ext/pybind11/docs/advanced/cast/eigen.rst - testing/jenkins-gem5-prod - Git at Google

 Eigen
 #####

 `Eigen <http://eigen.tuxfamily.org>`_ is C++ header-based library for dense and
 sparse linear algebra. Due to its popularity and widespread adoption, pybind11
 provides transparent conversion and limited mapping support between Eigen and
 Scientific Python linear algebra data types.

 To enable the built-in Eigen support you must include the optional header file
 :file:`pybind11/eigen.h`.

 Pass-by-value
 =============

 When binding a function with ordinary Eigen dense object arguments (for
 example, ``Eigen::MatrixXd``), pybind11 will accept any input value that is
 already (or convertible to) a ``numpy.ndarray`` with dimensions compatible with
 the Eigen type, copy its values into a temporary Eigen variable of the
 appropriate type, then call the function with this temporary variable.

 Sparse matrices are similarly copied to or from
 ``scipy.sparse.csr_matrix``/``scipy.sparse.csc_matrix`` objects.

 Pass-by-reference
 =================

 One major limitation of the above is that every data conversion implicitly
 involves a copy, which can be both expensive (for large matrices) and disallows
 binding functions that change their (Matrix) arguments.  Pybind11 allows you to
 work around this by using Eigen's ``Eigen::Ref<MatrixType>`` class much as you
 would when writing a function taking a generic type in Eigen itself (subject to
 some limitations discussed below).

 When calling a bound function accepting a ``Eigen::Ref<const MatrixType>``
 type, pybind11 will attempt to avoid copying by using an ``Eigen::Map`` object
 that maps into the source ``numpy.ndarray`` data: this requires both that the
 data types are the same (e.g. ``dtype='float64'`` and ``MatrixType::Scalar`` is
 ``double``); and that the storage is layout compatible.  The latter limitation
 is discussed in detail in the section below, and requires careful
 consideration: by default, numpy matrices and eigen matrices are *not* storage
 compatible.

 If the numpy matrix cannot be used as is (either because its types differ, e.g.
 passing an array of integers to an Eigen paramater requiring doubles, or
 because the storage is incompatible), pybind11 makes a temporary copy and
 passes the copy instead.

 When a bound function parameter is instead ``Eigen::Ref<MatrixType>`` (note the
 lack of ``const``), pybind11 will only allow the function to be called if it
 can be mapped *and* if the numpy array is writeable (that is
 ``a.flags.writeable`` is true).  Any access (including modification) made to
 the passed variable will be transparently carried out directly on the
 ``numpy.ndarray``.

 This means you can can write code such as the following and have it work as
 expected:

 .. code-block:: cpp

     void scale_by_2(Eigen::Ref<Eigen::VectorXd> v) {
         v *= 2;
     }

 Note, however, that you will likely run into limitations due to numpy and
 Eigen's difference default storage order for data; see the below section on
 :ref:`storage_orders` for details on how to bind code that won't run into such
 limitations.

 .. note::

     Passing by reference is not supported for sparse types.

 Returning values to Python
 ==========================

 When returning an ordinary dense Eigen matrix type to numpy (e.g.
 ``Eigen::MatrixXd`` or ``Eigen::RowVectorXf``) pybind11 keeps the matrix and
 returns a numpy array that directly references the Eigen matrix: no copy of the
 data is performed.  The numpy array will have ``array.flags.owndata`` set to
 ``False`` to indicate that it does not own the data, and the lifetime of the
 stored Eigen matrix will be tied to the returned ``array``.

 If you bind a function with a non-reference, ``const`` return type (e.g.
 ``const Eigen::MatrixXd``), the same thing happens except that pybind11 also
 sets the numpy array's ``writeable`` flag to false.

