netcdf-c/libdap2/cdf3.c

804 lines
24 KiB
C

/*********************************************************************
* Copyright 1993, UCAR/Unidata
* See netcdf/COPYRIGHT file for copying and redistribution conditions.
* $Header: /upc/share/CVS/netcdf-3/libncdap3/cdf3.c,v 1.33 2009/12/03 03:42:37 dmh Exp $
*********************************************************************/
#include "ncdap3.h"
#include "daputil.h"
#include "dapdump.h"
#ifdef DAPDEBUG
extern char* ocfqn(OCddsnode);
#endif
CDFnode* v4node = NULL;
/* Forward*/
static NCerror sequencecheck3r(CDFnode* node, NClist* vars, CDFnode* topseq);
static NCerror restruct3r(CDFnode*, CDFnode*, NClist*);
static NCerror repairgrids(NClist*);
static NCerror structwrap3(CDFnode*, CDFnode*, int, CDFnode*, int);
static int findin(CDFnode* parent, CDFnode* child);
static CDFnode* makenewstruct3(CDFnode* node, CDFnode* template);
static NCerror mapnodes3r(CDFnode*, CDFnode*, int depth);
static NCerror mapfcn(CDFnode* dstnode, CDFnode* srcnode);
static NCerror definedimsetplus3(NCDAPCOMMON* nccomm, CDFnode* node);
static NCerror definedimsetall3(NCDAPCOMMON* nccomm, CDFnode* node);
static NCerror definedimsetall3(NCDAPCOMMON* nccomm, CDFnode* node);
static NCerror definedimsettrans3(NCDAPCOMMON* nccomm, CDFnode* node);
/* Accumulate useful node sets */
NCerror
computecdfnodesets3(NCDAPCOMMON* nccomm, CDFtree* tree)
{
unsigned int i;
NClist* varnodes;
NClist* allnodes;
allnodes = tree->nodes;
varnodes = nclistnew();
if(tree->seqnodes == NULL) tree->seqnodes = nclistnew();
if(tree->gridnodes == NULL) tree->gridnodes = nclistnew();
nclistclear(tree->seqnodes);
nclistclear(tree->gridnodes);
computevarnodes3(nccomm,allnodes,varnodes);
nclistfree(tree->varnodes);
tree->varnodes = varnodes;
varnodes = NULL;
/* Now compute other sets of interest */
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* node = (CDFnode*)nclistget(allnodes,i);
switch (node->nctype) {
case NC_Sequence:
nclistpush(tree->seqnodes,(void*)node);
break;
case NC_Grid:
nclistpush(tree->gridnodes,(void*)node);
break;
default: break;
}
}
return NC_NOERR;
}
NCerror
computevarnodes3(NCDAPCOMMON* nccomm, NClist* allnodes, NClist* varnodes)
{
unsigned int i,len;
NClist* allvarnodes = nclistnew();
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* node = (CDFnode*)nclistget(allnodes,i);
#if 0
/* If this node has a bad name, repair it */
if(dap_badname(node->ocname)) {
char* newname = dap_repairname(node->ocname);
nullfree(node->ocname);
node->ocname = newname;
}
#endif
if(node->nctype == NC_Atomic)
nclistpush(allvarnodes,(void*)node);
}
/* Further process the variable nodes to get the final set */
/* Use toplevel vars first */
len = nclistlength(allvarnodes);
for(i=0;i<len;i++) {
CDFnode* node = (CDFnode*)nclistget(allvarnodes,i);
if(node == NULL) continue;
if(daptoplevel(node)) {
nclistpush(varnodes,(void*)node);
nclistset(allvarnodes,i,(void*)NULL);
}
}
/*... then grid arrays and maps.
