You are essentially trying to solve the problem

2^{i} x = w

and then finding the smallest integer greater than i. Solving, we get

2^{i} = w / x

i = log_{2} (w / x)

So one approach would be to compute this value explicitly and then take the ceiling. Of course, you'd have to watch out for numerical instability when doing this. For example, if you are using `float`

s to encode the values and then let w = 8,000,001 and x = 1,000,000, you will end up getting the wrong answer (3 instead of 4). If you use `double`

s to hold the value, you will also get the wrong answer when x = 1 and w = 536870912 (reporting 30 instead of 29, since 1 x 2^{29} = 536870912, but due to inaccuracies in the double the answer is erroneously rounded up to 30). It looks like we'll have to switch to a different approach.

Let's revisit your initial solution of just doubling the value of x until it exceeds w should be perfectly fine here. The maximum number of times you can double x until it reaches w is given by log_{2} (w/x), and since w/x is at most one billion, this iterates at most log_{2} 10^{9} times, which is about thirty times each. Doing thirty iterations of a multiply by two is probably going to be extremely fast. More generally, if the upper bound of w / x is U, then this will take at most O(log U) time to complete. If you have k (x, w) pairs to check, this takes time O(k log U).

If you're not satisfied with doing this, though, there's another very fast algorithm you could try. Essentially, you want to compute log_{2} w/x. You could start off by creating a table that lists all powers of two along with their logarithms. For example, your table might look like

```
T[1] = 0
T[2] = 1
T[4] = 2
T[8] = 3
...
```

You could then compute w/x, then do a binary search to figure out where in which range the value lies. The upper bound of this range is then the number of times the ball must bounce. This means that if you have k different pairs to inspect, and if you know that the maximum ratio of w/x is U, creating this table takes O(log U) time and each query then takes time proportional to the log of the size of the table, which is O(log log U). The overall runtime is then O(log U + k log log U), which is extremely good. Given that you're dealing with at most one million problem instances and that U is one billion, k log log U is just under five million, and log U is about thirty.

Finally, if you're willing to do some perversely awful stuff with bitwise hackery, since you know for a fact that w/x fits into a 32-bit word, you can use **this bitwise trickery with IEEE doubles** to compute the logarithm in a very small number of machine operations. This would probably be faster than the above two approaches, though I can't necessarily guarantee it.

Hope this helps!

naturallogarithms would be too sloooow :-) – Henning Makholm Aug 24 '11 at 23:58