 If you return an lvalue reference or pointer, the usual pybind11 rules apply,
 as dictated by the binding function's return value policy (see the
 documentation on :ref:`return_value_policies` for full details).  That means,
 without an explicit return value policy, lvalue references will be copied and
 pointers will be managed by pybind11.  In order to avoid copying, you should
 explictly specify an appropriate return value policy, as in the following
 example:

 .. code-block:: cpp

     class MyClass {
         Eigen::MatrixXd big_mat = Eigen::MatrixXd::Zero(10000, 10000);
     public:
         Eigen::MatrixXd &getMatrix() { return big_mat; }
         const Eigen::MatrixXd &viewMatrix() { return big_mat; }
     };

     // Later, in binding code:
     py::class_<MyClass>(m, "MyClass")
         .def(py::init<>())
         .def("copy_matrix", &MyClass::getMatrix) // Makes a copy!
         .def("get_matrix", &MyClass::getMatrix, py::return_value_policy::reference_internal)
         .def("view_matrix", &MyClass::viewMatrix, py::return_value_policy::reference_internal)
         ;

 .. code-block:: python

     a = MyClass()
     m = a.get_matrix()   # flags.writeable = True,  flags.owndata = False
     v = a.view_matrix()  # flags.writeable = False, flags.owndata = False
     c = a.copy_matrix()  # flags.writeable = True,  flags.owndata = True
     # m[5,6] and v[5,6] refer to the same element, c[5,6] does not.

 Note in this example that ``py::return_value_policy::reference_internal`` is
 used to tie the life of the MyClass object to the life of the returned arrays.

 You may also return an ``Eigen::Ref``, ``Eigen::Map`` or other map-like Eigen
 object (for example, the return value of ``matrix.block()`` and related
 methods) that map into a dense Eigen type.  When doing so, the default
 behaviour of pybind11 is to simply reference the returned data: you must take
 care to ensure that this data remains valid!  You may ask pybind11 to
 explicitly *copy* such a return value by using the
 ``py::return_value_policy::copy`` policy when binding the function.  You may
 also use ``py::return_value_policy::reference_internal`` or a
 ``py::keep_alive`` to ensure the data stays valid as long as the returned numpy
 array does.

 When returning such a reference of map, pybind11 additionally respects the
 readonly-status of the returned value, marking the numpy array as non-writeable
 if the reference or map was itself read-only.

 .. note::

     Sparse types are always copied when returned.

 .. _storage_orders:

 Storage orders
 ==============

 Passing arguments via ``Eigen::Ref`` has some limitations that you must be
 aware of in order to effectively pass matrices by reference.  First and
 foremost is that the default ``Eigen::Ref<MatrixType>`` class requires
 contiguous storage along columns (for column-major types, the default in Eigen)
 or rows if ``MatrixType`` is specifically an ``Eigen::RowMajor`` storage type.
 The former, Eigen's default, is incompatible with ``numpy``'s default row-major
 storage, and so you will not be able to pass numpy arrays to Eigen by reference
 without making one of two changes.

 (Note that this does not apply to vectors (or column or row matrices): for such
 types the "row-major" and "column-major" distinction is meaningless).

 The first approach is to change the use of ``Eigen::Ref<MatrixType>`` to the
 more general ``Eigen::Ref<MatrixType, 0, Eigen::Stride<Eigen::Dynamic,
 Eigen::Dynamic>>`` (or similar type with a fully dynamic stride type in the
 third template argument).  Since this is a rather cumbersome type, pybind11
 provides a ``py::EigenDRef<MatrixType>`` type alias for your convenience (along
 with EigenDMap for the equivalent Map, and EigenDStride for just the stride
 type).

 This type allows Eigen to map into any arbitrary storage order.  This is not
 the default in Eigen for performance reasons: contiguous storage allows
 vectorization that cannot be done when storage is not known to be contiguous at
 compile time.  The default ``Eigen::Ref`` stride type allows non-contiguous
 storage along the outer dimension (that is, the rows of a column-major matrix
 or columns of a row-major matrix), but not along the inner dimension.

