netcdf-c/ncgen/data.c

/*********************************************************************
 *   Copyright 2009, UCAR/Unidata
 *   See netcdf/COPYRIGHT file for copying and redistribution conditions.
 *********************************************************************/
/* $Id: data.c,v 1.7 2010/05/24 19:59:56 dmh Exp $ */
/* $Header: /upc/share/CVS/netcdf-3/ncgen/data.c,v 1.7 2010/05/24 19:59:56 dmh Exp $ */

#include        "includes.h"
#include        "offsets.h"
#include        "dump.h"

#define XVSNPRINTF vsnprintf
/*
#define XVSNPRINTF lvsnprintf
extern int lvsnprintf(char*, size_t, const char*, va_list);
*/

#define DATALISTINIT 32

/* Track all known datalist*/
Datalist* alldatalists = NULL;

NCConstant nullconstant;
NCConstant fillconstant;

Datalist nildatalist; /* to support NIL keyword */

Bytebuffer* codebuffer;
Bytebuffer* codetmp;
Bytebuffer* stmt;


/* Forward */

/**************************************************/
/**************************************************/

/* return 1 if the next element in the datasrc is compound*/
int
issublist(Datasrc* datasrc) {return istype(datasrc,NC_COMPOUND);}

/* return 1 if the next element in the datasrc is a string*/
int
isstring(Datasrc* datasrc) {return istype(datasrc,NC_STRING);}

/* return 1 if the next element in the datasrc is a fill value*/
int
isfillvalue(Datasrc* datasrc)
{
return srcpeek(datasrc) == NULL || istype(datasrc,NC_FILLVALUE);
}

/* return 1 if the next element in the datasrc is nc_type*/
int
istype(Datasrc* datasrc , nc_type nctype)
{
    NCConstant* ci = srcpeek(datasrc);
    if(ci != NULL && ci->nctype == nctype) return 1;
    return 0;
}

int
isstringable(nc_type nctype)
{
    switch (nctype) {
    case NC_CHAR: case NC_STRING:
    case NC_BYTE: case NC_UBYTE:
    case NC_FILLVALUE:
	return 1;
    default: break;
    }
    return 0;
}

/**************************************************/

void
freedatasrc(Datasrc* src)
{
    efree(src);
}

Datasrc*
allocdatasrc(void)
{
    Datasrc* src;
    src = emalloc(sizeof(Datasrc));
    src->data = NULL;
    src->index = 0;
    src->length = 0;
    src->prev = NULL;
    return src;
}

Datasrc*
datalist2src(Datalist* list)
{
    Datasrc* src;
    ASSERT(list != NULL);
    src = allocdatasrc();
    src->data = list->data;
    src->index = 0;
    src->length = list->length;
    DUMPSRC(src,"#");
    return src;
}

Datasrc*
const2src(NCConstant* con)
{
    Datasrc* src;
    ASSERT(con != NULL);
    src = allocdatasrc();
    src->data = con;
    src->index = 0;
    src->length = 1;
    DUMPSRC(src,"#");
    return src;
}

NCConstant
list2const(Datalist* list)
{
    NCConstant con;
    ASSERT(list != NULL);
    con.nctype = NC_COMPOUND;
    con.lineno = list->data[0].lineno;
    con.value.compoundv = list;
    con.filled = 0;
    return con;
}

Datalist*
const2list(NCConstant* con)
{
    Datalist* list;
    ASSERT(con != NULL);
    list = builddatalist(1);
    if(list != NULL) {
        dlappend(list,con);
    }
    return list;
}

NCConstant*
srcpeek(Datasrc* ds)
{
    if(ds == NULL) return NULL;
    if(ds->index < ds->length)
	return &ds->data[ds->index];
    if(ds->spliced)
	return srcpeek(ds->prev);
    return NULL;
}