but exclude the coordinate variables if we are trying to
exactly mimic nc-dap
*/
for(i=0;i<len;i++) {
CDFnode* node = (CDFnode*)nclistget(allvarnodes,i);
if(node == NULL) continue;
if(dapgridarray(node)) {
nclistpush(varnodes,(void*)node);
nclistset(allvarnodes,i,(void*)NULL);
} else if(dapgridmap(node)) {
if(!FLAGSET(nccomm->controls,NCF_NCDAP))
nclistpush(varnodes,(void*)node);
nclistset(allvarnodes,i,(void*)NULL);
}
}
/*... then all others */
for(i=0;i<len;i++) {
CDFnode* node = (CDFnode*)nclistget(allvarnodes,i);
if(node == NULL) continue;
nclistpush(varnodes,(void*)node);
}
nclistfree(allvarnodes);
#ifdef DEBUG2
for(i=0;i<nclistlength(varnodes);i++) {
CDFnode* node = (CDFnode*)nclistget(varnodes,i);
if(node == NULL) continue;
fprintf(stderr,"computevarnodes: var: %s\n",makecdfpathstring3(node,"."));
}
#endif
return NC_NOERR;
}
NCerror
fixgrids3(NCDAPCOMMON* nccomm)
{
unsigned int i;
NClist* gridnodes = nccomm->cdf.ddsroot->tree->gridnodes;
for(i=0;i<nclistlength(gridnodes);i++) {
CDFnode* grid = (CDFnode*)nclistget(gridnodes,i);
(void)fixgrid34(nccomm,grid);
/* Ignore mal-formed grids */
}
return NC_NOERR;
}
/*
Figure out the names for variables.
*/
NCerror
computecdfvarnames3(NCDAPCOMMON* nccomm, CDFnode* root, NClist* varnodes)
{
unsigned int i,j,d;
/* clear all elided marks; except for dataset and grids */
for(i=0;i<nclistlength(root->tree->nodes);i++) {
CDFnode* node = (CDFnode*)nclistget(root->tree->nodes,i);
node->elided = 0;
if(node->nctype == NC_Grid || node->nctype == NC_Dataset)
node->elided = 1;
}
/* ensure all variables have an initial full name defined */
for(i=0;i<nclistlength(varnodes);i++) {
CDFnode* var = (CDFnode*)nclistget(varnodes,i);
nullfree(var->ncfullname);
var->ncfullname = makecdfpathstring3(var,nccomm->cdf.separator);
#ifdef DEBUG2
fprintf(stderr,"var names: %s %s %s\n",
var->ocname,var->ncbasename,var->ncfullname);
#endif
}
/* unify all variables with same fullname and dimensions
basevar fields says: "for duplicate grid variables";
when does this happen?
*/
if(FLAGSET(nccomm->controls,NCF_NC3)) {
for(i=0;i<nclistlength(varnodes);i++) {
int match;
CDFnode* var = (CDFnode*)nclistget(varnodes,i);
for(j=0;j<i;j++) {
CDFnode* testnode = (CDFnode*)nclistget(varnodes,j);
match = 1;
if(testnode->array.basevar != NULL)
continue; /* already processed */
if(strcmp(var->ncfullname,testnode->ncfullname) != 0)
match = 0;
else if(nclistlength(testnode->array.dimsetall)
!= nclistlength(var->array.dimsetall))
match = 0;
else for(d=0;d<nclistlength(testnode->array.dimsetall);d++) {
CDFnode* vdim = (CDFnode*)nclistget(var->array.dimsetall,d);
CDFnode* tdim = (CDFnode*)nclistget(testnode->array.dimsetall,d);
if(vdim->dim.declsize != tdim->dim.declsize) {
match = 0;
break;
}
}
if(match) {
testnode->array.basevar = var;
fprintf(stderr,"basevar invoked: %s\n",var->ncfullname);
}
}
}
}
/* Finally, verify unique names */
for(i=0;i<nclistlength(varnodes);i++) {
CDFnode* var1 = (CDFnode*)nclistget(varnodes,i);
if(var1->array.basevar != NULL) continue;
for(j=0;j<i;j++) {
CDFnode* var2 = (CDFnode*)nclistget(varnodes,j);
if(var2->array.basevar != NULL) continue;
if(strcmp(var1->ncfullname,var2->ncfullname)==0) {
PANIC1("duplicate var names: %s",var1->ncfullname);
}
}
}
return NC_NOERR;
}
/* locate and connect usable sequences and vars.
