(feature);
- }
- else
- {
- nestedFeatures.add(feature);
+ nestedFeatures = new NCList<>(feature);
+ return true;
}
+ return nestedFeatures.add(feature, false);
}
/**
@@ -127,8 +362,6 @@ public class FeatureStore
* contained by) an existing feature. If there is no nesting, the feature is
* added to the list and the method returns true. If nesting is found, the
* feature is not added and the method returns false.
- *
- * Contact features are added at the position of their first contact point
*
* @param feature
* @return
@@ -137,7 +370,11 @@ public class FeatureStore
{
synchronized (nonNestedFeatures)
{
- int insertPosition = binarySearchForAdd(nonNestedFeatures, feature);
+ /*
+ * find the first stored feature which doesn't precede the new one
+ */
+ int insertPosition = binarySearch(nonNestedFeatures,
+ SearchCriterion.byFeature(feature, RangeComparator.BY_START_POSITION));
/*
* fail if we detect feature enclosure - of the new feature by
@@ -159,16 +396,10 @@ public class FeatureStore
}
/*
- * checks passed - add or append the feature
+ * checks passed - add the feature
*/
- if (insertPosition == nonNestedFeatures.size())
- {
- nonNestedFeatures.add(feature);
- }
- else
- {
- nonNestedFeatures.add(insertPosition, feature);
- }
+ nonNestedFeatures.add(insertPosition, feature);
+
return true;
}
}
@@ -198,56 +429,85 @@ public class FeatureStore
}
/**
- * Answers the index of the first element in the given list which follows or
- * matches the given feature in the sort order. If no such element, answers
- * the length of the list.
+ * Add a contact feature to the lists that hold them ordered by start (first
+ * contact) and by end (second contact) position, ensuring the lists remain
+ * ordered, and returns true. This method allows duplicate features to be
+ * added, so test before calling to avoid this.
*
- * @param list
* @param feature
- *
* @return
*/
- protected int binarySearchForAdd(List list, SequenceFeature feature)
+ protected synchronized boolean addContactFeature(SequenceFeature feature)
{
- // TODO binary search!
- int i = 0;
- while (i < list.size())
+ if (contactFeatureStarts == null)
{
- if (startOrdering.compare(nonNestedFeatures.get(i), feature) >= 0)
- {
- break;
- }
- i++;
+ contactFeatureStarts = new ArrayList();
+ }
+ if (contactFeatureEnds == null)
+ {
+ contactFeatureEnds = new ArrayList();
}
- return i;
+
+ /*
+ * binary search the sorted list to find the insertion point
+ */
+ int insertPosition = binarySearch(contactFeatureStarts,
+ SearchCriterion.byFeature(feature,
+ RangeComparator.BY_START_POSITION));
+ contactFeatureStarts.add(insertPosition, feature);
+ // and resort to mak siccar...just in case insertion point not quite right
+ Collections.sort(contactFeatureStarts, RangeComparator.BY_START_POSITION);
+
+ insertPosition = binarySearch(contactFeatureStarts,
+ SearchCriterion.byFeature(feature,
+ RangeComparator.BY_END_POSITION));
+ contactFeatureEnds.add(feature);
+ Collections.sort(contactFeatureEnds, RangeComparator.BY_END_POSITION);
+
+ return true;
}
/**
- * Add a contact feature to the lists that hold them ordered by start (first
- * contact) and by end (second contact) position, ensuring the lists remain
- * ordered
+ * Answers true if the list contains the feature, else false. This method is
+ * optimised for the condition that the list is sorted on feature start
+ * position ascending, and will give unreliable results if this does not hold.
*
+ * @param features
* @param feature
+ * @return
*/
- protected synchronized void addContactFeature(SequenceFeature feature)
+ protected static boolean listContains(List features,
+ SequenceFeature feature)
{
- // TODO binary search for insertion points!
