alpaqa 1.0.0a13
Nonconvex constrained optimization
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Namespaces | Classes | Concepts | Typedefs | Enumerations | Functions | Variables
alpaqa Namespace Reference

Namespaces

namespace  anonymous_namespace{ocproblem-counters.cpp}
 
namespace  anonymous_namespace{problem-counters.cpp}
 
namespace  anonymous_namespace{qpalm-adapter.cpp}
 
namespace  casadi_loader
 
namespace  csv
 
namespace  cutest
 
namespace  detail
 
namespace  dl
 
namespace  functions
 
namespace  lbfgsb
 
namespace  lbfgspp
 
namespace  params
 
namespace  sets
 
namespace  sparsity
 
namespace  tag_invoke_fn_ns
 
namespace  tag_invoke_ns
 
namespace  util
 
namespace  vec_util
 

Classes

struct  ALMParams
 Parameters for the Augmented Lagrangian solver. More...
 
class  ALMSolver
 Augmented Lagrangian Method solver. More...
 
class  AndersonAccel
 Anderson Acceleration. More...
 
struct  AndersonAccelParams
 Parameters for the AndersonAccel class. More...
 
struct  AndersonDirection
 
struct  AndersonDirectionParams
 Parameters for the AndersonDirection class. More...
 
class  AtomicStopSignal
 
class  BoxConstrProblem
 Implements common problem functions for minimization problems with box constraints. More...
 
class  CasADiControlProblem
 
class  CasADiProblem
 Problem definition for a CasADi problem, loaded from a DLL. More...
 
struct  CBFGSParams
 Cautious BFGS update. More...
 
struct  CircularIndexIterator
 
struct  CircularIndices
 
class  CircularRange
 
struct  ControlProblemVTable
 
struct  ControlProblemWithCounters
 
class  CUTEstLoader
 
class  CUTEstProblem
 Wrapper for CUTEst problems loaded from an external shared library. More...
 
struct  Dim
 
struct  EigenConfig
 
struct  EigenConfigd
 Double-precision double configuration. More...
 
struct  EigenConfigf
 Single-precision float configuration. More...
 
struct  EigenConfigl
 long double configuration. More...
 
struct  EvalCounter
 
class  FunctionalProblem
 Problem class that allows specifying the basic functions as C++ std::functions. More...
 
struct  InnerSolveOptions
 
struct  InnerStatsAccumulator
 
struct  InnerStatsAccumulator< lbfgsb::LBFGSBStats >
 
struct  InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > >
 
struct  InnerStatsAccumulator< PANOCOCPStats< Conf > >
 
struct  InnerStatsAccumulator< PANOCStats< Conf > >
 
struct  InnerStatsAccumulator< PANTRStats< Conf > >
 
struct  InnerStatsAccumulator< ZeroFPRStats< Conf > >
 
class  IpoptAdapter
 Based on https://coin-or.github.io/Ipopt/INTERFACES.html. More...
 
struct  is_complex_float
 
struct  is_complex_float< std::complex< T > >
 
struct  is_config
 
struct  is_config< EigenConfigd >
 
struct  is_config< EigenConfigf >
 
struct  is_config< EigenConfigl >
 
struct  is_config< EigenConfigq >
 
struct  KKTError
 
class  LBFGS
 Limited memory Broyden–Fletcher–Goldfarb–Shanno (L-BFGS) algorithm. More...
 
struct  LBFGSDirection
 
struct  LBFGSDirectionParams
 Parameters for the LBFGSDirection class. More...
 
struct  LBFGSParams
 Parameters for the LBFGS class. More...
 
struct  LBFGSStorage
 Layout: More...
 
class  LimitedMemoryQR
 Incremental QR factorization using modified Gram-Schmidt with reorthogonalization. More...
 
struct  LipschitzEstimateParams
 Parameters for the estimation of the Lipschitz constant of the gradient of the smooth term of the cost. More...
 
class  MaxHistory
 Keep track of the maximum value over a specified horizon length. More...
 
struct  NewtonTRDirection
 
struct  NewtonTRDirectionParams
 Parameters for the NewtonTRDirection class. More...
 
struct  NoopDirection
 Direction provider that provides no directions (apply always returns false). More...
 
struct  not_implemented_error
 
struct  OCPDim
 
struct  OCPEvalCounter
 
struct  OCPEvaluator
 
struct  OCPVariables
 
struct  OwningQPALMData
 
struct  PANOCDirection
 This class outlines the interface for direction providers used by PANOC-like algorithms. More...
 
struct  PANOCOCPParams
 Tuning parameters for the PANOC algorithm. More...
 
struct  PANOCOCPProgressInfo
 
class  PANOCOCPSolver
 
struct  PANOCOCPStats
 
struct  PANOCParams
 Tuning parameters for the PANOC algorithm. More...
 
struct  PANOCProgressInfo
 
class  PANOCSolver
 PANOC solver for ALM. More...
 
struct  PANOCStats
 
struct  PANTRDirection
 This class outlines the interface for direction providers used by PANTR-like algorithms. More...
 
struct  PANTRParams
 Tuning parameters for the PANTR algorithm. More...
 
struct  PANTRProgressInfo
 
class  PANTRSolver
 PANTR solver for ALM. More...
 
struct  PANTRStats
 
struct  ProblemVTable
 Struct containing function pointers to all problem functions (like the objective and constraint functions, with their derivatives, and more). More...
 
struct  ProblemWithCounters
 Problem wrapper that keeps track of the number of evaluations and the run time of each function. More...
 
struct  prox_fn
 Proximal mapping customization point. More...
 
struct  prox_step_fn
 Proximal mapping customization point for forward-backward steps. More...
 
struct  ReverseCircularIndexIterator
 
class  ReverseCircularRange
 
struct  ScopedMallocAllower
 
struct  ScopedMallocBlocker
 
struct  ScopedMallocChecker
 
struct  SerializedCasADiFunctions
 
struct  StatefulLQRFactor
 
struct  SteihaugCG
 Steihaug conjugate gradients procedure based on https://github.com/scipy/scipy/blob/583e70a50573169fc352b5dc6d94588a97c7389a/scipy/optimize/_trustregion_ncg.py#L44. More...
 
struct  SteihaugCGParams
 Parameters for SteihaugCG. More...
 
struct  StructuredLBFGSDirection
 
struct  StructuredLBFGSDirectionParams
 Parameters for the StructuredLBFGSDirection class. More...
 
struct  StructuredNewtonDirection
 
struct  StructuredNewtonDirectionParams
 Parameters for the StructuredNewtonDirection class. More...
 
struct  StructuredNewtonRegularizationParams
 Parameters for the StructuredNewtonDirection class. More...
 
class  TypeErasedControlProblem
 Nonlinear optimal control problem with finite horizon \( N \). More...
 
class  TypeErasedProblem
 The main polymorphic minimization problem interface. More...
 
class  UnconstrProblem
 Implements common problem functions for minimization problems without constraints. More...
 
struct  ZeroFPRParams
 Tuning parameters for the ZeroFPR algorithm. More...
 
