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+/** 
+ * @file llvector4a.h
+ * @brief LLVector4a class header file - memory aligned and vectorized 4 component vector
+ *
+ * $LicenseInfo:firstyear=2010&license=viewerlgpl$
+ * Second Life Viewer Source Code
+ * Copyright (C) 2010, Linden Research, Inc.
+ * 
+ * This library is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public
+ * License as published by the Free Software Foundation;
+ * version 2.1 of the License only.
+ * 
+ * This library is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+ * Lesser General Public License for more details.
+ * 
+ * You should have received a copy of the GNU Lesser General Public
+ * License along with this library; if not, write to the Free Software
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
+ * 
+ * Linden Research, Inc., 945 Battery Street, San Francisco, CA  94111  USA
+ * $/LicenseInfo$
+ */
+
+#ifndef	LL_LLVECTOR4A_H
+#define	LL_LLVECTOR4A_H
+
+
+class LLRotation;
+
+#include <assert.h>
+#include "llpreprocessor.h"
+
+///////////////////////////////////
+// FIRST TIME USERS PLEASE READ
+//////////////////////////////////
+// This is just the beginning of LLVector4a. There are many more useful functions
+// yet to be implemented. For example, setNeg to negate a vector, rotate() to apply
+// a matrix rotation, various functions to manipulate only the X, Y, and Z elements
+// and many others (including a whole variety of accessors). So if you don't see a 
+// function here that you need, please contact Falcon or someone else with SSE 
+// experience (Richard, I think, has some and davep has a little as of the time 
+// of this writing, July 08, 2010) about getting it implemented before you resort to
+// LLVector3/LLVector4. 
+/////////////////////////////////
+
+class LLVector4a
+{
+public:
+
+	///////////////////////////////////
+	// STATIC METHODS
+	///////////////////////////////////
+	
+	// Call initClass() at startup to avoid 15,000+ cycle penalties from denormalized numbers
+	static void initClass()
+	{
+		_MM_SET_FLUSH_ZERO_MODE(_MM_FLUSH_ZERO_ON);
+		_MM_SET_ROUNDING_MODE(_MM_ROUND_NEAREST);
+	}
+
+	// Return a vector of all zeros
+	static inline const LLVector4a& getZero()
+	{
+		extern const LLVector4a LL_V4A_ZERO;
+		return LL_V4A_ZERO;
+	}
+	
+	// Return a vector of all epsilon, where epsilon is a small float suitable for approximate equality checks
+	static inline const LLVector4a& getEpsilon()
+	{
+		extern const LLVector4a LL_V4A_EPSILON;
+		return LL_V4A_EPSILON;
+	}
+
+	// Copy 16 bytes from src to dst. Source and destination must be 16-byte aligned
+	static inline void copy4a(F32* dst, const F32* src)
+	{
+		_mm_store_ps(dst, _mm_load_ps(src));
+	}
+
+	// Copy words 16-byte blocks from src to dst. Source and destination must not overlap. 
+	static void memcpyNonAliased16(F32* __restrict dst, const F32* __restrict src, size_t bytes);
+
+	////////////////////////////////////
+	// CONSTRUCTORS 
+	////////////////////////////////////
+	
+	LLVector4a()
+	{ //DO NOT INITIALIZE -- The overhead is completely unnecessary
+	}
+	
+	LLVector4a(F32 x, F32 y, F32 z, F32 w = 0.f)
+	{
+		set(x,y,z,w);
+	}
+	
+	LLVector4a(F32 x)
+	{
+		splat(x);
+	}
+	
+	LLVector4a(const LLSimdScalar& x)
+	{
+		splat(x);
+	}
+
+	LLVector4a(LLQuad q)
+	{
+		mQ = q;
+	}
+
+	////////////////////////////////////
+	// LOAD/STORE
+	////////////////////////////////////
+	
+	// Load from 16-byte aligned src array (preferred method of loading)
+	inline void load4a(const F32* src);
+	
+	// Load from unaligned src array (NB: Significantly slower than load4a)
+	inline void loadua(const F32* src);
+	
+	// Load only three floats beginning at address 'src'. Slowest method.
