mirror of
https://github.com/microsoft/DirectXMath
synced 2024-11-22 12:20:06 +00:00
418 lines
12 KiB
C++
418 lines
12 KiB
C++
//-------------------------------------------------------------------------------------
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// DirectXMathSSE4.h -- SSE4.1 extensions for SIMD C++ Math library
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//
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// Copyright (c) Microsoft Corporation.
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// Licensed under the MIT License.
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//
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// http://go.microsoft.com/fwlink/?LinkID=615560
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//-------------------------------------------------------------------------------------
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#pragma once
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#if defined(_M_ARM) || defined(_M_ARM64) || defined(_M_HYBRID_X86_ARM64) || __arm__ || __aarch64__
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#error SSE4 not supported on ARM platform
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#endif
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#include <smmintrin.h>
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#include <DirectXMath.h>
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namespace DirectX
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{
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namespace SSE4
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{
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inline bool XMVerifySSE4Support()
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{
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// Should return true on AMD Bulldozer, Intel Core 2 ("Penryn"), and Intel Core i7 ("Nehalem") or later processors
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// See http://msdn.microsoft.com/en-us/library/hskdteyh.aspx
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int CPUInfo[4] = { -1 };
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#if defined(__clang__) || defined(__GNUC__)
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__cpuid(0, CPUInfo[0], CPUInfo[1], CPUInfo[2], CPUInfo[3]);
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#else
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__cpuid(CPUInfo, 0);
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#endif
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if ( CPUInfo[0] < 1 )
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return false;
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#if defined(__clang__) || defined(__GNUC__)
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__cpuid(1, CPUInfo[0], CPUInfo[1], CPUInfo[2], CPUInfo[3]);
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#else
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__cpuid(CPUInfo, 1);
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#endif
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// We only check for SSE4.1 instruction set. SSE4.2 instructions are not used.
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return ( (CPUInfo[2] & 0x80000) == 0x80000 );
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}
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//-------------------------------------------------------------------------------------
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// Vector
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//-------------------------------------------------------------------------------------
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#ifdef __clang__
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#pragma clang diagnostic ignored "-Wundefined-reinterpret-cast"
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#endif
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inline void XM_CALLCONV XMVectorGetYPtr(_Out_ float *y, _In_ FXMVECTOR V)
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{
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assert( y != nullptr );
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*reinterpret_cast<int*>(y) = _mm_extract_ps( V, 1 );
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}
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inline void XM_CALLCONV XMVectorGetZPtr(_Out_ float *z, _In_ FXMVECTOR V)
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{
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assert( z != nullptr );
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*reinterpret_cast<int*>(z) = _mm_extract_ps( V, 2 );
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}
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inline void XM_CALLCONV XMVectorGetWPtr(_Out_ float *w, _In_ FXMVECTOR V)
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{
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assert( w != nullptr );
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*reinterpret_cast<int*>(w) = _mm_extract_ps( V, 3 );
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}
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inline uint32_t XM_CALLCONV XMVectorGetIntY(FXMVECTOR V)
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{
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__m128i V1 = _mm_castps_si128( V );
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return static_cast<uint32_t>( _mm_extract_epi32( V1, 1 ) );
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}
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inline uint32_t XM_CALLCONV XMVectorGetIntZ(FXMVECTOR V)
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{
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__m128i V1 = _mm_castps_si128( V );
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return static_cast<uint32_t>( _mm_extract_epi32( V1, 2 ) );
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}
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inline uint32_t XM_CALLCONV XMVectorGetIntW(FXMVECTOR V)
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{
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__m128i V1 = _mm_castps_si128( V );
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return static_cast<uint32_t>( _mm_extract_epi32( V1, 3 ) );
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}
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inline void XM_CALLCONV XMVectorGetIntYPtr(_Out_ uint32_t *y, _In_ FXMVECTOR V)
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{
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assert( y != nullptr );
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__m128i V1 = _mm_castps_si128( V );
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*y = static_cast<uint32_t>( _mm_extract_epi32( V1, 1 ) );
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}
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inline void XM_CALLCONV XMVectorGetIntZPtr(_Out_ uint32_t *z, _In_ FXMVECTOR V)
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{
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assert( z != nullptr );
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__m128i V1 = _mm_castps_si128( V );
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*z = static_cast<uint32_t>( _mm_extract_epi32( V1, 2 ) );
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}
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inline void XM_CALLCONV XMVectorGetIntWPtr(_Out_ uint32_t *w, _In_ FXMVECTOR V)
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{
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assert( w != nullptr );
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__m128i V1 = _mm_castps_si128( V );
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*w = static_cast<uint32_t>( _mm_extract_epi32( V1, 3 ) );
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetY(FXMVECTOR V, float y)
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{
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XMVECTOR vResult = _mm_set_ss(y);
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vResult = _mm_insert_ps( V, vResult, 0x10 );
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return vResult;
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetZ(FXMVECTOR V, float z)
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{
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XMVECTOR vResult = _mm_set_ss(z);
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vResult = _mm_insert_ps( V, vResult, 0x20 );
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return vResult;
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetW(FXMVECTOR V, float w)
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{
