Shawn Landden via llvm-dev
2020-Jul-05 09:18 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
<div> </div><div><div><p>Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more.</p><p>This proposal is to add a <code>llvm.clmul</code> instruction. Or if that is contentious, <code>llvm.experimental.bitmanip.clmul</code> instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?)</p><p>If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys.</p><p>==Where is clmul used?==</p><p>While somewhat specialized, the RISC-V manual documents many uses: [2]</p><p>The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26]</p><p>and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17].</p><p>clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23].</p><p>clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16]</p><p>Carry-less multiply can also be used to implement Erasure code efficiently. [14]</p><p>==clmul lowering without hardware support==<br />A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3].</p><p>[1] <a href="https://en.wikipedia.org/wiki/Carry-less_product">https://en.wikipedia.org/wiki/Carry-less_product</a><br /><a href="https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html">[2] (page 30) </a><a href="https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf">https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf</a><br /><a href="https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html">[3] </a><a href="https://www.bearssl.org/constanttime.html">https://www.bearssl.org/constanttime.html</a></p><p> </p><p>(First posted to discord</p></div></div><div>-- </div><div>Shawn Landden</div><div> </div>
Roman Lebedev via llvm-dev
2020-Jul-05 10:21 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
On Sun, Jul 5, 2020 at 12:18 PM Shawn Landden via llvm-dev <llvm-dev at lists.llvm.org> wrote:> > > > Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more. > > This proposal is to add a llvm.clmul instruction. Or if that is contentious, llvm.experimental.bitmanip.clmul instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?) > > If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys. > > ==Where is clmul used?=> > While somewhat specialized, the RISC-V manual documents many uses: [2] > > The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] > > and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17]. > > clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23]. > > clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16] > > Carry-less multiply can also be used to implement Erasure code efficiently. [14] > > ==clmul lowering without hardware support=> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. > > [1] https://en.wikipedia.org/wiki/Carry-less_product > [2] (page 30) https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf > [3] https://www.bearssl.org/constanttime.htmlWhat benefit would this intrinsic would bring to the middle-end IR, over it's current naive expanded form? Note that teaching backends to produce it, or even adding it to backend (ISD opcodes) and matching it in DAGCombiner has much lower barrier of entry, i would suggest to start there.> (First posted to discord > > -- > Shawn LanddenRoman> _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev
Nicolai Hähnle via llvm-dev
2020-Jul-05 12:12 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
On 05.07.20 12:21, Roman Lebedev via llvm-dev wrote:> On Sun, Jul 5, 2020 at 12:18 PM Shawn Landden via llvm-dev > <llvm-dev at lists.llvm.org> wrote: >> >> >> >> Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more. >> >> This proposal is to add a llvm.clmul instruction. Or if that is contentious, llvm.experimental.bitmanip.clmul instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?) >> >> If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys. >> >> ==Where is clmul used?=>> >> While somewhat specialized, the RISC-V manual documents many uses: [2] >> >> The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] >> >> and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17]. >> >> clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23]. >> >> clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16] >> >> Carry-less multiply can also be used to implement Erasure code efficiently. [14] >> >> ==clmul lowering without hardware support=>> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. >> >> [1] https://en.wikipedia.org/wiki/Carry-less_product >> [2] (page 30) https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf >> [3] https://www.bearssl.org/constanttime.html > > What benefit would this intrinsic would bring to the middle-end IR, > over it's current naive expanded form?Isn't a "naive" expansion of NxN carryless multiply extremely involved? I'd expect something like 2N shifts, N truncs, N selects, and N xors. That link mentions an alternative that is more efficient, but I wouldn't exactly call it naive... Cheers, Nicolai> > Note that teaching backends to produce it, or even adding it to > backend (ISD opcodes) > and matching it in DAGCombiner has much lower barrier of entry, i > would suggest to start there. > >> (First posted to discord >> >> -- >> Shawn Landden > Roman > >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org >> https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >-- Lerne, wie die Welt wirklich ist, Aber vergiss niemals, wie sie sein sollte.
