int AllSubsetsMetaAnalysis(gsl_vector * esVector, gsl_vector * varVector,
gsl_vector * metaResultsVector, ST_uint4 from, ST_uint4 to ) {
ST_retcode rc;
ST_uint4 i, nStudies;
ST_long j, nSubsets;
char buf[80];
gsl_combination * comb;
nStudies = esVector->size;
nSubsets = gsl_pow_int(2, nStudies)-1 ;
j=1;
//for(i=1; i <= nStudies; i++) {
for(i=from; i <= to; i++) {
comb = gsl_combination_calloc(nStudies, i);
do {
if(j == nSubsets+1) {
snprintf(buf, 80,"combLength %u Obs %u\n",i, j);
SF_error(buf);
SF_error("Exceeded the maximum number of subsets!!!\n");
return(-2);
}
if ((rc = MetaAnalysis(esVector, varVector, metaResultsVector, comb) )) return(rc);
if ((rc = WriteOut(metaResultsVector, j, comb) )) return(rc);
j += 1;
} while (gsl_combination_next(comb) == GSL_SUCCESS);
}
gsl_combination_free(comb);
return(0);
}
static VALUE rb_gsl_combination_calloc(VALUE klass, VALUE n, VALUE k)
{
gsl_combination *c = NULL;
CHECK_FIXNUM(n);CHECK_FIXNUM(k);
c = gsl_combination_calloc(FIX2INT(n), FIX2INT(k));
return Data_Wrap_Struct(klass, 0, gsl_combination_free, c);
}
int
main (void)
{
size_t i, j;
int status = 0;
gsl_combination * c ;
c = gsl_combination_alloc (6,3);
gsl_combination_init_first (c);
i = 0;
do
{
if ( i >= 20 )
{
status = 1;
break;
}
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[i][j]);
}
i++;
}
while (gsl_combination_next(c) == GSL_SUCCESS);
gsl_test(status, "gsl_combination_next, 6 choose 3 combination, 20 steps");
gsl_combination_next(c);
gsl_combination_next(c);
gsl_combination_next(c);
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[19][j]);
}
gsl_test(status, "gsl_combination_next on the last combination");
gsl_combination_init_last (c);
i = 20;
do
{
if ( i == 0 )
{
status = 1;
break;
}
i--;
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[i][j]);
}
}
while (gsl_combination_prev(c) == GSL_SUCCESS);
gsl_test(status, "gsl_combination_prev, 6 choose 3 combination, 20 steps");
gsl_combination_prev(c);
gsl_combination_prev(c);
gsl_combination_prev(c);
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[0][j]);
}
gsl_test(status, "gsl_combination_prev on the first combination");
gsl_combination_free (c);
c = gsl_combination_calloc(7, 0);
/* should return GSL_FAILURE every time */
status |= (gsl_combination_next(c) != GSL_FAILURE);
status |= (gsl_combination_next(c) != GSL_FAILURE);
status |= (gsl_combination_prev(c) != GSL_FAILURE);
status |= (gsl_combination_prev(c) != GSL_FAILURE);
gsl_test(status, "gsl_combination 7 choose 0");
gsl_combination_free (c);
c = gsl_combination_calloc(7, 7);
/* should return GSL_FAILURE every time */
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_next(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_next(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_prev(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_prev(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
gsl_test(status, "gsl_combination 7 choose 7");
gsl_combination_free (c);
exit (gsl_test_summary());
}
int
main (void)
{
size_t i, j;
int status = 0, s;
gsl_combination * c ;
gsl_ieee_env_setup ();
c = gsl_combination_alloc (6,3);
/* Test combinations in forward order */
gsl_combination_init_first (c);
i = 0;
do
{
if ( i >= 20 )
{
status = 1;
break;
}
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[i][j]);
}
{
int s1 = gsl_combination_valid (c);
gsl_test (s1, "gsl_combination_valid (%u)", i);
}
i++;
}
while (gsl_combination_next(c) == GSL_SUCCESS);
gsl_test(status, "gsl_combination_next, 6 choose 3 combination, 20 steps");
gsl_combination_next(c);
gsl_combination_next(c);
gsl_combination_next(c);
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[19][j]);
}
gsl_test(status, "gsl_combination_next on the last combination");
{
int s1 = gsl_combination_valid (c);
gsl_test (s1, "gsl_combination_valid on the last combination");
}
{
gsl_combination * d = gsl_combination_alloc (6,3);
gsl_combination_memcpy (d, c);
