I have four 2-bit bitfields stored in a single byte. Each bitfield can thus represent 0, 1, 2, or 3. For example, here are the 4 possible values where the first 3 bitfields are zero:

```
00 00 00 00 = 0 0 0 0
00 00 00 01 = 0 0 0 1
00 00 00 10 = 0 0 0 2
00 00 00 11 = 0 0 0 3
```

I'd like an efficient way to sum the four bitfields. For example:

```
11 10 01 00 = 3 + 2 + 1 + 0 = 6
```

A 8-bit lookup table on a modern Intel x64 CPU takes 4 cycles to return an answer from L1. It seems like there should be some way to calculate the answer faster than that. 3 cycles gives about room for 6-12 simple bit operations. As a starter, the straightforward mask and shift look like it will take 5 cycles on Sandy Bridge:

Assuming the bit fields are: `d c b a`

, and that mask is: `00 00 00 11`

Clarifying with help from Ira: This presumes that `a`

, `b`

, `c`

, and `d`

are identical and have all been set to the initial `byte`

. Oddly, I think I can do this for free. Since I can do 2 loads per cycle, instead of loading `byte`

once, I can just load it four times: `a`

and `d`

on the first cycle, `b`

and `c`

on the second. The second two loads will be delayed one cycle, but I don't need them until the second cycle. The splits below represent how things should break into separate cycles.

```
a = *byte
d = *byte
b = *byte
c = *byte
latency
latency
a &= mask
d >>= 6
b >>= 2
c >>= 4
a += d
b &= mask
c &= mask
b += c
a += b
```

A different encoding for the bitfields to make the logic easier would actually be fine, so long as it fits within a single byte and maps one-to-one with this scheme somehow. Dropping to assembly is also fine. Current target is Sandy Bridge, but targetting Haswell or beyond is fine too.

Application and motivation: I'm trying to make an open-source variable bit decompression routine go faster. Each bitfield represents the compressed length of each of the four integers that follow. I need the sum to know how many bytes I need to jump to get to the next group of four. The current loop takes 10 cycles, with 5 of that coming the lookup I'm trying to avoid. Shaving off a cycle would be ~10% improvement.

Edit: Originally I said "8 cycles", but as Evgeny points out below I was wrong. As Evgeny points out, the only time there is an indirect 4 cycle load is if loading from the first 2K of system memory without using an index register. A correct list of latencies can be found in the Intel Architecture Optimization Manual Section 2.12

```
> Data Type (Base + Offset) > 2048 (Base + Offset) < 2048
> Base + Index [+ Offset]
> Integer 5 cycles 4 cycles
> MMX, SSE, 128-bit AVX 6 cycles 5 cycles
> X87 7 cycles 6 cycles
> 256-bit AVX 7 cycles 7 cycles
```

Edit: I think this is how Ira's solution below would break into cycles. I think it also takes 5 cycles of work post load.

```
a = *byte
b = *byte
latency
latency
latency
a &= 0x33
b >>= 2
b &= 0x33
c = a
a += b
c += b
a &= 7
c >>= 4
a += c
```

afteryou've computed the sum, but the point is you have to test to leave the loop. So, maybe the problem is finding the sum, knowing it is nonzero. – Ira Baxter Jul 28 '13 at 23:18