/* This is the byte-counted string class for rsyslog. It is a replacement
* for classical \0 terminated string functions. We introduce it in
* the hope it will make the program more secure, obtain some performance
* and, most importantly, lay they foundation for syslog-protocol, which
* requires strings to be able to handle embedded \0 characters.
* Please see syslogd.c for license information.
* All functions in this "class" start with rsCStr (rsyslog Counted String).
* begun 2005-09-07 rgerhards
* did some optimization (read: bugs!) rgerhards, 2009-06-16
*
* Copyright (C) 2007-2009 by Rainer Gerhards and Adiscon GmbH
*
* This file is part of the rsyslog runtime library.
*
* The rsyslog runtime library is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* The rsyslog runtime library 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with the rsyslog runtime library. If not, see .
*
* A copy of the GPL can be found in the file "COPYING" in this distribution.
* A copy of the LGPL can be found in the file "COPYING.LESSER" in this distribution.
*/
#include "config.h"
#include
#include
#include
#include
#include
#include
#include "rsyslog.h"
#include "stringbuf.h"
#include "srUtils.h"
#include "regexp.h"
#include "obj.h"
uchar* rsCStrGetSzStr(cstr_t *pThis);
/* ################################################################# *
* private members *
* ################################################################# */
/* static data */
DEFobjCurrIf(obj)
DEFobjCurrIf(regexp)
/* ################################################################# *
* public members *
* ################################################################# */
rsRetVal cstrConstruct(cstr_t **ppThis)
{
DEFiRet;
cstr_t *pThis;
ASSERT(ppThis != NULL);
CHKmalloc(pThis = (cstr_t*) calloc(1, sizeof(cstr_t)));
rsSETOBJTYPE(pThis, OIDrsCStr);
pThis->pBuf = NULL;
pThis->pszBuf = NULL;
pThis->iBufSize = 0;
pThis->iStrLen = 0;
*ppThis = pThis;
finalize_it:
RETiRet;
}
/* construct from sz string
* rgerhards 2005-09-15
*/
rsRetVal rsCStrConstructFromszStr(cstr_t **ppThis, uchar *sz)
{
DEFiRet;
cstr_t *pThis;
assert(ppThis != NULL);
CHKiRet(rsCStrConstruct(&pThis));
pThis->iBufSize = pThis->iStrLen = strlen((char *) sz);
if((pThis->pBuf = (uchar*) MALLOC(sizeof(uchar) * pThis->iStrLen)) == NULL) {
RSFREEOBJ(pThis);
ABORT_FINALIZE(RS_RET_OUT_OF_MEMORY);
}
/* we do NOT need to copy the \0! */
memcpy(pThis->pBuf, sz, pThis->iStrLen);
*ppThis = pThis;
finalize_it:
RETiRet;
}
/* construct from es_str_t string
* rgerhards 2010-12-03
*/
rsRetVal cstrConstructFromESStr(cstr_t **ppThis, es_str_t *str)
{
DEFiRet;
cstr_t *pThis;
assert(ppThis != NULL);
CHKiRet(rsCStrConstruct(&pThis));
pThis->iBufSize = pThis->iStrLen = es_strlen(str);
if((pThis->pBuf = (uchar*) MALLOC(sizeof(uchar) * pThis->iStrLen)) == NULL) {
RSFREEOBJ(pThis);
ABORT_FINALIZE(RS_RET_OUT_OF_MEMORY);
}
/* we do NOT need to copy the \0! */
memcpy(pThis->pBuf, es_getBufAddr(str), pThis->iStrLen);
*ppThis = pThis;
finalize_it:
RETiRet;
}
/* construct from CStr object. only the counted string is
* copied, not the szString.
