4#ifndef OPENVDB_MATH_QUAT_H_HAS_BEEN_INCLUDED
5#define OPENVDB_MATH_QUAT_H_HAS_BEEN_INCLUDED
23template<
typename T>
class Quat;
29 T qdot,
angle, sineAngle;
33 if (fabs(qdot) >= 1.0) {
38 sineAngle = sin(
angle);
47 if (sineAngle <= tolerance) {
50 Quat<T> qtemp(s * q1[0] + t * q2[0], s * q1[1] + t * q2[1],
51 s * q1[2] + t * q2[2], s * q1[3] + t * q2[3]);
58 double lengthSquared = qtemp.
dot(qtemp);
60 if (lengthSquared <= tolerance * tolerance) {
61 qtemp = (t < 0.5) ? q1 : q2;
63 qtemp *= 1.0 / sqrt(lengthSquared);
68 T sine = 1.0 / sineAngle;
69 T a = sin((1.0 - t) *
angle) * sine;
70 T b = sin(t *
angle) * sine;
71 return Quat<T>(a * q1[0] + b * q2[0], a * q1[1] + b * q2[1],
72 a * q1[2] + b * q2[2], a * q1[3] + b * q2[3]);
83 static const int size = 4;
116 T s = T(sin(
angle*T(0.5)));
118 mm[0] = axis.
x() * s;
119 mm[1] = axis.
y() * s;
120 mm[2] = axis.
z() * s;
122 mm[3] = T(cos(
angle*T(0.5)));
129 T s = T(sin(
angle*T(0.5)));
131 mm[0] = (axis==math::X_AXIS) * s;
132 mm[1] = (axis==math::Y_AXIS) * s;
133 mm[2] = (axis==math::Z_AXIS) * s;
135 mm[3] = T(cos(
angle*T(0.5)));
139 template<
typename T1>
145 "A non-rotation matrix can not be used to construct a quaternion");
149 "A reflection matrix can not be used to construct a quaternion");
152 T trace(rot.
trace());
155 T q_w = 0.5 * std::sqrt(trace+1);
156 T factor = 0.25 / q_w;
158 mm[0] = factor * (rot(1,2) - rot(2,1));
159 mm[1] = factor * (rot(2,0) - rot(0,2));
160 mm[2] = factor * (rot(0,1) - rot(1,0));
162 }
else if (rot(0,0) > rot(1,1) && rot(0,0) > rot(2,2)) {
164 T q_x = 0.5 * sqrt(rot(0,0)- rot(1,1)-rot(2,2)+1);
165 T factor = 0.25 / q_x;
168 mm[1] = factor * (rot(0,1) + rot(1,0));
169 mm[2] = factor * (rot(2,0) + rot(0,2));
170 mm[3] = factor * (rot(1,2) - rot(2,1));
171 }
else if (rot(1,1) > rot(2,2)) {
173 T q_y = 0.5 * sqrt(rot(1,1)-rot(0,0)-rot(2,2)+1);
174 T factor = 0.25 / q_y;
176 mm[0] = factor * (rot(0,1) + rot(1,0));
178 mm[2] = factor * (rot(1,2) + rot(2,1));
179 mm[3] = factor * (rot(2,0) - rot(0,2));
182 T q_z = 0.5 * sqrt(rot(2,2)-rot(0,0)-rot(1,1)+1);
183 T factor = 0.25 / q_z;
185 mm[0] = factor * (rot(2,0) + rot(0,2));
186 mm[1] = factor * (rot(1,2) + rot(2,1));
188 mm[3] = factor * (rot(0,1) - rot(1,0));
193 T&
x() {
return mm[0]; }
194 T&
y() {
return mm[1]; }
195 T&
z() {
return mm[2]; }
196 T&
w() {
return mm[3]; }
199 T
x()
const {
return mm[0]; }
200 T
y()
const {
return mm[1]; }
201 T
z()
const {
return mm[2]; }
202 T
w()
const {
return mm[3]; }
214 operator T*() {
return mm; }
215 operator const T*()
const {
return mm; }
226 T sqrLength = mm[0]*mm[0] + mm[1]*mm[1] + mm[2]*mm[2];
228 if ( sqrLength > 1.0e-8 ) {
230 return T(T(2.0) * acos(mm[3]));
241 T sqrLength = mm[0]*mm[0] + mm[1]*mm[1] + mm[2]*mm[2];
243 if ( sqrLength > 1.0e-8 ) {
245 T invLength = T(T(1)/sqrt(sqrLength));
247 return Vec3<T>( mm[0]*invLength, mm[1]*invLength, mm[2]*invLength );
258 mm[0] = x; mm[1] = y; mm[2] = z; mm[3] = w;
270 T s = T(sin(
angle*T(0.5)));
272 mm[0] = axis.
