doc/TutorialSlicingIndexing.dox - eigen - Git at Google

 namespace Eigen {

 /** \eigenManualPage TutorialSlicingIndexing Slicing and Indexing

 This page presents the numerous possibilities offered by `operator()` to index sub-set of rows and columns.
 This API has been introduced in %Eigen 3.4.
 It supports all the feature proposed by the \link TutorialBlockOperations block API \endlink, and much more.
 In particular, it supports \b slicing that consists in taking a set of rows, columns, or elements, uniformly spaced within a matrix or indexed from an array of indices.

 \eigenAutoToc

 \section TutorialSlicingOverview Overview

 All the aforementioned operations are handled through the generic DenseBase::operator()(const RowIndices&, const ColIndices&) method.
 Each argument can be:
   - An integer indexing a single row or column, including symbolic indices.
   - The symbol Eigen::all representing the whole set of respective rows or columns in increasing order.
   - An ArithmeticSequence as constructed by the Eigen::seq, Eigen::seqN, or Eigen::lastN functions.
   - Any 1D vector/array of integers including %Eigen's vector/array, expressions, std::vector, std::array, as well as plain C arrays: `int[N]`.

 More generally, it can accepts any object exposing the following two member functions:
   \code
   <integral type> operator[](<integral type>) const;
   <integral type> size() const;
   \endcode
 where `<integral type>` stands for any integer type compatible with Eigen::Index (i.e. `std::ptrdiff_t`).

 \section TutorialSlicingBasic Basic slicing

 Taking a set of rows, columns, or elements, uniformly spaced within a matrix or vector is achieved through the Eigen::seq or Eigen::seqN functions where "seq" stands for arithmetic sequence. Their signatures are summarized below:

 <table class="manual">
 <tr>
   <th>function</th>
   <th>description</th>
   <th>example</th>
 </tr>
 <tr>
   <td>\code seq(firstIdx,lastIdx) \endcode</td>
   <td>represents the sequence of integers ranging from \c firstIdx to \c lastIdx</td>
   <td>\code seq(2,5) <=> {2,3,4,5} \endcode</td>
 </tr>
 <tr>
   <td>\code seq(firstIdx,lastIdx,incr) \endcode</td>
   <td>same but using the increment \c incr to advance from one index to the next</td>
   <td>\code seq(2,8,2) <=> {2,4,6,8} \endcode</td>
 </tr>
 <tr>
   <td>\code seqN(firstIdx,size) \endcode</td>
   <td>represents the sequence of \c size integers starting from \c firstIdx</td>
   <td>\code seqN(2,5) <=> {2,3,4,5,6} \endcode</td>
 </tr>
 <tr>
   <td>\code seqN(firstIdx,size,incr) \endcode</td>
   <td>same but using the increment \c incr to advance from one index to the next</td>
   <td>\code seqN(2,3,3) <=> {2,5,8} \endcode</td>
 </tr>
 </table>

 The \c firstIdx and \c lastIdx parameters can also be defined with the help of the Eigen::last symbol representing the index of the last row, column or element of the underlying matrix/vector once the arithmetic sequence is passed to it through operator().
 Here are some examples for a 2D array/matrix \c A and a 1D array/vector \c v.
 <table class="manual">
 <tr>
   <th>Intent</th>
   <th>Code</th>
   <th>Block-API equivalence</th>
 </tr>
 <tr>
   <td>Bottom-left corner starting at row \c i with \c n columns</td>
   <td>\code A(seq(i,last), seqN(0,n)) \endcode</td>
   <td>\code A.bottomLeftCorner(A.rows()-i,n) \endcode</td>
 </tr>
 <tr>
   <td>%Block starting at \c i,j having \c m rows, and \c n columns</td>
   <td>\code A(seqN(i,m), seqN(i,n) \endcode</td>
   <td>\code A.block(i,j,m,n) \endcode</td>
 </tr>
 <tr>
   <td>%Block starting at \c i0,j0 and ending at \c i1,j1</td>
   <td>\code A(seq(i0,i1), seq(j0,j1) \endcode</td>
   <td>\code A.block(i0,j0,i1-i0+1,j1-j0+1) \endcode</td>
 </tr>
 <tr>
   <td>Even columns of A</td>
   <td>\code A(all, seq(0,last,2)) \endcode</td>
   <td></td>
 </tr>
 <tr>
   <td>First \c n odd rows A</td>
   <td>\code A(seqN(1,n,2), all) \endcode</td>
   <td></td>
 </tr>
 <tr>
   <td>The last past one column</td>
   <td>\code A(all, last-1) \endcode</td>
   <td>\code A.col(A.cols()-2) \endcode</td>
 </tr>
 <tr>
   <td>The middle row</td>
   <td>\code A(last/2,all) \endcode</td>
   <td>\code A.row((A.rows()-1)/2) \endcode</td>
 </tr>
 <tr>
   <td>Last elements of v starting at i</td>
   <td>\code v(seq(i,last)) \endcode</td>
   <td>\code v.tail(v.size()-i) \endcode</td>
 </tr>
 <tr>
   <td>Last \c n elements of v</td>
   <td>\code v(seq(last+1-n,last)) \endcode</td>
   <td>\code v.tail(n) \endcode</td>
 </tr>
 </table>

