I'm trying to implement a color conversion Func that outputs to 3 separate buffers. The rgb_to_ycocg function has a 4x8bit channel interleaved buffer (BGRA) and 3 output buffers (Y, Co and Cg) which are each 16bit values. Currently, I'm using this piece of code:
void rgb_to_ycocg(const uint8_t *pSrc, int32_t srcStep, int16_t *pDst[3], int32_t dstStep[3], int width, int height)
{
Buffer<uint8_t> inRgb((uint8_t *)pSrc, 4, width, height);
Buffer<int16_t> outY(pDst[0], width, height);
Buffer<int16_t> outCo(pDst[1], width, height);
Buffer<int16_t> outCg(pDst[2], width, height);
Var x, y, c;
Func calcY, calcCo, calcCg, inRgb16;
inRgb16(c, x, y) = cast<int16_t>(inRgb(c, x, y));
calcY(x, y) = (inRgb16(0, x, y) + ((inRgb16(2, x, y) - inRgb16(0, x, y)) >> 1)) + ((inRgb16(1, x, y) - (inRgb16(0, x, y) + ((inRgb16(2, x, y) - inRgb16(0, x, y)) >> 1))) >> 1);
calcCo(x, y) = inRgb16(2, x, y) - inRgb16(0, x, y);
calcCg(x, y) = inRgb16(1, x, y) - (inRgb16(0, x, y) + ((inRgb16(2, x, y) - inRgb16(0, x, y)) >> 1));
Pipeline p =Pipeline({calcY, calcCo, calcCg});
p.vectorize(x, 16).parallel(y);
p.realize({ outY, outCo, outCg });
}
The issue is, I'm getting poor performance compared to the reference implementation (basic for loops in c). I understand I need to try better scheduling, but I think I'm doing something wrong in terms of input/output buffers. I've seen the tutorials and tried to come up with a way to output to multiple buffers. Using a Pipeline was the only way I could find. Would I be better off making 3 Funcs and calling them separately? Is this a correct use of the Pipeline class?
