404 lines
10 KiB
C
404 lines
10 KiB
C
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions
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// are met:
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above copyright
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// notice, this list of conditions and the following disclaimer in the
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// documentation and/or other materials provided with the distribution.
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// * Neither the name of NVIDIA CORPORATION nor the names of its
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// contributors may be used to endorse or promote products derived
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// from this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``AS IS'' AND ANY
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// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
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// PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
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// CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
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// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
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// OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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//
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// Copyright (c) 2008-2019 NVIDIA Corporation. All rights reserved.
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// Copyright (c) 2004-2008 AGEIA Technologies, Inc. All rights reserved.
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// Copyright (c) 2001-2004 NovodeX AG. All rights reserved.
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#ifndef PXFOUNDATION_PXQUAT_H
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#define PXFOUNDATION_PXQUAT_H
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/** \addtogroup foundation
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@{
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*/
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#include "foundation/PxVec3.h"
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#if !PX_DOXYGEN
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namespace physx
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{
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#endif
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/**
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\brief This is a quaternion class. For more information on quaternion mathematics
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consult a mathematics source on complex numbers.
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*/
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class PxQuat
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{
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public:
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/**
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\brief Default constructor, does not do any initialization.
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat()
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{
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}
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//! identity constructor
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PX_CUDA_CALLABLE PX_INLINE PxQuat(PxIDENTITY r) : x(0.0f), y(0.0f), z(0.0f), w(1.0f)
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{
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PX_UNUSED(r);
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}
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/**
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\brief Constructor from a scalar: sets the real part w to the scalar value, and the imaginary parts (x,y,z) to zero
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*/
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explicit PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat(float r) : x(0.0f), y(0.0f), z(0.0f), w(r)
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{
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}
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/**
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\brief Constructor. Take note of the order of the elements!
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat(float nx, float ny, float nz, float nw) : x(nx), y(ny), z(nz), w(nw)
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{
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}
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/**
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\brief Creates from angle-axis representation.
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Axis must be normalized!
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Angle is in radians!
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<b>Unit:</b> Radians
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*/
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PX_CUDA_CALLABLE PX_INLINE PxQuat(float angleRadians, const PxVec3& unitAxis)
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{
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PX_SHARED_ASSERT(PxAbs(1.0f - unitAxis.magnitude()) < 1e-3f);
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const float a = angleRadians * 0.5f;
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const float s = PxSin(a);
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w = PxCos(a);
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x = unitAxis.x * s;
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y = unitAxis.y * s;
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z = unitAxis.z * s;
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}
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/**
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\brief Copy ctor.
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat(const PxQuat& v) : x(v.x), y(v.y), z(v.z), w(v.w)
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{
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}
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/**
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\brief Creates from orientation matrix.
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\param[in] m Rotation matrix to extract quaternion from.
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*/
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PX_CUDA_CALLABLE PX_INLINE explicit PxQuat(const PxMat33& m); /* defined in PxMat33.h */
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/**
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\brief returns true if quat is identity
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE bool isIdentity() const
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{
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return x==0.0f && y==0.0f && z==0.0f && w==1.0f;
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}
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/**
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\brief returns true if all elements are finite (not NAN or INF, etc.)
