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Ryujinx/ARMeilleure/CodeGen/X86/PreAllocator.cs
riperiperi 9db73f74cf
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 12:22:58 +02:00

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using ARMeilleure.CodeGen.RegisterAllocators;
using ARMeilleure.IntermediateRepresentation;
using ARMeilleure.Translation;
using System;
using System.Diagnostics;
using static ARMeilleure.IntermediateRepresentation.Operand.Factory;
using static ARMeilleure.IntermediateRepresentation.Operation.Factory;
namespace ARMeilleure.CodeGen.X86
{
class PreAllocator
{
public static void RunPass(CompilerContext cctx, StackAllocator stackAlloc, out int maxCallArgs)
{
maxCallArgs = -1;
Span<Operation> buffer = default;
CallConvName callConv = CallingConvention.GetCurrentCallConv();
Operand[] preservedArgs = new Operand[CallingConvention.GetArgumentsOnRegsCount()];
for (BasicBlock block = cctx.Cfg.Blocks.First; block != null; block = block.ListNext)
{
Operation nextNode;
for (Operation node = block.Operations.First; node != default; node = nextNode)
{
nextNode = node.ListNext;
if (node.Instruction == Instruction.Phi)
{
continue;
}
InsertConstantRegCopies(block.Operations, node);
InsertDestructiveRegCopies(block.Operations, node);
InsertConstrainedRegCopies(block.Operations, node);
switch (node.Instruction)
{
case Instruction.Call:
// Get the maximum number of arguments used on a call.
// On windows, when a struct is returned from the call,
// we also need to pass the pointer where the struct
// should be written on the first argument.
int argsCount = node.SourcesCount - 1;
if (node.Destination != default && node.Destination.Type == OperandType.V128)
{
argsCount++;
}
if (maxCallArgs < argsCount)
{
maxCallArgs = argsCount;
}
// Copy values to registers expected by the function
// being called, as mandated by the ABI.
if (callConv == CallConvName.Windows)
{
PreAllocatorWindows.InsertCallCopies(block.Operations, stackAlloc, node);
}
else /* if (callConv == CallConvName.SystemV) */
{
PreAllocatorSystemV.InsertCallCopies(block.Operations, node);
}
break;
case Instruction.ConvertToFPUI:
GenerateConvertToFPUI(block.Operations, node);
break;
case Instruction.LoadArgument:
if (callConv == CallConvName.Windows)
{
nextNode = PreAllocatorWindows.InsertLoadArgumentCopy(cctx, ref buffer, block.Operations, preservedArgs, node);
}
else /* if (callConv == CallConvName.SystemV) */
{
nextNode = PreAllocatorSystemV.InsertLoadArgumentCopy(cctx, ref buffer, block.Operations, preservedArgs, node);
}
break;
case Instruction.Negate:
if (!node.GetSource(0).Type.IsInteger())
{
GenerateNegate(block.Operations, node);
}
break;
case Instruction.Return:
if (callConv == CallConvName.Windows)
{
PreAllocatorWindows.InsertReturnCopy(cctx, block.Operations, preservedArgs, node);
}
else /* if (callConv == CallConvName.SystemV) */
{
PreAllocatorSystemV.InsertReturnCopy(block.Operations, node);
}
break;
case Instruction.Tailcall:
if (callConv == CallConvName.Windows)
{
PreAllocatorWindows.InsertTailcallCopies(block.Operations, stackAlloc, node);
}
else
{
PreAllocatorSystemV.InsertTailcallCopies(block.Operations, stackAlloc, node);
}
break;
case Instruction.VectorInsert8:
if (!HardwareCapabilities.SupportsSse41)
{
GenerateVectorInsert8(block.Operations, node);
}
break;
case Instruction.Extended:
if (node.Intrinsic == Intrinsic.X86Ldmxcsr)
{
int stackOffset = stackAlloc.Allocate(OperandType.I32);
node.SetSources(new Operand[] { Const(stackOffset), node.GetSource(0) });
}
else if (node.Intrinsic == Intrinsic.X86Stmxcsr)
{
int stackOffset = stackAlloc.Allocate(OperandType.I32);
node.SetSources(new Operand[] { Const(stackOffset) });
}
break;
}
}
}
}
protected static void InsertConstantRegCopies(IntrusiveList<Operation> nodes, Operation node)
{
if (node.SourcesCount == 0 || IsXmmIntrinsic(node))
{
return;
}
Instruction inst = node.Instruction;
Operand src1 = node.GetSource(0);
Operand src2;
if (src1.Kind == OperandKind.Constant)
{
if (!src1.Type.IsInteger())
{
// Handle non-integer types (FP32, FP64 and V128).
