Johannes Doerfert via llvm-dev
2021-Mar-12 00:10 UTC
[llvm-dev] NVPTX codegen for llvm.sin (and friends)
On 3/11/21 1:37 PM, Artem Belevich wrote:> On Thu, Mar 11, 2021 at 10:54 AM Johannes Doerfert < > johannesdoerfert at gmail.com> wrote: > >> I certainly agree we should try to avoid a hard-coded mapping >> in C++. >> >> I could see something like: >> >> ``` >> __attribute__((implementation("llvm.cos")) >> double __nv_cos(...) { ... } >> >> ``` >> >> and a pass that transforms all calls to a function with an >> "implementation" to calls to that implementation. Maybe >> later we attach a score/priority ;) >> >> > I'm not sure how that would work. > Where would you place that `__attribute__((implementation))` ? We do not > have the definitions for `__nv_*` as they come from NVIDIA-provided > bitcode. We could add the attribute to the declaration in > `__clang_cuda_libdevice_declares.h`. > How does LLVM handle the differences in function attributes between > function declaration and definition? Will there be trouble when we link in > the actual __nv_cos from the libdevice that would not have that attribute? > > Another potential gotcha is that for the functions that can't be directly > mapped 1:1 to `__nv_*` counterparts, we'd still need to provide the > implementation ourselves. We will not know whether the implementation will > be used until after the substitution pass, so we'll need to make sure it's > not DCE'd until then. It appears to be the same issue (though on a smaller > scale) as with linking in libdevice directly. > > Let's take a step back and figure out what are the issues we want to solve. > > The top-level goal is to provide implementation for LLVM intrinsics. For > now let's stick with libm-related ones. > What we have is the libdevice bitcode which uses different function names > and provides a subset of the functionality we need. > What we miss is > - something to connect LLVM's libcalls to the GPU-side implementation, > - additional code to provide implementations for the functions that are > missing or different in libdevice. > > Considering that we want this to work in LLVM, the additional code would > have to be a bitcode and it would have to exist in addition to libdevice. > Our options for the mapping between LLVM intrinsics and the implementation > are > * intrinsic -> __nv_* equivalent mapping pass > This would still need additional bitcode for the missing/different > functions. > * lower libcalls to the standard libm APIs, implement libm -> __nv_* > mapping in our own bitcode. > > Considering that additional bitcode is needed in both cases, I believe that > the second approach makes more sense.I really hope to avoid any additional bitcode, there are too many drawbacks and basically no benefits, IMHO.> LLVM does not need to know or care about what's provided by libdevice, and > we'd have more flexibility, compared to what we could do in the mapping > pass. It also makes it easy to substitute a different implementation, if we > have or need one.I agree that LLVM (core) should not know about __nv_*, that's why I suggested the `__attribute__((implements("...")))` approach. My preferred solution is still to annotate our declarations of __nv_* and point to the llvm.intrinsics (name) from there. If we have a missing mapping, we point to an intrinsic from a definition that lives in the Clang headers next to the __nv_* declarations. This does not yet work because -mlink-builtin-bitcode (which I assume triggers the llvm-link logic) will drop the attributes of a declaration if a definition is found. I think that should not be the case anyway such that the union of attributes is set. The benefit I see for the above is that the mapping is tied to the declarations and doesn't live in a tablegen file far away. It works well even if we can't map 1:1, and we could even restrict the "used" attribute to anything that has an "implements" attribute. So: ``` __nv_A() { ... } // called, inlined and optimized as before, DCE'ed after. __nv_B() { ... } // not called, DCE'ed. __attribute__((implements("llvm.C")) __nv_C() { ... } // calls are inlined and optimized as before, not DCE'ed // though because of the attribute. Replaces llvm.C as // callee in the special pass. ``` So "implements" gives you a way to statically replace a function declaration or definition with another one. I could see it being used to provide other intrinsics to platforms with backends that don't support them. Does that make some sense? ~ Johannes> > WDYT? > > --Artem > > >> >> On 3/10/21 8:44 PM, William Moses wrote: >>> We could also consider doing something slightly broader. >>> >>> For example we could define a special attribute on top of the llvm.cos >>> call/declaration etc with metadata or an attribute that points to the >>> actual __nv_cos function. Then in a subsequent lowering pass the >>> corresponding intrinsic with the relevant attribute has its uses replaced >>> by the actual function. >>> >>> >>> On Wed, Mar 10, 2021 at 7:57 PM Johannes Doerfert < >>> johannesdoerfert at gmail.com> wrote: >>> >>>> On 3/10/21 6:22 PM, Artem Belevich wrote: >>>>> On Wed, Mar 10, 2021 at 3:44 PM Johannes Doerfert < >>>>> johannesdoerfert at gmail.com> wrote: >>>>> >>>>>> On 3/10/21 4:38 PM, Artem Belevich wrote: >>>>>>> On Wed, Mar 10, 2021 at 1:55 PM Johannes Doerfert < >>>>>>> johannesdoerfert at gmail.com> wrote: >>>>>>> >>>>>>>> On 3/10/21 3:25 PM, Artem Belevich wrote: >>>>>>>>> On Wed, Mar 10, 2021 at 12:57 PM Johannes Doerfert < >>>>>>>>> johannesdoerfert at gmail.com> wrote: >>>>>>>>> >>>>>>>>>> Right. We could keep the definition of __nv_cos and friends >>>>>>>>>> around. Right now, -ffast-math might just crash on the user, >>>>>>>>>> which is arguably a bad thing. I can also see us benefiting >>>>>>>>>> in various other ways from llvm.cos uses instead of __nv_cos >>>>>>>>>> (assuming precision is according to the user requirements but >>>>>>>>>> that is always a condition). >>>>>>>>>> >>>>>>>>>> It could be as simple as introducing __nv_cos into >>>>>>>>>> "llvm.used" and a backend matching/rewrite pass. >>>>>>>>>> >>>>>>>>>> If the backend knew the libdevice location it could even pick >>>>>>>>>> the definitions from there. Maybe we could link libdevice late >>>>>>>>>> instead of eager? >>>>>>>>>> >>>>>>>>> It's possible, but it would require plumbing in CUDA SDK awareness >>>> into >>>>>>>>> LLVM. While clang driver can deal with