/* Unix SMB/CIFS implementation. Samba utility functions Copyright (C) Andrew Tridgell 1992-2001 Copyright (C) Simo Sorce 2001-2002 Copyright (C) Martin Pool 2003 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "includes.h" /** * @file * @brief String utilities. **/ /** * Get the next token from a string, return False if none found. * Handles double-quotes. * * Based on a routine by GJC@VILLAGE.COM. * Extensively modified by Andrew.Tridgell@anu.edu.au **/ BOOL next_token(const char **ptr,char *buff, const char *sep, size_t bufsize) { char *s; char *pbuf; BOOL quoted; size_t len=1; if (!ptr) return(False); s = (char *)*ptr; /* default to simple separators */ if (!sep) sep = " \t\n\r"; /* find the first non sep char */ while (*s && strchr_m(sep,*s)) s++; /* nothing left? */ if (! *s) return(False); /* copy over the token */ pbuf = buff; for (quoted = False; len < bufsize && *s && (quoted || !strchr_m(sep,*s)); s++) { if (*s == '\"') { quoted = !quoted; } else { len++; *pbuf++ = *s; } } *ptr = (*s) ? s+1 : s; *pbuf = 0; return(True); } /** This is like next_token but is not re-entrant and "remembers" the first parameter so you can pass NULL. This is useful for user interface code but beware the fact that it is not re-entrant! **/ static const char *last_ptr=NULL; BOOL next_token_nr(const char **ptr,char *buff, const char *sep, size_t bufsize) { BOOL ret; if (!ptr) ptr = &last_ptr; ret = next_token(ptr, buff, sep, bufsize); last_ptr = *ptr; return ret; } static uint16 tmpbuf[sizeof(pstring)]; void set_first_token(char *ptr) { last_ptr = ptr; } /** Convert list of tokens to array; dependent on above routine. Uses last_ptr from above - bit of a hack. **/ char **toktocliplist(int *ctok, const char *sep) { char *s=(char *)last_ptr; int ictok=0; char **ret, **iret; if (!sep) sep = " \t\n\r"; while(*s && strchr_m(sep,*s)) s++; /* nothing left? */ if (!*s) return(NULL); do { ictok++; while(*s && (!strchr_m(sep,*s))) s++; while(*s && strchr_m(sep,*s)) *s++=0; } while(*s); *ctok=ictok; s=(char *)last_ptr; if (!(ret=iret=malloc(ictok*sizeof(char *)))) return NULL; while(ictok--) { *iret++=s; while(*s++) ; while(!*s) s++; } return ret; } /** * Case insensitive string compararison. * * iconv does not directly give us a way to compare strings in * arbitrary unix character sets -- all we can is convert and then * compare. This is expensive. * * As an optimization, we do a first pass that considers only the * prefix of the strings that is entirely 7-bit. Within this, we * check whether they have the same value. * * Hopefully this will often give the answer without needing to copy. * In particular it should speed comparisons to literal ascii strings * or comparisons of strings that are "obviously" different. * * If we find a non-ascii character we fall back to converting via * iconv. * * This should never be slower than convering the whole thing, and * often faster. * * A different optimization would be to compare for bitwise equality * in the binary encoding. (It would be possible thought hairy to do * both simultaneously.) But in that case if they turn out to be * different, we'd need to restart the whole thing. * * Even better is to implement strcasecmp for each encoding and use a * function pointer. **/ int StrCaseCmp(const char *s, const char *t) { const char * ps, * pt; size_t size; smb_ucs2_t *buffer_s, *buffer_t; int ret; for (ps = s, pt = t; ; ps++, pt++) { char us, ut; if (!*ps && !*pt) return 0; /* both ended */ else if (!*ps) return -1; /* s is a prefix */ else if (!