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XMVECTOR vResult = _mm_set_ss(w);
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vResult = _mm_insert_ps( V, vResult, 0x30 );
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return vResult;
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetIntY(FXMVECTOR V, uint32_t y)
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{
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__m128i vResult = _mm_castps_si128( V );
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vResult = _mm_insert_epi32( vResult, static_cast<int>(y), 1 );
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return _mm_castsi128_ps( vResult );
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetIntZ(FXMVECTOR V, uint32_t z)
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{
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__m128i vResult = _mm_castps_si128( V );
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vResult = _mm_insert_epi32( vResult, static_cast<int>(z), 2 );
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return _mm_castsi128_ps( vResult );
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}
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inline XMVECTOR XM_CALLCONV XMVectorSetIntW(FXMVECTOR V, uint32_t w)
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{
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__m128i vResult = _mm_castps_si128( V );
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vResult = _mm_insert_epi32( vResult, static_cast<int>(w), 3 );
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return _mm_castsi128_ps( vResult );
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}
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inline XMVECTOR XM_CALLCONV XMVectorRound( FXMVECTOR V )
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{
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return _mm_round_ps( V, _MM_FROUND_TO_NEAREST_INT | _MM_FROUND_NO_EXC );
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}
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inline XMVECTOR XM_CALLCONV XMVectorTruncate( FXMVECTOR V )
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{
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return _mm_round_ps( V, _MM_FROUND_TO_ZERO | _MM_FROUND_NO_EXC );
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}
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inline XMVECTOR XM_CALLCONV XMVectorFloor( FXMVECTOR V )
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{
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return _mm_floor_ps( V );
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}
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inline XMVECTOR XM_CALLCONV XMVectorCeiling( FXMVECTOR V )
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{
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return _mm_ceil_ps( V );
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}
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//-------------------------------------------------------------------------------------
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// Vector2
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//-------------------------------------------------------------------------------------
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inline XMVECTOR XM_CALLCONV XMVector2Dot( FXMVECTOR V1, FXMVECTOR V2 )
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{
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return _mm_dp_ps( V1, V2, 0x3f );
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}
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inline XMVECTOR XM_CALLCONV XMVector2LengthSq( FXMVECTOR V )
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{
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return SSE4::XMVector2Dot(V, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector2ReciprocalLengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x3f );
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return _mm_rsqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector2ReciprocalLength( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x3f );
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XMVECTOR vLengthSq = _mm_sqrt_ps( vTemp );
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return _mm_div_ps( g_XMOne, vLengthSq );
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}
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inline XMVECTOR XM_CALLCONV XMVector2LengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x3f );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector2Length( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x3f );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector2NormalizeEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x3f );
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XMVECTOR vResult = _mm_rsqrt_ps( vTemp );
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return _mm_mul_ps(vResult, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector2Normalize( FXMVECTOR V )
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{
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XMVECTOR vLengthSq = _mm_dp_ps( V, V, 0x3f );
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// Prepare for the division
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XMVECTOR vResult = _mm_sqrt_ps(vLengthSq);
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// Create zero with a single instruction
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XMVECTOR vZeroMask = _mm_setzero_ps();
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// Test for a divide by zero (Must be FP to detect -0.0)
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vZeroMask = _mm_cmpneq_ps(vZeroMask,vResult);
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// Failsafe on zero (Or epsilon) length planes
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// If the length is infinity, set the elements to zero
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vLengthSq = _mm_cmpneq_ps(vLengthSq,g_XMInfinity);
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// Reciprocal mul to perform the normalization
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vResult = _mm_div_ps(V,vResult);
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// Any that are infinity, set to zero
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vResult = _mm_and_ps(vResult,vZeroMask);
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// Select qnan or result based on infinite length
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XMVECTOR vTemp1 = _mm_andnot_ps(vLengthSq,g_XMQNaN);
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XMVECTOR vTemp2 = _mm_and_ps(vResult,vLengthSq);
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vResult = _mm_or_ps(vTemp1,vTemp2);
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return vResult;
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}
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//-------------------------------------------------------------------------------------
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// Vector3
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//-------------------------------------------------------------------------------------
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inline XMVECTOR XM_CALLCONV XMVector3Dot( FXMVECTOR V1, FXMVECTOR V2 )
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{
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return _mm_dp_ps( V1, V2, 0x7f );
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}
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inline XMVECTOR XM_CALLCONV XMVector3LengthSq( FXMVECTOR V )
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{
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return SSE4::XMVector3Dot(V, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector3ReciprocalLengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x7f );
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return _mm_rsqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector3ReciprocalLength( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x7f );
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XMVECTOR vLengthSq = _mm_sqrt_ps( vTemp );
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return _mm_div_ps( g_XMOne, vLengthSq );
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}
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inline XMVECTOR XM_CALLCONV XMVector3LengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x7f );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector3Length( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x7f );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector3NormalizeEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0x7f );