that, LLVM currently can't. >>>> The >>>>>>>>> bitcode library path would have to be provided by the user. >>>>>>>> The PTX backend could arguably be CUDA SDK aware, IMHO, it would >>>>>>>> even be fine if the middle-end does the remapping to get inlining >>>>>>>> and folding benefits also after __nv_cos is used. See below. >>>>>>>> >>>>>>>> >>>>>>>>> The standard library as bitcode raises some questions. >>>>>>>> Which standard library? CUDAs libdevice is a bitcode library, right? >>>>>>>> >>>>>>> It's whatever LLVM will need to lower libcalls to. libdevice bitcode >> is >>>>>> the >>>>>>> closest approximation of that we have at the moment. >>>>>>> >>>>>>> >>>>>>>>> * When do we want to do the linking? If we do it at the beginning, >>>> then >>>>>>>> the >>>>>>>>> question is how to make sure unused functions are not eliminated >>>> before >>>>>>>> we >>>>>>>>> may need them, as we don't know apriori what's going to be needed. >> We >>>>>>>> also >>>>>>>>> do want the unused functions to be gone after we're done. Linking >> it >>>> in >>>>>>>>> early would allow optimizing the code better at the expense of >> having >>>>>> to >>>>>>>>> optimize a lot of code we'll throw away. Linking it in late has >> less >>>>>>>>> overhead, but leaves the linked in bitcode unoptimized, though it's >>>>>>>>> probably in the ballpark of what would happen with a real library >>>> call. >>>>>>>>> I.e. no inlining, etc. >>>>>>>>> >>>>>>>>> * It incorporates linking into LLVM, which is not LLVM's job. >>>> Arguably, >>>>>>>> the >>>>>>>>> line should be drawn at the lowering to libcalls as it's done for >>>> other >>>>>>>>> back-ends. However, we're also constrained to by the need to have >> the >>>>>>>>> linking done before we generate PTX which prevents doing it after >>>> LLVM >>>>>> is >>>>>>>>> done generating an object file. >>>>>>>> I'm confused. Clang links in libdevice.bc early. >>>>>>> Yes. Because that's where it has to happen if we want to keep LLVM >>>>>> unaware >>>>>>> of CUDA SDK. >>>>>>> It does not have to be the case if/when LLVM can do the linking >> itself. >>>>>>> >>>>>>>> If we make sure >>>>>>>> `__nv_cos` is not deleted early, we can at any point "lower" >>>> `llvm.cos` >>>>>>>> to `__nv_cos` which is available. After the lowering we can remove >>>>>>>> the artificial uses of `__nv_XXX` functions that we used to keep the >>>>>>>> definitions around in order to remove them from the final result. >>>>>>>> >>>>>>> This is the 'link early' approach, I should've been explicit that >> it's >>>>>>> 'link early *everything*' as opposed to linking only what's needed at >>>> the >>>>>>> beginning. >>>>>>> It would work at the expense of having to process/optimize 500KB >> worth >>>> of >>>>>>> bitcode for every compilation, whether it needs it or not. >>>>>>> >>>>>>> >>>>>>>> We get the benefit of having `llvm.cos` for some of the pipeline, >>>>>>>> we know it does not have all the bad effects while `__nv_cos` is >>>> defined >>>>>>>> with inline assembly. We also get the benefit of inlining `__nv_cos` >>>>>>>> and folding the implementation based on the arguments. Finally, >>>>>>>> this should work with the existing pipeline, the linking is the same >>>>>>>> as before, all we do is to keep the definitions alive longer and >>>>>>>> lower `llvm.cos` to `__nv_cos` in a middle end pass. >>>>>>>> >>>>>>> Again, I agree that it is doable. >>>>>>> >>>>>>> >>>>>>> >>>>>>>> This might be similar to the PTX solution you describe below but I >>>> feel >>>>>>>> we get the inline benefit from this without actually changing the >>>>>> pipeline >>>>>>>> at all. >>>>>>>> >>>>>>> So, to summarize: >>>>>>> * link the library as bitcode early, add artificial placeholders for >>>>>>> everything, compile, remove placeholders and DCE unused stuff away. >>>>>>> Pros: >>>>>>> - we're already doing most of it before clang hands hands off >>>> IR to >>>>>>> LLVM, so it just pushes it a bit lower in the compilation. >>>>>>> Cons: >>>>>>> - runtime cost of optimizing libdevice bitcode, >>>>>>> - libdevice may be required for all NVPTX compilations? >>>>>>> >>>>>>> * link the library as bitcode late. >>>>>>> Pros: >>>>>>> - lower runtime cost than link-early approach. >>>>>>> Cons: >>>>>>> - We'll need to make sure that NVVMReflect pass processes the >>>>>> library. >>>>>>> - less optimizations on the library functions. Some of the >> code >>>>>> gets >>>>>>> DCE'ed away after NVVMReflect and the rest could be optimized better. >>>>>>> - libdevice may be required for all NVPTX compilations? >>>>>>> * 'link' with the library as PTX appended as text to LLVM's output >> and >>>>>> let >>>>>>> ptxas do the 'linking' >>>>>>> Pros: LLVM remains agnostic of CUDA SDK installation details. >> All >>>> it >>>>>>> does is allows lowering libcalls and leaves their resolution to the >>>>>>> external tools. >>>>>>> Cons: Need to have the PTX library somewhere and need to >> integrate >>>> the >>>>>>> 'linking' into the compilation process somehow. >>>>>>> >>>>>>> Neither is particularly good. If the runtime overhead of link-early >> is >>>>>>> acceptable, then it may be a winner here, by a very small margin. >>>>>>> link-as-PTX may be better conceptually as it keeps linking and >>>>>> compilation >>>>>>> separate. >>>>>>> >>>>>>> As for the practical steps, here's what we need: >>>>>>> - allow libcall lowering in NVPTX, possibly guarded by a flag. This >> is >>>>>>> needed for all of the approaches above. >>>>>>> - teach LLVM how to link in bitcode (and, possibly, control >> early/late >>>>>> mode) >>>>>>> - teach clang driver to delegate libdevice linking to LLVM. >>>>>>> >>>>>>> This will allow us to experiment with all three approaches and see >> what >>>>>>> works best. >>>>>> I think if we embed knowledge about the nv_XXX functions we can >>>>>> even get away without the cons you listed for early linking above. >>>>>> >>>>> WDYM by `embed knowledge about the nv_XXX functions`? By linking those >>>>> functions in? Of do you mean that we should just declare them >>>>> before/instead of linking libdevice in? >>>> I mean by providing the "libcall lowering" pass. So the knowledge >>>> that llvm.cos maps to __nv_cos. >>>> >>>>>> For early link I'm assuming an order similar to [0] but I also discuss >>>>>> the case where we don't link libdevice early for a TU. >>>>>> >>>>> That link just describes the steps needed to use libdevice. It does not >>>>> deal with how/where