lib/Runtime/Language/SimdInt32x4Operation.cpp - external/github.com/Microsoft/ChakraCore - Git at Google

 //-------------------------------------------------------------------------------------------------------
 // Copyright (C) Microsoft Corporation and contributors. All rights reserved.
 // Licensed under the MIT license. See LICENSE.txt file in the project root for full license information.
 //-------------------------------------------------------------------------------------------------------

 #include "RuntimeLanguagePch.h"

 #if defined(_M_ARM32_OR_ARM64)

 namespace Js
 {
     SIMDValue SIMDInt32x4Operation::OpInt32x4(int x, int y, int z, int w)
     {
         SIMDValue result;

         result.i32[SIMD_X] = x;
         result.i32[SIMD_Y] = y;
         result.i32[SIMD_Z] = z;
         result.i32[SIMD_W] = w;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpSplat(int x)
     {
         SIMDValue result;

         result.i32[SIMD_X] = result.i32[SIMD_Y] = result.i32[SIMD_Z] = result.i32[SIMD_W] = x;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpBool(int x, int y, int z, int w)
     {
         SIMDValue result;

         int nX = x ? -1 : 0x0;
         int nY = y ? -1 : 0x0;
         int nZ = z ? -1 : 0x0;
         int nW = w ? -1 : 0x0;

         result.i32[SIMD_X] = nX;
         result.i32[SIMD_Y] = nY;
         result.i32[SIMD_Z] = nZ;
         result.i32[SIMD_W] = nW;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpBool(const SIMDValue& v)
     {
         SIMDValue result;

         // incoming 4 signed integers has to be 0 or -1
         Assert(v.i32[SIMD_X] == 0 || v.i32[SIMD_X] == -1);
         Assert(v.i32[SIMD_Y] == 0 || v.i32[SIMD_Y] == -1);
         Assert(v.i32[SIMD_Z] == 0 || v.i32[SIMD_Z] == -1);
         Assert(v.i32[SIMD_W] == 0 || v.i32[SIMD_W] == -1);
         result = v;
         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpFromFloat32x4(const SIMDValue& v, bool &throws)
     {
         SIMDValue result = { 0 };
         const int MIN_INT = 0x80000000, MAX_INT = 0x7FFFFFFF;

         for (uint i = 0; i < 4; i++)
         {
             if (v.f32[i] >= MIN_INT && v.f32[i] <= MAX_INT)
             {
                 result.u32[i] = (int)(v.f32[i]);
             }
             else
             {
                 // out of range. Caller should throw.
                 throws = true;
                 return result;
             }
         }
         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpFromFloat64x2(const SIMDValue& v)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (int)(v.f64[SIMD_X]);
         result.i32[SIMD_Y] = (int)(v.f64[SIMD_Y]);
         result.i32[SIMD_Z] = result.i32[SIMD_W] = 0;

         return result;
     }


     // Unary Ops
     SIMDValue SIMDInt32x4Operation::OpAbs(const SIMDValue& value)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (value.i32[SIMD_X] < 0) ? -1 * value.i32[SIMD_X] : value.i32[SIMD_X];
         result.i32[SIMD_Y] = (value.i32[SIMD_Y] < 0) ? -1 * value.i32[SIMD_Y] : value.i32[SIMD_Y];
         result.i32[SIMD_Z] = (value.i32[SIMD_Z] < 0) ? -1 * value.i32[SIMD_Z] : value.i32[SIMD_Z];
         result.i32[SIMD_W] = (value.i32[SIMD_W] < 0) ? -1 * value.i32[SIMD_W] : value.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpNeg(const SIMDValue& value)
     {
         SIMDValue result;

         result.i32[SIMD_X] = -1 * value.i32[SIMD_X];
         result.i32[SIMD_Y] = -1 * value.i32[SIMD_Y];
         result.i32[SIMD_Z] = -1 * value.i32[SIMD_Z];
         result.i32[SIMD_W] = -1 * value.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpNot(const SIMDValue& value)
     {
         SIMDValue result;

         result.i32[SIMD_X] = ~(value.i32[SIMD_X]);
         result.i32[SIMD_Y] = ~(value.i32[SIMD_Y]);
         result.i32[SIMD_Z] = ~(value.i32[SIMD_Z]);
         result.i32[SIMD_W] = ~(value.i32[SIMD_W]);

