From: Frank Lahm Date: Sat, 19 Jun 2010 11:16:47 +0000 (+0200) Subject: convert dos line endings to unix X-Git-Url: https://arthur.barton.de/gitweb/?a=commitdiff_plain;h=baf86eb5bf69521d96e3b754a2a7472589249d4a;p=netatalk.git convert dos line endings to unix --- diff --git a/include/atalk/bstrlib.h b/include/atalk/bstrlib.h old mode 100755 new mode 100644 index 6dc888a2..858a3fab --- a/include/atalk/bstrlib.h +++ b/include/atalk/bstrlib.h @@ -1,300 +1,300 @@ -/* - * This source file is part of the bstring string library. This code was - * written by Paul Hsieh in 2002-2008, and is covered by the BSD open source - * license and the GPL. Refer to the accompanying documentation for details - * on usage and license. - */ - -/*! - * @file - * This file is the core module for implementing the bstring functions. - */ - -#ifndef BSTRLIB_INCLUDE -#define BSTRLIB_INCLUDE - -#ifdef __cplusplus -extern "C" { -#endif - -#include -#include -#include -#include - -#if !defined (BSTRLIB_VSNP_OK) && !defined (BSTRLIB_NOVSNP) -# if defined (__TURBOC__) && !defined (__BORLANDC__) -# define BSTRLIB_NOVSNP -# endif -#endif - -#define BSTR_ERR (-1) -#define BSTR_OK (0) -#define BSTR_BS_BUFF_LENGTH_GET (0) - -typedef struct tagbstring * bstring; -typedef const struct tagbstring * const_bstring; - -/* Copy functions */ -#define cstr2bstr bfromcstr -extern bstring bfromcstr (const char * str); -extern bstring bfromcstralloc (int mlen, const char * str); -extern bstring blk2bstr (const void * blk, int len); -extern char * bstr2cstr (const_bstring s, char z); -extern int bcstrfree (char * s); -extern bstring bstrcpy (const_bstring b1); -extern int bassign (bstring a, const_bstring b); -extern int bassignmidstr (bstring a, const_bstring b, int left, int len); -extern int bassigncstr (bstring a, const char * str); -extern int bassignblk (bstring a, const void * s, int len); - -/* Destroy function */ -extern int bdestroy (bstring b); - -/* Space allocation hinting functions */ -extern int balloc (bstring s, int len); -extern int ballocmin (bstring b, int len); - -/* Substring extraction */ -extern bstring bmidstr (const_bstring b, int left, int len); - -/* Various standard manipulations */ -extern int bconcat (bstring b0, const_bstring b1); -extern int bconchar (bstring b0, char c); -extern int bcatcstr (bstring b, const char * s); -extern int bcatblk (bstring b, const void * s, int len); -extern int binsert (bstring s1, int pos, const_bstring s2, unsigned char fill); -extern int binsertch (bstring s1, int pos, int len, unsigned char fill); -extern int breplace (bstring b1, int pos, int len, const_bstring b2, unsigned char fill); -extern int bdelete (bstring s1, int pos, int len); -extern int bsetstr (bstring b0, int pos, const_bstring b1, unsigned char fill); -extern int btrunc (bstring b, int n); - -/* Scan/search functions */ -extern int bstricmp (const_bstring b0, const_bstring b1); -extern int bstrnicmp (const_bstring b0, const_bstring b1, int n); -extern int biseqcaseless (const_bstring b0, const_bstring b1); -extern int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len); -extern int biseq (const_bstring b0, const_bstring b1); -extern int bisstemeqblk (const_bstring b0, const void * blk, int len); -extern int biseqcstr (const_bstring b, const char * s); -extern int biseqcstrcaseless (const_bstring b, const char * s); -extern int bstrcmp (const_bstring b0, const_bstring b1); -extern int bstrncmp (const_bstring b0, const_bstring b1, int n); -extern int binstr (const_bstring s1, int pos, const_bstring s2); -extern int binstrr (const_bstring s1, int pos, const_bstring s2); -extern int binstrcaseless (const_bstring s1, int pos, const_bstring s2); -extern int binstrrcaseless (const_bstring s1, int pos, const_bstring s2); -extern int bstrchrp (const_bstring b, int c, int pos); -extern int bstrrchrp (const_bstring b, int c, int pos); -#define bstrchr(b,c) bstrchrp ((b), (c), 0) -#define bstrrchr(b,c) bstrrchrp ((b), (c), blength(b)-1) -extern int binchr (const_bstring b0, int pos, const_bstring b1); -extern int binchrr (const_bstring b0, int pos, const_bstring b1); -extern int bninchr (const_bstring b0, int pos, const_bstring b1); -extern int bninchrr (const_bstring b0, int pos, const_bstring b1); -extern int bfindreplace (bstring b, const_bstring find, const_bstring repl, int pos); -extern int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, int pos); - -/* List of string container functions */ -struct bstrList { - int qty, mlen; - bstring * entry; -}; -extern struct bstrList * bstrListCreate (void); -extern int bstrListDestroy (struct bstrList * sl); -extern int bstrListAlloc (struct bstrList * sl, int msz); -extern int bstrListAllocMin (struct bstrList * sl, int msz); - -/* String split and join functions */ -extern struct bstrList * bsplit (const_bstring str, unsigned char splitChar); -extern struct bstrList * bsplits (const_bstring str, const_bstring splitStr); -extern struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr); -extern bstring bjoin (const struct bstrList * bl, const_bstring sep); -extern int bsplitcb (const_bstring str, unsigned char splitChar, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm); -extern int bsplitscb (const_bstring str, const_bstring splitStr, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm); -extern int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm); - -/* Miscellaneous functions */ -extern int bpattern (bstring b, int len); -extern int btoupper (bstring b); -extern int btolower (bstring b); -extern int bltrimws (bstring b); -extern int brtrimws (bstring b); -extern int btrimws (bstring b); - -#if !defined (BSTRLIB_NOVSNP) -extern bstring bformat (const char * fmt, ...); -extern int bformata (bstring b, const char * fmt, ...); -extern int bassignformat (bstring b, const char * fmt, ...); -extern int bvcformata (bstring b, int count, const char * fmt, va_list arglist); - -#define bvformata(ret, b, fmt, lastarg) { \ -bstring bstrtmp_b = (b); \ -const char * bstrtmp_fmt = (fmt); \ -int bstrtmp_r = BSTR_ERR, bstrtmp_sz = 16; \ - for (;;) { \ - va_list bstrtmp_arglist; \ - va_start (bstrtmp_arglist, lastarg); \ - bstrtmp_r = bvcformata (bstrtmp_b, bstrtmp_sz, bstrtmp_fmt, bstrtmp_arglist); \ - va_end (bstrtmp_arglist); \ - if (bstrtmp_r >= 0) { /* Everything went ok */ \ - bstrtmp_r = BSTR_OK; \ - break; \ - } else if (-bstrtmp_r <= bstrtmp_sz) { /* A real error? */ \ - bstrtmp_r = BSTR_ERR; \ - break; \ - } \ - bstrtmp_sz = -bstrtmp_r; /* Doubled or target size */ \ - } \ - ret = bstrtmp_r; \ -} - -#endif - -typedef int (*bNgetc) (void *parm); -typedef size_t (* bNread) (void *buff, size_t elsize, size_t nelem, void *parm); - -/* Input functions */ -extern bstring bgets (bNgetc getcPtr, void * parm, char terminator); -extern bstring bread (bNread readPtr, void * parm); -extern int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator); -extern int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator); -extern int breada (bstring b, bNread readPtr, void * parm); - -/* Stream functions */ -extern struct bStream * bsopen (bNread readPtr, void * parm); -extern void * bsclose (struct bStream * s); -extern int bsbufflength (struct bStream * s, int sz); -extern int bsreadln (bstring b, struct bStream * s, char terminator); -extern int bsreadlns (bstring r, struct bStream * s, const_bstring term); -extern int bsread (bstring b, struct bStream * s, int n); -extern int bsreadlna (bstring b, struct bStream * s, char terminator); -extern int bsreadlnsa (bstring r, struct bStream * s, const_bstring term); -extern int bsreada (bstring b, struct bStream * s, int n); -extern int bsunread (struct bStream * s, const_bstring b); -extern int bspeek (bstring r, const struct bStream * s); -extern int bssplitscb (struct bStream * s, const_bstring splitStr, - int (* cb) (void * parm, int ofs, const_bstring entry), void * parm); -extern int bssplitstrcb (struct bStream * s, const_bstring splitStr, - int (* cb) (void * parm, int ofs, const_bstring entry), void * parm); -extern int bseof (const struct bStream * s); - -struct tagbstring { - int mlen; - int slen; - unsigned char * data; -}; - -/* Accessor macros */ -#define blengthe(b, e) (((b) == (void *)0 || (b)->slen < 0) ? (int)(e) : ((b)->slen)) -#define blength(b) (blengthe ((b), 0)) -#define bdataofse(b, o, e) (((b) == (void *)0 || (b)->data == (void*)0) ? (char *)(e) : ((char *)(b)->data) + (o)) -#define bdataofs(b, o) (bdataofse ((b), (o), (void *)0)) -#define bdatae(b, e) (bdataofse (b, 0, e)) -#define bdata(b) (bdataofs (b, 0)) -#define bchare(b, p, e) ((((unsigned)(p)) < (unsigned)blength(b)) ? ((b)->data[(p)]) : (e)) -#define bchar(b, p) bchare ((b), (p), '\0') - -/* Static constant string initialization macro */ -#define bsStaticMlen(q,m) {(m), (int) sizeof(q)-1, (unsigned char *) ("" q "")} -#if defined(_MSC_VER) -# define bsStatic(q) bsStaticMlen(q,-32) -#endif -#ifndef bsStatic -# define bsStatic(q) bsStaticMlen(q,-__LINE__) -#endif - -/* Static constant block parameter pair */ -#define bsStaticBlkParms(q) ((void *)("" q "")), ((int) sizeof(q)-1) - -/* Reference building macros */ -#define cstr2tbstr btfromcstr -#define btfromcstr(t,s) { \ - (t).data = (unsigned char *) (s); \ - (t).slen = ((t).data) ? ((int) (strlen) ((char *)(t).data)) : 0; \ - (t).mlen = -1; \ -} -#define blk2tbstr(t,s,l) { \ - (t).data = (unsigned char *) (s); \ - (t).slen = l; \ - (t).mlen = -1; \ -} -#define btfromblk(t,s,l) blk2tbstr(t,s,l) -#define bmid2tbstr(t,b,p,l) { \ - const_bstring bstrtmp_s = (b); \ - if (bstrtmp_s && bstrtmp_s->data && bstrtmp_s->slen >= 0) { \ - int bstrtmp_left = (p); \ - int bstrtmp_len = (l); \ - if (bstrtmp_left < 0) { \ - bstrtmp_len += bstrtmp_left; \ - bstrtmp_left = 0; \ - } \ - if (bstrtmp_len > bstrtmp_s->slen - bstrtmp_left) \ - bstrtmp_len = bstrtmp_s->slen - bstrtmp_left; \ - if (bstrtmp_len <= 0) { \ - (t).data = (unsigned char *)""; \ - (t).slen = 0; \ - } else { \ - (t).data = bstrtmp_s->data + bstrtmp_left; \ - (t).slen = bstrtmp_len; \ - } \ - } else { \ - (t).data = (unsigned char *)""; \ - (t).slen = 0; \ - } \ - (t).mlen = -__LINE__; \ -} -#define btfromblkltrimws(t,s,l) { \ - int bstrtmp_idx = 0, bstrtmp_len = (l); \ - unsigned char * bstrtmp_s = (s); \ - if (bstrtmp_s && bstrtmp_len >= 0) { \ - for (; bstrtmp_idx < bstrtmp_len; bstrtmp_idx++) { \ - if (!isspace (bstrtmp_s[bstrtmp_idx])) break; \ - } \ - } \ - (t).data = bstrtmp_s + bstrtmp_idx; \ - (t).slen = bstrtmp_len - bstrtmp_idx; \ - (t).mlen = -__LINE__; \ -} -#define btfromblkrtrimws(t,s,l) { \ - int bstrtmp_len = (l) - 1; \ - unsigned char * bstrtmp_s = (s); \ - if (bstrtmp_s && bstrtmp_len >= 0) { \ - for (; bstrtmp_len >= 0; bstrtmp_len--) { \ - if (!isspace (bstrtmp_s[bstrtmp_len])) break; \ - } \ - } \ - (t).data = bstrtmp_s; \ - (t).slen = bstrtmp_len + 1; \ - (t).mlen = -__LINE__; \ -} -#define btfromblktrimws(t,s,l) { \ - int bstrtmp_idx = 0, bstrtmp_len = (l) - 1; \ - unsigned char * bstrtmp_s = (s); \ - if (bstrtmp_s && bstrtmp_len >= 0) { \ - for (; bstrtmp_idx <= bstrtmp_len; bstrtmp_idx++) { \ - if (!isspace (bstrtmp_s[bstrtmp_idx])) break; \ - } \ - for (; bstrtmp_len >= bstrtmp_idx; bstrtmp_len--) { \ - if (!isspace (bstrtmp_s[bstrtmp_len])) break; \ - } \ - } \ - (t).data = bstrtmp_s + bstrtmp_idx; \ - (t).slen = bstrtmp_len + 1 - bstrtmp_idx; \ - (t).mlen = -__LINE__; \ -} - -/* Write protection macros */ -#define bwriteprotect(t) { if ((t).mlen >= 0) (t).mlen = -1; } -#define bwriteallow(t) { if ((t).mlen == -1) (t).mlen = (t).slen + ((t).slen == 0); } -#define biswriteprotected(t) ((t).mlen <= 0) - -#ifdef __cplusplus -} -#endif - -#endif +/* + * This source file is part of the bstring string library. This code was + * written by Paul Hsieh in 2002-2008, and is covered by the BSD open source + * license and the GPL. Refer to the accompanying documentation for details + * on usage and license. + */ + +/*! + * @file + * This file is the core module for implementing the bstring functions. + */ + +#ifndef BSTRLIB_INCLUDE +#define BSTRLIB_INCLUDE + +#ifdef __cplusplus +extern "C" { +#endif + +#include +#include +#include +#include + +#if !defined (BSTRLIB_VSNP_OK) && !defined (BSTRLIB_NOVSNP) +# if defined (__TURBOC__) && !defined (__BORLANDC__) +# define BSTRLIB_NOVSNP +# endif +#endif + +#define BSTR_ERR (-1) +#define BSTR_OK (0) +#define BSTR_BS_BUFF_LENGTH_GET (0) + +typedef struct tagbstring * bstring; +typedef const struct tagbstring * const_bstring; + +/* Copy functions */ +#define cstr2bstr bfromcstr +extern bstring bfromcstr (const char * str); +extern bstring bfromcstralloc (int mlen, const char * str); +extern bstring blk2bstr (const void * blk, int len); +extern char * bstr2cstr (const_bstring s, char z); +extern int bcstrfree (char * s); +extern bstring bstrcpy (const_bstring b1); +extern int bassign (bstring a, const_bstring b); +extern int bassignmidstr (bstring a, const_bstring b, int left, int len); +extern int bassigncstr (bstring a, const char * str); +extern int bassignblk (bstring a, const void * s, int len); + +/* Destroy function */ +extern int bdestroy (bstring b); + +/* Space allocation hinting functions */ +extern int balloc (bstring s, int len); +extern int ballocmin (bstring b, int len); + +/* Substring extraction */ +extern bstring bmidstr (const_bstring b, int left, int len); + +/* Various standard manipulations */ +extern int bconcat (bstring b0, const_bstring b1); +extern int bconchar (bstring b0, char c); +extern int bcatcstr (bstring b, const char * s); +extern int bcatblk (bstring b, const void * s, int len); +extern int binsert (bstring s1, int pos, const_bstring s2, unsigned char fill); +extern int binsertch (bstring s1, int pos, int len, unsigned char fill); +extern int breplace (bstring b1, int pos, int len, const_bstring b2, unsigned char fill); +extern int bdelete (bstring s1, int pos, int len); +extern int bsetstr (bstring b0, int pos, const_bstring b1, unsigned char fill); +extern int btrunc (bstring b, int n); + +/* Scan/search functions */ +extern int bstricmp (const_bstring b0, const_bstring b1); +extern int bstrnicmp (const_bstring b0, const_bstring b1, int n); +extern int biseqcaseless (const_bstring b0, const_bstring b1); +extern int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len); +extern int biseq (const_bstring b0, const_bstring b1); +extern int bisstemeqblk (const_bstring b0, const void * blk, int len); +extern int biseqcstr (const_bstring b, const char * s); +extern int biseqcstrcaseless (const_bstring b, const char * s); +extern int bstrcmp (const_bstring b0, const_bstring b1); +extern int bstrncmp (const_bstring b0, const_bstring b1, int n); +extern int binstr (const_bstring s1, int pos, const_bstring s2); +extern int binstrr (const_bstring s1, int pos, const_bstring s2); +extern int binstrcaseless (const_bstring s1, int pos, const_bstring s2); +extern int binstrrcaseless (const_bstring s1, int pos, const_bstring s2); +extern int bstrchrp (const_bstring b, int c, int pos); +extern int bstrrchrp (const_bstring b, int c, int pos); +#define bstrchr(b,c) bstrchrp ((b), (c), 0) +#define bstrrchr(b,c) bstrrchrp ((b), (c), blength(b)-1) +extern int binchr (const_bstring b0, int pos, const_bstring b1); +extern int binchrr (const_bstring b0, int pos, const_bstring b1); +extern int bninchr (const_bstring b0, int pos, const_bstring b1); +extern int bninchrr (const_bstring b0, int pos, const_bstring b1); +extern int bfindreplace (bstring b, const_bstring find, const_bstring repl, int pos); +extern int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, int pos); + +/* List of string container functions */ +struct bstrList { + int qty, mlen; + bstring * entry; +}; +extern struct bstrList * bstrListCreate (void); +extern int bstrListDestroy (struct bstrList * sl); +extern int bstrListAlloc (struct bstrList * sl, int msz); +extern int bstrListAllocMin (struct bstrList * sl, int msz); + +/* String split and join functions */ +extern struct bstrList * bsplit (const_bstring str, unsigned char splitChar); +extern struct bstrList * bsplits (const_bstring str, const_bstring splitStr); +extern struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr); +extern bstring bjoin (const struct bstrList * bl, const_bstring sep); +extern int bsplitcb (const_bstring str, unsigned char splitChar, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm); +extern int bsplitscb (const_bstring str, const_bstring splitStr, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm); +extern int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm); + +/* Miscellaneous functions */ +extern int bpattern (bstring b, int len); +extern int btoupper (bstring b); +extern int btolower (bstring b); +extern int bltrimws (bstring b); +extern int brtrimws (bstring b); +extern int btrimws (bstring b); + +#if !defined (BSTRLIB_NOVSNP) +extern bstring bformat (const char * fmt, ...); +extern int bformata (bstring b, const char * fmt, ...); +extern int bassignformat (bstring b, const char * fmt, ...); +extern int bvcformata (bstring b, int count, const char * fmt, va_list arglist); + +#define bvformata(ret, b, fmt, lastarg) { \ +bstring bstrtmp_b = (b); \ +const char * bstrtmp_fmt = (fmt); \ +int bstrtmp_r = BSTR_ERR, bstrtmp_sz = 16; \ + for (;;) { \ + va_list bstrtmp_arglist; \ + va_start (bstrtmp_arglist, lastarg); \ + bstrtmp_r = bvcformata (bstrtmp_b, bstrtmp_sz, bstrtmp_fmt, bstrtmp_arglist); \ + va_end (bstrtmp_arglist); \ + if (bstrtmp_r >= 0) { /* Everything went ok */ \ + bstrtmp_r = BSTR_OK; \ + break; \ + } else if (-bstrtmp_r <= bstrtmp_sz) { /* A real error? */ \ + bstrtmp_r = BSTR_ERR; \ + break; \ + } \ + bstrtmp_sz = -bstrtmp_r; /* Doubled or target size */ \ + } \ + ret = bstrtmp_r; \ +} + +#endif + +typedef int (*bNgetc) (void *parm); +typedef size_t (* bNread) (void *buff, size_t elsize, size_t nelem, void *parm); + +/* Input functions */ +extern bstring bgets (bNgetc getcPtr, void * parm, char terminator); +extern bstring bread (bNread readPtr, void * parm); +extern int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator); +extern int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator); +extern int breada (bstring b, bNread readPtr, void * parm); + +/* Stream functions */ +extern struct bStream * bsopen (bNread readPtr, void * parm); +extern void * bsclose (struct bStream * s); +extern int bsbufflength (struct bStream * s, int sz); +extern int bsreadln (bstring b, struct bStream * s, char terminator); +extern int bsreadlns (bstring r, struct bStream * s, const_bstring term); +extern int bsread (bstring b, struct bStream * s, int n); +extern int bsreadlna (bstring b, struct bStream * s, char terminator); +extern int bsreadlnsa (bstring r, struct bStream * s, const_bstring term); +extern int bsreada (bstring b, struct bStream * s, int n); +extern int bsunread (struct bStream * s, const_bstring b); +extern int bspeek (bstring r, const struct bStream * s); +extern int bssplitscb (struct bStream * s, const_bstring splitStr, + int (* cb) (void * parm, int ofs, const_bstring entry), void * parm); +extern int bssplitstrcb (struct bStream * s, const_bstring splitStr, + int (* cb) (void * parm, int ofs, const_bstring entry), void * parm); +extern int bseof (const struct bStream * s); + +struct tagbstring { + int mlen; + int slen; + unsigned char * data; +}; + +/* Accessor macros */ +#define blengthe(b, e) (((b) == (void *)0 || (b)->slen < 0) ? (int)(e) : ((b)->slen)) +#define blength(b) (blengthe ((b), 0)) +#define bdataofse(b, o, e) (((b) == (void *)0 || (b)->data == (void*)0) ? (char *)(e) : ((char *)(b)->data) + (o)) +#define bdataofs(b, o) (bdataofse ((b), (o), (void *)0)) +#define bdatae(b, e) (bdataofse (b, 0, e)) +#define bdata(b) (bdataofs (b, 0)) +#define bchare(b, p, e) ((((unsigned)(p)) < (unsigned)blength(b)) ? ((b)->data[(p)]) : (e)) +#define bchar(b, p) bchare ((b), (p), '\0') + +/* Static constant string initialization macro */ +#define bsStaticMlen(q,m) {(m), (int) sizeof(q)-1, (unsigned char *) ("" q "")} +#if defined(_MSC_VER) +# define bsStatic(q) bsStaticMlen(q,-32) +#endif +#ifndef bsStatic +# define bsStatic(q) bsStaticMlen(q,-__LINE__) +#endif + +/* Static constant block parameter pair */ +#define bsStaticBlkParms(q) ((void *)("" q "")), ((int) sizeof(q)-1) + +/* Reference building macros */ +#define cstr2tbstr btfromcstr +#define btfromcstr(t,s) { \ + (t).data = (unsigned char *) (s); \ + (t).slen = ((t).data) ? ((int) (strlen) ((char *)(t).data)) : 0; \ + (t).mlen = -1; \ +} +#define blk2tbstr(t,s,l) { \ + (t).data = (unsigned char *) (s); \ + (t).slen = l; \ + (t).mlen = -1; \ +} +#define btfromblk(t,s,l) blk2tbstr(t,s,l) +#define bmid2tbstr(t,b,p,l) { \ + const_bstring bstrtmp_s = (b); \ + if (bstrtmp_s && bstrtmp_s->data && bstrtmp_s->slen >= 0) { \ + int bstrtmp_left = (p); \ + int bstrtmp_len = (l); \ + if (bstrtmp_left < 0) { \ + bstrtmp_len += bstrtmp_left; \ + bstrtmp_left = 0; \ + } \ + if (bstrtmp_len > bstrtmp_s->slen - bstrtmp_left) \ + bstrtmp_len = bstrtmp_s->slen - bstrtmp_left; \ + if (bstrtmp_len <= 0) { \ + (t).data = (unsigned char *)""; \ + (t).slen = 0; \ + } else { \ + (t).data = bstrtmp_s->data + bstrtmp_left; \ + (t).slen = bstrtmp_len; \ + } \ + } else { \ + (t).data = (unsigned char *)""; \ + (t).slen = 0; \ + } \ + (t).mlen = -__LINE__; \ +} +#define btfromblkltrimws(t,s,l) { \ + int bstrtmp_idx = 0, bstrtmp_len = (l); \ + unsigned char * bstrtmp_s = (s); \ + if (bstrtmp_s && bstrtmp_len >= 0) { \ + for (; bstrtmp_idx < bstrtmp_len; bstrtmp_idx++) { \ + if (!isspace (bstrtmp_s[bstrtmp_idx])) break; \ + } \ + } \ + (t).data = bstrtmp_s + bstrtmp_idx; \ + (t).slen = bstrtmp_len - bstrtmp_idx; \ + (t).mlen = -__LINE__; \ +} +#define btfromblkrtrimws(t,s,l) { \ + int bstrtmp_len = (l) - 1; \ + unsigned char * bstrtmp_s = (s); \ + if (bstrtmp_s && bstrtmp_len >= 0) { \ + for (; bstrtmp_len >= 0; bstrtmp_len--) { \ + if (!isspace (bstrtmp_s[bstrtmp_len])) break; \ + } \ + } \ + (t).data = bstrtmp_s; \ + (t).slen = bstrtmp_len + 1; \ + (t).mlen = -__LINE__; \ +} +#define btfromblktrimws(t,s,l) { \ + int bstrtmp_idx = 0, bstrtmp_len = (l) - 1; \ + unsigned char * bstrtmp_s = (s); \ + if (bstrtmp_s && bstrtmp_len >= 0) { \ + for (; bstrtmp_idx <= bstrtmp_len; bstrtmp_idx++) { \ + if (!isspace (bstrtmp_s[bstrtmp_idx])) break; \ + } \ + for (; bstrtmp_len >= bstrtmp_idx; bstrtmp_len--) { \ + if (!isspace (bstrtmp_s[bstrtmp_len])) break; \ + } \ + } \ + (t).data = bstrtmp_s + bstrtmp_idx; \ + (t).slen = bstrtmp_len + 1 - bstrtmp_idx; \ + (t).mlen = -__LINE__; \ +} + +/* Write protection macros */ +#define bwriteprotect(t) { if ((t).mlen >= 0) (t).mlen = -1; } +#define bwriteallow(t) { if ((t).mlen == -1) (t).mlen = (t).slen + ((t).slen == 0); } +#define biswriteprotected(t) ((t).mlen <= 0) + +#ifdef __cplusplus +} +#endif + +#endif diff --git a/libatalk/bstring/bstrlib.c b/libatalk/bstring/bstrlib.c old mode 100755 new mode 100644 index 93c481ca..9748c002 --- a/libatalk/bstring/bstrlib.c +++ b/libatalk/bstring/bstrlib.c @@ -1,2956 +1,2956 @@ -/* - * This source file is part of the bstring string library. This code was - * written by Paul Hsieh in 2002-2008, and is covered by the BSD open source - * license and the GPL. Refer to the accompanying documentation for details - * on usage and license. - */ - -/* - * bstrlib.c - * - * This file is the core module for implementing the bstring functions. - */ - -#include -#include -#include -#include -#include -#include - -#include - -/* Optionally include a mechanism for debugging memory */ - -#if defined(MEMORY_DEBUG) || defined(BSTRLIB_MEMORY_DEBUG) -#include "memdbg.h" -#endif - -#ifndef bstr__alloc -#define bstr__alloc(x) malloc (x) -#endif - -#ifndef bstr__free -#define bstr__free(p) free (p) -#endif - -#ifndef bstr__realloc -#define bstr__realloc(p,x) realloc ((p), (x)) -#endif - -#ifndef bstr__memcpy -#define bstr__memcpy(d,s,l) memcpy ((d), (s), (l)) -#endif - -#ifndef bstr__memmove -#define bstr__memmove(d,s,l) memmove ((d), (s), (l)) -#endif - -#ifndef bstr__memset -#define bstr__memset(d,c,l) memset ((d), (c), (l)) -#endif - -#ifndef bstr__memcmp -#define bstr__memcmp(d,c,l) memcmp ((d), (c), (l)) -#endif - -#ifndef bstr__memchr -#define bstr__memchr(s,c,l) memchr ((s), (c), (l)) -#endif - -/* Just a length safe wrapper for memmove. */ - -#define bBlockCopy(D,S,L) { if ((L) > 0) bstr__memmove ((D),(S),(L)); } - -/* Compute the snapped size for a given requested size. By snapping to powers - of 2 like this, repeated reallocations are avoided. */ -static int snapUpSize (int i) { - if (i < 8) { - i = 8; - } else { - unsigned int j; - j = (unsigned int) i; - - j |= (j >> 1); - j |= (j >> 2); - j |= (j >> 4); - j |= (j >> 8); /* Ok, since int >= 16 bits */ -#if (UINT_MAX != 0xffff) - j |= (j >> 16); /* For 32 bit int systems */ -#if (UINT_MAX > 0xffffffffUL) - j |= (j >> 32); /* For 64 bit int systems */ -#endif -#endif - /* Least power of two greater than i */ - j++; - if ((int) j >= i) i = (int) j; - } - return i; -} - -/* int balloc (bstring b, int len) - * - * Increase the size of the memory backing the bstring b to at least len. - */ -int balloc (bstring b, int olen) { - int len; - if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen <= 0 || - b->mlen < b->slen || olen <= 0) { - return BSTR_ERR; - } - - if (olen >= b->mlen) { - unsigned char * x; - - if ((len = snapUpSize (olen)) <= b->mlen) return BSTR_OK; - - /* Assume probability of a non-moving realloc is 0.125 */ - if (7 * b->mlen < 8 * b->slen) { - - /* If slen is close to mlen in size then use realloc to reduce - the memory defragmentation */ - - reallocStrategy:; - - x = (unsigned char *) bstr__realloc (b->data, (size_t) len); - if (x == NULL) { - - /* Since we failed, try allocating the tighest possible - allocation */ - - if (NULL == (x = (unsigned char *) bstr__realloc (b->data, (size_t) (len = olen)))) { - return BSTR_ERR; - } - } - } else { - - /* If slen is not close to mlen then avoid the penalty of copying - the extra bytes that are allocated, but not considered part of - the string */ - - if (NULL == (x = (unsigned char *) bstr__alloc ((size_t) len))) { - - /* Perhaps there is no available memory for the two - allocations to be in memory at once */ - - goto reallocStrategy; - - } else { - if (b->slen) bstr__memcpy ((char *) x, (char *) b->data, (size_t) b->slen); - bstr__free (b->data); - } - } - b->data = x; - b->mlen = len; - b->data[b->slen] = (unsigned char) '\0'; - } - - return BSTR_OK; -} - -/* int ballocmin (bstring b, int len) - * - * Set the size of the memory backing the bstring b to len or b->slen+1, - * whichever is larger. Note that repeated use of this function can degrade - * performance. - */ -int ballocmin (bstring b, int len) { - unsigned char * s; - - if (b == NULL || b->data == NULL || (b->slen+1) < 0 || b->mlen <= 0 || - b->mlen < b->slen || len <= 0) { - return BSTR_ERR; - } - - if (len < b->slen + 1) len = b->slen + 1; - - if (len != b->mlen) { - s = (unsigned char *) bstr__realloc (b->data, (size_t) len); - if (NULL == s) return BSTR_ERR; - s[b->slen] = (unsigned char) '\0'; - b->data = s; - b->mlen = len; - } - - return BSTR_OK; -} - -/* bstring bfromcstr (const char * str) - * - * Create a bstring which contains the contents of the '\0' terminated char * - * buffer str. - */ -bstring bfromcstr (const char * str) { -bstring b; -int i; -size_t j; - - if (str == NULL) return NULL; - j = (strlen) (str); - i = snapUpSize ((int) (j + (2 - (j != 0)))); - if (i <= (int) j) return NULL; - - b = (bstring) bstr__alloc (sizeof (struct tagbstring)); - if (NULL == b) return NULL; - b->slen = (int) j; - if (NULL == (b->data = (unsigned char *) bstr__alloc (b->mlen = i))) { - bstr__free (b); - return NULL; - } - - bstr__memcpy (b->data, str, j+1); - return b; -} - -/* bstring bfromcstralloc (int mlen, const char * str) - * - * Create a bstring which contains the contents of the '\0' terminated char * - * buffer str. The memory buffer backing the string is at least len - * characters in length. - */ -bstring bfromcstralloc (int mlen, const char * str) { -bstring b; -int i; -size_t j; - - if (str == NULL) return NULL; - j = (strlen) (str); - i = snapUpSize ((int) (j + (2 - (j != 0)))); - if (i <= (int) j) return NULL; - - b = (bstring) bstr__alloc (sizeof (struct tagbstring)); - if (b == NULL) return NULL; - b->slen = (int) j; - if (i < mlen) i = mlen; - - if (NULL == (b->data = (unsigned char *) bstr__alloc (b->mlen = i))) { - bstr__free (b); - return NULL; - } - - bstr__memcpy (b->data, str, j+1); - return b; -} - -/* bstring blk2bstr (const void * blk, int len) - * - * Create a bstring which contains the content of the block blk of length - * len. - */ -bstring blk2bstr (const void * blk, int len) { -bstring b; -int i; - - if (blk == NULL || len < 0) return NULL; - b = (bstring) bstr__alloc (sizeof (struct tagbstring)); - if (b == NULL) return NULL; - b->slen = len; - - i = len + (2 - (len != 0)); - i = snapUpSize (i); - - b->mlen = i; - - b->data = (unsigned char *) bstr__alloc ((size_t) b->mlen); - if (b->data == NULL) { - bstr__free (b); - return NULL; - } - - if (len > 0) bstr__memcpy (b->data, blk, (size_t) len); - b->data[len] = (unsigned char) '\0'; - - return b; -} - -/* char * bstr2cstr (const_bstring s, char z) - * - * Create a '\0' terminated char * buffer which is equal to the contents of - * the bstring s, except that any contained '\0' characters are converted - * to the character in z. This returned value should be freed with a - * bcstrfree () call, by the calling application. - */ -char * bstr2cstr (const_bstring b, char z) { -int i, l; -char * r; - - if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; - l = b->slen; - r = (char *) bstr__alloc ((size_t) (l + 1)); - if (r == NULL) return r; - - for (i=0; i < l; i ++) { - r[i] = (char) ((b->data[i] == '\0') ? z : (char) (b->data[i])); - } - - r[l] = (unsigned char) '\0'; - - return r; -} - -/* int bcstrfree (char * s) - * - * Frees a C-string generated by bstr2cstr (). This is normally unnecessary - * since it just wraps a call to bstr__free (), however, if bstr__alloc () - * and bstr__free () have been redefined as a macros within the bstrlib - * module (via defining them in memdbg.h after defining - * BSTRLIB_MEMORY_DEBUG) with some difference in behaviour from the std - * library functions, then this allows a correct way of freeing the memory - * that allows higher level code to be independent from these macro - * redefinitions. - */ -int bcstrfree (char * s) { - if (s) { - bstr__free (s); - return BSTR_OK; - } - return BSTR_ERR; -} - -/* int bconcat (bstring b0, const_bstring b1) - * - * Concatenate the bstring b1 to the bstring b0. - */ -int bconcat (bstring b0, const_bstring b1) { -int len, d; -bstring aux = (bstring) b1; - - if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL) return BSTR_ERR; - - d = b0->slen; - len = b1->slen; - if ((d | (b0->mlen - d) | len | (d + len)) < 0) return BSTR_ERR; - - if (b0->mlen <= d + len + 1) { - ptrdiff_t pd = b1->data - b0->data; - if (0 <= pd && pd < b0->mlen) { - if (NULL == (aux = bstrcpy (b1))) return BSTR_ERR; - } - if (balloc (b0, d + len + 1) != BSTR_OK) { - if (aux != b1) bdestroy (aux); - return BSTR_ERR; - } - } - - bBlockCopy (&b0->data[d], &aux->data[0], (size_t) len); - b0->data[d + len] = (unsigned char) '\0'; - b0->slen = d + len; - if (aux != b1) bdestroy (aux); - return BSTR_OK; -} - -/* int bconchar (bstring b, char c) -/ * - * Concatenate the single character c to the bstring b. - */ -int bconchar (bstring b, char c) { -int d; - - if (b == NULL) return BSTR_ERR; - d = b->slen; - if ((d | (b->mlen - d)) < 0 || balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; - b->data[d] = (unsigned char) c; - b->data[d + 1] = (unsigned char) '\0'; - b->slen++; - return BSTR_OK; -} - -/* int bcatcstr (bstring b, const char * s) - * - * Concatenate a char * string to a bstring. - */ -int bcatcstr (bstring b, const char * s) { -char * d; -int i, l; - - if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen < b->slen - || b->mlen <= 0 || s == NULL) return BSTR_ERR; - - /* Optimistically concatenate directly */ - l = b->mlen - b->slen; - d = (char *) &b->data[b->slen]; - for (i=0; i < l; i++) { - if ((*d++ = *s++) == '\0') { - b->slen += i; - return BSTR_OK; - } - } - b->slen += i; - - /* Need to explicitely resize and concatenate tail */ - return bcatblk (b, (const void *) s, (int) strlen (s)); -} - -/* int bcatblk (bstring b, const void * s, int len) - * - * Concatenate a fixed length buffer to a bstring. - */ -int bcatblk (bstring b, const void * s, int len) { -int nl; - - if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen < b->slen - || b->mlen <= 0 || s == NULL || len < 0) return BSTR_ERR; - - if (0 > (nl = b->slen + len)) return BSTR_ERR; /* Overflow? */ - if (b->mlen <= nl && 0 > balloc (b, nl + 1)) return BSTR_ERR; - - bBlockCopy (&b->data[b->slen], s, (size_t) len); - b->slen = nl; - b->data[nl] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* bstring bstrcpy (const_bstring b) - * - * Create a copy of the bstring b. - */ -bstring bstrcpy (const_bstring b) { -bstring b0; -int i,j; - - /* Attempted to copy an invalid string? */ - if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; - - b0 = (bstring) bstr__alloc (sizeof (struct tagbstring)); - if (b0 == NULL) { - /* Unable to allocate memory for string header */ - return NULL; - } - - i = b->slen; - j = snapUpSize (i + 1); - - b0->data = (unsigned char *) bstr__alloc (j); - if (b0->data == NULL) { - j = i + 1; - b0->data = (unsigned char *) bstr__alloc (j); - if (b0->data == NULL) { - /* Unable to allocate memory for string data */ - bstr__free (b0); - return NULL; - } - } - - b0->mlen = j; - b0->slen = i; - - if (i) bstr__memcpy ((char *) b0->data, (char *) b->data, i); - b0->data[b0->slen] = (unsigned char) '\0'; - - return b0; -} - -/* int bassign (bstring a, const_bstring b) - * - * Overwrite the string a with the contents of string b. - */ -int bassign (bstring a, const_bstring b) { - if (b == NULL || b->data == NULL || b->slen < 0) - return BSTR_ERR; - if (b->slen != 0) { - if (balloc (a, b->slen) != BSTR_OK) return BSTR_ERR; - bstr__memmove (a->data, b->data, b->slen); - } else { - if (a == NULL || a->data == NULL || a->mlen < a->slen || - a->slen < 0 || a->mlen == 0) - return BSTR_ERR; - } - a->data[b->slen] = (unsigned char) '\0'; - a->slen = b->slen; - return BSTR_OK; -} - -/* int bassignmidstr (bstring a, const_bstring b, int left, int len) - * - * Overwrite the string a with the middle of contents of string b - * starting from position left and running for a length len. left and - * len are clamped to the ends of b as with the function bmidstr. - */ -int bassignmidstr (bstring a, const_bstring b, int left, int len) { - if (b == NULL || b->data == NULL || b->slen < 0) - return BSTR_ERR; - - if (left < 0) { - len += left; - left = 0; - } - - if (len > b->slen - left) len = b->slen - left; - - if (a == NULL || a->data == NULL || a->mlen < a->slen || - a->slen < 0 || a->mlen == 0) - return BSTR_ERR; - - if (len > 0) { - if (balloc (a, len) != BSTR_OK) return BSTR_ERR; - bstr__memmove (a->data, b->data + left, len); - a->slen = len; - } else { - a->slen = 0; - } - a->data[a->slen] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* int bassigncstr (bstring a, const char * str) - * - * Overwrite the string a with the contents of char * string str. Note that - * the bstring a must be a well defined and writable bstring. If an error - * occurs BSTR_ERR is returned however a may be partially overwritten. - */ -int bassigncstr (bstring a, const char * str) { -int i; -size_t len; - if (a == NULL || a->data == NULL || a->mlen < a->slen || - a->slen < 0 || a->mlen == 0 || NULL == str) - return BSTR_ERR; - - for (i=0; i < a->mlen; i++) { - if ('\0' == (a->data[i] = str[i])) { - a->slen = i; - return BSTR_OK; - } - } - - a->slen = i; - len = strlen (str + i); - if (len > INT_MAX || i + len + 1 > INT_MAX || - 0 > balloc (a, (int) (i + len + 1))) return BSTR_ERR; - bBlockCopy (a->data + i, str + i, (size_t) len + 1); - a->slen += (int) len; - return BSTR_OK; -} - -/* int bassignblk (bstring a, const void * s, int len) - * - * Overwrite the string a with the contents of the block (s, len). Note that - * the bstring a must be a well defined and writable bstring. If an error - * occurs BSTR_ERR is returned and a is not overwritten. - */ -int bassignblk (bstring a, const void * s, int len) { - if (a == NULL || a->data == NULL || a->mlen < a->slen || - a->slen < 0 || a->mlen == 0 || NULL == s || len + 1 < 1) - return BSTR_ERR; - if (len + 1 > a->mlen && 0 > balloc (a, len + 1)) return BSTR_ERR; - bBlockCopy (a->data, s, (size_t) len); - a->data[len] = (unsigned char) '\0'; - a->slen = len; - return BSTR_OK; -} - -/* int btrunc (bstring b, int n) - * - * Truncate the bstring to at most n characters. - */ -int btrunc (bstring b, int n) { - if (n < 0 || b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - if (b->slen > n) { - b->slen = n; - b->data[n] = (unsigned char) '\0'; - } - return BSTR_OK; -} - -#define upcase(c) (toupper ((unsigned char) c)) -#define downcase(c) (tolower ((unsigned char) c)) -#define wspace(c) (isspace ((unsigned char) c)) - -/* int btoupper (bstring b) - * - * Convert contents of bstring to upper case. - */ -int btoupper (bstring b) { -int i, len; - if (b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - for (i=0, len = b->slen; i < len; i++) { - b->data[i] = (unsigned char) upcase (b->data[i]); - } - return BSTR_OK; -} - -/* int btolower (bstring b) - * - * Convert contents of bstring to lower case. - */ -int btolower (bstring b) { -int i, len; - if (b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - for (i=0, len = b->slen; i < len; i++) { - b->data[i] = (unsigned char) downcase (b->data[i]); - } - return BSTR_OK; -} - -/* int bstricmp (const_bstring b0, const_bstring b1) - * - * Compare two strings without differentiating between case. The return - * value is the difference of the values of the characters where the two - * strings first differ after lower case transformation, otherwise 0 is - * returned indicating that the strings are equal. If the lengths are - * different, then a difference from 0 is given, but if the first extra - * character is '\0', then it is taken to be the value UCHAR_MAX+1. - */ -int bstricmp (const_bstring b0, const_bstring b1) { -int i, v, n; - - if (bdata (b0) == NULL || b0->slen < 0 || - bdata (b1) == NULL || b1->slen < 0) return SHRT_MIN; - if ((n = b0->slen) > b1->slen) n = b1->slen; - else if (b0->slen == b1->slen && b0->data == b1->data) return BSTR_OK; - - for (i = 0; i < n; i ++) { - v = (char) downcase (b0->data[i]) - - (char) downcase (b1->data[i]); - if (0 != v) return v; - } - - if (b0->slen > n) { - v = (char) downcase (b0->data[n]); - if (v) return v; - return UCHAR_MAX + 1; - } - if (b1->slen > n) { - v = - (char) downcase (b1->data[n]); - if (v) return v; - return - (int) (UCHAR_MAX + 1); - } - return BSTR_OK; -} - -/* int bstrnicmp (const_bstring b0, const_bstring b1, int n) - * - * Compare two strings without differentiating between case for at most n - * characters. If the position where the two strings first differ is - * before the nth position, the return value is the difference of the values - * of the characters, otherwise 0 is returned. If the lengths are different - * and less than n characters, then a difference from 0 is given, but if the - * first extra character is '\0', then it is taken to be the value - * UCHAR_MAX+1. - */ -int bstrnicmp (const_bstring b0, const_bstring b1, int n) { -int i, v, m; - - if (bdata (b0) == NULL || b0->slen < 0 || - bdata (b1) == NULL || b1->slen < 0 || n < 0) return SHRT_MIN; - m = n; - if (m > b0->slen) m = b0->slen; - if (m > b1->slen) m = b1->slen; - - if (b0->data != b1->data) { - for (i = 0; i < m; i ++) { - v = (char) downcase (b0->data[i]); - v -= (char) downcase (b1->data[i]); - if (v != 0) return b0->data[i] - b1->data[i]; - } - } - - if (n == m || b0->slen == b1->slen) return BSTR_OK; - - if (b0->slen > m) { - v = (char) downcase (b0->data[m]); - if (v) return v; - return UCHAR_MAX + 1; - } - - v = - (char) downcase (b1->data[m]); - if (v) return v; - return - (int) (UCHAR_MAX + 1); -} - -/* int biseqcaseless (const_bstring b0, const_bstring b1) - * - * Compare two strings for equality without differentiating between case. - * If the strings differ other than in case, 0 is returned, if the strings - * are the same, 1 is returned, if there is an error, -1 is returned. If - * the length of the strings are different, this function is O(1). '\0' - * termination characters are not treated in any special way. - */ -int biseqcaseless (const_bstring b0, const_bstring b1) { -int i, n; - - if (bdata (b0) == NULL || b0->slen < 0 || - bdata (b1) == NULL || b1->slen < 0) return BSTR_ERR; - if (b0->slen != b1->slen) return BSTR_OK; - if (b0->data == b1->data || b0->slen == 0) return 1; - for (i=0, n=b0->slen; i < n; i++) { - if (b0->data[i] != b1->data[i]) { - unsigned char c = (unsigned char) downcase (b0->data[i]); - if (c != (unsigned char) downcase (b1->data[i])) return 0; - } - } - return 1; -} - -/* int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len) - * - * Compare beginning of string b0 with a block of memory of length len - * without differentiating between case for equality. If the beginning of b0 - * differs from the memory block other than in case (or if b0 is too short), - * 0 is returned, if the strings are the same, 1 is returned, if there is an - * error, -1 is returned. '\0' characters are not treated in any special - * way. - */ -int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len) { -int i; - - if (bdata (b0) == NULL || b0->slen < 0 || NULL == blk || len < 0) - return BSTR_ERR; - if (b0->slen < len) return BSTR_OK; - if (b0->data == (const unsigned char *) blk || len == 0) return 1; - - for (i = 0; i < len; i ++) { - if (b0->data[i] != ((const unsigned char *) blk)[i]) { - if (downcase (b0->data[i]) != - downcase (((const unsigned char *) blk)[i])) return 0; - } - } - return 1; -} - -/* - * int bltrimws (bstring b) - * - * Delete whitespace contiguous from the left end of the string. - */ -int bltrimws (bstring b) { -int i, len; - - if (b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - - for (len = b->slen, i = 0; i < len; i++) { - if (!wspace (b->data[i])) { - return bdelete (b, 0, i); - } - } - - b->data[0] = (unsigned char) '\0'; - b->slen = 0; - return BSTR_OK; -} - -/* - * int brtrimws (bstring b) - * - * Delete whitespace contiguous from the right end of the string. - */ -int brtrimws (bstring b) { -int i; - - if (b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - - for (i = b->slen - 1; i >= 0; i--) { - if (!wspace (b->data[i])) { - if (b->mlen > i) b->data[i+1] = (unsigned char) '\0'; - b->slen = i + 1; - return BSTR_OK; - } - } - - b->data[0] = (unsigned char) '\0'; - b->slen = 0; - return BSTR_OK; -} - -/* - * int btrimws (bstring b) - * - * Delete whitespace contiguous from both ends of the string. - */ -int btrimws (bstring b) { -int i, j; - - if (b == NULL || b->data == NULL || b->mlen < b->slen || - b->slen < 0 || b->mlen <= 0) return BSTR_ERR; - - for (i = b->slen - 1; i >= 0; i--) { - if (!wspace (b->data[i])) { - if (b->mlen > i) b->data[i+1] = (unsigned char) '\0'; - b->slen = i + 1; - for (j = 0; wspace (b->data[j]); j++) {} - return bdelete (b, 0, j); - } - } - - b->data[0] = (unsigned char) '\0'; - b->slen = 0; - return BSTR_OK; -} - -/* int biseq (const_bstring b0, const_bstring b1) - * - * Compare the string b0 and b1. If the strings differ, 0 is returned, if - * the strings are the same, 1 is returned, if there is an error, -1 is - * returned. If the length of the strings are different, this function is - * O(1). '\0' termination characters are not treated in any special way. - */ -int biseq (const_bstring b0, const_bstring b1) { - if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || - b0->slen < 0 || b1->slen < 0) return BSTR_ERR; - if (b0->slen != b1->slen) return BSTR_OK; - if (b0->data == b1->data || b0->slen == 0) return 1; - return !bstr__memcmp (b0->data, b1->data, b0->slen); -} - -/* int bisstemeqblk (const_bstring b0, const void * blk, int len) - * - * Compare beginning of string b0 with a block of memory of length len for - * equality. If the beginning of b0 differs from the memory block (or if b0 - * is too short), 0 is returned, if the strings are the same, 1 is returned, - * if there is an error, -1 is returned. '\0' characters are not treated in - * any special way. - */ -int bisstemeqblk (const_bstring b0, const void * blk, int len) { -int i; - - if (bdata (b0) == NULL || b0->slen < 0 || NULL == blk || len < 0) - return BSTR_ERR; - if (b0->slen < len) return BSTR_OK; - if (b0->data == (const unsigned char *) blk || len == 0) return 1; - - for (i = 0; i < len; i ++) { - if (b0->data[i] != ((const unsigned char *) blk)[i]) return BSTR_OK; - } - return 1; -} - -/* int biseqcstr (const_bstring b, const char *s) - * - * Compare the bstring b and char * string s. The C string s must be '\0' - * terminated at exactly the length of the bstring b, and the contents - * between the two must be identical with the bstring b with no '\0' - * characters for the two contents to be considered equal. This is - * equivalent to the condition that their current contents will be always be - * equal when comparing them in the same format after converting one or the - * other. If the strings are equal 1 is returned, if they are unequal 0 is - * returned and if there is a detectable error BSTR_ERR is returned. - */ -int biseqcstr (const_bstring b, const char * s) { -int i; - if (b == NULL || s == NULL || b->data == NULL || b->slen < 0) return BSTR_ERR; - for (i=0; i < b->slen; i++) { - if (s[i] == '\0' || b->data[i] != (unsigned char) s[i]) return BSTR_OK; - } - return s[i] == '\0'; -} - -/* int biseqcstrcaseless (const_bstring b, const char *s) - * - * Compare the bstring b and char * string s. The C string s must be '\0' - * terminated at exactly the length of the bstring b, and the contents - * between the two must be identical except for case with the bstring b with - * no '\0' characters for the two contents to be considered equal. This is - * equivalent to the condition that their current contents will be always be - * equal ignoring case when comparing them in the same format after - * converting one or the other. If the strings are equal, except for case, - * 1 is returned, if they are unequal regardless of case 0 is returned and - * if there is a detectable error BSTR_ERR is returned. - */ -int biseqcstrcaseless (const_bstring b, const char * s) { -int i; - if (b == NULL || s == NULL || b->data == NULL || b->slen < 0) return BSTR_ERR; - for (i=0; i < b->slen; i++) { - if (s[i] == '\0' || - (b->data[i] != (unsigned char) s[i] && - downcase (b->data[i]) != (unsigned char) downcase (s[i]))) - return BSTR_OK; - } - return s[i] == '\0'; -} - -/* int bstrcmp (const_bstring b0, const_bstring b1) - * - * Compare the string b0 and b1. If there is an error, SHRT_MIN is returned, - * otherwise a value less than or greater than zero, indicating that the - * string pointed to by b0 is lexicographically less than or greater than - * the string pointed to by b1 is returned. If the the string lengths are - * unequal but the characters up until the length of the shorter are equal - * then a value less than, or greater than zero, indicating that the string - * pointed to by b0 is shorter or longer than the string pointed to by b1 is - * returned. 