# Rank Tree in C++

We need ADT having search and rank features. That is, in addition to the interface of STL map, a function 'int get_rank(key)' is required.

Standard implementation of such function requires supporting and updating an extra integer field in every node of self-balanced searching tree (e.g., in black-red tree, used in STL map/set). But it seems, STL map/set do not do this.

We're looking for a solution based on standard containers (STL, Boost) having the best possible Time Complexity: finding/adding/erasing an element take O(log n) (like in STL map/set), computing the rank by a key takes also O(log n).

By the rank of an element, we mean the position of the element in the sorted sequence of all the elements of the map/set.

Example. set = {0, 4, 6, 7, 8} rank(0)=1, rank(4)=2, rank(6)=3, rank(7)=4, rank(8)=5.

In our opinion, under Time Complexity constrains above, the problem cannot be solved by a combination of two maps one sorting by key and other sorting by rank.

Thanks.

• The complexities of search, insert and delete are often inversely related to each other. We can't decide which trade-off is best for you. – luke Feb 18 '10 at 17:59
• There is an implementation of rank tree satisfying all the time complexity constrains, see, e.g., the book of Cormen, T.H. "Introduction to Algorithms". – Slava Feb 23 '10 at 10:00
• It can be done with GNU extension in the `libstdc++`, see here. – Ali Apr 16 '14 at 13:35

The rank of the given key K is the number of keys which are less or equal to K.

E.g., let set s = {1, 3, 4, 6, 9}. Then rank(1) = 1, rank(4) = 3, rank(9) = 5.

The STL function distance() can be used for computing the rank of an element x appearing in the set s.

rank = distance(s.begin(), s.find(x));

The problem is that its time complexity is O(n).

Note that proposed two maps (or sets) indexed by key and by rank is not correct solution. The problem is that a change of one element affects ranks of many others. E.g., adding element 0 to the set s above change the ranks of all existing elements: s' = {0, 1, 3, 4, 6, 9}. rank(1) = 2, rank(4) = 4, rank(9) = 6.

Thanks.

I've implemented a "ranked red-black tree" which is similar to a red-black tree except each node stores the distance from the node that precedes it via an in-order traversal, rather than storing a key.

This does exactly what you want, except the "rank" of the first node is 0 and not 1 (you can add/subtract 1 if needed).

My solution is PUBLIC DOMAIN and is based on a public domain tutorial for a regular red-black tree. All operations -- including insert, remove, find, and determine rank have logarithmic time with respect to the number of elements in the data structure.

you can use some other map like containers .
keep a size fields can make binary search tree easy to random access .
here is my implementation ...
std style , random access iterator ...
size balanced tree ...
https://github.com/mm304321141/zzz_lib/blob/master/sbtree.h
and B+tree ...
https://github.com/mm304321141/zzz_lib/blob/master/bpptree.h

• Nice library. But why not provide some notes in English? – def Mar 7 '18 at 4:12
• I have a question. You have 2 specializations for sbtree: multimap and multiset. What about a regular map and set? Overall, a very useful classes, Cheers) Was looking for a while something like that. Can't see a reason why standard libs do not have weigh-balanced containers in them. – def Mar 10 '18 at 16:29
• one of my other project need a rank supported multimap ... i public it after that ... – 奏之章 Mar 11 '18 at 16:02

I would suppose that by `rank` you actually mean the distance from the root, since if it could be stored contiguously with the value you would not have to go to such length.

I think you could do it "externally", since in this case the rank can be extrapolated from the number of times the comparison predicate is used...

``````namespace detail
{
template <class Comparator>
class CounterComparator: Comparator
{
public:
CounterComparator(size_t& counter):
Comparator(), mCounter(&counter) {}
CounterComparator(Comparator comp, size_t& counter):
Comparator(comp), mCounter(&counter) {}

template <class T, class U>
bool operator()(T& lhs, U& rhs) const
{
++(*mCounter);
return this->Comparator::operator()(lhs,rhs);
}
private:
size_t* mCounter;
};
} // namespace detail

template <
class Key,
class Value,
class Cmp = std::less<Key>,
class Allocator = std::allocator< std::pair<const Key,Value> >
>
class SuperMap
{
typedef detail::CounterComparator<Cmp> Comparator;
public:
SuperMap(): mCounter(0), mData(Comparator(mCounter)) {}

Value& operator[](const Key& key) { return mData[key]; }

size_t rank(const Key& key) const
{
mCounter = 0; mData.find(key); return mCounter;
}

private:
typedef std::map<Key,Value, Comparator, Allocator> data_type;

mutable size_t mCounter;
data_type mData;
}; // class SuperMap

int main(int argc, char* argv[])
{
SuperMap<int,int> superMap;
superMap = 42;
std::cout << superMap.rank(1) << std::endl;
}

// outputs
// 2
``````

It counts the number of tests, but since `std::map` stops testing as soon as it gets the right key... it should be alright :) Though there is probably some offset to deduce there (1 or 2) to get the rank instead.

If you gave a better definition of `rank` I may work a bit more but I don't want to spend too much time in the wrong direction.