All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.optaplanner.examples.common.experimental.impl.ConsecutiveSetTree Maven / Gradle / Ivy

Go to download

OptaPlanner solves planning problems. This lightweight, embeddable planning engine implements powerful and scalable algorithms to optimize business resource scheduling and planning. This module contains the examples which demonstrate how to use it in a normal Java application.

There is a newer version: 9.44.0.Final
Show newest version
package org.optaplanner.examples.common.experimental.impl;

import java.util.Comparator;
import java.util.HashMap;
import java.util.Map;
import java.util.NavigableMap;
import java.util.NavigableSet;
import java.util.Objects;
import java.util.TreeMap;
import java.util.function.BiFunction;

import org.optaplanner.examples.common.experimental.api.Break;
import org.optaplanner.examples.common.experimental.api.ConsecutiveInfo;
import org.optaplanner.examples.common.experimental.api.Sequence;

/**
 * A {@code ConsecutiveSetTree} determines what values are consecutive. A sequence
 * x1, x2, x3, ..., xn
 * is understood to be consecutive by d iff
 * x2 − x1 ≤ d, x3 − x2 ≤ d, ..., xn −
 * xn-1 ≤ d.
 * This data structure can be thought as an interval tree that maps the point p to
 * the interval [p, p + d].
 *
 * @param  The type of value stored (examples: shifts)
 * @param  The type of the point (examples: int, LocalDateTime)
 * @param  The type of the difference (examples: int, Duration)
 */
public final class ConsecutiveSetTree, Difference_ extends Comparable>
        implements ConsecutiveInfo {
    private final BiFunction differenceFunction;
    private final BiFunction sumFunction;
    private final Difference_ maxDifference;
    private final Difference_ zeroDifference;
    private final NavigableMap itemToCountMap;
    private final NavigableMap> startItemToSequence;
    private final NavigableMap> startItemToPreviousBreak;

    private final Map indexMap;
    private final MapValuesIterable> sequenceList;
    private final MapValuesIterable> breakList;

    public ConsecutiveSetTree(BiFunction differenceFunction,
            BiFunction sumFunction,
            Difference_ maxDifference,
            Difference_ zeroDifference) {
        this.differenceFunction = differenceFunction;
        this.sumFunction = sumFunction;
        this.maxDifference = maxDifference;
        this.zeroDifference = zeroDifference;
        indexMap = new HashMap<>();
        Comparator comparator = new ValueComparator<>(indexMap);
        itemToCountMap = new TreeMap<>(comparator);
        startItemToSequence = new TreeMap<>(comparator);
        startItemToPreviousBreak = new TreeMap<>(comparator);
        sequenceList = new MapValuesIterable<>(startItemToSequence);
        breakList = new MapValuesIterable<>(startItemToPreviousBreak);
    }

    // Public API
    @SuppressWarnings({ "unchecked", "rawtypes" })
    @Override
    public Iterable> getConsecutiveSequences() {
        return (Iterable) sequenceList;
    }

    @SuppressWarnings({ "unchecked", "rawtypes" })
    @Override
    public Iterable> getBreaks() {
        return (Iterable) breakList;
    }