 As seen in the last exemple, referencing the <i> last n </i> elements (or rows/columns) is a bit cumbersome to write.
 This becomes even more tricky and error prone with a non-default increment.
 Here comes \link Eigen::lastN(SizeType) Eigen::lastN(size) \endlink, and \link Eigen::lastN(SizeType,IncrType) Eigen::lastN(size,incr) \endlink:

 <table class="manual">
 <tr>
   <th>Intent</th>
   <th>Code</th>
   <th>Block-API equivalence</th>
 </tr>
 <tr>
   <td>Last \c n elements of v</td>
   <td>\code v(lastN(n)) \endcode</td>
   <td>\code v.tail(n) \endcode</td>
 </tr>
 <tr>
   <td>Bottom-right corner of A of size \c m times \c n</td>
   <td>\code v(lastN(m), lastN(n)) \endcode</td>
   <td>\code A.bottomRightCorner(m,n) \endcode</td>
 </tr>
 <tr>
   <td>Bottom-right corner of A of size \c m times \c n</td>
   <td>\code v(lastN(m), lastN(n)) \endcode</td>
   <td>\code A.bottomRightCorner(m,n) \endcode</td>
 </tr>
 <tr>
   <td>Last \c n columns taking 1 column over 3</td>
   <td>\code A(all, lastN(n,3)) \endcode</td>
   <td></td>
 </tr>
 </table>

 \section TutorialSlicingFixed Compile time size and increment

 In terms of performance, %Eigen and the compiler can take advantage of compile-time size and increment.
 To this end, you can enforce compile-time parameters using Eigen::fix<val>.
 Such compile-time value can be combined with the Eigen::last symbol:
 \code v(seq(last-fix<7>, last-fix<2>))
 \endcode
 In this example %Eigen knowns at compile-time that the returned expression has 6 elements.
 It is equivalent to:
 \code v(seqN(last-7, fix<6>))
 \endcode

 We can revisit the <i>even columns of A</i> example as follows:
 \code A(all, seq(0,last,fix<2>))
 \endcode


 \section TutorialSlicingReverse Reverse order

 Row/column indices can also be enumerated in decreasing order using a negative increment.
 For instance, one over two columns of A from the column 20 to 10:
 \code A(all, seq(20, 10, fix<-2>))
 \endcode
 The last \c n rows starting from the last one:
 \code A(seqN(last, n, fix<-1>), all)
 \endcode
 You can also use the ArithmeticSequence::reverse() method to reverse its order.
 The previous example can thus also be written as:
 \code A(lastN(n).reverse(), all)
 \endcode


 \section TutorialSlicingArray Array of indices

 The generic `operator()` can also takes as input an arbitrary list of row or column indices stored as either an `ArrayXi`, a `std::vector<int>`, `std::array<int,N>`, etc.

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Slicing_stdvector_cxx11.cpp
 </td>
 <td>
 \verbinclude Slicing_stdvector_cxx11.out
 </td></tr></table>

 You can also directly pass a static array:
 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Slicing_rawarray_cxx11.cpp
 </td>
 <td>
 \verbinclude Slicing_rawarray_cxx11.out
 </td></tr></table>

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

 When passing an object with a compile-time size such as `Array4i`, `std::array<int,N>`, or a static array, then the returned expression also exhibit compile-time dimensions.

 \section TutorialSlicingCustomArray Custom index list

 More generally, `operator()` can accept as inputs any object \c ind of type \c T compatible with:
 \code
 Index s = ind.size(); or Index s = size(ind);
 Index i;
 i = ind[i];
 \endcode

 This means you can easily build your own fancy sequence generator and pass it to `operator()`.
 Here is an exemple enlarging a given matrix while padding the additional first rows and columns through repetition:

 <table class="example">
 <tr><th>Example:</th><th>Output:</th></tr>
 <tr><td>
 \include Slicing_custom_padding_cxx11.cpp
 </td>
 <td>
 \verbinclude Slicing_custom_padding_cxx11.out
 </td></tr></table>

 <br>

 */

 /*
 TODO add:
 so_repeat_inner.cpp
 so_repeleme.cpp
 */
 }
	namespace Eigen {

	/** \eigenManualPage TutorialSlicingIndexing Slicing and Indexing

	This page presents the numerous possibilities offered by `operator()` to index sub-set of rows and columns.
	This API has been introduced in %Eigen 3.4.
	It supports all the feature proposed by the \link TutorialBlockOperations block API \endlink, and much more.
	In particular, it supports \b slicing that consists in taking a set of rows, columns, or elements, uniformly spaced within a matrix or indexed from an array of indices.

