#include static void /* sum coefficients less than res */ eval(projUV **w, int nu, int nv, double res, projUV *resid) { int i, j; double ab; projUV *s; resid->u = resid->v = 0.; for (i = 0; i < nu; ++i) for (s = w[i], j = 0; j < nv; ++j, ++s) { if ((ab = fabs(s->u)) < res) resid->u += ab; if ((ab = fabs(s->v)) < res) resid->v += ab; } } static Tseries * /* create power series structure */ makeT(int nru, int nrv) { Tseries *T; int i; if ((T = (Tseries *)pj_malloc(sizeof(Tseries))) && (T->cu = (struct PW_COEF *)pj_malloc( sizeof(struct PW_COEF) * nru)) && (T->cv = (struct PW_COEF *)pj_malloc( sizeof(struct PW_COEF) * nrv))) { for (i = 0; i < nru; ++i) T->cu[i].c = 0; for (i = 0; i < nrv; ++i) T->cv[i].c = 0; return T; } else return 0; } Tseries * mk_cheby(projUV a, projUV b, double res, projUV *resid, projUV (*func)(projUV), int nu, int nv, int power) { int j, i, nru, nrv, *ncu, *ncv; Tseries *T = NULL; projUV **w; double cutres; if (!(w = (projUV **)vector2(nu, nv, sizeof(projUV))) || !(ncu = (int *)vector1(nu + nv, sizeof(int)))) return 0; ncv = ncu + nu; if (!bchgen(a, b, nu, nv, w, func)) { projUV *s; double ab, *p; /* analyse coefficients and adjust until residual OK */ cutres = res; for (i = 4; i ; --i) { eval(w, nu, nv, cutres, resid); if (resid->u < res && resid->v < res) break; cutres *= 0.5; } if (i <= 0) /* warn of too many tries */ resid->u = - resid->u; /* apply cut resolution and set pointers */ nru = nrv = 0; for (j = 0; j < nu; ++j) { ncu[j] = ncv[j] = 0; /* clear column maxes */ for (s = w[j], i = 0; i < nv; ++i, ++s) { if ((ab = fabs(s->u)) < cutres) /* < resolution ? */ s->u = 0.; /* clear coefficient */ else ncu[j] = i + 1; /* update column max */ if ((ab = fabs(s->v)) < cutres) /* same for v coef's */ s->v = 0.; else ncv[j] = i + 1; } if (ncu[j]) nru = j + 1; /* update row max */ if (ncv[j]) nrv = j + 1; } if (power) { /* convert to bivariate power series */ if (!bch2bps(a, b, w, nu, nv)) goto error; /* possible change in some row counts, so readjust */ nru = nrv = 0; for (j = 0; j < nu; ++j) { ncu[j] = ncv[j] = 0; /* clear column maxes */ for (s = w[j], i = 0; i < nv; ++i, ++s) { if (s->u) ncu[j] = i + 1; /* update column max */ if (s->v) ncv[j] = i + 1; } if (ncu[j]) nru = j + 1; /* update row max */ if (ncv[j]) nrv = j + 1; } if ((T = makeT(nru, nrv)) != NULL ) { T->a = a; T->b = b; T->mu = nru - 1; T->mv = nrv - 1; T->power = 1; for (i = 0; i < nru; ++i) /* store coefficient rows for u */ { if ((T->cu[i].m = ncu[i]) != 0) { if ((p = T->cu[i].c = (double *)pj_malloc(sizeof(double) * ncu[i]))) for (j = 0; j < ncu[i]; ++j) *p++ = (w[i] + j)->u; else goto error; } } for (i = 0; i < nrv; ++i) /* same for v */ { if ((T->cv[i].m = ncv[i]) != 0) { if ((p = T->cv[i].c = (double *)pj_malloc(sizeof(double) * ncv[i]))) for (j = 0; j < ncv[i]; ++j) *p++ = (w[i] + j)->v; else goto error; } } } } else if ((T = makeT(nru, nrv)) != NULL) { /* else make returned Chebyshev coefficient structure */ T->mu = nru - 1; /* save row degree */ T->mv = nrv - 1; T->a.u = a.u + b.u; /* set argument scaling */ T->a.v = a.v + b.v; T->b.u = 1. / (b.u - a.u); T->b.v = 1. / (b.v - a.v); T->power = 0; for (i = 0; i < nru; ++i) /* store coefficient rows for u */ { if ((T->cu[i].m = ncu[i]) != 0) { if ((p = T->cu[i].c = (double *)pj_malloc(sizeof(double) * ncu[i]))) for (j = 0; j < ncu[i]; ++j) *p++ = (w[i] + j)->u; else goto error; } } for (i = 0; i < nrv; ++i) /* same for v */ { if ((T->cv[i].m = ncv[i]) != 0) { if ((p = T->cv[i].c = (double *)pj_malloc(sizeof(double) * ncv[i]))) for (j = 0; j < ncv[i]; ++j) *p++ = (w[i] + j)->v; else goto error; } } } else goto error; } goto gohome; error: if (T) { /* pj_dalloc up possible allocations */ for (i = 0; i <= T->mu; ++i) if (T->cu[i].c) pj_dalloc(T->cu[i].c); for (i = 0; i <= T->mv; ++i) if (T->cv[i].c) pj_dalloc(T->cv[i].c); pj_dalloc(T); } T = 0; gohome: freev2((void **) w, nu); pj_dalloc(ncu); return T; }