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What is the time complexity for a clear function is std::map?
Would I be right in saying that it is O(1)?

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It has to destroy all the member objects. Sounds like O(n). – Bo Persson Jun 12 '12 at 9:32
@BoPersson: but what if the elements had a trivial destructor ? – Matthieu M. Jun 12 '12 at 9:36
Then it would run faster. :-) The actual time taken is k*n where k depends on the type of the member objects. But in big O terms, it is still O(n) even if k is very small. – Bo Persson Jun 12 '12 at 9:40
@BoPersson: maybe, maybe not. is_trivially_destructible is a compile-time trait so it could deduce at compile-time that no such action is needed. – Matthieu M. Jun 12 '12 at 9:49
@jrok: the map has to call deallocate on each node anyway, I am afraid, so the optimizer can be trusted to inline the destroy call to nothing and there is no need for additional code. – Matthieu M. Jun 12 '12 at 9:55

The Standard says in [associative.reqmts]/8 Table 102:

a.clear() <=> a.erase(a.begin(), a.end()) linear in a.size()

So it is actually mandated to be O(N).

EDIT: summing up the various bits.

To remove a node, a map does two operation:

  1. Call the allocator destroy method to destroy the element
  2. Call the allocator deallocate method to deallocate the memory occupied by the node

The former can be elided in code (checking for is_trivially_destructible), and actually it is generally done in vector for example. The latter is unfortunately trickier, and no trait exists, so we must rely on the optimizer.

Unfortunately, even if by inlining the optimizer could completely remove the destroy and deallocate nodes, I am afraid it would not be able to realize that the tree traversal is now useless and optimize that away too. Therefore you would end up in a Θ(N) traversal of the tree and nothing done at each step...

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+1 Finally someone to cite the "only reliable" source on this. – Nobody Jun 12 '12 at 9:46
Since the question was posted, it's been clear that the worst-case behaviour for any non-trivial destructor was O(N), but does the standard saying linear there not confirm that worst-case rather than eliminate the possibility that an implementation could achieve O(1)? – Tony D Jun 12 '12 at 9:48
@TonyDelroy: It's an interesting question. The Standard precises it cannot be worse than O(N) but I certainly hope it does not constrain applications not to optimize. I think the as-if rule still holds, and as long as the observational behavior is similar optimizations could be applied. – Matthieu M. Jun 12 '12 at 9:54
O(1) is O(N) so an O(1) implementation satisfies the O(N) requirement. – Charles Bailey Jun 12 '12 at 10:01
O(N) just says that there exists an n and a k such that for N > n the thing being measured (time / CPU ticks) is less than kN. An O(1) process can satisfy this with whatever n satisfies the equivalent O(1) requirement and k = k/n for the O(1) k. – Charles Bailey Jun 12 '12 at 10:05

The cplusplus reference site claims it has linear complexity in the container's size as the destructor of each element must be called.

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Because it's a template, it may be known at compile time that destruction in a no-op for the type (e.g. std::map<int>), so the need to destroy members isn't a good basis for deducing a necessary worst-case performance. Still, the compiler must visit every node of the binary tree, releasing the heap memory, and the number of nodes relates linearly to the number of elements (that erase() only invalidates iterators/references/pointers to the erased element, insert() doesn't invalidate any etc. all evidence the 1:1 relationship).

So, it's linear, but because of the need to clean up the heap usage even if element destructors aren't needed....

(Interestingly, this implies that a std::map<>-like associative container - or perhaps std::map<> itself with a clever custom allocator - could be made O(1) for elements with trivial no-op destructors if all the memory was allocated from a dedicated memory pool that could be "thrown away" in O(1).)

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What if the map is allocated on an arena or object pool which could release the memory in O(1)? – Puppy Jun 12 '12 at 9:40
I already challenged the destructors calls (for trivially_destructible values), now let me challenge the memory deallocation. Is it mandated by the Standard that the map cannot keep the allocated nodes in a pool for later reuse ;) ? – Matthieu M. Jun 12 '12 at 9:40
@DeadMG: I am afraid that the generic template would still call deallocate on each and every node, it cannot know that the allocator is pool-based. – Matthieu M. Jun 12 '12 at 9:41
@MatthieuM: you can provide a custom allocator with trivial deallocate though... again this is resolved at compile time. – Tony D Jun 12 '12 at 9:49
@DeadMG: Actually, it is interesting. Because it suggest that with more traits, an allocator could expose to the caller than destroy and deallocate are no-op so that the caller could take advantage of it; unfortunately it would be non-standard. – Matthieu M. Jun 12 '12 at 9:50

As I know, all the clean-operation's complexity is O(n), because you need to destuct these objects one by one.

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