*pt) return +1; /* t is a prefix */ else if ((*ps & 0x80) || (*pt & 0x80)) /* not ascii anymore, do it the hard way from here on in */ break; us = toupper(*ps); ut = toupper(*pt); if (us == ut) continue; else if (us < ut) return -1; else if (us > ut) return +1; } size = push_ucs2_allocate(&buffer_s, s); if (size == (size_t)-1) { return strcmp(s, t); /* Not quite the right answer, but finding the right one under this failure case is expensive, and it's pretty close */ } size = push_ucs2_allocate(&buffer_t, t); if (size == (size_t)-1) { SAFE_FREE(buffer_s); return strcmp(s, t); /* Not quite the right answer, but finding the right one under this failure case is expensive, and it's pretty close */ } ret = strcasecmp_w(buffer_s, buffer_t); SAFE_FREE(buffer_s); SAFE_FREE(buffer_t); return ret; } /** Case insensitive string compararison, length limited. **/ int StrnCaseCmp(const char *s, const char *t, size_t n) { pstring buf1, buf2; unix_strupper(s, strlen(s)+1, buf1, sizeof(buf1)); unix_strupper(t, strlen(t)+1, buf2, sizeof(buf2)); return strncmp(buf1,buf2,n); } /** * Compare 2 strings. * * @note The comparison is case-insensitive. **/ BOOL strequal(const char *s1, const char *s2) { if (s1 == s2) return(True); if (!s1 || !s2) return(False); return(StrCaseCmp(s1,s2)==0); } /** * Compare 2 strings up to and including the nth char. * * @note The comparison is case-insensitive. **/ BOOL strnequal(const char *s1,const char *s2,size_t n) { if (s1 == s2) return(True); if (!s1 || !s2 || !n) return(False); return(StrnCaseCmp(s1,s2,n)==0); } /** Compare 2 strings (case sensitive). **/ BOOL strcsequal(const char *s1,const char *s2) { if (s1 == s2) return(True); if (!s1 || !s2) return(False); return(strcmp(s1,s2)==0); } /** Do a case-insensitive, whitespace-ignoring string compare. **/ int strwicmp(const char *psz1, const char *psz2) { /* if BOTH strings are NULL, return TRUE, if ONE is NULL return */ /* appropriate value. */ if (psz1 == psz2) return (0); else if (psz1 == NULL) return (-1); else if (psz2 == NULL) return (1); /* sync the strings on first non-whitespace */ while (1) { while (isspace((int)*psz1)) psz1++; while (isspace((int)*psz2)) psz2++; if (toupper(*psz1) != toupper(*psz2) || *psz1 == '\0' || *psz2 == '\0') break; psz1++; psz2++; } return (*psz1 - *psz2); } /** Convert a string to upper case, but don't modify it. **/ char *strupper_static(const char *s) { static pstring str; pstrcpy(str, s); strupper_m(str); return str; } /** Convert a string to "normal" form. **/ void strnorm(char *s) { extern int case_default; if (case_default == CASE_UPPER) strupper_m(s); else strlower_m(s); } /** Check if a string is in "normal" case. **/ BOOL strisnormal(const char *s) { extern int case_default; if (case_default == CASE_UPPER) return(!strhaslower(s)); return(!strhasupper(s)); } /** String replace. NOTE: oldc and newc must be 7 bit characters **/ void string_replace(pstring s,char oldc,char newc) { unsigned char *p; /* this is quite a common operation, so we want it to be fast. We optimise for the ascii case, knowing that all our supported multi-byte character sets are ascii-compatible (ie. they match for the first 128 chars) */ for (p = (unsigned char *)s; *p; p++) { if (*p & 0x80) /* mb string - slow path. */ break; if (*p == oldc) *p = newc; } if (!