## The Maths

When you divide a positive integer `n`

by 16, you get a positive integer quotient `k`

and a remainder `c < 16`

:

```
(n/16) = k + (c/16).
```

(Or simply apply the Euclidan algorithm.) The question asks for multiplication by `3/16`

, so multiply by 3

```
(n/16) * 3 = 3k + (c/16) * 3.
```

The number `k`

is an integer, so the part `3k`

is still a whole number. However, `int`

arithmetic rounds down, so the second term may lose precision if you divide first, And since `c < 16`

, you can safely multiply first without overflowing (assuming `sizeof(int) >= 7`

). So the algorithm design can be

```
(3n/16) = 3k + (3c/16).
```

## The design

- The integer
`k`

is simply `n/16`

rounded down towards 0. So `k`

can be found by applying a single `AND`

operation. Two further operations will give `3k`

. Operation count: 3.
- The remainder
`c`

can also be found using an `AND`

operation (with the missing bits). Multiplication by 3 uses two more operations. And shifts finishes the division. Operation count: 4.
- Add them together gives you the final answer.

Total operation count: 8.

## Negatives

The above algorithm uses shift operations. It may not work well on negatives. However, assuming two's complement, the sign of `n`

is stored in a sign bit. It can be removed beforing applying the algorithm and reapplied on the answer.

- To find and store the sign of
`n`

, a single `AND`

is sufficient.
- To remove this sign,
`OR`

can be used.
- Apply the above algorithm.
- To restore the sign bit, Use a final
`OR`

operation on the algorithm output with the stored sign bit.

This brings the final operation count up to 11.

`eluding`

. – ajay Feb 27 '14 at 18:51`int(3*15/16) = 2`

, but`int(15/16)*3 = 0`

. – Nabla Feb 27 '14 at 18:57