# Time complexity measured as a function of the number of bits in the input?

I came across this problem that I am not sure how to solve:

Suppose A(.) is a subroutine that takes as input a number in binary, and takes linear time (that is, O(n), where n is the length (in bits) of the number). Consider the following piece of code, which starts with an n-bit number x.

``````while x>1:
call A(x)
x=x-1
``````

Assume that the subtraction takes O(n) time on an n-bit number.

(a) How many times does the inner loop iterate (as a function of n)? Leave your answer in big-O form.

(b) What is the overall running time (as a function of n), in big-O form?

My guess is that (a) is O(n^2) and (b) is O(n^3). Is this correct? The way I'm thinking about it is that the loop has to compute two steps each time it cycles through and it will cycle through x time each time subtracting 1 from n bits until x reaches 0. And for part b since A(.) takes time O(n) we multiply that with the time it takes to execute the loop and we then have the over all running time. Is my analysis correct?

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