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#[ cfg(feature = " serde-serialize " ) ]
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use serde ::{ Deserialize , Serialize } ;
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use num ::Zero ;
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use num_complex ::Complex ;
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use simba ::scalar ::RealField ;
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use crate ::ComplexHelper ;
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use na ::dimension ::{ Const , Dim } ;
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use na ::{ DefaultAllocator , Matrix , OMatrix , OVector , Scalar , allocator ::Allocator } ;
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use lapack ;
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/// Eigendecomposition of a real square matrix with real or complex eigenvalues.
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#[ cfg_attr(feature = " serde-serialize " , derive(Serialize, Deserialize)) ]
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#[ cfg_attr(
feature = " serde-serialize " ,
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serde (
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bound ( serialize = " DefaultAllocator: Allocator<T, D, D> + Allocator<T, D>,
OVector < T , D > : Serialize ,
OMatrix < T , D , D > : Serialize " )
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)
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) ]
#[ cfg_attr(
feature = " serde-serialize " ,
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serde (
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bound ( deserialize = " DefaultAllocator: Allocator<T, D, D> + Allocator<T, D>,
OVector < T , D > : Serialize ,
OMatrix < T , D , D > : Deserialize < ' de > " )
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)
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) ]
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#[ derive(Clone, Debug) ]
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pub struct Eigen < T : Scalar , D : Dim >
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where
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DefaultAllocator : Allocator < T , D > + Allocator < T , D , D > ,
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{
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/// The real parts of eigenvalues of the decomposed matrix.
pub eigenvalues_re : OVector < T , D > ,
/// The imaginary parts of the eigenvalues of the decomposed matrix.
pub eigenvalues_im : OVector < T , D > ,
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/// The (right) eigenvectors of the decomposed matrix.
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pub eigenvectors : Option < OMatrix < T , D , D > > ,
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/// The left eigenvectors of the decomposed matrix.
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pub left_eigenvectors : Option < OMatrix < T , D , D > > ,
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}
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impl < T : Scalar + Copy , D : Dim > Copy for Eigen < T , D >
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where
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DefaultAllocator : Allocator < T , D > + Allocator < T , D , D > ,
OVector < T , D > : Copy ,
OMatrix < T , D , D > : Copy ,
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{
}
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impl < T : EigenScalar + RealField , D : Dim > Eigen < T , D >
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where
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DefaultAllocator : Allocator < T , D , D > + Allocator < T , D > ,
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{
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/// Computes the eigenvalues and eigenvectors of the square matrix `m`.
///
/// If `eigenvectors` is `false` then, the eigenvectors are not computed explicitly.
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pub fn new (
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mut m : OMatrix < T , D , D > ,
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left_eigenvectors : bool ,
eigenvectors : bool ,
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) -> Option < Eigen < T , D > > {
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assert! (
m . is_square ( ) ,
" Unable to compute the eigenvalue decomposition of a non-square matrix. "
) ;
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let ljob = if left_eigenvectors { b 'V' } else { b 'N' } ;
let rjob = if eigenvectors { b 'V' } else { b 'N' } ;
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let ( nrows , ncols ) = m . shape_generic ( ) ;
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let n = nrows . value ( ) ;
let lda = n as i32 ;
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// TODO: avoid the initialization?
let mut wr = Matrix ::zeros_generic ( nrows , Const ::< 1 > ) ;
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// TODO: Tap into the workspace.
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let mut wi = Matrix ::zeros_generic ( nrows , Const ::< 1 > ) ;
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let mut info = 0 ;
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let mut placeholder1 = [ T ::zero ( ) ] ;
let mut placeholder2 = [ T ::zero ( ) ] ;
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let lwork = T ::xgeev_work_size (
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ljob ,
rjob ,
n as i32 ,
m . as_mut_slice ( ) ,
lda ,
wr . as_mut_slice ( ) ,
wi . as_mut_slice ( ) ,
& mut placeholder1 ,
n as i32 ,
& mut placeholder2 ,
n as i32 ,
& mut info ,
) ;
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lapack_check! ( info ) ;
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let mut work = vec! [ T ::zero ( ) ; lwork as usize ] ;
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let mut vl = if left_eigenvectors {
Some ( Matrix ::zeros_generic ( nrows , ncols ) )
} else {
None
} ;
let mut vr = if eigenvectors {
Some ( Matrix ::zeros_generic ( nrows , ncols ) )
} else {
None
} ;
let vl_ref = vl
. as_mut ( )
. map ( | m | m . as_mut_slice ( ) )
. unwrap_or ( & mut placeholder1 ) ;
let vr_ref = vr
. as_mut ( )
. map ( | m | m . as_mut_slice ( ) )
. unwrap_or ( & mut placeholder2 ) ;
T ::xgeev (
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ljob ,
rjob ,
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n as i32 ,
m . as_mut_slice ( ) ,
lda ,
wr . as_mut_slice ( ) ,
wi . as_mut_slice ( ) ,
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vl_ref ,
if left_eigenvectors { n as i32 } else { 1 } ,
vr_ref ,
if eigenvectors { n as i32 } else { 1 } ,
& mut work ,
lwork ,
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& mut info ,
) ;
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lapack_check! ( info ) ;
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Some ( Self {
eigenvalues_re : wr ,
eigenvalues_im : wi ,
left_eigenvectors : vl ,
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eigenvectors : vr
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} )
}
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/// Returns `true` if all the eigenvalues are real.
