source: issm/trunk-jpl/src/c/analyses/SealevelriseAnalysis.cpp@ 25754

#include "./SealevelriseAnalysis.h"
#include <math.h>
#include "../toolkits/toolkits.h"
#include "../classes/classes.h"
#include "../classes/Inputs/TransientInput.h"
#include "../shared/shared.h"
#include "../modules/modules.h"

/*Model processing*/
void SealevelriseAnalysis::CreateConstraints(Constraints* constraints,IoModel* iomodel){/*{{{*/
        /*No constraints*/
}/*}}}*/
void SealevelriseAnalysis::CreateLoads(Loads* loads, IoModel* iomodel){/*{{{*/
        /*No loads*/
}/*}}}*/
void SealevelriseAnalysis::CreateNodes(Nodes* nodes,IoModel* iomodel,bool isamr){/*{{{*/
        ::CreateNodes(nodes,iomodel,SealevelriseAnalysisEnum,P1Enum);
}/*}}}*/
int  SealevelriseAnalysis::DofsPerNode(int** doflist,int domaintype,int approximation){/*{{{*/
        return 1;
}/*}}}*/
void SealevelriseAnalysis::UpdateElements(Elements* elements,Inputs* inputs,IoModel* iomodel,int analysis_counter,int analysis_type){/*{{{*/

        int geodetic=0;
        int dslmodel=0;

        /*Update elements: */
        int counter=0;
        for(int i=0;i<iomodel->numberofelements;i++){
                if(iomodel->my_elements[i]){
                        Element* element=(Element*)elements->GetObjectByOffset(counter);
                        element->Update(inputs,i,iomodel,analysis_counter,analysis_type,P1Enum);
                        counter++;
                }
        }

        /*Create inputs: */
        iomodel->FetchDataToInput(inputs,elements,"md.mask.ocean_levelset",MaskOceanLevelsetEnum);
        iomodel->FetchDataToInput(inputs,elements,"md.mask.ice_levelset",MaskIceLevelsetEnum);
        iomodel->FetchData(&geodetic,"md.solidearth.settings.computesealevelchange");
        iomodel->FetchDataToInput(inputs,elements,"md.solidearth.surfaceload.icethicknesschange",SurfaceloadIceThicknessChangeEnum);
        iomodel->FetchDataToInput(inputs,elements,"md.solidearth.sealevel",SealevelEnum,0);
        iomodel->FetchDataToInput(inputs,elements,"md.geometry.bed",BedEnum);
        iomodel->FetchDataToInput(inputs,elements,"md.solidearth.surfaceload.waterheightchange",SurfaceloadWaterHeightChangeEnum);
                
        /*dynamic sea level: */
        iomodel->FetchData(&dslmodel,"md.dsl.model");
        if (dslmodel==1){ /*standard dsl model:{{{*/

                /*deal with global mean steric rate: */
                IssmDouble* str=NULL; 
                IssmDouble* times = NULL;
                int M,N;

                /*fetch str vector:*/
                iomodel->FetchData(&str,&M,&N,"md.dsl.global_average_thermosteric_sea_level_change"); _assert_(M==2);
                
                //recover time vector: 
                times=xNew<IssmDouble>(N);
                for(int t=0;t<N;t++) times[t] = str[N+t];

                /*create transient input: */
                inputs->SetTransientInput(DslGlobalAverageThermostericSeaLevelChangeEnum,times,N);
                TransientInput* transientinput = inputs->GetTransientInput(DslGlobalAverageThermostericSeaLevelChangeEnum);
                
                        
                for(Object* & object : elements->objects){
                        Element* element=xDynamicCast<Element*>(object);

                        for(int t=0;t<N;t++){
                                switch(element->ObjectEnum()){
                                        case TriaEnum:  transientinput->AddTriaTimeInput( t,1,&element->lid,&str[t],P0Enum); break;
                                        case PentaEnum: transientinput->AddPentaTimeInput(t,1,&element->lid,&str[t],P0Enum); break;
                                        default: _error_("Not implemented yet");
                                }
                        }
                }

                /*cleanup:*/
                xDelete<IssmDouble>(times);
                iomodel->DeleteData(str,"md.dsl.global_average_thermosteric_sea_level_change");

