inv
Computes the inverse of a given real matrix. In general, you should avoid using this metho in combination with *. Instead, wherever you might want to write inv(A) * B, you should write A \ B.
Type members
Inherited types
Value members
Inherited methods
final def apply[V1, @specialized(Int, Double, Float) V2, @specialized(Int, Double, Float) V3, @specialized(Int, Double, Float) VR](v1: V1, v2: V2, v3: V3)(implicit impl: Impl3[V1, V2, V3, VR]): VR
- Inherited from:
- UFunc
final def apply[@specialized(Int, Double, Float) V1, @specialized(Int, Double, Float) V2, @specialized(Int, Double, Float) VR](v1: V1, v2: V2)(implicit impl: Impl2[V1, V2, VR]): VR
- Inherited from:
- UFunc
final def apply[@specialized(Int, Double, Float) V, @specialized(Int, Double, Float) VR](v: V)(implicit impl: Impl[V, VR]): VR
- Inherited from:
- UFunc
final def inPlace[V, V2, V3](v: V, v2: V2, v3: V3)(implicit impl: InPlaceImpl3[inv.type, V, V2, V3]): V
- Inherited from:
- UFunc
Implicits
Implicits
implicit def canInvUsingLU_Double[T](implicit luImpl: Impl[T, (DenseMatrix[Double], Array[Int])]): Impl[T, DenseMatrix[Double]]
implicit def canInvUsingLU_Float[T](implicit luImpl: Impl[T, (DenseMatrix[Float], Array[Int])]): Impl[T, DenseMatrix[Float]]