I have been trying to figure out an efficient way of managing dynamic arrays which I may change occasionally but would like to randomly access and iterate over often.

I would like to be able to:

  • store the array in a continuous data block (reduce cache misses)
  • access each element individually and independently of the array handle (pointers > indices)
  • resize the array (dynamic)

So in order to achieve this I have been trying things out using std::vector<T>::iterator, and it worked very well, until recently, when I resized the vector (e.g. calling push_back()) that I was storing iterators of. All the iterators became invalid, because they were pointing to stale memory.

Is there any efficient (possibly STL-)way of keeping the iterator pointers up to date? Or do I have to update each Iterator manually?

Is this whole approach even worthwhile? Should I stick with indices?

EDIT: I have used indices before and it was ok, but I have changed my approach because it still wasn´t good. I would always have to drag the entire array into scope and the indices could be easily used for any array. also there is no perfect way of defining a "NULL" index (none I know about).

What about the option to update all pointers along with a resize operation? All you would have to do is to store the original vector::begin, resize the vector and afterwards update all pointers to vector.begin() + (ptr - prevBegin) and resize operations is already something you should try to avoid.

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    Use a std::vector and use size_t indexes instead of iterators. – Chris Dodd Aug 24 '17 at 18:23
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    @snow_abstraction an index is useless if you don't also have the starting point of the array, so you need two pieces of information. The pointer goes directly to the element itself (but can be invalidated), so you don't need anything else. – Nir Friedman Aug 24 '17 at 18:28
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    @SteveLorimer: then use a std::pair<std::vector<..> *, size_t> or even wrap it into a class that supports operator*()/operator->() – Chris Dodd Aug 24 '17 at 18:36
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    You can easily use an index of -1 to indicate NULL. It's not possible to update pointers, because there's no master list of all the pointers to the array that exist in your program. – Mark Ransom Aug 24 '17 at 18:43
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    @ChrisDodd if he ever removes an item, or adds one anywhere other than the back of the vector some of the indices will be invalidated too. Not sure if he needs that kinds of functionality – Steve Lorimer Aug 24 '17 at 18:54

Fully achieving all 3 of your goals is impossible. If you are fully contiguous, then you have one memory block with a finite size, and the only way to get more memory is to ask for more memory, which will not be contiguous with the memory you already have. So you have to sacrifice at least one requirement, to at least some degree:

  • If you are willing to partly sacrifice contiguity, you can use a std::deque. This is an array-of-arrays kind of structure. It doesn't invalidate references, for I think any operation that increases its size. It depends on the details of your data type but generally its performance is much closed to a contiguous array than a linked list. Well done but old (5 year) benchmarks: https://baptiste-wicht.com/posts/2012/12/cpp-benchmark-vector-list-deque.html. Another option is to write a chunking allocator, to use either with deque or another structure. This is quite a bit more work though.
  • If you can use indices, then you can just use a vector
  • If you don't need to resize, you can still just use a vector and never resize it.

Unless you have a good reason, I would stick with indices. If your main performance bottlenecks are iteration related over a large number of elements (as your contiguity requirement implies), then this whole indexing thing should really be a non-issue. If you do have a very good reason for avoiding indices (which you haven't stated), then I would profile the deque versus the vector on the main loop operation to see how much worse the deque really does. It might be barely worse, and if neither deque nor vector work well enough for you, the next alternatives are quite a bit more work (probably involving allocators or a custom data structure).

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    Reaching out and updating everything that points to you is difficult, you'd have to store pointers of some kind to all the vector's clients somewhere near the vector. It's more logical to have everyone who needs to access the ith element of your vector v, store both a reference to v and and i itself. I'm not really sure I see the problem with that? Also you can do a null index as -1; this will wrap around to the largest unsigned value 2^64-1 most likely, probably more memory than you have ;-). – Nir Friedman Aug 24 '17 at 18:39

Depending on your needs, if you can use the following data structure:


then no matter how the vector is resized, if you access your data via a Foo*, the pointer to foo will not be invalidated.

As the number of Foos you need to store in your vector changes, the vector may need to resize it's internal contiguous block of memory, which means any iterators you have pointing inside the vector will be invalidated when the vector resizes.

(You can read more here on C++0x iterator invalidation rules)

However, since the object stored in the vector is a pointer to an object elsewhere in the heap, the pointed-to-object (Foo in this example), will not be invalidated.

Note that the vector owns Foo (as alluded to by std::unique_ptr<Foo>), whilst you can store a non-owning pointer to Foo by keeping a Foo* as the means of accessing your Foo data.

So long as the vector outlives your need to access Foo via your Foo*, then you will not have any lifetime issues.

So in terms of your requirements:

  • store the array in a continuous data block (reduce cache misses)

yes, std::vector achieves this

  • access each element individually and independently of the array handle (pointers > indices)

yes, store a Foo* as your means of accessing each element individually, and that remains independent of the array handle (vector::iterator)

  • resize the array (dynamic)

yes, std::vector achieves this, automatically, resizing for you when you need it to.


Using a smart pointer (in this example std::unique_ptr) in the vector means memory management is also handled automatically for you. (Just make sure you don't try to access a Foo* after the vector is destroyed.


It has been pointed out in the comments that storing a std::unique_ptr<Foo> in the vector violates your requirement for the objects to be stored in contiguous memory (if indeed that is what you mean by store the array in contiguous memory, as the vector's underlying array will be contiguous, but accessing the Foo objects will incur an indirection).

However, if you use a suitable allocator (eg arena allocator) for both the vector and the Foo objects, then you will have a higher chance of suffering fewer cache misses, as your Foo objects will exist near to the memory used by your vector, thereby having a higher chance of being in cache when iterating over the vector.

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    To be blunt, this should not be getting upvotes. The actual data here is not being stored contiguously and iterating over this vector will potentially cause piles of cache misses, contradicting a requirement of the question. – Nir Friedman Aug 24 '17 at 18:12
  • @NirFriedman fair enough - I've added a comment about using a suitable allocator to get the objects near to the vector's buffer – Steve Lorimer Aug 24 '17 at 18:20
  • I agree with Friedman, how is the data of all Foos stored continuously? The pointers to each Foo might be, but unless I store all Foos in a vector they could be allocated anywhere. But when using std::vector to store all Foos I will still invalidate all the unique_ptr<Foo>s pointers when resizing the vector<Foo> – stimulate Aug 24 '17 at 18:23
  • @stimulate you can't achieve all 3 requirements at the same time - but by using an allocator you can get close – Steve Lorimer Aug 24 '17 at 18:25
  • @SteveLorimer You can obviously use an allocator but really you are just shifting the problem around, once you have a good allocator written you can also just used it with a linked list, which a vector of unique_ptr's is very similar to, or another data structure like a deque. The vector of unique_ptr's suggestion itself (which your answer is focused on) doesn't buy you much, in fact buys you nothing over a linked list that I can think of. – Nir Friedman Aug 24 '17 at 18:25

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