- if (contactFeatureStarts == null)
+ if (features == null || feature == null)
{
- contactFeatureStarts = new ArrayList();
+ return false;
}
- if (contactFeatureEnds == null)
+
+ /*
+ * locate the first entry in the list which does not precede the feature
+ */
+ int pos = binarySearch(features,
+ SearchCriterion.byFeature(feature, RangeComparator.BY_START_POSITION));
+ int len = features.size();
+ while (pos < len)
{
- contactFeatureEnds = new ArrayList();
+ SequenceFeature sf = features.get(pos);
+ if (sf.getBegin() > feature.getBegin())
+ {
+ return false; // no match found
+ }
+ if (sf.equals(feature))
+ {
+ return true;
+ }
+ pos++;
}
- contactFeatureStarts.add(feature);
- Collections.sort(contactFeatureStarts, startOrdering);
- contactFeatureEnds.add(feature);
- Collections.sort(contactFeatureEnds, endOrdering);
+ return false;
}
/**
- * Returns a (possibly empty) list of entries whose range overlaps the given
+ * Returns a (possibly empty) list of features whose extent overlaps the given
* range. The returned list is not ordered. Contact features are included if
* either of the contact points lies within the range.
*
@@ -259,7 +519,7 @@ public class FeatureStore
*/
public List findOverlappingFeatures(long start, long end)
{
- List result = new ArrayList();
+ List result = new ArrayList<>();
findNonNestedFeatures(start, end, result);
@@ -275,7 +535,7 @@ public class FeatureStore
/**
* Adds contact features to the result list where either the second or the
- * first contact position lies within the target range.
+ * first contact position lies within the target range
*
* @param from
* @param to
@@ -295,6 +555,10 @@ public class FeatureStore
}
/**
+ * Adds to the result list any contact features whose end (second contact
+ * point), but not start (first contact point), lies in the query from-to
+ * range
+ *
* @param from
* @param to
* @param result
@@ -302,8 +566,13 @@ public class FeatureStore
protected void findContactEndFeatures(long from, long to,
List result)
{
- // TODO binary search for startPosition
- for (int startPosition = 0; startPosition < contactFeatureEnds.size(); startPosition++)
+ /*
+ * find the first contact feature (if any) that does not lie
+ * entirely before the target range
+ */
+ int startPosition = binarySearch(contactFeatureEnds,
+ SearchCriterion.byEnd(from));
+ for (; startPosition < contactFeatureEnds.size(); startPosition++)
{
SequenceFeature sf = contactFeatureEnds.get(startPosition);
if (!sf.isContactFeature())
@@ -312,6 +581,7 @@ public class FeatureStore
+ sf.getType() + " in contact features list");
continue;
}
+
int begin = sf.getBegin();
if (begin >= from && begin <= to)
{
@@ -321,41 +591,22 @@ public class FeatureStore
*/
continue;
}
+
int end = sf.getEnd();
if (end >= from && end <= to)
{
result.add(sf);
}
- }
- }
-
- /**
- * Returns the index of the first contact feature found whose end (second
- * contact position) is not before the given start position. If no such
- * feature is found, returns the length of the contact features list.
- *
- * @param start
- * @return
- */
- protected int contactsBinarySearch(long start)
- {
- // TODO binary search!!
- int i = 0;
- while (i < contactFeatureEnds.size())
- {
- if (contactFeatureEnds.get(i).getEnd() >= start)
+ if (end > to)
{
break;
}
- i++;
}
-
- return i;
}
/**
- * Adds features to the result list that are at a single position which lies
- * within the target range. Non-positional features (start=end=0) and contact
+ * Adds non-nested features to the result list that lie within the target
+ * range. Non-positional features (start=end=0), contact features and nested
* features are excluded.
*
* @param from
@@ -365,27 +616,15 @@ public class FeatureStore
protected void findNonNestedFeatures(long from, long to,
List result)
{
- int startIndex = binarySearch(nonNestedFeatures, from);
- findNonNestedFeatures(startIndex, from, to, result);
- }
+ /*
+ * find the first feature whose end position is
+ * after the target range start
+ */
+ int startIndex = binarySearch(nonNestedFeatures,
+ SearchCriterion.byEnd(from));
- /**
- * Scans the list of non-nested features, starting from startIndex, to find
- * those that overlap the from-to range, and adds them to the result list.
- * Returns the index of the first feature whose start position is after the
- * target range (or the length of the whole list if none such feature exists).
