685 lines
23 KiB
C++
685 lines
23 KiB
C++
/**
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* @file BasisOptimize.cpp Functions which calculation optimized basis of the
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* stoichiometric coefficient matrix (see /ref equil functions)
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*/
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#include "cantera/thermo/ThermoPhase.h"
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#include "cantera/equil/MultiPhase.h"
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#include "cantera/numerics/ctlapack.h"
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using namespace Cantera;
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using namespace std;
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#ifdef DEBUG_MODE
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namespace Cantera
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{
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int BasisOptimize_print_lvl = 0;
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}
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//! Print a string within a given space limit.
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/*!
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* This routine limits the amount of the string that will be printed to a
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* maximum of "space" characters.
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* @param str String -> must be null terminated.
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* @param space space limit for the printing.
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* @param alignment 0 centered
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* 1 right aligned
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* 2 left aligned
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*/
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static void print_stringTrunc(const char* str, int space, int alignment);
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#endif
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//! Finds the location of the maximum component in a vector *x*
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/*!
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* @param x Vector to search
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* @param j j <= i < n : i is the range of indices to search in *x*
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* @param n Length of the vector
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*
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* @return index of the greatest value on *x* searched
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*/
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static size_t amax(double* x, size_t j, size_t n);
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size_t Cantera::BasisOptimize(int* usedZeroedSpecies, bool doFormRxn,
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MultiPhase* mphase, std::vector<size_t>& orderVectorSpecies,
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std::vector<size_t>& orderVectorElements,
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vector_fp& formRxnMatrix)
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{
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size_t j, jj, k=0, kk, l, i, jl, ml;
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bool lindep;
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std::string ename;
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std::string sname;
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/*
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* Get the total number of elements defined in the multiphase object
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*/
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size_t ne = mphase->nElements();
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/*
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* Get the total number of species in the multiphase object
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*/
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size_t nspecies = mphase->nSpecies();
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doublereal tmp;
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doublereal const USEDBEFORE = -1;
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/*
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* Perhaps, initialize the element ordering
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*/
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if (orderVectorElements.size() < ne) {
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orderVectorElements.resize(ne);
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for (j = 0; j < ne; j++) {
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orderVectorElements[j] = j;
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}
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}
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/*
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* Perhaps, initialize the species ordering
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*/
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if (orderVectorSpecies.size() != nspecies) {
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orderVectorSpecies.resize(nspecies);
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for (k = 0; k < nspecies; k++) {
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orderVectorSpecies[k] = k;
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}
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}
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#ifdef DEBUG_MODE
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double molSave = 0.0;
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if (BasisOptimize_print_lvl >= 1) {
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writelog(" ");
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for (i=0; i<77; i++) {
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writelog("-");
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}
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writelog("\n");
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writelog(" --- Subroutine BASOPT called to ");
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writelog("calculate the number of components and ");
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writelog("evaluate the formation matrix\n");
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if (BasisOptimize_print_lvl > 0) {
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writelog(" ---\n");
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writelog(" --- Formula Matrix used in BASOPT calculation\n");
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writelog(" --- Species | Order | ");
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for (j = 0; j < ne; j++) {
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jj = orderVectorElements[j];
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writelog(" ");
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ename = mphase->elementName(jj);
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print_stringTrunc(ename.c_str(), 4, 1);
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writelogf("(%1d)", j);
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}
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writelog("\n");
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for (k = 0; k < nspecies; k++) {
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kk = orderVectorSpecies[k];
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writelog(" --- ");
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sname = mphase->speciesName(kk);
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print_stringTrunc(sname.c_str(), 11, 1);
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writelogf(" | %4d |", k);
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for (j = 0; j < ne; j++) {
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jj = orderVectorElements[j];
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double num = mphase->nAtoms(kk,jj);
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writelogf("%6.1g ", num);
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}
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writelog("\n");
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}
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writelog(" --- \n");
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}
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}
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#endif
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/*
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* Calculate the maximum value of the number of components possible
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* It's equal to the minimum of the number of elements and the
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* number of total species.
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*/
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size_t nComponents = std::min(ne, nspecies);
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size_t nNonComponents = nspecies - nComponents;
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/*
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* Set this return variable to false
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*/
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*usedZeroedSpecies = false;
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/*
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* Create an array of mole numbers
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*/
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vector_fp molNum(nspecies,0.0);
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mphase->getMoles(DATA_PTR(molNum));
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/*
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* Other workspace
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*/
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vector_fp sm(ne*ne, 0.0);
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vector_fp ss(ne, 0.0);
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vector_fp sa(ne, 0.0);
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if (formRxnMatrix.size() < nspecies*ne) {
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formRxnMatrix.resize(nspecies*ne, 0.0);
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}
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#ifdef DEBUG_MODE
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/*
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* For debugging purposes keep an unmodified copy of the array.
