ranges)
+ {
+ boolean forwardStrand = true;
+ for (int[] range : ranges)
+ {
+ if (range[1] > range[0])
+ {
+ break; // forward strand confirmed
+ }
+ else if (range[1] < range[0])
+ {
+ forwardStrand = false;
+ break; // reverse strand confirmed
+ }
+ }
+ 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.
+ *
+ * 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.
+ *
+ *
+ * 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
+ *
+ *
+ * @param map
+ * @return
+ */
+ public MapList traverse(MapList map)
+ {
+ if (map == null)
+ {
+ return null;
+ }
+
+ /*
+ * 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 toRanges = new ArrayList<>();
+ for (int[] range : getToRanges())
+ {
+ int[] transferred = map.locateInTo(range[0], range[1]);
+ if (transferred == null || transferred.length % 2 != 0)
+ {
+ return null;
+ }
+
/*
- 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!
+ * convert [start1, end1, start2, end2, ...]
+ * to [[start1, end1], [start2, end2], ...]
+ */
+ for (int i = 0; i < transferred.length;)
+ {
+ toRanges.add(new int[] { transferred[i], transferred[i + 1] });
+ i += 2;
+ }
+ }
+
+ 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 [start, end, start, end, ...] ranges in the 'from' range that
+ * map to the given start-end in the 'to' range. Returns null if either
+ * {@code start} or {@code end} is not a mapped 'to' range position.
+ *
+ * @param start
+ * @param end
+ * @return
+ */
+ public int[] locateInFrom2(int start, int end)
+ {
+ List ranges = mapBetween(start, end, toShifts, fromShifts,
+ toRatio, fromRatio);
+
+ // TODO: or just return the List and adjust calling code to match
+ return ranges.isEmpty() ? null : MappingUtils.rangeListToArray(ranges);
+ }
+
+ /**
+ * Returns the [start, end, start, end, ...] ranges in the 'to' range that map
+ * to the given start-end in the 'from' range. Returns null if either
+ * {@code start} or {@code end} is not a mapped 'from' range position.
+ *
+ * @param start
+ * @param end
+ * @return
+ */
+ public int[] locateInTo2(int start, int end)
+ {
+ List ranges = mapBetween(start, end, fromShifts, toShifts,
+ fromRatio, toRatio);
+
+ return ranges.isEmpty() ? null : MappingUtils.rangeListToArray(ranges);
+ }
+
+ /**
+ * A helper method for navigating the mapping. Returns a (possibly empty) list
+ * of [start-end] positions in {@code ranges2} that map to positions in
+ * {@code ranges1} between {@code start} and {@code end}.
+ *
+ * @param start
+ * @param end
+ * @param ranges1
+ * @param ranges2
+ * @param wordLength1
+ * @param wordLength2
+ * @return
+ */
+ final static List mapBetween(int start, int end,
+ List ranges1, List ranges2, int wordLength1,
+ int wordLength2)
+ {
+ /*
+ * first traverse ranges1 and record count of mapped positions
+ * to any that overlap start-end
+ */
+ List overlaps = findOverlapPositions(ranges1, start, end);
+ if (overlaps.isEmpty())
+ {
+ return overlaps;
+ }
+
+ /*
+ * convert positions to equivalent 'word' positions in ranges
+ */
+ mapWords(overlaps, wordLength1, wordLength2);
+
+ /*
+ * walk ranges2 and record the values found at
+ * the offsets in 'overlaps'
+ */
+ List mapped = new ArrayList<>();
+ final int s1 = overlaps.size();
+ final int s2 = ranges2.size();
+ int rangeIndex = 0;
+ int rangeOffset = 0;
+ int mappedCount = 0;
+
+ for (int i = 0 ; i < s1 ; i++)
+ {
+ /*
+ * for each range in overlaps, walk ranges2 and record the values
+ * at the offsets, advancing rangeIndex / Offset
+ */
+ int [] mappedRange = ranges2.get(rangeIndex);
+ int [] overlap = overlaps.get(s1);
+ while (mappedCount < overlap[1])
+ {
+
+ }
+ }
+
+ return mapped;
+ }
+
+ /**
+ * Converts the start-end positions (counted from zero) in the {@code ranges}
+ * list from one word length to another. Start-end positions are expanded if
+ * necessary to cover a whole word of length {@code wordLength1}. Positions
+ * are then divided by {@code wordLength1} and multiplied by
+ * {@code wordLength2} to give equivalent mapped words.
