Exemplos de V_VC_STAR em C++ (Cpp)

Linguagem de programação: C++ (Cpp)

Método / Função: V_VC_STAR

Exemplos em hotexamples.com: 2

V_VC_STAR em C++ (Cpp) - 2 exemplos encontrados. Esses são os exemplos do mundo real mais bem avaliados de V_VC_STAR em C++ (Cpp) extraídos de projetos de código aberto. Você pode avaliar os exemplos para nos ajudar a melhorar a qualidade deles.

Exemplo n.º 1

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Arquivo: GolubReinsch.hpp Projeto: khalid-hasanov/Elemental

inline void GolubReinschUpper_FLA ( DistMatrix<F>& A, DistMatrix<BASE(F),VR,STAR>& s, DistMatrix<F>& V ) { #ifndef RELEASE CallStackEntry entry("svd::GolubReinschUpper_FLA"); #endif typedef BASE(F) Real; const Int m = A.Height(); const Int n = A.Width(); const Int k = Min( m, n ); const Int offdiagonal = ( m>=n ? 1 : -1 ); const Grid& g = A.Grid(); // Bidiagonalize A DistMatrix<F,STAR,STAR> tP(g), tQ(g); Bidiag( A, tP, tQ ); // Grab copies of the diagonal and sub/super-diagonal of A DistMatrix<Real,MD,STAR> d_MD_STAR(g), e_MD_STAR(g); A.GetRealPartOfDiagonal( d_MD_STAR ); A.GetRealPartOfDiagonal( e_MD_STAR, offdiagonal ); // In order to use serial QR kernels, we need the full bidiagonal matrix // on each process DistMatrix<Real,STAR,STAR> d_STAR_STAR( d_MD_STAR ), e_STAR_STAR( e_MD_STAR ); // Initialize U and VAdj to the appropriate identity matrices DistMatrix<F,VC,STAR> U_VC_STAR(g), V_VC_STAR(g); U_VC_STAR.AlignWith( A ); V_VC_STAR.AlignWith( V ); Identity( U_VC_STAR, m, k ); Identity( V_VC_STAR, n, k ); FlaSVD ( k, U_VC_STAR.LocalHeight(), V_VC_STAR.LocalHeight(), d_STAR_STAR.Buffer(), e_STAR_STAR.Buffer(), U_VC_STAR.Buffer(), U_VC_STAR.LDim(), V_VC_STAR.Buffer(), V_VC_STAR.LDim() ); // Make a copy of A (for the Householder vectors) and pull the necessary // portions of U and V into a standard matrix dist. DistMatrix<F> B( A ); if( m >= n ) { DistMatrix<F> AT(g), AB(g); DistMatrix<F,VC,STAR> UT_VC_STAR(g), UB_VC_STAR(g); PartitionDown( A, AT, AB, n ); PartitionDown( U_VC_STAR, UT_VC_STAR, UB_VC_STAR, n ); AT = UT_VC_STAR; MakeZeros( AB ); V = V_VC_STAR; } else { DistMatrix<F> VT(g), VB(g); DistMatrix<F,VC,STAR> VT_VC_STAR(g), VB_VC_STAR(g); PartitionDown( V, VT, VB, m ); PartitionDown( V_VC_STAR, VT_VC_STAR, VB_VC_STAR, m ); VT = VT_VC_STAR; MakeZeros( VB ); } // Backtransform U and V bidiag::ApplyU( LEFT, NORMAL, B, tQ, A ); bidiag::ApplyV( LEFT, NORMAL, B, tP, V ); // Copy out the appropriate subset of the singular values s = d_STAR_STAR; }