 This type, however, has the added benefit of also being able to map numpy array
 slices.  For example, the following (contrived) example uses Eigen with a numpy
 slice to multiply by 2 all coefficients that are both on even rows (0, 2, 4,
 ...) and in columns 2, 5, or 8:

 .. code-block:: cpp

     m.def("scale", [](py::EigenDRef<Eigen::MatrixXd> m, double c) { m *= c; });

 .. code-block:: python

     # a = np.array(...)
     scale_by_2(myarray[0::2, 2:9:3])

 The second approach to avoid copying is more intrusive: rearranging the
 underlying data types to not run into the non-contiguous storage problem in the
 first place.  In particular, that means using matrices with ``Eigen::RowMajor``
 storage, where appropriate, such as:

 .. code-block:: cpp

     using RowMatrixXd = Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor>;
     // Use RowMatrixXd instead of MatrixXd

 Now bound functions accepting ``Eigen::Ref<RowMatrixXd>`` arguments will be
 callable with numpy's (default) arrays without involving a copying.

 You can, alternatively, change the storage order that numpy arrays use by
 adding the ``order='F'`` option when creating an array:

 .. code-block:: python

     myarray = np.array(source, order='F')

 Such an object will be passable to a bound function accepting an
 ``Eigen::Ref<MatrixXd>`` (or similar column-major Eigen type).

 One major caveat with this approach, however, is that it is not entirely as
 easy as simply flipping all Eigen or numpy usage from one to the other: some
 operations may alter the storage order of a numpy array.  For example, ``a2 =
 array.transpose()`` results in ``a2`` being a view of ``array`` that references
 the same data, but in the opposite storage order!

 While this approach allows fully optimized vectorized calculations in Eigen, it
 cannot be used with array slices, unlike the first approach.

 When *returning* a matrix to Python (either a regular matrix, a reference via
 ``Eigen::Ref<>``, or a map/block into a matrix), no special storage
 consideration is required: the created numpy array will have the required
 stride that allows numpy to properly interpret the array, whatever its storage
 order.

 Failing rather than copying
 ===========================

 The default behaviour when binding ``Eigen::Ref<const MatrixType>`` eigen
 references is to copy matrix values when passed a numpy array that does not
 conform to the element type of ``MatrixType`` or does not have a compatible
 stride layout.  If you want to explicitly avoid copying in such a case, you
 should bind arguments using the ``py::arg().noconvert()`` annotation (as
 described in the :ref:`nonconverting_arguments` documentation).

 The following example shows an example of arguments that don't allow data
 copying to take place:

 .. code-block:: cpp

     // The method and function to be bound:
     class MyClass {
         // ...
         double some_method(const Eigen::Ref<const MatrixXd> &matrix) { /* ... */ }
     };
     float some_function(const Eigen::Ref<const MatrixXf> &big,
                         const Eigen::Ref<const MatrixXf> &small) {
         // ...
     }

     // The associated binding code:
     using namespace pybind11::literals; // for "arg"_a
     py::class_<MyClass>(m, "MyClass")
         // ... other class definitions
         .def("some_method", &MyClass::some_method, py::arg().noconvert());

     m.def("some_function", &some_function,
         "big"_a.noconvert(), // <- Don't allow copying for this arg
         "small"_a            // <- This one can be copied if needed
     );

 With the above binding code, attempting to call the the ``some_method(m)``
 method on a ``MyClass`` object, or attempting to call ``some_function(m, m2)``
 will raise a ``RuntimeError`` rather than making a temporary copy of the array.
 It will, however, allow the ``m2`` argument to be copied into a temporary if
 necessary.

 Note that explicitly specifying ``.noconvert()`` is not required for *mutable*
 Eigen references (e.g. ``Eigen::Ref<MatrixXd>`` without ``const`` on the
 ``MatrixXd``): mutable references will never be called with a temporary copy.