+	inline void load3(const F32* src);
+	
+	// Store to a 16-byte aligned memory address
+	inline void store4a(F32* dst) const;
+	
+	////////////////////////////////////
+	// BASIC GET/SET 
+	////////////////////////////////////
+	
+	// Return a "this" as an F32 pointer. Do not use unless you have a very good reason.  (Not sure? Ask Falcon)
+	inline F32* getF32ptr();
+	
+	// Return a "this" as a const F32 pointer. Do not use unless you have a very good reason.  (Not sure? Ask Falcon)
+	inline const F32* const getF32ptr() const;
+	
+	// Read-only access a single float in this vector. Do not use in proximity to any function call that manipulates
+	// the data at the whole vector level or you will incur a substantial penalty. Consider using the splat functions instead
+	inline F32 operator[](const S32 idx) const;
+
+	// Prefer this method for read-only access to a single element. Prefer the templated version if the elem is known at compile time.
+	inline LLSimdScalar getScalarAt(const S32 idx) const;
+
+	// Prefer this method for read-only access to a single element. Prefer the templated version if the elem is known at compile time.
+	template <int N> LL_FORCE_INLINE LLSimdScalar getScalarAt() const;
+
+	// Set to an x, y, z and optional w provided
+	inline void set(F32 x, F32 y, F32 z, F32 w = 0.f);
+	
+	// Set to all zeros. This is preferred to using ::getZero()
+	inline void clear();
+	
+	// Set all elements to 'x'
+	inline void splat(const F32 x);
+
+	// Set all elements to 'x'
+	inline void splat(const LLSimdScalar& x);
+	
+	// Set all 4 elements to element N of src, with N known at compile time
+	template <int N> void splat(const LLVector4a& src);
+	
+	// Set all 4 elements to element i of v, with i NOT known at compile time
+	inline void splat(const LLVector4a& v, U32 i);
+	
+	// Select bits from sourceIfTrue and sourceIfFalse according to bits in mask
+	inline void setSelectWithMask( const LLVector4Logical& mask, const LLVector4a& sourceIfTrue, const LLVector4a& sourceIfFalse );
+	
+	////////////////////////////////////
+	// ALGEBRAIC
+	////////////////////////////////////
+	
+	// Set this to the element-wise (a + b)
+	inline void setAdd(const LLVector4a& a, const LLVector4a& b);
+	
+	// Set this to element-wise (a - b)
+	inline void setSub(const LLVector4a& a, const LLVector4a& b);
+	
+	// Set this to element-wise multiply (a * b)
+	inline void setMul(const LLVector4a& a, const LLVector4a& b);
+	
+	// Set this to element-wise quotient (a / b)
+	inline void setDiv(const LLVector4a& a, const LLVector4a& b);
+	
+	// Set this to the element-wise absolute value of src
+	inline void setAbs(const LLVector4a& src);
+	
+	// Add to each component in this vector the corresponding component in rhs
+	inline void add(const LLVector4a& rhs);
+	
+	// Subtract from each component in this vector the corresponding component in rhs
+	inline void sub(const LLVector4a& rhs);
+	
+	// Multiply each component in this vector by the corresponding component in rhs
+	inline void mul(const LLVector4a& rhs);
+	
+	// Divide each component in this vector by the corresponding component in rhs
+	inline void div(const LLVector4a& rhs);
+	
+	// Multiply this vector by x in a scalar fashion
+	inline void mul(const F32 x);
+
+	// Set this to (a x b) (geometric cross-product)
+	inline void setCross3(const LLVector4a& a, const LLVector4a& b);
+	
+	// Set all elements to the dot product of the x, y, and z elements in a and b
+	inline void setAllDot3(const LLVector4a& a, const LLVector4a& b);
+
+	// Set all elements to the dot product of the x, y, z, and w elements in a and b
+	inline void setAllDot4(const LLVector4a& a, const LLVector4a& b);
+
+	// Return the 3D dot product of this vector and b
+	inline LLSimdScalar dot3(const LLVector4a& b) const;
+
+	// Return the 4D dot product of this vector and b
+	inline LLSimdScalar dot4(const LLVector4a& b) const;
+
+	// Normalize this vector with respect to the x, y, and z components only. Accurate to 22 bites of precision. W component is destroyed
+	// Note that this does not consider zero length vectors!
+	inline void normalize3();
+
+	// Same as normalize3() but with respect to all 4 components
+	inline void normalize4();
+
+	// Same as normalize3(), but returns length as a SIMD scalar
+	inline LLSimdScalar normalize3withLength();
+
+	// Normalize this vector with respect to the x, y, and z components only. Accurate only to 10-12 bits of precision. W component is destroyed
+	// Note that this does not consider zero length vectors!
