cantera/src/equil/vcs_solve_phaseStability.cpp

202 lines
5.5 KiB
C++

//! @file vcs_solve_phaseStability.cpp
/*
* Copyright (2005) Sandia Corporation. Under the terms of
* Contract DE-AC04-94AL85000 with Sandia Corporation, the
* U.S. Government retains certain rights in this software.
*/
#include "cantera/equil/vcs_solve.h"
#include "cantera/equil/vcs_internal.h"
#include "cantera/equil/vcs_VolPhase.h"
#include "cantera/equil/vcs_species_thermo.h"
#include "cantera/equil/vcs_prob.h"
#include "cantera/base/clockWC.h"
using namespace std;
namespace VCSnonideal
{
int VCS_SOLVE::vcs_PS(VCS_PROB* vprob, int iphase, int printLvl, double& feStable)
{
/*
* ifunc determines the problem type
*/
int ifunc = 0;
int iStab = 0;
/*
* This function is called to create the private data
* using the public data.
*/
size_t nspecies0 = vprob->nspecies + 10;
size_t nelements0 = vprob->ne;
size_t nphase0 = vprob->NPhase;
vcs_initSizes(nspecies0, nelements0, nphase0);
if (ifunc < 0 || ifunc > 2) {
plogf("vcs: Unrecognized value of ifunc, %d: bailing!\n",
ifunc);
return VCS_PUB_BAD;
}
/*
* This function is called to copy the public data
* and the current problem specification
* into the current object's data structure.
*/
int retn = vcs_prob_specifyFully(vprob);
if (retn != 0) {
plogf("vcs_pub_to_priv returned a bad status, %d: bailing!\n",
retn);
return retn;
}
/*
* Prep the problem data
* - adjust the identity of any phases
* - determine the number of components in the problem
*/
retn = vcs_prep_oneTime(printLvl);
if (retn != 0) {
plogf("vcs_prep_oneTime returned a bad status, %d: bailing!\n",
retn);
return retn;
}
/*
* This function is called to copy the current problem
* into the current object's data structure.
*/
retn = vcs_prob_specify(vprob);
if (retn != 0) {
plogf("vcs_prob_specify returned a bad status, %d: bailing!\n",
retn);
return retn;
}
/*
* Prep the problem data for this particular instantiation of
* the problem
*/
retn = vcs_prep();
if (retn != VCS_SUCCESS) {
plogf("vcs_prep returned a bad status, %d: bailing!\n", retn);
return retn;
}
/*
* Check to see if the current problem is well posed.
*/
if (!vcs_wellPosed(vprob)) {
plogf("vcs has determined the problem is not well posed: Bailing\n");
return VCS_PUB_BAD;
}
/*
* Store the temperature and pressure in the private global variables
*/
m_temperature = vprob->T;
m_pressurePA = vprob->PresPA;
/*
* Evaluate the standard state free energies
* at the current temperatures and pressures.
*/
vcs_evalSS_TP(printLvl, printLvl, m_temperature, m_pressurePA);
/*
* Prepare the problem data:
* ->nondimensionalize the free energies using
* the divisor, R * T
*/
vcs_nondim_TP();
/*
* Prep the fe field
*/
vcs_fePrep_TP();
/*
* Solve the problem at a fixed Temperature and Pressure
* (all information concerning Temperature and Pressure has already
* been derived. The free energies are now in dimensionless form.)
*/
iStab = vcs_solve_phaseStability(iphase, ifunc, feStable, printLvl);
/*
* Redimensionalize the free energies using
* the reverse of vcs_nondim to add back units.
*/
vcs_redim_TP();
/*
vcs_VolPhase *Vphase = m_VolPhaseList[iphase];
std::vector<double> mfPop = Vphase->moleFractions();
int nsp = Vphase->nSpecies();
vcs_VolPhase *VPphase = vprob->VPhaseList[iphase];
int kstart = Vphase->spGlobalIndexVCS(0);
for (int k = 0; k < nsp; k++) {
vprob->mf[kstart + k] = mfPop[k];
}
VPphase->setMoleFractionsState(Vphase->totalMoles(),
VCS_DATA_PTR(Vphase->moleFractions()),
VCS_STATECALC_TMP);
*/
vcs_prob_update(vprob);
/*
* Return the convergence success flag.
*/
return iStab;
}
int VCS_SOLVE::vcs_solve_phaseStability(const int iph, const int ifunc,
double& funcVal,
int printLvl)
{
double test = -1.0E-10;
bool usedZeroedSpecies;
// std::vector<size_t> phasePopPhaseIDs(0);
int iStab = 0;
std::vector<double> sm(m_numElemConstraints*m_numElemConstraints, 0.0);
std::vector<double> ss(m_numElemConstraints, 0.0);
std::vector<double> sa(m_numElemConstraints, 0.0);
std::vector<double> aw(m_numSpeciesTot, 0.0);
std::vector<double> wx(m_numElemConstraints, 0.0);
vcs_basopt(false, VCS_DATA_PTR(aw), VCS_DATA_PTR(sa), VCS_DATA_PTR(sm), VCS_DATA_PTR(ss),
test, &usedZeroedSpecies);
vcs_evaluate_speciesType();
vcs_dfe(VCS_STATECALC_OLD, 0, 0, m_numSpeciesRdc);
if (printLvl > 3) {
vcs_printSpeciesChemPot(VCS_STATECALC_OLD);
}
vcs_deltag(0, true, VCS_STATECALC_OLD);
if (printLvl > 3) {
vcs_printDeltaG(VCS_STATECALC_OLD);
}
vcs_dcopy(VCS_DATA_PTR(m_deltaGRxn_Deficient), VCS_DATA_PTR(m_deltaGRxn_old), m_numRxnRdc);
// phasePopPhaseIDs.clear();
// vcs_popPhaseID(phasePopPhaseIDs);
funcVal = vcs_phaseStabilityTest(iph);
if (funcVal > 0.0) {
iStab = 1;
} else {
iStab = 0;
}
return iStab;
}
}