LOOP (Intel ref manual entry)
decrements ecx / rcx, and then jumps if non-zero. It's slow, but couldn't Intel have cheaply made it fast?
dec/jnz already macro-fuses into a single uop on Sandybridge-family; the only difference being that that sets flags.
loop on various microarchitectures, from Agner Fog's instruction tables:
K8/K10: 7 m-ops
Bulldozer-family/Ryzen: 1 m-op (same cost as macro-fused test-and-branch, or
P4: 4 uops (same as
P6 (PII/PIII): 8 uops
Pentium M, Core2: 11 uops
Nehalem: 6 uops. (11 for
loopne). Throughput = 4c (
loop) or 7c (
SnB-family: 7 uops. (11 for
loopne). Throughput = one per 5 cycles, as much of a bottleneck as keeping your loop counter in memory!
jecxzis only 2 uops with same throughput as regular
Silvermont: 7 uops
AMD Jaguar (low-power): 8 uops, 5c throughput
Via Nano3000: 2 uops
Couldn't the decoders just decode the same as
lea rcx, [rcx-1] /
jrcxz? That would be 3 uops. At least that would be the case with no address-size prefix, otherwise it has to use
ecx and truncate
EIP if the jump is taken; maybe the odd choice of address-size controlling the width of the decrement explains the many uops? (Fun fact:
rep-string instructions have the same behaviour with using
ecx with 32-bit address-size.)
Or better, just decode it as a fused dec-and-branch that doesn't set flags?
dec ecx /
jnz on SnB decodes to a single uop (which does set flags).
I know that real code doesn't use it (because it's been slow since at least P5 or something), but AMD decided it was worth it to make it fast for Bulldozer. Probably because it was easy.
Would it be easy for SnB-family uarch to have fast
loop? If so, why don't they? If not, why is it hard? A lot of decoder transistors? Or extra bits in a fused dec&branch uop to record that it doesn't set flags? What could those 7 uops be doing? It's a really simple instruction.
What's special about Bulldozer that made a fast
loopeasy / worth it? Or did AMD waste a bunch of transistors on making
loopfast? If so, presumably someone thought it was a good idea.
loop was fast, it would be perfect for BigInteger arbitrary-precision
adc loops, to avoid partial-flag stalls / slowdowns (see my comments on my answer), or any other case where you want to loop without touching flags. It also has a minor code-size advantage over
dec/jnz only macro-fuses on SnB-family).
On modern CPUs where
dec/jnz is ok in an ADC loop,
loop would still be nice for ADCX / ADOX loops (to preserve OF).
loop had been fast, compilers would already be using it as a peephole optimization for code-size + speed on CPUs without macro-fusion.
It wouldn't stop me from getting annoyed at all the questions with bad 16bit code that uses
loop for every loop, even when they also need another counter inside the loop. But at least it wouldn't be as bad.