blas/level2_real_impl.h - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2009-2010 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // 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/.

 #include "common.h"

 // y = alpha*A*x + beta*y
 EIGEN_BLAS_FUNC(symv)
 (const char *uplo, const int *n, const RealScalar *palpha, const RealScalar *pa, const int *lda, const RealScalar *px,
  const int *incx, const RealScalar *pbeta, RealScalar *py, const int *incy) {
   typedef void (*functype)(int, const Scalar *, int, const Scalar *, Scalar *, Scalar);
   using Eigen::ColMajor;
   using Eigen::Lower;
   using Eigen::Upper;
   static const functype func[2] = {
       // array index: UP
       (Eigen::internal::selfadjoint_matrix_vector_product<Scalar, int, ColMajor, Upper, false, false>::run),
       // array index: LO
       (Eigen::internal::selfadjoint_matrix_vector_product<Scalar, int, ColMajor, Lower, false, false>::run),
   };

   const Scalar *a = reinterpret_cast<const Scalar *>(pa);
   const Scalar *x = reinterpret_cast<const Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);
   Scalar alpha = *reinterpret_cast<const Scalar *>(palpha);
   Scalar beta = *reinterpret_cast<const Scalar *>(pbeta);

   // check arguments
   int info = 0;
   if (UPLO(*uplo) == INVALID)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*lda < std::max(1, *n))
     info = 5;
   else if (*incx == 0)
     info = 7;
   else if (*incy == 0)
     info = 10;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "SYMV ", &info);

   if (*n == 0) return;

   const Scalar *actual_x = get_compact_vector(x, *n, *incx);
   Scalar *actual_y = get_compact_vector(y, *n, *incy);

   if (beta != Scalar(1)) {
     if (beta == Scalar(0))
       make_vector(actual_y, *n).setZero();
     else
       make_vector(actual_y, *n) *= beta;
   }

   int code = UPLO(*uplo);
   if (code >= 2 || func[code] == 0) return;

   func[code](*n, a, *lda, actual_x, actual_y, alpha);

   if (actual_x != x) delete[] actual_x;
   if (actual_y != y) delete[] copy_back(actual_y, y, *n, *incy);
 }

 // C := alpha*x*x' + C
 EIGEN_BLAS_FUNC(syr)
 (const char *uplo, const int *n, const RealScalar *palpha, const RealScalar *px, const int *incx, RealScalar *pc,
  const int *ldc) {
   typedef void (*functype)(int, Scalar *, int, const Scalar *, const Scalar *, const Scalar &);
   using Eigen::ColMajor;
   using Eigen::Lower;
   using Eigen::Upper;
   static const functype func[2] = {
       // array index: UP
       (Eigen::selfadjoint_rank1_update<Scalar, int, ColMajor, Upper, false, Conj>::run),
       // array index: LO
       (Eigen::selfadjoint_rank1_update<Scalar, int, ColMajor, Lower, false, Conj>::run),
   };

   const Scalar *x = reinterpret_cast<const Scalar *>(px);
   Scalar *c = reinterpret_cast<Scalar *>(pc);
   Scalar alpha = *reinterpret_cast<const Scalar *>(palpha);

   int info = 0;
   if (UPLO(*uplo) == INVALID)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*incx == 0)
     info = 5;
   else if (*ldc < std::max(1, *n))
     info = 7;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "SYR  ", &info);

   if (*n == 0 || alpha == Scalar(0)) return;

   // if the increment is not 1, let's copy it to a temporary vector to enable vectorization
   const Scalar *x_cpy = get_compact_vector(x, *n, *incx);

   int code = UPLO(*uplo);
   if (code >= 2 || func[code] == 0) return;

   func[code](*n, c, *ldc, x_cpy, x_cpy, alpha);

   if (x_cpy != x) delete[] x_cpy;
 }

 // C := alpha*x*y' + alpha*y*x' + C
 EIGEN_BLAS_FUNC(syr2)
 (const char *uplo, const int *n, const RealScalar *palpha, const RealScalar *px, const int *incx, const RealScalar *py,
  const int *incy, RealScalar *pc, const int *ldc) {
   typedef void (*functype)(int, Scalar *, int, const Scalar *, const Scalar *, Scalar);
   static const functype func[2] = {
       // array index: UP
       (Eigen::internal::rank2_update_selector<Scalar, int, Eigen::Upper>::run),
       // array index: LO
       (Eigen::internal::rank2_update_selector<Scalar, int, Eigen::Lower>::run),
   };

