I can't provide a full answer, but it might be a hint into the right direction.

**Basic ideas**:

- Let's assume you've calculated the average of
`n`

numbers `a_1,...,a_n`

, then this average is `avg=(a_1+...+a_n)/n`

. If we now replace `a_n`

by `b`

, we can recalculate the new average as follows: `avg'=(a_1+...+a_(n-1)+b)/n`

, or - simpler - `avg'=((avg*n)-a_n+b)/n`

. That means, if we exchange one element, we can recompute the average using the original average value by simple, fast operations, and don't need to re-iterate over all elements participating in the average.

Note: I assume that you want to have `log n`

neighbours on each side, i.e. in total we have `2 log(n)`

neighbours. You can simply adapt it if you want to have `log(n)`

neighbours in total. Moreover, since `log n`

in most cases won't be a natural number, I assume that you are talking about `floor(log n)`

, but I'll just write `log n`

for simplicity.

The main thing I'm considering is the fact that you have to tell the average around element `x`

in O(1). Thus, I suppose you have to somehow precompute this average and store it. So, i would store in a node the following:

- x value
- y value
- average around

Note that `update(x,y)`

runs strictly in O(log n) if you have this structure: If you update element `x`

to height `y`

, you have to consider the `2log(n)`

neighbours whose average is affected by this change. You can recalculate each of these averages in O(1):

Let's assume, `update(x,y)`

affects an element `b`

, whose average is to be updated as well. Then, you simply multiply `average(b)`

by the number of neighbours (`2log(n)`

as stated above). Then, we subtract the old `y-value`

of element `x`

, and add the new (updated) `y`

-value of `x`

. After that, we divide by `2 log(n)`

. This ensures that we now have the updated average for element `b`

. This involved only some calculations and can thus be done in O(1). Since we have `2log n`

neighbours, `update`

runs in `O(2log n)=O(log n)`

.

When you insert a new element `e`

, you have to update the average of all elements affected by this new element `e`

. This is *essentially* done like in the `update`

routine. However, you have to be careful when `log n`

(or precisely `floor(log n)`

) changes its value. If `floor(log n)`

stays the same (which it will, in most cases), then you can just do the analogue things described in `update`

, however you will have to "remove" the height of one element, and "add" the height of the newly added element. In these "good" cases, run time is again strictly `O(log n)`

.

Now, when `floor(log n)`

is changing (incrementing by 1), you have to perform an update for *all* elements. That is, you have to do an O(1) operation for `n`

elements, resulting in a running time of `O(n)`

. However, it is very seldom the case that `floor(log n)`

increments by 1 (you need to double the value of `n`

to increment `floor(log n)`

by 1 - assuming we are talking about `log`

to base 2, which is not uncommon in computer science). We denote this time by `c*n`

or simply `cn`

.

Thus, let's consider a sequence of inserts: The first insert needs an update: `c*1`

, the second insert needs an update: `2*c`

. The next time an expensive insert occurs, is the fourth insert: `4*c`

, then the eight insert: `8c`

, the sixtenth insert: `16*c`

. The distance between two expensive inserts is doubled each time:

```
insert # 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 ..
cost 1c 2c 1 4c 1 1 1 8c 1 1 1 1 1 1 1 16c 1 1 ..
```

Since no `remove`

is required, we can continue with our analysis without any "special cases" and consider only a sequence of inserts. You see that most inserts cost 1, while few are expensive (1,2,4,8,16,32,...). So, if we have `m`

inserts in total, we have roughly `log m`

expensive inserts, and roughly `m-log m`

cheap inserts. For simplicity, we assume simply `m`

cheap inserts.

Then, we can compute the cost for `m`

inserts:

```
log m
----
\ i
m*1 + / 2
----
i=0
```

`m*1`

counts the cheap operations, the sum the expensive ones. It can be shown that the whole thing is at most `4m`

(in fact you can even show better estimates quite easily, but for us this suffices).

Thus, we see that `m`

insert operations cost at most `4m`

in total. Thus, a single insert operation costs at most `4m/m=4`

, thus is `O(1)`

amortized.

So, there are 2 things left:

- How to store all the entries?
- How to initialize the data structure in O(n)?

I suggest storing all entries in a skip-list, or some tree that guarantees logarithmic search-operations (otherwise, insert and update require more than O(log n) for finding the correct position). Note that the data structure must be buildable in O(n) - which should be no big problem assuming the elements are sorted according to their x-coordinate.

To initialize the data structure in O(n), I suggest beginning at element at index `log n`

and computing its average the simple way (sum up, the `2log n`

neighbours, divide by `2 log n`

).

Then you move the index one further and compute `average(index)`

using `average(index-1)`

: `average(index)=average(index-1)*log(n)-y(index-1-log(n))+y(index+log(n))`

.

That is, we follow a similar approach as in update. This means that computing the averages costs `O(log n + n*1)=O(n)`

. Thus, we can compute the averages in O(n).

Note that you have to take some details into account which I haven't described here (e.g. border cases: element at index 1 does not have `log(n)`

neighbours on both sides - how do you proceed with this?).