it fits in the LLVM pipeline. >>>>> The gist is that NVVMreflect replaces some conditionals with constants. >>>>> libdevice uses that as a poor man's IR preprocessor, conditionally >>>> enabling >>>>> different implementations and relying on DCE and constant folding to >>>> remove >>>>> unused parts and eliminate the now useless branches. >>>>> While running NVVM alone will make libdevice code valid and usable, it >>>>> would still benefit from further optimizations. I do not know to what >>>>> degree, though. >>>>> >>>>> >>>>>> Link early: >>>>>> 1) clang emits module.bc and links in libdevice.bc but with the >>>>>> `optnone`, `noinline`, and "used" attribute for functions in >>>>>> libdevice. ("used" is not an attribute but could as well be.) >>>>>> At this stage module.bc might call __nv_XXX or llvm.XXX freely >>>>>> as defined by -ffast-math and friends. >>>>>> >>>>> That could work. Just carrying extra IR around would probably be OK. >>>>> We may want to do NVVMReflect as soon as we have it linked in and, >> maybe, >>>>> allow optimizing the functions that are explicitly used already. >>>> Right. NVVMReflect can be run twice and with `alwaysinline` >>>> on the call sites of __nv_XXX functions we will actually >>>> inline and optimize them while the definitions are just "dragged >>>> along" in case we need them later. >>>> >>>> >>>>>> 2) Run some optimizations in the middle end, maybe till the end of >>>>>> the inliner loop, unsure. >>>>>> 3) Run a libcall lowering pass and another NVVMReflect pass (or the >>>>>> only instance thereof). We effectively remove all llvm.XXX calls >>>>> in favor of __nv_XXX now. Note that we haven't spend (much) time >>>>>> on the libdevice code as it is optnone and most passes are good >>>>>> at skipping those. To me, it's unclear if the used parts should >>>>>> not be optimized before we inline them anyway to avoid redoing >>>>>> the optimizations over and over (per call site). That needs >>>>>> measuring I guess. Also note that we can still retain the >> current >>>>>> behavior for direct calls to __nv_XXX if we mark the call sites >>>>>> as `alwaysinline`, or at least the behavior is almost like the >>>>>> current one is. >>>>>> 4) Run an always inliner pass on the __nv_XXX calls because it is >>>>>> something we would do right now. Alternatively, remove `optnone` >>>>>> and `noinline` from the __nv_XXX calls. >>>>>> 5) Continue with the pipeline as before. >>>>>> >>>>>> >>>>> SGTM. >>>>> >>>>> >>>>>> As mentioned above, `optnone` avoids spending time on the libdevice >>>>>> until we "activate" it. At that point (globals) DCE can be scheduled >>>>>> to remove all unused parts right away. I don't think this is (much) >>>>>> more expensive than linking libdevice early right now. >>>>>> >>>>>> Link late, aka. translation units without libdevice: >>>>>> 1) clang emits module.bc but does not link in libdevice.bc, it will be >>>>>> made available later. We still can mix __nv_XXX and llvm.XXX >> calls >>>>>> freely as above. >>>>>> 2) Same as above. >>>>>> 3) Same as above. >>>>>> 4) Same as above but effectively a no-op, no __nv_XXX definitions are >>>>>> available. >>>>>> 5) Same as above. >>>>>> >>>>>> >>>>>> I might misunderstand something about the current pipeline but from >> [0] >>>>>> and the experiments I run locally it looks like the above should cover >>>> all >>>>>> the cases. WDYT? >>>>>> >>>>>> >>>>> The `optnone` trick may indeed remove much of the practical differences >>>>> between the early/late approaches. >>>>> In principle it should work. >>>>> >>>>> Next question is -- is libdevice sufficient to satisfy LLVM's >> assumptions >>>>> about the standard library. >>>>> While it does provide most of the equivalents of libm functions, the >> set >>>> is >>>>> not complete and some of the functions differ from their libm >>>> counterparts. >>>>> The differences are minor, so we should be able to deal with it by >>>>> generating few wrapper functions for the odd cases. >>>>> Here's what clang does to provide math functions using libdevice: >>>>> >> https://github.com/llvm/llvm-project/blob/main/clang/lib/Headers/__clang_cuda_math.h >>>> Right now, clang will generate any llvm intrinsic and we crash, so >> anything >>>> else is probably a step in the right direction. Eventually, we should >>>> "lower" >>>> all intrinsics that the NVPTX backend can't handle or at least emit a >> nice >>>> error message. Preferably, clang would know what we can't deal with and >> not >>>> generate intinsic calls for those in the first place. >>>> >>>> >>>>> The most concerning aspect of libdevice is that we don't know when >> we'll >>>> no >>>>> longer be able to use the libdevice bitcode? My understanding is that >> IR >>>>> does not guarantee binary stability and at some point we may just be >>>> unable >>>>> to use it. Ideally we need our own libm for GPUs. >>>> For OpenMP I did my best to avoid writing libm (code) for GPUs by piggy >>>> backing on CUDA and libc++ implementations, I hope it will stay that >> way. >>>> That said, if the need arises we might really have to port libc++ to the >>>> GPUs. >>>> >>>> Back to the problem with libdevice. I agree that the solution of NVIDIA >>>> to ship a .bc library is suboptimal but with the existing, or an >> extended, >>>> auto-upgrader we might be able to make that work reasonably well for the >>>> foreseeable future. That problem is orthogonal to what we are discussing >>>> above, I think. >>>> >>>> ~ Johannes >>>> >>>> >>>>> --Artem >>>>> >>>>> >>>>>> ~ Johannes >>>>>> >>>>>> >>>>>> P.S. If the rewrite capability (aka libcall lowering) is generic we >>>> could >>>>>> use the scheme for many other things as well. >>>>>> >>>>>> >>>>>> [0] https://llvm.org/docs/NVPTXUsage.html#linking-with-libdevice >>>>>> >>>>>> >>>>>>> --Artem >>>>>>> >>>>>>> >>>>>>>> ~ Johannes >>>>>>>> >>>>>>>> >>>>>>>>> One thing that may work within the existing compilation model is to >>>>>>>>> pre-compile the standard library into PTX and then textually embed >>>>>>>> relevant >>>>>>>>> functions into the generated PTX, thus pushing the 'linking' phase >>>> past >>>>>>>> the >>>>>>>>> end of LLVM's compilation and make it look closer to the standard >>>>>>>>> compile/link process. This way we'd only enable libcall lowering in >>>>>>>> NVPTX, >>>>>>>>> assuming that the library functions will be magically available out >>>>>>>> there. >>>>>>>>> Injection of PTX could