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AnalysisSystemForRadionucli.../include/armadillo_bits/mul_syrk.hpp
wanglong fe493fb636 Initial commit on main branch
2024-06-04 15:25:02 +08:00

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// Copyright (C) 2013 National ICT Australia (NICTA)
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this
// file, You can obtain one at http://mozilla.org/MPL/2.0/.
// -------------------------------------------------------------------
//
// Written by Conrad Sanderson - http://conradsanderson.id.au
//! \addtogroup syrk
//! @{
class syrk_helper
{
public:
template<typename eT>
inline
static
void
inplace_copy_upper_tri_to_lower_tri(Mat<eT>& C)
{
// under the assumption that C is a square matrix
const uword N = C.n_rows;
for(uword k=0; k < N; ++k)
{
eT* colmem = C.colptr(k);
uword i, j;
for(i=(k+1), j=(k+2); j < N; i+=2, j+=2)
{
const eT tmp_i = C.at(k,i);
const eT tmp_j = C.at(k,j);
colmem[i] = tmp_i;
colmem[j] = tmp_j;
}
if(i < N)
{
colmem[i] = C.at(k,i);
}
}
}
};
//! partial emulation of BLAS function syrk(), specialised for A being a vector
template<const bool do_trans_A=false, const bool use_alpha=false, const bool use_beta=false>
class syrk_vec
{
public:
template<typename eT, typename TA>
arma_hot
inline
static
void
apply
(
Mat<eT>& C,
const TA& A,
const eT alpha = eT(1),
const eT beta = eT(0)
)
{
arma_extra_debug_sigprint();
const uword A_n1 = (do_trans_A == false) ? A.n_rows : A.n_cols;
const uword A_n2 = (do_trans_A == false) ? A.n_cols : A.n_rows;
const eT* A_mem = A.memptr();
if(A_n1 == 1)
{
const eT acc1 = op_dot::direct_dot(A_n2, A_mem, A_mem);
if( (use_alpha == false) && (use_beta == false) ) { C[0] = acc1; }
else if( (use_alpha == true ) && (use_beta == false) ) { C[0] = alpha*acc1; }
else if( (use_alpha == false) && (use_beta == true ) ) { C[0] = acc1 + beta*C[0]; }
else if( (use_alpha == true ) && (use_beta == true ) ) { C[0] = alpha*acc1 + beta*C[0]; }
}
else
for(uword k=0; k < A_n1; ++k)
{
const eT A_k = A_mem[k];
uword i,j;
for(i=(k), j=(k+1); j < A_n1; i+=2, j+=2)
{
const eT acc1 = A_k * A_mem[i];
const eT acc2 = A_k * A_mem[j];
if( (use_alpha == false) && (use_beta == false) )
{
C.at(k, i) = acc1;
C.at(k, j) = acc2;
C.at(i, k) = acc1;
C.at(j, k) = acc2;
}
else
if( (use_alpha == true ) && (use_beta == false) )
{
const eT val1 = alpha*acc1;
const eT val2 = alpha*acc2;
C.at(k, i) = val1;
C.at(k, j) = val2;
C.at(i, k) = val1;
C.at(j, k) = val2;
}
else
if( (use_alpha == false) && (use_beta == true) )
{
C.at(k, i) = acc1 + beta*C.at(k, i);
C.at(k, j) = acc2 + beta*C.at(k, j);
if(i != k) { C.at(i, k) = acc1 + beta*C.at(i, k); }
C.at(j, k) = acc2 + beta*C.at(j, k);
}
else
if( (use_alpha == true ) && (use_beta == true) )
{
const eT val1 = alpha*acc1;
const eT val2 = alpha*acc2;
C.at(k, i) = val1 + beta*C.at(k, i);
C.at(k, j) = val2 + beta*C.at(k, j);
if(i != k) { C.at(i, k) = val1 + beta*C.at(i, k); }
C.at(j, k) = val2 + beta*C.at(j, k);
}
}
if(i < A_n1)
{
const eT acc1 = A_k * A_mem[i];
if( (use_alpha == false) && (use_beta == false) )
{
