#include <example_02.hpp>
Inheritance diagram for OptDualStdVector< Real, Element >:
Public Member Functions | |
| OptDualStdVector (const ROL::Ptr< std::vector< Element > > &std_vec) | |
| void | plus (const ROL::Vector< Real > &x) |
| Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\). More... | |
| void | scale (const Real alpha) |
| Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\). More... | |
| Real | dot (const ROL::Vector< Real > &x) const |
| Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\). More... | |
| Real | norm () const |
| Returns \( \| y \| \) where \(y = \mathtt{*this}\). More... | |
| ROL::Ptr< ROL::Vector< Real > > | clone () const |
| Clone to make a new (uninitialized) vector. More... | |
| ROL::Ptr< const std::vector< Element > > | getVector () const |
| ROL::Ptr< std::vector< Element > > | getVector () |
| ROL::Ptr< ROL::Vector< Real > > | basis (const int i) const |
| Return i-th basis vector. More... | |
| int | dimension () const |
| Return dimension of the vector space. More... | |
| const ROL::Vector< Real > & | dual () const |
| Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout. More... | |
| OptDualStdVector (const ROL::Ptr< std::vector< Element > > &std_vec) | |
| void | plus (const ROL::Vector< Real > &x) |
| Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\). More... | |
| void | scale (const Real alpha) |
| Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\). More... | |
| Real | dot (const ROL::Vector< Real > &x) const |
| Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\). More... | |
| Real | norm () const |
| Returns \( \| y \| \) where \(y = \mathtt{*this}\). More... | |
| ROL::Ptr< ROL::Vector< Real > > | clone () const |
| Clone to make a new (uninitialized) vector. More... | |
| ROL::Ptr< const std::vector< Element > > | getVector () const |
| ROL::Ptr< std::vector< Element > > | getVector () |
| ROL::Ptr< ROL::Vector< Real > > | basis (const int i) const |
| Return i-th basis vector. More... | |
| int | dimension () const |
| Return dimension of the vector space. More... | |
| const ROL::Vector< Real > & | dual () const |
| Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout. More... | |
| OptDualStdVector (const ROL::Ptr< std::vector< Element > > &std_vec, ROL::Ptr< FiniteDifference< Real > >fd) | |
| void | plus (const Vector< Real > &x) |
| Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\). More... | |
| void | scale (const Real alpha) |
| Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\). More... | |
| Real | dot (const Vector< Real > &x) const |
| Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\). More... | |
| Real | norm () const |
| Returns \( \| y \| \) where \(y = \mathtt{*this}\). More... | |
| ROL::Ptr< Vector< Real > > | clone () const |
| Clone to make a new (uninitialized) vector. More... | |
| ROL::Ptr< const std::vector< Element > > | getVector () const |
| ROL::Ptr< std::vector< Element > > | getVector () |
| ROL::Ptr< Vector< Real > > | basis (const int i) const |
| Return i-th basis vector. More... | |
| int | dimension () const |
| Return dimension of the vector space. More... | |
| const Vector< Real > & | dual () const |
| Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout. More... | |
| Public Member Functions inherited from ROL::Vector< Real > | |
| virtual | ~Vector () |
| virtual void | axpy (const Real alpha, const Vector &x) |
| Compute \(y \leftarrow \alpha x + y\) where \(y = \mathtt{*this}\). More... | |
| virtual void | zero () |
| Set to zero vector. More... | |
| virtual void | set (const Vector &x) |
| Set \(y \leftarrow x\) where \(y = \mathtt{*this}\). More... | |
| virtual void | applyUnary (const Elementwise::UnaryFunction< Real > &f) |
| virtual void | applyBinary (const Elementwise::BinaryFunction< Real > &f, const Vector &x) |
| virtual Real | reduce (const Elementwise::ReductionOp< Real > &r) const |
| virtual void | print (std::ostream &outStream) const |
| virtual void | setScalar (const Real C) |
| Set \(y \leftarrow C\) where \(C\in\mathbb{R}\). More... | |
| virtual void | randomize (const Real l=0.0, const Real u=1.0) |
| Set vector to be uniform random between [l,u]. More... | |
| virtual std::vector< Real > | checkVector (const Vector< Real > &x, const Vector< Real > &y, const bool printToStream=true, std::ostream &outStream=std::cout) const |
| Verify vector-space methods. More... | |
Private Types | |
| typedef std::vector< Element > | vector |
| typedef ROL::Vector< Real > | V |
| typedef vector::size_type | uint |
| typedef std::vector< Element > | vector |
| typedef ROL::Vector< Real > | V |
| typedef vector::size_type | uint |
| typedef std::vector< Element > | vector |
| typedef vector::size_type | uint |
Private Attributes | |
| ROL::Ptr< std::vector< Element > > | std_vec_ |
| ROL::Ptr< OptStdVector< Real > > | dual_vec_ |
| ROL::Ptr< FiniteDifference< Real > > | fd_ |
Detailed Description
template<class Real, class Element>
class OptDualStdVector< Real, Element >
Definition at line 69 of file dual-spaces/rosenbrock-1/example_01.cpp.
