It should be possible to check with the uop perf counter, in an artificial loop that just repeats an instruction that we want to know about. I've now done this, see below. AFAICT, 1-register modes can micro-fuse in read-modify instructions, but 2-register modes can't.
It would make sense that IACA is right that 1-register addressing modes can micro-fuse, while 2-register addressing modes can't. Normally uops can only have 2 input dependencies. (FMA is a special case). Instructions with more than 2 non-immediate input operands, other than FMA, always decode to multiple uops. (source: I think I read this in one of Agner Fog's manuals, probably the microarch one.) IDK how Intel CPUs track the 3 input deps for a single uop, without including enough silicon for the general case of 3 inputs and reducing the number of uops for many other instructions (like variable-mask shuffles and blends).
edit: also worth testing: instructions that don't read their dest. If there is no other dependency, like for a mov from memory, maybe a 2-register addressing mode can micro-fuse, and those registers would be the only 2 data dependencies for the uop. Or, multi-uop instructions can maybe micro-fuse one of their uops, and not require an extra one when one of their inputs is a register instead of a memory location. (Although pinsrw is already like this, and it doesn't count as micro-fusion. Maybe because the 'get 16bits from a reg' uop is just replaced with a 'load 16bits from mem' uop?)
I think this non-fusion for 2-reg addressing modes is accurate. Another piece of evidence is performance of LUT lookups with MMX punpckldq (which is 1 uop and can micro-fuse a memory operand), vs. pinsrw (which always takes 2 uops). I was expecting pinsrw to be slower, but it wasn't. (My memory addresses are of the (%rsi, %rax, 4) form, so punpckldq wouldn't fuse, and thus be 2 uops.)
Incidentally, on Haswell, vpgatherdd takes about 1.7x more cycles than a movd / pinsrw gather, when that's basically all you're doing in the loop. (read/PXOR/write the combined LUT lookups into a dest buffer.) Also interesting: with AVX-512, brute-force non-LUT GF16 multiplies will be faster than LUT lookups, unless future vpgather implementations get faster.
Update: confirmed by testing
Confirmed by testing with performance counters for uops and cycles.
I found a table of PMU events for Intel Sandybridge, for use with Linux's perf command. (Standard perf unfortunately doesn't have symbolic names for most hardware-specific PMU events, like uops.) I made use of it for a recent answer.
To test for uop micro-fusion, I constructed a test program that is bottlenecked on the 4-uops-per-cycle fused-domain limit of Intel CPUs. To avoid any execution-port contention, many of these uops are nops, which still sit in the uop cache and go through the pipeline the same as any other uop, except they don't get dispatched to an execution port. (An xor x, same, or an eliminated move, would be the same.)
Test program: yasm -f elf64 uop-test.s && ld uop-test.o -o uop-test
GLOBAL _start
_start:
xor eax, eax
xor ebx, ebx
xor edx, edx
xor edi, edi
lea rsi, [rel mydata] ; load pointer
mov ecx, 10000000
cmp dword [rsp], 2 ; argc >= 2
jge .loop_2reg
ALIGN 32
.loop_1reg:
or eax, [rsi + 0]
or ebx, [rsi + 4]
dec ecx
nop
nop
nop
nop
jg .loop_1reg
; xchg r8, r9 ; no effect on flags; decided to use NOPs instead
jmp .out
ALIGN 32
.loop_2reg:
or eax, [rsi + 0 + rdi]
or ebx, [rsi + 4 + rdi]
dec ecx
nop
nop
nop
nop
jg .loop_2reg
.out:
xor edi, edi
mov eax, 231 ; exit(0)
syscall
SECTION .rodata
mydata:
db 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff
I also found that the uop bandwidth out of the loop buffer isn't a constant 4 per cycle, if the loop isn't a multiple of 4 uops. (i.e. it's abc, abc, ...; not abca, bcab, ...). Agner Fog's microarch doc unfortunately wasn't clear on this limitation of the loop buffer.
I wanted to keep macro-fusion (compare-and-branch) out of the picture, so I used nops between the dec and the branch. I used 4 nops, so with micro-fusion, the loop would be 8 uops, and fill the pipeline with at 2 cycles per 1 iteration.
In the other version of the loop, using 2-operand addressing modes that don't micro-fuse, the loop will be 10 fused-domain uops, and run in 3 cycles.
