/********************************************************************* * Copyright 2018, UCAR/Unidata * See netcdf/COPYRIGHT file for copying and redistribution conditions. *********************************************************************/ #include "d4includes.h" #include #include "d4includes.h" #include "ezxml.h" /* The primary purpose of this code is to recursively traverse the incoming data to get the endianness correct. */ /* Forward */ static int walkAtomicVar(NCD4meta*, NCD4node*, NCD4node*, void** offsetp); static int walkOpaqueVar(NCD4meta*,NCD4node*, NCD4node*, void** offsetp); static int walkStructArray(NCD4meta*,NCD4node*, NCD4node*, void** offsetp); static int walkStruct(NCD4meta*, NCD4node*, NCD4node*, void** offsetp); static int walkSeqArray(NCD4meta*, NCD4node*, NCD4node*, void** offsetp); static int walkSeq(NCD4meta*,NCD4node*, NCD4node*, void** offsetp); /**************************************************/ /* Assumes that compiler->swap is true; does necessary byte swapping. */ int NCD4_swapdata(NCD4meta* compiler, NClist* topvars) { int ret = NC_NOERR; int i; void* offset; offset = compiler->serial.dap; for(i=0;idata.dap4data.memory = offset; switch (var->subsort) { default: if((ret=walkAtomicVar(compiler,var,var,&offset))) goto done; break; case NC_OPAQUE: /* The only thing we need to do is swap the counts */ if((ret=walkOpaqueVar(compiler,var,var,&offset))) goto done; break; case NC_STRUCT: if((ret=walkStructArray(compiler,var,var,&offset))) goto done; break; case NC_SEQ: if((ret=walkSeqArray(compiler,var,var,&offset))) goto done; break; } var->data.dap4data.size = DELTA(offset,var->data.dap4data.memory); /* skip checksum, if there is one */ if(compiler->serial.remotechecksumming) offset = INCR(offset,CHECKSUMSIZE); } done: return THROW(ret); } static int walkAtomicVar(NCD4meta* compiler, NCD4node* topvar, NCD4node* var, void** offsetp) { int ret = NC_NOERR; void* offset; d4size_t i; nc_type subsort; d4size_t dimproduct; NCD4node* basetype; basetype = (var->sort == NCD4_TYPE ? var : var->basetype); subsort = basetype->subsort; dimproduct = (var->sort == NCD4_TYPE ? 1 : NCD4_dimproduct(var)); offset = *offsetp; if(subsort == NC_ENUM) subsort = var->basetype->basetype->subsort; /* Only need to swap multi-byte integers and floats */ if(subsort != NC_STRING) { int typesize = NCD4_typesize(subsort); d4size_t totalsize = typesize*dimproduct; if(typesize == 1) { offset = INCR(offset,totalsize); } else { /*(typesize > 1)*/ for(i=0;iswap) { switch (typesize) { case 2: swapinline16(sp); break; case 4: swapinline32(sp); break; case 8: swapinline64(sp); break; default: break; } } offset = INCR(offset,typesize); } } } else if(subsort == NC_STRING) { /* remaining case; just convert the counts */ COUNTERTYPE count; for(i=0;iswap) swapinline64(offset); count = GETCOUNTER(offset); SKIPCOUNTER(offset); /* skip count bytes */ offset = INCR(offset,count); } } *offsetp = offset; return THROW(ret); } static int walkOpaqueVar(NCD4meta* compiler, NCD4node* topvar, NCD4node* var, void** offsetp) { int ret = NC_NOERR; void* offset; d4size_t i; unsigned long long count; d4size_t dimproduct = NCD4_dimproduct(var); dimproduct = (var->sort == NCD4_TYPE ? 1 : NCD4_dimproduct(var)); offset = *offsetp; for(i=0;iswap) swapinline64(offset); count = GETCOUNTER(offset); SKIPCOUNTER(offset); offset = INCR(offset,count); } *offsetp = offset; return THROW(ret); } static int walkStructArray(NCD4meta* compiler, NCD4node* topvar, NCD4node* var, void** offsetp) { int ret = NC_NOERR; void* offset; d4size_t i; d4size_t dimproduct = NCD4_dimproduct(var); NCD4node* basetype = var->basetype; offset = *offsetp; for(i=0;ivars);i++) { NCD4node* field = (NCD4node*)nclistget(structtype->vars,i); NCD4node* fieldbase = field->basetype; switch (fieldbase->subsort) { default: if((ret=walkAtomicVar(compiler,topvar,field,&offset))) goto done; break; case NC_OPAQUE: /* The only thing we need to do is swap the counts */ if((ret=walkOpaqueVar(compiler,topvar,field,&offset))) goto done; break; case NC_STRUCT: if((ret=walkStructArray(compiler,topvar,field,&offset))) goto done; break; case NC_SEQ: if((ret=walkSeqArray(compiler,topvar,field,&offset))) goto done; break; } } *offsetp = offset; done: return THROW(ret); } static int walkSeqArray(NCD4meta* compiler, NCD4node* topvar, NCD4node* var, void** offsetp) { int ret = NC_NOERR; void* offset; d4size_t i; d4size_t dimproduct; NCD4node* seqtype; assert(var->sort == NCD4_VAR); dimproduct = NCD4_dimproduct(var); seqtype = var->basetype; offset = *offsetp; for(i=0;iswap) swapinline64(offset); recordcount = GETCOUNTER(offset); SKIPCOUNTER(offset); basetype = vlentype->basetype; /* This may be of any type potentially */ assert(basetype->sort == NCD4_TYPE); for(i=0;isubsort) { default: /* atomic basetype */ if((ret=walkAtomicVar(compiler,topvar,basetype,&offset))) goto done; break; case NC_OPAQUE: if((ret=walkOpaqueVar(compiler,topvar,basetype,&offset))) goto done; break; case NC_STRUCT: /* We can treat each record like a structure instance */ if((ret=walkStruct(compiler,topvar,basetype,&offset))) goto done; break; case NC_SEQ: if((ret=walkSeq(compiler,topvar,basetype,&offset))) goto done; break; } } *offsetp = offset; done: return THROW(ret); }