A sequence is usable iff:
1. it has a path from one of its subnodes to a leaf and that
path does not contain a sequence.
2. No parent container has dimensions.
*/
NCerror
sequencecheck3(NCDAPCOMMON* nccomm)
{
(void)sequencecheck3r(nccomm->cdf.ddsroot,
nccomm->cdf.ddsroot->tree->varnodes,NULL);
return NC_NOERR;
}
static NCerror
sequencecheck3r(CDFnode* node, NClist* vars, CDFnode* topseq)
{
unsigned int i;
NCerror err = NC_NOERR;
int ok = 0;
if(topseq == NULL && nclistlength(node->array.dimset0) > 0) {
err = NC_EINVAL; /* This container has dimensions, so no sequence within it
can be usable */
} else if(node->nctype == NC_Sequence) {
/* Recursively walk the path for each subnode of this sequence node
looking for a path without any sequence */
for(i=0;i<nclistlength(node->subnodes);i++) {
CDFnode* sub = (CDFnode*)nclistget(node->subnodes,i);
err = sequencecheck3r(sub,vars,node);
if(err == NC_NOERR) ok = 1; /* there is at least 1 usable var below */
}
if(topseq == NULL && ok == 1) {
/* this sequence is usable because it has scalar container
(by construction) and has a path to a leaf without an intermediate
sequence. */
err = NC_NOERR;
node->usesequence = 1;
} else {
/* this sequence is unusable because it has no path
to a leaf without an intermediate sequence. */
node->usesequence = 0;
err = NC_EINVAL;
}
} else if(nclistcontains(vars,(void*)node)) {
/* If we reach a leaf, then topseq is usable, so save it */
node->array.sequence = topseq;
} else { /* Some kind of non-sequence container node with no dimensions */
/* recursively compute usability */
for(i=0;i<nclistlength(node->subnodes);i++) {
CDFnode* sub = (CDFnode*)nclistget(node->subnodes,i);
err = sequencecheck3r(sub,vars,topseq);
if(err == NC_NOERR) ok = 1;
}
err = (ok?NC_NOERR:NC_EINVAL);
}
return err;
}
/*
Originally, if one did a constraint on a Grid such that only
one array or map in the grid was returned, that element was
returned as a top level variable. This is incorrect because
it loses the Grid scope information.
Eventually, this behavior was changed so that such partial
grids are converted to structures where the structure name
is the grid name. This preserves the proper scoping.
However, it is still the case that some servers do the old
behavior.
The rules that most old-style servers appear to adhere to are these.
1. Asking for just a grid array or a single grid map
returns just the array not wrapped in a structure.
2. Asking for a subset of the fields (array plus map) of a grid
returns those fields wrapped in a structure.
3. However, there is an odd situation: asking for a grid array
plus any subset of maps that includes the last map in the grid
returns a malformed grid. This is clearly a bug.
For case 1, we insert a structure node so that case 1 is consistent
with case 2. Case 3 should cause an error with a malformed grid.
[Note: for some reason, this code has been difficult to get right;
I have rewritten 6 times and it probably is still not right.]
[2/25/2013 Sigh! Previous fixes have introducted another bug,
so now we fix the fix.]
Input is
(1) the root of the dds that needs to be re-gridded
(2) the full datadds tree that defines where the grids are.
(3) the projections that were used to produce (1) from (2).
*/
NCerror
restruct3(CDFnode* ddsroot, CDFnode* template, NClist* projections)
{
NCerror ncstat = NC_NOERR;
NClist* repairs = nclistnew();
/* The current restruct assumes that the ddsroot tree
has missing grids compared to the template.
It is also assumed that order of the nodes
in the ddsroot is the same as in the template.