struct  ZeroFPRProgressInfo
 
class  ZeroFPRSolver
 ZeroFPR solver for ALM. More...
 
struct  ZeroFPRStats
 

Concepts

concept  Config
 
concept  VectorRefLike
 
concept  float_or_complex_float
 
concept  tag_invocable
 
concept  nothrow_tag_invocable
 

Typedefs

using DefaultConfig = EigenConfigd
 
template<Config Conf = DefaultConfig>
using real_t = typename Conf::real_t
 
template<Config Conf = DefaultConfig>
using vec = typename Conf::vec
 
template<Config Conf = DefaultConfig>
using mvec = typename Conf::mvec
 
template<Config Conf = DefaultConfig>
using cmvec = typename Conf::cmvec
 
template<Config Conf = DefaultConfig>
using rvec = typename Conf::rvec
 
template<Config Conf = DefaultConfig>
using crvec = typename Conf::crvec
 
template<Config Conf = DefaultConfig>
using mat = typename Conf::mat
 
template<Config Conf = DefaultConfig>
using mmat = typename Conf::mmat
 
template<Config Conf = DefaultConfig>
using cmmat = typename Conf::cmmat
 
template<Config Conf = DefaultConfig>
using rmat = typename Conf::rmat
 
template<Config Conf = DefaultConfig>
using crmat = typename Conf::crmat
 
template<Config Conf = DefaultConfig>
using length_t = typename Conf::length_t
 
template<Config Conf = DefaultConfig>
using index_t = typename Conf::index_t
 
template<Config Conf = DefaultConfig>
using indexvec = typename Conf::indexvec
 
template<Config Conf = DefaultConfig>
using rindexvec = typename Conf::rindexvec
 
template<Config Conf = DefaultConfig>
using crindexvec = typename Conf::crindexvec
 
template<Config Conf = DefaultConfig>
using mindexvec = typename Conf::mindexvec
 
template<Config Conf = DefaultConfig>
using cmindexvec = typename Conf::cmindexvec
 
template<typename Tag , typename... Args>
using tag_invoke_result = std::invoke_result< decltype(::alpaqa::alpaqa_tag_invoke), Tag, Args... >
 
template<typename Tag , typename... Args>
using tag_invoke_result_t = std::invoke_result_t< decltype(::alpaqa::alpaqa_tag_invoke), Tag, Args... >
 
template<auto & Tag>
using tag_t = std::decay_t< decltype(Tag)>
 
using function_dict_t = alpaqa_function_dict_t
 
using problem_register_t = alpaqa_problem_register_t
 
using control_problem_register_t = alpaqa_control_problem_register_t
 
using problem_functions_t = alpaqa_problem_functions_t
 
using control_problem_functions_t = alpaqa_control_problem_functions_t
 

Enumerations

enum class  LBFGSStepSize { BasedOnExternalStepSize = 0 , BasedOnCurvature = 1 , BasedOnGradientStepSize }
 Which method to use to select the L-BFGS step size. More...
 
enum class  PANOCStopCrit {
  ApproxKKT = 0 , ApproxKKT2 , ProjGradNorm , ProjGradNorm2 ,
  ProjGradUnitNorm , ProjGradUnitNorm2 , FPRNorm , FPRNorm2 ,
  Ipopt , LBFGSBpp
}
 
enum class  SolverStatus {
  Busy = 0 , Converged , MaxTime , MaxIter ,
  NotFinite , NoProgress , Interrupted , Exception
}
 Exit status of a numerical solver such as ALM or PANOC. More...
 

Functions

template<Config Conf = DefaultConfig>
void minimize_update_anderson (LimitedMemoryQR< Conf > &qr, rmat< Conf > , crvec< Conf > rₖ, crvec< Conf > rₗₐₛₜ, crvec< Conf > gₖ, real_t< Conf > min_div_fac, rvec< Conf > γ_LS, rvec< Conf > xₖ_aa)
 Solve one step of Anderson acceleration to find a fixed point of a function g(x):
 
std::string_view float_to_str_vw_snprintf (auto &&print, auto &buf, std::floating_point auto value, int precision, const char *fmt)
 
std::string_view float_to_str_vw (auto &buf, double value, int precision=std::numeric_limits< double >::max_digits10)
 
std::string_view float_to_str_vw (auto &buf, float value, int precision=std::numeric_limits< float >::max_digits10)
 
std::string_view float_to_str_vw (auto &buf, long double value, int precision=std::numeric_limits< long double >::max_digits10)
 
template<std::floating_point F>
std::string float_to_str (F value, int precision)
 
template<std::floating_point F>
void print_elem (auto &buf, F value, std::ostream &os)
 
template<std::integral I>
void print_elem (auto &, I value, std::ostream &os)
 
template<std::floating_point F>
void print_elem (auto &buf, std::complex< F > value, std::ostream &os)
 
template<Config Conf, VectorRefLike< Conf > V>
constexpr auto const_or_mut_rvec (V &&v)
 
constexpr const charenum_name (PANOCStopCrit s)
 
std::ostream & operator<< (std::ostream &os, PANOCStopCrit s)
 
template<Config Conf>
InnerStatsAccumulator< PANOCOCPStats< Conf > > & operator+= (InnerStatsAccumulator< PANOCOCPStats< Conf > > &acc, const PANOCOCPStats< Conf > &s)
 
template<Config Conf>
InnerStatsAccumulator< PANOCStats< Conf > > & operator+= (InnerStatsAccumulator< PANOCStats< Conf > > &acc, const PANOCStats< Conf > &s)
 
template<Config Conf>
InnerStatsAccumulator< PANTRStats< Conf > > & operator+= (InnerStatsAccumulator< PANTRStats< Conf > > &acc, const PANTRStats< Conf > &s)
 
template<Config Conf>
InnerStatsAccumulator< ZeroFPRStats< Conf > > & operator+= (InnerStatsAccumulator< ZeroFPRStats< Conf > > &acc, const ZeroFPRStats< Conf > &s)
 
template<Config Conf>
KKTError< Confcompute_kkt_error (const TypeErasedProblem< Conf > &problem, crvec< Conf > x, crvec< Conf > y)
 
std::ostream & operator<< (std::ostream &, const OCPEvalCounter &)
 
OCPEvalCounter::OCPEvalTimeroperator+= (OCPEvalCounter::OCPEvalTimer &a, const OCPEvalCounter::OCPEvalTimer &b)
 
OCPEvalCounteroperator+= (OCPEvalCounter &a, const OCPEvalCounter &b)
 
OCPEvalCounter operator+ (OCPEvalCounter a, const OCPEvalCounter &b)
 
void check_finiteness (const auto &v, std::string_view msg)
 If the given vector v is not finite, break or throw an exception with the given message msg.
 
void check_finiteness (const std::floating_point auto &v, std::string_view msg)
 
template<class Problem >
auto ocproblem_with_counters (Problem &&p)
 
template<class Problem >
auto ocproblem_with_counters_ref (Problem &p)
 
std::ostream & operator<< (std::ostream &, const EvalCounter &)
 
