/********************************************************************* * Copyright 2016, UCAR/Unidata * See netcdf/COPYRIGHT file for copying and redistribution conditions. *********************************************************************/ #include "d4includes.h" #include #include "nc4internal.h" #include "ncoffsets.h" #include "ezxml.h" /** * Build the netcdf-4 metadata from the NCD4node nodes. */ /***************************************************/ /* Forwards */ static char* backslashEscape(const char* s); static char* getFieldFQN(NCD4node* field, const char* tail); static int build(NCD4meta* builder, NCD4node* root); static int buildAtomicVar(NCD4meta* builder, NCD4node* var); static int buildAttributes(NCD4meta* builder, NCD4node* varorgroup); static int buildBytestringType(NCD4meta* builder); static int buildCompound(NCD4meta* builder, NCD4node* cmpdtype, NCD4node* group, char* name); static int buildDimension(NCD4meta* builder, NCD4node* dim); static int buildEnumeration(NCD4meta* builder, NCD4node* en); static int buildGroups(NCD4meta*, NCD4node* parent); static int buildMaps(NCD4meta* builder, NCD4node* var); static int buildMetaData(NCD4meta* builder, NCD4node* var); static int buildOpaque(NCD4meta* builder, NCD4node* op); static int buildSequence(NCD4meta* builder, NCD4node* seq); static int buildStructure(NCD4meta* builder, NCD4node* structvar); static int buildStructureType(NCD4meta* builder, NCD4node* structtype); static int buildVariable(NCD4meta* builder, NCD4node* var); static int buildVlenType(NCD4meta* builder, NCD4node* seqtype); static int compileAttrValues(NCD4meta* builder, NCD4node* basetype, NClist* values, void** memoryp); static void computeOffsets(NCD4meta* builder, NCD4node* cmpd); static int convertString(union ATOMICS* converter, NCD4node* type, const char* s); static void* copyAtomic(union ATOMICS* converter, nc_type type, size_t len, void* dst); static int decodeEconst(NCD4meta* builder, NCD4node* enumtype, const char* nameorval, union ATOMICS* converter); static int downConvert(union ATOMICS* converter, NCD4node* type); static void freeStringMemory(char** mem, int count); static size_t getDimrefs(NCD4node* var, int* dimids); static size_t getDimsizes(NCD4node* var, size_t* dimsizes); static void reclaimNode(NCD4node* node); static d4size_t getpadding(d4size_t offset, size_t alignment); static int markdapsize(NCD4meta* meta); static int markfixedsize(NCD4meta* meta); static void savegroupbyid(NCD4meta*,NCD4node* group); static void savevarbyid(NCD4node* group, NCD4node* var); /***************************************************/ /* API */ int NCD4_metabuild(NCD4meta* metadata, int ncid) { int ret = NC_NOERR; int i; metadata->ncid = ncid; metadata->root->meta.id = ncid; /* Fix up the atomic types */ for(i=0;iallnodes);i++) { NCD4node* n = (NCD4node*)nclistget(metadata->allnodes,i); if(n->sort != NCD4_TYPE) continue; if(n->subsort > NC_MAX_ATOMIC_TYPE) continue; n->meta.id = n->subsort; n->meta.isfixedsize = (n->subsort == NC_STRING ? 