/usr/include/kinsol/kinsol_impl.h is in libsundials-dev 2.7.0+dfsg-2build1.
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* -----------------------------------------------------------------
* $Revision: 4924 $
* $Date: 2016-09-19 14:36:05 -0700 (Mon, 19 Sep 2016) $
* -----------------------------------------------------------------
* Programmer(s): Allan Taylor, Alan Hindmarsh, Radu Serban, and
* Aaron Collier @ LLNL
* -----------------------------------------------------------------
* LLNS Copyright Start
* Copyright (c) 2014, Lawrence Livermore National Security
* This work was performed under the auspices of the U.S. Department
* of Energy by Lawrence Livermore National Laboratory in part under
* Contract W-7405-Eng-48 and in part under Contract DE-AC52-07NA27344.
* Produced at the Lawrence Livermore National Laboratory.
* All rights reserved.
* For details, see the LICENSE file.
* LLNS Copyright End
* -----------------------------------------------------------------
* KINSOL solver module header file (private version)
* -----------------------------------------------------------------
*/
#ifndef _KINSOL_IMPL_H
#define _KINSOL_IMPL_H
#include <stdarg.h>
#include <kinsol/kinsol.h>
#ifdef __cplusplus /* wrapper to enable C++ usage */
extern "C" {
#endif
/*
* =================================================================
* M A I N S O L V E R M E M O R Y B L O C K
* =================================================================
*/
/* KINSOL default constants */
#define PRINTFL_DEFAULT 0
#define MXITER_DEFAULT 200
#define MXNBCF_DEFAULT 10
#define MSBSET_DEFAULT 10
#define MSBSET_SUB_DEFAULT 5
#define OMEGA_MIN RCONST(0.00001)
#define OMEGA_MAX RCONST(0.9)
/*
* -----------------------------------------------------------------
* Types : struct KINMemRec and struct *KINMem
* -----------------------------------------------------------------
* A variable declaration of type struct *KINMem denotes a
* pointer to a data structure of type struct KINMemRec. The
* KINMemRec structure contains numerous fields that must be
* accessible by KINSOL solver module routines.
* -----------------------------------------------------------------
*/
typedef struct KINMemRec {
realtype kin_uround; /* machine epsilon (or unit roundoff error)
(defined in sundials_types.h) */
/* problem specification data */
KINSysFn kin_func; /* nonlinear system function implementation */
void *kin_user_data; /* work space available to func routine */
realtype kin_fnormtol; /* stopping tolerance on L2-norm of function
value */
realtype kin_scsteptol; /* scaled step length tolerance */
int kin_globalstrategy; /* choices are KIN_NONE, KIN_LINESEARCH
KIN_PICARD and KIN_FP */
int kin_printfl; /* level of verbosity of output */
long int kin_mxiter; /* maximum number of nonlinear iterations */
long int kin_msbset; /* maximum number of nonlinear iterations that
may be performed between calls to the
linear solver setup routine (lsetup) */
long int kin_msbset_sub; /* subinterval length for residual monitoring */
long int kin_mxnbcf; /* maximum number of beta condition failures */
int kin_etaflag; /* choices are KIN_ETACONSTANT, KIN_ETACHOICE1
and KIN_ETACHOICE2 */
booleantype kin_noMinEps; /* flag controlling whether or not the value
of eps is bounded below */
booleantype kin_setupNonNull; /* flag indicating if linear solver setup
routine is non-null and if setup is used */
booleantype kin_constraintsSet; /* flag indicating if constraints are being
used */
booleantype kin_jacCurrent; /* flag indicating if the Jacobian info.
