Faster alpha blending using a lookup table?

I have made a lookup table that allows you to blend two single-byte channels (256 colors per channel) using a single-byte alpha channel using no floating point values (hence no float to int conversions). Each index in the lookup table corresponds to the value of 256ths of a channel, as related to an alpha value.

In all, to fully calculate a 3-channel RGB blend, it would require two lookups into the array per channel, plus an addition. This is a total of 6 lookups and 3 additions. In the example below, I split the colors into separate values for ease of demonstration. This example shows how to blend three channels, R G and B by an alpha value ranging from 0 to 256.

``````BYTE r1, r2, rDest;
BYTE g1, g2, gDest;
BYTE b1, b2, bDest;

BYTE av; // Alpha value
BYTE rem = 255 - av; // Remaining fraction

rDest = _lookup[r1][rem] + _lookup[r2][av];
gDest = _lookup[g1][rem] + _lookup[g2][av];
bDest = _lookup[b1][rem] + _lookup[b2][av];
``````

It works great. Precise as you can get using 256 color channels. In fact, you would get the same exact values using the actual floating point calculations. The lookup table was calculated using doubles to begin with. The lookup table is too big to fit in this post (65536 bytes). (If you would like a copy of it, email me at ten.turtle.toes@gmail.com, but don't expect a reply until tomorrow because I am going to sleep now.)

So... what do you think? Is it worth it or not?

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It's a very bad idea. Youll trash the cache and generally be punished hard by doing this silly thing. Compute it, and if possible do it in parallell using SSE/MMX etc. Or even better, use the GPU. – stefan Mar 25 '11 at 21:38
You could generate the table at compile time using templates or maybe at runtime during startup, thus avoiding the huuge file. – ronag Mar 25 '11 at 21:40
And I second the comment about cache trashing. – ronag Mar 25 '11 at 21:40
I am still having trouble wrapping my head around the XMM registers; they are intended for floating point but used for integer calculations? can you recommend any material to learn about them in detail? – TurtleToes Mar 25 '11 at 21:43
In the REAL world calculating it will be much faster than looking it up in memory (on a desktop PC anyway). If you make a microbenchmark that sits there and pounds on it with the same memory addresses, you will fool yourself into believing that the table is better because you'll end up caching more than you really would. Keep in mind that the core runs at LEAST 10x faster than the motherboard interface. A lot of work can get done in the time that it takes for one bus cycle to occur. The bad thing about giant tables: they push the real data out of cache. – doug65536 Jan 7 '13 at 18:50

I would be interested in seeing some benchmarks.

There is an algorithm that can do perfect alpha blending without any floating point calculations or lookup tables. You can find more info in the following document (the algorithm and code is described at the end)