Results from my 3.3GHz Intel Sandybridge (i5 2500k). I didn't do anything to get the cpufreq governor to ramp up clock speed before testing, because cycles are cycles when you aren't interacting with memory. I've added annotations for the performance counter events that I had to enter in hex.
testing the 1-reg addressing mode: no cmdline arg
$ perf stat -e task-clock,cycles,instructions,r1b1,r10e,r2c2,r1c2,stalled-cycles-frontend,stalled-cycles-backend ./uop-test
Performance counter stats for './uop-test':
11.489620 task-clock (msec) # 0.961 CPUs utilized
20,288,530 cycles # 1.766 GHz
80,082,993 instructions # 3.95 insns per cycle
# 0.00 stalled cycles per insn
60,190,182 r1b1 ; UOPS_DISPATCHED: (unfused-domain. 1->umask 02 -> uops sent to execution ports from this thread)
80,203,853 r10e ; UOPS_ISSUED: fused-domain
80,118,315 r2c2 ; UOPS_RETIRED: retirement slots used (fused-domain)
100,136,097 r1c2 ; UOPS_RETIRED: ALL (unfused-domain)
220,440 stalled-cycles-frontend # 1.09% frontend cycles idle
193,887 stalled-cycles-backend # 0.96% backend cycles idle
0.011949917 seconds time elapsed
testing the 2-reg addressing mode: with a cmdline arg
$ perf stat -e task-clock,cycles,instructions,r1b1,r10e,r2c2,r1c2,stalled-cycles-frontend,stalled-cycles-backend ./uop-test x
Performance counter stats for './uop-test x':
18.756134 task-clock (msec) # 0.981 CPUs utilized
30,377,306 cycles # 1.620 GHz
80,105,553 instructions # 2.64 insns per cycle
# 0.01 stalled cycles per insn
60,218,693 r1b1 ; UOPS_DISPATCHED: (unfused-domain. 1->umask 02 -> uops sent to execution ports from this thread)
100,224,654 r10e ; UOPS_ISSUED: fused-domain
100,148,591 r2c2 ; UOPS_RETIRED: retirement slots used (fused-domain)
100,172,151 r1c2 ; UOPS_RETIRED: ALL (unfused-domain)
307,712 stalled-cycles-frontend # 1.01% frontend cycles idle
1,100,168 stalled-cycles-backend # 3.62% backend cycles idle
0.019114911 seconds time elapsed
So, both versions ran 80M instructions, and dispatched 60M uops to execution ports. (or with a memory source dispatches to an ALU for the or, and a load port for the load, regardless of whether it was micro-fused or not in the rest of the pipeline. nop doesn't dispatch to an execution port at all.) Similarly, both versions retire 100M unfused-domain uops, because the 40M nops count here.
The difference is in the counters for the fused-domain.
- The 1-register address version only issues and retires 80M fused-domain uops. This is the same as the number of instructions. Each insn turns into one fused-domain uop.
- The 2-register address version issues 100M fused-domain uops. This is the same as the number of unfused-domain uops, indicating that no micro-fusion happened.
I suspect that you'd only see a difference between UOPS_ISSUED and UOPS_RETIRED(retirement slots used) if branch mispredicts led to uops being cancelled after issue, but before retirement.
And finally, the performance impact is real. The non-fused version took 1.5x as many clock cycles. This exaggerates the performance difference compared to most real cases. The loop has to run in a whole number of cycles, and the 2 extra uops push it from 2 to 3. Often, an extra 2 fused-domain uops will make less difference. And potentially no difference, if the code is bottlecked by something other than 4-fused-domain-uops-per-cycle.
Still, code that makes a lot of memory references in a loop might be faster if implemented by incrementing pointers, instead of the using [base + offset] addressing modes.
futher stuff
cmp [rip-rel], imm8 can't micro-fuse (on SnB). So IACA is wrong about this one:
cmp dword [abs mydata], 0x1b ; fused counters != unfused counters
cmp dword [rel mydata], 0x1b ; fused counters ~= unfused counters
However, rip-rel can micro-fuse in at least this other case:
or eax, dword [rel mydata] ; fused counters != unfused counters
Micro-fusion doesn't increase the latency of an instruction. The load can issue before the other input is ready.
ALIGN 32
.dep_fuse:
or eax, [rsi + 0]
or eax, [rsi + 0]
or eax, [rsi + 0]
or eax, [rsi + 0]
or eax, [rsi + 0]
dec ecx
jg .dep_fuse
This loop runs at 5 cycles per iteration, because of the eax dep chain. No faster than a sequence of or eax, [rsi + 0 + rdi], or mov ebx, [rsi + 0 + rdi] / or eax, ebx. (The unfused and the mov versions both run the same number of uops.) Scheduling / dep checking happens in the unfused-domain.
Micro-fusion doesn't have a shortcut for the base and offset being the same register. A loop with or eax, [mydata + rdi+4*rdi] (where rdi is zeroed) runs as many uops and cycles as the loop with or eax, [rsi+rdi]. This addressing mode could be used for iterating over an array of odd-sized structs starting at a fixed address. This is probably never used in most programs, so it's no surprise that Intel didn't spend transistors on allowing this special-case of 2-register modes to micro-fuse.
Macro-fusion of a cmp/jcc or dec/jcc creates a uop that stays as a single uop even in the unfused-domain. dec / nop / jge can still run in a single cycle, because of branch prediction, not actually checking the flags in time.