used by the linear solver is current */
booleantype kin_callForcingTerm; /* flag set if using either KIN_ETACHOICE1
or KIN_ETACHOICE2 */
booleantype kin_noResMon; /* flag indicating if the nonlinear
residual monitoring scheme should be
used */
booleantype kin_retry_nni; /* flag indicating if nonlinear iteration
should be retried (set by residual
monitoring algorithm) */
booleantype kin_update_fnorm_sub; /* flag indicating if the fnorm associated
with the subinterval needs to be
updated (set by residual monitoring
algorithm) */
realtype kin_mxnewtstep; /* maximum allowable scaled step length */
realtype kin_mxnstepin; /* input (or preset) value for mxnewtstep */
realtype kin_sqrt_relfunc; /* relative error bound for func(u) */
realtype kin_stepl; /* scaled length of current step */
realtype kin_stepmul; /* step scaling factor */
realtype kin_eps; /* current value of eps */
realtype kin_eta; /* current value of eta */
realtype kin_eta_gamma; /* gamma value used in eta calculation
(choice #2) */
realtype kin_eta_alpha; /* alpha value used in eta calculation
(choice #2) */
booleantype kin_noInitSetup; /* flag controlling whether or not the KINSol
routine makes an initial call to the
linear solver setup routine (lsetup) */
realtype kin_sthrsh; /* threshold value for calling the linear
solver setup routine */
/* counters */
long int kin_nni; /* number of nonlinear iterations */
long int kin_nfe; /* number of calls made to func routine */
long int kin_nnilset; /* value of nni counter when the linear solver
setup was last called */
long int kin_nnilset_sub; /* value of nni counter when the linear solver
setup was last called (subinterval) */
long int kin_nbcf; /* number of times the beta-condition could not
be met in KINLineSearch */
long int kin_nbktrk; /* number of backtracks performed by
KINLineSearch */
long int kin_ncscmx; /* number of consecutive steps of size
mxnewtstep taken */
/* vectors */
N_Vector kin_uu; /* solution vector/current iterate (initially
contains initial guess, but holds approximate
solution upon completion if no errors occurred) */
N_Vector kin_unew; /* next iterate (unew = uu+pp) */
N_Vector kin_fval; /* vector containing result of nonlinear system
function evaluated at a given iterate
(fval = func(uu)) */
N_Vector kin_gval; /* vector containing result of the fixed point
function evaluated at a given iterate;
used in KIN_PICARD strategy only.
(gval = uu - L^{-1}fval(uu)) */
N_Vector kin_uscale; /* iterate scaling vector */
N_Vector kin_fscale; /* fval scaling vector */
N_Vector kin_pp; /* incremental change vector (pp = unew-uu) */
N_Vector kin_constraints; /* constraints vector */
N_Vector kin_vtemp1; /* scratch vector #1 */
N_Vector kin_vtemp2; /* scratch vector #2 */
/* space requirements for AA, Broyden and NLEN */
N_Vector kin_fold_aa; /* vector needed for AA, Broyden, and NLEN */
N_Vector kin_gold_aa; /* vector needed for AA, Broyden, and NLEN */
N_Vector *kin_df_aa; /* vector array needed for AA, Broyden, and NLEN */
N_Vector *kin_dg_aa; /* vector array needed for AA, Broyden and NLEN */
N_Vector *kin_q_aa; /* vector array needed for AA */
realtype *kin_gamma_aa; /* array of size maa used in AA */
realtype *kin_R_aa; /* array of size maa*maa used in AA */
int *kin_ipt_map; /* array of size maa used in AA */
long int kin_m_aa; /* parameter for AA, Broyden or NLEN */
booleantype kin_aamem_aa; /* sets additional memory needed for Anderson Acc */
booleantype kin_setstop_aa; /* determines whether user will set stopping criterion */
/* space requirements for vector storage */
long int kin_lrw1; /* number of realtype-sized memory blocks needed
for a single N_Vector */
long int kin_liw1; /* number of int-sized memory blocks needed for
a single N_Vecotr */
long int kin_lrw; /* total number of realtype-sized memory blocks
needed for all KINSOL work vectors */
long int kin_liw; /* total number of int-sized memory blocks needed
for all KINSOL work vectors */
/* linear solver data */
/* function prototypes (pointers) */
int (*kin_linit)(struct KINMemRec *kin_mem);
int (*kin_lsetup)(struct KINMemRec *kin_mem);
int (*kin_lsolve)(struct KINMemRec *kin_mem, N_Vector xx, N_Vector bb,
realtype *sJpnorm, realtype *sFdotJp);
int (*kin_lfree)(struct KINMemRec *kin_mem);
booleantype kin_inexact_ls; /* flag set by the linear solver module
(in linit) indicating whether this is an
iterative linear solver (TRUE), or a direct
linear solver (FALSE) */
void *kin_lmem; /* pointer to linear solver memory block */
realtype kin_fnorm; /* value of L2-norm of fscale*fval */
realtype kin_f1norm; /* f1norm = 0.5*(fnorm)^2 */
realtype kin_sFdotJp; /* value of scaled F(u) vector (fscale*fval)
dotted with scaled J(u)*pp vector (set by lsolve) */
realtype kin_sJpnorm; /* value of L2-norm of fscale*(J(u)*pp)
(set by lsolve) */
realtype kin_fnorm_sub; /* value of L2-norm of fscale*fval (subinterval) */
booleantype kin_eval_omega; /* flag indicating that omega must be evaluated. */
realtype kin_omega; /* constant value for real scalar used in test to
determine if reduction of norm of nonlinear
residual is sufficient. Unless a valid constant
value is specified by the user, omega is estimated
from omega_min and omega_max at each iteration. */
realtype kin_omega_min; /* lower bound on omega */
realtype kin_omega_max; /* upper bound on omega */
/*
* -----------------------------------------------------------------
* Note: The KINLineSearch subroutine scales the values of the
* variables sFdotJp and sJpnorm by a factor rl (lambda) that is
* chosen by the line search algorithm such that the sclaed Newton
* step satisfies the following conditions:
*
* F(u_k+1) <= F(u_k) + alpha*(F(u_k)^T * J(u_k))*p*rl
*
* F(u_k+1) >= F(u_k) + beta*(F(u_k)^T * J(u_k))*p*rl
*
* where alpha = 1.0e-4, beta = 0.9, u_k+1 = u_k + rl*p,
* 0 < rl <= 1, J denotes the system Jacobian, and F represents
* the nonliner system function.
