1
0
Fork 0
mirror of https://github.com/Ryujinx/Ryujinx.git synced 2024-12-26 00:16:01 +00:00
Ryujinx/ARMeilleure/CodeGen/X86/IntrinsicTable.cs

200 lines
20 KiB
C#
Raw Normal View History

Add a new JIT compiler for CPU code (#693) * Start of the ARMeilleure project * Refactoring around the old IRAdapter, now renamed to PreAllocator * Optimize the LowestBitSet method * Add CLZ support and fix CLS implementation * Add missing Equals and GetHashCode overrides on some structs, misc small tweaks * Implement the ByteSwap IR instruction, and some refactoring on the assembler * Implement the DivideUI IR instruction and fix 64-bits IDIV * Correct constant operand type on CSINC * Move division instructions implementation to InstEmitDiv * Fix destination type for the ConditionalSelect IR instruction * Implement UMULH and SMULH, with new IR instructions * Fix some issues with shift instructions * Fix constant types for BFM instructions * Fix up new tests using the new V128 struct * Update tests * Move DIV tests to a separate file * Add support for calls, and some instructions that depends on them * Start adding support for SIMD & FP types, along with some of the related ARM instructions * Fix some typos and the divide instruction with FP operands * Fix wrong method call on Clz_V * Implement ARM FP & SIMD move instructions, Saddlv_V, and misc. fixes * Implement SIMD logical instructions and more misc. fixes * Fix PSRAD x86 instruction encoding, TRN, UABD and UABDL implementations * Implement float conversion instruction, merge in LDj3SNuD fixes, and some other misc. fixes * Implement SIMD shift instruction and fix Dup_V * Add SCVTF and UCVTF (vector, fixed-point) variants to the opcode table * Fix check with tolerance on tester * Implement FP & SIMD comparison instructions, and some fixes * Update FCVT (Scalar) encoding on the table to support the Half-float variants * Support passing V128 structs, some cleanup on the register allocator, merge LDj3SNuD fixes * Use old memory access methods, made a start on SIMD memory insts support, some fixes * Fix float constant passed to functions, save and restore non-volatile XMM registers, other fixes * Fix arguments count with struct return values, other fixes * More instructions * Misc. fixes and integrate LDj3SNuD fixes * Update tests * Add a faster linear scan allocator, unwinding support on windows, and other changes * Update Ryujinx.HLE * Update Ryujinx.Graphics * Fix V128 return pointer passing, RCX is clobbered * Update Ryujinx.Tests * Update ITimeZoneService * Stop using GetFunctionPointer as that can't be called from native code, misc. fixes and tweaks * Use generic GetFunctionPointerForDelegate method and other tweaks * Some refactoring on the code generator, assert on invalid operations and use a separate enum for intrinsics * Remove some unused code on the assembler * Fix REX.W prefix regression on float conversion instructions, add some sort of profiler * Add hardware capability detection * Fix regression on Sha1h and revert Fcm** changes * Add SSE2-only paths on vector extract and insert, some refactoring on the pre-allocator * Fix silly mistake introduced on last commit on CpuId * Generate inline stack probes when the stack allocation is too large * Initial support for the System-V ABI * Support multiple destination operands * Fix SSE2 VectorInsert8 path, and other fixes * Change placement of XMM callee save and restore code to match other compilers * Rename Dest to Destination and Inst to Instruction * Fix a regression related to calls and the V128 type * Add an extra space on comments to match code style * Some refactoring * Fix vector insert FP32 SSE2 path * Port over the ARM32 instructions * Avoid memory protection races on JIT Cache * Another fix on VectorInsert FP32 (thanks to LDj3SNuD * Float operands don't need to use the same register when VEX is supported * Add a new register allocator, higher quality code for hot code (tier up), and other tweaks * Some nits, small improvements on the pre allocator * CpuThreadState is gone * Allow changing CPU emulators with a config entry * Add runtime identifiers on the ARMeilleure project * Allow switching between CPUs through a config entry (pt. 2) * Change win10-x64 to win-x64 on projects * Update the Ryujinx project to use ARMeilleure * Ensure that the selected register is valid on the hybrid allocator * Allow exiting on returns to 0 (should fix test regression) * Remove register assignments for most used variables on the hybrid allocator * Do not use fixed registers as spill temp * Add missing namespace and remove unneeded using * Address PR feedback * Fix types, etc * Enable AssumeStrictAbiCompliance by default * Ensure that Spill and Fill don't load or store any more than necessary