0 : 1); if(n->subsort <= NC_STRING) n->meta.dapsize = NCD4_typesize(n->subsort); } /* Topo sort the set of all nodes */ NCD4_toposort(metadata); markfixedsize(metadata); markdapsize(metadata); /* Process the metadata state */ ret = build(metadata,metadata->root); /* Done with the metadata*/ if((ret=nc_enddef(metadata->ncid))) goto done; done: return THROW(ret); } /* Create an empty NCD4meta object for use in subsequent calls (is the the right src file to hold this?) */ NCD4meta* NCD4_newmeta(size_t rawsize, void* rawdata) { NCD4meta* meta = (NCD4meta*)calloc(1,sizeof(NCD4meta)); if(meta == NULL) return NULL; meta->allnodes = nclistnew(); meta->serial.rawsize = rawsize; meta->serial.rawdata = rawdata; #ifdef D4DEBUG meta->debuglevel = 1; #endif return meta; } void NCD4_setdebuglevel(NCD4meta* meta, int debuglevel) { meta->debuglevel = debuglevel; } void NCD4_reclaimMeta(NCD4meta* dataset) { int i; if(dataset == NULL) return; for(i=0;iallnodes);i++) { NCD4node* node = (NCD4node*)nclistget(dataset->allnodes,i); reclaimNode(node); } nullfree(dataset->error.parseerror); nullfree(dataset->error.message); nullfree(dataset->error.context); nullfree(dataset->error.otherinfo); nullfree(dataset->serial.errdata); nclistfree(dataset->groupbyid); #if 0 for(i=0;iblobs);i++) { void* p = nclistget(dataset->blobs,i); nullfree(p); } nclistfree(dataset->blobs); #endif nclistfree(dataset->allnodes); nullfree(dataset->serial.dmr); free(dataset); } static void reclaimNode(NCD4node* node) { if(node == NULL) return; nullfree(node->name); nclistfree(node->groups); nclistfree(node->vars); nclistfree(node->types); nclistfree(node->dims); nclistfree(node->attributes); nclistfree(node->maps); nclistfreeall(node->xmlattributes); nclistfreeall(node->attr.values); nclistfree(node->en.econsts); nclistfree(node->group.elements); nullfree(node->group.dapversion); nullfree(node->group.dmrversion); nullfree(node->group.datasetname); nclistfree(node->group.varbyid); nullfree(node->nc4.orig.name); } /**************************************************/ /* Recursively walk the tree to create the metadata */ static int build(NCD4meta* builder, NCD4node* root) { int i,ret = NC_NOERR; size_t len = nclistlength(builder->allnodes); /* Tag the root group */ savegroupbyid(builder,root); /* Compute the sizes for all type objects. Will of necessity compute the offsets for compound types as well */ for(i=0;iallnodes,i); if(x->sort != NCD4_TYPE) continue; switch (x->subsort) { case NC_OPAQUE: case NC_ENUM: case NC_SEQ: default: /* Atomic */ x->meta.memsize = NCD4_computeTypeSize(builder,x); x->meta.alignment = x->meta.memsize; /* Same for these cases */ break; case NC_STRUCT: /* We need to compute the field offsets in order to compute the struct size */ computeOffsets(builder,x); break; } } /* Start by defining group tree separately so we can maintain order */ if((ret=buildGroups(builder,root))) goto done; /* Now, walks selected other nodes to define the netcdf-4 substrate metadata */ /* Walk and define the dimensions */ for(i=0;iallnodes,i); if(x->sort != NCD4_DIM) continue; if((ret=buildDimension(builder,x))) goto done; } /* Walk and define the enums */ for(i=0;iallnodes,i); if(x->sort != NCD4_TYPE) continue; if(x->subsort != NC_ENUM) continue; if((ret=buildEnumeration(builder,x))) goto done; } /* Walk and define the opaques */ /* If _bytestring was required by parser, then create it */ if(builder->_bytestring != NULL && (ret = buildBytestringType(builder))) goto done; /* Create other opaque types */ for(i=0;iallnodes,i); if(x->sort != NCD4_TYPE) continue; if(x->subsort != NC_OPAQUE) continue; if(x->opaque.size > 0 && (ret=buildOpaque(builder,x))) goto done; } /* Walk and define the compounds and sequences */ for(i=0;iallnodes,i); if(x->sort != NCD4_TYPE) continue; switch(x->subsort) { case NC_STRUCT: if((ret=buildStructureType(builder,x))) goto done; break; case NC_SEQ: if((ret=buildVlenType(builder,x))) goto done; break; default: /* ignore */ break; } } /* Compute the type size for all type */ for(i=0;iallnodes,i); if(x->sort != NCD4_TYPE) continue;; NCD4_computeTypeSize(builder,x); } /* Finally, define the top-level variables */ for(i=0;iallnodes,i); if(ISVAR(x->sort) && ISTOPLEVEL(x)) buildVariable(builder,x); } done: return THROW(ret); } static int buildGroups(NCD4meta* builder, NCD4node* parent) { int i,ret=NC_NOERR; #ifdef D4DEBUG fprintf(stderr,"build group: %s\n",parent->name); #endif /* Define any group level attributes */ if((ret = buildAttributes(builder,parent))) goto done; for(i=0;igroups);i++) { NCD4node* g = (NCD4node*)nclistget(parent->groups,i); if(g->group.isdataset) { g->meta.id = builder->ncid; } else { NCCHECK((nc_def_grp(parent->meta.id,g->name,&g->meta.id))); savegroupbyid(builder,g); } if((ret=buildGroups(builder,g))) goto done; /* recurse */ } done: return THROW(ret); } static int buildDimension(NCD4meta* builder, NCD4node* dim) { int ret = NC_NOERR; NCD4node* group = NCD4_groupFor(dim); if(dim->dim.isunlimited) { NCCHECK((nc_def_dim(group->meta.id,dim->name,NC_UNLIMITED,&dim->meta.id))); } else { NCCHECK((nc_def_dim(group->meta.id,dim->name,(size_t)dim->dim.size,&dim->meta.id))); } done: return THROW(ret); } static int buildEnumeration(NCD4meta* builder, NCD4node* en) { int i,ret = NC_NOERR; NCD4node* group = NCD4_groupFor(en); NCCHECK((nc_def_enum(group->meta.id,en->basetype->meta.id,en->name,&en->meta.id))); for(i=0;ien.econsts);i++) { NCD4node* ec = (NCD4node*)nclistget(en->en.econsts,i); NCCHECK((nc_insert_enum(group->meta.id, en->meta.id, ec->name, ec->en.ecvalue.i8))); } done: return THROW(ret); } static int buildOpaque(NCD4meta* builder, NCD4node* op) { int ret = NC_NOERR; NCD4node* group = NCD4_groupFor(op); char* name = op->name; assert(op->opaque.size > 0); /* Two cases, with and without UCARTAGORIGTYPE */ if(op->nc4.orig.name != NULL) { name = op->nc4.orig.name; group = op->nc4.orig.group; } NCCHECK((nc_def_opaque(group->meta.id,op->opaque.size,name,&op->meta.id))); done: return THROW(ret); } static int buildBytestringType(NCD4meta* builder) { int ret = NC_NOERR; NCD4node* bstring = builder->_bytestring; assert(bstring != NULL); /* Will fail if we need bytestring and it was not created in d4parse*/ /* Define once */ if(bstring->meta.id > 0) goto done; /* create in root as ubyte(*) vlen named "_bytestring" */ NCCHECK((nc_def_vlen(builder->root->meta.id,bstring->name,NC_UBYTE,&bstring->meta.id))); done: return THROW(ret); } static int buildVariable(NCD4meta* builder, NCD4node* var) { int ret = NC_NOERR; switch (var->subsort) { default: if((ret = buildAtomicVar(builder,var))) goto done; break; case NC_STRUCT: if((ret = buildStructure(builder,var))) goto done; break; case NC_SEQ: if((ret = buildSequence(builder,var))) goto done; break; } done: return THROW(ret); } static int buildMetaData(NCD4meta* builder, NCD4node* var) { int ret = NC_NOERR; if((ret = buildAttributes(builder,var))) goto