* rgerhards 2005-10-18
*/
rsRetVal rsCStrConstructFromCStr(cstr_t **ppThis, cstr_t *pFrom)
{
DEFiRet;
cstr_t *pThis;
assert(ppThis != NULL);
rsCHECKVALIDOBJECT(pFrom, OIDrsCStr);
CHKiRet(rsCStrConstruct(&pThis));
pThis->iBufSize = pThis->iStrLen = pFrom->iStrLen;
if((pThis->pBuf = (uchar*) MALLOC(sizeof(uchar) * pThis->iStrLen)) == NULL) {
RSFREEOBJ(pThis);
ABORT_FINALIZE(RS_RET_OUT_OF_MEMORY);
}
/* copy properties */
memcpy(pThis->pBuf, pFrom->pBuf, pThis->iStrLen);
*ppThis = pThis;
finalize_it:
RETiRet;
}
void rsCStrDestruct(cstr_t **ppThis)
{
cstr_t *pThis = *ppThis;
free(pThis->pBuf);
free(pThis->pszBuf);
RSFREEOBJ(pThis);
*ppThis = NULL;
}
/* extend the string buffer if its size is insufficient.
* Param iMinNeeded is the minumum free space needed. If it is larger
* than the default alloc increment, space for at least this amount is
* allocated. In practice, a bit more is allocated because we envision that
* some more characters may be added after these.
* rgerhards, 2008-01-07
* changed to utilized realloc() -- rgerhards, 2009-06-16
*/
rsRetVal
rsCStrExtendBuf(cstr_t *pThis, size_t iMinNeeded)
{
uchar *pNewBuf;
size_t iNewSize;
DEFiRet;
/* first compute the new size needed */
if(iMinNeeded > RS_STRINGBUF_ALLOC_INCREMENT) {
/* we allocate "n" ALLOC_INCREMENTs. Usually, that should
* leave some room after the absolutely needed one. It also
* reduces memory fragmentation. Note that all of this are
* integer operations (very important to understand what is
* going on)! Parenthesis are for better readibility.
*/
iNewSize = (iMinNeeded / RS_STRINGBUF_ALLOC_INCREMENT + 1) * RS_STRINGBUF_ALLOC_INCREMENT;
} else {
iNewSize = pThis->iBufSize + RS_STRINGBUF_ALLOC_INCREMENT;
}
iNewSize += pThis->iBufSize; /* add current size */
/* DEV debugging only: dbgprintf("extending string buffer, old %d, new %d\n", pThis->iBufSize, iNewSize); */
CHKmalloc(pNewBuf = (uchar*) realloc(pThis->pBuf, iNewSize * sizeof(uchar)));
pThis->iBufSize = iNewSize;
pThis->pBuf = pNewBuf;
finalize_it:
RETiRet;
}
/* append a string of known length. In this case, we make sure we do at most
* one additional memory allocation.
* I optimized this function to use memcpy(), among others. Consider it a
* rewrite (which may be good to know in case of bugs) -- rgerhards, 2008-01-07
*/
rsRetVal rsCStrAppendStrWithLen(cstr_t *pThis, uchar* psz, size_t iStrLen)
{
DEFiRet;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
assert(psz != NULL);
/* does the string fit? */
if(pThis->iStrLen + iStrLen > pThis->iBufSize) {
CHKiRet(rsCStrExtendBuf(pThis, iStrLen)); /* need more memory! */
}
/* ok, now we always have sufficient continues memory to do a memcpy() */
memcpy(pThis->pBuf + pThis->iStrLen, psz, iStrLen);
pThis->iStrLen += iStrLen;
finalize_it:
RETiRet;
}
/* changed to be a wrapper to rsCStrAppendStrWithLen() so that
* we can save some time when we have the length but do not
* need to change existing code.
* rgerhards, 2007-07-03
*/
rsRetVal rsCStrAppendStr(cstr_t *pThis, uchar* psz)
{
return rsCStrAppendStrWithLen(pThis, psz, strlen((char*) psz));
}
/* append the contents of one cstr_t object to another
* rgerhards, 2008-02-25
*/
rsRetVal cstrAppendCStr(cstr_t *pThis, cstr_t *pstrAppend)
{
return rsCStrAppendStrWithLen(pThis, pstrAppend->pBuf, pstrAppend->iStrLen);
}
rsRetVal rsCStrAppendInt(cstr_t *pThis, long i)
{
DEFiRet;
uchar szBuf[32];
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
CHKiRet(srUtilItoA((char*) szBuf, sizeof(szBuf), i));
iRet = rsCStrAppendStr(pThis, szBuf);
finalize_it:
RETiRet;
}
/* Sets the string object to the classigal sz-string provided.
* Any previously stored vlaue is discarded. If a NULL pointer
* the the new value (pszNew) is provided, an empty string is
* created (this is NOT an error!).
* rgerhards, 2005-10-18
*/
rsRetVal rsCStrSetSzStr(cstr_t *pThis, uchar *pszNew)
{
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
free(pThis->pBuf);
free(pThis->pszBuf);
if(pszNew == NULL) {
pThis->iStrLen = 0;
pThis->iBufSize = 0;
pThis->pBuf = NULL;
pThis->pszBuf = NULL;
} else {
pThis->iStrLen = strlen((char*)pszNew);
pThis->iBufSize = pThis->iStrLen;
pThis->pszBuf = NULL;
/* now save the new value */
if((pThis->pBuf = (uchar*) MALLOC(sizeof(uchar) * pThis->iStrLen)) == NULL) {
RSFREEOBJ(pThis);
return RS_RET_OUT_OF_MEMORY;
}
/* we do NOT need to copy the \0! */
memcpy(pThis->pBuf, pszNew, pThis->iStrLen);
}
return RS_RET_OK;
}
/* Converts the CStr object to a classical sz string and returns that.
* Same restrictions as in rsCStrGetSzStr() applies (see there!). This
* function here guarantees that a valid string is returned, even if
* the CStr object currently holds a NULL pointer string buffer. If so,
* "" is returned.
* rgerhards 2005-10-19
* WARNING: The returned pointer MUST NOT be freed, as it may be
* obtained from that constant memory pool (in case of NULL!)
*/
uchar* rsCStrGetSzStrNoNULL(cstr_t *pThis)
{
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
if(pThis->pBuf == NULL)
return (uchar*) "";
else
return rsCStrGetSzStr(pThis);
}
/* Converts the CStr object to a classical zero-terminated C string
* and returns that string. The caller must not free it and must not
* destroy the CStr object as long as the ascii string is used.
* This function may return NULL, if the string is currently NULL. This
* is a feature, not a bug. If you need non-NULL in any case, use
* rsCStrGetSzStrNoNULL() instead.
* rgerhards, 2005-09-15
*/
uchar* rsCStrGetSzStr(cstr_t *pThis)
{
size_t i;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
if(pThis->pBuf != NULL)
if(pThis->pszBuf == NULL) {
/* we do not yet have a usable sz version - so create it... */
if((pThis->pszBuf = MALLOC((pThis->iStrLen + 1) * sizeof(uchar))) == NULL) {
/* TODO: think about what to do - so far, I have no bright
* idea... rgerhards 2005-09-07
*/
}
else { /* we can create the sz String */
/* now copy it while doing a sanity check. The string might contain a
* \0 byte. There is no way how a sz string can handle this. For
* the time being, we simply replace it with space - something that
* could definitely be improved (TODO).
* 2005-09-15 rgerhards
*/
for(i = 0 ; i < pThis->iStrLen ; ++i) {
if(pThis->pBuf[i] == '\0')
pThis->pszBuf[i] = ' ';
else
pThis->pszBuf[i] = pThis->pBuf[i];
}
/* write terminator... */
pThis->pszBuf[i] = '\0';
}
}
return(pThis->pszBuf);
}
/* Converts the CStr object to a classical zero-terminated C string,
* returns that string and destroys the CStr object. The returned string
* MUST be freed by the caller. The function might return NULL if
* no memory can be allocated.
*
* This is the NEW replacement for rsCStrConvSzStrAndDestruct which does
* no longer utilize a special buffer but soley works on pBuf (and also
* assumes that cstrFinalize had been called).
*
* Parameters are as follows:
* pointer to the object, pointer to string-pointer to receive string and
* bRetNULL: 0 - must not return NULL on empty string, return "" in that
* case, 1 - return NULL instead of an empty string.
* PLEASE NOTE: the caller must free the memory returned in ppSz in any case
* (except, of course, if it is NULL).
*/
rsRetVal cstrConvSzStrAndDestruct(cstr_t *pThis, uchar **ppSz, int bRetNULL)
{
DEFiRet;
uchar* pRetBuf;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
assert(ppSz != NULL);
assert(bRetNULL == 0 || bRetNULL == 1);
if(pThis->pBuf == NULL) {
if(bRetNULL == 0) {
CHKmalloc(pRetBuf = MALLOC(sizeof(uchar)));
*pRetBuf = '\0';
} else {
pRetBuf = NULL;
}
} else
pRetBuf = pThis->pBuf;
*ppSz = pRetBuf;
finalize_it:
/* We got it, now free the object ourselfs. Please note
* that we can NOT use the rsCStrDestruct function as it would
* also free the sz String buffer, which we pass on to the user.
*/
RSFREEOBJ(pThis);
RETiRet;
}
/* return the length of the current string
* 2005-09-09 rgerhards
* Please note: this is only a function in a debug build.
* For release builds, it is a macro defined in stringbuf.h.
* This is due to performance reasons.
*/
#ifndef NDEBUG
int cstrLen(cstr_t *pThis)
{
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
return(pThis->iStrLen);
}
#endif
/* Truncate characters from the end of the string.
* rgerhards 2005-09-15
*/
rsRetVal rsCStrTruncate(cstr_t *pThis, size_t nTrunc)
{
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
if(pThis->iStrLen < nTrunc)
return RS_TRUNCAT_TOO_LARGE;
pThis->iStrLen -= nTrunc;
if(pThis->pszBuf != NULL) {
/* in this case, we adjust the psz representation
* by writing a new \0 terminator - this is by far
* the fastest way and outweights the additional memory
* required. 2005-9-19 rgerhards.
*/
pThis->pszBuf[pThis->iStrLen] = '\0';
}
return RS_RET_OK;
}
/* Trim trailing whitespace from a given string
*/
rsRetVal rsCStrTrimTrailingWhiteSpace(cstr_t *pThis)
{
register int i;
register uchar *pC;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
i = pThis->iStrLen;
pC = pThis->pBuf + i - 1;
while(i > 0 && isspace((int)*pC)) {
--pC;
--i;
}
/* i now is the new string length! */
pThis->iStrLen = i;
return RS_RET_OK;
}
/* Trim trailing whitespace from a given string
*/
rsRetVal cstrTrimTrailingWhiteSpace(cstr_t *pThis)
{
register int i;
register uchar *pC;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
i = pThis->iStrLen;
pC = pThis->pBuf + i - 1;
while(i > 0 && isspace((int)*pC)) {
--pC;
--i;
}
/* i now is the new string length! */
pThis->iStrLen = i;
pThis->pBuf[pThis->iStrLen] = '0'; /* we always have this space */
return RS_RET_OK;
}
/* compare two string objects - works like strcmp(), but operates
* on CStr objects. Please note that this version here is
* faster in the majority of cases, simply because it can
* rely on StrLen.
* rgerhards 2005-09-19
* fixed bug, in which only the last byte was actually compared
* in equal-size strings.