	\eigenAutoToc

	\section TutorialSlicingOverview Overview

	All the aforementioned operations are handled through the generic DenseBase::operator()(const RowIndices&, const ColIndices&) method.
	Each argument can be:
	- An integer indexing a single row or column, including symbolic indices.
	- The symbol Eigen::all representing the whole set of respective rows or columns in increasing order.
	- An ArithmeticSequence as constructed by the Eigen::seq, Eigen::seqN, or Eigen::lastN functions.
	- Any 1D vector/array of integers including %Eigen's vector/array, expressions, std::vector, std::array, as well as plain C arrays: `int[N]`.

	More generally, it can accepts any object exposing the following two member functions:
	\code
	<integral type> operator[](<integral type>) const;
	<integral type> size() const;
	\endcode
	where `<integral type>` stands for any integer type compatible with Eigen::Index (i.e. `std::ptrdiff_t`).

	\section TutorialSlicingBasic Basic slicing

	Taking a set of rows, columns, or elements, uniformly spaced within a matrix or vector is achieved through the Eigen::seq or Eigen::seqN functions where "seq" stands for arithmetic sequence. Their signatures are summarized below:

	<table class="manual">
	<tr>
	<th>function</th>
	<th>description</th>
	<th>example</th>
	</tr>
	<tr>
	<td>\code seq(firstIdx,lastIdx) \endcode</td>
	<td>represents the sequence of integers ranging from \c firstIdx to \c lastIdx</td>
	<td>\code seq(2,5) <=> {2,3,4,5} \endcode</td>
	</tr>
	<tr>
	<td>\code seq(firstIdx,lastIdx,incr) \endcode</td>
	<td>same but using the increment \c incr to advance from one index to the next</td>
	<td>\code seq(2,8,2) <=> {2,4,6,8} \endcode</td>
	</tr>
	<tr>
	<td>\code seqN(firstIdx,size) \endcode</td>
	<td>represents the sequence of \c size integers starting from \c firstIdx</td>
	<td>\code seqN(2,5) <=> {2,3,4,5,6} \endcode</td>
	</tr>
	<tr>
	<td>\code seqN(firstIdx,size,incr) \endcode</td>
	<td>same but using the increment \c incr to advance from one index to the next</td>
	<td>\code seqN(2,3,3) <=> {2,5,8} \endcode</td>
	</tr>
	</table>

	The \c firstIdx and \c lastIdx parameters can also be defined with the help of the Eigen::last symbol representing the index of the last row, column or element of the underlying matrix/vector once the arithmetic sequence is passed to it through operator().
	Here are some examples for a 2D array/matrix \c A and a 1D array/vector \c v.
	<table class="manual">
	<tr>
	<th>Intent</th>
	<th>Code</th>
	<th>Block-API equivalence</th>
	</tr>
	<tr>
	<td>Bottom-left corner starting at row \c i with \c n columns</td>
	<td>\code A(seq(i,last), seqN(0,n)) \endcode</td>
	<td>\code A.bottomLeftCorner(A.rows()-i,n) \endcode</td>
	</tr>
	<tr>
	<td>%Block starting at \c i,j having \c m rows, and \c n columns</td>
	<td>\code A(seqN(i,m), seqN(i,n) \endcode</td>
	<td>\code A.block(i,j,m,n) \endcode</td>
	</tr>
	<tr>
	<td>%Block starting at \c i0,j0 and ending at \c i1,j1</td>
	<td>\code A(seq(i0,i1), seq(j0,j1) \endcode</td>
	<td>\code A.block(i0,j0,i1-i0+1,j1-j0+1) \endcode</td>
	</tr>
	<tr>
	<td>Even columns of A</td>
	<td>\code A(all, seq(0,last,2)) \endcode</td>
	<td></td>
	</tr>
	<tr>
	<td>First \c n odd rows A</td>
	<td>\code A(seqN(1,n,2), all) \endcode</td>
	<td></td>
	</tr>
	<tr>
	<td>The last past one column</td>
	<td>\code A(all, last-1) \endcode</td>
	<td>\code A.col(A.cols()-2) \endcode</td>
	</tr>
	<tr>
	<td>The middle row</td>
	<td>\code A(last/2,all) \endcode</td>
	<td>\code A.row((A.rows()-1)/2) \endcode</td>
	</tr>
	<tr>
	<td>Last elements of v starting at i</td>
	<td>\code v(seq(i,last)) \endcode</td>
	<td>\code v.tail(v.size()-i) \endcode</td>
	</tr>
	<tr>
	<td>Last \c n elements of v</td>
	<td>\code v(seq(last+1-n,last)) \endcode</td>
	<td>\code v.tail(n) \endcode</td>
	</tr>
	</table>