0 is returned if and only if the two strings are the same. If - * the length of the strings are different, this function is O(n). Like its - * standard C library counter part strcmp, the comparison does not proceed - * past any '\0' termination characters encountered. - */ -int bstrcmp (const_bstring b0, const_bstring b1) { -int i, v, n; - - if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || - b0->slen < 0 || b1->slen < 0) return SHRT_MIN; - n = b0->slen; if (n > b1->slen) n = b1->slen; - if (b0->slen == b1->slen && (b0->data == b1->data || b0->slen == 0)) - return BSTR_OK; - - for (i = 0; i < n; i ++) { - v = ((char) b0->data[i]) - ((char) b1->data[i]); - if (v != 0) return v; - if (b0->data[i] == (unsigned char) '\0') return BSTR_OK; - } - - if (b0->slen > n) return 1; - if (b1->slen > n) return -1; - return BSTR_OK; -} - -/* int bstrncmp (const_bstring b0, const_bstring b1, int n) - * - * Compare the string b0 and b1 for at most n characters. If there is an - * error, SHRT_MIN is returned, otherwise a value is returned as if b0 and - * b1 were first truncated to at most n characters then bstrcmp was called - * with these new strings are paremeters. If the length of the strings are - * different, this function is O(n). Like its standard C library counter - * part strcmp, the comparison does not proceed past any '\0' termination - * characters encountered. - */ -int bstrncmp (const_bstring b0, const_bstring b1, int n) { -int i, v, m; - - if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || - b0->slen < 0 || b1->slen < 0) return SHRT_MIN; - m = n; - if (m > b0->slen) m = b0->slen; - if (m > b1->slen) m = b1->slen; - - if (b0->data != b1->data) { - for (i = 0; i < m; i ++) { - v = ((char) b0->data[i]) - ((char) b1->data[i]); - if (v != 0) return v; - if (b0->data[i] == (unsigned char) '\0') return BSTR_OK; - } - } - - if (n == m || b0->slen == b1->slen) return BSTR_OK; - - if (b0->slen > m) return 1; - return -1; -} - -/* bstring bmidstr (const_bstring b, int left, int len) - * - * Create a bstring which is the substring of b starting from position left - * and running for a length len (clamped by the end of the bstring b.) If - * b is detectably invalid, then NULL is returned. The section described - * by (left, len) is clamped to the boundaries of b. - */ -bstring bmidstr (const_bstring b, int left, int len) { - - if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; - - if (left < 0) { - len += left; - left = 0; - } - - if (len > b->slen - left) len = b->slen - left; - - if (len <= 0) return bfromcstr (""); - return blk2bstr (b->data + left, len); -} - -/* int bdelete (bstring b, int pos, int len) - * - * Removes characters from pos to pos+len-1 inclusive and shifts the tail of - * the bstring starting from pos+len to pos. len must be positive for this - * call to have any effect. The section of the string described by (pos, - * len) is clamped to boundaries of the bstring b. - */ -int bdelete (bstring b, int pos, int len) { - /* Clamp to left side of bstring */ - if (pos < 0) { - len += pos; - pos = 0; - } - - if (len < 0 || b == NULL || b->data == NULL || b->slen < 0 || - b->mlen < b->slen || b->mlen <= 0) - return BSTR_ERR; - if (len > 0 && pos < b->slen) { - if (pos + len >= b->slen) { - b->slen = pos; - } else { - bBlockCopy ((char *) (b->data + pos), - (char *) (b->data + pos + len), - b->slen - (pos+len)); - b->slen -= len; - } - b->data[b->slen] = (unsigned char) '\0'; - } - return BSTR_OK; -} - -/* int bdestroy (bstring b) - * - * Free up the bstring. Note that if b is detectably invalid or not writable - * then no action is performed and BSTR_ERR is returned. Like a freed memory - * allocation, dereferences, writes or any other action on b after it has - * been bdestroyed is undefined. - */ -int bdestroy (bstring b) { - if (b == NULL || b->slen < 0 || b->mlen <= 0 || b->mlen < b->slen || - b->data == NULL) - return BSTR_ERR; - - bstr__free (b->data); - - /* In case there is any stale usage, there is one more chance to - notice this error. */ - - b->slen = -1; - b->mlen = -__LINE__; - b->data = NULL; - - bstr__free (b); - return BSTR_OK; -} - -/* int binstr (const_bstring b1, int pos, const_bstring b2) - * - * Search for the bstring b2 in b1 starting from position pos, and searching - * forward. If it is found then return with the first position where it is - * found, otherwise return BSTR_ERR. Note that this is just a brute force - * string searcher that does not attempt clever things like the Boyer-Moore - * search algorithm. Because of this there are many degenerate cases where - * this can take much longer than it needs to. - */ -int binstr (const_bstring b1, int pos, const_bstring b2) { -int j, ii, ll, lf; -unsigned char * d0; -unsigned char c0; -register unsigned char * d1; -register unsigned char c1; -register int i; - - if (b1 == NULL || b1->data == NULL || b1->slen < 0 || - b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; - if (b1->slen == pos) return (b2->slen == 0)?pos:BSTR_ERR; - if (b1->slen < pos || pos < 0) return BSTR_ERR; - if (b2->slen == 0) return pos; - - /* No space to find such a string? */ - if ((lf = b1->slen - b2->slen + 1) <= pos) return BSTR_ERR; - - /* An obvious alias case */ - if (b1->data == b2->data && pos == 0) return 0; - - i = pos; - - d0 = b2->data; - d1 = b1->data; - ll = b2->slen; - - /* Peel off the b2->slen == 1 case */ - c0 = d0[0]; - if (1 == ll) { - for (;i < lf; i++) if (c0 == d1[i]) return i; - return BSTR_ERR; - } - - c1 = c0; - j = 0; - lf = b1->slen - 1; - - ii = -1; - if (i < lf) do { - /* Unrolled current character test */ - if (c1 != d1[i]) { - if (c1 != d1[1+i]) { - i += 2; - continue; - } - i++; - } - - /* Take note if this is the start of a potential match */ - if (0 == j) ii = i; - - /* Shift the test character down by one */ - j++; - i++; - - /* If this isn't past the last character continue */ - if (j < ll) { - c1 = d0[j]; - continue; - } - - N0:; - - /* If no characters mismatched, then we matched */ - if (i == ii+j) return ii; - - /* Shift back to the beginning */ - i -= j; - j = 0; - c1 = c0; - } while (i < lf); - - /* Deal with last case if unrolling caused a misalignment */ - if (i == lf && ll == j+1 && c1 == d1[i]) goto N0; - - return BSTR_ERR; -} - -/* int binstrr (const_bstring b1, int pos, const_bstring b2) - * - * Search for the bstring b2 in b1 starting from position pos, and searching - * backward. If it is found then return with the first position where it is - * found, otherwise return BSTR_ERR. Note that this is just a brute force - * string searcher that does not attempt clever things like the Boyer-Moore - * search algorithm. Because of this there are many degenerate cases where - * this can take much longer than it needs to. - */ -int binstrr (const_bstring b1, int pos, const_bstring b2) { -int j, i, l; -unsigned char * d0, * d1; - - if (b1 == NULL || b1->data == NULL || b1->slen < 0 || - b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; - if (b1->slen == pos && b2->slen == 0) return pos; - if (b1->slen < pos || pos < 0) return BSTR_ERR; - if (b2->slen == 0) return pos; - - /* Obvious alias case */ - if (b1->data == b2->data && pos == 0 && b2->slen <= b1->slen) return 0; - - i = pos; - if ((l = b1->slen - b2->slen) < 0) return BSTR_ERR; - - /* If no space to find such a string then snap back */ - if (l + 1 <= i) i = l; - j = 0; - - d0 = b2->data; - d1 = b1->data; - l = b2->slen; - - for (;;) { - if (d0[j] == d1[i + j]) { - j ++; - if (j >= l) return i; - } else { - i --; - if (i < 0) break; - j=0; - } - } - - return BSTR_ERR; -} - -/* int binstrcaseless (const_bstring b1, int pos, const_bstring b2) - * - * Search for the bstring b2 in b1 starting from position pos, and searching - * forward but without regard to case. If it is found then return with the - * first position where it is found, otherwise return BSTR_ERR. Note that - * this is just a brute force string searcher that does not attempt clever - * things like the Boyer-Moore search algorithm. Because of this there are - * many degenerate cases where this can take much longer than it needs to. - */ -int binstrcaseless (const_bstring b1, int pos, const_bstring b2) { -int j, i, l, ll; -unsigned char * d0, * d1; - - if (b1 == NULL || b1->data == NULL || b1->slen < 0 || - b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; - if (b1->slen == pos) return (b2->slen == 0)?pos:BSTR_ERR; - if (b1->slen < pos || pos < 0) return BSTR_ERR; - if (b2->slen == 0) return pos; - - l = b1->slen - b2->slen + 1; - - /* No space to find such a string? */ - if (l <= pos) return BSTR_ERR; - - /* An obvious alias case */ - if (b1->data == b2->data && pos == 0) return BSTR_OK; - - i = pos; - j = 0; - - d0 = b2->data; - d1 = b1->data; - ll = b2->slen; - - for (;;) { - if (d0[j] == d1[i + j] || downcase (d0[j]) == downcase (d1[i + j])) { - j ++; - if (j >= ll) return i; - } else { - i ++; - if (i >= l) break; - j=0; - } - } - - return BSTR_ERR; -} - -/* int binstrrcaseless (const_bstring b1, int pos, const_bstring b2) - * - * Search for the bstring b2 in b1 starting from position pos, and searching - * backward but without regard to case. If it is found then return with the - * first position where it is found, otherwise return BSTR_ERR. Note that - * this is just a brute force string searcher that does not attempt clever - * things like the Boyer-Moore search algorithm. Because of this there are - * many degenerate cases where this can take much longer than it needs to. - */ -int binstrrcaseless (const_bstring b1, int pos, const_bstring b2) { -int j, i, l; -unsigned char * d0, * d1; - - if (b1 == NULL || b1->data == NULL || b1->slen < 0 || - b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; - if (b1->slen == pos && b2->slen == 0) return pos; - if (b1->slen < pos || pos < 0) return BSTR_ERR; - if (b2->slen == 0) return pos; - - /* Obvious alias case */ - if (b1->data == b2->data && pos == 0 && b2->slen <= b1->slen) return BSTR_OK; - - i = pos; - if ((l = b1->slen - b2->slen) < 0) return BSTR_ERR; - - /* If no space to find such a string then snap back */ - if (l + 1 <= i) i = l; - j = 0; - - d0 = b2->data; - d1 = b1->data; - l = b2->slen; - - for (;;) { - if (d0[j] == d1[i + j] || downcase (d0[j]) == downcase (d1[i + j])) { - j ++; - if (j >= l) return i; - } else { - i --; - if (i < 0) break; - j=0; - } - } - - return BSTR_ERR; -} - - -/* int bstrchrp (const_bstring b, int c, int pos) - * - * Search for the character c in b forwards from the position pos - * (inclusive). - */ -int bstrchrp (const_bstring b, int c, int pos) { -unsigned char * p; - - if (b == NULL || b->data == NULL || b->slen <= pos || pos < 0) return BSTR_ERR; - p = (unsigned char *) bstr__memchr ((b->data + pos), (unsigned char) c, (b->slen - pos)); - if (p) return (int) (p - b->data); - return BSTR_ERR; -} - -/* int bstrrchrp (const_bstring b, int c, int pos) - * - * Search for the character c in b backwards from the position pos in string - * (inclusive). - */ -int bstrrchrp (const_bstring b, int c, int pos) { -int i; - - if (b == NULL || b->data == NULL || b->slen <= pos || pos < 0) return BSTR_ERR; - for (i=pos; i >= 0; i--) { - if (b->data[i] == (unsigned char) c) return i; - } - return BSTR_ERR; -} - -#if !defined (BSTRLIB_AGGRESSIVE_MEMORY_FOR_SPEED_TRADEOFF) -#define LONG_LOG_BITS_QTY (3) -#define LONG_BITS_QTY (1 << LONG_LOG_BITS_QTY) -#define LONG_TYPE unsigned char - -#define CFCLEN ((1 << CHAR_BIT) / LONG_BITS_QTY) -struct charField { LONG_TYPE content[CFCLEN]; }; -#define testInCharField(cf,c) ((cf)->content[(c) >> LONG_LOG_BITS_QTY] & (((long)1) << ((c) & (LONG_BITS_QTY-1)))) -#define setInCharField(cf,idx) { \ - unsigned int c = (unsigned int) (idx); \ - (cf)->content[c >> LONG_LOG_BITS_QTY] |= (LONG_TYPE) (1ul << (c & (LONG_BITS_QTY-1))); \ -} - -#else - -#define CFCLEN (1 << CHAR_BIT) -struct charField { unsigned char content[CFCLEN]; }; -#define testInCharField(cf,c) ((cf)->content[(unsigned char) (c)]) -#define setInCharField(cf,idx) (cf)->content[(unsigned int) (idx)] = ~0 - -#endif - -/* Convert a bstring to charField */ -static int buildCharField (struct charField * cf, const_bstring b) { -int i; - if (b == NULL || b->data == NULL || b->slen <= 0) return BSTR_ERR; - memset ((void *) cf->content, 0, sizeof (struct charField)); - for (i=0; i < b->slen; i++) { - setInCharField (cf, b->data[i]); - } - return BSTR_OK; -} - -static void invertCharField (struct charField * cf) { -int i; - for (i=0; i < CFCLEN; i++) cf->content[i] = ~cf->content[i]; -} - -/* Inner engine for binchr */ -static int binchrCF (const unsigned char * data, int len, int pos, const struct charField * cf) { -int i; - for (i=pos; i < len; i++) { - unsigned char c = (unsigned char) data[i]; - if (testInCharField (cf, c)) return i; - } - return BSTR_ERR; -} - -/* int binchr (const_bstring b0, int pos, const_bstring b1); - * - * Search for the first position in b0 starting from pos or after, in which - * one of the characters in b1 is found and return it. If such a position - * does not exist in b0, then BSTR_ERR is returned. - */ -int binchr (const_bstring b0, int pos, const_bstring b1) { -struct charField chrs; - if (pos < 0 || b0 == NULL || b0->data == NULL || - b0->slen <= pos) return BSTR_ERR; - if (1 == b1->slen) return bstrchrp (b0, b1->data[0], pos); - if (0 > buildCharField (&chrs, b1)) return BSTR_ERR; - return binchrCF (b0->data, b0->slen, pos, &chrs); -} - -/* Inner engine for binchrr */ -static int binchrrCF (const unsigned char * data, int pos, const struct charField * cf) { -int i; - for (i=pos; i >= 0; i--) { - unsigned int c = (unsigned int) data[i]; - if (testInCharField (cf, c)) return i; - } - return BSTR_ERR; -} - -/* int binchrr (const_bstring b0, int pos, const_bstring b1); - * - * Search for the last position in b0 no greater than pos, in which one of - * the characters in b1 is found and return it. If such a position does not - * exist in b0, then BSTR_ERR is returned. - */ -int binchrr (const_bstring b0, int pos, const_bstring b1) { -struct charField chrs; - if (pos < 0 || b0 == NULL || b0->data == NULL || b1 == NULL || - b0->slen < pos) return BSTR_ERR; - if (pos == b0->slen) pos--; - if (1 == b1->slen) return bstrrchrp (b0, b1->data[0], pos); - if (0 > buildCharField (&chrs, b1)) return BSTR_ERR; - return binchrrCF (b0->data, pos, &chrs); -} - -/* int bninchr (const_bstring b0, int pos, const_bstring b1); - * - * Search for the first position in b0 starting from pos or after, in which - * none of the characters in b1 is found and return it. If such a position - * does not exist in b0, then BSTR_ERR is returned. - */ -int bninchr (const_bstring b0, int pos, const_bstring b1) { -struct charField chrs; - if (pos < 0 || b0 == NULL || b0->data == NULL || - b0->slen <= pos) return BSTR_ERR; - if (buildCharField (&chrs, b1) < 0) return BSTR_ERR; - invertCharField (&chrs); - return binchrCF (b0->data, b0->slen, pos, &chrs); -} - -/* int bninchrr (const_bstring b0, int pos, const_bstring b1); - * - * Search for the last position in b0 no greater than pos, in which none of - * the characters in b1 is found and return it. If such a position does not - * exist in b0, then BSTR_ERR is returned. - */ -int bninchrr (const_bstring b0, int pos, const_bstring b1) { -struct charField chrs; - if (pos < 0 || b0 == NULL || b0->data == NULL || - b0->slen < pos) return BSTR_ERR; - if (pos == b0->slen) pos--; - if (buildCharField (&chrs, b1) < 0) return BSTR_ERR; - invertCharField (&chrs); - return binchrrCF (b0->data, pos, &chrs); -} - -/* int bsetstr (bstring b0, int pos, bstring b1, unsigned char fill) - * - * Overwrite the string b0 starting at position pos with the string b1. If - * the position pos is past the end of b0, then the character "fill" is - * appended as necessary to make up the gap between the end of b0 and pos. - * If b1 is NULL, it behaves as if it were a 0-length string. - */ -int bsetstr (bstring b0, int pos, const_bstring b1, unsigned char fill) { -int d, newlen; -ptrdiff_t pd; -bstring aux = (bstring) b1; - - if (pos < 0 || b0 == NULL || b0->slen < 0 || NULL == b0->data || - b0->mlen < b0->slen || b0->mlen <= 0) return BSTR_ERR; - if (b1 != NULL && (b1->slen < 0 || b1->data == NULL)) return BSTR_ERR; - - d = pos; - - /* Aliasing case */ - if (NULL != aux) { - if ((pd = (ptrdiff_t) (b1->data - b0->data)) >= 0 && pd < (ptrdiff_t) b0->mlen) { - if (NULL == (aux = bstrcpy (b1))) return BSTR_ERR; - } - d += aux->slen; - } - - /* Increase memory size if necessary */ - if (balloc (b0, d + 1) != BSTR_OK) { - if (aux != b1) bdestroy (aux); - return BSTR_ERR; - } - - newlen = b0->slen; - - /* Fill in "fill" character as necessary */ - if (pos > newlen) { - bstr__memset (b0->data + b0->slen, (int) fill, (size_t) (pos - b0->slen)); - newlen = pos; - } - - /* Copy b1 to position pos in b0. */ - if (aux != NULL) { - bBlockCopy ((char *) (b0->data + pos), (char *) aux->data, aux->slen); - if (aux != b1) bdestroy (aux); - } - - /* Indicate the potentially increased size of b0 */ - if (d > newlen) newlen = d; - - b0->slen = newlen; - b0->data[newlen] = (unsigned char) '\0'; - - return BSTR_OK; -} - -/* int binsert (bstring b1, int pos, bstring b2, unsigned char fill) - * - * Inserts the string b2 into b1 at position pos. If the position pos is - * past the end of b1, then the character "fill" is appended as necessary to - * make up the gap between the end of b1 and pos. Unlike bsetstr, binsert - * does not allow b2 to be NULL. - */ -int binsert (bstring b1, int pos, const_bstring b2, unsigned char fill) { -int d, l; -ptrdiff_t pd; -bstring aux = (bstring) b2; - - if (pos < 0 || b1 == NULL || b2 == NULL || b1->slen < 0 || - b2->slen < 0 || b1->mlen < b1->slen || b1->mlen <= 0) return BSTR_ERR; - - /* Aliasing case */ - if ((pd = (ptrdiff_t) (b2->data - b1->data)) >= 0 && pd < (ptrdiff_t) b1->mlen) { - if (NULL == (aux = bstrcpy (b2))) return BSTR_ERR; - } - - /* Compute the two possible end pointers */ - d = b1->slen + aux->slen; - l = pos + aux->slen; - if ((d|l) < 0) return BSTR_ERR; - - if (l > d) { - /* Inserting past the end of the string */ - if (balloc (b1, l + 1) != BSTR_OK) { - if (aux != b2) bdestroy (aux); - return BSTR_ERR; - } - bstr__memset (b1->data + b1->slen, (int) fill, (size_t) (pos - b1->slen)); - b1->slen = l; - } else { - /* Inserting in the middle of the string */ - if (balloc (b1, d + 1) != BSTR_OK) { - if (aux != b2) bdestroy (aux); - return BSTR_ERR; - } - bBlockCopy (b1->data + l, b1->data + pos, d - l); - b1->slen = d; - } - bBlockCopy (b1->data + pos, aux->data, aux->slen); - b1->data[b1->slen] = (unsigned char) '\0'; - if (aux != b2) bdestroy (aux); - return BSTR_OK; -} - -/* int breplace (bstring b1, int pos, int len, bstring b2, - * unsigned char fill) - * - * Replace a section of a string from pos for a length len with the string b2. - * fill is used is pos > b1->slen. - */ -int breplace (bstring b1, int pos, int len, const_bstring b2, - unsigned char fill) { -int pl, ret; -ptrdiff_t pd; -bstring aux = (bstring) b2; - - if (pos < 0 || len < 0 || (pl = pos + len) < 0 || b1 == NULL || - b2 == NULL || b1->data == NULL || b2->data == NULL || - b1->slen < 0 || b2->slen < 0 || b1->mlen < b1->slen || - b1->mlen <= 0) return BSTR_ERR; - - /* Straddles the end? */ - if (pl >= b1->slen) { - if ((ret = bsetstr (b1, pos, b2, fill)) < 0) return ret; - if (pos + b2->slen < b1->slen) { - b1->slen = pos + b2->slen; - b1->data[b1->slen] = (unsigned char) '\0'; - } - return ret; - } - - /* Aliasing case */ - if ((pd = (ptrdiff_t) (b2->data - b1->data)) >= 0 && pd < (ptrdiff_t) b1->slen) { - if (NULL == (aux = bstrcpy (b2))) return BSTR_ERR; - } - - if (aux->slen > len) { - if (balloc (b1, b1->slen + aux->slen - len) != BSTR_OK) { - if (aux != b2) bdestroy (aux); - return BSTR_ERR; - } - } - - if (aux->slen != len) bstr__memmove (b1->data + pos + aux->slen, b1->data + pos + len, b1->slen - (pos + len)); - bstr__memcpy (b1->data + pos, aux->data, aux->slen); - b1->slen += aux->slen - len; - b1->data[b1->slen] = (unsigned char) '\0'; - if (aux != b2) bdestroy (aux); - return BSTR_OK; -} - -/* int bfindreplace (bstring b, const_bstring find, const_bstring repl, - * int pos) - * - * Replace all occurrences of a find string with a replace string after a - * given point in a bstring. - */ - -typedef int (*instr_fnptr) (const_bstring s1, int pos, const_bstring s2); - -static int findreplaceengine (bstring b, const_bstring find, const_bstring repl, int pos, instr_fnptr instr) { -int i, ret, slen, mlen, delta, acc; -int * d; -int static_d[32]; -ptrdiff_t pd; -bstring auxf = (bstring) find; -bstring auxr = (bstring) repl; - - if (b == NULL || b->data == NULL || find == NULL || - find->data == NULL || repl == NULL || repl->data == NULL || - pos < 0 || find->slen <= 0 || b->mlen < 0 || b->slen > b->mlen || - b->mlen <= 0 || b->slen < 0 || repl->slen < 0) return BSTR_ERR; - if (pos > b->slen - find->slen) return BSTR_OK; - - /* Alias with find string */ - pd = (ptrdiff_t) (find->data - b->data); - if ((ptrdiff_t) (pos - find->slen) < pd && pd < (ptrdiff_t) b->slen) { - if (NULL == (auxf = bstrcpy (find))) return BSTR_ERR; - } - - /* Alias with repl string */ - pd = (ptrdiff_t) (repl->data - b->data); - if ((ptrdiff_t) (pos - repl->slen) < pd && pd < (ptrdiff_t) b->slen) { - if (NULL == (auxr = bstrcpy (repl))) { - if (auxf != find) bdestroy (auxf); - return BSTR_ERR; - } - } - - delta = auxf->slen - auxr->slen; - - /* in-place replacement since find and replace strings are of equal - length */ - if (delta == 0) { - while ((pos = instr (b, pos, auxf)) >= 0) { - bstr__memcpy (b->data + pos, auxr->data, auxr->slen); - pos += auxf->slen; - } - if (auxf != find) bdestroy (auxf); - if (auxr != repl) bdestroy (auxr); - return BSTR_OK; - } - - /* shrinking replacement since auxf->slen > auxr->slen */ - if (delta > 0) { - acc = 0; - - while ((i = instr (b, pos, auxf)) >= 0) { - if (acc && i > pos) - bstr__memmove (b->data + pos - acc, b->data + pos, i - pos); - if (auxr->slen) - bstr__memcpy (b->data + i - acc, auxr->data, auxr->slen); - acc += delta; - pos = i + auxf->slen; - } - - if (acc) { - i = b->slen; - if (i > pos) - bstr__memmove (b->data + pos - acc, b->data + pos, i - pos); - b->slen -= acc; - b->data[b->slen] = (unsigned char) '\0'; - } - - if (auxf != find) bdestroy (auxf); - if (auxr != repl) bdestroy (auxr); - return BSTR_OK; - } - - /* expanding replacement since find->slen < repl->slen. Its a lot - more complicated. */ - - mlen = 32; - d = (int *) static_d; /* Avoid malloc for trivial cases */ - acc = slen = 0; - - while ((pos = instr (b, pos, auxf)) >= 0) { - if (slen + 1 >= mlen) { - int sl; - int * t; - mlen += mlen; - sl = sizeof (int *) * mlen; - if (static_d == d) d = NULL; - if (sl < mlen || NULL == (t = (int *) bstr__realloc (d, sl))) { - ret = BSTR_ERR; - goto done; - } - if (NULL == d) bstr__memcpy (t, static_d, sizeof (static_d)); - d = t; - } - d[slen] = pos; - slen++; - acc -= delta; - pos += auxf->slen; - if (pos < 0 || acc < 0) { - ret = BSTR_ERR; - goto done; - } - } - d[slen] = b->slen; - - if (BSTR_OK == (ret = balloc (b, b->slen + acc + 1))) { - b->slen += acc; - for (i = slen-1; i >= 0; i--) { - int s, l; - s = d[i] + auxf->slen; - l = d[i+1] - s; - if (l) { - bstr__memmove (b->data + s + acc, b->data + s, l); - } - if (auxr->slen) { - bstr__memmove (b->data + s + acc - auxr->slen, - auxr->data, auxr->slen); - } - acc += delta; - } - b->data[b->slen] = (unsigned char) '\0'; - } - - done:; - if (static_d == d) d = NULL; - bstr__free (d); - if (auxf != find) bdestroy (auxf); - if (auxr != repl) bdestroy (auxr); - return ret; -} - -/* int bfindreplace (bstring b, const_bstring find, const_bstring repl, - * int pos) - * - * Replace all occurrences of a find string with a replace string after a - * given point in a bstring. - */ -int bfindreplace (bstring b, const_bstring find, const_bstring repl, int pos) { - return findreplaceengine (b, find, repl, pos, binstr); -} - -/* int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, - * int pos) - * - * Replace all occurrences of a find string, ignoring case, with a replace - * string after a given point in a bstring. - */ -int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, int pos) { - return findreplaceengine (b, find, repl, pos, binstrcaseless); -} - -/* int binsertch (bstring b, int pos, int len, unsigned char fill) - * - * Inserts the character fill repeatedly into b at position pos for a - * length len. If the position pos is past the end of b, then the - * character "fill" is appended as necessary to make up the gap between the - * end of b and the position pos + len. - */ -int binsertch (bstring b, int pos, int len, unsigned char fill) { -int d, l, i; - - if (pos < 0 || b == NULL || b->slen < 0 || b->mlen < b->slen || - b->mlen <= 0 || len < 0) return BSTR_ERR; - - /* Compute the two possible end pointers */ - d = b->slen + len; - l = pos + len; - if ((d|l) < 0) return BSTR_ERR; - - if (l > d) { - /* Inserting past the end of the string */ - if (balloc (b, l + 1) != BSTR_OK) return BSTR_ERR; - pos = b->slen; - b->slen = l; - } else { - /* Inserting in the middle of the string */ - if (balloc (b, d + 1) != BSTR_OK) return BSTR_ERR; - for (i = d - 1; i >= l; i--) { - b->data[i] = b->data[i - len]; - } - b->slen = d; - } - - for (i=pos; i < l; i++) b->data[i] = fill; - b->data[b->slen] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* int bpattern (bstring b, int len) - * - * Replicate the bstring, b in place, end to end repeatedly until it - * surpasses len characters, then chop the result to exactly len characters. - * This function operates in-place. The function will return with BSTR_ERR - * if b is NULL or of length 0, otherwise BSTR_OK is returned. - */ -int bpattern (bstring b, int len) { -int i, d; - - d = blength (b); - if (d <= 0 || len < 0 || balloc (b, len + 1) != BSTR_OK) return BSTR_ERR; - if (len > 0) { - if (d == 1) return bsetstr (b, len, NULL, b->data[0]); - for (i = d; i < len; i++) b->data[i] = b->data[i - d]; - } - b->data[len] = (unsigned char) '\0'; - b->slen = len; - return BSTR_OK; -} - -#define BS_BUFF_SZ (1024) - -/* int breada (bstring b, bNread readPtr, void * parm) - * - * Use a finite buffer fread-like function readPtr to concatenate to the - * bstring b the entire contents of file-like source data in a roughly - * efficient way. - */ -int breada (bstring b, bNread readPtr, void * parm) { -int i, l, n; - - if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || - b->mlen <= 0 || readPtr == NULL) return BSTR_ERR; - - i = b->slen; - for (n=i+16; ; n += ((n < BS_BUFF_SZ) ? n : BS_BUFF_SZ)) { - if (BSTR_OK != balloc (b, n + 1)) return BSTR_ERR; - l = (int) readPtr ((void *) (b->data + i), 1, n - i, parm); - i += l; - b->slen = i; - if (i < n) break; - } - - b->data[i] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* bstring bread (bNread readPtr, void * parm) - * - * Use a finite buffer fread-like function readPtr to create a bstring - * filled with the entire contents of file-like source data in a roughly - * efficient way. - */ -bstring bread (bNread readPtr, void * parm) { -bstring buff; - - if (0 > breada (buff = bfromcstr (""), readPtr, parm)) { - bdestroy (buff); - return NULL; - } - return buff; -} - -/* int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator) - * - * Use an fgetc-like single character stream reading function (getcPtr) to - * obtain a sequence of characters which are concatenated to the end of the - * bstring b. The stream read is terminated by the passed in terminator - * parameter. - * - * If getcPtr returns with a negative number, or the terminator character - * (which is appended) is read, then the stream reading is halted and the - * function returns with a partial result in b. If there is an empty partial - * result, 1 is returned. If no characters are read, or there is some other - * detectable error, BSTR_ERR is returned. - */ -int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator) { -int c, d, e; - - if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || - b->mlen <= 0 || getcPtr == NULL) return BSTR_ERR; - d = 0; - e = b->mlen - 2; - - while ((c = getcPtr (parm)) >= 0) { - if (d > e) { - b->slen = d; - if (balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; - e = b->mlen - 2; - } - b->data[d] = (unsigned char) c; - d++; - if (c == terminator) break; - } - - b->data[d] = (unsigned char) '\0'; - b->slen = d; - - return d == 0 && c < 0; -} - -/* int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator) - * - * Use an fgetc-like single character stream reading function (getcPtr) to - * obtain a sequence of characters which are concatenated to the end of the - * bstring b. The stream read is terminated by the passed in terminator - * parameter. - * - * If getcPtr returns with a negative number, or the terminator character - * (which is appended) is read, then the stream reading is halted and the - * function returns with a partial result concatentated to b. If there is - * an empty partial result, 1 is returned. If no characters are read, or - * there is some other detectable error, BSTR_ERR is returned. - */ -int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator) { -int c, d, e; - - if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || - b->mlen <= 0 || getcPtr == NULL) return BSTR_ERR; - d = b->slen; - e = b->mlen - 2; - - while ((c = getcPtr (parm)) >= 0) { - if (d > e) { - b->slen = d; - if (balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; - e = b->mlen - 2; - } - b->data[d] = (unsigned char) c; - d++; - if (c == terminator) break; - } - - b->data[d] = (unsigned char) '\0'; - b->slen = d; - - return d == 0 && c < 0; -} - -/* bstring bgets (bNgetc getcPtr, void * parm, char terminator) - * - * Use an fgetc-like single character stream reading function (getcPtr) to - * obtain a sequence of characters which are concatenated into a bstring. - * The stream read is terminated by the passed in terminator function. - * - * If getcPtr returns with a negative number, or the terminator character - * (which is appended) is read, then the stream reading is halted and the - * result obtained thus far is returned. If no characters are read, or - * there is some other detectable error, NULL is returned. - */ -bstring bgets (bNgetc getcPtr, void * parm, char terminator) { -bstring buff; - - if (0 > bgetsa (buff = bfromcstr (""), getcPtr, parm, terminator) || 0 >= buff->slen) { - bdestroy (buff); - buff = NULL; - } - return buff; -} - -struct bStream { - bstring buff; /* Buffer for over-reads */ - void * parm; /* The stream handle for core stream */ - bNread readFnPtr; /* fread compatible fnptr for core stream */ - int isEOF; /* track file's EOF state */ - int maxBuffSz; -}; - -/* struct bStream * bsopen (bNread readPtr, void * parm) - * - * Wrap a given open stream (described by a fread compatible function - * pointer and stream handle) into an open bStream suitable for the bstring - * library streaming functions. - */ -struct bStream * bsopen (bNread readPtr, void * parm) { -struct bStream * s; - - if (readPtr == NULL) return NULL; - s = (struct bStream *) bstr__alloc (sizeof (struct bStream)); - if (s == NULL) return NULL; - s->parm = parm; - s->buff = bfromcstr (""); - s->readFnPtr = readPtr; - s->maxBuffSz = BS_BUFF_SZ; - s->isEOF = 0; - return s; -} - -/* int bsbufflength (struct bStream * s, int sz) - * - * Set the length of the buffer used by the bStream. If sz is zero, the - * length is not set. This function returns with the previous length. - */ -int bsbufflength (struct bStream * s, int sz) { -int oldSz; - if (s == NULL || sz < 0) return BSTR_ERR; - oldSz = s->maxBuffSz; - if (sz > 0) s->maxBuffSz = sz; - return oldSz; -} - -int bseof (const struct bStream * s) { - if (s == NULL || s->readFnPtr == NULL) return BSTR_ERR; - return s->isEOF && (s->buff->slen == 0); -} - -/* void * bsclose (struct bStream * s) - * - * Close the bStream, and return the handle to the stream that was originally - * used to open the given stream. - */ -void * bsclose (struct bStream * s) { -void * parm; - if (s == NULL) return NULL; - s->readFnPtr = NULL; - if (s->buff) bdestroy (s->buff); - s->buff = NULL; - parm = s->parm; - s->parm = NULL; - s->isEOF = 1; - bstr__free (s); - return parm; -} - -/* int bsreadlna (bstring r, struct bStream * s, char terminator) - * - * Read a bstring terminated by the terminator character or the end of the - * stream from the bStream (s) and return it into the parameter r. This - * function may read additional characters from the core stream that are not - * returned, but will be retained for subsequent read operations. - */ -int bsreadlna (bstring r, struct bStream * s, char terminator) { -int i, l, ret, rlo; -char * b; -struct tagbstring x; - - if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 || - r->slen < 0 || r->mlen < r->slen) return BSTR_ERR; - l = s->buff->slen; - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - b = (char *) s->buff->data; - x.data = (unsigned char *) b; - - /* First check if the current buffer holds the terminator */ - b[l] = terminator; /* Set sentinel */ - for (i=0; b[i] != terminator; i++) ; - if (i < l) { - x.slen = i + 1; - ret = bconcat (r, &x); - s->buff->slen = l; - if (BSTR_OK == ret) bdelete (s->buff, 0, i + 1); - return BSTR_OK; - } - - rlo = r->slen; - - /* If not then just concatenate the entire buffer to the output */ - x.slen = l; - if (BSTR_OK != bconcat (r, &x)) return BSTR_ERR; - - /* Perform direct in-place reads into the destination to allow for - the minimum of data-copies */ - for (;;) { - if (BSTR_OK != balloc (r, r->slen + s->maxBuffSz + 1)) return BSTR_ERR; - b = (char *) (r->data + r->slen); - l = (int) s->readFnPtr (b, 1, s->maxBuffSz, s->parm); - if (l <= 0) { - r->data[r->slen] = (unsigned char) '\0'; - s->buff->slen = 0; - s->isEOF = 1; - /* If nothing was read return with an error message */ - return BSTR_ERR & -(r->slen == rlo); - } - b[l] = terminator; /* Set sentinel */ - for (i=0; b[i] != terminator; i++) ; - if (i < l) break; - r->slen += l; - } - - /* Terminator found, push over-read back to buffer */ - i++; - r->slen += i; - s->buff->slen = l - i; - bstr__memcpy (s->buff->data, b + i, l - i); - r->data[r->slen] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* int bsreadlnsa (bstring r, struct bStream * s, bstring term) - * - * Read a bstring terminated by any character in the term string or the end - * of the stream from the bStream (s) and return it into the parameter r. - * This function may read additional characters from the core stream that - * are not returned, but will be retained for subsequent read operations. - */ -int bsreadlnsa (bstring r, struct bStream * s, const_bstring term) { -int i, l, ret, rlo; -unsigned char * b; -struct tagbstring x; -struct charField cf; - - if (s == NULL || s->buff == NULL || r == NULL || term == NULL || - term->data == NULL || r->mlen <= 0 || r->slen < 0 || - r->mlen < r->slen) return BSTR_ERR; - if (term->slen == 1) return bsreadlna (r, s, term->data[0]); - if (term->slen < 1 || buildCharField (&cf, term)) return BSTR_ERR; - - l = s->buff->slen; - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - b = (unsigned char *) s->buff->data; - x.data = b; - - /* First check if the current buffer holds the terminator */ - b[l] = term->data[0]; /* Set sentinel */ - for (i=0; !testInCharField (&cf, b[i]); i++) ; - if (i < l) { - x.slen = i + 1; - ret = bconcat (r, &x); - s->buff->slen = l; - if (BSTR_OK == ret) bdelete (s->buff, 0, i + 1); - return BSTR_OK; - } - - rlo = r->slen; - - /* If not then just concatenate the entire buffer to the output */ - x.slen = l; - if (BSTR_OK != bconcat (r, &x)) return BSTR_ERR; - - /* Perform direct in-place reads into the destination to allow for - the minimum of data-copies */ - for (;;) { - if (BSTR_OK != balloc (r, r->slen + s->maxBuffSz + 1)) return BSTR_ERR; - b = (unsigned char *) (r->data + r->slen); - l = (int) s->readFnPtr (b, 1, s->maxBuffSz, s->parm); - if (l <= 0) { - r->data[r->slen] = (unsigned char) '\0'; - s->buff->slen = 0; - s->isEOF = 1; - /* If nothing was read return with an error message */ - return BSTR_ERR & -(r->slen == rlo); - } - - b[l] = term->data[0]; /* Set sentinel */ - for (i=0; !testInCharField (&cf, b[i]); i++) ; - if (i < l) break; - r->slen += l; - } - - /* Terminator found, push over-read back to buffer */ - i++; - r->slen += i; - s->buff->slen = l - i; - bstr__memcpy (s->buff->data, b + i, l - i); - r->data[r->slen] = (unsigned char) '\0'; - return BSTR_OK; -} - -/* int bsreada (bstring r, struct bStream * s, int n) - * - * Read a bstring of length n (or, if it is fewer, as many bytes as is - * remaining) from the bStream. This function may read additional - * characters from the core stream that are not returned, but will be - * retained for subsequent read operations. This function will not read - * additional characters from the core stream beyond virtual stream pointer. - */ -int bsreada (bstring r, struct bStream * s, int n) { -int l, ret, orslen; -char * b; -struct tagbstring x; - - if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 - || r->slen < 0 || r->mlen < r->slen || n <= 0) return BSTR_ERR; - - n += r->slen; - if (n <= 0) return BSTR_ERR; - - l = s->buff->slen; - - orslen = r->slen; - - if (0 == l) { - if (s->isEOF) return BSTR_ERR; - if (r->mlen > n) { - l = (int) s->readFnPtr (r->data + r->slen, 1, n - r->slen, s->parm); - if (0 >= l || l > n - r->slen) { - s->isEOF = 1; - return BSTR_ERR; - } - r->slen += l; - r->data[r->slen] = (unsigned char) '\0'; - return 0; - } - } - - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - b = (char *) s->buff->data; - x.data = (unsigned char *) b; - - do { - if (l + r->slen >= n) { - x.slen = n - r->slen; - ret = bconcat (r, &x); - s->buff->slen = l; - if (BSTR_OK == ret) bdelete (s->buff, 0, x.slen); - return BSTR_ERR & -(r->slen == orslen); - } - - x.slen = l; - if (BSTR_OK != bconcat (r, &x)) break; - - l = n - r->slen; - if (l > s->maxBuffSz) l = s->maxBuffSz; - - l = (int) s->readFnPtr (b, 1, l, s->parm); - - } while (l > 0); - if (l < 0) l = 0; - if (l == 0) s->isEOF = 1; - s->buff->slen = l; - return BSTR_ERR & -(r->slen == orslen); -} - -/* int bsreadln (bstring r, struct bStream * s, char terminator) - * - * Read a bstring terminated by the terminator character or the end of the - * stream from the bStream (s) and return it into the parameter r. This - * function may read additional characters from the core stream that are not - * returned, but will be retained for subsequent read operations. - */ -int bsreadln (bstring r, struct bStream * s, char terminator) { - if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0) - return BSTR_ERR; - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - r->slen = 0; - return bsreadlna (r, s, terminator); -} - -/* int bsreadlns (bstring r, struct bStream * s, bstring term) - * - * Read a bstring terminated by any character in the term string or the end - * of the stream from the bStream (s) and return it into the parameter r. - * This function may read additional characters from the core stream that - * are not returned, but will be retained for subsequent read operations. - */ -int bsreadlns (bstring r, struct bStream * s, const_bstring term) { - if (s == NULL || s->buff == NULL || r == NULL || term == NULL - || term->data == NULL || r->mlen <= 0) return BSTR_ERR; - if (term->slen == 1) return bsreadln (r, s, term->data[0]); - if (term->slen < 1) return BSTR_ERR; - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - r->slen = 0; - return bsreadlnsa (r, s, term); -} - -/* int bsread (bstring r, struct bStream * s, int n) - * - * Read a bstring of length n (or, if it is fewer, as many bytes as is - * remaining) from the bStream. This function may read additional - * characters from the core stream that are not returned, but will be - * retained for subsequent read operations. This function will not read - * additional characters from the core stream beyond virtual stream pointer. - */ -int bsread (bstring r, struct bStream * s, int n) { - if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 - || n <= 0) return BSTR_ERR; - if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; - r->slen = 0; - return bsreada (r, s, n); -} - -/* int bsunread (struct bStream * s, const_bstring b) - * - * Insert a bstring into the bStream at the current position. These - * characters will be read prior to those that actually come from the core - * stream. - */ -int bsunread (struct bStream * s, const_bstring b) { - if (s == NULL || s->buff == NULL) return BSTR_ERR; - return binsert (s->buff, 0, b, (unsigned char) '?'); -} - -/* int bspeek (bstring r, const struct bStream * s) - * - * Return the currently buffered characters from the bStream that will be - * read prior to reads from the core stream. - */ -int bspeek (bstring r, const struct bStream * s) { - if (s == NULL || s->buff == NULL) return BSTR_ERR; - return bassign (r, s->buff); -} - -/* bstring bjoin (const struct bstrList * bl, const_bstring sep); - * - * Join the entries of a bstrList into one bstring by sequentially - * concatenating them with the sep string in between. If there is an error - * NULL is returned, otherwise a bstring with the correct result is returned. - */ -bstring bjoin (const struct bstrList * bl, const_bstring sep) { -bstring b; -int i, c, v; - - if (bl == NULL || bl->qty < 0) return NULL; - if (sep != NULL && (sep->slen < 0 || sep->data == NULL)) return NULL; - - for (i = 0, c = 1; i < bl->qty; i++) { - v = bl->entry[i]->slen; - if (v < 0) return NULL; /* Invalid input */ - c += v; - if (c < 0) return NULL; /* Wrap around ?? */ - } - - if (sep != NULL) c += (bl->qty - 1) * sep->slen; - - b = (bstring) bstr__alloc (sizeof (struct tagbstring)); - if (NULL == b) return NULL; /* Out of memory */ - b->data = (unsigned char *) bstr__alloc (c); - if (b->data == NULL) { - bstr__free (b); - return NULL; - } - - b->mlen = c; - b->slen = c-1; - - for (i = 0, c = 0; i < bl->qty; i++) { - if (i > 0 && sep != NULL) { - bstr__memcpy (b->data + c, sep->data, sep->slen); - c += sep->slen; - } - v = bl->entry[i]->slen; - bstr__memcpy (b->data + c, bl->entry[i]->data, v); - c += v; - } - b->data[c] = (unsigned char) '\0'; - return b; -} - -#define BSSSC_BUFF_LEN (256) - -/* int bssplitscb (struct bStream * s, const_bstring splitStr, - * int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) - * - * Iterate the set of disjoint sequential substrings read from a stream - * divided by any of the characters in splitStr. An empty splitStr causes - * the whole stream to be iterated once. - * - * Note: At the point of calling the cb function, the bStream pointer is - * pointed exactly at the position right after having read the split - * character. The cb function can act on the stream by causing the bStream - * pointer to move, and bssplitscb will continue by starting the next split - * at the position of the pointer after the return from cb. - * - * However, if the cb causes the bStream s to be destroyed then the cb must - * return with a negative value, otherwise bssplitscb will continue in an - * undefined manner. - */ -int bssplitscb (struct bStream * s, const_bstring splitStr, - int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) { -struct charField chrs; -bstring buff; -int i, p, ret; - - if (cb == NULL || s == NULL || s->readFnPtr == NULL - || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; - - if (NULL == (buff = bfromcstr (""))) return BSTR_ERR; - - if (splitStr->slen == 0) { - while (bsreada (buff, s, BSSSC_BUFF_LEN) >= 0) ; - if ((ret = cb (parm, 0, buff)) > 0) - ret = 0; - } else { - buildCharField (&chrs, splitStr); - ret = p = i = 0; - for (;;) { - if (i >= buff->slen) { - bsreada (buff, s, BSSSC_BUFF_LEN); - if (i >= buff->slen) { - if (0 < (ret = cb (parm, p, buff))) ret = 0; - break; - } - } - if (testInCharField (&chrs, buff->data[i])) { - struct tagbstring t; - unsigned char c; - - blk2tbstr (t, buff->data + i + 1, buff->slen - (i + 1)); - if ((ret = bsunread (s, &t)) < 0) break; - buff->slen = i; - c = buff->data[i]; - buff->data[i] = (unsigned char) '\0'; - if ((ret = cb (parm, p, buff)) < 0) break; - buff->data[i] = c; - buff->slen = 0; - p += i + 1; - i = -1; - } - i++; - } - } - - bdestroy (buff); - return ret; -} - -/* int bssplitstrcb (struct bStream * s, const_bstring splitStr, - * int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) - * - * Iterate the set of disjoint sequential substrings read from a stream - * divided by the entire substring splitStr. An empty splitStr causes - * each character of the stream to be iterated. - * - * Note: At the point of calling the cb function, the bStream pointer is - * pointed exactly at the position right after having read the split - * character. The cb function can act on the stream by causing the bStream - * pointer to move, and bssplitscb will continue by starting the next split - * at the position of the pointer after the return from cb. - * - * However, if the cb causes the bStream s to be destroyed then the cb must - * return with a negative value, otherwise bssplitscb will continue in an - * undefined manner. - */ -int bssplitstrcb (struct bStream * s, const_bstring splitStr, - int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) { -bstring buff; -int i, p, ret; - - if (cb == NULL || s == NULL || s->readFnPtr == NULL - || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; - - if (splitStr->slen == 1) return bssplitscb (s, splitStr, cb, parm); - - if (NULL == (buff = bfromcstr (""))) return BSTR_ERR; - - if (splitStr->slen == 0) { - for (i=0; bsreada (buff, s, BSSSC_BUFF_LEN) >= 0; i++) { - if ((ret = cb (parm, 0, buff)) < 0) { - bdestroy (buff); - return ret; - } - buff->slen = 0; - } - return BSTR_OK; - } else { - ret = p = i = 0; - for (i=p=0;;) { - if ((ret = binstr (buff, 0, splitStr)) >= 0) { - struct tagbstring t; - blk2tbstr (t, buff->data, ret); - i = ret + splitStr->slen; - if ((ret = cb (parm, p, &t)) < 0) break; - p += i; - bdelete (buff, 0, i); - } else { - bsreada (buff, s, BSSSC_BUFF_LEN); - if (bseof (s)) { - if ((ret = cb (parm, p, buff)) > 0) ret = 0; - break; - } - } - } - } - - bdestroy (buff); - return ret; -} - -/* int bstrListCreate (void) - * - * Create a bstrList. - */ -struct bstrList * bstrListCreate (void) { -struct bstrList * sl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); - if (sl) { - sl->entry = (bstring *) bstr__alloc (1*sizeof (bstring)); - if (!sl->entry) { - bstr__free (sl); - sl = NULL; - } else { - sl->qty = 0; - sl->mlen = 1; - } - } - return sl; -} - -/* int bstrListDestroy (struct bstrList * sl) - * - * Destroy a bstrList that has been created by bsplit, bsplits or bstrListCreate. - */ -int bstrListDestroy (struct bstrList * sl) { -int i; - if (sl == NULL || sl->qty < 0) return BSTR_ERR; - for (i=0; i < sl->qty; i++) { - if (sl->entry[i]) { - bdestroy (sl->entry[i]); - sl->entry[i] = NULL; - } - } - sl->qty = -1; - sl->mlen = -1; - bstr__free (sl->entry); - sl->entry = NULL; - bstr__free (sl); - return BSTR_OK; -} - -/* int bstrListAlloc (struct bstrList * sl, int msz) - * - * Ensure that there is memory for at least msz number of entries for the - * list. - */ -int bstrListAlloc (struct bstrList * sl, int msz) { -bstring * l; -int smsz; -size_t nsz; - if (!sl || msz <= 0 || !sl->entry || sl->qty < 0 || sl->mlen <= 0 || sl->qty > sl->mlen) return BSTR_ERR; - if (sl->mlen >= msz) return BSTR_OK; - smsz = snapUpSize (msz); - nsz = ((size_t) smsz) * sizeof (bstring); - if (nsz < (size_t) smsz) return BSTR_ERR; - l = (bstring *) bstr__realloc (sl->entry, nsz); - if (!l) { - smsz = msz; - nsz = ((size_t) smsz) * sizeof (bstring); - l = (bstring *) bstr__realloc (sl->entry, nsz); - if (!l) return BSTR_ERR; - } - sl->mlen = smsz; - sl->entry = l; - return BSTR_OK; -} - -/* int bstrListAllocMin (struct bstrList * sl, int msz) - * - * Try to allocate the minimum amount of memory for the list to include at - * least msz entries or sl->qty whichever is greater. - */ -int bstrListAllocMin (struct bstrList * sl, int msz) { -bstring * l; -size_t nsz; - if (!sl || msz <= 0 || !sl->entry || sl->qty < 0 || sl->mlen <= 0 || sl->qty > sl->mlen) return BSTR_ERR; - if (msz < sl->qty) msz = sl->qty; - if (sl->mlen == msz) return BSTR_OK; - nsz = ((size_t) msz) * sizeof (bstring); - if (nsz < (size_t) msz) return BSTR_ERR; - l = (bstring *) bstr__realloc (sl->entry, nsz); - if (!l) return BSTR_ERR; - sl->mlen = msz; - sl->entry = l; - return BSTR_OK; -} - -/* int bsplitcb (const_bstring str, unsigned char splitChar, int pos, - * int (* cb) (void * parm, int ofs, int len), void * parm) - * - * Iterate the set of disjoint sequential substrings over str divided by the - * character in splitChar. - * - * Note: Non-destructive modification of str from within the cb function - * while performing this split is not undefined. bsplitcb behaves in - * sequential lock step with calls to cb. I.e., after returning from a cb - * that return a non-negative integer, bsplitcb continues from the position - * 1 character after the last detected split character and it will halt - * immediately if the length of str falls below this point. However, if the - * cb function destroys str, then it *must* return with a negative value, - * otherwise bsplitcb will continue in an undefined manner. - */ -int bsplitcb (const_bstring str, unsigned char splitChar, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm) { -int i, p, ret; - - if (cb == NULL || str == NULL || pos < 0 || pos > str->slen) - return BSTR_ERR; - - p = pos; - do { - for (i=p; i < str->slen; i++) { - if (str->data[i] == splitChar) break; - } - if ((ret = cb (parm, p, i - p)) < 0) return ret; - p = i + 1; - } while (p <= str->slen); - return BSTR_OK; -} - -/* int bsplitscb (const_bstring str, const_bstring splitStr, int pos, - * int (* cb) (void * parm, int ofs, int len), void * parm) - * - * Iterate the set of disjoint sequential substrings over str divided by any - * of the characters in splitStr. An empty splitStr causes the whole str to - * be iterated once. - * - * Note: Non-destructive modification of str from within the cb function - * while performing this split is not undefined. bsplitscb behaves in - * sequential lock step with calls to cb. I.e., after returning from a cb - * that return a non-negative integer, bsplitscb continues from the position - * 1 character after the last detected split character and it will halt - * immediately if the length of str falls below this point. However, if the - * cb function destroys str, then it *must* return with a negative value, - * otherwise bsplitscb will continue in an undefined manner. - */ -int bsplitscb (const_bstring str, const_bstring splitStr, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm) { -struct charField chrs; -int i, p, ret; - - if (cb == NULL || str == NULL || pos < 0 || pos > str->slen - || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; - if (splitStr->slen == 0) { - if ((ret = cb (parm, 0, str->slen)) > 0) ret = 0; - return ret; - } - - if (splitStr->slen == 1) - return bsplitcb (str, splitStr->data[0], pos, cb, parm); - - buildCharField (&chrs, splitStr); - - p = pos; - do { - for (i=p; i < str->slen; i++) { - if (testInCharField (&chrs, str->data[i])) break; - } - if ((ret = cb (parm, p, i - p)) < 0) return ret; - p = i + 1; - } while (p <= str->slen); - return BSTR_OK; -} - -/* int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, - * int (* cb) (void * parm, int ofs, int len), void * parm) - * - * Iterate the set of disjoint sequential substrings over str divided by the - * substring splitStr. An empty splitStr causes the whole str to be - * iterated once. - * - * Note: Non-destructive modification of str from within the cb function - * while performing this split is not undefined. bsplitstrcb behaves in - * sequential lock step with calls to cb. I.e., after returning from a cb - * that return a non-negative integer, bsplitscb continues from the position - * 1 character after the last detected split character and it will halt - * immediately