*/
if(ddsroot->tree->restructed) return NC_NOERR;
#ifdef DEBUG
fprintf(stderr,"restruct: ddsroot=%s\n",dumptree(ddsroot));
fprintf(stderr,"restruct: template=%s\n",dumptree(template));
#endif
/* Match roots */
if(!simplenodematch34(ddsroot,template))
ncstat = NC_EDATADDS;
else if(!restruct3r(ddsroot,template,repairs))
ncstat = NC_EDATADDS;
else if(nclistlength(repairs) > 0) {
/* Do the repairs */
ncstat = repairgrids(repairs);
}
if(repairs)
nclistfree(repairs);
return THROW(ncstat);
}
/*
Locate nodes in the tree rooted at node
that correspond to a single grid field in the template
when the template is a grid.
Wrap that grid field in a synthesized structure.
The key thing to look for is the case where
we have an atomic variable that appear where
we expected a grid.
*/
static int
restruct3r(CDFnode* parentnode, CDFnode* templateparent, NClist* repairlist)
{
int index, i, j, match;
#ifdef DEBUG
fprintf(stderr,"restruct: matched: %s -> %s\n",
ocfqn(parentnode->ocnode),ocfqn(templateparent->ocnode));
#endif
/* walk each node child and locate its match
in the template's children; recurse on matches,
non-matches may be nodes needing wrapping.
*/
for(index=0;index<nclistlength(parentnode->subnodes);index++) {
CDFnode* subnode = (CDFnode*)nclistget(parentnode->subnodes,index);
CDFnode* matchnode = NULL;
/* Look for a matching template node with same ocname */
for(i=0;i<nclistlength(templateparent->subnodes);i++) {
CDFnode* subtemp = (CDFnode*)nclistget(templateparent->subnodes,i);
if(strcmp(subnode->ocname,subtemp->ocname) == 0) {
matchnode = subtemp;
break;
}
}
#ifdef DEBUG
fprintf(stderr,"restruct: candidate: %s -> %s\n",
ocfqn(subnode->ocnode),ocfqn(matchnode->ocnode));
#endif
if(simplenodematch34(subnode,matchnode)) {
/* this subnode of the node matches the corresponding
node of the template, so it is ok =>
recurse looking for nested mis-matches
*/
if(!restruct3r(subnode,matchnode,repairlist))
return 0;
} else {
/* If we do not have a direct match, then we need to look
at all the grids to see if this node matches a field
in one of the grids
*/
for(match=0,i=0;!match && i<nclistlength(templateparent->subnodes);i++) {
CDFnode* subtemp = (CDFnode*)nclistget(templateparent->subnodes,i);
if(subtemp->nctype == NC_Grid) { /* look inside */
for(j=0;j<nclistlength(templateparent->subnodes);j++) {
CDFnode* gridfield = (CDFnode*)nclistget(subtemp->subnodes,j);
if(simplenodematch34(subnode,gridfield)) {
/* We need to do this repair */
nclistpush(repairlist,(void*)subnode);
nclistpush(repairlist,(void*)gridfield);
match = 1;
break;
}
}
}
}
if(!match) return 0; /* we failed */
}
}
return 1; /* we matched everything at this level */
}
/* Wrap the node wrt the template grid or template struct */
static NCerror
repairgrids(NClist* repairlist)
{
NCerror ncstat = NC_NOERR;
int i;
assert(nclistlength(repairlist) % 2 == 0);
for(i=0;i<nclistlength(repairlist);i+=2) {
CDFnode* node = (CDFnode*)nclistget(repairlist,i);
CDFnode* template = (CDFnode*)nclistget(repairlist,i+1);
int index = findin(node->container,node);
int tindex = findin(template->container,template);
ncstat = structwrap3(node,node->container,index,
template->container,tindex);
#ifdef DEBUG
fprintf(stderr,"repairgrids: %s -> %s\n",
ocfqn(node->ocnode),ocfqn(template->ocnode));
#endif
}
return ncstat;
}
static NCerror
structwrap3(CDFnode* node, CDFnode* parent, int parentindex,
CDFnode* templategrid, int gridindex)
{
CDFnode* newstruct;
ASSERT((templategrid->nctype == NC_Grid));
newstruct = makenewstruct3(node,templategrid);
if(newstruct == NULL) {return THROW(NC_ENOMEM);}
/* replace the node with the new structure
in the parent's list of children*/
nclistset(parent->subnodes,parentindex,(void*)newstruct);
/* Update the list of all nodes in the tree */
nclistpush(node->root->tree->nodes,(void*)newstruct);
return NC_NOERR;
}
static int
findin(CDFnode* parent, CDFnode* child)
{
int i;
NClist* subnodes = parent->subnodes;
for(i=0;i<nclistlength(subnodes);i++) {
if(nclistget(subnodes,i) == child)
return i;
}
return -1;
}
/* Create a structure to surround projected grid array or map;
this occurs because some servers (that means you ferret and you thredds!)