+	inline void normalize3fast();
+
+	// Return true if this vector is normalized with respect to x,y,z up to tolerance
+	inline LLBool32 isNormalized3( F32 tolerance = 1e-3 ) const;
+
+	// Return true if this vector is normalized with respect to all components up to tolerance
+	inline LLBool32 isNormalized4( F32 tolerance = 1e-3 ) const;
+
+	// Set all elements to the length of vector 'v' 
+	inline void setAllLength3( const LLVector4a& v );
+
+	// Get this vector's length
+	inline LLSimdScalar getLength3() const;
+	
+	// Set the components of this vector to the minimum of the corresponding components of lhs and rhs
+	inline void setMin(const LLVector4a& lhs, const LLVector4a& rhs);
+	
+	// Set the components of this vector to the maximum of the corresponding components of lhs and rhs
+	inline void setMax(const LLVector4a& lhs, const LLVector4a& rhs);
+	
+	// Clamps this vector to be within the component-wise range low to high (inclusive)
+	inline void clamp( const LLVector4a& low, const LLVector4a& high );
+
+	// Set this to  (c * lhs) + rhs * ( 1 - c)
+	inline void setLerp(const LLVector4a& lhs, const LLVector4a& rhs, F32 c);
+	
+	// Return true (nonzero) if x, y, z (and w for Finite4) are all finite floats
+	inline LLBool32 isFinite3() const;	
+	inline LLBool32 isFinite4() const;
+
+	// Set this vector to 'vec' rotated by the LLRotation or LLQuaternion2 provided
+	void setRotated( const LLRotation& rot, const LLVector4a& vec );
+	void setRotated( const class LLQuaternion2& quat, const LLVector4a& vec );
+
+	// Set this vector to 'vec' rotated by the INVERSE of the LLRotation or LLQuaternion2 provided
+	inline void setRotatedInv( const LLRotation& rot, const LLVector4a& vec );
+	inline void setRotatedInv( const class LLQuaternion2& quat, const LLVector4a& vec );
+
+	// Quantize this vector to 8 or 16 bit precision
+	void quantize8( const LLVector4a& low, const LLVector4a& high );
+	void quantize16( const LLVector4a& low, const LLVector4a& high );
+
+	////////////////////////////////////
+	// LOGICAL
+	////////////////////////////////////	
+	// The functions in this section will compare the elements in this vector
+	// to those in rhs and return an LLVector4Logical with all bits set in elements
+	// where the comparison was true and all bits unset in elements where the comparison
+	// was false. See llvector4logica.h
+	////////////////////////////////////
+	// WARNING: Other than equals3 and equals4, these functions do NOT account
+	// for floating point tolerance. You should include the appropriate tolerance
+	// in the inputs.
+	////////////////////////////////////
+	
+	inline LLVector4Logical greaterThan(const LLVector4a& rhs) const;
+
+	inline LLVector4Logical lessThan(const LLVector4a& rhs) const;
+	
+	inline LLVector4Logical greaterEqual(const LLVector4a& rhs) const;
+
+	inline LLVector4Logical lessEqual(const LLVector4a& rhs) const;
+	
+	inline LLVector4Logical equal(const LLVector4a& rhs) const;
+
+	// Returns true if this and rhs are componentwise equal up to the specified absolute tolerance
+	inline bool equals4(const LLVector4a& rhs, F32 tolerance = F_APPROXIMATELY_ZERO ) const;
+
+	inline bool equals3(const LLVector4a& rhs, F32 tolerance = F_APPROXIMATELY_ZERO ) const;
+
+	////////////////////////////////////
+	// OPERATORS
+	////////////////////////////////////	
+	
+	// Do NOT add aditional operators without consulting someone with SSE experience
+	inline const LLVector4a& operator= ( const LLVector4a& rhs );
+	
+	inline const LLVector4a& operator= ( const LLQuad& rhs );
+
+	inline operator LLQuad() const;	
+
+private:
+	LLQuad mQ;
+};
+
+inline void update_min_max(LLVector4a& min, LLVector4a& max, const LLVector4a& p)
+{
+	min.setMin(min, p);
+	max.setMax(max, p);
+}
+
+#endif