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*/
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PX_CUDA_CALLABLE bool isFinite() const
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{
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return PxIsFinite(x) && PxIsFinite(y) && PxIsFinite(z) && PxIsFinite(w);
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}
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/**
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\brief returns true if finite and magnitude is close to unit
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*/
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PX_CUDA_CALLABLE bool isUnit() const
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{
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const float unitTolerance = 1e-4f;
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return isFinite() && PxAbs(magnitude() - 1) < unitTolerance;
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}
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/**
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\brief returns true if finite and magnitude is reasonably close to unit to allow for some accumulation of error vs
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isValid
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*/
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PX_CUDA_CALLABLE bool isSane() const
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{
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const float unitTolerance = 1e-2f;
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return isFinite() && PxAbs(magnitude() - 1) < unitTolerance;
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}
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/**
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\brief returns true if the two quaternions are exactly equal
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*/
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PX_CUDA_CALLABLE PX_INLINE bool operator==(const PxQuat& q) const
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{
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return x == q.x && y == q.y && z == q.z && w == q.w;
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}
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/**
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\brief converts this quaternion to angle-axis representation
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*/
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PX_CUDA_CALLABLE PX_INLINE void toRadiansAndUnitAxis(float& angle, PxVec3& axis) const
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{
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const float quatEpsilon = 1.0e-8f;
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const float s2 = x * x + y * y + z * z;
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if(s2 < quatEpsilon * quatEpsilon) // can't extract a sensible axis
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{
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angle = 0.0f;
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axis = PxVec3(1.0f, 0.0f, 0.0f);
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}
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else
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{
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const float s = PxRecipSqrt(s2);
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axis = PxVec3(x, y, z) * s;
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angle = PxAbs(w) < quatEpsilon ? PxPi : PxAtan2(s2 * s, w) * 2.0f;
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}
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}
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/**
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\brief Gets the angle between this quat and the identity quaternion.
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<b>Unit:</b> Radians
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*/
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PX_CUDA_CALLABLE PX_INLINE float getAngle() const
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{
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return PxAcos(w) * 2.0f;
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}
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/**
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\brief Gets the angle between this quat and the argument
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<b>Unit:</b> Radians
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*/
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PX_CUDA_CALLABLE PX_INLINE float getAngle(const PxQuat& q) const
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{
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return PxAcos(dot(q)) * 2.0f;
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}
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/**
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\brief This is the squared 4D vector length, should be 1 for unit quaternions.
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE float magnitudeSquared() const
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{
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return x * x + y * y + z * z + w * w;
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}
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/**
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\brief returns the scalar product of this and other.
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE float dot(const PxQuat& v) const
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{
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return x * v.x + y * v.y + z * v.z + w * v.w;
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}
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PX_CUDA_CALLABLE PX_INLINE PxQuat getNormalized() const
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{
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const float s = 1.0f / magnitude();
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return PxQuat(x * s, y * s, z * s, w * s);
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}
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PX_CUDA_CALLABLE PX_INLINE float magnitude() const
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{
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return PxSqrt(magnitudeSquared());
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}
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// modifiers:
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/**
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\brief maps to the closest unit quaternion.
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*/
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PX_CUDA_CALLABLE PX_INLINE float normalize() // convert this PxQuat to a unit quaternion
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{
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const float mag = magnitude();
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if(mag != 0.0f)
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{
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const float imag = 1.0f / mag;
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x *= imag;
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y *= imag;
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z *= imag;
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w *= imag;
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}
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return mag;
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}
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/*
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\brief returns the conjugate.
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\note for unit quaternions, this is the inverse.
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*/
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PX_CUDA_CALLABLE PX_INLINE PxQuat getConjugate() const
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{
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return PxQuat(-x, -y, -z, w);
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}
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/*
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\brief returns imaginary part.
