doc/TutorialBlockOperations.dox - eigen - Git at Google

 namespace Eigen {

 /** \eigenManualPage TutorialBlockOperations Block operations

 This page explains the essentials of block operations.
 A block is a rectangular part of a matrix or array. Blocks expressions can be used both
 as rvalues and as lvalues. As usual with Eigen expressions, this abstraction has zero runtime cost
 provided that you let your compiler optimize.

 \eigenAutoToc

 \section TutorialBlockOperationsUsing Using block operations

 The most general block operation in Eigen is called \link DenseBase::block() .block() \endlink.
 There are two versions, whose syntax is as follows:

 <table class="manual">
 <tr><th>\b %Block \b operation</td>
 <th>Version constructing a \n dynamic-size block expression</th>
 <th>Version constructing a \n fixed-size block expression</th></tr>
 <tr><td>%Block of size <tt>(p,q)</tt>, starting at <tt>(i,j)</tt></td>
     <td>\code
 matrix.block(i,j,p,q);\endcode </td>
     <td>\code
 matrix.block<p,q>(i,j);\endcode </td>
 </tr>
 </table>

 As always in Eigen, indices start at 0.

 Both versions can be used on fixed-size and dynamic-size matrices and arrays.
 These two expressions are semantically equivalent.
 The only difference is that the fixed-size version will typically give you faster code if the block size is small,
 but requires this size to be known at compile time.

 The following program uses the dynamic-size and fixed-size versions to print the values of several blocks inside a
 matrix.

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_BlockOperations_print_block.cpp
 </td>
 <td>
 \verbinclude Tutorial_BlockOperations_print_block.out
 </td></tr></table>

 In the above example the \link DenseBase::block() .block() \endlink function was employed as a \em rvalue, i.e.
 it was only read from. However, blocks can also be used as \em lvalues, meaning that you can assign to a block.

 This is illustrated in the following example. This example also demonstrates blocks in arrays, which works exactly like the above-demonstrated blocks in matrices.

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

 While the \link DenseBase::block() .block() \endlink method can be used for any block operation, there are
 other methods for special cases, providing more specialized API and/or better performance. On the topic of performance, all what
 matters is that you give Eigen as much information as possible at compile time. For example, if your block is a single whole column in a matrix,
 using the specialized \link DenseBase::col() .col() \endlink function described below lets Eigen know that, which can give it optimization opportunities.

 The rest of this page describes these specialized methods.

 \section TutorialBlockOperationsSyntaxColumnRows Columns and rows

 Individual columns and rows are special cases of blocks. Eigen provides methods to easily address them:
 \link DenseBase::col() .col() \endlink and \link DenseBase::row() .row()\endlink.

 <table class="manual">
 <tr><th>%Block operation</th>
 <th>Method</th>
 <tr><td>i<sup>th</sup> row
                     \link DenseBase::row() * \endlink</td>
     <td>\code
 matrix.row(i);\endcode </td>
 </tr>
 <tr><td>j<sup>th</sup> column
                     \link DenseBase::col() * \endlink</td>
     <td>\code
 matrix.col(j);\endcode </td>
 </tr>
 </table>

 The argument for \p col() and \p row() is the index of the column or row to be accessed. As always in Eigen, indices start at 0.

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_BlockOperations_colrow.cpp
 </td>
 <td>
 \verbinclude Tutorial_BlockOperations_colrow.out
 </td></tr></table>

 That example also demonstrates that block expressions (here columns) can be used in arithmetic like any other expression.


 \section TutorialBlockOperationsSyntaxCorners Corner-related operations

 Eigen also provides special methods for blocks that are flushed against one of the corners or sides of a
 matrix or array. For instance, \link DenseBase::topLeftCorner() .topLeftCorner() \endlink can be used to refer
 to a block in the top-left corner of a matrix.

 The different possibilities are summarized in the following table:

 <table class="manual">
 <tr><th>%Block \b operation</td>
 <th>Version constructing a \n dynamic-size block expression</th>
 <th>Version constructing a \n fixed-size block expression</th></tr>
 <tr><td>Top-left p by q block \link DenseBase::topLeftCorner() * \endlink</td>
     <td>\code
 matrix.topLeftCorner(p,q);\endcode </td>
     <td>\code
 matrix.topLeftCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Bottom-left p by q block
               \link DenseBase::bottomLeftCorner() * \endlink</td>
     <td>\code
 matrix.bottomLeftCorner(p,q);\endcode </td>
     <td>\code
 matrix.bottomLeftCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Top-right p by q block
               \link DenseBase::topRightCorner() * \endlink</td>
     <td>\code
 matrix.topRightCorner(p,q);\endcode </td>
     <td>\code
 matrix.topRightCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>Bottom-right p by q block
                \link DenseBase::bottomRightCorner() * \endlink</td>
     <td>\code
 matrix.bottomRightCorner(p,q);\endcode </td>
     <td>\code
 matrix.bottomRightCorner<p,q>();\endcode </td>
 </tr>
 <tr><td>%Block containing the first q rows
                    \link DenseBase::topRows() * \endlink</td>
     <td>\code
 matrix.topRows(q);\endcode </td>
     <td>\code
 matrix.topRows<q>();\endcode </td>
 </tr>
 <tr><td>%Block containing the last q rows
                     \link DenseBase::bottomRows() * \endlink</td>
     <td>\code
 matrix.bottomRows(q);\endcode </td>
     <td>\code
 matrix.bottomRows<q>();\endcode </td>
 </tr>
 <tr><td>%Block containing the first p columns
                     \link DenseBase::leftCols() * \endlink</td>
     <td>\code
 matrix.leftCols(p);\endcode </td>
     <td>\code
 matrix.leftCols<p>();\endcode </td>
 </tr>
 <tr><td>%Block containing the last q columns
                     \link DenseBase::rightCols() * \endlink</td>
     <td>\code
 matrix.rightCols(q);\endcode </td>
     <td>\code
 matrix.rightCols<q>();\endcode </td>
 </tr>
 </table>