*p) return; /* Slow (mb) path. */ push_ucs2(NULL, tmpbuf, p, sizeof(tmpbuf), STR_TERMINATE); string_replace_w(tmpbuf, UCS2_CHAR(oldc), UCS2_CHAR(newc)); pull_ucs2(NULL, p, tmpbuf, -1, sizeof(tmpbuf), STR_TERMINATE); } /** Skip past some strings in a buffer. **/ char *skip_string(char *buf,size_t n) { while (n--) buf += strlen(buf) + 1; return(buf); } /** Count the number of characters in a string. Normally this will be the same as the number of bytes in a string for single byte strings, but will be different for multibyte. **/ size_t str_charnum(const char *s) { uint16 tmpbuf2[sizeof(pstring)]; push_ucs2(NULL, tmpbuf2,s, sizeof(tmpbuf2), STR_TERMINATE); return strlen_w(tmpbuf2); } /** Count the number of characters in a string. Normally this will be the same as the number of bytes in a string for single byte strings, but will be different for multibyte. **/ size_t str_ascii_charnum(const char *s) { pstring tmpbuf2; push_ascii(tmpbuf2, s, sizeof(tmpbuf2), STR_TERMINATE); return strlen(tmpbuf2); } BOOL trim_char(char *s,char cfront,char cback) { BOOL ret = False; char *ep; char *fp = s; /* Ignore null or empty strings. */ if (!s || (s[0] == '\0')) return False; if (cfront) { while (*fp && *fp == cfront) fp++; if (!*fp) { /* We ate the string. */ s[0] = '\0'; return True; } if (fp != s) ret = True; } ep = fp + strlen(fp) - 1; if (cback) { /* Attempt ascii only. Bail for mb strings. */ while ((ep >= fp) && (*ep == cback)) { ret = True; if ((ep > fp) && (((unsigned char)ep[-1]) & 0x80)) { /* Could be mb... bail back to tim_string. */ char fs[2], bs[2]; if (cfront) { fs[0] = cfront; fs[1] = '\0'; } bs[0] = cback; bs[1] = '\0'; return trim_string(s, cfront ? fs : NULL, bs); } else { ep--; } } if (ep < fp) { /* We ate the string. */ s[0] = '\0'; return True; } } ep[1] = '\0'; memmove(s, fp, ep-fp+2); return ret; } /** Trim the specified elements off the front and back of a string. **/ BOOL trim_string(char *s,const char *front,const char *back) { BOOL ret = False; size_t front_len; size_t back_len; size_t len; /* Ignore null or empty strings. */ if (!s || (s[0] == '\0')) return False; front_len = front? strlen(front) : 0; back_len = back? strlen(back) : 0; len = strlen(s); if (front_len) { while (len && strncmp(s, front, front_len)==0) { /* Must use memmove here as src & dest can * easily overlap. Found by valgrind. JRA. */ memmove(s, s+front_len, (len-front_len)+1); len -= front_len; ret=True; } } if (back_len) { while ((len >= back_len) && strncmp(s+len-back_len,back,back_len)==0) { s[len-back_len]='\0'; len -= back_len; ret=True; } } return ret; } /** Does a string have any uppercase chars in it? **/ BOOL strhasupper(const char *s) { smb_ucs2_t *ptr; push_ucs2(NULL, tmpbuf,s, sizeof(tmpbuf), STR_TERMINATE); for(ptr=tmpbuf;*ptr;ptr++) if(isupper_w(*ptr)) return True; return(False); } /** Does a string have any lowercase chars in it? **/ BOOL strhaslower(const char *s) { smb_ucs2_t *ptr; push_ucs2(NULL, tmpbuf,s, sizeof(tmpbuf), STR_TERMINATE); for(ptr=tmpbuf;*ptr;ptr++) if(islower_w(*ptr)) return True; return(False); } /** Find the number of 'c' chars in a string **/ size_t count_chars(const char *s,char c) { smb_ucs2_t *ptr; int count; push_ucs2(NULL, tmpbuf,s, sizeof(tmpbuf), STR_TERMINATE); for(count=0,ptr=tmpbuf;*ptr;ptr++) if(*ptr==UCS2_CHAR(c)) count++; return(count); } /** Safe string copy into a known length string. maxlength does not include the terminating zero. **/ char *safe_strcpy_fn(const char *fn, int line, char *dest,const char *src, size_t maxlength) { size_t len; if (!dest) { DEBUG(0,("ERROR: NULL dest in safe_strcpy\n")); return NULL; } #ifdef DEVELOPER clobber_region(fn,line,dest, maxlength+1); #endif if (!src) { *dest = 0; return dest; } len = strnlen(src, maxlength+1); if (len > maxlength) { DEBUG(0,("ERROR: string overflow by %u (%u - %u) in safe_strcpy [%.50s]\n", (unsigned int)(len-maxlength), len, maxlength, src)); len = maxlength; } memmove(dest, src, len); dest[len] = 0; return dest; } /** Safe string cat into a string. maxlength does not include the terminating zero. **/ char *safe_strcat_fn(const char *fn, int line, char *dest, const char *src, size_t maxlength) { size_t src_len, dest_len; if (!dest) { DEBUG(0,("ERROR: NULL dest in safe_strcat\n")); return NULL; } if (!src) return dest; src_len = strnlen(src, maxlength + 1); dest_len = strnlen(dest, maxlength + 1); #ifdef DEVELOPER clobber_region(fn, line, dest + dest_len, maxlength + 1 - dest_len); #endif if (src_len + dest_len > maxlength) { DEBUG(0,("ERROR: string overflow by %d in safe_strcat [%.50s]\n", (int)(src_len + dest_len - maxlength), src)); if (maxlength > dest_len) { memcpy(&dest[dest_len], src, maxlength - dest_len); } dest[maxlength] = 0; return NULL; } memcpy(&dest[dest_len], src, src_len); dest[dest_len + src_len] = 0; return dest; } /** Paranoid strcpy into a buffer of given length (includes terminating zero. Strips out all but 'a-Z0-9' and the character in other_safe_chars and replaces with '_'. Deliberately does *NOT* check for multibyte characters. Don't change it ! **/ char *alpha_strcpy_fn(const char *fn, int line, char *dest, const char *src, const char *other_safe_chars, size_t maxlength) { size_t len, i; #ifdef DEVELOPER clobber_region(fn, line, dest, maxlength); #endif if (!dest) { DEBUG(0,("ERROR: NULL dest in alpha_strcpy\n")); return NULL; } if (!src) { *dest = 0; return dest; } len = strlen(src); if (len >= maxlength) len = maxlength - 1; if (!other_safe_chars) other_safe_chars = ""; for(i = 0; i < len; i++) { int val = (src[i] & 0xff); if (isupper(val) || islower(val) || isdigit(val) || strchr_m(other_safe_chars, val)) dest[i] = src[i]; else dest[i] = '_'; } dest[i] = '\0'; return dest; } /** Like strncpy but always null terminates. Make sure there is room! The variable n should always be one less than the available size. **/ char *StrnCpy_fn(const char *fn, int line,char *dest,const char *src,size_t n) { char *d = dest; #ifdef DEVELOPER clobber_region(fn, line, dest, n+1); #endif if (!dest) return(NULL); if (!src) { *dest = 0; return(dest); } while (n-- && (*d = *src)) { d++; src++; } *d = 0; return(dest); } #if 0 /** Like strncpy but copies up to the character marker. always null terminates. returns a pointer to the character marker in the source string (src). **/ static char *strncpyn(char *dest, const char *src, size_t n, char c) { char *p; size_t str_len; #ifdef DEVELOPER clobber_region(dest, n+1); #endif p = strchr_m(src, c); if (p == NULL) { DEBUG(5, ("strncpyn: separator character (%c) not found\n", c)); return NULL; } str_len = PTR_DIFF(p, src); strncpy(dest, src, MIN(n, str_len)); dest[str_len] = '\0'; return p; } #endif /** Routine to get hex characters and turn them into a 16 byte array. the array can be variable length, and any non-hex-numeric characters are skipped. "0xnn" or "0Xnn" is specially catered for. valid examples: "0A5D15"; "0x15, 0x49, 0xa2"; "59\ta9\te3\n" **/ size_t strhex_to_str(char *p, size_t len, const char *strhex) { size_t i; size_t num_chars = 0; unsigned char lonybble, hinybble; const char *hexchars = "0123456789ABCDEF"; char *p1 = NULL, *p2 = NULL; for (i = 0; i < len && strhex[i] != 0; i++) { if (strnequal(hexchars, "0x", 2)) { i++; /* skip two chars */ continue; } if (!(p1 = strchr_m(hexchars, toupper(strhex[i])))) break; i++; /* next hex digit */ if (!