source: issm/trunk-jpl/src/c/solvers/solver_newton.cpp@ 12515

/*!\file: solver_nonlinear.cpp
 * \brief: core of a non-linear solution, using fixed-point method 
 */ 

#include "../toolkits/toolkits.h"
#include "../objects/objects.h"
#include "../io/io.h"
#include "../EnumDefinitions/EnumDefinitions.h"
#include "../modules/modules.h"
#include "../solutions/solutions.h"
#include "./solvers.h"

void solver_newton(FemModel* femmodel){

        /*intermediary: */
        bool   converged;
        int    num_unstable_constraints;
        int    count;
        IssmDouble kmax;
        Matrix* Kff = NULL;
        Matrix* Kfs    = NULL;
        Matrix* Jff = NULL;
        Vector* ug  = NULL;
        Vector* old_ug = NULL;
        Vector* uf  = NULL;
        Vector* old_uf = NULL;
        Vector* duf = NULL;
        Vector* pf  = NULL;
        Vector* pJf    = NULL;
        Vector* df  = NULL;
        Vector* ys  = NULL;

        /*parameters:*/
        int max_nonlinear_iterations;
        int  configuration_type;

        /*Recover parameters: */
        femmodel->parameters->FindParam(&max_nonlinear_iterations,DiagnosticMaxiterEnum);
        femmodel->parameters->FindParam(&configuration_type,ConfigurationTypeEnum);
        UpdateConstraintsx(femmodel->nodes,femmodel->constraints,femmodel->parameters);

        count=1;
        converged=false;

        /*Start non-linear iteration using input velocity: */
        GetSolutionFromInputsx(&ug,femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters);
        Reducevectorgtofx(&uf,ug,femmodel->nodes,femmodel->parameters);

        //Update once again the solution to make sure that vx and vxold are similar (for next step in transient or steadystate)
        InputUpdateFromConstantx(femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters,converged,ConvergedEnum);
        InputUpdateFromSolutionx(femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters,ug);

        for(;;){

                xdelete(&old_ug);old_ug=ug;
                xdelete(&old_uf);old_uf=uf;

                /*Solver forward model*/
                SystemMatricesx(&Kff,&Kfs,&pf,&df,NULL,femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters);
                CreateNodalConstraintsx(&ys,femmodel->nodes,configuration_type);
                Reduceloadx(pf,Kfs,ys);xdelete(&Kfs);
                Solverx(&uf,Kff,pf,old_uf,df,femmodel->parameters);xdelete(&df);
                Mergesolutionfromftogx(&ug,uf,ys,femmodel->nodes,femmodel->parameters);xdelete(&ys);
                InputUpdateFromSolutionx(femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters,ug);xdelete(&ug);

                /*Check convergence*/
                convergence(&converged,Kff,pf,uf,old_uf,femmodel->parameters); 
                xdelete(&Kff); xdelete(&pf);
                if(converged==true){    
                        bool max_iteration_state=false;
                        int tempStep=1;
                        IssmDouble tempTime=1.0;
                        femmodel->results->AddObject(new BoolExternalResult(femmodel->results->Size()+1, MaxIterationConvergenceFlagEnum, max_iteration_state, tempStep, tempTime));
                        break;
                }
                if(count>=max_nonlinear_iterations){
                        if(true) _pprintLine_("   maximum number of Newton iterations (" << max_nonlinear_iterations << ") exceeded"); 
                        bool max_iteration_state=true;
                        int tempStep=1;
                        IssmDouble tempTime=1.0;
                        femmodel->results->AddObject(new BoolExternalResult(femmodel->results->Size()+1, MaxIterationConvergenceFlagEnum, max_iteration_state, tempStep, tempTime));
                        break;
                }

                /*Prepare next iteration using Newton's method*/
                SystemMatricesx(&Kff,&Kfs,&pf,NULL,&kmax,femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters);
                CreateNodalConstraintsx(&ys,femmodel->nodes,configuration_type);
                Reduceloadx(pf,Kfs,ys);   xdelete(&Kfs);

                pJf=pf->Duplicate(); Kff->MatMult(uf,pJf); xdelete(&Kff);
                pJf->Scale(-1.0); pJf->AXPY(pf,+1.0);     xdelete(&pf);

                CreateJacobianMatrixx(&Jff,femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters,kmax);
                Solverx(&duf,Jff,pJf,NULL,NULL,femmodel->parameters); xdelete(&Jff); xdelete(&pJf);
                uf->AXPY(duf, 1.0); xdelete(&duf);
                Mergesolutionfromftogx(&ug,uf,ys,femmodel->nodes,femmodel->parameters);xdelete(&ys);
                InputUpdateFromSolutionx(femmodel->elements,femmodel->nodes,femmodel->vertices,femmodel->loads,femmodel->materials,femmodel->parameters,ug);

                count++;
        }

        if(VerboseConvergence()) _pprintLine_("\n   total number of iterations: " << count-1);

        /*clean-up*/
        xdelete(&uf);
        xdelete(&ug);
        xdelete(&old_ug);
        xdelete(&old_uf);
}