do not adhere to the DAP2 protocol spec.
*/
static CDFnode*
makenewstruct3(CDFnode* node, CDFnode* templatenode)
{
CDFnode* newstruct = (CDFnode*)calloc(1,sizeof(CDFnode));
if(newstruct == NULL) return NULL;
newstruct->nctype = NC_Structure;
newstruct->nc_virtual = 1;
newstruct->ocname = nulldup(templatenode->ocname);
newstruct->ocnode = templatenode->ocnode;
newstruct->ncbasename = nulldup(templatenode->ncbasename);
newstruct->subnodes = nclistnew();
newstruct->container = node->container;
newstruct->template = templatenode;
node->container = newstruct;
nclistpush(newstruct->subnodes,(void*)node);
return newstruct;
}
/**
Make the constrained dds nodes (root)
point to the corresponding unconstrained
dds nodes (fullroot).
*/
NCerror
mapnodes3(CDFnode* root, CDFnode* fullroot)
{
NCerror ncstat = NC_NOERR;
ASSERT(root != NULL && fullroot != NULL);
if(!simplenodematch34(root,fullroot))
{THROWCHK(ncstat=NC_EINVAL); goto done;}
/* clear out old associations*/
unmap3(root);
ncstat = mapnodes3r(root,fullroot,0);
done:
return ncstat;
}
static NCerror
mapnodes3r(CDFnode* connode, CDFnode* fullnode, int depth)
{
unsigned int i,j;
NCerror ncstat = NC_NOERR;
ASSERT((simplenodematch34(connode,fullnode)));
#ifdef DEBUG
{
char* path1 = makecdfpathstring3(fullnode,".");
char* path2 = makecdfpathstring3(connode,".");
fprintf(stderr,"mapnode: %s->%s\n",path1,path2);
nullfree(path1); nullfree(path2);
}
#endif
/* Map node */
mapfcn(connode,fullnode);
#if 0
{
int i;
for(i=0;i<nclistlength(fullnode->subnodes);i++) {
CDFnode* n = (CDFnode*)nclistget(fullnode->subnodes,i);
fprintf(stderr,"fullnode.subnode[%d]: (%d) %s\n",i,n->nctype,n->ocname);
}
for(i=0;i<nclistlength(connode->subnodes);i++) {
CDFnode* n = (CDFnode*)nclistget(connode->subnodes,i);
fprintf(stderr,"connode.subnode[%d]: (%d) %s\n",i,n->nctype,n->ocname);
}
}
#endif
/* Try to match connode subnodes against fullnode subnodes */
ASSERT(nclistlength(connode->subnodes) <= nclistlength(fullnode->subnodes));
for(i=0;i<nclistlength(connode->subnodes);i++) {
CDFnode* consubnode = (CDFnode*)nclistget(connode->subnodes,i);
/* Search full subnodes for a matching subnode from con */
for(j=0;j<nclistlength(fullnode->subnodes);j++) {
CDFnode* fullsubnode = (CDFnode*)nclistget(fullnode->subnodes,j);
if(simplenodematch34(fullsubnode,consubnode)) {
ncstat = mapnodes3r(consubnode,fullsubnode,depth+1);
if(ncstat) goto done;
}
}
}
done:
return THROW(ncstat);
}
/* The specific actions of a map are defined
by this function.
