Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am looking for a container in c++ that satisfies my following needs:

  • I need to delete elements by index.
  • Right after I delete one element, I will insert another on in the front (ALWAYS!!!!!)
  • Besides that, there is not change in size.
  • It NEEDS to be indexed.
  • The values stored in the container are unique, as the index.
  • One index should be assigned to one value. Unless i delete or add one values. Then the index should be adapted.

For another set of data, that is working kinda parallel to that container, I need one with these features and these additional:

  • This one needs to work kinda in two directions: Since it stores a unique value, I need to be able to access the index through the actual value (which is 100% unique) very fast, since that will happen a lot of times.

I cannot grantee, that any of the value types support operators like <, <=, ... besides == and !=

If there are questions, go ahead an ask. If something is unclear, I will further explain it.

EDIT:

Since I've been requested, here comes the actual problem behind that:

I am writing a library made out of an template container class, which is able to store a certain amount of objects. All these Objects are the same type. (Well, of course...) Another very important property of these objects must be, that they can be recreated by a unique index. this index could be also anything. An example in this case would be a two dimensional space, where you can create objects, that are on the plane and all there properties can be recreated by giving the object class the coordinates (as a single object in this case). Now when the container reaches maximum capacity, it deletes the objects last used. My idea was here, that you give the container the unique index. If the desired object is still stored, the function return a pointer on the object and moves it inside the inner container to the front. If the desired object is NOT stored in the internal container, the last object in the internal container will be deleted and the new one will be generated and put to the front.

I need this, because I have a program which will easily use all my RAM and by far more. Well I could generated and destroy the object every time, but that just seems like a waste of computation power to me. So I came up with this container that only deletes the object, if it hasn't been used for quite a big time. Which is in my particularity case pretty useful (Path-finding on HUGE maps)

I hope that helps!

EDIT2:

Ok. I'm going to make this even more clear.

Let's start of with a simple data cache:

[0] d1  [1] d2  [2] d3  [3] d4

Now let's say i used d3. The structure should now look like this:

[0] d3  [1] d1  [2] d2  [3] d4

Now I add a completely new element to the container (d5).

[0] d5  [1] d3  [2] d1  [3] d2

That is the idea behind. Now instead of int-values as index, I allow to have a custom index class, which is able to restore every single object, that might possibly deleted (That is not a problem. Just a requirement in order for my class to work).

Let's begin with the beginning statement. That looks like this for the first case:

[0] i1  [1] i2  [2] i3  [3] i4
[i1] 0  [i2] 1  [i3] 2  [i4] 3

The second example looks like this:

[0] i3  [1] i1  [2] i2  [3] i4
[i1] 1  [i2] 2  [i3] 0  [i4] 3

And finally the last state looks like this:

[0] i5  [1] i3  [2] i1  [3] i2
[i1] 2  [i2] 3  [i3] 1  [i5] 0

I hope that makes it more clear. For the second one more than one container might be possible.

share|improve this question
    
Have you profiled something like std::deque to see if it is fast enough for what you need? –  Travis Gockel Jan 29 '13 at 5:23
    
I have read about the properties and it did not seem a good choice. Like all the other popular containers too. I don't even mind using a container from boost. –  BrainStone Jan 29 '13 at 5:25
    
More like you need std::map –  billz Jan 29 '13 at 5:32
    
devmentor.org/references/stl/stl.php std::list looks like what you are looking for –  Wee You Jan 29 '13 at 5:32
1  
@billz: I think by indexed that the OP means O(1) access through a numeric key that represents the ordinal position in a list. –  Omnifarious Jan 29 '13 at 5:42
show 12 more comments

5 Answers 5

Sorry - I find your question a bit vague - but I'll state what I think your requirement must be then discuss the data structure needs...

So, we have indexed data like - something like this (where indexes are in brackets):

[0] a  [1] h  [2] b  [3] q

Your main operation is the delete/insert - say we did delete element 2 and insert value x, we'd have:

[0] x  [1] a  [2] h  [3] q

So, if we call the element index being deleted n, given what we've effectively done is move [0..n-1] along one position, then overwrite [0] with the extra value.

Discussion

If you do this operation with a vector, then the move operation can be arbitrarily large and relatively slow. But if you use some other container such as an associative container (map, unordered map) you'd have to update the keys for all those "moved" elements anyway. Other common containers don't provide O(log2N) or better indexing, so aren't promising, so let's stick with vector and see how to minimise the pain. As well as the move being O(N), it involves shifting arbitrarily large objects: in the case when the objects are much larger than a pointer, you could have an array of points to objects and just move the array's pointers without moving the objects: that could be much faster (it's also useful for objects that don't like being moved, typical reason is the C++03 copy slowness for which C++11 introduced move operators).

I can't think of anything much better than this vector approach.

