/********************************************************************* * Copyright 2018, UCAR/Unidata * See netcdf/COPYRIGHT file for copying and redistribution conditions. *********************************************************************/ #include "config.h" #include #include #include "d4includes.h" #include "ncdispatch.h" #include "netcdf_aux.h" #ifdef D4CATCH /* Place breakpoint here to catch errors close to where they occur*/ int d4breakpoint(int err) {return err;} int d4throw(int err) { if(err == 0) return err; return d4breakpoint(err); } #endif int d4panic(const char* fmt, ...) { va_list args; if(fmt != NULL) { va_start(args, fmt); vfprintf(stderr, fmt, args); fprintf(stderr, "\n" ); va_end( args ); } else { fprintf(stderr, "panic" ); } fprintf(stderr, "\n" ); fflush(stderr); return 0; } const char* NCD4_sortname(NCD4sort sort) { switch (sort) { case NCD4_NULL: return "NCD4_NULL"; case NCD4_ATTR: return "NCD4_ATTR"; case NCD4_ATTRSET: return "NCD4_ATTRSET"; case NCD4_XML: return "NCD4_XML"; case NCD4_DIM: return "NCD4_DIM"; case NCD4_GROUP: return "NCD4_GROUP"; case NCD4_TYPE: return "NCD4_TYPE"; case NCD4_VAR: return "NCD4_VAR"; case NCD4_ECONST: return "NCD4_ECONST"; default: break; } return "unknown"; } const char* NCD4_subsortname(nc_type subsort) { switch (subsort) { case NC_NAT: return "NC_NAT"; case NC_BYTE: return "NC_BYTE"; case NC_CHAR: return "NC_CHAR"; case NC_SHORT: return "NC_SHORT"; case NC_INT: return "NC_INT"; case NC_FLOAT: return "NC_FLOAT"; case NC_DOUBLE: return "NC_DOUBLE"; case NC_UBYTE: return "NC_UBYTE"; case NC_USHORT: return "NC_USHORT"; case NC_UINT: return "NC_UINT"; case NC_INT64: return "NC_INT64"; case NC_UINT64: return "NC_UINT64"; case NC_STRING: return "NC_STRING"; case NC_VLEN: return "NC_VLEN"; case NC_OPAQUE: return "NC_OPAQUE"; case NC_ENUM: return "NC_ENUM"; case NC_COMPOUND: return "NC_COMPOUND"; default: break; } return "unknown"; } /* For debugging purposes, it is desirable to fake an nccopy bv inserting the data into the substrate and then writing it out. */ int NCD4_debugcopy(NCD4INFO* info) { int i,ret=NC_NOERR; NCD4meta* meta = info->substrate.metadata; NClist* topvars = nclistnew(); NC* ncp = info->controller; void* memory = NULL; /* Walk each top level variable, read all of it and write it to the substrate */ if((ret=NCD4_getToplevelVars(meta, NULL, topvars))) goto done; /* Read from the dap data by going thru the dap4 interface */ for(i=0;ibasetype; NCD4node* grp = NCD4_groupFor(var); int grpid = grp->meta.id; int varid = var->meta.id; d4size_t varsize; size_t dimprod = NCD4_dimproduct(var); int ncid = info->substrate.nc4id; varsize = type->meta.memsize * dimprod; memory = d4alloc(varsize); if(memory == NULL) {ret = NC_ENOMEM; goto done;} { /* We need to read via NCD4 */ int d4gid = makedap4id(ncp,grpid); if((ret=nc_get_var(d4gid,varid,memory))) goto done; } /* Now, turn around and write it to the substrate. WARNING: we have to specify the shape ourselves because, if unlimited is involved then there is potentially a difference between the substrate unlimited size and the dap4 data specified size. In fact, the substrate will always be zero unless debugcopy is used. */ { size_t edges[NC_MAX_VAR_DIMS]; int d; for(d=0;ddims);d++) { NCD4node* dim = (NCD4node*)nclistget(var->dims,d); edges[d] = (size_t)dim->dim.size; } if((ret=nc_put_vara(grpid,varid,NC_coord_zero,edges,memory))) goto done; } if((ret=ncaux_reclaim_data(ncid,type->meta.id,memory,dimprod))) goto done; nullfree(memory); memory = NULL; } done: nullfree(memory); nclistfree(topvars); if(ret != NC_NOERR) { fprintf(stderr,"debugcopy: %d %s\n",ret,nc_strerror(ret)); } return THROW(ret); } /* Provide a string printer that can be called from gdb */ void NCD4_printstring(const char* s) { fprintf(stderr,"%s\n",s); fflush(stderr); }