Cong Hou via llvm-dev
2015-Nov-25 23:07 UTC
[llvm-dev] [RFC] Introducing a vector reduction add instruction.
On Wed, Nov 25, 2015 at 2:32 PM, Hal Finkel <hfinkel at anl.gov> wrote:> Hi Cong, > > After reading the original RFC and this update, I'm still not entirely sure I understand the semantics of the flag you're proposing to add. Does it having something to do with the ordering of the reduction operations?The flag is only useful for vectorized reduction for now. I'll give you an example how this flag is used. Given the following reduction loop: int a[N]; int s = 0; for (int i = 0; i < N; ++i) s += a[i]; After it is vectorized, we have a reduction operation add whose operands and the result are vectors. Suppose it is represented as: [s0, s1, s2, s3] = [s0, s1, s2, s3] + [a0, a1, a2, a3]. If we know this operation is a reduction one, then we could have some flexibility on how elements in the result are organized, as long as the sum of them stays the same (the precondition is that the only use of the reduction result is the reduction phi node, and this is usually true as long as a reduction loop can be vectorized). For example, if we let the result be [s0+s1, 0, s2+s3, 0] or [0, 0, s0+s1+s2+s3, 0], the reduction result won't change. This enable us to detect SAD or dot-product patterns and use SSE's psadbw and pmaddwd instructions. Please see my respond to your another email for more details. Thanks! Cong> > Thanks again, > Hal > > ----- Original Message ----- >> From: "Cong Hou via llvm-dev" <llvm-dev at lists.llvm.org> >> To: "llvm-dev" <llvm-dev at lists.llvm.org> >> Cc: "David Li" <davidxl at google.com> >> Sent: Thursday, November 19, 2015 3:12:10 PM >> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add instruction. >> >> After some attempt to implement reduce-add in LLVM, I found out a >> easier way to detect reduce-add without introducing new IR >> operations. >> The basic idea is annotating phi node instead of add (so that it is >> easier to handle other reduction operations). In PHINode class, we >> can >> add a flag indicating if the phi node is a reduction one (the flag >> can >> be set in loop vectorizer for vectorized phi nodes). Then when we >> build SDNode for instruction selection, we detect those reduction phi >> nodes and then annotate reduction operations. This requires an >> additional flag in SDNodeFlags. We can then check this flag when >> combining instructions to detect reduction operations. >> >> In this approach, I have managed to let LLVM compile a SAD loop into >> psadbw instructions. >> >> Source code: >> >> >> const int N = 1024; >> unsigned char a[N], b[N]; >> >> int sad() { >> int s = 0; >> for (int i = 0; i < N; ++i) { >> int res = a[i] - b[i]; >> s += (res > 0) ? res : -res; >> } >> return s; >> } >> >> >> Emitted instructions on X86: >> >> >> >> # BB#0: # %entry >> pxor %xmm0, %xmm0 >> movq $-1024, %rax # imm = 0xFFFFFFFFFFFFFC00 >> pxor %xmm1, %xmm1 >> .align 16, 0x90 >> .LBB0_1: # %vector.body >> # =>This Inner Loop Header: >> Depth=1 >> movd b+1024(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero >> movd a+1024(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero >> psadbw %xmm2, %xmm3 >> paddd %xmm3, %xmm0 >> movd b+1028(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero >> movd a+1028(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero >> psadbw %xmm2, %xmm3 >> paddd %xmm3, %xmm1 >> addq $8, %rax >> jne .LBB0_1 >> # BB#2: # %middle.block >> paddd %xmm0, %xmm1 >> pshufd $78, %xmm1, %xmm0 # xmm0 = xmm1[2,3,0,1] >> paddd %xmm1, %xmm0 >> pshufd $229, %xmm0, %xmm1 # xmm1 = xmm0[1,1,2,3] >> paddd %xmm0, %xmm1 >> movd %xmm1, %eax >> retq >> >> >> Note that due to smaller VF we are using now (currently 4), we could >> not explore the most benefit of psadbw. The patch in >> http://reviews.llvm.org/D8943 has enables us to use bigger VFs based >> on the smallest type in a loop. The follow-up work is refining the >> cost model to let bigger VFs have less cost. For the example above >> the >> best result is from VF >=16. >> >> The draft of the patch is here: http://reviews.llvm.org/D14840 >> >> I will refine the patch later and submit it for review. >> >> >> thanks, >> Cong >> >> >> On Wed, Nov 18, 2015 at 2:45 PM, Cong Hou <congh at google.com> wrote: >> > On Mon, Nov 16, 2015 at 9:31 PM, Shahid, Asghar-ahmad >> > <Asghar-ahmad.Shahid at amd.com> wrote: >> >> Hi Cong, >> >> >> >>> -----Original Message----- >> >>> From: Cong Hou [mailto:congh at google.com] >> >>> Sent: Tuesday, November 17, 2015 12:47 AM >> >>> To: Shahid, Asghar-ahmad >> >>> Cc: David Li >> >>> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add >> >>> instruction. >> >>> >> >>> On Thu, Nov 12, 2015 at 9:37 PM, Shahid, Asghar-ahmad <Asghar- >> >>> ahmad.Shahid at amd.com> wrote: >> >>> > Hi Cong, >> >>> > >> >>> > We had proposed an intrinsic approach to do this. However the >> >>> > discussion reached to a point where it was asked that "Why do >> >>> > we need >> >>> > another approach if "reduction add" can be pattern matched in >> >>> DAGCombine?" >> >>> > However I feel if we have strong enough rationale for >> >>> > introduction of >> >>> > this instruction, it would be great. The 1st link below has the >> >>> > complete >> >>> discussion about the intrinsic approach. >> >>> >> >>> Yes, I think introducing such a reduction add can let us do >> >>> pattern recognition >> >>> of either SAD or dot production (or more?) without introducing >> >>> any >> >>> additional intrinsics. >> >> I agree. Another use case could be POPCOUNT operation. Moreover, >> >> as 'reduction add' >> >> Is being adopted by more targets now a days, reflecting that in >> >> LLVM IR as an instruction >> >> Is a good idea. >> >> BTW, what is the idea of the syntax and semantic of this operation >> >> you have? >> > >> > We can introduce a reduce-add for vectors only, or make it general >> > so >> > that it could also accept scale operands. Normally it is identical >> > to >> > normal add, but during instruction selection we can do pattern >> > recognition based on more information provided by this new >> > operations. >> > For vectors, this means the result of this operation only guarantee >> > that the sum of all elements in the result is identical to the sum >> > of >> > all elements of its operands. This gives us enough freedom to do >> > aggressive transformations, such as SAD or dot-product. >> > >> > Do you think if this is enough for us to get there? >> > >> > >> > Cong >> > >> >> >> >> The main concern may be cost >> >>> model: we could not guarantee that a SAD loop is unrolled 16 >> >>> times on SSE to >> >>> make use the most benefit of SAD. After the patch >> >>> http://reviews.llvm.org/D8943 is landed, I am now working on >> >>> improving cost >> >>> models of type conversions on X86. I believe even without SAD >> >>> instruction >> >>> we can still get better performance with unrolling a SAD loop 16 >> >>> times. This >> >>> seems tricky but it works. What do you think? >> >> I also think same as we can increase the bandwidth with proper >> >> cost modeling. >> >> >> >> Regards, >> >> Shahid >> >>> >> >>> Cong >> >>> >> >>> > >> >>> > http://reviews.llvm.org/D10964 >> >>> > http://lists.llvm.org/pipermail/llvm-dev/2015-May/085078.html >> >>> > >> >>> > Regards, >> >>> > Shahid >> >>> > >> >>> > >> >>> > >> >>> >> -----Original Message----- >> >>> >> From: llvm-dev [mailto:llvm-dev-bounces at lists.llvm.org] On >> >>> >> Behalf Of >> >>> >> Cong Hou via llvm-dev >> >>> >> Sent: Friday, November 13, 2015 5:47 AM >> >>> >> To: llvm-dev at lists.llvm.org >> >>> >> Cc: David Li >> >>> >> Subject: [llvm-dev] [RFC] Introducing a vector reduction add >> >>> >> instruction. >> >>> >> >> >>> >> Hi >> >>> >> >> >>> >> When a reduction instruction is vectorized in a loop, it will >> >>> >> be >> >>> >> turned into an instruction with vector operands of the same >> >>> >> operation >> >>> >> type. This new instruction has a special property that can >> >>> >> give us >> >>> >> more flexibility during instruction selection later: this >> >>> >> operation >> >>> >> is valid as long as the reduction of all elements of the >> >>> >> result >> >>> >> vector is identical to the reduction of all elements of its >> >>> >> operands. >> >>> >> >> >>> >> One example that can benefit this property is SAD (sum of >> >>> >> absolute >> >>> >> differences) pattern detection in SSE2, which provides a >> >>> >> psadbw >> >>> >> instruction whose description is shown below: >> >>> >> >> >>> >> ''' >> >>> >> psadbw: Compute the absolute differences of packed unsigned >> >>> >> 8-bit >> >>> >> integers in a and b, then horizontally sum each consecutive 8 >> >>> >> differences to produce two unsigned 16-bit integers, and pack >> >>> >> these >> >>> >> unsigned 16-bit integers in the low 16 bits of 64-bit elements >> >>> >> in dst. >> >>> >> ''' >> >>> >> >> >>> >> In LLVM's IR, for a SAD loop we will have two v4i8 as inputs >> >>> >> and one >> >>> >> v4i32 as output. However, psadbw will actually produce one i32 >> >>> >> result >> >>> >> for four pairs of 8-bit integers (an already reduced result), >> >>> >> and the >> >>> >> result is stored in the first element in v4i32. If we properly >> >>> >> zero >> >>> >> out the other three