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*/
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vector_fp molNumBase(molNum);
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#endif
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size_t jr = npos;
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/*
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* Top of a loop of some sort based on the index JR. JR is the
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* current number of component species found.
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*/
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do {
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++jr;
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/* - Top of another loop point based on finding a linearly */
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/* - independent species */
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do {
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/*
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* Search the remaining part of the mole number vector, molNum
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* for the largest remaining species. Return its identity.
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* kk is the raw number. k is the orderVectorSpecies index.
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*/
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kk = amax(DATA_PTR(molNum), 0, nspecies);
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for (j = 0; j < nspecies; j++) {
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if (orderVectorSpecies[j] == kk) {
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k = j;
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break;
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}
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}
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if (j == nspecies) {
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throw CanteraError("BasisOptimize", "orderVectorSpecies contains an error");
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}
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if (molNum[kk] == 0.0) {
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*usedZeroedSpecies = true;
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}
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/*
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* If the largest molNum is negative, then we are done.
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*/
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if (molNum[kk] == USEDBEFORE) {
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nComponents = jr;
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nNonComponents = nspecies - nComponents;
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break;
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}
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/*
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* Assign a small negative number to the component that we have
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* just found, in order to take it out of further consideration.
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*/
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#ifdef DEBUG_MODE
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molSave = molNum[kk];
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#endif
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molNum[kk] = USEDBEFORE;
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/* *********************************************************** */
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/* **** CHECK LINEAR INDEPENDENCE WITH PREVIOUS SPECIES ****** */
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/* *********************************************************** */
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/*
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* Modified Gram-Schmidt Method, p. 202 Dalquist
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* QR factorization of a matrix without row pivoting.
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*/
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jl = jr;
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for (j = 0; j < ne; ++j) {
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jj = orderVectorElements[j];
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sm[j + jr*ne] = mphase->nAtoms(kk,jj);
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}
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if (jl > 0) {
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/*
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* Compute the coefficients of JA column of the
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* the upper triangular R matrix, SS(J) = R_J_JR
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* (this is slightly different than Dalquist)
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* R_JA_JA = 1
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*/
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for (j = 0; j < jl; ++j) {
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ss[j] = 0.0;
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for (i = 0; i < ne; ++i) {
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ss[j] += sm[i + jr*ne] * sm[i + j*ne];
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}
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ss[j] /= sa[j];
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}
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/*
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* Now make the new column, (*,JR), orthogonal to the
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* previous columns
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*/
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for (j = 0; j < jl; ++j) {
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for (l = 0; l < ne; ++l) {
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sm[l + jr*ne] -= ss[j] * sm[l + j*ne];
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}
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}
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}
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/*
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* Find the new length of the new column in Q.
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* It will be used in the denominator in future row calcs.
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*/
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sa[jr] = 0.0;
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for (ml = 0; ml < ne; ++ml) {
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tmp = sm[ml + jr*ne];
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sa[jr] += tmp * tmp;
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}
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/* **************************************************** */
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/* **** IF NORM OF NEW ROW .LT. 1E-3 REJECT ********** */
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/* **************************************************** */
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if (sa[jr] < 1.0e-6) {
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lindep = true;
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} else {
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lindep = false;
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}
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} while (lindep);
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/* ****************************************** */
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/* **** REARRANGE THE DATA ****************** */
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/* ****************************************** */
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if (jr != k) {
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#ifdef DEBUG_MODE
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if (BasisOptimize_print_lvl >= 1) {
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kk = orderVectorSpecies[k];
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sname = mphase->speciesName(kk);
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writelogf(" --- %-12.12s", sname.c_str());
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jj = orderVectorSpecies[jr];
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ename = mphase->speciesName(jj);
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writelogf("(%9.2g) replaces %-12.12s", molSave, ename.c_str());
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writelogf("(%9.2g) as component %3d\n", molNum[jj], jr);
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}
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#endif
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std::swap(orderVectorSpecies[jr], orderVectorSpecies[k]);
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}
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/*
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* If we haven't found enough components, go back
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* and find some more. (nc -1 is used below, because
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* jr is counted from 0, via the C convention.
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*/
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} while (jr < (nComponents-1));
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if (! doFormRxn) {
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return nComponents;
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}
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/* ****************************************************** */
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/* **** EVALUATE THE STOICHIOMETRY ********************** */
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/* ****************************************************** */
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/*
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* Formulate the matrix problem for the stoichiometric
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* coefficients. CX + B = 0
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* C will be an nc x nc matrix made up of the formula
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* vectors for the components. Each component's formula
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* vector is a column. The rows are the elements.
