/* Copyright (c) 1998-2018 University Corporation for Atmospheric Research/Unidata See COPYRIGHT for license information. */ /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright by The HDF Group. * * Copyright by the Board of Trustees of the University of Illinois. * * All rights reserved. * * * * This file is part of HDF5. The full HDF5 copyright notice, including * * terms governing use, modification, and redistribution, is contained in * * the files COPYING and Copyright.html. COPYING can be found at the root * * of the source code distribution tree; Copyright.html can be found at the * * root level of an installed copy of the electronic HDF5 document set and * * is linked from the top-level documents page. It can also be found at * * http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have * * access to either file, you may request a copy from help@hdfgroup.org. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ #include "config.h" #include #include #include #include "config.h" #include "netcdf.h" #include "netcdf_aux.h" #include "ncoffsets.h" #include "nclog.h" #include "ncrc.h" #include "netcdf_filter.h" struct NCAUX_FIELD { char* name; nc_type fieldtype; size_t ndims; int dimsizes[NC_MAX_VAR_DIMS]; size_t size; size_t offset; size_t alignment; }; struct NCAUX_CMPD { int ncid; int mode; char* name; size_t nfields; struct NCAUX_FIELD* fields; size_t size; size_t offset; /* cumulative as fields are added */ size_t alignment; }; /* It is helpful to have a structure that contains memory and an offset */ typedef struct Position{char* memory; ptrdiff_t offset;} Position; /* Forward */ static int reclaim_datar(int ncid, int xtype, size_t typesize, Position*); static int ncaux_initialized = 0; #ifdef USE_NETCDF4 static int reclaim_usertype(int ncid, int xtype, Position* offset); static int reclaim_compound(int ncid, int xtype, size_t size, size_t nfields, Position* offset); static int reclaim_vlen(int ncid, int xtype, int basetype, Position* offset); static int reclaim_enum(int ncid, int xtype, int basetype, size_t, Position* offset); static int reclaim_opaque(int ncid, int xtype, size_t size, Position* offset); static int computefieldinfo(struct NCAUX_CMPD* cmpd); #endif /* USE_NETCDF4 */ static int filterspec_cvt(const char* txt, size_t* nparamsp, unsigned int* params); /**************************************************/ /** Reclaim the output tree of data from a call to e.g. nc_get_vara or the input to e.g. nc_put_vara. This recursively walks the top-level instances to reclaim any nested data such as vlen or strings or such. Assumes it is passed a pointer to count instances of xtype. Reclaims any nested data. WARNING: does not reclaim the top-level memory because we do not know how it was allocated. Should work for any netcdf format. @param ncid file ncid @param xtype type id @param memory to reclaim @param count number of instances of the type in memory @return error code */ EXTERNL int ncaux_reclaim_data(int ncid, int xtype, void* memory, size_t count) { int stat = NC_NOERR; size_t typesize = 0; size_t i; Position offset; if(ncid < 0 || xtype < 0 || (memory == NULL && count > 0) || xtype == NC_NAT) {stat = NC_EINVAL; goto done;} if(memory == NULL || count == 0) goto done; /* ok, do nothing */ if((stat=nc_inq_type(ncid,xtype,NULL,&typesize))) goto done; offset.memory = (char*)memory; /* use char* so we can do pointer arithmetic */ offset.offset = 0; for(i=0;ioffset += typesize; break; #ifdef USE_NETCDF4 case NC_STRING: { char** sp = (char**)(offset->memory + offset->offset); /* Need to reclaim string */ if(*sp != NULL) free(*sp); offset->offset += typesize; } break; default: /* reclaim a user type */ stat = reclaim_usertype(ncid,xtype,offset); #else default: stat = NC_ENOTNC4; #endif break; } return stat; } #ifdef USE_NETCDF4 static ptrdiff_t read_align(ptrdiff_t offset, size_t alignment) { size_t loc_align = (alignment == 0 ? 