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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance
 * with the License.  You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.cassandra.dht;

import java.io.Serializable;
import java.util.*;

import org.apache.commons.lang3.ObjectUtils;

import org.apache.cassandra.db.PartitionPosition;
import org.apache.cassandra.utils.Pair;

/**
 * A representation of the range that a node is responsible for on the DHT ring.
 *
 * A Range is responsible for the tokens between (left, right].
 *
 * Used by the partitioner and by map/reduce by-token range scans.
 *
 * Note: this class has a natural ordering that is inconsistent with equals
 */
public class Range> extends AbstractBounds implements Comparable>, Serializable
{
    public static final long serialVersionUID = 1L;

    public Range(T left, T right)
    {
        super(left, right);
    }

    public static > boolean contains(T left, T right, T point)
    {
        if (isWrapAround(left, right))
        {
            /*
             * We are wrapping around, so the interval is (a,b] where a >= b,
             * then we have 3 cases which hold for any given token k:
             * (1) a < k -- return true
             * (2) k <= b -- return true
             * (3) b < k <= a -- return false
             */
            if (point.compareTo(left) > 0)
                return true;
            else
                return right.compareTo(point) >= 0;
        }
        else
        {
            /*
             * This is the range (a, b] where a < b.
             */
            return point.compareTo(left) > 0 && right.compareTo(point) >= 0;
        }
    }

    public boolean contains(Range that)
    {
        if (this.left.equals(this.right))
        {
            // full ring always contains all other ranges
            return true;
        }

        boolean thiswraps = isWrapAround(left, right);
        boolean thatwraps = isWrapAround(that.left, that.right);
        if (thiswraps == thatwraps)
        {
            return left.compareTo(that.left) <= 0 && that.right.compareTo(right) <= 0;
        }
        else if (thiswraps)
        {
            // wrapping might contain non-wrapping
            // that is contained if both its tokens are in one of our wrap segments
            return left.compareTo(that.left) <= 0 || that.right.compareTo(right) <= 0;
        }
        else
        {
            // (thatwraps)
            // non-wrapping cannot contain wrapping
            return false;
        }
    }

    /**
     * Helps determine if a given point on the DHT ring is contained
     * in the range in question.
     * @param point point in question
     * @return true if the point contains within the range else false.
     */
    public boolean contains(T point)
    {
        return contains(left, right, point);
    }

    /**
     * @param that range to check for intersection
     * @return true if the given range intersects with this range.
     */
    public boolean intersects(Range that)
    {
        return intersectionWith(that).size() > 0;
    }

    public boolean intersects(AbstractBounds that)
    {
        // implemented for cleanup compaction membership test, so only Range + Bounds are supported for now
        if (that instanceof Range)
            return intersects((Range) that);
        if (that instanceof Bounds)
            return intersects((Bounds) that);
        throw new UnsupportedOperationException("Intersection is only supported for Bounds and Range objects; found " + that.getClass());
    }

    /**
     * @param that range to check for intersection
     * @return true if the given range intersects with this range.
     */
    public boolean intersects(Bounds that)
    {
        // Same punishment than in Bounds.contains(), we must be carefull if that.left == that.right as
        // as new Range(that.left, that.right) will then cover the full ring which is not what we
        // want.
        return contains(that.left) || (!that.left.equals(that.right) && intersects(new Range(that.left, that.right)));
    }

    @SafeVarargs
    public static > Set> rangeSet(Range ... ranges)
    {
        return Collections.unmodifiableSet(new HashSet>(Arrays.asList(ranges)));
    }

    public static > Set> rangeSet(Range range)
    {
        return Collections.singleton(range);
    }

    /**
     * @param that
     * @return the intersection of the two Ranges.  this can be two disjoint Ranges if one is wrapping and one is not.
     * say you have nodes G and M, with query range (D,T]; the intersection is (M-T] and (D-G].
     * If there is no intersection, an empty list is returned.
     */
    public Set> intersectionWith(Range that)
    {
        if (that.contains(this))
            return rangeSet(this);
        if (this.contains(that))
            return rangeSet(that);

        boolean thiswraps = isWrapAround(left, right);
        boolean thatwraps = isWrapAround(that.left, that.right);
        if (!thiswraps && !thatwraps)
        {
            // neither wraps:  the straightforward case.
            if (!(left.compareTo(that.right) < 0 && that.left.compareTo(right) < 0))
                return Collections.emptySet();
            return rangeSet(new Range(ObjectUtils.max(this.left, that.left),
                                         ObjectUtils.min(this.right, that.right)));
        }
        if (thiswraps && thatwraps)
        {
            //both wrap: if the starts are the same, one contains the other, which we have already ruled out.
            assert !this.left.equals(that.left);
            // two wrapping ranges always intersect.
            // since we have already determined that neither this nor that contains the other, we have 2 cases,
            // and mirror images of those case.
            // (1) both of that's (1, 2] endpoints lie in this's (A, B] right segment:
            //  ---------B--------A--1----2------>
            // (2) only that's start endpoint lies in this's right segment:
            //  ---------B----1---A-------2------>
            // or, we have the same cases on the left segement, which we can handle by swapping this and that.
            return this.left.compareTo(that.left) < 0
                   ? intersectionBothWrapping(this, that)
                   : intersectionBothWrapping(that, this);
        }
        if (thiswraps) // this wraps, that does not wrap
            return intersectionOneWrapping(this, that);
        // the last case: this does not wrap, that wraps
        return intersectionOneWrapping(that, this);
    }