x() * s;
273 mm[1] = axis.
y() * s;
274 mm[2] = axis.
z() * s;
276 mm[3] = T(cos(
angle*T(0.5)));
284 mm[0] = mm[1] = mm[2] = mm[3] = 0;
291 mm[0] = mm[1] = mm[2] = 0;
298 {
return math::eulerAngles(
Mat3<T>(*
this), rotationOrder); }
310 bool eq(
const Quat &q, T eps=1.0e-7)
const
352 return Quat<T>(mm[0]+q.
mm[0], mm[1]+q.
mm[1], mm[2]+q.
mm[2], mm[3]+q.
mm[3]);
358 return Quat<T>(mm[0]-q.
mm[0], mm[1]-q.
mm[1], mm[2]-q.
mm[2], mm[3]-q.
mm[3]);
366 prod.
mm[0] = mm[3]*q.
mm[0] + mm[0]*q.
mm[3] + mm[1]*q.
mm[2] - mm[2]*q.
mm[1];
367 prod.
mm[1] = mm[3]*q.
mm[1] + mm[1]*q.
mm[3] + mm[2]*q.
mm[0] - mm[0]*q.
mm[2];
368 prod.
mm[2] = mm[3]*q.
mm[2] + mm[2]*q.
mm[3] + mm[0]*q.
mm[1] - mm[1]*q.
mm[0];
369 prod.
mm[3] = mm[3]*q.
mm[3] - mm[0]*q.
mm[0] - mm[1]*q.
mm[1] - mm[2]*q.
mm[2];
385 return Quat<T>(mm[0]*scalar, mm[1]*scalar, mm[2]*scalar, mm[3]*scalar);
391 return Quat<T>(mm[0]/scalar, mm[1]/scalar, mm[2]/scalar, mm[3]/scalar);
396 {
return Quat<T>(-mm[0], -mm[1], -mm[2], -mm[3]); }
402 mm[0] = q1.
mm[0] + q2.
mm[0];
403 mm[1] = q1.
mm[1] + q2.
mm[1];
404 mm[2] = q1.
mm[2] + q2.
mm[2];
405 mm[3] = q1.
mm[3] + q2.
mm[3];
414 mm[0] = q1.
mm[0] - q2.
mm[0];
415 mm[1] = q1.
mm[1] - q2.
mm[1];
416 mm[2] = q1.
mm[2] - q2.
mm[2];
417 mm[3] = q1.
mm[3] - q2.
mm[3];
426 mm[0] = q1.
mm[3]*q2.
mm[0] + q1.
mm[0]*q2.
mm[3] +
427 q1.
mm[1]*q2.
mm[2] - q1.
mm[2]*q2.
mm[1];
428 mm[1] = q1.
mm[3]*q2.
mm[1] + q1.
mm[1]*q2.
mm[3] +
429 q1.
mm[2]*q2.
mm[0] - q1.
mm[0]*q2.
mm[2];
430 mm[2] = q1.
mm[3]*q2.
mm[2] + q1.
mm[2]*q2.
mm[3] +
431 q1.
mm[0]*q2.
mm[1] - q1.
mm[1]*q2.
mm[0];
432 mm[3] = q1.
mm[3]*q2.
mm[3] - q1.
mm[0]*q2.
mm[0] -
433 q1.
mm[1]*q2.
mm[1] - q1.
mm[2]*q2.
mm[2];
453 return (mm[0]*q.
mm[0] + mm[1]*q.
mm[1] + mm[2]*q.
mm[2] + mm[3]*q.
mm[3]);
460 return Quat<T>( +w()*omega.
x() -z()*omega.
y() +y()*omega.
z() ,
461 +z()*omega.
x() +w()*omega.
y() -x()*omega.
z() ,
462 -y()*omega.
x() +x()*omega.
y() +w()*omega.
z() ,
463 -x()*omega.
x() -y()*omega.
y() -z()*omega.
z() );
469 T d = T(sqrt(mm[0]*mm[0] + mm[1]*mm[1] + mm[2]*mm[2] + mm[3]*mm[3]));
478 T d = sqrt(mm[0]*mm[0] + mm[1]*mm[1] + mm[2]*mm[2] + mm[3]*mm[3]);
481 "Normalizing degenerate quaternion");
488 T d = mm[0]*mm[0] + mm[1]*mm[1] + mm[2]*mm[2] + mm[3]*mm[3];
491 "Cannot invert degenerate quaternion");
492 Quat result = *
this/-d;
493 result.
