netcdf-c/ncgen/bindata.c
Peter Hill d07dac918c
Silence conversion warnings from malloc arguments
Mostly just add an explicit cast when calling `malloc` and its
variants. Sometimes instead change the type of a local variable if
this would silence multiple warnings.
2023-11-24 18:20:52 +00:00

601 lines
18 KiB
C

/*********************************************************************
* Copyright 2018, UCAR/Unidata
* See netcdf/COPYRIGHT file for copying and redistribution conditions.
*********************************************************************/
#include "includes.h"
#include "nclog.h"
#include <stddef.h>
#ifdef ENABLE_BINARY
/* Forward */
static void alignto(int alignment, Bytebuffer* buf, ptrdiff_t base);
static int bin_uid = 0;
static int
bin_charconstant(Generator* generator, Symbol* sym, Bytebuffer* buf, ...)
{
/* Just transfer charbuf to codebuf */
Bytebuffer* charbuf;
va_list ap;
va_start(ap,buf);
charbuf = va_arg(ap, Bytebuffer*);
va_end(ap);
bbNull(charbuf);
bbCatbuf(buf,charbuf);
return 1;
}
static int
bin_constant(Generator* generator, Symbol* sym, NCConstant* con, Bytebuffer* buf,...)
{
if(con->nctype != NC_ECONST) {
alignbuffer(con,buf);
}
switch (con->nctype) {
case NC_OPAQUE: {
unsigned char* bytes = NULL;
size_t len;
/* Assume the opaque string has been normalized */
bytes=makebytestring(con->value.opaquev.stringv,&len);
bbAppendn(buf,(void*)bytes,len);
efree(bytes);
} break;
case NC_CHAR:
bbAppendn(buf,&con->value.charv,sizeof(con->value.charv));
break;
case NC_BYTE:
bbAppendn(buf,(void*)&con->value.int8v,sizeof(con->value.int8v));
break;
case NC_SHORT:
bbAppendn(buf,(void*)&con->value.int16v,sizeof(con->value.int16v));
break;
case NC_INT:
bbAppendn(buf,(void*)&con->value.int32v,sizeof(con->value.int32v));
break;
case NC_FLOAT:
bbAppendn(buf,(void*)&con->value.floatv,sizeof(con->value.floatv));
break;
case NC_DOUBLE:
bbAppendn(buf,(void*)&con->value.doublev,sizeof(con->value.doublev));
break;
case NC_UBYTE:
bbAppendn(buf,(void*)&con->value.uint8v,sizeof(con->value.uint8v));
break;
case NC_USHORT:
bbAppendn(buf,(void*)&con->value.uint16v,sizeof(con->value.uint16v));
break;
case NC_UINT:
bbAppendn(buf,(void*)&con->value.uint32v,sizeof(con->value.uint32v));
break;
case NC_INT64: {
union SI64 { char ch[8]; long long i64;} si64;
si64.i64 = con->value.int64v;
bbAppendn(buf,(void*)si64.ch,sizeof(si64.ch));
} break;
case NC_UINT64: {
union SU64 { char ch[8]; unsigned long long i64;} su64;
su64.i64 = con->value.uint64v;
bbAppendn(buf,(void*)su64.ch,sizeof(su64.ch));
} break;
case NC_NIL:
case NC_STRING: {
size_t len = (size_t)con->value.stringv.len;
if(len == 0 && con->value.stringv.stringv == NULL) {
char* nil = NULL;
bbAppendn(buf,(void*)&nil,sizeof(nil));
} else {
char* ptr = (char*)ecalloc(len+1);
memcpy(ptr,con->value.stringv.stringv,len);
ptr[len] = '\0';
bbAppendn(buf,(void*)&ptr,sizeof(ptr));
ptr = NULL;
}
} break;
default: PANIC1("bin_constant: unexpected type: %d",con->nctype);
}
return 1;
}
static int
bin_listbegin(Generator* generator, Symbol* tsym, void* liststate, ListClass lc, size_t size, Bytebuffer* buf, int* uidp, ...)