elements in v4i32, and with the >> >>> >> information that >> >>> >> we have a reduction add that is performed on this result, then >> >>> >> we can >> >>> >> safely use psadbw here for much better performance. This can >> >>> >> be done >> >>> >> during DAG combine. Another similar example is dot product. >> >>> >> And I >> >>> >> think there may be many other scenarios that can benefit from >> >>> >> this >> >>> >> property like eliminating redundant shuffles. >> >>> >> >> >>> >> The question is, how to let DAG combiner know that a vector >> >>> >> operation >> >>> >> is a reduction one? >> >>> >> >> >>> >> Here I propose to introduce a "reduction add" instruction for >> >>> >> vectors. >> >>> >> This will be a new instruction with vector operands only. >> >>> >> Normally it >> >>> >> is treated as a normal ADD operation, but the selection DAG >> >>> >> combiner >> >>> >> can make use of this new operation to generate better >> >>> >> instructions. >> >>> >> This new instruction is generated when vectorizing reduction >> >>> >> add in >> >>> >> loop vectorizer. >> >>> >> >> >>> >> I would like to hear more comments on this proposal or >> >>> >> suggestions of >> >>> >> better alternative implementations. >> >>> >> >> >>> >> >> >>> >> thanks, >> >>> >> Cong >> >>> >> _______________________________________________ >> >>> >> LLVM Developers mailing list >> >>> >> llvm-dev at lists.llvm.org >> >>> >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >> > > -- > Hal Finkel > Assistant Computational Scientist > Leadership Computing Facility > Argonne National Laboratory
Xinliang David Li via llvm-dev
2015-Nov-25 23:17 UTC
[llvm-dev] [RFC] Introducing a vector reduction add instruction.
Hal is probably not questioning about the usefulness of reduction recognition and a way to represent it, but the clear semantics of the flag. You can probably draw some ideas from OMP SIMD reduction clause, or intel's SIMD pragma's reduction clause. https://software.intel.com/en-us/articles/enabling-simd-in-program-using-openmp40 David On Wed, Nov 25, 2015 at 3:07 PM, Cong Hou <congh at google.com> wrote:> On Wed, Nov 25, 2015 at 2:32 PM, Hal Finkel <hfinkel at anl.gov> wrote: > > Hi Cong, > > > > After reading the original RFC and this update, I'm still not entirely > sure I understand the semantics of the flag you're proposing to add. Does > it having something to do with the ordering of the reduction operations? > > The flag is only useful for vectorized reduction for now. I'll give > you an example how this flag is used. > > Given the following reduction loop: > > int a[N]; > int s = 0; > for (int i = 0; i < N; ++i) > s += a[i]; > > After it is vectorized, we have a reduction operation add whose > operands and the result are vectors. Suppose it is represented as: > > [s0, s1, s2, s3] = [s0, s1, s2, s3] + [a0, a1, a2, a3]. > > If we know this operation is a reduction one, then we could have some > flexibility on how elements in the result are organized, as long as > the sum of them stays the same (the precondition is that the only use > of the reduction result is the reduction phi node, and this is usually > true as long as a reduction loop can be vectorized). For example, if > we let the result be [s0+s1, 0, s2+s3, 0] or [0, 0, s0+s1+s2+s3, 0], > the reduction result won't change. This enable us to detect SAD or > dot-product patterns and use SSE's psadbw and pmaddwd instructions. > Please see my respond to your another email for more details. > > Thanks! > > Cong > > > > > Thanks again, > > Hal > > > > ----- Original Message ----- > >> From: "Cong Hou via llvm-dev" <llvm-dev at lists.llvm.org> > >> To: "llvm-dev" <llvm-dev at lists.llvm.org> > >> Cc: "David Li" <davidxl at google.com> > >> Sent: Thursday, November 19, 2015 3:12:10 PM > >> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add > instruction. > >> > >> After some attempt to implement reduce-add in LLVM, I found out a > >> easier way to detect reduce-add without introducing new IR > >> operations. > >> The basic idea is annotating phi node instead of add (so that it is > >> easier to handle other reduction operations). In PHINode class, we > >> can > >> add a flag indicating if the phi node is a reduction one (the flag > >> can > >> be set in loop vectorizer for vectorized phi nodes). Then when we > >> build SDNode for instruction selection, we detect those reduction phi > >> nodes and then annotate reduction operations. This requires an > >> additional flag in SDNodeFlags. We can then check this flag when > >> combining instructions to detect reduction operations. > >> > >> In this approach, I have managed to