2019-08-08 19:56:22 +01:00
using ARMeilleure.Common;
using ARMeilleure.IntermediateRepresentation;
namespace ARMeilleure.CodeGen.X86
{
static class IntrinsicTable
{
private static IntrinsicInfo[] _intrinTable;
static IntrinsicTable()
{
_intrinTable = new IntrinsicInfo[EnumUtils.GetCount(typeof(Intrinsic))];
Add(Intrinsic.X86Addpd, new IntrinsicInfo(X86Instruction.Addpd, IntrinsicType.Binary));
Add(Intrinsic.X86Addps, new IntrinsicInfo(X86Instruction.Addps, IntrinsicType.Binary));
Add(Intrinsic.X86Addsd, new IntrinsicInfo(X86Instruction.Addsd, IntrinsicType.Binary));
Add(Intrinsic.X86Addss, new IntrinsicInfo(X86Instruction.Addss, IntrinsicType.Binary));
Add(Intrinsic.X86Aesdec, new IntrinsicInfo(X86Instruction.Aesdec, IntrinsicType.Binary));
Add(Intrinsic.X86Aesdeclast, new IntrinsicInfo(X86Instruction.Aesdeclast, IntrinsicType.Binary));
Add(Intrinsic.X86Aesenc, new IntrinsicInfo(X86Instruction.Aesenc, IntrinsicType.Binary));
Add(Intrinsic.X86Aesenclast, new IntrinsicInfo(X86Instruction.Aesenclast, IntrinsicType.Binary));
Add(Intrinsic.X86Aesimc, new IntrinsicInfo(X86Instruction.Aesimc, IntrinsicType.Unary));
Add(Intrinsic.X86Andnpd, new IntrinsicInfo(X86Instruction.Andnpd, IntrinsicType.Binary));
Add(Intrinsic.X86Andnps, new IntrinsicInfo(X86Instruction.Andnps, IntrinsicType.Binary));
Add(Intrinsic.X86Andpd, new IntrinsicInfo(X86Instruction.Andpd, IntrinsicType.Binary));
Add(Intrinsic.X86Andps, new IntrinsicInfo(X86Instruction.Andps, IntrinsicType.Binary));
Add(Intrinsic.X86Blendvpd, new IntrinsicInfo(X86Instruction.Blendvpd, IntrinsicType.Ternary));
Add(Intrinsic.X86Blendvps, new IntrinsicInfo(X86Instruction.Blendvps, IntrinsicType.Ternary));
Add(Intrinsic.X86Cmppd, new IntrinsicInfo(X86Instruction.Cmppd, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Cmpps, new IntrinsicInfo(X86Instruction.Cmpps, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Cmpsd, new IntrinsicInfo(X86Instruction.Cmpsd, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Cmpss, new IntrinsicInfo(X86Instruction.Cmpss, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Comisdeq, new IntrinsicInfo(X86Instruction.Comisd, IntrinsicType.Comis_));
Add(Intrinsic.X86Comisdge, new IntrinsicInfo(X86Instruction.Comisd, IntrinsicType.Comis_));
Add(Intrinsic.X86Comisdlt, new IntrinsicInfo(X86Instruction.Comisd, IntrinsicType.Comis_));
Add(Intrinsic.X86Comisseq, new IntrinsicInfo(X86Instruction.Comiss, IntrinsicType.Comis_));
Add(Intrinsic.X86Comissge, new IntrinsicInfo(X86Instruction.Comiss, IntrinsicType.Comis_));
Add(Intrinsic.X86Comisslt, new IntrinsicInfo(X86Instruction.Comiss, IntrinsicType.Comis_));
Add(Intrinsic.X86Crc32, new IntrinsicInfo(X86Instruction.Crc32, IntrinsicType.Crc32));
Add(Intrinsic.X86Crc32_16, new IntrinsicInfo(X86Instruction.Crc32_16, IntrinsicType.Crc32));
Add(Intrinsic.X86Crc32_8, new IntrinsicInfo(X86Instruction.Crc32_8, IntrinsicType.Crc32));
Add(Intrinsic.X86Cvtdq2pd, new IntrinsicInfo(X86Instruction.Cvtdq2pd, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtdq2ps, new IntrinsicInfo(X86Instruction.Cvtdq2ps, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtpd2dq, new IntrinsicInfo(X86Instruction.Cvtpd2dq, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtpd2ps, new IntrinsicInfo(X86Instruction.Cvtpd2ps, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtps2dq, new IntrinsicInfo(X86Instruction.Cvtps2dq, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtps2pd, new IntrinsicInfo(X86Instruction.Cvtps2pd, IntrinsicType.Unary));
Add(Intrinsic.X86Cvtsd2si, new IntrinsicInfo(X86Instruction.Cvtsd2si, IntrinsicType.UnaryToGpr));
Add(Intrinsic.X86Cvtsd2ss, new IntrinsicInfo(X86Instruction.Cvtsd2ss, IntrinsicType.Binary));
Add(Intrinsic.X86Cvtsi2sd, new IntrinsicInfo(X86Instruction.Cvtsi2sd, IntrinsicType.BinaryGpr));
Add(Intrinsic.X86Cvtsi2si, new IntrinsicInfo(X86Instruction.Movd, IntrinsicType.UnaryToGpr));
Add(Intrinsic.X86Cvtsi2ss, new IntrinsicInfo(X86Instruction.Cvtsi2ss, IntrinsicType.BinaryGpr));
Add(Intrinsic.X86Cvtss2sd, new IntrinsicInfo(X86Instruction.Cvtss2sd, IntrinsicType.Binary));
Add(Intrinsic.X86Cvtss2si, new IntrinsicInfo(X86Instruction.Cvtss2si, IntrinsicType.UnaryToGpr));
Add(Intrinsic.X86Divpd, new IntrinsicInfo(X86Instruction.Divpd, IntrinsicType.Binary));
