// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2009 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/.
// TODO if the maxCoeff is much much smaller than the current scale, // then we can neglect this sub vector if(scale>Scalar(0)) // if scale==0, then bl is 0
ssq += (bl*invScale).squaredNorm();
}
enum {
CanAlign = ( (int(VectorTypeCopyClean::Flags)&DirectAccessBit)
|| (int(internal::evaluator<VectorTypeCopyClean>::Alignment)>0) // FIXME Alignment)>0 might not be enough
) && (blockSize*sizeof(Scalar)*2<EIGEN_STACK_ALLOCATION_LIMIT)
&& (EIGEN_MAX_STATIC_ALIGN_BYTES>0) // if we cannot allocate on the stack, then let's not bother about this optimization
}; typedeftypename internal::conditional<CanAlign, Ref<const Matrix<Scalar,Dynamic,1,0,blockSize,1>, internal::evaluator<VectorTypeCopyClean>::Alignment>, typename VectorTypeCopyClean::ConstSegmentReturnType>::type SegmentWrapper;
Index n = vec.size();
Index bi = internal::first_default_aligned(copy); if (bi>0)
internal::stable_norm_kernel(copy.head(bi), ssq, scale, invScale); for (; bi<n; bi+=blockSize)
internal::stable_norm_kernel(SegmentWrapper(copy.segment(bi,numext::mini(blockSize, n - bi))), ssq, scale, invScale);
}
template<typename VectorType> typename VectorType::RealScalar
stable_norm_impl(const VectorType &vec, typename enable_if<VectorType::IsVectorAtCompileTime>::type* = 0 )
{ using std::sqrt; using std::abs;
Index n = vec.size();
if(n==1) return abs(vec.coeff(0));
typedeftypename VectorType::RealScalar RealScalar;
RealScalar scale(0);
RealScalar invScale(1);
RealScalar ssq(0); // sum of squares
template<typename Derived> inlinetypename NumTraits<typename traits<Derived>::Scalar>::Real
blueNorm_impl(const EigenBase<Derived>& _vec)
{ typedeftypename Derived::RealScalar RealScalar; using std::pow; using std::sqrt; using std::abs;
// This program calculates the machine-dependent constants // bl, b2, slm, s2m, relerr overfl // from the "basic" machine-dependent numbers // nbig, ibeta, it, iemin, iemax, rbig. // The following define the basic machine-dependent constants. // For portability, the PORT subprograms "ilmaeh" and "rlmach" // are used. For any specific computer, each of the assignment // statements can be replaced staticconstint ibeta = std::numeric_limits<RealScalar>::radix; // base for floating-point numbers staticconstint it = NumTraits<RealScalar>::digits(); // number of base-beta digits in mantissa staticconstint iemin = NumTraits<RealScalar>::min_exponent(); // minimum exponent staticconstint iemax = NumTraits<RealScalar>::max_exponent(); // maximum exponent staticconst RealScalar rbig = NumTraits<RealScalar>::highest(); // largest floating-point number staticconst RealScalar b1 = RealScalar(pow(RealScalar(ibeta),RealScalar(-((1-iemin)/2)))); // lower boundary of midrange staticconst RealScalar b2 = RealScalar(pow(RealScalar(ibeta),RealScalar((iemax + 1 - it)/2))); // upper boundary of midrange staticconst RealScalar s1m = RealScalar(pow(RealScalar(ibeta),RealScalar((2-iemin)/2))); // scaling factor for lower range staticconst RealScalar s2m = RealScalar(pow(RealScalar(ibeta),RealScalar(- ((iemax+it)/2)))); // scaling factor for upper range staticconst RealScalar eps = RealScalar(pow(double(ibeta), 1-it)); staticconst RealScalar relerr = sqrt(eps); // tolerance for neglecting asml
/** \returns the \em l2 norm of \c *this avoiding underflow and overflow. * This version use a blockwise two passes algorithm: * 1 - find the absolute largest coefficient \c s * 2 - compute \f$ s \Vert \frac{*this}{s} \Vert \f$ in a standard way * * For architecture/scalar types supporting vectorization, this version * is faster than blueNorm(). Otherwise the blueNorm() is much faster. * * \sa norm(), blueNorm(), hypotNorm()
*/ template<typename Derived> inlinetypename NumTraits<typename internal::traits<Derived>::Scalar>::Real
MatrixBase<Derived>::stableNorm() const
{ return internal::stable_norm_impl(derived());
}
/** \returns the \em l2 norm of \c *this using the Blue's algorithm. * A Portable Fortran Program to Find the Euclidean Norm of a Vector, * ACM TOMS, Vol 4, Issue 1, 1978. * * For architecture/scalar types without vectorization, this version * is much faster than stableNorm(). Otherwise the stableNorm() is faster. * * \sa norm(), stableNorm(), hypotNorm()
*/ template<typename Derived> inlinetypename NumTraits<typename internal::traits<Derived>::Scalar>::Real
MatrixBase<Derived>::blueNorm() const
{ return internal::blueNorm_impl(*this);
}
/** \returns the \em l2 norm of \c *this avoiding undeflow and overflow. * This version use a concatenation of hypot() calls, and it is very slow. * * \sa norm(), stableNorm()
*/ template<typename Derived> inlinetypename NumTraits<typename internal::traits<Derived>::Scalar>::Real
MatrixBase<Derived>::hypotNorm() const
{ if(size()==1) return numext::abs(coeff(0,0)); else return this->cwiseAbs().redux(internal::scalar_hypot_op<RealScalar>());
}
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