   const Scalar *x = reinterpret_cast<const Scalar *>(px);
   const Scalar *y = reinterpret_cast<const Scalar *>(py);
   Scalar *c = reinterpret_cast<Scalar *>(pc);
   Scalar alpha = *reinterpret_cast<const Scalar *>(palpha);

   int info = 0;
   if (UPLO(*uplo) == INVALID)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*incx == 0)
     info = 5;
   else if (*incy == 0)
     info = 7;
   else if (*ldc < std::max(1, *n))
     info = 9;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "SYR2 ", &info);

   if (alpha == Scalar(0)) return;

   const Scalar *x_cpy = get_compact_vector(x, *n, *incx);
   const Scalar *y_cpy = get_compact_vector(y, *n, *incy);

   int code = UPLO(*uplo);
   if (code >= 2 || func[code] == 0) return;

   func[code](*n, c, *ldc, x_cpy, y_cpy, alpha);

   if (x_cpy != x) delete[] x_cpy;
   if (y_cpy != y) delete[] y_cpy;

   //   int code = UPLO(*uplo);
   //   if(code>=2 || func[code]==0)
   //     return 0;

   //   func[code](*n, a, *inca, b, *incb, c, *ldc, alpha);
 }

 /**  DSBMV  performs the matrix-vector  operation
  *
  *     y := alpha*A*x + beta*y,
  *
  *  where alpha and beta are scalars, x and y are n element vectors and
  *  A is an n by n symmetric band matrix, with k super-diagonals.
  */
 // EIGEN_BLAS_FUNC(sbmv)( char *uplo, int *n, int *k, RealScalar *alpha, RealScalar *a, int *lda,
 //                            RealScalar *x, int *incx, RealScalar *beta, RealScalar *y, int *incy)
 // {
 //   return 1;
 // }

 /**  DSPMV  performs the matrix-vector operation
  *
  *     y := alpha*A*x + beta*y,
  *
  *  where alpha and beta are scalars, x and y are n element vectors and
  *  A is an n by n symmetric matrix, supplied in packed form.
  *
  */
 // EIGEN_BLAS_FUNC(spmv)(char *uplo, int *n, RealScalar *alpha, RealScalar *ap, RealScalar *x, int *incx, RealScalar
 // *beta, RealScalar *y, int *incy)
 // {
 //   return 1;
 // }

 /**  DSPR    performs the symmetric rank 1 operation
  *
  *     A := alpha*x*x' + A,
  *
  *  where alpha is a real scalar, x is an n element vector and A is an
  *  n by n symmetric matrix, supplied in packed form.
  */
 EIGEN_BLAS_FUNC(spr)(char *uplo, int *n, Scalar *palpha, Scalar *px, int *incx, Scalar *pap) {
   typedef void (*functype)(int, Scalar *, const Scalar *, Scalar);
   static const functype func[2] = {
       // array index: UP
       (Eigen::internal::selfadjoint_packed_rank1_update<Scalar, int, Eigen::ColMajor, Eigen::Upper, false, false>::run),
       // array index: LO
       (Eigen::internal::selfadjoint_packed_rank1_update<Scalar, int, Eigen::ColMajor, Eigen::Lower, false, false>::run),
   };

   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *ap = reinterpret_cast<Scalar *>(pap);
   Scalar alpha = *reinterpret_cast<Scalar *>(palpha);

   int info = 0;
   if (UPLO(*uplo) == INVALID)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*incx == 0)
     info = 5;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "SPR  ", &info);

   if (alpha == Scalar(0)) return;

   Scalar *x_cpy = get_compact_vector(x, *n, *incx);

   int code = UPLO(*uplo);
   if (code >= 2 || func[code] == 0) return;

   func[code](*n, ap, x_cpy, alpha);

   if (x_cpy != x) delete[] x_cpy;
 }

 /**  DSPR2  performs the symmetric rank 2 operation
  *
  *     A := alpha*x*y' + alpha*y*x' + A,
  *
  *  where alpha is a scalar, x and y are n element vectors and A is an
  *  n by n symmetric matrix, supplied in packed form.
  */
 EIGEN_BLAS_FUNC(spr2)
 (char *uplo, int *n, RealScalar *palpha, RealScalar *px, int *incx, RealScalar *py, int *incy, RealScalar *pap) {
   typedef void (*functype)(int, Scalar *, const Scalar *, const Scalar *, Scalar);
   static const functype func[2] = {
       // array index: UP
       (Eigen::internal::packed_rank2_update_selector<Scalar, int, Eigen::Upper>::run),
       // array index: LO
       (Eigen::internal::packed_rank2_update_selector<Scalar, int, Eigen::Lower>::run),
   };

