**1a**. Expression `x & -x`

is a well-known "bit hack": it evaluates to a value that has all bits set to `0`

except for one bit: the lowest `1`

bit in the original value of `x`

. (Unless `x`

is `0`

, of course.)

For example, in unsigned arithmetic: `5 & -5 = 1`

, `4 & -4 = 4`

etc.

**2a**. This immediately tells us what function `f`

does: by using `|`

operator it combines all `1`

bits in `A`

and `B`

and then finds the lowest `1`

in the combined value. In other words, the result of `f`

is a word that contains a sole `1`

bit in the position of the lowest `1`

in `A`

or `B`

.

**1b**. Expression `(x + 1) & ~x`

is a well-known "bit hack": it evaluates to all bits set to `0`

except for the lowest `0`

bit in the original value of `x`

. The lowest `0`

bit in `x`

becomes the sole `1`

in the resultant value. (Unless `x`

is all-1-bits, of course.)

For example, in unsigned arithmetic: `(5 + 1) & -5 = 2`

, `(4 + 1) & -4 = 1`

etc.

**2b**. Expression `x - 1`

replaces all trailing `0`

bits in `x`

with `1`

and replaces the lowest `1`

in `x`

with `0`

, keeping the rest of `x`

unchanged. Operator `&`

combines all `0`

bits (just like operator `|`

combines all `1`

bits). That means that `(A - 1) & (B - 1)`

will have its lowest `0`

bit where the lowest `1`

bit was in `A`

or `B`

.

**3b**. Per 1b, `(C + 1) & ~C`

replaces that lowest `0`

with a lone `1`

, zeroing out everything else.

That means that `g`

does the same thing as `f`

. Both functions find and return the lowest `1`

bit between two input values. The result is always a power of 2 (or just 0). E.g. if at least one input value is odd, the result is 1.

I have an intuitive feeling (which could be wrong) that in order to build a formal transformation of one function into the other by applying additional operations to the existing expressions, one needs at least one of these functions to be "reversible" (is some semi-informal meaning of the term). Neither of these two looks sufficiently "reversible" to me...