The ECMA specification does not specify a bounding complexity, however, you can derive one from the specification's algorithms.

`push`

is *O(1)*, however, in practice it will encounter an *O(N)* copy costs at engine defined boundaries as the slot array needs to be reallocated. These boundaries are typically logarithmic.

`pop`

is *O(1)* with a similar caveat to `push`

but the *O(N)* copy is rarely encountered as it is often folded into garbage collection (e.g. a copying collector could only copy the used part of an array).

`shift`

is at worst *O(N)* however it can, in specially cases, be implemented as *O(1)* at the cost of slowing down indexing so your mileage may vary.

`slice`

is *O(N)* where *N* is `end - start`

. Not a tremendous amount of optimization opportunity here without significantly slowing down writes to both arrays.

`splice`

is, worst case, *O(N)*. There are array storage techniques that divide *N* by a constant but they significantly slow down indexing. If an engine uses such techniques you might notice unusually slow operations as it switches between storage techniques triggered by access pattern changes.

One you didn't mention, is `sort`

. It is, in the average case, *O(N log N)*. However, depending on the algorithm chosen by the engine, you could get *O(N^2)* in some cases. For example, if the engine uses QuickSort (even with an late out to InsertionSort), it has well-known *N^2* cases. This could be a source of DoS for your application. If this is a concern either limit the size of the arrays you sort (maybe merging the sub-arrays) or bail-out to HeapSort.