// For instructions without an immediate operand, we do the following:
// - Insert a copy with the constant value (as integer) to a GPR.
// - Insert a copy from the GPR to a XMM register.
// - Replace the constant use with the XMM register.
src1 = AddXmmCopy(nodes, node, src1);
node.SetSource(0, src1);
}
else if (!HasConstSrc1(inst))
{
// Handle integer types.
// Most ALU instructions accepts a 32-bits immediate on the second operand.
// We need to ensure the following:
// - If the constant is on operand 1, we need to move it.
// -- But first, we try to swap operand 1 and 2 if the instruction is commutative.
// -- Doing so may allow us to encode the constant as operand 2 and avoid a copy.
// - If the constant is on operand 2, we check if the instruction supports it,
// if not, we also add a copy. 64-bits constants are usually not supported.
if (IsCommutative(node))
{
src2 = node.GetSource(1);
Operand temp = src1;
src1 = src2;
src2 = temp;
node.SetSource(0, src1);
node.SetSource(1, src2);
}
if (src1.Kind == OperandKind.Constant)
{
src1 = AddCopy(nodes, node, src1);
node.SetSource(0, src1);
}
}
}
if (node.SourcesCount < 2)
{
return;
}
src2 = node.GetSource(1);
if (src2.Kind == OperandKind.Constant)
{
if (!src2.Type.IsInteger())
{
src2 = AddXmmCopy(nodes, node, src2);
node.SetSource(1, src2);
}
else if (!HasConstSrc2(inst) || CodeGenCommon.IsLongConst(src2))
{
src2 = AddCopy(nodes, node, src2);
node.SetSource(1, src2);
}
}
}
protected static void InsertConstrainedRegCopies(IntrusiveList<Operation> nodes, Operation node)
{
Operand dest = node.Destination;
switch (node.Instruction)
{
case Instruction.CompareAndSwap:
case Instruction.CompareAndSwap16:
case Instruction.CompareAndSwap8:
{
OperandType type = node.GetSource(1).Type;
if (type == OperandType.V128)
{
// Handle the many restrictions of the compare and exchange (16 bytes) instruction:
// - The expected value should be in RDX:RAX.
// - The new value to be written should be in RCX:RBX.
// - The value at the memory location is loaded to RDX:RAX.
void SplitOperand(Operand source, Operand lr, Operand hr)
{
nodes.AddBefore(node, Operation(Instruction.VectorExtract, lr, source, Const(0)));
nodes.AddBefore(node, Operation(Instruction.VectorExtract, hr, source, Const(1)));
}
Operand rax = Gpr(X86Register.Rax, OperandType.I64);
Operand rbx = Gpr(X86Register.Rbx, OperandType.I64);
Operand rcx = Gpr(X86Register.Rcx, OperandType.I64);
Operand rdx = Gpr(X86Register.Rdx, OperandType.I64);
SplitOperand(node.GetSource(1), rax, rdx);
SplitOperand(node.GetSource(2), rbx, rcx);
Operation operation = node;
node = nodes.AddAfter(node, Operation(Instruction.VectorCreateScalar, dest, rax));
nodes.AddAfter(node, Operation(Instruction.VectorInsert, dest, dest, rdx, Const(1)));
operation.SetDestinations(new Operand[] { rdx, rax });
operation.SetSources(new Operand[] { operation.GetSource(0), rdx, rax, rcx, rbx });
}
else
{
// Handle the many restrictions of the compare and exchange (32/64) instruction:
// - The expected value should be in (E/R)AX.