if the length of str falls below this point. However, if the - * cb function destroys str, then it *must* return with a negative value, - * otherwise bsplitscb will continue in an undefined manner. - */ -int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, - int (* cb) (void * parm, int ofs, int len), void * parm) { -int i, p, ret; - - if (cb == NULL || str == NULL || pos < 0 || pos > str->slen - || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; - - if (0 == splitStr->slen) { - for (i=pos; i < str->slen; i++) { - if ((ret = cb (parm, i, 1)) < 0) return ret; - } - return BSTR_OK; - } - - if (splitStr->slen == 1) - return bsplitcb (str, splitStr->data[0], pos, cb, parm); - - for (i=p=pos; i <= str->slen - splitStr->slen; i++) { - if (0 == bstr__memcmp (splitStr->data, str->data + i, splitStr->slen)) { - if ((ret = cb (parm, p, i - p)) < 0) return ret; - i += splitStr->slen; - p = i; - } - } - if ((ret = cb (parm, p, str->slen - p)) < 0) return ret; - return BSTR_OK; -} - -struct genBstrList { - bstring b; - struct bstrList * bl; -}; - -static int bscb (void * parm, int ofs, int len) { -struct genBstrList * g = (struct genBstrList *) parm; - if (g->bl->qty >= g->bl->mlen) { - int mlen = g->bl->mlen * 2; - bstring * tbl; - - while (g->bl->qty >= mlen) { - if (mlen < g->bl->mlen) return BSTR_ERR; - mlen += mlen; - } - - tbl = (bstring *) bstr__realloc (g->bl->entry, sizeof (bstring) * mlen); - if (tbl == NULL) return BSTR_ERR; - - g->bl->entry = tbl; - g->bl->mlen = mlen; - } - - g->bl->entry[g->bl->qty] = bmidstr (g->b, ofs, len); - g->bl->qty++; - return BSTR_OK; -} - -/* struct bstrList * bsplit (const_bstring str, unsigned char splitChar) - * - * Create an array of sequential substrings from str divided by the character - * splitChar. - */ -struct bstrList * bsplit (const_bstring str, unsigned char splitChar) { -struct genBstrList g; - - if (str == NULL || str->data == NULL || str->slen < 0) return NULL; - - g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); - if (g.bl == NULL) return NULL; - g.bl->mlen = 4; - g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); - if (NULL == g.bl->entry) { - bstr__free (g.bl); - return NULL; - } - - g.b = (bstring) str; - g.bl->qty = 0; - if (bsplitcb (str, splitChar, 0, bscb, &g) < 0) { - bstrListDestroy (g.bl); - return NULL; - } - return g.bl; -} - -/* struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr) - * - * Create an array of sequential substrings from str divided by the entire - * substring splitStr. - */ -struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr) { -struct genBstrList g; - - if (str == NULL || str->data == NULL || str->slen < 0) return NULL; - - g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); - if (g.bl == NULL) return NULL; - g.bl->mlen = 4; - g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); - if (NULL == g.bl->entry) { - bstr__free (g.bl); - return NULL; - } - - g.b = (bstring) str; - g.bl->qty = 0; - if (bsplitstrcb (str, splitStr, 0, bscb, &g) < 0) { - bstrListDestroy (g.bl); - return NULL; - } - return g.bl; -} - -/* struct bstrList * bsplits (const_bstring str, bstring splitStr) - * - * Create an array of sequential substrings from str divided by any of the - * characters in splitStr. An empty splitStr causes a single entry bstrList - * containing a copy of str to be returned. - */ -struct bstrList * bsplits (const_bstring str, const_bstring splitStr) { -struct genBstrList g; - - if ( str == NULL || str->slen < 0 || str->data == NULL || - splitStr == NULL || splitStr->slen < 0 || splitStr->data == NULL) - return NULL; - - g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); - if (g.bl == NULL) return NULL; - g.bl->mlen = 4; - g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); - if (NULL == g.bl->entry) { - bstr__free (g.bl); - return NULL; - } - g.b = (bstring) str; - g.bl->qty = 0; - - if (bsplitscb (str, splitStr, 0, bscb, &g) < 0) { - bstrListDestroy (g.bl); - return NULL; - } - return g.bl; -} - -#if defined (__TURBOC__) && !defined (__BORLANDC__) -# ifndef BSTRLIB_NOVSNP -# define BSTRLIB_NOVSNP -# endif -#endif - -/* Give WATCOM C/C++, MSVC some latitude for their non-support of vsnprintf */ -#if defined(__WATCOMC__) || defined(_MSC_VER) -#define exvsnprintf(r,b,n,f,a) {r = _vsnprintf (b,n,f,a);} -#else -#ifdef BSTRLIB_NOVSNP -/* This is just a hack. If you are using a system without a vsnprintf, it is - not recommended that bformat be used at all. */ -#define exvsnprintf(r,b,n,f,a) {vsprintf (b,f,a); r = -1;} -#define START_VSNBUFF (256) -#else - -#ifdef __GNUC__ -/* Something is making gcc complain about this prototype not being here, so - I've just gone ahead and put it in. */ -extern int vsnprintf (char *buf, size_t count, const char *format, va_list arg); -#endif - -#define exvsnprintf(r,b,n,f,a) {r = vsnprintf (b,n,f,a);} -#endif -#endif - -#if !defined (BSTRLIB_NOVSNP) - -#ifndef START_VSNBUFF -#define START_VSNBUFF (16) -#endif - -/* On IRIX vsnprintf returns n-1 when the operation would overflow the target - buffer, WATCOM and MSVC both return -1, while C99 requires that the - returned value be exactly what the length would be if the buffer would be - large enough. This leads to the idea that if the return value is larger - than n, then changing n to the return value will reduce the number of - iterations required. */ - -/* int bformata (bstring b, const char * fmt, ...) - * - * After the first parameter, it takes the same parameters as printf (), but - * rather than outputting results to stdio, it appends the results to - * a bstring which contains what would have been output. Note that if there - * is an early generation of a '\0' character, the bstring will be truncated - * to this end point. - */ -int bformata (bstring b, const char * fmt, ...) { -va_list arglist; -bstring buff; -int n, r; - - if (b == NULL || fmt == NULL || b->data == NULL || b->mlen <= 0 - || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; - - /* Since the length is not determinable beforehand, a search is - performed using the truncating "vsnprintf" call (to avoid buffer - overflows) on increasing potential sizes for the output result. */ - - if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) { - n = 1; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) return BSTR_ERR; - } - - for (;;) { - va_start (arglist, fmt); - exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); - va_end (arglist); - - buff->data[n] = (unsigned char) '\0'; - buff->slen = (int) (strlen) ((char *) buff->data); - - if (buff->slen < n) break; - - if (r > n) n = r; else n += n; - - if (BSTR_OK != balloc (buff, n + 2)) { - bdestroy (buff); - return BSTR_ERR; - } - } - - r = bconcat (b, buff); - bdestroy (buff); - return r; -} - -/* int bassignformat (bstring b, const char * fmt, ...) - * - * After the first parameter, it takes the same parameters as printf (), but - * rather than outputting results to stdio, it outputs the results to - * the bstring parameter b. Note that if there is an early generation of a - * '\0' character, the bstring will be truncated to this end point. - */ -int bassignformat (bstring b, const char * fmt, ...) { -va_list arglist; -bstring buff; -int n, r; - - if (b == NULL || fmt == NULL || b->data == NULL || b->mlen <= 0 - || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; - - /* Since the length is not determinable beforehand, a search is - performed using the truncating "vsnprintf" call (to avoid buffer - overflows) on increasing potential sizes for the output result. */ - - if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) { - n = 1; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) return BSTR_ERR; - } - - for (;;) { - va_start (arglist, fmt); - exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); - va_end (arglist); - - buff->data[n] = (unsigned char) '\0'; - buff->slen = (int) (strlen) ((char *) buff->data); - - if (buff->slen < n) break; - - if (r > n) n = r; else n += n; - - if (BSTR_OK != balloc (buff, n + 2)) { - bdestroy (buff); - return BSTR_ERR; - } - } - - r = bassign (b, buff); - bdestroy (buff); - return r; -} - -/* bstring bformat (const char * fmt, ...) - * - * Takes the same parameters as printf (), but rather than outputting results - * to stdio, it forms a bstring which contains what would have been output. - * Note that if there is an early generation of a '\0' character, the - * bstring will be truncated to this end point. - */ -bstring bformat (const char * fmt, ...) { -va_list arglist; -bstring buff; -int n, r; - - if (fmt == NULL) return NULL; - - /* Since the length is not determinable beforehand, a search is - performed using the truncating "vsnprintf" call (to avoid buffer - overflows) on increasing potential sizes for the output result. */ - - if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) { - n = 1; - if (NULL == (buff = bfromcstralloc (n + 2, ""))) return NULL; - } - - for (;;) { - va_start (arglist, fmt); - exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); - va_end (arglist); - - buff->data[n] = (unsigned char) '\0'; - buff->slen = (int) (strlen) ((char *) buff->data); - - if (buff->slen < n) break; - - if (r > n) n = r; else n += n; - - if (BSTR_OK != balloc (buff, n + 2)) { - bdestroy (buff); - return NULL; - } - } - - return buff; -} - -/* int bvcformata (bstring b, int count, const char * fmt, va_list arglist) - * - * The bvcformata function formats data under control of the format control - * string fmt and attempts to append the result to b. The fmt parameter is - * the same as that of the printf function. The variable argument list is - * replaced with arglist, which has been initialized by the va_start macro. - * The size of the output is upper bounded by count. If the required output - * exceeds count, the string b is not augmented with any contents and a value - * below BSTR_ERR is returned. If a value below -count is returned then it - * is recommended that the negative of this value be used as an update to the - * count in a subsequent pass. On other errors, such as running out of - * memory, parameter errors or numeric wrap around BSTR_ERR is returned. - * BSTR_OK is returned when the output is successfully generated and - * appended to b. - * - * Note: There is no sanity checking of arglist, and this function is - * destructive of the contents of b from the b->slen point onward. If there - * is an early generation of a '\0' character, the bstring will be truncated - * to this end point. - */ -int bvcformata (bstring b, int count, const char * fmt, va_list arg) { -int n, r, l; - - if (b == NULL || fmt == NULL || count <= 0 || b->data == NULL - || b->mlen <= 0 || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; - - if (count > (n = b->slen + count) + 2) return BSTR_ERR; - if (BSTR_OK != balloc (b, n + 2)) return BSTR_ERR; - - exvsnprintf (r, (char *) b->data + b->slen, count + 2, fmt, arg); - - /* Did the operation complete successfully within bounds? */ - - if (n >= (l = b->slen + (int) (strlen) ((const char *) b->data + b->slen))) { - b->slen = l; - return BSTR_OK; - } - - /* Abort, since the buffer was not large enough. The return value - tries to help set what the retry length should be. */ - - b->data[b->slen] = '\0'; - if (r > count+1) l = r; else { - l = count+count; - if (count > l) l = INT_MAX; - } - n = -l; - if (n > BSTR_ERR-1) n = BSTR_ERR-1; - return n; -} - -#endif +/* + * This source file is part of the bstring string library. This code was + * written by Paul Hsieh in 2002-2008, and is covered by the BSD open source + * license and the GPL. Refer to the accompanying documentation for details + * on usage and license. + */ + +/* + * bstrlib.c + * + * This file is the core module for implementing the bstring functions. + */ + +#include +#include +#include +#include +#include +#include + +#include + +/* Optionally include a mechanism for debugging memory */ + +#if defined(MEMORY_DEBUG) || defined(BSTRLIB_MEMORY_DEBUG) +#include "memdbg.h" +#endif + +#ifndef bstr__alloc +#define bstr__alloc(x) malloc (x) +#endif + +#ifndef bstr__free +#define bstr__free(p) free (p) +#endif + +#ifndef bstr__realloc +#define bstr__realloc(p,x) realloc ((p), (x)) +#endif + +#ifndef bstr__memcpy +#define bstr__memcpy(d,s,l) memcpy ((d), (s), (l)) +#endif + +#ifndef bstr__memmove +#define bstr__memmove(d,s,l) memmove ((d), (s), (l)) +#endif + +#ifndef bstr__memset +#define bstr__memset(d,c,l) memset ((d), (c), (l)) +#endif + +#ifndef bstr__memcmp +#define bstr__memcmp(d,c,l) memcmp ((d), (c), (l)) +#endif + +#ifndef bstr__memchr +#define bstr__memchr(s,c,l) memchr ((s), (c), (l)) +#endif + +/* Just a length safe wrapper for memmove. */ + +#define bBlockCopy(D,S,L) { if ((L) > 0) bstr__memmove ((D),(S),(L)); } + +/* Compute the snapped size for a given requested size. By snapping to powers + of 2 like this, repeated reallocations are avoided. */ +static int snapUpSize (int i) { + if (i < 8) { + i = 8; + } else { + unsigned int j; + j = (unsigned int) i; + + j |= (j >> 1); + j |= (j >> 2); + j |= (j >> 4); + j |= (j >> 8); /* Ok, since int >= 16 bits */ +#if (UINT_MAX != 0xffff) + j |= (j >> 16); /* For 32 bit int systems */ +#if (UINT_MAX > 0xffffffffUL) + j |= (j >> 32); /* For 64 bit int systems */ +#endif +#endif + /* Least power of two greater than i */ + j++; + if ((int) j >= i) i = (int) j; + } + return i; +} + +/* int balloc (bstring b, int len) + * + * Increase the size of the memory backing the bstring b to at least len. + */ +int balloc (bstring b, int olen) { + int len; + if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen <= 0 || + b->mlen < b->slen || olen <= 0) { + return BSTR_ERR; + } + + if (olen >= b->mlen) { + unsigned char * x; + + if ((len = snapUpSize (olen)) <= b->mlen) return BSTR_OK; + + /* Assume probability of a non-moving realloc is 0.125 */ + if (7 * b->mlen < 8 * b->slen) { + + /* If slen is close to mlen in size then use realloc to reduce + the memory defragmentation */ + + reallocStrategy:; + + x = (unsigned char *) bstr__realloc (b->data, (size_t) len); + if (x == NULL) { + + /* Since we failed, try allocating the tighest possible + allocation */ + + if (NULL == (x = (unsigned char *) bstr__realloc (b->data, (size_t) (len = olen)))) { + return BSTR_ERR; + } + } + } else { + + /* If slen is not close to mlen then avoid the penalty of copying + the extra bytes that are allocated, but not considered part of + the string */ + + if (NULL == (x = (unsigned char *) bstr__alloc ((size_t) len))) { + + /* Perhaps there is no available memory for the two + allocations to be in memory at once */ + + goto reallocStrategy; + + } else { + if (b->slen) bstr__memcpy ((char *) x, (char *) b->data, (size_t) b->slen); + bstr__free (b->data); + } + } + b->data = x; + b->mlen = len; + b->data[b->slen] = (unsigned char) '\0'; + } + + return BSTR_OK; +} + +/* int ballocmin (bstring b, int len) + * + * Set the size of the memory backing the bstring b to len or b->slen+1, + * whichever is larger. Note that repeated use of this function can degrade + * performance. + */ +int ballocmin (bstring b, int len) { + unsigned char * s; + + if (b == NULL || b->data == NULL || (b->slen+1) < 0 || b->mlen <= 0 || + b->mlen < b->slen || len <= 0) { + return BSTR_ERR; + } + + if (len < b->slen + 1) len = b->slen + 1; + + if (len != b->mlen) { + s = (unsigned char *) bstr__realloc (b->data, (size_t) len); + if (NULL == s) return BSTR_ERR; + s[b->slen] = (unsigned char) '\0'; + b->data = s; + b->mlen = len; + } + + return BSTR_OK; +} + +/* bstring bfromcstr (const char * str) + * + * Create a bstring which contains the contents of the '\0' terminated char * + * buffer str. + */ +bstring bfromcstr (const char * str) { +bstring b; +int i; +size_t j; + + if (str == NULL) return NULL; + j = (strlen) (str); + i = snapUpSize ((int) (j + (2 - (j != 0)))); + if (i <= (int) j) return NULL; + + b = (bstring) bstr__alloc (sizeof (struct tagbstring)); + if (NULL == b) return NULL; + b->slen = (int) j; + if (NULL == (b->data = (unsigned char *) bstr__alloc (b->mlen = i))) { + bstr__free (b); + return NULL; + } + + bstr__memcpy (b->data, str, j+1); + return b; +} + +/* bstring bfromcstralloc (int mlen, const char * str) + * + * Create a bstring which contains the contents of the '\0' terminated char * + * buffer str. The memory buffer backing the string is at least len + * characters in length. + */ +bstring bfromcstralloc (int mlen, const char * str) { +bstring b; +int i; +size_t j; + + if (str == NULL) return NULL; + j = (strlen) (str); + i = snapUpSize ((int) (j + (2 - (j != 0)))); + if (i <= (int) j) return NULL; + + b = (bstring) bstr__alloc (sizeof (struct tagbstring)); + if (b == NULL) return NULL; + b->slen = (int) j; + if (i < mlen) i = mlen; + + if (NULL == (b->data = (unsigned char *) bstr__alloc (b->mlen = i))) { + bstr__free (b); + return NULL; + } + + bstr__memcpy (b->data, str, j+1); + return b; +} + +/* bstring blk2bstr (const void * blk, int len) + * + * Create a bstring which contains the content of the block blk of length + * len. + */ +bstring blk2bstr (const void * blk, int len) { +bstring b; +int i; + + if (blk == NULL || len < 0) return NULL; + b = (bstring) bstr__alloc (sizeof (struct tagbstring)); + if (b == NULL) return NULL; + b->slen = len; + + i = len + (2 - (len != 0)); + i = snapUpSize (i); + + b->mlen = i; + + b->data = (unsigned char *) bstr__alloc ((size_t) b->mlen); + if (b->data == NULL) { + bstr__free (b); + return NULL; + } + + if (len > 0) bstr__memcpy (b->data, blk, (size_t) len); + b->data[len] = (unsigned char) '\0'; + + return b; +} + +/* char * bstr2cstr (const_bstring s, char z) + * + * Create a '\0' terminated char * buffer which is equal to the contents of + * the bstring s, except that any contained '\0' characters are converted + * to the character in z. This returned value should be freed with a + * bcstrfree () call, by the calling application. + */ +char * bstr2cstr (const_bstring b, char z) { +int i, l; +char * r; + + if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; + l = b->slen; + r = (char *) bstr__alloc ((size_t) (l + 1)); + if (r == NULL) return r; + + for (i=0; i < l; i ++) { + r[i] = (char) ((b->data[i] == '\0') ? z : (char) (b->data[i])); + } + + r[l] = (unsigned char) '\0'; + + return r; +} + +/* int bcstrfree (char * s) + * + * Frees a C-string generated by bstr2cstr (). This is normally unnecessary + * since it just wraps a call to bstr__free (), however, if bstr__alloc () + * and bstr__free () have been redefined as a macros within the bstrlib + * module (via defining them in memdbg.h after defining + * BSTRLIB_MEMORY_DEBUG) with some difference in behaviour from the std + * library functions, then this allows a correct way of freeing the memory + * that allows higher level code to be independent from these macro + * redefinitions. + */ +int bcstrfree (char * s) { + if (s) { + bstr__free (s); + return BSTR_OK; + } + return BSTR_ERR; +} + +/* int bconcat (bstring b0, const_bstring b1) + * + * Concatenate the bstring b1 to the bstring b0. + */ +int bconcat (bstring b0, const_bstring b1) { +int len, d; +bstring aux = (bstring) b1; + + if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL) return BSTR_ERR; + + d = b0->slen; + len = b1->slen; + if ((d | (b0->mlen - d) | len | (d + len)) < 0) return BSTR_ERR; + + if (b0->mlen <= d + len + 1) { + ptrdiff_t pd = b1->data - b0->data; + if (0 <= pd && pd < b0->mlen) { + if (NULL == (aux = bstrcpy (b1))) return BSTR_ERR; + } + if (balloc (b0, d + len + 1) != BSTR_OK) { + if (aux != b1) bdestroy (aux); + return BSTR_ERR; + } + } + + bBlockCopy (&b0->data[d], &aux->data[0], (size_t) len); + b0->data[d + len] = (unsigned char) '\0'; + b0->slen = d + len; + if (aux != b1) bdestroy (aux); + return BSTR_OK; +} + +/* int bconchar (bstring b, char c) +/ * + * Concatenate the single character c to the bstring b. + */ +int bconchar (bstring b, char c) { +int d; + + if (b == NULL) return BSTR_ERR; + d = b->slen; + if ((d | (b->mlen - d)) < 0 || balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; + b->data[d] = (unsigned char) c; + b->data[d + 1] = (unsigned char) '\0'; + b->slen++; + return BSTR_OK; +} + +/* int bcatcstr (bstring b, const char * s) + * + * Concatenate a char * string to a bstring. + */ +int bcatcstr (bstring b, const char * s) { +char * d; +int i, l; + + if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen < b->slen + || b->mlen <= 0 || s == NULL) return BSTR_ERR; + + /* Optimistically concatenate directly */ + l = b->mlen - b->slen; + d = (char *) &b->data[b->slen]; + for (i=0; i < l; i++) { + if ((*d++ = *s++) == '\0') { + b->slen += i; + return BSTR_OK; + } + } + b->slen += i; + + /* Need to explicitely resize and concatenate tail */ + return bcatblk (b, (const void *) s, (int) strlen (s)); +} + +/* int bcatblk (bstring b, const void * s, int len) + * + * Concatenate a fixed length buffer to a bstring. + */ +int bcatblk (bstring b, const void * s, int len) { +int nl; + + if (b == NULL || b->data == NULL || b->slen < 0 || b->mlen < b->slen + || b->mlen <= 0 || s == NULL || len < 0) return BSTR_ERR; + + if (0 > (nl = b->slen + len)) return BSTR_ERR; /* Overflow? */ + if (b->mlen <= nl && 0 > balloc (b, nl + 1)) return BSTR_ERR; + + bBlockCopy (&b->data[b->slen], s, (size_t) len); + b->slen = nl; + b->data[nl] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* bstring bstrcpy (const_bstring b) + * + * Create a copy of the bstring b. + */ +bstring bstrcpy (const_bstring b) { +bstring b0; +int i,j; + + /* Attempted to copy an invalid string? */ + if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; + + b0 = (bstring) bstr__alloc (sizeof (struct tagbstring)); + if (b0 == NULL) { + /* Unable to allocate memory for string header */ + return NULL; + } + + i = b->slen; + j = snapUpSize (i + 1); + + b0->data = (unsigned char *) bstr__alloc (j); + if (b0->data == NULL) { + j = i + 1; + b0->data = (unsigned char *) bstr__alloc (j); + if (b0->data == NULL) { + /* Unable to allocate memory for string data */ + bstr__free (b0); + return NULL; + } + } + + b0->mlen = j; + b0->slen = i; + + if (i) bstr__memcpy ((char *) b0->data, (char *) b->data, i); + b0->data[b0->slen] = (unsigned char) '\0'; + + return b0; +} + +/* int bassign (bstring a, const_bstring b) + * + * Overwrite the string a with the contents of string b. + */ +int bassign (bstring a, const_bstring b) { + if (b == NULL || b->data == NULL || b->slen < 0) + return BSTR_ERR; + if (b->slen != 0) { + if (balloc (a, b->slen) != BSTR_OK) return BSTR_ERR; + bstr__memmove (a->data, b->data, b->slen); + } else { + if (a == NULL || a->data == NULL || a->mlen < a->slen || + a->slen < 0 || a->mlen == 0) + return BSTR_ERR; + } + a->data[b->slen] = (unsigned char) '\0'; + a->slen = b->slen; + return BSTR_OK; +} + +/* int bassignmidstr (bstring a, const_bstring b, int left, int len) + * + * Overwrite the string a with the middle of contents of string b + * starting from position left and running for a length len. left and + * len are clamped to the ends of b as with the function bmidstr. + */ +int bassignmidstr (bstring a, const_bstring b, int left, int len) { + if (b == NULL || b->data == NULL || b->slen < 0) + return BSTR_ERR; + + if (left < 0) { + len += left; + left = 0; + } + + if (len > b->slen - left) len = b->slen - left; + + if (a == NULL || a->data == NULL || a->mlen < a->slen || + a->slen < 0 || a->mlen == 0) + return BSTR_ERR; + + if (len > 0) { + if (balloc (a, len) != BSTR_OK) return BSTR_ERR; + bstr__memmove (a->data, b->data + left, len); + a->slen = len; + } else { + a->slen = 0; + } + a->data[a->slen] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* int bassigncstr (bstring a, const char * str) + * + * Overwrite the string a with the contents of char * string str. Note that + * the bstring a must be a well defined and writable bstring. If an error + * occurs BSTR_ERR is returned however a may be partially overwritten. + */ +int bassigncstr (bstring a, const char * str) { +int i; +size_t len; + if (a == NULL || a->data == NULL || a->mlen < a->slen || + a->slen < 0 || a->mlen == 0 || NULL == str) + return BSTR_ERR; + + for (i=0; i < a->mlen; i++) { + if ('\0' == (a->data[i] = str[i])) { + a->slen = i; + return BSTR_OK; + } + } + + a->slen = i; + len = strlen (str + i); + if (len > INT_MAX || i + len + 1 > INT_MAX || + 0 > balloc (a, (int) (i + len + 1))) return BSTR_ERR; + bBlockCopy (a->data + i, str + i, (size_t) len + 1); + a->slen += (int) len; + return BSTR_OK; +} + +/* int bassignblk (bstring a, const void * s, int len) + * + * Overwrite the string a with the contents of the block (s, len). Note that + * the bstring a must be a well defined and writable bstring. If an error + * occurs BSTR_ERR is returned and a is not overwritten. + */ +int bassignblk (bstring a, const void * s, int len) { + if (a == NULL || a->data == NULL || a->mlen < a->slen || + a->slen < 0 || a->mlen == 0 || NULL == s || len + 1 < 1) + return BSTR_ERR; + if (len + 1 > a->mlen && 0 > balloc (a, len + 1)) return BSTR_ERR; + bBlockCopy (a->data, s, (size_t) len); + a->data[len] = (unsigned char) '\0'; + a->slen = len; + return BSTR_OK; +} + +/* int btrunc (bstring b, int n) + * + * Truncate the bstring to at most n characters. + */ +int btrunc (bstring b, int n) { + if (n < 0 || b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + if (b->slen > n) { + b->slen = n; + b->data[n] = (unsigned char) '\0'; + } + return BSTR_OK; +} + +#define upcase(c) (toupper ((unsigned char) c)) +#define downcase(c) (tolower ((unsigned char) c)) +#define wspace(c) (isspace ((unsigned char) c)) + +/* int btoupper (bstring b) + * + * Convert contents of bstring to upper case. + */ +int btoupper (bstring b) { +int i, len; + if (b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + for (i=0, len = b->slen; i < len; i++) { + b->data[i] = (unsigned char) upcase (b->data[i]); + } + return BSTR_OK; +} + +/* int btolower (bstring b) + * + * Convert contents of bstring to lower case. + */ +int btolower (bstring b) { +int i, len; + if (b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + for (i=0, len = b->slen; i < len; i++) { + b->data[i] = (unsigned char) downcase (b->data[i]); + } + return BSTR_OK; +} + +/* int bstricmp (const_bstring b0, const_bstring b1) + * + * Compare two strings without differentiating between case. The return + * value is the difference of the values of the characters where the two + * strings first differ after lower case transformation, otherwise 0 is + * returned indicating that the strings are equal. If the lengths are + * different, then a difference from 0 is given, but if the first extra + * character is '\0', then it is taken to be the value UCHAR_MAX+1. + */ +int bstricmp (const_bstring b0, const_bstring b1) { +int i, v, n; + + if (bdata (b0) == NULL || b0->slen < 0 || + bdata (b1) == NULL || b1->slen < 0) return SHRT_MIN; + if ((n = b0->slen) > b1->slen) n = b1->slen; + else if (b0->slen == b1->slen && b0->data == b1->data) return BSTR_OK; + + for (i = 0; i < n; i ++) { + v = (char) downcase (b0->data[i]) + - (char) downcase (b1->data[i]); + if (0 != v) return v; + } + + if (b0->slen > n) { + v = (char) downcase (b0->data[n]); + if (v) return v; + return UCHAR_MAX + 1; + } + if (b1->slen > n) { + v = - (char) downcase (b1->data[n]); + if (v) return v; + return - (int) (UCHAR_MAX + 1); + } + return BSTR_OK; +} + +/* int bstrnicmp (const_bstring b0, const_bstring b1, int n) + * + * Compare two strings without differentiating between case for at most n + * characters. If the position where the two strings first differ is + * before the nth position, the return value is the difference of the values + * of the characters, otherwise 0 is returned. If the lengths are different + * and less than n characters, then a difference from 0 is given, but if the + * first extra character is '\0', then it is taken to be the value + * UCHAR_MAX+1. + */ +int bstrnicmp (const_bstring b0, const_bstring b1, int n) { +int i, v, m; + + if (bdata (b0) == NULL || b0->slen < 0 || + bdata (b1) == NULL || b1->slen < 0 || n < 0) return SHRT_MIN; + m = n; + if (m > b0->slen) m = b0->slen; + if (m > b1->slen) m = b1->slen; + + if (b0->data != b1->data) { + for (i = 0; i < m; i ++) { + v = (char) downcase (b0->data[i]); + v -= (char) downcase (b1->data[i]); + if (v != 0) return b0->data[i] - b1->data[i]; + } + } + + if (n == m || b0->slen == b1->slen) return BSTR_OK; + + if (b0->slen > m) { + v = (char) downcase (b0->data[m]); + if (v) return v; + return UCHAR_MAX + 1; + } + + v = - (char) downcase (b1->data[m]); + if (v) return v; + return - (int) (UCHAR_MAX + 1); +} + +/* int biseqcaseless (const_bstring b0, const_bstring b1) + * + * Compare two strings for equality without differentiating between case. + * If the strings differ other than in case, 0 is returned, if the strings + * are the same, 1 is returned, if there is an error, -1 is returned. If + * the length of the strings are different, this function is O(1). '\0' + * termination characters are not treated in any special way. + */ +int biseqcaseless (const_bstring b0, const_bstring b1) { +int i, n; + + if (bdata (b0) == NULL || b0->slen < 0 || + bdata (b1) == NULL || b1->slen < 0) return BSTR_ERR; + if (b0->slen != b1->slen) return BSTR_OK; + if (b0->data == b1->data || b0->slen == 0) return 1; + for (i=0, n=b0->slen; i < n; i++) { + if (b0->data[i] != b1->data[i]) { + unsigned char c = (unsigned char) downcase (b0->data[i]); + if (c != (unsigned char) downcase (b1->data[i])) return 0; + } + } + return 1; +} + +/* int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len) + * + * Compare beginning of string b0 with a block of memory of length len + * without differentiating between case for equality. If the beginning of b0 + * differs from the memory block other than in case (or if b0 is too short), + * 0 is returned, if the strings are the same, 1 is returned, if there is an + * error, -1 is returned. '\0' characters are not treated in any special + * way. + */ +int bisstemeqcaselessblk (const_bstring b0, const void * blk, int len) { +int i; + + if (bdata (b0) == NULL || b0->slen < 0 || NULL == blk || len < 0) + return BSTR_ERR; + if (b0->slen < len) return BSTR_OK; + if (b0->data == (const unsigned char *) blk || len == 0) return 1; + + for (i = 0; i < len; i ++) { + if (b0->data[i] != ((const unsigned char *) blk)[i]) { + if (downcase (b0->data[i]) != + downcase (((const unsigned char *) blk)[i])) return 0; + } + } + return 1; +} + +/* + * int bltrimws (bstring b) + * + * Delete whitespace contiguous from the left end of the string. + */ +int bltrimws (bstring b) { +int i, len; + + if (b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + + for (len = b->slen, i = 0; i < len; i++) { + if (!wspace (b->data[i])) { + return bdelete (b, 0, i); + } + } + + b->data[0] = (unsigned char) '\0'; + b->slen = 0; + return BSTR_OK; +} + +/* + * int brtrimws (bstring b) + * + * Delete whitespace contiguous from the right end of the string. + */ +int brtrimws (bstring b) { +int i; + + if (b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + + for (i = b->slen - 1; i >= 0; i--) { + if (!wspace (b->data[i])) { + if (b->mlen > i) b->data[i+1] = (unsigned char) '\0'; + b->slen = i + 1; + return BSTR_OK; + } + } + + b->data[0] = (unsigned char) '\0'; + b->slen = 0; + return BSTR_OK; +} + +/* + * int btrimws (bstring b) + * + * Delete whitespace contiguous from both ends of the string. + */ +int btrimws (bstring b) { +int i, j; + + if (b == NULL || b->data == NULL || b->mlen < b->slen || + b->slen < 0 || b->mlen <= 0) return BSTR_ERR; + + for (i = b->slen - 1; i >= 0; i--) { + if (!wspace (b->data[i])) { + if (b->mlen > i) b->data[i+1] = (unsigned char) '\0'; + b->slen = i + 1; + for (j = 0; wspace (b->data[j]); j++) {} + return bdelete (b, 0, j); + } + } + + b->data[0] = (unsigned char) '\0'; + b->slen = 0; + return BSTR_OK; +} + +/* int biseq (const_bstring b0, const_bstring b1) + * + * Compare the string b0 and b1. If the strings differ, 0 is returned, if + * the strings are the same, 1 is returned, if there is an error, -1 is + * returned. If the length of the strings are different, this function is + * O(1). '\0' termination characters are not treated in any special way. + */ +int biseq (const_bstring b0, const_bstring b1) { + if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || + b0->slen < 0 || b1->slen < 0) return BSTR_ERR; + if (b0->slen != b1->slen) return BSTR_OK; + if (b0->data == b1->data || b0->slen == 0) return 1; + return !bstr__memcmp (b0->data, b1->data, b0->slen); +} + +/* int bisstemeqblk (const_bstring b0, const void * blk, int len) + * + * Compare beginning of string b0 with a block of memory of length len for + * equality. If the beginning of b0 differs from the memory block (or if b0 + * is too short), 0 is returned, if the strings are the same, 1 is returned, + * if there is an error, -1 is returned. '\0' characters are not treated in + * any special way. + */ +int bisstemeqblk (const_bstring b0, const void * blk, int len) { +int i; + + if (bdata (b0) == NULL || b0->slen < 0 || NULL == blk || len < 0) + return BSTR_ERR; + if (b0->slen < len) return BSTR_OK; + if (b0->data == (const unsigned char *) blk || len == 0) return 1; + + for (i = 0; i < len; i ++) { + if (b0->data[i] != ((const unsigned char *) blk)[i]) return BSTR_OK; + } + return 1; +} + +/* int biseqcstr (const_bstring b, const char *s) + * + * Compare the bstring b and char * string s. The C string s must be '\0' + * terminated at exactly the length of the bstring b, and the contents + * between the two must be identical with the bstring b with no '\0' + * characters for the two contents to be considered equal. This is + * equivalent to the condition that their current contents will be always be + * equal when comparing them in the same format after converting one or the + * other. If the strings are equal 1 is returned, if they are unequal 0 is + * returned and if there is a detectable error BSTR_ERR is returned. + */ +int biseqcstr (const_bstring b, const char * s) { +int i; + if (b == NULL || s == NULL || b->data == NULL || b->slen < 0) return BSTR_ERR; + for (i=0; i < b->slen; i++) { + if (s[i] == '\0' || b->data[i] != (unsigned char) s[i]) return BSTR_OK; + } + return s[i] == '\0'; +} + +/* int biseqcstrcaseless (const_bstring b, const char *s) + * + * Compare the bstring b and char * string s. The C string s must be '\0' + * terminated at exactly the length of the bstring b, and the contents + * between the two must be identical except for case with the bstring b with + * no '\0' characters for the two contents to be considered equal. This is + * equivalent to the condition that their current contents will be always be + * equal ignoring case when comparing them in the same format after + * converting one or the other. If the strings are equal, except for case, + * 1 is returned, if they are unequal regardless of case 0 is returned and + * if there is a detectable error BSTR_ERR is returned. + */ +int biseqcstrcaseless (const_bstring b, const char * s) { +int i; + if (b == NULL || s == NULL || b->data == NULL || b->slen < 0) return BSTR_ERR; + for (i=0; i < b->slen; i++) { + if (s[i] == '\0' || + (b->data[i] != (unsigned char) s[i] && + downcase (b->data[i]) != (unsigned char) downcase (s[i]))) + return BSTR_OK; + } + return s[i] == '\0'; +} + +/* int bstrcmp (const_bstring b0, const_bstring b1) + * + * Compare the string b0 and b1. If there is an error, SHRT_MIN is returned, + * otherwise a value less than or greater than zero, indicating that the + * string pointed to by b0 is lexicographically less than or greater than + * the string pointed to by b1 is returned. If the the string lengths are + * unequal but the characters up until the length of the shorter are equal + * then a value less than, or greater than zero, indicating that the string + * pointed to by b0 is shorter or longer than the string pointed to by b1 is + * returned. 0 is returned if and only if the two strings are the same. If + * the length of the strings are different, this function is O(n). Like its + * standard C library counter part strcmp, the comparison does not proceed + * past any '\0' termination characters encountered. + */ +int bstrcmp (const_bstring b0, const_bstring b1) { +int i, v, n; + + if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || + b0->slen < 0 || b1->slen < 0) return SHRT_MIN; + n = b0->slen; if (n > b1->slen) n = b1->slen; + if (b0->slen == b1->slen && (b0->data == b1->data || b0->slen == 0)) + return BSTR_OK; + + for (i = 0; i < n; i ++) { + v = ((char) b0->data[i]) - ((char) b1->data[i]); + if (v != 0) return v; + if (b0->data[i] == (unsigned char) '\0') return BSTR_OK; + } + + if (b0->slen > n) return 1; + if (b1->slen > n) return -1; + return BSTR_OK; +} + +/* int bstrncmp (const_bstring b0, const_bstring b1, int n) + * + * Compare the string b0 and b1 for at most n characters. If there is an + * error, SHRT_MIN is returned, otherwise a value is returned as if b0 and + * b1 were first truncated to at most n characters then bstrcmp was called + * with these new strings are paremeters. If the length of the strings are + * different, this function is O(n). Like its standard C library counter + * part strcmp, the comparison does not proceed past any '\0' termination + * characters encountered. + */ +int bstrncmp (const_bstring b0, const_bstring b1, int n) { +int i, v, m; + + if (b0 == NULL || b1 == NULL || b0->data == NULL || b1->data == NULL || + b0->slen < 0 || b1->slen < 0) return SHRT_MIN; + m = n; + if (m > b0->slen) m = b0->slen; + if (m > b1->slen) m = b1->slen; + + if (b0->data != b1->data) { + for (i = 0; i < m; i ++) { + v = ((char) b0->data[i]) - ((char) b1->data[i]); + if (v != 0) return v; + if (b0->data[i] == (unsigned char) '\0') return BSTR_OK; + } + } + + if (n == m || b0->slen == b1->slen) return BSTR_OK; + + if (b0->slen > m) return 1; + return -1; +} + +/* bstring bmidstr (const_bstring b, int left, int len) + * + * Create a bstring which is the substring of b starting from position left + * and running for a length len (clamped by the end of the bstring b.) If + * b is detectably invalid, then NULL is returned. The section described + * by (left, len) is clamped to the boundaries of b. + */ +bstring bmidstr (const_bstring b, int left, int len) { + + if (b == NULL || b->slen < 0 || b->data == NULL) return NULL; + + if (left < 0) { + len += left; + left = 0; + } + + if (len > b->slen - left) len = b->slen - left; + + if (len <= 0) return bfromcstr (""); + return blk2bstr (b->data + left, len); +} + +/* int bdelete (bstring b, int pos, int len) + * + * Removes characters from pos to pos+len-1 inclusive and shifts the tail of + * the bstring starting from pos+len to pos. len must be positive for this + * call to have any effect. The section of the string described by (pos, + * len) is clamped to boundaries of the bstring b. + */ +int bdelete (bstring b, int pos, int len) { + /* Clamp to left side of bstring */ + if (pos < 0) { + len += pos; + pos = 0; + } + + if (len < 0 || b == NULL || b->data == NULL || b->slen < 0 || + b->mlen < b->slen || b->mlen <= 0) + return BSTR_ERR; + if (len > 0 && pos < b->slen) { + if (pos + len >= b->slen) { + b->slen = pos; + } else { + bBlockCopy ((char *) (b->data + pos), + (char *) (b->data + pos + len), + b->slen - (pos+len)); + b->slen -= len; + } + b->data[b->slen] = (unsigned char) '\0'; + } + return BSTR_OK; +} + +/* int bdestroy (bstring b) + * + * Free up the bstring. Note that if b is detectably invalid or not writable + * then no action is performed and BSTR_ERR is returned. Like a freed memory + * allocation, dereferences, writes or any other action on b after it has + * been bdestroyed is undefined. + */ +int bdestroy (bstring b) { + if (b == NULL || b->slen < 0 || b->mlen <= 0 || b->mlen < b->slen || + b->data == NULL) + return BSTR_ERR; + + bstr__free (b->data); + + /* In case there is any stale usage, there is one more chance to + notice this error. */ + + b->slen = -1; + b->mlen = -__LINE__; + b->data = NULL; + + bstr__free (b); + return BSTR_OK; +} + +/* int binstr (const_bstring b1, int pos, const_bstring b2) + * + * Search for the bstring b2 in b1 starting from position pos, and searching + * forward. If it is found then return with the first position where it is + * found, otherwise return BSTR_ERR. Note that this is just a brute force + * string searcher that does not attempt clever things like the Boyer-Moore + * search algorithm. Because of this there are many degenerate cases where + * this can take much longer than it needs to. + */ +int binstr (const_bstring b1, int pos, const_bstring b2) { +int j, ii, ll, lf; +unsigned char * d0; +unsigned char c0; +register unsigned char * d1; +register unsigned char c1; +register int i; + + if (b1 == NULL || b1->data == NULL || b1->slen < 0 || + b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; + if (b1->slen == pos) return (b2->slen == 0)?pos:BSTR_ERR; + if (b1->slen < pos || pos < 0) return BSTR_ERR; + if (b2->slen == 0) return pos; + + /* No space to find such a string? */ + if ((lf = b1->slen - b2->slen + 1) <= pos) return BSTR_ERR; + + /* An obvious alias case */ + if (b1->data == b2->data && pos == 0) return 0; + + i = pos; + + d0 = b2->data; + d1 = b1->data; + ll = b2->slen; + + /* Peel off the b2->slen == 1 case */ + c0 = d0[0]; + if (1 == ll) { + for (;i < lf; i++) if (c0 == d1[i]) return i; + return BSTR_ERR; + } + + c1 = c0; + j = 0; + lf = b1->slen - 1; + + ii = -1; + if (i < lf) do { + /* Unrolled current character test */ + if (c1 != d1[i]) { + if (c1 != d1[1+i]) { + i += 2; + continue; + } + i++; + } + + /* Take note if this is the start of a potential match */ + if (0 == j) ii = i; + + /* Shift the test character down by one */ + j++; + i++; + + /* If this isn't past the last character continue */ + if (j < ll) { + c1 = d0[j]; + continue; + } + + N0:; + + /* If no characters mismatched, then we matched */ + if (i == ii+j) return ii; + + /* Shift back to the beginning */ + i -= j; + j = 0; + c1 = c0; + } while (i < lf); + + /* Deal with last case if unrolling caused a misalignment */ + if (i == lf && ll == j+1 && c1 == d1[i]) goto N0; + + return BSTR_ERR; +} + +/* int binstrr (const_bstring b1, int pos, const_bstring b2) + * + * Search for the bstring b2 in b1 starting from position pos, and searching + * backward. If it is found then return with the first position where it is + * found, otherwise return BSTR_ERR. Note that this is just a brute force + * string searcher that does not attempt clever things like the Boyer-Moore + * search algorithm. Because of this there are many degenerate cases where + * this can take much longer than it needs to. + */ +int binstrr (const_bstring b1, int pos, const_bstring b2) { +int j, i, l; +unsigned char * d0, * d1; + + if (b1 == NULL || b1->data == NULL || b1->slen < 0 || + b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; + if (b1->slen == pos && b2->slen == 0) return pos; + if (b1->slen < pos || pos < 0) return BSTR_ERR; + if (b2->slen == 0) return pos; + + /* Obvious alias case */ + if (b1->data == b2->data && pos == 0 && b2->slen <= b1->slen) return 0; + + i = pos; + if ((l = b1->slen - b2->slen) < 0) return BSTR_ERR; + + /* If no space to find such a string then snap back */ + if (l + 1 <= i) i = l; + j = 0; + + d0 = b2->data; + d1 = b1->data; + l = b2->slen; + + for (;;) { + if (d0[j] == d1[i + j]) { + j ++; + if (j >= l) return i; + } else { + i --; + if (i < 0) break; + j=0; + } + } + + return BSTR_ERR; +} + +/* int binstrcaseless (const_bstring b1, int pos, const_bstring b2) + * + * Search for the bstring b2 in b1 starting from position pos, and searching + * forward but without regard to case. If it is found then return with the + * first position where it is found, otherwise return BSTR_ERR. Note that + * this is just a brute force string searcher that does not attempt clever + * things like the Boyer-Moore search algorithm. Because of this there are + * many degenerate cases where this can take much longer than it needs to. + */ +int binstrcaseless (const_bstring b1, int pos, const_bstring b2) { +int j, i, l, ll; +unsigned char * d0, * d1; + + if (b1 == NULL || b1->data == NULL || b1->slen < 0 || + b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; + if (b1->slen == pos) return (b2->slen == 0)?pos:BSTR_ERR; + if (b1->slen < pos || pos < 0) return BSTR_ERR; + if (b2->slen == 0) return pos; + + l = b1->slen - b2->slen + 1; + + /* No space to find such a string? */ + if (l <= pos) return BSTR_ERR; + + /* An obvious alias case */ + if (b1->data == b2->data && pos == 0) return BSTR_OK; + + i = pos; + j = 0; + + d0 = b2->data; + d1 = b1->data; + ll = b2->slen; + + for (;;) { + if (d0[j] == d1[i + j] || downcase (d0[j]) == downcase (d1[i + j])) { + j ++; + if (j >= ll) return i; + } else { + i ++; + if (i >= l) break; + j=0; + } + } + + return BSTR_ERR; +} + +/* int binstrrcaseless (const_bstring b1, int pos, const_bstring b2) + * + * Search for the bstring b2 in b1 starting from position pos, and searching + * backward but without regard to case. If it is found then return with the + * first position where it is found, otherwise return BSTR_ERR. Note that + * this is just a brute force string searcher that does not attempt clever + * things like the Boyer-Moore search algorithm. Because of this there are + * many degenerate cases where this can take much longer than it needs to. + */ +int binstrrcaseless (const_bstring b1, int pos, const_bstring b2) { +int j, i, l; +unsigned char * d0, * d1; + + if (b1 == NULL || b1->data == NULL || b1->slen < 0 || + b2 == NULL || b2->data == NULL || b2->slen < 0) return BSTR_ERR; + if (b1->slen == pos && b2->slen == 0) return pos; + if (b1->slen < pos || pos < 0) return BSTR_ERR; + if (b2->slen == 0) return pos; + + /* Obvious alias case */ + if (b1->data == b2->data && pos == 0 && b2->slen <= b1->slen) return BSTR_OK; + + i = pos; + if ((l = b1->slen - b2->slen) < 0) return BSTR_ERR; + + /* If no space to find such a string then snap back */ + if (l + 1 <= i) i = l; + j = 0; + + d0 = b2->data; + d1 = b1->data; + l = b2->slen; + + for (;;) { + if (d0[j] == d1[i + j] || downcase (d0[j]) == downcase (d1[i + j])) { + j ++; + if (j >= l) return i; + } else { + i --; + if (i < 0) break; + j=0; + } + } + + return BSTR_ERR; +} + + +/* int bstrchrp (const_bstring b, int c, int pos) + * + * Search for the character c in b forwards from the position pos + * (inclusive). + */ +int bstrchrp (const_bstring b, int c, int pos) { +unsigned char * p; + + if (b == NULL || b->data == NULL || b->slen <= pos || pos < 0) return BSTR_ERR; + p = (unsigned char *) bstr__memchr ((b->data + pos), (unsigned char) c, (b->slen - pos)); + if (p) return (int) (p - b->data); + return BSTR_ERR; +} + +/* int bstrrchrp (const_bstring b, int c, int pos) + * + * Search for the character c in b backwards from the position pos in string + * (inclusive). + */ +int bstrrchrp (const_bstring b, int c, int pos) { +int i; + + if (b == NULL || b->data == NULL || b->slen <= pos || pos < 0) return BSTR_ERR; + for (i=pos; i >= 0; i--) { + if (b->data[i] == (unsigned char) c) return i; + } + return BSTR_ERR; +} + +#if !defined (BSTRLIB_AGGRESSIVE_MEMORY_FOR_SPEED_TRADEOFF) +#define LONG_LOG_BITS_QTY (3) +#define LONG_BITS_QTY (1 << LONG_LOG_BITS_QTY) +#define LONG_TYPE unsigned char + +#define CFCLEN ((1 << CHAR_BIT) / LONG_BITS_QTY) +struct charField { LONG_TYPE content[CFCLEN]; }; +#define testInCharField(cf,c) ((cf)->content[(c) >> LONG_LOG_BITS_QTY] & (((long)1) << ((c) & (LONG_BITS_QTY-1)))) +#define setInCharField(cf,idx) { \ + unsigned int c = (unsigned int) (idx); \ + (cf)->content[c >> LONG_LOG_BITS_QTY] |= (LONG_TYPE) (1ul << (c & (LONG_BITS_QTY-1))); \ +} + +#else + +#define CFCLEN (1 << CHAR_BIT) +struct charField { unsigned char content[CFCLEN]; }; +#define testInCharField(cf,c) ((cf)->content[(unsigned char) (c)]) +#define setInCharField(cf,idx) (cf)->content[(unsigned int) (idx)] = ~0 + +#endif + +/* Convert a bstring to charField */ +static int buildCharField (struct charField * cf, const_bstring b) { +int i; + if (b == NULL || b->data == NULL || b->slen <= 0) return BSTR_ERR; + memset ((void *) cf->content, 0, sizeof (struct charField)); + for (i=0; i < b->slen; i++) { + setInCharField (cf, b->data[i]); + } + return BSTR_OK; +} + +static void invertCharField (struct charField * cf) { +int i; + for (i=0; i < CFCLEN; i++) cf->content[i] = ~cf->content[i]; +} + +/* Inner engine for binchr */ +static int binchrCF (const unsigned char * data, int len, int pos, const struct charField * cf) { +int i; + for (i=pos; i < len; i++) { + unsigned char c = (unsigned char) data[i]; + if (testInCharField (cf, c)) return i; + } + return BSTR_ERR; +} + +/* int binchr (const_bstring b0, int pos, const_bstring b1); + * + * Search for the first position in b0 starting from pos or after, in which + * one of the characters in b1 is found and return it. If such a position + * does not exist in b0, then BSTR_ERR is returned. + */ +int binchr (const_bstring b0, int pos, const_bstring b1) { +struct charField chrs; + if (pos < 0 || b0 == NULL || b0->data == NULL || + b0->slen <= pos) return BSTR_ERR; + if (1 == b1->slen) return bstrchrp (b0, b1->data[0], pos); + if (0 > buildCharField (&chrs, b1)) return BSTR_ERR; + return binchrCF (b0->data, b0->slen, pos, &chrs); +} + +/* Inner engine for binchrr */ +static int binchrrCF (const unsigned char * data, int pos, const struct charField * cf) { +int i; + for (i=pos; i >= 0; i--) { + unsigned int c = (unsigned int) data[i]; + if (testInCharField (cf, c)) return i; + } + return BSTR_ERR; +} + +/* int binchrr (const_bstring b0, int pos, const_bstring b1); + * + * Search for the last position in b0 no greater than pos, in which one of + * the