I also did an SSE implementation of this long ago, if you are interested...

``````void PreOver_SSE2(void* dest, const void* source1, const void* source2, size_t size)
{
static const size_t STRIDE = sizeof(__m128i)*4;
static const u32 PSD = 64;

static const __m128i round = _mm_set1_epi16(128);
static const __m128i lomask = _mm_set1_epi32(0x00FF00FF);

assert(source1 != NULL && source2 != NULL && dest != NULL);
assert(size % STRIDE == 0);

const __m128i* source128_1 = reinterpret_cast<const __m128i*>(source1);
const __m128i* source128_2 = reinterpret_cast<const __m128i*>(source2);
__m128i*       dest128 = reinterpret_cast<__m128i*>(dest);

__m128i d, s, a, rb, ag, t;

for(size_t k = 0, length = size/STRIDE; k < length; ++k)
{
// TODO: put prefetch between calculations?(R.N)
_mm_prefetch(reinterpret_cast<const s8*>(source128_1+PSD), _MM_HINT_NTA);
_mm_prefetch(reinterpret_cast<const s8*>(source128_2+PSD), _MM_HINT_NTA);

// work on entire cacheline before next prefetch
for(int n = 0; n < 4; ++n, ++dest128, ++source128_1, ++source128_2)
{
// TODO: assembly optimization use PSHUFD on moves before calculations, lower latency than MOVDQA (R.N) http://software.intel.com/en-us/articles/fast-simd-integer-move-for-the-intel-pentiumr-4-processor/

// TODO: load entire cacheline at the same time? are there enough registers? 32 bit mode (special compile for 64bit?) (R.N)
s = _mm_load_si128(source128_1);        // AABGGRR
d = _mm_load_si128(source128_2);        // AABGGRR

// PRELERP(S, D) = S+D - ((S*D[A]+0x80)>>8)+(S*D[A]+0x80))>>8
// T = S*D[A]+0x80 => PRELERP(S,D) = S+D - ((T>>8)+T)>>8

// set alpha to lo16 from dest_
a = _mm_srli_epi32(d, 24);          // 000000AA
rb = _mm_slli_epi32(a, 16);         // 00AA0000
a = _mm_or_si128(rb, a);            // 00AA00AA

rb = _mm_and_si128(lomask, s);      // 00BB00RR
rb = _mm_mullo_epi16(rb, a);        // BBBBRRRR
rb = _mm_add_epi16(rb, round);      // BBBBRRRR
t = _mm_srli_epi16(rb, 8);
t = _mm_add_epi16(t, rb);
rb = _mm_srli_epi16(t, 8);          // 00BB00RR

ag = _mm_srli_epi16(s, 8);          // 00AA00GG
ag = _mm_mullo_epi16(ag, a);        // AAAAGGGG
ag = _mm_add_epi16(ag, round);
t = _mm_srli_epi16(ag, 8);
t = _mm_add_epi16(t, ag);
ag = _mm_andnot_si128(lomask, t);   // AA00GG00

rb = _mm_or_si128(rb, ag);          // AABGGRR      pack

rb = _mm_sub_epi8(s, rb);           // sub S-[(D[A]*S)/255]
d = _mm_add_epi8(d, rb);            // add D+[S-(D[A]*S)/255]

_mm_stream_si128(dest128, d);
}
}
_mm_mfence();   //ensure last WC buffers get flushed to memory
}
``````
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nice... thank you; now i can get rid of the giant lookup table – TurtleToes Mar 25 '11 at 21:38

Today's processors can do a lot of calculation in the time it takes to get one value from memory, especially if it's not in cache. That makes it especially important to benchmark possible solutions, because you can't easily reason what the result will be.

I don't know why you're concerned about floating point conversions, this can all be done as integers.

``````BYTE r1, r2, rDest;
BYTE g1, g2, gDest;
BYTE b1, b2, bDest;

BYTE av; // Alpha value BYTE
rem = 255 - av; // Remaining fraction

rDest = (r1*rem + r2*av) / 255;
gDest = (g1*rem + g2*av) / 255;
bDest = (b1*rem + b2*av) / 255;
``````

If you want to get really clever, you can replace the divide with a multiply followed by a right-shift.

Edit: Here's the version using a right-shift. Adding a constant might reduce any truncation errors, but I'll leave that as an exercise for the reader.

``````BYTE r1, r2, rDest;
BYTE g1, g2, gDest;
BYTE b1, b2, bDest;

BYTE av; // Alpha value BYTE
int aMult = 0x10000 * av / 255;
rem = 0x10000 - aMult; // Remaining fraction

rDest = (r1*rem + r2*aMult) >> 16;
gDest = (g1*rem + g2*aMult) >> 16;
bDest = (b1*rem + b2*aMult) >> 16;
``````
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Mixing colors is computationally trivial. I would be surprised if this yielded a significant benefit, but as always, you must first prove that this calculation is a bottleneck in performance in the first place. And I would suggest that a better solution is to use hardware accelerated blending.

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not all platforms and machines support hardware blending; and conversion from float to int kills performance, even using the fistp instruction. Fixed point is even worse. This only requires memory lookups and additions. However, I am wondering if the lookups would be faster than the float-to-int conversion. – TurtleToes Mar 25 '11 at 21:34