let LLVM compile a SAD loop into > >> psadbw instructions. > >> > >> Source code: > >> > >> > >> const int N = 1024; > >> unsigned char a[N], b[N]; > >> > >> int sad() { > >> int s = 0; > >> for (int i = 0; i < N; ++i) { > >> int res = a[i] - b[i]; > >> s += (res > 0) ? res : -res; > >> } > >> return s; > >> } > >> > >> > >> Emitted instructions on X86: > >> > >> > >> > >> # BB#0: # %entry > >> pxor %xmm0, %xmm0 > >> movq $-1024, %rax # imm = 0xFFFFFFFFFFFFFC00 > >> pxor %xmm1, %xmm1 > >> .align 16, 0x90 > >> .LBB0_1: # %vector.body > >> # =>This Inner Loop Header: > >> Depth=1 > >> movd b+1024(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero > >> movd a+1024(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero > >> psadbw %xmm2, %xmm3 > >> paddd %xmm3, %xmm0 > >> movd b+1028(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero > >> movd a+1028(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero > >> psadbw %xmm2, %xmm3 > >> paddd %xmm3, %xmm1 > >> addq $8, %rax > >> jne .LBB0_1 > >> # BB#2: # %middle.block > >> paddd %xmm0, %xmm1 > >> pshufd $78, %xmm1, %xmm0 # xmm0 = xmm1[2,3,0,1] > >> paddd %xmm1, %xmm0 > >> pshufd $229, %xmm0, %xmm1 # xmm1 = xmm0[1,1,2,3] > >> paddd %xmm0, %xmm1 > >> movd %xmm1, %eax > >> retq > >> > >> > >> Note that due to smaller VF we are using now (currently 4), we could > >> not explore the most benefit of psadbw. The patch in > >> http://reviews.llvm.org/D8943 has enables us to use bigger VFs based > >> on the smallest type in a loop. The follow-up work is refining the > >> cost model to let bigger VFs have less cost. For the example above > >> the > >> best result is from VF >=16. > >> > >> The draft of the patch is here: http://reviews.llvm.org/D14840 > >> > >> I will refine the patch later and submit it for review. > >> > >> > >> thanks, > >> Cong > >> > >> > >> On Wed, Nov 18, 2015 at 2:45 PM, Cong Hou <congh at google.com> wrote: > >> > On Mon, Nov 16, 2015 at 9:31 PM, Shahid, Asghar-ahmad > >> > <Asghar-ahmad.Shahid at amd.com> wrote: > >> >> Hi Cong, > >> >> > >> >>> -----Original Message----- > >> >>> From: Cong Hou [mailto:congh at google.com] > >> >>> Sent: Tuesday, November 17, 2015 12:47 AM > >> >>> To: Shahid, Asghar-ahmad > >> >>> Cc: David Li > >> >>> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add > >> >>> instruction. > >> >>> > >> >>> On Thu, Nov 12, 2015 at 9:37 PM, Shahid, Asghar-ahmad <Asghar- > >> >>> ahmad.Shahid at amd.com> wrote: > >> >>> > Hi Cong, > >> >>> > > >> >>> > We had proposed an intrinsic approach to do this. However the > >> >>> > discussion reached to a point where it was asked that "Why do > >> >>> > we need > >> >>> > another approach if "reduction add" can be pattern matched in > >> >>> DAGCombine?" > >> >>> > However I feel if we have strong enough rationale for > >> >>> > introduction of > >> >>> > this instruction, it would be great. The 1st link below has the > >> >>> > complete > >> >>> discussion about the intrinsic approach. > >> >>> > >> >>> Yes, I think introducing such a reduction add can let us do > >> >>> pattern recognition > >> >>> of either SAD or dot production (or more?) without introducing > >> >>> any > >> >>> additional intrinsics. > >> >> I agree. Another use case could be POPCOUNT operation. Moreover, > >> >> as 'reduction add' > >> >> Is being adopted by more targets now a days, reflecting that in > >> >> LLVM IR as an instruction > >> >> Is a good idea. > >> >> BTW, what is the idea of the syntax and semantic of this operation > >> >> you have? > >> > > >> > We can introduce a reduce-add for vectors only, or make it general > >> > so > >> > that it could also accept scale operands. Normally it is identical > >> > to > >> > normal add, but during instruction selection we can do pattern > >> > recognition based on more information provided by this new > >> > operations. > >> > For vectors, this means the result of this operation only guarantee > >> > that the sum of all elements in the result is identical to the sum > >> > of > >> > all elements of its operands. This gives us enough freedom to do > >> > aggressive transformations, such as SAD or dot-product. > >> > > >> > Do you think if this is enough for us to get there? > >> > > >> > > >> > Cong > >> > > >> >> > >> >> The main concern may be cost > >> >>> model: we could not guarantee that a SAD loop is unrolled 16 > >> >>> times on SSE to > >> >>> make use the most benefit of SAD. After the patch > >> >>> http://reviews.llvm.org/D8943 is landed, I am now working on > >> >>> improving cost > >> >>> models of type conversions on X86. I believe even without SAD > >> >>> instruction > >> >>> we