(p2 = strchr_m(hexchars, toupper(strhex[i])))) break; /* get the two nybbles */ hinybble = PTR_DIFF(p1, hexchars); lonybble = PTR_DIFF(p2, hexchars); p[num_chars] = (hinybble << 4) | lonybble; num_chars++; p1 = NULL; p2 = NULL; } return num_chars; } /** * Routine to print a buffer as HEX digits, into an allocated string. */ void hex_encode(const unsigned char *buff_in, size_t len, char **out_hex_buffer) { int i; char *hex_buffer; *out_hex_buffer = smb_xmalloc((len*2)+1); hex_buffer = *out_hex_buffer; for (i = 0; i < len; i++) slprintf(&hex_buffer[i*2], 3, "%02X", buff_in[i]); } /** Check if a string is part of a list. **/ BOOL in_list(char *s,char *list,BOOL casesensitive) { pstring tok; const char *p=list; if (!list) return(False); while (next_token(&p,tok,LIST_SEP,sizeof(tok))) { if (casesensitive) { if (strcmp(tok,s) == 0) return(True); } else { if (StrCaseCmp(tok,s) == 0) return(True); } } return(False); } /* this is used to prevent lots of mallocs of size 1 */ static char *null_string = NULL; /** Set a string value, allocing the space for the string **/ static BOOL string_init(char **dest,const char *src) { size_t l; if (!src) src = ""; l = strlen(src); if (l == 0) { if (!null_string) { if((null_string = (char *)malloc(1)) == NULL) { DEBUG(0,("string_init: malloc fail for null_string.\n")); return False; } *null_string = 0; } *dest = null_string; } else { (*dest) = strdup(src); if ((*dest) == NULL) { DEBUG(0,("Out of memory in string_init\n")); return False; } } return(True); } /** Free a string value. **/ void string_free(char **s) { if (!s || !(*s)) return; if (*s == null_string) *s = NULL; SAFE_FREE(*s); } /** Set a string value, deallocating any existing space, and allocing the space for the string **/ BOOL string_set(char **dest,const char *src) { string_free(dest); return(string_init(dest,src)); } /** Substitute a string for a pattern in another string. Make sure there is enough room! This routine looks for pattern in s and replaces it with insert. It may do multiple replacements. Any of " ; ' $ or ` in the insert string are replaced with _ if len==0 then the string cannot be extended. This is different from the old use of len==0 which was for no length checks to be done. **/ void string_sub(char *s,const char *pattern, const char *insert, size_t len) { char *p; ssize_t ls,lp,li, i; if (!insert || !pattern || !*pattern || !s) return; ls = (ssize_t)strlen(s); lp = (ssize_t)strlen(pattern); li = (ssize_t)strlen(insert); if (len == 0) len = ls + 1; /* len is number of *bytes* */ while (lp <= ls && (p = strstr(s,pattern))) { if (ls + (li-lp) >= len) { DEBUG(0,("ERROR: string overflow by %d in string_sub(%.50s, %d)\n", (int)(ls + (li-lp) - len), pattern, (int)len)); break; } if (li != lp) { memmove(p+li,p+lp,strlen(p+lp)+1); } for (i=0;i 0) { int offset = PTR_DIFF(s,string); char *t = Realloc(string, ls + ld + 1); if (!t) { DEBUG(0, ("realloc_string_sub: out of memory!\n")); SAFE_FREE(in); return NULL; } string = t; p = t + offset + (p - s); } if (li != lp) { memmove(p+li,p+lp,strlen(p+lp)+1); } memcpy(p, in, li); s = p + li; ls += ld; } SAFE_FREE(in); return string; } /** Similar to string_sub() but allows for any character to be substituted. Use with caution! if len==0 then the string cannot be extended. This is different from the old use of len==0 which was for no length checks to be done. **/ void all_string_sub(char *s,const char *pattern,const char *insert, size_t len) { char *p; ssize_t ls,lp,li; if (!insert || !pattern || !s) return; ls = (ssize_t)strlen(s); lp = (ssize_t)strlen(pattern); li = (ssize_t)strlen(insert); if (!*pattern) return; if (len == 0) len = ls + 1; /* len is number of *bytes* */ while (lp <= ls && (p = strstr(s,pattern))) { if (ls + (li-lp) >= len) { DEBUG(0,("ERROR: string overflow by %d in all_string_sub(%.50s, %d)\n", (int)(ls + (li-lp) - len), pattern, (int)len)); break; } if (li != lp) { memmove(p+li,p+lp,strlen(p+lp)+1); } memcpy(p, insert, li); s = p + li; ls += (li-lp); } } /** Similar to all_string_sub but for unicode strings. Return a new allocated unicode string. similar to string_sub() but allows for any character to be substituted. Use with caution! **/ static smb_ucs2_t *all_string_sub_w(const smb_ucs2_t *s, const smb_ucs2_t *pattern, const smb_ucs2_t *insert) { smb_ucs2_t *r, *rp; const smb_ucs2_t *sp; size_t lr, lp, li, lt; if (!insert || !pattern || !