// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2008-2009 Gael Guennebaud // Copyright (C) 2006-2008 Benoit Jacob // // 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/. #ifndef EIGEN_DENSESTORAGEBASE_H #define EIGEN_DENSESTORAGEBASE_H #if defined(EIGEN_INITIALIZE_MATRICES_BY_ZERO) #define EIGEN_INITIALIZE_COEFFS #define EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED \ for (Index i = 0; i < base().size(); ++i) coeffRef(i) = Scalar(0); #elif defined(EIGEN_INITIALIZE_MATRICES_BY_NAN) #define EIGEN_INITIALIZE_COEFFS #define EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED \ for (Index i = 0; i < base().size(); ++i) coeffRef(i) = std::numeric_limits::quiet_NaN(); #else #undef EIGEN_INITIALIZE_COEFFS #define EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED #endif // IWYU pragma: private #include "./InternalHeaderCheck.h" namespace Eigen { namespace internal { #ifndef EIGEN_NO_DEBUG template struct check_rows_cols_for_overflow { EIGEN_STATIC_ASSERT(MaxRowsAtCompileTime* MaxColsAtCompileTime == MaxSizeAtCompileTime, YOU MADE A PROGRAMMING MISTAKE) template EIGEN_DEVICE_FUNC static EIGEN_ALWAYS_INLINE constexpr void run(Index, Index) {} }; template struct check_rows_cols_for_overflow { template EIGEN_DEVICE_FUNC static EIGEN_ALWAYS_INLINE constexpr void run(Index, Index cols) { constexpr Index MaxIndex = NumTraits::highest(); bool error = cols > (MaxIndex / MaxRowsAtCompileTime); if (error) throw_std_bad_alloc(); } }; template struct check_rows_cols_for_overflow { template EIGEN_DEVICE_FUNC static EIGEN_ALWAYS_INLINE constexpr void run(Index rows, Index) { constexpr Index MaxIndex = NumTraits::highest(); bool error = rows > (MaxIndex / MaxColsAtCompileTime); if (error) throw_std_bad_alloc(); } }; template <> struct check_rows_cols_for_overflow { template EIGEN_DEVICE_FUNC static EIGEN_ALWAYS_INLINE constexpr void run(Index rows, Index cols) { constexpr Index MaxIndex = NumTraits::highest(); bool error = cols == 0 ? false : (rows > (MaxIndex / cols)); if (error) throw_std_bad_alloc(); } }; #endif template struct conservative_resize_like_impl; template struct matrix_swap_impl; } // end namespace internal /** \class PlainObjectBase * \ingroup Core_Module * \brief %Dense storage base class for matrices and arrays. * * This class can be extended with the help of the plugin mechanism described on the page * \ref TopicCustomizing_Plugins by defining the preprocessor symbol \c EIGEN_PLAINOBJECTBASE_PLUGIN. * * \tparam Derived is the derived type, e.g., a Matrix or Array * * \sa \ref TopicClassHierarchy */ template class PlainObjectBase : public internal::dense_xpr_base::type { public: enum { Options = internal::traits::Options }; typedef typename internal::dense_xpr_base::type Base; typedef typename internal::traits::StorageKind StorageKind; typedef typename internal::traits::Scalar Scalar; typedef typename internal::packet_traits::type PacketScalar; typedef typename NumTraits::Real RealScalar; typedef Derived DenseType; using Base::ColsAtCompileTime; using Base::Flags; using Base::IsVectorAtCompileTime; using Base::MaxColsAtCompileTime; using Base::MaxRowsAtCompileTime; using Base::MaxSizeAtCompileTime; using Base::RowsAtCompileTime; using Base::SizeAtCompileTime; typedef Eigen::Map MapType; typedef const Eigen::Map ConstMapType; typedef Eigen::Map AlignedMapType; typedef const Eigen::Map ConstAlignedMapType; template struct StridedMapType { typedef Eigen::Map type; }; template struct StridedConstMapType { typedef Eigen::Map type; }; template struct StridedAlignedMapType { typedef Eigen::Map type; }; template struct StridedConstAlignedMapType { typedef Eigen::Map type; }; protected: DenseStorage m_storage; public: enum { NeedsToAlign = (SizeAtCompileTime != Dynamic) && (internal::traits::Alignment > 0) }; EIGEN_MAKE_ALIGNED_OPERATOR_NEW_IF(NeedsToAlign) EIGEN_STATIC_ASSERT(internal::check_implication(MaxRowsAtCompileTime == 1 && MaxColsAtCompileTime != 1, (int(Options) & RowMajor) == RowMajor), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT(internal::check_implication(MaxColsAtCompileTime == 1 && MaxRowsAtCompileTime != 1, (int(Options) & RowMajor) == 0), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((RowsAtCompileTime == Dynamic) || (RowsAtCompileTime >= 0), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((ColsAtCompileTime == Dynamic) || (ColsAtCompileTime >= 0), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((MaxRowsAtCompileTime == Dynamic) || (MaxRowsAtCompileTime >= 0), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((MaxColsAtCompileTime == Dynamic) || (MaxColsAtCompileTime >= 0), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((MaxRowsAtCompileTime == RowsAtCompileTime || RowsAtCompileTime == Dynamic), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT((MaxColsAtCompileTime == ColsAtCompileTime || ColsAtCompileTime == Dynamic), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_STATIC_ASSERT(((Options & (DontAlign | RowMajor)) == Options), INVALID_MATRIX_TEMPLATE_PARAMETERS) EIGEN_DEVICE_FUNC Base& base() { return *static_cast(this); } EIGEN_DEVICE_FUNC const Base& base() const { return *static_cast(this); } EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Index rows() const noexcept { return m_storage.rows(); } EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Index cols() const noexcept { return m_storage.cols(); } /** This is an overloaded version of DenseCoeffsBase::coeff(Index,Index) const * provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts. * * See DenseCoeffsBase::coeff(Index) const for details. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr const Scalar& coeff(Index rowId, Index colId) const { if (Flags & RowMajorBit) return m_storage.data()[colId + rowId * m_storage.cols()]; else // column-major return m_storage.data()[rowId + colId * m_storage.rows()]; } /** This is an overloaded version of DenseCoeffsBase::coeff(Index) const * provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts. * * See DenseCoeffsBase::coeff(Index) const for details. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr const Scalar& coeff(Index index) const { return m_storage.data()[index]; } /** This is an overloaded version of DenseCoeffsBase::coeffRef(Index,Index) const * provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts. * * See DenseCoeffsBase::coeffRef(Index,Index) const for details. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Scalar& coeffRef(Index rowId, Index colId) { if (Flags & RowMajorBit) return m_storage.data()[colId + rowId * m_storage.cols()]; else // column-major return m_storage.data()[rowId + colId * m_storage.rows()]; } /** This is an overloaded version of DenseCoeffsBase::coeffRef(Index) const * provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts. * * See DenseCoeffsBase::coeffRef(Index) const for details. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Scalar& coeffRef(Index index) { return m_storage.data()[index]; } /** This is the const version of coeffRef(Index,Index) which is thus synonym of coeff(Index,Index). * It is provided for convenience. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr const Scalar& coeffRef(Index rowId, Index colId) const { if (Flags & RowMajorBit) return m_storage.data()[colId + rowId * m_storage.cols()]; else // column-major return m_storage.data()[rowId + colId * m_storage.rows()]; } /** This is the const version of coeffRef(Index) which is thus synonym of coeff(Index). * It is provided for convenience. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr const Scalar& coeffRef(Index index) const { return m_storage.data()[index]; } /** \internal */ template EIGEN_STRONG_INLINE PacketScalar packet(Index rowId, Index colId) const { return internal::ploadt( m_storage.data() + (Flags & RowMajorBit ? colId + rowId * m_storage.cols() : rowId + colId * m_storage.rows())); } /** \internal */ template EIGEN_STRONG_INLINE PacketScalar packet(Index index) const { return internal::ploadt(m_storage.data() + index); } /** \internal */ template EIGEN_STRONG_INLINE void writePacket(Index rowId, Index colId, const PacketScalar& val) { internal::pstoret( m_storage.data() + (Flags & RowMajorBit ? colId + rowId * m_storage.cols() : rowId + colId * m_storage.rows()), val); } /** \internal */ template EIGEN_STRONG_INLINE void writePacket(Index index, const PacketScalar& val) { internal::pstoret(m_storage.data() + index, val); } /** \returns a const pointer to the data array of this matrix */ EIGEN_DEVICE_FUNC constexpr const Scalar* data() const { return m_storage.data(); } /** \returns a pointer to the data array of this matrix */ EIGEN_DEVICE_FUNC constexpr Scalar* data() { return m_storage.data(); } /** Resizes \c *this to a \a rows x \a cols matrix. * * This method is intended for dynamic-size matrices, although it is legal to call it on any * matrix as long as fixed dimensions are left unchanged. If you only want to change the number * of rows and/or of columns, you can use resize(NoChange_t, Index), resize(Index, NoChange_t). * * If the current number of coefficients of \c *this exactly matches the * product \a rows * \a cols, then no memory allocation is performed and * the current values are left unchanged. In all other cases, including * shrinking, the data is