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* n rhs's will be solved for. Thus, B is an nc x n
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* matrix.
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*
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* BIG PROBLEM 1/21/99:
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*
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* This algorithm makes the assumption that the
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* first nc rows of the formula matrix aren't rank deficient.
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* However, this might not be the case. For example, assume
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* that the first element in FormulaMatrix[] is argon. Assume that
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* no species in the matrix problem actually includes argon.
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* Then, the first row in sm[], below will be identically
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* zero. bleh.
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* What needs to be done is to perform a rearrangement
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* of the ELEMENTS -> i.e. rearrange, FormulaMatrix, sp, and gai, such
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* that the first nc elements form in combination with the
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* nc components create an invertible sm[]. not a small
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* project, but very doable.
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* An alternative would be to turn the matrix problem
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* below into an ne x nc problem, and do QR elimination instead
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* of Gauss-Jordan elimination.
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* Note the rearrangement of elements need only be done once
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* in the problem. It's actually very similar to the top of
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* this program with ne being the species and nc being the
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* elements!!
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*/
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for (k = 0; k < nComponents; ++k) {
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kk = orderVectorSpecies[k];
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for (j = 0; j < nComponents; ++j) {
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jj = orderVectorElements[j];
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sm[j + k*ne] = mphase->nAtoms(kk, jj);
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}
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}
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for (i = 0; i < nNonComponents; ++i) {
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k = nComponents + i;
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kk = orderVectorSpecies[k];
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for (j = 0; j < nComponents; ++j) {
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jj = orderVectorElements[j];
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formRxnMatrix[j + i * ne] = - mphase->nAtoms(kk, jj);
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}
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}
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// Use LU factorization to calculate the reaction matrix
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int info;
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vector_int ipiv(nComponents);
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ct_dgetrf(nComponents, nComponents, &sm[0], ne, &ipiv[0], info);
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if (info) {
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throw CanteraError("basopt", "factorization returned an error condition");
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}
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ct_dgetrs(ctlapack::NoTranspose, nComponents, nNonComponents, &sm[0], ne,
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&ipiv[0], &formRxnMatrix[0], ne, info);
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#ifdef DEBUG_MODE
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if (Cantera::BasisOptimize_print_lvl >= 1) {
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writelog(" ---\n");
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writelogf(" --- Number of Components = %d\n", nComponents);
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writelog(" --- Formula Matrix:\n");
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writelog(" --- Components: ");
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for (k = 0; k < nComponents; k++) {
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kk = orderVectorSpecies[k];
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writelogf(" %3d (%3d) ", k, kk);
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}
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writelog("\n --- Components Moles: ");
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for (k = 0; k < nComponents; k++) {
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kk = orderVectorSpecies[k];
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writelogf("%-11.3g", molNumBase[kk]);
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}
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writelog("\n --- NonComponent | Moles | ");
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for (i = 0; i < nComponents; i++) {
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kk = orderVectorSpecies[i];
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sname = mphase->speciesName(kk);
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writelogf("%-11.10s", sname.c_str());
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}
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writelog("\n");
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for (i = 0; i < nNonComponents; i++) {
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k = i + nComponents;
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kk = orderVectorSpecies[k];
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writelogf(" --- %3d (%3d) ", k, kk);
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sname = mphase->speciesName(kk);
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writelogf("%-10.10s", sname.c_str());
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writelogf("|%10.3g|", molNumBase[kk]);
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/*
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* Print the negative of formRxnMatrix[]; it's easier to interpret.
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*/
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for (j = 0; j < nComponents; j++) {
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writelogf(" %6.2f", - formRxnMatrix[j + i * ne]);
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}
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writelog("\n");
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}
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writelog(" ");
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for (i=0; i<77; i++) {
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writelog("-");
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}
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writelog("\n");
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}
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#endif
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return nComponents;
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} /* basopt() ************************************************************/
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#ifdef DEBUG_MODE
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static void print_stringTrunc(const char* str, int space, int alignment)
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/***********************************************************************
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* vcs_print_stringTrunc():
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*
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* Print a string within a given space limit. This routine
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* limits the amount of the string that will be printed to a
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* maximum of "space" characters.
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*
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* str = String -> must be null terminated.
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* space = space limit for the printing.