Add(Intrinsic.X86Divps, new IntrinsicInfo(X86Instruction.Divps, IntrinsicType.Binary));
Add(Intrinsic.X86Divsd, new IntrinsicInfo(X86Instruction.Divsd, IntrinsicType.Binary));
Add(Intrinsic.X86Divss, new IntrinsicInfo(X86Instruction.Divss, IntrinsicType.Binary));
Add(Intrinsic.X86Gf2p8affineqb, new IntrinsicInfo(X86Instruction.Gf2p8affineqb, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Haddpd, new IntrinsicInfo(X86Instruction.Haddpd, IntrinsicType.Binary));
Add(Intrinsic.X86Haddps, new IntrinsicInfo(X86Instruction.Haddps, IntrinsicType.Binary));
Add(Intrinsic.X86Insertps, new IntrinsicInfo(X86Instruction.Insertps, IntrinsicType.TernaryImm));
ARMeilleure: Respect FZ/RM flags for all floating point operations (#4618) * ARMeilleure: Respect Fz flag for all floating point operations. This is a change in strategy for emulating the Fz FPCR flag. Before, it was set before instructions that "needed it" and reset after. However, this missed a few hot instructions like the multiplication instruction, and the entirety of A32. The new strategy is to set the Fz flag only in the following circumstances: - Set to match FPCR before translated functions/loop are executed. - Reset when calling SoftFloat methods, set when returning. - Reset when exiting execution. This allows us to remove the code around the existing Fz aware instructions, and get the accuracy benefits on all floating point instructions executed while in translated code. Single step executions now need to be called with a context wrapper - right now it just contains the Fz flag initialization, and won't actually do anything on ARM. This fixes a bug in Breath of the Wild where some physics interactions could randomly crash the game due to subnormal values not flushing to zero. This is draft right now because I need to answer the questions: - Does dotnet avoid changing the value of Mxcsr? - Is it a good idea to assume that? Or should the flag set/restore be done on every managed method call, not just softfloat? - If we assume that, do we want a unit test to verify the behaviour? I recommend testing a bunch of games, especially games affected when this was originally added, such as #1611. * Remove unused method * Use FMA for Fmadd, Fmsub, Fnmadd, Fnmsub, Fmla, Fmls ...when available. Similar implementation to A32 * Use FMA for Frecps, Frsqrts * Don't set DAZ. * Add round mode to ARM FP mode * Fix mistakes * Add test for FP state when calling managed methods * Add explanatory comment to test. * Cleanup * Add A64 FPCR flags * Vrintx_S A32 fast path on A64 backend * Address feedback 1, re-enable DAZ * Fix FMA instructions By Elem * Address feedback
2023-04-10 11:22:58 +01:00
Add(Intrinsic.X86Ldmxcsr, new IntrinsicInfo(X86Instruction.None, IntrinsicType.Mxcsr));
Add(Intrinsic.X86Maxpd, new IntrinsicInfo(X86Instruction.Maxpd, IntrinsicType.Binary));
Add(Intrinsic.X86Maxps, new IntrinsicInfo(X86Instruction.Maxps, IntrinsicType.Binary));
Add(Intrinsic.X86Maxsd, new IntrinsicInfo(X86Instruction.Maxsd, IntrinsicType.Binary));
Add(Intrinsic.X86Maxss, new IntrinsicInfo(X86Instruction.Maxss, IntrinsicType.Binary));
Add(Intrinsic.X86Minpd, new IntrinsicInfo(X86Instruction.Minpd, IntrinsicType.Binary));
Add(Intrinsic.X86Minps, new IntrinsicInfo(X86Instruction.Minps, IntrinsicType.Binary));
Add(Intrinsic.X86Minsd, new IntrinsicInfo(X86Instruction.Minsd, IntrinsicType.Binary));
Add(Intrinsic.X86Minss, new IntrinsicInfo(X86Instruction.Minss, IntrinsicType.Binary));
Add(Intrinsic.X86Movhlps, new IntrinsicInfo(X86Instruction.Movhlps, IntrinsicType.Binary));
Add(Intrinsic.X86Movlhps, new IntrinsicInfo(X86Instruction.Movlhps, IntrinsicType.Binary));
Add(Intrinsic.X86Movss, new IntrinsicInfo(X86Instruction.Movss, IntrinsicType.Binary));
Add(Intrinsic.X86Mulpd, new IntrinsicInfo(X86Instruction.Mulpd, IntrinsicType.Binary));
Add(Intrinsic.X86Mulps, new IntrinsicInfo(X86Instruction.Mulps, IntrinsicType.Binary));
Add(Intrinsic.X86Mulsd, new IntrinsicInfo(X86Instruction.Mulsd, IntrinsicType.Binary));
Add(Intrinsic.X86Mulss, new IntrinsicInfo(X86Instruction.Mulss, IntrinsicType.Binary));
Add(Intrinsic.X86Paddb, new IntrinsicInfo(X86Instruction.Paddb, IntrinsicType.Binary));
Add(Intrinsic.X86Paddd, new IntrinsicInfo(X86Instruction.Paddd, IntrinsicType.Binary));
Add(Intrinsic.X86Paddq, new IntrinsicInfo(X86Instruction.Paddq, IntrinsicType.Binary));
Add(Intrinsic.X86Paddw, new IntrinsicInfo(X86Instruction.Paddw, IntrinsicType.Binary));
