
+ * @return true if from, or to is a three to 1 mapping
+ */
+ public boolean isTripletMap()
+ {
+ return (toRatio == 3 && fromRatio == 1)
+ || (fromRatio == 3 && toRatio == 1);
+ }
+
+ /**
+ * Returns a map which is the composite of this one and the input map. That
+ * is, the output map has the fromRanges of this map, and its toRanges are the
+ * toRanges of this map as transformed by the input map.
+ * <p>
+ * Returns null if the mappings cannot be traversed (not all toRanges of this
+ * map correspond to fromRanges of the input), or if this.toRatio does not
+ * match map.fromRatio.
+ *
+ * <pre>
+ * Example 1:
+ * this: from [1-100] to [501-600]
+ * input: from [10-40] to [60-90]
+ * output: from [10-40] to [560-590]
+ * Example 2 ('reverse strand exons'):
+ * this: from [1-100] to [2000-1951], [1000-951] // transcript to loci
+ * input: from [1-50] to [41-90] // CDS to transcript
+ * output: from [10-40] to [1960-1951], [1000-971] // CDS to gene loci
+ * </pre>
+ *
+ * @param map
+ * @return
+ */
+ public MapList traverse(MapList map)
+ {
+ if (map == null)
{
- if (mmap[1][i - 1] == -1)
- {
- System.out.print(i+"=XXX");
+ return null;
+ }
- }
- else
+ /*
+ * compound the ratios by this rule:
+ * A:B with M:N gives A*M:B*N
+ * reduced by greatest common divisor
+ * so 1:3 with 3:3 is 3:9 or 1:3
+ * 1:3 with 3:1 is 3:3 or 1:1
+ * 1:3 with 1:3 is 1:9
+ * 2:5 with 3:7 is 6:35
+ */
+ int outFromRatio = getFromRatio() * map.getFromRatio();
+ int outToRatio = getToRatio() * map.getToRatio();
+ int gcd = MathUtils.gcd(outFromRatio, outToRatio);
+ outFromRatio /= gcd;
+ outToRatio /= gcd;
+
+ List<int[]> toRanges = new ArrayList<>();
+ for (int[] range : getToRanges())
+ {
+ int fromLength = Math.abs(range[1] - range[0]) + 1;
+ int[] transferred = map.locateInTo(range[0], range[1]);
+ if (transferred == null || transferred.length % 2 != 0)
{
- System.out.print(i+"="+(mmap[0][2]+mmap[1][i-1]));
+ return null;
}
- if (i % 20==0)
+
+ /*
+ * convert [start1, end1, start2, end2, ...]
+ * to [[start1, end1], [start2, end2], ...]
+ */
+ int toLength = 0;
+ for (int i = 0; i < transferred.length;)
{
- System.out.print("\n");
+ toRanges.add(new int[] { transferred[i], transferred[i + 1] });
+ toLength += Math.abs(transferred[i + 1] - transferred[i]) + 1;
+ i += 2;
}
- else
+
+ /*
+ * check we mapped the full range - if not, abort
+ */
+ if (fromLength * map.getToRatio() != toLength * map.getFromRatio())
{
- System.out.print(",");
+ return null;
}
}
- //test range function
- System.out.print("\nTest locateInFrom\n");
+
+ return new MapList(getFromRanges(), toRanges, outFromRatio, outToRatio);
+ }
+
+ /**
+ * Answers true if the mapping is from one contiguous range to another, else
+ * false
+ *
+ * @return
+ */
+ public boolean isContiguous()
+ {
+ return fromShifts.size() == 1 && toShifts.size() == 1;
+ }
+
+ /**
+ * Returns the [start1, end1, start2, end2, ...] positions in the 'from' range
+ * that map to positions between {@code start} and {@code end} in the 'to'
+ * range. Note that for a reverse strand mapping this will return ranges with
+ * end < start. Returns null if no mapped positions are found in start-end.
