/* rainerscript.c - routines to support RainerScript config language
*
* Module begun 2011-07-01 by Rainer Gerhards
*
* Copyright 2011 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
#include
#include
#include
#include
#include "rsyslog.h"
#include "rainerscript.h"
#include "parserif.h"
#include "grammar.h"
#include "queue.h"
#include "srUtils.h"
#include "regexp.h"
#include "obj.h"
DEFobjCurrIf(obj)
DEFobjCurrIf(regexp)
void
readConfFile(FILE *fp, es_str_t **str)
{
char ln[10240];
char buf[512];
int lenBuf;
int bWriteLineno = 0;
int len, i;
int start; /* start index of to be submitted text */
int bContLine = 0;
int lineno = 0;
*str = es_newStr(4096);
while(fgets(ln, sizeof(ln), fp) != NULL) {
++lineno;
if(bWriteLineno) {
bWriteLineno = 0;
lenBuf = sprintf(buf, "PreprocFileLineNumber(%d)\n", lineno);
es_addBuf(str, buf, lenBuf);
}
len = strlen(ln);
/* if we are continuation line, we need to drop leading WS */
if(bContLine) {
for(start = 0 ; start < len && isspace(ln[start]) ; ++start)
/* JUST SCAN */;
} else {
start = 0;
}
for(i = len - 1 ; i >= start && isspace(ln[i]) ; --i)
/* JUST SCAN */;
if(i >= 0) {
if(ln[i] == '\\') {
--i;
bContLine = 1;
} else {
if(bContLine) /* write line number if we had cont line */
bWriteLineno = 1;
bContLine = 0;
}
/* add relevant data to buffer */
es_addBuf(str, ln+start, i+1 - start);
}
if(!bContLine)
es_addChar(str, '\n');
}
/* indicate end of buffer to flex */
es_addChar(str, '\0');
es_addChar(str, '\0');
}
struct nvlst*
nvlstNew(es_str_t *name, es_str_t *value)
{
struct nvlst *lst;
if((lst = malloc(sizeof(struct nvlst))) != NULL) {
lst->next = NULL;
lst->name = name;
lst->val.datatype = 'S';
lst->val.d.estr = value;
lst->bUsed = 0;
}
return lst;
}
void
nvlstDestruct(struct nvlst *lst)
{
struct nvlst *toDel;
while(lst != NULL) {
toDel = lst;
lst = lst->next;
es_deleteStr(toDel->name);
if(toDel->val.datatype == 'S')
es_deleteStr(toDel->val.d.estr);
free(toDel);
}
}
void
nvlstPrint(struct nvlst *lst)
{
char *name, *value;
dbgprintf("nvlst %p:\n", lst);
while(lst != NULL) {
name = es_str2cstr(lst->name, NULL);
// TODO: support for non-string types
value = es_str2cstr(lst->val.d.estr, NULL);
dbgprintf("\tname: '%s', value '%s'\n", name, value);
free(name);
free(value);
lst = lst->next;
}
}
/* find a name starting at node lst. Returns node with this
* name or NULL, if none found.
*/
struct nvlst*
nvlstFindName(struct nvlst *lst, es_str_t *name)
{
while(lst != NULL && es_strcmp(lst->name, name))
lst = lst->next;
return lst;
}
/* find a name starting at node lst. Same as nvlstFindName, but
* for classical C strings. This is useful because the config system
* uses C string constants.
*/
static inline struct nvlst*
nvlstFindNameCStr(struct nvlst *lst, char *name)
{
es_size_t lenName = strlen(name);
while(lst != NULL && es_strcasebufcmp(lst->name, (uchar*)name, lenName))
lst = lst->next;
return lst;
}
/* check if there are duplicate names inside a nvlst and emit
* an error message, if so.
*/
static inline void
nvlstChkDupes(struct nvlst *lst)
{
char *cstr;
while(lst != NULL) {
if(nvlstFindName(lst->next, lst->name) != NULL) {
cstr = es_str2cstr(lst->name, NULL);
parser_errmsg("duplicate parameter '%s' -- "
"interpretation is ambigious, one value "
"will be randomly selected. Fix this problem.",
cstr);
free(cstr);
}
lst = lst->next;
}
}
/* check for unused params and emit error message is found. This must
* be called after all config params have been pulled from the object
* (otherwise the flags are not correctly set).