Add(Intrinsic.X86Palignr, new IntrinsicInfo(X86Instruction.Palignr, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Pand, new IntrinsicInfo(X86Instruction.Pand, IntrinsicType.Binary));
Add(Intrinsic.X86Pandn, new IntrinsicInfo(X86Instruction.Pandn, IntrinsicType.Binary));
Add(Intrinsic.X86Pavgb, new IntrinsicInfo(X86Instruction.Pavgb, IntrinsicType.Binary));
Add(Intrinsic.X86Pavgw, new IntrinsicInfo(X86Instruction.Pavgw, IntrinsicType.Binary));
Add(Intrinsic.X86Pblendvb, new IntrinsicInfo(X86Instruction.Pblendvb, IntrinsicType.Ternary));
Add(Intrinsic.X86Pclmulqdq, new IntrinsicInfo(X86Instruction.Pclmulqdq, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Pcmpeqb, new IntrinsicInfo(X86Instruction.Pcmpeqb, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpeqd, new IntrinsicInfo(X86Instruction.Pcmpeqd, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpeqq, new IntrinsicInfo(X86Instruction.Pcmpeqq, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpeqw, new IntrinsicInfo(X86Instruction.Pcmpeqw, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpgtb, new IntrinsicInfo(X86Instruction.Pcmpgtb, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpgtd, new IntrinsicInfo(X86Instruction.Pcmpgtd, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpgtq, new IntrinsicInfo(X86Instruction.Pcmpgtq, IntrinsicType.Binary));
Add(Intrinsic.X86Pcmpgtw, new IntrinsicInfo(X86Instruction.Pcmpgtw, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxsb, new IntrinsicInfo(X86Instruction.Pmaxsb, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxsd, new IntrinsicInfo(X86Instruction.Pmaxsd, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxsw, new IntrinsicInfo(X86Instruction.Pmaxsw, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxub, new IntrinsicInfo(X86Instruction.Pmaxub, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxud, new IntrinsicInfo(X86Instruction.Pmaxud, IntrinsicType.Binary));
Add(Intrinsic.X86Pmaxuw, new IntrinsicInfo(X86Instruction.Pmaxuw, IntrinsicType.Binary));
Add(Intrinsic.X86Pminsb, new IntrinsicInfo(X86Instruction.Pminsb, IntrinsicType.Binary));
Add(Intrinsic.X86Pminsd, new IntrinsicInfo(X86Instruction.Pminsd, IntrinsicType.Binary));
Add(Intrinsic.X86Pminsw, new IntrinsicInfo(X86Instruction.Pminsw, IntrinsicType.Binary));
Add(Intrinsic.X86Pminub, new IntrinsicInfo(X86Instruction.Pminub, IntrinsicType.Binary));
Add(Intrinsic.X86Pminud, new IntrinsicInfo(X86Instruction.Pminud, IntrinsicType.Binary));
Add(Intrinsic.X86Pminuw, new IntrinsicInfo(X86Instruction.Pminuw, IntrinsicType.Binary));
Add(Intrinsic.X86Pmovsxbw, new IntrinsicInfo(X86Instruction.Pmovsxbw, IntrinsicType.Unary));
Add(Intrinsic.X86Pmovsxdq, new IntrinsicInfo(X86Instruction.Pmovsxdq, IntrinsicType.Unary));
Add(Intrinsic.X86Pmovsxwd, new IntrinsicInfo(X86Instruction.Pmovsxwd, IntrinsicType.Unary));
Add(Intrinsic.X86Pmovzxbw, new IntrinsicInfo(X86Instruction.Pmovzxbw, IntrinsicType.Unary));
Add(Intrinsic.X86Pmovzxdq, new IntrinsicInfo(X86Instruction.Pmovzxdq, IntrinsicType.Unary));
Add(Intrinsic.X86Pmovzxwd, new IntrinsicInfo(X86Instruction.Pmovzxwd, IntrinsicType.Unary));
Add(Intrinsic.X86Pmulld, new IntrinsicInfo(X86Instruction.Pmulld, IntrinsicType.Binary));
Add(Intrinsic.X86Pmullw, new IntrinsicInfo(X86Instruction.Pmullw, IntrinsicType.Binary));
Add(Intrinsic.X86Popcnt, new IntrinsicInfo(X86Instruction.Popcnt, IntrinsicType.PopCount));
Add(Intrinsic.X86Por, new IntrinsicInfo(X86Instruction.Por, IntrinsicType.Binary));
Add(Intrinsic.X86Pshufb, new IntrinsicInfo(X86Instruction.Pshufb, IntrinsicType.Binary));
Add(Intrinsic.X86Pshufd, new IntrinsicInfo(X86Instruction.Pshufd, IntrinsicType.BinaryImm));
Add(Intrinsic.X86Pslld, new IntrinsicInfo(X86Instruction.Pslld, IntrinsicType.Binary));
Add(Intrinsic.X86Pslldq, new IntrinsicInfo(X86Instruction.Pslldq, IntrinsicType.Binary));
Add(Intrinsic.X86Psllq, new IntrinsicInfo(X86Instruction.Psllq, IntrinsicType.Binary));
Add(Intrinsic.X86Psllw, new IntrinsicInfo(X86Instruction.Psllw, IntrinsicType.Binary));
Add(Intrinsic.X86Psrad, new IntrinsicInfo(X86Instruction.Psrad, IntrinsicType.Binary));
Add(Intrinsic.X86Psraw, new IntrinsicInfo(X86Instruction.Psraw, IntrinsicType.Binary));
Add(Intrinsic.X86Psrld, new IntrinsicInfo(X86Instruction.Psrld, IntrinsicType.Binary));
Add(Intrinsic.X86Psrlq, new IntrinsicInfo(X86Instruction.Psrlq, IntrinsicType.Binary));
Add(Intrinsic.X86Psrldq, new IntrinsicInfo(X86Instruction.Psrldq, IntrinsicType.Binary));
Add(Intrinsic.X86Psrlw, new IntrinsicInfo(X86Instruction.Psrlw, IntrinsicType.Binary));