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* alignment = 0 centered
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* 1 right aligned
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* 2 left aligned
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***********************************************************************/
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{
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int i, ls=0, rs=0;
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int len = strlen(str);
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if ((len) >= space) {
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for (i = 0; i < space; i++) {
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writelogf("%c", str[i]);
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}
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} else {
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if (alignment == 1) {
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ls = space - len;
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} else if (alignment == 2) {
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rs = space - len;
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} else {
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ls = (space - len) / 2;
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rs = space - len - ls;
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}
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if (ls != 0) {
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for (i = 0; i < ls; i++) {
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writelog(" ");
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}
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}
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writelogf("%s", str);
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if (rs != 0) {
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for (i = 0; i < rs; i++) {
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writelog(" ");
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}
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}
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}
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}
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#endif
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/*
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* Finds the location of the maximum component in a double vector
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* INPUT
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* x(*) - Vector to search
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* j <= i < n : i is the range of indices to search in X(*)
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*
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* RETURN
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* return index of the greatest value on X(*) searched
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*/
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static size_t amax(double* x, size_t j, size_t n)
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{
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size_t largest = j;
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double big = x[j];
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for (size_t i = j + 1; i < n; ++i) {
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if (x[i] > big) {
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largest = i;
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big = x[i];
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}
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}
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return largest;
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}
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size_t Cantera::ElemRearrange(size_t nComponents, const vector_fp& elementAbundances,
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MultiPhase* mphase,
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std::vector<size_t>& orderVectorSpecies,
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std::vector<size_t>& orderVectorElements)
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{
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size_t j, k, l, i, jl, ml, jr, ielem, jj, kk=0;
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bool lindep = false;
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size_t nelements = mphase->nElements();
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std::string ename;
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/*
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* Get the total number of species in the multiphase object
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*/
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size_t nspecies = mphase->nSpecies();
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double test = -1.0E10;
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#ifdef DEBUG_MODE
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if (BasisOptimize_print_lvl > 0) {
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writelog(" ");
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for (i=0; i<77; i++) {
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writelog("-");
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}
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writelog("\n");
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writelog(" --- Subroutine ElemRearrange() called to ");
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writelog("check stoich. coefficient matrix\n");
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writelog(" --- and to rearrange the element ordering once\n");
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}
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#endif
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/*
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* Perhaps, initialize the element ordering
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*/
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if (orderVectorElements.size() < nelements) {
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orderVectorElements.resize(nelements);
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for (j = 0; j < nelements; j++) {
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orderVectorElements[j] = j;
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}
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}
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/*
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* Perhaps, initialize the species ordering. However, this is
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* dangerous, as this ordering is assumed to yield the
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* component species for the problem
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*/
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if (orderVectorSpecies.size() != nspecies) {
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orderVectorSpecies.resize(nspecies);
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for (k = 0; k < nspecies; k++) {
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orderVectorSpecies[k] = k;
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}
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}
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/*
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* If the elementAbundances aren't input, just create a fake one
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* based on summing the column of the stoich matrix.
|
|
* This will force elements with zero species to the
|
|
* end of the element ordering.
|
|
*/
|
|
vector_fp eAbund(nelements,0.0);
|
|
if (elementAbundances.size() != nelements) {
|
|
for (j = 0; j < nelements; j++) {
|
|
eAbund[j] = 0.0;
|
|
for (k = 0; k < nspecies; k++) {
|
|
eAbund[j] += fabs(mphase->nAtoms(k, j));
|
|
}
|
|
}
|
|
} else {
|
|
copy(elementAbundances.begin(), elementAbundances.end(),
|
|
eAbund.begin());
|
|
}
|
|
|
|
vector_fp sa(nelements,0.0);
|
|
vector_fp ss(nelements,0.0);
|
|
vector_fp sm(nelements*nelements,0.0);
|
|
|
|
/*
|
|
* Top of a loop of some sort based on the index JR. JR is the
|
|
* current number independent elements found.
|
|
*/
|
|
jr = npos;
|
|
do {
|
|
++jr;
|
|
/*
|
|
* Top of another loop point based on finding a linearly
|
|
* independent element
|
|
*/
|
|
do {
|
|
/*
|
|
* Search the element vector. We first locate elements that
|
|
* are present in any amount. Then, we locate elements that
|
|
* are not present in any amount.
|
|
* Return its identity in K.
|
|
*/
|
|
k = nelements;
|
|
for (ielem = jr; ielem < nelements; ielem++) {
|
|
kk = orderVectorElements[ielem];
|
|
if (eAbund[kk] != test && eAbund[kk] > 0.0) {
|
|
k = ielem;
|
|
break;
|
|
}
|
|
}
|
|
for (ielem = jr; ielem < nelements; ielem++) {
|
|
kk = orderVectorElements[ielem];
|
|
if (eAbund[kk] != test) {
|
|
k = ielem;
|
|
break;
|
|
}
|
|
}
|
|
|
|
if (k == nelements) {
|
|
// When we are here, there is an error usually.