NCConstant*
srcnext(Datasrc* ds)
{
    DUMPSRC(ds,"!");
    if(ds == NULL) return NULL;
    if(ds->index < ds->length)
	return &ds->data[ds->index++];
    if(ds->spliced) {
	srcpop(ds);
	return srcnext(ds);
    }
    return NULL;
}

int
srcmore(Datasrc* ds)
{
    if(ds == NULL) return 0;
    if(ds->index < ds->length) return 1;
    if(ds->spliced) return srcmore(ds->prev);
    return 0;
}

int
srcline(Datasrc* ds)
{
    int index = ds->index;
    int len = ds->length;
    /* pick closest available entry*/
    if(len == 0) return 0;
    if(index >= len) index = len-1;
    return ds->data[index].lineno;
}

void
srcpush(Datasrc* src)
{
    NCConstant* con;
    ASSERT(src != NULL);
    con = srcnext(src);
    ASSERT(con->nctype == NC_COMPOUND);
    srcpushlist(src,con->value.compoundv);
}

void
srcpushlist(Datasrc* src, Datalist* dl)
{
    Datasrc* newsrc;
    ASSERT(src != NULL && dl != NULL);
    newsrc = allocdatasrc();
    *newsrc = *src;
    src->prev = newsrc;
    src->index = 0;
    src->data = dl->data;
    src->length = dl->length;
    DUMPSRC(src,">!");
}

void
srcpop(Datasrc* src)
{
    if(src != NULL) {
        Datasrc* prev = src->prev;
	*src = *prev;
        freedatasrc(prev);
    }
    DUMPSRC(src,"<");
}

void
srcsplice(Datasrc* ds, Datalist* list)
{
    srcpushlist(ds,list);
    ds->spliced = 1;    
}

void
srcsetfill(Datasrc* ds, Datalist* list)
{
    if(ds->index >= ds->length) PANIC("srcsetfill: no space");
    if(ds->data[ds->index].nctype != NC_FILLVALUE) PANIC("srcsetfill: not fill");
    ds->data[ds->index].nctype = NC_COMPOUND;
    ds->data[ds->index].value.compoundv = list;
}


/**************************************************/
#ifdef GENDEBUG
void
report(char* lead, Datalist* list)
{
extern void bufdump(Datalist*,Bytebuffer*);
Bytebuffer* buf = bbNew();
bufdump(list,buf);
fprintf(stderr,"\n%s::%s\n",lead,bbContents(buf));
fflush(stderr);
bbFree(buf);
}

void
report0(char* lead, Datasrc* src, int index)
{
}
#endif

/**************************************************/

/* Shallow constant cloning*/
NCConstant
cloneconstant(NCConstant* con)
{
    NCConstant newcon = *con;
    char* s;
    switch (newcon.nctype) {
    case NC_STRING:
	s = (char*)emalloc(newcon.value.stringv.len+1);
	memcpy(s,newcon.value.stringv.stringv,newcon.value.stringv.len);
	s[newcon.value.stringv.len] = '\0';
	newcon.value.stringv.stringv = s;
	break;
    case NC_OPAQUE:
	s = (char*)emalloc(newcon.value.opaquev.len+1);
	memcpy(s,newcon.value.opaquev.stringv,newcon.value.opaquev.len);
	s[newcon.value.opaquev.len] = '\0';
	newcon.value.opaquev.stringv = s;
	break;
    default: break;
    }
    return newcon;
}

/**************************************************/

Datalist*
datalistclone(Datalist* dl)
{
    int i;
    Datalist* clone = builddatalist(dl->length);
    for(i=0;i<dl->length;i++) {
	clone->data[i] = cloneconstant(dl->data+i);
    }
    return clone;
}

Datalist*
datalistconcat(Datalist* dl1, Datalist* dl2)
{
    NCConstant* vector;
    ASSERT(dl1 != NULL);
    if(dl2 == NULL) return dl1;
    vector = (NCConstant*)erealloc(dl1->data,sizeof(NCConstant)*(dl1->length+dl2->length));
    if(vector == NULL) return NULL;
    memcpy((void*)(vector+dl1->length),dl2->data,sizeof(NCConstant)*(dl2->length));
    dl1->data = vector;
    return dl1;
}