Member Typedef Documentation
◆ vector [1/3]
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private |
Definition at line 160 of file dual-spaces/rosenbrock-1/example_01.cpp.
◆ V [1/2]
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private |
Definition at line 161 of file dual-spaces/rosenbrock-1/example_01.cpp.
◆ uint [1/3]
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private |
Definition at line 163 of file dual-spaces/rosenbrock-1/example_01.cpp.
◆ vector [2/3]
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private |
Definition at line 166 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
◆ V [2/2]
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private |
Definition at line 167 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
◆ uint [2/3]
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private |
Definition at line 168 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
◆ vector [3/3]
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private |
Definition at line 211 of file gross-pitaevskii/example_02.hpp.
◆ uint [3/3]
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private |
Definition at line 212 of file gross-pitaevskii/example_02.hpp.
Constructor & Destructor Documentation
◆ OptDualStdVector() [1/3]
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inline |
Definition at line 171 of file dual-spaces/rosenbrock-1/example_01.cpp.
◆ OptDualStdVector() [2/3]
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inline |
Definition at line 176 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
◆ OptDualStdVector() [3/3]
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inline |
Definition at line 221 of file gross-pitaevskii/example_02.hpp.
Member Function Documentation
◆ plus() [1/3]
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inlinevirtual |
Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\).
@param[in] x is the vector to be added to \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \mathtt{*this} + x\f$.
---
Implements ROL::Vector< Real >.
Definition at line 173 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
◆ scale() [1/3]
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inlinevirtual |
Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\).
@param[in] alpha is the scaling of \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \alpha (\mathtt{*this}) \f$.
---
Implements ROL::Vector< Real >.
Definition at line 183 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
◆ dot() [1/3]
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inlinevirtual |
Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\).
@param[in] x is the vector that forms the dot product with \f$\mathtt{*this}\f$.
@return The number equal to \f$\langle \mathtt{*this}, x \rangle\f$.
---
Implements ROL::Vector< Real >.
Definition at line 190 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
Referenced by OptDualStdVector< Real, Element >::norm().
◆ norm() [1/3]
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inlinevirtual |
Returns \( \| y \| \) where \(y = \mathtt{*this}\).
@return A nonnegative number equal to the norm of \f$\mathtt{*this}\f$.
---
Implements ROL::Vector< Real >.
Definition at line 201 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dot().
◆ clone() [1/3]
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inlinevirtual |
Clone to make a new (uninitialized) vector.
@return A reference-counted pointer to the cloned vector. Provides the means of allocating temporary memory in ROL. ---
Implements ROL::Vector< Real >.
Definition at line 207 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ getVector() [1/6]
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inline |
Definition at line 211 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
Referenced by OptDualStdVector< Real, Element >::dot(), and OptDualStdVector< Real, Element >::plus().
◆ getVector() [2/6]
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inline |
Definition at line 215 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ basis() [1/3]
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inlinevirtual |
Return i-th basis vector.
@param[in] i is the index of the basis function. @return A reference-counted pointer to the basis vector with index @b i. Overloading the basis is only required if the default gradient implementation is used, which computes a finite-difference approximation. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 219 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ dimension() [1/3]
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inlinevirtual |
Return dimension of the vector space.
@return The dimension of the vector space, i.e., the total number of basis vectors. Overload if the basis is overloaded. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 228 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
Referenced by OptDualStdVector< Real, Element >::dot(), OptDualStdVector< Real, Element >::plus(), and OptDualStdVector< Real, Element >::scale().
◆ dual() [1/3]
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inlinevirtual |
Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout.
- Returns
- A const reference to dual representation.
By default, returns the current object. Please overload if you need a dual representation.
Reimplemented from ROL::Vector< Real >.
Definition at line 230 of file dual-spaces/rosenbrock-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dual_vec_.
◆ plus() [2/3]
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inlinevirtual |
Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\).
@param[in] x is the vector to be added to \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \mathtt{*this} + x\f$.
---
Implements ROL::Vector< Real >.
Definition at line 178 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
◆ scale() [2/3]
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inlinevirtual |
Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\).
@param[in] alpha is the scaling of \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \alpha (\mathtt{*this}) \f$.
---
Implements ROL::Vector< Real >.
Definition at line 187 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
◆ dot() [2/3]
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inlinevirtual |
Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\).
@param[in] x is the vector that forms the dot product with \f$\mathtt{*this}\f$.
@return The number equal to \f$\langle \mathtt{*this}, x \rangle\f$.
---
Implements ROL::Vector< Real >.
Definition at line 194 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dimension(), and OptDualStdVector< Real, Element >::std_vec_.
◆ norm() [2/3]
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inlinevirtual |
Returns \( \| y \| \) where \(y = \mathtt{*this}\).
@return A nonnegative number equal to the norm of \f$\mathtt{*this}\f$.
---
Implements ROL::Vector< Real >.
Definition at line 205 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dot().
◆ clone() [2/3]
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inlinevirtual |
Clone to make a new (uninitialized) vector.
@return A reference-counted pointer to the cloned vector. Provides the means of allocating temporary memory in ROL. ---
Implements ROL::Vector< Real >.