*/
void
nvlstChkUnused(struct nvlst *lst)
{
char *cstr;
while(lst != NULL) {
if(!lst->bUsed) {
cstr = es_str2cstr(lst->name, NULL);
parser_errmsg("parameter '%s' not known -- "
"typo in config file?",
cstr);
free(cstr);
}
lst = lst->next;
}
}
static inline void
doGetSize(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
unsigned char *c;
es_size_t i;
long long n;
c = es_getBufAddr(valnode->val.d.estr);
n = 0;
i = 0;
while(i < es_strlen(valnode->val.d.estr) && isdigit(*c)) {
n = 10 * n + *c - '0';
++i;
++c;
}
if(i < es_strlen(valnode->val.d.estr)) {
++i;
switch(*c) {
/* traditional binary-based definitions */
case 'k': n *= 1024; break;
case 'm': n *= 1024 * 1024; break;
case 'g': n *= 1024 * 1024 * 1024; break;
case 't': n *= (int64) 1024 * 1024 * 1024 * 1024; break; /* tera */
case 'p': n *= (int64) 1024 * 1024 * 1024 * 1024 * 1024; break; /* peta */
case 'e': n *= (int64) 1024 * 1024 * 1024 * 1024 * 1024 * 1024; break; /* exa */
/* and now the "new" 1000-based definitions */
case 'K': n *= 1000; break;
case 'M': n *= 1000000; break;
case 'G': n *= 1000000000; break;
/* we need to use the multiplication below because otherwise
* the compiler gets an error during constant parsing */
case 'T': n *= (int64) 1000 * 1000000000; break; /* tera */
case 'P': n *= (int64) 1000000 * 1000000000; break; /* peta */
case 'E': n *= (int64) 1000000000 * 1000000000; break; /* exa */
default: --i; break; /* indicates error */
}
}
if(i == es_strlen(valnode->val.d.estr)) {
val->val.datatype = 'N';
val->val.d.n = n;
} else {
parser_errmsg("parameter '%s' does not contain a valid size",
param->name);
}
}
static inline void
doGetBinary(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
val->val.datatype = 'N';
if(!es_strbufcmp(valnode->val.d.estr, (unsigned char*) "on", 2)) {
val->val.d.n = 1;
} else if(!es_strbufcmp(valnode->val.d.estr, (unsigned char*) "off", 3)) {
val->val.d.n = 0;
} else {
parser_errmsg("parameter '%s' must be \"on\" or \"off\" but "
"is neither. Results unpredictable.", param->name);
val->val.d.n = 0;
}
}
static inline void
doGetQueueType(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
char *cstr;
if(!es_strcasebufcmp(valnode->val.d.estr, (uchar*)"fixedarray", 10)) {
val->val.d.n = QUEUETYPE_FIXED_ARRAY;
} else if(!es_strcasebufcmp(valnode->val.d.estr, (uchar*)"linkedlist", 10)) {
val->val.d.n = QUEUETYPE_LINKEDLIST;
} else if(!es_strcasebufcmp(valnode->val.d.estr, (uchar*)"disk", 4)) {
val->val.d.n = QUEUETYPE_DISK;
} else if(!es_strcasebufcmp(valnode->val.d.estr, (uchar*)"direct", 6)) {
val->val.d.n = QUEUETYPE_DIRECT;
} else {
cstr = es_str2cstr(valnode->val.d.estr, NULL);
parser_errmsg("param '%s': unknown queue type: '%s'",
param->name, cstr);
free(cstr);
}
val->val.datatype = 'N';
}
/* A file create-mode must be a four-digit octal number
* starting with '0'.
*/
static inline void
doGetFileCreateMode(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
int fmtOK = 0;
char *cstr;
uchar *c;
if(es_strlen(valnode->val.d.estr) == 4) {
c = es_getBufAddr(valnode->val.d.estr);
if(!( (c[0] == '0')
&& (c[1] >= '0' && c[1] <= '7')
&& (c[2] >= '0' && c[2] <= '7')
&& (c[3] >= '0' && c[3] <= '7') ) ) {
fmtOK = 1;
}
}
if(fmtOK) {
val->val.datatype = 'N';
val->val.d.n = (c[1]-'0') * 64 + (c[2]-'0') * 8 + (c[3]-'0');;
} else {
cstr = es_str2cstr(valnode->val.d.estr, NULL);
parser_errmsg("file modes need to be specified as "
"4-digit octal numbers starting with '0' -"
"parameter '%s=\"%s\"' is not a file mode",
param->name, cstr);
free(cstr);
}
}
static inline void
doGetGID(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
char *cstr;
struct group *resultBuf;
struct group wrkBuf;
char stringBuf[2048]; /* 2048 has been proven to be large enough */
cstr = es_str2cstr(valnode->val.d.estr, NULL);
getgrnam_r(cstr, &wrkBuf, stringBuf, sizeof(stringBuf), &resultBuf);
if(resultBuf == NULL) {
parser_errmsg("parameter '%s': ID for group %s could not "
"be found", param->name, cstr);
} else {
val->val.datatype = 'N';
val->val.d.n = resultBuf->gr_gid;
dbgprintf("param '%s': uid %d obtained for group '%s'\n",
param->name, (int) resultBuf->gr_gid, cstr);
}
free(cstr);
}
static inline void
doGetUID(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
char *cstr;
struct passwd *resultBuf;
struct passwd wrkBuf;
char stringBuf[2048]; /* 2048 has been proven to be large enough */
cstr = es_str2cstr(valnode->val.d.estr, NULL);
getpwnam_r(cstr, &wrkBuf, stringBuf, sizeof(stringBuf), &resultBuf);
if(resultBuf == NULL) {
parser_errmsg("parameter '%s': ID for user %s could not "
"be found", param->name, cstr);
} else {
val->val.datatype = 'N';
val->val.d.n = resultBuf->pw_uid;
dbgprintf("param '%s': uid %d obtained for user '%s'\n",
param->name, (int) resultBuf->pw_uid, cstr);
}
free(cstr);
}
/* note: we support all integer formats that es_str2num support,
* so hex and octal representations are also valid.
*/
static inline void
doGetInt(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
long long n;
int bSuccess;
n = es_str2num(valnode->val.d.estr, &bSuccess);
if(!bSuccess) {
parser_errmsg("parameter '%s' is not a proper number",
param->name);
}
val->val.datatype = 'N';
val->val.d.n = n;
}
static inline void
doGetWord(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
es_size_t i;
unsigned char *c;
val->val.datatype = 'S';
val->val.d.estr = es_newStr(32);
c = es_getBufAddr(valnode->val.d.estr);
for(i = 0 ; i < es_strlen(valnode->val.d.estr) && !isspace(c[i]) ; ++i) {
es_addChar(&val->val.d.estr, c[i]);
}
if(i != es_strlen(valnode->val.d.estr)) {
parser_errmsg("parameter '%s' contains whitespace, which is not "
"permitted - data after first whitespace ignored",
param->name);
}
}
static inline void
doGetChar(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
if(es_strlen(valnode->val.d.estr) != 1) {
parser_errmsg("parameter '%s' must contain exactly one character "
"but contains %d - cannot be processed",
param->name, es_strlen(valnode->val.d.estr));
}
val->val.datatype = 'S';
val->val.d.estr = es_strdup(valnode->val.d.estr);
}
/* get a single parameter according to its definition. Helper to
* nvlstGetParams.