Datalist*
datalistappend(Datalist* dl, NCConstant* con)
{
    NCConstant* vector;
    ASSERT(dl != NULL);
    if(con == NULL) return dl;
    vector = (NCConstant*)erealloc(dl->data,sizeof(NCConstant)*(dl->length+1));
    if(vector == NULL) return NULL;
    vector[dl->length] = *con;
    dl->length++;
    dl->data = vector;
    return dl;
}

Datalist*
datalistreplace(Datalist* dl, unsigned int index, NCConstant* con)
{
    ASSERT(dl != NULL);
    ASSERT(index < dl->length);
    ASSERT(con != NULL);
    dl->data[index] = *con;
    return dl;
}

int
datalistline(Datalist* ds)
{
    if(ds == NULL || ds->length == 0) return 0;
    return ds->data[0].lineno;
}


/* Go thru a databuf of possibly nested constants
   and insert commas as needed; ideally, this
   operation should be idempotent so that
   the caller need not worry about it having already
   been applied. Also, handle situation where there may be missing
   matching right braces.
*/

static char* commifyr(char* p, Bytebuffer* buf);
static char* wordstring(char* p, Bytebuffer* buf, int quote);

void
commify(Bytebuffer* buf)
{
    char* list,*p;

    if(bbLength(buf) == 0) return;
    list = bbDup(buf);
    p = list;
    bbClear(buf);
    commifyr(p,buf);
    bbNull(buf);
    efree(list);
}

/* Requires that the string be balanced
   WRT to braces
*/
static char*
commifyr(char* p, Bytebuffer* buf)
{
    int comma = 0;
    int c;
    while((c=*p++)) {
	if(c == ' ') continue;
	if(c == ',') continue;
	else if(c == '}') {
	    break;
	}
	if(comma) bbCat(buf,", "); else comma=1;
	if(c == '{') {
	    bbAppend(buf,'{');
	    p = commifyr(p,buf);
	    bbAppend(buf,'}');
	} else if(c == '\'' || c == '\"') {
	    p = wordstring(p,buf,c);
	} else {
	    bbAppend(buf,c);
	    p=word(p,buf);
	}
    }    
    return p;
}

char*
word(char* p, Bytebuffer* buf)
{
    int c;
    while((c=*p++)) {
	if(c == '}' || c == ' ' || c == ',') break;
	if(c == '\\') {
	    bbAppend(buf,c);
	    c=*p++;
	    if(!c) break;
	}
	bbAppend(buf,(char)c);	
    }	
    p--; /* leave terminator for parent */
    return p;
}

static char*
wordstring(char* p, Bytebuffer* buf, int quote)
{
    int c;
    bbAppend(buf,quote);
    while((c=*p++)) {	    
	if(c == '\\') {
	    bbAppend(buf,c);
	    c = *p++;
	    if(c == '\0') return --p;
	} else if(c == quote) {
	    bbAppend(buf,c);
	    return p;
	}
	bbAppend(buf,c);
    }
    return p;
}


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";
void
alignbuffer(NCConstant* prim, Bytebuffer* buf)
{
    int alignment,pad,offset;

    if(prim->nctype == NC_ECONST)
        alignment = nctypealignment(prim->value.enumv->typ.typecode);
    else if(usingclassic && prim->nctype == NC_STRING)
        alignment = nctypealignment(NC_CHAR);
    else if(prim->nctype == NC_CHAR)
        alignment = nctypealignment(NC_CHAR);
    else
        alignment = nctypealignment(prim->nctype);
    offset = bbLength(buf);
    pad = getpadding(offset,alignment);
    if(pad > 0) {
	bbAppendn(buf,(void*)zeros,pad);
    }
}



