[llvm-dev] [RFC] Add IR level interprocedural outliner for code size.

Quentin Colombet via llvm-dev llvm-dev at lists.llvm.org
Tue Jul 25 09:31:10 PDT 2017


> On Jul 25, 2017, at 9:24 AM, Jessica Paquette <jpaquette at apple.com> wrote:
> 
>> The two passes are pretty different in their approaches to congruency finding, so I don't think it helps to group them as though they were interchangeable "outliner technology". The two passes might be totally orthogonal.
> 
> I think that based off how River described his algorithm, the actual underlying method should be pretty similar. If it is, then we could probably compare the performance of the suffix tree vs. suffix array method and then create a general outliner that can be run at any level of representation.

+1, I believe that would be the ideal outcome.
I can see a split like this:
- Outliner algorithm IR-agnostic (with possibly different mode: suffix tree, array.)
- Pluggable cost model
- Rewriter

> By that I mean that the actual suffix tree/array candidate search algorithm would be separate from the actual implementation of *outlining things*. The actual implementation at each level of representation would define
> 
> - How to outline a sequence of instructions
> - An equivalence/congruence scheme for two instructions
> - A cost model
> 
> I don’t think it’d be too difficult to split it up in that sort of way. I’d also like to experiment with pre-regalloc outlining in general, so it’d make it easier to explore that route as well.
> 
>> 1. if you run the LLVM IR level code size outliner, then the MachineOutliner fails to find any significant redundancies.
>> 
>> 2. if you run the LLVM IR level code size outliner, then the MachineOutliner finds just as many redundancies.
> 
> This would be interesting. The MachineOutliner deems two instructions equivalent iff their opcodes and operands are identical. This isn’t super flexible (pre-register allocation outlining would be much better). However, an IR-level outliner has a lot more wiggle-room. It would be interesting to see how certain equivalence schemes perform. Once again, making assumptions about River’s algorithm, but the equivalence/congruence schemes are probably where the most significant differences in the way each technique handles outlining lie.
> 
> - Jessica
> 
>> On Jul 24, 2017, at 10:25 PM, Sean Silva via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>> wrote:
>> 
>> 
>> 
>> On Mon, Jul 24, 2017 at 4:14 PM, Quentin Colombet via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>> wrote:
>> Hi River,
>> 
>>> On Jul 24, 2017, at 2:36 PM, River Riddle <riddleriver at gmail.com <mailto:riddleriver at gmail.com>> wrote:
>>> 
>>> Hi Quentin,
>>>  I appreciate the feedback. When I reference the cost of Target Hooks it's mainly for maintainability and cost on a target author. We want to keep the intrusion into target information minimized. The heuristics used for the outliner are the same used by any other IR level pass seeking target information, i.e TTI for the most part. I can see where you are coming from with "having heuristics solely focused on code size do not seem realistic", but I don't agree with that statement.
>> 
>> If you only want code size I agree it makes sense, but I believe, even in Oz, we probably don’t want to slow the code by a big factor for a couple bytes. That’s what I wanted to say and what I wanted to point out is that you need to have some kind of model for the performance to avoid those worst cases. Unless we don’t care :).
>> 
>>> I think there is a disconnect on heuristics. The only user tunable parameters are the lower bound parameters(to the cost model), the actual analysis(heuristic calculation) is based upon TTI information. 
>> 
>> I don’t see how you can get around adding more hooks to know how a specific function prototype is going to be lowered (e.g., i64 needs to be split into two registers, fourth and onward parameters need to be pushed on the stack and so on). Those change the code size benefit.
>> 
>>>  When you say "Would still be interesting to see how well this could perform on some exact model (i.e., at the Machine level), IMO." I am slightly confused as to what you mean. I do not intend to try and implement this algorithm at the MIR level given that it exists in Machine Outliner.
>> 
>> Of course, I don’t expect you to do that :). What I meant is that the claim that IR offers the better trade off is not based on hard evidences. I actually don’t buy it.
>> 
>> My point was to make sure I understand what you are trying to solve and given you have mentioned the MachineOutliner, why you are not working on improving it instead of suggesting a new framework.
>> Don’t take me wrong, maybe creating a new framework at the IR level is the right thing to do, but I still didn’t get that from your comments.
>> 
>>> There are several comparison benchmarks given in the "More detailed performance data" of the original RFC. It includes comparisons to the Machine Outliner when possible(I can't build clang on Linux with Machine Outliner). I welcome any and all discussion on the placement of the outliner in LLVM.
>> 
>> My fear with a new framework is that we are going to split the effort for pushing the outliner technology forward and I’d like to avoid that if at all possible.
>> 
>> The two passes are pretty different in their approaches to congruency finding, so I don't think it helps to group them as though they were interchangeable "outliner technology". The two passes might be totally orthogonal.
>> 
>> I can imagine two extreme outcomes (reality is probably somewhere in between):
>> 
>> 1. if you run the LLVM IR level code size outliner, then the MachineOutliner fails to find any significant redundancies.
>> 
