doc/C04_TutorialBlockOperations.dox - chromium.googlesource.com/external/gitlab.com/libeigen/eigen - Gitiles

 namespace Eigen {

 /** \page TutorialBlockOperations Tutorial page 4 - Block operations
     \ingroup Tutorial

 \li \b Previous: \ref TutorialArrayClass
 \li \b Next: (not yet written)

 This tutorial explains the essentials of Block operations together with many examples.

 \b Table \b of \b contents
   - \ref TutorialBlockOperationsWhatIs
     - \ref TutorialBlockOperationsFixedAndDynamicSize
   - \ref TutorialBlockOperationsSyntax
      - \ref TutorialBlockOperationsSyntaxColumnRows
      - \ref TutorialBlockOperationsSyntaxCorners


 \section TutorialBlockOperationsWhatIs What are Block operations?
 Block operations are a set of functions that provide an easy way to access a set of coefficients
 inside a \b Matrix or \link ArrayBase Array \endlink. A typical example is accessing a single row or
 column within a given matrix, as well as extracting a sub-matrix from the latter.

 Blocks are highly flexible and can be used both as \b rvalues and \b lvalues in expressions, simplifying
 the task of writing combined expressions with Eigen.

 \subsection TutorialBlockOperationsFixedAndDynamicSize Block operations and compile-time optimizations
 As said earlier, a block operation is a way of accessing a group of coefficients inside a Matrix or
 Array object. Eigen considers two different cases in order to provide compile-time optimization for
 block operations, depending on whether the the size of the block to be accessed is known at compile time or not.

 To deal with these two situations, for each type of block operation Eigen provides a default version that
 is able to work with run-time dependant block sizes and another one for block operations whose block size is
 known at compile-time.

 Even though both functions can be applied to fixed-size objects, it is advisable to use special block operations
 in this case, allowing Eigen to perform more optimizations at compile-time.

 \section TutorialBlockOperationsUsing Using block operations
 Block operations are implemented such that they are easy to use and combine with operators and other
 matrices or arrays.

 The most general block operation in Eigen is called \link DenseBase::block() .block() \endlink.
 This function returns a block of size <tt>(p,q)</tt> whose origin is at <tt>(i,j)</tt> by using
 the following syntax:

 <table class="tutorial_code" align="center">
 <tr><td align="center">\b Block \b operation</td>
 <td align="center">Default \b version</td>
 <td align="center">Optimized version when the<br>size is known at compile time</td></tr>
 <tr><td>Block of length <tt>(p,q)</tt>, starting at <tt>(i,j)</tt></td>
     <td>\code
 MatrixXf m;
 std::cout << m.block(i,j,p,q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.block<p,q>(i,j);\endcode </td>
 </tr>
 </table>

 Therefore, if we want to print the values of a block inside a matrix we can simply write:
 <table class="tutorial_code"><tr><td>
 \include Tutorial_BlockOperations_print_block.cpp
 </td>
 <td>
 Output:
 \verbinclude Tutorial_BlockOperations_print_block.out
 </td></tr></table>


 In the previous example the \link DenseBase::block() .block() \endlink function was employed
 to read the values inside matrix \p m . Blocks can also be used to perform operations and
 assignments within matrices or arrays of different size:

 <table class="tutorial_code"><tr><td>
 \include Tutorial_BlockOperations_block_assignment.cpp
 </td>
 <td>
 Output:
 \verbinclude Tutorial_BlockOperations_block_assignment.out
 </td></tr></table>


 Blocks can also be combined with matrices and arrays to create more complex expressions:

 \code
   MatrixXf m(3,3), n(2,2);
   MatrixXf p(3,3);

   m.block(0,0,2,2) = m.block(0,0,2,2) * n + p.block(1,1,2,2);
 \endcode

 It is important to point out that \link DenseBase::block() .block() \endlink is the
 general case for a block operation but there are many other useful block operations,
 as described in the next section.

 \section TutorialBlockOperationsSyntax Block operation syntax
 The following tables show a summary of Eigen's block operations and how they are applied to
 fixed- and dynamic-sized Eigen objects.