* rgerhards, 2005-09-26
*/
int rsCStrCStrCmp(cstr_t *pCS1, cstr_t *pCS2)
{
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
rsCHECKVALIDOBJECT(pCS2, OIDrsCStr);
if(pCS1->iStrLen == pCS2->iStrLen)
if(pCS1->iStrLen == 0)
return 0; /* zero-sized string are equal ;) */
else { /* we now have two non-empty strings of equal
* length, so we need to actually check if they
* are equal.
*/
register size_t i;
for(i = 0 ; i < pCS1->iStrLen ; ++i) {
if(pCS1->pBuf[i] != pCS2->pBuf[i])
return pCS1->pBuf[i] - pCS2->pBuf[i];
}
/* if we arrive here, the strings are equal */
return 0;
}
else
return pCS1->iStrLen - pCS2->iStrLen;
}
/* check if a sz-type string starts with a CStr object. This function
* is initially written to support the "startswith" property-filter
* comparison operation. Maybe it also has other needs.
* This functions is modelled after the strcmp() series, thus a
* return value of 0 indicates that the string starts with the
* sequence while -1 indicates it does not!
* rgerhards 2005-10-19
*/
int rsCStrSzStrStartsWithCStr(cstr_t *pCS1, uchar *psz, size_t iLenSz)
{
register int i;
int iMax;
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
assert(psz != NULL);
assert(iLenSz == strlen((char*)psz)); /* just make sure during debugging! */
if(iLenSz >= pCS1->iStrLen) {
/* we need to checkusing pCS1->iStrLen charactes at maximum, thus
* we move it to iMax.
*/
iMax = pCS1->iStrLen;
if(iMax == 0)
return 0; /* yes, it starts with a zero-sized string ;) */
else { /* we now have something to compare, so let's do it... */
for(i = 0 ; i < iMax ; ++i) {
if(psz[i] != pCS1->pBuf[i])
return psz[i] - pCS1->pBuf[i];
}
/* if we arrive here, the string actually starts with pCS1 */
return 0;
}
}
else
return -1; /* pCS1 is less then psz */
}
/* check if a CStr object starts with a sz-type string.
* This functions is modelled after the strcmp() series, thus a
* return value of 0 indicates that the string starts with the
* sequence while -1 indicates it does not!
* rgerhards 2005-09-26
*/
int rsCStrStartsWithSzStr(cstr_t *pCS1, uchar *psz, size_t iLenSz)
{
register size_t i;
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
assert(psz != NULL);
assert(iLenSz == strlen((char*)psz)); /* just make sure during debugging! */
if(pCS1->iStrLen >= iLenSz) {
/* we are using iLenSz below, because we need to check
* iLenSz characters at maximum (start with!)
*/
if(iLenSz == 0)
return 0; /* yes, it starts with a zero-sized string ;) */
else { /* we now have something to compare, so let's do it... */
for(i = 0 ; i < iLenSz ; ++i) {
if(pCS1->pBuf[i] != psz[i])
return pCS1->pBuf[i] - psz[i];
}
/* if we arrive here, the string actually starts with psz */
return 0;
}
}
else
return -1; /* pCS1 is less then psz */
}
/* The same as rsCStrStartsWithSzStr(), but does a case-insensitive
* comparison. TODO: consolidate the two.
* rgerhards 2008-02-28
*/
int rsCStrCaseInsensitveStartsWithSzStr(cstr_t *pCS1, uchar *psz, size_t iLenSz)
{
register size_t i;
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
assert(psz != NULL);
assert(iLenSz == strlen((char*)psz)); /* just make sure during debugging! */
if(pCS1->iStrLen >= iLenSz) {
/* we are using iLenSz below, because we need to check
* iLenSz characters at maximum (start with!)