*pattern || !s) return NULL; lt = (size_t)strlen_w(s); lp = (size_t)strlen_w(pattern); li = (size_t)strlen_w(insert); if (li > lp) { const smb_ucs2_t *st = s; int ld = li - lp; while ((sp = strstr_w(st, pattern))) { st = sp + lp; lt += ld; } } r = rp = (smb_ucs2_t *)malloc((lt + 1)*(sizeof(smb_ucs2_t))); if (!r) { DEBUG(0, ("all_string_sub_w: out of memory!\n")); return NULL; } while ((sp = strstr_w(s, pattern))) { memcpy(rp, s, (sp - s)); rp += ((sp - s) / sizeof(smb_ucs2_t)); memcpy(rp, insert, (li * sizeof(smb_ucs2_t))); s = sp + lp; rp += li; } lr = ((rp - r) / sizeof(smb_ucs2_t)); if (lr < lt) { memcpy(rp, s, ((lt - lr) * sizeof(smb_ucs2_t))); rp += (lt - lr); } *rp = 0; return r; } smb_ucs2_t *all_string_sub_wa(smb_ucs2_t *s, const char *pattern, const char *insert) { wpstring p, i; if (!insert || !pattern || !s) return NULL; push_ucs2(NULL, p, pattern, sizeof(wpstring) - 1, STR_TERMINATE); push_ucs2(NULL, i, insert, sizeof(wpstring) - 1, STR_TERMINATE); return all_string_sub_w(s, p, i); } #if 0 /** Splits out the front and back at a separator. **/ static void split_at_last_component(char *path, char *front, char sep, char *back) { char *p = strrchr_m(path, sep); if (p != NULL) *p = 0; if (front != NULL) pstrcpy(front, path); if (p != NULL) { if (back != NULL) pstrcpy(back, p+1); *p = '\\'; } else { if (back != NULL) back[0] = 0; } } #endif /** Write an octal as a string. **/ const char *octal_string(int i) { static char ret[64]; if (i == -1) return "-1"; slprintf(ret, sizeof(ret)-1, "0%o", i); return ret; } /** Truncate a string at a specified length. **/ char *string_truncate(char *s, unsigned int length) { if (s && strlen(s) > length) s[length] = 0; return s; } /** Strchr and strrchr_m are very hard to do on general multi-byte strings. We convert via ucs2 for now. **/ char *strchr_m(const char *s, char c) { wpstring ws; pstring s2; smb_ucs2_t *p; /* this is quite a common operation, so we want it to be fast. We optimise for the ascii case, knowing that all our supported multi-byte character sets are ascii-compatible (ie. they match for the first 128 chars) */ while (*s && (((unsigned char)s[0]) & 0x80)) { if (*s == c) return s; } if (!*s) return NULL; push_ucs2(NULL, ws, s, sizeof(ws), STR_TERMINATE); p = strchr_w(ws, UCS2_CHAR(c)); if (!p) return NULL; *p = 0; pull_ucs2_pstring(s2, ws); return (char *)(s+strlen(s2)); } char *strrchr_m(const char *s, char c) { /* this is quite a common operation, so we want it to be fast. We optimise for the ascii case, knowing that all our supported multi-byte character sets are ascii-compatible (ie. they match for the first 128 chars). Also, in Samba we only search for ascii characters in 'c' and that in all mb character sets with a compound character containing c, if 'c' is not a match at position p, then p[-1] > 0x7f. JRA. */ { size_t len = strlen(s); const char *cp = s; BOOL got_mb = False; if (len == 0) return NULL; cp += (len - 1); do { if (c == *cp) { /* Could be a match. Part of a multibyte ? */ if ((cp > s) && (((unsigned char)cp[-1]) & 0x80)) { /* Yep - go slow :-( */ got_mb = True; break; } /* No - we have a match ! */ return cp; } } while (cp-- != s); if (!got_mb) return NULL; } /* String contained a non-ascii char. Slow path. */ { wpstring ws; pstring s2; smb_ucs2_t *p; push_ucs2(NULL, ws, s, sizeof(ws), STR_TERMINATE); p = strrchr_w(ws, UCS2_CHAR(c)); if (!p) return NULL; *p = 0; pull_ucs2_pstring(s2, ws); return (char *)(s+strlen(s2)); } } /*********************************************************************** Return