be done with an external script outside of >>>> LLVM >>>>>>>> and >>>>>>>>> it could be incorporated into clang driver. Bonus points for the >> fact >>>>>>>> that >>>>>>>>> this scheme is compatible with -fgpu-rdc out of the box -- assemble >>>> the >>>>>>>> PTX >>>>>>>>> with `ptxas -rdc` and then actually link with the library, instead >> of >>>>>>>>> injecting its PTX before invoking ptxas. >>>>>>>>> >>>>>>>>> --Artem >>>>>>>>> >>>>>>>>> Trying to figure out a good way to have the cake and eat it too. >>>>>>>>>> ~ Johannes >>>>>>>>>> >>>>>>>>>> >>>>>>>>>> On 3/10/21 2:49 PM, William Moses wrote: >>>>>>>>>>> Since clang (and arguably any other frontend that uses) should >> link >>>>>> in >>>>>>>>>>> libdevice, could we lower these intrinsics to the libdevice code? >>>>>>>>> The linking happens *before* LLVM gets to work on IR. >>>>>>>>> As I said, it's a workaround, not the solution. It's possible for >>>> LLVM >>>>>> to >>>>>>>>> still attempt lowering something in the IR into a libcall and we >>>> would >>>>>>>> not >>>>>>>>> be able to deal with that. It happens to work well enough in >>>> practice. >>>>>>>>> Do you have an example where you see the problem with -ffast-math? >>>>>>>>> >>>>>>>>> >>>>>>>>> >>>>>>>>>>> For example, consider compiling the simple device function below: >>>>>>>>>>> >>>>>>>>>>> ``` >>>>>>>>>>> // /mnt/sabrent/wmoses/llvm13/build/bin/clang tmp.cu -S >> -emit-llvm >>>>>>>>>>> --cuda-path=/usr/local/cuda-11.0 >> -L/usr/local/cuda-11.0/lib64 >>>>>>>>>>> --cuda-gpu-arch=sm_37 >>>>>>>>>>> __device__ double f(double x) { >>>>>>>>>>> return cos(x); >>>>>>>>>>> } >>>>>>>>>>> ``` >>>>>>>>>>> >>>>>>>>>>> The LLVM module for it is as follows: >>>>>>>>>>> >>>>>>>>>>> ``` >>>>>>>>>>> ... >>>>>>>>>>> define dso_local double @_Z1fd(double %x) #0 { >>>>>>>>>>> entry: >>>>>>>>>>> %__a.addr.i = alloca double, align 8 >>>>>>>>>>> %x.addr = alloca double, align 8 >>>>>>>>>>> store double %x, double* %x.addr, align 8 >>>>>>>>>>> %0 = load double, double* %x.addr, align 8 >>>>>>>>>>> store double %0, double* %__a.addr.i, align 8 >>>>>>>>>>> %1 = load double, double* %__a.addr.i, align 8 >>>>>>>>>>> %call.i = call contract double @__nv_cos(double %1) #7 >>>>>>>>>>> ret double %call.i >>>>>>>>>>> } >>>>>>>>>>> >>>>>>>>>>> define internal double @__nv_cos(double %a) #1 { >>>>>>>>>>> %q.i = alloca i32, align 4 >>>>>>>>>>> ``` >>>>>>>>>>> >>>>>>>>>>> Obviously we would need to do something to ensure these functions >>>>>> don't >>>>>>>>>> get >>>>>>>>>>> deleted prior to their use in lowering from intrinsic to >> libdevice. >>>>>>>>>>> ... >>>>>>>>>>> >>>>>>>>>>> >>>>>>>>>>> On Wed, Mar 10, 2021 at 3:39 PM Artem Belevich <tra at google.com> >>>>>> wrote: >>>>>>>>>>>> On Wed, Mar 10, 2021 at 11:41 AM Johannes Doerfert < >>>>>>>>>>>> johannesdoerfert at gmail.com> wrote: >>>>>>>>>>>> >>>>>>>>>>>>> Artem, Justin, >>>>>>>>>>>>> >>>>>>>>>>>>> I am running into a problem and I'm curious if I'm missing >>>>>> something >>>>>>>> or >>>>>>>>>>>>> if the support is simply missing. >>>>>>>>>>>>> Am I correct to assume the NVPTX backend does not deal with >>>>>>>> `llvm.sin` >>>>>>>>>>>>> and friends? >>>>>>>>>>>>> >>>>>>>>>>>> Correct. It can't deal with anything that may need to lower to a >>>>>>>>>> standard >>>>>>>>>>>> library call. >>>>>>>>>>>> >>>>>>>>>>>>> This is what I see, with some variations: >>>>>>>> https://godbolt.org/z/PxsEWs >>>>>>>>>>>>> If this is missing in the backend, is there a plan to get this >>>>>>>> working, >>>>>>>>>>>>> I'd really like to have the >>>>>>>>>>>>> intrinsics in the middle end rather than __nv_cos, not to >> mention >>>>>>>> that >>>>>>>>>>>>> -ffast-math does emit intrinsics >>>>>>>>>>>>> and crashes. >>>>>>>>>>>>> >>>>>>>>>>>> It all boils down to the fact that PTX does not have the >> standard >>>>>>>>>>>> libc/libm which LLVM could lower the calls to, nor does it have >> a >>>>>>>>>> 'linking' >>>>>>>>>>>> phase where we could link such a library in, if we had it. >>>>>>>>>>>> >>>>>>>>>>>> Libdevice bitcode does provide the implementations for some of >> the >>>>>>>>>>>> functions (though with a __nv_ prefix) and clang links it in in >>>>>> order >>>>>>>> to >>>>>>>>>>>> avoid generating IR that LLVM can't handle, but that's a >>>> workaround >>>>>>>> that >>>>>>>>>>>> does not help LLVM itself. >>>>>>>>>>>> >>>>>>>>>>>> --Artem >>>>>>>>>>>> >>>>>>>>>>>> >>>>>>>>>>>> >>>>>>>>>>>>> ~ Johannes >>>>>>>>>>>>> >>>>>>>>>>>>> >>>>>>>>>>>>> -- >>>>>>>>>>>>> ─────────────────── >>>>>>>>>>>>> ∽ Johannes (he/his) >>>>>>>>>>>>> >>>>>>>>>>>>> >>>>>>>>>>>> -- >>>>>>>>>>>> --Artem Belevich >>>>>>>>>>>> >
Artem Belevich via llvm-dev
2021-Mar-12 01:59 UTC
[llvm-dev] NVPTX codegen for llvm.sin (and friends)
On Thu, Mar 11, 2021 at 4:10 PM Johannes Doerfert < johannesdoerfert at gmail.com> wrote:> > On 3/11/21 1:37 PM, Artem Belevich wrote: > > On Thu, Mar 11, 2021 at 10:54 AM Johannes Doerfert < > > johannesdoerfert at gmail.com> wrote: > > > >> I certainly agree we should try to avoid a hard-coded mapping > >> in C++. > >> > >> I could see something like: > >> > >> ``` > >> __attribute__((implementation("llvm.cos")) > >> double __nv_cos(...) { ... } > >> > >> ``` > >> > >> and a pass that transforms all calls to a function with an > >> "implementation" to calls to that implementation. Maybe > >> later we attach a score/priority ;) > >> > >> > > I'm not sure how that would work. > > Where would you place that `__attribute__((implementation))` ? We do not > > have the definitions for `__nv_*` as they come from NVIDIA-provided > > bitcode. We could add the attribute to the declaration in > > `__clang_cuda_libdevice_declares.h`. > > How does LLVM handle the differences in function attributes between > > function declaration and definition? Will there be trouble when we link > in > > the actual __nv_cos from the libdevice that would not have that > attribute? > > > > Another potential gotcha is that for the functions that can't be directly > > mapped 1:1 to `__nv_*` counterparts, we'd still need to provide the > > implementation ourselves. We will not know whether the implementation > will > > be used until after the substitution pass, so we'll need to make sure > it's > > not DCE'd until then. It appears to be the same issue (though on a > smaller > > scale) as with linking in libdevice directly. > > > > Let's take a step back and figure out what are the issues we want to > solve. > > > > The