netcdf-c/ncgen/genchar.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

385 lines
13 KiB
C

/*********************************************************************
* Copyright 2018, UCAR/Unidata
* See netcdf/COPYRIGHT file for copying and redistribution conditions.
*********************************************************************/
#include "includes.h"
/******************************************************/
/* Code for generating char variables etc; mostly
language independent */
/******************************************************/
/*Forward*/
static size_t gen_charconstant(NCConstant*, Bytebuffer*, int fillchar);
static int getfillchar(Datalist* fillsrc);
static void gen_leafchararray(Dimset*,int,Datalist*,Bytebuffer*, int);
static NCConstant* makeconst(int lineno, int len, char* str);
static void rebuildsingletons(Datalist* data);
/*
Matching strings to char variables, attributes, and vlen
constants is challenging because it is desirable to mimic
the original ncgen(3). The "algorithms" used there have no
simple characterization (such as "abc" == {'a','b','c'}).
So, this rather ugly code is kept in this file
and a variety of heuristics are used to mimic ncgen3.
The core algorithm is as follows.
1. Assume we have a set of dimensions D1..Dn.
Any of the Di may be unlimited,
but it is assumed that the sizes of the Di are all known.
2. Given a sequence of string or character constants
C1..Cm, our goal is to construct a single string
whose length is the cross product of D1 thru Dn.
3. For purposes of this algorithm, character constants
are treated as strings of size 1.
4. Construct Dx = cross product of D1 thru D(n-1).
5. For each constant Ci, add fill characters, if necessary,
so that its length is a multiple of Dn.
6. Concatenate the modified C1..Cm to produce string S.
7. Add fill characters to S to make its size be a multiple of
Dn.
8. If S is longer than the Dx * Dn, then truncate
and generate a warning.
Two special cases:
1. character vlen: char(*) vlen_t.
For this case, we simply concat all the elements.
2. character attribute.
For this case, we simply concat all the elements.
*/
void
gen_chararray(Dimset* dimset, int dimindex, Datalist* data, Bytebuffer* charbuf, Datalist* fillsrc)
{
int fillchar = getfillchar(fillsrc);
int rank = rankfor(dimset);
int firstunlim = findunlimited(dimset,0);
int nunlim = countunlimited(dimset);
int nc3unlim = (nunlim <= 1 && (firstunlim == 0 || firstunlim == rank)); /* netcdf-3 case of at most 1 unlim in 0th dimension */
/* Case: netcdf3 case */
if(nc3unlim) {
gen_leafchararray(dimset,0,data,charbuf,fillchar);
return;
}
#if 0
if(dimindex < (rank - 1)) {
size_t stop = datalistlen(data);
size_t offset;
for(offset=0;offset<stop;offset++) {
NCConstant* con = datalistith(data,offset);
ASSERT((islistconst(con)));
gen_chararray(dimset,dimindex+1,compoundfor(con),charbuf,fillsrc);
}
} else
#endif
gen_leafchararray(dimset,dimindex,data,charbuf,fillchar);
}
/* I think there is a flaw in the ncgen manual
about handling something like this:
dimensions:
n = 8 ;
variables:
char cdata2(n) ;
data:
cdata2 = '\000','\001','\002','\177','\200','\201','\376','\377';
The rules would say that each of the 8 char constants must
be padded to length 8. I think this is only true if the dimension
is unlimited, and even then, I am not sure.
*/
static void
gen_leafchararray(Dimset* dimset, int dimindex, Datalist* data,
Bytebuffer* charbuf, int fillchar)
{
int i;
size_t expectedsize,xproduct,unitsize;
int rank = rankfor(dimset);
Datalist* flat = NULL;
#if 0
ASSERT(bbLength(charbuf) == 0);
ASSERT((findlastunlimited(dimset) == rank || findlastunlimited(dimset) == dimindex));
#endif
/*
There are a number of special cases that must be
considered, mostly driven by the need to keep consistent
with ncgen3. These cases are driven by the number of
dimensions, which dimensions are unlimited (if any), etc.
The general rule is based on the size of the last
dimension, we compute the required size (after padding)
of each string constant. Expected size is then the size
of concat of the string constants after padding.
*/
/*
There is another special case used for back compatibility with ncgen3.