                /*deal with dynamic sea level fields: */
                iomodel->FetchDataToInput(inputs,elements,"md.dsl.sea_surface_height_change_above_geoid", DslSeaSurfaceHeightChangeAboveGeoidEnum);
                iomodel->FetchDataToInput(inputs,elements,"md.dsl.sea_water_pressure_change_at_sea_floor", DslSeaWaterPressureChangeAtSeaFloorEnum);
                
        } /*}}}*/
        else if (dslmodel==2){ /*multi-model ensemble dsl model:{{{*/
        
                /*variables:*/
                int nummodels;
                IssmDouble** pstr=NULL; 
                IssmDouble*  str=NULL;
                IssmDouble*  times = NULL;
                int* pM = NULL;
                int* pN = NULL;
                int M,N;

                /*deal with dsl.global_average_thermosteric_sea_level_change {{{*/
                iomodel->FetchData(&pstr,&pM,&pN,&nummodels,"md.dsl.global_average_thermosteric_sea_level_change");

                /*go through the mat array and create a dataset of transient inputs:*/
                for (int i=0;i<nummodels;i++){

                        M=pM[i];
                        N=pN[i];
                        str=pstr[i];

                        //recover time vector: 
                        times=xNew<IssmDouble>(N);
                        for(int t=0;t<N;t++) times[t] = str[(M-1)*N+t];

                        TransientInput* transientinput=inputs->SetDatasetTransientInput(DslGlobalAverageThermostericSeaLevelChangeEnum,i, times,N);
                        
                        for(Object* & object : elements->objects){
                                Element* element=xDynamicCast<Element*>(object);

                                for(int t=0;t<N;t++){
                                        switch(element->ObjectEnum()){
                                                case TriaEnum:  transientinput->AddTriaTimeInput( t,1,&element->lid,&str[t],P0Enum); break;
                                                case PentaEnum: transientinput->AddPentaTimeInput(t,1,&element->lid,&str[t],P0Enum); break;
                                                default: _error_("Not implemented yet");
                                        }
                                }
                        }
                        xDelete<IssmDouble>(times);
                }
                /*Delete data:*/
                for(int i=0;i<nummodels;i++){
                        IssmDouble* str=pstr[i];
                        xDelete<IssmDouble>(str);
                }
                xDelete<IssmDouble*>(pstr);
                xDelete<int>(pM);
                xDelete<int>(pN);
                /*}}}*/
                iomodel->FetchDataToInput(inputs,elements,"md.dsl.sea_surface_height_change_above_geoid",DslSeaSurfaceHeightChangeAboveGeoidEnum);
                iomodel->FetchDataToInput(inputs,elements,"md.dsl.sea_water_pressure_change_at_sea_floor",DslSeaWaterPressureChangeAtSeaFloorEnum);

        } /*}}}*/
        else _error_("Dsl model " << dslmodel << " not implemented yet!");
                
        

        /*Initialize cumdeltalthickness and sealevel rise rate input*/
        InputUpdateFromConstantx(inputs,elements,0.,SealevelriseCumDeltathicknessEnum);
        InputUpdateFromConstantx(inputs,elements,0.,SealevelNEsaRateEnum);
        InputUpdateFromConstantx(inputs,elements,0.,SealevelUEsaRateEnum);
        InputUpdateFromConstantx(inputs,elements,0.,SealevelRSLRateEnum);
        InputUpdateFromConstantx(inputs,elements,0.,SealevelEustaticMaskEnum);
        InputUpdateFromConstantx(inputs,elements,0.,SealevelEustaticOceanMaskEnum);

}/*}}}*/
void SealevelriseAnalysis::UpdateParameters(Parameters* parameters,IoModel* iomodel,int solution_enum,int analysis_enum){/*{{{*/

        int         nl;
        IssmDouble* love_h=NULL;
        IssmDouble* love_k=NULL;
        IssmDouble* love_l=NULL;
        IssmDouble* love_th=NULL;
        IssmDouble* love_tk=NULL;
        IssmDouble* love_tl=NULL;
        int         dslmodel=0;

        IssmDouble* G_rigid = NULL;
        IssmDouble* G_rigid_local = NULL;
        IssmDouble* G_elastic = NULL;
        IssmDouble* G_elastic_local = NULL;
        IssmDouble* U_elastic = NULL;
        IssmDouble* U_elastic_local = NULL;
        IssmDouble* H_elastic = NULL;
        IssmDouble* H_elastic_local = NULL;
        int         M,m,lower_row,upper_row;
        IssmDouble  degacc=.01;
        IssmDouble  planetradius=0;
        IssmDouble  planetarea=0;
        bool            rigid=false;
        bool            elastic=false;
        bool            rotation=false;

        int     numoutputs;
        char**  requestedoutputs = NULL;

