If you're not too concerned with precision then this inner loop should give you twice the compute throughput compared to the more accurate algorithm:

```
for (i=0; i<640; i+= 32)
{
uint8x16x2_t a, b;
uint8x16_t c, d;
/* load upper row, splitting even and odd pixels into a.val[0]
* and a.val[1] respectively. */
a = vld2q_u8(src1);
/* as above, but for lower row */
b = vld2q_u8(src2);
/* compute average of even and odd pixel pairs for upper row */
c = vrhaddq_u8(a.val[0], a.val[1]);
/* compute average of even and odd pixel pairs for lower row */
d = vrhaddq_u8(b.val[0], b.val[1]);
/* compute average of upper and lower rows, and store result */
vst1q_u8(dest, vrhaddq_u8(c, d));
src1+=32;
src2+=32;
dest+=16;
}
```

It works by using the `vhadd`

operation, which has a result the same size as the input. This way you don't have to shift the final sum back down to 8-bit, and all of the arithmetic throughout is eight-bit, which means you can perform twice as many operations per instruction.

However it is less accurate, because the intermediate sum is quantised, and GCC 4.7 does a terrible job of generating code. GCC 4.8 does just fine.

The whole operation has a good chance of being I/O bound, though. The loop should be unrolled to maximise separation between loads and arithmetic, and `__builtin_prefetch()`

(or `PLD`

) should be used to hoist the incoming data into caches before it's needed.

Bestneeds to be defined. Fastest, highest quality, minimum size, etc? Forhighest quality, there are different tradeoffs in image reduction. Preserving low frequency content is important is some cases and high frequency in others. What is8-bit? A gray scale, colour mapped, or something else? – artless noise Jul 23 '13 at 17:20