In the datalist, all sequences of character constants (i.e. 'X')
are concatenated into a single string; the result, however is not
concatenated with any trailing or leading string (with double quotes).
*/
rebuildsingletons(data);
/* Compute crossproduct from dimindex up to (but not including) the last dimension */
xproduct = crossproduct(dimset,dimindex,rank-1);
/* Start casing it out */
if(rank == 0) {
unitsize = 1;
expectedsize = (xproduct * unitsize);
} else if(rank == 1) {
unitsize = 1;
expectedsize = (xproduct * declsizefor(dimset,rank-1));
} else if(isunlimited(dimset,rank-1)) {/* last dimension is unlimited */
unitsize = 1;
expectedsize = (xproduct*declsizefor(dimset,rank-1));
} else if(rank > 0 && !isunlimited(dimset,rank-1)) {/*last dim is not unlimited */
unitsize = declsizefor(dimset,rank-1);
expectedsize = (xproduct * unitsize);
} else
abort(); /* in case we forgot a case */
flat = flatten(data,rank);
for(i=0;i<flat->length;i++) {
NCConstant* c = datalistith(flat,i);
ASSERT(!islistconst(c));
if(isstringable(c->nctype)) {
int j;
size_t constsize;
constsize = gen_charconstant(c,charbuf,fillchar);
if(constsize == 0 || constsize % unitsize > 0) {
size_t padsize = unitsize - (constsize % unitsize);
for(j=0;j<padsize;j++) bbAppend(charbuf,fillchar);
}
} else {
semwarn(constline(c),"Encountered non-string and non-char constant in datalist; ignored");
}
}
freedatalist(flat);
/* If |databuf| > expectedsize, complain: exception is zero length */
if(bbLength(charbuf) == 0 && expectedsize == 1) {
/* this is okay */
} else if(bbLength(charbuf) > expectedsize) {
semwarn(flat->data[0]->lineno,"character data list too long; expected %d character constant, found %d: ",expectedsize,bbLength(charbuf));
} else {
size_t bufsize = bbLength(charbuf);
/* Pad to size dimproduct size */
if(bufsize % expectedsize > 0) {
size_t padsize = expectedsize - (bufsize % expectedsize);
for(i=0;i<padsize;i++) bbAppend(charbuf,fillchar);
}
}
}
void
gen_charattr(Datalist* data, Bytebuffer* databuf)
{
gen_charseq(data,databuf);
}
void
gen_charseq(Datalist* data, Bytebuffer* databuf)
{
int i;
NCConstant* c;
ASSERT(bbLength(databuf) == 0);
for(i=0;i<data->length;i++) {
c = datalistith(data,i);
if(isstringable(c->nctype)) {
(void)gen_charconstant(c,databuf,NC_FILL_CHAR);
} else {
semerror(constline(c),
"Encountered non-string and non-char constant in datalist");
return;
}
}
}
static size_t
gen_charconstant(NCConstant* con, Bytebuffer* databuf, int fillchar)
{
/* Following cases should be consistent with isstringable */
size_t constsize = 1;
switch (con->nctype) {
case NC_CHAR:
bbAppend(databuf,con->value.charv);
break;
case NC_BYTE:
bbAppend(databuf,con->value.int8v);
break;
case NC_UBYTE:
bbAppend(databuf,con->value.uint8v);
break;
case NC_STRING:
constsize = con->value.stringv.len;
if(constsize > 0)
bbAppendn(databuf,con->value.stringv.stringv,
con->value.stringv.len);
bbNull(databuf);
break;
case NC_FILL:
bbAppend(databuf,fillchar);
break;
default:
PANIC("unexpected constant type");
}
return constsize;
}
/* Create a new string constant */
static NCConstant*
makeconst(int lineno, int len, char* str)
{
NCConstant* con = nullconst();
con->nctype = NC_STRING;
con->lineno = lineno;
con->filled = 0;
con->value.stringv.len = len;
/* We cannot use strdup because str might have embedded nuls */
con->value.stringv.stringv = (char*)ecalloc((size_t)len+1);
memcpy((void*)con->value.stringv.stringv,(void*)str, (size_t)len);
con->value.stringv.stringv[len] = '\0';
return con;
}
static int
getfillchar(Datalist* fillsrc)
{
/* Determine the fill char */
int fillchar = 0;
if(fillsrc != NULL && fillsrc->length > 0) {
NCConstant* ccon = fillsrc->data[0];
if(ccon->nctype == NC_CHAR) {
fillchar = ccon->value.charv;
} else if(ccon->nctype == NC_STRING) {
if(ccon->value.stringv.len > 0) {
fillchar = ccon->value.stringv.stringv[0];
}
}
}
if(fillchar == 0) fillchar = NC_FILL_CHAR; /* default */
return fillchar;
}
/* Rebuild the datalist to merge '0x' constants; WARNING: this is tricky. */
static void
rebuildsingletons(Datalist* data)
{
int i,cccount = 0;
/* Do initial walk */
for(i=0;i<datalistlen(data);i++) {
NCConstant* con = datalistith(data,i);
if(consttype(con) == NC_CHAR || consttype(con) == NC_BYTE) {
cccount++;
}
}
if(cccount > 1) {
Bytebuffer* accum = bbNew();
int len = 0; /* >0 implies doing accum */
Datalist* newlist = builddatalist(datalistlen(data));
int lineno = 0;
NCConstant* con;
/* We are going to construct a single string constant for each
contiguous sequence of single char values.