the equivalent of doing strrchr 'n' times - always going backwards. ***********************************************************************/ char *strnrchr_m(const char *s, char c, unsigned int n) { wpstring ws; pstring s2; smb_ucs2_t *p; push_ucs2(NULL, ws, s, sizeof(ws), STR_TERMINATE); p = strnrchr_w(ws, UCS2_CHAR(c), n); if (!p) return NULL; *p = 0; pull_ucs2_pstring(s2, ws); return (char *)(s+strlen(s2)); } /** Convert a string to lower case. **/ void strlower_m(char *s) { /* this is quite a common operation, so we want it to be fast. We optimise for the ascii case, knowing that all our supported multi-byte character sets are ascii-compatible (ie. they match for the first 128 chars) */ while (*s && !(((unsigned char)s[0]) & 0x7F)) { *s = tolower((unsigned char)*s); s++; } if (!*s) return; /* I assume that lowercased string takes the same number of bytes * as source string even in UTF-8 encoding. (VIV) */ unix_strlower(s,strlen(s)+1,s,strlen(s)+1); } /** Convert a string to upper case. **/ void strupper_m(char *s) { /* this is quite a common operation, so we want it to be fast. We optimise for the ascii case, knowing that all our supported multi-byte character sets are ascii-compatible (ie. they match for the first 128 chars) */ while (*s && !(((unsigned char)s[0]) & 0x7F)) { *s = toupper((unsigned char)*s); s++; } if (!*s) return; /* I assume that lowercased string takes the same number of bytes * as source string even in multibyte encoding. (VIV) */ unix_strupper(s,strlen(s)+1,s,strlen(s)+1); } /** Return a RFC2254 binary string representation of a buffer. Used in LDAP filters. Caller must free. **/ char *binary_string(char *buf, int len) { char *s; int i, j; const char *hex = "0123456789ABCDEF"; s = malloc(len * 3 + 1); if (!s) return NULL; for (j=i=0;i> 4]; s[j+2] = hex[((unsigned char)buf[i]) & 0xF]; j += 3; } s[j] = 0; return s; } /** Just a typesafety wrapper for snprintf into a pstring. **/ int pstr_sprintf(pstring s, const char *fmt, ...) { va_list ap; int ret; va_start(ap, fmt); ret = vsnprintf(s, PSTRING_LEN, fmt, ap); va_end(ap); return ret; } /** Just a typesafety wrapper for snprintf into a fstring. **/ int fstr_sprintf(fstring s, const char *fmt, ...) { va_list ap; int ret; va_start(ap, fmt); ret = vsnprintf(s, FSTRING_LEN, fmt, ap); va_end(ap); return ret; } #ifndef HAVE_STRNDUP /** Some platforms don't have strndup. **/ char *strndup(const char *s, size_t n) { char *ret; n = strnlen(s, n); ret = malloc(n+1); if (!ret) return NULL; memcpy(ret, s, n); ret[n] = 0; return ret; } #endif #ifndef HAVE_STRNLEN /** Some platforms don't have strnlen **/ size_t strnlen(const char *s, size_t n) { int i; for (i=0; s[i] && iip), service->port); SAFE_FREE(*ipstr_list); } else { asprintf(&new_ipstr, "%s:%d", inet_ntoa(service->ip), service->port); } *ipstr_list = new_ipstr; return *ipstr_list; } /** * Allocate and initialise an ipstr list using ip adresses * passed as arguments. * * @param ipstr_list pointer to string meant to be allocated and set * @param ip_list array of ip addresses to place in the list * @param ip_count number of addresses stored in ip_list * @return pointer to allocated ip string **/ char* ipstr_list_make(char** ipstr_list, const struct ip_service* ip_list, int ip_count) { int i; /* arguments checking */ if (!ip_list && !ipstr_list) return 0; *ipstr_list = NULL; /* process ip addresses given as arguments */ for (i = 0; i < ip_count; i++) *ipstr_list = ipstr_list_add(ipstr_list, &ip_list[i]); return (*ipstr_list); } /** * Parse given ip string list into array of ip addresses * (as ip_service structures) * e.g. 