*/
static inline void
nvlstGetParam(struct nvlst *valnode, struct cnfparamdescr *param,
struct cnfparamvals *val)
{
uchar *cstr;
dbgprintf("XXXX: in nvlstGetParam, name '%s', type %d, valnode->bUsed %d\n",
param->name, (int) param->type, valnode->bUsed);
valnode->bUsed = 1;
val->bUsed = 1;
switch(param->type) {
case eCmdHdlrQueueType:
doGetQueueType(valnode, param, val);
break;
case eCmdHdlrUID:
doGetUID(valnode, param, val);
break;
case eCmdHdlrGID:
doGetGID(valnode, param, val);
break;
case eCmdHdlrBinary:
doGetBinary(valnode, param, val);
break;
case eCmdHdlrFileCreateMode:
doGetFileCreateMode(valnode, param, val);
break;
case eCmdHdlrInt:
doGetInt(valnode, param, val);
break;
case eCmdHdlrSize:
doGetSize(valnode, param, val);
break;
case eCmdHdlrGetChar:
doGetChar(valnode, param, val);
break;
case eCmdHdlrFacility:
cstr = (uchar*) es_str2cstr(valnode->val.d.estr, NULL);
val->val.datatype = 'N';
val->val.d.n = decodeSyslogName(cstr, syslogFacNames);
free(cstr);
break;
case eCmdHdlrSeverity:
cstr = (uchar*) es_str2cstr(valnode->val.d.estr, NULL);
val->val.datatype = 'N';
val->val.d.n = decodeSyslogName(cstr, syslogPriNames);
free(cstr);
break;
case eCmdHdlrGetWord:
doGetWord(valnode, param, val);
break;
case eCmdHdlrString:
val->val.datatype = 'S';
val->val.d.estr = es_strdup(valnode->val.d.estr);
break;
case eCmdHdlrGoneAway:
parser_errmsg("parameter '%s' is no longer supported",
param->name);
break;
default:
dbgprintf("error: invalid param type\n");
break;
}
}
/* obtain conf params from an nvlst and emit error messages if
* necessary. If an already-existing param value is passed, that is
* used. If NULL is passed instead, a new one is allocated. In that case,
* it is the caller's duty to free it when no longer needed.
* NULL is returned on error, otherwise a pointer to the vals array.
*/
struct cnfparamvals*
nvlstGetParams(struct nvlst *lst, struct cnfparamblk *params,
struct cnfparamvals *vals)
{
int i;
struct nvlst *valnode;
struct cnfparamdescr *param;
if(params->version != CNFPARAMBLK_VERSION) {
dbgprintf("nvlstGetParams: invalid param block version "
"%d, expected %d\n",
params->version, CNFPARAMBLK_VERSION);
return NULL;
}
if(vals == NULL) {
if((vals = calloc(params->nParams,
sizeof(struct cnfparamvals))) == NULL)
return NULL;
}
for(i = 0 ; i < params->nParams ; ++i) {
param = params->descr + i;
if((valnode = nvlstFindNameCStr(lst, param->name)) == NULL)
continue;
if(vals[i].bUsed) {
parser_errmsg("parameter '%s' specified more than once - "
"one instance is ignored. Fix config", param->name);
continue;
}
nvlstGetParam(valnode, param, vals + i);
}
return vals;
}
void
cnfparamsPrint(struct cnfparamblk *params, struct cnfparamvals *vals)
{
int i;
char *cstr;
for(i = 0 ; i < params->nParams ; ++i) {
dbgprintf("%s: ", params->descr[i].name);
if(vals[i].bUsed) {
// TODO: other types!
switch(vals[i].val.datatype) {
case 'S':
cstr = es_str2cstr(vals[i].val.d.estr, NULL);
dbgprintf(" '%s'", cstr);
free(cstr);
break;
case 'N':
dbgprintf("%lld", vals[i].val.d.n);
break;
default:
dbgprintf("(unsupported datatype %c)",
vals[i].val.datatype);
}
} else {
dbgprintf("(unset)");
}
dbgprintf("\n");
}
}
struct cnfobj*
cnfobjNew(enum cnfobjType objType, struct nvlst *lst)
{
struct cnfobj *o;
if((o = malloc(sizeof(struct nvlst))) != NULL) {
nvlstChkDupes(lst);
o->objType = objType;
o->nvlst = lst;
}
return o;
}
void
cnfobjDestruct(struct cnfobj *o)
{
if(o != NULL) {
nvlstDestruct(o->nvlst);
free(o);
}
}
void
cnfobjPrint(struct cnfobj *o)
{
dbgprintf("obj: '%s'\n", cnfobjType2str(o->objType));
nvlstPrint(o->nvlst);
}
struct cnfactlst*
cnfactlstNew(enum cnfactType actType, struct nvlst *lst, char *actLine)
{
struct cnfactlst *actlst;
if((actlst = malloc(sizeof(struct cnfactlst))) != NULL) {
actlst->next = NULL;
actlst->syslines = NULL;
actlst->actType = actType;
actlst->lineno = yylineno;