/*
Following routines are in support of language-oriented output
*/

void
codedump(Bytebuffer* buf)
{
   bbCatbuf(codebuffer,buf);
   bbClear(buf);
}

void
codepartial(const char* txt)
{
    bbCat(codebuffer,txt);
}

void
codeline(const char* line)
{
    codepartial(line);
    codepartial("\n");
}

void
codelined(int n, const char* txt)
{
    bbindent(codebuffer,n);
    bbCat(codebuffer,txt);
    codepartial("\n");
}

void
codeflush(void)
{
    if(bbLength(codebuffer) > 0) {
        bbNull(codebuffer);
        fputs(bbContents(codebuffer),stdout);
        fflush(stdout);
        bbClear(codebuffer);
    }
}

void
bbindent(Bytebuffer* buf, const int n)
{
    bbCat(buf,indented(n));
}

/* Provide an restrict snprintf that writes to an expandable buffer */
/* Simulates a simple snprintf because apparently
   the IRIX one is broken wrt return value.
   Supports only %u %d %f %s and %% specifiers
   with optional leading hh or ll.
*/

static void
vbbprintf(Bytebuffer* buf, const char* fmt, va_list argv)
{
    char tmp[128];
    const char* p;
    int c;
    int hcount;
    int lcount;

    char* text;

    for(p=fmt;(c=*p++);) {
	hcount = 0; lcount = 0;
	switch (c) {
	case '%':
retry:	    switch ((c=*p++)) {
	    case '\0': bbAppend(buf,'%'); p--; break;
	    case '%': bbAppend(buf,c); break;
	    case 'h':
		hcount++;
		while((c=*p) && (c == 'h')) {hcount++; p++;}
		if(hcount > 2) hcount = 2;
		goto retry;	        
	    case 'l':
		lcount++;
		while((c=*p) && (c == 'l')) {
		    lcount++;
		    p++;
		}
		if(lcount > 2) lcount = 2;
		goto retry;	        
	    case 'u':
		if(hcount == 2) {
   	            snprintf(tmp,sizeof(tmp),"%hhu",
			(unsigned int)va_arg(argv,unsigned int));
		} else if(hcount == 1) {
   	            snprintf(tmp,sizeof(tmp),"%hu",
			(unsigned int)va_arg(argv,unsigned int));
		} else if(lcount == 2) {
   	            snprintf(tmp,sizeof(tmp),"%llu",
			(unsigned long long)va_arg(argv,unsigned long long));
		} else if(lcount == 1) {
   	            snprintf(tmp,sizeof(tmp),"%lu",
			(unsigned long)va_arg(argv,unsigned long));
		} else {
   	            snprintf(tmp,sizeof(tmp),"%u",
			(unsigned int)va_arg(argv,unsigned int));
		}
		bbCat(buf,tmp);
		break;
	    case 'd':
		if(hcount == 2) {
   	            snprintf(tmp,sizeof(tmp),"%hhd",
			(signed int)va_arg(argv,signed int));
		} else if(hcount == 1) {
   	            snprintf(tmp,sizeof(tmp),"%hd",
			(signed int)va_arg(argv,signed int));
		} else if(lcount == 2) {
   	            snprintf(tmp,sizeof(tmp),"%lld",
			(signed long long)va_arg(argv,signed long long));
		} else if(lcount == 1) {
   	            snprintf(tmp,sizeof(tmp),"%ld",
			(signed long)va_arg(argv,signed long));
		} else {
   	            snprintf(tmp,sizeof(tmp),"%d",
			(signed int)va_arg(argv,signed int));
		}
		bbCat(buf,tmp);
		break;
            case 'f':
		if(lcount > 0) {
   	            snprintf(tmp,sizeof(tmp),"((double)%.16g)",
			(double)va_arg(argv,double));
		} else {
   	            snprintf(tmp,sizeof(tmp),"((float)%.8g)",
			(double)va_arg(argv,double));
		}
		bbCat(buf,tmp);
	        break;
	    case 's':
		text = va_arg(argv,char*);
		bbCat(buf,text);
		break;		
	    case 'c':
		c = va_arg(argv,int);
		bbAppend(buf,(char)c);
		break;		
            default:
		PANIC1("vbbprintf: unknown specifier: %c",(char)c);
	    }
	    break;
	default: 
	    bbAppend(buf,c);
	}
    }
}

void
bbprintf(Bytebuffer* buf, const char *fmt, ...)
{
    va_list argv;
    va_start(argv,fmt);
    vbbprintf(buf,fmt,argv);
    va_end(argv);
}

void
bbprintf0(Bytebuffer* buf, const char *fmt, ...)
{
    va_list argv;
    va_start(argv,fmt);
    bbClear(buf);
    vbbprintf(buf,fmt,argv);
    va_end(argv);
}

void
codeprintf(const char *fmt, ...)
{
    va_list argv;
    va_start(argv,fmt);
    vbbprintf(codebuffer,fmt,argv);
    va_end(argv);
}

