You can do the math to try to figure how this kind of thing works.
A popular method to work with asymptotic analysis is the Bankers method. What you do is markup all your operations with an extra cost, "saving" it for later to pay for an expensive operation latter on.
Let's make some dump assumptions to simplify the math:
- Writing into an array costs
1. (Same for inserting and moving between arrays)
- Allocating a larger array is free.
And our algorithm looks like:
if n_elements >= maximum array size:
move all elements to a new array that
is K times larger than the current size
add x to array
n_elements += 1
Obviously, the "worst case" happens when we have to move the elements to the new array. Let's try to amortize this by adding a constant markup of
d to the insertion cost, bringing it to a total of
(1 + d) per operation.
Just after an array has been resized, we have (1/K) of it filled up and no money saved.
By the time we fill the array up, we can be sure to have at least
d * (1 - 1/K) * N saved up. Since this money must be able to pay for all N elements being moved, we can figure out a relation between
d*(1 - 1/K)*N = N
d*(K-1)/K = 1
d = K/(K-1)
A helpful table:
k d 1+d(total insertion cost)
1.0 inf inf
1.1 11.0 12.0
1.5 3.0 4.0
2.0 2.0 3.0
3.0 1.5 2.5
4.0 1.3 2.3
inf 1.0 2.0
So from this you can get a rough mathematician's idea of how the time/memory tradeoff works for this problem. There are some caveats, of course: I didn't go over shrinking the array when it gets less elements, this only covers the worst case where no elements are ever removed and the time costs of allocating extra memory weren't accounted for.
They most likely ran a bunch of experimental tests to figure this out in the end making most of what I wrote irrelevant though.