        /*transition vectors: */
        IssmDouble **transitions    = NULL;
        int         *transitions_M    = NULL;
        int         *transitions_N    = NULL;
        int          ntransitions;
        IssmDouble*  partitionice=NULL;
        IssmDouble*  partitionhydro=NULL;
        IssmDouble*  bslrice_partition=NULL;
        IssmDouble*  bslrhydro_partition=NULL;
        int          npartice,nparthydro,nel;


        /*some constant parameters: */
        parameters->AddObject(iomodel->CopyConstantObject("md.dsl.model",DslModelEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.runfrequency",SolidearthSettingsRunFrequencyEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.reltol",SolidearthSettingsReltolEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.abstol",SolidearthSettingsAbstolEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.maxiter",SolidearthSettingsMaxiterEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.rigid",SolidearthSettingsRigidEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.horiz",SolidearthSettingsHorizEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.elastic",SolidearthSettingsElasticEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.rotation",SolidearthSettingsRotationEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.rotational.equatorialmoi",RotationalEquatorialMoiEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.rotational.polarmoi",RotationalPolarMoiEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.rotational.angularvelocity",RotationalAngularVelocityEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.ocean_area_scaling",SolidearthSettingsOceanAreaScalingEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.computesealevelchange",SolidearthSettingsComputesealevelchangeEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.planetradius",SolidearthPlanetRadiusEnum));
        parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.settings.glfraction",SolidearthSettingsGlfractionEnum));
        parameters->AddObject(new DoubleParam(CumBslrEnum,0.0));
        parameters->AddObject(new DoubleParam(CumBslrIceEnum,0.0));
        parameters->AddObject(new DoubleParam(CumBslrHydroEnum,0.0));
        parameters->AddObject(new DoubleParam(CumGmtslrEnum,0.0));

        /*compute planet area and plug into parameters:*/
        iomodel->FetchData(&planetradius,"md.solidearth.planetradius");
        planetarea=4*PI*planetradius*planetradius;
        parameters->AddObject(new DoubleParam(SolidearthPlanetAreaEnum,planetarea));

        /*Deal with partition of the barystatic contribution:*/
        iomodel->FetchData(&npartice,"md.solidearth.npartice");
        parameters->AddObject(new IntParam(SolidearthNpartIceEnum,npartice));
        if(npartice){
                iomodel->FetchData(&partitionice,&nel,NULL,"md.solidearth.partitionice");
                parameters->AddObject(new DoubleMatParam(SolidearthPartitionIceEnum,partitionice,nel,1));
                parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.npartice",SolidearthNpartIceEnum));
                bslrice_partition=xNewZeroInit<IssmDouble>(npartice);
                parameters->AddObject(new DoubleMatParam(CumBslrIcePartitionEnum,bslrice_partition,npartice,1));
                xDelete<IssmDouble>(partitionice);
        }
        iomodel->FetchData(&nparthydro,"md.solidearth.nparthydro");
        parameters->AddObject(new IntParam(SolidearthNpartHydroEnum,nparthydro));
        if(nparthydro){
                iomodel->FetchData(&partitionhydro,&nel,NULL,"md.solidearth.partitionhydro");
                parameters->AddObject(new DoubleMatParam(SolidearthPartitionHydroEnum,partitionhydro,nel,1));
                parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.nparthydro",SolidearthNpartHydroEnum));
                bslrhydro_partition=xNewZeroInit<IssmDouble>(nparthydro);
                parameters->AddObject(new DoubleMatParam(CumBslrHydroPartitionEnum,bslrhydro_partition,nparthydro,1));
                xDelete<IssmDouble>(partitionhydro);
        }


        /*Deal with dsl multi-model ensembles: {{{*/
        iomodel->FetchData(&dslmodel,"md.dsl.model");
        parameters->AddObject(iomodel->CopyConstantObject("md.dsl.compute_fingerprints",DslComputeFingerprintsEnum));
        if(dslmodel==2){
                IssmDouble modelid; 
                int nummodels;
                