Exemplo n.º 2

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Arquivo: SVD.hpp Projeto: certik/Elemental

inline void SimpleSVDUpper ( DistMatrix<Complex<double> >& A, DistMatrix<double,VR,STAR>& s, DistMatrix<Complex<double> >& V ) { #ifndef RELEASE PushCallStack("svd::SimpleSVDUpper"); #endif typedef double Real; typedef Complex<Real> C; const int m = A.Height(); const int n = A.Width(); const int k = std::min( m, n ); const int offdiagonal = ( m>=n ? 1 : -1 ); const char uplo = ( m>=n ? 'U' : 'L' ); const Grid& g = A.Grid(); // Bidiagonalize A DistMatrix<C,STAR,STAR> tP( g ), tQ( g ); Bidiag( A, tP, tQ ); // Grab copies of the diagonal and sub/super-diagonal of A DistMatrix<Real,MD,STAR> d_MD_STAR( g ), e_MD_STAR( g ); A.GetRealPartOfDiagonal( d_MD_STAR ); A.GetRealPartOfDiagonal( e_MD_STAR, offdiagonal ); // In order to use serial QR kernels, we need the full bidiagonal matrix // on each process DistMatrix<Real,STAR,STAR> d_STAR_STAR( d_MD_STAR ), e_STAR_STAR( e_MD_STAR ); // Initialize U and VAdj to the appropriate identity matrices DistMatrix<C,VC,STAR> U_VC_STAR( g ); DistMatrix<C,VC,STAR> V_VC_STAR( g ); U_VC_STAR.AlignWith( A ); V_VC_STAR.AlignWith( V ); Identity( m, k, U_VC_STAR ); Identity( n, k, V_VC_STAR ); // Compute the SVD of the bidiagonal matrix and accumulate the Givens // rotations into our local portion of U and V // NOTE: This _only_ works in the case where m >= n const int numAccum = 32; const int maxNumIts = 30; const int bAlg = 512; std::vector<C> GBuffer( (k-1)*numAccum ), HBuffer( (k-1)*numAccum ); FLA_Bsvd_v_opz_var1 ( k, U_VC_STAR.LocalHeight(), V_VC_STAR.LocalHeight(), numAccum, maxNumIts, d_STAR_STAR.LocalBuffer(), 1, e_STAR_STAR.LocalBuffer(), 1, &GBuffer[0], 1, k-1, &HBuffer[0], 1, k-1, U_VC_STAR.LocalBuffer(), 1, U_VC_STAR.LocalLDim(), V_VC_STAR.LocalBuffer(), 1, V_VC_STAR.LocalLDim(), bAlg ); // Make a copy of A (for the Householder vectors) and pull the necessary // portions of U and V into a standard matrix dist. DistMatrix<C> B( A ); if( m >= n ) { DistMatrix<C> AT( g ), AB( g ); DistMatrix<C,VC,STAR> UT_VC_STAR( g ), UB_VC_STAR( g ); PartitionDown( A, AT, AB, n ); PartitionDown( U_VC_STAR, UT_VC_STAR, UB_VC_STAR, n ); AT = UT_VC_STAR; MakeZeros( AB ); V = V_VC_STAR; } else { DistMatrix<C> VT( g ), VB( g ); DistMatrix<C,VC,STAR> VT_VC_STAR( g ), VB_VC_STAR( g ); PartitionDown( V, VT, VB, m ); PartitionDown ( V_VC_STAR, VT_VC_STAR, VB_VC_STAR, m ); VT = VT_VC_STAR; MakeZeros( VB ); } // Backtransform U and V if( m >= n ) { ApplyPackedReflectors ( LEFT, LOWER, VERTICAL, BACKWARD, UNCONJUGATED, 0, B, tQ, A ); ApplyPackedReflectors ( LEFT, UPPER, HORIZONTAL, BACKWARD, UNCONJUGATED, 1, B, tP, V ); } else { ApplyPackedReflectors ( LEFT, LOWER, VERTICAL, BACKWARD, UNCONJUGATED, -1, B, tQ, A ); ApplyPackedReflectors ( LEFT, UPPER, HORIZONTAL, BACKWARD, UNCONJUGATED, 0, B, tP, V ); } // Copy out the appropriate subset of the singular values s = d_STAR_STAR; #ifndef RELEASE PopCallStack(); #endif }