// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com> // Copyright (C) 2013 Christian Seiler <christian@iwakd.de> // // 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/.
/** \class Tensor * \ingroup CXX11_Tensor_Module * * \brief The tensor class. * * The %Tensor class is the work-horse for all \em dense tensors within Eigen. * * The %Tensor class encompasses only dynamic-size objects so far. * * The first two template parameters are required: * \tparam Scalar_ Numeric type, e.g. float, double, int or `std::complex<float>`. * User defined scalar types are supported as well (see \ref user_defined_scalars "here"). * \tparam NumIndices_ Number of indices (i.e. rank of the tensor) * * The remaining template parameters are optional -- in most cases you don't have to worry about them. * \tparam Options_ A combination of either \b #RowMajor or \b #ColMajor, and of either * \b #AutoAlign or \b #DontAlign. * The former controls \ref TopicStorageOrders "storage order", and defaults to column-major. The latter controls alignment, which is required * for vectorization. It defaults to aligning tensors. Note that tensors currently do not support any operations that profit from vectorization. * Support for such operations (i.e. adding two tensors etc.) is planned. * * You can access elements of tensors using normal subscripting: * * \code * Eigen::Tensor<double, 4> t(10, 10, 10, 10); * t(0, 1, 2, 3) = 42.0; * \endcode * * 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_TENSOR_PLUGIN. * * <i><b>Some notes:</b></i> * * <dl> * <dt><b>Relation to other parts of Eigen:</b></dt> * <dd>The midterm development goal for this class is to have a similar hierarchy as Eigen uses for matrices, so that * taking blocks or using tensors in expressions is easily possible, including an interface with the vector/matrix code * by providing .asMatrix() and .asVector() (or similar) methods for rank 2 and 1 tensors. However, currently, the %Tensor * class does not provide any of these features and is only available as a stand-alone class that just allows for * coefficient access. Also, when fixed-size tensors are implemented, the number of template arguments is likely to * change dramatically.</dd> * </dl> * * \ref TopicStorageOrders
*/
// This makes EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED // work, because that uses base().coeffRef() - and we don't yet // implement a similar class hierarchy inline Self& base() { return *this; } inlineconst Self& base() const { return *this; }
#if EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes>
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& coeff(Index firstIndex, Index secondIndex, IndexTypes... otherIndices) const
{ // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor.
EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) return coeff(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}});
} #endif
// normal indices
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& coeff(const array<Index, NumIndices>& indices) const
{
eigen_internal_assert(checkIndexRange(indices)); return m_storage.data()[linearizedIndex(indices)];
}
#if EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline Scalar& coeffRef(Index firstIndex, Index secondIndex, IndexTypes... otherIndices)
{ // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor.
EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) return coeffRef(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}});
} #endif
// normal indices
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& coeffRef(const array<Index, NumIndices>& indices)
{
eigen_internal_assert(checkIndexRange(indices)); return m_storage.data()[linearizedIndex(indices)];
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE const Scalar& operator[](Index index) const
{ // The bracket operator is only for vectors, use the parenthesis operator instead.
EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE); return coeff(index);
}
#if EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> inline Scalar& operator()(Index firstIndex, Index secondIndex, IndexTypes... otherIndices)
{ // The number of indices used to access a tensor coefficient must be equal to the rank of the tensor.
EIGEN_STATIC_ASSERT(sizeof...(otherIndices) + 2 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE) returnoperator()(array<Index, NumIndices>{{firstIndex, secondIndex, otherIndices...}});
} #else
EIGEN_DEVICE_FUNC
EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1)
{ return coeffRef(array<Index, 2>(i0, i1));
}
EIGEN_DEVICE_FUNC
EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2)
{ return coeffRef(array<Index, 3>(i0, i1, i2));
}
EIGEN_DEVICE_FUNC
EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3)
{ return coeffRef(array<Index, 4>(i0, i1, i2, i3));
}
EIGEN_DEVICE_FUNC
EIGEN_STRONG_INLINE Scalar& operator()(Index i0, Index i1, Index i2, Index i3, Index i4)
{ return coeffRef(array<Index, 5>(i0, i1, i2, i3, i4));
} #endif
// normal indices
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& operator()(const array<Index, NumIndices>& indices)
{ return coeffRef(indices);
}
EIGEN_DEVICE_FUNC EIGEN_STRONG_INLINE Scalar& operator[](Index index)
{ // The bracket operator is only for vectors, use the parenthesis operator instead
EIGEN_STATIC_ASSERT(NumIndices == 1, YOU_MADE_A_PROGRAMMING_MISTAKE) return coeffRef(index);
}
#if EIGEN_HAS_VARIADIC_TEMPLATES template<typename... IndexTypes> EIGEN_DEVICE_FUNC void resize(Index firstDimension, IndexTypes... otherDimensions)
{ // The number of dimensions used to resize a tensor must be equal to the rank of the tensor.
EIGEN_STATIC_ASSERT(sizeof...(otherDimensions) + 1 == NumIndices, YOU_MADE_A_PROGRAMMING_MISTAKE)
resize(array<Index, NumIndices>{{firstDimension, otherDimensions...}});
} #endif
/** Normal Dimension */
EIGEN_DEVICE_FUNC void resize(const array<Index, NumIndices>& dimensions)
{ int i;
Index size = Index(1); for (i = 0; i < NumIndices; i++) {
internal::check_rows_cols_for_overflow<Dynamic>::run(size, dimensions[i]);
size *= dimensions[i];
} #ifdef EIGEN_INITIALIZE_COEFFS bool size_changed = size != this->size();
m_storage.resize(size, dimensions); if(size_changed) EIGEN_INITIALIZE_COEFFS_IF_THAT_OPTION_IS_ENABLED #else
m_storage.resize(size, dimensions); #endif
}
// Why this overload, DSizes is derived from array ??? //
EIGEN_DEVICE_FUNC void resize(const DSizes<Index, NumIndices>& dimensions) {
array<Index, NumIndices> dims; for (int i = 0; i < NumIndices; ++i) {
dims[i] = dimensions[i];
}
resize(dims);
}
EIGEN_DEVICE_FUNC void resize()
{
EIGEN_STATIC_ASSERT(NumIndices == 0, YOU_MADE_A_PROGRAMMING_MISTAKE); // Nothing to do: rank 0 tensors have fixed size
}
bool checkIndexRange(const array<Index, NumIndices>& indices) const
{ using internal::array_apply_and_reduce; using internal::array_zip_and_reduce; using internal::greater_equal_zero_op; using internal::logical_and_op; using internal::lesser_op;
return // check whether the indices are all >= 0
array_apply_and_reduce<logical_and_op, greater_equal_zero_op>(indices) && // check whether the indices fit in the dimensions
array_zip_and_reduce<logical_and_op, lesser_op>(indices, m_storage.dimensions());
}
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