Craig Topper via llvm-dev
2018-Jul-23 22:22 UTC
[llvm-dev] [LoopVectorizer] Improving the performance of dot product reduction loop
Hello all, This code https://godbolt.org/g/tTyxpf is a dot product reduction loop multipying sign extended 16-bit values to produce a 32-bit accumulated result. The x86 backend is currently not able to optimize it as well as gcc and icc. The IR we are getting from the loop vectorizer has several v8i32 adds and muls inside the loop. These are fed by v8i16 loads and sexts from v8i16 to v8i32. The x86 backend recognizes that these are addition reductions of multiplication so we use the vpmaddwd instruction which calculates 32-bit products from 16-bit inputs and does a horizontal add of adjacent pairs. A vpmaddwd given two v8i16 inputs will produce a v4i32 result. In the example code, because we are reducing the number of elements from 8->4 in the vpmaddwd step we are left with a width mismatch between vpmaddwd and the vpaddd instruction that we use to sum with the results from the previous loop iterations. We rely on the fact that a 128-bit vpmaddwd zeros the upper bits of the register so that we can use a 256-bit vpaddd instruction so that the upper elements can keep going around the loop without being disturbed in case they weren't initialized to 0. But this still means the vpmaddwd instruction is doing half the amount of work the CPU is capable of if we had been able to use a 256-bit vpmaddwd instruction. Additionally, future x86 CPUs will be gaining an instruction that can do VPMADDWD and VPADDD in one instruction, but that width mismatch makes that instruction difficult to utilize. In order for the backend to handle this better it would be great if we could have something like two v32i8 loads, two shufflevectors to extract the even elements and the odd elements to create four v16i8 pieces.Sign extend each of those pieces. Multiply the two even pieces and the two odd pieces separately, sum those results with a v8i32 add. Then another v8i32 add to accumulate the previous loop iterations. Then ensures that no pieces exceed the target vector width and the final operation is correctly sized to go around the loop in one register. All but the last add can then be pattern matched to vpmaddwd as proposed in https://reviews.llvm.org/D49636. And for the future CPU the whole thing can be matched to the new instruction. Do other targets have a similar instruction or a similar issue to this? Is this something we can solve in the loop vectorizer? Or should we have a separate IR transformation that can recognize this pattern and generate the new sequence? As a separate pass we would need to pair two vector loads together, remove a reduction step outside the loop and remove half the phis assuming the loop was partially unrolled. Or if there was only one add/mul inside the loop we'd have to reduce its width and the width of the phi. Thanks, ~Craig -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180723/8e50d952/attachment.html>
Hal Finkel via llvm-dev
2018-Jul-23 23:23 UTC
[llvm-dev] [LoopVectorizer] Improving the performance of dot product reduction loop
On 07/23/2018 05:22 PM, Craig Topper wrote:> Hello all, > > This code https://godbolt.org/g/tTyxpf is a dot product reduction loop > multipying sign extended 16-bit values to produce a 32-bit accumulated > result. The x86 backend is currently not able to optimize it as well > as gcc and icc. The IR we are getting from the loop vectorizer has > several v8i32 adds and muls inside the loop. These are fed by v8i16 > loads and sexts from v8i16 to v8i32. The x86 backend recognizes that > these are addition reductions of multiplication so we use the vpmaddwd > instruction which calculates 32-bit products from 16-bit inputs and > does a horizontal add of adjacent pairs. A vpmaddwd given two v8i16 > inputs will produce a v4i32 result. > > In the example code, because we are reducing the number of elements > from 8->4 in the vpmaddwd step we are left with a width mismatch > between vpmaddwd and the vpaddd instruction that we use to sum with > the results from the previous loop iterations. We rely on the fact > that a 128-bit vpmaddwd zeros the upper bits of the register so that > we can use a 256-bit vpaddd instruction so that the upper elements can > keep going around the loop without being disturbed in case they > weren't initialized to 0. But this still means the vpmaddwd > instruction is doing half the amount of work the CPU is capable of if > we had been able to use a 256-bit vpmaddwd instruction. Additionally, > future x86 CPUs will be gaining an instruction that can do VPMADDWD > and VPADDD in one instruction, but that width mismatch makes that > instruction difficult to utilize. > > In order for the backend to handle this better it would be great if we > could have something like two v32i8 loads, two shufflevectors to > extract the even elements and the odd elements to create four v16i8 > pieces.Why v*i8 loads? I thought that we have 16-bit and 32-bit types here?