sysklogd/ksym_mod.c
Joey Schulze e9b180bb9b * Corrected some code that caused klogd to dump core when receiving some
special messages from 2.1.78.  Thanks to Chu-yeon Park
    <kokids@doit.ajou.ac.kr> for informing me.
  * Fixed bug that caused klogd to die if there is no System.map
    available.
  * Added -x switch to omit EIP translation and System.map evaluation.
    Thanks to Florian La Roche <florian@knorke.saar.de>.
  * Fixed small bugs in F_FORW_UNKN meachanism.  Thanks to Torsten Neumann
    <torsten@londo.rhein-main.de> for pointing me to it.
  * Fixed problem with klogd not being able to be built on a kernel newer
    than 2.1.18.  Worked in a patch from Alessandro Suardi <asuardi@uninetcom.it>
1998-01-10 18:02:57 +00:00

672 lines
16 KiB
C

/*
ksym_mod.c - functions for building symbol lookup tables for klogd
Copyright (c) 1995, 1996 Dr. G.W. Wettstein <greg@wind.rmcc.com>
Copyright (c) 1996 Enjellic Systems Development
This file is part of the sysklogd package, a kernel and system log daemon.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/*
* This file implements functions which are useful for building
* a symbol lookup table based on the in kernel symbol table
* maintained by the Linux kernel.
*
* Proper logging of kernel panics generated by loadable modules
* tends to be difficult. Since the modules are loaded dynamically
* their addresses are not known at kernel load time. A general
* protection fault (Oops) cannot be properly deciphered with
* classic methods using the static symbol map produced at link time.
*
* One solution to this problem is to have klogd attempt to translate
* addresses from module when the fault occurs. By referencing the
* the kernel symbol table proper resolution of these symbols is made
* possible.
*
* At least that is the plan.
*
* Wed Aug 21 09:20:09 CDT 1996: Dr. Wettstein
* The situation where no module support has been compiled into a
* kernel is now detected. An informative message is output indicating
* that the kernel has no loadable module support whenever kernel
* module symbols are loaded.
*
* An informative message is printed indicating the number of kernel
* modules and the number of symbols loaded from these modules.
*
* Sun Jun 15 16:23:29 MET DST 1997: Michael Alan Dorman
* Some more glibc patches made by <mdorman@debian.org>.
*
* Sat Jan 10 15:00:18 CET 1998: Martin Schulze <joey@infodrom.north.de>
* Fixed problem with klogd not being able to be built on a kernel
* newer than 2.1.18. It was caused by modified structures
* inside the kernel that were included. I have worked in a
* patch from Alessandro Suardi <asuardi@uninetcom.it>.
*/
/* Includes. */
#include <stdlib.h>
#include <malloc.h>
#include <unistd.h>
#include <signal.h>
#include <errno.h>
#include <sys/fcntl.h>
#include <sys/stat.h>
#if !defined(__GLIBC__)
#include <linux/time.h>
#include <linux/module.h>
#else /* __GLIBC__ */
#include <sys/module.h>
#endif /* __GLIBC__ */
#include <stdarg.h>
#include <paths.h>
#include <linux/version.h>
#include "klogd.h"
#include "ksyms.h"
#if !defined(__GLIBC__)
/*
* The following bit uses some kernel/library magic to product what
* looks like a function call to user level code. This function is
* actually a system call in disguise. The purpose of the getsyms
* call is to return a current copy of the in-kernel symbol table.
*/
#define __LIBRARY__
#include <linux/unistd.h>
#define __NR_getsyms __NR_get_kernel_syms
_syscall1(int, getsyms, struct kernel_sym *, syms);
#undef __LIBRARY__
extern int getsyms(struct kernel_sym *);
#else /* __GLIBC__ */
#define getsyms get_kernel_syms
#endif /* __GLIBC__ */
/* Variables static to this module. */
struct sym_table
{
unsigned long value;
char *name;
};
struct Module
{
struct sym_table *sym_array;
int num_syms;
char *name;
struct module module;
#if LINUX_VERSION_CODE >= 0x20112
struct module_info module_info;
#endif
};
static int num_modules = 0;
struct Module *sym_array_modules = (struct Module *) 0;
static int have_modules = 0;
#if defined(TEST)
static int debugging = 1;
#else
extern int debugging;
#endif
/* Function prototypes. */
static void FreeModules(void);
static int AddSymbol(struct Module *mp, unsigned long, char *);
static int AddModule(unsigned long, char *);
static int symsort(const void *, const void *);
/**************************************************************************
* Function: InitMsyms
*
* Purpose: This function is responsible for building a symbol
* table which can be used to resolve addresses for
* loadable modules.