actlst->cnfFile = strdup(cnfcurrfn);
if(actType == CNFACT_V2)
actlst->data.lst = lst;
else
actlst->data.legActLine = actLine;
}
return actlst;
}
struct cnfactlst*
cnfactlstAddSysline(struct cnfactlst* actlst, char *line)
{
struct cnfcfsyslinelst *cflst;
if((cflst = malloc(sizeof(struct cnfcfsyslinelst))) != NULL) {
cflst->line = line;
if(actlst->syslines == NULL) {
cflst->next = NULL;
} else {
cflst->next = actlst->syslines;
}
actlst->syslines = cflst;
}
return actlst;
}
void
cnfactlstDestruct(struct cnfactlst *actlst)
{
struct cnfactlst *toDel;
while(actlst != NULL) {
toDel = actlst;
actlst = actlst->next;
free(toDel->cnfFile);
cnfcfsyslinelstDestruct(toDel->syslines);
if(toDel->actType == CNFACT_V2)
nvlstDestruct(toDel->data.lst);
else
free(toDel->data.legActLine);
free(toDel);
}
}
static inline struct cnfcfsyslinelst*
cnfcfsyslinelstReverse(struct cnfcfsyslinelst *lst)
{
struct cnfcfsyslinelst *curr, *prev;
if(lst == NULL)
return NULL;
prev = NULL;
while(lst != NULL) {
curr = lst;
lst = lst->next;
curr->next = prev;
prev = curr;
}
return prev;
}
struct cnfactlst*
cnfactlstReverse(struct cnfactlst *actlst)
{
struct cnfactlst *curr, *prev;
prev = NULL;
while(actlst != NULL) {
curr = actlst;
actlst = actlst->next;
curr->syslines = cnfcfsyslinelstReverse(curr->syslines);
curr->next = prev;
prev = curr;
}
return prev;
}
void
cnfactlstPrint(struct cnfactlst *actlst)
{
struct cnfcfsyslinelst *cflst;
while(actlst != NULL) {
dbgprintf("aclst %p: ", actlst);
if(actlst->actType == CNFACT_V2) {
dbgprintf("V2 action type: ");
nvlstPrint(actlst->data.lst);
} else {
dbgprintf("legacy action line: '%s'\n",
actlst->data.legActLine);
}
for( cflst = actlst->syslines
; cflst != NULL ; cflst = cflst->next) {
dbgprintf("action:cfsysline: '%s'\n", cflst->line);
}
actlst = actlst->next;
}
}
struct cnfexpr*
cnfexprNew(unsigned nodetype, struct cnfexpr *l, struct cnfexpr *r)
{
struct cnfexpr *expr;
/* optimize some constructs during parsing */
if(nodetype == 'M' && r->nodetype == 'N') {
((struct cnfnumval*)r)->val *= -1;
expr = r;
goto done;
}
if((expr = malloc(sizeof(struct cnfexpr))) != NULL) {
expr->nodetype = nodetype;
expr->l = l;
expr->r = r;
}
done:
return expr;
}
/* ensure that retval is a number; if string is no number,
* try to convert it to one. The semantics from es_str2num()
* are used (bSuccess tells if the conversion went well or not).
*/
static inline long long
var2Number(struct var *r, int *bSuccess)
{
long long n;
if(r->datatype == 'S') {
n = es_str2num(r->d.estr, bSuccess);
} else {
n = r->d.n;
if(bSuccess)
*bSuccess = 1;
}
return n;
}
/* ensure that retval is a string
*/
static inline es_str_t *
var2String(struct var *r, int *bMustFree)
{
if(r->datatype == 'N') {
*bMustFree = 1;
return es_newStrFromNumber(r->d.n);
}
*bMustFree = 0;
return r->d.estr;
}
/* Perform a function call. This has been moved out of cnfExprEval in order
* to keep the code small and easier to maintain.
*/
static inline void
doFuncCall(struct cnffunc *func, struct var *ret, void* usrptr)
{
char *fname;
char *envvar;
int bMustFree;
es_str_t *estr;
char *str;
int retval;
struct var r[CNFFUNC_MAX_ARGS];
dbgprintf("rainerscript: executing function id %d\n", func->fID);
switch(func->fID) {
case CNFFUNC_STRLEN:
if(func->expr[0]->nodetype == 'S') {
/* if we already have a string, we do not need to
* do one more recursive call.
*/
ret->d.n = es_strlen(((struct cnfstringval*) func->expr[0])->estr);
} else {
cnfexprEval(func->expr[0], &r[0], usrptr);
estr = var2String(&r[0], &bMustFree);
ret->d.n = es_strlen(estr);
if(bMustFree) es_deleteStr(estr);
}
ret->datatype = 'N';
break;
case CNFFUNC_GETENV:
/* note: the optimizer shall have replaced calls to getenv()
* with a constant argument to a single string (once obtained via
* getenv()). So we do NOT need to check if there is just a
* string following.
