/* tests a single evaluator function from the high-level interface */
static int
test_single_high_level(
double (*evaluator)(const gsl_spline2d *, const double, const double,
gsl_interp_accel *, gsl_interp_accel *),
int (*evaluator_e)(const gsl_spline2d *, const double, const double,
gsl_interp_accel *, gsl_interp_accel *, double *),
const gsl_spline2d * interp, const double x, const double y,
gsl_interp_accel * xa, gsl_interp_accel * ya,
const double expected_results[], size_t i)
{
if (expected_results != NULL)
{
int status;
double result = evaluator(interp, x, y, xa, ya);
gsl_test_rel(result, expected_results[i], 1e-10,
"high level %s %d", gsl_spline2d_name(interp), i);
status = evaluator_e(interp, x, y, xa, ya, &result);
if (status == GSL_SUCCESS)
{
gsl_test_rel(result, expected_results[i], 1e-10,
"high level _e %s %d", gsl_spline2d_name(interp), i);
}
}
return 0;
}
int
main()
{
double latc, rc;
double lon;
rc = 100.0 + 6371.2;
lon = 20.0;
for (latc = -90.0; latc < 90.0; latc += 1.0)
{
double latc_rad = latc * M_PI / 180.0;
double latd, altd;
double lat, r;
geo2geodetic(latc_rad,
lon * M_PI / 180.0,
rc,
&latd,
&altd);
geodetic2geo(latd, altd, &lat, &r);
gsl_test_rel(lat, latc_rad, 1.0e-7, "lat");
gsl_test_rel(r, rc, 1.0e-7, "r");
}
exit (gsl_test_summary());
}
/*
* Test the identities:
*
* Sum_{k=0}^n (n choose k) (2 y)^{n - k} H_k(x) = H_n(x + y)
*
* and
*
* Sum_{k=0}^n (n choose k) y^{n-k} He_k(x) = He_n(x + y)
*
* see: http://mathworld.wolfram.com/HermitePolynomial.html (Eq. 55)
*/
void
test_hermite_id1(const int n, const double x, const double y)
{
double *a = malloc((n + 1) * sizeof(double));
double *b = malloc((n + 1) * sizeof(double));
double lhs, rhs;
int k;
a[0] = gsl_pow_int(2.0 * y, n);
b[0] = gsl_pow_int(y, n);
for (k = 1; k <= n; ++k)
{
double fac = (n - k + 1.0) / (k * y);
a[k] = 0.5 * fac * a[k - 1];
b[k] = fac * b[k - 1];
}
lhs = gsl_sf_hermite_phys_series(n, x, a);
rhs = gsl_sf_hermite_phys(n, x + y);
gsl_test_rel(lhs, rhs, TEST_TOL4, "identity1 phys n=%d x=%g y=%g", n, x, y);
lhs = gsl_sf_hermite_prob_series(n, x, b);
rhs = gsl_sf_hermite_prob(n, x + y);
gsl_test_rel(lhs, rhs, TEST_TOL3, "identity1 prob n=%d x=%g y=%g", n, x, y);
free(a);
free(b);
}
static int
test_pontius_results(const char *str,
const gsl_vector *c, const gsl_vector *expected_c,
const gsl_vector *cov_diag, const gsl_vector *expected_sd,
const double chisq, const double chisq_res,
const double expected_chisq)
{
size_t i;
/* test coefficient vector */
for (i = 0; i < pontius_p; ++i)
{
gsl_test_rel (gsl_vector_get(c,i),
gsl_vector_get(expected_c, i),
1.0e-10,
"%s c["F_ZU"]", str, i) ;
if (cov_diag && expected_sd)
{
gsl_test_rel (sqrt(gsl_vector_get(cov_diag, i)),
gsl_vector_get(expected_sd, i),
1e-10,
"%s cov["F_ZU","F_ZU"]", str, i, i);
}
}
gsl_test_rel (chisq, expected_chisq, 1.0e-10, "%s chisq", str);
gsl_test_rel (chisq_res, expected_chisq, 1.0e-10, "%s chisq residuals", str);
return GSL_SUCCESS;
}
void
test_lmder (gsl_multifit_function_fdf * f, double x0[],
double * X, double F[], double * cov)