+ *
+ * Put simply, this converts peptide residue positions to the corresponding
+ * codon ranges, and codons - including partial codons - to the corresponding
+ * peptide positions; for example
+ *
+ *
+ * [1, 10] with word lengths 3:1 converts (as if bases [0-11]) to [1, 4]
+ *
+ *
+ * @param ranges
+ * @param wordLength1
+ * @param wordLength2
+ * @return
+ */
+ final static void mapWords(List ranges, int wordLength1,
+ int wordLength2)
+ {
+ if (wordLength1 == 1 && wordLength2 == 1)
+ {
+ return; // nothing to do here
+ }
+ int s = ranges.size();
+ for (int i = 0; i < s; i++)
+ {
+ int[] range = ranges.get(i);
+
+ /*
+ * expand range start to the start of a word,
+ * and convert to wordLength2
+ */
+ range[0] -= range[0] % wordLength1;
+ range[0] = range[0] / wordLength1 * wordLength2;
+
+ /*
+ * similar calculation for range end, adding
+ * (wordLength2 - 1) for end of mapped word
+ */
+ range[1] -= range[1] % wordLength1;
+ range[1] = range[1] / wordLength1 * wordLength2;
+ range[1] += wordLength2 - 1;
+ }
+ }
+
+ /**
+ * Helper method that returns a (possibly empty) list of offsets in
+ * {@code ranges} to subranges that overlap {@code start-end}. The list
+ * returned holds counts of the number of positions traversed (inclusive) to
+ * reach the overlapping positions, not the overlapping values. Returns null
+ * if there are no overlaps.
+ *
+ * @param ranges
+ * @param start
+ * @param end
+ * @return
+ */
+ final static List findOverlapPositions(List ranges,
+ int start, int end)
+ {
+ List positions = new ArrayList<>();
+ int pos = 0;
+ int s = ranges.size();
+ for (int i = 0; i < s; i++)
+ {
+ int[] range = ranges.get(i);
+ addOverlap(positions, pos, range, start, end);
+ pos += 1 + Math.abs(range[1] - range[0]);
+ }
+ return positions;
+ }
+
+ /**
+ * A helper method that checks whether {@code range} overlaps
+ * {@code start-end}, and if so adds the positional offset of the overlap to
+ * {@code positions}.
+ *
+ * @param positions
+ * a list of map offsets to add to
+ * @param pos
+ * the number of mapped positions already visited
+ * @param range
+ * a from-to range (may be forward or reverse)
+ * @param start
+ * position to test for overlap in range
+ * @param end
+ * position to test for overlap in range
+ * @return
+ */
+ final static void addOverlap(List positions, int pos, int[] range,
+ int start, int end)
+ {
+ if (range[1] >= range[0])
+ {
+ /*
+ * forward direction range
+ */
+ if (start <= range[1] && end >= range[0])
+ {
+ /*
+ * overlap
+ */
+ int overlapStart = Math.max(start, range[0]);
+ int overlapEnd = Math.min(end, range[1]);
+ positions
+ .add(new int[]
+ { 1 + overlapStart - range[0], 1 + overlapEnd - range[0] });
+ }
+ }
+ else
+ {
+ /*
+ * reverse direction range
+ */
+ if (start <= range[0] && end >= range[1])
+ {
+ /*
+ * overlap
+ */
+ int overlapStart = Math.max(start, range[1]);
+ int overlapEnd = Math.min(end, range[0]);
+ positions
+ .add(new int[]
+ { 1 + range[0] - overlapStart, 1 + range[0] - overlapEnd });
+ }
+ }
}
}