   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);
   Scalar *ap = reinterpret_cast<Scalar *>(pap);
   Scalar alpha = *reinterpret_cast<Scalar *>(palpha);

   int info = 0;
   if (UPLO(*uplo) == INVALID)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*incx == 0)
     info = 5;
   else if (*incy == 0)
     info = 7;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "SPR2 ", &info);

   if (alpha == Scalar(0)) return;

   Scalar *x_cpy = get_compact_vector(x, *n, *incx);
   Scalar *y_cpy = get_compact_vector(y, *n, *incy);

   int code = UPLO(*uplo);
   if (code >= 2 || func[code] == 0) return;

   func[code](*n, ap, x_cpy, y_cpy, alpha);

   if (x_cpy != x) delete[] x_cpy;
   if (y_cpy != y) delete[] y_cpy;
 }

 /**  DGER   performs the rank 1 operation
  *
  *     A := alpha*x*y' + A,
  *
  *  where alpha is a scalar, x is an m element vector, y is an n element
  *  vector and A is an m by n matrix.
  */
 EIGEN_BLAS_FUNC(ger)
 (int *m, int *n, Scalar *palpha, Scalar *px, int *incx, Scalar *py, int *incy, Scalar *pa, int *lda) {
   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);
   Scalar *a = reinterpret_cast<Scalar *>(pa);
   Scalar alpha = *reinterpret_cast<Scalar *>(palpha);

   int info = 0;
   if (*m < 0)
     info = 1;
   else if (*n < 0)
     info = 2;
   else if (*incx == 0)
     info = 5;
   else if (*incy == 0)
     info = 7;
   else if (*lda < std::max(1, *m))
     info = 9;
   if (info) return xerbla_(SCALAR_SUFFIX_UP "GER  ", &info);

   if (alpha == Scalar(0)) return;

   Scalar *x_cpy = get_compact_vector(x, *m, *incx);
   Scalar *y_cpy = get_compact_vector(y, *n, *incy);

   Eigen::internal::general_rank1_update<Scalar, int, Eigen::ColMajor, false, false>::run(*m, *n, a, *lda, x_cpy, y_cpy,
                                                                                          alpha);

   if (x_cpy != x) delete[] x_cpy;
   if (y_cpy != y) delete[] y_cpy;
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2009-2010 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// 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/.

	#include "common.h"

	// y = alphaAx + beta*y
	EIGEN_BLAS_FUNC(symv)
	(const char uplo, const int n, const RealScalar palpha, const RealScalar pa, const int lda, const RealScalar px,
	const int incx, const RealScalar pbeta, RealScalar py, const int incy) {
	typedef void (functype)(int, const Scalar , int, const Scalar , Scalar , Scalar);
	using Eigen::ColMajor;
	using Eigen::Lower;
	using Eigen::Upper;
	static const functype func[2] = {
	// array index: UP
	(Eigen::internal::selfadjoint_matrix_vector_product<Scalar, int, ColMajor, Upper, false, false>::run),
	// array index: LO
	(Eigen::internal::selfadjoint_matrix_vector_product<Scalar, int, ColMajor, Lower, false, false>::run),
	};

	const Scalar a = reinterpret_cast<const Scalar >(pa);
	const Scalar x = reinterpret_cast<const Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);
	Scalar alpha = reinterpret_cast<const Scalar >(palpha);
	Scalar beta = reinterpret_cast<const Scalar >(pbeta);

	// check arguments
	int info = 0;
	if (UPLO(*uplo) == INVALID)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (lda < std::max(1, n))
	info = 5;
	else if (*incx == 0)
	info = 7;
	else if (*incy == 0)
	info = 10;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "SYMV ", &info);

	if (*n == 0) return;

	const Scalar actual_x = get_compact_vector(x, n, *incx);
	Scalar actual_y = get_compact_vector(y, n, *incy);

	if (beta != Scalar(1)) {
	if (beta == Scalar(0))
	make_vector(actual_y, *n).setZero();
	else
	make_vector(actual_y, n) = beta;
	}

	int code = UPLO(*uplo);
	if (code >= 2 \|\| func[code] == 0) return;

	func[code](n, a, lda, actual_x, actual_y, alpha);

	if (actual_x != x) delete[] actual_x;
	if (actual_y != y) delete[] copy_back(actual_y, y, n, incy);
	}

