/* msg.c
* The msg object. Implementation of all msg-related functions
*
* File begun on 2007-07-13 by RGerhards (extracted from syslogd.c)
* This file is under development and has not yet arrived at being fully
* self-contained and a real object. So far, it is mostly an excerpt
* of the "old" message code without any modifications. However, it
* helps to have things at the right place one we go to the meat of it.
*
* Copyright 2007 Rainer Gerhards and Adiscon GmbH.
*
* This file is part of rsyslog.
*
* Rsyslog 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 3 of the License, or
* (at your option) any later version.
*
* Rsyslog 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 Rsyslog. If not, see .
*
* A copy of the GPL can be found in the file "COPYING" in this distribution.
*/
#include "config.h"
#include
#include
#include
#define SYSLOG_NAMES
#include
#include
#include
#include
#include "rsyslog.h"
#include "syslogd.h"
#include "srUtils.h"
#include "stringbuf.h"
#include "template.h"
#include "msg.h"
DEFobjStaticHelpers
static syslogCODE rs_prioritynames[] =
{
{ "alert", LOG_ALERT },
{ "crit", LOG_CRIT },
{ "debug", LOG_DEBUG },
{ "emerg", LOG_EMERG },
{ "err", LOG_ERR },
{ "error", LOG_ERR }, /* DEPRECATED */
{ "info", LOG_INFO },
{ "none", INTERNAL_NOPRI }, /* INTERNAL */
{ "notice", LOG_NOTICE },
{ "panic", LOG_EMERG }, /* DEPRECATED */
{ "warn", LOG_WARNING }, /* DEPRECATED */
{ "warning", LOG_WARNING },
{ NULL, -1 }
};
static syslogCODE rs_facilitynames[] =
{
{ "auth", LOG_AUTH },
{ "authpriv", LOG_AUTHPRIV },
{ "cron", LOG_CRON },
{ "daemon", LOG_DAEMON },
{ "ftp", LOG_FTP },
{ "kern", LOG_KERN },
{ "lpr", LOG_LPR },
{ "mail", LOG_MAIL },
{ "mark", INTERNAL_MARK }, /* INTERNAL */
{ "news", LOG_NEWS },
{ "security", LOG_AUTH }, /* DEPRECATED */
{ "syslog", LOG_SYSLOG },
{ "user", LOG_USER },
{ "uucp", LOG_UUCP },
{ "local0", LOG_LOCAL0 },
{ "local1", LOG_LOCAL1 },
{ "local2", LOG_LOCAL2 },
{ "local3", LOG_LOCAL3 },
{ "local4", LOG_LOCAL4 },
{ "local5", LOG_LOCAL5 },
{ "local6", LOG_LOCAL6 },
{ "local7", LOG_LOCAL7 },
{ NULL, -1 }
};
/* some forward declarations */
static int getAPPNAMELen(msg_t *pM);
/* The following functions will support advanced output module
* multithreading, once this is implemented. Currently, we
* include them as hooks only. The idea is that we need to guard
* some msg objects data fields against concurrent access if
* we run on multiple threads. Please note that in any case this
* is not necessary for calls from INPUT modules, because they
* construct the message object and do this serially. Only when
* the message is in the processing queue, multiple threads may
* access a single object. Consequently, there are no guard functions
* for "set" methods, as these are called during input. Only "get"
* functions that modify important structures have them.
* rgerhards, 2007-07-20
* We now support locked and non-locked operations, depending on
* the configuration of rsyslog. To support this, we use function
* pointers. Initially, we start in non-locked mode. There, all
* locking operations call into dummy functions. When locking is
* enabled, the function pointers are changed to functions doing
* actual work. We also introduced another MsgPrepareEnqueue() function
* which initializes the locking structures, if needed. This is
* necessary because internal messages during config file startup
* processing are always created in non-locking mode. So we can
* not initialize locking structures during constructions. We now
* postpone this until when the message is fully constructed and
* enqueued. Then we know the status of locking. This has a nice
* side effect, and that is that during the initial creation of
* the Msg object no locking needs to be done, which results in better
* performance. -- rgerhards, 2008-01-05
*/
static void (*funcLock)(msg_t *pMsg);
static void (*funcUnlock)(msg_t *pMsg);
static void (*funcDeleteMutex)(msg_t *pMsg);
void (*funcMsgPrepareEnqueue)(msg_t *pMsg);
#if 1 /* This is a debug aid */
#define MsgLock(pMsg) funcLock(pMsg)
#define MsgUnlock(pMsg) funcUnlock(pMsg)
#else
#define MsgLock(pMsg) {dbgprintf("line %d\n - ", __LINE__); funcLock(pMsg);; }
#define MsgUnlock(pMsg) {dbgprintf("line %d - ", __LINE__); funcUnlock(pMsg); }
#endif
/* the next function is a dummy to be used by the looking functions
* when the class is not yet running in an environment where locking
* is necessary. Please note that the need to lock can (and will) change
* during a single run. Typically, this is depending on the operation mode
* of the message queues (which is operator-configurable). -- rgerhards, 2008-01-05
*/
static void MsgLockingDummy(msg_t __attribute__((unused)) *pMsg)
{
/* empty be design */
}
/* The following function prepares a message for enqueue into the queue. This is
* where a message may be accessed by multiple threads. This implementation here
* is the version for multiple concurrent acces. It initializes the locking
* structures.
*/
static void MsgPrepareEnqueueLockingCase(msg_t *pThis)
{
assert(pThis != NULL);
pthread_mutexattr_settype(&pThis->mutAttr, PTHREAD_MUTEX_RECURSIVE);
pthread_mutex_init(&pThis->mut, &pThis->mutAttr);
}
/* ... and now the locking and unlocking implementations: */
static void MsgLockLockingCase(msg_t *pThis)
{
/* DEV debug only! dbgprintf("MsgLock(0x%lx)\n", (unsigned long) pThis); */
assert(pThis != NULL);
pthread_mutex_lock(&pThis->mut);
}
static void MsgUnlockLockingCase(msg_t *pThis)
{
/* DEV debug only! dbgprintf("MsgUnlock(0x%lx)\n", (unsigned long) pThis); */
assert(pThis != NULL);
pthread_mutex_unlock(&pThis->mut);
}
/* delete the mutex object on message destruction (locking case)
*/
static void MsgDeleteMutexLockingCase(msg_t *pThis)
{
assert(pThis != NULL);
pthread_mutex_destroy(&pThis->mut);
}
/* enable multiple concurrent access on the message object
* This works on a class-wide basis and can bot be undone.
* That is, if it is once enabled, it can not be disabled during
* the same run. When this function is called, no other thread
* must manipulate message objects. Then we would have race conditions,
* but guarding against this is counter-productive because it
* would cost additional time. Plus, it would be a programming error.
* rgerhards, 2008-01-05
*/
rsRetVal MsgEnableThreadSafety(void)
{
funcLock = MsgLockLockingCase;
funcUnlock = MsgUnlockLockingCase;
funcMsgPrepareEnqueue = MsgPrepareEnqueueLockingCase;
funcDeleteMutex = MsgDeleteMutexLockingCase;
return RS_RET_OK;
}
/* end locking functions */
/* "Constructor" for a msg "object". Returns a pointer to
* the new object or NULL if no such object could be allocated.
* An object constructed via this function should only be destroyed
* via "msgDestruct()".