Add(Intrinsic.X86Psubb, new IntrinsicInfo(X86Instruction.Psubb, IntrinsicType.Binary));
Add(Intrinsic.X86Psubd, new IntrinsicInfo(X86Instruction.Psubd, IntrinsicType.Binary));
Add(Intrinsic.X86Psubq, new IntrinsicInfo(X86Instruction.Psubq, IntrinsicType.Binary));
Add(Intrinsic.X86Psubw, new IntrinsicInfo(X86Instruction.Psubw, IntrinsicType.Binary));
Add(Intrinsic.X86Punpckhbw, new IntrinsicInfo(X86Instruction.Punpckhbw, IntrinsicType.Binary));
Add(Intrinsic.X86Punpckhdq, new IntrinsicInfo(X86Instruction.Punpckhdq, IntrinsicType.Binary));
Add(Intrinsic.X86Punpckhqdq, new IntrinsicInfo(X86Instruction.Punpckhqdq, IntrinsicType.Binary));
Add(Intrinsic.X86Punpckhwd, new IntrinsicInfo(X86Instruction.Punpckhwd, IntrinsicType.Binary));
Add(Intrinsic.X86Punpcklbw, new IntrinsicInfo(X86Instruction.Punpcklbw, IntrinsicType.Binary));
Add(Intrinsic.X86Punpckldq, new IntrinsicInfo(X86Instruction.Punpckldq, IntrinsicType.Binary));
Add(Intrinsic.X86Punpcklqdq, new IntrinsicInfo(X86Instruction.Punpcklqdq, IntrinsicType.Binary));
Add(Intrinsic.X86Punpcklwd, new IntrinsicInfo(X86Instruction.Punpcklwd, IntrinsicType.Binary));
Add(Intrinsic.X86Pxor, new IntrinsicInfo(X86Instruction.Pxor, IntrinsicType.Binary));
Add(Intrinsic.X86Rcpps, new IntrinsicInfo(X86Instruction.Rcpps, IntrinsicType.Unary));
Add(Intrinsic.X86Rcpss, new IntrinsicInfo(X86Instruction.Rcpss, IntrinsicType.Unary));
Add(Intrinsic.X86Roundpd, new IntrinsicInfo(X86Instruction.Roundpd, IntrinsicType.BinaryImm));
Add(Intrinsic.X86Roundps, new IntrinsicInfo(X86Instruction.Roundps, IntrinsicType.BinaryImm));
Add(Intrinsic.X86Roundsd, new IntrinsicInfo(X86Instruction.Roundsd, IntrinsicType.BinaryImm));
Add(Intrinsic.X86Roundss, new IntrinsicInfo(X86Instruction.Roundss, IntrinsicType.BinaryImm));
Add(Intrinsic.X86Rsqrtps, new IntrinsicInfo(X86Instruction.Rsqrtps, IntrinsicType.Unary));
Add(Intrinsic.X86Rsqrtss, new IntrinsicInfo(X86Instruction.Rsqrtss, IntrinsicType.Unary));
Add(Intrinsic.X86Sha256Msg1, new IntrinsicInfo(X86Instruction.Sha256Msg1, IntrinsicType.Binary));
Add(Intrinsic.X86Sha256Msg2, new IntrinsicInfo(X86Instruction.Sha256Msg2, IntrinsicType.Binary));
Add(Intrinsic.X86Sha256Rnds2, new IntrinsicInfo(X86Instruction.Sha256Rnds2, IntrinsicType.Ternary));
Add(Intrinsic.X86Shufpd, new IntrinsicInfo(X86Instruction.Shufpd, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Shufps, new IntrinsicInfo(X86Instruction.Shufps, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Sqrtpd, new IntrinsicInfo(X86Instruction.Sqrtpd, IntrinsicType.Unary));
Add(Intrinsic.X86Sqrtps, new IntrinsicInfo(X86Instruction.Sqrtps, IntrinsicType.Unary));
Add(Intrinsic.X86Sqrtsd, new IntrinsicInfo(X86Instruction.Sqrtsd, IntrinsicType.Unary));
Add(Intrinsic.X86Sqrtss, new IntrinsicInfo(X86Instruction.Sqrtss, IntrinsicType.Unary));
ARMeilleure: Respect FZ/RM flags for all floating point operations (#4618) * ARMeilleure: Respect Fz flag for all floating point operations. This is a change in strategy for emulating the Fz FPCR flag. Before, it was set before instructions that "needed it" and reset after. However, this missed a few hot instructions like the multiplication instruction, and the entirety of A32. The new strategy is to set the Fz flag only in the following circumstances: - Set to match FPCR before translated functions/loop are executed. - Reset when calling SoftFloat methods, set when returning. - Reset when exiting execution. This allows us to remove the code around the existing Fz aware instructions, and get the accuracy benefits on all floating point instructions executed while in translated code. Single step executions now need to be called with a context wrapper - right now it just contains the Fz flag initialization, and won't actually do anything on ARM. This fixes a bug in Breath of the Wild where some physics interactions could randomly crash the game due to subnormal values not flushing to zero. This is draft right now because I need to answer the questions: - Does dotnet avoid changing the value of Mxcsr? - Is it a good idea to assume that? Or should the flag set/restore be done on every managed method call, not just softfloat? - If we assume that, do we want a unit test to verify the behaviour? I recommend testing a bunch of games, especially games affected when this was originally added, such as #1611. * Remove unused method * Use FMA for Fmadd, Fmsub, Fnmadd, Fnmsub, Fmla, Fmls ...when available. Similar implementation to A32 * Use FMA for Frecps, Frsqrts * Don't set DAZ. * Add round mode to ARM FP mode * Fix mistakes * Add test for FP state when calling managed methods * Add explanatory comment to test. * Cleanup * Add A64 FPCR flags * Vrintx_S A32 fast path on A64 backend * Address feedback 1, re-enable DAZ * Fix FMA instructions By Elem * Address feedback