{
const gsl_multifit_fdfsolver_type *T;
gsl_multifit_fdfsolver *s;
const size_t n = f->n;
const size_t p = f->p;
int status;
size_t iter = 0, i;
gsl_vector_view x = gsl_vector_view_array (x0, p);
T = gsl_multifit_fdfsolver_lmsder;
s = gsl_multifit_fdfsolver_alloc (T, n, p);
gsl_multifit_fdfsolver_set (s, f, &x.vector);
do
{
status = gsl_multifit_fdfsolver_iterate (s);
for (i = 0 ; i < p; i++)
{
gsl_test_rel (gsl_vector_get (s->x, i), X[p*iter+i], 1e-5,
"lmsder, iter=%u, x%u", iter, i);
}
gsl_test_rel (gsl_blas_dnrm2 (s->f), F[iter], 1e-5,
"lmsder, iter=%u, f", iter);
iter++;
}
while (iter < 20);
{
size_t i, j;
gsl_matrix * covar = gsl_matrix_alloc (4, 4);
gsl_multifit_covar (s->J, 0.0, covar);
for (i = 0; i < 4; i++)
{
for (j = 0; j < 4; j++)
{
gsl_test_rel (gsl_matrix_get(covar,i,j), cov[i*p + j], 1e-7,
"gsl_multifit_covar cov(%d,%d)", i, j) ;
}
}
gsl_matrix_free (covar);
}
gsl_multifit_fdfsolver_free (s);
}
void
test_eigen_gensymm_results (const gsl_matrix * A,
const gsl_matrix * B,
const gsl_vector * eval,
const gsl_matrix * evec,
size_t count,
const char * desc,
const char * desc2)
{
const size_t N = A->size1;
size_t i, j;
gsl_vector * x = gsl_vector_alloc(N);
gsl_vector * y = gsl_vector_alloc(N);
gsl_vector * z = gsl_vector_alloc(N);
/* check A v = lambda B v */
for (i = 0; i < N; i++)
{
double ei = gsl_vector_get (eval, i);
gsl_vector_const_view vi = gsl_matrix_const_column(evec, i);
double norm = gsl_blas_dnrm2(&vi.vector);
/* check that eigenvector is normalized */
gsl_test_rel(norm, 1.0, N * GSL_DBL_EPSILON,
"gensymm(N=%u,cnt=%u), %s, normalized(%d), %s", N, count,
desc, i, desc2);
gsl_vector_memcpy(z, &vi.vector);
/* compute y = A z */
gsl_blas_dgemv (CblasNoTrans, 1.0, A, z, 0.0, y);
/* compute x = B z */
gsl_blas_dgemv (CblasNoTrans, 1.0, B, z, 0.0, x);
/* compute x = lambda B z */
gsl_blas_dscal(ei, x);
/* now test if y = x */
for (j = 0; j < N; j++)
{
double xj = gsl_vector_get (x, j);
double yj = gsl_vector_get (y, j);
gsl_test_rel(yj, xj, 1e9 * GSL_DBL_EPSILON,
"gensymm(N=%u,cnt=%u), %s, eigenvalue(%d,%d), real, %s", N, count, desc, i, j, desc2);
}
}
gsl_vector_free(x);
gsl_vector_free(y);
gsl_vector_free(z);
}
void
test_eigen_genherm_results (const gsl_matrix_complex * A,
const gsl_matrix_complex * B,
const gsl_vector * eval,
const gsl_matrix_complex * evec,
size_t count,
const char * desc,
const char * desc2)
{
const size_t N = A->size1;
size_t i, j;
gsl_vector_complex * x = gsl_vector_complex_alloc(N);
gsl_vector_complex * y = gsl_vector_complex_alloc(N);
/* check A v = lambda B v */
for (i = 0; i < N; i++)
{
double ei = gsl_vector_get (eval, i);
gsl_vector_complex_const_view vi =
gsl_matrix_complex_const_column(evec, i);
double norm = gsl_blas_dznrm2(&vi.vector);
/* check that eigenvector is normalized */
gsl_test_rel(norm, 1.0, N * GSL_DBL_EPSILON,
"genherm(N=%u,cnt=%u), %s, normalized(%d), %s", N, count,
desc, i, desc2);
/* compute y = A z */
gsl_blas_zgemv (CblasNoTrans, GSL_COMPLEX_ONE, A, &vi.vector, GSL_COMPLEX_ZERO, y);