*/
rsRetVal msgConstruct(msg_t **ppThis)
{
DEFiRet;
msg_t *pM;
assert(ppThis != NULL);
if((pM = calloc(1, sizeof(msg_t))) == NULL)
ABORT_FINALIZE(RS_RET_OUT_OF_MEMORY);
/* initialize members that are non-zero */
pM->iRefCount = 1;
pM->iSeverity = -1;
pM->iFacility = -1;
getCurrTime(&(pM->tRcvdAt));
objConstructSetObjInfo(pM);
/* DEV debugging only! dbgprintf("msgConstruct\t0x%x, ref 1\n", (int)pM);*/
*ppThis = pM;
finalize_it:
RETiRet;
}
BEGINobjDestruct(msg) /* be sure to specify the object type also in END and CODESTART macros! */
CODESTARTobjDestruct(msg)
/* DEV Debugging only ! dbgprintf("msgDestruct\t0x%lx, Ref now: %d\n", (unsigned long)pM, pM->iRefCount - 1); */
if(--pThis->iRefCount == 0)
{
/* DEV Debugging Only! dbgprintf("msgDestruct\t0x%lx, RefCount now 0, doing DESTROY\n", (unsigned long)pThis); */
if(pThis->pszUxTradMsg != NULL)
free(pThis->pszUxTradMsg);
if(pThis->pszRawMsg != NULL)
free(pThis->pszRawMsg);
if(pThis->pszTAG != NULL)
free(pThis->pszTAG);
if(pThis->pszHOSTNAME != NULL)
free(pThis->pszHOSTNAME);
if(pThis->pszRcvFrom != NULL)
free(pThis->pszRcvFrom);
if(pThis->pszMSG != NULL)
free(pThis->pszMSG);
if(pThis->pszFacility != NULL)
free(pThis->pszFacility);
if(pThis->pszFacilityStr != NULL)
free(pThis->pszFacilityStr);
if(pThis->pszSeverity != NULL)
free(pThis->pszSeverity);
if(pThis->pszSeverityStr != NULL)
free(pThis->pszSeverityStr);
if(pThis->pszRcvdAt3164 != NULL)
free(pThis->pszRcvdAt3164);
if(pThis->pszRcvdAt3339 != NULL)
free(pThis->pszRcvdAt3339);
if(pThis->pszRcvdAt_MySQL != NULL)
free(pThis->pszRcvdAt_MySQL);
if(pThis->pszRcvdAt_PgSQL != NULL)
free(pThis->pszRcvdAt_PgSQL);
if(pThis->pszTIMESTAMP3164 != NULL)
free(pThis->pszTIMESTAMP3164);
if(pThis->pszTIMESTAMP3339 != NULL)
free(pThis->pszTIMESTAMP3339);
if(pThis->pszTIMESTAMP_MySQL != NULL)
free(pThis->pszTIMESTAMP_MySQL);
if(pThis->pszTIMESTAMP_PgSQL != NULL)
free(pThis->pszTIMESTAMP_PgSQL);
if(pThis->pszPRI != NULL)
free(pThis->pszPRI);
if(pThis->pCSProgName != NULL)
rsCStrDestruct(&pThis->pCSProgName);
if(pThis->pCSStrucData != NULL)
rsCStrDestruct(&pThis->pCSStrucData);
if(pThis->pCSAPPNAME != NULL)
rsCStrDestruct(&pThis->pCSAPPNAME);
if(pThis->pCSPROCID != NULL)
rsCStrDestruct(&pThis->pCSPROCID);
if(pThis->pCSMSGID != NULL)
rsCStrDestruct(&pThis->pCSMSGID);
funcDeleteMutex(pThis);
} else {
pThis = NULL; /* tell framework not to destructing the object! */
}
ENDobjDestruct(msg)
/* The macros below are used in MsgDup(). I use macros
* to keep the fuction code somewhat more readyble. It is my
* replacement for inline functions in CPP
*/
#define tmpCOPYSZ(name) \
if(pOld->psz##name != NULL) { \
if((pNew->psz##name = srUtilStrDup(pOld->psz##name, pOld->iLen##name)) == NULL) {\
msgDestruct(&pNew);\
return NULL;\
}\
pNew->iLen##name = pOld->iLen##name;\
}
/* copy the CStr objects.
* if the old value is NULL, we do not need to do anything because we
* initialized the new value to NULL via calloc().
*/
#define tmpCOPYCSTR(name) \
if(pOld->pCS##name != NULL) {\
if(rsCStrConstructFromCStr(&(pNew->pCS##name), pOld->pCS##name) != RS_RET_OK) {\
msgDestruct(&pNew);\
return NULL;\
}\
}
/* Constructs a message object by duplicating another one.
* Returns NULL if duplication failed. We do not need to lock the
* message object here, because a fully-created msg object is never
* allowed to be manipulated. For this, MsgDup() must be used, so MsgDup()
* can never run into a situation where the message object is being
* modified while its content is copied - it's forbidden by definition.
* rgerhards, 2007-07-10
*/
msg_t* MsgDup(msg_t* pOld)
{
msg_t* pNew;
assert(pOld != NULL);
BEGINfunc
if(msgConstruct(&pNew) != RS_RET_OK) {
return NULL;
}
/* now copy the message properties */
pNew->iRefCount = 1;
pNew->iSeverity = pOld->iSeverity;
pNew->iFacility = pOld->iFacility;
pNew->bParseHOSTNAME = pOld->bParseHOSTNAME;
pNew->msgFlags = pOld->msgFlags;
pNew->iProtocolVersion = pOld->iProtocolVersion;
memcpy(&pNew->tRcvdAt, &pOld->tRcvdAt, sizeof(struct syslogTime));
memcpy(&pNew->tTIMESTAMP, &pOld->tTIMESTAMP, sizeof(struct syslogTime));
tmpCOPYSZ(Severity);
tmpCOPYSZ(SeverityStr);
tmpCOPYSZ(Facility);
tmpCOPYSZ(FacilityStr);
tmpCOPYSZ(PRI);
tmpCOPYSZ(RawMsg);
tmpCOPYSZ(MSG);
tmpCOPYSZ(UxTradMsg);
tmpCOPYSZ(TAG);
tmpCOPYSZ(HOSTNAME);
tmpCOPYSZ(RcvFrom);
tmpCOPYCSTR(ProgName);
tmpCOPYCSTR(StrucData);
tmpCOPYCSTR(APPNAME);
tmpCOPYCSTR(PROCID);
tmpCOPYCSTR(MSGID);
/* we do not copy all other cache properties, as we do not even know
* if they are needed once again. So we let them re-create if needed.
*/
ENDfunc
return pNew;
}
#undef tmpCOPYSZ
#undef tmpCOPYCSTR
/* This method serializes a message object. That means the whole
* object is modified into text form. That text form is suitable for
* later reconstruction of the object by calling MsgDeSerialize().
* The most common use case for this method is the creation of an
* on-disk representation of the message object.
* We do not serialize the cache properties. We re-create them when needed.
* This saves us a lot of memory. Performance is no concern, as serializing
* is a so slow operation that recration of the caches does not count. Also,
* we do not serialize bParseHOSTNAME, as this is only a helper variable
* during msg construction - and never again used later.
* rgerhards, 2008-01-03
*/
static rsRetVal MsgSerialize(msg_t *pThis, strm_t *pStrm)
{
DEFiRet;
assert(pThis != NULL);
assert(pStrm != NULL);
CHKiRet(objBeginSerialize(pStrm, (obj_t*) pThis));
objSerializeSCALAR(pStrm, iProtocolVersion, SHORT);
objSerializeSCALAR(pStrm, iSeverity, SHORT);
objSerializeSCALAR(pStrm, iFacility, SHORT);
objSerializeSCALAR(pStrm, msgFlags, INT);
objSerializeSCALAR(pStrm, tRcvdAt, SYSLOGTIME);
objSerializeSCALAR(pStrm, tTIMESTAMP, SYSLOGTIME);
objSerializePTR(pStrm, pszRawMsg, PSZ);
objSerializePTR(pStrm, pszMSG, PSZ);
objSerializePTR(pStrm, pszUxTradMsg, PSZ);
objSerializePTR(pStrm, pszTAG, PSZ);
objSerializePTR(pStrm, pszHOSTNAME, PSZ);
objSerializePTR(pStrm, pszRcvFrom, PSZ);
objSerializePTR(pStrm, pCSStrucData, CSTR);
objSerializePTR(pStrm, pCSAPPNAME, CSTR);
objSerializePTR(pStrm, pCSPROCID, CSTR);
objSerializePTR(pStrm, pCSMSGID, CSTR);
CHKiRet(objEndSerialize(pStrm));
finalize_it:
RETiRet;
}
/* Increment reference count - see description of the "msg"
* structure for details. As a convenience to developers,
* this method returns the msg pointer that is passed to it.
* It is recommended that it is called as follows:
*
* pSecondMsgPointer = MsgAddRef(pOrgMsgPointer);
*/
msg_t *MsgAddRef(msg_t *pM)
{
assert(pM != NULL);
MsgLock(pM);
pM->iRefCount++;
MsgUnlock(pM);
/* DEV debugging only! dbgprintf("MsgAddRef\t0x%x done, Ref now: %d\n", (int)pM, pM->iRefCount);*/
return(pM);
}
/* This functions tries to aquire the PROCID from TAG. Its primary use is
* when a legacy syslog message has been received and should be forwarded as
* syslog-protocol (or the PROCID is requested for any other reason).
* In legacy syslog, the PROCID is considered to be the character sequence
* between the first [ and the first ]. This usually are digits only, but we
* do not check that. However, if there is no closing ], we do not assume we
* can obtain a PROCID. Take in mind that not every legacy syslog message
* actually has a PROCID.
* rgerhards, 2005-11-24
*/
static rsRetVal aquirePROCIDFromTAG(msg_t *pM)
{
register int i;
DEFiRet;
assert(pM != NULL);
if(pM->pCSPROCID != NULL)
return RS_RET_OK; /* we are already done ;) */
if(getProtocolVersion(pM) != 0)
return RS_RET_OK; /* we can only emulate if we have legacy format */
/* find first '['... */
i = 0;
while((i < pM->iLenTAG) && (pM->pszTAG[i] != '['))
++i;
if(!(i < pM->iLenTAG))
return RS_RET_OK; /* no [, so can not emulate... */
++i; /* skip '[' */
/* now obtain the PROCID string... */
CHKiRet(rsCStrConstruct(&pM->pCSPROCID));
rsCStrSetAllocIncrement(pM->pCSPROCID, 16);
while((i < pM->iLenTAG) && (pM->pszTAG[i] != ']')) {
CHKiRet(rsCStrAppendChar(pM->pCSPROCID, pM->pszTAG[i]));
++i;
}
if(!(i < pM->iLenTAG)) {
/* oops... it looked like we had a PROCID, but now it has
* turned out this is not true. In this case, we need to free
* the buffer and simply return. Note that this is NOT an error
* case!