* -----------------------------------------------------------------
*/
booleantype kin_MallocDone; /* flag indicating if KINMalloc has been
called yet */
/* message files */
/*-------------------------------------------
Error handler function and error ouput file
-------------------------------------------*/
KINErrHandlerFn kin_ehfun; /* Error messages are handled by ehfun */
void *kin_eh_data; /* dats pointer passed to ehfun */
FILE *kin_errfp; /* KINSOL error messages are sent to errfp */
KINInfoHandlerFn kin_ihfun; /* Info messages are handled by ihfun */
void *kin_ih_data; /* dats pointer passed to ihfun */
FILE *kin_infofp; /* where KINSol info messages are sent */
} *KINMem;
/*
* =================================================================
* I N T E R F A C E T O L I N E A R S O L V E R
* =================================================================
*/
/*
* -----------------------------------------------------------------
* Function : int (*kin_linit)(KINMem kin_mem)
* -----------------------------------------------------------------
* kin_linit initializes solver-specific data structures (including
* variables used as counters or for storing statistical information),
* but system memory allocation should be done by the subroutine
* that actually initializes the environment for liner solver
* package. If the linear system is to be preconditioned, then the
* variable setupNonNull (type booleantype) should be set to TRUE
* (predefined constant) and the kin_lsetup routine should be
* appropriately defined.
*
* kinmem pointer to an internal memory block allocated during
* prior calls to KINCreate and KINMalloc
*
* If the necessary variables have been successfully initialized,
* then the kin_linit function should return 0 (zero). Otherwise,
* the subroutine should indicate a failure has occurred by
* returning a non-zero integer value.
* -----------------------------------------------------------------
*/
/*
* -----------------------------------------------------------------
* Function : int (*kin_lsetup)(KINMem kin_mem)
* -----------------------------------------------------------------
* kin_lsetup interfaces with the user-supplied pset subroutine (the
* preconditioner setup routine), and updates relevant variable
* values (see KINSpgmrSetup/KINSpbcgSetup). Simply stated, the
* kin_lsetup routine prepares the linear solver for a subsequent
* call to the user-supplied kin_lsolve function.
*
* kinmem pointer to an internal memory block allocated during
* prior calls to KINCreate and KINMalloc
*
* If successful, the kin_lsetup routine should return 0 (zero).
* Otherwise it should return a non-zero value.
* -----------------------------------------------------------------
*/
/*
* -----------------------------------------------------------------
* Function : int (*kin_lsolve)(KINMem kin_mem, N_Vector xx,
* N_Vector bb, realtype *sJpnorm, realtype *sFdotJp)
* -----------------------------------------------------------------
* kin_lsolve interfaces with the subroutine implementing the
* numerical method to be used to solve the linear system J*xx = bb,
* and must increment the relevant counter variable values in
* addition to computing certain values used by the global strategy
* and forcing term routines (see KINInexactNewton, KINLineSearch,
* KINForcingTerm, and KINSpgmrSolve/KINSpbcgSolve).