pub fn eigenvalues_are_real ( & self ) -> bool {
self . eigenvalues_im . iter ( ) . all ( | e | e . is_zero ( ) )
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}
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/// The determinant of the decomposed matrix.
#[ inline ]
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#[ must_use ]
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pub fn determinant ( & self ) -> Complex < T > {
let mut det : Complex < T > = na ::one ( ) ;
for ( re , im ) in self . eigenvalues_re . iter ( ) . zip ( self . eigenvalues_im . iter ( ) ) {
det * = Complex ::new ( re . clone ( ) , im . clone ( ) ) ;
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}
det
}
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/// Returns a tuple of vectors. The elements of the tuple are the complex eigenvalues, complex left eigenvectors and complex right eigenvectors respectively.
/// The elements appear as conjugate pairs within each vector, with the positive of the pair always being first.
pub fn get_complex_elements ( & self ) -> ( Option < Vec < Complex < T > > > , Option < Vec < OVector < Complex < T > , D > > > , Option < Vec < OVector < Complex < T > , D > > > ) where DefaultAllocator : Allocator < Complex < T > , D > {
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match self . eigenvalues_are_real ( ) {
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true = > ( None , None , None ) ,
false = > {
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let ( number_of_elements , _ ) = self . eigenvalues_re . shape_generic ( ) ;
let number_of_elements_value = number_of_elements . value ( ) ;
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let number_of_complex_entries = self . eigenvalues_im . iter ( ) . fold ( 0 , | acc , e | if ! e . is_zero ( ) { acc + 1 } else { acc } ) ;
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let mut eigenvalues = Vec ::< Complex < T > > ::with_capacity ( number_of_complex_entries ) ;
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let mut eigenvectors = match self . eigenvectors . is_some ( ) {
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true = > Some ( Vec ::< OVector < Complex < T > , D > > ::with_capacity ( number_of_complex_entries ) ) ,
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false = > None
} ;
let mut left_eigenvectors = match self . left_eigenvectors . is_some ( ) {
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true = > Some ( Vec ::< OVector < Complex < T > , D > > ::with_capacity ( number_of_complex_entries ) ) ,
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false = > None
} ;
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let mut c = 0 ;
while c < number_of_elements_value {
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if self . eigenvalues_im [ c ] ! = T ::zero ( ) {
//Complex conjugate pairs of eigenvalues appear consecutively with the eigenvalue having the positive imaginary part first.