can still get better performance with unrolling a SAD loop 16 > >> >>> times. This > >> >>> seems tricky but it works. What do you think? > >> >> I also think same as we can increase the bandwidth with proper > >> >> cost modeling. > >> >> > >> >> Regards, > >> >> Shahid > >> >>> > >> >>> Cong > >> >>> > >> >>> > > >> >>> > http://reviews.llvm.org/D10964 > >> >>> > http://lists.llvm.org/pipermail/llvm-dev/2015-May/085078.html > >> >>> > > >> >>> > Regards, > >> >>> > Shahid > >> >>> > > >> >>> > > >> >>> > > >> >>> >> -----Original Message----- > >> >>> >> From: llvm-dev [mailto:llvm-dev-bounces at lists.llvm.org] On > >> >>> >> Behalf Of > >> >>> >> Cong Hou via llvm-dev > >> >>> >> Sent: Friday, November 13, 2015 5:47 AM > >> >>> >> To: llvm-dev at lists.llvm.org > >> >>> >> Cc: David Li > >> >>> >> Subject: [llvm-dev] [RFC] Introducing a vector reduction add > >> >>> >> instruction. > >> >>> >> > >> >>> >> Hi > >> >>> >> > >> >>> >> When a reduction instruction is vectorized in a loop, it will > >> >>> >> be > >> >>> >> turned into an instruction with vector operands of the same > >> >>> >> operation > >> >>> >> type. This new instruction has a special property that can > >> >>> >> give us > >> >>> >> more flexibility during instruction selection later: this > >> >>> >> operation > >> >>> >> is valid as long as the reduction of all elements of the > >> >>> >> result > >> >>> >> vector is identical to the reduction of all elements of its > >> >>> >> operands. > >> >>> >> > >> >>> >> One example that can benefit this property is SAD (sum of > >> >>> >> absolute > >> >>> >> differences) pattern detection in SSE2, which provides a > >> >>> >> psadbw > >> >>> >> instruction whose description is shown below: > >> >>> >> > >> >>> >> ''' > >> >>> >> psadbw: Compute the absolute differences of packed unsigned > >> >>> >> 8-bit > >> >>> >> integers in a and b, then horizontally sum each consecutive 8 > >> >>> >> differences to produce two unsigned 16-bit integers, and pack > >> >>> >> these > >> >>> >> unsigned 16-bit integers in the low 16 bits of 64-bit elements > >> >>> >> in dst. > >> >>> >> ''' > >> >>> >> > >> >>> >> In LLVM's IR, for a SAD loop we will have two v4i8 as inputs > >> >>> >> and one > >> >>> >> v4i32 as output. However, psadbw will actually produce one i32 > >> >>> >> result > >> >>> >> for four pairs of 8-bit integers (an already reduced result), > >> >>> >> and the > >> >>> >> result is stored in the first element in v4i32. If we properly > >> >>> >> zero > >> >>> >> out the other three elements in v4i32, and with the > >> >>> >> information that > >> >>> >> we have a reduction add that is performed on this result, then > >> >>> >> we can > >> >>> >> safely use psadbw here for much better performance. This can > >> >>> >> be done > >> >>> >> during DAG combine. Another similar example is dot product. > >> >>> >> And I > >> >>> >> think there may be many other scenarios that can benefit from > >> >>> >> this > >> >>> >> property like eliminating redundant shuffles. > >> >>> >> > >> >>> >> The question is, how to let DAG combiner know that a vector > >> >>> >> operation > >> >>> >> is a reduction one? > >> >>> >> > >> >>> >> Here I propose to introduce a "reduction add" instruction for > >> >>> >> vectors. > >> >>> >> This will be a new instruction with vector operands only. > >> >>> >> Normally it > >> >>> >> is treated as a normal ADD operation, but the selection DAG > >> >>> >> combiner > >> >>> >> can make use of this new operation to generate better > >> >>> >> instructions. > >> >>> >> This new instruction is generated when vectorizing reduction > >> >>> >> add in > >> >>> >> loop vectorizer. > >> >>> >> > >> >>> >> I would like to hear more comments on this proposal or > >> >>> >> suggestions of > >> >>> >> better alternative implementations. > >> >>> >> > >> >>> >> > >> >>> >> thanks, > >> >>> >> Cong > >> >>> >> _______________________________________________ > >> >>> >> LLVM Developers mailing list > >> >>> >> llvm-dev at lists.llvm.org > >> >>> >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >> _______________________________________________ > >> LLVM Developers mailing list > >> llvm-dev at lists.llvm.org > >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >> > > > > -- > > Hal Finkel > > Assistant Computational Scientist > > Leadership Computing Facility > > Argonne National Laboratory >-------------- next part -------------- An HTML attachment was scrubbed... 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Hal Finkel via llvm-dev
2015-Nov-25 23:44 UTC
[llvm-dev] [RFC] Introducing a vector reduction add instruction.