 \subsection TutorialBlockOperationsSyntaxColumnRows Columns and rows
 Other extremely useful block operations are \link DenseBase::col() .col() \endlink and
 \link DenseBase::row() .row() \endlink which provide access to a
 specific row or column. This is a special case in the sense that the syntax for fixed- and
 dynamic-sized objects is exactly the same:

 <table class="tutorial_code" align="center">
 <tr><td align="center">\b Block \b operation</td>
 <td align="center">Default version</td>
 <td align="center">Optimized version when the<br>size is known at compile time</td></tr>
 <tr><td>i<sup>th</sup> row
                     \link DenseBase::row() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.row(i);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.row(i);\endcode </td>
 </tr>
 <tr><td>j<sup>th</sup> column
                     \link DenseBase::col() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.col(j);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.col(j);\endcode </td>
 </tr>
 </table>

 A simple example demonstrating these feature follows:

 <table class="tutorial_code"><tr><td>
 C++ code:
 \include Tutorial_BlockOperations_colrow.cpp
 </td>
 <td>
 Output:
 \include Tutorial_BlockOperations_colrow.out
 </td></tr></table>


 \b NOTE: the argument for \p col() and \p row() is the index of the column or row to be accessed,
 starting at 0. Therefore, \p col(0) will access the first column and \p col(1) the second one.


 \subsection TutorialBlockOperationsSyntaxCorners Corner-related operations
 <table class="tutorial_code" align="center">
 <tr><td align="center">\b Block \b operation</td>
 <td align="center">Default version</td>
 <td align="center">Optimized version when the<br>size is known at compile time</td></tr>
 <tr><td>Top-left p by q block \link DenseBase::topLeftCorner() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.topLeftCorner(p,q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.topLeftCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Bottom-left p by q block
               \link DenseBase::bottomLeftCorner() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.bottomLeftCorner(p,q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.bottomLeftCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Top-right p by q block
               \link DenseBase::topRightCorner() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.topRightCorner(p,q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.topRightCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Bottom-right p by q block
                \link DenseBase::bottomRightCorner() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.bottomRightCorner(p,q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.bottomRightCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Block containing the first q rows
                    \link DenseBase::topRows() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.topRows(q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.topRows<q>();\endcode </td>
 </tr>
 <tr><td>Block containing the last q rows
                     \link DenseBase::bottomRows() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.bottomRows(q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.bottomRows<q>();\endcode </td>
 </tr>
 <tr><td>Block containing the first p columns
                     \link DenseBase::leftCols() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.leftCols(p);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.leftCols<p>();\endcode </td>
 </tr>
 <tr><td>Block containing the last q columns
                     \link DenseBase::rightCols() * \endlink</td>
     <td>\code
 MatrixXf m;
 std::cout << m.rightCols(q);\endcode </td>
     <td>\code
 Matrix3f m;
 std::cout << m.rightCols<q>();\endcode </td>
 </tr>
 </table>


 Here is a simple example showing the power of the operations presented above:

 <table class="tutorial_code"><tr><td>
 C++ code:
 \include Tutorial_BlockOperations_corner.cpp
 </td>
 <td>
 Output:
 \include Tutorial_BlockOperations_corner.out
 </td></tr></table>


 \subsection TutorialBlockOperationsSyntaxVectors Block operations for vectors
 Eigen also provides a set of block operations designed specifically for vectors:

 <table class="tutorial_code" align="center">
 <tr><td align="center">\b Block \b operation</td>
 <td align="center">Default version</td>
 <td align="center">Optimized version when the<br>size is known at compile time</td></tr>
 <tr><td>Block containing the first \p n elements
                     \link DenseBase::head() * \endlink</td>
     <td>\code
 VectorXf v;
 std::cout << v.head(n);\endcode </td>
     <td>\code
 Vector3f v;
 std::cout << v.head<n>();\endcode </td>
 </tr>
 <tr><td>Block containing the last \p n elements
                     \link DenseBase::tail() * \endlink</td>
     <td>\code
 VectorXf v;
 std::cout << v.tail(n);\endcode </td>
     <td>\code
 Vector3f m;
 std::cout << v.tail<n>();\endcode </td>
 </tr>
 <tr><td>Block containing \p n elements, starting at position \p i
                     \link DenseBase::segment() * \endlink</td>
     <td>\code
 VectorXf v;
 std::cout << v.segment(i,n);\endcode </td>
     <td>\code
 Vector3f m;
 std::cout << v.segment<n>(i);\endcode </td>
 </tr>
 </table>


 An example is presented below:
 <table class="tutorial_code"><tr><td>
 C++ code:
 \include Tutorial_BlockOperations_vector.cpp
 </td>
 <td>
 Output:
 \include Tutorial_BlockOperations_vector.out
 </td></tr></table>


 */

 }
	namespace Eigen {

	/** \page TutorialBlockOperations Tutorial page 4 - Block operations
	\ingroup Tutorial

	\li \b Previous: \ref TutorialArrayClass
	\li \b Next: (not yet written)

	This tutorial explains the essentials of Block operations together with many examples.