top-level goal is to provide implementation for LLVM intrinsics. For > > now let's stick with libm-related ones. > > What we have is the libdevice bitcode which uses different function names > > and provides a subset of the functionality we need. > > What we miss is > > - something to connect LLVM's libcalls to the GPU-side implementation, > > - additional code to provide implementations for the functions that > are > > missing or different in libdevice. > > > > Considering that we want this to work in LLVM, the additional code would > > have to be a bitcode and it would have to exist in addition to libdevice. > > Our options for the mapping between LLVM intrinsics and the > implementation > > are > > * intrinsic -> __nv_* equivalent mapping pass > > This would still need additional bitcode for the missing/different > > functions. > > * lower libcalls to the standard libm APIs, implement libm -> __nv_* > > mapping in our own bitcode. > > > > Considering that additional bitcode is needed in both cases, I believe > that > > the second approach makes more sense. > > I really hope to avoid any additional bitcode, there are too many > drawbacks and basically no benefits, IMHO. >Could you elaborate on the drawbacks? The fact is that we already depend on the external bitcode (libdevice in this case), though right now we're trying to keep that to clang only. The current approach is not sound in principle and is rather brittle in practice. Nor clang is the only source of the IR for the LLVM to compile, so it leaves LLVM-only users without a good solution. There are already a handful of JIT compilers that each do their own gluing of libdevice into the IR they want to compile for NVPTX. I think we do have a very good reason to deal with that in LLVM itself. While I agree that additional bitcode is a hassle, I think it would be a net positive change for LLVM usability for NVPTX users. The external bitcode would not be required for those who do not need libdevice now, so the change should not be disruptive.> > > LLVM does not need to know or care about what's provided by libdevice, > and > > we'd have more flexibility, compared to what we could do in the mapping > > pass. It also makes it easy to substitute a different implementation, if > we > > have or need one. > > I agree that LLVM (core) should not know about __nv_*, that's why I > suggested > the `__attribute__((implements("...")))` approach. My preferred solution > is still to annotate our declarations of __nv_* and point to the > llvm.intrinsics (name) from there. If we have a missing mapping, we > point to an > intrinsic from a definition that lives in the Clang headers next to the > __nv_* declarations. >We may have slightly different end goals in mind. I was thinking of making the solution work for LLVM. I.e. users would be free to use llvm.sin with NVPTX back-end with a few documented steps needed to make it work (basically "pass additional -link-libm-bitcode=path/to/bitcode_libm.bc"). Your scenario above suggests that the goal is to allow clang to generate both llvm intrinsics and the glue which would then be used by LLVM to make it work for clang, but not in general. It's an improvement compared to what we have now, but I still think we should try a more general solution.> > This does not yet work because -mlink-builtin-bitcode (which I assume > triggers the llvm-link logic) will drop the attributes of a declaration > if a definition is found. I think that should not be the case anyway > such that the union of attributes is set. > > The benefit I see for the above is that the mapping is tied to the > declarations and doesn't live in a tablegen file far away. It works well > even if we can't map 1:1, and we could even restrict the "used" attribute > to anything that has an "implements" attribute.I do not think we need tablegen for anything here. I was thinking of just compiling a real math library (or a wrapper on top of libdevice) from C/C++ sources. Our approaches are not mutually exclusive. If there's a strong opposition to providing a bitcode libm for NVPTX, implementing it somewhere closer to clang would still be an improvement, even if it's not as general as I'd like. It should still be possible to allow LLVM to lower libcalls in NVPTX to standard libm API, enabled with a flag, and just let the end users who are interested (e.g. JITs) to provide their own implementation. --Artem> So: > > ``` > __nv_A() { ... } // called, inlined and optimized as before, DCE'ed after. > > __nv_B() { ... } // not called, DCE'ed. > > __attribute__((implements("llvm.C")) > __nv_C() { ... } // calls are inlined and optimized as before, not DCE'ed > // though because of the attribute. Replaces llvm.C as > // callee in the special pass. > ``` > > So "implements" gives you a way to statically replace a function > declaration > or definition with another one. I could see it being used to provide other > intrinsics to platforms with backends that don't support them. > > Does that make some sense? > > ~ Johannes > > > > > > WDYT? > > > > --Artem > > > > > >> > >> On 3/10/21 8:44 PM, William Moses wrote: > >>> We could also consider doing something slightly broader. > >>> > >>> For example we could define a special attribute on top of the llvm.cos > >>> call/declaration etc with metadata or an attribute that points to the > >>> actual __nv_cos function. Then in a subsequent lowering pass the > >>> corresponding intrinsic with the relevant attribute has its uses > replaced > >>> by the actual function. > >>> > >>> > >>> On Wed, Mar 10, 2021 at 7:57 PM Johannes Doerfert < > >>> johannesdoerfert at gmail.com> wrote: > >>> > >>>> On 3/10/21 6:22 PM, Artem Belevich wrote: > >>>>> On Wed, Mar 10, 2021 at 3:44 PM Johannes Doerfert < > >>>>> johannesdoerfert at gmail.com> wrote: > >>>>> > >>>>>> On 3/10/21 4:38 PM, Artem Belevich wrote: > >>>>>>> On Wed, Mar 10, 2021 at 1:55 PM Johannes Doerfert < > >>>>>>> johannesdoerfert at gmail.com> wrote: > >>>>>>> > >>>>>>>> On 3/10/21 3:25 PM, Artem Belevich wrote: > >>>>>>>>> On Wed, Mar 10, 2021 at 12:57 PM Johannes Doerfert < > >>>>>>>>> johannesdoerfert at gmail.com> wrote: > >>>>>>>>> > >>>>>>>>>> Right. We could keep the definition of __nv_cos and friends > >>>>>>>>>> around. Right now, -ffast-math might just crash on the user, > >>>>>>>>>> which is arguably a bad thing. I can also see us benefiting > >>>>>>>>>> in various other ways from llvm.cos