*/
if(iLenSz == 0)
return 0; /* yes, it starts with a zero-sized string ;) */
else { /* we now have something to compare, so let's do it... */
for(i = 0 ; i < iLenSz ; ++i) {
if(tolower(pCS1->pBuf[i]) != tolower(psz[i]))
return tolower(pCS1->pBuf[i]) - tolower(psz[i]);
}
/* if we arrive here, the string actually starts with psz */
return 0;
}
}
else
return -1; /* pCS1 is less then psz */
}
/* check if a CStr object matches a regex.
* msamia@redhat.com 2007-07-12
* @return returns 0 if matched
* bug: doesn't work for CStr containing \0
* rgerhards, 2007-07-16: bug is no real bug, because rsyslogd ensures there
* never is a \0 *inside* a property string.
* Note that the function returns -1 if regexp functionality is not available.
* rgerhards: 2009-03-04: ERE support added, via parameter iType: 0 - BRE, 1 - ERE
* Arnaud Cornet/rgerhards: 2009-04-02: performance improvement by caching compiled regex
* If a caller does not need the cached version, it must still provide memory for it
* and must call rsCStrRegexDestruct() afterwards.
*/
rsRetVal rsCStrSzStrMatchRegex(cstr_t *pCS1, uchar *psz, int iType, void *rc)
{
regex_t **cache = (regex_t**) rc;
int ret;
DEFiRet;
assert(pCS1 != NULL);
assert(psz != NULL);
assert(cache != NULL);
if(objUse(regexp, LM_REGEXP_FILENAME) == RS_RET_OK) {
if (*cache == NULL) {
*cache = calloc(sizeof(regex_t), 1);
regexp.regcomp(*cache, (char*) rsCStrGetSzStr(pCS1), (iType == 1 ? REG_EXTENDED : 0) | REG_NOSUB);
}
ret = regexp.regexec(*cache, (char*) psz, 0, NULL, 0);
if(ret != 0)
ABORT_FINALIZE(RS_RET_NOT_FOUND);
} else {
ABORT_FINALIZE(RS_RET_NOT_FOUND);
}
finalize_it:
RETiRet;
}
/* free a cached compiled regex
* Caller must provide a pointer to a buffer that was created by
* rsCStrSzStrMatchRegexCache()
*/
void rsCStrRegexDestruct(void *rc)
{
regex_t **cache = rc;
assert(cache != NULL);
assert(*cache != NULL);
if(objUse(regexp, LM_REGEXP_FILENAME) == RS_RET_OK) {
regexp.regfree(*cache);
free(*cache);
*cache = NULL;
}
}
/* compare a rsCStr object with a classical sz string. This function
* is almost identical to rsCStrZsStrCmp(), but it also takes an offset
* to the CStr object from where the comparison is to start.
* I have thought quite a while if it really makes sense to more or
* less duplicate the code. After all, if you call it with an offset of
* zero, the functionality is exactly the same. So it looks natural to
* just have a single function. However, supporting the offset requires
* some (few) additional integer operations. While they are few, they
* happen at places in the code that is run very frequently. All in all,
* I have opted for performance and thus duplicated the code. I hope
* this is a good, or at least acceptable, compromise.
* rgerhards, 2005-09-26
* This function also has an offset-pointer which allows to
* specify *where* the compare operation should begin in
* the CStr. If everything is to be compared, it must be set
* to 0. If some leading bytes are to be skipped, it must be set
* to the first index that is to be compared. It must not be
* set higher than the string length (this is considered a
* program bug and will lead to unpredictable results and program aborts).
* rgerhards 2005-09-26
*/
int rsCStrOffsetSzStrCmp(cstr_t *pCS1, size_t iOffset, uchar *psz, size_t iLenSz)
{
BEGINfunc
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
assert(iOffset < pCS1->iStrLen);
assert(psz != NULL);
assert(iLenSz == strlen((char*)psz)); /* just make sure during debugging! */
if((pCS1->iStrLen - iOffset) == iLenSz) {
/* we are using iLenSz below, because the lengths
* are equal and iLenSz is faster to access
*/
if(iLenSz == 0) {
return 0; /* zero-sized strings are equal ;) */
ENDfunc
} else { /* we now have two non-empty strings of equal
* length, so we need to actually check if they
* are equal.