/* compute x = B z */
gsl_blas_zgemv (CblasNoTrans, GSL_COMPLEX_ONE, B, &vi.vector, GSL_COMPLEX_ZERO, x);
/* compute x = lambda B z */
gsl_blas_zdscal(ei, x);
/* now test if y = x */
for (j = 0; j < N; j++)
{
gsl_complex xj = gsl_vector_complex_get (x, j);
gsl_complex yj = gsl_vector_complex_get (y, j);
gsl_test_rel(GSL_REAL(yj), GSL_REAL(xj), 1e9 * GSL_DBL_EPSILON,
"genherm(N=%u,cnt=%u), %s, eigenvalue(%d,%d), real, %s", N, count, desc, i, j, desc2);
gsl_test_abs(GSL_IMAG(yj), GSL_IMAG(xj), 1e9 * GSL_DBL_EPSILON,
"genherm(N=%u,cnt=%u), %s, eigenvalue(%d,%d), imag, %s", N, count, desc, i, j, desc2);
}
}
gsl_vector_complex_free(x);
gsl_vector_complex_free(y);
}
/* solve system with lambda = 0 and test against OLS solution */
static void
test_reg1(const gsl_matrix * X, const gsl_vector * y,
const gsl_vector * wts, const double tol,
gsl_multifit_linear_workspace * w, const char * desc)
{
const size_t n = X->size1;
const size_t p = X->size2;
double rnorm, snorm, chisq;
gsl_vector *c0 = gsl_vector_alloc(p);
gsl_vector *c1 = gsl_vector_alloc(p);
gsl_matrix *cov = gsl_matrix_alloc(p, p);
size_t j;
if (wts)
{
gsl_matrix *Xs = gsl_matrix_alloc(n, p);
gsl_vector *ys = gsl_vector_alloc(n);
gsl_multifit_wlinear(X, wts, y, c0, cov, &chisq, w);
gsl_multifit_linear_wstdform1(NULL, X, wts, y, Xs, ys, w);
gsl_multifit_linear_svd(Xs, w);
gsl_multifit_linear_solve(0.0, Xs, ys, c1, &rnorm, &snorm, w);
gsl_matrix_free(Xs);
gsl_vector_free(ys);
}
else
{
gsl_multifit_linear(X, y, c0, cov, &chisq, w);
gsl_multifit_linear_svd(X, w);
gsl_multifit_linear_solve(0.0, X, y, c1, &rnorm, &snorm, w);
}
gsl_test_rel(rnorm*rnorm, chisq, tol,
"test_reg1: %s, lambda = 0, n=%zu p=%zu chisq", desc, n, p);
/* test c0 = c1 */
for (j = 0; j < p; ++j)
{
double c0j = gsl_vector_get(c0, j);
double c1j = gsl_vector_get(c1, j);
gsl_test_rel(c1j, c0j, tol, "test_reg1: %s, lambda = 0, n=%zu p=%zu c0/c1",
desc, n, p);
}
gsl_vector_free(c0);
gsl_vector_free(c1);
gsl_matrix_free(cov);
}
static void
osborne_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
const double sumsq_exact = 5.464894697482687e-05;
const double osborne_x[osborne_P] = {
3.754100521058740e-01, GSL_NAN, GSL_NAN, GSL_NAN, GSL_NAN };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
/* only the first model parameter is uniquely constrained */
gsl_test_rel(x[0], osborne_x[0], epsrel, "%s/%s i=0",
sname, pname);
}
static int
test_COD_decomp_eps(const gsl_matrix * m, const double eps, const char *desc)
{
int s = 0;
size_t i, j, M = m->size1, N = m->size2;
size_t rank;
gsl_matrix * QRZT = gsl_matrix_alloc(M, N);
gsl_matrix * Q = gsl_matrix_alloc(M, M);
gsl_matrix * R = gsl_matrix_alloc(M, N);
gsl_matrix * QR = gsl_matrix_alloc(M, N);
gsl_matrix * Z = gsl_matrix_alloc(N, N);
gsl_vector * tau_Q = gsl_vector_alloc(GSL_MIN(M, N));
gsl_vector * tau_Z = gsl_vector_alloc(GSL_MIN(M, N));
gsl_vector * work = gsl_vector_alloc(N);
gsl_matrix * lhs = gsl_matrix_alloc(M, N);
gsl_matrix * rhs = gsl_matrix_alloc(M, N);
gsl_permutation * perm = gsl_permutation_alloc(N);