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpAdd(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] + bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] + bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] + bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] + bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpSub(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] - bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] - bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] - bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] - bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpMul(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] * bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] * bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] * bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] * bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpAnd(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] & bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] & bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] & bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] & bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpOr(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] | bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] | bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] | bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] | bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpXor(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = aValue.i32[SIMD_X] ^ bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = aValue.i32[SIMD_Y] ^ bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = aValue.i32[SIMD_Z] ^ bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = aValue.i32[SIMD_W] ^ bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpMin(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] < bValue.i32[SIMD_X]) ? aValue.i32[SIMD_X] : bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] < bValue.i32[SIMD_Y]) ? aValue.i32[SIMD_Y] : bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] < bValue.i32[SIMD_Z]) ? aValue.i32[SIMD_Z] : bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] < bValue.i32[SIMD_W]) ? aValue.i32[SIMD_W] : bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpMax(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] > bValue.i32[SIMD_X]) ? aValue.i32[SIMD_X] : bValue.i32[SIMD_X];
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] > bValue.i32[SIMD_Y]) ? aValue.i32[SIMD_Y] : bValue.i32[SIMD_Y];
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] > bValue.i32[SIMD_Z]) ? aValue.i32[SIMD_Z] : bValue.i32[SIMD_Z];
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] > bValue.i32[SIMD_W]) ? aValue.i32[SIMD_W] : bValue.i32[SIMD_W];

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpLessThan(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] < bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] < bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] < bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] < bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpLessThanOrEqual(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] <= bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] <= bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] <= bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] <= bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpEqual(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] == bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] == bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] == bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] == bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpNotEqual(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] != bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] != bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] != bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] != bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpGreaterThan(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] > bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] > bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] > bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] > bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpGreaterThanOrEqual(const SIMDValue& aValue, const SIMDValue& bValue)
     {
         SIMDValue result;

         result.i32[SIMD_X] = (aValue.i32[SIMD_X] >= bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] >= bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
         result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] >= bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
         result.i32[SIMD_W] = (aValue.i32[SIMD_W] >= bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpShiftLeftByScalar(const SIMDValue& value, int count)
     {
         SIMDValue result;

         count = count & SIMDUtils::SIMDGetShiftAmountMask(4);

         result.i32[SIMD_X] = value.i32[SIMD_X] << count;
         result.i32[SIMD_Y] = value.i32[SIMD_Y] << count;
         result.i32[SIMD_Z] = value.i32[SIMD_Z] << count;
         result.i32[SIMD_W] = value.i32[SIMD_W] << count;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpShiftRightByScalar(const SIMDValue& value, int count)
     {
         SIMDValue result;

         count = count & SIMDUtils::SIMDGetShiftAmountMask(4);

         result.i32[SIMD_X] = value.i32[SIMD_X] >> count;
         result.i32[SIMD_Y] = value.i32[SIMD_Y] >> count;
         result.i32[SIMD_Z] = value.i32[SIMD_Z] >> count;
         result.i32[SIMD_W] = value.i32[SIMD_W] >> count;

         return result;
     }

     SIMDValue SIMDInt32x4Operation::OpSelect(const SIMDValue& mV, const SIMDValue& tV, const SIMDValue& fV)
     {
         SIMDValue result;

         SIMDValue trueResult  = SIMDInt32x4Operation::OpAnd(mV, tV);
         SIMDValue notValue    = SIMDInt32x4Operation::OpNot(mV);
         SIMDValue falseResult = SIMDInt32x4Operation::OpAnd(notValue, fV);

         result = SIMDInt32x4Operation::OpOr(trueResult, falseResult);

         return result;
     }
 }
 #endif
	//-------------------------------------------------------------------------------------------------------
	// Copyright (C) Microsoft Corporation and contributors. All rights reserved.
	// Licensed under the MIT license. See LICENSE.txt file in the project root for full license information.
	//-------------------------------------------------------------------------------------------------------

