I understand how random access iterators work for contiguous containers like std::vector: the iterator simply maintains a pointer to the current element and any additions/subtractions are applied to the pointer.

However, I'm baffled as to how similar functionality could be implemented for a non-contiguous container. My first guess for how std::deque:iterator works, is that it maintains a pointer to some table of the groups of contiguous memory it contains, but I'm not sure.

How would a typical standard library implement this?

  • Who says a deque isn't contiguous? It's usually implemented as a dynamic array.
    – ooga
    Apr 22 '14 at 3:16
  • 2
    @ooga from here As opposed to std::vector, the elements of a deque are not stored contiguously: typical implementations use a sequence of individually allocated fixed-size arrays.
    – Bryan Chen
    Apr 22 '14 at 3:18
  • 1
    @ooga, Then how would it differ from a vector?
    – chris
    Apr 22 '14 at 3:18
  • @BryanChen I wonder what that means? A "sequence ... of arrays"?
    – ooga
    Apr 22 '14 at 3:20
  • 1
    A diagram for a typical deque: kremer.cpsc.ucalgary.ca/STL/1024x768/deque.html and an article that looks like it might be helpful (though I've only glanced at it): secweb.cs.odu.edu/~zeil/cs361/web/website/Lectures/deques/page/… Apr 22 '14 at 3:21

You can satisfy the requirememts of a std::deque with a std::vector<std::unique_ptr<std::array<T,N>>> roughly. plus a low/high water mark telling you where the first/last elements are. (for an implementation defined N that could vary with T, and the std::arrays are actually blocks of properly aligned uninitialized memory and not std::arrays, but you get the idea).

Use usual exponential growth, but on both front and back.

Lookup simply does (index+first)/N and %N to find the block and sub element.

This is more expensive than a std::vector lookup, but is O(1).

  • At http://cppreference.com the page for deque::push_back indicate constant time complexity while the page for vector::push_back indicated amortized constant time complexity. Wouldn't using a vector as a backend for pointers to arrays violate the requirement that deque::push_back be constant? Or is amortized constant acceptable?
    – chbaker0
    Apr 22 '14 at 3:34
  • @mebob elsewhere it states amortized constant: is error. I should fix it after confirming with the standard. Apr 22 '14 at 4:19
  • OK that makes sense. I can't really think of a way to get around the amortized constant limit anyway. And back to my question about iterators: so an iterator would simply hold a reference to the said vector and switch buffers when it reached the end of one?
    – chbaker0
    Apr 22 '14 at 4:28
  • @mebob yes, something like that. Apr 22 '14 at 11:40
  • You might also want to add that making N a compile-time constant that's also a power of two (a static_assert, perhaps) should be very good for performance. Apr 4 '18 at 7:31

A deque iterator can be implemented by storing both a pointer to the referenced value and a double pointer to the contiguous block of memory in which that value is located. The double pointer points into a contiguous array of pointers to blocks managed by the deque.

class deque_iterator
  T* value;
  T** block;

Because both value and block point into contiguous memory, you can implement operations such finding the distance between iterators in constant time (example adapted from libc++).

difference_type operator-(deque_iterator const& x, deque_iterator const& y)
  return (x.block - y.block) * block_size
       + (x.value - *x.block)
       - (y.value - *y.block);

Note that, while value will not be invalidated by operations such as push_front and push_back, block might be, which is why deque_iterator is invalidated by such operations.

  • Thats the only answer that answers the question so far, and definitely a good one.
    – CharMstr
    Jan 30 '21 at 13:03

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