*/
static NCerror
mapfcn(CDFnode* dstnode, CDFnode* srcnode)
{
/* Mark node as having been mapped */
dstnode->basenode = srcnode;
return NC_NOERR;
}
void
unmap3(CDFnode* root)
{
unsigned int i;
CDFtree* tree = root->tree;
for(i=0;i<nclistlength(tree->nodes);i++) {
CDFnode* node = (CDFnode*)nclistget(tree->nodes,i);
node->basenode = NULL;
}
}
/*
Move dimension data from basenodes to nodes
*/
NCerror
dimimprint3(NCDAPCOMMON* nccomm)
{
NCerror ncstat = NC_NOERR;
NClist* allnodes;
int i,j;
CDFnode* basenode;
allnodes = nccomm->cdf.ddsroot->tree->nodes;
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* node = (CDFnode*)nclistget(allnodes,i);
int noderank, baserank;
/* Do dimension imprinting */
basenode = node->basenode;
if(basenode == NULL) continue;
noderank = nclistlength(node->array.dimset0);
baserank = nclistlength(basenode->array.dimset0);
if(noderank == 0) continue;
ASSERT(noderank == baserank);
#ifdef DEBUG
fprintf(stderr,"dimimprint %s/%d -> %s/%d\n",
makecdfpathstring3(basenode,"."),
noderank,
makecdfpathstring3(node,"."),
baserank);
#endif
for(j=0;j<noderank;j++) {
CDFnode* dim = (CDFnode*)nclistget(node->array.dimset0,j);
CDFnode* basedim = (CDFnode*)nclistget(basenode->array.dimset0,j);
dim->dim.declsize0 = basedim->dim.declsize;
#ifdef DEBUG
fprintf(stderr,"dimimprint: %d: %lu -> %lu\n",i,basedim->dim.declsize,dim->dim.declsize0);
#endif
}
}
return ncstat;
}
static CDFnode*
clonedim(NCDAPCOMMON* nccomm, CDFnode* dim, CDFnode* var)
{
CDFnode* clone;
clone = makecdfnode34(nccomm,dim->ocname,OC_Dimension,
NULL,dim->container);
/* Record its existence */
nclistpush(dim->container->root->tree->nodes,(void*)clone);
clone->dim = dim->dim; /* copy most everything */
clone->dim.dimflags |= CDFDIMCLONE;
clone->dim.array = var;
return clone;
}
static NClist*
clonedimset3(NCDAPCOMMON* nccomm, NClist* dimset, CDFnode* var)
{
NClist* result = nclistnew();
int i;
for(i=0;i<nclistlength(dimset);i++) {
CDFnode* dim = (CDFnode*)nclistget(dimset,i);
nclistpush(result,(void*)clonedim(nccomm,dim,var));
}
return result;
}
/* Define the dimsetplus list for a node */
static NCerror
definedimsetplus3(NCDAPCOMMON* nccomm/*notused*/, CDFnode* node)
{
int ncstat = NC_NOERR;
NClist* dimset;
CDFnode* clone;
ASSERT(node->array.dimsetplus == NULL);
if(node->array.dimset0 == NULL)
dimset = nclistnew();
else { /* copy the dimset0 into dimset */
dimset = nclistclone(node->array.dimset0);
}
/* Insert the sequence or string dims */
if(node->array.stringdim != NULL) {
clone = node->array.stringdim;
nclistpush(dimset,(void*)clone);
}
if(node->array.seqdim != NULL) {
clone = node->array.seqdim;
nclistpush(dimset,(void*)clone);
}
node->array.dimsetplus = dimset;
return ncstat;
}
/* Define the dimsetall list for a node */
static NCerror
definedimsetall3(NCDAPCOMMON* nccomm/*notused*/, CDFnode* node)
{
int i;
int ncstat = NC_NOERR;
NClist* dimsetall;
/* Because of upward recursion (see below) the dimsetall may
already be defined */
if(node->array.dimsetall != NULL)
return ncstat;
if(node->container != NULL) {