done; if((ret = buildMaps(builder,var))) goto done; done: return THROW(ret); } static int buildMaps(NCD4meta* builder, NCD4node* var) { int i,ret = NC_NOERR; size_t count = nclistlength(var->maps); char** memory = NULL; char** p; NCD4node* group; if(count == 0) goto done; /* Add an attribute to the parent variable listing fqn's of all specified variables in map order*/ memory = (char**)d4alloc(count*sizeof(char*)); if(memory == NULL) {ret=NC_ENOMEM; goto done;} p = memory; for(i=0;imaps,i); char* fqn = NCD4_makeFQN(mapref); *p++ = fqn; } /* Make map info visible in the netcdf-4 file */ group = NCD4_groupFor(var); NCCHECK((nc_put_att(group->meta.id,var->meta.id,NC4TAGMAPS,NC_STRING,count,memory))); done: if(memory != NULL) freeStringMemory(memory,count); return THROW(ret); } static int buildAttributes(NCD4meta* builder, NCD4node* varorgroup) { int i,ret = NC_NOERR; for(i=0;iattributes);i++) { NCD4node* attr = nclistget(varorgroup->attributes,i); void* memory = NULL; size_t count = nclistlength(attr->attr.values); NCD4node* group; int varid; /* Supress all UCARTAG attributes */ if(strncmp(attr->name,UCARTAG,strlen(UCARTAG)) == 0) continue; if(ISGROUP(varorgroup->sort)) varid = NC_GLOBAL; else varid = varorgroup->meta.id; if((ret=compileAttrValues(builder,attr->basetype,attr->attr.values,&memory))) { nullfree(memory); FAIL(NC_ERANGE,"Malformed attribute value(s) for: %s",attr->name); } group = NCD4_groupFor(varorgroup); NCCHECK((nc_put_att(group->meta.id,varid,attr->name,attr->basetype->meta.id,count,memory))); nullfree(memory); } done: return THROW(ret); } static int buildStructureType(NCD4meta* builder, NCD4node* structtype) { int tid,ret = NC_NOERR; NCD4node* group = NULL; char* name = NULL; group = NCD4_groupFor(structtype); /* default */ /* Figure out the type name and containing group */ if(structtype->nc4.orig.name != NULL) { name = strdup(structtype->nc4.orig.name); group = structtype->nc4.orig.group; } else { name = getFieldFQN(structtype,"_t"); } /* Step 2: See if already defined */ if(nc_inq_typeid(group->meta.id,name,&tid) == NC_NOERR) {/* Already exists */ FAIL(NC_ENAMEINUSE,"Inferred type name conflict",name); } /* Since netcdf does not support forward references, we presume all field types are defined */ if((ret=buildCompound(builder,structtype,group,name))) goto done; done: nullfree(name); return THROW(ret); } static int buildVlenType(NCD4meta* builder, NCD4node* vlentype) { int ret = NC_NOERR; NCD4node* group; NCD4node* basetype; nc_type tid = NC_NAT; char* name = NULL; group = NCD4_groupFor(vlentype); /* Figure out the type name and containing group */ if(vlentype->nc4.orig.name != NULL) { name = strdup(vlentype->nc4.orig.name); group = vlentype->nc4.orig.group; } else { name = getFieldFQN(vlentype,NULL); } /* See if already defined */ if(nc_inq_typeid(group->meta.id,name,&tid) == NC_NOERR) {/* Already exists */ FAIL(NC_ENAMEINUSE,"Inferred type name conflict",name); } /* Get the baseline type */ basetype = vlentype->basetype; /* build the vlen type */ NCCHECK(nc_def_vlen(group->meta.id, name, basetype->meta.id, &vlentype->meta.id)); done: nullfree(name); return THROW(ret); } static int buildCompound(NCD4meta* builder, NCD4node* cmpdtype, NCD4node* group, char* name) { int i,ret = NC_NOERR; /* Step 1: compute field offsets */ computeOffsets(builder,cmpdtype); /* Step 2: define this node's compound type */ NCCHECK((nc_def_compound(group->meta.id,(size_t)cmpdtype->meta.memsize,name,&cmpdtype->meta.id))); /* Step 3: add the fields to type */ for(i=0;ivars);i++) { int rank; size_t dimsizes[NC_MAX_VAR_DIMS]; NCD4node* field = (NCD4node*)nclistget(cmpdtype->vars,i); rank = nclistlength(field->dims); if(rank == 0) { /* scalar */ NCCHECK((nc_insert_compound(group->meta.id, cmpdtype->meta.id, field->name, field->meta.offset, field->basetype->meta.id))); } else if(rank > 0) { /* array */ getDimsizes(field,dimsizes); NCCHECK((nc_insert_array_compound(group->meta.id, cmpdtype->meta.id, field->name, field->meta.offset, field->basetype->meta.id, rank, dimsizes))); } } done: return THROW(ret); } static int buildAtomicVar(NCD4meta* builder, NCD4node* var) { int ret = NC_NOERR; size_t rank; int dimids[NC_MAX_VAR_DIMS]; NCD4node* group; group = NCD4_groupFor(var); #ifdef D4DEBUG fprintf(stderr,"build var: %s.%s\n",group->name,var->name); fflush(stderr); #endif rank = getDimrefs(var,dimids); NCCHECK((nc_def_var(group->meta.id,var->name,var->basetype->meta.id,rank,dimids,&var->meta.id))); /* Tag the var */ savevarbyid(group,var); /* Build attributes and map attributes */ if((ret = buildMetaData(builder,var))) goto done; done: return THROW(ret); } static int buildStructure(NCD4meta* builder, NCD4node* structvar) { int ret = NC_NOERR; NCD4node* group; int rank; int dimids[NC_MAX_VAR_DIMS]; /* Step 1: define the variable */ rank = nclistlength(structvar->dims); getDimrefs(structvar,dimids); group = NCD4_groupFor(structvar); NCCHECK((nc_def_var(group->meta.id,structvar->name,structvar->basetype->meta.id,rank,dimids,&structvar->meta.id))); /* Tag the var */ savevarbyid(group,structvar); /* Build attributes and map attributes WRT the variable */ if((ret = buildMetaData(builder,structvar))) goto done; done: return THROW(ret); } static int buildSequence(NCD4meta* builder, NCD4node* seq) { int ret = NC_NOERR; NCD4node* group; int rank; int dimids[NC_MAX_VAR_DIMS]; rank = nclistlength(seq->dims); getDimrefs(seq,dimids); group = NCD4_groupFor(seq); NCCHECK((nc_def_var(group->meta.id,seq->name,seq->basetype->meta.id,rank,dimids,&seq->meta.id))); savevarbyid(group,seq); /* Build attributes and map attributes WRT the variable */ if((ret = buildMetaData(builder,seq))) goto done; done: return THROW(ret); } /***************************************************/ /* Utilities */ /* Insert a group into the groupbyid for a group */ static void savegroupbyid(NCD4meta* meta, NCD4node* group) { if(meta->groupbyid == NULL) meta->groupbyid = nclistnew(); nclistsetalloc(meta->groupbyid,GROUPIDPART(group->meta.id)); nclistinsert(meta->groupbyid,GROUPIDPART(group->meta.id),group); } /* Insert a var into the varbyid for a group */ static void savevarbyid(NCD4node* group, NCD4node* var) { if(group->group.varbyid == NULL) group->group.varbyid = nclistnew(); nclistsetalloc(group->group.varbyid,var->meta.id); nclistinsert(group->group.varbyid,var->meta.id,var); } /* Collect FQN path from node upto (but not including) the first enclosing group and create an name from it */ static char* getFieldFQN(NCD4node* field, const char* tail) { int i; NCD4node* x = NULL; NClist* path = NULL; NCbytes* fqn = NULL; char* result; path = nclistnew(); for(x=field;!ISGROUP(x->sort);x=x->container) { nclistinsert(path,0,x); } fqn = ncbytesnew(); for(i=0;iname); if(escaped == NULL) return NULL; if(i > 0) ncbytesappend(fqn,'.'); ncbytescat(fqn,escaped); free(escaped); } if(tail != NULL) ncbytescat(fqn,tail); result = ncbytesextract(fqn); ncbytesfree(fqn); return result; } static size_t getDimrefs(NCD4node* var, int* dimids) { int i; int rank = nclistlength(var->dims); for(i=0;idims,i); dimids[i] = dim->meta.id; } return rank; } static size_t getDimsizes(NCD4node* var, size_t* dimsizes) { int i; int rank = nclistlength(var->dims); for(i=0;idims,i); dimsizes[i] = dim->dim.size; } return rank; } /**************************************************/ /* Utilities */ static void freeStringMemory(char** mem, int count) { int i; if(mem == NULL) return; for(i=0;isubsort == NC_ENUM); truebase = (isenum ? basetype->basetype : basetype); if(!ISTYPE(truebase->sort) || (truebase->meta.id > NC_MAX_ATOMIC_TYPE)) FAIL(NC_EBADTYPE,"Illegal attribute type: %s",basetype->name); size = NCD4_typesize(truebase->meta.id); if((memory = (char*)d4alloc(count*size))==NULL) return THROW(NC_ENOMEM); p = memory; for(i=0;iname); } ret = downConvert(&converter,truebase); p = copyAtomic(&converter,truebase->meta.id,NCD4_typesize(truebase->meta.id),p); } if(memoryp) *memoryp = memory; done: return THROW(ret); } static void* copyAtomic(union ATOMICS* converter, nc_type type, size_t len, void* dst) { switch (type) { case NC_CHAR: case NC_BYTE: case NC_UBYTE: memcpy(dst,&converter->u8[0],len); break; case NC_SHORT: case NC_USHORT: memcpy(dst,&converter->u16[0],len); break; case NC_INT: case NC_UINT: memcpy(dst,&converter->u32[0],len); break; case NC_INT64: case NC_UINT64: memcpy(dst,&converter->u64[0],len); break; case NC_FLOAT: memcpy(dst,&converter->f32[0],len); break; case NC_DOUBLE: memcpy(dst,&converter->f64[0],len); break; case NC_STRING: memcpy(dst,&converter->s[0],len); break; converter->s[0] = NULL; /* avoid duplicate free */ }/*switch*/ return (((char*)dst)+len); } static int convertString(union ATOMICS* converter, NCD4node* type, const char* s) { switch (type->subsort) { case NC_BYTE: case NC_SHORT: case NC_INT: case NC_INT64: if(sscanf(s,"%lld",&converter->i64) != 1) return THROW(NC_ERANGE); break; case NC_UBYTE: case NC_USHORT: case NC_UINT: case NC_UINT64: if(sscanf(s,"%llu",&converter->u64) != 1) return THROW(NC_ERANGE); break; case NC_FLOAT: case NC_DOUBLE: if(sscanf(s,"%lf",&converter->f64) != 1) return THROW(NC_ERANGE); break; case NC_CHAR: converter->i8[0] = s[0]; break; case NC_STRING: converter->s[0]= strdup(s); break; }/*switch*/ return downConvert(converter,type); } static int downConvert(union ATOMICS* converter, NCD4node* type) { d4size_t u64 = converter->u64[0]; long long i64 = converter->i64[0]; double f64 = converter->f64[0]; char* s = converter->s[0]; switch (type->subsort) { case NC_CHAR: case NC_BYTE: converter->i8[0] = (char)i64; break; case NC_UBYTE: converter->u8[0] = (unsigned char)u64; break; case NC_SHORT: converter->i16[0] = (short)i64; break; case NC_USHORT: converter->u16[0] = (unsigned short)u64; break; case NC_INT: converter->i32[0] = (int)i64; break; case NC_UINT: converter->u32[0] = (unsigned int)u64; break; case NC_INT64: converter->i64[0] = i64; break; case NC_UINT64: converter->u64[0]= u64; break; case