|
|
// We haven't found the number of elements necessary.
|
|
// This is signalled by returning jr != nComponents.
|
|
#ifdef DEBUG_MODE
|
|
if (BasisOptimize_print_lvl > 0) {
|
|
writelogf("Error exit: returning with nComponents = %d\n", jr);
|
|
}
|
|
#endif
|
|
return jr;
|
|
}
|
|
|
|
/*
|
|
* Assign a large negative number to the element that we have
|
|
* just found, in order to take it out of further consideration.
|
|
*/
|
|
eAbund[kk] = test;
|
|
|
|
/* *********************************************************** */
|
|
/* **** CHECK LINEAR INDEPENDENCE OF CURRENT FORMULA MATRIX */
|
|
/* **** LINE WITH PREVIOUS LINES OF THE FORMULA MATRIX ****** */
|
|
/* *********************************************************** */
|
|
/*
|
|
* Modified Gram-Schmidt Method, p. 202 Dalquist
|
|
* QR factorization of a matrix without row pivoting.
|
|
*/
|
|
jl = jr;
|
|
/*
|
|
* Fill in the row for the current element, k, under consideration
|
|
* The row will contain the Formula matrix value for that element
|
|
* with respect to the vector of component species.
|
|
* (note j and k indices are flipped compared to the previous routine)
|
|
*/
|
|
for (j = 0; j < nComponents; ++j) {
|
|
jj = orderVectorSpecies[j];
|
|
kk = orderVectorElements[k];
|
|
sm[j + jr*nComponents] = mphase->nAtoms(jj,kk);
|
|
}
|
|
if (jl > 0) {
|
|
/*
|
|
* Compute the coefficients of JA column of the
|
|
* the upper triangular R matrix, SS(J) = R_J_JR
|
|
* (this is slightly different than Dalquist)
|
|
* R_JA_JA = 1
|
|
*/
|
|
for (j = 0; j < jl; ++j) {
|
|
ss[j] = 0.0;
|
|
for (i = 0; i < nComponents; ++i) {
|
|
ss[j] += sm[i + jr*nComponents] * sm[i + j*nComponents];
|
|
}
|
|
ss[j] /= sa[j];
|
|
}
|
|
/*
|
|
* Now make the new column, (*,JR), orthogonal to the
|
|
* previous columns
|
|
*/
|
|
for (j = 0; j < jl; ++j) {
|
|
for (l = 0; l < nComponents; ++l) {
|
|
sm[l + jr*nComponents] -= ss[j] * sm[l + j*nComponents];
|
|
}
|
|
}
|
|
}
|
|
|
|
/*
|
|
* Find the new length of the new column in Q.
|
|
* It will be used in the denominator in future row calcs.
|
|
*/
|
|
sa[jr] = 0.0;
|
|
for (ml = 0; ml < nComponents; ++ml) {
|
|
double tmp = sm[ml + jr*nComponents];
|
|
sa[jr] += tmp * tmp;
|
|
}
|
|
/* **************************************************** */
|
|
/* **** IF NORM OF NEW ROW .LT. 1E-6 REJECT ********** */
|
|
/* **************************************************** */
|
|
if (sa[jr] < 1.0e-6) {
|
|
lindep = true;
|
|
} else {
|
|
lindep = false;
|
|
}
|
|
} while (lindep);
|
|
/* ****************************************** */
|
|
/* **** REARRANGE THE DATA ****************** */
|
|
/* ****************************************** */
|
|
if (jr != k) {
|
|
#ifdef DEBUG_MODE
|
|
if (BasisOptimize_print_lvl > 0) {
|
|
kk = orderVectorElements[k];
|
|
ename = mphase->elementName(kk);
|
|
writelog(" --- ");
|
|
writelogf("%-2.2s", ename.c_str());
|
|
writelog("replaces ");
|
|
kk = orderVectorElements[jr];
|
|
ename = mphase->elementName(kk);
|
|
writelogf("%-2.2s", ename.c_str());
|
|
writelogf(" as element %3d\n", jr);
|
|
}
|
|
#endif
|
|
std::swap(orderVectorElements[jr], orderVectorElements[k]);
|
|
}
|
|
|
|
/*
|
|
* If we haven't found enough components, go back
|
|
* and find some more. (nc -1 is used below, because
|
|
* jr is counted from 0, via the C convention.
|
|
*/
|
|
} while (jr < (nComponents-1));
|
|
return nComponents;
|
|
}
|