1 : alignment); size_t delta = (offset % loc_align); if(delta == 0) return offset; return offset + (alignment - delta); } static int reclaim_usertype(int ncid, int xtype, Position* offset) { int stat = NC_NOERR; size_t size; nc_type basetype; size_t nfields; int klass; /* Get info about the xtype */ stat = nc_inq_user_type(ncid, xtype, NULL, &size, &basetype, &nfields, &klass); switch (klass) { case NC_OPAQUE: stat = reclaim_opaque(ncid,xtype,size,offset); break; case NC_ENUM: stat = reclaim_enum(ncid,xtype,basetype,size,offset); break; case NC_COMPOUND: stat = reclaim_compound(ncid,xtype,size,nfields,offset); break; case NC_VLEN: stat = reclaim_vlen(ncid,xtype,basetype,offset); break; default: stat = NC_EINVAL; break; } return stat; } static int reclaim_vlen(int ncid, int xtype, int basetype, Position* offset) { int stat = NC_NOERR; size_t i, basesize; nc_vlen_t* vl = (nc_vlen_t*)(offset->memory+offset->offset); /* Get size of the basetype */ if((stat=nc_inq_type(ncid,basetype,NULL,&basesize))) goto done; /* Free up each entry in the vlen list */ if(vl->p != NULL) { Position voffset; unsigned int alignment = ncaux_type_alignment(basetype,ncid); voffset.memory = vl->p; voffset.offset = 0; for(i=0;ilen;i++) { voffset.offset = read_align(voffset.offset,alignment); if((stat = reclaim_datar(ncid,basetype,basesize,&voffset))) goto done; } offset->offset += sizeof(nc_vlen_t); free(vl->p); } done: return stat; } static int reclaim_enum(int ncid, int xtype, int basetype, size_t basesize, Position* offset) { /* basically same as an instance of the enum's integer basetype */ return reclaim_datar(ncid,basetype,basesize,offset); } static int reclaim_opaque(int ncid, int xtype, size_t opsize, Position* offset) { /* basically a fixed size sequence of bytes */ offset->offset += opsize; return NC_NOERR; } static int reclaim_compound(int ncid, int xtype, size_t cmpdsize, size_t nfields, Position* offset) { int stat = NC_NOERR; size_t fid, fieldoffset, i, fieldsize, arraycount; int dimsizes[NC_MAX_VAR_DIMS]; int ndims; nc_type fieldtype; ptrdiff_t saveoffset; saveoffset = offset->offset; /* Get info about each field in turn and reclaim it */ for(fid=0;fidoffset = read_align(offset->offset,fieldalignment); /* compute the total number of elements in the field array */ arraycount = 1; for(i=0;ioffset = saveoffset; offset->offset += cmpdsize; done: return stat; } #endif /*USE_NETCDF4*/ /**************************************************/ /* This code is a variant of the H5detect.c code from HDF5. Author: D. Heimbigner 10/7/2008 */ EXTERNL int ncaux_begin_compound(int ncid, const char *name, int alignmode, void** tagp) { #ifdef USE_NETCDF4 int status = NC_NOERR; struct NCAUX_CMPD* cmpd = NULL; if(tagp) *tagp = NULL; cmpd = (struct NCAUX_CMPD*)calloc(1,sizeof(struct NCAUX_CMPD)); if(cmpd == NULL) {status = NC_ENOMEM; goto fail;} cmpd->ncid = ncid; cmpd->mode = alignmode; cmpd->nfields = 0; cmpd->name = strdup(name); if(cmpd->name == NULL) {status = NC_ENOMEM; goto fail;} if(tagp) { *tagp = (void*)cmpd; } else { /* Error, free cmpd to avoid memory leak. */ free(cmpd); } return status; fail: ncaux_abort_compound((void*)cmpd); return status; #else return NC_ENOTBUILT; #endif } EXTERNL int ncaux_abort_compound(void* tag) { #ifdef USE_NETCDF4 int i; struct NCAUX_CMPD* cmpd = (struct NCAUX_CMPD*)tag; if(cmpd == NULL) goto done; if(cmpd->name) free(cmpd->name); for(i=0;infields;i++) { struct NCAUX_FIELD* field = &cmpd->fields[i]; if(field->name) free(field->name); } if(cmpd->fields) free(cmpd->fields); free(cmpd); done: return NC_NOERR; #else return NC_ENOTBUILT; #endif } EXTERNL int ncaux_add_field(void* tag, const char *name, nc_type field_type, int ndims, const int* dimsizes) { #ifdef USE_NETCDF4 int