                /*create double param, not int param, because Dakota will be updating it as 
                 * a double potentially: */
                iomodel->FetchData(&modelid,"md.dsl.modelid");
                parameters->AddObject(new DoubleParam(DslModelidEnum,modelid));
                parameters->AddObject(iomodel->CopyConstantObject("md.dsl.nummodels",DslNummodelsEnum));
                iomodel->FetchData(&nummodels,"md.dsl.nummodels");

                /*quick checks: */
                if(nummodels<=0)_error_("dslmme object in  md.dsl field should contain at least 1 ensemble model!");
                if(modelid<=0 || modelid>nummodels)_error_("modelid field in dslmme object of md.dsl field should be between 1 and the number of ensemble runs!");
        } /*}}}*/
        /*Deal with elasticity {{{*/
        iomodel->FetchData(&rigid,"md.solidearth.settings.rigid");
        iomodel->FetchData(&elastic,"md.solidearth.settings.elastic");
        iomodel->FetchData(&rotation,"md.solidearth.settings.rotation");

        if(elastic | rigid){
                /*compute green functions for a range of angles*/
                iomodel->FetchData(&degacc,"md.solidearth.settings.degacc");
                M=reCast<int,IssmDouble>(180./degacc+1.);
        }

        /*love numbers: */
        if(elastic){
                iomodel->FetchData(&love_h,&nl,NULL,"md.solidearth.lovenumbers.h");
                iomodel->FetchData(&love_k,&nl,NULL,"md.solidearth.lovenumbers.k");
                iomodel->FetchData(&love_l,&nl,NULL,"md.solidearth.lovenumbers.l");
                iomodel->FetchData(&love_th,&nl,NULL,"md.solidearth.lovenumbers.th");
                iomodel->FetchData(&love_tk,&nl,NULL,"md.solidearth.lovenumbers.tk");
                iomodel->FetchData(&love_tl,&nl,NULL,"md.solidearth.lovenumbers.tl");

                parameters->AddObject(new DoubleMatParam(LoadLoveHEnum,love_h,nl,1));
                parameters->AddObject(new DoubleMatParam(LoadLoveKEnum,love_k,nl,1));
                parameters->AddObject(new DoubleMatParam(LoadLoveLEnum,love_l,nl,1));
                parameters->AddObject(new DoubleMatParam(TidalLoveHEnum,love_th,nl,1));
                parameters->AddObject(new DoubleMatParam(TidalLoveKEnum,love_tk,nl,1));
                parameters->AddObject(new DoubleMatParam(TidalLoveLEnum,love_tl,nl,1));

                // AD performance is sensitive to calls to ensurecontiguous.
                // // Providing "t" will cause ensurecontiguous to be called.
                #ifdef _HAVE_AD_
                G_elastic=xNew<IssmDouble>(M,"t");
                U_elastic=xNew<IssmDouble>(M,"t");
                H_elastic=xNew<IssmDouble>(M,"t");
                #else
                G_elastic=xNew<IssmDouble>(M);
                U_elastic=xNew<IssmDouble>(M);
                H_elastic=xNew<IssmDouble>(M);
                #endif
        }
        if(rigid){
                #ifdef _HAVE_AD_
                G_rigid=xNew<IssmDouble>(M,"t");
                #else
                G_rigid=xNew<IssmDouble>(M);
                #endif
        }
        
        if(rotation)parameters->AddObject(iomodel->CopyConstantObject("md.solidearth.lovenumbers.tk2secular",TidalLoveK2SecularEnum));

        if(rigid | elastic){

                /*compute combined legendre + love number (elastic green function:*/
                m=DetermineLocalSize(M,IssmComm::GetComm());
                GetOwnershipBoundariesFromRange(&lower_row,&upper_row,m,IssmComm::GetComm());
        }
        if(elastic){
                #ifdef _HAVE_AD_
                G_elastic_local=xNew<IssmDouble>(m,"t");
                U_elastic_local=xNew<IssmDouble>(m,"t");
                H_elastic_local=xNew<IssmDouble>(m,"t");
                #else
                G_elastic_local=xNew<IssmDouble>(m);
                U_elastic_local=xNew<IssmDouble>(m);
                H_elastic_local=xNew<IssmDouble>(m);
                #endif
        }
        if(rigid){
                #ifdef _HAVE_AD_
                G_rigid_local=xNew<IssmDouble>(m,"t");
                #else
                G_rigid_local=xNew<IssmDouble>(m);
                #endif
        }

        if(rigid){
                for(int i=lower_row;i<upper_row;i++){
                        IssmDouble alpha,x;
                        alpha= reCast<IssmDouble>(i)*degacc * PI / 180.0;
                        G_rigid_local[i-lower_row]= .5/sin(alpha/2.0);
                }
        }
        if(elastic){
                for(int i=lower_row;i<upper_row;i++){
                        IssmDouble alpha,x;
                        alpha= reCast<IssmDouble>(i)*degacc * PI / 180.0;

