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jinx/ARMeilleure/IntermediateRepresentation/Intrinsic.cs
Wunk 45ce540b9b
ARMeilleure: Add gfni acceleration (#3669)
* ARMeilleure: Add `GFNI` detection

This is intended for utilizing the `gf2p8affineqb` instruction

* ARMeilleure: Add `gf2p8affineqb`

Not using the VEX or EVEX-form of this instruction is intentional. There
are `GFNI`-chips that do not support AVX(so no VEX encoding) such as
Tremont(Lakefield) chips as well as Jasper Lake.

13df339fe7/GenuineIntel/GenuineIntel00806A1_Lakefield_LC_InstLatX64.txt (L1297-L1299)

13df339fe7/GenuineIntel/GenuineIntel00906C0_JasperLake_InstLatX64.txt (L1252-L1254)

* ARMeilleure: Add `gfni` acceleration of `Rbit_V`

Passes all `Rbit_V*` unit tests on my `i9-11900k`

* ARMeilleure: Add `gfni` acceleration of `S{l,r}i_V`

Also added a fast-path for when the shift amount is greater than the
size of the element.

* ARMeilleure: Add `gfni` acceleration of `Shl_V` and `Sshr_V`

* ARMeilleure: Increment InternalVersion

* ARMeilleure: Fix Intrinsic and Assembler Table alignment

`gf2p8affineqb` is the longest instruction name I know of. It shouldn't
get any wider than this.

* ARMeilleure: Remove SSE2+SHA requirement for GFNI

* ARMeilleure Add `X86GetGf2p8LogicalShiftLeft`

Used to generate GF(2^8) 8x8 bit-matrices for bit-shifting for the `gf2p8affineqb` instruction.

* ARMeilleure: Append `FeatureInfo7Ecx` to `FeatureInfo`
2022-10-02 11:17:19 +02:00

177 lines
No EOL
3.4 KiB
C#

namespace ARMeilleure.IntermediateRepresentation
{
enum Intrinsic : ushort
{
X86Addpd,
X86Addps,
X86Addsd,
X86Addss,
X86Aesdec,
X86Aesdeclast,
X86Aesenc,
X86Aesenclast,
X86Aesimc,
X86Andnpd,
X86Andnps,
X86Andpd,
X86Andps,
X86Blendvpd,
X86Blendvps,
X86Cmppd,
X86Cmpps,
X86Cmpsd,
X86Cmpss,
X86Comisdeq,
X86Comisdge,
X86Comisdlt,
X86Comisseq,
X86Comissge,
X86Comisslt,
X86Crc32,
X86Crc32_16,
X86Crc32_8,
X86Cvtdq2pd,
X86Cvtdq2ps,
X86Cvtpd2dq,
X86Cvtpd2ps,
X86Cvtps2dq,
X86Cvtps2pd,
X86Cvtsd2si,
X86Cvtsd2ss,
X86Cvtsi2sd,
X86Cvtsi2si,
X86Cvtsi2ss,
X86Cvtss2sd,
X86Cvtss2si,
X86Divpd,
X86Divps,
X86Divsd,
X86Divss,
X86Gf2p8affineqb,
X86Haddpd,
X86Haddps,
X86Insertps,
X86Maxpd,
X86Maxps,
X86Maxsd,
X86Maxss,
X86Minpd,
X86Minps,
X86Minsd,
X86Minss,
X86Movhlps,
X86Movlhps,
X86Movss,
X86Mulpd,
X86Mulps,
X86Mulsd,
X86Mulss,
X86Mxcsrmb,
X86Mxcsrub,
X86Paddb,
X86Paddd,
X86Paddq,
X86Paddw,
X86Palignr,
X86Pand,
X86Pandn,
X86Pavgb,
X86Pavgw,
X86Pblendvb,
X86Pclmulqdq,
X86Pcmpeqb,
X86Pcmpeqd,
X86Pcmpeqq,
X86Pcmpeqw,
X86Pcmpgtb,
X86Pcmpgtd,
X86Pcmpgtq,
X86Pcmpgtw,
X86Pmaxsb,
X86Pmaxsd,
X86Pmaxsw,
X86Pmaxub,
X86Pmaxud,
X86Pmaxuw,
X86Pminsb,
X86Pminsd,
X86Pminsw,
X86Pminub,
X86Pminud,
X86Pminuw,
X86Pmovsxbw,
X86Pmovsxdq,
X86Pmovsxwd,
X86Pmovzxbw,
X86Pmovzxdq,
X86Pmovzxwd,
X86Pmulld,
X86Pmullw,
X86Popcnt,
X86Por,
X86Pshufb,
X86Pshufd,
X86Pslld,
X86Pslldq,
X86Psllq,
X86Psllw,
X86Psrad,
X86Psraw,
X86Psrld,
X86Psrlq,
X86Psrldq,
X86Psrlw,
X86Psubb,
X86Psubd,
X86Psubq,
X86Psubw,
X86Punpckhbw,
X86Punpckhdq,
X86Punpckhqdq,
X86Punpckhwd,
X86Punpcklbw,
X86Punpckldq,
X86Punpcklqdq,
X86Punpcklwd,
X86Pxor,
X86Rcpps,
X86Rcpss,
X86Roundpd,
X86Roundps,
X86Roundsd,
X86Roundss,
X86Rsqrtps,
X86Rsqrtss,
X86Sha256Msg1,
X86Sha256Msg2,
X86Sha256Rnds2,
X86Shufpd,
X86Shufps,
X86Sqrtpd,
X86Sqrtps,
X86Sqrtsd,
X86Sqrtss,
X86Subpd,
X86Subps,
X86Subsd,
X86Subss,
X86Unpckhpd,
X86Unpckhps,
X86Unpcklpd,
X86Unpcklps,
X86Vcvtph2ps,
X86Vcvtps2ph,
X86Vfmadd231ps,
X86Vfmadd231sd,
X86Vfmadd231ss,
X86Vfmsub231sd,
X86Vfmsub231ss,
X86Vfnmadd231ps,
X86Vfnmadd231sd,
X86Vfnmadd231ss,
X86Vfnmsub231sd,
X86Vfnmsub231ss,
X86Xorpd,
X86Xorps
}
}