479 lines
14 KiB
C++
479 lines
14 KiB
C++
#include "solvespace.h"
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void System::WriteJacobian(int eqTag, int paramTag) {
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int a, i, j;
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j = 0;
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for(a = 0; a < param.n; a++) {
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Param *p = &(param.elem[a]);
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if(p->tag != paramTag) continue;
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mat.param[j] = p->h;
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j++;
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}
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mat.n = j;
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i = 0;
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for(a = 0; a < eq.n; a++) {
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Equation *e = &(eq.elem[a]);
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if(e->tag != eqTag) continue;
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mat.eq[i] = e->h;
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Expr *f = e->e->DeepCopyWithParamsAsPointers(¶m, &(SS.param));
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f = f->FoldConstants();
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// Hash table (31 bits) to accelerate generation of zero partials.
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DWORD scoreboard = f->ParamsUsed();
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for(j = 0; j < mat.n; j++) {
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Expr *pd;
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if(scoreboard & (1 << (mat.param[j].v % 31))) {
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pd = f->PartialWrt(mat.param[j]);
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pd = pd->FoldConstants();
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pd = pd->DeepCopyWithParamsAsPointers(¶m, &(SS.param));
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} else {
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pd = Expr::From(0.0);
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}
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mat.A.sym[i][j] = pd;
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}
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mat.B.sym[i] = f;
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i++;
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}
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mat.m = i;
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}
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void System::EvalJacobian(void) {
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int i, j;
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for(i = 0; i < mat.m; i++) {
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for(j = 0; j < mat.n; j++) {
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mat.A.num[i][j] = (mat.A.sym[i][j])->Eval();
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}
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}
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}
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bool System::IsDragged(hParam p) {
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if(SS.GW.pending.point.v) {
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// The pending point could be one in a group that has not yet
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// been processed, in which case the lookup will fail; but
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// that's not an error.
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Entity *pt = SS.entity.FindByIdNoOops(SS.GW.pending.point);
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if(pt) {
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switch(pt->type) {
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case Entity::POINT_N_TRANS:
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case Entity::POINT_IN_3D:
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if(p.v == (pt->param[0]).v) return true;
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if(p.v == (pt->param[1]).v) return true;
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if(p.v == (pt->param[2]).v) return true;
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break;
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case Entity::POINT_IN_2D:
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if(p.v == (pt->param[0]).v) return true;
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if(p.v == (pt->param[1]).v) return true;
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break;
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}
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}
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}
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if(SS.GW.pending.circle.v) {
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Entity *circ = SS.entity.FindByIdNoOops(SS.GW.pending.circle);
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if(circ) {
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Entity *dist = SS.GetEntity(circ->distance);
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switch(dist->type) {
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case Entity::DISTANCE:
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if(p.v == (dist->param[0].v)) return true;
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break;
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}
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}
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}
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if(SS.GW.pending.normal.v) {
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Entity *norm = SS.entity.FindByIdNoOops(SS.GW.pending.normal);
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if(norm) {
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switch(norm->type) {
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case Entity::NORMAL_IN_3D:
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if(p.v == (norm->param[0].v)) return true;
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if(p.v == (norm->param[1].v)) return true;
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if(p.v == (norm->param[2].v)) return true;
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if(p.v == (norm->param[3].v)) return true;
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break;
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// other types are locked, so not draggable
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}
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}
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}
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return false;
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}
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void System::SolveBySubstitution(void) {
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int i;
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for(i = 0; i < eq.n; i++) {
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Equation *teq = &(eq.elem[i]);
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Expr *tex = teq->e;
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if(tex->op == Expr::MINUS &&
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tex->a->op == Expr::PARAM &&
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tex->b->op == Expr::PARAM)
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{
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hParam a = (tex->a)->x.parh;
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hParam b = (tex->b)->x.parh;
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if(!(param.FindByIdNoOops(a) && param.FindByIdNoOops(b))) {
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// Don't substitute unless they're both solver params;
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// otherwise it's an equation that can be solved immediately,
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// or an error to flag later.
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continue;
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}
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if(IsDragged(a)) {
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// A is being dragged, so A should stay, and B should go
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hParam t = a;
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a = b;
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b = t;
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}
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int j;
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for(j = 0; j < eq.n; j++) {
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Equation *req = &(eq.elem[j]);
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(req->e)->Substitute(a, b); // A becomes B, B unchanged
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}
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for(j = 0; j < param.n; j++) {
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Param *rp = &(param.elem[j]);
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if(rp->substd.v == a.v) {
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rp->substd = b;
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}
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}
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Param *ptr = param.FindById(a);
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ptr->tag = VAR_SUBSTITUTED;
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ptr->substd = b;
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teq->tag = EQ_SUBSTITUTED;
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}
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}
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}
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bool System::Tol(double v) {
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return (fabs(v) < 0.01);
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}
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int System::GaussJordan(void) {
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int i, j;
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for(j = 0; j < mat.n; j++) {
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mat.bound[j] = false;
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}
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// Now eliminate.