                        G_elastic_local[i-lower_row]= (love_k[nl-1]-love_h[nl-1])*G_rigid_local[i-lower_row];
                        U_elastic_local[i-lower_row]= (love_h[nl-1])*G_rigid_local[i-lower_row];
                        H_elastic_local[i-lower_row]= 0; 
                        IssmDouble Pn = 0.; 
                        IssmDouble Pn1 = 0.; 
                        IssmDouble Pn2 = 0.; 
                        IssmDouble Pn_p = 0.; 
                        IssmDouble Pn_p1 = 0.; 
                        IssmDouble Pn_p2 = 0.; 

                        for (int n=0;n<nl;n++) {
                                IssmDouble deltalove_G;
                                IssmDouble deltalove_U;

                                deltalove_G = (love_k[n]-love_k[nl-1]-love_h[n]+love_h[nl-1]);
                                deltalove_U = (love_h[n]-love_h[nl-1]);

                                /*compute legendre polynomials: P_n(cos\theta) & d P_n(cos\theta)/ d\theta: */
                                if(n==0){
                                        Pn=1; 
                                        Pn_p=0; 
                                }
                                else if(n==1){ 
                                        Pn = cos(alpha); 
                                        Pn_p = 1; 
                                }
                                else{
                                        Pn = ( (2*n-1)*cos(alpha)*Pn1 - (n-1)*Pn2 ) /n;
                                        Pn_p = ( (2*n-1)*(Pn1+cos(alpha)*Pn_p1) - (n-1)*Pn_p2 ) /n;
                                }
                                Pn2=Pn1; Pn1=Pn;
                                Pn_p2=Pn_p1; Pn_p1=Pn_p;

                                G_elastic_local[i-lower_row] += deltalove_G*Pn;         // gravitational potential 
                                U_elastic_local[i-lower_row] += deltalove_U*Pn;         // vertical (up) displacement 
                                H_elastic_local[i-lower_row] += sin(alpha)*love_l[n]*Pn_p;              // horizontal displacements 
                        }
                }
        }
        if(rigid){

                /*merge G_elastic_local into G_elastic; U_elastic_local into U_elastic; H_elastic_local to H_elastic:{{{*/
                int* recvcounts=xNew<int>(IssmComm::GetSize());
                int* displs=xNew<int>(IssmComm::GetSize());

                //recvcounts:
                ISSM_MPI_Allgather(&m,1,ISSM_MPI_INT,recvcounts,1,ISSM_MPI_INT,IssmComm::GetComm());

                /*displs: */
                ISSM_MPI_Allgather(&lower_row,1,ISSM_MPI_INT,displs,1,ISSM_MPI_INT,IssmComm::GetComm());

                /*All gather:*/
                ISSM_MPI_Allgatherv(G_rigid_local, m, ISSM_MPI_DOUBLE, G_rigid, recvcounts, displs, ISSM_MPI_DOUBLE,IssmComm::GetComm());
                if(elastic){
                        ISSM_MPI_Allgatherv(G_elastic_local, m, ISSM_MPI_DOUBLE, G_elastic, recvcounts, displs, ISSM_MPI_DOUBLE,IssmComm::GetComm());
                        ISSM_MPI_Allgatherv(U_elastic_local, m, ISSM_MPI_DOUBLE, U_elastic, recvcounts, displs, ISSM_MPI_DOUBLE,IssmComm::GetComm());
                        ISSM_MPI_Allgatherv(H_elastic_local, m, ISSM_MPI_DOUBLE, H_elastic, recvcounts, displs, ISSM_MPI_DOUBLE,IssmComm::GetComm());
                }
                
                /*free resources: */
                xDelete<int>(recvcounts);
                xDelete<int>(displs);