EvalCounter::EvalTimeroperator+= (EvalCounter::EvalTimer &a, const EvalCounter::EvalTimer &b)
 
EvalCounteroperator+= (EvalCounter &a, const EvalCounter &b)
 
EvalCounter operator+ (EvalCounter a, const EvalCounter &b)
 
template<class Problem >
auto problem_with_counters (Problem &&p)
 Wraps the given problem into a ProblemWithCounters and keeps track of how many times each function is called, and how long these calls took.
 
template<class Problem >
auto problem_with_counters_ref (Problem &p)
 Wraps the given problem into a ProblemWithCounters and keeps track of how many times each function is called, and how long these calls took.
 
template<Config Conf>
void print_provided_functions (std::ostream &os, const TypeErasedProblem< Conf > &problem)
 
template<class Derived , class... Args>
std::ostream & print_csv (std::ostream &os, const Eigen::DenseBase< Derived > &M, Args &&...args)
 
template<class Derived , class... Args>
std::ostream & print_matlab (std::ostream &os, const Eigen::DenseBase< Derived > &M, Args &&...args)
 
template<class Derived , class... Args>
std::ostream & print_python (std::ostream &os, const Eigen::DenseBase< Derived > &M, Args &&...args)
 
template<class Solver >
auto attach_cancellation (Solver &solver)
 Attach SIGINT and SIGTERM handlers to stop the given solver.
 
std::ostream & operator<< (std::ostream &os, SolverStatus s)
 
template<Config Conf>
Sparsity< Confconvert_csc (const auto &sp, sparsity::Symmetry symmetry)
 
template<class Func >
void register_function (function_dict_t *&extra_functions, std::string name, Func &&func)
 Make the given function available to alpaqa.
 
template<class Func >
void register_function (problem_register_t &result, std::string name, Func &&func)
 
template<class Func >
void register_function (control_problem_register_t &result, std::string name, Func &&func)
 
template<class Result , class T , class Ret , class... Args>
void register_member_function (Result &result, std::string name, Ret(T::*member)(Args...))
 
template<auto Member>
static auto member_caller ()
 Wrap the given member function or variable into a (possibly generic) lambda function that accepts the instance as a type-erased void pointer.
 
void unregister_functions (function_dict_t *&extra_functions)
 Cleans up the extra functions registered by register_function.
 
InnerStatsAccumulator< lbfgsb::LBFGSBStats > & operator+= (InnerStatsAccumulator< lbfgsb::LBFGSBStats > &acc, const lbfgsb::LBFGSBStats &s)
 
template<Config Conf>
InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > > & operator+= (InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > > &acc, const lbfgspp::LBFGSBStats< Conf > &s)
 
OwningQPALMData build_qpalm_problem (const TypeErasedProblem< EigenConfigd > &problem)
 

Variables

template<class T >
constexpr bool is_config_v = is_config<T>::value
 
template<Config Conf>
constexpr const auto inf = std::numeric_limits<real_t<Conf>>::infinity()
 
template<Config Conf>
constexpr const auto NaN = std::numeric_limits<real_t<Conf>>::quiet_NaN()
 
template<Config Conf>
const rvec< Confnull_vec = mvec<Conf>{nullptr, 0}
 Global empty vector for convenience.
 
template<Config Conf>
const rindexvec< Confnull_indexvec = mindexvec<Conf>{nullptr, 0}
 Global empty index vector for convenience.
 
struct alpaqa::prox_fn prox
 Compute the proximal mapping.
 
struct alpaqa::prox_step_fn prox_step
 Compute a generalized forward-backward step.
 
template<class T >
constexpr bool is_complex_float_v = is_complex_float<T>::value
 
constexpr tag_invoke_fn_ns::tag_invoke_fn alpaqa_tag_invoke = {}
 
template<typename Tag , typename... Args>
constexpr bool is_tag_invocable_v = tag_invocable<Tag, Args...>
 
template<typename Tag , typename... Args>
constexpr bool is_nothrow_tag_invocable_v
 

Class Documentation

◆ alpaqa::EigenConfig

struct alpaqa::EigenConfig
+ Collaboration diagram for EigenConfig< RealT >:
Class Members
typedef RealT real_t Real scalar element type.
typedef VectorX< real_t > vec Dynamic vector type.
typedef Map< vec > mvec Map of vector type.
typedef Map< const vec > cmvec Immutable map of vector type.
typedef Ref< vec > rvec Reference to mutable vector.
typedef Ref< const vec > crvec Reference to immutable vector.
typedef MatrixX< real_t > mat Dynamic matrix type.
typedef Map< mat > mmat Map of matrix type.
typedef Map< const mat > cmmat Immutable map of matrix type.
typedef Ref< mat > rmat Reference to mutable matrix.
typedef Ref< const mat > crmat Reference to immutable matrix.
typedef Index length_t Type for lengths and sizes.
typedef Index index_t Type for vector and matrix indices.
typedef VectorX< index_t > indexvec Dynamic vector of indices.
typedef Ref< indexvec > rindexvec Reference to mutable index vector.
typedef Ref< const indexvec > crindexvec Reference to immutable index vector.
typedef Map< indexvec > mindexvec Map of index vector type.
typedef Map< const indexvec > cmindexvec Immutable map of index vector type.

◆ alpaqa::InnerSolveOptions

struct alpaqa::InnerSolveOptions
+ Collaboration diagram for InnerSolveOptions< Conf >:
Class Members
bool always_overwrite_results = true Return the final iterate and multipliers, even if the solver did not converge.
optional< nanoseconds > max_time = std::nullopt Maximum run time (in addition to the inner solver's own timeout).

Zero means no timeout.

real_t tolerance = 0 Desired tolerance (overrides the solver's own tolerance).

Zero means no tolerance (use solver's own tolerance).

ostream * os = nullptr Output stream to print to.
unsigned outer_iter = 0 The current iteration of the outer solver.
bool check = true Call TypeErasedProblem::check() before starting to solve.

◆ alpaqa::InnerStatsAccumulator

struct alpaqa::InnerStatsAccumulator
+ Collaboration diagram for InnerStatsAccumulator< InnerSolverStats >:

◆ alpaqa::InnerStatsAccumulator< lbfgsb::LBFGSBStats >

struct alpaqa::InnerStatsAccumulator< lbfgsb::LBFGSBStats >
+ Collaboration diagram for InnerStatsAccumulator< lbfgsb::LBFGSBStats >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
unsigned iterations = 0 Total number of inner PANOC iterations.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).
unsigned lbfgs_rejected = 0 Total number of times that the L-BFGS update was rejected (i.e.

it could have resulted in a non-positive definite Hessian estimate).

◆ alpaqa::InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > >

struct alpaqa::InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > >
+ Collaboration diagram for InnerStatsAccumulator< lbfgspp::LBFGSBStats< Conf > >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
unsigned iterations = 0 Total number of inner PANOC iterations.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).