reallocated and all previous values are lost. * * Example: \include Matrix_resize_int_int.cpp * Output: \verbinclude Matrix_resize_int_int.out * * \sa resize(Index) for vectors, resize(NoChange_t, Index), resize(Index, NoChange_t) */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr void resize(Index rows, Index cols) { eigen_assert(internal::check_implication(RowsAtCompileTime != Dynamic, rows == RowsAtCompileTime) && internal::check_implication(ColsAtCompileTime != Dynamic, cols == ColsAtCompileTime) && internal::check_implication(RowsAtCompileTime == Dynamic && MaxRowsAtCompileTime != Dynamic, rows <= MaxRowsAtCompileTime) && internal::check_implication(ColsAtCompileTime == Dynamic && MaxColsAtCompileTime != Dynamic, cols <= MaxColsAtCompileTime) && rows >= 0 && cols >= 0 && "Invalid sizes when resizing a matrix or array."); #ifndef EIGEN_NO_DEBUG internal::check_rows_cols_for_overflow::run(rows, cols); #endif #ifdef EIGEN_INITIALIZE_COEFFS Index size = rows * cols; bool size_changed = size != this->size(); m_storage.resize(size, rows, cols); if (size_changed) EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED #else m_storage.resize(rows * cols, rows, cols); #endif } /** Resizes \c *this to a vector of length \a size * * \only_for_vectors. This method does not work for * partially dynamic matrices when the static dimension is anything other * than 1. For example it will not work with Matrix. * * Example: \include Matrix_resize_int.cpp * Output: \verbinclude Matrix_resize_int.out * * \sa resize(Index,Index), resize(NoChange_t, Index), resize(Index, NoChange_t) */ EIGEN_DEVICE_FUNC constexpr void resize(Index size) { EIGEN_STATIC_ASSERT_VECTOR_ONLY(PlainObjectBase) eigen_assert(((SizeAtCompileTime == Dynamic && (MaxSizeAtCompileTime == Dynamic || size <= MaxSizeAtCompileTime)) || SizeAtCompileTime == size) && size >= 0); #ifdef EIGEN_INITIALIZE_COEFFS bool size_changed = size != this->size(); #endif if (RowsAtCompileTime == 1) m_storage.resize(size, 1, size); else m_storage.resize(size, size, 1); #ifdef EIGEN_INITIALIZE_COEFFS if (size_changed) EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED #endif } /** Resizes the matrix, changing only the number of columns. For the parameter of type NoChange_t, just pass the * special value \c NoChange as in the example below. * * Example: \include Matrix_resize_NoChange_int.cpp * Output: \verbinclude Matrix_resize_NoChange_int.out * * \sa resize(Index,Index) */ EIGEN_DEVICE_FUNC constexpr void resize(NoChange_t, Index cols) { resize(rows(), cols); } /** Resizes the matrix, changing only the number of rows. For the parameter of type NoChange_t, just pass the special * value \c NoChange as in the example below. * * Example: \include Matrix_resize_int_NoChange.cpp * Output: \verbinclude Matrix_resize_int_NoChange.out * * \sa resize(Index,Index) */ EIGEN_DEVICE_FUNC constexpr void resize(Index rows, NoChange_t) { resize(rows, cols()); } /** Resizes \c *this to have the same dimensions as \a other. * Takes care of doing all the checking that's needed. * * Note that copying a row-vector into a vector (and conversely) is allowed. * The resizing, if any, is then done in the appropriate way so that row-vectors * remain row-vectors and vectors remain vectors. */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void resizeLike(const EigenBase& _other) { const OtherDerived& other = _other.derived(); #ifndef EIGEN_NO_DEBUG internal::check_rows_cols_for_overflow::run( other.rows(), other.cols()); #endif const Index othersize = other.rows() * other.cols(); if (RowsAtCompileTime == 1) { eigen_assert(other.rows() == 1 || other.cols() == 1); resize(1, othersize); } else if (ColsAtCompileTime == 1) { eigen_assert(other.rows() == 1 || other.cols() == 1); resize(othersize, 1); } else resize(other.rows(), other.cols()); } /** Resizes the matrix to \a rows x \a cols while leaving old values untouched. * * The method is intended for matrices of dynamic size. If you only want to change the number * of rows and/or of columns, you can use conservativeResize(NoChange_t, Index) or * conservativeResize(Index, NoChange_t). * * Matrices are resized relative to the top-left element. In case values need to be * appended to the matrix they will be uninitialized. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void conservativeResize(Index rows, Index cols) { internal::conservative_resize_like_impl::run(*this, rows, cols); } /** Resizes the matrix to \a rows x \a cols while leaving old values untouched. * * As opposed to conservativeResize(Index rows, Index cols), this version leaves * the number of columns unchanged. * * In case the matrix is growing, new rows will be uninitialized. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void conservativeResize(Index rows, NoChange_t) { // Note: see the comment in conservativeResize(Index,Index) conservativeResize(rows, cols()); } /** Resizes the matrix to \a rows x \a cols while leaving old values untouched. * * As opposed to conservativeResize(Index rows, Index cols), this version leaves * the number of rows unchanged. * * In case the matrix is growing, new columns will be uninitialized. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void conservativeResize(NoChange_t, Index cols) { // Note: see the comment in conservativeResize(Index,Index) conservativeResize(rows(), cols); } /** Resizes the vector to \a size while retaining old values. * * \only_for_vectors. This method does not work for * partially dynamic matrices when the static dimension is anything other * than 1. For example it will not work with Matrix. * * When values are appended, they will be uninitialized. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void conservativeResize(Index size) { internal::conservative_resize_like_impl::run(*this, size); } /** Resizes the matrix to \a rows x \a cols of \c other, while leaving old values untouched. * * The method is intended for matrices of dynamic size. If you only want to change the number * of rows and/or of columns, you can use conservativeResize(NoChange_t, Index) or * conservativeResize(Index, NoChange_t). * * Matrices are resized relative to the top-left element. In case values need to be * appended to the matrix they will copied from \c other. */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void conservativeResizeLike(const DenseBase& other) { internal::conservative_resize_like_impl::run(*this, other); } /** This is a special case of the templated operator=. Its purpose is to * prevent a default operator= from hiding the templated operator=. */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Derived& operator=(const PlainObjectBase& other) { return _set(other); } /** \sa MatrixBase::lazyAssign() */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Derived& lazyAssign(const DenseBase& other) { _resize_to_match(other); return Base::lazyAssign(other.derived()); } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Derived& operator=(const ReturnByValue& func) { resize(func.rows(), func.cols()); return Base::operator=(func); } // Prevent user from trying to instantiate PlainObjectBase objects // by making all its constructor protected. See bug 1074. protected: EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr PlainObjectBase() = default; /** \brief Move constructor */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr PlainObjectBase(PlainObjectBase&&) = default; /** \brief Move assignment operator */ EIGEN_DEVICE_FUNC constexpr PlainObjectBase& operator=(PlainObjectBase&& other) noexcept { m_storage = std::move(other.m_storage); return *this; } /** Copy constructor */ EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr PlainObjectBase(const PlainObjectBase&) = default; EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PlainObjectBase(Index size, Index rows, Index cols) : m_storage(size, rows, cols) {} /** \brief Construct a row of column vector with fixed size from an arbitrary number of coefficients. * * \only_for_vectors * * This constructor is for 1D array or vectors with more than 4 coefficients. * * \warning To construct a column (resp. row) vector of fixed length, the number of values passed to this * constructor must match the the fixed number of rows (resp. columns) of \c *this. */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PlainObjectBase(const Scalar& a0, const Scalar& a1, const Scalar& a2, const Scalar& a3, const ArgTypes&... args) : m_storage() { EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(PlainObjectBase, sizeof...(args) + 4); m_storage.data()[0] = a0; m_storage.data()[1] = a1; m_storage.data()[2] = a2; m_storage.data()[3] = a3; Index i = 4; auto x = {(m_storage.data()[i++] = args, 0)...