{
if(uidp) *uidp = ++bin_uid;
if(lc == LISTCOMPOUND)
*((int*)liststate) = bbLength(buf);
return 1;
}
static int
bin_list(Generator* generator, Symbol* tsym, void* liststate, ListClass lc, int uid, size_t count, Bytebuffer* buf, ...)
{
if(lc == LISTCOMPOUND) {
int offsetbase = *((int*)liststate);
/* Pad for the alignment */
alignto(tsym->typ.alignment,buf,offsetbase);
}
return 1;
}
static int
bin_listend(Generator* generator, Symbol* tsym, void* liststate, ListClass lc, int uid, size_t count, Bytebuffer* buf, ...)
{
if(lc == LISTCOMPOUND) {
int offsetbase = *((int*)liststate);
/* Pad out the whole instance */
alignto(tsym->typ.cmpdalign,buf,offsetbase);
}
return 1;
}
static int
bin_vlendecl(Generator* generator, Symbol* tsym, Bytebuffer* buf, int uid, size_t count,...)
{
va_list ap;
Bytebuffer* vlenmem;
nc_vlen_t ptr;
va_start(ap,count);
vlenmem = va_arg(ap, Bytebuffer*);
va_end(ap);
ptr.len = count;
ptr.p = bbExtract(vlenmem);
bbAppendn(buf,(char*)&ptr,sizeof(ptr));
return 1;
}
static int
bin_vlenstring(Generator* generator, Symbol* sym, Bytebuffer* codebuf, int* uidp, size_t* sizep,...)
{
Bytebuffer* vlenmem;
nc_vlen_t ptr;
va_list ap;
if(uidp) *uidp = ++bin_uid;
va_start(ap,sizep);
vlenmem = va_arg(ap, Bytebuffer*);
va_end(ap);
ptr.len = bbLength(vlenmem);
ptr.p = bbDup(vlenmem);
bbAppendn(codebuf,(char*)&ptr,sizeof(ptr));
return 1;
}
static const char zeros[] =
"\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0";
static void
alignto(int alignment, Bytebuffer* buf, ptrdiff_t base)
{
int pad = 0;
ptrdiff_t offset = bbLength(buf);
offset -= base; /* Need to actually align wrt to the base */
pad = getpadding(offset,alignment);
if(pad > 0) {
bbAppendn(buf,(void*)zeros,pad);
}
}
/* Define the single static bin data generator */
static Generator bin_generator_singleton = {
NULL,
bin_charconstant,
bin_constant,
bin_listbegin,
bin_list,
bin_listend,
bin_vlendecl,
bin_vlenstring
};
Generator* bin_generator = &bin_generator_singleton;
/**************************************************/
static int bin_generate_data_r(NCConstant* instance, Symbol* tsym, Datalist* fillvalue, Bytebuffer* databuf);
static void
write_alignment(int alignment, Bytebuffer* buf)
{
int pad = 0;
ptrdiff_t offset = bbLength(buf);
pad = getpadding(offset,alignment);
if(pad > 0) {
bbAppendn(buf,(void*)zeros,pad);
}
}
/**
Alternate binary data generator.