gsl_matrix_memcpy(QRZT, m);
s += gsl_linalg_COD_decomp(QRZT, tau_Q, tau_Z, perm, &rank, work);
s += gsl_linalg_COD_unpack(QRZT, tau_Q, tau_Z, rank, Q, R, Z);
/* compute lhs = m P */
gsl_matrix_memcpy(lhs, m);
gsl_permute_matrix(perm, lhs);
/* compute rhs = Q R Z^T */
gsl_blas_dgemm (CblasNoTrans, CblasNoTrans, 1.0, Q, R, 0.0, QR);
gsl_blas_dgemm (CblasNoTrans, CblasTrans, 1.0, QR, Z, 0.0, rhs);
for (i = 0; i < M; i++)
{
for (j = 0; j < N; j++)
{
double aij = gsl_matrix_get(rhs, i, j);
double bij = gsl_matrix_get(lhs, i, j);
gsl_test_rel(aij, bij, eps, "%s (%3lu,%3lu)[%lu,%lu]: %22.18g %22.18g\n",
desc, M, N, i, j, aij, bij);
}
}
gsl_permutation_free (perm);
gsl_vector_free(work);
gsl_vector_free(tau_Q);
gsl_vector_free(tau_Z);
gsl_matrix_free(QRZT);
gsl_matrix_free(lhs);
gsl_matrix_free(rhs);
gsl_matrix_free(QR);
gsl_matrix_free(Q);
gsl_matrix_free(R);
gsl_matrix_free(Z);
return s;
}
static void
powell1_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < powell1_P; ++i)
{
gsl_test_rel(x[i], 0.0, epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
lin1_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = (double) (lin1_N - lin1_P);
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < lin1_P; ++i)
{
gsl_test_rel(x[i], -1.0, epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
static void
rosenbrock_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < rosenbrock_P; ++i)
{
gsl_test_rel(x[i], 1.0, epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
void
test_bspline(gsl_bspline_workspace * bw, gsl_bspline_deriv_workspace * dbw)
{
gsl_vector *B;
gsl_matrix *dB;
size_t i, j;
size_t n = 100;
size_t ncoeffs = gsl_bspline_ncoeffs(bw);
size_t order = gsl_bspline_order(bw);
size_t nbreak = gsl_bspline_nbreak(bw);
double a = gsl_bspline_breakpoint(0, bw);
double b = gsl_bspline_breakpoint(nbreak - 1, bw);
B = gsl_vector_alloc(ncoeffs);
dB = gsl_matrix_alloc(ncoeffs, 1);
/* Ensure B-splines form a partition of unity */
for (i = 0; i < n; i++)
{
double xi = a + (b - a) * (i / (n - 1.0));
double sum = 0;
gsl_bspline_eval(xi, B, bw);
for (j = 0; j < ncoeffs; j++)
{
double Bj = gsl_vector_get(B, j);
int s = (Bj < 0 || Bj > 1);
gsl_test(s,
"basis-spline coefficient %u is in range [0,1] for x=%g",
j, xi);
sum += Bj;
}
gsl_test_rel(sum, 1.0, order * GSL_DBL_EPSILON,
"basis-spline order %u is normalized for x=%g", order,
xi);
}
/* Ensure B-splines 0th derivatives agree with regular evaluation */
for (i = 0; i < n; i++)
{
double xi = a + (b - a) * (i / (n - 1.0));
gsl_bspline_eval(xi, B, bw);
gsl_bspline_deriv_eval(xi, 0, dB, bw, dbw);
for (j = 0; j < ncoeffs; j++)
{
gsl_test_abs(gsl_matrix_get(dB, j, 0), gsl_vector_get(B, j),
GSL_DBL_EPSILON,
"b-spline order %d basis #%d evaluation and 0th derivative consistent for x=%g",
order, j, xi);
}
}
gsl_vector_free(B);
gsl_matrix_free(dB);
}
static void
brown2_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
double sumsq_exact;
double alpha;
const double p = (double) brown2_P;
double alpha1mp, lhs, lastel;
if (sumsq < 0.5)
{