    public boolean add(Value_ item, Point_ point) {
        indexMap.put(item, point);
        int newCount = itemToCountMap.compute(item, (key, count) -> count == null ? 1 : count + 1);
        if (newCount > 1) { // Item already in bag.
            return true;
        }
        Value_ firstBeforeItem = startItemToSequence.floorKey(item);
        Point_ itemIndex = indexMap.get(item);
        if (firstBeforeItem != null) {
            Value_ endOfBeforeSequenceItem = getEndItem(firstBeforeItem);
            Point_ endOfBeforeSequenceIndex = indexMap.get(endOfBeforeSequenceItem);
            if (isInNaturalOrderAndHashOrderIfEqual(itemIndex, item, endOfBeforeSequenceIndex, endOfBeforeSequenceItem)) {
                // Item is already in the bag; do nothing
                return true;
            } else {
                // Item is outside the bag
                Value_ firstAfterItem = startItemToSequence.higherKey(item);
                if (firstAfterItem != null) {
                    Point_ startOfAfterSequenceIndex = indexMap.get(firstAfterItem);
                    addBetweenItems(item, itemIndex, firstBeforeItem, endOfBeforeSequenceItem,
                            endOfBeforeSequenceIndex, firstAfterItem, startOfAfterSequenceIndex);
                } else {
                    SequenceImpl prevBag = startItemToSequence.get(firstBeforeItem);
                    if (isFirstSuccessorOfSecond(itemIndex, item, endOfBeforeSequenceIndex, endOfBeforeSequenceItem)) {
                        // We need to extend the first bag
                        // No break since afterItem is null
                        prevBag.setEnd(item);
                    } else {
                        // Start a new bag of consecutive items
                        SequenceImpl newBag = new SequenceImpl<>(this, item);
                        startItemToSequence.put(item, newBag);
                        startItemToPreviousBreak.put(item,
                                new BreakImpl<>(prevBag, newBag,
                                        differenceFunction.apply(endOfBeforeSequenceIndex, itemIndex)));
                    }
                }
            }
        } else {
            // No items before it
            Value_ firstAfterItem = startItemToSequence.higherKey(item);
            if (firstAfterItem != null) {
                Point_ startOfAfterSequenceIndex = indexMap.get(firstAfterItem);

                if (isFirstSuccessorOfSecond(startOfAfterSequenceIndex, firstAfterItem, itemIndex, item)) {
                    // We need to move the after bag to use item as key
                    SequenceImpl afterBag = startItemToSequence.remove(firstAfterItem);
                    afterBag.setStart(item);
                    // No break since this is the first sequence
                    startItemToSequence.put(item, afterBag);
                } else {
                    // Start a new bag of consecutive items
                    SequenceImpl afterBag = startItemToSequence.get(firstAfterItem);
                    SequenceImpl newBag = new SequenceImpl<>(this, item);
                    startItemToSequence.put(item, newBag);
                    startItemToPreviousBreak.put(firstAfterItem,
                            new BreakImpl<>(newBag, afterBag,
                                    differenceFunction.apply(itemIndex, startOfAfterSequenceIndex)));
                }
            } else {
                // Start a new bag of consecutive items
                SequenceImpl newBag = new SequenceImpl<>(this, item);
                startItemToSequence.put(item, newBag);
                // Bag have no other items, so no break
            }
        }
        return true;
    }

    public boolean remove(Value_ item) {
        Integer currentCount = itemToCountMap.get(item);
        if (currentCount == null) { // Item not in bag.
            return false;
        }
        if (currentCount == 1) {
            itemToCountMap.remove(item);
        } else { // Item still in bag.
            itemToCountMap.put(item, currentCount - 1);
            return true;
        }

        // Item is removed from bag
        Value_ firstBeforeItem = startItemToSequence.floorKey(item);
        SequenceImpl bag = startItemToSequence.get(firstBeforeItem);
        Value_ endItem = bag.getLastItem();

        // Bag is empty if first item = last item
        if (bag.getFirstItem() == bag.getLastItem()) {
            startItemToSequence.remove(firstBeforeItem);
            BreakImpl removedBreak = startItemToPreviousBreak.remove(firstBeforeItem);
            Map.Entry> extendedBreakEntry =
                    startItemToPreviousBreak.higherEntry(firstBeforeItem);
            if (extendedBreakEntry != null) {
                if (removedBreak != null) {
                    BreakImpl extendedBreak = extendedBreakEntry.getValue();
                    extendedBreak.setPreviousSequence(removedBreak.getPreviousSequence());
                    updateLengthOfBreak(extendedBreak);
                } else {
                    startItemToPreviousBreak.remove(extendedBreakEntry.getKey());
                }
            }
            indexMap.remove(item);
            return true;
        }

        // Bag is not empty
        return removeItemFromBag(bag, item, firstBeforeItem, endItem);
    }

    // Protected API
    Break getBreakBefore(Value_ item) {
        return startItemToPreviousBreak.get(item);
    }