	As seen in the last exemple, referencing the <i> last n </i> elements (or rows/columns) is a bit cumbersome to write.
	This becomes even more tricky and error prone with a non-default increment.
	Here comes \link Eigen::lastN(SizeType) Eigen::lastN(size) \endlink, and \link Eigen::lastN(SizeType,IncrType) Eigen::lastN(size,incr) \endlink:

	<table class="manual">
	<tr>
	<th>Intent</th>
	<th>Code</th>
	<th>Block-API equivalence</th>
	</tr>
	<tr>
	<td>Last \c n elements of v</td>
	<td>\code v(lastN(n)) \endcode</td>
	<td>\code v.tail(n) \endcode</td>
	</tr>
	<tr>
	<td>Bottom-right corner of A of size \c m times \c n</td>
	<td>\code v(lastN(m), lastN(n)) \endcode</td>
	<td>\code A.bottomRightCorner(m,n) \endcode</td>
	</tr>
	<tr>
	<td>Bottom-right corner of A of size \c m times \c n</td>
	<td>\code v(lastN(m), lastN(n)) \endcode</td>
	<td>\code A.bottomRightCorner(m,n) \endcode</td>
	</tr>
	<tr>
	<td>Last \c n columns taking 1 column over 3</td>
	<td>\code A(all, lastN(n,3)) \endcode</td>
	<td></td>
	</tr>
	</table>

	\section TutorialSlicingFixed Compile time size and increment

	In terms of performance, %Eigen and the compiler can take advantage of compile-time size and increment.
	To this end, you can enforce compile-time parameters using Eigen::fix<val>.
	Such compile-time value can be combined with the Eigen::last symbol:
	\code v(seq(last-fix<7>, last-fix<2>))
	\endcode
	In this example %Eigen knowns at compile-time that the returned expression has 6 elements.
	It is equivalent to:
	\code v(seqN(last-7, fix<6>))
	\endcode

	We can revisit the <i>even columns of A</i> example as follows:
	\code A(all, seq(0,last,fix<2>))
	\endcode


	\section TutorialSlicingReverse Reverse order

	Row/column indices can also be enumerated in decreasing order using a negative increment.
	For instance, one over two columns of A from the column 20 to 10:
	\code A(all, seq(20, 10, fix<-2>))
	\endcode
	The last \c n rows starting from the last one:
	\code A(seqN(last, n, fix<-1>), all)
	\endcode
	You can also use the ArithmeticSequence::reverse() method to reverse its order.
	The previous example can thus also be written as:
	\code A(lastN(n).reverse(), all)
	\endcode


	\section TutorialSlicingArray Array of indices

	The generic `operator()` can also takes as input an arbitrary list of row or column indices stored as either an `ArrayXi`, a `std::vector<int>`, `std::array<int,N>`, etc.

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Slicing_stdvector_cxx11.cpp
	</td>
	<td>
	\verbinclude Slicing_stdvector_cxx11.out
	</td></tr></table>

	You can also directly pass a static array:
	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Slicing_rawarray_cxx11.cpp
	</td>
	<td>
	\verbinclude Slicing_rawarray_cxx11.out
	</td></tr></table>

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

	When passing an object with a compile-time size such as `Array4i`, `std::array<int,N>`, or a static array, then the returned expression also exhibit compile-time dimensions.

	\section TutorialSlicingCustomArray Custom index list

	More generally, `operator()` can accept as inputs any object \c ind of type \c T compatible with:
	\code
	Index s = ind.size(); or Index s = size(ind);
	Index i;
	i = ind[i];
	\endcode

	This means you can easily build your own fancy sequence generator and pass it to `operator()`.
	Here is an exemple enlarging a given matrix while padding the additional first rows and columns through repetition:

	<table class="example">
	<tr><th>Example:</th><th>Output:</th></tr>
	<tr><td>
	\include Slicing_custom_padding_cxx11.cpp
	</td>
	<td>
	\verbinclude Slicing_custom_padding_cxx11.out
	</td></tr></table>

	<br>

	*/

	/*
	TODO add:
	so_repeat_inner.cpp
	so_repeleme.cpp
	*/
	}