+ *
+ * @param start
+ * @param end
+ * @return
+ */
+ public int[] locateInFrom(int start, int end)
+ {
+ return mapPositions(start, end, toShifts, fromShifts,
+ toRatio, fromRatio);
+ }
+
+ /**
+ * Returns the [start1, end1, start2, end2, ...] positions in the 'to' range
+ * that map to positions between {@code start} and {@code end} in the 'from'
+ * range. Note that for a reverse strand mapping this will return ranges with
+ * end < start. Returns null if no mapped positions are found in start-end.
+ *
+ * @param start
+ * @param end
+ * @return
+ */
+ public int[] locateInTo(int start, int end)
+ {
+ return mapPositions(start, end, fromShifts, toShifts,
+ fromRatio, toRatio);
+ }
+
+ /**
+ * Helper method that returns the [start1, end1, start2, end2, ...] positions
+ * in {@code targetRange} that map to positions between {@code start} and
+ * {@code end} in {@code sourceRange}. Note that for a reverse strand mapping
+ * this will return ranges with end < start. Returns null if no mapped
+ * positions are found in start-end.
+ *
+ * @param start
+ * @param end
+ * @param sourceRange
+ * @param targetRange
+ * @param sourceWordLength
+ * @param targetWordLength
+ * @return
+ */
+ final static int[] mapPositions(int start, int end,
+ List<int[]> sourceRange, List<int[]> targetRange,
+ int sourceWordLength, int targetWordLength)
+ {
+ if (end < start)
{
- int f=mmap[0][2],t=mmap[0][3];
- while (f<t) {
- System.out.println("Range "+f+" to "+t);
- int rng[] = ml.locateInFrom(f,t);
- if (rng!=null)
- {
- for (int i=0; i<rng.length; i++) {
- System.out.print(rng[i]+((i%2==0) ? "," : ";"));
- }
- }
- else
- {
- System.out.println("No range!");
- }
- System.out.print("\nReversed\n");
- rng = ml.locateInFrom(t,f);
- if (rng!=null)
- {
- for (int i=0; i<rng.length; i++) {
- System.out.print(rng[i]+((i%2==0) ? "," : ";"));
- }
- }
- else
- {
- System.out.println("No range!");
- }
- System.out.print("\n");
- f++;t--;
- }
+ int tmp = end;
+ end = start;
+ start = tmp;
}
- System.out.print("\n");
- mmap = ml.makeToMap();
- System.out.println("ToMap : (" + mmap[0][0] + " " + mmap[0][1] + " " +
- mmap[0][2] + " " + mmap[0][3] + " ");
- for (int i = 1; i <= mmap[1].length; i++)
+
+ /*
+ * traverse sourceRange and mark offsets in targetRange
+ * of any positions that lie in [start, end]
+ */
+ BitSet offsets = getMappedOffsetsForPositions(start, end, sourceRange,
+ sourceWordLength, targetWordLength);
+
+ /*
+ * traverse targetRange and collect positions at the marked offsets
+ */
+ List<int[]> mapped = getPositionsForOffsets(targetRange, offsets);
+
+ // TODO: or just return the List and adjust calling code to match
+ return mapped.isEmpty() ? null : MappingUtils.rangeListToArray(mapped);
+ }
+
+ /**
+ * Scans the list of {@code ranges} for any values (positions) that lie
+ * between start and end (inclusive), and records the <em>offsets</em> from
+ * the start of the list as a BitSet. The offset positions are converted to
+ * corresponding words in blocks of {@code wordLength2}.
