Having stumbled across this relatively old post entirely by accident, I thought it pertinent to elaborate on Volte's previous conjecture for the benefit of inexperienced readers.

Firstly, the signed range of a 128-bit number is -2^{127} to 2^{127}-1 and not -2^{127} to 2^{127} as originally stipulated.

Secondly, due to the cyclic nature of finite arithmetic the largest required differential between two 128-bit numbers is -2^{127} to 2^{127}-1, which has a storage prerequisite of 128-bits, not 129. Although (2^{127}-1) - (-2^{127}) = 2^{128}-1 which is clearly greater than our maximum 2^{127}-1 positive integer, arithmetic overflow always ensures that the nearest distance between any two *n*-bit numbers always falls within the range 0 to 2^{n}-1 and thus implicitly -2^{n-1} to 2^{n-1}-1.

In order to clarify, let us first examine how a hypothetical 3-bit processor would implement binary addition. As an example, consider the following table which depicts the absolute unsigned range of a 3-bit integer.

0 = 000b

1 = 001b

2 = 010b

3 = 011b

4 = 100b

5 = 101b

6 = 110b

7 = 111b ---> [Cycles back to 000b on overflow]

From the above table it is readily apparent that:

001b(1) + 010b(2) = 011b(3)

It is also apparent that adding any of these numbers with its numeric complement always yields 2^{n}-1:

010b(2) + 101b([complement of 2] = 5) = 111b(7) = (2^{3}-1)

Due to the cyclic overflow which occurs when the addition of two *n*-bit numbers results in an (*n*+1)-bit result, it therefore follows that adding any of these numbers with its numeric complement + 1 will always yield 0:

010b(2) + 110b([complement of 2] + 1) = 000b(0)

Thus we can say that [complement of *n*] + 1 = -*n*, so that *n* + [complement of *n*] + 1 = *n* + (-*n*) = 0. Furthermore, if we now know that *n* + [complement of *n*] + 1 = 0, then *n* + [complement of *n* - *x*] + 1 must = *n* - (*n*-*x*) = *x*.

Applying this to our original 3-bit table yields:

0 = 000b = [complement of 0] + 1 = 0

1 = 001b = [complement of 7] + 1 = -7

2 = 010b = [complement of 6] + 1 = -6

3 = 011b = [complement of 5] + 1 = -5

4 = 100b = [complement of 4] + 1 = -4

5 = 101b = [complement of 3] + 1 = -3

6 = 110b = [complement of 2] + 1 = -2

7 = 111b = [complement of 1] + 1 = -1 ---> [Cycles back to 000b on overflow]

Whether the representational abstraction is positive, negative or a combination of both as implied with signed twos-complement arithmetic, we now have 2^{n} *n*-bit patterns which can seamlessly serve both positive 0 to 2^{n}-1 and negative 0 to -(2^{n})-1 ranges as and when required. In point of fact, all modern processors employ just such a system in order to implement common ALU circuitry for both addition and subtraction operations. When a CPU encounters an `i1 - i2`

subtraction instruction, it internally performs a [complement + 1] operation on `i2`

and subsequently processes the operands through the addition circuitry in order to compute `i1`

+ [complement of `i2`

] + 1. With the exception of an additional carry/sign XOR-gated overflow flag, both signed and unsigned addition, and by implication subtraction, are each implicit.

If we apply the above table to the input sequence [-2^{n-1}, 2^{n-1}-1, -2^{n-1}] as presented in Volte's original reply, we are now able to compute the following n-bit differentials:

diff #1:

(2^{n-1}-1) - (-2^{n-1}) =

3 - (-4) = 3 + 4 =

(-1) = 7 = 111b

diff #2:

(-2^{n-1}) - (2^{n-1}-1) =

(-4) - 3 = (-4) + (5) =

(-7) = 1 = 001b

Starting with our seed -2^{n-1}, we are now able to reproduce the original input sequence by applying each of the above differentials sequentially:

(-2^{n-1}) + (diff #1) =

(-4) + 7 = 3 =

2^{n-1}-1

(2^{n-1}-1) + (diff #2) =

3 + (-7) = (-4) =

-2^{n-1}

You may of course wish to adopt a more philosophical approach to this problem and conjecture as to why 2^{n} cyclically-sequential numbers would require more than 2^{n} cyclically-sequential differentials?

Taliadon.