> Sign extend each of those pieces. Multiply the two even pieces and the > two odd pieces separately, sum those results with a v8i32 add. Then > another v8i32 add to accumulate the previous loop iterations. Then > ensures that no pieces exceed the target vector width and the final > operation is correctly sized to go around the loop in one register. > All but the last add can then be pattern matched to vpmaddwd as > proposed in https://reviews.llvm.org/D49636. And for the future CPU > the whole thing can be matched to the new instruction. > > Do other targets have a similar instruction or a similar issue to > this? Is this something we can solve in the loop vectorizer? Or should > we have a separate IR transformation that can recognize this pattern > and generate the new sequence? As a separate pass we would need to > pair two vector loads together, remove a reduction step outside the > loop and remove half the phis assuming the loop was partially > unrolled. Or if there was only one add/mul inside the loop we'd have > to reduce its width and the width of the phi.Can you explain how the desired code from the vectorizer differs from the code that the vectorizer produces if you add '#pragma clang loop vectorize(enable) vectorize_width(16)' above the loop? I tried it in your godbolt example and the generated code looks very similar to the icc-generated code. Thanks again, Hal> > Thanks, > ~Craig-- Hal Finkel Lead, Compiler Technology and Programming Languages Leadership Computing Facility Argonne National Laboratory -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180723/21f45a42/attachment.html>
Hal Finkel via llvm-dev
2018-Jul-23 23:34 UTC
[llvm-dev] [LoopVectorizer] Improving the performance of dot product reduction loop
On 07/23/2018 06:23 PM, Hal Finkel via llvm-dev wrote:> > On 07/23/2018 05:22 PM, Craig Topper wrote: >> Hello all, >> >> This code https://godbolt.org/g/tTyxpf is a dot product reduction >> loop multipying sign extended 16-bit values to produce a 32-bit >> accumulated result. The x86 backend is currently not able to optimize >> it as well as gcc and icc. The IR we are getting from the loop >> vectorizer has several v8i32 adds and muls inside the loop. These are >> fed by v8i16 loads and sexts from v8i16 to v8i32. The x86 backend >> recognizes that these are addition reductions of multiplication so we >> use the vpmaddwd instruction which calculates 32-bit products from >> 16-bit inputs and does a horizontal add of adjacent pairs. A vpmaddwd >> given two v8i16 inputs will produce a v4i32 result. >> >> In the example code, because we are reducing the number of elements >> from 8->4 in the vpmaddwd step we are left with a width mismatch >> between vpmaddwd and the vpaddd instruction that we use to sum with >> the results from the previous loop iterations. We rely on the fact >> that a 128-bit vpmaddwd zeros the upper bits of the register so that >> we can use a 256-bit vpaddd instruction so that the upper elements >> can keep going around the loop without being disturbed in case they >> weren't initialized to 0. But this still means the vpmaddwd >> instruction is doing half the amount of work the CPU is capable of if >> we had been able to use a 256-bit vpmaddwd instruction. Additionally, >> future x86 CPUs will be gaining an instruction that can do VPMADDWD >> and VPADDD in one instruction, but that width mismatch makes that >> instruction difficult to utilize. >> >> In order for the backend to handle this better it would be great if >> we could have something like two v32i8 loads, two shufflevectors to >> extract the even elements and the odd elements to create four v16i8 >> pieces. > > Why v*i8 loads? I thought that we have 16-bit and 32-bit types here? > >> Sign extend each of those pieces. Multiply the two even pieces and >> the two odd pieces separately, sum those results with a v8i32 add. >> Then another v8i32 add to accumulate the previous loop iterations. >> Then ensures that no pieces exceed the target vector width and the >> final operation is correctly sized to go around the loop in one >> register. All but the last add can then be pattern matched to >> vpmaddwd as proposed in https://reviews.llvm.org/D49636. And for the >> future CPU the whole thing can be matched to the new instruction. >> >> Do other targets have a similar instruction or a similar issue to >> this? Is this something we can solve in the loop vectorizer? Or >> should we have a separate IR transformation that can recognize this >> pattern and generate the new sequence? As a separate pass we would >> need to pair two vector loads together, remove a reduction step >> outside the loop and remove half the phis assuming the loop was >> partially unrolled. Or if there was only one add/mul inside the loop >> we'd have to reduce its width and the width of the phi. > > Can you explain how the desired code from the vectorizer differs from > the code that the vectorizer produces if you add '#pragma clang loop > vectorize(enable) vectorize_width(16)' above the loop? I tried it in > your godbolt example and the generated code looks very similar to the > icc-generated code.(specifically, I mean this: https://godbolt.org/g/LJA38e)> > Thanks again, > Hal > >> >> Thanks, >> ~Craig > > -- > Hal Finkel > Lead, Compiler Technology and Programming Languages > Leadership Computing Facility > Argonne National Laboratory > > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev-- Hal Finkel Lead, Compiler Technology and Programming Languages Leadership Computing Facility Argonne National Laboratory -------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180723/ac36030b/attachment.html>
