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/Eigen3Eigen::PlainObjectBase
template<typename Derived>
class Eigen::PlainObjectBase< Derived >
Dense storage base class for matrices and arrays.
This class can be extended with the help of the plugin mechanism described on the page Extending MatrixBase (and other classes) by defining the preprocessor symbol EIGEN_PLAINOBJECTBASE_PLUGIN.
- See also
- The class hierarchy
| const Scalar & | coeff (Index index) const |
| const Scalar & | coeff (Index rowId, Index colId) const |
| Scalar & | coeffRef (Index index) |
| const Scalar & | coeffRef (Index index) const |
| Scalar & | coeffRef (Index rowId, Index colId) |
| const Scalar & | coeffRef (Index rowId, Index colId) const |
| void | conservativeResize (Index rows, Index cols) |
| void | conservativeResize (Index rows, NoChange_t) |
| void | conservativeResize (Index size) |
| void | conservativeResize (NoChange_t, Index cols) |
| template<typename OtherDerived > | |
| void | conservativeResizeLike (const DenseBase< OtherDerived > &other) |
| Scalar * | data () |
| const Scalar * | data () const |
| template<typename OtherDerived > | |
| Derived & | lazyAssign (const DenseBase< OtherDerived > &other) |
| template<typename OtherDerived > | |
| Derived & | operator= (const EigenBase< OtherDerived > &other) |
| Copies the generic expression other into *this. More... |
|
| Derived & | operator= (const PlainObjectBase &other) |
| void | resize (Index rows, Index cols) |
| void | resize (Index rows, NoChange_t) |
| void | resize (Index size) |
| void | resize (NoChange_t, Index cols) |
| template<typename OtherDerived > | |
| void | resizeLike (const EigenBase< OtherDerived > &_other) |
| template<typename OtherDerived > | |
| PlainObjectBase (const DenseBase< OtherDerived > &other) | |
| template<typename OtherDerived > | |
| PlainObjectBase (const EigenBase< OtherDerived > &other) | |
| PlainObjectBase (const PlainObjectBase &other) | |
| template<typename OtherDerived > | |
| PlainObjectBase (const ReturnByValue< OtherDerived > &other) | |
| Copy constructor with in-place evaluation. |
|
| template<typename... ArgTypes> | |
| PlainObjectBase (const Scalar &a0, const Scalar &a1, const Scalar &a2, const Scalar &a3, const ArgTypes &... args) | |
| Construct a row of column vector with fixed size from an arbitrary number of coefficients. [c++11] More... |
|
| PlainObjectBase (const std::initializer_list< std::initializer_list< Scalar >> &list) | |
| Constructs a Matrix or Array and initializes it by elements given by an initializer list of initializer lists [c++11] |
|
|
These are convenience functions returning Map objects. The Map() static functions return unaligned Map objects, while the AlignedMap() functions return aligned Map objects and thus should be called only with 16-byte-aligned data pointers. Here is an example using strides: Matrix4i A;
A << 1, 2, 3, 4,
5, 6, 7, 8,
9, 10, 11, 12,
13, 14, 15, 16;
std::cout << Matrix2i::Map(&A(1,1),Stride<8,2>()) << std::endl;
Output: 6 8 14 16
| |
| Derived & | setConstant (Index size, const Scalar &val) |
| Derived & | setConstant (Index rows, Index cols, const Scalar &val) |
| Derived & | setConstant (NoChange_t, Index cols, const Scalar &val) |
| Derived & | setConstant (Index rows, NoChange_t, const Scalar &val) |
| Derived & | setZero (Index size) |
| Derived & | setZero (Index rows, Index cols) |
| Derived & | setZero (NoChange_t, Index cols) |
| Derived & | setZero (Index rows, NoChange_t) |
| Derived & | setOnes (Index size) |
| Derived & | setOnes (Index rows, Index cols) |
| Derived & | setOnes (NoChange_t, Index cols) |
| Derived & | setOnes (Index rows, NoChange_t) |
| Derived & | setRandom (Index size) |
| Derived & | setRandom (Index rows, Index cols) |
| Derived & | setRandom (NoChange_t, Index cols) |
| Derived & | setRandom (Index rows, NoChange_t) |
| template<typename OtherDerived > | |
| void | _resize_to_match (const EigenBase< OtherDerived > &other) |
| template<typename OtherDerived > | |
| Derived & | _set (const DenseBase< OtherDerived > &other) |
Copies the value of the expression other into *this with automatic resizing. More... |
|
| template<typename OtherDerived > | |
| Derived & | _set_noalias (const DenseBase< OtherDerived > &other) |
| template<typename T0 , typename T1 > | |
| void | _init2 (Index rows, Index cols, typename internal::enable_if< Base::SizeAtCompileTime!=2, T0 >::type *=0) |
| template<typename T0 , typename T1 > | |
| void | _init2 (const T0 &val0, const T1 &val1, typename internal::enable_if< Base::SizeAtCompileTime==2, T0 >::type *=0) |
| template<typename T0 , typename T1 > | |
| void | _init2 (const Index &val0, const Index &val1, typename internal::enable_if<(!internal::is_same< Index, Scalar >::value) &&(internal::is_same< T0, Index >::value) &&(internal::is_same< T1, Index >::value) &&Base::SizeAtCompileTime==2, T1 >::type *=0) |
