Type Alias nalgebra::base::SquareMatrix
source · pub type SquareMatrix<T, D, S> = Matrix<T, D, D, S>;
Expand description
A square matrix.
Aliased Type§
struct SquareMatrix<T, D, S> {
pub data: S,
/* private fields */
}
Fields§
§data: S
The data storage that contains all the matrix components. Disappointed?
Well, if you came here to see how you can access the matrix components,
you may be in luck: you can access the individual components of all vectors with compile-time
dimensions <= 6 using field notation like this:
vec.x
, vec.y
, vec.z
, vec.w
, vec.a
, vec.b
. Reference and assignation work too:
let mut vec = Vector3::new(1.0, 2.0, 3.0);
vec.x = 10.0;
vec.y += 30.0;
assert_eq!(vec.x, 10.0);
assert_eq!(vec.y + 100.0, 132.0);
Similarly, for matrices with compile-time dimensions <= 6, you can use field notation
like this: mat.m11
, mat.m42
, etc. The first digit identifies the row to address
and the second digit identifies the column to address. So mat.m13
identifies the component
at the first row and third column (note that the count of rows and columns start at 1 instead
of 0 here. This is so we match the mathematical notation).
For all matrices and vectors, independently from their size, individual components can
be accessed and modified using indexing: vec[20]
, mat[(20, 19)]
. Here the indexing
starts at 0 as you would expect.
Implementations§
source§impl<T, D1: Dim, S: StorageMut<T, D1, D1>> SquareMatrix<T, D1, S>
impl<T, D1: Dim, S: StorageMut<T, D1, D1>> SquareMatrix<T, D1, S>
sourcepub fn quadform_tr_with_workspace<D2, S2, R3, C3, S3, D4, S4>(
&mut self,
work: &mut Vector<T, D2, S2>,
alpha: T,
lhs: &Matrix<T, R3, C3, S3>,
mid: &SquareMatrix<T, D4, S4>,
beta: T
)
pub fn quadform_tr_with_workspace<D2, S2, R3, C3, S3, D4, S4>( &mut self, work: &mut Vector<T, D2, S2>, alpha: T, lhs: &Matrix<T, R3, C3, S3>, mid: &SquareMatrix<T, D4, S4>, beta: T )
Computes the quadratic form self = alpha * lhs * mid * lhs.transpose() + beta * self
.
This uses the provided workspace work
to avoid allocations for intermediate results.
§Example
// Note that all those would also work with statically-sized matrices.
// We use DMatrix/DVector since that's the only case where pre-allocating the
// workspace is actually useful (assuming the same workspace is re-used for
// several computations) because it avoids repeated dynamic allocations.
let mut mat = DMatrix::identity(2, 2);
let lhs = DMatrix::from_row_slice(2, 3, &[1.0, 2.0, 3.0,
4.0, 5.0, 6.0]);
let mid = DMatrix::from_row_slice(3, 3, &[0.1, 0.2, 0.3,
0.5, 0.6, 0.7,
0.9, 1.0, 1.1]);
// The random shows that values on the workspace do not
// matter as they will be overwritten.
let mut workspace = DVector::new_random(2);
let expected = &lhs * &mid * lhs.transpose() * 10.0 + &mat * 5.0;
mat.quadform_tr_with_workspace(&mut workspace, 10.0, &lhs, &mid, 5.0);
assert_relative_eq!(mat, expected);
sourcepub fn quadform_tr<R3, C3, S3, D4, S4>(
&mut self,
alpha: T,
lhs: &Matrix<T, R3, C3, S3>,
mid: &SquareMatrix<T, D4, S4>,
beta: T
)
pub fn quadform_tr<R3, C3, S3, D4, S4>( &mut self, alpha: T, lhs: &Matrix<T, R3, C3, S3>, mid: &SquareMatrix<T, D4, S4>, beta: T )
Computes the quadratic form self = alpha * lhs * mid * lhs.transpose() + beta * self
.