◆ alpaqa::InnerStatsAccumulator< PANOCOCPStats< Conf > >

struct alpaqa::InnerStatsAccumulator< PANOCOCPStats< Conf > >
+ Collaboration diagram for InnerStatsAccumulator< PANOCOCPStats< Conf > >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
nanoseconds time_prox {} Total time spent computing proximal mappings.
nanoseconds time_forward {} Total time spent doing forward simulations.
nanoseconds time_backward {} Total time spent doing backward gradient evaluations.
nanoseconds time_jacobians {} Total time spent computing dynamics Jacobians.
nanoseconds time_hessians {} Total time spent computing cost Hessians and Hessian-vector products.
nanoseconds time_indices {} Total time spent determining active indices.
nanoseconds time_lqr_factor {} Total time spent performing LQR factorizations.
nanoseconds time_lqr_solve {} Total time spent solving the (factorized) LQR problem.
nanoseconds time_lbfgs_indices {} Total time spent determining active indices for L-BFGS applications.
nanoseconds time_lbfgs_apply {} Total time spent applying L-BFGS estimates.
nanoseconds time_lbfgs_update {} Total time spent updating the L-BFGS estimate.
nanoseconds time_progress_callback {} Total time spent in the user-provided progress callback.
unsigned iterations = 0 Total number of inner PANOC iterations.
unsigned linesearch_failures = 0 Total number of PANOC line search failures.
unsigned linesearch_backtracks = 0 Total number of PANOC line search backtracking steps.
unsigned stepsize_backtracks = 0 Total number of PANOC step size reductions.
unsigned lbfgs_failures = 0 Total number of times that the L-BFGS direction was not finite.
unsigned lbfgs_rejected = 0 Total number of times that the L-BFGS update was rejected (i.e.

it could have resulted in a non-positive definite Hessian estimate).

unsigned τ_1_accepted = 0 Total number of times that a line search parameter of \( \tau = 1 \) was accepted (i.e.

no backtracking necessary).

unsigned count_τ = 0 The total number of line searches performed (used for computing the average value of \( \tau \)).
real_t sum_τ = 0 The sum of the line search parameter \( \tau \) in all iterations (used for computing the average value of \( \tau \)).
real_t final_γ = 0 The final PANOC step size γ.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).
real_t final_h = 0 Final value of the nonsmooth cost \( h(\hat x) \).
real_t final_φγ = 0 Final value of the forward-backward envelope, \( \varphi_\gamma(x) \) (note that this is in the point \( x \), not \( \hat x \)).

◆ alpaqa::InnerStatsAccumulator< PANOCStats< Conf > >

struct alpaqa::InnerStatsAccumulator< PANOCStats< Conf > >
+ Collaboration diagram for InnerStatsAccumulator< PANOCStats< Conf > >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
nanoseconds time_progress_callback {} Total time spent in the user-provided progress callback.
unsigned iterations = 0 Total number of inner PANOC iterations.
unsigned linesearch_failures = 0 Total number of PANOC line search failures.
unsigned linesearch_backtracks = 0 Total number of PANOC line search backtracking steps.
unsigned stepsize_backtracks = 0 Total number of PANOC step size reductions.
unsigned lbfgs_failures = 0 Total number of times that the L-BFGS direction was not finite.
unsigned lbfgs_rejected = 0 Total number of times that the L-BFGS update was rejected (i.e.

it could have resulted in a non-positive definite Hessian estimate).

unsigned τ_1_accepted = 0 Total number of times that a line search parameter of \( \tau = 1 \) was accepted (i.e.

no backtracking necessary).

unsigned count_τ = 0 The total number of line searches performed (used for computing the average value of \( \tau \)).
real_t sum_τ = 0 The sum of the line search parameter \( \tau \) in all iterations (used for computing the average value of \( \tau \)).
real_t final_γ = 0 The final PANOC step size γ.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).
real_t final_h = 0 Final value of the nonsmooth cost \( h(\hat x) \).
real_t final_φγ = 0 Final value of the forward-backward envelope, \( \varphi_\gamma(x) \) (note that this is in the point \( x \), not \( \hat x \)).

◆ alpaqa::InnerStatsAccumulator< PANTRStats< Conf > >

struct alpaqa::InnerStatsAccumulator< PANTRStats< Conf > >
+ Collaboration diagram for InnerStatsAccumulator< PANTRStats< Conf > >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
nanoseconds time_progress_callback {} Total time spent in the user-provided progress callback.
unsigned iterations = 0 Total number of inner PANTR iterations.
unsigned accelerated_step_rejected = 0 Total number of PANTR rejected accelerated steps.
unsigned stepsize_backtracks = 0 Total number of FB step size reductions.
unsigned direction_failures = 0 Total number of times that the accelerated direction was not finite.
unsigned direction_update_rejected = 0 Total number of times that the direction update was rejected (e.g.

it could have resulted in a non-positive definite Hessian estimate).

real_t final_γ = 0 The final FB step size γ.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).
real_t final_h = 0 Final value of the nonsmooth cost \( h(\hat x) \).
real_t final_φγ = 0 Final value of the forward-backward envelope, \( \varphi_\gamma(x) \) (note that this is in the point \( x \), not \( \hat x \)).

◆ alpaqa::InnerStatsAccumulator< ZeroFPRStats< Conf > >

struct alpaqa::InnerStatsAccumulator< ZeroFPRStats< Conf > >
+ Collaboration diagram for InnerStatsAccumulator< ZeroFPRStats< Conf > >:
Class Members
nanoseconds elapsed_time {} Total elapsed time in the inner solver.
nanoseconds time_progress_callback {} Total time spent in the user-provided progress callback.
unsigned iterations = 0 Total number of inner ZeroFPR iterations.
unsigned linesearch_failures = 0 Total number of ZeroFPR line search failures.
unsigned linesearch_backtracks = 0 Total number of ZeroFPR line search backtracking steps.
unsigned stepsize_backtracks = 0 Total number of ZeroFPR step size reductions.
unsigned lbfgs_failures = 0 Total number of times that the L-BFGS direction was not finite.
unsigned lbfgs_rejected = 0 Total number of times that the L-BFGS update was rejected (i.e.

it could have resulted in a non-positive definite Hessian estimate).

unsigned τ_1_accepted = 0 Total number of times that a line search parameter of \( \tau = 1 \) was accepted (i.e.

no backtracking necessary).

unsigned count_τ = 0 The total number of line searches performed (used for computing the average value of \( \tau \)).
real_t sum_τ = 0 The sum of the line search parameter \( \tau \) in all iterations (used for computing the average value of \( \tau \)).
real_t final_γ = 0 The final ZeroFPR step size γ.
real_t final_ψ = 0 Final value of the smooth cost \( \psi(\hat x) \).
real_t final_h = 0 Final value of the nonsmooth cost \( h(\hat x) \).
real_t final_φγ = 0 Final value of the forward-backward envelope, \( \varphi_\gamma(x) \) (note that this is in the point \( x \), not \( \hat x \)).

