/** * Updates the lower and upper bounds for each alternative to reflect potential minimum and * maximum weighted results in case the provided leaves are set to their potential minimum and * maximum values respectively. * * @param leafSet leaves for the plan to consider * @param resultRanges the result ranges to update */ private void updateBounds( final Set<VPlanLeaf> leafSet, List<AlternativeResultRange> resultRanges) { for (VPlanLeaf leaf : leafSet) { double leafMinimum = leaf.getPotentialMinimum(); double leafMaximum = leaf.getPotentialMaximum(); for (AlternativeResultRange resultRange : resultRanges) { resultRange.setLowerBound( resultRange.getLowerBound() - ((resultRange.getResult() - leafMinimum) * leaf.getTotalWeight())); resultRange.setUpperBound( resultRange.getUpperBound() + ((leafMaximum - resultRange.getResult()) * leaf.getTotalWeight())); } } }
/** * Takes a list of lower bounds and a list of corresponding upper bounds of ranges and checks if * there are overlapping ranges. * * <p>Note: lowerBounds and upperBounds must have the same length * * @param resultRanges the result ranges to check * @return true if at least one range overlaps another, false otherwise */ private boolean rangesOverlapping(List<AlternativeResultRange> resultRanges) { // Sort by upper bound Collections.sort( resultRanges, new Comparator<AlternativeResultRange>() { @Override public int compare(AlternativeResultRange o1, AlternativeResultRange o2) { return Double.compare(o1.getUpperBound(), o2.getUpperBound()); } }); double lastUpperBound = Double.NEGATIVE_INFINITY; for (AlternativeResultRange resultRange : resultRanges) { if (resultRange.getLowerBound() < lastUpperBound) { return true; } lastUpperBound = resultRange.getUpperBound(); } return false; }