This allocates a workspace vector of dimension D1 for intermediate results.
If D1
is a type-level integer, then the allocation is performed on the stack.
Use .quadform_tr_with_workspace(...)
instead to avoid allocations.
§Example
let mut mat = Matrix2::identity();
let lhs = Matrix2x3::new(1.0, 2.0, 3.0,
4.0, 5.0, 6.0);
let mid = Matrix3::new(0.1, 0.2, 0.3,
0.5, 0.6, 0.7,
0.9, 1.0, 1.1);
let expected = lhs * mid * lhs.transpose() * 10.0 + mat * 5.0;
mat.quadform_tr(10.0, &lhs, &mid, 5.0);
assert_relative_eq!(mat, expected);
sourcepub fn quadform_with_workspace<D2, S2, D3, S3, R4, C4, S4>(
&mut self,
work: &mut Vector<T, D2, S2>,
alpha: T,
mid: &SquareMatrix<T, D3, S3>,
rhs: &Matrix<T, R4, C4, S4>,
beta: T
)where
D2: Dim,
D3: Dim,
R4: Dim,
C4: Dim,
S2: StorageMut<T, D2>,
S3: Storage<T, D3, D3>,
S4: Storage<T, R4, C4>,
ShapeConstraint: DimEq<D3, R4> + DimEq<D1, C4> + DimEq<D2, D3> + AreMultipliable<C4, R4, D2, U1>,
pub fn quadform_with_workspace<D2, S2, D3, S3, R4, C4, S4>(
&mut self,
work: &mut Vector<T, D2, S2>,
alpha: T,
mid: &SquareMatrix<T, D3, S3>,
rhs: &Matrix<T, R4, C4, S4>,
beta: T
)where
D2: Dim,
D3: Dim,
R4: Dim,
C4: Dim,
S2: StorageMut<T, D2>,
S3: Storage<T, D3, D3>,
S4: Storage<T, R4, C4>,
ShapeConstraint: DimEq<D3, R4> + DimEq<D1, C4> + DimEq<D2, D3> + AreMultipliable<C4, R4, D2, U1>,
Computes the quadratic form self = alpha * rhs.transpose() * mid * rhs + beta * self
.
This uses the provided workspace work
to avoid allocations for intermediate results.
§Example
// Note that all those would also work with statically-sized matrices.
// We use DMatrix/DVector since that's the only case where pre-allocating the
// workspace is actually useful (assuming the same workspace is re-used for
// several computations) because it avoids repeated dynamic allocations.
let mut mat = DMatrix::identity(2, 2);
let rhs = DMatrix::from_row_slice(3, 2, &[1.0, 2.0,
3.0, 4.0,
5.0, 6.0]);
let mid = DMatrix::from_row_slice(3, 3, &[0.1, 0.2, 0.3,
0.5, 0.6, 0.7,
0.9, 1.0, 1.1]);
// The random shows that values on the workspace do not
// matter as they will be overwritten.
let mut workspace = DVector::new_random(3);
let expected = rhs.transpose() * &mid * &rhs * 10.0 + &mat * 5.0;
mat.quadform_with_workspace(&mut workspace, 10.0, &mid, &rhs, 5.0);
assert_relative_eq!(mat, expected);
sourcepub fn quadform<D2, S2, R3, C3, S3>(
&mut self,
alpha: T,
mid: &SquareMatrix<T, D2, S2>,
rhs: &Matrix<T, R3, C3, S3>,
beta: T
)where
D2: Dim,
R3: Dim,
C3: Dim,
S2: Storage<T, D2, D2>,
S3: Storage<T, R3, C3>,
ShapeConstraint: DimEq<D2, R3> + DimEq<D1, C3> + AreMultipliable<C3, R3, D2, U1>,
DefaultAllocator: Allocator<T, D2>,
pub fn quadform<D2, S2, R3, C3, S3>(
&mut self,
alpha: T,
mid: &SquareMatrix<T, D2, S2>,
rhs: &Matrix<T, R3, C3, S3>,
beta: T
)where
D2: Dim,
R3: Dim,
C3: Dim,
S2: Storage<T, D2, D2>,
S3: Storage<T, R3, C3>,
ShapeConstraint: DimEq<D2, R3> + DimEq<D1, C3> + AreMultipliable<C3, R3, D2, U1>,
DefaultAllocator: Allocator<T, D2>,
Computes the quadratic form self = alpha * rhs.transpose() * mid * rhs + beta * self
.