*/
cnfexprEval(func->expr[0], &r[0], usrptr);
estr = var2String(&r[0], &bMustFree);
str = (char*) es_str2cstr(estr, NULL);
envvar = getenv(str);
ret->datatype = 'S';
ret->d.estr = es_newStrFromCStr(envvar, strlen(envvar));
if(bMustFree) es_deleteStr(estr);
if(r[0].datatype == 'S') es_deleteStr(r[0].d.estr);
free(str);
break;
case CNFFUNC_TOLOWER:
cnfexprEval(func->expr[0], &r[0], usrptr);
estr = var2String(&r[0], &bMustFree);
if(!bMustFree) /* let caller handle that M) */
estr = es_strdup(estr);
es_tolower(estr);
ret->datatype = 'S';
ret->d.estr = estr;
if(r[0].datatype == 'S') es_deleteStr(r[0].d.estr);
break;
case CNFFUNC_CSTR:
cnfexprEval(func->expr[0], &r[0], usrptr);
estr = var2String(&r[0], &bMustFree);
if(!bMustFree) /* let caller handle that M) */
estr = es_strdup(estr);
ret->datatype = 'S';
ret->d.estr = estr;
if(r[0].datatype == 'S') es_deleteStr(r[0].d.estr);
break;
case CNFFUNC_CNUM:
if(func->expr[0]->nodetype == 'N') {
ret->d.n = ((struct cnfnumval*)func->expr[0])->val;
} else if(func->expr[0]->nodetype == 'S') {
ret->d.n = es_str2num(((struct cnfstringval*) func->expr[0])->estr,
NULL);
} else {
cnfexprEval(func->expr[0], &r[0], usrptr);
ret->d.n = var2Number(&r[0], NULL);
if(r[0].datatype == 'S') es_deleteStr(r[0].d.estr);
}
ret->datatype = 'N';
break;
case CNFFUNC_RE_MATCH:
cnfexprEval(func->expr[0], &r[0], usrptr);
estr = var2String(&r[0], &bMustFree);
str = es_str2cstr(estr, NULL);
retval = regexp.regexec(func->funcdata, str, 0, NULL, 0);
if(retval == 0)
ret->d.n = 1;
else {
ret->d.n = 0;
if(retval != REG_NOMATCH) {
DBGPRINTF("re_match: regexec returned error %d\n", retval);
}
}
ret->datatype = 'N';
if(bMustFree) es_deleteStr(estr);
free(str);
if(r[0].datatype == 'S') es_deleteStr(r[0].d.estr);
break;
default:
if(Debug) {
fname = es_str2cstr(func->fname, NULL);
dbgprintf("rainerscript: invalid function id %u (name '%s')\n",
(unsigned) func->fID, fname);
free(fname);
}
ret->datatype = 'N';
ret->d.n = 0;
}
}
#define FREE_BOTH_RET \
if(r.datatype == 'S') es_deleteStr(r.d.estr); \
if(l.datatype == 'S') es_deleteStr(l.d.estr)
#define COMP_NUM_BINOP(x) \
cnfexprEval(expr->l, &l, usrptr); \
cnfexprEval(expr->r, &r, usrptr); \
ret->datatype = 'N'; \
ret->d.n = var2Number(&l, &convok_l) x var2Number(&r, &convok_r); \
FREE_BOTH_RET
#define PREP_TWO_STRINGS \
cnfexprEval(expr->l, &l, usrptr); \
estr_l = var2String(&l, &bMustFree2); \
cnfexprEval(expr->r, &r, usrptr); \
estr_r = var2String(&r, &bMustFree)
#define FREE_TWO_STRINGS \
if(bMustFree) es_deleteStr(estr_r); \
if(bMustFree2) es_deleteStr(estr_l); \
FREE_BOTH_RET
/* evaluate an expression.
* Note that we try to avoid malloc whenever possible (because of
* the large overhead it has, especially on highly threaded programs).
* As such, the each caller level must provide buffer space for the
* result on its stack during recursion. This permits the callee to store
* the return value without malloc. As the value is a somewhat larger
* struct, we could otherwise not return it without malloc.
* Note that we implement boolean shortcut operations. For our needs, there
* simply is no case where full evaluation would make any sense at all.
*/
void
cnfexprEval(struct cnfexpr *expr, struct var *ret, void* usrptr)
{
struct var r, l; /* memory for subexpression results */
es_str_t *estr_r, *estr_l;
int convok_r, convok_l;
int bMustFree, bMustFree2;
long long n_r, n_l;
dbgprintf("eval expr %p, type '%c'(%u)\n", expr, expr->nodetype, expr->nodetype);
switch(expr->nodetype) {
/* note: comparison operations are extremely similar. The code can be copyied, only
* places flagged with "CMP" need to be changed.
*/
case CMP_EQ:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = !es_strcmp(l.d.estr, r.d.estr); /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l == r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = !es_strcmp(l.d.estr, estr_r); /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n == n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = !es_strcmp(r.d.estr, estr_l); /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n == r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_NE:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = es_strcmp(l.d.estr, r.d.estr); /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l != r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = es_strcmp(l.d.estr, estr_r); /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n != n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = es_strcmp(r.d.estr, estr_l); /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n != r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_LE:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = es_strcmp(l.d.estr, r.d.estr) <= 0; /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l <= r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = es_strcmp(l.d.estr, estr_r) <= 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n <= n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = es_strcmp(r.d.estr, estr_l) <= 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n <= r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_GE:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = es_strcmp(l.d.estr, r.d.estr) >= 0; /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l >= r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = es_strcmp(l.d.estr, estr_r) >= 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n >= n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = es_strcmp(r.d.estr, estr_l) >= 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n >= r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_LT:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = es_strcmp(l.d.estr, r.d.estr) < 0; /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l < r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = es_strcmp(l.d.estr, estr_r) < 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n < n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = es_strcmp(r.d.estr, estr_l) < 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n < r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_GT:
cnfexprEval(expr->l, &l, usrptr);
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
if(l.datatype == 'S') {
if(r.datatype == 'S') {
ret->d.n = es_strcmp(l.d.estr, r.d.estr) > 0; /*CMP*/
} else {
n_l = var2Number(&l, &convok_l);
if(convok_l) {
ret->d.n = (n_l > r.d.n); /*CMP*/
} else {
estr_r = var2String(&r, &bMustFree);
ret->d.n = es_strcmp(l.d.estr, estr_r) > 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_r);
}
}
} else {
if(r.datatype == 'S') {
n_r = var2Number(&r, &convok_r);
if(convok_r) {
ret->d.n = (l.d.n > n_r); /*CMP*/
} else {
estr_l = var2String(&l, &bMustFree);
ret->d.n = es_strcmp(r.d.estr, estr_l) > 0; /*CMP*/
if(bMustFree) es_deleteStr(estr_l);
}
} else {
ret->d.n = (l.d.n > r.d.n); /*CMP*/
}
}
FREE_BOTH_RET;
break;
case CMP_STARTSWITH:
PREP_TWO_STRINGS;
ret->datatype = 'N';
ret->d.n = es_strncmp(estr_l, estr_r, estr_r->lenStr) == 0;
FREE_TWO_STRINGS;
break;
case CMP_STARTSWITHI:
PREP_TWO_STRINGS;
ret->datatype = 'N';
ret->d.n = es_strncasecmp(estr_l, estr_r, estr_r->lenStr) == 0;
FREE_TWO_STRINGS;
break;
case CMP_CONTAINS:
PREP_TWO_STRINGS;
ret->datatype = 'N';
ret->d.n = es_strContains(estr_l, estr_r) != -1;
FREE_TWO_STRINGS;
break;
case CMP_CONTAINSI:
PREP_TWO_STRINGS;
ret->datatype = 'N';
ret->d.n = es_strCaseContains(estr_l, estr_r) != -1;
FREE_TWO_STRINGS;
break;
case OR:
cnfexprEval(expr->l, &l, usrptr);
ret->datatype = 'N';
if(var2Number(&l, &convok_l)) {
ret->d.n = 1ll;
} else {
cnfexprEval(expr->r, &r, usrptr);
if(var2Number(&r, &convok_r))
ret->d.n = 1ll;
else
ret->d.n = 0ll;
if(r.datatype == 'S') es_deleteStr(r.d.estr);
}
if(l.datatype == 'S') es_deleteStr(l.d.estr);
break;
case AND:
cnfexprEval(expr->l, &l, usrptr);
ret->datatype = 'N';
if(var2Number(&l, &convok_l)) {
cnfexprEval(expr->r, &r, usrptr);
if(var2Number(&r, &convok_r))
ret->d.n = 1ll;
else
ret->d.n = 0ll;
if(r.datatype == 'S') es_deleteStr(r.d.estr);
} else {
ret->d.n = 0ll;
}
if(l.datatype == 'S') es_deleteStr(l.d.estr);
break;
case NOT:
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
ret->d.n = !var2Number(&r, &convok_r);
if(r.datatype == 'S') es_deleteStr(r.d.estr);
break;
case 'N':
ret->datatype = 'N';
ret->d.n = ((struct cnfnumval*)expr)->val;
break;
case 'S':
ret->datatype = 'S';
ret->d.estr = es_strdup(((struct cnfstringval*)expr)->estr);
break;
case 'V':
ret->datatype = 'S';
ret->d.estr = cnfGetVar(((struct cnfvar*)expr)->name, usrptr);
break;
case '+':
COMP_NUM_BINOP(+);
break;
case '-':
COMP_NUM_BINOP(-);
break;
case '*':
COMP_NUM_BINOP(*);
break;
case '/':
COMP_NUM_BINOP(/);
break;
case '%':
COMP_NUM_BINOP(%);
break;
case 'M':
cnfexprEval(expr->r, &r, usrptr);
ret->datatype = 'N';
ret->d.n = -var2Number(&r, &convok_r);
if(r.datatype == 'S') es_deleteStr(r.d.estr);
break;
case 'F':
doFuncCall((struct cnffunc*) expr, ret, usrptr);
break;
default:
ret->datatype = 'N';
ret->d.n = 0ll;
dbgprintf("eval error: unknown nodetype %u['%c']\n",
(unsigned) expr->nodetype, (char) expr->nodetype);
break;
}
}
//---------------------------------------------------------
static inline void
cnffuncDestruct(struct cnffunc *func)
{
unsigned short i;
for(i = 0 ; i < func->nParams ; ++i) {
cnfexprDestruct(func->expr[i]);
}
/* some functions require special destruction */
switch(func->fID) {
case CNFFUNC_RE_MATCH:
regexp.regfree(func->funcdata);
free(func->funcdata);
free(func->fname);
break;
default:break;
}
}
/* Destruct an expression and all sub-expressions contained in it.
*/
void
cnfexprDestruct(struct cnfexpr *expr)
{
dbgprintf("cnfexprDestruct expr %p, type '%c'(%u)\n", expr, expr->nodetype, expr->nodetype);
switch(expr->nodetype) {
case CMP_NE:
case CMP_EQ:
case CMP_LE:
case CMP_GE:
case CMP_LT:
case CMP_GT:
case CMP_STARTSWITH:
case CMP_STARTSWITHI:
case CMP_CONTAINS:
case CMP_CONTAINSI:
case OR:
case AND:
case '+':
case '-':
case '*':
case '/':
case '%': /* binary */
cnfexprDestruct(expr->l);
cnfexprDestruct(expr->r);
break;
case NOT:
case 'M': /* unary */
cnfexprDestruct(expr->r);
break;
case 'N':
break;
case 'S':
es_deleteStr(((struct cnfstringval*)expr)->estr);
break;
case 'V':
free(((struct cnfvar*)expr)->name);
break;
case 'F':
cnffuncDestruct((struct cnffunc*)expr);
break;
default:break;
}
free(expr);
}
//---- END
/* Evaluate an expression as a bool. This is added because expressions are
* mostly used inside filters, and so this function is quite common and
* important.