James Y Knight via llvm-dev
2020-Jul-05 14:54 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
It'd be useful in your proposal to to note which of the existing llvm target specific intrinsics this generic intrinsic can effectively supersede. (E.g. llvm.x86.pclmulqdq for x86.) When we are already supporting a given function via target specific intrinsics for a number of different targets, that seems a pretty good argument for making it available as a more generic target independent intrinsic. On Sun, Jul 5, 2020, 5:18 AM Shawn Landden via llvm-dev < llvm-dev at lists.llvm.org> wrote:> > > Carry-less multiplication[1] instructions exist (at least optionally) on > many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly > more. > > This proposal is to add a llvm.clmul instruction. Or if that is > contentious, llvm.experimental.bitmanip.clmul instruction. It takes two > integer operands of the same width, and returns an integer with twice the > width of the operands. (Is there a good reason to make these the same > width, as all the other operations do even when it doesn’t really make > sense for the mathematical operation–like multiplication or > ctpop/ctlz/cttz?) > > If the CPU does not have a dedication clmul operation, it can be lowered > to regular multiplication, by using holes to avoid carrys. > > ==Where is clmul used?=> > While somewhat specialized, the RISC-V manual documents many uses: [2] > > The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] > > and Galois/CounterMode (GCM), but more applications exist, including the > following examples.There are obvious applications in hashing and pseudo > random number generations. For exam-ple, it has been reported that hashes > based on carry-less multiplications can outperform Google’sCityHash [17]. > > clmulof a number with itself inserts zeroes between each input bit. This > can be useful for generatingMorton code [23]. > > clmulof a number with -1 calculates the prefix XOR operation. This can be > useful for decodinggray codes.Another application of XOR prefix sums > calculated withclmulis branchless tracking of quotedstrings in > high-performance parsers. [16] > > Carry-less multiply can also be used to implement Erasure code > efficiently. [14] > > ==clmul lowering without hardware support=> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when > there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if > bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. > > [1] https://en.wikipedia.org/wiki/Carry-less_product > [2] (page 30) > <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html> > https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf > [3] > <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html> > https://www.bearssl.org/constanttime.html > > > > (First posted to discord > -- > Shawn Landden > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20200705/a56891ea/attachment.html>
Craig Topper via llvm-dev
2020-Jul-05 18:44 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
Shawn, Are you able to summarize the different instructions from the various targets. It looks like there different implementation choices made for each target. For example, X86 takes two v2i64 inputs and picks either an even or odd element from each to multiply to produce a v1i128 result. It looks like RISC-V has instructions to produce either the high half of the result or the low half of the result. Those are the only two I checked. Will a common intrinsic need custom handling for each target or is there a common version that multiple targets use that we should choose for the intrinsic? ~Craig On Sun, Jul 5, 2020 at 7:55 AM James Y Knight via llvm-dev < llvm-dev at lists.llvm.org> wrote:> It'd be useful in your proposal to to note which of the existing llvm > target specific intrinsics this generic intrinsic can effectively > supersede. (E.g. llvm.x86.pclmulqdq for x86.) > > When we are already supporting a given function via target specific > intrinsics for a number of different targets, that seems a pretty good > argument for making it available as a more generic target independent > intrinsic. > > On Sun, Jul 5, 2020, 5:18 AM Shawn Landden via llvm-dev < > llvm-dev at lists.llvm.org> wrote: > >> >> >> Carry-less multiplication[1] instructions exist (at least optionally) on >> many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly >> more. >> >> This proposal is to add a llvm.clmul instruction. Or if that is >> contentious, llvm.experimental.bitmanip.clmul instruction. It takes two >> integer operands of the same width, and returns an integer with twice the >> width of the operands. (Is there a good reason to make these the same >> width, as all the other operations do even when it doesn’t really make >> sense for the mathematical operation–like multiplication or >> ctpop/ctlz/cttz?) >> >> If the CPU does not have a dedication clmul operation, it can be lowered >> to regular multiplication, by using holes to avoid carrys. >> >> ==Where is clmul used?