I work on AVX2 and need to calculate 64-bit x64-bit -> 128-bit widening multiplication and got 64-bit high part in the fastest manner. Since AVX2 has not such an instruction, is it reasonable for me to use Karatsuba algorithm for efficiency and gaining speed?
No. On modern architectures the crossover at which Karatsuba beats schoolbook multiplication is usually somewhere between 8 and 24 machine words (e.g. between 512 and 1536 bits on x86_64). For fixed sizes, the threshold is at the smaller end of that range, and the new ADCX/ADOX instructions likely bring it in somewhat further for scalar code, but 64x64 is still too small to benefit from Karatsuba.
It's highly unlikely that AVX2 will beat the
mulx instruction which does 64bx64b to 128b in one instruction. There is one exception I'm aware of large multiplications using floating point FFT.
However, if you don't need exactly 64bx64b to 128b you could consider 53bx53b to 106b using double-double arithmetic.
To multiply four 53-bit numbers
b to get four 106-bit number only needs two instructions:
__m256 p = _mm256_mul_pd(a,b); __m256 e = _mm256_fmsub_pd(a,b,p);
This gives four 106-bit numbers in two instructions compared to one 128-bit number in one instruction using
It's hard to tell without trying, but it might me faster to just use the AMD64 MUL instruction, which supports 64x64=128 with the same throughput as most AVX2 instructions (but not vectorized). The drawback is that you need to load to regular registers if the operands were in YMM registers. That would give something like
LOAD + MUL + STORE for a single 64x64=128.
If you can vectorize Karatsuba in AVX2, try both AVX2 and
MUL and see which is faster. If you can't vectorize, single
MUL will probably be faster. If you can remove the load and store to regular registers, single
MUL will be definitely faster.
MUL and AVX2 instructions can have an operand in memory with the same throughput, and it may help to remove one load for