This allocates a workspace vector of dimension D2 for intermediate results.
If D2
is a type-level integer, then the allocation is performed on the stack.
Use .quadform_with_workspace(...)
instead to avoid allocations.
§Example
let mut mat = Matrix2::identity();
let rhs = Matrix3x2::new(1.0, 2.0,
3.0, 4.0,
5.0, 6.0);
let mid = Matrix3::new(0.1, 0.2, 0.3,
0.5, 0.6, 0.7,
0.9, 1.0, 1.1);
let expected = rhs.transpose() * mid * rhs * 10.0 + mat * 5.0;
mat.quadform(10.0, &mid, &rhs, 5.0);
assert_relative_eq!(mat, expected);
source§impl<T: Scalar + Zero + One + ClosedMul + ClosedAdd, D: DimName, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: Scalar + Zero + One + ClosedMul + ClosedAdd, D: DimName, S: Storage<T, D, D>> SquareMatrix<T, D, S>
§Append/prepend translation and scaling
sourcepub fn append_scaling(&self, scaling: T) -> OMatrix<T, D, D>
pub fn append_scaling(&self, scaling: T) -> OMatrix<T, D, D>
Computes the transformation equal to self
followed by an uniform scaling factor.
sourcepub fn prepend_scaling(&self, scaling: T) -> OMatrix<T, D, D>
pub fn prepend_scaling(&self, scaling: T) -> OMatrix<T, D, D>
Computes the transformation equal to an uniform scaling factor followed by self
.
sourcepub fn append_nonuniform_scaling<SB>(
&self,
scaling: &Vector<T, DimNameDiff<D, U1>, SB>
) -> OMatrix<T, D, D>
pub fn append_nonuniform_scaling<SB>( &self, scaling: &Vector<T, DimNameDiff<D, U1>, SB> ) -> OMatrix<T, D, D>
Computes the transformation equal to self
followed by a non-uniform scaling factor.
sourcepub fn prepend_nonuniform_scaling<SB>(
&self,
scaling: &Vector<T, DimNameDiff<D, U1>, SB>
) -> OMatrix<T, D, D>
pub fn prepend_nonuniform_scaling<SB>( &self, scaling: &Vector<T, DimNameDiff<D, U1>, SB> ) -> OMatrix<T, D, D>
Computes the transformation equal to a non-uniform scaling factor followed by self
.
sourcepub fn append_translation<SB>(
&self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
) -> OMatrix<T, D, D>
pub fn append_translation<SB>( &self, shift: &Vector<T, DimNameDiff<D, U1>, SB> ) -> OMatrix<T, D, D>
Computes the transformation equal to self
followed by a translation.
sourcepub fn prepend_translation<SB>(
&self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
) -> OMatrix<T, D, D>where
D: DimNameSub<U1>,
SB: Storage<T, DimNameDiff<D, U1>>,
DefaultAllocator: Allocator<T, D, D> + Allocator<T, DimNameDiff<D, U1>>,
pub fn prepend_translation<SB>(
&self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
) -> OMatrix<T, D, D>where
D: DimNameSub<U1>,
SB: Storage<T, DimNameDiff<D, U1>>,
DefaultAllocator: Allocator<T, D, D> + Allocator<T, DimNameDiff<D, U1>>,
Computes the transformation equal to a translation followed by self
.