----- Original Message -----> From: "Xinliang David Li" <davidxl at google.com> > To: "Cong Hou" <congh at google.com> > Cc: "Hal Finkel" <hfinkel at anl.gov>, "llvm-dev" <llvm-dev at lists.llvm.org> > Sent: Wednesday, November 25, 2015 5:17:58 PM > Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add instruction. > > > Hal is probably not questioning about the usefulness of reduction > recognition and a way to represent it, but the clear semantics of > the flag. You can probably draw some ideas from OMP SIMD reduction > clause, or intel's SIMD pragma's reduction clause.True, but nevertheless, Cong's reply was useful. Here's my interpretation so far: Placing this flag on a PHI node, which is only valid for a vector-valued PHI, indicates that only the sum of vector elements is meaningful. This could easily be extended to cover any associative operation (only the product is useful, only the maximum or minimum value is useful, etc.). Now I completely understand why the flag is useful at the SDAG level. Because SDAG is basic-block local, we can't examine the loop structure when doing instruction selection for the relevant operations composing the psadbw (and friends). We also need to realize, when lowering the horizontal reduction at the end of the loop, to lower it in some more-trivial way (right?). Regarding the metadata at the IR level: the motivation here is that, without it, the SDAG builder would need to examine the uses of the PHI, determine that the only uses were shuffles and extracts representing a horizontal reduction (add, etc.), and then deduce that it could add the flag from that. If this matching is practical (and I suspect that it is, given that we already do it in the backends to match horizontal adds), this seems better than using vectorizer-added metadata. In this way, IR generated using vector intrinsics (etc.) can receive the same good code generation as that generated by the vectorizer. Thanks again, Hal> > > https://software.intel.com/en-us/articles/enabling-simd-in-program-using-openmp40 > > > > David > > > On Wed, Nov 25, 2015 at 3:07 PM, Cong Hou < congh at google.com > wrote: > > > On Wed, Nov 25, 2015 at 2:32 PM, Hal Finkel < hfinkel at anl.gov > > wrote: > > Hi Cong, > > > > After reading the original RFC and this update, I'm still not > > entirely sure I understand the semantics of the flag you're > > proposing to add. Does it having something to do with the ordering > > of the reduction operations? > > The flag is only useful for vectorized reduction for now. I'll give > you an example how this flag is used. > > Given the following reduction loop: > > int a[N]; > int s = 0; > for (int i = 0; i < N; ++i) > s += a[i]; > > After it is vectorized, we have a reduction operation add whose > operands and the result are vectors. Suppose it is represented as: > > [s0, s1, s2, s3] = [s0, s1, s2, s3] + [a0, a1, a2, a3]. > > If we know this operation is a reduction one, then we could have some > flexibility on how elements in the result are organized, as long as > the sum of them stays the same (the precondition is that the only use > of the reduction result is the reduction phi node, and this is > usually > true as long as a reduction loop can be vectorized). For example, if > we let the result be [s0+s1, 0, s2+s3, 0] or [0, 0, s0+s1+s2+s3, 0], > the reduction result won't change. This enable us to detect SAD or > dot-product patterns and use SSE's psadbw and pmaddwd instructions. > Please see my respond to your another email for more details. > > Thanks! > > Cong > > > > > > > Thanks again, > > Hal > > > > ----- Original Message ----- > >> From: "Cong Hou via llvm-dev" < llvm-dev at lists.llvm.org > > >> To: "llvm-dev" < llvm-dev at lists.llvm.org > > >> Cc: "David Li" < davidxl at google.com > > >> Sent: Thursday, November 19, 2015 3:12:10 PM > >> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction add > >> instruction. > >> > >> After some attempt to implement reduce-add in LLVM, I found out a > >> easier way to detect reduce-add without introducing new IR > >> operations. > >> The basic idea is annotating phi node instead of add (so that it > >> is > >> easier to handle other reduction operations). In PHINode class, we > >> can > >> add a flag indicating if the phi node is a reduction one (the flag > >> can > >> be set in loop vectorizer for vectorized phi nodes). Then when we > >> build SDNode for instruction selection, we detect those reduction > >> phi > >> nodes and then annotate reduction operations. This requires an > >> additional flag in SDNodeFlags. We can then check this flag when > >> combining instructions to detect reduction operations. > >> > >> In this approach, I have managed to let LLVM compile a SAD loop > >> into > >> psadbw instructions. > >> > >> Source code: > >> > >> > >> const int N = 1024; > >> unsigned char a[N], b[N]; > >> > >> int sad() { > >> int s = 0; > >> for (int i = 0; i < N; ++i) { > >> int res = a[i] - b[i]; > >> s += (res > 0) ? res : -res; > >> } > >> return s; > >> } > >> > >> > >> Emitted instructions on X86: > >> > >> > >> > >> # BB#0: # %entry > >> pxor %xmm0, %xmm0 > >> movq $-1024, %rax # imm = 0xFFFFFFFFFFFFFC00 > >> pxor %xmm1, %xmm1 > >> .align 16, 0x90 > >> .LBB0_1: # %vector.body > >> # =>This Inner Loop Header: > >> Depth=1 > >> movd b+1024(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero > >> movd a+1024(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero > >> psadbw %xmm2, %xmm3 > >> paddd %xmm3, %xmm0 > >> movd b+1028(%rax), %xmm2 # xmm2 = mem[0],zero,zero,zero > >> movd a+1028(%rax), %xmm3 # xmm3 = mem[0],zero,zero,zero > >> psadbw %xmm2, %xmm3 > >> paddd %xmm3, %xmm1 > >> addq $8, %rax > >> jne .LBB0_1 > >> # BB#2: # %middle.block > >> paddd %xmm0, %xmm1 > >> pshufd $78, %xmm1, %xmm0 # xmm0 = xmm1[2,3,0,1] > >> paddd %xmm1, %xmm0 > >> pshufd $229, %xmm0, %xmm1 # xmm1 = xmm0[1,1,2,3] > >> paddd %xmm0, %xmm1 > >> movd %xmm1, %eax > >> retq > >> > >> > >> Note that due to smaller VF we are using now (currently 4), we > >> could > >> not explore the most benefit of psadbw. The patch in > >> http://reviews.llvm.org/D8943 has enables us to use bigger VFs > >> based > >> on the smallest type in a loop. The follow-up work is refining the > >> cost model to let bigger VFs have less cost. For the example above > >> the > >> best result is from VF >=16. > >> > >> The draft of the patch is here: http://reviews.llvm.org/D14840 > >> > >> I will refine the patch later and submit it for review. > >> > >> > >> thanks, > >> Cong > >> > >> > >> On Wed, Nov 18, 2015 at 2:45 PM, Cong Hou < congh at google.com > > >> wrote: > >> > On Mon, Nov 16, 2015 at 9:31 PM, Shahid, Asghar-ahmad > >> > < Asghar-ahmad.Shahid at amd.com > wrote: > >> >> Hi Cong, > >> >> > >> >>> -----Original Message----- > >> >>> From: Cong Hou [mailto: congh at google.com ] > >> >>> Sent: Tuesday, November 17, 2015 12:47 AM > >> >>> To: Shahid, Asghar-ahmad > >> >>> Cc: David Li > >> >>> Subject: Re: [llvm-dev] [RFC] Introducing a vector reduction > >> >>> add > >> >>> instruction. > >> >>> > >> >>> On Thu, Nov 12, 2015 at 9:37 PM, Shahid, Asghar-ahmad <Asghar- > >> >>> ahmad.Shahid at amd.com > wrote: > >> >>> > Hi Cong, > >> >>> > > >> >>> > We had proposed an intrinsic approach to do this. However > >> >>> > the > >> >>> > discussion reached to a point where it was asked that "Why > >> >>> > do > >> >>> > we need > >> >>> > another approach if "reduction add" can be pattern matched > >> >>> > in > >> >>> DAGCombine?" > >> >>> > However I feel if we have strong enough rationale for > >> >>> > introduction of > >> >>> > this instruction, it would be great. The 1st link below has > >> >>> > the > >> >>> > complete > >> >>> discussion about the intrinsic approach. > >> >>> > >> >>> Yes, I think introducing such a reduction add can let us do > >> >>> pattern recognition > >> >>> of either SAD or dot production (or more?) without introducing > >> >>> any > >> >>> additional intrinsics. > >> >> I agree. Another use case could be POPCOUNT operation. > >> >> Moreover, > >> >> as 'reduction add' > >> >> Is being adopted by more targets now a days, reflecting that in > >> >> LLVM IR as an instruction > >> >> Is a good idea. > >> >> BTW, what is the idea of the syntax and semantic of this > >> >> operation > >> >> you have? > >> > > >> > We can introduce a reduce-add for vectors only, or make it > >> > general > >> > so > >> > that it could also accept scale operands. Normally it is > >> > identical > >> > to > >> > normal add, but during instruction selection we can do pattern > >> > recognition based on more information provided by this new > >> > operations. > >> > For vectors, this means the result of this operation only > >> > guarantee > >> > that the sum of all elements in the result is identical to the > >> > sum > >> > of > >> > all elements of its operands. This gives us enough freedom to do > >> > aggressive transformations, such as SAD or dot-product. > >> > > >> > Do you think if this is enough for us to get there? > >> > > >> > > >> > Cong > >> > > >> >> > >> >> The main concern may be cost > >> >>> model: we could not guarantee that a SAD loop is unrolled 16 > >> >>> times on SSE to > >> >>> make use the most benefit of SAD. After the patch > >> >>> http://reviews.llvm.org/D8943 is landed, I am now working on > >> >>> improving cost > >> >>> models of type conversions on X86. I believe even without SAD > >> >>> instruction > >> >>> we can still get