uses instead of __nv_cos > >>>>>>>>>> (assuming precision is according to the user requirements but > >>>>>>>>>> that is always a condition). > >>>>>>>>>> > >>>>>>>>>> It could be as simple as introducing __nv_cos into > >>>>>>>>>> "llvm.used" and a backend matching/rewrite pass. > >>>>>>>>>> > >>>>>>>>>> If the backend knew the libdevice location it could even pick > >>>>>>>>>> the definitions from there. Maybe we could link libdevice late > >>>>>>>>>> instead of eager? > >>>>>>>>>> > >>>>>>>>> It's possible, but it would require plumbing in CUDA SDK > awareness > >>>> into > >>>>>>>>> LLVM. While clang driver can deal with that, LLVM currently > can't. > >>>> The > >>>>>>>>> bitcode library path would have to be provided by the user. > >>>>>>>> The PTX backend could arguably be CUDA SDK aware, IMHO, it would > >>>>>>>> even be fine if the middle-end does the remapping to get inlining > >>>>>>>> and folding benefits also after __nv_cos is used. See below. > >>>>>>>> > >>>>>>>> > >>>>>>>>> The standard library as bitcode raises some questions. > >>>>>>>> Which standard library? CUDAs libdevice is a bitcode library, > right? > >>>>>>>> > >>>>>>> It's whatever LLVM will need to lower libcalls to. libdevice > bitcode > >> is > >>>>>> the > >>>>>>> closest approximation of that we have at the moment. > >>>>>>> > >>>>>>> > >>>>>>>>> * When do we want to do the linking? If we do it at the > beginning, > >>>> then > >>>>>>>> the > >>>>>>>>> question is how to make sure unused functions are not eliminated > >>>> before > >>>>>>>> we > >>>>>>>>> may need them, as we don't know apriori what's going to be > needed. > >> We > >>>>>>>> also > >>>>>>>>> do want the unused functions to be gone after we're done. Linking > >> it > >>>> in > >>>>>>>>> early would allow optimizing the code better at the expense of > >> having > >>>>>> to > >>>>>>>>> optimize a lot of code we'll throw away. Linking it in late has > >> less > >>>>>>>>> overhead, but leaves the linked in bitcode unoptimized, though > it's > >>>>>>>>> probably in the ballpark of what would happen with a real library > >>>> call. > >>>>>>>>> I.e. no inlining, etc. > >>>>>>>>> > >>>>>>>>> * It incorporates linking into LLVM, which is not LLVM's job. > >>>> Arguably, > >>>>>>>> the > >>>>>>>>> line should be drawn at the lowering to libcalls as it's done for > >>>> other > >>>>>>>>> back-ends. However, we're also constrained to by the need to have > >> the > >>>>>>>>> linking done before we generate PTX which prevents doing it after > >>>> LLVM > >>>>>> is > >>>>>>>>> done generating an object file. > >>>>>>>> I'm confused. Clang links in libdevice.bc early. > >>>>>>> Yes. Because that's where it has to happen if we want to keep LLVM > >>>>>> unaware > >>>>>>> of CUDA SDK. > >>>>>>> It does not have to be the case if/when LLVM can do the linking > >> itself. > >>>>>>> > >>>>>>>> If we make sure > >>>>>>>> `__nv_cos` is not deleted early, we can at any point "lower" > >>>> `llvm.cos` > >>>>>>>> to `__nv_cos` which is available. After the lowering we can remove > >>>>>>>> the artificial uses of `__nv_XXX` functions that we used to keep > the > >>>>>>>> definitions around in order to remove them from the final result. > >>>>>>>> > >>>>>>> This is the 'link early' approach, I should've been explicit that > >> it's > >>>>>>> 'link early *everything*' as opposed to linking only what's needed > at > >>>> the > >>>>>>> beginning. > >>>>>>> It would work at the expense of having to process/optimize 500KB > >> worth > >>>> of > >>>>>>> bitcode for every compilation, whether it needs it or not. > >>>>>>> > >>>>>>> > >>>>>>>> We get the benefit of having `llvm.cos` for some of the pipeline, > >>>>>>>> we know it does not have all the bad effects while `__nv_cos` is > >>>> defined > >>>>>>>> with inline assembly. We also get the benefit of inlining > `__nv_cos` > >>>>>>>> and folding the implementation based on the arguments. Finally, > >>>>>>>> this should work with the existing pipeline, the linking is the > same > >>>>>>>> as before, all we do is to keep the definitions alive longer and > >>>>>>>> lower `llvm.cos` to `__nv_cos` in a middle end pass. > >>>>>>>> > >>>>>>> Again, I agree that it is doable. > >>>>>>> > >>>>>>> > >>>>>>> > >>>>>>>> This might be similar to the PTX solution you describe below but I > >>>> feel > >>>>>>>> we get the inline benefit from this without actually changing the > >>>>>> pipeline > >>>>>>>> at all. > >>>>>>>> > >>>>>>> So, to summarize: > >>>>>>> * link the library as bitcode early, add artificial placeholders > for > >>>>>>> everything, compile, remove placeholders and DCE unused stuff away. > >>>>>>> Pros: > >>>>>>> - we're already doing most of it before clang hands hands > off > >>>> IR to > >>>>>>> LLVM, so it just pushes it a bit lower in the compilation. > >>>>>>> Cons: > >>>>>>> - runtime cost of optimizing libdevice bitcode, > >>>>>>> - libdevice may be required for all NVPTX compilations? > >>>>>>> > >>>>>>> * link the library as bitcode late. > >>>>>>> Pros: > >>>>>>> - lower runtime cost than link-early approach. > >>>>>>> Cons: > >>>>>>> - We'll need to make sure that NVVMReflect pass processes > the > >>>>>> library. > >>>>>>> - less optimizations on the library functions. Some of the > >> code > >>>>>> gets > >>>>>>> DCE'ed away after NVVMReflect and the rest could be optimized > better. > >>>>>>> - libdevice may be required for all NVPTX compilations? > >>>>>>> * 'link' with the library as PTX appended as text to LLVM's output > >> and > >>>>>> let > >>>>>>> ptxas do the 'linking' > >>>>>>> Pros: LLVM remains agnostic of CUDA SDK installation > details. > >> All > >>>> it > >>>>>>> does is allows lowering libcalls and leaves their resolution to the > >>>>>>> external tools. > >>>>>>> Cons: Need to have the PTX library somewhere and need to > >> integrate > >>>> the > >>>>>>> 'linking' into the compilation process somehow. > >>>>>>> > >>>>>>> Neither is particularly good. If the runtime overhead of link-early > >> is > >>>>>>> acceptable, then it may be a winner here, by a very small margin. > >>>>>>> link-as-PTX may be better conceptually as it keeps linking and > >>>>>> compilation > >>>>>>> separate. > >>>>>>> > >>>>>>> As for the practical steps, here's what we need: > >>>>>>> - allow libcall lowering in NVPTX, possibly guarded by a flag. This > >> is > >>>>>>> needed for all of the approaches above. > >>>>>>> - teach LLVM how to