    private static > Set> intersectionBothWrapping(Range first, Range that)
    {
        Set> intersection = new HashSet>(2);
        if (that.right.compareTo(first.left) > 0)
            intersection.add(new Range(first.left, that.right));
        intersection.add(new Range(that.left, first.right));
        return Collections.unmodifiableSet(intersection);
    }

    private static > Set> intersectionOneWrapping(Range wrapping, Range other)
    {
        Set> intersection = new HashSet>(2);
        if (other.contains(wrapping.right))
            intersection.add(new Range(other.left, wrapping.right));
        // need the extra compareto here because ranges are asymmetrical; wrapping.left _is not_ contained by the wrapping range
        if (other.contains(wrapping.left) && wrapping.left.compareTo(other.right) < 0)
            intersection.add(new Range(wrapping.left, other.right));
        return Collections.unmodifiableSet(intersection);
    }

    public Pair, AbstractBounds> split(T position)
    {
        assert contains(position) || left.equals(position);
        // Check if the split would have no effect on the range
        if (position.equals(left) || position.equals(right))
            return null;

        AbstractBounds lb = new Range(left, position);
        AbstractBounds rb = new Range(position, right);
        return Pair.create(lb, rb);
    }

    public boolean inclusiveLeft()
    {
        return false;
    }

    public boolean inclusiveRight()
    {
        return true;
    }

    public List> unwrap()
    {
        T minValue = right.minValue();
        if (!isWrapAround() || right.equals(minValue))
            return Arrays.asList(this);
        List> unwrapped = new ArrayList>(2);
        unwrapped.add(new Range(left, minValue));
        unwrapped.add(new Range(minValue, right));
        return unwrapped;
    }

    /**
     * Tells if the given range is a wrap around.
     */
    public static > boolean isWrapAround(T left, T right)
    {
       return left.compareTo(right) >= 0;
    }

    /**
     * Note: this class has a natural ordering that is inconsistent with equals
     */
    public int compareTo(Range rhs)
    {
        boolean lhsWrap = isWrapAround(left, right);
        boolean rhsWrap = isWrapAround(rhs.left, rhs.right);

        // if one of the two wraps, that's the smaller one.
        if (lhsWrap != rhsWrap)
            return Boolean.compare(!lhsWrap, !rhsWrap);
        // otherwise compare by right.
        return right.compareTo(rhs.right);
    }

    /**
     * Subtracts a portion of this range.
     * @param contained The range to subtract from this. It must be totally
     * contained by this range.
     * @return An ArrayList of the Ranges left after subtracting contained
     * from this.
     */
    private ArrayList> subtractContained(Range contained)
    {
        ArrayList> difference = new ArrayList>(2);

        if (!left.equals(contained.left))
            difference.add(new Range(left, contained.left));
        if (!right.equals(contained.right))
            difference.add(new Range(contained.right, right));
        return difference;
    }

    public Set> subtract(Range rhs)
    {
        return rhs.differenceToFetch(this);
    }

    public Set> subtractAll(Collection> ranges)
    {
        Set> result = new HashSet<>();
        result.add(this);
        for(Range range : ranges)
        {
            result = substractAllFromToken(result, range);
        }

        return result;
    }

    private static > Set> substractAllFromToken(Set> ranges, Range subtract)
    {
        Set> result = new HashSet<>();
        for(Range range : ranges)
        {
            result.addAll(range.subtract(subtract));
        }

        return result;
    }
    /**
     * Calculate set of the difference ranges of given two ranges
     * (as current (A, B] and rhs is (C, D])
     * which node will need to fetch when moving to a given new token
     *
     * @param rhs range to calculate difference
     * @return set of difference ranges
     */
    public Set> differenceToFetch(Range rhs)
    {
        Set> result;
        Set> intersectionSet = this.intersectionWith(rhs);
        if (intersectionSet.isEmpty())
        {
            result = new HashSet>();
            result.add(rhs);
        }
        else
        {
            @SuppressWarnings("unchecked")
            Range[] intersections = new Range[intersectionSet.size()];
            intersectionSet.toArray(intersections);
            if (intersections.length == 1)
            {
                result = new HashSet>(rhs.subtractContained(intersections[0]));
            }
            else
            {
                // intersections.length must be 2
                Range first = intersections[0];
                Range second = intersections[1];
                ArrayList> temp = rhs.subtractContained(first);