i; int status = NC_NOERR; struct NCAUX_CMPD* cmpd = (struct NCAUX_CMPD*)tag; struct NCAUX_FIELD* newfields = NULL; struct NCAUX_FIELD* field = NULL; if(cmpd == NULL) goto done; if(ndims < 0) {status = NC_EINVAL; goto done;} for(i=0;ifields == NULL) { newfields = (struct NCAUX_FIELD*)calloc(1,sizeof(struct NCAUX_FIELD)); } else { newfields = (struct NCAUX_FIELD*)realloc(cmpd->fields,cmpd->nfields+1*sizeof(struct NCAUX_FIELD)); } if(cmpd->fields == NULL) {status = NC_ENOMEM; goto done;} cmpd->fields = newfields; field = &cmpd->fields[cmpd->nfields+1]; field->name = strdup(name); field->fieldtype = field_type; if(field->name == NULL) {status = NC_ENOMEM; goto done;} field->ndims = (size_t)ndims; memcpy(field->dimsizes,dimsizes,sizeof(int)*field->ndims); cmpd->nfields++; done: if(newfields) free(newfields); return status; #else return NC_ENOTBUILT; #endif } EXTERNL int ncaux_end_compound(void* tag, nc_type* idp) { #ifdef USE_NETCDF4 int i; int status = NC_NOERR; struct NCAUX_CMPD* cmpd = (struct NCAUX_CMPD*)tag; if(cmpd == NULL) {status = NC_EINVAL; goto done;} /* Compute field and compound info */ status = computefieldinfo(cmpd); if(status != NC_NOERR) goto done; status = nc_def_compound(cmpd->ncid, cmpd->size, cmpd->name, idp); if(status != NC_NOERR) goto done; for(i=0;infields;i++) { struct NCAUX_FIELD* field = &cmpd->fields[i]; if(field->ndims > 0) { status = nc_insert_compound(cmpd->ncid, *idp, field->name, field->offset, field->fieldtype); } else { status = nc_insert_array_compound(cmpd->ncid, *idp, field->name, field->offset, field->fieldtype, (int)field->ndims,field->dimsizes); } if(status != NC_NOERR) goto done; } done: return status; #else return NC_ENOTBUILT; #endif } /**************************************************/ /** @param ncclass - type class for which alignment is requested; excludes ENUM|COMPOUND */ size_t ncaux_class_alignment(int ncclass) { if(ncclass <= NC_MAX_ATOMIC_TYPE || ncclass == NC_VLEN || ncclass == NC_OPAQUE) return NC_class_alignment(ncclass); nclog(NCLOGERR,"ncaux_class_alignment: class %d; alignment cannot be determermined",ncclass); return 0; } /** @param ncid - only needed for a compound type @param xtype - type for which alignment is requested */ size_t ncaux_type_alignment(int xtype, int ncid) { if(!ncaux_initialized) { NC_compute_alignments(); ncaux_initialized = 1; } if(xtype <= NC_MAX_ATOMIC_TYPE) return NC_class_alignment(xtype); /* type == class */ #ifdef USE_NETCDF4 else {/* Presumably a user type */ int klass = NC_NAT; int stat = nc_inq_user_type(ncid,xtype,NULL,NULL,NULL,NULL,&klass); if(stat) goto done; switch(klass) { case NC_VLEN: return NC_class_alignment(klass); case NC_OPAQUE: return NC_class_alignment(klass); case NC_COMPOUND: {/* get alignment of the first field of the compound */ int fieldtype = NC_NAT; if((stat=nc_inq_compound_fieldtype(ncid,xtype,0,&fieldtype))) goto done; return ncaux_type_alignment(fieldtype,ncid); /* may recurse repeatedly */ } break; default: break; } } done: #endif /*USE_NETCDF4 */ return 0; /* fail */ } #ifdef USE_NETCDF4 /* Find first primitive field of a possibly nested sequence of compounds */ static nc_type findfirstfield(int ncid, nc_type xtype) { int status = NC_NOERR; nc_type fieldtype = xtype; if(xtype <= NC_MAX_ATOMIC_TYPE) goto done; status = nc_inq_compound_fieldtype(ncid, xtype, 0, &fieldtype); if(status != NC_NOERR) goto done; fieldtype = findfirstfield(ncid,fieldtype); done: return (status == NC_NOERR?fieldtype:NC_NAT); } static size_t getpadding(size_t offset, size_t alignment) { size_t rem = (alignment==0?0:(offset % alignment)); size_t pad = (rem==0?0:(alignment - rem)); return pad; } static size_t dimproduct(size_t ndims, int* dimsizes) { int i; size_t product = 1; for(i=0;infields;i++) { struct NCAUX_FIELD* field = &cmpd->fields[i]; status = nc_inq_type(cmpd->ncid,field->fieldtype,NULL,&field->size); if(status != NC_NOERR) goto done; totaldimsize = dimproduct(field->ndims,field->dimsizes); field->size *= totaldimsize; } for(offset=0,i=0;infields;i++) { struct NCAUX_FIELD* field = &cmpd->fields[i]; int alignment = 0; nc_type firsttype = findfirstfield(cmpd->ncid,field->fieldtype); /* only support 'c' alignment for now*/ switch (field->fieldtype) { case NC_OPAQUE: field->alignment = 1; break; case NC_ENUM: field->alignment = ncaux_type_alignment(firsttype,cmpd->ncid); break; case NC_VLEN: /*fall thru*/ case NC_COMPOUND: field->alignment = ncaux_type_alignment(firsttype,cmpd->ncid); break; default: field->alignment = ncaux_type_alignment(field->fieldtype,cmpd->ncid); break; } offset += getpadding(offset,alignment); field->offset = offset; offset += field->size; } cmpd->size = offset; cmpd->alignment = cmpd->fields[0].alignment; done: return status; } #endif /*USE_NETCDF4*/ /**************************************************/ /* Forward */ #define NUMCHAR "0123456789" #define LPAREN '(' #define RPAREN ')' #define LBRACK '[' #define RBRACK ']' static int gettype(const int q0, const int q1, int* unsignedp); /* Look at q0 and q1) to determine type */ static int gettype(const int q0, const int q1, int* isunsignedp) { int type = 0; int isunsigned = 0; char typechar; isunsigned = (q0 == 'u' || q0 == 'U'); if(q1 == '\0') typechar = q0; /* we were given only a single char */ else if(isunsigned) typechar = q1; /* we have something like Ux as the tag */ else typechar = q1; /* look at last char for tag */ switch (typechar) { case 'f': case 'F': case '.': type = 'f'; break; /* float */ case 'd': case 'D': type = 'd'; break; /* double */ case 'b': case 'B': type = 'b'; break; /* byte */ case 's': case 'S': type = 's'; break; /* short */ case 'l': case 'L': type = 'l'; break; /* long long */ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': type = 'i'; break; case 'u': case 'U': type = 'i'; isunsigned = 1; break; /* unsigned int */ case '\0': type = 'i'; break; default: break; } if(isunsignedp) *isunsignedp = isunsigned; return type; } #ifdef WORDS_BIGENDIAN /* Byte swap an 8-byte integer in place */ static void byteswap8(unsigned char* mem) { unsigned char c; c = mem[0]; mem[0] = mem[7]; mem[7] = c; c = mem[1]; mem[1] = mem[6]; mem[6] = c; c = mem[2]; mem[2] = mem[5]; mem[5] = c; c = mem[3]; mem[3] = mem[4]; mem[4] = c; } /* Byte swap an 8-byte integer in place */ static void byteswap4(unsigned char* mem) { unsigned char c; c = mem[0]; mem[0] = mem[3]; mem[3] = c; c = mem[1]; mem[1] = mem[2]; mem[2] = c; } #endif /**************************************************/ /* Moved here from netcdf_filter.h */ /* This function implements the 8-byte conversion algorithms for HDF5 Before calling *nc_def_var_filter* (unless *NC_parsefilterspec* was used), the client must call this function with the decode argument set to 0. Inside the filter code, this function should be called with the decode argument set to 1. * @params mem8 is a pointer to the 8-byte value either to fix. * @params decode is 1 if the function should apply the 8-byte decoding algorithm else apply the encoding algorithm. */ void ncaux_h5filterspec_fix8(unsigned char* mem8, int decode) { #ifdef WORDS_BIGENDIAN if(decode) { /* Apply inverse of the encode case */ byteswap4(mem8); /* step 1: byte-swap each piece */ byteswap4(mem8+4); byteswap8(mem8); /* step 2: convert to little endian format */ } else { /* encode */ byteswap8(mem8); /* step 1: convert to little endian format */ byteswap4(mem8); /* step 2: byte-swap each piece */ byteswap4(mem8+4); } #else /* Little endian */ /* No action is necessary */ #endif } /* Parse a filter spec string into a NC_FILTER_SPEC* Note that this differs from the usual case in that the function is called once to get both the number of parameters and