Unfortunately, the standard underspecifies behavior on allocator-aware sequence container assignment, and indeed is strictly speaking inconsistent.
We know (from Table 28 and from 23.2.1p7) that if
true then the allocator is replaced on copy assignment. Further, from Tables 96 and 99 we find that the complexity of copy assignment is linear, and the post-condition on operation
a = t is that
a == t, i.e. (Table 96) that
distance(a.begin(), a.end()) == distance(t.begin(), t.end()) && equal(a.begin(), a.end(), t.begin()). From 23.2.1p7, after copy assignment, if the allocator propagates, then
a.get_allocator() == t.get_allocator().
With regard to vector capacity, 220.127.116.11 [vector.capacity] has:
5 - Remarks: Reallocation invalidates all the references, pointers, and iterators referring to the elements in the sequence. It is guaranteed that no reallocation takes place during insertions that happen after a call to
reserve() until the time when an insertion would make the size of the vector greater than the value of
If we take library DR341 as a guide to reading the Standard:
However, the wording of 18.104.22.168 [vector.capacity]paragraph 5 prevents the capacity of a vector being reduced, following a call to reserve(). This invalidates the idiom, as swap() is thus prevented from reducing the capacity. [...]
DR341 was resolved by adding paragraphs into 22.214.171.124:
void swap(vector<T,Allocator>& x);
7 - Effects: Exchanges the contents and
*this with that of
8 - Complexity: Constant time.
The conclusion is that from the point of view of the Library committee, operations only modify
capacity() if mentioned under 126.96.36.199. Copy assignment is not mentioned under 188.8.131.52, and thus does not modify
capacity(). (Move assignment has the same issue, especially considering the proposed resolution to Library DR2321.)
Clearly, this is a defect in the Standard, as copy assignment propagating unequal allocators must result in reallocation, contradicting 184.108.40.206p5.
We can expect and hope this defect to be resolved in favour of:
capacity() on non-allocator-modifying copy assignment;
capacity() on allocator-modifying copy assignment;
capacity() on non-allocator-propagating move assignment;
capacity() on allocator-propagating move assignment.
However, in the current situation and until this is clarified you would do well not to depend on any particular behavior. Fortunately, there is a simple workaround that is guaranteed not to reduce