                /*Avoid singularity at 0: */
                G_rigid[0]=G_rigid[1];
                G_elastic[0]=G_elastic[1];
                U_elastic[0]=U_elastic[1];
                H_elastic[0]=H_elastic[1];

                /*Save our precomputed tables into parameters*/
                parameters->AddObject(new DoubleVecParam(SealevelriseGRigidEnum,G_rigid,M));
                if(elastic){
                        parameters->AddObject(new DoubleVecParam(SealevelriseGElasticEnum,G_elastic,M));
                        parameters->AddObject(new DoubleVecParam(SealevelriseUElasticEnum,U_elastic,M));
                        parameters->AddObject(new DoubleVecParam(SealevelriseHElasticEnum,H_elastic,M));
                }

                /*free resources: */
                xDelete<IssmDouble>(G_rigid);
                xDelete<IssmDouble>(G_rigid_local);
                if(elastic){
                        xDelete<IssmDouble>(love_h);
                        xDelete<IssmDouble>(love_k);
                        xDelete<IssmDouble>(love_l);
                        xDelete<IssmDouble>(love_th);
                        xDelete<IssmDouble>(love_tk);
                        xDelete<IssmDouble>(love_tl);
                        xDelete<IssmDouble>(G_elastic);
                        xDelete<IssmDouble>(G_elastic_local);
                        xDelete<IssmDouble>(U_elastic);
                        xDelete<IssmDouble>(U_elastic_local);
                        xDelete<IssmDouble>(H_elastic);
                        xDelete<IssmDouble>(H_elastic_local);
                }
        }
        /*}}}*/

        /*Indicate we have not yet run the Geometry Core module: */
        parameters->AddObject(new BoolParam(SealevelriseGeometryDoneEnum,false));

        /*Transitions:{{{ */
        iomodel->FetchData(&transitions,&transitions_M,&transitions_N,&ntransitions,"md.solidearth.transitions");
        if(transitions){
                parameters->AddObject(new DoubleMatArrayParam(SealevelriseTransitionsEnum,transitions,ntransitions,transitions_M,transitions_N));

                for(int i=0;i<ntransitions;i++){
                        IssmDouble* transition=transitions[i];
                        xDelete<IssmDouble>(transition);
                }
                xDelete<IssmDouble*>(transitions);
                xDelete<int>(transitions_M);
                xDelete<int>(transitions_N);
        } /*}}}*/
        /*Requested outputs {{{*/
        iomodel->FindConstant(&requestedoutputs,&numoutputs,"md.solidearth.requested_outputs");
        if(numoutputs)parameters->AddObject(new StringArrayParam(SealevelriseRequestedOutputsEnum,requestedoutputs,numoutputs));
        iomodel->DeleteData(&requestedoutputs,numoutputs,"md.solidearth.requested_outputs");
        /*}}}*/

}/*}}}*/

/*Finite Element Analysis*/
void           SealevelriseAnalysis::Core(FemModel* femmodel){/*{{{*/
        _error_("not implemented");
}/*}}}*/
ElementVector* SealevelriseAnalysis::CreateDVector(Element* element){/*{{{*/
        /*Default, return NULL*/
        return NULL;
}/*}}}*/
ElementMatrix* SealevelriseAnalysis::CreateJacobianMatrix(Element* element){/*{{{*/
_error_("Not implemented");
}/*}}}*/
ElementMatrix* SealevelriseAnalysis::CreateKMatrix(Element* element){/*{{{*/
        _error_("not implemented yet");
}/*}}}*/
ElementVector* SealevelriseAnalysis::CreatePVector(Element* element){/*{{{*/
_error_("not implemented yet");
}/*}}}*/
void           SealevelriseAnalysis::GetSolutionFromInputs(Vector<IssmDouble>* solution,Element* element){/*{{{*/
           _error_("not implemented yet");
}/*}}}*/
void           SealevelriseAnalysis::GradientJ(Vector<IssmDouble>* gradient,Element*  element,int control_type,int control_interp,int control_index){/*{{{*/
        _error_("Not implemented yet");
}/*}}}*/
void           SealevelriseAnalysis::InputUpdateFromSolution(IssmDouble* solution,Element* element){/*{{{*/
        _error_("not implemeneted yet!");

}/*}}}*/
void           SealevelriseAnalysis::UpdateConstraints(FemModel* femmodel){/*{{{*/
        /*Default, do nothing*/
        return;
}/*}}}*/