better performance with unrolling a SAD loop > >> >>> 16 > >> >>> times. This > >> >>> seems tricky but it works. What do you think? > >> >> I also think same as we can increase the bandwidth with proper > >> >> cost modeling. > >> >> > >> >> Regards, > >> >> Shahid > >> >>> > >> >>> Cong > >> >>> > >> >>> > > >> >>> > http://reviews.llvm.org/D10964 > >> >>> > http://lists.llvm.org/pipermail/llvm-dev/2015-May/085078.html > >> >>> > > >> >>> > Regards, > >> >>> > Shahid > >> >>> > > >> >>> > > >> >>> > > >> >>> >> -----Original Message----- > >> >>> >> From: llvm-dev [mailto: llvm-dev-bounces at lists.llvm.org ] > >> >>> >> On > >> >>> >> Behalf Of > >> >>> >> Cong Hou via llvm-dev > >> >>> >> Sent: Friday, November 13, 2015 5:47 AM > >> >>> >> To: llvm-dev at lists.llvm.org > >> >>> >> Cc: David Li > >> >>> >> Subject: [llvm-dev] [RFC] Introducing a vector reduction > >> >>> >> add > >> >>> >> instruction. > >> >>> >> > >> >>> >> Hi > >> >>> >> > >> >>> >> When a reduction instruction is vectorized in a loop, it > >> >>> >> will > >> >>> >> be > >> >>> >> turned into an instruction with vector operands of the same > >> >>> >> operation > >> >>> >> type. This new instruction has a special property that can > >> >>> >> give us > >> >>> >> more flexibility during instruction selection later: this > >> >>> >> operation > >> >>> >> is valid as long as the reduction of all elements of the > >> >>> >> result > >> >>> >> vector is identical to the reduction of all elements of its > >> >>> >> operands. > >> >>> >> > >> >>> >> One example that can benefit this property is SAD (sum of > >> >>> >> absolute > >> >>> >> differences) pattern detection in SSE2, which provides a > >> >>> >> psadbw > >> >>> >> instruction whose description is shown below: > >> >>> >> > >> >>> >> ''' > >> >>> >> psadbw: Compute the absolute differences of packed unsigned > >> >>> >> 8-bit > >> >>> >> integers in a and b, then horizontally sum each consecutive > >> >>> >> 8 > >> >>> >> differences to produce two unsigned 16-bit integers, and > >> >>> >> pack > >> >>> >> these > >> >>> >> unsigned 16-bit integers in the low 16 bits of 64-bit > >> >>> >> elements > >> >>> >> in dst. > >> >>> >> ''' > >> >>> >> > >> >>> >> In LLVM's IR, for a SAD loop we will have two v4i8 as > >> >>> >> inputs > >> >>> >> and one > >> >>> >> v4i32 as output. However, psadbw will actually produce one > >> >>> >> i32 > >> >>> >> result > >> >>> >> for four pairs of 8-bit integers (an already reduced > >> >>> >> result), > >> >>> >> and the > >> >>> >> result is stored in the first element in v4i32. If we > >> >>> >> properly > >> >>> >> zero > >> >>> >> out the other three elements in v4i32, and with the > >> >>> >> information that > >> >>> >> we have a reduction add that is performed on this result, > >> >>> >> then > >> >>> >> we can > >> >>> >> safely use psadbw here for much better performance. This > >> >>> >> can > >> >>> >> be done > >> >>> >> during DAG combine. Another similar example is dot product. > >> >>> >> And I > >> >>> >> think there may be many other scenarios that can benefit > >> >>> >> from > >> >>> >> this > >> >>> >> property like eliminating redundant shuffles. > >> >>> >> > >> >>> >> The question is, how to let DAG combiner know that a vector > >> >>> >> operation > >> >>> >> is a reduction one? > >> >>> >> > >> >>> >> Here I propose to introduce a "reduction add" instruction > >> >>> >> for > >> >>> >> vectors. > >> >>> >> This will be a new instruction with vector operands only. > >> >>> >> Normally it > >> >>> >> is treated as a normal ADD operation, but the selection DAG > >> >>> >> combiner > >> >>> >> can make use of this new operation to generate better > >> >>> >> instructions. > >> >>> >> This new instruction is generated when vectorizing > >> >>> >> reduction > >> >>> >> add in > >> >>> >> loop vectorizer. > >> >>> >> > >> >>> >> I would like to hear more comments on this proposal or > >> >>> >> suggestions of > >> >>> >> better alternative implementations. > >> >>> >> > >> >>> >> > >> >>> >> thanks, > >> >>> >> Cong > >> >>> >> _______________________________________________ > >> >>> >> LLVM Developers mailing list > >> >>> >> llvm-dev at lists.llvm.org > >> >>> >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >> _______________________________________________ > >> LLVM Developers mailing list > >> llvm-dev at lists.llvm.org > >> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > >> > > > > -- > > Hal Finkel > > Assistant Computational Scientist > > Leadership Computing Facility > > Argonne National Laboratory > >-- Hal Finkel Assistant Computational Scientist Leadership Computing Facility Argonne National Laboratory
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