blas/level1_cplx_impl.h - eigen - 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"

 struct scalar_norm1_op {
   typedef RealScalar result_type;
   inline RealScalar operator()(const Scalar &a) const { return Eigen::numext::norm1(a); }
 };
 namespace Eigen {
 namespace internal {
 template <>
 struct functor_traits<scalar_norm1_op> {
   enum { Cost = 3 * NumTraits<Scalar>::AddCost, PacketAccess = 0 };
 };
 }  // namespace internal
 }  // namespace Eigen

 // computes the sum of magnitudes of all vector elements or, for a complex vector x, the sum
 // res = |Rex1| + |Imx1| + |Rex2| + |Imx2| + ... + |Rexn| + |Imxn|, where x is a vector of order n
 extern "C" RealScalar EIGEN_CAT(REAL_SCALAR_SUFFIX, EIGEN_BLAS_FUNC_NAME(asum))(int *n, RealScalar *px, int *incx) {
   //   std::cerr << "__asum " << *n << " " << *incx << "\n";
   Complex *x = reinterpret_cast<Complex *>(px);

   if (*n <= 0) return 0;

   if (*incx == 1)
     return make_vector(x, *n).unaryExpr<scalar_norm1_op>().sum();
   else
     return make_vector(x, *n, std::abs(*incx)).unaryExpr<scalar_norm1_op>().sum();
 }

 extern "C" int EIGEN_CAT(i, EIGEN_BLAS_FUNC_NAME(amax))(int *n, RealScalar *px, int *incx) {
   if (*n <= 0) return 0;
   Scalar *x = reinterpret_cast<Scalar *>(px);

   Eigen::DenseIndex ret;
   if (*incx == 1)
     make_vector(x, *n).unaryExpr<scalar_norm1_op>().maxCoeff(&ret);
   else
     make_vector(x, *n, std::abs(*incx)).unaryExpr<scalar_norm1_op>().maxCoeff(&ret);
   return int(ret) + 1;
 }

 extern "C" int EIGEN_CAT(i, EIGEN_BLAS_FUNC_NAME(amin))(int *n, RealScalar *px, int *incx) {
   if (*n <= 0) return 0;
   Scalar *x = reinterpret_cast<Scalar *>(px);

   Eigen::DenseIndex ret;
   if (*incx == 1)
     make_vector(x, *n).unaryExpr<scalar_norm1_op>().minCoeff(&ret);
   else
     make_vector(x, *n, std::abs(*incx)).unaryExpr<scalar_norm1_op>().minCoeff(&ret);
   return int(ret) + 1;
 }

 // computes a dot product of a conjugated vector with another vector.
 EIGEN_BLAS_FUNC(dotcw)(int *n, RealScalar *px, int *incx, RealScalar *py, int *incy, RealScalar *pres) {
   //   std::cerr << "_dotc " << *n << " " << *incx << " " << *incy << "\n";
   Scalar *res = reinterpret_cast<Scalar *>(pres);

   if (*n <= 0) {
     *res = Scalar(0);
     return;
   }

   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);

   if (*incx == 1 && *incy == 1)
     *res = (make_vector(x, *n).dot(make_vector(y, *n)));
   else if (*incx > 0 && *incy > 0)
     *res = (make_vector(x, *n, *incx).dot(make_vector(y, *n, *incy)));
   else if (*incx < 0 && *incy > 0)
     *res = (make_vector(x, *n, -*incx).reverse().dot(make_vector(y, *n, *incy)));
   else if (*incx > 0 && *incy < 0)
     *res = (make_vector(x, *n, *incx).dot(make_vector(y, *n, -*incy).reverse()));
   else if (*incx < 0 && *incy < 0)
     *res = (make_vector(x, *n, -*incx).reverse().dot(make_vector(y, *n, -*incy).reverse()));
 }

 // computes a vector-vector dot product without complex conjugation.
 EIGEN_BLAS_FUNC(dotuw)(int *n, RealScalar *px, int *incx, RealScalar *py, int *incy, RealScalar *pres) {
   Scalar *res = reinterpret_cast<Scalar *>(pres);

   if (*n <= 0) {
     *res = Scalar(0);
     return;
   }

   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);

   if (*incx == 1 && *incy == 1)
     *res = (make_vector(x, *n).cwiseProduct(make_vector(y, *n))).sum();
   else if (*incx > 0 && *incy > 0)
     *res = (make_vector(x, *n, *incx).cwiseProduct(make_vector(y, *n, *incy))).sum();
   else if (*incx < 0 && *incy > 0)
     *res = (make_vector(x, *n, -*incx).reverse().cwiseProduct(make_vector(y, *n, *incy))).sum();
   else if (*incx > 0 && *incy < 0)
     *res = (make_vector(x, *n, *incx).cwiseProduct(make_vector(y, *n, -*incy).reverse())).sum();
   else if (*incx < 0 && *incy < 0)
     *res = (make_vector(x, *n, -*incx).reverse().cwiseProduct(make_vector(y, *n, -*incy).reverse())).sum();
 }

 extern "C" RealScalar EIGEN_CAT(REAL_SCALAR_SUFFIX, EIGEN_BLAS_FUNC_NAME(nrm2))(int *n, RealScalar *px, int *incx) {
   //   std::cerr << "__nrm2 " << *n << " " << *incx << "\n";
   if (*n <= 0) return 0;

