I'm looking for a C++ implementation of a data structure ( or a combination of data structures ) that meet the following criteria:

  • items are accessed in the same way as in std::vector
  • provides random access iterator ( along with iterator comparison <,> )
  • average item access(:lookup) time is at worst of O(log(n)) complexity
  • items are iterated over in the same order as they were added to the container
  • given an iterator, i can find out the ordinal position of the item pointed to in the container, at worst of O(log(n)) complexity
  • provides item insertion and removal at specific position of at worst O(log(n)) complexity
  • removal/insertion of items does not invalidate previously obtained iterators

Thank you in advance for any suggestions


(Edit) Answers:

The answer I selected describes a data structure that meet all these requirements. However, boost::multi_index, as suggested by Maxim Yegorushkin, provides features very close to those above.

(Edit) Some of the requirements were not correctly specified. They are modified according to correction(:original)

(Edit) I've found an implementation of the data structure described in the accepted answer. So far, it works as expected. It's called counter tree

(Edit) Consider using the AVL-Array suggested by sp2danny

  • You can't have multi-line comments. Better to edit the question. Aug 10 '11 at 12:18
  • Perhaps a boost.multi_index with an underlying vector plus a set-type index for fast lookup...
    – Kerrek SB
    Aug 10 '11 at 12:19
  • 1
    There is no such container that would meet all your requirements in the standard library. Also, I don't believe there exists such a container even theoretically. You should prioritize your requirements so that we can think of something most suitable Aug 10 '11 at 12:24
  • 2
    your list of requirements precludes the use of any known single data structure. The only way you will meet all of them is to use something which combines multiple data structures (such the boost::multi_index mentioned by Kerrek)
    – Nim
    Aug 10 '11 at 12:24
  • 1
    If there were such a container, that would be the only one in the standard library.
    – Bo Persson
    Aug 10 '11 at 13:19

Based on your requirements boost::multi_index with two indices does the trick.

The first index is ordered index. It allows for O(log(n)) insert/lookup/remove. The second index is random access index. It allows for random access and the elements are stored in the order of insertion. For both indices iterators don't get invalidated when other elements are removed. Converting from one iterator to another is O(1) operation.

  • I guess you have to be careful to track which iterator you have. Also, is iterating over all the items in order O(N) or O(N*log(N))? I.e. is the iterator's operator++ O(1) or O(log(N))? Aug 10 '11 at 13:16
  • The doc for ordered index does not state the complexity of operator++. However, it is implemented as red-black tree, so the complexity of iterator's operator++ is the same as that of std::set or std::map. Namely O(1). Aug 10 '11 at 13:26
  • complexity of iterating over all the items is not important. I think I was unclear in the provided specification. I need to access the items only by the order of their insertion. I have nothing else to order them by (that would be of use), so I think that disqualifies the ordered index of boost::multi_index. Random access index seems to almost do the trick, except inserting/deleting elements at any place other than the end of the sequence has O(log(n)) complexity Aug 10 '11 at 14:22
  • @Dalibor: looks like you are not familiar with boost::multi_index. I suggest you read the Tutorial and then re-read my answer. Aug 10 '11 at 14:35

Let's go through these...

  • average item lookup time is at worst of O(log(n)) complexity
  • removal/insertion of items does not invalidate previously obtained iterators
  • provides item insertion and removal of at worst O(log(n)) complexity

That pretty much screams "tree".

  • provides random access iterator ( along with iterator comparison <,> )
  • given an iterator, i can find out the ordinal position of the item pointed to in the container, at worst of O(log(n)) complexity
  • items are iterated over in the same order as they were added to the container

I'm assuming that the index you're providing your random-access iterator is by order of insertion, so [0] would be the oldest element in the container, [1] would be the next oldest, etc. This means that, on deletion, for the iterators to be valid, the iterator internally cannot store the index, since it could change without notice. So just using a map with the key being the insertion order isn't going to work.

Given that, each node of your tree needs to keep track of how many elements are in each subtree, in addition to its usual members. This will allow random-access with O(log(N)) time. I don't know of a ready-to-go set of code, but subclassing std::rb_tree and std::rb_node would be my starting point.

  • This is exactly of what I was thinking of, but I did not know any existing implementation. Aug 10 '11 at 12:41
  • That's why I said you'd probably have to roll your own starting with the standard library red-black tree code. Aug 10 '11 at 13:18
  • Never heard that the standard library had rb_tree and rb_node?
    – UncleBens
    Aug 10 '11 at 14:41
  • rb_tree and rb_node are not documented because they are implementation details (used internally) of the provided STL containers. Aug 10 '11 at 14:45

See here: STL Containers (scroll down the page to see information on algorithmic complexity) and I think std::deque fits your requirements.

  • 2
    How does deque allow for fast look-up by value? Also, container modification does invalidate iterators (but not references to elements).
    – Kerrek SB
    Aug 10 '11 at 12:20
  • 1
    deque is worst-case O(N) lookup and removal, IIRC. Aug 10 '11 at 12:21
  • 2
    I don't think a deque satisfies the insertion/removal constraints (except for insertions/removals at the front and end). See in n3290.pdf C++0x preliminary standard.
    – user786653
    Aug 10 '11 at 12:21
  • for a deque insertion and removal may not have O(log(n)) time complexity
    – A. K.
    Aug 10 '11 at 12:23
  • @Aditya: Correct. Insertion and/or removal should be O(1) from either end or O(N) anywhere else. Aug 10 '11 at 12:36

AVL-Array should fit the bill.

  • Don't know why this has been down-voted. The referenced data structure, according to the documentation, satisfies the requirements. Only thing I'm missing is the ability to tell the ordinal position of an object in the array given its iterator. I may have overlooked something in the documentation? Jun 24 '14 at 14:20
  • ordinal position from iterator is missing from the source. I needed it myself, and added it as a one-liner.
    – sp2danny
    Jun 24 '14 at 14:21

Here's my "lv" container that fit the requirement, O(log n) insert/delete/access time. https://github.com/xhawk18/lv

The container is header only C++ libraries, and has the same iterator and functions with other C++ containers, such as list and vector.

"lv" container is based on rb-tree, each node of which has a size value about the amount of nodes in the sub-tree. By check the size of left/right child of a tree, we can fast access the node randomly.

  • Thanks. How does it compare to the counter_tree and AVL-array mentioned in the question edits? Nov 23 '14 at 15:22
  • Hi, Dalibor, It's an implement of counter tree, with rb-tree as the base data structure.
    – xhawk18
    Mar 2 '15 at 7:03

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