sourcepub fn append_scaling_mut(&mut self, scaling: T)
pub fn append_scaling_mut(&mut self, scaling: T)
Computes in-place the transformation equal to self
followed by an uniform scaling factor.
sourcepub fn prepend_scaling_mut(&mut self, scaling: T)
pub fn prepend_scaling_mut(&mut self, scaling: T)
Computes in-place the transformation equal to an uniform scaling factor followed by self
.
sourcepub fn append_nonuniform_scaling_mut<SB>(
&mut self,
scaling: &Vector<T, DimNameDiff<D, U1>, SB>
)
pub fn append_nonuniform_scaling_mut<SB>( &mut self, scaling: &Vector<T, DimNameDiff<D, U1>, SB> )
Computes in-place the transformation equal to self
followed by a non-uniform scaling factor.
sourcepub fn prepend_nonuniform_scaling_mut<SB>(
&mut self,
scaling: &Vector<T, DimNameDiff<D, U1>, SB>
)
pub fn prepend_nonuniform_scaling_mut<SB>( &mut self, scaling: &Vector<T, DimNameDiff<D, U1>, SB> )
Computes in-place the transformation equal to a non-uniform scaling factor followed by self
.
sourcepub fn append_translation_mut<SB>(
&mut self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
)
pub fn append_translation_mut<SB>( &mut self, shift: &Vector<T, DimNameDiff<D, U1>, SB> )
Computes the transformation equal to self
followed by a translation.
sourcepub fn prepend_translation_mut<SB>(
&mut self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
)where
D: DimNameSub<U1>,
S: StorageMut<T, D, D>,
SB: Storage<T, DimNameDiff<D, U1>>,
DefaultAllocator: Allocator<T, DimNameDiff<D, U1>>,
pub fn prepend_translation_mut<SB>(
&mut self,
shift: &Vector<T, DimNameDiff<D, U1>, SB>
)where
D: DimNameSub<U1>,
S: StorageMut<T, D, D>,
SB: Storage<T, DimNameDiff<D, U1>>,
DefaultAllocator: Allocator<T, DimNameDiff<D, U1>>,
Computes the transformation equal to a translation followed by self
.
source§impl<T: RealField, D: DimNameSub<U1>, S: Storage<T, D, D>> SquareMatrix<T, D, S>where
DefaultAllocator: Allocator<T, D, D> + Allocator<T, DimNameDiff<D, U1>> + Allocator<T, DimNameDiff<D, U1>, DimNameDiff<D, U1>>,
impl<T: RealField, D: DimNameSub<U1>, S: Storage<T, D, D>> SquareMatrix<T, D, S>where
DefaultAllocator: Allocator<T, D, D> + Allocator<T, DimNameDiff<D, U1>> + Allocator<T, DimNameDiff<D, U1>, DimNameDiff<D, U1>>,
§Transformation of vectors and points
sourcepub fn transform_vector(
&self,
v: &OVector<T, DimNameDiff<D, U1>>
) -> OVector<T, DimNameDiff<D, U1>>
pub fn transform_vector( &self, v: &OVector<T, DimNameDiff<D, U1>> ) -> OVector<T, DimNameDiff<D, U1>>
Transforms the given vector, assuming the matrix self
uses homogeneous coordinates.
source§impl<T: RealField, S: Storage<T, Const<3>, Const<3>>> SquareMatrix<T, Const<3>, S>
impl<T: RealField, S: Storage<T, Const<3>, Const<3>>> SquareMatrix<T, Const<3>, S>
sourcepub fn transform_point(&self, pt: &Point<T, 2>) -> Point<T, 2>
pub fn transform_point(&self, pt: &Point<T, 2>) -> Point<T, 2>
Transforms the given point, assuming the matrix self
uses homogeneous coordinates.