if(node->container->array.dimsetall == NULL) {
#ifdef DEBUG1
fprintf(stderr,"dimsetall: recurse to container%s\n",node->container->ocname);
#endif
ncstat = definedimsetall3(nccomm,node->container);
if(ncstat != NC_NOERR) return ncstat;
}
/* We need to clone the parent dimensions because we will be assigning
indices vis-a-vis this variable */
dimsetall = clonedimset3(nccomm,node->container->array.dimsetall,node);
} else
dimsetall = nclistnew();
// concat parentall and dimset;
for(i=0;i<nclistlength(node->array.dimsetplus);i++) {
CDFnode* clone = (CDFnode*)nclistget(node->array.dimsetplus,i);
nclistpush(dimsetall,(void*)clone);
}
node->array.dimsetall = dimsetall;
#ifdef DEBUG1
fprintf(stderr,"dimsetall: |%s|=%d\n",node->ocname,(int)nclistlength(dimsetall));
#endif
return ncstat;
}
/* Define the dimsettrans list for a node */
static NCerror
definedimsettrans3(NCDAPCOMMON* nccomm/*notused*/, CDFnode* node)
{
int i;
int ncstat = NC_NOERR;
NClist* dimsettrans;
/* Because of upward recursion (see below) the dimsettrans may
already be defined */
if(node->array.dimsettrans != NULL)
return ncstat;
if(node->container != NULL) {
if(node->container->array.dimsettrans == NULL) {
#ifdef DEBUG1
fprintf(stderr,"dimsettrans: recurse to container%s\n",node->container->ocname);
#endif
ncstat = definedimsettrans3(nccomm,node->container);
if(ncstat != NC_NOERR) return ncstat;
}
/* We need to clone the parent dimensions because we will be assigning
indices vis-a-vis this variable */
dimsettrans = clonedimset3(nccomm,node->container->array.dimsettrans,node);
} else
dimsettrans = nclistnew();
// concat parent dimset0 and dimset;
for(i=0;i<nclistlength(node->array.dimset0);i++) {
CDFnode* clone = (CDFnode*)nclistget(node->array.dimset0,i);
nclistpush(dimsettrans,(void*)clone);
}
node->array.dimsettrans = dimsettrans;
#ifdef DEBUG1
fprintf(stderr,"dimsettrans: |%s|=%d\n",node->ocname,(int)nclistlength(dimsettrans));
#endif
return ncstat;
}
/* Define the dimsetplus, dimsettrans, and dimsetall lists for
all nodes with dimensions
*/
NCerror
definedimsets3(NCDAPCOMMON* nccomm, CDFtree* tree)
{
int i;
int ncstat = NC_NOERR;
NClist* allnodes = tree->nodes;
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* rankednode = (CDFnode*)nclistget(allnodes,i);
if(rankednode->nctype == NC_Dimension) continue; //ignore
ASSERT((rankednode->array.dimsettrans == NULL));
ncstat = definedimsettrans3(nccomm,rankednode);
if(ncstat != NC_NOERR) return ncstat;
}
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* rankednode = (CDFnode*)nclistget(allnodes,i);
if(rankednode->nctype == NC_Dimension) continue; //ignore
ASSERT((rankednode->array.dimsetplus == NULL));
ncstat = definedimsetplus3(nccomm,rankednode);
if(ncstat != NC_NOERR) return ncstat;
}
for(i=0;i<nclistlength(allnodes);i++) {
CDFnode* rankednode = (CDFnode*)nclistget(allnodes,i);
if(rankednode->nctype == NC_Dimension) continue; //ignore
ASSERT((rankednode->array.dimsetplus != NULL));
ncstat = definedimsetall3(nccomm,rankednode);
if(ncstat != NC_NOERR) return ncstat;
}
return NC_NOERR;
}