| template<typename T > | |
| void | _init1 (Index size, typename internal::enable_if<(Base::SizeAtCompileTime!=1||!internal::is_convertible< T, Scalar >::value) &&((!internal::is_same< typename internal::traits< Derived >::XprKind, ArrayXpr >::value||Base::SizeAtCompileTime==Dynamic)), T >::type *=0) |
| template<typename T > | |
| void | _init1 (const Scalar &val0, typename internal::enable_if< Base::SizeAtCompileTime==1 &&internal::is_convertible< T, Scalar >::value, T >::type *=0) |
| template<typename T > | |
| void | _init1 (const Index &val0, typename internal::enable_if<(!internal::is_same< Index, Scalar >::value) &&(internal::is_same< Index, T >::value) &&Base::SizeAtCompileTime==1 &&internal::is_convertible< T, Scalar >::value, T * >::type *=0) |
| template<typename T > | |
| void | _init1 (const Scalar *data) |
| template<typename T , typename OtherDerived > | |
| void | _init1 (const DenseBase< OtherDerived > &other) |
| template<typename T > | |
| void | _init1 (const Derived &other) |
| template<typename T , typename OtherDerived > | |
| void | _init1 (const EigenBase< OtherDerived > &other) |
| template<typename T , typename OtherDerived > | |
| void | _init1 (const ReturnByValue< OtherDerived > &other) |
| template<typename T , typename OtherDerived , int ColsAtCompileTime> | |
| void | _init1 (const RotationBase< OtherDerived, ColsAtCompileTime > &r) |
| template<typename T > | |
| void | _init1 (const Scalar &val0, typename internal::enable_if< Base::SizeAtCompileTime!=Dynamic &&Base::SizeAtCompileTime!=1 &&internal::is_convertible< T, Scalar >::value &&internal::is_same< typename internal::traits< Derived >::XprKind, ArrayXpr >::value, T >::type *=0) |
| template<typename T > | |
| void | _init1 (const Index &val0, typename internal::enable_if<(!internal::is_same< Index, Scalar >::value) &&(internal::is_same< Index, T >::value) &&Base::SizeAtCompileTime!=Dynamic &&Base::SizeAtCompileTime!=1 &&internal::is_convertible< T, Scalar >::value &&internal::is_same< typename internal::traits< Derived >::XprKind, ArrayXpr >::value, T * >::type *=0) |
| static ConstMapType | Map (const Scalar *data) |
| static MapType | Map (Scalar *data) |
| static ConstMapType | Map (const Scalar *data, Index size) |
| static MapType | Map (Scalar *data, Index size) |
| static ConstMapType | Map (const Scalar *data, Index rows, Index cols) |
| static MapType | Map (Scalar *data, Index rows, Index cols) |
| static ConstAlignedMapType | MapAligned (const Scalar *data) |
| static AlignedMapType | MapAligned (Scalar *data) |
| static ConstAlignedMapType | MapAligned (const Scalar *data, Index size) |
| static AlignedMapType | MapAligned (Scalar *data, Index size) |
| static ConstAlignedMapType | MapAligned (const Scalar *data, Index rows, Index cols) |
| static AlignedMapType | MapAligned (Scalar *data, Index rows, Index cols) |
| template<int Outer, int Inner> | |
| static StridedConstMapType< Stride< Outer, Inner > >::type | Map (const Scalar *data, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedMapType< Stride< Outer, Inner > >::type | Map (Scalar *data, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedConstMapType< Stride< Outer, Inner > >::type | Map (const Scalar *data, Index size, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedMapType< Stride< Outer, Inner > >::type | Map (Scalar *data, Index size, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedConstMapType< Stride< Outer, Inner > >::type | Map (const Scalar *data, Index rows, Index cols, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedMapType< Stride< Outer, Inner > >::type | Map (Scalar *data, Index rows, Index cols, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedConstAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (const Scalar *data, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (Scalar *data, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedConstAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (const Scalar *data, Index size, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (Scalar *data, Index size, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedConstAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (const Scalar *data, Index rows, Index cols, const Stride< Outer, Inner > &stride) |
| template<int Outer, int Inner> | |
| static StridedAlignedMapType< Stride< Outer, Inner > >::type | MapAligned (Scalar *data, Index rows, Index cols, const Stride< Outer, Inner > &stride) |
PlainObjectBase() [1/4]
| inlineprotected |
Copy constructor
PlainObjectBase() [2/4]
| inlineprotected |
Construct a row of column vector with fixed size from an arbitrary number of coefficients. [c++11]
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
This constructor is for 1D array or vectors with more than 4 coefficients. There exists C++98 analogue constructors for fixed-size array/vector having 1, 2, 3, or 4 coefficients.