the parameters themselves (hence the unsigned int** paramsp). @param txt - a string containing the spec as a sequence of constants separated by commas, where first constant is the filter id and the rest are parameters. @param idp - store the parsed filter id here @param nparamsp - store the number of parameters here @param paramsp - store the vector of parameters here; caller frees. @return NC_NOERR if parse succeeded @return NC_EINVAL otherwise */ EXTERNL int ncaux_h5filterspec_parse(const char* txt, unsigned int* idp, size_t* nparamsp, unsigned int** paramsp) { int i,stat = NC_NOERR; char* p; char* sdata0 = NULL; /* what to free */ char* sdata = NULL; /* sdata0 with leading prefix skipped */ size_t nparams; /* no. of comma delimited params */ size_t nactual; /* actual number of unsigned int's */ const char* sid = NULL; unsigned int filterid = 0; unsigned int* params = NULL; size_t len; if(txt == NULL) {stat = NC_EINVAL; goto done;} len = strlen(txt); if(len == 0) {stat = NC_EINVAL; goto done;} if((sdata0 = (char*)calloc(1,len+1+1))==NULL) {stat = NC_ENOMEM; goto done;} memcpy(sdata0,txt,len); sdata = sdata0; /* Count number of parameters + id and delimit */ p=sdata; for(nparams=0;;nparams++) { char* q = strchr(p,','); if(q == NULL) break; *q++ = '\0'; p = q; } nparams++; /* for final piece */ if(nparams == 0) {stat = NC_EINVAL; goto done;} /* no id and no parameters */ p = sdata; /* Extract the filter id */ sid = p; if((sscanf(sid,"%u",&filterid)) != 1) {stat = NC_EINVAL; goto done;} nparams--; /* skip past the filter id */ p = p + strlen(p) + 1; /* Allocate the max needed space (assume all params are 64 bit) */ if((params = (unsigned int*)calloc(sizeof(unsigned int),(nparams)*2))==NULL) {stat = NC_ENOMEM; goto done;} /* walk and capture */ for(nactual=0,i=0;i 0) { int count = 0; if((vector = (NC_H5_Filterspec**)calloc(sizeof(NC_H5_Filterspec*),nspecs)) == NULL) {stat = NC_ENOMEM; goto done;} /* pass 2: parse */ p = spec; for(count=0;countfilterid,&spec->nparams,&spec->params))) goto done; p = q+1; /* ok because of double nul */ } } if(formatp) *formatp = format; if(nspecsp) *nspecsp = nspecs; if(vectorp) {*vectorp = vector; vector = NULL;} done: nullfree(spec); if(vector) { int i; for(i=0;iparams); nullfree(f); } /* Convert a parameter string to one or two unsigned ints/ @param txt - (in) string constant @param nparamsp - (out) # of unsigned ints produced @param params - (out) produced unsigned ints @return NC_NOERR if parse succeeded @return NC_EINVAL if bad parameters or parse failed */ static int filterspec_cvt(const char* txt, size_t* nparamsp, unsigned int* params) { int stat = NC_NOERR; size_t nparams = 0; /*actual count*/ unsigned long long val64u; unsigned int val32u; double vald; float valf; unsigned int *vector; unsigned char mem[8]; int isunsigned = 0; int isnegative = 0; int type = 0; const char* q; const char* p = txt; size_t len = strlen(p); int sstat; /* skip leading white space */ while(strchr(" ",*p) != NULL) {p++; len--;} /* Get leading sign character, if any */ if(*p == '-') isnegative = 1; /* Get trailing type tag characters */ switch (len) { case 0: stat = NC_EINVAL; goto done; /* empty parameter */ case 1: case 2: q = (p + len) - 1; /* point to last char */ type = gettype(*q,'\0',&isunsigned); break; default: /* > 2 => we might have a two letter tag */ q = (p + len) - 2; type = gettype(*q,*(q+1),&isunsigned); break; } /* Now parse */ switch (type) { case 'b': case 's': case 'i': /* special case for a positive integer;for back compatibility.