}; static_cast(x); } /** \brief Constructs a Matrix or Array and initializes it by elements given by an initializer list of initializer * lists */ EIGEN_DEVICE_FUNC explicit constexpr EIGEN_STRONG_INLINE PlainObjectBase( const std::initializer_list>& list) : m_storage() { size_t list_size = 0; if (list.begin() != list.end()) { list_size = list.begin()->size(); } // This is to allow syntax like VectorXi {{1, 2, 3, 4}} if (ColsAtCompileTime == 1 && list.size() == 1) { eigen_assert(list_size == static_cast(RowsAtCompileTime) || RowsAtCompileTime == Dynamic); resize(list_size, ColsAtCompileTime); if (list.begin()->begin() != nullptr) { Index index = 0; for (const Scalar& e : *list.begin()) { coeffRef(index++) = e; } } } else { eigen_assert(list.size() == static_cast(RowsAtCompileTime) || RowsAtCompileTime == Dynamic); eigen_assert(list_size == static_cast(ColsAtCompileTime) || ColsAtCompileTime == Dynamic); resize(list.size(), list_size); Index row_index = 0; for (const std::initializer_list& row : list) { eigen_assert(list_size == row.size()); Index col_index = 0; for (const Scalar& e : row) { coeffRef(row_index, col_index) = e; ++col_index; } ++row_index; } } } /** \sa PlainObjectBase::operator=(const EigenBase&) */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PlainObjectBase(const DenseBase& other) : m_storage() { resizeLike(other); _set_noalias(other); } /** \sa PlainObjectBase::operator=(const EigenBase&) */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PlainObjectBase(const EigenBase& other) : m_storage() { resizeLike(other); *this = other.derived(); } /** \brief Copy constructor with in-place evaluation */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE PlainObjectBase(const ReturnByValue& other) { // FIXME this does not automatically transpose vectors if necessary resize(other.rows(), other.cols()); other.evalTo(this->derived()); } public: /** \brief Copies the generic expression \a other into *this. * \copydetails DenseBase::operator=(const EigenBase &other) */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Derived& operator=(const EigenBase& other) { _resize_to_match(other); Base::operator=(other.derived()); return this->derived(); } /** \name Map * These are convenience functions returning Map objects. The Map() static functions return unaligned Map objects, * while the AlignedMap() functions return aligned Map objects and thus should be called only with 16-byte-aligned * \a data pointers. * * Here is an example using strides: * \include Matrix_Map_stride.cpp * Output: \verbinclude Matrix_Map_stride.out * * \see class Map */ ///@{ static inline ConstMapType Map(const Scalar* data) { return ConstMapType(data); } static inline MapType Map(Scalar* data) { return MapType(data); } static inline ConstMapType Map(const Scalar* data, Index size) { return ConstMapType(data, size); } static inline MapType Map(Scalar* data, Index size) { return MapType(data, size); } static inline ConstMapType Map(const Scalar* data, Index rows, Index cols) { return ConstMapType(data, rows, cols); } static inline MapType Map(Scalar* data, Index rows, Index cols) { return MapType(data, rows, cols); } static inline ConstAlignedMapType MapAligned(const Scalar* data) { return ConstAlignedMapType(data); } static inline AlignedMapType MapAligned(Scalar* data) { return AlignedMapType(data); } static inline ConstAlignedMapType MapAligned(const Scalar* data, Index size) { return ConstAlignedMapType(data, size); } static inline AlignedMapType MapAligned(Scalar* data, Index size) { return AlignedMapType(data, size); } static inline ConstAlignedMapType MapAligned(const Scalar* data, Index rows, Index cols) { return ConstAlignedMapType(data, rows, cols); } static inline AlignedMapType MapAligned(Scalar* data, Index rows, Index cols) { return AlignedMapType(data, rows, cols); } template static inline typename StridedConstMapType>::type Map(const Scalar* data, const Stride& stride) { return typename StridedConstMapType>::type(data, stride); } template static inline typename StridedMapType>::type Map(Scalar* data, const Stride& stride) { return typename StridedMapType>::type(data, stride); } template static inline typename StridedConstMapType>::type Map(const Scalar* data, Index size, const Stride& stride) { return typename StridedConstMapType>::type(data, size, stride); } template static inline typename StridedMapType>::type Map(Scalar* data, Index size, const Stride& stride) { return typename StridedMapType>::type(data, size, stride); } template static inline typename StridedConstMapType>::type Map(const Scalar* data, Index rows, Index cols, const Stride& stride) { return typename StridedConstMapType>::type(data, rows, cols, stride); } template static inline typename StridedMapType>::type Map(Scalar* data, Index rows, Index cols, const Stride& stride) { return typename StridedMapType>::type(data, rows, cols, stride); } template static inline typename StridedConstAlignedMapType>::type MapAligned( const Scalar* data, const Stride& stride) { return typename StridedConstAlignedMapType>::type(data, stride); } template static inline typename StridedAlignedMapType>::type MapAligned( Scalar* data, const Stride& stride) { return typename StridedAlignedMapType>::type(data, stride); } template