link in bitcode (and, possibly, control > >> early/late > >>>>>> mode) > >>>>>>> - teach clang driver to delegate libdevice linking to LLVM. > >>>>>>> > >>>>>>> This will allow us to experiment with all three approaches and see > >> what > >>>>>>> works best. > >>>>>> I think if we embed knowledge about the nv_XXX functions we can > >>>>>> even get away without the cons you listed for early linking above. > >>>>>> > >>>>> WDYM by `embed knowledge about the nv_XXX functions`? By linking > those > >>>>> functions in? Of do you mean that we should just declare them > >>>>> before/instead of linking libdevice in? > >>>> I mean by providing the "libcall lowering" pass. So the knowledge > >>>> that llvm.cos maps to __nv_cos. > >>>> > >>>>>> For early link I'm assuming an order similar to [0] but I also > discuss > >>>>>> the case where we don't link libdevice early for a TU. > >>>>>> > >>>>> That link just describes the steps needed to use libdevice. It does > not > >>>>> deal with how/where it fits in the LLVM pipeline. > >>>>> The gist is that NVVMreflect replaces some conditionals with > constants. > >>>>> libdevice uses that as a poor man's IR preprocessor, conditionally > >>>> enabling > >>>>> different implementations and relying on DCE and constant folding to > >>>> remove > >>>>> unused parts and eliminate the now useless branches. > >>>>> While running NVVM alone will make libdevice code valid and usable, > it > >>>>> would still benefit from further optimizations. I do not know to what > >>>>> degree, though. > >>>>> > >>>>> > >>>>>> Link early: > >>>>>> 1) clang emits module.bc and links in libdevice.bc but with the > >>>>>> `optnone`, `noinline`, and "used" attribute for functions in > >>>>>> libdevice. ("used" is not an attribute but could as well be.) > >>>>>> At this stage module.bc might call __nv_XXX or llvm.XXX > freely > >>>>>> as defined by -ffast-math and friends. > >>>>>> > >>>>> That could work. Just carrying extra IR around would probably be OK. > >>>>> We may want to do NVVMReflect as soon as we have it linked in and, > >> maybe, > >>>>> allow optimizing the functions that are explicitly used already. > >>>> Right. NVVMReflect can be run twice and with `alwaysinline` > >>>> on the call sites of __nv_XXX functions we will actually > >>>> inline and optimize them while the definitions are just "dragged > >>>> along" in case we need them later. > >>>> > >>>> > >>>>>> 2) Run some optimizations in the middle end, maybe till the end of > >>>>>> the inliner loop, unsure. > >>>>>> 3) Run a libcall lowering pass and another NVVMReflect pass (or the > >>>>>> only instance thereof). We effectively remove all llvm.XXX > calls > >>>>> in favor of __nv_XXX now. Note that we haven't spend (much) > time > >>>>>> on the libdevice code as it is optnone and most passes are > good > >>>>>> at skipping those. To me, it's unclear if the used parts > should > >>>>>> not be optimized before we inline them anyway to avoid > redoing > >>>>>> the optimizations over and over (per call site). That needs > >>>>>> measuring I guess. Also note that we can still retain the > >> current > >>>>>> behavior for direct calls to __nv_XXX if we mark the call > sites > >>>>>> as `alwaysinline`, or at least the behavior is almost like > the > >>>>>> current one is. > >>>>>> 4) Run an always inliner pass on the __nv_XXX calls because it is > >>>>>> something we would do right now. Alternatively, remove > `optnone` > >>>>>> and `noinline` from the __nv_XXX calls. > >>>>>> 5) Continue with the pipeline as before. > >>>>>> > >>>>>> > >>>>> SGTM. > >>>>> > >>>>> > >>>>>> As mentioned above, `optnone` avoids spending time on the libdevice > >>>>>> until we "activate" it. At that point (globals) DCE can be scheduled > >>>>>> to remove all unused parts right away. I don't think this is (much) > >>>>>> more expensive than linking libdevice early right now. > >>>>>> > >>>>>> Link late, aka. translation units without libdevice: > >>>>>> 1) clang emits module.bc but does not link in libdevice.bc, it will > be > >>>>>> made available later. We still can mix __nv_XXX and llvm.XXX > >> calls > >>>>>> freely as above. > >>>>>> 2) Same as above. > >>>>>> 3) Same as above. > >>>>>> 4) Same as above but effectively a no-op, no __nv_XXX definitions > are > >>>>>> available. > >>>>>> 5) Same as above. > >>>>>> > >>>>>> > >>>>>> I might misunderstand something about the current pipeline but from > >> [0] > >>>>>> and the experiments I run locally it looks like the above should > cover > >>>> all > >>>>>> the cases. WDYT? > >>>>>> > >>>>>> > >>>>> The `optnone` trick may indeed remove much of the practical > differences > >>>>> between the early/late approaches. > >>>>> In principle it should work. > >>>>> > >>>>> Next question is -- is libdevice sufficient to satisfy LLVM's > >> assumptions > >>>>> about the standard library. > >>>>> While it does provide most of the equivalents of libm functions, the > >> set > >>>> is > >>>>> not complete and some of the functions differ from their libm > >>>> counterparts. > >>>>> The differences are minor, so we should be able to deal with it by > >>>>> generating few wrapper functions for the odd cases. > >>>>> Here's what clang does to provide math functions using libdevice: > >>>>> > >> > https://github.com/llvm/llvm-project/blob/main/clang/lib/Headers/__clang_cuda_math.h > >>>> Right now, clang will generate any llvm intrinsic and we crash, so > >> anything > >>>> else is probably a step in the right direction. Eventually, we should > >>>> "lower" > >>>> all intrinsics that the NVPTX backend can't handle or at least emit a > >> nice > >>>> error message. Preferably, clang would know what we can't deal with > and > >> not > >>>> generate intinsic calls for those in the first place. > >>>> > >>>> > >>>>> The most concerning aspect of libdevice is that we don't know when > >> we'll > >>>> no > >>>>> longer be able to use the libdevice bitcode? My understanding is that > >> IR > >>>>> does not guarantee binary stability and at some point we may just be > >>>> unable > >>>>> to use it. Ideally we need our own libm for GPUs. > >>>> For OpenMP I did my best to avoid writing libm (code) for GPUs by > piggy > >>>> backing on CUDA and libc++ implementations, I hope it will stay that > >> way. > >>>> That said, if the need arises we might really have to port libc++ to > the > >>>> GPUs. > >>>> > >>>> Back to the problem with