doc/TutorialAdvancedInitialization.dox - eigen - Git at Google

 namespace Eigen {

 /** \eigenManualPage TutorialAdvancedInitialization Advanced initialization

 This page discusses several advanced methods for initializing matrices. It gives more details on the
 comma-initializer, which was introduced before. It also explains how to get special matrices such as the
 identity matrix and the zero matrix.

 \eigenAutoToc

 \section TutorialAdvancedInitializationCommaInitializer The comma initializer

 Eigen offers a comma initializer syntax which allows the user to easily set all the coefficients of a matrix,
 vector or array. Simply list the coefficients, starting at the top-left corner and moving from left to right
 and from the top to the bottom. The size of the object needs to be specified beforehand. If you list too few
 or too many coefficients, Eigen will complain.

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_commainit_01.cpp
 </td>
 <td>
 \verbinclude Tutorial_commainit_01.out
 </td></tr></table>

 Moreover, the elements of the initialization list may themselves be vectors or matrices. A common use is
 to join vectors or matrices together. For example, here is how to join two row vectors together. Remember
 that you have to set the size before you can use the comma initializer.

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

 We can use the same technique to initialize matrices with a block structure.

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

 The comma initializer can also be used to fill block expressions such as <tt>m.row(i)</tt>. Here is a more
 complicated way to get the same result as in the first example above:

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Tutorial_commainit_01b.cpp
 </td>
 <td>
 \verbinclude Tutorial_commainit_01b.out
 </td></tr></table>


 \section TutorialAdvancedInitializationSpecialMatrices Special matrices and arrays

 The Matrix and Array classes have static methods like \link DenseBase::Zero() Zero()\endlink, which can be
 used to initialize all coefficients to zero. There are three variants. The first variant takes no arguments
 and can only be used for fixed-size objects. If you want to initialize a dynamic-size object to zero, you need
 to specify the size. Thus, the second variant requires one argument and can be used for one-dimensional
 dynamic-size objects, while the third variant requires two arguments and can be used for two-dimensional
 objects. All three variants are illustrated in the following example:

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

 Similarly, the static method \link DenseBase::Constant() Constant\endlink(value) sets all coefficients to \c value.
 If the size of the object needs to be specified, the additional arguments go before the \c value
 argument, as in <tt>MatrixXd::Constant(rows, cols, value)</tt>. The method \link DenseBase::Random() Random()
 \endlink fills the matrix or array with random coefficients. The identity matrix can be obtained by calling
 \link MatrixBase::Identity() Identity()\endlink; this method is only available for Matrix, not for Array,
 because "identity matrix" is a linear algebra concept.  The method
 \link DenseBase::LinSpaced LinSpaced\endlink(size, low, high) is only available for vectors and
 one-dimensional arrays; it yields a vector of the specified size whose coefficients are equally spaced between
 \c low and \c high. The method \c LinSpaced() is illustrated in the following example, which prints a table
 with angles in degrees, the corresponding angle in radians, and their sine and cosine.

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

 This example shows that objects like the ones returned by LinSpaced() can be assigned to variables (and
 expressions). Eigen defines utility functions like \link DenseBase::setZero() setZero()\endlink,
 \link MatrixBase::setIdentity() \endlink and \link DenseBase::setLinSpaced() \endlink to do this
 conveniently. The following example contrasts three ways to construct the matrix
 \f$ J = \bigl[ \begin{smallmatrix} O & I \\ I & O \end{smallmatrix} \bigr] \f$: using static methods and
 assignment, using static methods and the comma-initializer, or using the setXxx() methods.

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

 A summary of all pre-defined matrix, vector and array objects can be found in the \ref QuickRefPage.


 \section TutorialAdvancedInitializationTemporaryObjects Usage as temporary objects

 As shown above, static methods as Zero() and Constant() can be used to initialize variables at the time of
 declaration or at the right-hand side of an assignment operator. You can think of these methods as returning a
 matrix or array; in fact, they return so-called \ref TopicEigenExpressionTemplates "expression objects" which
 evaluate to a matrix or array when needed, so that this syntax does not incur any overhead.

 These expressions can also be used as a temporary object. The second example in
 the \ref GettingStarted guide, which we reproduce here, already illustrates this.

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include QuickStart_example2_dynamic.cpp
 </td>
 <td>
 \verbinclude QuickStart_example2_dynamic.out
 </td></tr></table>

 The expression <tt>m + MatrixXf::Constant(3,3,1.2)</tt> constructs the 3-by-3 matrix expression with all its coefficients
 equal to 1.2 plus the corresponding coefficient of \a m.

 The comma-initializer, too, can also be used to construct temporary objects. The following example constructs a random
 matrix of size 2-by-3, and then multiplies this matrix on the left with
 \f$ \bigl[ \begin{smallmatrix} 0 & 1 \\ 1 & 0 \end{smallmatrix} \bigr] \f$.

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

 The \link CommaInitializer::finished() finished() \endlink method is necessary here to get the actual matrix
 object once the comma initialization of our temporary submatrix is done.