                // Because there are two intersections, subtracting only one of them
                // will yield a single Range.
                Range single = temp.get(0);
                result = new HashSet>(single.subtractContained(second));
            }
        }
        return result;
    }

    public static > boolean isInRanges(T token, Iterable> ranges)
    {
        assert ranges != null;

        for (Range range : ranges)
        {
            if (range.contains(token))
            {
                return true;
            }
        }
        return false;
    }

    @Override
    public boolean equals(Object o)
    {
        if (!(o instanceof Range))
            return false;
        Range rhs = (Range)o;
        return left.equals(rhs.left) && right.equals(rhs.right);
    }

    @Override
    public String toString()
    {
        return "(" + left + "," + right + "]";
    }

    protected String getOpeningString()
    {
        return "(";
    }

    protected String getClosingString()
    {
        return "]";
    }

    public boolean isStartInclusive()
    {
        return false;
    }

    public boolean isEndInclusive()
    {
        return true;
    }

    public List asList()
    {
        ArrayList ret = new ArrayList(2);
        ret.add(left.toString());
        ret.add(right.toString());
        return ret;
    }

    public boolean isWrapAround()
    {
        return isWrapAround(left, right);
    }

    /**
     * @return A copy of the given list of with all ranges unwrapped, sorted by left bound and with overlapping bounds merged.
     */
    public static > List> normalize(Collection> ranges)
    {
        // unwrap all
        List> output = new ArrayList>(ranges.size());
        for (Range range : ranges)
            output.addAll(range.unwrap());

        // sort by left
        Collections.sort(output, new Comparator>()
        {
            public int compare(Range b1, Range b2)
            {
                return b1.left.compareTo(b2.left);
            }
        });

        // deoverlap
        return deoverlap(output);
    }

    /**
     * Given a list of unwrapped ranges sorted by left position, return an
     * equivalent list of ranges but with no overlapping ranges.
     */
    private static > List> deoverlap(List> ranges)
    {
        if (ranges.isEmpty())
            return ranges;

        List> output = new ArrayList>();

        Iterator> iter = ranges.iterator();
        Range current = iter.next();

        T min = current.left.minValue();
        while (iter.hasNext())
        {
            // If current goes to the end of the ring, we're done
            if (current.right.equals(min))
            {
                // If one range is the full range, we return only that
                if (current.left.equals(min))
                    return Collections.>singletonList(current);

                output.add(new Range(current.left, min));
                return output;
            }

            Range next = iter.next();

            // if next left is equal to current right, we do not intersect per se, but replacing (A, B] and (B, C] by (A, C] is
            // legit, and since this avoid special casing and will result in more "optimal" ranges, we do the transformation
            if (next.left.compareTo(current.right) <= 0)
            {
                // We do overlap
                // (we've handled current.right.equals(min) already)
                if (next.right.equals(min) || current.right.compareTo(next.right) < 0)
                    current = new Range(current.left, next.right);
            }
            else
            {
                output.add(current);
                current = next;
            }
        }
        output.add(current);
        return output;
    }

    public AbstractBounds withNewRight(T newRight)
    {
        return new Range(left, newRight);
    }

    public static > List> sort(Collection> ranges)
    {
        List> output = new ArrayList<>(ranges.size());
        for (Range r : ranges)
            output.addAll(r.unwrap());
        // sort by left
        Collections.sort(output, new Comparator>()
        {
            public int compare(Range b1, Range b2)
            {
                return b1.left.compareTo(b2.left);
            }
        });
        return output;
    }


    /**
     * Compute a range of keys corresponding to a given range of token.
     */
    public static Range makeRowRange(Token left, Token right)
    {
        return new Range(left.maxKeyBound(), right.maxKeyBound());
    }

    public static Range makeRowRange(Range tokenBounds)
    {
        return makeRowRange(tokenBounds.left, tokenBounds.right);
    }

    /**
     * Helper class to check if a token is contained within a given collection of ranges
     */
    public static class OrderedRangeContainmentChecker
    {
        private final Iterator> normalizedRangesIterator;
        private Token lastToken = null;
        private Range currentRange;

        public OrderedRangeContainmentChecker(Collection> ranges)
        {
            normalizedRangesIterator = normalize(ranges).iterator();
            assert normalizedRangesIterator.hasNext();
            currentRange = normalizedRangesIterator.next();
        }

        /**
         * Returns true if the ranges given in the constructor contains the token, false otherwise.
         *
         * The tokens passed to this method must be in increasing order
         *
         * @param t token to check, must be larger than or equal to the last token passed
         * @return true if the token is contained within the ranges given to the constructor.
         */
        public boolean contains(Token t)
        {
            assert lastToken == null || lastToken.compareTo(t) <= 0;
            lastToken = t;
            while (true)
            {
                if (t.compareTo(currentRange.left) <= 0)
                    return false;
                else if (t.compareTo(currentRange.right) <= 0 || currentRange.right.compareTo(currentRange.left) <= 0)
                    return true;

                if (!normalizedRangesIterator.hasNext())
                    return false;
                currentRange = normalizedRangesIterator.next();
            }
        }
    }
}




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