◆ alpaqa::OCPDim

struct alpaqa::OCPDim
+ Collaboration diagram for OCPDim< Conf >:
Class Members
length_t N
length_t nx
length_t nu
length_t nh
length_t nc

◆ alpaqa::PANOCOCPStats

struct alpaqa::PANOCOCPStats
+ Collaboration diagram for PANOCOCPStats< Conf >:
Class Members
SolverStatus status = SolverStatus::Busy
real_t ε = inf<config_t>
nanoseconds elapsed_time {}
nanoseconds time_prox {}
nanoseconds time_forward {}
nanoseconds time_backward {}
nanoseconds time_jacobians {}
nanoseconds time_hessians {}
nanoseconds time_indices {}
nanoseconds time_lqr_factor {}
nanoseconds time_lqr_solve {}
nanoseconds time_lbfgs_indices {}
nanoseconds time_lbfgs_apply {}
nanoseconds time_lbfgs_update {}
nanoseconds time_progress_callback {}
unsigned iterations = 0
unsigned linesearch_failures = 0
unsigned linesearch_backtracks = 0
unsigned stepsize_backtracks = 0
unsigned lbfgs_failures = 0
unsigned lbfgs_rejected = 0
unsigned τ_1_accepted = 0
unsigned count_τ = 0
real_t sum_τ = 0
real_t final_γ = 0
real_t final_ψ = 0
real_t final_h = 0
real_t final_φγ = 0

◆ alpaqa::PANOCProgressInfo

struct alpaqa::PANOCProgressInfo
+ Collaboration diagram for PANOCProgressInfo< Conf >:
Class Members
unsigned k
SolverStatus status
crvec x
crvec p
real_t norm_sq_p
crvec
crvec ŷ
real_t φγ
real_t ψ
crvec grad_ψ
real_t ψ_hat
crvec grad_ψ_hat
crvec q
real_t L
real_t γ
real_t τ
real_t ε
crvec Σ
crvec y
unsigned outer_iter
const TypeErasedProblem< config_t > * problem
const PANOCParams< config_t > * params

◆ alpaqa::PANOCStats

struct alpaqa::PANOCStats
+ Collaboration diagram for PANOCStats< Conf >:
Class Members
SolverStatus status = SolverStatus::Busy
real_t ε = inf<config_t>
nanoseconds elapsed_time {}
nanoseconds time_progress_callback {}
unsigned iterations = 0
unsigned linesearch_failures = 0
unsigned linesearch_backtracks = 0
unsigned stepsize_backtracks = 0
unsigned lbfgs_failures = 0
unsigned lbfgs_rejected = 0
unsigned τ_1_accepted = 0
unsigned count_τ = 0
real_t sum_τ = 0
real_t final_γ = 0
real_t final_ψ = 0
real_t final_h = 0
real_t final_φγ = 0

◆ alpaqa::PANTRProgressInfo

struct alpaqa::PANTRProgressInfo
+ Collaboration diagram for PANTRProgressInfo< Conf >:
Class Members
unsigned k
SolverStatus status
crvec x
crvec p
real_t norm_sq_p
crvec
crvec ŷ
real_t φγ
real_t ψ
crvec grad_ψ
real_t ψ_hat
crvec grad_ψ_hat
crvec q
real_t L
real_t γ
real_t Δ
real_t ρ
real_t τ 1 if previous step accepted, 0 otherwise (PANOC compatibility)
real_t ε
crvec Σ
crvec y
unsigned outer_iter
const TypeErasedProblem< config_t > * problem
const PANTRParams< config_t > * params

◆ alpaqa::PANTRStats

struct alpaqa::PANTRStats
+ Collaboration diagram for PANTRStats< Conf >:
Class Members
SolverStatus status = SolverStatus::Busy
real_t ε = inf<config_t>
nanoseconds elapsed_time {}
nanoseconds time_progress_callback {}
unsigned iterations = 0
unsigned accelerated_step_rejected = 0
unsigned stepsize_backtracks = 0
unsigned direction_failures = 0
unsigned direction_update_rejected = 0
real_t final_γ = 0
real_t final_ψ = 0
real_t final_h = 0
real_t final_φγ = 0

◆ alpaqa::ScopedMallocChecker

struct alpaqa::ScopedMallocChecker
+ Collaboration diagram for ScopedMallocChecker< bool >:

◆ alpaqa::SerializedCasADiFunctions

struct alpaqa::SerializedCasADiFunctions
+ Collaboration diagram for SerializedCasADiFunctions:
Class Members
map< string, string > functions

◆ alpaqa::ZeroFPRProgressInfo

struct alpaqa::ZeroFPRProgressInfo
+ Collaboration diagram for ZeroFPRProgressInfo< Conf >:
Class Members
unsigned k
SolverStatus status
crvec x
crvec p
real_t norm_sq_p
crvec
crvec ŷ
real_t φγ
real_t ψ
crvec grad_ψ
real_t ψ_hat
crvec grad_ψ_hat
crvec q
real_t L
real_t γ
real_t τ
real_t ε
crvec Σ
crvec y
unsigned outer_iter
const TypeErasedProblem< config_t > * problem
const ZeroFPRParams< config_t > * params

◆ alpaqa::ZeroFPRStats

struct alpaqa::ZeroFPRStats
+ Collaboration diagram for ZeroFPRStats< Conf >:
Class Members
SolverStatus status = SolverStatus::Busy
real_t ε = inf<config_t>
nanoseconds elapsed_time {}
nanoseconds time_progress_callback {}
unsigned iterations = 0
unsigned linesearch_failures = 0
unsigned linesearch_backtracks = 0
unsigned stepsize_backtracks = 0
unsigned lbfgs_failures = 0
unsigned lbfgs_rejected = 0
unsigned τ_1_accepted = 0
unsigned count_τ = 0
real_t sum_τ = 0
real_t final_γ = 0
real_t final_ψ = 0
real_t final_h = 0
real_t final_φγ = 0

Typedef Documentation

◆ DefaultConfig

Definition at line 25 of file config.hpp.

◆ real_t

template<Config Conf = DefaultConfig>
using real_t = typename Conf::real_t

Definition at line 65 of file config.hpp.

◆ vec

template<Config Conf = DefaultConfig>
using vec = typename Conf::vec

Definition at line 66 of file config.hpp.

◆ mvec

template<Config Conf = DefaultConfig>
using mvec = typename Conf::mvec

Definition at line 67 of file config.hpp.

◆ cmvec

template<Config Conf = DefaultConfig>
using cmvec = typename Conf::cmvec

Definition at line 68 of file config.hpp.

◆ rvec

template<Config Conf = DefaultConfig>
using rvec = typename Conf::rvec

Definition at line 69 of file config.hpp.

◆ crvec

template<Config Conf = DefaultConfig>
using crvec = typename Conf::crvec

Definition at line 70 of file config.hpp.

◆ mat

template<Config Conf = DefaultConfig>
using mat = typename Conf::mat

Definition at line 71 of file config.hpp.

◆ mmat

template<Config Conf = DefaultConfig>
using mmat = typename Conf::mmat

Definition at line 72 of file config.hpp.

◆ cmmat

template<Config Conf = DefaultConfig>
using cmmat = typename Conf::cmmat

Definition at line 73 of file config.hpp.