+ *
+ * <pre>
+ * For example:
+ * 1:1 (e.g. gene to CDS):
+ * ranges { [10-20], [31-40] }, wordLengthFrom = wordLength 2 = 1
+ * for start = 1, end = 9, returns a BitSet with no bits set
+ * for start = 1, end = 11, returns a BitSet with bits 0-1 set
+ * for start = 15, end = 35, returns a BitSet with bits 5-15 set
+ * 1:3 (peptide to codon):
+ * ranges { [1-200] }, wordLengthFrom = 1, wordLength 2 = 3
+ * for start = 9, end = 9, returns a BitSet with bits 24-26 set
+ * 3:1 (codon to peptide):
+ * ranges { [101-150], [171-180] }, wordLengthFrom = 3, wordLength 2 = 1
+ * for start = 101, end = 102 (partial first codon), returns a BitSet with bit 0 set
+ * for start = 150, end = 171 (partial 17th codon), returns a BitSet with bit 16 set
+ * 3:1 (circular DNA to peptide):
+ * ranges { [101-150], [21-30] }, wordLengthFrom = 3, wordLength 2 = 1
+ * for start = 24, end = 40 (spans codons 18-20), returns a BitSet with bits 17-19 set
+ * </pre>
+ *
+ * @param start
+ * @param end
+ * @param sourceRange
+ * @param sourceWordLength
+ * @param targetWordLength
+ * @return
+ */
+ protected final static BitSet getMappedOffsetsForPositions(int start,
+ int end, List<int[]> sourceRange, int sourceWordLength, int targetWordLength)
+ {
+ BitSet overlaps = new BitSet();
+ int offset = 0;
+ final int s1 = sourceRange.size();
+ for (int i = 0; i < s1; i++)
{
- if (mmap[1][i - 1] == -1)
- {
- System.out.print(i+"=XXX");
+ int[] range = sourceRange.get(i);
+ final int offset1 = offset;
+ int overlapStartOffset = -1;
+ int overlapEndOffset = -1;
- }
- else
+ if (range[1] >= range[0])
{
- System.out.print(i+"="+(mmap[0][2]+mmap[1][i-1]));
- }
- if (i % 20==0)
- {
- System.out.print("\n");
+ /*
+ * forward direction range
+ */
+ if (start <= range[1] && end >= range[0])
+ {
+ /*
+ * overlap
+ */
+ int overlapStart = Math.max(start, range[0]);
+ overlapStartOffset = offset1 + overlapStart - range[0];
+ int overlapEnd = Math.min(end, range[1]);
+ overlapEndOffset = offset1 + overlapEnd - range[0];
+ }
}
else
{
- System.out.print(",");
- }
- }
- System.out.print("\n");
- //test range function
- System.out.print("\nTest locateInTo\n");
- {
- int f=mmap[0][2],t=mmap[0][3];
- while (f<t) {
- System.out.println("Range "+f+" to "+t);
- int rng[] = ml.locateInTo(f,t);
- if (rng!=null) {
- for (int i=0; i<rng.length; i++) {
- System.out.print(rng[i]+((i%2==0) ? "," : ";"));
- }
- }
- else
- {
- System.out.println("No range!");
- }
- System.out.print("\nReversed\n");
- rng = ml.locateInTo(t,f);
- if (rng!=null)
+ /*
+ * reverse direction range
+ */
+ if (start <= range[0] && end >= range[1])
{
- for (int i=0; i<rng.length; i++) {
- System.out.print(rng[i]+((i%2==0) ? "," : ";"));
- }
+ /*
+ * overlap
+ */
+ int overlapStart = Math.max(start, range[1]);
+ int overlapEnd = Math.min(end, range[0]);
+ overlapStartOffset = offset1 + range[0] - overlapEnd;
+ overlapEndOffset = offset1 + range[0] - overlapStart;
}
- else
+ }
+
+ if (overlapStartOffset > -1)
+ {
+ /*
+ * found an overlap
+ */
+ if (sourceWordLength != targetWordLength)
{
- System.out.println("No range!");
+ /*
+ * convert any overlap found to whole words in the target range
+ * (e.g. treat any partial codon overlap as if the whole codon)
+ */
+ overlapStartOffset -= overlapStartOffset % sourceWordLength;
+ overlapStartOffset = overlapStartOffset / sourceWordLength
+ * targetWordLength;
+
+ /*
+ * similar calculation for range end, adding
+ * (wordLength2 - 1) for end of mapped word
+ */
+ overlapEndOffset -= overlapEndOffset % sourceWordLength;
+ overlapEndOffset = overlapEndOffset / sourceWordLength
+ * targetWordLength;
+ overlapEndOffset += targetWordLength - 1;
}
- f++; t--;
- System.out.print("\n");
+ overlaps.set(overlapStartOffset, overlapEndOffset + 1);
}
+ offset += 1 + Math.abs(range[1] - range[0]);
}
-
+ return overlaps;
}
- public static void main(String argv[])
+ /**
+ * Returns a (possibly empty) list of the [start-end] values (positions) at
+ * offsets in the {@code targetRange} list that are marked by 'on' bits in the
+ * {@code offsets} bitset.