// - The value at the memory location is loaded to (E/R)AX.
Operand expected = node.GetSource(1);
Operand newValue = node.GetSource(2);
Operand rax = Gpr(X86Register.Rax, expected.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, rax, expected));
// We need to store the new value into a temp, since it may
// be a constant, and this instruction does not support immediate operands.
Operand temp = Local(newValue.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, temp, newValue));
node.SetSources(new Operand[] { node.GetSource(0), rax, temp });
nodes.AddAfter(node, Operation(Instruction.Copy, dest, rax));
node.Destination = rax;
}
break;
}
case Instruction.Divide:
case Instruction.DivideUI:
{
// Handle the many restrictions of the division instructions:
// - The dividend is always in RDX:RAX.
// - The result is always in RAX.
// - Additionally it also writes the remainder in RDX.
if (dest.Type.IsInteger())
{
Operand src1 = node.GetSource(0);
Operand rax = Gpr(X86Register.Rax, src1.Type);
Operand rdx = Gpr(X86Register.Rdx, src1.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, rax, src1));
nodes.AddBefore(node, Operation(Instruction.Clobber, rdx));
nodes.AddAfter(node, Operation(Instruction.Copy, dest, rax));
node.SetSources(new Operand[] { rdx, rax, node.GetSource(1) });
node.Destination = rax;
}
break;
}
case Instruction.Extended:
{
bool isBlend = node.Intrinsic == Intrinsic.X86Blendvpd ||
node.Intrinsic == Intrinsic.X86Blendvps ||
node.Intrinsic == Intrinsic.X86Pblendvb;
// BLENDVPD, BLENDVPS, PBLENDVB last operand is always implied to be XMM0 when VEX is not supported.
// SHA256RNDS2 always has an implied XMM0 as a last operand.
if ((isBlend && !HardwareCapabilities.SupportsVexEncoding) || node.Intrinsic == Intrinsic.X86Sha256Rnds2)
{
Operand xmm0 = Xmm(X86Register.Xmm0, OperandType.V128);
nodes.AddBefore(node, Operation(Instruction.Copy, xmm0, node.GetSource(2)));
node.SetSource(2, xmm0);
}
break;
}
case Instruction.Multiply64HighSI:
case Instruction.Multiply64HighUI:
{
// Handle the many restrictions of the i64 * i64 = i128 multiply instructions:
// - The multiplicand is always in RAX.
// - The lower 64-bits of the result is always in RAX.
// - The higher 64-bits of the result is always in RDX.
Operand src1 = node.GetSource(0);
Operand rax = Gpr(X86Register.Rax, src1.Type);
Operand rdx = Gpr(X86Register.Rdx, src1.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, rax, src1));
node.SetSource(0, rax);
nodes.AddAfter(node, Operation(Instruction.Copy, dest, rdx));
node.SetDestinations(new Operand[] { rdx, rax });
break;
}
case Instruction.RotateRight:
case Instruction.ShiftLeft:
case Instruction.ShiftRightSI:
case Instruction.ShiftRightUI:
{
// The shift register is always implied to be CL (low 8-bits of RCX or ECX).
if (node.GetSource(1).Kind == OperandKind.LocalVariable)
{
Operand rcx = Gpr(X86Register.Rcx, OperandType.I32);
nodes.AddBefore(node, Operation(Instruction.Copy, rcx, node.GetSource(1)));
node.SetSource(1, rcx);
}
break;
}
}
}
protected static void InsertDestructiveRegCopies(IntrusiveList<Operation> nodes, Operation node)
{
if (node.Destination == default || node.SourcesCount == 0)
{
return;
}
Instruction inst = node.Instruction;
Operand dest = node.Destination;
Operand src1 = node.GetSource(0);
// The multiply instruction (that maps to IMUL) is somewhat special, it has
// a three operand form where the second source is a immediate value.
bool threeOperandForm = inst == Instruction.Multiply && node.GetSource(1).Kind == OperandKind.Constant;
if (IsSameOperandDestSrc1(node) && src1.Kind == OperandKind.LocalVariable && !threeOperandForm)
{
bool useNewLocal = false;
for (int srcIndex = 1; srcIndex < node.SourcesCount; srcIndex++)
{
if (node.GetSource(srcIndex) == dest)
{
useNewLocal = true;
break;
}
}
if (useNewLocal)
{
// Dest is being used as some source already, we need to use a new
// local to store the temporary value, otherwise the value on dest
// local would be overwritten.
Operand temp = Local(dest.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, temp, src1));
node.SetSource(0, temp);
nodes.AddAfter(node, Operation(Instruction.Copy, dest, temp));
node.Destination = temp;
}
else
{
nodes.AddBefore(node, Operation(Instruction.Copy, dest, src1));
node.SetSource(0, dest);
}
}
else if (inst == Instruction.ConditionalSelect)
{
Operand src2 = node.GetSource(1);
Operand src3 = node.GetSource(2);
if (src1 == dest || src2 == dest)
{
Operand temp = Local(dest.Type);
nodes.AddBefore(node, Operation(Instruction.Copy, temp, src3));
node.SetSource(2, temp);
nodes.AddAfter(node, Operation(Instruction.Copy, dest, temp));
node.Destination = temp;
}
else
{
nodes.AddBefore(node, Operation(Instruction.Copy, dest, src3));
node.SetSource(2, dest);
}
}
}
private static void GenerateConvertToFPUI(IntrusiveList<Operation> nodes, Operation node)
{
// Unsigned integer to FP conversions are not supported on X86.
// We need to turn them into signed integer to FP conversions, and
// adjust the final result.
Operand dest = node.Destination;
Operand source = node.GetSource(0);
Debug.Assert(source.Type.IsInteger(), $"Invalid source type \"{source.Type}\".");
Operation currentNode = node;
if (source.Type == OperandType.I32)
{
// For 32-bits integers, we can just zero-extend to 64-bits,
// and then use the 64-bits signed conversion instructions.
Operand zex = Local(OperandType.I64);
node = nodes.AddAfter(node, Operation(Instruction.ZeroExtend32, zex, source));
node = nodes.AddAfter(node, Operation(Instruction.ConvertToFP, dest, zex));
}
else /* if (source.Type == OperandType.I64) */
{
// For 64-bits integers, we need to do the following:
// - Ensure that the integer has the most significant bit clear.
// -- This can be done by shifting the value right by 1, that is, dividing by 2.
// -- The least significant bit is lost in this case though.
// - We can then convert the shifted value with a signed integer instruction.
// - The result still needs to be corrected after that.
// -- First, we need to multiply the result by 2, as we divided it by 2 before.
// --- This can be done efficiently by adding the result to itself.
// -- Then, we need to add the least significant bit that was shifted out.
// --- We can convert the least significant bit to float, and add it to the result.
Operand lsb = Local(OperandType.I64);
Operand half = Local(OperandType.I64);
Operand lsbF = Local(dest.Type);
node = nodes.AddAfter(node, Operation(Instruction.Copy, lsb, source));
node = nodes.AddAfter(node, Operation(Instruction.Copy, half, source));
node = nodes.AddAfter(node, Operation(Instruction.BitwiseAnd, lsb, lsb, Const(1L)));
node = nodes.AddAfter(node, Operation(Instruction.ShiftRightUI, half, half, Const(1)));
node = nodes.AddAfter(node, Operation(Instruction.ConvertToFP, lsbF, lsb));
node = nodes.AddAfter(node, Operation(Instruction.ConvertToFP, dest, half));
node = nodes.AddAfter(node, Operation(Instruction.Add, dest, dest, dest));
nodes.AddAfter(node, Operation(Instruction.Add, dest, dest, lsbF));
}
Delete(nodes, currentNode);
}
private static void GenerateNegate(IntrusiveList<Operation> nodes, Operation node)
{
// There's no SSE FP negate instruction, so we need to transform that into
// a XOR of the value to be negated with a mask with the highest bit set.
// This also produces -0 for a negation of the value 0.