*/
rsCStrDestruct(&pM->pCSPROCID);
FINALIZE;
}
/* OK, finaally we could obtain a PROCID. So let's use it ;) */
CHKiRet(rsCStrFinish(pM->pCSPROCID));
finalize_it:
RETiRet;
}
/* Parse and set the "programname" for a given MSG object. Programname
* is a BSD concept, it is the tag without any instance-specific information.
* Precisely, the programname is terminated by either (whichever occurs first):
* - end of tag
* - nonprintable character
* - ':'
* - '['
* - '/'
* The above definition has been taken from the FreeBSD syslogd sources.
*
* The program name is not parsed by default, because it is infrequently-used.
* If it is needed, this function should be called first. It checks if it is
* already set and extracts it, if not.
* A message object must be provided, else a crash will occur.
* rgerhards, 2005-10-19
*/
static rsRetVal aquireProgramName(msg_t *pM)
{
DEFiRet;
register int i;
assert(pM != NULL);
if(pM->pCSProgName == NULL) {
/* ok, we do not yet have it. So let's parse the TAG
* to obtain it.
*/
CHKiRet(rsCStrConstruct(&pM->pCSProgName));
rsCStrSetAllocIncrement(pM->pCSProgName, 33);
for( i = 0
; (i < pM->iLenTAG) && isprint((int) pM->pszTAG[i])
&& (pM->pszTAG[i] != '\0') && (pM->pszTAG[i] != ':')
&& (pM->pszTAG[i] != '[') && (pM->pszTAG[i] != '/')
; ++i) {
CHKiRet(rsCStrAppendChar(pM->pCSProgName, pM->pszTAG[i]));
}
CHKiRet(rsCStrFinish(pM->pCSProgName));
}
finalize_it:
RETiRet;
}
/* This function moves the HOSTNAME inside the message object to the
* TAG. It is a specialised function used to handle the condition when
* a message without HOSTNAME is being processed. The missing HOSTNAME
* is only detected at a later stage, during TAG processing, so that
* we already had set the HOSTNAME property and now need to move it to
* the TAG. Of course, we could do this via a couple of get/set methods,
* but it is far more efficient to do it via this specialised method.
* This is especially important as this can be a very common case, e.g.
* when BSD syslog is acting as a sender.
* rgerhards, 2005-11-10.
*/
void moveHOSTNAMEtoTAG(msg_t *pM)
{
assert(pM != NULL);
if(pM->pszTAG != NULL)
free(pM->pszTAG);
pM->pszTAG = pM->pszHOSTNAME;
pM->iLenTAG = pM->iLenHOSTNAME;
pM->pszHOSTNAME = NULL;
pM->iLenHOSTNAME = 0;
}
/* Access methods - dumb & easy, not a comment for each ;)
*/
void setProtocolVersion(msg_t *pM, int iNewVersion)
{
assert(pM != NULL);
if(iNewVersion != 0 && iNewVersion != 1) {
dbgprintf("Tried to set unsupported protocol version %d - changed to 0.\n", iNewVersion);
iNewVersion = 0;
}
pM->iProtocolVersion = iNewVersion;
}
int getProtocolVersion(msg_t *pM)
{
assert(pM != NULL);
return(pM->iProtocolVersion);
}
/* note: string is taken from constant pool, do NOT free */
char *getProtocolVersionString(msg_t *pM)
{
assert(pM != NULL);
return(pM->iProtocolVersion ? "1" : "0");
}
int getMSGLen(msg_t *pM)
{
return((pM == NULL) ? 0 : pM->iLenMSG);
}
char *getRawMsg(msg_t *pM)
{
if(pM == NULL)
return "";
else
if(pM->pszRawMsg == NULL)
return "";
else
return (char*)pM->pszRawMsg;
}
char *getUxTradMsg(msg_t *pM)
{
if(pM == NULL)
return "";
else
if(pM->pszUxTradMsg == NULL)
return "";
else
return (char*)pM->pszUxTradMsg;
}
char *getMSG(msg_t *pM)
{
if(pM == NULL)
return "";
else
if(pM->pszMSG == NULL)
return "";
else
return (char*)pM->pszMSG;
}
/* Get PRI value in text form */
char *getPRI(msg_t *pM)
{
if(pM == NULL)
return "";
MsgLock(pM);
if(pM->pszPRI == NULL) {
/* OK, we need to construct it...
* we use a 5 byte buffer - as of
* RFC 3164, it can't be longer. Should it
* still be, snprintf will truncate...
*/
if((pM->pszPRI = malloc(5)) == NULL) return "";
pM->iLenPRI = snprintf((char*)pM->pszPRI, 5, "%d",
LOG_MAKEPRI(pM->iFacility, pM->iSeverity));
}
MsgUnlock(pM);
return (char*)pM->pszPRI;
}
/* Get PRI value as integer */
int getPRIi(msg_t *pM)
{
assert(pM != NULL);
return (pM->iFacility << 3) + (pM->iSeverity);
}
char *getTimeReported(msg_t *pM, enum tplFormatTypes eFmt)
{
if(pM == NULL)
return "";
switch(eFmt) {
case tplFmtDefault:
MsgLock(pM);
if(pM->pszTIMESTAMP3164 == NULL) {
if((pM->pszTIMESTAMP3164 = malloc(16)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestamp3164(&pM->tTIMESTAMP, pM->pszTIMESTAMP3164, 16);
}
MsgUnlock(pM);
return(pM->pszTIMESTAMP3164);
case tplFmtMySQLDate:
MsgLock(pM);
if(pM->pszTIMESTAMP_MySQL == NULL) {
if((pM->pszTIMESTAMP_MySQL = malloc(15)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestampToMySQL(&pM->tTIMESTAMP, pM->pszTIMESTAMP_MySQL, 15);
}
MsgUnlock(pM);
return(pM->pszTIMESTAMP_MySQL);
case tplFmtPgSQLDate:
MsgLock(pM);
if(pM->pszTIMESTAMP_PgSQL == NULL) {
if((pM->pszTIMESTAMP_PgSQL = malloc(21)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestampToPgSQL(&pM->tTIMESTAMP, pM->pszTIMESTAMP_PgSQL, 21);
}
MsgUnlock(pM);
return(pM->pszTIMESTAMP_PgSQL);
case tplFmtRFC3164Date:
MsgLock(pM);
if(pM->pszTIMESTAMP3164 == NULL) {
if((pM->pszTIMESTAMP3164 = malloc(16)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestamp3164(&pM->tTIMESTAMP, pM->pszTIMESTAMP3164, 16);
}
MsgUnlock(pM);
return(pM->pszTIMESTAMP3164);
case tplFmtRFC3339Date:
MsgLock(pM);
if(pM->pszTIMESTAMP3339 == NULL) {
if((pM->pszTIMESTAMP3339 = malloc(33)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return ""; /* TODO: check this: can it cause a free() of constant memory?) */
}
formatTimestamp3339(&pM->tTIMESTAMP, pM->pszTIMESTAMP3339, 33);
}
MsgUnlock(pM);
return(pM->pszTIMESTAMP3339);
}
return "INVALID eFmt OPTION!";
}
char *getTimeGenerated(msg_t *pM, enum tplFormatTypes eFmt)
{
if(pM == NULL)
return "";
switch(eFmt) {
case tplFmtDefault:
MsgLock(pM);
if(pM->pszRcvdAt3164 == NULL) {
if((pM->pszRcvdAt3164 = malloc(16)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestamp3164(&pM->tRcvdAt, pM->pszRcvdAt3164, 16);
}
MsgUnlock(pM);
return(pM->pszRcvdAt3164);
case tplFmtMySQLDate:
MsgLock(pM);
if(pM->pszRcvdAt_MySQL == NULL) {
if((pM->pszRcvdAt_MySQL = malloc(15)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestampToMySQL(&pM->tRcvdAt, pM->pszRcvdAt_MySQL, 15);
}
MsgUnlock(pM);
return(pM->pszRcvdAt_MySQL);
case tplFmtPgSQLDate:
MsgLock(pM);
if(pM->pszRcvdAt_PgSQL == NULL) {
if((pM->pszRcvdAt_PgSQL = malloc(21)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestampToPgSQL(&pM->tRcvdAt, pM->pszRcvdAt_PgSQL, 21);
}
MsgUnlock(pM);
return(pM->pszRcvdAt_PgSQL);
case tplFmtRFC3164Date:
MsgLock(pM);
if(pM->pszRcvdAt3164 == NULL) {
if((pM->pszRcvdAt3164 = malloc(16)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestamp3164(&pM->tRcvdAt, pM->pszRcvdAt3164, 16);
}
MsgUnlock(pM);
return(pM->pszRcvdAt3164);
case tplFmtRFC3339Date:
MsgLock(pM);
if(pM->pszRcvdAt3339 == NULL) {
if((pM->pszRcvdAt3339 = malloc(33)) == NULL) {
glblHadMemShortage = 1;
MsgUnlock(pM);
return "";
}
formatTimestamp3339(&pM->tRcvdAt, pM->pszRcvdAt3339, 33);
}
MsgUnlock(pM);
return(pM->pszRcvdAt3339);
}
return "INVALID eFmt OPTION!";
}
char *getSeverity(msg_t *pM)
{
if(pM == NULL)
return "";
MsgLock(pM);
if(pM->pszSeverity == NULL) {
/* we use a 2 byte buffer - can only be one digit */
if((pM->pszSeverity = malloc(2)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenSeverity =
snprintf((char*)pM->pszSeverity, 2, "%d", pM->iSeverity);
}
MsgUnlock(pM);
return((char*)pM->pszSeverity);
}
char *getSeverityStr(msg_t *pM)
{
syslogCODE *c;
int val;
char *name = NULL;
if(pM == NULL)
return "";
MsgLock(pM);
if(pM->pszSeverityStr == NULL) {
for(c = rs_prioritynames, val = pM->iSeverity; c->c_name; c++)
if(c->c_val == val) {
name = c->c_name;
break;
}
if(name == NULL) {
/* we use a 2 byte buffer - can only be one digit */
if((pM->pszSeverityStr = malloc(2)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenSeverityStr =
snprintf((char*)pM->pszSeverityStr, 2, "%d", pM->iSeverity);
} else {
if((pM->pszSeverityStr = (uchar*) strdup(name)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenSeverityStr = strlen((char*)name);
}
}
MsgUnlock(pM);
return((char*)pM->pszSeverityStr);
}
char *getFacility(msg_t *pM)
{
if(pM == NULL)
return "";
MsgLock(pM);
if(pM->pszFacility == NULL) {
/* we use a 12 byte buffer - as of
* syslog-protocol, facility can go
* up to 2^32 -1
*/
if((pM->pszFacility = malloc(12)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenFacility =
snprintf((char*)pM->pszFacility, 12, "%d", pM->iFacility);
}
MsgUnlock(pM);
return((char*)pM->pszFacility);
}
char *getFacilityStr(msg_t *pM)
{
syslogCODE *c;
int val;
char *name = NULL;
if(pM == NULL)
return "";
MsgLock(pM);
if(pM->pszFacilityStr == NULL) {
for(c = rs_facilitynames, val = pM->iFacility << 3; c->c_name; c++)
if(c->c_val == val) {
name = c->c_name;
break;
}
if(name == NULL) {
/* we use a 12 byte buffer - as of
* syslog-protocol, facility can go
* up to 2^32 -1
*/
if((pM->pszFacilityStr = malloc(12)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenFacilityStr =
snprintf((char*)pM->pszFacilityStr, 12, "%d", val >> 3);
} else {
if((pM->pszFacilityStr = (uchar*)strdup(name)) == NULL) { MsgUnlock(pM) ; return ""; }
pM->iLenFacilityStr = strlen((char*)name);
}
}
MsgUnlock(pM);
return((char*)pM->pszFacilityStr);
}
/* rgerhards 2004-11-24: set APP-NAME in msg object
* TODO: revisit msg locking code!
*/
rsRetVal MsgSetAPPNAME(msg_t *pMsg, char* pszAPPNAME)
{
DEFiRet;
assert(pMsg != NULL);
if(pMsg->pCSAPPNAME == NULL) {
/* we need to obtain the object first */
CHKiRet(rsCStrConstruct(&pMsg->pCSAPPNAME));
rsCStrSetAllocIncrement(pMsg->pCSAPPNAME, 128);
}
/* if we reach this point, we have the object */
iRet = rsCStrSetSzStr(pMsg->pCSAPPNAME, (uchar*) pszAPPNAME);
finalize_it:
RETiRet;
}
static void tryEmulateAPPNAME(msg_t *pM); /* forward reference */
/* rgerhards, 2005-11-24
*/
char *getAPPNAME(msg_t *pM)
{
assert(pM != NULL);
MsgLock(pM);
if(pM->pCSAPPNAME == NULL)
tryEmulateAPPNAME(pM);
MsgUnlock(pM);
return (pM->pCSAPPNAME == NULL) ? "" : (char*) rsCStrGetSzStrNoNULL(pM->pCSAPPNAME);
}
/* rgerhards 2004-11-24: set PROCID in msg object
*/
rsRetVal MsgSetPROCID(msg_t *pMsg, char* pszPROCID)
{
DEFiRet;
ISOBJ_TYPE_assert(pMsg, msg);
if(pMsg->pCSPROCID == NULL) {
/* we need to obtain the object first */
CHKiRet(rsCStrConstruct(&pMsg->pCSPROCID));
rsCStrSetAllocIncrement(pMsg->pCSPROCID, 128);
}
/* if we reach this point, we have the object */
iRet = rsCStrSetSzStr(pMsg->pCSPROCID, (uchar*) pszPROCID);
finalize_it:
RETiRet;
}
/* rgerhards, 2005-11-24
*/
int getPROCIDLen(msg_t *pM)
{
assert(pM != NULL);
MsgLock(pM);
if(pM->pCSPROCID == NULL)
aquirePROCIDFromTAG(pM);
MsgUnlock(pM);
return (pM->pCSPROCID == NULL) ? 1 : rsCStrLen(pM->pCSPROCID);
}
/* rgerhards, 2005-11-24
*/
char *getPROCID(msg_t *pM)
{
char* pszRet;
ISOBJ_TYPE_assert(pM, msg);
MsgLock(pM);
if(pM->pCSPROCID == NULL)
aquirePROCIDFromTAG(pM);
pszRet = (pM->pCSPROCID == NULL) ? "-" : (char*) rsCStrGetSzStrNoNULL(pM->pCSPROCID);
MsgUnlock(pM);
return pszRet;
}
/* rgerhards 2004-11-24: set MSGID in msg object
*/
rsRetVal MsgSetMSGID(msg_t *pMsg, char* pszMSGID)
{
DEFiRet;
ISOBJ_TYPE_assert(pMsg, msg);
if(pMsg->pCSMSGID == NULL) {
/* we need to obtain the object first */
CHKiRet(rsCStrConstruct(&pMsg->pCSMSGID));
rsCStrSetAllocIncrement(pMsg->pCSMSGID, 128);
}
/* if we reach this point, we have the object */
iRet = rsCStrSetSzStr(pMsg->pCSMSGID, (uchar*) pszMSGID);
finalize_it:
RETiRet;
}
/* rgerhards, 2005-11-24
*/
#if 0 /* This method is currently not called, be we like to preserve it */
static int getMSGIDLen(msg_t *pM)
{
return (pM->pCSMSGID == NULL) ? 1 : rsCStrLen(pM->pCSMSGID);
}
#endif
/* rgerhards, 2005-11-24
*/
char *getMSGID(msg_t *pM)
{
return (pM->pCSMSGID == NULL) ? "-" : (char*) rsCStrGetSzStrNoNULL(pM->pCSMSGID);
}
/* Set the TAG to a caller-provided string. This is thought
* to be a heap buffer that the caller will no longer use. This
* function is a performance optimization over MsgSetTAG().
* rgerhards 2004-11-19
*/
void MsgAssignTAG(msg_t *pMsg, uchar *pBuf)
{
assert(pMsg != NULL);
pMsg->iLenTAG = (pBuf == NULL) ? 0 : strlen((char*)pBuf);
pMsg->pszTAG = (uchar*) pBuf;
}
/* rgerhards 2004-11-16: set TAG in msg object
*/
void MsgSetTAG(msg_t *pMsg, char* pszTAG)
{
assert(pMsg != NULL);
if(pMsg->pszTAG != NULL)
free(pMsg->pszTAG);
pMsg->iLenTAG = strlen(pszTAG);
if((pMsg->pszTAG = malloc(pMsg->iLenTAG + 1)) != NULL)
memcpy(pMsg->pszTAG, pszTAG, pMsg->iLenTAG + 1);
else
dbgprintf("Could not allocate memory in MsgSetTAG()\n");
}
/* This function tries to emulate the TAG if none is
* set. Its primary purpose is to provide an old-style TAG
* when a syslog-protocol message has been received. Then,
* the tag is APP-NAME "[" PROCID "]". The function first checks
* if there is a TAG and, if not, if it can emulate it.