C.at(k, i) = acc1;
C.at(i, k) = acc1;
}
else
if( (use_alpha == true) && (use_beta == false) )
{
const eT val1 = alpha*acc1;
C.at(k, i) = val1;
C.at(i, k) = val1;
}
else
if( (use_alpha == false) && (use_beta == true) )
{
C.at(k, i) = acc1 + beta*C.at(k, i);
if(i != k) { C.at(i, k) = acc1 + beta*C.at(i, k); }
}
else
if( (use_alpha == true) && (use_beta == true) )
{
const eT val1 = alpha*acc1;
C.at(k, i) = val1 + beta*C.at(k, i);
if(i != k) { C.at(i, k) = val1 + beta*C.at(i, k); }
}
}
}
}
};
//! partial emulation of BLAS function syrk()
template<const bool do_trans_A=false, const bool use_alpha=false, const bool use_beta=false>
class syrk_emul
{
public:
template<typename eT, typename TA>
arma_hot
inline
static
void
apply
(
Mat<eT>& C,
const TA& A,
const eT alpha = eT(1),
const eT beta = eT(0)
)
{
arma_extra_debug_sigprint();
// do_trans_A == false -> C = alpha * A * A^T + beta*C
// do_trans_A == true -> C = alpha * A^T * A + beta*C
if(do_trans_A == false)
{
Mat<eT> AA;
op_strans::apply_mat_noalias(AA, A);
syrk_emul<true, use_alpha, use_beta>::apply(C, AA, alpha, beta);
}
else
if(do_trans_A == true)
{
const uword A_n_rows = A.n_rows;
const uword A_n_cols = A.n_cols;
for(uword col_A=0; col_A < A_n_cols; ++col_A)
{
// col_A is interpreted as row_A when storing the results in matrix C
const eT* A_coldata = A.colptr(col_A);
for(uword k=col_A; k < A_n_cols; ++k)
{
const eT acc = op_dot::direct_dot_arma(A_n_rows, A_coldata, A.colptr(k));
if( (use_alpha == false) && (use_beta == false) )
{
C.at(col_A, k) = acc;
C.at(k, col_A) = acc;
}
else
if( (use_alpha == true ) && (use_beta == false) )
{
const eT val = alpha*acc;
C.at(col_A, k) = val;
C.at(k, col_A) = val;
}
else
if( (use_alpha == false) && (use_beta == true ) )
{
C.at(col_A, k) = acc + beta*C.at(col_A, k);
if(col_A != k) { C.at(k, col_A) = acc + beta*C.at(k, col_A); }
}
else
if( (use_alpha == true ) && (use_beta == true ) )
{
const eT val = alpha*acc;
C.at(col_A, k) = val + beta*C.at(col_A, k);
if(col_A != k) { C.at(k, col_A) = val + beta*C.at(k, col_A); }
}
}
}
}
}
};
template<const bool do_trans_A=false, const bool use_alpha=false, const bool use_beta=false>
class syrk
{
public:
template<typename eT, typename TA>
inline
static
void
apply_blas_type( Mat<eT>& C, const TA& A, const eT alpha = eT(1), const eT beta = eT(0) )
{
arma_extra_debug_sigprint();
if(A.is_vec())
{
// work around poor handling of vectors by syrk() in ATLAS 3.8.4 and standard BLAS
syrk_vec<do_trans_A, use_alpha, use_beta>::apply(C,A,alpha,beta);
return;
}
const uword threshold = (is_cx<eT>::yes ? 16u : 48u);
if( A.n_elem <= threshold )
{
syrk_emul<do_trans_A, use_alpha, use_beta>::apply(C,A,alpha,beta);
}
else
{
#if defined(ARMA_USE_ATLAS)
{
if(use_beta == true)
{
// use a temporary matrix, as we can't assume that matrix C is already symmetric
Mat<eT> D(C.n_rows, C.n_cols);
syrk<do_trans_A, use_alpha, false>::apply_blas_type(D,A,alpha);
// NOTE: assuming beta=1; this is okay for now, as currently glue_times only uses beta=1
arrayops::inplace_plus(C.memptr(), D.memptr(), C.n_elem);
return;
}