*/
int
cnfexprEvalBool(struct cnfexpr *expr, void *usrptr)
{
int convok;
struct var ret;
cnfexprEval(expr, &ret, usrptr);
return var2Number(&ret, &convok);
}
inline static void
doIndent(int indent)
{
int i;
for(i = 0 ; i < indent ; ++i)
dbgprintf(" ");
}
void
cnfexprPrint(struct cnfexpr *expr, int indent)
{
struct cnffunc *func;
int i;
//dbgprintf("expr %p, indent %d, type '%c'\n", expr, indent, expr->nodetype);
switch(expr->nodetype) {
case CMP_EQ:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("==\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_NE:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("!=\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_LE:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("<=\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_GE:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf(">=\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_LT:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("<\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_GT:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf(">\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_CONTAINS:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("CONTAINS\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_CONTAINSI:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("CONTAINS_I\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_STARTSWITH:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("STARTSWITH\n");
cnfexprPrint(expr->r, indent+1);
break;
case CMP_STARTSWITHI:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("STARTSWITH_I\n");
cnfexprPrint(expr->r, indent+1);
break;
case OR:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("OR\n");
cnfexprPrint(expr->r, indent+1);
break;
case AND:
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("AND\n");
cnfexprPrint(expr->r, indent+1);
break;
case NOT:
doIndent(indent);
dbgprintf("NOT\n");
cnfexprPrint(expr->r, indent+1);
break;
case 'S':
doIndent(indent);
cstrPrint("string '", ((struct cnfstringval*)expr)->estr);
dbgprintf("'\n");
break;
case 'N':
doIndent(indent);
dbgprintf("%lld\n", ((struct cnfnumval*)expr)->val);
break;
case 'V':
doIndent(indent);
dbgprintf("var '%s'\n", ((struct cnfvar*)expr)->name);
break;
case 'F':
doIndent(indent);
func = (struct cnffunc*) expr;
cstrPrint("function '", func->fname);
dbgprintf("' (id:%d, params:%hu)\n", func->fID, func->nParams);
for(i = 0 ; i < func->nParams ; ++i) {
cnfexprPrint(func->expr[i], indent+1);
}
break;
case '+':
case '-':
case '*':
case '/':
case '%':
case 'M':
if(expr->l != NULL)
cnfexprPrint(expr->l, indent+1);
doIndent(indent);
dbgprintf("%c\n", (char) expr->nodetype);
cnfexprPrint(expr->r, indent+1);
break;
default:
dbgprintf("error: unknown nodetype %u\n",
(unsigned) expr->nodetype);
break;
}
}
struct cnfnumval*
cnfnumvalNew(long long val)
{
struct cnfnumval *numval;
if((numval = malloc(sizeof(struct cnfnumval))) != NULL) {
numval->nodetype = 'N';
numval->val = val;
}
return numval;
}
struct cnfstringval*
cnfstringvalNew(es_str_t *estr)
{
struct cnfstringval *strval;
if((strval = malloc(sizeof(struct cnfstringval))) != NULL) {
strval->nodetype = 'S';
strval->estr = estr;
}
return strval;
}
struct cnfvar*
cnfvarNew(char *name)
{
struct cnfvar *var;
if((var = malloc(sizeof(struct cnfvar))) != NULL) {
var->nodetype = 'V';
var->name = name;
}
return var;
}
struct cnfrule *
cnfruleNew(enum cnfFiltType filttype, struct cnfactlst *actlst)
{
struct cnfrule* cnfrule;
if((cnfrule = malloc(sizeof(struct cnfrule))) != NULL) {
cnfrule->nodetype = 'R';
cnfrule->filttype = filttype;
cnfrule->actlst = cnfactlstReverse(actlst);
}
return cnfrule;
}
void
cnfrulePrint(struct cnfrule *rule)
{
dbgprintf("------ start rule %p:\n", rule);
dbgprintf("%s: ", cnfFiltType2str(rule->filttype));
switch(rule->filttype) {
case CNFFILT_NONE:
break;
case CNFFILT_PRI:
case CNFFILT_PROP:
dbgprintf("%s\n", rule->filt.s);
break;
case CNFFILT_SCRIPT:
dbgprintf("\n");
cnfexprPrint(rule->filt.expr, 0);
break;
}
cnfactlstPrint(rule->actlst);
dbgprintf("------ end rule %p\n", rule);
}
/* note: the sysline itself was already freed during processing
* and as such MUST NOT be freed again!
*/
void
cnfcfsyslinelstDestruct(struct cnfcfsyslinelst *cfslst)
{
struct cnfcfsyslinelst *toDel;
while(cfslst != NULL) {
toDel = cfslst;
cfslst = cfslst->next;
free(toDel);
}
}
void
cnfruleDestruct(struct cnfrule *rule)
{
if( rule->filttype == CNFFILT_PRI
|| rule->filttype == CNFFILT_PROP)
free(rule->filt.s);
cnfactlstDestruct(rule->actlst);
free(rule);
}
struct cnffparamlst *
cnffparamlstNew(struct cnfexpr *expr, struct cnffparamlst *next)
{
struct cnffparamlst* lst;
if((lst = malloc(sizeof(struct cnffparamlst))) != NULL) {
lst->nodetype = 'P';
lst->expr = expr;
lst->next = next;
}
return lst;
}
/* Obtain function id from name AND number of params. Issues the
* relevant error messages if errors are detected.