>> 2. if you run the LLVM IR level code size outliner, then the MachineOutliner finds just as many redundancies.
>> 
>> It would be good if River could get some data about this.
>> 
>> -- Sean Silva
>>  
>> 
>> Now, to be more concrete on your proposal, could you describe the cost model for deciding what to outline? (Really the cost model, not the suffix algo.)
>> Are outlined functions pushed into the list candidates for further outlining?
>> 
>> Cheers,
>> -Quentin
>> 
>>>  Thanks,
>>> River Riddle
>>> 
>>> On Mon, Jul 24, 2017 at 1:42 PM, Quentin Colombet <qcolombet at apple.com <mailto:qcolombet at apple.com>> wrote:
>>> Hi River,
>>> 
>>>> On Jul 24, 2017, at 11:55 AM, River Riddle via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>> wrote:
>>>> 
>>>> Hi Jessica,
>>>>  The comparison to the inliner is an interesting one but we think it's important to note the difference in the use of heuristics. The inliner is juggling many different tasks at the same time, execution speed, code size, etc. which can cause the parameters to be very sensitive depending on the benchmark/platform/etc. The outliners heuristics are focused solely on the potential code size savings from outlining, and is thus only sensitive to the current platform. This only creates a problem when we are over estimating the potential cost of a set of instructions for a particular target. The cost model parameters are only minimums: instruction sequence length, estimated benefit, occurrence amount. The heuristics themselves are conservative and based upon all of the target information available at the IR level, the parameters are just setting a lower bound to weed out any outliers. You are correct in that being at the machine level, before or after RA, will give the most accurate heuristics but we feel there's an advantage to being at the IR level. At the IR level we can do so many more things that are either too difficult/complex for the machine level(e.g parameterization/outputs/etc). Not only can we do these things but they are available on all targets immediately, without the need for target hooks. The caution on the use of heuristics is understandable, but there comes a point when trade offs need to be made. We made the trade off for a loss in exact cost modeling to gain flexibility, coverage, and potential for further features. This trade off is the same made for quite a few IR level optimizations, including inlining. As for the worry about code size regressions, so far the results seem to support our hypothesis.
>>> 
>>> Would still be interesting to see how well this could perform on some exact model (i.e., at the Machine level), IMO. Target hooks are cheap and choosing an implementation because it is simpler might not be the right long term solution.
>>> At the very least, to know what trade-off we are making, having prototypes with the different approaches sounds sensible.
>>> In particular, all the heuristics about cost for parameter passing (haven’t checked how you did it) sounds already complex enough and would require target hooks. Therefore, I am not seeing a clear win with an IR approach here.
>>> 
>>> Finally, having heuristics solely focused on code size do not seem realistic. Indeed, I am guessing you have some thresholds to avoid outlining some piece of code too small that would end up adding a whole lot of indirections and I don’t like magic numbers in general :).
>>> 
>>> To summarize, I wanted to point out that an IR approach is not as a clear win as you describe and would thus deserve more discussion.
>>> 
>>> Cheers,
>>> -Quentin
>>> 
>>>>  Thanks,
>>>> River Riddle
>>>> 
>>>> On Mon, Jul 24, 2017 at 11:12 AM, Jessica Paquette <jpaquette at apple.com <mailto:jpaquette at apple.com>> wrote:
>>>> 
>>>> Hi River,
>>>> 
>>>> I’m working on the MachineOutliner pass at the MIR level. Working at the IR level sounds interesting! It also seems like our algorithms are similar. I was thinking of taking the suffix array route with the MachineOutliner in the future. 
>>>> 
>>>> Anyway, I’d like to ask about this:
>>>> 
>>>>> On Jul 20, 2017, at 3:47 PM, River Riddle via llvm-dev <llvm-dev at lists.llvm.org <mailto:llvm-dev at lists.llvm.org>> wrote:
>>>>> 
>>>>> The downside to having this type of transformation be at the IR level is it means there will be less accuracy in the cost model -  we can somewhat accurately model the cost per instruction but we can’t get information on how a window of instructions may lower. This can cause regressions depending on the platform/codebase, therefore to help alleviate this there are several tunable parameters for the cost model.
>>>> 
>>>> The inliner is threshold-based and it can be rather unpredictable how it will impact the code size of a program. Do you have any idea as to how heuristics/thresholds/parameters could be tuned to prevent this? In my experience, making good code size decisions with these sorts of passes requires a lot of knowledge about what instructions you’re dealing with exactly. I’ve seen the inliner cause some pretty serious code size regressions in projects due to small changes to the cost model/parameters which cause improvements in other projects. I’m a little worried that an IR-level outliner for code size would be doomed to a similar fate.
>>>> 
>>>> Perhaps it would be interesting to run this sort of pass pre-register allocation? This would help pull you away from having to use heuristics, but give you some more opportunities for finding repeated instruction sequences. I’ve thought of doing something like this in the future with the MachineOutliner and seeing how it goes.
>>>> 
>>>> - Jessica
>>>> 
>>>> 
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>>> 
>> 
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