*
* Arguements: Void
*
* Return: A boolean return value is assumed.
*
* A false value indicates that something went wrong.
*
* True if loading is successful.
**************************************************************************/
extern int InitMsyms()
{
auto int rtn,
tmp;
auto struct kernel_sym *ksym_table,
*p;
/* Initialize the kernel module symbol table. */
FreeModules();
/*
* The system call which returns the kernel symbol table has
* essentialy two modes of operation. Called with a null pointer
* the system call returns the number of symbols defined in the
* the table.
*
* The second mode of operation is to pass a valid pointer to
* the call which will then load the current symbol table into
* the memory provided.
*
* Returning the symbol table is essentially an all or nothing
* proposition so we need to pre-allocate enough memory for the
* complete table regardless of how many symbols we need.
*
* Bummer.
*/
if ( (rtn = getsyms((struct kernel_sym *) 0)) < 0 )
{
if ( errno == ENOSYS )
Syslog(LOG_INFO, "No module symbols loaded - "
"kernel modules not enabled.\n");
else
Syslog(LOG_ERR, "Error loading kernel symbols " \
"- %s\n", strerror(errno));
return(0);
}
if ( debugging )
fprintf(stderr, "Loading kernel module symbols - "
"Size of table: %d\n", rtn);
ksym_table = (struct kernel_sym *) malloc(rtn * \
sizeof(struct kernel_sym));
if ( ksym_table == (struct kernel_sym *) 0 )
{
Syslog(LOG_WARNING, " Failed memory allocation for kernel " \
"symbol table.\n");
return(0);
}
if ( (rtn = getsyms(ksym_table)) < 0 )
{
Syslog(LOG_WARNING, "Error reading kernel symbols - %s\n", \
strerror(errno));
return(0);
}
/*
* Build a symbol table compatible with the other one used by
* klogd.
*/
tmp = rtn;
p = ksym_table;
while ( tmp-- )
{
if ( !AddModule(p->value, p->name) )
{
Syslog(LOG_WARNING, "Error adding kernel module table "
"entry.\n");
free(ksym_table);
return(0);
}
++p;
}
/* Sort the symbol tables in each module. */
for (rtn = tmp= 0; tmp < num_modules; ++tmp)
{
rtn += sym_array_modules[tmp].num_syms;
if ( sym_array_modules[tmp].num_syms < 2 )
continue;
qsort(sym_array_modules[tmp].sym_array, \
sym_array_modules[tmp].num_syms, \
sizeof(struct sym_table), symsort);
}
if ( rtn == 0 )
Syslog(LOG_INFO, "No module symbols loaded.");
else
Syslog(LOG_INFO, "Loaded %d %s from %d module%s", rtn, \
(rtn == 1) ? "symbol" : "symbols", \
num_modules, (num_modules == 1) ? "." : "s.");
free(ksym_table);
return(1);
}
static int symsort(p1, p2)
const void *p1;
const void *p2;
{
auto const struct sym_table *sym1 = p1,
*sym2 = p2;
if ( sym1->value < sym2->value )
return(-1);
if ( sym1->value == sym2->value )
return(0);
return(1);
}
/**************************************************************************
* Function: FreeModules
*
* Purpose: This function is used to free all memory which has been
* allocated for the modules and their symbols.
*
* Arguements: None specified.
*
* Return: void
**************************************************************************/
static void FreeModules()
{
auto int nmods,
nsyms;
auto struct Module *mp;
/* Check to see if the module symbol tables need to be cleared. */
have_modules = 0;
if ( num_modules == 0 )
return;
for (nmods= 0; nmods < num_modules; ++nmods)
{
mp = &sym_array_modules[nmods];
if ( mp->num_syms == 0 )
continue;
for (nsyms= 0; nsyms < mp->num_syms; ++nsyms)
free(mp->sym_array[nsyms].name);
free(mp->sym_array);
}
free(sym_array_modules);
sym_array_modules = (struct Module *) 0;
num_modules = 0;
return;
}
/**************************************************************************
* Function: AddModule
*
* Purpose: This function is responsible for adding a module to
* the list of currently loaded modules.
