RyuKen/ARMeilleure/Instructions/InstEmitSimdLogical32.cs
riperiperi dd433c1296
Implement AESMC, AESIMC, AESE, AESD and VEOR AArch32 instructions (#982)
* Add VEOR and AES instructions.

* Add tests for crypto instructions.

* Update ValueSource name.
2020-03-14 10:29:58 +11:00

146 lines
4.7 KiB
C#

using ARMeilleure.Decoders;
using ARMeilleure.IntermediateRepresentation;
using ARMeilleure.Translation;
using static ARMeilleure.Instructions.InstEmitHelper;
using static ARMeilleure.Instructions.InstEmitSimdHelper;
using static ARMeilleure.Instructions.InstEmitSimdHelper32;
using static ARMeilleure.IntermediateRepresentation.OperandHelper;
namespace ARMeilleure.Instructions
{
static partial class InstEmit32
{
public static void Vand_I(ArmEmitterContext context)
{
if (Optimizations.UseSse2)
{
EmitVectorBinaryOpF32(context, Intrinsic.X86Pand, Intrinsic.X86Pand);
}
else
{
EmitVectorBinaryOpZx32(context, (op1, op2) => context.BitwiseAnd(op1, op2));
}
}
public static void Vbif(ArmEmitterContext context)
{
EmitBifBit(context, true);
}
public static void Vbit(ArmEmitterContext context)
{
EmitBifBit(context, false);
}
public static void Vbsl(ArmEmitterContext context)
{
if (Optimizations.UseSse2)
{
EmitVectorTernaryOpSimd32(context, (d, n, m) =>
{
Operand res = context.AddIntrinsic(Intrinsic.X86Pxor, n, m);
res = context.AddIntrinsic(Intrinsic.X86Pand, res, d);
return context.AddIntrinsic(Intrinsic.X86Pxor, res, m);
});
}
else
{
EmitVectorTernaryOpZx32(context, (op1, op2, op3) =>
{
return context.BitwiseExclusiveOr(
context.BitwiseAnd(op1,
context.BitwiseExclusiveOr(op2, op3)), op3);
});
}
}
public static void Veor_I(ArmEmitterContext context)
{
if (Optimizations.UseSse2)
{
EmitVectorBinaryOpF32(context, Intrinsic.X86Pxor, Intrinsic.X86Pxor);
}
else
{
EmitVectorBinaryOpZx32(context, (op1, op2) => context.BitwiseExclusiveOr(op1, op2));
}
}
public static void Vorr_I(ArmEmitterContext context)
{
if (Optimizations.UseSse2)
{
EmitVectorBinaryOpF32(context, Intrinsic.X86Por, Intrinsic.X86Por);
}
else
{
EmitVectorBinaryOpZx32(context, (op1, op2) => context.BitwiseOr(op1, op2));
}
}
public static void Vorr_II(ArmEmitterContext context)
{
OpCode32SimdImm op = (OpCode32SimdImm)context.CurrOp;
long immediate = op.Immediate;
// Replicate fields to fill the 64-bits, if size is < 64-bits.
switch (op.Size)
{
case 0: immediate *= 0x0101010101010101L; break;
case 1: immediate *= 0x0001000100010001L; break;
case 2: immediate *= 0x0000000100000001L; break;
}
Operand imm = Const(immediate);
Operand res = GetVecA32(op.Qd);
if (op.Q)
{
for (int elem = 0; elem < 2; elem++)
{
Operand de = EmitVectorExtractZx(context, op.Qd, elem, 3);
res = EmitVectorInsert(context, res, context.BitwiseOr(de, imm), elem, 3);
}
}
else
{
Operand de = EmitVectorExtractZx(context, op.Qd, op.Vd & 1, 3);
res = EmitVectorInsert(context, res, context.BitwiseOr(de, imm), op.Vd & 1, 3);
}
context.Copy(GetVecA32(op.Qd), res);
}
private static void EmitBifBit(ArmEmitterContext context, bool notRm)
{
OpCode32SimdReg op = (OpCode32SimdReg)context.CurrOp;
if (Optimizations.UseSse2)
{
EmitVectorTernaryOpSimd32(context, (d, n, m) =>
{
Operand res = context.AddIntrinsic(Intrinsic.X86Pxor, n, d);
res = context.AddIntrinsic((notRm) ? Intrinsic.X86Pandn : Intrinsic.X86Pand, m, res);
return context.AddIntrinsic(Intrinsic.X86Pxor, d, res);
});
}
else
{
EmitVectorTernaryOpZx32(context, (d, n, m) =>
{
if (notRm)
{
m = context.BitwiseNot(m);
}
return context.BitwiseExclusiveOr(
context.BitwiseAnd(m,
context.BitwiseExclusiveOr(d, n)), d);
});
}
}
}
}