static inline typename StridedConstAlignedMapType>::type MapAligned( const Scalar* data, Index size, const Stride& stride) { return typename StridedConstAlignedMapType>::type(data, size, stride); } template static inline typename StridedAlignedMapType>::type MapAligned( Scalar* data, Index size, const Stride& stride) { return typename StridedAlignedMapType>::type(data, size, stride); } template static inline typename StridedConstAlignedMapType>::type MapAligned( const Scalar* data, Index rows, Index cols, const Stride& stride) { return typename StridedConstAlignedMapType>::type(data, rows, cols, stride); } template static inline typename StridedAlignedMapType>::type MapAligned( Scalar* data, Index rows, Index cols, const Stride& stride) { return typename StridedAlignedMapType>::type(data, rows, cols, stride); } ///@} using Base::setConstant; EIGEN_DEVICE_FUNC Derived& setConstant(Index size, const Scalar& val); EIGEN_DEVICE_FUNC Derived& setConstant(Index rows, Index cols, const Scalar& val); EIGEN_DEVICE_FUNC Derived& setConstant(NoChange_t, Index cols, const Scalar& val); EIGEN_DEVICE_FUNC Derived& setConstant(Index rows, NoChange_t, const Scalar& val); using Base::setZero; EIGEN_DEVICE_FUNC Derived& setZero(Index size); EIGEN_DEVICE_FUNC Derived& setZero(Index rows, Index cols); EIGEN_DEVICE_FUNC Derived& setZero(NoChange_t, Index cols); EIGEN_DEVICE_FUNC Derived& setZero(Index rows, NoChange_t); using Base::setOnes; EIGEN_DEVICE_FUNC Derived& setOnes(Index size); EIGEN_DEVICE_FUNC Derived& setOnes(Index rows, Index cols); EIGEN_DEVICE_FUNC Derived& setOnes(NoChange_t, Index cols); EIGEN_DEVICE_FUNC Derived& setOnes(Index rows, NoChange_t); using Base::setRandom; Derived& setRandom(Index size); Derived& setRandom(Index rows, Index cols); Derived& setRandom(NoChange_t, Index cols); Derived& setRandom(Index rows, NoChange_t); #ifdef EIGEN_PLAINOBJECTBASE_PLUGIN #include EIGEN_PLAINOBJECTBASE_PLUGIN #endif protected: /** \internal Resizes *this in preparation for assigning \a other to it. * Takes care of doing all the checking that's needed. * * Note that copying a row-vector into a vector (and conversely) is allowed. * The resizing, if any, is then done in the appropriate way so that row-vectors * remain row-vectors and vectors remain vectors. */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _resize_to_match(const EigenBase& other) { #ifdef EIGEN_NO_AUTOMATIC_RESIZING eigen_assert((this->size() == 0 || (IsVectorAtCompileTime ? (this->size() == other.size()) : (rows() == other.rows() && cols() == other.cols()))) && "Size mismatch. Automatic resizing is disabled because EIGEN_NO_AUTOMATIC_RESIZING is defined"); EIGEN_ONLY_USED_FOR_DEBUG(other); #else resizeLike(other); #endif } /** * \brief Copies the value of the expression \a other into \c *this with automatic resizing. * * *this might be resized to match the dimensions of \a other. If *this was a null matrix (not already initialized), * it will be initialized. * * Note that copying a row-vector into a vector (and conversely) is allowed. * The resizing, if any, is then done in the appropriate way so that row-vectors * remain row-vectors and vectors remain vectors. * * \sa operator=(const MatrixBase&), _set_noalias() * * \internal */ // aliasing is dealt once in internal::call_assignment // so at this stage we have to assume aliasing... and resising has to be done later. template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Derived& _set(const DenseBase& other) { internal::call_assignment(this->derived(), other.derived()); return this->derived(); } /** \internal Like _set() but additionally makes the assumption that no aliasing effect can happen (which * is the case when creating a new matrix) so one can enforce lazy evaluation. * * \sa operator=(const MatrixBase&), _set() */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE constexpr Derived& _set_noalias(const DenseBase& other) { // I don't think we need this resize call since the lazyAssign will anyways resize // and lazyAssign will be called by the assign selector. //_resize_to_match(other); // the 'false' below means to enforce lazy evaluation. We don't use lazyAssign() because // it wouldn't allow to copy a row-vector into a column-vector. internal::call_assignment_no_alias(this->derived(), other.derived(), internal::assign_op()); return this->derived(); } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init2(Index rows, Index cols, std::enable_if_t* = 0) { EIGEN_STATIC_ASSERT(internal::is_valid_index_type::value && internal::is_valid_index_type::value, T0 AND T1 MUST BE INTEGER