Inputs:
Datalist* data - to use to generate the binary data
Symbol* tsym - the top-level type for which instances
are to be generated
Datalist* fillvalue - the fillvalue for the toplevel type
Bytebuffer* databuf - the buffer into which instances are to be stored
*/
int
binary_generate_data(Datalist* data, Symbol* tsym, Datalist* fillvalue, Bytebuffer* databuf)
{
int stat = NC_NOERR;
size_t count = data->length;
size_t i;
bbClear(databuf);
for(i=0;i<count;i++) {
NCConstant* instance = datalistith(data,i);
if((stat = bin_generate_data_r(instance, tsym, fillvalue, databuf))) goto done;
}
done:
return stat;
}
/* Recursive helper that does the bulk of the work */
static int
bin_generate_data_r(NCConstant* instance, Symbol* tsym, Datalist* fillvalue, Bytebuffer* databuf)
{
int stat = NC_NOERR;
if(instance->nctype == NC_FILLVALUE) {
/* replace with fillvalue for the type */
Datalist* filllist = (fillvalue == NULL ? getfiller(tsym) : fillvalue);
ASSERT(datalistlen(filllist)==1)
instance = datalistith(filllist,0);
}
switch (tsym->subclass) {
case NC_PRIM: {
switch (tsym->nc_id) {
case NC_CHAR: {
char* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_CHAR;
convert1(instance,tmp);
p = &tmp->value.charv;;
bbAppendn(databuf,p,sizeof(char));
reclaimconstant(tmp);
} break;
case NC_BYTE: {
signed char* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_BYTE;
convert1(instance,tmp);
p = &tmp->value.int8v;
bbAppendn(databuf,p,sizeof(signed char));
reclaimconstant(tmp);
} break;
case NC_UBYTE: {
unsigned char* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_UBYTE;
convert1(instance,tmp);
p = &tmp->value.uint8v;
bbAppendn(databuf,p,sizeof(unsigned char));
reclaimconstant(tmp);
} break;
case NC_SHORT: {
short* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_SHORT;
convert1(instance,tmp);
p = &tmp->value.int16v;
bbAppendn(databuf,p,sizeof(short));
reclaimconstant(tmp);
} break;
case NC_USHORT: {
unsigned short* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_USHORT;
convert1(instance,tmp);
p = &tmp->value.uint16v;
bbAppendn(databuf,p,sizeof(unsigned short));
reclaimconstant(tmp);
} break;
case NC_INT: {
int* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_INT;
convert1(instance,tmp);
p = &tmp->value.int32v;
bbAppendn(databuf,p,sizeof(int));
reclaimconstant(tmp);
} break;
case NC_UINT: {
unsigned int* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_UINT;
convert1(instance,tmp);
p = &tmp->value.uint32v;
bbAppendn(databuf,p,sizeof(unsigned int));
reclaimconstant(tmp);
} break;
case NC_INT64: {
long long* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_INT64;
convert1(instance,tmp);
p = &tmp->value.int64v;
bbAppendn(databuf,p,sizeof(long long));
reclaimconstant(tmp);
} break;
case NC_UINT64: {
unsigned long long* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_UINT64;
convert1(instance,tmp);
p = &tmp->value.uint64v;
bbAppendn(databuf,p,sizeof(unsigned long long));
reclaimconstant(tmp);
} break;
case NC_FLOAT: {
float* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_FLOAT;
convert1(instance,tmp);
p = &tmp->value.floatv;
bbAppendn(databuf,p,sizeof(float));
reclaimconstant(tmp);
} break;
case NC_DOUBLE: {
double* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_DOUBLE;
convert1(instance,tmp);
p = &tmp->value.doublev;
bbAppendn(databuf,p,sizeof(double));
reclaimconstant(tmp);
