For the classic interview question "How do you perform integer multiplication without the multiplication operator?", the easiest answer is, of course, the following linear-time algorithm in C:

```
int mult(int multiplicand, int multiplier)
{
for (int i = 1; i < multiplier; i++)
{
multiplicand += multiplicand;
}
return multiplicand;
}
```

Of course, there is a faster algorithm. If we take advantage of the property that bit shifting to the left is equivalent to multiplying by 2 to the power of the number of bits shifted, we can bit-shift up to the nearest power of 2, and use our previous algorithm to add up from there. So, our code would now look something like this:

```
#include <math.h>
int log2( double n )
{
return log(n) / log(2);
}
int mult(int multiplicand, int multiplier)
{
int nearest_power = 2 ^ (floor(log2(multiplier)));
multiplicand << nearest_power;
for (int i = nearest_power; i < multiplier; i++)
{
multiplicand += multiplicand;
}
return multiplicand;
}
```

I'm having trouble determining what the time complexity of this algorithm is. I don't believe that `O(n - 2^(floor(log2(n))))`

is the correct way to express this, although (I think?) it's technically correct. Can anyone provide some insight on this?

`multiplicant * pow(2,multiplier)`

, no? – Jens Gustedt Mar 23 '12 at 18:35`log2()`

as expensive, as multiplication by shifting? – gbulmer Mar 23 '12 at 18:51