TYPES) resize(rows, cols); } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init2(const T0& val0, const T1& val1, std::enable_if_t* = 0) { EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(PlainObjectBase, 2) m_storage.data()[0] = Scalar(val0); m_storage.data()[1] = Scalar(val1); } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init2( const Index& val0, const Index& val1, std::enable_if_t<(!internal::is_same::value) && (internal::is_same::value) && (internal::is_same::value) && Base::SizeAtCompileTime == 2, T1>* = 0) { EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(PlainObjectBase, 2) m_storage.data()[0] = Scalar(val0); m_storage.data()[1] = Scalar(val1); } // The argument is convertible to the Index type and we either have a non 1x1 Matrix, or a dynamic-sized Array, // then the argument is meant to be the size of the object. template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1( Index size, std::enable_if_t<(Base::SizeAtCompileTime != 1 || !internal::is_convertible::value) && ((!internal::is_same::XprKind, ArrayXpr>::value || Base::SizeAtCompileTime == Dynamic)), T>* = 0) { // NOTE MSVC 2008 complains if we directly put bool(NumTraits::IsInteger) as the EIGEN_STATIC_ASSERT argument. const bool is_integer_alike = internal::is_valid_index_type::value; EIGEN_UNUSED_VARIABLE(is_integer_alike); EIGEN_STATIC_ASSERT(is_integer_alike, FLOATING_POINT_ARGUMENT_PASSED__INTEGER_WAS_EXPECTED) resize(size); } // We have a 1x1 matrix/array => the argument is interpreted as the value of the unique coefficient (case where scalar // type can be implicitly converted) template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1( const Scalar& val0, std::enable_if_t::value, T>* = 0) { EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(PlainObjectBase, 1) m_storage.data()[0] = val0; } // We have a 1x1 matrix/array => the argument is interpreted as the value of the unique coefficient (case where scalar // type match the index type) template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1( const Index& val0, std::enable_if_t<(!internal::is_same::value) && (internal::is_same::value) && Base::SizeAtCompileTime == 1 && internal::is_convertible::value, T*>* = 0) { EIGEN_STATIC_ASSERT_VECTOR_SPECIFIC_SIZE(PlainObjectBase, 1) m_storage.data()[0] = Scalar(val0); } // Initialize a fixed size matrix from a pointer to raw data template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const Scalar* data) { this->_set_noalias(ConstMapType(data)); } // Initialize an arbitrary matrix from a dense expression template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const DenseBase& other) { this->_set_noalias(other); } // Initialize an arbitrary matrix from an object convertible to the Derived type. template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const Derived& other) { this->_set_noalias(other); } // Initialize an arbitrary matrix from a generic Eigen expression template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const EigenBase& other) { this->derived() = other; } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const ReturnByValue& other) { resize(other.rows(), other.cols()); other.evalTo(this->derived()); } template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1(const RotationBase& r) { this->derived() = r; } // For fixed-size Array template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1( const Scalar& val0, std::enable_if_t::value && internal::is_same::XprKind, ArrayXpr>::value, T>* = 0) { Base::setConstant(val0); } // For fixed-size Array template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void _init1( const Index& val0, std::enable_if_t<(!internal::is_same::value) && (internal::is_same::value) && Base::SizeAtCompileTime != Dynamic && Base::SizeAtCompileTime != 1 && internal::is_convertible::value && internal::is_same::XprKind, ArrayXpr>::value, T*>* = 0) { Base::setConstant(val0); } template friend struct internal::matrix_swap_impl; public: #ifndef EIGEN_PARSED_BY_DOXYGEN /** \internal * \brief Override DenseBase::swap() since for dynamic-sized matrices * of same type it is enough to swap the data pointers. */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void swap(DenseBase& other) { enum {SwapPointers = internal::is_same::value && Base::SizeAtCompileTime == Dynamic}; internal::matrix_swap_impl::run(this->derived(), other.derived()); } /** \internal * \brief const version forwarded to DenseBase::swap */ template EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE void swap(DenseBase const& other) { Base::swap(other.derived()); } enum {IsPlainObjectBase = 1}; #endif public: // These apparently need to be down here for