    Break getBreakAfter(Value_ item) {
        Map.Entry> entry = startItemToPreviousBreak.higherEntry(item);
        if (entry != null) {
            return entry.getValue();
        }
        return null;
    }

    NavigableSet getItemSet() {
        return (NavigableSet) itemToCountMap.keySet();
    }

    void updateLengthOfBreak(BreakImpl theBreak) {
        theBreak.setLength(getBreakLengthBetween(theBreak.getPreviousSequenceEnd(), theBreak.getNextSequenceStart()));
    }

    Difference_ getSequenceLength(Sequence sequence) {
        return sumFunction.apply(maxDifference, differenceFunction.apply(indexMap.get(sequence.getFirstItem()),
                indexMap.get(sequence.getLastItem())));
    }

    Difference_ getBreakLengthBetween(Value_ from, Value_ to) {
        return differenceFunction.apply(indexMap.get(from), indexMap.get(to));
    }

    Value_ getEndItem(Value_ key) {
        return startItemToSequence.get(key).getLastItem();
    }

    private > boolean isInNaturalOrderAndHashOrderIfEqual(T a, Value_ aItem, T b,
            Value_ bItem) {
        int difference = a.compareTo(b);
        if (difference != 0) {
            return difference < 0;
        }
        return System.identityHashCode(aItem) - System.identityHashCode(bItem) < 0;
    }

    private boolean isFirstSuccessorOfSecond(Point_ first, Value_ firstValue, Point_ second,
            Value_ secondValue) {
        Difference_ difference = differenceFunction.apply(second, first);
        return isInNaturalOrderAndHashOrderIfEqual(zeroDifference, secondValue, difference, firstValue) &&
                difference.compareTo(maxDifference) <= 0;
    }

    private void addBetweenItems(Value_ item, Point_ itemIndex,
            Value_ firstBeforeItem, Value_ endOfBeforeSequenceItem, Point_ endOfBeforeSequenceItemIndex,
            Value_ firstAfterItem, Point_ startOfAfterSequenceIndex) {
        if (isFirstSuccessorOfSecond(itemIndex, item, endOfBeforeSequenceItemIndex, endOfBeforeSequenceItem)) {
            // We need to extend the first bag
            SequenceImpl prevBag = startItemToSequence.get(firstBeforeItem);
            if (isFirstSuccessorOfSecond(startOfAfterSequenceIndex, firstAfterItem, itemIndex, item)) {
                // We need to merge the two bags
                startItemToPreviousBreak.remove(firstAfterItem);
                SequenceImpl afterBag = startItemToSequence.remove(firstAfterItem);
                prevBag.merge(afterBag);
                Map.Entry> maybeNextBreak =
                        startItemToPreviousBreak.higherEntry(firstAfterItem);
                if (maybeNextBreak != null) {
                    maybeNextBreak.getValue().setPreviousSequence(prevBag);
                }
            } else {
                prevBag.setEnd(item);
                BreakImpl nextBreak = startItemToPreviousBreak.get(firstAfterItem);
                nextBreak.setLength(differenceFunction.apply(itemIndex, startOfAfterSequenceIndex));
            }
        } else {
            // Don't need to extend the first bag
            if (isFirstSuccessorOfSecond(startOfAfterSequenceIndex, firstAfterItem, itemIndex, item)) {
                // We need to move the after bag to use item as key
                SequenceImpl afterBag = startItemToSequence.remove(firstAfterItem);
                afterBag.setStart(item);
                startItemToSequence.put(item, afterBag);
                BreakImpl prevBreak = startItemToPreviousBreak.remove(firstAfterItem);
                prevBreak.setLength(differenceFunction.apply(endOfBeforeSequenceItemIndex, itemIndex));
                startItemToPreviousBreak.put(item, prevBreak);
            } else {
                // Start a new bag of consecutive items
                SequenceImpl newBag = new SequenceImpl<>(this, item);
                startItemToSequence.put(item, newBag);
                BreakImpl nextBreak = startItemToPreviousBreak.get(firstAfterItem);
                nextBreak.setPreviousSequence(newBag);
                nextBreak.setLength(differenceFunction.apply(itemIndex, startOfAfterSequenceIndex));
                startItemToPreviousBreak.put(item, new BreakImpl<>(startItemToSequence.get(firstBeforeItem), newBag,
                        differenceFunction.apply(endOfBeforeSequenceItemIndex, itemIndex)));
            }
        }
    }