characters in b1 is found and return it. If such a position does not + * exist in b0, then BSTR_ERR is returned. + */ +int binchrr (const_bstring b0, int pos, const_bstring b1) { +struct charField chrs; + if (pos < 0 || b0 == NULL || b0->data == NULL || b1 == NULL || + b0->slen < pos) return BSTR_ERR; + if (pos == b0->slen) pos--; + if (1 == b1->slen) return bstrrchrp (b0, b1->data[0], pos); + if (0 > buildCharField (&chrs, b1)) return BSTR_ERR; + return binchrrCF (b0->data, pos, &chrs); +} + +/* int bninchr (const_bstring b0, int pos, const_bstring b1); + * + * Search for the first position in b0 starting from pos or after, in which + * none of the characters in b1 is found and return it. If such a position + * does not exist in b0, then BSTR_ERR is returned. + */ +int bninchr (const_bstring b0, int pos, const_bstring b1) { +struct charField chrs; + if (pos < 0 || b0 == NULL || b0->data == NULL || + b0->slen <= pos) return BSTR_ERR; + if (buildCharField (&chrs, b1) < 0) return BSTR_ERR; + invertCharField (&chrs); + return binchrCF (b0->data, b0->slen, pos, &chrs); +} + +/* int bninchrr (const_bstring b0, int pos, const_bstring b1); + * + * Search for the last position in b0 no greater than pos, in which none of + * the characters in b1 is found and return it. If such a position does not + * exist in b0, then BSTR_ERR is returned. + */ +int bninchrr (const_bstring b0, int pos, const_bstring b1) { +struct charField chrs; + if (pos < 0 || b0 == NULL || b0->data == NULL || + b0->slen < pos) return BSTR_ERR; + if (pos == b0->slen) pos--; + if (buildCharField (&chrs, b1) < 0) return BSTR_ERR; + invertCharField (&chrs); + return binchrrCF (b0->data, pos, &chrs); +} + +/* int bsetstr (bstring b0, int pos, bstring b1, unsigned char fill) + * + * Overwrite the string b0 starting at position pos with the string b1. If + * the position pos is past the end of b0, then the character "fill" is + * appended as necessary to make up the gap between the end of b0 and pos. + * If b1 is NULL, it behaves as if it were a 0-length string. + */ +int bsetstr (bstring b0, int pos, const_bstring b1, unsigned char fill) { +int d, newlen; +ptrdiff_t pd; +bstring aux = (bstring) b1; + + if (pos < 0 || b0 == NULL || b0->slen < 0 || NULL == b0->data || + b0->mlen < b0->slen || b0->mlen <= 0) return BSTR_ERR; + if (b1 != NULL && (b1->slen < 0 || b1->data == NULL)) return BSTR_ERR; + + d = pos; + + /* Aliasing case */ + if (NULL != aux) { + if ((pd = (ptrdiff_t) (b1->data - b0->data)) >= 0 && pd < (ptrdiff_t) b0->mlen) { + if (NULL == (aux = bstrcpy (b1))) return BSTR_ERR; + } + d += aux->slen; + } + + /* Increase memory size if necessary */ + if (balloc (b0, d + 1) != BSTR_OK) { + if (aux != b1) bdestroy (aux); + return BSTR_ERR; + } + + newlen = b0->slen; + + /* Fill in "fill" character as necessary */ + if (pos > newlen) { + bstr__memset (b0->data + b0->slen, (int) fill, (size_t) (pos - b0->slen)); + newlen = pos; + } + + /* Copy b1 to position pos in b0. */ + if (aux != NULL) { + bBlockCopy ((char *) (b0->data + pos), (char *) aux->data, aux->slen); + if (aux != b1) bdestroy (aux); + } + + /* Indicate the potentially increased size of b0 */ + if (d > newlen) newlen = d; + + b0->slen = newlen; + b0->data[newlen] = (unsigned char) '\0'; + + return BSTR_OK; +} + +/* int binsert (bstring b1, int pos, bstring b2, unsigned char fill) + * + * Inserts the string b2 into b1 at position pos. If the position pos is + * past the end of b1, then the character "fill" is appended as necessary to + * make up the gap between the end of b1 and pos. Unlike bsetstr, binsert + * does not allow b2 to be NULL. + */ +int binsert (bstring b1, int pos, const_bstring b2, unsigned char fill) { +int d, l; +ptrdiff_t pd; +bstring aux = (bstring) b2; + + if (pos < 0 || b1 == NULL || b2 == NULL || b1->slen < 0 || + b2->slen < 0 || b1->mlen < b1->slen || b1->mlen <= 0) return BSTR_ERR; + + /* Aliasing case */ + if ((pd = (ptrdiff_t) (b2->data - b1->data)) >= 0 && pd < (ptrdiff_t) b1->mlen) { + if (NULL == (aux = bstrcpy (b2))) return BSTR_ERR; + } + + /* Compute the two possible end pointers */ + d = b1->slen + aux->slen; + l = pos + aux->slen; + if ((d|l) < 0) return BSTR_ERR; + + if (l > d) { + /* Inserting past the end of the string */ + if (balloc (b1, l + 1) != BSTR_OK) { + if (aux != b2) bdestroy (aux); + return BSTR_ERR; + } + bstr__memset (b1->data + b1->slen, (int) fill, (size_t) (pos - b1->slen)); + b1->slen = l; + } else { + /* Inserting in the middle of the string */ + if (balloc (b1, d + 1) != BSTR_OK) { + if (aux != b2) bdestroy (aux); + return BSTR_ERR; + } + bBlockCopy (b1->data + l, b1->data + pos, d - l); + b1->slen = d; + } + bBlockCopy (b1->data + pos, aux->data, aux->slen); + b1->data[b1->slen] = (unsigned char) '\0'; + if (aux != b2) bdestroy (aux); + return BSTR_OK; +} + +/* int breplace (bstring b1, int pos, int len, bstring b2, + * unsigned char fill) + * + * Replace a section of a string from pos for a length len with the string b2. + * fill is used is pos > b1->slen. + */ +int breplace (bstring b1, int pos, int len, const_bstring b2, + unsigned char fill) { +int pl, ret; +ptrdiff_t pd; +bstring aux = (bstring) b2; + + if (pos < 0 || len < 0 || (pl = pos + len) < 0 || b1 == NULL || + b2 == NULL || b1->data == NULL || b2->data == NULL || + b1->slen < 0 || b2->slen < 0 || b1->mlen < b1->slen || + b1->mlen <= 0) return BSTR_ERR; + + /* Straddles the end? */ + if (pl >= b1->slen) { + if ((ret = bsetstr (b1, pos, b2, fill)) < 0) return ret; + if (pos + b2->slen < b1->slen) { + b1->slen = pos + b2->slen; + b1->data[b1->slen] = (unsigned char) '\0'; + } + return ret; + } + + /* Aliasing case */ + if ((pd = (ptrdiff_t) (b2->data - b1->data)) >= 0 && pd < (ptrdiff_t) b1->slen) { + if (NULL == (aux = bstrcpy (b2))) return BSTR_ERR; + } + + if (aux->slen > len) { + if (balloc (b1, b1->slen + aux->slen - len) != BSTR_OK) { + if (aux != b2) bdestroy (aux); + return BSTR_ERR; + } + } + + if (aux->slen != len) bstr__memmove (b1->data + pos + aux->slen, b1->data + pos + len, b1->slen - (pos + len)); + bstr__memcpy (b1->data + pos, aux->data, aux->slen); + b1->slen += aux->slen - len; + b1->data[b1->slen] = (unsigned char) '\0'; + if (aux != b2) bdestroy (aux); + return BSTR_OK; +} + +/* int bfindreplace (bstring b, const_bstring find, const_bstring repl, + * int pos) + * + * Replace all occurrences of a find string with a replace string after a + * given point in a bstring. + */ + +typedef int (*instr_fnptr) (const_bstring s1, int pos, const_bstring s2); + +static int findreplaceengine (bstring b, const_bstring find, const_bstring repl, int pos, instr_fnptr instr) { +int i, ret, slen, mlen, delta, acc; +int * d; +int static_d[32]; +ptrdiff_t pd; +bstring auxf = (bstring) find; +bstring auxr = (bstring) repl; + + if (b == NULL || b->data == NULL || find == NULL || + find->data == NULL || repl == NULL || repl->data == NULL || + pos < 0 || find->slen <= 0 || b->mlen < 0 || b->slen > b->mlen || + b->mlen <= 0 || b->slen < 0 || repl->slen < 0) return BSTR_ERR; + if (pos > b->slen - find->slen) return BSTR_OK; + + /* Alias with find string */ + pd = (ptrdiff_t) (find->data - b->data); + if ((ptrdiff_t) (pos - find->slen) < pd && pd < (ptrdiff_t) b->slen) { + if (NULL == (auxf = bstrcpy (find))) return BSTR_ERR; + } + + /* Alias with repl string */ + pd = (ptrdiff_t) (repl->data - b->data); + if ((ptrdiff_t) (pos - repl->slen) < pd && pd < (ptrdiff_t) b->slen) { + if (NULL == (auxr = bstrcpy (repl))) { + if (auxf != find) bdestroy (auxf); + return BSTR_ERR; + } + } + + delta = auxf->slen - auxr->slen; + + /* in-place replacement since find and replace strings are of equal + length */ + if (delta == 0) { + while ((pos = instr (b, pos, auxf)) >= 0) { + bstr__memcpy (b->data + pos, auxr->data, auxr->slen); + pos += auxf->slen; + } + if (auxf != find) bdestroy (auxf); + if (auxr != repl) bdestroy (auxr); + return BSTR_OK; + } + + /* shrinking replacement since auxf->slen > auxr->slen */ + if (delta > 0) { + acc = 0; + + while ((i = instr (b, pos, auxf)) >= 0) { + if (acc && i > pos) + bstr__memmove (b->data + pos - acc, b->data + pos, i - pos); + if (auxr->slen) + bstr__memcpy (b->data + i - acc, auxr->data, auxr->slen); + acc += delta; + pos = i + auxf->slen; + } + + if (acc) { + i = b->slen; + if (i > pos) + bstr__memmove (b->data + pos - acc, b->data + pos, i - pos); + b->slen -= acc; + b->data[b->slen] = (unsigned char) '\0'; + } + + if (auxf != find) bdestroy (auxf); + if (auxr != repl) bdestroy (auxr); + return BSTR_OK; + } + + /* expanding replacement since find->slen < repl->slen. Its a lot + more complicated. */ + + mlen = 32; + d = (int *) static_d; /* Avoid malloc for trivial cases */ + acc = slen = 0; + + while ((pos = instr (b, pos, auxf)) >= 0) { + if (slen + 1 >= mlen) { + int sl; + int * t; + mlen += mlen; + sl = sizeof (int *) * mlen; + if (static_d == d) d = NULL; + if (sl < mlen || NULL == (t = (int *) bstr__realloc (d, sl))) { + ret = BSTR_ERR; + goto done; + } + if (NULL == d) bstr__memcpy (t, static_d, sizeof (static_d)); + d = t; + } + d[slen] = pos; + slen++; + acc -= delta; + pos += auxf->slen; + if (pos < 0 || acc < 0) { + ret = BSTR_ERR; + goto done; + } + } + d[slen] = b->slen; + + if (BSTR_OK == (ret = balloc (b, b->slen + acc + 1))) { + b->slen += acc; + for (i = slen-1; i >= 0; i--) { + int s, l; + s = d[i] + auxf->slen; + l = d[i+1] - s; + if (l) { + bstr__memmove (b->data + s + acc, b->data + s, l); + } + if (auxr->slen) { + bstr__memmove (b->data + s + acc - auxr->slen, + auxr->data, auxr->slen); + } + acc += delta; + } + b->data[b->slen] = (unsigned char) '\0'; + } + + done:; + if (static_d == d) d = NULL; + bstr__free (d); + if (auxf != find) bdestroy (auxf); + if (auxr != repl) bdestroy (auxr); + return ret; +} + +/* int bfindreplace (bstring b, const_bstring find, const_bstring repl, + * int pos) + * + * Replace all occurrences of a find string with a replace string after a + * given point in a bstring. + */ +int bfindreplace (bstring b, const_bstring find, const_bstring repl, int pos) { + return findreplaceengine (b, find, repl, pos, binstr); +} + +/* int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, + * int pos) + * + * Replace all occurrences of a find string, ignoring case, with a replace + * string after a given point in a bstring. + */ +int bfindreplacecaseless (bstring b, const_bstring find, const_bstring repl, int pos) { + return findreplaceengine (b, find, repl, pos, binstrcaseless); +} + +/* int binsertch (bstring b, int pos, int len, unsigned char fill) + * + * Inserts the character fill repeatedly into b at position pos for a + * length len. If the position pos is past the end of b, then the + * character "fill" is appended as necessary to make up the gap between the + * end of b and the position pos + len. + */ +int binsertch (bstring b, int pos, int len, unsigned char fill) { +int d, l, i; + + if (pos < 0 || b == NULL || b->slen < 0 || b->mlen < b->slen || + b->mlen <= 0 || len < 0) return BSTR_ERR; + + /* Compute the two possible end pointers */ + d = b->slen + len; + l = pos + len; + if ((d|l) < 0) return BSTR_ERR; + + if (l > d) { + /* Inserting past the end of the string */ + if (balloc (b, l + 1) != BSTR_OK) return BSTR_ERR; + pos = b->slen; + b->slen = l; + } else { + /* Inserting in the middle of the string */ + if (balloc (b, d + 1) != BSTR_OK) return BSTR_ERR; + for (i = d - 1; i >= l; i--) { + b->data[i] = b->data[i - len]; + } + b->slen = d; + } + + for (i=pos; i < l; i++) b->data[i] = fill; + b->data[b->slen] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* int bpattern (bstring b, int len) + * + * Replicate the bstring, b in place, end to end repeatedly until it + * surpasses len characters, then chop the result to exactly len characters. + * This function operates in-place. The function will return with BSTR_ERR + * if b is NULL or of length 0, otherwise BSTR_OK is returned. + */ +int bpattern (bstring b, int len) { +int i, d; + + d = blength (b); + if (d <= 0 || len < 0 || balloc (b, len + 1) != BSTR_OK) return BSTR_ERR; + if (len > 0) { + if (d == 1) return bsetstr (b, len, NULL, b->data[0]); + for (i = d; i < len; i++) b->data[i] = b->data[i - d]; + } + b->data[len] = (unsigned char) '\0'; + b->slen = len; + return BSTR_OK; +} + +#define BS_BUFF_SZ (1024) + +/* int breada (bstring b, bNread readPtr, void * parm) + * + * Use a finite buffer fread-like function readPtr to concatenate to the + * bstring b the entire contents of file-like source data in a roughly + * efficient way. + */ +int breada (bstring b, bNread readPtr, void * parm) { +int i, l, n; + + if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || + b->mlen <= 0 || readPtr == NULL) return BSTR_ERR; + + i = b->slen; + for (n=i+16; ; n += ((n < BS_BUFF_SZ) ? n : BS_BUFF_SZ)) { + if (BSTR_OK != balloc (b, n + 1)) return BSTR_ERR; + l = (int) readPtr ((void *) (b->data + i), 1, n - i, parm); + i += l; + b->slen = i; + if (i < n) break; + } + + b->data[i] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* bstring bread (bNread readPtr, void * parm) + * + * Use a finite buffer fread-like function readPtr to create a bstring + * filled with the entire contents of file-like source data in a roughly + * efficient way. + */ +bstring bread (bNread readPtr, void * parm) { +bstring buff; + + if (0 > breada (buff = bfromcstr (""), readPtr, parm)) { + bdestroy (buff); + return NULL; + } + return buff; +} + +/* int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator) + * + * Use an fgetc-like single character stream reading function (getcPtr) to + * obtain a sequence of characters which are concatenated to the end of the + * bstring b. The stream read is terminated by the passed in terminator + * parameter. + * + * If getcPtr returns with a negative number, or the terminator character + * (which is appended) is read, then the stream reading is halted and the + * function returns with a partial result in b. If there is an empty partial + * result, 1 is returned. If no characters are read, or there is some other + * detectable error, BSTR_ERR is returned. + */ +int bassigngets (bstring b, bNgetc getcPtr, void * parm, char terminator) { +int c, d, e; + + if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || + b->mlen <= 0 || getcPtr == NULL) return BSTR_ERR; + d = 0; + e = b->mlen - 2; + + while ((c = getcPtr (parm)) >= 0) { + if (d > e) { + b->slen = d; + if (balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; + e = b->mlen - 2; + } + b->data[d] = (unsigned char) c; + d++; + if (c == terminator) break; + } + + b->data[d] = (unsigned char) '\0'; + b->slen = d; + + return d == 0 && c < 0; +} + +/* int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator) + * + * Use an fgetc-like single character stream reading function (getcPtr) to + * obtain a sequence of characters which are concatenated to the end of the + * bstring b. The stream read is terminated by the passed in terminator + * parameter. + * + * If getcPtr returns with a negative number, or the terminator character + * (which is appended) is read, then the stream reading is halted and the + * function returns with a partial result concatentated to b. If there is + * an empty partial result, 1 is returned. If no characters are read, or + * there is some other detectable error, BSTR_ERR is returned. + */ +int bgetsa (bstring b, bNgetc getcPtr, void * parm, char terminator) { +int c, d, e; + + if (b == NULL || b->mlen <= 0 || b->slen < 0 || b->mlen < b->slen || + b->mlen <= 0 || getcPtr == NULL) return BSTR_ERR; + d = b->slen; + e = b->mlen - 2; + + while ((c = getcPtr (parm)) >= 0) { + if (d > e) { + b->slen = d; + if (balloc (b, d + 2) != BSTR_OK) return BSTR_ERR; + e = b->mlen - 2; + } + b->data[d] = (unsigned char) c; + d++; + if (c == terminator) break; + } + + b->data[d] = (unsigned char) '\0'; + b->slen = d; + + return d == 0 && c < 0; +} + +/* bstring bgets (bNgetc getcPtr, void * parm, char terminator) + * + * Use an fgetc-like single character stream reading function (getcPtr) to + * obtain a sequence of characters which are concatenated into a bstring. + * The stream read is terminated by the passed in terminator function. + * + * If getcPtr returns with a negative number, or the terminator character + * (which is appended) is read, then the stream reading is halted and the + * result obtained thus far is returned. If no characters are read, or + * there is some other detectable error, NULL is returned. + */ +bstring bgets (bNgetc getcPtr, void * parm, char terminator) { +bstring buff; + + if (0 > bgetsa (buff = bfromcstr (""), getcPtr, parm, terminator) || 0 >= buff->slen) { + bdestroy (buff); + buff = NULL; + } + return buff; +} + +struct bStream { + bstring buff; /* Buffer for over-reads */ + void * parm; /* The stream handle for core stream */ + bNread readFnPtr; /* fread compatible fnptr for core stream */ + int isEOF; /* track file's EOF state */ + int maxBuffSz; +}; + +/* struct bStream * bsopen (bNread readPtr, void * parm) + * + * Wrap a given open stream (described by a fread compatible function + * pointer and stream handle) into an open bStream suitable for the bstring + * library streaming functions. + */ +struct bStream * bsopen (bNread readPtr, void * parm) { +struct bStream * s; + + if (readPtr == NULL) return NULL; + s = (struct bStream *) bstr__alloc (sizeof (struct bStream)); + if (s == NULL) return NULL; + s->parm = parm; + s->buff = bfromcstr (""); + s->readFnPtr = readPtr; + s->maxBuffSz = BS_BUFF_SZ; + s->isEOF = 0; + return s; +} + +/* int bsbufflength (struct bStream * s, int sz) + * + * Set the length of the buffer used by the bStream. If sz is zero, the + * length is not set. This function returns with the previous length. + */ +int bsbufflength (struct bStream * s, int sz) { +int oldSz; + if (s == NULL || sz < 0) return BSTR_ERR; + oldSz = s->maxBuffSz; + if (sz > 0) s->maxBuffSz = sz; + return oldSz; +} + +int bseof (const struct bStream * s) { + if (s == NULL || s->readFnPtr == NULL) return BSTR_ERR; + return s->isEOF && (s->buff->slen == 0); +} + +/* void * bsclose (struct bStream * s) + * + * Close the bStream, and return the handle to the stream that was originally + * used to open the given stream. + */ +void * bsclose (struct bStream * s) { +void * parm; + if (s == NULL) return NULL; + s->readFnPtr = NULL; + if (s->buff) bdestroy (s->buff); + s->buff = NULL; + parm = s->parm; + s->parm = NULL; + s->isEOF = 1; + bstr__free (s); + return parm; +} + +/* int bsreadlna (bstring r, struct bStream * s, char terminator) + * + * Read a bstring terminated by the terminator character or the end of the + * stream from the bStream (s) and return it into the parameter r. This + * function may read additional characters from the core stream that are not + * returned, but will be retained for subsequent read operations. + */ +int bsreadlna (bstring r, struct bStream * s, char terminator) { +int i, l, ret, rlo; +char * b; +struct tagbstring x; + + if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 || + r->slen < 0 || r->mlen < r->slen) return BSTR_ERR; + l = s->buff->slen; + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + b = (char *) s->buff->data; + x.data = (unsigned char *) b; + + /* First check if the current buffer holds the terminator */ + b[l] = terminator; /* Set sentinel */ + for (i=0; b[i] != terminator; i++) ; + if (i < l) { + x.slen = i + 1; + ret = bconcat (r, &x); + s->buff->slen = l; + if (BSTR_OK == ret) bdelete (s->buff, 0, i + 1); + return BSTR_OK; + } + + rlo = r->slen; + + /* If not then just concatenate the entire buffer to the output */ + x.slen = l; + if (BSTR_OK != bconcat (r, &x)) return BSTR_ERR; + + /* Perform direct in-place reads into the destination to allow for + the minimum of data-copies */ + for (;;) { + if (BSTR_OK != balloc (r, r->slen + s->maxBuffSz + 1)) return BSTR_ERR; + b = (char *) (r->data + r->slen); + l = (int) s->readFnPtr (b, 1, s->maxBuffSz, s->parm); + if (l <= 0) { + r->data[r->slen] = (unsigned char) '\0'; + s->buff->slen = 0; + s->isEOF = 1; + /* If nothing was read return with an error message */ + return BSTR_ERR & -(r->slen == rlo); + } + b[l] = terminator; /* Set sentinel */ + for (i=0; b[i] != terminator; i++) ; + if (i < l) break; + r->slen += l; + } + + /* Terminator found, push over-read back to buffer */ + i++; + r->slen += i; + s->buff->slen = l - i; + bstr__memcpy (s->buff->data, b + i, l - i); + r->data[r->slen] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* int bsreadlnsa (bstring r, struct bStream * s, bstring term) + * + * Read a bstring terminated by any character in the term string or the end + * of the stream from the bStream (s) and return it into the parameter r. + * This function may read additional characters from the core stream that + * are not returned, but will be retained for subsequent read operations. + */ +int bsreadlnsa (bstring r, struct bStream * s, const_bstring term) { +int i, l, ret, rlo; +unsigned char * b; +struct tagbstring x; +struct charField cf; + + if (s == NULL || s->buff == NULL || r == NULL || term == NULL || + term->data == NULL || r->mlen <= 0 || r->slen < 0 || + r->mlen < r->slen) return BSTR_ERR; + if (term->slen == 1) return bsreadlna (r, s, term->data[0]); + if (term->slen < 1 || buildCharField (&cf, term)) return BSTR_ERR; + + l = s->buff->slen; + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + b = (unsigned char *) s->buff->data; + x.data = b; + + /* First check if the current buffer holds the terminator */ + b[l] = term->data[0]; /* Set sentinel */ + for (i=0; !testInCharField (&cf, b[i]); i++) ; + if (i < l) { + x.slen = i + 1; + ret = bconcat (r, &x); + s->buff->slen = l; + if (BSTR_OK == ret) bdelete (s->buff, 0, i + 1); + return BSTR_OK; + } + + rlo = r->slen; + + /* If not then just concatenate the entire buffer to the output */ + x.slen = l; + if (BSTR_OK != bconcat (r, &x)) return BSTR_ERR; + + /* Perform direct in-place reads into the destination to allow for + the minimum of data-copies */ + for (;;) { + if (BSTR_OK != balloc (r, r->slen + s->maxBuffSz + 1)) return BSTR_ERR; + b = (unsigned char *) (r->data + r->slen); + l = (int) s->readFnPtr (b, 1, s->maxBuffSz, s->parm); + if (l <= 0) { + r->data[r->slen] = (unsigned char) '\0'; + s->buff->slen = 0; + s->isEOF = 1; + /* If nothing was read return with an error message */ + return BSTR_ERR & -(r->slen == rlo); + } + + b[l] = term->data[0]; /* Set sentinel */ + for (i=0; !testInCharField (&cf, b[i]); i++) ; + if (i < l) break; + r->slen += l; + } + + /* Terminator found, push over-read back to buffer */ + i++; + r->slen += i; + s->buff->slen = l - i; + bstr__memcpy (s->buff->data, b + i, l - i); + r->data[r->slen] = (unsigned char) '\0'; + return BSTR_OK; +} + +/* int bsreada (bstring r, struct bStream * s, int n) + * + * Read a bstring of length n (or, if it is fewer, as many bytes as is + * remaining) from the bStream. This function may read additional + * characters from the core stream that are not returned, but will be + * retained for subsequent read operations. This function will not read + * additional characters from the core stream beyond virtual stream pointer. + */ +int bsreada (bstring r, struct bStream * s, int n) { +int l, ret, orslen; +char * b; +struct tagbstring x; + + if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 + || r->slen < 0 || r->mlen < r->slen || n <= 0) return BSTR_ERR; + + n += r->slen; + if (n <= 0) return BSTR_ERR; + + l = s->buff->slen; + + orslen = r->slen; + + if (0 == l) { + if (s->isEOF) return BSTR_ERR; + if (r->mlen > n) { + l = (int) s->readFnPtr (r->data + r->slen, 1, n - r->slen, s->parm); + if (0 >= l || l > n - r->slen) { + s->isEOF = 1; + return BSTR_ERR; + } + r->slen += l; + r->data[r->slen] = (unsigned char) '\0'; + return 0; + } + } + + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + b = (char *) s->buff->data; + x.data = (unsigned char *) b; + + do { + if (l + r->slen >= n) { + x.slen = n - r->slen; + ret = bconcat (r, &x); + s->buff->slen = l; + if (BSTR_OK == ret) bdelete (s->buff, 0, x.slen); + return BSTR_ERR & -(r->slen == orslen); + } + + x.slen = l; + if (BSTR_OK != bconcat (r, &x)) break; + + l = n - r->slen; + if (l > s->maxBuffSz) l = s->maxBuffSz; + + l = (int) s->readFnPtr (b, 1, l, s->parm); + + } while (l > 0); + if (l < 0) l = 0; + if (l == 0) s->isEOF = 1; + s->buff->slen = l; + return BSTR_ERR & -(r->slen == orslen); +} + +/* int bsreadln (bstring r, struct bStream * s, char terminator) + * + * Read a bstring terminated by the terminator character or the end of the + * stream from the bStream (s) and return it into the parameter r. This + * function may read additional characters from the core stream that are not + * returned, but will be retained for subsequent read operations. + */ +int bsreadln (bstring r, struct bStream * s, char terminator) { + if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0) + return