* rgerhards, 2005-11-24
*/
static void tryEmulateTAG(msg_t *pM)
{
int iTAGLen;
uchar *pBuf;
assert(pM != NULL);
if(pM->pszTAG != NULL)
return; /* done, no need to emulate */
if(getProtocolVersion(pM) == 1) {
if(!strcmp(getPROCID(pM), "-")) {
/* no process ID, use APP-NAME only */
MsgSetTAG(pM, getAPPNAME(pM));
} else {
/* now we can try to emulate */
iTAGLen = getAPPNAMELen(pM) + getPROCIDLen(pM) + 3;
if((pBuf = malloc(iTAGLen * sizeof(char))) == NULL)
return; /* nothing we can do */
snprintf((char*)pBuf, iTAGLen, "%s[%s]", getAPPNAME(pM), getPROCID(pM));
MsgAssignTAG(pM, pBuf);
}
}
}
#if 0 /* This method is currently not called, be we like to preserve it */
static int getTAGLen(msg_t *pM)
{
if(pM == NULL)
return 0;
else {
tryEmulateTAG(pM);
if(pM->pszTAG == NULL)
return 0;
else
return pM->iLenTAG;
}
}
#endif
char *getTAG(msg_t *pM)
{
char *ret;
if(pM == NULL)
ret = "";
else {
MsgLock(pM);
tryEmulateTAG(pM);
if(pM->pszTAG == NULL)
ret = "";
else
ret = (char*) pM->pszTAG;
MsgUnlock(pM);
}
return(ret);
}
int getHOSTNAMELen(msg_t *pM)
{
if(pM == NULL)
return 0;
else
if(pM->pszHOSTNAME == NULL)
return 0;
else
return pM->iLenHOSTNAME;
}
char *getHOSTNAME(msg_t *pM)
{
if(pM == NULL)
return "";
else
if(pM->pszHOSTNAME == NULL)
return "";
else
return (char*) pM->pszHOSTNAME;
}
char *getRcvFrom(msg_t *pM)
{
if(pM == NULL)
return "";
else
if(pM->pszRcvFrom == NULL)
return "";
else
return (char*) pM->pszRcvFrom;
}
/* rgerhards 2004-11-24: set STRUCTURED DATA in msg object
*/
rsRetVal MsgSetStructuredData(msg_t *pMsg, char* pszStrucData)
{
DEFiRet;
ISOBJ_TYPE_assert(pMsg, msg);
if(pMsg->pCSStrucData == NULL) {
/* we need to obtain the object first */
CHKiRet(rsCStrConstruct(&pMsg->pCSStrucData));
rsCStrSetAllocIncrement(pMsg->pCSStrucData, 128);
}
/* if we reach this point, we have the object */
iRet = rsCStrSetSzStr(pMsg->pCSStrucData, (uchar*) pszStrucData);
finalize_it:
RETiRet;
}
/* get the length of the "STRUCTURED-DATA" sz string
* rgerhards, 2005-11-24
*/
#if 0 /* This method is currently not called, be we like to preserve it */
static int getStructuredDataLen(msg_t *pM)
{
return (pM->pCSStrucData == NULL) ? 1 : rsCStrLen(pM->pCSStrucData);
}
#endif
/* get the "STRUCTURED-DATA" as sz string
* rgerhards, 2005-11-24
*/
char *getStructuredData(msg_t *pM)
{
return (pM->pCSStrucData == NULL) ? "-" : (char*) rsCStrGetSzStrNoNULL(pM->pCSStrucData);
}
/* get the length of the "programname" sz string
* rgerhards, 2005-10-19
*/
int getProgramNameLen(msg_t *pM)
{
int iRet;
assert(pM != NULL);
MsgLock(pM);
if((iRet = aquireProgramName(pM)) != RS_RET_OK) {
dbgprintf("error %d returned by aquireProgramName() in getProgramNameLen()\n", iRet);
MsgUnlock(pM);
return 0; /* best we can do (consistent wiht what getProgramName() returns) */
}
MsgUnlock(pM);
return (pM->pCSProgName == NULL) ? 0 : rsCStrLen(pM->pCSProgName);
}
/* get the "programname" as sz string
* rgerhards, 2005-10-19
*/
char *getProgramName(msg_t *pM) /* this is the non-locking version for internal use */
{
int iRet;
char *pszRet;
assert(pM != NULL);
MsgLock(pM);
if((iRet = aquireProgramName(pM)) != RS_RET_OK) {
dbgprintf("error %d returned by aquireProgramName() in getProgramName()\n", iRet);
pszRet = ""; /* best we can do */
} else {
pszRet = (pM->pCSProgName == NULL) ? "" : (char*) rsCStrGetSzStrNoNULL(pM->pCSProgName);
}
MsgUnlock(pM);
return pszRet;
}
/* The code below was an approach without PTHREAD_MUTEX_RECURSIVE
* However, it turned out to be quite complex. So far, we use recursive
* locking, which is OK from a performance point of view, especially as
* we do not anticipate that multithreading msg objects is used often.
* However, we may re-think about using non-recursive locking and I leave this
* code in here to conserve the idea. -- rgerhards, 2008-01-05
*/
#if 0
static char *getProgramNameNoLock(msg_t *pM) /* this is the non-locking version for internal use */
{
int iRet;
assert(pM != NULL);
if((iRet = aquireProgramName(pM)) != RS_RET_OK) {
dbgprintf("error %d returned by aquireProgramName() in getProgramName()\n", iRet);
return ""; /* best we can do */
}
return (pM->pCSProgName == NULL) ? "" : (char*) rsCStrGetSzStrNoNULL(pM->pCSProgName);
}
char *getProgramName(msg_t *pM) /* this is the external callable version */
{
char *pszRet;
MsgLock(pM);
pszRet = getProgramNameNoLock(pM);
MsgUnlock(pM);
return pszRet;
}
/* an alternative approach has been: */
/* The macro below is used to generate external function definitions
* for such functions that may also be called internally (and thus have
* both a locking and non-locking implementation. Over time, we could
* reconsider how we handle that. -- rgerhards, 2008-01-05
*/
#define EXT_LOCKED_FUNC(fName, ret) \
ret fName(msg_t *pM) \
{ \
ret valRet; \
MsgLock(pM); \
valRet = fName##NoLock(pM); \
MsgUnlock(pM); \
return(valRet); \
}
EXT_LOCKED_FUNC(getProgramName, char*)
/* in this approach, the external function is provided by the macro and
* needs not to be writen.
*/
#endif /* #if 0 -- saved code */
/* This function tries to emulate APPNAME if it is not present. Its
* main use is when we have received a log record via legacy syslog and
* now would like to send out the same one via syslog-protocol.
*/
static void tryEmulateAPPNAME(msg_t *pM)
{
assert(pM != NULL);
if(pM->pCSAPPNAME != NULL)
return; /* we are already done */
if(getProtocolVersion(pM) == 0) {
/* only then it makes sense to emulate */
MsgSetAPPNAME(pM, getProgramName(pM));
}
}
/* rgerhards, 2005-11-24
*/
static int getAPPNAMELen(msg_t *pM)
{
assert(pM != NULL);
if(pM->pCSAPPNAME == NULL)
tryEmulateAPPNAME(pM);
return (pM->pCSAPPNAME == NULL) ? 0 : rsCStrLen(pM->pCSAPPNAME);
}
/* rgerhards 2004-11-16: set pszRcvFrom in msg object
*/
void MsgSetRcvFrom(msg_t *pMsg, char* pszRcvFrom)
{
assert(pMsg != NULL);
if(pMsg->pszRcvFrom != NULL)
free(pMsg->pszRcvFrom);
pMsg->iLenRcvFrom = strlen(pszRcvFrom);
if((pMsg->pszRcvFrom = malloc(pMsg->iLenRcvFrom + 1)) != NULL) {
memcpy(pMsg->pszRcvFrom, pszRcvFrom, pMsg->iLenRcvFrom + 1);
}
}
/* Set the HOSTNAME to a caller-provided string. This is thought
* to be a heap buffer that the caller will no longer use. This
* function is a performance optimization over MsgSetHOSTNAME().
* rgerhards 2004-11-19
*/
void MsgAssignHOSTNAME(msg_t *pMsg, char *pBuf)
{
assert(pMsg != NULL);
assert(pBuf != NULL);
pMsg->iLenHOSTNAME = strlen(pBuf);
pMsg->pszHOSTNAME = (uchar*) pBuf;
}
/* rgerhards 2004-11-09: set HOSTNAME in msg object
* rgerhards, 2007-06-21:
* Does not return anything. If an error occurs, the hostname is
* simply not set. I have changed this behaviour. The only problem
* we can run into is memory shortage. If we have such, it is better
* to loose the hostname than the full message. So we silently ignore
* that problem and hope that memory will be available the next time
* we need it. The rest of the code already knows how to handle an
* unset HOSTNAME.
*/
void MsgSetHOSTNAME(msg_t *pMsg, char* pszHOSTNAME)
{
assert(pMsg != NULL);
if(pMsg->pszHOSTNAME != NULL)
free(pMsg->pszHOSTNAME);
pMsg->iLenHOSTNAME = strlen(pszHOSTNAME);
if((pMsg->pszHOSTNAME = malloc(pMsg->iLenHOSTNAME + 1)) != NULL)
memcpy(pMsg->pszHOSTNAME, pszHOSTNAME, pMsg->iLenHOSTNAME + 1);
else
dbgprintf("Could not allocate memory in MsgSetHOSTNAME()\n");
}
/* Set the UxTradMsg to a caller-provided string. This is thought
* to be a heap buffer that the caller will no longer use. This
* function is a performance optimization over MsgSetUxTradMsg().
