12

Can somebody explain the Latency and the Throughput values given in the Intel Intrinsic Guide?

Have I understood it correctly that the latency is the amount of time units an instruction takes to run, and the throughput is the number of instructions that can be started per time unit?

If my definition is correct, why is the latency for some instructions higher on newer CPU versions (e.g. mulps)?

  • 1
    Hmm, no, those latency timings appear to include an L1 access for some strange reason. Which did increase from 2 to 3 cycles. Google "agner fog instruction tables" instead. – Hans Passant Oct 23 '16 at 16:58
  • 1
    @HansPassant: no, Intel's timings exactly match Agner Fog's tables in this case. Why do you think they include an L1 load-use latency? – Peter Cordes Oct 24 '16 at 7:43
  • 1
    This web page has an explanation for the latency and throughput values software.intel.com/en-us/articles/… – Harald Mar 1 '17 at 12:43
10

Missing from that table: MULPS latency on Broadwell: 3. On Skylake: 4.

The intrinsic finder's latency is accurate in this case, although it occasionally doesn't match Agner Fog's experimental testing. (That VEXTRACTF128 latency may be a case of Intel not including a bypass delay in their table). See my answer on that linked question for more details about what to do with throughput and latency numbers, and what they mean for a modern out-of-order CPU.

MULPS latency did increase from 4 (Nehalem) to 5 (Sandybridge). This may have been to save power or transistors, but more likely because SandyBridge standardized uop latencies to only a few different values, to avoid writeback conflict: i.e. when the same execution unit would produce two results in the same cycle, e.g. from starting a 2c uop one cycle, then a 1c uop the next cycle.

This simplifies the uop scheduler, which dispatches uops from the Reservation Station to the execution units. More or less in oldest-first order, but it has has to filter by which ones have their inputs ready. The scheduler is power-hungry, and this is a significant part of the power cost of out-of-order execution. (It's unfortunately not practical to make a scheduler that picks uops in critical-path-first order, to avoid having independent uops steal cycles from the critical path with resource conflicts.)

Agner Fog explains the same thing (in the SnB section of his microarch pdf):

Mixing μops with different latencies

Previous processors have a write-back conflict when μops with different latencies are issued to the same execution port, as described on page 114. This problem is largely solved on the Sandy Bridge. Execution latencies are standardized so that all μops with a latency of 3 are issued to port 1 and all μops with a latency of 5 go to port 0. μops with a latency of 1 can go to port 0, 1 or 5. No other latencies are allowed, except for division and square root.

The standardization of latencies has the advantage that write-back conflicts are avoided. The disadvantage is that some μops have higher latencies than necessary.

Hmm, I just realized that Agner's numbers for VEXTRACTF128 xmm, ymm, imm8 are weird. Agner lists it as 1 uop 2c latency on SnB, but Intel lists it as 1c latency (as discussed here). Maybe the execution unit is 1c latency, but there's a built-in 1c bypass delay (for lane-crossing?) before you can use the result. That would explain the discrepancy between Intel's numbers and Agner's experimental test.


Some instructions are still 2c latency, because they decode to 2 dependent uops that are each 1c latency. MULPS is a single uop, even the AVX 256b version, because even Intel's first-gen AVX CPUs have full-width 256b execution units (except the divide/sqrt unit). Needing twice as many copies of the FP multiplier circuitry is a good reason for optimizing it to save transistors at the cost of latency.


This pattern holds up to and including Broadwell, AFAICT from searching Agner's tables. (Using LibreOffice, I selected the whole table, and did data->filter->standard filter, and looked for rows with column C = 1 and column F = 4. (And then repeat for 2.) Look for any uops that aren't loads or stores.

Haswell sticks to the pattern of only 1, 3 and 5 cycle ALU uop latencies (except for AESENC/AESDEC, which is 1 uop for port5 with 7c latency. And of course DIVPS and SQRTPS). There's also CVTPI2PS xmm, mm, at 1 uop 4c latency, but maybe that's 3c for the p1 uop and 1c of bypass delay, the way Agner Fog measured it or unavoidable. VMOVMSKPS r32, ymm is also 2c (vs. 3c for the r32,xmm version).

Broadwell dropped MULPS latency to 3, same as ADDPS, but kept FMA at 5c. Presumably they figured out how to shortcut the FMA unit to produce just a multiply when no add was needed.


Skylake is able to handle uops with latency=4. Latency for FMA, ADDPS/D, and MULPS/D = 4 cycles. (SKL drops the dedicated vector-FP add unit, and does everything with the FMA unit. So ADDPS/D throughput is doubled to match MULPS/D and FMA...PS/D. I'm not sure which change motivated what, and whether they would have introduced 4c latency instructions at all if they hadn't wanted to drop the vec-FP adder without hurting ADDPS latency too badly.)

Other SKL instructions with 4c latency: PHMINPOSUW (down from 5c), AESDEC/AESENC, CVTDQ2PS (up from 3c, but this might be 3c + bypass), RCPPS (down from 5c), RSQRTPS, CMPPS/D (up from 3c). Hmm, I guess FP compares were done in the adder, and now have to use FMA.

MOVD r32, xmm and MOVD xmm, r32 are listed as 2c, perhaps a bypass delay from int-vec to int? Or a glitch in Agner's testing? Testing the latency would require other instructions to create a round-trip back to xmm. It's 1c on HSW. Agner lists SKL MOVQ r64, xmm as 2 cycles (port0), but MOVQ xmm, r64 as 1c (port5), and it seems extremely weird that reading a 64-bit register is faster than reading a 32-bit register. Agner has had mistakes in his table in the past; this may be another.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.