mm[3] = -result.
mm[3];
502 return Quat<T>(-mm[0], -mm[1], -mm[2], mm[3]);
519 std::ostringstream buffer;
524 for (
unsigned j(0); j < 4; j++) {
525 if (j) buffer <<
", ";
543 void write(std::ostream& os)
const { os.write(
static_cast<char*
>(&mm),
sizeof(T) * 4); }
544 void read(std::istream& is) { is.read(
static_cast<char*
>(&mm),
sizeof(T) * 4); }
551template <
typename S,
typename T>
558template <
typename T,
typename T0>
566 if (q1.
dot(q2) < 0) q2 *= -1;
568 Quat<T> qslerp = slerp<T>(q1, q2,
static_cast<T
>(t));
569 MatType m = rotation<MatType>(qslerp);
583template <
typename T,
typename T0>
588 Mat3<T> m00, m01, m02, m10, m11;
590 m00 =
slerp(m1, m2, t);
591 m01 =
slerp(m2, m3, t);
592 m02 =
slerp(m3, m4, t);
594 m10 =
slerp(m00, m01, t);
595 m11 =
slerp(m01, m02, t);
597 return slerp(m10, m11, t);
609template<>
inline math::Quats zeroVal<math::Quats >() {
return math::Quats::zero(); }
610template<>
inline math::Quatd zeroVal<math::Quatd >() {
return math::Quatd::zero(); }
General-purpose arithmetic and comparison routines, most of which accept arbitrary value types (or at...
#define OPENVDB_IS_POD(Type)
Definition Math.h:56
Definition Exceptions.h:56
3x3 matrix class.
Definition Vec4.h:21
T trace() const
Trace of matrix.
Definition Mat3.h:488
T det() const
Determinant of matrix.
Definition Mat3.h:479
Vec3< T0 > transform(const Vec3< T0 > &v) const
Definition Mat3.h:505
T angle() const
Return angle of rotation.
Definition Quat.h:224
T & x()
Reference to the component, e.g. q.x() = 4.5f;.
Definition Quat.h:193
Quat & sub(const Quat &q1, const Quat &q2)
Definition Quat.h:412
Quat conjugate() const
Definition Quat.h:500
Vec3< T > axis() const
Return axis of rotation.
Definition Quat.h:239
Quat operator/(T scalar) const
Return (this/scalar), e.g. q = q1 / scalar;.
Definition Quat.h:389
Quat & operator*=(T scalar)
Scale "this" quaternion by scalar, e.g. q *= scalar;.
Definition Quat.h:339
Quat & setAxisAngle(const Vec3< T > &axis, T angle)
Definition Quat.h:267
Quat unit() const
this = normalized this
Definition Quat.h:476
void write(std::ostream &os) const
Definition Quat.h:543
Quat operator*(const Quat &q) const
Return (this*q), e.g. q = q1 * q2;.
Definition Quat.h:362
bool operator==(const Quat &q) const
Equality operator, does exact floating point comparisons.
Definition Quat.h:301
Quat(T *a)
Constructor with array argument, e.g. float a[4]; Quatf q(a);.
Definition Quat.h:101
Quat & add(const Quat &q1, const Quat &q2)
Definition Quat.h:400
friend std::ostream & operator<<(std::ostream &stream, const Quat &q)
Output to the stream, e.g. std::cout << q << std::endl;.
Definition Quat.h:535
T w() const
Definition Quat.h:202
Quat(math::Axis axis, T angle)
Constructor given rotation as axis and angle.
Definition Quat.h:127
Quat & operator+=(const Quat &q)
Add quaternion q to "this" quaternion, e.g. q += q1;.
Definition Quat.h:317
Quat operator-() const
Negation operator, e.g. q = -q;.
Definition Quat.h:395
T & operator()(int i)
Alternative indexed reference to the elements.
Definition Quat.h:218
T & y()
Definition Quat.h:194
T & z()
Definition Quat.h:195
Quat(const Vec3< T > &axis, T angle)
Definition Quat.h:112
Quat & scale(T scale, const Quat &q)
Definition Quat.h:440
T operator()(int i) const
Alternative indexed constant reference to the elements,.
Definition Quat.h:221
Quat(const Mat3< T1 > &rot)
Constructor given a rotation matrix.
Definition Quat.h:140
Quat & setIdentity()
Set "this" vector to identity.
Definition Quat.h:289
Quat operator+(const Quat &q) const
Return (this+q), e.g. q = q1 + q2;.
