Consider two vectors, **A** and **B**, of size *n*, 7 <= *n* <= 23. Both **A** and **B** consists of -1s, 0s and 1s only.

I need a fast algorithm which computes the inner product of **A** and **B**.

So far I've thought of storing the signs and values in separate `uint32_t`

s using the following encoding:

- sign 0, value 0 → 0
- sign 0, value 1 → 1
- sign 1, value 1 → -1.

The C++ implementation I've thought of looks like the following:

```
struct ternary_vector {
uint32_t sign, value;
};
int inner_product(const ternary_vector & a, const ternary_vector & b) {
uint32_t psign = a.sign ^ b.sign;
uint32_t pvalue = a.value & b.value;
psign &= pvalue;
pvalue ^= psign;
return __builtin_popcount(pvalue) - __builtin_popcount(psign);
}
```

This works reasonably well, but I'm not sure whether it is possible to do it better. Any comment on the matter is highly appreciated.

`uint32_t`

variables. Each vector element consumes one bit of`sign`

and one bit of`value`

. Remember that his vectors have a maximum length of 23. – rob mayoff Nov 1 '13 at 18:08