Some preliminary remarks:

- The statement is true for when
*n* is non-zero. There must be at least one 1-bit.
- A bitwise AND-operation copies the bits that are
*the same* in both operands (`1&1==1`

and `0&0==0`

), and produces a zero bit when the corresponding bits are *different* (`1&0==0`

and `0&1==0`

).

Subtraction of 1 is easy when *n* is odd: you just clear that final 1-bit and you're done. When *n* is not odd, you need to "borrow" from an adjacent bit, which leads to a potential cascade of borrowing, until you find a 1-bit you can borrow from (See American method for manual subtraction on Wikipedia). This means that starting from the right (at the least significant bit of *n*), you flip bits one by one, until the first 1-bit is encountered, which is also flipped.

So in a subtraction you flip a group of bits which includes exactly *one* 1-bit, which by consequence is the only one that gets flipped to a 0-bit.

As the bit-wise AND-operation on *n* will produce a 0 for every bit that was flipped for getting *n-1*, but will keep any other bit of *n* as it was before, it actually clears *one* 1-bit of *n*.

From this follows also that the bit that is cleared, is always the least significant 1-bit in *n*.