   Scalar *x = reinterpret_cast<Scalar *>(px);

   if (*incx == 1) return make_vector(x, *n).stableNorm();

   return make_vector(x, *n, *incx).stableNorm();
 }

 EIGEN_BLAS_FUNC(EIGEN_CAT(REAL_SCALAR_SUFFIX, rot))
 (int *n, RealScalar *px, int *incx, RealScalar *py, int *incy, RealScalar *pc, RealScalar *ps) {
   if (*n <= 0) return;

   Scalar *x = reinterpret_cast<Scalar *>(px);
   Scalar *y = reinterpret_cast<Scalar *>(py);
   RealScalar c = *pc;
   RealScalar s = *ps;

   StridedVectorType vx(make_vector(x, *n, std::abs(*incx)));
   StridedVectorType vy(make_vector(y, *n, std::abs(*incy)));

   Eigen::Reverse<StridedVectorType> rvx(vx);
   Eigen::Reverse<StridedVectorType> rvy(vy);

   // TODO implement mixed real-scalar rotations
   if (*incx < 0 && *incy > 0)
     Eigen::internal::apply_rotation_in_the_plane(rvx, vy, Eigen::JacobiRotation<Scalar>(c, s));
   else if (*incx > 0 && *incy < 0)
     Eigen::internal::apply_rotation_in_the_plane(vx, rvy, Eigen::JacobiRotation<Scalar>(c, s));
   else
     Eigen::internal::apply_rotation_in_the_plane(vx, vy, Eigen::JacobiRotation<Scalar>(c, s));
 }

 EIGEN_BLAS_FUNC(EIGEN_CAT(REAL_SCALAR_SUFFIX, scal))(int *n, RealScalar *palpha, RealScalar *px, int *incx) {
   if (*n <= 0) return;

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

   //   std::cerr << "__scal " << *n << " " << alpha << " " << *incx << "\n";

   if (*incx == 1)
     make_vector(x, *n) *= alpha;
   else
     make_vector(x, *n, std::abs(*incx)) *= alpha;
 }
	// 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"

	struct scalar_norm1_op {
	typedef RealScalar result_type;
	inline RealScalar operator()(const Scalar &a) const { return Eigen::numext::norm1(a); }
	};
	namespace Eigen {
	namespace internal {
	template <>
	struct functor_traits<scalar_norm1_op> {
	enum { Cost = 3 * NumTraits<Scalar>::AddCost, PacketAccess = 0 };
	};
	} // namespace internal
	} // namespace Eigen

	// computes the sum of magnitudes of all vector elements or, for a complex vector x, the sum
	// res = \|Rex1\| + \|Imx1\| + \|Rex2\| + \|Imx2\| + ... + \|Rexn\| + \|Imxn\|, where x is a vector of order n
	extern "C" RealScalar EIGEN_CAT(REAL_SCALAR_SUFFIX, EIGEN_BLAS_FUNC_NAME(asum))(int n, RealScalar px, int *incx) {
	// std::cerr << "__asum " << n << " " << incx << "\n";
	Complex x = reinterpret_cast<Complex >(px);

	if (*n <= 0) return 0;

	if (*incx == 1)
	return make_vector(x, *n).unaryExpr<scalar_norm1_op>().sum();
	else
	return make_vector(x, n, std::abs(incx)).unaryExpr<scalar_norm1_op>().sum();
	}

	extern "C" int EIGEN_CAT(i, EIGEN_BLAS_FUNC_NAME(amax))(int n, RealScalar px, int *incx) {
	if (*n <= 0) return 0;
	Scalar x = reinterpret_cast<Scalar >(px);

	Eigen::DenseIndex ret;
	if (*incx == 1)
	make_vector(x, *n).unaryExpr<scalar_norm1_op>().maxCoeff(&ret);
	else
	make_vector(x, n, std::abs(incx)).unaryExpr<scalar_norm1_op>().maxCoeff(&ret);
	return int(ret) + 1;
	}

	extern "C" int EIGEN_CAT(i, EIGEN_BLAS_FUNC_NAME(amin))(int n, RealScalar px, int *incx) {
	if (*n <= 0) return 0;
	Scalar x = reinterpret_cast<Scalar >(px);