libdevice. I agree that the solution of > NVIDIA > >>>> to ship a .bc library is suboptimal but with the existing, or an > >> extended, > >>>> auto-upgrader we might be able to make that work reasonably well for > the > >>>> foreseeable future. That problem is orthogonal to what we are > discussing > >>>> above, I think. > >>>> > >>>> ~ Johannes > >>>> > >>>> > >>>>> --Artem > >>>>> > >>>>> > >>>>>> ~ Johannes > >>>>>> > >>>>>> > >>>>>> P.S. If the rewrite capability (aka libcall lowering) is generic we > >>>> could > >>>>>> use the scheme for many other things as well. > >>>>>> > >>>>>> > >>>>>> [0] https://llvm.org/docs/NVPTXUsage.html#linking-with-libdevice > >>>>>> > >>>>>> > >>>>>>> --Artem > >>>>>>> > >>>>>>> > >>>>>>>> ~ Johannes > >>>>>>>> > >>>>>>>> > >>>>>>>>> One thing that may work within the existing compilation model is > to > >>>>>>>>> pre-compile the standard library into PTX and then textually > embed > >>>>>>>> relevant > >>>>>>>>> functions into the generated PTX, thus pushing the 'linking' > phase > >>>> past > >>>>>>>> the > >>>>>>>>> end of LLVM's compilation and make it look closer to the standard > >>>>>>>>> compile/link process. This way we'd only enable libcall lowering > in > >>>>>>>> NVPTX, > >>>>>>>>> assuming that the library functions will be magically available > out > >>>>>>>> there. > >>>>>>>>> Injection of PTX could be done with an external script outside of > >>>> LLVM > >>>>>>>> and > >>>>>>>>> it could be incorporated into clang driver. Bonus points for the > >> fact > >>>>>>>> that > >>>>>>>>> this scheme is compatible with -fgpu-rdc out of the box -- > assemble > >>>> the > >>>>>>>> PTX > >>>>>>>>> with `ptxas -rdc` and then actually link with the library, > instead > >> of > >>>>>>>>> injecting its PTX before invoking ptxas. > >>>>>>>>> > >>>>>>>>> --Artem > >>>>>>>>> > >>>>>>>>> Trying to figure out a good way to have the cake and eat it too. > >>>>>>>>>> ~ Johannes > >>>>>>>>>> > >>>>>>>>>> > >>>>>>>>>> On 3/10/21 2:49 PM, William Moses wrote: > >>>>>>>>>>> Since clang (and arguably any other frontend that uses) should > >> link > >>>>>> in > >>>>>>>>>>> libdevice, could we lower these intrinsics to the libdevice > code? > >>>>>>>>> The linking happens *before* LLVM gets to work on IR. > >>>>>>>>> As I said, it's a workaround, not the solution. It's possible for > >>>> LLVM > >>>>>> to > >>>>>>>>> still attempt lowering something in the IR into a libcall and we > >>>> would > >>>>>>>> not > >>>>>>>>> be able to deal with that. It happens to work well enough in > >>>> practice. > >>>>>>>>> Do you have an example where you see the problem with > -ffast-math? > >>>>>>>>> > >>>>>>>>> > >>>>>>>>> > >>>>>>>>>>> For example, consider compiling the simple device function > below: > >>>>>>>>>>> > >>>>>>>>>>> ``` > >>>>>>>>>>> // /mnt/sabrent/wmoses/llvm13/build/bin/clang tmp.cu -S > >> -emit-llvm > >>>>>>>>>>> --cuda-path=/usr/local/cuda-11.0 > >> -L/usr/local/cuda-11.0/lib64 > >>>>>>>>>>> --cuda-gpu-arch=sm_37 > >>>>>>>>>>> __device__ double f(double x) { > >>>>>>>>>>> return cos(x); > >>>>>>>>>>> } > >>>>>>>>>>> ``` > >>>>>>>>>>> > >>>>>>>>>>> The LLVM module for it is as follows: > >>>>>>>>>>> > >>>>>>>>>>> ``` > >>>>>>>>>>> ... > >>>>>>>>>>> define dso_local double @_Z1fd(double %x) #0 { > >>>>>>>>>>> entry: > >>>>>>>>>>> %__a.addr.i = alloca double, align 8 > >>>>>>>>>>> %x.addr = alloca double, align 8 > >>>>>>>>>>> store double %x, double* %x.addr, align 8 > >>>>>>>>>>> %0 = load double, double* %x.addr, align 8 > >>>>>>>>>>> store double %0, double* %__a.addr.i, align 8 > >>>>>>>>>>> %1 = load double, double* %__a.addr.i, align 8 > >>>>>>>>>>> %call.i = call contract double @__nv_cos(double %1) #7 > >>>>>>>>>>> ret double %call.i > >>>>>>>>>>> } > >>>>>>>>>>> > >>>>>>>>>>> define internal double @__nv_cos(double %a) #1 { > >>>>>>>>>>> %q.i = alloca i32, align 4 > >>>>>>>>>>> ``` > >>>>>>>>>>> > >>>>>>>>>>> Obviously we would need to do something to ensure these > functions > >>>>>> don't > >>>>>>>>>> get > >>>>>>>>>>> deleted prior to their use in lowering from intrinsic to > >> libdevice. > >>>>>>>>>>> ... > >>>>>>>>>>> > >>>>>>>>>>> > >>>>>>>>>>> On Wed, Mar 10, 2021 at 3:39 PM Artem Belevich <tra at google.com > > > >>>>>> wrote: > >>>>>>>>>>>> On Wed, Mar 10, 2021 at 11:41 AM Johannes Doerfert < > >>>>>>>>>>>> johannesdoerfert at gmail.com> wrote: > >>>>>>>>>>>> > >>>>>>>>>>>>> Artem, Justin, > >>>>>>>>>>>>> > >>>>>>>>>>>>> I am running into a problem and I'm curious if I'm missing > >>>>>> something > >>>>>>>> or > >>>>>>>>>>>>> if the support is simply missing. > >>>>>>>>>>>>> Am I correct to assume the NVPTX backend does not deal with > >>>>>>>> `llvm.sin` > >>>>>>>>>>>>> and friends? > >>>>>>>>>>>>> > >>>>>>>>>>>> Correct. It can't deal with anything that may need to lower > to a > >>>>>>>>>> standard > >>>>>>>>>>>> library call. > >>>>>>>>>>>> > >>>>>>>>>>>>> This is what I see, with some variations: > >>>>>>>> https://godbolt.org/z/PxsEWs > >>>>>>>>>>>>> If this is missing in the backend, is there a plan to get > this > >>>>>>>> working, > >>>>>>>>>>>>> I'd really like to have the > >>>>>>>>>>>>> intrinsics in the middle end rather than __nv_cos, not to > >> mention > >>>>>>>> that > >>>>>>>>>>>>> -ffast-math does emit intrinsics > >>>>>>>>>>>>> and crashes. > >>>>>>>>>>>>> > >>>>>>>>>>>> It all boils down to the fact that PTX does not have the > >> standard > >>>>>>>>>>>> libc/libm which LLVM could lower the calls to, nor does it > have > >> a > >>>>>>>>>> 'linking' > >>>>>>>>>>>> phase where we could link such a library in, if we had it. > >>>>>>>>>>>> > >>>>>>>>>>>> Libdevice bitcode does provide the implementations for some of > >> the > >>>>>>>>>>>> functions (though with a __nv_ prefix) and clang links it in > in > >>>>>> order > >>>>>>>> to > >>>>>>>>>>>> avoid generating IR that LLVM can't handle, but that's a > >>>> workaround > >>>>>>>> that > >>>>>>>>>>>> does not help LLVM itself. > >>>>>>>>>>>> > >>>>>>>>>>>> --Artem > >>>>>>>>>>>> > >>>>>>>>>>>> > >>>>>>>>>>>> > >>>>>>>>>>>>> ~ Johannes > >>>>>>>>>>>>> > >>>>>>>>>>>>> > >>>>>>>>>>>>> -- > >>>>>>>>>>>>> ─────────────────── > >>>>>>>>>>>>> ∽ Johannes (he/his) > >>>>>>>>>>>>> > >>>>>>>>>>>>> > >>>>>>>>>>>> -- > >>>>>>>>>>>> --Artem Belevich > >>>>>>>>>>>> > > >-- --Artem Belevich -------------- next part -------------- An HTML attachment was scrubbed... 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