status = 0;
for (j = 0; j < 3; j++)
{
status |= (d->data[j] != c->data[j]);
}
gsl_test (status, "gsl_combination_memcpy, 6 choose 3 combination");
gsl_combination_free(d);
}
/* Now test combinations in reverse order */
gsl_combination_init_last (c);
i = 20;
do
{
if ( i == 0 )
{
status = 1;
break;
}
i--;
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[i][j]);
}
{
int s1 = gsl_combination_valid (c);
gsl_test (s1, "gsl_combination_valid (%u)", i);
}
}
while (gsl_combination_prev(c) == GSL_SUCCESS);
gsl_test(status, "gsl_combination_prev, 6 choose 3 combination, 20 steps");
gsl_combination_prev(c);
gsl_combination_prev(c);
gsl_combination_prev(c);
for (j = 0; j < 3; j++)
{
status |= (c->data[j] != c63[0][j]);
}
gsl_test(status, "gsl_combination_prev on the first combination");
{
int s1 = gsl_combination_valid (c);
gsl_test (s1, "gsl_combination_valid on the first combination");
}
{
gsl_combination * d = gsl_combination_alloc (6,3);
gsl_combination_memcpy (d, c);
status = 0;
for (j = 0; j < 3; j++)
{
status |= (d->data[j] != c->data[j]);
}
gsl_test (status, "gsl_combination_memcpy, 6 choose 3 combination");
gsl_combination_free(d);
}
gsl_combination_free (c);
c = gsl_combination_calloc(7, 0);
/* should return GSL_FAILURE every time */
status |= (gsl_combination_next(c) != GSL_FAILURE);
status |= (gsl_combination_next(c) != GSL_FAILURE);
status |= (gsl_combination_prev(c) != GSL_FAILURE);
status |= (gsl_combination_prev(c) != GSL_FAILURE);
gsl_test(status, "gsl_combination 7 choose 0");
gsl_combination_free (c);
c = gsl_combination_calloc(7, 7);
/* should return GSL_FAILURE every time */
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_next(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_next(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_prev(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
status |= (gsl_combination_prev(c) != GSL_FAILURE);
for(j = 0; j < 7; j++)
{
status |= (gsl_combination_get(c, j) != j);
}
gsl_test(status, "gsl_combination 7 choose 7");
gsl_combination_free (c);
c = gsl_combination_calloc(6, 3);
gsl_set_error_handler (&my_error_handler);
c->data[0] = 1;
c->data[1] = 1;
c->data[2] = 2;
s = gsl_combination_valid (c);
gsl_test (!s, "gsl_combination_valid on an invalid combination (1,1,2)");
c->data[0] = 2;
c->data[1] = 1;
c->data[2] = 0;
s = gsl_combination_valid (c);
gsl_test (!s, "gsl_combination_valid on an invalid combination (2,1,0)");
c->data[0] = 1;
c->data[1] = 2;
c->data[2] = 0;
s = gsl_combination_valid (c);
gsl_test (!s, "gsl_combination_valid on an invalid combination (1,2,0)");
{
gsl_combination * d = gsl_combination_alloc (6,4);
int s = gsl_combination_memcpy (d, c);
gsl_test (!s, "gsl_combination_memcpy, (6,4) vs (6,3)");
gsl_combination_free(d);
}
{
gsl_combination * d = gsl_combination_alloc (7,3);
int s = gsl_combination_memcpy (d, c);
gsl_test (!s, "gsl_combination_memcpy, (7,3) vs (6,3)");
gsl_combination_free(d);
}
{
gsl_combination * d = gsl_combination_alloc (7,2);
int s = gsl_combination_memcpy (d, c);
gsl_test (!s, "gsl_combination_memcpy, (7,2) vs (6,3)");
gsl_combination_free(d);
}
gsl_combination_free (c);
exit (gsl_test_summary());
}
}
DEFAPI(void) defGslComb(CTX ctx, kclass_t cid, kclassdef_t *cdef)
{
cdef->name = "GslComb";
cdef->init = GslComb_init;
cdef->free = GslComb_free;
}
//## @Native GslComb GslComb.new(int n, int k);
KMETHOD GslComb_new(CTX ctx, ksfp_t *sfp _RIX)
{
size_t n = Int_to(size_t, sfp[1]);
size_t k = Int_to(size_t, sfp[2]);
kRawPtr *p = sfp[0].p;
p->rawptr = gsl_combination_calloc(n, k);
RETURN_(p);
}
//## @Native void GslComb.initFirst();
KMETHOD GslComb_initFirst(CTX ctx, ksfp_t *sfp _RIX)
{
gsl_combination *c = RawPtr_to(gsl_combination *, sfp[0]);
gsl_combination_init_first(c);
RETURNvoid_();
}
//## @Native void GslComb.initLast();
KMETHOD GslComb_initLast(CTX ctx, ksfp_t *sfp _RIX)
{
gsl_combination *c = RawPtr_to(gsl_combination *, sfp[0]);