2023-04-10 11:22:58 +01:00
Add(Intrinsic.X86Stmxcsr, new IntrinsicInfo(X86Instruction.None, IntrinsicType.Mxcsr));
Add(Intrinsic.X86Subpd, new IntrinsicInfo(X86Instruction.Subpd, IntrinsicType.Binary));
Add(Intrinsic.X86Subps, new IntrinsicInfo(X86Instruction.Subps, IntrinsicType.Binary));
Add(Intrinsic.X86Subsd, new IntrinsicInfo(X86Instruction.Subsd, IntrinsicType.Binary));
Add(Intrinsic.X86Subss, new IntrinsicInfo(X86Instruction.Subss, IntrinsicType.Binary));
Add(Intrinsic.X86Unpckhpd, new IntrinsicInfo(X86Instruction.Unpckhpd, IntrinsicType.Binary));
Add(Intrinsic.X86Unpckhps, new IntrinsicInfo(X86Instruction.Unpckhps, IntrinsicType.Binary));
Add(Intrinsic.X86Unpcklpd, new IntrinsicInfo(X86Instruction.Unpcklpd, IntrinsicType.Binary));
Add(Intrinsic.X86Unpcklps, new IntrinsicInfo(X86Instruction.Unpcklps, IntrinsicType.Binary));
Add(Intrinsic.X86Vcvtph2ps, new IntrinsicInfo(X86Instruction.Vcvtph2ps, IntrinsicType.Unary));
Add(Intrinsic.X86Vcvtps2ph, new IntrinsicInfo(X86Instruction.Vcvtps2ph, IntrinsicType.BinaryImm));
ARMeilleure: Respect FZ/RM flags for all floating point operations (#4618) * ARMeilleure: Respect Fz flag for all floating point operations. This is a change in strategy for emulating the Fz FPCR flag. Before, it was set before instructions that "needed it" and reset after. However, this missed a few hot instructions like the multiplication instruction, and the entirety of A32. The new strategy is to set the Fz flag only in the following circumstances: - Set to match FPCR before translated functions/loop are executed. - Reset when calling SoftFloat methods, set when returning. - Reset when exiting execution. This allows us to remove the code around the existing Fz aware instructions, and get the accuracy benefits on all floating point instructions executed while in translated code. Single step executions now need to be called with a context wrapper - right now it just contains the Fz flag initialization, and won't actually do anything on ARM. This fixes a bug in Breath of the Wild where some physics interactions could randomly crash the game due to subnormal values not flushing to zero. This is draft right now because I need to answer the questions: - Does dotnet avoid changing the value of Mxcsr? - Is it a good idea to assume that? Or should the flag set/restore be done on every managed method call, not just softfloat? - If we assume that, do we want a unit test to verify the behaviour? I recommend testing a bunch of games, especially games affected when this was originally added, such as #1611. * Remove unused method * Use FMA for Fmadd, Fmsub, Fnmadd, Fnmsub, Fmla, Fmls ...when available. Similar implementation to A32 * Use FMA for Frecps, Frsqrts * Don't set DAZ. * Add round mode to ARM FP mode * Fix mistakes * Add test for FP state when calling managed methods * Add explanatory comment to test. * Cleanup * Add A64 FPCR flags * Vrintx_S A32 fast path on A64 backend * Address feedback 1, re-enable DAZ * Fix FMA instructions By Elem * Address feedback
2023-04-10 11:22:58 +01:00
Add(Intrinsic.X86Vfmadd231pd, new IntrinsicInfo(X86Instruction.Vfmadd231pd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfmadd231ps, new IntrinsicInfo(X86Instruction.Vfmadd231ps, IntrinsicType.Fma));
Add(Intrinsic.X86Vfmadd231sd, new IntrinsicInfo(X86Instruction.Vfmadd231sd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfmadd231ss, new IntrinsicInfo(X86Instruction.Vfmadd231ss, IntrinsicType.Fma));
Add(Intrinsic.X86Vfmsub231sd, new IntrinsicInfo(X86Instruction.Vfmsub231sd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfmsub231ss, new IntrinsicInfo(X86Instruction.Vfmsub231ss, IntrinsicType.Fma));