Craig Topper via llvm-dev
2018-Jul-23 23:37 UTC
[llvm-dev] [LoopVectorizer] Improving the performance of dot product reduction loop
~Craig On Mon, Jul 23, 2018 at 4:24 PM Hal Finkel <hfinkel at anl.gov> wrote:> > On 07/23/2018 05:22 PM, Craig Topper wrote: > > Hello all, > > This code https://godbolt.org/g/tTyxpf is a dot product reduction loop > multipying sign extended 16-bit values to produce a 32-bit accumulated > result. The x86 backend is currently not able to optimize it as well as gcc > and icc. The IR we are getting from the loop vectorizer has several v8i32 > adds and muls inside the loop. These are fed by v8i16 loads and sexts from > v8i16 to v8i32. The x86 backend recognizes that these are addition > reductions of multiplication so we use the vpmaddwd instruction which > calculates 32-bit products from 16-bit inputs and does a horizontal add of > adjacent pairs. A vpmaddwd given two v8i16 inputs will produce a v4i32 > result. > >That godbolt link seems wrong. It wasn't supposed to be clang IR. This should be right.> > In the example code, because we are reducing the number of elements from > 8->4 in the vpmaddwd step we are left with a width mismatch between > vpmaddwd and the vpaddd instruction that we use to sum with the results > from the previous loop iterations. We rely on the fact that a 128-bit > vpmaddwd zeros the upper bits of the register so that we can use a 256-bit > vpaddd instruction so that the upper elements can keep going around the > loop without being disturbed in case they weren't initialized to 0. But > this still means the vpmaddwd instruction is doing half the amount of work > the CPU is capable of if we had been able to use a 256-bit vpmaddwd > instruction. Additionally, future x86 CPUs will be gaining an instruction > that can do VPMADDWD and VPADDD in one instruction, but that width mismatch > makes that instruction difficult to utilize. > > In order for the backend to handle this better it would be great if we > could have something like two v32i8 loads, two shufflevectors to extract > the even elements and the odd elements to create four v16i8 pieces. > > > Why v*i8 loads? I thought that we have 16-bit and 32-bit types here? >Oops that should have been v16i16. Mixed up my 256-bit types.> > Sign extend each of those pieces. Multiply the two even pieces and the two > odd pieces separately, sum those results with a v8i32 add. Then another > v8i32 add to accumulate the previous loop iterations. Then ensures that no > pieces exceed the target vector width and the final operation is correctly > sized to go around the loop in one register. All but the last add can then > be pattern matched to vpmaddwd as proposed in > https://reviews.llvm.org/D49636. And for the future CPU the whole thing > can be matched to the new instruction. > > Do other targets have a similar instruction or a similar issue to this? Is > this something we can solve in the loop vectorizer? Or should we have a > separate IR transformation that can recognize this pattern and generate the > new sequence? As a separate pass we would need to pair two vector loads > together, remove a reduction step outside the loop and remove half the phis > assuming the loop was partially unrolled. Or if there was only one add/mul > inside the loop we'd have to reduce its width and the width of the phi. > > > Can you explain how the desired code from the vectorizer differs from the > code that the vectorizer produces if you add '#pragma clang loop > vectorize(enable) vectorize_width(16)' above the loop? I tried it in your > godbolt example and the generated code looks very similar to the > icc-generated code. >It's similar, but the vpxor %xmm0, %xmm0, %xmm0 is being unnecessarily carried across the loop. It's then redundantly added twice in the reduction after the loop despite it being 0. This happens because we basically tricked the backend into generating a 256-bit vpmaddwd concated with a 256-bit zero vector going into a 512-bit vaddd before type legalization. The 512-bit concat and vpaddd get split during type legalization, and the high half of the add gets constant folded away. I'm guessing we probably finished with 4 vpxors before the loop but MachineCSE(or some other pass?) combined two of them when it figured out the loop didn't modify them.> > Thanks again, > Hal > > > Thanks, > ~Craig > > > -- > Hal Finkel > Lead, Compiler Technology and Programming Languages > Leadership Computing Facility > Argonne National Laboratory > >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20180723/51426c1f/attachment.html>
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