- *
- * @param startIndex
- * @param from
- * @param to
- * @param result
- * @return
- */
- protected int findNonNestedFeatures(final int startIndex, long from,
- long to,
- List result)
- {
- int i = startIndex;
+ final int startIndex1 = startIndex;
+ int i = startIndex1;
while (i < nonNestedFeatures.size())
{
SequenceFeature sf = nonNestedFeatures.get(i);
@@ -393,46 +632,12 @@ public class FeatureStore
{
break;
}
- int start = sf.getBegin();
- int end = sf.getEnd();
- if (start <= to && end >= from)
+ if (sf.getBegin() <= to && sf.getEnd() >= from)
{
result.add(sf);
}
i++;
}
- return i;
- }
-
- /**
- * Performs a binary search of the (sorted) list to find the index of the
- * first entry whose end position is not less than the target position (i.e.
- * skip all features that properly precede the given position)
- *
- * @param features
- * @param target
- * @return
- */
- protected int binarySearch(List features, long target)
- {
- int width = features.size() / 2;
- int lastpos = width;
- while (width > 0)
- {
- int end = features.get(lastpos).getEnd();
- width = width / 2;
- if (end > target)
- {
- lastpos -= width;
- }
- else
- {
- lastpos += width;
- }
- }
- // todo correct binary search
- return lastpos > 1 ? lastpos - 2 : 0;
- // return lastpos;
}
/**
@@ -446,8 +651,10 @@ public class FeatureStore
protected void findContactStartFeatures(long from, long to,
List result)
{
- // TODO binary search for startPosition
- for (int startPosition = 0; startPosition < contactFeatureStarts.size(); startPosition++)
+ int startPosition = binarySearch(contactFeatureStarts,
+ SearchCriterion.byStart(from));
+
+ for (; startPosition < contactFeatureStarts.size(); startPosition++)
{
SequenceFeature sf = contactFeatureStarts.get(startPosition);
if (!sf.isContactFeature())
@@ -465,17 +672,16 @@ public class FeatureStore
}
/**
- * Answers a list of all features stored (including any non-positional
- * features), in no guaranteed order
+ * Answers a list of all positional features stored, in no guaranteed order
*
* @return
*/
- public List getFeatures()
+ public List getPositionalFeatures()
{
/*
* add non-nested features (may be all features for many cases)
*/
- List result = new ArrayList();
+ List result = new ArrayList<>();
result.addAll(nonNestedFeatures);
/*
@@ -487,14 +693,6 @@ public class FeatureStore
}
/*
- * add any non-positional features
- */
- if (nonPositionalFeatures != null)
- {
- result.addAll(nonPositionalFeatures);
- }
-
- /*
* add any nested features
*/
if (nestedFeatures != null)
@@ -517,7 +715,7 @@ public class FeatureStore
{
return Collections.emptyList();
}
- return new ArrayList(contactFeatureStarts);
+ return new ArrayList<>(contactFeatureStarts);
}
/**
@@ -532,6 +730,355 @@ public class FeatureStore
{
return Collections.emptyList();
}
- return new ArrayList(nonPositionalFeatures);
+ return new ArrayList<>(nonPositionalFeatures);
+ }
+
+ /**
+ * Deletes the given feature from the store, returning true if it was found
+ * (and deleted), else false. This method makes no assumption that the feature
+ * is in the 'expected' place in the store, in case it has been modified since
+ * it was added.
+ *
+ * @param sf
+ */
+ public synchronized boolean delete(SequenceFeature sf)
+ {
+ /*
+ * try the non-nested positional features first
+ */
+ boolean removed = nonNestedFeatures.remove(sf);
+
+ /*
+ * if not found, try contact positions (and if found, delete
+ * from both lists of contact positions)
+ */
+ if (!removed && contactFeatureStarts != null)
+ {
+ removed = contactFeatureStarts.remove(sf);
+ if (removed)
+ {
+ contactFeatureEnds.remove(sf);
+ }
+ }
+
+ boolean removedNonPositional = false;
+
+ /*
+ * if not found, try non-positional features
+ */
+ if (!removed && nonPositionalFeatures != null)
+ {
+ removedNonPositional = nonPositionalFeatures.remove(sf);
+ removed = removedNonPositional;
+ }
+
+ /*
+ * if not found, try nested features
+ */
+ if (!removed && nestedFeatures != null)
+ {
+ removed = nestedFeatures.delete(sf);
+ }
+
+ if (removed)
+ {
+ rescanAfterDelete();
+ }
+
+ return removed;
+ }
+
+ /**
+ * Rescan all features to recompute any cached values after an entry has been
+ * deleted. This is expected to be an infrequent event, so performance here is
+ * not critical.