	// C := alphaxx' + C
	EIGEN_BLAS_FUNC(syr)
	(const char uplo, const int n, const RealScalar palpha, const RealScalar px, const int incx, RealScalar pc,
	const int *ldc) {
	typedef void (functype)(int, Scalar , int, const Scalar , const Scalar , const Scalar &);
	using Eigen::ColMajor;
	using Eigen::Lower;
	using Eigen::Upper;
	static const functype func[2] = {
	// array index: UP
	(Eigen::selfadjoint_rank1_update<Scalar, int, ColMajor, Upper, false, Conj>::run),
	// array index: LO
	(Eigen::selfadjoint_rank1_update<Scalar, int, ColMajor, Lower, false, Conj>::run),
	};

	const Scalar x = reinterpret_cast<const Scalar >(px);
	Scalar c = reinterpret_cast<Scalar >(pc);
	Scalar alpha = reinterpret_cast<const Scalar >(palpha);

	int info = 0;
	if (UPLO(*uplo) == INVALID)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (*incx == 0)
	info = 5;
	else if (ldc < std::max(1, n))
	info = 7;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "SYR ", &info);

	if (*n == 0 \|\| alpha == Scalar(0)) return;

	// if the increment is not 1, let's copy it to a temporary vector to enable vectorization
	const Scalar x_cpy = get_compact_vector(x, n, *incx);

	int code = UPLO(*uplo);
	if (code >= 2 \|\| func[code] == 0) return;

	func[code](n, c, ldc, x_cpy, x_cpy, alpha);

	if (x_cpy != x) delete[] x_cpy;
	}

	// C := alphaxy' + alphayx' + C
	EIGEN_BLAS_FUNC(syr2)
	(const char uplo, const int n, const RealScalar palpha, const RealScalar px, const int incx, const RealScalar py,
	const int incy, RealScalar pc, const int *ldc) {
	typedef void (functype)(int, Scalar , int, const Scalar , const Scalar , Scalar);
	static const functype func[2] = {
	// array index: UP
	(Eigen::internal::rank2_update_selector<Scalar, int, Eigen::Upper>::run),
	// array index: LO
	(Eigen::internal::rank2_update_selector<Scalar, int, Eigen::Lower>::run),
	};

	const Scalar x = reinterpret_cast<const Scalar >(px);
	const Scalar y = reinterpret_cast<const Scalar >(py);
	Scalar c = reinterpret_cast<Scalar >(pc);
	Scalar alpha = reinterpret_cast<const Scalar >(palpha);

	int info = 0;
	if (UPLO(*uplo) == INVALID)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (*incx == 0)
	info = 5;
	else if (*incy == 0)
	info = 7;
	else if (ldc < std::max(1, n))
	info = 9;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "SYR2 ", &info);

	if (alpha == Scalar(0)) return;

	const Scalar x_cpy = get_compact_vector(x, n, *incx);
	const Scalar y_cpy = get_compact_vector(y, n, *incy);

	int code = UPLO(*uplo);
	if (code >= 2 \|\| func[code] == 0) return;

	func[code](n, c, ldc, x_cpy, y_cpy, alpha);

	if (x_cpy != x) delete[] x_cpy;
	if (y_cpy != y) delete[] y_cpy;

	// int code = UPLO(*uplo);
	// if(code>=2 \|\| func[code]==0)
	// return 0;

	// func[code](n, a, inca, b, incb, c, ldc, alpha);
	}

	/** DSBMV performs the matrix-vector operation
	*
	* y := alphaAx + beta*y,
	*
	* where alpha and beta are scalars, x and y are n element vectors and
	* A is an n by n symmetric band matrix, with k super-diagonals.
	*/
	// EIGEN_BLAS_FUNC(sbmv)( char uplo, int n, int k, RealScalar alpha, RealScalar a, int lda,
	// RealScalar x, int incx, RealScalar beta, RealScalar y, int *incy)
	// {
	// return 1;
	// }

	/** DSPMV performs the matrix-vector operation
	*
	* y := alphaAx + beta*y,
	*
	* where alpha and beta are scalars, x and y are n element vectors and
	* A is an n by n symmetric matrix, supplied in packed form.
	*
	*/
	// EIGEN_BLAS_FUNC(spmv)(char uplo, int n, RealScalar alpha, RealScalar ap, RealScalar x, int incx, RealScalar
	// beta, RealScalar y, int *incy)
	// {
	// return 1;
	// }