BSTR_ERR; + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + r->slen = 0; + return bsreadlna (r, s, terminator); +} + +/* int bsreadlns (bstring r, struct bStream * s, bstring term) + * + * Read a bstring terminated by any character in the term string or the end + * of the stream from the bStream (s) and return it into the parameter r. + * This function may read additional characters from the core stream that + * are not returned, but will be retained for subsequent read operations. + */ +int bsreadlns (bstring r, struct bStream * s, const_bstring term) { + if (s == NULL || s->buff == NULL || r == NULL || term == NULL + || term->data == NULL || r->mlen <= 0) return BSTR_ERR; + if (term->slen == 1) return bsreadln (r, s, term->data[0]); + if (term->slen < 1) return BSTR_ERR; + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + r->slen = 0; + return bsreadlnsa (r, s, term); +} + +/* int bsread (bstring r, struct bStream * s, int n) + * + * Read a bstring of length n (or, if it is fewer, as many bytes as is + * remaining) from the bStream. This function may read additional + * characters from the core stream that are not returned, but will be + * retained for subsequent read operations. This function will not read + * additional characters from the core stream beyond virtual stream pointer. + */ +int bsread (bstring r, struct bStream * s, int n) { + if (s == NULL || s->buff == NULL || r == NULL || r->mlen <= 0 + || n <= 0) return BSTR_ERR; + if (BSTR_OK != balloc (s->buff, s->maxBuffSz + 1)) return BSTR_ERR; + r->slen = 0; + return bsreada (r, s, n); +} + +/* int bsunread (struct bStream * s, const_bstring b) + * + * Insert a bstring into the bStream at the current position. These + * characters will be read prior to those that actually come from the core + * stream. + */ +int bsunread (struct bStream * s, const_bstring b) { + if (s == NULL || s->buff == NULL) return BSTR_ERR; + return binsert (s->buff, 0, b, (unsigned char) '?'); +} + +/* int bspeek (bstring r, const struct bStream * s) + * + * Return the currently buffered characters from the bStream that will be + * read prior to reads from the core stream. + */ +int bspeek (bstring r, const struct bStream * s) { + if (s == NULL || s->buff == NULL) return BSTR_ERR; + return bassign (r, s->buff); +} + +/* bstring bjoin (const struct bstrList * bl, const_bstring sep); + * + * Join the entries of a bstrList into one bstring by sequentially + * concatenating them with the sep string in between. If there is an error + * NULL is returned, otherwise a bstring with the correct result is returned. + */ +bstring bjoin (const struct bstrList * bl, const_bstring sep) { +bstring b; +int i, c, v; + + if (bl == NULL || bl->qty < 0) return NULL; + if (sep != NULL && (sep->slen < 0 || sep->data == NULL)) return NULL; + + for (i = 0, c = 1; i < bl->qty; i++) { + v = bl->entry[i]->slen; + if (v < 0) return NULL; /* Invalid input */ + c += v; + if (c < 0) return NULL; /* Wrap around ?? */ + } + + if (sep != NULL) c += (bl->qty - 1) * sep->slen; + + b = (bstring) bstr__alloc (sizeof (struct tagbstring)); + if (NULL == b) return NULL; /* Out of memory */ + b->data = (unsigned char *) bstr__alloc (c); + if (b->data == NULL) { + bstr__free (b); + return NULL; + } + + b->mlen = c; + b->slen = c-1; + + for (i = 0, c = 0; i < bl->qty; i++) { + if (i > 0 && sep != NULL) { + bstr__memcpy (b->data + c, sep->data, sep->slen); + c += sep->slen; + } + v = bl->entry[i]->slen; + bstr__memcpy (b->data + c, bl->entry[i]->data, v); + c += v; + } + b->data[c] = (unsigned char) '\0'; + return b; +} + +#define BSSSC_BUFF_LEN (256) + +/* int bssplitscb (struct bStream * s, const_bstring splitStr, + * int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) + * + * Iterate the set of disjoint sequential substrings read from a stream + * divided by any of the characters in splitStr. An empty splitStr causes + * the whole stream to be iterated once. + * + * Note: At the point of calling the cb function, the bStream pointer is + * pointed exactly at the position right after having read the split + * character. The cb function can act on the stream by causing the bStream + * pointer to move, and bssplitscb will continue by starting the next split + * at the position of the pointer after the return from cb. + * + * However, if the cb causes the bStream s to be destroyed then the cb must + * return with a negative value, otherwise bssplitscb will continue in an + * undefined manner. + */ +int bssplitscb (struct bStream * s, const_bstring splitStr, + int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) { +struct charField chrs; +bstring buff; +int i, p, ret; + + if (cb == NULL || s == NULL || s->readFnPtr == NULL + || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; + + if (NULL == (buff = bfromcstr (""))) return BSTR_ERR; + + if (splitStr->slen == 0) { + while (bsreada (buff, s, BSSSC_BUFF_LEN) >= 0) ; + if ((ret = cb (parm, 0, buff)) > 0) + ret = 0; + } else { + buildCharField (&chrs, splitStr); + ret = p = i = 0; + for (;;) { + if (i >= buff->slen) { + bsreada (buff, s, BSSSC_BUFF_LEN); + if (i >= buff->slen) { + if (0 < (ret = cb (parm, p, buff))) ret = 0; + break; + } + } + if (testInCharField (&chrs, buff->data[i])) { + struct tagbstring t; + unsigned char c; + + blk2tbstr (t, buff->data + i + 1, buff->slen - (i + 1)); + if ((ret = bsunread (s, &t)) < 0) break; + buff->slen = i; + c = buff->data[i]; + buff->data[i] = (unsigned char) '\0'; + if ((ret = cb (parm, p, buff)) < 0) break; + buff->data[i] = c; + buff->slen = 0; + p += i + 1; + i = -1; + } + i++; + } + } + + bdestroy (buff); + return ret; +} + +/* int bssplitstrcb (struct bStream * s, const_bstring splitStr, + * int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) + * + * Iterate the set of disjoint sequential substrings read from a stream + * divided by the entire substring splitStr. An empty splitStr causes + * each character of the stream to be iterated. + * + * Note: At the point of calling the cb function, the bStream pointer is + * pointed exactly at the position right after having read the split + * character. The cb function can act on the stream by causing the bStream + * pointer to move, and bssplitscb will continue by starting the next split + * at the position of the pointer after the return from cb. + * + * However, if the cb causes the bStream s to be destroyed then the cb must + * return with a negative value, otherwise bssplitscb will continue in an + * undefined manner. + */ +int bssplitstrcb (struct bStream * s, const_bstring splitStr, + int (* cb) (void * parm, int ofs, const_bstring entry), void * parm) { +bstring buff; +int i, p, ret; + + if (cb == NULL || s == NULL || s->readFnPtr == NULL + || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; + + if (splitStr->slen == 1) return bssplitscb (s, splitStr, cb, parm); + + if (NULL == (buff = bfromcstr (""))) return BSTR_ERR; + + if (splitStr->slen == 0) { + for (i=0; bsreada (buff, s, BSSSC_BUFF_LEN) >= 0; i++) { + if ((ret = cb (parm, 0, buff)) < 0) { + bdestroy (buff); + return ret; + } + buff->slen = 0; + } + return BSTR_OK; + } else { + ret = p = i = 0; + for (i=p=0;;) { + if ((ret = binstr (buff, 0, splitStr)) >= 0) { + struct tagbstring t; + blk2tbstr (t, buff->data, ret); + i = ret + splitStr->slen; + if ((ret = cb (parm, p, &t)) < 0) break; + p += i; + bdelete (buff, 0, i); + } else { + bsreada (buff, s, BSSSC_BUFF_LEN); + if (bseof (s)) { + if ((ret = cb (parm, p, buff)) > 0) ret = 0; + break; + } + } + } + } + + bdestroy (buff); + return ret; +} + +/* int bstrListCreate (void) + * + * Create a bstrList. + */ +struct bstrList * bstrListCreate (void) { +struct bstrList * sl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); + if (sl) { + sl->entry = (bstring *) bstr__alloc (1*sizeof (bstring)); + if (!sl->entry) { + bstr__free (sl); + sl = NULL; + } else { + sl->qty = 0; + sl->mlen = 1; + } + } + return sl; +} + +/* int bstrListDestroy (struct bstrList * sl) + * + * Destroy a bstrList that has been created by bsplit, bsplits or bstrListCreate. + */ +int bstrListDestroy (struct bstrList * sl) { +int i; + if (sl == NULL || sl->qty < 0) return BSTR_ERR; + for (i=0; i < sl->qty; i++) { + if (sl->entry[i]) { + bdestroy (sl->entry[i]); + sl->entry[i] = NULL; + } + } + sl->qty = -1; + sl->mlen = -1; + bstr__free (sl->entry); + sl->entry = NULL; + bstr__free (sl); + return BSTR_OK; +} + +/* int bstrListAlloc (struct bstrList * sl, int msz) + * + * Ensure that there is memory for at least msz number of entries for the + * list. + */ +int bstrListAlloc (struct bstrList * sl, int msz) { +bstring * l; +int smsz; +size_t nsz; + if (!sl || msz <= 0 || !sl->entry || sl->qty < 0 || sl->mlen <= 0 || sl->qty > sl->mlen) return BSTR_ERR; + if (sl->mlen >= msz) return BSTR_OK; + smsz = snapUpSize (msz); + nsz = ((size_t) smsz) * sizeof (bstring); + if (nsz < (size_t) smsz) return BSTR_ERR; + l = (bstring *) bstr__realloc (sl->entry, nsz); + if (!l) { + smsz = msz; + nsz = ((size_t) smsz) * sizeof (bstring); + l = (bstring *) bstr__realloc (sl->entry, nsz); + if (!l) return BSTR_ERR; + } + sl->mlen = smsz; + sl->entry = l; + return BSTR_OK; +} + +/* int bstrListAllocMin (struct bstrList * sl, int msz) + * + * Try to allocate the minimum amount of memory for the list to include at + * least msz entries or sl->qty whichever is greater. + */ +int bstrListAllocMin (struct bstrList * sl, int msz) { +bstring * l; +size_t nsz; + if (!sl || msz <= 0 || !sl->entry || sl->qty < 0 || sl->mlen <= 0 || sl->qty > sl->mlen) return BSTR_ERR; + if (msz < sl->qty) msz = sl->qty; + if (sl->mlen == msz) return BSTR_OK; + nsz = ((size_t) msz) * sizeof (bstring); + if (nsz < (size_t) msz) return BSTR_ERR; + l = (bstring *) bstr__realloc (sl->entry, nsz); + if (!l) return BSTR_ERR; + sl->mlen = msz; + sl->entry = l; + return BSTR_OK; +} + +/* int bsplitcb (const_bstring str, unsigned char splitChar, int pos, + * int (* cb) (void * parm, int ofs, int len), void * parm) + * + * Iterate the set of disjoint sequential substrings over str divided by the + * character in splitChar. + * + * Note: Non-destructive modification of str from within the cb function + * while performing this split is not undefined. bsplitcb behaves in + * sequential lock step with calls to cb. I.e., after returning from a cb + * that return a non-negative integer, bsplitcb continues from the position + * 1 character after the last detected split character and it will halt + * immediately if the length of str falls below this point. However, if the + * cb function destroys str, then it *must* return with a negative value, + * otherwise bsplitcb will continue in an undefined manner. + */ +int bsplitcb (const_bstring str, unsigned char splitChar, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm) { +int i, p, ret; + + if (cb == NULL || str == NULL || pos < 0 || pos > str->slen) + return BSTR_ERR; + + p = pos; + do { + for (i=p; i < str->slen; i++) { + if (str->data[i] == splitChar) break; + } + if ((ret = cb (parm, p, i - p)) < 0) return ret; + p = i + 1; + } while (p <= str->slen); + return BSTR_OK; +} + +/* int bsplitscb (const_bstring str, const_bstring splitStr, int pos, + * int (* cb) (void * parm, int ofs, int len), void * parm) + * + * Iterate the set of disjoint sequential substrings over str divided by any + * of the characters in splitStr. An empty splitStr causes the whole str to + * be iterated once. + * + * Note: Non-destructive modification of str from within the cb function + * while performing this split is not undefined. bsplitscb behaves in + * sequential lock step with calls to cb. I.e., after returning from a cb + * that return a non-negative integer, bsplitscb continues from the position + * 1 character after the last detected split character and it will halt + * immediately if the length of str falls below this point. However, if the + * cb function destroys str, then it *must* return with a negative value, + * otherwise bsplitscb will continue in an undefined manner. + */ +int bsplitscb (const_bstring str, const_bstring splitStr, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm) { +struct charField chrs; +int i, p, ret; + + if (cb == NULL || str == NULL || pos < 0 || pos > str->slen + || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; + if (splitStr->slen == 0) { + if ((ret = cb (parm, 0, str->slen)) > 0) ret = 0; + return ret; + } + + if (splitStr->slen == 1) + return bsplitcb (str, splitStr->data[0], pos, cb, parm); + + buildCharField (&chrs, splitStr); + + p = pos; + do { + for (i=p; i < str->slen; i++) { + if (testInCharField (&chrs, str->data[i])) break; + } + if ((ret = cb (parm, p, i - p)) < 0) return ret; + p = i + 1; + } while (p <= str->slen); + return BSTR_OK; +} + +/* int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, + * int (* cb) (void * parm, int ofs, int len), void * parm) + * + * Iterate the set of disjoint sequential substrings over str divided by the + * substring splitStr. An empty splitStr causes the whole str to be + * iterated once. + * + * Note: Non-destructive modification of str from within the cb function + * while performing this split is not undefined. bsplitstrcb behaves in + * sequential lock step with calls to cb. I.e., after returning from a cb + * that return a non-negative integer, bsplitscb continues from the position + * 1 character after the last detected split character and it will halt + * immediately if the length of str falls below this point. However, if the + * cb function destroys str, then it *must* return with a negative value, + * otherwise bsplitscb will continue in an undefined manner. + */ +int bsplitstrcb (const_bstring str, const_bstring splitStr, int pos, + int (* cb) (void * parm, int ofs, int len), void * parm) { +int i, p, ret; + + if (cb == NULL || str == NULL || pos < 0 || pos > str->slen + || splitStr == NULL || splitStr->slen < 0) return BSTR_ERR; + + if (0 == splitStr->slen) { + for (i=pos; i < str->slen; i++) { + if ((ret = cb (parm, i, 1)) < 0) return ret; + } + return BSTR_OK; + } + + if (splitStr->slen == 1) + return bsplitcb (str, splitStr->data[0], pos, cb, parm); + + for (i=p=pos; i <= str->slen - splitStr->slen; i++) { + if (0 == bstr__memcmp (splitStr->data, str->data + i, splitStr->slen)) { + if ((ret = cb (parm, p, i - p)) < 0) return ret; + i += splitStr->slen; + p = i; + } + } + if ((ret = cb (parm, p, str->slen - p)) < 0) return ret; + return BSTR_OK; +} + +struct genBstrList { + bstring b; + struct bstrList * bl; +}; + +static int bscb (void * parm, int ofs, int len) { +struct genBstrList * g = (struct genBstrList *) parm; + if (g->bl->qty >= g->bl->mlen) { + int mlen = g->bl->mlen * 2; + bstring * tbl; + + while (g->bl->qty >= mlen) { + if (mlen < g->bl->mlen) return BSTR_ERR; + mlen += mlen; + } + + tbl = (bstring *) bstr__realloc (g->bl->entry, sizeof (bstring) * mlen); + if (tbl == NULL) return BSTR_ERR; + + g->bl->entry = tbl; + g->bl->mlen = mlen; + } + + g->bl->entry[g->bl->qty] = bmidstr (g->b, ofs, len); + g->bl->qty++; + return BSTR_OK; +} + +/* struct bstrList * bsplit (const_bstring str, unsigned char splitChar) + * + * Create an array of sequential substrings from str divided by the character + * splitChar. + */ +struct bstrList * bsplit (const_bstring str, unsigned char splitChar) { +struct genBstrList g; + + if (str == NULL || str->data == NULL || str->slen < 0) return NULL; + + g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); + if (g.bl == NULL) return NULL; + g.bl->mlen = 4; + g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); + if (NULL == g.bl->entry) { + bstr__free (g.bl); + return NULL; + } + + g.b = (bstring) str; + g.bl->qty = 0; + if (bsplitcb (str, splitChar, 0, bscb, &g) < 0) { + bstrListDestroy (g.bl); + return NULL; + } + return g.bl; +} + +/* struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr) + * + * Create an array of sequential substrings from str divided by the entire + * substring splitStr. + */ +struct bstrList * bsplitstr (const_bstring str, const_bstring splitStr) { +struct genBstrList g; + + if (str == NULL || str->data == NULL || str->slen < 0) return NULL; + + g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); + if (g.bl == NULL) return NULL; + g.bl->mlen = 4; + g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); + if (NULL == g.bl->entry) { + bstr__free (g.bl); + return NULL; + } + + g.b = (bstring) str; + g.bl->qty = 0; + if (bsplitstrcb (str, splitStr, 0, bscb, &g) < 0) { + bstrListDestroy (g.bl); + return NULL; + } + return g.bl; +} + +/* struct bstrList * bsplits (const_bstring str, bstring splitStr) + * + * Create an array of sequential substrings from str divided by any of the + * characters in splitStr. An empty splitStr causes a single entry bstrList + * containing a copy of str to be returned. + */ +struct bstrList * bsplits (const_bstring str, const_bstring splitStr) { +struct genBstrList g; + + if ( str == NULL || str->slen < 0 || str->data == NULL || + splitStr == NULL || splitStr->slen < 0 || splitStr->data == NULL) + return NULL; + + g.bl = (struct bstrList *) bstr__alloc (sizeof (struct bstrList)); + if (g.bl == NULL) return NULL; + g.bl->mlen = 4; + g.bl->entry = (bstring *) bstr__alloc (g.bl->mlen * sizeof (bstring)); + if (NULL == g.bl->entry) { + bstr__free (g.bl); + return NULL; + } + g.b = (bstring) str; + g.bl->qty = 0; + + if (bsplitscb (str, splitStr, 0, bscb, &g) < 0) { + bstrListDestroy (g.bl); + return NULL; + } + return g.bl; +} + +#if defined (__TURBOC__) && !defined (__BORLANDC__) +# ifndef BSTRLIB_NOVSNP +# define BSTRLIB_NOVSNP +# endif +#endif + +/* Give WATCOM C/C++, MSVC some latitude for their non-support of vsnprintf */ +#if defined(__WATCOMC__) || defined(_MSC_VER) +#define exvsnprintf(r,b,n,f,a) {r = _vsnprintf (b,n,f,a);} +#else +#ifdef BSTRLIB_NOVSNP +/* This is just a hack. If you are using a system without a vsnprintf, it is + not recommended that bformat be used at all. */ +#define exvsnprintf(r,b,n,f,a) {vsprintf (b,f,a); r = -1;} +#define START_VSNBUFF (256) +#else + +#ifdef __GNUC__ +/* Something is making gcc complain about this prototype not being here, so + I've just gone ahead and put it in. */ +extern int vsnprintf (char *buf, size_t count, const char *format, va_list arg); +#endif + +#define exvsnprintf(r,b,n,f,a) {r = vsnprintf (b,n,f,a);} +#endif +#endif + +#if !defined (BSTRLIB_NOVSNP) + +#ifndef START_VSNBUFF +#define START_VSNBUFF (16) +#endif + +/* On IRIX vsnprintf returns n-1 when the operation would overflow the target + buffer, WATCOM and MSVC both return -1, while C99 requires that the + returned value be exactly what the length would be if the buffer would be + large enough. This leads to the idea that if the return value is larger + than n, then changing n to the return value will reduce the number of + iterations required. */ + +/* int bformata (bstring b, const char * fmt, ...) + * + * After the first parameter, it takes the same parameters as printf (), but + * rather than outputting results to stdio, it appends the results to + * a bstring which contains what would have been output. Note that if there + * is an early generation of a '\0' character, the bstring will be truncated + * to this end point. + */ +int bformata (bstring b, const char * fmt, ...) { +va_list arglist; +bstring buff; +int n, r; + + if (b == NULL || fmt == NULL || b->data == NULL || b->mlen <= 0 + || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; + + /* Since the length is not determinable beforehand, a search is + performed using the truncating "vsnprintf" call (to avoid buffer + overflows) on increasing potential sizes for the output result. */ + + if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) { + n = 1; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) return BSTR_ERR; + } + + for (;;) { + va_start (arglist, fmt); + exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); + va_end (arglist); + + buff->data[n] = (unsigned char) '\0'; + buff->slen = (int) (strlen) ((char *) buff->data); + + if (buff->slen < n) break; + + if (r > n) n = r; else n += n; + + if (BSTR_OK != balloc (buff, n + 2)) { + bdestroy (buff); + return BSTR_ERR; + } + } + + r = bconcat (b, buff); + bdestroy (buff); + return r; +} + +/* int bassignformat (bstring b, const char * fmt, ...) + * + * After the first parameter, it takes the same parameters as printf (), but + * rather than outputting results to stdio, it outputs the results to + * the bstring parameter b. Note that if there is an early generation of a + * '\0' character, the bstring will be truncated to this end point. + */ +int bassignformat (bstring b, const char * fmt, ...) { +va_list arglist; +bstring buff; +int n, r; + + if (b == NULL || fmt == NULL || b->data == NULL || b->mlen <= 0 + || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; + + /* Since the length is not determinable beforehand, a search is + performed using the truncating "vsnprintf" call (to avoid buffer + overflows) on increasing potential sizes for the output result. */ + + if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) { + n = 1; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) return BSTR_ERR; + } + + for (;;) { + va_start (arglist, fmt); + exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); + va_end (arglist); + + buff->data[n] = (unsigned char) '\0'; + buff->slen = (int) (strlen) ((char *) buff->data); + + if (buff->slen < n) break; + + if (r > n) n = r; else n += n; + + if (BSTR_OK != balloc (buff, n + 2)) { + bdestroy (buff); + return BSTR_ERR; + } + } + + r = bassign (b, buff); + bdestroy (buff); + return r; +} + +/* bstring bformat (const char * fmt, ...) + * + * Takes the same parameters as printf (), but rather than outputting results + * to stdio, it forms a bstring which contains what would have been output. + * Note that if there is an early generation of a '\0' character, the + * bstring will be truncated to this end point. + */ +bstring bformat (const char * fmt, ...) { +va_list arglist; +bstring buff; +int n, r; + + if (fmt == NULL) return NULL; + + /* Since the length is not determinable beforehand, a search is + performed using the truncating "vsnprintf" call (to avoid buffer + overflows) on increasing potential sizes for the output result. */ + + if ((n = (int) (2*strlen (fmt))) < START_VSNBUFF) n = START_VSNBUFF; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) { + n = 1; + if (NULL == (buff = bfromcstralloc (n + 2, ""))) return NULL; + } + + for (;;) { + va_start (arglist, fmt); + exvsnprintf (r, (char *) buff->data, n + 1, fmt, arglist); + va_end (arglist); + + buff->data[n] = (unsigned char) '\0'; + buff->slen = (int) (strlen) ((char *) buff->data); + + if (buff->slen < n) break; + + if (r > n) n = r; else n += n; + + if (BSTR_OK != balloc (buff, n + 2)) { + bdestroy (buff); + return NULL; + } + } + + return buff; +} + +/* int bvcformata (bstring b, int count, const char * fmt, va_list arglist) + * + * The bvcformata function formats data under control of the format control + * string fmt and attempts to append the result to b. The fmt parameter is + * the same as that of the printf function. The variable argument list is + * replaced with arglist, which has been initialized by the va_start macro. + * The size of the output is upper bounded by count. If the required output + * exceeds count, the string b is not augmented with any contents and a value + * below BSTR_ERR is returned. If a value below -count is returned then it + * is recommended that the negative of this value be used as an update to the + * count in a subsequent pass. On other errors, such as running out of + * memory, parameter errors or numeric wrap around BSTR_ERR is returned. + * BSTR_OK is returned when the output is successfully generated and + * appended to b. + * + * Note: There is no sanity checking of arglist, and this function is + * destructive of the contents of b from the b->slen point onward. If there + * is an early generation of a '\0' character, the bstring will be truncated + * to this end point. + */ +int bvcformata (bstring b, int count, const char * fmt, va_list arg) { +int n, r, l; + + if (b == NULL || fmt == NULL || count <= 0 || b->data == NULL + || b->mlen <= 0 || b->slen < 0 || b->slen > b->mlen) return BSTR_ERR; + + if (count > (n = b->slen + count) + 2) return BSTR_ERR; + if (BSTR_OK != balloc (b, n + 2)) return BSTR_ERR; + + exvsnprintf (r, (char *) b->data + b->slen, count + 2, fmt, arg); + + /* Did the operation complete successfully within bounds? */ + + if (n >= (l = b->slen + (int) (strlen) ((const char *) b->data + b->slen))) { + b->slen = l; + return BSTR_OK; + } + + /* Abort, since the buffer was not large enough. The return value + tries to help set what the retry length should be. */ + + b->data[b->slen] = '\0'; + if (r > count+1) l = r; else { + l = count+count; + if (count > l) l = INT_MAX; + } + n = -l; + if (n > BSTR_ERR-1) n = BSTR_ERR-1; + return n; +} + +#endif