*/
static inline enum cnffuncid
funcName2ID(es_str_t *fname, unsigned short nParams)
{
if(!es_strbufcmp(fname, (unsigned char*)"strlen", sizeof("strlen") - 1)) {
if(nParams != 1) {
parser_errmsg("number of parameters for strlen() must be one "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_STRLEN;
} else if(!es_strbufcmp(fname, (unsigned char*)"getenv", sizeof("getenv") - 1)) {
if(nParams != 1) {
parser_errmsg("number of parameters for getenv() must be one "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_GETENV;
} else if(!es_strbufcmp(fname, (unsigned char*)"tolower", sizeof("tolower") - 1)) {
if(nParams != 1) {
parser_errmsg("number of parameters for tolower() must be one "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_TOLOWER;
} else if(!es_strbufcmp(fname, (unsigned char*)"cstr", sizeof("cstr") - 1)) {
if(nParams != 1) {
parser_errmsg("number of parameters for cstr() must be one "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_CSTR;
} else if(!es_strbufcmp(fname, (unsigned char*)"cnum", sizeof("cnum") - 1)) {
if(nParams != 1) {
parser_errmsg("number of parameters for cnum() must be one "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_CNUM;
} else if(!es_strbufcmp(fname, (unsigned char*)"re_match", sizeof("re_match") - 1)) {
if(nParams != 2) {
parser_errmsg("number of parameters for re_match() must be two "
"but is %d.", nParams);
return CNFFUNC_INVALID;
}
return CNFFUNC_RE_MATCH;
} else {
return CNFFUNC_INVALID;
}
}
static inline rsRetVal
initFunc_re_match(struct cnffunc *func)
{
rsRetVal localRet;
char *regex = NULL;
regex_t *re;
DEFiRet;
func->funcdata = NULL;
if(func->expr[1]->nodetype != 'S') {
parser_errmsg("param 2 of re_match() must be a constant string");
FINALIZE;
}
CHKmalloc(re = malloc(sizeof(regex_t)));
func->funcdata = re;
regex = es_str2cstr(((struct cnfstringval*) func->expr[1])->estr, NULL);
if((localRet = objUse(regexp, LM_REGEXP_FILENAME)) == RS_RET_OK) {
if(regexp.regcomp(re, (char*) regex, REG_EXTENDED) != 0) {
parser_errmsg("cannot compile regex '%s'", regex);
ABORT_FINALIZE(RS_RET_ERR);
}
} else { /* regexp object could not be loaded */
parser_errmsg("could not load regex support - regex ignored");
ABORT_FINALIZE(RS_RET_ERR);
}
finalize_it:
free(regex);
RETiRet;
}
struct cnffunc *
cnffuncNew(es_str_t *fname, struct cnffparamlst* paramlst)
{
struct cnffunc* func;
struct cnffparamlst *param, *toDel;
unsigned short i;
unsigned short nParams;
/* we first need to find out how many params we have */
nParams = 0;
for(param = paramlst ; param != NULL ; param = param->next)
++nParams;
if((func = malloc(sizeof(struct cnffunc) + (nParams * sizeof(struct cnfexp*))))
!= NULL) {
func->nodetype = 'F';
func->fname = fname;
func->nParams = nParams;
func->fID = funcName2ID(fname, nParams);
/* shuffle params over to array (access speed!) */
param = paramlst;
for(i = 0 ; i < nParams ; ++i) {
func->expr[i] = param->expr;
toDel = param;
param = param->next;
free(toDel);
}
/* some functions require special initialization */
switch(func->fID) {
case CNFFUNC_RE_MATCH:
/* need to compile the regexp in param 2, so this MUST be a constant */
initFunc_re_match(func);
break;
default:break;
}
}
return func;
}
int
cnfDoInclude(char *name)
{
char *cfgFile;
unsigned i;
int result;
glob_t cfgFiles;
struct stat fileInfo;
/* Use GLOB_MARK to append a trailing slash for directories.
* Required by doIncludeDirectory().
*/
result = glob(name, GLOB_MARK, NULL, &cfgFiles);
if(result == GLOB_NOSPACE || result == GLOB_ABORTED) {
#if 0
char errStr[1024];
rs_strerror_r(errno, errStr, sizeof(errStr));
errmsg.LogError(0, RS_RET_FILE_NOT_FOUND, "error accessing config file or directory '%s': %s",
pattern, errStr);
ABORT_FINALIZE(RS_RET_FILE_NOT_FOUND);
#endif
dbgprintf("includeconfig glob error %d\n", errno);
return 1;
}
for(i = 0; i < cfgFiles.gl_pathc; i++) {
cfgFile = cfgFiles.gl_pathv[i];
if(stat(cfgFile, &fileInfo) != 0)
continue; /* continue with the next file if we can't stat() the file */
if(S_ISREG(fileInfo.st_mode)) { /* config file */
dbgprintf("requested to include config file '%s'\n", cfgFile);
cnfSetLexFile(cfgFile);
} else if(S_ISDIR(fileInfo.st_mode)) { /* config directory */
if(strcmp(name, cfgFile)) {
/* do not include ourselves! */
dbgprintf("requested to include directory '%s'\n", cfgFile);
cnfDoInclude(cfgFile);
}
} else {
dbgprintf("warning: unable to process IncludeConfig directive '%s'\n", cfgFile);
}
}
globfree(&cfgFiles);
return 0;
}
void
varDelete(struct var *v)
{
if(v->datatype == 'S')
es_deleteStr(v->d.estr);
}
void
cnfparamvalsDestruct(struct cnfparamvals *paramvals, struct cnfparamblk *blk)
{
int i;
for(i = 0 ; i < blk->nParams ; ++i) {
varDelete(¶mvals[i].val);
}
free(paramvals);
}
/* find the index (or -1!) for a config param by name. This is used to
* address the parameter array. Of course, we could use with static
* indices, but that would create some extra bug potential. So we
* resort to names. As we do this only during the initial config parsing
* stage the (considerable!) extra overhead is OK. -- rgerhards, 2011-07-19
*/
int
cnfparamGetIdx(struct cnfparamblk *params, char *name)
{
int i;
for(i = 0 ; i < params->nParams ; ++i)
if(!strcmp(params->descr[i].name, name))
break;
if(i == params->nParams)
i = -1; /* not found */
return i;
}
void
cstrPrint(char *text, es_str_t *estr)
{
char *str;
str = es_str2cstr(estr, NULL);
dbgprintf("%s%s", text, str);
free(str);
}
/* init must be called once before any parsing of the script files start */
rsRetVal
initRainerscript(void)
{
DEFiRet;
CHKiRet(objGetObjInterface(&obj));
finalize_it:
RETiRet;
}