IntervalTree.h

#ifndef __INTERVAL_TREE_H
#define __INTERVAL_TREE_H

#include <vector>
#include <algorithm>
#include <iostream>
#include <memory>
#include <cassert>

#ifdef USE_INTERVAL_TREE_NAMESPACE
namespace interval_tree {
#endif
template <class Scalar, typename Value>
class Interval {
public:
    Scalar start;
    Scalar stop;
    Value value;
    Interval(const Scalar& s, const Scalar& e, const Value& v)
    : start(std::min(s, e))
    , stop(std::max(s, e))
    , value(v) 
    {}
};

template <class Scalar, typename Value>
Value intervalStart(const Interval<Scalar,Value>& i) {
    return i.start;
}

template <class Scalar, typename Value>
Value intervalStop(const Interval<Scalar, Value>& i) {
    return i.stop;
}

template <class Scalar, typename Value>
std::ostream& operator<<(std::ostream& out, const Interval<Scalar, Value>& i) {
    out << "Interval(" << i.start << ", " << i.stop << "): " << i.value;
    return out;
}

template <class Scalar, class Value>
class IntervalTree {
public:
    typedef Interval<Scalar, Value> interval;
    typedef std::vector<interval> interval_vector;


    struct IntervalStartCmp {
        bool operator()(const interval& a, const interval& b) {
            return a.start < b.start;
        }
    };

    struct IntervalStopCmp {
        bool operator()(const interval& a, const interval& b) {
            return a.stop < b.stop;
        }
    };

    IntervalTree()
        : left(nullptr)
        , right(nullptr)
        , center(0)
    {}

    ~IntervalTree() = default;

    std::unique_ptr<IntervalTree> clone() const {
        return std::unique_ptr<IntervalTree>(new IntervalTree(*this));
    }

    IntervalTree(const IntervalTree& other)
    :   intervals(other.intervals),
        left(other.left ? other.left->clone() : nullptr),
        right(other.right ? other.right->clone() : nullptr),
        center(other.center)
    {}

    IntervalTree& operator=(IntervalTree&&) = default;
    IntervalTree(IntervalTree&&) = default;

    IntervalTree& operator=(const IntervalTree& other) {
        center = other.center;
        intervals = other.intervals;
        left = other.left ? other.left->clone() : nullptr;
        right = other.right ? other.right->clone() : nullptr;
        return *this;
    }

    IntervalTree(
            interval_vector&& ivals,
            std::size_t depth = 16,
            std::size_t minbucket = 64,
            std::size_t maxbucket = 512, 
            Scalar leftextent = 0,
            Scalar rightextent = 0)
      : left(nullptr)
      , right(nullptr)
    {
        --depth;
        const auto minmaxStop = std::minmax_element(ivals.begin(), ivals.end(), 
                                                    IntervalStopCmp());
        const auto minmaxStart = std::minmax_element(ivals.begin(), ivals.end(), 
                                                     IntervalStartCmp());
        if (!ivals.empty()) {
            center = (minmaxStart.first->start + minmaxStop.second->stop) / 2;
        }
        if (leftextent == 0 && rightextent == 0) {
            // sort intervals by start
            std::sort(ivals.begin(), ivals.end(), IntervalStartCmp());
        } else {
            assert(std::is_sorted(ivals.begin(), ivals.end(), IntervalStartCmp()));
        }
        if (depth == 0 || (ivals.size() < minbucket && ivals.size() < maxbucket)) {
            std::sort(ivals.begin(), ivals.end(), IntervalStartCmp());
            intervals = std::move(ivals);
            assert(is_valid().first);
            return;
        } else {
            Scalar leftp = 0;
            Scalar rightp = 0;

            if (leftextent || rightextent) {
                leftp = leftextent;
                rightp = rightextent;
            } else {
                leftp = ivals.front().start;
                rightp = std::max_element(ivals.begin(), ivals.end(),
                                          IntervalStopCmp())->stop;
            }

            interval_vector lefts;
            interval_vector rights;

            for (typename interval_vector::const_iterator i = ivals.begin(); 
                 i != ivals.end(); ++i) {
                const interval& interval = *i;
                if (interval.stop < center) {
                    lefts.push_back(interval);
                } else if (interval.start > center) {
                    rights.push_back(interval);
                } else {
                    assert(interval.start <= center);
                    assert(center <= interval.stop);
                    intervals.push_back(interval);
                }
            }

            if (!lefts.empty()) {
                left.reset(new IntervalTree(std::move(lefts), 
                                            depth, minbucket, maxbucket,
                                            leftp, center));
            }
            if (!rights.empty()) {
                right.reset(new IntervalTree(std::move(rights), 
                                             depth, minbucket, maxbucket, 
                                             center, rightp));
            }
        }
        assert(is_valid().first);
    }

    // Call f on all intervals near the range [start, stop]:
    template <class UnaryFunction>
    void visit_near(const Scalar& start, const Scalar& stop, UnaryFunction f) const {
        if (!intervals.empty() && ! (stop < intervals.front().start)) {
            for (auto & i : intervals) {
              f(i);
            }
        }
        if (left && start <= center) {
            left->visit_near(start, stop, f);
        }
        if (right && stop >= center) {
            right->visit_near(start, stop, f);
        }
    }