} break;
case NC_STRING: {
char* p = NULL;
NCConstant* tmp = nullconst();
tmp->nctype = NC_STRING;
convert1(instance,tmp);
p = emalloc((size_t)tmp->value.stringv.len+1);
memcpy(p,tmp->value.stringv.stringv, (size_t)tmp->value.stringv.len);
p[tmp->value.stringv.len] = '\0';
bbAppendn(databuf,&p,sizeof(char*));
reclaimconstant(tmp);
} break;
default: stat = NC_EINTERNAL; goto done; /* Should never happen */
} break; /*switch*/
} break; /*NC_PRIM*/
case NC_ENUM: {
Symbol* basetype = tsym->typ.basetype;
/* Pretend */
stat = bin_generate_data_r(instance,basetype,fillvalue,databuf);
} break;
case NC_OPAQUE: {
unsigned char* bytes = NULL;
size_t len = 0;
if(instance->nctype != NC_OPAQUE)
{stat = NC_EBADTYPE; goto done;}
/* Assume the opaque string has been normalized */
bytes=makebytestring(instance->value.opaquev.stringv,&len);
if(bytes == NULL) {stat = NC_ENOMEM; goto done;}
bbAppendn(databuf,(void*)bytes,len);
free(bytes);
} break;
case NC_VLEN: {
Datalist* sublist = NULL;
Bytebuffer* vlendata = NULL;
nc_vlen_t p;
if(instance->nctype != NC_COMPOUND) {
nclog(NCLOGERR,"Translating vlen: expected sublist");
stat = NC_EBADTYPE; goto done;
}
sublist = instance->value.compoundv;
vlendata = bbNew();
if((stat = binary_generate_data(sublist,tsym->typ.basetype,NULL,vlendata))) goto done;
p.len = datalistlen(sublist);
p.p = bbContents(vlendata);
bbAppendn(databuf,(char*)&p,sizeof(nc_vlen_t));
} break;
case NC_COMPOUND: { /* The really hard one */
size_t nfields, fid, i;
Datalist* cmpd = instance->value.compoundv;
write_alignment(tsym->typ.cmpdalign,databuf);
/* Get info about each field in turn and build it*/
nfields = listlength(tsym->subnodes);
for(fid=0;fid<nfields;fid++) {
Symbol* field = listget(tsym->subnodes,fid);
NCConstant* fieldinstance = datalistith(cmpd,fid);
int ndims = field->typ.dimset.ndims;
size_t arraycount = 1;
if(ndims == 0) {
ndims=1; /* fake the scalar case */
}
/* compute the total number of elements in the field array */
for(i=0;i<ndims;i++) arraycount *= field->typ.dimset.dimsyms[i]->dim.declsize;
write_alignment(field->typ.alignment,databuf);
/* Write the instances */
for(i=0;i<arraycount;i++) {
if((stat = bin_generate_data_r(fieldinstance, field->typ.basetype, NULL, databuf))) goto done;
}
}
} break;
default: stat = NC_EINTERNAL; goto done; /* Should never happen */
}
done:
return stat;
}
#if 0
/**
Internal equivalent of ncaux_reclaim_data.
*/
/* It is helpful to have a structure that contains memory and an offset */
typedef struct Reclaim {char* memory; ptrdiff_t offset;} Reclaim;
static int bin_reclaim_datar(Symbol* tsym, Reclaim* reclaim);
#ifdef USE_NETCDF4
static ptrdiff_t read_alignment(ptrdiff_t offset, unsigned long alignment);
static int bin_reclaim_usertype(Symbol* tsym, Reclaim* reclaim);
static int bin_reclaim_compound(Symbol* tsym, Reclaim* reclaim);
static int bin_reclaim_vlen(Symbol* tsym, Reclaim* reclaim);
static int bin_reclaim_enum(Symbol* tsym, Reclaim* reclaim);
static int bin_reclaim_opaque(Symbol* tsym, Reclaim* reclaim);
#endif
int
binary_reclaim_data(Symbol* tsym, void* memory, size_t count)
{
int stat = NC_NOERR;
size_t i;
Reclaim reclaimer;
if(tsym == NULL
|| (memory == NULL && count > 0))
{stat = NC_EINVAL; goto done;}
if(memory == NULL || count == 0)
goto done; /* ok, do nothing */
reclaimer.offset = 0;
reclaimer.memory = memory;