NCConstant*
emptycompoundconst(int lineno, NCConstant* c)
{
    ASSERT(c != NULL);
    c->lineno = lineno;
    c->nctype = NC_COMPOUND;
    c->value.compoundv = builddatalist(0);
    c->filled = 0;
    return c;    
}

NCConstant*
emptystringconst(int lineno, NCConstant* c)
{
    ASSERT(c != NULL);
    c->lineno = lineno;
    c->nctype = NC_STRING;
    c->value.stringv.len = 0;
    c->value.stringv.stringv = NULL;
    c->filled = 0;
    return c;    
}

#define INDENTMAX 256
static char* dent = NULL;

char*
indented(int n)
{
    char* indentation;
    if(dent == NULL) {
	dent = (char*)emalloc(INDENTMAX+1);
	memset((void*)dent,' ',INDENTMAX);
	dent[INDENTMAX] = '\0';	
    }
    if(n*4 >= INDENTMAX) n = INDENTMAX/4;
    indentation = dent+(INDENTMAX - 4*n);
    return indentation;
}

void
dlextend(Datalist* dl)
{
    size_t newalloc;
    newalloc = (dl->alloc > 0?2*dl->alloc:1);
    dlsetalloc(dl,newalloc);
}

void
dlsetalloc(Datalist* dl, size_t newalloc)
{
    NCConstant* newdata;
    if(newalloc <= 0) newalloc = 1;
    if(dl->alloc > 0)
        newdata = (NCConstant*)erealloc((void*)dl->data,sizeof(NCConstant)*newalloc);
    else {
        newdata = (NCConstant*)emalloc(sizeof(NCConstant)*newalloc);
        memset((void*)newdata,0,sizeof(NCConstant)*newalloc);
    }
    dl->alloc = newalloc;
    dl->data = newdata;
}


Datalist*
builddatalist(int initial)
{
    Datalist* ci;
    if(initial <= 0) initial = DATALISTINIT;
    initial++; /* for header*/
    ci = (Datalist*)emalloc(sizeof(Datalist));
    memset((void*)ci,0,sizeof(Datalist)); /* only clear the hdr*/
    ci->data = (NCConstant*)emalloc(sizeof(NCConstant)*initial);
    memset((void*)ci->data,0,sizeof(NCConstant)*initial);
    ci->alloc = initial;
    ci->length = 0;
    return ci;
}

void
dlappend(Datalist* dl, NCConstant* constant)
{
    if(dl->length >= dl->alloc) dlextend(dl);
    if(constant == NULL) constant = &nullconstant;
    dl->data[dl->length++] = *constant;
}

NCConstant
builddatasublist(Datalist* dl)
{

  NCConstant d;
  d.nctype = NC_COMPOUND;
  d.lineno = (dl->length > 0?dl->data[0].lineno:0);
  d.value.compoundv = dl;
  d.filled = 0;
  return d;

}

/*! Function to free an allocated datalist.

  This function is used to free an individual datalist
  object.  It is possible, hypothetically, that a
  datalist will appear in the middle of a set of datalists,
  in which case we'll need to determine that and shuffle around
  'next' pointers.  For the time being, this assumes that
  we are freeing a datalist which was allocated locally
  and must be discarded.

  Using this function instead of an inline 'free' just in
  case we ever want to extend it, we won't have to go back
  and re-write a bunch of stuff. I hope.

  @param dlist Pointer to datalist object being freed.

 */
void dlfree(Datalist **dlist) {

  if(*dlist) free(*dlist);
  dlist = NULL;
}