/* sumsq = 0 case */
sumsq_exact = 0.0;
alpha = x[0];
alpha1mp = pow(alpha, 1.0 - p);
lhs = p*pow(alpha, p) - (p + 1)/alpha1mp;
lastel = alpha1mp;
gsl_test_rel(lhs, -1.0, epsrel, "%s/%s alpha lhs",
sname, pname);
}
else
{
/* sumsq = 1 case */
sumsq_exact = 1.0;
alpha = 0.0;
lastel = p + 1.0;
}
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 1; i < brown2_P - 1; ++i)
{
gsl_test_rel(x[i], alpha, epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
gsl_test_rel(x[brown2_P - 1], lastel, epsrel, "%s/%s last element",
sname, pname);
}
static void
brown3_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
const double brown3_x[brown3_P] = { 1.0e6, 2.0e-6 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < brown3_P; ++i)
{
gsl_test_rel(x[i], brown3_x[i], epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
static void
exp1_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 1.0e-2;
const double exp1_x[exp1_P] = { -4.0, -5.0, 4.0, -4.0 }; /* approx */
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < exp1_P; ++i)
{
gsl_test_rel(x[i], exp1_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
beale_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
const double beale_x[beale_P] = { 3.0, 0.5 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < beale_P; ++i)
{
gsl_test_rel(x[i], beale_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
wood_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
const double wood_x[wood_P] = { 1.0, 1.0, 1.0, 1.0 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < wood_P; ++i)
{
gsl_test_rel(x[i], wood_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
kowalik_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
gsl_vector_const_view v = gsl_vector_const_view_array(x, kowalik_P);
const double norm = gsl_blas_dnrm2(&v.vector);
const double sumsq_exact1 = 3.075056038492370e-04;
const double kowalik_x1[kowalik_P] = { 1.928069345723978e-01,
1.912823290344599e-01,
1.230565070690708e-01,
1.360623308065148e-01 };
const double sumsq_exact2 = 0.00102734304869549252;
const double kowalik_x2[kowalik_P] = { GSL_NAN, /* inf */
-14.0758834005984603,
GSL_NAN, /* -inf */
GSL_NAN }; /* -inf */
const double *kowalik_x;
double sumsq_exact;
if (norm < 10.0)
{
kowalik_x = kowalik_x1;
sumsq_exact = sumsq_exact1;
}
else
{
kowalik_x = kowalik_x2;
sumsq_exact = sumsq_exact2;
}
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < kowalik_P; ++i)
{
if (!gsl_finite(kowalik_x[i]))
continue;
gsl_test_rel(x[i], kowalik_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
powell3_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 0.0;
const double powell3_x[powell3_P] = { 1.09815932969975976e-05,
9.10614673986700218 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < powell3_P; ++i)
{
gsl_test_rel(x[i], powell3_x[i], epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
static void
penalty2_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
const double sumsq_exact = 9.37629300735544219e-06;
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