NC_FLOAT: converter->f32[0] = (float)f64; break; case NC_DOUBLE: converter->f64[0] = f64; break; case NC_STRING: converter->s[0]= s; break; }/*switch*/ return THROW(NC_NOERR); } /* Given an enum type, and a string representing an econst, convert to integer. Note: this will work if the econst string is a number or a econst name */ static int decodeEconst(NCD4meta* builder, NCD4node* enumtype, const char* nameorval, union ATOMICS* converter) { int i,ret=NC_NOERR; union ATOMICS number; NCD4node* match = NULL; /* First, see if the value is an econst name */ for(i=0;ien.econsts);i++) { NCD4node* ec = (NCD4node*)nclistget(enumtype->en.econsts,i); if(strcmp(ec->name,nameorval)==0) {match = ec; break;} } /* If no match, try to invert as a number to see if there is a matching econst */ if(!match) { /* get the incoming value as number */ if((ret=convertString(&number,enumtype->basetype,nameorval))) goto done; for(i=0;ien.econsts);i++) { NCD4node* ec = (NCD4node*)nclistget(enumtype->en.econsts,i); if(ec->en.ecvalue.u64[0] == number.u64[0]) {match = ec; break;} } } if(match == NULL) FAIL(NC_EINVAL,"No enum const matching value: %s",nameorval); if(converter) *converter = match->en.ecvalue; done: return THROW(ret); } static char* backslashEscape(const char* s) { const char* p; char* q; size_t len; char* escaped = NULL; len = strlen(s); escaped = (char*)d4alloc(1+(2*len)); /* max is everychar is escaped */ if(escaped == NULL) return NULL; for(p=s,q=escaped;*p;p++) { char c = *p; switch (c) { case '\\': case '/': case '.': case '@': *q++ = '\\'; *q++ = '\\'; break; default: *q++ = c; break; } } *q = '\0'; return escaped; } /* Tag each compound type as fixed size or not Assumes: - atomic types defined and marked - topo sorted */ static int markfixedsize(NCD4meta* meta) { int i,j; for(i=0;iallnodes);i++) { int fixed = 1; NCD4node* n = (NCD4node*)nclistget(meta->allnodes,i); if(n->sort != NCD4_TYPE) continue; switch (n->subsort) { case NC_STRUCT: for(j=0;jvars);j++) { NCD4node* field = (NCD4node*)nclistget(n->vars,j); if(!field->basetype->meta.isfixedsize) { fixed = 0; break; } } n->meta.isfixedsize = fixed; break; case NC_ENUM: n->meta.isfixedsize = 1; break; default: /* leave as is */ break; } } return NC_NOERR; } /* Compute compound type field offsets and compound type total size */ static void computeOffsets(NCD4meta* builder, NCD4node* cmpd) { int i; d4size_t offset = 0; d4size_t largestalign = 1; d4size_t size = 0; for(i=0;ivars);i++) { NCD4node* field = (NCD4node*)nclistget(cmpd->vars,i); NCD4node* ftype = field->basetype; size_t alignment; if(ftype->subsort == NC_STRUCT) { /* Recurse */ computeOffsets(builder, ftype); assert(ftype->meta.memsize > 0); size=ftype->meta.memsize; alignment = ftype->meta.alignment; } else {/* Size and alignment will already have been set */ assert(ftype->meta.memsize > 0); alignment = ftype->meta.alignment; size=ftype->meta.memsize; } #if 0 } else if(ftype->subsort == NC_SEQ) { /* VLEN */ alignment = nctypealignment(NC_VLEN); assert(ftype->meta.memsize > 0); size=ftype->meta.memsize; //size = NCD4_computeTypeSize(builder,ftype); } else if(ftype->subsort == NC_OPAQUE) { /* Either fixed or a vlen */ assert(ftype->meta.memsize > 0); size=ftype->meta.memsize; if(ftype->opaque.size == 0) {/* treat like vlen */ alignment = nctypealignment(NC_VLEN); //size = NCD4_computeTypeSize(builder,ftype); } else { /* fixed size */ alignment = nctypealignment(NC_OPAQUE); //size = NCD4_computeTypeSize(builder,ftype); } } else if(ftype->subsort == NC_ENUM) { NCD4node* truetype = ftype->basetype; alignment = nctypealignment(truetype->meta.id); assert(ftype->meta.memsize > 0); size=ftype->meta.memsize; //size = NCD4_computeTypeSize(builder,truetype); } else { /* Basically a primitive */ alignment = nctypealignment(ftype->meta.id); assert(ftype->meta.memsize > 0); size=ftype->meta.memsize; //size = NCD4_computeTypeSize(builder,ftype); } #endif if(alignment > largestalign) largestalign = alignment; /* Add possible padding wrt to previous field */ offset += getpadding(offset,alignment); field->meta.offset = offset; assert(ftype->meta.memsize > 0); size = ftype->meta.memsize; //field->meta.memsize = size; /* Now ultiply by the field dimproduct*/ if(nclistlength(field->dims) > 0) { d4size_t count = NCD4_dimproduct(field); size = (size * count); } offset += size; } /* Compute compound-level info */ /* A struct alignment is the same as largestalign */ cmpd->meta.alignment = largestalign; offset += (offset % largestalign); /* round up compound size */ cmpd->meta.memsize = offset; } /* Compute the in-memory size of an instance of a type. Note that nc_inq_type is used, so that C struct field alignment is taken into account for compound types. The variables total size will be this * dimproduct. */ size_t NCD4_computeTypeSize(NCD4meta* builder, NCD4node* type) { size_t size = 0; switch (type->sort) { case NCD4_TYPE: switch (type->subsort) { default: size = NCD4_typesize(type->meta.id); break; case NC_OPAQUE: size = (type->opaque.size == 0 ? sizeof(nc_vlen_t) : type->opaque.size); break; case NC_ENUM: size = NCD4_computeTypeSize(builder,type->basetype); break; case NC_SEQ: size = sizeof(nc_vlen_t); break; case NC_STRUCT: { int ret; NCD4node* group = NCD4_groupFor(type); if((ret = nc_inq_type(group->meta.id,type->meta.id,/*name*/NULL,&size))) return 0; }; break; } break; default: break; /* ignore */ } type->meta.memsize = size; return size; } static d4size_t getpadding(d4size_t offset, size_t alignment) { d4size_t rem = (alignment==0?0:(offset % alignment)); d4size_t pad = (rem==0?0:(alignment - rem)); return pad; } /* Compute the dap data size for each type; note that this is unlikely to be the same as the meta.memsize unless the type is atomic and is <= NC_UINT64. */ static int markdapsize(NCD4meta* meta) { int i,j; for(i=0;iallnodes);i++) { NCD4node* type = (NCD4node*)nclistget(meta->allnodes,i); size_t totalsize; if(type->sort != NCD4_TYPE) continue; switch (type->subsort) { case NC_STRUCT: totalsize = 0; for(j=0;jvars);j++) { NCD4node* field = (NCD4node*)nclistget(type->vars,j); size_t size = field->basetype->meta.dapsize; if(size == 0) { totalsize = 0; break; } else totalsize += size; } type->meta.dapsize = totalsize; break; case NC_SEQ: type->meta.dapsize = 0; /* has no fixed size */ break; case NC_OPAQUE: type->meta.dapsize = type->opaque.size; break; case NC_ENUM: type->meta.dapsize = type->basetype->meta.dapsize; break; case NC_STRING: type->meta.dapsize = 0; /* has no fixed size */ break; default: assert(type->subsort <= NC_UINT64); /* Already assigned */ break; } } return NC_NOERR; }