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i = 0;
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int rank = 0;
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for(j = 0; j < mat.n; j++) {
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// First, seek a pivot in our column.
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int ip, imax;
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double max = 0;
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for(ip = i; ip < mat.m; ip++) {
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double v = fabs(mat.A.num[ip][j]);
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if(v > max) {
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imax = ip;
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max = v;
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}
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}
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if(!Tol(max)) {
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// There's a usable pivot in this column. Swap it in:
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int js;
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for(js = j; js < mat.n; js++) {
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double temp;
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temp = mat.A.num[imax][js];
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mat.A.num[imax][js] = mat.A.num[i][js];
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mat.A.num[i][js] = temp;
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}
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// Get a 1 as the leading entry in the row we're working on.
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double v = mat.A.num[i][j];
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for(js = 0; js < mat.n; js++) {
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mat.A.num[i][js] /= v;
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}
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// Eliminate this column from rows except this one.
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int is;
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for(is = 0; is < mat.m; is++) {
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if(is == i) continue;
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// We're trying to drive A[is][j] to zero. We know
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// that A[i][j] is 1, so we want to subtract off
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// A[is][j] times our present row.
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double v = mat.A.num[is][j];
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for(js = 0; js < mat.n; js++) {
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mat.A.num[is][js] -= v*mat.A.num[i][js];
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}
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mat.A.num[is][j] = 0;
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}
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// And mark this as a bound variable.
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mat.bound[j] = true;
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rank++;
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// Move on to the next row, since we just used this one to
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// eliminate from column j.
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i++;
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if(i >= mat.m) break;
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}
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}
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return rank;
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}
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bool System::SolveLinearSystem(double X[], double A[][MAX_UNKNOWNS],
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double B[], int n)
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{
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// Gaussian elimination, with partial pivoting. It's an error if the
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// matrix is singular, because that means two constraints are
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// equivalent.
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int i, j, ip, jp, imax;
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double max, temp;
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for(i = 0; i < n; i++) {
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// We are trying eliminate the term in column i, for rows i+1 and
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// greater. First, find a pivot (between rows i and N-1).
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max = 0;
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for(ip = i; ip < n; ip++) {
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if(fabs(A[ip][i]) > max) {
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imax = ip;
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max = fabs(A[ip][i]);
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}
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}
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// Don't give up on a singular matrix unless it's really bad; the
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// assumption code is responsible for identifying that condition,
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// so we're not responsible for reporting that error.
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if(fabs(max) < 1e-20) return false;
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// Swap row imax with row i
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for(jp = 0; jp < n; jp++) {
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SWAP(double, A[i][jp], A[imax][jp]);
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}
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SWAP(double, B[i], B[imax]);
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// For rows i+1 and greater, eliminate the term in column i.
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for(ip = i+1; ip < n; ip++) {
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temp = A[ip][i]/A[i][i];
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for(jp = 0; jp < n; jp++) {
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A[ip][jp] -= temp*(A[i][jp]);
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}
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B[ip] -= temp*B[i];
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}
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}
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// We've put the matrix in upper triangular form, so at this point we
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// can solve by back-substitution.
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for(i = n - 1; i >= 0; i--) {
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if(fabs(A[i][i]) < 1e-20) return false;
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temp = B[i];
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for(j = n - 1; j > i; j--) {
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temp -= X[j]*A[i][j];
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}
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X[i] = temp / A[i][i];
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}
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return true;
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}
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bool System::SolveLeastSquares(void) {
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int r, c, i;
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// Scale the columns; this scale weights the parameters for the least
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// squares solve, so that we can encourage the solver to make bigger
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// changes in some parameters, and smaller in others.
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for(c = 0; c < mat.n; c++) {
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if(IsDragged(mat.param[c])) {
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mat.scale[c] = 1/5.0;
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} else {
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mat.scale[c] = 1;
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}
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for(r = 0; r < mat.m; r++) {
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mat.A.num[r][c] *= mat.scale[c];
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}
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}
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// Write A*A'
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for(r = 0; r < mat.m; r++) {
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for(c = 0; c < mat.m; c++) { // yes, AAt is square
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double sum = 0;
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for(i = 0; i < mat.n; i++) {
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sum += mat.A.num[r][i]*mat.A.num[c][i];
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}
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mat.AAt[r][c] = sum;
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}
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}
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if(!SolveLinearSystem(mat.Z, mat.AAt, mat.B.num, mat.m)) return false;
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// And multiply that by A' to get our solution.
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for(c = 0; c < mat.n; c++) {
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double sum = 0;
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for(i = 0; i < mat.m; i++) {
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sum += mat.A.num[i][c]*mat.Z[i];
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}
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mat.X[c] = sum * mat.scale[c];
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}
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return true;
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}
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bool System::NewtonSolve(int tag) {
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WriteJacobian(tag, tag);
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if(mat.m > mat.n) return false;
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int iter = 0;
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bool converged = false;
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int i;
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// Evaluate the functions at our operating point.