*/ if(!isnegative) sstat = sscanf(p,"%u",&val32u); else sstat = sscanf(p,"%d",(int*)&val32u); if(sstat != 1) {stat = NC_EINVAL; goto done;} switch(type) { case 'b': val32u = (val32u & 0xFF); break; case 's': val32u = (val32u & 0xFFFF); break; } params[nparams++] = val32u; break; case 'f': sstat = sscanf(p,"%lf",&vald); if(sstat != 1) {stat = NC_EINVAL; goto done;} valf = (float)vald; params[nparams++] = *(unsigned int*)&valf; break; /* The following are 8-byte values, so we must swap pieces if this is a little endian machine */ case 'd': sstat = sscanf(p,"%lf",&vald); if(sstat != 1) {stat = NC_EINVAL; goto done;}; memcpy(mem,&vald,sizeof(mem)); ncaux_h5filterspec_fix8(mem,0); vector = (unsigned int*)mem; params[nparams++] = vector[0]; params[nparams++] = vector[1]; break; case 'l': /* long long */ if(isunsigned) sstat = sscanf(p,"%llu",&val64u); else sstat = sscanf(p,"%lld",(long long*)&val64u); if(sstat != 1) {stat = NC_EINVAL; goto done;}; memcpy(mem,&val64u,sizeof(mem)); ncaux_h5filterspec_fix8(mem,0); vector = (unsigned int*)&mem; params[nparams++] = vector[0]; params[nparams++] = vector[1]; break; default: {stat = NC_EINVAL; goto done;}; } *nparamsp = nparams; done: return stat; } #if 0 /* Parse a filter spec string into a NC_H5_Filterspec* @param txt - a string containing the spec as a sequence of constants separated by commas. @param specp - store the parsed filter here -- caller frees @return NC_NOERR if parse succeeded @return NC_EINVAL otherwise */ EXTERNL int ncaux_filter_parsespec(const char* txt, NC_H5_Filterspec** h5specp) { int stat = NC_NOERR; NC_Filterspec* spec = NULL; NC_H5_Filterspec* h5spec = NULL; size_t len; if(txt == NULL) {stat = NC_EINVAL; goto done;} len = strlen(txt); if(len == 0) {stat = NC_EINVAL; goto done;} /* Parse as strings */ if((stat = ncaux_filterspec_parse(txt,&spec))) goto done; /* walk and convert */ if((stat = ncaux_filterspec_cvt(spec,&h5spec))) goto done; /* Now return results */ if(h5specp != NULL) {*h5specp = h5spec; h5spec = NULL;} done: ncaux_filterspec_free(spec); if(h5spec) nullfree(h5spec->params); nullfree(h5spec); return stat; } /* Parse a string containing multiple '|' separated filter specs. @param spec0 - a string containing the list of filter specs. @param nspecsp - # of parsed specs @param specsp - pointer to hold vector of parsed specs. Caller frees @return NC_NOERR if parse succeeded @return NC_EINVAL if bad parameters or parse failed */ EXTERNL int ncaux_filter_parselist(const char* txt0, size_t* nspecsp, NC_H5_Filterspec*** vectorp) { int stat = NC_NOERR; size_t len = 0; size_t nspecs = 0; NC_H5_Filterspec** vector = NULL; char* spec0 = NULL; /* with prefix */ char* spec = NULL; /* without prefix */ char* p = NULL; char* q = NULL; if(txt0 == NULL) return NC_EINVAL; /* Duplicate txt0 so we can modify it */ len = strlen(txt0); if((spec = calloc(1,len+1+1)) == NULL) return NC_ENOMEM; memcpy(spec,txt0,len); /* Note double ending nul */ spec0 = spec; /* Save for later free */ /* See if there is a prefix '[format]' tag; ignore it */ if(spec[0] == LBRACK) { spec = q; /* skip tag wrt later processing */ } /* pass 1: count number of specs */ p = spec; nspecs = 0; while(*p) { q = strchr(p,'|'); if(q == NULL) q = p + strlen(p); /* fake it */ nspecs++; p = q + 1; } if(nspecs > 0) { int count = 0; if((vector = (NC_H5_Filterspec**)malloc(sizeof(NC_H5_Filterspec*)*nspecs)) == NULL) {stat = NC_ENOMEM; goto done;} /* pass 2: parse */ p = spec; for(count=0;countparams) free(nfs->params); nullfree(nfs); } free(vector); } return stat; } #endif /**************************************************/ /* Wrappers to export selected functions from libnetcdf */ EXTERNL int ncaux_readfile(const char* filename, size_t* sizep, void** contentp) { int stat = NC_NOERR; NCbytes* content = ncbytesnew(); stat = NC_readfile(filename,content); if(stat == NC_NOERR && sizep) *sizep = ncbyteslength(content); if(stat == NC_NOERR && contentp) *contentp = ncbytesextract(content); ncbytesfree(content); return stat; } EXTERNL int ncaux_writefile(const char* filename, size_t size, void* content) { return NC_writefile(filename,size,content); }