* rgerhards 2004-11-19
*/
#if 0 /* This method is currently not called, be we like to preserve it */
static void MsgAssignUxTradMsg(msg_t *pMsg, char *pBuf)
{
assert(pMsg != NULL);
assert(pBuf != NULL);
pMsg->iLenUxTradMsg = strlen(pBuf);
pMsg->pszUxTradMsg = pBuf;
}
#endif
/* rgerhards 2004-11-17: set the traditional Unix message in msg object
*/
int MsgSetUxTradMsg(msg_t *pMsg, char* pszUxTradMsg)
{
assert(pMsg != NULL);
assert(pszUxTradMsg != NULL);
pMsg->iLenUxTradMsg = strlen(pszUxTradMsg);
if(pMsg->pszUxTradMsg != NULL)
free(pMsg->pszUxTradMsg);
if((pMsg->pszUxTradMsg = malloc(pMsg->iLenUxTradMsg + 1)) != NULL)
memcpy(pMsg->pszUxTradMsg, pszUxTradMsg, pMsg->iLenUxTradMsg + 1);
else
dbgprintf("Could not allocate memory for pszUxTradMsg buffer.");
return(0);
}
/* rgerhards 2004-11-09: set MSG in msg object
*/
void MsgSetMSG(msg_t *pMsg, char* pszMSG)
{
assert(pMsg != NULL);
assert(pszMSG != NULL);
if(pMsg->pszMSG != NULL)
free(pMsg->pszMSG);
pMsg->iLenMSG = strlen(pszMSG);
if((pMsg->pszMSG = (uchar*) malloc(pMsg->iLenMSG + 1)) != NULL)
memcpy(pMsg->pszMSG, pszMSG, pMsg->iLenMSG + 1);
else
dbgprintf("MsgSetMSG could not allocate memory for pszMSG buffer.");
}
/* rgerhards 2004-11-11: set RawMsg in msg object
*/
void MsgSetRawMsg(msg_t *pMsg, char* pszRawMsg)
{
assert(pMsg != NULL);
if(pMsg->pszRawMsg != NULL)
free(pMsg->pszRawMsg);
pMsg->iLenRawMsg = strlen(pszRawMsg);
if((pMsg->pszRawMsg = (uchar*) malloc(pMsg->iLenRawMsg + 1)) != NULL)
memcpy(pMsg->pszRawMsg, pszRawMsg, pMsg->iLenRawMsg + 1);
else
dbgprintf("Could not allocate memory for pszRawMsg buffer.");
}
/* Decode a priority into textual information like auth.emerg.
* The variable pRes must point to a user-supplied buffer and
* pResLen must contain its size. The pointer to the buffer
* is also returned, what makes this functiona suitable for
* use in printf-like functions.
* Note: a buffer size of 20 characters is always sufficient.
* Interface to this function changed 2007-06-15 by RGerhards
*/
char *textpri(char *pRes, size_t pResLen, int pri)
{
syslogCODE *c_pri, *c_fac;
assert(pRes != NULL);
assert(pResLen > 0);
for (c_fac = rs_facilitynames; c_fac->c_name && !(c_fac->c_val == LOG_FAC(pri)<<3); c_fac++);
for (c_pri = rs_prioritynames; c_pri->c_name && !(c_pri->c_val == LOG_PRI(pri)); c_pri++);
snprintf (pRes, pResLen, "%s.%s<%d>", c_fac->c_name, c_pri->c_name, pri);
return pRes;
}
/* This function returns the current date in different
* variants. It is used to construct the $NOW series of
* system properties. The returned buffer must be freed
* by the caller when no longer needed. If the function
* can not allocate memory, it returns a NULL pointer.
* Added 2007-07-10 rgerhards
*/
typedef enum ENOWType { NOW_NOW, NOW_YEAR, NOW_MONTH, NOW_DAY, NOW_HOUR, NOW_MINUTE } eNOWType;
#define tmpBUFSIZE 16 /* size of formatting buffer */
static uchar *getNOW(eNOWType eNow)
{
uchar *pBuf;
struct syslogTime t;
if((pBuf = (uchar*) malloc(sizeof(uchar) * tmpBUFSIZE)) == NULL) {
glblHadMemShortage = 1;
return NULL;
}
getCurrTime(&t);
switch(eNow) {
case NOW_NOW:
snprintf((char*) pBuf, tmpBUFSIZE, "%4.4d-%2.2d-%2.2d", t.year, t.month, t.day);
break;
case NOW_YEAR:
snprintf((char*) pBuf, tmpBUFSIZE, "%4.4d", t.year);
break;
case NOW_MONTH:
snprintf((char*) pBuf, tmpBUFSIZE, "%2.2d", t.month);
break;
case NOW_DAY:
snprintf((char*) pBuf, tmpBUFSIZE, "%2.2d", t.day);
break;
case NOW_HOUR:
snprintf((char*) pBuf, tmpBUFSIZE, "%2.2d", t.hour);
break;
case NOW_MINUTE:
snprintf((char*) pBuf, tmpBUFSIZE, "%2.2d", t.minute);
break;
}
return(pBuf);
}
#undef tmpBUFSIZE /* clean up */
/* This function returns a string-representation of the
* requested message property. This is a generic function used
* to abstract properties so that these can be easier
* queried. Returns NULL if property could not be found.
* Actually, this function is a big if..elseif. What it does
* is simply to map property names (from MonitorWare) to the
* message object data fields.
*
* In case we need string forms of propertis we do not
* yet have in string form, we do a memory allocation that
* is sufficiently large (in all cases). Once the string
* form has been obtained, it is saved until the Msg object
* is finally destroyed. This is so that we save the processing
* time in the (likely) case that this property is requested
* again. It also saves us a lot of dynamic memory management
* issues in the upper layers, because we so can guarantee that
* the buffer will remain static AND available during the lifetime
* of the object. Please note that both the max size allocation as
* well as keeping things in memory might like look like a
* waste of memory (some might say it actually is...) - we
* deliberately accept this because performance is more important
* to us ;)
* rgerhards 2004-11-18
* Parameter "bMustBeFreed" is set by this function. It tells the
* caller whether or not the string returned must be freed by the
* caller itself. It is is 0, the caller MUST NOT free it. If it is
* 1, the caller MUST free 1. Handling this wrongly leads to either
* a memory leak of a program abort (do to double-frees or frees on
* the constant memory pool). So be careful to do it right.
* rgerhards 2004-11-23
* regular expression support contributed by Andres Riancho merged
* on 2005-09-13
* changed so that it now an be called without a template entry (NULL).
* In this case, only the (unmodified) property is returned. This will
* be used in selector line processing.