	#include "RuntimeLanguagePch.h"

	#if defined(_M_ARM32_OR_ARM64)

	namespace Js
	{
	SIMDValue SIMDInt32x4Operation::OpInt32x4(int x, int y, int z, int w)
	{
	SIMDValue result;

	result.i32[SIMD_X] = x;
	result.i32[SIMD_Y] = y;
	result.i32[SIMD_Z] = z;
	result.i32[SIMD_W] = w;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpSplat(int x)
	{
	SIMDValue result;

	result.i32[SIMD_X] = result.i32[SIMD_Y] = result.i32[SIMD_Z] = result.i32[SIMD_W] = x;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpBool(int x, int y, int z, int w)
	{
	SIMDValue result;

	int nX = x ? -1 : 0x0;
	int nY = y ? -1 : 0x0;
	int nZ = z ? -1 : 0x0;
	int nW = w ? -1 : 0x0;

	result.i32[SIMD_X] = nX;
	result.i32[SIMD_Y] = nY;
	result.i32[SIMD_Z] = nZ;
	result.i32[SIMD_W] = nW;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpBool(const SIMDValue& v)
	{
	SIMDValue result;

	// incoming 4 signed integers has to be 0 or -1
	Assert(v.i32[SIMD_X] == 0 \|\| v.i32[SIMD_X] == -1);
	Assert(v.i32[SIMD_Y] == 0 \|\| v.i32[SIMD_Y] == -1);
	Assert(v.i32[SIMD_Z] == 0 \|\| v.i32[SIMD_Z] == -1);
	Assert(v.i32[SIMD_W] == 0 \|\| v.i32[SIMD_W] == -1);
	result = v;
	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpFromFloat32x4(const SIMDValue& v, bool &throws)
	{
	SIMDValue result = { 0 };
	const int MIN_INT = 0x80000000, MAX_INT = 0x7FFFFFFF;

	for (uint i = 0; i < 4; i++)
	{
	if (v.f32[i] >= MIN_INT && v.f32[i] <= MAX_INT)
	{
	result.u32[i] = (int)(v.f32[i]);
	}
	else
	{
	// out of range. Caller should throw.
	throws = true;
	return result;
	}
	}
	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpFromFloat64x2(const SIMDValue& v)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (int)(v.f64[SIMD_X]);
	result.i32[SIMD_Y] = (int)(v.f64[SIMD_Y]);
	result.i32[SIMD_Z] = result.i32[SIMD_W] = 0;

	return result;
	}


	// Unary Ops
	SIMDValue SIMDInt32x4Operation::OpAbs(const SIMDValue& value)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (value.i32[SIMD_X] < 0) ? -1 * value.i32[SIMD_X] : value.i32[SIMD_X];
	result.i32[SIMD_Y] = (value.i32[SIMD_Y] < 0) ? -1 * value.i32[SIMD_Y] : value.i32[SIMD_Y];
	result.i32[SIMD_Z] = (value.i32[SIMD_Z] < 0) ? -1 * value.i32[SIMD_Z] : value.i32[SIMD_Z];
	result.i32[SIMD_W] = (value.i32[SIMD_W] < 0) ? -1 * value.i32[SIMD_W] : value.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpNeg(const SIMDValue& value)
	{
	SIMDValue result;

	result.i32[SIMD_X] = -1 * value.i32[SIMD_X];
	result.i32[SIMD_Y] = -1 * value.i32[SIMD_Y];
	result.i32[SIMD_Z] = -1 * value.i32[SIMD_Z];
	result.i32[SIMD_W] = -1 * value.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpNot(const SIMDValue& value)
	{
	SIMDValue result;

	result.i32[SIMD_X] = ~(value.i32[SIMD_X]);
	result.i32[SIMD_Y] = ~(value.i32[SIMD_Y]);
	result.i32[SIMD_Z] = ~(value.i32[SIMD_Z]);
	result.i32[SIMD_W] = ~(value.i32[SIMD_W]);