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for(i = 0; i < mat.m; i++) {
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mat.B.num[i] = (mat.B.sym[i])->Eval();
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}
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do {
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// And evaluate the Jacobian at our initial operating point.
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EvalJacobian();
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if(!SolveLeastSquares()) break;
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// Take the Newton step;
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// J(x_n) (x_{n+1} - x_n) = 0 - F(x_n)
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for(i = 0; i < mat.n; i++) {
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(param.FindById(mat.param[i]))->val -= mat.X[i];
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}
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// Re-evalute the functions, since the params have just changed.
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for(i = 0; i < mat.m; i++) {
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mat.B.num[i] = (mat.B.sym[i])->Eval();
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}
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// Check for convergence
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converged = true;
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for(i = 0; i < mat.m; i++) {
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if(fabs(mat.B.num[i]) > 1e-10) {
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converged = false;
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break;
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}
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}
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} while(iter++ < 50 && !converged);
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return converged;
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}
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void System::WriteEquationsExceptFor(hConstraint hc, hGroup hg) {
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int i;
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// Generate all the equations from constraints in this group
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for(i = 0; i < SS.constraint.n; i++) {
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Constraint *c = &(SS.constraint.elem[i]);
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if(c->group.v != hg.v) continue;
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if(c->h.v == hc.v) continue;
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c->Generate(&eq);
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}
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// And the equations from entities
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for(i = 0; i < SS.entity.n; i++) {
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Entity *e = &(SS.entity.elem[i]);
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if(e->group.v != hg.v) continue;
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e->GenerateEquations(&eq);
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}
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// And from the groups themselves
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(SS.GetGroup(hg))->GenerateEquations(&eq);
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}
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void System::FindWhichToRemoveToFixJacobian(Group *g) {
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int i;
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(g->solved.remove).Clear();
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for(i = 0; i < SS.constraint.n; i++) {
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Constraint *c = &(SS.constraint.elem[i]);
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if(c->group.v != g->h.v) continue;
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param.ClearTags();
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eq.Clear();
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WriteEquationsExceptFor(c->h, g->h);
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eq.ClearTags();
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WriteJacobian(0, 0);
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EvalJacobian();
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int rank = GaussJordan();
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if(rank == mat.m) {
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// We fixed it by removing this constraint
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(g->solved.remove).Add(&(c->h));
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}
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}
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}
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void System::Solve(Group *g) {
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g->solved.remove.Clear();
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WriteEquationsExceptFor(Constraint::NO_CONSTRAINT, g->h);
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int i, j = 0;
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/*
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dbp("%d equations", eq.n);
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for(i = 0; i < eq.n; i++) {
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dbp(" %.3f = %s = 0", eq.elem[i].e->Eval(), eq.elem[i].e->Print());
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}
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dbp("%d parameters", param.n);
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for(i = 0; i < param.n; i++) {
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dbp(" param %08x at %.3f", param.elem[i].h.v, param.elem[i].val);
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} */
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param.ClearTags();
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eq.ClearTags();
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SolveBySubstitution();
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WriteJacobian(0, 0);
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EvalJacobian();
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/*
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for(i = 0; i < mat.m; i++) {
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dbp("function %d: %s", i, mat.B.sym[i]->Print());
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}
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dbp("m=%d", mat.m);
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for(i = 0; i < mat.m; i++) {
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for(j = 0; j < mat.n; j++) {
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dbp("A(%d,%d) = %.10f;", i+1, j+1, mat.A.num[i][j]);
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}
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} */
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int rank = GaussJordan();
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if(rank != mat.m) {
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FindWhichToRemoveToFixJacobian(g);
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g->solved.how = Group::SINGULAR_JACOBIAN;
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TextWindow::ReportHowGroupSolved(g->h);
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return;
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}
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/* dbp("bound states:");
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for(j = 0; j < mat.n; j++) {
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dbp(" param %08x: %d", mat.param[j], mat.bound[j]);
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} */
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bool ok = NewtonSolve(0);
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if(ok) {
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// System solved correctly, so write the new values back in to the
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// main parameter table.
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for(i = 0; i < param.n; i++) {
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Param *p = &(param.elem[i]);
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double val;
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if(p->tag == VAR_SUBSTITUTED) {
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val = param.FindById(p->substd)->val;
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} else {
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val = p->val;
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}
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Param *pp = SS.GetParam(p->h);
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pp->val = val;
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pp->known = true;
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// The main param table keeps track of what was assumed.
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pp->assumed = (p->tag == VAR_ASSUMED);
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}
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if(g->solved.how != Group::SOLVED_OKAY) {
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g->solved.how = Group::SOLVED_OKAY;
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TextWindow::ReportHowGroupSolved(g->h);
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}
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} else {
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g->solved.how = Group::DIDNT_CONVERGE;
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TextWindow::ReportHowGroupSolved(g->h);
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}
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}
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