Definition at line 211 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ getVector() [3/6]
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inline |
Definition at line 215 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ getVector() [4/6]
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inline |
Definition at line 219 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ basis() [2/3]
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inlinevirtual |
Return i-th basis vector.
@param[in] i is the index of the basis function. @return A reference-counted pointer to the basis vector with index @b i. Overloading the basis is only required if the default gradient implementation is used, which computes a finite-difference approximation. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 223 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ dimension() [2/3]
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inlinevirtual |
Return dimension of the vector space.
@return The dimension of the vector space, i.e., the total number of basis vectors. Overload if the basis is overloaded. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 231 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::std_vec_.
◆ dual() [2/3]
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inlinevirtual |
Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout.
- Returns
- A const reference to dual representation.
By default, returns the current object. Please overload if you need a dual representation.
Reimplemented from ROL::Vector< Real >.
Definition at line 233 of file dual-spaces/simple-eq-constr-1/example_01.cpp.
References OptDualStdVector< Real, Element >::dual_vec_.
◆ plus() [3/3]
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inlinevirtual |
Compute \(y \leftarrow y + x\), where \(y = \mathtt{*this}\).
@param[in] x is the vector to be added to \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \mathtt{*this} + x\f$.
---
Implements ROL::Vector< Real >.
Definition at line 224 of file gross-pitaevskii/example_02.hpp.
References OptDualStdVector< Real, Element >::getVector().
◆ scale() [3/3]
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inlinevirtual |
Compute \(y \leftarrow \alpha y\) where \(y = \mathtt{*this}\).
@param[in] alpha is the scaling of \f$\mathtt{*this}\f$.
On return \f$\mathtt{*this} = \alpha (\mathtt{*this}) \f$.
---
Implements ROL::Vector< Real >.
Definition at line 233 of file gross-pitaevskii/example_02.hpp.
◆ dot() [3/3]
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inlinevirtual |
Compute \( \langle y,x \rangle \) where \(y = \mathtt{*this}\).
@param[in] x is the vector that forms the dot product with \f$\mathtt{*this}\f$.
@return The number equal to \f$\langle \mathtt{*this}, x \rangle\f$.
---
Implements ROL::Vector< Real >.
Definition at line 240 of file gross-pitaevskii/example_02.hpp.
References OptDualStdVector< Real, Element >::getVector().
◆ norm() [3/3]
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inlinevirtual |
Returns \( \| y \| \) where \(y = \mathtt{*this}\).
@return A nonnegative number equal to the norm of \f$\mathtt{*this}\f$.
---
Implements ROL::Vector< Real >.
Definition at line 254 of file gross-pitaevskii/example_02.hpp.
◆ clone() [3/3]
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inlinevirtual |
Clone to make a new (uninitialized) vector.
@return A reference-counted pointer to the cloned vector. Provides the means of allocating temporary memory in ROL. ---
Implements ROL::Vector< Real >.
Definition at line 260 of file gross-pitaevskii/example_02.hpp.
◆ getVector() [5/6]
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inline |
Definition at line 264 of file gross-pitaevskii/example_02.hpp.
◆ getVector() [6/6]
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inline |
Definition at line 268 of file gross-pitaevskii/example_02.hpp.
◆ basis() [3/3]
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inlinevirtual |
Return i-th basis vector.
@param[in] i is the index of the basis function. @return A reference-counted pointer to the basis vector with index @b i. Overloading the basis is only required if the default gradient implementation is used, which computes a finite-difference approximation. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 272 of file gross-pitaevskii/example_02.hpp.
◆ dimension() [3/3]
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inlinevirtual |
Return dimension of the vector space.
@return The dimension of the vector space, i.e., the total number of basis vectors. Overload if the basis is overloaded. ---
Reimplemented from ROL::Vector< Real >.
Definition at line 279 of file gross-pitaevskii/example_02.hpp.
◆ dual() [3/3]
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inlinevirtual |
Return dual representation of \(\mathtt{*this}\), for example, the result of applying a Riesz map, or change of basis, or change of memory layout.
- Returns
- A const reference to dual representation.
By default, returns the current object. Please overload if you need a dual representation.
Reimplemented from ROL::Vector< Real >.
Definition at line 281 of file gross-pitaevskii/example_02.hpp.
Member Data Documentation
◆ std_vec_
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private |
Definition at line 166 of file dual-spaces/rosenbrock-1/example_01.cpp.
Referenced by OptDualStdVector< Real, Element >::basis(), OptDualStdVector< Real, Element >::clone(), OptDualStdVector< Real, Element >::dimension(), OptDualStdVector< Real, Element >::dot(), OptDualStdVector< Real, Element >::getVector(), OptDualStdVector< Real, Element >::plus(), and OptDualStdVector< Real, Element >::scale().
◆ dual_vec_
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mutableprivate |
Definition at line 167 of file dual-spaces/rosenbrock-1/example_01.cpp.
Referenced by OptDualStdVector< Real, Element >::dual().
◆ fd_
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private |
Definition at line 217 of file gross-pitaevskii/example_02.hpp.
The documentation for this class was generated from the following files:
