2023-01-10 17:16:59 -05:00
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using ARMeilleure.IntermediateRepresentation;
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using System.Numerics;
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namespace ARMeilleure.CodeGen.Arm64
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{
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static class CodeGenCommon
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{
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public const int TcAddressRegister = 8;
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public const int ReservedRegister = 17;
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public static bool ConstFitsOnSImm7(int value, int scale)
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{
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return (((value >> scale) << 25) >> (25 - scale)) == value;
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}
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public static bool ConstFitsOnSImm9(int value)
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{
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return ((value << 23) >> 23) == value;
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}
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public static bool ConstFitsOnUImm12(int value)
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{
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return (value & 0xfff) == value;
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}
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public static bool ConstFitsOnUImm12(int value, OperandType type)
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{
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int scale = Assembler.GetScaleForType(type);
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return (((value >> scale) & 0xfff) << scale) == value;
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}
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public static bool TryEncodeBitMask(Operand operand, out int immN, out int immS, out int immR)
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{
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2023-01-22 09:15:49 -05:00
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return TryEncodeBitMask(operand.Type, operand.Value, out immN, out immS, out immR);
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}
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2023-01-10 17:16:59 -05:00
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2023-01-22 09:15:49 -05:00
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public static bool TryEncodeBitMask(OperandType type, ulong value, out int immN, out int immS, out int immR)
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{
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if (type == OperandType.I32)
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2023-01-10 17:16:59 -05:00
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{
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value |= value << 32;
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}
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return TryEncodeBitMask(value, out immN, out immS, out immR);
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}
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public static bool TryEncodeBitMask(ulong value, out int immN, out int immS, out int immR)
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{
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// Some special values also can't be encoded:
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// 0 can't be encoded because we need to subtract 1 from onesCount (which would became negative if 0).
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// A value with all bits set can't be encoded because it is reserved according to the spec, because:
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// Any value AND all ones will be equal itself, so it's effectively a no-op.
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// Any value OR all ones will be equal all ones, so one can just use MOV.
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// Any value XOR all ones will be equal its inverse, so one can just use MVN.
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if (value == 0 || value == ulong.MaxValue)
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2023-01-10 17:16:59 -05:00
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{
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immN = 0;
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immS = 0;
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immR = 0;
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return false;
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}
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2023-01-22 09:15:49 -05:00
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// Normalize value, rotating it such that the LSB is 1: Ensures we get a complete element that has not
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// been cut-in-half across the word boundary.
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int rotation = BitOperations.TrailingZeroCount(value & (value + 1));
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ulong rotatedValue = ulong.RotateRight(value, rotation);
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2023-01-22 09:15:49 -05:00
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// Now that we have a complete element in the LSB with the LSB = 1, determine size and number of ones
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// in element.
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int elementSize = BitOperations.TrailingZeroCount(rotatedValue & (rotatedValue + 1));
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int onesInElement = BitOperations.TrailingZeroCount(~rotatedValue);
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2023-01-22 09:15:49 -05:00
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// Check the value is repeating; also ensures element size is a power of two.
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if (ulong.RotateRight(value, elementSize) != value)
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{
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immN = 0;
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immS = 0;
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immR = 0;
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return false;
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}
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2023-01-22 09:15:49 -05:00
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immN = (elementSize >> 6) & 1;
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immS = (((~elementSize + 1) << 1) | (onesInElement - 1)) & 0x3f;
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immR = (elementSize - rotation) & (elementSize - 1);
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2023-01-10 17:16:59 -05:00
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return true;
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}
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}
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}
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