similar to: [RFC] carry-less multiplication instruction

Displaying 20 results from an estimated 200 matches similar to: "[RFC] carry-less multiplication instruction"

2020 Jul 09
2
[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
2020 Jul 05
5
[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
2020 Jul 09
2
[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
2012 Apr 28
9
[Bug 49243] New: graphical corruption with GeForce 6150SE nForce 430
https://bugs.freedesktop.org/show_bug.cgi?id=49243 Bug #: 49243 Summary: graphical corruption with GeForce 6150SE nForce 430 Classification: Unclassified Product: Mesa Version: git Platform: x86-64 (AMD64) OS/Version: Linux (All) Status: NEW Severity: normal Priority: medium Component:
2013 Dec 04
3
[Bug 881] New: SIGSEGV on startup
https://bugzilla.netfilter.org/show_bug.cgi?id=881 Summary: SIGSEGV on startup Product: nftables Version: unspecified Platform: x86_64 OS/Version: All Status: NEW Severity: enhancement Priority: P5 Component: nft AssignedTo: pablo at netfilter.org ReportedBy: shawn at churchofgit.com
2019 May 29
3
Basic block merging
Am Mi., 29. Mai 2019 um 13:31 Uhr schrieb Shawn Landden via llvm-dev <llvm-dev at lists.llvm.org>: > > On Wed, May 29, 2019 at 10:49 AM David Jones via llvm-dev > <llvm-dev at lists.llvm.org> wrote: > > > > Under certain circumstances, my compiler outputs basic blocks having the same function: > > > > bb_97: ;
2019 Jun 24
2
RFC: Interface user provided vector functions with the vectorizer.
For example, Type 2 case, scalar-foo used call by value while vector-foo used call by ref. The question Johannes is asking is whether we can decipher that after the fact, only by looking at the two function signatures, or need some more info (what kind, what's minimal)? I think we need to list up cases of interest, and for each vector ABI of interest, we need to work on the requirements and
2019 Jun 24
3
RFC: Interface user provided vector functions with the vectorizer.
> On Jun 24, 2019, at 10:53 AM, Tian, Xinmin <xinmin.tian at intel.com> wrote: > > To me, it is also an issue related to SIMD signature matching when the vectorizer kicks in. Losing info from FE to BE is not good in general. > Yes, we cannot loose such information. In particular, the three examples I reported are all generating i64 in the scalar function signature: // Type 1
2020 Mar 19
3
RISC-V LLVM sync-up call 19 Mar 2020
For background on these calls, see <http://lists.llvm.org/pipermail/llvm-dev/2019-September/135087.html>. Reminder: the purpose is to co-ordinate between active contributors. If you have support questions etc then it's best to post to llvm-dev. We have a call each Thursday at 4pm GMT, via <https://meet.google.com/ske-zcog-spp>. I've created a shared calendar which may help
2019 Aug 14
3
[RFC][RISCV] Selection of complex codegen patterns into RISCV bit manipulation instructions
Hi all, I'm currently working on the implementation for LLVM of the RISCV Bit Manipulation ISA extension described by Clifford Wolf in the following presentation: https://content.riscv.org/wp-content/uploads/2019/06/17.10-b_wolf.pdf and the following document: https://github.com/riscv/riscv-bitmanip/blob/master/bitmanip-0.90.pdf The aim is to provide the intrinsic functions to the user in
2020 Nov 12
1
RISC-V LLVM sync-up call 12 November 2020
For background on these calls, see <http://lists.llvm.org/pipermail/llvm-dev/2019-September/135087.html>. Reminder: the purpose is to co-ordinate between active contributors. If you have support questions etc then it's best to post to llvm-dev. We have a call every alternate Thursday at 4pm GMT, via <https://meet.google.com/ske-zcog-spp>. We have a shared calendar which may help
2019 Jun 24
4
RFC: Interface user provided vector functions with the vectorizer.