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*/
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PX_CUDA_CALLABLE PX_INLINE PxVec3 getImaginaryPart() const
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{
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return PxVec3(x, y, z);
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}
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/** brief computes rotation of x-axis */
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxVec3 getBasisVector0() const
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{
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const float x2 = x * 2.0f;
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const float w2 = w * 2.0f;
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return PxVec3((w * w2) - 1.0f + x * x2, (z * w2) + y * x2, (-y * w2) + z * x2);
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}
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/** brief computes rotation of y-axis */
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxVec3 getBasisVector1() const
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{
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const float y2 = y * 2.0f;
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const float w2 = w * 2.0f;
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return PxVec3((-z * w2) + x * y2, (w * w2) - 1.0f + y * y2, (x * w2) + z * y2);
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}
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/** brief computes rotation of z-axis */
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxVec3 getBasisVector2() const
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{
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const float z2 = z * 2.0f;
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const float w2 = w * 2.0f;
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return PxVec3((y * w2) + x * z2, (-x * w2) + y * z2, (w * w2) - 1.0f + z * z2);
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}
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/**
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rotates passed vec by this (assumed unitary)
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE const PxVec3 rotate(const PxVec3& v) const
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{
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const float vx = 2.0f * v.x;
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const float vy = 2.0f * v.y;
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const float vz = 2.0f * v.z;
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const float w2 = w * w - 0.5f;
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const float dot2 = (x * vx + y * vy + z * vz);
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return PxVec3((vx * w2 + (y * vz - z * vy) * w + x * dot2), (vy * w2 + (z * vx - x * vz) * w + y * dot2),
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(vz * w2 + (x * vy - y * vx) * w + z * dot2));
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}
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/**
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inverse rotates passed vec by this (assumed unitary)
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE const PxVec3 rotateInv(const PxVec3& v) const
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{
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const float vx = 2.0f * v.x;
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const float vy = 2.0f * v.y;
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const float vz = 2.0f * v.z;
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const float w2 = w * w - 0.5f;
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const float dot2 = (x * vx + y * vy + z * vz);
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return PxVec3((vx * w2 - (y * vz - z * vy) * w + x * dot2), (vy * w2 - (z * vx - x * vz) * w + y * dot2),
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(vz * w2 - (x * vy - y * vx) * w + z * dot2));
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}
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/**
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\brief Assignment operator
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*/
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat& operator=(const PxQuat& p)
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{
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x = p.x;
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y = p.y;
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z = p.z;
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w = p.w;
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return *this;
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat& operator*=(const PxQuat& q)
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{
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const float tx = w * q.x + q.w * x + y * q.z - q.y * z;
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const float ty = w * q.y + q.w * y + z * q.x - q.z * x;
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const float tz = w * q.z + q.w * z + x * q.y - q.x * y;
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w = w * q.w - q.x * x - y * q.y - q.z * z;
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x = tx;
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y = ty;
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z = tz;
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return *this;
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat& operator+=(const PxQuat& q)
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{
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x += q.x;
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y += q.y;
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z += q.z;
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w += q.w;
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return *this;
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat& operator-=(const PxQuat& q)
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{
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x -= q.x;
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y -= q.y;
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z -= q.z;
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w -= q.w;
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return *this;
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat& operator*=(const float s)
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{
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x *= s;
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y *= s;
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z *= s;
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w *= s;
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return *this;
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}
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/** quaternion multiplication */
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PX_CUDA_CALLABLE PX_INLINE PxQuat operator*(const PxQuat& q) const
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{
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return PxQuat(w * q.x + q.w * x + y * q.z - q.y * z, w * q.y + q.w * y + z * q.x - q.z * x,
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w * q.z + q.w * z + x * q.y - q.x * y, w * q.w - x * q.x - y * q.y - z * q.z);
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}
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/** quaternion addition */
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat operator+(const PxQuat& q) const
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{
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return PxQuat(x + q.x, y + q.y, z + q.z, w + q.w);
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}
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/** quaternion subtraction */
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat operator-() const
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{
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return PxQuat(-x, -y, -z, -w);
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat operator-(const PxQuat& q) const
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{
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return PxQuat(x - q.x, y - q.y, z - q.z, w - q.w);
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}
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PX_CUDA_CALLABLE PX_FORCE_INLINE PxQuat operator*(float r) const
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{
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return PxQuat(x * r, y * r, z * r, w * r);
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}
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/** the quaternion elements */
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float x, y, z, w;
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};
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#if !PX_DOXYGEN
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} // namespace physx
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#endif
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/** @} */
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#endif // #ifndef PXFOUNDATION_PXQUAT_H
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