* rgerhards 2005-09-15
*/
char *MsgGetProp(msg_t *pMsg, struct templateEntry *pTpe,
cstr_t *pCSPropName, unsigned short *pbMustBeFreed)
{
uchar *pName;
char *pRes; /* result pointer */
char *pBufStart;
char *pBuf;
int iLen;
#ifdef FEATURE_REGEXP
/* Variables necessary for regular expression matching */
size_t nmatch = 2;
regmatch_t pmatch[2];
#endif
assert(pMsg != NULL);
assert(pbMustBeFreed != NULL);
if(pCSPropName == NULL) {
assert(pTpe != NULL);
pName = pTpe->data.field.pPropRepl;
} else {
pName = rsCStrGetSzStrNoNULL(pCSPropName);
}
*pbMustBeFreed = 0;
/* sometimes there are aliases to the original MonitoWare
* property names. These come after || in the ifs below. */
if(!strcmp((char*) pName, "msg")) {
pRes = getMSG(pMsg);
} else if(!strcmp((char*) pName, "rawmsg")) {
pRes = getRawMsg(pMsg);
} else if(!strcmp((char*) pName, "UxTradMsg")) {
pRes = getUxTradMsg(pMsg);
} else if(!strcmp((char*) pName, "FROMHOST")) {
pRes = getRcvFrom(pMsg);
} else if(!strcmp((char*) pName, "source")
|| !strcmp((char*) pName, "HOSTNAME")) {
pRes = getHOSTNAME(pMsg);
} else if(!strcmp((char*) pName, "syslogtag")) {
pRes = getTAG(pMsg);
} else if(!strcmp((char*) pName, "PRI")) {
pRes = getPRI(pMsg);
} else if(!strcmp((char*) pName, "PRI-text")) {
pBuf = malloc(20 * sizeof(char));
if(pBuf == NULL) {
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
} else {
*pbMustBeFreed = 1;
pRes = textpri(pBuf, 20, getPRIi(pMsg));
}
} else if(!strcmp((char*) pName, "iut")) {
pRes = "1"; /* always 1 for syslog messages (a MonitorWare thing;)) */
} else if(!strcmp((char*) pName, "syslogfacility")) {
pRes = getFacility(pMsg);
} else if(!strcmp((char*) pName, "syslogfacility-text")) {
pRes = getFacilityStr(pMsg);
} else if(!strcmp((char*) pName, "syslogseverity") || !strcmp((char*) pName, "syslogpriority")) {
pRes = getSeverity(pMsg);
} else if(!strcmp((char*) pName, "syslogseverity-text") || !strcmp((char*) pName, "syslogpriority-text")) {
pRes = getSeverityStr(pMsg);
} else if(!strcmp((char*) pName, "timegenerated")) {
pRes = getTimeGenerated(pMsg, pTpe->data.field.eDateFormat);
} else if(!strcmp((char*) pName, "timereported")
|| !strcmp((char*) pName, "TIMESTAMP")) {
pRes = getTimeReported(pMsg, pTpe->data.field.eDateFormat);
} else if(!strcmp((char*) pName, "programname")) {
pRes = getProgramName(pMsg);
} else if(!strcmp((char*) pName, "PROTOCOL-VERSION")) {
pRes = getProtocolVersionString(pMsg);
} else if(!strcmp((char*) pName, "STRUCTURED-DATA")) {
pRes = getStructuredData(pMsg);
} else if(!strcmp((char*) pName, "APP-NAME")) {
pRes = getAPPNAME(pMsg);
} else if(!strcmp((char*) pName, "PROCID")) {
pRes = getPROCID(pMsg);
} else if(!strcmp((char*) pName, "MSGID")) {
pRes = getMSGID(pMsg);
/* here start system properties (those, that do not relate to the message itself */
} else if(!strcmp((char*) pName, "$NOW")) {
if((pRes = (char*) getNOW(NOW_NOW)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else if(!strcmp((char*) pName, "$YEAR")) {
if((pRes = (char*) getNOW(NOW_YEAR)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else if(!strcmp((char*) pName, "$MONTH")) {
if((pRes = (char*) getNOW(NOW_MONTH)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else if(!strcmp((char*) pName, "$DAY")) {
if((pRes = (char*) getNOW(NOW_DAY)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else if(!strcmp((char*) pName, "$HOUR")) {
if((pRes = (char*) getNOW(NOW_HOUR)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else if(!strcmp((char*) pName, "$MINUTE")) {
if((pRes = (char*) getNOW(NOW_MINUTE)) == NULL) {
return "***OUT OF MEMORY***";
} else
*pbMustBeFreed = 1; /* all of these functions allocate dyn. memory */
} else {
/* there is no point in continuing, we may even otherwise render the
* error message unreadable. rgerhards, 2007-07-10
*/
return "**INVALID PROPERTY NAME**";
}
/* If we did not receive a template pointer, we are already done... */
if(pTpe == NULL) {
return pRes;
}
/* Now check if we need to make "temporary" transformations (these
* are transformations that do not go back into the message -
* memory must be allocated for them!).
*/
/* substring extraction */
/* first we check if we need to extract by field number
* rgerhards, 2005-12-22
*/
if(pTpe->data.field.has_fields == 1) {
size_t iCurrFld;
char *pFld;
char *pFldEnd;
/* first, skip to the field in question. The field separator
* is always one character and is stored in the template entry.
*/
iCurrFld = 1;
pFld = pRes;
while(*pFld && iCurrFld < pTpe->data.field.iToPos) {
/* skip fields until the requested field or end of string is found */
while(*pFld && (uchar) *pFld != pTpe->data.field.field_delim)
++pFld; /* skip to field terminator */
if(*pFld == pTpe->data.field.field_delim) {
++pFld; /* eat it */
++iCurrFld;
}
}
dbgprintf("field requested %d, field found %d\n", pTpe->data.field.iToPos, (int) iCurrFld);
if(iCurrFld == pTpe->data.field.iToPos) {
/* field found, now extract it */
/* first of all, we need to find the end */
pFldEnd = pFld;
while(*pFldEnd && *pFldEnd != pTpe->data.field.field_delim)
++pFldEnd;
--pFldEnd; /* we are already at the delimiter - so we need to
* step back a little not to copy it as part of the field. */
/* we got our end pointer, now do the copy */
/* TODO: code copied from below, this is a candidate for a separate function */
iLen = pFldEnd - pFld + 1; /* the +1 is for an actual char, NOT \0! */
pBufStart = pBuf = malloc((iLen + 1) * sizeof(char));
if(pBuf == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
/* now copy */
memcpy(pBuf, pFld, iLen);
pBuf[iLen] = '\0'; /* terminate it */
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pBufStart;
*pbMustBeFreed = 1;
if(*(pFldEnd+1) != '\0')
++pFldEnd; /* OK, skip again over delimiter char */
} else {
/* field not found, return error */
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**FIELD NOT FOUND**";
}
} else if(pTpe->data.field.iFromPos != 0 || pTpe->data.field.iToPos != 0) {
/* we need to obtain a private copy */
int iFrom, iTo;
char *pSb;
iFrom = pTpe->data.field.iFromPos;
iTo = pTpe->data.field.iToPos;
/* need to zero-base to and from (they are 1-based!) */
if(iFrom > 0)
--iFrom;
if(iTo > 0)
--iTo;
iLen = iTo - iFrom + 1; /* the +1 is for an actual char, NOT \0! */
pBufStart = pBuf = malloc((iLen + 1) * sizeof(char));
if(pBuf == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
pSb = pRes;
if(iFrom) {
/* skip to the start of the substring (can't do pointer arithmetic
* because the whole string might be smaller!!)
*/
while(*pSb && iFrom) {
--iFrom;
++pSb;
}
}
/* OK, we are at the begin - now let's copy... */
while(*pSb && iLen) {
*pBuf++ = *pSb;
++pSb;
--iLen;
}
*pBuf = '\0';
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pBufStart;
*pbMustBeFreed = 1;
#ifdef FEATURE_REGEXP
} else {
/* Check for regular expressions */
if (pTpe->data.field.has_regex != 0) {
if (pTpe->data.field.has_regex == 2)
/* Could not compile regex before! */
return
"**NO MATCH** **BAD REGULAR EXPRESSION**";
dbgprintf("debug: String to match for regex is: %s\n",
pRes);
if (0 != regexec(&pTpe->data.field.re, pRes, nmatch,
pmatch, 0)) {
/* we got no match! */
return "**NO MATCH**";
} else {
/* Match! */
/* I need to malloc pB */
int iLenBuf;
char *pB;
iLenBuf = pmatch[1].rm_eo - pmatch[1].rm_so;
pB = (char *) malloc((iLenBuf + 1) * sizeof(char));
if (pB == NULL) {
if (*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY ALLOCATING pBuf**";
}
/* Lets copy the matched substring to the buffer */
memcpy(pB, pRes + pmatch[1].rm_so, iLenBuf);
pB[iLenBuf] = '\0';/* terminate string, did not happen before */
if (*pbMustBeFreed == 1)
free(pRes);
pRes = pB;
*pbMustBeFreed = 1;
}
}
#endif /* #ifdef FEATURE_REGEXP */
}
if(*pRes) {
/* case conversations (should go after substring, because so we are able to
* work on the smallest possible buffer).
*/
if(pTpe->data.field.eCaseConv != tplCaseConvNo) {
/* we need to obtain a private copy */
int iBufLen = strlen(pRes);
char *pBStart;
char *pB;
char *pSrc;
pBStart = pB = malloc((iBufLen + 1) * sizeof(char));
if(pB == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
pSrc = pRes;
while(*pSrc) {
*pB++ = (pTpe->data.field.eCaseConv == tplCaseConvUpper) ?
(char)toupper((int)*pSrc) : (char)tolower((int)*pSrc);
/* currently only these two exist */
++pSrc;
}
*pB = '\0';
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pBStart;
*pbMustBeFreed = 1;
}
/* now do control character dropping/escaping/replacement
* Only one of these can be used. If multiple options are given, the
* result is random (though currently there obviously is an order of
* preferrence, see code below. But this is NOT guaranteed.
* RGerhards, 2006-11-17
* We must copy the strings if we modify them, because they may either
* point to static memory or may point into the message object, in which
* case we would actually modify the original property (which of course
* is wrong).
* This was found and fixed by varmojefkoj on 2007-09-11
*/
if(pTpe->data.field.options.bDropCC) {
int iLenBuf = 0;
char *pSrc = pRes;
char *pDstStart;
char *pDst;
char bDropped = 0;
while(*pSrc) {
if(!iscntrl((int) *pSrc++))
iLenBuf++;
else
bDropped = 1;
}
if(bDropped) {
pDst = pDstStart = malloc(iLenBuf + 1);
if(pDst == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
for(pSrc = pRes; *pSrc; pSrc++) {
if(!iscntrl((int) *pSrc))
*pDst++ = *pSrc;
}
*pDst = '\0';
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pDstStart;
*pbMustBeFreed = 1;
}
} else if(pTpe->data.field.options.bSpaceCC) {
char *pSrc;
char *pDstStart;
char *pDst;
if(*pbMustBeFreed == 1) {
/* in this case, we already work on dynamic
* memory, so there is no need to copy it - we can
* modify it in-place without any harm. This is a
* performance optiomization.