    private boolean removeItemFromBag(SequenceImpl bag, Value_ item, Value_ sequenceStart,
            Value_ sequenceEnd) {
        NavigableSet itemSet = getItemSet();
        if (item.equals(sequenceStart)) {
            // Change start key to the item after this one
            bag.setStart(itemSet.higher(item));
            startItemToSequence.remove(sequenceStart);
            BreakImpl extendedBreak = startItemToPreviousBreak.remove(sequenceStart);
            Value_ firstItem = bag.getFirstItem();
            startItemToSequence.put(firstItem, bag);
            if (extendedBreak != null) {
                updateLengthOfBreak(extendedBreak);
                startItemToPreviousBreak.put(firstItem, extendedBreak);
            }
            indexMap.remove(item);
            return true;
        }
        if (item.equals(sequenceEnd)) {
            // Set end key to the item before this one
            bag.setEnd(itemSet.lower(item));
            Map.Entry> extendedBreakEntry =
                    startItemToPreviousBreak.higherEntry(item);
            if (extendedBreakEntry != null) {
                BreakImpl extendedBreak = extendedBreakEntry.getValue();
                updateLengthOfBreak(extendedBreak);
            }
            indexMap.remove(item);
            return true;
        }

        Value_ firstAfterItem = bag.getItems().higher(item);
        Value_ firstBeforeItem = bag.getItems().lower(item);

        if (isFirstSuccessorOfSecond(
                indexMap.get(firstAfterItem), firstAfterItem,
                indexMap.get(firstBeforeItem), firstBeforeItem)) {
            // Bag is not split since the next two items are still close enough
            indexMap.remove(item);
            return true;
        }

        // Need to split bag into two halves
        // Both halves are not empty as the item was not an endpoint
        // Additional, the breaks before and after the broken sequence
        // are not affected since an endpoint was not removed
        SequenceImpl splitBag = bag.split(item);
        Value_ firstSplitItem = splitBag.getFirstItem();
        Value_ lastOriginalItem = bag.getLastItem();
        startItemToSequence.put(firstSplitItem, splitBag);
        startItemToPreviousBreak.put(firstSplitItem,
                new BreakImpl<>(bag, splitBag, getBreakLengthBetween(lastOriginalItem, firstSplitItem)));
        Map.Entry> maybeNextBreak =
                startItemToPreviousBreak.higherEntry(firstAfterItem);
        if (maybeNextBreak != null) {
            maybeNextBreak.getValue().setPreviousSequence(splitBag);
        }
        indexMap.remove(item);
        return true;
    }

    @Override
    public String toString() {
        return "Sequences {" +
                "sequenceList=" + sequenceList +
                ", breakList=" + breakList +
                '}';
    }

    private static final class ValueComparator> implements Comparator {

        private final Map indexMap;

        public ValueComparator(Map indexMap) {
            this.indexMap = Objects.requireNonNull(indexMap);
        }

        @Override
        public int compare(Value_ o1, Value_ o2) {
            if (o1 == o2) {
                return 0;
            }
            Point_ point1 = indexMap.get(o1);
            Point_ point2 = indexMap.get(o2);
            if (point1 == point2) {
                return compareWithIdentityHashCode(o1, o2);
            }
            int comparison = point1.compareTo(point2);
            if (comparison != 0) {
                return comparison;
            }
            return compareWithIdentityHashCode(o1, o2);
        }

        private static int compareWithIdentityHashCode(Object o1, Object o2) {
            // Identity Hashcode for duplicate protection; we must always include duplicates.
            // Ex: two different games on the same time slot
            int identityHashCode1 = System.identityHashCode(o1);
            int identityHashCode2 = System.identityHashCode(o2);
            return Integer.compare(identityHashCode1, identityHashCode2);
        }
    }

}




© 2015 - 2024 Weber Informatics LLC | Privacy Policy