Here's a bit of math: naively you can describe each element with two bits, so you could pack four elements into one byte and get decent random access. Four elements have 3^{4} = 81 states, so that's a usage of 81 / 256 ≈ 32%. If you want to stay on a byte boundary, you could look for the nearest power of three that fits into 2^{8}, which is 3^{5} = 243. In other words, if you one one byte to enumerate all possible states of five consecutive elements, you have a space efficiency of 243 / 256 ≈ 95%.

It makes no sense to do this packing in memory unless you're processing *vast* amounts of data and cannot fit everything into physical memory *and* can't partition your algorithm to run on smaller chunks at a time. For efficient computation, you should at the very least use a single byte (`uint8_t`

), or even a machine word (`uint8fast_t`

) to store your data. It's only when you serialize your data to disk and find that your terabytes of data are too expensive for your RAID-50 storage that you may wish to consider a complicated packing scheme. (Though then again you could just pipe your data through `gzip`

, which basically does all that for you.)

Here's a rudimentary decoding algorithm for getting the five elements out of a byte:

```
unsigned int get_tristate(unsigned char const n, size_t const i)
{
/* Conditions: n in [0, 243)
i in [0, 5)
Returns: the i^th trivalent element encoded in n, in [0, 2).
*/
static unsigned int const powers[] = { 1, 3, 9, 27, 81, 243 };
return (n / powers[i]) % powers[i + 1];
}
```

eightbits on a million elements, that's like one megabyte. Unless you're programming for a washing machine (from the 1970s), I'd say leave this alone and do something more important. – Kerrek SB Feb 16 '13 at 10:24`uint8_t`

and bitmasks? (Here I have to disappoint you:`bool`

is just typedeffed to`char`

or`int`

in most implementations...) – user529758 Feb 16 '13 at 10:28