*/
for(pDst = pRes; *pDst; pDst++) {
if(iscntrl((int) *pDst))
*pDst = ' ';
}
} else {
pDst = pDstStart = malloc(strlen(pRes) + 1);
if(pDst == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
for(pSrc = pRes; *pSrc; pSrc++) {
if(iscntrl((int) *pSrc))
*pDst++ = ' ';
else
*pDst++ = *pSrc;
}
*pDst = '\0';
pRes = pDstStart;
*pbMustBeFreed = 1;
}
} else if(pTpe->data.field.options.bEscapeCC) {
/* we must first count how many control charactes are
* present, because we need this to compute the new string
* buffer length. While doing so, we also compute the string
* length.
*/
int iNumCC = 0;
int iLenBuf = 0;
char *pB;
for(pB = pRes ; *pB ; ++pB) {
++iLenBuf;
if(iscntrl((int) *pB))
++iNumCC;
}
if(iNumCC > 0) { /* if 0, there is nothing to escape, so we are done */
/* OK, let's do the escaping... */
char *pBStart;
char szCCEsc[8]; /* buffer for escape sequence */
int i;
iLenBuf += iNumCC * 4;
pBStart = pB = malloc((iLenBuf + 1) * sizeof(char));
if(pB == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
while(*pRes) {
if(iscntrl((int) *pRes)) {
snprintf(szCCEsc, sizeof(szCCEsc), "#%3.3d", *pRes);
for(i = 0 ; i < 4 ; ++i)
*pB++ = szCCEsc[i];
} else {
*pB++ = *pRes;
}
++pRes;
}
*pB = '\0';
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pBStart;
*pbMustBeFreed = 1;
}
}
}
/* Take care of spurious characters to make the property safe
* for a path definition
*/
if(pTpe->data.field.options.bSecPathDrop || pTpe->data.field.options.bSecPathReplace) {
if(pTpe->data.field.options.bSecPathDrop) {
int iLenBuf = 0;
char *pSrc = pRes;
char *pDstStart;
char *pDst;
char bDropped = 0;
while(*pSrc) {
if(*pSrc++ != '/')
iLenBuf++;
else
bDropped = 1;
}
if(bDropped) {
pDst = pDstStart = malloc(iLenBuf + 1);
if(pDst == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
for(pSrc = pRes; *pSrc; pSrc++) {
if(*pSrc != '/')
*pDst++ = *pSrc;
}
*pDst = '\0';
if(*pbMustBeFreed == 1)
free(pRes);
pRes = pDstStart;
*pbMustBeFreed = 1;
}
} else {
char *pSrc;
char *pDstStart;
char *pDst;
if(*pbMustBeFreed == 1) {
/* here, again, we can modify the string as we already obtained
* a private buffer. As we do not change the size of that buffer,
* in-place modification is possible. This is a performance
* enhancement.
*/
for(pDst = pRes; *pDst; pDst++) {
if(*pDst == '/')
*pDst++ = '_';
}
} else {
pDst = pDstStart = malloc(strlen(pRes) + 1);
if(pDst == NULL) {
if(*pbMustBeFreed == 1)
free(pRes);
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
for(pSrc = pRes; *pSrc; pSrc++) {
if(*pSrc == '/')
*pDst++ = '_';
else
*pDst++ = *pSrc;
}
*pDst = '\0';
/* we must NOT check if it needs to be freed, because we have done
* this in the if above. So if we come to hear, the pSrc string needs
* not to be freed (and we do not need to care about it).
*/
pRes = pDstStart;
*pbMustBeFreed = 1;
}
}
/* check for "." and ".." (note the parenthesis in the if condition!) */
if((*pRes == '.') && (*(pRes + 1) == '\0' || (*(pRes + 1) == '.' && *(pRes + 2) == '\0'))) {
char *pTmp = pRes;
if(*(pRes + 1) == '\0')
pRes = "_";
else
pRes = "_.";;
if(*pbMustBeFreed == 1)
free(pTmp);
*pbMustBeFreed = 0;
} else if(*pRes == '\0') {
if(*pbMustBeFreed == 1)
free(pRes);
pRes = "_";
*pbMustBeFreed = 0;
}
}
/* Now drop last LF if present (pls note that this must not be done
* if bEscapeCC was set!
*/
if(pTpe->data.field.options.bDropLastLF && !pTpe->data.field.options.bEscapeCC) {
int iLn = strlen(pRes);
char *pB;
if(iLn > 0 && *(pRes + iLn - 1) == '\n') {
/* we have a LF! */
/* check if we need to obtain a private copy */
if(*pbMustBeFreed == 0) {
/* ok, original copy, need a private one */
pB = malloc((iLn + 1) * sizeof(char));
if(pB == NULL) {
*pbMustBeFreed = 0;
return "**OUT OF MEMORY**";
}
memcpy(pB, pRes, iLn - 1);
pRes = pB;
*pbMustBeFreed = 1;
}
*(pRes + iLn - 1) = '\0'; /* drop LF ;) */
}
}
/*dbgprintf("MsgGetProp(\"%s\"): \"%s\"\n", pName, pRes); only for verbose debug logging */
return(pRes);
}
/* This function can be used as a generic way to set properties.
* We have to handle a lot of legacy, so our return value is not always
* 100% correct (called functions do not always provide one, should
* change over time).
* rgerhards, 2008-01-07
*/
#define isProp(name) !rsCStrSzStrCmp(pProp->pcsName, (uchar*) name, sizeof(name) - 1)
rsRetVal MsgSetProperty(msg_t *pThis, var_t *pProp)
{
DEFiRet;
ISOBJ_TYPE_assert(pThis, msg);
assert(pProp != NULL);
if(isProp("iProtocolVersion")) {
setProtocolVersion(pThis, pProp->val.vShort);
} else if(isProp("iSeverity")) {
pThis->iSeverity = pProp->val.vShort;
} else if(isProp("iFacility")) {
pThis->iFacility = pProp->val.vShort;
} else if(isProp("msgFlags")) {
pThis->msgFlags = pProp->val.vInt;
} else if(isProp("pszRawMsg")) {
MsgSetRawMsg(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pszMSG")) {
MsgSetMSG(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pszUxTradMsg")) {
MsgSetUxTradMsg(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pszTAG")) {
MsgSetTAG(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pszRcvFrom")) {
MsgSetHOSTNAME(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pszHOSTNAME")) {
MsgSetRcvFrom(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pCSStrucData")) {
MsgSetStructuredData(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pCSAPPNAME")) {
MsgSetAPPNAME(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pCSPROCID")) {
MsgSetPROCID(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("pCSMSGID")) {
MsgSetMSGID(pThis, (char*) rsCStrGetSzStrNoNULL(pProp->val.vpCStr));
} else if(isProp("tRcvdAt")) {
memcpy(&pThis->tRcvdAt, &pProp->val.vSyslogTime, sizeof(struct syslogTime));
} else if(isProp("tTIMESTAMP")) {
memcpy(&pThis->tTIMESTAMP, &pProp->val.vSyslogTime, sizeof(struct syslogTime));
}
RETiRet;
}
#undef isProp
/* This is a construction finalizer that must be called after all properties
* have been set. It does some final work on the message object. After this
* is done, the object is considered ready for full processing.
* rgerhards, 2008-07-08
*/
static rsRetVal msgConstructFinalizer(msg_t *pThis)
{
MsgPrepareEnqueue(pThis);
return RS_RET_OK;
}
/* get the severity - this is an entry point that
* satisfies the base object class getSeverity semantics.
* rgerhards, 2008-01-14
*/
static rsRetVal
MsgGetSeverity(obj_t *pThis, int *piSeverity)
{
ISOBJ_TYPE_assert(pThis, msg);
assert(piSeverity != NULL);
*piSeverity = ((msg_t*) pThis)->iSeverity;
return RS_RET_OK;
}
/* Initialize the message class. Must be called as the very first method
* before anything else is called inside this class.
* rgerhards, 2008-01-04
*/
BEGINObjClassInit(msg, 1)
OBJSetMethodHandler(objMethod_SERIALIZE, MsgSerialize);
OBJSetMethodHandler(objMethod_SETPROPERTY, MsgSetProperty);
OBJSetMethodHandler(objMethod_CONSTRUCTION_FINALIZER, msgConstructFinalizer);
OBJSetMethodHandler(objMethod_GETSEVERITY, MsgGetSeverity);
/* initially, we have no need to lock message objects */
funcLock = MsgLockingDummy;
funcUnlock = MsgLockingDummy;
funcDeleteMutex = MsgLockingDummy;
funcMsgPrepareEnqueue = MsgLockingDummy;
ENDObjClassInit(msg)
/*
* vi:set ai:
*/