Operand dest = node.Destination;
Operand source = node.GetSource(0);
Debug.Assert(dest.Type == OperandType.FP32 ||
dest.Type == OperandType.FP64, $"Invalid destination type \"{dest.Type}\".");
Operation currentNode = node;
Operand res = Local(dest.Type);
node = nodes.AddAfter(node, Operation(Instruction.VectorOne, res));
if (dest.Type == OperandType.FP32)
{
node = nodes.AddAfter(node, Operation(Intrinsic.X86Pslld, res, res, Const(31)));
}
else /* if (dest.Type == OperandType.FP64) */
{
node = nodes.AddAfter(node, Operation(Intrinsic.X86Psllq, res, res, Const(63)));
}
node = nodes.AddAfter(node, Operation(Intrinsic.X86Xorps, res, res, source));
nodes.AddAfter(node, Operation(Instruction.Copy, dest, res));
Delete(nodes, currentNode);
}
private static void GenerateVectorInsert8(IntrusiveList<Operation> nodes, Operation node)
{
// Handle vector insertion, when SSE 4.1 is not supported.
Operand dest = node.Destination;
Operand src1 = node.GetSource(0); // Vector
Operand src2 = node.GetSource(1); // Value
Operand src3 = node.GetSource(2); // Index
Debug.Assert(src3.Kind == OperandKind.Constant);
byte index = src3.AsByte();
Debug.Assert(index < 16);
Operation currentNode = node;
Operand temp1 = Local(OperandType.I32);
Operand temp2 = Local(OperandType.I32);
node = nodes.AddAfter(node, Operation(Instruction.Copy, temp2, src2));
Operation vextOp = Operation(Instruction.VectorExtract16, temp1, src1, Const(index >> 1));
node = nodes.AddAfter(node, vextOp);
if ((index & 1) != 0)
{
node = nodes.AddAfter(node, Operation(Instruction.ZeroExtend8, temp1, temp1));
node = nodes.AddAfter(node, Operation(Instruction.ShiftLeft, temp2, temp2, Const(8)));
node = nodes.AddAfter(node, Operation(Instruction.BitwiseOr, temp1, temp1, temp2));
}
else
{
node = nodes.AddAfter(node, Operation(Instruction.ZeroExtend8, temp2, temp2));
node = nodes.AddAfter(node, Operation(Instruction.BitwiseAnd, temp1, temp1, Const(0xff00)));
node = nodes.AddAfter(node, Operation(Instruction.BitwiseOr, temp1, temp1, temp2));
}
Operation vinsOp = Operation(Instruction.VectorInsert16, dest, src1, temp1, Const(index >> 1));
nodes.AddAfter(node, vinsOp);
Delete(nodes, currentNode);
}
protected static Operand AddXmmCopy(IntrusiveList<Operation> nodes, Operation node, Operand source)
{
Operand temp = Local(source.Type);
Operand intConst = AddCopy(nodes, node, GetIntConst(source));
Operation copyOp = Operation(Instruction.VectorCreateScalar, temp, intConst);
nodes.AddBefore(node, copyOp);
return temp;
}
protected static Operand AddCopy(IntrusiveList<Operation> nodes, Operation node, Operand source)
{
Operand temp = Local(source.Type);
Operation copyOp = Operation(Instruction.Copy, temp, source);
nodes.AddBefore(node, copyOp);
return temp;
}
private static Operand GetIntConst(Operand value)
{
if (value.Type == OperandType.FP32)
{
return Const(value.AsInt32());
}
else if (value.Type == OperandType.FP64)
{
return Const(value.AsInt64());
}
return value;
}
protected static void Delete(IntrusiveList<Operation> nodes, Operation node)
{
node.Destination = default;
for (int index = 0; index < node.SourcesCount; index++)
{
node.SetSource(index, default);
}
nodes.Remove(node);
}
protected static Operand Gpr(X86Register register, OperandType type)
{
return Register((int)register, RegisterType.Integer, type);
}
protected static Operand Xmm(X86Register register, OperandType type)
{
return Register((int)register, RegisterType.Vector, type);
}
private static bool IsSameOperandDestSrc1(Operation operation)