source§impl<T: RealField, S: Storage<T, Const<4>, Const<4>>> SquareMatrix<T, Const<4>, S>
impl<T: RealField, S: Storage<T, Const<4>, Const<4>>> SquareMatrix<T, Const<4>, S>
sourcepub fn transform_point(&self, pt: &Point<T, 3>) -> Point<T, 3>
pub fn transform_point(&self, pt: &Point<T, 3>) -> Point<T, 3>
Transforms the given point, assuming the matrix self
uses homogeneous coordinates.
source§impl<T: Scalar, D: Dim, S: RawStorage<T, D, D>> SquareMatrix<T, D, S>
impl<T: Scalar, D: Dim, S: RawStorage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn diagonal(&self) -> OVector<T, D>where
DefaultAllocator: Allocator<T, D>,
pub fn diagonal(&self) -> OVector<T, D>where
DefaultAllocator: Allocator<T, D>,
The diagonal of this matrix.
sourcepub fn map_diagonal<T2: Scalar>(&self, f: impl FnMut(T) -> T2) -> OVector<T2, D>where
DefaultAllocator: Allocator<T2, D>,
pub fn map_diagonal<T2: Scalar>(&self, f: impl FnMut(T) -> T2) -> OVector<T2, D>where
DefaultAllocator: Allocator<T2, D>,
Apply the given function to this matrix’s diagonal and returns it.
This is a more efficient version of self.diagonal().map(f)
since this
allocates only once.
source§impl<T: SimdComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: SimdComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn symmetric_part(&self) -> OMatrix<T, D, D>where
DefaultAllocator: Allocator<T, D, D>,
pub fn symmetric_part(&self) -> OMatrix<T, D, D>where
DefaultAllocator: Allocator<T, D, D>,
The symmetric part of self
, i.e., 0.5 * (self + self.transpose())
.
sourcepub fn hermitian_part(&self) -> OMatrix<T, D, D>where
DefaultAllocator: Allocator<T, D, D>,
pub fn hermitian_part(&self) -> OMatrix<T, D, D>where
DefaultAllocator: Allocator<T, D, D>,
The hermitian part of self
, i.e., 0.5 * (self + self.adjoint())
.
source§impl<T: RealField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>where
DefaultAllocator: Allocator<T, D, D>,
impl<T: RealField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>where
DefaultAllocator: Allocator<T, D, D>,
sourcepub fn is_special_orthogonal(&self, eps: T) -> bool
pub fn is_special_orthogonal(&self, eps: T) -> bool
Checks that this matrix is orthogonal and has a determinant equal to 1.
sourcepub fn is_invertible(&self) -> bool
pub fn is_invertible(&self) -> bool
Returns true
if this matrix is invertible.
source§impl<T: ComplexField, D: DimMin<D, Output = D>, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D: DimMin<D, Output = D>, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn determinant(&self) -> T
pub fn determinant(&self) -> T
Computes the matrix determinant.
If the matrix has a dimension larger than 3, an LU decomposition is used.
source§impl<T: ComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn try_inverse(self) -> Option<OMatrix<T, D, D>>where
DefaultAllocator: Allocator<T, D, D>,
pub fn try_inverse(self) -> Option<OMatrix<T, D, D>>where
DefaultAllocator: Allocator<T, D, D>,
source§impl<T: ComplexField, D: Dim, S: StorageMut<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D: Dim, S: StorageMut<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn try_inverse_mut(&mut self) -> boolwhere
DefaultAllocator: Allocator<T, D, D>,
pub fn try_inverse_mut(&mut self) -> boolwhere
DefaultAllocator: Allocator<T, D, D>,
Attempts to invert this square matrix in-place. Returns false
and leaves self
untouched if
inversion fails.
