As a result of this question from a few days ago there are a few things that have been bugging me about the complexity requirements for `std::deque::push_back/push_front`

vs the actual `std::deque`

implementations out in the wild.

The upshot of the previous question was that these operations are required to have `O(1)`

worst case complexity. I verified that this was indeed the case in `c++11`

:

from 23.3.3.4 deque modifiers, refering to insert, push/emplace front/back

Complexity: The complexity is linear in the number of elements inserted plus the lesser of the distances to the beginning and end of the deque. Inserting a single element either at the beginning or end of a deque always takes constant time and causes a single call to a constructor of T.

This is combined with the `O(1)`

complexity requirement for indexing, via `operator[]`

etc.

The issue is that implementations don't strictly satisfy these requirements.

In terms of both `msvc`

and `gcc`

the `std::deque`

implementation is a blocked data structure, consisting of a dynamic array of pointers to (fixed size) blocks, where each block stores a number of data elements.

In the worst case, `push_back/front etc`

could require an extra block to be allocated (which is fine - fixed size allocation is `O(1)`

), but it could also require that the dynamic array of block pointers be resized - this is not fine, since this is `O(m)`

where `m`

is the number of blocks, which at the end of the day is `O(n)`

.

Obviously this is still amortised `O(1)`

complexity and since generally `m << n`

it's going to be pretty fast in practice. But it seems there's an issue with conformance?

As a further point, I don't see how you can design a data structure that strictly satisfies both the `O(1)`

complexity for both `push_back/front etc`

and `operator[]`

. You could have a linked-list of block pointers, but this doesn't give you the desired `operator[]`

behaviour. Can it actually be done?