 Vectors versus column/row matrices
 ==================================

 Eigen and numpy have fundamentally different notions of a vector.  In Eigen, a
 vector is simply a matrix with the number of columns or rows set to 1 at
 compile time (for a column vector or row vector, respectively).  Numpy, in
 contast, has comparable 2-dimensional 1xN and Nx1 arrays, but *also* has
 1-dimensional arrays of size N.

 When passing a 2-dimensional 1xN or Nx1 array to Eigen, the Eigen type must
 have matching dimensions: That is, you cannot pass a 2-dimensional Nx1 numpy
 array to an Eigen value expecting a row vector, or a 1xN numpy array as a
 column vector argument.

 On the other hand, pybind11 allows you to pass 1-dimensional arrays of length N
 as Eigen parameters.  If the Eigen type can hold a column vector of length N it
 will be passed as such a column vector.  If not, but the Eigen type constraints
 will accept a row vector, it will be passed as a row vector.  (The column
 vector takes precendence when both are supported, for example, when passing a
 1D numpy array to a MatrixXd argument).  Note that the type need not be
 expicitly a vector: it is permitted to pass a 1D numpy array of size 5 to an
 Eigen ``Matrix<double, Dynamic, 5>``: you would end up with a 1x5 Eigen matrix.
 Passing the same to an ``Eigen::MatrixXd`` would result in a 5x1 Eigen matrix.

 When returning an eigen vector to numpy, the conversion is ambiguous: a row
 vector of length 4 could be returned as either a 1D array of length 4, or as a
 2D array of size 1x4.  When encoutering such a situation, pybind11 compromises
 by considering the returned Eigen type: if it is a compile-time vector--that
 is, the type has either the number of rows or columns set to 1 at compile
 time--pybind11 converts to a 1D numpy array when returning the value.  For
 instances that are a vector only at run-time (e.g. ``MatrixXd``,
 ``Matrix<float, Dynamic, 4>``), pybind11 returns the vector as a 2D array to
 numpy.  If this isn't want you want, you can use ``array.reshape(...)`` to get
 a view of the same data in the desired dimensions.

 .. seealso::

     The file :file:`tests/test_eigen.cpp` contains a complete example that
     shows how to pass Eigen sparse and dense data types in more detail.
	Eigen
	#####

	`Eigen <http://eigen.tuxfamily.org>`_ is C++ header-based library for dense and
	sparse linear algebra. Due to its popularity and widespread adoption, pybind11
	provides transparent conversion and limited mapping support between Eigen and
	Scientific Python linear algebra data types.

	To enable the built-in Eigen support you must include the optional header file
	:file:`pybind11/eigen.h`.

	Pass-by-value
	=============

	When binding a function with ordinary Eigen dense object arguments (for
	example, ``Eigen::MatrixXd``), pybind11 will accept any input value that is
	already (or convertible to) a ``numpy.ndarray`` with dimensions compatible with
	the Eigen type, copy its values into a temporary Eigen variable of the
	appropriate type, then call the function with this temporary variable.

	Sparse matrices are similarly copied to or from
	``scipy.sparse.csr_matrix``/``scipy.sparse.csc_matrix`` objects.

	Pass-by-reference
	=================

	One major limitation of the above is that every data conversion implicitly
	involves a copy, which can be both expensive (for large matrices) and disallows
	binding functions that change their (Matrix) arguments. Pybind11 allows you to
	work around this by using Eigen's ``Eigen::Ref<MatrixType>`` class much as you
	would when writing a function taking a generic type in Eigen itself (subject to
	some limitations discussed below).

	When calling a bound function accepting a ``Eigen::Ref<const MatrixType>``
	type, pybind11 will attempt to avoid copying by using an ``Eigen::Map`` object
	that maps into the source ``numpy.ndarray`` data: this requires both that the
	data types are the same (e.g. ``dtype='float64'`` and ``MatrixType::Scalar`` is
	``double``); and that the storage is layout compatible. The latter limitation
	is discussed in detail in the section below, and requires careful
	consideration: by default, numpy matrices and eigen matrices are not storage
	compatible.