    // Call f on all intervals crossing pos
    template <class UnaryFunction>
    void visit_overlapping(const Scalar& pos, UnaryFunction f) const {
        visit_overlapping(pos, pos, f);
    }

    // Call f on all intervals overlapping [start, stop]
    template <class UnaryFunction>
    void visit_overlapping(const Scalar& start, const Scalar& stop, UnaryFunction f) const {
        auto filterF = [&](const interval& interval) {
            if (interval.stop >= start && interval.start <= stop) {
                // Only apply f if overlapping
                f(interval);
            }
        };
        visit_near(start, stop, filterF);
    }

    // Call f on all intervals contained within [start, stop]
    template <class UnaryFunction>
    void visit_contained(const Scalar& start, const Scalar& stop, UnaryFunction f) const {
        auto filterF = [&](const interval& interval) {
            if (start <= interval.start && interval.stop <= stop) {
                f(interval);
            }
        };
        visit_near(start, stop, filterF);
    }

    interval_vector findOverlapping(const Scalar& start, const Scalar& stop) const {
        interval_vector result;
        visit_overlapping(start, stop,
                          [&](const interval& interval) { 
                            result.emplace_back(interval); 
                          });
        return result;
    }

    interval_vector findContained(const Scalar& start, const Scalar& stop) const {
        interval_vector result;
        visit_contained(start, stop,
                        [&](const interval& interval) { 
                          result.push_back(interval); 
                        });
        return result;
    }
    bool empty() const {
        if (left && !left->empty()) {
            return false;
        }
        if (!intervals.empty()) { 
            return false;
        }
        if (right && !right->empty()) {
            return false;
        }
        return true;
    }

    template <class UnaryFunction>
    void visit_all(UnaryFunction f) const {
        if (left) {
            left->visit_all(f);
        }
        std::for_each(intervals.begin(), intervals.end(), f);
        if (right) {
            right->visit_all(f);
        }
    }

    std::pair<Scalar, Scalar> extentBruitForce() const {
        struct Extent {
            std::pair<Scalar, Scalar> x = {std::numeric_limits<Scalar>::max(),
                                                       std::numeric_limits<Scalar>::min() };
            void operator()(const interval & interval) {
                x.first  = std::min(x.first,  interval.start);
                x.second = std::max(x.second, interval.stop);
            }
                                                                };
                                            Extent extent;

        visit_all([&](const interval & interval) { extent(interval); });
        return extent.x;
                                            }

    // Check all constraints.
    // If first is false, second is invalid.
    std::pair<bool, std::pair<Scalar, Scalar>> is_valid() const {
        const auto minmaxStop = std::minmax_element(intervals.begin(), intervals.end(), 
                                                    IntervalStopCmp());
        const auto minmaxStart = std::minmax_element(intervals.begin(), intervals.end(), 
                                                     IntervalStartCmp());
        
        std::pair<bool, std::pair<Scalar, Scalar>> result = {true, { std::numeric_limits<Scalar>::max(),
                                                                     std::numeric_limits<Scalar>::min() }};
        if (!intervals.empty()) {
            result.second.first   = std::min(result.second.first,  minmaxStart.first->start);
            result.second.second  = std::min(result.second.second, minmaxStop.second->stop);
        }
        if (left) {
            auto valid = left->is_valid();
            result.first &= valid.first;
            result.second.first   = std::min(result.second.first,  valid.second.first);
            result.second.second  = std::min(result.second.second, valid.second.second);
            if (!result.first) { return result; }
            if (valid.second.second >= center) {
                result.first = false;
                return result;
            }
        }
        if (right) {
            auto valid = right->is_valid();
            result.first &= valid.first;
            result.second.first   = std::min(result.second.first,  valid.second.first);
            result.second.second  = std::min(result.second.second, valid.second.second);
            if (!result.first) { return result; }
            if (valid.second.first <= center) { 
                result.first = false;
                return result;
            }
        }
        if (!std::is_sorted(intervals.begin(), intervals.end(), IntervalStartCmp())) {
            result.first = false;
        }
        return result;        
    }

    friend std::ostream& operator<<(std::ostream& os, const IntervalTree& itree) {
        return writeOut(os, itree);
    }

    friend std::ostream& writeOut(std::ostream& os, const IntervalTree& itree, 
                                  std::size_t depth = 0) {
        auto pad = [&]() { for (std::size_t i = 0; i != depth; ++i) { os << ' '; } };
        pad(); os << "center: " << itree.center << '\n';
        for (const interval & inter : itree.intervals) {
            pad(); os << inter << '\n';
        }
        if (itree.left) {
            pad(); os << "left:\n";
            writeOut(os, *itree.left, depth + 1);
        } else {
            pad(); os << "left: nullptr\n";
        }
        if (itree.right) {
            pad(); os << "right:\n";
            writeOut(os, *itree.right, depth + 1);
        } else {
            pad(); os << "right: nullptr\n";
        }
        return os;
    }

private:
    interval_vector intervals;
    std::unique_ptr<IntervalTree> left;
    std::unique_ptr<IntervalTree> right;
    Scalar center;
};
#ifdef USE_INTERVAL_TREE_NAMESPACE
}
#endif

#endif