+ */
+ protected synchronized void rescanAfterDelete()
+ {
+ positionalFeatureGroups.clear();
+ nonPositionalFeatureGroups.clear();
+ totalExtent = 0;
+ positionalMinScore = Float.NaN;
+ positionalMaxScore = Float.NaN;
+ nonPositionalMinScore = Float.NaN;
+ nonPositionalMaxScore = Float.NaN;
+
+ /*
+ * scan non-positional features for groups and scores
+ */
+ for (SequenceFeature sf : getNonPositionalFeatures())
+ {
+ nonPositionalFeatureGroups.add(sf.getFeatureGroup());
+ float score = sf.getScore();
+ nonPositionalMinScore = min(nonPositionalMinScore, score);
+ nonPositionalMaxScore = max(nonPositionalMaxScore, score);
+ }
+
+ /*
+ * scan positional features for groups, scores and extents
+ */
+ for (SequenceFeature sf : getPositionalFeatures())
+ {
+ positionalFeatureGroups.add(sf.getFeatureGroup());
+ float score = sf.getScore();
+ positionalMinScore = min(positionalMinScore, score);
+ positionalMaxScore = max(positionalMaxScore, score);
+ totalExtent += getFeatureLength(sf);
+ }
+ }
+
+ /**
+ * A helper method to return the minimum of two floats, where a non-NaN value
+ * is treated as 'less than' a NaN value (unlike Math.min which does the
+ * opposite)
+ *
+ * @param f1
+ * @param f2
+ */
+ protected static float min(float f1, float f2)
+ {
+ if (Float.isNaN(f1))
+ {
+ return Float.isNaN(f2) ? f1 : f2;
+ }
+ else
+ {
+ return Float.isNaN(f2) ? f1 : Math.min(f1, f2);
+ }
+ }
+
+ /**
+ * A helper method to return the maximum of two floats, where a non-NaN value
+ * is treated as 'greater than' a NaN value (unlike Math.max which does the
+ * opposite)
+ *
+ * @param f1
+ * @param f2
+ */
+ protected static float max(float f1, float f2)
+ {
+ if (Float.isNaN(f1))
+ {
+ return Float.isNaN(f2) ? f1 : f2;
+ }
+ else
+ {
+ return Float.isNaN(f2) ? f1 : Math.max(f1, f2);
+ }
+ }
+
+ /**
+ * Answers true if this store has no features, else false
+ *
+ * @return
+ */
+ public boolean isEmpty()
+ {
+ boolean hasFeatures = !nonNestedFeatures.isEmpty()
+ || (contactFeatureStarts != null && !contactFeatureStarts
+ .isEmpty())
+ || (nonPositionalFeatures != null && !nonPositionalFeatures
+ .isEmpty())
+ || (nestedFeatures != null && nestedFeatures.size() > 0);
+
+ return !hasFeatures;
+ }
+
+ /**
+ * Answers the set of distinct feature groups stored, possibly including null,
+ * as an unmodifiable view of the set. The parameter determines whether the
+ * groups for positional or for non-positional features are returned.
+ *
+ * @param positionalFeatures
+ * @return
+ */
+ public Set getFeatureGroups(boolean positionalFeatures)
+ {
+ if (positionalFeatures)
+ {
+ return Collections.unmodifiableSet(positionalFeatureGroups);
+ }
+ else
+ {
+ return nonPositionalFeatureGroups == null ? Collections
+ . emptySet() : Collections
+ .unmodifiableSet(nonPositionalFeatureGroups);
+ }
+ }
+
+ /**
+ * Performs a binary search of the (sorted) list to find the index of the
+ * first entry which returns true for the given comparator function. Returns
+ * the length of the list if there is no such entry.