 */

 }
	namespace Eigen {

	/** \eigenManualPage TutorialAdvancedInitialization Advanced initialization

	This page discusses several advanced methods for initializing matrices. It gives more details on the
	comma-initializer, which was introduced before. It also explains how to get special matrices such as the
	identity matrix and the zero matrix.

	\eigenAutoToc

	\section TutorialAdvancedInitializationCommaInitializer The comma initializer

	Eigen offers a comma initializer syntax which allows the user to easily set all the coefficients of a matrix,
	vector or array. Simply list the coefficients, starting at the top-left corner and moving from left to right
	and from the top to the bottom. The size of the object needs to be specified beforehand. If you list too few
	or too many coefficients, Eigen will complain.

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_commainit_01.cpp
	</td>
	<td>
	\verbinclude Tutorial_commainit_01.out
	</td></tr></table>

	Moreover, the elements of the initialization list may themselves be vectors or matrices. A common use is
	to join vectors or matrices together. For example, here is how to join two row vectors together. Remember
	that you have to set the size before you can use the comma initializer.

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

	We can use the same technique to initialize matrices with a block structure.

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

	The comma initializer can also be used to fill block expressions such as <tt>m.row(i)</tt>. Here is a more
	complicated way to get the same result as in the first example above:

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Tutorial_commainit_01b.cpp
	</td>
	<td>
	\verbinclude Tutorial_commainit_01b.out
	</td></tr></table>


	\section TutorialAdvancedInitializationSpecialMatrices Special matrices and arrays

	The Matrix and Array classes have static methods like \link DenseBase::Zero() Zero()\endlink, which can be
	used to initialize all coefficients to zero. There are three variants. The first variant takes no arguments
	and can only be used for fixed-size objects. If you want to initialize a dynamic-size object to zero, you need
	to specify the size. Thus, the second variant requires one argument and can be used for one-dimensional
	dynamic-size objects, while the third variant requires two arguments and can be used for two-dimensional
	objects. All three variants are illustrated in the following example:

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

	Similarly, the static method \link DenseBase::Constant() Constant\endlink(value) sets all coefficients to \c value.
	If the size of the object needs to be specified, the additional arguments go before the \c value
	argument, as in <tt>MatrixXd::Constant(rows, cols, value)</tt>. The method \link DenseBase::Random() Random()
	\endlink fills the matrix or array with random coefficients. The identity matrix can be obtained by calling
	\link MatrixBase::Identity() Identity()\endlink; this method is only available for Matrix, not for Array,
	because "identity matrix" is a linear algebra concept. The method
	\link DenseBase::LinSpaced LinSpaced\endlink(size, low, high) is only available for vectors and
	one-dimensional arrays; it yields a vector of the specified size whose coefficients are equally spaced between
	\c low and \c high. The method \c LinSpaced() is illustrated in the following example, which prints a table
	with angles in degrees, the corresponding angle in radians, and their sine and cosine.

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

	This example shows that objects like the ones returned by LinSpaced() can be assigned to variables (and
	expressions). Eigen defines utility functions like \link DenseBase::setZero() setZero()\endlink,
	\link MatrixBase::setIdentity() \endlink and \link DenseBase::setLinSpaced() \endlink to do this
	conveniently. The following example contrasts three ways to construct the matrix
	\f$ J = \bigl[ \begin{smallmatrix} O & I \\ I & O \end{smallmatrix} \bigr] \f$: using static methods and
	assignment, using static methods and the comma-initializer, or using the setXxx() methods.

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

	A summary of all pre-defined matrix, vector and array objects can be found in the \ref QuickRefPage.


	\section TutorialAdvancedInitializationTemporaryObjects Usage as temporary objects

	As shown above, static methods as Zero() and Constant() can be used to initialize variables at the time of
	declaration or at the right-hand side of an assignment operator. You can think of these methods as returning a
	matrix or array; in fact, they return so-called \ref TopicEigenExpressionTemplates "expression objects" which
	evaluate to a matrix or array when needed, so that this syntax does not incur any overhead.

	These expressions can also be used as a temporary object. The second example in
	the \ref GettingStarted guide, which we reproduce here, already illustrates this.

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include QuickStart_example2_dynamic.cpp
	</td>
	<td>
	\verbinclude QuickStart_example2_dynamic.out
	</td></tr></table>

	The expression <tt>m + MatrixXf::Constant(3,3,1.2)</tt> constructs the 3-by-3 matrix expression with all its coefficients
	equal to 1.2 plus the corresponding coefficient of \a m.

	The comma-initializer, too, can also be used to construct temporary objects. The following example constructs a random
	matrix of size 2-by-3, and then multiplies this matrix on the left with
	\f$ \bigl[ \begin{smallmatrix} 0 & 1 \\ 1 & 0 \end{smallmatrix} \bigr] \f$.

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

	The \link CommaInitializer::finished() finished() \endlink method is necessary here to get the actual matrix
	object once the comma initialization of our temporary submatrix is done.


	*/

	}