{
switch (operation.Instruction)
{
case Instruction.Add:
return !HardwareCapabilities.SupportsVexEncoding && !operation.Destination.Type.IsInteger();
case Instruction.Multiply:
case Instruction.Subtract:
return !HardwareCapabilities.SupportsVexEncoding || operation.Destination.Type.IsInteger();
case Instruction.BitwiseAnd:
case Instruction.BitwiseExclusiveOr:
case Instruction.BitwiseNot:
case Instruction.BitwiseOr:
case Instruction.ByteSwap:
case Instruction.Negate:
case Instruction.RotateRight:
case Instruction.ShiftLeft:
case Instruction.ShiftRightSI:
case Instruction.ShiftRightUI:
return true;
case Instruction.Divide:
return !HardwareCapabilities.SupportsVexEncoding && !operation.Destination.Type.IsInteger();
case Instruction.VectorInsert:
case Instruction.VectorInsert16:
case Instruction.VectorInsert8:
return !HardwareCapabilities.SupportsVexEncoding;
case Instruction.Extended:
return IsIntrinsicSameOperandDestSrc1(operation);
}
return IsVexSameOperandDestSrc1(operation);
}
private static bool IsIntrinsicSameOperandDestSrc1(Operation operation)
{
IntrinsicInfo info = IntrinsicTable.GetInfo(operation.Intrinsic);
return info.Type == IntrinsicType.Crc32 || info.Type == IntrinsicType.Fma || IsVexSameOperandDestSrc1(operation);
}
private static bool IsVexSameOperandDestSrc1(Operation operation)
{
if (IsIntrinsic(operation.Instruction))
{
IntrinsicInfo info = IntrinsicTable.GetInfo(operation.Intrinsic);
bool hasVex = HardwareCapabilities.SupportsVexEncoding && Assembler.SupportsVexPrefix(info.Inst);
bool isUnary = operation.SourcesCount < 2;
bool hasVecDest = operation.Destination != default && operation.Destination.Type == OperandType.V128;
return !hasVex && !isUnary && hasVecDest;
}
return false;
}
private static bool HasConstSrc1(Instruction inst)
{
switch (inst)
{
case Instruction.Copy:
case Instruction.LoadArgument:
case Instruction.Spill:
case Instruction.SpillArg:
return true;
}
return false;
}
private static bool HasConstSrc2(Instruction inst)
{
switch (inst)
{
case Instruction.Add:
case Instruction.BitwiseAnd:
case Instruction.BitwiseExclusiveOr:
case Instruction.BitwiseOr:
case Instruction.BranchIf:
case Instruction.Compare:
case Instruction.Multiply:
case Instruction.RotateRight:
case Instruction.ShiftLeft:
case Instruction.ShiftRightSI:
case Instruction.ShiftRightUI:
case Instruction.Store:
case Instruction.Store16:
case Instruction.Store8:
case Instruction.Subtract:
case Instruction.VectorExtract:
case Instruction.VectorExtract16:
case Instruction.VectorExtract8:
return true;
}
return false;
}
private static bool IsCommutative(Operation operation)
{
switch (operation.Instruction)
{
case Instruction.Add:
case Instruction.BitwiseAnd:
case Instruction.BitwiseExclusiveOr:
case Instruction.BitwiseOr:
case Instruction.Multiply:
return true;
case Instruction.BranchIf:
case Instruction.Compare:
{
Operand comp = operation.GetSource(2);
Debug.Assert(comp.Kind == OperandKind.Constant);
var compType = (Comparison)comp.AsInt32();
return compType == Comparison.Equal || compType == Comparison.NotEqual;
}
}
return false;
}
private static bool IsIntrinsic(Instruction inst)
{
return inst == Instruction.Extended;
}
private static bool IsXmmIntrinsic(Operation operation)
{
if (operation.Instruction != Instruction.Extended)
{
return false;
}
IntrinsicInfo info = IntrinsicTable.GetInfo(operation.Intrinsic);
return info.Type != IntrinsicType.Crc32;
}
}
}
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