	\b Table \b of \b contents
	- \ref TutorialBlockOperationsWhatIs
	- \ref TutorialBlockOperationsFixedAndDynamicSize
	- \ref TutorialBlockOperationsSyntax
	- \ref TutorialBlockOperationsSyntaxColumnRows
	- \ref TutorialBlockOperationsSyntaxCorners


	\section TutorialBlockOperationsWhatIs What are Block operations?
	Block operations are a set of functions that provide an easy way to access a set of coefficients
	inside a \b Matrix or \link ArrayBase Array \endlink. A typical example is accessing a single row or
	column within a given matrix, as well as extracting a sub-matrix from the latter.

	Blocks are highly flexible and can be used both as \b rvalues and \b lvalues in expressions, simplifying
	the task of writing combined expressions with Eigen.

	\subsection TutorialBlockOperationsFixedAndDynamicSize Block operations and compile-time optimizations
	As said earlier, a block operation is a way of accessing a group of coefficients inside a Matrix or
	Array object. Eigen considers two different cases in order to provide compile-time optimization for
	block operations, depending on whether the the size of the block to be accessed is known at compile time or not.

	To deal with these two situations, for each type of block operation Eigen provides a default version that
	is able to work with run-time dependant block sizes and another one for block operations whose block size is
	known at compile-time.

	Even though both functions can be applied to fixed-size objects, it is advisable to use special block operations
	in this case, allowing Eigen to perform more optimizations at compile-time.

	\section TutorialBlockOperationsUsing Using block operations
	Block operations are implemented such that they are easy to use and combine with operators and other
	matrices or arrays.

	The most general block operation in Eigen is called \link DenseBase::block() .block() \endlink.
	This function returns a block of size <tt>(p,q)</tt> whose origin is at <tt>(i,j)</tt> by using
	the following syntax:

	<table class="tutorial_code" align="center">
	<tr><td align="center">\b Block \b operation</td>
	<td align="center">Default \b version</td>
	<td align="center">Optimized version when the<br>size is known at compile time</td></tr>
	<tr><td>Block of length <tt>(p,q)</tt>, starting at <tt>(i,j)</tt></td>
	<td>\code
	MatrixXf m;
	std::cout << m.block(i,j,p,q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.block<p,q>(i,j);\endcode </td>
	</tr>
	</table>

	Therefore, if we want to print the values of a block inside a matrix we can simply write:
	<table class="tutorial_code"><tr><td>
	\include Tutorial_BlockOperations_print_block.cpp
	</td>
	<td>
	Output:
	\verbinclude Tutorial_BlockOperations_print_block.out
	</td></tr></table>


	In the previous example the \link DenseBase::block() .block() \endlink function was employed
	to read the values inside matrix \p m . Blocks can also be used to perform operations and
	assignments within matrices or arrays of different size:

	<table class="tutorial_code"><tr><td>
	\include Tutorial_BlockOperations_block_assignment.cpp
	</td>
	<td>
	Output:
	\verbinclude Tutorial_BlockOperations_block_assignment.out
	</td></tr></table>


	Blocks can also be combined with matrices and arrays to create more complex expressions:

	\code
	MatrixXf m(3,3), n(2,2);
	MatrixXf p(3,3);

	m.block(0,0,2,2) = m.block(0,0,2,2) * n + p.block(1,1,2,2);
	\endcode

	It is important to point out that \link DenseBase::block() .block() \endlink is the
	general case for a block operation but there are many other useful block operations,
	as described in the next section.

	\section TutorialBlockOperationsSyntax Block operation syntax
	The following tables show a summary of Eigen's block operations and how they are applied to
	fixed- and dynamic-sized Eigen objects.