Definition Quat.h:350
Quat & init()
"this" quaternion gets initialized to identity, same as setIdentity()
Definition Quat.h:263
Quat operator*=(const Quat &q)
Assigns this to (this*q), e.g. q *= q1;.
Definition Quat.h:376
Quat(T x, T y, T z, T w)
Constructor with four arguments, e.g. Quatf q(1,2,3,4);.
Definition Quat.h:91
Vec3< T > rotateVector(const Vec3< T > &v) const
Return rotated vector by "this" quaternion.
Definition Quat.h:506
T x() const
Get the component, e.g. float f = q.w();.
Definition Quat.h:199
bool normalize(T eps=T(1.0e-8))
this = normalized this
Definition Quat.h:467
static Quat identity()
Definition Quat.h:514
Quat & init(T x, T y, T z, T w)
"this" quaternion gets initialized to [x, y, z, w]
Definition Quat.h:256
T z() const
Definition Quat.h:201
T y() const
Definition Quat.h:200
Vec3< T > eulerAngles(RotationOrder rotationOrder) const
Returns vector of x,y,z rotational components.
Definition Quat.h:297
T operator[](int i) const
Array style constant reference to the components, e.g. float f = q[1];.
Definition Quat.h:211
static unsigned numElements()
Definition Quat.h:205
Quat derivative(const Vec3< T > &omega) const
Definition Quat.h:458
T & operator[](int i)
Array style reference to the components, e.g. q[3] = 1.34f;.
Definition Quat.h:208
Quat operator*(T scalar) const
Return (this*scalar), e.g. q = q1 * scalar;.
Definition Quat.h:383
T mm[4]
Definition Quat.h:547
std::string str() const
Definition Quat.h:517
Quat & operator-=(const Quat &q)
Subtract quaternion q from "this" quaternion, e.g. q -= q1;.
Definition Quat.h:328
T ValueType
Definition Quat.h:82
Quat & mult(const Quat &q1, const Quat &q2)
Definition Quat.h:424
static Quat zero()
Predefined constants, e.g. Quat q = Quat::identity();.
Definition Quat.h:513
Quat inverse(T tolerance=T(0)) const
returns inverse of this
Definition Quat.h:486
bool eq(const Quat &q, T eps=1.0e-7) const
Test if "this" is equivalent to q with tolerance of eps value.
Definition Quat.h:310
Quat & setZero()
Set "this" vector to zero.
Definition Quat.h:282
Quat operator-(const Quat &q) const
Return (this-q), e.g. q = q1 - q2;.
Definition Quat.h:356
T value_type
Definition Quat.h:81
T & w()
Definition Quat.h:196
void read(std::istream &is)
Definition Quat.h:544
T dot(const Quat &q) const
Dot product.
Definition Quat.h:451
T & x()
Reference to the component, e.g. v.x() = 4.5f;.
Definition Vec3.h:85
T & y()
Definition Vec3.h:86
T & z()
Definition Vec3.h:87
Mat3< typename promote< T0, T1 >::type > operator*(const Mat3< T0 > &m0, const Mat3< T1 > &m1)
Multiply m0 by m1 and return the resulting matrix.
Definition Mat3.h:597
bool isApproxEqual(const Type &a, const Type &b, const Type &tolerance)
Return true if a is equal to b to within the given tolerance.
Definition Math.h:406
MatType scale(const Vec3< typename MatType::value_type > &s)
Return a matrix that scales by s.
Definition Mat.h:615
bool isUnitary(const MatType &m)
Determine if a matrix is unitary (i.e., rotation or reflection).
Definition Mat.h:889
T angle(const Vec2< T > &v1, const Vec2< T > &v2)
Definition Vec2.h:446
bool isExactlyEqual(const T0 &a, const T1 &b)
Return true if a is exactly equal to b.
Definition Math.h:443
Axis
Definition Math.h:901
Mat3< T > bezLerp(const Mat3< T0 > &m1, const Mat3< T0 > &m2, const Mat3< T0 > &m3, const Mat3< T0 > &m4, T t)
Definition Quat.h:584
RotationOrder
Definition Math.h:908
Quat< T > slerp(const Quat< T > &q1, const Quat< T > &q2, T t, T tolerance=0.00001)
Linear interpolation between the two quaternions.
Definition Quat.h:27
Definition Exceptions.h:13
#define OPENVDB_THROW(exception, message)
Definition Exceptions.h:74
#define OPENVDB_VERSION_NAME
The version namespace name for this library version.
Definition version.h.in:121
#define OPENVDB_USE_VERSION_NAMESPACE
Definition version.h.in:212