```
inline uint8_t pack8bools(bool* a)
{
uint64_t t;
memcpy(&t, a, sizeof t); // t = *((uint64_t*)a) without aliasing
return 0x8040201008040201*t >> 56;
}
void unpack8bools(uint8_t b, bool* a)
{
auto MAGIC = 0x8040201008040201ULL;
auto MASK = 0x8080808080808080ULL;
uint64_t t = ((MAGIC*b) & MASK) >> 7;
memcpy(a, &t, sizeof t); // *(uint64_t*)a = t;
}
```

Assuming `sizeof(bool) == 1`

Of course you may need to make sure that the bool array is correctly 8-byte aligned to avoid performance shoot down and/or UB

## How they work

Suppose we have 8 bools `b[0]`

to `b[7]`

whose least significant bits are named a-h respectively that we want to pack into a single byte. Treating those 8 consecutive `bool`

s as one 64-bit word and load them we'll get the bits in reversed order in a little-endian machine. Now we'll do a multiplication (here dots are zero bits)

```
| b7 || b6 || b4 || b4 || b3 || b2 || b1 || b0 |
.......h.......g.......f.......e.......d.......c.......b.......a
× 1000000001000000001000000001000000001000000001000000001000000001
────────────────────────────────────────────────────────────────
↑......h.↑.....g..↑....f...↑...e....↑..d.....↑.c......↑b.......a
↑.....g..↑....f...↑...e....↑..d.....↑.c......↑b.......a
↑....f...↑...e....↑..d.....↑.c......↑b.......a
+ ↑...e....↑..d.....↑.c......↑b.......a
↑..d.....↑.c......↑b.......a
↑.c......↑b.......a
↑b.......a
a
────────────────────────────────────────────────────────────────
= abcdefghxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
```

The arrows are added so it's easier to see the position of the set bits in the magic number. At this point 8 least significant bits has been put in the top byte, we'll just need to mask the remaining bits out

So the magic number for packing would be `0b1000000001000000001000000001000000001000000001000000001000000001`

or `0x8040201008040201`

. If you're on a big endian machine you'll need to use the magic number `0x0102040810204080`

which is calculated in a similar manner

For unpacking we can do a similar multiplication

```
| b7 || b6 || b4 || b4 || b3 || b2 || b1 || b0 |
abcdefgh
× 1000000001000000001000000001000000001000000001000000001000000001
────────────────────────────────────────────────────────────────
= h0abcdefgh0abcdefgh0abcdefgh0abcdefgh0abcdefgh0abcdefgh0abcdefgh
& 1000000010000000100000001000000010000000100000001000000010000000
────────────────────────────────────────────────────────────────
= h0000000g0000000f0000000e0000000d0000000c0000000b0000000a0000000
```

After multiplying we have the needed bits at the most significant positions, so we need to mask out irrelevant bits and shift the remaining ones to the least significant positions. The output will be the bytes contain a to h in little endian.

## The efficient way

On newer x86 CPUs with BMI2 there are PEXT and PDEP instructions for this purpose. The `pack8bools`

function above can be replaced with

```
_pext_u64(*((uint64_t*)a), 0x0101010101010101ULL);
```

And the `unpack8bools`

function can be implemented as

```
_pdep_u64(b, 0x0101010101010101ULL);
```

Unfortunately those instructions are very slow on AMD so you may need to compare with the multiplication method above to see which is better