 Here is a simple example illustrating the use of the operations presented above:

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_BlockOperations_corner.cpp
 </td>
 <td>
 \verbinclude Tutorial_BlockOperations_corner.out
 </td></tr></table>


 \section TutorialBlockOperationsSyntaxVectors Block operations for vectors

 Eigen also provides a set of block operations designed specifically for the special case of vectors and one-dimensional arrays:

 <table class="manual">
 <tr><th> %Block operation</th>
 <th>Version constructing a \n dynamic-size block expression</th>
 <th>Version constructing a \n fixed-size block expression</th></tr>
 <tr><td>%Block containing the first \p n elements
                     \link DenseBase::head() * \endlink</td>
     <td>\code
 vector.head(n);\endcode </td>
     <td>\code
 vector.head<n>();\endcode </td>
 </tr>
 <tr><td>%Block containing the last \p n elements
                     \link DenseBase::tail() * \endlink</td>
     <td>\code
 vector.tail(n);\endcode </td>
     <td>\code
 vector.tail<n>();\endcode </td>
 </tr>
 <tr><td>%Block containing \p n elements, starting at position \p i
                     \link DenseBase::segment() * \endlink</td>
     <td>\code
 vector.segment(i,n);\endcode </td>
     <td>\code
 vector.segment<n>(i);\endcode </td>
 </tr>
 </table>


 An example is presented below:
 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_BlockOperations_vector.cpp
 </td>
 <td>
 \verbinclude Tutorial_BlockOperations_vector.out
 </td></tr></table>

 */

 }
	namespace Eigen {

	/** \eigenManualPage TutorialBlockOperations Block operations

	This page explains the essentials of block operations.
	A block is a rectangular part of a matrix or array. Blocks expressions can be used both
	as rvalues and as lvalues. As usual with Eigen expressions, this abstraction has zero runtime cost
	provided that you let your compiler optimize.

	\eigenAutoToc

	\section TutorialBlockOperationsUsing Using block operations

	The most general block operation in Eigen is called \link DenseBase::block() .block() \endlink.
	There are two versions, whose syntax is as follows:

	<table class="manual">
	<tr><th>\b %Block \b operation</td>
	<th>Version constructing a \n dynamic-size block expression</th>
	<th>Version constructing a \n fixed-size block expression</th></tr>
	<tr><td>%Block of size <tt>(p,q)</tt>, starting at <tt>(i,j)</tt></td>
	<td>\code
	matrix.block(i,j,p,q);\endcode </td>
	<td>\code
	matrix.block<p,q>(i,j);\endcode </td>
	</tr>
	</table>

	As always in Eigen, indices start at 0.

	Both versions can be used on fixed-size and dynamic-size matrices and arrays.
	These two expressions are semantically equivalent.
	The only difference is that the fixed-size version will typically give you faster code if the block size is small,
	but requires this size to be known at compile time.

	The following program uses the dynamic-size and fixed-size versions to print the values of several blocks inside a
	matrix.

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_BlockOperations_print_block.cpp
	</td>
	<td>
	\verbinclude Tutorial_BlockOperations_print_block.out
	</td></tr></table>

	In the above example the \link DenseBase::block() .block() \endlink function was employed as a \em rvalue, i.e.
	it was only read from. However, blocks can also be used as \em lvalues, meaning that you can assign to a block.

	This is illustrated in the following example. This example also demonstrates blocks in arrays, which works exactly like the above-demonstrated blocks in matrices.

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

	While the \link DenseBase::block() .block() \endlink method can be used for any block operation, there are
	other methods for special cases, providing more specialized API and/or better performance. On the topic of performance, all what
	matters is that you give Eigen as much information as possible at compile time. For example, if your block is a single whole column in a matrix,
	using the specialized \link DenseBase::col() .col() \endlink function described below lets Eigen know that, which can give it optimization opportunities.

	The rest of this page describes these specialized methods.