=>> >> While somewhat specialized, the RISC-V manual documents many uses: [2] >> >> The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, >> 26] >> >> and Galois/CounterMode (GCM), but more applications exist, including the >> following examples.There are obvious applications in hashing and pseudo >> random number generations. For exam-ple, it has been reported that hashes >> based on carry-less multiplications can outperform Google’sCityHash [17]. >> >> clmulof a number with itself inserts zeroes between each input bit. This >> can be useful for generatingMorton code [23]. >> >> clmulof a number with -1 calculates the prefix XOR operation. This can be >> useful for decodinggray codes.Another application of XOR prefix sums >> calculated withclmulis branchless tracking of quotedstrings in >> high-performance parsers. [16] >> >> Carry-less multiply can also be used to implement Erasure code >> efficiently. [14] >> >> ==clmul lowering without hardware support=>> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when >> there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if >> bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. >> >> [1] https://en.wikipedia.org/wiki/Carry-less_product >> [2] (page 30) >> <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html> >> https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf >> [3] >> <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html> >> https://www.bearssl.org/constanttime.html >> >> >> >> (First posted to discord >> -- >> Shawn Landden >> >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org >> https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >> > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev >-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20200705/7d5f05ff/attachment.html>
Steve (Numerics) Canon via llvm-dev
2020-Jul-08 16:23 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
FWIW, this seems like a no-brainer to me (as llvm.experimental initially), assuming that it can be designed in such a way that it would eliminate the need for intrinsics on at least two targets (I think it should be possible to do so, with a small amount of back-end work). – Steve> On Jul 5, 2020, at 5:18 AM, Shawn Landden via llvm-dev <llvm-dev at lists.llvm.org> wrote: > > Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more. > > This proposal is to add a llvm.clmul instruction. Or if that is contentious, llvm.experimental.bitmanip.clmul instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?) > > If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys. > > ==Where is clmul used?=> > While somewhat specialized, the RISC-V manual documents many uses: [2] > > The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] > > and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17]. > > clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23]. > > clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16] > > Carry-less multiply can also be used to implement Erasure code efficiently. [14] > > ==clmul lowering without hardware support=> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. > > [1] https://en.wikipedia.org/wiki/Carry-less_product <https://en.wikipedia.org/wiki/Carry-less_product> > [2] (page 30) <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html>https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf <https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf> > [3] <https://en.wikipedia.org/wiki/Carry-less_product%5B2%5D%20(page%2030)%20https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf%5B3%5D%20https://www.bearssl.org/constanttime.html>https://www.bearssl.org/constanttime.html <https://www.bearssl.org/constanttime.html> > > (First posted to discord > > -- > Shawn Landden > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev-------------- next part -------------- An HTML attachment was scrubbed... URL: <http://lists.llvm.org/pipermail/llvm-dev/attachments/20200708/05fc4700/attachment.html>
Roman Lebedev via llvm-dev
2020-Jul-09 14:41 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
(As per IRC discussion) I understand that the carry-less multiplication algorithm has it's uses since/and it is implemented as an instruction in many architectures and that adding it as a general-purpose intrinsic will allow us to drop target-specific intrinsics as by-product. What i do *NOT* understand is: what is the actual/main goal/driving factor of adding an LLVM intrinsic for it? The use that was mentioned is crypto, and i'm personally not really registering anything else. Am i just misreading it? The crypto use-case doesn't make sense to me, because as of this moment LLVM "explicitly" has zero constant-time guarantees for LLVM IR instructions/intrinsics. I feel like it's a really important question. If there isn't interest in crypto/constant-time here, i think it would be best to explicitly state so. If there is, i think it may be good to hear from Chandler (who IIRC is driving some constant-time work for C++/LLVM, that is not yet widely public) Roman On Wed, Jul 8, 2020 at 7:23 PM Steve (Numerics) Canon via llvm-dev <llvm-dev at lists.llvm.org> wrote:> > FWIW, this seems like a no-brainer to me (as llvm.experimental initially), assuming that it can be designed in such a way that it would eliminate the need for intrinsics on at least two targets (I think it should be possible to do so, with a small amount of back-end work). > > – Steve > > On Jul 5, 2020, at 5:18 AM, Shawn Landden via llvm-dev <llvm-dev at lists.llvm.org> wrote: > > Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more. > > This proposal is to add a llvm.clmul instruction. Or if that is contentious, llvm.experimental.bitmanip.clmul instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?) > > If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys. > > ==Where is clmul used?=> > While somewhat specialized, the RISC-V manual documents many uses: [2] > > The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] > > and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17]. > > clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23]. > > clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16] > > Carry-less multiply can also be used to implement Erasure code efficiently. [14] > > ==clmul lowering without hardware support=> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. > > [1] https://en.wikipedia.org/wiki/Carry-less_product > [2] (page 30) https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf > [3] https://www.bearssl.org/constanttime.html > > > > (First posted to discord > > -- > Shawn Landden > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev > > > _______________________________________________ > LLVM Developers mailing list > llvm-dev at lists.llvm.org > https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev
Shawn Landden via llvm-dev
2020-Jul-09 16:39 UTC
[llvm-dev] [RFC] carry-less multiplication instruction
05.07.2020, 05:22, "Roman Lebedev" <lebedev.ri at gmail.com>:> On Sun, Jul 5, 2020 at 12:18 PM Shawn Landden via llvm-dev > <llvm-dev at lists.llvm.org> wrote: >> Carry-less multiplication[1] instructions exist (at least optionally) on many architectures: armv8, RISC-V, x86_64, POWER, SPARC, C64x, and possibly more. >> >> This proposal is to add a llvm.clmul instruction. Or if that is contentious, llvm.experimental.bitmanip.clmul instruction. It takes two integer operands of the same width, and returns an integer with twice the width of the operands. (Is there a good reason to make these the same width, as all the other operations do even when it doesn’t really make sense for the mathematical operation–like multiplication or ctpop/ctlz/cttz?) >> >> If the CPU does not have a dedication clmul operation, it can be lowered to regular multiplication, by using holes to avoid carrys. >> >> ==Where is clmul used?=>> >> While somewhat specialized, the RISC-V manual documents many uses: [2] >> >> The classic applications forclmulare Cyclic Redundancy Check (CRC) [11, 26] >> >> and Galois/CounterMode (GCM), but more applications exist, including the following examples.There are obvious applications in hashing and pseudo random number generations. For exam-ple, it has been reported that hashes based on carry-less multiplications can outperform Google’sCityHash [17]. >> >> clmulof a number with itself inserts zeroes between each input bit. This can be useful for generatingMorton code [23]. >> >> clmulof a number with -1 calculates the prefix XOR operation. This can be useful for decodinggray codes.Another application of XOR prefix sums calculated withclmulis branchless tracking of quotedstrings in high-performance parsers. [16] >> >> Carry-less multiply can also be used to implement Erasure code efficiently. [14] >> >> ==clmul lowering without hardware support=>> A 8x8=>16 clmul can also be lowered to a 32x32=>64 multiplication when there is no specialized instruction (also 15x15=>30, to a 60x60=>120, or if bitreverse is available 16x16=>32 to TWO 64x64=>64 multiplications)[3]. >> >> [1] https://en.wikipedia.org/wiki/Carry-less_product >> [2] (page 30) https://raw.githubusercontent.com/riscv/riscv-bitmanip/master/bitmanip-0.92.pdf >> [3] https://www.bearssl.org/constanttime.html > > What benefit would this intrinsic would bring to the middle-end IR, > over it's current naive expanded form? > > Note that teaching backends to produce it, or even adding it to > backend (ISD opcodes) > and matching it in DAGCombiner has much lower barrier of entry, i > would suggest to start there.It cannot be matched.> >> (First posted to discord >> >> -- >> Shawn Landden > > Roman > >> _______________________________________________ >> LLVM Developers mailing list >> llvm-dev at lists.llvm.org >> https://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-dev-- Shawn Landden
Shawn Landden via llvm-dev
2020-Jul-19 15:23 UTC
[llvm-dev] Difficulty matching zext in tablegen/SelectionDAG (was: [RFC] Carry-less multiplication)
In trying to implement my RFC I ran into difficulty selecting zero-extends, either in a custom lowering, or in tablegen. For example, Power 8 has <2 x i32> -> <2 x i64>, <4 x i16> -> <4 x i32>, <1 x i64> -> <1 x i128> instructions. And the generated MIR looks different for the different cases: LLVM ERROR: Cannot select: t10: v2i64 = clmul t36, t35 t36: v2i64 = bitcast t33 t33: v16i8 vector_shuffle<0,1,2,3,16,17,18,19,4,5,6,7,20,21,22,23> t32, t29 t32: v16i8 = bitcast t2 t2: v4i32,ch = CopyFromReg t0, Register:v4i32 %0 t1: v4i32 = Register %0 t29: v16i8 = bitcast t19 t19: v4i32 = BUILD_VECTOR Constant:i32<0>, Constant:i32<0>, Constant:i32<0>, Constant:i32<0> t18: i32 = Constant<0> t18: i32 = Constant<0> t18: i32 = Constant<0> t18: i32 = Constant<0> t35: v2i64 = bitcast t30 t30: v16i8 vector_shuffle<0,1,2,3,16,17,18,19,4,5,6,7,20,21,22,23> t28, t29 t28: v16i8 = bitcast t4 t4: v4i32,ch = CopyFromReg t0, Register:v4i32 %1 t3: v4i32 = Register %1 t29: v16i8 = bitcast t19 t19: v4i32 = BUILD_VECTOR Constant:i32<0>, Constant:i32<0>, Constant:i32<0>, Constant:i32<0> t18: i32 = Constant<0> t18: i32 = Constant<0> t18: i32 = Constant<0> t18: i32 = Constant<0> LLVM ERROR: Cannot select: t9: v1i128 = clmul t24, t28 t24: v1i128 = bitcast t23 t23: v2i64 = BUILD_VECTOR t2, Constant:i64<0> t2: i64,ch = CopyFromReg t0, Register:i64 %0 t1: i64 = Register %0 t13: i64 = Constant<0> t28: v1i128 = bitcast t27 t27: v2i64 = BUILD_VECTOR t4, Constant:i64<0> t4: i64,ch = CopyFromReg t0, Register:i64 %1 t3: i64 = Register %1 t13: i64 = Constant<0> I might be able to use demandedBits in a custom rule, but it sure would nice if zext actually worked, like it would in LLVM-IR. The burden of learning totally distinct tools for different levels of the compiler (in addition to the assembly of the target) is quite annoying.
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