Returning to the vagueness of your question - if your confusing "index" with "key" and simply need a keyed container but don't need objects to shift their keys with each delete/insert operation, then a map or unordered map is a much better choice.

share|improve this answer
    
This seems to be a good approach. Would it make sense, to add elements to the back, instead of the front? And would the vector class not automatically adjust everything by itself? –  BrainStone Jan 29 '13 at 5:52
    
Adding elements to the back isn't necessarily any better... main consequence would be if you happened to normally find the next element towards the back of the indices then there'd be a less object-moving involved, but I see no reason to assume that would happen. Just to be clear - what would be massively faster is to insert the element where-ever the element you're removing had happened to be - then no copy/move of other elements is needed. cont –  Tony D Jan 29 '13 at 6:41
    
...The vector class does not automatically move elements: the vector represents an indexed area of contiguous storage... computer memory systems don't generally have a notion of whether specific memory is an array/vector is in use, and the program itself has to shift content to repack the array to keep it contiguous so that it can be indexed quickly using a baseAddress + sizeof(Element) * index approach. –  Tony D Jan 29 '13 at 6:44
    
Yeah. I figured. That's the reason, why I am going with list and std::advance though. But really thank you!! –  BrainStone Jan 29 '13 at 6:48
    
Might work for you, but using std::advance to navigate to an arbitrary index n all the way from the first element will be very slow compared to direct indexing: possibly enough to stop your program working very well at all. –  Tony D Jan 29 '13 at 9:31
add comment

If you are using boost c++ libraries, take a look at Multi-index containers.

http://www.boost.org/doc/libs/1_52_0/libs/multi_index/doc/index.html

share|improve this answer
    
I was thinking of using boost anyways. But I did not know, that something like that existed! thank you! –  BrainStone Jan 29 '13 at 7:38
add comment

Let's have a look at your requirements:

  • Access by position
  • Access by element
  • Deletion at arbitrary position
  • Unicity of elements

How to ?

  • You need something with Random Access to support the "access by position", or at least close to Random Access O(log N) might be sufficient
  • Given that elements may not support ordering, unicity would require the use of a hash-set

This can be easily achieved using Boost.MultiIndex I think. The examples section already gives a MRU cache implementation and you are close enough. I would suggest combining:

This means something like:

typedef multi_index_container<
  T,
  indexed_by<
    random_access<>,
    hashed_unique</*...*/>
  > 
> cache_type;

Note: that for a Hashed Index to work, you need both support for == (or a specialization of std::equal<T>) and a hash functor. The latter can be provided by the user at the point of declaration of the container if the type does not already support it.

share|improve this answer
    
Thank you for this answer. But I have a few questions about that: Is it fast/effective? If not, this is not an option! And will the "standard" index be automatically adapted? Means, if i delete one object, will the index hole be closed? Like 1 2 3 turns into 1 2? –  BrainStone Jan 30 '13 at 4:08
1  
@YannickSchinko: 1/ It's probably faster that the solution you proposed yourself, whether this is sufficient for your needs however is another thing altogether. Most notably: it's more space efficient than most "multiple-container" solutions 2/ Yes, all indexes are automatically kept in sync; this is actually one big selling point of this solution: no object is "partially" present. –  Matthieu M. Jan 30 '13 at 8:41
add comment

Ok. Thank you everybody, but I found a very effective solution for this:

Since my problems requires the following data structure;

[0] d1  [1] d2  [2] d3  [3] d4
[0] i1  [1] i2  [2] i3  [3] i4
[i1] 0  [i2] 1  [i3] 2  [i4] 3

I decided, to use these Containers:

  1. list
  2. list
  3. map

Through some research I found out about std::advance and std::next, which allow me to effectively access certain elements in the list. To update the map, I will just run a simple for loop, which should work quite efficient.

If you have better ideas, please post the here!

Thank you again!

share|improve this answer
1  
list are probably the worst container you can use: not cache-friendly, bulky, etc... Note that std::advance is O(N) for list (ie, if you ask to advance by 18, it will advance 18 times). A vector of unique_ptr to objects will likely be more efficient. –  Matthieu M. Jan 29 '13 at 7:48
    
Since i delete more, than I search, I really think list should be faster since deleting and adding is just O(1). –  BrainStone Jan 30 '13 at 4:15
    
It depends on the number of items you have, and how expensive to move/copy they are. Beware that Big O complexity is only meaningful for huge volumes, for smaller volumes (~100/~1000 items) constant factors are more important. –  Matthieu M. Jan 30 '13 at 8:43
add comment

Just wanted to point out the multi_index_container solution has the same inefficiency as using a vector for random access support: deletion will have a cost linear in the size of the data structure. Internally, the random_access index uses a data structure similar to a vector of pointers.

There aren't that many data structures that allow both random access AND deletion of any element at better-than-linear time. AFAIK std::deque has linear time deletion, unless the item is close to one of the ends of the sequence.

This leaves us with balanced binary trees (and variants, like skip lists). A self balancing binary tree can maintain the size of the subtree below any node at a fixed overhead, and with this "augmentation" implement random access in O(log n). Unfortunately, the default implementations of std::map generally don't have this feature. So using std::map and std::advance gives you linear time random-access. You can't implement efficient random-access "on top" of std::map as your user code is not aware of the tree manipulations done internally by std::map.

You could roll your own (AVL trees are relatively easy to implement). Can't think of any easier way unless you're willing to accept poor performance on either the random access lookup or the delete+insert operation. The "least bad" solution that doesn't involve trees is probably using std::deque

EDIT: The augmented tree data structures I've mentioned are known as http://en.wikipedia.org/wiki/Order_statistic_tree.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.