 Quat[Class Summary] |
 x |
| y |
| z |
| w |
| identity[static][const] |
| nan[static][const] |
 ctor (+7 overloads) |
| WorldX()[const] |
| WorldY()[const] |
| WorldZ()[const] |
| Axis()[const] |
| Angle()[const] |
| Dot(rhs)[const] |
| LengthSq()[const] |
| Length()[const] |
| Normalize() |
| Normalized()[const] |
| IsNormalized(epsilon)[const] |
| IsInvertible(epsilon)[const] |
| IsFinite()[const] |
| Equals(rhs,epsilon)[const] |
| BitEquals(other)[const] |
| ptr() (+1 overload) |
| Inverse() |
| Inverted()[const] |
| InverseAndNormalize() |
| Conjugate() |
| Conjugated()[const] |
| Transform(x,y,z)[const] (+2 overloads) |
| Lerp(target,t)[const] |
| Slerp(target,t)[const] |
| AngleBetween(target)[const] |
| AxisFromTo(target)[const] |
| ToAxisAngle(...)[const] (+1 overload) |
| SetFromAxisAngle(...) (+1 overload) |
| Set(matrix) (+3 overloads) |
| ToEulerXYX()[const] |
| ToFloat3x3()[const] |
| ToFloat3x4()[const] |
| ToFloat4x4()[const] (+2 overloads) |
| ToString()[const] |
| ToString2()[const] |
| SerializeToString()[const] |
| SerializeToCodeString()[const] |
 operator*(rhs)[const] (+2 overloads) |
| operator/(rhs)[const] |
| operator+()[const] |
| Mul(rhs)[const] (+3 overloads) |
| Neg()[const] |
| Lerp(source,target,t)[static] |
| Slerp(source,target,t)[static] |
| SlerpVector(from,to,t)[static] |
| SlerpVectorAbs(...)[static] |
| LookAt(...)[static] |
| RotateX(angleRadians)[static] |
| RotateY(angleRadians)[static] |
| RotateZ(angleRadians)[static] |
| RotateAxisAngle(...)[static] |
| RotateFromTo(...)[static] (+2 overloads) |
| FromEuler***(x2,y,x)[static] |
| RandomRotation(lcg)[static] |
| FromString(str,outEndStr)[static] (+1 overload) |
Quat::Inverse
Syntax
void Quat::Inverse(); [6 lines of code]Inverses this quaternion in-place.
Note
For optimization purposes, this function assumes that the quaternion is unitary, in which case the inverse of the quaternion is simply just the same as its conjugate. This function does not detect whether the operation succeeded or failed.