eigenvalues . push ( Complex ::< T > ::new ( self . eigenvalues_re [ c ] . clone ( ) , self . eigenvalues_im [ c ] . clone ( ) ) ) ;
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eigenvalues . push ( Complex ::< T > ::new ( self . eigenvalues_re [ c + 1 ] . clone ( ) , self . eigenvalues_im [ c + 1 ] . clone ( ) ) ) ;
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if eigenvectors . is_some ( ) {
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let mut vec = OVector ::< Complex < T > , D > ::zeros_generic ( number_of_elements , Const ::< 1 > ) ;
let mut vec_conj = OVector ::< Complex < T > , D > ::zeros_generic ( number_of_elements , Const ::< 1 > ) ;
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for r in 0 .. number_of_elements_value {
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vec [ r ] = Complex ::< T > ::new ( ( & self . eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c ) ] . clone ( ) , ( & self . eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c + 1 ) ] . clone ( ) ) ;
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vec_conj [ r ] = Complex ::< T > ::new ( ( & self . eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c ) ] . clone ( ) , ( & self . eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c + 1 ) ] . clone ( ) ) ;
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}
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eigenvectors . as_mut ( ) . unwrap ( ) . push ( vec ) ;
eigenvectors . as_mut ( ) . unwrap ( ) . push ( vec_conj ) ;
}
if left_eigenvectors . is_some ( ) {
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let mut vec = OVector ::< Complex < T > , D > ::zeros_generic ( number_of_elements , Const ::< 1 > ) ;
let mut vec_conj = OVector ::< Complex < T > , D > ::zeros_generic ( number_of_elements , Const ::< 1 > ) ;
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for r in 0 .. number_of_elements_value {
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vec [ r ] = Complex ::< T > ::new ( ( & self . left_eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c ) ] . clone ( ) , ( & self . left_eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c + 1 ) ] . clone ( ) ) ;
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vec_conj [ r ] = Complex ::< T > ::new ( ( & self . left_eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c ) ] . clone ( ) , ( & self . left_eigenvectors . as_ref ( ) ) . unwrap ( ) [ ( r , c + 1 ) ] . clone ( ) ) ;
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}
left_eigenvectors . as_mut ( ) . unwrap ( ) . push ( vec ) ;
left_eigenvectors . as_mut ( ) . unwrap ( ) . push ( vec_conj ) ;
}
//skip next entry
c + = 1 ;
}
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c + = 1 ;
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}
( Some ( eigenvalues ) , left_eigenvectors , eigenvectors )
}
}
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}
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}
/*
*
* Lapack functions dispatch .
*
* /
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/// Trait implemented by scalar type for which Lapack function exist to compute the
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/// eigendecomposition.
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pub trait EigenScalar : Scalar {
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#[ allow(missing_docs) ]
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fn xgeev (
jobvl : u8 ,
jobvr : u8 ,
n : i32 ,
a : & mut [ Self ] ,
lda : i32 ,
wr : & mut [ Self ] ,
wi : & mut [ Self ] ,
vl : & mut [ Self ] ,
ldvl : i32 ,
vr : & mut [ Self ] ,
ldvr : i32 ,
work : & mut [ Self ] ,
lwork : i32 ,
info : & mut i32 ,
) ;
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#[ allow(missing_docs) ]
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fn xgeev_work_size (
jobvl : u8 ,
jobvr : u8 ,
n : i32 ,
a : & mut [ Self ] ,
lda : i32 ,
wr : & mut [ Self ] ,
wi : & mut [ Self ] ,
vl : & mut [ Self ] ,
ldvl : i32 ,
vr : & mut [ Self ] ,
ldvr : i32 ,
info : & mut i32 ,
) -> i32 ;
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}
macro_rules ! real_eigensystem_scalar_impl (
( $N : ty , $xgeev : path ) = > (
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impl EigenScalar for $N {
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#[ inline ]
fn xgeev ( jobvl : u8 , jobvr : u8 , n : i32 , a : & mut [ Self ] , lda : i32 ,
wr : & mut [ Self ] , wi : & mut [ Self ] ,
vl : & mut [ Self ] , ldvl : i32 , vr : & mut [ Self ] , ldvr : i32 ,
work : & mut [ Self ] , lwork : i32 , info : & mut i32 ) {
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unsafe { $xgeev ( jobvl , jobvr , n , a , lda , wr , wi , vl , ldvl , vr , ldvr , work , lwork , info ) }
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}
#[ inline ]
fn xgeev_work_size ( jobvl : u8 , jobvr : u8 , n : i32 , a : & mut [ Self ] , lda : i32 ,
wr : & mut [ Self ] , wi : & mut [ Self ] , vl : & mut [ Self ] , ldvl : i32 ,
vr : & mut [ Self ] , ldvr : i32 , info : & mut i32 ) -> i32 {
let mut work = [ Zero ::zero ( ) ] ;
let lwork = - 1 as i32 ;
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unsafe { $xgeev ( jobvl , jobvr , n , a , lda , wr , wi , vl , ldvl , vr , ldvr , & mut work , lwork , info ) } ;
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ComplexHelper ::real_part ( work [ 0 ] ) as i32
}
}
)
) ;
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real_eigensystem_scalar_impl! ( f32 , lapack ::sgeev ) ;
real_eigensystem_scalar_impl! ( f64 , lapack ::dgeev ) ;
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//// TODO: decomposition of complex matrix and matrices with complex eigenvalues.
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// eigensystem_complex_impl!(f32, lapack::cgeev);
// eigensystem_complex_impl!(f64, lapack::zgeev);