for(i=0;i<count;i++) {
if((stat=bin_reclaim_datar(tsym,&reclaimer))) /* reclaim one instance */
break;
}
done:
return stat;
}
/* Recursive type walker: reclaim a single instance */
static int
bin_reclaim_datar(Symbol* tsym, Reclaim* reclaimer)
{
int stat = NC_NOERR;
switch (tsym->subclass) {
case NC_CHAR: case NC_BYTE: case NC_UBYTE:
case NC_SHORT: case NC_USHORT:
case NC_INT: case NC_UINT: case NC_FLOAT:
case NC_INT64: case NC_UINT64: case NC_DOUBLE:
reclaimer->offset += tsym->typ.size;
break;
#ifdef USE_NETCDF4
case NC_STRING: {
char** sp = (char**)(reclaimer->memory+reclaimer->offset);
/* Need to reclaim string */
if(*sp != NULL) efree(*sp);
reclaimer->offset += tsym->typ.size;
} break;
default:
/* reclaim a user type */
stat = bin_reclaim_usertype(tsym,reclaimer);
#else
default:
stat = NC_ENOTNC4;
#endif
break;
}
return stat;
}
#ifdef USE_NETCDF4
static int
bin_reclaim_usertype(Symbol* tsym, Reclaim* reclaimer)
{
int stat = NC_NOERR;
/* Get info about the xtype */
switch (tsym->subclass) {
case NC_OPAQUE: stat = bin_reclaim_opaque(tsym,reclaimer); break;
case NC_ENUM: stat = bin_reclaim_enum(tsym,reclaimer); break;
case NC_VLEN: stat = bin_reclaim_vlen(tsym,reclaimer); break;
case NC_COMPOUND: stat = bin_reclaim_compound(tsym,reclaimer); break;
default:
stat = NC_EINVAL;
break;
}
return stat;
}
static ptrdiff_t
read_alignment(ptrdiff_t offset, unsigned long alignment)
{
size_t delta = (offset % alignment);
if(delta == 0) return offset;
return offset + (alignment - delta);
}
static int
bin_reclaim_vlen(Symbol* tsym, Reclaim* reclaimer)
{
int stat = NC_NOERR;
size_t i;
Symbol* basetype = tsym->typ.basetype;
nc_vlen_t* vl = (nc_vlen_t*)(reclaimer->memory+reclaimer->offset);
/* Free up each entry in the vlen list */
if(vl->p != NULL) {
Reclaim vreclaimer;
vreclaimer.memory = vl->p;
vreclaimer.offset = 0;
for(i=0;i<vl->len;i++) {
vreclaimer.offset = read_alignment(vreclaimer.offset,basetype->typ.alignment);
if((stat = bin_reclaim_datar(basetype,&vreclaimer))) goto done;
vreclaimer.offset += basetype->typ.size;
}
reclaimer->offset += tsym->typ.size;
efree(vl->p);
}
done:
return stat;
}
static int
bin_reclaim_enum(Symbol* tsym, Reclaim* reclaimer)
{
return bin_reclaim_datar(tsym->typ.basetype,reclaimer);
}
static int
bin_reclaim_opaque(Symbol* tsym, Reclaim* reclaimer)
{
/* basically a fixed size sequence of bytes */
reclaimer->offset += tsym->typ.size;
return NC_NOERR;
}
static int
bin_reclaim_compound(Symbol* tsym, Reclaim* reclaimer)
{
int stat = NC_NOERR;
int nfields;
size_t fid, i;
size_t arraycount = 1;
ptrdiff_t saveoffset;
reclaimer->offset = read_alignment(reclaimer->offset,tsym->typ.cmpdalign);
saveoffset = reclaimer->offset;
/* Get info about each field in turn and reclaim it */
nfields = listlength(tsym->subnodes);
for(fid=0;fid<nfields;fid++) {
Symbol* field = listget(tsym->subnodes,fid);
int ndims = field->typ.dimset.ndims;
/* compute the total number of elements in the field array */
for(i=0;i<ndims;i++) arraycount *= field->typ.dimset.dimsyms[i]->dim.declsize;
reclaimer->offset = read_alignment(reclaimer->offset,field->typ.alignment);
for(i=0;i<arraycount;i++) {
if((stat = bin_reclaim_datar(field->typ.basetype, reclaimer))) goto done;
}
}
reclaimer->offset = saveoffset;
reclaimer->offset += tsym->typ.size;
done:
return stat;
}
#endif /*USE_NETCDF4*/
#endif /*0*/
#endif /*ENABLE_BINARY*/