§Panics
Panics if self
isn’t a square matrix.
source§impl<T: ComplexField, D, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn eigenvalues(&self) -> Option<OVector<T, D>>
pub fn eigenvalues(&self) -> Option<OVector<T, D>>
Computes the eigenvalues of this matrix.
sourcepub fn complex_eigenvalues(&self) -> OVector<NumComplex<T>, D>
pub fn complex_eigenvalues(&self) -> OVector<NumComplex<T>, D>
Computes the eigenvalues of this matrix.
source§impl<T: ComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
) -> bool
pub fn solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> ) -> bool
Solves the linear system self . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_lower_triangular_with_diag_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>,
diag: T
) -> bool
pub fn solve_lower_triangular_with_diag_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2>, diag: T ) -> bool
Solves the linear system self . x = b
where x
is the unknown and only the
lower-triangular part of self
is considered not-zero. The diagonal is never read as it is
assumed to be equal to diag
. Returns false
and does not modify its inputs if diag
is zero.
sourcepub fn solve_upper_triangular_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
) -> bool
pub fn solve_upper_triangular_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> ) -> bool
Solves the linear system self . x = b
where x
is the unknown and only the
upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn tr_solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.transpose() . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn tr_solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.transpose() . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
) -> bool
pub fn tr_solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> ) -> bool
Solves the linear system self.transpose() . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_upper_triangular_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
) -> bool
pub fn tr_solve_upper_triangular_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> ) -> bool
Solves the linear system self.transpose() . x = b
where x
is the unknown and only the
upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn ad_solve_lower_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.adjoint() . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn ad_solve_upper_triangular<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> Option<OMatrix<T, R2, C2>>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.adjoint() . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
) -> bool
pub fn ad_solve_lower_triangular_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> ) -> bool
Solves the linear system self.adjoint() . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
source§impl<T: SimdComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: SimdComplexField, D: Dim, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn solve_lower_triangular_with_diag_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>,
diag: T
)
pub fn solve_lower_triangular_with_diag_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2>, diag: T )
Solves the linear system self . x = b
where x
is the unknown and only the
lower-triangular part of self
is considered not-zero. The diagonal is never read as it is
assumed to be equal to diag
. Returns false
and does not modify its inputs if diag
is zero.
sourcepub fn solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self . x = b
where x
is the unknown and only the
upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn tr_solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.transpose() . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn tr_solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.transpose() . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn tr_solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self.transpose() . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn tr_solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn tr_solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self.transpose() . x = b
where x
is the unknown and only the
upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn ad_solve_lower_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.adjoint() . x = b
where x
is the unknown and only
the lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
pub fn ad_solve_upper_triangular_unchecked<R2: Dim, C2: Dim, S2>(
&self,
b: &Matrix<T, R2, C2, S2>
) -> OMatrix<T, R2, C2>where
S2: Storage<T, R2, C2>,
DefaultAllocator: Allocator<T, R2, C2>,
ShapeConstraint: SameNumberOfRows<R2, D>,
Computes the solution of the linear system self.adjoint() . x = b
where x
is the unknown and only
the upper-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn ad_solve_lower_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self.adjoint() . x = b
where x
is the unknown and only the
lower-triangular part of self
(including the diagonal) is considered not-zero.
sourcepub fn ad_solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>(
&self,
b: &mut Matrix<T, R2, C2, S2>
)
pub fn ad_solve_upper_triangular_unchecked_mut<R2: Dim, C2: Dim, S2>( &self, b: &mut Matrix<T, R2, C2, S2> )
Solves the linear system self.adjoint() . x = b
where x
is the unknown and only the
upper-triangular part of self
(including the diagonal) is considered not-zero.
source§impl<T: ComplexField, D: DimSub<U1>, S: Storage<T, D, D>> SquareMatrix<T, D, S>
impl<T: ComplexField, D: DimSub<U1>, S: Storage<T, D, D>> SquareMatrix<T, D, S>
sourcepub fn symmetric_eigenvalues(&self) -> OVector<T::RealField, D>
pub fn symmetric_eigenvalues(&self) -> OVector<T::RealField, D>
Computes the eigenvalues of this symmetric matrix.
Only the lower-triangular part of the matrix is read.