ARMeilleure: Respect FZ/RM flags for all floating point operations (#4618) * ARMeilleure: Respect Fz flag for all floating point operations. This is a change in strategy for emulating the Fz FPCR flag. Before, it was set before instructions that "needed it" and reset after. However, this missed a few hot instructions like the multiplication instruction, and the entirety of A32. The new strategy is to set the Fz flag only in the following circumstances: - Set to match FPCR before translated functions/loop are executed. - Reset when calling SoftFloat methods, set when returning. - Reset when exiting execution. This allows us to remove the code around the existing Fz aware instructions, and get the accuracy benefits on all floating point instructions executed while in translated code. Single step executions now need to be called with a context wrapper - right now it just contains the Fz flag initialization, and won't actually do anything on ARM. This fixes a bug in Breath of the Wild where some physics interactions could randomly crash the game due to subnormal values not flushing to zero. This is draft right now because I need to answer the questions: - Does dotnet avoid changing the value of Mxcsr? - Is it a good idea to assume that? Or should the flag set/restore be done on every managed method call, not just softfloat? - If we assume that, do we want a unit test to verify the behaviour? I recommend testing a bunch of games, especially games affected when this was originally added, such as #1611. * Remove unused method * Use FMA for Fmadd, Fmsub, Fnmadd, Fnmsub, Fmla, Fmls ...when available. Similar implementation to A32 * Use FMA for Frecps, Frsqrts * Don't set DAZ. * Add round mode to ARM FP mode * Fix mistakes * Add test for FP state when calling managed methods * Add explanatory comment to test. * Cleanup * Add A64 FPCR flags * Vrintx_S A32 fast path on A64 backend * Address feedback 1, re-enable DAZ * Fix FMA instructions By Elem * Address feedback
2023-04-10 11:22:58 +01:00
Add(Intrinsic.X86Vfnmadd231pd, new IntrinsicInfo(X86Instruction.Vfnmadd231pd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfnmadd231ps, new IntrinsicInfo(X86Instruction.Vfnmadd231ps, IntrinsicType.Fma));
Add(Intrinsic.X86Vfnmadd231sd, new IntrinsicInfo(X86Instruction.Vfnmadd231sd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfnmadd231ss, new IntrinsicInfo(X86Instruction.Vfnmadd231ss, IntrinsicType.Fma));
Add(Intrinsic.X86Vfnmsub231sd, new IntrinsicInfo(X86Instruction.Vfnmsub231sd, IntrinsicType.Fma));
Add(Intrinsic.X86Vfnmsub231ss, new IntrinsicInfo(X86Instruction.Vfnmsub231ss, IntrinsicType.Fma));
ARMeilleure: Add initial support for AVX512 (EVEX encoding) (cont) (#4147) * ARMeilleure: Add AVX512{F,VL,DQ,BW} detection Add `UseAvx512Ortho` and `UseAvx512OrthoFloat` optimization flags as short-hands for `F+VL` and `F+VL+DQ`. * ARMeilleure: Add initial support for EVEX instruction encoding Does not implement rounding, or exception controls. * ARMeilleure: Add `X86Vpternlogd` Accelerates the vector-`Not` instruction. * ARMeilleure: Add check for `OSXSAVE` for AVX{2,512} * ARMeilleure: Add check for `XCR0` flags Add XCR0 register checks for AVX and AVX512F, following the guidelines from section 14.3 and 15.2 from the Intel Architecture Software Developer's Manual. * ARMeilleure: Remove redundant `ReProtect` and `Dispose`, formatting * ARMeilleure: Move XCR0 procedure to GetXcr0Eax * ARMeilleure: Add `XCR0` to `FeatureInfo` structure * ARMeilleure: Utilize `ReadOnlySpan` for Xcr0 assembly Avoids an additional allocation * ARMeilleure: Formatting fixes * ARMeilleure: Fix EVEX encoding src2 register index > Just like in VEX prefix, vvvv is provided in inverted form. * ARMeilleure: Add `X86Vpternlogd` acceleration to `Vmvn_I` Passes unit tests, verified instruction utilization * ARMeilleure: Fix EVEX register operand designations Operand 2 was being sourced improperly. EVEX encoded instructions source their operands like so: Operand 1: ModRM:reg Operand 2: EVEX.vvvvv Operand 3: ModRM:r/m Operand 4: Imm This fixes the improper register designations when emitting vpternlog. Now "dest", "src1", "src2" arguments emit in the proper order in EVEX instructions. * ARMeilleure: Add `X86Vpternlogd` acceleration to `Orn_V` * ARMeilleure: PTC version bump * ARMeilleure: Update EVEX encoding Debug.Assert to Debug.Fail * ARMeilleure: Update EVEX encoding comment capitalization
2023-03-20 19:09:24 +00:00
Add(Intrinsic.X86Vpternlogd, new IntrinsicInfo(X86Instruction.Vpternlogd, IntrinsicType.TernaryImm));
Add(Intrinsic.X86Xorpd, new IntrinsicInfo(X86Instruction.Xorpd, IntrinsicType.Binary));
Add(Intrinsic.X86Xorps, new IntrinsicInfo(X86Instruction.Xorps, IntrinsicType.Binary));