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XMVECTOR vResult = _mm_rsqrt_ps( vTemp );
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return _mm_mul_ps(vResult, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector3Normalize( FXMVECTOR V )
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{
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XMVECTOR vLengthSq = _mm_dp_ps( V, V, 0x7f );
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// Prepare for the division
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XMVECTOR vResult = _mm_sqrt_ps(vLengthSq);
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// Create zero with a single instruction
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XMVECTOR vZeroMask = _mm_setzero_ps();
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// Test for a divide by zero (Must be FP to detect -0.0)
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vZeroMask = _mm_cmpneq_ps(vZeroMask,vResult);
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// Failsafe on zero (Or epsilon) length planes
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// If the length is infinity, set the elements to zero
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vLengthSq = _mm_cmpneq_ps(vLengthSq,g_XMInfinity);
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// Divide to perform the normalization
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vResult = _mm_div_ps(V,vResult);
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// Any that are infinity, set to zero
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vResult = _mm_and_ps(vResult,vZeroMask);
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// Select qnan or result based on infinite length
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XMVECTOR vTemp1 = _mm_andnot_ps(vLengthSq,g_XMQNaN);
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XMVECTOR vTemp2 = _mm_and_ps(vResult,vLengthSq);
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vResult = _mm_or_ps(vTemp1,vTemp2);
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return vResult;
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}
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//-------------------------------------------------------------------------------------
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// Vector4
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//-------------------------------------------------------------------------------------
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inline XMVECTOR XM_CALLCONV XMVector4Dot( FXMVECTOR V1, FXMVECTOR V2 )
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{
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return _mm_dp_ps( V1, V2, 0xff );
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}
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inline XMVECTOR XM_CALLCONV XMVector4LengthSq( FXMVECTOR V )
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{
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return SSE4::XMVector4Dot(V, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector4ReciprocalLengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0xff );
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return _mm_rsqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector4ReciprocalLength( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0xff );
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XMVECTOR vLengthSq = _mm_sqrt_ps( vTemp );
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return _mm_div_ps( g_XMOne, vLengthSq );
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}
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inline XMVECTOR XM_CALLCONV XMVector4LengthEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0xff );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector4Length( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0xff );
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return _mm_sqrt_ps( vTemp );
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}
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inline XMVECTOR XM_CALLCONV XMVector4NormalizeEst( FXMVECTOR V )
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{
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XMVECTOR vTemp = _mm_dp_ps( V, V, 0xff );
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XMVECTOR vResult = _mm_rsqrt_ps( vTemp );
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return _mm_mul_ps(vResult, V);
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}
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inline XMVECTOR XM_CALLCONV XMVector4Normalize( FXMVECTOR V )
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{
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XMVECTOR vLengthSq = _mm_dp_ps( V, V, 0xff );
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// Prepare for the division
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XMVECTOR vResult = _mm_sqrt_ps(vLengthSq);
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// Create zero with a single instruction
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XMVECTOR vZeroMask = _mm_setzero_ps();
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// Test for a divide by zero (Must be FP to detect -0.0)
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vZeroMask = _mm_cmpneq_ps(vZeroMask,vResult);
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// Failsafe on zero (Or epsilon) length planes
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// If the length is infinity, set the elements to zero
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vLengthSq = _mm_cmpneq_ps(vLengthSq,g_XMInfinity);
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// Divide to perform the normalization
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vResult = _mm_div_ps(V,vResult);
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// Any that are infinity, set to zero
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vResult = _mm_and_ps(vResult,vZeroMask);
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// Select qnan or result based on infinite length
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XMVECTOR vTemp1 = _mm_andnot_ps(vLengthSq,g_XMQNaN);
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XMVECTOR vTemp2 = _mm_and_ps(vResult,vLengthSq);
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vResult = _mm_or_ps(vTemp1,vTemp2);
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return vResult;
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}
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//-------------------------------------------------------------------------------------
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// Plane
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//-------------------------------------------------------------------------------------
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inline XMVECTOR XM_CALLCONV XMPlaneNormalizeEst( FXMVECTOR P )
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{
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XMVECTOR vTemp = _mm_dp_ps( P, P, 0x7f );
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XMVECTOR vResult = _mm_rsqrt_ps( vTemp );
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return _mm_mul_ps(vResult, P);
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}
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inline XMVECTOR XM_CALLCONV XMPlaneNormalize( FXMVECTOR P )
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{
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XMVECTOR vLengthSq = _mm_dp_ps( P, P, 0x7f );
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// Prepare for the division
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XMVECTOR vResult = _mm_sqrt_ps(vLengthSq);
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// Failsafe on zero (Or epsilon) length planes
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// If the length is infinity, set the elements to zero
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vLengthSq = _mm_cmpneq_ps(vLengthSq,g_XMInfinity);
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// Reciprocal mul to perform the normalization
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vResult = _mm_div_ps(P,vResult);
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// Any that are infinity, set to zero
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vResult = _mm_and_ps(vResult,vLengthSq);
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return vResult;
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}
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} // namespace SSE4
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} // namespace DirectX
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