- Warning
- To construct a column (resp. row) vector of fixed length, the number of values passed to this constructor must match the the fixed number of rows (resp. columns) of
*this.
PlainObjectBase() [3/4]
| inlineprotected |
PlainObjectBase() [4/4]
| inlineprotected |
_init1() [1/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [2/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [3/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [4/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [5/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [6/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [7/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [8/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [9/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [10/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init1() [11/11]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init2() [1/3]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init2() [2/3]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_init2() [3/3]
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_resize_to_match()
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
_set()
| inlineprotected |
Copies the value of the expression other into *this with automatic resizing.
*this might be resized to match the dimensions of other. If *this was a null matrix (not already initialized), it will be initialized.
Note that copying a row-vector into a vector (and conversely) is allowed. The resizing, if any, is then done in the appropriate way so that row-vectors remain row-vectors and vectors remain vectors.
- See also
- operator=(const MatrixBase<OtherDerived>&), _set_noalias()
_set_noalias()
| inlineprotected |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
coeff() [1/2]
| inline |
This is an overloaded version of DenseCoeffsBase<Derived,ReadOnlyAccessors>::coeff(Index) const provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts.
See DenseCoeffsBase<Derived,ReadOnlyAccessors>::coeff(Index) const for details.
coeff() [2/2]
| inline |
This is an overloaded version of DenseCoeffsBase<Derived,ReadOnlyAccessors>::coeff(Index,Index) const provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts.
See DenseCoeffsBase<Derived,ReadOnlyAccessors>::coeff(Index) const for details.
coeffRef() [1/4]
| inline |
This is an overloaded version of DenseCoeffsBase<Derived,WriteAccessors>::coeffRef(Index) const provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts.
See DenseCoeffsBase<Derived,WriteAccessors>::coeffRef(Index) const for details.
coeffRef() [2/4]
| inline |
This is the const version of coeffRef(Index) which is thus synonym of coeff(Index). It is provided for convenience.
coeffRef() [3/4]
| inline |
This is an overloaded version of DenseCoeffsBase<Derived,WriteAccessors>::coeffRef(Index,Index) const provided to by-pass the creation of an evaluator of the expression, thus saving compilation efforts.
See DenseCoeffsBase<Derived,WriteAccessors>::coeffRef(Index,Index) const for details.
coeffRef() [4/4]
| inline |
This is the const version of coeffRef(Index,Index) which is thus synonym of coeff(Index,Index). It is provided for convenience.
conservativeResize() [1/4]
| inline |
Resizes the matrix to rows x cols while leaving old values untouched.
The method is intended for matrices of dynamic size. If you only want to change the number of rows and/or of columns, you can use conservativeResize(NoChange_t, Index) or conservativeResize(Index, NoChange_t).
Matrices are resized relative to the top-left element. In case values need to be appended to the matrix they will be uninitialized.
conservativeResize() [2/4]
| inline |
Resizes the matrix to rows x cols while leaving old values untouched.
As opposed to conservativeResize(Index rows, Index cols), this version leaves the number of columns unchanged.
In case the matrix is growing, new rows will be uninitialized.
conservativeResize() [3/4]
| inline |
Resizes the vector to size while retaining old values.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.. This method does not work for partially dynamic matrices when the static dimension is anything other than 1. For example it will not work with Matrix<double, 2, Dynamic>.
When values are appended, they will be uninitialized.
conservativeResize() [4/4]
| inline |
Resizes the matrix to rows x cols while leaving old values untouched.
As opposed to conservativeResize(Index rows, Index cols), this version leaves the number of rows unchanged.
In case the matrix is growing, new columns will be uninitialized.
conservativeResizeLike()
| inline |
Resizes the matrix to rows x cols of other, while leaving old values untouched.