*
* kinmem pointer to an internal memory block allocated during
* prior calls to KINCreate and KINMalloc
*
* xx vector (type N_Vector) set to initial guess by kin_lsolve
* routine prior to calling the linear solver, but which upon
* return contains an approximate solution of the linear
* system J*xx = bb, where J denotes the system Jacobian
*
* bb vector (type N_Vector) set to -func(u) (negative of the
* value of the system function evaluated at the current
* iterate) by KINLinSolDrv before kin_lsolve is called
*
* sJpnorm holds the value of the L2-norm (Euclidean norm) of
* fscale*(J(u)*pp) upon return
*
* sFdotJp holds the value of the scaled F(u) (fscale*F) dotted
* with the scaled J(u)*pp vector upon return
*
* If successful, the kin_lsolve routine should return 0 (zero).
* Otherwise it should return a positive value if a re-evaluation
* of the lsetup function could recover, or a negative value if
* no such recovery is possible.
* -----------------------------------------------------------------
*/
/*
* -----------------------------------------------------------------
* Function : int (*kin_lfree)(KINMem kin_mem)
* -----------------------------------------------------------------
* kin_lfree is called by KINFree and should free (deallocate) all
* system memory resources allocated for the linear solver module
* (see KINSpgmrFree/KINSpbcgFree). It should return 0 upon
* success, nonzero on failure.
*
* kinmem pointer to an internal memory block allocated during
* prior calls to KINCreate and KINMalloc
* -----------------------------------------------------------------
*/
/*
* =================================================================
* K I N S O L I N T E R N A L F U N C T I O N S
* =================================================================
*/
/* High level error handler */
void KINProcessError(KINMem kin_mem,
int error_code, const char *module, const char *fname,
const char *msgfmt, ...);
/* Prototype of internal errHandler function */
void KINErrHandler(int error_code, const char *module, const char *function,
char *msg, void *user_data);
/* High level info handler */
void KINPrintInfo(KINMem kin_mem,
int info_code, const char *module, const char *fname,
const char *msgfmt, ...);
/* Prototype of internal infoHandler function */
void KINInfoHandler(const char *module, const char *function,
char *msg, void *user_data);
/*
* =================================================================
* K I N S O L E R R O R M E S S A G E S
* =================================================================
*/
#define MSG_MEM_FAIL "A memory request failed."
#define MSG_NO_MEM "kinsol_mem = NULL illegal."
#define MSG_BAD_NVECTOR "A required vector operation is not implemented."
#define MSG_FUNC_NULL "func = NULL illegal."
#define MSG_NO_MALLOC "Attempt to call before KINMalloc illegal."
#define MSG_BAD_PRINTFL "Illegal value for printfl."
#define MSG_BAD_MXITER "Illegal value for mxiter."
#define MSG_BAD_MSBSET "Illegal msbset < 0."
#define MSG_BAD_MSBSETSUB "Illegal msbsetsub < 0."
#define MSG_BAD_ETACHOICE "Illegal value for etachoice."
#define MSG_BAD_ETACONST "eta out of range."
#define MSG_BAD_GAMMA "gamma out of range."
#define MSG_BAD_ALPHA "alpha out of range."
#define MSG_BAD_MXNEWTSTEP "Illegal mxnewtstep < 0."
#define MSG_BAD_RELFUNC "relfunc < 0 illegal."
#define MSG_BAD_FNORMTOL "fnormtol < 0 illegal."
#define MSG_BAD_SCSTEPTOL "scsteptol < 0 illegal."
#define MSG_BAD_MXNBCF "mxbcf < 0 illegal."
#define MSG_BAD_CONSTRAINTS "Illegal values in constraints vector."
#define MSG_BAD_OMEGA "scalars < 0 illegal."
#define MSG_BAD_MAA "maa < 0 illegal."
#define MSG_ZERO_MAA "maa = 0 illegal."
#define MSG_LSOLV_NO_MEM "The linear solver memory pointer is NULL."
#define MSG_UU_NULL "uu = NULL illegal."
#define MSG_BAD_GLSTRAT "Illegal value for global strategy."
#define MSG_BAD_USCALE "uscale = NULL illegal."
#define MSG_USCALE_NONPOSITIVE "uscale has nonpositive elements."
#define MSG_BAD_FSCALE "fscale = NULL illegal."
#define MSG_FSCALE_NONPOSITIVE "fscale has nonpositive elements."
#define MSG_CONSTRAINTS_NOTOK "Constraints not allowed with fixed point or Picard iterations"
#define MSG_INITIAL_CNSTRNT "Initial guess does NOT meet constraints."
#define MSG_LINIT_FAIL "The linear solver's init routine failed."
#define MSG_SYSFUNC_FAILED "The system function failed in an unrecoverable manner."