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpAdd(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] + bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] + bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] + bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] + bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpSub(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] - bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] - bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] - bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] - bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpMul(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] * bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] * bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] * bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] * bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpAnd(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] & bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] & bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] & bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] & bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpOr(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] \| bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] \| bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] \| bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] \| bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpXor(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = aValue.i32[SIMD_X] ^ bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = aValue.i32[SIMD_Y] ^ bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = aValue.i32[SIMD_Z] ^ bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = aValue.i32[SIMD_W] ^ bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpMin(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] < bValue.i32[SIMD_X]) ? aValue.i32[SIMD_X] : bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] < bValue.i32[SIMD_Y]) ? aValue.i32[SIMD_Y] : bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] < bValue.i32[SIMD_Z]) ? aValue.i32[SIMD_Z] : bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] < bValue.i32[SIMD_W]) ? aValue.i32[SIMD_W] : bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpMax(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] > bValue.i32[SIMD_X]) ? aValue.i32[SIMD_X] : bValue.i32[SIMD_X];
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] > bValue.i32[SIMD_Y]) ? aValue.i32[SIMD_Y] : bValue.i32[SIMD_Y];
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] > bValue.i32[SIMD_Z]) ? aValue.i32[SIMD_Z] : bValue.i32[SIMD_Z];
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] > bValue.i32[SIMD_W]) ? aValue.i32[SIMD_W] : bValue.i32[SIMD_W];

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpLessThan(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] < bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] < bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] < bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] < bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpLessThanOrEqual(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] <= bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] <= bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] <= bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] <= bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpEqual(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] == bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] == bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] == bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] == bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpNotEqual(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] != bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] != bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] != bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] != bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpGreaterThan(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] > bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] > bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] > bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] > bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpGreaterThanOrEqual(const SIMDValue& aValue, const SIMDValue& bValue)
	{
	SIMDValue result;

	result.i32[SIMD_X] = (aValue.i32[SIMD_X] >= bValue.i32[SIMD_X]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Y] = (aValue.i32[SIMD_Y] >= bValue.i32[SIMD_Y]) ? 0xffffffff : 0x0;
	result.i32[SIMD_Z] = (aValue.i32[SIMD_Z] >= bValue.i32[SIMD_Z]) ? 0xffffffff : 0x0;
	result.i32[SIMD_W] = (aValue.i32[SIMD_W] >= bValue.i32[SIMD_W]) ? 0xffffffff : 0x0;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpShiftLeftByScalar(const SIMDValue& value, int count)
	{
	SIMDValue result;

	count = count & SIMDUtils::SIMDGetShiftAmountMask(4);

	result.i32[SIMD_X] = value.i32[SIMD_X] << count;
	result.i32[SIMD_Y] = value.i32[SIMD_Y] << count;
	result.i32[SIMD_Z] = value.i32[SIMD_Z] << count;
	result.i32[SIMD_W] = value.i32[SIMD_W] << count;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpShiftRightByScalar(const SIMDValue& value, int count)
	{
	SIMDValue result;

	count = count & SIMDUtils::SIMDGetShiftAmountMask(4);

	result.i32[SIMD_X] = value.i32[SIMD_X] >> count;
	result.i32[SIMD_Y] = value.i32[SIMD_Y] >> count;
	result.i32[SIMD_Z] = value.i32[SIMD_Z] >> count;
	result.i32[SIMD_W] = value.i32[SIMD_W] >> count;

	return result;
	}

	SIMDValue SIMDInt32x4Operation::OpSelect(const SIMDValue& mV, const SIMDValue& tV, const SIMDValue& fV)
	{
	SIMDValue result;

	SIMDValue trueResult = SIMDInt32x4Operation::OpAnd(mV, tV);
	SIMDValue notValue = SIMDInt32x4Operation::OpNot(mV);
	SIMDValue falseResult = SIMDInt32x4Operation::OpAnd(notValue, fV);

	result = SIMDInt32x4Operation::OpOr(trueResult, falseResult);

	return result;
	}
	}
	#endif