An easy way to do this is to maintain two sorted containers, one lower than the median, one greater.

When you find a new element, see what container to insert it into (so that all elements of lower are always less than or equal to all elements of upper), then rebalance counts so that the median is "in the gap" between them.

Yours sort of does this, but defines the lower range to be `[.begin(), it)`

and the upper to be `[it, .end())`

. I'd make them separate containers to reduce the amount of state you need to keep in your head to understand the code, unless performance was particularly important.

Maintain two sorted containers, `low`

and `high`

, with the following invariants:

`low.size()`

is the same as `high.size()`

or 1 larger
- Every element of
`low`

is less than or equal to every element of `high`

.
Then the median of `low`

union `high`

is `low.last()`

.

Assuming you have such a pair of containers, if you wanted to add an element `x`

, I would first maintain invariant 2 -- if `low.empty()`

or `x <= low.last()`

, stick it in `low`

, otherwise stick it in `high`

.

Next, maintain invariant 1: if `high`

has more elements than low, remove the lowest element from `high`

and add it to `low`

. If `low`

has 2 more elements than `high`

, remove the highest element from `low`

and add it to `high`

.

If we started with a `low`

and `high`

that obeyed the above two invariants, then after the above steps we still have a `low`

and `high`

that obeys these two invariants. And when the above two invariants hold, the median is `low.last()`

!

`p=k; if(p<=k) ...`

– Geobits Oct 4 '13 at 18:12`std::multiset`

is ordered and there's also`std::unordered_multiset`

. A bit strange, but the ordered one came first. – aschepler Oct 4 '13 at 18:32