◆ rmat

template<Config Conf = DefaultConfig>
using rmat = typename Conf::rmat

Definition at line 74 of file config.hpp.

◆ crmat

template<Config Conf = DefaultConfig>
using crmat = typename Conf::crmat

Definition at line 75 of file config.hpp.

◆ length_t

template<Config Conf = DefaultConfig>
using length_t = typename Conf::length_t

Definition at line 76 of file config.hpp.

◆ index_t

template<Config Conf = DefaultConfig>
using index_t = typename Conf::index_t

Definition at line 77 of file config.hpp.

◆ indexvec

template<Config Conf = DefaultConfig>
using indexvec = typename Conf::indexvec

Definition at line 78 of file config.hpp.

◆ rindexvec

template<Config Conf = DefaultConfig>
using rindexvec = typename Conf::rindexvec

Definition at line 79 of file config.hpp.

◆ crindexvec

template<Config Conf = DefaultConfig>
using crindexvec = typename Conf::crindexvec

Definition at line 80 of file config.hpp.

◆ mindexvec

template<Config Conf = DefaultConfig>
using mindexvec = typename Conf::mindexvec

Definition at line 81 of file config.hpp.

◆ cmindexvec

template<Config Conf = DefaultConfig>
using cmindexvec = typename Conf::cmindexvec

Definition at line 82 of file config.hpp.

◆ tag_invoke_result

template<typename Tag , typename... Args>
using tag_invoke_result = std::invoke_result<decltype(::alpaqa::alpaqa_tag_invoke), Tag, Args...>

Definition at line 66 of file tag-invoke.hpp.

◆ tag_invoke_result_t

template<typename Tag , typename... Args>
using tag_invoke_result_t = std::invoke_result_t<decltype(::alpaqa::alpaqa_tag_invoke), Tag, Args...>

Definition at line 70 of file tag-invoke.hpp.

◆ tag_t

template<auto & Tag>
using tag_t = std::decay_t<decltype(Tag)>

Definition at line 74 of file tag-invoke.hpp.

◆ function_dict_t

Definition at line 601 of file dl-problem.h.

◆ problem_register_t

Definition at line 602 of file dl-problem.h.

◆ control_problem_register_t

Definition at line 603 of file dl-problem.h.

◆ problem_functions_t

Definition at line 604 of file dl-problem.h.

◆ control_problem_functions_t

Definition at line 605 of file dl-problem.h.

Enumeration Type Documentation

◆ LBFGSStepSize

Which method to use to select the L-BFGS step size.

Enumerator
BasedOnExternalStepSize 

Initial inverse Hessian approximation is set to \( H_0 = \gamma I \), where \( \gamma \) is the forward-backward splitting step size.

BasedOnCurvature 

Initial inverse Hessian approximation is set to \( H_0 = \frac{s^\top y}{y^\top y} I \).

BasedOnGradientStepSize 

Definition at line 26 of file lbfgs.hpp.

◆ PANOCStopCrit

Enumerator
ApproxKKT 

Find an ε-approximate KKT point in the ∞-norm:

\[ \varepsilon = \left\| \gamma_k^{-1} (x^k - \hat x^k) + \nabla \psi(\hat x^k) - \nabla \psi(x^k) \right\|_\infty \]

ApproxKKT2 

Find an ε-approximate KKT point in the 2-norm:

\[ \varepsilon = \left\| \gamma_k^{-1} (x^k - \hat x^k) + \nabla \psi(\hat x^k) - \nabla \psi(x^k) \right\|_2 \]

ProjGradNorm 

∞-norm of the projected gradient with step size γ:

\[ \varepsilon = \left\| x^k - \Pi_C\left(x^k - \gamma_k \nabla \psi(x^k)\right) \right\|_\infty \]

ProjGradNorm2 

2-norm of the projected gradient with step size γ:

\[ \varepsilon = \left\| x^k - \Pi_C\left(x^k - \gamma_k \nabla \psi(x^k)\right) \right\|_2 \]

This is the same criterion as used by OpEn.

ProjGradUnitNorm 

∞-norm of the projected gradient with unit step size:

\[ \varepsilon = \left\| x^k - \Pi_C\left(x^k - \nabla \psi(x^k)\right) \right\|_\infty \]

ProjGradUnitNorm2 

2-norm of the projected gradient with unit step size:

\[ \varepsilon = \left\| x^k - \Pi_C\left(x^k - \nabla \psi(x^k)\right) \right\|_2 \]

FPRNorm 

∞-norm of fixed point residual:

\[ \varepsilon = \gamma_k^{-1} \left\| x^k - \Pi_C\left(x^k - \gamma_k \nabla \psi(x^k)\right) \right\|_\infty \]

FPRNorm2 

2-norm of fixed point residual:

\[ \varepsilon = \gamma_k^{-1} \left\| x^k - \Pi_C\left(x^k - \gamma_k \nabla \psi(x^k)\right) \right\|_2 \]

Ipopt 

The stopping criterion used by Ipopt, see https://link.springer.com/article/10.1007/s10107-004-0559-y equation (5).

Given a candidate iterate \( \hat x^k \) and the corresponding candidate Lagrange multipliers \( \hat y^k \) for the general constraints \( g(x)\in D \), the multipliers \( w \) for the box constraints \( x\in C \) (that are otherwise not computed explicitly) are given by

\[ w^k = v^k - \Pi_C(v^k), \]

where

\[ \begin{aligned} v^k &\triangleq \hat x^k - \nabla f(\hat x^k) - \nabla g(\hat x^k)\, \hat y^k \\ &= \hat x^k - \nabla \psi(\hat x^k) \end{aligned} \]

The quantity that is compared to the (scaled) tolerance is then given by

\[ \begin{aligned} \varepsilon' &= \left\| \nabla f(\hat x^k) + \nabla g(\hat x^k)\, \hat y^k + w^k \right\|_\infty \\ &= \left\| \hat x^k - \Pi_C\left(v^k\right) \right\|_\infty \end{aligned} \]

Finally, the quantity is scaled by the factor

\[ s_d \triangleq \max\left\{ s_\text{max},\;\frac{\|\hat y^k\|_1 + \|w^k\|_1}{2m + 2n} \right\} / s_\text{max}, \]

i.e. \( \varepsilon = \varepsilon' / s_d \).

LBFGSBpp 

The stopping criterion used by LBFGS++, see https://lbfgspp.statr.me/doc/classLBFGSpp_1_1LBFGSBParam.html#afb20e8fd6c6808c1f736218841ba6947.

\[ \varepsilon = \frac{\left\| x^k - \Pi_C\left(x^k - \nabla \psi(x^k)\right) \right\|_\infty} {\max\left\{1, \|x\|_2 \right\}} \]

Definition at line 8 of file panoc-stop-crit.hpp.

◆ SolverStatus

Exit status of a numerical solver such as ALM or PANOC.

Enumerator
Busy 

In progress.

Converged 

Converged and reached given tolerance.

MaxTime 

Maximum allowed execution time exceeded.

