This is from the number theory chapter in CLRS.

We are asked to prove that binary "paper and pencil" long division `a/b`

with result `q`

and reminder `r`

does `O((1+lgq)lgb)`

operations on bits.

The way I see it is we do 1 subtraction of `b`

for each bit in `q`

. So assuming that subtracting `b`

does `lgb`

operations (one for each bit in `b`

), then we have a total of `O(lgblgq)`

operations, which is not what is requested.

If you take into account that the first subtraction operation you do might result in a 0 bit (for example, dividing 100b by 11b), then, OK, you can add 1 to `lgq`

to compensate for this subtraction. But... the same could be said of the subtraction itself - it can take `lgb`

operations or it can take `lg(b)+1`

operations depending on the numbers (in the 100b and 11b example, the second subtraction will be 100b-11b which takes 3 operations to complete).

So if we're factoring these cases, then the number of operations should be `O((1+lgb)(1+lgq))`

.

So the question is, how can you show that the division takes `O((1+lgq)lgb)`

operations?