192.168.1.100:389,192.168.1.78, ... * * @param ipstr ip string list to be parsed * @param ip_list pointer to array of ip addresses which is * allocated by this function and must be freed by caller * @return number of succesfully parsed addresses **/ int ipstr_list_parse(const char* ipstr_list, struct ip_service **ip_list) { fstring token_str; size_t count; int i; if (!ipstr_list || !ip_list) return 0; count = count_chars(ipstr_list, IPSTR_LIST_CHAR) + 1; if ( (*ip_list = (struct ip_service*)malloc(count * sizeof(struct ip_service))) == NULL ) { DEBUG(0,("ipstr_list_parse: malloc failed for %lu entries\n", (unsigned long)count)); return 0; } for ( i=0; next_token(&ipstr_list, token_str, IPSTR_LIST_SEP, FSTRING_LEN) && i= '0' && c1 <= '9') c1 = c1 - '0'; else if (c1 >= 'A' && c1 <= 'F') c1 = 10 + c1 - 'A'; else if (c1 >= 'a' && c1 <= 'f') c1 = 10 + c1 - 'a'; else {p++; continue;} if (c2 >= '0' && c2 <= '9') c2 = c2 - '0'; else if (c2 >= 'A' && c2 <= 'F') c2 = 10 + c2 - 'A'; else if (c2 >= 'a' && c2 <= 'f') c2 = 10 + c2 - 'a'; else {p++; continue;} *p = (c1<<4) | c2; memmove(p+1, p+3, strlen(p+3)+1); p++; } } static const char *b64 = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/"; /** * Decode a base64 string into a DATA_BLOB - simple and slow algorithm **/ DATA_BLOB base64_decode_data_blob(const char *s) { int bit_offset, byte_offset, idx, i, n; DATA_BLOB decoded = data_blob(s, strlen(s)+1); unsigned char *d = decoded.data; char *p; n=i=0; while (*s && (p=strchr_m(b64,*s))) { idx = (int)(p - b64); byte_offset = (i*6)/8; bit_offset = (i*6)%8; d[byte_offset] &= ~((1<<(8-bit_offset))-1); if (bit_offset < 3) { d[byte_offset] |= (idx << (2-bit_offset)); n = byte_offset+1; } else { d[byte_offset] |= (idx >> (bit_offset-2)); d[byte_offset+1] = 0; d[byte_offset+1] |= (idx << (8-(bit_offset-2))) & 0xFF; n = byte_offset+2; } s++; i++; } /* fix up length */ decoded.length = n; return decoded; } /** * Decode a base64 string in-place - wrapper for the above **/ void base64_decode_inplace(char *s) { DATA_BLOB decoded = base64_decode_data_blob(s); memcpy(s, decoded.data, decoded.length); /* null terminate */ s[decoded.length] = '\0'; data_blob_free(&decoded); } /** * Encode a base64 string into a malloc()ed string caller to free. * *From SQUID: adopted from http://ftp.sunet.se/pub2/gnu/vm/base64-encode.c with adjustments **/ char * base64_encode_data_blob(DATA_BLOB data) { int bits = 0; int char_count = 0; size_t out_cnt = 0; size_t len = data.length; size_t output_len = data.length * 2; char *result = malloc(output_len); /* get us plenty of space */ while (len-- && out_cnt < (data.length * 2) - 5) { int c = (unsigned char) *(data.data++); bits += c; char_count++; if (char_count == 3) { result[out_cnt++] = b64[bits >> 18]; result[out_cnt++] = b64[(bits >> 12) & 0x3f]; result[out_cnt++] = b64[(bits >> 6) & 0x3f]; result[out_cnt++] = b64[bits & 0x3f]; bits = 0; char_count = 0; } else { bits <<= 8; } } if (char_count != 0) { bits <<= 16 - (8 * char_count); result[out_cnt++] = b64[bits >> 18]; result[out_cnt++] = b64[(bits >> 12) & 0x3f]; if (char_count == 1) { result[out_cnt++] = '='; result[out_cnt++] = '='; } else { result[out_cnt++] = b64[(bits >> 6) & 0x3f]; result[out_cnt++] = '='; } } result[out_cnt] = '\0'; /* terminate */ return result; } /* read a SMB_BIG_UINT from a string */ SMB_BIG_UINT STR_TO_SMB_BIG_UINT(const char *nptr, const char **entptr) { SMB_BIG_UINT val = -1; const char *p = nptr; while (p && *p && isspace(*p)) p++; #ifdef LARGE_SMB_OFF_T sscanf(p,"%llu",&val); #else /* LARGE_SMB_OFF_T */ sscanf(p,"%lu",&val); #endif /* LARGE_SMB_OFF_T */ if (entptr) { while (p && *p && isdigit(*p)) p++; *entptr = p; } return val; }