MaxIter 

Maximum number of iterations exceeded.

NotFinite 

Intermediate results were infinite or not-a-number.

NoProgress 

No progress was made in the last iteration.

Interrupted 

Solver was interrupted by the user.

Exception 

An unexpected exception was thrown.

Definition at line 11 of file solverstatus.hpp.

Function Documentation

◆ minimize_update_anderson()

template<Config Conf = DefaultConfig>
void minimize_update_anderson ( LimitedMemoryQR< Conf > &  qr,
rmat< Conf ,
crvec< Conf rₖ,
crvec< Conf rₗₐₛₜ,
crvec< Conf gₖ,
real_t< Conf min_div_fac,
rvec< Conf γ_LS,
rvec< Conf xₖ_aa 
)
inline

Solve one step of Anderson acceleration to find a fixed point of a function g(x):

\( g(x^\star) - x^\star = 0 \)

Updates the QR factorization of \( \mathcal{R}_k = QR \), solves the least squares problem to find \( \gamma_\text{LS} \), computes the next iterate \( x_{k+1} \), and stores the current function value \( g_k \) in the matrix \( G \), which is used as a circular buffer.

\[ \begin{aligned} \def\gammaLS{\gamma_\text{LS}} m_k &= \min \{k, m\} \\ g_i &= g(x_i) \\ r_i &= r(x_i) g_i - x_i \\ \Delta r_i &= r_i - r_{i-1} \\ \mathcal{R}_k &= \begin{pmatrix} \Delta r_{k-m_k+1} & \dots & \Delta r_k \end{pmatrix} \in \R^{n\times m_k} \\ \gammaLS &= \argmin_{\gamma \in \R^{m_k}}\; \norm{\mathcal{R}_k \gamma - r_k}_2 \\ \alpha_i &= \begin{cases} \gammaLS[0] & i = 0 \\ \gammaLS[i] - \gammaLS[i-1] & 0 \lt i \lt m_k \\ 1 - \gammaLS[m_k - 1] & i = m_k \end{cases} \\ \tilde G_k &= \begin{pmatrix} g_{k - m_k} & \dots & g_{k-1} \end{pmatrix} \\ G_k &= \begin{pmatrix} g_{k - m_k} & \dots & g_{k} \end{pmatrix} \\ &= \begin{pmatrix} \tilde G_k & g_{k} \end{pmatrix} \\ x_{k+1} &= \sum_{i=0}^{m_k} \alpha_i\,g_{k - m_k + i} \\ &= G_k \alpha \\ \end{aligned} \]

Parameters
[in,out]qrQR factorization of \( \mathcal{R}_k \)
[in,out]Matrix of previous function values \( \tilde G_k \) (stored as ring buffer with the same indices as qr)
[in]rₖCurrent residual \( r_k \)
[in]rₗₐₛₜPrevious residual \( r_{k-1} \)
[in]gₖCurrent function value \( g_k \)
[in]min_div_facMinimum divisor when solving close to singular systems, scaled by the maximum eigenvalue of R
[out]γ_LSSolution to the least squares system
[out]xₖ_aaNext Anderson iterate

Definition at line 39 of file anderson-helpers.hpp.

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◆ float_to_str_vw_snprintf()

std::string_view float_to_str_vw_snprintf ( auto &&  print,
auto buf,
std::floating_point auto  value,
int  precision,
const char fmt 
)
inline

Definition at line 14 of file print.tpp.

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◆ float_to_str_vw() [1/3]

std::string_view float_to_str_vw ( auto buf,
double  value,
int  precision = std::numeric_limits<double>::max_digits10 
)
inline

Definition at line 39 of file print.tpp.

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◆ float_to_str_vw() [2/3]

std::string_view float_to_str_vw ( auto buf,
float  value,
int  precision = std::numeric_limits<float>::max_digits10 
)
inline

Definition at line 45 of file print.tpp.

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◆ float_to_str_vw() [3/3]

std::string_view float_to_str_vw ( auto buf,
long double  value,
int  precision = std::numeric_limits<long double>::max_digits10 
)
inline

Definition at line 49 of file print.tpp.

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◆ float_to_str()

template<std::floating_point F>
std::string float_to_str ( F  value,
int  precision 
)
Examples
C++/Advanced/lasso-fbs.cpp, and C++/CustomControlCppProblem/main.cpp.

Definition at line 67 of file print.tpp.

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◆ print_elem() [1/3]

template<std::floating_point F>
void print_elem ( auto buf,
F  value,
std::ostream &  os 
)

Definition at line 73 of file print.tpp.

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◆ print_elem() [2/3]

template<std::integral I>
void print_elem ( auto ,
I  value,
std::ostream &  os 
)

Definition at line 78 of file print.tpp.

◆ print_elem() [3/3]

template<std::floating_point F>
void print_elem ( auto buf,
std::complex< F value,
std::ostream &  os 
)

Definition at line 83 of file print.tpp.

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◆ const_or_mut_rvec()

template<Config Conf, VectorRefLike< Conf > V>
constexpr auto const_or_mut_rvec ( V &&  v)
constexpr

Definition at line 15 of file ocp-vars.hpp.

◆ enum_name()

constexpr const char * enum_name ( PANOCStopCrit  s)
inlineconstexpr

Definition at line 105 of file panoc-stop-crit.hpp.

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◆ operator<<() [1/4]

std::ostream & operator<< ( std::ostream &  os,
PANOCStopCrit  s 
)

Definition at line 7 of file panoc-stop-crit.cpp.

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◆ operator+=() [1/10]

template<Config Conf>
InnerStatsAccumulator< PANOCOCPStats< Conf > > & operator+= ( InnerStatsAccumulator< PANOCOCPStats< Conf > > &  acc,
const PANOCOCPStats< Conf > &  s 
)

Definition at line 271 of file panoc-ocp.hpp.

◆ operator+=() [2/10]

template<Config Conf>
InnerStatsAccumulator< PANOCStats< Conf > > & operator+= ( InnerStatsAccumulator< PANOCStats< Conf > > &  acc,
const PANOCStats< Conf > &  s 
)

Definition at line 251 of file panoc.hpp.

◆ operator+=() [3/10]

template<Config Conf>
InnerStatsAccumulator< PANTRStats< Conf > > & operator+= ( InnerStatsAccumulator< PANTRStats< Conf > > &  acc,
const PANTRStats< Conf > &  s 
)

Definition at line 252 of file pantr.hpp.

◆ operator+=() [4/10]

template<Config Conf>
InnerStatsAccumulator< ZeroFPRStats< Conf > > & operator+= ( InnerStatsAccumulator< ZeroFPRStats< Conf > > &  acc,
const ZeroFPRStats< Conf > &  s 
)

Definition at line 249 of file zerofpr.hpp.

◆ compute_kkt_error()

template<Config Conf>
KKTError< Conf > compute_kkt_error ( const TypeErasedProblem< Conf > &  problem,
crvec< Conf x,
crvec< Conf y 
)

Definition at line 17 of file kkt-error.hpp.