*
* Arguements: (unsigned long) address, (char *) symbol
*
* address:-> The address of the module.
*
* symbol:-> The name of the module.
*
* Return: int
**************************************************************************/
static int AddModule(address, symbol)
unsigned long address;
char *symbol;
{
auto int memfd;
auto struct Module *mp;
/* Return if we have loaded the modules. */
if ( have_modules )
return(1);
/*
* The following section of code is responsible for determining
* whether or not we are done reading the list of modules.
*/
if ( symbol[0] == '#' )
{
if ( symbol[1] == '\0' )
{
/*
* A symbol which consists of a # sign only
* signifies a a resident kernel segment. When we
* hit one of these we are done reading the
* module list.
*/
have_modules = 1;
return(1);
}
/* Allocate space for the module. */
sym_array_modules = (struct Module *) \
realloc(sym_array_modules, \
(num_modules+1) * sizeof(struct Module));
if ( sym_array_modules == (struct Module *) 0 )
{
Syslog(LOG_WARNING, "Cannot allocate Module array.\n");
return(0);
}
mp = &sym_array_modules[num_modules];
if ( (memfd = open("/dev/kmem", O_RDONLY)) < 0 )
{
Syslog(LOG_WARNING, "Error opening /dev/kmem\n");
return(1);
}
if ( lseek(memfd, address, SEEK_SET) < 0 )
{
Syslog(LOG_WARNING, "Error seeking in /dev/kmem\n");
return(0);
}
if ( read(memfd, \
(char *)&sym_array_modules[num_modules].module, \
sizeof(struct module)) < 0 )
{
Syslog(LOG_WARNING, "Error reading module "
"descriptor.\n");
return(0);
}
close(memfd);
/* Save the module name. */
mp->name = (char *) malloc(strlen(&symbol[1]) + 1);
if ( mp->name == (char *) 0 )
return(0);
strcpy(mp->name, &symbol[1]);
mp->num_syms = 0;
mp->sym_array = (struct sym_table *) 0;
++num_modules;
return(1);
}
else
{
mp = &sym_array_modules[num_modules - 1];
AddSymbol(mp, address, symbol);
}
return(1);
}
/**************************************************************************
* Function: AddSymbol
*
* Purpose: This function is responsible for adding a symbol name
* and its address to the symbol table.
*
* Arguements: (struct Module *) mp, (unsigned long) address, (char *) symbol
*
* mp:-> A pointer to the module which the symbol is
* to be added to.
*
* address:-> The address of the symbol.
*
* symbol:-> The name of the symbol.
*
* Return: int
*
* A boolean value is assumed. True if the addition is
* successful. False if not.
**************************************************************************/
static int AddSymbol(mp, address, symbol)
struct Module *mp;
unsigned long address;
char *symbol;
{
auto int tmp;
/* Allocate space for the symbol table entry. */
mp->sym_array = (struct sym_table *) realloc(mp->sym_array, \
(mp->num_syms+1) * sizeof(struct sym_table));
if ( mp->sym_array == (struct sym_table *) 0 )
return(0);
/* Then the space for the symbol. */
tmp = strlen(symbol);
tmp += (strlen(mp->name) + 1);
mp->sym_array[mp->num_syms].name = (char *) malloc(tmp + 1);
if ( mp->sym_array[mp->num_syms].name == (char *) 0 )
return(0);
memset(mp->sym_array[mp->num_syms].name, '\0', tmp + 1);
/* Stuff interesting information into the module. */
mp->sym_array[mp->num_syms].value = address;
strcpy(mp->sym_array[mp->num_syms].name, mp->name);
strcat(mp->sym_array[mp->num_syms].name, ":");
strcat(mp->sym_array[mp->num_syms].name, symbol);
++mp->num_syms;
return(1);
}
/**************************************************************************
* Function: LookupModuleSymbol
*
* Purpose: Find the symbol which is related to the given address from
* a kernel module.