The method is intended for matrices of dynamic size. If you only want to change the number of rows and/or of columns, you can use conservativeResize(NoChange_t, Index) or conservativeResize(Index, NoChange_t).
Matrices are resized relative to the top-left element. In case values need to be appended to the matrix they will copied from other.
data() [1/2]
| inline |
- Returns
- a pointer to the data array of this matrix
data() [2/2]
| inline |
- Returns
- a const pointer to the data array of this matrix
lazyAssign()
| inline |
- See also
- MatrixBase::lazyAssign()
Map() [1/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [2/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [3/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [4/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [5/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [6/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [7/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [8/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [9/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [10/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [11/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
Map() [12/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [1/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [2/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [3/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [4/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [5/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [6/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [7/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [8/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [9/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [10/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [11/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
MapAligned() [12/12]
| inlinestatic |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
operator=() [1/2]
| inline |
Copies the generic expression other into *this.
The expression must provide a (templated) evalTo(Derived& dst) const function which does the actual job. In practice, this allows any user to write its own special matrix without having to modify MatrixBase
- Returns
- a reference to *this.
operator=() [2/2]
| inline |
This is a special case of the templated operator=. Its purpose is to prevent a default operator= from hiding the templated operator=.
resize() [1/4]
| inline |
Resizes *this to a rows x cols matrix.
This method is intended for dynamic-size matrices, although it is legal to call it on any matrix as long as fixed dimensions are left unchanged. If you only want to change the number of rows and/or of columns, you can use resize(NoChange_t, Index), resize(Index, NoChange_t).
If the current number of coefficients of *this exactly matches the product rows * cols, then no memory allocation is performed and the current values are left unchanged. In all other cases, including shrinking, the data is reallocated and all previous values are lost.
Example:
MatrixXd m(2,3); m << 1,2,3,4,5,6; cout << "here's the 2x3 matrix m:" << endl << m << endl; cout << "let's resize m to 3x2. This is a conservative resizing because 2*3==3*2." << endl; m.resize(3,2); cout << "here's the 3x2 matrix m:" << endl << m << endl; cout << "now let's resize m to size 2x2. This is NOT a conservative resizing, so it becomes uninitialized:" << endl; m.resize(2,2); cout << m << endl;
Output:
here's the 2x3 matrix m: 1 2 3 4 5 6 let's resize m to 3x2. This is a conservative resizing because 2*3==3*2. here's the 3x2 matrix m: 1 5 4 3 2 6 now let's resize m to size 2x2. This is NOT a conservative resizing, so it becomes uninitialized: 0 0 0 0
- See also
- resize(Index) for vectors, resize(NoChange_t, Index), resize(Index, NoChange_t)
resize() [2/4]
| inline |
Resizes the matrix, changing only the number of rows. For the parameter of type NoChange_t, just pass the special value NoChange as in the example below.
Example:
MatrixXd m(3,4); m.resize(5, NoChange); cout << "m: " << m.rows() << " rows, " << m.cols() << " cols" << endl;
Output:
m: 5 rows, 4 cols
- See also
- resize(Index,Index)
resize() [3/4]
| inline |
Resizes *this to a vector of length size
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.. This method does not work for partially dynamic matrices when the static dimension is anything other than 1. For example it will not work with Matrix<double, 2, Dynamic>.
Example:
VectorXd v(10); v.resize(3); RowVector3d w; w.resize(3); // this is legal, but has no effect cout << "v: " << v.rows() << " rows, " << v.cols() << " cols" << endl; cout << "w: " << w.rows() << " rows, " << w.cols() << " cols" << endl;
Output:
v: 3 rows, 1 cols w: 1 rows, 3 cols
resize() [4/4]
| inline |
Resizes the matrix, changing only the number of columns. For the parameter of type NoChange_t, just pass the special value NoChange as in the example below.
Example:
MatrixXd m(3,4); m.resize(NoChange, 5); cout << "m: " << m.rows() << " rows, " << m.cols() << " cols" << endl;
Output:
m: 3 rows, 5 cols
- See also
- resize(Index,Index)
resizeLike()
| inline |
Resizes *this to have the same dimensions as other. Takes care of doing all the checking that's needed.