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◆ operator<<() [2/4]

std::ostream & operator<< ( std::ostream &  os,
const OCPEvalCounter c 
)

Definition at line 32 of file ocproblem-counters.cpp.

◆ operator+=() [5/10]

Definition at line 62 of file ocproblem-counters.hpp.

◆ operator+=() [6/10]

Definition at line 88 of file ocproblem-counters.hpp.

◆ operator+() [1/2]

Definition at line 114 of file ocproblem-counters.hpp.

◆ check_finiteness() [1/2]

void check_finiteness ( const auto v,
std::string_view  msg 
)
inline

If the given vector v is not finite, break or throw an exception with the given message msg.

Definition at line 508 of file ocproblem.hpp.

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◆ check_finiteness() [2/2]

void check_finiteness ( const std::floating_point auto v,
std::string_view  msg 
)
inline

Definition at line 516 of file ocproblem.hpp.

◆ ocproblem_with_counters()

template<class Problem >
auto ocproblem_with_counters ( Problem &&  p)

Definition at line 648 of file ocproblem.hpp.

◆ ocproblem_with_counters_ref()

template<class Problem >
auto ocproblem_with_counters_ref ( Problem &  p)

Definition at line 655 of file ocproblem.hpp.

◆ operator<<() [3/4]

std::ostream & operator<< ( std::ostream &  os,
const EvalCounter c 
)

Definition at line 32 of file problem-counters.cpp.

◆ operator+=() [7/10]

Definition at line 62 of file problem-counters.hpp.

◆ operator+=() [8/10]

EvalCounter & operator+= ( EvalCounter a,
const EvalCounter b 
)
inline

Definition at line 88 of file problem-counters.hpp.

◆ operator+() [2/2]

EvalCounter operator+ ( EvalCounter  a,
const EvalCounter b 
)
inline

Definition at line 114 of file problem-counters.hpp.

◆ print_csv()

template<class Derived , class... Args>
std::ostream & print_csv ( std::ostream &  os,
const Eigen::DenseBase< Derived > &  M,
Args &&...  args 
)

Definition at line 67 of file print.hpp.

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◆ print_matlab()

template<class Derived , class... Args>
std::ostream & print_matlab ( std::ostream &  os,
const Eigen::DenseBase< Derived > &  M,
Args &&...  args 
)

Definition at line 68 of file print.hpp.

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◆ print_python()

template<class Derived , class... Args>
std::ostream & print_python ( std::ostream &  os,
const Eigen::DenseBase< Derived > &  M,
Args &&...  args 
)

◆ attach_cancellation()

template<class Solver >
auto attach_cancellation ( Solver solver)

Attach SIGINT and SIGTERM handlers to stop the given solver.

Parameters
solverThe solver that should be stopped by the handler.
Returns
A RAII object that detaches the handler when destroyed.

Definition at line 21 of file cancel.hpp.

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◆ operator<<() [4/4]

std::ostream & operator<< ( std::ostream &  os,
SolverStatus  s 
)

Definition at line 7 of file solverstatus.cpp.

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◆ convert_csc()

template<Config Conf>
Sparsity< Conf > convert_csc ( const auto sp,
sparsity::Symmetry  symmetry 
)

Definition at line 340 of file CasADiProblem.tpp.

◆ register_function() [1/3]

template<class Func >
void register_function ( function_dict_t *&  extra_functions,
std::string  name,
Func &&  func 
)

Make the given function available to alpaqa.

See also
alpaqa::dl::DLProblem::call_extra_func
alpaqa::dl::DLControlProblem::call_extra_func

Definition at line 611 of file dl-problem.h.

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◆ register_function() [2/3]

template<class Func >
void register_function ( problem_register_t result,
std::string  name,
Func &&  func 
)

Definition at line 620 of file dl-problem.h.

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◆ register_function() [3/3]

template<class Func >
void register_function ( control_problem_register_t result,
std::string  name,
Func &&  func 
)

Definition at line 627 of file dl-problem.h.

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◆ register_member_function()

template<class Result , class T , class Ret , class... Args>
void register_member_function ( Result result,
std::string  name,
Ret(T::*)(Args...)  member 
)
Examples
problems/sparse-logistic-regression.cpp.

Definition at line 634 of file dl-problem.h.

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◆ member_caller()

template<auto Member>
static auto member_caller ( )
static

Wrap the given member function or variable into a (possibly generic) lambda function that accepts the instance as a type-erased void pointer.

The signature of the resulting function depends on the signature of the member function:

If the given member is a variable:

  • Type Class::memberType &(void *self)
  • Type Class::memberconst Type &(const void *self)
Examples
problems/sparse-logistic-regression.cpp.

Definition at line 704 of file dl-problem.h.

◆ unregister_functions()

void unregister_functions ( function_dict_t *&  extra_functions)
inline

Cleans up the extra functions registered by register_function.

Note
This does not need to be called for the functions returned by the registration function, those functions will be cleaned up by alpaqa.
The alpaqa_problem_register_t and alpaqa_control_problem_register_t structs are part of the C API and do not automatically clean up their resources when destroyed, you have to do it manually by calling this function.

Definition at line 715 of file dl-problem.h.

◆ operator+=() [9/10]

Definition at line 104 of file lbfgsb-adapter.hpp.

◆ operator+=() [10/10]

Definition at line 102 of file lbfgsb-adapter.hpp.

◆ build_qpalm_problem()

OwningQPALMData build_qpalm_problem ( const TypeErasedProblem< EigenConfigd > &  problem)

Definition at line 125 of file qpalm-adapter.cpp.

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Variable Documentation

◆ is_config_v

template<class T >
constexpr bool is_config_v = is_config<T>::value
inlineconstexpr

Definition at line 16 of file config.hpp.

◆ inf

template<Config Conf>
constexpr const auto inf = std::numeric_limits<real_t<Conf>>::infinity()
constexpr

◆ NaN

template<Config Conf>
constexpr const auto NaN = std::numeric_limits<real_t<Conf>>::quiet_NaN()
constexpr

Definition at line 87 of file config.hpp.

◆ null_vec

template<Config Conf>
const rvec<Conf> null_vec = mvec<Conf>{nullptr, 0}
inline

Global empty vector for convenience.

Definition at line 152 of file config.hpp.

◆ null_indexvec

template<Config Conf>
const rindexvec<Conf> null_indexvec = mindexvec<Conf>{nullptr, 0}
inline

Global empty index vector for convenience.

Definition at line 155 of file config.hpp.

◆ is_complex_float_v

template<class T >
constexpr bool is_complex_float_v = is_complex_float<T>::value
inlineconstexpr

Definition at line 19 of file float.hpp.

◆ is_tag_invocable_v

template<typename Tag , typename... Args>
constexpr bool is_tag_invocable_v = tag_invocable<Tag, Args...>
inlineconstexpr

Definition at line 59 of file tag-invoke.hpp.

◆ is_nothrow_tag_invocable_v

template<typename Tag , typename... Args>
constexpr bool is_nothrow_tag_invocable_v
inlineconstexpr
Initial value:

Definition at line 62 of file tag-invoke.hpp.