	/** DSPR performs the symmetric rank 1 operation
	*
	* A := alphaxx' + A,
	*
	* where alpha is a real scalar, x is an n element vector and A is an
	* n by n symmetric matrix, supplied in packed form.
	*/
	EIGEN_BLAS_FUNC(spr)(char uplo, int n, Scalar palpha, Scalar px, int incx, Scalar pap) {
	typedef void (functype)(int, Scalar , const Scalar *, Scalar);
	static const functype func[2] = {
	// array index: UP
	(Eigen::internal::selfadjoint_packed_rank1_update<Scalar, int, Eigen::ColMajor, Eigen::Upper, false, false>::run),
	// array index: LO
	(Eigen::internal::selfadjoint_packed_rank1_update<Scalar, int, Eigen::ColMajor, Eigen::Lower, false, false>::run),
	};

	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar ap = reinterpret_cast<Scalar >(pap);
	Scalar alpha = reinterpret_cast<Scalar >(palpha);

	int info = 0;
	if (UPLO(*uplo) == INVALID)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (*incx == 0)
	info = 5;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "SPR ", &info);

	if (alpha == Scalar(0)) return;

	Scalar x_cpy = get_compact_vector(x, n, *incx);

	int code = UPLO(*uplo);
	if (code >= 2 \|\| func[code] == 0) return;

	func[code](*n, ap, x_cpy, alpha);

	if (x_cpy != x) delete[] x_cpy;
	}

	/** DSPR2 performs the symmetric rank 2 operation
	*
	* A := alphaxy' + alphayx' + A,
	*
	* where alpha is a scalar, x and y are n element vectors and A is an
	* n by n symmetric matrix, supplied in packed form.
	*/
	EIGEN_BLAS_FUNC(spr2)
	(char uplo, int n, RealScalar palpha, RealScalar px, int incx, RealScalar py, int incy, RealScalar pap) {
	typedef void (functype)(int, Scalar , const Scalar , const Scalar , Scalar);
	static const functype func[2] = {
	// array index: UP
	(Eigen::internal::packed_rank2_update_selector<Scalar, int, Eigen::Upper>::run),
	// array index: LO
	(Eigen::internal::packed_rank2_update_selector<Scalar, int, Eigen::Lower>::run),
	};

	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);
	Scalar ap = reinterpret_cast<Scalar >(pap);
	Scalar alpha = reinterpret_cast<Scalar >(palpha);

	int info = 0;
	if (UPLO(*uplo) == INVALID)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (*incx == 0)
	info = 5;
	else if (*incy == 0)
	info = 7;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "SPR2 ", &info);

	if (alpha == Scalar(0)) return;

	Scalar x_cpy = get_compact_vector(x, n, *incx);
	Scalar y_cpy = get_compact_vector(y, n, *incy);

	int code = UPLO(*uplo);
	if (code >= 2 \|\| func[code] == 0) return;

	func[code](*n, ap, x_cpy, y_cpy, alpha);

	if (x_cpy != x) delete[] x_cpy;
	if (y_cpy != y) delete[] y_cpy;
	}

	/** DGER performs the rank 1 operation
	*
	* A := alphaxy' + A,
	*
	* where alpha is a scalar, x is an m element vector, y is an n element
	* vector and A is an m by n matrix.
	*/
	EIGEN_BLAS_FUNC(ger)
	(int m, int n, Scalar palpha, Scalar px, int incx, Scalar py, int incy, Scalar pa, int *lda) {
	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);
	Scalar a = reinterpret_cast<Scalar >(pa);
	Scalar alpha = reinterpret_cast<Scalar >(palpha);

	int info = 0;
	if (*m < 0)
	info = 1;
	else if (*n < 0)
	info = 2;
	else if (*incx == 0)
	info = 5;
	else if (*incy == 0)
	info = 7;
	else if (lda < std::max(1, m))
	info = 9;
	if (info) return xerbla_(SCALAR_SUFFIX_UP "GER ", &info);

	if (alpha == Scalar(0)) return;

	Scalar x_cpy = get_compact_vector(x, m, *incx);
	Scalar y_cpy = get_compact_vector(y, n, *incy);

	Eigen::internal::general_rank1_update<Scalar, int, Eigen::ColMajor, false, false>::run(m, n, a, *lda, x_cpy, y_cpy,
	alpha);

	if (x_cpy != x) delete[] x_cpy;
	if (y_cpy != y) delete[] y_cpy;
	}