	If the numpy matrix cannot be used as is (either because its types differ, e.g.
	passing an array of integers to an Eigen paramater requiring doubles, or
	because the storage is incompatible), pybind11 makes a temporary copy and
	passes the copy instead.

	When a bound function parameter is instead ``Eigen::Ref<MatrixType>`` (note the
	lack of ``const``), pybind11 will only allow the function to be called if it
	can be mapped and if the numpy array is writeable (that is
	``a.flags.writeable`` is true). Any access (including modification) made to
	the passed variable will be transparently carried out directly on the
	``numpy.ndarray``.

	This means you can can write code such as the following and have it work as
	expected:

	.. code-block:: cpp

	void scale_by_2(Eigen::Ref<Eigen::VectorXd> v) {
	v *= 2;
	}

	Note, however, that you will likely run into limitations due to numpy and
	Eigen's difference default storage order for data; see the below section on
	:ref:`storage_orders` for details on how to bind code that won't run into such
	limitations.

	.. note::

	Passing by reference is not supported for sparse types.

	Returning values to Python
	==========================

	When returning an ordinary dense Eigen matrix type to numpy (e.g.
	``Eigen::MatrixXd`` or ``Eigen::RowVectorXf``) pybind11 keeps the matrix and
	returns a numpy array that directly references the Eigen matrix: no copy of the
	data is performed. The numpy array will have ``array.flags.owndata`` set to
	``False`` to indicate that it does not own the data, and the lifetime of the
	stored Eigen matrix will be tied to the returned ``array``.

	If you bind a function with a non-reference, ``const`` return type (e.g.
	``const Eigen::MatrixXd``), the same thing happens except that pybind11 also
	sets the numpy array's ``writeable`` flag to false.

	If you return an lvalue reference or pointer, the usual pybind11 rules apply,
	as dictated by the binding function's return value policy (see the
	documentation on :ref:`return_value_policies` for full details). That means,
	without an explicit return value policy, lvalue references will be copied and
	pointers will be managed by pybind11. In order to avoid copying, you should
	explictly specify an appropriate return value policy, as in the following
	example:

	.. code-block:: cpp

	class MyClass {
	Eigen::MatrixXd big_mat = Eigen::MatrixXd::Zero(10000, 10000);
	public:
	Eigen::MatrixXd &getMatrix() { return big_mat; }
	const Eigen::MatrixXd &viewMatrix() { return big_mat; }
	};

	// Later, in binding code:
	py::class_<MyClass>(m, "MyClass")
	.def(py::init<>())
	.def("copy_matrix", &MyClass::getMatrix) // Makes a copy!
	.def("get_matrix", &MyClass::getMatrix, py::return_value_policy::reference_internal)
	.def("view_matrix", &MyClass::viewMatrix, py::return_value_policy::reference_internal)
	;

	.. code-block:: python

	a = MyClass()
	m = a.get_matrix() # flags.writeable = True, flags.owndata = False
	v = a.view_matrix() # flags.writeable = False, flags.owndata = False
	c = a.copy_matrix() # flags.writeable = True, flags.owndata = True
	# m[5,6] and v[5,6] refer to the same element, c[5,6] does not.

	Note in this example that ``py::return_value_policy::reference_internal`` is
	used to tie the life of the MyClass object to the life of the returned arrays.

	You may also return an ``Eigen::Ref``, ``Eigen::Map`` or other map-like Eigen
	object (for example, the return value of ``matrix.block()`` and related
	methods) that map into a dense Eigen type. When doing so, the default
	behaviour of pybind11 is to simply reference the returned data: you must take
	care to ensure that this data remains valid! You may ask pybind11 to
	explicitly copy such a return value by using the
	``py::return_value_policy::copy`` policy when binding the function. You may
	also use ``py::return_value_policy::reference_internal`` or a
	``py::keep_alive`` to ensure the data stays valid as long as the returned numpy
	array does.