*
* Arguements: (long int) value, (struct symbol *) sym
*
* value:-> The address to be located.
*
* sym:-> A pointer to a structure which will be
* loaded with the symbol's parameters.
*
* Return: (char *)
*
* If a match cannot be found a diagnostic string is printed.
* If a match is found the pointer to the symbolic name most
* closely matching the address is returned.
**************************************************************************/
extern char * LookupModuleSymbol(value, sym)
unsigned long value;
struct symbol *sym;
{
auto int nmod,
nsym;
auto struct sym_table *last;
auto struct Module *mp;
sym->size = 0;
sym->offset = 0;
if ( num_modules == 0 )
return((char *) 0);
for(nmod= 0; nmod < num_modules; ++nmod)
{
mp = &sym_array_modules[nmod];
/*
* Run through the list of symbols in this module and
* see if the address can be resolved.
*/
for(nsym= 1, last = &mp->sym_array[0];
nsym < mp->num_syms;
++nsym)
{
if ( mp->sym_array[nsym].value > value )
{
sym->offset = value - last->value;
sym->size = mp->sym_array[nsym].value - \
last->value;
return(last->name);
}
last = &mp->sym_array[nsym];
}
/*
* At this stage of the game we still cannot give up the
* ghost. There is the possibility that the address is
* from a module which has no symbols registered with
* the kernel. The solution is to compare the address
* against the starting address and extant of the module
* If it is in this range we can at least return the
* name of the module.
*/
#if LINUX_VERSION_CODE < 0x20112
if ( (void *) value >= mp->module.addr &&
(void *) value <= (mp->module.addr + \
mp->module.size * 4096) )
#else
if ( value >= mp->module_info.addr &&
value <= (mp->module_info.addr + \
mp->module.size * 4096) )
#endif
{
/*
* A special case needs to be checked for. The above
* conditional tells us that we are within the
* extant of this module but symbol lookup has
* failed.
*
* We need to check to see if any symbols have
* been defined in this module. If there have been
* symbols defined the assumption must be made that
* the faulting address lies somewhere beyond the
* last symbol. About the only thing we can do
* at this point is use an offset from this
* symbol.
*/
if ( mp->num_syms > 0 )
{
last = &mp->sym_array[mp->num_syms - 1];
#if LINUX_VERSION_CODE < 0x20112
sym->size = (int) mp->module.addr + \
(mp->module.size * 4096) - value;
#else
sym->size = (int) mp->module_info.addr + \
(mp->module.size * 4096) - value;
#endif
sym->offset = value - last->value;
return(last->name);
}
/*
* There were no symbols defined for this module.
* Return the module name and the offset of the
* faulting address in the module.
*/
sym->size = mp->module.size * 4096;
#if LINUX_VERSION_CODE < 0x20112
sym->offset = (void *) value - mp->module.addr;
#else
sym->offset = value - mp->module_info.addr;
#endif
return(mp->name);
}
}
/* It has been a hopeless exercise. */
return((char *) 0);
}
/*
* Setting the -DTEST define enables the following code fragment to
* be compiled. This produces a small standalone program which will
* dump the current kernel symbol table.
*/
#if defined(TEST)
#include <stdarg.h>
extern int main(int, char **);
int main(argc, argv)
int argc;
char *argv[];
{
auto int lp, syms;
if ( !InitMsyms() )
{
fprintf(stderr, "Cannot load module symbols.\n");
return(1);
}
printf("Number of modules: %d\n\n", num_modules);
for(lp= 0; lp < num_modules; ++lp)
{
printf("Module #%d = %s, Number of symbols = %d\n", lp + 1, \
sym_array_modules[lp].name, \
sym_array_modules[lp].num_syms);
for (syms= 0; syms < sym_array_modules[lp].num_syms; ++syms)
{
printf("\tSymbol #%d\n", syms + 1);
printf("\tName: %s\n", \
sym_array_modules[lp].sym_array[syms].name);
printf("\tAddress: %lx\n\n", \
sym_array_modules[lp].sym_array[syms].value);
}
}
FreeModules();
return(0);
}
extern void Syslog(int priority, char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
fprintf(stdout, "Pr: %d, ", priority);
vfprintf(stdout, fmt, ap);
va_end(ap);
fputc('\n', stdout);
return;
}
#endif