Have you considered using a linked list plus the current length and sum? For each operation you can maintain the current average with constant extra work (you know the length of the list and the sum, and all operations change those two values in a constant way).

The only non-constant operation would be adding a constant to an arbitrary prefix, which would take time proportional to the size of the prefix since you'd need to adjust each number.

To make all operations constant (amortized) constant requires more work. Instead of using a doubly-linked list, back the array with a stack. Each slot `i`

in the array now contains both the number at `i`

and the constant that was to be added to every element up to `i`

. (Note that if you say "add 3 to every element up to element 11," slot 11 would contain the number 3 but slots 0-10 would be empty.) Now every operation is as it was before, except that appending a new element involves the standard array-doubling trick, and when you pop the last element off the end of the queue you need to (a) add in the constant at that slot, and (b) add the constant value from slot `i`

to the constant for slot `i-1`

. So for your example:

Append 0: `[(0,0)], sum 0, length 1`

Append 5: `([(0,0),(5,0)], sum 5, length 2`

Append 6: `[(0,0),(5,0),(6,0)], sum 11, length 3`

Add 3 to the first 2 elements in the sequence: `[(0,0),(5,3),(6,0)], sum 17, length 3`

Retrieve the average 5.66

Remove the last element `[(0,0),(5,3)], sum 11, length 2`

Retrieve the average 5.5

Remove the last element `[(0,3)], sum 3, length 1`

Here's some Java code that illustrates the idea perhaps more clearly:

```
class Averager {
private int sum;
private ArrayList<Integer> elements = new ArrayList<Integer>();
private ArrayList<Integer> addedConstants = new ArrayList<Integer>();
public void addElement(int i) {
elements.add(i);
addedConstants.add(0);
sum += i;
}
public void addToPrefix(int k, int upto) {
addedConstants.set(upto, addedConstants.get(upto) + k);
sum += k * (upto + 1);
// Note: assumes prefix exists; in real code handle an error
}
public int pop() {
int lastIndex = addedConstants.length() - 1;
int constantToAdd = addedConstants.get(lastIndex);
int valueToReturn = elements.get(lastIndex);
addedConstants.set(
lastIndex-1,
addedConstants.get(lastIndex-1) + constantToAdd);
sum -= valueToReturn;
elements.remove(lastIndex);
addedConstants.remove(lastIndex);
return valueToReturn + constantToAdd;
// Again you need to handle errors here as well, particularly where the stack
// is already empty or has exactly one element
}
public double average() {
return ((double) sum) / elements.length();
}
}
```