	Eigen::DenseIndex ret;
	if (*incx == 1)
	make_vector(x, *n).unaryExpr<scalar_norm1_op>().minCoeff(&ret);
	else
	make_vector(x, n, std::abs(incx)).unaryExpr<scalar_norm1_op>().minCoeff(&ret);
	return int(ret) + 1;
	}

	// computes a dot product of a conjugated vector with another vector.
	EIGEN_BLAS_FUNC(dotcw)(int n, RealScalar px, int incx, RealScalar py, int incy, RealScalar pres) {
	// std::cerr << "_dotc " << n << " " << incx << " " << *incy << "\n";
	Scalar res = reinterpret_cast<Scalar >(pres);

	if (*n <= 0) {
	*res = Scalar(0);
	return;
	}

	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);

	if (incx == 1 && incy == 1)
	res = (make_vector(x, n).dot(make_vector(y, *n)));
	else if (incx > 0 && incy > 0)
	res = (make_vector(x, n, incx).dot(make_vector(y, n, *incy)));
	else if (incx < 0 && incy > 0)
	res = (make_vector(x, n, -incx).reverse().dot(make_vector(y, n, *incy)));
	else if (incx > 0 && incy < 0)
	res = (make_vector(x, n, incx).dot(make_vector(y, n, -*incy).reverse()));
	else if (incx < 0 && incy < 0)
	res = (make_vector(x, n, -incx).reverse().dot(make_vector(y, n, -*incy).reverse()));
	}

	// computes a vector-vector dot product without complex conjugation.
	EIGEN_BLAS_FUNC(dotuw)(int n, RealScalar px, int incx, RealScalar py, int incy, RealScalar pres) {
	Scalar res = reinterpret_cast<Scalar >(pres);

	if (*n <= 0) {
	*res = Scalar(0);
	return;
	}

	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);

	if (incx == 1 && incy == 1)
	res = (make_vector(x, n).cwiseProduct(make_vector(y, *n))).sum();
	else if (incx > 0 && incy > 0)
	res = (make_vector(x, n, incx).cwiseProduct(make_vector(y, n, *incy))).sum();
	else if (incx < 0 && incy > 0)
	res = (make_vector(x, n, -incx).reverse().cwiseProduct(make_vector(y, n, *incy))).sum();
	else if (incx > 0 && incy < 0)
	res = (make_vector(x, n, incx).cwiseProduct(make_vector(y, n, -*incy).reverse())).sum();
	else if (incx < 0 && incy < 0)
	res = (make_vector(x, n, -incx).reverse().cwiseProduct(make_vector(y, n, -*incy).reverse())).sum();
	}

	extern "C" RealScalar EIGEN_CAT(REAL_SCALAR_SUFFIX, EIGEN_BLAS_FUNC_NAME(nrm2))(int n, RealScalar px, int *incx) {
	// std::cerr << "__nrm2 " << n << " " << incx << "\n";
	if (*n <= 0) return 0;

	Scalar x = reinterpret_cast<Scalar >(px);

	if (incx == 1) return make_vector(x, n).stableNorm();

	return make_vector(x, n, incx).stableNorm();
	}

	EIGEN_BLAS_FUNC(EIGEN_CAT(REAL_SCALAR_SUFFIX, rot))
	(int n, RealScalar px, int incx, RealScalar py, int incy, RealScalar pc, RealScalar *ps) {
	if (*n <= 0) return;

	Scalar x = reinterpret_cast<Scalar >(px);
	Scalar y = reinterpret_cast<Scalar >(py);
	RealScalar c = *pc;
	RealScalar s = *ps;

	StridedVectorType vx(make_vector(x, n, std::abs(incx)));
	StridedVectorType vy(make_vector(y, n, std::abs(incy)));

	Eigen::Reverse<StridedVectorType> rvx(vx);
	Eigen::Reverse<StridedVectorType> rvy(vy);

	// TODO implement mixed real-scalar rotations
	if (incx < 0 && incy > 0)
	Eigen::internal::apply_rotation_in_the_plane(rvx, vy, Eigen::JacobiRotation<Scalar>(c, s));
	else if (incx > 0 && incy < 0)
	Eigen::internal::apply_rotation_in_the_plane(vx, rvy, Eigen::JacobiRotation<Scalar>(c, s));
	else
	Eigen::internal::apply_rotation_in_the_plane(vx, vy, Eigen::JacobiRotation<Scalar>(c, s));
	}

	EIGEN_BLAS_FUNC(EIGEN_CAT(REAL_SCALAR_SUFFIX, scal))(int n, RealScalar palpha, RealScalar px, int incx) {
	if (*n <= 0) return;

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

	// std::cerr << "__scal " << n << " " << alpha << " " << incx << "\n";

	if (*incx == 1)
	make_vector(x, n) = alpha;
	else
	make_vector(x, n, std::abs(incx)) *= alpha;
	}