	When returning such a reference of map, pybind11 additionally respects the
	readonly-status of the returned value, marking the numpy array as non-writeable
	if the reference or map was itself read-only.

	.. note::

	Sparse types are always copied when returned.

	.. _storage_orders:

	Storage orders
	==============

	Passing arguments via ``Eigen::Ref`` has some limitations that you must be
	aware of in order to effectively pass matrices by reference. First and
	foremost is that the default ``Eigen::Ref<MatrixType>`` class requires
	contiguous storage along columns (for column-major types, the default in Eigen)
	or rows if ``MatrixType`` is specifically an ``Eigen::RowMajor`` storage type.
	The former, Eigen's default, is incompatible with ``numpy``'s default row-major
	storage, and so you will not be able to pass numpy arrays to Eigen by reference
	without making one of two changes.

	(Note that this does not apply to vectors (or column or row matrices): for such
	types the "row-major" and "column-major" distinction is meaningless).

	The first approach is to change the use of ``Eigen::Ref<MatrixType>`` to the
	more general ``Eigen::Ref<MatrixType, 0, Eigen::Stride<Eigen::Dynamic,
	Eigen::Dynamic>>`` (or similar type with a fully dynamic stride type in the
	third template argument). Since this is a rather cumbersome type, pybind11
	provides a ``py::EigenDRef<MatrixType>`` type alias for your convenience (along
	with EigenDMap for the equivalent Map, and EigenDStride for just the stride
	type).

	This type allows Eigen to map into any arbitrary storage order. This is not
	the default in Eigen for performance reasons: contiguous storage allows
	vectorization that cannot be done when storage is not known to be contiguous at
	compile time. The default ``Eigen::Ref`` stride type allows non-contiguous
	storage along the outer dimension (that is, the rows of a column-major matrix
	or columns of a row-major matrix), but not along the inner dimension.

	This type, however, has the added benefit of also being able to map numpy array
	slices. For example, the following (contrived) example uses Eigen with a numpy
	slice to multiply by 2 all coefficients that are both on even rows (0, 2, 4,
	...) and in columns 2, 5, or 8:

	.. code-block:: cpp

	m.def("scale", [](py::EigenDRef<Eigen::MatrixXd> m, double c) { m *= c; });

	.. code-block:: python

	# a = np.array(...)
	scale_by_2(myarray[0::2, 2:9:3])

	The second approach to avoid copying is more intrusive: rearranging the
	underlying data types to not run into the non-contiguous storage problem in the
	first place. In particular, that means using matrices with ``Eigen::RowMajor``
	storage, where appropriate, such as:

	.. code-block:: cpp

	using RowMatrixXd = Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor>;
	// Use RowMatrixXd instead of MatrixXd

	Now bound functions accepting ``Eigen::Ref<RowMatrixXd>`` arguments will be
	callable with numpy's (default) arrays without involving a copying.

	You can, alternatively, change the storage order that numpy arrays use by
	adding the ``order='F'`` option when creating an array:

	.. code-block:: python

	myarray = np.array(source, order='F')

	Such an object will be passable to a bound function accepting an
	``Eigen::Ref<MatrixXd>`` (or similar column-major Eigen type).

	One major caveat with this approach, however, is that it is not entirely as
	easy as simply flipping all Eigen or numpy usage from one to the other: some
	operations may alter the storage order of a numpy array. For example, ``a2 =
	array.transpose()`` results in ``a2`` being a view of ``array`` that references
	the same data, but in the opposite storage order!

	While this approach allows fully optimized vectorized calculations in Eigen, it
	cannot be used with array slices, unlike the first approach.

	When returning a matrix to Python (either a regular matrix, a reference via
	``Eigen::Ref<>``, or a map/block into a matrix), no special storage
	consideration is required: the created numpy array will have the required
	stride that allows numpy to properly interpret the array, whatever its storage
	order.