#define MSG_SYSFUNC_FIRST "The system function failed at the first call."
#define MSG_LSETUP_FAILED "The linear solver's setup function failed in an unrecoverable manner."
#define MSG_LSOLVE_FAILED "The linear solver's solve function failed in an unrecoverable manner."
#define MSG_LINSOLV_NO_RECOVERY "The linear solver's solve function failed recoverably, but the Jacobian data is already current."
#define MSG_LINESEARCH_NONCONV "The line search algorithm was unable to find an iterate sufficiently distinct from the current iterate."
#define MSG_LINESEARCH_BCFAIL "The line search algorithm was unable to satisfy the beta-condition for nbcfails iterations."
#define MSG_MAXITER_REACHED "The maximum number of iterations was reached before convergence."
#define MSG_MXNEWT_5X_EXCEEDED "Five consecutive steps have been taken that satisfy a scaled step length test."
#define MSG_SYSFUNC_REPTD "Unable to correct repeated recoverable system function errors."
#define MSG_NOL_FAIL "Unable to find user's Linear Jacobian, which is required for the KIN_PICARD Strategy"
/*
* =================================================================
* K I N S O L I N F O M E S S A G E S
* =================================================================
*/
#define INFO_RETVAL "Return value: %d"
#define INFO_ADJ "no. of lambda adjustments = %ld"
#if defined(SUNDIALS_EXTENDED_PRECISION)
#define INFO_NNI "nni = %4ld nfe = %6ld fnorm = %26.16Lg"
#define INFO_TOL "scsteptol = %12.3Lg fnormtol = %12.3Lg"
#define INFO_FMAX "scaled f norm (for stopping) = %12.3Lg"
#define INFO_PNORM "pnorm = %12.4Le"
#define INFO_PNORM1 "(ivio=1) pnorm = %12.4Le"
#define INFO_FNORM "fnorm(L2) = %20.8Le"
#define INFO_LAM "min_lam = %11.4Le f1norm = %11.4Le pnorm = %11.4Le"
#define INFO_ALPHA "fnorm = %15.8Le f1norm = %15.8Le alpha_cond = %15.8Le lam = %15.8Le"
#define INFO_BETA "f1norm = %15.8Le beta_cond = %15.8Le lam = %15.8Le"
#define INFO_ALPHABETA "f1norm = %15.8Le alpha_cond = %15.8Le beta_cond = %15.8Le lam = %15.8Le"
#elif defined(SUNDIALS_DOUBLE_PRECISION)
#define INFO_NNI "nni = %4ld nfe = %6ld fnorm = %26.16lg"
#define INFO_TOL "scsteptol = %12.3lg fnormtol = %12.3lg"
#define INFO_FMAX "scaled f norm (for stopping) = %12.3lg"
#define INFO_PNORM "pnorm = %12.4le"
#define INFO_PNORM1 "(ivio=1) pnorm = %12.4le"
#define INFO_FNORM "fnorm(L2) = %20.8le"
#define INFO_LAM "min_lam = %11.4le f1norm = %11.4le pnorm = %11.4le"
#define INFO_ALPHA "fnorm = %15.8le f1norm = %15.8le alpha_cond = %15.8le lam = %15.8le"
#define INFO_BETA "f1norm = %15.8le beta_cond = %15.8le lam = %15.8le"
#define INFO_ALPHABETA "f1norm = %15.8le alpha_cond = %15.8le beta_cond = %15.8le lam = %15.8le"
#else
#define INFO_NNI "nni = %4ld nfe = %6ld fnorm = %26.16g"
#define INFO_TOL "scsteptol = %12.3g fnormtol = %12.3g"
#define INFO_FMAX "scaled f norm (for stopping) = %12.3g"
#define INFO_PNORM "pnorm = %12.4e"
#define INFO_PNORM1 "(ivio=1) pnorm = %12.4e"
#define INFO_FNORM "fnorm(L2) = %20.8e"
#define INFO_LAM "min_lam = %11.4e f1norm = %11.4e pnorm = %11.4e"
#define INFO_ALPHA "fnorm = %15.8e f1norm = %15.8e alpha_cond = %15.8e lam = %15.8e"
#define INFO_BETA "f1norm = %15.8e beta_cond = %15.8e lam = %15.8e"
#define INFO_ALPHABETA "f1norm = %15.8e alpha_cond = %15.8e beta_cond = %15.8e lam = %15.8e"
#endif
#ifdef __cplusplus
}
#endif
#endif
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