nvcc+icc to prevent duplicate // Map symbol. template friend class Eigen::Map; friend class Eigen::Map; friend class Eigen::Map; #if EIGEN_MAX_ALIGN_BYTES > 0 // for EIGEN_MAX_ALIGN_BYTES==0, AlignedMax==Unaligned, and many compilers generate warnings for friend-ing a class // twice. friend class Eigen::Map; friend class Eigen::Map; #endif }; namespace internal { template struct conservative_resize_like_impl { static constexpr bool IsRelocatable = std::is_trivially_copyable::value; static void run(DenseBase& _this, Index rows, Index cols) { if (_this.rows() == rows && _this.cols() == cols) return; EIGEN_STATIC_ASSERT_DYNAMIC_SIZE(Derived) if (IsRelocatable && ((Derived::IsRowMajor && _this.cols() == cols) || // row-major and we change only the number of rows (!Derived::IsRowMajor && _this.rows() == rows))) // column-major and we change only the number of columns { #ifndef EIGEN_NO_DEBUG internal::check_rows_cols_for_overflow::run(rows, cols); #endif _this.derived().m_storage.conservativeResize(rows * cols, rows, cols); } else { // The storage order does not allow us to use reallocation. Derived tmp(rows, cols); const Index common_rows = numext::mini(rows, _this.rows()); const Index common_cols = numext::mini(cols, _this.cols()); tmp.block(0, 0, common_rows, common_cols) = _this.block(0, 0, common_rows, common_cols); _this.derived().swap(tmp); } } static void run(DenseBase& _this, const DenseBase& other) { if (_this.rows() == other.rows() && _this.cols() == other.cols()) return; // Note: Here is space for improvement. Basically, for conservativeResize(Index,Index), // neither RowsAtCompileTime or ColsAtCompileTime must be Dynamic. If only one of the // dimensions is dynamic, one could use either conservativeResize(Index rows, NoChange_t) or // conservativeResize(NoChange_t, Index cols). For these methods new static asserts like // EIGEN_STATIC_ASSERT_DYNAMIC_ROWS and EIGEN_STATIC_ASSERT_DYNAMIC_COLS would be good. EIGEN_STATIC_ASSERT_DYNAMIC_SIZE(Derived) EIGEN_STATIC_ASSERT_DYNAMIC_SIZE(OtherDerived) if (IsRelocatable && ((Derived::IsRowMajor && _this.cols() == other.cols()) || // row-major and we change only the number of rows (!Derived::IsRowMajor && _this.rows() == other.rows()))) // column-major and we change only the number of columns { const Index new_rows = other.rows() - _this.rows(); const Index new_cols = other.cols() - _this.cols(); _this.derived().m_storage.conservativeResize(other.size(), other.rows(), other.cols()); if (new_rows > 0) _this.bottomRightCorner(new_rows, other.cols()) = other.bottomRows(new_rows); else if (new_cols > 0) _this.bottomRightCorner(other.rows(), new_cols) = other.rightCols(new_cols); } else { // The storage order does not allow us to use reallocation. Derived tmp(other); const Index common_rows = numext::mini(tmp.rows(), _this.rows()); const Index common_cols = numext::mini(tmp.cols(), _this.cols()); tmp.block(0, 0, common_rows, common_cols) = _this.block(0, 0, common_rows, common_cols); _this.derived().swap(tmp); } } }; // Here, the specialization for vectors inherits from the general matrix case // to allow calling .conservativeResize(rows,cols) on vectors. template struct conservative_resize_like_impl : conservative_resize_like_impl { typedef conservative_resize_like_impl Base; using Base::IsRelocatable; using Base::run; static void run(DenseBase& _this, Index size) { const Index new_rows = Derived::RowsAtCompileTime == 1 ? 1 : size; const Index new_cols = Derived::RowsAtCompileTime == 1 ? size : 1; if (IsRelocatable) _this.derived().m_storage.conservativeResize(size, new_rows, new_cols); else Base::run(_this.derived(), new_rows, new_cols); } static void run(DenseBase& _this, const DenseBase& other) { if (_this.rows() == other.rows() && _this.cols() == other.cols()) return; const Index num_new_elements = other.size() - _this.size(); const Index new_rows = Derived::RowsAtCompileTime == 1 ? 1 : other.rows(); const Index new_cols = Derived::RowsAtCompileTime == 1 ? other.cols() : 1; if (IsRelocatable) _this.derived().m_storage.conservativeResize(other.size(), new_rows, new_cols); else Base::run(_this.derived(), new_rows, new_cols); if (num_new_elements > 0) _this.tail(num_new_elements) = other.tail(num_new_elements); } }; template struct matrix_swap_impl { EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE void run(MatrixTypeA& a, MatrixTypeB& b) { a.base().swap(b); } }; template struct matrix_swap_impl { EIGEN_DEVICE_FUNC static inline void run(MatrixTypeA& a, MatrixTypeB& b) { static_cast(a).m_storage.swap(static_cast(b).m_storage); } }; } // end namespace internal } // end namespace Eigen #endif // EIGEN_DENSESTORAGEBASE_H