+ *
+ * @param targetRange
+ * @param offsets
+ * @return
+ */
+ protected final static List<int[]> getPositionsForOffsets(
+ List<int[]> targetRange, BitSet offsets)
{
- MapList ml = new MapList(new int[]
- {1, 5, 10, 15, 25, 20},
- new int[]
- {51, 1}, 1, 3);
- MapList ml1 = new MapList(new int[]
- {1, 3, 17, 4},
- new int[]
- {51, 1}, 1, 3);
- MapList ml2 = new MapList(new int[] { 1, 60 },
- new int[] { 1, 20 }, 3, 1);
- // test internal consistency
- int to[] = new int[51];
- MapList.testMap(ml, 1, 60);
+ List<int[]> mapped = new ArrayList<>();
+ if (offsets.isEmpty())
+ {
+ return mapped;
+ }
+
+ /*
+ * count of positions preceding ranges[i]
+ */
+ int traversed = 0;
+
/*
- for (int from=1; from<=51; from++) {
- int[] too=ml.shiftTo(from);
- int[] toofrom=ml.shiftFrom(too[0]);
- System.out.println("ShiftFrom("+from+")=="+too[0]+" % "+too[1]+"\t+-+\tShiftTo("+too[0]+")=="+toofrom[0]+" % "+toofrom[1]);
- }*/
- System.out.print("Success?\n"); // if we get here - something must be working!
+ * for each [from-to] range in ranges:
+ * - find subranges (if any) at marked offsets
+ * - add the start-end values at the marked positions
+ */
+ final int toAdd = offsets.cardinality();
+ int added = 0;
+ final int s2 = targetRange.size();
+ for (int i = 0; added < toAdd && i < s2; i++)
+ {
+ int[] range = targetRange.get(i);
+ added += addOffsetPositions(mapped, traversed, range, offsets);
+ traversed += Math.abs(range[1] - range[0]) + 1;
+ }
+ return mapped;
+ }
+
+ /**
+ * Helper method that adds any start-end subranges of {@code range} that are
+ * at offsets in {@code range} marked by set bits in overlaps.
+ * {@code mapOffset} is added to {@code range} offset positions. Returns the
+ * count of positions added.
+ *
+ * @param mapped
+ * @param mapOffset
+ * @param range
+ * @param overlaps
+ * @return
+ */
+ final static int addOffsetPositions(List<int[]> mapped,
+ final int mapOffset, final int[] range, final BitSet overlaps)
+ {
+ final int rangeLength = 1 + Math.abs(range[1] - range[0]);
+ final int step = range[1] < range[0] ? -1 : 1;
+ int offsetStart = 0; // offset into range
+ int added = 0;
+
+ while (offsetStart < rangeLength)
+ {
+ /*
+ * find the start of the next marked overlap offset;
+ * if there is none, or it is beyond range, then finished
+ */
+ int overlapStart = overlaps.nextSetBit(mapOffset + offsetStart);
+ if (overlapStart == -1 || overlapStart - mapOffset >= rangeLength)
+ {
+ /*
+ * no more overlaps, or no more within range[]
+ */
+ return added;
+ }
+ overlapStart -= mapOffset;
+
+ /*
+ * end of the overlap range is just before the next clear bit;
+ * restrict it to end of range if necessary;
+ * note we may add a reverse strand range here (end < start)
+ */
+ int overlapEnd = overlaps.nextClearBit(mapOffset + overlapStart + 1);
+ overlapEnd = (overlapEnd == -1) ? rangeLength - 1
+ : Math.min(rangeLength - 1, overlapEnd - mapOffset - 1);
+ int startPosition = range[0] + step * overlapStart;
+ int endPosition = range[0] + step * overlapEnd;
+ mapped.add(new int[] { startPosition, endPosition });
+ offsetStart = overlapEnd + 1;
+ added += Math.abs(endPosition - startPosition) + 1;
+ }
+
+ return added;
}
}