	Failing rather than copying
	===========================

	The default behaviour when binding ``Eigen::Ref<const MatrixType>`` eigen
	references is to copy matrix values when passed a numpy array that does not
	conform to the element type of ``MatrixType`` or does not have a compatible
	stride layout. If you want to explicitly avoid copying in such a case, you
	should bind arguments using the ``py::arg().noconvert()`` annotation (as
	described in the :ref:`nonconverting_arguments` documentation).

	The following example shows an example of arguments that don't allow data
	copying to take place:

	.. code-block:: cpp

	// The method and function to be bound:
	class MyClass {
	// ...
	double some_method(const Eigen::Ref<const MatrixXd> &matrix) { /* ... */ }
	};
	float some_function(const Eigen::Ref<const MatrixXf> &big,
	const Eigen::Ref<const MatrixXf> &small) {
	// ...
	}

	// The associated binding code:
	using namespace pybind11::literals; // for "arg"_a
	py::class_<MyClass>(m, "MyClass")
	// ... other class definitions
	.def("some_method", &MyClass::some_method, py::arg().noconvert());

	m.def("some_function", &some_function,
	"big"_a.noconvert(), // <- Don't allow copying for this arg
	"small"_a // <- This one can be copied if needed
	);

	With the above binding code, attempting to call the the ``some_method(m)``
	method on a ``MyClass`` object, or attempting to call ``some_function(m, m2)``
	will raise a ``RuntimeError`` rather than making a temporary copy of the array.
	It will, however, allow the ``m2`` argument to be copied into a temporary if
	necessary.

	Note that explicitly specifying ``.noconvert()`` is not required for mutable
	Eigen references (e.g. ``Eigen::Ref<MatrixXd>`` without ``const`` on the
	``MatrixXd``): mutable references will never be called with a temporary copy.

	Vectors versus column/row matrices
	==================================

	Eigen and numpy have fundamentally different notions of a vector. In Eigen, a
	vector is simply a matrix with the number of columns or rows set to 1 at
	compile time (for a column vector or row vector, respectively). Numpy, in
	contast, has comparable 2-dimensional 1xN and Nx1 arrays, but also has
	1-dimensional arrays of size N.

	When passing a 2-dimensional 1xN or Nx1 array to Eigen, the Eigen type must
	have matching dimensions: That is, you cannot pass a 2-dimensional Nx1 numpy
	array to an Eigen value expecting a row vector, or a 1xN numpy array as a
	column vector argument.

	On the other hand, pybind11 allows you to pass 1-dimensional arrays of length N
	as Eigen parameters. If the Eigen type can hold a column vector of length N it
	will be passed as such a column vector. If not, but the Eigen type constraints
	will accept a row vector, it will be passed as a row vector. (The column
	vector takes precendence when both are supported, for example, when passing a
	1D numpy array to a MatrixXd argument). Note that the type need not be
	expicitly a vector: it is permitted to pass a 1D numpy array of size 5 to an
	Eigen ``Matrix<double, Dynamic, 5>``: you would end up with a 1x5 Eigen matrix.
	Passing the same to an ``Eigen::MatrixXd`` would result in a 5x1 Eigen matrix.

	When returning an eigen vector to numpy, the conversion is ambiguous: a row
	vector of length 4 could be returned as either a 1D array of length 4, or as a
	2D array of size 1x4. When encoutering such a situation, pybind11 compromises
	by considering the returned Eigen type: if it is a compile-time vector--that
	is, the type has either the number of rows or columns set to 1 at compile
	time--pybind11 converts to a 1D numpy array when returning the value. For
	instances that are a vector only at run-time (e.g. ``MatrixXd``,
	``Matrix<float, Dynamic, 4>``), pybind11 returns the vector as a 2D array to
	numpy. If this isn't want you want, you can use ``array.reshape(...)`` to get
	a view of the same data in the desired dimensions.

	.. seealso::

	The file :file:`tests/test_eigen.cpp` contains a complete example that
	shows how to pass Eigen sparse and dense data types in more detail.