}
static void
boxbod_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 1.1680088766E+03;
const double boxbod_x[boxbod_P] = { 2.1380940889E+02,
5.4723748542E-01 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < boxbod_P; ++i)
{
gsl_test_rel(x[i], boxbod_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
gaussian_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 1.12793276961871985e-08;
const double gaussian_x[gaussian_P] = { 0.398956137838762825,
1.00001908448786647,
0.0 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < gaussian_P; ++i)
{
gsl_test_rel(x[i], gaussian_x[i], epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
static void
kirby2_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 3.9050739624E+00;
const double kirby2_x[kirby2_P] = {
1.6745063063E+00, -1.3927397867E-01, 2.5961181191E-03,
-1.7241811870E-03, 2.1664802578E-05 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < kirby2_P; ++i)
{
gsl_test_rel(x[i], kirby2_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
wnlin_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 29.7481259665713758;
const double wnlin_x[wnlin_P] = { 5.17378551196259195,
0.111041758006851149,
1.05282724070446099 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < wnlin_P; ++i)
{
gsl_test_rel(x[i], wnlin_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
eckerle_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 1.4635887487E-03;
const double eckerle_x[eckerle_P] = { 1.5543827178E+00,
4.0888321754E+00,
4.5154121844E+02 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < eckerle_P; ++i)
{
gsl_test_rel(x[i], eckerle_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
void
test_eigenvalues_complex (const gsl_vector_complex * eval,
const gsl_vector_complex * eval2,
const char * desc, const char * desc2)
{
const size_t N = eval->size;
size_t i;
for (i = 0; i < N; i++)
{
gsl_complex ei = gsl_vector_complex_get (eval, i);
gsl_complex e2i = gsl_vector_complex_get (eval2, i);
gsl_test_rel(GSL_REAL(ei), GSL_REAL(e2i), 10*N*GSL_DBL_EPSILON,
"%s, direct eigenvalue(%d) real, %s",
desc, i, desc2);
gsl_test_rel(GSL_IMAG(ei), GSL_IMAG(e2i), 10*N*GSL_DBL_EPSILON,
"%s, direct eigenvalue(%d) imag, %s",
desc, i, desc2);
}
}
static void
rat42_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 8.0565229338E+00;
const double rat42_x[rat42_P] = { 7.2462237576E+01,
2.6180768402E+00,
6.7359200066E-02 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < rat42_P; ++i)
{
gsl_test_rel(x[i], rat42_x[i], epsrel, "%s/%s i="F_ZU,
sname, pname, i);
}
}
static void
meyer_checksol(const double x[], const double sumsq,
const double epsrel, const char *sname,
const char *pname)
{
size_t i;
const double sumsq_exact = 8.794585517053883e+01;
const double meyer_x[meyer_P] = { 5.609636471049458e-03,
6.181346346283188e+03,
3.452236346240292e+02 };
gsl_test_rel(sumsq, sumsq_exact, epsrel, "%s/%s sumsq",
sname, pname);
for (i = 0; i < meyer_P; ++i)
{
gsl_test_rel(x[i], meyer_x[i], epsrel, "%s/%s i=%zu",
sname, pname, i);
}
}