*/
register size_t i;
for(i = 0 ; i < iLenSz ; ++i) {
if(pCS1->pBuf[i+iOffset] != psz[i])
return pCS1->pBuf[i+iOffset] - psz[i];
}
/* if we arrive here, the strings are equal */
return 0;
ENDfunc
}
}
else {
return pCS1->iStrLen - iOffset - iLenSz;
ENDfunc
}
}
/* Converts a string to a number. If the string dos not contain a number,
* RS_RET_NOT_A_NUMBER is returned and the contents of pNumber is undefined.
* If all goes well, pNumber contains the number that the string was converted
* to.
*/
rsRetVal
rsCStrConvertToNumber(cstr_t *pStr, number_t *pNumber)
{
DEFiRet;
number_t n;
int bIsNegative;
size_t i;
ASSERT(pStr != NULL);
ASSERT(pNumber != NULL);
if(pStr->iStrLen == 0) {
/* can be converted to 0! (by convention) */
pNumber = 0;
FINALIZE;
}
/* first skip whitespace (if present) */
for(i = 0 ; i < pStr->iStrLen && isspace(pStr->pBuf[i]) ; ++i) {
/*DO NOTHING*/
}
/* we have a string, so let's check its syntax */
if(pStr->pBuf[i] == '+') {
++i; /* skip that char */
bIsNegative = 0;
} else if(pStr->pBuf[0] == '-') {
++i; /* skip that char */
bIsNegative = 1;
} else {
bIsNegative = 0;
}
/* TODO: octal? hex? */
n = 0;
while(i < pStr->iStrLen && isdigit(pStr->pBuf[i])) {
n = n * 10 + pStr->pBuf[i] - '0';
++i;
}
if(i < pStr->iStrLen) /* non-digits before end of string? */
ABORT_FINALIZE(RS_RET_NOT_A_NUMBER);
if(bIsNegative)
n *= -1;
/* we got it, so return the number */
*pNumber = n;
finalize_it:
RETiRet;
}
/* Converts a string to a boolen. First tries to convert to a number. If
* that succeeds, we are done (number is then used as boolean value). If
* that fails, we look if the string is "yes" or "true". If so, a value
* of 1 is returned. In all other cases, a value of 0 is returned. Please
* note that we do not have a specific boolean type, so we return a number.
* so, these are
* RS_RET_NOT_A_NUMBER is returned and the contents of pNumber is undefined.
* If all goes well, pNumber contains the number that the string was converted
* to.
*/
rsRetVal
rsCStrConvertToBool(cstr_t *pStr, number_t *pBool)
{
DEFiRet;
ASSERT(pStr != NULL);
ASSERT(pBool != NULL);
iRet = rsCStrConvertToNumber(pStr, pBool);
if(iRet != RS_RET_NOT_A_NUMBER) {
FINALIZE; /* in any case, we have nothing left to do */
}
/* TODO: maybe we can do better than strcasecmp ;) -- overhead! */
if(!strcasecmp((char*)rsCStrGetSzStr(pStr), "true")) {
*pBool = 1;
} else if(!strcasecmp((char*)rsCStrGetSzStr(pStr), "yes")) {
*pBool = 1;
} else {
*pBool = 0;
}
finalize_it:
RETiRet;
}
/* compare a rsCStr object with a classical sz string.
* Just like rsCStrCStrCmp, just for a different data type.
* There must not only the sz string but also its length be
* provided. If the caller does not know the length he can
* call with
* rsCstrSzStrCmp(pCS, psz, strlen((char*)psz));
* we are not doing the strlen((char*)) ourselfs as the caller might
* already know the length and in such cases we can save the
* overhead of doing it one more time (strelen() is costly!).
* The bottom line is that the provided length MUST be correct!