	\section TutorialBlockOperationsSyntaxColumnRows Columns and rows

	Individual columns and rows are special cases of blocks. Eigen provides methods to easily address them:
	\link DenseBase::col() .col() \endlink and \link DenseBase::row() .row()\endlink.

	<table class="manual">
	<tr><th>%Block operation</th>
	<th>Method</th>
	<tr><td>i<sup>th</sup> row
	\link DenseBase::row() * \endlink</td>
	<td>\code
	matrix.row(i);\endcode </td>
	</tr>
	<tr><td>j<sup>th</sup> column
	\link DenseBase::col() * \endlink</td>
	<td>\code
	matrix.col(j);\endcode </td>
	</tr>
	</table>

	The argument for \p col() and \p row() is the index of the column or row to be accessed. As always in Eigen, indices start at 0.

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_BlockOperations_colrow.cpp
	</td>
	<td>
	\verbinclude Tutorial_BlockOperations_colrow.out
	</td></tr></table>

	That example also demonstrates that block expressions (here columns) can be used in arithmetic like any other expression.


	\section TutorialBlockOperationsSyntaxCorners Corner-related operations

	Eigen also provides special methods for blocks that are flushed against one of the corners or sides of a
	matrix or array. For instance, \link DenseBase::topLeftCorner() .topLeftCorner() \endlink can be used to refer
	to a block in the top-left corner of a matrix.

	The different possibilities are summarized in the following table:

	<table class="manual">
	<tr><th>%Block \b operation</td>
	<th>Version constructing a \n dynamic-size block expression</th>
	<th>Version constructing a \n fixed-size block expression</th></tr>
	<tr><td>Top-left p by q block \link DenseBase::topLeftCorner() * \endlink</td>
	<td>\code
	matrix.topLeftCorner(p,q);\endcode </td>
	<td>\code
	matrix.topLeftCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Bottom-left p by q block
	\link DenseBase::bottomLeftCorner() * \endlink</td>
	<td>\code
	matrix.bottomLeftCorner(p,q);\endcode </td>
	<td>\code
	matrix.bottomLeftCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Top-right p by q block
	\link DenseBase::topRightCorner() * \endlink</td>
	<td>\code
	matrix.topRightCorner(p,q);\endcode </td>
	<td>\code
	matrix.topRightCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>Bottom-right p by q block
	\link DenseBase::bottomRightCorner() * \endlink</td>
	<td>\code
	matrix.bottomRightCorner(p,q);\endcode </td>
	<td>\code
	matrix.bottomRightCorner<p,q>();\endcode </td>
	</tr>
	<tr><td>%Block containing the first q rows
	\link DenseBase::topRows() * \endlink</td>
	<td>\code
	matrix.topRows(q);\endcode </td>
	<td>\code
	matrix.topRows<q>();\endcode </td>
	</tr>
	<tr><td>%Block containing the last q rows
	\link DenseBase::bottomRows() * \endlink</td>
	<td>\code
	matrix.bottomRows(q);\endcode </td>
	<td>\code
	matrix.bottomRows<q>();\endcode </td>
	</tr>
	<tr><td>%Block containing the first p columns
	\link DenseBase::leftCols() * \endlink</td>
	<td>\code
	matrix.leftCols(p);\endcode </td>
	<td>\code
	matrix.leftCols<p>();\endcode </td>
	</tr>
	<tr><td>%Block containing the last q columns
	\link DenseBase::rightCols() * \endlink</td>
	<td>\code
	matrix.rightCols(q);\endcode </td>
	<td>\code
	matrix.rightCols<q>();\endcode </td>
	</tr>
	</table>

	Here is a simple example illustrating the use of the operations presented above:

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_BlockOperations_corner.cpp
	</td>
	<td>
	\verbinclude Tutorial_BlockOperations_corner.out
	</td></tr></table>


	\section TutorialBlockOperationsSyntaxVectors Block operations for vectors

	Eigen also provides a set of block operations designed specifically for the special case of vectors and one-dimensional arrays:

	<table class="manual">
	<tr><th> %Block operation</th>
	<th>Version constructing a \n dynamic-size block expression</th>
	<th>Version constructing a \n fixed-size block expression</th></tr>
	<tr><td>%Block containing the first \p n elements
	\link DenseBase::head() * \endlink</td>
	<td>\code
	vector.head(n);\endcode </td>
	<td>\code
	vector.head<n>();\endcode </td>
	</tr>
	<tr><td>%Block containing the last \p n elements
	\link DenseBase::tail() * \endlink</td>
	<td>\code
	vector.tail(n);\endcode </td>
	<td>\code
	vector.tail<n>();\endcode </td>
	</tr>
	<tr><td>%Block containing \p n elements, starting at position \p i
	\link DenseBase::segment() * \endlink</td>
	<td>\code
	vector.segment(i,n);\endcode </td>
	<td>\code
	vector.segment<n>(i);\endcode </td>
	</tr>
	</table>


	An example is presented below:
	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_BlockOperations_vector.cpp
	</td>
	<td>
	\verbinclude Tutorial_BlockOperations_vector.out
	</td></tr></table>

	*/

	}