Assume that the constants are all primitive types */
for(i=0;i<datalistlen(data);i++) {
con = datalistith(data,i);
if(consttype(con) == NC_CHAR || consttype(con) == NC_BYTE) {
if(len == 0) { /* Start an accumulation */
lineno = constline(con);
bbClear(accum);
}
bbAppend(accum,con->value.charv);
len++;
/* Discard this constant */
reclaimconstant(con);
} else {
if(len > 0) { /* End the accumulation */
bbNull(accum);
con = makeconst(lineno,len,bbContents(accum));
len = 0;
lineno = 0;
dlappend(newlist,con);
} else
dlappend(newlist,con);
}
}
/* deal with any unclosed strings */
if(len > 0) {
con = makeconst(lineno,len,bbContents(accum));
len = 0;
lineno = 0;
dlappend(newlist,con);
}
bbFree(accum);
/* Move the newlist sequence of constants into the old list */
efree(data->data);
data->data = newlist->data;
data->length = newlist->length;
data->alloc = newlist->alloc;
efree(newlist);
}
}
#if 0
/* Recursive helper */
static void
gen_chararrayr(Dimset* dimset, int dimindex,
Bytebuffer* databuf, Datalist* data, int fillchar,
int unitsize, int expectedsize)
{
int i;
size_t dimsize = declsizefor(dimset,dimindex);
int rank = dimset->ndims;
int firstunlim = findunlimited(dimset,0);
int lastunlimited = findlastunlimited(dimset);
int nextunlimited = findunlimited(dimset,dimindex+1);
int islastgroup = (lastunlimited == rank || dimindex >= lastunlimited || dimindex == rank-1);
ASSERT(rank > 0);
ASSERT((islastgroup));
/* we should be at a list of simple constants */
for(i=0;i<data->length;i++) {
NCConstant* c = datalistith(data,i);
ASSERT(!islistconst(c));
if(isstringable(c->nctype)) {
int j;
size_t constsize;
constsize = gen_charconstant(c,databuf,fillchar);
if(constsize % unitsize > 0) {
size_t padsize = unitsize - (constsize % unitsize);
for(j=0;j<padsize;j++) bbAppend(databuf,fillchar);
}
} else {
semwarn(constline(c),
"Encountered non-string and non-char constant in datalist; ignored");
}
}/* for */
/* If |databuf| > expectedsize, complain: exception is zero length */
if(bbLength(databuf) == 0 && expectedsize == 1) {
/* this is okay */
} else if(bbLength(databuf) > expectedsize) {
semwarn(data->data[0].lineno,"character data list too long; expected %lu character constant, found %lu: ",expectedsize,(unsigned long)bbLength(databuf));
} else {
size_t bufsize = bbLength(databuf);
/* Pad to size dimproduct size */
if(bufsize % expectedsize > 0) {
size_t padsize = expectedsize - (bufsize % expectedsize);
for(i=0;i<padsize;i++) bbAppend(databuf,fillchar);
}
}
}
#endif