Add a new JIT compiler for CPU code (#693) * Start of the ARMeilleure project * Refactoring around the old IRAdapter, now renamed to PreAllocator * Optimize the LowestBitSet method * Add CLZ support and fix CLS implementation * Add missing Equals and GetHashCode overrides on some structs, misc small tweaks * Implement the ByteSwap IR instruction, and some refactoring on the assembler * Implement the DivideUI IR instruction and fix 64-bits IDIV * Correct constant operand type on CSINC * Move division instructions implementation to InstEmitDiv * Fix destination type for the ConditionalSelect IR instruction * Implement UMULH and SMULH, with new IR instructions * Fix some issues with shift instructions * Fix constant types for BFM instructions * Fix up new tests using the new V128 struct * Update tests * Move DIV tests to a separate file * Add support for calls, and some instructions that depends on them * Start adding support for SIMD & FP types, along with some of the related ARM instructions * Fix some typos and the divide instruction with FP operands * Fix wrong method call on Clz_V * Implement ARM FP & SIMD move instructions, Saddlv_V, and misc. fixes * Implement SIMD logical instructions and more misc. fixes * Fix PSRAD x86 instruction encoding, TRN, UABD and UABDL implementations * Implement float conversion instruction, merge in LDj3SNuD fixes, and some other misc. fixes * Implement SIMD shift instruction and fix Dup_V * Add SCVTF and UCVTF (vector, fixed-point) variants to the opcode table * Fix check with tolerance on tester * Implement FP & SIMD comparison instructions, and some fixes * Update FCVT (Scalar) encoding on the table to support the Half-float variants * Support passing V128 structs, some cleanup on the register allocator, merge LDj3SNuD fixes * Use old memory access methods, made a start on SIMD memory insts support, some fixes * Fix float constant passed to functions, save and restore non-volatile XMM registers, other fixes * Fix arguments count with struct return values, other fixes * More instructions * Misc. fixes and integrate LDj3SNuD fixes * Update tests * Add a faster linear scan allocator, unwinding support on windows, and other changes * Update Ryujinx.HLE * Update Ryujinx.Graphics * Fix V128 return pointer passing, RCX is clobbered * Update Ryujinx.Tests * Update ITimeZoneService * Stop using GetFunctionPointer as that can't be called from native code, misc. fixes and tweaks * Use generic GetFunctionPointerForDelegate method and other tweaks * Some refactoring on the code generator, assert on invalid operations and use a separate enum for intrinsics * Remove some unused code on the assembler * Fix REX.W prefix regression on float conversion instructions, add some sort of profiler * Add hardware capability detection * Fix regression on Sha1h and revert Fcm** changes * Add SSE2-only paths on vector extract and insert, some refactoring on the pre-allocator * Fix silly mistake introduced on last commit on CpuId * Generate inline stack probes when the stack allocation is too large * Initial support for the System-V ABI * Support multiple destination operands * Fix SSE2 VectorInsert8 path, and other fixes * Change placement of XMM callee save and restore code to match other compilers * Rename Dest to Destination and Inst to Instruction * Fix a regression related to calls and the V128 type * Add an extra space on comments to match code style * Some refactoring * Fix vector insert FP32 SSE2 path * Port over the ARM32 instructions * Avoid memory protection races on JIT Cache * Another fix on VectorInsert FP32 (thanks to LDj3SNuD * Float operands don't need to use the same register when VEX is supported * Add a new register allocator, higher quality code for hot code (tier up), and other tweaks * Some nits, small improvements on the pre allocator * CpuThreadState is gone * Allow changing CPU emulators with a config entry * Add runtime identifiers on the ARMeilleure project * Allow switching between CPUs through a config entry (pt. 2) * Change win10-x64 to win-x64 on projects * Update the Ryujinx project to use ARMeilleure * Ensure that the selected register is valid on the hybrid allocator * Allow exiting on returns to 0 (should fix test regression) * Remove register assignments for most used variables on the hybrid allocator * Do not use fixed registers as spill temp * Add missing namespace and remove unneeded using * Address PR feedback * Fix types, etc * Enable AssumeStrictAbiCompliance by default * Ensure that Spill and Fill don't load or store any more than necessary
2019-08-08 19:56:22 +01:00
}
private static void Add(Intrinsic intrin, IntrinsicInfo info)
{
_intrinTable[(int)intrin] = info;
}
public static IntrinsicInfo GetInfo(Intrinsic intrin)
{
return _intrinTable[(int)intrin];
}
}
}