# Bit checking in two's complement implemented only with subtraction and branch if less than zero

In two's complement representation, using only subtraction and "branch if less than zero" I am supposed to implement bit checking. No straightforward logical operations are allowed, unless they are implemented with these two instructions.

So lets say than I have an integer x such as `b(n-1) b(n-2) ... b(i) ... b(2) b(1) b(0)` where (i) indicates the i-th bit of the n-bit number.

I want to find a number y to subtract from x that gives the results:

• x-y >= 0 if b(i) = 1
• x-y < 0 if b(i) = 0

I have been banging my head for a couple of days now, and as a last result I came here for a couple of ideas/tips.

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This is not a practical problem. It looks more like a puzzle. Any modern programming language will support bit operations. –  Raymond Chen Mar 30 at 23:31
If x >= 2**n then x =x - n, idem for n-1, n-2 etc. Once at i, if x>=2**i, b(i) is set otherwise it is not. –  assylias Mar 30 at 23:38
I am working on a hypothetical one-instruction computer, I just made things simple so others can understand. –  Tolis Mar 30 at 23:39
@Tolis does my suggestion not work (it only uses comparisons and subtractions)? –  assylias Mar 30 at 23:48
@assylias Thanks for the help, by using yor algorithm and by using a temporary value you can "mirror" the bits of x. So you get an integer temp such as b(0) b(1) ... b(i) ... b(n-3) b(n-2) b(n-1). We are in two's complement so if temp is less than zero that means that b(0) is equal to 1. We then can shift temp to the left by doing temp = temp -(-temp). We continue n times. –  Tolis Apr 1 at 0:00