atlas::cblas_syrk<eT>
(
atlas::CblasColMajor,
atlas::CblasUpper,
(do_trans_A) ? atlas::CblasTrans : atlas::CblasNoTrans,
C.n_cols,
(do_trans_A) ? A.n_rows : A.n_cols,
(use_alpha) ? alpha : eT(1),
A.mem,
(do_trans_A) ? A.n_rows : C.n_cols,
(use_beta) ? beta : eT(0),
C.memptr(),
C.n_cols
);
syrk_helper::inplace_copy_upper_tri_to_lower_tri(C);
}
#elif defined(ARMA_USE_BLAS)
{
if(use_beta == true)
{
// use a temporary matrix, as we can't assume that matrix C is already symmetric
Mat<eT> D(C.n_rows, C.n_cols);
syrk<do_trans_A, use_alpha, false>::apply_blas_type(D,A,alpha);
// NOTE: assuming beta=1; this is okay for now, as currently glue_times only uses beta=1
arrayops::inplace_plus(C.memptr(), D.memptr(), C.n_elem);
return;
}
arma_extra_debug_print("blas::syrk()");
const char uplo = 'U';
const char trans_A = (do_trans_A) ? 'T' : 'N';
const blas_int n = blas_int(C.n_cols);
const blas_int k = (do_trans_A) ? blas_int(A.n_rows) : blas_int(A.n_cols);
const eT local_alpha = (use_alpha) ? alpha : eT(1);
const eT local_beta = (use_beta) ? beta : eT(0);
const blas_int lda = (do_trans_A) ? k : n;
arma_extra_debug_print( arma_boost::format("blas::syrk(): trans_A = %c") % trans_A );
blas::syrk<eT>
(
&uplo,
&trans_A,
&n,
&k,
&local_alpha,
A.mem,
&lda,
&local_beta,
C.memptr(),
&n // &ldc
);
syrk_helper::inplace_copy_upper_tri_to_lower_tri(C);
}
#else
{
syrk_emul<do_trans_A, use_alpha, use_beta>::apply(C,A,alpha,beta);
}
#endif
}
}
template<typename eT, typename TA>
inline
static
void
apply( Mat<eT>& C, const TA& A, const eT alpha = eT(1), const eT beta = eT(0) )
{
if(is_cx<eT>::no)
{
if(A.is_vec())
{
syrk_vec<do_trans_A, use_alpha, use_beta>::apply(C,A,alpha,beta);
}
else
{
syrk_emul<do_trans_A, use_alpha, use_beta>::apply(C,A,alpha,beta);
}
}
else
{
// handling of complex matrix by syrk_emul() is not yet implemented
return;
}
}
template<typename TA>
arma_inline
static
void
apply
(
Mat<float>& C,
const TA& A,
const float alpha = float(1),
const float beta = float(0)
)
{
syrk<do_trans_A, use_alpha, use_beta>::apply_blas_type(C,A,alpha,beta);
}
template<typename TA>
arma_inline
static
void
apply
(
Mat<double>& C,
const TA& A,
const double alpha = double(1),
const double beta = double(0)
)
{
syrk<do_trans_A, use_alpha, use_beta>::apply_blas_type(C,A,alpha,beta);
}
template<typename TA>
arma_inline
static
void
apply
(
Mat< std::complex<float> >& C,
const TA& A,
const std::complex<float> alpha = std::complex<float>(1),
const std::complex<float> beta = std::complex<float>(0)
)
{
arma_ignore(C);
arma_ignore(A);
arma_ignore(alpha);
arma_ignore(beta);
// handling of complex matrix by syrk() is not yet implemented
return;
}
template<typename TA>
arma_inline
static
void
apply
(
Mat< std::complex<double> >& C,
const TA& A,
const std::complex<double> alpha = std::complex<double>(1),
const std::complex<double> beta = std::complex<double>(0)
)
{
arma_ignore(C);
arma_ignore(A);
arma_ignore(alpha);
arma_ignore(beta);
// handling of complex matrix by syrk() is not yet implemented
return;
}
};
//! @}
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