	\subsection TutorialBlockOperationsSyntaxColumnRows Columns and rows
	Other extremely useful block operations are \link DenseBase::col() .col() \endlink and
	\link DenseBase::row() .row() \endlink which provide access to a
	specific row or column. This is a special case in the sense that the syntax for fixed- and
	dynamic-sized objects is exactly the same:

	<table class="tutorial_code" align="center">
	<tr><td align="center">\b Block \b operation</td>
	<td align="center">Default version</td>
	<td align="center">Optimized version when the<br>size is known at compile time</td></tr>
	<tr><td>i<sup>th</sup> row
	\link DenseBase::row() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.row(i);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.row(i);\endcode </td>
	</tr>
	<tr><td>j<sup>th</sup> column
	\link DenseBase::col() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.col(j);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.col(j);\endcode </td>
	</tr>
	</table>

	A simple example demonstrating these feature follows:

	<table class="tutorial_code"><tr><td>
	C++ code:
	\include Tutorial_BlockOperations_colrow.cpp
	</td>
	<td>
	Output:
	\include Tutorial_BlockOperations_colrow.out
	</td></tr></table>


	\b NOTE: the argument for \p col() and \p row() is the index of the column or row to be accessed,
	starting at 0. Therefore, \p col(0) will access the first column and \p col(1) the second one.


	\subsection TutorialBlockOperationsSyntaxCorners Corner-related operations
	<table class="tutorial_code" align="center">
	<tr><td align="center">\b Block \b operation</td>
	<td align="center">Default version</td>
	<td align="center">Optimized version when the<br>size is known at compile time</td></tr>
	<tr><td>Top-left p by q block \link DenseBase::topLeftCorner() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.topLeftCorner(p,q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.topLeftCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Bottom-left p by q block
	\link DenseBase::bottomLeftCorner() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.bottomLeftCorner(p,q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.bottomLeftCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Top-right p by q block
	\link DenseBase::topRightCorner() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.topRightCorner(p,q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.topRightCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Bottom-right p by q block
	\link DenseBase::bottomRightCorner() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.bottomRightCorner(p,q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.bottomRightCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Block containing the first q rows
	\link DenseBase::topRows() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.topRows(q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.topRows<q>();\endcode </td>
	</tr>
	<tr><td>Block containing the last q rows
	\link DenseBase::bottomRows() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.bottomRows(q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.bottomRows<q>();\endcode </td>
	</tr>
	<tr><td>Block containing the first p columns
	\link DenseBase::leftCols() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.leftCols(p);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.leftCols<p>();\endcode </td>
	</tr>
	<tr><td>Block containing the last q columns
	\link DenseBase::rightCols() * \endlink</td>
	<td>\code
	MatrixXf m;
	std::cout << m.rightCols(q);\endcode </td>
	<td>\code
	Matrix3f m;
	std::cout << m.rightCols<q>();\endcode </td>
	</tr>
	</table>


	Here is a simple example showing the power of the operations presented above:

	<table class="tutorial_code"><tr><td>
	C++ code:
	\include Tutorial_BlockOperations_corner.cpp
	</td>
	<td>
	Output:
	\include Tutorial_BlockOperations_corner.out
	</td></tr></table>








	\subsection TutorialBlockOperationsSyntaxVectors Block operations for vectors
	Eigen also provides a set of block operations designed specifically for vectors:

	<table class="tutorial_code" align="center">
	<tr><td align="center">\b Block \b operation</td>
	<td align="center">Default version</td>
	<td align="center">Optimized version when the<br>size is known at compile time</td></tr>
	<tr><td>Block containing the first \p n elements
	\link DenseBase::head() * \endlink</td>
	<td>\code
	VectorXf v;
	std::cout << v.head(n);\endcode </td>
	<td>\code
	Vector3f v;
	std::cout << v.head<n>();\endcode </td>
	</tr>
	<tr><td>Block containing the last \p n elements
	\link DenseBase::tail() * \endlink</td>
	<td>\code
	VectorXf v;
	std::cout << v.tail(n);\endcode </td>
	<td>\code
	Vector3f m;
	std::cout << v.tail<n>();\endcode </td>
	</tr>
	<tr><td>Block containing \p n elements, starting at position \p i
	\link DenseBase::segment() * \endlink</td>
	<td>\code
	VectorXf v;
	std::cout << v.segment(i,n);\endcode </td>
	<td>\code
	Vector3f m;
	std::cout << v.segment<n>(i);\endcode </td>
	</tr>
	</table>


	An example is presented below:
	<table class="tutorial_code"><tr><td>
	C++ code:
	\include Tutorial_BlockOperations_vector.cpp
	</td>
	<td>
	Output:
	\include Tutorial_BlockOperations_vector.out
	</td></tr></table>


	*/

	}