+ *
+ * @param features
+ * @param sc
+ * @return
+ */
+ protected static int binarySearch(List features,
+ SearchCriterion sc)
+ {
+ int start = 0;
+ int end = features.size() - 1;
+ int matched = features.size();
+
+ while (start <= end)
+ {
+ int mid = (start + end) / 2;
+ SequenceFeature entry = features.get(mid);
+ boolean compare = sc.compare(entry);
+ if (compare)
+ {
+ matched = mid;
+ end = mid - 1;
+ }
+ else
+ {
+ start = mid + 1;
+ }
+ }
+
+ return matched;
+ }
+
+ /**
+ * Answers the number of positional (or non-positional) features stored.
+ * Contact features count as 1.
+ *
+ * @param positional
+ * @return
+ */
+ public int getFeatureCount(boolean positional)
+ {
+ if (!positional)
+ {
+ return nonPositionalFeatures == null ? 0 : nonPositionalFeatures
+ .size();
+ }
+
+ int size = nonNestedFeatures.size();
+
+ if (contactFeatureStarts != null)
+ {
+ // note a contact feature (start/end) counts as one
+ size += contactFeatureStarts.size();
+ }
+
+ if (nestedFeatures != null)
+ {
+ size += nestedFeatures.size();
+ }
+
+ return size;
+ }
+
+ /**
+ * Answers the total length of positional features (or zero if there are
+ * none). Contact features contribute a value of 1 to the total.
+ *
+ * @return
+ */
+ public int getTotalFeatureLength()
+ {
+ return totalExtent;
+ }
+
+ /**
+ * Answers the minimum score held for positional or non-positional features.
+ * This may be Float.NaN if there are no features, are none has a non-NaN
+ * score.
+ *
+ * @param positional
+ * @return
+ */
+ public float getMinimumScore(boolean positional)
+ {
+ return positional ? positionalMinScore : nonPositionalMinScore;
+ }
+
+ /**
+ * Answers the maximum score held for positional or non-positional features.
+ * This may be Float.NaN if there are no features, are none has a non-NaN
+ * score.
+ *
+ * @param positional
+ * @return
+ */
+ public float getMaximumScore(boolean positional)
+ {
+ return positional ? positionalMaxScore : nonPositionalMaxScore;
+ }
+
+ /**
+ * Answers a list of all either positional or non-positional features whose
+ * feature group matches the given group (which may be null)
+ *
+ * @param positional
+ * @param group
+ * @return
+ */
+ public List getFeaturesForGroup(boolean positional,
+ String group)
+ {
+ List result = new ArrayList<>();
+
+ /*
+ * if we know features don't include the target group, no need
+ * to inspect them for matches
+ */
+ if (positional && !positionalFeatureGroups.contains(group)
+ || !positional && !nonPositionalFeatureGroups.contains(group))
+ {
+ return result;
+ }
+
+ List sfs = positional ? getPositionalFeatures()
+ : getNonPositionalFeatures();
+ for (SequenceFeature sf : sfs)
+ {
+ String featureGroup = sf.getFeatureGroup();
+ if (group == null && featureGroup == null || group != null
+ && group.equals(featureGroup))
+ {
+ result.add(sf);
+ }
+ }
+ return result;
+ }
+
+ /**
+ * Adds the shift value to the start and end of all positional features.
+ * Returns true if at least one feature was updated, else false.
+ *
+ * @param shift
+ * @return
+ */
+ public synchronized boolean shiftFeatures(int shift)
+ {
+ /*
+ * Because begin and end are final fields (to ensure the data store's
+ * integrity), we have to delete each feature and re-add it as amended.
+ * (Although a simple shift of all values would preserve data integrity!)
+ */
+ boolean modified = false;
+ for (SequenceFeature sf : getPositionalFeatures())
+ {
+ modified = true;
+ int newBegin = sf.getBegin() + shift;
+ int newEnd = sf.getEnd() + shift;
+
+ /*
+ * sanity check: don't shift left of the first residue
+ */
+ if (newEnd > 0)
+ {
+ newBegin = Math.max(1, newBegin);
+ SequenceFeature sf2 = new SequenceFeature(sf, newBegin, newEnd,
+ sf.getFeatureGroup(), sf.getScore());
+ addFeature(sf2);
+ }
+ delete(sf);
+ }
+ return modified;
}
}