* The to sz string pointer must not be NULL!
* rgerhards 2005-09-26
*/
int rsCStrSzStrCmp(cstr_t *pCS1, uchar *psz, size_t iLenSz)
{
rsCHECKVALIDOBJECT(pCS1, OIDrsCStr);
assert(psz != NULL);
assert(iLenSz == strlen((char*)psz)); /* just make sure during debugging! */
if(pCS1->iStrLen == iLenSz)
/* we are using iLenSz below, because the lengths
* are equal and iLenSz is faster to access
*/
if(iLenSz == 0)
return 0; /* zero-sized strings are equal ;) */
else { /* we now have two non-empty strings of equal
* length, so we need to actually check if they
* are equal.
*/
register size_t i;
for(i = 0 ; i < iLenSz ; ++i) {
if(pCS1->pBuf[i] != psz[i])
return pCS1->pBuf[i] - psz[i];
}
/* if we arrive here, the strings are equal */
return 0;
}
else
return pCS1->iStrLen - iLenSz;
}
/* Locate the first occurence of this rsCStr object inside a standard sz string.
* Returns the offset (0-bound) of this first occurrence. If not found, -1 is
* returned. Both parameters MUST be given (NULL is not allowed).
* rgerhards 2005-09-19
*/
int rsCStrLocateInSzStr(cstr_t *pThis, uchar *sz)
{
int i;
int iMax;
int bFound;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
assert(sz != NULL);
if(pThis->iStrLen == 0)
return 0;
/* compute the largest index where a match could occur - after all,
* the to-be-located string must be able to be present in the
* searched string (it needs its size ;)).
*/
iMax = strlen((char*)sz) - pThis->iStrLen;
bFound = 0;
i = 0;
while(i <= iMax && !bFound) {
size_t iCheck;
uchar *pComp = sz + i;
for(iCheck = 0 ; iCheck < pThis->iStrLen ; ++iCheck)
if(*(pComp + iCheck) != *(pThis->pBuf + iCheck))
break;
if(iCheck == pThis->iStrLen)
bFound = 1; /* found! - else it wouldn't be equal */
else
++i; /* on to the next try */
}
return(bFound ? i : -1);
}
/* This is the same as rsCStrLocateInSzStr(), but does a case-insensitve
* comparison.
* TODO: over time, consolidate the two.
* rgerhards, 2008-02-28
*/
int rsCStrCaseInsensitiveLocateInSzStr(cstr_t *pThis, uchar *sz)
{
int i;
int iMax;
int bFound;
rsCHECKVALIDOBJECT(pThis, OIDrsCStr);
assert(sz != NULL);
if(pThis->iStrLen == 0)
return 0;
/* compute the largest index where a match could occur - after all,
* the to-be-located string must be able to be present in the
* searched string (it needs its size ;)).
*/
iMax = strlen((char*)sz) - pThis->iStrLen;
bFound = 0;
i = 0;
while(i <= iMax && !bFound) {
size_t iCheck;
uchar *pComp = sz + i;
for(iCheck = 0 ; iCheck < pThis->iStrLen ; ++iCheck)
if(tolower(*(pComp + iCheck)) != tolower(*(pThis->pBuf + iCheck)))
break;
if(iCheck == pThis->iStrLen)
bFound = 1; /* found! - else it wouldn't be equal */
else
++i; /* on to the next try */
}
return(bFound ? i : -1);
}
/* our exit function. TODO: remove once converted to a class
* rgerhards, 2008-03-11
*/
rsRetVal strExit()
{
DEFiRet;
objRelease(regexp, LM_REGEXP_FILENAME);
RETiRet;
}
/* our init function. TODO: remove once converted to a class
*/
rsRetVal strInit()
{
DEFiRet;
CHKiRet(objGetObjInterface(&obj));
finalize_it:
RETiRet;
}
/* vi:set ai:
*/