@Xinmin, Saito: If Clang/the frontend generates the version there is no problem, or is there? The frontend knows about the original source type and it's ABI specific lowering already. @Francesco, we should even consider putting the generating capabilities outside of the OpenMP code generation (in the future). That could allow easier reuse by other frontends. Get Outlook for
2019 May 29
2
Basic block merging
Under certain circumstances, my compiler outputs basic blocks having the same function: bb_97: ; preds = %bb_1 %476 = getelementptr inbounds %LMtop.I0.ARType, %LMtop.I0.ARType* %0, i64 0, i32 6 %477 = bitcast i8** %476 to %LBstd.Cprocess.CRType** %478 = load %LBstd.Cprocess.CRType*, %LBstd.Cprocess.CRType** %477, align 8 %479 = getelementptr
2019 Jun 24
2
RFC: Interface user provided vector functions with the vectorizer.
>Thank you everybody for their input, and for your patience. This is proving harder than expected! :) Thank you for doing the hard part of the work. Hideki -----Original Message----- From: Francesco Petrogalli [mailto:Francesco.Petrogalli at arm.com] Sent: Monday, June 24, 2019 11:26 AM To: Saito, Hideki <hideki.saito at intel.com> Cc: Doerfert, Johannes <jdoerfert at anl.gov>;
2020 Mar 20
2
RISC-V LLVM sync-up call 19 Mar 2020
If I’m following correctly, there are two size-limited areas. One area, limited to 2GB, is the “text” area. This contains all the code. Then there’s a “global” area, limited to 4GB, which is pointed to by the global pointer. This contains the GOT, plus a flexible area that the object file can stick small bits of data into. And then outside of both of those, additional data is unlimited. It
2019 Jan 30
2
[8.0.0 Release] rc1 has been tagged
Alex, ping? There was a thread about moving Risc-V out of experimental but I think it didn't go anywhere? Separately, do the listed patches sound okay for merging? Thanks, Hans On Fri, Jan 25, 2019 at 4:40 PM Bruce Hoult <brucehoult at sifive.com> wrote: > > In https://llvm.org/svn/llvm-project/llvm/branches/release_80 I find > that RISCV is still in
2019 Jun 21
2
RFC: Interface user provided vector functions with the vectorizer.
>In all cases, the IR type of the parameters in `foo` is i64, therefore is not possible to distinguish what C type generated the signature of `foo`. Ouch. >I don’t know if this is going to be a problem for other architectures I haven't checked what IA-32/Intel64 should do for type 2, but I fully agree that this needs to be done properly according to the ABI. >Therefore, I would
2020 Mar 20
2
RISC-V LLVM sync-up call 19 Mar 2020
Oh, I wasn’t really thinking about devices without an MMU where the addresses are physically separated. Makes sense. This reminds me of rwpi on ARM; it has a sort of similar scheme of referring to data indirectly through a pointer, but it also changes the ABI to keep the pointer in a reserved register. -Eli From: Evandro Menezes <evandro.menezes at sifive.com> Sent: Friday, March 20, 2020
2020 Jan 16
7
[RFC] Upstream development of support for yet-to-be-ratified RISC-V extensions
# Overview and background RISC-V is a free and open instruction set architecture. It is a modular specification, with a range of standard extensions (e.g. floating point, atomics, etc). New standard extensions are developed through RISC-V Foundation working groups. The specifications for such extensions (e.g. vector and bit manipulation) are publicly available, but are still in flux and won't
2020 Mar 23
2
RISC-V LLVM sync-up call 19 Mar 2020
Hi, Sam. I think that it's a fair comparison. Keep in mind that the GP is only used to reach global variables of local scope and the GOT, where the address of global variables of global scope reside. This model assumes that the distance between the GP and the global data area, GOT and local scope variables is defined at link time. __ Evandro Menezes ◊ SiFive ◊ Austin, TX > On Mar