Note that copying a row-vector into a vector (and conversely) is allowed. The resizing, if any, is then done in the appropriate way so that row-vectors remain row-vectors and vectors remain vectors.
setConstant() [1/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
- Parameters
-
rows the new number of rows cols the new number of columns val the value to which all coefficients are set
Example:
MatrixXf m; m.setConstant(3, 3, 5); cout << m << endl;
Output:
5 5 5 5 5 5 5 5 5
setConstant() [2/4]
| inline |
Resizes to the given size, changing only the number of rows, and sets all coefficients in this expression to the given value val. For the parameter of type NoChange_t, just pass the special value NoChange.
setConstant() [3/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to the given value val.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setConstant(3, 5); cout << v << endl;
Output:
5 5 5
setConstant() [4/4]
| inline |
Resizes to the given size, changing only the number of columns, and sets all coefficients in this expression to the given value val. For the parameter of type NoChange_t, just pass the special value NoChange.
setOnes() [1/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to one.
- Parameters
-
rows the new number of rows cols the new number of columns
Example:
MatrixXf m; m.setOnes(3, 3); cout << m << endl;
Output:
1 1 1 1 1 1 1 1 1
- See also
- MatrixBase::setOnes(), setOnes(Index), class CwiseNullaryOp, MatrixBase::Ones()
setOnes() [2/4]
| inline |
Resizes to the given size, changing only the number of rows, and sets all coefficients in this expression to one. For the parameter of type NoChange_t, just pass the special value NoChange.
setOnes() [3/4]
| inline |
Resizes to the given newSize, and sets all coefficients in this expression to one.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setOnes(3); cout << v << endl;
Output:
1 1 1
- See also
- MatrixBase::setOnes(), setOnes(Index,Index), class CwiseNullaryOp, MatrixBase::Ones()
setOnes() [4/4]
| inline |
Resizes to the given size, changing only the number of columns, and sets all coefficients in this expression to one. For the parameter of type NoChange_t, just pass the special value NoChange.
setRandom() [1/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to random values.
Numbers are uniformly spread through their whole definition range for integer types, and in the [-1:1] range for floating point scalar types.
- Warning
- This function is not re-entrant.
- Parameters
-
rows the new number of rows cols the new number of columns
Example:
MatrixXf m; m.setRandom(3, 3); cout << m << endl;
Output:
0.68 0.597 -0.33 -0.211 0.823 0.536 0.566 -0.605 -0.444
- See also
- DenseBase::setRandom(), setRandom(Index), class CwiseNullaryOp, DenseBase::Random()
setRandom() [2/4]
| inline |
Resizes to the given size, changing only the number of rows, and sets all coefficients in this expression to random values. For the parameter of type NoChange_t, just pass the special value NoChange.
Numbers are uniformly spread through their whole definition range for integer types, and in the [-1:1] range for floating point scalar types.
- Warning
- This function is not re-entrant.
setRandom() [3/4]
| inline |
Resizes to the given newSize, and sets all coefficients in this expression to random values.
Numbers are uniformly spread through their whole definition range for integer types, and in the [-1:1] range for floating point scalar types.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
- Warning
- This function is not re-entrant.
Example:
VectorXf v; v.setRandom(3); cout << v << endl;
Output:
0.68 -0.211 0.566
- See also
- DenseBase::setRandom(), setRandom(Index,Index), class CwiseNullaryOp, DenseBase::Random()
setRandom() [4/4]
| inline |
Resizes to the given size, changing only the number of columns, and sets all coefficients in this expression to random values. For the parameter of type NoChange_t, just pass the special value NoChange.
Numbers are uniformly spread through their whole definition range for integer types, and in the [-1:1] range for floating point scalar types.
- Warning
- This function is not re-entrant.
setZero() [1/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to zero.
- Parameters
-
rows the new number of rows cols the new number of columns
Example:
MatrixXf m; m.setZero(3, 3); cout << m << endl;
Output:
0 0 0 0 0 0 0 0 0
- See also
- DenseBase::setZero(), setZero(Index), class CwiseNullaryOp, DenseBase::Zero()
setZero() [2/4]
| inline |
Resizes to the given size, changing only the number of rows, and sets all coefficients in this expression to zero. For the parameter of type NoChange_t, just pass the special value NoChange.
setZero() [3/4]
| inline |
Resizes to the given size, and sets all coefficients in this expression to zero.
This is only for vectors (either row-vectors or column-vectors), i.e. matrices which are known at compile-time to have either one row or one column.
Example:
VectorXf v; v.setZero(3); cout << v << endl;
Output:
0 0 0
- See also
- DenseBase::setZero(), setZero(Index,Index), class CwiseNullaryOp, DenseBase::Zero()
setZero() [4/4]
| inline |
Resizes to the given size, changing only the number of columns, and sets all coefficients in this expression to zero. For the parameter of type NoChange_t, just pass the special value NoChange.
The documentation for this class was generated from the following files:
© Eigen.
Licensed under the MPL2 License.
https://eigen.tuxfamily.org/dox/classEigen_1_1PlainObjectBase.html